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llvm-mirror/lib/Transforms/IPO/IROutliner.cpp
Andrew Litteken 48bef97e44 [IROutliner] Adding DebugInfo handling for IR Outlined Functions
This adds support for functions outlined by the IR Outliner to be
recognized by the debugger.  The expected behavior is that it will
skip over the instructions included in that section.  This is due to the
fact that we can not say which of the original locations the
instructions originated from.

These functions will show up in the call stack, but you cannot step
through them.

Reviewers: paquette, vsk, djtodoro

Differential Revision: https://reviews.llvm.org/D87302
2021-06-15 10:57:08 -05:00

1842 lines
73 KiB
C++

//===- IROutliner.cpp -- Outline Similar Regions ----------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
///
/// \file
// Implementation for the IROutliner which is used by the IROutliner Pass.
//
//===----------------------------------------------------------------------===//
#include "llvm/Transforms/IPO/IROutliner.h"
#include "llvm/Analysis/IRSimilarityIdentifier.h"
#include "llvm/Analysis/OptimizationRemarkEmitter.h"
#include "llvm/Analysis/TargetTransformInfo.h"
#include "llvm/IR/Attributes.h"
#include "llvm/IR/DebugInfoMetadata.h"
#include "llvm/IR/DIBuilder.h"
#include "llvm/IR/Mangler.h"
#include "llvm/IR/PassManager.h"
#include "llvm/InitializePasses.h"
#include "llvm/Pass.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Transforms/IPO.h"
#include <map>
#include <set>
#include <vector>
#define DEBUG_TYPE "iroutliner"
using namespace llvm;
using namespace IRSimilarity;
// Set to true if the user wants the ir outliner to run on linkonceodr linkage
// functions. This is false by default because the linker can dedupe linkonceodr
// functions. Since the outliner is confined to a single module (modulo LTO),
// this is off by default. It should, however, be the default behavior in
// LTO.
static cl::opt<bool> EnableLinkOnceODRIROutlining(
"enable-linkonceodr-ir-outlining", cl::Hidden,
cl::desc("Enable the IR outliner on linkonceodr functions"),
cl::init(false));
// This is a debug option to test small pieces of code to ensure that outlining
// works correctly.
static cl::opt<bool> NoCostModel(
"ir-outlining-no-cost", cl::init(false), cl::ReallyHidden,
cl::desc("Debug option to outline greedily, without restriction that "
"calculated benefit outweighs cost"));
/// The OutlinableGroup holds all the overarching information for outlining
/// a set of regions that are structurally similar to one another, such as the
/// types of the overall function, the output blocks, the sets of stores needed
/// and a list of the different regions. This information is used in the
/// deduplication of extracted regions with the same structure.
struct OutlinableGroup {
/// The sections that could be outlined
std::vector<OutlinableRegion *> Regions;
/// The argument types for the function created as the overall function to
/// replace the extracted function for each region.
std::vector<Type *> ArgumentTypes;
/// The FunctionType for the overall function.
FunctionType *OutlinedFunctionType = nullptr;
/// The Function for the collective overall function.
Function *OutlinedFunction = nullptr;
/// Flag for whether we should not consider this group of OutlinableRegions
/// for extraction.
bool IgnoreGroup = false;
/// The return block for the overall function.
BasicBlock *EndBB = nullptr;
/// A set containing the different GVN store sets needed. Each array contains
/// a sorted list of the different values that need to be stored into output
/// registers.
DenseSet<ArrayRef<unsigned>> OutputGVNCombinations;
/// Flag for whether the \ref ArgumentTypes have been defined after the
/// extraction of the first region.
bool InputTypesSet = false;
/// The number of input values in \ref ArgumentTypes. Anything after this
/// index in ArgumentTypes is an output argument.
unsigned NumAggregateInputs = 0;
/// The number of instructions that will be outlined by extracting \ref
/// Regions.
InstructionCost Benefit = 0;
/// The number of added instructions needed for the outlining of the \ref
/// Regions.
InstructionCost Cost = 0;
/// The argument that needs to be marked with the swifterr attribute. If not
/// needed, there is no value.
Optional<unsigned> SwiftErrorArgument;
/// For the \ref Regions, we look at every Value. If it is a constant,
/// we check whether it is the same in Region.
///
/// \param [in,out] NotSame contains the global value numbers where the
/// constant is not always the same, and must be passed in as an argument.
void findSameConstants(DenseSet<unsigned> &NotSame);
/// For the regions, look at each set of GVN stores needed and account for
/// each combination. Add an argument to the argument types if there is
/// more than one combination.
///
/// \param [in] M - The module we are outlining from.
void collectGVNStoreSets(Module &M);
};
/// Move the contents of \p SourceBB to before the last instruction of \p
/// TargetBB.
/// \param SourceBB - the BasicBlock to pull Instructions from.
/// \param TargetBB - the BasicBlock to put Instruction into.
static void moveBBContents(BasicBlock &SourceBB, BasicBlock &TargetBB) {
BasicBlock::iterator BBCurr, BBEnd, BBNext;
for (BBCurr = SourceBB.begin(), BBEnd = SourceBB.end(); BBCurr != BBEnd;
BBCurr = BBNext) {
BBNext = std::next(BBCurr);
BBCurr->moveBefore(TargetBB, TargetBB.end());
}
}
void OutlinableRegion::splitCandidate() {
assert(!CandidateSplit && "Candidate already split!");
Instruction *StartInst = (*Candidate->begin()).Inst;
Instruction *EndInst = (*Candidate->end()).Inst;
assert(StartInst && EndInst && "Expected a start and end instruction?");
StartBB = StartInst->getParent();
PrevBB = StartBB;
// The basic block gets split like so:
// block: block:
// inst1 inst1
// inst2 inst2
// region1 br block_to_outline
// region2 block_to_outline:
// region3 -> region1
// region4 region2
// inst3 region3
// inst4 region4
// br block_after_outline
// block_after_outline:
// inst3
// inst4
std::string OriginalName = PrevBB->getName().str();
StartBB = PrevBB->splitBasicBlock(StartInst, OriginalName + "_to_outline");
// This is the case for the inner block since we do not have to include
// multiple blocks.
EndBB = StartBB;
FollowBB = EndBB->splitBasicBlock(EndInst, OriginalName + "_after_outline");
CandidateSplit = true;
}
void OutlinableRegion::reattachCandidate() {
assert(CandidateSplit && "Candidate is not split!");
// The basic block gets reattached like so:
// block: block:
// inst1 inst1
// inst2 inst2
// br block_to_outline region1
// block_to_outline: -> region2
// region1 region3
// region2 region4
// region3 inst3
// region4 inst4
// br block_after_outline
// block_after_outline:
// inst3
// inst4
assert(StartBB != nullptr && "StartBB for Candidate is not defined!");
assert(FollowBB != nullptr && "StartBB for Candidate is not defined!");
// StartBB should only have one predecessor since we put an unconditional
// branch at the end of PrevBB when we split the BasicBlock.
PrevBB = StartBB->getSinglePredecessor();
assert(PrevBB != nullptr &&
"No Predecessor for the region start basic block!");
assert(PrevBB->getTerminator() && "Terminator removed from PrevBB!");
assert(EndBB->getTerminator() && "Terminator removed from EndBB!");
PrevBB->getTerminator()->eraseFromParent();
EndBB->getTerminator()->eraseFromParent();
moveBBContents(*StartBB, *PrevBB);
BasicBlock *PlacementBB = PrevBB;
if (StartBB != EndBB)
PlacementBB = EndBB;
moveBBContents(*FollowBB, *PlacementBB);
PrevBB->replaceSuccessorsPhiUsesWith(StartBB, PrevBB);
PrevBB->replaceSuccessorsPhiUsesWith(FollowBB, PlacementBB);
StartBB->eraseFromParent();
FollowBB->eraseFromParent();
// Make sure to save changes back to the StartBB.
StartBB = PrevBB;
EndBB = nullptr;
PrevBB = nullptr;
FollowBB = nullptr;
CandidateSplit = false;
}
/// Find whether \p V matches the Constants previously found for the \p GVN.
///
/// \param V - The value to check for consistency.
/// \param GVN - The global value number assigned to \p V.
/// \param GVNToConstant - The mapping of global value number to Constants.
/// \returns true if the Value matches the Constant mapped to by V and false if
/// it \p V is a Constant but does not match.
/// \returns None if \p V is not a Constant.
static Optional<bool>
constantMatches(Value *V, unsigned GVN,
DenseMap<unsigned, Constant *> &GVNToConstant) {
// See if we have a constants
Constant *CST = dyn_cast<Constant>(V);
if (!CST)
return None;
// Holds a mapping from a global value number to a Constant.
DenseMap<unsigned, Constant *>::iterator GVNToConstantIt;
bool Inserted;
// If we have a constant, try to make a new entry in the GVNToConstant.
std::tie(GVNToConstantIt, Inserted) =
GVNToConstant.insert(std::make_pair(GVN, CST));
// If it was found and is not equal, it is not the same. We do not
// handle this case yet, and exit early.
if (Inserted || (GVNToConstantIt->second == CST))
return true;
return false;
}
InstructionCost OutlinableRegion::getBenefit(TargetTransformInfo &TTI) {
InstructionCost Benefit = 0;
// Estimate the benefit of outlining a specific sections of the program. We
// delegate mostly this task to the TargetTransformInfo so that if the target
// has specific changes, we can have a more accurate estimate.
