lib/ProfileData/ProfileSummaryBuilder.cpp - llvm-project/llvm - Git at Google

 //=-- ProfilesummaryBuilder.cpp - Profile summary computation ---------------=//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file contains support for computing profile summary data.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/IR/Attributes.h"
 #include "llvm/IR/Function.h"
 #include "llvm/IR/Metadata.h"
 #include "llvm/IR/Type.h"
 #include "llvm/ProfileData/InstrProf.h"
 #include "llvm/ProfileData/ProfileCommon.h"
 #include "llvm/ProfileData/SampleProf.h"
 #include "llvm/Support/Casting.h"
 #include "llvm/Support/CommandLine.h"

 using namespace llvm;

 cl::opt<bool> UseContextLessSummary(
     "profile-summary-contextless", cl::Hidden, cl::init(false), cl::ZeroOrMore,
     cl::desc("Merge context profiles before calculating thresholds."));

 // A set of cutoff values. Each value, when divided by ProfileSummary::Scale
 // (which is 1000000) is a desired percentile of total counts.
 static const uint32_t DefaultCutoffsData[] = {
     10000,  /*  1% */
     100000, /* 10% */
     200000, 300000, 400000, 500000, 600000, 700000, 800000,
     900000, 950000, 990000, 999000, 999900, 999990, 999999};
 const ArrayRef<uint32_t> ProfileSummaryBuilder::DefaultCutoffs =
     DefaultCutoffsData;

 const ProfileSummaryEntry &
 ProfileSummaryBuilder::getEntryForPercentile(SummaryEntryVector &DS,
                                              uint64_t Percentile) {
   auto It = partition_point(DS, [=](const ProfileSummaryEntry &Entry) {
     return Entry.Cutoff < Percentile;
   });
   // The required percentile has to be <= one of the percentiles in the
   // detailed summary.
   if (It == DS.end())
     report_fatal_error("Desired percentile exceeds the maximum cutoff");
   return *It;
 }

 void InstrProfSummaryBuilder::addRecord(const InstrProfRecord &R) {
   // The first counter is not necessarily an entry count for IR
   // instrumentation profiles.
   // Eventually MaxFunctionCount will become obsolete and this can be
   // removed.
   addEntryCount(R.Counts[0]);
   for (size_t I = 1, E = R.Counts.size(); I < E; ++I)
     addInternalCount(R.Counts[I]);
 }

 // To compute the detailed summary, we consider each line containing samples as
 // equivalent to a block with a count in the instrumented profile.
 void SampleProfileSummaryBuilder::addRecord(
     const sampleprof::FunctionSamples &FS, bool isCallsiteSample) {
   if (!isCallsiteSample) {
     NumFunctions++;
     if (FS.getHeadSamples() > MaxFunctionCount)
       MaxFunctionCount = FS.getHeadSamples();
   }
   for (const auto &I : FS.getBodySamples())
     addCount(I.second.getSamples());
   for (const auto &I : FS.getCallsiteSamples())
     for (const auto &CS : I.second)
       addRecord(CS.second, true);
 }

 // The argument to this method is a vector of cutoff percentages and the return
 // value is a vector of (Cutoff, MinCount, NumCounts) triplets.
 void ProfileSummaryBuilder::computeDetailedSummary() {
   if (DetailedSummaryCutoffs.empty())
     return;
   llvm::sort(DetailedSummaryCutoffs);
   auto Iter = CountFrequencies.begin();
   const auto End = CountFrequencies.end();

   uint32_t CountsSeen = 0;
   uint64_t CurrSum = 0, Count = 0;

   for (const uint32_t Cutoff : DetailedSummaryCutoffs) {
     assert(Cutoff <= 999999);
     APInt Temp(128, TotalCount);
     APInt N(128, Cutoff);
     APInt D(128, ProfileSummary::Scale);
     Temp *= N;
     Temp = Temp.sdiv(D);
     uint64_t DesiredCount = Temp.getZExtValue();
     assert(DesiredCount <= TotalCount);
     while (CurrSum < DesiredCount && Iter != End) {
       Count = Iter->first;
       uint32_t Freq = Iter->second;
       CurrSum += (Count * Freq);
       CountsSeen += Freq;
       Iter++;
     }
     assert(CurrSum >= DesiredCount);
     ProfileSummaryEntry PSE = {Cutoff, Count, CountsSeen};
     DetailedSummary.push_back(PSE);
   }
 }

 std::unique_ptr<ProfileSummary> SampleProfileSummaryBuilder::getSummary() {
   computeDetailedSummary();
   return std::make_unique<ProfileSummary>(
       ProfileSummary::PSK_Sample, DetailedSummary, TotalCount, MaxCount, 0,
       MaxFunctionCount, NumCounts, NumFunctions);
 }

