../plugins/wdc/wdc-nvme.c

Bug Summary

File:	.build-ci/../plugins/wdc/wdc-nvme.c
Warning:	line 6481, column 42 Result of 'malloc' is converted to a pointer of type 'struct wdc_nvme_hw_rev_log', which is incompatible with sizeof operand type '__u8'

Annotated Source Code

Press '?' to see keyboard shortcuts

Show analyzer invocation

clang -cc1 -cc1 -triple x86_64-pc-linux-gnu -analyze -disable-free -clear-ast-before-backend -disable-llvm-verifier -discard-value-names -main-file-name wdc-nvme.c -analyzer-checker=core -analyzer-checker=apiModeling -analyzer-checker=unix -analyzer-checker=deadcode -analyzer-checker=security.insecureAPI.UncheckedReturn -analyzer-checker=security.insecureAPI.getpw -analyzer-checker=security.insecureAPI.gets -analyzer-checker=security.insecureAPI.mktemp -analyzer-checker=security.insecureAPI.mkstemp -analyzer-checker=security.insecureAPI.vfork -analyzer-checker=nullability.NullPassedToNonnull -analyzer-checker=nullability.NullReturnedFromNonnull -analyzer-output plist -w -setup-static-analyzer -mrelocation-model pic -pic-level 2 -pic-is-pie -mframe-pointer=none -fmath-errno -ffp-contract=on -fno-rounding-math -mconstructor-aliases -funwind-tables=2 -target-cpu x86-64 -tune-cpu generic -debugger-tuning=gdb -fdebug-compilation-dir=/__w/nvme-cli/nvme-cli/.build-ci -fcoverage-compilation-dir=/__w/nvme-cli/nvme-cli/.build-ci -resource-dir /usr/lib/llvm-19/lib/clang/19 -include /__w/nvme-cli/nvme-cli/.build-ci/nvme-config.h -I nvme.p -I . -I .. -I ccan -I ../ccan -I libnvme/src -I ../libnvme/src -I /usr/include/json-c -D _FILE_OFFSET_BITS=64 -D _GNU_SOURCE -U NDEBUG -internal-isystem /usr/lib/llvm-19/lib/clang/19/include -internal-isystem /usr/local/include -internal-isystem /usr/lib/gcc/x86_64-linux-gnu/14/../../../../x86_64-linux-gnu/include -internal-externc-isystem /usr/include/x86_64-linux-gnu -internal-externc-isystem /include -internal-externc-isystem /usr/include -O3 -std=gnu99 -ferror-limit 19 -fgnuc-version=4.2.1 -fskip-odr-check-in-gmf -fcolor-diagnostics -vectorize-loops -vectorize-slp -analyzer-opt-analyze-headers -analyzer-output=html -faddrsig -D__GCC_HAVE_DWARF2_CFI_ASM=1 -o /__w/nvme-cli/nvme-cli/.build-ci/scan-results/2026-06-24-175442-590-1 -x c ../plugins/wdc/wdc-nvme.c

1	// SPDX-License-Identifier: GPL-2.0-or-later
2	/*
3	* Copyright (c) 2015-2018 Western Digital Corporation or its affiliates.
4	*
5	* This program is free software; you can redistribute it and/or
6	* modify it under the terms of the GNU General Public License
7	* as published by the Free Software Foundation; either version 2
8	* of the License, or (at your option) any later version.
9	*
10	* This program is distributed in the hope that it will be useful,
11	* but WITHOUT ANY WARRANTY; without even the implied warranty of
12	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13	* GNU General Public License for more details.
14	*
15	* You should have received a copy of the GNU General Public License
16	* along with this program; if not, write to the Free Software
17	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
18	* MA 02110-1301, USA.
19	*
20	* Author: Chaitanya Kulkarni <chaitanya.kulkarni@hgst.com>,
21	* Dong Ho <dong.ho@hgst.com>,
22	* Jeff Lien <jeff.lien@wdc.com>
23	* Brandon Paupore <brandon.paupore@wdc.com>
24	*/
25	#include <stdio.h>
26	#include <string.h>
27	#include <stdlib.h>
28	#include <inttypes.h>
29	#include <errno(*__errno_location ()).h>
30	#include <limits.h>
31	#include <fcntl.h>
32	#include <unistd.h>
33
34	#include <libnvme.h>
35
36	#include "common.h"
37	#include "nvme-cmds.h"
38	#include "nvme-print.h"
39	#include "nvme.h"
40	#include "plugin.h"
41	#include "util/cleanup.h"
42	#include "util/types.h"
43
44	#define CREATE_CMD
45	#include "wdc-nvme.h"
46	#include "wdc-utils.h"
47	#include "wdc-nvme-cmds.h"
48
49	#define WRITE_SIZE(sizeof(__u8) * 4096) (sizeof(__u8) * 4096)
50
51	#define WDC_NVME_SUBCMD_SHIFT8 8
52
53	#define WDC_NVME_LOG_SIZE_DATA_LEN0x08 0x08
54	#define WDC_NVME_LOG_SIZE_HDR_LEN0x08 0x08
55
56	/* Enclosure */
57	#define WDC_OPENFLEX_MI_DEVICE_MODEL"OpenFlex" "OpenFlex"
58	#define WDC_RESULT_MORE_DATA0x80000000 0x80000000
59	#define WDC_RESULT_NOT_AVAILABLE0x7FFFFFFF 0x7FFFFFFF
60
61	/* Device Config */
62	#define WDC_NVME_VID0x1c58 0x1c58
63	#define WDC_NVME_VID_20x1b96 0x1b96
64	#define WDC_NVME_SNDK_VID0x15b7 0x15b7
65
66	#define WDC_NVME_SN100_DEV_ID0x0003 0x0003
67	#define WDC_NVME_SN200_DEV_ID0x0023 0x0023
68	#define WDC_NVME_SN630_DEV_ID0x2200 0x2200
69	#define WDC_NVME_SN630_DEV_ID_10x2201 0x2201
70	#define WDC_NVME_SN840_DEV_ID0x2300 0x2300
71	#define WDC_NVME_SN840_DEV_ID_10x2500 0x2500
72	#define WDC_NVME_SN640_DEV_ID0x2400 0x2400
73	#define WDC_NVME_SN640_DEV_ID_10x2401 0x2401
74	#define WDC_NVME_SN640_DEV_ID_20x2402 0x2402
75	#define WDC_NVME_SN640_DEV_ID_30x2404 0x2404
76	#define WDC_NVME_ZN540_DEV_ID0x2600 0x2600
77	#define WDC_NVME_SN540_DEV_ID0x2610 0x2610
78	#define WDC_NVME_SN650_DEV_ID0x2700 0x2700
79	#define WDC_NVME_SN650_DEV_ID_10x2701 0x2701
80	#define WDC_NVME_SN650_DEV_ID_20x2702 0x2702
81	#define WDC_NVME_SN650_DEV_ID_30x2720 0x2720
82	#define WDC_NVME_SN650_DEV_ID_40x2721 0x2721
83	#define WDC_NVME_SN655_DEV_ID0x2722 0x2722
84	#define WDC_NVME_SN655_DEV_ID_10x2723 0x2723
85	#define WDC_NVME_SN860_DEV_ID0x2730 0x2730
86	#define WDC_NVME_SN660_DEV_ID0x2704 0x2704
87	#define WDC_NVME_SN560_DEV_ID_10x2712 0x2712
88	#define WDC_NVME_SN560_DEV_ID_20x2713 0x2713
89	#define WDC_NVME_SN560_DEV_ID_30x2714 0x2714
90	#define WDC_NVME_SN861_DEV_ID0x2750 0x2750
91	#define WDC_NVME_SN861_DEV_ID_10x2751 0x2751
92	#define WDC_NVME_SN861_DEV_ID_20x2752 0x2752
93	#define WDC_NVME_SNTMP_DEV_ID0x2761 0x2761
94	#define WDC_NVME_SNTMP_DEV_ID_10x2763 0x2763
95
96	#define WDC_NVME_SNESSD1_DEV_ID_E1L0x2765 0x2765
97	#define WDC_NVME_SNESSD1_DEV_ID_E20x2766 0x2766
98	#define WDC_NVME_SNESSD1_DEV_ID_E3S0x2767 0x2767
99	#define WDC_NVME_SNESSD1_DEV_ID_E3L0x2768 0x2768
100	#define WDC_NVME_SNESSD1_DEV_ID_U20x2769 0x2769
101
102	/* This id's are no longer supported, delete ?? */
103	#define WDC_NVME_SN550_DEV_ID0x2708 0x2708
104
105	#define WDC_NVME_SXSLCL_DEV_ID0x2001 0x2001
106	#define WDC_NVME_SN520_DEV_ID0x5003 0x5003
107	#define WDC_NVME_SN520_DEV_ID_10x5004 0x5004
108	#define WDC_NVME_SN520_DEV_ID_20x5005 0x5005
109
110	#define WDC_NVME_SN530_DEV_ID_10x5007 0x5007
111	#define WDC_NVME_SN530_DEV_ID_20x5008 0x5008
112	#define WDC_NVME_SN530_DEV_ID_30x5009 0x5009
113	#define WDC_NVME_SN530_DEV_ID_40x500b 0x500b
114	#define WDC_NVME_SN530_DEV_ID_50x501d 0x501d
115
116	#define WDC_NVME_SN350_DEV_ID0x5019 0x5019
117
118	#define WDC_NVME_SN570_DEV_ID0x501A 0x501A
119
120	#define WDC_NVME_SN850X_DEV_ID0x5030 0x5030
121
122	#define WDC_NVME_SN5000_DEV_ID_10x5034 0x5034
123	#define WDC_NVME_SN5000_DEV_ID_20x5035 0x5035
124	#define WDC_NVME_SN5000_DEV_ID_30x5036 0x5036
125	#define WDC_NVME_SN5000_DEV_ID_40x504A 0x504A
126
127	#define WDC_NVME_SN7000S_DEV_ID_10x5039 0x5039
128
129	#define WDC_NVME_SN7150_DEV_ID_10x503b 0x503b
130	#define WDC_NVME_SN7150_DEV_ID_20x503c 0x503c
131	#define WDC_NVME_SN7150_DEV_ID_30x503d 0x503d
132	#define WDC_NVME_SN7150_DEV_ID_40x503e 0x503e
133	#define WDC_NVME_SN7150_DEV_ID_50x503f 0x503f
134
135	#define WDC_NVME_SN7100_DEV_ID_10x5043 0x5043
136	#define WDC_NVME_SN7100_DEV_ID_20x5044 0x5044
137	#define WDC_NVME_SN7100_DEV_ID_30x5045 0x5045
138
139	#define WDC_NVME_SN8000S_DEV_ID0x5049 0x5049
140
141	#define WDC_NVME_SN720_DEV_ID0x5002 0x5002
142	#define WDC_NVME_SN730_DEV_ID0x5006 0x5006
143	#define WDC_NVME_SN740_DEV_ID0x5015 0x5015
144	#define WDC_NVME_SN740_DEV_ID_10x5016 0x5016
145	#define WDC_NVME_SN740_DEV_ID_20x5017 0x5017
146	#define WDC_NVME_SN740_DEV_ID_30x5025 0x5025
147	#define WDC_NVME_SN340_DEV_ID0x500d 0x500d
148	#define WDC_NVME_ZN350_DEV_ID0x5010 0x5010
149	#define WDC_NVME_ZN350_DEV_ID_10x5018 0x5018
150	#define WDC_NVME_SN810_DEV_ID0x5011 0x5011
151	#define WDC_NVME_SN820CL_DEV_ID0x5037 0x5037
152
153	#define WDC_NVME_SN5100S_DEV_ID_10x5061 0x5061
154	#define WDC_NVME_SN5100S_DEV_ID_20x5062 0x5062
155	#define WDC_NVME_SN5100S_DEV_ID_30x5063 0x5063
156
157	/* Shared flag space with SNDK plugin, should be kept in sync */
158	#define WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 0x0000000000000001
159	#define WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 0x0000000000000002
160	#define WDC_DRIVE_CAP_C1_LOG_PAGE0x0000000000000004 0x0000000000000004
161	#define WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008 0x0000000000000008
162	#define WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010 0x0000000000000010
163	#define WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 0x0000000000000020
164	#define WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 0x0000000000000040
165	#define WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080 0x0000000000000080
166	#define WDC_DRIVE_CAP_RESIZE0x0000000000000100 0x0000000000000100
167	#define WDC_DRIVE_CAP_NAND_STATS0x0000000000000200 0x0000000000000200
168	#define WDC_DRIVE_CAP_DRIVE_LOG0x0000000000000400 0x0000000000000400
169	#define WDC_DRIVE_CAP_CRASH_DUMP0x0000000000000800 0x0000000000000800
170	#define WDC_DRIVE_CAP_PFAIL_DUMP0x0000000000001000 0x0000000000001000
171	#define WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY0x0000000000002000 0x0000000000002000
172	#define WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY0x0000000000004000 0x0000000000004000
173	#define WDC_DRVIE_CAP_DISABLE_CTLR_TELE_LOG0x0000000000008000 0x0000000000008000
174	#define WDC_DRIVE_CAP_REASON_ID0x0000000000010000 0x0000000000010000
175	#define WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000 0x0000000000020000
176	#define WDC_DRIVE_CAP_NS_RESIZE0x0000000000040000 0x0000000000040000
177	#define WDC_DRIVE_CAP_INFO0x0000000000080000 0x0000000000080000
178	#define WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000 0x0000000000100000
179	#define WDC_DRIVE_CAP_TEMP_STATS0x0000000000200000 0x0000000000200000
180	#define WDC_DRIVE_CAP_VUC_CLEAR_PCIE0x0000000000400000 0x0000000000400000
181	#define WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000 0x0000000000800000
182	#define WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_C20x0000000001000000 0x0000000001000000
183	#define WDC_DRIVE_CAP_VU_FID_CLEAR_FW_ACT_HISTORY0x0000000002000000 0x0000000002000000
184	#define WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000 0x0000000004000000
185	#define WDC_DRIVE_CAP_PCIE_STATS0x0000000008000000 0x0000000008000000
186	#define WDC_DRIVE_CAP_HW_REV_LOG_PAGE0x0000000010000000 0x0000000010000000
187	#define WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000 0x0000000020000000
188	#define WDC_DRIVE_CAP_CLOUD_BOOT_SSD_VERSION0x0000000040000000 0x0000000040000000
189	#define WDC_DRIVE_CAP_CLOUD_LOG_PAGE0x0000000080000000 0x0000000080000000
190	#define WDC_DRIVE_CAP_DRIVE_ESSENTIALS0x0000000100000000 0x0000000100000000
191	#define WDC_DRIVE_CAP_DUI_DATA0x0000000200000000 0x0000000200000000
192	#define WDC_SN730B_CAP_VUC_LOG0x0000000400000000 0x0000000400000000
193	#define WDC_DRIVE_CAP_DUI0x0000000800000000 0x0000000800000000
194	#define WDC_DRIVE_CAP_PURGE0x0000001000000000 0x0000001000000000
195	#define WDC_DRIVE_CAP_OCP_C1_LOG_PAGE0x0000002000000000 0x0000002000000000
196	#define WDC_DRIVE_CAP_OCP_C4_LOG_PAGE0x0000004000000000 0x0000004000000000
197	#define WDC_DRIVE_CAP_OCP_C5_LOG_PAGE0x0000008000000000 0x0000008000000000
198	#define WDC_DRIVE_CAP_DEVICE_WAF0x0000010000000000 0x0000010000000000
199	#define WDC_DRIVE_CAP_SET_LATENCY_MONITOR0x0000020000000000 0x0000020000000000
200	#define WDC_DRIVE_CAP_UDUI0x0000040000000000 0x0000040000000000
201	#define WDC_DRIVE_CAP_RESIZE_SN8610x0000080000000000 0x0000080000000000
202
203	/* Any new capability flags should be added to the SNDK plugin */
204
205	#define WDC_DRIVE_CAP_SMART_LOG_MASK(0x0000000000100000 \| 0x0000000000000004 \| 0x0000000000000008 \| 0x0000000000000010) (WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000 \| \
206	WDC_DRIVE_CAP_C1_LOG_PAGE0x0000000000000004 \| \
207	WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008 \| \
208	WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010)
209	#define WDC_DRIVE_CAP_CLEAR_PCIE_MASK(0x0000000000000080 \| 0x0000000000400000 \| 0x0000000000800000 ) (WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080 \| \
210	WDC_DRIVE_CAP_VUC_CLEAR_PCIE0x0000000000400000 \| \
211	WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000)
212	#define WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_MASK(0x0000000000002000 \| 0x0000000001000000) (WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY0x0000000000002000 \| \
213	WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_C20x0000000001000000)
214	#define WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY_MASK(0x0000000000004000 \| 0x0000000002000000) (WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY0x0000000000004000 \| \
215	WDC_DRIVE_CAP_VU_FID_CLEAR_FW_ACT_HISTORY0x0000000002000000)
216	#define WDC_DRIVE_CAP_INTERNAL_LOG_MASK(0x0000000000000002 \| 0x0000000800000000 \| 0x0000000200000000 \| 0x0000000400000000) (WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \| \
217	WDC_DRIVE_CAP_DUI0x0000000800000000 \| \
218	WDC_DRIVE_CAP_DUI_DATA0x0000000200000000 \| \
219	WDC_SN730B_CAP_VUC_LOG0x0000000400000000)
220
221	/* SN730 Get Log Capabilities */
222	#define SN730_NVME_GET_LOG_OPCODE0xc2 0xc2
223	#define SN730_GET_FULL_LOG_LENGTH0x00080009 0x00080009
224	#define SN730_GET_KEY_LOG_LENGTH0x00090009 0x00090009
225	#define SN730_GET_COREDUMP_LOG_LENGTH0x00120009 0x00120009
226	#define SN730_GET_EXTENDED_LOG_LENGTH0x00420009 0x00420009
227
228	#define SN730_GET_FULL_LOG_SUBOPCODE0x00010009 0x00010009
229	#define SN730_GET_KEY_LOG_SUBOPCODE0x00020009 0x00020009
230	#define SN730_GET_CORE_LOG_SUBOPCODE0x00030009 0x00030009
231	#define SN730_GET_EXTEND_LOG_SUBOPCODE0x00040009 0x00040009
232	#define SN730_LOG_CHUNK_SIZE0x1000 0x1000
233
234	/* Customer ID's */
235	#define WDC_CUSTOMER_ID_GN0x0001 0x0001
236	#define WDC_CUSTOMER_ID_GD0x0101 0x0101
237	#define WDC_CUSTOMER_ID_BD0x1009 0x1009
238
239	#define WDC_CUSTOMER_ID_0x00F00x00F0 0x00F0
240	#define WDC_CUSTOMER_ID_0x10040x1004 0x1004
241	#define WDC_CUSTOMER_ID_0x10050x1005 0x1005
242	#define WDC_CUSTOMER_ID_0x10080x1008 0x1008
243	#define WDC_CUSTOMER_ID_0x13040x1304 0x1304
244	#define WDC_INVALID_CUSTOMER_ID-1 -1
245
246	#define WDC_ALL_PAGE_MASK0xFFFF 0xFFFF
247	#define WDC_C0_PAGE_MASK0x0001 0x0001
248	#define WDC_C1_PAGE_MASK0x0002 0x0002
249	#define WDC_CA_PAGE_MASK0x0004 0x0004
250	#define WDC_D0_PAGE_MASK0x0008 0x0008
251
252	/* Drive Resize */
253	#define WDC_NVME_DRIVE_RESIZE_OPCODE0xCC 0xCC
254	#define WDC_NVME_DRIVE_RESIZE_CMD0x03 0x03
255	#define WDC_NVME_DRIVE_RESIZE_SUBCMD0x01 0x01
256
257	/* Namespace Resize */
258	#define WDC_NVME_NAMESPACE_RESIZE_OPCODE0xFB 0xFB
259
260	/* Drive Info */
261	#define WDC_NVME_DRIVE_INFO_OPCODE0xC6 0xC6
262	#define WDC_NVME_DRIVE_INFO_CMD0x22 0x22
263	#define WDC_NVME_DRIVE_INFO_SUBCMD0x06 0x06
264
265	/* VS PCIE Stats */
266	#define WDC_NVME_PCIE_STATS_OPCODE0xD1 0xD1
267
268	/* Capture Diagnostics */
269	#define WDC_NVME_CAP_DIAG_HEADER_TOC_SIZE0x08 WDC_NVME_LOG_SIZE_DATA_LEN0x08
270	#define WDC_NVME_CAP_DIAG_OPCODE0xE6 0xE6
271	#define WDC_NVME_CAP_DIAG_CMD_OPCODE0xC6 0xC6
272	#define WDC_NVME_CAP_DIAG_SUBCMD0x00 0x00
273	#define WDC_NVME_CAP_DIAG_CMD0x00 0x00
274
275	#define WDC_NVME_CRASH_DUMP_TYPE1 1
276	#define WDC_NVME_PFAIL_DUMP_TYPE2 2
277
278	/* Capture Device Unit Info */
279	#define WDC_NVME_CAP_DUI_HEADER_SIZE0x400 0x400
280	#define WDC_NVME_CAP_DUI_OPCODE0xFA 0xFA
281	#define WDC_NVME_CAP_DUI_DISABLE_IO0x01 0x01
282	#define WDC_NVME_DUI_MAX_SECTION0x3A 0x3A
283	#define WDC_NVME_DUI_MAX_SECTION_V20x26 0x26
284	#define WDC_NVME_DUI_MAX_SECTION_V30x23 0x23
285	#define WDC_NVME_DUI_MAX_DATA_AREA0x05 0x05
286	#define WDC_NVME_SN730_SECTOR_SIZE512 512
287
288	/* Telemtery types for vs-internal-log command */
289	#define WDC_TELEMETRY_TYPE_NONE0x0 0x0
290	#define WDC_TELEMETRY_TYPE_HOST0x1 0x1
291	#define WDC_TELEMETRY_TYPE_CONTROLLER0x2 0x2
292	#define WDC_TELEMETRY_HEADER_LENGTH512 512
293	#define WDC_TELEMETRY_BLOCK_SIZE512 512
294
295	/* Crash dump */
296	#define WDC_NVME_CRASH_DUMP_SIZE_DATA_LEN0x08 WDC_NVME_LOG_SIZE_DATA_LEN0x08
297	#define WDC_NVME_CRASH_DUMP_SIZE_NDT0x02 0x02
298	#define WDC_NVME_CRASH_DUMP_SIZE_CMD0x20 0x20
299	#define WDC_NVME_CRASH_DUMP_SIZE_SUBCMD0x03 0x03
300
301	#define WDC_NVME_CRASH_DUMP_OPCODE0xC6 WDC_NVME_CAP_DIAG_CMD_OPCODE0xC6
302	#define WDC_NVME_CRASH_DUMP_CMD0x20 0x20
303	#define WDC_NVME_CRASH_DUMP_SUBCMD0x04 0x04
304
305	/* PFail Crash dump */
306	#define WDC_NVME_PF_CRASH_DUMP_SIZE_DATA_LEN0x08 WDC_NVME_LOG_SIZE_HDR_LEN0x08
307	#define WDC_NVME_PF_CRASH_DUMP_SIZE_NDT0x02 0x02
308	#define WDC_NVME_PF_CRASH_DUMP_SIZE_CMD0x20 0x20
309	#define WDC_NVME_PF_CRASH_DUMP_SIZE_SUBCMD0x05 0x05
310
311	#define WDC_NVME_PF_CRASH_DUMP_OPCODE0xC6 WDC_NVME_CAP_DIAG_CMD_OPCODE0xC6
312	#define WDC_NVME_PF_CRASH_DUMP_CMD0x20 0x20
313	#define WDC_NVME_PF_CRASH_DUMP_SUBCMD0x06 0x06
314
315	/* Drive Log */
316	#define WDC_NVME_DRIVE_LOG_SIZE_OPCODE0xC6 WDC_NVME_CAP_DIAG_CMD_OPCODE0xC6
317	#define WDC_NVME_DRIVE_LOG_SIZE_DATA_LEN0x08 WDC_NVME_LOG_SIZE_DATA_LEN0x08
318	#define WDC_NVME_DRIVE_LOG_SIZE_NDT0x02 0x02
319	#define WDC_NVME_DRIVE_LOG_SIZE_CMD0x20 0x20
320	#define WDC_NVME_DRIVE_LOG_SIZE_SUBCMD0x01 0x01
321
322	#define WDC_NVME_DRIVE_LOG_OPCODE0xC6 WDC_NVME_CAP_DIAG_CMD_OPCODE0xC6
323	#define WDC_NVME_DRIVE_LOG_CMD0x20 0x20
324	#define WDC_NVME_DRIVE_LOG_SUBCMD0x00 0x00
325
326	/* Purge and Purge Monitor */
327	#define WDC_NVME_PURGE_CMD_OPCODE0xDD 0xDD
328	#define WDC_NVME_PURGE_MONITOR_OPCODE0xDE 0xDE
329	#define WDC_NVME_PURGE_MONITOR_DATA_LEN0x2F 0x2F
330	#define WDC_NVME_PURGE_MONITOR_CMD_CDW100x0000000C 0x0000000C
331	#define WDC_NVME_PURGE_MONITOR_TIMEOUT0x7530 0x7530
332	#define WDC_NVME_PURGE_CMD_SEQ_ERR0x0C 0x0C
333	#define WDC_NVME_PURGE_INT_DEV_ERR0x06 0x06
334
335	#define WDC_NVME_PURGE_STATE_IDLE0x00 0x00
336	#define WDC_NVME_PURGE_STATE_DONE0x01 0x01
337	#define WDC_NVME_PURGE_STATE_BUSY0x02 0x02
338	#define WDC_NVME_PURGE_STATE_REQ_PWR_CYC0x03 0x03
339	#define WDC_NVME_PURGE_STATE_PWR_CYC_PURGE0x04 0x04
340
341	/* Clear dumps */
342	#define WDC_NVME_CLEAR_DUMP_OPCODE0xFF 0xFF
343	#define WDC_NVME_CLEAR_CRASH_DUMP_CMD0x03 0x03
344	#define WDC_NVME_CLEAR_CRASH_DUMP_SUBCMD0x05 0x05
345	#define WDC_NVME_CLEAR_PF_CRASH_DUMP_SUBCMD0x06 0x06
346
347	/* Clear FW Activate History */
348	#define WDC_NVME_CLEAR_FW_ACT_HIST_OPCODE0xC6 0xC6
349	#define WDC_NVME_CLEAR_FW_ACT_HIST_CMD0x23 0x23
350	#define WDC_NVME_CLEAR_FW_ACT_HIST_SUBCMD0x05 0x05
351	#define WDC_NVME_CLEAR_FW_ACT_HIST_VU_FID0xC1 0xC1
352
353	/* Additional Smart Log */
354	#define WDC_ADD_LOG_BUF_LEN0x4000 0x4000
355	#define WDC_NVME_ADD_LOG_OPCODE0xC1 0xC1
356	#define WDC_GET_LOG_PAGE_SSD_PERFORMANCE0x37 0x37
357	#define WDC_NVME_GET_STAT_PERF_INTERVAL_LIFETIME0x0F 0x0F
358
359	/* C2 Log Page */
360	#define WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2 0xC2
361	#define WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID_C80xC8 0xC8
362	#define WDC_C2_LOG_BUF_LEN0x1000 0x1000
363	#define WDC_C2_MARKETING_NAME_ID0x07 0x07
364	#define WDC_C2_LOG_PAGES_SUPPORTED_ID0x08 0x08
365	#define WDC_C2_CUSTOMER_ID_ID0x15 0x15
366	#define WDC_C2_THERMAL_THROTTLE_STATUS_ID0x18 0x18
367	#define WDC_C2_ASSERT_DUMP_PRESENT_ID0x19 0x19
368	#define WDC_C2_USER_EOL_STATUS_ID0x1A 0x1A
369	#define WDC_C2_USER_EOL_STATE_ID0x1C 0x1C
370	#define WDC_C2_SYSTEM_EOL_STATE_ID0x1D 0x1D
371	#define WDC_C2_FORMAT_CORRUPT_REASON_ID0x1E 0x1E
372	#define WDC_EOL_STATUS_NORMALcpu_to_le32(0x00000000) cpu_to_le32(0x00000000)
373	#define WDC_EOL_STATUS_END_OF_LIFEcpu_to_le32(0x00000001) cpu_to_le32(0x00000001)
374	#define WDC_EOL_STATUS_READ_ONLYcpu_to_le32(0x00000002) cpu_to_le32(0x00000002)
375	#define WDC_ASSERT_DUMP_NOT_PRESENTcpu_to_le32(0x00000000) cpu_to_le32(0x00000000)
376	#define WDC_ASSERT_DUMP_PRESENTcpu_to_le32(0x00000001) cpu_to_le32(0x00000001)
377	#define WDC_THERMAL_THROTTLING_OFFcpu_to_le32(0x00000000) cpu_to_le32(0x00000000)
378	#define WDC_THERMAL_THROTTLING_ONcpu_to_le32(0x00000001) cpu_to_le32(0x00000001)
379	#define WDC_THERMAL_THROTTLING_UNAVAILABLEcpu_to_le32(0x00000002) cpu_to_le32(0x00000002)
380	#define WDC_FORMAT_NOT_CORRUPTcpu_to_le32(0x00000000) cpu_to_le32(0x00000000)
381	#define WDC_FORMAT_CORRUPT_FW_ASSERTcpu_to_le32(0x00000001) cpu_to_le32(0x00000001)
382	#define WDC_FORMAT_CORRUPT_UNKNOWNcpu_to_le32(0x000000FF) cpu_to_le32(0x000000FF)
383	#define WDC_SN861_MARKETING_NAME_1"Ultrastar DC SN861" "Ultrastar DC SN861"
384	#define WDC_SN861_MARKETING_NAME_2"ULTRASTAR DC SN861" "ULTRASTAR DC SN861"
385
386	/* CA Log Page */
387	#define WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA 0xCA
388	#define WDC_FB_CA_LOG_BUF_LEN0x80 0x80
389	/* Added 4 padding bytes to resolve build warning messages */
390	#define WDC_BD_CA_LOG_BUF_LEN0xA0 0xA0
391
392	/* C0 EOL Status Log Page */
393	#define WDC_NVME_GET_EOL_STATUS_LOG_OPCODE0xC0 0xC0
394	#define WDC_NVME_EOL_STATUS_LOG_LEN0x200 0x200
395	#define WDC_NVME_SMART_CLOUD_ATTR_LEN0x200 0x200
396
397	/* C0 SMART Cloud Attributes Log Page*/
398	#define WDC_NVME_GET_SMART_CLOUD_ATTR_LOG_ID0xC0 0xC0
399
400	/* CB - FW Activate History Log Page */
401	#define WDC_NVME_GET_FW_ACT_HISTORY_LOG_ID0xCB 0xCB
402	#define WDC_FW_ACT_HISTORY_LOG_BUF_LEN0x3d0 0x3d0
403
404	/* C2 - FW Activation History Log Page */
405	#define WDC_NVME_GET_FW_ACT_HISTORY_C2_LOG_ID0xC2 0xC2
406	#define WDC_FW_ACT_HISTORY_C2_LOG_BUF_LEN0x1000 0x1000
407	#define WDC_MAX_NUM_ACT_HIST_ENTRIES20 20
408	#define WDC_C2_GUID_LENGTH16 16
409
410	/* C3 Latency Monitor Log Page */
411	#define WDC_LATENCY_MON_LOG_BUF_LEN0x200 0x200
412	#define WDC_LATENCY_MON_LOG_ID0xC3 0xC3
413	#define WDC_LATENCY_MON_VERSION0x0001 0x0001
414
415	#define WDC_C3_GUID_LENGTH16 16
416	static __u8 wdc_lat_mon_guid[WDC_C3_GUID_LENGTH16] = {
417	0x92, 0x7a, 0xc0, 0x8c, 0xd0, 0x84, 0x6c, 0x9c,
418	0x70, 0x43, 0xe6, 0xd4, 0x58, 0x5e, 0xd4, 0x85
419	};
420
421	/* D0 Smart Log Page */
422	#define WDC_NVME_GET_VU_SMART_LOG_OPCODE0xD0 0xD0
423	#define WDC_NVME_VU_SMART_LOG_LEN0x200 0x200
424
425	/* Log Page Directory defines */
426	#define NVME_LOG_PERSISTENT_EVENT0x0D 0x0D
427	#define WDC_LOG_ID_C00xC0 0xC0
428	#define WDC_LOG_ID_C10xC1 0xC1
429	#define WDC_LOG_ID_C20xC2 WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2
430	#define WDC_LOG_ID_C30xC3 0xC3
431	#define WDC_LOG_ID_C40xC4 0xC4
432	#define WDC_LOG_ID_C50xC5 0xC5
433	#define WDC_LOG_ID_C60xC6 0xC6
434	#define WDC_LOG_ID_C80xC8 WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID_C80xC8
435	#define WDC_LOG_ID_CA0xCA WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA
436	#define WDC_LOG_ID_CB0xCB WDC_NVME_GET_FW_ACT_HISTORY_LOG_ID0xCB
437	#define WDC_LOG_ID_D00xD0 WDC_NVME_GET_VU_SMART_LOG_OPCODE0xD0
438	#define WDC_LOG_ID_D10xD1 0xD1
439	#define WDC_LOG_ID_D60xD6 0xD6
440	#define WDC_LOG_ID_D70xD7 0xD7
441	#define WDC_LOG_ID_D80xD8 0xD8
442	#define WDC_LOG_ID_DE0xDE 0xDE
443	#define WDC_LOG_ID_F00xF0 0xF0
444	#define WDC_LOG_ID_F10xF1 0xF1
445	#define WDC_LOG_ID_F20xF2 0xF2
446	#define WDC_LOG_ID_FA0xFA 0xFA
447
448	/* Clear PCIe Correctable Errors */
449	#define WDC_NVME_CLEAR_PCIE_CORR_OPCODE0xC6 WDC_NVME_CAP_DIAG_CMD_OPCODE0xC6
450	#define WDC_NVME_CLEAR_PCIE_CORR_CMD0x22 0x22
451	#define WDC_NVME_CLEAR_PCIE_CORR_SUBCMD0x04 0x04
452	#define WDC_NVME_CLEAR_PCIE_CORR_OPCODE_VUC0xD2 0xD2
453	#define WDC_NVME_CLEAR_PCIE_CORR_FEATURE_ID0xC3 0xC3
454	/* Clear Assert Dump Status */
455	#define WDC_NVME_CLEAR_ASSERT_DUMP_OPCODE0xD8 0xD8
456	#define WDC_NVME_CLEAR_ASSERT_DUMP_CMD0x03 0x03
457	#define WDC_NVME_CLEAR_ASSERT_DUMP_SUBCMD0x05 0x05
458
459	#define WDC_VU_DISABLE_CNTLR_TELEMETRY_OPTION_FEATURE_ID0xD2 0xD2
460
461	/* Drive Essentials */
462	#define WDC_DE_DEFAULT_NUMBER_OF_ERROR_ENTRIES64 64
463	#define WDC_DE_GENERIC_BUFFER_SIZE80 80
464	#define WDC_DE_GLOBAL_NSID0xFFFFFFFF 0xFFFFFFFF
465	#define WDC_DE_DEFAULT_NAMESPACE_ID0x01 0x01
466	#define WDC_DE_PATH_SEPARATOR"/" "/"
467	#define WDC_DE_TAR_FILES".bin" ".bin"
468	#define WDC_DE_TAR_FILE_EXTN".tar.gz" ".tar.gz"
469	#define WDC_DE_TAR_CMD"tar -czf" "tar -czf"
470
471	/* VS NAND Stats */
472	#define WDC_NVME_NAND_STATS_LOG_ID0xFB 0xFB
473	#define WDC_NVME_NAND_STATS_SIZE0x200 0x200
474
475	/* VU Opcodes */
476	#define WDC_DE_VU_READ_SIZE_OPCODE0xC0 0xC0
477	#define WDC_DE_VU_READ_BUFFER_OPCODE0xC2 0xC2
478	#define WDC_NVME_ADMIN_ENC_MGMT_SND0xC9 0xC9
479	#define WDC_NVME_ADMIN_ENC_MGMT_RCV0xCA 0xCA
480
481	#define WDC_DE_FILE_HEADER_SIZE4 4
482	#define WDC_DE_FILE_OFFSET_SIZE2 2
483	#define WDC_DE_FILE_NAME_SIZE32 32
484	#define WDC_DE_VU_READ_BUFFER_STANDARD_OFFSET0x8000 0x8000
485	#define WDC_DE_READ_MAX_TRANSFER_SIZE0x8000 0x8000
486
487	#define WDC_DE_MANUFACTURING_INFO_PAGE_FILE_NAME"manufacturing_info" "manufacturing_info" /* Unique log entry page name. */
488	#define WDC_DE_CORE_DUMP_FILE_NAME"core_dump" "core_dump"
489	#define WDC_DE_EVENT_LOG_FILE_NAME"event_log" "event_log"
490	#define WDC_DE_DESTN_SPI1 1
491	#define WDC_DE_DUMPTRACE_DESTINATION6 6
492
493	#define NVME_ID_CTRL_MODEL_NUMBER_SIZE40 40
494	#define NVME_ID_CTRL_SERIAL_NUMBER_SIZE20 20
495
496	/* Enclosure log */
497	#define WDC_NVME_ENC_LOG_SIZE_CHUNK0x1000 0x1000
498	#define WDC_NVME_ENC_NIC_LOG_SIZE0x400000 0x400000
499
500	/* Enclosure nic crash dump get-log id */
501	#define WDC_ENC_NIC_CRASH_DUMP_ID_SLOT_10xD1 0xD1
502	#define WDC_ENC_NIC_CRASH_DUMP_ID_SLOT_20xD2 0xD2
503	#define WDC_ENC_NIC_CRASH_DUMP_ID_SLOT_30xD3 0xD3
504	#define WDC_ENC_NIC_CRASH_DUMP_ID_SLOT_40xD4 0xD4
505	#define WDC_ENC_CRASH_DUMP_ID0xE4 0xE4
506	#define WDC_ENC_LOG_DUMP_ID0xE2 0xE2
507
508	/* OCP Log Page Directory Data Structure */
509	#define BYTE_TO_BIT(byte)((byte) * 8) ((byte) * 8)
510
511	/* Set latency monitor feature */
512	#define NVME_FEAT_OCP_LATENCY_MONITOR0xC5 0xC5
513
514	enum _NVME_FEATURES_SELECT {
515	FS_CURRENT = 0,
516	FS_DEFAULT = 1,
517	FS_SAVED = 2,
518	FS_SUPPORTED_CAPBILITIES = 3
519	};
520
521	enum NVME_FEATURE_IDENTIFIERS {
522	FID_ARBITRATION = 0x01,
523	FID_POWER_MANAGEMENT = 0x02,
524	FID_LBA_RANGE_TYPE = 0x03,
525	FID_TEMPERATURE_THRESHOLD = 0x04,
526	FID_ERROR_RECOVERY = 0x05,
527	FID_VOLATILE_WRITE_CACHE = 0x06,
528	FID_NUMBER_OF_QUEUES = 0x07,
529	FID_INTERRUPT_COALESCING = 0x08,
530	FID_INTERRUPT_VECTOR_CONFIGURATION = 0x09,
531	FID_WRITE_ATOMICITY = 0x0A,
532	FID_ASYNCHRONOUS_EVENT_CONFIGURATION = 0x0B,
533	FID_AUTONOMOUS_POWER_STATE_TRANSITION = 0x0C,
534	/Below FID's are NVM Command Set Specific/
535	FID_SOFTWARE_PROGRESS_MARKER = 0x80,
536	FID_HOST_IDENTIFIER = 0x81,
537	FID_RESERVATION_NOTIFICATION_MASK = 0x82,
538	FID_RESERVATION_PERSISTENCE = 0x83
539	};
540
541	/* WDC UUID value */
542	static const __u8 WDC_UUID[NVME_UUID_LEN16] = {
543	0x2d, 0xb9, 0x8c, 0x52, 0x0c, 0x4c, 0x5a, 0x15,
544	0xab, 0xe6, 0x33, 0x29, 0x9a, 0x70, 0xdf, 0xd0
545	};
546
547	/* WDC_UUID value for SN640_3 devices */
548	static const __u8 WDC_UUID_SN640_3[NVME_UUID_LEN16] = {
549	0x11, 0x11, 0x11, 0x11, 0x11, 0x11, 0x11, 0x11,
550	0x22, 0x22, 0x22, 0x22, 0x22, 0x22, 0x22, 0x22
551	};
552
553	/* Sandisk UUID value */
554	static const __u8 SNDK_UUID[NVME_UUID_LEN16] = {
555	0xde, 0x87, 0xd1, 0xeb, 0x72, 0xc5, 0x58, 0x0b,
556	0xad, 0xd8, 0x3c, 0x29, 0xd1, 0x23, 0x7c, 0x70
557	};
558
559	enum WDC_DRIVE_ESSENTIAL_TYPE {
560	WDC_DE_TYPE_IDENTIFY = 0x1,
561	WDC_DE_TYPE_SMARTATTRIBUTEDUMP = 0x2,
562	WDC_DE_TYPE_EVENTLOG = 0x4,
563	WDC_DE_TYPE_DUMPTRACE = 0x8,
564	WDC_DE_TYPE_DUMPSNAPSHOT = 0x10,
565	WDC_DE_TYPE_ATA_LOGS = 0x20,
566	WDC_DE_TYPE_SMART_LOGS = 0x40,
567	WDC_DE_TYPE_SCSI_LOGS = 0x80,
568	WDC_DE_TYPE_SCSI_MODE_PAGES = 0x100,
569	WDC_DE_TYPE_NVMe_FEATURES = 0x200,
570	WDC_DE_TYPE_DUMPSMARTERRORLOG3 = 0x400,
571	WDC_DE_TYPE_DUMPLOG3E = 0x800,
572	WDC_DE_TYPE_DUMPSCRAM = 0x1000,
573	WDC_DE_TYPE_PCU_LOG = 0x2000,
574	WDC_DE_TYPE_DUMP_ERROR_LOGS = 0x4000,
575	WDC_DE_TYPE_FW_SLOT_LOGS = 0x8000,
576	WDC_DE_TYPE_MEDIA_SETTINGS = 0x10000,
577	WDC_DE_TYPE_SMART_DATA = 0x20000,
578	WDC_DE_TYPE_NVME_SETTINGS = 0x40000,
579	WDC_DE_TYPE_NVME_ERROR_LOGS = 0x80000,
580	WDC_DE_TYPE_NVME_LOGS = 0x100000,
581	WDC_DE_TYPE_UART_LOGS = 0x200000,
582	WDC_DE_TYPE_DLOGS_SPI = 0x400000,
583	WDC_DE_TYPE_DLOGS_RAM = 0x800000,
584	WDC_DE_TYPE_NVME_MANF_INFO = 0x2000000,
585	WDC_DE_TYPE_NONE = 0x1000000,
586	WDC_DE_TYPE_ALL = 0xFFFFFFF,
587	};
588
589	#define WDC_C0_GUID_LENGTH16 16
590	#define WDC_SCA_V1_NAND_STATS0x1 0x1
591	#define WDC_SCA_V1_ALL0xF 0xF
592	enum {
593	SCAO_V1_PMUWT = 0, /* Physical media units written TLC */
594	SCAO_V1_PMUWS = 16, /* Physical media units written SLC */
595	SCAO_V1_BUNBN = 32, /* Bad user nand blocks normalized */
596	SCAO_V1_BUNBR = 34, /* Bad user nand blocks raw */
597	SCAO_V1_XRC = 40, /* XOR recovery count */
598	SCAO_V1_UREC = 48, /* Uncorrectable read error count */
599	SCAO_V1_EECE = 56, /* End to end corrected errors */
600	SCAO_V1_EEDE = 64, /* End to end detected errors */
601	SCAO_V1_EEUE = 72, /* End to end uncorrected errors */
602	SCAO_V1_SDPU = 80, /* System data percent used */
603	SCAO_V1_MNUDEC = 84, /* Min User data erase counts (TLC) */
604	SCAO_V1_MXUDEC = 92, /* Max User data erase counts (TLC) */
605	SCAO_V1_AVUDEC = 100, /* Average User data erase counts (TLC) */
606	SCAO_V1_MNEC = 108, /* Min Erase counts (SLC) */
607	SCAO_V1_MXEC = 116, /* Max Erase counts (SLC) */
608	SCAO_V1_AVEC = 124, /* Average Erase counts (SLC) */
609	SCAO_V1_PFCN = 132, /* Program fail count normalized */
610	SCAO_V1_PFCR = 134, /* Program fail count raw */
611	SCAO_V1_EFCN = 140, /* Erase fail count normalized */
612	SCAO_V1_EFCR = 142, /* Erase fail count raw */
613	SCAO_V1_PCEC = 148, /* PCIe correctable error count */
614	SCAO_V1_PFBU = 156, /* Percent free blocks (User) */
615	SCAO_V1_SVN = 160, /* Security Version Number */
616	SCAO_V1_PFBS = 168, /* Percent free blocks (System) */
617	SCAO_V1_DCC = 172, /* Deallocate Commands Completed */
618	SCAO_V1_TNU = 188, /* Total Namespace Utilization */
619	SCAO_V1_FCC = 196, /* Format NVM Commands Completed */
620	SCAO_V1_BBPG = 198, /* Background Back-Pressure Gauge */
621	SCAO_V1_SEEC = 202, /* Soft ECC error count */
622	SCAO_V1_RFSC = 210, /* Refresh count */
623	SCAO_V1_BSNBN = 218, /* Bad system nand blocks normalized */
624	SCAO_V1_BSNBR = 220, /* Bad system nand blocks raw */
625	SCAO_V1_EEST = 226, /* Endurance estimate */
626	SCAO_V1_TTC = 242, /* Thermal throttling count */
627	SCAO_V1_UIO = 244, /* Unaligned I/O */
628	SCAO_V1_PMUR = 252, /* Physical media units read */
629	SCAO_V1_RTOC = 268, /* Read command timeout count */
630	SCAO_V1_WTOC = 272, /* Write command timeout count */
631	SCAO_V1_TTOC = 276, /* Trim command timeout count */
632	SCAO_V1_PLRC = 284, /* PCIe Link Retraining Count */
633	SCAO_V1_PSCC = 292, /* Power State Change Count */
634	SCAO_V1_MAVF = 300, /* Boot SSD major version field */
635	SCAO_V1_MIVF = 302, /* Boot SSD minor version field */
636	SCAO_V1_PVF = 304, /* Boot SSD point version field */
637	SCAO_V1_EVF = 306, /* Boot SSD errata version field */
638	SCAO_V1_FTLUS = 308, /* FTL Unit Size */
639	SCAO_V1_TCGOS = 312, /* TCG Ownership Status */
640
641	SCAO_V1_LPV = 494, /* Log page version - 0x0001 */
642	SCAO_V1_LPG = 496, /* Log page GUID */
643	};
644
645	static __u8 ext_smart_guid[WDC_C0_GUID_LENGTH16] = {
646	0x65, 0x43, 0x88, 0x78, 0xAC, 0xD8, 0x78, 0xA1,
647	0x66, 0x42, 0x1E, 0x0F, 0x92, 0xD7, 0x6D, 0xC4
648	};
649
650	struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log {
651	__u8 ext_smart_pmuwt[16]; /* 000 Physical media units written TLC */
652	__u8 ext_smart_pmuws[16]; /* 016 Physical media units written SLC */
653	__u8 ext_smart_bunbc[8]; /* 032 Bad user nand block count */
654	__u64 ext_smart_xrc; /* 040 XOR recovery count */
655	__u64 ext_smart_urec; /* 048 Uncorrectable read error count */
656	__u64 ext_smart_eece; /* 056 End to end corrected errors */
657	__u64 ext_smart_eede; /* 064 End to end detected errors */
658	__u64 ext_smart_eeue; /* 072 End to end uncorrected errors */
659	__u8 ext_smart_sdpu; /* 080 System data percent used */
660	__u8 ext_smart_rsvd1[3]; /* 081 reserved */
661	__u64 ext_smart_mnudec; /* 084 Min User data erase counts (TLC) */
662	__u64 ext_smart_mxudec; /* 092 Max User data erase counts (TLC) */
663	__u64 ext_smart_avudec; /* 100 Average User data erase counts (TLC) */
664	__u64 ext_smart_mnec; /* 108 Min Erase counts (SLC) */
665	__u64 ext_smart_mxec; /* 116 Max Erase counts (SLC) */
666	__u64 ext_smart_avec; /* 124 Average Erase counts (SLC) */
667	__u8 ext_smart_pfc[8]; /* 132 Program fail count */
668	__u8 ext_smart_efc[8]; /* 140 Erase fail count */
669	__u64 ext_smart_pcec; /* 148 PCIe correctable error count */
670	__u8 ext_smart_pfbu; /* 156 Percent free blocks (User) */
671	__u8 ext_smart_rsvd2[3]; /* 157 reserved */
672	__u64 ext_smart_svn; /* 160 Security Version Number */
673	__u8 ext_smart_pfbs; /* 168 Percent free blocks (System) */
674	__u8 ext_smart_rsvd3[3]; /* 169 reserved */
675	__u8 ext_smart_dcc[16]; /* 172 Deallocate Commands Completed */
676	__u64 ext_smart_tnu; /* 188 Total Namespace Utilization */
677	__u16 ext_smart_fcc; /* 196 Format NVM Commands Completed */
678	__u8 ext_smart_bbpg; /* 198 Background Back-Pressure Gauge */
679	__u8 ext_smart_rsvd4[3]; /* 199 reserved */
680	__u64 ext_smart_seec; /* 202 Soft ECC error count */
681	__u64 ext_smart_rfsc; /* 210 Refresh count */
682	__u8 ext_smart_bsnbc[8]; /* 218 Bad system nand block count */
683	__u8 ext_smart_eest[16]; /* 226 Endurance estimate */
684	__u16 ext_smart_ttc; /* 242 Thermal throttling count */
685	__u64 ext_smart_uio; /* 244 Unaligned I/O */
686	__u8 ext_smart_pmur[16]; /* 252 Physical media units read */
687	__u32 ext_smart_rtoc; /* 268 Read command timeout count */
688	__u32 ext_smart_wtoc; /* 272 Write command timeout count */
689	__u32 ext_smart_ttoc; /* 276 Trim command timeout count */
690	__u8 ext_smart_rsvd5[4]; /* 280 reserved */
691	__u64 ext_smart_plrc; /* 284 PCIe Link Retraining Count */
692	__u64 ext_smart_pscc; /* 292 Power State Change Count */
693	__u16 ext_smart_maj; /* 300 Boot SSD major version field */
694	__u16 ext_smart_min; /* 302 Boot SSD minor version field */
695	__u16 ext_smart_pt; /* 304 Boot SSD point version field */
696	__u16 ext_smart_err; /* 306 Boot SSD errata version field */
697	__u32 ext_smart_ftlus; /* 308 FTL Unit Size */
698	__u32 ext_smart_tcgos; /* 312 TCG Ownership Status */
699	__u8 ext_smart_rsvd6[178]; /* 316 reserved */
700	__u16 ext_smart_lpv; /* 494 Log page version - 0x0001 */
701	__u8 ext_smart_lpg[16]; /* 496 Log page GUID */
702	};
703
704	struct ocp_bad_nand_block_count {
705	__u64 raw : 48;
706	__u16 normalized : 16;
707	};
708
709	struct ocp_e2e_correction_count {
710	__u32 detected;
711	__u32 corrected;
712	};
713
714	struct ocp_user_data_erase_count {
715	__u32 maximum;
716	__u32 minimum;
717	};
718
719	struct ocp_thermal_status {
720	__u8 num_events;
721	__u8 current_status;
722	};
723
724	struct __packed__attribute__((__packed__)) ocp_dssd_specific_ver {
725	__u8 errata_ver;
726	__u16 point_ver;
727	__u16 minor_ver;
728	__u8 major_ver;
729	};
730
731	struct ocp_cloud_smart_log {
732	__u8 physical_media_units_written[16];
733	__u8 physical_media_units_read[16];
734	struct ocp_bad_nand_block_count bad_user_nand_blocks;
735	struct ocp_bad_nand_block_count bad_system_nand_blocks;
736	__u64 xor_recovery_count;
737	__u64 uncorrectable_read_error_count;
738	__u64 soft_ecc_error_count;
739	struct ocp_e2e_correction_count e2e_correction_counts;
740	__u8 system_data_percent_used;
741	__u64 refresh_counts : 56;
742	struct ocp_user_data_erase_count user_data_erase_counts;
743	struct ocp_thermal_status thermal_status;
744	struct ocp_dssd_specific_ver dssd_specific_ver;
745	__u64 pcie_correctable_error_count;
746	__u32 incomplete_shutdowns;
747	__u8 rsvd116[4];
748	__u8 percent_free_blocks;
749	__u8 rsvd121[7];
750	__u16 capacitor_health;
751	__u8 nvme_base_errata_ver;
752	__u8 nvme_cmd_set_errata_ver;
753	__u8 rsvd132[4];
754	__u64 unaligned_io;
755	__u64 security_version_number;
756	__u64 total_nuse;
757	__u8 plp_start_count[16];
758	__u8 endurance_estimate[16];
759	__u64 pcie_link_retraining_cnt;
760	__u64 power_state_change_cnt;
761	char lowest_permitted_fw_rev[8];
762	__u8 rsvd216[278];
763	__u16 log_page_version;
764	__u8 log_page_guid[16];
765	};
766
767	static __u8 scao_guid[WDC_C0_GUID_LENGTH16] = {
768	0xC5, 0xAF, 0x10, 0x28, 0xEA, 0xBF, 0xF2, 0xA4,
769	0x9C, 0x4F, 0x6F, 0x7C, 0xC9, 0x14, 0xD5, 0xAF
770	};
771
772	enum {
773	EOL_RBC = 76, /* Realloc Block Count */
774	EOL_ECCR = 80, /* ECC Rate */
775	EOL_WRA = 84, /* Write Amp */
776	EOL_PLR = 88, /* Percent Life Remaining */
777	EOL_RSVBC = 92, /* Reserved Block Count */
778	EOL_PFC = 96, /* Program Fail Count */
779	EOL_EFC = 100, /* Erase Fail Count */
780	EOL_RRER = 108, /* Raw Read Error Rate */
781	};
782
783	#define WDC_NVME_C6_GUID_LENGTH16 16
784	#define WDC_NVME_GET_HW_REV_LOG_OPCODE0xc6 0xc6
785	#define WDC_NVME_HW_REV_LOG_PAGE_LEN512 512
786
787	struct __packed__attribute__((__packed__)) wdc_nvme_hw_rev_log {
788	__u8 hw_rev_gdr; /* 0 Global Device HW Revision */
789	__u8 hw_rev_ar; /* 1 ASIC HW Revision */
790	__u8 hw_rev_pbc_mc; /* 2 PCB Manufacturer Code */
791	__u8 hw_rev_dram_mc; /* 3 DRAM Manufacturer Code */
792	__u8 hw_rev_nand_mc; /* 4 NAND Manufacturer Code */
793	__u8 hw_rev_pmic1_mc; /* 5 PMIC 1 Manufacturer Code */
794	__u8 hw_rev_pmic2_mc; /* 6 PMIC 2 Manufacturer Code */
795	__u8 hw_rev_c1_mc; /* 7 Other Component 1 Manf Code */
796	__u8 hw_rev_c2_mc; /* 8 Other Component 2 Manf Code */
797	__u8 hw_rev_c3_mc; /* 9 Other Component 3 Manf Code */
798	__u8 hw_rev_c4_mc; /* 10 Other Component 4 Manf Code */
799	__u8 hw_rev_c5_mc; /* 11 Other Component 5 Manf Code */
800	__u8 hw_rev_c6_mc; /* 12 Other Component 6 Manf Code */
801	__u8 hw_rev_c7_mc; /* 13 Other Component 7 Manf Code */
802	__u8 hw_rev_c8_mc; /* 14 Other Component 8 Manf Code */
803	__u8 hw_rev_c9_mc; /* 15 Other Component 9 Manf Code */
804	__u8 hw_rev_rsrvd1[48]; /* 16 Reserved 48 bytes */
805	__u8 hw_rev_dev_mdi[16]; /* 64 Device Manf Detailed Info */
806	__u8 hw_rev_asic_di[16]; /* 80 ASIC Detailed Info */
807	__u8 hw_rev_pcb_di[16]; /* 96 PCB Detailed Info */
808	__u8 hw_rev_dram_di[16]; /* 112 DRAM Detailed Info */
809	__u8 hw_rev_nand_di[16]; /* 128 NAND Detailed Info */
810	__u8 hw_rev_pmic1_di[16]; /* 144 PMIC1 Detailed Info */
811	__u8 hw_rev_pmic2_di[16]; /* 160 PMIC2 Detailed Info */
812	__u8 hw_rev_c1_di[16]; /* 176 Component 1 Detailed Info */
813	__u8 hw_rev_c2_di[16]; /* 192 Component 2 Detailed Info */
814	__u8 hw_rev_c3_di[16]; /* 208 Component 3 Detailed Info */
815	__u8 hw_rev_c4_di[16]; /* 224 Component 4 Detailed Info */
816	__u8 hw_rev_c5_di[16]; /* 240 Component 5 Detailed Info */
817	__u8 hw_rev_c6_di[16]; /* 256 Component 6 Detailed Info */
818	__u8 hw_rev_c7_di[16]; /* 272 Component 7 Detailed Info */
819	__u8 hw_rev_c8_di[16]; /* 288 Component 8 Detailed Info */
820	__u8 hw_rev_c9_di[16]; /* 304 Component 9 Detailed Info */
821	__u8 hw_rev_sn[32]; /* 320 Serial Number */
822	__u8 hw_rev_rsrvd2[142]; /* 352 Reserved 143 bytes */
823	__u16 hw_rev_version; /* 494 Log Page Version */
824	__u8 hw_rev_guid[16]; /* 496 Log Page GUID */
825	};
826
827	static __u8 hw_rev_log_guid[WDC_NVME_C6_GUID_LENGTH16] = {
828	0xAA, 0xB0, 0x05, 0xF5, 0x13, 0x5E, 0x48, 0x15,
829	0xAB, 0x89, 0x05, 0xBA, 0x8B, 0xE2, 0xBF, 0x3C
830	};
831
832	struct __packed__attribute__((__packed__)) WDC_DE_VU_FILE_META_DATA {
833	__u8 fileName[WDC_DE_FILE_NAME_SIZE32];
834	__u16 fileID;
835	__u64 fileSize;
836	};
837
838	struct WDC_DRIVE_ESSENTIALS {
839	struct __packed__attribute__((__packed__)) WDC_DE_VU_FILE_META_DATA metaData;
840	enum WDC_DRIVE_ESSENTIAL_TYPE essentialType;
841	};
842
843	struct WDC_DE_VU_LOG_DIRECTORY {
844	struct WDC_DRIVE_ESSENTIALS logEntry; / Caller to allocate memory */
845	__u32 maxNumLogEntries; /* Caller to input memory allocated */
846	__u32 numOfValidLogEntries; /* API will output this value */
847	};
848
849	struct WDC_DE_CSA_FEATURE_ID_LIST {
850	enum NVME_FEATURE_IDENTIFIERS featureId;
851	__u8 featureName[WDC_DE_GENERIC_BUFFER_SIZE80];
852	};
853
854	struct tarfile_metadata {
855	char fileName[MAX_PATH_LEN256];
856	int8_t bufferFolderPath[MAX_PATH_LEN256];
857	char bufferFolderName[MAX_PATH_LEN256];
858	char tarFileName[MAX_PATH_LEN256];
859	char tarFiles[MAX_PATH_LEN256];
860	char tarCmd[MAX_PATH_LEN256+MAX_PATH_LEN256];
861	char currDir[MAX_PATH_LEN256];
862	UtilsTimeInfo timeInfo;
863	uint8_t *timeString[MAX_PATH_LEN256];
864	};
865
866	static struct WDC_DE_CSA_FEATURE_ID_LIST deFeatureIdList[] = {
867	{0x00, "Dummy Placeholder"},
868	{FID_ARBITRATION, "Arbitration"},
869	{FID_POWER_MANAGEMENT, "PowerMgmnt"},
870	{FID_LBA_RANGE_TYPE, "LbaRangeType"},
871	{FID_TEMPERATURE_THRESHOLD, "TempThreshold"},
872	{FID_ERROR_RECOVERY, "ErrorRecovery"},
873	{FID_VOLATILE_WRITE_CACHE, "VolatileWriteCache"},
874	{FID_NUMBER_OF_QUEUES, "NumOfQueues"},
875	{FID_INTERRUPT_COALESCING, "InterruptCoalesing"},
876	{FID_INTERRUPT_VECTOR_CONFIGURATION, "InterruptVectorConfig"},
877	{FID_WRITE_ATOMICITY, "WriteAtomicity"},
878	{FID_ASYNCHRONOUS_EVENT_CONFIGURATION, "AsynEventConfig"},
879	{FID_AUTONOMOUS_POWER_STATE_TRANSITION, "AutonomousPowerState"},
880	};
881
882	enum NVME_VU_DE_LOGPAGE_NAMES {
883	NVME_DE_LOGPAGE_E3 = 0x01,
884	NVME_DE_LOGPAGE_C0 = 0x02
885	};
886
887	struct NVME_VU_DE_LOGPAGE_LIST {
888	enum NVME_VU_DE_LOGPAGE_NAMES logPageName;
889	__u32 logPageId;
890	__u32 logPageLen;
891	char logPageIdStr[5];
892	};
893
894	struct WDC_NVME_DE_VU_LOGPAGES {
895	enum NVME_VU_DE_LOGPAGE_NAMES vuLogPageReqd;
896	__u32 numOfVULogPages;
897	};
898
899	static struct NVME_VU_DE_LOGPAGE_LIST deVULogPagesList[] = {
900	{ NVME_DE_LOGPAGE_E3, 0xE3, 1072, "0xe3"},
901	{ NVME_DE_LOGPAGE_C0, 0xC0, 512, "0xc0"}
902	};
903
904	enum {
905	WDC_NVME_ADMIN_VUC_OPCODE_D2 = 0xD2,
906	WDC_VUC_SUBOPCODE_VS_DRIVE_INFO_D2 = 0x0000010A,
907	WDC_VUC_SUBOPCODE_LOG_PAGE_DIR_D2 = 0x00000105,
908	};
909
910	enum {
911	NVME_LOG_NS_BASE = 0x80,
912	NVME_LOG_VS_BASE = 0xC0,
913	};
914
915	/drive_info struct/
916	struct ocp_drive_info {
917	__u32 hw_revision;
918	__u32 ftl_unit_size;
919	};
920
921	/get log page directory struct/
922	struct log_page_directory {
923	__u64 supported_lid_bitmap;
924	__u64 rsvd;
925	__u64 supported_ns_lid_bitmap;
926	__u64 supported_vs_lid_bitmap;
927	};
928
929	/set latency monitor feature /
930	struct __packed__attribute__((__packed__)) feature_latency_monitor {
931	__u16 active_bucket_timer_threshold;
932	__u8 active_threshold_a;
933	__u8 active_threshold_b;
934	__u8 active_threshold_c;
935	__u8 active_threshold_d;
936	__u16 active_latency_config;
937	__u8 active_latency_minimum_window;
938	__u16 debug_log_trigger_enable;
939	__u8 discard_debug_log;
940	__u8 latency_monitor_feature_enable;
941	__u8 reserved[4083];
942	};
943
944	static int wdc_get_serial_name(struct libnvme_transport_handle hdl, char file, size_t len, const char *suffix);
945	static int wdc_create_log_file(const char file, const __u8 drive_log_data,
946	__u32 drive_log_length);
947	static int wdc_do_clear_dump(struct libnvme_transport_handle *hdl, __u8 opcode, __u32 cdw12);
948	static int wdc_do_dump(struct libnvme_transport_handle *hdl, __u32 opcode, __u32 data_len, __u32 cdw12,
949	const char *file, __u32 xfer_size);
950	static int wdc_do_crash_dump(struct libnvme_transport_handle hdl, char file, int type);
951	static int wdc_crash_dump(struct libnvme_transport_handle hdl, const char file, int type);
952	static int wdc_get_crash_dump(int argc, char *argv, struct command acmd,
953	struct plugin *plugin);
954	static int wdc_do_drive_log(struct libnvme_transport_handle hdl, const char file);
955	static int wdc_drive_log(int argc, char *argv, struct command acmd, struct plugin *plugin);
956	static const char *wdc_purge_mon_status_to_string(__u32 status);
957	static int wdc_purge(int argc, char *argv, struct command acmd, struct plugin *plugin);
958	static int wdc_purge_monitor(int argc, char *argv, struct command acmd, struct plugin *plugin);
959	static bool_Bool wdc_nvme_check_supported_log_page(struct libnvme_global_ctx *ctx,
960	struct libnvme_transport_handle *hdl,
961	__u8 log_id,
962	__u8 uuid_index);
963	static int wdc_clear_pcie_correctable_errors(int argc, char *argv, struct command acmd,
964	struct plugin *plugin);
965	static int wdc_do_drive_essentials(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char dir, char key);
966	static int wdc_drive_essentials(int argc, char *argv, struct command acmd,
967	struct plugin *plugin);
968	static int wdc_drive_status(int argc, char *argv, struct command acmd, struct plugin *plugin);
969	static int wdc_clear_assert_dump(int argc, char *argv, struct command acmd,
970	struct plugin *plugin);
971	static int wdc_drive_resize(int argc, char *argv, struct command acmd, struct plugin *plugin);
972	static int wdc_do_drive_resize(struct libnvme_transport_handle *hdl, uint64_t new_size);
973	static int wdc_namespace_resize(int argc, char *argv, struct command acmd,
974	struct plugin *plugin);
975	static int wdc_do_namespace_resize(struct libnvme_transport_handle *hdl, __u32 nsid, __u32 op_option);
976	static int wdc_reason_identifier(int argc, char *argv, struct command acmd,
977	struct plugin *plugin);
978	static int wdc_do_get_reason_id(struct libnvme_transport_handle hdl, const char file, int log_id);
979	static int wdc_save_reason_id(struct libnvme_transport_handle hdl, __u8 rsn_ident, int size);
980	static int wdc_clear_reason_id(struct libnvme_transport_handle *hdl);
981	static int wdc_log_page_directory(int argc, char *argv, struct command acmd,
982	struct plugin *plugin);
983	static int wdc_do_drive_info(struct libnvme_transport_handle hdl, __u32 result);
984	static int wdc_vs_drive_info(int argc, char *argv, struct command acmd, struct plugin *plugin);
985	static int wdc_vs_temperature_stats(int argc, char *argv, struct command acmd,
986	struct plugin *plugin);
987	static __u64 wdc_get_enc_drive_capabilities(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl);
988	static int wdc_enc_get_nic_log(struct libnvme_transport_handle *hdl, __u8 log_id, __u32 xfer_size, __u32 data_len,
989	FILE *out);
990	static int wdc_enc_submit_move_data(struct libnvme_transport_handle hdl, char cmd, int len, int xfer_size,
991	FILE *out, int data_id, int cdw14, int cdw15);
992	static bool_Bool get_dev_mgment_cbs_data(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, __u8 log_id,
993	void **cbs_data);
994	static __u32 wdc_get_fw_cust_id(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl);
995	static int wdc_print_c0_cloud_attr_log(void *data,
996	int fmt,
997	struct libnvme_transport_handle *hdl);
998	static int wdc_print_c0_eol_log(void *data, int fmt);
999	static void wdc_show_cloud_smart_log_normal(struct ocp_cloud_smart_log *log,
1000	struct libnvme_transport_handle *hdl);
1001	static void wdc_show_cloud_smart_log_json(struct ocp_cloud_smart_log *log);
1002	static bool_Bool get_dev_mgment_data(struct libnvme_global_ctx *ctx,
1003	struct libnvme_transport_handle *hdl,
1004	void **data);
1005	static bool_Bool wdc_nvme_parse_dev_status_log_entry(void *log_data,
1006	__u32 *ret_data,
1007	__u32 entry_id);
1008	static bool_Bool wdc_nvme_parse_dev_status_log_str(void *log_data,
1009	__u32 entry_id,
1010	char *ret_data,
1011	__u32 *ret_data_len);
1012
1013	/* Drive log data size */
1014	struct wdc_log_size {
1015	__le32 log_size;
1016	};
1017
1018	/* E6 log header */
1019	struct wdc_e6_log_hdr {
1020	__le32 eye_catcher;
1021	__u8 log_size[4];
1022	};
1023
1024	/* DUI log header */
1025	struct wdc_dui_log_section {
1026	__le16 section_type;
1027	__le16 reserved;
1028	__le32 section_size;
1029	};
1030
1031	/* DUI log header V2 */
1032	struct __packed__attribute__((__packed__)) wdc_dui_log_section_v2 {
1033	__le16 section_type;
1034	__le16 data_area_id;
1035	__le64 section_size;
1036	};
1037
1038	/* DUI log header V4 */
1039	struct wdc_dui_log_section_v4 {
1040	__le16 section_type;
1041	__u8 data_area_id;
1042	__u8 reserved;
1043	__le32 section_size_sectors;
1044	};
1045
1046	struct wdc_dui_log_hdr {
1047	__u8 telemetry_hdr[512];
1048	__le16 hdr_version;
1049	__le16 section_count;
1050	__le32 log_size;
1051	struct wdc_dui_log_section log_section[WDC_NVME_DUI_MAX_SECTION0x3A];
1052	__u8 log_data[40];
1053	};
1054
1055	struct __packed__attribute__((__packed__)) wdc_dui_log_hdr_v2 {
1056	__u8 telemetry_hdr[512];
1057	__u8 hdr_version;
1058	__u8 product_id;
1059	__le16 section_count;
1060	__le64 log_size;
1061	struct wdc_dui_log_section_v2 log_section[WDC_NVME_DUI_MAX_SECTION_V20x26];
1062	__u8 log_data[40];
1063	};
1064
1065	struct __packed__attribute__((__packed__)) wdc_dui_log_hdr_v3 {
1066	__u8 telemetry_hdr[512];
1067	__u8 hdr_version;
1068	__u8 product_id;
1069	__le16 section_count;
1070	__le64 log_size;
1071	struct wdc_dui_log_section_v2 log_section[WDC_NVME_DUI_MAX_SECTION_V30x23];
1072	__u8 securityNonce[36];
1073	__u8 log_data[40];
1074	};
1075
1076	struct __packed__attribute__((__packed__)) wdc_dui_log_hdr_v4 {
1077	__u8 telemetry_hdr[512];
1078	__u8 hdr_version;
1079	__u8 product_id;
1080	__le16 section_count;
1081	__le32 log_size_sectors;
1082	struct wdc_dui_log_section_v4 log_section[WDC_NVME_DUI_MAX_SECTION0x3A];
1083	__u8 log_data[40];
1084	};
1085
1086	/* Purge monitor response */
1087	struct wdc_nvme_purge_monitor_data {
1088	__le16 rsvd1;
1089	__le16 rsvd2;
1090	__le16 first_erase_failure_cnt;
1091	__le16 second_erase_failure_cnt;
1092	__le16 rsvd3;
1093	__le16 programm_failure_cnt;
1094	__le32 rsvd4;
1095	__le32 rsvd5;
1096	__le32 entire_progress_total;
1097	__le32 entire_progress_current;
1098	__u8 rsvd6[14];
1099	};
1100
1101	/* Additional Smart Log */
1102	struct wdc_log_page_header {
1103	uint8_t num_subpages;
1104	uint8_t reserved;
1105	__le16 total_log_size;
1106	};
1107
1108	struct wdc_log_page_subpage_header {
1109	uint8_t spcode;
1110	uint8_t pcset;
1111	__le16 subpage_length;
1112	};
1113
1114	struct wdc_ssd_perf_stats {
1115	__le64 hr_cmds; /* Host Read Commands */
1116	__le64 hr_blks; /* Host Read Blocks */
1117	__le64 hr_ch_cmds; /* Host Read Cache Hit Commands */
1118	__le64 hr_ch_blks; /* Host Read Cache Hit Blocks */
1119	__le64 hr_st_cmds; /* Host Read Stalled Commands */
1120	__le64 hw_cmds; /* Host Write Commands */
1121	__le64 hw_blks; /* Host Write Blocks */
1122	__le64 hw_os_cmds; /* Host Write Odd Start Commands */
1123	__le64 hw_oe_cmds; /* Host Write Odd End Commands */
1124	__le64 hw_st_cmds; /* Host Write Commands Stalled */
1125	__le64 nr_cmds; /* NAND Read Commands */
1126	__le64 nr_blks; /* NAND Read Blocks */
1127	__le64 nw_cmds; /* NAND Write Commands */
1128	__le64 nw_blks; /* NAND Write Blocks */
1129	__le64 nrbw; /* NAND Read Before Write */
1130	};
1131
1132	/* Additional C2 Log Page */
1133	struct wdc_c2_log_page_header {
1134	__le32 length;
1135	__le32 version;
1136	};
1137
1138	struct wdc_c2_log_subpage_header {
1139	__le32 length;
1140	__le32 entry_id;
1141	__le32 data;
1142	};
1143
1144	struct wdc_c2_cbs_data {
1145	__le32 length;
1146	__u8 data[];
1147	};
1148
1149	struct __packed__attribute__((__packed__)) wdc_bd_ca_log_format {
1150	__u8 field_id;
1151	__u8 reserved1[2];
1152	__u8 normalized_value;
1153	__u8 raw_value[8];
1154	};
1155
1156	#define WDC_LATENCY_LOG_BUCKET_READ3 3
1157	#define WDC_LATENCY_LOG_BUCKET_WRITE2 2
1158	#define WDC_LATENCY_LOG_BUCKET_TRIM1 1
1159	#define WDC_LATENCY_LOG_BUCKET_RESERVED0 0
1160
1161	#define WDC_LATENCY_LOG_MEASURED_LAT_READ2 2
1162	#define WDC_LATENCY_LOG_MEASURED_LAT_WRITE1 1
1163	#define WDC_LATENCY_LOG_MEASURED_LAT_TRIM0 0
1164
1165	struct __packed__attribute__((__packed__)) wdc_ssd_latency_monitor_log {
1166	__u8 feature_status; /* 0x00 */
1167	__u8 rsvd1; /* 0x01 */
1168	__le16 active_bucket_timer; /* 0x02 */
1169	__le16 active_bucket_timer_threshold; /* 0x04 */
1170	__u8 active_threshold_a; /* 0x06 */
1171	__u8 active_threshold_b; /* 0x07 */
1172	__u8 active_threshold_c; /* 0x08 */
1173	__u8 active_threshold_d; /* 0x09 */
1174	__le16 active_latency_config; /* 0x0A */
1175	__u8 active_latency_min_window; /* 0x0C */
1176	__u8 rsvd2[0x13]; /* 0x0D */
1177
1178	__le32 active_bucket_counter[4][4]; /* 0x20 - 0x5F */
1179	__le64 active_latency_timestamp[4][3]; /* 0x60 - 0xBF */
1180	__le16 active_measured_latency[4][3]; /* 0xC0 - 0xD7 */
1181	__le16 active_latency_stamp_units; /* 0xD8 */
1182	__u8 rsvd3[0x16]; /* 0xDA */
1183
1184	__le32 static_bucket_counter[4][4] ; /* 0xF0 - 0x12F */
1185	__le64 static_latency_timestamp[4][3]; /* 0x130 - 0x18F */
1186	__le16 static_measured_latency[4][3]; /* 0x190 - 0x1A7 */
1187	__le16 static_latency_stamp_units; /* 0x1A8 */
1188	__u8 rsvd4[10]; /* 0x1AA */
1189
1190	__u8 debug_telemetry_log_size[12]; /* 0x1B4 */
1191	__le16 debug_log_trigger_enable; /* 0x1C0 */
1192	__le16 debug_log_measured_latency; /* 0x1C2 */
1193	__le64 debug_log_latency_stamp; /* 0x1C4 */
1194	__le16 debug_log_ptr; /* 0x1CC */
1195	__le16 debug_log_counter_trigger; /* 0x1CE */
1196	__u8 debug_log_stamp_units; /* 0x1D0 */
1197	__u8 rsvd5[0x1D]; /* 0x1D1 */
1198
1199	__le16 log_page_version; /* 0x1EE */
1200	__u8 log_page_guid[0x10]; /* 0x1F0 */
1201	};
1202
1203	struct __packed__attribute__((__packed__)) wdc_ssd_ca_perf_stats {
1204	__le64 nand_bytes_wr_lo; /* 0x00 - NAND Bytes Written lo */
1205	__le64 nand_bytes_wr_hi; /* 0x08 - NAND Bytes Written hi */
1206	__le64 nand_bytes_rd_lo; /* 0x10 - NAND Bytes Read lo */
1207	__le64 nand_bytes_rd_hi; /* 0x18 - NAND Bytes Read hi */
1208	__le64 nand_bad_block; /* 0x20 - NAND Bad Block Count */
1209	__le64 uncorr_read_count; /* 0x28 - Uncorrectable Read Count */
1210	__le64 ecc_error_count; /* 0x30 - Soft ECC Error Count */
1211	__le32 ssd_detect_count; /* 0x38 - SSD End to End Detection Count */
1212	__le32 ssd_correct_count; /* 0x3C - SSD End to End Correction Count */
1213	__u8 data_percent_used; /* 0x40 - System Data Percent Used */
1214	__le32 data_erase_max; /* 0x41 - User Data Erase Counts */
1215	__le32 data_erase_min; /* 0x45 - User Data Erase Counts */
1216	__le64 refresh_count; /* 0x49 - Refresh Count */
1217	__le64 program_fail; /* 0x51 - Program Fail Count */
1218	__le64 user_erase_fail; /* 0x59 - User Data Erase Fail Count */
1219	__le64 system_erase_fail; /* 0x61 - System Area Erase Fail Count */
1220	__u8 thermal_throttle_status; /* 0x69 - Thermal Throttling Status */
1221	__u8 thermal_throttle_count; /* 0x6A - Thermal Throttling Count */
1222	__le64 pcie_corr_error; /* 0x6B - pcie Correctable Error Count */
1223	__le32 incomplete_shutdown_count; /* 0x73 - Incomplete Shutdown Count */
1224	__u8 percent_free_blocks; /* 0x77 - Percent Free Blocks */
1225	__u8 rsvd[392]; /* 0x78 - Reserved bytes 120-511 */
1226	};
1227
1228	struct __packed__attribute__((__packed__)) wdc_ssd_d0_smart_log {
1229	__le32 smart_log_page_header; /* 0x00 - Smart Log Page Header */
1230	__le32 lifetime_realloc_erase_block_count; /* 0x04 - Lifetime reallocated erase block count */
1231	__le32 lifetime_power_on_hours; /* 0x08 - Lifetime power on hours */
1232	__le32 lifetime_uecc_count; /* 0x0C - Lifetime UECC count */
1233	__le32 lifetime_wrt_amp_factor; /* 0x10 - Lifetime write amplification factor */
1234	__le32 trailing_hr_wrt_amp_factor; /* 0x14 - Trailing hour write amplification factor */
1235	__le32 reserve_erase_block_count; /* 0x18 - Reserve erase block count */
1236	__le32 lifetime_program_fail_count; /* 0x1C - Lifetime program fail count */
1237	__le32 lifetime_block_erase_fail_count; /* 0x20 - Lifetime block erase fail count */
1238	__le32 lifetime_die_failure_count; /* 0x24 - Lifetime die failure count */
1239	__le32 lifetime_link_rate_downgrade_count; /* 0x28 - Lifetime link rate downgrade count */
1240	__le32 lifetime_clean_shutdown_count; /* 0x2C - Lifetime clean shutdown count on power loss */
1241	__le32 lifetime_unclean_shutdown_count; /* 0x30 - Lifetime unclean shutdowns on power loss */
1242	__le32 current_temp; /* 0x34 - Current temperature */
1243	__le32 max_recorded_temp; /* 0x38 - Max recorded temperature */
1244	__le32 lifetime_retired_block_count; /* 0x3C - Lifetime retired block count */
1245	__le32 lifetime_read_disturb_realloc_events; /* 0x40 - Lifetime read disturb reallocation events */
1246	__le64 lifetime_nand_writes; /* 0x44 - Lifetime NAND write Lpages */
1247	__le32 capacitor_health; /* 0x4C - Capacitor health */
1248	__le64 lifetime_user_writes; /* 0x50 - Lifetime user writes */
1249	__le64 lifetime_user_reads; /* 0x58 - Lifetime user reads */
1250	__le32 lifetime_thermal_throttle_act; /* 0x60 - Lifetime thermal throttle activations */
1251	__le32 percentage_pe_cycles_remaining; /* 0x64 - Percentage of P/E cycles remaining */
1252	__u8 rsvd[408]; /* 0x68 - 408 Reserved bytes */
1253	};
1254
1255	#define WDC_OCP_C1_GUID_LENGTH16 16
1256	#define WDC_ERROR_REC_LOG_BUF_LEN512 512
1257	#define WDC_ERROR_REC_LOG_ID0xC1 0xC1
1258
1259	struct __packed__attribute__((__packed__)) wdc_ocp_c1_error_recovery_log {
1260	__le16 panic_reset_wait_time; /* 000 - Panic Reset Wait Time */
1261	__u8 panic_reset_action; /* 002 - Panic Reset Action */
1262	__u8 dev_recovery_action1; /* 003 - Device Recovery Action 1 */
1263	__le64 panic_id; /* 004 - Panic ID */
1264	__le32 dev_capabilities; /* 012 - Device Capabilities */
1265	__u8 vs_recovery_opc; /* 016 - Vendor Specific Recovery Opcode */
1266	__u8 rsvd1[3]; /* 017 - 3 Reserved Bytes */
1267	__le32 vs_cmd_cdw12; /* 020 - Vendor Specific Command CDW12 */
1268	__le32 vs_cmd_cdw13; /* 024 - Vendor Specific Command CDW13 */
1269	__u8 vs_cmd_to; /* 028 - Vendor Specific Command Timeout V2 */
1270	__u8 dev_recovery_action2; /* 029 - Device Recovery Action 2 V2 */
1271	__u8 dev_recovery_action2_to; /* 030 - Device Recovery Action 2 Timeout V2 */
1272	__u8 panic_count; /* 031 - Number of panics encountered */
1273	__le64 prev_panic_ids[4]; /* 032 - 063 Previous Panic ID's */
1274	__u8 rsvd2[430]; /* 064 - 493 Reserved Bytes */
1275	/* 430 reserved bytes aligns with the rest */
1276	/* of the data structure. The size of 463 */
1277	/* bytes mentioned in the OCP spec */
1278	/* (version 2.5) would not fit here. */
1279	__le16 log_page_version; /* 494 - Log Page Version */
1280	__u8 log_page_guid[WDC_OCP_C1_GUID_LENGTH16]; /* 496 - Log Page GUID */
1281	};
1282
1283	static __u8 wdc_ocp_c1_guid[WDC_OCP_C1_GUID_LENGTH16] = { 0x44, 0xD9, 0x31, 0x21, 0xFE, 0x30, 0x34, 0xAE,
1284	0xAB, 0x4D, 0xFD, 0x3D, 0xBA, 0x83, 0x19, 0x5A };
1285
1286	/* NAND Stats */
1287	struct __packed__attribute__((__packed__)) wdc_nand_stats {
1288	__u8 nand_write_tlc[16];
1289	__u8 nand_write_slc[16];
1290	__le32 nand_prog_failure;
1291	__le32 nand_erase_failure;
1292	__le32 bad_block_count;
1293	__le64 nand_rec_trigger_event;
1294	__le64 e2e_error_counter;
1295	__le64 successful_ns_resize_event;
1296	__u8 rsvd[442];
1297	__u16 log_page_version;
1298	};
1299
1300	struct __packed__attribute__((__packed__)) wdc_nand_stats_V3 {
1301	__u8 nand_write_tlc[16];
1302	__u8 nand_write_slc[16];
1303	__u8 bad_nand_block_count[8];
1304	__le64 xor_recovery_count;
1305	__le64 uecc_read_error_count;
1306	__u8 ssd_correction_counts[16];
1307	__u8 percent_life_used;
1308	__le64 user_data_erase_counts[4];
1309	__u8 program_fail_count[8];
1310	__u8 erase_fail_count[8];
1311	__le64 correctable_error_count;
1312	__u8 percent_free_blocks_user;
1313	__le64 security_version_number;
1314	__u8 percent_free_blocks_system;
1315	__u8 trim_completions[25];
1316	__u8 back_pressure_guage;
1317	__le64 soft_ecc_error_count;
1318	__le64 refresh_count;
1319	__u8 bad_sys_nand_block_count[8];
1320	__u8 endurance_estimate[16];
1321	__u8 thermal_throttling_st_ct[2];
1322	__le64 unaligned_IO;
1323	__u8 physical_media_units[16];
1324	__u8 reserved[279];
1325	__u16 log_page_version;
1326	};
1327
1328	struct wdc_vs_pcie_stats {
1329	__le64 unsupportedRequestErrorCount;
1330	__le64 ecrcErrorStatusCount;
1331	__le64 malformedTlpStatusCount;
1332	__le64 receiverOverflowStatusCount;
1333	__le64 unexpectedCmpltnStatusCount;
1334	__le64 completeAbortStatusCount;
1335	__le64 cmpltnTimoutStatusCount;
1336	__le64 flowControlErrorStatusCount;
1337	__le64 poisonedTlpStatusCount;
1338	__le64 dLinkPrtclErrorStatusCount;
1339	__le64 advsryNFatalErrStatusCount;
1340	__le64 replayTimerToStatusCount;
1341	__le64 replayNumRolloverStCount;
1342	__le64 badDllpStatusCount;
1343	__le64 badTlpStatusCount;
1344	__le64 receiverErrStatusCount;
1345	__u8 reserved1[384];
1346	};
1347
1348	struct wdc_fw_act_history_log_hdr {
1349	__le32 eye_catcher;
1350	__u8 version;
1351	__u8 reserved1;
1352	__u8 num_entries;
1353	__u8 reserved2;
1354	__le32 entry_size;
1355	__le32 reserved3;
1356	};
1357
1358	struct wdc_fw_act_history_log_entry {
1359	__le32 entry_num;
1360	__le32 power_cycle_count;
1361	__le64 power_on_seconds;
1362	__le64 previous_fw_version;
1363	__le64 new_fw_version;
1364	__u8 slot_number;
1365	__u8 commit_action_type;
1366	__le16 result;
1367	__u8 reserved[12];
1368	};
1369
1370	struct __packed__attribute__((__packed__)) wdc_fw_act_history_log_entry_c2 {
1371	__u8 entry_version_num;
1372	__u8 entry_len;
1373	__le16 reserved;
1374	__le16 fw_act_hist_entries;
1375	__le64 timestamp;
1376	__u8 reserved2[8];
1377	__le64 power_cycle_count;
1378	__le64 previous_fw_version;
1379	__le64 current_fw_version;
1380	__u8 slot_number;
1381	__u8 commit_action_type;
1382	__le16 result;
1383	__u8 reserved3[14];
1384	};
1385
1386	struct __packed__attribute__((__packed__)) wdc_fw_act_history_log_format_c2 {
1387	__u8 log_identifier;
1388	__u8 reserved[3];
1389	__le32 num_entries;
1390	struct wdc_fw_act_history_log_entry_c2 entry[WDC_MAX_NUM_ACT_HIST_ENTRIES20];
1391	__u8 reserved2[2790];
1392	__le16 log_page_version;
1393	__u8 log_page_guid[WDC_C2_GUID_LENGTH16];
1394	};
1395
1396	static __u8 ocp_C2_guid[WDC_C2_GUID_LENGTH16] = {
1397	0x6D, 0x79, 0x9A, 0x76, 0xB4, 0xDA, 0xF6, 0xA3,
1398	0xE2, 0x4D, 0xB2, 0x8A, 0xAC, 0xF3, 0x1C, 0xD1
1399	};
1400
1401	#define WDC_OCP_C4_GUID_LENGTH16 16
1402	#define WDC_DEV_CAP_LOG_BUF_LEN4096 4096
1403	#define WDC_DEV_CAP_LOG_ID0xC4 0xC4
1404	#define WDC_DEV_CAP_LOG_VERSION0001 0001
1405	#define WDC_OCP_C4_NUM_PS_DESCR127 127
1406
1407	struct __packed__attribute__((__packed__)) wdc_ocp_C4_dev_cap_log {
1408	__le16 num_pcie_ports; /* 0000 - Number of PCI Express Ports */
1409	__le16 oob_mgmt_support; /* 0002 - OOB Management Interfaces Supported */
1410	__le16 wrt_zeros_support; /* 0004 - Write Zeros Command Support */
1411	__le16 sanitize_support; /* 0006 - Sanitize Command Support */
1412	__le16 dsm_support; /* 0008 - Dataset Management Command Support */
1413	__le16 wrt_uncor_support; /* 0010 - Write Uncorrectable Command Support */
1414	__le16 fused_support; /* 0012 - Fused Operation Support */
1415	__le16 min_dssd_ps; /* 0014 - Minimum Valid DSSD Power State */
1416	__u8 rsvd1; /* 0016 - Reserved must be cleared to zero */
1417	__u8 dssd_ps_descr[WDC_OCP_C4_NUM_PS_DESCR127];/* 0017 - DSSD Power State Descriptors */
1418	__u8 rsvd2[3934]; /* 0144 - Reserved must be cleared to zero */
1419	__le16 log_page_version; /* 4078 - Log Page Version */
1420	__u8 log_page_guid[WDC_OCP_C4_GUID_LENGTH16]; /* 4080 - Log Page GUID */
1421	};
1422
1423	static __u8 wdc_ocp_c4_guid[WDC_OCP_C4_GUID_LENGTH16] = {
1424	0x97, 0x42, 0x05, 0x0D, 0xD1, 0xE1, 0xC9, 0x98,
1425	0x5D, 0x49, 0x58, 0x4B, 0x91, 0x3C, 0x05, 0xB7
1426	};
1427
1428	#define WDC_OCP_C5_GUID_LENGTH16 16
1429	#define WDC_UNSUPPORTED_REQS_LOG_BUF_LEN4096 4096
1430	#define WDC_UNSUPPORTED_REQS_LOG_ID0xC5 0xC5
1431	#define WDC_UNSUPPORTED_REQS_LOG_VERSION0001 0001
1432	#define WDC_NUM_UNSUPPORTED_REQ_ENTRIES253 253
1433
1434	struct __packed__attribute__((__packed__)) wdc_ocp_C5_unsupported_reqs {
1435	__le16 unsupported_count; /* 0000 - Number of Unsupported Requirement IDs */
1436	__u8 rsvd1[14]; /* 0002 - Reserved must be cleared to zero */
1437	__u8 unsupported_req_list[WDC_NUM_UNSUPPORTED_REQ_ENTRIES253][16]; /* 0016 - Unsupported Requirements List */
1438	__u8 rsvd2[14]; /* 4064 - Reserved must be cleared to zero */
1439	__le16 log_page_version; /* 4078 - Log Page Version */
1440	__u8 log_page_guid[WDC_OCP_C5_GUID_LENGTH16]; /* 4080 - Log Page GUID */
1441	};
1442
1443	static __u8 wdc_ocp_c5_guid[WDC_OCP_C5_GUID_LENGTH16] = { 0x2F, 0x72, 0x9C, 0x0E, 0x99, 0x23, 0x2C, 0xBB,
1444	0x63, 0x48, 0x32, 0xD0, 0xB7, 0x98, 0xBB, 0xC7 };
1445
1446	#define WDC_REASON_INDEX_MAX16 16
1447	#define WDC_REASON_ID_ENTRY_LEN128 128
1448	#define WDC_REASON_ID_PATH_NAME"/usr/local/nvmecli" "/usr/local/nvmecli"
1449
1450	const char *log_page_name[256] = {
1451	[NVME_LOG_LID_ERROR] = "Error Information",
1452	[NVME_LOG_LID_SMART] = "SMART / Health Information",
1453	[NVME_LOG_LID_FW_SLOT] = "Firmware Slot Information",
1454	[NVME_LOG_LID_CHANGED_NS] = "Changed Namespace List",
1455	[NVME_LOG_LID_CMD_EFFECTS] = "Command Supported and Effects",
1456	[NVME_LOG_LID_TELEMETRY_HOST] = "Telemetry Host-Initiated",
1457	[NVME_LOG_LID_TELEMETRY_CTRL] = "Telemetry Controller-Initiated",
1458	[NVME_LOG_LID_SANITIZE] = "Sanitize Status",
1459	[WDC_LOG_ID_C00xC0] = "Extended SMART Information",
1460	[WDC_LOG_ID_C20xC2] = "Firmware Activation History",
1461	[WDC_LOG_ID_C30xC3] = "Latency Monitor",
1462	[WDC_LOG_ID_C40xC4] = "Device Capabilities",
1463	[WDC_LOG_ID_C50xC5] = "Unsupported Requirements",
1464	};
1465
1466	static double safe_div_fp(double numerator, double denominator)
1467	{
1468	return denominator ? numerator / denominator : 0;
1469	}
1470
1471	static double calc_percent(uint64_t numerator, uint64_t denominator)
1472	{
1473	return denominator ?
