964053d56f
This change aims at supporting LBR only sample perf script which is used for regular(Non-CS) profile generation. A LBR perf script includes a batch of LBR sample which starts with a frame pointer and a group of 32 LBR entries is followed. The FROM/TO LBR pair and the range between two consecutive entries (the former entry's TO and the latter entry's FROM) will be used to infer function profile info.
An example of LBR perf script(created by `perf script -F ip,brstack -i perf.data`)
```
40062f 0x40062f/0x4005b0/P/-/-/9 0x400645/0x4005ff/P/-/-/1 0x400637/0x400645/P/-/-/1 ...
4005d7 0x4005d7/0x4005e5/P/-/-/8 0x40062f/0x4005b0/P/-/-/6 0x400645/0x4005ff/P/-/-/1 ...
...
```
For implementation:
- Extended a new child class `LBRPerfReader` for the sample parsing, reused all the functionalities in `extractLBRStack` except for an extension to parsing leading instruction pointer.
- `HybridSample` is reused(just leave the call stack empty) and the parsed samples is still aggregated in `AggregatedSamples`. After that, range samples, branch sample, address samples are computed and recorded.
- Reused `ContextSampleCounterMap` to store the raw profile, since it's no need to aggregation by context, here it just registered one sample counter with a fake context key.
- Unified to use `show-raw-profile` instead of `show-unwinder-output` to dump the intermediate raw profile, see the comments of the format of the raw profile. For CS profile, it remains to output the unwinder output.
Profile generation part will come soon.
Differential Revision: https://reviews.llvm.org/D108153
576 lines
21 KiB
C++
576 lines
21 KiB
C++
//===-- ProfiledBinary.cpp - Binary decoder ---------------------*- 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 "ProfiledBinary.h"
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#include "ErrorHandling.h"
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#include "ProfileGenerator.h"
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#include "llvm/ADT/Triple.h"
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#include "llvm/Demangle/Demangle.h"
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#include "llvm/IR/DebugInfoMetadata.h"
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#include "llvm/Support/CommandLine.h"
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#include "llvm/Support/Format.h"
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#include "llvm/Support/TargetRegistry.h"
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#include "llvm/Support/TargetSelect.h"
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#define DEBUG_TYPE "load-binary"
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using namespace llvm;
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using namespace sampleprof;
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cl::opt<bool> ShowDisassemblyOnly("show-disassembly-only", cl::ReallyHidden,
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cl::init(false), cl::ZeroOrMore,
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cl::desc("Print disassembled code."));
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cl::opt<bool> ShowSourceLocations("show-source-locations", cl::ReallyHidden,
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cl::init(false), cl::ZeroOrMore,
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cl::desc("Print source locations."));
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cl::opt<bool> ShowCanonicalFnName("show-canonical-fname", cl::ReallyHidden,
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cl::init(false), cl::ZeroOrMore,
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cl::desc("Print canonical function name."));
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cl::opt<bool> ShowPseudoProbe(
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"show-pseudo-probe", cl::ReallyHidden, cl::init(false), cl::ZeroOrMore,
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cl::desc("Print pseudo probe section and disassembled info."));
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namespace llvm {
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namespace sampleprof {
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static const Target *getTarget(const ObjectFile *Obj) {
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Triple TheTriple = Obj->makeTriple();
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std::string Error;
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std::string ArchName;
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const Target *TheTarget =
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TargetRegistry::lookupTarget(ArchName, TheTriple, Error);
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if (!TheTarget)
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exitWithError(Error, Obj->getFileName());
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return TheTarget;
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}
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void BinarySizeContextTracker::addInstructionForContext(
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const SampleContextFrameVector &Context, uint32_t InstrSize) {
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ContextTrieNode *CurNode = &RootContext;
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bool IsLeaf = true;
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for (const auto &Callsite : reverse(Context)) {
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StringRef CallerName = Callsite.CallerName;
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LineLocation CallsiteLoc = IsLeaf ? LineLocation(0, 0) : Callsite.Callsite;
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CurNode = CurNode->getOrCreateChildContext(CallsiteLoc, CallerName);
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IsLeaf = false;
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}
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CurNode->addFunctionSize(InstrSize);
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}
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uint32_t
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BinarySizeContextTracker::getFuncSizeForContext(const SampleContext &Context) {
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ContextTrieNode *CurrNode = &RootContext;
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ContextTrieNode *PrevNode = nullptr;
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SampleContextFrames Frames = Context.getContextFrames();
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int32_t I = Frames.size() - 1;
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Optional<uint32_t> Size;
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// Start from top-level context-less function, traverse down the reverse
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// context trie to find the best/longest match for given context, then
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// retrieve the size.
