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nvme-print-stdout.c
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nvme-print-stdout.c
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// SPDX-License-Identifier: GPL-2.0-or-later
#include <assert.h>
#include <errno.h>
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <time.h>
#include <sys/stat.h>
#include <ccan/ccan/strset/strset.h>
#include <ccan/ccan/htable/htable_type.h>
#include <ccan/ccan/htable/htable.h>
#include <ccan/ccan/hash/hash.h>
#include "nvme.h"
#include "libnvme.h"
#include "nvme-print.h"
#include "nvme-models.h"
#include "util/suffix.h"
#include "util/types.h"
#include "common.h"
static const uint8_t zero_uuid[16] = { 0 };
static const uint8_t invalid_uuid[16] = {[0 ... 15] = 0xff };
static const char dash[100] = {[0 ... 99] = '-'};
static struct print_ops stdout_print_ops;
static const char *subsys_key(const struct nvme_subsystem *s)
{
return nvme_subsystem_get_name((nvme_subsystem_t)s);
}
static const char *ctrl_key(const struct nvme_ctrl *c)
{
return nvme_ctrl_get_name((nvme_ctrl_t)c);
}
static const char *ns_key(const struct nvme_ns *n)
{
return nvme_ns_get_name((nvme_ns_t)n);
}
static bool subsys_cmp(const struct nvme_subsystem *s, const char *name)
{
return !strcmp(nvme_subsystem_get_name((nvme_subsystem_t)s), name);
}
static bool ctrl_cmp(const struct nvme_ctrl *c, const char *name)
{
return !strcmp(nvme_ctrl_get_name((nvme_ctrl_t)c), name);
}
static bool ns_cmp(const struct nvme_ns *n, const char *name)
{
return !strcmp(nvme_ns_get_name((nvme_ns_t)n), name);
}
HTABLE_DEFINE_TYPE(struct nvme_subsystem, subsys_key, hash_string,
subsys_cmp, htable_subsys);
HTABLE_DEFINE_TYPE(struct nvme_ctrl, ctrl_key, hash_string,
ctrl_cmp, htable_ctrl);
HTABLE_DEFINE_TYPE(struct nvme_ns, ns_key, hash_string,
ns_cmp, htable_ns);
static void htable_ctrl_add_unique(struct htable_ctrl *ht, nvme_ctrl_t c)
{
if (htable_ctrl_get(ht, nvme_ctrl_get_name(c)))
return;
htable_ctrl_add(ht, c);
}
static void htable_ns_add_unique(struct htable_ns *ht, nvme_ns_t n)
{
struct htable_ns_iter it;
nvme_ns_t _n;
/*
* Test if namespace pointer is already in the hash, and thus avoid
* inserting severaltimes the same pointer.
*/
for (_n = htable_ns_getfirst(ht, nvme_ns_get_name(n), &it);
_n;
_n = htable_ns_getnext(ht, nvme_ns_get_name(n), &it)) {
if (_n == n)
return;
}
htable_ns_add(ht, n);
}
struct nvme_resources {
nvme_root_t r;
struct htable_subsys ht_s;
struct htable_ctrl ht_c;
struct htable_ns ht_n;
struct strset subsystems;
struct strset ctrls;
struct strset namespaces;
};
static int nvme_resources_init(nvme_root_t r, struct nvme_resources *res)
{
nvme_host_t h;
nvme_subsystem_t s;
nvme_ctrl_t c;
nvme_ns_t n;
nvme_path_t p;
res->r = r;
htable_subsys_init(&res->ht_s);
htable_ctrl_init(&res->ht_c);
htable_ns_init(&res->ht_n);
strset_init(&res->subsystems);
strset_init(&res->ctrls);
strset_init(&res->namespaces);
nvme_for_each_host(r, h) {
nvme_for_each_subsystem(h, s) {
htable_subsys_add(&res->ht_s, s);
strset_add(&res->subsystems, nvme_subsystem_get_name(s));
nvme_subsystem_for_each_ctrl(s, c) {
htable_ctrl_add_unique(&res->ht_c, c);
strset_add(&res->ctrls, nvme_ctrl_get_name(c));
nvme_ctrl_for_each_ns(c, n) {
htable_ns_add_unique(&res->ht_n, n);
strset_add(&res->namespaces, nvme_ns_get_name(n));
}
nvme_ctrl_for_each_path(c, p) {
n = nvme_path_get_ns(p);
if (n) {
htable_ns_add_unique(&res->ht_n, n);
strset_add(&res->namespaces, nvme_ns_get_name(n));
}
}
}
nvme_subsystem_for_each_ns(s, n) {
htable_ns_add_unique(&res->ht_n, n);
strset_add(&res->namespaces, nvme_ns_get_name(n));
}
}
}
return 0;
}
static void nvme_resources_free(struct nvme_resources *res)
{
strset_clear(&res->namespaces);
strset_clear(&res->ctrls);
strset_clear(&res->subsystems);
htable_ns_clear(&res->ht_n);
htable_ctrl_clear(&res->ht_c);
htable_subsys_clear(&res->ht_s);
}
static void stdout_feature_show_fields(enum nvme_features_id fid,
unsigned int result,
unsigned char *buf);
static void stdout_smart_log(struct nvme_smart_log *smart, unsigned int nsid, const char *devname);
static void stdout_predictable_latency_per_nvmset(
struct nvme_nvmset_predictable_lat_log *plpns_log,
__u16 nvmset_id, const char *devname)
{