1474	(uint64_t)(((double)numerator / (double)denominator) * 100) : 0;
1475	}
1476
1477	static int wdc_get_pci_ids(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl,
1478	uint32_t device_id, uint32_t vendor_id)
1479	{
1480	const char *name = libnvme_transport_handle_get_name(hdl);
1481	char vid[256], did[256], id[32];
1482	libnvme_ctrl_t c = NULL((void*)0);
1483	libnvme_ns_t n = NULL((void*)0);
1484	int fd, ret;
1485
1486	ret = libnvme_scan_ctrl(ctx, name, &c);
1487	if (!ret) {
1488	snprintf(vid, sizeof(vid), "%s/device/vendor",
1489	libnvme_ctrl_get_sysfs_dir(c));
1490	snprintf(did, sizeof(did), "%s/device/device",
1491	libnvme_ctrl_get_sysfs_dir(c));
1492	libnvme_free_ctrl(c);
1493	} else {
1494	ret = libnvme_scan_namespace(ctx, name, &n);
1495	if (ret) {
1496	fprintf(stderrstderr, "Unable to find %s\n", name);
1497	return ret;
1498	}
1499
1500	snprintf(vid, sizeof(vid), "%s/device/device/vendor",
1501	libnvme_ns_get_sysfs_dir(n));
1502	snprintf(did, sizeof(did), "%s/device/device/device",
1503	libnvme_ns_get_sysfs_dir(n));
1504	libnvme_free_ns(n);
1505	}
1506
1507	fd = open(vid, O_RDONLY00);
1508	if (fd < 0) {
1509	fprintf(stderrstderr, "ERROR: WDC: %s : Open vendor file failed\n", __func__);
1510	return -1;
1511	}
1512
1513	ret = read(fd, id, 32);
1514	close(fd);
1515
1516	if (ret < 0) {
1517	fprintf(stderrstderr, "%s: Read of pci vendor id failed\n", __func__);
1518	return -1;
1519	}
1520	id[ret < 32 ? ret : 31] = '\0';
1521	if (id[strlen(id) - 1] == '\n')
1522	id[strlen(id) - 1] = '\0';
1523
1524	vendor_id = strtol(id, NULL((void)0), 0);
1525	ret = 0;
1526
1527	fd = open(did, O_RDONLY00);
1528	if (fd < 0) {
1529	fprintf(stderrstderr, "ERROR: WDC: %s : Open device file failed\n", __func__);
1530	return -1;
1531	}
1532
1533	ret = read(fd, id, 32);
1534	close(fd);
1535
1536	if (ret < 0) {
1537	fprintf(stderrstderr, "%s: Read of pci device id failed\n", __func__);
1538	return -1;
1539	}
1540	id[ret < 32 ? ret : 31] = '\0';
1541	if (id[strlen(id) - 1] == '\n')
1542	id[strlen(id) - 1] = '\0';
1543
1544	device_id = strtol(id, NULL((void)0), 0);
1545	return 0;
1546	}
1547
1548	static int wdc_get_vendor_id(struct libnvme_transport_handle hdl, uint32_t vendor_id)
1549	{
1550	struct nvme_id_ctrl ctrl;
1551	int ret;
1552
1553	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
1554	ret = nvme_identify_ctrl(hdl, &ctrl);
1555	if (ret) {
1556	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed 0x%x\n", ret);
1557	return -1;
1558	}
1559
1560	*vendor_id = (uint32_t) ctrl.vid;
1561
1562	return ret;
1563	}
1564
1565	static bool_Bool wdc_is_sn861(__u32 device_id)
1566	{
1567	if ((device_id == WDC_NVME_SN861_DEV_ID0x2750) \|\|
1568	(device_id == WDC_NVME_SN861_DEV_ID_10x2751) \|\|
1569	(device_id == WDC_NVME_SN861_DEV_ID_20x2752))
1570	return true1;
1571	else
1572	return false0;
1573	}
1574
1575
1576	static bool_Bool wdc_is_sn640(__u32 device_id)
1577	{
1578	if ((device_id == WDC_NVME_SN640_DEV_ID0x2400) \|\|
1579	(device_id == WDC_NVME_SN640_DEV_ID_10x2401) \|\|
1580	(device_id == WDC_NVME_SN640_DEV_ID_20x2402))
1581	return true1;
1582	else
1583	return false0;
1584	}
1585
1586	static bool_Bool wdc_is_sn650_u2(__u32 device_id)
1587	{
1588	if (device_id == WDC_NVME_SN650_DEV_ID_30x2720)
1589	return true1;
1590	else
1591	return false0;
1592	}
1593
1594	static bool_Bool wdc_is_sn650_e1l(__u32 device_id)
1595	{
1596	if (device_id == WDC_NVME_SN650_DEV_ID_40x2721)
1597	return true1;
1598	else
1599	return false0;
1600	}
1601
1602	static bool_Bool wdc_is_zn350(__u32 device_id)
1603	{
1604	return (device_id == WDC_NVME_ZN350_DEV_ID0x5010 \|\|
1605	device_id == WDC_NVME_ZN350_DEV_ID_10x5018);
1606	}
1607	static bool_Bool needs_c2_log_page_check(__u32 device_id)
1608	{
1609	if ((wdc_is_sn640(device_id)) \|\|
1610	(wdc_is_sn650_u2(device_id)) \|\|
1611	(wdc_is_sn650_e1l(device_id)))
1612	return true1;
1613	else
1614	return false0;
1615	}
1616
1617	static bool_Bool wdc_check_power_of_2(int num)
1618	{
1619	return num && (!(num & (num-1)));
1620	}
1621
1622	static int wdc_get_model_number(struct libnvme_transport_handle hdl, char model)
1623	{
1624	struct nvme_id_ctrl ctrl;
1625	int ret, i;
1626
1627	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
1628	ret = nvme_identify_ctrl(hdl, &ctrl);
1629	if (ret) {
1630	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed 0x%x\n", ret);
1631	return -1;
1632	}
1633
1634	memcpy(model, ctrl.mn, NVME_ID_CTRL_MODEL_NUMBER_SIZE40);
1635	/* get rid of the padded spaces */
1636	i = NVME_ID_CTRL_MODEL_NUMBER_SIZE40-1;
1637	while (model[i] == ' ')
1638	i--;
1639	model[i+1] = 0;
1640
1641	return ret;
1642	}
1643
1644	static bool_Bool wdc_check_device(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl)
1645	{
1646	int ret;
1647	bool_Bool supported;
1648	uint32_t read_device_id = -1, read_vendor_id = -1;
1649
1650	ret = wdc_get_pci_ids(ctx, hdl, &read_device_id, &read_vendor_id);
1651	if (ret < 0) {
1652	/* Use the identify nvme command to get vendor id due to NVMeOF device. */
1653	if (wdc_get_vendor_id(hdl, &read_vendor_id) < 0)
1654	return false0;
1655	}
1656
1657	supported = false0;
1658
1659	if (read_vendor_id == WDC_NVME_VID0x1c58 \|\|
1660	read_vendor_id == WDC_NVME_VID_20x1b96 \|\|
1661	read_vendor_id == WDC_NVME_SNDK_VID0x15b7)
1662	supported = true1;
1663	else
1664	fprintf(stderrstderr,
1665	"ERROR: WDC: unsupported WDC device, Vendor ID = 0x%x, Device ID = 0x%x\n",
1666	read_vendor_id, read_device_id);
1667
1668	return supported;
1669	}
1670
1671	static bool_Bool wdc_enc_check_model(struct libnvme_transport_handle *hdl)
1672	{
1673	int ret;
1674	bool_Bool supported;
1675	char model[NVME_ID_CTRL_MODEL_NUMBER_SIZE40+1];
1676
1677	ret = wdc_get_model_number(hdl, model);
1678	if (ret < 0)
1679	return false0;
1680
1681	supported = false0;
1682	model[NVME_ID_CTRL_MODEL_NUMBER_SIZE40] = 0; /* forced termination */
1683	if (strstr(model, WDC_OPENFLEX_MI_DEVICE_MODEL"OpenFlex"))
1684	supported = true1;
1685	else
1686	fprintf(stderrstderr, "ERROR: WDC: unsupported WDC enclosure, Model = %s\n", model);
1687
1688	return supported;
1689	}
1690
1691	static __u64 wdc_get_drive_capabilities(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl)
1692	{
1693	int ret;
1694	uint32_t read_device_id = -1, read_vendor_id = -1;
1695	__u64 capabilities = 0;
1696	__u32 cust_id;
1697
1698	ret = wdc_get_pci_ids(ctx, hdl, &read_device_id, &read_vendor_id);
1699	if (ret < 0) {
1700	if (wdc_get_vendor_id(hdl, &read_vendor_id) < 0)
1701	return capabilities;
1702	}
1703
1704	/* below check condition is added due in NVMeOF device we dont have device_id so we need to use only vendor_id*/
1705	if (read_device_id == -1 && read_vendor_id != -1) {
1706	capabilities = wdc_get_enc_drive_capabilities(ctx, hdl);
1707	return capabilities;
1708	}
1709
1710	switch (read_vendor_id) {
1711	case WDC_NVME_VID0x1c58:
1712	switch (read_device_id) {
1713	case WDC_NVME_SN100_DEV_ID0x0003:
1714	capabilities = (WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 \| WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \| WDC_DRIVE_CAP_C1_LOG_PAGE0x0000000000000004 \|
1715	WDC_DRIVE_CAP_DRIVE_LOG0x0000000000000400 \| WDC_DRIVE_CAP_CRASH_DUMP0x0000000000000800 \| WDC_DRIVE_CAP_PFAIL_DUMP0x0000000000001000 \|
1716	WDC_DRIVE_CAP_PURGE0x0000001000000000);
1717	break;
1718
1719	case WDC_NVME_SN200_DEV_ID0x0023:
1720	capabilities = (WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 \| WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \| WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080 \|
1721	WDC_DRIVE_CAP_DRIVE_LOG0x0000000000000400 \| WDC_DRIVE_CAP_CRASH_DUMP0x0000000000000800 \| WDC_DRIVE_CAP_PFAIL_DUMP0x0000000000001000 \|
1722	WDC_DRIVE_CAP_PURGE0x0000001000000000);
1723
1724	/* verify the 0xCA log page is supported */
1725	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1726	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA, 0))
1727	capabilities \|= WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008;
1728
1729	/* verify the 0xC1 log page is supported */
1730	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1731	WDC_NVME_ADD_LOG_OPCODE0xC1, 0))
1732	capabilities \|= WDC_DRIVE_CAP_C1_LOG_PAGE0x0000000000000004;
1733	break;
1734
1735	default:
1736	capabilities = 0;
1737	}
1738	break;
1739
1740	case WDC_NVME_VID_20x1b96:
1741	switch (read_device_id) {
1742	case WDC_NVME_SN630_DEV_ID0x2200:
1743	case WDC_NVME_SN630_DEV_ID_10x2201:
1744	capabilities = (WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 \| WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \|
1745	WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 \| WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 \|
1746	WDC_DRIVE_CAP_RESIZE0x0000000000000100 \| WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080);
1747	/* verify the 0xCA log page is supported */
1748	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1749	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA, 0))
1750	capabilities \|= WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008;
1751
1752	/* verify the 0xD0 log page is supported */
1753	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1754	WDC_NVME_GET_VU_SMART_LOG_OPCODE0xD0, 0))
1755	capabilities \|= WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010;
1756	break;
1757
1758	case WDC_NVME_SN640_DEV_ID0x2400:
1759	case WDC_NVME_SN640_DEV_ID_10x2401:
1760	case WDC_NVME_SN640_DEV_ID_20x2402:
1761	case WDC_NVME_SN640_DEV_ID_30x2404:
1762	case WDC_NVME_SN560_DEV_ID_10x2712:
1763	case WDC_NVME_SN560_DEV_ID_20x2713:
1764	case WDC_NVME_SN560_DEV_ID_30x2714:
1765	case WDC_NVME_SN660_DEV_ID0x2704:
1766	/* verify the 0xC0 log page is supported */
1767	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1768	WDC_NVME_GET_SMART_CLOUD_ATTR_LOG_ID0xC0, 0)
1769	== true1) {
1770	capabilities \|= WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000;
1771	}
1772
1773	capabilities \|= (WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 \| WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \|
1774	WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 \| WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 \|
1775	WDC_DRIVE_CAP_RESIZE0x0000000000000100 \| WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY0x0000000000002000 \|
1776	WDC_DRVIE_CAP_DISABLE_CTLR_TELE_LOG0x0000000000008000 \| WDC_DRIVE_CAP_REASON_ID0x0000000000010000 \|
1777	WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000);
1778
1779	/* verify the 0xC1 (OCP Error Recovery) log page is supported */
1780	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1781	WDC_ERROR_REC_LOG_ID0xC1, 0))
1782	capabilities \|= WDC_DRIVE_CAP_OCP_C1_LOG_PAGE0x0000002000000000;
1783
1784	/* verify the 0xC3 (OCP Latency Monitor) log page is supported */
1785	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1786	WDC_LATENCY_MON_LOG_ID0xC3, 0))
1787	capabilities \|= WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000;
1788
1789	/* verify the 0xC4 (OCP Device Capabilities) log page is supported */
1790	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1791	WDC_DEV_CAP_LOG_ID0xC4, 0))
1792	capabilities \|= WDC_DRIVE_CAP_OCP_C4_LOG_PAGE0x0000004000000000;
1793
1794	/* verify the 0xC5 (OCP Unsupported Requirements) log page is supported */
1795	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1796	WDC_UNSUPPORTED_REQS_LOG_ID0xC5, 0))
1797	capabilities \|= WDC_DRIVE_CAP_OCP_C5_LOG_PAGE0x0000008000000000;
1798
1799	/* verify the 0xCA log page is supported */
1800	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1801	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA, 0))
1802	capabilities \|= WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008;
1803
1804	/* verify the 0xD0 log page is supported */
1805	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1806	WDC_NVME_GET_VU_SMART_LOG_OPCODE0xD0, 0))
1807	capabilities \|= WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010;
1808
1809	cust_id = wdc_get_fw_cust_id(ctx, hdl);
1810	/* Can still determine some capabilities in this case, but log an error */
1811	if (cust_id == WDC_INVALID_CUSTOMER_ID-1)
1812	fprintf(stderrstderr,
1813	"%s: ERROR: WDC: invalid customer ID; device ID = %x\n",
1814	__func__, read_device_id);
1815
1816	if ((cust_id == WDC_CUSTOMER_ID_0x10040x1004) \|\| (cust_id == WDC_CUSTOMER_ID_0x10080x1008) \|\|
1817	(cust_id == WDC_CUSTOMER_ID_0x10050x1005) \|\| (cust_id == WDC_CUSTOMER_ID_0x13040x1304))
1818	capabilities \|= (WDC_DRIVE_CAP_VU_FID_CLEAR_FW_ACT_HISTORY0x0000000002000000 \| WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000 \|
1819	WDC_DRIVE_CAP_INFO0x0000000000080000 \| WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000);
1820	else
1821	capabilities \|= (WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY0x0000000000004000 \| WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080);
1822
1823	break;
1824
1825	case WDC_NVME_SN840_DEV_ID0x2300:
1826	case WDC_NVME_SN840_DEV_ID_10x2500:
1827	case WDC_NVME_SN860_DEV_ID0x2730:
1828	/* verify the 0xC0 log page is supported */
1829	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1830	WDC_NVME_GET_EOL_STATUS_LOG_OPCODE0xC0, 0))
1831	capabilities \|= WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000;
1832	fallthrough__attribute__((fallthrough));
1833	case WDC_NVME_ZN540_DEV_ID0x2600:
1834	case WDC_NVME_SN540_DEV_ID0x2610:
1835	capabilities \|= (WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 \| WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \|
1836	WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 \| WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 \|
1837	WDC_DRIVE_CAP_RESIZE0x0000000000000100 \| WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080 \|
1838	WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY0x0000000000002000 \| WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY0x0000000000004000 \|
1839	WDC_DRVIE_CAP_DISABLE_CTLR_TELE_LOG0x0000000000008000 \| WDC_DRIVE_CAP_REASON_ID0x0000000000010000 \|
1840	WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000);
1841
1842	/* verify the 0xCA log page is supported */
1843	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1844	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA, 0))
1845	capabilities \|= WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008;
1846
1847	/* verify the 0xD0 log page is supported */
1848	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1849	WDC_NVME_GET_VU_SMART_LOG_OPCODE0xD0, 0))
1850	capabilities \|= WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010;
1851	break;
1852
1853	case WDC_NVME_SN650_DEV_ID0x2700:
1854	case WDC_NVME_SN650_DEV_ID_10x2701:
1855	case WDC_NVME_SN650_DEV_ID_20x2702:
1856	case WDC_NVME_SN650_DEV_ID_30x2720:
1857	case WDC_NVME_SN650_DEV_ID_40x2721:
1858	case WDC_NVME_SN655_DEV_ID0x2722:
1859	case WDC_NVME_SN655_DEV_ID_10x2723:
1860	case WDC_NVME_SN550_DEV_ID0x2708:
1861	/* verify the 0xC0 log page is supported */
1862	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1863	WDC_NVME_GET_SMART_CLOUD_ATTR_LOG_ID0xC0, 0))
1864	capabilities \|= WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000;
1865
1866	/* verify the 0xC1 (OCP Error Recovery) log page is supported */
1867	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1868	WDC_ERROR_REC_LOG_ID0xC1, 0))
1869	capabilities \|= WDC_DRIVE_CAP_OCP_C1_LOG_PAGE0x0000002000000000;
1870
1871	/* verify the 0xC3 (OCP Latency Monitor) log page is supported */
1872	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1873	WDC_LATENCY_MON_LOG_ID0xC3, 0))
1874	capabilities \|= WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000;
1875
1876	/* verify the 0xC4 (OCP Device Capabilities) log page is supported */
1877	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1878	WDC_DEV_CAP_LOG_ID0xC4, 0))
1879	capabilities \|= WDC_DRIVE_CAP_OCP_C4_LOG_PAGE0x0000004000000000;
1880
1881	/* verify the 0xC5 (OCP Unsupported Requirements) log page is supported */
1882	if (wdc_nvme_check_supported_log_page(ctx, hdl,
1883	WDC_UNSUPPORTED_REQS_LOG_ID0xC5, 0))
1884	capabilities \|= WDC_DRIVE_CAP_OCP_C5_LOG_PAGE0x0000008000000000;
1885
1886	capabilities \|= (WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 \| WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \|
1887	WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 \| WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 \|
1888	WDC_DRIVE_CAP_RESIZE0x0000000000000100 \| WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY0x0000000000002000 \|
1889	WDC_DRVIE_CAP_DISABLE_CTLR_TELE_LOG0x0000000000008000 \|
1890	WDC_DRIVE_CAP_REASON_ID0x0000000000010000 \| WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000);
1891
1892	cust_id = wdc_get_fw_cust_id(ctx, hdl);
1893	/* Can still determine some capabilities in this case, but log an error */
1894	if (cust_id == WDC_INVALID_CUSTOMER_ID-1)
1895	fprintf(stderrstderr,
1896	"%s: ERROR: WDC: invalid customer ID; device ID = %x\n",
1897	__func__, read_device_id);
1898
1899	if ((cust_id == WDC_CUSTOMER_ID_0x10040x1004) \|\|
1900	(cust_id == WDC_CUSTOMER_ID_0x10080x1008) \|\|
1901	(cust_id == WDC_CUSTOMER_ID_0x10050x1005) \|\|
1902	(cust_id == WDC_CUSTOMER_ID_0x13040x1304))
1903	capabilities \|= (WDC_DRIVE_CAP_VU_FID_CLEAR_FW_ACT_HISTORY0x0000000002000000 \|
1904	WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000 \|
1905	WDC_DRIVE_CAP_INFO0x0000000000080000 \|
1906	WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000);
1907	else
1908	capabilities \|= (WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY0x0000000000004000 \|
1909	WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080);
1910
1911	break;
1912
1913	case WDC_NVME_SN861_DEV_ID0x2750:
1914	case WDC_NVME_SN861_DEV_ID_10x2751:
1915	case WDC_NVME_SN861_DEV_ID_20x2752:
1916	capabilities \|= (WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000 \|
1917	WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000 \|
1918	WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008 \|
1919	WDC_DRIVE_CAP_OCP_C4_LOG_PAGE0x0000004000000000 \|
1920	WDC_DRIVE_CAP_OCP_C5_LOG_PAGE0x0000008000000000 \|
1921	WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \|
1922	WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_C20x0000000001000000 \|
1923	WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000 \|
1924	WDC_DRIVE_CAP_VU_FID_CLEAR_FW_ACT_HISTORY0x0000000002000000 \|
1925	WDC_DRIVE_CAP_INFO0x0000000000080000 \|
1926	WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000 \|
1927	WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000 \|
1928	WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 \|
1929	WDC_DRIVE_CAP_SET_LATENCY_MONITOR0x0000020000000000);
1930	break;
1931
1932	case WDC_NVME_SNTMP_DEV_ID0x2761:
1933	case WDC_NVME_SNTMP_DEV_ID_10x2763:
1934	capabilities \|= (WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000 \|
1935	WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000 \|
1936	WDC_DRIVE_CAP_OCP_C4_LOG_PAGE0x0000004000000000 \|
1937	WDC_DRIVE_CAP_OCP_C5_LOG_PAGE0x0000008000000000 \|
1938	WDC_DRIVE_CAP_DUI0x0000000800000000 \|
1939	WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000 \|
1940	WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 \|
1941	WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000 \|
1942	WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000 \|
1943	WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 \|
1944	WDC_DRIVE_CAP_SET_LATENCY_MONITOR0x0000020000000000);
1945	break;
1946
1947	default:
1948	capabilities = 0;
1949	}
1950	break;
1951
1952	case WDC_NVME_SNDK_VID0x15b7:
1953	switch (read_device_id) {
1954	case WDC_NVME_SNESSD1_DEV_ID_E1L0x2765:
1955	case WDC_NVME_SNESSD1_DEV_ID_E20x2766:
1956	case WDC_NVME_SNESSD1_DEV_ID_E3S0x2767:
1957	case WDC_NVME_SNESSD1_DEV_ID_E3L0x2768:
1958	case WDC_NVME_SNESSD1_DEV_ID_U20x2769:
1959	capabilities \|= (WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000 \|
1960	WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000 \|
1961	WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008 \|
1962	WDC_DRIVE_CAP_OCP_C4_LOG_PAGE0x0000004000000000 \|
1963	WDC_DRIVE_CAP_OCP_C5_LOG_PAGE0x0000008000000000 \|
1964	WDC_DRIVE_CAP_UDUI0x0000040000000000 \|
1965	WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000 \|
1966	WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 \|
1967	WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000 \|
1968	WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000 \|
1969	WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 \|
1970	WDC_DRIVE_CAP_SET_LATENCY_MONITOR0x0000020000000000);
1971	break;
1972
1973	case WDC_NVME_SXSLCL_DEV_ID0x2001:
1974	capabilities = WDC_DRIVE_CAP_DRIVE_ESSENTIALS0x0000000100000000;
1975	break;
1976
1977	case WDC_NVME_SN520_DEV_ID0x5003:
1978	case WDC_NVME_SN520_DEV_ID_10x5004:
1979	case WDC_NVME_SN520_DEV_ID_20x5005:
1980	case WDC_NVME_SN810_DEV_ID0x5011:
1981	capabilities = WDC_DRIVE_CAP_DUI_DATA0x0000000200000000;
1982	break;
1983
1984	case WDC_NVME_SN820CL_DEV_ID0x5037:
1985	capabilities = WDC_DRIVE_CAP_DUI_DATA0x0000000200000000 \|
1986	WDC_DRIVE_CAP_CLOUD_BOOT_SSD_VERSION0x0000000040000000 \|
1987	WDC_DRIVE_CAP_CLOUD_LOG_PAGE0x0000000080000000 \| WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000 \|
1988	WDC_DRIVE_CAP_HW_REV_LOG_PAGE0x0000000010000000 \| WDC_DRIVE_CAP_INFO0x0000000000080000 \|
1989	WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000 \| WDC_DRIVE_CAP_NAND_STATS0x0000000000000200 \|
1990	WDC_DRIVE_CAP_DEVICE_WAF0x0000010000000000 \| WDC_DRIVE_CAP_TEMP_STATS0x0000000000200000;
1991	break;
1992
1993	case WDC_NVME_SN720_DEV_ID0x5002:
1994	capabilities = WDC_DRIVE_CAP_DUI_DATA0x0000000200000000 \| WDC_DRIVE_CAP_NAND_STATS0x0000000000000200 \|
1995	WDC_DRIVE_CAP_NS_RESIZE0x0000000000040000;
1996	break;
1997
1998	case WDC_NVME_SN730_DEV_ID0x5006:
1999	capabilities = WDC_DRIVE_CAP_DUI0x0000000800000000 \| WDC_DRIVE_CAP_NAND_STATS0x0000000000000200 \|
2000	WDC_DRIVE_CAP_INFO0x0000000000080000 \| WDC_DRIVE_CAP_TEMP_STATS0x0000000000200000 \|
2001	WDC_DRIVE_CAP_VUC_CLEAR_PCIE0x0000000000400000 \| WDC_DRIVE_CAP_PCIE_STATS0x0000000008000000;
2002	break;
2003
2004	case WDC_NVME_SN530_DEV_ID_10x5007:
2005	fallthrough__attribute__((fallthrough));
2006	case WDC_NVME_SN530_DEV_ID_20x5008:
2007	fallthrough__attribute__((fallthrough));
2008	case WDC_NVME_SN530_DEV_ID_30x5009:
2009	fallthrough__attribute__((fallthrough));
2010	case WDC_NVME_SN530_DEV_ID_40x500b:
2011	fallthrough__attribute__((fallthrough));
2012	case WDC_NVME_SN530_DEV_ID_50x501d:
2013	fallthrough__attribute__((fallthrough));
2014	case WDC_NVME_SN350_DEV_ID0x5019:
2015	fallthrough__attribute__((fallthrough));
2016	case WDC_NVME_SN570_DEV_ID0x501A:
2017	fallthrough__attribute__((fallthrough));
2018	case WDC_NVME_SN850X_DEV_ID0x5030:
2019	fallthrough__attribute__((fallthrough));
2020	case WDC_NVME_SN5000_DEV_ID_10x5034:
2021	fallthrough__attribute__((fallthrough));
2022	case WDC_NVME_SN5000_DEV_ID_20x5035:
2023	fallthrough__attribute__((fallthrough));
2024	case WDC_NVME_SN5000_DEV_ID_30x5036:
2025	fallthrough__attribute__((fallthrough));
2026	case WDC_NVME_SN5000_DEV_ID_40x504A:
2027	fallthrough__attribute__((fallthrough));
2028	case WDC_NVME_SN7000S_DEV_ID_10x5039:
2029	fallthrough__attribute__((fallthrough));
2030	case WDC_NVME_SN7150_DEV_ID_10x503b:
2031	fallthrough__attribute__((fallthrough));
2032	case WDC_NVME_SN7150_DEV_ID_20x503c:
2033	fallthrough__attribute__((fallthrough));
2034	case WDC_NVME_SN7150_DEV_ID_30x503d:
2035	fallthrough__attribute__((fallthrough));
2036	case WDC_NVME_SN7150_DEV_ID_40x503e:
2037	fallthrough__attribute__((fallthrough));
2038	case WDC_NVME_SN7150_DEV_ID_50x503f:
2039	fallthrough__attribute__((fallthrough));
2040	case WDC_NVME_SN7100_DEV_ID_10x5043:
2041	fallthrough__attribute__((fallthrough));
2042	case WDC_NVME_SN7100_DEV_ID_20x5044:
2043	fallthrough__attribute__((fallthrough));
2044	case WDC_NVME_SN7100_DEV_ID_30x5045:
2045	fallthrough__attribute__((fallthrough));
2046	case WDC_NVME_SN8000S_DEV_ID0x5049:
2047	fallthrough__attribute__((fallthrough));
2048	case WDC_NVME_SN5100S_DEV_ID_10x5061:
2049	fallthrough__attribute__((fallthrough));
2050	case WDC_NVME_SN5100S_DEV_ID_20x5062:
2051	fallthrough__attribute__((fallthrough));
2052	case WDC_NVME_SN5100S_DEV_ID_30x5063:
2053	fallthrough__attribute__((fallthrough));
2054	case WDC_NVME_SN740_DEV_ID0x5015:
2055	case WDC_NVME_SN740_DEV_ID_10x5016:
2056	case WDC_NVME_SN740_DEV_ID_20x5017:
2057	case WDC_NVME_SN740_DEV_ID_30x5025:
2058	case WDC_NVME_SN340_DEV_ID0x500d:
2059	capabilities = WDC_DRIVE_CAP_DUI0x0000000800000000;
2060	break;
2061
2062	case WDC_NVME_ZN350_DEV_ID0x5010:
2063	case WDC_NVME_ZN350_DEV_ID_10x5018:
2064	capabilities = WDC_DRIVE_CAP_DUI_DATA0x0000000200000000 \| WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000 \|
2065	WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000 \|
2066	WDC_DRIVE_CAP_VU_FID_CLEAR_FW_ACT_HISTORY0x0000000002000000 \|
2067	WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_C20x0000000001000000 \| WDC_DRIVE_CAP_INFO0x0000000000080000 \|
2068	WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000 \| WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000;
2069	break;
2070
2071	default:
2072	capabilities = 0;
2073	}
2074	break;
2075	default:
2076	capabilities = 0;
2077	}
2078
2079	return capabilities;
2080	}
2081
2082	static __u64 wdc_get_enc_drive_capabilities(struct libnvme_global_ctx *ctx,
2083	struct libnvme_transport_handle *hdl)
2084	{
2085	int ret;
2086	uint32_t read_vendor_id;
2087	__u64 capabilities = 0;
2088	__u32 cust_id, market_name_len;
2089	char marketing_name[64];
2090	void dev_mng_log = NULL((void)0);
2091	int uuid_index = 0;
2092	struct nvme_id_uuid_list uuid_list;
2093
2094	memset(marketing_name, 0, 64);
2095
2096	ret = wdc_get_vendor_id(hdl, &read_vendor_id);
2097	if (ret < 0)
2098	return capabilities;
2099
2100	switch (read_vendor_id) {
2101	case WDC_NVME_VID0x1c58:
2102	capabilities = (WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 \| WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \| WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080 \|
2103	WDC_DRIVE_CAP_DRIVE_LOG0x0000000000000400 \| WDC_DRIVE_CAP_CRASH_DUMP0x0000000000000800 \| WDC_DRIVE_CAP_PFAIL_DUMP0x0000000000001000);
2104
2105	/* verify the 0xCA log page is supported */
2106	if (wdc_nvme_check_supported_log_page(ctx, hdl,
2107	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA, 0) == true1)
2108	capabilities \|= WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008;
2109
2110	/* verify the 0xC1 log page is supported */
2111	if (wdc_nvme_check_supported_log_page(ctx, hdl,
2112	WDC_NVME_ADD_LOG_OPCODE0xC1, 0) == true1)
2113	capabilities \|= WDC_DRIVE_CAP_C1_LOG_PAGE0x0000000000000004;
2114	break;
2115	case WDC_NVME_VID_20x1b96:
2116	capabilities = (WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 \| WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002 \|
2117	WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 \| WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 \|
2118	WDC_DRIVE_CAP_RESIZE0x0000000000000100);
2119
2120	/* Find the WDC UUID index */
2121	memset(&uuid_list, 0, sizeof(struct nvme_id_uuid_list));
2122	if (wdc_CheckUuidListSupport(hdl, &uuid_list)) {
2123	/* check for the Sandisk UUID first */
2124	uuid_index = libnvme_find_uuid(&uuid_list, SNDK_UUID);
2125
2126	if (uuid_index < 0)
2127	/* The Sandisk UUID is not found;
2128	* check for the WDC UUID second.
2129	*/
2130	uuid_index = libnvme_find_uuid(&uuid_list, WDC_UUID);
2131	}
2132
2133	/* WD UUID not found, use default uuid index - 0 */
2134	if (uuid_index < 0)
2135	uuid_index = 0;
2136
2137	/* verify the 0xC2 Device Manageability log page is supported */
2138	if (wdc_nvme_check_supported_log_page(ctx, hdl,
2139	WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2,
2140	uuid_index) == false0) {
2141	fprintf(stderrstderr, "ERROR: SNDK: 0xC2 Log Page not supported, index: %d\n",
2142	uuid_index);
2143	ret = -1;
2144	goto out;
2145	}
2146
2147	if (!get_dev_mgment_data(ctx, hdl, &dev_mng_log)) {
2148	fprintf(stderrstderr, "ERROR: SNDK: 0xC2 Log Page not found\n");
2149	ret = -1;
2150	goto out;
2151	}
2152
2153	/* Get the customer ID and marketing name from WD C2 log page */
2154	if (!wdc_nvme_parse_dev_status_log_entry(dev_mng_log,
2155	&cust_id,
2156	WDC_C2_CUSTOMER_ID_ID0x15))
2157	fprintf(stderrstderr, "ERROR: SNDK: Get Customer FW ID Failed\n");
2158
2159	if (!wdc_nvme_parse_dev_status_log_str(dev_mng_log,
2160	WDC_C2_MARKETING_NAME_ID0x07,
2161	(char *)marketing_name,
2162	&market_name_len))
2163	fprintf(stderrstderr, "ERROR: SNDK: Get Marketing Name Failed\n");
2164
2165	/* verify the 0xC3 log page is supported */
2166	if (wdc_nvme_check_supported_log_page(ctx, hdl,
2167	WDC_LATENCY_MON_LOG_ID0xC3, 0) == true1)
2168	capabilities \|= WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000;
2169
2170	/* verify the 0xCA log page is supported */
2171	if (wdc_nvme_check_supported_log_page(ctx, hdl,
2172	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA, 0) == true1)
2173	capabilities \|= WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008;
2174
2175	/* verify the 0xD0 log page is supported */
2176	if (wdc_nvme_check_supported_log_page(ctx, hdl,
2177	WDC_NVME_GET_VU_SMART_LOG_OPCODE0xD0, 0) == true1)
2178	capabilities \|= WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010;
2179
2180	if ((cust_id == WDC_CUSTOMER_ID_0x10040x1004) \|\|
2181	(cust_id == WDC_CUSTOMER_ID_0x10080x1008) \|\|
2182	(cust_id == WDC_CUSTOMER_ID_0x10050x1005) \|\|
2183	(cust_id == WDC_CUSTOMER_ID_0x13040x1304) \|\|
2184	(!strncmp(marketing_name, WDC_SN861_MARKETING_NAME_1"Ultrastar DC SN861", market_name_len)) \|\|
2185	(!strncmp(marketing_name, WDC_SN861_MARKETING_NAME_2"ULTRASTAR DC SN861", market_name_len)))
2186	/* Set capabilities for OCP compliant drives */
2187	capabilities \|= (WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_C20x0000000001000000 \|
2188	WDC_DRIVE_CAP_VU_FID_CLEAR_FW_ACT_HISTORY0x0000000002000000 \|
2189	WDC_DRIVE_CAP_VU_FID_CLEAR_PCIE0x0000000000800000);
2190	else {
2191	capabilities \|= (WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY0x0000000000004000 \|
2192	WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080);
2193
2194	/* if the 0xCB log page is supported */
2195	if (wdc_nvme_check_supported_log_page(ctx, hdl,
2196	WDC_NVME_GET_FW_ACT_HISTORY_LOG_ID0xCB, 0) == true1)
2197	capabilities \|= WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY0x0000000000002000;
2198	}
2199
2200	break;
2201	case WDC_NVME_SNDK_VID0x15b7:
2202	capabilities = WDC_DRIVE_CAP_DRIVE_ESSENTIALS0x0000000100000000;
2203	break;
2204	default:
2205	capabilities = 0;
2206	}
2207
2208	out:
2209	return capabilities;
2210	}
2211
2212	static int wdc_get_serial_name(struct libnvme_transport_handle hdl, char file, size_t len,
2213	const char *suffix)
2214	{
2215	int i;
2216	int ret;
2217	int res_len = 0;
2218	char orig[PATH_MAX4096] = {0};
2219	struct nvme_id_ctrl ctrl;
2220	int ctrl_sn_len = sizeof(ctrl.sn);
2221
2222	i = sizeof(ctrl.sn) - 1;
2223	strncpy(orig, file, PATH_MAX4096 - 1);
2224	memset(file, 0, len);
2225	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
2226	ret = nvme_identify_ctrl(hdl, &ctrl);
2227	if (ret) {
2228	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed 0x%x\n", ret);
2229	return -1;
2230	}
2231	/* Remove trailing spaces from the name */
2232	while (i && ctrl.sn[i] == ' ') {
2233	ctrl.sn[i] = '\0';
2234	i--;
2235	}
2236	if (ctrl.sn[sizeof(ctrl.sn) - 1] == '\0')
2237	ctrl_sn_len = strlen(ctrl.sn);
2238
2239	res_len = snprintf(file, len, "%s%.*s%s", orig, ctrl_sn_len, ctrl.sn, suffix);
2240	if (len <= res_len) {
2241	fprintf(stderrstderr,
2242	"ERROR: WDC: cannot format serial number due to data of unexpected length\n");
2243	return -1;
2244	}
2245
2246	return 0;
2247	}
2248
2249	static int wdc_create_log_file(const char file, const __u8 drive_log_data,
2250	__u32 drive_log_length)
2251	{
2252	int fd;
2253	int ret;
2254
2255	if (!drive_log_length) {
2256	fprintf(stderrstderr, "ERROR: WDC: invalid log file length\n");
2257	return -1;
2258	}
2259
2260	fd = nvme_open_rawdata(file, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((file), (01 \| 0100 \| 01000), 0666);
2261	if (fd < 0) {
2262	fprintf(stderrstderr, "ERROR: WDC: open: %s\n", libnvme_strerror(errno(*__errno_location ())));
2263	return -1;
2264	}
2265
2266	while (drive_log_length > WRITE_SIZE(sizeof(__u8) * 4096)) {
2267	ret = write(fd, drive_log_data, WRITE_SIZE(sizeof(__u8) * 4096));
2268	if (ret < 0) {
2269	fprintf(stderrstderr, "ERROR: WDC: write: %s\n", libnvme_strerror(errno(*__errno_location ())));
2270	close(fd);
2271	return -1;
2272	}
2273	drive_log_data += WRITE_SIZE(sizeof(__u8) * 4096);
2274	drive_log_length -= WRITE_SIZE(sizeof(__u8) * 4096);
2275	}
2276
2277	ret = write(fd, drive_log_data, drive_log_length);
2278	if (ret < 0) {
2279	fprintf(stderrstderr, "ERROR: WDC: write: %s\n", libnvme_strerror(errno(*__errno_location ())));
2280	close(fd);
2281	return -1;
2282	}
2283
2284	if (fsync(fd) < 0) {
2285	fprintf(stderrstderr, "ERROR: WDC: fsync: %s\n", libnvme_strerror(errno(*__errno_location ())));
2286	close(fd);
2287	return -1;
2288	}
2289	close(fd);
2290	return 0;
2291	}
2292
2293	bool_Bool wdc_validate_dev_mng_log(void *data)
2294	{
2295	__u32 remaining_len = 0;
2296	__u32 log_length = 0;
2297	__u32 log_entry_size = 0;
2298	__u32 log_entry_id = 0;
2299	__u32 offset = 0;
2300	bool_Bool valid_log = false0;
2301	struct wdc_c2_log_subpage_header p_next_log_entry = NULL((void)0);
2302	struct wdc_c2_log_page_header hdr_ptr = (struct wdc_c2_log_page_header )data;
2303
2304	log_length = le32_to_cpu(hdr_ptr->length);
2305	/* Ensure log data is large enough for common header */
2306	if (log_length < sizeof(struct wdc_c2_log_page_header)) {
2307	fprintf(stderrstderr,
2308	"ERROR: %s: log smaller than header. log_len: 0x%x HdrSize: %"PRIxPTR"l" "x""\n",
2309	__func__, log_length, sizeof(struct wdc_c2_log_page_header));
2310	return valid_log;
2311	}
2312
2313	/* Get pointer to first log Entry */
2314	offset = sizeof(struct wdc_c2_log_page_header);
2315	p_next_log_entry = (struct wdc_c2_log_subpage_header )(((__u8 )data) + offset);
2316	remaining_len = log_length - offset;
2317
2318	/* Proceed only if there is at least enough data to read an entry header */
2319	while (remaining_len >= sizeof(struct wdc_c2_log_subpage_header)) {
2320	/* Get size of the next entry */
2321	log_entry_size = le32_to_cpu(p_next_log_entry->length);
2322	log_entry_id = le32_to_cpu(p_next_log_entry->entry_id);
2323	/*
2324	* If log entry size is 0 or the log entry goes past the end
2325	* of the data, we must be at the end of the data
2326	*/
2327	if (!log_entry_size \|\| log_entry_size > remaining_len) {
2328	fprintf(stderrstderr, "ERROR: WDC: %s: Detected unaligned end of the data. ",
2329	__func__);
2330	fprintf(stderrstderr, "Data Offset: 0x%x Entry Size: 0x%x, ",
2331	offset, log_entry_size);
2332	fprintf(stderrstderr, "Remaining Log Length: 0x%x Entry Id: 0x%x\n",
2333	remaining_len, log_entry_id);
2334
2335	/* Force the loop to end */
2336	remaining_len = 0;
2337	} else if (!log_entry_id \|\| log_entry_id > 200) {
2338	/* Invalid entry - fail the search */
2339	fprintf(stderrstderr, "ERROR: WDC: %s: Invalid entry found at offset: 0x%x ",
2340	__func__, offset);
2341	fprintf(stderrstderr, "Entry Size: 0x%x, Remaining Log Length: 0x%x ",
2342	log_entry_size, remaining_len);
2343	fprintf(stderrstderr, "Entry Id: 0x%x\n", log_entry_id);
2344
2345	/* Force the loop to end */
2346	remaining_len = 0;
2347	valid_log = false0;
2348	} else {
2349	/* A valid log has at least one entry and no invalid entries */
2350	valid_log = true1;
2351	remaining_len -= log_entry_size;
2352	if (remaining_len > 0) {
2353	/* Increment the offset counter */
2354	offset += log_entry_size;
2355	/* Get the next entry */
2356	p_next_log_entry =
2357	(struct wdc_c2_log_subpage_header )(((__u8 )data) + offset);
2358	}
2359	}
2360	}
2361
2362	return valid_log;
2363	}
2364
2365	bool_Bool wdc_parse_dev_mng_log_entry(void *data, __u32 entry_id,
2366	struct wdc_c2_log_subpage_header **log_entry)
2367	{
2368	__u32 remaining_len = 0;
2369	__u32 log_length = 0;
2370	__u32 log_entry_size = 0;
2371	__u32 log_entry_id = 0;
2372	__u32 offset = 0;
2373	bool_Bool found = false0;
2374	struct wdc_c2_log_subpage_header p_next_log_entry = NULL((void)0);
2375	struct wdc_c2_log_page_header hdr_ptr = (struct wdc_c2_log_page_header )data;
2376
2377	log_length = le32_to_cpu(hdr_ptr->length);
2378	/* Ensure log data is large enough for common header */
2379	if (log_length < sizeof(struct wdc_c2_log_page_header)) {
2380	fprintf(stderrstderr,
2381	"ERROR: %s: log smaller than header. log_len: 0x%x HdrSize: %"PRIxPTR"l" "x""\n",
2382	__func__, log_length, sizeof(struct wdc_c2_log_page_header));
2383	return found;
2384	}
2385
2386	/* Get pointer to first log Entry */
2387	offset = sizeof(struct wdc_c2_log_page_header);
2388	p_next_log_entry = (struct wdc_c2_log_subpage_header )(((__u8 )data) + offset);
2389	remaining_len = log_length - offset;
2390
2391	if (!log_entry) {
2392	fprintf(stderrstderr, "ERROR: WDC - %s: No log entry pointer.\n", __func__);
2393	return found;
2394	}
2395	log_entry = NULL((void)0);
2396
2397	/* Proceed only if there is at least enough data to read an entry header */
2398	while (remaining_len >= sizeof(struct wdc_c2_log_subpage_header)) {
2399	/* Get size of the next entry */
2400	log_entry_size = le32_to_cpu(p_next_log_entry->length);
2401	log_entry_id = le32_to_cpu(p_next_log_entry->entry_id);
2402
2403	/*
2404	* If log entry size is 0 or the log entry goes past the end
2405	* of the data, we must be at the end of the data
2406	*/
2407	if (!log_entry_size \|\| log_entry_size > remaining_len) {
2408	fprintf(stderrstderr, "ERROR: WDC: %s: Detected unaligned end of the data. ",
2409	__func__);
2410	fprintf(stderrstderr, "Data Offset: 0x%x Entry Size: 0x%x, ",
2411	offset, log_entry_size);
2412	fprintf(stderrstderr, "Remaining Log Length: 0x%x Entry Id: 0x%x\n",
2413	remaining_len, log_entry_id);
2414
2415	/* Force the loop to end */
2416	remaining_len = 0;
2417	} else if (!log_entry_id \|\| log_entry_id > 200) {
2418	/* Invalid entry - fail the search */
2419	fprintf(stderrstderr, "ERROR: WDC: %s: Invalid entry found at offset: 0x%x ",
2420	__func__, offset);
2421	fprintf(stderrstderr, "Entry Size: 0x%x, Remaining Log Length: 0x%x ",
2422	log_entry_size, remaining_len);
2423	fprintf(stderrstderr, "Entry Id: 0x%x\n", log_entry_id);
2424
2425	/* Force the loop to end */
2426	remaining_len = 0;
2427	} else {
2428	if (log_entry_id == entry_id) {
2429	found = true1;
2430	*log_entry = p_next_log_entry;
2431	remaining_len = 0;
2432	} else {
2433	remaining_len -= log_entry_size;
2434	}
2435
2436	if (remaining_len > 0) {
2437	/* Increment the offset counter */
2438	offset += log_entry_size;
2439
2440	/* Get the next entry */
2441	p_next_log_entry =
2442	(struct wdc_c2_log_subpage_header )(((__u8 )data) + offset);
2443	}
2444	}
2445	}
2446
2447	return found;
2448	}
2449
2450	bool_Bool wdc_get_dev_mng_log_entry(__u32 log_length, __u32 entry_id,
2451	struct wdc_c2_log_page_header *p_log_hdr,
2452	struct wdc_c2_log_subpage_header **p_p_found_log_entry)
2453	{
2454	__u32 remaining_len = 0;
2455	__u32 log_entry_hdr_size = sizeof(struct wdc_c2_log_subpage_header) - 1;
2456	__u32 log_entry_size = 0;
2457	__u32 log_entry_id = 0;
2458	__u32 size = 0;
2459	bool_Bool valid_log;
2460	__u32 offset = 0;
2461	struct wdc_c2_log_subpage_header p_next_log_entry = NULL((void)0);
2462
2463	if (!*p_p_found_log_entry) {
2464	fprintf(stderrstderr, "ERROR: WDC - %s: No ppLogEntry pointer.\n", __func__);
2465	return false0;
2466	}
2467
2468	p_p_found_log_entry = NULL((void)0);
2469
2470	/* Ensure log data is large enough for common header */
2471	if (log_length < sizeof(struct wdc_c2_log_page_header)) {
2472	fprintf(stderrstderr,
2473	"ERROR: WDC - %s: Buffer is not large enough for the common header. BufSize: 0x%x HdrSize: %"PRIxPTR"l" "x""\n",
2474	__func__, log_length, sizeof(struct wdc_c2_log_page_header));
2475	return false0;
2476	}
2477
2478	/* Get pointer to first log Entry */
2479	size = sizeof(struct wdc_c2_log_page_header);
2480	offset = size;
2481	p_next_log_entry = (struct wdc_c2_log_subpage_header )(((__u8 )p_log_hdr) + offset);
2482	remaining_len = log_length - size;
2483	valid_log = false0;
2484
2485	/*
2486	* Walk the entire structure. Perform a sanity check to make sure this is a
2487	* standard version of the structure. This means making sure each entry looks
2488	* valid. But allow for the data to overflow the allocated
2489	* buffer (we don't want a false negative because of a FW formatting error)
2490	*/
2491
2492	/* Proceed only if there is at least enough data to read an entry header */
2493	while (remaining_len >= log_entry_hdr_size) {
2494	/* Get size of the next entry */
2495	log_entry_size = le32_to_cpu(p_next_log_entry->length);
2496	log_entry_id = le32_to_cpu(p_next_log_entry->entry_id);
2497
2498	/*
2499	* If log entry size is 0 or the log entry goes past the end
2500	* of the data, we must be at the end of the data
2501	*/
2502	if (!log_entry_size \|\| log_entry_size > remaining_len) {
2503	fprintf(stderrstderr, "ERROR: WDC: %s: Detected unaligned end of the data. ",
2504	__func__);
2505	fprintf(stderrstderr, "Data Offset: 0x%x Entry Size: 0x%x, ",
2506	offset, log_entry_size);
2507	fprintf(stderrstderr, "Remaining Log Length: 0x%x Entry Id: 0x%x\n",
2508	remaining_len, log_entry_id);
2509
2510	/* Force the loop to end */
2511	remaining_len = 0;
2512	} else if (!log_entry_id \|\| log_entry_id > 200) {
2513	/* Invalid entry - fail the search */
2514	fprintf(stderrstderr, "ERROR: WDC: %s: Invalid entry found at offset: 0x%x ",
2515	__func__, offset);
2516	fprintf(stderrstderr, "Entry Size: 0x%x, Remaining Log Length: 0x%x ",
2517	log_entry_size, remaining_len);
2518	fprintf(stderrstderr, "Entry Id: 0x%x\n", log_entry_id);
2519
2520	/* Force the loop to end */
2521	remaining_len = 0;
2522	valid_log = false0;
2523
2524	/* The structure is invalid, so any match that was found is invalid. */
2525	p_p_found_log_entry = NULL((void)0);
2526	} else {
2527	/* Structure must have at least one valid entry to be considered valid */
2528	valid_log = true1;
2529	if (log_entry_id == entry_id)
2530	/* A potential match. */
2531	*p_p_found_log_entry = p_next_log_entry;
2532
2533	remaining_len -= log_entry_size;
2534
2535	if (remaining_len > 0) {
2536	/* Increment the offset counter */
2537	offset += log_entry_size;
2538
2539	/* Get the next entry */
2540	p_next_log_entry =
2541	(struct wdc_c2_log_subpage_header )(((__u8 )p_log_hdr) + offset);
2542	}
2543	}
2544	}
2545
2546	return valid_log;
2547	}
2548
2549	static bool_Bool get_dev_mgmt_log_page_data(struct libnvme_transport_handle hdl, void *log_data,
2550	__u8 uuid_ix)
2551	{
2552	struct wdc_c2_log_page_header *hdr_ptr;
2553	struct libnvme_passthru_cmd cmd;
2554	bool_Bool valid = false0;
2555	__u32 length = 0;
2556	void *data;
2557	int ret = 0;
2558
2559	data = (__u8 )malloc(sizeof(__u8) WDC_C2_LOG_BUF_LEN0x1000);
2560	if (!data) {
2561	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
2562	return false0;
2563	}
2564
2565	memset(data, 0, sizeof(__u8) * WDC_C2_LOG_BUF_LEN0x1000);
2566
2567	/* get the log page length */
2568	nvme_init_get_log(&cmd, NVME_NSID_ALL,
2569	WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2, NVME_CSI_NVM, data,
2570	WDC_C2_LOG_BUF_LEN0x1000);
2571	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_ix,(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2572	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2573	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
2574	ret = libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
2575	if (ret) {
2576	fprintf(stderrstderr,
2577	"ERROR: WDC: Unable to get 0x%x Log Page with uuid %d, ret = 0x%x\n",
2578	WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2, uuid_ix, ret);
2579	goto end;
2580	}
2581
2582	hdr_ptr = (struct wdc_c2_log_page_header *)data;
2583	length = le32_to_cpu(hdr_ptr->length);
2584
2585	if (length > WDC_C2_LOG_BUF_LEN0x1000) {
2586	/* Log page buffer too small for actual data */
2587	free(data);
2588	data = calloc(length, sizeof(__u8));
2589	if (!data) {
2590	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
2591	goto end;
2592	}
2593
2594	/* get the log page data with the increased length */
2595	nvme_init_get_log(&cmd, NVME_NSID_ALL,
2596	WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2, NVME_CSI_NVM, data,
2597	length);
2598	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_ix,(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2599	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2600	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
2601	ret = libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
2602	if (ret) {
2603	fprintf(stderrstderr,
2604	"ERROR: WDC: Unable to read 0x%x Log with uuid %d, ret = 0x%x\n",
2605	WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2, uuid_ix, ret);
2606	goto end;
2607	}
2608	}
2609
2610	valid = wdc_validate_dev_mng_log(data);
2611	if (valid) {
2612	/* Ensure size of log data matches length in log header */
2613	*log_data = calloc(length, sizeof(__u8));
2614	if (!*log_data) {
2615	fprintf(stderrstderr, "ERROR: WDC: calloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
2616	valid = false0;
2617	goto end;
2618	}
2619	memcpy((void )log_data, data, length);
2620	} else {
2621	fprintf(stderrstderr, "ERROR: WDC: C2 log page not found with uuid index %d\n",
2622	uuid_ix);
2623	}
2624
2625	end:
2626	free(data);
2627	return valid;
2628	}
2629
2630	static bool_Bool get_dev_mgmt_log_page_lid_data(struct libnvme_transport_handle *hdl,
2631	void **cbs_data,
2632	__u8 lid,
2633	__u8 log_id,
2634	__u8 uuid_ix)
2635	{
2636	void *data;
2637	struct wdc_c2_log_page_header *hdr_ptr;
2638	struct wdc_c2_log_subpage_header *sph;
2639	struct libnvme_passthru_cmd cmd;
2640	__u32 length = 0;
2641	int ret = 0;
2642	bool_Bool found = false0;
2643
2644	data = (__u8 )malloc(sizeof(__u8) WDC_C2_LOG_BUF_LEN0x1000);
2645	if (!data) {
2646	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
2647	return false0;
2648	}
2649
2650	memset(data, 0, sizeof(__u8) * WDC_C2_LOG_BUF_LEN0x1000);
2651
2652	/* get the log page length */
2653	nvme_init_get_log(&cmd, NVME_NSID_ALL, lid, NVME_CSI_NVM, data,
2654	WDC_C2_LOG_BUF_LEN0x1000);
2655	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_ix,(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2656	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2657	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
2658	ret = libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
2659	if (ret) {
2660	fprintf(stderrstderr,
2661	"ERROR: WDC: Unable to get 0x%x Log Page length with uuid %d, ret = 0x%x\n",
2662	lid, uuid_ix, ret);
2663	goto end;
2664	}
2665
2666	hdr_ptr = (struct wdc_c2_log_page_header *)data;
2667	length = le32_to_cpu(hdr_ptr->length);
2668
2669	if (length > WDC_C2_LOG_BUF_LEN0x1000) {
2670	/* Log Page buffer too small, free and reallocate the necessary size */
2671	free(data);
2672	data = calloc(length, sizeof(__u8));
2673	if (!data) {
2674	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
2675	goto end;
2676	}
2677
2678	/* get the log page data with the increased length */
2679	nvme_init_get_log(&cmd, NVME_NSID_ALL, lid, NVME_CSI_NVM, data,
2680	length);
2681	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_ix,(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2682	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2683	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_ix) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
2684	ret = libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
2685	if (ret) {
2686	fprintf(stderrstderr,
2687	"ERROR: WDC: Unable to read 0x%x Log Page data with uuid %d, ret = 0x%x\n",
2688	lid, uuid_ix, ret);
2689	goto end;
2690	}
2691	}
2692
2693	/* Check the log data to see if the WD version of log page ID's is found */
2694	length = sizeof(struct wdc_c2_log_page_header);
2695	hdr_ptr = (struct wdc_c2_log_page_header *)data;
2696	sph = (struct wdc_c2_log_subpage_header *)(data + length);
2697	found = wdc_get_dev_mng_log_entry(le32_to_cpu(hdr_ptr->length), log_id, hdr_ptr, &sph);
2698	if (found) {
2699	*cbs_data = calloc(le32_to_cpu(sph->length), sizeof(__u8));
2700	if (!*cbs_data) {
2701	fprintf(stderrstderr, "ERROR: WDC: calloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
2702	found = false0;
2703	goto end;
2704	}
2705	memcpy((void )cbs_data, (void *)&sph->data, le32_to_cpu(sph->length));
2706	} else {
2707	fprintf(stderrstderr, "ERROR: WDC: C2 log id 0x%x not found with uuid index %d\n",
2708	log_id, uuid_ix);
2709	}
2710
2711	end:
2712	free(data);
2713	return found;
2714	}
2715
2716	static bool_Bool get_dev_mgment_data(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl,
2717	void **data)
2718	{
2719	bool_Bool found = false0;
2720	__u32 device_id = 0, vendor_id = 0;
2721	int uuid_index = 0;
2722	struct nvme_id_uuid_list uuid_list;
2723
2724	data = NULL((void)0);
2725
2726	/* The wdc_get_pci_ids function could fail when drives are connected
2727	* via a PCIe switch. Therefore, the return code is intentionally
2728	* being ignored. The device_id and vendor_id variables have been
2729	* initialized to 0 so the code can continue on without issue for
2730	* both cases: wdc_get_pci_ids successful or failed.
2731	*/
2732	wdc_get_pci_ids(ctx, hdl, &device_id, &vendor_id);
2733
2734	memset(&uuid_list, 0, sizeof(struct nvme_id_uuid_list));
2735	if (wdc_CheckUuidListSupport(hdl, &uuid_list)) {
2736	/* check for the Sandisk UUID first */
2737	uuid_index = libnvme_find_uuid(&uuid_list, SNDK_UUID);
2738
2739	if (uuid_index < 0) {
2740	/* The Sandisk UUID is not found;
2741	* check for the WDC UUID second.
2742	*/
2743	uuid_index = libnvme_find_uuid(&uuid_list, WDC_UUID);
2744	if (uuid_index < 0)
2745	uuid_index = libnvme_find_uuid(&uuid_list, WDC_UUID_SN640_3);
2746	}
2747
2748	if (uuid_index >= 0)
2749	found = get_dev_mgmt_log_page_data(hdl, data, uuid_index);
2750	else {
2751	fprintf(stderrstderr, "%s: UUID lists are supported but a matching ",
2752	__func__);
2753	fprintf(stderrstderr, "uuid was not found\n");
2754	}
2755	} else if (needs_c2_log_page_check(device_id)) {
2756	/* In certain devices that don't support UUID lists, there are multiple
2757	* definitions of the C2 logpage. In those cases, the code
2758	* needs to try two UUID indexes and use an identification algorithm
2759	* to determine which is returning the correct log page data.
2760	*/
2761
2762	uuid_index = 1;
2763	found = get_dev_mgmt_log_page_data(hdl, data, uuid_index);
2764
2765	if (!found) {
2766	/* not found with uuid = 1 try with uuid = 0 */
2767	uuid_index = 0;
2768	fprintf(stderrstderr, "Not found, requesting log page with uuid_index %d\n",
2769	uuid_index);
2770
2771	found = get_dev_mgmt_log_page_data(hdl, data, uuid_index);
2772	}
2773	} else {
2774	/* Default to uuid-index 0 for cases where UUID lists are not supported */
2775	uuid_index = 0;
2776	found = get_dev_mgmt_log_page_data(hdl, data, uuid_index);
2777	}
2778
2779	return found;
2780	}
2781
2782	static bool_Bool get_dev_mgment_cbs_data(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl,
2783	__u8 log_id, void **cbs_data)
2784	{
2785	bool_Bool found = false0;
2786	__u8 lid = 0;
2787	__u32 device_id = 0, vendor_id = 0;
2788	int uuid_index = 0;
2789	struct nvme_id_uuid_list uuid_list;
2790
2791	cbs_data = NULL((void)0);
2792
2793	/* The wdc_get_pci_ids function could fail when drives are connected
2794	* via a PCIe switch. Therefore, the return code is intentionally
2795	* being ignored. The device_id and vendor_id variables have been
2796	* initialized to 0 so the code can continue on without issue for
2797	* both cases: wdc_get_pci_ids successful or failed.
2798	*/
2799	wdc_get_pci_ids(ctx, hdl, &device_id, &vendor_id);
2800
2801	lid = WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2;
2802
2803	memset(&uuid_list, 0, sizeof(struct nvme_id_uuid_list));
2804	if (wdc_CheckUuidListSupport(hdl, &uuid_list)) {
2805	/* check for the Sandisk UUID first */
2806	uuid_index = libnvme_find_uuid(&uuid_list, SNDK_UUID);
2807
2808	if (uuid_index < 0) {
2809	/* The Sandisk UUID is not found;
2810	* check for the WDC UUID second.
2811	*/
2812	uuid_index = libnvme_find_uuid(&uuid_list, WDC_UUID);
2813	if (uuid_index < 0)
2814	uuid_index = libnvme_find_uuid(&uuid_list, WDC_UUID_SN640_3);
2815	}
2816
2817	if (uuid_index >= 0)
2818	found = get_dev_mgmt_log_page_lid_data(hdl, cbs_data, lid,
2819	log_id, uuid_index);
2820	else {
2821	fprintf(stderrstderr, "%s: UUID lists are supported but a matching ",
2822	__func__);
2823	fprintf(stderrstderr, "uuid was not found\n");
2824	}
2825	} else if (needs_c2_log_page_check(device_id)) {
2826	/* In certain devices that don't support UUID lists, there are multiple
2827	* definitions of the C2 logpage. In those cases, the code
2828	* needs to try two UUID indexes and use an identification algorithm
2829	* to determine which is returning the correct log page data.
2830	*/
2831	uuid_index = 1;
2832	found = get_dev_mgmt_log_page_lid_data(hdl, cbs_data, lid, log_id, uuid_index);
2833	if (!found) {
2834	/* not found with uuid = 1 try with uuid = 0 */
2835	uuid_index = 0;
2836	fprintf(stderrstderr, "Not found, requesting log page with uuid_index %d\n",
2837	uuid_index);
2838
2839	found = get_dev_mgmt_log_page_lid_data(hdl, cbs_data, lid, log_id,
2840	uuid_index);
2841	}
2842	} else {
2843	/* Default to uuid-index 0 for cases where UUID lists are not supported */
2844	uuid_index = 0;
2845	found = get_dev_mgmt_log_page_lid_data(hdl, cbs_data, lid, log_id, uuid_index);
2846	}
2847
2848	return found;
2849	}
2850
2851	static int wdc_get_supported_log_pages(struct libnvme_transport_handle *hdl,
2852	struct nvme_supported_log_pages *supported,
2853	int uuid_index)
2854	{
2855	struct libnvme_passthru_cmd cmd;
2856
2857	memset(supported, 0, sizeof(*supported));
2858	nvme_init_get_log(&cmd, NVME_NSID_ALL, NVME_LOG_LID_SUPPORTED_LOG_PAGES,
2859	NVME_CSI_NVM, supported, sizeof(*supported));
2860	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_index,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2861	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
2862	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
2863	return libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
2864	}
2865
2866	static bool_Bool wdc_nvme_check_supported_log_page(struct libnvme_global_ctx *ctx,
2867	struct libnvme_transport_handle *hdl,
2868	__u8 log_id,
2869	__u8 uuid_index)
2870	{
2871	int i;
2872	bool_Bool found = false0;
2873	int err = -1;
2874	struct wdc_c2_cbs_data cbs_data = NULL((void)0);
2875
2876	__cleanup_libnvme_free__attribute__((cleanup(libnvme_freep))) struct nvme_supported_log_pages supports = NULL((void)0);
2877
2878	/* Check log page id 0 (supported log pages) first */
2879	supports = libnvme_alloc(sizeof(*supports));
2880	if (!supports)
2881	return -ENOMEM12;
2882
2883	err = wdc_get_supported_log_pages(hdl,
2884	supports,
2885	uuid_index);
2886
2887	if (!err) {
2888	/* Check support log page list for support */
2889	if (supports->lid_support[log_id])
2890	/* Support for Log Page found in supported log pages */
2891	found = true1;
2892	}
2893
2894	/* if not found in the supported log pages (log id 0),
2895	* check the WDC C2 log page
2896	*/
2897	if (!found) {
2898	if (get_dev_mgment_cbs_data(ctx, hdl,
2899	WDC_C2_LOG_PAGES_SUPPORTED_ID0x08,
2900	(void *)&cbs_data)) {
2901	if (cbs_data) {
2902	for (i = 0; i < le32_to_cpu(cbs_data->length); i++) {
2903	if (log_id == cbs_data->data[i]) {
2904	found = true1;
2905	break;
2906	}
2907	}
2908
2909	#ifdef WDC_NVME_CLI_DEBUG
2910	if (!found) {
2911	fprintf(stderrstderr, "ERROR: WDC: Log Page 0x%x not supported\n",
2912	log_id);
2913	fprintf(stderrstderr, "WDC: Supported Log Pages:\n");
2914	/* print the supported pages */
2915	d((__u8 *)cbs_data->data, le32_to_cpu(cbs_data->length),
2916	16, 1);
2917	}
2918	#endif
2919	free(cbs_data);
2920	} else {
2921	fprintf(stderrstderr, "ERROR: WDC: cbs_data ptr = NULL\n");
2922	}
2923	} else {
2924	fprintf(stderrstderr, "ERROR: WDC: 0xC2 Log Page entry ID 0x%x not found\n",
2925	WDC_C2_LOG_PAGES_SUPPORTED_ID0x08);
2926	}
2927	}
2928
2929	return found;
2930	}
2931
2932	static bool_Bool wdc_nvme_parse_dev_status_log_entry(void log_data, __u32 ret_data,
2933	__u32 entry_id)
2934	{
2935	struct wdc_c2_log_subpage_header entry_data = NULL((void)0);
2936
2937	if (wdc_parse_dev_mng_log_entry(log_data, entry_id, &entry_data)) {
2938	if (entry_data) {
2939	*ret_data = le32_to_cpu(entry_data->data);
2940	return true1;
2941	}
2942	}
2943
2944	*ret_data = 0;
2945	return false0;
2946	}
2947
2948	static bool_Bool wdc_nvme_parse_dev_status_log_str(void *log_data,
2949	__u32 entry_id,
2950	char *ret_data,
2951	__u32 *ret_data_len)
2952	{
2953	struct wdc_c2_log_subpage_header entry_data = NULL((void)0);
2954	struct wdc_c2_cbs_data entry_str_data = NULL((void)0);
2955
2956	if (wdc_parse_dev_mng_log_entry(log_data, entry_id, &entry_data)) {
2957	if (entry_data) {
2958	entry_str_data = (struct wdc_c2_cbs_data *)&entry_data->data;
2959	memcpy(ret_data,
2960	(void *)&entry_str_data->data,
2961	le32_to_cpu(entry_str_data->length));
2962	*ret_data_len = le32_to_cpu(entry_str_data->length);
2963	return true1;
2964	}
2965	}
2966
2967	*ret_data = 0;
2968	*ret_data_len = 0;
2969	return false0;
2970	}
2971
2972	static bool_Bool wdc_nvme_get_dev_status_log_data(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, __le32 *ret_data,
2973	__u8 log_id)
2974	{
2975	__u32 cbs_data = NULL((void)0);
2976
2977	if (get_dev_mgment_cbs_data(ctx, hdl, log_id, (void *)&cbs_data)) {
2978	if (cbs_data) {
2979	memcpy((void )ret_data, (void )cbs_data, 4);
2980	free(cbs_data);
2981
2982	return true1;
2983	}
2984	}
2985
2986	*ret_data = 0;
2987	return false0;
2988	}
2989
2990	static int wdc_do_clear_dump(struct libnvme_transport_handle *hdl, __u8 opcode, __u32 cdw12)
2991	{
2992	int ret;
2993	struct libnvme_passthru_cmd admin_cmd;
2994
2995	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
2996	admin_cmd.opcode = opcode;
2997	admin_cmd.cdw12 = cdw12;
2998	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
2999	if (ret)
3000	fprintf(stdoutstdout, "ERROR: WDC: Crash dump erase failed\n");
3001	nvme_show_status(ret);
3002	return ret;
3003	}
3004
3005	static __u32 wdc_dump_length(struct libnvme_transport_handle link, __u32 opcode, __u32 cdw10, __u32 cdw12, __u32 dump_length)
3006	{
3007	int ret;
3008	__u8 buf[WDC_NVME_LOG_SIZE_DATA_LEN0x08] = {0};
3009	struct wdc_log_size *l;
3010	struct libnvme_passthru_cmd admin_cmd;
3011
3012	l = (struct wdc_log_size *) buf;
3013	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
3014	admin_cmd.opcode = opcode;
3015	admin_cmd.addr = (__u64)(uintptr_t)buf;
3016	admin_cmd.data_len = WDC_NVME_LOG_SIZE_DATA_LEN0x08;
3017	admin_cmd.cdw10 = cdw10;
3018	admin_cmd.cdw12 = cdw12;
3019
3020	ret = libnvme_exec_admin_passthru(link, &admin_cmd);
3021	if (ret) {
3022	l->log_size = 0;
3023	ret = -1;
3024	fprintf(stderrstderr, "ERROR: WDC: reading dump length failed\n");
3025	nvme_show_status(ret);
3026	return ret;
3027	}
3028
3029	if (opcode == WDC_NVME_CAP_DIAG_OPCODE0xE6)
3030	*dump_length = buf[0x04] << 24 \| buf[0x05] << 16 \| buf[0x06] << 8 \| buf[0x07];
3031	else
3032	*dump_length = le32_to_cpu(l->log_size);
3033	return ret;
3034	}
3035
3036	static __u32 wdc_dump_length_e6(struct libnvme_transport_handle hdl, __u32 opcode, __u32 cdw10, __u32 cdw12, struct wdc_e6_log_hdr dump_hdr)
3037	{
3038	int ret;
3039	struct libnvme_passthru_cmd admin_cmd;
3040
3041	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
3042	admin_cmd.opcode = opcode;
3043	admin_cmd.addr = (__u64)(uintptr_t)dump_hdr;
3044	admin_cmd.data_len = WDC_NVME_LOG_SIZE_HDR_LEN0x08;
3045	admin_cmd.cdw10 = cdw10;
3046	admin_cmd.cdw12 = cdw12;
3047
3048	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
3049	if (ret) {
3050	fprintf(stderrstderr, "ERROR: WDC: reading dump length failed\n");
3051	nvme_show_status(ret);
3052	}
3053
3054	return ret;
3055	}
3056
3057	static __u32 wdc_dump_dui_data(struct libnvme_transport_handle hdl, __u32 dataLen, __u32 offset, __u8 dump_data, bool_Bool last_xfer)
3058	{
3059	int ret;
3060	struct libnvme_passthru_cmd admin_cmd;
3061
3062	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
3063	admin_cmd.opcode = WDC_NVME_CAP_DUI_OPCODE0xFA;
3064	admin_cmd.nsid = 0xFFFFFFFF;
3065	admin_cmd.addr = (__u64)(uintptr_t)dump_data;
3066	admin_cmd.data_len = dataLen;
3067	admin_cmd.cdw10 = ((dataLen >> 2) - 1);
3068	admin_cmd.cdw12 = offset;
3069	if (last_xfer)
3070	admin_cmd.cdw14 = 0;
3071	else
3072	admin_cmd.cdw14 = WDC_NVME_CAP_DUI_DISABLE_IO0x01;
3073
3074
3075	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
3076	if (ret) {
3077	fprintf(stderrstderr, "ERROR: WDC: reading DUI data failed\n");
3078	nvme_show_status(ret);
3079	}
3080
3081	return ret;
3082	}
3083
3084	static __u32 wdc_dump_dui_data_v2(struct libnvme_transport_handle hdl, __u32 dataLen, __u64 offset, __u8 dump_data, bool_Bool last_xfer)
3085	{
3086	int ret;
3087	struct libnvme_passthru_cmd admin_cmd;
3088	__u64 offset_lo, offset_hi;
3089
3090	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
3091	admin_cmd.opcode = WDC_NVME_CAP_DUI_OPCODE0xFA;
3092	admin_cmd.nsid = 0xFFFFFFFF;
3093	admin_cmd.addr = (__u64)(uintptr_t)dump_data;
3094	admin_cmd.data_len = dataLen;
3095	admin_cmd.cdw10 = ((dataLen >> 2) - 1);
3096	offset_lo = offset & 0x00000000FFFFFFFF;
3097	offset_hi = ((offset & 0xFFFFFFFF00000000) >> 32);
3098	admin_cmd.cdw12 = (__u32)offset_lo;
3099	admin_cmd.cdw13 = (__u32)offset_hi;
3100
3101	if (last_xfer)
3102	admin_cmd.cdw14 = 0;
3103	else
3104	admin_cmd.cdw14 = WDC_NVME_CAP_DUI_DISABLE_IO0x01;
3105
3106	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
3107	if (ret) {
3108	fprintf(stderrstderr, "ERROR: WDC: reading DUI data V2 failed\n");
3109	nvme_show_status(ret);
3110	}
3111
3112	return ret;
3113	}
3114
3115	static int wdc_do_dump(struct libnvme_transport_handle *hdl, __u32 opcode, __u32 data_len,
3116	__u32 cdw12, const char *file, __u32 xfer_size)
3117	{
3118	int ret = 0;
3119	__u8 *dump_data;
3120	__u32 curr_data_offset, curr_data_len;
3121	int i;
3122	struct libnvme_passthru_cmd admin_cmd;
3123	__u32 dump_length = data_len;
3124
3125	dump_data = (__u8 )malloc(sizeof(__u8) dump_length);
3126	if (!dump_data) {
3127	fprintf(stderrstderr, "%s: ERROR: malloc: %s\n", __func__, libnvme_strerror(errno(*__errno_location ())));
3128	return -1;
3129	}
3130	memset(dump_data, 0, sizeof(__u8) * dump_length);
3131	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
3132	curr_data_offset = 0;
3133	curr_data_len = xfer_size;
3134	i = 0;
3135
3136	admin_cmd.opcode = opcode;
3137	admin_cmd.addr = (__u64)(uintptr_t)dump_data;
3138	admin_cmd.data_len = curr_data_len;
3139	admin_cmd.cdw10 = curr_data_len >> 2;
3140	admin_cmd.cdw12 = cdw12;
3141	admin_cmd.cdw13 = curr_data_offset;
3142
3143	while (curr_data_offset < data_len) {
3144	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
3145	if (ret) {
3146	nvme_show_status(ret);
3147	fprintf(stderrstderr, "%s: ERROR: WDC: Get chunk %d, size = 0x%x, offset = 0x%x, addr = 0x%lx\n",
3148	__func__, i, admin_cmd.data_len, curr_data_offset, (unsigned long)admin_cmd.addr);
3149	break;
3150	}
3151
3152	if ((curr_data_offset + xfer_size) <= data_len)
3153	curr_data_len = xfer_size;
3154	else
3155	curr_data_len = data_len - curr_data_offset; /* last transfer */
3156
3157	curr_data_offset += curr_data_len;
3158	admin_cmd.addr = (__u64)(uintptr_t)dump_data + (__u64)curr_data_offset;
3159	admin_cmd.data_len = curr_data_len;
3160	admin_cmd.cdw10 = curr_data_len >> 2;
3161	admin_cmd.cdw13 = curr_data_offset >> 2;
3162	i++;
3163	}
3164
3165	if (!ret) {
3166	nvme_show_status(ret);
3167	ret = wdc_create_log_file(file, dump_data, dump_length);
3168	}
3169	free(dump_data);
3170	return ret;
3171	}
3172
3173	static int wdc_do_dump_e6(struct libnvme_transport_handle *hdl, __u32 opcode, __u32 data_len,
3174	__u32 cdw12, char file, __u32 xfer_size, __u8 log_hdr)
3175	{
3176	int ret = 0;
3177	__u8 *dump_data;
3178	__u32 curr_data_offset, log_size;
3179	int i;
3180	struct libnvme_passthru_cmd admin_cmd;
3181
3182	/* if data_len is not 4 byte aligned */
3183	if (data_len & 0x00000003) {
3184	/* Round down to the next 4 byte aligned value */
3185	fprintf(stderrstderr, "%s: INFO: data_len 0x%x not 4 byte aligned.\n",
3186	__func__, data_len);
3187	fprintf(stderrstderr, "%s: INFO: Round down to 0x%x.\n",
3188	__func__, (data_len &= 0xFFFFFFFC));
3189	data_len &= 0xFFFFFFFC;
3190	}
3191
3192	dump_data = (__u8 )malloc(sizeof(__u8) data_len);
3193
3194	if (!dump_data) {
3195	fprintf(stderrstderr, "%s: ERROR: malloc: %s\n", __func__, libnvme_strerror(errno(*__errno_location ())));
3196	return -1;
3197	}
3198	memset(dump_data, 0, sizeof(__u8) * data_len);
3199	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
3200	curr_data_offset = WDC_NVME_LOG_SIZE_HDR_LEN0x08;
3201	i = 0;
3202
3203	/* copy the 8 byte header into the dump_data buffer */
3204	memcpy(dump_data, log_hdr, WDC_NVME_LOG_SIZE_HDR_LEN0x08);
3205
3206	admin_cmd.opcode = opcode;
3207	admin_cmd.cdw12 = cdw12;
3208
3209	/* subtract off the header size since that was already copied into the buffer */
3210	log_size = (data_len - curr_data_offset);
3211	while (log_size > 0) {
3212	xfer_size = min(xfer_size, log_size)((xfer_size) > (log_size) ? (log_size) : (xfer_size));
3213
3214	admin_cmd.addr = (__u64)(uintptr_t)dump_data + (__u64)curr_data_offset;
3215	admin_cmd.data_len = xfer_size;
3216	admin_cmd.cdw10 = xfer_size >> 2;
3217	admin_cmd.cdw13 = curr_data_offset >> 2;
3218
3219	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
3220	if (ret) {
3221	nvme_show_status(ret);
3222	fprintf(stderrstderr, "%s: ERROR: WDC: Get chunk %d, size = 0x%x, offset = 0x%x, addr = 0x%lx\n",
3223	__func__, i, admin_cmd.data_len, curr_data_offset, (unsigned long)admin_cmd.addr);
3224	break;
3225	}
3226
3227	log_size -= xfer_size;
3228	curr_data_offset += xfer_size;
3229	i++;
3230	}
3231
3232	if (!ret) {
3233	fprintf(stderrstderr, "%s: INFO: ", __func__);
3234	nvme_show_status(ret);
3235	} else {
3236	fprintf(stderrstderr, "%s: FAILURE: ", __func__);
3237	nvme_show_status(ret);
3238	fprintf(stderrstderr, "%s: Partial data may have been captured\n", __func__);
3239	snprintf(file + strlen(file), PATH_MAX4096, "%s", "-PARTIAL");
3240	}
3241
3242	ret = wdc_create_log_file(file, dump_data, data_len);
3243
3244	free(dump_data);
3245	return ret;
3246	}
3247
3248	static int wdc_do_cap_telemetry_log(struct libnvme_global_ctx *ctx,
3249	struct libnvme_transport_handle hdl, const char file,
3250	__u32 bs, int type, int data_area)
3251	{
3252	struct nvme_telemetry_log *log;
3253	size_t full_size = 0;
3254	int err = 0, output;
3255	__u32 host_gen = 1;
3256	int ctrl_init = 0;
3257	__u64 result;
3258	void buf = NULL((void)0);
3259	__u8 data_ptr = NULL((void)0);
3260	int data_written = 0, data_remaining = 0;
3261	struct nvme_id_ctrl ctrl;
3262	__u64 capabilities = 0;
3263
3264	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
3265	err = nvme_identify_ctrl(hdl, &ctrl);
3266	if (err) {
3267	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed 0x%x\n", err);
3268	return err;
3269	}
3270
3271	if (!(ctrl.lpa & 0x8)) {
3272	fprintf(stderrstderr, "Telemetry Host-Initiated and Telemetry Controller-Initiated log pages not supported\n");
3273	return -EINVAL22;
3274	}
3275
3276	err = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
3277	if (err) {
3278	fprintf(stderrstderr, "Failed to scan nvme subsystems\n");
3279	return err;
3280	}
3281
3282	capabilities = wdc_get_drive_capabilities(ctx, hdl);
3283
3284	if (type == WDC_TELEMETRY_TYPE_HOST0x1) {
3285	host_gen = 1;
3286	ctrl_init = 0;
3287	} else if (type == WDC_TELEMETRY_TYPE_CONTROLLER0x2) {
3288	if ((capabilities & WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002) == WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002) {
3289	/* Verify the Controller Initiated Option is enabled */
3290	err = nvme_get_features(hdl, 0,
3291	WDC_VU_DISABLE_CNTLR_TELEMETRY_OPTION_FEATURE_ID0xD2,
3292	NVME_GET_FEATURES_SEL_CURRENT, 0, 0,
3293	buf, 4, &result);
3294	if (!err) {
3295	if (!result) {
3296	/* enabled */
3297	host_gen = 0;
3298	ctrl_init = 1;
3299	} else {
3300	fprintf(stderrstderr, "%s: Controller initiated option telemetry log page disabled\n", __func__);
3301	return -EINVAL22;
3302	}
3303	} else {
3304	fprintf(stderrstderr, "ERROR: WDC: Get telemetry option feature failed.");
3305	nvme_show_status(err);
3306	return -EPERM1;
3307	}
3308	} else {
3309	host_gen = 0;
3310	ctrl_init = 1;
3311	}
3312	} else {
3313	fprintf(stderrstderr, "%s: Invalid type parameter; type = %d\n", __func__, type);
3314	return -EINVAL22;
3315	}
3316
3317	if (!file) {
3318	fprintf(stderrstderr, "%s: Please provide an output file!\n", __func__);
3319	return -EINVAL22;
3320	}
3321
3322	output = nvme_open_rawdata(file, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((file), (01 \| 0100 \| 01000), 0666);
3323	if (output < 0) {
3324	fprintf(stderrstderr, "%s: Failed to open output file %s: %s!\n",
3325	__func__, file, libnvme_strerror(errno(*__errno_location ())));
3326	return output;
3327	}
3328
3329	if (ctrl_init)
3330	err = libnvme_get_ctrl_telemetry(hdl, true1, &log,
3331	data_area, &full_size);
3332	else if (host_gen)
3333	err = libnvme_get_new_host_telemetry(hdl, &log,
3334	data_area, &full_size);
3335	else
3336	err = libnvme_get_host_telemetry(hdl, &log, data_area,
3337	&full_size);
3338
3339	if (err < 0) {
3340	perror("get-telemetry-log");
3341	goto close_output;
3342	} else if (err > 0) {
3343	nvme_show_status(err);
3344	fprintf(stderrstderr, "%s: Failed to acquire telemetry header!\n", __func__);
3345	goto close_output;
3346	}
3347
3348	/*
3349	*Continuously pull data until the offset hits the end of the last
3350	*block.
