#include <fcntl.h>
#include <errno.h>
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include <dirent.h>
#include <ctype.h>
#include <sys/stat.h>
#include <sys/time.h>
#include "nvme.h"
#include "nvme-print.h"
#include "nvme-ioctl.h"
#include "plugin.h"
#include "argconfig.h"
#include "suffix.h"
#define CREATE_CMD
#include "dera-nvme.h"
static int char4_to_int(__u8 *data)
{
int i;
int result = 0;
for (i = 0; i < 4; i++) {
result = result << 8;
result += data[3 - i];
}
return result;
}
struct nvme_dera_smart_info_log
{
__u8 quick_rebuild_cnt0[4];
__u8 quick_rebuild_cnt1[4];
__u8 full_rebuild_cnt0[4];
__u8 full_rebuild_cnt1[4];
__u8 raw_rebuild_cnt0[4];
__u8 raw_rebuild_cnt1[4];
__u8 cap_aged;
__u8 cap_aged_ratio;
__u8 cap_status;
__u8 cap_voltage[4];
__u8 cap_charge_ctrl_en;
__u8 cap_charge_ctrl_val[2];
__u8 cap_charge_max_thr[2];
__u8 cap_charge_min_thr[2];
__u8 dev_status;
__u8 dev_status_up;
__u8 nand_erase_err_cnt[4];
__u8 nand_program_err_cnt[4];
__u8 ddra_1bit_err[2];
__u8 ddra_2bit_err[2];
__u8 ddrb_1bit_err[2];
__u8 ddrb_2bit_err[2];
__u8 ddr_err_bit;
__u8 pcie_corr_err[2];
__u8 pcie_uncorr_err[2];
__u8 pcie_fatal_err[2];
__u8 pcie_err_bit;
__u8 power_level;
__u8 current_power[2];
__u8 nand_init_fail[2];
__u8 fw_loader_version[8];
__u8 uefi_driver_version[8];
__u8 gpio0_err[2];
__u8 gpio5_err[2];
__u8 gpio_err_bit[2];
__u8 rebuild_percent;
__u8 pcie_volt_status;
__u8 current_pcie_volt[2];
__u8 init_pcie_volt_thr[2];
__u8 rt_pcie_volt_thr[2];
__u8 init_pcie_volt_low[2];
__u8 rt_pcie_volt_low[2];
__u8 temp_sensor_abnormal[2];
__u8 nand_read_retry_fail_cnt[4];
__u8 fw_slot_version[8];
__u8 rsved[395];
};
enum dera_device_status
{
DEVICE_STATUS_READY = 0x00,
DEVICE_STATUS_QUICK_REBUILDING = 0x01,
DEVICE_STATUS_FULL_REBUILDING = 0x02,
DEVICE_STATUS_RAW_REBUILDING = 0x03,
DEVICE_STATUS_CARD_READ_ONLY = 0x04,
DEVICE_STATUS_FATAL_ERROR = 0x05,
DEVICE_STATUS_BUSY = 0x06,
DEVICE_STAUTS_LOW_LEVEL_FORMAT = 0x07,
DEVICE_STAUTS_FW_COMMITING = 0x08,
DEVICE_STAUTS__OVER_TEMPRATURE = 0x09,
};
static int nvme_dera_get_device_status(int fd, enum dera_device_status *result)
{
int err = 0;
struct nvme_passthru_cmd cmd = {
.opcode = 0xc0,
.addr = (__u64)(uintptr_t)NULL,
.data_len = 0,
.cdw10 = 0,
.cdw12 = 0x104,
};
err = nvme_submit_passthru(fd, NVME_IOCTL_ADMIN_CMD, &cmd);
if (!err && result) {
*result = cmd.result;
}
return err;
}
static int get_status(int argc, char **argv, struct command *cmd, struct plugin *plugin)
{
int fd, err;
struct nvme_dera_smart_info_log log;
enum dera_device_status state = DEVICE_STATUS_FATAL_ERROR;
char *desc = "Get the Dera device status";
OPT_ARGS(opts) = {
OPT_END()
};
fd = parse_and_open(argc, argv, desc, opts);
if (fd < 0)
return fd;
err = nvme_get_log(fd, 0xffffffff, 0xc0, false, sizeof(log), &log);
if (err) {
goto exit;
}
const char* dev_status[] = {
"Normal",
"Quick Rebuilding",
