For CS profile generation, the process of call stack unwinding is time-consuming since for each LBR entry we need linear time to generate the context( hash, compression, string concatenation). This change speeds up this by grouping all the call frame within one LBR sample into a trie and aggregating the result(sample counter) on it, deferring the context compression and string generation to the end of unwinding. Specifically, it uses `StackLeaf` as the top frame on the stack and manipulates(pop or push a trie node) it dynamically during virtual unwinding so that the raw sample can just be recoded on the leaf node, the path(root to leaf) will represent its calling context. In the end, it traverses the trie and generates the context on the fly. Results: Our internal branch shows about 5X speed-up on some large workloads in SPEC06 benchmark. Differential Revision: https://reviews.llvm.org/D94110
432 lines
16 KiB
C++
432 lines
16 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/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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static cl::opt<bool> ShowDisassembly("show-disassembly", cl::ReallyHidden,
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cl::init(false), cl::ZeroOrMore,
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cl::desc("Print disassembled code."));
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static cl::opt<bool> ShowSourceLocations("show-source-locations",
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cl::ReallyHidden, cl::init(false),
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cl::ZeroOrMore,
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cl::desc("Print source locations."));
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static 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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template <class ELFT>
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static uint64_t getELFImageLMAForSec(const ELFFile<ELFT> &Obj,
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const object::ELFSectionRef &Sec,
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StringRef FileName) {
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// Search for a PT_LOAD segment containing the requested section. Return this
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// segment's p_addr as the image load address for the section.
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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_vaddr <= Sec.getAddress()) &&
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(Phdr.p_vaddr + Phdr.p_memsz > Sec.getAddress()))
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// Segments will always be loaded at a page boundary.
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return Phdr.p_paddr & ~(Phdr.p_align - 1U);
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return 0;
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}
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// Get the image load address for a specific section. Note that an image is
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// loaded by segments (a group of sections) and segments may not be consecutive
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// in memory.
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static uint64_t getELFImageLMAForSec(const object::ELFSectionRef &Sec) {
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if (const auto *ELFObj = dyn_cast<ELF32LEObjectFile>(Sec.getObject()))
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return getELFImageLMAForSec(ELFObj->getELFFile(), Sec,
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ELFObj->getFileName());
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else if (const auto *ELFObj = dyn_cast<ELF32BEObjectFile>(Sec.getObject()))
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return getELFImageLMAForSec(ELFObj->getELFFile(), Sec,
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ELFObj->getFileName());
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else if (const auto *ELFObj = dyn_cast<ELF64LEObjectFile>(Sec.getObject()))
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return getELFImageLMAForSec(ELFObj->getELFFile(), Sec,
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ELFObj->getFileName());
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const auto *ELFObj = cast<ELF64BEObjectFile>(Sec.getObject());
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return getELFImageLMAForSec(ELFObj->getELFFile(), Sec, ELFObj->getFileName());
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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 base address for text sections.
