logpage.c revision 1.10
1 1.10 mlelstv /* $NetBSD: logpage.c,v 1.10 2022/07/31 13:49:23 mlelstv Exp $ */ 2 1.1 nonaka 3 1.1 nonaka /*- 4 1.6 nonaka * SPDX-License-Identifier: BSD-2-Clause-FreeBSD 5 1.6 nonaka * 6 1.1 nonaka * Copyright (c) 2013 EMC Corp. 7 1.1 nonaka * All rights reserved. 8 1.1 nonaka * 9 1.1 nonaka * Copyright (C) 2012-2013 Intel Corporation 10 1.1 nonaka * All rights reserved. 11 1.1 nonaka * 12 1.1 nonaka * Redistribution and use in source and binary forms, with or without 13 1.1 nonaka * modification, are permitted provided that the following conditions 14 1.1 nonaka * are met: 15 1.1 nonaka * 1. Redistributions of source code must retain the above copyright 16 1.1 nonaka * notice, this list of conditions and the following disclaimer. 17 1.1 nonaka * 2. Redistributions in binary form must reproduce the above copyright 18 1.1 nonaka * notice, this list of conditions and the following disclaimer in the 19 1.1 nonaka * documentation and/or other materials provided with the distribution. 20 1.1 nonaka * 21 1.1 nonaka * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND 22 1.1 nonaka * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 23 1.1 nonaka * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 24 1.1 nonaka * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE 25 1.1 nonaka * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 26 1.1 nonaka * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 27 1.1 nonaka * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 28 1.1 nonaka * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 29 1.1 nonaka * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 30 1.1 nonaka * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 31 1.1 nonaka * SUCH DAMAGE. 32 1.1 nonaka */ 33 1.1 nonaka 34 1.1 nonaka #include <sys/cdefs.h> 35 1.1 nonaka #ifndef lint 36 1.10 mlelstv __RCSID("$NetBSD: logpage.c,v 1.10 2022/07/31 13:49:23 mlelstv Exp $"); 37 1.1 nonaka #if 0 38 1.7 nonaka __FBSDID("$FreeBSD: head/sbin/nvmecontrol/logpage.c 329824 2018-02-22 13:32:31Z wma $"); 39 1.1 nonaka #endif 40 1.1 nonaka #endif 41 1.1 nonaka 42 1.1 nonaka #include <sys/param.h> 43 1.1 nonaka #include <sys/ioccom.h> 44 1.4 nonaka #include <sys/endian.h> 45 1.1 nonaka 46 1.1 nonaka #include <ctype.h> 47 1.1 nonaka #include <err.h> 48 1.1 nonaka #include <fcntl.h> 49 1.1 nonaka #include <stdbool.h> 50 1.1 nonaka #include <stddef.h> 51 1.1 nonaka #include <stdio.h> 52 1.1 nonaka #include <stdlib.h> 53 1.1 nonaka #include <string.h> 54 1.1 nonaka #include <unistd.h> 55 1.1 nonaka 56 1.1 nonaka #include "nvmectl.h" 57 1.1 nonaka 58 1.1 nonaka #define DEFAULT_SIZE (4096) 59 1.1 nonaka #define MAX_FW_SLOTS (7) 60 1.1 nonaka 61 1.6 nonaka typedef void (*print_fn_t)(const struct nvm_identify_controller *cdata, void *buf, 62 1.6 nonaka uint32_t size); 63 1.1 nonaka 64 1.4 nonaka struct kv_name { 65 1.4 nonaka uint32_t key; 66 1.4 nonaka const char *name; 67 1.4 nonaka }; 68 1.4 nonaka 69 1.4 nonaka static const char * 70 1.4 nonaka kv_lookup(const struct kv_name *kv, size_t kv_count, uint32_t key) 71 1.4 nonaka { 72 1.4 nonaka static char bad[32]; 73 1.4 nonaka size_t i; 74 1.4 nonaka 75 1.4 nonaka for (i = 0; i < kv_count; i++, kv++) 76 1.4 nonaka if (kv->key == key) 77 1.4 nonaka return kv->name; 78 1.4 nonaka snprintf(bad, sizeof(bad), "Attribute %#x", key); 79 1.4 nonaka return bad; 80 1.4 nonaka } 81 1.4 nonaka 82 1.4 nonaka static void 83 1.6 nonaka print_log_hex(const struct nvm_identify_controller *cdata __unused, void *data, 84 1.6 nonaka uint32_t length) 85 1.4 nonaka { 86 1.6 nonaka print_hex(data, length); 87 1.4 nonaka } 88 1.4 nonaka 89 1.6 nonaka static void 90 1.6 nonaka print_bin(const struct nvm_identify_controller *cdata __unused, void *data, 91 1.6 nonaka uint32_t length) 92 1.4 nonaka { 93 1.6 nonaka write(STDOUT_FILENO, data, length); 94 1.4 nonaka } 95 1.4 nonaka 96 1.1 nonaka static void * 97 1.1 nonaka get_log_buffer(uint32_t size) 98 1.1 nonaka { 99 1.1 nonaka void *buf; 100 1.1 nonaka 101 1.1 nonaka if ((buf = malloc(size)) == NULL) 102 1.1 nonaka errx(1, "unable to malloc %u bytes", size); 103 1.1 nonaka 104 1.1 nonaka memset(buf, 0, size); 105 1.1 nonaka return (buf); 106 1.1 nonaka } 107 1.1 nonaka 108 1.1 nonaka void 109 1.1 nonaka read_logpage(int fd, uint8_t log_page, int nsid, void *payload, 110 1.1 nonaka uint32_t payload_size) 111 1.1 nonaka { 112 1.1 nonaka struct nvme_pt_command pt; 113 1.1 nonaka 114 1.1 nonaka memset(&pt, 0, sizeof(pt)); 115 1.1 nonaka pt.cmd.opcode = NVM_ADMIN_GET_LOG_PG; 116 1.1 nonaka pt.cmd.nsid = nsid; 117 1.1 nonaka pt.cmd.cdw10 = ((payload_size/sizeof(uint32_t)) - 1) << 16; 118 1.1 nonaka pt.cmd.cdw10 |= log_page; 119 1.1 nonaka pt.buf = payload; 120 1.1 nonaka pt.len = payload_size; 121 1.1 nonaka pt.is_read = 1; 122 1.1 nonaka 123 1.1 nonaka if (ioctl(fd, NVME_PASSTHROUGH_CMD, &pt) < 0) 124 1.1 nonaka err(1, "get log page request failed"); 125 1.1 nonaka 126 1.1 nonaka if (nvme_completion_is_error(&pt.cpl)) 127 1.10 mlelstv errx(1, "get log page request returned error 0x%x/0x%02x", 128 1.10 mlelstv (uint8_t)__SHIFTOUT(pt.cpl.flags, NVME_CQE_SCT_MASK), 129 1.10 mlelstv (uint8_t)__SHIFTOUT(pt.cpl.flags, NVME_CQE_SC_MASK)); 130 1.1 nonaka } 131 1.1 nonaka 132 1.1 nonaka static void 133 1.7 nonaka nvme_error_information_entry_swapbytes(struct nvme_error_information_entry *e) 134 1.7 nonaka { 135 1.7 nonaka #if _BYTE_ORDER != _LITTLE_ENDIAN 136 1.7 nonaka e->error_count = le64toh(e->error_count); 137 1.7 nonaka e->sqid = le16toh(e->sqid); 138 1.7 nonaka e->cid = le16toh(e->cid); 139 1.7 nonaka e->status = le16toh(e->status); 140 1.7 nonaka e->error_location = le16toh(e->error_location); 141 1.7 nonaka e->lba = le64toh(e->lba); 142 1.7 nonaka e->nsid = le32toh(e->nsid); 143 1.7 nonaka e->command_specific = le64toh(e->command_specific); 144 1.7 nonaka #endif 145 1.7 nonaka } 146 1.7 nonaka 147 1.7 nonaka static void 148 1.6 nonaka print_log_error(const struct nvm_identify_controller *cdata __unused, void *buf, 149 1.6 nonaka uint32_t size) 150 1.1 nonaka { 151 1.1 nonaka int i, nentries; 152 1.1 nonaka struct nvme_error_information_entry *entry = buf; 153 1.1 nonaka 154 1.7 nonaka /* Convert data to host endian */ 155 1.7 nonaka nvme_error_information_entry_swapbytes(entry); 156 1.7 nonaka 157 1.1 nonaka printf("Error Information Log\n"); 158 1.1 nonaka printf("=====================\n"); 159 1.1 nonaka 160 1.1 nonaka if (entry->error_count == 0) { 161 1.1 nonaka printf("No error entries found\n"); 162 1.1 nonaka return; 163 1.1 nonaka } 164 1.1 nonaka 165 1.1 nonaka nentries = size/sizeof(struct nvme_error_information_entry); 166 1.1 nonaka for (i = 0; i < nentries; i++, entry++) { 167 1.1 nonaka if (entry->error_count == 0) 168 1.1 nonaka break; 169 1.1 nonaka 170 1.1 nonaka printf("Entry %02d\n", i + 1); 171 1.1 nonaka printf("=========\n"); 172 1.1 nonaka printf(" Error count: %ju\n", entry->error_count); 173 1.1 nonaka printf(" Submission queue ID: %u\n", entry->sqid); 174 1.1 nonaka printf(" Command ID: %u\n", entry->cid); 175 1.1 nonaka /* TODO: Export nvme_status_string structures from kernel? */ 176 1.1 nonaka printf(" Status:\n"); 177 1.1 nonaka printf(" Phase tag: %d\n", 178 1.1 nonaka (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_PHASE)); 179 1.1 nonaka printf(" Status code: %d\n", 180 1.1 nonaka (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_SC_MASK)); 181 1.1 nonaka printf(" Status code type: %d\n", 182 1.1 nonaka (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_SCT_MASK)); 183 1.1 nonaka printf(" More: %d\n", 184 1.1 nonaka (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_M)); 185 1.1 nonaka printf(" DNR: %d\n", 186 1.1 nonaka (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_DNR)); 187 1.1 nonaka printf(" Error location: %u\n", entry->error_location); 188 1.1 nonaka printf(" LBA: %ju\n", entry->lba); 189 1.1 nonaka printf(" Namespace ID: %u\n", entry->nsid); 190 1.1 nonaka printf(" Vendor specific info: %u\n", entry->vendor_specific); 191 1.1 nonaka printf(" Command specific info: %ju\n", 192 1.1 nonaka entry->command_specific); 193 1.1 nonaka } 194 1.1 nonaka } 195 1.1 nonaka 196 1.1 nonaka static void 197 1.4 nonaka print_temp(uint16_t t) 198 1.4 nonaka { 199 1.4 nonaka printf("%u K, %2.2f C, %3.2f F\n", t, (float)t - 273.15, 200 1.4 nonaka (float)t * 9 / 5 - 459.67); 201 1.4 nonaka } 202 1.4 nonaka 203 1.4 nonaka static void 204 1.7 nonaka nvme_health_information_page_swapbytes(struct nvme_health_information_page *e) 205 1.7 nonaka { 206 1.7 nonaka #if _BYTE_ORDER != _LITTLE_ENDIAN 207 1.7 nonaka u_int i; 208 1.7 nonaka 209 1.7 nonaka e->composite_temperature = le16toh(e->composite_temperature); 210 1.7 nonaka nvme_le128toh(e->data_units_read); 211 1.7 nonaka nvme_le128toh(e->data_units_written); 212 1.7 nonaka nvme_le128toh(e->host_read_commands); 213 1.7 nonaka nvme_le128toh(e->host_write_commands); 214 1.7 nonaka nvme_le128toh(e->controller_busy_time); 215 1.7 nonaka nvme_le128toh(e->power_cycles); 216 1.7 nonaka nvme_le128toh(e->power_on_hours); 217 1.7 nonaka nvme_le128toh(e->unsafe_shutdowns); 218 1.7 nonaka nvme_le128toh(e->media_errors); 219 1.7 nonaka nvme_le128toh(e->num_error_info_log_entries); 220 1.7 nonaka e->warning_temp_time = le32toh(e->warning_temp_time); 221 1.7 nonaka e->error_temp_time = le32toh(e->error_temp_time); 222 1.7 nonaka for (i = 0; i < __arraycount(e->temp_sensor); i++) 223 1.7 nonaka e->temp_sensor[i] = le16toh(e->temp_sensor[i]); 224 1.7 nonaka #endif 225 1.7 nonaka } 226 1.7 nonaka 227 1.7 nonaka static void 228 1.6 nonaka print_log_health(const struct nvm_identify_controller *cdata __unused, void *buf, 229 1.6 nonaka uint32_t size __unused) 230 1.1 nonaka { 231 1.1 nonaka struct nvme_health_information_page *health = buf; 232 1.7 nonaka u_int i; 233 1.7 nonaka 234 1.7 nonaka /* Convert data to host endian */ 235 1.7 nonaka nvme_health_information_page_swapbytes(health); 236 1.1 nonaka 237 1.1 nonaka printf("SMART/Health Information Log\n"); 238 1.1 nonaka printf("============================\n"); 239 1.1 nonaka 240 1.1 nonaka printf("Critical Warning State: 0x%02x\n", 241 1.1 nonaka health->critical_warning); 242 1.1 nonaka printf(" Available spare: %d\n", 243 1.1 nonaka (uint8_t)__SHIFTOUT(health->critical_warning, 244 1.1 nonaka NVME_HEALTH_PAGE_CW_AVAIL_SPARE)); 245 1.1 nonaka printf(" Temperature: %d\n", 246 1.1 nonaka (uint8_t)__SHIFTOUT(health->critical_warning, 247 1.1 nonaka NVME_HEALTH_PAGE_CW_TEMPERTURE)); 248 1.1 nonaka printf(" Device reliability: %d\n", 249 1.1 nonaka (uint8_t)__SHIFTOUT(health->critical_warning, 250 1.1 nonaka NVME_HEALTH_PAGE_CW_DEVICE_RELIABLITY)); 251 1.1 nonaka printf(" Read only: %d\n", 252 1.1 nonaka (uint8_t)__SHIFTOUT(health->critical_warning, 253 1.1 nonaka NVME_HEALTH_PAGE_CW_READ_ONLY)); 254 1.1 nonaka printf(" Volatile memory backup: %d\n", 255 1.1 nonaka (uint8_t)__SHIFTOUT(health->critical_warning, 256 1.1 nonaka NVME_HEALTH_PAGE_CW_VOLATILE_MEMORY_BACKUP)); 257 1.4 nonaka printf("Temperature: "); 258 1.4 nonaka print_temp(health->composite_temperature); 259 1.1 nonaka printf("Available spare: %u\n", 260 1.1 nonaka health->available_spare); 261 1.1 nonaka printf("Available spare threshold: %u\n", 262 1.1 nonaka health->available_spare_threshold); 263 1.1 nonaka printf("Percentage used: %u\n", 264 1.1 nonaka health->percentage_used); 265 1.1 nonaka 266 1.4 nonaka print_bignum("Data units (512 byte) read:", health->data_units_read, ""); 267 1.4 nonaka print_bignum("Data units (512 byte) written:", health->data_units_written, 268 1.4 nonaka ""); 269 1.4 nonaka