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while (CurrNode && I >= 0) {
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// Process from leaf function to callers (added to context).
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const auto &ChildFrame = Frames[I--];
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PrevNode = CurrNode;
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CurrNode =
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CurrNode->getChildContext(ChildFrame.Callsite, ChildFrame.CallerName);
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if (CurrNode && CurrNode->getFunctionSize().hasValue())
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Size = CurrNode->getFunctionSize().getValue();
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}
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// If we traversed all nodes along the path of the context and haven't
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// found a size yet, pivot to look for size from sibling nodes, i.e size
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// of inlinee under different context.
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if (!Size.hasValue()) {
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if (!CurrNode)
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CurrNode = PrevNode;
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while (!Size.hasValue() && CurrNode &&
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!CurrNode->getAllChildContext().empty()) {
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CurrNode = &CurrNode->getAllChildContext().begin()->second;
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if (CurrNode->getFunctionSize().hasValue())
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Size = CurrNode->getFunctionSize().getValue();
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}
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}
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assert(Size.hasValue() && "We should at least find one context size.");
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return Size.getValue();
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}
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void BinarySizeContextTracker::trackInlineesOptimizedAway(
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MCPseudoProbeDecoder &ProbeDecoder) {
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ProbeFrameStack ProbeContext;
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for (const auto &Child : ProbeDecoder.getDummyInlineRoot().getChildren())
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trackInlineesOptimizedAway(ProbeDecoder, *Child.second.get(), ProbeContext);
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}
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void BinarySizeContextTracker::trackInlineesOptimizedAway(
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MCPseudoProbeDecoder &ProbeDecoder,
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MCDecodedPseudoProbeInlineTree &ProbeNode, ProbeFrameStack &ProbeContext) {
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StringRef FuncName =
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ProbeDecoder.getFuncDescForGUID(ProbeNode.Guid)->FuncName;
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ProbeContext.emplace_back(FuncName, 0);
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// This ProbeContext has a probe, so it has code before inlining and
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// optimization. Make sure we mark its size as known.
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if (!ProbeNode.getProbes().empty()) {
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ContextTrieNode *SizeContext = &RootContext;
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for (auto &ProbeFrame : reverse(ProbeContext)) {
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StringRef CallerName = ProbeFrame.first;
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LineLocation CallsiteLoc(ProbeFrame.second, 0);
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SizeContext =
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SizeContext->getOrCreateChildContext(CallsiteLoc, CallerName);
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}
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// Add 0 size to make known.
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SizeContext->addFunctionSize(0);
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}
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// DFS down the probe inline tree
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for (const auto &ChildNode : ProbeNode.getChildren()) {
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InlineSite Location = ChildNode.first;
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ProbeContext.back().second = std::get<1>(Location);
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trackInlineesOptimizedAway(ProbeDecoder, *ChildNode.second.get(), ProbeContext);
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}
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ProbeContext.pop_back();
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}
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void ProfiledBinary::load() {
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// Attempt to open the binary.
