tools/timer/TimerData.cpp - skia - Git at Google

 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */
 #include "TimerData.h"

 #include "Timer.h"
 #include <limits>

 TimerData::TimerData(int maxNumTimings)
     : fMaxNumTimings(maxNumTimings)
     , fCurrTiming(0)
     , fWallTimes(maxNumTimings)
     , fTruncatedWallTimes(maxNumTimings)
     , fCpuTimes(maxNumTimings)
     , fTruncatedCpuTimes(maxNumTimings)
     , fGpuTimes(maxNumTimings) {}

 bool TimerData::appendTimes(Timer* timer) {
     SkASSERT(timer != NULL);
     if (fCurrTiming >= fMaxNumTimings) {
         return false;
     }

     fWallTimes[fCurrTiming] = timer->fWall;
     fTruncatedWallTimes[fCurrTiming] = timer->fTruncatedWall;
     fCpuTimes[fCurrTiming] = timer->fCpu;
     fTruncatedCpuTimes[fCurrTiming] = timer->fTruncatedCpu;
     fGpuTimes[fCurrTiming] = timer->fGpu;

     ++fCurrTiming;

     return true;
 }

 SkString TimerData::getResult(const char* doubleFormat,
                               Result result,
                               const char *configName,
                               uint32_t timerFlags,
                               int itersPerTiming) {
     SkASSERT(itersPerTiming >= 1);

     if (!fCurrTiming) {
         return SkString("");
     }

     int numTimings = fCurrTiming;

     SkString wallStr(" msecs = ");
     SkString truncWallStr(" Wmsecs = ");
     SkString cpuStr(" cmsecs = ");
     SkString truncCpuStr(" Cmsecs = ");
     SkString gpuStr(" gmsecs = ");

     double wallMin = std::numeric_limits<double>::max();
     double truncWallMin = std::numeric_limits<double>::max();
     double cpuMin = std::numeric_limits<double>::max();
     double truncCpuMin = std::numeric_limits<double>::max();
     double gpuMin = std::numeric_limits<double>::max();

     double wallSum = 0;
     double truncWallSum = 0;
     double cpuSum = 0;
     double truncCpuSum = 0;
     double gpuSum = 0;

     for (int i = 0; i < numTimings; ++i) {
         if (kPerIter_Result == result) {
             wallStr.appendf(doubleFormat, fWallTimes[i] / itersPerTiming);
             truncWallStr.appendf(doubleFormat, fTruncatedWallTimes[i] / itersPerTiming);
             cpuStr.appendf(doubleFormat, fCpuTimes[i] / itersPerTiming);
             truncCpuStr.appendf(doubleFormat, fTruncatedCpuTimes[i] / itersPerTiming);
             gpuStr.appendf(doubleFormat, fGpuTimes[i] / itersPerTiming);

             if (i != numTimings - 1) {
                 static const char kSep[] = ", ";
                 wallStr.append(kSep);
                 truncWallStr.append(kSep);
                 cpuStr.append(kSep);
                 truncCpuStr.append(kSep);
                 gpuStr.append(kSep);
             }
         } else if (kMin_Result == result) {
             wallMin = SkTMin(wallMin, fWallTimes[i]);
             truncWallMin = SkTMin(truncWallMin, fTruncatedWallTimes[i]);
             cpuMin = SkTMin(cpuMin, fCpuTimes[i]);
             truncCpuMin = SkTMin(truncCpuMin, fTruncatedCpuTimes[i]);
             gpuMin = SkTMin(gpuMin, fGpuTimes[i]);
         } else {
             SkASSERT(kAvg_Result == result);
             wallSum += fWallTimes[i];
             truncWallSum += fTruncatedWallTimes[i];
             cpuSum += fCpuTimes[i];
             truncCpuSum += fTruncatedCpuTimes[i];
         }

         // We always track the GPU sum because whether it is non-zero indicates if valid gpu times
         // were recorded at all.
         gpuSum += fGpuTimes[i];
     }

     if (kMin_Result == result) {
         wallStr.appendf(doubleFormat, wallMin / itersPerTiming);
         truncWallStr.appendf(doubleFormat, truncWallMin / itersPerTiming);
         cpuStr.appendf(doubleFormat, cpuMin / itersPerTiming);
         truncCpuStr.appendf(doubleFormat, truncCpuMin / itersPerTiming);
         gpuStr.appendf(doubleFormat, gpuMin / itersPerTiming);
     } else if (kAvg_Result == result) {
         int divisor = numTimings * itersPerTiming;
         wallStr.appendf(doubleFormat, wallSum / divisor);
         truncWallStr.appendf(doubleFormat, truncWallSum / divisor);
         cpuStr.appendf(doubleFormat, cpuSum / divisor);
         truncCpuStr.appendf(doubleFormat, truncCpuSum / divisor);
         gpuStr.appendf(doubleFormat, gpuSum / divisor);
     }

