sbin/nvmectl/logpage.c

1.7    nonaka /*	$NetBSD: logpage.c,v 1.7 2018/04/18 10:11:44 nonaka Exp $	*/
1.1    nonaka
1.1    nonaka /*-
1.6    nonaka  * SPDX-License-Identifier: BSD-2-Clause-FreeBSD
1.6    nonaka  *
1.1    nonaka  * Copyright (c) 2013 EMC Corp.
1.1    nonaka  * All rights reserved.
1.1    nonaka  *
1.1    nonaka  * Copyright (C) 2012-2013 Intel Corporation
1.1    nonaka  * All rights reserved.
1.1    nonaka  *
1.1    nonaka  * Redistribution and use in source and binary forms, with or without
1.1    nonaka  * modification, are permitted provided that the following conditions
1.1    nonaka  * are met:
1.1    nonaka  * 1. Redistributions of source code must retain the above copyright
1.1    nonaka  *    notice, this list of conditions and the following disclaimer.
1.1    nonaka  * 2. Redistributions in binary form must reproduce the above copyright
1.1    nonaka  *    notice, this list of conditions and the following disclaimer in the
1.1    nonaka  *    documentation and/or other materials provided with the distribution.
1.1    nonaka  *
1.1    nonaka  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
1.1    nonaka  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1    nonaka  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1    nonaka  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
1.1    nonaka  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1    nonaka  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1    nonaka  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1    nonaka  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1    nonaka  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1    nonaka  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1    nonaka  * SUCH DAMAGE.
1.1    nonaka  */
1.1    nonaka
1.1    nonaka #include <sys/cdefs.h>
1.1    nonaka #ifndef lint
1.7    nonaka __RCSID("$NetBSD: logpage.c,v 1.7 2018/04/18 10:11:44 nonaka Exp $");
1.1    nonaka #if 0
1.7    nonaka __FBSDID("$FreeBSD: head/sbin/nvmecontrol/logpage.c 329824 2018-02-22 13:32:31Z wma $");
1.1    nonaka #endif
1.1    nonaka #endif
1.1    nonaka
1.1    nonaka #include <sys/param.h>
1.1    nonaka #include <sys/ioccom.h>
1.4    nonaka #include <sys/endian.h>
1.1    nonaka
1.1    nonaka #include <ctype.h>
1.1    nonaka #include <err.h>
1.1    nonaka #include <fcntl.h>
1.1    nonaka #include <stdbool.h>
1.1    nonaka #include <stddef.h>
1.1    nonaka #include <stdio.h>
1.1    nonaka #include <stdlib.h>
1.1    nonaka #include <string.h>
1.1    nonaka #include <unistd.h>
1.1    nonaka
1.1    nonaka #include "nvmectl.h"
1.1    nonaka
1.1    nonaka #define DEFAULT_SIZE	(4096)
1.1    nonaka #define MAX_FW_SLOTS	(7)
1.1    nonaka
1.6    nonaka typedef void (*print_fn_t)(const struct nvm_identify_controller *cdata, void *buf,
1.6    nonaka     uint32_t size);
1.1    nonaka
1.4    nonaka struct kv_name {
1.4    nonaka 	uint32_t key;
1.4    nonaka 	const char *name;
1.4    nonaka };
1.4    nonaka
1.4    nonaka static const char *
1.4    nonaka kv_lookup(const struct kv_name *kv, size_t kv_count, uint32_t key)
1.4    nonaka {
1.4    nonaka 	static char bad[32];
1.4    nonaka 	size_t i;
1.4    nonaka
1.4    nonaka 	for (i = 0; i < kv_count; i++, kv++)
1.4    nonaka 		if (kv->key == key)
1.4    nonaka 			return kv->name;
1.4    nonaka 	snprintf(bad, sizeof(bad), "Attribute %#x", key);
1.4    nonaka 	return bad;
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.6    nonaka print_log_hex(const struct nvm_identify_controller *cdata __unused, void *data,
1.6    nonaka     uint32_t length)
1.4    nonaka {
1.6    nonaka 	print_hex(data, length);
1.4    nonaka }
1.4    nonaka
1.6    nonaka static void
1.6    nonaka print_bin(const struct nvm_identify_controller *cdata __unused, void *data,
1.6    nonaka     uint32_t length)
1.4    nonaka {
1.6    nonaka 	write(STDOUT_FILENO, data, length);
1.4    nonaka }
1.4    nonaka
1.1    nonaka static void *
1.1    nonaka get_log_buffer(uint32_t size)
1.1    nonaka {
1.1    nonaka 	void	*buf;
1.1    nonaka
1.1    nonaka 	if ((buf = malloc(size)) == NULL)
1.1    nonaka 		errx(1, "unable to malloc %u bytes", size);
1.1    nonaka
1.1    nonaka 	memset(buf, 0, size);
1.1    nonaka 	return (buf);
1.1    nonaka }
1.1    nonaka
1.1    nonaka void
1.1    nonaka read_logpage(int fd, uint8_t log_page, int nsid, void *payload,
1.1    nonaka     uint32_t payload_size)
1.1    nonaka {
1.1    nonaka 	struct nvme_pt_command	pt;
1.1    nonaka
1.1    nonaka 	memset(&pt, 0, sizeof(pt));
1.1    nonaka 	pt.cmd.opcode = NVM_ADMIN_GET_LOG_PG;
1.1    nonaka 	pt.cmd.nsid = nsid;
1.1    nonaka 	pt.cmd.cdw10 = ((payload_size/sizeof(uint32_t)) - 1) << 16;
1.1    nonaka 	pt.cmd.cdw10 |= log_page;
1.1    nonaka 	pt.buf = payload;
1.1    nonaka 	pt.len = payload_size;
1.1    nonaka 	pt.is_read = 1;
1.1    nonaka
1.1    nonaka 	if (ioctl(fd, NVME_PASSTHROUGH_CMD, &pt) < 0)
1.1    nonaka 		err(1, "get log page request failed");
1.1    nonaka
1.1    nonaka 	if (nvme_completion_is_error(&pt.cpl))
1.1    nonaka 		errx(1, "get log page request returned error");
1.1    nonaka }
1.1    nonaka
1.1    nonaka static void
1.7    nonaka nvme_error_information_entry_swapbytes(struct nvme_error_information_entry *e)
1.7    nonaka {
1.7    nonaka #if _BYTE_ORDER != _LITTLE_ENDIAN
1.7    nonaka 	e->error_count = le64toh(e->error_count);
1.7    nonaka 	e->sqid = le16toh(e->sqid);
1.7    nonaka 	e->cid = le16toh(e->cid);
1.7    nonaka 	e->status = le16toh(e->status);
1.7    nonaka 	e->error_location = le16toh(e->error_location);
1.7    nonaka 	e->lba = le64toh(e->lba);
1.7    nonaka 	e->nsid = le32toh(e->nsid);
1.7    nonaka 	e->command_specific = le64toh(e->command_specific);
1.7    nonaka #endif
1.7    nonaka }
1.7    nonaka
1.7    nonaka static void
