| //===-- PerfReader.h - perfscript reader -----------------------*- C++ -*-===// |
| // |
| // 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 |
| // |
| //===----------------------------------------------------------------------===// |
| |
| #ifndef LLVM_TOOLS_LLVM_PROFGEN_PERFREADER_H |
| #define LLVM_TOOLS_LLVM_PROFGEN_PERFREADER_H |
| #include "ErrorHandling.h" |
| #include "ProfiledBinary.h" |
| #include "llvm/Support/Casting.h" |
| #include "llvm/Support/CommandLine.h" |
| #include "llvm/Support/Regex.h" |
| #include <cstdint> |
| #include <fstream> |
| #include <list> |
| #include <map> |
| #include <vector> |
| |
| using namespace llvm; |
| using namespace sampleprof; |
| |
| namespace llvm { |
| namespace sampleprof { |
| |
| // Stream based trace line iterator |
| class TraceStream { |
| std::string CurrentLine; |
| std::ifstream Fin; |
| bool IsAtEoF = false; |
| uint64_t LineNumber = 0; |
| |
| public: |
| TraceStream(StringRef Filename) : Fin(Filename.str()) { |
| if (!Fin.good()) |
| exitWithError("Error read input perf script file", Filename); |
| advance(); |
| } |
| |
| StringRef getCurrentLine() { |
| assert(!IsAtEoF && "Line iterator reaches the End-of-File!"); |
| return CurrentLine; |
| } |
| |
| uint64_t getLineNumber() { return LineNumber; } |
| |
| bool isAtEoF() { return IsAtEoF; } |
| |
| // Read the next line |
| void advance() { |
| if (!std::getline(Fin, CurrentLine)) { |
| IsAtEoF = true; |
| return; |
| } |
| LineNumber++; |
| } |
| }; |
| |
| // The type of input format. |
| enum PerfFormat { |
| UnknownFormat = 0, |
| PerfData = 1, // Raw linux perf.data. |
| PerfScript = 2, // Perf script create by `perf script` command. |
| UnsymbolizedProfile = 3, // Unsymbolized profile generated by llvm-profgen. |
| |
| }; |
| |
| // The type of perfscript content. |
| enum PerfContent { |
| UnknownContent = 0, |
| LBR = 1, // Only LBR sample. |
| LBRStack = 2, // Hybrid sample including call stack and LBR stack. |
| }; |
| |
| struct PerfInputFile { |
| std::string InputFile; |
| PerfFormat Format = PerfFormat::UnknownFormat; |
| PerfContent Content = PerfContent::UnknownContent; |
| }; |
| |
| // The parsed LBR sample entry. |
| struct LBREntry { |
| uint64_t Source = 0; |
| uint64_t Target = 0; |
| // An artificial branch stands for a series of consecutive branches starting |
| // from the current binary with a transition through external code and |
| // eventually landing back in the current binary. |
| bool IsArtificial = false; |
| LBREntry(uint64_t S, uint64_t T, bool I) |
| : Source(S), Target(T), IsArtificial(I) {} |
| |
| #ifndef NDEBUG |
| void print() const { |
| dbgs() << "from " << format("%#010x", Source) << " to " |
| << format("%#010x", Target); |
| if (IsArtificial) |
| dbgs() << " Artificial"; |
| } |
| #endif |
| }; |
| |
| #ifndef NDEBUG |
| static inline void printLBRStack(const SmallVectorImpl<LBREntry> &LBRStack) { |
| for (size_t I = 0; I < LBRStack.size(); I++) { |
| dbgs() << "[" << I << "] "; |
| LBRStack[I].print(); |
| dbgs() << "\n"; |
| } |
| } |
| |
| static inline void printCallStack(const SmallVectorImpl<uint64_t> &CallStack) { |
| for (size_t I = 0; I < CallStack.size(); I++) { |
| dbgs() << "[" << I << "] " << format("%#010x", CallStack[I]) << "\n"; |
| } |
| } |
| #endif |
| |
| // Hash interface for generic data of type T |
| // Data should implement a \fn getHashCode and a \fn isEqual |
| // Currently getHashCode is non-virtual to avoid the overhead of calling vtable, |
| // i.e we explicitly calculate hash of derived class, assign to base class's |