3351	*/
3352	data_written = 0;
3353	data_remaining = full_size;
3354	data_ptr = (__u8 *)log;
3355
3356	while (data_remaining) {
3357	data_written = write(output, data_ptr, data_remaining);
3358
3359	if (data_written < 0) {
3360	data_remaining = data_written;
3361	break;
3362	} else if (data_written <= data_remaining) {
3363	data_remaining -= data_written;
3364	data_ptr += data_written;
3365	} else {
3366	/* Unexpected overwrite */
3367	fprintf(stderrstderr, "Failure: Unexpected telemetry log overwrite - data_remaining = 0x%x, data_written = 0x%x\n",
3368	data_remaining, data_written);
3369	break;
3370	}
3371	}
3372
3373	if (fsync(output) < 0) {
3374	fprintf(stderrstderr, "ERROR: %s: fsync: %s\n", __func__, libnvme_strerror(errno(*__errno_location ())));
3375	err = -1;
3376	}
3377
3378	free(log);
3379	close_output:
3380	close(output);
3381	return err;
3382	}
3383
3384	static int wdc_do_cap_diag(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char *file,
3385	__u32 xfer_size, int type, int data_area)
3386	{
3387	int ret = -1;
3388	__u32 e6_log_hdr_size = WDC_NVME_CAP_DIAG_HEADER_TOC_SIZE0x08;
3389	struct wdc_e6_log_hdr *log_hdr;
3390	__u32 cap_diag_length;
3391
3392	log_hdr = (struct wdc_e6_log_hdr *)malloc(e6_log_hdr_size);
3393	if (!log_hdr) {
3394	fprintf(stderrstderr, "%s: ERROR: malloc: %s\n", __func__, libnvme_strerror(errno(*__errno_location ())));
3395	ret = -1;
3396	goto out;
3397	}
3398	memset(log_hdr, 0, e6_log_hdr_size);
3399
3400	if (type == WDC_TELEMETRY_TYPE_NONE0x0) {
3401	if (data_area) {
3402	fprintf(stderrstderr,
3403	"%s: ERROR: Data area parameter is not supported when type is NONE\n",
3404	__func__);
3405	ret = -1;
3406	goto out;
3407	}
3408	ret = wdc_dump_length_e6(hdl,
3409	WDC_NVME_CAP_DIAG_OPCODE0xE6,
3410	WDC_NVME_CAP_DIAG_HEADER_TOC_SIZE0x08>>2,
3411	0x00,
3412	log_hdr);
3413	if (ret == -1) {
3414	ret = -1;
3415	goto out;
3416	}
3417
3418	cap_diag_length = (log_hdr->log_size[0] << 24 \| log_hdr->log_size[1] << 16 \|
3419	log_hdr->log_size[2] << 8 \| log_hdr->log_size[3]);
3420
3421	if (!cap_diag_length) {
3422	fprintf(stderrstderr, "INFO: WDC: Capture Diagnostics log is empty\n");
3423	} else {
3424	ret = wdc_do_dump_e6(hdl,
3425	WDC_NVME_CAP_DIAG_OPCODE0xE6,
3426	cap_diag_length,
3427	(WDC_NVME_CAP_DIAG_SUBCMD0x00 << WDC_NVME_SUBCMD_SHIFT8) \| WDC_NVME_CAP_DIAG_CMD0x00,
3428	file, xfer_size, (__u8 *)log_hdr);
3429
3430	fprintf(stderrstderr, "INFO: WDC: Capture Diagnostics log, length = 0x%x\n", cap_diag_length);
3431	}
3432	} else if ((type == WDC_TELEMETRY_TYPE_HOST0x1) \|\|
3433	(type == WDC_TELEMETRY_TYPE_CONTROLLER0x2)) {
3434	/* Get the desired telemetry log page */
3435	ret = wdc_do_cap_telemetry_log(ctx, hdl, file, xfer_size,
3436	type, data_area);
3437	} else {
3438	fprintf(stderrstderr, "%s: ERROR: Invalid type : %d\n", __func__, type);
3439	}
3440
3441	out:
3442	free(log_hdr);
3443	return ret;
3444	}
3445
3446	static int wdc_do_cap_dui_v1(struct libnvme_transport_handle hdl, char file, __u32 xfer_size, int data_area, int verbose,
3447	struct wdc_dui_log_hdr log_hdr, __s64 total_size)
3448	{
3449	__s32 log_size = 0;
3450	__u32 cap_dui_length = le32_to_cpu(log_hdr->log_size);
3451	__u32 curr_data_offset = 0;
3452	__u8 *buffer_addr;
3453	__u8 dump_data = NULL((void)0);
3454	bool_Bool last_xfer = false0;
3455	int err;
3456	int i;
3457	int j;
3458	int output;
3459	int ret = 0;
3460
3461	if (verbose) {
3462	fprintf(stderrstderr, "INFO: WDC: Capture V1 Device Unit Info log, data area = %d\n",
3463	data_area);
3464	fprintf(stderrstderr, "INFO: WDC: DUI Header Version = 0x%x\n", log_hdr->hdr_version);
3465	fprintf(stderrstderr, "INFO: WDC: DUI section count = 0x%x\n", log_hdr->section_count);
3466	fprintf(stderrstderr, "INFO: WDC: DUI log size = 0x%x\n", log_hdr->log_size);
3467	}
3468
3469	if (!cap_dui_length) {
3470	fprintf(stderrstderr, "INFO: WDC: Capture V1 Device Unit Info log is empty\n");
3471	return 0;
3472	}
3473
3474	/* parse log header for all sections up to specified data area inclusively */
3475	if (data_area != WDC_NVME_DUI_MAX_DATA_AREA0x05) {
3476	for (j = 0; j < log_hdr->section_count; j++) {
3477	log_size += log_hdr->log_section[j].section_size;
3478	if (verbose)
3479	fprintf(stderrstderr,
3480	"%s: section size 0x%x, total size = 0x%x\n",
3481	__func__,
3482	(unsigned int)log_hdr->log_section[j].section_size,
3483	(unsigned int)log_size);
3484
3485	}
3486	} else {
3487	log_size = cap_dui_length;
3488	}
3489
3490	*total_size = log_size;
3491
3492	dump_data = (__u8 )malloc(sizeof(__u8) xfer_size);
3493	if (!dump_data) {
3494	fprintf(stderrstderr, "%s: ERROR: dump data V1 malloc failed : status %s, size = 0x%x\n",
3495	__func__, libnvme_strerror(errno(*__errno_location ())), (unsigned int)xfer_size);
3496	return -1;
3497	}
3498	memset(dump_data, 0, sizeof(__u8) * xfer_size);
3499
3500	output = nvme_open_rawdata(file, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((file), (01 \| 0100 \| 01000), 0666);
3501	if (output < 0) {
3502	fprintf(stderrstderr, "%s: Failed to open output file %s: %s!\n", __func__, file,
3503	libnvme_strerror(errno(*__errno_location ())));
3504	free(dump_data);
3505	return output;
3506	}
3507
3508	/* write the telemetry and log headers into the dump_file */
3509	err = write(output, (void *)log_hdr, WDC_NVME_CAP_DUI_HEADER_SIZE0x400);
3510	if (err != WDC_NVME_CAP_DUI_HEADER_SIZE0x400) {
3511	fprintf(stderrstderr, "%s: Failed to flush header data to file!\n", __func__);
3512	goto free_mem;
3513	}
3514
3515	log_size -= WDC_NVME_CAP_DUI_HEADER_SIZE0x400;
3516	curr_data_offset = WDC_NVME_CAP_DUI_HEADER_SIZE0x400;
3517	i = 0;
3518	buffer_addr = dump_data;
3519
3520	for (; log_size > 0; log_size -= xfer_size) {
3521	xfer_size = min(xfer_size, log_size)((xfer_size) > (log_size) ? (log_size) : (xfer_size));
3522
3523	if (log_size <= xfer_size)
3524	last_xfer = true1;
3525
3526	ret = wdc_dump_dui_data(hdl, xfer_size, curr_data_offset, buffer_addr, last_xfer);
3527	if (ret) {
3528	fprintf(stderrstderr,
3529	"%s: ERROR: WDC: Get chunk %d, size = 0x%"PRIx64"l" "x"", offset = 0x%x, addr = %p\n",
3530	__func__, i, (uint64_t)log_size, curr_data_offset, buffer_addr);
3531	fprintf(stderrstderr, "%s: ERROR: WDC: ", __func__);
3532	nvme_show_status(ret);
3533	break;
3534	}
3535
3536	/* write the dump data into the file */
3537	err = write(output, (void *)buffer_addr, xfer_size);
3538	if (err != xfer_size) {
3539	fprintf(stderrstderr,
3540	"%s: ERROR: WDC: Failed to flush DUI data to file! chunk %d, err = 0x%x, xfer_size = 0x%x\n",
3541	__func__, i, err, xfer_size);
3542	ret = -1;
3543	goto free_mem;
3544	}
3545
3546	curr_data_offset += xfer_size;
3547	i++;
3548	}
3549
3550	free_mem:
3551	close(output);
3552	free(dump_data);
3553	return ret;
3554	}
3555
3556	static int wdc_do_cap_dui_v2_v3(struct libnvme_transport_handle hdl, char file, __u32 xfer_size, int data_area, int verbose,
3557	struct wdc_dui_log_hdr log_hdr, __s64 total_size, __u64 file_size,
3558	__u64 offset)
3559	{
3560	__u64 cap_dui_length_v3;
3561	__u64 curr_data_offset = 0;
3562	__s64 log_size = 0;
3563	__u64 xfer_size_long = (__u64)xfer_size;
3564	__u8 *buffer_addr;
3565	__u8 dump_data = NULL((void)0);
3566	bool_Bool last_xfer = false0;
3567	int err;
3568	int i;
3569	int j;
3570	int output;
3571	int ret = 0;
3572	struct wdc_dui_log_hdr_v3 log_hdr_v3 = (struct wdc_dui_log_hdr_v3 )log_hdr;
3573
3574	cap_dui_length_v3 = le64_to_cpu(log_hdr_v3->log_size);
3575
3576	if (verbose) {
3577	fprintf(stderrstderr,
3578	"INFO: WDC: Capture V2 or V3 Device Unit Info log, data area = %d\n",
3579	data_area);
3580
3581	fprintf(stderrstderr, "INFO: WDC: DUI Header Version = 0x%x\n",
3582	log_hdr_v3->hdr_version);
3583	if ((log_hdr->hdr_version & 0xFF) == 0x03)
3584	fprintf(stderrstderr, "INFO: WDC: DUI Product ID = 0x%x/%c\n",
3585	log_hdr_v3->product_id, log_hdr_v3->product_id);
3586	}
3587
3588	if (!cap_dui_length_v3) {
3589	fprintf(stderrstderr, "INFO: WDC: Capture V2 or V3 Device Unit Info log is empty\n");
3590	return 0;
3591	}
3592
3593	/* parse log header for all sections up to specified data area inclusively */
3594	if (data_area != WDC_NVME_DUI_MAX_DATA_AREA0x05) {
3595	for (j = 0; j < WDC_NVME_DUI_MAX_SECTION_V30x23; j++) {
3596	if (log_hdr_v3->log_section[j].data_area_id <= data_area &&
3597	log_hdr_v3->log_section[j].data_area_id) {
3598	log_size += log_hdr_v3->log_section[j].section_size;
3599	if (verbose)
3600	fprintf(stderrstderr,
3601	"%s: Data area ID %d : section size 0x%x, total size = 0x%"PRIx64"l" "x""\n",
3602	__func__, log_hdr_v3->log_section[j].data_area_id,
3603	(unsigned int)log_hdr_v3->log_section[j].section_size,
3604	(uint64_t)log_size);
3605	} else {
3606	if (verbose)
3607	fprintf(stderrstderr, "%s: break, total size = 0x%"PRIx64"l" "x""\n",
3608	__func__, (uint64_t)log_size);
3609	break;
3610	}
3611	}
3612	} else {
3613	log_size = cap_dui_length_v3;
3614	}
3615
3616	*total_size = log_size;
3617
3618	if (offset >= *total_size) {
3619	fprintf(stderrstderr,
3620	"%s: INFO: WDC: Offset 0x%"PRIx64"l" "x"" exceeds total size 0x%"PRIx64"l" "x"", no data retrieved\n",
3621	__func__, (uint64_t)offset, (uint64_t)*total_size);
3622	return -1;
3623	}
3624
3625	dump_data = (__u8 )malloc(sizeof(__u8) xfer_size_long);
3626	if (!dump_data) {
3627	fprintf(stderrstderr,
3628	"%s: ERROR: dump data v3 malloc failed : status %s, size = 0x%"PRIx64"l" "x""\n",
3629	__func__, libnvme_strerror(errno(*__errno_location ())), (uint64_t)xfer_size_long);
3630	return -1;
3631	}
3632	memset(dump_data, 0, sizeof(__u8) * xfer_size_long);
3633
3634	output = nvme_open_rawdata(file, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((file), (01 \| 0100 \| 01000), 0666);
3635	if (output < 0) {
3636	fprintf(stderrstderr, "%s: Failed to open output file %s: %s!\n",
3637	__func__, file, libnvme_strerror(errno(*__errno_location ())));
3638	free(dump_data);
3639	return output;
3640	}
3641
3642	curr_data_offset = 0;
3643
3644	if (file_size) {
3645	/* Write the DUI data based on the passed in file size */
3646	if ((offset + file_size) > *total_size)
3647	log_size = min((total_size - offset), file_size)(((total_size - offset)) > (file_size) ? (file_size) : (( *total_size - offset)));
3648	else
3649	log_size = min(total_size, file_size)((total_size) > (file_size) ? (file_size) : (*total_size) );
3650
3651	if (verbose)
3652	fprintf(stderrstderr,
3653	"%s: INFO: WDC: Offset 0x%"PRIx64"l" "x"", file size 0x%"PRIx64"l" "x"", total size 0x%"PRIx64"l" "x"", log size 0x%"PRIx64"l" "x""\n",
3654	__func__, (uint64_t)offset,
3655	(uint64_t)file_size, (uint64_t)*total_size, (uint64_t)log_size);
3656
3657	curr_data_offset = offset;
3658	}
3659
3660	i = 0;
3661	buffer_addr = dump_data;
3662
3663	for (; log_size > 0; log_size -= xfer_size_long) {
3664	xfer_size_long = min(xfer_size_long, log_size)((xfer_size_long) > (log_size) ? (log_size) : (xfer_size_long ));
3665
3666	if (log_size <= xfer_size_long)
3667	last_xfer = true1;
3668
3669	ret = wdc_dump_dui_data_v2(hdl, (__u32)xfer_size_long, curr_data_offset, buffer_addr,
3670	last_xfer);
3671	if (ret) {
3672	fprintf(stderrstderr,
3673	"%s: ERROR: WDC: Get chunk %d, size = 0x%"PRIx64"l" "x"", offset = 0x%"PRIx64"l" "x"", addr = %p\n",
3674	__func__, i, (uint64_t)*total_size, (uint64_t)curr_data_offset,
3675	buffer_addr);
3676	fprintf(stderrstderr, "%s: ERROR: WDC: ", __func__);
3677	nvme_show_status(ret);
3678	break;
3679	}
3680
3681	/* write the dump data into the file */
3682	err = write(output, (void *)buffer_addr, xfer_size_long);
3683	if (err != xfer_size_long) {
3684	fprintf(stderrstderr,
3685	"%s: ERROR: WDC: Failed to flush DUI data to file! chunk %d, err = 0x%x, xfer_size = 0x%"PRIx64"l" "x""\n",
3686	__func__, i, err, (uint64_t)xfer_size_long);
3687	ret = -1;
3688	goto free_mem;
3689	}
3690
3691	curr_data_offset += xfer_size_long;
3692	i++;
3693	}
3694
3695	free_mem:
3696	close(output);
3697	free(dump_data);
3698	return ret;
3699	}
3700
3701	static int wdc_do_cap_dui_v4(struct libnvme_transport_handle hdl, char file, __u32 xfer_size, int data_area, int verbose,
3702	struct wdc_dui_log_hdr log_hdr, __s64 total_size, __u64 file_size,
3703	__u64 offset)
3704	{
3705	__s64 log_size = 0;
3706	__s64 section_size_bytes = 0;
3707	__s64 xfer_size_long = (__s64)xfer_size;
3708	__u64 cap_dui_length_v4;
3709	__u64 curr_data_offset = 0;
3710	__u8 *buffer_addr;
3711	__u8 dump_data = NULL((void)0);
3712	int err;
3713	int i;
3714	int j;
3715	int output;
3716	int ret = 0;
3717	bool_Bool last_xfer = false0;
3718	struct wdc_dui_log_hdr_v4 log_hdr_v4 = (struct wdc_dui_log_hdr_v4 )log_hdr;
3719
3720	cap_dui_length_v4 = le64_to_cpu(log_hdr_v4->log_size_sectors) * WDC_NVME_SN730_SECTOR_SIZE512;
3721
3722	if (verbose) {
3723	fprintf(stderrstderr, "INFO: WDC: Capture V4 Device Unit Info log, data area = %d\n", data_area);
3724	fprintf(stderrstderr, "INFO: WDC: DUI Header Version = 0x%x\n", log_hdr_v4->hdr_version);
3725	fprintf(stderrstderr, "INFO: WDC: DUI Product ID = 0x%x/%c\n", log_hdr_v4->product_id, log_hdr_v4->product_id);
3726	fprintf(stderrstderr, "INFO: WDC: DUI log size sectors = 0x%x\n", log_hdr_v4->log_size_sectors);
3727	fprintf(stderrstderr, "INFO: WDC: DUI cap_dui_length = 0x%"PRIx64"l" "x""\n", (uint64_t)cap_dui_length_v4);
3728	}
3729
3730	if (!cap_dui_length_v4) {
3731	fprintf(stderrstderr, "INFO: WDC: Capture V4 Device Unit Info log is empty\n");
3732	return 0;
3733	}
3734
3735	/* parse log header for all sections up to specified data area inclusively */
3736	if (data_area != WDC_NVME_DUI_MAX_DATA_AREA0x05) {
3737	for (j = 0; j < WDC_NVME_DUI_MAX_SECTION0x3A; j++) {
3738	if (log_hdr_v4->log_section[j].data_area_id <= data_area &&
3739	log_hdr_v4->log_section[j].data_area_id) {
3740	section_size_bytes = ((__s64)log_hdr_v4->log_section[j].section_size_sectors * WDC_NVME_SN730_SECTOR_SIZE512);
3741	log_size += section_size_bytes;
3742	if (verbose)
3743	fprintf(stderrstderr,
3744	"%s: Data area ID %d : section size 0x%x sectors, section size 0x%"PRIx64"l" "x"" bytes, total size = 0x%"PRIx64"l" "x""\n",
3745	__func__, log_hdr_v4->log_section[j].data_area_id,
3746	log_hdr_v4->log_section[j].section_size_sectors,
3747	(uint64_t)section_size_bytes, (uint64_t)log_size);
3748	} else {
3749	if (verbose)
3750	fprintf(stderrstderr, "%s: break, total size = 0x%"PRIx64"l" "x""\n", __func__, (uint64_t)log_size);
3751	break;
3752	}
3753	}
3754	} else {
3755	log_size = cap_dui_length_v4;
3756	}
3757
3758	*total_size = log_size;
3759
3760	if (offset >= *total_size) {
3761	fprintf(stderrstderr,
3762	"%s: INFO: WDC: Offset 0x%"PRIx64"l" "x"" exceeds total size 0x%"PRIx64"l" "x"", no data retrieved\n",
3763	__func__, (uint64_t)offset, (uint64_t)*total_size);
3764	return -1;
3765	}
3766
3767	dump_data = (__u8 )malloc(sizeof(__u8) xfer_size_long);
3768	if (!dump_data) {
3769	fprintf(stderrstderr, "%s: ERROR: dump data V4 malloc failed : status %s, size = 0x%x\n",
3770	__func__, libnvme_strerror(errno(*__errno_location ())), (unsigned int)xfer_size_long);
3771	return -1;
3772	}
3773	memset(dump_data, 0, sizeof(__u8) * xfer_size_long);
3774
3775	output = nvme_open_rawdata(file, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((file), (01 \| 0100 \| 01000), 0666);
3776	if (output < 0) {
3777	fprintf(stderrstderr, "%s: Failed to open output file %s: %s!\n", __func__, file,
3778	libnvme_strerror(errno(*__errno_location ())));
3779	free(dump_data);
3780	return output;
3781	}
3782
3783	curr_data_offset = 0;
3784
3785	if (file_size) {
3786	/* Write the DUI data based on the passed in file size */
3787	if ((offset + file_size) > *total_size)
3788	log_size = min((total_size - offset), file_size)(((total_size - offset)) > (file_size) ? (file_size) : (( *total_size - offset)));
3789	else
3790	log_size = min(total_size, file_size)((total_size) > (file_size) ? (file_size) : (*total_size) );
3791
3792	if (verbose)
3793	fprintf(stderrstderr,
3794	"%s: INFO: WDC: Offset 0x%"PRIx64"l" "x"", file size 0x%"PRIx64"l" "x"", total size 0x%"PRIx64"l" "x"", log size 0x%"PRIx64"l" "x""\n",
3795	__func__, (uint64_t)offset, (uint64_t)file_size,
3796	(uint64_t)*total_size, (uint64_t)log_size);
3797
3798	curr_data_offset = offset;
3799	}
3800
3801	i = 0;
3802	buffer_addr = dump_data;
3803
3804	for (; log_size > 0; log_size -= xfer_size_long) {
3805	xfer_size_long = min(xfer_size_long, log_size)((xfer_size_long) > (log_size) ? (log_size) : (xfer_size_long ));
3806
3807	if (log_size <= xfer_size_long)
3808	last_xfer = true1;
3809
3810	ret = wdc_dump_dui_data_v2(hdl, (__u32)xfer_size_long, curr_data_offset, buffer_addr, last_xfer);
3811	if (ret) {
3812	fprintf(stderrstderr,
3813	"%s: ERROR: WDC: Get chunk %d, size = 0x%"PRIx64"l" "x"", offset = 0x%"PRIx64"l" "x"", addr = %p\n",
3814	__func__, i, (uint64_t)log_size, (uint64_t)curr_data_offset,
3815	buffer_addr);
3816	fprintf(stderrstderr, "%s: ERROR: WDC:", __func__);
3817	nvme_show_status(ret);
3818	break;
3819	}
3820
3821	/* write the dump data into the file */
3822	err = write(output, (void *)buffer_addr, xfer_size_long);
3823	if (err != xfer_size_long) {
3824	fprintf(stderrstderr,
3825	"%s: ERROR: WDC: Failed to flush DUI data to file! chunk %d, err = 0x%x, xfer_size_long = 0x%"PRIx64"l" "x""\n",
3826	__func__, i, err, (uint64_t)xfer_size_long);
3827	ret = -1;
3828	goto free_mem;
3829	}
3830
3831	curr_data_offset += xfer_size_long;
3832	i++;
3833	}
3834
3835	free_mem:
3836	close(output);
3837	free(dump_data);
3838	return ret;
3839	}
3840
3841	static int wdc_do_cap_dui(struct libnvme_transport_handle hdl, char file, __u32 xfer_size, int data_area, int verbose,
3842	__u64 file_size, __u64 offset)
3843	{
3844	int ret = 0;
3845	__u32 dui_log_hdr_size = WDC_NVME_CAP_DUI_HEADER_SIZE0x400;
3846	struct wdc_dui_log_hdr *log_hdr;
3847	__s64 total_size = 0;
3848	bool_Bool last_xfer = false0;
3849
3850	log_hdr = (struct wdc_dui_log_hdr *)malloc(dui_log_hdr_size);
3851	if (!log_hdr) {
3852	fprintf(stderrstderr, "%s: ERROR: log header malloc failed : status %s, size 0x%x\n",
3853	__func__, libnvme_strerror(errno(*__errno_location ())), dui_log_hdr_size);
3854	return -1;
3855	}
3856	memset(log_hdr, 0, dui_log_hdr_size);
3857
3858	/* get the dui telemetry and log headers */
3859	ret = wdc_dump_dui_data(hdl, WDC_NVME_CAP_DUI_HEADER_SIZE0x400, 0x00, (__u8 *)log_hdr, last_xfer);
3860	if (ret) {
3861	fprintf(stderrstderr, "%s: ERROR: WDC: Get DUI headers failed\n", __func__);
3862	fprintf(stderrstderr, "%s: ERROR: WDC: ", __func__);
3863	nvme_show_status(ret);
3864	goto out;
3865	}
3866
3867	/* Check the Log Header version */
3868	if ((log_hdr->hdr_version & 0xFF) == 0x00 \|\| (log_hdr->hdr_version & 0xFF) == 0x01) {
3869	ret = wdc_do_cap_dui_v1(hdl, file, xfer_size, data_area, verbose, log_hdr,
3870	&total_size);
3871	if (ret)
3872	goto out;
3873	} else if ((log_hdr->hdr_version & 0xFF) == 0x02 \|\|
3874	(log_hdr->hdr_version & 0xFF) == 0x03) {
3875	/* Process Version 2 or 3 header */
3876	ret = wdc_do_cap_dui_v2_v3(hdl, file, xfer_size, data_area, verbose, log_hdr,
3877	&total_size, file_size, offset);
3878	if (ret)
3879	goto out;
3880	} else if ((log_hdr->hdr_version & 0xFF) == 0x04) {
3881	ret = wdc_do_cap_dui_v4(hdl, file, xfer_size, data_area, verbose, log_hdr,
3882	&total_size, file_size, offset);
3883	if (ret)
3884	goto out;
3885	} else {
3886	fprintf(stderrstderr, "INFO: WDC: Unsupported header version = 0x%x\n",
3887	log_hdr->hdr_version);
3888	goto out;
3889	}
3890
3891	nvme_show_status(ret);
3892	if (verbose)
3893	fprintf(stderrstderr, "INFO: WDC: Capture Device Unit Info log, length = 0x%"PRIx64"l" "x""\n",
3894	(uint64_t)total_size);
3895
3896	out:
3897	free(log_hdr);
3898	return ret;
3899	}
3900
3901	static int wdc_cap_diag(int argc, char *argv, struct command acmd,
3902	struct plugin *plugin)
3903	{
3904	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
3905	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
3906	const char *desc = "Capture Diagnostics Log.";
3907	const char *file = "Output file pathname.";
3908	const char *size = "Data retrieval transfer size.";
3909	__u64 capabilities = 0;
3910	char f[PATH_MAX4096] = {0};
3911	__u32 xfer_size = 0;
3912	int ret = 0;
3913
3914	struct config {
3915	char *file;
3916	__u32 xfer_size;
3917	};
3918
3919	struct config cfg = {
3920	.file = NULL((void*)0),
3921	.xfer_size = 0x10000
3922	};
3923
3924	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
3925	OPT_FILE("output-file", 'O', &cfg.file, file),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
3926	OPT_UINT("transfer-size", 's', &cfg.xfer_size, size))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
3927
3928	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
3929	if (ret)
3930	return ret;
3931
3932	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
3933	if (ret)
3934	return ret;
3935
3936	if (cfg.file)
3937	strncpy(f, cfg.file, PATH_MAX4096 - 1);
3938	if (cfg.xfer_size)
3939	xfer_size = cfg.xfer_size;
3940	ret = wdc_get_serial_name(hdl, f, PATH_MAX4096, "cap_diag");
3941	if (ret) {
3942	fprintf(stderrstderr, "ERROR: WDC: failed to generate file name\n");
3943	return ret;
3944	}
3945	if (!cfg.file) {
3946	if (strlen(f) > PATH_MAX4096 - 5) {
3947	fprintf(stderrstderr, "ERROR: WDC: file name overflow\n");
3948	return -1;
3949	}
3950	strcat(f, ".bin");
3951	}
3952
3953	capabilities = wdc_get_drive_capabilities(ctx, hdl);
3954	if ((capabilities & WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001) == WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001)
3955	ret = wdc_do_cap_diag(ctx, hdl, f, xfer_size, 0, 0);
3956	else
3957	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
3958	return ret;
3959	}
3960
3961	static int wdc_do_get_sn730_log_len(struct libnvme_transport_handle hdl, uint32_t len_buf, uint32_t subopcode)
3962	{
3963	int ret;
3964	uint32_t output = NULL((void)0);
3965	struct libnvme_passthru_cmd admin_cmd;
3966
3967	output = (uint32_t *)malloc(sizeof(uint32_t));
3968	if (!output) {
3969	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
3970	return -1;
3971	}
3972	memset(output, 0, sizeof(uint32_t));
3973	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
3974
3975	admin_cmd.data_len = 8;
3976	admin_cmd.opcode = SN730_NVME_GET_LOG_OPCODE0xc2;
3977	admin_cmd.addr = (uintptr_t)output;
3978	admin_cmd.cdw12 = subopcode;
3979	admin_cmd.cdw10 = SN730_LOG_CHUNK_SIZE0x1000 / 4;
3980
3981	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
3982	if (!ret)
3983	len_buf = output;
3984	free(output);
3985	return ret;
3986	}
3987
3988	static int wdc_do_get_sn730_log(struct libnvme_transport_handle hdl, void log_buf, uint32_t offset, uint32_t subopcode)
3989	{
3990	int ret;
3991	uint8_t output = NULL((void)0);
3992	struct libnvme_passthru_cmd admin_cmd;
3993
3994	output = (uint8_t *)calloc(SN730_LOG_CHUNK_SIZE0x1000, sizeof(uint8_t));
3995	if (!output) {
3996	fprintf(stderrstderr, "ERROR: WDC: calloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
3997	return -1;
3998	}
3999	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
4000	admin_cmd.data_len = SN730_LOG_CHUNK_SIZE0x1000;
4001	admin_cmd.opcode = SN730_NVME_GET_LOG_OPCODE0xc2;
4002	admin_cmd.addr = (uintptr_t)output;
4003	admin_cmd.cdw12 = subopcode;
4004	admin_cmd.cdw13 = offset;
4005	admin_cmd.cdw10 = SN730_LOG_CHUNK_SIZE0x1000 / 4;
4006
4007	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
4008	if (!ret)
4009	memcpy(log_buf, output, SN730_LOG_CHUNK_SIZE0x1000);
4010	return ret;
4011	}
4012
4013	static int get_sn730_log_chunks(struct libnvme_transport_handle hdl, uint8_t log_buf, uint32_t log_len, uint32_t subopcode)
4014	{
4015	int ret = 0;
4016	uint8_t chunk_buf = NULL((void)0);
4017	int remaining = log_len;
4018	int curr_offset = 0;
4019
4020	chunk_buf = (uint8_t )malloc(sizeof(uint8_t) SN730_LOG_CHUNK_SIZE0x1000);
4021	if (!chunk_buf) {
4022	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
4023	ret = -1;
4024	goto out;
4025	}
4026
4027	while (remaining > 0) {
4028	memset(chunk_buf, 0, SN730_LOG_CHUNK_SIZE0x1000);
4029	ret = wdc_do_get_sn730_log(hdl, chunk_buf, curr_offset, subopcode);
4030	if (!ret) {
4031	if (remaining >= SN730_LOG_CHUNK_SIZE0x1000) {
4032	memcpy(log_buf + (curr_offset * SN730_LOG_CHUNK_SIZE0x1000),
4033	chunk_buf, SN730_LOG_CHUNK_SIZE0x1000);
4034	} else {
4035	memcpy(log_buf + (curr_offset * SN730_LOG_CHUNK_SIZE0x1000),
4036	chunk_buf, remaining);
4037	}
4038	remaining -= SN730_LOG_CHUNK_SIZE0x1000;
4039	curr_offset += 1;
4040	} else {
4041	goto out;
4042	}
4043	}
4044	out:
4045	free(chunk_buf);
4046	return ret;
4047	}
4048
4049	static int wdc_do_sn730_get_and_tar(struct libnvme_transport_handle hdl, char outputName)
4050	{
4051	int ret = 0;
4052	void *retPtr;
4053	uint8_t full_log_buf = NULL((void)0);
4054	uint8_t key_log_buf = NULL((void)0);
4055	uint8_t core_dump_log_buf = NULL((void)0);
4056	uint8_t extended_log_buf = NULL((void)0);
4057	uint32_t full_log_len = 0;
4058	uint32_t key_log_len = 0;
4059	uint32_t core_dump_log_len = 0;
4060	uint32_t extended_log_len = 0;
4061	struct tarfile_metadata tarInfo = NULL((void)0);
4062
4063	tarInfo = (struct tarfile_metadata *)malloc(sizeof(struct tarfile_metadata));
4064	if (!tarInfo) {
4065	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
4066	ret = -1;
4067	goto free_buf;
4068	}
4069	memset(tarInfo, 0, sizeof(struct tarfile_metadata));
4070
4071	/* Create Logs directory */
4072	wdc_UtilsGetTime(&tarInfo->timeInfo);
4073	memset(tarInfo->timeString, 0, sizeof(tarInfo->timeString));
4074	wdc_UtilsSnprintf((char *)tarInfo->timeString, MAX_PATH_LEN256, "%02u%02u%02u_%02u%02u%02u",
4075	tarInfo->timeInfo.year, tarInfo->timeInfo.month, tarInfo->timeInfo.dayOfMonth,
4076	tarInfo->timeInfo.hour, tarInfo->timeInfo.minute, tarInfo->timeInfo.second);
4077
4078	wdc_UtilsSnprintf((char *)tarInfo->bufferFolderName, MAX_PATH_LEN256, "%s",
4079	(char *)outputName);
4080
4081	retPtr = getcwd((char *)tarInfo->currDir, MAX_PATH_LEN256);
4082	if (retPtr) {
4083	wdc_UtilsSnprintf((char *)tarInfo->bufferFolderPath, MAX_PATH_LEN256, "%s%s%s",
4084	(char )tarInfo->currDir, WDC_DE_PATH_SEPARATOR"/", (char )tarInfo->bufferFolderName);
4085	} else {
4086	fprintf(stderrstderr, "ERROR: WDC: get current working directory failed\n");
4087	goto free_buf;
4088	}
4089
4090	ret = wdc_UtilsCreateDir((char *)tarInfo->bufferFolderPath);
4091	if (ret) {
4092	fprintf(stderrstderr, "ERROR: WDC: create directory failed, ret = %d, dir = %s\n", ret, tarInfo->bufferFolderPath);
4093	goto free_buf;
4094	} else {
4095	fprintf(stderrstderr, "Stored log files in directory: %s\n", tarInfo->bufferFolderPath);
4096	}
4097
4098	ret = wdc_do_get_sn730_log_len(hdl, &full_log_len, SN730_GET_FULL_LOG_LENGTH0x00080009);
4099	if (ret) {
4100	nvme_show_status(ret);
4101	goto free_buf;
4102	}
4103	ret = wdc_do_get_sn730_log_len(hdl, &key_log_len, SN730_GET_KEY_LOG_LENGTH0x00090009);
4104	if (ret) {
4105	nvme_show_status(ret);
4106	goto free_buf;
4107	}
4108	ret = wdc_do_get_sn730_log_len(hdl, &core_dump_log_len, SN730_GET_COREDUMP_LOG_LENGTH0x00120009);
4109	if (ret) {
4110	nvme_show_status(ret);
4111	goto free_buf;
4112	}
4113	ret = wdc_do_get_sn730_log_len(hdl, &extended_log_len, SN730_GET_EXTENDED_LOG_LENGTH0x00420009);
4114	if (ret) {
4115	nvme_show_status(ret);
4116	goto free_buf;
4117	}
4118
4119	full_log_buf = (uint8_t *) calloc(full_log_len, sizeof(uint8_t));
4120	key_log_buf = (uint8_t *) calloc(key_log_len, sizeof(uint8_t));
4121	core_dump_log_buf = (uint8_t *) calloc(core_dump_log_len, sizeof(uint8_t));
4122	extended_log_buf = (uint8_t *) calloc(extended_log_len, sizeof(uint8_t));
4123
4124	if (!full_log_buf \|\| !key_log_buf \|\| !core_dump_log_buf \|\| !extended_log_buf) {
4125	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
4126	ret = -1;
4127	goto free_buf;
4128	}
4129
4130	/* Get the full log */
4131	ret = get_sn730_log_chunks(hdl, full_log_buf, full_log_len, SN730_GET_FULL_LOG_SUBOPCODE0x00010009);
4132	if (ret) {
4133	nvme_show_status(ret);
4134	goto free_buf;
4135	}
4136
4137	/* Get the key log */
4138	ret = get_sn730_log_chunks(hdl, key_log_buf, key_log_len, SN730_GET_KEY_LOG_SUBOPCODE0x00020009);
4139	if (ret) {
4140	nvme_show_status(ret);
4141	goto free_buf;
4142	}
4143
4144	/* Get the core dump log */
4145	ret = get_sn730_log_chunks(hdl, core_dump_log_buf, core_dump_log_len, SN730_GET_CORE_LOG_SUBOPCODE0x00030009);
4146	if (ret) {
4147	nvme_show_status(ret);
4148	goto free_buf;
4149	}
4150
4151	/* Get the extended log */
4152	ret = get_sn730_log_chunks(hdl, extended_log_buf, extended_log_len, SN730_GET_EXTEND_LOG_SUBOPCODE0x00040009);
4153	if (ret) {
4154	nvme_show_status(ret);
4155	goto free_buf;
4156	}
4157
4158	/* Write log files */
4159	wdc_UtilsSnprintf(tarInfo->fileName, MAX_PATH_LEN256, "%s%s%s_%s.bin", (char *)tarInfo->bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
4160	"full_log", (char *)tarInfo->timeString);
4161	wdc_WriteToFile(tarInfo->fileName, (char *)full_log_buf, full_log_len);
4162
4163	wdc_UtilsSnprintf(tarInfo->fileName, MAX_PATH_LEN256, "%s%s%s_%s.bin", (char *)tarInfo->bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
4164	"key_log", (char *)tarInfo->timeString);
4165	wdc_WriteToFile(tarInfo->fileName, (char *)key_log_buf, key_log_len);
4166
4167	wdc_UtilsSnprintf(tarInfo->fileName, MAX_PATH_LEN256, "%s%s%s_%s.bin", (char *)tarInfo->bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
4168	"core_dump_log", (char *)tarInfo->timeString);
4169	wdc_WriteToFile(tarInfo->fileName, (char *)core_dump_log_buf, core_dump_log_len);
4170
4171	wdc_UtilsSnprintf(tarInfo->fileName, MAX_PATH_LEN256, "%s%s%s_%s.bin", (char *)tarInfo->bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
4172	"extended_log", (char *)tarInfo->timeString);
4173	wdc_WriteToFile(tarInfo->fileName, (char *)extended_log_buf, extended_log_len);
4174
4175	/* Tar the log directory */
4176	wdc_UtilsSnprintf(tarInfo->tarFileName, sizeof(tarInfo->tarFileName), "%s%s", (char *)tarInfo->bufferFolderPath, WDC_DE_TAR_FILE_EXTN".tar.gz");
4177	wdc_UtilsSnprintf(tarInfo->tarFiles, sizeof(tarInfo->tarFiles), "%s%s%s", (char )tarInfo->bufferFolderName, WDC_DE_PATH_SEPARATOR"/", WDC_DE_TAR_FILES".bin");
4178	wdc_UtilsSnprintf(tarInfo->tarCmd, sizeof(tarInfo->tarCmd), "%s %s %s", WDC_DE_TAR_CMD"tar -czf", (char )tarInfo->tarFileName, (char )tarInfo->tarFiles);
4179
4180	ret = system(tarInfo->tarCmd);
4181
4182	if (ret)
4183	fprintf(stderrstderr, "ERROR: WDC: Tar of log data failed, ret = %d\n", ret);
4184
4185	free_buf:
4186	free(tarInfo);
4187	free(full_log_buf);
4188	free(core_dump_log_buf);
4189	free(key_log_buf);
4190	free(extended_log_buf);
4191	return ret;
4192	}
4193
4194	static int dump_internal_logs(struct libnvme_transport_handle hdl, const char dir_name, int verbose)
4195	{
4196	char file_path[PATH_MAX4096];
4197	void *telemetry_log;
4198	const size_t bs = 512;
4199	struct nvme_telemetry_log *hdr;
4200	struct libnvme_passthru_cmd cmd;
4201	size_t full_size, offset = bs;
4202	int err, output;
4203
4204	if (verbose)
4205	printf("NVMe Telemetry log...\n");
4206
4207	hdr = malloc(bs);
4208	telemetry_log = malloc(bs);
4209	if (!hdr \|\| !telemetry_log) {
4210	fprintf(stderrstderr, "Failed to allocate %zu bytes for log: %s\n", bs, libnvme_strerror(errno(*__errno_location ())));
4211	err = -ENOMEM12;
4212	goto free_mem;
4213	}
4214	memset(hdr, 0, bs);
4215
4216	sprintf(file_path, "%s/telemetry.bin", dir_name);
4217	output = nvme_open_rawdata(file_path, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((file_path), (01 \| 0100 \| 01000), 0666);
4218	if (output < 0) {
4219	fprintf(stderrstderr, "Failed to open output file %s: %s!\n", file_path, libnvme_strerror(errno(*__errno_location ())));
4220	err = output;
4221	goto free_mem;
4222	}
4223
4224	nvme_init_get_log(&cmd, NVME_NSID_ALL, NVME_LOG_LID_TELEMETRY_HOST,
4225	NVME_CSI_NVM, hdr, bs);
4226	cmd.cdw10 \|= NVME_FIELD_ENCODE(NVME_LOG_TELEM_HOST_LSP_CREATE,(((__u32)(NVME_LOG_TELEM_HOST_LSP_CREATE) & (NVME_LOG_CDW10_LSP_MASK )) << (NVME_LOG_CDW10_LSP_SHIFT))
4227	NVME_LOG_CDW10_LSP_SHIFT,(((__u32)(NVME_LOG_TELEM_HOST_LSP_CREATE) & (NVME_LOG_CDW10_LSP_MASK )) << (NVME_LOG_CDW10_LSP_SHIFT))
4228	NVME_LOG_CDW10_LSP_MASK)(((__u32)(NVME_LOG_TELEM_HOST_LSP_CREATE) & (NVME_LOG_CDW10_LSP_MASK )) << (NVME_LOG_CDW10_LSP_SHIFT));
4229	err = libnvme_get_log(hdl, &cmd, true1, NVME_LOG_PAGE_PDU_SIZE4096);
4230	if (err < 0)
4231	perror("get-telemetry-log");
4232	else if (err > 0) {
4233	nvme_show_status(err);
4234	fprintf(stderrstderr, "Failed to acquire telemetry header %d!\n", err);
4235	goto close_output;
4236	}
4237
4238	err = write(output, (void *)hdr, bs);
4239	if (err != bs) {
4240	fprintf(stderrstderr, "Failed to flush all data to file!\n");
4241	goto close_output;
4242	}
4243
4244	full_size = (le16_to_cpu(hdr->dalb3) * bs) + offset;
4245
4246	while (offset != full_size) {
4247	nvme_init_get_log(&cmd, NVME_NSID_ALL, NVME_LOG_LID_TELEMETRY_HOST,
4248	NVME_CSI_NVM, telemetry_log, bs);
4249	nvme_init_get_log_lpo(&cmd, offset);
4250	err = libnvme_get_log(hdl, &cmd, true1, NVME_LOG_PAGE_PDU_SIZE4096);
4251	if (err < 0) {
4252	perror("get-telemetry-log");
4253	break;
4254	} else if (err > 0) {
4255	fprintf(stderrstderr, "Failed to acquire full telemetry log!\n");
4256	nvme_show_status(err);
4257	break;
4258	}
4259
4260	err = write(output, (void *)telemetry_log, bs);
4261	if (err != bs) {
4262	fprintf(stderrstderr, "Failed to flush all data to file!\n");
4263	break;
4264	}
4265	err = 0;
4266	offset += bs;
4267	}
4268
4269	close_output:
4270	close(output);
4271	free_mem:
4272	free(hdr);
4273	free(telemetry_log);
4274
4275	return err;
4276	}
4277
4278	static int wdc_get_default_telemetry_da(struct libnvme_transport_handle *hdl,
4279	int *data_area)
4280	{
4281	struct nvme_id_ctrl ctrl;
4282	int err;
4283
4284	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
4285	err = nvme_identify_ctrl(hdl, &ctrl);
4286	if (err) {
4287	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed 0x%x\n", err);
4288	return err;
4289	}
4290
4291	if (ctrl.lpa & 0x40)
4292	*data_area = 4;
4293	else
4294	*data_area = 3;
4295
4296	return 0;
4297	}
4298
4299	static int wdc_vs_internal_fw_log(int argc, char *argv, struct command acmd,
4300	struct plugin *plugin)
4301	{
4302	const char *desc = "Internal Firmware Log.";
4303	const char *file = "Output file pathname.";
4304	const char *size = "Data retrieval transfer size.";
4305	const char *data_area =
4306	"Data area to retrieve up to. Supported for telemetry, see man page for other use cases.";
4307	const char *type =
4308	"Telemetry type - NONE, HOST, or CONTROLLER:\n" \
4309	" NONE - Default, capture without using NVMe telemetry.\n" \
4310	" HOST - Host-initiated telemetry.\n" \
4311	" CONTROLLER - Controller-initiated telemetry.";
4312	const char *verbose = "Display more debug messages.";
4313	const char *file_size =
4314	"Output file size. Deprecated, see man page for supported devices.";
4315	const char *offset =
4316	"Output file data offset. Deprecated, see man page for supported devices.";
4317	char f[PATH_MAX4096] = {0};
4318	char fb[PATH_MAX4096/2] = {0};
4319	char fileSuffix[PATH_MAX4096] = {0};
4320	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
4321	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
4322	__u32 xfer_size = 0;
4323	int telemetry_type = 0, telemetry_data_area = 0;
4324	UtilsTimeInfo timeInfo;
4325	__u8 timeStamp[MAX_PATH_LEN256];
4326	__u64 capabilities = 0;
4327	__u32 device_id, read_vendor_id;
4328	char file_path[PATH_MAX4096/2] = {0};
4329	char cmd_buf[PATH_MAX4096] = {0};
4330	int ret = -1;
4331
4332	struct config {
4333	char *file;
4334	__u32 xfer_size;
4335	int data_area;
4336	__u64 file_size;
4337	__u64 offset;
4338	char *type;
4339	bool_Bool verbose;
4340	};
4341
4342	struct config cfg = {
4343	.file = NULL((void*)0),
4344	.xfer_size = 0x10000,
4345	.data_area = 0,
4346	.file_size = 0,
4347	.offset = 0,
4348	.type = NULL((void*)0),
4349	.verbose = false0,
4350	};
4351
4352	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4353	OPT_FILE("output-file", 'O', &cfg.file, file),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4354	OPT_UINT("transfer-size", 's', &cfg.xfer_size, size),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4355	OPT_UINT("data-area", 'd', &cfg.data_area, data_area),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4356	OPT_FILE("type", 't', &cfg.type, type),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4357	OPT_FLAG("verbose", 'V', &cfg.verbose, verbose),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4358	OPT_LONG("file-size", 'f', &cfg.file_size, file_size),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4359	OPT_LONG("offset", 'e', &cfg.offset, offset),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4360	OPT_END())struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"data-area", 'd', "NUM", CFG_POSITIVE , &cfg.data_area, 1, data_area, 0, }, {"type", 't', "FILE" , CFG_STRING, &cfg.type, 1, type, 0, }, {"verbose", 'V', ( (void)0), CFG_FLAG, &cfg.verbose, 0, verbose, 0, }, {"file-size" , 'f', "NUM", CFG_LONG, &cfg.file_size, 1, file_size, 0, } , {"offset", 'e', "NUM", CFG_LONG, &cfg.offset, 1, offset , 0, }, { ((void)0) }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
4361
4362	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
4363	if (ret)
4364	return ret;
4365
4366	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
4367	if (ret \|\| !wdc_check_device(ctx, hdl))
4368	goto out;
4369
4370	if (cfg.xfer_size) {
4371	xfer_size = cfg.xfer_size;
4372	} else {
4373	fprintf(stderrstderr, "ERROR: WDC: Invalid length\n");
4374	goto out;
4375	}
4376
4377	ret = wdc_get_pci_ids(ctx, hdl, &device_id, &read_vendor_id);
4378
4379	if (!wdc_is_sn861(device_id)) {
4380	if (cfg.file) {
4381	int verify_file;
4382
4383	/* verify file name and path is valid before getting dump data */
4384	verify_file = nvme_open_rawdata(cfg.file, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((cfg.file), (01 \| 0100 \| 01000), 0666);
4385	if (verify_file < 0) {
4386	fprintf(stderrstderr, "ERROR: WDC: open: %s\n", libnvme_strerror(errno(*__errno_location ())));
4387	goto out;
4388	}
4389	close(verify_file);
4390	strncpy(f, cfg.file, PATH_MAX4096 - 1);
4391	} else {
4392	wdc_UtilsGetTime(&timeInfo);
4393	memset(timeStamp, 0, sizeof(timeStamp));
4394	wdc_UtilsSnprintf((char *)timeStamp, MAX_PATH_LEN256,
4395	"%02u%02u%02u_%02u%02u%02u", timeInfo.year,
4396	timeInfo.month, timeInfo.dayOfMonth,
4397	timeInfo.hour, timeInfo.minute,
4398	timeInfo.second);
4399	snprintf(fileSuffix, PATH_MAX4096, "_internal_fw_log_%s", (char *)timeStamp);
4400
4401	ret = wdc_get_serial_name(hdl, f, PATH_MAX4096, fileSuffix);
4402	if (ret) {
4403	fprintf(stderrstderr, "ERROR: WDC: failed to generate file name\n");
4404	goto out;
4405	}
4406	}
4407
4408	if (!cfg.file) {
4409	if (strlen(f) > PATH_MAX4096 - 5) {
4410	fprintf(stderrstderr, "ERROR: WDC: file name overflow\n");
4411	ret = -1;
4412	goto out;
4413	}
4414	strcat(f, ".bin");
4415	}
4416	fprintf(stderrstderr, "%s: filename = %s\n", __func__, f);
4417
4418	if (cfg.data_area) {
4419	if (cfg.data_area > 5 \|\| cfg.data_area < 1) {
4420	fprintf(stderrstderr, "ERROR: WDC: Data area must be 1-5\n");
4421	ret = -1;
4422	goto out;
4423	}
4424	}
4425
4426	if (!cfg.type \|\| !strcmp(cfg.type, "NONE") \|\| !strcmp(cfg.type, "none")) {
4427	telemetry_type = WDC_TELEMETRY_TYPE_NONE0x0;
4428	data_area = 0;
4429	} else if (!strcmp(cfg.type, "HOST") \|\| !strcmp(cfg.type, "host")) {
4430	telemetry_type = WDC_TELEMETRY_TYPE_HOST0x1;
4431	telemetry_data_area = cfg.data_area;
4432	} else if (!strcmp(cfg.type, "CONTROLLER") \|\| !strcmp(cfg.type, "controller")) {
4433	telemetry_type = WDC_TELEMETRY_TYPE_CONTROLLER0x2;
4434	telemetry_data_area = cfg.data_area;
4435	} else {
4436	fprintf(stderrstderr,
4437	"ERROR: WDC: Invalid type - Must be NONE, HOST or CONTROLLER\n");
4438	ret = -1;
4439	goto out;
4440	}
4441	} else {
4442	if (cfg.file) {
4443	strncpy(fb, cfg.file, PATH_MAX4096/2 - 8);
4444	} else {
4445	wdc_UtilsGetTime(&timeInfo);
4446	memset(timeStamp, 0, sizeof(timeStamp));
4447	wdc_UtilsSnprintf((char *)timeStamp, MAX_PATH_LEN256,
4448	"%02u%02u%02u_%02u%02u%02u", timeInfo.year,
4449	timeInfo.month, timeInfo.dayOfMonth,
4450	timeInfo.hour, timeInfo.minute,
4451	timeInfo.second);
4452	snprintf(fileSuffix, PATH_MAX4096, "_internal_fw_log_%s", (char *)timeStamp);
4453
4454	ret = wdc_get_serial_name(hdl, fb, PATH_MAX4096/2 - 7, fileSuffix);
4455	if (ret) {
4456	fprintf(stderrstderr, "ERROR: WDC: failed to generate file name\n");
4457	goto out;
4458	}
4459
4460	if (strlen(fb) > PATH_MAX4096/2 - 7) {
4461	fprintf(stderrstderr, "ERROR: WDC: file name overflow\n");
4462	ret = -1;
4463	goto out;
4464	}
4465	}
4466	fprintf(stderrstderr, "%s: filename = %s.tar.gz\n", __func__, fb);
4467
4468
4469	memset(file_path, 0, sizeof(file_path));
4470	if (snprintf(file_path, PATH_MAX4096/2 - 8, "%s.tar.gz", fb) >= PATH_MAX4096/2 - 8) {
4471	fprintf(stderrstderr, "File path is too long!\n");
4472	ret = -1;
4473	goto out;
4474	}
4475	if (access(file_path, F_OK0) != -1) {
4476	fprintf(stderrstderr, "Output file already exists!\n");
4477	ret = -EEXIST17;
4478	goto out;
4479	}
4480	}
4481
4482	capabilities = wdc_get_drive_capabilities(ctx, hdl);
4483	if ((capabilities & WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002) == WDC_DRIVE_CAP_INTERNAL_LOG0x0000000000000002) {
4484	if (!wdc_is_sn861(device_id)) {
4485	if (telemetry_type != WDC_TELEMETRY_TYPE_NONE0x0 &&
4486	wdc_get_default_telemetry_da(hdl, &telemetry_data_area)) {
4487	fprintf(stderrstderr, "%s: Error determining default telemetry data area\n",
4488	__func__);
4489	return -EINVAL22;
4490	}
4491
4492	ret = wdc_do_cap_diag(ctx, hdl, f, xfer_size,
4493	telemetry_type, telemetry_data_area);
4494	} else {
4495	if (nvme_args.verbose)
4496	printf("Creating temp directory...\n");
4497
4498	ret = mkdir(fb, 0666);
4499	if (ret) {
4500	fprintf(stderrstderr, "Failed to create directory!\n");
4501	goto out;
4502	}
4503
4504	ret = dump_internal_logs(hdl, fb, nvme_args.verbose);
4505	if (ret < 0)
4506	perror("vs-internal-log");
4507
4508	if (nvme_args.verbose)
4509	printf("Archiving...\n");
4510
4511	if (snprintf(cmd_buf, PATH_MAX4096,
4512	"tar --remove-files -czf %s %s",
4513	file_path, fb) >= PATH_MAX4096) {
4514	fprintf(stderrstderr, "Command buffer is too long!\n");
4515	ret = -1;
4516	goto out;
4517	}
4518
4519	ret = system(cmd_buf);
4520	if (ret)
4521	fprintf(stderrstderr, "Failed to create an archive file!\n");
4522	}
4523	goto out;
4524	}
4525	if ((capabilities & WDC_DRIVE_CAP_DUI0x0000000800000000) == WDC_DRIVE_CAP_DUI0x0000000800000000) {
4526	if ((telemetry_type == WDC_TELEMETRY_TYPE_HOST0x1) \|\|
4527	(telemetry_type == WDC_TELEMETRY_TYPE_CONTROLLER0x2)) {
4528	if (wdc_get_default_telemetry_da(hdl, &telemetry_data_area)) {
4529	fprintf(stderrstderr, "%s: Error determining default telemetry data area\n",
4530	__func__);
4531	return -EINVAL22;
4532	}
4533	/* Get the desired telemetry log page */
4534	ret = wdc_do_cap_telemetry_log(ctx, hdl, f, xfer_size,
4535	telemetry_type, telemetry_data_area);
4536	goto out;
4537	} else {
4538	if (!cfg.data_area)
4539	cfg.data_area = 1;
4540
4541	/* FW requirement - xfer size must be 256k for data area 4 */
4542	if (cfg.data_area >= 4)
4543	xfer_size = 0x40000;
4544	ret = wdc_do_cap_dui(hdl, f, xfer_size,
4545	cfg.data_area,
4546	nvme_args.verbose, cfg.file_size,
4547	cfg.offset);
4548	goto out;
4549	}
4550	}
4551	if ((capabilities & WDC_DRIVE_CAP_DUI_DATA0x0000000200000000) == WDC_DRIVE_CAP_DUI_DATA0x0000000200000000) {
4552	if ((telemetry_type == WDC_TELEMETRY_TYPE_HOST0x1) \|\|
4553	(telemetry_type == WDC_TELEMETRY_TYPE_CONTROLLER0x2)) {
4554	if (wdc_get_default_telemetry_da(hdl, &telemetry_data_area)) {
4555	fprintf(stderrstderr, "%s: Error determining default telemetry data area\n",
4556	__func__);
4557	return -EINVAL22;
4558	}
4559	ret = wdc_do_cap_telemetry_log(ctx, hdl, f, xfer_size,
4560	telemetry_type, telemetry_data_area);
4561	goto out;
4562	} else {
4563	ret = wdc_do_cap_dui(hdl, f, xfer_size,
4564	WDC_NVME_DUI_MAX_DATA_AREA0x05,
4565	nvme_args.verbose, 0, 0);
4566	goto out;
4567	}
4568	}
4569	if ((capabilities & WDC_SN730B_CAP_VUC_LOG0x0000000400000000) == WDC_SN730B_CAP_VUC_LOG0x0000000400000000) {
4570	ret = wdc_do_sn730_get_and_tar(hdl, f);
4571	} else {
4572	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
4573	ret = -1;
4574	}
4575	out:
4576	return ret;
4577	}
4578
4579	static int wdc_do_crash_dump(struct libnvme_transport_handle hdl, char file, int type)
4580	{
4581	int ret;
4582	__u32 crash_dump_length;
4583	__u32 opcode;
4584	__u32 cdw12;
4585	__u32 cdw10_size;
4586	__u32 cdw12_size;
4587	__u32 cdw12_clear;
4588
4589	if (type == WDC_NVME_PFAIL_DUMP_TYPE2) {
4590	/* set parms to get the PFAIL Crash Dump */
4591	opcode = WDC_NVME_PF_CRASH_DUMP_OPCODE0xC6;
4592	cdw10_size = WDC_NVME_PF_CRASH_DUMP_SIZE_NDT0x02;
4593	cdw12_size = ((WDC_NVME_PF_CRASH_DUMP_SIZE_SUBCMD0x05 << WDC_NVME_SUBCMD_SHIFT8) \|
4594	WDC_NVME_PF_CRASH_DUMP_SIZE_CMD0x20);
4595
4596	cdw12 = (WDC_NVME_PF_CRASH_DUMP_SUBCMD0x06 << WDC_NVME_SUBCMD_SHIFT8) \|
4597	WDC_NVME_PF_CRASH_DUMP_CMD0x20;
4598
4599	cdw12_clear = ((WDC_NVME_CLEAR_PF_CRASH_DUMP_SUBCMD0x06 << WDC_NVME_SUBCMD_SHIFT8) \|
4600	WDC_NVME_CLEAR_CRASH_DUMP_CMD0x03);
4601
4602	} else {
4603	/* set parms to get the Crash Dump */
4604	opcode = WDC_NVME_CRASH_DUMP_OPCODE0xC6;
4605	cdw10_size = WDC_NVME_CRASH_DUMP_SIZE_NDT0x02;
4606	cdw12_size = ((WDC_NVME_CRASH_DUMP_SIZE_SUBCMD0x03 << WDC_NVME_SUBCMD_SHIFT8) \|
4607	WDC_NVME_CRASH_DUMP_SIZE_CMD0x20);
4608
4609	cdw12 = (WDC_NVME_CRASH_DUMP_SUBCMD0x04 << WDC_NVME_SUBCMD_SHIFT8) \|
4610	WDC_NVME_CRASH_DUMP_CMD0x20;
4611
4612	cdw12_clear = ((WDC_NVME_CLEAR_CRASH_DUMP_SUBCMD0x05 << WDC_NVME_SUBCMD_SHIFT8) \|
4613	WDC_NVME_CLEAR_CRASH_DUMP_CMD0x03);
4614	}
4615
4616	ret = wdc_dump_length(hdl,
4617	opcode,
4618	cdw10_size,
4619	cdw12_size,
4620	&crash_dump_length);
4621
4622	if (ret == -1) {
4623	if (type == WDC_NVME_PFAIL_DUMP_TYPE2)
4624	fprintf(stderrstderr, "INFO: WDC: Pfail dump get size failed\n");
4625	else
4626	fprintf(stderrstderr, "INFO: WDC: Crash dump get size failed\n");
4627
4628	return -1;
4629	}
4630
4631	if (!crash_dump_length) {
4632	if (type == WDC_NVME_PFAIL_DUMP_TYPE2)
4633	fprintf(stderrstderr, "INFO: WDC: Pfail dump is empty\n");
4634	else
4635	fprintf(stderrstderr, "INFO: WDC: Crash dump is empty\n");
4636	} else {
4637	ret = wdc_do_dump(hdl,
4638	opcode,
4639	crash_dump_length,
4640	cdw12,
4641	file,
4642	crash_dump_length);
4643
4644	if (!ret)
4645	ret = wdc_do_clear_dump(hdl, WDC_NVME_CLEAR_DUMP_OPCODE0xFF,
4646	cdw12_clear);
4647	}
4648	return ret;
4649	}
4650
4651	static int wdc_crash_dump(struct libnvme_transport_handle hdl, const char file, int type)
4652	{
4653	char f[PATH_MAX4096] = {0};
4654	const char *dump_type;
4655	int ret;
4656
4657	if (file)
4658	strncpy(f, file, PATH_MAX4096 - 1);
4659
4660	if (type == WDC_NVME_PFAIL_DUMP_TYPE2)
4661	dump_type = "_pfail_dump";
4662	else
4663	dump_type = "_crash_dump";
4664
4665	ret = wdc_get_serial_name(hdl, f, PATH_MAX4096, dump_type);
4666	if (ret)
4667	fprintf(stderrstderr, "ERROR: WDC: failed to generate file name\n");
4668	else
4669	ret = wdc_do_crash_dump(hdl, f, type);
4670	return ret;
4671	}
4672
4673	static int wdc_do_drive_log(struct libnvme_transport_handle hdl, const char file)
4674	{
4675	int ret;
4676	__u8 *drive_log_data;
4677	__u32 drive_log_length;
4678	struct libnvme_passthru_cmd admin_cmd;
4679
4680	ret = wdc_dump_length(hdl, WDC_NVME_DRIVE_LOG_SIZE_OPCODE0xC6,
4681	WDC_NVME_DRIVE_LOG_SIZE_NDT0x02,
4682	(WDC_NVME_DRIVE_LOG_SIZE_SUBCMD0x01 <<
4683	WDC_NVME_SUBCMD_SHIFT8 \| WDC_NVME_DRIVE_LOG_SIZE_CMD0x20),
4684	&drive_log_length);
4685	if (ret == -1)
4686	return -1;
4687
4688	drive_log_data = (__u8 )malloc(sizeof(__u8) drive_log_length);
4689	if (!drive_log_data) {
4690	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
4691	return -1;
4692	}
4693
4694	memset(drive_log_data, 0, sizeof(__u8) * drive_log_length);
4695	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
4696	admin_cmd.opcode = WDC_NVME_DRIVE_LOG_OPCODE0xC6;
4697	admin_cmd.addr = (__u64)(uintptr_t)drive_log_data;
4698	admin_cmd.data_len = drive_log_length;
4699	admin_cmd.cdw10 = drive_log_length;
4700	admin_cmd.cdw12 = ((WDC_NVME_DRIVE_LOG_SUBCMD0x00 <<
4701	WDC_NVME_SUBCMD_SHIFT8) \| WDC_NVME_DRIVE_LOG_SIZE_CMD0x20);
4702
4703	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
4704	nvme_show_status(ret);
4705	if (!ret)
4706	ret = wdc_create_log_file(file, drive_log_data, drive_log_length);
4707	free(drive_log_data);
4708	return ret;
4709	}
4710
4711	static int wdc_drive_log(int argc, char *argv, struct command acmd,
4712	struct plugin *plugin)
4713	{
4714	const char *desc = "Capture Drive Log.";
4715	const char *file = "Output file pathname.";
4716	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
4717	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
4718	char f[PATH_MAX4096] = {0};
4719	int ret;
4720	__u64 capabilities = 0;
4721	struct config {
4722	char *file;
4723	};
4724
4725	struct config cfg = {
4726	.file = NULL((void*)0)
4727	};
4728
4729	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void )0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM" , CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4730	OPT_FILE("output-file", 'O', &cfg.file, file))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void )0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM" , CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
4731
4732	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
4733	if (ret)
4734	return ret;
4735
4736	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
4737	if (ret \|\| !wdc_check_device(ctx, hdl))
4738	return ret;
4739
4740	capabilities = wdc_get_drive_capabilities(ctx, hdl);
4741
4742	if (!(capabilities & WDC_DRIVE_CAP_DRIVE_LOG0x0000000000000400)) {
4743	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
4744	ret = -1;
4745	} else {
4746	if (cfg.file)
4747	strncpy(f, cfg.file, PATH_MAX4096 - 1);
4748	ret = wdc_get_serial_name(hdl, f, PATH_MAX4096, "drive_log");
4749	if (ret)
4750	fprintf(stderrstderr, "ERROR: WDC: failed to generate file name\n");
4751	else
4752	ret = wdc_do_drive_log(hdl, f);
4753	}
4754	return ret;
4755	}
4756
4757	static int wdc_get_crash_dump(int argc, char *argv, struct command acmd,
4758	struct plugin *plugin)
4759	{
4760	const char *desc = "Get Crash Dump.";
4761	const char *file = "Output file pathname.";
4762	__u64 capabilities = 0;
4763	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
4764	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
4765	int ret;
4766
4767	struct config {
4768	char *file;
4769	};
4770
4771	struct config cfg = {
4772	.file = NULL((void*)0),
4773	};
4774
4775	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void )0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM" , CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4776	OPT_FILE("output-file", 'O', &cfg.file, file))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void )0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM" , CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
4777
4778	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
4779	if (ret)
4780	return ret;
4781
4782	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
4783	if (ret \|\| !wdc_check_device(ctx, hdl))
4784	return ret;
4785
4786	capabilities = wdc_get_drive_capabilities(ctx, hdl);
4787
4788	if (!(capabilities & WDC_DRIVE_CAP_CRASH_DUMP0x0000000000000800)) {
4789	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
4790	ret = -1;
4791	} else {
4792	ret = wdc_crash_dump(hdl, cfg.file, WDC_NVME_CRASH_DUMP_TYPE1);
4793	if (ret)
4794	fprintf(stderrstderr, "ERROR: WDC: failed to read crash dump\n");
4795	}
4796	return ret;
4797	}
4798
4799	static int wdc_get_pfail_dump(int argc, char *argv, struct command acmd,
4800	struct plugin *plugin)
4801	{
4802	const char *desc = "Get Pfail Crash Dump.";
4803	const char *file = "Output file pathname.";
4804	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
4805	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
4806	__u64 capabilities = 0;
4807	struct config {
4808	char *file;
4809	};
4810	int ret;
4811
4812	struct config cfg = {
4813	.file = NULL((void*)0),
4814	};
4815
4816	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void )0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM" , CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
4817	OPT_FILE("output-file", 'O', &cfg.file, file))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void )0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM" , CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
4818
4819	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
4820	if (ret)
4821	return ret;
4822
4823	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
4824	if (ret \|\| !wdc_check_device(ctx, hdl))
4825	return ret;
4826
4827	capabilities = wdc_get_drive_capabilities(ctx, hdl);
4828	if (!(capabilities & WDC_DRIVE_CAP_PFAIL_DUMP0x0000000000001000)) {
4829	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
4830	ret = -1;
4831	} else {
4832	ret = wdc_crash_dump(hdl, cfg.file, WDC_NVME_PFAIL_DUMP_TYPE2);
4833	if (ret)
4834	fprintf(stderrstderr, "ERROR: WDC: failed to read pfail crash dump\n");
4835	}
4836	return ret;
4837	}
4838
4839	static void wdc_do_id_ctrl(__u8 vs, struct json_object root)
4840	{
4841	char vsn[24] = {0};
4842	int base = 3072;
4843	int vsn_start = 3081;
4844
4845	memcpy(vsn, &vs[vsn_start - base], sizeof(vsn));
4846	if (root)
4847	json_object_add_value_string(root, "wdc vsn", strlen(vsn) > 1 ? vsn : "NULL");
4848	else
4849	printf("wdc vsn: %s\n", strlen(vsn) > 1 ? vsn : "NULL");
4850	}
4851
4852	static int wdc_id_ctrl(int argc, char *argv, struct command acmd, struct plugin *plugin)
4853	{
4854	return __id_ctrl(argc, argv, acmd, plugin, wdc_do_id_ctrl);
4855	}
4856
4857	static const char *wdc_purge_mon_status_to_string(__u32 status)
4858	{
4859	const char *str;
4860
4861	switch (status) {
4862	case WDC_NVME_PURGE_STATE_IDLE0x00:
4863	str = "Purge State Idle.";
4864	break;
4865	case WDC_NVME_PURGE_STATE_DONE0x01:
4866	str = "Purge State Done.";
4867	break;
4868	case WDC_NVME_PURGE_STATE_BUSY0x02:
4869	str = "Purge State Busy.";
4870	break;
4871	case WDC_NVME_PURGE_STATE_REQ_PWR_CYC0x03:
4872	str = "Purge Operation resulted in an error that requires power cycle.";
4873	break;
4874	case WDC_NVME_PURGE_STATE_PWR_CYC_PURGE0x04:
4875	str = "The previous purge operation was interrupted by a power cycle\n"
4876	"or reset interruption. Other commands may be rejected until\n"
4877	"Purge Execute is issued and completed.";
4878	break;
4879	default:
4880	str = "Unknown.";
4881	}
4882	return str;
4883	}
4884
4885	static int wdc_purge(int argc, char **argv,
4886	struct command command, struct plugin plugin)
4887	{
4888	const char *desc = "Send a Purge command.";
4889	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
4890	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
4891	struct libnvme_passthru_cmd admin_cmd;
4892	__u64 capabilities = 0;
4893	char *err_str;
4894	int ret;
4895
4896	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
4897
4898	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
4899	if (ret)
4900	return ret;
4901
4902	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
4903	if (ret \|\| !wdc_check_device(ctx, hdl))
4904	return ret;
4905
4906	capabilities = wdc_get_drive_capabilities(ctx, hdl);
4907	if (!(capabilities & WDC_DRIVE_CAP_PURGE0x0000001000000000)) {
4908	ret = -1;
4909	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
4910	} else {
4911	err_str = "";
4912	memset(&admin_cmd, 0, sizeof(admin_cmd));
4913	admin_cmd.opcode = WDC_NVME_PURGE_CMD_OPCODE0xDD;
4914
4915	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
4916	if (ret > 0) {
4917	switch (ret) {
4918	case WDC_NVME_PURGE_CMD_SEQ_ERR0x0C:
4919	err_str = "ERROR: WDC: Cannot execute purge, Purge operation is in progress.\n";
4920	break;
4921	case WDC_NVME_PURGE_INT_DEV_ERR0x06:
4922	err_str = "ERROR: WDC: Internal Device Error.\n";
4923	break;
4924	default:
4925	err_str = "ERROR: WDC\n";
4926	}
4927	}
4928
4929	fprintf(stderrstderr, "%s", err_str);
4930	nvme_show_status(ret);
4931	}
4932	return ret;
4933	}
4934
4935	static int wdc_purge_monitor(int argc, char **argv,
4936	struct command command, struct plugin plugin)
4937	{
4938	const char *desc = "Send a Purge Monitor command.";
4939	__u8 output[WDC_NVME_PURGE_MONITOR_DATA_LEN0x2F];
4940	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
4941	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
4942	double progress_percent;
4943	struct libnvme_passthru_cmd admin_cmd;
4944	struct wdc_nvme_purge_monitor_data *mon;
4945	__u64 capabilities;
4946	int ret;
4947
4948	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
4949
4950	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
4951	if (ret)
4952	return ret;
4953
4954	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
4955	if (ret \|\| !wdc_check_device(ctx, hdl))
4956	return ret;
4957
4958	capabilities = wdc_get_drive_capabilities(ctx, hdl);
4959	if (!(capabilities & WDC_DRIVE_CAP_PURGE0x0000001000000000)) {
4960	ret = -1;
4961	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
4962	} else {
4963	memset(output, 0, sizeof(output));
4964	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
4965	admin_cmd.opcode = WDC_NVME_PURGE_MONITOR_OPCODE0xDE;
4966	admin_cmd.addr = (__u64)(uintptr_t)output;
4967	admin_cmd.data_len = WDC_NVME_PURGE_MONITOR_DATA_LEN0x2F;
4968	admin_cmd.cdw10 = WDC_NVME_PURGE_MONITOR_CMD_CDW100x0000000C;
4969	admin_cmd.timeout_ms = WDC_NVME_PURGE_MONITOR_TIMEOUT0x7530;
4970
4971	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
4972	if (!ret) {
4973	mon = (struct wdc_nvme_purge_monitor_data *) output;
4974	printf("Purge state = 0x%0"PRIx64"l" "x""\n",
4975	(uint64_t)admin_cmd.result);
4976	printf("%s\n", wdc_purge_mon_status_to_string(admin_cmd.result));
4977	if (admin_cmd.result == WDC_NVME_PURGE_STATE_BUSY0x02) {
4978	progress_percent =
4979	((double)le32_to_cpu(mon->entire_progress_current) * 100) /
4980	le32_to_cpu(mon->entire_progress_total);
4981	printf("Purge Progress = %f%%\n", progress_percent);
4982	}
4983	}
4984
4985	nvme_show_status(ret);
4986	}
4987	return ret;
4988	}
4989
4990	static void wdc_print_log_normal(struct wdc_ssd_perf_stats *perf)
4991	{
4992	printf(" C1 Log Page Performance Statistics :-\n");
4993	printf(" Host Read Commands %20"PRIu64"l" "u""\n",
4994	le64_to_cpu(perf->hr_cmds));
4995	printf(" Host Read Blocks %20"PRIu64"l" "u""\n",
4996	le64_to_cpu(perf->hr_blks));
4997	printf(" Average Read Size %20lf\n",
4998	safe_div_fp((le64_to_cpu(perf->hr_blks)), (le64_to_cpu(perf->hr_cmds))));
4999	printf(" Host Read Cache Hit Commands %20"PRIu64"l" "u""\n",
5000	le64_to_cpu(perf->hr_ch_cmds));
5001	printf(" Host Read Cache Hit_Percentage %20"PRIu64"l" "u""%%\n",
5002	(uint64_t) calc_percent(le64_to_cpu(perf->hr_ch_cmds), le64_to_cpu(perf->hr_cmds)));
5003	printf(" Host Read Cache Hit Blocks %20"PRIu64"l" "u""\n",
5004	le64_to_cpu(perf->hr_ch_blks));
5005	printf(" Average Read Cache Hit Size %20f\n",
5006	safe_div_fp((le64_to_cpu(perf->hr_ch_blks)), (le64_to_cpu(perf->hr_ch_cmds))));
5007	printf(" Host Read Commands Stalled %20"PRIu64"l" "u""\n",
5008	le64_to_cpu(perf->hr_st_cmds));
5009	printf(" Host Read Commands Stalled Percentage %20"PRIu64"l" "u""%%\n",
5010	(uint64_t)calc_percent((le64_to_cpu(perf->hr_st_cmds)), le64_to_cpu(perf->hr_cmds)));
5011	printf(" Host Write Commands %20"PRIu64"l" "u""\n",
5012	le64_to_cpu(perf->hw_cmds));
5013	printf(" Host Write Blocks %20"PRIu64"l" "u""\n",
5014	le64_to_cpu(perf->hw_blks));
5015	printf(" Average Write Size %20f\n",
5016	safe_div_fp((le64_to_cpu(perf->hw_blks)), (le64_to_cpu(perf->hw_cmds))));
5017	printf(" Host Write Odd Start Commands %20"PRIu64"l" "u""\n",
5018	le64_to_cpu(perf->hw_os_cmds));
5019	printf(" Host Write Odd Start Commands Percentage %20"PRIu64"l" "u""%%\n",
5020	(uint64_t)calc_percent((le64_to_cpu(perf->hw_os_cmds)), (le64_to_cpu(perf->hw_cmds))));
5021	printf(" Host Write Odd End Commands %20"PRIu64"l" "u""\n",
5022	le64_to_cpu(perf->hw_oe_cmds));
5023	printf(" Host Write Odd End Commands Percentage %20"PRIu64"l" "u""%%\n",
5024	(uint64_t)calc_percent((le64_to_cpu(perf->hw_oe_cmds)), (le64_to_cpu((perf->hw_cmds)))));
5025	printf(" Host Write Commands Stalled %20"PRIu64"l" "u""\n",
5026	le64_to_cpu(perf->hw_st_cmds));
5027	printf(" Host Write Commands Stalled Percentage %20"PRIu64"l" "u""%%\n",
5028	(uint64_t)calc_percent((le64_to_cpu(perf->hw_st_cmds)), (le64_to_cpu(perf->hw_cmds))));
5029	printf(" NAND Read Commands %20"PRIu64"l" "u""\n",
5030	le64_to_cpu(perf->nr_cmds));
5031	printf(" NAND Read Blocks Commands %20"PRIu64"l" "u""\n",
5032	le64_to_cpu(perf->nr_blks));
5033	printf(" Average NAND Read Size %20f\n",
5034	safe_div_fp((le64_to_cpu(perf->nr_blks)), (le64_to_cpu((perf->nr_cmds)))));
5035	printf(" Nand Write Commands %20"PRIu64"l" "u""\n",
5036	le64_to_cpu(perf->nw_cmds));
5037	printf(" NAND Write Blocks %20"PRIu64"l" "u""\n",
5038	le64_to_cpu(perf->nw_blks));
5039	printf(" Average NAND Write Size %20f\n",
5040	safe_div_fp((le64_to_cpu(perf->nw_blks)), (le64_to_cpu(perf->nw_cmds))));
5041	printf(" NAND Read Before Write %20"PRIu64"l" "u""\n",
5042	le64_to_cpu(perf->nrbw));
5043	}
5044
5045	static void wdc_print_log_json(struct wdc_ssd_perf_stats *perf)
5046	{
5047	struct json_object *root = json_create_object()json_object_new_object();
5048
5049	json_object_add_value_int(root, "Host Read Commands", le64_to_cpu(perf->hr_cmds))json_object_object_add(root, "Host Read Commands", json_object_new_int (le64_to_cpu(perf->hr_cmds)));
5050	json_object_add_value_int(root, "Host Read Blocks", le64_to_cpu(perf->hr_blks))json_object_object_add(root, "Host Read Blocks", json_object_new_int (le64_to_cpu(perf->hr_blks)));
5051	json_object_add_value_int(root, "Average Read Size",json_object_object_add(root, "Average Read Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->hr_blks)), (le64_to_cpu(perf ->hr_cmds)))))
5052	safe_div_fp((le64_to_cpu(perf->hr_blks)), (le64_to_cpu(perf->hr_cmds))))json_object_object_add(root, "Average Read Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->hr_blks)), (le64_to_cpu(perf ->hr_cmds)))));
5053	json_object_add_value_int(root, "Host Read Cache Hit Commands",json_object_object_add(root, "Host Read Cache Hit Commands", json_object_new_int (le64_to_cpu(perf->hr_ch_cmds)))
5054	le64_to_cpu(perf->hr_ch_cmds))json_object_object_add(root, "Host Read Cache Hit Commands", json_object_new_int (le64_to_cpu(perf->hr_ch_cmds)));
5055	json_object_add_value_int(root, "Host Read Cache Hit Percentage",json_object_object_add(root, "Host Read Cache Hit Percentage" , json_object_new_int((uint64_t) calc_percent(le64_to_cpu(perf ->hr_ch_cmds), le64_to_cpu(perf->hr_cmds))))
5056	(uint64_t) calc_percent(le64_to_cpu(perf->hr_ch_cmds), le64_to_cpu(perf->hr_cmds)))json_object_object_add(root, "Host Read Cache Hit Percentage" , json_object_new_int((uint64_t) calc_percent(le64_to_cpu(perf ->hr_ch_cmds), le64_to_cpu(perf->hr_cmds))));
5057	json_object_add_value_int(root, "Host Read Cache Hit Blocks",json_object_object_add(root, "Host Read Cache Hit Blocks", json_object_new_int (le64_to_cpu(perf->hr_ch_blks)))
5058	le64_to_cpu(perf->hr_ch_blks))json_object_object_add(root, "Host Read Cache Hit Blocks", json_object_new_int (le64_to_cpu(perf->hr_ch_blks)));
5059	json_object_add_value_int(root, "Average Read Cache Hit Size",json_object_object_add(root, "Average Read Cache Hit Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->hr_ch_blks)), (le64_to_cpu (perf->hr_ch_cmds)))))
5060	safe_div_fp((le64_to_cpu(perf->hr_ch_blks)), (le64_to_cpu(perf->hr_ch_cmds))))json_object_object_add(root, "Average Read Cache Hit Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->hr_ch_blks)), (le64_to_cpu (perf->hr_ch_cmds)))));
5061	json_object_add_value_int(root, "Host Read Commands Stalled",json_object_object_add(root, "Host Read Commands Stalled", json_object_new_int (le64_to_cpu(perf->hr_st_cmds)))
5062	le64_to_cpu(perf->hr_st_cmds))json_object_object_add(root, "Host Read Commands Stalled", json_object_new_int (le64_to_cpu(perf->hr_st_cmds)));
5063	json_object_add_value_int(root, "Host Read Commands Stalled Percentage",json_object_object_add(root, "Host Read Commands Stalled Percentage" , json_object_new_int((uint64_t)calc_percent((le64_to_cpu(perf ->hr_st_cmds)), le64_to_cpu(perf->hr_cmds))))
5064	(uint64_t)calc_percent((le64_to_cpu(perf->hr_st_cmds)), le64_to_cpu(perf->hr_cmds)))json_object_object_add(root, "Host Read Commands Stalled Percentage" , json_object_new_int((uint64_t)calc_percent((le64_to_cpu(perf ->hr_st_cmds)), le64_to_cpu(perf->hr_cmds))));
5065	json_object_add_value_int(root, "Host Write Commands",json_object_object_add(root, "Host Write Commands", json_object_new_int (le64_to_cpu(perf->hw_cmds)))
5066	le64_to_cpu(perf->hw_cmds))json_object_object_add(root, "Host Write Commands", json_object_new_int (le64_to_cpu(perf->hw_cmds)));
5067	json_object_add_value_int(root, "Host Write Blocks",json_object_object_add(root, "Host Write Blocks", json_object_new_int (le64_to_cpu(perf->hw_blks)))
5068	le64_to_cpu(perf->hw_blks))json_object_object_add(root, "Host Write Blocks", json_object_new_int (le64_to_cpu(perf->hw_blks)));
5069	json_object_add_value_int(root, "Average Write Size",json_object_object_add(root, "Average Write Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->hw_blks)), (le64_to_cpu(perf ->hw_cmds)))))
5070	safe_div_fp((le64_to_cpu(perf->hw_blks)), (le64_to_cpu(perf->hw_cmds))))json_object_object_add(root, "Average Write Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->hw_blks)), (le64_to_cpu(perf ->hw_cmds)))));
5071	json_object_add_value_int(root, "Host Write Odd Start Commands",json_object_object_add(root, "Host Write Odd Start Commands", json_object_new_int(le64_to_cpu(perf->hw_os_cmds)))
5072	le64_to_cpu(perf->hw_os_cmds))json_object_object_add(root, "Host Write Odd Start Commands", json_object_new_int(le64_to_cpu(perf->hw_os_cmds)));
5073	json_object_add_value_int(root, "Host Write Odd Start Commands Percentage",json_object_object_add(root, "Host Write Odd Start Commands Percentage" , json_object_new_int((uint64_t)calc_percent((le64_to_cpu(perf ->hw_os_cmds)), (le64_to_cpu(perf->hw_cmds)))))
5074	(uint64_t)calc_percent((le64_to_cpu(perf->hw_os_cmds)), (le64_to_cpu(perf->hw_cmds))))json_object_object_add(root, "Host Write Odd Start Commands Percentage" , json_object_new_int((uint64_t)calc_percent((le64_to_cpu(perf ->hw_os_cmds)), (le64_to_cpu(perf->hw_cmds)))));
5075	json_object_add_value_int(root, "Host Write Odd End Commands",json_object_object_add(root, "Host Write Odd End Commands", json_object_new_int (le64_to_cpu(perf->hw_oe_cmds)))
5076	le64_to_cpu(perf->hw_oe_cmds))json_object_object_add(root, "Host Write Odd End Commands", json_object_new_int (le64_to_cpu(perf->hw_oe_cmds)));
5077	json_object_add_value_int(root, "Host Write Odd End Commands Percentage",json_object_object_add(root, "Host Write Odd End Commands Percentage" , json_object_new_int((uint64_t)calc_percent((le64_to_cpu(perf ->hw_oe_cmds)), (le64_to_cpu((perf->hw_cmds))))))
5078	(uint64_t)calc_percent((le64_to_cpu(perf->hw_oe_cmds)), (le64_to_cpu((perf->hw_cmds)))))json_object_object_add(root, "Host Write Odd End Commands Percentage" , json_object_new_int((uint64_t)calc_percent((le64_to_cpu(perf ->hw_oe_cmds)), (le64_to_cpu((perf->hw_cmds))))));
5079	json_object_add_value_int(root, "Host Write Commands Stalled",json_object_object_add(root, "Host Write Commands Stalled", json_object_new_int (le64_to_cpu(perf->hw_st_cmds)))
5080	le64_to_cpu(perf->hw_st_cmds))json_object_object_add(root, "Host Write Commands Stalled", json_object_new_int (le64_to_cpu(perf->hw_st_cmds)));
5081	json_object_add_value_int(root, "Host Write Commands Stalled Percentage",json_object_object_add(root, "Host Write Commands Stalled Percentage" , json_object_new_int((uint64_t)calc_percent((le64_to_cpu(perf ->hw_st_cmds)), (le64_to_cpu(perf->hw_cmds)))))
5082	(uint64_t)calc_percent((le64_to_cpu(perf->hw_st_cmds)), (le64_to_cpu(perf->hw_cmds))))json_object_object_add(root, "Host Write Commands Stalled Percentage" , json_object_new_int((uint64_t)calc_percent((le64_to_cpu(perf ->hw_st_cmds)), (le64_to_cpu(perf->hw_cmds)))));
5083	json_object_add_value_int(root, "NAND Read Commands",json_object_object_add(root, "NAND Read Commands", json_object_new_int (le64_to_cpu(perf->nr_cmds)))
5084	le64_to_cpu(perf->nr_cmds))json_object_object_add(root, "NAND Read Commands", json_object_new_int (le64_to_cpu(perf->nr_cmds)));
5085	json_object_add_value_int(root, "NAND Read Blocks Commands",json_object_object_add(root, "NAND Read Blocks Commands", json_object_new_int (le64_to_cpu(perf->nr_blks)))
5086	le64_to_cpu(perf->nr_blks))json_object_object_add(root, "NAND Read Blocks Commands", json_object_new_int (le64_to_cpu(perf->nr_blks)));
5087	json_object_add_value_int(root, "Average NAND Read Size",json_object_object_add(root, "Average NAND Read Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->nr_blks)), (le64_to_cpu((perf ->nr_cmds))))))
5088	safe_div_fp((le64_to_cpu(perf->nr_blks)), (le64_to_cpu((perf->nr_cmds)))))json_object_object_add(root, "Average NAND Read Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->nr_blks)), (le64_to_cpu((perf ->nr_cmds))))));
5089	json_object_add_value_int(root, "Nand Write Commands",json_object_object_add(root, "Nand Write Commands", json_object_new_int (le64_to_cpu(perf->nw_cmds)))
5090	le64_to_cpu(perf->nw_cmds))json_object_object_add(root, "Nand Write Commands", json_object_new_int (le64_to_cpu(perf->nw_cmds)));
5091	json_object_add_value_int(root, "NAND Write Blocks",json_object_object_add(root, "NAND Write Blocks", json_object_new_int (le64_to_cpu(perf->nw_blks)))
5092	le64_to_cpu(perf->nw_blks))json_object_object_add(root, "NAND Write Blocks", json_object_new_int (le64_to_cpu(perf->nw_blks)));
5093	json_object_add_value_int(root, "Average NAND Write Size",json_object_object_add(root, "Average NAND Write Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->nw_blks)), (le64_to_cpu(perf ->nw_cmds)))))
5094	safe_div_fp((le64_to_cpu(perf->nw_blks)), (le64_to_cpu(perf->nw_cmds))))json_object_object_add(root, "Average NAND Write Size", json_object_new_int (safe_div_fp((le64_to_cpu(perf->nw_blks)), (le64_to_cpu(perf ->nw_cmds)))));
5095	json_object_add_value_int(root, "NAND Read Before Written",json_object_object_add(root, "NAND Read Before Written", json_object_new_int (le64_to_cpu(perf->nrbw)))
5096	le64_to_cpu(perf->nrbw))json_object_object_add(root, "NAND Read Before Written", json_object_new_int (le64_to_cpu(perf->nrbw)));
5097	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
5098	printf("\n");
