Hardware/CPU/IntelCPU.cs
author moel.mich
Sun, 01 Jul 2012 21:44:07 +0000
changeset 355 17dbf781401e
parent 344 3145aadca3d2
child 396 c7e2a6aa4f96
permissions -rw-r--r--
Added experimental support for Nuvoton NCT6779D super I/O chips.
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/*
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  This Source Code Form is subject to the terms of the Mozilla Public
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  License, v. 2.0. If a copy of the MPL was not distributed with this
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  file, You can obtain one at http://mozilla.org/MPL/2.0/.
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  Copyright (C) 2009-2012 Michael Möller <mmoeller@openhardwaremonitor.org>
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*/
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using System;
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using System.Globalization;
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using System.Text;
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namespace OpenHardwareMonitor.Hardware.CPU {
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  internal sealed class IntelCPU : GenericCPU {
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    private enum Microarchitecture {
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      Unknown,
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      NetBurst,
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      Core,
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      Atom,
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      Nehalem,
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      SandyBridge,
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      IvyBridge
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    }
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    private readonly Sensor[] coreTemperatures;
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    private readonly Sensor packageTemperature;
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    private readonly Sensor[] coreClocks;
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    private readonly Sensor busClock;
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    private readonly Sensor[] powerSensors;
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    private readonly Microarchitecture microarchitecture;
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    private readonly double timeStampCounterMultiplier;
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    private const uint IA32_THERM_STATUS_MSR = 0x019C;
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    private const uint IA32_TEMPERATURE_TARGET = 0x01A2;
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    private const uint IA32_PERF_STATUS = 0x0198;
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    private const uint MSR_PLATFORM_INFO = 0xCE;
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    private const uint IA32_PACKAGE_THERM_STATUS = 0x1B1;
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    private const uint MSR_RAPL_POWER_UNIT = 0x606;
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    private const uint MSR_PKG_ENERY_STATUS = 0x611;
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    private const uint MSR_DRAM_ENERGY_STATUS = 0x619;
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    private const uint MSR_PP0_ENERY_STATUS = 0x639;
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    private const uint MSR_PP1_ENERY_STATUS = 0x641;
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    private readonly uint[] energyStatusMSRs = { MSR_PKG_ENERY_STATUS, 
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      MSR_PP0_ENERY_STATUS, MSR_PP1_ENERY_STATUS, MSR_DRAM_ENERGY_STATUS };
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    private readonly string[] powerSensorLabels = 
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      { "CPU Package", "CPU Cores", "CPU Graphics", "CPU DRAM" };
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    private float energyUnitMultiplier = 0;
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    private DateTime[] lastEnergyTime;
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    private uint[] lastEnergyConsumed;
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    private float[] Floats(float f) {
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      float[] result = new float[coreCount];
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      for (int i = 0; i < coreCount; i++)
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        result[i] = f;
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      return result;
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    }
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    private float[] GetTjMaxFromMSR() {
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      uint eax, edx;
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      float[] result = new float[coreCount];
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      for (int i = 0; i < coreCount; i++) {
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        if (Ring0.RdmsrTx(IA32_TEMPERATURE_TARGET, out eax,
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          out edx, 1UL << cpuid[i][0].Thread)) {
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          result[i] = (eax >> 16) & 0xFF;
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        } else {
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          result[i] = 100;
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        }
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      }
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      return result;
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    }
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    public IntelCPU(int processorIndex, CPUID[][] cpuid, ISettings settings)
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      : base(processorIndex, cpuid, settings) {
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      // set tjMax
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      float[] tjMax;
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      switch (family) {
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        case 0x06: {
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            switch (model) {
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              case 0x0F: // Intel Core 2 (65nm)
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                microarchitecture = Microarchitecture.Core;
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                switch (stepping) {
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                  case 0x06: // B2
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                    switch (coreCount) {
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                      case 2:
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                        tjMax = Floats(80 + 10); break;
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                      case 4:
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                        tjMax = Floats(90 + 10); break;
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                      default:
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                        tjMax = Floats(85 + 10); break;
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                    }
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                    tjMax = Floats(80 + 10); break;
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                  case 0x0B: // G0
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                    tjMax = Floats(90 + 10); break;
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                  case 0x0D: // M0