| // HashCode. This also provides the flexibility for calculating the hash code |
| // incrementally(like rolling hash) during frame stack unwinding since unwinding |
| // only changes the leaf of frame stack. \fn isEqual is a virtual function, |
| // which will have perf overhead. In the future, if we redesign a better hash |
| // function, then we can just skip this or switch to non-virtual function(like |
| // just ignore comparision if hash conflicts probabilities is low) |
| template <class T> class Hashable { |
| public: |
| std::shared_ptr<T> Data; |
| Hashable(const std::shared_ptr<T> &D) : Data(D) {} |
| |
| // Hash code generation |
| struct Hash { |
| uint64_t operator()(const Hashable<T> &Key) const { |
| // Don't make it virtual for getHashCode |
| uint64_t Hash = Key.Data->getHashCode(); |
| assert(Hash && "Should generate HashCode for it!"); |
| return Hash; |
| } |
| }; |
| |
| // Hash equal |
| struct Equal { |
| bool operator()(const Hashable<T> &LHS, const Hashable<T> &RHS) const { |
| // Precisely compare the data, vtable will have overhead. |
| return LHS.Data->isEqual(RHS.Data.get()); |
| } |
| }; |
| |
| T *getPtr() const { return Data.get(); } |
| }; |
| |
| struct PerfSample { |
| // LBR stack recorded in FIFO order. |
| SmallVector<LBREntry, 16> LBRStack; |
| // Call stack recorded in FILO(leaf to root) order, it's used for CS-profile |
| // generation |
| SmallVector<uint64_t, 16> CallStack; |
| |
| virtual ~PerfSample() = default; |
| uint64_t getHashCode() const { |
| // Use simple DJB2 hash |
| auto HashCombine = [](uint64_t H, uint64_t V) { |
| return ((H << 5) + H) + V; |
| }; |
| uint64_t Hash = 5381; |
| for (const auto &Value : CallStack) { |
| Hash = HashCombine(Hash, Value); |
| } |
| for (const auto &Entry : LBRStack) { |
| Hash = HashCombine(Hash, Entry.Source); |
| Hash = HashCombine(Hash, Entry.Target); |
| } |
| return Hash; |
| } |
| |
| bool isEqual(const PerfSample *Other) const { |
| const SmallVector<uint64_t, 16> &OtherCallStack = Other->CallStack; |
| const SmallVector<LBREntry, 16> &OtherLBRStack = Other->LBRStack; |
| |
| if (CallStack.size() != OtherCallStack.size() || |
| LBRStack.size() != OtherLBRStack.size()) |
| return false; |
| |
| if (!std::equal(CallStack.begin(), CallStack.end(), OtherCallStack.begin())) |
| return false; |
| |
| for (size_t I = 0; I < OtherLBRStack.size(); I++) { |
| if (LBRStack[I].Source != OtherLBRStack[I].Source || |
| LBRStack[I].Target != OtherLBRStack[I].Target) |
| return false; |
| } |
| return true; |
| } |
| |
| #ifndef NDEBUG |
| void print() const { |
| dbgs() << "LBR stack\n"; |
| printLBRStack(LBRStack); |
| dbgs() << "Call stack\n"; |
| printCallStack(CallStack); |
| } |
| #endif |
| }; |
| // After parsing the sample, we record the samples by aggregating them |
| // into this counter. The key stores the sample data and the value is |
| // the sample repeat times. |
| using AggregatedCounter = |
| std::unordered_map<Hashable<PerfSample>, uint64_t, |
| Hashable<PerfSample>::Hash, Hashable<PerfSample>::Equal>; |
| |
| using SampleVector = SmallVector<std::tuple<uint64_t, uint64_t, uint64_t>, 16>; |
| // The state for the unwinder, it doesn't hold the data but only keep the |
| // pointer/index of the data, While unwinding, the CallStack is changed |
| // dynamicially and will be recorded as the context of the sample |
| struct UnwindState { |
| // Profiled binary that current frame address belongs to |
| const ProfiledBinary *Binary; |
| // Call stack trie node |
| struct ProfiledFrame { |
| const uint64_t Address = 0; |
| ProfiledFrame *Parent; |
| SampleVector RangeSamples; |