5099	json_free_object(root)json_object_put(root);
5100	}
5101
5102	static int wdc_print_log(struct wdc_ssd_perf_stats *perf, int fmt)
5103	{
5104	if (!perf) {
5105	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read perf stats\n");
5106	return -1;
5107	}
5108	switch (fmt) {
5109	case NORMAL:
5110	wdc_print_log_normal(perf);
5111	break;
5112	case JSON:
5113	wdc_print_log_json(perf);
5114	break;
5115	}
5116	return 0;
5117	}
5118
5119	static int wdc_print_latency_monitor_log_normal(struct libnvme_transport_handle *hdl,
5120	struct wdc_ssd_latency_monitor_log *log_data)
5121	{
5122	printf("Latency Monitor/C3 Log Page Data\n");
5123	printf(" Controller : %s\n", libnvme_transport_handle_get_name(hdl));
5124	int err = -1, i, j;
5125	struct nvme_id_ctrl ctrl;
5126	char ts_buf[128];
5127
5128	err = nvme_identify_ctrl(hdl, &ctrl);
5129	if (!err) {
5130	printf(" Serial Number: %-.*s\n", (int)sizeof(ctrl.sn), ctrl.sn);
5131	} else {
5132	fprintf(stderrstderr, "ERROR: WDC: latency monitor read id ctrl failure, err = %d\n", err);
5133	return err;
5134	}
5135
5136	printf(" Feature Status 0x%x\n", log_data->feature_status);
5137	printf(" Active Bucket Timer %d min\n", 5*le16_to_cpu(log_data->active_bucket_timer));
5138	printf(" Active Bucket Timer Threshold %d min\n", 5*le16_to_cpu(log_data->active_bucket_timer_threshold));
5139	printf(" Active Threshold A %d ms\n", 5*(le16_to_cpu(log_data->active_threshold_a+1)));
5140	printf(" Active Threshold B %d ms\n", 5*(le16_to_cpu(log_data->active_threshold_b+1)));
5141	printf(" Active Threshold C %d ms\n", 5*(le16_to_cpu(log_data->active_threshold_c+1)));
5142	printf(" Active Threshold D %d ms\n", 5*(le16_to_cpu(log_data->active_threshold_d+1)));
5143	printf(" Active Latency Config 0x%x\n", le16_to_cpu(log_data->active_latency_config));
5144	printf(" Active Latency Minimum Window %d ms\n", 100*log_data->active_latency_min_window);
5145	printf(" Active Latency Stamp Units %d\n", le16_to_cpu(log_data->active_latency_stamp_units));
5146	printf(" Static Latency Stamp Units %d\n", le16_to_cpu(log_data->static_latency_stamp_units));
5147	if (le16_to_cpu(log_data->log_page_version) >= 4)
5148	printf(" Debug Telemetry Log Size %"PRIu64"l" "u""\n",
5149	le64_to_cpu((uint64_t )log_data->debug_telemetry_log_size));
5150	printf(" Debug Log Trigger Enable %d\n",
5151	le16_to_cpu(log_data->debug_log_trigger_enable));
5152	printf(" Log Page Version %d\n",
5153	le16_to_cpu(log_data->log_page_version));
5154	printf(" Log page GUID 0x");
5155	for (j = 0; j < WDC_C3_GUID_LENGTH16; j++)
5156	printf("%x", log_data->log_page_guid[j]);
5157	printf("\n");
5158
5159	printf(" Read Write Deallocate/Trim\n");
5160	for (i = 0; i <= 3; i++)
5161	printf(" Active Bucket Counter: Bucket %d %27d %27d %27d\n",
5162	i, le32_to_cpu(log_data->active_bucket_counter[i][WDC_LATENCY_LOG_BUCKET_READ3]),
5163	le32_to_cpu(log_data->active_bucket_counter[i][WDC_LATENCY_LOG_BUCKET_WRITE2]),
5164	le32_to_cpu(log_data->active_bucket_counter[i][WDC_LATENCY_LOG_BUCKET_TRIM1]));
5165
5166	for (i = 3; i >= 0; i--)
5167	printf(" Active Measured Latency: Bucket %d %27d ms %27d ms %27d ms\n",
5168	3-i, le16_to_cpu(log_data->active_measured_latency[i][WDC_LATENCY_LOG_MEASURED_LAT_READ2]),
5169	le16_to_cpu(log_data->active_measured_latency[i][WDC_LATENCY_LOG_MEASURED_LAT_WRITE1]),
5170	le16_to_cpu(log_data->active_measured_latency[i][WDC_LATENCY_LOG_MEASURED_LAT_TRIM0]));
5171
5172	for (i = 3; i >= 0; i--) {
5173	printf(" Active Latency Time Stamp: Bucket %d ", 3-i);
5174	for (j = 2; j >= 0; j--) {
5175	if (le64_to_cpu(log_data->active_latency_timestamp[i][j]) == -1) {
5176	printf(" N/A ");
5177	} else {
5178	convert_ts(le64_to_cpu(log_data->active_latency_timestamp[i][j]), ts_buf);
5179	printf("%s ", ts_buf);
5180	}
5181	}
5182	printf("\n");
5183	}
5184
5185	for (i = 0; i <= 3; i++)
5186	printf(" Static Bucket Counter: Bucket %d %27d %27d %27d\n",
5187	i, le32_to_cpu(log_data->static_bucket_counter[i][WDC_LATENCY_LOG_BUCKET_READ3]),
5188	le32_to_cpu(log_data->static_bucket_counter[i][WDC_LATENCY_LOG_BUCKET_WRITE2]),
5189	le32_to_cpu(log_data->static_bucket_counter[i][WDC_LATENCY_LOG_BUCKET_TRIM1]));
5190
5191	for (i = 3; i >= 0; i--)
5192	printf(" Static Measured Latency: Bucket %d %27d ms %27d ms %27d ms\n",
5193	3-i, le16_to_cpu(log_data->static_measured_latency[i][WDC_LATENCY_LOG_MEASURED_LAT_READ2]),
5194	le16_to_cpu(log_data->static_measured_latency[i][WDC_LATENCY_LOG_MEASURED_LAT_WRITE1]),
5195	le16_to_cpu(log_data->static_measured_latency[i][WDC_LATENCY_LOG_MEASURED_LAT_TRIM0]));
5196
5197	for (i = 3; i >= 0; i--) {
5198	printf(" Static Latency Time Stamp: Bucket %d ", 3-i);
5199	for (j = 2; j >= 0; j--) {
5200	if (le64_to_cpu(log_data->static_latency_timestamp[i][j]) == -1) {
5201	printf(" N/A ");
5202	} else {
5203	convert_ts(le64_to_cpu(log_data->static_latency_timestamp[i][j]), ts_buf);
5204	printf("%s ", ts_buf);
5205	}
5206	}
5207	printf("\n");
5208	}
5209
5210	return 0;
5211	}
5212
5213	static void wdc_print_latency_monitor_log_json(struct wdc_ssd_latency_monitor_log *log_data)
5214	{
5215	int i, j;
5216	char buf[128];
5217	const char *operation[3] = {"Read", "Write", "Trim"};
5218	struct json_object *root = json_create_object()json_object_new_object();
5219
5220	json_object_add_value_int(root, "Feature Status", log_data->feature_status)json_object_object_add(root, "Feature Status", json_object_new_int (log_data->feature_status));
5221	json_object_add_value_int(root, "Active Bucket Timer", 5le16_to_cpu(log_data->active_bucket_timer))json_object_object_add(root, "Active Bucket Timer", json_object_new_int (5le16_to_cpu(log_data->active_bucket_timer)));
5222	json_object_add_value_int(root, "Active Bucket Timer Threshold", 5le16_to_cpu(log_data->active_bucket_timer_threshold))json_object_object_add(root, "Active Bucket Timer Threshold", json_object_new_int(5le16_to_cpu(log_data->active_bucket_timer_threshold )));
5223	json_object_add_value_int(root, "Active Threshold A", 5le16_to_cpu(log_data->active_threshold_a+1))json_object_object_add(root, "Active Threshold A", json_object_new_int (5le16_to_cpu(log_data->active_threshold_a+1)));
5224	json_object_add_value_int(root, "Active Threshold B", 5le16_to_cpu(log_data->active_threshold_b+1))json_object_object_add(root, "Active Threshold B", json_object_new_int (5le16_to_cpu(log_data->active_threshold_b+1)));
5225	json_object_add_value_int(root, "Active Threshold C", 5le16_to_cpu(log_data->active_threshold_c+1))json_object_object_add(root, "Active Threshold C", json_object_new_int (5le16_to_cpu(log_data->active_threshold_c+1)));
5226	json_object_add_value_int(root, "Active Threshold D", 5le16_to_cpu(log_data->active_threshold_d+1))json_object_object_add(root, "Active Threshold D", json_object_new_int (5le16_to_cpu(log_data->active_threshold_d+1)));
5227	json_object_add_value_int(root, "Active Latency Config", le16_to_cpu(log_data->active_latency_config))json_object_object_add(root, "Active Latency Config", json_object_new_int (le16_to_cpu(log_data->active_latency_config)));
5228	json_object_add_value_int(root, "Active Lantency Minimum Window", 100log_data->active_latency_min_window)json_object_object_add(root, "Active Lantency Minimum Window" , json_object_new_int(100log_data->active_latency_min_window ));
5229	json_object_add_value_int(root, "Active Latency Stamp Units", le16_to_cpu(log_data->active_latency_stamp_units))json_object_object_add(root, "Active Latency Stamp Units", json_object_new_int (le16_to_cpu(log_data->active_latency_stamp_units)));
5230	json_object_add_value_int(root, "Static Latency Stamp Units", le16_to_cpu(log_data->static_latency_stamp_units))json_object_object_add(root, "Static Latency Stamp Units", json_object_new_int (le16_to_cpu(log_data->static_latency_stamp_units)));
5231	if (le16_to_cpu(log_data->log_page_version) >= 4) {
5232	json_object_add_value_int(root, "Debug Telemetry Log Size",json_object_object_add(root, "Debug Telemetry Log Size", json_object_new_int (le64_to_cpu((uint64_t )log_data->debug_telemetry_log_size )))
5233	le64_to_cpu((uint64_t )log_data->debug_telemetry_log_size))json_object_object_add(root, "Debug Telemetry Log Size", json_object_new_int (le64_to_cpu((uint64_t )log_data->debug_telemetry_log_size )));
5234	}
5235	json_object_add_value_int(root, "Debug Log Trigger Enable",json_object_object_add(root, "Debug Log Trigger Enable", json_object_new_int (le16_to_cpu(log_data->debug_log_trigger_enable)))
5236	le16_to_cpu(log_data->debug_log_trigger_enable))json_object_object_add(root, "Debug Log Trigger Enable", json_object_new_int (le16_to_cpu(log_data->debug_log_trigger_enable)));
5237	json_object_add_value_int(root, "Log Page Version",json_object_object_add(root, "Log Page Version", json_object_new_int (le16_to_cpu(log_data->log_page_version)))
5238	le16_to_cpu(log_data->log_page_version))json_object_object_add(root, "Log Page Version", json_object_new_int (le16_to_cpu(log_data->log_page_version)));
5239
5240	char guid[40];
5241
5242	memset((void *)guid, 0, 40);
5243	sprintf((char *)guid, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""",
5244	(uint64_t)le64_to_cpu((uint64_t )&log_data->log_page_guid[8]),
5245	(uint64_t)le64_to_cpu((uint64_t )&log_data->log_page_guid[0]));
5246	json_object_add_value_string(root, "Log page GUID", guid);
5247
5248	for (i = 0; i <= 3; i++) {
5249	for (j = 2; j >= 0; j--) {
5250	sprintf(buf, "Active Bucket Counter: Bucket %d %s", i, operation[2-j]);
5251	json_object_add_value_int(root, buf, le32_to_cpu(log_data->active_bucket_counter[i][j+1]))json_object_object_add(root, buf, json_object_new_int(le32_to_cpu (log_data->active_bucket_counter[i][j+1])));
5252	}
5253	}
5254	for (i = 3; i >= 0; i--) {
5255	for (j = 2; j >= 0; j--) {
5256	sprintf(buf, "Active Measured Latency: Bucket %d %s", 3-i, operation[2-j]);
5257	json_object_add_value_int(root, buf, le16_to_cpu(log_data->active_measured_latency[i][j]))json_object_object_add(root, buf, json_object_new_int(le16_to_cpu (log_data->active_measured_latency[i][j])));
5258	}
5259	}
5260	for (i = 3; i >= 0; i--) {
5261	for (j = 2; j >= 0; j--) {
5262	sprintf(buf, "Active Latency Time Stamp: Bucket %d %s", 3-i, operation[2-j]);
5263	json_object_add_value_int(root, buf, le64_to_cpu(log_data->active_latency_timestamp[i][j]))json_object_object_add(root, buf, json_object_new_int(le64_to_cpu (log_data->active_latency_timestamp[i][j])));
5264	}
5265	}
5266	for (i = 0; i <= 3; i++) {
5267	for (j = 2; j >= 0; j--) {
5268	sprintf(buf, "Static Bucket Counter: Bucket %d %s", i, operation[2-j]);
5269	json_object_add_value_int(root, buf, le32_to_cpu(log_data->static_bucket_counter[i][j+1]))json_object_object_add(root, buf, json_object_new_int(le32_to_cpu (log_data->static_bucket_counter[i][j+1])));
5270	}
5271	}
5272	for (i = 3; i >= 0; i--) {
5273	for (j = 2; j >= 0; j--) {
5274	sprintf(buf, "Static Measured Latency: Bucket %d %s", 3-i, operation[2-j]);
5275	json_object_add_value_int(root, buf, le16_to_cpu(log_data->static_measured_latency[i][j]))json_object_object_add(root, buf, json_object_new_int(le16_to_cpu (log_data->static_measured_latency[i][j])));
5276	}
5277	}
5278	for (i = 3; i >= 0; i--) {
5279	for (j = 2; j >= 0; j--) {
5280	sprintf(buf, "Static Latency Time Stamp: Bucket %d %s", 3-i, operation[2-j]);
5281	json_object_add_value_int(root, buf, le64_to_cpu(log_data->static_latency_timestamp[i][j]))json_object_object_add(root, buf, json_object_new_int(le64_to_cpu (log_data->static_latency_timestamp[i][j])));
5282	}
5283	}
5284
5285	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
5286	printf("\n");
5287
5288	json_free_object(root)json_object_put(root);
5289	}
5290
5291	static void wdc_print_error_rec_log_normal(struct wdc_ocp_c1_error_recovery_log *log_data)
5292	{
5293	int j;
5294
5295	printf("Error Recovery/C1 Log Page Data\n");
5296
5297	printf(" Panic Reset Wait Time : 0x%x\n", le16_to_cpu(log_data->panic_reset_wait_time));
5298	printf(" Panic Reset Action : 0x%x\n", log_data->panic_reset_action);
5299	printf(" Device Recovery Action 1 : 0x%x\n", log_data->dev_recovery_action1);
5300	printf(" Panic ID : 0x%" PRIu64"l" "u" "\n", le64_to_cpu(log_data->panic_id));
5301	printf(" Device Capabilities : 0x%x\n", le32_to_cpu(log_data->dev_capabilities));
5302	printf(" Vendor Specific Recovery Opcode : 0x%x\n", log_data->vs_recovery_opc);
5303	printf(" Vendor Specific Command CDW12 : 0x%x\n", le32_to_cpu(log_data->vs_cmd_cdw12));
5304	printf(" Vendor Specific Command CDW13 : 0x%x\n", le32_to_cpu(log_data->vs_cmd_cdw13));
5305	if (le16_to_cpu(log_data->log_page_version) >= 2) {
5306	printf(" Vendor Specific Command Timeout : 0x%x\n", log_data->vs_cmd_to);
5307	printf(" Device Recovery Action 2 : 0x%x\n", log_data->dev_recovery_action2);
5308	printf(" Device Recovery Action 2 Timeout : 0x%x\n", log_data->dev_recovery_action2_to);
5309	}
5310	if (le16_to_cpu(log_data->log_page_version) >= 3) {
5311	printf(" Panic Count : 0x%x\n", log_data->panic_count);
5312	for (j = 0; j < 4; j++)
5313	printf(" Previous Panic ID N-%d : 0x%"PRIx64"l" "x""\n",
5314	j+1, le64_to_cpu(log_data->prev_panic_ids[j]));
5315	}
5316	printf(" Log Page Version : 0x%x\n",
5317	le16_to_cpu(log_data->log_page_version));
5318	printf(" Log page GUID : 0x");
5319	for (j = 0; j < WDC_OCP_C1_GUID_LENGTH16; j++)
5320	printf("%x", log_data->log_page_guid[j]);
5321	printf("\n");
5322	}
5323
5324	static void wdc_print_error_rec_log_json(struct wdc_ocp_c1_error_recovery_log *log_data)
5325	{
5326	int j;
5327	char buf[128];
5328	struct json_object *root = json_create_object()json_object_new_object();
5329
5330	json_object_add_value_int(root, "Panic Reset Wait Time", le16_to_cpu(log_data->panic_reset_wait_time))json_object_object_add(root, "Panic Reset Wait Time", json_object_new_int (le16_to_cpu(log_data->panic_reset_wait_time)));
5331	json_object_add_value_int(root, "Panic Reset Action", log_data->panic_reset_wait_time)json_object_object_add(root, "Panic Reset Action", json_object_new_int (log_data->panic_reset_wait_time));
5332	json_object_add_value_int(root, "Device Recovery Action 1", log_data->dev_recovery_action1)json_object_object_add(root, "Device Recovery Action 1", json_object_new_int (log_data->dev_recovery_action1));
5333	json_object_add_value_int(root, "Panic ID", le64_to_cpu(log_data->panic_id))json_object_object_add(root, "Panic ID", json_object_new_int( le64_to_cpu(log_data->panic_id)));
5334	json_object_add_value_int(root, "Device Capabilities", le32_to_cpu(log_data->dev_capabilities))json_object_object_add(root, "Device Capabilities", json_object_new_int (le32_to_cpu(log_data->dev_capabilities)));
5335	json_object_add_value_int(root, "Vendor Specific Recovery Opcode", log_data->vs_recovery_opc)json_object_object_add(root, "Vendor Specific Recovery Opcode" , json_object_new_int(log_data->vs_recovery_opc));
5336	json_object_add_value_int(root, "Vendor Specific Command CDW12", le32_to_cpu(log_data->vs_cmd_cdw12))json_object_object_add(root, "Vendor Specific Command CDW12", json_object_new_int(le32_to_cpu(log_data->vs_cmd_cdw12)));
5337	json_object_add_value_int(root, "Vendor Specific Command CDW13", le32_to_cpu(log_data->vs_cmd_cdw13))json_object_object_add(root, "Vendor Specific Command CDW13", json_object_new_int(le32_to_cpu(log_data->vs_cmd_cdw13)));
5338	if (le16_to_cpu(log_data->log_page_version) >= 2) {
5339	json_object_add_value_int(root, "Vendor Specific Command Timeout", log_data->vs_cmd_to)json_object_object_add(root, "Vendor Specific Command Timeout" , json_object_new_int(log_data->vs_cmd_to));
5340	json_object_add_value_int(root, "Device Recovery Action 2", log_data->dev_recovery_action2)json_object_object_add(root, "Device Recovery Action 2", json_object_new_int (log_data->dev_recovery_action2));
5341	json_object_add_value_int(root, "Device Recovery Action 2 Timeout", log_data->dev_recovery_action2_to)json_object_object_add(root, "Device Recovery Action 2 Timeout" , json_object_new_int(log_data->dev_recovery_action2_to));
5342	}
5343	if (le16_to_cpu(log_data->log_page_version) >= 3) {
5344	json_object_add_value_int(root, "Panic Count", log_data->panic_count)json_object_object_add(root, "Panic Count", json_object_new_int (log_data->panic_count));
5345	for (j = 0; j < 4; j++) {
5346	sprintf(buf, "Previous Panic ID N-%d", j+1);
5347	json_object_add_value_int(root, buf,json_object_object_add(root, buf, json_object_new_int(le64_to_cpu (log_data->prev_panic_ids[j])))
5348	le64_to_cpu(log_data->prev_panic_ids[j]))json_object_object_add(root, buf, json_object_new_int(le64_to_cpu (log_data->prev_panic_ids[j])));
5349	}
5350	}
5351	json_object_add_value_int(root, "Log Page Version",json_object_object_add(root, "Log Page Version", json_object_new_int (le16_to_cpu(log_data->log_page_version)))
5352	le16_to_cpu(log_data->log_page_version))json_object_object_add(root, "Log Page Version", json_object_new_int (le16_to_cpu(log_data->log_page_version)));
5353
5354	char guid[40];
5355
5356	memset((void *)guid, 0, 40);
5357	sprintf((char *)guid, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""",
5358	(uint64_t)le64_to_cpu((uint64_t )&log_data->log_page_guid[8]),
5359	(uint64_t)le64_to_cpu((uint64_t )&log_data->log_page_guid[0]));
5360	json_object_add_value_string(root, "Log page GUID", guid);
5361
5362	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
5363	printf("\n");
5364
5365	json_free_object(root)json_object_put(root);
5366	}
5367
5368	static void wdc_print_dev_cap_log_normal(struct wdc_ocp_C4_dev_cap_log *log_data)
5369	{
5370	int j;
5371
5372	printf("Device Capabilities/C4 Log Page Data\n");
5373
5374	printf(" Number PCIE Ports : 0x%x\n", le16_to_cpu(log_data->num_pcie_ports));
5375	printf(" Number OOB Management Interfaces : 0x%x\n", le16_to_cpu(log_data->oob_mgmt_support));
5376	printf(" Write Zeros Command Support : 0x%x\n", le16_to_cpu(log_data->wrt_zeros_support));
5377	printf(" Sanitize Command Support : 0x%x\n", le16_to_cpu(log_data->sanitize_support));
5378	printf(" DSM Command Support : 0x%x\n", le16_to_cpu(log_data->dsm_support));
5379	printf(" Write Uncorr Command Support : 0x%x\n", le16_to_cpu(log_data->wrt_uncor_support));
5380	printf(" Fused Command Support : 0x%x\n", le16_to_cpu(log_data->fused_support));
5381	printf(" Minimum DSSD Power State : 0x%x\n", le16_to_cpu(log_data->min_dssd_ps));
5382
5383	for (j = 0; j < WDC_OCP_C4_NUM_PS_DESCR127; j++)
5384	printf(" DSSD Power State %d Descriptor : 0x%x\n", j, log_data->dssd_ps_descr[j]);
5385
5386	printf(" Log Page Version : 0x%x\n", le16_to_cpu(log_data->log_page_version));
5387	printf(" Log page GUID : 0x");
5388	for (j = 0; j < WDC_OCP_C4_GUID_LENGTH16; j++)
5389	printf("%x", log_data->log_page_guid[j]);
5390	printf("\n");
5391	}
5392
5393	static void wdc_print_dev_cap_log_json(struct wdc_ocp_C4_dev_cap_log *log_data)
5394	{
5395	int j;
5396	struct json_object *root = json_create_object()json_object_new_object();
5397
5398	json_object_add_value_int(root, "Number PCIE Ports", le16_to_cpu(log_data->num_pcie_ports))json_object_object_add(root, "Number PCIE Ports", json_object_new_int (le16_to_cpu(log_data->num_pcie_ports)));
5399	json_object_add_value_int(root, "Number OOB Management Interfaces", le16_to_cpu(log_data->num_pcie_ports))json_object_object_add(root, "Number OOB Management Interfaces" , json_object_new_int(le16_to_cpu(log_data->num_pcie_ports )));
5400	json_object_add_value_int(root, "Write Zeros Command Support", le16_to_cpu(log_data->num_pcie_ports))json_object_object_add(root, "Write Zeros Command Support", json_object_new_int (le16_to_cpu(log_data->num_pcie_ports)));
5401	json_object_add_value_int(root, "Sanitize Command Support", le16_to_cpu(log_data->num_pcie_ports))json_object_object_add(root, "Sanitize Command Support", json_object_new_int (le16_to_cpu(log_data->num_pcie_ports)));
5402	json_object_add_value_int(root, "DSM Command Support", le16_to_cpu(log_data->num_pcie_ports))json_object_object_add(root, "DSM Command Support", json_object_new_int (le16_to_cpu(log_data->num_pcie_ports)));
5403	json_object_add_value_int(root, "Write Uncorr Command Support", le16_to_cpu(log_data->num_pcie_ports))json_object_object_add(root, "Write Uncorr Command Support", json_object_new_int (le16_to_cpu(log_data->num_pcie_ports)));
5404	json_object_add_value_int(root, "Fused Command Support", le16_to_cpu(log_data->num_pcie_ports))json_object_object_add(root, "Fused Command Support", json_object_new_int (le16_to_cpu(log_data->num_pcie_ports)));
5405	json_object_add_value_int(root, "Minimum DSSD Power State", le16_to_cpu(log_data->num_pcie_ports))json_object_object_add(root, "Minimum DSSD Power State", json_object_new_int (le16_to_cpu(log_data->num_pcie_ports)));
5406
5407	char dssd_descr_str[40];
5408
5409	memset((void *)dssd_descr_str, 0, 40);
5410	for (j = 0; j < WDC_OCP_C4_NUM_PS_DESCR127; j++) {
5411	sprintf((char *)dssd_descr_str, "DSSD Power State %d Descriptor", j);
5412	json_object_add_value_int(root, dssd_descr_str, log_data->dssd_ps_descr[j])json_object_object_add(root, dssd_descr_str, json_object_new_int (log_data->dssd_ps_descr[j]));
5413	}
5414
5415	json_object_add_value_int(root, "Log Page Version", le16_to_cpu(log_data->log_page_version))json_object_object_add(root, "Log Page Version", json_object_new_int (le16_to_cpu(log_data->log_page_version)));
5416	char guid[40];
5417
5418	memset((void *)guid, 0, 40);
5419	sprintf((char *)guid, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""",
5420	(uint64_t)le64_to_cpu((uint64_t )&log_data->log_page_guid[8]),
5421	(uint64_t)le64_to_cpu((uint64_t )&log_data->log_page_guid[0]));
5422	json_object_add_value_string(root, "Log page GUID", guid);
5423
5424	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
5425	printf("\n");
5426
5427	json_free_object(root)json_object_put(root);
5428	}
5429
5430	static void wdc_print_unsupported_reqs_log_normal(struct wdc_ocp_C5_unsupported_reqs *log_data)
5431	{
5432	int j;
5433
5434	printf("Unsupported Requirements/C5 Log Page Data\n");
5435
5436	printf(" Number Unsupported Req IDs : 0x%x\n",
5437	le16_to_cpu(log_data->unsupported_count));
5438
5439	for (j = 0; j < le16_to_cpu(log_data->unsupported_count); j++)
5440	printf(" Unsupported Requirement List %d : %s\n", j,
5441	log_data->unsupported_req_list[j]);
5442
5443	printf(" Log Page Version : 0x%x\n", le16_to_cpu(log_data->log_page_version));
5444	printf(" Log page GUID : 0x");
5445	for (j = 0; j < WDC_OCP_C5_GUID_LENGTH16; j++)
5446	printf("%x", log_data->log_page_guid[j]);
5447	printf("\n");
5448	}
5449
5450	static void wdc_print_unsupported_reqs_log_json(struct wdc_ocp_C5_unsupported_reqs *log_data)
5451	{
5452	int j;
5453	struct json_object *root = json_create_object()json_object_new_object();
5454
5455	json_object_add_value_int(root, "Number Unsupported Req IDs", le16_to_cpu(log_data->unsupported_count))json_object_object_add(root, "Number Unsupported Req IDs", json_object_new_int (le16_to_cpu(log_data->unsupported_count)));
5456
5457	char unsup_req_list_str[41];
5458
5459	memset((void *)unsup_req_list_str, 0, 41);
5460	for (j = 0; j < le16_to_cpu(log_data->unsupported_count); j++) {
5461	sprintf((char *)unsup_req_list_str, "Unsupported Requirement List %d", j);
5462	json_object_add_value_string(root, unsup_req_list_str, (char *)log_data->unsupported_req_list[j]);
5463	}
5464
5465	json_object_add_value_int(root, "Log Page Version",json_object_object_add(root, "Log Page Version", json_object_new_int (le16_to_cpu(log_data->log_page_version)))
5466	le16_to_cpu(log_data->log_page_version))json_object_object_add(root, "Log Page Version", json_object_new_int (le16_to_cpu(log_data->log_page_version)));
5467	char guid[40];
5468
5469	memset((void *)guid, 0, 40);
5470	sprintf((char *)guid, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""",
5471	(uint64_t)le64_to_cpu((uint64_t )&log_data->log_page_guid[8]),
5472	(uint64_t)le64_to_cpu((uint64_t )&log_data->log_page_guid[0]));
5473	json_object_add_value_string(root, "Log page GUID", guid);
5474
5475	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
5476	printf("\n");
5477
5478	json_free_object(root)json_object_put(root);
5479	}
5480
5481	static void wdc_print_fb_ca_log_normal(struct wdc_ssd_ca_perf_stats *perf)
5482	{
5483	uint64_t converted = 0;
5484
5485	printf(" CA Log Page Performance Statistics :-\n");
5486	printf(" NAND Bytes Written %20"PRIu64"l" "u" "%20"PRIu64"l" "u""\n",
5487	le64_to_cpu(perf->nand_bytes_wr_hi), le64_to_cpu(perf->nand_bytes_wr_lo));
5488	printf(" NAND Bytes Read %20"PRIu64"l" "u" "%20"PRIu64"l" "u""\n",
5489	le64_to_cpu(perf->nand_bytes_rd_hi), le64_to_cpu(perf->nand_bytes_rd_lo));
5490
5491	converted = le64_to_cpu(perf->nand_bad_block);
5492	printf(" NAND Bad Block Count (Normalized) %20"PRIu64"l" "u""\n",
5493	converted & 0xFFFF);
5494	printf(" NAND Bad Block Count (Raw) %20"PRIu64"l" "u""\n",
5495	converted >> 16);
5496
5497	printf(" Uncorrectable Read Count %20"PRIu64"l" "u""\n",
5498	le64_to_cpu(perf->uncorr_read_count));
5499	printf(" Soft ECC Error Count %20"PRIu64"l" "u""\n",
5500	le64_to_cpu(perf->ecc_error_count));
5501	printf(" SSD End to End Detected Correction Count %20"PRIu32"u""\n",
5502	(uint32_t)le32_to_cpu(perf->ssd_detect_count));
5503	printf(" SSD End to End Corrected Correction Count %20"PRIu32"u""\n",
5504	(uint32_t)le32_to_cpu(perf->ssd_correct_count));
5505	printf(" System Data Percent Used %20"PRIu32"u""%%\n",
5506	perf->data_percent_used);
5507	printf(" User Data Erase Counts Max %20"PRIu32"u""\n",
5508	(uint32_t)le32_to_cpu(perf->data_erase_max));
5509	printf(" User Data Erase Counts Min %20"PRIu32"u""\n",
5510	(uint32_t)le32_to_cpu(perf->data_erase_min));
5511	printf(" Refresh Count %20"PRIu64"l" "u""\n",
5512	le64_to_cpu(perf->refresh_count));
5513
5514	converted = le64_to_cpu(perf->program_fail);
5515	printf(" Program Fail Count (Normalized) %20"PRIu64"l" "u""\n",
5516	converted & 0xFFFF);
5517	printf(" Program Fail Count (Raw) %20"PRIu64"l" "u""\n",
5518	converted >> 16);
5519
5520	converted = le64_to_cpu(perf->user_erase_fail);
5521	printf(" User Data Erase Fail Count (Normalized) %20"PRIu64"l" "u""\n",
5522	converted & 0xFFFF);
5523	printf(" User Data Erase Fail Count (Raw) %20"PRIu64"l" "u""\n",
5524	converted >> 16);
5525
5526	converted = le64_to_cpu(perf->system_erase_fail);
5527	printf(" System Area Erase Fail Count (Normalized) %20"PRIu64"l" "u""\n",
5528	converted & 0xFFFF);
5529	printf(" System Area Erase Fail Count (Raw) %20"PRIu64"l" "u""\n",
5530	converted >> 16);
5531
5532	printf(" Thermal Throttling Status %20"PRIu8"u""\n",
5533	perf->thermal_throttle_status);
5534	printf(" Thermal Throttling Count %20"PRIu8"u""\n",
5535	perf->thermal_throttle_count);
5536	printf(" PCIe Correctable Error Count %20"PRIu64"l" "u""\n",
5537	le64_to_cpu(perf->pcie_corr_error));
5538	printf(" Incomplete Shutdown Count %20"PRIu32"u""\n",
5539	(uint32_t)le32_to_cpu(perf->incomplete_shutdown_count));
5540	printf(" Percent Free Blocks %20"PRIu32"u""%%\n",
5541	perf->percent_free_blocks);
5542	}
5543
5544	static void wdc_print_fb_ca_log_json(struct wdc_ssd_ca_perf_stats *perf)
5545	{
5546	struct json_object *root = json_create_object()json_object_new_object();
5547	uint64_t converted = 0;
5548
5549	json_object_add_value_int(root, "NAND Bytes Written Hi", le64_to_cpu(perf->nand_bytes_wr_hi))json_object_object_add(root, "NAND Bytes Written Hi", json_object_new_int (le64_to_cpu(perf->nand_bytes_wr_hi)));
5550	json_object_add_value_int(root, "NAND Bytes Written Lo", le64_to_cpu(perf->nand_bytes_wr_lo))json_object_object_add(root, "NAND Bytes Written Lo", json_object_new_int (le64_to_cpu(perf->nand_bytes_wr_lo)));
5551	json_object_add_value_int(root, "NAND Bytes Read Hi", le64_to_cpu(perf->nand_bytes_rd_hi))json_object_object_add(root, "NAND Bytes Read Hi", json_object_new_int (le64_to_cpu(perf->nand_bytes_rd_hi)));
5552	json_object_add_value_int(root, "NAND Bytes Read Lo", le64_to_cpu(perf->nand_bytes_rd_lo))json_object_object_add(root, "NAND Bytes Read Lo", json_object_new_int (le64_to_cpu(perf->nand_bytes_rd_lo)));
5553
5554	converted = le64_to_cpu(perf->nand_bad_block);
5555	json_object_add_value_int(root, "NAND Bad Block Count (Normalized)",json_object_object_add(root, "NAND Bad Block Count (Normalized)" , json_object_new_int(converted & 0xFFFF))
5556	converted & 0xFFFF)json_object_object_add(root, "NAND Bad Block Count (Normalized)" , json_object_new_int(converted & 0xFFFF));
5557	json_object_add_value_int(root, "NAND Bad Block Count (Raw)",json_object_object_add(root, "NAND Bad Block Count (Raw)", json_object_new_int (converted >> 16))
5558	converted >> 16)json_object_object_add(root, "NAND Bad Block Count (Raw)", json_object_new_int (converted >> 16));
5559
5560	json_object_add_value_int(root, "Uncorrectable Read Count", le64_to_cpu(perf->uncorr_read_count))json_object_object_add(root, "Uncorrectable Read Count", json_object_new_int (le64_to_cpu(perf->uncorr_read_count)));
5561	json_object_add_value_int(root, "Soft ECC Error Count", le64_to_cpu(perf->ecc_error_count))json_object_object_add(root, "Soft ECC Error Count", json_object_new_int (le64_to_cpu(perf->ecc_error_count)));
5562	json_object_add_value_int(root, "SSD End to End Detected Correction Count",json_object_object_add(root, "SSD End to End Detected Correction Count" , json_object_new_int(le32_to_cpu(perf->ssd_detect_count)) )
5563	le32_to_cpu(perf->ssd_detect_count))json_object_object_add(root, "SSD End to End Detected Correction Count" , json_object_new_int(le32_to_cpu(perf->ssd_detect_count)) );
5564	json_object_add_value_int(root, "SSD End to End Corrected Correction Count",json_object_object_add(root, "SSD End to End Corrected Correction Count" , json_object_new_int(le32_to_cpu(perf->ssd_correct_count) ))
5565	le32_to_cpu(perf->ssd_correct_count))json_object_object_add(root, "SSD End to End Corrected Correction Count" , json_object_new_int(le32_to_cpu(perf->ssd_correct_count) ));
5566	json_object_add_value_int(root, "System Data Percent Used",json_object_object_add(root, "System Data Percent Used", json_object_new_int (perf->data_percent_used))
5567	perf->data_percent_used)json_object_object_add(root, "System Data Percent Used", json_object_new_int (perf->data_percent_used));
5568	json_object_add_value_int(root, "User Data Erase Counts Max",json_object_object_add(root, "User Data Erase Counts Max", json_object_new_int (le32_to_cpu(perf->data_erase_max)))
5569	le32_to_cpu(perf->data_erase_max))json_object_object_add(root, "User Data Erase Counts Max", json_object_new_int (le32_to_cpu(perf->data_erase_max)));
5570	json_object_add_value_int(root, "User Data Erase Counts Min",json_object_object_add(root, "User Data Erase Counts Min", json_object_new_int (le32_to_cpu(perf->data_erase_min)))
5571	le32_to_cpu(perf->data_erase_min))json_object_object_add(root, "User Data Erase Counts Min", json_object_new_int (le32_to_cpu(perf->data_erase_min)));
5572	json_object_add_value_int(root, "Refresh Count", le64_to_cpu(perf->refresh_count))json_object_object_add(root, "Refresh Count", json_object_new_int (le64_to_cpu(perf->refresh_count)));
5573
5574	converted = le64_to_cpu(perf->program_fail);
5575	json_object_add_value_int(root, "Program Fail Count (Normalized)",json_object_object_add(root, "Program Fail Count (Normalized)" , json_object_new_int(converted & 0xFFFF))
5576	converted & 0xFFFF)json_object_object_add(root, "Program Fail Count (Normalized)" , json_object_new_int(converted & 0xFFFF));
5577	json_object_add_value_int(root, "Program Fail Count (Raw)",json_object_object_add(root, "Program Fail Count (Raw)", json_object_new_int (converted >> 16))
5578	converted >> 16)json_object_object_add(root, "Program Fail Count (Raw)", json_object_new_int (converted >> 16));
5579
5580	converted = le64_to_cpu(perf->user_erase_fail);
5581	json_object_add_value_int(root, "User Data Erase Fail Count (Normalized)",json_object_object_add(root, "User Data Erase Fail Count (Normalized)" , json_object_new_int(converted & 0xFFFF))
5582	converted & 0xFFFF)json_object_object_add(root, "User Data Erase Fail Count (Normalized)" , json_object_new_int(converted & 0xFFFF));
5583	json_object_add_value_int(root, "User Data Erase Fail Count (Raw)",json_object_object_add(root, "User Data Erase Fail Count (Raw)" , json_object_new_int(converted >> 16))
5584	converted >> 16)json_object_object_add(root, "User Data Erase Fail Count (Raw)" , json_object_new_int(converted >> 16));
5585
5586	converted = le64_to_cpu(perf->system_erase_fail);
5587	json_object_add_value_int(root, "System Area Erase Fail Count (Normalized)",json_object_object_add(root, "System Area Erase Fail Count (Normalized)" , json_object_new_int(converted & 0xFFFF))
5588	converted & 0xFFFF)json_object_object_add(root, "System Area Erase Fail Count (Normalized)" , json_object_new_int(converted & 0xFFFF));
5589	json_object_add_value_int(root, "System Area Erase Fail Count (Raw)",json_object_object_add(root, "System Area Erase Fail Count (Raw)" , json_object_new_int(converted >> 16))
5590	converted >> 16)json_object_object_add(root, "System Area Erase Fail Count (Raw)" , json_object_new_int(converted >> 16));
5591
5592	json_object_add_value_int(root, "Thermal Throttling Status",json_object_object_add(root, "Thermal Throttling Status", json_object_new_int (perf->thermal_throttle_status))
5593	perf->thermal_throttle_status)json_object_object_add(root, "Thermal Throttling Status", json_object_new_int (perf->thermal_throttle_status));
5594	json_object_add_value_int(root, "Thermal Throttling Count",json_object_object_add(root, "Thermal Throttling Count", json_object_new_int (perf->thermal_throttle_count))
5595	perf->thermal_throttle_count)json_object_object_add(root, "Thermal Throttling Count", json_object_new_int (perf->thermal_throttle_count));
5596	json_object_add_value_int(root, "PCIe Correctable Error", le64_to_cpu(perf->pcie_corr_error))json_object_object_add(root, "PCIe Correctable Error", json_object_new_int (le64_to_cpu(perf->pcie_corr_error)));
5597	json_object_add_value_int(root, "Incomplete Shutdown Counte", le32_to_cpu(perf->incomplete_shutdown_count))json_object_object_add(root, "Incomplete Shutdown Counte", json_object_new_int (le32_to_cpu(perf->incomplete_shutdown_count)));
5598	json_object_add_value_int(root, "Percent Free Blocks", perf->percent_free_blocks)json_object_object_add(root, "Percent Free Blocks", json_object_new_int (perf->percent_free_blocks));
5599	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
5600	printf("\n");
5601	json_free_object(root)json_object_put(root);
5602	}
5603
5604	static void wdc_print_bd_ca_log_normal(struct libnvme_transport_handle hdl, void data)
5605	{
5606	struct wdc_bd_ca_log_format bd_data = (struct wdc_bd_ca_log_format )data;
5607	__u64 *raw;
5608	__u64 rawSwapped;
5609	__u16 word_raw1 = NULL((void)0),
5610	word_raw2 = NULL((void)0),
5611	word_raw3 = NULL((void)0);
5612	__u32 dword_raw = NULL((void)0);
5613	__u8 byte_raw = NULL((void)0);
5614	bool_Bool valid_id = true1;
5615
5616	while (valid_id) {
5617	raw = (__u64 *)&bd_data->raw_value[0];
5618	rawSwapped = (le64_to_cpu(*raw)>>8);
5619
5620	switch (bd_data->field_id) {
5621	case 0x0:
5622	printf("Additional Smart Log for NVME device:%s namespace-id:%x\n",
5623	libnvme_transport_handle_get_name(hdl), WDC_DE_GLOBAL_NSID0xFFFFFFFF);
5624	printf("key normalized raw\n");
5625	printf("program_fail_count : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5626	bd_data->normalized_value, (uint64_t)rawSwapped);
5627	break;
5628	case 0x1:
5629	printf("erase_fail_count : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5630	bd_data->normalized_value, (uint64_t)rawSwapped);
5631	break;
5632	case 0x2:
5633	word_raw1 = (__u16 *)&bd_data->raw_value[1];
5634	word_raw2 = (__u16 *)&bd_data->raw_value[3];
5635	word_raw3 = (__u16 *)&bd_data->raw_value[5];
5636	printf("wear_leveling : %3"PRIu8"u",
5637	bd_data->normalized_value);
5638	printf("%% min: %"PRIu16"u"", max: %"PRIu16"u"", avg: %"PRIu16"u""\n",
5639	le16_to_cpu(*word_raw1),
5640	le16_to_cpu(*word_raw2),
5641	le16_to_cpu(*word_raw3));
5642	break;
5643	case 0x3:
5644	printf("end_to_end_error_detection_count: %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5645	bd_data->normalized_value, (uint64_t)rawSwapped);
5646	break;
5647	case 0x4:
5648	printf("crc_error_count : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5649	bd_data->normalized_value, (uint64_t)rawSwapped);
5650	break;
5651	case 0x5:
5652	printf("timed_workload_media_wear : %3"PRIu8"u""%% %-.3f%%\n",
5653	bd_data->normalized_value,
5654	safe_div_fp((rawSwapped), 1024.0));
5655	break;
5656	case 0x6:
5657	printf("timed_workload_host_reads : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5658	bd_data->normalized_value, (uint64_t)rawSwapped);
5659	break;
5660	case 0x7:
5661	printf("timed_workload_timer : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5662	bd_data->normalized_value, (uint64_t)rawSwapped);
5663	break;
5664	case 0x8:
5665	byte_raw = (__u8 *)&bd_data->raw_value[1];
5666	dword_raw = (__u32 *)&bd_data->raw_value[2];
5667	printf("thermal_throttle_status : %3"PRIu8"u""%% %"PRIu16"u",
5668	bd_data->normalized_value, *byte_raw);
5669	printf("%%, cnt: %"PRIu16"u""\n", le32_to_cpu(*dword_raw));
5670	break;
5671	case 0x9:
5672	printf("retry_buffer_overflow_count : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5673	bd_data->normalized_value, (uint64_t)rawSwapped);
5674	break;
5675	case 0xA:
5676	printf("pll_lock_loss_count : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5677	bd_data->normalized_value, (uint64_t)rawSwapped);
5678	break;
5679	case 0xB:
5680	printf("nand_bytes_written : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5681	bd_data->normalized_value, (uint64_t)rawSwapped);
5682	break;
5683	case 0xC:
5684	printf("host_bytes_written : %3"PRIu8"u""%% %"PRIu64"l" "u""\n",
5685	bd_data->normalized_value, (uint64_t)rawSwapped);
5686	/* last entry, break from while loop */
5687	valid_id = false0;
5688	break;
5689	default:
5690	printf(" Invalid Field ID = %d\n", bd_data->field_id);
5691	break;
5692	}
5693
5694	bd_data++;
5695	}
5696
5697	return;
5698	}
5699
5700	static void wdc_print_bd_ca_log_json(void *data)
5701	{
5702	struct wdc_bd_ca_log_format bd_data = (struct wdc_bd_ca_log_format )data;
5703	__u64 *raw, rawSwapped;
5704	__u16 *word_raw;
5705	__u32 *dword_raw;
5706	__u8 *byte_raw;
5707	bool_Bool valid_id = true1;
5708	struct json_object *root = json_create_object()json_object_new_object();
5709
5710	while (valid_id) {
5711	raw = (__u64 *)&bd_data->raw_value[0];
5712	rawSwapped = (le64_to_cpu(*raw)>>8);
5713
5714	switch (bd_data->field_id) {
5715	case 0x0:
5716	json_object_add_value_int(root, "program_fail_count normalized",json_object_object_add(root, "program_fail_count normalized", json_object_new_int(bd_data->normalized_value))
5717	bd_data->normalized_value)json_object_object_add(root, "program_fail_count normalized", json_object_new_int(bd_data->normalized_value));
5718	json_object_add_value_uint64(root, "program_fail_count raw",json_object_object_add(root, "program_fail_count raw", json_object_new_uint64 (rawSwapped))
5719	rawSwapped)json_object_object_add(root, "program_fail_count raw", json_object_new_uint64 (rawSwapped));
5720	break;
5721	case 0x1:
5722	json_object_add_value_int(root, "erase_fail_count normalized",json_object_object_add(root, "erase_fail_count normalized", json_object_new_int (bd_data->normalized_value))
5723	bd_data->normalized_value)json_object_object_add(root, "erase_fail_count normalized", json_object_new_int (bd_data->normalized_value));
5724	json_object_add_value_uint64(root, "erase_fail_count raw",json_object_object_add(root, "erase_fail_count raw", json_object_new_uint64 (rawSwapped))
5725	rawSwapped)json_object_object_add(root, "erase_fail_count raw", json_object_new_uint64 (rawSwapped));
5726	break;
5727	case 0x2:
5728	word_raw = (__u16 *)&bd_data->raw_value[1];
5729	json_object_add_value_int(root, "wear_leveling normalized",json_object_object_add(root, "wear_leveling normalized", json_object_new_int (bd_data->normalized_value))
5730	bd_data->normalized_value)json_object_object_add(root, "wear_leveling normalized", json_object_new_int (bd_data->normalized_value));
5731	json_object_add_value_int(root, "wear_leveling min",json_object_object_add(root, "wear_leveling min", json_object_new_int (le16_to_cpu(*word_raw)))
5732	le16_to_cpu(word_raw))json_object_object_add(root, "wear_leveling min", json_object_new_int (le16_to_cpu(word_raw)));
5733	word_raw = (__u16 *)&bd_data->raw_value[3];
5734	json_object_add_value_int(root, "wear_leveling max",json_object_object_add(root, "wear_leveling max", json_object_new_int (le16_to_cpu(*word_raw)))
5735	le16_to_cpu(word_raw))json_object_object_add(root, "wear_leveling max", json_object_new_int (le16_to_cpu(word_raw)));
5736	word_raw = (__u16 *)&bd_data->raw_value[5];
5737	json_object_add_value_int(root, "wear_leveling avg",json_object_object_add(root, "wear_leveling avg", json_object_new_int (le16_to_cpu(*word_raw)))
5738	le16_to_cpu(word_raw))json_object_object_add(root, "wear_leveling avg", json_object_new_int (le16_to_cpu(word_raw)));
5739	break;
5740	case 0x3:
5741	json_object_add_value_int(root,json_object_object_add(root, "end_to_end_error_detection_count normalized" , json_object_new_int(bd_data->normalized_value))
5742	"end_to_end_error_detection_count normalized",json_object_object_add(root, "end_to_end_error_detection_count normalized" , json_object_new_int(bd_data->normalized_value))
5743	bd_data->normalized_value)json_object_object_add(root, "end_to_end_error_detection_count normalized" , json_object_new_int(bd_data->normalized_value));
5744	json_object_add_value_uint64(root,json_object_object_add(root, "end_to_end_error_detection_count raw" , json_object_new_uint64(rawSwapped))
5745	"end_to_end_error_detection_count raw",json_object_object_add(root, "end_to_end_error_detection_count raw" , json_object_new_uint64(rawSwapped))
5746	rawSwapped)json_object_object_add(root, "end_to_end_error_detection_count raw" , json_object_new_uint64(rawSwapped));
5747	break;
5748	case 0x4:
5749	json_object_add_value_int(root, "crc_error_count normalized",json_object_object_add(root, "crc_error_count normalized", json_object_new_int (bd_data->normalized_value))
5750	bd_data->normalized_value)json_object_object_add(root, "crc_error_count normalized", json_object_new_int (bd_data->normalized_value));
5751	json_object_add_value_uint64(root, "crc_error_count raw",json_object_object_add(root, "crc_error_count raw", json_object_new_uint64 (rawSwapped))
5752	rawSwapped)json_object_object_add(root, "crc_error_count raw", json_object_new_uint64 (rawSwapped));
5753	break;
5754	case 0x5:
5755	json_object_add_value_int(root, "timed_workload_media_wear normalized",json_object_object_add(root, "timed_workload_media_wear normalized" , json_object_new_int(bd_data->normalized_value))
5756	bd_data->normalized_value)json_object_object_add(root, "timed_workload_media_wear normalized" , json_object_new_int(bd_data->normalized_value));
5757	json_object_add_value_double(root, "timed_workload_media_wear raw",json_object_object_add(root, "timed_workload_media_wear raw", util_json_object_new_double(safe_div_fp(((uint64_t)rawSwapped ), 1024.0)))
5758	safe_div_fp(((uint64_t)rawSwapped), 1024.0))json_object_object_add(root, "timed_workload_media_wear raw", util_json_object_new_double(safe_div_fp(((uint64_t)rawSwapped ), 1024.0)));
5759	break;
5760	case 0x6:
5761	json_object_add_value_int(root, "timed_workload_host_reads normalized",json_object_object_add(root, "timed_workload_host_reads normalized" , json_object_new_int(bd_data->normalized_value))
5762	bd_data->normalized_value)json_object_object_add(root, "timed_workload_host_reads normalized" , json_object_new_int(bd_data->normalized_value));
5763	json_object_add_value_uint64(root, "timed_workload_host_reads raw",json_object_object_add(root, "timed_workload_host_reads raw", json_object_new_uint64(rawSwapped))
5764	rawSwapped)json_object_object_add(root, "timed_workload_host_reads raw", json_object_new_uint64(rawSwapped));
5765	break;
5766	case 0x7:
5767	json_object_add_value_int(root, "timed_workload_timer normalized",json_object_object_add(root, "timed_workload_timer normalized" , json_object_new_int(bd_data->normalized_value))
5768	bd_data->normalized_value)json_object_object_add(root, "timed_workload_timer normalized" , json_object_new_int(bd_data->normalized_value));
5769	json_object_add_value_uint64(root, "timed_workload_timer",json_object_object_add(root, "timed_workload_timer", json_object_new_uint64 (rawSwapped))
5770	rawSwapped)json_object_object_add(root, "timed_workload_timer", json_object_new_uint64 (rawSwapped));
5771	break;
5772	case 0x8:
5773	byte_raw = (__u8 *)&bd_data->raw_value[1];
5774	json_object_add_value_int(root, "thermal_throttle_status normalized",json_object_object_add(root, "thermal_throttle_status normalized" , json_object_new_int(bd_data->normalized_value))
5775	bd_data->normalized_value)json_object_object_add(root, "thermal_throttle_status normalized" , json_object_new_int(bd_data->normalized_value));
5776	json_object_add_value_int(root, "thermal_throttle_status",json_object_object_add(root, "thermal_throttle_status", json_object_new_int (*byte_raw))
5777	byte_raw)json_object_object_add(root, "thermal_throttle_status", json_object_new_int (byte_raw));
5778	dword_raw = (__u32 *)&bd_data->raw_value[2];
5779	json_object_add_value_int(root, "thermal_throttle_cnt",json_object_object_add(root, "thermal_throttle_cnt", json_object_new_int (le32_to_cpu(*dword_raw)))
5780	le32_to_cpu(dword_raw))json_object_object_add(root, "thermal_throttle_cnt", json_object_new_int (le32_to_cpu(dword_raw)));
5781	break;
5782	case 0x9:
5783	json_object_add_value_int(root, "retry_buffer_overflow_count normalized",json_object_object_add(root, "retry_buffer_overflow_count normalized" , json_object_new_int(bd_data->normalized_value))
5784	bd_data->normalized_value)json_object_object_add(root, "retry_buffer_overflow_count normalized" , json_object_new_int(bd_data->normalized_value));
5785	json_object_add_value_uint64(root, "retry_buffer_overflow_count raw",json_object_object_add(root, "retry_buffer_overflow_count raw" , json_object_new_uint64(rawSwapped))
5786	rawSwapped)json_object_object_add(root, "retry_buffer_overflow_count raw" , json_object_new_uint64(rawSwapped));
5787	break;
5788	case 0xA:
5789	json_object_add_value_int(root, "pll_lock_loss_count normalized",json_object_object_add(root, "pll_lock_loss_count normalized" , json_object_new_int(bd_data->normalized_value))
5790	bd_data->normalized_value)json_object_object_add(root, "pll_lock_loss_count normalized" , json_object_new_int(bd_data->normalized_value));
5791	json_object_add_value_uint64(root, "pll_lock_loss_count raw",json_object_object_add(root, "pll_lock_loss_count raw", json_object_new_uint64 (rawSwapped))
5792	rawSwapped)json_object_object_add(root, "pll_lock_loss_count raw", json_object_new_uint64 (rawSwapped));
5793	break;
5794	case 0xB:
5795	json_object_add_value_int(root, "nand_bytes_written normalized",json_object_object_add(root, "nand_bytes_written normalized", json_object_new_int(bd_data->normalized_value))
5796	bd_data->normalized_value)json_object_object_add(root, "nand_bytes_written normalized", json_object_new_int(bd_data->normalized_value));
5797	json_object_add_value_uint64(root, "nand_bytes_written raw",json_object_object_add(root, "nand_bytes_written raw", json_object_new_uint64 (rawSwapped))
5798	rawSwapped)json_object_object_add(root, "nand_bytes_written raw", json_object_new_uint64 (rawSwapped));
5799	break;
5800	case 0xC:
5801	json_object_add_value_int(root, "host_bytes_written normalized",json_object_object_add(root, "host_bytes_written normalized", json_object_new_int(bd_data->normalized_value))
5802	bd_data->normalized_value)json_object_object_add(root, "host_bytes_written normalized", json_object_new_int(bd_data->normalized_value));
5803	json_object_add_value_uint64(root, "host_bytes_written raw",json_object_object_add(root, "host_bytes_written raw", json_object_new_uint64 (rawSwapped))
5804	rawSwapped)json_object_object_add(root, "host_bytes_written raw", json_object_new_uint64 (rawSwapped));
5805
5806	/* last entry, break from while loop */
5807	valid_id = false0;
5808	break;
5809	default:
5810	printf(" Invalid Field ID = %d\n", bd_data->field_id);
5811	break;
5812	}
5813
5814	bd_data++;
5815	}
5816
5817	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
5818	printf("\n");
5819	json_free_object(root)json_object_put(root);
5820
5821	return;
5822	}
5823
5824	static void wdc_print_d0_log_normal(struct wdc_ssd_d0_smart_log *perf)
5825	{
5826	printf(" D0 Smart Log Page Statistics :-\n");
5827	printf(" Lifetime Reallocated Erase Block Count %20"PRIu32"u""\n",
5828	(uint32_t)le32_to_cpu(perf->lifetime_realloc_erase_block_count));
5829	printf(" Lifetime Power on Hours %20"PRIu32"u""\n",
5830	(uint32_t)le32_to_cpu(perf->lifetime_power_on_hours));
5831	printf(" Lifetime UECC Count %20"PRIu32"u""\n",
5832	(uint32_t)le32_to_cpu(perf->lifetime_uecc_count));
5833	printf(" Lifetime Write Amplification Factor %20"PRIu32"u""\n",
5834	(uint32_t)le32_to_cpu(perf->lifetime_wrt_amp_factor));
5835	printf(" Trailing Hour Write Amplification Factor %20"PRIu32"u""\n",
5836	(uint32_t)le32_to_cpu(perf->trailing_hr_wrt_amp_factor));
5837	printf(" Reserve Erase Block Count %20"PRIu32"u""\n",
5838	(uint32_t)le32_to_cpu(perf->reserve_erase_block_count));
5839	printf(" Lifetime Program Fail Count %20"PRIu32"u""\n",
5840	(uint32_t)le32_to_cpu(perf->lifetime_program_fail_count));
5841	printf(" Lifetime Block Erase Fail Count %20"PRIu32"u""\n",
5842	(uint32_t)le32_to_cpu(perf->lifetime_block_erase_fail_count));
5843	printf(" Lifetime Die Failure Count %20"PRIu32"u""\n",
5844	(uint32_t)le32_to_cpu(perf->lifetime_die_failure_count));
5845	printf(" Lifetime Link Rate Downgrade Count %20"PRIu32"u""\n",
5846	(uint32_t)le32_to_cpu(perf->lifetime_link_rate_downgrade_count));
5847	printf(" Lifetime Clean Shutdown Count on Power Loss %20"PRIu32"u""\n",
5848	(uint32_t)le32_to_cpu(perf->lifetime_clean_shutdown_count));
5849	printf(" Lifetime Unclean Shutdowns on Power Loss %20"PRIu32"u""\n",
5850	(uint32_t)le32_to_cpu(perf->lifetime_unclean_shutdown_count));
5851	printf(" Current Temperature %20"PRIu32"u""\n",
5852	(uint32_t)le32_to_cpu(perf->current_temp));
5853	printf(" Max Recorded Temperature %20"PRIu32"u""\n",
5854	(uint32_t)le32_to_cpu(perf->max_recorded_temp));
5855	printf(" Lifetime Retired Block Count %20"PRIu32"u""\n",
5856	(uint32_t)le32_to_cpu(perf->lifetime_retired_block_count));
5857	printf(" Lifetime Read Disturb Reallocation Events %20"PRIu32"u""\n",
5858	(uint32_t)le32_to_cpu(perf->lifetime_read_disturb_realloc_events));
5859	printf(" Lifetime NAND Writes %20"PRIu64"l" "u""\n",
5860	le64_to_cpu(perf->lifetime_nand_writes));
5861	printf(" Capacitor Health %20"PRIu32"u""%%\n",
5862	(uint32_t)le32_to_cpu(perf->capacitor_health));
5863	printf(" Lifetime User Writes %20"PRIu64"l" "u""\n",
5864	le64_to_cpu(perf->lifetime_user_writes));
5865	printf(" Lifetime User Reads %20"PRIu64"l" "u""\n",
5866	le64_to_cpu(perf->lifetime_user_reads));
5867	printf(" Lifetime Thermal Throttle Activations %20"PRIu32"u""\n",
5868	(uint32_t)le32_to_cpu(perf->lifetime_thermal_throttle_act));
5869	printf(" Percentage of P/E Cycles Remaining %20"PRIu32"u""%%\n",
5870	(uint32_t)le32_to_cpu(perf->percentage_pe_cycles_remaining));
5871	}
5872
5873	static void wdc_print_d0_log_json(struct wdc_ssd_d0_smart_log *perf)
5874	{
5875	struct json_object *root = json_create_object()json_object_new_object();
5876
5877	json_object_add_value_int(root, "Lifetime Reallocated Erase Block Count",json_object_object_add(root, "Lifetime Reallocated Erase Block Count" , json_object_new_int(le32_to_cpu(perf->lifetime_realloc_erase_block_count )))
5878	le32_to_cpu(perf->lifetime_realloc_erase_block_count))json_object_object_add(root, "Lifetime Reallocated Erase Block Count" , json_object_new_int(le32_to_cpu(perf->lifetime_realloc_erase_block_count )));
5879	json_object_add_value_int(root, "Lifetime Power on Hours",json_object_object_add(root, "Lifetime Power on Hours", json_object_new_int (le32_to_cpu(perf->lifetime_power_on_hours)))
5880	le32_to_cpu(perf->lifetime_power_on_hours))json_object_object_add(root, "Lifetime Power on Hours", json_object_new_int (le32_to_cpu(perf->lifetime_power_on_hours)));
5881	json_object_add_value_int(root, "Lifetime UECC Count",json_object_object_add(root, "Lifetime UECC Count", json_object_new_int (le32_to_cpu(perf->lifetime_uecc_count)))
5882	le32_to_cpu(perf->lifetime_uecc_count))json_object_object_add(root, "Lifetime UECC Count", json_object_new_int (le32_to_cpu(perf->lifetime_uecc_count)));
5883	json_object_add_value_int(root, "Lifetime Write Amplification Factor",json_object_object_add(root, "Lifetime Write Amplification Factor" , json_object_new_int(le32_to_cpu(perf->lifetime_wrt_amp_factor )))
5884	le32_to_cpu(perf->lifetime_wrt_amp_factor))json_object_object_add(root, "Lifetime Write Amplification Factor" , json_object_new_int(le32_to_cpu(perf->lifetime_wrt_amp_factor )));
5885	json_object_add_value_int(root, "Trailing Hour Write Amplification Factor",json_object_object_add(root, "Trailing Hour Write Amplification Factor" , json_object_new_int(le32_to_cpu(perf->trailing_hr_wrt_amp_factor )))
5886	le32_to_cpu(perf->trailing_hr_wrt_amp_factor))json_object_object_add(root, "Trailing Hour Write Amplification Factor" , json_object_new_int(le32_to_cpu(perf->trailing_hr_wrt_amp_factor )));
5887	json_object_add_value_int(root, "Reserve Erase Block Count",json_object_object_add(root, "Reserve Erase Block Count", json_object_new_int (le32_to_cpu(perf->reserve_erase_block_count)))
5888	le32_to_cpu(perf->reserve_erase_block_count))json_object_object_add(root, "Reserve Erase Block Count", json_object_new_int (le32_to_cpu(perf->reserve_erase_block_count)));
5889	json_object_add_value_int(root, "Lifetime Program Fail Count",json_object_object_add(root, "Lifetime Program Fail Count", json_object_new_int (le32_to_cpu(perf->lifetime_program_fail_count)))
5890	le32_to_cpu(perf->lifetime_program_fail_count))json_object_object_add(root, "Lifetime Program Fail Count", json_object_new_int (le32_to_cpu(perf->lifetime_program_fail_count)));
5891	json_object_add_value_int(root, "Lifetime Block Erase Fail Count",json_object_object_add(root, "Lifetime Block Erase Fail Count" , json_object_new_int(le32_to_cpu(perf->lifetime_block_erase_fail_count )))
5892	le32_to_cpu(perf->lifetime_block_erase_fail_count))json_object_object_add(root, "Lifetime Block Erase Fail Count" , json_object_new_int(le32_to_cpu(perf->lifetime_block_erase_fail_count )));
5893	json_object_add_value_int(root, "Lifetime Die Failure Count",json_object_object_add(root, "Lifetime Die Failure Count", json_object_new_int (le32_to_cpu(perf->lifetime_die_failure_count)))
5894	le32_to_cpu(perf->lifetime_die_failure_count))json_object_object_add(root, "Lifetime Die Failure Count", json_object_new_int (le32_to_cpu(perf->lifetime_die_failure_count)));
5895	json_object_add_value_int(root, "Lifetime Link Rate Downgrade Count",json_object_object_add(root, "Lifetime Link Rate Downgrade Count" , json_object_new_int(le32_to_cpu(perf->lifetime_link_rate_downgrade_count )))
5896	le32_to_cpu(perf->lifetime_link_rate_downgrade_count))json_object_object_add(root, "Lifetime Link Rate Downgrade Count" , json_object_new_int(le32_to_cpu(perf->lifetime_link_rate_downgrade_count )));
5897	json_object_add_value_int(root, "Lifetime Clean Shutdown Count on Power Loss",json_object_object_add(root, "Lifetime Clean Shutdown Count on Power Loss" , json_object_new_int(le32_to_cpu(perf->lifetime_clean_shutdown_count )))
5898	le32_to_cpu(perf->lifetime_clean_shutdown_count))json_object_object_add(root, "Lifetime Clean Shutdown Count on Power Loss" , json_object_new_int(le32_to_cpu(perf->lifetime_clean_shutdown_count )));
5899	json_object_add_value_int(root, "Lifetime Unclean Shutdowns on Power Loss",json_object_object_add(root, "Lifetime Unclean Shutdowns on Power Loss" , json_object_new_int(le32_to_cpu(perf->lifetime_unclean_shutdown_count )))
5900	le32_to_cpu(perf->lifetime_unclean_shutdown_count))json_object_object_add(root, "Lifetime Unclean Shutdowns on Power Loss" , json_object_new_int(le32_to_cpu(perf->lifetime_unclean_shutdown_count )));
5901	json_object_add_value_int(root, "Current Temperature",json_object_object_add(root, "Current Temperature", json_object_new_int (le32_to_cpu(perf->current_temp)))
5902	le32_to_cpu(perf->current_temp))json_object_object_add(root, "Current Temperature", json_object_new_int (le32_to_cpu(perf->current_temp)));
5903	json_object_add_value_int(root, "Max Recorded Temperature",json_object_object_add(root, "Max Recorded Temperature", json_object_new_int (le32_to_cpu(perf->max_recorded_temp)))
5904	le32_to_cpu(perf->max_recorded_temp))json_object_object_add(root, "Max Recorded Temperature", json_object_new_int (le32_to_cpu(perf->max_recorded_temp)));
5905	json_object_add_value_int(root, "Lifetime Retired Block Count",json_object_object_add(root, "Lifetime Retired Block Count", json_object_new_int (le32_to_cpu(perf->lifetime_retired_block_count)))
5906	le32_to_cpu(perf->lifetime_retired_block_count))json_object_object_add(root, "Lifetime Retired Block Count", json_object_new_int (le32_to_cpu(perf->lifetime_retired_block_count)));
5907	json_object_add_value_int(root, "Lifetime Read Disturb Reallocation Events",json_object_object_add(root, "Lifetime Read Disturb Reallocation Events" , json_object_new_int(le32_to_cpu(perf->lifetime_read_disturb_realloc_events )))
5908	le32_to_cpu(perf->lifetime_read_disturb_realloc_events))json_object_object_add(root, "Lifetime Read Disturb Reallocation Events" , json_object_new_int(le32_to_cpu(perf->lifetime_read_disturb_realloc_events )));
5909	json_object_add_value_int(root, "Lifetime NAND Writes",json_object_object_add(root, "Lifetime NAND Writes", json_object_new_int (le64_to_cpu(perf->lifetime_nand_writes)))
5910	le64_to_cpu(perf->lifetime_nand_writes))json_object_object_add(root, "Lifetime NAND Writes", json_object_new_int (le64_to_cpu(perf->lifetime_nand_writes)));
5911	json_object_add_value_int(root, "Capacitor Health",json_object_object_add(root, "Capacitor Health", json_object_new_int (le32_to_cpu(perf->capacitor_health)))
5912	le32_to_cpu(perf->capacitor_health))json_object_object_add(root, "Capacitor Health", json_object_new_int (le32_to_cpu(perf->capacitor_health)));
5913	json_object_add_value_int(root, "Lifetime User Writes",json_object_object_add(root, "Lifetime User Writes", json_object_new_int (le64_to_cpu(perf->lifetime_user_writes)))
5914	le64_to_cpu(perf->lifetime_user_writes))json_object_object_add(root, "Lifetime User Writes", json_object_new_int (le64_to_cpu(perf->lifetime_user_writes)));
5915	json_object_add_value_int(root, "Lifetime User Reads",json_object_object_add(root, "Lifetime User Reads", json_object_new_int (le64_to_cpu(perf->lifetime_user_reads)))
5916	le64_to_cpu(perf->lifetime_user_reads))json_object_object_add(root, "Lifetime User Reads", json_object_new_int (le64_to_cpu(perf->lifetime_user_reads)));
5917	json_object_add_value_int(root, "Lifetime Thermal Throttle Activations",json_object_object_add(root, "Lifetime Thermal Throttle Activations" , json_object_new_int(le32_to_cpu(perf->lifetime_thermal_throttle_act )))
5918	le32_to_cpu(perf->lifetime_thermal_throttle_act))json_object_object_add(root, "Lifetime Thermal Throttle Activations" , json_object_new_int(le32_to_cpu(perf->lifetime_thermal_throttle_act )));
5919	json_object_add_value_int(root, "Percentage of P/E Cycles Remaining",json_object_object_add(root, "Percentage of P/E Cycles Remaining" , json_object_new_int(le32_to_cpu(perf->percentage_pe_cycles_remaining )))
5920	le32_to_cpu(perf->percentage_pe_cycles_remaining))json_object_object_add(root, "Percentage of P/E Cycles Remaining" , json_object_new_int(le32_to_cpu(perf->percentage_pe_cycles_remaining )));
5921
5922	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
5923	printf("\n");
5924	json_free_object(root)json_object_put(root);
5925	}
5926
5927	static void wdc_get_commit_action_bin(__u8 commit_action_type, char *action_bin)
5928	{
5929
5930	switch (commit_action_type) {
5931	case 0:
5932	strcpy(action_bin, "000b");
5933	break;
5934	case 1:
5935	strcpy(action_bin, "001b");
5936	break;
5937	case 2:
5938	strcpy(action_bin, "010b");
5939	break;
5940	case 3:
5941	strcpy(action_bin, "011b");
5942	break;
5943	case 4:
5944	strcpy(action_bin, "100b");
5945	break;
5946	case 5:
5947	strcpy(action_bin, "101b");
5948	break;
5949	case 6:
5950	strcpy(action_bin, "110b");
5951	break;
5952	case 7:
5953	strcpy(action_bin, "111b");
5954	break;
5955	default:
5956	strcpy(action_bin, "INVALID");
5957	}
5958
5959	}
5960
5961	static void wdc_print_fw_act_history_log_normal(__u8 *data, int num_entries,
5962	__u32 cust_id, __u32 vendor_id,
5963	__u32 device_id)
5964	{
5965	int i, j;
5966	char previous_fw[9];
5967	char new_fw[9];
5968	char commit_action_bin[8];
5969	char time_str[100];
5970	__u16 oldestEntryIdx = 0, entryIdx = 0;
5971	uint64_t timestamp;
5972	__u64 timestamp_sec;
5973	const char *null_fw = "--------";
5974
5975	memset((void *)time_str, '\0', 100);
5976
5977	if (data[0] == WDC_NVME_GET_FW_ACT_HISTORY_C2_LOG_ID0xC2) {
5978	printf(" Firmware Activate History Log\n");
5979	if (cust_id == WDC_CUSTOMER_ID_0x10050x1005 \|\|
5980	vendor_id == WDC_NVME_SNDK_VID0x15b7) {
5981	printf(" Power on Hour Power Cycle Previous New\n");
5982	printf(" Entry hh:mm:ss Count Firmware Firmware Slot Action Result\n");
5983	printf(" ----- ----------------- ----------------- --------- --------- ----- ------ -------\n");
5984	} else {
5985	printf(" Power Cycle Previous New\n");
5986	printf(" Entry Timestamp Count Firmware Firmware Slot Action Result\n");
5987	printf(" ----- ----------------- ----------------- --------- --------- ----- ------ -------\n");
5988	}
5989
5990	struct wdc_fw_act_history_log_format_c2 fw_act_history_entry = (struct wdc_fw_act_history_log_format_c2 )(data);
5991
5992	oldestEntryIdx = WDC_MAX_NUM_ACT_HIST_ENTRIES20;
5993	if (num_entries == WDC_MAX_NUM_ACT_HIST_ENTRIES20) {
5994	/* find lowest/oldest entry */
5995	for (i = 0; i < num_entries; i++) {
5996	j = (i+1 == WDC_MAX_NUM_ACT_HIST_ENTRIES20) ? 0 : i+1;
5997	if (le16_to_cpu(fw_act_history_entry->entry[i].fw_act_hist_entries) >
5998	le16_to_cpu(fw_act_history_entry->entry[j].fw_act_hist_entries)) {
5999	oldestEntryIdx = j;
6000	break;
6001	}
6002	}
6003	}
6004	if (oldestEntryIdx == WDC_MAX_NUM_ACT_HIST_ENTRIES20)
6005	entryIdx = 0;
6006	else
6007	entryIdx = oldestEntryIdx;
6008
6009	for (i = 0; i < num_entries; i++) {
6010	memset((void *)previous_fw, 0, 9);
6011	memset((void *)new_fw, 0, 9);
6012	memset((void *)commit_action_bin, 0, 8);
6013
6014	memcpy(previous_fw, (char *)&(fw_act_history_entry->entry[entryIdx].previous_fw_version), 8);
6015	if (strlen((char *)&(fw_act_history_entry->entry[entryIdx].current_fw_version)) > 1)
6016	memcpy(new_fw, (char *)&(fw_act_history_entry->entry[entryIdx].current_fw_version), 8);
6017	else
6018	memcpy(new_fw, null_fw, 8);
6019
6020	printf("%5"PRIu16"u""", (uint16_t)le16_to_cpu(fw_act_history_entry->entry[entryIdx].fw_act_hist_entries));
6021
6022	timestamp = (0x0000FFFFFFFFFFFF &
6023	le64_to_cpu(
6024	fw_act_history_entry->entry[entryIdx].timestamp));
6025	timestamp_sec = timestamp / 1000;
6026	if (cust_id == WDC_CUSTOMER_ID_0x10050x1005) {
6027	printf(" ");
6028	memset((void *)time_str, 0, 9);
6029	sprintf((char *)time_str, "%"PRIu32"u"":%u:%u",
6030	(__u32)(timestamp_sec/3600),
6031	(__u8)(timestamp_sec%3600/60),
6032	(__u8)(timestamp_sec%60));
6033
6034	printf("%s", time_str);
6035	printf(" ");
6036	} else if (vendor_id == WDC_NVME_SNDK_VID0x15b7) {
6037	printf(" ");
6038
6039	memset((void *)time_str, 0, 9);
6040	sprintf((char *)time_str, "%"PRIu32"u"":%u:%u",
6041	(__u32)((timestamp_sec/3600)%24),
6042	(__u8)((timestamp_sec/60)%60),
6043	(__u8)(timestamp_sec%60));
6044	printf("%s", time_str);
6045	printf(" ");
6046	} else {
6047	printf(" ");
6048	printf("%16"PRIu64"l" "u""", timestamp);
6049	printf(" ");
6050	}
6051
6052	printf("%16"PRIu64"l" "u""", (uint64_t)le64_to_cpu(fw_act_history_entry->entry[entryIdx].power_cycle_count));
6053	printf(" ");
6054	printf("%s", (char *)previous_fw);
6055	printf(" ");
6056	printf("%s", (char *)new_fw);
6057	printf(" ");
6058	printf("%2"PRIu8"u""", (uint8_t)fw_act_history_entry->entry[entryIdx].slot_number);
6059	printf(" ");
6060	wdc_get_commit_action_bin(
6061	fw_act_history_entry->entry[entryIdx].commit_action_type,
6062	(char *)&commit_action_bin);
6063	printf(" %s", (char *)commit_action_bin);
6064	printf(" ");
6065	if (!le16_to_cpu(fw_act_history_entry->entry[entryIdx].result))
6066	printf("pass");
6067	else
6068	printf("fail #%d", (uint16_t)le16_to_cpu(fw_act_history_entry->entry[entryIdx].result));
6069	printf("\n");
6070
6071	entryIdx++;
6072	if (entryIdx >= WDC_MAX_NUM_ACT_HIST_ENTRIES20)
6073	entryIdx = 0;
6074	}
6075	} else {
6076	printf(" Firmware Activate History Log\n");
6077	printf(" Power on Hour Power Cycle Previous New\n");
6078	printf(" Entry hh:mm:ss Count Firmware Firmware Slot Action Result\n");
6079	printf(" ----- -------------- -------------------- ---------- ---------- ----- ------ -------\n");
6080
6081	struct wdc_fw_act_history_log_entry fw_act_history_entry = (struct wdc_fw_act_history_log_entry )(data + sizeof(struct wdc_fw_act_history_log_hdr));
6082
6083	oldestEntryIdx = WDC_MAX_NUM_ACT_HIST_ENTRIES20;
6084	if (num_entries == WDC_MAX_NUM_ACT_HIST_ENTRIES20) {
6085	/* find lowest/oldest entry */
6086	for (i = 0; i < num_entries; i++) {
6087	if (le32_to_cpu(fw_act_history_entry[i].entry_num) > le32_to_cpu(fw_act_history_entry[i+1].entry_num)) {
6088	oldestEntryIdx = i+1;
6089	break;
6090	}
6091	}
6092	}
6093
6094	if (oldestEntryIdx == WDC_MAX_NUM_ACT_HIST_ENTRIES20)
6095	entryIdx = 0;
6096	else
6097	entryIdx = oldestEntryIdx;
6098
6099	for (i = 0; i < num_entries; i++) {
6100	memset((void *)previous_fw, 0, 9);
6101	memset((void *)new_fw, 0, 9);
6102	memset((void *)commit_action_bin, 0, 8);
6103
6104	memcpy(previous_fw, (char *)&(fw_act_history_entry[entryIdx].previous_fw_version), 8);
6105	if (strlen((char *)&(fw_act_history_entry[entryIdx].new_fw_version)) > 1)
6106	memcpy(new_fw, (char *)&(fw_act_history_entry[entryIdx].new_fw_version), 8);
6107	else
6108	memcpy(new_fw, null_fw, 8);
6109
6110	printf("%5"PRIu32"u""", (uint32_t)le32_to_cpu(fw_act_history_entry[entryIdx].entry_num));
6111	printf(" ");
6112	printf("%04d:%02d:%02d", (int)(le64_to_cpu(fw_act_history_entry[entryIdx].power_on_seconds)/3600),
6113	(int)((le64_to_cpu(fw_act_history_entry[entryIdx].power_on_seconds)%3600)/60),
6114	(int)(le64_to_cpu(fw_act_history_entry[entryIdx].power_on_seconds)%60));
6115	printf(" ");
6116	printf("%16"PRIu32"u""", (uint32_t)le32_to_cpu(fw_act_history_entry[entryIdx].power_cycle_count));
6117	printf(" ");
6118	printf("%s", (char *)previous_fw);
6119	printf(" ");
6120	printf("%s", (char *)new_fw);
6121	printf(" ");
6122	printf("%2"PRIu8"u""", (uint8_t)fw_act_history_entry[entryIdx].slot_number);
6123	printf(" ");
6124	wdc_get_commit_action_bin(fw_act_history_entry[entryIdx].commit_action_type,
6125	(char *)&commit_action_bin);
6126	printf(" %s", (char *)commit_action_bin);
6127	printf(" ");
6128	if (!le16_to_cpu(fw_act_history_entry[entryIdx].result))
6129	printf("pass");
6130	else
6131	printf("fail #%d", (uint16_t)le16_to_cpu(fw_act_history_entry[entryIdx].result));
6132
6133	printf("\n");
6134
6135	entryIdx++;
6136	if (entryIdx >= WDC_MAX_NUM_ACT_HIST_ENTRIES20)
6137	entryIdx = 0;
6138	}
6139	}
6140	}
6141
6142	static void wdc_print_fw_act_history_log_json(__u8 *data, int num_entries,
6143	__u32 cust_id, __u32 vendor_id,
6144	__u32 device_id)
6145	{
6146	struct json_object *root = json_create_object()json_object_new_object();
6147	int i, j;
6148	char previous_fw[9];
6149	char new_fw[9];
6150	char commit_action_bin[8];
6151	char fail_str[32];
6152	char time_str[100];
6153	char ext_time_str[20];
6154	uint64_t timestamp;
6155	__u64 timestamp_sec;
6156
6157	memset((void *)previous_fw, 0, 9);
6158	memset((void *)new_fw, 0, 9);
6159	memset((void *)commit_action_bin, 0, 8);
6160	memset((void *)time_str, '\0', 100);
6161	memset((void *)ext_time_str, 0, 20);
6162	memset((void *)fail_str, 0, 11);
6163	char *null_fw = "--------";
6164	__u16 oldestEntryIdx = 0, entryIdx = 0;
6165
6166	if (data[0] == WDC_NVME_GET_FW_ACT_HISTORY_C2_LOG_ID0xC2) {
6167	struct wdc_fw_act_history_log_format_c2 fw_act_history_entry = (struct wdc_fw_act_history_log_format_c2 )(data);
6168
6169	oldestEntryIdx = WDC_MAX_NUM_ACT_HIST_ENTRIES20;
6170	if (num_entries == WDC_MAX_NUM_ACT_HIST_ENTRIES20) {
6171	/* find lowest/oldest entry */
6172	for (i = 0; i < num_entries; i++) {
6173	j = (i+1 == WDC_MAX_NUM_ACT_HIST_ENTRIES20) ? 0 : i+1;
6174	if (le16_to_cpu(fw_act_history_entry->entry[i].fw_act_hist_entries) >
6175	le16_to_cpu(fw_act_history_entry->entry[j].fw_act_hist_entries)) {
6176	oldestEntryIdx = j;
6177	break;
6178	}
6179	}
6180	}
6181	if (oldestEntryIdx == WDC_MAX_NUM_ACT_HIST_ENTRIES20)
6182	entryIdx = 0;
6183	else
6184	entryIdx = oldestEntryIdx;
6185
6186	for (i = 0; i < num_entries; i++) {
6187	memcpy(previous_fw,
6188	(char *)&(fw_act_history_entry->entry[entryIdx].previous_fw_version),
6189	8);
6190	if (strlen((char *)&(fw_act_history_entry->entry[entryIdx].current_fw_version)) > 1)
6191	memcpy(new_fw,
6192	(char *)&(fw_act_history_entry->entry[entryIdx].current_fw_version),
6193	8);
6194	else
6195	memcpy(new_fw, null_fw, 8);
6196
6197	json_object_add_value_int(root, "Entry",json_object_object_add(root, "Entry", json_object_new_int(le16_to_cpu (fw_act_history_entry->entry[entryIdx].fw_act_hist_entries )))
6198	le16_to_cpu(fw_act_history_entry->entry[entryIdx].fw_act_hist_entries))json_object_object_add(root, "Entry", json_object_new_int(le16_to_cpu (fw_act_history_entry->entry[entryIdx].fw_act_hist_entries )));
6199
6200	timestamp = (0x0000FFFFFFFFFFFF &
6201	le64_to_cpu(
6202	fw_act_history_entry->entry[entryIdx].timestamp));
6203	timestamp_sec = timestamp / 1000;
6204	if (cust_id == WDC_CUSTOMER_ID_0x10050x1005) {
6205	sprintf((char *)time_str, "%"PRIu32"u"":%u:%u",
6206	(__u32)(timestamp_sec/3600),
6207	(__u8)(timestamp_sec%3600/60),
6208	(__u8)(timestamp_sec%60));
6209
6210	json_object_add_value_string(root, "Power on Hour", time_str);
6211
6212	} else if (vendor_id == WDC_NVME_SNDK_VID0x15b7) {
6213	sprintf((char *)time_str, "%"PRIu32"u"":%u:%u",
6214	(__u32)((timestamp_sec/3600)%24),
6215	(__u8)((timestamp_sec/60)%60),
6216	(__u8)(timestamp_sec%60));
6217	json_object_add_value_string(root, "Power on Hour", time_str);
6218	} else {
6219	json_object_add_value_uint64(root, "Timestamp", timestamp)json_object_object_add(root, "Timestamp", json_object_new_uint64 (timestamp));