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OwningBinary<Binary> OBinary = unwrapOrError(createBinary(Path), Path);
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Binary &Binary = *OBinary.getBinary();
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auto *Obj = dyn_cast<ELFObjectFileBase>(&Binary);
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if (!Obj)
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exitWithError("not a valid Elf image", Path);
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TheTriple = Obj->makeTriple();
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// Current only support X86
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if (!TheTriple.isX86())
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exitWithError("unsupported target", TheTriple.getTriple());
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LLVM_DEBUG(dbgs() << "Loading " << Path << "\n");
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// Find the preferred load address for text sections.
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setPreferredTextSegmentAddresses(Obj);
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// Decode pseudo probe related section
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decodePseudoProbe(Obj);
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// Disassemble the text sections.
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disassemble(Obj);
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// Track size for optimized inlinees when probe is available
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if (UsePseudoProbes && TrackFuncContextSize)
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FuncSizeTracker.trackInlineesOptimizedAway(ProbeDecoder);
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// Use function start and return address to infer prolog and epilog
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ProEpilogTracker.inferPrologOffsets(FuncStartAddrMap);
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ProEpilogTracker.inferEpilogOffsets(RetAddrs);
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// TODO: decode other sections.
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}
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bool ProfiledBinary::inlineContextEqual(uint64_t Address1,
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uint64_t Address2) const {
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uint64_t Offset1 = virtualAddrToOffset(Address1);
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uint64_t Offset2 = virtualAddrToOffset(Address2);
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const SampleContextFrameVector &Context1 = getFrameLocationStack(Offset1);
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const SampleContextFrameVector &Context2 = getFrameLocationStack(Offset2);
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if (Context1.size() != Context2.size())
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return false;
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if (Context1.empty())
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return false;
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// The leaf frame contains location within the leaf, and it
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// needs to be remove that as it's not part of the calling context
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return std::equal(Context1.begin(), Context1.begin() + Context1.size() - 1,
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Context2.begin(), Context2.begin() + Context2.size() - 1);
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}
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SampleContextFrameVector
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ProfiledBinary::getExpandedContext(const SmallVectorImpl<uint64_t> &Stack,
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bool &WasLeafInlined) const {
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SampleContextFrameVector ContextVec;
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// Process from frame root to leaf
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for (auto Address : Stack) {
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uint64_t Offset = virtualAddrToOffset(Address);
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const SampleContextFrameVector &ExpandedContext =
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getFrameLocationStack(Offset);
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// An instruction without a valid debug line will be ignored by sample
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// processing
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if (ExpandedContext.empty())
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return SampleContextFrameVector();
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// Set WasLeafInlined to the size of inlined frame count for the last
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// address which is leaf
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WasLeafInlined = (ExpandedContext.size() > 1);
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ContextVec.append(ExpandedContext);
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}
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// Compress the context string except for the leaf frame
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auto LeafFrame = ContextVec.back();
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LeafFrame.Callsite = LineLocation(0, 0);
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ContextVec.pop_back();
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assert(ContextVec.size() && "Context length should be at least 1");
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CSProfileGenerator::compressRecursionContext(ContextVec);
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CSProfileGenerator::trimContext(ContextVec);
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ContextVec.push_back(LeafFrame);
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return ContextVec;
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}
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template <class ELFT>
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void ProfiledBinary::setPreferredTextSegmentAddresses(const ELFFile<ELFT> &Obj, StringRef FileName) {
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const auto &PhdrRange = unwrapOrError(Obj.program_headers(), FileName);
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for (const typename ELFT::Phdr &Phdr : PhdrRange) {
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if ((Phdr.p_type == ELF::PT_LOAD) && (Phdr.p_flags & ELF::PF_X)) {
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// Segments will always be loaded at a page boundary.
