Pulse/internal/sensors/parser.go
rcourtman 2b7492ac59 feat: Add temperature collection to pulse-host-agent (related to #661)
Implements temperature monitoring in pulse-host-agent to support Docker-in-VM
deployments where the sensor proxy socket cannot cross VM boundaries.

Changes:
- Create internal/sensors package with local collection and parsing
- Add temperature collection to host agent (Linux only, best-effort)
- Support CPU package/core, NVMe, and GPU temperature sensors
- Update TEMPERATURE_MONITORING.md with Docker-in-VM setup instructions
- Update HOST_AGENT.md to document temperature feature

The host agent now automatically collects temperature data on Linux systems
with lm-sensors installed. This provides an alternative path for temperature
monitoring when running Pulse in a VM, avoiding the unix socket limitation.

Temperature collection is best-effort and fails gracefully if lm-sensors is
not available, ensuring other metrics continue to be reported.

Related to #661
2025-11-07 22:54:40 +00:00

248 lines
6.8 KiB
Go

package sensors
import (
"encoding/json"
"fmt"
"math"
"strings"
"github.com/rs/zerolog/log"
)
// TemperatureData contains parsed temperature readings from sensors
type TemperatureData struct {
CPUPackage float64 // Overall CPU package temperature
CPUMax float64 // Maximum CPU temperature
Cores map[string]float64 // Per-core temperatures (e.g., "Core 0": 45.0)
NVMe map[string]float64 // NVMe drive temperatures (e.g., "nvme0": 42.0)
GPU map[string]float64 // GPU temperatures (e.g., "amdgpu-pci-0400": 55.0)
Available bool // Whether any temperature data was found
}
// Parse extracts temperature data from sensors -j JSON output
func Parse(jsonStr string) (*TemperatureData, error) {
if strings.TrimSpace(jsonStr) == "" {
return nil, fmt.Errorf("empty sensors output")
}
var sensorsData map[string]interface{}
if err := json.Unmarshal([]byte(jsonStr), &sensorsData); err != nil {
return nil, fmt.Errorf("failed to parse sensors JSON: %w", err)
}
data := &TemperatureData{
Cores: make(map[string]float64),
NVMe: make(map[string]float64),
GPU: make(map[string]float64),
}
foundCPUChip := false
// Parse each sensor chip
for chipName, chipData := range sensorsData {
chipMap, ok := chipData.(map[string]interface{})
if !ok {
continue
}
chipLower := strings.ToLower(chipName)
// Handle CPU temperature sensors
if isCPUChip(chipLower) {
foundCPUChip = true
parseCPUTemps(chipMap, data)
}
// Handle NVMe temperature sensors
if strings.Contains(chipName, "nvme") {
parseNVMeTemps(chipName, chipMap, data)
}
// Handle GPU temperature sensors
if strings.Contains(chipLower, "amdgpu") || strings.Contains(chipLower, "nouveau") {
parseGPUTemps(chipName, chipMap, data)
}
}
// If we got CPU temps, calculate max from cores if package not available
if data.CPUPackage == 0 && len(data.Cores) > 0 {
for _, temp := range data.Cores {
if temp > data.CPUMax {
data.CPUMax = temp
}
}
// Use max core temp as package temp if not available
data.CPUPackage = data.CPUMax
}
data.Available = foundCPUChip || len(data.NVMe) > 0 || len(data.GPU) > 0
log.Debug().
Bool("available", data.Available).
Float64("cpuPackage", data.CPUPackage).
Float64("cpuMax", data.CPUMax).
Int("coreCount", len(data.Cores)).
Int("nvmeCount", len(data.NVMe)).
Int("gpuCount", len(data.GPU)).
Msg("Parsed temperature data")
return data, nil
}
func isCPUChip(chipLower string) bool {
cpuChips := []string{
"coretemp", "k10temp", "zenpower", "k8temp", "acpitz",
"it87", "nct6687", "nct6775", "nct6776", "nct6779",
"nct6791", "nct6792", "nct6793", "nct6795", "nct6796",
"nct6797", "nct6798", "w83627", "f71882",
"cpu_thermal", "rpitemp",
}
for _, chip := range cpuChips {
if strings.Contains(chipLower, chip) {