printf("Predictable Latency Per NVM Set Log for device: %s\n",
devname);
printf("Predictable Latency Per NVM Set Log for NVM Set ID: %u\n",
le16_to_cpu(nvmset_id));
printf("Status: %u\n", plpns_log->status);
printf("Event Type: %u\n",
le16_to_cpu(plpns_log->event_type));
printf("DTWIN Reads Typical: %"PRIu64"\n",
le64_to_cpu(plpns_log->dtwin_rt));
printf("DTWIN Writes Typical: %"PRIu64"\n",
le64_to_cpu(plpns_log->dtwin_wt));
printf("DTWIN Time Maximum: %"PRIu64"\n",
le64_to_cpu(plpns_log->dtwin_tmax));
printf("NDWIN Time Minimum High: %"PRIu64"\n",
le64_to_cpu(plpns_log->ndwin_tmin_hi));
printf("NDWIN Time Minimum Low: %"PRIu64"\n",
le64_to_cpu(plpns_log->ndwin_tmin_lo));
printf("DTWIN Reads Estimate: %"PRIu64"\n",
le64_to_cpu(plpns_log->dtwin_re));
printf("DTWIN Writes Estimate: %"PRIu64"\n",
le64_to_cpu(plpns_log->dtwin_we));
printf("DTWIN Time Estimate: %"PRIu64"\n\n\n",
le64_to_cpu(plpns_log->dtwin_te));
}
static void stdout_predictable_latency_event_agg_log(
struct nvme_aggregate_predictable_lat_event *pea_log,
__u64 log_entries, __u32 size, const char *devname)
{
__u64 num_iter;
__u64 num_entries;
num_entries = le64_to_cpu(pea_log->num_entries);
printf("Predictable Latency Event Aggregate Log for device: %s\n", devname);
printf("Number of Entries Available: %"PRIu64"\n", (uint64_t)num_entries);
num_iter = min(num_entries, log_entries);
for (int i = 0; i < num_iter; i++)
printf("Entry[%d]: %u\n", i + 1, le16_to_cpu(pea_log->entries[i]));
}
static void stdout_persistent_event_log_rci(__le32 pel_header_rci)
{
__u32 rci = le32_to_cpu(pel_header_rci);
__u32 rsvd19 = NVME_PEL_RCI_RSVD(rci);
__u8 rce = NVME_PEL_RCI_RCE(rci);
__u8 rcpit = NVME_PEL_RCI_RCPIT(rci);
__u16 rcpid = NVME_PEL_RCI_RCPID(rci);
if (rsvd19)
printf(" [31:19] : %#x\tReserved\n", rsvd19);
printf("\tReporting Context Exists (RCE): %s(%u)\n", rce ? "true" : "false", rce);
printf("\tReporting Context Port Identifier Type (RCPIT): %u(%s)\n", rcpit,
nvme_pel_rci_rcpit_to_string(rcpit));
printf("\tReporting Context Port Identifier (RCPID): %#x\n\n", rcpid);
}
static void stdout_persistent_event_entry_ehai(__u8 ehai)
{
__u8 rsvd1 = NVME_PEL_EHAI_RSVD(ehai);
__u8 pit = NVME_PEL_EHAI_PIT(ehai);
printf(" [7:2] : %#x\tReserved\n", rsvd1);
printf("\tPort Identifier Type (PIT): %u(%s)\n", pit, nvme_pel_ehai_pit_to_string(pit));
}
static void stdout_add_bitmap(int i, __u8 seb)
{
for (int bit = 0; bit < CHAR_BIT; bit++) {
if (nvme_pel_event_to_string(bit + i * CHAR_BIT)) {
if ((seb >> bit) & 0x1)
printf(" Support %s\n",
nvme_pel_event_to_string(bit + i * CHAR_BIT));
}
}
}
static void stdout_persistent_event_log(void *pevent_log_info,
__u8 action, __u32 size,
const char *devname)
{
__u32 offset, por_info_len, por_info_list;
__u64 *fw_rev;
int fid, cdw11, dword_cnt;
unsigned char *mem_buf = NULL;
struct nvme_smart_log *smart_event;
struct nvme_fw_commit_event *fw_commit_event;
struct nvme_time_stamp_change_event *ts_change_event;
struct nvme_power_on_reset_info_list *por_event;
struct nvme_nss_hw_err_event *nss_hw_err_event;
struct nvme_change_ns_event *ns_event;
struct nvme_format_nvm_start_event *format_start_event;
struct nvme_format_nvm_compln_event *format_cmpln_event;
struct nvme_sanitize_start_event *sanitize_start_event;
struct nvme_sanitize_compln_event *sanitize_cmpln_event;
struct nvme_set_feature_event *set_feat_event;
struct nvme_thermal_exc_event *thermal_exc_event;
struct nvme_persistent_event_log *pevent_log_head;
struct nvme_persistent_event_entry *pevent_entry_head;
int human = stdout_print_ops.flags & VERBOSE;
offset = sizeof(*pevent_log_head);
printf("Persistent Event Log for device: %s\n", devname);
printf("Action for Persistent Event Log: %u\n", action);
if (size >= offset) {
pevent_log_head = pevent_log_info;
printf("Log Identifier: %u\n", pevent_log_head->lid);
printf("Total Number of Events: %u\n",
le32_to_cpu(pevent_log_head->tnev));
printf("Total Log Length : %"PRIu64"\n",
le64_to_cpu(pevent_log_head->tll));
printf("Log Revision: %u\n", pevent_log_head->rv);
printf("Log Header Length: %u\n", pevent_log_head->lhl);
printf("Timestamp: %"PRIu64"\n",
le64_to_cpu(pevent_log_head->ts));
printf("Power On Hours (POH): %s",
