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llvm-project/bolt/lib/Passes/SplitFunctions.cpp

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//===- bolt/Passes/SplitFunctions.cpp - Pass for splitting function code --===//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// This file implements the SplitFunctions pass.
//
//===----------------------------------------------------------------------===//
#include "bolt/Passes/SplitFunctions.h"
#include "bolt/Core/BinaryFunction.h"
#include "bolt/Core/ParallelUtilities.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/FormatVariadic.h"
#include <vector>
#define DEBUG_TYPE "bolt-opts"
using namespace llvm;
using namespace bolt;
namespace {
class DeprecatedSplitFunctionOptionParser : public cl::parser<bool> {
public:
explicit DeprecatedSplitFunctionOptionParser(cl::Option &O)
: cl::parser<bool>(O) {}
bool parse(cl::Option &O, StringRef ArgName, StringRef Arg, bool &Value) {
if (Arg == "2" || Arg == "3") {
Value = true;
errs() << formatv("BOLT-WARNING: specifying non-boolean value \"{0}\" "
"for option -{1} is deprecated\n",
Arg, ArgName);
return false;
}
return cl::parser<bool>::parse(O, ArgName, Arg, Value);
}
};
} // namespace
namespace opts {
extern cl::OptionCategory BoltOptCategory;
extern cl::opt<bool> SplitEH;
extern cl::opt<unsigned> ExecutionCountThreshold;
static cl::opt<bool> AggressiveSplitting(
"split-all-cold", cl::desc("outline as many cold basic blocks as possible"),
cl::cat(BoltOptCategory));
static cl::opt<unsigned> SplitAlignThreshold(
"split-align-threshold",
cl::desc("when deciding to split a function, apply this alignment "
"while doing the size comparison (see -split-threshold). "
"Default value: 2."),
cl::init(2),
cl::Hidden, cl::cat(BoltOptCategory));
static cl::opt<bool, false, DeprecatedSplitFunctionOptionParser>
SplitFunctions("split-functions",
cl::desc("split functions into hot and cold regions"),
cl::cat(BoltOptCategory));
static cl::opt<unsigned> SplitThreshold(
"split-threshold",
cl::desc("split function only if its main size is reduced by more than "
"given amount of bytes. Default value: 0, i.e. split iff the "
"size is reduced. Note that on some architectures the size can "
"increase after splitting."),
cl::init(0), cl::Hidden, cl::cat(BoltOptCategory));
} // namespace opts
namespace llvm {
namespace bolt {
bool SplitFunctions::shouldOptimize(const BinaryFunction &BF) const {
// Apply execution count threshold
if (BF.getKnownExecutionCount() < opts::ExecutionCountThreshold)
return false;
return BinaryFunctionPass::shouldOptimize(BF);
}
void SplitFunctions::runOnFunctions(BinaryContext &BC) {
if (!opts::SplitFunctions)
return;
ParallelUtilities::WorkFuncTy WorkFun = [&](BinaryFunction &BF) {
splitFunction(BF);
};
ParallelUtilities::PredicateTy SkipFunc = [&](const BinaryFunction &BF) {
return !shouldOptimize(BF);
};
ParallelUtilities::runOnEachFunction(
BC, ParallelUtilities::SchedulingPolicy::SP_BB_LINEAR, WorkFun, SkipFunc,
"SplitFunctions");
if (SplitBytesHot + SplitBytesCold > 0)
outs() << "BOLT-INFO: splitting separates " << SplitBytesHot
<< " hot bytes from " << SplitBytesCold << " cold bytes "
<< format("(%.2lf%% of split functions is hot).\n",
100.0 * SplitBytesHot / (SplitBytesHot + SplitBytesCold));
}
void SplitFunctions::splitFunction(BinaryFunction &BF) {
if (!BF.size())
return;
if (!BF.hasValidProfile())
return;
bool AllCold = true;
for (BinaryBasicBlock *BB : BF.layout()) {
const uint64_t ExecCount = BB->getExecutionCount();
if (ExecCount == BinaryBasicBlock::COUNT_NO_PROFILE)
return;
if (ExecCount != 0)
AllCold = false;
}
if (AllCold)
return;
BinaryFunction::BasicBlockOrderType PreSplitLayout = BF.getLayout();
BinaryContext &BC = BF.getBinaryContext();
size_t OriginalHotSize;
size_t HotSize;
size_t ColdSize;
if (BC.isX86()) {
std::tie(OriginalHotSize, ColdSize) = BC.calculateEmittedSize(BF);
LLVM_DEBUG(dbgs() << "Estimated size for function " << BF
<< " pre-split is <0x"
<< Twine::utohexstr(OriginalHotSize) << ", 0x"
<< Twine::utohexstr(ColdSize) << ">\n");
}
// Never outline the first basic block.
BF.layout_front()->setCanOutline(false);
for (BinaryBasicBlock *BB : BF.layout()) {
if (!BB->canOutline())
continue;
if (BB->getExecutionCount() != 0) {
BB->setCanOutline(false);
continue;
}
// Do not split extra entry points in aarch64. They can be referred by
// using ADRs and when this happens, these blocks cannot be placed far
// away due to the limited range in ADR instruction.
if (BC.isAArch64() && BB->isEntryPoint()) {
BB->setCanOutline(false);
continue;
}
if (BF.hasEHRanges() && !opts::SplitEH) {
// We cannot move landing pads (or rather entry points for landing pads).
if (BB->isLandingPad()) {
BB->setCanOutline(false);
continue;
}
// We cannot move a block that can throw since exception-handling
// runtime cannot deal with split functions. However, if we can guarantee
// that the block never throws, it is safe to move the block to
// decrease the size of the function.
for (MCInst &Instr : *BB) {
if (BC.MIB->isInvoke(Instr)) {
BB->setCanOutline(false);
break;
}
}
}
}
if (opts::AggressiveSplitting) {
// All blocks with 0 count that we can move go to the end of the function.
