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5 Commits
v8.18 ... v8.23

Author SHA1 Message Date
Mikhail Chusavitin
5285c0d101 Capture per-run IPMI power and GPU telemetry in power benchmark 
- Sample IPMI loaded_w per single-card calibration and per ramp step
  instead of averaging over the entire Phase 2; top-level ServerPower
  uses the final (all-GPU) ramp step value
- Add ServerLoadedW/ServerDeltaW to NvidiaPowerBenchGPU and
  NvidiaPowerBenchStep so external tooling can compare wall power per
  phase without re-parsing logs
- Write gpu-metrics.csv/.html inside each single-XX/ and step-XX/
  subdir; aggregate all phases into a top-level gpu-metrics.csv/.html
- Write 00-nvidia-smi-q.log at the start of every power run
- Add Telemetry (p95 temp/power/fan/clock) to NvidiaPowerBenchGPU in
  result.json from the converged calibration attempt
- Power benchmark page: split "Achieved W" into Single-card W and
  Multi-GPU W (StablePowerLimitW); derate highlight and status color
  now reflect the final multi-GPU limit vs nominal
- Performance benchmark page: add Status column and per-GPU score
  color coding (green/yellow/red) based on gpu.Status and OverallStatus

Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
 2026-04-17 17:59:58 +03:00
Mikhail Chusavitin
dca4afb8d0 Seed power ramp with single-card TDP limits 2026-04-16 11:43:01 +03:00
Mikhail Chusavitin
b4280941f5 Move NCCL and NVBandwidth into validate mode 2026-04-16 11:02:30 +03:00
Mikhail Chusavitin
f74976ec4c Use static overlay wallpaper in ISO build 2026-04-16 10:54:03 +03:00
Mikhail Chusavitin
18e24a9aa5 Estimate fan duty from observed RPM maxima 2026-04-16 10:10:18 +03:00
13 changed files with 557 additions and 250 deletions
Expand all files Collapse all files

11
audit/internal/app/app.go
View File

@@ -146,7 +146,7 @@ type satRunner interface {
RunSATStressPack(ctx context.Context, baseDir string, durationSec int, logFunc func(string)) (string, error)
RunFanStressTest(ctx context.Context, baseDir string, opts platform.FanStressOptions) (string, error)
RunPlatformStress(ctx context.Context, baseDir string, opts platform.PlatformStressOptions, logFunc func(string)) (string, error)
RunNCCLTests(ctx context.Context, baseDir string, logFunc func(string)) (string, error)
RunNCCLTests(ctx context.Context, baseDir string, gpuIndices []int, logFunc func(string)) (string, error)
}
type runtimeChecker interface {
@@ -744,8 +744,15 @@ func (a *App) RunPlatformStress(ctx context.Context, baseDir string, opts platfo
return a.sat.RunPlatformStress(ctx, baseDir, opts, logFunc)
}
func (a *App) RunNCCLTests(ctx context.Context, baseDir string, gpuIndices []int, logFunc func(string)) (string, error) {
if strings.TrimSpace(baseDir) == "" {
baseDir = DefaultSATBaseDir
}
return a.sat.RunNCCLTests(ctx, baseDir, gpuIndices, logFunc)
}
func (a *App) RunNCCLTestsResult(ctx context.Context) (ActionResult, error) {
path, err := a.sat.RunNCCLTests(ctx, DefaultSATBaseDir, nil)
path, err := a.RunNCCLTests(ctx, DefaultSATBaseDir, nil, nil)
body := "Results: " + path
if err != nil && err != context.Canceled {
body += "\nERROR: " + err.Error()

36
audit/internal/app/app_test.go
View File

@@ -128,6 +128,7 @@ type fakeSAT struct {
runNvidiaPowerFn func(string, int, []int) (string, error)
runNvidiaPulseFn func(string, int, []int) (string, error)
runNvidiaBandwidthFn func(string, []int) (string, error)
runNCCLFn func(string, []int) (string, error)
runNvidiaTargetedStressFn func(string, int, []int) (string, error)
runMemoryFn func(string) (string, error)
runStorageFn func(string) (string, error)
@@ -287,10 +288,43 @@ func (f fakeSAT) RunPlatformStress(_ context.Context, _ string, _ platform.Platf
return "", nil
}
func (f fakeSAT) RunNCCLTests(_ context.Context, _ string, _ func(string)) (string, error) {
func (f fakeSAT) RunNCCLTests(_ context.Context, baseDir string, gpuIndices []int, _ func(string)) (string, error) {
if f.runNCCLFn != nil {
return f.runNCCLFn(baseDir, gpuIndices)
}
return "", nil
}
func TestRunNCCLTestsPassesSelectedGPUs(t *testing.T) {
t.Parallel()
var gotBaseDir string
var gotGPUIndices []int
a := &App{
sat: fakeSAT{
runNCCLFn: func(baseDir string, gpuIndices []int) (string, error) {
gotBaseDir = baseDir
gotGPUIndices = append([]int(nil), gpuIndices...)
return "/tmp/nccl-tests.tar.gz", nil
},
},
}
path, err := a.RunNCCLTests(context.Background(), "/tmp/sat", []int{3, 1}, nil)
if err != nil {
t.Fatalf("RunNCCLTests error: %v", err)
}
if path != "/tmp/nccl-tests.tar.gz" {
t.Fatalf("path=%q want %q", path, "/tmp/nccl-tests.tar.gz")
}
if gotBaseDir != "/tmp/sat" {
t.Fatalf("baseDir=%q want %q", gotBaseDir, "/tmp/sat")
}
if len(gotGPUIndices) != 2 || gotGPUIndices[0] != 3 || gotGPUIndices[1] != 1 {
t.Fatalf("gpuIndices=%v want [3 1]", gotGPUIndices)
}
}
func TestNetworkStatusFormatsInterfacesAndRoute(t *testing.T) {
t.Parallel()