uint128_t_to_l10n_string(le128_to_cpu(pevent_log_head->poh)));
printf("Power Cycle Count: %"PRIu64"\n",
le64_to_cpu(pevent_log_head->pcc));
printf("PCI Vendor ID (VID): %u\n",
le16_to_cpu(pevent_log_head->vid));
printf("PCI Subsystem Vendor ID (SSVID): %u\n",
le16_to_cpu(pevent_log_head->ssvid));
printf("Serial Number (SN): %-.*s\n",
(int)sizeof(pevent_log_head->sn), pevent_log_head->sn);
printf("Model Number (MN): %-.*s\n",
(int)sizeof(pevent_log_head->mn), pevent_log_head->mn);
printf("NVM Subsystem NVMe Qualified Name (SUBNQN): %-.*s\n",
(int)sizeof(pevent_log_head->subnqn),
pevent_log_head->subnqn);
printf("Generation Number: %u\n",
le16_to_cpu(pevent_log_head->gen_number));
printf("Reporting Context Information (RCI): %u\n",
le32_to_cpu(pevent_log_head->rci));
if (human)
stdout_persistent_event_log_rci(pevent_log_head->rci);
printf("Supported Events Bitmap:\n");
for (int i = 0; i < 32; i++) {
if (pevent_log_head->seb[i] == 0)
continue;
stdout_add_bitmap(i, pevent_log_head->seb[i]);
}
} else {
printf("No log data can be shown with this log len at least " \
"512 bytes is required or can be 0 to read the complete "\
"log page after context established\n");
return;
}
printf("\n");
printf("\nPersistent Event Entries:\n");
for (int i = 0; i < le32_to_cpu(pevent_log_head->tnev); i++) {
if (offset + sizeof(*pevent_entry_head) >= size)
break;
pevent_entry_head = pevent_log_info + offset;
if ((offset + pevent_entry_head->ehl + 3 +
le16_to_cpu(pevent_entry_head->el)) >= size)
break;
printf("Event Number: %u\n", i);
printf("Event Type: %s\n", nvme_pel_event_to_string(pevent_entry_head->etype));
printf("Event Type Revision: %u\n", pevent_entry_head->etype_rev);
printf("Event Header Length: %u\n", pevent_entry_head->ehl);
printf("Event Header Additional Info: %u\n", pevent_entry_head->ehai);
if (human)
stdout_persistent_event_entry_ehai(pevent_entry_head->ehai);
printf("Controller Identifier: %u\n",
le16_to_cpu(pevent_entry_head->cntlid));
printf("Event Timestamp: %"PRIu64"\n",
le64_to_cpu(pevent_entry_head->ets));
printf("Port Identifier: %u\n",
le16_to_cpu(pevent_entry_head->pelpid));
printf("Vendor Specific Information Length: %u\n",
le16_to_cpu(pevent_entry_head->vsil));
printf("Event Length: %u\n", le16_to_cpu(pevent_entry_head->el));
offset += pevent_entry_head->ehl + 3;
switch (pevent_entry_head->etype) {
case NVME_PEL_SMART_HEALTH_EVENT:
smart_event = pevent_log_info + offset;
printf("Smart Health Event Entry:\n");
stdout_smart_log(smart_event, NVME_NSID_ALL, devname);
break;
case NVME_PEL_FW_COMMIT_EVENT:
fw_commit_event = pevent_log_info + offset;
printf("FW Commit Event Entry:\n");
printf("Old Firmware Revision: %"PRIu64" (%s)\n",
le64_to_cpu(fw_commit_event->old_fw_rev),
util_fw_to_string((char *)&fw_commit_event->old_fw_rev));
printf("New Firmware Revision: %"PRIu64" (%s)\n",
le64_to_cpu(fw_commit_event->new_fw_rev),
util_fw_to_string((char *)&fw_commit_event->new_fw_rev));
printf("FW Commit Action: %u\n",
fw_commit_event->fw_commit_action);
printf("FW Slot: %u\n", fw_commit_event->fw_slot);
printf("Status Code Type for Firmware Commit Command: %u\n",
fw_commit_event->sct_fw);
printf("Status Returned for Firmware Commit Command: %u\n",
fw_commit_event->sc_fw);
printf("Vendor Assigned Firmware Commit Result Code: %u\n",
le16_to_cpu(fw_commit_event->vndr_assign_fw_commit_rc));
break;
case NVME_PEL_TIMESTAMP_EVENT:
ts_change_event = pevent_log_info + offset;
printf("Time Stamp Change Event Entry:\n");
printf("Previous Timestamp: %"PRIu64"\n",
le64_to_cpu(ts_change_event->previous_timestamp));
printf("Milliseconds Since Reset: %"PRIu64"\n",
le64_to_cpu(ts_change_event->ml_secs_since_reset));
break;
case NVME_PEL_POWER_ON_RESET_EVENT:
por_info_len = (le16_to_cpu(pevent_entry_head->el) -
le16_to_cpu(pevent_entry_head->vsil) - sizeof(*fw_rev));
por_info_list = por_info_len / sizeof(*por_event);
printf("Power On Reset Event Entry:\n");
fw_rev = pevent_log_info + offset;
printf("Firmware Revision: %"PRIu64" (%s)\n", le64_to_cpu(*fw_rev),
util_fw_to_string((char *)fw_rev));
printf("Reset Information List:\n");
for (int i = 0; i < por_info_list; i++) {
por_event = pevent_log_info + offset +
sizeof(*fw_rev) + i * sizeof(*por_event);
