// Copyright 2022 The Prometheus Authors // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package main import ( "fmt" "log/slog" "regexp" "strings" "github.com/prometheus/client_golang/prometheus" "github.com/tidwall/gjson" ) // SMARTDevice - short info about device type SMARTDevice struct { device string serial string family string model string // These are used to select types of metrics. interface_ string protocol string } // SMARTctl object type SMARTctl struct { ch chan<- prometheus.Metric json gjson.Result logger *slog.Logger device SMARTDevice } func buildDeviceLabel(inputName string, inputType string) string { // Strip /dev prefix and replace / with _ (/dev/bus/0 becomes bus_0, /dev/disk/by-id/abcd becomes abcd) devReg := regexp.MustCompile(`^/dev/(?:disk/by-id/|disk/by-path/|)`) deviceName := strings.ReplaceAll(devReg.ReplaceAllString(inputName, ""), "/", "_") if strings.Contains(inputType, ",") { return deviceName + "_" + strings.ReplaceAll(inputType, ",", "_") } return deviceName } // NewSMARTctl is smartctl constructor func NewSMARTctl(logger *slog.Logger, json gjson.Result, ch chan<- prometheus.Metric) SMARTctl { var model_name string if obj := json.Get("model_name"); obj.Exists() { model_name = obj.String() } else if obj := json.Get("scsi_model_name"); obj.Exists() { model_name = obj.String() } // If the drive returns an empty model name, replace that with unknown. if model_name == "" { model_name = "unknown" } return SMARTctl{ ch: ch, json: json, logger: logger, device: SMARTDevice{ device: buildDeviceLabel(json.Get("device.name").String(), json.Get("device.type").String()), serial: strings.TrimSpace(json.Get("serial_number").String()), family: strings.TrimSpace(GetStringIfExists(json, "model_family", "unknown")), model: strings.TrimSpace(model_name), interface_: strings.TrimSpace(json.Get("device.type").String()), protocol: strings.TrimSpace(json.Get("device.protocol").String()), }, } } // Collect metrics func (smart *SMARTctl) Collect() { smart.logger.Debug("Collecting metrics from", "device", smart.device.device, "family", smart.device.family, "model", smart.device.model) smart.mineExitStatus() smart.mineDevice() smart.mineCapacity() smart.mineBlockSize() smart.mineInterfaceSpeed() smart.mineDeviceAttribute() smart.minePowerOnSeconds() smart.mineRotationRate() smart.mineTemperatures() smart.minePowerCycleCount() // ATA/SATA, NVME, SCSI, SAS smart.mineDeviceSCTStatus() smart.mineDeviceStatistics() smart.mineDeviceErrorLog() smart.mineDeviceSelfTestLog() smart.mineDeviceERC() smart.mineSmartStatus() if smart.device.interface_ == "nvme" { smart.mineNvmePercentageUsed() smart.mineNvmeAvailableSpare() smart.mineNvmeAvailableSpareThreshold() smart.mineNvmeCriticalWarning() smart.mineNvmeMediaErrors() smart.mineNvmeNumErrLogEntries() smart.mineNvmeBytesRead() smart.mineNvmeBytesWritten() } // SCSI, SAS if smart.device.interface_ == "scsi" { smart.mineSCSIGrownDefectList() smart.mineSCSIErrorCounterLog() smart.mineSCSIBytesRead() smart.mineSCSIBytesWritten() } } func (smart *SMARTctl) mineExitStatus() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceExitStatus, prometheus.GaugeValue, smart.json.Get("smartctl.exit_status").Float(), smart.device.device, ) } func (smart *SMARTctl) mineDevice() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceModel, prometheus.GaugeValue, 1, smart.device.device, smart.device.interface_, smart.device.protocol, smart.device.family, smart.device.model, smart.device.serial, GetStringIfExists(smart.json, "ata_additional_product_id", "unknown"), smart.json.Get("firmware_version").String(), smart.json.Get("ata_version.string").String(), smart.json.Get("sata_version.string").String(), smart.json.Get("form_factor.name").String(), // scsi_model_name is mapped into model_name smart.json.Get("scsi_vendor").String(), smart.json.Get("scsi_product").String(), smart.json.Get("scsi_revision").String(), smart.json.Get("scsi_version").String(), ) } func (smart *SMARTctl) mineCapacity() { // The user_capacity exists only when NVMe have single namespace. Otherwise, // for NVMe devices with multiple namespaces, when device name used without // namespace number (exporter case) user_capacity will be absent smart.ch <- prometheus.MustNewConstMetric( metricDeviceCapacityBlocks, prometheus.GaugeValue, smart.json.Get("user_capacity.blocks").Float(), smart.device.device, ) smart.ch <- prometheus.MustNewConstMetric( metricDeviceCapacityBytes, prometheus.GaugeValue, smart.json.Get("user_capacity.bytes").Float(), smart.device.device, ) nvme_total_capacity := smart.json.Get("nvme_total_capacity") if nvme_total_capacity.