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PreferredTextSegmentAddresses.push_back(Phdr.p_vaddr & ~(Phdr.p_align - 1U));
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TextSegmentOffsets.push_back(Phdr.p_offset & ~(Phdr.p_align - 1U));
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}
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}
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if (PreferredTextSegmentAddresses.empty())
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exitWithError("no executable segment found", FileName);
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}
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void ProfiledBinary::setPreferredTextSegmentAddresses(const ELFObjectFileBase *Obj) {
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if (const auto *ELFObj = dyn_cast<ELF32LEObjectFile>(Obj))
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setPreferredTextSegmentAddresses(ELFObj->getELFFile(), Obj->getFileName());
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else if (const auto *ELFObj = dyn_cast<ELF32BEObjectFile>(Obj))
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setPreferredTextSegmentAddresses(ELFObj->getELFFile(), Obj->getFileName());
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else if (const auto *ELFObj = dyn_cast<ELF64LEObjectFile>(Obj))
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setPreferredTextSegmentAddresses(ELFObj->getELFFile(), Obj->getFileName());
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else if (const auto *ELFObj = cast<ELF64BEObjectFile>(Obj))
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setPreferredTextSegmentAddresses(ELFObj->getELFFile(), Obj->getFileName());
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else
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llvm_unreachable("invalid ELF object format");
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}
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void ProfiledBinary::decodePseudoProbe(const ELFObjectFileBase *Obj) {
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StringRef FileName = Obj->getFileName();
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for (section_iterator SI = Obj->section_begin(), SE = Obj->section_end();
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SI != SE; ++SI) {
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const SectionRef &Section = *SI;
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StringRef SectionName = unwrapOrError(Section.getName(), FileName);
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if (SectionName == ".pseudo_probe_desc") {
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StringRef Contents = unwrapOrError(Section.getContents(), FileName);
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if (!ProbeDecoder.buildGUID2FuncDescMap(
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reinterpret_cast<const uint8_t *>(Contents.data()),
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Contents.size()))
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exitWithError("Pseudo Probe decoder fail in .pseudo_probe_desc section");
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} else if (SectionName == ".pseudo_probe") {
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StringRef Contents = unwrapOrError(Section.getContents(), FileName);
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if (!ProbeDecoder.buildAddress2ProbeMap(
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reinterpret_cast<const uint8_t *>(Contents.data()),
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Contents.size()))
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exitWithError("Pseudo Probe decoder fail in .pseudo_probe section");
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// set UsePseudoProbes flag, used for PerfReader
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UsePseudoProbes = true;
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}
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}
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if (ShowPseudoProbe)
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ProbeDecoder.printGUID2FuncDescMap(outs());
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}
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bool ProfiledBinary::dissassembleSymbol(std::size_t SI, ArrayRef<uint8_t> Bytes,
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SectionSymbolsTy &Symbols,
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const SectionRef &Section) {
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std::size_t SE = Symbols.size();
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uint64_t SectionOffset = Section.getAddress() - getPreferredBaseAddress();
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uint64_t SectSize = Section.getSize();
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uint64_t StartOffset = Symbols[SI].Addr - getPreferredBaseAddress();
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uint64_t EndOffset = (SI + 1 < SE)
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? Symbols[SI + 1].Addr - getPreferredBaseAddress()
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: SectionOffset + SectSize;
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if (StartOffset >= EndOffset)
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return true;
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StringRef SymbolName =
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ShowCanonicalFnName
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? FunctionSamples::getCanonicalFnName(Symbols[SI].Name)
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: Symbols[SI].Name;
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if (ShowDisassemblyOnly)
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outs() << '<' << SymbolName << ">:\n";
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auto WarnInvalidInsts = [](uint64_t Start, uint64_t End) {
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WithColor::warning() << "Invalid instructions at "
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<< format("%8" PRIx64, Start) << " - "
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<< format("%8" PRIx64, End) << "\n";
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};
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uint64_t Offset = StartOffset;
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// Size of a consecutive invalid instruction range starting from Offset -1
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// backwards.
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uint64_t InvalidInstLength = 0;
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while (Offset < EndOffset) {
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MCInst Inst;
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uint64_t Size;
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// Disassemble an instruction.