printf("Controller ID: %u\n", le16_to_cpu(por_event->cid));
printf("Firmware Activation: %u\n",
por_event->fw_act);
printf("Operation in Progress: %u\n",
por_event->op_in_prog);
printf("Controller Power Cycle: %u\n",
le32_to_cpu(por_event->ctrl_power_cycle));
printf("Power on milliseconds: %"PRIu64"\n",
le64_to_cpu(por_event->power_on_ml_seconds));
printf("Controller Timestamp: %"PRIu64"\n",
le64_to_cpu(por_event->ctrl_time_stamp));
}
break;
case NVME_PEL_NSS_HW_ERROR_EVENT:
nss_hw_err_event = pevent_log_info + offset;
printf("NVM Subsystem Hardware Error Event Code Entry: %u, %s\n",
le16_to_cpu(nss_hw_err_event->nss_hw_err_event_code),
nvme_nss_hw_error_to_string(nss_hw_err_event->nss_hw_err_event_code));
break;
case NVME_PEL_CHANGE_NS_EVENT:
ns_event = pevent_log_info + offset;
printf("Change Namespace Event Entry:\n");
printf("Namespace Management CDW10: %u\n",
le32_to_cpu(ns_event->nsmgt_cdw10));
printf("Namespace Size: %"PRIu64"\n",
le64_to_cpu(ns_event->nsze));
printf("Namespace Capacity: %"PRIu64"\n",
le64_to_cpu(ns_event->nscap));
printf("Formatted LBA Size: %u\n", ns_event->flbas);
printf("End-to-end Data Protection Type Settings: %u\n",
ns_event->dps);
printf("Namespace Multi-path I/O and Namespace Sharing" \
" Capabilities: %u\n", ns_event->nmic);
printf("ANA Group Identifier: %u\n",
le32_to_cpu(ns_event->ana_grp_id));
printf("NVM Set Identifier: %u\n", le16_to_cpu(ns_event->nvmset_id));
printf("Namespace ID: %u\n", le32_to_cpu(ns_event->nsid));
break;
case NVME_PEL_FORMAT_START_EVENT:
format_start_event = pevent_log_info + offset;
printf("Format NVM Start Event Entry:\n");
printf("Namespace Identifier: %u\n",
le32_to_cpu(format_start_event->nsid));
printf("Format NVM Attributes: %u\n",
format_start_event->fna);
printf("Format NVM CDW10: %u\n",
le32_to_cpu(format_start_event->format_nvm_cdw10));
break;
case NVME_PEL_FORMAT_COMPLETION_EVENT:
format_cmpln_event = pevent_log_info + offset;
printf("Format NVM Completion Event Entry:\n");
printf("Namespace Identifier: %u\n",
le32_to_cpu(format_cmpln_event->nsid));
printf("Smallest Format Progress Indicator: %u\n",
format_cmpln_event->smallest_fpi);
printf("Format NVM Status: %u\n",
format_cmpln_event->format_nvm_status);
printf("Completion Information: %u\n",
le16_to_cpu(format_cmpln_event->compln_info));
printf("Status Field: %u\n",
le32_to_cpu(format_cmpln_event->status_field));
break;
case NVME_PEL_SANITIZE_START_EVENT:
sanitize_start_event = pevent_log_info + offset;
printf("Sanitize Start Event Entry:\n");
printf("SANICAP: %u\n", sanitize_start_event->sani_cap);
printf("Sanitize CDW10: %u\n",
le32_to_cpu(sanitize_start_event->sani_cdw10));
printf("Sanitize CDW11: %u\n",
le32_to_cpu(sanitize_start_event->sani_cdw11));
break;
case NVME_PEL_SANITIZE_COMPLETION_EVENT:
sanitize_cmpln_event = pevent_log_info + offset;
printf("Sanitize Completion Event Entry:\n");
printf("Sanitize Progress: %u\n",
le16_to_cpu(sanitize_cmpln_event->sani_prog));
printf("Sanitize Status: %u\n",
le16_to_cpu(sanitize_cmpln_event->sani_status));
printf("Completion Information: %u\n",
le16_to_cpu(sanitize_cmpln_event->cmpln_info));
break;
case NVME_PEL_SET_FEATURE_EVENT:
set_feat_event = pevent_log_info + offset;
printf("Set Feature Event Entry:\n");
dword_cnt = NVME_SET_FEAT_EVENT_DW_COUNT(set_feat_event->layout);
fid = NVME_GET(le32_to_cpu(set_feat_event->cdw_mem[0]), FEATURES_CDW10_FID);
cdw11 = le32_to_cpu(set_feat_event->cdw_mem[1]);
printf("Set Feature ID :%#02x (%s), value:%#08x\n", fid,
nvme_feature_to_string(fid), cdw11);
if (NVME_SET_FEAT_EVENT_MB_COUNT(set_feat_event->layout)) {
mem_buf = (unsigned char *)(set_feat_event + 4 + dword_cnt * 4);
stdout_feature_show_fields(fid, cdw11, mem_buf);
}
break;
case NVME_PEL_TELEMETRY_CRT:
d(pevent_log_info + offset, 512, 16, 1);
break;
case NVME_PEL_THERMAL_EXCURSION_EVENT:
thermal_exc_event = pevent_log_info + offset;
printf("Thermal Excursion Event Entry:\n");
printf("Over Temperature: %u\n", thermal_exc_event->over_temp);
printf("Threshold: %u\n", thermal_exc_event->threshold);
break;
default:
printf("Reserved Event\n\n");
break;
}
offset += le16_to_cpu(pevent_entry_head->el);
printf("\n");
}
}
static void stdout_endurance_group_event_agg_log(