6220	}
6221
6222	json_object_add_value_int(root, "Power Cycle Count",json_object_object_add(root, "Power Cycle Count", json_object_new_int (le64_to_cpu(fw_act_history_entry->entry[entryIdx].power_cycle_count )))
6223	le64_to_cpu(fw_act_history_entry->entry[entryIdx].power_cycle_count))json_object_object_add(root, "Power Cycle Count", json_object_new_int (le64_to_cpu(fw_act_history_entry->entry[entryIdx].power_cycle_count )));
6224	json_object_add_value_string(root, "Previous Firmware",
6225	previous_fw);
6226	json_object_add_value_string(root, "New Firmware",
6227	new_fw);
6228	json_object_add_value_int(root, "Slot",json_object_object_add(root, "Slot", json_object_new_int(fw_act_history_entry ->entry[entryIdx].slot_number))
6229	fw_act_history_entry->entry[entryIdx].slot_number)json_object_object_add(root, "Slot", json_object_new_int(fw_act_history_entry ->entry[entryIdx].slot_number));
6230
6231	wdc_get_commit_action_bin(
6232	fw_act_history_entry->entry[entryIdx].commit_action_type,
6233	(char *)&commit_action_bin);
6234	json_object_add_value_string(root, "Action", commit_action_bin);
6235
6236	if (!le16_to_cpu(fw_act_history_entry->entry[entryIdx].result)) {
6237	json_object_add_value_string(root, "Result", "pass");
6238	} else {
6239	sprintf((char *)fail_str, "fail #%d", (int)(le16_to_cpu(fw_act_history_entry->entry[entryIdx].result)));
6240	json_object_add_value_string(root, "Result", fail_str);
6241	}
6242
6243	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
6244	printf("\n");
6245
6246	entryIdx++;
6247	if (entryIdx >= WDC_MAX_NUM_ACT_HIST_ENTRIES20)
6248	entryIdx = 0;
6249	}
6250	} else {
6251	struct wdc_fw_act_history_log_entry fw_act_history_entry = (struct wdc_fw_act_history_log_entry )(data + sizeof(struct wdc_fw_act_history_log_hdr));
6252
6253	oldestEntryIdx = WDC_MAX_NUM_ACT_HIST_ENTRIES20;
6254	if (num_entries == WDC_MAX_NUM_ACT_HIST_ENTRIES20) {
6255	/* find lowest/oldest entry */
6256	for (i = 0; i < num_entries; i++) {
6257	if (le32_to_cpu(fw_act_history_entry[i].entry_num) > le32_to_cpu(fw_act_history_entry[i+1].entry_num)) {
6258	oldestEntryIdx = i+1;
6259	break;
6260	}
6261	}
6262	}
6263	if (oldestEntryIdx == WDC_MAX_NUM_ACT_HIST_ENTRIES20)
6264	entryIdx = 0;
6265	else
6266	entryIdx = oldestEntryIdx;
6267
6268	for (i = 0; i < num_entries; i++) {
6269	memcpy(previous_fw,
6270	(char *)&(fw_act_history_entry[entryIdx].previous_fw_version), 8);
6271	if (strlen((char *)&(fw_act_history_entry[entryIdx].new_fw_version)) > 1)
6272	memcpy(new_fw,
6273	(char *)&(fw_act_history_entry[entryIdx].new_fw_version), 8);
6274	else
6275	memcpy(new_fw, null_fw, 8);
6276
6277	json_object_add_value_int(root, "Entry",json_object_object_add(root, "Entry", json_object_new_int(le32_to_cpu (fw_act_history_entry[entryIdx].entry_num)))
6278	le32_to_cpu(fw_act_history_entry[entryIdx].entry_num))json_object_object_add(root, "Entry", json_object_new_int(le32_to_cpu (fw_act_history_entry[entryIdx].entry_num)));
6279
6280	sprintf((char *)time_str, "%04d:%02d:%02d", (int)(le64_to_cpu(fw_act_history_entry[entryIdx].power_on_seconds)/3600),
6281	(int)((le64_to_cpu(fw_act_history_entry[entryIdx].power_on_seconds)%3600)/60),
6282	(int)(le64_to_cpu(fw_act_history_entry[entryIdx].power_on_seconds)%60));
6283	json_object_add_value_string(root, "Power on Hour", time_str);
6284
6285	json_object_add_value_int(root, "Power Cycle Count",json_object_object_add(root, "Power Cycle Count", json_object_new_int (le32_to_cpu(fw_act_history_entry[entryIdx].power_cycle_count )))
6286	le32_to_cpu(fw_act_history_entry[entryIdx].power_cycle_count))json_object_object_add(root, "Power Cycle Count", json_object_new_int (le32_to_cpu(fw_act_history_entry[entryIdx].power_cycle_count )));
6287	json_object_add_value_string(root, "Previous Firmware",
6288	previous_fw);
6289	json_object_add_value_string(root, "New Firmware",
6290	new_fw);
6291	json_object_add_value_int(root, "Slot",json_object_object_add(root, "Slot", json_object_new_int(fw_act_history_entry [entryIdx].slot_number))
6292	fw_act_history_entry[entryIdx].slot_number)json_object_object_add(root, "Slot", json_object_new_int(fw_act_history_entry [entryIdx].slot_number));
6293
6294	wdc_get_commit_action_bin(fw_act_history_entry[entryIdx].commit_action_type,
6295	(char *)&commit_action_bin);
6296	json_object_add_value_string(root, "Action", commit_action_bin);
6297
6298	if (!le16_to_cpu(fw_act_history_entry[entryIdx].result)) {
6299	json_object_add_value_string(root, "Result", "pass");
6300	} else {
6301	sprintf((char *)fail_str, "fail #%d", (int)(le16_to_cpu(fw_act_history_entry[entryIdx].result)));
6302	json_object_add_value_string(root, "Result", fail_str);
6303	}
6304
6305	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
6306	printf("\n");
6307
6308	entryIdx++;
6309	if (entryIdx >= WDC_MAX_NUM_ACT_HIST_ENTRIES20)
6310	entryIdx = 0;
6311	}
6312	}
6313
6314	json_free_object(root)json_object_put(root);
6315	}
6316
6317	static int nvme_get_print_ocp_cloud_smart_log(struct libnvme_transport_handle *hdl,
6318	int uuid_index,
6319	__u32 namespace_id,
6320	int fmt)
6321	{
6322	__u32 length = WDC_NVME_SMART_CLOUD_ATTR_LEN0x200;
6323	struct ocp_cloud_smart_log log_ptr = NULL((void)0);
6324	struct libnvme_passthru_cmd cmd;
6325	int ret, i;
6326
6327	log_ptr = (struct ocp_cloud_smart_log )malloc(sizeof(__u8) length);
6328	if (!log_ptr) {
6329	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
6330	return -1;
6331	}
6332
6333	if (namespace_id == NVME_NSID_ALL) {
6334	ret = libnvme_get_nsid(hdl, &namespace_id);
6335	if (ret < 0)
6336	namespace_id = NVME_NSID_ALL;
6337	}
6338
6339	/* Get the 0xC0 log data */
6340	nvme_init_get_log(&cmd, namespace_id,
6341	WDC_NVME_GET_SMART_CLOUD_ATTR_LOG_ID0xC0, NVME_CSI_NVM,
6342	log_ptr, length);
6343	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_index,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
6344	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
6345	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
6346	ret = libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
6347	if (fmt == JSON)
6348	nvme_show_status(ret);
6349
6350	if (!ret) {
6351	/* Verify GUID matches */
6352	for (i = 0; i < 16; i++) {
6353	if (scao_guid[i] != log_ptr->log_page_guid[i]) {
6354	fprintf(stderrstderr, "ERROR: WDC: Unknown GUID in C0 Log Page data\n");
6355	int j;
6356
6357	fprintf(stderrstderr, "ERROR: WDC: Expected GUID: 0x");
6358	for (j = 0; j < 16; j++)
6359	fprintf(stderrstderr, "%x", scao_guid[j]);
6360	fprintf(stderrstderr, "\nERROR: WDC: Actual GUID: 0x");
6361	for (j = 0; j < 16; j++)
6362	fprintf(stderrstderr, "%x", log_ptr->log_page_guid[j]);
6363	fprintf(stderrstderr, "\n");
6364
6365	ret = -1;
6366	break;
6367	}
6368	}
6369
6370	if (!ret)
6371	/* parse the data */
6372	wdc_print_c0_cloud_attr_log(log_ptr, fmt, hdl);
6373	} else {
6374	fprintf(stderrstderr, "ERROR: WDC: Unable to read C0 Log Page data\n");
6375	ret = -1;
6376	}
6377
6378	free(log_ptr);
6379	return ret;
6380	}
6381
6382	static int nvme_get_print_c0_eol_log(struct libnvme_transport_handle *hdl,
6383	int uuid_index,
6384	__u32 namespace_id,
6385	int fmt)
6386	{
6387	__u32 length = WDC_NVME_EOL_STATUS_LOG_LEN0x200;
6388	struct libnvme_passthru_cmd cmd;
6389	void log_ptr = NULL((void)0);
6390	int ret;
6391
6392	log_ptr = (void )malloc(sizeof(__u8) length);
6393	if (!log_ptr) {
6394	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
6395	return -1;
6396	}
6397
6398	if (namespace_id == NVME_NSID_ALL) {
6399	ret = libnvme_get_nsid(hdl, &namespace_id);
6400	if (ret < 0)
6401	namespace_id = NVME_NSID_ALL;
6402	}
6403
6404	/* Get the 0xC0 log data */
6405	nvme_init_get_log(&cmd, namespace_id,
6406	WDC_NVME_GET_EOL_STATUS_LOG_OPCODE0xC0, NVME_CSI_NVM,
6407	log_ptr, length);
6408	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_index,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
6409	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
6410	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
6411	ret = libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
6412	if (fmt == JSON)
6413	nvme_show_status(ret);
6414
6415	if (!ret) {
6416	/* parse the data */
6417	wdc_print_c0_eol_log(log_ptr, fmt);
6418	} else {
6419	fprintf(stderrstderr, "ERROR: WDC: Unable to read C0 Log Page data ");
6420	fprintf(stderrstderr, "with uuid index %d\n", uuid_index);
6421	ret = -1;
6422	}
6423
6424	free(log_ptr);
6425	return ret;
6426	}
6427
6428	static int nvme_get_ext_smart_cloud_log(struct libnvme_transport_handle hdl, __u8 *data, int uuid_index, __u32 namespace_id)
6429	{
6430	struct libnvme_passthru_cmd cmd;
6431	__u8 log_ptr = NULL((void)0);
6432	int ret, i;
6433
6434	log_ptr = (__u8 )malloc(sizeof(__u8) WDC_NVME_SMART_CLOUD_ATTR_LEN0x200);
6435	if (!log_ptr) {
6436	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
6437	return -1;
6438	}
6439
6440	/* Get the 0xC0 log data */
6441	nvme_init_get_log(&cmd, namespace_id,
6442	WDC_NVME_GET_SMART_CLOUD_ATTR_LOG_ID0xC0, NVME_CSI_NVM,
6443	log_ptr, WDC_NVME_SMART_CLOUD_ATTR_LEN0x200);
6444	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_index,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
6445	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
6446	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
6447	ret = libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
6448	if (!ret) {
6449	/* Verify GUID matches */
6450	for (i = 0; i < WDC_C0_GUID_LENGTH16; i++) {
6451	if (ext_smart_guid[i] != *&log_ptr[SCAO_V1_LPG + i]) {
6452	fprintf(stderrstderr, "ERROR: WDC: Unknown GUID in C0 Log Page V1 data\n");
6453	int j;
6454
6455	fprintf(stderrstderr, "ERROR: WDC: Expected GUID: 0x");
6456	for (j = 0; j < WDC_C0_GUID_LENGTH16; j++)
6457	fprintf(stderrstderr, "%x", ext_smart_guid[j]);
6458	fprintf(stderrstderr, "\nERROR: WDC: Actual GUID: 0x");
6459	for (j = 0; j < WDC_C0_GUID_LENGTH16; j++)
6460	fprintf(stderrstderr, "%x", *&log_ptr[SCAO_V1_LPG + j]);
6461	fprintf(stderrstderr, "\n");
6462
6463	ret = -1;
6464	break;
6465	}
6466	}
6467	}
6468
6469	*data = log_ptr;
6470
6471	return ret;
6472	}
6473
6474
6475	static int nvme_get_hw_rev_log(struct libnvme_transport_handle hdl, __u8 *data, int uuid_index, __u32 namespace_id)
6476	{
6477	struct wdc_nvme_hw_rev_log log_ptr = NULL((void)0);
6478	struct libnvme_passthru_cmd cmd;
6479	int ret, i;
6480
6481	log_ptr = (struct wdc_nvme_hw_rev_log )malloc(sizeof(__u8) WDC_NVME_HW_REV_LOG_PAGE_LEN512);
	Result of 'malloc' is converted to a pointer of type 'struct wdc_nvme_hw_rev_log', which is incompatible with sizeof operand type '__u8'
6482	if (!log_ptr) {
6483	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
6484	return -1;
6485	}
6486
6487	/* Get the 0xC0 log data */
6488	nvme_init_get_log(&cmd, namespace_id,
6489	WDC_NVME_GET_HW_REV_LOG_OPCODE0xc6, NVME_CSI_NVM,
6490	log_ptr, WDC_NVME_HW_REV_LOG_PAGE_LEN512);
6491	cmd.cdw14 \|= NVME_FIELD_ENCODE(uuid_index,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
6492	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
6493	NVME_LOG_CDW14_UUID_MASK)(((__u32)(uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
6494	ret = libnvme_get_log(hdl, &cmd, false0, NVME_LOG_PAGE_PDU_SIZE4096);
6495	if (!ret) {
6496	/* Verify GUID matches */
6497	for (i = 0; i < WDC_NVME_C6_GUID_LENGTH16; i++) {
6498	if (hw_rev_log_guid[i] != log_ptr->hw_rev_guid[i]) {
6499	fprintf(stderrstderr, "ERROR: WDC: Unknown GUID in HW Revision Log Page data\n");
6500	int j;
6501
6502	fprintf(stderrstderr, "ERROR: WDC: Expected GUID: 0x");
6503	for (j = 0; j < WDC_NVME_C6_GUID_LENGTH16; j++)
6504	fprintf(stderrstderr, "%x", hw_rev_log_guid[j]);
6505	fprintf(stderrstderr, "\nERROR: WDC: Actual GUID: 0x");
6506	for (j = 0; j < WDC_NVME_C6_GUID_LENGTH16; j++)
6507	fprintf(stderrstderr, "%x", log_ptr->hw_rev_guid[j]);
6508	fprintf(stderrstderr, "\n");
6509
6510	ret = -1;
6511	break;
6512	}
6513	}
6514	}
6515
6516	data = (__u8 )log_ptr;
6517
6518	return ret;
6519	}
6520
6521
6522	static void wdc_print_hw_rev_log_normal(void *data)
6523	{
6524	int i;
6525	struct wdc_nvme_hw_rev_log log_data = (struct wdc_nvme_hw_rev_log )data;
6526
6527	printf(" Hardware Revision Log:-\n");
6528
6529	printf(" Global Device HW Revision : %d\n",
6530	log_data->hw_rev_gdr);
6531	printf(" ASIC HW Revision : %d\n",
6532	log_data->hw_rev_ar);
6533	printf(" PCB Manufacturer Code : %d\n",
6534	log_data->hw_rev_pbc_mc);
6535	printf(" DRAM Manufacturer Code : %d\n",
6536	log_data->hw_rev_dram_mc);
6537	printf(" NAND Manufacturer Code : %d\n",
6538	log_data->hw_rev_nand_mc);
6539	printf(" PMIC 1 Manufacturer Code : %d\n",
6540	log_data->hw_rev_pmic1_mc);
6541	printf(" PMIC 2 Manufacturer Code : %d\n",
6542	log_data->hw_rev_pmic2_mc);
6543	printf(" Other Component 1 Manf Code : %d\n",
6544	log_data->hw_rev_c1_mc);
6545	printf(" Other Component 2 Manf Code : %d\n",
6546	log_data->hw_rev_c2_mc);
6547	printf(" Other Component 3 Manf Code : %d\n",
6548	log_data->hw_rev_c3_mc);
6549	printf(" Other Component 4 Manf Code : %d\n",
6550	log_data->hw_rev_c4_mc);
6551	printf(" Other Component 5 Manf Code : %d\n",
6552	log_data->hw_rev_c5_mc);
6553	printf(" Other Component 6 Manf Code : %d\n",
6554	log_data->hw_rev_c6_mc);
6555	printf(" Other Component 7 Manf Code : %d\n",
6556	log_data->hw_rev_c7_mc);
6557	printf(" Other Component 8 Manf Code : %d\n",
6558	log_data->hw_rev_c8_mc);
6559	printf(" Other Component 9 Manf Code : %d\n",
6560	log_data->hw_rev_c9_mc);
6561
6562	printf(" Device Manf Detailed Info : 0x");
6563	for (i = 0; i < 16; i++) {
6564	printf("%02x", log_data->hw_rev_dev_mdi[i]);
6565	if (i == 7)
6566	printf(" 0x");
6567	}
6568	printf("\n");
6569	printf(" ASIC Detailed Info : 0x");
6570	for (i = 0; i < 16; i++) {
6571	printf("%02x", log_data->hw_rev_asic_di[i]);
6572	if (i == 7)
6573	printf(" 0x");
6574	}
6575	printf("\n");
6576	printf(" PCB Detailed Info : 0x");
6577	for (i = 0; i < 16; i++) {
6578	printf("%02x", log_data->hw_rev_pcb_di[i]);
6579	if (i == 7)
6580	printf(" 0x");
6581	}
6582	printf("\n");
6583	printf(" DRAM Detailed Info : 0x");
6584	for (i = 0; i < 16; i++) {
6585	printf("%02x", log_data->hw_rev_dram_di[i]);
6586	if (i == 7)
6587	printf(" 0x");
6588	}
6589	printf("\n");
6590	printf(" NAND Detailed Info : 0x");
6591	for (i = 0; i < 16; i++) {
6592	printf("%02x", log_data->hw_rev_nand_di[i]);
6593	if (i == 7)
6594	printf(" 0x");
6595	}
6596	printf("\n");
6597	printf(" PMIC 1 Detailed Info : 0x");
6598	for (i = 0; i < 16; i++) {
6599	printf("%02x", log_data->hw_rev_pmic1_di[i]);
6600	if (i == 7)
6601	printf(" 0x");
6602	}
6603	printf("\n");
6604	printf(" PMIC 2 Detailed Info : 0x");
6605	for (i = 0; i < 16; i++) {
6606	printf("%02x", log_data->hw_rev_pmic2_di[i]);
6607	if (i == 7)
6608	printf(" 0x");
6609	}
6610	printf("\n");
6611	printf(" Component 1 Detailed Info : 0x");
6612	for (i = 0; i < 16; i++) {
6613	printf("%02x", log_data->hw_rev_c1_di[i]);
6614	if (i == 7)
6615	printf(" 0x");
6616	}
6617	printf("\n");
6618	printf(" Component 2 Detailed Info : 0x");
6619	for (i = 0; i < 16; i++) {
6620	printf("%02x", log_data->hw_rev_c2_di[i]);
6621	if (i == 7)
6622	printf(" 0x");
6623	}
6624	printf("\n");
6625	printf(" Component 3 Detailed Info : 0x");
6626	for (i = 0; i < 16; i++) {
6627	printf("%02x", log_data->hw_rev_c3_di[i]);
6628	if (i == 7)
6629	printf(" 0x");
6630	}
6631	printf("\n");
6632	printf(" Component 4 Detailed Info : 0x");
6633	for (i = 0; i < 16; i++) {
6634	printf("%02x", log_data->hw_rev_c4_di[i]);
6635	if (i == 7)
6636	printf(" 0x");
6637	}
6638	printf("\n");
6639	printf(" Component 5 Detailed Info : 0x");
6640	for (i = 0; i < 16; i++) {
6641	printf("%02x", log_data->hw_rev_c5_di[i]);
6642	if (i == 7)
6643	printf(" 0x");
6644	}
6645	printf("\n");
6646	printf(" Component 6 Detailed Info : 0x");
6647	for (i = 0; i < 16; i++) {
6648	printf("%02x", log_data->hw_rev_c6_di[i]);
6649	if (i == 7)
6650	printf(" 0x");
6651	}
6652	printf("\n");
6653	printf(" Component 7 Detailed Info : 0x");
6654	for (i = 0; i < 16; i++) {
6655	printf("%02x", log_data->hw_rev_c7_di[i]);
6656	if (i == 7)
6657	printf(" 0x");
6658	}
6659	printf("\n");
6660	printf(" Component 8 Detailed Info : 0x");
6661	for (i = 0; i < 16; i++) {
6662	printf("%02x", log_data->hw_rev_c8_di[i]);
6663	if (i == 7)
6664	printf(" 0x");
6665	}
6666	printf("\n");
6667	printf(" Component 9 Detailed Info : 0x");
6668	for (i = 0; i < 16; i++) {
6669	printf("%02x", log_data->hw_rev_c9_di[i]);
6670	if (i == 7)
6671	printf(" 0x");
6672	}
6673	printf("\n");
6674	printf(" Serial Number : 0x");
6675	for (i = 0; i < 32; i++) {
6676	if ((i > 1) & !(i % 8))
6677	printf(" 0x");
6678	printf("%02x", log_data->hw_rev_sn[i]);
6679	}
6680	printf("\n");
6681
6682	printf(" Log Page Version : %d\n", log_data->hw_rev_version);
6683	printf(" Log page GUID : 0x");
6684	printf("%"PRIx64"l" "x""%"PRIx64"l" "x""\n", le64_to_cpu((uint64_t )&log_data->hw_rev_guid[8]),
6685	le64_to_cpu((uint64_t )&log_data->hw_rev_guid[0]));
6686	printf("\n");
6687	}
6688
6689	static void wdc_print_hw_rev_log_json(void *data)
6690	{
6691	struct wdc_nvme_hw_rev_log log_data = (struct wdc_nvme_hw_rev_log )data;
6692	struct json_object *root = json_create_object()json_object_new_object();
6693	char json_data[80];
6694
6695	json_object_add_value_uint(root, "Global Device HW Revision",json_object_object_add(root, "Global Device HW Revision", json_object_new_uint64 (log_data->hw_rev_gdr))
6696	log_data->hw_rev_gdr)json_object_object_add(root, "Global Device HW Revision", json_object_new_uint64 (log_data->hw_rev_gdr));
6697	json_object_add_value_uint(root, "ASIC HW Revision",json_object_object_add(root, "ASIC HW Revision", json_object_new_uint64 (log_data->hw_rev_ar))
6698	log_data->hw_rev_ar)json_object_object_add(root, "ASIC HW Revision", json_object_new_uint64 (log_data->hw_rev_ar));
6699	json_object_add_value_uint(root, "PCB Manufacturer Code",json_object_object_add(root, "PCB Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_pbc_mc))
6700	log_data->hw_rev_pbc_mc)json_object_object_add(root, "PCB Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_pbc_mc));
6701	json_object_add_value_uint(root, "DRAM Manufacturer Code",json_object_object_add(root, "DRAM Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_dram_mc))
6702	log_data->hw_rev_dram_mc)json_object_object_add(root, "DRAM Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_dram_mc));
6703	json_object_add_value_uint(root, "NAND Manufacturer Code",json_object_object_add(root, "NAND Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_nand_mc))
6704	log_data->hw_rev_nand_mc)json_object_object_add(root, "NAND Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_nand_mc));
6705	json_object_add_value_uint(root, "PMIC 1 Manufacturer Code",json_object_object_add(root, "PMIC 1 Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_pmic1_mc))
6706	log_data->hw_rev_pmic1_mc)json_object_object_add(root, "PMIC 1 Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_pmic1_mc));
6707	json_object_add_value_uint(root, "PMIC 2 Manufacturer Code",json_object_object_add(root, "PMIC 2 Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_pmic2_mc))
6708	log_data->hw_rev_pmic2_mc)json_object_object_add(root, "PMIC 2 Manufacturer Code", json_object_new_uint64 (log_data->hw_rev_pmic2_mc));
6709	json_object_add_value_uint(root, "Other Component 1 Manf Code",json_object_object_add(root, "Other Component 1 Manf Code", json_object_new_uint64 (log_data->hw_rev_c1_mc))
6710	log_data->hw_rev_c1_mc)json_object_object_add(root, "Other Component 1 Manf Code", json_object_new_uint64 (log_data->hw_rev_c1_mc));
6711	json_object_add_value_uint(root, "Other Component 2 Manf Code",json_object_object_add(root, "Other Component 2 Manf Code", json_object_new_uint64 (log_data->hw_rev_c2_mc))
6712	log_data->hw_rev_c2_mc)json_object_object_add(root, "Other Component 2 Manf Code", json_object_new_uint64 (log_data->hw_rev_c2_mc));
6713	json_object_add_value_uint(root, "Other Component 3 Manf Code",json_object_object_add(root, "Other Component 3 Manf Code", json_object_new_uint64 (log_data->hw_rev_c3_mc))
6714	log_data->hw_rev_c3_mc)json_object_object_add(root, "Other Component 3 Manf Code", json_object_new_uint64 (log_data->hw_rev_c3_mc));
6715	json_object_add_value_uint(root, "Other Component 4 Manf Code",json_object_object_add(root, "Other Component 4 Manf Code", json_object_new_uint64 (log_data->hw_rev_c4_mc))
6716	log_data->hw_rev_c4_mc)json_object_object_add(root, "Other Component 4 Manf Code", json_object_new_uint64 (log_data->hw_rev_c4_mc));
6717	json_object_add_value_uint(root, "Other Component 5 Manf Code",json_object_object_add(root, "Other Component 5 Manf Code", json_object_new_uint64 (log_data->hw_rev_c5_mc))
6718	log_data->hw_rev_c5_mc)json_object_object_add(root, "Other Component 5 Manf Code", json_object_new_uint64 (log_data->hw_rev_c5_mc));
6719	json_object_add_value_uint(root, "Other Component 6 Manf Code",json_object_object_add(root, "Other Component 6 Manf Code", json_object_new_uint64 (log_data->hw_rev_c6_mc))
6720	log_data->hw_rev_c6_mc)json_object_object_add(root, "Other Component 6 Manf Code", json_object_new_uint64 (log_data->hw_rev_c6_mc));
6721	json_object_add_value_uint(root, "Other Component 7 Manf Code",json_object_object_add(root, "Other Component 7 Manf Code", json_object_new_uint64 (log_data->hw_rev_c7_mc))
6722	log_data->hw_rev_c7_mc)json_object_object_add(root, "Other Component 7 Manf Code", json_object_new_uint64 (log_data->hw_rev_c7_mc));
6723	json_object_add_value_uint(root, "Other Component 8 Manf Code",json_object_object_add(root, "Other Component 8 Manf Code", json_object_new_uint64 (log_data->hw_rev_c8_mc))
6724	log_data->hw_rev_c8_mc)json_object_object_add(root, "Other Component 8 Manf Code", json_object_new_uint64 (log_data->hw_rev_c8_mc));
6725	json_object_add_value_uint(root, "Other Component 9 Manf Code",json_object_object_add(root, "Other Component 9 Manf Code", json_object_new_uint64 (log_data->hw_rev_c9_mc))
6726	log_data->hw_rev_c9_mc)json_object_object_add(root, "Other Component 9 Manf Code", json_object_new_uint64 (log_data->hw_rev_c9_mc));
6727
6728	memset((void *)json_data, 0, 40);
6729	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_dev_mdi[8]),
6730	le64_to_cpu((uint64_t )&log_data->hw_rev_dev_mdi[0]));
6731	json_object_add_value_string(root, "Device Manf Detailed Info", json_data);
6732
6733	memset((void *)json_data, 0, 40);
6734	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_asic_di[8]),
6735	le64_to_cpu((uint64_t )&log_data->hw_rev_asic_di[0]));
6736	json_object_add_value_string(root, "ASIC Detailed Info", json_data);
6737
6738	memset((void *)json_data, 0, 40);
6739	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_pcb_di[8]),
6740	le64_to_cpu((uint64_t )&log_data->hw_rev_pcb_di[0]));
6741	json_object_add_value_string(root, "PCB Detailed Info", json_data);
6742
6743	memset((void *)json_data, 0, 40);
6744	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_dram_di[8]),
6745	le64_to_cpu((uint64_t )&log_data->hw_rev_dram_di[0]));
6746	json_object_add_value_string(root, "DRAM Detailed Info", json_data);
6747
6748	memset((void *)json_data, 0, 40);
6749	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_nand_di[8]),
6750	le64_to_cpu((uint64_t )&log_data->hw_rev_nand_di[0]));
6751	json_object_add_value_string(root, "NAND Detailed Info", json_data);
6752
6753	memset((void *)json_data, 0, 40);
6754	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_pmic1_di[8]),
6755	le64_to_cpu((uint64_t )&log_data->hw_rev_pmic1_di[0]));
6756	json_object_add_value_string(root, "PMIC 1 Detailed Info", json_data);
6757
6758	memset((void *)json_data, 0, 40);
6759	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_pmic2_di[8]),
6760	le64_to_cpu((uint64_t )&log_data->hw_rev_pmic2_di[0]));
6761	json_object_add_value_string(root, "PMIC 2 Detailed Info", json_data);
6762
6763	memset((void *)json_data, 0, 40);
6764	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c1_di[8]),
6765	le64_to_cpu((uint64_t )&log_data->hw_rev_c1_di[0]));
6766	json_object_add_value_string(root, "Component 1 Detailed Info", json_data);
6767
6768	memset((void *)json_data, 0, 40);
6769	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c2_di[8]),
6770	le64_to_cpu((uint64_t )&log_data->hw_rev_c2_di[0]));
6771	json_object_add_value_string(root, "Component 2 Detailed Info", json_data);
6772
6773	memset((void *)json_data, 0, 40);
6774	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c3_di[8]),
6775	le64_to_cpu((uint64_t )&log_data->hw_rev_c3_di[0]));
6776	json_object_add_value_string(root, "Component 3 Detailed Info", json_data);
6777
6778	memset((void *)json_data, 0, 40);
6779	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c4_di[8]),
6780	le64_to_cpu((uint64_t )&log_data->hw_rev_c4_di[0]));
6781	json_object_add_value_string(root, "Component 4 Detailed Info", json_data);
6782
6783	memset((void *)json_data, 0, 40);
6784	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c5_di[8]),
6785	le64_to_cpu((uint64_t )&log_data->hw_rev_c5_di[0]));
6786	json_object_add_value_string(root, "Component 5 Detailed Info", json_data);
6787
6788	memset((void *)json_data, 0, 40);
6789	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c6_di[8]),
6790	le64_to_cpu((uint64_t )&log_data->hw_rev_c6_di[0]));
6791	json_object_add_value_string(root, "Component 6 Detailed Info", json_data);
6792
6793	memset((void *)json_data, 0, 40);
6794	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c7_di[8]),
6795	le64_to_cpu((uint64_t )&log_data->hw_rev_c7_di[0]));
6796	json_object_add_value_string(root, "Component 7 Detailed Info", json_data);
6797
6798	memset((void *)json_data, 0, 40);
6799	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c8_di[8]),
6800	le64_to_cpu((uint64_t )&log_data->hw_rev_c8_di[0]));
6801	json_object_add_value_string(root, "Component 8 Detailed Info", json_data);
6802
6803	memset((void *)json_data, 0, 40);
6804	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_c9_di[8]),
6805	le64_to_cpu((uint64_t )&log_data->hw_rev_c9_di[0]));
6806	json_object_add_value_string(root, "Component 9 Detailed Info", json_data);
6807
6808	memset((void *)json_data, 0, 80);
6809	sprintf((char *)json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""%"PRIx64"l" "x""%"PRIx64"l" "x""",
6810	le64_to_cpu((uint64_t )&log_data->hw_rev_sn[0]), le64_to_cpu((uint64_t )&log_data->hw_rev_sn[8]),
6811	le64_to_cpu((uint64_t )&log_data->hw_rev_sn[16]), le64_to_cpu((uint64_t )&log_data->hw_rev_sn[24]));
6812	json_object_add_value_string(root, "Serial Number", json_data);
6813
6814	json_object_add_value_uint(root, "Log Page Version",json_object_object_add(root, "Log Page Version", json_object_new_uint64 (le16_to_cpu(log_data->hw_rev_version)))
6815	le16_to_cpu(log_data->hw_rev_version))json_object_object_add(root, "Log Page Version", json_object_new_uint64 (le16_to_cpu(log_data->hw_rev_version)));
6816
6817	memset((void *)json_data, 0, 40);
6818	sprintf((char )json_data, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""", le64_to_cpu((uint64_t *)&log_data->hw_rev_guid[8]),
6819	le64_to_cpu((uint64_t )&log_data->hw_rev_guid[0]));
6820	json_object_add_value_string(root, "Log Page GUID", json_data);
6821
6822	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
6823	printf("\n");
6824	json_free_object(root)json_object_put(root);
6825	}
6826
6827	static void wdc_print_ext_smart_cloud_log_normal(void *data, int mask)
6828	{
6829	int i;
6830	struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log * ext_smart_log_ptr = (struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log *)data;
6831
6832	if (mask == WDC_SCA_V1_NAND_STATS0x1)
6833	printf(" NAND Statistics :-\n");
6834	else
6835	printf(" SMART Cloud Attributes :-\n");
6836
6837	printf(" Physical Media Units Written TLC (Bytes): %s\n",
6838	uint128_t_to_string(le128_to_cpu(
6839	ext_smart_log_ptr->ext_smart_pmuwt)));
6840	printf(" Physical Media Units Written SLC (Bytes): %s\n",
6841	uint128_t_to_string(le128_to_cpu(
6842	ext_smart_log_ptr->ext_smart_pmuws)));
6843	printf(" Bad User NAND Block Count (Normalized) (Int) : %d\n",
6844	le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_bunbc));
6845	printf(" Bad User NAND Block Count (Raw) (Int) : %"PRIu64"l" "u""\n",
6846	le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_bunbc & 0xFFFFFFFFFFFF0000));
6847	printf(" XOR Recovery Count (Int) : %"PRIu64"l" "u""\n",
6848	le64_to_cpu(ext_smart_log_ptr->ext_smart_xrc));
6849	printf(" Uncorrectable Read Error Count (Int) : %"PRIu64"l" "u""\n",
6850	le64_to_cpu(ext_smart_log_ptr->ext_smart_urec));
6851	if (mask == WDC_SCA_V1_ALL0xF) {
6852	printf(" SSD End to End correction counts (Corrected Errors) (Int) : %"PRIu64"l" "u""\n",
6853	le64_to_cpu(ext_smart_log_ptr->ext_smart_eece));
6854	printf(" SSD End to End correction counts (Detected Errors) (Int) : %"PRIu64"l" "u""\n",
6855	le64_to_cpu(ext_smart_log_ptr->ext_smart_eede));
6856	printf(" SSD End to End correction counts (Uncorrected E2E Errors) (Int) : %"PRIu64"l" "u""\n",
6857	le64_to_cpu(ext_smart_log_ptr->ext_smart_eeue));
6858	printf(" System Data %% life-used : %d %%\n",
6859	ext_smart_log_ptr->ext_smart_sdpu);
6860	}
6861	printf(" User data erase counts (Minimum TLC) (Int) : %"PRIu64"l" "u""\n",
6862	le64_to_cpu(ext_smart_log_ptr->ext_smart_mnudec));
6863	printf(" User data erase counts (Maximum TLC) (Int) : %"PRIu64"l" "u""\n",
6864	le64_to_cpu(ext_smart_log_ptr->ext_smart_mxudec));
6865	printf(" User data erase counts (Minimum SLC) (Int) : %"PRIu64"l" "u""\n",
6866	le64_to_cpu(ext_smart_log_ptr->ext_smart_mnec));
6867	printf(" User data erase counts (Maximum SLC) (Int) : %"PRIu64"l" "u""\n",
6868	le64_to_cpu(ext_smart_log_ptr->ext_smart_mxec));
6869	printf(" User data erase counts (Average SLC) (Int) : %"PRIu64"l" "u""\n",
6870	le64_to_cpu(ext_smart_log_ptr->ext_smart_avec));
6871	printf(" User data erase counts (Average TLC) (Int) : %"PRIu64"l" "u""\n",
6872	le64_to_cpu(ext_smart_log_ptr->ext_smart_avudec));
6873	printf(" Program Fail Count (Normalized) (Int) : %d\n",
6874	le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_pfc));
6875	printf(" Program Fail Count (Raw) (Int) : %"PRIu64"l" "u""\n",
6876	le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_pfc & 0xFFFFFFFFFFFF0000));
6877	printf(" Erase Fail Count (Normalized) (Int) : %d\n",
6878	le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_efc));
6879	printf(" Erase Fail Count (Raw) (Int) : %"PRIu64"l" "u""\n",
6880	le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_efc & 0xFFFFFFFFFFFF0000));
6881	if (mask == WDC_SCA_V1_ALL0xF) {
6882	printf(" PCIe Correctable Error Count (Int) : %"PRIu64"l" "u""\n",
6883	le64_to_cpu(ext_smart_log_ptr->ext_smart_pcec));
6884	printf(" %% Free Blocks (User) (Int) : %d %%\n",
6885	ext_smart_log_ptr->ext_smart_pfbu);
6886	printf(" Security Version Number (Int) : %"PRIu64"l" "u""\n",
6887	le64_to_cpu(ext_smart_log_ptr->ext_smart_svn));
6888	printf(" %% Free Blocks (System) (Int) : %d %%\n",
6889	ext_smart_log_ptr->ext_smart_pfbs);
6890	printf(" NVMe Stats (# Data Set Management/TRIM Commands Completed) (Int): %s\n",
6891	uint128_t_to_string(le128_to_cpu(
6892	ext_smart_log_ptr->ext_smart_dcc)));
6893	printf(" Total Namespace Utilization (nvme0n1 NUSE) (Bytes) : %"PRIu64"l" "u""\n",
6894	le64_to_cpu(ext_smart_log_ptr->ext_smart_tnu));
6895	printf(" NVMe Stats (# NVMe Format Commands Completed) (Int) : %d\n",
6896	le16_to_cpu(ext_smart_log_ptr->ext_smart_fcc));
6897	printf(" Background Back-Pressure Gauge(%%) (Int) : %d\n",
6898	ext_smart_log_ptr->ext_smart_bbpg);
6899	}
6900	printf(" Total # of Soft ECC Error Count (Int) : %"PRIu64"l" "u""\n",
6901	le64_to_cpu(ext_smart_log_ptr->ext_smart_seec));
6902	if (mask == WDC_SCA_V1_ALL0xF) {
6903	printf(" Total # of Read Refresh Count (Int) : %"PRIu64"l" "u""\n",
6904	le64_to_cpu(ext_smart_log_ptr->ext_smart_rfsc));
6905	}
6906	printf(" Bad System NAND Block Count (Normalized) (Int) : %d\n",
6907	le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_bsnbc));
6908	printf(" Bad System NAND Block Count (Raw) (Int) : %"PRIu64"l" "u""\n",
6909	le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_bsnbc & 0xFFFFFFFFFFFF0000));
6910	printf(" Endurance Estimate (Total Writable Lifetime Bytes) (Bytes) : %s\n",
6911	uint128_t_to_string(
6912	le128_to_cpu(ext_smart_log_ptr->ext_smart_eest)));
6913	if (mask == WDC_SCA_V1_ALL0xF) {
6914	printf(" Thermal Throttling Status & Count (Number of thermal throttling events) (Int) : %d\n",
6915	le16_to_cpu(ext_smart_log_ptr->ext_smart_ttc));
6916	printf(" Total # Unaligned I/O (Int) : %"PRIu64"l" "u""\n",
6917	le64_to_cpu(ext_smart_log_ptr->ext_smart_uio));
6918	}
6919	printf(" Total Physical Media Units Read (Bytes) (Int) : %s\n",
6920	uint128_t_to_string(
6921	le128_to_cpu(ext_smart_log_ptr->ext_smart_pmur)));
6922	if (mask == WDC_SCA_V1_ALL0xF) {
6923	printf(" Command Timeout (# of READ Commands > 5 Seconds) (Int) : %"PRIu32"u""\n",
6924	le32_to_cpu(ext_smart_log_ptr->ext_smart_rtoc));
6925	printf(" Command Timeout (# of WRITE Commands > 5 Seconds) (Int) : %"PRIu32"u""\n",
6926	le32_to_cpu(ext_smart_log_ptr->ext_smart_wtoc));
6927	printf(" Command Timeout (# of TRIM Commands > 5 Seconds) (Int) : %"PRIu32"u""\n",
6928	le32_to_cpu(ext_smart_log_ptr->ext_smart_ttoc));
6929	printf(" Total PCIe Link Retraining Count (Int) : %"PRIu64"l" "u""\n",
6930	le64_to_cpu(ext_smart_log_ptr->ext_smart_plrc));
6931	printf(" Active Power State Change Count (Int) : %"PRIu64"l" "u""\n",
6932	le64_to_cpu(ext_smart_log_ptr->ext_smart_pscc));
6933	}
6934	printf(" Cloud Boot SSD Spec Version (Int) : %d.%d.%d.%d\n",
6935	le16_to_cpu(ext_smart_log_ptr->ext_smart_maj),
6936	le16_to_cpu(ext_smart_log_ptr->ext_smart_min),
6937	le16_to_cpu(ext_smart_log_ptr->ext_smart_pt),
6938	le16_to_cpu(ext_smart_log_ptr->ext_smart_err));
6939	printf(" Cloud Boot SSD HW Revision (Int) : %d.%d.%d.%d\n",
6940	0, 0, 0, 0);
6941	if (mask == WDC_SCA_V1_ALL0xF) {
6942	printf(" FTL Unit Size : %"PRIu32"u""\n",
6943	le32_to_cpu(ext_smart_log_ptr->ext_smart_ftlus));
6944	printf(" TCG Ownership Status : %"PRIu32"u""\n",
6945	le32_to_cpu(ext_smart_log_ptr->ext_smart_tcgos));
6946	printf(" Log Page Version (Int) : %d\n",
6947	le16_to_cpu(ext_smart_log_ptr->ext_smart_lpv));
6948	printf(" Log page GUID (Hex) : 0x");
6949	for (i = WDC_C0_GUID_LENGTH16; i > 0; i--)
6950	printf("%02x", ext_smart_log_ptr->ext_smart_lpg[i-1]);
6951	printf("\n");
6952	}
6953	printf("\n");
6954	}
6955
6956	static void wdc_print_ext_smart_cloud_log_json(void *data, int mask)
6957	{
6958	struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log * ext_smart_log_ptr =
6959	(struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log *)data;
6960	struct json_object *root = json_create_object()json_object_new_object();
6961
6962	json_object_add_value_uint128(root, "physical_media_units_bytes_tlc",json_object_object_add(root, "physical_media_units_bytes_tlc" , util_json_object_new_uint128(le128_to_cpu(ext_smart_log_ptr ->ext_smart_pmuwt)))
6963	le128_to_cpu(ext_smart_log_ptr->ext_smart_pmuwt))json_object_object_add(root, "physical_media_units_bytes_tlc" , util_json_object_new_uint128(le128_to_cpu(ext_smart_log_ptr ->ext_smart_pmuwt)));
6964	json_object_add_value_uint128(root, "physical_media_units_bytes_slc",json_object_object_add(root, "physical_media_units_bytes_slc" , util_json_object_new_uint128(le128_to_cpu(ext_smart_log_ptr ->ext_smart_pmuws)))
6965	le128_to_cpu(ext_smart_log_ptr->ext_smart_pmuws))json_object_object_add(root, "physical_media_units_bytes_slc" , util_json_object_new_uint128(le128_to_cpu(ext_smart_log_ptr ->ext_smart_pmuws)));
6966	json_object_add_value_uint(root, "bad_user_blocks_normalized",json_object_object_add(root, "bad_user_blocks_normalized", json_object_new_uint64 (le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_bunbc )))
6967	le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_bunbc))json_object_object_add(root, "bad_user_blocks_normalized", json_object_new_uint64 (le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_bunbc )));
6968	json_object_add_value_uint64(root, "bad_user_blocks_raw",json_object_object_add(root, "bad_user_blocks_raw", json_object_new_uint64 (le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_bunbc & 0xFFFFFFFFFFFF0000)))
6969	le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_bunbc & 0xFFFFFFFFFFFF0000))json_object_object_add(root, "bad_user_blocks_raw", json_object_new_uint64 (le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_bunbc & 0xFFFFFFFFFFFF0000)));
6970	json_object_add_value_uint64(root, "xor_recovery_count",json_object_object_add(root, "xor_recovery_count", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_xrc)))
6971	le64_to_cpu(ext_smart_log_ptr->ext_smart_xrc))json_object_object_add(root, "xor_recovery_count", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_xrc)));
6972	json_object_add_value_uint64(root, "uncorrectable_read_errors",json_object_object_add(root, "uncorrectable_read_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_urec)))
6973	le64_to_cpu(ext_smart_log_ptr->ext_smart_urec))json_object_object_add(root, "uncorrectable_read_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_urec)));
6974	if (mask == WDC_SCA_V1_ALL0xF) {
6975	json_object_add_value_uint64(root, "corrected_e2e_errors",json_object_object_add(root, "corrected_e2e_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_eece)))
6976	le64_to_cpu(ext_smart_log_ptr->ext_smart_eece))json_object_object_add(root, "corrected_e2e_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_eece)));
6977	json_object_add_value_uint64(root, "detected_e2e_errors",json_object_object_add(root, "detected_e2e_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_eede)))
6978	le64_to_cpu(ext_smart_log_ptr->ext_smart_eede))json_object_object_add(root, "detected_e2e_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_eede)));
6979	json_object_add_value_uint64(root, "uncorrected_e2e_errors",json_object_object_add(root, "uncorrected_e2e_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_eeue)))
6980	le64_to_cpu(ext_smart_log_ptr->ext_smart_eeue))json_object_object_add(root, "uncorrected_e2e_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_eeue)));
6981	json_object_add_value_uint(root, "system_data_life_used_pct",json_object_object_add(root, "system_data_life_used_pct", json_object_new_uint64 ((__u8)ext_smart_log_ptr->ext_smart_sdpu))
6982	(__u8)ext_smart_log_ptr->ext_smart_sdpu)json_object_object_add(root, "system_data_life_used_pct", json_object_new_uint64 ((__u8)ext_smart_log_ptr->ext_smart_sdpu));
6983	}
6984	json_object_add_value_uint64(root, "min_slc_user_data_erase_count",json_object_object_add(root, "min_slc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_mnec )))
6985	le64_to_cpu(ext_smart_log_ptr->ext_smart_mnec))json_object_object_add(root, "min_slc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_mnec )));
6986	json_object_add_value_uint64(root, "min_tlc_user_data_erase_count",json_object_object_add(root, "min_tlc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_mnudec )))
6987	le64_to_cpu(ext_smart_log_ptr->ext_smart_mnudec))json_object_object_add(root, "min_tlc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_mnudec )));
6988	json_object_add_value_uint64(root, "max_slc_user_data_erase_count",json_object_object_add(root, "max_slc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_mxec )))
6989	le64_to_cpu(ext_smart_log_ptr->ext_smart_mxec))json_object_object_add(root, "max_slc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_mxec )));
6990	json_object_add_value_uint64(root, "max_tlc_user_data_erase_count",json_object_object_add(root, "max_tlc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_mxudec )))
6991	le64_to_cpu(ext_smart_log_ptr->ext_smart_mxudec))json_object_object_add(root, "max_tlc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_mxudec )));
6992	json_object_add_value_uint64(root, "avg_slc_user_data_erase_count",json_object_object_add(root, "avg_slc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_avec )))
6993	le64_to_cpu(ext_smart_log_ptr->ext_smart_avec))json_object_object_add(root, "avg_slc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_avec )));
6994	json_object_add_value_uint64(root, "avg_tlc_user_data_erase_count",json_object_object_add(root, "avg_tlc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_avudec )))
6995	le64_to_cpu(ext_smart_log_ptr->ext_smart_avudec))json_object_object_add(root, "avg_tlc_user_data_erase_count", json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_avudec )));
6996	json_object_add_value_uint(root, "program_fail_count_normalized",json_object_object_add(root, "program_fail_count_normalized", json_object_new_uint64(le16_to_cpu((uint16_t )ext_smart_log_ptr ->ext_smart_pfc)))
6997	le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_pfc))json_object_object_add(root, "program_fail_count_normalized", json_object_new_uint64(le16_to_cpu((uint16_t )ext_smart_log_ptr ->ext_smart_pfc)));
6998	json_object_add_value_uint64(root, "program_fail_count_raw",json_object_object_add(root, "program_fail_count_raw", json_object_new_uint64 (le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_pfc & 0xFFFFFFFFFFFF0000)))
6999	le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_pfc & 0xFFFFFFFFFFFF0000))json_object_object_add(root, "program_fail_count_raw", json_object_new_uint64 (le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_pfc & 0xFFFFFFFFFFFF0000)));
7000	json_object_add_value_uint(root, "erase_fail_count_normalized",json_object_object_add(root, "erase_fail_count_normalized", json_object_new_uint64 (le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_efc )))
7001	le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_efc))json_object_object_add(root, "erase_fail_count_normalized", json_object_new_uint64 (le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_efc )));
7002	json_object_add_value_uint64(root, "erase_fail_count_raw",json_object_object_add(root, "erase_fail_count_raw", json_object_new_uint64 (le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_efc & 0xFFFFFFFFFFFF0000)))
7003	le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_efc & 0xFFFFFFFFFFFF0000))json_object_object_add(root, "erase_fail_count_raw", json_object_new_uint64 (le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_efc & 0xFFFFFFFFFFFF0000)));
7004	if (mask == WDC_SCA_V1_ALL0xF) {
7005	json_object_add_value_uint64(root, "pcie_correctable_errors",json_object_object_add(root, "pcie_correctable_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_pcec)))
7006	le64_to_cpu(ext_smart_log_ptr->ext_smart_pcec))json_object_object_add(root, "pcie_correctable_errors", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_pcec)));
7007	json_object_add_value_uint(root, "pct_free_blocks_user",json_object_object_add(root, "pct_free_blocks_user", json_object_new_uint64 ((__u8)ext_smart_log_ptr->ext_smart_pfbu))
7008	(__u8)ext_smart_log_ptr->ext_smart_pfbu)json_object_object_add(root, "pct_free_blocks_user", json_object_new_uint64 ((__u8)ext_smart_log_ptr->ext_smart_pfbu));
7009	json_object_add_value_uint64(root, "security_version",json_object_object_add(root, "security_version", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_svn)))
7010	le64_to_cpu(ext_smart_log_ptr->ext_smart_svn))json_object_object_add(root, "security_version", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_svn)));
7011	json_object_add_value_uint(root, "pct_free_blocks_system",json_object_object_add(root, "pct_free_blocks_system", json_object_new_uint64 ((__u8)ext_smart_log_ptr->ext_smart_pfbs))
7012	(__u8)ext_smart_log_ptr->ext_smart_pfbs)json_object_object_add(root, "pct_free_blocks_system", json_object_new_uint64 ((__u8)ext_smart_log_ptr->ext_smart_pfbs));
7013	json_object_add_value_uint128(root, "num_of_trim_commands",json_object_object_add(root, "num_of_trim_commands", util_json_object_new_uint128 (le128_to_cpu(ext_smart_log_ptr->ext_smart_dcc)))
7014	le128_to_cpu(ext_smart_log_ptr->ext_smart_dcc))json_object_object_add(root, "num_of_trim_commands", util_json_object_new_uint128 (le128_to_cpu(ext_smart_log_ptr->ext_smart_dcc)));
7015	json_object_add_value_uint64(root, "total_nuse_bytes",json_object_object_add(root, "total_nuse_bytes", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_tnu)))
7016	le64_to_cpu(ext_smart_log_ptr->ext_smart_tnu))json_object_object_add(root, "total_nuse_bytes", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_tnu)));
7017	json_object_add_value_uint(root, "num_of_format_commands",json_object_object_add(root, "num_of_format_commands", json_object_new_uint64 (le16_to_cpu(ext_smart_log_ptr->ext_smart_fcc)))
7018	le16_to_cpu(ext_smart_log_ptr->ext_smart_fcc))json_object_object_add(root, "num_of_format_commands", json_object_new_uint64 (le16_to_cpu(ext_smart_log_ptr->ext_smart_fcc)));
7019	json_object_add_value_uint(root, "background_pressure_gauge",json_object_object_add(root, "background_pressure_gauge", json_object_new_uint64 ((__u8)ext_smart_log_ptr->ext_smart_bbpg))
7020	(__u8)ext_smart_log_ptr->ext_smart_bbpg)json_object_object_add(root, "background_pressure_gauge", json_object_new_uint64 ((__u8)ext_smart_log_ptr->ext_smart_bbpg));
7021	}
7022	json_object_add_value_uint64(root, "soft_ecc_error_count",json_object_object_add(root, "soft_ecc_error_count", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_seec)))
7023	le64_to_cpu(ext_smart_log_ptr->ext_smart_seec))json_object_object_add(root, "soft_ecc_error_count", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_seec)));
7024	if (mask == WDC_SCA_V1_ALL0xF)
7025	json_object_add_value_uint64(root, "read_refresh_count",json_object_object_add(root, "read_refresh_count", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_rfsc)))
7026	le64_to_cpu(ext_smart_log_ptr->ext_smart_rfsc))json_object_object_add(root, "read_refresh_count", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_rfsc)));
7027	json_object_add_value_uint(root, "bad_system_block_normalized",json_object_object_add(root, "bad_system_block_normalized", json_object_new_uint64 (le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_bsnbc )))
7028	le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_bsnbc))json_object_object_add(root, "bad_system_block_normalized", json_object_new_uint64 (le16_to_cpu((uint16_t )ext_smart_log_ptr->ext_smart_bsnbc )));
7029	json_object_add_value_uint64(root, "bad_system_block_raw",json_object_object_add(root, "bad_system_block_raw", json_object_new_uint64 (le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_bsnbc & 0xFFFFFFFFFFFF0000)))
7030	le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_bsnbc & 0xFFFFFFFFFFFF0000))json_object_object_add(root, "bad_system_block_raw", json_object_new_uint64 (le64_to_cpu((uint64_t )ext_smart_log_ptr->ext_smart_bsnbc & 0xFFFFFFFFFFFF0000)));
7031	json_object_add_value_uint128(root, "endurance_est_bytes",json_object_object_add(root, "endurance_est_bytes", util_json_object_new_uint128 (le128_to_cpu(ext_smart_log_ptr->ext_smart_eest)))
7032	le128_to_cpu(ext_smart_log_ptr->ext_smart_eest))json_object_object_add(root, "endurance_est_bytes", util_json_object_new_uint128 (le128_to_cpu(ext_smart_log_ptr->ext_smart_eest)));
7033	if (mask == WDC_SCA_V1_ALL0xF) {
7034	json_object_add_value_uint(root, "num_throttling_events",json_object_object_add(root, "num_throttling_events", json_object_new_uint64 (le16_to_cpu(ext_smart_log_ptr->ext_smart_ttc)))
7035	le16_to_cpu(ext_smart_log_ptr->ext_smart_ttc))json_object_object_add(root, "num_throttling_events", json_object_new_uint64 (le16_to_cpu(ext_smart_log_ptr->ext_smart_ttc)));
7036	json_object_add_value_uint64(root, "total_unaligned_io",json_object_object_add(root, "total_unaligned_io", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_uio)))
7037	le64_to_cpu(ext_smart_log_ptr->ext_smart_uio))json_object_object_add(root, "total_unaligned_io", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_uio)));
7038	}
7039	json_object_add_value_uint128(root, "physical_media_units_read_bytes",json_object_object_add(root, "physical_media_units_read_bytes" , util_json_object_new_uint128(le128_to_cpu(ext_smart_log_ptr ->ext_smart_pmur)))
7040	le128_to_cpu(ext_smart_log_ptr->ext_smart_pmur))json_object_object_add(root, "physical_media_units_read_bytes" , util_json_object_new_uint128(le128_to_cpu(ext_smart_log_ptr ->ext_smart_pmur)));
7041	if (mask == WDC_SCA_V1_ALL0xF) {
7042	json_object_add_value_uint(root, "num_read_timeouts",json_object_object_add(root, "num_read_timeouts", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_rtoc)))
7043	le32_to_cpu(ext_smart_log_ptr->ext_smart_rtoc))json_object_object_add(root, "num_read_timeouts", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_rtoc)));
7044	json_object_add_value_uint(root, "num_write_timeouts",json_object_object_add(root, "num_write_timeouts", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_wtoc)))
7045	le32_to_cpu(ext_smart_log_ptr->ext_smart_wtoc))json_object_object_add(root, "num_write_timeouts", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_wtoc)));
7046	json_object_add_value_uint(root, "num_trim_timeouts",json_object_object_add(root, "num_trim_timeouts", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_ttoc)))
7047	le32_to_cpu(ext_smart_log_ptr->ext_smart_ttoc))json_object_object_add(root, "num_trim_timeouts", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_ttoc)));
7048	json_object_add_value_uint64(root, "pcie_link_retrain_count",json_object_object_add(root, "pcie_link_retrain_count", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_plrc)))
7049	le64_to_cpu(ext_smart_log_ptr->ext_smart_plrc))json_object_object_add(root, "pcie_link_retrain_count", json_object_new_uint64 (le64_to_cpu(ext_smart_log_ptr->ext_smart_plrc)));
7050	json_object_add_value_uint64(root, "active_power_state_change_count",json_object_object_add(root, "active_power_state_change_count" , json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_pscc )))
7051	le64_to_cpu(ext_smart_log_ptr->ext_smart_pscc))json_object_object_add(root, "active_power_state_change_count" , json_object_new_uint64(le64_to_cpu(ext_smart_log_ptr->ext_smart_pscc )));
7052	}
7053	char vers_str[40];
7054
7055	memset((void *)vers_str, 0, 40);
7056	sprintf((char *)vers_str, "%d.%d.%d.%d",
7057	le16_to_cpu(ext_smart_log_ptr->ext_smart_maj),
7058	le16_to_cpu(ext_smart_log_ptr->ext_smart_min),
7059	le16_to_cpu(ext_smart_log_ptr->ext_smart_pt),
7060	le16_to_cpu(ext_smart_log_ptr->ext_smart_err));
7061	json_object_add_value_string(root, "cloud_boot_ssd_spec_ver", vers_str);
7062	memset((void *)vers_str, 0, 40);
7063	sprintf((char *)vers_str, "%d.%d.%d.%d", 0, 0, 0, 0);
7064	json_object_add_value_string(root, "cloud_boot_ssd_hw_ver", vers_str);
7065
7066	if (mask == WDC_SCA_V1_ALL0xF) {
7067	json_object_add_value_uint(root, "ftl_unit_size",json_object_object_add(root, "ftl_unit_size", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_ftlus)))
7068	le32_to_cpu(ext_smart_log_ptr->ext_smart_ftlus))json_object_object_add(root, "ftl_unit_size", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_ftlus)));
7069	json_object_add_value_uint(root, "tcg_ownership_status",json_object_object_add(root, "tcg_ownership_status", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_tcgos)))
7070	le32_to_cpu(ext_smart_log_ptr->ext_smart_tcgos))json_object_object_add(root, "tcg_ownership_status", json_object_new_uint64 (le32_to_cpu(ext_smart_log_ptr->ext_smart_tcgos)));
7071	json_object_add_value_uint(root, "log_page_ver",json_object_object_add(root, "log_page_ver", json_object_new_uint64 (le16_to_cpu(ext_smart_log_ptr->ext_smart_lpv)))
7072	le16_to_cpu(ext_smart_log_ptr->ext_smart_lpv))json_object_object_add(root, "log_page_ver", json_object_new_uint64 (le16_to_cpu(ext_smart_log_ptr->ext_smart_lpv)));
7073	char guid[40];
7074
7075	memset((void *)guid, 0, 40);
7076	sprintf((char *)guid, "0x%"PRIx64"l" "x""%"PRIx64"l" "x""",
7077	le64_to_cpu((uint64_t )&ext_smart_log_ptr->ext_smart_lpg[8]),
7078	le64_to_cpu((uint64_t )&ext_smart_log_ptr->ext_smart_lpg[0]));
7079	json_object_add_value_string(root, "log_page_guid", guid);
7080	}
7081
7082	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
7083	printf("\n");
7084	json_free_object(root)json_object_put(root);
7085	}
7086
7087
7088	static void wdc_print_eol_c0_normal(void *data)
7089	{
7090
7091	__u8 log_data = (__u8 )data;
7092
7093	printf(" End of Life Log Page 0xC0 :-\n");
7094
7095	printf(" Realloc Block Count %"PRIu32"u""\n",
7096	(uint32_t)le32_to_cpu(log_data[EOL_RBC]));
7097	printf(" ECC Rate %"PRIu32"u""\n",
7098	(uint32_t)le32_to_cpu(log_data[EOL_ECCR]));
7099	printf(" Write Amp %"PRIu32"u""\n",
7100	(uint32_t)le32_to_cpu(log_data[EOL_WRA]));
7101	printf(" Percent Life Remaining %"PRIu32"u""\n",
7102	(uint32_t)le32_to_cpu(log_data[EOL_PLR]));
7103	printf(" Program Fail Count %"PRIu32"u""\n",
7104	(uint32_t)le32_to_cpu(log_data[EOL_PFC]));
7105	printf(" Erase Fail Count %"PRIu32"u""\n",
7106	(uint32_t)le32_to_cpu(log_data[EOL_EFC]));
7107	printf(" Raw Read Error Rate %"PRIu32"u""\n",
7108	(uint32_t)le32_to_cpu(log_data[EOL_RRER]));
7109
7110	}
7111
7112	static void wdc_print_eol_c0_json(void *data)
7113	{
7114	__u8 log_data = (__u8 )data;
7115	struct json_object *root = json_create_object()json_object_new_object();
7116
7117	json_object_add_value_uint(root, "Realloc Block Count",json_object_object_add(root, "Realloc Block Count", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_RBC])))
7118	(uint32_t)le32_to_cpu(log_data[EOL_RBC]))json_object_object_add(root, "Realloc Block Count", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_RBC])));
7119	json_object_add_value_uint(root, "ECC Rate",json_object_object_add(root, "ECC Rate", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_ECCR])))
7120	(uint32_t)le32_to_cpu(log_data[EOL_ECCR]))json_object_object_add(root, "ECC Rate", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_ECCR])));
7121	json_object_add_value_uint(root, "Write Amp",json_object_object_add(root, "Write Amp", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_WRA])))
7122	(uint32_t)le32_to_cpu(log_data[EOL_WRA]))json_object_object_add(root, "Write Amp", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_WRA])));
7123	json_object_add_value_uint(root, "Percent Life Remaining",json_object_object_add(root, "Percent Life Remaining", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_PLR])))
7124	(uint32_t)le32_to_cpu(log_data[EOL_PLR]))json_object_object_add(root, "Percent Life Remaining", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_PLR])));
7125	json_object_add_value_uint(root, "Program Fail Count",json_object_object_add(root, "Program Fail Count", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_PFC])))
7126	(uint32_t)le32_to_cpu(log_data[EOL_PFC]))json_object_object_add(root, "Program Fail Count", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_PFC])));
7127	json_object_add_value_uint(root, "Erase Fail Count",json_object_object_add(root, "Erase Fail Count", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_EFC])))
7128	(uint32_t)le32_to_cpu(log_data[EOL_EFC]))json_object_object_add(root, "Erase Fail Count", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_EFC])));
7129	json_object_add_value_uint(root, "Raw Read Error Rate",json_object_object_add(root, "Raw Read Error Rate", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_RRER])))
7130	(uint32_t)le32_to_cpu(log_data[EOL_RRER]))json_object_object_add(root, "Raw Read Error Rate", json_object_new_uint64 ((uint32_t)le32_to_cpu(log_data[EOL_RRER])));
7131
7132	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
7133	printf("\n");
7134	json_free_object(root)json_object_put(root);
7135	}
7136
7137	static int wdc_print_ext_smart_cloud_log(void *data, int fmt)
7138	{
7139	if (!data) {
7140	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read 0xC0 V1 log\n");
7141	return -1;
7142	}
7143	switch (fmt) {
7144	case NORMAL:
7145	wdc_print_ext_smart_cloud_log_normal(data, WDC_SCA_V1_ALL0xF);
7146	break;
7147	case JSON:
7148	wdc_print_ext_smart_cloud_log_json(data, WDC_SCA_V1_ALL0xF);
7149	break;
7150	}
7151	return 0;
7152	}
7153
7154	static int wdc_print_c0_cloud_attr_log(void *data,
7155	int fmt,
7156	struct libnvme_transport_handle *hdl)
7157	{
7158	struct ocp_cloud_smart_log log = (struct ocp_cloud_smart_log )data;
7159
7160	if (!data) {
7161	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read 0xC0 log\n");
7162	return -1;
7163	}
7164
7165	switch (fmt) {
7166	case BINARY:
7167	d_raw((unsigned char *)log, sizeof(struct ocp_cloud_smart_log));
7168	break;
7169	case NORMAL:
7170	wdc_show_cloud_smart_log_normal(log, hdl);
7171	break;
7172	case JSON:
7173	wdc_show_cloud_smart_log_json(log);
7174	break;
7175	}
7176	return 0;
7177	}
7178
7179	static int wdc_print_c0_eol_log(void *data, int fmt)
7180	{
7181	if (!data) {
7182	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read 0xC0 log\n");
7183	return -1;
7184	}
7185	switch (fmt) {
7186	case BINARY:
7187	d_raw((unsigned char *)data, WDC_NVME_EOL_STATUS_LOG_LEN0x200);
7188	break;
7189	case NORMAL:
7190	wdc_print_eol_c0_normal(data);
7191	break;
7192	case JSON:
7193	wdc_print_eol_c0_json(data);
7194	break;
7195	}
7196	return 0;
7197	}
7198
7199	static int wdc_get_c0_log_page_sn_customer_id_0x100X(struct libnvme_transport_handle *hdl, int uuid_index,
7200	char *format, __u32 namespace_id, int fmt)
7201	{
7202	int ret;
7203
7204	if (!uuid_index) {
7205	ret = nvme_get_print_ocp_cloud_smart_log(hdl,
7206	uuid_index,
7207	namespace_id,
7208	fmt);
7209	} else if (uuid_index == 1) {
7210	ret = nvme_get_print_c0_eol_log(hdl,
7211	uuid_index,
7212	namespace_id,
7213	fmt);
7214	} else {
7215	fprintf(stderrstderr, "ERROR: WDC: Unknown uuid index\n");
7216	ret = -1;
7217	}
7218
7219	return ret;
7220	}
7221
7222	static int wdc_get_c0_log_page_sn(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, int uuid_index, char *format,
7223	__u32 namespace_id, int fmt)
7224	{
7225	int ret = 0;
7226	__u32 cust_id;
7227
7228	cust_id = wdc_get_fw_cust_id(ctx, hdl);
7229	if (cust_id == WDC_INVALID_CUSTOMER_ID-1) {
7230	fprintf(stderrstderr, "%s: ERROR: WDC: invalid customer id\n", __func__);
7231	return -1;
7232	}
7233
7234	if ((cust_id == WDC_CUSTOMER_ID_0x10040x1004) \|\| (cust_id == WDC_CUSTOMER_ID_0x10080x1008) \|\|
7235	(cust_id == WDC_CUSTOMER_ID_0x10050x1005)) {
7236	ret = wdc_get_c0_log_page_sn_customer_id_0x100X(hdl, uuid_index, format,
7237	namespace_id, fmt);
7238	} else {
7239	ret = nvme_get_print_c0_eol_log(hdl,
7240	0,
7241	namespace_id,
7242	fmt);
7243	}
7244
7245	return ret;
7246	}
7247
7248	static int wdc_get_c0_log_page(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char *format, int uuid_index,
7249	__u32 namespace_id)
7250	{
7251	uint32_t device_id, read_vendor_id;
7252	nvme_print_flags_t fmt;
7253	int ret;
7254	__u8 *data;
7255
7256	if (!wdc_check_device(ctx, hdl))
7257	return -1;
7258	ret = validate_output_format(format, &fmt);
7259	if (ret < 0) {
7260	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
7261	return ret;
7262	}
7263
7264	ret = wdc_get_pci_ids(ctx, hdl, &device_id, &read_vendor_id);
7265
7266	switch (device_id) {
7267	case WDC_NVME_SN640_DEV_ID0x2400:
7268	case WDC_NVME_SN640_DEV_ID_10x2401:
7269	case WDC_NVME_SN640_DEV_ID_20x2402:
7270	case WDC_NVME_SN640_DEV_ID_30x2404:
7271	case WDC_NVME_SN840_DEV_ID0x2300:
7272	case WDC_NVME_SN840_DEV_ID_10x2500:
7273	case WDC_NVME_SN860_DEV_ID0x2730:
7274	case WDC_NVME_SN560_DEV_ID_10x2712:
7275	case WDC_NVME_SN560_DEV_ID_20x2713:
7276	case WDC_NVME_SN560_DEV_ID_30x2714:
7277	case WDC_NVME_SN550_DEV_ID0x2708:
7278	ret = wdc_get_c0_log_page_sn(ctx, hdl, uuid_index, format, namespace_id, fmt);
7279	break;
7280	case WDC_NVME_SN650_DEV_ID0x2700:
7281	case WDC_NVME_SN650_DEV_ID_10x2701:
7282	case WDC_NVME_SN650_DEV_ID_20x2702:
7283	case WDC_NVME_SN650_DEV_ID_30x2720:
7284	case WDC_NVME_SN650_DEV_ID_40x2721:
7285	case WDC_NVME_SN655_DEV_ID0x2722:
7286	case WDC_NVME_SN655_DEV_ID_10x2723:
7287	case WDC_NVME_SNTMP_DEV_ID0x2761:
7288	case WDC_NVME_SNTMP_DEV_ID_10x2763:
7289	case WDC_NVME_SNESSD1_DEV_ID_E1L0x2765:
7290	case WDC_NVME_SNESSD1_DEV_ID_E20x2766:
7291	case WDC_NVME_SNESSD1_DEV_ID_E3S0x2767:
7292	case WDC_NVME_SNESSD1_DEV_ID_E3L0x2768:
7293	case WDC_NVME_SNESSD1_DEV_ID_U20x2769:
7294	if (uuid_index == 0) {
7295	ret = nvme_get_print_ocp_cloud_smart_log(hdl,
7296	uuid_index,
7297	namespace_id,
7298	fmt);
7299	} else {
7300	ret = nvme_get_print_c0_eol_log(hdl,
7301	uuid_index,
7302	namespace_id,
7303	fmt);
7304	}
7305	break;
7306	case WDC_NVME_ZN350_DEV_ID0x5010:
7307	case WDC_NVME_ZN350_DEV_ID_10x5018:
7308	ret = nvme_get_print_ocp_cloud_smart_log(hdl,
7309	0,
7310	NVME_NSID_ALL,
7311	fmt);
7312	break;
7313	case WDC_NVME_SN820CL_DEV_ID0x5037:
7314	/* Get the 0xC0 Extended Smart Cloud Attribute log data */
7315	data = NULL((void*)0);
7316	ret = nvme_get_ext_smart_cloud_log(hdl, &data,
7317	uuid_index, namespace_id);
7318
7319	if (strcmp(format, "json"))
7320	nvme_show_status(ret);
7321
7322	if (!ret) {
7323	/* parse the data */
7324	wdc_print_ext_smart_cloud_log(data, fmt);
7325	} else {
7326	fprintf(stderrstderr, "ERROR: WDC: Unable to read C0 Log Page V1 data\n");
7327	ret = -1;
7328	}
7329
7330	free(data);
7331	break;
7332	default:
7333	fprintf(stderrstderr, "ERROR: WDC: Unknown device id - 0x%x\n", device_id);
7334	ret = -1;
7335	break;
7336
7337	}
7338
7339	return ret;
7340	}
7341
7342	static int wdc_print_latency_monitor_log(struct libnvme_transport_handle *hdl,
7343	struct wdc_ssd_latency_monitor_log *log_data,
7344	int fmt)
7345	{
7346	if (!log_data) {
7347	fprintf(stderrstderr, "ERROR: WDC: Invalid C3 log data buffer\n");
7348	return -1;
7349	}
7350	switch (fmt) {
7351	case NORMAL:
7352	wdc_print_latency_monitor_log_normal(hdl, log_data);
7353	break;
7354	case JSON:
7355	wdc_print_latency_monitor_log_json(log_data);
7356	break;
7357	}
7358	return 0;
7359	}
7360
7361	static int wdc_print_error_rec_log(struct wdc_ocp_c1_error_recovery_log *log_data, int fmt)
7362	{
7363	if (!log_data) {
7364	fprintf(stderrstderr, "ERROR: WDC: Invalid C1 log data buffer\n");
7365	return -1;
7366	}
7367	switch (fmt) {
7368	case NORMAL:
7369	wdc_print_error_rec_log_normal(log_data);
7370	break;
7371	case JSON:
7372	wdc_print_error_rec_log_json(log_data);
7373	break;
7374	}
7375	return 0;
7376	}
7377
7378	static int wdc_print_dev_cap_log(struct wdc_ocp_C4_dev_cap_log *log_data, int fmt)
7379	{
7380	if (!log_data) {
7381	fprintf(stderrstderr, "ERROR: WDC: Invalid C4 log data buffer\n");
7382	return -1;
7383	}
7384	switch (fmt) {
7385	case NORMAL:
7386	wdc_print_dev_cap_log_normal(log_data);
7387	break;
7388	case JSON:
7389	wdc_print_dev_cap_log_json(log_data);
7390	break;
7391	}
7392	return 0;
7393	}
7394
7395	static int wdc_print_unsupported_reqs_log(struct wdc_ocp_C5_unsupported_reqs *log_data, int fmt)
7396	{
7397	if (!log_data) {
7398	fprintf(stderrstderr, "ERROR: WDC: Invalid C5 log data buffer\n");
7399	return -1;
7400	}
7401	switch (fmt) {
7402	case NORMAL:
7403	wdc_print_unsupported_reqs_log_normal(log_data);
7404	break;
7405	case JSON:
7406	wdc_print_unsupported_reqs_log_json(log_data);
7407	break;
7408	}
7409	return 0;
7410	}
7411
7412	static int wdc_print_fb_ca_log(struct wdc_ssd_ca_perf_stats *perf, int fmt)
7413	{
7414	if (!perf) {
7415	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read perf stats\n");
7416	return -1;
7417	}
7418	switch (fmt) {
7419	case NORMAL:
7420	wdc_print_fb_ca_log_normal(perf);
7421	break;
7422	case JSON:
7423	wdc_print_fb_ca_log_json(perf);
7424	break;
7425	}
7426	return 0;
7427	}
7428
7429	static int wdc_print_bd_ca_log(struct libnvme_transport_handle hdl, void bd_data, int fmt)
7430	{
7431	if (!bd_data) {
7432	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read data\n");
7433	return -1;
7434	}
7435	switch (fmt) {
7436	case NORMAL:
7437	wdc_print_bd_ca_log_normal(hdl, bd_data);
7438	break;
7439	case JSON:
7440	wdc_print_bd_ca_log_json(bd_data);
7441	break;
7442	default:
7443	fprintf(stderrstderr, "ERROR: WDC: Unknown format - %d\n", fmt);
7444	return -1;
7445	}
7446	return 0;
7447	}
7448
7449	static int wdc_print_d0_log(struct wdc_ssd_d0_smart_log *perf, int fmt)
7450	{
7451	if (!perf) {
7452	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read perf stats\n");
7453	return -1;
7454	}
7455	switch (fmt) {
7456	case NORMAL:
7457	wdc_print_d0_log_normal(perf);
7458	break;
7459	case JSON:
7460	wdc_print_d0_log_json(perf);
7461	break;
7462	}
7463	return 0;
7464	}
7465
7466	static int wdc_print_fw_act_history_log(__u8 *data, int num_entries, int fmt,
7467	__u32 cust_id, __u32 vendor_id,
7468	__u32 device_id)
7469	{
7470	if (!data) {
7471	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read fw activate history entries\n");
7472	return -1;
7473	}
7474
7475	switch (fmt) {
7476	case NORMAL:
7477	wdc_print_fw_act_history_log_normal(data, num_entries, cust_id,
7478	vendor_id, device_id);
7479	break;
7480	case JSON:
7481	wdc_print_fw_act_history_log_json(data, num_entries, cust_id,
7482	vendor_id, device_id);
7483	break;
7484	}
7485	return 0;
7486	}
7487
7488	static int wdc_get_ca_log_page(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char *format)
7489	{
7490	uint32_t read_device_id, read_vendor_id;
7491	struct wdc_ssd_ca_perf_stats *perf;
7492	nvme_print_flags_t fmt;
7493	__u32 cust_id;
7494	__u8 *data;
7495	int ret;
7496
7497	if (!wdc_check_device(ctx, hdl))
7498	return -1;
7499	ret = validate_output_format(format, &fmt);
7500	if (ret < 0) {
7501	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
7502	return ret;
7503	}
7504
7505	/* verify the 0xCA log page is supported */
7506	if (wdc_nvme_check_supported_log_page(ctx, hdl,
7507	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA, 0) == false0) {
7508	fprintf(stderrstderr, "ERROR: WDC: 0xCA Log Page not supported\n");
7509	return -1;
7510	}
7511
7512	/* get the FW customer id */
7513	cust_id = wdc_get_fw_cust_id(ctx, hdl);
7514	if (cust_id == WDC_INVALID_CUSTOMER_ID-1) {
7515	fprintf(stderrstderr, "%s: ERROR: WDC: invalid customer id\n", __func__);
7516	return -1;
7517	}
7518
7519	ret = wdc_get_pci_ids(ctx, hdl, &read_device_id, &read_vendor_id);
7520
7521	switch (read_device_id) {
7522	case WDC_NVME_SN200_DEV_ID0x0023:
7523	if (cust_id == WDC_CUSTOMER_ID_0x10050x1005) {
7524	data = (__u8 )malloc(sizeof(__u8) WDC_FB_CA_LOG_BUF_LEN0x80);
7525	if (!data) {
7526	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7527	return -1;
7528	}
7529
7530	memset(data, 0, sizeof(__u8) * WDC_FB_CA_LOG_BUF_LEN0x80);
7531
7532	ret = nvme_get_log_simple(hdl,
7533	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA,
7534	data, WDC_FB_CA_LOG_BUF_LEN0x80);
7535	if (strcmp(format, "json"))
7536	nvme_show_status(ret);
7537
7538	if (!ret) {
7539	/* parse the data */
7540	perf = (struct wdc_ssd_ca_perf_stats *)(data);
7541	ret = wdc_print_fb_ca_log(perf, fmt);
7542	} else {
7543	fprintf(stderrstderr, "ERROR: WDC: Unable to read CA Log Page data\n");
7544	ret = -1;
7545	}
7546	} else {
7547
7548	fprintf(stderrstderr, "ERROR: WDC: Unsupported Customer id, id = 0x%x\n", cust_id);
7549	return -1;
7550	}
7551	break;
7552	case WDC_NVME_SN640_DEV_ID0x2400:
7553	case WDC_NVME_SN640_DEV_ID_10x2401:
7554	case WDC_NVME_SN640_DEV_ID_20x2402:
7555	case WDC_NVME_SN640_DEV_ID_30x2404:
7556	case WDC_NVME_SN840_DEV_ID0x2300:
7557	case WDC_NVME_SN840_DEV_ID_10x2500:
7558	case WDC_NVME_SN860_DEV_ID0x2730:
7559	if (cust_id == WDC_CUSTOMER_ID_0x10050x1005) {
7560	data = (__u8 )malloc(sizeof(__u8) WDC_FB_CA_LOG_BUF_LEN0x80);
7561	if (!data) {
7562	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7563	return -1;
7564	}
7565
7566	memset(data, 0, sizeof(__u8) * WDC_FB_CA_LOG_BUF_LEN0x80);
7567
7568	ret = nvme_get_log_simple(hdl,
7569	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA,
7570	data, WDC_FB_CA_LOG_BUF_LEN0x80);
7571	if (strcmp(format, "json"))
7572	nvme_show_status(ret);
7573
7574	if (!ret) {
7575	/* parse the data */
7576	perf = (struct wdc_ssd_ca_perf_stats *)(data);
7577	ret = wdc_print_fb_ca_log(perf, fmt);
7578	} else {
7579	fprintf(stderrstderr, "ERROR: WDC: Unable to read CA Log Page data\n");
7580	ret = -1;
7581	}
7582	} else if ((cust_id == WDC_CUSTOMER_ID_GN0x0001) \|\| (cust_id == WDC_CUSTOMER_ID_GD0x0101) \|\|
7583	(cust_id == WDC_CUSTOMER_ID_BD0x1009)) {
7584	data = (__u8 )malloc(sizeof(__u8) WDC_BD_CA_LOG_BUF_LEN0xA0);
7585	if (!data) {
7586	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7587	return -1;
7588	}
7589
7590	memset(data, 0, sizeof(__u8) * WDC_BD_CA_LOG_BUF_LEN0xA0);
7591	ret = nvme_get_log_simple(hdl,
7592	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA,
7593	data, WDC_BD_CA_LOG_BUF_LEN0xA0);
7594	if (strcmp(format, "json"))
7595	nvme_show_status(ret);
7596
7597	if (!ret) {
7598	/* parse the data */
7599	ret = wdc_print_bd_ca_log(hdl, data, fmt);
7600	} else {
7601	fprintf(stderrstderr, "ERROR: WDC: Unable to read CA Log Page data\n");
7602	ret = -1;
7603	}
7604	} else {
7605	fprintf(stderrstderr, "ERROR: WDC: Unsupported Customer id, id = 0x%x\n", cust_id);
7606	return -1;
7607	}
7608	break;
7609	default:
7610	fprintf(stderrstderr, "ERROR: WDC: Log page 0xCA not supported for this device\n");
7611	return -1;
7612	}
7613
7614	free(data);
7615	return ret;
7616	}
7617
7618	static int wdc_get_c1_log_page(struct libnvme_global_ctx *ctx,
7619	struct libnvme_transport_handle hdl, char format,
7620	uint8_t interval)
7621	{
7622	struct wdc_log_page_subpage_header *sph;
7623	struct wdc_ssd_perf_stats *perf;
7624	struct wdc_log_page_header *l;
7625	nvme_print_flags_t fmt;
7626	int total_subpages;
7627	int skip_cnt = 4;
7628	__u8 *data;
7629	__u8 *p;
7630	int i;
7631	int ret;
7632
7633	if (!wdc_check_device(ctx, hdl))
7634	return -1;
7635
7636	ret = validate_output_format(format, &fmt);
7637	if (ret < 0) {
7638	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
7639	return ret;
7640	}
7641
7642	if (interval < 1 \|\| interval > 15) {
7643	fprintf(stderrstderr, "ERROR: WDC: interval out of range [1-15]\n");
7644	return -1;
7645	}
7646
7647	data = (__u8 )malloc(sizeof(__u8) WDC_ADD_LOG_BUF_LEN0x4000);
7648	if (!data) {
7649	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7650	return -1;
7651	}
7652	memset(data, 0, sizeof(__u8) * WDC_ADD_LOG_BUF_LEN0x4000);
7653
7654	ret = nvme_get_log_simple(hdl, WDC_NVME_ADD_LOG_OPCODE0xC1,
7655	data, WDC_ADD_LOG_BUF_LEN0x4000);
7656	if (strcmp(format, "json"))
7657	nvme_show_status(ret);
7658	if (!ret) {
7659	l = (struct wdc_log_page_header *)data;
7660	total_subpages = l->num_subpages + WDC_NVME_GET_STAT_PERF_INTERVAL_LIFETIME0x0F - 1;
7661	for (i = 0, p = data + skip_cnt; i < total_subpages; i++, p += skip_cnt) {