179
audit/internal/platform/benchmark.go
View File

@@ -59,6 +59,9 @@ type benchmarkPowerCalibrationResult struct {
// ≥20% while server fans were below 100% duty cycle — a signal that the
// cooling system may not be correctly configured for full GPU load.
CoolingWarning string
// MetricRows holds the telemetry rows from the final (converged) attempt
// for this GPU. Used to build per-run gpu-metrics.csv.
MetricRows []GPUMetricRow
}
type benchmarkBurnProfile struct {
@@ -1122,6 +1125,7 @@ type benchmarkCoolingSample struct {
AvgFanRPM float64
AvgFanDutyCyclePct float64
FanDutyCycleAvailable bool
FanDutyCycleEstimated bool
}
func sampleBenchmarkTelemetry(gpuIndices []int) ([]GPUMetricRow, error) {
@@ -1134,6 +1138,7 @@ func sampleBenchmarkTelemetry(gpuIndices []int) ([]GPUMetricRow, error) {
samples[i].FanAvgRPM = fanSample.AvgFanRPM
samples[i].FanDutyCyclePct = fanSample.AvgFanDutyCyclePct
samples[i].FanDutyCycleAvailable = fanSample.FanDutyCycleAvailable
samples[i].FanDutyCycleEstimated = fanSample.FanDutyCycleEstimated
}
return samples, nil
}
@@ -1141,11 +1146,12 @@ func sampleBenchmarkTelemetry(gpuIndices []int) ([]GPUMetricRow, error) {
func sampleBenchmarkCoolingSample() benchmarkCoolingSample {
fans, _ := sampleFanSpeeds()
avgRPM, _, _ := fanRPMStats(fans)
dutyPct, dutyAvailable := sampleFanDutyCyclePct()
dutyPct, dutyAvailable, dutyEstimated := sampleFanDutyCyclePctFromFans(fans)
return benchmarkCoolingSample{
AvgFanRPM: avgRPM,
AvgFanDutyCyclePct: dutyPct,
FanDutyCycleAvailable: dutyAvailable,
FanDutyCycleEstimated: dutyEstimated,
}
}
@@ -1387,25 +1393,33 @@ func summarizeBenchmarkCooling(rows []GPUMetricRow) *BenchmarkCoolingSummary {
}
var rpmValues []float64
var dutyValues []float64
var dutyEstimated bool
for _, row := range rows {
if row.FanAvgRPM > 0 {
rpmValues = append(rpmValues, row.FanAvgRPM)
}
if row.FanDutyCycleAvailable {
dutyValues = append(dutyValues, row.FanDutyCyclePct)
if row.FanDutyCycleEstimated {
dutyEstimated = true
}
}
}
if len(rpmValues) == 0 && len(dutyValues) == 0 {
return nil
}
summary := &BenchmarkCoolingSummary{
Available: true,
AvgFanRPM: benchmarkMean(rpmValues),
Available: true,
AvgFanRPM: benchmarkMean(rpmValues),
FanDutyCycleEstimated: dutyEstimated,
}
if len(dutyValues) > 0 {
summary.FanDutyCycleAvailable = true
summary.AvgFanDutyCyclePct = benchmarkMean(dutyValues)
summary.P95FanDutyCyclePct = benchmarkPercentile(dutyValues, 95)
if summary.FanDutyCycleEstimated {
summary.Notes = append(summary.Notes, "fan duty cycle is estimated from the highest fan RPM observed since boot; treat it as an approximation, not a direct PWM reading")
}
} else {
summary.Notes = append(summary.Notes, "fan duty cycle unavailable on this host; RPM-only fan telemetry was collected")
}
@@ -2770,7 +2784,7 @@ func runBenchmarkPowerCalibration(
infoByIndex map[int]benchmarkGPUInfo,
logFunc func(string),
seedLimits map[int]int,
) (map[int]benchmarkPowerCalibrationResult, []benchmarkRestoreAction) {
) (map[int]benchmarkPowerCalibrationResult, []benchmarkRestoreAction, []GPUMetricRow) {
const calibDurationSec = 120
const maxDerateW = 150
// calibSearchTolerance is the binary-search convergence threshold in watts.
@@ -2784,7 +2798,7 @@ func runBenchmarkPowerCalibration(
if _, err := exec.LookPath("dcgmi"); err != nil {
logFunc("power calibration: dcgmi not found, skipping (will use default power limit)")
return map[int]benchmarkPowerCalibrationResult{}, nil
return map[int]benchmarkPowerCalibrationResult{}, nil, nil
}
if killed := KillTestWorkers(); len(killed) > 0 {
for _, p := range killed {
@@ -2818,6 +2832,8 @@ func runBenchmarkPowerCalibration(
results := make(map[int]benchmarkPowerCalibrationResult, len(gpuIndices))
var restore []benchmarkRestoreAction
var allCalibRows []GPUMetricRow // accumulated telemetry across all attempts
var calibCursor float64
// Initialise per-GPU state.
states := make([]*gpuCalibState, 0, len(gpuIndices))
@@ -2970,6 +2986,8 @@ calibDone:
ticker.Stop()
cancelAttempt()
_ = os.WriteFile(filepath.Join(runDir, logName), ar.out, 0644)
// Accumulate telemetry rows with attempt stage label.
appendBenchmarkMetrics(&allCalibRows, ar.rows, fmt.Sprintf("attempt-%d", sharedAttempt), &calibCursor, float64(calibDurationSec))
// Resource busy: retry with exponential back-off (shared — one DCGM session).
if ar.err != nil && isDCGMResourceBusy(ar.err) {
@@ -3054,6 +3072,7 @@ calibDone:
}
}
}
s.calib.MetricRows = filterRowsByGPU(ar.rows, s.idx)
s.converged = true
continue
}
@@ -3092,6 +3111,7 @@ calibDone:
} else {
s.calib.Notes = append(s.calib.Notes, fmt.Sprintf("could not find a stable targeted_power limit within %d W of the default", maxDerateW))
}
s.calib.MetricRows = filterRowsByGPU(ar.rows, s.idx)
s.converged = true
continue
}
@@ -3129,7 +3149,8 @@ calibDone:
results[s.idx] = s.calib
}
}
return results, restore
writeBenchmarkMetricsFiles(runDir, allCalibRows)
return results, restore, allCalibRows
}
// isDCGMResourceBusy returns true when dcgmi exits with DCGM_ST_IN_USE (222),
@@ -3219,21 +3240,25 @@ func renderPowerBenchReport(result NvidiaPowerBenchResult) string {
}
if len(result.RampSteps) > 0 {
b.WriteString("## Ramp Sequence\n\n")
b.WriteString("| Step | New GPU | Stable Limit | Total Observed | Derated | Status |\n")
b.WriteString("|------|---------|--------------|----------------|---------|--------|\n")
b.WriteString("| Step | New GPU | Stable Limit | Total Observed | Server Δ (IPMI) | Derated | Status |\n")
b.WriteString("|------|---------|--------------|----------------|-----------------|---------|--------|\n")
for _, step := range result.RampSteps {
derated := "-"
if step.Derated {
derated = "⚠ yes"
}
fmt.Fprintf(&b, "| %d | GPU %d | %.0f W | %.0f W | %s | %s |\n",
step.StepIndex, step.NewGPUIndex, step.NewGPUStableLimitW, step.TotalObservedPowerW, derated, step.Status)
serverDelta := "-"
if step.ServerDeltaW > 0 {
serverDelta = fmt.Sprintf("%.0f W", step.ServerDeltaW)
}
fmt.Fprintf(&b, "| %d | GPU %d | %.0f W | %.0f W | %s | %s | %s |\n",
step.StepIndex, step.NewGPUIndex, step.NewGPUStableLimitW, step.TotalObservedPowerW, serverDelta, derated, step.Status)
}
b.WriteString("\n")
}
b.WriteString("## Per-Slot Results\n\n")
b.WriteString("| GPU | Status | Single-card Limit | Stable Limit | Temp | Attempts |\n")
b.WriteString("|-----|--------|-------------------|--------------|------|----------|\n")
b.WriteString("| GPU | Status | Single-card Limit | Stable Limit | Server Δ (IPMI) | Temp | Attempts |\n")
b.WriteString("|-----|--------|-------------------|--------------|-----------------|------|----------|\n")
for _, gpu := range result.GPUs {
stableLimit := "-"
if gpu.StablePowerLimitW > 0 {
@@ -3243,8 +3268,12 @@ func renderPowerBenchReport(result NvidiaPowerBenchResult) string {
stableLimit = fmt.Sprintf("%.0f W", gpu.StablePowerLimitW)
}
}
fmt.Fprintf(&b, "| GPU %d | %s | %.0f W | %s | %.1f C | %d |\n",
gpu.Index, gpu.Status, gpu.AppliedPowerLimitW, stableLimit, gpu.MaxObservedTempC, gpu.CalibrationAttempts)
serverDelta := "-"
if gpu.ServerDeltaW > 0 {
serverDelta = fmt.Sprintf("%.0f W", gpu.ServerDeltaW)
}
fmt.Fprintf(&b, "| GPU %d | %s | %.0f W | %s | %s | %.1f C | %d |\n",
gpu.Index, gpu.Status, gpu.AppliedPowerLimitW, stableLimit, serverDelta, gpu.MaxObservedTempC, gpu.CalibrationAttempts)
}
b.WriteString("\n")
for _, gpu := range result.GPUs {
@@ -3273,11 +3302,19 @@ func renderPowerBenchSummary(result NvidiaPowerBenchResult) string {
fmt.Fprintf(&b, "ramp_step_%d_new_gpu=%d\n", step.StepIndex, step.NewGPUIndex)
fmt.Fprintf(&b, "ramp_step_%d_stable_limit_w=%.0f\n", step.StepIndex, step.NewGPUStableLimitW)
fmt.Fprintf(&b, "ramp_step_%d_total_power_w=%.0f\n", step.StepIndex, step.TotalObservedPowerW)
if step.ServerLoadedW > 0 {
fmt.Fprintf(&b, "ramp_step_%d_server_loaded_w=%.0f\n", step.StepIndex, step.ServerLoadedW)
fmt.Fprintf(&b, "ramp_step_%d_server_delta_w=%.0f\n", step.StepIndex, step.ServerDeltaW)
}
}
for _, gpu := range result.GPUs {
if gpu.StablePowerLimitW > 0 {
fmt.Fprintf(&b, "gpu_%d_stable_limit_w=%.0f\n", gpu.Index, gpu.StablePowerLimitW)
}
if gpu.ServerLoadedW > 0 {
fmt.Fprintf(&b, "gpu_%d_server_loaded_w=%.0f\n", gpu.Index, gpu.ServerLoadedW)