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                    tjMax = Floats(85 + 10); break;
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                  default:
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                    tjMax = Floats(85 + 10); break;
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                } break;
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              case 0x17: // Intel Core 2 (45nm)
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                microarchitecture = Microarchitecture.Core;
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                tjMax = Floats(100); break;
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              case 0x1C: // Intel Atom (45nm)
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                microarchitecture = Microarchitecture.Atom;
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                switch (stepping) {
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                  case 0x02: // C0
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                    tjMax = Floats(90); break;
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                  case 0x0A: // A0, B0
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                    tjMax = Floats(100); break;
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                  default:
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                    tjMax = Floats(90); break;
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                } break;
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              case 0x1A: // Intel Core i7 LGA1366 (45nm)
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              case 0x1E: // Intel Core i5, i7 LGA1156 (45nm)
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              case 0x1F: // Intel Core i5, i7 
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              case 0x25: // Intel Core i3, i5, i7 LGA1156 (32nm)
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              case 0x2C: // Intel Core i7 LGA1366 (32nm) 6 Core
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              case 0x2E: // Intel Xeon Processor 7500 series (45nm)
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              case 0x2F: // Intel Xeon Processor (32nm)
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                microarchitecture = Microarchitecture.Nehalem;
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                tjMax = GetTjMaxFromMSR();
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                break;
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              case 0x2A: // Intel Core i5, i7 2xxx LGA1155 (32nm)
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              case 0x2D: // Next Generation Intel Xeon, i7 3xxx LGA2011 (32nm)
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                microarchitecture = Microarchitecture.SandyBridge;
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                tjMax = GetTjMaxFromMSR();
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                break;
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              case 0x3A: // Intel Core i5, i7 3xxx LGA1155 (22nm)
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                microarchitecture = Microarchitecture.IvyBridge;
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                tjMax = GetTjMaxFromMSR();
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                break;
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              default:
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                microarchitecture = Microarchitecture.Unknown;
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                tjMax = Floats(100);
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                break;
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            }
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          } break;
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        case 0x0F: {
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            switch (model) {
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              case 0x00: // Pentium 4 (180nm)
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              case 0x01: // Pentium 4 (130nm)
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              case 0x02: // Pentium 4 (130nm)
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              case 0x03: // Pentium 4, Celeron D (90nm)
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              case 0x04: // Pentium 4, Pentium D, Celeron D (90nm)
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              case 0x06: // Pentium 4, Pentium D, Celeron D (65nm)
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                microarchitecture = Microarchitecture.NetBurst;
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                tjMax = Floats(100);
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                break;
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              default:
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                microarchitecture = Microarchitecture.Unknown;
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                tjMax = Floats(100);
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                break;
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            }
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          } break;
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        default:
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          microarchitecture = Microarchitecture.Unknown;
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          tjMax = Floats(100);
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          break;
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      }
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      // set timeStampCounterMultiplier
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      switch (microarchitecture) {
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        case Microarchitecture.NetBurst:
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        case Microarchitecture.Atom:
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        case Microarchitecture.Core: {
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            uint eax, edx;
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            if (Ring0.Rdmsr(IA32_PERF_STATUS, out eax, out edx)) {
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              timeStampCounterMultiplier =
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                ((edx >> 8) & 0x1f) + 0.5 * ((edx >> 14) & 1);
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            }
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          } break;
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        case Microarchitecture.Nehalem:
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        case Microarchitecture.SandyBridge:
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        case Microarchitecture.IvyBridge: {
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            uint eax, edx;
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            if (Ring0.Rdmsr(MSR_PLATFORM_INFO, out eax, out edx)) {
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              timeStampCounterMultiplier = (eax >> 8) & 0xff;
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            }
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          } break;
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        default: 
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          timeStampCounterMultiplier = 0;
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          break;
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      }