 std::unique_ptr<ProfileSummary>
 SampleProfileSummaryBuilder::computeSummaryForProfiles(
     const StringMap<sampleprof::FunctionSamples> &Profiles) {
   assert(NumFunctions == 0 &&
          "This can only be called on an empty summary builder");
   StringMap<sampleprof::FunctionSamples> ContextLessProfiles;
   const StringMap<sampleprof::FunctionSamples> *ProfilesToUse = &Profiles;
   // For CSSPGO, context-sensitive profile effectively split a function profile
   // into many copies each representing the CFG profile of a particular calling
   // context. That makes the count distribution looks more flat as we now have
   // more function profiles each with lower counts, which in turn leads to lower
   // hot thresholds. To compensate for that, by defauly we merge context
   // profiles before coumputing profile summary.
   if (UseContextLessSummary || (sampleprof::FunctionSamples::ProfileIsCS &&
                                 !UseContextLessSummary.getNumOccurrences())) {
     for (const auto &I : Profiles) {
       ContextLessProfiles[I.second.getName()].merge(I.second);
     }
     ProfilesToUse = &ContextLessProfiles;
   }

   for (const auto &I : *ProfilesToUse) {
     const sampleprof::FunctionSamples &Profile = I.second;
     addRecord(Profile);
   }

   return getSummary();
 }

 std::unique_ptr<ProfileSummary> InstrProfSummaryBuilder::getSummary() {
   computeDetailedSummary();
   return std::make_unique<ProfileSummary>(
       ProfileSummary::PSK_Instr, DetailedSummary, TotalCount, MaxCount,
       MaxInternalBlockCount, MaxFunctionCount, NumCounts, NumFunctions);
 }

 void InstrProfSummaryBuilder::addEntryCount(uint64_t Count) {
   NumFunctions++;

   // Skip invalid count.
   if (Count == (uint64_t)-1)
     return;

   addCount(Count);
   if (Count > MaxFunctionCount)
     MaxFunctionCount = Count;
 }

 void InstrProfSummaryBuilder::addInternalCount(uint64_t Count) {
   // Skip invalid count.
   if (Count == (uint64_t)-1)
     return;

   addCount(Count);
   if (Count > MaxInternalBlockCount)
     MaxInternalBlockCount = Count;
 }
	//=-- ProfilesummaryBuilder.cpp - Profile summary computation ---------------=//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains support for computing profile summary data.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/IR/Attributes.h"
	#include "llvm/IR/Function.h"
	#include "llvm/IR/Metadata.h"
	#include "llvm/IR/Type.h"
	#include "llvm/ProfileData/InstrProf.h"
	#include "llvm/ProfileData/ProfileCommon.h"
	#include "llvm/ProfileData/SampleProf.h"
	#include "llvm/Support/Casting.h"
	#include "llvm/Support/CommandLine.h"

	using namespace llvm;

	cl::opt<bool> UseContextLessSummary(
	"profile-summary-contextless", cl::Hidden, cl::init(false), cl::ZeroOrMore,
	cl::desc("Merge context profiles before calculating thresholds."));

	// A set of cutoff values. Each value, when divided by ProfileSummary::Scale
	// (which is 1000000) is a desired percentile of total counts.
	static const uint32_t DefaultCutoffsData[] = {
	10000, /* 1% */
	100000, /* 10% */
	200000, 300000, 400000, 500000, 600000, 700000, 800000,
	900000, 950000, 990000, 999000, 999900, 999990, 999999};
	const ArrayRef<uint32_t> ProfileSummaryBuilder::DefaultCutoffs =
	DefaultCutoffsData;

	const ProfileSummaryEntry &
	ProfileSummaryBuilder::getEntryForPercentile(SummaryEntryVector &DS,
	uint64_t Percentile) {
	auto It = partition_point(DS, [=](const ProfileSummaryEntry &Entry) {
	return Entry.Cutoff < Percentile;
	});
	// The required percentile has to be <= one of the percentiles in the
	// detailed summary.
	if (It == DS.end())
	report_fatal_error("Desired percentile exceeds the maximum cutoff");
	return *It;
	}

	void InstrProfSummaryBuilder::addRecord(const InstrProfRecord &R) {
	// The first counter is not necessarily an entry count for IR
	// instrumentation profiles.
	// Eventually MaxFunctionCount will become obsolete and this can be
	// removed.
	addEntryCount(R.Counts[0]);
	for (size_t I = 1, E = R.Counts.size(); I < E; ++I)
	addInternalCount(R.Counts[I]);
	}