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bool Disassembled =
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DisAsm->getInstruction(Inst, Size, Bytes.slice(Offset - SectionOffset),
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Offset + getPreferredBaseAddress(), nulls());
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if (Size == 0)
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Size = 1;
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if (ShowDisassemblyOnly) {
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if (ShowPseudoProbe) {
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ProbeDecoder.printProbeForAddress(outs(),
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Offset + getPreferredBaseAddress());
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}
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outs() << format("%8" PRIx64 ":", Offset + getPreferredBaseAddress());
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size_t Start = outs().tell();
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if (Disassembled)
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IPrinter->printInst(&Inst, Offset + Size, "", *STI.get(), outs());
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else
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outs() << "\t<unknown>";
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if (ShowSourceLocations) {
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unsigned Cur = outs().tell() - Start;
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if (Cur < 40)
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outs().indent(40 - Cur);
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InstructionPointer IP(this, Offset);
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outs() << getReversedLocWithContext(
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symbolize(IP, ShowCanonicalFnName, ShowPseudoProbe));
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}
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outs() << "\n";
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}
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if (Disassembled) {
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const MCInstrDesc &MCDesc = MII->get(Inst.getOpcode());
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// Populate a vector of the symbolized callsite at this location
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// We don't need symbolized info for probe-based profile, just use an
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// empty stack as an entry to indicate a valid binary offset
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SampleContextFrameVector SymbolizedCallStack;
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if (!UsePseudoProbes || TrackFuncContextSize) {
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InstructionPointer IP(this, Offset);
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// TODO: reallocation of Offset2LocStackMap will lead to dangling
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// strings We need ProfiledBinary to owned these string.
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Offset2LocStackMap[Offset] = symbolize(IP, true, UsePseudoProbes);
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SampleContextFrameVector &SymbolizedCallStack =
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Offset2LocStackMap[Offset];
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// Record instruction size for the corresponding context
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if (TrackFuncContextSize && !SymbolizedCallStack.empty())
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FuncSizeTracker.addInstructionForContext(Offset2LocStackMap[Offset],
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Size);
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} else {
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Offset2LocStackMap[Offset] = SampleContextFrameVector();
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}
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// Populate address maps.
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CodeAddrs.push_back(Offset);
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if (MCDesc.isCall())
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CallAddrs.insert(Offset);
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else if (MCDesc.isReturn())
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RetAddrs.insert(Offset);
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if (InvalidInstLength) {
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WarnInvalidInsts(Offset - InvalidInstLength, Offset - 1);
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InvalidInstLength = 0;
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}
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} else {
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InvalidInstLength += Size;
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}
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Offset += Size;
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}
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if (InvalidInstLength)
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WarnInvalidInsts(Offset - InvalidInstLength, Offset - 1);
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if (ShowDisassemblyOnly)
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outs() << "\n";
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FuncStartAddrMap[StartOffset] = Symbols[SI].Name.str();
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return true;
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}
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void ProfiledBinary::setUpDisassembler(const ELFObjectFileBase *Obj) {
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const Target *TheTarget = getTarget(Obj);
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std::string TripleName = TheTriple.getTriple();
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StringRef FileName = Obj->getFileName();
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MRI.reset(TheTarget->createMCRegInfo(TripleName));
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if (!MRI)
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exitWithError("no register info for target " + TripleName, FileName);
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MCTargetOptions MCOptions;
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AsmInfo.reset(TheTarget->createMCAsmInfo(*MRI, TripleName, MCOptions));
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if (!AsmInfo)
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exitWithError("no assembly info for target " + TripleName, FileName);
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SubtargetFeatures Features = Obj->getFeatures();
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STI.reset(
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TheTarget->createMCSubtargetInfo(TripleName, "", Features.getString()));
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if (!STI)
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exitWithError("no subtarget info for target " + TripleName, FileName);
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MII.reset(TheTarget->createMCInstrInfo());
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if (!MII)
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exitWithError("no instruction info for target " + TripleName, FileName);
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MCContext Ctx(Triple(TripleName), AsmInfo.get(), MRI.get(), STI.get());
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std::unique_ptr<MCObjectFileInfo> MOFI(
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TheTarget->createMCObjectFileInfo(Ctx, /*PIC=*/false));
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Ctx.setObjectFileInfo(MOFI.get());
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DisAsm.reset(TheTarget->createMCDisassembler(*STI, Ctx));
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if (!DisAsm)
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exitWithError("no disassembler for target " + TripleName, FileName);
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MIA.reset(TheTarget->createMCInstrAnalysis(MII.get()));
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int AsmPrinterVariant = AsmInfo->getAssemblerDialect();
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IPrinter.reset(TheTarget->createMCInstPrinter(
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Triple(TripleName), AsmPrinterVariant, *AsmInfo, *MII, *MRI));
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IPrinter->setPrintBranchImmAsAddress(true);
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}
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void ProfiledBinary::disassemble(const ELFObjectFileBase *Obj) {
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// Set up disassembler and related components.
