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llvm-project/lld/ELF/LTO.cpp
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Sriraman Tallam 94317878d8 LLD Support for Basic Block Sections 
This is part of the Propeller framework to do post link code layout
optimizations. Please see the RFC here:
https://groups.google.com/forum/#!msg/llvm-dev/ef3mKzAdJ7U/1shV64BYBAAJ and the
detailed RFC doc here:
https://github.com/google/llvm-propeller/blob/plo-dev/Propeller_RFC.pdf

This patch adds lld support for basic block sections and performs relaxations
after the basic blocks have been reordered.

After the linker has reordered the basic block sections according to the
desired sequence, it runs a relaxation pass to optimize jump instructions.
Currently, the compiler emits the long form of all jump instructions. AMD64 ISA
supports variants of jump instructions with one byte offset or a four byte
offset. The compiler generates jump instructions with R_X86_64 32-bit PC
relative relocations. We would like to use a new relocation type for these jump
instructions as it makes it easy and accurate while relaxing these instructions.

The relaxation pass does two things:

First, it deletes all explicit fall-through direct jump instructions between
adjacent basic blocks. This is done by discarding the tail of the basic block
section.

Second, If there are consecutive jump instructions, it checks if the first
conditional jump can be inverted to convert the second into a fall through and
delete the second.

The jump instructions are relaxed by using jump instruction mods, something
like relocations. These are used to modify the opcode of the jump instruction.
Jump instruction mods contain three values, instruction offset, jump type and
size. While writing this jump instruction out to the final binary, the linker
uses the jump instruction mod to determine the opcode and the size of the
modified jump instruction. These mods are required because the input object
files are memory-mapped without write permissions and directly modifying the
object files requires copying these sections. Copying a large number of basic
block sections significantly bloats memory.

Differential Revision: https://reviews.llvm.org/D68065
2020-04-07 06:55:57 -07:00

