public override void Update()
{
if (context != IntPtr.Zero && overdriveVersion >= 8 &&
ADL.ADL2_New_QueryPMLogData_Get(context, adapterIndex,
out var data) == ADLStatus.OK)
{
GetPMLog(data, ADLSensorType.TEMPERATURE_EDGE, temperatureCore);
GetPMLog(data, ADLSensorType.TEMPERATURE_MEM, temperatureMemory);
GetPMLog(data, ADLSensorType.TEMPERATURE_VRVDDC, temperatureVrmCore);
GetPMLog(data, ADLSensorType.TEMPERATURE_VRMVDD, temperatureVrmMemory);
GetPMLog(data, ADLSensorType.TEMPERATURE_VRMVDD0, temperatureVrmMemory0);
GetPMLog(data, ADLSensorType.TEMPERATURE_VRMVDD1, temperatureVrmMemory1);
GetPMLog(data, ADLSensorType.TEMPERATURE_VRSOC, temperatureVrmSoc);
GetPMLog(data, ADLSensorType.TEMPERATURE_LIQUID, temperatureLiquid);
GetPMLog(data, ADLSensorType.TEMPERATURE_PLX, temperaturePlx);
GetPMLog(data, ADLSensorType.TEMPERATURE_HOTSPOT, temperatureHotSpot);
GetPMLog(data, ADLSensorType.GFX_POWER, powerCore);
GetPMLog(data, ADLSensorType.ASIC_POWER, powerTotal);
GetPMLog(data, ADLSensorType.SOC_POWER, powerSoc);
GetPMLog(data, ADLSensorType.FAN_RPM, fan);
GetPMLog(data, ADLSensorType.CLK_GFXCLK, coreClock);
GetPMLog(data, ADLSensorType.CLK_MEMCLK, memoryClock);
GetPMLog(data, ADLSensorType.CLK_SOCCLK, socClock);
GetPMLog(data, ADLSensorType.GFX_VOLTAGE, coreVoltage, 0.001f);
GetPMLog(data, ADLSensorType.MEM_VOLTAGE, memoryVoltage, 0.001f);
GetPMLog(data, ADLSensorType.SOC_VOLTAGE, socVoltage, 0.001f);
GetPMLog(data, ADLSensorType.INFO_ACTIVITY_GFX, coreLoad);
GetPMLog(data, ADLSensorType.INFO_ACTIVITY_MEM, memoryLoad);
GetPMLog(data, ADLSensorType.FAN_PERCENTAGE, controlSensor);
}
else
{
if (context != IntPtr.Zero && overdriveVersion >= 7)
{
GetODNTemperature(ADLODNTemperatureType.CORE, temperatureCore);
GetODNTemperature(ADLODNTemperatureType.MEMORY, temperatureMemory);
GetODNTemperature(ADLODNTemperatureType.VRM_CORE, temperatureVrmCore);
GetODNTemperature(ADLODNTemperatureType.VRM_MEMORY, temperatureVrmMemory);
GetODNTemperature(ADLODNTemperatureType.LIQUID, temperatureLiquid);
GetODNTemperature(ADLODNTemperatureType.PLX, temperaturePlx);
GetODNTemperature(ADLODNTemperatureType.HOTSPOT, temperatureHotSpot);
}
else
{
ADLTemperature adlt = new ADLTemperature();
if (ADL.ADL_Overdrive5_Temperature_Get(adapterIndex, 0, ref adlt)
== ADLStatus.OK)
{
temperatureCore.Value = 0.001f * adlt.Temperature;
ActivateSensor(temperatureCore);
}
else
{
temperatureCore.Value = null;
}
}
if (context != IntPtr.Zero && overdriveVersion >= 6)
{
GetOD6Power(ADLODNCurrentPowerType.TOTAL_POWER, powerTotal);
GetOD6Power(ADLODNCurrentPowerType.CHIP_POWER, powerCore);
GetOD6Power(ADLODNCurrentPowerType.PPT_POWER, powerPpt);
GetOD6Power(ADLODNCurrentPowerType.SOCKET_POWER, powerSocket);
}
ADLFanSpeedValue adlf = new ADLFanSpeedValue();
adlf.SpeedType = ADL.ADL_DL_FANCTRL_SPEED_TYPE_RPM;
if (ADL.ADL_Overdrive5_FanSpeed_Get(adapterIndex, 0, ref adlf)
== ADLStatus.OK)
{
fan.Value = adlf.FanSpeed;
ActivateSensor(fan);
}
else
{
fan.Value = null;
}
adlf = new ADLFanSpeedValue();