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setUpDisassembler(Obj);
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// Create a mapping from virtual address to symbol name. The symbols in text
|
|
// sections are the candidates to dissassemble.
|
|
std::map<SectionRef, SectionSymbolsTy> AllSymbols;
|
|
StringRef FileName = Obj->getFileName();
|
|
for (const SymbolRef &Symbol : Obj->symbols()) {
|
|
const uint64_t Addr = unwrapOrError(Symbol.getAddress(), FileName);
|
|
const StringRef Name = unwrapOrError(Symbol.getName(), FileName);
|
|
section_iterator SecI = unwrapOrError(Symbol.getSection(), FileName);
|
|
if (SecI != Obj->section_end())
|
|
AllSymbols[*SecI].push_back(SymbolInfoTy(Addr, Name, ELF::STT_NOTYPE));
|
|
}
|
|
|
|
// Sort all the symbols. Use a stable sort to stabilize the output.
|
|
for (std::pair<const SectionRef, SectionSymbolsTy> &SecSyms : AllSymbols)
|
|
stable_sort(SecSyms.second);
|
|
|
|
if (ShowDisassemblyOnly)
|
|
outs() << "\nDisassembly of " << FileName << ":\n";
|
|
|
|
// Dissassemble a text section.
|
|
for (section_iterator SI = Obj->section_begin(), SE = Obj->section_end();
|
|
SI != SE; ++SI) {
|
|
const SectionRef &Section = *SI;
|
|
if (!Section.isText())
|
|
continue;
|
|
|
|
uint64_t ImageLoadAddr = getPreferredBaseAddress();
|
|
uint64_t SectionOffset = Section.getAddress() - ImageLoadAddr;
|
|
uint64_t SectSize = Section.getSize();
|
|
if (!SectSize)
|
|
continue;
|
|
|
|
// Register the text section.
|
|
TextSections.insert({SectionOffset, SectSize});
|
|
|
|
if (ShowDisassemblyOnly) {
|
|
StringRef SectionName = unwrapOrError(Section.getName(), FileName);
|
|
outs() << "\nDisassembly of section " << SectionName;
|
|
outs() << " [" << format("0x%" PRIx64, Section.getAddress()) << ", "
|
|
<< format("0x%" PRIx64, Section.getAddress() + SectSize)
|
|
<< "]:\n\n";
|
|
}
|
|
|
|
// Get the section data.
|
|
ArrayRef<uint8_t> Bytes =
|
|
arrayRefFromStringRef(unwrapOrError(Section.getContents(), FileName));
|
|
|
|
// Get the list of all the symbols in this section.
|
|
SectionSymbolsTy &Symbols = AllSymbols[Section];
|
|
|
|
// Disassemble symbol by symbol.