     SkString str;
     str.printf("  %4s:", configName);
     if (timerFlags & kWall_Flag) {
         str += wallStr;
     }
     if (timerFlags & kTruncatedWall_Flag) {
         str += truncWallStr;
     }
     if (timerFlags & kCpu_Flag) {
         str += cpuStr;
     }
     if (timerFlags & kTruncatedCpu_Flag) {
         str += truncCpuStr;
     }
     if ((timerFlags & kGpu_Flag) && gpuSum > 0) {
         str += gpuStr;
     }
     return str;
 }

 Json::Value TimerData::getJSON(uint32_t timerFlags,
                                Result result,
                                int itersPerTiming) {
     SkASSERT(itersPerTiming >= 1);
     Json::Value dataNode;
     Json::Value wallNode, truncWall, cpuNode, truncCpu, gpuNode;
     if (!fCurrTiming) {
         return dataNode;
     }

     int numTimings = fCurrTiming;

     double wallMin = std::numeric_limits<double>::max();
     double truncWallMin = std::numeric_limits<double>::max();
     double cpuMin = std::numeric_limits<double>::max();
     double truncCpuMin = std::numeric_limits<double>::max();
     double gpuMin = std::numeric_limits<double>::max();

     double wallSum = 0;
     double truncWallSum = 0;
     double cpuSum = 0;
     double truncCpuSum = 0;
     double gpuSum = 0;

     for (int i = 0; i < numTimings; ++i) {
         if (kPerIter_Result == result) {
             wallNode.append(fWallTimes[i] / itersPerTiming);
             truncWall.append(fTruncatedWallTimes[i] / itersPerTiming);
             cpuNode.append(fCpuTimes[i] / itersPerTiming);
             truncCpu.append(fTruncatedCpuTimes[i] / itersPerTiming);
             gpuNode.append(fGpuTimes[i] / itersPerTiming);
         } else if (kMin_Result == result) {
             wallMin = SkTMin(wallMin, fWallTimes[i]);
             truncWallMin = SkTMin(truncWallMin, fTruncatedWallTimes[i]);
             cpuMin = SkTMin(cpuMin, fCpuTimes[i]);
             truncCpuMin = SkTMin(truncCpuMin, fTruncatedCpuTimes[i]);
             gpuMin = SkTMin(gpuMin, fGpuTimes[i]);
         } else {
             SkASSERT(kAvg_Result == result);
             wallSum += fWallTimes[i];
             truncWallSum += fTruncatedWallTimes[i];
             cpuSum += fCpuTimes[i];
             truncCpuSum += fTruncatedCpuTimes[i];
         }

         // We always track the GPU sum because whether it is non-zero indicates if valid gpu times
         // were recorded at all.
         gpuSum += fGpuTimes[i];
     }

     if (kMin_Result == result) {
         wallNode.append(wallMin / itersPerTiming);
         truncWall.append(truncWallMin / itersPerTiming);
         cpuNode.append(cpuMin / itersPerTiming);
         truncCpu.append(truncCpuMin / itersPerTiming);
         gpuNode.append(gpuMin / itersPerTiming);
     } else if (kAvg_Result == result) {
         int divisor = numTimings * itersPerTiming;
         wallNode.append(wallSum / divisor);
         truncWall.append(truncWallSum / divisor);
         cpuNode.append(cpuSum / divisor);
         truncCpu.append(truncCpuSum / divisor);
         gpuNode.append(gpuSum / divisor);
     }

     if (timerFlags & kWall_Flag) {
         dataNode["wall"] = wallNode;
     }
     if (timerFlags & kTruncatedWall_Flag) {
         dataNode["truncWall"] = truncWall;
     }
     if (timerFlags & kCpu_Flag) {
         dataNode["cpu"] = cpuNode;
     }
     if (timerFlags & kTruncatedCpu_Flag) {
         dataNode["trucCpu"] = truncCpu;
     }
     if ((timerFlags & kGpu_Flag) && gpuSum > 0) {
         dataNode["gpu"] = gpuNode;
     }
     return dataNode;
 }
	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/
	#include "TimerData.h"