// However, getInstructionCost delegates the code size calculation for
// arithmetic instructions to getArithmeticInstrCost in
// include/Analysis/TargetTransformImpl.h, where it always estimates that the
// code size for a division and remainder instruction to be equal to 4, and
// everything else to 1. This is not an accurate representation of the
// division instruction for targets that have a native division instruction.
// To be overly conservative, we only add 1 to the number of instructions for
// each division instruction.
for (Instruction &I : *StartBB) {
switch (I.getOpcode()) {
case Instruction::FDiv:
case Instruction::FRem:
case Instruction::SDiv:
case Instruction::SRem:
case Instruction::UDiv:
case Instruction::URem:
Benefit += 1;
break;
default:
Benefit += TTI.getInstructionCost(&I, TargetTransformInfo::TCK_CodeSize);
break;
}
}
return Benefit;
}
/// Find whether \p Region matches the global value numbering to Constant
/// mapping found so far.
///
/// \param Region - The OutlinableRegion we are checking for constants
/// \param GVNToConstant - The mapping of global value number to Constants.
/// \param NotSame - The set of global value numbers that do not have the same
/// constant in each region.
/// \returns true if all Constants are the same in every use of a Constant in \p
/// Region and false if not
static bool
collectRegionsConstants(OutlinableRegion &Region,
DenseMap<unsigned, Constant *> &GVNToConstant,
DenseSet<unsigned> &NotSame) {
bool ConstantsTheSame = true;
IRSimilarityCandidate &C = *Region.Candidate;
for (IRInstructionData &ID : C) {
// Iterate over the operands in an instruction. If the global value number,
// assigned by the IRSimilarityCandidate, has been seen before, we check if
// the the number has been found to be not the same value in each instance.
for (Value *V : ID.OperVals) {
Optional<unsigned> GVNOpt = C.getGVN(V);
assert(GVNOpt.hasValue() && "Expected a GVN for operand?");
unsigned GVN = GVNOpt.getValue();
// Check if this global value has been found to not be the same already.
if (NotSame.contains(GVN)) {
if (isa<Constant>(V))
ConstantsTheSame = false;
continue;
}
// If it has been the same so far, we check the value for if the
// associated Constant value match the previous instances of the same
// global value number. If the global value does not map to a Constant,
// it is considered to not be the same value.
Optional<bool> ConstantMatches = constantMatches(V, GVN, GVNToConstant);
if (ConstantMatches.hasValue()) {
if (ConstantMatches.getValue())
continue;
else
ConstantsTheSame = false;
}
// While this value is a register, it might not have been previously,
// make sure we don't already have a constant mapped to this global value
// number.
if (GVNToConstant.find(GVN) != GVNToConstant.end())
ConstantsTheSame = false;
NotSame.insert(GVN);
}
}
return ConstantsTheSame;
}
void OutlinableGroup::findSameConstants(DenseSet<unsigned> &NotSame) {
DenseMap<unsigned, Constant *> GVNToConstant;
for (OutlinableRegion *Region : Regions)
collectRegionsConstants(*Region, GVNToConstant, NotSame);
}
void OutlinableGroup::collectGVNStoreSets(Module &M) {
for (OutlinableRegion *OS : Regions)
OutputGVNCombinations.insert(OS->GVNStores);
// We are adding an extracted argument to decide between which output path
// to use in the basic block. It is used in a switch statement and only
// needs to be an integer.
if (OutputGVNCombinations.size() > 1)
ArgumentTypes.push_back(Type::getInt32Ty(M.getContext()));
}
/// Get the subprogram if it exists for one of the outlined regions.
///
/// \param [in] Group - The set of regions to find a subprogram for.
/// \returns the subprogram if it exists, or nullptr.
static DISubprogram *getSubprogramOrNull(OutlinableGroup &Group) {
for (OutlinableRegion *OS : Group.Regions)
if (Function *F = OS->Call->getFunction())
if (DISubprogram *SP = F->getSubprogram())
return SP;
return nullptr;
}
Function *IROutliner::createFunction(Module &M, OutlinableGroup &Group,
unsigned FunctionNameSuffix) {
assert(!Group.OutlinedFunction && "Function is already defined!");
Group.OutlinedFunctionType = FunctionType::get(
Type::getVoidTy(M.getContext()), Group.ArgumentTypes, false);
// These functions will only be called from within the same module, so
// we can set an internal linkage.
Group.OutlinedFunction = Function::Create(
Group.OutlinedFunctionType, GlobalValue::InternalLinkage,
"outlined_ir_func_" + std::to_string(FunctionNameSuffix), M);
// Transfer the swifterr attribute to the correct function parameter.
if (Group.SwiftErrorArgument.hasValue())
Group.OutlinedFunction->addParamAttr(Group.SwiftErrorArgument.getValue(),
Attribute::SwiftError);
Group.OutlinedFunction->addFnAttr(Attribute::OptimizeForSize);
Group.OutlinedFunction->addFnAttr(Attribute::MinSize);
// If there's a DISubprogram associated with this outlined function, then
// emit debug info for the outlined function.
if (DISubprogram *SP = getSubprogramOrNull(Group)) {
Function *F = Group.OutlinedFunction;
// We have a DISubprogram. Get its DICompileUnit.
DICompileUnit *CU = SP->getUnit();
DIBuilder DB(M, true, CU);
DIFile *Unit = SP->getFile();
Mangler Mg;
// Get the mangled name of the function for the linkage name.
std::string Dummy;
llvm::raw_string_ostream MangledNameStream(Dummy);
Mg.getNameWithPrefix(MangledNameStream, F, false);
DISubprogram *OutlinedSP = DB.createFunction(
Unit /* Context */, F->getName(), MangledNameStream.str(),
Unit /* File */,
0 /* Line 0 is reserved for compiler-generated code. */,
DB.createSubroutineType(DB.getOrCreateTypeArray(None)), /* void type */
0, /* Line 0 is reserved for compiler-generated code. */
DINode::DIFlags::FlagArtificial /* Compiler-generated code. */,
/* Outlined code is optimized code by definition. */
DISubprogram::SPFlagDefinition | DISubprogram::SPFlagOptimized);
// Don't add any new variables to the subprogram.
DB.finalizeSubprogram(OutlinedSP);
// Attach subprogram to the function.
F->setSubprogram(OutlinedSP);
// We're done with the DIBuilder.
DB.finalize();
}
return Group.OutlinedFunction;
}
/// Move each BasicBlock in \p Old to \p New.
///
/// \param [in] Old - The function to move the basic blocks from.
/// \param [in] New - The function to move the basic blocks to.
/// \returns the first return block for the function in New.
static BasicBlock *moveFunctionData(Function &Old, Function &New) {
Function::iterator CurrBB, NextBB, FinalBB;
BasicBlock *NewEnd = nullptr;
std::vector<Instruction *> DebugInsts;
for (CurrBB = Old.begin(), FinalBB = Old.end(); CurrBB != FinalBB;
CurrBB = NextBB) {
NextBB = std::next(CurrBB);
CurrBB->removeFromParent();
CurrBB->insertInto(&New);
Instruction *I = CurrBB->getTerminator();
if (isa<ReturnInst>(I))
NewEnd = &(*CurrBB);
for (Instruction &Val : *CurrBB) {
// We must handle the scoping of called functions differently than
// other outlined instructions.
if (!isa<CallInst>(&Val)) {
// Remove the debug information for outlined functions.
Val.setDebugLoc(DebugLoc());
continue;
}
// From this point we are only handling call instructions.
CallInst *CI = cast<CallInst>(&Val);
// We add any debug statements here, to be removed after. Since the
// instructions originate from many different locations in the program,
// it will cause incorrect reporting from a debugger if we keep the
// same debug instructions.
if (isa<DbgInfoIntrinsic>(CI)) {
DebugInsts.push_back(&Val);
continue;
}
// Edit the scope of called functions inside of outlined functions.
if (DISubprogram *SP = New.getSubprogram()) {
DILocation *DI = DILocation::get(New.getContext(), 0, 0, SP);
Val.setDebugLoc(DI);
}
}
for (Instruction *I : DebugInsts)
I->eraseFromParent();
}
assert(NewEnd && "No return instruction for new function?");
return NewEnd;
}
/// Find the the constants that will need to be lifted into arguments
/// as they are not the same in each instance of the region.
///
/// \param [in] C - The IRSimilarityCandidate containing the region we are
/// analyzing.
/// \param [in] NotSame - The set of global value numbers that do not have a
/// single Constant across all OutlinableRegions similar to \p C.