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//===- LTO.cpp ------------------------------------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
#include "LTO.h"
#include "Config.h"
#include "InputFiles.h"
#include "LinkerScript.h"
#include "SymbolTable.h"
#include "Symbols.h"
#include "lld/Common/Args.h"
#include "lld/Common/ErrorHandler.h"
#include "lld/Common/TargetOptionsCommandFlags.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/Twine.h"
#include "llvm/BinaryFormat/ELF.h"
#include "llvm/Bitcode/BitcodeReader.h"
#include "llvm/Bitcode/BitcodeWriter.h"
#include "llvm/IR/DiagnosticPrinter.h"
#include "llvm/LTO/Caching.h"
#include "llvm/LTO/Config.h"
#include "llvm/LTO/LTO.h"
#include "llvm/Object/SymbolicFile.h"
#include "llvm/Support/CodeGen.h"
#include "llvm/Support/Error.h"
#include "llvm/Support/FileSystem.h"
#include "llvm/Support/MemoryBuffer.h"
#include <algorithm>
#include <cstddef>
#include <memory>
#include <string>
#include <system_error>
#include <vector>
using namespace llvm;
using namespace llvm::object;
using namespace llvm::ELF;
namespace lld {
namespace elf {
// Creates an empty file to store a list of object files for final
// linking of distributed ThinLTO.
static std::unique_ptr<raw_fd_ostream> openFile(StringRef file) {
std::error_code ec;
auto ret =
std::make_unique<raw_fd_ostream>(file, ec, sys::fs::OpenFlags::OF_None);
if (ec) {
error("cannot open " + file + ": " + ec.message());
return nullptr;
}
return ret;
}
static std::string getThinLTOOutputFile(StringRef modulePath) {
return lto::getThinLTOOutputFile(
std::string(modulePath), std::string(config->thinLTOPrefixReplace.first),
std::string(config->thinLTOPrefixReplace.second));
}
static lto::Config createConfig() {
lto::Config c;
// LLD supports the new relocations and address-significance tables.
c.Options = initTargetOptionsFromCodeGenFlags();
c.Options.RelaxELFRelocations = true;
c.Options.EmitAddrsig = true;
// Always emit a section per function/datum with LTO.
c.Options.FunctionSections = true;
c.Options.DataSections = true;
// Check if basic block sections must be used.
// Allowed values for --lto-basicblock-sections are "all", "labels",
// "<file name specifying basic block ids>", or none. This is the equivalent
// of -fbasicblock-sections= flag in clang.
if (!config->ltoBasicBlockSections.empty()) {
if (config->ltoBasicBlockSections == "all") {
c.Options.BBSections = BasicBlockSection::All;
} else if (config->ltoBasicBlockSections == "labels") {
c.Options.BBSections = BasicBlockSection::Labels;
} else if (config->ltoBasicBlockSections == "none") {
c.Options.BBSections = BasicBlockSection::None;
} else {
ErrorOr<std::unique_ptr<MemoryBuffer>> MBOrErr =
MemoryBuffer::getFile(config->ltoBasicBlockSections.str());
if (!MBOrErr) {
error("cannot open " + config->ltoBasicBlockSections + ":" +
MBOrErr.getError().message());
} else {
c.Options.BBSectionsFuncListBuf = std::move(*MBOrErr);
}
c.Options.BBSections = BasicBlockSection::List;
}
}
c.Options.UniqueBBSectionNames = config->ltoUniqueBBSectionNames;
if (auto relocModel = getRelocModelFromCMModel())
c.RelocModel = *relocModel;
else if (config->relocatable)
c.RelocModel = None;
else if (config->isPic)
c.RelocModel = Reloc::PIC_;
else
c.RelocModel = Reloc::Static;
c.CodeModel = getCodeModelFromCMModel();
c.DisableVerify = config->disableVerify;
c.DiagHandler = diagnosticHandler;
c.OptLevel = config->ltoo;
c.CPU = getCPUStr();
c.MAttrs = getMAttrs();
c.CGOptLevel = args::getCGOptLevel(config->ltoo);
c.PTO.LoopVectorization = c.OptLevel > 1;
c.PTO.SLPVectorization = c.OptLevel > 1;
// Set up a custom pipeline if we've been asked to.
c.OptPipeline = std::string(config->ltoNewPmPasses);
c.AAPipeline = std::string(config->ltoAAPipeline);
// Set up optimization remarks if we've been asked to.
c.RemarksFilename = std::string(config->optRemarksFilename);
c.RemarksPasses = std::string(config->optRemarksPasses);
c.RemarksWithHotness = config->optRemarksWithHotness;
c.RemarksFormat = std::string(config->optRemarksFormat);
c.SampleProfile = std::string(config->ltoSampleProfile);
c.UseNewPM = config->ltoNewPassManager;
c.DebugPassManager = config->ltoDebugPassManager;
c.DwoDir = std::string(config->dwoDir);
c.HasWholeProgramVisibility = config->ltoWholeProgramVisibility;
c.TimeTraceEnabled = config->timeTraceEnabled;
c.TimeTraceGranularity = config->timeTraceGranularity;
c.CSIRProfile = std::string(config->ltoCSProfileFile);
c.RunCSIRInstr = config->ltoCSProfileGenerate;
if (config->emitLLVM) {
c.PostInternalizeModuleHook = [](size_t task, const Module &m) {
if (std::unique_ptr<raw_fd_ostream> os = openFile(config->outputFile))
WriteBitcodeToFile(m, *os, false);
return false;
};
}
if (config->saveTemps)
checkError(c.addSaveTemps(config->outputFile.str() + ".",
/*UseInputModulePath*/ true));
return c;
}
BitcodeCompiler::BitcodeCompiler() {
// Initialize indexFile.
if (!config->thinLTOIndexOnlyArg.empty())
indexFile = openFile(config->thinLTOIndexOnlyArg);
// Initialize ltoObj.
lto::ThinBackend backend;
if (config->thinLTOIndexOnly) {
auto onIndexWrite = [&](StringRef s) { thinIndices.erase(s); };
backend = lto::createWriteIndexesThinBackend(
std::string(config->thinLTOPrefixReplace.first),
std::string(config->thinLTOPrefixReplace.second),
config->thinLTOEmitImportsFiles, indexFile.get(), onIndexWrite);
} else {
backend = lto::createInProcessThinBackend(
llvm::heavyweight_hardware_concurrency(config->thinLTOJobs));
}
ltoObj = std::make_unique<lto::LTO>(createConfig(), backend,
