/** * @file llstat.cpp * * Copyright (c) 2001-$CurrentYear$, Linden Research, Inc. * $License$ */ #include "linden_common.h" #include "llstat.h" #include "llframetimer.h" #include "timing.h" class LLStatAccum::impl { public: static const TimeScale IMPL_NUM_SCALES = (TimeScale)(SCALE_TWO_MINUTE + 1); static U64 sScaleTimes[IMPL_NUM_SCALES]; BOOL mUseFrameTimer; BOOL mRunning; U64 mLastTime; struct Bucket { F64 accum; U64 endTime; BOOL lastValid; F64 lastAccum; }; Bucket mBuckets[IMPL_NUM_SCALES]; BOOL mLastSampleValid; F64 mLastSampleValue; impl(bool useFrameTimer); void reset(U64 when); void sum(F64 value); void sum(F64 value, U64 when); F32 meanValue(TimeScale scale) const; U64 getCurrentUsecs() const; // Get current microseconds based on timer type }; U64 LLStatAccum::impl::sScaleTimes[IMPL_NUM_SCALES] = { USEC_PER_SEC * 1, // seconds USEC_PER_SEC * 60, // minutes USEC_PER_SEC * 60 * 2 // minutes #if 0 // enable these when more time scales are desired USEC_PER_SEC * 60*60, // hours USEC_PER_SEC * 24*60*60, // days USEC_PER_SEC * 7*24*60*60, // weeks #endif }; LLStatAccum::impl::impl(bool useFrameTimer) { mUseFrameTimer = useFrameTimer; mRunning = FALSE; mLastSampleValid = FALSE; } void LLStatAccum::impl::reset(U64 when) { mRunning = TRUE; mLastTime = when; for (int i = 0; i < IMPL_NUM_SCALES; ++i) { mBuckets[i].accum = 0.0; mBuckets[i].endTime = when + sScaleTimes[i]; mBuckets[i].lastValid = FALSE; } } void LLStatAccum::impl::sum(F64 value) { sum(value, getCurrentUsecs()); } void LLStatAccum::impl::sum(F64 value, U64 when) { if (!mRunning) { reset(when); return; } if (when < mLastTime) { // This happens a LOT on some dual core systems. lldebugs << "LLStatAccum::sum clock has gone backwards from " << mLastTime << " to " << when << ", resetting" << llendl; reset(when); return; } for (int i = 0; i < IMPL_NUM_SCALES; ++i) { Bucket& bucket = mBuckets[i]; if (when < bucket.endTime) { bucket.accum += value; } else { U64 timeScale = sScaleTimes[i]; U64 timeSpan = when - mLastTime; // how long is this value for U64 timeLeft = when - bucket.endTime; // how much time is left after filling this bucket if (timeLeft < timeScale) { F64 valueLeft = value * timeLeft / timeSpan; bucket.lastValid = TRUE; bucket.lastAccum = bucket.accum + (value - valueLeft); bucket.accum = valueLeft; bucket.endTime += timeScale; } else { U64 timeTail = timeLeft % timeScale; bucket.lastValid = TRUE; bucket.lastAccum = value * timeScale / timeSpan; bucket.accum = value * timeTail / timeSpan; bucket.endTime += (timeLeft - timeTail) + timeScale; } } } mLastTime = when; } F32 LLStatAccum::impl::meanValue(TimeScale scale) const { if (!mRunning) { return 0.0; } if (scale < 0 || scale >= IMPL_NUM_SCALES) { llwarns << "llStatAccum::meanValue called for unsupported scale: " << scale << llendl; return 0.0; } const Bucket& bucket = mBuckets[scale]; F64 value = bucket.accum; U64 timeLeft = bucket.endTime - mLastTime; U64 scaleTime = sScaleTimes[scale]; if (bucket.lastValid) { value += bucket.lastAccum * timeLeft / scaleTime; } else if (timeLeft < scaleTime) { value *= scaleTime / (scaleTime - timeLeft); } else { value = 0.0; } return (F32)(value / scaleTime); } U64 LLStatAccum::impl::getCurrentUsecs() const { if (mUseFrameTimer) { return LLFrameTimer::getTotalTime(); } else { return totalTime(); } } LLStatAccum::LLStatAccum(bool useFrameTimer) : m(* new impl(useFrameTimer)) { } LLStatAccum::~LLStatAccum() { delete &m; } F32 LLStatAccum::meanValue(TimeScale scale) const { return m.meanValue(scale); } LLStatMeasure::LLStatMeasure(bool use_frame_timer) : LLStatAccum(use_frame_timer) { } void LLStatMeasure::sample(F64 value) { U64 when = m.getCurrentUsecs(); if (m.mLastSampleValid) { F64 avgValue = (value + m.mLastSampleValue) / 2.0; F64 interval = (F64)(when - m.mLastTime); m.sum(avgValue * interval, when); } else { m.reset(when); } m.mLastSampleValid = TRUE; m.mLastSampleValue = value; } LLStatRate::LLStatRate(bool use_frame_timer) : LLStatAccum(use_frame_timer) { } void LLStatRate::count(U32 value) { m.sum((F64)value * impl::sScaleTimes[SCALE_SECOND]); } LLStatTime::LLStatTime(bool use_frame_timer) : LLStatAccum(use_frame_timer) { } void LLStatTime::start() { m.sum(0.0); } void LLStatTime::stop() { U64 endTime = m.getCurrentUsecs(); m.sum((F64)(endTime - m.mLastTime), endTime); } LLTimer LLStat::sTimer; LLFrameTimer LLStat::sFrameTimer; LLStat::LLStat(const U32 num_bins, const BOOL use_frame_timer) { llassert(num_bins > 0); U32 i; mUseFrameTimer = use_frame_timer; mNumValues = 0; mLastValue = 0.f; mLastTime = 0.f; mNumBins = num_bins; mCurBin = (mNumBins-1); mNextBin = 0; mBins = new F32[mNumBins]; mBeginTime = new F64[mNumBins]; mTime = new F64[mNumBins]; mDT = new F32[mNumBins]; for (i = 0; i < mNumBins; i++) { mBins[i] = 0.f; mBeginTime[i] = 0.0; mTime[i] = 0.0; mDT[i] = 0.f; } } LLStat::~LLStat() { delete[] mBins; delete[] mBeginTime; delete[] mTime; delete[] mDT; } void LLStat::reset() { U32 i; mNumValues = 0; mLastValue = 0.f; mCurBin = (mNumBins-1); delete[] mBins; delete[] mBeginTime; delete[] mTime; delete[] mDT; mBins = new F32[mNumBins]; mBeginTime = new F64[mNumBins]; mTime = new F64[mNumBins]; mDT = new F32[mNumBins]; for (i = 0; i < mNumBins; i++) { mBins[i] = 0.f; mBeginTime[i] = 0.0; mTime[i] = 0.0; mDT[i] = 0.f; } } void LLStat::setBeginTime(const F64 time) { mBeginTime[mNextBin] = time; } void LLStat::addValueTime(const F64 time, const F32 value) { if (mNumValues < mNumBins) { mNumValues++; } // Increment the bin counters. mCurBin++; if ((U32)mCurBin == mNumBins) { mCurBin = 0; } mNextBin++; if ((U32)mNextBin == mNumBins) { mNextBin = 0; } mBins[mCurBin] = value; mTime[mCurBin] = time; mDT[mCurBin] = (F32)(mTime[mCurBin] - mBeginTime[mCurBin]); //this value is used to prime the min/max calls mLastTime = mTime[mCurBin]; mLastValue = value; // Set the begin time for the next stat segment. mBeginTime[mNextBin] = mTime[mCurBin]; mTime[mNextBin] = mTime[mCurBin]; mDT[mNextBin] = 0.f; } void LLStat::start() { if (mUseFrameTimer) { mBeginTime[mNextBin] = sFrameTimer.getElapsedSeconds(); } else { mBeginTime[mNextBin] = sTimer.getElapsedTimeF64(); } } void LLStat::addValue(const F32 value) { if (mNumValues < mNumBins) { mNumValues++; } // Increment the bin counters. mCurBin++; if ((U32)mCurBin == mNumBins) { mCurBin = 0; } mNextBin++; if ((U32)mNextBin == mNumBins) { mNextBin = 0; } mBins[mCurBin] = value; if (mUseFrameTimer) { mTime[mCurBin] = sFrameTimer.getElapsedSeconds(); } else { mTime[mCurBin] = sTimer.getElapsedTimeF64(); } mDT[mCurBin] = (F32)(mTime[mCurBin] - mBeginTime[mCurBin]); //this value is used to prime the min/max calls mLastTime = mTime[mCurBin]; mLastValue = value; // Set the begin time for the next stat segment. mBeginTime[mNextBin] = mTime[mCurBin]; mTime[mNextBin] = mTime[mCurBin]; mDT[mNextBin] = 0.f; } F32 LLStat::getMax() const { U32 i; F32 current_max = mLastValue; if (mNumBins == 0) { current_max = 0.f; } else { for (i = 0; (i < mNumBins) && (i < mNumValues); i++) { // Skip the bin we're currently filling. if (i == (U32)mNextBin) { continue; } if (mBins[i] > current_max) { current_max = mBins[i]; } } } return current_max; } F32 LLStat::getMean() const { U32 i; F32 current_mean = 0.f; U32 samples = 0; for (i = 0; (i < mNumBins) && (i < mNumValues); i++) { // Skip the bin we're currently filling. if (i == (U32)mNextBin) { continue; } current_mean += mBins[i]; samples++; } // There will be a wrap error at 2^32. :) if (samples != 0) { current_mean /= samples; } else { current_mean = 0.f; } return current_mean; } F32 LLStat::getMin() const { U32 i; F32 current_min = mLastValue; if (mNumBins == 0) { current_min = 0.f; } else { for (i = 0; (i < mNumBins) && (i < mNumValues); i++) { // Skip the bin we're currently filling. if (i == (U32)mNextBin) { continue; } if (mBins[i] < current_min) { current_min = mBins[i]; } } } return current_min; } F32 LLStat::getSum() const { U32 i; F32 sum = 0.f; for (i = 0; (i < mNumBins) && (i < mNumValues); i++) { // Skip the bin we're currently filling. if (i == (U32)mNextBin) { continue; } sum += mBins[i]; } return sum; } F32 LLStat::getSumDuration() const { U32 i; F32 sum = 0.f; for (i = 0; (i < mNumBins) && (i < mNumValues); i++) { // Skip the bin we're currently filling. if (i == (U32)mNextBin) { continue; } sum += mDT[i]; } return sum; } F32 LLStat::getPrev(S32 age) const { S32 bin; bin = mCurBin - age; while (bin < 0) { bin += mNumBins; } if (bin == mNextBin) { // Bogus for bin we're currently working on. return 0.f; } return mBins[bin]; } F32 LLStat::getPrevPerSec(S32 age) const { S32 bin; bin = mCurBin - age; while (bin < 0) { bin += mNumBins; } if (bin == mNextBin) { // Bogus for bin we're currently working on. return 0.f; } return mBins[bin] / mDT[bin]; } F64 LLStat::getPrevBeginTime(S32 age) const { S32 bin; bin = mCurBin - age; while (bin < 0) { bin += mNumBins; } if (bin == mNextBin) { // Bogus for bin we're currently working on. return 0.f; } return mBeginTime[bin]; } F64 LLStat::getPrevTime(S32 age) const { S32 bin; bin = mCurBin - age; while (bin < 0) { bin += mNumBins; } if (bin == mNextBin) { // Bogus for bin we're currently working on. return 0.f; } return mTime[bin]; } F32 LLStat::getBin(S32 bin) const { return mBins[bin]; } F32 LLStat::getBinPerSec(S32 bin) const { return mBins[bin] / mDT[bin]; } F64 LLStat::getBinBeginTime(S32 bin) const { return mBeginTime[bin]; } F64 LLStat::getBinTime(S32 bin) const { return mTime[bin]; } F32 LLStat::getCurrent() const { return mBins[mCurBin]; } F32 LLStat::getCurrentPerSec() const { return mBins[mCurBin] / mDT[mCurBin]; } F64 LLStat::getCurrentBeginTime() const { return mBeginTime[mCurBin]; } F64 LLStat::getCurrentTime() const { return mTime[mCurBin]; } F32 LLStat::getCurrentDuration() const { return mDT[mCurBin]; } F32 LLStat::getMeanPerSec() const { U32 i; F32 value = 0.f; F32 dt = 0.f; for (i = 0; (i < mNumBins) && (i < mNumValues); i++) { // Skip the bin we're currently filling. if (i == (U32)mNextBin) { continue; } value += mBins[i]; dt += mDT[i]; } if (dt > 0.f) { return value/dt; } else { return 0.f; } } F32 LLStat::getMeanDuration() const { F32 dur = 0.0f; U32 count = 0; for (U32 i=0; (i < mNumBins) && (i < mNumValues); i++) { if (i == (U32)mNextBin) { continue; } dur += mDT[i]; count++; } if (count > 0) { dur /= F32(count); return dur; } else { return 0.f; } } F32 LLStat::getMaxPerSec() const { U32 i; F32 value; if (mNextBin != 0) { value = mBins[0]/mDT[0]; } else if (mNumValues > 0) { value = mBins[1]/mDT[1]; } else { value = 0.f; } for (i = 0; (i < mNumBins) && (i < mNumValues); i++) { // Skip the bin we're currently filling. if (i == (U32)mNextBin) { continue; } value = llmax(value, mBins[i]/mDT[i]); } return value; } F32 LLStat::getMinPerSec() const { U32 i; F32 value; if (mNextBin != 0) { value = mBins[0]/mDT[0]; } else if (mNumValues > 0) { value = mBins[1]/mDT[1]; } else { value = 0.f; } for (i = 0; (i < mNumBins) && (i < mNumValues); i++) { // Skip the bin we're currently filling. if (i == (U32)mNextBin) { continue; } value = llmin(value, mBins[i]/mDT[i]); } return value; } F32 LLStat::getMinDuration() const { F32 dur = 0.0f; for (U32 i=0; (i < mNumBins) && (i < mNumValues); i++) { dur = llmin(dur, mDT[i]); } return dur; } U32 LLStat::getNumValues() const { return mNumValues; } S32 LLStat::getNumBins() const { return mNumBins; } S32 LLStat::getCurBin() const { return mCurBin; } S32 LLStat::getNextBin() const { return mNextBin; } F64 LLStat::getLastTime() const { return mLastTime; }