struct nvme_aggregate_predictable_lat_event *endurance_log,
__u64 log_entries, __u32 size, const char *devname)
{
printf("Endurance Group Event Aggregate Log for device: %s\n", devname);
printf("Number of Entries Available: %"PRIu64"\n",
le64_to_cpu(endurance_log->num_entries));
for (int i = 0; i < log_entries; i++) {
printf("Entry[%d]: %u\n", i + 1,
le16_to_cpu(endurance_log->entries[i]));
}
}
static void stdout_lba_status_log(void *lba_status, __u32 size,
const char *devname)
{
struct nvme_lba_status_log *hdr;
struct nvme_lbas_ns_element *ns_element;
struct nvme_lba_rd *range_desc;
int offset = sizeof(*hdr);
__u32 num_lba_desc, num_elements;
hdr = lba_status;
printf("LBA Status Log for device: %s\n", devname);
printf("LBA Status Log Page Length: %"PRIu32"\n",
le32_to_cpu(hdr->lslplen));
num_elements = le32_to_cpu(hdr->nlslne);
printf("Number of LBA Status Log Namespace Elements: %"PRIu32"\n",
num_elements);
printf("Estimate of Unrecoverable Logical Blocks: %"PRIu32"\n",
le32_to_cpu(hdr->estulb));
printf("LBA Status Generation Counter: %"PRIu16"\n", le16_to_cpu(hdr->lsgc));
for (int ele = 0; ele < num_elements; ele++) {
ns_element = lba_status + offset;
printf("Namespace Element Identifier: %"PRIu32"\n",
le32_to_cpu(ns_element->neid));
num_lba_desc = le32_to_cpu(ns_element->nlrd);
printf("Number of LBA Range Descriptors: %"PRIu32"\n", num_lba_desc);
printf("Recommended Action Type: %u\n", ns_element->ratype);
offset += sizeof(*ns_element);
if (num_lba_desc != 0xffffffff) {
for (int i = 0; i < num_lba_desc; i++) {
range_desc = lba_status + offset;
printf("RSLBA[%d]: %"PRIu64"\n", i,
le64_to_cpu(range_desc->rslba));
printf("RNLB[%d]: %"PRIu32"\n", i,
le32_to_cpu(range_desc->rnlb));
offset += sizeof(*range_desc);
}
} else {
printf("Number of LBA Range Descriptors (NLRD) set to %#x for "\
"NS element %d\n", num_lba_desc, ele);
}
}
}
static void stdout_resv_notif_log(struct nvme_resv_notification_log *resv,
const char *devname)
{
printf("Reservation Notif Log for device: %s\n", devname);
printf("Log Page Count : %"PRIx64"\n",
le64_to_cpu(resv->lpc));
printf("Resv Notif Log Page Type : %u (%s)\n",
resv->rnlpt,
nvme_resv_notif_to_string(resv->rnlpt));
printf("Num of Available Log Pages : %u\n", resv->nalp);
printf("Namespace ID: : %"PRIx32"\n",
le32_to_cpu(resv->nsid));
}
static void stdout_fid_support_effects_log_human(__u32 fid_support)
{
const char *set = "+";
const char *clr = "-";
__u16 fsp;
printf(" FSUPP+");
printf(" UDCC%s", (fid_support & NVME_FID_SUPPORTED_EFFECTS_UDCC) ? set : clr);
printf(" NCC%s", (fid_support & NVME_FID_SUPPORTED_EFFECTS_NCC) ? set : clr);
printf(" NIC%s", (fid_support & NVME_FID_SUPPORTED_EFFECTS_NIC) ? set : clr);
printf(" CCC%s", (fid_support & NVME_FID_SUPPORTED_EFFECTS_CCC) ? set : clr);
printf(" USS%s", (fid_support & NVME_FID_SUPPORTED_EFFECTS_UUID_SEL) ? set : clr);
fsp = NVME_GET(fid_support, FID_SUPPORTED_EFFECTS_SCOPE);
printf(" NAMESPACE SCOPE%s", (fsp & NVME_FID_SUPPORTED_EFFECTS_SCOPE_NS) ? set : clr);
printf(" CONTROLLER SCOPE%s", (fsp & NVME_FID_SUPPORTED_EFFECTS_SCOPE_CTRL) ? set : clr);
printf(" NVM SET SCOPE%s", (fsp & NVME_FID_SUPPORTED_EFFECTS_SCOPE_NVM_SET) ? set : clr);
printf(" ENDURANCE GROUP SCOPE%s", (fsp & NVME_FID_SUPPORTED_EFFECTS_SCOPE_ENDGRP) ? set : clr);
printf(" DOMAIN SCOPE%s", (fsp & NVME_FID_SUPPORTED_EFFECTS_SCOPE_DOMAIN) ? set : clr);
printf(" NVM Subsystem SCOPE%s", (fsp & NVME_FID_SUPPORTED_EFFECTS_SCOPE_NSS) ? set : clr);
}
static void stdout_fid_support_effects_log(struct nvme_fid_supported_effects_log *fid_log,
const char *devname)
{
__u32 fid_effect;
int i, human = stdout_print_ops.flags & VERBOSE;
printf("FID Supports Effects Log for device: %s\n", devname);
printf("Admin Command Set\n");
for (i = 0; i < 256; i++) {
fid_effect = le32_to_cpu(fid_log->fid_support[i]);
if (fid_effect & NVME_FID_SUPPORTED_EFFECTS_FSUPP) {
printf("FID %02x -> Support Effects Log: %08x", i,
fid_effect);
if (human)
stdout_fid_support_effects_log_human(fid_effect);
printf("\n");
}
}
}
static void stdout_mi_cmd_support_effects_log_human(__u32 mi_cmd_support)
{
const char *set = "+";
const char *clr = "-";
__u16 csp;
printf(" CSUPP+");