adlf.SpeedType = ADL.ADL_DL_FANCTRL_SPEED_TYPE_PERCENT;
if (ADL.ADL_Overdrive5_FanSpeed_Get(adapterIndex, 0, ref adlf)
== ADLStatus.OK)
{
controlSensor.Value = adlf.FanSpeed;
ActivateSensor(controlSensor);
}
else
{
controlSensor.Value = null;
}
ADLPMActivity adlp = new ADLPMActivity();
if (ADL.ADL_Overdrive5_CurrentActivity_Get(adapterIndex, ref adlp)
== ADLStatus.OK)
{
if (adlp.EngineClock > 0)
{
coreClock.Value = 0.01f * adlp.EngineClock;
ActivateSensor(coreClock);
}
else
{
coreClock.Value = null;
}
if (adlp.MemoryClock > 0)
{
memoryClock.Value = 0.01f * adlp.MemoryClock;
ActivateSensor(memoryClock);
}
else
{
memoryClock.Value = null;
}
if (adlp.Vddc > 0)
{
coreVoltage.Value = 0.001f * adlp.Vddc;
ActivateSensor(coreVoltage);
}
else
{
coreVoltage.Value = null;
}
if (adlp.ActivityPercent >= 0 && adlp.ActivityPercent <= 100)
{
coreLoad.Value = adlp.ActivityPercent;
ActivateSensor(coreLoad);
}
else
{
coreLoad.Value = null;
}
}
else
{
coreClock.Value = null;
memoryClock.Value = null;
coreVoltage.Value = null;
coreLoad.Value = null;
}
}
}
public override string GetReport()
{
var r = new StringBuilder();
r.AppendLine("AMD GPU");
r.AppendLine();
r.Append("AdapterIndex: ");
r.AppendLine(adapterIndex.ToString(CultureInfo.InvariantCulture));
r.AppendLine();
r.AppendLine("Overdrive Caps");
r.AppendLine();
try {
var status = ADL.ADL_Overdrive_Caps(adapterIndex,
out int supported, out int enabled, out int version);
r.Append(" Status: ");
r.AppendLine(status.ToString());
r.Append(" Supported: ");
r.AppendLine(supported.ToString(CultureInfo.InvariantCulture));
r.Append(" Enabled: ");
r.AppendLine(enabled.ToString(CultureInfo.InvariantCulture));
r.Append(" Version: ");
r.AppendLine(version.ToString(CultureInfo.InvariantCulture));
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
r.AppendLine("Overdrive5 Parameters");
r.AppendLine();
try {
var status = ADL.ADL_Overdrive5_ODParameters_Get(
adapterIndex, out var p);
r.Append(" Status: ");
r.AppendLine(status.ToString());
r.AppendFormat(" NumberOfPerformanceLevels: {0}{1}",
p.NumberOfPerformanceLevels, Environment.NewLine);
r.AppendFormat(" ActivityReportingSupported: {0}{1}",
p.ActivityReportingSupported, Environment.NewLine);
r.AppendFormat(" DiscretePerformanceLevels: {0}{1}",
p.DiscretePerformanceLevels, Environment.NewLine);
r.AppendFormat(" EngineClock.Min: {0}{1}",
p.EngineClock.Min, Environment.NewLine);
r.AppendFormat(" EngineClock.Max: {0}{1}",
p.EngineClock.Max, Environment.NewLine);
r.AppendFormat(" EngineClock.Step: {0}{1}",
p.EngineClock.Step, Environment.NewLine);
r.AppendFormat(" MemoryClock.Min: {0}{1}",
p.MemoryClock.Min, Environment.NewLine);
r.AppendFormat(" MemoryClock.Max: {0}{1}",
p.MemoryClock.Max, Environment.NewLine);
r.AppendFormat(" MemoryClock.Step: {0}{1}",
p.MemoryClock.Step, Environment.NewLine);
r.AppendFormat(" Vddc.Min: {0}{1}",
p.Vddc.Min, Environment.NewLine);
r.AppendFormat(" Vddc.Max: {0}{1}",
p.Vddc.Max, Environment.NewLine);
r.AppendFormat(" Vddc.Step: {0}{1}",
p.Vddc.Step, Environment.NewLine);