| SampleVector BranchSamples; |
| std::unordered_map<uint64_t, std::unique_ptr<ProfiledFrame>> Children; |
| |
| ProfiledFrame(uint64_t Addr = 0, ProfiledFrame *P = nullptr) |
| : Address(Addr), Parent(P) {} |
| ProfiledFrame *getOrCreateChildFrame(uint64_t Address) { |
| assert(Address && "Address can't be zero!"); |
| auto Ret = Children.emplace( |
| Address, std::make_unique<ProfiledFrame>(Address, this)); |
| return Ret.first->second.get(); |
| } |
| void recordRangeCount(uint64_t Start, uint64_t End, uint64_t Count) { |
| RangeSamples.emplace_back(std::make_tuple(Start, End, Count)); |
| } |
| void recordBranchCount(uint64_t Source, uint64_t Target, uint64_t Count) { |
| BranchSamples.emplace_back(std::make_tuple(Source, Target, Count)); |
| } |
| bool isDummyRoot() { return Address == 0; } |
| bool isLeafFrame() { return Children.empty(); } |
| }; |
| |
| ProfiledFrame DummyTrieRoot; |
| ProfiledFrame *CurrentLeafFrame; |
| // Used to fall through the LBR stack |
| uint32_t LBRIndex = 0; |
| // Reference to PerfSample.LBRStack |
| const SmallVector<LBREntry, 16> &LBRStack; |
| // Used to iterate the address range |
| InstructionPointer InstPtr; |
| UnwindState(const PerfSample *Sample, const ProfiledBinary *Binary) |
| : Binary(Binary), LBRStack(Sample->LBRStack), |
| InstPtr(Binary, Sample->CallStack.front()) { |
| initFrameTrie(Sample->CallStack); |
| } |
| |
| bool validateInitialState() { |
| uint64_t LBRLeaf = LBRStack[LBRIndex].Target; |
| uint64_t LeafAddr = CurrentLeafFrame->Address; |
| // When we take a stack sample, ideally the sampling distance between the |
| // leaf IP of stack and the last LBR target shouldn't be very large. |
| // Use a heuristic size (0x100) to filter out broken records. |
| if (LeafAddr < LBRLeaf || LeafAddr >= LBRLeaf + 0x100) { |
| WithColor::warning() << "Bogus trace: stack tip = " |
| << format("%#010x", LeafAddr) |
| << ", LBR tip = " << format("%#010x\n", LBRLeaf); |
| return false; |
| } |
| return true; |
| } |
| |
| void checkStateConsistency() { |
| assert(InstPtr.Address == CurrentLeafFrame->Address && |
| "IP should align with context leaf"); |
| } |
| |
| bool hasNextLBR() const { return LBRIndex < LBRStack.size(); } |
| uint64_t getCurrentLBRSource() const { return LBRStack[LBRIndex].Source; } |
| uint64_t getCurrentLBRTarget() const { return LBRStack[LBRIndex].Target; } |
| const LBREntry &getCurrentLBR() const { return LBRStack[LBRIndex]; } |
| void advanceLBR() { LBRIndex++; } |
| |
| ProfiledFrame *getParentFrame() { return CurrentLeafFrame->Parent; } |
| |
| void pushFrame(uint64_t Address) { |
| CurrentLeafFrame = CurrentLeafFrame->getOrCreateChildFrame(Address); |
| } |
| |
| void switchToFrame(uint64_t Address) { |
| if (CurrentLeafFrame->Address == Address) |
| return; |
| CurrentLeafFrame = CurrentLeafFrame->Parent->getOrCreateChildFrame(Address); |
| } |
| |
| void popFrame() { CurrentLeafFrame = CurrentLeafFrame->Parent; } |
| |
| void initFrameTrie(const SmallVectorImpl<uint64_t> &CallStack) { |
| ProfiledFrame *Cur = &DummyTrieRoot; |
| for (auto Address : reverse(CallStack)) { |
| Cur = Cur->getOrCreateChildFrame(Address); |
| } |
| CurrentLeafFrame = Cur; |
| } |
| |
| ProfiledFrame *getDummyRootPtr() { return &DummyTrieRoot; } |
| }; |
| |
| // Base class for sample counter key with context |
| struct ContextKey { |
| uint64_t HashCode = 0; |
| virtual ~ContextKey() = default; |
| uint64_t getHashCode() { |
| if (HashCode == 0) |
| genHashCode(); |
| return HashCode; |
| } |
| virtual void genHashCode() = 0; |
| virtual bool isEqual(const ContextKey *K) const { |
| return HashCode == K->HashCode; |