printf(" UDCC%s", (mi_cmd_support & NVME_MI_CMD_SUPPORTED_EFFECTS_UDCC) ? set : clr);
printf(" NCC%s", (mi_cmd_support & NVME_MI_CMD_SUPPORTED_EFFECTS_NCC) ? set : clr);
printf(" NIC%s", (mi_cmd_support & NVME_MI_CMD_SUPPORTED_EFFECTS_NIC) ? set : clr);
printf(" CCC%s", (mi_cmd_support & NVME_MI_CMD_SUPPORTED_EFFECTS_CCC) ? set : clr);
csp = NVME_GET(mi_cmd_support, MI_CMD_SUPPORTED_EFFECTS_SCOPE);
printf(" NAMESPACE SCOPE%s", (csp & NVME_MI_CMD_SUPPORTED_EFFECTS_SCOPE_NS) ? set : clr);
printf(" CONTROLLER SCOPE%s", (csp & NVME_MI_CMD_SUPPORTED_EFFECTS_SCOPE_CTRL) ? set : clr);
printf(" NVM SET SCOPE%s", (csp & NVME_MI_CMD_SUPPORTED_EFFECTS_SCOPE_NVM_SET) ? set : clr);
printf(" ENDURANCE GROUP SCOPE%s", (csp & NVME_MI_CMD_SUPPORTED_EFFECTS_SCOPE_ENDGRP) ? set : clr);
printf(" DOMAIN SCOPE%s", (csp & NVME_MI_CMD_SUPPORTED_EFFECTS_SCOPE_DOMAIN) ? set : clr);
printf(" NVM Subsystem SCOPE%s", (csp & NVME_MI_CMD_SUPPORTED_EFFECTS_SCOPE_NSS) ? set : clr);
}
static void stdout_mi_cmd_support_effects_log(struct nvme_mi_cmd_supported_effects_log *mi_cmd_log,
const char *devname)
{
__u32 mi_cmd_effect;
int i, human = stdout_print_ops.flags & VERBOSE;
printf("MI Commands Support Effects Log for device: %s\n", devname);
printf("Admin Command Set\n");
for (i = 0; i < NVME_LOG_MI_CMD_SUPPORTED_EFFECTS_MAX; i++) {
mi_cmd_effect = le32_to_cpu(mi_cmd_log->mi_cmd_support[i]);
if (mi_cmd_effect & NVME_MI_CMD_SUPPORTED_EFFECTS_CSUPP) {
printf("MI CMD %02x -> Support Effects Log: %08x", i,
mi_cmd_effect);
if (human)
stdout_mi_cmd_support_effects_log_human(mi_cmd_effect);
printf("\n");
}
}
}
static void stdout_boot_part_log(void *bp_log, const char *devname,
__u32 size)
{
struct nvme_boot_partition *hdr = bp_log;
printf("Boot Partition Log for device: %s\n", devname);
printf("Log ID: %u\n", hdr->lid);
printf("Boot Partition Size: %u KiB\n",
NVME_BOOT_PARTITION_INFO_BPSZ(le32_to_cpu(hdr->bpinfo)));
printf("Active BPID: %u\n", NVME_BOOT_PARTITION_INFO_ABPID(le32_to_cpu(hdr->bpinfo)));
}
static const char *eomip_to_string(__u8 eomip)
{
const char *string;
switch (eomip) {
case NVME_PHY_RX_EOM_NOT_STARTED:
string = "Not Started";
break;
case NVME_PHY_RX_EOM_IN_PROGRESS:
string = "In Progress";
break;
case NVME_PHY_RX_EOM_COMPLETED:
string = "Completed";
break;
default:
string = "Unknown";
break;
}
return string;
}
static void stdout_phy_rx_eom_odp(uint8_t odp)
{
__u8 rsvd = NVME_EOM_ODP_RSVD(odp);
__u8 edfp = NVME_EOM_ODP_EDFP(odp);
__u8 pefp = NVME_EOM_ODP_PEFP(odp);
if (rsvd)
printf(" [7:2] : %#x\tReserved\n", rsvd);
printf(" [1:1] : %#x\tEye Data Field %sPresent\n",
edfp, edfp ? "" : "Not ");
printf(" [0:0] : %#x\tPrintable Eye Field %sPresent\n",
pefp, pefp ? "" : "Not ");
}
static void stdout_eom_printable_eye(struct nvme_eom_lane_desc *lane)
{
char *eye = (char *)lane->eye_desc;
int i, j;
for (i = 0; i < lane->nrows; i++) {
for (j = 0; j < lane->ncols; j++)
printf("%c", eye[i * lane->ncols + j]);
printf("\n");
}
}
static void stdout_phy_rx_eom_descs(struct nvme_phy_rx_eom_log *log)
{
void *p = log->descs;
int i;
for (i = 0; i < log->nd; i++) {
struct nvme_eom_lane_desc *desc = p;
printf("Measurement Status: %s\n",
desc->mstatus ? "Successful" : "Not Successful");
printf("Lane: %u\n", desc->lane);
printf("Eye: %u\n", desc->eye);
printf("Top: %u\n", le16_to_cpu(desc->top));
printf("Bottom: %u\n", le16_to_cpu(desc->bottom));
printf("Left: %u\n", le16_to_cpu(desc->left));
printf("Right: %u\n", le16_to_cpu(desc->right));
printf("Number of Rows: %u\n", le16_to_cpu(desc->nrows));
printf("Number of Columns: %u\n", le16_to_cpu(desc->ncols));
printf("Eye Data Length: %u\n", le16_to_cpu(desc->edlen));
if (NVME_EOM_ODP_PEFP(log->odp))
stdout_eom_printable_eye(desc);
/* Eye Data field is vendor specific */
p += log->dsize;
}
}
static void stdout_phy_rx_eom_log(struct nvme_phy_rx_eom_log *log, __u16 controller)
{
int human = stdout_print_ops.flags & VERBOSE;
printf("Physical Interface Receiver Eye Opening Measurement Log for controller ID: %u\n", controller);
printf("Log ID: %u\n", log->lid);
printf("EOM In Progress: %s\n", eomip_to_string(log->eomip));
printf("Header Size: %u\n", le16_to_cpu(log->hsize));
printf("Result Size: %u\n", le32_to_cpu(log->rsize));
printf("EOM Data Generation Number: %u\n", log->eomdgn);