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      // check if processor supports a digital thermal sensor at core level
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      if (cpuid[0][0].Data.GetLength(0) > 6 &&
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        (cpuid[0][0].Data[6, 0] & 1) != 0 && 
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        microarchitecture != Microarchitecture.Unknown) 
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      {
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        coreTemperatures = new Sensor[coreCount];
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        for (int i = 0; i < coreTemperatures.Length; i++) {
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          coreTemperatures[i] = new Sensor(CoreString(i), i,
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            SensorType.Temperature, this, new[] { 
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              new ParameterDescription(
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                "TjMax [°C]", "TjMax temperature of the core sensor.\n" + 
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                "Temperature = TjMax - TSlope * Value.", tjMax[i]), 
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              new ParameterDescription("TSlope [°C]", 
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                "Temperature slope of the digital thermal sensor.\n" + 
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                "Temperature = TjMax - TSlope * Value.", 1)}, settings);
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          ActivateSensor(coreTemperatures[i]);
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        }
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      } else {
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        coreTemperatures = new Sensor[0];
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      }
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      // check if processor supports a digital thermal sensor at package level
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      if (cpuid[0][0].Data.GetLength(0) > 6 &&
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        (cpuid[0][0].Data[6, 0] & 0x40) != 0 && 
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        microarchitecture != Microarchitecture.Unknown) 
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      {
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        packageTemperature = new Sensor("CPU Package",
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          coreTemperatures.Length, SensorType.Temperature, this, new[] { 
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              new ParameterDescription(
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                "TjMax [°C]", "TjMax temperature of the package sensor.\n" + 
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                "Temperature = TjMax - TSlope * Value.", tjMax[0]), 
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              new ParameterDescription("TSlope [°C]", 
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                "Temperature slope of the digital thermal sensor.\n" + 
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                "Temperature = TjMax - TSlope * Value.", 1)}, settings);
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        ActivateSensor(packageTemperature);
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      }
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      busClock = new Sensor("Bus Speed", 0, SensorType.Clock, this, settings);
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      coreClocks = new Sensor[coreCount];
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      for (int i = 0; i < coreClocks.Length; i++) {
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        coreClocks[i] =
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          new Sensor(CoreString(i), i + 1, SensorType.Clock, this, settings);
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        if (HasTimeStampCounter && microarchitecture != Microarchitecture.Unknown)
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          ActivateSensor(coreClocks[i]);
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      }
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      if (microarchitecture == Microarchitecture.SandyBridge ||
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          microarchitecture == Microarchitecture.IvyBridge) 
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      {
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        powerSensors = new Sensor[energyStatusMSRs.Length];
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        lastEnergyTime = new DateTime[energyStatusMSRs.Length];
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        lastEnergyConsumed = new uint[energyStatusMSRs.Length];
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        uint eax, edx;
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        if (Ring0.Rdmsr(MSR_RAPL_POWER_UNIT, out eax, out edx))
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          energyUnitMultiplier = 1.0f / (1 << (int)((eax >> 8) & 0x1FF));
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        if (energyUnitMultiplier != 0) {
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          for (int i = 0; i < energyStatusMSRs.Length; i++) {
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            if (!Ring0.Rdmsr(energyStatusMSRs[i], out eax, out edx))
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              continue;
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            lastEnergyTime[i] = DateTime.UtcNow;
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            lastEnergyConsumed[i] = eax;
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            powerSensors[i] = new Sensor(powerSensorLabels[i], i,
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              SensorType.Power, this, settings);
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            ActivateSensor(powerSensors[i]);
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          }
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        }
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      }
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      Update();
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    }
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    protected override uint[] GetMSRs() {
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      return new[] {
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        MSR_PLATFORM_INFO,
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        IA32_PERF_STATUS ,
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        IA32_THERM_STATUS_MSR,
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        IA32_TEMPERATURE_TARGET,
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        IA32_PACKAGE_THERM_STATUS,
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        MSR_RAPL_POWER_UNIT,
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        MSR_PKG_ENERY_STATUS,
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        MSR_DRAM_ENERGY_STATUS,
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        MSR_PP0_ENERY_STATUS,
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        MSR_PP1_ENERY_STATUS
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      };
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    }
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    public override string GetReport() {
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      StringBuilder r = new StringBuilder();
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      r.Append(base.GetReport());
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      r.Append("Microarchitecture: ");