| }; |
| |
| // Utilities for LLVM-style RTTI |
| enum ContextKind { CK_StringBased, CK_ProbeBased }; |
| const ContextKind Kind; |
| ContextKind getKind() const { return Kind; } |
| ContextKey(ContextKind K) : Kind(K){}; |
| }; |
| |
| // String based context id |
| struct StringBasedCtxKey : public ContextKey { |
| SampleContextFrameVector Context; |
| |
| bool WasLeafInlined; |
| StringBasedCtxKey() : ContextKey(CK_StringBased), WasLeafInlined(false){}; |
| static bool classof(const ContextKey *K) { |
| return K->getKind() == CK_StringBased; |
| } |
| |
| bool isEqual(const ContextKey *K) const override { |
| const StringBasedCtxKey *Other = dyn_cast<StringBasedCtxKey>(K); |
| return Context == Other->Context; |
| } |
| |
| void genHashCode() override { |
| HashCode = hash_value(SampleContextFrames(Context)); |
| } |
| }; |
| |
| // Probe based context key as the intermediate key of context |
| // String based context key will introduce redundant string handling |
| // since the callee context is inferred from the context string which |
| // need to be splitted by '@' to get the last location frame, so we |
| // can just use probe instead and generate the string in the end. |
| struct ProbeBasedCtxKey : public ContextKey { |
| SmallVector<const MCDecodedPseudoProbe *, 16> Probes; |
| |
| ProbeBasedCtxKey() : ContextKey(CK_ProbeBased) {} |
| static bool classof(const ContextKey *K) { |
| return K->getKind() == CK_ProbeBased; |
| } |
| |
| bool isEqual(const ContextKey *K) const override { |
| const ProbeBasedCtxKey *O = dyn_cast<ProbeBasedCtxKey>(K); |
| assert(O != nullptr && "Probe based key shouldn't be null in isEqual"); |
| return std::equal(Probes.begin(), Probes.end(), O->Probes.begin(), |
| O->Probes.end()); |
| } |
| |
| void genHashCode() override { |
| for (const auto *P : Probes) { |
| HashCode = hash_combine(HashCode, P); |
| } |
| if (HashCode == 0) { |
| // Avoid zero value of HashCode when it's an empty list |
| HashCode = 1; |
| } |
| } |
| }; |
| |
| // The counter of branch samples for one function indexed by the branch, |
| // which is represented as the source and target offset pair. |
| using BranchSample = std::map<std::pair<uint64_t, uint64_t>, uint64_t>; |
| // The counter of range samples for one function indexed by the range, |
| // which is represented as the start and end offset pair. |
| using RangeSample = std::map<std::pair<uint64_t, uint64_t>, uint64_t>; |
| // Wrapper for sample counters including range counter and branch counter |
| struct SampleCounter { |
| RangeSample RangeCounter; |
| BranchSample BranchCounter; |
| |
| void recordRangeCount(uint64_t Start, uint64_t End, uint64_t Repeat) { |
| assert(Start <= End && "Invalid instruction range"); |
| RangeCounter[{Start, End}] += Repeat; |
| } |
| void recordBranchCount(uint64_t Source, uint64_t Target, uint64_t Repeat) { |
| BranchCounter[{Source, Target}] += Repeat; |
| } |
| }; |
| |
| // Sample counter with context to support context-sensitive profile |
| using ContextSampleCounterMap = |
| std::unordered_map<Hashable<ContextKey>, SampleCounter, |
| Hashable<ContextKey>::Hash, Hashable<ContextKey>::Equal>; |
| |
| struct FrameStack { |
| SmallVector<uint64_t, 16> Stack; |
| ProfiledBinary *Binary; |
| FrameStack(ProfiledBinary *B) : Binary(B) {} |
| bool pushFrame(UnwindState::ProfiledFrame *Cur) { |
| Stack.push_back(Cur->Address); |
| return true; |
| } |
| |
| void popFrame() { |
| if (!Stack.empty()) |
| Stack.pop_back(); |
| } |
| std::shared_ptr<StringBasedCtxKey> getContextKey(); |
| }; |
| |
| struct ProbeStack { |