1.6    nonaka print_log_error(const struct nvm_identify_controller *cdata __unused, void *buf,
1.6    nonaka     uint32_t size)
1.1    nonaka {
1.1    nonaka 	int					i, nentries;
1.1    nonaka 	struct nvme_error_information_entry	*entry = buf;
1.1    nonaka
1.7    nonaka 	/* Convert data to host endian */
1.7    nonaka 	nvme_error_information_entry_swapbytes(entry);
1.7    nonaka
1.1    nonaka 	printf("Error Information Log\n");
1.1    nonaka 	printf("=====================\n");
1.1    nonaka
1.1    nonaka 	if (entry->error_count == 0) {
1.1    nonaka 		printf("No error entries found\n");
1.1    nonaka 		return;
1.1    nonaka 	}
1.1    nonaka
1.1    nonaka 	nentries = size/sizeof(struct nvme_error_information_entry);
1.1    nonaka 	for (i = 0; i < nentries; i++, entry++) {
1.1    nonaka 		if (entry->error_count == 0)
1.1    nonaka 			break;
1.1    nonaka
1.1    nonaka 		printf("Entry %02d\n", i + 1);
1.1    nonaka 		printf("=========\n");
1.1    nonaka 		printf(" Error count:           %ju\n", entry->error_count);
1.1    nonaka 		printf(" Submission queue ID:   %u\n", entry->sqid);
1.1    nonaka 		printf(" Command ID:            %u\n", entry->cid);
1.1    nonaka 		/* TODO: Export nvme_status_string structures from kernel? */
1.1    nonaka 		printf(" Status:\n");
1.1    nonaka 		printf("  Phase tag:            %d\n",
1.1    nonaka 		    (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_PHASE));
1.1    nonaka 		printf("  Status code:          %d\n",
1.1    nonaka 		    (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_SC_MASK));
1.1    nonaka 		printf("  Status code type:     %d\n",
1.1    nonaka 		    (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_SCT_MASK));
1.1    nonaka 		printf("  More:                 %d\n",
1.1    nonaka 		    (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_M));
1.1    nonaka 		printf("  DNR:                  %d\n",
1.1    nonaka 		    (uint16_t)__SHIFTOUT(entry->status, NVME_CQE_DNR));
1.1    nonaka 		printf(" Error location:        %u\n", entry->error_location);
1.1    nonaka 		printf(" LBA:                   %ju\n", entry->lba);
1.1    nonaka 		printf(" Namespace ID:          %u\n", entry->nsid);
1.1    nonaka 		printf(" Vendor specific info:  %u\n", entry->vendor_specific);
1.1    nonaka 		printf(" Command specific info: %ju\n",
1.1    nonaka 		    entry->command_specific);
1.1    nonaka 	}
1.1    nonaka }
1.1    nonaka
1.1    nonaka static void
1.4    nonaka print_temp(uint16_t t)
1.4    nonaka {
1.4    nonaka 	printf("%u K, %2.2f C, %3.2f F\n", t, (float)t - 273.15,
1.4    nonaka 	    (float)t * 9 / 5 - 459.67);
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.7    nonaka nvme_health_information_page_swapbytes(struct nvme_health_information_page *e)
1.7    nonaka {
1.7    nonaka #if _BYTE_ORDER != _LITTLE_ENDIAN
1.7    nonaka 	u_int i;
1.7    nonaka
1.7    nonaka 	e->composite_temperature = le16toh(e->composite_temperature);
1.7    nonaka 	nvme_le128toh(e->data_units_read);
1.7    nonaka 	nvme_le128toh(e->data_units_written);
1.7    nonaka 	nvme_le128toh(e->host_read_commands);
1.7    nonaka 	nvme_le128toh(e->host_write_commands);
1.7    nonaka 	nvme_le128toh(e->controller_busy_time);
1.7    nonaka 	nvme_le128toh(e->power_cycles);
1.7    nonaka 	nvme_le128toh(e->power_on_hours);
1.7    nonaka 	nvme_le128toh(e->unsafe_shutdowns);
1.7    nonaka 	nvme_le128toh(e->media_errors);
1.7    nonaka 	nvme_le128toh(e->num_error_info_log_entries);
1.7    nonaka 	e->warning_temp_time = le32toh(e->warning_temp_time);
1.7    nonaka 	e->error_temp_time = le32toh(e->error_temp_time);
1.7    nonaka 	for (i = 0; i < __arraycount(e->temp_sensor); i++)
1.7    nonaka 		e->temp_sensor[i] = le16toh(e->temp_sensor[i]);
1.7    nonaka #endif
1.7    nonaka }
1.7    nonaka
1.7    nonaka static void
1.6    nonaka print_log_health(const struct nvm_identify_controller *cdata __unused, void *buf,
1.6    nonaka     uint32_t size __unused)
1.1    nonaka {
1.1    nonaka 	struct nvme_health_information_page *health = buf;
1.7    nonaka 	u_int i;
1.7    nonaka
1.7    nonaka 	/* Convert data to host endian */
1.7    nonaka 	nvme_health_information_page_swapbytes(health);
1.1    nonaka
1.1    nonaka 	printf("SMART/Health Information Log\n");
1.1    nonaka 	printf("============================\n");
1.1    nonaka
1.1    nonaka 	printf("Critical Warning State:         0x%02x\n",
1.1    nonaka 	    health->critical_warning);
1.1    nonaka 	printf(" Available spare:               %d\n",
1.1    nonaka 	    (uint8_t)__SHIFTOUT(health->critical_warning,
1.1    nonaka 	      NVME_HEALTH_PAGE_CW_AVAIL_SPARE));
1.1    nonaka 	printf(" Temperature:                   %d\n",
1.1    nonaka 	    (uint8_t)__SHIFTOUT(health->critical_warning,
1.1    nonaka 	      NVME_HEALTH_PAGE_CW_TEMPERTURE));
1.1    nonaka 	printf(" Device reliability:            %d\n",
1.1    nonaka 	    (uint8_t)__SHIFTOUT(health->critical_warning,
1.1    nonaka 	      NVME_HEALTH_PAGE_CW_DEVICE_RELIABLITY));
1.1    nonaka 	printf(" Read only:                     %d\n",
1.1    nonaka 	    (uint8_t)__SHIFTOUT(health->critical_warning,
1.1    nonaka 	      NVME_HEALTH_PAGE_CW_READ_ONLY));
1.1    nonaka 	printf(" Volatile memory backup:        %d\n",
1.1    nonaka 	    (uint8_t)__SHIFTOUT(health->critical_warning,
1.1    nonaka 	      NVME_HEALTH_PAGE_CW_VOLATILE_MEMORY_BACKUP));
1.4    nonaka 	printf("Temperature:                    ");
1.4    nonaka 	print_temp(health->composite_temperature);
1.1    nonaka 	printf("Available spare:                %u\n",
1.1    nonaka 	    health->available_spare);
1.1    nonaka 	printf("Available spare threshold:      %u\n",
1.1    nonaka 	    health->available_spare_threshold);
1.1    nonaka 	printf("Percentage used:                %u\n",
1.1    nonaka 	    health->percentage_used);
1.1    nonaka
1.4    nonaka 	print_bignum("Data units (512 byte) read:", health->data_units_read, "");
