/* * nvmecmds.cpp * * Home page of code is: https://www.smartmontools.org * * Copyright (C) 2016-23 Christian Franke * * SPDX-License-Identifier: GPL-2.0-or-later */ #include "config.h" #include "nvmecmds.h" const char * nvmecmds_cvsid = "$Id: nvmecmds.cpp 5473 2023-05-30 12:36:57Z chrfranke $" NVMECMDS_H_CVSID; #include "dev_interface.h" #include "atacmds.h" // swapx(), dont_print_serial_number #include "scsicmds.h" // dStrHex() #include "utility.h" #include using namespace smartmontools; // Print NVMe debug messages? unsigned char nvme_debugmode = 0; // Dump up to 4096 bytes, do not dump trailing zero bytes. // TODO: Handle this by new unified function in utility.cpp static void debug_hex_dump(const void * data, unsigned size) { const unsigned char * p = (const unsigned char *)data; const unsigned limit = 4096; // sizeof(nvme_id_ctrl) unsigned sz = (size <= limit ? size : limit); while (sz > 0x10 && !p[sz-1]) sz--; if (sz < size) { if (sz & 0x0f) sz = (sz & ~0x0f) + 0x10; sz += 0x10; if (sz > size) sz = size; } dStrHex((const uint8_t *)p, sz, 0); if (sz < size) pout(" ...\n"); } // Call NVMe pass-through and print debug info if requested. static bool nvme_pass_through(nvme_device * device, const nvme_cmd_in & in, nvme_cmd_out & out) { if (nvme_debugmode) { pout(" [NVMe call: opcode=0x%02x, size=0x%04x, nsid=0x%08x, cdw10=0x%08x", in.opcode, in.size, in.nsid, in.cdw10); if (in.cdw11 || in.cdw12 || in.cdw13 || in.cdw14 || in.cdw15) pout(",\n cdw1x=0x%08x, 0x%08x, 0x%08x, 0x%08x, 0x%08x", in.cdw11, in.cdw12, in.cdw13, in.cdw14, in.cdw15); pout("]\n"); } auto start_usec = (nvme_debugmode ? get_timer_usec() : -1); bool ok = device->nvme_pass_through(in, out); if (start_usec >= 0) { auto duration_usec = get_timer_usec() - start_usec; if (duration_usec > 0) pout(" [Duration: %.6fs]\n", duration_usec / 1000000.0); } if (dont_print_serial_number && ok && in.opcode == nvme_admin_identify) { if (in.cdw10 == 0x01 && in.size >= sizeof(nvme_id_ctrl)) { // Identify controller: Invalidate serial number nvme_id_ctrl & id_ctrl = *reinterpret_cast(in.buffer); memset(id_ctrl.sn, 'X', sizeof(id_ctrl.sn)); } else if (in.cdw10 == 0x00 && in.size >= sizeof(nvme_id_ns)) { // Identify namespace: Invalidate IEEE EUI-64 nvme_id_ns & id_ns = *reinterpret_cast(in.buffer); memset(id_ns.eui64, 0x00, sizeof(id_ns.eui64)); } } if (nvme_debugmode) { if (!ok) { pout(" [NVMe call failed: "); if (out.status_valid) pout("NVMe Status=0x%04x", out.status); else pout("%s", device->get_errmsg()); } else { pout(" [NVMe call succeeded: result=0x%08x", out.result); if (nvme_debugmode > 1 && in.direction() == nvme_cmd_in::data_in) { pout("\n"); debug_hex_dump(in.buffer, in.size); pout(" "); } } pout("]\n"); } return ok; } // Call NVMe pass-through and print debug info if requested. // Version without output parameters. static bool nvme_pass_through(nvme_device * device, const nvme_cmd_in & in) { nvme_cmd_out out; return nvme_pass_through(device, in, out); } // Read NVMe identify info with controller/namespace field CNS. static bool nvme_read_identify(nvme_device * device, unsigned nsid, unsigned char cns, void * data, unsigned size) { memset(data, 0, size); nvme_cmd_in in; in.set_data_in(nvme_admin_identify, data, size); in.nsid = nsid; in.cdw10 = cns; return nvme_pass_through(device, in); } // Read NVMe Identify Controller data structure. bool nvme_read_id_ctrl(nvme_device * device, nvme_id_ctrl & id_ctrl) { if (!nvme_read_identify(device, 0, 0x01, &id_ctrl, sizeof(id_ctrl))) return false; if (isbigendian()) { swapx(&id_ctrl.vid); swapx(&id_ctrl.ssvid); swapx(&id_ctrl.cntlid); swapx(&id_ctrl.ver); swapx(&id_ctrl.oacs); swapx(&id_ctrl.wctemp); swapx(&id_ctrl.cctemp); swapx(&id_ctrl.mtfa); swapx(&id_ctrl.hmpre); swapx(&id_ctrl.hmmin); swapx(&id_ctrl.rpmbs); swapx(&id_ctrl.nn); swapx(&id_ctrl.oncs); swapx(&id_ctrl.fuses); swapx(&id_ctrl.awun); swapx(&id_ctrl.awupf); swapx(&id_ctrl.acwu); swapx(&id_ctrl.sgls); for (int i = 0; i < 