7662	sph = (struct wdc_log_page_subpage_header *)p;
7663	if (sph->spcode == WDC_GET_LOG_PAGE_SSD_PERFORMANCE0x37) {
7664	if (sph->pcset == interval) {
7665	perf = (struct wdc_ssd_perf_stats *)(p + 4);
7666	ret = wdc_print_log(perf, fmt);
7667	break;
7668	}
7669	}
7670	skip_cnt = le16_to_cpu(sph->subpage_length) + 4;
7671	}
7672	if (ret)
7673	fprintf(stderrstderr, "ERROR: WDC: Unable to read data from buffer\n");
7674	}
7675	free(data);
7676	return ret;
7677	}
7678
7679	static int wdc_get_c3_log_page(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char *format)
7680	{
7681	struct wdc_ssd_latency_monitor_log *log_data;
7682	nvme_print_flags_t fmt;
7683	__u8 *data;
7684	int ret;
7685	int i;
7686
7687	if (!wdc_check_device(ctx, hdl))
7688	return -1;
7689
7690	ret = validate_output_format(format, &fmt);
7691	if (ret < 0) {
7692	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
7693	return ret;
7694	}
7695
7696	data = (__u8 )malloc(sizeof(__u8) WDC_LATENCY_MON_LOG_BUF_LEN0x200);
7697	if (!data) {
7698	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7699	return -1;
7700	}
7701	memset(data, 0, sizeof(__u8) * WDC_LATENCY_MON_LOG_BUF_LEN0x200);
7702
7703	ret = nvme_get_log_simple(hdl, WDC_LATENCY_MON_LOG_ID0xC3,
7704	data, WDC_LATENCY_MON_LOG_BUF_LEN0x200);
7705
7706	if (strcmp(format, "json"))
7707	fprintf(stderrstderr, "NVMe Status:%s(%x)\n", libnvme_status_to_string(ret, false0), ret);
7708
7709	if (!ret) {
7710	log_data = (struct wdc_ssd_latency_monitor_log *)data;
7711
7712	/* check log page version */
7713	if (log_data->log_page_version != WDC_LATENCY_MON_VERSION0x0001) {
7714	fprintf(stderrstderr, "ERROR: WDC: invalid latency monitor version\n");
7715	ret = -1;
7716	goto out;
7717	}
7718
7719	/* check log page guid */
7720	/* Verify GUID matches */
7721	for (i = 0; i < 16; i++) {
7722	if (wdc_lat_mon_guid[i] != log_data->log_page_guid[i]) {
7723	fprintf(stderrstderr, "ERROR: WDC: Unknown GUID in C3 Log Page data\n");
7724	int j;
7725
7726	fprintf(stderrstderr, "ERROR: WDC: Expected GUID: 0x");
7727	for (j = 0; j < 16; j++)
7728	fprintf(stderrstderr, "%x", wdc_lat_mon_guid[j]);
7729	fprintf(stderrstderr, "\nERROR: WDC: Actual GUID: 0x");
7730	for (j = 0; j < 16; j++)
7731	fprintf(stderrstderr, "%x", log_data->log_page_guid[j]);
7732	fprintf(stderrstderr, "\n");
7733
7734	ret = -1;
7735	goto out;
7736	}
7737	}
7738
7739	/* parse the data */
7740	wdc_print_latency_monitor_log(hdl, log_data, fmt);
7741	} else {
7742	fprintf(stderrstderr, "ERROR: WDC: Unable to read C3 data from buffer\n");
7743	}
7744
7745	out:
7746	free(data);
7747	return ret;
7748
7749	}
7750
7751	static int wdc_get_ocp_c1_log_page(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char *format)
7752	{
7753	struct wdc_ocp_c1_error_recovery_log *log_data;
7754	nvme_print_flags_t fmt;
7755	__u8 *data;
7756	int ret;
7757	int i;
7758
7759	if (!wdc_check_device(ctx, hdl))
7760	return -1;
7761
7762	ret = validate_output_format(format, &fmt);
7763	if (ret < 0) {
7764	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
7765	return ret;
7766	}
7767
7768	data = (__u8 )malloc(sizeof(__u8) WDC_ERROR_REC_LOG_BUF_LEN512);
7769	if (!data) {
7770	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7771	return -1;
7772	}
7773	memset(data, 0, sizeof(__u8) * WDC_ERROR_REC_LOG_BUF_LEN512);
7774
7775	ret = nvme_get_log_simple(hdl, WDC_ERROR_REC_LOG_ID0xC1,
7776	data, WDC_ERROR_REC_LOG_BUF_LEN512);
7777
7778	if (strcmp(format, "json"))
7779	fprintf(stderrstderr, "NVMe Status:%s(%x)\n", libnvme_status_to_string(ret, false0), ret);
7780
7781	if (!ret) {
7782	log_data = (struct wdc_ocp_c1_error_recovery_log *)data;
7783
7784	/* check log page version */
7785	if ((log_data->log_page_version < 1) \|\|
7786	(log_data->log_page_version > 3)) {
7787	fprintf(stderrstderr, "ERROR: WDC: invalid error recovery log version - %d\n",
7788	log_data->log_page_version);
7789	ret = -1;
7790	goto out;
7791	}
7792
7793	/* Verify GUID matches */
7794	for (i = 0; i < WDC_OCP_C1_GUID_LENGTH16; i++) {
7795	if (wdc_ocp_c1_guid[i] != log_data->log_page_guid[i]) {
7796	fprintf(stderrstderr, "ERROR: WDC: Unknown GUID in C1 Log Page data\n");
7797	int j;
7798
7799	fprintf(stderrstderr, "ERROR: WDC: Expected GUID: 0x");
7800	for (j = 0; j < 16; j++)
7801	fprintf(stderrstderr, "%x", wdc_ocp_c1_guid[j]);
7802	fprintf(stderrstderr, "\nERROR: WDC: Actual GUID: 0x");
7803	for (j = 0; j < 16; j++)
7804	fprintf(stderrstderr, "%x", log_data->log_page_guid[j]);
7805	fprintf(stderrstderr, "\n");
7806
7807	ret = -1;
7808	goto out;
7809	}
7810	}
7811
7812	/* parse the data */
7813	wdc_print_error_rec_log(log_data, fmt);
7814	} else {
7815	fprintf(stderrstderr, "ERROR: WDC: Unable to read error recovery (C1) data from buffer\n");
7816	}
7817
7818	out:
7819	free(data);
7820	return ret;
7821	}
7822
7823	static int wdc_get_ocp_c4_log_page(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char *format)
7824	{
7825	struct wdc_ocp_C4_dev_cap_log *log_data;
7826	nvme_print_flags_t fmt;
7827	__u8 *data;
7828	int ret;
7829	int i;
7830
7831	if (!wdc_check_device(ctx, hdl))
7832	return -1;
7833
7834	ret = validate_output_format(format, &fmt);
7835	if (ret < 0) {
7836	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
7837	return ret;
7838	}
7839
7840	data = (__u8 )malloc(sizeof(__u8) WDC_DEV_CAP_LOG_BUF_LEN4096);
7841	if (!data) {
7842	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7843	return -1;
7844	}
7845	memset(data, 0, sizeof(__u8) * WDC_DEV_CAP_LOG_BUF_LEN4096);
7846
7847	ret = nvme_get_log_simple(hdl, WDC_DEV_CAP_LOG_ID0xC4,
7848	data, WDC_DEV_CAP_LOG_BUF_LEN4096);
7849
7850	if (strcmp(format, "json"))
7851	fprintf(stderrstderr, "NVMe Status:%s(%x)\n", libnvme_status_to_string(ret, false0), ret);
7852
7853	if (!ret) {
7854	log_data = (struct wdc_ocp_C4_dev_cap_log *)data;
7855
7856	/* check log page version */
7857	if (log_data->log_page_version != WDC_DEV_CAP_LOG_VERSION0001) {
7858	fprintf(stderrstderr, "ERROR: WDC: invalid device capabilities log version - %d\n", log_data->log_page_version);
7859	ret = -1;
7860	goto out;
7861	}
7862
7863	/* Verify GUID matches */
7864	for (i = 0; i < WDC_OCP_C4_GUID_LENGTH16; i++) {
7865	if (wdc_ocp_c4_guid[i] != log_data->log_page_guid[i]) {
7866	fprintf(stderrstderr, "ERROR: WDC: Unknown GUID in C4 Log Page data\n");
7867	int j;
7868
7869	fprintf(stderrstderr, "ERROR: WDC: Expected GUID: 0x");
7870	for (j = 0; j < 16; j++)
7871	fprintf(stderrstderr, "%x", wdc_ocp_c4_guid[j]);
7872	fprintf(stderrstderr, "\nERROR: WDC: Actual GUID: 0x");
7873	for (j = 0; j < 16; j++)
7874	fprintf(stderrstderr, "%x", log_data->log_page_guid[j]);
7875	fprintf(stderrstderr, "\n");
7876
7877	ret = -1;
7878	goto out;
7879	}
7880	}
7881
7882	/* parse the data */
7883	wdc_print_dev_cap_log(log_data, fmt);
7884	} else {
7885	fprintf(stderrstderr, "ERROR: WDC: Unable to read device capabilities (C4) data from buffer\n");
7886	}
7887
7888	out:
7889	free(data);
7890	return ret;
7891	}
7892
7893	static int wdc_get_ocp_c5_log_page(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char *format)
7894	{
7895	struct wdc_ocp_C5_unsupported_reqs *log_data;
7896	nvme_print_flags_t fmt;
7897	int ret;
7898	__u8 *data;
7899	int i;
7900
7901	if (!wdc_check_device(ctx, hdl))
7902	return -1;
7903
7904	ret = validate_output_format(format, &fmt);
7905	if (ret < 0) {
7906	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
7907	return ret;
7908	}
7909
7910	data = (__u8 )malloc(sizeof(__u8) WDC_UNSUPPORTED_REQS_LOG_BUF_LEN4096);
7911	if (!data) {
7912	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7913	return -1;
7914	}
7915	memset(data, 0, sizeof(__u8) * WDC_UNSUPPORTED_REQS_LOG_BUF_LEN4096);
7916
7917	ret = nvme_get_log_simple(hdl, WDC_UNSUPPORTED_REQS_LOG_ID0xC5,
7918	data, WDC_UNSUPPORTED_REQS_LOG_BUF_LEN4096);
7919
7920	if (strcmp(format, "json"))
7921	fprintf(stderrstderr, "NVMe Status:%s(%x)\n", libnvme_status_to_string(ret, false0), ret);
7922
7923	if (!ret) {
7924	log_data = (struct wdc_ocp_C5_unsupported_reqs *)data;
7925
7926	/* check log page version */
7927	if (log_data->log_page_version != WDC_UNSUPPORTED_REQS_LOG_VERSION0001) {
7928	fprintf(stderrstderr, "ERROR: WDC: invalid 0xC5 log page version\n");
7929	fprintf(stderrstderr, "ERROR: WDC: log page version: %d\n",
7930	log_data->log_page_version);
7931	ret = -1;
7932	goto out;
7933	}
7934
7935	/* Verify GUID matches */
7936	for (i = 0; i < WDC_OCP_C5_GUID_LENGTH16; i++) {
7937	if (wdc_ocp_c5_guid[i] != log_data->log_page_guid[i]) {
7938	fprintf(stderrstderr, "ERROR: WDC: Unknown GUID in C5 Log Page data\n");
7939	int j;
7940
7941	fprintf(stderrstderr, "ERROR: WDC: Expected GUID: 0x");
7942	for (j = 0; j < 16; j++)
7943	fprintf(stderrstderr, "%x", wdc_ocp_c5_guid[j]);
7944	fprintf(stderrstderr, "\nERROR: WDC: Actual GUID: 0x");
7945	for (j = 0; j < 16; j++)
7946	fprintf(stderrstderr, "%x", log_data->log_page_guid[j]);
7947	fprintf(stderrstderr, "\n");
7948
7949	ret = -1;
7950	goto out;
7951	}
7952	}
7953
7954	/* parse the data */
7955	wdc_print_unsupported_reqs_log(log_data, fmt);
7956	} else {
7957	fprintf(stderrstderr, "ERROR: WDC: Unable to read unsupported requirements (C5) data from buffer\n");
7958	}
7959
7960	out:
7961	free(data);
7962	return ret;
7963	}
7964
7965	static int wdc_get_d0_log_page(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl, char *format)
7966	{
7967	struct wdc_ssd_d0_smart_log *perf;
7968	nvme_print_flags_t fmt;
7969	int ret = 0;
7970	__u8 *data;
7971
7972	if (!wdc_check_device(ctx, hdl))
7973	return -1;
7974
7975	ret = validate_output_format(format, &fmt);
7976	if (ret < 0) {
7977	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
7978	return ret;
7979	}
7980
7981	/* verify the 0xD0 log page is supported */
7982	if (wdc_nvme_check_supported_log_page(ctx, hdl,
7983	WDC_NVME_GET_VU_SMART_LOG_OPCODE0xD0, 0) == false0) {
7984	fprintf(stderrstderr, "ERROR: WDC: 0xD0 Log Page not supported\n");
7985	return -1;
7986	}
7987
7988	data = (__u8 )malloc(sizeof(__u8) WDC_NVME_VU_SMART_LOG_LEN0x200);
7989	if (!data) {
7990	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
7991	return -1;
7992	}
7993	memset(data, 0, sizeof(__u8) * WDC_NVME_VU_SMART_LOG_LEN0x200);
7994
7995	ret = nvme_get_log_simple(hdl,
7996	WDC_NVME_GET_VU_SMART_LOG_OPCODE0xD0,
7997	data, WDC_NVME_VU_SMART_LOG_LEN0x200);
7998	if (strcmp(format, "json"))
7999	nvme_show_status(ret);
8000
8001	if (!ret) {
8002	/* parse the data */
8003	perf = (struct wdc_ssd_d0_smart_log *)(data);
8004	ret = wdc_print_d0_log(perf, fmt);
8005	} else {
8006	fprintf(stderrstderr, "ERROR: WDC: Unable to read D0 Log Page data\n");
8007	ret = -1;
8008	}
8009
8010	free(data);
8011	return ret;
8012	}
8013
8014	static long double le_to_float(__u8 *data, int byte_len)
8015	{
8016	long double result = 0;
8017	int i;
8018
8019	for (i = 0; i < byte_len; i++) {
8020	result *= 256;
8021	result += data[15 - i];
8022	}
8023
8024	return result;
8025	}
8026
8027	static void stringify_log_page_guid(__u8 guid, char buf)
8028	{
8029	char *ptr = buf;
8030	int i;
8031
8032	memset(buf, 0, sizeof(char) * 19);
8033
8034	ptr += sprintf(ptr, "0x");
8035	for (i = 0; i < 16; i++)
8036	ptr += sprintf(ptr, "%x", guid[15 - i]);
8037	}
8038
8039	static const char *const cloud_smart_log_thermal_status[] = {
8040	[0x00] = "unthrottled",
8041	[0x01] = "first_level",
8042	[0x02] = "second_level",
8043	[0x03] = "third_level",
8044	};
8045
8046	static const char *stringify_cloud_smart_log_thermal_status(__u8 status)
8047	{
8048	if (status < ARRAY_SIZE(cloud_smart_log_thermal_status)(sizeof(cloud_smart_log_thermal_status) / sizeof((cloud_smart_log_thermal_status )[0])) &&
8049	cloud_smart_log_thermal_status[status])
8050	return cloud_smart_log_thermal_status[status];
8051	return "unrecognized";
8052	}
8053
8054	static void wdc_show_cloud_smart_log_json(struct ocp_cloud_smart_log *log)
8055	{
8056	struct json_object *root;
8057	struct json_object *bad_user_nand_blocks;
8058	struct json_object *bad_system_nand_blocks;
8059	struct json_object *e2e_correction_counts;
8060	struct json_object *user_data_erase_counts;
8061	struct json_object *thermal_status;
8062	struct json_object *dssd_specific_ver;
8063	char buf[2 * sizeof(log->log_page_guid) + 3];
8064	char lowest_fr[sizeof(log->lowest_permitted_fw_rev) + 1];
8065	uint16_t smart_log_ver = (uint16_t)le16_to_cpu(log->log_page_version);
8066
8067	bad_user_nand_blocks = json_create_object()json_object_new_object();
8068	json_object_add_value_uint(bad_user_nand_blocks, "normalized",json_object_object_add(bad_user_nand_blocks, "normalized", json_object_new_uint64 (le16_to_cpu(log->bad_user_nand_blocks.normalized)))
8069	le16_to_cpu(log->bad_user_nand_blocks.normalized))json_object_object_add(bad_user_nand_blocks, "normalized", json_object_new_uint64 (le16_to_cpu(log->bad_user_nand_blocks.normalized)));
8070	json_object_add_value_uint(bad_user_nand_blocks, "raw",json_object_object_add(bad_user_nand_blocks, "raw", json_object_new_uint64 (le64_to_cpu(log->bad_user_nand_blocks.raw)))
8071	le64_to_cpu(log->bad_user_nand_blocks.raw))json_object_object_add(bad_user_nand_blocks, "raw", json_object_new_uint64 (le64_to_cpu(log->bad_user_nand_blocks.raw)));
8072
8073	bad_system_nand_blocks = json_create_object()json_object_new_object();
8074	json_object_add_value_uint(bad_system_nand_blocks, "normalized",json_object_object_add(bad_system_nand_blocks, "normalized", json_object_new_uint64 (le16_to_cpu(log->bad_system_nand_blocks.normalized)))
8075	le16_to_cpu(log->bad_system_nand_blocks.normalized))json_object_object_add(bad_system_nand_blocks, "normalized", json_object_new_uint64 (le16_to_cpu(log->bad_system_nand_blocks.normalized)));
8076	json_object_add_value_uint(bad_system_nand_blocks, "raw",json_object_object_add(bad_system_nand_blocks, "raw", json_object_new_uint64 (le64_to_cpu(log->bad_system_nand_blocks.raw)))
8077	le64_to_cpu(log->bad_system_nand_blocks.raw))json_object_object_add(bad_system_nand_blocks, "raw", json_object_new_uint64 (le64_to_cpu(log->bad_system_nand_blocks.raw)));
8078
8079	e2e_correction_counts = json_create_object()json_object_new_object();
8080	json_object_add_value_uint(e2e_correction_counts, "corrected",json_object_object_add(e2e_correction_counts, "corrected", json_object_new_uint64 (le32_to_cpu(log->e2e_correction_counts.corrected)))
8081	le32_to_cpu(log->e2e_correction_counts.corrected))json_object_object_add(e2e_correction_counts, "corrected", json_object_new_uint64 (le32_to_cpu(log->e2e_correction_counts.corrected)));
8082	json_object_add_value_uint(e2e_correction_counts, "detected",json_object_object_add(e2e_correction_counts, "detected", json_object_new_uint64 (le32_to_cpu(log->e2e_correction_counts.detected)))
8083	le32_to_cpu(log->e2e_correction_counts.detected))json_object_object_add(e2e_correction_counts, "detected", json_object_new_uint64 (le32_to_cpu(log->e2e_correction_counts.detected)));
8084
8085	user_data_erase_counts = json_create_object()json_object_new_object();
8086	json_object_add_value_uint(user_data_erase_counts, "minimum",json_object_object_add(user_data_erase_counts, "minimum", json_object_new_uint64 (le32_to_cpu(log->user_data_erase_counts.minimum)))
8087	le32_to_cpu(log->user_data_erase_counts.minimum))json_object_object_add(user_data_erase_counts, "minimum", json_object_new_uint64 (le32_to_cpu(log->user_data_erase_counts.minimum)));
8088	json_object_add_value_uint(user_data_erase_counts, "maximum",json_object_object_add(user_data_erase_counts, "maximum", json_object_new_uint64 (le32_to_cpu(log->user_data_erase_counts.maximum)))
8089	le32_to_cpu(log->user_data_erase_counts.maximum))json_object_object_add(user_data_erase_counts, "maximum", json_object_new_uint64 (le32_to_cpu(log->user_data_erase_counts.maximum)));
8090
8091	thermal_status = json_create_object()json_object_new_object();
8092	json_object_add_value_string(thermal_status, "current_status",
8093	stringify_cloud_smart_log_thermal_status(log->thermal_status.current_status));
8094	json_object_add_value_uint(thermal_status, "num_events",json_object_object_add(thermal_status, "num_events", json_object_new_uint64 (log->thermal_status.num_events))
8095	log->thermal_status.num_events)json_object_object_add(thermal_status, "num_events", json_object_new_uint64 (log->thermal_status.num_events));
8096
8097	dssd_specific_ver = json_create_object()json_object_new_object();
8098	json_object_add_value_uint(dssd_specific_ver, "major_ver",json_object_object_add(dssd_specific_ver, "major_ver", json_object_new_uint64 (log->dssd_specific_ver.major_ver))
8099	log->dssd_specific_ver.major_ver)json_object_object_add(dssd_specific_ver, "major_ver", json_object_new_uint64 (log->dssd_specific_ver.major_ver));
8100	json_object_add_value_uint(dssd_specific_ver, "minor_ver",json_object_object_add(dssd_specific_ver, "minor_ver", json_object_new_uint64 (le16_to_cpu(log->dssd_specific_ver.minor_ver)))
8101	le16_to_cpu(log->dssd_specific_ver.minor_ver))json_object_object_add(dssd_specific_ver, "minor_ver", json_object_new_uint64 (le16_to_cpu(log->dssd_specific_ver.minor_ver)));
8102	json_object_add_value_uint(dssd_specific_ver, "point_ver",json_object_object_add(dssd_specific_ver, "point_ver", json_object_new_uint64 (le16_to_cpu(log->dssd_specific_ver.point_ver)))
8103	le16_to_cpu(log->dssd_specific_ver.point_ver))json_object_object_add(dssd_specific_ver, "point_ver", json_object_new_uint64 (le16_to_cpu(log->dssd_specific_ver.point_ver)));
8104	json_object_add_value_uint(dssd_specific_ver, "errata_ver",json_object_object_add(dssd_specific_ver, "errata_ver", json_object_new_uint64 (log->dssd_specific_ver.errata_ver))
8105	log->dssd_specific_ver.errata_ver)json_object_object_add(dssd_specific_ver, "errata_ver", json_object_new_uint64 (log->dssd_specific_ver.errata_ver));
8106
8107	root = json_create_object()json_object_new_object();
8108	json_object_add_value_uint64(root, "physical_media_units_written",json_object_object_add(root, "physical_media_units_written", json_object_new_uint64 (le_to_float(log->physical_media_units_written, 16)))
8109	le_to_float(log->physical_media_units_written, 16))json_object_object_add(root, "physical_media_units_written", json_object_new_uint64 (le_to_float(log->physical_media_units_written, 16)));
8110	json_object_add_value_uint64(root, "physical_media_units_read",json_object_object_add(root, "physical_media_units_read", json_object_new_uint64 (le_to_float(log->physical_media_units_read, 16)))
8111	le_to_float(log->physical_media_units_read, 16))json_object_object_add(root, "physical_media_units_read", json_object_new_uint64 (le_to_float(log->physical_media_units_read, 16)));
8112	json_object_add_value_object(root, "bad_user_nand_blocks",json_object_object_add(root, "bad_user_nand_blocks", bad_user_nand_blocks )
8113	bad_user_nand_blocks)json_object_object_add(root, "bad_user_nand_blocks", bad_user_nand_blocks );
8114	json_object_add_value_object(root, "bad_system_nand_blocks",json_object_object_add(root, "bad_system_nand_blocks", bad_system_nand_blocks )
8115	bad_system_nand_blocks)json_object_object_add(root, "bad_system_nand_blocks", bad_system_nand_blocks );
8116	json_object_add_value_uint(root, "xor_recovery_count",json_object_object_add(root, "xor_recovery_count", json_object_new_uint64 (le64_to_cpu(log->xor_recovery_count)))
8117	le64_to_cpu(log->xor_recovery_count))json_object_object_add(root, "xor_recovery_count", json_object_new_uint64 (le64_to_cpu(log->xor_recovery_count)));
8118	json_object_add_value_uint(root, "uncorrectable_read_error_count",json_object_object_add(root, "uncorrectable_read_error_count" , json_object_new_uint64(le64_to_cpu(log->uncorrectable_read_error_count )))
8119	le64_to_cpu(log->uncorrectable_read_error_count))json_object_object_add(root, "uncorrectable_read_error_count" , json_object_new_uint64(le64_to_cpu(log->uncorrectable_read_error_count )));
8120	json_object_add_value_uint(root, "soft_ecc_error_count",json_object_object_add(root, "soft_ecc_error_count", json_object_new_uint64 (le64_to_cpu(log->soft_ecc_error_count)))
8121	le64_to_cpu(log->soft_ecc_error_count))json_object_object_add(root, "soft_ecc_error_count", json_object_new_uint64 (le64_to_cpu(log->soft_ecc_error_count)));
8122	json_object_add_value_object(root, "e2e_correction_counts",json_object_object_add(root, "e2e_correction_counts", e2e_correction_counts )
8123	e2e_correction_counts)json_object_object_add(root, "e2e_correction_counts", e2e_correction_counts );
8124	json_object_add_value_uint(root, "system_data_percent_used",json_object_object_add(root, "system_data_percent_used", json_object_new_uint64 (log->system_data_percent_used))
8125	log->system_data_percent_used)json_object_object_add(root, "system_data_percent_used", json_object_new_uint64 (log->system_data_percent_used));
8126	json_object_add_value_uint(root, "refresh_counts",json_object_object_add(root, "refresh_counts", json_object_new_uint64 (le64_to_cpu(log->refresh_counts)))
8127	le64_to_cpu(log->refresh_counts))json_object_object_add(root, "refresh_counts", json_object_new_uint64 (le64_to_cpu(log->refresh_counts)));
8128	json_object_add_value_object(root, "user_data_erase_counts",json_object_object_add(root, "user_data_erase_counts", user_data_erase_counts )
8129	user_data_erase_counts)json_object_object_add(root, "user_data_erase_counts", user_data_erase_counts );
8130	json_object_add_value_object(root, "thermal_status", thermal_status)json_object_object_add(root, "thermal_status", thermal_status );
8131	if (smart_log_ver >= 3)
8132	json_object_add_value_object(root, "dssd_specific_ver",json_object_object_add(root, "dssd_specific_ver", dssd_specific_ver )
8133	dssd_specific_ver)json_object_object_add(root, "dssd_specific_ver", dssd_specific_ver );
8134	json_object_add_value_uint(root, "pcie_correctable_error_count",json_object_object_add(root, "pcie_correctable_error_count", json_object_new_uint64 (le64_to_cpu(log->pcie_correctable_error_count)))
8135	le64_to_cpu(log->pcie_correctable_error_count))json_object_object_add(root, "pcie_correctable_error_count", json_object_new_uint64 (le64_to_cpu(log->pcie_correctable_error_count)));
8136	json_object_add_value_uint(root, "incomplete_shutdowns",json_object_object_add(root, "incomplete_shutdowns", json_object_new_uint64 (le32_to_cpu(log->incomplete_shutdowns)))
8137	le32_to_cpu(log->incomplete_shutdowns))json_object_object_add(root, "incomplete_shutdowns", json_object_new_uint64 (le32_to_cpu(log->incomplete_shutdowns)));
8138	json_object_add_value_uint(root, "percent_free_blocks",json_object_object_add(root, "percent_free_blocks", json_object_new_uint64 (log->percent_free_blocks))
8139	log->percent_free_blocks)json_object_object_add(root, "percent_free_blocks", json_object_new_uint64 (log->percent_free_blocks));
8140	json_object_add_value_uint(root, "capacitor_health",json_object_object_add(root, "capacitor_health", json_object_new_uint64 (le16_to_cpu(log->capacitor_health)))
8141	le16_to_cpu(log->capacitor_health))json_object_object_add(root, "capacitor_health", json_object_new_uint64 (le16_to_cpu(log->capacitor_health)));
8142	if (smart_log_ver >= 3) {
8143	if (smart_log_ver >= 4) {
8144	sprintf(buf, "%c", log->nvme_base_errata_ver);
8145	json_object_add_value_string(root, "nvme_base_errata_version", buf);
8146	sprintf(buf, "%c", log->nvme_cmd_set_errata_ver);
8147	json_object_add_value_string(root, "nvme_cmd_set_errata_version", buf);
8148	} else {
8149	sprintf(buf, "%c", log->nvme_base_errata_ver);
8150	json_object_add_value_string(root, "nvme_errata_version", buf);
8151	}
8152	}
8153
8154	json_object_add_value_uint(root, "unaligned_io",json_object_object_add(root, "unaligned_io", json_object_new_uint64 (le64_to_cpu(log->unaligned_io)))
8155	le64_to_cpu(log->unaligned_io))json_object_object_add(root, "unaligned_io", json_object_new_uint64 (le64_to_cpu(log->unaligned_io)));
8156	json_object_add_value_uint(root, "security_version_number",json_object_object_add(root, "security_version_number", json_object_new_uint64 (le64_to_cpu(log->security_version_number)))
8157	le64_to_cpu(log->security_version_number))json_object_object_add(root, "security_version_number", json_object_new_uint64 (le64_to_cpu(log->security_version_number)));
8158	json_object_add_value_uint(root, "total_nuse",json_object_object_add(root, "total_nuse", json_object_new_uint64 (le64_to_cpu(log->total_nuse)))
8159	le64_to_cpu(log->total_nuse))json_object_object_add(root, "total_nuse", json_object_new_uint64 (le64_to_cpu(log->total_nuse)));
8160	json_object_add_value_uint64(root, "plp_start_count",json_object_object_add(root, "plp_start_count", json_object_new_uint64 (le_to_float(log->plp_start_count, 16)))
8161	le_to_float(log->plp_start_count, 16))json_object_object_add(root, "plp_start_count", json_object_new_uint64 (le_to_float(log->plp_start_count, 16)));
8162	json_object_add_value_uint64(root, "endurance_estimate",json_object_object_add(root, "endurance_estimate", json_object_new_uint64 (le_to_float(log->endurance_estimate, 16)))
8163	le_to_float(log->endurance_estimate, 16))json_object_object_add(root, "endurance_estimate", json_object_new_uint64 (le_to_float(log->endurance_estimate, 16)));
8164	if (smart_log_ver >= 3) {
8165	json_object_add_value_uint(root, "pcie_link_retraining_count",json_object_object_add(root, "pcie_link_retraining_count", json_object_new_uint64 (le64_to_cpu(log->pcie_link_retraining_cnt)))
8166	le64_to_cpu(log->pcie_link_retraining_cnt))json_object_object_add(root, "pcie_link_retraining_count", json_object_new_uint64 (le64_to_cpu(log->pcie_link_retraining_cnt)));
8167	json_object_add_value_uint(root, "power_state_change_count",json_object_object_add(root, "power_state_change_count", json_object_new_uint64 (le64_to_cpu(log->power_state_change_cnt)))
8168	le64_to_cpu(log->power_state_change_cnt))json_object_object_add(root, "power_state_change_count", json_object_new_uint64 (le64_to_cpu(log->power_state_change_cnt)));
8169	if (smart_log_ver >= 4) {
8170	snprintf(lowest_fr, sizeof(lowest_fr), "%-.*s",
8171	(int)sizeof(log->lowest_permitted_fw_rev),
8172	log->lowest_permitted_fw_rev);
8173	json_object_add_value_string(root, "lowest_permitted_fw_rev", lowest_fr);
8174	} else
8175	json_object_add_value_uint128(root, "hardware_revision",json_object_object_add(root, "hardware_revision", util_json_object_new_uint128 (le128_to_cpu((__u8 *)&log->lowest_permitted_fw_rev[0] )))
8176	le128_to_cpu((__u8 )&log->lowest_permitted_fw_rev[0]))json_object_object_add(root, "hardware_revision", util_json_object_new_uint128 (le128_to_cpu((__u8 )&log->lowest_permitted_fw_rev[0] )));
8177	}
8178	json_object_add_value_uint(root, "log_page_version",json_object_object_add(root, "log_page_version", json_object_new_uint64 (smart_log_ver))
8179	smart_log_ver)json_object_object_add(root, "log_page_version", json_object_new_uint64 (smart_log_ver));
8180	stringify_log_page_guid(log->log_page_guid, buf);
8181	json_object_add_value_string(root, "log_page_guid", buf);
8182
8183	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
8184	printf("\n");
8185	json_free_object(root)json_object_put(root);
8186	}
8187
8188	static void wdc_show_cloud_smart_log_normal(struct ocp_cloud_smart_log *log,
8189	struct libnvme_transport_handle *hdl)
8190	{
8191	char buf[2 * sizeof(log->log_page_guid) + 3];
8192	uint16_t smart_log_ver = (uint16_t)le16_to_cpu(log->log_page_version);
8193
8194	printf("SMART Cloud Attributes for NVMe device : %s\n",
8195	libnvme_transport_handle_get_name(hdl));
8196	printf("Physical Media Units Written : %'.0Lf\n",
8197	le_to_float(log->physical_media_units_written, 16));
8198	printf("Physical Media Units Read : %'.0Lf\n",
8199	le_to_float(log->physical_media_units_read, 16));
8200	printf("Bad User NAND Blocks (Normalized) : %" PRIu16"u" "%%\n",
8201	le16_to_cpu(log->bad_user_nand_blocks.normalized));
8202	printf("Bad User NAND Blocks (Raw) : %" PRIu64"l" "u" "\n",
8203	le64_to_cpu(log->bad_user_nand_blocks.raw));
8204	printf("Bad System NAND Blocks (Normalized) : %" PRIu16"u" "%%\n",
8205	le16_to_cpu(log->bad_system_nand_blocks.normalized));
8206	printf("Bad System NAND Blocks (Raw) : %" PRIu64"l" "u" "\n",
8207	le64_to_cpu(log->bad_system_nand_blocks.raw));
8208	printf("XOR Recovery Count : %" PRIu64"l" "u" "\n",
8209	le64_to_cpu(log->xor_recovery_count));
8210	printf("Uncorrectable Read Error Count : %" PRIu64"l" "u" "\n",
8211	le64_to_cpu(log->uncorrectable_read_error_count));
8212	printf("Soft ECC Error Count : %" PRIu64"l" "u" "\n",
8213	le64_to_cpu(log->soft_ecc_error_count));
8214	printf("End to End Correction Counts (Corrected) : %" PRIu32"u" "\n",
8215	le32_to_cpu(log->e2e_correction_counts.corrected));
8216	printf("End to End Correction Counts (Detected) : %" PRIu32"u" "\n",
8217	le32_to_cpu(log->e2e_correction_counts.detected));
8218	printf("System Data %% Used : %" PRIu8"u" "%%\n",
8219	log->system_data_percent_used);
8220	printf("Refresh Counts : %" PRIu64"l" "u" "\n",
8221	le64_to_cpu(log->refresh_counts));
8222	printf("User Data Erase Counts (Minimum) : %" PRIu32"u" "\n",
8223	le32_to_cpu(log->user_data_erase_counts.minimum));
8224	printf("User Data Erase Counts (Maximum) : %" PRIu32"u" "\n",
8225	le32_to_cpu(log->user_data_erase_counts.maximum));
8226	printf("Thermal Throttling Status (Current Status) : %s\n",
8227	stringify_cloud_smart_log_thermal_status(log->thermal_status.current_status));
8228	printf("Thermal Throttling Status (Number of Events) : %" PRIu8"u" "\n",
8229	log->thermal_status.num_events);
8230	if (smart_log_ver >= 3) {
8231	printf("NVMe Major Version : %" PRIu8"u" "\n",
8232	log->dssd_specific_ver.major_ver);
8233	printf(" Minor Version : %" PRIu16"u" "\n",
8234	le16_to_cpu(log->dssd_specific_ver.minor_ver));
8235	printf(" Point Version : %" PRIu16"u" "\n",
8236	le16_to_cpu(log->dssd_specific_ver.point_ver));
8237	printf(" Errata Version : %" PRIu8"u" "\n",
8238	log->dssd_specific_ver.errata_ver);
8239	}
8240	printf("PCIe Correctable Error Count : %" PRIu64"l" "u" "\n",
8241	le64_to_cpu(log->pcie_correctable_error_count));
8242	printf("Incomplete Shutdowns : %" PRIu32"u" "\n",
8243	le32_to_cpu(log->incomplete_shutdowns));
8244	printf("%% Free Blocks : %" PRIu8"u" "%%\n",
8245	log->percent_free_blocks);
8246	printf("Capacitor Health : %" PRIu16"u" "%%\n",
8247	le16_to_cpu(log->capacitor_health));
8248	if (smart_log_ver >= 3) {
8249	if (smart_log_ver >= 4) {
8250	printf("NVMe Base Errata Version : %c\n",
8251	log->nvme_base_errata_ver);
8252	printf("NVMe Command Set Errata Version : %c\n",
8253	log->nvme_cmd_set_errata_ver);
8254	} else {
8255	printf("NVMe Errata Version : %c\n",
8256	log->nvme_base_errata_ver);
8257	}
8258	}
8259	printf("Unaligned IO : %" PRIu64"l" "u" "\n",
8260	le64_to_cpu(log->unaligned_io));
8261	printf("Security Version Number : %" PRIu64"l" "u" "\n",
8262	le64_to_cpu(log->security_version_number));
8263	printf("Total NUSE : %" PRIu64"l" "u" "\n",
8264	le64_to_cpu(log->total_nuse));
8265	printf("PLP Start Count : %'.0Lf\n",
8266	le_to_float(log->plp_start_count, 16));
8267	printf("Endurance Estimate : %'.0Lf\n",
8268	le_to_float(log->endurance_estimate, 16));
8269	if (smart_log_ver >= 3) {
8270	printf("PCIe Link Retraining Count : %" PRIu64"l" "u" "\n",
8271	le64_to_cpu(log->pcie_link_retraining_cnt));
8272	printf("Power State Change Count : %" PRIu64"l" "u" "\n",
8273	le64_to_cpu(log->power_state_change_cnt));
8274	if (smart_log_ver >= 4)
8275	printf("Lowest Permitted FW Revision : %-.*s\n",
8276	(int)sizeof(log->lowest_permitted_fw_rev),
8277	log->lowest_permitted_fw_rev);
8278	else
8279	printf("Hardware Revision : %s\n",
8280	uint128_t_to_string(le128_to_cpu(
8281	(__u8 *)&log->lowest_permitted_fw_rev[0])));
8282	}
8283	printf("Log Page Version : %" PRIu16"u" "\n",
8284	smart_log_ver);
8285	stringify_log_page_guid(log->log_page_guid, buf);
8286	printf("Log Page GUID : %s\n", buf);
8287	printf("\n\n");
8288	}
8289
8290	static int wdc_vs_smart_add_log(int argc, char *argv, struct command acmd,
8291	struct plugin *plugin)
8292	{
8293	const char *desc = "Retrieve additional performance statistics.";
8294	const char *interval = "Interval to read the statistics from [1, 15].";
8295	const char *log_page_version = "Log Page Version: 0 = vendor, 1 = WDC";
8296	const char *log_page_mask = "Log Page Mask, comma separated list: 0xC0, 0xC1, 0xCA, 0xD0";
8297	const char *namespace_id = "desired namespace id";
8298	nvme_print_flags_t fmt;
8299	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
8300	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
8301	int ret = 0;
8302	int uuid_index = 0;
8303	int page_mask = 0, num, i;
8304	int log_page_list[16];
8305	__u64 capabilities = 0;
8306	__u32 device_id, read_vendor_id;
8307
8308	struct config {
8309	uint8_t interval;
8310	__u8 log_page_version;
8311	char *log_page_mask;
8312	__u32 namespace_id;
8313	};
8314
8315	struct config cfg = {
8316	.interval = 14,
8317	.log_page_version = 0,
8318	.log_page_mask = "",
8319	.namespace_id = NVME_NSID_ALL,
8320	};
8321
8322	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"interval", 'i', "NUM", CFG_POSITIVE, &cfg.interval , 1, interval, 0, }, {"log-page-version", 'l', "NUM", CFG_BYTE , &cfg.log_page_version, 1, log_page_version, 0, }, {"log-page-mask" , 'p', "LIST", CFG_STRING, &cfg.log_page_mask, 1, log_page_mask , 0, }, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
8323	OPT_UINT("interval", 'i', &cfg.interval, interval),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"interval", 'i', "NUM", CFG_POSITIVE, &cfg.interval , 1, interval, 0, }, {"log-page-version", 'l', "NUM", CFG_BYTE , &cfg.log_page_version, 1, log_page_version, 0, }, {"log-page-mask" , 'p', "LIST", CFG_STRING, &cfg.log_page_mask, 1, log_page_mask , 0, }, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
8324	OPT_BYTE("log-page-version", 'l', &cfg.log_page_version, log_page_version),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"interval", 'i', "NUM", CFG_POSITIVE, &cfg.interval , 1, interval, 0, }, {"log-page-version", 'l', "NUM", CFG_BYTE , &cfg.log_page_version, 1, log_page_version, 0, }, {"log-page-mask" , 'p', "LIST", CFG_STRING, &cfg.log_page_mask, 1, log_page_mask , 0, }, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
8325	OPT_LIST("log-page-mask", 'p', &cfg.log_page_mask, log_page_mask),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"interval", 'i', "NUM", CFG_POSITIVE, &cfg.interval , 1, interval, 0, }, {"log-page-version", 'l', "NUM", CFG_BYTE , &cfg.log_page_version, 1, log_page_version, 0, }, {"log-page-mask" , 'p', "LIST", CFG_STRING, &cfg.log_page_mask, 1, log_page_mask , 0, }, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
8326	OPT_UINT("namespace-id", 'n', &cfg.namespace_id, namespace_id))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"interval", 'i', "NUM", CFG_POSITIVE, &cfg.interval , 1, interval, 0, }, {"log-page-version", 'l', "NUM", CFG_BYTE , &cfg.log_page_version, 1, log_page_version, 0, }, {"log-page-mask" , 'p', "LIST", CFG_STRING, &cfg.log_page_mask, 1, log_page_mask , 0, }, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8327
8328	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8329	if (ret)
8330	return ret;
8331
8332	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8333	if (ret)
8334	return ret;
8335
8336	if (!cfg.log_page_version) {
8337	uuid_index = 0;
8338	} else if (cfg.log_page_version == 1) {
8339	uuid_index = 1;
8340	} else {
8341	fprintf(stderrstderr, "ERROR: WDC: unsupported log page version for this command\n");
8342	ret = -1;
8343	goto out;
8344	}
8345
8346	num = argconfig_parse_comma_sep_array(cfg.log_page_mask, log_page_list, 16);
8347
8348	if (num == -1) {
8349	fprintf(stderrstderr, "ERROR: WDC: log page list is malformed\n");
8350	ret = -1;
8351	goto out;
8352	}
8353
8354	if (!num) {
8355	page_mask \|= WDC_ALL_PAGE_MASK0xFFFF;
8356	} else {
8357	for (i = 0; i < num; i++) {
8358	if (log_page_list[i] == 0xc0)
8359	page_mask \|= WDC_C0_PAGE_MASK0x0001;
8360	if (log_page_list[i] == 0xc1)
8361	page_mask \|= WDC_C1_PAGE_MASK0x0002;
8362	if (log_page_list[i] == 0xca)
8363	page_mask \|= WDC_CA_PAGE_MASK0x0004;
8364	if (log_page_list[i] == 0xd0)
8365	page_mask \|= WDC_D0_PAGE_MASK0x0008;
8366	}
8367	}
8368
8369	if (!page_mask)
8370	fprintf(stderrstderr, "ERROR: WDC: Unknown log page mask - %s\n", cfg.log_page_mask);
8371
8372	ret = wdc_get_pci_ids(ctx, hdl, &device_id, &read_vendor_id);
8373
8374	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8375	if (!(capabilities & WDC_DRIVE_CAP_SMART_LOG_MASK(0x0000000000100000 \| 0x0000000000000004 \| 0x0000000000000008 \| 0x0000000000000010))) {
8376	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8377	ret = -1;
8378	goto out;
8379	}
8380
8381	if (((capabilities & WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000) == WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000) &&
8382	(page_mask & WDC_C0_PAGE_MASK0x0001)) {
8383	/* Get 0xC0 log page if possible. */
8384	if (!wdc_is_sn861(device_id)) {
8385	ret = wdc_get_c0_log_page(ctx, hdl,
8386	nvme_args.output_format,
8387	uuid_index, cfg.namespace_id);
8388	if (ret)
8389	fprintf(stderrstderr,
8390	"ERROR: WDC: Failure reading the C0 Log Page, ret = %d\n",
8391	ret);
8392	} else {
8393	ret = validate_output_format(nvme_args.output_format,
8394	&fmt);
8395	if (ret < 0) {
8396	fprintf(stderrstderr, "Invalid output format: %s\n",
8397	nvme_args.output_format);
8398	goto out;
8399	}
8400
8401	ret = nvme_get_print_ocp_cloud_smart_log(hdl,
8402	0,
8403	NVME_NSID_ALL,
8404	fmt);
8405	}
8406	}
8407	if (((capabilities & (WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008)) == (WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008)) &&
8408	(page_mask & WDC_CA_PAGE_MASK0x0004) &&
8409	(!wdc_is_sn861(device_id))) {
8410	/* Get the CA Log Page */
8411	ret = wdc_get_ca_log_page(ctx, hdl, nvme_args.output_format);
8412	if (ret)
8413	fprintf(stderrstderr, "ERROR: WDC: Failure reading the CA Log Page, ret = %d\n", ret);
8414	}
8415	if (((capabilities & WDC_DRIVE_CAP_C1_LOG_PAGE0x0000000000000004) == WDC_DRIVE_CAP_C1_LOG_PAGE0x0000000000000004) &&
8416	(page_mask & WDC_C1_PAGE_MASK0x0002)) {
8417	/* Get the C1 Log Page */
8418	ret = wdc_get_c1_log_page(ctx, hdl, nvme_args.output_format,
8419	cfg.interval);
8420	if (ret)
8421	fprintf(stderrstderr, "ERROR: WDC: Failure reading the C1 Log Page, ret = %d\n", ret);
8422	}
8423	if (((capabilities & WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010) == WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010) &&
8424	(page_mask & WDC_D0_PAGE_MASK0x0008)) {
8425	/* Get the D0 Log Page */
8426	ret = wdc_get_d0_log_page(ctx, hdl, nvme_args.output_format);
8427	if (ret)
8428	fprintf(stderrstderr, "ERROR: WDC: Failure reading the D0 Log Page, ret = %d\n", ret);
8429	}
8430
8431	out:
8432	return ret;
8433	}
8434
8435	static int wdc_cu_smart_log(int argc, char *argv, struct command acmd,
8436	struct plugin *plugin)
8437	{
8438	const char *desc = "Retrieve customer unique smart log statistics.";
8439	const char *uuid_index = "The uuid index to select the correct log page implementation.";
8440	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
8441	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
8442	struct libnvme_passthru_cmd cmd;
8443	int ret = 0;
8444	__u64 capabilities = 0;
8445	uint32_t read_device_id, read_vendor_id;
8446	nvme_print_flags_t fmt;
8447	__u8 *data;
8448
8449	struct config {
8450	int uuid_index;
8451	};
8452
8453	struct config cfg = {
8454	.uuid_index = 0,
8455	};
8456
8457	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"uuid-index", 'u', "NUM", CFG_POSITIVE, &cfg.uuid_index , 1, uuid_index, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
8458	OPT_UINT("uuid-index", 'u', &cfg.uuid_index, uuid_index))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"uuid-index", 'u', "NUM", CFG_POSITIVE, &cfg.uuid_index , 1, uuid_index, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8459
8460	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8461	if (ret)
8462	return ret;
8463
8464	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8465	if (ret)
8466	return ret;
8467
8468	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8469	if (!(capabilities & WDC_DRIVE_CAP_SMART_LOG_MASK(0x0000000000100000 \| 0x0000000000000004 \| 0x0000000000000008 \| 0x0000000000000010))) {
8470	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8471	ret = -1;
8472	goto out;
8473	}
8474
8475	if ((capabilities & WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008) == WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008) {
8476	if (!wdc_check_device(ctx, hdl))
8477	return -1;
8478
8479	ret = validate_output_format(nvme_args.output_format, &fmt);
8480
8481	if (ret < 0) {
8482	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
8483	return ret;
8484	}
8485
8486	/* verify the 0xCA log page is supported */
8487	if (wdc_nvme_check_supported_log_page(ctx, hdl,
8488	WDC_NVME_GET_DEVICE_INFO_LOG_OPCODE0xCA, 0) == false0) {
8489	fprintf(stderrstderr, "ERROR: WDC: 0xCA Log Page not supported\n");
8490	return -1;
8491	}
8492
8493	ret = wdc_get_pci_ids(ctx, hdl, &read_device_id, &read_vendor_id);
8494
8495	switch (read_device_id) {
8496	case WDC_NVME_SN861_DEV_ID0x2750:
8497	case WDC_NVME_SN861_DEV_ID_10x2751:
8498	data = (__u8 *)malloc(WDC_BD_CA_LOG_BUF_LEN0xA0);
8499	if (!data) {
8500	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
8501	ret = -1;
8502	break;
8503	}
8504
8505	memset(data, 0, sizeof(__u8) * WDC_BD_CA_LOG_BUF_LEN0xA0);
8506
8507	/* Get the CA Log Page */
8508	nvme_init_get_log(&cmd, NVME_NSID_ALL,
8509	WDC_NVME_GET_SMART_CLOUD_ATTR_LOG_ID0xC0,
8510	NVME_CSI_NVM, data, WDC_BD_CA_LOG_BUF_LEN0xA0);
8511	cmd.cdw14 \|= NVME_FIELD_ENCODE(cfg.uuid_index,(((__u32)(cfg.uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
8512	NVME_LOG_CDW14_UUID_SHIFT,(((__u32)(cfg.uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT))
8513	NVME_LOG_CDW14_UUID_MASK)(((__u32)(cfg.uuid_index) & (NVME_LOG_CDW14_UUID_MASK)) << (NVME_LOG_CDW14_UUID_SHIFT));
8514	ret = libnvme_get_log(hdl, &cmd, false0,
8515	NVME_LOG_PAGE_PDU_SIZE4096);
8516
8517	if (strcmp(nvme_args.output_format, "json"))
8518	nvme_show_status(ret);
8519
8520	if (!ret) {
8521	/* parse the data */
8522	ret = wdc_print_bd_ca_log(hdl, data, fmt);
8523	} else {
8524	fprintf(stderrstderr, "ERROR: WDC: Unable to read CA Log Page data\n");
8525	ret = -1;
8526	}
8527
8528	free(data);
8529	break;
8530	default:
8531	fprintf(stderrstderr, "ERROR: WDC: Command not supported on this device\n");
8532	ret = -1;
8533	}
8534	} else {
8535	fprintf(stderrstderr, "ERROR: WDC: CA log page supported on this device\n");
8536	ret = -1;
8537	}
8538
8539	out:
8540	return ret;
8541	}
8542
8543	static int wdc_vs_cloud_log(int argc, char *argv, struct command acmd,
8544	struct plugin *plugin)
8545	{
8546	const char *desc = "Retrieve Cloud Log Smart/Health Information";
8547	const char *namespace_id = "desired namespace id";
8548	nvme_print_flags_t fmt;
8549	__u64 capabilities = 0;
8550	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
8551	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
8552	int ret;
8553	__u8 *data;
8554
8555	struct config {
8556	char *output_format;
8557	__u32 namespace_id;
8558	};
8559
8560	struct config cfg = {
8561	.output_format = "normal",
8562	.namespace_id = NVME_NSID_ALL,
8563	};
8564
8565	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
8566	OPT_UINT("namespace-id", 'n', &cfg.namespace_id, namespace_id))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8567
8568	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8569	if (ret)
8570	return ret;
8571
8572	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8573	if (ret)
8574	return ret;
8575
8576	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8577
8578	if (!(capabilities & WDC_DRIVE_CAP_CLOUD_LOG_PAGE0x0000000080000000)) {
8579	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8580	ret = -1;
8581	goto out;
8582	}
8583
8584	data = NULL((void*)0);
8585	ret = nvme_get_ext_smart_cloud_log(hdl, &data, 0,
8586	cfg.namespace_id);
8587
8588	if (strcmp(cfg.output_format, "json"))
8589	nvme_show_status(ret);
8590
8591	if (!ret) {
8592	ret = validate_output_format(cfg.output_format, &fmt);
8593	if (ret < 0) {
8594	fprintf(stderrstderr, "ERROR: WDC %s: invalid output format\n", __func__);
8595	} else {
8596	/* parse the data */
8597	wdc_print_ext_smart_cloud_log(data, fmt);
8598	}
8599	} else {
8600	fprintf(stderrstderr, "ERROR: WDC: Unable to read C0 Log Page V1 data\n");
8601	ret = -1;
8602	}
8603
8604	free(data);
8605
8606	out:
8607	return ret;
8608	}
8609
8610	static int wdc_vs_hw_rev_log(int argc, char *argv, struct command acmd,
8611	struct plugin *plugin)
8612	{
8613	const char *desc = "Retrieve Hardware Revision Log Information";
8614	const char *namespace_id = "desired namespace id";
8615	nvme_print_flags_t fmt;
8616	__u64 capabilities = 0;
8617	struct libnvme_transport_handle *hdl;
8618	int ret;
8619	__u8 data = NULL((void)0);
8620	struct libnvme_global_ctx *ctx;
8621
8622	struct config {
8623	char *output_format;
8624	__u32 namespace_id;
8625	};
8626
8627	struct config cfg = {
8628	.output_format = "normal",
8629	.namespace_id = NVME_NSID_ALL,
8630	};
8631
8632	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
8633	OPT_UINT("namespace-id", 'n', &cfg.namespace_id, namespace_id))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8634
8635	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8636	if (ret)
8637	return ret;
8638
8639	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8640	if (ret)
8641	return ret;
8642
8643	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8644
8645	if (!(capabilities & WDC_DRIVE_CAP_HW_REV_LOG_PAGE0x0000000010000000)) {
8646	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8647	ret = -1;
8648	goto out;
8649	}
8650
8651	ret = nvme_get_hw_rev_log(hdl, &data, 0, cfg.namespace_id);
8652
8653	if (strcmp(cfg.output_format, "json"))
8654	nvme_show_status(ret);
8655
8656	if (!ret) {
8657	ret = validate_output_format(cfg.output_format, &fmt);
8658	if (ret < 0) {
8659	fprintf(stderrstderr, "ERROR: WDC %s: invalid output format\n", __func__);
8660	goto free_buf;
8661	}
8662
8663	if (!data) {
8664	fprintf(stderrstderr, "ERROR: WDC: Invalid buffer to read Hardware Revision log\n");
8665	ret = -1;
8666	goto out;
8667	}
8668	switch (fmt) {
8669	case NORMAL:
8670	wdc_print_hw_rev_log_normal(data);
8671	break;
8672	case JSON:
8673	wdc_print_hw_rev_log_json(data);
8674	break;
8675	default:
8676	break;
8677	}
8678	} else {
8679	fprintf(stderrstderr, "ERROR: WDC: Unable to read Hardware Revision Log Page data\n");
8680	ret = -1;
8681	}
8682
8683	free_buf:
8684	free(data);
8685
8686	out:
8687	return ret;
8688	}
8689
8690	static int wdc_vs_device_waf(int argc, char *argv, struct command acmd,
8691	struct plugin *plugin)
8692	{
8693	const char *desc = "Retrieve Device Write Amplication Factor";
8694	const char *namespace_id = "desired namespace id";
8695	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
8696	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
8697	struct nvme_smart_log smart_log;
8698	nvme_print_flags_t fmt;
8699	__u8 *data;
8700	int ret = 0;
8701	__u64 capabilities = 0;
8702	struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log * ext_smart_log_ptr;
8703	long double data_units_written = 0,
8704	phys_media_units_written_tlc = 0,
8705	phys_media_units_written_slc = 0;
8706	struct json_object root = NULL((void)0);
8707	char tlc_waf_str[32] = { 0 },
8708	slc_waf_str[32] = { 0 };
8709
8710	struct config {
8711	char *output_format;
8712	__u32 namespace_id;
8713	};
8714
8715	struct config cfg = {
8716	.output_format = "normal",
8717	.namespace_id = NVME_NSID_ALL,
8718	};
8719
8720	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
8721	OPT_UINT("namespace-id", 'n', &cfg.namespace_id, namespace_id))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8722
8723	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8724	if (ret)
8725	return ret;
8726
8727	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8728	if (ret)
8729	return ret;
8730
8731	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8732
8733	if (!(capabilities & WDC_DRIVE_CAP_DEVICE_WAF0x0000010000000000)) {
8734	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8735	ret = -1;
8736	goto out;
8737	}
8738
8739	/* get data units written from the smart log page */
8740	ret = nvme_get_log_smart(hdl, cfg.namespace_id, &smart_log);
8741	if (!ret) {
8742	data_units_written = int128_to_double(smart_log.data_units_written);
8743	} else if (ret > 0) {
8744	nvme_show_status(ret);
8745	ret = -1;
8746	goto out;
8747	} else {
8748	fprintf(stderrstderr, "smart log: %s\n", libnvme_strerror(errno(*__errno_location ())));
8749	ret = -1;
8750	goto out;
8751	}
8752
8753	/* get Physical Media Units Written from extended smart/C0 log page */
8754	data = NULL((void*)0);
8755	ret = nvme_get_ext_smart_cloud_log(hdl, &data, 0,
8756	cfg.namespace_id);
8757
8758	if (!ret) {
8759	ext_smart_log_ptr = (struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log *)data;
8760	phys_media_units_written_tlc = int128_to_double(ext_smart_log_ptr->ext_smart_pmuwt);
8761	phys_media_units_written_slc = int128_to_double(ext_smart_log_ptr->ext_smart_pmuws);
8762
8763	free(data);
8764	} else {
8765	fprintf(stderrstderr, "ERROR: WDC %s: get smart cloud log failure\n", __func__);
8766	ret = -1;
8767	goto out;
8768	}
8769
8770	if (strcmp(cfg.output_format, "json"))
8771	nvme_show_status(ret);
8772
8773	ret = validate_output_format(cfg.output_format, &fmt);
8774	if (ret < 0) {
8775	fprintf(stderrstderr, "ERROR: WDC %s: invalid output format\n", __func__);
8776	goto out;
8777	}
8778
8779	if (!data_units_written) {
8780	fprintf(stderrstderr, "ERROR: WDC %s: 0 data units written\n", __func__);
8781	ret = -1;
8782	goto out;
8783	}
8784
8785	if (fmt == NORMAL) {
8786	printf("Device Write Amplification Factor TLC : %4.2Lf\n",
8787	(phys_media_units_written_tlc/data_units_written));
8788	printf("Device Write Amplification Factor SLC : %4.2Lf\n",
8789	(phys_media_units_written_slc/data_units_written));
8790	} else if (fmt == JSON) {
8791	root = json_create_object()json_object_new_object();
8792	sprintf(tlc_waf_str, "%4.2Lf", (phys_media_units_written_tlc/data_units_written));
8793	sprintf(slc_waf_str, "%4.2Lf", (phys_media_units_written_slc/data_units_written));
8794
8795	json_object_add_value_string(root, "Device Write Amplification Factor TLC", tlc_waf_str);
8796	json_object_add_value_string(root, "Device Write Amplification Factor SLC", slc_waf_str);
8797
8798	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
8799	printf("\n");
8800
8801	json_free_object(root)json_object_put(root);
8802	}
8803
8804	out:
8805	return ret;
8806	}
8807
8808	static int wdc_get_latency_monitor_log(int argc, char *argv, struct command acmd,
8809	struct plugin *plugin)
8810	{
8811	const char *desc = "Retrieve latency monitor log data.";
8812	__u64 capabilities = 0;
8813	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
8814	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
8815	int ret = 0;
8816
8817	struct config {
8818	char *output_format;
8819	};
8820
8821	struct config cfg = {
8822	.output_format = "normal",
8823	};
8824
8825	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8826
8827	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8828	if (ret)
8829	return ret;
8830
8831	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8832	if (ret)
8833	return ret;
8834	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8835
8836	if (!(capabilities & WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000)) {
8837	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8838	ret = -1;
8839	goto out;
8840	}
8841
8842	ret = wdc_get_c3_log_page(ctx, hdl, cfg.output_format);
8843	if (ret)
8844	fprintf(stderrstderr, "ERROR: WDC: Failure reading the Latency Monitor (C3) Log Page, ret = %d\n", ret);
8845
8846	out:
8847	return ret;
8848	}
8849
8850	static int wdc_get_error_recovery_log(int argc, char *argv, struct command acmd,
8851	struct plugin *plugin)
8852	{
8853	const char *desc = "Retrieve error recovery log data.";
8854	__u64 capabilities = 0;
8855	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
8856	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
8857	int ret = 0;
8858
8859	struct config {
8860	char *output_format;
8861	};
8862
8863	struct config cfg = {
8864	.output_format = "normal",
8865	};
8866
8867	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8868
8869	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8870	if (ret)
8871	return ret;
8872
8873	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8874	if (ret)
8875	return ret;
8876
8877	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8878
8879	if (!(capabilities & WDC_DRIVE_CAP_OCP_C1_LOG_PAGE0x0000002000000000)) {
8880	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8881	ret = -1;
8882	goto out;
8883	}
8884
8885	ret = wdc_get_ocp_c1_log_page(ctx, hdl, cfg.output_format);
8886	if (ret)
8887	fprintf(stderrstderr, "ERROR: WDC: Failure reading the Error Recovery (C1) Log Page, ret = 0x%x\n", ret);
8888
8889	out:
8890	return ret;
8891	}
8892
8893	static int wdc_get_dev_capabilities_log(int argc, char *argv, struct command acmd,
8894	struct plugin *plugin)
8895	{
8896	const char *desc = "Retrieve device capabilities log data.";
8897	__u64 capabilities = 0;
8898	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
8899	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
8900	int ret = 0;
8901
8902	struct config {
8903	char *output_format;
8904	};
8905
8906	struct config cfg = {
8907	.output_format = "normal",
8908	};
8909
8910	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8911
8912	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8913	if (ret)
8914	return ret;
8915
8916	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8917	if (ret)
8918	return ret;
8919
8920	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8921
8922	if (!(capabilities & WDC_DRIVE_CAP_OCP_C4_LOG_PAGE0x0000004000000000)) {
8923	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8924	ret = -1;
8925	goto out;
8926	}
8927
8928	ret = wdc_get_ocp_c4_log_page(ctx, hdl, cfg.output_format);
8929	if (ret)
8930	fprintf(stderrstderr, "ERROR: WDC: Failure reading the Device Capabilities (C4) Log Page, ret = 0x%x\n", ret);
8931
8932	out:
8933	return ret;
8934	}
8935
8936	static int wdc_get_unsupported_reqs_log(int argc, char *argv, struct command acmd,
8937	struct plugin *plugin)
8938	{
8939	const char *desc = "Retrieve unsupported requirements log data.";
8940	__u64 capabilities = 0;
8941	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
8942	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
8943	int ret = 0;
8944
8945	struct config {
8946	char *output_format;
8947	};
8948
8949	struct config cfg = {
8950	.output_format = "normal",
8951	};
8952
8953	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
8954
8955	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
8956	if (ret)
8957	return ret;
8958
8959	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
8960	if (ret)
8961	return ret;
8962
8963	capabilities = wdc_get_drive_capabilities(ctx, hdl);
8964
8965	if (!(capabilities & WDC_DRIVE_CAP_OCP_C5_LOG_PAGE0x0000008000000000)) {
8966	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
8967	ret = -1;
8968	goto out;
8969	}
8970
8971	ret = wdc_get_ocp_c5_log_page(ctx, hdl, cfg.output_format);
8972	if (ret)
8973	fprintf(stderrstderr, "ERROR: WDC: Failure reading the Unsupported Requirements (C5) Log Page, ret = 0x%x\n", ret);
8974
8975	out:
8976	return ret;
8977	}
8978
8979	static int wdc_do_clear_pcie_correctable_errors(struct libnvme_transport_handle *hdl)
8980	{
8981	int ret;
8982	struct libnvme_passthru_cmd admin_cmd;
8983
8984	memset(&admin_cmd, 0, sizeof(admin_cmd));
8985	admin_cmd.opcode = WDC_NVME_CLEAR_PCIE_CORR_OPCODE0xC6;
8986	admin_cmd.cdw12 = ((WDC_NVME_CLEAR_PCIE_CORR_SUBCMD0x04 << WDC_NVME_SUBCMD_SHIFT8) \|
8987	WDC_NVME_CLEAR_PCIE_CORR_CMD0x22);
8988
8989	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
8990	nvme_show_status(ret);
8991	return ret;
8992	}
8993
8994	static int wdc_do_clear_pcie_correctable_errors_vuc(struct libnvme_transport_handle *hdl)
8995	{
8996	int ret;
8997	struct libnvme_passthru_cmd admin_cmd;
8998
8999	memset(&admin_cmd, 0, sizeof(admin_cmd));
9000	admin_cmd.opcode = WDC_NVME_CLEAR_PCIE_CORR_OPCODE_VUC0xD2;
9001
9002	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
9003	nvme_show_status(ret);
9004	return ret;
9005	}
9006
9007	static int wdc_do_clear_pcie_correctable_errors_fid(struct libnvme_transport_handle *hdl)
9008	{
9009	int ret;
9010	__u64 result;
9011	__u32 value = 1 << 31; /* Bit 31 - clear PCIe correctable count */
9012
9013	ret = nvme_set_features_simple(hdl, 0, WDC_NVME_CLEAR_PCIE_CORR_FEATURE_ID0xC3, false0,
9014	value, &result);
9015
9016	nvme_show_status(ret);
9017	return ret;
9018	}
9019
9020	static int wdc_clear_pcie_correctable_errors(int argc, char *argv, struct command acmd,
9021	struct plugin *plugin)
9022	{
9023	const char *desc = "Clear PCIE Correctable Errors.";
9024	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
9025	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
9026	__u64 capabilities = 0;
9027	int ret;
9028
9029	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
9030
9031	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
9032	if (ret)
9033	return ret;
9034
9035	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
9036	if (ret \|\| !wdc_check_device(ctx, hdl))
9037	return -1;
9038
9039	capabilities = wdc_get_drive_capabilities(ctx, hdl);
9040	if (!(capabilities & WDC_DRIVE_CAP_CLEAR_PCIE_MASK(0x0000000000000080 \| 0x0000000000400000 \| 0x0000000000800000 ))) {
9041	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
9042	ret = -1;
9043	goto out;
9044	}
9045
9046	if (capabilities & WDC_DRIVE_CAP_CLEAR_PCIE0x0000000000000080)
9047	ret = wdc_do_clear_pcie_correctable_errors(hdl);
9048	else if (capabilities & WDC_DRIVE_CAP_VUC_CLEAR_PCIE0x0000000000400000)
9049	ret = wdc_do_clear_pcie_correctable_errors_vuc(hdl);
9050	else
9051	ret = wdc_do_clear_pcie_correctable_errors_fid(hdl);
9052
9053	out:
9054	return ret;
9055	}
9056
9057	static int wdc_drive_status(int argc, char *argv, struct command acmd,
9058	struct plugin *plugin)
9059	{
9060	const char *desc = "Get Drive Status.";
9061	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
9062	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
9063	int ret = 0;
9064	int uuid_index;
9065	void dev_mng_log = NULL((void)0);
9066	__u32 system_eol_state;
9067	__u32 user_eol_state;
9068	__u32 format_corrupt_reason = 0xFFFFFFFF;
9069	__u32 eol_status;
9070	__u32 assert_status = 0xFFFFFFFF;
9071	__u32 thermal_status = 0xFFFFFFFF;
9072	__u64 capabilities = 0;
9073	struct nvme_id_uuid_list uuid_list;
9074
9075	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
9076
9077	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
9078	if (ret)
9079	return ret;
9080
9081	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
9082	if (ret)
9083	return ret;
9084
9085	capabilities = wdc_get_drive_capabilities(ctx, hdl);
9086
9087	if ((capabilities & WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020) != WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020) {
9088	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
9089	ret = -1;
9090	goto out;
9091	}
9092
9093	uuid_index = 0;
9094
9095	/* Find the WDC UUID index */
9096	memset(&uuid_list, 0, sizeof(struct nvme_id_uuid_list));
9097	if (wdc_CheckUuidListSupport(hdl, &uuid_list)) {
9098	/* check for the Sandisk UUID first */
9099	uuid_index = libnvme_find_uuid(&uuid_list, SNDK_UUID);
9100
9101	if (uuid_index < 0)
9102	/* The Sandisk UUID is not found;
9103	* check for the WDC UUID second.
9104	*/
9105	uuid_index = libnvme_find_uuid(&uuid_list, WDC_UUID);
9106	}
9107
9108	/* WD UUID not found, use default uuid index - 0 */
9109	if (uuid_index < 0)
9110	uuid_index = 0;
9111
9112	/* verify the 0xC2 Device Manageability log page is supported */
9113	if (wdc_nvme_check_supported_log_page(ctx, hdl,
9114	WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2,
9115	uuid_index) == false0) {
9116	fprintf(stderrstderr, "ERROR: WDC: 0xC2 Log Page not supported, uuid_index: %d\n",
9117	uuid_index);
9118	ret = -1;
9119	goto out;
9120	}
9121
9122	if (!get_dev_mgment_data(ctx, hdl, &dev_mng_log)) {
9123	fprintf(stderrstderr, "ERROR: WDC: 0xC2 Log Page not found\n");
9124	ret = -1;
9125	goto out;
9126	}
9127
9128	/* Get the assert dump present status */
9129	if (!wdc_nvme_parse_dev_status_log_entry(dev_mng_log, &assert_status,
9130	WDC_C2_ASSERT_DUMP_PRESENT_ID0x19))
9131	fprintf(stderrstderr, "ERROR: WDC: Get Assert Status Failed\n");
9132
9133	/* Get the thermal throttling status */
9134	if (!wdc_nvme_parse_dev_status_log_entry(dev_mng_log, &thermal_status,
9135	WDC_C2_THERMAL_THROTTLE_STATUS_ID0x18))
9136	fprintf(stderrstderr, "ERROR: WDC: Get Thermal Throttling Status Failed\n");
9137
9138	/* Get EOL status */
9139	if (!wdc_nvme_parse_dev_status_log_entry(dev_mng_log, &eol_status,
9140	WDC_C2_USER_EOL_STATUS_ID0x1A)) {
9141	fprintf(stderrstderr, "ERROR: WDC: Get User EOL Status Failed\n");
9142	eol_status = cpu_to_le32(-1);
9143	}
9144
9145	/* Get Customer EOL state */
9146	if (!wdc_nvme_parse_dev_status_log_entry(dev_mng_log, &user_eol_state,
9147	WDC_C2_USER_EOL_STATE_ID0x1C))
9148	fprintf(stderrstderr, "ERROR: WDC: Get User EOL State Failed\n");
9149
9150	/* Get System EOL state*/
9151	if (!wdc_nvme_parse_dev_status_log_entry(dev_mng_log, &system_eol_state,
9152	WDC_C2_SYSTEM_EOL_STATE_ID0x1D))
9153	fprintf(stderrstderr, "ERROR: WDC: Get System EOL State Failed\n");
9154
9155	/* Get format corrupt reason*/
9156	if (!wdc_nvme_parse_dev_status_log_entry(dev_mng_log, &format_corrupt_reason,
9157	WDC_C2_FORMAT_CORRUPT_REASON_ID0x1E))
9158	fprintf(stderrstderr, "ERROR: WDC: Get Format Corrupt Reason Failed\n");
9159
9160	printf(" Drive Status :-\n");
9161	if ((int)le32_to_cpu(eol_status) >= 0)
9162	printf(" Percent Used: %"PRIu32"u""%%\n",
9163	le32_to_cpu(eol_status));
9164	else
9165	printf(" Percent Used: Unknown\n");
9166	if (system_eol_state == WDC_EOL_STATUS_NORMALcpu_to_le32(0x00000000) && user_eol_state == WDC_EOL_STATUS_NORMALcpu_to_le32(0x00000000))
9167	printf(" Drive Life Status: Normal\n");
9168	else if (system_eol_state == WDC_EOL_STATUS_END_OF_LIFEcpu_to_le32(0x00000001) \|\|
9169	user_eol_state == WDC_EOL_STATUS_END_OF_LIFEcpu_to_le32(0x00000001))
9170	printf(" Drive Life Status: End Of Life\n");
9171	else if (system_eol_state == WDC_EOL_STATUS_READ_ONLYcpu_to_le32(0x00000002) \|\|
9172	user_eol_state == WDC_EOL_STATUS_READ_ONLYcpu_to_le32(0x00000002))
9173	printf(" Drive Life Status: Read Only\n");
9174	else
9175	printf(" Drive Life Status: Unknown : 0x%08x/0x%08x\n",
9176	le32_to_cpu(user_eol_state), le32_to_cpu(system_eol_state));
9177
9178	if (assert_status == WDC_ASSERT_DUMP_PRESENTcpu_to_le32(0x00000001))
9179	printf(" Assert Dump Status: Present\n");
9180	else if (assert_status == WDC_ASSERT_DUMP_NOT_PRESENTcpu_to_le32(0x00000000))
9181	printf(" Assert Dump Status: Not Present\n");
9182	else
9183	printf(" Assert Dump Status: Unknown : 0x%08x\n", le32_to_cpu(assert_status));
9184
9185	if (thermal_status == WDC_THERMAL_THROTTLING_OFFcpu_to_le32(0x00000000))
9186	printf(" Thermal Throttling Status: Off\n");
9187	else if (thermal_status == WDC_THERMAL_THROTTLING_ONcpu_to_le32(0x00000001))
9188	printf(" Thermal Throttling Status: On\n");
9189	else if (thermal_status == WDC_THERMAL_THROTTLING_UNAVAILABLEcpu_to_le32(0x00000002))
9190	printf(" Thermal Throttling Status: Unavailable\n");
9191	else
9192	printf(" Thermal Throttling Status: Unknown : 0x%08x\n", le32_to_cpu(thermal_status));
9193
9194	if (format_corrupt_reason == WDC_FORMAT_NOT_CORRUPTcpu_to_le32(0x00000000))
9195	printf(" Format Corrupt Reason: Format Not Corrupted\n");
9196	else if (format_corrupt_reason == WDC_FORMAT_CORRUPT_FW_ASSERTcpu_to_le32(0x00000001))
9197	printf(" Format Corrupt Reason: Format Corrupt due to FW Assert\n");
9198	else if (format_corrupt_reason == WDC_FORMAT_CORRUPT_UNKNOWNcpu_to_le32(0x000000FF))
9199	printf(" Format Corrupt Reason: Format Corrupt for Unknown Reason\n");
9200	else
9201	printf(" Format Corrupt Reason: Unknown : 0x%08x\n", le32_to_cpu(format_corrupt_reason));
9202
9203	free(dev_mng_log);
9204	out:
9205	return ret;
9206	}
9207
9208	static int wdc_clear_assert_dump(int argc, char *argv, struct command acmd,
9209	struct plugin *plugin)
9210	{
9211	const char *desc = "Clear Assert Dump Present Status.";
9212	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
9213	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
9214	int ret = -1;
9215	__le32 assert_status = cpu_to_le32(0xFFFFFFFF);
9216	__u64 capabilities = 0;
9217	struct libnvme_passthru_cmd admin_cmd;
9218
9219	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
9220
9221	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
9222	if (ret)
9223	return ret;
9224
9225	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
9226	if (ret)
9227	return ret;
9228
9229	capabilities = wdc_get_drive_capabilities(ctx, hdl);
9230
9231	if ((capabilities & WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040) != WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040) {
9232	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
9233	ret = -1;
9234	goto out;
9235	}
9236	if (!wdc_nvme_get_dev_status_log_data(ctx, hdl, &assert_status,
9237	WDC_C2_ASSERT_DUMP_PRESENT_ID0x19)) {
9238	fprintf(stderrstderr, "ERROR: WDC: Get Assert Status Failed\n");
9239	ret = -1;
9240	goto out;
9241	}
9242
9243	/* Get the assert dump present status */
9244	if (assert_status == WDC_ASSERT_DUMP_PRESENTcpu_to_le32(0x00000001)) {
9245	memset(&admin_cmd, 0, sizeof(admin_cmd));
9246	admin_cmd.opcode = WDC_NVME_CLEAR_ASSERT_DUMP_OPCODE0xD8;
9247	admin_cmd.cdw12 = ((WDC_NVME_CLEAR_ASSERT_DUMP_SUBCMD0x05 << WDC_NVME_SUBCMD_SHIFT8) \|
9248	WDC_NVME_CLEAR_ASSERT_DUMP_CMD0x03);
9249
9250	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
9251	nvme_show_status(ret);
9252	} else
9253	fprintf(stderrstderr, "INFO: WDC: No Assert Dump Present\n");
9254
9255	out:
9256	return ret;
9257	}
9258
9259	static int wdc_get_fw_act_history(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl,
9260	char *format)
9261	{
9262	struct wdc_fw_act_history_log_hdr *fw_act_history_hdr;
9263	nvme_print_flags_t fmt;
9264	int ret;
9265	__u8 *data;
9266
9267	if (!wdc_check_device(ctx, hdl))
9268	return -1;
9269
9270	ret = validate_output_format(format, &fmt);
9271	if (ret < 0) {
9272	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
9273	return ret;
9274	}
9275
9276	/* verify the FW Activate History log page is supported */
9277	if (!wdc_nvme_check_supported_log_page(ctx, hdl,
9278	WDC_NVME_GET_FW_ACT_HISTORY_LOG_ID0xCB, 0)) {
9279	fprintf(stderrstderr, "ERROR: WDC: %d Log Page not supported\n",
9280	WDC_NVME_GET_FW_ACT_HISTORY_LOG_ID0xCB);
9281	return -1;
9282	}
9283
9284	data = (__u8 )malloc(sizeof(__u8) WDC_FW_ACT_HISTORY_LOG_BUF_LEN0x3d0);
9285	if (!data) {
9286	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
9287	return -1;
9288	}
9289
9290	memset(data, 0, sizeof(__u8) * WDC_FW_ACT_HISTORY_LOG_BUF_LEN0x3d0);
9291
9292	ret = nvme_get_log_simple(hdl,
9293	WDC_NVME_GET_FW_ACT_HISTORY_LOG_ID0xCB,
9294	data, WDC_FW_ACT_HISTORY_LOG_BUF_LEN0x3d0);
9295
9296	if (strcmp(format, "json"))
9297	nvme_show_status(ret);
9298
9299	if (!ret) {
9300	/* parse the data */
9301	fw_act_history_hdr = (struct wdc_fw_act_history_log_hdr *)(data);
9302
9303	if ((fw_act_history_hdr->num_entries > 0) &&
9304	(fw_act_history_hdr->num_entries <= WDC_MAX_NUM_ACT_HIST_ENTRIES20)) {
9305	ret = wdc_print_fw_act_history_log(data, fw_act_history_hdr->num_entries,
9306	fmt, 0, 0, 0);
9307	} else if (!fw_act_history_hdr->num_entries) {
9308	fprintf(stderrstderr, "INFO: WDC: No FW Activate History entries found.\n");
9309	ret = 0;
9310	} else {
9311	fprintf(stderrstderr,
9312	"ERROR: WDC: Invalid number entries found in FW Activate History Log Page - %d\n",
9313	fw_act_history_hdr->num_entries);
9314	ret = -1;
9315	}
9316	} else {
9317	fprintf(stderrstderr, "ERROR: WDC: Unable to read FW Activate History Log Page data\n");
9318	ret = -1;
9319	}
9320
9321	free(data);
9322	return ret;
9323	}
9324
9325	static __u32 wdc_get_fw_cust_id(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl)
9326	{
9327
9328	__u32 cust_id = WDC_INVALID_CUSTOMER_ID-1;
9329	__u32 cust_id_ptr = NULL((void)0);
9330
9331	if (!get_dev_mgment_cbs_data(ctx, hdl, WDC_C2_CUSTOMER_ID_ID0x15, (void *)&cust_id_ptr))
9332	fprintf(stderrstderr, "%s: ERROR: WDC: 0xC2 Log Page entry ID 0x%x not found\n",
9333	__func__, WDC_C2_CUSTOMER_ID_ID0x15);
9334	else
9335	cust_id = *cust_id_ptr;
9336
9337	free(cust_id_ptr);
9338	return cust_id;
9339	}
9340
9341	static int wdc_get_fw_act_history_C2(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl,
9342	char *format)
9343	{
9344	struct wdc_fw_act_history_log_format_c2 *fw_act_history_log;
9345	__u32 tot_entries = 0, num_entries = 0;
9346	__u32 vendor_id = 0, device_id = 0;
9347	__u32 cust_id = 0;
9348	nvme_print_flags_t fmt;
9349	__u8 *data;
9350	int ret;
9351	bool_Bool c2GuidMatch = false0;
9352
9353	if (!wdc_check_device(ctx, hdl))
9354	return -1;
9355
9356	ret = validate_output_format(format, &fmt);
9357	if (ret < 0) {
9358	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
9359	return ret;
9360	}
9361
9362	ret = wdc_get_pci_ids(ctx, hdl, &device_id, &vendor_id);
9363
9364	data = (__u8 )malloc(sizeof(__u8) WDC_FW_ACT_HISTORY_C2_LOG_BUF_LEN0x1000);
9365	if (!data) {
9366	fprintf(stderrstderr, "ERROR: WDC: malloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
9367	return -1;
9368	}
9369
9370	memset(data, 0, sizeof(__u8) * WDC_FW_ACT_HISTORY_C2_LOG_BUF_LEN0x1000);
9371
9372	ret = nvme_get_log_simple(hdl,
9373	WDC_NVME_GET_FW_ACT_HISTORY_C2_LOG_ID0xC2,
9374	data, WDC_FW_ACT_HISTORY_C2_LOG_BUF_LEN0x1000);
9375
9376	if (strcmp(format, "json"))
9377	nvme_show_status(ret);
9378
9379	if (!ret) {
9380	/* Get the log page data and verify the GUID */
9381	fw_act_history_log = (struct wdc_fw_act_history_log_format_c2 *)(data);
9382
9383	c2GuidMatch = !memcmp(ocp_C2_guid,
9384	fw_act_history_log->log_page_guid,
9385	WDC_C2_GUID_LENGTH16);
9386
9387	if (c2GuidMatch) {
9388	/* parse the data */
9389	tot_entries = le32_to_cpu(fw_act_history_log->num_entries);
9390
9391	if (tot_entries > 0) {
9392	/* get the FW customer id */
9393	if (!wdc_is_sn861(device_id)) {
9394	cust_id = wdc_get_fw_cust_id(ctx, hdl);
9395	if (cust_id == WDC_INVALID_CUSTOMER_ID-1) {
9396	fprintf(stderrstderr,
9397	"%s: ERROR: WDC: invalid customer id\n",
9398	__func__);
9399	ret = -1;
9400	goto freeData;
9401	}
9402	}
9403	num_entries = (tot_entries < WDC_MAX_NUM_ACT_HIST_ENTRIES20) ?