1.4    nonaka 	print_bignum("Data units (512 byte) written:", health->data_units_written,
1.4    nonaka 	    "");
1.4    nonaka 	print_bignum("Host read commands:", health->host_read_commands, "");
1.4    nonaka 	print_bignum("Host write commands:", health->host_write_commands, "");
1.4    nonaka 	print_bignum("Controller busy time (minutes):", health->controller_busy_time,
1.4    nonaka 	    "");
1.4    nonaka 	print_bignum("Power cycles:", health->power_cycles, "");
1.4    nonaka 	print_bignum("Power on hours:", health->power_on_hours, "");
1.4    nonaka 	print_bignum("Unsafe shutdowns:", health->unsafe_shutdowns, "");
1.4    nonaka 	print_bignum("Media errors:", health->media_errors, "");
1.3    nonaka 	print_bignum("No. error info log entries:",
1.3    nonaka 	    health->num_error_info_log_entries, "");
1.4    nonaka
1.4    nonaka 	printf("Warning Temp Composite Time:    %d\n", health->warning_temp_time);
1.4    nonaka 	printf("Error Temp Composite Time:      %d\n", health->error_temp_time);
1.7    nonaka 	for (i = 0; i < __arraycount(health->temp_sensor); i++) {
1.4    nonaka 		if (health->temp_sensor[i] == 0)
1.4    nonaka 			continue;
1.4    nonaka 		printf("Temperature Sensor %d:           ", i + 1);
1.4    nonaka 		print_temp(health->temp_sensor[i]);
1.4    nonaka 	}
1.1    nonaka }
1.1    nonaka
1.1    nonaka static void
1.7    nonaka nvme_firmware_page_swapbytes(struct nvme_firmware_page *e)
1.7    nonaka {
1.7    nonaka #if _BYTE_ORDER != _LITTLE_ENDIAN
1.7    nonaka 	u_int i;
1.7    nonaka
1.7    nonaka 	for (i = 0; i < __arraycount(e->revision); i++)
1.7    nonaka 		e->revision[i] = le64toh(e->revision[i]);
1.7    nonaka #endif
1.7    nonaka }
1.7    nonaka
1.7    nonaka static void
1.6    nonaka print_log_firmware(const struct nvm_identify_controller *cdata, void *buf,
1.6    nonaka     uint32_t size __unused)
1.1    nonaka {
1.6    nonaka 	u_int				i, slots;
1.1    nonaka 	const char			*status;
1.1    nonaka 	struct nvme_firmware_page	*fw = buf;
1.1    nonaka
1.7    nonaka 	/* Convert data to host endian */
1.7    nonaka 	nvme_firmware_page_swapbytes(fw);
1.7    nonaka
1.1    nonaka 	printf("Firmware Slot Log\n");
1.1    nonaka 	printf("=================\n");
1.1    nonaka
1.6    nonaka 	if (!(cdata->oacs & NVME_ID_CTRLR_OACS_FW))
1.6    nonaka 		slots = 1;
1.6    nonaka 	else
1.6    nonaka 		slots = MIN(__SHIFTOUT(cdata->frmw, NVME_ID_CTRLR_FRMW_NSLOT),
1.6    nonaka 		    MAX_FW_SLOTS);
1.6    nonaka
1.6    nonaka 	for (i = 0; i < slots; i++) {
1.1    nonaka 		printf("Slot %d: ", i + 1);
1.1    nonaka 		if (__SHIFTOUT(fw->afi, NVME_FW_PAGE_AFI_SLOT) == i + 1)
1.1    nonaka 			status = "  Active";
1.1    nonaka 		else
1.1    nonaka 			status = "Inactive";
1.1    nonaka
1.1    nonaka 		if (fw->revision[i] == 0LLU)
1.1    nonaka 			printf("Empty\n");
1.1    nonaka 		else
1.1    nonaka 			if (isprint(*(uint8_t *)&fw->revision[i]))
1.1    nonaka 				printf("[%s] %.8s\n", status,
1.1    nonaka 				    (char *)&fw->revision[i]);
1.1    nonaka 			else
1.1    nonaka 				printf("[%s] %016jx\n", status,
1.1    nonaka 				    fw->revision[i]);
1.1    nonaka 	}
1.1    nonaka }
1.1    nonaka
1.4    nonaka /*
1.4    nonaka  * Intel specific log pages from
1.4    nonaka  * http://www.intel.com/content/dam/www/public/us/en/documents/product-specifications/ssd-dc-p3700-spec.pdf
1.4    nonaka  *
1.4    nonaka  * Though the version as of this date has a typo for the size of log page 0xca,
1.4    nonaka  * offset 147: it is only 1 byte, not 6.
1.4    nonaka  */
1.4    nonaka static void
1.7    nonaka intel_log_temp_stats_swapbytes(struct intel_log_temp_stats *e)
1.7    nonaka {
1.7    nonaka #if _BYTE_ORDER != _LITTLE_ENDIAN
1.7    nonaka 	e->current = le64toh(e->current);
1.7    nonaka 	e->overtemp_flag_last = le64toh(e->overtemp_flag_last);
1.7    nonaka 	e->overtemp_flag_life = le64toh(e->overtemp_flag_life);
1.7    nonaka 	e->max_temp = le64toh(e->max_temp);
1.7    nonaka 	e->min_temp = le64toh(e->min_temp);
1.7    nonaka 	e->max_oper_temp = le64toh(e->max_oper_temp);
1.7    nonaka 	e->min_oper_temp = le64toh(e->min_oper_temp);
1.7    nonaka 	e->est_offset = le64toh(e->est_offset);
1.7    nonaka #endif
1.7    nonaka }
1.7    nonaka
1.7    nonaka static void
1.6    nonaka print_intel_temp_stats(const struct nvm_identify_controller *cdata __unused,
1.6    nonaka     void *buf, uint32_t size __unused)
1.4    nonaka {
1.4    nonaka 	struct intel_log_temp_stats	*temp = buf;
1.4    nonaka
1.7    nonaka 	/* Convert data to host endian */
1.7    nonaka 	intel_log_temp_stats_swapbytes(temp);
1.7    nonaka
1.4    nonaka 	printf("Intel Temperature Log\n");
1.4    nonaka 	printf("=====================\n");
1.4    nonaka
1.4    nonaka 	printf("Current:                        ");
1.4    nonaka 	print_temp(temp->current);
1.4    nonaka 	printf("Overtemp Last Flags             %#jx\n",
1.4    nonaka 	    (uintmax_t)temp->overtemp_flag_last);
1.4    nonaka 	printf("Overtemp Lifetime Flags         %#jx\n",
1.4    nonaka 	    (uintmax_t)temp->overtemp_flag_life);
1.4    nonaka 	printf("Max Temperature                 ");
1.4    nonaka 	print_temp(temp->max_temp);
1.4    nonaka 	printf("Min Temperature                 ");
1.4    nonaka 	print_temp(temp->min_temp);
1.4    nonaka 	printf("Max Operating Temperature       ");
1.4    nonaka 	print_temp(temp->max_oper_temp);
1.4    nonaka 	printf("Min Operating Temperature       ");
1.4    nonaka 	print_temp(temp->min_oper_temp);
1.4    nonaka 	printf("Estimated Temperature Offset:   %ju C/K\n",
1.4    nonaka 	    (uintmax_t)temp->est_offset);
1.4    nonaka }
1.4    nonaka
1.4    nonaka /*
1.4    nonaka  * Format from Table 22, section 5.7 IO Command Latency Statistics.
1.4    nonaka  * Read and write stats pages have identical encoding.