/// \param [out] Inputs - The list containing the global value numbers of the
/// arguments needed for the region of code.
static void findConstants(IRSimilarityCandidate &C, DenseSet<unsigned> &NotSame,
std::vector<unsigned> &Inputs) {
DenseSet<unsigned> Seen;
// Iterate over the instructions, and find what constants will need to be
// extracted into arguments.
for (IRInstructionDataList::iterator IDIt = C.begin(), EndIDIt = C.end();
IDIt != EndIDIt; IDIt++) {
for (Value *V : (*IDIt).OperVals) {
// Since these are stored before any outlining, they will be in the
// global value numbering.
unsigned GVN = C.getGVN(V).getValue();
if (isa<Constant>(V))
if (NotSame.contains(GVN) && !Seen.contains(GVN)) {
Inputs.push_back(GVN);
Seen.insert(GVN);
}
}
}
}
/// Find the GVN for the inputs that have been found by the CodeExtractor.
///
/// \param [in] C - The IRSimilarityCandidate containing the region we are
/// analyzing.
/// \param [in] CurrentInputs - The set of inputs found by the
/// CodeExtractor.
/// \param [in] OutputMappings - The mapping of values that have been replaced
/// by a new output value.
/// \param [out] EndInputNumbers - The global value numbers for the extracted
/// arguments.
static void mapInputsToGVNs(IRSimilarityCandidate &C,
SetVector<Value *> &CurrentInputs,
const DenseMap<Value *, Value *> &OutputMappings,
std::vector<unsigned> &EndInputNumbers) {
// Get the Global Value Number for each input. We check if the Value has been
// replaced by a different value at output, and use the original value before
// replacement.
for (Value *Input : CurrentInputs) {
assert(Input && "Have a nullptr as an input");
if (OutputMappings.find(Input) != OutputMappings.end())
Input = OutputMappings.find(Input)->second;
assert(C.getGVN(Input).hasValue() &&
"Could not find a numbering for the given input");
EndInputNumbers.push_back(C.getGVN(Input).getValue());
}
}
/// Find the original value for the \p ArgInput values if any one of them was
/// replaced during a previous extraction.
///
/// \param [in] ArgInputs - The inputs to be extracted by the code extractor.
/// \param [in] OutputMappings - The mapping of values that have been replaced
/// by a new output value.
/// \param [out] RemappedArgInputs - The remapped values according to
/// \p OutputMappings that will be extracted.
static void
remapExtractedInputs(const ArrayRef<Value *> ArgInputs,
const DenseMap<Value *, Value *> &OutputMappings,
SetVector<Value *> &RemappedArgInputs) {
// Get the global value number for each input that will be extracted as an
// argument by the code extractor, remapping if needed for reloaded values.
for (Value *Input : ArgInputs) {
if (OutputMappings.find(Input) != OutputMappings.end())
Input = OutputMappings.find(Input)->second;
RemappedArgInputs.insert(Input);
}
}
/// Find the input GVNs and the output values for a region of Instructions.
/// Using the code extractor, we collect the inputs to the extracted function.
///
/// The \p Region can be identified as needing to be ignored in this function.
/// It should be checked whether it should be ignored after a call to this
/// function.
///
/// \param [in,out] Region - The region of code to be analyzed.
/// \param [out] InputGVNs - The global value numbers for the extracted
/// arguments.
/// \param [in] NotSame - The global value numbers in the region that do not
/// have the same constant value in the regions structurally similar to
/// \p Region.
/// \param [in] OutputMappings - The mapping of values that have been replaced
/// by a new output value after extraction.
/// \param [out] ArgInputs - The values of the inputs to the extracted function.
/// \param [out] Outputs - The set of values extracted by the CodeExtractor
/// as outputs.
static void getCodeExtractorArguments(
OutlinableRegion &Region, std::vector<unsigned> &InputGVNs,
DenseSet<unsigned> &NotSame, DenseMap<Value *, Value *> &OutputMappings,
SetVector<Value *> &ArgInputs, SetVector<Value *> &Outputs) {
IRSimilarityCandidate &C = *Region.Candidate;
// OverallInputs are the inputs to the region found by the CodeExtractor,
// SinkCands and HoistCands are used by the CodeExtractor to find sunken
// allocas of values whose lifetimes are contained completely within the
// outlined region. PremappedInputs are the arguments found by the
// CodeExtractor, removing conditions such as sunken allocas, but that
// may need to be remapped due to the extracted output values replacing
// the original values. We use DummyOutputs for this first run of finding
// inputs and outputs since the outputs could change during findAllocas,
// the correct set of extracted outputs will be in the final Outputs ValueSet.
SetVector<Value *> OverallInputs, PremappedInputs, SinkCands, HoistCands,
DummyOutputs;
// Use the code extractor to get the inputs and outputs, without sunken
// allocas or removing llvm.assumes.
CodeExtractor *CE = Region.CE;
CE->findInputsOutputs(OverallInputs, DummyOutputs, SinkCands);
assert(Region.StartBB && "Region must have a start BasicBlock!");
Function *OrigF = Region.StartBB->getParent();
CodeExtractorAnalysisCache CEAC(*OrigF);
BasicBlock *Dummy = nullptr;
// The region may be ineligible due to VarArgs in the parent function. In this
// case we ignore the region.
if (!CE->isEligible()) {
Region.IgnoreRegion = true;
return;
}
// Find if any values are going to be sunk into the function when extracted
CE->findAllocas(CEAC, SinkCands, HoistCands, Dummy);
CE->findInputsOutputs(PremappedInputs, Outputs, SinkCands);
// TODO: Support regions with sunken allocas: values whose lifetimes are
// contained completely within the outlined region. These are not guaranteed
// to be the same in every region, so we must elevate them all to arguments
// when they appear. If these values are not equal, it means there is some
// Input in OverallInputs that was removed for ArgInputs.
if (OverallInputs.size() != PremappedInputs.size()) {
Region.IgnoreRegion = true;
return;
}
findConstants(C, NotSame, InputGVNs);
mapInputsToGVNs(C, OverallInputs, OutputMappings, InputGVNs);
remapExtractedInputs(PremappedInputs.getArrayRef(), OutputMappings,
ArgInputs);
// Sort the GVNs, since we now have constants included in the \ref InputGVNs
// we need to make sure they are in a deterministic order.
stable_sort(InputGVNs);
}
/// Look over the inputs and map each input argument to an argument in the
/// overall function for the OutlinableRegions. This creates a way to replace
/// the arguments of the extracted function with the arguments of the new
/// overall function.
///
/// \param [in,out] Region - The region of code to be analyzed.
/// \param [in] InputGVNs - The global value numbering of the input values
/// collected.
/// \param [in] ArgInputs - The values of the arguments to the extracted
/// function.
static void
findExtractedInputToOverallInputMapping(OutlinableRegion &Region,
std::vector<unsigned> &InputGVNs,
SetVector<Value *> &ArgInputs) {
IRSimilarityCandidate &C = *Region.Candidate;
OutlinableGroup &Group = *Region.Parent;
// This counts the argument number in the overall function.
unsigned TypeIndex = 0;
// This counts the argument number in the extracted function.
unsigned OriginalIndex = 0;
// Find the mapping of the extracted arguments to the arguments for the
// overall function. Since there may be extra arguments in the overall
// function to account for the extracted constants, we have two different
// counters as we find extracted arguments, and as we come across overall
// arguments.
for (unsigned InputVal : InputGVNs) {
Optional<Value *> InputOpt = C.fromGVN(InputVal);
assert(InputOpt.hasValue() && "Global value number not found?");
Value *Input = InputOpt.getValue();
if (!Group.InputTypesSet) {
Group.ArgumentTypes.push_back(Input->getType());
// If the input value has a swifterr attribute, make sure to mark the
// argument in the overall function.
if (Input->isSwiftError()) {
assert(
!Group.SwiftErrorArgument.hasValue() &&
"Argument already marked with swifterr for this OutlinableGroup!");
Group.SwiftErrorArgument = TypeIndex;
}
}
// Check if we have a constant. If we do add it to the overall argument
// number to Constant map for the region, and continue to the next input.
if (Constant *CST = dyn_cast<Constant>(Input)) {
Region.AggArgToConstant.insert(std::make_pair(TypeIndex, CST));
TypeIndex++;
continue;
}
// It is not a constant, we create the mapping from extracted argument list
// to the overall argument list.
assert(ArgInputs.count(Input) && "Input cannot be found!");
Region.ExtractedArgToAgg.insert(std::make_pair(OriginalIndex, TypeIndex));
Region.AggArgToExtracted.insert(std::make_pair(TypeIndex, OriginalIndex));
OriginalIndex++;
TypeIndex++;
}
// If the function type definitions for the OutlinableGroup holding the region
// have not been set, set the length of the inputs here. We should have the
// same inputs for all of the different regions contained in the
// OutlinableGroup since they are all structurally similar to one another.
if (!Group.InputTypesSet) {
Group.NumAggregateInputs = TypeIndex;
Group.InputTypesSet = true;
}
Region.NumExtractedInputs = OriginalIndex;
}
/// Create a mapping of the output arguments for the \p Region to the output
/// arguments of the overall outlined function.
///
/// \param [in,out] Region - The region of code to be analyzed.
