// SPDX-License-Identifier: GPL-2.0-or-later #include #include #include #include #include #include #include #include #include #include #include "nvme.h" #include "libnvme.h" #include "plugin.h" #include "linux/types.h" #include "nvme-print.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_admin_passthru(fd, &cmd, NULL); if (!err && result) *result = cmd.result; return err; } static int get_status(int argc, char **argv, struct command *cmd, struct plugin *plugin) { struct nvme_dera_smart_info_log log; enum dera_device_status state = DEVICE_STATUS_FATAL_ERROR; char *desc = "Get the Dera device status"; struct nvme_dev *dev; int err; OPT_ARGS(opts) = { OPT_END() }; err = parse_and_open(&dev, argc, argv, desc, opts); if (err) return err; err = nvme_get_log_simple(dev_fd(dev), 0xc0, sizeof(log), &log); if (err) goto exit; static const char *dev_status[] = { "Normal", "Quick Rebuilding", "Full Rebuilding", "Raw Rebuilding", "Card Read Only", "Fatal Error", "Busy", "Low Level Format", "Firmware Committing", "Over Temperature" }; static const char *volt_status[] = { "Normal", "Initial Low", "Runtime Low", }; err = nvme_dera_get_device_status(dev_fd(dev), &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 < 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) nvme_show_status(err); dev_close(dev); return err; }