| SmallVector<const MCDecodedPseudoProbe *, 16> Stack; |
| ProfiledBinary *Binary; |
| ProbeStack(ProfiledBinary *B) : Binary(B) {} |
| bool pushFrame(UnwindState::ProfiledFrame *Cur) { |
| const MCDecodedPseudoProbe *CallProbe = |
| Binary->getCallProbeForAddr(Cur->Address); |
| // We may not find a probe for a merged or external callsite. |
| // Callsite merging may cause the loss of original probe IDs. |
| // Cutting off the context from here since the inliner will |
| // not know how to consume a context with unknown callsites. |
| if (!CallProbe) |
| return false; |
| Stack.push_back(CallProbe); |
| return true; |
| } |
| |
| void popFrame() { |
| if (!Stack.empty()) |
| Stack.pop_back(); |
| } |
| // Use pseudo probe based context key to get the sample counter |
| // A context stands for a call path from 'main' to an uninlined |
| // callee with all inline frames recovered on that path. The probes |
| // belonging to that call path is the probes either originated from |
| // the callee or from any functions inlined into the callee. Since |
| // pseudo probes are organized in a tri-tree style after decoded, |
| // the tree path from the tri-tree root (which is the uninlined |
| // callee) to the probe node forms an inline context. |
| // Here we use a list of probe(pointer) as the context key to speed up |
| // aggregation and the final context string will be generate in |
| // ProfileGenerator |
| std::shared_ptr<ProbeBasedCtxKey> getContextKey(); |
| }; |
| |
| /* |
| As in hybrid sample we have a group of LBRs and the most recent sampling call |
| stack, we can walk through those LBRs to infer more call stacks which would be |
| used as context for profile. VirtualUnwinder is the class to do the call stack |
| unwinding based on LBR state. Two types of unwinding are processd here: |
| 1) LBR unwinding and 2) linear range unwinding. |
| Specifically, for each LBR entry(can be classified into call, return, regular |
| branch), LBR unwinding will replay the operation by pushing, popping or |
| switching leaf frame towards the call stack and since the initial call stack |
| is most recently sampled, the replay should be in anti-execution order, i.e. for |
| the regular case, pop the call stack when LBR is call, push frame on call stack |
| when LBR is return. After each LBR processed, it also needs to align with the |
| next LBR by going through instructions from previous LBR's target to current |
| LBR's source, which is the linear unwinding. As instruction from linear range |
| can come from different function by inlining, linear unwinding will do the range |
| splitting and record counters by the range with same inline context. Over those |
| unwinding process we will record each call stack as context id and LBR/linear |
| range as sample counter for further CS profile generation. |
| */ |
| class VirtualUnwinder { |
| public: |
| VirtualUnwinder(ContextSampleCounterMap *Counter, ProfiledBinary *B) |
| : CtxCounterMap(Counter), Binary(B) {} |
| bool unwind(const PerfSample *Sample, uint64_t Repeat); |
| std::set<uint64_t> &getUntrackedCallsites() { return UntrackedCallsites; } |
| |
| private: |
| bool isCallState(UnwindState &State) const { |
| // The tail call frame is always missing here in stack sample, we will |
| // use a specific tail call tracker to infer it. |
| return Binary->addressIsCall(State.getCurrentLBRSource()); |
| } |
| |
| bool isReturnState(UnwindState &State) const { |
| // Simply check addressIsReturn, as ret is always reliable, both for |
| // regular call and tail call. |
| return Binary->addressIsReturn(State.getCurrentLBRSource()); |