// Even if they were natural to cluster formation and were seen in-between
// hot basic blocks.
llvm::stable_sort(BF.layout(),
[&](BinaryBasicBlock *A, BinaryBasicBlock *B) {
return A->canOutline() < B->canOutline();
});
} else if (BF.hasEHRanges() && !opts::SplitEH) {
// Typically functions with exception handling have landing pads at the end.
// We cannot move beginning of landing pads, but we can move 0-count blocks
// comprising landing pads to the end and thus facilitate splitting.
auto FirstLP = BF.layout_begin();
while ((*FirstLP)->isLandingPad())
++FirstLP;
std::stable_sort(FirstLP, BF.layout_end(),
[&](BinaryBasicBlock *A, BinaryBasicBlock *B) {
return A->canOutline() < B->canOutline();
});
}
// Separate hot from cold starting from the bottom.
for (auto I = BF.layout_rbegin(), E = BF.layout_rend(); I != E; ++I) {
BinaryBasicBlock *BB = *I;
if (!BB->canOutline())
break;
BB->setIsCold(true);
}
// For shared objects, place invoke instructions and corresponding landing
// pads in the same fragment. To reduce hot code size, create trampoline
// landing pads that will redirect the execution to the real LP.
if (!BC.HasFixedLoadAddress && BF.hasEHRanges() && BF.isSplit())
createEHTrampolines(BF);
// Check the new size to see if it's worth splitting the function.
if (BC.isX86() && BF.isSplit()) {
std::tie(HotSize, ColdSize) = BC.calculateEmittedSize(BF);
LLVM_DEBUG(dbgs() << "Estimated size for function " << BF
<< " post-split is <0x" << Twine::utohexstr(HotSize)
<< ", 0x" << Twine::utohexstr(ColdSize) << ">\n");
if (alignTo(OriginalHotSize, opts::SplitAlignThreshold) <=
alignTo(HotSize, opts::SplitAlignThreshold) + opts::SplitThreshold) {
LLVM_DEBUG(dbgs() << "Reversing splitting of function " << BF << ":\n 0x"
<< Twine::utohexstr(HotSize) << ", 0x"
<< Twine::utohexstr(ColdSize) << " -> 0x"
<< Twine::utohexstr(OriginalHotSize) << '\n');
BF.updateBasicBlockLayout(PreSplitLayout);
for (BinaryBasicBlock &BB : BF)
BB.setIsCold(false);
} else {
SplitBytesHot += HotSize;
SplitBytesCold += ColdSize;
}
}
}
void SplitFunctions::createEHTrampolines(BinaryFunction &BF) const {
const auto &MIB = BF.getBinaryContext().MIB;
// Map real landing pads to the corresponding trampolines.
std::unordered_map<const MCSymbol *, const MCSymbol *> LPTrampolines;
// Iterate over the copy of basic blocks since we are adding new blocks to the
// function which will invalidate its iterators.
std::vector<BinaryBasicBlock *> Blocks(BF.pbegin(), BF.pend());
for (BinaryBasicBlock *BB : Blocks) {
for (MCInst &Instr : *BB) {
const Optional<MCPlus::MCLandingPad> EHInfo = MIB->getEHInfo(Instr);
if (!EHInfo || !EHInfo->first)
continue;
const MCSymbol *LPLabel = EHInfo->first;
BinaryBasicBlock *LPBlock = BF.getBasicBlockForLabel(LPLabel);
if (BB->isCold() == LPBlock->isCold())
continue;
const MCSymbol *TrampolineLabel = nullptr;
auto Iter = LPTrampolines.find(LPLabel);
if (Iter != LPTrampolines.end()) {
TrampolineLabel = Iter->second;
} else {
// Create a trampoline basic block in the same fragment as the thrower.
// Note: there's no need to insert the jump instruction, it will be
// added by fixBranches().
BinaryBasicBlock *TrampolineBB = BF.addBasicBlock();
TrampolineBB->setIsCold(BB->isCold());
TrampolineBB->setExecutionCount(LPBlock->getExecutionCount());
TrampolineBB->addSuccessor(LPBlock, TrampolineBB->getExecutionCount());
TrampolineBB->setCFIState(LPBlock->getCFIState());
TrampolineLabel = TrampolineBB->getLabel();
LPTrampolines.emplace(std::make_pair(LPLabel, TrampolineLabel));
}
// Substitute the landing pad with the trampoline.
MIB->updateEHInfo(Instr,
MCPlus::MCLandingPad(TrampolineLabel, EHInfo->second));
}
}
if (LPTrampolines.empty())
return;
// All trampoline blocks were added to the end of the function. Place them at
// the end of corresponding fragments.
std::stable_sort(BF.layout_begin(), BF.layout_end(),
[&](BinaryBasicBlock *A, BinaryBasicBlock *B) {
return A->isCold() < B->isCold();
});
// Conservatively introduce branch instructions.
BF.fixBranches();
// Update exception-handling CFG for the function.
BF.recomputeLandingPads();
}
} // namespace bolt
} // namespace llvm
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