/// \param [in] Outputs - The values found by the code extractor.
static void
findExtractedOutputToOverallOutputMapping(OutlinableRegion &Region,
ArrayRef<Value *> Outputs) {
OutlinableGroup &Group = *Region.Parent;
IRSimilarityCandidate &C = *Region.Candidate;
// This counts the argument number in the extracted function.
unsigned OriginalIndex = Region.NumExtractedInputs;
// This counts the argument number in the overall function.
unsigned TypeIndex = Group.NumAggregateInputs;
bool TypeFound;
DenseSet<unsigned> AggArgsUsed;
// Iterate over the output types and identify if there is an aggregate pointer
// type whose base type matches the current output type. If there is, we mark
// that we will use this output register for this value. If not we add another
// type to the overall argument type list. We also store the GVNs used for
// stores to identify which values will need to be moved into an special
// block that holds the stores to the output registers.
for (Value *Output : Outputs) {
TypeFound = false;
// We can do this since it is a result value, and will have a number
// that is necessarily the same. BUT if in the future, the instructions
// do not have to be in same order, but are functionally the same, we will
// have to use a different scheme, as one-to-one correspondence is not
// guaranteed.
unsigned GlobalValue = C.getGVN(Output).getValue();
unsigned ArgumentSize = Group.ArgumentTypes.size();
for (unsigned Jdx = TypeIndex; Jdx < ArgumentSize; Jdx++) {
if (Group.ArgumentTypes[Jdx] != PointerType::getUnqual(Output->getType()))
continue;
if (AggArgsUsed.contains(Jdx))
continue;
TypeFound = true;
AggArgsUsed.insert(Jdx);
Region.ExtractedArgToAgg.insert(std::make_pair(OriginalIndex, Jdx));
Region.AggArgToExtracted.insert(std::make_pair(Jdx, OriginalIndex));
Region.GVNStores.push_back(GlobalValue);
break;
}
// We were unable to find an unused type in the output type set that matches
// the output, so we add a pointer type to the argument types of the overall
// function to handle this output and create a mapping to it.
if (!TypeFound) {
Group.ArgumentTypes.push_back(PointerType::getUnqual(Output->getType()));
AggArgsUsed.insert(Group.ArgumentTypes.size() - 1);
Region.ExtractedArgToAgg.insert(
std::make_pair(OriginalIndex, Group.ArgumentTypes.size() - 1));
Region.AggArgToExtracted.insert(
std::make_pair(Group.ArgumentTypes.size() - 1, OriginalIndex));
Region.GVNStores.push_back(GlobalValue);
}
stable_sort(Region.GVNStores);
OriginalIndex++;
TypeIndex++;
}
}
void IROutliner::findAddInputsOutputs(Module &M, OutlinableRegion &Region,
DenseSet<unsigned> &NotSame) {
std::vector<unsigned> Inputs;
SetVector<Value *> ArgInputs, Outputs;
getCodeExtractorArguments(Region, Inputs, NotSame, OutputMappings, ArgInputs,
Outputs);
if (Region.IgnoreRegion)
return;
// Map the inputs found by the CodeExtractor to the arguments found for
// the overall function.
findExtractedInputToOverallInputMapping(Region, Inputs, ArgInputs);
// Map the outputs found by the CodeExtractor to the arguments found for
// the overall function.
findExtractedOutputToOverallOutputMapping(Region, Outputs.getArrayRef());
}
/// Replace the extracted function in the Region with a call to the overall
/// function constructed from the deduplicated similar regions, replacing and
/// remapping the values passed to the extracted function as arguments to the
/// new arguments of the overall function.
///
/// \param [in] M - The module to outline from.
/// \param [in] Region - The regions of extracted code to be replaced with a new
/// function.
/// \returns a call instruction with the replaced function.
CallInst *replaceCalledFunction(Module &M, OutlinableRegion &Region) {
std::vector<Value *> NewCallArgs;
DenseMap<unsigned, unsigned>::iterator ArgPair;
OutlinableGroup &Group = *Region.Parent;
CallInst *Call = Region.Call;
assert(Call && "Call to replace is nullptr?");
Function *AggFunc = Group.OutlinedFunction;
assert(AggFunc && "Function to replace with is nullptr?");
// If the arguments are the same size, there are not values that need to be
// made argument, or different output registers to handle. We can simply
// replace the called function in this case.
if (AggFunc->arg_size() == Call->arg_size()) {
LLVM_DEBUG(dbgs() << "Replace call to " << *Call << " with call to "
<< *AggFunc << " with same number of arguments\n");
Call->setCalledFunction(AggFunc);
return Call;
}
// We have a different number of arguments than the new function, so
// we need to use our previously mappings off extracted argument to overall
// function argument, and constants to overall function argument to create the
// new argument list.
for (unsigned AggArgIdx = 0; AggArgIdx < AggFunc->arg_size(); AggArgIdx++) {
if (AggArgIdx == AggFunc->arg_size() - 1 &&
Group.OutputGVNCombinations.size() > 1) {
// If we are on the last argument, and we need to differentiate between
// output blocks, add an integer to the argument list to determine
// what block to take
LLVM_DEBUG(dbgs() << "Set switch block argument to "
<< Region.OutputBlockNum << "\n");
NewCallArgs.push_back(ConstantInt::get(Type::getInt32Ty(M.getContext()),
Region.OutputBlockNum));
continue;
}
ArgPair = Region.AggArgToExtracted.find(AggArgIdx);
if (ArgPair != Region.AggArgToExtracted.end()) {
Value *ArgumentValue = Call->getArgOperand(ArgPair->second);
// If we found the mapping from the extracted function to the overall
// function, we simply add it to the argument list. We use the same
// value, it just needs to honor the new order of arguments.
LLVM_DEBUG(dbgs() << "Setting argument " << AggArgIdx << " to value "
<< *ArgumentValue << "\n");
NewCallArgs.push_back(ArgumentValue);
continue;
}
// If it is a constant, we simply add it to the argument list as a value.
if (Region.AggArgToConstant.find(AggArgIdx) !=
Region.AggArgToConstant.end()) {
Constant *CST = Region.AggArgToConstant.find(AggArgIdx)->second;
LLVM_DEBUG(dbgs() << "Setting argument " << AggArgIdx << " to value "
<< *CST << "\n");
NewCallArgs.push_back(CST);
continue;
}
// Add a nullptr value if the argument is not found in the extracted
// function. If we cannot find a value, it means it is not in use
// for the region, so we should not pass anything to it.
LLVM_DEBUG(dbgs() << "Setting argument " << AggArgIdx << " to nullptr\n");
NewCallArgs.push_back(ConstantPointerNull::get(
static_cast<PointerType *>(AggFunc->getArg(AggArgIdx)->getType())));
}
LLVM_DEBUG(dbgs() << "Replace call to " << *Call << " with call to "
<< *AggFunc << " with new set of arguments\n");
// Create the new call instruction and erase the old one.
Call = CallInst::Create(AggFunc->getFunctionType(), AggFunc, NewCallArgs, "",
Call);
// It is possible that the call to the outlined function is either the first
// instruction is in the new block, the last instruction, or both. If either
// of these is the case, we need to make sure that we replace the instruction
// in the IRInstructionData struct with the new call.
CallInst *OldCall = Region.Call;
if (Region.NewFront->Inst == OldCall)
Region.NewFront->Inst = Call;
if (Region.NewBack->Inst == OldCall)
Region.NewBack->Inst = Call;
// Transfer any debug information.
Call->setDebugLoc(Region.Call->getDebugLoc());
// Remove the old instruction.
OldCall->eraseFromParent();
Region.Call = Call;
// Make sure that the argument in the new function has the SwiftError
// argument.
if (Group.SwiftErrorArgument.hasValue())
Call->addParamAttr(Group.SwiftErrorArgument.getValue(),
Attribute::SwiftError);
return Call;
}
// Within an extracted function, replace the argument uses of the extracted
// region with the arguments of the function for an OutlinableGroup.
//
/// \param [in] Region - The region of extracted code to be changed.
/// \param [in,out] OutputBB - The BasicBlock for the output stores for this
/// region.
static void replaceArgumentUses(OutlinableRegion &Region,
BasicBlock *OutputBB) {
OutlinableGroup &Group = *Region.Parent;
assert(Region.ExtractedFunction && "Region has no extracted function?");
for (unsigned ArgIdx = 0; ArgIdx < Region.ExtractedFunction->arg_size();
ArgIdx++) {
assert(Region.ExtractedArgToAgg.find(ArgIdx) !=
Region.ExtractedArgToAgg.end() &&
"No mapping from extracted to outlined?");
unsigned AggArgIdx = Region.ExtractedArgToAgg.find(ArgIdx)->second;
Argument *AggArg = Group.OutlinedFunction->getArg(AggArgIdx);
Argument *Arg = Region.ExtractedFunction->getArg(ArgIdx);
// The argument is an input, so we can simply replace it with the overall
// argument value
if (ArgIdx < Region.NumExtractedInputs) {
LLVM_DEBUG(dbgs() << "Replacing uses of input " << *Arg << " in function "
<< *Region.ExtractedFunction << " with " << *AggArg
<< " in function " << *Group.OutlinedFunction << "\n");
Arg->replaceAllUsesWith(AggArg);
continue;
}
// If we are replacing an output, we place the store value in its own
// block inside the overall function before replacing the use of the output
// in the function.
assert(Arg->hasOneUse() && "Output argument can only have one use");
User *InstAsUser = Arg->user_back();
assert(InstAsUser && "User is nullptr!");
Instruction *I = cast<Instruction>(InstAsUser);
I->setDebugLoc(DebugLoc());
LLVM_DEBUG(dbgs() << "Move store for instruction " << *I << " to "
<< *OutputBB << "\n");
I->moveBefore(*OutputBB, OutputBB->end());
LLVM_DEBUG(dbgs() << "Replacing uses of output " << *Arg << " in function "
<< *Region.ExtractedFunction << " with " << *AggArg
<< " in function " << *Group.OutlinedFunction << "\n");
Arg->replaceAllUsesWith(AggArg);
}
}
/// Within an extracted function, replace the constants that need to be lifted
/// into arguments with the actual argument.