1.4    nonaka  */
1.4    nonaka static void
1.6    nonaka print_intel_read_write_lat_log(const struct nvm_identify_controller *cdata __unused,
1.6    nonaka     void *buf, uint32_t size __unused)
1.4    nonaka {
1.4    nonaka 	const char *walker = buf;
1.4    nonaka 	int i;
1.4    nonaka
1.4    nonaka 	printf("Major:                         %d\n", le16dec(walker + 0));
1.4    nonaka 	printf("Minor:                         %d\n", le16dec(walker + 2));
1.4    nonaka 	for (i = 0; i < 32; i++)
1.4    nonaka 		printf("%4dus-%4dus:                 %ju\n", i * 32, (i + 1) * 32,
1.4    nonaka 		    (uintmax_t)le32dec(walker + 4 + i * 4));
1.4    nonaka 	for (i = 1; i < 32; i++)
1.4    nonaka 		printf("%4dms-%4dms:                 %ju\n", i, i + 1,
1.4    nonaka 		    (uintmax_t)le32dec(walker + 132 + i * 4));
1.4    nonaka 	for (i = 1; i < 32; i++)
1.4    nonaka 		printf("%4dms-%4dms:                 %ju\n", i * 32, (i + 1) * 32,
1.4    nonaka 		    (uintmax_t)le32dec(walker + 256 + i * 4));
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.6    nonaka print_intel_read_lat_log(const struct nvm_identify_controller *cdata, void *buf,
1.6    nonaka     uint32_t size)
1.4    nonaka {
1.4    nonaka
1.4    nonaka 	printf("Intel Read Latency Log\n");
1.4    nonaka 	printf("======================\n");
1.6    nonaka 	print_intel_read_write_lat_log(cdata, buf, size);
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.6    nonaka print_intel_write_lat_log(const struct nvm_identify_controller *cdata, void *buf,
1.6    nonaka     uint32_t size)
1.4    nonaka {
1.4    nonaka
1.4    nonaka 	printf("Intel Write Latency Log\n");
1.4    nonaka 	printf("=======================\n");
1.6    nonaka 	print_intel_read_write_lat_log(cdata, buf, size);
1.4    nonaka }
1.4    nonaka
1.4    nonaka /*
1.4    nonaka  * Table 19. 5.4 SMART Attributes.
1.4    nonaka  * Samsung also implements this and some extra data not documented.
1.4    nonaka  */
1.4    nonaka static void
1.6    nonaka print_intel_add_smart(const struct nvm_identify_controller *cdata __unused,
1.6    nonaka     void *buf, uint32_t size __unused)
1.4    nonaka {
1.4    nonaka 	uint8_t *walker = buf;
1.4    nonaka 	uint8_t *end = walker + 150;
1.4    nonaka 	const char *name;
1.4    nonaka 	uint64_t raw;
1.4    nonaka 	uint8_t normalized;
1.4    nonaka
1.4    nonaka 	static struct kv_name kv[] = {
1.4    nonaka 		{ 0xab, "Program Fail Count" },
1.4    nonaka 		{ 0xac, "Erase Fail Count" },
1.4    nonaka 		{ 0xad, "Wear Leveling Count" },
1.4    nonaka 		{ 0xb8, "End to End Error Count" },
1.4    nonaka 		{ 0xc7, "CRC Error Count" },
1.4    nonaka 		{ 0xe2, "Timed: Media Wear" },
1.4    nonaka 		{ 0xe3, "Timed: Host Read %" },
1.4    nonaka 		{ 0xe4, "Timed: Elapsed Time" },
1.4    nonaka 		{ 0xea, "Thermal Throttle Status" },
1.4    nonaka 		{ 0xf0, "Retry Buffer Overflows" },
1.4    nonaka 		{ 0xf3, "PLL Lock Loss Count" },
1.4    nonaka 		{ 0xf4, "NAND Bytes Written" },
1.4    nonaka 		{ 0xf5, "Host Bytes Written" },
1.4    nonaka 	};
1.4    nonaka
1.4    nonaka 	printf("Additional SMART Data Log\n");
1.4    nonaka 	printf("=========================\n");
1.4    nonaka 	/*
1.4    nonaka 	 * walker[0] = Key
1.4    nonaka 	 * walker[1,2] = reserved
1.4    nonaka 	 * walker[3] = Normalized Value
1.4    nonaka 	 * walker[4] = reserved
1.4    nonaka 	 * walker[5..10] = Little Endian Raw value
1.4    nonaka 	 *	(or other represenations)
1.4    nonaka 	 * walker[11] = reserved
1.4    nonaka 	 */
1.4    nonaka 	while (walker < end) {
1.4    nonaka 		name = kv_lookup(kv, __arraycount(kv), *walker);
1.4    nonaka 		normalized = walker[3];
1.4    nonaka 		raw = le48dec(walker + 5);
1.4    nonaka 		switch (*walker){
1.4    nonaka 		case 0:
1.4    nonaka 			break;
1.4    nonaka 		case 0xad:
1.4    nonaka 			printf("%-32s: %3d min: %u max: %u ave: %u\n", name,
1.4    nonaka 			    normalized, le16dec(walker + 5), le16dec(walker + 7),
1.4    nonaka 			    le16dec(walker + 9));
1.4    nonaka 			break;
1.4    nonaka 		case 0xe2:
1.4    nonaka 			printf("%-32s: %3d %.3f%%\n", name, normalized, raw / 1024.0);
1.4    nonaka 			break;
1.4    nonaka 		case 0xea:
1.4    nonaka 			printf("%-32s: %3d %d%% %d times\n", name, normalized,
1.4    nonaka 			    walker[5], le32dec(walker+6));
1.4    nonaka 			break;
1.4    nonaka 		default:
1.4    nonaka 			printf("%-32s: %3d %ju\n", name, normalized, (uintmax_t)raw);
1.4    nonaka 			break;
1.4    nonaka 		}
1.4    nonaka 		walker += 12;
1.4    nonaka 	}
1.4    nonaka }
1.4    nonaka
1.4    nonaka /*
1.4    nonaka  * HGST's 0xc1 page. This is a grab bag of additional data. Please see
1.4    nonaka  * https://www.hgst.com/sites/default/files/resources/US_SN150_ProdManual.pdf
1.4    nonaka  * https://www.hgst.com/sites/default/files/resources/US_SN100_ProdManual.pdf
1.4    nonaka  * Appendix A for details
1.4    nonaka  */
1.4    nonaka
1.6    nonaka typedef void (*subprint_fn_t)(void *buf, uint16_t subtype, uint8_t res,
1.6    nonaka     uint32_t size);
1.4    nonaka
1.4    nonaka struct subpage_print {
1.4    nonaka 	uint16_t key;
1.4    nonaka 	subprint_fn_t fn;
1.4    nonaka };
1.4    nonaka
1.4    nonaka static void print_hgst_info_write_errors(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_read_errors(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_verify_errors(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_self_test(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_background_scan(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_erase_errors(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_erase_counts(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_temp_history(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_ssd_perf(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka static void print_hgst_info_firmware_load(void *, uint16_t, uint8_t, uint32_t);