32; i++) { swapx(&id_ctrl.psd[i].max_power); swapx(&id_ctrl.psd[i].entry_lat); swapx(&id_ctrl.psd[i].exit_lat); swapx(&id_ctrl.psd[i].idle_power); swapx(&id_ctrl.psd[i].active_power); } } return true; } // Read NVMe Identify Namespace data structure for namespace NSID. bool nvme_read_id_ns(nvme_device * device, unsigned nsid, nvme_id_ns & id_ns) { if (!nvme_read_identify(device, nsid, 0x00, &id_ns, sizeof(id_ns))) return false; if (isbigendian()) { swapx(&id_ns.nsze); swapx(&id_ns.ncap); swapx(&id_ns.nuse); swapx(&id_ns.nawun); swapx(&id_ns.nawupf); swapx(&id_ns.nacwu); swapx(&id_ns.nabsn); swapx(&id_ns.nabo); swapx(&id_ns.nabspf); for (int i = 0; i < 16; i++) swapx(&id_ns.lbaf[i].ms); } return true; } static bool nvme_read_log_page_1(nvme_device * device, unsigned nsid, unsigned char lid, void * data, unsigned size, unsigned offset = 0) { if (!(4 <= size && size <= 0x1000 && !(size % 4) && !(offset % 4))) return device->set_err(EINVAL, "Invalid NVMe log size %u or offset %u", size, offset); memset(data, 0, size); nvme_cmd_in in; in.set_data_in(nvme_admin_get_log_page, data, size); in.nsid = nsid; in.cdw10 = lid | (((size / 4) - 1) << 16); in.cdw12 = offset; // LPOL, NVMe 1.2.1 return nvme_pass_through(device, in); } // Read NVMe log page with identifier LID. unsigned nvme_read_log_page(nvme_device * device, unsigned nsid, unsigned char lid, void * data, unsigned size, bool lpo_sup, unsigned offset /* = 0 */) { unsigned n, bs; for (n = 0; n < size; n += bs) { if (!lpo_sup && offset + n > 0) { device->set_err(ENOSYS, "Log Page Offset not supported"); break; } // Limit transfer size to one page to avoid problems with // limits of NVMe pass-through layer or too low MDTS values. bs = size - n; if (bs > 0x1000) bs = 0x1000; if (!nvme_read_log_page_1(device, nsid, lid, (char *)data + n, bs, offset + n)) break; } return n; } // Read NVMe Error Information Log. unsigned nvme_read_error_log(nvme_device * device, nvme_error_log_page * error_log, unsigned num_entries, bool lpo_sup) { unsigned n = nvme_read_log_page(device, 0xffffffff, 0x01, error_log, num_entries * sizeof(*error_log), lpo_sup); unsigned read_entries = n / sizeof(*error_log); if (isbigendian()) { for (unsigned i = 0; i < read_entries; i++) { swapx(&error_log[i].error_count); swapx(&error_log[i].sqid); swapx(&error_log[i].cmdid); swapx(&error_log[i].status_field); swapx(&error_log[i].parm_error_location); swapx(&error_log[i].lba); swapx(&error_log[i].nsid); } } return read_entries; } // Read NVMe SMART/Health Information log. bool nvme_read_smart_log(nvme_device * device, nvme_smart_log & smart_log) { if (!nvme_read_log_page_1(device, 0xffffffff, 0x02, &smart_log, sizeof(smart_log))) return false; if (isbigendian()) { swapx(&smart_log.warning_temp_time); swapx(&smart_log.critical_comp_time); for (int i = 0; i < 8; i++) swapx(&smart_log.temp_sensor[i]); } return true; } // Read NVMe Self-test Log. bool nvme_read_self_test_log(nvme_device * device, uint32_t nsid, smartmontools::nvme_self_test_log & self_test_log) { if (!nvme_read_log_page_1(device, nsid, 0x06, &self_test_log, sizeof(self_test_log))) return false; if (isbigendian()) { for (int i = 0; i < 20; i++) swapx(&self_test_log.results[i].nsid); } return true; } // Start Self-test bool nvme_self_test(nvme_device * device, uint8_t stc, uint32_t nsid) { nvme_cmd_in in; in.opcode = nvme_admin_dev_self_test; in.nsid = nsid; in.cdw10 = stc; return nvme_pass_through(device, in); } // Return flagged error message for NVMe status SCT/SC fields or nullptr if unknown. // If message starts with '-', the status indicates an invalid command (EINVAL). static const char * nvme_status_to_flagged_str(uint16_t status) { // Section 3.3.3.2.1 of NVM Express Base Specification Revision 2.0c, October 4, 2022 uint8_t sc = (uint8_t)status; switch ((status >> 8) & 0x7) { case 0x0: // Generic Command Status if (sc < 0x80) switch (sc) { case 0x00: return "Successful Completion"; case 0x01: return "-Invalid Command