fmt.Fprintf(&b, "gpu_%d_server_delta_w=%.0f\n", gpu.Index, gpu.ServerDeltaW)
}
}
if sp := result.ServerPower; sp != nil && sp.Available {
fmt.Fprintf(&b, "server_idle_w=%.0f\n", sp.IdleW)
@@ -3316,6 +3353,10 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
if infoErr != nil {
return "", infoErr
}
// Capture full nvidia-smi -q snapshot at the start of the run.
if out, err := runSATCommandCtx(ctx, verboseLog, "00-nvidia-smi-q.log", []string{"nvidia-smi", "-q"}, nil, nil); err == nil {
_ = os.WriteFile(filepath.Join(runDir, "00-nvidia-smi-q.log"), out, 0644)
}
hostname, _ := os.Hostname()
result := NvidiaPowerBenchResult{
BenchmarkVersion: benchmarkVersion,
@@ -3341,13 +3382,31 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
// Phase 1: calibrate each GPU individually (sequentially, one at a time) to
// establish a true single-card power baseline unaffected by neighbour heat.
calibByIndex := make(map[int]benchmarkPowerCalibrationResult, len(selected))
singleIPMILoadedW := make(map[int]float64, len(selected))
var allRestoreActions []benchmarkRestoreAction
// allPowerRows accumulates telemetry from all phases for the top-level gpu-metrics.csv.
var allPowerRows []GPUMetricRow
var powerCursor float64
for _, idx := range selected {
singleDir := filepath.Join(runDir, fmt.Sprintf("single-%02d", idx))
_ = os.MkdirAll(singleDir, 0755)
singleInfo := cloneBenchmarkGPUInfoMap(infoByIndex)
logFunc(fmt.Sprintf("power calibration: GPU %d single-card baseline", idx))
c, restore := runBenchmarkPowerCalibration(ctx, verboseLog, singleDir, []int{idx}, singleInfo, logFunc, nil)
ipmiSingleCtx, ipmiSingleCancel := context.WithCancel(ctx)
ipmiSingleDone := make(chan float64, 1)
go func() {
defer close(ipmiSingleDone)
if w, ok := sampleIPMIPowerSeries(ipmiSingleCtx, 3600); ok {
ipmiSingleDone <- w
}
}()
c, restore, singleRows := runBenchmarkPowerCalibration(ctx, verboseLog, singleDir, []int{idx}, singleInfo, logFunc, nil)
appendBenchmarkMetrics(&allPowerRows, singleRows, fmt.Sprintf("single-gpu-%d", idx), &powerCursor, 0)
ipmiSingleCancel()
if w, ok := <-ipmiSingleDone; ok {
singleIPMILoadedW[idx] = w
logFunc(fmt.Sprintf("power calibration: GPU %d single-card IPMI loaded: %.0f W", idx, w))
}
allRestoreActions = append(allRestoreActions, restore...)
if r, ok := c[idx]; ok {
calibByIndex[idx] = r
@@ -3372,7 +3431,7 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
result.OverallStatus = "PARTIAL"
}
}
gpus = append(gpus, NvidiaPowerBenchGPU{
gpu := NvidiaPowerBenchGPU{
Index: idx,
Name: info.Name,
BusID: info.BusID,
@@ -3385,7 +3444,16 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
Status: status,
Notes: append([]string(nil), calib.Notes...),
CoolingWarning: calib.CoolingWarning,
})
}
if w, ok := singleIPMILoadedW[idx]; ok && serverIdleOK && w > 0 {
gpu.ServerLoadedW = w
gpu.ServerDeltaW = w - serverIdleW
}
if len(calib.MetricRows) > 0 {
t := summarizeBenchmarkTelemetry(calib.MetricRows)
gpu.Telemetry = &t
}
gpus = append(gpus, gpu)
}
sort.Slice(gpus, func(i, j int) bool {
if gpus[i].MaxObservedPowerW != gpus[j].MaxObservedPowerW {
@@ -3434,20 +3502,11 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
// stableLimits accumulates GPU index → fixed stable limit (W) across steps.
stableLimits := make(map[int]int, len(result.RecommendedSlotOrder))
// Start an IPMI sampling goroutine that runs throughout Phase 2 to capture
// server-side loaded power while GPUs are under stress. The goroutine is
// cancelled as soon as Phase 2 finishes, and the average is used to compare
// against PlatformMaxTDPW (GPU-reported stable limits sum).
// serverLoadedW tracks the IPMI server power from the final ramp step
// (all GPUs simultaneously loaded). Earlier steps' values are stored
// per-step in NvidiaPowerBenchStep.ServerLoadedW.
var serverLoadedW float64
var serverLoadedOK bool
ipmiPhase2Ctx, ipmiPhase2Cancel := context.WithCancel(ctx)
ipmiPhase2Done := make(chan float64, 1)
go func() {
defer close(ipmiPhase2Done)
if w, ok := sampleIPMIPowerSeries(ipmiPhase2Ctx, 3600); ok {
ipmiPhase2Done <- w
}
}()
// Step 1: reuse single-card calibration result directly.
if len(result.RecommendedSlotOrder) > 0 {
@@ -3464,6 +3523,10 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
Derated: firstCalib.Derated,
Status: "OK",
}
if w, ok := singleIPMILoadedW[firstIdx]; ok && serverIdleOK && w > 0 {
ramp.ServerLoadedW = w
ramp.ServerDeltaW = w - serverIdleW
}
if !firstCalib.Completed {
ramp.Status = "FAILED"
ramp.Notes = append(ramp.Notes, fmt.Sprintf("GPU %d did not complete single-card targeted_power", firstIdx))
@@ -3491,17 +3554,45 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
_ = os.MkdirAll(stepDir, 0755)
// Reuse the latest stable limits as starting points, but re-check every
// active GPU in this hotter configuration.
seedForStep := make(map[int]int, len(stableLimits))
for k, v := range stableLimits {
seedForStep[k] = v
// active GPU in this hotter configuration. For the newly introduced GPU,
// seed from its single-card calibration so we do not restart from the
// default TDP when a prior derated limit is already known.
seedForStep := make(map[int]int, len(subset))
for _, idx := range subset {
if lim, ok := stableLimits[idx]; ok && lim > 0 {
seedForStep[idx] = lim
continue
}
if base, ok := calibByIndex[idx]; ok {
lim := int(math.Round(base.AppliedPowerLimitW))
if lim > 0 {
seedForStep[idx] = lim
}
}
}
logFunc(fmt.Sprintf("power ramp: step %d/%d — revalidating %d active GPU(s) including new GPU %d",
step, len(result.RecommendedSlotOrder), len(subset), newGPUIdx))
stepInfo := cloneBenchmarkGPUInfoMap(infoByIndex)
stepCalib, stepRestore := runBenchmarkPowerCalibration(ctx, verboseLog, stepDir, subset, stepInfo, logFunc, seedForStep)
ipmiStepCtx, ipmiStepCancel := context.WithCancel(ctx)
ipmiStepDone := make(chan float64, 1)
go func() {
defer close(ipmiStepDone)
if w, ok := sampleIPMIPowerSeries(ipmiStepCtx, 3600); ok {
ipmiStepDone <- w
}
}()
stepCalib, stepRestore, stepRows := runBenchmarkPowerCalibration(ctx, verboseLog, stepDir, subset, stepInfo, logFunc, seedForStep)
appendBenchmarkMetrics(&allPowerRows, stepRows, fmt.Sprintf("ramp-step-%d", step), &powerCursor, 0)
ipmiStepCancel()
var stepIPMILoadedW float64
var stepIPMIOK bool
if w, ok := <-ipmiStepDone; ok {
stepIPMILoadedW = w
stepIPMIOK = true
logFunc(fmt.Sprintf("power ramp: step %d IPMI loaded: %.0f W", step, w))
}
// Accumulate restore actions; they all run in the outer defer.
allRestoreActions = append(allRestoreActions, stepRestore...)
@@ -3564,15 +3655,17 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
result.Findings = append(result.Findings, fmt.Sprintf("Ramp step %d (GPU %d) required derating to %.0f W under combined thermal load.", step, newGPUIdx, c.AppliedPowerLimitW))
}
result.RampSteps = append(result.RampSteps, ramp)
}
if stepIPMIOK && serverIdleOK && stepIPMILoadedW > 0 {
ramp.ServerLoadedW = stepIPMILoadedW
ramp.ServerDeltaW = stepIPMILoadedW - serverIdleW
// The last step has all GPUs loaded — use it as the top-level loaded_w.
if step == len(result.RecommendedSlotOrder) {
serverLoadedW = stepIPMILoadedW
serverLoadedOK = true
}
}
// Stop IPMI Phase 2 sampling and collect result.
ipmiPhase2Cancel()
if w, ok := <-ipmiPhase2Done; ok {
serverLoadedW = w
serverLoadedOK = true
logFunc(fmt.Sprintf("server loaded power (IPMI, Phase 2 avg): %.0f W", w))
result.RampSteps = append(result.RampSteps, ramp)
}
// Populate StablePowerLimitW on each GPU entry from the accumulated stable limits.
@@ -3602,6 +3695,8 @@ func (s *System) RunNvidiaPowerBench(ctx context.Context, baseDir string, opts N
// ~1.0 → GPU telemetry matches wall power; <0.75 → GPU over-reports its TDP.
_ = serverIdleOK // used implicitly via characterizeServerPower
result.ServerPower = characterizeServerPower(serverIdleW, serverLoadedW, result.PlatformMaxTDPW, serverIdleOK && serverLoadedOK)
// Write top-level gpu-metrics.csv/.html aggregating all phases.
writeBenchmarkMetricsFiles(runDir, allPowerRows)
resultJSON, err := json.MarshalIndent(result, "", " ")
if err != nil {
return "", fmt.Errorf("marshal power result: %w", err)