1.4    nonaka
1.4    nonaka static struct subpage_print hgst_subpage[] = {
1.4    nonaka 	{ 0x02, print_hgst_info_write_errors },
1.4    nonaka 	{ 0x03, print_hgst_info_read_errors },
1.4    nonaka 	{ 0x05, print_hgst_info_verify_errors },
1.4    nonaka 	{ 0x10, print_hgst_info_self_test },
1.4    nonaka 	{ 0x15, print_hgst_info_background_scan },
1.4    nonaka 	{ 0x30, print_hgst_info_erase_errors },
1.4    nonaka 	{ 0x31, print_hgst_info_erase_counts },
1.4    nonaka 	{ 0x32, print_hgst_info_temp_history },
1.4    nonaka 	{ 0x37, print_hgst_info_ssd_perf },
1.4    nonaka 	{ 0x38, print_hgst_info_firmware_load },
1.4    nonaka };
1.4    nonaka
1.4    nonaka /* Print a subpage that is basically just key value pairs */
1.4    nonaka static void
1.4    nonaka print_hgst_info_subpage_gen(void *buf, uint16_t subtype __unused, uint32_t size,
1.4    nonaka     const struct kv_name *kv, size_t kv_count)
1.4    nonaka {
1.4    nonaka 	uint8_t *wsp, *esp;
1.4    nonaka 	uint16_t ptype;
1.4    nonaka 	uint8_t plen;
1.4    nonaka 	uint64_t param;
1.4    nonaka 	int i;
1.4    nonaka
1.4    nonaka 	wsp = buf;
1.4    nonaka 	esp = wsp + size;
1.4    nonaka 	while (wsp < esp) {
1.4    nonaka 		ptype = le16dec(wsp);
1.4    nonaka 		wsp += 2;
1.4    nonaka 		wsp++;			/* Flags, just ignore */
1.4    nonaka 		plen = *wsp++;
1.4    nonaka 		param = 0;
1.4    nonaka 		for (i = 0; i < plen; i++)
1.4    nonaka 			param |= (uint64_t)*wsp++ << (i * 8);
1.4    nonaka 		printf("  %-30s: %jd\n", kv_lookup(kv, kv_count, ptype),
1.4    nonaka 		    (uintmax_t)param);
1.4    nonaka 	}
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_write_errors(void *buf, uint16_t subtype, uint8_t res __unused,
1.4    nonaka     uint32_t size)
1.4    nonaka {
1.4    nonaka 	static const struct kv_name kv[] = {
1.4    nonaka 		{ 0x0000, "Corrected Without Delay" },
1.4    nonaka 		{ 0x0001, "Corrected Maybe Delayed" },
1.4    nonaka 		{ 0x0002, "Re-Writes" },
1.4    nonaka 		{ 0x0003, "Errors Corrected" },
1.4    nonaka 		{ 0x0004, "Correct Algorithm Used" },
1.4    nonaka 		{ 0x0005, "Bytes Processed" },
1.4    nonaka 		{ 0x0006, "Uncorrected Errors" },
1.4    nonaka 		{ 0x8000, "Flash Write Commands" },
1.4    nonaka 		{ 0x8001, "HGST Special" },
1.4    nonaka 	};
1.4    nonaka
1.4    nonaka 	printf("Write Errors Subpage:\n");
1.4    nonaka 	print_hgst_info_subpage_gen(buf, subtype, size, kv, __arraycount(kv));
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_read_errors(void *buf, uint16_t subtype, uint8_t res __unused,
1.4    nonaka     uint32_t size)
1.4    nonaka {
1.4    nonaka 	static const struct kv_name kv[] = {
1.4    nonaka 		{ 0x0000, "Corrected Without Delay" },
1.4    nonaka 		{ 0x0001, "Corrected Maybe Delayed" },
1.4    nonaka 		{ 0x0002, "Re-Reads" },
1.4    nonaka 		{ 0x0003, "Errors Corrected" },
1.4    nonaka 		{ 0x0004, "Correct Algorithm Used" },
1.4    nonaka 		{ 0x0005, "Bytes Processed" },
1.4    nonaka 		{ 0x0006, "Uncorrected Errors" },
1.4    nonaka 		{ 0x8000, "Flash Read Commands" },
1.4    nonaka 		{ 0x8001, "XOR Recovered" },
1.4    nonaka 		{ 0x8002, "Total Corrected Bits" },
1.4    nonaka 	};
1.4    nonaka
1.4    nonaka 	printf("Read Errors Subpage:\n");
1.4    nonaka 	print_hgst_info_subpage_gen(buf, subtype, size, kv, __arraycount(kv));
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_verify_errors(void *buf, uint16_t subtype, uint8_t res __unused,
1.4    nonaka     uint32_t size)
1.4    nonaka {
1.4    nonaka 	static const struct kv_name kv[] = {
1.4    nonaka 		{ 0x0000, "Corrected Without Delay" },
1.4    nonaka 		{ 0x0001, "Corrected Maybe Delayed" },
1.4    nonaka 		{ 0x0002, "Re-Reads" },
1.4    nonaka 		{ 0x0003, "Errors Corrected" },
1.4    nonaka 		{ 0x0004, "Correct Algorithm Used" },
1.4    nonaka 		{ 0x0005, "Bytes Processed" },
1.4    nonaka 		{ 0x0006, "Uncorrected Errors" },
1.4    nonaka 		{ 0x8000, "Commands Processed" },
1.4    nonaka 	};
1.4    nonaka
1.4    nonaka 	printf("Verify Errors Subpage:\n");
1.4    nonaka 	print_hgst_info_subpage_gen(buf, subtype, size, kv, __arraycount(kv));
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_self_test(void *buf, uint16_t subtype __unused, uint8_t res __unused,
1.4    nonaka     uint32_t size)
1.4    nonaka {
1.4    nonaka 	size_t i;
1.4    nonaka 	uint8_t *walker = buf;
1.4    nonaka 	uint16_t code, hrs;
1.4    nonaka 	uint32_t lba;
1.4    nonaka
1.4    nonaka 	printf("Self Test Subpage:\n");
1.4    nonaka 	for (i = 0; i < size / 20; i++) {	/* Each entry is 20 bytes */
1.4    nonaka 		code = le16dec(walker);
1.4    nonaka 		walker += 2;
1.4    nonaka 		walker++;			/* Ignore fixed flags */
1.4    nonaka 		if (*walker == 0)		/* Last entry is zero length */
1.4    nonaka 			break;
1.4    nonaka 		if (*walker++ != 0x10) {
1.4    nonaka 			printf("Bad length for self test report\n");
1.4    nonaka 			return;
1.4    nonaka 		}
1.4    nonaka 		printf("  %-30s: %d\n", "Recent Test", code);
1.4    nonaka 		printf("    %-28s: %#x\n", "Self-Test Results", *walker & 0xf);
1.4    nonaka 		printf("    %-28s: %#x\n", "Self-Test Code", (*walker >> 5) & 0x7);
1.4    nonaka 		walker++;
1.4    nonaka 		printf("    %-28s: %#x\n", "Self-Test Number", *walker++);
1.4    nonaka 		hrs = le16dec(walker);
1.4    nonaka 		walker += 2;
1.4    nonaka 		lba = le32dec(walker);
1.4    nonaka 		walker += 4;
1.4    nonaka 		printf("    %-28s: %u\n", "Total Power On Hrs", hrs);
1.4    nonaka 		printf("    %-28s: %#jx (%jd)\n", "LBA", (uintmax_t)lba,