9404	tot_entries : WDC_MAX_NUM_ACT_HIST_ENTRIES20;
9405	ret = wdc_print_fw_act_history_log(data, num_entries,
9406	fmt, cust_id, vendor_id, device_id);
9407	} else {
9408	fprintf(stderrstderr, "INFO: WDC: No entries found.\n");
9409	ret = 0;
9410	}
9411	} else {
9412	fprintf(stderrstderr, "ERROR: WDC: Invalid C2 log page GUID\n");
9413	ret = -1;
9414	}
9415	} else {
9416	fprintf(stderrstderr, "ERROR: WDC: Unable to read FW Activate History Log Page data\n");
9417	ret = -1;
9418	}
9419
9420	freeData:
9421	free(data);
9422	return ret;
9423	}
9424
9425	static int wdc_vs_fw_activate_history(int argc, char *argv, struct command acmd,
9426	struct plugin *plugin)
9427	{
9428	const char *desc = "Retrieve FW activate history table.";
9429	__u64 capabilities = 0;
9430	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
9431	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
9432	int ret = -1;
9433
9434	struct config {
9435	char *output_format;
9436	};
9437
9438	struct config cfg = {
9439	.output_format = "normal",
9440	};
9441
9442	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
9443
9444	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
9445	if (ret)
9446	return ret;
9447
9448	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
9449	if (ret)
9450	return ret;
9451
9452	capabilities = wdc_get_drive_capabilities(ctx, hdl);
9453
9454	if (!(capabilities & WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_MASK(0x0000000000002000 \| 0x0000000001000000))) {
9455	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
9456	ret = -1;
9457	goto out;
9458	}
9459
9460	if (capabilities & WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY0x0000000000002000) {
9461	__u32 cust_fw_id = 0;
9462	/* get the FW customer id */
9463	cust_fw_id = wdc_get_fw_cust_id(ctx, hdl);
9464	if (cust_fw_id == WDC_INVALID_CUSTOMER_ID-1) {
9465	fprintf(stderrstderr, "%s: ERROR: WDC: invalid customer id\n", __func__);
9466	ret = -1;
9467	goto out;
9468	}
9469
9470	if ((cust_fw_id == WDC_CUSTOMER_ID_0x10040x1004) \|\|
9471	(cust_fw_id == WDC_CUSTOMER_ID_0x10080x1008) \|\|
9472	(cust_fw_id == WDC_CUSTOMER_ID_0x10050x1005) \|\|
9473	(cust_fw_id == WDC_CUSTOMER_ID_0x13040x1304))
9474	ret = wdc_get_fw_act_history_C2(ctx, hdl, cfg.output_format);
9475	else
9476	ret = wdc_get_fw_act_history(ctx, hdl, cfg.output_format);
9477	} else if (capabilities & WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_C20x0000000001000000) {
9478	ret = wdc_get_fw_act_history_C2(ctx, hdl, cfg.output_format);
9479	}
9480
9481	if (ret)
9482	fprintf(stderrstderr, "ERROR: WDC: Failure reading the FW Activate History, ret = %d\n", ret);
9483	out:
9484	return ret;
9485	}
9486
9487	static int wdc_do_clear_fw_activate_history_vuc(struct libnvme_transport_handle *hdl)
9488	{
9489	int ret = -1;
9490	struct libnvme_passthru_cmd admin_cmd;
9491
9492	memset(&admin_cmd, 0, sizeof(admin_cmd));
9493	admin_cmd.opcode = WDC_NVME_CLEAR_FW_ACT_HIST_OPCODE0xC6;
9494	admin_cmd.cdw12 = ((WDC_NVME_CLEAR_FW_ACT_HIST_SUBCMD0x05 << WDC_NVME_SUBCMD_SHIFT8) \|
9495	WDC_NVME_CLEAR_FW_ACT_HIST_CMD0x23);
9496
9497	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
9498	nvme_show_status(ret);
9499
9500	return ret;
9501	}
9502
9503	static int wdc_do_clear_fw_activate_history_fid(struct libnvme_transport_handle *hdl)
9504	{
9505	int ret = -1;
9506	__u64 result;
9507	__u32 value = 1 << 31; /* Bit 31 - Clear Firmware Update History Log */
9508
9509	ret = nvme_set_features_simple(hdl, 0, WDC_NVME_CLEAR_FW_ACT_HIST_VU_FID0xC1, false0,
9510	value, &result);
9511
9512	nvme_show_status(ret);
9513	return ret;
9514	}
9515
9516	static int wdc_clear_fw_activate_history(int argc, char *argv, struct command acmd,
9517	struct plugin *plugin)
9518	{
9519	const char *desc = "Clear FW activate history table.";
9520	__u64 capabilities = 0;
9521	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
9522	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
9523	int ret;
9524
9525	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
9526
9527	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
9528	if (ret)
9529	return ret;
9530
9531	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
9532	if (ret)
9533	return ret;
9534
9535	capabilities = wdc_get_drive_capabilities(ctx, hdl);
9536
9537	if (!(capabilities & WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY_MASK(0x0000000000004000 \| 0x0000000002000000))) {
9538	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
9539	ret = -1;
9540	goto out;
9541	}
9542
9543	if (capabilities & WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY0x0000000000004000)
9544	ret = wdc_do_clear_fw_activate_history_vuc(hdl);
9545	else
9546	ret = wdc_do_clear_fw_activate_history_fid(hdl);
9547
9548	out:
9549	return ret;
9550	}
9551
9552	static int wdc_vs_telemetry_controller_option(int argc, char *argv, struct command acmd,
9553	struct plugin *plugin)
9554	{
9555	const char *desc = "Disable/Enable Controller Option of the Telemetry Log Page.";
9556	const char *disable = "Disable controller option of the telemetry log page.";
9557	const char *enable = "Enable controller option of the telemetry log page.";
9558	const char *status = "Displays the current state of the controller initiated log page.";
9559	__u64 capabilities = 0;
9560	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
9561	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
9562	__u64 result;
9563	int ret = -1;
9564
9565
9566	struct config {
9567	bool_Bool disable;
9568	bool_Bool enable;
9569	bool_Bool status;
9570	};
9571
9572	struct config cfg = {
9573	.disable = false0,
9574	.enable = false0,
9575	.status = false0,
9576	};
9577
9578	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"disable", 'd', ((void)0), CFG_FLAG, &cfg.disable , 0, disable, 0, }, {"enable", 'e', ((void)0), CFG_FLAG, & cfg.enable, 0, enable, 0, }, {"status", 's', ((void)0), CFG_FLAG , &cfg.status, 0, status, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void)0) } }
9579	OPT_FLAG("disable", 'd', &cfg.disable, disable),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"disable", 'd', ((void)0), CFG_FLAG, &cfg.disable , 0, disable, 0, }, {"enable", 'e', ((void)0), CFG_FLAG, & cfg.enable, 0, enable, 0, }, {"status", 's', ((void)0), CFG_FLAG , &cfg.status, 0, status, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void)0) } }
9580	OPT_FLAG("enable", 'e', &cfg.enable, enable),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"disable", 'd', ((void)0), CFG_FLAG, &cfg.disable , 0, disable, 0, }, {"enable", 'e', ((void)0), CFG_FLAG, & cfg.enable, 0, enable, 0, }, {"status", 's', ((void)0), CFG_FLAG , &cfg.status, 0, status, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void)0) } }
9581	OPT_FLAG("status", 's', &cfg.status, status))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"disable", 'd', ((void)0), CFG_FLAG, &cfg.disable , 0, disable, 0, }, {"enable", 'e', ((void)0), CFG_FLAG, & cfg.enable, 0, enable, 0, }, {"status", 's', ((void)0), CFG_FLAG , &cfg.status, 0, status, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void)0) } };
9582
9583	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
9584	if (ret)
9585	return ret;
9586
9587	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
9588	if (ret)
9589	return ret;
9590
9591	capabilities = wdc_get_drive_capabilities(ctx, hdl);
9592
9593	if ((capabilities & WDC_DRVIE_CAP_DISABLE_CTLR_TELE_LOG0x0000000000008000) != WDC_DRVIE_CAP_DISABLE_CTLR_TELE_LOG0x0000000000008000) {
9594	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
9595	ret = -1;
9596	goto out;
9597	}
9598
9599	/* allow only one option at a time */
9600	if ((cfg.disable + cfg.enable + cfg.status) > 1) {
9601
9602	fprintf(stderrstderr, "ERROR: WDC: Invalid option\n");
9603	ret = -1;
9604	goto out;
9605	}
9606
9607	if (cfg.disable) {
9608	ret = nvme_set_features_simple(hdl, 0,
9609	WDC_VU_DISABLE_CNTLR_TELEMETRY_OPTION_FEATURE_ID0xD2,
9610	false0, 1, &result);
9611
9612	wdc_clear_reason_id(hdl);
9613	} else {
9614	if (cfg.enable) {
9615	ret = nvme_set_features_simple(hdl, 0,
9616	WDC_VU_DISABLE_CNTLR_TELEMETRY_OPTION_FEATURE_ID0xD2,
9617	false0, 0, &result);
9618	} else if (cfg.status) {
9619	ret = nvme_get_features_simple(hdl,
9620	WDC_VU_DISABLE_CNTLR_TELEMETRY_OPTION_FEATURE_ID0xD2,
9621	NVME_GET_FEATURES_SEL_CURRENT,
9622	&result);
9623	if (!ret) {
9624	if (result)
9625	fprintf(stderrstderr, "Controller Option Telemetry Log Page State: Disabled\n");
9626	else
9627	fprintf(stderrstderr, "Controller Option Telemetry Log Page State: Enabled\n");
9628	} else {
9629	nvme_show_status(ret);
9630	}
9631	} else {
9632	fprintf(stderrstderr, "ERROR: WDC: unsupported option for this command\n");
9633	fprintf(stderrstderr, "Please provide an option, -d, -e or -s\n");
9634	ret = -1;
9635	goto out;
9636	}
9637	}
9638
9639	out:
9640	return ret;
9641	}
9642
9643
9644	static int wdc_get_serial_and_fw_rev(struct libnvme_transport_handle hdl, char sn, char *fw_rev)
9645	{
9646	struct nvme_id_ctrl ctrl;
9647	int ret;
9648	int i;
9649
9650	i = sizeof(ctrl.sn) - 1;
9651	memset(sn, 0, WDC_SERIAL_NO_LEN20);
9652	memset(fw_rev, 0, WDC_NVME_FIRMWARE_REV_LEN9);
9653	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
9654	ret = nvme_identify_ctrl(hdl, &ctrl);
9655	if (ret) {
9656	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed 0x%x\n", ret);
9657	return -1;
9658	}
9659	/* Remove trailing spaces from the name */
9660	while (i && ctrl.sn[i] == ' ') {
9661	ctrl.sn[i] = '\0';
9662	i--;
9663	}
9664	snprintf(sn, WDC_SERIAL_NO_LEN20, "%s", ctrl.sn);
9665	snprintf(fw_rev, WDC_NVME_FIRMWARE_REV_LEN9, "%s", ctrl.fr);
9666
9667	return 0;
9668	}
9669
9670	static int wdc_get_max_transfer_len(struct libnvme_transport_handle hdl, __u32 maxTransferLen)
9671	{
9672	struct nvme_id_ctrl ctrl;
9673	int ret = 0;
9674
9675	__u32 maxTransferLenDevice = 0;
9676
9677	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
9678	ret = nvme_identify_ctrl(hdl, &ctrl);
9679	if (ret) {
9680	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed 0x%x\n", ret);
9681	return -1;
9682	}
9683
9684	maxTransferLenDevice = (1 << ctrl.mdts) * getpagesize();
9685	*maxTransferLen = maxTransferLenDevice;
9686
9687	return ret;
9688	}
9689
9690	static int wdc_de_VU_read_size(struct libnvme_transport_handle hdl, __u32 fileId, __u16 spiDestn, __u32 logSize)
9691	{
9692	int ret = WDC_STATUS_FAILURE-1;
9693	struct libnvme_passthru_cmd cmd;
9694
9695	if (!logSize) {
9696	ret = WDC_STATUS_INVALID_PARAMETER-3;
9697	goto end;
9698	}
9699
9700	memset(&cmd, 0, sizeof(struct libnvme_passthru_cmd));
9701	cmd.opcode = WDC_DE_VU_READ_SIZE_OPCODE0xC0;
9702	cmd.nsid = WDC_DE_DEFAULT_NAMESPACE_ID0x01;
9703	cmd.cdw13 = fileId << 16;
9704	cmd.cdw14 = spiDestn;
9705
9706	ret = libnvme_exec_admin_passthru(hdl, &cmd);
9707
9708	if (!ret && logSize)
9709	*logSize = cmd.result;
9710	if (ret != WDC_STATUS_SUCCESS0) {
9711	fprintf(stderrstderr, "ERROR: WDC: VUReadSize() failed, ");
9712	nvme_show_status(ret);
9713	}
9714
9715	end:
9716	return ret;
9717	}
9718
9719	static int wdc_de_VU_read_buffer(struct libnvme_transport_handle *hdl, __u32 fileId, __u16 spiDestn,
9720	__u32 offsetInDwords, __u8 dataBuffer, __u32 bufferSize)
9721	{
9722	int ret = WDC_STATUS_FAILURE-1;
9723	struct libnvme_passthru_cmd cmd;
9724	__u32 noOfDwordExpected = 0;
9725
9726	if (!dataBuffer \|\| !bufferSize) {
9727	ret = WDC_STATUS_INVALID_PARAMETER-3;
9728	goto end;
9729	}
9730
9731	memset(&cmd, 0, sizeof(struct libnvme_passthru_cmd));
9732	noOfDwordExpected = *bufferSize / sizeof(__u32);
9733	cmd.opcode = WDC_DE_VU_READ_BUFFER_OPCODE0xC2;
9734	cmd.nsid = WDC_DE_DEFAULT_NAMESPACE_ID0x01;
9735	cmd.cdw10 = noOfDwordExpected;
9736	cmd.cdw13 = fileId << 16;
9737	cmd.cdw14 = spiDestn;
9738	cmd.cdw15 = offsetInDwords;
9739
9740	cmd.addr = (__u64)(__u64)(uintptr_t)dataBuffer;
9741	cmd.data_len = *bufferSize;
9742
9743	ret = libnvme_exec_admin_passthru(hdl, &cmd);
9744
9745	if (ret != WDC_STATUS_SUCCESS0) {
9746	fprintf(stderrstderr, "ERROR: WDC: VUReadBuffer() failed, ");
9747	nvme_show_status(ret);
9748	}
9749
9750	end:
9751	return ret;
9752	}
9753
9754	static int wdc_get_log_dir_max_entries(struct libnvme_transport_handle hdl, __u32 maxNumOfEntries)
9755	{
9756	int ret = WDC_STATUS_FAILURE-1;
9757	__u32 headerPayloadSize = 0;
9758	__u8 fileIdOffsetsBuffer = NULL((void)0);
9759	__u32 fileIdOffsetsBufferSize = 0;
9760	__u32 fileNum = 0;
9761	__u16 fileOffset = 0;
9762
9763
9764	if (!maxNumOfEntries) {
9765	ret = WDC_STATUS_INVALID_PARAMETER-3;
9766	return ret;
9767	}
9768	/* 1.Get log directory first four bytes */
9769	ret = wdc_de_VU_read_size(hdl, 0, 5, (__u32 *)&headerPayloadSize);
9770	if (ret != WDC_STATUS_SUCCESS0) {
9771	fprintf(stderrstderr,
9772	"ERROR: WDC: %s: Failed to get headerPayloadSize from file directory 0x%x\n",
9773	__func__, ret);
9774	return ret;
9775	}
9776
9777	fileIdOffsetsBufferSize =
9778	WDC_DE_FILE_HEADER_SIZE4 + (headerPayloadSize * WDC_DE_FILE_OFFSET_SIZE2);
9779	fileIdOffsetsBuffer = (__u8 *)calloc(1, fileIdOffsetsBufferSize);
9780
9781	/* 2.Read to get file offsets */
9782	ret = wdc_de_VU_read_buffer(hdl, 0, 5, 0, fileIdOffsetsBuffer, &fileIdOffsetsBufferSize);
9783	if (ret != WDC_STATUS_SUCCESS0) {
9784	fprintf(stderrstderr,
9785	"ERROR: WDC: %s: Failed to get fileIdOffsets from file directory 0x%x\n",
9786	__func__, ret);
9787	goto end;
9788	}
9789	/* 3.Determine valid entries */
9790	for (fileNum = 0;
9791	fileNum < (headerPayloadSize - WDC_DE_FILE_HEADER_SIZE4) / WDC_DE_FILE_OFFSET_SIZE2;
9792	fileNum++) {
9793	fileOffset = (fileIdOffsetsBuffer[WDC_DE_FILE_HEADER_SIZE4 +
9794	(fileNum * WDC_DE_FILE_OFFSET_SIZE2)] << 8) +
9795	fileIdOffsetsBuffer[WDC_DE_FILE_HEADER_SIZE4 +
9796	(fileNum * WDC_DE_FILE_OFFSET_SIZE2) + 1];
9797	if (!fileOffset)
9798	continue;
9799	(*maxNumOfEntries)++;
9800	}
9801
9802	end:
9803	free(fileIdOffsetsBuffer);
9804	return ret;
9805	}
9806
9807	static enum WDC_DRIVE_ESSENTIAL_TYPE wdc_get_essential_type(__u8 fileName[])
9808	{
9809	enum WDC_DRIVE_ESSENTIAL_TYPE essentialType = WDC_DE_TYPE_NONE;
9810
9811	if (!wdc_UtilsStrCompare((char *)fileName, WDC_DE_CORE_DUMP_FILE_NAME"core_dump"))
9812	essentialType = WDC_DE_TYPE_DUMPSNAPSHOT;
9813	else if (!wdc_UtilsStrCompare((char *)fileName, WDC_DE_EVENT_LOG_FILE_NAME"event_log"))
9814	essentialType = WDC_DE_TYPE_EVENTLOG;
9815	else if (!wdc_UtilsStrCompare((char *)fileName, WDC_DE_MANUFACTURING_INFO_PAGE_FILE_NAME"manufacturing_info"))
9816	essentialType = WDC_DE_TYPE_NVME_MANF_INFO;
9817
9818	return essentialType;
9819	}
9820
9821	static int wdc_fetch_log_directory(struct libnvme_transport_handle hdl, struct WDC_DE_VU_LOG_DIRECTORY directory)
9822	{
9823	int ret = WDC_STATUS_FAILURE-1;
9824	__u8 fileOffset = NULL((void)0);
9825	__u8 fileDirectory = NULL((void)0);
9826	__u32 headerSize = 0;
9827	__u32 fileNum = 0, startIdx = 0;
9828	__u16 fileOffsetTemp = 0;
9829	__u32 entryId = 0;
9830	__u32 fileDirectorySize = 0;
9831
9832	if (!directory) {
9833	ret = WDC_STATUS_INVALID_PARAMETER-3;
9834	goto end;
9835	}
9836
9837	ret = wdc_de_VU_read_size(hdl, 0, 5, &fileDirectorySize);
9838	if (ret != WDC_STATUS_SUCCESS0) {
9839	fprintf(stderrstderr,
9840	"ERROR: WDC: %s: Failed to get filesystem directory size, ret = %d\n",
9841	__func__, ret);
9842	goto end;
9843	}
9844
9845	fileDirectory = (__u8 *)calloc(1, fileDirectorySize);
9846	ret = wdc_de_VU_read_buffer(hdl, 0, 5, 0, fileDirectory, &fileDirectorySize);
9847	if (ret != WDC_STATUS_SUCCESS0) {
9848	fprintf(stderrstderr, "ERROR: WDC: %s: Failed to get filesystem directory, ret = %d\n",
9849	__func__, ret);
9850	goto end;
9851	}
9852
9853	/* First four bytes of header directory is headerSize */
9854	memcpy(&headerSize, fileDirectory, WDC_DE_FILE_HEADER_SIZE4);
9855
9856	/* minimum buffer for 1 entry is required */
9857	if (!directory->maxNumLogEntries) {
9858	ret = WDC_STATUS_INVALID_PARAMETER-3;
9859	goto end;
9860	}
9861
9862	for (fileNum = 0;
9863	fileNum < (headerSize - WDC_DE_FILE_HEADER_SIZE4) / WDC_DE_FILE_OFFSET_SIZE2;
9864	fileNum++) {
9865	if (entryId >= directory->maxNumLogEntries)
9866	break;
9867
9868	startIdx = WDC_DE_FILE_HEADER_SIZE4 + (fileNum * WDC_DE_FILE_OFFSET_SIZE2);
9869	memcpy(&fileOffsetTemp, fileDirectory + startIdx, sizeof(fileOffsetTemp));
9870	fileOffset = fileDirectory + fileOffsetTemp;
9871
9872	if (!fileOffsetTemp)
9873	continue;
9874
9875	memset(&directory->logEntry[entryId], 0, sizeof(struct WDC_DRIVE_ESSENTIALS));
9876	memcpy(&directory->logEntry[entryId].metaData, fileOffset, sizeof(struct __packed__attribute__((__packed__)) WDC_DE_VU_FILE_META_DATA));
9877	directory->logEntry[entryId].metaData.fileName[WDC_DE_FILE_NAME_SIZE32 - 1] = '\0';
9878	wdc_UtilsDeleteCharFromString((char *)directory->logEntry[entryId].metaData.fileName,
9879	WDC_DE_FILE_NAME_SIZE32, ' ');
9880	if (!directory->logEntry[entryId].metaData.fileID)
9881	continue;
9882
9883	directory->logEntry[entryId].essentialType = wdc_get_essential_type(directory->logEntry[entryId].metaData.fileName);
9884	entryId++;
9885	}
9886
9887	directory->numOfValidLogEntries = entryId;
9888
9889	end:
9890	free(fileDirectory);
9891	return ret;
9892	}
9893
9894	static int wdc_fetch_log_file_from_device(struct libnvme_transport_handle *hdl, __u32 fileId,
9895	__u16 spiDestn, __u64 fileSize, __u8 *dataBuffer)
9896	{
9897	int ret = WDC_STATUS_FAILURE-1;
9898	__u32 chunckSize = WDC_DE_VU_READ_BUFFER_STANDARD_OFFSET0x8000;
9899	__u32 maximumTransferLength = 0;
9900	__u32 buffSize = 0;
9901	__u64 offsetIdx = 0;
9902
9903	if (!dataBuffer \|\| !fileSize) {
9904	ret = WDC_STATUS_INVALID_PARAMETER-3;
9905	goto end;
9906	}
9907
9908	if (wdc_get_max_transfer_len(hdl, &maximumTransferLength) < 0) {
9909	ret = WDC_STATUS_FAILURE-1;
9910	goto end;
9911	}
9912
9913	/* Fetch Log File Data */
9914	if ((fileSize >= maximumTransferLength) \|\| (fileSize > 0xFFFFFFFF)) {
9915	chunckSize = WDC_DE_VU_READ_BUFFER_STANDARD_OFFSET0x8000;
9916	if (maximumTransferLength < WDC_DE_VU_READ_BUFFER_STANDARD_OFFSET0x8000)
9917	chunckSize = maximumTransferLength;
9918
9919	buffSize = chunckSize;
9920	for (offsetIdx = 0; (offsetIdx * chunckSize) < fileSize; offsetIdx++) {
9921	if (((offsetIdx * chunckSize) + buffSize) > fileSize)
9922	buffSize = (__u32)(fileSize - (offsetIdx * chunckSize));
9923	/* Limitation in VU read buffer - offsetIdx and bufferSize are not greater than u32 */
9924	ret = wdc_de_VU_read_buffer(hdl, fileId, spiDestn,
9925	(__u32)((offsetIdx * chunckSize) / sizeof(__u32)), dataBuffer + (offsetIdx * chunckSize), &buffSize);
9926	if (ret != WDC_STATUS_SUCCESS0) {
9927	fprintf(stderrstderr, "ERROR: WDC: %s: wdc_de_VU_read_buffer failed with ret = %d, fileId = 0x%x, fileSize = 0x%lx\n",
9928	__func__, ret, fileId, (unsigned long)fileSize);
9929	break;
9930	}
9931	}
9932	} else {
9933	buffSize = (__u32)fileSize;
9934	ret = wdc_de_VU_read_buffer(hdl, fileId, spiDestn,
9935	(__u32)((offsetIdx * chunckSize) / sizeof(__u32)),
9936	dataBuffer, &buffSize);
9937	if (ret != WDC_STATUS_SUCCESS0) {
9938	fprintf(stderrstderr, "ERROR: WDC: %s: wdc_de_VU_read_buffer failed with ret = %d, fileId = 0x%x, fileSize = 0x%lx\n",
9939	__func__, ret, fileId, (unsigned long)fileSize);
9940	}
9941	}
9942
9943	end:
9944	return ret;
9945	}
9946
9947	static int wdc_de_get_dump_trace(struct libnvme_transport_handle hdl, const char filePath, __u16 binFileNameLen,
9948	const char *binFileName)
9949	{
9950	int ret = WDC_STATUS_FAILURE-1;
9951	__u8 readBuffer = NULL((void)0);
9952	__u32 readBufferLen = 0;
9953	__u32 lastPktReadBufferLen = 0;
9954	__u32 maxTransferLen = 0;
9955	__u32 dumptraceSize = 0;
9956	__u32 chunkSize;
9957	__u32 chunks;
9958	__u32 offset;
9959	__u32 i;
9960	__u32 maximumTransferLength = 0;
9961
9962	if (!binFileName \|\| !filePath) {
9963	ret = WDC_STATUS_INVALID_PARAMETER-3;
9964	return ret;
9965	}
9966
9967	if (wdc_get_max_transfer_len(hdl, &maximumTransferLength) < 0)
9968	return WDC_STATUS_FAILURE-1;
9969
9970	do {
9971	/* Get dumptrace size */
9972	ret = wdc_de_VU_read_size(hdl, 0, WDC_DE_DUMPTRACE_DESTINATION6, &dumptraceSize);
9973	if (ret != WDC_STATUS_SUCCESS0) {
9974	fprintf(stderrstderr, "ERROR: WDC: %s: wdc_de_VU_read_size failed with ret = %d\n",
9975	__func__, ret);
9976	break;
9977	}
9978
9979	/* Make sure the size requested is greater than dword */
9980	if (dumptraceSize < 4) {
9981	ret = WDC_STATUS_FAILURE-1;
9982	fprintf(stderrstderr, "ERROR: WDC: %s: wdc_de_VU_read_size failed, read size is less than 4 bytes, dumptraceSize = 0x%x\n",
9983	__func__, dumptraceSize);
9984	break;
9985	}
9986
9987	/* Choose the least max transfer length */
9988	maxTransferLen = maximumTransferLength < WDC_DE_READ_MAX_TRANSFER_SIZE0x8000 ? maximumTransferLength : WDC_DE_READ_MAX_TRANSFER_SIZE0x8000;
9989
9990	/* Comment from FW Team:
9991	* The max non - block transfer size is 0xFFFF (16 bits allowed as the block size).Use 0x8000
9992	* to keep it on a word - boundary.
9993	* max_xfer = int(pow(2, id_data['MDTS'])) * 4096 # 4k page size as reported in pcie capabiltiies
9994	*/
9995	chunkSize = dumptraceSize < maxTransferLen ? dumptraceSize : maxTransferLen;
9996	chunks = (dumptraceSize / maxTransferLen) + ((dumptraceSize % maxTransferLen) ? 1 : 0);
9997
9998	readBuffer = (unsigned char *)calloc(dumptraceSize, sizeof(unsigned char));
9999	readBufferLen = chunkSize;
10000	lastPktReadBufferLen = (dumptraceSize % maxTransferLen) ? (dumptraceSize % maxTransferLen) : chunkSize;
10001
10002	if (!readBuffer) {
10003	fprintf(stderrstderr, "ERROR: WDC: %s: readBuffer calloc failed\n", __func__);
10004	ret = WDC_STATUS_INSUFFICIENT_MEMORY-2;
10005	break;
10006	}
10007
10008	for (i = 0; i < chunks; i++) {
10009	offset = (i * chunkSize) / 4;
10010
10011	/* Last loop call, Assign readBufferLen to read only left over bytes */
10012	if (i == (chunks - 1))
10013	readBufferLen = lastPktReadBufferLen;
10014
10015	ret = wdc_de_VU_read_buffer(hdl, 0, WDC_DE_DUMPTRACE_DESTINATION6, 0,
10016	readBuffer + offset, &readBufferLen);
10017	if (ret != WDC_STATUS_SUCCESS0) {
10018	fprintf(stderrstderr,
10019	"ERROR: WDC: %s: wdc_de_VU_read_buffer failed, ret = %d on offset 0x%x\n",
10020	__func__, ret, offset);
10021	break;
10022	}
10023	}
10024	} while (0);
10025
10026	if (ret == WDC_STATUS_SUCCESS0) {
10027	ret = wdc_WriteToFile(binFileName, (char *)readBuffer, dumptraceSize);
10028	if (ret != WDC_STATUS_SUCCESS0)
10029	fprintf(stderrstderr, "ERROR: WDC: %s: wdc_WriteToFile failed, ret = %d\n",
10030	__func__, ret);
10031	} else {
10032	fprintf(stderrstderr, "ERROR: WDC: %s: Read Buffer Loop failed, ret = %d\n", __func__,
10033	ret);
10034	}
10035
10036	free(readBuffer);
10037
10038	return ret;
10039	}
10040
10041	int wdc_fetch_vu_file_directory(struct libnvme_transport_handle *hdl,
10042	struct WDC_DE_VU_LOG_DIRECTORY deEssentialsList,
10043	__s8 bufferFolderPath, __u8 serialNo, __u8 *timeString)
10044	{
10045	int ret = wdc_fetch_log_directory(hdl, &deEssentialsList);
10046	__u32 listIdx;
10047	char *dataBuffer;
10048	char fileName[MAX_PATH_LEN256];
10049
10050	if (ret != WDC_STATUS_SUCCESS0) {
10051	fprintf(stderrstderr, "WDC: wdc_fetch_log_directory failed, ret = %d\n", ret);
10052	return ret;
10053	}
10054
10055	/* Get Debug Data Files */
10056	for (listIdx = 0; listIdx < deEssentialsList.numOfValidLogEntries; listIdx++) {
10057	if (!deEssentialsList.logEntry[listIdx].metaData.fileSize) {
10058	fprintf(stderrstderr, "ERROR: WDC: File Size for %s is 0\n",
10059	deEssentialsList.logEntry[listIdx].metaData.fileName);
10060	ret = WDC_STATUS_FILE_SIZE_ZERO-27;
10061	} else {
10062	/* Fetch Log File Data */
10063	dataBuffer = (char *)calloc(1, (size_t)deEssentialsList.logEntry[listIdx].metaData.fileSize);
10064	ret = wdc_fetch_log_file_from_device(hdl,
10065	deEssentialsList.logEntry[listIdx].metaData.fileID,
10066	WDC_DE_DESTN_SPI1,
10067	deEssentialsList.logEntry[listIdx].metaData.fileSize,
10068	(__u8 *)dataBuffer);
10069
10070	/* Write databuffer to file */
10071	if (ret == WDC_STATUS_SUCCESS0) {
10072	memset(fileName, 0, sizeof(fileName));
10073	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s_%s_%s.bin", bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
10074	deEssentialsList.logEntry[listIdx].metaData.fileName, serialNo, timeString);
10075	if (deEssentialsList.logEntry[listIdx].metaData.fileSize > 0xFFFFFFFF) {
10076	wdc_WriteToFile(fileName, dataBuffer, 0xFFFFFFFF);
10077	wdc_WriteToFile(fileName, dataBuffer + 0xFFFFFFFF, (__u32)(deEssentialsList.logEntry[listIdx].metaData.fileSize - 0xFFFFFFFF));
10078	} else {
10079	wdc_WriteToFile(fileName, dataBuffer, (__u32)deEssentialsList.logEntry[listIdx].metaData.fileSize);
10080	}
10081	} else {
10082	fprintf(stderrstderr, "ERROR: WDC: wdc_fetch_log_file_from_device: %s failed, ret = %d\n",
10083	deEssentialsList.logEntry[listIdx].metaData.fileName, ret);
10084	}
10085	free(dataBuffer);
10086	}
10087	}
10088
10089	return ret;
10090	}
10091
10092	int wdc_read_debug_directory(struct libnvme_transport_handle hdl, __s8 bufferFolderPath, __u8 *serialNo,
10093	__u8 *timeString)
10094	{
10095	__u32 maxNumOfVUFiles = 0;
10096	int ret = wdc_get_log_dir_max_entries(hdl, &maxNumOfVUFiles);
10097	struct WDC_DE_VU_LOG_DIRECTORY deEssentialsList;
10098
10099	if (ret != WDC_STATUS_SUCCESS0) {
10100	fprintf(stderrstderr, "WDC: wdc_get_log_dir_max_entries failed, ret = %d\n", ret);
10101	return ret;
10102	}
10103
10104	memset(&deEssentialsList, 0, sizeof(deEssentialsList));
10105	deEssentialsList.logEntry =
10106	(struct WDC_DRIVE_ESSENTIALS )calloc(1, sizeof(struct WDC_DRIVE_ESSENTIALS) maxNumOfVUFiles);
10107	deEssentialsList.maxNumLogEntries = maxNumOfVUFiles;
10108
10109	ret = wdc_fetch_vu_file_directory(hdl, deEssentialsList, bufferFolderPath, serialNo,
10110	timeString);
10111
10112	free(deEssentialsList.logEntry);
10113	deEssentialsList.logEntry = NULL((void*)0);
10114
10115	return ret;
10116	}
10117
10118	static int wdc_do_drive_essentials(struct libnvme_global_ctx ctx, struct libnvme_transport_handle hdl,
10119	char dir, char key)
10120	{
10121	int ret = 0;
10122	void *retPtr;
10123	char fileName[MAX_PATH_LEN256];
10124	__s8 bufferFolderPath[MAX_PATH_LEN256];
10125	char bufferFolderName[MAX_PATH_LEN256];
10126	char tarFileName[MAX_PATH_LEN256];
10127	char tarFiles[MAX_PATH_LEN256];
10128	char tarCmd[MAX_PATH_LEN256+MAX_PATH_LEN256];
10129	UtilsTimeInfo timeInfo;
10130	__u8 timeString[MAX_PATH_LEN256];
10131	__u8 serialNo[WDC_SERIAL_NO_LEN20];
10132	__u8 firmwareRevision[WDC_NVME_FIRMWARE_REV_LEN9];
10133	__u8 idSerialNo[WDC_SERIAL_NO_LEN20];
10134	__u8 idFwRev[WDC_NVME_FIRMWARE_REV_LEN9];
10135	__u8 featureIdBuff[4];
10136	char currDir[MAX_PATH_LEN256];
10137	char dataBuffer = NULL((void)0);
10138	__u32 elogNumEntries, elogBufferSize;
10139	__u32 dataBufferSize;
10140	__u32 listIdx = 0;
10141	__u32 vuLogIdx = 0;
10142	__u64 result;
10143	struct nvme_id_ctrl ctrl;
10144	struct nvme_id_ns ns;
10145	struct nvme_error_log_page *elogBuffer;
10146	struct nvme_smart_log smart_log;
10147	struct nvme_firmware_slot fw_log;
10148	struct WDC_NVME_DE_VU_LOGPAGES vuLogInput = NULL((void)0);
10149
10150	memset(bufferFolderPath, 0, sizeof(bufferFolderPath));
10151	memset(bufferFolderName, 0, sizeof(bufferFolderName));
10152	memset(tarFileName, 0, sizeof(tarFileName));
10153	memset(tarFiles, 0, sizeof(tarFiles));
10154	memset(tarCmd, 0, sizeof(tarCmd));
10155	memset(&timeInfo, 0, sizeof(timeInfo));
10156
10157	if (wdc_get_serial_and_fw_rev(hdl, (char )idSerialNo, (char )idFwRev)) {
10158	fprintf(stderrstderr, "ERROR: WDC: get serial # and fw revision failed\n");
10159	return -1;
10160	}
10161
10162	fprintf(stderrstderr, "Get Drive Essentials Data for device serial #: %s and fw revision: %s\n",
10163	idSerialNo, idFwRev);
10164
10165	/* Create Drive Essentials directory */
10166	wdc_UtilsGetTime(&timeInfo);
10167	memset(timeString, 0, sizeof(timeString));
10168	wdc_UtilsSnprintf((char *)timeString, MAX_PATH_LEN256, "%02u%02u%02u_%02u%02u%02u",
10169	timeInfo.year, timeInfo.month, timeInfo.dayOfMonth,
10170	timeInfo.hour, timeInfo.minute, timeInfo.second);
10171
10172	wdc_UtilsSnprintf((char )serialNo, WDC_SERIAL_NO_LEN20, (char )idSerialNo);
10173	/* Remove any space form serialNo */
10174	wdc_UtilsDeleteCharFromString((char *)serialNo, WDC_SERIAL_NO_LEN20, ' ');
10175
10176	memset(firmwareRevision, 0, sizeof(firmwareRevision));
10177	wdc_UtilsSnprintf((char )firmwareRevision, WDC_NVME_FIRMWARE_REV_LEN9, (char )idFwRev);
10178	/* Remove any space form FirmwareRevision */
10179	wdc_UtilsDeleteCharFromString((char *)firmwareRevision, WDC_NVME_FIRMWARE_REV_LEN9, ' ');
10180
10181	wdc_UtilsSnprintf((char *)bufferFolderName, MAX_PATH_LEN256, "%s_%s_%s_%s",
10182	"DRIVE_ESSENTIALS", (char )serialNo, (char )firmwareRevision, (char *)timeString);
10183
10184	if (dir) {
10185	wdc_UtilsSnprintf((char *)bufferFolderPath, MAX_PATH_LEN256, "%s%s%s",
10186	(char )dir, WDC_DE_PATH_SEPARATOR"/", (char )bufferFolderName);
10187	} else {
10188	retPtr = getcwd((char *)currDir, MAX_PATH_LEN256);
10189	if (retPtr) {
10190	wdc_UtilsSnprintf((char *)bufferFolderPath, MAX_PATH_LEN256, "%s%s%s",
10191	(char )currDir, WDC_DE_PATH_SEPARATOR"/", (char )bufferFolderName);
10192	} else {
10193	fprintf(stderrstderr, "ERROR: WDC: get current working directory failed\n");
10194	return -1;
10195	}
10196	}
10197
10198	ret = wdc_UtilsCreateDir((char *)bufferFolderPath);
10199	if (ret) {
10200	fprintf(stderrstderr, "ERROR: WDC: create directory failed, ret = %d, dir = %s\n", ret, bufferFolderPath);
10201	return -1;
10202	}
10203
10204	fprintf(stderrstderr, "Store Drive Essentials bin files in directory: %s\n", bufferFolderPath);
10205
10206	/* Get Identify Controller Data */
10207	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
10208	ret = nvme_identify_ctrl(hdl, &ctrl);
10209	if (ret) {
10210	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed, ret = %d\n", ret);
10211	return -1;
10212	}
10213
10214	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s_%s_%s.bin", (char *)bufferFolderPath,
10215	WDC_DE_PATH_SEPARATOR"/", "IdentifyController", (char *)serialNo,
10216	(char *)timeString);
10217	wdc_WriteToFile(fileName, (char *)&ctrl, sizeof(struct nvme_id_ctrl));
10218
10219	memset(&ns, 0, sizeof(struct nvme_id_ns));
10220	ret = nvme_identify_ns(hdl, 1, &ns);
10221	if (ret) {
10222	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ns() failed, ret = %d\n", ret);
10223	} else {
10224	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s_%s_%s.bin", (char *)bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
10225	"IdentifyNamespace", (char )serialNo, (char )timeString);
10226	wdc_WriteToFile(fileName, (char *)&ns, sizeof(struct nvme_id_ns));
10227	}
10228
10229	/* Get Log Pages (0x01, 0x02, 0x03, 0xC0 and 0xE3) */
10230	elogNumEntries = WDC_DE_DEFAULT_NUMBER_OF_ERROR_ENTRIES64;
10231	elogBufferSize = elogNumEntries*sizeof(struct nvme_error_log_page);
10232	dataBuffer = calloc(1, elogBufferSize);
10233	elogBuffer = (struct nvme_error_log_page *)dataBuffer;
10234
10235	ret = nvme_get_log_error(hdl, NVME_NSID_ALL, elogNumEntries, elogBuffer);
10236	if (ret) {
10237	fprintf(stderrstderr, "ERROR: WDC: nvme_error_log() failed, ret = %d\n", ret);
10238	} else {
10239	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s_%s_%s.bin", (char *)bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
10240	"ErrorLog", (char )serialNo, (char )timeString);
10241	wdc_WriteToFile(fileName, (char *)elogBuffer, elogBufferSize);
10242	}
10243
10244	free(dataBuffer);
10245	dataBuffer = NULL((void*)0);
10246
10247	/* Get Smart log page */
10248	memset(&smart_log, 0, sizeof(struct nvme_smart_log));
10249	ret = nvme_get_log_smart(hdl, NVME_NSID_ALL, &smart_log);
10250	if (ret) {
10251	fprintf(stderrstderr, "ERROR: WDC: nvme_smart_log() failed, ret = %d\n", ret);
10252	} else {
10253	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s_%s_%s.bin", (char *)bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
10254	"SmartLog", (char )serialNo, (char )timeString);
10255	wdc_WriteToFile(fileName, (char *)&smart_log, sizeof(struct nvme_smart_log));
10256	}
10257
10258	/* Get FW Slot log page */
10259	memset(&fw_log, 0, sizeof(struct nvme_firmware_slot));
10260	ret = nvme_get_log_fw_slot(hdl, false0, &fw_log);
10261	if (ret) {
10262	fprintf(stderrstderr, "ERROR: WDC: nvme_fw_log() failed, ret = %d\n", ret);
10263	} else {
10264	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s_%s_%s.bin", (char *)bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
10265	"FwSLotLog", (char )serialNo, (char )timeString);
10266	wdc_WriteToFile(fileName, (char *)&fw_log, sizeof(struct nvme_firmware_slot));
10267	}
10268
10269	/* Get VU log pages */
10270	/* define inputs for vendor unique log pages */
10271	vuLogInput = (struct WDC_NVME_DE_VU_LOGPAGES *)calloc(1, sizeof(struct WDC_NVME_DE_VU_LOGPAGES));
10272	vuLogInput->numOfVULogPages = ARRAY_SIZE(deVULogPagesList)(sizeof(deVULogPagesList) / sizeof((deVULogPagesList)[0]));
10273
10274	for (vuLogIdx = 0; vuLogIdx < vuLogInput->numOfVULogPages; vuLogIdx++) {
10275	dataBufferSize = deVULogPagesList[vuLogIdx].logPageLen;
10276	dataBuffer = calloc(1, dataBufferSize);
10277	memset(dataBuffer, 0, dataBufferSize);
10278
10279	ret = nvme_get_log_simple(hdl,
10280	deVULogPagesList[vuLogIdx].logPageId,
10281	dataBuffer, dataBufferSize);
10282	if (ret) {
10283	fprintf(stderrstderr, "ERROR: WDC: libnvme_get_log() for log page 0x%x failed, ret = %d\n",
10284	deVULogPagesList[vuLogIdx].logPageId, ret);
10285	} else {
10286	wdc_UtilsDeleteCharFromString((char *)deVULogPagesList[vuLogIdx].logPageIdStr, 4, ' ');
10287	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s_%s_%s_%s.bin", (char *)bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
10288	"LogPage", (char )&deVULogPagesList[vuLogIdx].logPageIdStr, (char )serialNo, (char *)timeString);
10289	wdc_WriteToFile(fileName, (char *)dataBuffer, dataBufferSize);
10290	}
10291
10292	free(dataBuffer);
10293	dataBuffer = NULL((void*)0);
10294	}
10295
10296	free(vuLogInput);
10297
10298	/* Get NVMe Features (0x01, 0x02, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0A, 0x0B, 0x0C) */
10299	for (listIdx = 1; listIdx < ARRAY_SIZE(deFeatureIdList)(sizeof(deFeatureIdList) / sizeof((deFeatureIdList)[0])); listIdx++) {
10300	memset(featureIdBuff, 0, sizeof(featureIdBuff));
10301	/* skipping LbaRangeType as it is an optional nvme command and not supported */
10302	if (deFeatureIdList[listIdx].featureId == FID_LBA_RANGE_TYPE)
10303	continue;
10304	ret = nvme_get_features(hdl, WDC_DE_GLOBAL_NSID0xFFFFFFFF,
10305	(enum nvme_features_id)deFeatureIdList[listIdx].featureId,
10306	NVME_GET_FEATURES_SEL_CURRENT, 0, 0, &featureIdBuff,
10307	sizeof(featureIdBuff), &result);
10308	if (ret) {
10309	fprintf(stderrstderr, "ERROR: WDC: nvme_get_feature id 0x%x failed, ret = %d\n",
10310	deFeatureIdList[listIdx].featureId, ret);
10311	} else {
10312	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s0x%x_%s_%s_%s.bin", (char *)bufferFolderPath, WDC_DE_PATH_SEPARATOR"/",
10313	"FEATURE_ID_", deFeatureIdList[listIdx].featureId,
10314	deFeatureIdList[listIdx].featureName, serialNo, timeString);
10315	wdc_WriteToFile(fileName, (char *)featureIdBuff, sizeof(featureIdBuff));
10316	}
10317	}
10318
10319	ret = wdc_read_debug_directory(hdl, bufferFolderPath, serialNo, timeString);
10320
10321	/* Get Dump Trace Data */
10322	wdc_UtilsSnprintf(fileName, MAX_PATH_LEN256, "%s%s%s_%s_%s.bin", (char *)bufferFolderPath, WDC_DE_PATH_SEPARATOR"/", "dumptrace", serialNo, timeString);
10323	ret = wdc_de_get_dump_trace(hdl, (char *)bufferFolderPath, 0, fileName);
10324	if (ret != WDC_STATUS_SUCCESS0)
10325	fprintf(stderrstderr, "ERROR: WDC: wdc_de_get_dump_trace failed, ret = %d\n", ret);
10326
10327	/* Tar the Drive Essentials directory */
10328	wdc_UtilsSnprintf(tarFileName, sizeof(tarFileName), "%s%s", (char *)bufferFolderPath, WDC_DE_TAR_FILE_EXTN".tar.gz");
10329	if (dir)
10330	wdc_UtilsSnprintf(tarFiles, sizeof(tarFiles), "%s%s%s%s%s", (char *)dir,
10331	WDC_DE_PATH_SEPARATOR"/", (char *)bufferFolderName,
10332	WDC_DE_PATH_SEPARATOR"/", WDC_DE_TAR_FILES"*.bin");
10333	else
10334	wdc_UtilsSnprintf(tarFiles, sizeof(tarFiles), "%s%s%s", (char *)bufferFolderName,
10335	WDC_DE_PATH_SEPARATOR"/", WDC_DE_TAR_FILES"*.bin");
10336	wdc_UtilsSnprintf(tarCmd, sizeof(tarCmd), "%s %s %s", WDC_DE_TAR_CMD"tar -czf", (char )tarFileName, (char )tarFiles);
10337
10338	ret = system(tarCmd);
10339
10340	if (ret)
10341	fprintf(stderrstderr, "ERROR: WDC: Tar of Drive Essentials data failed, ret = %d\n",
10342	ret);
10343
10344	fprintf(stderrstderr, "Get of Drive Essentials data successful\n");
10345	return 0;
10346	}
10347
10348	static int wdc_drive_essentials(int argc, char *argv, struct command acmd,
10349	struct plugin *plugin)
10350	{
10351	const char *desc = "Capture Drive Essentials.";
10352	const char *dirName = "Output directory pathname.";
10353	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
10354	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
10355	char d[PATH_MAX4096] = {0};
10356	char k[PATH_MAX4096] = {0};
10357	__u64 capabilities = 0;
10358	char *d_ptr;
10359	int ret;
10360
10361	struct config {
10362	char *dirName;
10363	};
10364
10365	struct config cfg = {
10366	.dirName = NULL((void*)0),
10367	};
10368
10369	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"dir-name", 'd', "DIRECTORY", CFG_STRING, &cfg.dirName , 1, dirName, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ( (void)0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v' , "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
10370	OPT_STRING("dir-name", 'd', "DIRECTORY", &cfg.dirName, dirName))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"dir-name", 'd', "DIRECTORY", CFG_STRING, &cfg.dirName , 1, dirName, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ( (void)0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v' , "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
10371
10372
10373	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
10374	if (ret)
10375	return ret;
10376
10377	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
10378	if (ret)
10379	return ret;
10380
10381	capabilities = wdc_get_drive_capabilities(ctx, hdl);
10382
10383	if ((capabilities & WDC_DRIVE_CAP_DRIVE_ESSENTIALS0x0000000100000000) != WDC_DRIVE_CAP_DRIVE_ESSENTIALS0x0000000100000000) {
10384	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
10385	ret = -1;
10386	goto out;
10387	}
10388
10389	if (cfg.dirName) {
10390	strncpy(d, cfg.dirName, PATH_MAX4096 - 1);
10391	d_ptr = d;
10392	} else {
10393	d_ptr = NULL((void*)0);
10394	}
10395
10396	ret = wdc_do_drive_essentials(ctx, hdl, d_ptr, k);
10397	out:
10398	return ret;
10399	}
10400
10401	static int wdc_do_drive_resize(struct libnvme_transport_handle *hdl, uint64_t new_size)
10402	{
10403	int ret;
10404	struct libnvme_passthru_cmd admin_cmd;
10405
10406	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
10407	admin_cmd.opcode = WDC_NVME_DRIVE_RESIZE_OPCODE0xCC;
10408	admin_cmd.cdw12 = ((WDC_NVME_DRIVE_RESIZE_SUBCMD0x01 << WDC_NVME_SUBCMD_SHIFT8) \|
10409	WDC_NVME_DRIVE_RESIZE_CMD0x03);
10410	admin_cmd.cdw13 = new_size;
10411
10412	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
10413	return ret;
10414	}
10415
10416	static int wdc_do_namespace_resize(struct libnvme_transport_handle *hdl, __u32 nsid, __u32 op_option)
10417	{
10418	int ret;
10419	struct libnvme_passthru_cmd admin_cmd;
10420
10421	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
10422	admin_cmd.opcode = WDC_NVME_NAMESPACE_RESIZE_OPCODE0xFB;
10423	admin_cmd.nsid = nsid;
10424	admin_cmd.cdw10 = op_option;
10425
10426	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
10427	return ret;
10428	}
10429
10430	static int wdc_do_drive_info(struct libnvme_transport_handle hdl, __u32 result)
10431	{
10432	int ret;
10433	struct libnvme_passthru_cmd admin_cmd;
10434
10435	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
10436	admin_cmd.opcode = WDC_NVME_DRIVE_INFO_OPCODE0xC6;
10437	admin_cmd.cdw12 = ((WDC_NVME_DRIVE_INFO_SUBCMD0x06 << WDC_NVME_SUBCMD_SHIFT8) \|
10438	WDC_NVME_DRIVE_INFO_CMD0x22);
10439
10440	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
10441
10442	if (!ret && result)
10443	*result = admin_cmd.result;
10444
10445	return ret;
10446	}
10447
10448	static int wdc_drive_resize(int argc, char **argv,
10449	struct command command, struct plugin plugin)
10450	{
10451	const char *desc = "Send a Resize command.";
10452	const char *size = "The new size (in GB) to resize the drive to.";
10453	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
10454	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
10455	uint64_t capabilities = 0;
10456	int ret;
10457
10458	struct config {
10459	uint64_t size;
10460	};
10461
10462	struct config cfg = {
10463	.size = 0,
10464	};
10465
10466	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"size", 's', "NUM", CFG_POSITIVE, &cfg.size, 1, size , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
10467	OPT_UINT("size", 's', &cfg.size, size))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"size", 's', "NUM", CFG_POSITIVE, &cfg.size, 1, size , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
10468
10469	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
10470	if (ret)
10471	return ret;
10472
10473	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
10474	if (ret \|\| !wdc_check_device(ctx, hdl))
10475	return -1;
10476
10477	capabilities = wdc_get_drive_capabilities(ctx, hdl);
10478
10479	if ((capabilities & WDC_DRIVE_CAP_RESIZE0x0000000000000100) == WDC_DRIVE_CAP_RESIZE0x0000000000000100) {
10480	ret = wdc_do_drive_resize(hdl, cfg.size);
10481	} else {
10482	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
10483	ret = -1;
10484	}
10485
10486	if (!ret)
10487	printf("New size: %" PRIu64"l" "u" " GB\n", cfg.size);
10488
10489	nvme_show_status(ret);
10490	return ret;
10491	}
10492
10493	static int wdc_namespace_resize(int argc, char **argv,
10494	struct command command, struct plugin plugin)
10495	{
10496	const char *desc = "Send a Namespace Resize command.";
10497	const char *namespace_id = "The namespace id to resize.";
10498	const char *op_option = "The over provisioning option to set for namespace.";
10499	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
10500	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
10501	uint64_t capabilities = 0;
10502	int ret;
10503
10504	struct config {
10505	__u32 namespace_id;
10506	__u32 op_option;
10507	};
10508
10509	struct config cfg = {
10510	.namespace_id = 0x1,
10511	.op_option = 0xF,
10512	};
10513
10514	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"op-option", 'O', "NUM", CFG_POSITIVE , &cfg.op_option, 1, op_option, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Global options", 0, ((void )0)}, {"verbose", 'v', "NUM", CFG_INCREMENT, &nvme_args. verbose, 0, "Increase output verbosity", 0, }, {"output-format" , 'o', "FMT", CFG_STRING, &nvme_args.output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
10515	OPT_UINT("namespace-id", 'n', &cfg.namespace_id, namespace_id),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"op-option", 'O', "NUM", CFG_POSITIVE , &cfg.op_option, 1, op_option, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Global options", 0, ((void )0)}, {"verbose", 'v', "NUM", CFG_INCREMENT, &nvme_args. verbose, 0, "Increase output verbosity", 0, }, {"output-format" , 'o', "FMT", CFG_STRING, &nvme_args.output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
10516	OPT_UINT("op-option", 'O', &cfg.op_option, op_option))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"op-option", 'O', "NUM", CFG_POSITIVE , &cfg.op_option, 1, op_option, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Global options", 0, ((void )0)}, {"verbose", 'v', "NUM", CFG_INCREMENT, &nvme_args. verbose, 0, "Increase output verbosity", 0, }, {"output-format" , 'o', "FMT", CFG_STRING, &nvme_args.output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
10517
10518	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
10519	if (ret)
10520	return ret;
10521
10522	if ((cfg.op_option != 0x1) && (cfg.op_option != 0x2) && (cfg.op_option != 0x3) &&
10523	(cfg.op_option != 0xF)) {
10524	fprintf(stderrstderr, "ERROR: WDC: unsupported OP option parameter\n");
10525	return -1;
10526	}
10527
10528	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
10529	if (ret \|\| !wdc_check_device(ctx, hdl))
10530	return -1;
10531
10532	capabilities = wdc_get_drive_capabilities(ctx, hdl);
10533
10534	if ((capabilities & WDC_DRIVE_CAP_NS_RESIZE0x0000000000040000) == WDC_DRIVE_CAP_NS_RESIZE0x0000000000040000) {
10535	ret = wdc_do_namespace_resize(hdl, cfg.namespace_id,
10536	cfg.op_option);
10537
10538	if (ret)
10539	printf("ERROR: WDC: Namespace Resize of namespace id 0x%x, op option 0x%x failed\n", cfg.namespace_id, cfg.op_option);
10540	} else {
10541	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
10542	ret = -1;
10543	}
10544
10545	nvme_show_status(ret);
10546	return ret;
10547	}
10548
10549	static int wdc_reason_identifier(int argc, char **argv,
10550	struct command command, struct plugin plugin)
10551	{
10552	const char *desc = "Retrieve telemetry log reason identifier.";
10553	const char *log_id = "Log ID to retrieve - host - 7 or controller - 8";
10554	const char *fname = "File name to save raw binary identifier";
10555	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
10556	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
10557	int ret;
10558	uint64_t capabilities = 0;
10559	char f[PATH_MAX4096] = {0};
10560	char fileSuffix[PATH_MAX4096] = {0};
10561	UtilsTimeInfo timeInfo;
10562	__u8 timeStamp[MAX_PATH_LEN256];
10563
10564
10565	struct config {
10566	int log_id;
10567	char *file;
10568	};
10569	struct config cfg = {
10570	.log_id = 7,
10571	.file = NULL((void*)0),
10572	};
10573
10574	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"log-id", 'i', "NUM", CFG_POSITIVE, &cfg.log_id, 1 , log_id, 0, }, {"file", 'O', "FILE", CFG_STRING, &cfg.file , 1, fname, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, (( void)0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v' , "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
10575	OPT_UINT("log-id", 'i', &cfg.log_id, log_id),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"log-id", 'i', "NUM", CFG_POSITIVE, &cfg.log_id, 1 , log_id, 0, }, {"file", 'O', "FILE", CFG_STRING, &cfg.file , 1, fname, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, (( void)0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v' , "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
10576	OPT_FILE("file", 'O', &cfg.file, fname))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"log-id", 'i', "NUM", CFG_POSITIVE, &cfg.log_id, 1 , log_id, 0, }, {"file", 'O', "FILE", CFG_STRING, &cfg.file , 1, fname, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, (( void)0), 0, "Global options", 0, ((void)0)}, {"verbose", 'v' , "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
10577
10578	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
10579
10580	if (ret)
10581	return ret;
10582
10583	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
10584	if (ret)
10585	return ret;
10586
10587	if (cfg.log_id != NVME_LOG_LID_TELEMETRY_HOST &&
10588	cfg.log_id != NVME_LOG_LID_TELEMETRY_CTRL) {
10589	fprintf(stderrstderr, "ERROR: WDC: Invalid Log ID. It must be 7 (Host) or 8 (Controller)\n");
10590	return -1;
10591	}
10592
10593	if (cfg.file) {
10594	int verify_file;
10595
10596	/* verify the passed in file name and path is valid before getting the dump data */
10597	verify_file = nvme_open_rawdata(cfg.file, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((cfg.file), (01 \| 0100 \| 01000), 0666);
10598	if (verify_file < 0) {
10599	fprintf(stderrstderr, "ERROR: WDC: open: %s\n", libnvme_strerror(errno(*__errno_location ())));
10600	return -1;
10601	}
10602	close(verify_file);
10603	strncpy(f, cfg.file, PATH_MAX4096 - 1);
10604	} else {
10605	wdc_UtilsGetTime(&timeInfo);
10606	memset(timeStamp, 0, sizeof(timeStamp));
10607	wdc_UtilsSnprintf((char *)timeStamp, MAX_PATH_LEN256, "%02u%02u%02u_%02u%02u%02u",
10608	timeInfo.year, timeInfo.month, timeInfo.dayOfMonth,
10609	timeInfo.hour, timeInfo.minute, timeInfo.second);
10610	if (cfg.log_id == NVME_LOG_LID_TELEMETRY_CTRL)
10611	snprintf(fileSuffix, PATH_MAX4096, "_error_reason_identifier_ctlr_%s", (char *)timeStamp);
10612	else
10613	snprintf(fileSuffix, PATH_MAX4096, "_error_reason_identifier_host_%s", (char *)timeStamp);
10614
10615	if (wdc_get_serial_name(hdl, f, PATH_MAX4096, fileSuffix) == -1) {
10616	fprintf(stderrstderr, "ERROR: WDC: failed to generate file name\n");
10617	return -1;
10618	}
10619	if (strlen(f) > PATH_MAX4096 - 5) {
10620	fprintf(stderrstderr, "ERROR: WDC: file name overflow\n");
10621	return -1;
10622	}
10623	strcat(f, ".bin");
10624	}
10625
10626	fprintf(stderrstderr, "%s: filename = %s\n", __func__, f);
10627
10628	capabilities = wdc_get_drive_capabilities(ctx, hdl);
10629	if ((capabilities & WDC_DRIVE_CAP_REASON_ID0x0000000000010000) == WDC_DRIVE_CAP_REASON_ID0x0000000000010000) {
10630	ret = wdc_do_get_reason_id(hdl, f, cfg.log_id);
10631	} else {
10632	fprintf(stderrstderr, "ERROR: WDC:unsupported device for this command\n");
10633	ret = -1;
10634	}
10635
10636	nvme_show_status(ret);
10637
10638	return ret;
10639	}
10640
10641	static const char *nvme_log_id_to_string(__u8 log_id)
10642	{
10643	switch (log_id) {
10644	case NVME_LOG_LID_ERROR:
10645	return "Error Information Log ID";
10646	case NVME_LOG_LID_SMART:
10647	return "Smart/Health Information Log ID";
10648	case NVME_LOG_LID_FW_SLOT:
10649	return "Firmware Slot Information Log ID";
10650	case NVME_LOG_LID_CHANGED_NS:
10651	return "Namespace Changed Log ID";
10652	case NVME_LOG_LID_CMD_EFFECTS:
10653	return "Commamds Supported and Effects Log ID";
10654	case NVME_LOG_LID_DEVICE_SELF_TEST:
10655	return "Device Self Test Log ID";
10656	case NVME_LOG_LID_TELEMETRY_HOST:
10657	return "Telemetry Host Initiated Log ID";
10658	case NVME_LOG_LID_TELEMETRY_CTRL:
10659	return "Telemetry Controller Generated Log ID";
10660	case NVME_LOG_LID_ENDURANCE_GROUP:
10661	return "Endurance Group Log ID";
10662	case NVME_LOG_LID_ANA:
10663	return "ANA Log ID";
10664	case NVME_LOG_LID_PERSISTENT_EVENT:
10665	return "Persistent Event Log ID";
10666	case NVME_LOG_LID_DISCOVERY:
10667	return "Discovery Log ID";
10668	case NVME_LOG_LID_RESERVATION:
10669	return "Reservation Notification Log ID";
10670	case NVME_LOG_LID_SANITIZE:
10671	return "Sanitize Status Log ID";
10672	case WDC_LOG_ID_C00xC0:
10673	return "WDC Vendor Unique Log ID C0";
10674	case WDC_LOG_ID_C10xC1:
10675	return "WDC Vendor Unique Log ID C1";
10676	case WDC_LOG_ID_C20xC2:
10677	return "WDC Vendor Unique Log ID C2";
10678	case WDC_LOG_ID_C30xC3:
10679	return "WDC Vendor Unique Log ID C3";
10680	case WDC_LOG_ID_C40xC4:
10681	return "WDC Vendor Unique Log ID C4";
10682	case WDC_LOG_ID_C50xC5:
10683	return "WDC Vendor Unique Log ID C5";
10684	case WDC_LOG_ID_C60xC6:
10685	return "WDC Vendor Unique Log ID C6";
10686	case WDC_LOG_ID_C80xC8:
10687	return "WDC Vendor Unique Log ID C8";
10688	case WDC_LOG_ID_CA0xCA:
10689	return "WDC Vendor Unique Log ID CA";
10690	case WDC_LOG_ID_CB0xCB:
10691	return "WDC Vendor Unique Log ID CB";
10692	case WDC_LOG_ID_D00xD0:
10693	return "WDC Vendor Unique Log ID D0";
10694	case WDC_LOG_ID_D10xD1:
10695	return "WDC Vendor Unique Log ID D1";
10696	case WDC_LOG_ID_D60xD6:
10697	return "WDC Vendor Unique Log ID D6";
10698	case WDC_LOG_ID_D70xD7:
10699	return "WDC Vendor Unique Log ID D7";
10700	case WDC_LOG_ID_D80xD8:
10701	return "WDC Vendor Unique Log ID D8";
10702	case WDC_LOG_ID_DE0xDE:
10703	return "WDC Vendor Unique Log ID DE";
10704	case WDC_LOG_ID_F00xF0:
10705	return "WDC Vendor Unique Log ID F0";
10706	case WDC_LOG_ID_F10xF1:
10707	return "WDC Vendor Unique Log ID F1";
10708	case WDC_LOG_ID_F20xF2:
10709	return "WDC Vendor Unique Log ID F2";
10710	case WDC_LOG_ID_FA0xFA:
10711	return "WDC Vendor Unique Log ID FA";
10712	default:
10713	return "Unknown Log ID";
10714	}
10715	}
10716
10717	static void __json_log_page_directory(struct log_page_directory *directory)
10718	{
10719	__u32 bitmap_idx;
10720	__u8 log_id;
10721	struct json_object *root;
10722	struct json_object *entries;
10723
10724	root = json_create_object()json_object_new_object();
10725
10726	entries = json_create_array()json_object_new_array();
10727	json_object_add_value_array(root, "Entries", entries)json_object_object_add(root, "Entries", entries);
10728
10729	for (bitmap_idx = 0; bitmap_idx < BYTE_TO_BIT(sizeof(__u64))((sizeof(__u64)) * 8); bitmap_idx++) {
10730	log_id = bitmap_idx;
10731	if (!log_page_name[log_id])
10732	continue;
10733	if (directory->supported_lid_bitmap & (1ULL << bitmap_idx)) {
10734	struct json_object *json_entry = json_create_object()json_object_new_object();
10735
10736	json_object_add_value_uint(json_entry, "Log ID", log_id)json_object_object_add(json_entry, "Log ID", json_object_new_uint64 (log_id));
10737	json_object_add_value_string(json_entry, "Log Page Name",
10738	log_page_name[log_id]);
10739
10740	json_array_add_value_object(entries, json_entry)json_object_array_add(entries, json_entry);
10741	}
10742	}
10743
10744	for (bitmap_idx = 0; bitmap_idx < BYTE_TO_BIT(sizeof(__u64))((sizeof(__u64)) * 8); bitmap_idx++) {
10745	log_id = NVME_LOG_NS_BASE + bitmap_idx;
10746	if (!log_page_name[log_id])
10747	continue;
10748	if (directory->supported_ns_lid_bitmap & (1ULL << bitmap_idx)) {
10749	struct json_object *json_entry = json_create_object()json_object_new_object();
10750
10751	json_object_add_value_uint(json_entry, "Log ID", log_id)json_object_object_add(json_entry, "Log ID", json_object_new_uint64 (log_id));
10752	json_object_add_value_string(json_entry, "Log Page Name",
10753	log_page_name[log_id]);
10754
10755	json_array_add_value_object(entries, json_entry)json_object_array_add(entries, json_entry);
10756	}
10757	}
10758
10759	for (bitmap_idx = 0; bitmap_idx < BYTE_TO_BIT(sizeof(__u64))((sizeof(__u64)) * 8); bitmap_idx++) {
10760	log_id = NVME_LOG_VS_BASE + bitmap_idx;
10761	if (!log_page_name[log_id])
10762	continue;
10763	if (directory->supported_vs_lid_bitmap & (1ULL << bitmap_idx)) {
10764	struct json_object *json_entry = json_create_object()json_object_new_object();
10765
10766	json_object_add_value_uint(json_entry, "Log ID", log_id)json_object_object_add(json_entry, "Log ID", json_object_new_uint64 (log_id));
10767	json_object_add_value_string(json_entry, "Log Page Name",
10768	log_page_name[log_id]);
10769
10770	json_array_add_value_object(entries, json_entry)json_object_array_add(entries, json_entry);
10771	}
10772	}
10773
10774	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
10775	printf("\n");
10776	json_free_object(root)json_object_put(root);
10777	}
10778
10779
10780	static void __show_log_page_directory(struct log_page_directory *directory)
10781	{
10782	__u32 bitmap_idx;
10783	__u8 log_id;
10784
10785	for (bitmap_idx = 0; bitmap_idx < BYTE_TO_BIT(sizeof(__u64))((sizeof(__u64)) * 8); bitmap_idx++) {
10786	if (directory->supported_lid_bitmap & (1ULL << bitmap_idx)) {
10787	log_id = bitmap_idx;
10788	if (log_page_name[log_id])
10789	printf("0x%02X: %s\n", log_id, log_page_name[log_id]);
10790	}
10791	}
10792
10793	for (bitmap_idx = 0; bitmap_idx < BYTE_TO_BIT(sizeof(__u64))((sizeof(__u64)) * 8); bitmap_idx++) {
10794	if (directory->supported_ns_lid_bitmap & (1ULL << bitmap_idx)) {
10795	log_id = NVME_LOG_NS_BASE + bitmap_idx;
10796	if (log_page_name[log_id])
10797	printf("0x%02X: %s\n", log_id, log_page_name[log_id]);
10798	}
10799	}
10800
10801	for (bitmap_idx = 0; bitmap_idx < BYTE_TO_BIT(sizeof(__u64))((sizeof(__u64)) * 8); bitmap_idx++) {
10802	if (directory->supported_vs_lid_bitmap & (1ULL << bitmap_idx)) {
10803	log_id = NVME_LOG_VS_BASE + bitmap_idx;
10804	if (log_page_name[log_id])
10805	printf("0x%02X: %s\n", log_id, log_page_name[log_id]);
10806	}
10807	}
10808	}
10809
10810	static int wdc_log_page_directory(int argc, char *argv, struct command acmd,
10811	struct plugin *plugin)
10812	{
10813	const char *desc = "Retrieve Log Page Directory.";
10814	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
10815	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
10816	nvme_print_flags_t fmt;
10817	int ret = 0;
10818	__u64 capabilities = 0;
10819	struct wdc_c2_cbs_data cbs_data = NULL((void)0);
10820	int i, uuid_index = 0;
10821	__u8 log_id = 0;
10822	__u32 device_id, read_vendor_id;
10823	bool_Bool uuid_supported = false0;
10824	struct nvme_id_uuid_list uuid_list;
10825
10826	struct config {
10827	char *output_format;
10828	};
10829
10830	struct config cfg = {
10831	.output_format = "normal",
10832	};
10833
10834	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
10835
10836	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
10837	if (ret)
10838	return ret;
10839
10840	ret = validate_output_format(cfg.output_format, &fmt);
10841	if (ret < 0) {
10842	fprintf(stderrstderr, "%s: ERROR: WDC: invalid output format\n", __func__);
10843	return ret;
10844	}
10845
10846	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
10847	if (ret)
10848	return ret;
10849
10850	capabilities = wdc_get_drive_capabilities(ctx, hdl);
10851
10852	if (!(capabilities & WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000)) {
10853	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
10854	ret = -1;
10855	} else {
10856	memset(&uuid_list, 0, sizeof(struct nvme_id_uuid_list));
10857	if (wdc_CheckUuidListSupport(hdl, &uuid_list))
10858	uuid_supported = true1;
10859
10860	if (uuid_supported)
10861	fprintf(stderrstderr, "WDC: UUID lists supported\n");
10862	else
10863	fprintf(stderrstderr, "WDC: UUID lists NOT supported\n");
10864
10865
10866	ret = wdc_get_pci_ids(ctx, hdl, &device_id, &read_vendor_id);
10867	log_id = wdc_is_zn350(device_id) ?
10868	WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID_C80xC8 :
10869	WDC_NVME_GET_DEV_MGMNT_LOG_PAGE_ID0xC2;
10870
10871	if (!wdc_is_sn861(device_id)) {
10872	if (uuid_supported) {
10873	/* check for the Sandisk UUID first */
10874	uuid_index = libnvme_find_uuid(&uuid_list, SNDK_UUID);
10875
10876	if (uuid_index < 0)
10877	/* The Sandisk UUID is not found;
10878	* check for the WDC UUID second.
10879	*/
10880	uuid_index = libnvme_find_uuid(&uuid_list, WDC_UUID);
10881	}
10882
10883	/* WD UUID not found, use default uuid index - 0 */
10884	if (uuid_index < 0)
10885	uuid_index = 0;
10886
10887	/* verify the 0xC2 Device Manageability log page is supported */
10888	if (!wdc_nvme_check_supported_log_page(ctx, hdl, log_id, uuid_index)) {
10889	fprintf(stderrstderr, "%s: ERROR: WDC: 0x%x Log Page not supported\n",
10890	__func__, log_id);
10891	ret = -1;
10892	goto out;
10893	}
10894
10895	if (!get_dev_mgment_cbs_data(ctx, hdl,
10896	WDC_C2_LOG_PAGES_SUPPORTED_ID0x08,
10897	(void *)&cbs_data)) {
10898	fprintf(stderrstderr,
10899	"%s: ERROR: WDC: 0xC2 Log Page entry ID 0x%x not found\n",
10900	__func__, WDC_C2_LOG_PAGES_SUPPORTED_ID0x08);
10901	ret = -1;
10902	goto out;
10903	}
10904	if (!cbs_data) {
10905	fprintf(stderrstderr, "%s: ERROR: WDC: NULL_data ptr\n", __func__);
10906	ret = -1;
10907	goto out;
10908	}
10909	printf("Log Page Directory\n");
10910	/* print the supported pages */
10911	if (!strcmp(cfg.output_format, "normal")) {
10912	for (i = 0; i < le32_to_cpu(cbs_data->length); i++)
10913	printf("0x%x - %s\n", cbs_data->data[i],
10914	nvme_log_id_to_string(cbs_data->data[i]));
10915	} else if (!strcmp(cfg.output_format, "binary")) {
10916	d((__u8 *)cbs_data->data,
10917	le32_to_cpu(cbs_data->length), 16, 1);
10918	} else if (!strcmp(cfg.output_format, "json")) {
10919	struct json_object *root = json_create_object()json_object_new_object();
10920
10921	for (i = 0; i < le32_to_cpu(cbs_data->length); i++) {
10922	json_object_add_value_int(root,json_object_object_add(root, nvme_log_id_to_string(cbs_data-> data[i]), json_object_new_int(cbs_data->data[i]))
10923	nvme_log_id_to_string(cbs_data->data[i]),json_object_object_add(root, nvme_log_id_to_string(cbs_data-> data[i]), json_object_new_int(cbs_data->data[i]))
10924	cbs_data->data[i])json_object_object_add(root, nvme_log_id_to_string(cbs_data-> data[i]), json_object_new_int(cbs_data->data[i]));
10925	}
10926
10927	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
10928	printf("\n");
10929	json_free_object(root)json_object_put(root);
10930	} else {
10931	fprintf(stderrstderr,
10932	"%s: ERROR: WDC: Invalid format, format = %s\n",
10933	__func__, cfg.output_format);
10934	}
10935
10936	free(cbs_data);
10937	} else {
10938	struct log_page_directory *dir;
10939	__cleanup_libnvme_free__attribute__((cleanup(libnvme_freep))) void data = NULL((void)0);
10940
10941	data = libnvme_alloc(512);
10942	if (!data) {
10943	fprintf(stderrstderr,
10944	"can not allocate log page directory payload\n");
10945	return -ENOMEM12;
10946	}
10947
10948	dir = (struct log_page_directory *)data;
10949	struct libnvme_passthru_cmd cmd = {
10950	.opcode = WDC_NVME_ADMIN_VUC_OPCODE_D2,
10951	.cdw10 = 8,
10952	.cdw12 = WDC_VUC_SUBOPCODE_LOG_PAGE_DIR_D2,
10953	.addr = (__u64)(uintptr_t)data,
10954	.data_len = 32,
10955	};
10956
10957	ret = libnvme_exec_admin_passthru(hdl, &cmd);
10958	if (!ret) {
10959	switch (fmt) {
10960	case BINARY:
10961	d_raw((unsigned char *)data, 32);
10962	break;
10963	case JSON:
10964	__json_log_page_directory(dir);
10965	break;
10966	default:
10967	__show_log_page_directory(dir);
10968	}
10969	} else {
10970	fprintf(stderrstderr, "NVMe Status:%s(%x)\n",
10971	libnvme_status_to_string(ret, false0), ret);
10972	}
10973	}
10974	}
10975
10976	out:
10977	return ret;
10978	}
10979
10980	static int wdc_get_drive_reason_id(struct libnvme_transport_handle hdl, char drive_reason_id, size_t len)
10981	{
10982	const char *reason_id_str = "reason_id";
10983	struct nvme_id_ctrl ctrl;
10984	int res_len = 0;
10985	int i, j;
10986	int ret;
10987
10988	i = sizeof(ctrl.sn) - 1;
10989	j = sizeof(ctrl.mn) - 1;
10990	memset(drive_reason_id, 0, len);
10991	memset(&ctrl, 0, sizeof(struct nvme_id_ctrl));
10992	ret = nvme_identify_ctrl(hdl, &ctrl);
10993	if (ret) {
10994	fprintf(stderrstderr, "ERROR: WDC: nvme_identify_ctrl() failed 0x%x\n", ret);
10995	return -1;
10996	}
10997	/* Remove trailing spaces from the sn and mn */
10998	while (i && ctrl.sn[i] == ' ') {
10999	ctrl.sn[i] = '\0';
11000	i--;
11001	}
11002
11003	while (j && ctrl.mn[j] == ' ') {
11004	ctrl.mn[j] = '\0';
11005	j--;
11006	}
11007
11008	res_len = snprintf(drive_reason_id, len, "%s_%s_%s", ctrl.sn, ctrl.mn, reason_id_str);
11009	if (len <= res_len) {
11010	fprintf(stderrstderr,
11011	"ERROR: WDC: cannot format serial number due to data of unexpected length\n");
11012	return -1;
11013	}
11014
11015	return 0;
11016	}
11017
11018	static int wdc_save_reason_id(struct libnvme_transport_handle hdl, __u8 rsn_ident, int size)
11019	{
11020	int ret = 0;
11021	char *reason_id_file;
11022	char drive_reason_id[PATH_MAX4096] = {0};
11023	char reason_id_path[PATH_MAX4096] = WDC_REASON_ID_PATH_NAME"/usr/local/nvmecli";
11024	struct stat st = {0};
11025
11026	if (wdc_get_drive_reason_id(hdl, drive_reason_id, PATH_MAX4096) == -1) {
11027	fprintf(stderrstderr, "%s: ERROR: failed to get drive reason id\n", __func__);
11028	return -1;
11029	}
11030
11031	/* make the nvmecli dir in /usr/local if it doesn't already exist */
11032	if (stat(reason_id_path, &st) == -1) {
11033	if (mkdir(reason_id_path, 0700) < 0) {
11034	fprintf(stderrstderr, "%s: ERROR: failed to mkdir %s: %s\n",
11035	__func__, reason_id_path, libnvme_strerror(errno(*__errno_location ())));
11036	return -1;
11037	}
11038	}
11039
11040	if (asprintf(&reason_id_file, "%s/%s%s", reason_id_path,
11041	drive_reason_id, ".bin") < 0)
11042	return -ENOMEM12;
11043
11044	fprintf(stderrstderr, "%s: reason id file = %s\n", __func__, reason_id_file);
11045
11046	/* save off the error reason identifier to a file in /usr/local/nvmecli */
11047	ret = wdc_create_log_file(reason_id_file, rsn_ident, WDC_REASON_ID_ENTRY_LEN128);
11048	free(reason_id_file);
11049
11050	return ret;
11051	}
11052
11053	static int wdc_clear_reason_id(struct libnvme_transport_handle *hdl)
11054	{
11055	int ret = -1;
11056	int verify_file;
11057	char *reason_id_file;
11058	char drive_reason_id[PATH_MAX4096] = {0};
11059
11060	if (wdc_get_drive_reason_id(hdl, drive_reason_id, PATH_MAX4096) == -1) {
11061	fprintf(stderrstderr, "%s: ERROR: failed to get drive reason id\n", __func__);
11062	return -1;
11063	}
11064
11065	if (asprintf(&reason_id_file, "%s/%s%s", WDC_REASON_ID_PATH_NAME"/usr/local/nvmecli",
11066	drive_reason_id, ".bin") < 0)
11067	return -ENOMEM12;
11068
11069	/* verify the drive reason id file name and path is valid */
11070	verify_file = nvme_open_rawdata(reason_id_file, O_WRONLY \| O_CREAT \| O_TRUNC, 0666)open((reason_id_file), (01 \| 0100 \| 01000), 0666);
11071	if (verify_file < 0) {
11072	ret = -1;
11073	goto free;
11074	}
11075	close(verify_file);
11076
11077	/* remove the reason id file */
11078	ret = remove(reason_id_file);
11079
11080	free:
11081	free(reason_id_file);
11082
11083	return ret;
11084	}
11085
11086	static int wdc_dump_telemetry_hdr(struct libnvme_transport_handle hdl, int log_id, struct nvme_telemetry_log log_hdr)
11087	{
11088	int ret = 0;
11089
11090	if (log_id == NVME_LOG_LID_TELEMETRY_HOST)
11091	ret = nvme_get_log_create_telemetry_host(hdl, log_hdr);
11092	else
11093	ret = nvme_get_log_telemetry_ctrl(hdl, false0, 0, (void *)log_hdr, 512);
11094
11095	if (ret < 0) {
11096	perror("get-telemetry-log");
11097	} else if (ret > 0) {
11098	nvme_show_status(ret);
11099	fprintf(stderrstderr, "%s: ERROR: Failed to acquire telemetry header, ret = %d!\n", __func__, ret);
11100	}
11101
11102	return ret;
11103	}
11104
11105	static int wdc_do_get_reason_id(struct libnvme_transport_handle hdl, const char file, int log_id)
11106	{
11107	int ret;
11108	struct nvme_telemetry_log *log_hdr;
11109	__u32 log_hdr_size = sizeof(struct nvme_telemetry_log);
11110	__u32 reason_id_size = 0;
11111
11112	log_hdr = (struct nvme_telemetry_log *)malloc(log_hdr_size);
11113	if (!log_hdr) {
11114	fprintf(stderrstderr, "%s: ERROR: malloc failed, size : 0x%x, status: %s\n", __func__, log_hdr_size, libnvme_strerror(errno(*__errno_location ())));
11115	ret = -1;
11116	goto out;
11117	}
11118	memset(log_hdr, 0, log_hdr_size);
11119
11120	ret = wdc_dump_telemetry_hdr(hdl, log_id, log_hdr);
11121	if (ret) {
11122	fprintf(stderrstderr, "%s: ERROR: get telemetry header failed, ret : %d\n", __func__, ret);
11123	ret = -1;
11124	goto out;
11125	}
11126
11127	reason_id_size = sizeof(log_hdr->rsnident);
11128
11129	if (log_id == NVME_LOG_LID_TELEMETRY_CTRL)
11130	wdc_save_reason_id(hdl, log_hdr->rsnident, reason_id_size);
11131
11132	ret = wdc_create_log_file(file, (__u8 *)log_hdr->rsnident, reason_id_size);
11133
11134	out:
11135	free(log_hdr);
11136	return ret;
11137	}
11138
11139	static void wdc_print_nand_stats_normal(__u16 version, void *data)
11140	{
11141	struct wdc_nand_stats nand_stats = (struct wdc_nand_stats )(data);
11142	struct wdc_nand_stats_V3 nand_stats_v3 = (struct wdc_nand_stats_V3 )(data);
11143	__u64 temp_raw;
11144	__u16 temp_norm;
11145	__u64 temp_ptr = NULL((void)0);
11146
11147	switch (version) {
11148	case 0:
11149	printf(" NAND Statistics :-\n");
11150	printf(" NAND Writes TLC (Bytes) %s\n",
11151	uint128_t_to_string(
11152	le128_to_cpu(nand_stats->nand_write_tlc)));
11153	printf(" NAND Writes SLC (Bytes) %s\n",
11154	uint128_t_to_string(
11155	le128_to_cpu(nand_stats->nand_write_slc)));
11156	printf(" NAND Program Failures %"PRIu32"u""\n",
11157	(uint32_t)le32_to_cpu(nand_stats->nand_prog_failure));
11158	printf(" NAND Erase Failures %"PRIu32"u""\n",
11159	(uint32_t)le32_to_cpu(nand_stats->nand_erase_failure));
11160	printf(" Bad Block Count %"PRIu32"u""\n",
11161	(uint32_t)le32_to_cpu(nand_stats->bad_block_count));
11162	printf(" NAND XOR/RAID Recovery Trigger Events %"PRIu64"l" "u""\n",
11163	le64_to_cpu(nand_stats->nand_rec_trigger_event));
11164	printf(" E2E Error Counter %"PRIu64"l" "u""\n",
11165	le64_to_cpu(nand_stats->e2e_error_counter));
11166	printf(" Number Successful NS Resizing Events %"PRIu64"l" "u""\n",
11167	le64_to_cpu(nand_stats->successful_ns_resize_event));
11168	printf(" log page version %"PRIu16"u""\n",
11169	le16_to_cpu(nand_stats->log_page_version));
11170	break;
11171	case 3:
11172	printf(" NAND Statistics V3:-\n");
11173	printf(" TLC Units Written %s\n",
11174	uint128_t_to_string(
11175	le128_to_cpu(nand_stats_v3->nand_write_tlc)));
11176	printf(" SLC Units Written %s\n",
11177	uint128_t_to_string(
11178	le128_to_cpu(nand_stats_v3->nand_write_slc)));
11179	temp_ptr = (__u64 *)nand_stats_v3->bad_nand_block_count;
11180	temp_norm = (__u16)(*temp_ptr & 0x000000000000FFFF);
11181	temp_raw = ((*temp_ptr & 0xFFFFFFFFFFFF0000) >> 16);
11182	printf(" Bad NAND Blocks Count - Normalized %"PRIu16"u""\n",
11183	le16_to_cpu(temp_norm));
11184	printf(" Bad NAND Blocks Count - Raw %"PRIu64"l" "u""\n",
11185	le64_to_cpu(temp_raw));
11186	printf(" NAND XOR Recovery count %"PRIu64"l" "u""\n",
11187	le64_to_cpu(nand_stats_v3->xor_recovery_count));
11188	printf(" UECC Read Error count %"PRIu64"l" "u""\n",
11189	le64_to_cpu(nand_stats_v3->uecc_read_error_count));
11190	printf(" SSD End to End corrected errors %"PRIu64"l" "u""\n",
11191	le64_to_cpu(nand_stats_v3->ssd_correction_counts[0]));
11192	printf(" SSD End to End detected errors %"PRIu32"u""\n",
11193	le32_to_cpu(nand_stats_v3->ssd_correction_counts[8]));
11194	printf(" SSD End to End uncorrected E2E errors %"PRIu32"u""\n",
11195	le32_to_cpu(nand_stats_v3->ssd_correction_counts[12]));
11196	printf(" System data %% life-used %u\n",
11197	nand_stats_v3->percent_life_used);
11198	printf(" User Data Erase Counts - TLC Min %"PRIu64"l" "u""\n",
11199	le64_to_cpu(nand_stats_v3->user_data_erase_counts[0]));
11200	printf(" User Data Erase Counts - TLC Max %"PRIu64"l" "u""\n",
11201	le64_to_cpu(nand_stats_v3->user_data_erase_counts[1]));
11202	printf(" User Data Erase Counts - SLC Min %"PRIu64"l" "u""\n",
11203	le64_to_cpu(nand_stats_v3->user_data_erase_counts[2]));
11204	printf(" User Data Erase Counts - SLC Max %"PRIu64"l" "u""\n",
11205	le64_to_cpu(nand_stats_v3->user_data_erase_counts[3]));
11206	temp_ptr = (__u64 *)nand_stats_v3->program_fail_count;
11207	temp_norm = (__u16)(*temp_ptr & 0x000000000000FFFF);
11208	temp_raw = ((*temp_ptr & 0xFFFFFFFFFFFF0000) >> 16);
11209	printf(" Program Fail Count - Normalized %"PRIu16"u""\n",
11210	le16_to_cpu(temp_norm));
11211	printf(" Program Fail Count - Raw %"PRIu64"l" "u""\n",
11212	le64_to_cpu(temp_raw));
11213	temp_ptr = (__u64 *)nand_stats_v3->erase_fail_count;
11214	temp_norm = (__u16)(*temp_ptr & 0x000000000000FFFF);
11215	temp_raw = ((*temp_ptr & 0xFFFFFFFFFFFF0000) >> 16);
11216	printf(" Erase Fail Count - Normalized %"PRIu16"u""\n",
11217	le16_to_cpu(temp_norm));
11218	printf(" Erase Fail Count - Raw %"PRIu64"l" "u""\n",
11219	le64_to_cpu(temp_raw));
11220	printf(" PCIe Correctable Error Count %"PRIu16"u""\n",
11221	le16_to_cpu(nand_stats_v3->correctable_error_count));
11222	printf(" %% Free Blocks (User) %u\n",
11223	nand_stats_v3->percent_free_blocks_user);
11224	printf(" Security Version Number %"PRIu64"l" "u""\n",
11225	le64_to_cpu(nand_stats_v3->security_version_number));
11226	printf(" %% Free Blocks (System) %u\n",
11227	nand_stats_v3->percent_free_blocks_system);
11228	printf(" Data Set Management Commands %s\n",
11229	uint128_t_to_string(
11230	le128_to_cpu(nand_stats_v3->trim_completions)));
11231	printf(" Estimate of Incomplete Trim Data %"PRIu64"l" "u""\n",
11232	le64_to_cpu(nand_stats_v3->trim_completions[16]));
11233	printf(" %% of completed trim %u\n",
11234	nand_stats_v3->trim_completions[24]);
11235	printf(" Background Back-Pressure-Guage %u\n",
11236	nand_stats_v3->back_pressure_guage);
11237	printf(" Soft ECC Error Count %"PRIu64"l" "u""\n",
11238	le64_to_cpu(nand_stats_v3->soft_ecc_error_count));
11239	printf(" Refresh Count %"PRIu64"l" "u""\n",
11240	le64_to_cpu(nand_stats_v3->refresh_count));
11241	temp_ptr = (__u64 *)nand_stats_v3->bad_sys_nand_block_count;
11242	temp_norm = (__u16)(*temp_ptr & 0x000000000000FFFF);
11243	temp_raw = ((*temp_ptr & 0xFFFFFFFFFFFF0000) >> 16);
11244	printf(" Bad System Nand Block Count - Normalized %"PRIu16"u""\n",
11245	le16_to_cpu(temp_norm));
11246	printf(" Bad System Nand Block Count - Raw %"PRIu64"l" "u""\n",
11247	le64_to_cpu(temp_raw));
11248	printf(" Endurance Estimate %s\n",
11249	uint128_t_to_string(
11250	le128_to_cpu(nand_stats_v3->endurance_estimate)));
11251	printf(" Thermal Throttling Count %u\n",
11252	nand_stats_v3->thermal_throttling_st_ct[0]);
11253	printf(" Thermal Throttling Status %u\n",
11254	nand_stats_v3->thermal_throttling_st_ct[1]);
11255	printf(" Unaligned I/O %"PRIu64"l" "u""\n",
11256	le64_to_cpu(nand_stats_v3->unaligned_IO));
11257	printf(" Physical Media Units Read %s\n",
11258	uint128_t_to_string(
11259	le128_to_cpu(nand_stats_v3->physical_media_units)));
11260	printf(" log page version %"PRIu16"u""\n",
11261	le16_to_cpu(nand_stats_v3->log_page_version));
11262	break;
11263
11264	default:
11265	fprintf(stderrstderr, "WDC: Nand Stats ERROR: Invalid version\n");
11266	break;
11267
11268	}
11269	}
11270
11271	static void wdc_print_nand_stats_json(__u16 version, void *data)
11272	{
11273	struct wdc_nand_stats nand_stats = (struct wdc_nand_stats )(data);
11274	struct wdc_nand_stats_V3 nand_stats_v3 = (struct wdc_nand_stats_V3 )(data);
11275	struct json_object *root = json_create_object()json_object_new_object();
11276	__u64 temp_raw;
11277	__u16 temp_norm;
11278	__u64 temp_ptr = NULL((void)0);
11279
11280	switch (version) {
11281	case 0:
11282	json_object_add_value_uint128(root, "NAND Writes TLC (Bytes)",json_object_object_add(root, "NAND Writes TLC (Bytes)", util_json_object_new_uint128 (le128_to_cpu(nand_stats->nand_write_tlc)))
11283	le128_to_cpu(nand_stats->nand_write_tlc))json_object_object_add(root, "NAND Writes TLC (Bytes)", util_json_object_new_uint128 (le128_to_cpu(nand_stats->nand_write_tlc)));
11284	json_object_add_value_uint128(root, "NAND Writes SLC (Bytes)",json_object_object_add(root, "NAND Writes SLC (Bytes)", util_json_object_new_uint128 (le128_to_cpu(nand_stats->nand_write_slc)))
11285	le128_to_cpu(nand_stats->nand_write_slc))json_object_object_add(root, "NAND Writes SLC (Bytes)", util_json_object_new_uint128 (le128_to_cpu(nand_stats->nand_write_slc)));
11286	json_object_add_value_uint(root, "NAND Program Failures",json_object_object_add(root, "NAND Program Failures", json_object_new_uint64 (le32_to_cpu(nand_stats->nand_prog_failure)))
11287	le32_to_cpu(nand_stats->nand_prog_failure))json_object_object_add(root, "NAND Program Failures", json_object_new_uint64 (le32_to_cpu(nand_stats->nand_prog_failure)));
11288	json_object_add_value_uint(root, "NAND Erase Failures",json_object_object_add(root, "NAND Erase Failures", json_object_new_uint64 (le32_to_cpu(nand_stats->nand_erase_failure)))
11289	le32_to_cpu(nand_stats->nand_erase_failure))json_object_object_add(root, "NAND Erase Failures", json_object_new_uint64 (le32_to_cpu(nand_stats->nand_erase_failure)));
11290	json_object_add_value_uint(root, "Bad Block Count",json_object_object_add(root, "Bad Block Count", json_object_new_uint64 (le32_to_cpu(nand_stats->bad_block_count)))
11291	le32_to_cpu(nand_stats->bad_block_count))json_object_object_add(root, "Bad Block Count", json_object_new_uint64 (le32_to_cpu(nand_stats->bad_block_count)));
11292	json_object_add_value_uint64(root, "NAND XOR/RAID Recovery Trigger Events",json_object_object_add(root, "NAND XOR/RAID Recovery Trigger Events" , json_object_new_uint64(le64_to_cpu(nand_stats->nand_rec_trigger_event )))
11293	le64_to_cpu(nand_stats->nand_rec_trigger_event))json_object_object_add(root, "NAND XOR/RAID Recovery Trigger Events" , json_object_new_uint64(le64_to_cpu(nand_stats->nand_rec_trigger_event )));
11294	json_object_add_value_uint64(root, "E2E Error Counter",json_object_object_add(root, "E2E Error Counter", json_object_new_uint64 (le64_to_cpu(nand_stats->e2e_error_counter)))
11295	le64_to_cpu(nand_stats->e2e_error_counter))json_object_object_add(root, "E2E Error Counter", json_object_new_uint64 (le64_to_cpu(nand_stats->e2e_error_counter)));
11296	json_object_add_value_uint64(root, "Number Successful NS Resizing Events",json_object_object_add(root, "Number Successful NS Resizing Events" , json_object_new_uint64(le64_to_cpu(nand_stats->successful_ns_resize_event )))
11297	le64_to_cpu(nand_stats->successful_ns_resize_event))json_object_object_add(root, "Number Successful NS Resizing Events" , json_object_new_uint64(le64_to_cpu(nand_stats->successful_ns_resize_event )));
11298
11299	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
11300	printf("\n");
11301	break;
11302	case 3:
11303	json_object_add_value_uint128(root, "NAND Writes TLC (Bytes)",json_object_object_add(root, "NAND Writes TLC (Bytes)", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->nand_write_tlc)))
11304	le128_to_cpu(nand_stats_v3->nand_write_tlc))json_object_object_add(root, "NAND Writes TLC (Bytes)", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->nand_write_tlc)));
11305	json_object_add_value_uint128(root, "NAND Writes SLC (Bytes)",json_object_object_add(root, "NAND Writes SLC (Bytes)", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->nand_write_slc)))
11306	le128_to_cpu(nand_stats_v3->nand_write_slc))json_object_object_add(root, "NAND Writes SLC (Bytes)", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->nand_write_slc)));
11307	temp_ptr = (__u64 *)nand_stats_v3->bad_nand_block_count;
11308	temp_norm = (__u16)(*temp_ptr & 0x000000000000FFFF);
11309	temp_raw = ((*temp_ptr & 0xFFFFFFFFFFFF0000) >> 16);
11310	json_object_add_value_uint(root, "Bad NAND Blocks Count - Normalized",json_object_object_add(root, "Bad NAND Blocks Count - Normalized" , json_object_new_uint64(le16_to_cpu(temp_norm)))
11311	le16_to_cpu(temp_norm))json_object_object_add(root, "Bad NAND Blocks Count - Normalized" , json_object_new_uint64(le16_to_cpu(temp_norm)));
11312	json_object_add_value_uint64(root, "Bad NAND Blocks Count - Raw",json_object_object_add(root, "Bad NAND Blocks Count - Raw", json_object_new_uint64 (le64_to_cpu(temp_raw)))
11313	le64_to_cpu(temp_raw))json_object_object_add(root, "Bad NAND Blocks Count - Raw", json_object_new_uint64 (le64_to_cpu(temp_raw)));
11314	json_object_add_value_uint64(root, "NAND XOR Recovery count",json_object_object_add(root, "NAND XOR Recovery count", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->xor_recovery_count)))
11315	le64_to_cpu(nand_stats_v3->xor_recovery_count))json_object_object_add(root, "NAND XOR Recovery count", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->xor_recovery_count)));
11316	json_object_add_value_uint64(root, "UECC Read Error count",json_object_object_add(root, "UECC Read Error count", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->uecc_read_error_count)))
11317	le64_to_cpu(nand_stats_v3->uecc_read_error_count))json_object_object_add(root, "UECC Read Error count", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->uecc_read_error_count)));
11318	json_object_add_value_uint64(root, "SSD End to End corrected errors",json_object_object_add(root, "SSD End to End corrected errors" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->ssd_correction_counts [0])))
11319	le64_to_cpu(nand_stats_v3->ssd_correction_counts[0]))json_object_object_add(root, "SSD End to End corrected errors" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->ssd_correction_counts [0])));
11320	json_object_add_value_uint(root, "SSD End to End detected errors",json_object_object_add(root, "SSD End to End detected errors" , json_object_new_uint64(le32_to_cpu(nand_stats_v3->ssd_correction_counts [8])))
11321	le32_to_cpu(nand_stats_v3->ssd_correction_counts[8]))json_object_object_add(root, "SSD End to End detected errors" , json_object_new_uint64(le32_to_cpu(nand_stats_v3->ssd_correction_counts [8])));