100
audit/internal/platform/benchmark_types.go
View File

@@ -31,6 +31,7 @@ type BenchmarkCoolingSummary struct {
Available bool `json:"available"`
AvgFanRPM float64 `json:"avg_fan_rpm,omitempty"`
FanDutyCycleAvailable bool `json:"fan_duty_cycle_available,omitempty"`
FanDutyCycleEstimated bool `json:"fan_duty_cycle_estimated,omitempty"`
AvgFanDutyCyclePct float64 `json:"avg_fan_duty_cycle_pct,omitempty"`
P95FanDutyCyclePct float64 `json:"p95_fan_duty_cycle_pct,omitempty"`
Notes []string `json:"notes,omitempty"`
@@ -55,32 +56,32 @@ type NvidiaBenchmarkOptions struct {
}
type NvidiaBenchmarkResult struct {
BenchmarkVersion string `json:"benchmark_version"`
GeneratedAt time.Time `json:"generated_at"`
Hostname string `json:"hostname,omitempty"`
ServerModel string `json:"server_model,omitempty"`
BenchmarkProfile string `json:"benchmark_profile"`
ParallelGPUs bool `json:"parallel_gpus,omitempty"`
RampStep int `json:"ramp_step,omitempty"`
RampTotal int `json:"ramp_total,omitempty"`
RampRunID string `json:"ramp_run_id,omitempty"`
ScalabilityScore float64 `json:"scalability_score,omitempty"`
BenchmarkVersion string `json:"benchmark_version"`
GeneratedAt time.Time `json:"generated_at"`
Hostname string `json:"hostname,omitempty"`
ServerModel string `json:"server_model,omitempty"`
BenchmarkProfile string `json:"benchmark_profile"`
ParallelGPUs bool `json:"parallel_gpus,omitempty"`
RampStep int `json:"ramp_step,omitempty"`
RampTotal int `json:"ramp_total,omitempty"`
RampRunID string `json:"ramp_run_id,omitempty"`
ScalabilityScore float64 `json:"scalability_score,omitempty"`
// PlatformPowerScore is the mean compute scalability across ramp steps 2..N.
// 100% = each added GPU contributes exactly its single-card throughput.
// < 100% = throughput loss due to thermal throttle, power limits, or contention.
PlatformPowerScore float64 `json:"platform_power_score,omitempty"`
PerformanceRampSteps []NvidiaPerformanceRampStep `json:"performance_ramp_steps,omitempty"`
OverallStatus string `json:"overall_status"`
SelectedGPUIndices []int `json:"selected_gpu_indices"`
Findings []string `json:"findings,omitempty"`
Warnings []string `json:"warnings,omitempty"`
Normalization BenchmarkNormalization `json:"normalization"`
HostConfig *BenchmarkHostConfig `json:"host_config,omitempty"`
CPULoad *BenchmarkCPULoad `json:"cpu_load,omitempty"`
Cooling *BenchmarkCoolingSummary `json:"cooling,omitempty"`
GPUs []BenchmarkGPUResult `json:"gpus"`
Interconnect *BenchmarkInterconnectResult `json:"interconnect,omitempty"`
ServerPower *BenchmarkServerPower `json:"server_power,omitempty"`
PlatformPowerScore float64 `json:"platform_power_score,omitempty"`
PerformanceRampSteps []NvidiaPerformanceRampStep `json:"performance_ramp_steps,omitempty"`
OverallStatus string `json:"overall_status"`
SelectedGPUIndices []int `json:"selected_gpu_indices"`
Findings []string `json:"findings,omitempty"`
Warnings []string `json:"warnings,omitempty"`
Normalization BenchmarkNormalization `json:"normalization"`
HostConfig *BenchmarkHostConfig `json:"host_config,omitempty"`
CPULoad *BenchmarkCPULoad `json:"cpu_load,omitempty"`
Cooling *BenchmarkCoolingSummary `json:"cooling,omitempty"`
GPUs []BenchmarkGPUResult `json:"gpus"`
Interconnect *BenchmarkInterconnectResult `json:"interconnect,omitempty"`
ServerPower *BenchmarkServerPower `json:"server_power,omitempty"`
}
type BenchmarkNormalization struct {
@@ -223,8 +224,8 @@ type BenchmarkScorecard struct {
// Throttle breakdown — percentage of steady-state time in each throttle type.
// Used for diagnosis: tells WHY the GPU throttled, not just whether it did.
ThermalThrottlePct float64 `json:"thermal_throttle_pct"` // HW+SW thermal slowdown
PowerCapThrottlePct float64 `json:"power_cap_throttle_pct"` // SW power cap
ThermalThrottlePct float64 `json:"thermal_throttle_pct"` // HW+SW thermal slowdown
PowerCapThrottlePct float64 `json:"power_cap_throttle_pct"` // SW power cap
SyncBoostThrottlePct float64 `json:"sync_boost_throttle_pct,omitempty"`
// Temperature headroom: distance to the 100°C destruction threshold.
@@ -300,22 +301,22 @@ type NvidiaPowerBenchResult struct {
// PlatformMaxTDPW is the sum of per-GPU stable power limits found during the
// cumulative thermal ramp. Represents the actual sustained power budget of
// this server under full GPU load. Use for rack power planning.
PlatformMaxTDPW float64 `json:"platform_max_tdp_w"`
PlatformMaxTDPW float64 `json:"platform_max_tdp_w"`
// ServerPower captures IPMI server power delta (idle→loaded) measured in
// parallel with the thermal ramp. Use to compare GPU-reported TDP against
// actual wall-power draw as seen by the server's power supply.
ServerPower *BenchmarkServerPower `json:"server_power,omitempty"`
Findings []string `json:"findings,omitempty"`
GPUs []NvidiaPowerBenchGPU `json:"gpus"`
ServerPower *BenchmarkServerPower `json:"server_power,omitempty"`
Findings []string `json:"findings,omitempty"`
GPUs []NvidiaPowerBenchGPU `json:"gpus"`
}
type NvidiaPowerBenchGPU struct {
Index int `json:"index"`
Name string `json:"name,omitempty"`
BusID string `json:"bus_id,omitempty"`
DefaultPowerLimitW float64 `json:"default_power_limit_w,omitempty"`
Index int `json:"index"`
Name string `json:"name,omitempty"`
BusID string `json:"bus_id,omitempty"`
DefaultPowerLimitW float64 `json:"default_power_limit_w,omitempty"`
// AppliedPowerLimitW is the stable limit found during single-card calibration.
AppliedPowerLimitW float64 `json:"applied_power_limit_w,omitempty"`
AppliedPowerLimitW float64 `json:"applied_power_limit_w,omitempty"`
// StablePowerLimitW is the final fixed limit for this GPU after the
// cumulative thermal ramp. This is the limit at which the GPU operated
// stably with all other GPUs running simultaneously at their own limits.
@@ -330,13 +331,20 @@ type NvidiaPowerBenchGPU struct {
Notes []string `json:"notes,omitempty"`
// CoolingWarning mirrors BenchmarkGPUResult.CoolingWarning for the power workflow.
CoolingWarning string `json:"cooling_warning,omitempty"`
// ServerLoadedW is the IPMI server power reading captured during this
// GPU's single-card calibration run. ServerDeltaW = ServerLoadedW idle.
ServerLoadedW float64 `json:"server_loaded_w,omitempty"`
ServerDeltaW float64 `json:"server_delta_w,omitempty"`
// Telemetry holds the aggregated stats from the final converged calibration
// attempt for this GPU (temperature, power, fan, clock percentiles).
Telemetry *BenchmarkTelemetrySummary `json:"telemetry,omitempty"`
}
type NvidiaPowerBenchStep struct {
StepIndex int `json:"step_index"`
GPUIndices []int `json:"gpu_indices"`
StepIndex int `json:"step_index"`
GPUIndices []int `json:"gpu_indices"`
// NewGPUIndex is the GPU whose stable limit was searched in this step.
NewGPUIndex int `json:"new_gpu_index"`
NewGPUIndex int `json:"new_gpu_index"`
// NewGPUStableLimitW is the stable power limit found for the new GPU.
NewGPUStableLimitW float64 `json:"new_gpu_stable_limit_w,omitempty"`
TotalObservedPowerW float64 `json:"total_observed_power_w,omitempty"`
@@ -344,20 +352,24 @@ type NvidiaPowerBenchStep struct {
Derated bool `json:"derated,omitempty"`
Status string `json:"status"`
Notes []string `json:"notes,omitempty"`
// ServerLoadedW is the IPMI server power reading captured during this
// ramp step's calibration run. ServerDeltaW = ServerLoadedW idle.
ServerLoadedW float64 `json:"server_loaded_w,omitempty"`
ServerDeltaW float64 `json:"server_delta_w,omitempty"`
}
// NvidiaPerformanceRampStep holds per-step performance data for the
// scalability ramp-up phase of the performance benchmark.
type NvidiaPerformanceRampStep struct {
StepIndex int `json:"step_index"`
GPUIndices []int `json:"gpu_indices"`
StepIndex int `json:"step_index"`
GPUIndices []int `json:"gpu_indices"`
// TotalSyntheticTOPS is the sum of per-GPU SyntheticScore (fp32-equivalent
// TOPS from dedicated single-precision phases) across all GPUs in this step.
TotalSyntheticTOPS float64 `json:"total_synthetic_tops"`
TotalMixedTOPS float64 `json:"total_mixed_tops,omitempty"`
TotalSyntheticTOPS float64 `json:"total_synthetic_tops"`
TotalMixedTOPS float64 `json:"total_mixed_tops,omitempty"`
// ScalabilityPct = TotalSyntheticTOPS / (k × best_single_gpu_tops) × 100.
// 100% = perfect linear scaling. < 100% = thermal/power/interconnect loss.
ScalabilityPct float64 `json:"scalability_pct"`
Status string `json:"status"`
Notes []string `json:"notes,omitempty"`
ScalabilityPct float64 `json:"scalability_pct"`
Status string `json:"status"`
Notes []string `json:"notes,omitempty"`
}