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
r.AppendLine("Overdrive5 Temperature");
r.AppendLine();
try {
var adlt = new ADLTemperature();
var status = ADL.ADL_Overdrive5_Temperature_Get(adapterIndex, 0,
ref adlt);
r.Append(" Status: ");
r.AppendLine(status.ToString());
r.AppendFormat(" Value: {0}{1}",
0.001f * adlt.Temperature, Environment.NewLine);
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
r.AppendLine("Overdrive5 FanSpeed");
r.AppendLine();
try {
var adlf = new ADLFanSpeedValue();
adlf.SpeedType = ADL.ADL_DL_FANCTRL_SPEED_TYPE_RPM;
var status = ADL.ADL_Overdrive5_FanSpeed_Get(adapterIndex, 0, ref adlf);
r.Append(" Status RPM: ");
r.AppendLine(status.ToString());
r.AppendFormat(" Value RPM: {0}{1}",
adlf.FanSpeed, Environment.NewLine);
adlf.SpeedType = ADL.ADL_DL_FANCTRL_SPEED_TYPE_PERCENT;
status = ADL.ADL_Overdrive5_FanSpeed_Get(adapterIndex, 0, ref adlf);
r.Append(" Status Percent: ");
r.AppendLine(status.ToString());
r.AppendFormat(" Value Percent: {0}{1}",
adlf.FanSpeed, Environment.NewLine);
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
r.AppendLine("Overdrive5 CurrentActivity");
r.AppendLine();
try {
var adlp = new ADLPMActivity();
var status = ADL.ADL_Overdrive5_CurrentActivity_Get(adapterIndex,
ref adlp);
r.Append(" Status: ");
r.AppendLine(status.ToString());
r.AppendFormat(" EngineClock: {0}{1}",
0.01f * adlp.EngineClock, Environment.NewLine);
r.AppendFormat(" MemoryClock: {0}{1}",
0.01f * adlp.MemoryClock, Environment.NewLine);
r.AppendFormat(" Vddc: {0}{1}",
0.001f * adlp.Vddc, Environment.NewLine);
r.AppendFormat(" ActivityPercent: {0}{1}",
adlp.ActivityPercent, Environment.NewLine);
r.AppendFormat(" CurrentPerformanceLevel: {0}{1}",
adlp.CurrentPerformanceLevel, Environment.NewLine);
r.AppendFormat(" CurrentBusSpeed: {0}{1}",
adlp.CurrentBusSpeed, Environment.NewLine);
r.AppendFormat(" CurrentBusLanes: {0}{1}",
adlp.CurrentBusLanes, Environment.NewLine);
r.AppendFormat(" MaximumBusLanes: {0}{1}",
adlp.MaximumBusLanes, Environment.NewLine);
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
if (context != IntPtr.Zero)
{
r.AppendLine("Overdrive6 CurrentPower");
r.AppendLine();
try {
for (int i = 0; i < 4; i++)
{
var pt = ((ADLODNCurrentPowerType)i).ToString();
var status = ADL.ADL2_Overdrive6_CurrentPower_Get(
context, adapterIndex, (ADLODNCurrentPowerType)i,
out int power);
if (status == ADLStatus.OK)
{
r.AppendFormat(" Power[{0}].Value: {1}{2}", pt,
power * (1.0f / 0xFF), Environment.NewLine);
}
else
{
r.AppendFormat(" Power[{0}].Status: {1}{2}", pt,
status.ToString(), Environment.NewLine);
}
}
} catch (EntryPointNotFoundException) {
r.AppendLine(" Status: Entry point not found");
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
}
if (context != IntPtr.Zero)
{
r.AppendLine("OverdriveN Temperature");
r.AppendLine();
try {
for (int i = 1; i < 8; i++)
{
var tt = ((ADLODNTemperatureType)i).ToString();
var status = ADL.ADL2_OverdriveN_Temperature_Get(
context, adapterIndex, (ADLODNTemperatureType)i,
