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e734b4c21b
The change adds support for triming and merging cold context when mergine CSSPGO profiles using llvm-profdata. This is similar to the context profile trimming in llvm-profgen, however the flexibility to trim cold context after profile is generated can be useful. Differential Revision: https://reviews.llvm.org/D100528
641 lines
25 KiB
C++
641 lines
25 KiB
C++
//===-- ProfileGenerator.cpp - Profile Generator ---------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "ProfileGenerator.h"
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#include "llvm/ProfileData/ProfileCommon.h"
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static cl::opt<std::string> OutputFilename("output", cl::value_desc("output"),
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cl::Required,
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cl::desc("Output profile file"));
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static cl::alias OutputA("o", cl::desc("Alias for --output"),
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cl::aliasopt(OutputFilename));
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static cl::opt<SampleProfileFormat> OutputFormat(
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"format", cl::desc("Format of output profile"), cl::init(SPF_Text),
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cl::values(
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clEnumValN(SPF_Binary, "binary", "Binary encoding (default)"),
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clEnumValN(SPF_Compact_Binary, "compbinary", "Compact binary encoding"),
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clEnumValN(SPF_Ext_Binary, "extbinary", "Extensible binary encoding"),
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clEnumValN(SPF_Text, "text", "Text encoding"),
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clEnumValN(SPF_GCC, "gcc",
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"GCC encoding (only meaningful for -sample)")));
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static cl::opt<int32_t, true> RecursionCompression(
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"compress-recursion",
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cl::desc("Compressing recursion by deduplicating adjacent frame "
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"sequences up to the specified size. -1 means no size limit."),
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cl::Hidden,
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cl::location(llvm::sampleprof::CSProfileGenerator::MaxCompressionSize));
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static cl::opt<uint64_t> CSProfColdThreshold(
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"csprof-cold-thres", cl::init(100), cl::ZeroOrMore,
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cl::desc("Specify the total samples threshold for a context profile to "
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"be considered cold, any cold profiles will be merged into "
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"context-less base profiles"));
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static cl::opt<bool> CSProfMergeColdContext(
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"csprof-merge-cold-context", cl::init(true), cl::ZeroOrMore,
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cl::desc("This works together with --csprof-cold-thres. If the total count "
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"of context profile is smaller than the threshold, it will be "
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"merged into context-less base profile."));
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static cl::opt<bool> CSProfTrimColdContext(
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"csprof-trim-cold-context", cl::init(true), cl::ZeroOrMore,
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cl::desc("This works together with --csprof-cold-thres. If the total count "
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"of the profile after all merge is done is still smaller than "
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"threshold, it will be trimmed."));
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using namespace llvm;
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using namespace sampleprof;
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namespace llvm {
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namespace sampleprof {
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// Initialize the MaxCompressionSize to -1 which means no size limit
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int32_t CSProfileGenerator::MaxCompressionSize = -1;
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static bool
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usePseudoProbes(const BinarySampleCounterMap &BinarySampleCounters) {
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return BinarySampleCounters.size() &&
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BinarySampleCounters.begin()->first->usePseudoProbes();
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}
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std::unique_ptr<ProfileGenerator>
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ProfileGenerator::create(const BinarySampleCounterMap &BinarySampleCounters,
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enum PerfScriptType SampleType) {
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std::unique_ptr<ProfileGenerator> ProfileGenerator;
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if (SampleType == PERF_LBR_STACK) {
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if (usePseudoProbes(BinarySampleCounters)) {
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ProfileGenerator.reset(
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new PseudoProbeCSProfileGenerator(BinarySampleCounters));
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} else {
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ProfileGenerator.reset(new CSProfileGenerator(BinarySampleCounters));
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}
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} else {
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// TODO:
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llvm_unreachable("Unsupported perfscript!");
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}
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return ProfileGenerator;
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}
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void ProfileGenerator::write(std::unique_ptr<SampleProfileWriter> Writer,
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StringMap<FunctionSamples> &ProfileMap) {
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if (std::error_code EC = Writer->write(ProfileMap))
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exitWithError(std::move(EC));
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}
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void ProfileGenerator::write() {
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auto WriterOrErr = SampleProfileWriter::create(OutputFilename, OutputFormat);
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if (std::error_code EC = WriterOrErr.getError())
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exitWithError(EC, OutputFilename);
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write(std::move(WriterOrErr.get()), ProfileMap);
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}
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void ProfileGenerator::findDisjointRanges(RangeSample &DisjointRanges,
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const RangeSample &Ranges) {
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/*
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Regions may overlap with each other. Using the boundary info, find all
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disjoint ranges and their sample count. BoundaryPoint contains the count
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multiple samples begin/end at this points.