return true
}
}
return false
}
func parseCPUTemps(chipMap map[string]interface{}, data *TemperatureData) {
foundPackageTemp := false
var chipletTemps []float64
for sensorName, sensorData := range chipMap {
sensorMap, ok := sensorData.(map[string]interface{})
if !ok {
continue
}
sensorNameLower := strings.ToLower(sensorName)
// Look for Package id (Intel) or Tdie/Tctl (AMD)
if strings.Contains(sensorName, "Package id") ||
strings.Contains(sensorName, "Tdie") ||
strings.Contains(sensorNameLower, "tctl") {
if tempVal := extractTempInput(sensorMap); !math.IsNaN(tempVal) {
data.CPUPackage = tempVal
foundPackageTemp = true
if tempVal > data.CPUMax {
data.CPUMax = tempVal
}
}
}
// Look for AMD chiplet temperatures
if strings.HasPrefix(sensorName, "Tccd") {
if tempVal := extractTempInput(sensorMap); !math.IsNaN(tempVal) && tempVal > 0 {
chipletTemps = append(chipletTemps, tempVal)
if tempVal > data.CPUMax {
data.CPUMax = tempVal
}
}
}
// Look for SuperIO chip CPU temperature fields
if strings.Contains(sensorNameLower, "cputin") ||
strings.Contains(sensorNameLower, "cpu temperature") ||
(strings.Contains(sensorNameLower, "temp") && strings.Contains(sensorNameLower, "cpu")) {
if tempVal := extractTempInput(sensorMap); !math.IsNaN(tempVal) && tempVal > 0 {
if !foundPackageTemp {
data.CPUPackage = tempVal
foundPackageTemp = true
}
if tempVal > data.CPUMax {
data.CPUMax = tempVal
}
}
}
// Look for individual core temperatures
if strings.Contains(sensorName, "Core ") {
if tempVal := extractTempInput(sensorMap); !math.IsNaN(tempVal) {
data.Cores[sensorName] = tempVal
if tempVal > data.CPUMax {
data.CPUMax = tempVal
}
}
}
}
// If no package temp but we have chiplet temps, use highest chiplet
if !foundPackageTemp && len(chipletTemps) > 0 {
for _, temp := range chipletTemps {
if temp > data.CPUPackage {
data.CPUPackage = temp
}
}
}
}
func parseNVMeTemps(chipName string, chipMap map[string]interface{}, data *TemperatureData) {
for sensorName, sensorData := range chipMap {
sensorMap, ok := sensorData.(map[string]interface{})
if !ok {
continue
}
// Look for Composite temperature (main NVMe temp)
if strings.Contains(sensorName, "Composite") {
if tempVal := extractTempInput(sensorMap); !math.IsNaN(tempVal) {
data.NVMe[chipName] = tempVal
log.Debug().
Str("chip", chipName).
Float64("temp", tempVal).
Msg("Found NVMe temperature")
}
}
}
}
func parseGPUTemps(chipName string, chipMap map[string]interface{}, data *TemperatureData) {
for sensorName, sensorData := range chipMap {
sensorMap, ok := sensorData.(map[string]interface{})
if !ok {
continue
}
sensorNameLower := strings.ToLower(sensorName)
// Look for GPU temperature fields
if strings.Contains(sensorNameLower, "edge") ||
strings.Contains(sensorNameLower, "junction") ||
strings.Contains(sensorNameLower, "mem") ||
strings.Contains(sensorNameLower, "temp1") {
if tempVal := extractTempInput(sensorMap); !math.IsNaN(tempVal) {
// Use sensor name as key (e.g., "edge", "junction")
key := fmt.Sprintf("%s_%s", chipName, sensorName)
data.GPU[key] = tempVal
log.Debug().
Str("chip", chipName).
Str("sensor", sensorName).
Float64("temp", tempVal).
Msg("Found GPU temperature")
}
}
}
}
func extractTempInput(sensorMap map[string]interface{}) float64 {
// Look for temp*_input field (the actual temperature reading)
for key, value := range sensorMap {
if strings.HasSuffix(key, "_input") {
switch v := value.(type) {
case float64:
return v
case int:
return float64(v)
case string:
// Raspberry Pi reports in millidegrees as string
var milliTemp float64
if _, err := fmt.Sscanf(v, "%f", &milliTemp); err == nil {
// Convert from millidegrees to degrees
return milliTemp / 1000.0
}
}
}
}
return math.NaN()
}