out int temperature);
if (status == ADLStatus.OK)
{
r.AppendFormat(" Temperature[{0}].Value: {1}{2}", tt,
0.001f * temperature, Environment.NewLine);
}
else
{
r.AppendFormat(" Temperature[{0}].Status: {1}{2}", tt,
status.ToString(), Environment.NewLine);
}
}
} catch (EntryPointNotFoundException) {
r.AppendLine(" Status: Entry point not found");
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
}
if (context != IntPtr.Zero)
{
r.AppendLine("OverdriveN Performance Status");
r.AppendLine();
try {
var status = ADL.ADL2_OverdriveN_PerformanceStatus_Get(context,
adapterIndex, out var ps);
r.Append(" Status: ");
r.AppendLine(status.ToString());
r.AppendFormat(" CoreClock: {0}{1}",
ps.CoreClock, Environment.NewLine);
r.AppendFormat(" MemoryClock: {0}{1}",
ps.MemoryClock, Environment.NewLine);
r.AppendFormat(" DCEFClock: {0}{1}",
ps.DCEFClock, Environment.NewLine);
r.AppendFormat(" GFXClock: {0}{1}",
ps.GFXClock, Environment.NewLine);
r.AppendFormat(" UVDClock: {0}{1}",
ps.UVDClock, Environment.NewLine);
r.AppendFormat(" VCEClock: {0}{1}",
ps.VCEClock, Environment.NewLine);
r.AppendFormat(" GPUActivityPercent: {0}{1}",
ps.GPUActivityPercent, Environment.NewLine);
r.AppendFormat(" CurrentCorePerformanceLevel: {0}{1}",
ps.CurrentCorePerformanceLevel, Environment.NewLine);
r.AppendFormat(" CurrentMemoryPerformanceLevel: {0}{1}",
ps.CurrentMemoryPerformanceLevel, Environment.NewLine);
r.AppendFormat(" CurrentDCEFPerformanceLevel: {0}{1}",
ps.CurrentDCEFPerformanceLevel, Environment.NewLine);
r.AppendFormat(" CurrentGFXPerformanceLevel: {0}{1}",
ps.CurrentGFXPerformanceLevel, Environment.NewLine);
r.AppendFormat(" UVDPerformanceLevel: {0}{1}",
ps.UVDPerformanceLevel, Environment.NewLine);
r.AppendFormat(" VCEPerformanceLevel: {0}{1}",
ps.VCEPerformanceLevel, Environment.NewLine);
r.AppendFormat(" CurrentBusSpeed: {0}{1}",
ps.CurrentBusSpeed, Environment.NewLine);
r.AppendFormat(" CurrentBusLanes: {0}{1}",
ps.CurrentBusLanes, Environment.NewLine);
r.AppendFormat(" MaximumBusLanes: {0}{1}",
ps.MaximumBusLanes, Environment.NewLine);
r.AppendFormat(" VDDC: {0}{1}",
ps.VDDC, Environment.NewLine);
r.AppendFormat(" VDDCI: {0}{1}",
ps.VDDCI, Environment.NewLine);
} catch (EntryPointNotFoundException) {
r.AppendLine(" Status: Entry point not found");
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
}
if (context != IntPtr.Zero)
{
r.AppendLine("Performance Metrics");
r.AppendLine();
try {
var status = ADL.ADL2_New_QueryPMLogData_Get(context, adapterIndex,
out var data);
if (status == ADLStatus.OK)
{
for (int i = 0; i < data.Sensors.Length; i++)
{
if (data.Sensors[i].Supported)
{
var st = ((ADLSensorType)i).ToString();
r.AppendFormat(" Sensor[{0}].Value: {1}{2}", st,
data.Sensors[i].Value, Environment.NewLine);
}
}
}
else
{
r.Append(" Status: ");
r.AppendLine(status.ToString());
}
} catch (EntryPointNotFoundException) {
r.AppendLine(" Status: Entry point not found");
} catch (Exception e) {
r.AppendLine(" Status: " + e.Message);
}
r.AppendLine();
}
return(r.ToString());
}