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|<--100-->| Sample1
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|<------200------>| Sample2
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A B C
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In the example above,
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Sample1 begins at A, ends at B, its value is 100.
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Sample2 beings at A, ends at C, its value is 200.
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For A, BeginCount is the sum of sample begins at A, which is 300 and no
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samples ends at A, so EndCount is 0.
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Then boundary points A, B, and C with begin/end counts are:
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A: (300, 0)
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B: (0, 100)
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C: (0, 200)
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*/
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struct BoundaryPoint {
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// Sum of sample counts beginning at this point
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uint64_t BeginCount;
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// Sum of sample counts ending at this point
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uint64_t EndCount;
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BoundaryPoint() : BeginCount(0), EndCount(0){};
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void addBeginCount(uint64_t Count) { BeginCount += Count; }
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void addEndCount(uint64_t Count) { EndCount += Count; }
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};
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/*
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For the above example. With boundary points, follwing logic finds two
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disjoint region of
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[A,B]: 300
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[B+1,C]: 200
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If there is a boundary point that both begin and end, the point itself
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becomes a separate disjoint region. For example, if we have original
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ranges of
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|<--- 100 --->|
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|<--- 200 --->|
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A B C
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there are three boundary points with their begin/end counts of
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A: (100, 0)
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B: (200, 100)
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C: (0, 200)
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the disjoint ranges would be
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[A, B-1]: 100
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[B, B]: 300
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[B+1, C]: 200.
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*/
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std::map<uint64_t, BoundaryPoint> Boundaries;
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for (auto Item : Ranges) {
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uint64_t Begin = Item.first.first;
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uint64_t End = Item.first.second;
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uint64_t Count = Item.second;
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if (Boundaries.find(Begin) == Boundaries.end())
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Boundaries[Begin] = BoundaryPoint();
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Boundaries[Begin].addBeginCount(Count);
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if (Boundaries.find(End) == Boundaries.end())
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Boundaries[End] = BoundaryPoint();
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Boundaries[End].addEndCount(Count);
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}
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uint64_t BeginAddress = 0;
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int Count = 0;
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for (auto Item : Boundaries) {
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uint64_t Address = Item.first;
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BoundaryPoint &Point = Item.second;
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if (Point.BeginCount) {
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if (BeginAddress)
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DisjointRanges[{BeginAddress, Address - 1}] = Count;
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Count += Point.BeginCount;
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BeginAddress = Address;
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}
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if (Point.EndCount) {
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assert(BeginAddress && "First boundary point cannot be 'end' point");
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DisjointRanges[{BeginAddress, Address}] = Count;
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Count -= Point.EndCount;
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BeginAddress = Address + 1;
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}
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}
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}
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FunctionSamples &
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CSProfileGenerator::getFunctionProfileForContext(StringRef ContextStr,
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bool WasLeafInlined) {
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auto Ret = ProfileMap.try_emplace(ContextStr, FunctionSamples());
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if (Ret.second) {
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// Make a copy of the underlying context string in string table
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// before StringRef wrapper is used for context.