config->ltoPartitions);
// Initialize usedStartStop.
for (Symbol *sym : symtab->symbols()) {
StringRef s = sym->getName();
for (StringRef prefix : {"__start_", "__stop_"})
if (s.startswith(prefix))
usedStartStop.insert(s.substr(prefix.size()));
}
}
BitcodeCompiler::~BitcodeCompiler() = default;
void BitcodeCompiler::add(BitcodeFile &f) {
lto::InputFile &obj = *f.obj;
bool isExec = !config->shared && !config->relocatable;
if (config->thinLTOIndexOnly)
thinIndices.insert(obj.getName());
ArrayRef<Symbol *> syms = f.getSymbols();
ArrayRef<lto::InputFile::Symbol> objSyms = obj.symbols();
std::vector<lto::SymbolResolution> resols(syms.size());
// Provide a resolution to the LTO API for each symbol.
for (size_t i = 0, e = syms.size(); i != e; ++i) {
Symbol *sym = syms[i];
const lto::InputFile::Symbol &objSym = objSyms[i];
lto::SymbolResolution &r = resols[i];
// Ideally we shouldn't check for SF_Undefined but currently IRObjectFile
// reports two symbols for module ASM defined. Without this check, lld
// flags an undefined in IR with a definition in ASM as prevailing.
// Once IRObjectFile is fixed to report only one symbol this hack can
// be removed.
r.Prevailing = !objSym.isUndefined() && sym->file == &f;
// We ask LTO to preserve following global symbols:
// 1) All symbols when doing relocatable link, so that them can be used
// for doing final link.
// 2) Symbols that are used in regular objects.
// 3) C named sections if we have corresponding __start_/__stop_ symbol.
// 4) Symbols that are defined in bitcode files and used for dynamic linking.
r.VisibleToRegularObj = config->relocatable || sym->isUsedInRegularObj ||
(r.Prevailing && sym->includeInDynsym()) ||
usedStartStop.count(objSym.getSectionName());
const auto *dr = dyn_cast<Defined>(sym);
r.FinalDefinitionInLinkageUnit =
(isExec || sym->visibility != STV_DEFAULT) && dr &&
// Skip absolute symbols from ELF objects, otherwise PC-rel relocations
// will be generated by for them, triggering linker errors.
// Symbol section is always null for bitcode symbols, hence the check
// for isElf(). Skip linker script defined symbols as well: they have
// no File defined.
!(dr->section == nullptr && (!sym->file || sym->file->isElf()));
if (r.Prevailing)
sym->replace(Undefined{nullptr, sym->getName(), STB_GLOBAL, STV_DEFAULT,
sym->type});
// We tell LTO to not apply interprocedural optimization for wrapped
// (with --wrap) symbols because otherwise LTO would inline them while
// their values are still not final.
r.LinkerRedefined = !sym->canInline;
}
checkError(ltoObj->add(std::move(f.obj), resols));
}
// If LazyObjFile has not been added to link, emit empty index files.
// This is needed because this is what GNU gold plugin does and we have a
// distributed build system that depends on that behavior.
static void thinLTOCreateEmptyIndexFiles() {
for (LazyObjFile *f : lazyObjFiles) {
if (!isBitcode(f->mb))
continue;
std::string path = replaceThinLTOSuffix(getThinLTOOutputFile(f->getName()));
std::unique_ptr<raw_fd_ostream> os = openFile(path + ".thinlto.bc");
if (!os)
continue;
ModuleSummaryIndex m(/*HaveGVs*/ false);
m.setSkipModuleByDistributedBackend();
WriteIndexToFile(m, *os);
if (config->thinLTOEmitImportsFiles)
openFile(path + ".imports");
}
}
// Merge all the bitcode files we have seen, codegen the result
// and return the resulting ObjectFile(s).
std::vector<InputFile *> BitcodeCompiler::compile() {
unsigned maxTasks = ltoObj->getMaxTasks();
buf.resize(maxTasks);
files.resize(maxTasks);
// The --thinlto-cache-dir option specifies the path to a directory in which
// to cache native object files for ThinLTO incremental builds. If a path was
// specified, configure LTO to use it as the cache directory.
lto::NativeObjectCache cache;
if (!config->thinLTOCacheDir.empty())
cache = check(
lto::localCache(config->thinLTOCacheDir,
[&](size_t task, std::unique_ptr<MemoryBuffer> mb) {
files[task] = std::move(mb);
}));
if (!bitcodeFiles.empty())
checkError(ltoObj->run(
[&](size_t task) {
return std::make_unique<lto::NativeObjectStream>(
std::make_unique<raw_svector_ostream>(buf[task]));
},
cache));
// Emit empty index files for non-indexed files
for (StringRef s : thinIndices) {
std::string path = getThinLTOOutputFile(s);
openFile(path + ".thinlto.bc");
if (config->thinLTOEmitImportsFiles)
openFile(path + ".imports");
}
if (config->thinLTOIndexOnly) {
thinLTOCreateEmptyIndexFiles();
if (!config->ltoObjPath.empty())
saveBuffer(buf[0], config->ltoObjPath);
// ThinLTO with index only option is required to generate only the index
// files. After that, we exit from linker and ThinLTO backend runs in a
// distributed environment.
if (indexFile)
indexFile->close();
return {};
}
if (!config->thinLTOCacheDir.empty())
pruneCache(config->thinLTOCacheDir, config->thinLTOCachePolicy);
if (!config->ltoObjPath.empty()) {
saveBuffer(buf[0], config->ltoObjPath);
for (unsigned i = 1; i != maxTasks; ++i)
saveBuffer(buf[i], config->ltoObjPath + Twine(i));
}
if (config->saveTemps) {
saveBuffer(buf[0], config->outputFile + ".lto.o");
for (unsigned i = 1; i != maxTasks; ++i)
saveBuffer(buf[i], config->outputFile + Twine(i) + ".lto.o");
}
std::vector<InputFile *> ret;
for (unsigned i = 0; i != maxTasks; ++i)
if (!buf[i].empty())
ret.push_back(createObjectFile(MemoryBufferRef(buf[i], "lto.tmp")));
for (std::unique_ptr<MemoryBuffer> &file : files)
if (file)
ret.push_back(createObjectFile(*file));
return ret;
}
} // namespace elf
} // namespace lld
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