1.4    nonaka 		    (uintmax_t)lba);
1.4    nonaka 		printf("    %-28s: %#x\n", "Sense Key", *walker++ & 0xf);
1.4    nonaka 		printf("    %-28s: %#x\n", "Additional Sense Code", *walker++);
1.4    nonaka 		printf("    %-28s: %#x\n", "Additional Sense Qualifier", *walker++);
1.4    nonaka 		printf("    %-28s: %#x\n", "Vendor Specific Detail", *walker++);
1.4    nonaka 	}
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_background_scan(void *buf, uint16_t subtype __unused,
1.4    nonaka     uint8_t res __unused, uint32_t size)
1.4    nonaka {
1.4    nonaka 	uint8_t *walker = buf;
1.4    nonaka 	uint8_t status;
1.4    nonaka 	uint16_t code, nscan, progress;
1.4    nonaka 	uint32_t pom, nand;
1.4    nonaka
1.4    nonaka 	printf("Background Media Scan Subpage:\n");
1.4    nonaka 	/* Decode the header */
1.4    nonaka 	code = le16dec(walker);
1.4    nonaka 	walker += 2;
1.4    nonaka 	walker++;			/* Ignore fixed flags */
1.4    nonaka 	if (*walker++ != 0x10) {
1.4    nonaka 		printf("Bad length for background scan header\n");
1.4    nonaka 		return;
1.4    nonaka 	}
1.4    nonaka 	if (code != 0) {
1.4    nonaka 		printf("Expceted code 0, found code %#x\n", code);
1.4    nonaka 		return;
1.4    nonaka 	}
1.4    nonaka 	pom = le32dec(walker);
1.4    nonaka 	walker += 4;
1.4    nonaka 	walker++;			/* Reserved */
1.4    nonaka 	status = *walker++;
1.4    nonaka 	nscan = le16dec(walker);
1.4    nonaka 	walker += 2;
1.4    nonaka 	progress = le16dec(walker);
1.4    nonaka 	walker += 2;
1.4    nonaka 	walker += 6;			/* Reserved */
1.4    nonaka 	printf("  %-30s: %d\n", "Power On Minutes", pom);
1.4    nonaka 	printf("  %-30s: %x (%s)\n", "BMS Status", status,
1.4    nonaka 	    status == 0 ? "idle" : (status == 1 ? "active" :
1.4    nonaka 	      (status == 8 ? "suspended" : "unknown")));
1.4    nonaka 	printf("  %-30s: %d\n", "Number of BMS", nscan);
1.4    nonaka 	printf("  %-30s: %d\n", "Progress Current BMS", progress);
1.4    nonaka 	/* Report retirements */
1.4    nonaka 	if (walker - (uint8_t *)buf != 20) {
1.4    nonaka 		printf("Coding error, offset not 20\n");
1.4    nonaka 		return;
1.4    nonaka 	}
1.4    nonaka 	size -= 20;
1.4    nonaka 	printf("  %-30s: %d\n", "BMS retirements", size / 0x18);
1.4    nonaka 	while (size > 0) {
1.4    nonaka 		code = le16dec(walker);
1.4    nonaka 		walker += 2;
1.4    nonaka 		walker++;
1.4    nonaka 		if (*walker++ != 0x14) {
1.4    nonaka 			printf("Bad length parameter\n");
1.4    nonaka 			return;
1.4    nonaka 		}
1.4    nonaka 		pom = le32dec(walker);
1.4    nonaka 		walker += 4;
1.4    nonaka 		/*
1.4    nonaka 		 * Spec sheet says the following are hard coded, if true, just
1.4    nonaka 		 * print the NAND retirement.
1.4    nonaka 		 */
1.4    nonaka 		if (walker[0] == 0x41 &&
1.4    nonaka 		    walker[1] == 0x0b &&
1.4    nonaka 		    walker[2] == 0x01 &&
1.4    nonaka 		    walker[3] == 0x00 &&
1.4    nonaka 		    walker[4] == 0x00 &&
1.4    nonaka 		    walker[5] == 0x00 &&
1.4    nonaka 		    walker[6] == 0x00 &&
1.4    nonaka 		    walker[7] == 0x00) {
1.4    nonaka 			walker += 8;
1.4    nonaka 			walker += 4;	/* Skip reserved */
1.4    nonaka 			nand = le32dec(walker);
1.4    nonaka 			walker += 4;
1.4    nonaka 			printf("  %-30s: %d\n", "Retirement number", code);
1.4    nonaka 			printf("    %-28s: %#x\n", "NAND (C/T)BBBPPP", nand);
1.4    nonaka 		} else {
1.4    nonaka 			printf("Parameter %#x entry corrupt\n", code);
1.4    nonaka 			walker += 16;
1.4    nonaka 		}
1.4    nonaka 	}
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_erase_errors(void *buf, uint16_t subtype __unused,
1.4    nonaka     uint8_t res __unused, uint32_t size)
1.4    nonaka {
1.4    nonaka 	static const struct kv_name kv[] = {
1.4    nonaka 		{ 0x0000, "Corrected Without Delay" },
1.4    nonaka 		{ 0x0001, "Corrected Maybe Delayed" },
1.4    nonaka 		{ 0x0002, "Re-Erase" },
1.4    nonaka 		{ 0x0003, "Errors Corrected" },
1.4    nonaka 		{ 0x0004, "Correct Algorithm Used" },
1.4    nonaka 		{ 0x0005, "Bytes Processed" },
1.4    nonaka 		{ 0x0006, "Uncorrected Errors" },
1.4    nonaka 		{ 0x8000, "Flash Erase Commands" },
1.4    nonaka 		{ 0x8001, "Mfg Defect Count" },
1.4    nonaka 		{ 0x8002, "Grown Defect Count" },
1.4    nonaka 		{ 0x8003, "Erase Count -- User" },
1.4    nonaka 		{ 0x8004, "Erase Count -- System" },
1.4    nonaka 	};
1.4    nonaka
1.4    nonaka 	printf("Erase Errors Subpage:\n");
1.4    nonaka 	print_hgst_info_subpage_gen(buf, subtype, size, kv, __arraycount(kv));
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_erase_counts(void *buf, uint16_t subtype, uint8_t res __unused,
1.4    nonaka     uint32_t size)
1.4    nonaka {
1.4    nonaka 	/* My drive doesn't export this -- so not coding up */
1.4    nonaka 	printf("XXX: Erase counts subpage: %p, %#x %d\n", buf, subtype, size);
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_temp_history(void *buf, uint16_t subtype __unused,
1.4    nonaka     uint8_t res __unused, uint32_t size __unused)
1.4    nonaka {
1.4    nonaka 	uint8_t *walker = buf;
1.4    nonaka 	uint32_t min;
1.4    nonaka
1.4    nonaka 	printf("Temperature History:\n");
1.4    nonaka 	printf("  %-30s: %d C\n", "Current Temperature", *walker++);
1.4    nonaka 	printf("  %-30s: %d C\n", "Reference Temperature", *walker++);
1.4    nonaka 	printf("  %-30s: %d C\n", "Maximum Temperature", *walker++);
1.4    nonaka 	printf("  %-30s: %d C\n", "Minimum Temperature", *walker++);
1.4    nonaka 	min = le32dec(walker);
1.4    nonaka 	walker += 4;
1.4    nonaka 	printf("  %-30s: %d:%02d:00\n", "Max Temperature Time", min / 60, min % 60);
1.4    nonaka 	min = le32dec(walker);