11
audit/internal/platform/gpu_metrics.go
View File

@@ -27,6 +27,7 @@ type GPUMetricRow struct {
FanAvgRPM float64 `json:"fan_avg_rpm,omitempty"`
FanDutyCyclePct float64 `json:"fan_duty_cycle_pct,omitempty"`
FanDutyCycleAvailable bool `json:"fan_duty_cycle_available,omitempty"`
FanDutyCycleEstimated bool `json:"fan_duty_cycle_estimated,omitempty"`
}
// sampleGPUMetrics runs nvidia-smi once and returns current metrics for each GPU.
@@ -147,14 +148,18 @@ func sampleAMDGPUMetrics() ([]GPUMetricRow, error) {
// WriteGPUMetricsCSV writes collected rows as a CSV file.
func WriteGPUMetricsCSV(path string, rows []GPUMetricRow) error {
var b bytes.Buffer
b.WriteString("stage,elapsed_sec,gpu_index,temperature_c,usage_pct,mem_usage_pct,power_w,clock_mhz,mem_clock_mhz,fan_avg_rpm,fan_duty_cycle_pct,fan_duty_cycle_available\n")
b.WriteString("stage,elapsed_sec,gpu_index,temperature_c,usage_pct,mem_usage_pct,power_w,clock_mhz,mem_clock_mhz,fan_avg_rpm,fan_duty_cycle_pct,fan_duty_cycle_available,fan_duty_cycle_estimated\n")
for _, r := range rows {
dutyAvail := 0
if r.FanDutyCycleAvailable {
dutyAvail = 1
}
fmt.Fprintf(&b, "%s,%.1f,%d,%.1f,%.1f,%.1f,%.1f,%.0f,%.0f,%.0f,%.1f,%d\n",
strconv.Quote(strings.TrimSpace(r.Stage)), r.ElapsedSec, r.GPUIndex, r.TempC, r.UsagePct, r.MemUsagePct, r.PowerW, r.ClockMHz, r.MemClockMHz, r.FanAvgRPM, r.FanDutyCyclePct, dutyAvail)
dutyEstimated := 0
if r.FanDutyCycleEstimated {
dutyEstimated = 1
}
fmt.Fprintf(&b, "%s,%.1f,%d,%.1f,%.1f,%.1f,%.1f,%.0f,%.0f,%.0f,%.1f,%d,%d\n",
strconv.Quote(strings.TrimSpace(r.Stage)), r.ElapsedSec, r.GPUIndex, r.TempC, r.UsagePct, r.MemUsagePct, r.PowerW, r.ClockMHz, r.MemClockMHz, r.FanAvgRPM, r.FanDutyCyclePct, dutyAvail, dutyEstimated)
}
return os.WriteFile(path, b.Bytes(), 0644)
}

14
audit/internal/platform/sat.go
View File

@@ -366,12 +366,14 @@ func (s *System) ResetNvidiaGPU(index int) (string, error) {
return string(raw), err
}
// RunNCCLTests runs nccl-tests all_reduce_perf across all NVIDIA GPUs.
// RunNCCLTests runs nccl-tests all_reduce_perf across the selected NVIDIA GPUs.
// Measures collective communication bandwidth over NVLink/PCIe.
func (s *System) RunNCCLTests(ctx context.Context, baseDir string, logFunc func(string)) (string, error) {
// detect GPU count
out, _ := exec.Command("nvidia-smi", "--query-gpu=index", "--format=csv,noheader").Output()
gpuCount := len(strings.Split(strings.TrimSpace(string(out)), "\n"))
func (s *System) RunNCCLTests(ctx context.Context, baseDir string, gpuIndices []int, logFunc func(string)) (string, error) {
selected, err := resolveDCGMGPUIndices(gpuIndices)
if err != nil {
return "", err
}
gpuCount := len(selected)
if gpuCount < 1 {
gpuCount = 1
}
@@ -380,7 +382,7 @@ func (s *System) RunNCCLTests(ctx context.Context, baseDir string, logFunc func(
satJob{name: "02-all-reduce-perf.log", cmd: []string{
"all_reduce_perf", "-b", "512M", "-e", "4G", "-f", "2",
"-g", strconv.Itoa(gpuCount), "--iters", "20",
}},
}, env: nvidiaVisibleDevicesEnv(selected)},
), logFunc)
}

161
audit/internal/platform/sat_fan_stress.go
View File

@@ -4,6 +4,7 @@ import (
"context"
"encoding/json"
"fmt"
"math"
"os"
"os/exec"
"path/filepath"
@@ -56,13 +57,37 @@ type cachedPowerReading struct {
UpdatedAt time.Time
}
type fanObservationState struct {
MaxRPM map[string]float64 `json:"max_rpm"`
}
type fanPeakCandidate struct {
FirstSeen time.Time
RPM float64
}
var (
systemPowerCacheMu sync.Mutex
systemPowerCache cachedPowerReading
fanObservationMu sync.Mutex
fanObservation fanObservationState
fanObservationInit bool
fanPeakCandidates = make(map[string]fanPeakCandidate)
)
const systemPowerHoldTTL = 15 * time.Second
var fanObservationStatePath = "/var/log/bee-sat/fan-observation.json"
const fanObservationMinPeakHold = time.Second
func normalizeObservedFanMaxRPM(rpm float64) float64 {
if rpm <= 0 {
return 0
}
return math.Ceil(rpm/1000.0) * 1000.0
}
// RunFanStressTest runs a two-phase GPU stress test while monitoring fan speeds,
// temperatures, and power draw every second. Exports metrics.csv and fan-sensors.csv.
// Designed to reproduce case-04 fan-speed lag and detect GPU thermal throttling.
@@ -310,11 +335,13 @@ func sampleFanSpeeds() ([]FanReading, error) {
out, err := exec.Command("ipmitool", "sdr", "type", "Fan").Output()
if err == nil {
if fans := parseFanSpeeds(string(out)); len(fans) > 0 {
updateFanObservation(fans, time.Now())
return fans, nil
}
}
fans, sensorsErr := sampleFanSpeedsViaSensorsJSON()
if len(fans) > 0 {
updateFanObservation(fans, time.Now())
return fans, nil
}
if err != nil {
@@ -323,6 +350,119 @@ func sampleFanSpeeds() ([]FanReading, error) {
return nil, sensorsErr
}
func loadFanObservationLocked() {
if fanObservationInit {
return
}
fanObservationInit = true
fanObservation.MaxRPM = make(map[string]float64)
raw, err := os.ReadFile(fanObservationStatePath)
if err != nil || len(raw) == 0 {
return
}
var persisted fanObservationState
if json.Unmarshal(raw, &persisted) != nil {
return
}
for name, rpm := range persisted.MaxRPM {
name = strings.TrimSpace(name)
if name == "" || rpm <= 0 {
continue
}
fanObservation.MaxRPM[name] = rpm
}
}
func saveFanObservationLocked() {
if len(fanObservation.MaxRPM) == 0 {
return
}
dir := filepath.Dir(fanObservationStatePath)
if dir == "" || dir == "." {
dir = "/var/log/bee-sat"
}
if err := os.MkdirAll(dir, 0755); err != nil {
return
}
raw, err := json.MarshalIndent(fanObservation, "", " ")
if err != nil {
return
}
_ = os.WriteFile(fanObservationStatePath, raw, 0644)
}
func updateFanObservation(fans []FanReading, now time.Time) {
if len(fans) == 0 {
return
}
fanObservationMu.Lock()
defer fanObservationMu.Unlock()
loadFanObservationLocked()
changed := false
for _, fan := range fans {
name := strings.TrimSpace(fan.Name)
if name == "" || fan.RPM <= 0 {
continue
}
currentMax := fanObservation.MaxRPM[name]
if fan.RPM <= currentMax {
delete(fanPeakCandidates, name)
continue
}
if cand, ok := fanPeakCandidates[name]; ok {
if now.Sub(cand.FirstSeen) >= fanObservationMinPeakHold {
newMax := math.Max(cand.RPM, fan.RPM)
if newMax > currentMax {
fanObservation.MaxRPM[name] = normalizeObservedFanMaxRPM(newMax)
changed = true
}
delete(fanPeakCandidates, name)
continue
}
if fan.RPM > cand.RPM {
fanPeakCandidates[name] = fanPeakCandidate{FirstSeen: cand.FirstSeen, RPM: fan.RPM}
}
continue
}
fanPeakCandidates[name] = fanPeakCandidate{FirstSeen: now, RPM: fan.RPM}
}
if changed {
saveFanObservationLocked()
}
}
func estimateFanDutyCyclePctFromObservation(fans []FanReading) (float64, bool) {
if len(fans) == 0 {
return 0, false
}
fanObservationMu.Lock()
defer fanObservationMu.Unlock()
loadFanObservationLocked()
var samples []float64
for _, fan := range fans {
name := strings.TrimSpace(fan.Name)
if name == "" || fan.RPM <= 0 {
continue
}
maxRPM := fanObservation.MaxRPM[name]
if maxRPM <= 0 {
continue
}
pct := fan.RPM / maxRPM * 100.0
if pct > 100 {
pct = 100
}
if pct < 0 {
pct = 0
}
samples = append(samples, pct)
}
if len(samples) == 0 {
return 0, false
}
return benchmarkMean(samples), true
}
// parseFanSpeeds parses "ipmitool sdr type Fan" output.
// Handles two formats:
//
@@ -428,12 +568,27 @@ func sampleFanSpeedsViaSensorsJSON() ([]FanReading, error) {
// sampleFanDutyCyclePct reads fan PWM/duty-cycle controls from lm-sensors.
// Returns the average duty cycle across all exposed PWM controls.
func sampleFanDutyCyclePct() (float64, bool) {
func sampleFanDutyCyclePct() (float64, bool, bool) {
out, err := exec.Command("sensors", "-j").Output()
if err != nil || len(out) == 0 {
return 0, false
fans, fanErr := sampleFanSpeeds()
if fanErr != nil {
return 0, false, false
}
return sampleFanDutyCyclePctFromFans(fans)
}
return parseFanDutyCyclePctSensorsJSON(out)
pct, ok := parseFanDutyCyclePctSensorsJSON(out)
return pct, ok, false
}
func sampleFanDutyCyclePctFromFans(fans []FanReading) (float64, bool, bool) {
if len(fans) == 0 {
return 0, false, false
}
if pct, ok := estimateFanDutyCyclePctFromObservation(fans); ok {
return pct, true, true
}
return 0, false, false
}
func parseFanDutyCyclePctSensorsJSON(raw []byte) (float64, bool) {