| } |
| |
| void unwindCall(UnwindState &State); |
| void unwindLinear(UnwindState &State, uint64_t Repeat); |
| void unwindReturn(UnwindState &State); |
| void unwindBranchWithinFrame(UnwindState &State); |
| |
| template <typename T> |
| void collectSamplesFromFrame(UnwindState::ProfiledFrame *Cur, T &Stack); |
| // Collect each samples on trie node by DFS traversal |
| template <typename T> |
| void collectSamplesFromFrameTrie(UnwindState::ProfiledFrame *Cur, T &Stack); |
| void collectSamplesFromFrameTrie(UnwindState::ProfiledFrame *Cur); |
| |
| void recordRangeCount(uint64_t Start, uint64_t End, UnwindState &State, |
| uint64_t Repeat); |
| void recordBranchCount(const LBREntry &Branch, UnwindState &State, |
| uint64_t Repeat); |
| |
| ContextSampleCounterMap *CtxCounterMap; |
| // Profiled binary that current frame address belongs to |
| ProfiledBinary *Binary; |
| // Keep track of all untracked callsites |
| std::set<uint64_t> UntrackedCallsites; |
| }; |
| |
| // Read perf trace to parse the events and samples. |
| class PerfReaderBase { |
| public: |
| PerfReaderBase(ProfiledBinary *B, StringRef PerfTrace) |
| : Binary(B), PerfTraceFile(PerfTrace) { |
| // Initialize the base address to preferred address. |
| Binary->setBaseAddress(Binary->getPreferredBaseAddress()); |
| }; |
| virtual ~PerfReaderBase() = default; |
| static std::unique_ptr<PerfReaderBase> create(ProfiledBinary *Binary, |
| PerfInputFile &PerfInput); |
| |
| // Entry of the reader to parse multiple perf traces |
| virtual void parsePerfTraces() = 0; |
| const ContextSampleCounterMap &getSampleCounters() const { |
| return SampleCounters; |
| } |
| bool profileIsCS() { return ProfileIsCS; } |
| |
| protected: |
| ProfiledBinary *Binary = nullptr; |
| StringRef PerfTraceFile; |
| |
| ContextSampleCounterMap SampleCounters; |
| bool ProfileIsCS = false; |
| }; |
| |
| // Read perf script to parse the events and samples. |
| class PerfScriptReader : public PerfReaderBase { |
| public: |
| PerfScriptReader(ProfiledBinary *B, StringRef PerfTrace) |
| : PerfReaderBase(B, PerfTrace){}; |
| |
| // Entry of the reader to parse multiple perf traces |
| virtual void parsePerfTraces() override; |
| // Generate perf script from perf data |
| static PerfInputFile convertPerfDataToTrace(ProfiledBinary *Binary, |
| PerfInputFile &File); |
| // Extract perf script type by peaking at the input |
| static PerfContent checkPerfScriptType(StringRef FileName); |
| |
| protected: |
| // The parsed MMap event |
| struct MMapEvent { |
| uint64_t PID = 0; |
| uint64_t Address = 0; |
| uint64_t Size = 0; |
| uint64_t Offset = 0; |
| StringRef BinaryPath; |
| }; |
| |
| // Check whether a given line is LBR sample |
| static bool isLBRSample(StringRef Line); |
| // Check whether a given line is MMAP event |
| static bool isMMap2Event(StringRef Line); |
| // Parse a single line of a PERF_RECORD_MMAP2 event looking for a |
| // mapping between the binary name and its memory layout. |
| static bool extractMMap2EventForBinary(ProfiledBinary *Binary, StringRef Line, |
| MMapEvent &MMap); |
| // Update base address based on mmap events |
| void updateBinaryAddress(const MMapEvent &Event); |
| // Parse mmap event and update binary address |
| void parseMMap2Event(TraceStream &TraceIt); |
| // Parse perf events/samples and do aggregation |
| void parseAndAggregateTrace(); |
| // Parse either an MMAP event or a perf sample |
| void parseEventOrSample(TraceStream &TraceIt); |
| // Warn if the relevant mmap event is missing. |
| void warnIfMissingMMap(); |
| // Emit accumulate warnings. |
| void warnTruncatedStack(); |