	#include "Timer.h"
	#include <limits>

	TimerData::TimerData(int maxNumTimings)
	: fMaxNumTimings(maxNumTimings)
	, fCurrTiming(0)
	, fWallTimes(maxNumTimings)
	, fTruncatedWallTimes(maxNumTimings)
	, fCpuTimes(maxNumTimings)
	, fTruncatedCpuTimes(maxNumTimings)
	, fGpuTimes(maxNumTimings) {}

	bool TimerData::appendTimes(Timer* timer) {
	SkASSERT(timer != NULL);
	if (fCurrTiming >= fMaxNumTimings) {
	return false;
	}

	fWallTimes[fCurrTiming] = timer->fWall;
	fTruncatedWallTimes[fCurrTiming] = timer->fTruncatedWall;
	fCpuTimes[fCurrTiming] = timer->fCpu;
	fTruncatedCpuTimes[fCurrTiming] = timer->fTruncatedCpu;
	fGpuTimes[fCurrTiming] = timer->fGpu;

	++fCurrTiming;

	return true;
	}

	SkString TimerData::getResult(const char* doubleFormat,
	Result result,
	const char *configName,
	uint32_t timerFlags,
	int itersPerTiming) {
	SkASSERT(itersPerTiming >= 1);

	if (!fCurrTiming) {
	return SkString("");
	}

	int numTimings = fCurrTiming;

	SkString wallStr(" msecs = ");
	SkString truncWallStr(" Wmsecs = ");
	SkString cpuStr(" cmsecs = ");
	SkString truncCpuStr(" Cmsecs = ");
	SkString gpuStr(" gmsecs = ");

	double wallMin = std::numeric_limits<double>::max();
	double truncWallMin = std::numeric_limits<double>::max();
	double cpuMin = std::numeric_limits<double>::max();
	double truncCpuMin = std::numeric_limits<double>::max();
	double gpuMin = std::numeric_limits<double>::max();

	double wallSum = 0;
	double truncWallSum = 0;
	double cpuSum = 0;
	double truncCpuSum = 0;
	double gpuSum = 0;

	for (int i = 0; i < numTimings; ++i) {
	if (kPerIter_Result == result) {
	wallStr.appendf(doubleFormat, fWallTimes[i] / itersPerTiming);
	truncWallStr.appendf(doubleFormat, fTruncatedWallTimes[i] / itersPerTiming);
	cpuStr.appendf(doubleFormat, fCpuTimes[i] / itersPerTiming);
	truncCpuStr.appendf(doubleFormat, fTruncatedCpuTimes[i] / itersPerTiming);
	gpuStr.appendf(doubleFormat, fGpuTimes[i] / itersPerTiming);

	if (i != numTimings - 1) {
	static const char kSep[] = ", ";
	wallStr.append(kSep);
	truncWallStr.append(kSep);
	cpuStr.append(kSep);
	truncCpuStr.append(kSep);
	gpuStr.append(kSep);
	}
	} else if (kMin_Result == result) {
	wallMin = SkTMin(wallMin, fWallTimes[i]);
	truncWallMin = SkTMin(truncWallMin, fTruncatedWallTimes[i]);
	cpuMin = SkTMin(cpuMin, fCpuTimes[i]);
	truncCpuMin = SkTMin(truncCpuMin, fTruncatedCpuTimes[i]);
	gpuMin = SkTMin(gpuMin, fGpuTimes[i]);
	} else {
	SkASSERT(kAvg_Result == result);
	wallSum += fWallTimes[i];
	truncWallSum += fTruncatedWallTimes[i];
	cpuSum += fCpuTimes[i];
	truncCpuSum += fTruncatedCpuTimes[i];
	}

	// We always track the GPU sum because whether it is non-zero indicates if valid gpu times
	// were recorded at all.
	gpuSum += fGpuTimes[i];
	}

	if (kMin_Result == result) {
	wallStr.appendf(doubleFormat, wallMin / itersPerTiming);
	truncWallStr.appendf(doubleFormat, truncWallMin / itersPerTiming);
	cpuStr.appendf(doubleFormat, cpuMin / itersPerTiming);
	truncCpuStr.appendf(doubleFormat, truncCpuMin / itersPerTiming);
	gpuStr.appendf(doubleFormat, gpuMin / itersPerTiming);
	} else if (kAvg_Result == result) {
	int divisor = numTimings * itersPerTiming;
	wallStr.appendf(doubleFormat, wallSum / divisor);
	truncWallStr.appendf(doubleFormat, truncWallSum / divisor);
	cpuStr.appendf(doubleFormat, cpuSum / divisor);
	truncCpuStr.appendf(doubleFormat, truncCpuSum / divisor);
	gpuStr.appendf(doubleFormat, gpuSum / divisor);
	}