print_bignum("Host read commands:", health->host_read_commands, ""); 270 1.4 nonaka print_bignum("Host write commands:", health->host_write_commands, ""); 271 1.4 nonaka print_bignum("Controller busy time (minutes):", health->controller_busy_time, 272 1.4 nonaka ""); 273 1.4 nonaka print_bignum("Power cycles:", health->power_cycles, ""); 274 1.4 nonaka print_bignum("Power on hours:", health->power_on_hours, ""); 275 1.4 nonaka print_bignum("Unsafe shutdowns:", health->unsafe_shutdowns, ""); 276 1.4 nonaka print_bignum("Media errors:", health->media_errors, ""); 277 1.3 nonaka print_bignum("No. error info log entries:", 278 1.3 nonaka health->num_error_info_log_entries, ""); 279 1.4 nonaka 280 1.4 nonaka printf("Warning Temp Composite Time: %d\n", health->warning_temp_time); 281 1.4 nonaka printf("Error Temp Composite Time: %d\n", health->error_temp_time); 282 1.7 nonaka for (i = 0; i < __arraycount(health->temp_sensor); i++) { 283 1.4 nonaka if (health->temp_sensor[i] == 0) 284 1.4 nonaka continue; 285 1.4 nonaka printf("Temperature Sensor %d: ", i + 1); 286 1.4 nonaka print_temp(health->temp_sensor[i]); 287 1.4 nonaka } 288 1.1 nonaka } 289 1.1 nonaka 290 1.1 nonaka static void 291 1.7 nonaka nvme_firmware_page_swapbytes(struct nvme_firmware_page *e) 292 1.7 nonaka { 293 1.7 nonaka #if _BYTE_ORDER != _LITTLE_ENDIAN 294 1.7 nonaka u_int i; 295 1.7 nonaka 296 1.7 nonaka for (i = 0; i < __arraycount(e->revision); i++) 297 1.7 nonaka e->revision[i] = le64toh(e->revision[i]); 298 1.7 nonaka #endif 299 1.7 nonaka } 300 1.7 nonaka 301 1.7 nonaka static void 302 1.6 nonaka print_log_firmware(const struct nvm_identify_controller *cdata, void *buf, 303 1.6 nonaka uint32_t size __unused) 304 1.1 nonaka { 305 1.6 nonaka u_int i, slots; 306 1.1 nonaka const char *status; 307 1.1 nonaka struct nvme_firmware_page *fw = buf; 308 1.1 nonaka 309 1.7 nonaka /* Convert data to host endian */ 310 1.7 nonaka nvme_firmware_page_swapbytes(fw); 311 1.7 nonaka 312 1.1 nonaka printf("Firmware Slot Log\n"); 313 1.1 nonaka printf("=================\n"); 314 1.1 nonaka 315 1.6 nonaka if (!(cdata->oacs & NVME_ID_CTRLR_OACS_FW)) 316 1.6 nonaka slots = 1; 317 1.6 nonaka else 318 1.6 nonaka slots = MIN(__SHIFTOUT(cdata->frmw, NVME_ID_CTRLR_FRMW_NSLOT), 319 1.6 nonaka MAX_FW_SLOTS); 320 1.6 nonaka 321 1.6 nonaka for (i = 0; i < slots; i++) { 322 1.1 nonaka printf("Slot %d: ", i + 1); 323 1.1 nonaka if (__SHIFTOUT(fw->afi, NVME_FW_PAGE_AFI_SLOT) == i + 1) 324 1.1 nonaka status = " Active"; 325 1.1 nonaka else 326 1.1 nonaka status = "Inactive"; 327 1.1 nonaka 328 1.1 nonaka if (fw->revision[i] == 0LLU) 329 1.1 nonaka printf("Empty\n"); 330 1.1 nonaka else 331 1.1 nonaka if (isprint(*(uint8_t *)&fw->revision[i])) 332 1.1 nonaka printf("[%s] %.8s\n", status, 333 1.1 nonaka (char *)&fw->revision[i]); 334 1.1 nonaka else 335 1.1 nonaka printf("[%s] %016jx\n", status, 336 1.1 nonaka fw->revision[i]); 337 1.1 nonaka } 338 1.1 nonaka } 339 1.1 nonaka 340 1.4 nonaka /* 341 1.4 nonaka * Intel specific log pages from 342 1.4 nonaka * http://www.intel.com/content/dam/www/public/us/en/documents/product-specifications/ssd-dc-p3700-spec.pdf 343 1.4 nonaka * 344 1.4 nonaka * Though the version as of this date has a typo for the size of log page 0xca, 345 1.4 nonaka * offset 147: it is only 1 byte, not 6. 346 1.4 nonaka */ 347 1.4 nonaka static void 348 1.7 nonaka intel_log_temp_stats_swapbytes(struct intel_log_temp_stats *e) 349 1.7 nonaka { 350 1.7 nonaka #if _BYTE_ORDER != _LITTLE_ENDIAN 351 1.7 nonaka e->current = le64toh(e->current); 352 1.7 nonaka e->overtemp_flag_last = le64toh(e->overtemp_flag_last); 353 1.7 nonaka e->overtemp_flag_life = le64toh(e->overtemp_flag_life); 354 1.7 nonaka e->max_temp = le64toh(e->max_temp); 355 1.7 nonaka e->min_temp = le64toh(e->min_temp); 356 1.7 nonaka e->max_oper_temp = le64toh(e->max_oper_temp); 357 1.7 nonaka e->min_oper_temp = le64toh(e->min_oper_temp); 358 1.7 nonaka e->est_offset = le64toh(e->est_offset); 359 1.7 nonaka #endif 360 1.7 nonaka } 361 1.7 nonaka 362 1.7 nonaka static void 363 1.6 nonaka print_intel_temp_stats(const struct nvm_identify_controller *cdata __unused, 364 1.6 nonaka void *buf, uint32_t size __unused) 365 1.4 nonaka { 366 1.4 nonaka struct intel_log_temp_stats *temp = buf; 367 1.4 nonaka 368 1.7 nonaka /* Convert data to host endian */ 369 1.7 nonaka intel_log_temp_stats_swapbytes(temp); 370 1.7 nonaka 371 1.4 nonaka printf("Intel Temperature Log\n"); 372 1.4 nonaka printf("=====================\n"); 373 1.4 nonaka 374 1.4 nonaka printf("Current: "); 375 1.4 nonaka print_temp(temp->current); 376 1.4 nonaka printf("Overtemp Last Flags %#jx\n", 377 1.4 nonaka (uintmax_t)temp->overtemp_flag_last); 378 1.4 nonaka printf("Overtemp Lifetime Flags %#jx\n", 379 1.4 nonaka (uintmax_t)temp->overtemp_flag_life); 380 1.4 nonaka printf("Max Temperature "); 381 1.4 nonaka print_temp(temp->max_temp); 382 1.4 nonaka printf("Min Temperature "); 383 1.4 nonaka print_temp(temp->min_temp); 384 1.4 nonaka printf("Max Operating Temperature "); 385 1.4 nonaka print_temp(temp->max_oper_temp); 386 1.4 nonaka printf("Min Operating Temperature "); 387 1.4 nonaka print_temp(temp->min_oper_temp); 388 1.4 nonaka printf("Estimated Temperature Offset: %ju C/K\n", 389 1.4 nonaka (uintmax_t)temp->est_offset); 390 1.4 nonaka } 391 1.4 nonaka 392 1.4 nonaka /* 393 1.4 nonaka * Format from Table 22, section 5.7 IO Command Latency Statistics. 394 1.4 nonaka * Read and write stats pages have identical encoding. 