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceTotalCapacityBytes, prometheus.GaugeValue, nvme_total_capacity.Float(), smart.device.device, ) } } func (smart *SMARTctl) mineBlockSize() { for _, blockType := range []string{"logical", "physical"} { smart.ch <- prometheus.MustNewConstMetric( metricDeviceBlockSize, prometheus.GaugeValue, smart.json.Get(fmt.Sprintf("%s_block_size", blockType)).Float(), smart.device.device, blockType, ) } } func (smart *SMARTctl) mineInterfaceSpeed() { // TODO: Support scsi_sas_port_[01].phy_N.negotiated_logical_link_rate iSpeed := smart.json.Get("interface_speed") if iSpeed.Exists() { for _, speedType := range []string{"max", "current"} { tSpeed := iSpeed.Get(speedType) if tSpeed.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceInterfaceSpeed, prometheus.GaugeValue, tSpeed.Get("units_per_second").Float()*tSpeed.Get("bits_per_unit").Float(), smart.device.device, speedType, ) } } } } func (smart *SMARTctl) mineDeviceAttribute() { for _, attribute := range smart.json.Get("ata_smart_attributes.table").Array() { name := strings.TrimSpace(attribute.Get("name").String()) flagsShort := strings.TrimSpace(attribute.Get("flags.string").String()) flagsLong := smart.mineLongFlags(attribute.Get("flags"), []string{ "prefailure", "updated_online", "performance", "error_rate", "event_count", "auto_keep", }) id := attribute.Get("id").String() for key, path := range map[string]string{ "value": "value", "worst": "worst", "thresh": "thresh", "raw": "raw.value", } { smart.ch <- prometheus.MustNewConstMetric( metricDeviceAttribute, prometheus.GaugeValue, attribute.Get(path).Float(), smart.device.device, name, flagsShort, flagsLong, key, id, ) } } } func (smart *SMARTctl) minePowerOnSeconds() { pot := smart.json.Get("power_on_time") // If the power_on_time is NOT present, do not report as 0. if pot.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricDevicePowerOnSeconds, prometheus.CounterValue, GetFloatIfExists(pot, "hours", 0)*60*60+GetFloatIfExists(pot, "minutes", 0)*60, smart.device.device, ) } } func (smart *SMARTctl) mineRotationRate() { rRate := GetFloatIfExists(smart.json, "rotation_rate", 0) // TODO: what should be done if this is absent vs really zero (for // solid-state drives)? if rRate > 0 { smart.ch <- prometheus.MustNewConstMetric( metricDeviceRotationRate, prometheus.GaugeValue, rRate, smart.device.device, ) } } func (smart *SMARTctl) mineTemperatures() { temperatures := smart.json.Get("temperature") // TODO: Implement scsi_environmental_reports if temperatures.Exists() { temperatures.ForEach(func(key, value gjson.Result) bool { smart.ch <- prometheus.MustNewConstMetric( metricDeviceTemperature, prometheus.GaugeValue, value.Float(), smart.device.device, key.String(), ) return true }) } } func (smart *SMARTctl) minePowerCycleCount() { // ATA & NVME powerCycleCount := smart.json.Get("power_cycle_count") if powerCycleCount.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricDevicePowerCycleCount, prometheus.CounterValue, powerCycleCount.Float(), smart.device.device, ) return } // SCSI powerCycleCount = smart.json.Get("scsi_start_stop_cycle_counter.accumulated_start_stop_cycles") if powerCycleCount.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricDevicePowerCycleCount, prometheus.CounterValue, powerCycleCount.Float(), smart.device.device, ) return } } func (smart *SMARTctl) mineDeviceSCTStatus() { status := smart.json.Get("ata_sct_status") if status.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceState, prometheus.GaugeValue, status.Get("device_state").Float(), smart.device.device, ) } } func (smart *SMARTctl) mineNvmePercentageUsed() { smart.ch <- prometheus.MustNewConstMetric( metricDevicePercentageUsed, prometheus.CounterValue, smart.json.Get("nvme_smart_health_information_log.percentage_used").Float(), smart.device.device, ) } func (smart *SMARTctl) mineNvmeAvailableSpare() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceAvailableSpare, prometheus.CounterValue, smart.json.Get("nvme_smart_health_information_log.available_spare").Float(), smart.device.device, ) } func (smart *SMARTctl) mineNvmeAvailableSpareThreshold() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceAvailableSpareThreshold, prometheus.CounterValue, smart.json.Get("nvme_smart_health_information_log.available_spare_threshold").Float(), smart.device.device, ) } func (smart *SMARTctl) mineNvmeCriticalWarning() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceCriticalWarning, prometheus.CounterValue, smart.json.Get("nvme_smart_health_information_log.critical_warning").Float(), smart.device.device, ) } func (smart *SMARTctl) mineNvmeMediaErrors() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceMediaErrors, prometheus.CounterValue, smart.json.Get("nvme_smart_health_information_log.media_errors").Float(), smart.device.device, ) } func (smart *SMARTctl) mineNvmeNumErrLogEntries() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceNumErrLogEntries, prometheus.CounterValue, smart.json.Get("nvme_smart_health_information_log.num_err_log_entries").Float(), smart.device.device, ) } // https://nvmexpress.org/wp-content/uploads/NVM-Express-NVM-Command-Set-Specification-1.0d-2023.12.28-Ratified.pdf // 4.1.4.2 SMART / Health Information (02h) // The SMART / Health Information log page is as defined in the NVM Express Base Specification. For the // Data Units Read and Data Units Written fields, when the logical block size is a value other than 512 bytes, // the controller shall convert the amount of data read to 512 byte units. // https://nvmexpress.org/wp-content/uploads/NVM-Express-Base-Specification-2.0d-2024.01.11-Ratified.pdf // Figure 208: SMART / Health Information Log Page // Bytes 47:32 // Data Units Read: Contains the number of 512 byte data units the host has read from the // controller as part of processing a SMART Data Units Read Command; this value does not // include metadata. This value is reported in thousands (i.e., a value of 1 corresponds to 1,000 // units of 512 bytes read) and is rounded up (e.g., one indicates that the number of 512 byte // data units read is from 1 to 1,000, three indicates that the number of 512 byte data units read // is from 2,001 to 3,000). // // A value of 0h in this field indicates that the number of SMART Data Units Read is not reported. // // Bytes 63:48 // // Data Units Written: Contains the number of 512 byte data units the host has written to the ... // (the same as Data Units Read) func (smart *SMARTctl) mineNvmeBytesRead() { data_units_read := smart.json.Get("nvme_smart_health_information_log.data_units_read") // 0 => not reported by underlying hardware if !data_units_read.Exists() || data_units_read.Int() == 0 { return } smart.ch <- prometheus.MustNewConstMetric( metricDeviceBytesRead, prometheus.CounterValue, // WARNING: Float64 will lose precision when drives reach ~32EiB read/write // The underlying data_units_written,data_units_read are 128-bit integers data_units_read.Float()*1000.0*512.0, smart.device.device, ) } func (smart *SMARTctl) mineNvmeBytesWritten() { data_units_written := smart.json.Get("nvme_smart_health_information_log.data_units_written") // 0 => not reported by underlying hardware if !data_units_written.Exists() || data_units_written.Int() == 0 { return } smart.ch <- prometheus.MustNewConstMetric( metricDeviceBytesWritten, prometheus.CounterValue, // WARNING: Float64 will lose precision when drives reach ~32EiB read/write // The underlying data_units_written,data_units_read are 128-bit integers data_units_written.Float()*1000.0*512.0, smart.device.device, ) } func (smart *SMARTctl) mineSCSIBytesRead() { SCSIHealth := smart.json.Get("scsi_error_counter_log") if SCSIHealth.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceBytesRead, prometheus.CounterValue, // This value is reported by SMARTctl in GB [10^9]. // It is possible that some drives mis-report the value, but // that is not the responsibility of the exporter or smartctl SCSIHealth.Get("read.gigabytes_processed").Float()*1e9, smart.device.device, ) } } func (smart *SMARTctl) mineSCSIBytesWritten() { SCSIHealth := smart.json.Get("scsi_error_counter_log") if SCSIHealth.