11322	json_object_add_value_uint(root, "SSD End to End uncorrected E2E errors",json_object_object_add(root, "SSD End to End uncorrected E2E errors" , json_object_new_uint64(le32_to_cpu(nand_stats_v3->ssd_correction_counts [12])))
11323	le32_to_cpu(nand_stats_v3->ssd_correction_counts[12]))json_object_object_add(root, "SSD End to End uncorrected E2E errors" , json_object_new_uint64(le32_to_cpu(nand_stats_v3->ssd_correction_counts [12])));
11324	json_object_add_value_uint(root, "System data % life-used",json_object_object_add(root, "System data % life-used", json_object_new_uint64 (nand_stats_v3->percent_life_used))
11325	nand_stats_v3->percent_life_used)json_object_object_add(root, "System data % life-used", json_object_new_uint64 (nand_stats_v3->percent_life_used));
11326	json_object_add_value_uint64(root, "User Data Erase Counts - TLC Min",json_object_object_add(root, "User Data Erase Counts - TLC Min" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->user_data_erase_counts [0])))
11327	le64_to_cpu(nand_stats_v3->user_data_erase_counts[0]))json_object_object_add(root, "User Data Erase Counts - TLC Min" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->user_data_erase_counts [0])));
11328	json_object_add_value_uint64(root, "User Data Erase Counts - TLC Max",json_object_object_add(root, "User Data Erase Counts - TLC Max" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->user_data_erase_counts [1])))
11329	le64_to_cpu(nand_stats_v3->user_data_erase_counts[1]))json_object_object_add(root, "User Data Erase Counts - TLC Max" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->user_data_erase_counts [1])));
11330	json_object_add_value_uint64(root, "User Data Erase Counts - SLC Min",json_object_object_add(root, "User Data Erase Counts - SLC Min" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->user_data_erase_counts [2])))
11331	le64_to_cpu(nand_stats_v3->user_data_erase_counts[2]))json_object_object_add(root, "User Data Erase Counts - SLC Min" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->user_data_erase_counts [2])));
11332	json_object_add_value_uint64(root, "User Data Erase Counts - SLC Max",json_object_object_add(root, "User Data Erase Counts - SLC Max" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->user_data_erase_counts [3])))
11333	le64_to_cpu(nand_stats_v3->user_data_erase_counts[3]))json_object_object_add(root, "User Data Erase Counts - SLC Max" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->user_data_erase_counts [3])));
11334	temp_ptr = (__u64 *)nand_stats_v3->program_fail_count;
11335	temp_norm = (__u16)(*temp_ptr & 0x000000000000FFFF);
11336	temp_raw = ((*temp_ptr & 0xFFFFFFFFFFFF0000) >> 16);
11337	json_object_add_value_uint(root, "Program Fail Count - Normalized",json_object_object_add(root, "Program Fail Count - Normalized" , json_object_new_uint64(le16_to_cpu(temp_norm)))
11338	le16_to_cpu(temp_norm))json_object_object_add(root, "Program Fail Count - Normalized" , json_object_new_uint64(le16_to_cpu(temp_norm)));
11339	json_object_add_value_uint64(root, "Program Fail Count - Raw",json_object_object_add(root, "Program Fail Count - Raw", json_object_new_uint64 (le64_to_cpu(temp_raw)))
11340	le64_to_cpu(temp_raw))json_object_object_add(root, "Program Fail Count - Raw", json_object_new_uint64 (le64_to_cpu(temp_raw)));
11341	temp_ptr = (__u64 *)nand_stats_v3->erase_fail_count;
11342	temp_norm = (__u16)(*temp_ptr & 0x000000000000FFFF);
11343	temp_raw = ((*temp_ptr & 0xFFFFFFFFFFFF0000) >> 16);
11344	json_object_add_value_uint(root, "Erase Fail Count - Normalized",json_object_object_add(root, "Erase Fail Count - Normalized", json_object_new_uint64(le16_to_cpu(temp_norm)))
11345	le16_to_cpu(temp_norm))json_object_object_add(root, "Erase Fail Count - Normalized", json_object_new_uint64(le16_to_cpu(temp_norm)));
11346	json_object_add_value_uint64(root, "Erase Fail Count - Raw",json_object_object_add(root, "Erase Fail Count - Raw", json_object_new_uint64 (le64_to_cpu(temp_raw)))
11347	le64_to_cpu(temp_raw))json_object_object_add(root, "Erase Fail Count - Raw", json_object_new_uint64 (le64_to_cpu(temp_raw)));
11348	json_object_add_value_uint(root, "PCIe Correctable Error Count",json_object_object_add(root, "PCIe Correctable Error Count", json_object_new_uint64 (le16_to_cpu(nand_stats_v3->correctable_error_count)))
11349	le16_to_cpu(nand_stats_v3->correctable_error_count))json_object_object_add(root, "PCIe Correctable Error Count", json_object_new_uint64 (le16_to_cpu(nand_stats_v3->correctable_error_count)));
11350	json_object_add_value_uint(root, "% Free Blocks (User)",json_object_object_add(root, "% Free Blocks (User)", json_object_new_uint64 (nand_stats_v3->percent_free_blocks_user))
11351	nand_stats_v3->percent_free_blocks_user)json_object_object_add(root, "% Free Blocks (User)", json_object_new_uint64 (nand_stats_v3->percent_free_blocks_user));
11352	json_object_add_value_uint64(root, "Security Version Number",json_object_object_add(root, "Security Version Number", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->security_version_number)))
11353	le64_to_cpu(nand_stats_v3->security_version_number))json_object_object_add(root, "Security Version Number", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->security_version_number)));
11354	json_object_add_value_uint(root, "% Free Blocks (System)",json_object_object_add(root, "% Free Blocks (System)", json_object_new_uint64 (nand_stats_v3->percent_free_blocks_system))
11355	nand_stats_v3->percent_free_blocks_system)json_object_object_add(root, "% Free Blocks (System)", json_object_new_uint64 (nand_stats_v3->percent_free_blocks_system));
11356	json_object_add_value_uint128(root, "Data Set Management Commands",json_object_object_add(root, "Data Set Management Commands", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->trim_completions)))
11357	le128_to_cpu(nand_stats_v3->trim_completions))json_object_object_add(root, "Data Set Management Commands", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->trim_completions)));
11358	json_object_add_value_uint64(root, "Estimate of Incomplete Trim Data",json_object_object_add(root, "Estimate of Incomplete Trim Data" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->trim_completions [16])))
11359	le64_to_cpu(nand_stats_v3->trim_completions[16]))json_object_object_add(root, "Estimate of Incomplete Trim Data" , json_object_new_uint64(le64_to_cpu(nand_stats_v3->trim_completions [16])));
11360	json_object_add_value_uint(root, "%% of completed trim",json_object_object_add(root, "%% of completed trim", json_object_new_uint64 (nand_stats_v3->trim_completions[24]))
11361	nand_stats_v3->trim_completions[24])json_object_object_add(root, "%% of completed trim", json_object_new_uint64 (nand_stats_v3->trim_completions[24]));
11362	json_object_add_value_uint(root, "Background Back-Pressure-Guage",json_object_object_add(root, "Background Back-Pressure-Guage" , json_object_new_uint64(nand_stats_v3->back_pressure_guage ))
11363	nand_stats_v3->back_pressure_guage)json_object_object_add(root, "Background Back-Pressure-Guage" , json_object_new_uint64(nand_stats_v3->back_pressure_guage ));
11364	json_object_add_value_uint64(root, "Soft ECC Error Count",json_object_object_add(root, "Soft ECC Error Count", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->soft_ecc_error_count)))
11365	le64_to_cpu(nand_stats_v3->soft_ecc_error_count))json_object_object_add(root, "Soft ECC Error Count", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->soft_ecc_error_count)));
11366	json_object_add_value_uint64(root, "Refresh Count",json_object_object_add(root, "Refresh Count", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->refresh_count)))
11367	le64_to_cpu(nand_stats_v3->refresh_count))json_object_object_add(root, "Refresh Count", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->refresh_count)));
11368	temp_ptr = (__u64 *)nand_stats_v3->bad_sys_nand_block_count;
11369	temp_norm = (__u16)(*temp_ptr & 0x000000000000FFFF);
11370	temp_raw = ((*temp_ptr & 0xFFFFFFFFFFFF0000) >> 16);
11371	json_object_add_value_uint(root, "Bad System Nand Block Count - Normalized",json_object_object_add(root, "Bad System Nand Block Count - Normalized" , json_object_new_uint64(le16_to_cpu(temp_norm)))
11372	le16_to_cpu(temp_norm))json_object_object_add(root, "Bad System Nand Block Count - Normalized" , json_object_new_uint64(le16_to_cpu(temp_norm)));
11373	json_object_add_value_uint64(root, "Bad System Nand Block Count - Raw",json_object_object_add(root, "Bad System Nand Block Count - Raw" , json_object_new_uint64(le64_to_cpu(temp_raw)))
11374	le64_to_cpu(temp_raw))json_object_object_add(root, "Bad System Nand Block Count - Raw" , json_object_new_uint64(le64_to_cpu(temp_raw)));
11375	json_object_add_value_uint128(root, "Endurance Estimate",json_object_object_add(root, "Endurance Estimate", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->endurance_estimate)))
11376	le128_to_cpu(nand_stats_v3->endurance_estimate))json_object_object_add(root, "Endurance Estimate", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->endurance_estimate)));
11377	json_object_add_value_uint(root, "Thermal Throttling Status",json_object_object_add(root, "Thermal Throttling Status", json_object_new_uint64 (nand_stats_v3->thermal_throttling_st_ct[0]))
11378	nand_stats_v3->thermal_throttling_st_ct[0])json_object_object_add(root, "Thermal Throttling Status", json_object_new_uint64 (nand_stats_v3->thermal_throttling_st_ct[0]));
11379	json_object_add_value_uint(root, "Thermal Throttling Count",json_object_object_add(root, "Thermal Throttling Count", json_object_new_uint64 (nand_stats_v3->thermal_throttling_st_ct[1]))
11380	nand_stats_v3->thermal_throttling_st_ct[1])json_object_object_add(root, "Thermal Throttling Count", json_object_new_uint64 (nand_stats_v3->thermal_throttling_st_ct[1]));
11381	json_object_add_value_uint64(root, "Unaligned I/O",json_object_object_add(root, "Unaligned I/O", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->unaligned_IO)))
11382	le64_to_cpu(nand_stats_v3->unaligned_IO))json_object_object_add(root, "Unaligned I/O", json_object_new_uint64 (le64_to_cpu(nand_stats_v3->unaligned_IO)));
11383	json_object_add_value_uint128(root, "Physical Media Units Read",json_object_object_add(root, "Physical Media Units Read", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->physical_media_units)))
11384	le128_to_cpu(nand_stats_v3->physical_media_units))json_object_object_add(root, "Physical Media Units Read", util_json_object_new_uint128 (le128_to_cpu(nand_stats_v3->physical_media_units)));
11385	json_object_add_value_uint(root, "log page version",json_object_object_add(root, "log page version", json_object_new_uint64 (le16_to_cpu(nand_stats_v3->log_page_version)))
11386	le16_to_cpu(nand_stats_v3->log_page_version))json_object_object_add(root, "log page version", json_object_new_uint64 (le16_to_cpu(nand_stats_v3->log_page_version)));
11387
11388	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
11389	printf("\n");
11390	break;
11391	default:
11392	printf("%s: Invalid Stats Version = %d\n", __func__, version);
11393	break;
11394	}
11395
11396	json_free_object(root)json_object_put(root);
11397
11398	}
11399
11400	static void wdc_print_pcie_stats_normal(struct wdc_vs_pcie_stats *pcie_stats)
11401	{
11402	printf(" PCIE Statistics :-\n");
11403	printf(" Unsupported Request Error Counter %20"PRIu64"l" "u""\n",
11404	le64_to_cpu(pcie_stats->unsupportedRequestErrorCount));
11405	printf(" ECRC Error Status Counter %20"PRIu64"l" "u""\n",
11406	le64_to_cpu(pcie_stats->ecrcErrorStatusCount));
11407	printf(" Malformed TLP Status Counter %20"PRIu64"l" "u""\n",
11408	le64_to_cpu(pcie_stats->malformedTlpStatusCount));
11409	printf(" Receiver Overflow Status Counter %20"PRIu64"l" "u""\n",
11410	le64_to_cpu(pcie_stats->receiverOverflowStatusCount));
11411	printf(" Unexpected Completion Status Counter %20"PRIu64"l" "u""\n",
11412	le64_to_cpu(pcie_stats->unexpectedCmpltnStatusCount));
11413	printf(" Complete Abort Status Counter %20"PRIu64"l" "u""\n",
11414	le64_to_cpu(pcie_stats->completeAbortStatusCount));
11415	printf(" Completion Timeout Status Counter %20"PRIu64"l" "u""\n",
11416	le64_to_cpu(pcie_stats->cmpltnTimoutStatusCount));
11417	printf(" Flow Control Error Status Counter %20"PRIu64"l" "u""\n",
11418	le64_to_cpu(pcie_stats->flowControlErrorStatusCount));
11419	printf(" Poisoned TLP Status Counter %20"PRIu64"l" "u""\n",
11420	le64_to_cpu(pcie_stats->poisonedTlpStatusCount));
11421	printf(" Dlink Protocol Error Status Counter %20"PRIu64"l" "u""\n",
11422	le64_to_cpu(pcie_stats->dLinkPrtclErrorStatusCount));
11423	printf(" Advisory Non Fatal Error Status Counter %20"PRIu64"l" "u""\n",
11424	le64_to_cpu(pcie_stats->advsryNFatalErrStatusCount));
11425	printf(" Replay Timer TO Status Counter %20"PRIu64"l" "u""\n",
11426	le64_to_cpu(pcie_stats->replayTimerToStatusCount));
11427	printf(" Replay Number Rollover Status Counter %20"PRIu64"l" "u""\n",
11428	le64_to_cpu(pcie_stats->replayNumRolloverStCount));
11429	printf(" Bad DLLP Status Counter %20"PRIu64"l" "u""\n",
11430	le64_to_cpu(pcie_stats->badDllpStatusCount));
11431	printf(" Bad TLP Status Counter %20"PRIu64"l" "u""\n",
11432	le64_to_cpu(pcie_stats->badTlpStatusCount));
11433	printf(" Receiver Error Status Counter %20"PRIu64"l" "u""\n",
11434	le64_to_cpu(pcie_stats->receiverErrStatusCount));
11435
11436	}
11437
11438	static void wdc_print_pcie_stats_json(struct wdc_vs_pcie_stats *pcie_stats)
11439	{
11440	struct json_object *root = json_create_object()json_object_new_object();
11441
11442	json_object_add_value_uint64(root, "Unsupported Request Error Counter",json_object_object_add(root, "Unsupported Request Error Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->unsupportedRequestErrorCount )))
11443	le64_to_cpu(pcie_stats->unsupportedRequestErrorCount))json_object_object_add(root, "Unsupported Request Error Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->unsupportedRequestErrorCount )));
11444	json_object_add_value_uint64(root, "ECRC Error Status Counter",json_object_object_add(root, "ECRC Error Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->ecrcErrorStatusCount)))
11445	le64_to_cpu(pcie_stats->ecrcErrorStatusCount))json_object_object_add(root, "ECRC Error Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->ecrcErrorStatusCount)));
11446	json_object_add_value_uint64(root, "Malformed TLP Status Counter",json_object_object_add(root, "Malformed TLP Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->malformedTlpStatusCount)))
11447	le64_to_cpu(pcie_stats->malformedTlpStatusCount))json_object_object_add(root, "Malformed TLP Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->malformedTlpStatusCount)));
11448
11449	json_object_add_value_uint64(root, "Receiver Overflow Status Counter",json_object_object_add(root, "Receiver Overflow Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->receiverOverflowStatusCount )))
11450	le64_to_cpu(pcie_stats->receiverOverflowStatusCount))json_object_object_add(root, "Receiver Overflow Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->receiverOverflowStatusCount )));
11451	json_object_add_value_uint64(root, "Unexpected Completion Status Counter",json_object_object_add(root, "Unexpected Completion Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->unexpectedCmpltnStatusCount )))
11452	le64_to_cpu(pcie_stats->unexpectedCmpltnStatusCount))json_object_object_add(root, "Unexpected Completion Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->unexpectedCmpltnStatusCount )));
11453	json_object_add_value_uint64(root, "Complete Abort Status Counter",json_object_object_add(root, "Complete Abort Status Counter", json_object_new_uint64(le64_to_cpu(pcie_stats->completeAbortStatusCount )))
11454	le64_to_cpu(pcie_stats->completeAbortStatusCount))json_object_object_add(root, "Complete Abort Status Counter", json_object_new_uint64(le64_to_cpu(pcie_stats->completeAbortStatusCount )));
11455	json_object_add_value_uint64(root, "Completion Timeout Status Counter",json_object_object_add(root, "Completion Timeout Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->cmpltnTimoutStatusCount )))
11456	le64_to_cpu(pcie_stats->cmpltnTimoutStatusCount))json_object_object_add(root, "Completion Timeout Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->cmpltnTimoutStatusCount )));
11457	json_object_add_value_uint64(root, "Flow Control Error Status Counter",json_object_object_add(root, "Flow Control Error Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->flowControlErrorStatusCount )))
11458	le64_to_cpu(pcie_stats->flowControlErrorStatusCount))json_object_object_add(root, "Flow Control Error Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->flowControlErrorStatusCount )));
11459	json_object_add_value_uint64(root, "Poisoned TLP Status Counter",json_object_object_add(root, "Poisoned TLP Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->poisonedTlpStatusCount)))
11460	le64_to_cpu(pcie_stats->poisonedTlpStatusCount))json_object_object_add(root, "Poisoned TLP Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->poisonedTlpStatusCount)));
11461	json_object_add_value_uint64(root, "Dlink Protocol Error Status Counter",json_object_object_add(root, "Dlink Protocol Error Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->dLinkPrtclErrorStatusCount )))
11462	le64_to_cpu(pcie_stats->dLinkPrtclErrorStatusCount))json_object_object_add(root, "Dlink Protocol Error Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->dLinkPrtclErrorStatusCount )));
11463	json_object_add_value_uint64(root, "Advisory Non Fatal Error Status Counter",json_object_object_add(root, "Advisory Non Fatal Error Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->advsryNFatalErrStatusCount )))
11464	le64_to_cpu(pcie_stats->advsryNFatalErrStatusCount))json_object_object_add(root, "Advisory Non Fatal Error Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->advsryNFatalErrStatusCount )));
11465	json_object_add_value_uint64(root, "Replay Timer TO Status Counter",json_object_object_add(root, "Replay Timer TO Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->replayTimerToStatusCount )))
11466	le64_to_cpu(pcie_stats->replayTimerToStatusCount))json_object_object_add(root, "Replay Timer TO Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->replayTimerToStatusCount )));
11467	json_object_add_value_uint64(root, "Replay Number Rollover Status Counter",json_object_object_add(root, "Replay Number Rollover Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->replayNumRolloverStCount )))
11468	le64_to_cpu(pcie_stats->replayNumRolloverStCount))json_object_object_add(root, "Replay Number Rollover Status Counter" , json_object_new_uint64(le64_to_cpu(pcie_stats->replayNumRolloverStCount )));
11469	json_object_add_value_uint64(root, "Bad DLLP Status Counter",json_object_object_add(root, "Bad DLLP Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->badDllpStatusCount)))
11470	le64_to_cpu(pcie_stats->badDllpStatusCount))json_object_object_add(root, "Bad DLLP Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->badDllpStatusCount)));
11471	json_object_add_value_uint64(root, "Bad TLP Status Counter",json_object_object_add(root, "Bad TLP Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->badTlpStatusCount)))
11472	le64_to_cpu(pcie_stats->badTlpStatusCount))json_object_object_add(root, "Bad TLP Status Counter", json_object_new_uint64 (le64_to_cpu(pcie_stats->badTlpStatusCount)));
11473	json_object_add_value_uint64(root, "Receiver Error Status Counter",json_object_object_add(root, "Receiver Error Status Counter", json_object_new_uint64(le64_to_cpu(pcie_stats->receiverErrStatusCount )))
11474	le64_to_cpu(pcie_stats->receiverErrStatusCount))json_object_object_add(root, "Receiver Error Status Counter", json_object_new_uint64(le64_to_cpu(pcie_stats->receiverErrStatusCount )));
11475
11476	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
11477	printf("\n");
11478
11479	json_free_object(root)json_object_put(root);
11480	}
11481
11482	static int wdc_do_vs_nand_stats_sn810_2(struct libnvme_transport_handle hdl, char format)
11483	{
11484	nvme_print_flags_t fmt;
11485	uint8_t data = NULL((void)0);
11486	int ret;
11487
11488	data = NULL((void*)0);
11489	ret = nvme_get_ext_smart_cloud_log(hdl, &data, 0,
11490	NVME_NSID_ALL);
11491
11492	if (ret) {
11493	fprintf(stderrstderr, "ERROR: WDC: %s : Failed to retrieve NAND stats\n", __func__);
11494	goto out;
11495	} else {
11496	ret = validate_output_format(format, &fmt);
11497	if (ret < 0) {
11498	fprintf(stderrstderr, "ERROR: WDC: %s : invalid output format\n", __func__);
11499	goto out;
11500	}
11501
11502	/* parse the data */
11503	switch (fmt) {
11504	case NORMAL:
11505	wdc_print_ext_smart_cloud_log_normal(data, WDC_SCA_V1_NAND_STATS0x1);
11506	break;
11507	case JSON:
11508	wdc_print_ext_smart_cloud_log_json(data, WDC_SCA_V1_NAND_STATS0x1);
11509	break;
11510	default:
11511	break;
11512	}
11513	}
11514
11515	out:
11516	free(data);
11517	return ret;
11518	}
11519
11520	static int wdc_do_vs_nand_stats(struct libnvme_transport_handle hdl, char format)
11521	{
11522	nvme_print_flags_t fmt;
11523	uint8_t output = NULL((void)0);
11524	__u16 version = 0;
11525	int ret;
11526
11527	output = (uint8_t *)calloc(WDC_NVME_NAND_STATS_SIZE0x200, sizeof(uint8_t));
11528	if (!output) {
11529	fprintf(stderrstderr, "ERROR: WDC: calloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
11530	ret = -1;
11531	goto out;
11532	}
11533
11534	ret = nvme_get_log_simple(hdl, WDC_NVME_NAND_STATS_LOG_ID0xFB,
11535	(void *)output, WDC_NVME_NAND_STATS_SIZE0x200);
11536	if (ret) {
11537	fprintf(stderrstderr, "ERROR: WDC: %s : Failed to retrieve NAND stats\n", __func__);
11538	goto out;
11539	} else {
11540	ret = validate_output_format(format, &fmt);
11541	if (ret < 0) {
11542	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
11543	goto out;
11544	}
11545
11546	version = output[WDC_NVME_NAND_STATS_SIZE0x200 - 2];
11547
11548	/* parse the data */
11549	switch (fmt) {
11550	case NORMAL:
11551	wdc_print_nand_stats_normal(version, output);
11552	break;
11553	case JSON:
11554	wdc_print_nand_stats_json(version, output);
11555	break;
11556	default:
11557	break;
11558	}
11559	}
11560
11561	out:
11562	free(output);
11563	return ret;
11564	}
11565
11566	static int wdc_vs_nand_stats(int argc, char *argv, struct command acmd,
11567	struct plugin *plugin)
11568	{
11569	const char *desc = "Retrieve NAND statistics.";
11570	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
11571	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
11572	__u64 capabilities = 0;
11573	uint32_t read_device_id = 0, read_vendor_id = 0;
11574	int ret;
11575
11576	struct config {
11577	char *output_format;
11578	};
11579
11580	struct config cfg = {
11581	.output_format = "normal",
11582	};
11583
11584	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
11585
11586	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
11587	if (ret)
11588	return ret;
11589
11590	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
11591	if (ret)
11592	return ret;
11593
11594	capabilities = wdc_get_drive_capabilities(ctx, hdl);
11595
11596	if (!(capabilities & WDC_DRIVE_CAP_NAND_STATS0x0000000000000200)) {
11597	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
11598	ret = -1;
11599	} else {
11600	ret = wdc_get_pci_ids(ctx, hdl, &read_device_id, &read_vendor_id);
11601	if (ret < 0) {
11602	fprintf(stderrstderr, "ERROR: WDC: %s: failure to get pci ids, ret = %d\n", __func__, ret);
11603	return -1;
11604	}
11605
11606	switch (read_device_id) {
11607	case WDC_NVME_SN820CL_DEV_ID0x5037:
11608	ret = wdc_do_vs_nand_stats_sn810_2(hdl,
11609	cfg.output_format);
11610	break;
11611	default:
11612	ret = wdc_do_vs_nand_stats(hdl, cfg.output_format);
11613	break;
11614	}
11615	}
11616
11617	if (ret)
11618	fprintf(stderrstderr, "ERROR: WDC: Failure reading NAND statistics, ret = %d\n", ret);
11619
11620	return ret;
11621	}
11622
11623	static int wdc_do_vs_pcie_stats(struct libnvme_transport_handle *hdl,
11624	struct wdc_vs_pcie_stats *pcieStatsPtr)
11625	{
11626	int ret;
11627	struct libnvme_passthru_cmd admin_cmd;
11628	int pcie_stats_size = sizeof(struct wdc_vs_pcie_stats);
11629
11630	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
11631	admin_cmd.opcode = WDC_NVME_PCIE_STATS_OPCODE0xD1;
11632	admin_cmd.addr = (__u64)(uintptr_t)pcieStatsPtr;
11633	admin_cmd.data_len = pcie_stats_size;
11634
11635	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
11636
11637	return ret;
11638	}
11639
11640	static int wdc_vs_pcie_stats(int argc, char *argv, struct command acmd,
11641	struct plugin *plugin)
11642	{
11643	const char *desc = "Retrieve PCIE statistics.";
11644	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
11645	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
11646	nvme_print_flags_t fmt;
11647	int ret;
11648	__u64 capabilities = 0;
11649	__cleanup_huge__attribute__((cleanup(libnvme_free_huge))) struct libnvme_mem_huge mh = { 0, };
11650	struct wdc_vs_pcie_stats pcieStatsPtr = NULL((void)0);
11651	int pcie_stats_size = sizeof(struct wdc_vs_pcie_stats);
11652
11653	struct config {
11654	char *output_format;
11655	};
11656
11657	struct config cfg = {
11658	.output_format = "normal",
11659	};
11660
11661	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
11662
11663	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
11664	if (ret)
11665	return ret;
11666
11667	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
11668	if (ret)
11669	return ret;
11670
11671	ret = validate_output_format(cfg.output_format, &fmt);
11672	if (ret < 0) {
11673	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
11674	goto out;
11675	}
11676
11677	pcieStatsPtr = libnvme_alloc_huge(pcie_stats_size, &mh);
11678	if (!pcieStatsPtr) {
11679	fprintf(stderrstderr, "ERROR: WDC: PCIE Stats alloc: %s\n", libnvme_strerror(errno(*__errno_location ())));
11680	ret = -1;
11681	goto out;
11682	}
11683
11684	memset((void *)pcieStatsPtr, 0, pcie_stats_size);
11685
11686	capabilities = wdc_get_drive_capabilities(ctx, hdl);
11687
11688	if (!(capabilities & WDC_DRIVE_CAP_PCIE_STATS0x0000000008000000)) {
11689	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
11690	ret = -1;
11691	} else {
11692	ret = wdc_do_vs_pcie_stats(hdl, pcieStatsPtr);
11693	if (ret) {
11694	fprintf(stderrstderr, "ERROR: WDC: Failure reading PCIE statistics, ret = 0x%x\n", ret);
11695	} else {
11696	/* parse the data */
11697	switch (fmt) {
11698	case NORMAL:
11699	wdc_print_pcie_stats_normal(pcieStatsPtr);
11700	break;
11701	case JSON:
11702	wdc_print_pcie_stats_json(pcieStatsPtr);
11703	break;
11704	default:
11705	break;
11706	}
11707	}
11708	}
11709	out:
11710	return ret;
11711	}
11712
11713	static int wdc_vs_drive_info(int argc, char **argv,
11714	struct command command, struct plugin plugin)
11715	{
11716	const char *desc = "Send a vs-drive-info command.";
11717	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
11718	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
11719	nvme_print_flags_t fmt;
11720	uint64_t capabilities = 0;
11721	int ret;
11722	__le32 result;
11723	__u16 size;
11724	double rev;
11725	struct nvme_id_ctrl ctrl;
11726	char vsData[32] = {0};
11727	char major_rev = 0, minor_rev = 0;
11728	__u8 data = NULL((void)0);
11729	__u32 ftl_unit_size = 0, tcg_dev_ownership = 0;
11730	__u16 boot_spec_major = 0, boot_spec_minor = 0;
11731	struct json_object root = NULL((void)0);
11732	char formatter[41] = { 0 };
11733	char rev_str[16] = { 0 };
11734	uint32_t read_device_id = -1, read_vendor_id = -1;
11735	struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log * ext_smart_log_ptr = NULL((void*)0);
11736	struct ocp_drive_info info;
11737	__u32 data_len = 0;
11738	unsigned int num_dwords = 0;
11739
11740	struct config {
11741	char *output_format;
11742	};
11743
11744	struct config cfg = {
11745	.output_format = "normal",
11746	};
11747
11748	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
11749
11750	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
11751	if (ret)
11752	return ret;
11753
11754	ret = validate_output_format(cfg.output_format, &fmt);
11755	if (ret < 0) {
11756	fprintf(stderrstderr, "ERROR: WDC %s invalid output format\n", __func__);
11757	return ret;
11758	}
11759
11760	/* get the id ctrl data used to fill in drive info below */
11761	ret = nvme_identify_ctrl(hdl, &ctrl);
11762	if (ret) {
11763	fprintf(stderrstderr, "ERROR: WDC %s: Identify Controller failed\n", __func__);
11764	return ret;
11765	}
11766
11767	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
11768	if (ret \|\| !wdc_check_device(ctx, hdl))
11769	return -1;
11770
11771	capabilities = wdc_get_drive_capabilities(ctx, hdl);
11772
11773	if ((capabilities & WDC_DRIVE_CAP_INFO0x0000000000080000) == WDC_DRIVE_CAP_INFO0x0000000000080000) {
11774	ret = wdc_get_pci_ids(ctx, hdl, &read_device_id, &read_vendor_id);
11775	if (ret < 0) {
11776	fprintf(stderrstderr, "ERROR: WDC: %s: failure to get pci ids, ret = %d\n", __func__, ret);
11777	goto out;
11778	}
11779
11780	switch (read_device_id) {
11781	case WDC_NVME_SN640_DEV_ID0x2400:
11782	case WDC_NVME_SN640_DEV_ID_10x2401:
11783	case WDC_NVME_SN640_DEV_ID_20x2402:
11784	case WDC_NVME_SN640_DEV_ID_30x2404:
11785	case WDC_NVME_SN650_DEV_ID0x2700:
11786	case WDC_NVME_SN650_DEV_ID_10x2701:
11787	case WDC_NVME_SN650_DEV_ID_20x2702:
11788	case WDC_NVME_SN650_DEV_ID_30x2720:
11789	case WDC_NVME_SN650_DEV_ID_40x2721:
11790	case WDC_NVME_SN655_DEV_ID0x2722:
11791	case WDC_NVME_SN655_DEV_ID_10x2723:
11792	case WDC_NVME_SN560_DEV_ID_10x2712:
11793	case WDC_NVME_SN560_DEV_ID_20x2713:
11794	case WDC_NVME_SN560_DEV_ID_30x2714:
11795	case WDC_NVME_SN550_DEV_ID0x2708:
11796	case WDC_NVME_ZN350_DEV_ID0x5010:
11797	case WDC_NVME_ZN350_DEV_ID_10x5018:
11798	ret = wdc_do_drive_info(hdl, &result);
11799
11800	if (!ret) {
11801	size = (__u16)((cpu_to_le32(result) & 0xffff0000) >> 16);
11802	rev = (double)(cpu_to_le32(result) & 0x0000ffff);
11803
11804	if (fmt == NORMAL) {
11805	printf("Drive HW Revision: %4.1f\n", (.1 * rev));
11806	printf("FTL Unit Size: 0x%x KB\n", size);
11807	printf("Customer SN: %-.*s\n", (int)sizeof(ctrl.sn), &ctrl.sn[0]);
11808	} else if (fmt == JSON) {
11809	root = json_create_object()json_object_new_object();
11810	sprintf(rev_str, "%4.1f", (.1 * rev));
11811	json_object_add_value_string(root, "Drive HW Revision", rev_str);
11812
11813	json_object_add_value_int(root, "FTL Unit Size", le16_to_cpu(size))json_object_object_add(root, "FTL Unit Size", json_object_new_int (le16_to_cpu(size)));
11814	wdc_StrFormat(formatter, sizeof(formatter), &ctrl.sn[0], sizeof(ctrl.sn));
11815	json_object_add_value_string(root, "Customer SN", formatter);
11816
11817	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
11818	printf("\n");
11819
11820	json_free_object(root)json_object_put(root);
11821	}
11822	}
11823	break;
11824	case WDC_NVME_SN730_DEV_ID0x5006:
11825	memcpy(vsData, &ctrl.vs[0], 32);
11826
11827	major_rev = ctrl.sn[12];
11828	minor_rev = ctrl.sn[13];
11829
11830	if (fmt == NORMAL) {
11831	printf("Drive HW Revision: %c.%c\n", major_rev, minor_rev);
11832	printf("Customer SN: %-.*s\n", 14, &ctrl.sn[0]);
11833	} else if (fmt == JSON) {
11834	root = json_create_object()json_object_new_object();
11835	sprintf(rev_str, "%c.%c", major_rev, minor_rev);
11836	json_object_add_value_string(root, "Drive HW Revison", rev_str);
11837	wdc_StrFormat(formatter, sizeof(formatter), &ctrl.sn[0], 14);
11838	json_object_add_value_string(root, "Customer SN", formatter);
11839
11840	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
11841	printf("\n");
11842
11843	json_free_object(root)json_object_put(root);
11844	}
11845	break;
11846	case WDC_NVME_SN820CL_DEV_ID0x5037:
11847	/* Get the Drive HW Rev from the C6 Log page */
11848	ret = nvme_get_hw_rev_log(hdl, &data, 0,
11849	NVME_NSID_ALL);
11850	if (!ret) {
11851	struct wdc_nvme_hw_rev_log log_data = (struct wdc_nvme_hw_rev_log )data;
11852
11853	major_rev = log_data->hw_rev_gdr;
11854
11855	free(data);
11856	data = NULL((void*)0);
11857	} else {
11858	fprintf(stderrstderr, "ERROR: WDC: %s: failure to get hw revision log\n", __func__);
11859	ret = -1;
11860	goto out;
11861	}
11862
11863	/* Get the Smart C0 log page */
11864	if (!(capabilities & WDC_DRIVE_CAP_CLOUD_LOG_PAGE0x0000000080000000)) {
11865	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
11866	ret = -1;
11867	goto out;
11868	}
11869
11870	ret = nvme_get_ext_smart_cloud_log(hdl, &data,
11871	0, NVME_NSID_ALL);
11872
11873	if (!ret) {
11874	ext_smart_log_ptr = (struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log *)data;
11875
11876	/* Set the FTL Unit size */
11877	ftl_unit_size = le32_to_cpu(ext_smart_log_ptr->ext_smart_ftlus);
11878
11879	/* Set the Boot Spec Version */
11880	boot_spec_major = le16_to_cpu(ext_smart_log_ptr->ext_smart_maj);
11881	boot_spec_minor = le16_to_cpu(ext_smart_log_ptr->ext_smart_min);
11882
11883	/* Set the Drive Ownership Status */
11884	tcg_dev_ownership = le32_to_cpu(ext_smart_log_ptr->ext_smart_tcgos);
11885	free(data);
11886	} else {
11887	fprintf(stderrstderr, "ERROR: WDC: %s: failure to get extended smart cloud log\n", __func__);
11888	ret = -1;
11889	goto out;
11890	}
11891
11892	if (fmt == NORMAL) {
11893	printf("Drive HW Revision: %2d\n", major_rev);
11894	printf("FTL Unit Size: %d\n", ftl_unit_size);
11895	printf("HyperScale Boot Version Spec: %d.%d\n", boot_spec_major, boot_spec_minor);
11896	printf("TCG Device Ownership Status: %2d\n", tcg_dev_ownership);
11897
11898	} else if (fmt == JSON) {
11899	root = json_create_object()json_object_new_object();
11900
11901	json_object_add_value_int(root, "Drive HW Revison", major_rev)json_object_object_add(root, "Drive HW Revison", json_object_new_int (major_rev));
11902	json_object_add_value_int(root, "FTL Unit Size", ftl_unit_size)json_object_object_add(root, "FTL Unit Size", json_object_new_int (ftl_unit_size));
11903	sprintf(rev_str, "%d.%d", boot_spec_major, boot_spec_minor);
11904	json_object_add_value_string(root, "HyperScale Boot Version Spec", rev_str);
11905	json_object_add_value_int(root, "TCG Device Ownership Status", tcg_dev_ownership)json_object_object_add(root, "TCG Device Ownership Status", json_object_new_int (tcg_dev_ownership));
11906
11907	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
11908	printf("\n");
11909
11910	json_free_object(root)json_object_put(root);
11911	}
11912
11913	break;
11914	case WDC_NVME_SN861_DEV_ID0x2750:
11915	case WDC_NVME_SN861_DEV_ID_10x2751:
11916	case WDC_NVME_SN861_DEV_ID_20x2752:
11917	data_len = sizeof(info);
11918	num_dwords = data_len / 4;
11919	if (data_len % 4 != 0)
11920	num_dwords += 1;
11921
11922	struct libnvme_passthru_cmd cmd = {
11923	.opcode = WDC_NVME_ADMIN_VUC_OPCODE_D2,
11924	.cdw10 = num_dwords,
11925	.cdw12 = WDC_VUC_SUBOPCODE_VS_DRIVE_INFO_D2,
11926	.addr = (__u64)(uintptr_t)&info,
11927	.data_len = data_len,
11928	};
11929	ret = libnvme_exec_admin_passthru(hdl, &cmd);
11930	if (!ret) {
11931	__u16 hw_rev_major, hw_rev_minor;
11932
11933	hw_rev_major = le32_to_cpu(info.hw_revision) / 10;
11934	hw_rev_minor = le32_to_cpu(info.hw_revision) % 10;
11935	if (fmt == NORMAL) {
11936	printf("HW Revision : %" PRIu32"u" ".%" PRIu32"u" "\n",
11937	hw_rev_major, hw_rev_minor);
11938	printf("FTL Unit Size : %" PRIu32"u" "\n",
11939	le32_to_cpu(info.ftl_unit_size));
11940	} else if (fmt == JSON) {
11941	char buf[20];
11942
11943	root = json_create_object()json_object_new_object();
11944
11945	memset((void *)buf, 0, 20);
11946	sprintf(buf, "%" PRIu32"u" ".%" PRIu32"u",
11947	hw_rev_major, hw_rev_minor);
11948
11949	json_object_add_value_string(root,
11950	"hw_revision", buf);
11951	json_object_add_value_uint(root,json_object_object_add(root, "ftl_unit_size", json_object_new_uint64 (le32_to_cpu(info.ftl_unit_size)))
11952	"ftl_unit_size",json_object_object_add(root, "ftl_unit_size", json_object_new_uint64 (le32_to_cpu(info.ftl_unit_size)))
11953	le32_to_cpu(info.ftl_unit_size))json_object_object_add(root, "ftl_unit_size", json_object_new_uint64 (le32_to_cpu(info.ftl_unit_size)));
11954
11955	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
11956	printf("\n");
11957	json_free_object(root)json_object_put(root);
11958	}
11959	}
11960	break;
11961	default:
11962	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
11963	ret = -1;
11964	break;
11965	}
11966	} else {
11967	fprintf(stderrstderr, "ERROR: WDC: capability not supported by this device\n");
11968	ret = -1;
11969	}
11970
11971	out:
11972	nvme_show_status(ret);
11973	return ret;
11974	}
11975
11976	static int wdc_vs_temperature_stats(int argc, char **argv,
11977	struct command command, struct plugin plugin)
11978	{
11979	const char *desc = "Send a vs-temperature-stats command.";
11980	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
11981	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
11982	struct nvme_smart_log smart_log;
11983	struct nvme_id_ctrl id_ctrl;
11984	nvme_print_flags_t fmt;
11985	uint64_t capabilities = 0;
11986	__u64 hctm_tmt;
11987	int temperature, temp_tmt1, temp_tmt2;
11988	int ret;
11989
11990	struct config {
11991	char *output_format;
11992	};
11993
11994	struct config cfg = {
11995	.output_format = "normal",
11996	};
11997
11998	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
11999
12000	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
12001	if (ret)
12002	return ret;
12003
12004	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
12005	if (ret)
12006	return ret;
12007
12008	ret = validate_output_format(cfg.output_format, &fmt);
12009	if (ret < 0) {
12010	fprintf(stderrstderr, "ERROR: WDC: invalid output format\n");
12011	goto out;
12012	}
12013
12014	/* check if command is supported */
12015	wdc_check_device(ctx, hdl);
12016	capabilities = wdc_get_drive_capabilities(ctx, hdl);
12017	if ((capabilities & WDC_DRIVE_CAP_TEMP_STATS0x0000000000200000) != WDC_DRIVE_CAP_TEMP_STATS0x0000000000200000) {
12018	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
12019	ret = -1;
12020	goto out;
12021	}
12022
12023	/* get the temperature stats or report errors */
12024	ret = nvme_identify_ctrl(hdl, &id_ctrl);
12025	if (ret)
12026	goto out;
12027	ret = nvme_get_log_smart(hdl, NVME_NSID_ALL, &smart_log);
12028	if (ret)
12029	goto out;
12030
12031	/* convert from kelvins to degrees Celsius */
12032	temperature = ((smart_log.temperature[1] << 8) \| smart_log.temperature[0]) - 273;
12033
12034	/* retrieve HCTM Thermal Management Temperatures */
12035	nvme_get_features_simple(hdl, 0x10,
12036	NVME_GET_FEATURES_SEL_CURRENT, &hctm_tmt);
12037	temp_tmt1 = ((hctm_tmt >> 16) & 0xffff) ? ((hctm_tmt >> 16) & 0xffff) - 273 : 0;
12038	temp_tmt2 = (hctm_tmt & 0xffff) ? (hctm_tmt & 0xffff) - 273 : 0;
12039
12040	if (fmt == NORMAL) {
12041	/* print the temperature stats */
12042	printf("Temperature Stats for NVME device:%s namespace-id:%x\n",
12043	libnvme_transport_handle_get_name(hdl), WDC_DE_GLOBAL_NSID0xFFFFFFFF);
12044
12045	printf("Current Composite Temperature : %d °C\n", temperature);
12046	printf("WCTEMP : %"PRIu16"u"" °C\n", id_ctrl.wctemp - 273);
12047	printf("CCTEMP : %"PRIu16"u"" °C\n", id_ctrl.cctemp - 273);
12048	printf("DITT support : 0\n");
12049	printf("HCTM support : %"PRIu16"u""\n", id_ctrl.hctma);
12050
12051	printf("HCTM Light (TMT1) : %"PRIu16"u"" °C\n", temp_tmt1);
12052	printf("TMT1 Transition Counter : %"PRIu32"u""\n", smart_log.thm_temp1_trans_count);
12053	printf("TMT1 Total Time : %"PRIu32"u""\n", smart_log.thm_temp1_total_time);
12054
12055	printf("HCTM Heavy (TMT2) : %"PRIu16"u"" °C\n", temp_tmt2);
12056	printf("TMT2 Transition Counter : %"PRIu32"u""\n", smart_log.thm_temp2_trans_count);
12057	printf("TMT2 Total Time : %"PRIu32"u""\n", smart_log.thm_temp2_total_time);
12058	printf("Thermal Shutdown Threshold : 95 °C\n");
12059	} else if (fmt == JSON) {
12060	struct json_object *root;
12061
12062	root = json_create_object()json_object_new_object();
12063
12064	json_object_add_value_int(root, "Current Composite Temperature", le32_to_cpu(temperature))json_object_object_add(root, "Current Composite Temperature", json_object_new_int(le32_to_cpu(temperature)));
12065	json_object_add_value_int(root, "WCTEMP", le16_to_cpu(id_ctrl.wctemp - 273))json_object_object_add(root, "WCTEMP", json_object_new_int(le16_to_cpu (id_ctrl.wctemp - 273)));
12066	json_object_add_value_int(root, "CCTEMP", le16_to_cpu(id_ctrl.cctemp - 273))json_object_object_add(root, "CCTEMP", json_object_new_int(le16_to_cpu (id_ctrl.cctemp - 273)));
12067	json_object_add_value_int(root, "DITT support", 0)json_object_object_add(root, "DITT support", json_object_new_int (0));
12068	json_object_add_value_int(root, "HCTM support", le16_to_cpu(id_ctrl.hctma))json_object_object_add(root, "HCTM support", json_object_new_int (le16_to_cpu(id_ctrl.hctma)));
12069
12070	json_object_add_value_int(root, "HCTM Light (TMT1)", le16_to_cpu(temp_tmt1))json_object_object_add(root, "HCTM Light (TMT1)", json_object_new_int (le16_to_cpu(temp_tmt1)));
12071	json_object_add_value_int(root, "TMT1 Transition Counter", le32_to_cpu(smart_log.thm_temp1_trans_count))json_object_object_add(root, "TMT1 Transition Counter", json_object_new_int (le32_to_cpu(smart_log.thm_temp1_trans_count)));
12072	json_object_add_value_int(root, "TMT1 Total Time", le32_to_cpu(smart_log.thm_temp1_total_time))json_object_object_add(root, "TMT1 Total Time", json_object_new_int (le32_to_cpu(smart_log.thm_temp1_total_time)));
12073
12074	json_object_add_value_int(root, "HCTM Light (TMT2)", le16_to_cpu(temp_tmt2))json_object_object_add(root, "HCTM Light (TMT2)", json_object_new_int (le16_to_cpu(temp_tmt2)));
12075	json_object_add_value_int(root, "TMT2 Transition Counter", le32_to_cpu(smart_log.thm_temp2_trans_count))json_object_object_add(root, "TMT2 Transition Counter", json_object_new_int (le32_to_cpu(smart_log.thm_temp2_trans_count)));
12076	json_object_add_value_int(root, "TMT2 Total Time", le32_to_cpu(smart_log.thm_temp2_total_time))json_object_object_add(root, "TMT2 Total Time", json_object_new_int (le32_to_cpu(smart_log.thm_temp2_total_time)));
12077	json_object_add_value_int(root, "Thermal Shutdown Threshold", 95)json_object_object_add(root, "Thermal Shutdown Threshold", json_object_new_int (95));
12078
12079	json_print_object(root, NULL)printf("%s", json_object_to_json_string_ext(root, (1 << 1) \| (1 << 4)));
12080	printf("\n");
12081
12082	json_free_object(root)json_object_put(root);
12083	} else {
12084	printf("%s: Invalid format\n", __func__);
12085	}
12086
12087	out:
12088	nvme_show_status(ret);
12089	return ret;
12090	}
12091
12092	static int wdc_capabilities(int argc, char *argv, struct command acmd, struct plugin *plugin)
12093	{
12094	const char *desc = "Send a capabilities command.";
12095	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
12096	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
12097	uint64_t capabilities = 0;
12098	int ret;
12099
12100	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
12101
12102	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
12103	if (ret)
12104	return ret;
12105
12106	/* get capabilities */
12107	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
12108	if (ret \|\| !wdc_check_device(ctx, hdl))
12109	return -1;
12110
12111	capabilities = wdc_get_drive_capabilities(ctx, hdl);
12112
12113	/* print command and supported status */
12114	printf("WDC Plugin Capabilities for NVME device:%s\n", libnvme_transport_handle_get_name(hdl));
12115	printf("cap-diag : %s\n",
12116	capabilities & WDC_DRIVE_CAP_CAP_DIAG0x0000000000000001 ? "Supported" : "Not Supported");
12117	printf("drive-log : %s\n",
12118	capabilities & WDC_DRIVE_CAP_DRIVE_LOG0x0000000000000400 ? "Supported" : "Not Supported");
12119	printf("get-crash-dump : %s\n",
12120	capabilities & WDC_DRIVE_CAP_CRASH_DUMP0x0000000000000800 ? "Supported" : "Not Supported");
12121	printf("get-pfail-dump : %s\n",
12122	capabilities & WDC_DRIVE_CAP_PFAIL_DUMP0x0000000000001000 ? "Supported" : "Not Supported");
12123	printf("id-ctrl : Supported\n");
12124	printf("purge : %s\n",
12125	capabilities & WDC_DRIVE_CAP_PURGE0x0000001000000000 ? "Supported" : "Not Supported");
12126	printf("purge-monitor : %s\n",
12127	capabilities & WDC_DRIVE_CAP_PURGE0x0000001000000000 ? "Supported" : "Not Supported");
12128	printf("vs-internal-log : %s\n",
12129	capabilities & WDC_DRIVE_CAP_INTERNAL_LOG_MASK(0x0000000000000002 \| 0x0000000800000000 \| 0x0000000200000000 \| 0x0000000400000000) ? "Supported" : "Not Supported");
12130	printf("vs-nand-stats : %s\n",
12131	capabilities & WDC_DRIVE_CAP_NAND_STATS0x0000000000000200 ? "Supported" : "Not Supported");
12132	printf("vs-smart-add-log : %s\n",
12133	capabilities & WDC_DRIVE_CAP_SMART_LOG_MASK(0x0000000000100000 \| 0x0000000000000004 \| 0x0000000000000008 \| 0x0000000000000010) ? "Supported" : "Not Supported");
12134	printf("--C0 Log Page : %s\n",
12135	capabilities & WDC_DRIVE_CAP_C0_LOG_PAGE0x0000000000100000 ? "Supported" : "Not Supported");
12136	printf("--C1 Log Page : %s\n",
12137	capabilities & WDC_DRIVE_CAP_C1_LOG_PAGE0x0000000000000004 ? "Supported" : "Not Supported");
12138	printf("--C3 Log Page : %s\n",
12139	capabilities & WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000 ? "Supported" : "Not Supported");
12140	printf("--CA Log Page : %s\n",
12141	capabilities & WDC_DRIVE_CAP_CA_LOG_PAGE0x0000000000000008 ? "Supported" : "Not Supported");
12142	printf("--D0 Log Page : %s\n",
12143	capabilities & WDC_DRIVE_CAP_D0_LOG_PAGE0x0000000000000010 ? "Supported" : "Not Supported");
12144	printf("clear-pcie-correctable-errors : %s\n",
12145	capabilities & WDC_DRIVE_CAP_CLEAR_PCIE_MASK(0x0000000000000080 \| 0x0000000000400000 \| 0x0000000000800000 ) ? "Supported" : "Not Supported");
12146	printf("drive-essentials : %s\n",
12147	capabilities & WDC_DRIVE_CAP_DRIVE_ESSENTIALS0x0000000100000000 ? "Supported" : "Not Supported");
12148	printf("get-drive-status : %s\n",
12149	capabilities & WDC_DRIVE_CAP_DRIVE_STATUS0x0000000000000020 ? "Supported" : "Not Supported");
12150	printf("clear-assert-dump : %s\n",
12151	capabilities & WDC_DRIVE_CAP_CLEAR_ASSERT0x0000000000000040 ? "Supported" : "Not Supported");
12152	printf("drive-resize : %s\n",
12153	capabilities & WDC_DRIVE_CAP_RESIZE0x0000000000000100 ? "Supported" : "Not Supported");
12154	printf("vs-fw-activate-history : %s\n",
12155	capabilities & WDC_DRIVE_CAP_FW_ACTIVATE_HISTORY_MASK(0x0000000000002000 \| 0x0000000001000000) ? "Supported" : "Not Supported");
12156	printf("clear-fw-activate-history : %s\n",
12157	capabilities & WDC_DRIVE_CAP_CLEAR_FW_ACT_HISTORY_MASK(0x0000000000004000 \| 0x0000000002000000) ? "Supported" : "Not Supported");
12158	printf("vs-telemetry-controller-option: %s\n",
12159	capabilities & WDC_DRVIE_CAP_DISABLE_CTLR_TELE_LOG0x0000000000008000 ? "Supported" : "Not Supported");
12160	printf("vs-error-reason-identifier : %s\n",
12161	capabilities & WDC_DRIVE_CAP_REASON_ID0x0000000000010000 ? "Supported" : "Not Supported");
12162	printf("log-page-directory : %s\n",
12163	capabilities & WDC_DRIVE_CAP_LOG_PAGE_DIR0x0000000000020000 ? "Supported" : "Not Supported");
12164	printf("namespace-resize : %s\n",
12165	capabilities & WDC_DRIVE_CAP_NS_RESIZE0x0000000000040000 ? "Supported" : "Not Supported");
12166	printf("vs-drive-info : %s\n",
12167	capabilities & WDC_DRIVE_CAP_INFO0x0000000000080000 ? "Supported" : "Not Supported");
12168	printf("vs-temperature-stats : %s\n",
12169	capabilities & WDC_DRIVE_CAP_TEMP_STATS0x0000000000200000 ? "Supported" : "Not Supported");
12170	printf("cloud-SSD-plugin-version : %s\n",
12171	capabilities & WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000 ? "Supported" : "Not Supported");
12172	printf("vs-pcie-stats : %s\n",
12173	capabilities & WDC_DRIVE_CAP_PCIE_STATS0x0000000008000000 ? "Supported" : "Not Supported");
12174	printf("get-error-recovery-log : %s\n",
12175	capabilities & WDC_DRIVE_CAP_OCP_C1_LOG_PAGE0x0000002000000000 ? "Supported" : "Not Supported");
12176	printf("get-dev-capabilities-log : %s\n",
12177	capabilities & WDC_DRIVE_CAP_OCP_C4_LOG_PAGE0x0000004000000000 ? "Supported" : "Not Supported");
12178	printf("get-unsupported-reqs-log : %s\n",
12179	capabilities & WDC_DRIVE_CAP_OCP_C5_LOG_PAGE0x0000008000000000 ? "Supported" : "Not Supported");
12180	printf("get-latency-monitor-log : %s\n",
12181	capabilities & WDC_DRIVE_CAP_C3_LOG_PAGE0x0000000020000000 ? "Supported" : "Not Supported");
12182	printf("cloud-boot-SSD-version : %s\n",
12183	capabilities & WDC_DRIVE_CAP_CLOUD_BOOT_SSD_VERSION0x0000000040000000 ? "Supported" : "Not Supported");
12184	printf("vs-cloud-log : %s\n",
12185	capabilities & WDC_DRIVE_CAP_CLOUD_LOG_PAGE0x0000000080000000 ? "Supported" : "Not Supported");
12186	printf("vs-hw-rev-log : %s\n",
12187	capabilities & WDC_DRIVE_CAP_HW_REV_LOG_PAGE0x0000000010000000 ? "Supported" : "Not Supported");
12188	printf("vs-device_waf : %s\n",
12189	capabilities & WDC_DRIVE_CAP_DEVICE_WAF0x0000010000000000 ? "Supported" : "Not Supported");
12190	printf("set-latency-monitor-feature : %s\n",
12191	capabilities & WDC_DRIVE_CAP_SET_LATENCY_MONITOR0x0000020000000000 ? "Supported" : "Not Supported");
12192	printf("capabilities : Supported\n");
12193	return 0;
12194	}
12195
12196	static int wdc_cloud_ssd_plugin_version(int argc, char *argv, struct command acmd,
12197	struct plugin *plugin)
12198	{
12199	const char *desc = "Get Cloud SSD Plugin Version command.";
12200	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
12201	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
12202	uint64_t capabilities = 0;
12203	int ret;
12204
12205	NVME_ARGS(opts)struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
12206
12207	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
12208	if (ret)
12209	return ret;
12210
12211	/* get capabilities */
12212	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
12213	if (ret \|\| !wdc_check_device(ctx, hdl))
12214	return -1;
12215
12216	capabilities = wdc_get_drive_capabilities(ctx, hdl);
12217
12218	if ((capabilities & WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000) == WDC_DRIVE_CAP_CLOUD_SSD_VERSION0x0000000004000000) {
12219	/* print command and supported status */
12220	printf("WDC Cloud SSD Plugin Version: 1.0\n");
12221	} else {
12222	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
12223	}
12224
12225	return 0;
12226	}
12227
12228	static int wdc_cloud_boot_SSD_version(int argc, char *argv, struct command acmd,
12229	struct plugin *plugin)
12230	{
12231	const char *desc = "Get Cloud Boot SSD Version command.";
12232	const char *namespace_id = "desired namespace id";
12233	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
12234	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
12235	uint64_t capabilities = 0;
12236	int ret;
12237	int major = 0, minor = 0;
12238	__u8 data = NULL((void)0);
12239	struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log * ext_smart_log_ptr = NULL((void*)0);
12240
12241	struct config {
12242	__u32 namespace_id;
12243	};
12244
12245	struct config cfg = {
12246	.namespace_id = NVME_NSID_ALL,
12247	};
12248
12249	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12250	OPT_UINT("namespace-id", 'n', &cfg.namespace_id, namespace_id))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"namespace-id", 'n', "NUM", CFG_POSITIVE, &cfg.namespace_id , 1, namespace_id, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
12251
12252	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
12253	if (ret)
12254	return ret;
12255
12256	/* get capabilities */
12257	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
12258	if (ret \|\| !wdc_check_device(ctx, hdl))
12259	return -1;
12260
12261	capabilities = wdc_get_drive_capabilities(ctx, hdl);
12262
12263	if ((capabilities & WDC_DRIVE_CAP_CLOUD_BOOT_SSD_VERSION0x0000000040000000) == WDC_DRIVE_CAP_CLOUD_BOOT_SSD_VERSION0x0000000040000000) {
12264	/* Get the 0xC0 Smart Cloud Attribute V1 log data */
12265	ret = nvme_get_ext_smart_cloud_log(hdl, &data, 0,
12266	cfg.namespace_id);
12267
12268	ext_smart_log_ptr = (struct __packed__attribute__((__packed__)) wdc_nvme_ext_smart_log *)data;
12269	if (!ret) {
12270	major = le16_to_cpu(ext_smart_log_ptr->ext_smart_maj);
12271	minor = le16_to_cpu(ext_smart_log_ptr->ext_smart_min);
12272
12273	/* print the version returned from the log page */
12274	printf("HyperScale Boot Version: %d.%d\n", major, minor);
12275	} else {
12276	fprintf(stderrstderr, "ERROR: WDC: Unable to read Extended Smart/C0 Log Page data\n");
12277	ret = -1;
12278	}
12279
12280	free(data);
12281	} else {
12282	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
12283	}
12284
12285	return ret;
12286	}
12287
12288	static int wdc_enc_get_log(int argc, char *argv, struct command acmd, struct plugin *plugin)
12289	{
12290	const char *desc = "Get Enclosure Log.";
12291	const char *file = "Output file pathname.";
12292	const char *size = "Data retrieval transfer size.";
12293	const char *log = "Enclosure Log Page ID.";
12294	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
12295	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
12296	FILE *output_fd;
12297	int xfer_size = 0;
12298	int len;
12299	int err = 0;
12300
12301	struct config {
12302	char *file;
12303	__u32 xfer_size;
12304	__u32 log_id;
12305	};
12306
12307	struct config cfg = {
12308	.file = NULL((void*)0),
12309	.xfer_size = 0,
12310	.log_id = 0xffffffff,
12311	};
12312
12313	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"log-id", 'l', "NUM", CFG_POSITIVE , &cfg.log_id, 1, log, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12314	OPT_FILE("output-file", 'O', &cfg.file, file),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"log-id", 'l', "NUM", CFG_POSITIVE , &cfg.log_id, 1, log, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12315	OPT_UINT("transfer-size", 's', &cfg.xfer_size, size),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"log-id", 'l', "NUM", CFG_POSITIVE , &cfg.log_id, 1, log, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12316	OPT_UINT("log-id", 'l', &cfg.log_id, log))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"output-file", 'O', "FILE", CFG_STRING, &cfg.file , 1, file, 0, }, {"transfer-size", 's', "NUM", CFG_POSITIVE, & cfg.xfer_size, 1, size, 0, }, {"log-id", 'l', "NUM", CFG_POSITIVE , &cfg.log_id, 1, log, 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR , ((void)0), 0, "Global options", 0, ((void)0)}, {"verbose" , 'v', "NUM", CFG_INCREMENT, &nvme_args.verbose, 0, "Increase output verbosity" , 0, }, {"output-format", 'o', "FMT", CFG_STRING, &nvme_args .output_format, 1, "Output format: normal\|json\|binary\|tabular" , 0, }, {"timeout", 0, "NUM", CFG_POSITIVE, &nvme_args.timeout , 1, "timeout value, in milliseconds", 0, }, {"dry-run", 0, ( (void)0), CFG_FLAG, &nvme_args.dry_run, 0, "show command instead of executing" , 0, }, {"no-retries", 0, ((void)0), CFG_FLAG, &nvme_args .no_retries, 0, "disable retry logic on errors", 0, }, {"no-ioctl-probing" , 0, ((void)0), CFG_FLAG, &nvme_args.no_ioctl_probing, 0 , "disable 64-bit IOCTL support probing", 0, }, {"output-format-version" , 0, "NUM", CFG_POSITIVE, &nvme_args.output_format_ver, 1 , "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args.verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
12317
12318	err = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
12319	if (err)
12320	return err;
12321
12322	if (!wdc_enc_check_model(hdl))
12323	return -EINVAL22;
12324
12325	if (cfg.log_id > 0xff) {
12326	fprintf(stderrstderr,
12327	"Invalid log identifier: %d. Valid 0xd1, 0xd2, 0xd3, 0xd4, 0xe2, 0xe4\n",
12328	cfg.log_id);
12329	return -EINVAL22;
12330	}
12331
12332	if (cfg.xfer_size) {
12333	xfer_size = cfg.xfer_size;
12334	if (!wdc_check_power_of_2(cfg.xfer_size)) {
12335	fprintf(stderrstderr, "%s: ERROR: xfer-size (%d) must be a power of 2\n",
12336	__func__, cfg.xfer_size);
12337	return -EINVAL22;
12338	}
12339	}
12340
12341	/* Log IDs are only for specific enclosures */
12342	if (cfg.log_id) {
12343	xfer_size = (xfer_size) ? xfer_size : WDC_NVME_ENC_LOG_SIZE_CHUNK0x1000;
12344	len = !cfg.file ? 0 : strlen(cfg.file);
12345	if (len > 0) {
12346	output_fd = fopen(cfg.file, "wb");
12347	if (!output_fd) {
12348	fprintf(stderrstderr, "%s: ERROR: opening:%s: %s\n", __func__, cfg.file,
12349	libnvme_strerror(errno(*__errno_location ())));
12350	return -EINVAL22;
12351	}
12352	} else {
12353	output_fd = stdoutstdout;
12354	}
12355	if (cfg.log_id == WDC_ENC_NIC_CRASH_DUMP_ID_SLOT_10xD1 \|\|
12356	cfg.log_id == WDC_ENC_NIC_CRASH_DUMP_ID_SLOT_20xD2 \|\|
12357	cfg.log_id == WDC_ENC_NIC_CRASH_DUMP_ID_SLOT_30xD3 \|\|
12358	cfg.log_id == WDC_ENC_NIC_CRASH_DUMP_ID_SLOT_40xD4) {
12359	fprintf(stderrstderr, "args - sz:%x logid:%x of:%s\n", xfer_size, cfg.log_id,
12360	cfg.file);
12361	err = wdc_enc_get_nic_log(hdl, cfg.log_id, xfer_size,
12362	WDC_NVME_ENC_NIC_LOG_SIZE0x400000, output_fd);
12363	} else {
12364	fprintf(stderrstderr, "args - sz:%x logid:%x of:%s\n", xfer_size, cfg.log_id,
12365	cfg.file);
12366	err = wdc_enc_submit_move_data(hdl, NULL((void*)0), 0, xfer_size, output_fd,
12367	cfg.log_id, 0, 0);
12368	}
12369
12370	if (err == WDC_RESULT_NOT_AVAILABLE0x7FFFFFFF) {
12371	fprintf(stderrstderr, "No Log/Crashdump available\n");
12372	err = 0;
12373	} else if (err) {
12374	fprintf(stderrstderr, "ERROR: 0x%x Failed to collect log-id:%x\n", err,
12375	cfg.log_id);
12376	}
12377	}
12378	return err;
12379	}
12380
12381	static int wdc_enc_submit_move_data(struct libnvme_transport_handle hdl, char cmd, int len,
12382	int xfer_size, FILE *out, int log_id,
12383	int cdw14, int cdw15)
12384	{
12385	struct timespec time;
12386	uint32_t response_size, more;
12387	int err;
12388	int handle;
12389	uint32_t offset = 0;
12390	char *buf;
12391
12392	buf = (char )malloc(sizeof(__u8) xfer_size);
12393	if (!buf) {
12394	fprintf(stderrstderr, "%s: ERROR: malloc: %s\n", __func__, libnvme_strerror(errno(*__errno_location ())));
12395	return -1;
12396	}
12397	/* send something no matter what */
12398	cmd = (len) ? cmd : buf;
12399	len = (len) ? len : 0x20;
12400
12401	struct libnvme_passthru_cmd nvme_cmd = {
12402	.opcode = WDC_NVME_ADMIN_ENC_MGMT_SND0xC9,
12403	.nsid = 0,
12404	.addr = (__u64)(uintptr_t) cmd,
12405	.data_len = ((len + sizeof(uint32_t) - 1) / sizeof(uint32_t)) * sizeof(uint32_t),
12406	.cdw10 = len,
12407	.cdw12 = log_id,
12408	.cdw13 = 0,
12409	.cdw14 = cdw14,
12410	.cdw15 = cdw15,
12411	};
12412
12413	clock_gettime(CLOCK_REALTIME0, &time);
12414	srand(time.tv_nsec);
12415	handle = random(); /* Handle to associate send request with receive request */
12416	nvme_cmd.cdw11 = handle;
12417
12418	#ifdef WDC_NVME_CLI_DEBUG
12419	unsigned char d = (unsigned char )nvme_cmd.addr;
12420	unsigned char md = (unsigned char )nvme_cmd.metadata;
12421
12422	printf("NVME_ADMIN_COMMAND:\n");
12423	printf("opcode: 0x%02x, flags: 0x%02x, rsvd: 0x%04x, nsid: 0x%08x, cdw2: 0x%08x, ",
12424	nvme_cmd.opcode, nvme_cmd.flags, nvme_cmd.rsvd1, nvme_cmd.nsid, nvme_cmd.cdw2);
12425	printf("cdw3: 0x%08x, metadata_len: 0x%08x, data_len: 0x%08x, cdw10: 0x%08x, "
12426	nvme_cmd.cdw3, nvme_cmd.metadata_len, nvme_cmd.data_len, nvme_cmd.cdw10);
12427	printf("cdw11: 0x%08x, cdw12: 0x%08x, cdw13: 0x%08x, cdw14: 0x%08x, cdw15: 0x%08x, "
12428	nvme_cmd.cdw11, nvme_cmd.cdw12, nvme_cmd.cdw13, nvme_cmd.cdw14, nvme_cmd.cdw15);
12429	printf("timeout_ms: 0x%08x, result: 0x%08x, metadata: %s, data: %s\n",
12430	nvme_cmd.timeout_ms, nvme_cmd.result, md, d);
12431	#endif
12432	nvme_cmd.result = 0;
12433	err = libnvme_exec_admin_passthru(hdl, &nvme_cmd);
12434	if (nvme_status_equals(err, NVME_STATUS_TYPE_NVME, NVME_SC_INTERNAL)) {
12435	fprintf(stderrstderr, "%s: WARNING : WDC: No log ID:x%x available\n", __func__, log_id);
12436	} else if (err) {
12437	fprintf(stderrstderr, "%s: ERROR: WDC: NVMe Snd Mgmt\n", __func__);
12438	nvme_show_status(err);
12439	} else {
12440	if (nvme_cmd.result == WDC_RESULT_NOT_AVAILABLE0x7FFFFFFF) {
12441	free(buf);
12442	return WDC_RESULT_NOT_AVAILABLE0x7FFFFFFF;
12443	}
12444
12445	do {
12446	/* Sent request, now go retrieve response */
12447	nvme_cmd.flags = 0;
12448	nvme_cmd.opcode = WDC_NVME_ADMIN_ENC_MGMT_RCV0xCA;
12449	nvme_cmd.addr = (__u64)(uintptr_t) buf;
12450	nvme_cmd.data_len = xfer_size;
12451	nvme_cmd.cdw10 = xfer_size / sizeof(uint32_t);
12452	nvme_cmd.cdw11 = handle;
12453	nvme_cmd.cdw12 = log_id;
12454	nvme_cmd.cdw13 = offset / sizeof(uint32_t);
12455	nvme_cmd.cdw14 = cdw14;
12456	nvme_cmd.cdw15 = cdw15;
12457	nvme_cmd.result = 0; /* returned result !=0 indicates more data available */
12458	err = libnvme_exec_admin_passthru(hdl, &nvme_cmd);
12459	if (err) {
12460	more = 0;
12461	fprintf(stderrstderr, "%s: ERROR: WDC: NVMe Rcv Mgmt ", __func__);
12462	nvme_show_status(err);
12463	} else {
12464	more = nvme_cmd.result & WDC_RESULT_MORE_DATA0x80000000;
12465	response_size = nvme_cmd.result & ~WDC_RESULT_MORE_DATA0x80000000;
12466	fwrite(buf, response_size, 1, out);
12467	offset += response_size;
12468	if (more && (response_size & (sizeof(uint32_t)-1))) {
12469	fprintf(stderrstderr, "%s: ERROR: WDC: NVMe Rcv Mgmt response size:x%x not LW aligned\n",
12470	__func__, response_size);
12471	}
12472	}
12473	} while (more);
12474	}
12475
12476	free(buf);
12477	return err;
12478	}
12479
12480	static int wdc_enc_get_nic_log(struct libnvme_transport_handle hdl, __u8 log_id, __u32 xfer_size, __u32 data_len, FILE out)
12481	{
12482	__u8 *dump_data;
12483	__u32 curr_data_offset, curr_data_len;
12484	int i, ret = -1;
12485	struct libnvme_passthru_cmd admin_cmd;
12486	__u32 dump_length = data_len;
12487	__u32 numd;
12488	__u16 numdu, numdl;
12489
12490	dump_data = (__u8 )malloc(sizeof(__u8) dump_length);
12491	if (!dump_data) {
12492	fprintf(stderrstderr, "%s: ERROR: malloc: %s\n", __func__, libnvme_strerror(errno(*__errno_location ())));
12493	return -1;
12494	}
12495	memset(dump_data, 0, sizeof(__u8) * dump_length);
12496	memset(&admin_cmd, 0, sizeof(struct libnvme_passthru_cmd));
12497	curr_data_offset = 0;
12498	curr_data_len = xfer_size;
12499	i = 0;
12500
12501	numd = (curr_data_len >> 2) - 1;
12502	numdu = numd >> 16;
12503	numdl = numd & 0xffff;
12504	admin_cmd.opcode = nvme_admin_get_log_page;
12505	admin_cmd.nsid = curr_data_offset;
12506	admin_cmd.addr = (__u64)(uintptr_t) dump_data;
12507	admin_cmd.data_len = curr_data_len;
12508	admin_cmd.cdw10 = log_id \| (numdl << 16);
12509	admin_cmd.cdw11 = numdu;
12510
12511	while (curr_data_offset < data_len) {
12512	#ifdef WDC_NVME_CLI_DEBUG
12513	fprintf(stderrstderr,
12514	"nsid 0x%08x addr 0x%08llx, data_len 0x%08x, cdw10 0x%08x, cdw11 0x%08x, cdw12 0x%08x, cdw13 0x%08x, cdw14 0x%08x\n",
12515	admin_cmd.nsid, admin_cmd.addr, admin_cmd.data_len, admin_cmd.cdw10,
12516	admin_cmd.cdw11, admin_cmd.cdw12, admin_cmd.cdw13, admin_cmd.cdw14);
12517	#endif
12518	ret = libnvme_exec_admin_passthru(hdl, &admin_cmd);
12519	if (ret) {
12520	nvme_show_status(ret);
12521	fprintf(stderrstderr, "%s: ERROR: WDC: Get chunk %d, size = 0x%x, offset = 0x%x, addr = 0x%lx\n",
12522	__func__, i, admin_cmd.data_len, curr_data_offset, (unsigned long)admin_cmd.addr);
12523	break;
12524	}
12525
12526	if ((curr_data_offset + xfer_size) <= data_len)
12527	curr_data_len = xfer_size;
12528	else
12529	curr_data_len = data_len - curr_data_offset; /* last transfer */
12530
12531	curr_data_offset += curr_data_len;
12532	numd = (curr_data_len >> 2) - 1;
12533	numdu = numd >> 16;
12534	numdl = numd & 0xffff;
12535	admin_cmd.addr = (__u64)(uintptr_t)dump_data + (__u64)curr_data_offset;
12536	admin_cmd.nsid = curr_data_offset;
12537	admin_cmd.data_len = curr_data_len;
12538	admin_cmd.cdw10 = log_id \| (numdl << 16);
12539	admin_cmd.cdw11 = numdu;
12540	i++;
12541	}
12542	fwrite(dump_data, data_len, 1, out);
12543	free(dump_data);
12544	return ret;
12545	}
12546
12547	//------------------------------------------------------------------------------------
12548	// Description: set latency monitor feature
12549	//
12550	int wdc_set_latency_monitor_feature(int argc, char *argv, struct command acmd,
12551	struct plugin *plugin)
12552	{
12553	const char *desc = "Set Latency Monitor feature.";
12554
12555	struct feature_latency_monitor buf = {0,};
12556	__cleanup_nvme_transport_handle__attribute__((cleanup(cleanup_nvme_transport_handle))) struct libnvme_transport_handle hdl = NULL((void)0);
12557	__cleanup_nvme_global_ctx__attribute__((cleanup(cleanup_nvme_global_ctx))) struct libnvme_global_ctx ctx = NULL((void)0);
12558	uint64_t capabilities = 0;
12559	__u64 result;
12560	int ret;
12561
12562	const char *active_bucket_timer_threshold =
12563	"This is the value that loads the Active Bucket Timer Threshold.";
12564	const char *active_threshold_a =
12565	"This is the value that loads into the Active Threshold A.";
12566	const char *active_threshold_b =
12567	"This is the value that loads into the Active Threshold B.";
12568	const char *active_threshold_c =
12569	"This is the value that loads into the Active Threshold C.";
12570	const char *active_threshold_d =
12571	"This is the value that loads into the Active Threshold D.";
12572	const char *active_latency_config =
12573	"This is the value that loads into the Active Latency Configuration.";
12574	const char *active_latency_minimum_window =
12575	"This is the value that loads into the Active Latency Minimum Window.";
12576	const char *debug_log_trigger_enable =
12577	"This is the value that loads into the Debug Log Trigger Enable.";
12578	const char *discard_debug_log = "Discard Debug Log.";
12579	const char *latency_monitor_feature_enable = "Latency Monitor Feature Enable.";
12580
12581	struct config {
12582	__u16 active_bucket_timer_threshold;
12583	__u8 active_threshold_a;
12584	__u8 active_threshold_b;
12585	__u8 active_threshold_c;
12586	__u8 active_threshold_d;
12587	__u16 active_latency_config;
12588	__u8 active_latency_minimum_window;
12589	__u16 debug_log_trigger_enable;
12590	__u8 discard_debug_log;
12591	__u8 latency_monitor_feature_enable;
12592	};
12593
12594	struct config cfg = {
12595	.active_bucket_timer_threshold = 0x7E0,
12596	.active_threshold_a = 0x5,
12597	.active_threshold_b = 0x13,
12598	.active_threshold_c = 0x1E,
12599	.active_threshold_d = 0x2E,
12600	.active_latency_config = 0xFFF,
12601	.active_latency_minimum_window = 0xA,
12602	.debug_log_trigger_enable = 0,
12603	.discard_debug_log = 0,
12604	.latency_monitor_feature_enable = 0x7,
12605	};
12606
12607	NVME_ARGS(opts,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12608	OPT_UINT("active_bucket_timer_threshold", 't',struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12609	&cfg.active_bucket_timer_threshold,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12610	active_bucket_timer_threshold),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12611	OPT_UINT("active_threshold_a", 'a', &cfg.active_threshold_a,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12612	active_threshold_a),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12613	OPT_UINT("active_threshold_b", 'b', &cfg.active_threshold_b,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12614	active_threshold_b),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12615	OPT_UINT("active_threshold_c", 'c', &cfg.active_threshold_c,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12616	active_threshold_c),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12617	OPT_UINT("active_threshold_d", 'd', &cfg.active_threshold_d,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12618	active_threshold_d),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12619	OPT_UINT("active_latency_config", 'f',struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12620	&cfg.active_latency_config, active_latency_config),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12621	OPT_UINT("active_latency_minimum_window", 'w',struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12622	&cfg.active_latency_minimum_window,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12623	active_latency_minimum_window),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12624	OPT_UINT("debug_log_trigger_enable", 'r',struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12625	&cfg.debug_log_trigger_enable, debug_log_trigger_enable),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12626	OPT_UINT("discard_debug_log", 'l', &cfg.discard_debug_log,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12627	discard_debug_log),struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12628	OPT_UINT("latency_monitor_feature_enable", 'e',struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12629	&cfg.latency_monitor_feature_enable,struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } }
12630	latency_monitor_feature_enable))struct argconfig_commandline_options opts[] = { {"", 0, ((void )0), CFG_GROUP_SEPARATOR, ((void)0), 0, "Options", 0, ((void )0)}, {"active_bucket_timer_threshold", 't', "NUM", CFG_POSITIVE , &cfg.active_bucket_timer_threshold, 1, active_bucket_timer_threshold , 0, }, {"active_threshold_a", 'a', "NUM", CFG_POSITIVE, & cfg.active_threshold_a, 1, active_threshold_a, 0, }, {"active_threshold_b" , 'b', "NUM", CFG_POSITIVE, &cfg.active_threshold_b, 1, active_threshold_b , 0, }, {"active_threshold_c", 'c', "NUM", CFG_POSITIVE, & cfg.active_threshold_c, 1, active_threshold_c, 0, }, {"active_threshold_d" , 'd', "NUM", CFG_POSITIVE, &cfg.active_threshold_d, 1, active_threshold_d , 0, }, {"active_latency_config", 'f', "NUM", CFG_POSITIVE, & cfg.active_latency_config, 1, active_latency_config, 0, }, {"active_latency_minimum_window" , 'w', "NUM", CFG_POSITIVE, &cfg.active_latency_minimum_window , 1, active_latency_minimum_window, 0, }, {"debug_log_trigger_enable" , 'r', "NUM", CFG_POSITIVE, &cfg.debug_log_trigger_enable , 1, debug_log_trigger_enable, 0, }, {"discard_debug_log", 'l' , "NUM", CFG_POSITIVE, &cfg.discard_debug_log, 1, discard_debug_log , 0, }, {"latency_monitor_feature_enable", 'e', "NUM", CFG_POSITIVE , &cfg.latency_monitor_feature_enable, 1, latency_monitor_feature_enable , 0, }, {"", 0, ((void)0), CFG_GROUP_SEPARATOR, ((void)0), 0 , "Global options", 0, ((void)0)}, {"verbose", 'v', "NUM", CFG_INCREMENT , &nvme_args.verbose, 0, "Increase output verbosity", 0, } , {"output-format", 'o', "FMT", CFG_STRING, &nvme_args.output_format , 1, "Output format: normal\|json\|binary\|tabular", 0, }, {"timeout" , 0, "NUM", CFG_POSITIVE, &nvme_args.timeout, 1, "timeout value, in milliseconds" , 0, }, {"dry-run", 0, ((void)0), CFG_FLAG, &nvme_args.dry_run , 0, "show command instead of executing", 0, }, {"no-retries" , 0, ((void)0), CFG_FLAG, &nvme_args.no_retries, 0, "disable retry logic on errors" , 0, }, {"no-ioctl-probing", 0, ((void)0), CFG_FLAG, &nvme_args .no_ioctl_probing, 0, "disable 64-bit IOCTL support probing", 0, }, {"output-format-version", 0, "NUM", CFG_POSITIVE, & nvme_args.output_format_ver, 1, "output format version: 1\|2", 0, }, {"human-readable", 'H', ((void)0), CFG_FLAG, &nvme_args .verbose, 0, ((void)0), 0, ((void)0), 1}, { ((void*)0) } };
12631
12632	ret = parse_and_open(&ctx, &hdl, argc, argv, desc, opts);
12633
12634	if (ret < 0)
12635	return ret;
12636
12637	/* get capabilities */
12638	ret = libnvme_scan_topology(ctx, NULL((void)0), NULL((void)0));
12639	if (ret \|\| !wdc_check_device(ctx, hdl))
12640	return -1;
12641
12642	capabilities = wdc_get_drive_capabilities(ctx, hdl);
12643
12644	if (!(capabilities & WDC_DRIVE_CAP_SET_LATENCY_MONITOR0x0000020000000000)) {
12645	fprintf(stderrstderr, "ERROR: WDC: unsupported device for this command\n");
12646	return -1;
12647	}
12648
12649	memset(&buf, 0, sizeof(struct feature_latency_monitor));
12650
12651	buf.active_bucket_timer_threshold = cfg.active_bucket_timer_threshold;
12652	buf.active_threshold_a = cfg.active_threshold_a;
12653	buf.active_threshold_b = cfg.active_threshold_b;
12654	buf.active_threshold_c = cfg.active_threshold_c;
12655	buf.active_threshold_d = cfg.active_threshold_d;
12656	buf.active_latency_config = cfg.active_latency_config;
12657	buf.active_latency_minimum_window = cfg.active_latency_minimum_window;
12658	buf.debug_log_trigger_enable = cfg.debug_log_trigger_enable;
12659	buf.discard_debug_log = cfg.discard_debug_log;
12660	buf.latency_monitor_feature_enable = cfg.latency_monitor_feature_enable;
12661
12662	ret = nvme_set_features(hdl, 0, NVME_FEAT_OCP_LATENCY_MONITOR0xC5, 1, 0, 0, 0,
12663	0, 0, (void *)&buf, sizeof(struct feature_latency_monitor), &result);
12664
12665	if (ret < 0) {
12666	perror("set-feature");
12667	} else if (!ret) {
12668	printf("NVME_FEAT_OCP_LATENCY_MONITOR: 0x%02x\n",
12669	NVME_FEAT_OCP_LATENCY_MONITOR0xC5);
12670	printf("active bucket timer threshold: 0x%x\n",
12671	buf.active_bucket_timer_threshold);
12672	printf("active threshold a: 0x%x\n", buf.active_threshold_a);
12673	printf("active threshold b: 0x%x\n", buf.active_threshold_b);
12674	printf("active threshold c: 0x%x\n", buf.active_threshold_c);
12675	printf("active threshold d: 0x%x\n", buf.active_threshold_d);
12676	printf("active latency config: 0x%x\n", buf.active_latency_config);
12677	printf("active latency minimum window: 0x%x\n",
12678	buf.active_latency_minimum_window);
12679	printf("debug log trigger enable: 0x%x\n",
12680	buf.debug_log_trigger_enable);
12681	printf("discard debug log: 0x%x\n", buf.discard_debug_log);
12682	printf("latency monitor feature enable: 0x%x\n",
12683	buf.latency_monitor_feature_enable);
12684	} else if (ret > 0)
12685	fprintf(stderrstderr, "NVMe Status:%s(%x)\n",
12686	libnvme_status_to_string(ret, false0), ret);
12687
12688	return ret;
12689	}
12690
12691	/*
12692	* Externally available functions used to call the WDC Plugin commands
12693	*/
12694	int run_wdc_cloud_ssd_plugin_version(int argc, char **argv,
12695	struct command *command,
12696	struct plugin *plugin)
12697	{
12698	return wdc_cloud_ssd_plugin_version(argc, argv, command, plugin);
12699	}
12700
12701	int run_wdc_vs_internal_fw_log(int argc, char **argv,
12702	struct command *command,
12703	struct plugin *plugin)
12704	{
12705	return wdc_vs_internal_fw_log(argc, argv, command, plugin);
12706	}
12707
12708	int run_wdc_vs_nand_stats(int argc, char **argv,
12709	struct command *command,
12710	struct plugin *plugin)
12711	{
12712	return wdc_vs_nand_stats(argc, argv, command, plugin);
12713	}
12714
12715	int run_wdc_vs_smart_add_log(int argc, char **argv,
12716	struct command *command,
12717	struct plugin *plugin)
12718	{
12719	return wdc_vs_smart_add_log(argc, argv, command, plugin);
12720	}
12721
12722	int run_wdc_clear_pcie_correctable_errors(int argc, char **argv,
12723	struct command *command,
12724	struct plugin *plugin)
12725	{
12726	return wdc_clear_pcie_correctable_errors(argc, argv, command, plugin);
12727	}
12728
12729	int run_wdc_drive_status(int argc, char **argv,
12730	struct command *command,
12731	struct plugin *plugin)
12732	{
12733	return wdc_drive_status(argc, argv, command, plugin);
12734	}
12735
12736	int run_wdc_clear_assert_dump(int argc, char **argv,
12737	struct command *command,
12738	struct plugin *plugin)
12739	{
12740	return wdc_clear_assert_dump(argc, argv, command, plugin);
12741	}
12742
12743	int run_wdc_drive_resize(int argc, char **argv,
12744	struct command *command,
12745	struct plugin *plugin)
12746	{
12747	return wdc_drive_resize(argc, argv, command, plugin);
12748	}
12749
12750	int run_wdc_vs_fw_activate_history(int argc, char **argv,
12751	struct command *command,
12752	struct plugin *plugin)
12753	{
12754	return wdc_vs_fw_activate_history(argc, argv, command, plugin);
12755	}
12756
12757	int run_wdc_clear_fw_activate_history(int argc, char **argv,
12758	struct command *command,
12759	struct plugin *plugin)
12760	{
12761	return wdc_clear_fw_activate_history(argc, argv, command, plugin);
12762	}
12763
12764	int run_wdc_vs_telemetry_controller_option(int argc, char **argv,
12765	struct command *command,
12766	struct plugin *plugin)
12767	{
12768	return wdc_vs_telemetry_controller_option(argc, argv, command, plugin);
12769	}
12770
12771	int run_wdc_reason_identifier(int argc, char **argv,
12772	struct command *command,
12773	struct plugin *plugin)
12774	{
12775	return wdc_reason_identifier(argc, argv, command, plugin);
12776	}
12777
12778	int run_wdc_log_page_directory(int argc, char **argv,
12779	struct command *command,
12780	struct plugin *plugin)
12781	{
12782	return wdc_log_page_directory(argc, argv, command, plugin);
12783	}
12784
12785	int run_wdc_namespace_resize(int argc, char **argv,
12786	struct command *command,
12787	struct plugin *plugin)
12788	{
12789	return wdc_namespace_resize(argc, argv, command, plugin);
12790	}
12791
12792	int run_wdc_vs_drive_info(int argc, char **argv,
12793	struct command *command,
12794	struct plugin *plugin)
12795	{
12796	return wdc_vs_drive_info(argc, argv, command, plugin);
12797	}
12798
12799	int run_wdc_vs_pcie_stats(int argc, char **argv,
12800	struct command *command,
12801	struct plugin *plugin)
12802	{
12803	return wdc_vs_pcie_stats(argc, argv, command, plugin);
12804	}
12805
12806	int run_wdc_get_latency_monitor_log(int argc, char **argv,
12807	struct command *command,
12808	struct plugin *plugin)
12809	{
12810	return wdc_get_latency_monitor_log(argc, argv, command, plugin);
12811	}
12812
12813	int run_wdc_get_error_recovery_log(int argc, char **argv,
12814	struct command *command,
12815	struct plugin *plugin)
12816	{
12817	return wdc_get_error_recovery_log(argc, argv, command, plugin);
12818	}
12819
12820	int run_wdc_get_dev_capabilities_log(int argc, char **argv,
12821	struct command *command,
12822	struct plugin *plugin)
12823	{
12824	return wdc_get_dev_capabilities_log(argc, argv, command, plugin);
12825	}
12826
12827	int run_wdc_get_unsupported_reqs_log(int argc, char **argv,
12828	struct command *command,
12829	struct plugin *plugin)
12830	{
12831	return wdc_get_unsupported_reqs_log(argc, argv, command, plugin);
12832	}
12833
12834	int run_wdc_cloud_boot_SSD_version(int argc, char **argv,
12835	struct command *command,
12836	struct plugin *plugin)
12837	{
12838	return wdc_cloud_boot_SSD_version(argc, argv, command, plugin);
12839	}
12840
12841	int run_wdc_vs_cloud_log(int argc, char **argv,
12842	struct command *command,
12843	struct plugin *plugin)
12844	{
12845	return wdc_vs_cloud_log(argc, argv, command, plugin);
12846	}
12847
12848	int run_wdc_vs_hw_rev_log(int argc, char **argv,
12849	struct command *command,
12850	struct plugin *plugin)
12851	{
12852	return wdc_vs_hw_rev_log(argc, argv, command, plugin);
12853	}
12854
12855	int run_wdc_vs_device_waf(int argc, char **argv,
12856	struct command *command,
12857	struct plugin *plugin)
12858	{
12859	return wdc_vs_device_waf(argc, argv, command, plugin);
12860	}
12861
12862	int run_wdc_set_latency_monitor_feature(int argc, char **argv,
12863	struct command *command,
12864	struct plugin *plugin)
12865	{
12866	return wdc_set_latency_monitor_feature(argc, argv, command, plugin);
12867	}
12868
12869	int run_wdc_vs_temperature_stats(int argc, char **argv,
12870	struct command *command,
12871	struct plugin *plugin)
12872	{
12873	return wdc_vs_temperature_stats(argc, argv, command, plugin);
12874	}
12875
12876	int run_wdc_cu_smart_log(int argc, char **argv,
12877	struct command *command,
12878	struct plugin *plugin)
12879	{
12880	return wdc_cu_smart_log(argc, argv, command, plugin);
12881	}
12882
12883
12884	__u32 run_wdc_get_fw_cust_id(struct libnvme_global_ctx *ctx,
12885	struct libnvme_transport_handle *hdl)
12886	{
12887	return wdc_get_fw_cust_id(ctx, hdl);
12888	}
12889
12890	bool_Bool run_wdc_nvme_check_supported_log_page(struct libnvme_global_ctx *ctx,
12891	struct libnvme_transport_handle *hdl,
12892	__u8 log_id,
12893	__u8 uuid_index)
12894	{
12895	return wdc_nvme_check_supported_log_page(ctx,
12896	hdl,
12897	log_id,
12898	uuid_index);
12899	}
12900
12901	__u64 run_wdc_get_drive_capabilities(struct libnvme_global_ctx *ctx,
12902	struct libnvme_transport_handle *hdl)
12903	{
12904	return wdc_get_drive_capabilities(ctx, hdl);
12905	}