	// To compute the detailed summary, we consider each line containing samples as
	// equivalent to a block with a count in the instrumented profile.
	void SampleProfileSummaryBuilder::addRecord(
	const sampleprof::FunctionSamples &FS, bool isCallsiteSample) {
	if (!isCallsiteSample) {
	NumFunctions++;
	if (FS.getHeadSamples() > MaxFunctionCount)
	MaxFunctionCount = FS.getHeadSamples();
	}
	for (const auto &I : FS.getBodySamples())
	addCount(I.second.getSamples());
	for (const auto &I : FS.getCallsiteSamples())
	for (const auto &CS : I.second)
	addRecord(CS.second, true);
	}

	// The argument to this method is a vector of cutoff percentages and the return
	// value is a vector of (Cutoff, MinCount, NumCounts) triplets.
	void ProfileSummaryBuilder::computeDetailedSummary() {
	if (DetailedSummaryCutoffs.empty())
	return;
	llvm::sort(DetailedSummaryCutoffs);
	auto Iter = CountFrequencies.begin();
	const auto End = CountFrequencies.end();

	uint32_t CountsSeen = 0;
	uint64_t CurrSum = 0, Count = 0;

	for (const uint32_t Cutoff : DetailedSummaryCutoffs) {
	assert(Cutoff <= 999999);
	APInt Temp(128, TotalCount);
	APInt N(128, Cutoff);
	APInt D(128, ProfileSummary::Scale);
	Temp *= N;
	Temp = Temp.sdiv(D);
	uint64_t DesiredCount = Temp.getZExtValue();
	assert(DesiredCount <= TotalCount);
	while (CurrSum < DesiredCount && Iter != End) {
	Count = Iter->first;
	uint32_t Freq = Iter->second;
	CurrSum += (Count * Freq);
	CountsSeen += Freq;
	Iter++;
	}
	assert(CurrSum >= DesiredCount);
	ProfileSummaryEntry PSE = {Cutoff, Count, CountsSeen};
	DetailedSummary.push_back(PSE);
	}
	}

	std::unique_ptr<ProfileSummary> SampleProfileSummaryBuilder::getSummary() {
	computeDetailedSummary();
	return std::make_unique<ProfileSummary>(
	ProfileSummary::PSK_Sample, DetailedSummary, TotalCount, MaxCount, 0,
	MaxFunctionCount, NumCounts, NumFunctions);
	}

	std::unique_ptr<ProfileSummary>
	SampleProfileSummaryBuilder::computeSummaryForProfiles(
	const StringMap<sampleprof::FunctionSamples> &Profiles) {
	assert(NumFunctions == 0 &&
	"This can only be called on an empty summary builder");
	StringMap<sampleprof::FunctionSamples> ContextLessProfiles;
	const StringMap<sampleprof::FunctionSamples> *ProfilesToUse = &Profiles;
	// For CSSPGO, context-sensitive profile effectively split a function profile
	// into many copies each representing the CFG profile of a particular calling
	// context. That makes the count distribution looks more flat as we now have
	// more function profiles each with lower counts, which in turn leads to lower
	// hot thresholds. To compensate for that, by defauly we merge context
	// profiles before coumputing profile summary.
	if (UseContextLessSummary \|\| (sampleprof::FunctionSamples::ProfileIsCS &&
	!UseContextLessSummary.getNumOccurrences())) {
	for (const auto &I : Profiles) {
	ContextLessProfiles[I.second.getName()].merge(I.second);
	}
	ProfilesToUse = &ContextLessProfiles;
	}

	for (const auto &I : *ProfilesToUse) {
	const sampleprof::FunctionSamples &Profile = I.second;
	addRecord(Profile);
	}

	return getSummary();
	}

	std::unique_ptr<ProfileSummary> InstrProfSummaryBuilder::getSummary() {
	computeDetailedSummary();
	return std::make_unique<ProfileSummary>(
	ProfileSummary::PSK_Instr, DetailedSummary, TotalCount, MaxCount,
	MaxInternalBlockCount, MaxFunctionCount, NumCounts, NumFunctions);
	}

	void InstrProfSummaryBuilder::addEntryCount(uint64_t Count) {
	NumFunctions++;

	// Skip invalid count.
	if (Count == (uint64_t)-1)
	return;

	addCount(Count);
	if (Count > MaxFunctionCount)
	MaxFunctionCount = Count;
	}

	void InstrProfSummaryBuilder::addInternalCount(uint64_t Count) {
	// Skip invalid count.
	if (Count == (uint64_t)-1)
	return;

	addCount(Count);
	if (Count > MaxInternalBlockCount)
	MaxInternalBlockCount = Count;
	}