48
audit/internal/platform/sat_fan_stress_test.go
View File

@@ -1,6 +1,7 @@
package platform
import (
"path/filepath"
"testing"
"time"
)
@@ -50,6 +51,53 @@ func TestParseFanDutyCyclePctSensorsJSON(t *testing.T) {
}
}
func TestEstimateFanDutyCyclePctFromObservation(t *testing.T) {
t.Parallel()
oldPath := fanObservationStatePath
oldState := fanObservation
oldInit := fanObservationInit
oldCandidates := fanPeakCandidates
fanObservationStatePath = filepath.Join(t.TempDir(), "fan-observation.json")
fanObservation = fanObservationState{}
fanObservationInit = false
fanPeakCandidates = make(map[string]fanPeakCandidate)
t.Cleanup(func() {
fanObservationStatePath = oldPath
fanObservation = oldState
fanObservationInit = oldInit
fanPeakCandidates = oldCandidates
})
start := time.Unix(100, 0)
updateFanObservation([]FanReading{{Name: "FAN1", RPM: 5000}}, start)
if _, ok := estimateFanDutyCyclePctFromObservation([]FanReading{{Name: "FAN1", RPM: 2500}}); ok {
t.Fatalf("single-sample spike should not establish observed max")
}
updateFanObservation([]FanReading{{Name: "FAN1", RPM: 5200}}, start.Add(500*time.Millisecond))
updateFanObservation([]FanReading{{Name: "FAN1", RPM: 5100}}, start.Add(1500*time.Millisecond))
got, ok := estimateFanDutyCyclePctFromObservation([]FanReading{{Name: "FAN1", RPM: 2600}})
if !ok {
t.Fatalf("expected estimated duty cycle from persisted observed max")
}
if got < 43 || got > 44 {
t.Fatalf("got=%v want ~43.3", got)
}
fanObservation = fanObservationState{}
fanObservationInit = false
fanPeakCandidates = make(map[string]fanPeakCandidate)
got, ok = estimateFanDutyCyclePctFromObservation([]FanReading{{Name: "FAN1", RPM: 2600}})
if !ok {
t.Fatalf("expected persisted observed max to be reloaded from disk")
}
if got < 43 || got > 44 {
t.Fatalf("reloaded got=%v want ~43.3", got)
}
}
func TestParseDCMIPowerReading(t *testing.T) {
raw := `
Instantaneous power reading: 512 Watts

13
audit/internal/platform/sat_test.go
View File

@@ -321,6 +321,19 @@ func TestNvidiaDCGMNamedDiagCommandUsesDurationAndSelection(t *testing.T) {
}
}
func TestNvidiaDCGMNamedDiagCommandSkipsDurationForNVBandwidth(t *testing.T) {
cmd := nvidiaDCGMNamedDiagCommand("nvbandwidth", 0, []int{2, 0})
want := []string{"dcgmi", "diag", "-r", "nvbandwidth", "-i", "2,0"}
if len(cmd) != len(want) {
t.Fatalf("cmd len=%d want %d (%v)", len(cmd), len(want), cmd)
}
for i := range want {
if cmd[i] != want[i] {
t.Fatalf("cmd[%d]=%q want %q", i, cmd[i], want[i])
}
}
}
func TestNvidiaVisibleDevicesEnvUsesSelectedGPUs(t *testing.T) {
env := nvidiaVisibleDevicesEnv([]int{0, 2, 4})
if len(env) != 2 {