| // Warn if range is invalid. |
| void warnInvalidRange(); |
| // Extract call stack from the perf trace lines |
| bool extractCallstack(TraceStream &TraceIt, |
| SmallVectorImpl<uint64_t> &CallStack); |
| // Extract LBR stack from one perf trace line |
| bool extractLBRStack(TraceStream &TraceIt, |
| SmallVectorImpl<LBREntry> &LBRStack); |
| uint64_t parseAggregatedCount(TraceStream &TraceIt); |
| // Parse one sample from multiple perf lines, override this for different |
| // sample type |
| void parseSample(TraceStream &TraceIt); |
| // An aggregated count is given to indicate how many times the sample is |
| // repeated. |
| virtual void parseSample(TraceStream &TraceIt, uint64_t Count){}; |
| void computeCounterFromLBR(const PerfSample *Sample, uint64_t Repeat); |
| // Post process the profile after trace aggregation, we will do simple range |
| // overlap computation for AutoFDO, or unwind for CSSPGO(hybrid sample). |
| virtual void generateUnsymbolizedProfile(); |
| void writeUnsymbolizedProfile(StringRef Filename); |
| void writeUnsymbolizedProfile(raw_fd_ostream &OS); |
| |
| // Samples with the repeating time generated by the perf reader |
| AggregatedCounter AggregatedSamples; |
| // Keep track of all invalid return addresses |
| std::set<uint64_t> InvalidReturnAddresses; |
| }; |
| |
| /* |
| The reader of LBR only perf script. |
| A typical LBR sample is like: |
| 40062f 0x4005c8/0x4005dc/P/-/-/0 0x40062f/0x4005b0/P/-/-/0 ... |
| ... 0x4005c8/0x4005dc/P/-/-/0 |
| */ |
| class LBRPerfReader : public PerfScriptReader { |
| public: |
| LBRPerfReader(ProfiledBinary *Binary, StringRef PerfTrace) |
| : PerfScriptReader(Binary, PerfTrace){}; |
| // Parse the LBR only sample. |
| virtual void parseSample(TraceStream &TraceIt, uint64_t Count) override; |
| }; |
| |
| /* |
| Hybrid perf script includes a group of hybrid samples(LBRs + call stack), |
| which is used to generate CS profile. An example of hybrid sample: |
| 4005dc # call stack leaf |
| 400634 |
| 400684 # call stack root |
| 0x4005c8/0x4005dc/P/-/-/0 0x40062f/0x4005b0/P/-/-/0 ... |
| ... 0x4005c8/0x4005dc/P/-/-/0 # LBR Entries |
| */ |
| class HybridPerfReader : public PerfScriptReader { |
| public: |
| HybridPerfReader(ProfiledBinary *Binary, StringRef PerfTrace) |
| : PerfScriptReader(Binary, PerfTrace){}; |
| // Parse the hybrid sample including the call and LBR line |
| void parseSample(TraceStream &TraceIt, uint64_t Count) override; |
| void generateUnsymbolizedProfile() override; |
| |
| private: |
| // Unwind the hybrid samples after aggregration |
| void unwindSamples(); |
| }; |
| |
| /* |
| Format of unsymbolized profile: |
| |
| [frame1 @ frame2 @ ...] # If it's a CS profile |
| number of entries in RangeCounter |
| from_1-to_1:count_1 |
| from_2-to_2:count_2 |
| ...... |
| from_n-to_n:count_n |
| number of entries in BranchCounter |
| src_1->dst_1:count_1 |
| src_2->dst_2:count_2 |
| ...... |
| src_n->dst_n:count_n |
| [frame1 @ frame2 @ ...] # Next context |
| ...... |
| |
| Note that non-CS profile doesn't have the empty `[]` context. |
| */ |
| class UnsymbolizedProfileReader : public PerfReaderBase { |
| public: |
| UnsymbolizedProfileReader(ProfiledBinary *Binary, StringRef PerfTrace) |
| : PerfReaderBase(Binary, PerfTrace){}; |
| void parsePerfTraces() override; |
| |
| private: |
| void readSampleCounters(TraceStream &TraceIt, SampleCounter &SCounters); |
| void readUnsymbolizedProfile(StringRef Filename); |
| |
| std::unordered_set<std::string> ContextStrSet; |
| }; |
| |
| } // end namespace sampleprof |
| } // end namespace llvm |
| |
| #endif |