printf("Log Revision: %u\n", log->lr);
printf("Optional Data Present: %u\n", log->odp);
if (human)
stdout_phy_rx_eom_odp(log->odp);
printf("Lanes: %u\n", log->lanes);
printf("Eyes Per Lane: %u\n", log->epl);
printf("Log Specific Parameter Field Copy: %u\n", log->lspfc);
printf("Link Information: %u\n", log->li);
printf("Log Specific Identifier Copy: %u\n", le16_to_cpu(log->lsic));
printf("Descriptor Size: %u\n", le32_to_cpu(log->dsize));
printf("Number of Descriptors: %u\n", le16_to_cpu(log->nd));
printf("Maximum Top Bottom: %u\n", le16_to_cpu(log->maxtb));
printf("Maximum Left Right: %u\n", le16_to_cpu(log->maxlr));
printf("Estimated Time for Good Quality: %u\n", le16_to_cpu(log->etgood));
printf("Estimated Time for Better Quality: %u\n", le16_to_cpu(log->etbetter));
printf("Estimated Time for Best Quality: %u\n", le16_to_cpu(log->etbest));
if (log->eomip == NVME_PHY_RX_EOM_COMPLETED)
stdout_phy_rx_eom_descs(log);
}
static void stdout_media_unit_stat_log(struct nvme_media_unit_stat_log *mus_log)
{
int i;
int nmu = le16_to_cpu(mus_log->nmu);
printf("Number of Media Unit Status Descriptors: %u\n", nmu);
printf("Number of Channels: %u\n", le16_to_cpu(mus_log->cchans));
printf("Selected Configuration: %u\n", le16_to_cpu(mus_log->sel_config));
for (i = 0; i < nmu; i++) {
printf("Media Unit Status Descriptor: %u\n", i);
printf("Media Unit Identifier: %u\n",
le16_to_cpu(mus_log->mus_desc[i].muid));
printf("Domain Identifier: %u\n",
le16_to_cpu(mus_log->mus_desc[i].domainid));
printf("Endurance Group Identifier: %u\n",
le16_to_cpu(mus_log->mus_desc[i].endgid));
printf("NVM Set Identifier: %u\n",
le16_to_cpu(mus_log->mus_desc[i].nvmsetid));
printf("Capacity Adjustment Factor: %u\n",
le16_to_cpu(mus_log->mus_desc[i].cap_adj_fctr));
printf("Available Spare: %u\n", mus_log->mus_desc[i].avl_spare);
printf("Percentage Used: %u\n", mus_log->mus_desc[i].percent_used);
printf("Number of Channels: %u\n", mus_log->mus_desc[i].mucs);
printf("Channel Identifiers Offset: %u\n", mus_log->mus_desc[i].cio);
}
}
static void stdout_fdp_config_fdpa(uint8_t fdpa)
{
__u8 valid = NVME_GET(fdpa, FDP_CONFIG_FDPA_VALID);
__u8 rsvd = (fdpa >> 5) & 0x3;
__u8 fdpvwc = NVME_GET(fdpa, FDP_CONFIG_FDPA_FDPVWC);
__u8 rgif = NVME_GET(fdpa, FDP_CONFIG_FDPA_RGIF);
printf(" [7:7] : %#x\tFDP Configuration %sValid\n",
valid, valid ? "" : "Not ");
if (rsvd)
printf(" [6:5] : %#x\tReserved\n", rsvd);
printf(" [4:4] : %#x\tFDP Volatile Write Cache %sPresent\n",
fdpvwc, fdpvwc ? "" : "Not ");
printf(" [3:0] : %#x\tReclaim Group Identifier Format\n", rgif);
}
static void stdout_fdp_configs(struct nvme_fdp_config_log *log, size_t len)
{
void *p = log->configs;
int human = stdout_print_ops.flags & VERBOSE;
uint16_t n;
n = le16_to_cpu(log->n) + 1;
for (int i = 0; i < n; i++) {
struct nvme_fdp_config_desc *config = p;
printf("FDP Attributes: %#x\n", config->fdpa);
if (human)
stdout_fdp_config_fdpa(config->fdpa);
printf("Vendor Specific Size: %u\n", config->vss);
printf("Number of Reclaim Groups: %"PRIu32"\n", le32_to_cpu(config->nrg));
printf("Number of Reclaim Unit Handles: %"PRIu16"\n", le16_to_cpu(config->nruh));
printf("Number of Namespaces Supported: %"PRIu32"\n", le32_to_cpu(config->nnss));
printf("Reclaim Unit Nominal Size: %"PRIu64"\n", le64_to_cpu(config->runs));
printf("Estimated Reclaim Unit Time Limit: %"PRIu32"\n", le32_to_cpu(config->erutl));
printf("Reclaim Unit Handle List:\n");
for (int j = 0; j < le16_to_cpu(config->nruh); j++) {
struct nvme_fdp_ruh_desc *ruh = &config->ruhs[j];
printf(" [%d]: %s\n", j, ruh->ruht == NVME_FDP_RUHT_INITIALLY_ISOLATED ? "Initially Isolated" : "Persistently Isolated");
}
p += config->size;
}
}
static void stdout_fdp_usage(struct nvme_fdp_ruhu_log *log, size_t len)
{
uint16_t nruh = le16_to_cpu(log->nruh);
for (int i = 0; i < nruh; i++) {
struct nvme_fdp_ruhu_desc *ruhu = &log->ruhus[i];
printf("Reclaim Unit Handle %d Attributes: %#"PRIx8" (%s)\n", i, ruhu->ruha,
ruhu->ruha == 0x0 ? "Unused" : (
ruhu->ruha == 0x1 ? "Host Specified" : (
ruhu->ruha == 0x2 ? "Controller Specified" : "Unknown")));
}
}
static void stdout_fdp_stats(struct nvme_fdp_stats_log *log)
{
printf("Host Bytes with Metadata Written (HBMW): %s\n",