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      r.AppendLine(microarchitecture.ToString());
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      r.Append("Time Stamp Counter Multiplier: ");
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      r.AppendLine(timeStampCounterMultiplier.ToString(
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        CultureInfo.InvariantCulture));
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      r.AppendLine();
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      return r.ToString();
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    }
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    public override void Update() {
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      base.Update();
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      for (int i = 0; i < coreTemperatures.Length; i++) {
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        uint eax, edx;
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        if (Ring0.RdmsrTx(
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          IA32_THERM_STATUS_MSR, out eax, out edx,
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            1UL << cpuid[i][0].Thread)) {
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          // if reading is valid
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          if ((eax & 0x80000000) != 0) {
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            // get the dist from tjMax from bits 22:16
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            float deltaT = ((eax & 0x007F0000) >> 16);
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            float tjMax = coreTemperatures[i].Parameters[0].Value;
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            float tSlope = coreTemperatures[i].Parameters[1].Value;
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            coreTemperatures[i].Value = tjMax - tSlope * deltaT;
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          } else {
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            coreTemperatures[i].Value = null;
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          }
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        }
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      }
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      if (packageTemperature != null) {
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        uint eax, edx;
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        if (Ring0.RdmsrTx(
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          IA32_PACKAGE_THERM_STATUS, out eax, out edx,
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            1UL << cpuid[0][0].Thread)) {
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          // get the dist from tjMax from bits 22:16
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          float deltaT = ((eax & 0x007F0000) >> 16);
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          float tjMax = packageTemperature.Parameters[0].Value;
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          float tSlope = packageTemperature.Parameters[1].Value;
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          packageTemperature.Value = tjMax - tSlope * deltaT;
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        } else {
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          packageTemperature.Value = null;
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        }
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      }
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      if (HasTimeStampCounter && timeStampCounterMultiplier > 0) {
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        double newBusClock = 0;
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        uint eax, edx;
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        for (int i = 0; i < coreClocks.Length; i++) {
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          System.Threading.Thread.Sleep(1);
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          if (Ring0.RdmsrTx(IA32_PERF_STATUS, out eax, out edx,
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            1UL << cpuid[i][0].Thread)) {
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            newBusClock =
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              TimeStampCounterFrequency / timeStampCounterMultiplier;
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            switch (microarchitecture) {
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              case Microarchitecture.Nehalem: {
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                  uint multiplier = eax & 0xff;
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                  coreClocks[i].Value = (float)(multiplier * newBusClock);
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                } break;
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              case Microarchitecture.SandyBridge:
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              case Microarchitecture.IvyBridge: {
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                  uint multiplier = (eax >> 8) & 0xff;
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                  coreClocks[i].Value = (float)(multiplier * newBusClock);
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                } break;
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              default: {
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                  double multiplier =
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                    ((eax >> 8) & 0x1f) + 0.5 * ((eax >> 14) & 1);
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                  coreClocks[i].Value = (float)(multiplier * newBusClock);
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                } break;
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            }
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          } else {
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            // if IA32_PERF_STATUS is not available, assume TSC frequency
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            coreClocks[i].Value = (float)TimeStampCounterFrequency;
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          }
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        }
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        if (newBusClock > 0) {
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          this.busClock.Value = (float)newBusClock;
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          ActivateSensor(this.busClock);
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        }
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      }
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      if (powerSensors != null) {
moel@321
   366
        foreach (Sensor sensor in powerSensors) {
moel@321
   367
          if (sensor == null)
moel@321
   368
            continue;
moel@317
   369
moel@321
   370
          uint eax, edx;
moel@321
   371
          if (!Ring0.Rdmsr(energyStatusMSRs[sensor.Index], out eax, out edx))
moel@321
   372
            continue;
moel@317
   373
moel@317
   374
          DateTime time = DateTime.UtcNow;
moel@317
   375
          uint energyConsumed = eax;
moel@321
   376
          float deltaTime =
moel@321
   377
            (float)(time - lastEnergyTime[sensor.Index]).TotalSeconds;
moel@321
   378
          if (deltaTime < 0.01)
moel@321
   379
            continue;
moel@321
   380
moel@321
   381
          sensor.Value = energyUnitMultiplier * unchecked(
moel@321
   382
            energyConsumed - lastEnergyConsumed[sensor.Index]) / deltaTime;
moel@321
   383
          lastEnergyTime[sensor.Index] = time;
moel@321
   384
          lastEnergyConsumed[sensor.Index] = energyConsumed;
moel@317
   385
        }
moel@317
   386
      }
moel@46
   387
    }
moel@191
   388
  }
moel@1
   389
}