87
audit/internal/webui/pages.go
View File

@@ -1481,7 +1481,7 @@ func renderValidate(opts HandlerOptions) string {
inv.NVIDIA,
`Verifies NVLink/NVSwitch fabric bandwidth using NCCL all_reduce_perf across all selected GPUs. Pass/fail based on achieved bandwidth vs. theoretical.`,
`<code>all_reduce_perf</code> (NCCL tests)`,
`Skipped in Validate mode. Runs in Stress mode only. Runs across all selected GPUs simultaneously (requires ≥2).<p id="sat-ni-mode-hint" style="color:var(--warn-fg);font-size:12px;margin:8px 0 0">Only runs in Stress mode. Switch mode above to enable in Run All.</p>`,
`Runs in Validate and Stress. Uses all selected GPUs simultaneously (requires ≥2) and is kept short so it fits the Validate flow.`,
)) +
`</div>` +
`<div id="sat-card-nvidia-bandwidth">` +
@@ -1489,7 +1489,7 @@ func renderValidate(opts HandlerOptions) string {
inv.NVIDIA,
`Validates GPU memory copy and peer-to-peer bandwidth paths using NVBandwidth.`,
`<code>nvbandwidth</code>`,
`Skipped in Validate mode. Runs in Stress mode only. Runs across all selected GPUs simultaneously.<p id="sat-nb-mode-hint" style="color:var(--warn-fg);font-size:12px;margin:8px 0 0">Only runs in Stress mode. Switch mode above to enable in Run All.</p>`,
`Runs in Validate and Stress across all selected GPUs simultaneously. Intended to stay short enough for Validate.`,
)) +
`</div>` +
`</div>
@@ -1527,8 +1527,6 @@ function satModeChanged() {
{card: 'sat-card-nvidia-targeted-stress', hint: 'sat-ts-mode-hint'},
{card: 'sat-card-nvidia-targeted-power', hint: 'sat-tp-mode-hint'},
{card: 'sat-card-nvidia-pulse', hint: 'sat-pt-mode-hint'},
{card: 'sat-card-nvidia-interconnect', hint: 'sat-ni-mode-hint'},
{card: 'sat-card-nvidia-bandwidth', hint: 'sat-nb-mode-hint'},
].forEach(function(item) {
const card = document.getElementById(item.card);
if (card) {
@@ -1776,7 +1774,7 @@ function runAllSAT() {
const cycles = 1;
const status = document.getElementById('sat-all-status');
status.textContent = 'Enqueuing...';
const stressOnlyTargets = ['nvidia-targeted-stress', 'nvidia-targeted-power', 'nvidia-pulse', 'nvidia-interconnect', 'nvidia-bandwidth'];
const stressOnlyTargets = ['nvidia-targeted-stress', 'nvidia-targeted-power', 'nvidia-pulse'];
const baseTargets = ['nvidia','nvidia-targeted-stress','nvidia-targeted-power','nvidia-pulse','nvidia-interconnect','nvidia-bandwidth','memory','storage','cpu'].concat(selectedAMDValidateTargets());
const activeTargets = baseTargets.filter(target => {
if (stressOnlyTargets.indexOf(target) >= 0 && !satStressMode()) return false;
@@ -2016,9 +2014,11 @@ func renderSATCard(id, label, runAction, headerActions, body string) string {
// ── Benchmark ─────────────────────────────────────────────────────────────────
type benchmarkHistoryRun struct {
generatedAt time.Time
displayTime string
gpuScores map[int]float64 // GPU index → composite score
generatedAt time.Time
displayTime string
gpuScores map[int]float64 // GPU index → composite score
gpuStatuses map[int]string // GPU index → status ("OK", "WARNING", "FAILED", …)
overallStatus string
}
func renderBenchmark(opts HandlerOptions) string {
@@ -2082,7 +2082,7 @@ func renderBenchmark(opts HandlerOptions) string {
</div>
</div>
`+`<div id="benchmark-results-section">`+renderBenchmarkResultsCard(opts.ExportDir)+`</div>`+`
` + `<div id="benchmark-results-section">` + renderBenchmarkResultsCard(opts.ExportDir) + `</div>` + `
<div id="benchmark-output" style="display:none;margin-top:16px" class="card">
<div class="card-head">Benchmark Output <span id="benchmark-title"></span></div>
@@ -2326,7 +2326,7 @@ func renderBenchmarkResultsCardFromRuns(title, description, emptyMessage string,
b.WriteString(`<p style="color:var(--muted);font-size:13px;margin-bottom:12px">` + html.EscapeString(description) + `</p>`)
}
b.WriteString(`<div style="overflow-x:auto">`)
b.WriteString(`<table><thead><tr><th>Run</th><th>Time</th>`)
b.WriteString(`<table><thead><tr><th>Run</th><th>Time</th><th>Status</th>`)
for i := 0; i <= maxGPUIndex; i++ {
b.WriteString(`<th>GPU ` + strconv.Itoa(i) + `</th>`)
}
@@ -2335,13 +2335,36 @@ func renderBenchmarkResultsCardFromRuns(title, description, emptyMessage string,
b.WriteString(`<tr>`)
b.WriteString(`<td>#` + strconv.Itoa(i+1) + `</td>`)
b.WriteString(`<td>` + html.EscapeString(run.displayTime) + `</td>`)
overallColor := "var(--ok)"
overallLabel := run.overallStatus
if overallLabel == "" {
overallLabel = "OK"
}
if overallLabel == "FAILED" {
overallColor = "var(--crit-fg,#9f3a38)"
} else if overallLabel != "OK" {
overallColor = "var(--warn)"
}
b.WriteString(`<td style="color:` + overallColor + `;font-weight:600">` + html.EscapeString(overallLabel) + `</td>`)
for idx := 0; idx <= maxGPUIndex; idx++ {
score, ok := run.gpuScores[idx]
if !ok {
b.WriteString(`<td style="color:var(--muted)">-</td>`)
continue
}
b.WriteString(`<td>` + fmt.Sprintf("%.2f", score) + `</td>`)
gpuStatus := run.gpuStatuses[idx]
scoreColor := ""
switch gpuStatus {
case "FAILED":
scoreColor = ` style="color:var(--crit-fg,#9f3a38);font-weight:600"`
case "WARNING", "PARTIAL":
scoreColor = ` style="color:var(--warn);font-weight:600"`
case "", "OK":
// no override
default:
scoreColor = ` style="color:var(--warn);font-weight:600"`
}
b.WriteString(`<td` + scoreColor + `>` + fmt.Sprintf("%.2f", score) + `</td>`)
}
b.WriteString(`</tr>`)
}
@@ -2375,12 +2398,15 @@ func loadBenchmarkHistoryFromPaths(paths []string) (int, []benchmarkHistoryRun)
continue
}
run := benchmarkHistoryRun{
generatedAt: result.GeneratedAt,
displayTime: result.GeneratedAt.Local().Format("2006-01-02 15:04:05"),
gpuScores: make(map[int]float64),
generatedAt: result.GeneratedAt,
displayTime: result.GeneratedAt.Local().Format("2006-01-02 15:04:05"),
gpuScores: make(map[int]float64),
gpuStatuses: make(map[int]string),
overallStatus: result.OverallStatus,
}
for _, gpu := range result.GPUs {
run.gpuScores[gpu.Index] = gpu.Scores.CompositeScore
run.gpuStatuses[gpu.Index] = gpu.Status
if gpu.Index > maxGPUIndex {
maxGPUIndex = gpu.Index
}
@@ -2449,31 +2475,45 @@ func renderPowerBenchmarkResultsCard(exportDir string) string {
if len(latest.GPUs) > 0 {
b.WriteString(`<div style="overflow-x:auto"><table><thead><tr>`)
b.WriteString(`<th>GPU</th><th>Model</th><th>Nominal W</th><th>Achieved W</th><th>P95 Observed W</th><th>Status</th>`)
b.WriteString(`<th>GPU</th><th>Model</th><th>Nominal W</th><th>Single-card W</th><th>Multi-GPU W</th><th>P95 Observed W</th><th>Status</th>`)
b.WriteString(`</tr></thead><tbody>`)
for _, gpu := range latest.GPUs {
derated := gpu.Derated || (gpu.DefaultPowerLimitW > 0 && gpu.AppliedPowerLimitW < gpu.DefaultPowerLimitW-1)
// finalLimitW is the definitive TDP: multi-GPU stable limit from the ramp,
// falling back to single-card applied limit if the ramp hasn't run.
finalLimitW := gpu.StablePowerLimitW
if finalLimitW <= 0 {
finalLimitW = gpu.AppliedPowerLimitW
}
// Derate is relative to nominal (DefaultPowerLimitW), using the final limit.
derated := gpu.Derated ||
(gpu.DefaultPowerLimitW > 0 && finalLimitW > 0 && finalLimitW < gpu.DefaultPowerLimitW-1)
rowStyle := ""
achievedStyle := ""
finalStyle := ""
if derated {
rowStyle = ` style="background:rgba(255,180,0,0.08)"`
achievedStyle = ` style="color:#e6a000;font-weight:600"`
finalStyle = ` style="color:#e6a000;font-weight:600"`
}
statusLabel := gpu.Status
if statusLabel == "" {
statusLabel = "OK"
}
statusColor := "var(--ok)"
if statusLabel != "OK" {
if statusLabel == "FAILED" {
statusColor = "var(--crit-fg,#9f3a38)"
} else if statusLabel != "OK" {
statusColor = "var(--warn)"
}
nominalStr := "-"
if gpu.DefaultPowerLimitW > 0 {
nominalStr = fmt.Sprintf("%.0f", gpu.DefaultPowerLimitW)
}
achievedStr := "-"
singleStr := "-"
if gpu.AppliedPowerLimitW > 0 {
achievedStr = fmt.Sprintf("%.0f", gpu.AppliedPowerLimitW)
singleStr = fmt.Sprintf("%.0f", gpu.AppliedPowerLimitW)
}
multiStr := "-"
if gpu.StablePowerLimitW > 0 {
multiStr = fmt.Sprintf("%.0f", gpu.StablePowerLimitW)
}
p95Str := "-"
if gpu.MaxObservedPowerW > 0 {
@@ -2483,7 +2523,8 @@ func renderPowerBenchmarkResultsCard(exportDir string) string {
b.WriteString(`<td>` + strconv.Itoa(gpu.Index) + `</td>`)
b.WriteString(`<td>` + html.EscapeString(gpu.Name) + `</td>`)
b.WriteString(`<td>` + nominalStr + `</td>`)
b.WriteString(`<td` + achievedStyle + `>` + achievedStr + `</td>`)
b.WriteString(`<td>` + singleStr + `</td>`)
b.WriteString(`<td` + finalStyle + `>` + multiStr + `</td>`)
b.WriteString(`<td>` + p95Str + `</td>`)
b.WriteString(`<td style="color:` + statusColor + `;font-weight:600">` + html.EscapeString(statusLabel) + `</td>`)
b.WriteString(`</tr>`)
@@ -2517,7 +2558,7 @@ func renderPowerBenchmarkResultsCard(exportDir string) string {
func renderBurn() string {
return `<div class="alert alert-warn" style="margin-bottom:16px"><strong>&#9888; Warning:</strong> Stress tests on this page run hardware at high load. Repeated or prolonged use may reduce hardware lifespan. Use only when necessary.</div>
<div class="alert alert-info" style="margin-bottom:16px"><strong>Scope:</strong> DCGM diagnostics (` + "targeted_stress, targeted_power, pulse_test" + `), NCCL, NVBandwidth, and LINPACK remain in <a href="/validate">Validate → Stress mode</a>. Burn exposes sustained GPU compute load recipes.</div>
<div class="alert alert-info" style="margin-bottom:16px"><strong>Scope:</strong> Burn exposes sustained GPU compute load recipes. DCGM diagnostics (` + "targeted_stress, targeted_power, pulse_test" + `) and LINPACK remain in <a href="/validate">Validate → Stress mode</a>; NCCL and NVBandwidth are available directly from <a href="/validate">Validate</a>.</div>
<p style="color:var(--muted);font-size:13px;margin-bottom:16px">Tasks continue in the background — view progress in <a href="/tasks">Tasks</a>.</p>
<div class="card" style="margin-bottom:16px">