Opcode"; case 0x02: return "-Invalid Field in Command"; case 0x03: return "Command ID Conflict"; case 0x04: return "Data Transfer Error"; case 0x05: return "Commands Aborted due to Power Loss Notification"; case 0x06: return "Internal Error"; case 0x07: return "Command Abort Requested"; case 0x08: return "Command Aborted due to SQ Deletion"; case 0x09: return "Command Aborted due to Failed Fused Command"; case 0x0a: return "Command Aborted due to Missing Fused Command"; case 0x0b: return "-Invalid Namespace or Format"; case 0x0c: return "Command Sequence Error"; case 0x0d: return "-Invalid SGL Segment Descriptor"; case 0x0e: return "-Invalid Number of SGL Descriptors"; case 0x0f: return "-Data SGL Length Invalid"; case 0x10: return "-Metadata SGL Length Invalid"; case 0x11: return "-SGL Descriptor Type Invalid"; case 0x12: return "-Invalid Use of Controller Memory Buffer"; case 0x13: return "-PRP Offset Invalid"; case 0x14: return "Atomic Write Unit Exceeded"; case 0x15: return "Operation Denied"; case 0x16: return "-SGL Offset Invalid"; case 0x18: return "Host Identifier Inconsistent Format"; case 0x19: return "Keep Alive Timer Expired"; case 0x1a: return "-Keep Alive Timeout Invalid"; case 0x1b: return "Command Aborted due to Preempt and Abort"; case 0x1c: return "Sanitize Failed"; case 0x1d: return "Sanitize In Progress"; case 0x1e: return "SGL Data Block Granularity Invalid"; case 0x1f: return "Command Not Supported for Queue in CMB"; case 0x20: return "Namespace is Write Protected"; case 0x21: return "Command Interrupted"; case 0x22: return "Transient Transport Error"; case 0x23: return "Command Prohibited by Command and Feature Lockdown"; case 0x24: return "Admin Command Media Not Ready"; // 0x25-0x7f: Reserved } else switch (sc) { // 0x80-0xbf: I/O Command Set Specific case 0x80: return "LBA Out of Range"; case 0x81: return "Capacity Exceeded"; case 0x82: return "Namespace Not Ready"; case 0x83: return "Reservation Conflict"; case 0x84: return "Format In Progress"; case 0x85: return "-Invalid Value Size"; case 0x86: return "-Invalid Key Size"; case 0x87: return "KV Key Does Not Exist"; case 0x88: return "Unrecovered Error"; case 0x89: return "Key Exists"; // 0x90-0xbf: Reserved // 0xc0-0xff: Vendor Specific } break; case 0x1: // Command Specific Status if (sc < 0x80) switch (sc) { case 0x00: return "-Completion Queue Invalid"; case 0x01: return "-Invalid Queue Identifier"; case 0x02: return "-Invalid Queue Size"; case 0x03: return "Abort Command Limit Exceeded"; case 0x04: return "Abort Command Is Missing"; case 0x05: return "Asynchronous Event Request Limit Exceeded"; case 0x06: return "-Invalid Firmware Slot"; case 0x07: return "-Invalid Firmware Image"; case 0x08: return "-Invalid Interrupt Vector"; case 0x09: return "-Invalid Log Page"; case 0x0a: return "-Invalid Format"; case 0x0b: return "Firmware Activation Requires Conventional Reset"; case 0x0c: return "-Invalid Queue Deletion"; case 0x0d: return "Feature Identifier Not Saveable"; case 0x0e: return "Feature Not Changeable"; case 0x0f: return "Feature Not Namespace Specific"; case 0x10: return "Firmware Activation Requires NVM Subsystem Reset"; case 0x11: return "Firmware Activation Requires Controller Level Reset"; case 0x12: return "Firmware Activation Requires Maximum Time Violation"; case 0x13: return "Firmware Activation Prohibited"; case 0x14: return "Overlapping Range"; case 0x15: return "Namespace Insufficient Capacity"; case 0x16: return "-Namespace Identifier Unavailable"; case 0x18: return "Namespace Already Attached"; case 0x19: return "Namespace Is Private"; case 0x1a: return "Namespace Not Attached"; case 0x1b: return "Thin Provisioning Not Supported"; case 0x1c: return "-Controller List Invalid"; case 0x1d: return "Device Self-test In Progress"; case 0x1e: return "Boot Partition Write Prohibited"; case 0x1f: return "Invalid Controller Identifier"; case 0x20: return "-Invalid Secondary Controller State"; case 0x21: return "-Invalid Number of Controller Resources"; case 0x22: return "-Invalid Resource Identifier"; case 0x23: return "Sanitize Prohibited While Persistent Memory Region is Enabled"; case 0x24: return "-ANA Group Identifier Invalid"; case 0x25: return "ANA Attach Failed"; case 0x26: return "Insufficient Capacity"; case 0x27: return "Namespace Attachment Limit Exceeded"; case 0x28: return "Prohibition of Command Execution Not Supported"; case 0x29: return "I/O Command Set Not Supported"; case 0x2a: return "I/O Command Set Not Enabled"; case 0x2b: return "I/O Command Set Combination Rejected"; case 0x2c: return "-Invalid I/O Command Set"; case 0x2d: return "-Identifier Unavailable"; // 0x2e-0x6f: Reserved // 0x70-0x7f: Directive Specific } else if (sc < 0xb8) switch (sc) { // 0x80-0xbf: I/O Command Set Specific (overlap with Fabrics Command Set) case 0x80: return "-Conflicting Attributes"; case 0x81: return "-Invalid Protection Information"; case 0x82: return "Attempted Write to Read Only Range"; case 0x83: return "Command Size Limit Exceeded"; // 0x84-0xb7: Reserved } else switch (sc) { case 0xb8: return "Zoned Boundary Error"; case 0xb9: return "Zone Is Full"; case 0xba: return "Zone Is Read Only"; case 0xbb: return "Zone Is Offline"; case 0xbc: return "Zone Invalid Write"; case 0xbd: return "Too Many Active Zones"; case 0xbe: return "Too Many Open Zones"; case 0xbf: return "Invalid Zone State Transition"; // 0xc0-0xff: Vendor Specific } break; case 0x2: // Media and Data Integrity Errors switch (sc) { // 0x00-0x7f: Reserved case 0x80: return "Write Fault"; case 0x81: return "Unrecovered Read Error"; case 0x82: return "End-to-end Guard Check Error"; case 0x83: return "End-to-end Application Tag Check Error"; case 0x84: return "End-to-end Reference Tag Check Error"; case 0x85: return "Compare Failure"; case 0x86: return "Access Denied"; case 0x87: return "Deallocated or Unwritten Logical Block"; case 0x88: return "End-to-End Storage Tag Check Error"; // 0x89-0xbf: Reserved // 0xc0-0xff: Vendor Specific } break; case 0x3: // Path Related Status switch (sc) { case 0x00: return "Internal Path Error"; case 0x01: return "Asymmetric Access Persistent Loss"; case 0x02: return "Asymmetric Access Inaccessible"; case 0x03: return "Asymmetric Access Transition"; // 0x04-0x5f: Reserved // 0x60-0x6f: Controller Detected Pathing Errors case 0x60: return "Controller Pathing Error"; // 0x61-0x6f: Reserved // 0x70-0x7f: Host Detected Pathing Errors case 0x70: return "Host Pathing Error"; case 0x71: return "Command Aborted By Host"; // 0x72-0x7f: Reserved // 0x80-0xbf: I/O Command Set Specific // 0xc0-0xff: Vendor Specific } break; // 0x4-0x6: Reserved // 0x7: Vendor Specific } return nullptr; } // Return errno for NVMe status SCT/SC fields: 0, EINVAL or EIO. int nvme_status_to_errno(uint16_t status) { if (!nvme_status_is_error(status)) return 0; const char * s = nvme_status_to_flagged_str(status); if (s && *s == '-') return EINVAL; return EIO; } // Return error message for NVMe status SCT/SC fields or nullptr if unknown. const char * nvme_status_to_str(uint16_t status) { const char * s = nvme_status_to_flagged_str(status); return (s && *s == '-' ? s + 1 : s); } // Return error message for NVMe status SCT/SC fields or explanatory message if unknown. const char * nvme_status_to_info_str(char * buf, size_t bufsize, uint16_t status) { const char * s = nvme_status_to_str(status); if (s) return s; uint8_t sct = (status >> 8) & 0x7, sc = (uint8_t)status; const char * pfx = (sc >= 0xc0 ? "Vendor Specific " : "Unknown "); switch (sct) { case 0x0: s = "Generic Command Status"; break; case 0x1: s = "Command Specific Status"; break; case 0x2: s = "Media and Data Integrity Error"; break; case 0x3: s = "Path Related Status"; break; case 0x7: s = "Vendor Specific Status"; pfx = ""; break; } if (s) snprintf(buf, bufsize, "%s%s 0x%02x", pfx, s, sc); else snprintf(buf, bufsize, "Unknown Status 0x%x/0x%02x", sct, sc); return buf; }