uint128_t_to_l10n_string(le128_to_cpu(log->hbmw)));
printf("Media Bytes with Metadata Written (MBMW): %s\n",
uint128_t_to_l10n_string(le128_to_cpu(log->mbmw)));
printf("Media Bytes Erased (MBE): %s\n",
uint128_t_to_l10n_string(le128_to_cpu(log->mbe)));
}
static void stdout_fdp_events(struct nvme_fdp_events_log *log)
{
struct tm *tm;
char buffer[320];
time_t ts;
uint32_t n = le32_to_cpu(log->n);
for (unsigned int i = 0; i < n; i++) {
struct nvme_fdp_event *event = &log->events[i];
ts = int48_to_long(event->ts.timestamp) / 1000;
tm = localtime(&ts);
printf("Event[%u]\n", i);
printf(" Event Type: %#"PRIx8" (%s)\n", event->type,
nvme_fdp_event_to_string(event->type));
printf(" Event Timestamp: %"PRIu64" (%s)\n", int48_to_long(event->ts.timestamp),
strftime(buffer, sizeof(buffer), "%c %Z", tm) ? buffer : "-");
if (event->flags & NVME_FDP_EVENT_F_PIV)
printf(" Placement Identifier (PID): %#"PRIx16"\n",
le16_to_cpu(event->pid));
if (event->flags & NVME_FDP_EVENT_F_NSIDV)
printf(" Namespace Identifier (NSID): %"PRIu32"\n", le32_to_cpu(event->nsid));
if (event->type == NVME_FDP_EVENT_REALLOC) {
struct nvme_fdp_event_realloc *mr;
mr = (struct nvme_fdp_event_realloc *)&event->type_specific;
printf(" Number of LBAs Moved (NLBAM): %"PRIu16"\n", le16_to_cpu(mr->nlbam));
if (mr->flags & NVME_FDP_EVENT_REALLOC_F_LBAV)
printf(" Logical Block Address (LBA): %#"PRIx64"\n",
le64_to_cpu(mr->lba));
}
if (event->flags & NVME_FDP_EVENT_F_LV) {
printf(" Reclaim Group Identifier: %"PRIu16"\n", le16_to_cpu(event->rgid));
printf(" Reclaim Unit Handle Identifier %"PRIu8"\n", event->ruhid);
}
printf("\n");
}
}
static void stdout_fdp_ruh_status(struct nvme_fdp_ruh_status *status, size_t len)
{
uint16_t nruhsd = le16_to_cpu(status->nruhsd);
for (unsigned int i = 0; i < nruhsd; i++) {
struct nvme_fdp_ruh_status_desc *ruhs = &status->ruhss[i];
printf("Placement Identifier %"PRIu16"; Reclaim Unit Handle Identifier %"PRIu16"\n",
le16_to_cpu(ruhs->pid), le16_to_cpu(ruhs->ruhid));
printf(" Estimated Active Reclaim Unit Time Remaining (EARUTR): %"PRIu32"\n",
le32_to_cpu(ruhs->earutr));
printf(" Reclaim Unit Available Media Writes (RUAMW): %"PRIu64"\n",
le64_to_cpu(ruhs->ruamw));
printf("\n");
}
}
static void stdout_supported_cap_config_log(struct nvme_supported_cap_config_list_log *cap)
{
struct nvme_end_grp_chan_desc *chan_desc;
int i, j, k, l, m, sccn, egcn, egsets, egchans, chmus;
sccn = cap->sccn;
printf("Number of Supported Capacity Configurations: %u\n", sccn);
for (i = 0; i < sccn; i++) {
printf("Capacity Configuration Descriptor: %u\n", i);
printf("Capacity Configuration Identifier: %u\n",
le16_to_cpu(cap->cap_config_desc[i].cap_config_id));
printf("Domain Identifier: %u\n",
le16_to_cpu(cap->cap_config_desc[i].domainid));
egcn = le16_to_cpu(cap->cap_config_desc[i].egcn);
printf("Number of Endurance Group Configuration Descriptors: %u\n", egcn);
for (j = 0; j < egcn; j++) {
printf("Endurance Group Identifier: %u\n",
le16_to_cpu(cap->cap_config_desc[i].egcd[j].endgid));
printf("Capacity Adjustment Factor: %u\n",
le16_to_cpu(cap->cap_config_desc[i].egcd[j].cap_adj_factor));
printf("Total Endurance Group Capacity: %s\n",
uint128_t_to_l10n_string(le128_to_cpu(
cap->cap_config_desc[i].egcd[j].tegcap)));
printf("Spare Endurance Group Capacity: %s\n",
uint128_t_to_l10n_string(le128_to_cpu(
cap->cap_config_desc[i].egcd[j].segcap)));
printf("Endurance Estimate: %s\n",
uint128_t_to_l10n_string(le128_to_cpu(
cap->cap_config_desc[i].egcd[j].end_est)));
egsets = le16_to_cpu(cap->cap_config_desc[i].egcd[j].egsets);
printf("Number of NVM Sets: %u\n", egsets);
for (k = 0; k < egsets; k++)
printf("NVM Set %d Identifier: %u\n", i,
le16_to_cpu(cap->cap_config_desc[i].egcd[j].nvmsetid[k]));
chan_desc = (struct nvme_end_grp_chan_desc *)
&cap->cap_config_desc[i].egcd[j].nvmsetid[egsets];
egchans = le16_to_cpu(chan_desc->egchans);
printf("Number of Channels: %u\n", egchans);
for (l = 0; l < egchans; l++) {
printf("Channel Identifier: %u\n",
le16_to_cpu(chan_desc->chan_config_desc[l].chanid));
chmus = le16_to_cpu(chan_desc->chan_config_desc[l].chmus);
printf("Number of Channel Media Units: %u\n", chmus);
for (m = 0; m < chmus; m++) {
printf("Media Unit Identifier: %u\n",