"Full Rebuilding",
"Raw Rebuilding",
"Card Read Only",
"Fatal Error",
"Busy",
"Low Level Format",
"Firmware Committing",
"Over Temperature" };
const char *volt_status[] = {
"Normal",
"Initial Low",
"Runtime Low",
};
err = nvme_dera_get_device_status(fd, &state);
if (!err){
if (state > 0 && state < 4){
printf("device_status : %s %d%% completed\n", dev_status[state], log.rebuild_percent);
}
else{
printf("device_status : %s\n", dev_status[state]);
}
}
else {
goto exit;
}
printf("dev_status_up : %s\n", dev_status[log.dev_status_up]);
printf("cap_aged : %s\n", log.cap_aged == 1 ? "True" : "False");
printf("cap_aged_ratio : %d%%\n", log.cap_aged_ratio < 100 ? log.cap_aged_ratio : 100);
printf("cap_status : %s\n", log.cap_status == 0 ? "Normal" : (log.cap_status == 1 ? "Warning" : "Critical"));
printf("cap_voltage : %d mV\n", char4_to_int(log.cap_voltage));
printf("nand_erase_err_cnt : %d\n", char4_to_int(log.nand_erase_err_cnt));
printf("nand_program_err_cnt : %d\n", char4_to_int(log.nand_program_err_cnt));
printf("ddra_1bit_err : %d\n", log.ddra_1bit_err[1] << 8 | log.ddra_1bit_err[0]);
printf("ddra_2bit_err : %d\n", log.ddra_2bit_err[1] << 8 | log.ddra_2bit_err[0]);
printf("ddrb_1bit_err : %d\n", log.ddrb_1bit_err[1] << 8 | log.ddrb_1bit_err[0]);
printf("ddrb_2bit_err : %d\n", log.ddrb_2bit_err[1] << 8 | log.ddrb_2bit_err[0]);
printf("ddr_err_bit : %d\n", log.ddr_err_bit);
printf("pcie_corr_err : %d\n", log.pcie_corr_err[1] << 8 | log.pcie_corr_err[0]);
printf("pcie_uncorr_err : %d\n", log.pcie_uncorr_err[1] << 8 | log.pcie_uncorr_err[0]);
printf("pcie_fatal_err : %d\n", log.pcie_fatal_err[1] << 8 | log.pcie_fatal_err[0]);
printf("power_level : %d W\n", log.power_level);
printf("current_power : %d mW\n", log.current_power[1] << 8 | log.current_power[0]);
printf("nand_init_fail : %d\n", log.nand_init_fail[1] << 8 | log.nand_init_fail[0]);
printf("fw_loader_version : %.*s\n", 8, log.fw_loader_version);
printf("uefi_driver_version : %.*s\n", 8, log.uefi_driver_version);
if (log.pcie_volt_status >= 0 && log.pcie_volt_status <= sizeof(volt_status) / sizeof(const char *)){
printf("pcie_volt_status : %s\n", volt_status[log.pcie_volt_status]);
}
else{
printf("pcie_volt_status : Unknown\n");
}
printf("current_pcie_volt : %d mV\n", log.current_pcie_volt[1] << 8 | log.current_pcie_volt[0]);
printf("init_pcie_volt_low_cnt : %d\n", log.init_pcie_volt_low[1] << 8 | log.init_pcie_volt_low[0]);
printf("rt_pcie_volt_low_cnt : %d\n", log.rt_pcie_volt_low[1] << 8 | log.rt_pcie_volt_low[0]);
printf("temp_sensor_abnormal_cnt : %d\n", log.temp_sensor_abnormal[1] << 8 | log.temp_sensor_abnormal[0]);
printf("nand_read_retry_fail_cnt : %d\n", char4_to_int(log.nand_read_retry_fail_cnt));
printf("fw_slot_version : %.*s\n", 8, log.fw_slot_version);
exit:
if (err > 0)
fprintf(stderr, "\nNVMe status:%s(0x%x)\n", nvme_status_to_string(err), err);
return err;
}