///
/// \param Region [in] - The region of extracted code to be changed.
void replaceConstants(OutlinableRegion &Region) {
OutlinableGroup &Group = *Region.Parent;
// Iterate over the constants that need to be elevated into arguments
for (std::pair<unsigned, Constant *> &Const : Region.AggArgToConstant) {
unsigned AggArgIdx = Const.first;
Function *OutlinedFunction = Group.OutlinedFunction;
assert(OutlinedFunction && "Overall Function is not defined?");
Constant *CST = Const.second;
Argument *Arg = Group.OutlinedFunction->getArg(AggArgIdx);
// Identify the argument it will be elevated to, and replace instances of
// that constant in the function.
// TODO: If in the future constants do not have one global value number,
// i.e. a constant 1 could be mapped to several values, this check will
// have to be more strict. It cannot be using only replaceUsesWithIf.
LLVM_DEBUG(dbgs() << "Replacing uses of constant " << *CST
<< " in function " << *OutlinedFunction << " with "
<< *Arg << "\n");
CST->replaceUsesWithIf(Arg, [OutlinedFunction](Use &U) {
if (Instruction *I = dyn_cast<Instruction>(U.getUser()))
return I->getFunction() == OutlinedFunction;
return false;
});
}
}
/// For the given function, find all the nondebug or lifetime instructions,
/// and return them as a vector. Exclude any blocks in \p ExludeBlocks.
///
/// \param [in] F - The function we collect the instructions from.
/// \param [in] ExcludeBlocks - BasicBlocks to ignore.
/// \returns the list of instructions extracted.
static std::vector<Instruction *>
collectRelevantInstructions(Function &F,
DenseSet<BasicBlock *> &ExcludeBlocks) {
std::vector<Instruction *> RelevantInstructions;
for (BasicBlock &BB : F) {
if (ExcludeBlocks.contains(&BB))
continue;
for (Instruction &Inst : BB) {
if (Inst.isLifetimeStartOrEnd())
continue;
if (isa<DbgInfoIntrinsic>(Inst))
continue;
RelevantInstructions.push_back(&Inst);
}
}
return RelevantInstructions;
}
/// It is possible that there is a basic block that already performs the same
/// stores. This returns a duplicate block, if it exists
///
/// \param OutputBB [in] the block we are looking for a duplicate of.
/// \param OutputStoreBBs [in] The existing output blocks.
/// \returns an optional value with the number output block if there is a match.
Optional<unsigned>
findDuplicateOutputBlock(BasicBlock *OutputBB,
ArrayRef<BasicBlock *> OutputStoreBBs) {
bool WrongInst = false;
bool WrongSize = false;
unsigned MatchingNum = 0;
for (BasicBlock *CompBB : OutputStoreBBs) {
WrongInst = false;
if (CompBB->size() - 1 != OutputBB->size()) {
WrongSize = true;
MatchingNum++;
continue;
}
WrongSize = false;
BasicBlock::iterator NIt = OutputBB->begin();
for (Instruction &I : *CompBB) {
if (isa<BranchInst>(&I))
continue;
if (!I.isIdenticalTo(&(*NIt))) {
WrongInst = true;
break;
}
NIt++;
}
if (!WrongInst && !WrongSize)
return MatchingNum;
MatchingNum++;
}
return None;
}
/// For the outlined section, move needed the StoreInsts for the output
/// registers into their own block. Then, determine if there is a duplicate
/// output block already created.
///
/// \param [in] OG - The OutlinableGroup of regions to be outlined.
/// \param [in] Region - The OutlinableRegion that is being analyzed.
/// \param [in,out] OutputBB - the block that stores for this region will be
/// placed in.
/// \param [in] EndBB - the final block of the extracted function.
/// \param [in] OutputMappings - OutputMappings the mapping of values that have
/// been replaced by a new output value.
/// \param [in,out] OutputStoreBBs - The existing output blocks.
static void
alignOutputBlockWithAggFunc(OutlinableGroup &OG, OutlinableRegion &Region,
BasicBlock *OutputBB, BasicBlock *EndBB,
const DenseMap<Value *, Value *> &OutputMappings,
std::vector<BasicBlock *> &OutputStoreBBs) {
DenseSet<unsigned> ValuesToFind(Region.GVNStores.begin(),
Region.GVNStores.end());
// We iterate over the instructions in the extracted function, and find the
// global value number of the instructions. If we find a value that should
// be contained in a store, we replace the uses of the value with the value
// from the overall function, so that the store is storing the correct
// value from the overall function.
DenseSet<BasicBlock *> ExcludeBBs(OutputStoreBBs.begin(),
OutputStoreBBs.end());
ExcludeBBs.insert(OutputBB);
std::vector<Instruction *> ExtractedFunctionInsts =
collectRelevantInstructions(*(Region.ExtractedFunction), ExcludeBBs);
std::vector<Instruction *> OverallFunctionInsts =
collectRelevantInstructions(*OG.OutlinedFunction, ExcludeBBs);
assert(ExtractedFunctionInsts.size() == OverallFunctionInsts.size() &&
"Number of relevant instructions not equal!");
unsigned NumInstructions = ExtractedFunctionInsts.size();
for (unsigned Idx = 0; Idx < NumInstructions; Idx++) {
Value *V = ExtractedFunctionInsts[Idx];
if (OutputMappings.find(V) != OutputMappings.end())
V = OutputMappings.find(V)->second;
Optional<unsigned> GVN = Region.Candidate->getGVN(V);
// If we have found one of the stored values for output, replace the value
// with the corresponding one from the overall function.
if (GVN.hasValue() && ValuesToFind.erase(GVN.getValue())) {
V->replaceAllUsesWith(OverallFunctionInsts[Idx]);
if (ValuesToFind.size() == 0)
break;
}
if (ValuesToFind.size() == 0)
break;
}
assert(ValuesToFind.size() == 0 && "Not all store values were handled!");
// If the size of the block is 0, then there are no stores, and we do not
// need to save this block.
if (OutputBB->size() == 0) {
Region.OutputBlockNum = -1;
OutputBB->eraseFromParent();
return;
}
// Determine is there is a duplicate block.
Optional<unsigned> MatchingBB =
findDuplicateOutputBlock(OutputBB, OutputStoreBBs);
// If there is, we remove the new output block. If it does not,
// we add it to our list of output blocks.
if (MatchingBB.hasValue()) {
LLVM_DEBUG(dbgs() << "Set output block for region in function"
<< Region.ExtractedFunction << " to "
<< MatchingBB.getValue());
Region.OutputBlockNum = MatchingBB.getValue();
OutputBB->eraseFromParent();
return;
}
Region.OutputBlockNum = OutputStoreBBs.size();
LLVM_DEBUG(dbgs() << "Create output block for region in"
<< Region.ExtractedFunction << " to "
<< *OutputBB);
OutputStoreBBs.push_back(OutputBB);
BranchInst::Create(EndBB, OutputBB);
}
/// Create the switch statement for outlined function to differentiate between
/// all the output blocks.
///
/// For the outlined section, determine if an outlined block already exists that
/// matches the needed stores for the extracted section.
/// \param [in] M - The module we are outlining from.
/// \param [in] OG - The group of regions to be outlined.
/// \param [in] EndBB - The final block of the extracted function.
/// \param [in,out] OutputStoreBBs - The existing output blocks.
void createSwitchStatement(Module &M, OutlinableGroup &OG, BasicBlock *EndBB,
ArrayRef<BasicBlock *> OutputStoreBBs) {
// We only need the switch statement if there is more than one store
// combination.
if (OG.OutputGVNCombinations.size() > 1) {
Function *AggFunc = OG.OutlinedFunction;
// Create a final block
BasicBlock *ReturnBlock =
BasicBlock::Create(M.getContext(), "final_block", AggFunc);
Instruction *Term = EndBB->getTerminator();
Term->moveBefore(*ReturnBlock, ReturnBlock->end());
// Put the switch statement in the old end basic block for the function with
// a fall through to the new return block
LLVM_DEBUG(dbgs() << "Create switch statement in " << *AggFunc << " for "
<< OutputStoreBBs.size() << "\n");
SwitchInst *SwitchI =
SwitchInst::Create(AggFunc->getArg(AggFunc->arg_size() - 1),
ReturnBlock, OutputStoreBBs.size(), EndBB);
unsigned Idx = 0;
for (BasicBlock *BB : OutputStoreBBs) {
SwitchI->addCase(ConstantInt::get(Type::getInt32Ty(M.getContext()), Idx),
BB);
Term = BB->getTerminator();
Term->setSuccessor(0, ReturnBlock);
Idx++;
}
return;
}
// If there needs to be stores, move them from the output block to the end
// block to save on branching instructions.
if (OutputStoreBBs.size() == 1) {
LLVM_DEBUG(dbgs() << "Move store instructions to the end block in "
<< *OG.OutlinedFunction << "\n");
BasicBlock *OutputBlock = OutputStoreBBs[0];
Instruction *Term = OutputBlock->getTerminator();
Term->eraseFromParent();
Term = EndBB->getTerminator();
moveBBContents(*OutputBlock, *EndBB);
Term->moveBefore(*EndBB, EndBB->end());
OutputBlock->eraseFromParent();
}
}
/// Fill the new function that will serve as the replacement function for all of
/// the extracted regions of a certain structure from the first region in the
/// list of regions. Replace this first region's extracted function with the
/// new overall function.