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceBytesWritten, prometheus.CounterValue, // This value is reported by SMARTctl in GB [10^9]. // It is possible that some drives mis-report the value, but // that is not the responsibility of the exporter or smartctl SCSIHealth.Get("write.gigabytes_processed").Float()*1e9, smart.device.device, ) } } func (smart *SMARTctl) mineSmartStatus() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceSmartStatus, prometheus.GaugeValue, smart.json.Get("smart_status.passed").Float(), smart.device.device, ) } func (smart *SMARTctl) mineDeviceStatistics() { for _, page := range smart.json.Get("ata_device_statistics.pages").Array() { table := strings.TrimSpace(page.Get("name").String()) // skip vendor-specific statistics (they lead to duplicate metric labels on Seagate Exos drives, // see https://github.com/Sheridan/smartctl_exporter/issues/3 for details) if table == "Vendor Specific Statistics" { continue } for _, statistic := range page.Get("table").Array() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceStatistics, prometheus.GaugeValue, statistic.Get("value").Float(), smart.device.device, table, strings.TrimSpace(statistic.Get("name").String()), strings.TrimSpace(statistic.Get("flags.string").String()), smart.mineLongFlags(statistic.Get("flags"), []string{ "valid", "normalized", "supports_dsn", "monitored_condition_met", }), ) } } for _, statistic := range smart.json.Get("sata_phy_event_counters.table").Array() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceStatistics, prometheus.GaugeValue, statistic.Get("value").Float(), smart.device.device, "SATA PHY Event Counters", strings.TrimSpace(statistic.Get("name").String()), "V---", "valid", ) } } func (smart *SMARTctl) mineLongFlags(json gjson.Result, flags []string) string { var result []string for _, flag := range flags { jFlag := json.Get(flag) if jFlag.Exists() && jFlag.Bool() { result = append(result, flag) } } return strings.Join(result, ",") } func (smart *SMARTctl) mineDeviceErrorLog() { for logType, status := range smart.json.Get("ata_smart_error_log").Map() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceErrorLogCount, prometheus.GaugeValue, status.Get("count").Float(), smart.device.device, logType, ) } } func (smart *SMARTctl) mineDeviceSelfTestLog() { for logType, status := range smart.json.Get("ata_smart_self_test_log").Map() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceSelfTestLogCount, prometheus.GaugeValue, status.Get("count").Float(), smart.device.device, logType, ) smart.ch <- prometheus.MustNewConstMetric( metricDeviceSelfTestLogErrorCount, prometheus.GaugeValue, status.Get("error_count_total").Float(), smart.device.device, logType, ) } } func (smart *SMARTctl) mineDeviceERC() { for ercType, status := range smart.json.Get("ata_sct_erc").Map() { smart.ch <- prometheus.MustNewConstMetric( metricDeviceERCSeconds, prometheus.GaugeValue, status.Get("deciseconds").Float()/10.0, smart.device.device, ercType, ) } } func (smart *SMARTctl) mineSCSIGrownDefectList() { scsi_grown_defect_list := smart.json.Get("scsi_grown_defect_list") if scsi_grown_defect_list.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricSCSIGrownDefectList, prometheus.GaugeValue, scsi_grown_defect_list.Float(), smart.device.device, ) } } func (smart *SMARTctl) mineSCSIErrorCounterLog() { SCSIHealth := smart.json.Get("scsi_error_counter_log") if SCSIHealth.Exists() { smart.ch <- prometheus.MustNewConstMetric( metricReadErrorsCorrectedByRereadsRewrites, prometheus.GaugeValue, SCSIHealth.Get("read.errors_corrected_by_rereads_rewrites").Float(), smart.device.device, ) smart.ch <- prometheus.MustNewConstMetric( metricReadErrorsCorrectedByEccFast, prometheus.GaugeValue, SCSIHealth.Get("read.errors_corrected_by_eccfast").Float(), smart.device.device, ) smart.ch <- prometheus.MustNewConstMetric( metricReadErrorsCorrectedByEccDelayed, prometheus.GaugeValue, SCSIHealth.Get("read.errors_corrected_by_eccdelayed").Float(), smart.device.device, ) smart.ch <- prometheus.MustNewConstMetric( metricReadTotalUncorrectedErrors, prometheus.GaugeValue, SCSIHealth.Get("read.total_uncorrected_errors").Float(), smart.device.device, ) smart.ch <- prometheus.MustNewConstMetric( metricWriteErrorsCorrectedByRereadsRewrites, prometheus.GaugeValue, SCSIHealth.Get("write.errors_corrected_by_rereads_rewrites").Float(), smart.device.device, ) smart.ch <- prometheus.MustNewConstMetric( metricWriteErrorsCorrectedByEccFast, prometheus.GaugeValue, SCSIHealth.Get("write.errors_corrected_by_eccfast").Float(), smart.device.device, ) smart.ch <- prometheus.MustNewConstMetric( metricWriteErrorsCorrectedByEccDelayed, prometheus.GaugeValue, SCSIHealth.Get("write.errors_corrected_by_eccdelayed").Float(), smart.device.device, ) smart.ch <- prometheus.MustNewConstMetric( metricWriteTotalUncorrectedErrors, prometheus.GaugeValue, SCSIHealth.Get("write.total_uncorrected_errors").Float(), smart.device.device, ) // TODO: Should we also export the verify category? } }