395 1.4 nonaka */ 396 1.4 nonaka static void 397 1.6 nonaka print_intel_read_write_lat_log(const struct nvm_identify_controller *cdata __unused, 398 1.6 nonaka void *buf, uint32_t size __unused) 399 1.4 nonaka { 400 1.4 nonaka const char *walker = buf; 401 1.4 nonaka int i; 402 1.4 nonaka 403 1.4 nonaka printf("Major: %d\n", le16dec(walker + 0)); 404 1.4 nonaka printf("Minor: %d\n", le16dec(walker + 2)); 405 1.4 nonaka for (i = 0; i < 32; i++) 406 1.4 nonaka printf("%4dus-%4dus: %ju\n", i * 32, (i + 1) * 32, 407 1.4 nonaka (uintmax_t)le32dec(walker + 4 + i * 4)); 408 1.4 nonaka for (i = 1; i < 32; i++) 409 1.4 nonaka printf("%4dms-%4dms: %ju\n", i, i + 1, 410 1.4 nonaka (uintmax_t)le32dec(walker + 132 + i * 4)); 411 1.4 nonaka for (i = 1; i < 32; i++) 412 1.4 nonaka printf("%4dms-%4dms: %ju\n", i * 32, (i + 1) * 32, 413 1.4 nonaka (uintmax_t)le32dec(walker + 256 + i * 4)); 414 1.4 nonaka } 415 1.4 nonaka 416 1.4 nonaka static void 417 1.6 nonaka print_intel_read_lat_log(const struct nvm_identify_controller *cdata, void *buf, 418 1.6 nonaka uint32_t size) 419 1.4 nonaka { 420 1.4 nonaka 421 1.4 nonaka printf("Intel Read Latency Log\n"); 422 1.4 nonaka printf("======================\n"); 423 1.6 nonaka print_intel_read_write_lat_log(cdata, buf, size); 424 1.4 nonaka } 425 1.4 nonaka 426 1.4 nonaka static void 427 1.6 nonaka print_intel_write_lat_log(const struct nvm_identify_controller *cdata, void *buf, 428 1.6 nonaka uint32_t size) 429 1.4 nonaka { 430 1.4 nonaka 431 1.4 nonaka printf("Intel Write Latency Log\n"); 432 1.4 nonaka printf("=======================\n"); 433 1.6 nonaka print_intel_read_write_lat_log(cdata, buf, size); 434 1.4 nonaka } 435 1.4 nonaka 436 1.4 nonaka /* 437 1.4 nonaka * Table 19. 5.4 SMART Attributes. 438 1.4 nonaka * Samsung also implements this and some extra data not documented. 439 1.4 nonaka */ 440 1.4 nonaka static void 441 1.6 nonaka print_intel_add_smart(const struct nvm_identify_controller *cdata __unused, 442 1.6 nonaka void *buf, uint32_t size __unused) 443 1.4 nonaka { 444 1.4 nonaka uint8_t *walker = buf; 445 1.4 nonaka uint8_t *end = walker + 150; 446 1.4 nonaka const char *name; 447 1.4 nonaka uint64_t raw; 448 1.4 nonaka uint8_t normalized; 449 1.4 nonaka 450 1.4 nonaka static struct kv_name kv[] = { 451 1.4 nonaka { 0xab, "Program Fail Count" }, 452 1.4 nonaka { 0xac, "Erase Fail Count" }, 453 1.4 nonaka { 0xad, "Wear Leveling Count" }, 454 1.4 nonaka { 0xb8, "End to End Error Count" }, 455 1.4 nonaka { 0xc7, "CRC Error Count" }, 456 1.4 nonaka { 0xe2, "Timed: Media Wear" }, 457 1.4 nonaka { 0xe3, "Timed: Host Read %" }, 458 1.4 nonaka { 0xe4, "Timed: Elapsed Time" }, 459 1.4 nonaka { 0xea, "Thermal Throttle Status" }, 460 1.4 nonaka { 0xf0, "Retry Buffer Overflows" }, 461 1.4 nonaka { 0xf3, "PLL Lock Loss Count" }, 462 1.4 nonaka { 0xf4, "NAND Bytes Written" }, 463 1.4 nonaka { 0xf5, "Host Bytes Written" }, 464 1.4 nonaka }; 465 1.4 nonaka 466 1.4 nonaka printf("Additional SMART Data Log\n"); 467 1.4 nonaka printf("=========================\n"); 468 1.4 nonaka /* 469 1.4 nonaka * walker[0] = Key 470 1.4 nonaka * walker[1,2] = reserved 471 1.4 nonaka * walker[3] = Normalized Value 472 1.4 nonaka * walker[4] = reserved 473 1.4 nonaka * walker[5..10] = Little Endian Raw value 474 1.4 nonaka * (or other represenations) 475 1.4 nonaka * walker[11] = reserved 476 1.4 nonaka */ 477 1.4 nonaka while (walker < end) { 478 1.4 nonaka name = kv_lookup(kv, __arraycount(kv), *walker); 479 1.4 nonaka normalized = walker[3]; 480 1.4 nonaka raw = le48dec(walker + 5); 481 1.4 nonaka switch (*walker){ 482 1.4 nonaka case 0: 483 1.4 nonaka break; 484 1.4 nonaka case 0xad: 485 1.4 nonaka printf("%-32s: %3d min: %u max: %u ave: %u\n", name, 486 1.4 nonaka normalized, le16dec(walker + 5), le16dec(walker + 7), 487 1.4 nonaka le16dec(walker + 9)); 488 1.4 nonaka break; 489 1.4 nonaka case 0xe2: 490 1.4 nonaka printf("%-32s: %3d %.3f%%\n", name, normalized, raw / 1024.0); 491 1.4 nonaka break; 492 1.4 nonaka case 0xea: 493 1.4 nonaka printf("%-32s: %3d %d%% %d times\n", name, normalized, 494 1.4 nonaka walker[5], le32dec(walker+6)); 495 1.4 nonaka break; 496 1.4 nonaka default: 497 1.4 nonaka printf("%-32s: %3d %ju\n", name, normalized, (uintmax_t)raw); 498 1.4 nonaka break; 499 1.4 nonaka } 500 1.4 nonaka walker += 12; 501 1.4 nonaka } 502 1.4 nonaka } 503 1.4 nonaka 504 1.4 nonaka /* 505 1.4 nonaka * HGST's 0xc1 page. This is a grab bag of additional data. Please see 506 1.4 nonaka * https://www.hgst.com/sites/default/files/resources/US_SN150_ProdManual.pdf 507 1.4 nonaka * https://www.hgst.com/sites/default/files/resources/US_SN100_ProdManual.pdf 508 1.4 nonaka * Appendix A for details 509 1.4 nonaka */ 510 1.4 nonaka 511 1.6 nonaka typedef void (*subprint_fn_t)(void *buf, uint16_t subtype, uint8_t res, 512 1.6 nonaka uint32_t size); 513 1.4 nonaka 514 1.4 nonaka struct subpage_print { 515 1.4 nonaka uint16_t key; 516 1.4 nonaka subprint_fn_t fn; 517 1.4 nonaka }; 518 1.4 nonaka 519 1.4 nonaka static void print_hgst_info_write_errors(void *, uint16_t, uint8_t, uint32_t); 520 1.4 nonaka static void print_hgst_info_read_errors(void *, uint16_t, uint8_t, uint32_t); 521 1.4 nonaka static void print_hgst_info_verify_errors(void *, uint16_t, uint8_t, uint32_t); 522 1.4 nonaka static void print_hgst_info_self_test(void *, uint16_t, uint8_t, uint32_t); 523 1.4 nonaka static void print_hgst_info_background_scan(void *, uint16_t, uint8_t, uint32_t); 524 1.4 nonaka static void print_hgst_info_erase_errors(void *, uint16_t, uint8_t, uint32_t); 525 1.4 nonaka static void print_hgst_info_erase_counts(void *, uint16_t, uint8_t, uint32_t); 526 1.4 nonaka static void print_hgst_info_temp_history(void *, uint16_t, uint8_t, uint32_t); 527 1.4 nonaka static void print_hgst_info_ssd_perf(void *, uint16_t, uint8_t, uint32_t); 528 1.4 nonaka static void print_hgst_info_firmware_load(void *, uint16_t, uint8_t, uint32_t); 529 1.4 nonaka 530 1.4 nonaka static struct subpage_print hgst_subpage[] = { 531 1.4 nonaka { 0x02, print_hgst_info_write_errors }, 532 1.4 nonaka { 0x03, print_hgst_info_read_errors }, 533 1.4 nonaka { 0x05, print_hgst_info_verify_errors }, 534 1.4 nonaka { 0x10, print_hgst_info_self_test }, 535 1.4 nonaka { 0x15, print_hgst_info_background_scan }, 536 1.4 nonaka { 0x30, print_hgst_info_erase_errors }, 537 1.4 nonaka { 0x31, print_hgst_info_erase_counts }, 538 1.4 nonaka { 0x32, print_hgst_info_temp_history }, 539 1.4 nonaka { 0x37, print_hgst_info_ssd_perf }, 540 1.4 nonaka { 0x38, print_hgst_info_firmware_load }, 541 1.4 nonaka }; 542 1.4 nonaka 543 1.4 nonaka /* Print a subpage that is basically just key value pairs */ 544 1.4 nonaka static void 545 1.4 nonaka print_hgst_info_subpage_gen(void *buf, uint16_t subtype __unused, uint32_t size, 546 1.4 nonaka const struct kv_name *kv, size_t kv_count) 547 1.4 nonaka { 548 1.4 nonaka uint8_t *wsp, *esp; 549 1.4 nonaka uint16_t ptype; 550 1.4 nonaka uint8_t plen; 551 1.4 nonaka uint64_t param; 552 1.4 nonaka int i; 553 1.4 nonaka 554 1.4 nonaka wsp = buf; 555 1.4 nonaka esp = wsp + size; 556 1.4 nonaka while (wsp < esp) { 557 1.4 nonaka ptype = le16dec(wsp); 558 1.4 nonaka wsp += 2; 559 1.4 nonaka wsp++; /* Flags, just ignore */ 560 1.4 nonaka plen = *wsp++; 561 1.4 nonaka param = 0; 562 1.4 nonaka for (i = 0; i < plen; i++) 563 1.4 nonaka param |= (uint64_t)*wsp++ << (i * 8); 564 1.4 nonaka printf(" %-30s: %jd\n", kv_lookup(kv, kv_count, ptype), 565 1.4 nonaka (uintmax_t)param); 566 1.4 nonaka } 567 1.4 nonaka } 568 1.4 nonaka 569 1.4 nonaka static void 570 1.4 nonaka print_hgst_info_write_errors(void *buf, uint16_t subtype, uint8_t res __unused, 571 1.4 nonaka uint32_t size) 572 1.4 nonaka { 573 1.4 nonaka static const struct kv_name kv[] = { 574 1.4 nonaka { 0x0000, "Corrected Without Delay" }, 575 1.4 nonaka { 0x0001, "Corrected Maybe Delayed" }, 576 1.4 nonaka { 0x0002, "Re-Writes" }, 577 1.4 nonaka { 0x0003, "Errors Corrected" }, 578 1.4 nonaka { 0x0004, "Correct Algorithm Used" }, 579 1.4 nonaka { 0x0005, "Bytes Processed" }, 580 1.4 nonaka { 0x0006, "Uncorrected Errors" }, 581 1.4 nonaka { 0x8000, "Flash Write Commands" }, 582 1.4 nonaka { 0x8001, "HGST Special" }, 583 1.4 nonaka }; 584 1.4 nonaka 585 1.4 nonaka printf("Write Errors Subpage:\n"); 586 1.4 nonaka print_hgst_info_subpage_gen(buf, subtype, size, kv, __arraycount(kv)); 587 1.4 nonaka } 588 1.4 nonaka 589 1.4 nonaka static void 590 1.4 nonaka print_hgst_info_read_errors(void *buf, uint16_t subtype, uint8_t res __unused, 591 1.4 nonaka uint32_t size) 592 1.4 nonaka { 593 1.4 nonaka static const struct kv_name kv[] = { 594 1.4 nonaka { 0x0000, "Corrected Without Delay" }, 595 1.4 nonaka { 0x0001, "Corrected Maybe Delayed" }, 596 1.4 nonaka { 0x0002, "Re-Reads" }, 597 1.4 nonaka { 0x0003, "Errors Corrected" }, 598 1.4 nonaka { 0x0004, "Correct Algorithm Used" }, 599 1.4 nonaka { 0x0005, "Bytes Processed" }, 600 1.4 nonaka { 0x0006, "Uncorrected Errors" }, 601 1.4 nonaka { 0x8000, "Flash Read Commands" }, 602 1.4 nonaka { 0x8001, "XOR Recovered" }, 603 1.4 nonaka { 0x8002, "Total Corrected Bits" }, 604 1.4 nonaka }; 605 1.4 nonaka 606 1.4 nonaka printf("Read Errors Subpage:\n"); 607 1.4 nonaka print_hgst_info_subpage_gen(buf, subtype, size, kv, __arraycount(kv)); 608 1.4 nonaka } 609 1.4 nonaka 610 1.4 nonaka static void 611 1.4 nonaka print_hgst_info_verify_errors(void *buf, uint16_t subtype, uint8_t res __unused, 612 1.4 nonaka uint32_t size) 613 1.4 nonaka { 614 1.4 nonaka static const struct kv_name kv[] = { 615 1.4 nonaka { 0x0000, "Corrected Without Delay" }, 616 1.4 nonaka { 0x0001, "Corrected Maybe Delayed" }, 617 1.4 nonaka { 0x0002, "Re-Reads" }, 618 1.4 nonaka { 0x0003, "Errors Corrected" }, 619 1.4 nonaka { 0x0004, "Correct Algorithm Used" }, 620 1.4 nonaka { 0x0005, "Bytes Processed" }, 621 1.4 nonaka { 0x0006, "Uncorrected Errors" }, 622 1.4 nonaka { 0x8000, "Commands Processed" }, 623 1.4 nonaka }; 624 1.4 nonaka 625 1.4 nonaka printf("Verify Errors Subpage:\n"); 626 1.4 nonaka print_hgst_info_subpage_gen(buf, subtype, size, kv, __arraycount(kv)); 627 1.4 nonaka } 628 1.4 nonaka 629 1.4 nonaka static void 630 1.4 nonaka print_hgst_info_self_test(void *buf, uint16_t subtype __unused, uint8_t res __unused, 631 1.4 nonaka uint32_t size) 632 1.4 nonaka { 633 1.4 nonaka size_t i; 634 1.4 nonaka uint8_t *walker = buf; 635 1.4 nonaka uint16_t code, hrs; 636 1.4 nonaka uint32_t lba; 637 1.4 nonaka 638 1.4 nonaka printf("Self Test Subpage:\n"); 639 1.4 nonaka for (i = 0; i < size / 20; i++) { /* Each entry is 20 bytes */ 640 1.4 nonaka code = le16dec(walker); 641 1.4 nonaka walker += 2; 642 1.4 nonaka walker++; /* Ignore fixed flags */ 643 1.4 nonaka if (*walker == 0) /* Last entry is zero length */ 644 1.4 nonaka break; 645 1.4 nonaka if (*walker++ != 0x10) { 646 1.4 nonaka printf("Bad length for self test report\n"); 647 1.4 nonaka return; 648 1.4 nonaka } 649 1.4 nonaka printf(" %-30s: %d\n", "Recent Test", code); 650 1.4 nonaka printf(" %-28s: %#x\n", "Self-Test Results", *walker & 0xf); 651 1.4 nonaka printf(" %-28s: %#x\n", "Self-Test Code", (*walker >> 5) & 0x7); 652 1.4 nonaka walker++; 653 1.4 nonaka printf(" %-28s: %#x\n", "Self-Test Number", *walker++); 654 1.4 nonaka hrs = le16dec(walker); 655 1.4 nonaka walker += 2; 656 1.4 nonaka lba = le32dec(walker); 657 1.4 nonaka walker += 4; 658 1.4 nonaka printf(" %-28s: %u\n", "Total Power On Hrs", hrs); 659 1.4 nonaka printf(" %-28s: %#jx (%jd)\n", "LBA", (uintmax_t)lba, 660 1.4 nonaka (uintmax_t)lba); 661 1.4 nonaka printf(" %-28s: %#x\n", "Sense Key", *walker++ & 0xf); 662 1.4 nonaka printf(" %-28s: %#x\n", "Additional Sense Code", *walker++); 663 1.4 nonaka printf(" %-28s: %#x\n", "Additional Sense Qualifier", *walker++); 664 1.4 nonaka printf(" %-28s: %#x\n", "Vendor Specific Detail", *walker++); 665 1.4 nonaka } 666 1.4 nonaka } 667 1.4 nonaka 668 1.4 nonaka static void 669 1.4 nonaka