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auto It = ContextStrings.insert(ContextStr.str());
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SampleContext FContext(*It.first, RawContext);
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if (WasLeafInlined)
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FContext.setAttribute(ContextWasInlined);
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FunctionSamples &FProfile = Ret.first->second;
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FProfile.setContext(FContext);
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FProfile.setName(FContext.getNameWithoutContext());
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}
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return Ret.first->second;
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}
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void CSProfileGenerator::generateProfile() {
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FunctionSamples::ProfileIsCS = true;
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for (const auto &BI : BinarySampleCounters) {
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ProfiledBinary *Binary = BI.first;
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for (const auto &CI : BI.second) {
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const StringBasedCtxKey *CtxKey =
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dyn_cast<StringBasedCtxKey>(CI.first.getPtr());
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StringRef ContextId(CtxKey->Context);
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// Get or create function profile for the range
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FunctionSamples &FunctionProfile =
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getFunctionProfileForContext(ContextId, CtxKey->WasLeafInlined);
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// Fill in function body samples
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populateFunctionBodySamples(FunctionProfile, CI.second.RangeCounter,
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Binary);
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// Fill in boundary sample counts as well as call site samples for calls
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populateFunctionBoundarySamples(ContextId, FunctionProfile,
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CI.second.BranchCounter, Binary);
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}
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}
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// Fill in call site value sample for inlined calls and also use context to
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// infer missing samples. Since we don't have call count for inlined
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// functions, we estimate it from inlinee's profile using the entry of the
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// body sample.
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populateInferredFunctionSamples();
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postProcessProfiles();
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}
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void CSProfileGenerator::updateBodySamplesforFunctionProfile(
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FunctionSamples &FunctionProfile, const FrameLocation &LeafLoc,
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uint64_t Count) {
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// Filter out invalid negative(int type) lineOffset
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if (LeafLoc.second.LineOffset & 0x80000000)
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return;
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// Use the maximum count of samples with same line location
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ErrorOr<uint64_t> R = FunctionProfile.findSamplesAt(
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LeafLoc.second.LineOffset, LeafLoc.second.Discriminator);
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uint64_t PreviousCount = R ? R.get() : 0;
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if (PreviousCount < Count) {
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FunctionProfile.addBodySamples(LeafLoc.second.LineOffset,
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LeafLoc.second.Discriminator,
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Count - PreviousCount);
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}
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}
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void CSProfileGenerator::populateFunctionBodySamples(
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FunctionSamples &FunctionProfile, const RangeSample &RangeCounter,
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ProfiledBinary *Binary) {
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// Compute disjoint ranges first, so we can use MAX
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// for calculating count for each location.
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RangeSample Ranges;
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findDisjointRanges(Ranges, RangeCounter);
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for (auto Range : Ranges) {
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uint64_t RangeBegin = Binary->offsetToVirtualAddr(Range.first.first);
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uint64_t RangeEnd = Binary->offsetToVirtualAddr(Range.first.second);
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uint64_t Count = Range.second;
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// Disjoint ranges have introduce zero-filled gap that
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// doesn't belong to current context, filter them out.
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if (Count == 0)
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continue;
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InstructionPointer IP(Binary, RangeBegin, true);
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// Disjoint ranges may have range in the middle of two instr,
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// e.g. If Instr1 at Addr1, and Instr2 at Addr2, disjoint range
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// can be Addr1+1 to Addr2-1. We should ignore such range.