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setPreferredBaseAddress(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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// 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 FrameLocationStack &Context1 = getFrameLocationStack(Offset1);
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const FrameLocationStack &Context2 = getFrameLocationStack(Offset2);
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if (Context1.size() != Context2.size())
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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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std::string ProfiledBinary::getExpandedContextStr(
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const SmallVectorImpl<uint64_t> &Stack) const {
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std::string ContextStr;
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SmallVector<std::string, 16> 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 FrameLocationStack &ExpandedContext = getFrameLocationStack(Offset);
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for (const auto &Loc : ExpandedContext) {
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ContextVec.push_back(getCallSite(Loc));
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}
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}
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assert(ContextVec.size() && "Context length should be at least 1");
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// Compress the context string except for the leaf frame
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std::string LeafFrame = ContextVec.back();
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ContextVec.pop_back();
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CSProfileGenerator::compressRecursionContext<std::string>(ContextVec);
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std::ostringstream OContextStr;
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for (uint32_t I = 0; I < (uint32_t)ContextVec.size(); I++) {
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if (OContextStr.str().size()) {
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OContextStr << " @ ";
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}
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OContextStr << ContextVec[I];
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}
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// Only keep the function name for the leaf frame
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if (OContextStr.str().size())
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OContextStr << " @ ";
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OContextStr << StringRef(LeafFrame).split(":").first.str();
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return OContextStr.str();
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}
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void ProfiledBinary::setPreferredBaseAddress(const ELFObjectFileBase *Obj) {
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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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if (Section.isText()) {
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PreferredBaseAddress = getELFImageLMAForSec(Section);
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return;
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}
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}
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exitWithError("no text section found", Obj->getFileName());
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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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ProbeDecoder.buildGUID2FuncDescMap(
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reinterpret_cast<const uint8_t *>(Contents.data()), Contents.size());
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} else if (SectionName == ".pseudo_probe") {
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StringRef Contents = unwrapOrError(Section.getContents(), FileName);
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ProbeDecoder.buildAddress2ProbeMap(
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reinterpret_cast<const uint8_t *>(Contents.data()), Contents.size());
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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() - PreferredBaseAddress;
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uint64_t SectSize = Section.getSize();
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uint64_t StartOffset = Symbols[SI].Addr - PreferredBaseAddress;
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uint64_t EndOffset = (SI + 1 < SE)
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? Symbols[SI + 1].Addr - PreferredBaseAddress
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: SectionOffset + SectSize;
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if (StartOffset >= EndOffset)
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return true;
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std::string &&SymbolName = Symbols[SI].Name.str();
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if (ShowDisassembly)
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outs() << '<' << SymbolName << ">:\n";
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uint64_t Offset = StartOffset;
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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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if (!DisAsm->getInstruction(Inst, Size, Bytes.slice(Offset - SectionOffset),
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Offset + PreferredBaseAddress, nulls()))
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return false;
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if (ShowDisassembly) {
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if (ShowPseudoProbe) {
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ProbeDecoder.printProbeForAddress(outs(),
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Offset + PreferredBaseAddress);
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}
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outs() << format("%8" PRIx64 ":", Offset);
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size_t Start = outs().tell();
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IPrinter->printInst(&Inst, Offset + Size, "", *STI.get(), outs());
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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 Inst(this, Offset);
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outs() << getReversedLocWithContext(symbolize(Inst));
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}
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outs() << "\n";
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}
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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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InstructionPointer IP(this, Offset);
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Offset2LocStackMap[Offset] = symbolize(IP, true);
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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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Offset += Size;
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}
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if (ShowDisassembly)
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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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MCObjectFileInfo MOFI;
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MCContext Ctx(AsmInfo.get(), MRI.get(), &MOFI);
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MOFI.InitMCObjectFileInfo(Triple(TripleName), false, Ctx);
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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
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// sections are the candidates to dissassemble.
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std::map<SectionRef, SectionSymbolsTy> AllSymbols;
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StringRef FileName = Obj->getFileName();
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for (const SymbolRef &Symbol : Obj->symbols()) {
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const uint64_t Addr = unwrapOrError(Symbol.getAddress(), FileName);
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const StringRef Name = unwrapOrError(Symbol.getName(), FileName);
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section_iterator SecI = unwrapOrError(Symbol.getSection(), FileName);
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if (SecI != Obj->section_end())
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AllSymbols[*SecI].push_back(SymbolInfoTy(Addr, Name, ELF::STT_NOTYPE));
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}
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// Sort all the symbols. Use a stable sort to stabilize the output.
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for (std::pair<const SectionRef, SectionSymbolsTy> &SecSyms : AllSymbols)
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stable_sort(SecSyms.second);
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if (ShowDisassembly)
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outs() << "\nDisassembly of " << FileName << ":\n";
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// Dissassemble a text section.