1.4    nonaka 	walker += 4;
1.4    nonaka 	printf("  %-30s: %d:%02d:00\n", "Over Temperature Duration", min / 60,
1.4    nonaka 	    min % 60);
1.4    nonaka 	min = le32dec(walker);
1.4    nonaka 	walker += 4;
1.4    nonaka 	printf("  %-30s: %d:%02d:00\n", "Min Temperature Time", min / 60, min % 60);
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_ssd_perf(void *buf, uint16_t subtype __unused, uint8_t res,
1.4    nonaka     uint32_t size __unused)
1.4    nonaka {
1.4    nonaka 	uint8_t *walker = buf;
1.4    nonaka 	uint64_t val;
1.4    nonaka
1.4    nonaka 	printf("SSD Performance Subpage Type %d:\n", res);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Read Commands", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Read Blocks", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Cache Read Hits Commands", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Cache Read Hits Blocks", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Read Commands Stalled", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Write Commands", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Write Blocks", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Write Odd Start Commands", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Write Odd End Commands", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "Host Write Commands Stalled", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "NAND Read Commands", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "NAND Read Blocks", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "NAND Write Commands", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "NAND Write Blocks", val);
1.4    nonaka 	val = le64dec(walker);
1.4    nonaka 	walker += 8;
1.4    nonaka 	printf("  %-30s: %ju\n", "NAND Read Before Writes", val);
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka print_hgst_info_firmware_load(void *buf, uint16_t subtype __unused,
1.4    nonaka     uint8_t res __unused, uint32_t size __unused)
1.4    nonaka {
1.4    nonaka 	uint8_t *walker = buf;
1.4    nonaka
1.4    nonaka 	printf("Firmware Load Subpage:\n");
1.4    nonaka 	printf("  %-30s: %d\n", "Firmware Downloads", le32dec(walker));
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.4    nonaka kv_indirect(void *buf, uint32_t subtype, uint8_t res, uint32_t size,
1.4    nonaka     struct subpage_print *sp, size_t nsp)
1.4    nonaka {
1.4    nonaka 	size_t i;
1.4    nonaka
1.4    nonaka 	for (i = 0; i < nsp; i++, sp++) {
1.4    nonaka 		if (sp->key == subtype) {
1.4    nonaka 			sp->fn(buf, subtype, res, size);
1.4    nonaka 			return;
1.4    nonaka 		}
1.4    nonaka 	}
1.4    nonaka 	printf("No handler for page type %x\n", subtype);
1.4    nonaka }
1.4    nonaka
1.4    nonaka static void
1.6    nonaka print_hgst_info_log(const struct nvm_identify_controller *cdata __unused, void *buf,
1.6    nonaka     uint32_t size __unused)
1.4    nonaka {
1.4    nonaka 	uint8_t	*walker, *end, *subpage;
1.4    nonaka 	int pages __unused;
1.4    nonaka 	uint16_t len;
1.4    nonaka 	uint8_t subtype, res;
1.4    nonaka
1.4    nonaka 	printf("HGST Extra Info Log\n");
1.4    nonaka 	printf("===================\n");
1.4    nonaka
1.4    nonaka 	walker = buf;
1.4    nonaka 	pages = *walker++;
1.4    nonaka 	walker++;
1.4    nonaka 	len = le16dec(walker);
1.4    nonaka 	walker += 2;
1.4    nonaka 	end = walker + len;		/* Length is exclusive of this header */
1.4    nonaka
1.4    nonaka 	while (walker < end) {
1.4    nonaka 		subpage = walker + 4;
1.4    nonaka 		subtype = *walker++ & 0x3f;	/* subtype */
1.4    nonaka 		res = *walker++;		/* Reserved */
1.4    nonaka 		len = le16dec(walker);
1.4    nonaka 		walker += len + 2;		/* Length, not incl header */
1.4    nonaka 		if (walker > end) {
1.4    nonaka 			printf("Ooops! Off the end of the list\n");
1.4    nonaka 			break;
1.4    nonaka 		}
1.4    nonaka 		kv_indirect(subpage, subtype, res, len, hgst_subpage,
1.4    nonaka 		    __arraycount(hgst_subpage));
1.4    nonaka 	}
1.4    nonaka }
1.4    nonaka
1.4    nonaka /*
1.4    nonaka  * Table of log page printer / sizing.
1.4    nonaka  *
1.4    nonaka  * This includes Intel specific pages that are widely implemented.
1.4    nonaka  * Make sure you keep all the pages of one vendor together so -v help
1.4    nonaka  * lists all the vendors pages.
1.4    nonaka  */
1.1    nonaka static struct logpage_function {
1.1    nonaka 	uint8_t		log_page;
1.4    nonaka 	const char     *vendor;
1.4    nonaka 	const char     *name;
1.4    nonaka 	print_fn_t	print_fn;
1.4    nonaka 	size_t		size;
1.1    nonaka } logfuncs[] = {
1.4    nonaka 	{NVME_LOG_ERROR,		NULL,	"Drive Error Log",
1.4    nonaka 	 print_log_error,		0},
1.4    nonaka 	{NVME_LOG_HEALTH_INFORMATION,	NULL,	"Health/SMART Data",
1.4    nonaka 	 print_log_health,		sizeof(struct nvme_health_information_page)},
1.4    nonaka 	{NVME_LOG_FIRMWARE_SLOT,	NULL,	"Firmware Information",
1.4    nonaka 	 print_log_firmware,		sizeof(struct nvme_firmware_page)},
1.4    nonaka 	{HGST_INFO_LOG,			"hgst",	"Detailed Health/SMART",
1.4    nonaka 	 print_hgst_info_log,		DEFAULT_SIZE},
1.4    nonaka 	{HGST_INFO_LOG,			"wds",	"Detailed Health/SMART",
1.4    nonaka 	 print_hgst_info_log,		DEFAULT_SIZE},
1.4    nonaka 	{INTEL_LOG_TEMP_STATS,		"intel", "Temperature Stats",
1.4    nonaka 	 print_intel_temp_stats,	sizeof(struct intel_log_temp_stats)},
1.4    nonaka 	{INTEL_LOG_READ_LAT_LOG,	"intel", "Read Latencies",
1.4    nonaka 	 print_intel_read_lat_log,	DEFAULT_SIZE},
1.4    nonaka 	{INTEL_LOG_WRITE_LAT_LOG,	"intel", "Write Latencies",
1.4    nonaka 	 print_intel_write_lat_log,	DEFAULT_SIZE},