///
/// \param [in] M - The module we are outlining from.
/// \param [in] CurrentGroup - The group of regions to be outlined.
/// \param [in,out] OutputStoreBBs - The output blocks for each different
/// set of stores needed for the different functions.
/// \param [in,out] FuncsToRemove - Extracted functions to erase from module
/// once outlining is complete.
static void fillOverallFunction(Module &M, OutlinableGroup &CurrentGroup,
std::vector<BasicBlock *> &OutputStoreBBs,
std::vector<Function *> &FuncsToRemove) {
OutlinableRegion *CurrentOS = CurrentGroup.Regions[0];
// Move first extracted function's instructions into new function.
LLVM_DEBUG(dbgs() << "Move instructions from "
<< *CurrentOS->ExtractedFunction << " to instruction "
<< *CurrentGroup.OutlinedFunction << "\n");
CurrentGroup.EndBB = moveFunctionData(*CurrentOS->ExtractedFunction,
*CurrentGroup.OutlinedFunction);
// Transfer the attributes from the function to the new function.
for (Attribute A :
CurrentOS->ExtractedFunction->getAttributes().getFnAttributes())
CurrentGroup.OutlinedFunction->addFnAttr(A);
// Create an output block for the first extracted function.
BasicBlock *NewBB = BasicBlock::Create(
M.getContext(), Twine("output_block_") + Twine(static_cast<unsigned>(0)),
CurrentGroup.OutlinedFunction);
CurrentOS->OutputBlockNum = 0;
replaceArgumentUses(*CurrentOS, NewBB);
replaceConstants(*CurrentOS);
// If the new basic block has no new stores, we can erase it from the module.
// It it does, we create a branch instruction to the last basic block from the
// new one.
if (NewBB->size() == 0) {
CurrentOS->OutputBlockNum = -1;
NewBB->eraseFromParent();
} else {
BranchInst::Create(CurrentGroup.EndBB, NewBB);
OutputStoreBBs.push_back(NewBB);
}
// Replace the call to the extracted function with the outlined function.
CurrentOS->Call = replaceCalledFunction(M, *CurrentOS);
// We only delete the extracted functions at the end since we may need to
// reference instructions contained in them for mapping purposes.
FuncsToRemove.push_back(CurrentOS->ExtractedFunction);
}
void IROutliner::deduplicateExtractedSections(
Module &M, OutlinableGroup &CurrentGroup,
std::vector<Function *> &FuncsToRemove, unsigned &OutlinedFunctionNum) {
createFunction(M, CurrentGroup, OutlinedFunctionNum);
std::vector<BasicBlock *> OutputStoreBBs;
OutlinableRegion *CurrentOS;
fillOverallFunction(M, CurrentGroup, OutputStoreBBs, FuncsToRemove);
for (unsigned Idx = 1; Idx < CurrentGroup.Regions.size(); Idx++) {
CurrentOS = CurrentGroup.Regions[Idx];
AttributeFuncs::mergeAttributesForOutlining(*CurrentGroup.OutlinedFunction,
*CurrentOS->ExtractedFunction);
// Create a new BasicBlock to hold the needed store instructions.
BasicBlock *NewBB = BasicBlock::Create(
M.getContext(), "output_block_" + std::to_string(Idx),
CurrentGroup.OutlinedFunction);
replaceArgumentUses(*CurrentOS, NewBB);
alignOutputBlockWithAggFunc(CurrentGroup, *CurrentOS, NewBB,
CurrentGroup.EndBB, OutputMappings,
OutputStoreBBs);
CurrentOS->Call = replaceCalledFunction(M, *CurrentOS);
FuncsToRemove.push_back(CurrentOS->ExtractedFunction);
}
// Create a switch statement to handle the different output schemes.
createSwitchStatement(M, CurrentGroup, CurrentGroup.EndBB, OutputStoreBBs);
OutlinedFunctionNum++;
}
void IROutliner::pruneIncompatibleRegions(
std::vector<IRSimilarityCandidate> &CandidateVec,
OutlinableGroup &CurrentGroup) {
bool PreviouslyOutlined;
// Sort from beginning to end, so the IRSimilarityCandidates are in order.
stable_sort(CandidateVec, [](const IRSimilarityCandidate &LHS,
const IRSimilarityCandidate &RHS) {
return LHS.getStartIdx() < RHS.getStartIdx();
});
unsigned CurrentEndIdx = 0;
for (IRSimilarityCandidate &IRSC : CandidateVec) {
PreviouslyOutlined = false;
unsigned StartIdx = IRSC.getStartIdx();
unsigned EndIdx = IRSC.getEndIdx();
for (unsigned Idx = StartIdx; Idx <= EndIdx; Idx++)
if (Outlined.contains(Idx)) {
PreviouslyOutlined = true;
break;
}
if (PreviouslyOutlined)
continue;
// TODO: If in the future we can outline across BasicBlocks, we will need to
// check all BasicBlocks contained in the region.
if (IRSC.getStartBB()->hasAddressTaken())
continue;
if (IRSC.front()->Inst->getFunction()->hasLinkOnceODRLinkage() &&
!OutlineFromLinkODRs)
continue;
// Greedily prune out any regions that will overlap with already chosen
// regions.
if (CurrentEndIdx != 0 && StartIdx <= CurrentEndIdx)
continue;
bool BadInst = any_of(IRSC, [this](IRInstructionData &ID) {
// We check if there is a discrepancy between the InstructionDataList
// and the actual next instruction in the module. If there is, it means
// that an extra instruction was added, likely by the CodeExtractor.
// Since we do not have any similarity data about this particular
// instruction, we cannot confidently outline it, and must discard this
// candidate.
if (std::next(ID.getIterator())->Inst !=
ID.Inst->getNextNonDebugInstruction())
return true;
return !this->InstructionClassifier.visit(ID.Inst);
});
if (BadInst)
continue;
OutlinableRegion *OS = new (RegionAllocator.Allocate())
OutlinableRegion(IRSC, CurrentGroup);
CurrentGroup.Regions.push_back(OS);
CurrentEndIdx = EndIdx;
}
}
InstructionCost
IROutliner::findBenefitFromAllRegions(OutlinableGroup &CurrentGroup) {
InstructionCost RegionBenefit = 0;
for (OutlinableRegion *Region : CurrentGroup.Regions) {
TargetTransformInfo &TTI = getTTI(*Region->StartBB->getParent());
// We add the number of instructions in the region to the benefit as an
// estimate as to how much will be removed.
RegionBenefit += Region->getBenefit(TTI);
LLVM_DEBUG(dbgs() << "Adding: " << RegionBenefit
<< " saved instructions to overfall benefit.\n");
}
return RegionBenefit;
}
InstructionCost
IROutliner::findCostOutputReloads(OutlinableGroup &CurrentGroup) {
InstructionCost OverallCost = 0;
for (OutlinableRegion *Region : CurrentGroup.Regions) {
TargetTransformInfo &TTI = getTTI(*Region->StartBB->getParent());
// Each output incurs a load after the call, so we add that to the cost.
for (unsigned OutputGVN : Region->GVNStores) {
Optional<Value *> OV = Region->Candidate->fromGVN(OutputGVN);
assert(OV.hasValue() && "Could not find value for GVN?");
Value *V = OV.getValue();
InstructionCost LoadCost =
TTI.getMemoryOpCost(Instruction::Load, V->getType(), Align(1), 0,
TargetTransformInfo::TCK_CodeSize);
LLVM_DEBUG(dbgs() << "Adding: " << LoadCost
<< " instructions to cost for output of type "
<< *V->getType() << "\n");
OverallCost += LoadCost;
}
}
return OverallCost;
}
/// Find the extra instructions needed to handle any output values for the
/// region.
///
/// \param [in] M - The Module to outline from.
/// \param [in] CurrentGroup - The collection of OutlinableRegions to analyze.
/// \param [in] TTI - The TargetTransformInfo used to collect information for
/// new instruction costs.