20
audit/internal/webui/server_test.go
View File

@@ -744,6 +744,26 @@ func TestValidatePageRendersNvidiaTargetedStressCard(t *testing.T) {
}
}
func TestValidatePageRendersNvidiaFabricCardsInValidateMode(t *testing.T) {
handler := NewHandler(HandlerOptions{})
rec := httptest.NewRecorder()
handler.ServeHTTP(rec, httptest.NewRequest(http.MethodGet, "/validate", nil))
if rec.Code != http.StatusOK {
t.Fatalf("status=%d", rec.Code)
}
body := rec.Body.String()
for _, needle := range []string{
`NVIDIA Interconnect (NCCL)`,
`Runs in Validate and Stress.`,
`NVIDIA Bandwidth (NVBandwidth)`,
`Intended to stay short enough for Validate.`,
} {
if !strings.Contains(body, needle) {
t.Fatalf("validate page missing %q: %s", needle, body)
}
}
}
func TestBurnPageRendersGoalBasedNVIDIACards(t *testing.T) {
handler := NewHandler(HandlerOptions{})
rec := httptest.NewRecorder()

10
audit/internal/webui/tasks.go
View File

@@ -736,15 +736,7 @@ func (q *taskQueue) runTask(t *Task, j *jobState, ctx context.Context) {
err = fmt.Errorf("app not configured")
break
}
dur := t.params.Duration
if t.params.BurnProfile != "" && dur <= 0 {
dur = resolveBurnPreset(t.params.BurnProfile).DurationSec
}
archive, err = runNvidiaStressPackCtx(a, ctx, "", platform.NvidiaStressOptions{
DurationSec: dur,
Loader: platform.NvidiaStressLoaderNCCL,
GPUIndices: t.params.GPUIndices,
}, j.append)
archive, err = a.RunNCCLTests(ctx, "", t.params.GPUIndices, j.append)
case "nvidia-stress":
if a == nil {
err = fmt.Errorf("app not configured")

117
iso/builder/config/hooks/normal/9001-wallpaper.hook.chroot
View File

@@ -1,117 +0,0 @@
#!/bin/sh
# 9001-wallpaper.hook.chroot — generate /usr/share/bee/wallpaper.png inside chroot
set -e
echo "=== generating bee wallpaper ==="
mkdir -p /usr/share/bee
python3 - <<'PYEOF'
from PIL import Image, ImageDraw, ImageFont, ImageFilter
import os
W, H = 1920, 1080
ASCII_ART = [
" ███████╗ █████╗ ███████╗██╗ ██╗ ██████╗ ███████╗███████╗",
" ██╔════╝██╔══██╗██╔════╝╚██╗ ██╔╝ ██╔══██╗██╔════╝██╔════╝",
" █████╗ ███████║███████╗ ╚████╔╝ █████╗██████╔╝█████╗ █████╗",
" ██╔══╝ ██╔══██║╚════██║ ╚██╔╝ ╚════╝██╔══██╗██╔══╝ ██╔══╝",
" ███████╗██║ ██║███████║ ██║ ██████╔╝███████╗███████╗",
" ╚══════╝╚═╝ ╚═╝╚══════╝ ╚═╝ ╚═════╝ ╚══════╝╚══════╝",
]
SUBTITLE = " Hardware Audit LiveCD"
FG = (0xF6, 0xD0, 0x47)
FG_DIM = (0xD4, 0xA9, 0x1C)
SHADOW = (0x5E, 0x47, 0x05)
SUB = (0x96, 0x7A, 0x17)
BG = (0x05, 0x05, 0x05)
MONO_FONT_CANDIDATES = [
'/usr/share/fonts/truetype/dejavu/DejaVuSansMono-Bold.ttf',
'/usr/share/fonts/truetype/liberation2/LiberationMono-Bold.ttf',
'/usr/share/fonts/truetype/liberation/LiberationMono-Bold.ttf',
'/usr/share/fonts/truetype/freefont/FreeMonoBold.ttf',
]
SUB_FONT_CANDIDATES = [
'/usr/share/fonts/truetype/dejavu/DejaVuSans-Bold.ttf',
'/usr/share/fonts/truetype/liberation2/LiberationSans-Bold.ttf',
'/usr/share/fonts/truetype/liberation/LiberationSans-Bold.ttf',
'/usr/share/fonts/truetype/freefont/FreeSansBold.ttf',
]
def load_font(candidates, size):
for path in candidates:
if os.path.exists(path):
return ImageFont.truetype(path, size)
return ImageFont.load_default()
def mono_metrics(font):
probe = Image.new('L', (W, H), 0)
draw = ImageDraw.Draw(probe)
char_w = int(round(draw.textlength("M", font=font)))
bb = draw.textbbox((0, 0), "Mg", font=font)
char_h = bb[3] - bb[1]
return char_w, char_h
def render_ascii_mask(font, lines, char_w, char_h, line_gap):
width = max(len(line) for line in lines) * char_w
height = len(lines) * char_h + line_gap * (len(lines) - 1)
mask = Image.new('L', (width, height), 0)
draw = ImageDraw.Draw(mask)
for row, line in enumerate(lines):
y = row * (char_h + line_gap)
for col, ch in enumerate(line):
if ch == ' ':
continue
x = col * char_w
draw.text((x, y), ch, font=font, fill=255)
return mask
img = Image.new('RGB', (W, H), BG)
draw = ImageDraw.Draw(img)
# Soft amber glow under the logo without depending on font rendering.
glow = Image.new('RGBA', (W, H), (0, 0, 0, 0))
glow_draw = ImageDraw.Draw(glow)
glow_draw.ellipse((360, 250, 1560, 840), fill=(180, 120, 10, 56))
glow_draw.ellipse((520, 340, 1400, 760), fill=(255, 190, 40, 36))
glow = glow.filter(ImageFilter.GaussianBlur(60))
img = Image.alpha_composite(img.convert('RGBA'), glow)
TARGET_LOGO_W = 400
max_chars = max(len(line) for line in ASCII_ART)
_probe_font = load_font(MONO_FONT_CANDIDATES, 64)
_probe_cw, _ = mono_metrics(_probe_font)
font_size_logo = max(6, int(64 * TARGET_LOGO_W / (_probe_cw * max_chars)))
font_logo = load_font(MONO_FONT_CANDIDATES, font_size_logo)
char_w, char_h = mono_metrics(font_logo)
logo_mask = render_ascii_mask(font_logo, ASCII_ART, char_w, char_h, 2)
logo_w, logo_h = logo_mask.size
logo_x = (W - logo_w) // 2
logo_y = 380
sh_off = max(1, font_size_logo // 6)
shadow_mask = logo_mask.filter(ImageFilter.GaussianBlur(1))
img.paste(SHADOW, (logo_x + sh_off * 2, logo_y + sh_off * 2), shadow_mask)
img.paste(FG_DIM, (logo_x + sh_off, logo_y + sh_off), logo_mask)
img.paste(FG, (logo_x, logo_y), logo_mask)
font_sub = load_font(SUB_FONT_CANDIDATES, 30)
sub_bb = draw.textbbox((0, 0), SUBTITLE, font=font_sub)
sub_x = (W - (sub_bb[2] - sub_bb[0])) // 2
sub_y = logo_y + logo_h + 48
draw = ImageDraw.Draw(img)
draw.text((sub_x + 2, sub_y + 2), SUBTITLE, font=font_sub, fill=(35, 28, 6))
draw.text((sub_x, sub_y), SUBTITLE, font=font_sub, fill=SUB)
img = img.convert('RGB')
img.save('/usr/share/bee/wallpaper.png', optimize=True)
print('wallpaper written: /usr/share/bee/wallpaper.png')
PYEOF
echo "=== wallpaper done ==="