1.4    nonaka 	{INTEL_LOG_ADD_SMART,		"intel", "Extra Health/SMART Data",
1.4    nonaka 	 print_intel_add_smart,		DEFAULT_SIZE},
1.4    nonaka 	{INTEL_LOG_ADD_SMART,		"samsung", "Extra Health/SMART Data",
1.4    nonaka 	 print_intel_add_smart,		DEFAULT_SIZE},
1.4    nonaka
1.4    nonaka 	{0, NULL, NULL, NULL, 0},
1.1    nonaka };
1.1    nonaka
1.2     joerg __dead static void
1.1    nonaka logpage_usage(void)
1.1    nonaka {
1.1    nonaka 	fprintf(stderr, "usage:\n");
1.5  jdolecek 	fprintf(stderr, "\t%s " LOGPAGE_USAGE, getprogname());
1.1    nonaka 	exit(1);
1.1    nonaka }
1.1    nonaka
1.4    nonaka __dead static void
1.4    nonaka logpage_help(void)
1.4    nonaka {
1.4    nonaka 	struct logpage_function		*f;
1.4    nonaka 	const char 			*v;
1.4    nonaka
1.4    nonaka 	fprintf(stderr, "\n");
1.4    nonaka 	fprintf(stderr, "%-8s %-10s %s\n", "Page", "Vendor","Page Name");
1.4    nonaka 	fprintf(stderr, "-------- ---------- ----------\n");
1.4    nonaka 	for (f = logfuncs; f->log_page > 0; f++) {
1.4    nonaka 		v = f->vendor == NULL ? "-" : f->vendor;
1.4    nonaka 		fprintf(stderr, "0x%02x     %-10s %s\n", f->log_page, v, f->name);
1.4    nonaka 	}
1.4    nonaka
1.4    nonaka 	exit(1);
1.4    nonaka }
1.4    nonaka
1.1    nonaka void
1.1    nonaka logpage(int argc, char *argv[])
1.1    nonaka {
1.1    nonaka 	int				fd, nsid;
1.1    nonaka 	int				log_page = 0, pageflag = false;
1.4    nonaka 	int				binflag = false, hexflag = false, ns_specified;
1.1    nonaka 	int				ch;
1.1    nonaka 	char				*p;
1.1    nonaka 	char				cname[64];
1.1    nonaka 	uint32_t			size;
1.1    nonaka 	void				*buf;
1.4    nonaka 	const char 			*vendor = NULL;
1.1    nonaka 	struct logpage_function		*f;
1.1    nonaka 	struct nvm_identify_controller	cdata;
1.1    nonaka 	print_fn_t			print_fn;
1.1    nonaka
1.4    nonaka 	while ((ch = getopt(argc, argv, "bp:xv:")) != -1) {
1.1    nonaka 		switch (ch) {
1.4    nonaka 		case 'b':
1.4    nonaka 			binflag = true;
1.4    nonaka 			break;
1.1    nonaka 		case 'p':
1.4    nonaka 			if (strcmp(optarg, "help") == 0)
1.4    nonaka 				logpage_help();
1.4    nonaka
1.1    nonaka 			/* TODO: Add human-readable ASCII page IDs */
1.1    nonaka 			log_page = strtol(optarg, &p, 0);
1.1    nonaka 			if (p != NULL && *p != '\0') {
1.1    nonaka 				fprintf(stderr,
1.1    nonaka 				    "\"%s\" not valid log page id.\n",
1.1    nonaka 				    optarg);
1.1    nonaka 				logpage_usage();
1.1    nonaka 			}
1.1    nonaka 			pageflag = true;
1.1    nonaka 			break;
1.1    nonaka 		case 'x':
1.1    nonaka 			hexflag = true;
1.1    nonaka 			break;
1.4    nonaka 		case 'v':
1.4    nonaka 			if (strcmp(optarg, "help") == 0)
1.4    nonaka 				logpage_help();
1.4    nonaka 			vendor = optarg;
1.4    nonaka 			break;
1.1    nonaka 		}
1.1    nonaka 	}
1.1    nonaka
1.1    nonaka 	if (!pageflag) {
1.1    nonaka 		printf("Missing page_id (-p).\n");
1.1    nonaka 		logpage_usage();
1.1    nonaka 	}
1.1    nonaka
1.1    nonaka 	/* Check that a controller and/or namespace was specified. */
1.1    nonaka 	if (optind >= argc)
1.1    nonaka 		logpage_usage();
1.1    nonaka
1.1    nonaka 	if (strstr(argv[optind], NVME_NS_PREFIX) != NULL) {
1.1    nonaka 		ns_specified = true;
1.1    nonaka 		parse_ns_str(argv[optind], cname, &nsid);
1.1    nonaka 		open_dev(cname, &fd, 1, 1);
1.1    nonaka 	} else {
1.1    nonaka 		ns_specified = false;
1.1    nonaka 		nsid = 0xffffffff;
1.1    nonaka 		open_dev(argv[optind], &fd, 1, 1);
1.1    nonaka 	}
1.1    nonaka
1.1    nonaka 	read_controller_data(fd, &cdata);
1.1    nonaka
1.1    nonaka 	/*
1.1    nonaka 	 * The log page attribtues indicate whether or not the controller
1.1    nonaka 	 * supports the SMART/Health information log page on a per
1.1    nonaka 	 * namespace basis.
1.1    nonaka 	 */
1.1    nonaka 	if (ns_specified) {
1.1    nonaka 		if (log_page != NVME_LOG_HEALTH_INFORMATION)
1.1    nonaka 			errx(1, "log page %d valid only at controller level",
1.1    nonaka 			    log_page);
1.1    nonaka 		if (!(cdata.lpa & NVME_ID_CTRLR_LPA_NS_SMART))
1.1    nonaka 			errx(1,
1.1    nonaka 			    "controller does not support per namespace "
1.1    nonaka 			    "smart/health information");
1.1    nonaka 	}
1.1    nonaka
1.6    nonaka 	print_fn = print_log_hex;
1.4    nonaka 	size = DEFAULT_SIZE;
1.4    nonaka 	if (binflag)
1.4    nonaka 		print_fn = print_bin;
1.4    nonaka 	if (!binflag && !hexflag) {
1.1    nonaka 		/*
1.4    nonaka 		 * See if there is a pretty print function for the specified log
1.4    nonaka 		 * page.  If one isn't found, we just revert to the default
1.4    nonaka 		 * (print_hex). If there was a vendor specified bt the user, and
1.4    nonaka 		 * the page is vendor specific, don't match the print function
1.4    nonaka 		 * unless the vendors match.
1.1    nonaka 		 */
1.4    nonaka 		for (f = logfuncs; f->log_page > 0; f++) {
1.4    nonaka 			if (f->vendor != NULL && vendor != NULL &&
1.4    nonaka 			    strcmp(f->vendor, vendor) != 0)
1.4    nonaka 				continue;
1.4    nonaka 			if (log_page != f->log_page)
1.4    nonaka 				continue;
1.4    nonaka 			print_fn = f->print_fn;
1.4    nonaka 			size = f->size;
1.4    nonaka 			break;
1.1    nonaka 		}
1.1    nonaka 	}
1.1    nonaka
1.4    nonaka 	if (log_page == NVME_LOG_ERROR) {
1.1    nonaka 		size = sizeof(struct nvme_error_information_entry);
1.1    nonaka 		size *= (cdata.elpe + 1);
1.1    nonaka 	}
1.1    nonaka
1.4    nonaka 	/* Read the log page */
1.1    nonaka 	buf = get_log_buffer(size);
1.1    nonaka 	read_logpage(fd, log_page, nsid, buf, size);
1.6    nonaka 	print_fn(&cdata, buf, size);
1.1    nonaka
1.1    nonaka 	close(fd);
1.1    nonaka 	exit(0);
1.1    nonaka }