/// \returns the additional cost to handle the outputs.
static InstructionCost findCostForOutputBlocks(Module &M,
OutlinableGroup &CurrentGroup,
TargetTransformInfo &TTI) {
InstructionCost OutputCost = 0;
for (const ArrayRef<unsigned> &OutputUse :
CurrentGroup.OutputGVNCombinations) {
IRSimilarityCandidate &Candidate = *CurrentGroup.Regions[0]->Candidate;
for (unsigned GVN : OutputUse) {
Optional<Value *> OV = Candidate.fromGVN(GVN);
assert(OV.hasValue() && "Could not find value for GVN?");
Value *V = OV.getValue();
InstructionCost StoreCost =
TTI.getMemoryOpCost(Instruction::Load, V->getType(), Align(1), 0,
TargetTransformInfo::TCK_CodeSize);
// An instruction cost is added for each store set that needs to occur for
// various output combinations inside the function, plus a branch to
// return to the exit block.
LLVM_DEBUG(dbgs() << "Adding: " << StoreCost
<< " instructions to cost for output of type "
<< *V->getType() << "\n");
OutputCost += StoreCost;
}
InstructionCost BranchCost =
TTI.getCFInstrCost(Instruction::Br, TargetTransformInfo::TCK_CodeSize);
LLVM_DEBUG(dbgs() << "Adding " << BranchCost << " to the current cost for"
<< " a branch instruction\n");
OutputCost += BranchCost;
}
// If there is more than one output scheme, we must have a comparison and
// branch for each different item in the switch statement.
if (CurrentGroup.OutputGVNCombinations.size() > 1) {
InstructionCost ComparisonCost = TTI.getCmpSelInstrCost(
Instruction::ICmp, Type::getInt32Ty(M.getContext()),
Type::getInt32Ty(M.getContext()), CmpInst::BAD_ICMP_PREDICATE,
TargetTransformInfo::TCK_CodeSize);
InstructionCost BranchCost =
TTI.getCFInstrCost(Instruction::Br, TargetTransformInfo::TCK_CodeSize);
unsigned DifferentBlocks = CurrentGroup.OutputGVNCombinations.size();
InstructionCost TotalCost = ComparisonCost * BranchCost * DifferentBlocks;
LLVM_DEBUG(dbgs() << "Adding: " << TotalCost
<< " instructions for each switch case for each different"
<< " output path in a function\n");
OutputCost += TotalCost;
}
return OutputCost;
}
void IROutliner::findCostBenefit(Module &M, OutlinableGroup &CurrentGroup) {
InstructionCost RegionBenefit = findBenefitFromAllRegions(CurrentGroup);
CurrentGroup.Benefit += RegionBenefit;
LLVM_DEBUG(dbgs() << "Current Benefit: " << CurrentGroup.Benefit << "\n");
InstructionCost OutputReloadCost = findCostOutputReloads(CurrentGroup);
CurrentGroup.Cost += OutputReloadCost;
LLVM_DEBUG(dbgs() << "Current Cost: " << CurrentGroup.Cost << "\n");
InstructionCost AverageRegionBenefit =
RegionBenefit / CurrentGroup.Regions.size();
unsigned OverallArgumentNum = CurrentGroup.ArgumentTypes.size();
unsigned NumRegions = CurrentGroup.Regions.size();
TargetTransformInfo &TTI =
getTTI(*CurrentGroup.Regions[0]->Candidate->getFunction());
// We add one region to the cost once, to account for the instructions added
// inside of the newly created function.
LLVM_DEBUG(dbgs() << "Adding: " << AverageRegionBenefit
<< " instructions to cost for body of new function.\n");
CurrentGroup.Cost += AverageRegionBenefit;
LLVM_DEBUG(dbgs() << "Current Cost: " << CurrentGroup.Cost << "\n");
// For each argument, we must add an instruction for loading the argument
// out of the register and into a value inside of the newly outlined function.
LLVM_DEBUG(dbgs() << "Adding: " << OverallArgumentNum
<< " instructions to cost for each argument in the new"
<< " function.\n");
CurrentGroup.Cost +=
OverallArgumentNum * TargetTransformInfo::TCC_Basic;
LLVM_DEBUG(dbgs() << "Current Cost: " << CurrentGroup.Cost << "\n");
// Each argument needs to either be loaded into a register or onto the stack.
// Some arguments will only be loaded into the stack once the argument
// registers are filled.
LLVM_DEBUG(dbgs() << "Adding: " << OverallArgumentNum
<< " instructions to cost for each argument in the new"
<< " function " << NumRegions << " times for the "
<< "needed argument handling at the call site.\n");
CurrentGroup.Cost +=
2 * OverallArgumentNum * TargetTransformInfo::TCC_Basic * NumRegions;
LLVM_DEBUG(dbgs() << "Current Cost: " << CurrentGroup.Cost << "\n");
CurrentGroup.Cost += findCostForOutputBlocks(M, CurrentGroup, TTI);
LLVM_DEBUG(dbgs() << "Current Cost: " << CurrentGroup.Cost << "\n");
}
void IROutliner::updateOutputMapping(OutlinableRegion &Region,
ArrayRef<Value *> Outputs,
LoadInst *LI) {
// For and load instructions following the call
Value *Operand = LI->getPointerOperand();
Optional<unsigned> OutputIdx = None;
// Find if the operand it is an output register.
for (unsigned ArgIdx = Region.NumExtractedInputs;
ArgIdx < Region.Call->arg_size(); ArgIdx++) {
if (Operand == Region.Call->getArgOperand(ArgIdx)) {
OutputIdx = ArgIdx - Region.NumExtractedInputs;
break;
}
}
// If we found an output register, place a mapping of the new value
// to the original in the mapping.
if (!OutputIdx.hasValue())
return;
if (OutputMappings.find(Outputs[OutputIdx.getValue()]) ==
OutputMappings.end()) {
LLVM_DEBUG(dbgs() << "Mapping extracted output " << *LI << " to "
<< *Outputs[OutputIdx.getValue()] << "\n");
OutputMappings.insert(std::make_pair(LI, Outputs[OutputIdx.getValue()]));
} else {
Value *Orig = OutputMappings.find(Outputs[OutputIdx.getValue()])->second;
LLVM_DEBUG(dbgs() << "Mapping extracted output " << *Orig << " to "
<< *Outputs[OutputIdx.getValue()] << "\n");
OutputMappings.insert(std::make_pair(LI, Orig));
}
}
bool IROutliner::extractSection(OutlinableRegion &Region) {
SetVector<Value *> ArgInputs, Outputs, SinkCands;
Region.CE->findInputsOutputs(ArgInputs, Outputs, SinkCands);
assert(Region.StartBB && "StartBB for the OutlinableRegion is nullptr!");
assert(Region.FollowBB && "FollowBB for the OutlinableRegion is nullptr!");
Function *OrigF = Region.StartBB->getParent();
CodeExtractorAnalysisCache CEAC(*OrigF);
Region.ExtractedFunction = Region.CE->extractCodeRegion(CEAC);
// If the extraction was successful, find the BasicBlock, and reassign the
// OutlinableRegion blocks
if (!Region.ExtractedFunction) {
LLVM_DEBUG(dbgs() << "CodeExtractor failed to outline " << Region.StartBB
<< "\n");
Region.reattachCandidate();
return false;
}
BasicBlock *RewrittenBB = Region.FollowBB->getSinglePredecessor();
Region.StartBB = RewrittenBB;
Region.EndBB = RewrittenBB;
// The sequences of outlinable regions has now changed. We must fix the
// IRInstructionDataList for consistency. Although they may not be illegal
// instructions, they should not be compared with anything else as they
// should not be outlined in this round. So marking these as illegal is
// allowed.
IRInstructionDataList *IDL = Region.Candidate->front()->IDL;
Instruction *BeginRewritten = &*RewrittenBB->begin();
Instruction *EndRewritten = &*RewrittenBB->begin();
Region.NewFront = new (InstDataAllocator.Allocate()) IRInstructionData(
*BeginRewritten, InstructionClassifier.visit(*BeginRewritten), *IDL);
Region.NewBack = new (InstDataAllocator.Allocate()) IRInstructionData(
*EndRewritten, InstructionClassifier.visit(*EndRewritten), *IDL);
// Insert the first IRInstructionData of the new region in front of the
// first IRInstructionData of the IRSimilarityCandidate.
IDL->insert(Region.Candidate->begin(), *Region.NewFront);
// Insert the first IRInstructionData of the new region after the
// last IRInstructionData of the IRSimilarityCandidate.
IDL->insert(Region.Candidate->end(), *Region.NewBack);
// Remove the IRInstructionData from the IRSimilarityCandidate.
IDL->erase(Region.Candidate->begin(), std::prev(Region.Candidate->end()));
assert(RewrittenBB != nullptr &&
"Could not find a predecessor after extraction!");
// Iterate over the new set of instructions to find the new call
// instruction.
for (Instruction &I : *RewrittenBB)
if (CallInst *CI = dyn_cast<CallInst>(&I)) {
if (Region.ExtractedFunction == CI->getCalledFunction())
Region.Call = CI;
} else if (LoadInst *LI = dyn_cast<LoadInst>(&I))
updateOutputMapping(Region, Outputs.getArrayRef(), LI);
Region.reattachCandidate();
return true;
}
unsigned IROutliner::doOutline(Module &M) {
// Find the possible similarity sections.