print_hgst_info_background_scan(void *buf, uint16_t subtype __unused, 670 1.4 nonaka uint8_t res __unused, uint32_t size) 671 1.4 nonaka { 672 1.4 nonaka uint8_t *walker = buf; 673 1.4 nonaka uint8_t status; 674 1.4 nonaka uint16_t code, nscan, progress; 675 1.4 nonaka uint32_t pom, nand; 676 1.4 nonaka 677 1.4 nonaka printf("Background Media Scan Subpage:\n"); 678 1.4 nonaka /* Decode the header */ 679 1.4 nonaka code = le16dec(walker); 680 1.4 nonaka walker += 2; 681 1.4 nonaka walker++; /* Ignore fixed flags */ 682 1.4 nonaka if (*walker++ != 0x10) { 683 1.4 nonaka printf("Bad length for background scan header\n"); 684 1.4 nonaka return; 685 1.4 nonaka } 686 1.4 nonaka if (code != 0) { 687 1.8 andvar printf("Expected code 0, found code %#x\n", code); 688 1.4 nonaka return; 689 1.4 nonaka } 690 1.4 nonaka pom = le32dec(walker); 691 1.4 nonaka walker += 4; 692 1.4 nonaka walker++; /* Reserved */ 693 1.4 nonaka status = *walker++; 694 1.4 nonaka nscan = le16dec(walker); 695 1.4 nonaka walker += 2; 696 1.4 nonaka progress = le16dec(walker); 697 1.4 nonaka walker += 2; 698 1.4 nonaka walker += 6; /* Reserved */ 699 1.4 nonaka printf(" %-30s: %d\n", "Power On Minutes", pom); 700 1.4 nonaka printf(" %-30s: %x (%s)\n", "BMS Status", status, 701 1.4 nonaka status == 0 ? "idle" : (status == 1 ? "active" : 702 1.4 nonaka (status == 8 ? "suspended" : "unknown"))); 703 1.4 nonaka printf(" %-30s: %d\n", "Number of BMS", nscan); 704 1.4 nonaka printf(" %-30s: %d\n", "Progress Current BMS", progress); 705 1.4 nonaka /* Report retirements */ 706 1.4 nonaka if (walker - (uint8_t *)buf != 20) { 707 1.4 nonaka printf("Coding error, offset not 20\n"); 708 1.4 nonaka return; 709 1.4 nonaka } 710 1.4 nonaka size -= 20; 711 1.4 nonaka printf(" %-30s: %d\n", "BMS retirements", size / 0x18); 712 1.4 nonaka while (size > 0) { 713 1.4 nonaka code = le16dec(walker); 714 1.4 nonaka walker += 2; 715 1.4 nonaka walker++; 716 1.4 nonaka if (*walker++ != 0x14) { 717 1.4 nonaka printf("Bad length parameter\n"); 718 1.4 nonaka return; 719 1.4 nonaka } 720 1.4 nonaka pom = le32dec(walker); 721 1.4 nonaka walker += 4; 722 1.4 nonaka /* 723 1.4 nonaka * Spec sheet says the following are hard coded, if true, just 724 1.4 nonaka * print the NAND retirement. 725 1.4 nonaka */ 726 1.4 nonaka if (walker[0] == 0x41 && 727 1.4 nonaka walker[1] == 0x0b && 728 1.4 nonaka walker[2] == 0x01 && 729 1.4 nonaka walker[3] == 0x00 && 730 1.4 nonaka walker[4] == 0x00 && 731 1.4 nonaka walker[5] == 0x00 && 732 1.4 nonaka walker[6] == 0x00 && 733 1.4 nonaka walker[7] == 0x00) { 734 1.4 nonaka walker += 8; 735 1.4 nonaka walker += 4; /* Skip reserved */ 736 1.4 nonaka nand = le32dec(walker); 737 1.4 nonaka walker += 4; 738 1.4 nonaka printf(" %-30s: %d\n", "Retirement number", code); 739 1.4 nonaka printf(" %-28s: %#x\n", "NAND (C/T)BBBPPP", nand); 740 1.4 nonaka } else { 741 1.4 nonaka printf("Parameter %#x entry corrupt\n", code); 742 1.4 nonaka walker += 16; 743 1.4 nonaka } 744 1.4 nonaka } 745 1.4 nonaka } 746 1.4 nonaka 747 1.4 nonaka static void 748 1.4 nonaka print_hgst_info_erase_errors(void *buf, uint16_t subtype __unused, 749 1.4 nonaka uint8_t res __unused, uint32_t size) 750 1.4 nonaka { 751 1.4 nonaka static const struct kv_name kv[] = { 752 1.4 nonaka { 0x0000, "Corrected Without Delay" }, 753 1.4 nonaka { 0x0001, "Corrected Maybe Delayed" }, 754 1.4 nonaka { 0x0002, "Re-Erase" }, 755 1.4 nonaka { 0x0003, "Errors Corrected" }, 756 1.4 nonaka { 0x0004, "Correct Algorithm Used" }, 757 1.4 nonaka { 0x0005, "Bytes Processed" }, 758 1.4 nonaka { 0x0006, "Uncorrected Errors" }, 759 1.4 nonaka { 0x8000, "Flash Erase Commands" }, 760 1.4 nonaka { 0x8001, "Mfg Defect Count" }, 761 1.4 nonaka { 0x8002, "Grown Defect Count" }, 762 1.4 nonaka { 0x8003, "Erase Count -- User" }, 763 1.4 nonaka { 0x8004, "Erase Count -- System" }, 764 1.4 nonaka }; 765 1.4 nonaka 766 1.4 nonaka printf("Erase Errors Subpage:\n"); 767 1.4 nonaka print_hgst_info_subpage_gen(buf, subtype, size, kv, __arraycount(kv)); 768 1.4 nonaka } 769 1.4 nonaka 770 1.4 nonaka static void 771 1.4 nonaka print_hgst_info_erase_counts(void *buf, uint16_t subtype, uint8_t res __unused, 772 1.4 nonaka uint32_t size) 773 1.4 nonaka { 774 1.4 nonaka /* My drive doesn't export this -- so not coding up */ 775 1.4 nonaka printf("XXX: Erase counts subpage: %p, %#x %d\n", buf, subtype, size); 776 1.4 nonaka } 777 1.4 nonaka 778 1.4 nonaka static void 779 1.4 nonaka print_hgst_info_temp_history(void *buf, uint16_t subtype __unused, 780 1.4 nonaka uint8_t res __unused, uint32_t size __unused) 781 1.4 nonaka { 782 1.4 nonaka uint8_t *walker = buf; 783 1.4 nonaka uint32_t min; 784 1.4 nonaka 785 1.4 nonaka printf("Temperature History:\n"); 786 1.4 nonaka printf(" %-30s: %d C\n", "Current Temperature", *walker++); 787 1.4 nonaka printf(" %-30s: %d C\n", "Reference Temperature", *walker++); 788 1.4 nonaka printf(" %-30s: %d C\n", "Maximum Temperature", *walker++); 789 1.4 nonaka printf(" %-30s: %d C\n", "Minimum Temperature", *walker++); 790 1.4 nonaka min = le32dec(walker); 791 1.4 nonaka walker += 4; 792 1.4 nonaka printf(" %-30s: %d:%02d:00\n", "Max Temperature Time", min / 60, min % 60); 793 1.4 nonaka min = le32dec(walker); 794 1.4 nonaka walker += 4; 795 1.4 nonaka printf(" %-30s: %d:%02d:00\n", "Over Temperature Duration", min / 60, 796 1.4 nonaka min % 60); 797 1.4 nonaka min = le32dec(walker); 798 1.4 nonaka walker += 4; 799 1.4 nonaka printf(" %-30s: %d:%02d:00\n", "Min Temperature Time", min / 60, min % 60); 800 1.4 nonaka } 801 1.4 nonaka 802 1.4 nonaka static void 803 1.4 nonaka print_hgst_info_ssd_perf(void *buf, uint16_t subtype __unused, uint8_t res, 804 1.4 nonaka uint32_t size __unused) 805 1.4 nonaka { 806 1.4 nonaka uint8_t *walker = buf; 807 1.4 nonaka uint64_t val; 808 1.4 nonaka 809 