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if (IP.Address > RangeEnd)
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continue;
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while (IP.Address <= RangeEnd) {
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uint64_t Offset = Binary->virtualAddrToOffset(IP.Address);
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auto LeafLoc = Binary->getInlineLeafFrameLoc(Offset);
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if (LeafLoc.hasValue()) {
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// Recording body sample for this specific context
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updateBodySamplesforFunctionProfile(FunctionProfile, *LeafLoc, Count);
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}
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// Accumulate total sample count even it's a line with invalid debug info
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FunctionProfile.addTotalSamples(Count);
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// Move to next IP within the range
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IP.advance();
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}
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}
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}
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void CSProfileGenerator::populateFunctionBoundarySamples(
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StringRef ContextId, FunctionSamples &FunctionProfile,
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const BranchSample &BranchCounters, ProfiledBinary *Binary) {
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for (auto Entry : BranchCounters) {
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uint64_t SourceOffset = Entry.first.first;
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uint64_t TargetOffset = Entry.first.second;
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uint64_t Count = Entry.second;
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// Get the callee name by branch target if it's a call branch
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StringRef CalleeName = FunctionSamples::getCanonicalFnName(
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Binary->getFuncFromStartOffset(TargetOffset));
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if (CalleeName.size() == 0)
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continue;
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// Record called target sample and its count
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auto LeafLoc = Binary->getInlineLeafFrameLoc(SourceOffset);
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if (!LeafLoc.hasValue())
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continue;
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FunctionProfile.addCalledTargetSamples(LeafLoc->second.LineOffset,
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LeafLoc->second.Discriminator,
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CalleeName, Count);
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// Record head sample for called target(callee)
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std::ostringstream OCalleeCtxStr;
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if (ContextId.find(" @ ") != StringRef::npos) {
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OCalleeCtxStr << ContextId.rsplit(" @ ").first.str();
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OCalleeCtxStr << " @ ";
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}
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OCalleeCtxStr << getCallSite(*LeafLoc) << " @ " << CalleeName.str();
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FunctionSamples &CalleeProfile =
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getFunctionProfileForContext(OCalleeCtxStr.str());
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assert(Count != 0 && "Unexpected zero weight branch");
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CalleeProfile.addHeadSamples(Count);
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}
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}
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static FrameLocation getCallerContext(StringRef CalleeContext,
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StringRef &CallerNameWithContext) {
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StringRef CallerContext = CalleeContext.rsplit(" @ ").first;
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CallerNameWithContext = CallerContext.rsplit(':').first;
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auto ContextSplit = CallerContext.rsplit(" @ ");
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StringRef CallerFrameStr = ContextSplit.second.size() == 0
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? ContextSplit.first
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: ContextSplit.second;
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FrameLocation LeafFrameLoc = {"", {0, 0}};
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StringRef Funcname;
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SampleContext::decodeContextString(CallerFrameStr, Funcname,
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LeafFrameLoc.second);
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LeafFrameLoc.first = Funcname.str();
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return LeafFrameLoc;
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}
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void CSProfileGenerator::populateInferredFunctionSamples() {
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for (const auto &Item : ProfileMap) {
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const StringRef CalleeContext = Item.first();
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const FunctionSamples &CalleeProfile = Item.second;
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// If we already have head sample counts, we must have value profile
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// for call sites added already. Skip to avoid double counting.
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if (CalleeProfile.getHeadSamples())
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continue;
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// If we don't have context, nothing to do for caller's call site.
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// This could happen for entry point function.
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if (CalleeContext.find(" @ ") == StringRef::npos)
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continue;
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// Infer Caller's frame loc and context ID through string splitting
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StringRef CallerContextId;
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FrameLocation &&CallerLeafFrameLoc =
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getCallerContext(CalleeContext, CallerContextId);
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// It's possible that we haven't seen any sample directly in the caller,
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// in which case CallerProfile will not exist. But we can't modify
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// ProfileMap while iterating it.
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// TODO: created function profile for those callers too
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if (ProfileMap.find(CallerContextId) == ProfileMap.end())
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continue;
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FunctionSamples &CallerProfile = ProfileMap[CallerContextId];
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// Since we don't have call count for inlined functions, we
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// estimate it from inlinee's profile using entry body sample.
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uint64_t EstimatedCallCount = CalleeProfile.getEntrySamples();
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// If we don't have samples with location, use 1 to indicate live.
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if (!EstimatedCallCount && !CalleeProfile.getBodySamples().size())
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EstimatedCallCount = 1;
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CallerProfile.addCalledTargetSamples(
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CallerLeafFrameLoc.second.LineOffset,
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CallerLeafFrameLoc.second.Discriminator,
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CalleeProfile.getContext().getNameWithoutContext(), EstimatedCallCount);
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CallerProfile.addBodySamples(CallerLeafFrameLoc.second.LineOffset,
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CallerLeafFrameLoc.second.Discriminator,
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EstimatedCallCount);
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CallerProfile.addTotalSamples(EstimatedCallCount);
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}
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}
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void CSProfileGenerator::postProcessProfiles() {
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// Compute hot/cold threshold based on profile. This will be used for cold
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// context profile merging/trimming.