IRSimilarityIdentifier &Identifier = getIRSI(M);
SimilarityGroupList &SimilarityCandidates = *Identifier.getSimilarity();
// Sort them by size of extracted sections
unsigned OutlinedFunctionNum = 0;
// If we only have one SimilarityGroup in SimilarityCandidates, we do not have
// to sort them by the potential number of instructions to be outlined
if (SimilarityCandidates.size() > 1)
llvm::stable_sort(SimilarityCandidates,
[](const std::vector<IRSimilarityCandidate> &LHS,
const std::vector<IRSimilarityCandidate> &RHS) {
return LHS[0].getLength() * LHS.size() >
RHS[0].getLength() * RHS.size();
});
DenseSet<unsigned> NotSame;
std::vector<Function *> FuncsToRemove;
// Iterate over the possible sets of similarity.
for (SimilarityGroup &CandidateVec : SimilarityCandidates) {
OutlinableGroup CurrentGroup;
// Remove entries that were previously outlined
pruneIncompatibleRegions(CandidateVec, CurrentGroup);
// We pruned the number of regions to 0 to 1, meaning that it's not worth
// trying to outlined since there is no compatible similar instance of this
// code.
if (CurrentGroup.Regions.size() < 2)
continue;
// Determine if there are any values that are the same constant throughout
// each section in the set.
NotSame.clear();
CurrentGroup.findSameConstants(NotSame);
if (CurrentGroup.IgnoreGroup)
continue;
// Create a CodeExtractor for each outlinable region. Identify inputs and
// outputs for each section using the code extractor and create the argument
// types for the Aggregate Outlining Function.
std::vector<OutlinableRegion *> OutlinedRegions;
for (OutlinableRegion *OS : CurrentGroup.Regions) {
// Break the outlinable region out of its parent BasicBlock into its own
// BasicBlocks (see function implementation).
OS->splitCandidate();
std::vector<BasicBlock *> BE = {OS->StartBB};
OS->CE = new (ExtractorAllocator.Allocate())
CodeExtractor(BE, nullptr, false, nullptr, nullptr, nullptr, false,
false, "outlined");
findAddInputsOutputs(M, *OS, NotSame);
if (!OS->IgnoreRegion)
OutlinedRegions.push_back(OS);
else
OS->reattachCandidate();
}
CurrentGroup.Regions = std::move(OutlinedRegions);
if (CurrentGroup.Regions.empty())
continue;
CurrentGroup.collectGVNStoreSets(M);
if (CostModel)
findCostBenefit(M, CurrentGroup);
// If we are adhering to the cost model, reattach all the candidates
if (CurrentGroup.Cost >= CurrentGroup.Benefit && CostModel) {
for (OutlinableRegion *OS : CurrentGroup.Regions)
OS->reattachCandidate();
OptimizationRemarkEmitter &ORE = getORE(
*CurrentGroup.Regions[0]->Candidate->getFunction());
ORE.emit([&]() {
IRSimilarityCandidate *C = CurrentGroup.Regions[0]->Candidate;
OptimizationRemarkMissed R(DEBUG_TYPE, "WouldNotDecreaseSize",
C->frontInstruction());
R << "did not outline "
<< ore::NV(std::to_string(CurrentGroup.Regions.size()))
<< " regions due to estimated increase of "
<< ore::NV("InstructionIncrease",
CurrentGroup.Cost - CurrentGroup.Benefit)
<< " instructions at locations ";
interleave(
CurrentGroup.Regions.begin(), CurrentGroup.Regions.end(),
[&R](OutlinableRegion *Region) {
R << ore::NV(
"DebugLoc",
Region->Candidate->frontInstruction()->getDebugLoc());
},
[&R]() { R << " "; });
return R;
});
continue;
}
LLVM_DEBUG(dbgs() << "Outlining regions with cost " << CurrentGroup.Cost
<< " and benefit " << CurrentGroup.Benefit << "\n");
// Create functions out of all the sections, and mark them as outlined.
OutlinedRegions.clear();
for (OutlinableRegion *OS : CurrentGroup.Regions) {
bool FunctionOutlined = extractSection(*OS);
if (FunctionOutlined) {
unsigned StartIdx = OS->Candidate->getStartIdx();
unsigned EndIdx = OS->Candidate->getEndIdx();
for (unsigned Idx = StartIdx; Idx <= EndIdx; Idx++)
Outlined.insert(Idx);
OutlinedRegions.push_back(OS);
}
}
LLVM_DEBUG(dbgs() << "Outlined " << OutlinedRegions.size()
<< " with benefit " << CurrentGroup.Benefit
<< " and cost " << CurrentGroup.Cost << "\n");
CurrentGroup.Regions = std::move(OutlinedRegions);
if (CurrentGroup.Regions.empty())
continue;
OptimizationRemarkEmitter &ORE =
getORE(*CurrentGroup.Regions[0]->Call->getFunction());
ORE.emit([&]() {
IRSimilarityCandidate *C = CurrentGroup.Regions[0]->Candidate;
OptimizationRemark R(DEBUG_TYPE, "Outlined", C->front()->Inst);
R << "outlined " << ore::NV(std::to_string(CurrentGroup.Regions.size()))
<< " regions with decrease of "
<< ore::NV("Benefit", CurrentGroup.Benefit - CurrentGroup.Cost)
<< " instructions at locations ";
interleave(
CurrentGroup.Regions.begin(), CurrentGroup.Regions.end(),
[&R](OutlinableRegion *Region) {
R << ore::NV("DebugLoc",
Region->Candidate->frontInstruction()->getDebugLoc());
},
[&R]() { R << " "; });
return R;
});
deduplicateExtractedSections(M, CurrentGroup, FuncsToRemove,
OutlinedFunctionNum);
}
for (Function *F : FuncsToRemove)
F->eraseFromParent();
return OutlinedFunctionNum;
}
bool IROutliner::run(Module &M) {
CostModel = !NoCostModel;
OutlineFromLinkODRs = EnableLinkOnceODRIROutlining;
return doOutline(M) > 0;
}
// Pass Manager Boilerplate
class IROutlinerLegacyPass : public ModulePass {
public:
static char ID;
IROutlinerLegacyPass() : ModulePass(ID) {
initializeIROutlinerLegacyPassPass(*PassRegistry::getPassRegistry());
}
void getAnalysisUsage(AnalysisUsage &AU) const override {
AU.addRequired<OptimizationRemarkEmitterWrapperPass>();
AU.addRequired<TargetTransformInfoWrapperPass>();
AU.addRequired<IRSimilarityIdentifierWrapperPass>();
}
bool runOnModule(Module &M) override;
};
bool IROutlinerLegacyPass::runOnModule(Module &M) {
if (skipModule(M))
return false;
std::unique_ptr<OptimizationRemarkEmitter> ORE;
auto GORE = [&ORE](Function &F) -> OptimizationRemarkEmitter & {
ORE.reset(new OptimizationRemarkEmitter(&F));
return *ORE.get();
};
auto GTTI = [this](Function &F) -> TargetTransformInfo & {
return this->getAnalysis<TargetTransformInfoWrapperPass>().getTTI(F);
};
auto GIRSI = [this](Module &) -> IRSimilarityIdentifier & {
return this->getAnalysis<IRSimilarityIdentifierWrapperPass>().getIRSI();
};
return IROutliner(GTTI, GIRSI, GORE).run(M);
}
PreservedAnalyses IROutlinerPass::run(Module &M, ModuleAnalysisManager &AM) {
auto &FAM = AM.getResult<FunctionAnalysisManagerModuleProxy>(M).getManager();
std::function<TargetTransformInfo &(Function &)> GTTI =
[&FAM](Function &F) -> TargetTransformInfo & {
return FAM.getResult<TargetIRAnalysis>(F);
};
std::function<IRSimilarityIdentifier &(Module &)> GIRSI =
[&AM](Module &M) -> IRSimilarityIdentifier & {
return AM.getResult<IRSimilarityAnalysis>(M);
};
std::unique_ptr<OptimizationRemarkEmitter> ORE;
std::function<OptimizationRemarkEmitter &(Function &)> GORE =
[&ORE](Function &F) -> OptimizationRemarkEmitter & {
ORE.reset(new OptimizationRemarkEmitter(&F));
return *ORE.get();
};
if (IROutliner(GTTI, GIRSI, GORE).run(M))
return PreservedAnalyses::none();
return PreservedAnalyses::all();
}
char IROutlinerLegacyPass::ID = 0;
INITIALIZE_PASS_BEGIN(IROutlinerLegacyPass, "iroutliner", "IR Outliner", false,
false)
INITIALIZE_PASS_DEPENDENCY(IRSimilarityIdentifierWrapperPass)
INITIALIZE_PASS_DEPENDENCY(OptimizationRemarkEmitterWrapperPass)
INITIALIZE_PASS_DEPENDENCY(TargetTransformInfoWrapperPass)
INITIALIZE_PASS_END(IROutlinerLegacyPass, "iroutliner", "IR Outliner", false,
false)
ModulePass *llvm::createIROutlinerPass() { return new IROutlinerLegacyPass(); }