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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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if (!Section.isText())
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continue;
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uint64_t ImageLoadAddr = PreferredBaseAddress;
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uint64_t SectionOffset = Section.getAddress() - ImageLoadAddr;
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uint64_t SectSize = Section.getSize();
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if (!SectSize)
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continue;
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// Register the text section.
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TextSections.insert({SectionOffset, SectSize});
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if (ShowDisassembly) {
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StringRef SectionName = unwrapOrError(Section.getName(), FileName);
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outs() << "\nDisassembly of section " << SectionName;
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outs() << " [" << format("0x%" PRIx64, SectionOffset) << ", "
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<< format("0x%" PRIx64, SectionOffset + SectSize) << "]:\n\n";
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}
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// Get the section data.
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ArrayRef<uint8_t> Bytes =
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arrayRefFromStringRef(unwrapOrError(Section.getContents(), FileName));
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// Get the list of all the symbols in this section.
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SectionSymbolsTy &Symbols = AllSymbols[Section];
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// Disassemble symbol by symbol.
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for (std::size_t SI = 0, SE = Symbols.size(); SI != SE; ++SI) {
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if (!dissassembleSymbol(SI, Bytes, Symbols, Section))
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exitWithError("disassembling error", FileName);
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}
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}
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}
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void ProfiledBinary::setupSymbolizer() {
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symbolize::LLVMSymbolizer::Options SymbolizerOpts;
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SymbolizerOpts.PrintFunctions =
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DILineInfoSpecifier::FunctionNameKind::LinkageName;
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SymbolizerOpts.Demangle = false;
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SymbolizerOpts.DefaultArch = TheTriple.getArchName().str();
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SymbolizerOpts.UseSymbolTable = false;
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SymbolizerOpts.RelativeAddresses = false;
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Symbolizer = std::make_unique<symbolize::LLVMSymbolizer>(SymbolizerOpts);
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}
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FrameLocationStack ProfiledBinary::symbolize(const InstructionPointer &IP,
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bool UseCanonicalFnName) {
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assert(this == IP.Binary &&
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"Binary should only symbolize its own instruction");
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auto Addr = object::SectionedAddress{IP.Offset + PreferredBaseAddress,
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object::SectionedAddress::UndefSection};
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DIInliningInfo InlineStack =
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unwrapOrError(Symbolizer->symbolizeInlinedCode(Path, Addr), getName());
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FrameLocationStack CallStack;
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for (int32_t I = InlineStack.getNumberOfFrames() - 1; I >= 0; I--) {
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const auto &CallerFrame = InlineStack.getFrame(I);
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if (CallerFrame.FunctionName == "<invalid>")
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break;
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StringRef FunctionName(CallerFrame.FunctionName);
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if (UseCanonicalFnName)
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FunctionName = FunctionSamples::getCanonicalFnName(FunctionName);
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LineLocation Line(CallerFrame.Line - CallerFrame.StartLine,
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CallerFrame.Discriminator);
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FrameLocation Callsite(FunctionName.str(), Line);
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CallStack.push_back(Callsite);
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}
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return CallStack;
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}
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InstructionPointer::InstructionPointer(ProfiledBinary *Binary, uint64_t Address,
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bool RoundToNext)
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: Binary(Binary), Address(Address) {
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Index = Binary->getIndexForAddr(Address);
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if (RoundToNext) {
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// we might get address which is not the code
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// it should round to the next valid address
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this->Address = Binary->getAddressforIndex(Index);
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}
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}
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void InstructionPointer::advance() {
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Index++;
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Address = Binary->getAddressforIndex(Index);
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}
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void InstructionPointer::backward() {
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Index--;
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Address = Binary->getAddressforIndex(Index);
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}
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void InstructionPointer::update(uint64_t Addr) {
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Address = Addr;
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Index = Binary->getIndexForAddr(Address);
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}
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} // end namespace sampleprof
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} // end namespace llvm
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