	SkString str;
	str.printf(" %4s:", configName);
	if (timerFlags & kWall_Flag) {
	str += wallStr;
	}
	if (timerFlags & kTruncatedWall_Flag) {
	str += truncWallStr;
	}
	if (timerFlags & kCpu_Flag) {
	str += cpuStr;
	}
	if (timerFlags & kTruncatedCpu_Flag) {
	str += truncCpuStr;
	}
	if ((timerFlags & kGpu_Flag) && gpuSum > 0) {
	str += gpuStr;
	}
	return str;
	}

	Json::Value TimerData::getJSON(uint32_t timerFlags,
	Result result,
	int itersPerTiming) {
	SkASSERT(itersPerTiming >= 1);
	Json::Value dataNode;
	Json::Value wallNode, truncWall, cpuNode, truncCpu, gpuNode;
	if (!fCurrTiming) {
	return dataNode;
	}

	int numTimings = fCurrTiming;

	double wallMin = std::numeric_limits<double>::max();
	double truncWallMin = std::numeric_limits<double>::max();
	double cpuMin = std::numeric_limits<double>::max();
	double truncCpuMin = std::numeric_limits<double>::max();
	double gpuMin = std::numeric_limits<double>::max();

	double wallSum = 0;
	double truncWallSum = 0;
	double cpuSum = 0;
	double truncCpuSum = 0;
	double gpuSum = 0;

	for (int i = 0; i < numTimings; ++i) {
	if (kPerIter_Result == result) {
	wallNode.append(fWallTimes[i] / itersPerTiming);
	truncWall.append(fTruncatedWallTimes[i] / itersPerTiming);
	cpuNode.append(fCpuTimes[i] / itersPerTiming);
	truncCpu.append(fTruncatedCpuTimes[i] / itersPerTiming);
	gpuNode.append(fGpuTimes[i] / itersPerTiming);
	} else if (kMin_Result == result) {
	wallMin = SkTMin(wallMin, fWallTimes[i]);
	truncWallMin = SkTMin(truncWallMin, fTruncatedWallTimes[i]);
	cpuMin = SkTMin(cpuMin, fCpuTimes[i]);
	truncCpuMin = SkTMin(truncCpuMin, fTruncatedCpuTimes[i]);
	gpuMin = SkTMin(gpuMin, fGpuTimes[i]);
	} else {
	SkASSERT(kAvg_Result == result);
	wallSum += fWallTimes[i];
	truncWallSum += fTruncatedWallTimes[i];
	cpuSum += fCpuTimes[i];
	truncCpuSum += fTruncatedCpuTimes[i];
	}

	// We always track the GPU sum because whether it is non-zero indicates if valid gpu times
	// were recorded at all.
	gpuSum += fGpuTimes[i];
	}

	if (kMin_Result == result) {
	wallNode.append(wallMin / itersPerTiming);
	truncWall.append(truncWallMin / itersPerTiming);
	cpuNode.append(cpuMin / itersPerTiming);
	truncCpu.append(truncCpuMin / itersPerTiming);
	gpuNode.append(gpuMin / itersPerTiming);
	} else if (kAvg_Result == result) {
	int divisor = numTimings * itersPerTiming;
	wallNode.append(wallSum / divisor);
	truncWall.append(truncWallSum / divisor);
	cpuNode.append(cpuSum / divisor);
	truncCpu.append(truncCpuSum / divisor);
	gpuNode.append(gpuSum / divisor);
	}

	if (timerFlags & kWall_Flag) {
	dataNode["wall"] = wallNode;
	}
	if (timerFlags & kTruncatedWall_Flag) {
	dataNode["truncWall"] = truncWall;
	}
	if (timerFlags & kCpu_Flag) {
	dataNode["cpu"] = cpuNode;
	}
	if (timerFlags & kTruncatedCpu_Flag) {
	dataNode["trucCpu"] = truncCpu;
	}
	if ((timerFlags & kGpu_Flag) && gpuSum > 0) {
	dataNode["gpu"] = gpuNode;
	}
	return dataNode;
	}