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computeSummaryAndThreshold();
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// Run global pre-inliner to adjust/merge context profile based on estimated
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// inline decisions.
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CSPreInliner(ProfileMap, HotCountThreshold, ColdCountThreshold).run();
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// Trim and merge cold context profile using cold threshold above;
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SampleContextTrimmer(ProfileMap)
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.trimAndMergeColdContextProfiles(
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ColdCountThreshold, CSProfTrimColdContext, CSProfMergeColdContext);
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}
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void CSProfileGenerator::computeSummaryAndThreshold() {
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SampleProfileSummaryBuilder Builder(ProfileSummaryBuilder::DefaultCutoffs);
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auto Summary = Builder.computeSummaryForProfiles(ProfileMap);
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HotCountThreshold = ProfileSummaryBuilder::getHotCountThreshold(
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(Summary->getDetailedSummary()));
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ColdCountThreshold = ProfileSummaryBuilder::getColdCountThreshold(
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(Summary->getDetailedSummary()));
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// Use threshold calculated from profile summary unless specified.
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if (CSProfColdThreshold.getNumOccurrences()) {
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ColdCountThreshold = CSProfColdThreshold;
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}
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}
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void CSProfileGenerator::write(std::unique_ptr<SampleProfileWriter> Writer,
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StringMap<FunctionSamples> &ProfileMap) {
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if (std::error_code EC = Writer->write(ProfileMap))
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exitWithError(std::move(EC));
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}
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// Helper function to extract context prefix string stack
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// Extract context stack for reusing, leaf context stack will
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// be added compressed while looking up function profile
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static void
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extractPrefixContextStack(SmallVectorImpl<std::string> &ContextStrStack,
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const SmallVectorImpl<const PseudoProbe *> &Probes,
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ProfiledBinary *Binary) {
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for (const auto *P : Probes) {
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Binary->getInlineContextForProbe(P, ContextStrStack, true);
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}
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}
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void PseudoProbeCSProfileGenerator::generateProfile() {
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// Enable pseudo probe functionalities in SampleProf
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FunctionSamples::ProfileIsProbeBased = true;
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FunctionSamples::ProfileIsCS = true;
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for (const auto &BI : BinarySampleCounters) {
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ProfiledBinary *Binary = BI.first;
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for (const auto &CI : BI.second) {
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const ProbeBasedCtxKey *CtxKey =
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dyn_cast<ProbeBasedCtxKey>(CI.first.getPtr());
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SmallVector<std::string, 16> ContextStrStack;
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extractPrefixContextStack(ContextStrStack, CtxKey->Probes, Binary);
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// Fill in function body samples from probes, also infer caller's samples
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// from callee's probe
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populateBodySamplesWithProbes(CI.second.RangeCounter, ContextStrStack,
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Binary);
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// Fill in boundary samples for a call probe
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populateBoundarySamplesWithProbes(CI.second.BranchCounter,
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ContextStrStack, Binary);
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}
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}
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postProcessProfiles();
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}
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void PseudoProbeCSProfileGenerator::extractProbesFromRange(
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const RangeSample &RangeCounter, ProbeCounterMap &ProbeCounter,
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ProfiledBinary *Binary) {
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RangeSample Ranges;
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findDisjointRanges(Ranges, RangeCounter);
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for (const auto &Range : Ranges) {
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uint64_t RangeBegin = Binary->offsetToVirtualAddr(Range.first.first);
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uint64_t RangeEnd = Binary->offsetToVirtualAddr(Range.first.second);
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uint64_t Count = Range.second;
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// Disjoint ranges have introduce zero-filled gap that
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// doesn't belong to current context, filter them out.