1.4 nonaka printf("SSD Performance Subpage Type %d:\n", res); 810 1.4 nonaka val = le64dec(walker); 811 1.4 nonaka walker += 8; 812 1.4 nonaka printf(" %-30s: %ju\n", "Host Read Commands", val); 813 1.4 nonaka val = le64dec(walker); 814 1.4 nonaka walker += 8; 815 1.4 nonaka printf(" %-30s: %ju\n", "Host Read Blocks", val); 816 1.4 nonaka val = le64dec(walker); 817 1.4 nonaka walker += 8; 818 1.4 nonaka printf(" %-30s: %ju\n", "Host Cache Read Hits Commands", val); 819 1.4 nonaka val = le64dec(walker); 820 1.4 nonaka walker += 8; 821 1.4 nonaka printf(" %-30s: %ju\n", "Host Cache Read Hits Blocks", val); 822 1.4 nonaka val = le64dec(walker); 823 1.4 nonaka walker += 8; 824 1.4 nonaka printf(" %-30s: %ju\n", "Host Read Commands Stalled", val); 825 1.4 nonaka val = le64dec(walker); 826 1.4 nonaka walker += 8; 827 1.4 nonaka printf(" %-30s: %ju\n", "Host Write Commands", val); 828 1.4 nonaka val = le64dec(walker); 829 1.4 nonaka walker += 8; 830 1.4 nonaka printf(" %-30s: %ju\n", "Host Write Blocks", val); 831 1.4 nonaka val = le64dec(walker); 832 1.4 nonaka walker += 8; 833 1.4 nonaka printf(" %-30s: %ju\n", "Host Write Odd Start Commands", val); 834 1.4 nonaka val = le64dec(walker); 835 1.4 nonaka walker += 8; 836 1.4 nonaka printf(" %-30s: %ju\n", "Host Write Odd End Commands", val); 837 1.4 nonaka val = le64dec(walker); 838 1.4 nonaka walker += 8; 839 1.4 nonaka printf(" %-30s: %ju\n", "Host Write Commands Stalled", val); 840 1.4 nonaka val = le64dec(walker); 841 1.4 nonaka walker += 8; 842 1.4 nonaka printf(" %-30s: %ju\n", "NAND Read Commands", val); 843 1.4 nonaka val = le64dec(walker); 844 1.4 nonaka walker += 8; 845 1.4 nonaka printf(" %-30s: %ju\n", "NAND Read Blocks", val); 846 1.4 nonaka val = le64dec(walker); 847 1.4 nonaka walker += 8; 848 1.4 nonaka printf(" %-30s: %ju\n", "NAND Write Commands", val); 849 1.4 nonaka val = le64dec(walker); 850 1.4 nonaka walker += 8; 851 1.4 nonaka printf(" %-30s: %ju\n", "NAND Write Blocks", val); 852 1.4 nonaka val = le64dec(walker); 853 1.4 nonaka walker += 8; 854 1.4 nonaka printf(" %-30s: %ju\n", "NAND Read Before Writes", val); 855 1.4 nonaka } 856 1.4 nonaka 857 1.4 nonaka static void 858 1.4 nonaka print_hgst_info_firmware_load(void *buf, uint16_t subtype __unused, 859 1.4 nonaka uint8_t res __unused, uint32_t size __unused) 860 1.4 nonaka { 861 1.4 nonaka uint8_t *walker = buf; 862 1.4 nonaka 863 1.4 nonaka printf("Firmware Load Subpage:\n"); 864 1.4 nonaka printf(" %-30s: %d\n", "Firmware Downloads", le32dec(walker)); 865 1.4 nonaka } 866 1.4 nonaka 867 1.4 nonaka static void 868 1.4 nonaka kv_indirect(void *buf, uint32_t subtype, uint8_t res, uint32_t size, 869 1.4 nonaka struct subpage_print *sp, size_t nsp) 870 1.4 nonaka { 871 1.4 nonaka size_t i; 872 1.4 nonaka 873 1.4 nonaka for (i = 0; i < nsp; i++, sp++) { 874 1.4 nonaka if (sp->key == subtype) { 875 1.4 nonaka sp->fn(buf, subtype, res, size); 876 1.4 nonaka return; 877 1.4 nonaka } 878 1.4 nonaka } 879 1.4 nonaka printf("No handler for page type %x\n", subtype); 880 1.4 nonaka } 881 1.4 nonaka 882 1.4 nonaka static void 883 1.6 nonaka print_hgst_info_log(const struct nvm_identify_controller *cdata __unused, void *buf, 884 1.6 nonaka uint32_t size __unused) 885 1.4 nonaka { 886 1.4 nonaka uint8_t *walker, *end, *subpage; 887 1.4 nonaka int pages __unused; 888 1.4 nonaka uint16_t len; 889 1.4 nonaka uint8_t subtype, res; 890 1.4 nonaka 891 1.4 nonaka printf("HGST Extra Info Log\n"); 892 1.4 nonaka printf("===================\n"); 893 1.4 nonaka 894 1.4 nonaka walker = buf; 895 1.4 nonaka pages = *walker++; 896 1.4 nonaka walker++; 897 1.4 nonaka len = le16dec(walker); 898 1.4 nonaka walker += 2; 899 1.4 nonaka end = walker + len; /* Length is exclusive of this header */ 900 1.4 nonaka 901 1.4 nonaka while (walker < end) { 902 1.4 nonaka subpage = walker + 4; 903 1.4 nonaka subtype = *walker++ & 0x3f; /* subtype */ 904 1.4 nonaka res = *walker++; /* Reserved */ 905 1.4 nonaka len = le16dec(walker); 906 1.4 nonaka walker += len + 2; /* Length, not incl header */ 907 1.4 nonaka if (walker > end) { 908 1.4 nonaka printf("Ooops! Off the end of the list\n"); 909 1.4 nonaka break; 910 1.4 nonaka } 911 1.4 nonaka kv_indirect(subpage, subtype, res, len, hgst_subpage, 912 1.4 nonaka __arraycount(hgst_subpage)); 913 1.4 nonaka } 914 1.4 nonaka } 915 1.4 nonaka 916 1.4 nonaka /* 917 1.4 nonaka * Table of log page printer / sizing. 918 1.4 nonaka * 919 1.4 nonaka * This includes Intel specific pages that are widely implemented. 920 1.4 nonaka * Make sure you keep all the pages of one vendor together so -v help 921 1.4 nonaka * lists all the vendors pages. 922 1.4 nonaka */ 923 1.1 nonaka static struct logpage_function { 924 1.1 nonaka uint8_t log_page; 925 1.4 nonaka const char *vendor; 926 1.4 nonaka const char *name; 927 1.4 nonaka print_fn_t print_fn; 928 1.4 nonaka size_t size; 929 1.1 nonaka } logfuncs[] = { 930 1.4 nonaka {NVME_LOG_ERROR, NULL, "Drive Error Log", 931 1.4 nonaka print_log_error, 0}, 932 1.4 nonaka {NVME_LOG_HEALTH_INFORMATION, NULL, "Health/SMART Data", 933 1.4 nonaka print_log_health, sizeof(struct nvme_health_information_page)}, 934 1.4 nonaka {NVME_LOG_FIRMWARE_SLOT, NULL, "Firmware Information", 935 1.4 nonaka print_log_firmware, sizeof(struct nvme_firmware_page)}, 936 1.4 nonaka {HGST_INFO_LOG, "hgst", "Detailed Health/SMART", 937 1.4 nonaka print_hgst_info_log, DEFAULT_SIZE}, 938 1.4 nonaka {HGST_INFO_LOG, "wds", "Detailed Health/SMART", 939 1.4 nonaka print_hgst_info_log, DEFAULT_SIZE}, 940 1.4 nonaka {INTEL_LOG_TEMP_STATS, "intel", "Temperature Stats", 941 1.4 nonaka print_intel_temp_stats, sizeof(struct intel_log_temp_stats)}, 942 1.4 nonaka {INTEL_LOG_READ_LAT_LOG, "intel", "Read Latencies", 943 1.4 nonaka print_intel_read_lat_log, DEFAULT_SIZE}, 944 1.4 nonaka {INTEL_LOG_WRITE_LAT_LOG, "intel", "Write Latencies", 945 1.4 nonaka print_intel_write_lat_log, DEFAULT_SIZE}, 946 1.4 nonaka {INTEL_LOG_ADD_SMART, "intel", "Extra Health/SMART Data", 947 1.4 nonaka print_intel_add_smart, DEFAULT_SIZE}, 948 1.4 nonaka {INTEL_LOG_ADD_SMART, "samsung", "Extra Health/SMART Data", 949 1.4 nonaka print_intel_add_smart, DEFAULT_SIZE}, 950 1.4 nonaka 951 1.4 nonaka {0, NULL, NULL, NULL, 0}, 952 1.1 nonaka }; 953 1.1 nonaka 954 1.2 joerg __dead static void 955 1.1 nonaka logpage_usage(void) 956 1.1 nonaka { 957 1.1 nonaka fprintf(stderr, "usage:\n"); 958 1.5 jdolecek fprintf(stderr, "\t%s " LOGPAGE_USAGE, getprogname()); 959 1.1 nonaka exit(1); 960 1.1 nonaka } 961 1.1 nonaka 962 1.4 nonaka __dead static void 963 1.4 nonaka logpage_help(void) 964 1.4 nonaka { 965 1.4 nonaka struct logpage_function *f; 966 1.4 nonaka const char *v; 967 1.4 nonaka 968 1.4 nonaka fprintf(stderr, "\n"); 969 1.4 nonaka fprintf(stderr, "%-8s %-10s %s\n", "Page", "Vendor","Page Name"); 970 1.4 nonaka fprintf(stderr, "-------- ---------- ----------\n"); 971 1.4 nonaka for (f = logfuncs; f->log_page > 0; f++) { 972 1.4 nonaka v = f->vendor == NULL ? "-" : f->vendor; 973 1.4 nonaka fprintf(stderr, "0x%02x %-10s %s\n", f->log_page, v, f->name); 974 1.4 nonaka } 975 1.4 nonaka 976 1.4 nonaka exit(1); 977 1.4 nonaka } 978 1.4 nonaka 979 1.1 nonaka void 980 1.1 nonaka logpage(int argc, char *argv[]) 981 1.1 nonaka { 982 1.1 nonaka int fd, nsid; 983 1.1 nonaka int log_page = 0, pageflag = false; 984 1.4 nonaka int binflag = false, hexflag = false, ns_specified; 985 1.1 nonaka int ch; 986 1.1 nonaka char *p; 987 1.1 nonaka char cname[64]; 988 1.1 nonaka uint32_t size; 989 1.1 nonaka void *buf; 990 1.4 nonaka const char *vendor = NULL; 991 1.1 nonaka struct logpage_function *f; 992 1.1 nonaka struct nvm_identify_controller cdata; 993 1.1 nonaka print_fn_t print_fn; 994 1.1 nonaka 995 1.4 nonaka while ((ch = getopt(argc, argv, "bp:xv:")) != -1) { 996 1.1 nonaka switch (ch) { 997 1.4 nonaka case 'b': 998 1.4 nonaka binflag = true; 999 1.4 nonaka break; 1000 1.1 nonaka case 'p': 1001 1.4 nonaka if (strcmp(optarg, "help") == 0) 1002 1.4 nonaka logpage_help(); 1003 1.4 nonaka 1004 1.1 nonaka /* TODO: Add human-readable ASCII page IDs */ 1005 1.1 nonaka log_page = strtol(optarg, &p, 0); 1006 1.1 nonaka if (p != NULL && *p != '\0') { 1007 1.1 nonaka fprintf(stderr, 1008 1.1 nonaka "\"%s\" not valid log page id.\n", 1009 1.1 nonaka optarg); 1010 1.1 nonaka logpage_usage(); 1011 1.1 nonaka } 1012 1.1 nonaka pageflag = true; 1013 1.1 nonaka break; 1014 1.1 nonaka case 'x': 1015 1.1 nonaka hexflag = true; 1016 1.1 nonaka break; 1017 1.4 nonaka case 'v': 1018 1.4 nonaka if (strcmp(optarg, "help") == 0) 1019 1.4 nonaka logpage_help(); 1020 1.4 nonaka vendor = optarg; 1021 1.4 nonaka break; 1022 1.1 nonaka } 1023 1.1 nonaka } 1024 1.1 nonaka 1025 1.1 nonaka if (!pageflag) { 1026 1.1 nonaka printf("Missing page_id (-p).\n"); 1027 1.1 nonaka logpage_usage(); 1028 1.1 nonaka } 1029 1.1 nonaka 1030 1.1 nonaka /* Check that a controller and/or namespace was specified. */ 1031 1.1 nonaka if (optind >= argc) 1032 1.1 nonaka logpage_usage(); 1033 1.1 nonaka 1034 1.1 nonaka if (strstr(argv[optind], NVME_NS_PREFIX) != NULL) { 1035 1.1 nonaka ns_specified = true; 1036 1.1 nonaka parse_ns_str(argv[optind], cname, &nsid); 1037 1.1 nonaka open_dev(cname, &fd, 1, 1); 1038 1.1 nonaka } else { 1039 1.1 nonaka ns_specified = false; 1040 1.1 nonaka nsid = 0xffffffff; 1041 1.1 nonaka open_dev(argv[optind], &fd, 1, 1); 1042 1.1 nonaka } 1043 1.1 nonaka 1044 1.1 nonaka read_controller_data(fd, &cdata); 1045 1.1 nonaka 1046 1.1 nonaka /* 1047 1.8 andvar * The log page attributes indicate whether or not the controller 1048 1.1 nonaka * supports the SMART/Health information log page on a per 1049 1.1 nonaka * namespace basis. 1050 1.1 nonaka */ 1051 1.1 nonaka if (ns_specified) { 1052 1.1 nonaka if (log_page != NVME_LOG_HEALTH_INFORMATION) 1053 1.1 nonaka errx(1, "log page %d valid only at controller level", 1054 1.1 nonaka log_page); 1055 1.1 nonaka if (!(cdata.lpa & NVME_ID_CTRLR_LPA_NS_SMART)) 1056 1.1 nonaka errx(1, 1057 1.1 nonaka "controller does not support per namespace " 1058 1.1 nonaka "smart/health information"); 1059 1.1 nonaka } 1060 1.1 nonaka 1061 1.6 nonaka print_fn = print_log_hex; 1062 1.4 nonaka size = DEFAULT_SIZE; 1063 1.4 nonaka if (binflag) 1064 1.4 nonaka print_fn = print_bin; 1065 1.4 nonaka if (!binflag && !hexflag) { 1066 1.1 nonaka /* 1067 1.4 nonaka * See if there is a pretty print function for the specified log 1068 1.4 nonaka * page. If one isn't found, we just revert to the default 1069 1.4 nonaka * (print_hex). If there was a vendor specified bt the user, and 1070 1.4 nonaka * the page is vendor specific, don't match the print function 1071 1.4 nonaka * unless the vendors match. 1072 1.1 nonaka */ 1073 1.4 nonaka for (f = logfuncs; f->log_page > 0; f++) { 1074 1.4 nonaka if (f->vendor != NULL && vendor != NULL && 1075 1.4 nonaka strcmp(f->vendor, vendor) != 0) 1076 1.4 nonaka continue; 1077 1.4 nonaka if (log_page != f->log_page) 1078 1.4 nonaka continue; 1079 1.4 nonaka print_fn = f->print_fn; 1080 1.4 nonaka size = f->size; 1081 1.4 nonaka break; 1082 1.1 nonaka } 1083 1.1 nonaka } 1084 1.1 nonaka 1085 1.4 nonaka if (log_page == NVME_LOG_ERROR) { 1086 1.1 nonaka size = sizeof(struct nvme_error_information_entry); 1087 1.1 nonaka size *= (cdata.elpe + 1); 1088 1.1 nonaka } 1089 1.1 nonaka 1090 1.4 nonaka /* Read the log page */ 1091 1.1 nonaka buf = get_log_buffer(size); 1092 1.1 nonaka read_logpage(fd, log_page, nsid, buf, size); 1093 1.6 nonaka print_fn(&cdata, buf, size); 1094 1.1 nonaka 1095 1.1 nonaka close(fd); 1096 1.1 nonaka exit(0); 1097 1.1 nonaka } 1098
Indexes created Mon Sep 22 10:09:38 GMT 2025