|
|
for (std::size_t SI = 0, SE = Symbols.size(); SI != SE; ++SI) {
|
|
if (!dissassembleSymbol(SI, Bytes, Symbols, Section))
|
|
exitWithError("disassembling error", FileName);
|
|
}
|
|
}
|
|
}
|
|
|
|
void ProfiledBinary::setupSymbolizer() {
|
|
symbolize::LLVMSymbolizer::Options SymbolizerOpts;
|
|
SymbolizerOpts.PrintFunctions =
|
|
DILineInfoSpecifier::FunctionNameKind::LinkageName;
|
|
SymbolizerOpts.Demangle = false;
|
|
SymbolizerOpts.DefaultArch = TheTriple.getArchName().str();
|
|
SymbolizerOpts.UseSymbolTable = false;
|
|
SymbolizerOpts.RelativeAddresses = false;
|
|
Symbolizer = std::make_unique<symbolize::LLVMSymbolizer>(SymbolizerOpts);
|
|
}
|
|
|
|
SampleContextFrameVector ProfiledBinary::symbolize(const InstructionPointer &IP,
|
|
bool UseCanonicalFnName,
|
|
bool UseProbeDiscriminator) {
|
|
assert(this == IP.Binary &&
|
|
"Binary should only symbolize its own instruction");
|
|
auto Addr = object::SectionedAddress{IP.Offset + getPreferredBaseAddress(),
|
|
object::SectionedAddress::UndefSection};
|
|
DIInliningInfo InlineStack =
|
|
unwrapOrError(Symbolizer->symbolizeInlinedCode(Path, Addr), getName());
|
|
|
|
SampleContextFrameVector CallStack;
|
|
for (int32_t I = InlineStack.getNumberOfFrames() - 1; I >= 0; I--) {
|
|
const auto &CallerFrame = InlineStack.getFrame(I);
|
|
if (CallerFrame.FunctionName == "<invalid>")
|
|
break;
|
|
|
|
StringRef FunctionName(CallerFrame.FunctionName);
|
|
if (UseCanonicalFnName)
|
|
FunctionName = FunctionSamples::getCanonicalFnName(FunctionName);
|
|
|
|
uint32_t Discriminator = CallerFrame.Discriminator;
|
|
uint32_t LineOffset = CallerFrame.Line - CallerFrame.StartLine;
|
|
if (UseProbeDiscriminator) {
|
|
LineOffset =
|
|
PseudoProbeDwarfDiscriminator::extractProbeIndex(Discriminator);
|
|
Discriminator = 0;
|
|
} else {
|
|
Discriminator = DILocation::getBaseDiscriminatorFromDiscriminator(
|
|
CallerFrame.Discriminator,
|
|
/* IsFSDiscriminator */ false);
|
|
}
|
|
|
|
LineLocation Line(LineOffset, Discriminator);
|
|
auto It = NameStrings.insert(FunctionName.str());
|
|
CallStack.emplace_back(*It.first, Line);
|
|
}
|
|
|
|
return CallStack;
|
|
}
|
|
|
|
InstructionPointer::InstructionPointer(const ProfiledBinary *Binary,
|
|
uint64_t Address, bool RoundToNext)
|
|
: Binary(Binary), Address(Address) {
|
|
Index = Binary->getIndexForAddr(Address);
|
|
if (RoundToNext) {
|
|
// we might get address which is not the code
|
|
// it should round to the next valid address
|
|
this->Address = Binary->getAddressforIndex(Index);
|
|
}
|
|
}
|
|
|
|
void InstructionPointer::advance() {
|
|
Index++;
|
|
Address = Binary->getAddressforIndex(Index);
|
|
}
|
|
|
|
void InstructionPointer::backward() {
|
|
Index--;
|
|
Address = Binary->getAddressforIndex(Index);
|
|
}
|
|
|
|
void InstructionPointer::update(uint64_t Addr) {
|
|
Address = Addr;
|
|
Index = Binary->getIndexForAddr(Address);
|
|
}
|
|
|
|
} // end namespace sampleprof
|
|
} // end namespace llvm
|