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if (Count == 0)
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continue;
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|
|
|
InstructionPointer IP(Binary, RangeBegin, true);
|
|
|
|
// Disjoint ranges may have range in the middle of two instr,
|
|
// e.g. If Instr1 at Addr1, and Instr2 at Addr2, disjoint range
|
|
// can be Addr1+1 to Addr2-1. We should ignore such range.
|
|
if (IP.Address > RangeEnd)
|
|
continue;
|
|
|
|
while (IP.Address <= RangeEnd) {
|
|
const AddressProbesMap &Address2ProbesMap =
|
|
Binary->getAddress2ProbesMap();
|
|
auto It = Address2ProbesMap.find(IP.Address);
|
|
if (It != Address2ProbesMap.end()) {
|
|
for (const auto &Probe : It->second) {
|
|
if (!Probe.isBlock())
|
|
continue;
|
|
ProbeCounter[&Probe] += Count;
|
|
}
|
|
}
|
|
|
|
IP.advance();
|
|
}
|
|
}
|
|
}
|
|
|
|
void PseudoProbeCSProfileGenerator::populateBodySamplesWithProbes(
|
|
const RangeSample &RangeCounter,
|
|
SmallVectorImpl<std::string> &ContextStrStack, ProfiledBinary *Binary) {
|
|
ProbeCounterMap ProbeCounter;
|
|
// Extract the top frame probes by looking up each address among the range in
|
|
// the Address2ProbeMap
|
|
extractProbesFromRange(RangeCounter, ProbeCounter, Binary);
|
|
std::unordered_map<PseudoProbeInlineTree *, FunctionSamples *> FrameSamples;
|
|
for (auto PI : ProbeCounter) {
|
|
const PseudoProbe *Probe = PI.first;
|
|
uint64_t Count = PI.second;
|
|
// Ignore dangling probes since they will be reported later if needed.
|
|
if (Probe->isDangling())
|
|
continue;
|
|
FunctionSamples &FunctionProfile =
|
|
getFunctionProfileForLeafProbe(ContextStrStack, Probe, Binary);
|
|
// Record the current frame and FunctionProfile whenever samples are
|
|
// collected for non-danglie probes. This is for reporting all of the
|
|
// dangling probes of the frame later.
|
|
FrameSamples[Probe->getInlineTreeNode()] = &FunctionProfile;
|
|
FunctionProfile.addBodySamplesForProbe(Probe->Index, Count);
|
|
FunctionProfile.addTotalSamples(Count);
|
|
if (Probe->isEntry()) {
|
|
FunctionProfile.addHeadSamples(Count);
|
|
// Look up for the caller's function profile
|
|
const auto *InlinerDesc = Binary->getInlinerDescForProbe(Probe);
|
|
if (InlinerDesc != nullptr) {
|
|
// Since the context id will be compressed, we have to use callee's
|
|
// context id to infer caller's context id to ensure they share the
|
|
// same context prefix.
|
|
StringRef CalleeContextId =
|
|
FunctionProfile.getContext().getNameWithContext();
|
|
StringRef CallerContextId;
|
|
FrameLocation &&CallerLeafFrameLoc =
|
|
getCallerContext(CalleeContextId, CallerContextId);
|
|
uint64_t CallerIndex = CallerLeafFrameLoc.second.LineOffset;
|
|
assert(CallerIndex &&
|
|
"Inferred caller's location index shouldn't be zero!");
|
|
FunctionSamples &CallerProfile =
|
|
getFunctionProfileForContext(CallerContextId);
|
|
CallerProfile.setFunctionHash(InlinerDesc->FuncHash);
|
|
CallerProfile.addBodySamples(CallerIndex, 0, Count);
|
|
CallerProfile.addTotalSamples(Count);
|
|
CallerProfile.addCalledTargetSamples(
|
|
CallerIndex, 0,
|
|
FunctionProfile.getContext().getNameWithoutContext(), Count);
|
|
}
|
|
}
|
|
|
|
// Report dangling probes for frames that have real samples collected.
|
|
// Dangling probes are the probes associated to an empty block. With this
|
|
// place holder, sample count on a dangling probe will not be trusted by the
|
|
// compiler and we will rely on the counts inference algorithm to get the
|
|
// probe a reasonable count. Use InvalidProbeCount to mark sample count for
|
|
// a dangling probe.
|
|
for (auto &I : FrameSamples) {
|
|
auto *FunctionProfile = I.second;
|
|
for (auto *Probe : I.first->getProbes()) {
|
|
if (Probe->isDangling()) {
|
|
FunctionProfile->addBodySamplesForProbe(
|
|
Probe->Index, FunctionSamples::InvalidProbeCount);
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
void PseudoProbeCSProfileGenerator::populateBoundarySamplesWithProbes(
|
|
const BranchSample &BranchCounter,
|
|
SmallVectorImpl<std::string> &ContextStrStack, ProfiledBinary *Binary) {
|
|
for (auto BI : BranchCounter) {
|
|
uint64_t SourceOffset = BI.first.first;
|
|
uint64_t TargetOffset = BI.first.second;
|
|
uint64_t Count = BI.second;
|
|
uint64_t SourceAddress = Binary->offsetToVirtualAddr(SourceOffset);
|
|
const PseudoProbe *CallProbe = Binary->getCallProbeForAddr(SourceAddress);
|
|
if (CallProbe == nullptr)
|
|
continue;
|
|
FunctionSamples &FunctionProfile =
|
|
getFunctionProfileForLeafProbe(ContextStrStack, CallProbe, Binary);
|
|
FunctionProfile.addBodySamples(CallProbe->Index, 0, Count);
|
|
FunctionProfile.addTotalSamples(Count);
|
|
StringRef CalleeName = FunctionSamples::getCanonicalFnName(
|
|
Binary->getFuncFromStartOffset(TargetOffset));
|
|
if (CalleeName.size() == 0)
|
|
continue;
|
|
FunctionProfile.addCalledTargetSamples(CallProbe->Index, 0, CalleeName,
|
|
Count);
|
|
}
|
|
}
|
|
|
|
FunctionSamples &PseudoProbeCSProfileGenerator::getFunctionProfileForLeafProbe(
|
|
SmallVectorImpl<std::string> &ContextStrStack,
|
|
const PseudoProbeFuncDesc *LeafFuncDesc, bool WasLeafInlined) {
|
|
assert(ContextStrStack.size() && "Profile context must have the leaf frame");
|
|
// Compress the context string except for the leaf frame
|
|
std::string LeafFrame = ContextStrStack.back();
|
|
ContextStrStack.pop_back();
|
|
CSProfileGenerator::compressRecursionContext(ContextStrStack);
|
|
|
|
std::ostringstream OContextStr;
|
|
for (uint32_t I = 0; I < ContextStrStack.size(); I++) {
|
|
if (OContextStr.str().size())
|
|
OContextStr << " @ ";
|
|
OContextStr << ContextStrStack[I];
|
|
}
|
|
// For leaf inlined context with the top frame, we should strip off the top
|
|
// frame's probe id, like:
|
|
// Inlined stack: [foo:1, bar:2], the ContextId will be "foo:1 @ bar"
|
|
if (OContextStr.str().size())
|
|
OContextStr << " @ ";
|
|
OContextStr << StringRef(LeafFrame).split(":").first.str();
|
|
|
|
FunctionSamples &FunctionProile =
|
|
getFunctionProfileForContext(OContextStr.str(), WasLeafInlined);
|
|
FunctionProile.setFunctionHash(LeafFuncDesc->FuncHash);
|
|
return FunctionProile;
|
|
}
|
|
|
|
FunctionSamples &PseudoProbeCSProfileGenerator::getFunctionProfileForLeafProbe(
|
|
SmallVectorImpl<std::string> &ContextStrStack, const PseudoProbe *LeafProbe,
|
|
ProfiledBinary *Binary) {
|
|
// Explicitly copy the context for appending the leaf context
|
|
SmallVector<std::string, 16> ContextStrStackCopy(ContextStrStack.begin(),
|
|
ContextStrStack.end());
|
|
Binary->getInlineContextForProbe(LeafProbe, ContextStrStackCopy, true);
|
|
const auto *FuncDesc = Binary->getFuncDescForGUID(LeafProbe->GUID);
|
|
bool WasLeafInlined = LeafProbe->InlineTree->hasInlineSite();
|
|
return getFunctionProfileForLeafProbe(ContextStrStackCopy, FuncDesc,
|
|
WasLeafInlined);
|
|
}
|
|
|
|
} // end namespace sampleprof
|
|
} // end namespace llvm
|