llvm-6502/lib/CodeGen/Passes.cpp
Quentin Colombet dcd3cbea54 [PeepholeOptimizer] Refactor the advanced copy optimization to take advantage of
the isRegSequence property.

This is a follow-up of r215394 and r215404, which respectively introduces the
isRegSequence property and uses it for ARM.

Thanks to the property introduced by the previous commits, this patch is able
to optimize the following sequence:
vmov	d0, r2, r3
vmov	d1, r0, r1
vmov	r0, s0
vmov	r1, s2
udiv	r0, r1, r0
vmov	r1, s1
vmov	r2, s3
udiv	r1, r2, r1
vmov.32	d16[0], r0
vmov.32	d16[1], r1
vmov	r0, r1, d16
bx	lr

into:
udiv	r0, r0, r2
udiv	r1, r1, r3
vmov.32	d16[0], r0
vmov.32	d16[1], r1
vmov	r0, r1, d16
bx	lr

This patch refactors how the copy optimizations are done in the peephole
optimizer. Prior to this patch, we had one copy-related optimization that
replaced a copy or bitcast by a generic, more suitable (in terms of register
file), copy.

With this patch, the peephole optimizer features two copy-related optimizations:
1. One for rewriting generic copies to generic copies:
PeepholeOptimizer::optimizeCoalescableCopy.
2. One for replacing non-generic copies with generic copies:
PeepholeOptimizer::optimizeUncoalescableCopy.

The goals of these two optimizations are slightly different: one rewrite the
operand of the instruction (#1), the other kills off the non-generic instruction
and replace it by a (sequence of) generic instruction(s).

Both optimizations rely on the ValueTracker introduced in r212100.

The ValueTracker has been refactored to use the information from the
TargetInstrInfo for non-generic instruction. As part of the refactoring, we
switched the tracking from the index of the definition to the actual register
(virtual or physical). This one change is to provide better consistency with
register related APIs and to ease the use of the TargetInstrInfo.

Moreover, this patch introduces a new helper class CopyRewriter used to ease the
rewriting of generic copies (i.e., #1).

Finally, this patch adds a dead code elimination pass right after the peephole
optimizer to get rid of dead code that may appear after rewriting.

This is related to <rdar://problem/12702965>.

Review: http://reviews.llvm.org/D4874


git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@216088 91177308-0d34-0410-b5e6-96231b3b80d8
2014-08-20 17:41:48 +00:00

790 lines
30 KiB
C++

//===-- Passes.cpp - Target independent code generation passes ------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines interfaces to access the target independent code
// generation passes provided by the LLVM backend.
//
//===---------------------------------------------------------------------===//
#include "llvm/CodeGen/Passes.h"
#include "llvm/Analysis/Passes.h"
#include "llvm/CodeGen/GCStrategy.h"
#include "llvm/CodeGen/MachineFunctionPass.h"
#include "llvm/CodeGen/RegAllocRegistry.h"
#include "llvm/IR/IRPrintingPasses.h"
#include "llvm/IR/Verifier.h"
#include "llvm/MC/MCAsmInfo.h"
#include "llvm/PassManager.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Target/TargetLowering.h"
#include "llvm/Target/TargetSubtargetInfo.h"
#include "llvm/Transforms/Scalar.h"
using namespace llvm;
static cl::opt<bool> DisablePostRA("disable-post-ra", cl::Hidden,
cl::desc("Disable Post Regalloc"));
static cl::opt<bool> DisableBranchFold("disable-branch-fold", cl::Hidden,
cl::desc("Disable branch folding"));
static cl::opt<bool> DisableTailDuplicate("disable-tail-duplicate", cl::Hidden,
cl::desc("Disable tail duplication"));
static cl::opt<bool> DisableEarlyTailDup("disable-early-taildup", cl::Hidden,
cl::desc("Disable pre-register allocation tail duplication"));
static cl::opt<bool> DisableBlockPlacement("disable-block-placement",
cl::Hidden, cl::desc("Disable probability-driven block placement"));
static cl::opt<bool> EnableBlockPlacementStats("enable-block-placement-stats",
cl::Hidden, cl::desc("Collect probability-driven block placement stats"));
static cl::opt<bool> DisableSSC("disable-ssc", cl::Hidden,
cl::desc("Disable Stack Slot Coloring"));
static cl::opt<bool> DisableMachineDCE("disable-machine-dce", cl::Hidden,
cl::desc("Disable Machine Dead Code Elimination"));
static cl::opt<bool> DisableEarlyIfConversion("disable-early-ifcvt", cl::Hidden,
cl::desc("Disable Early If-conversion"));
static cl::opt<bool> DisableMachineLICM("disable-machine-licm", cl::Hidden,
cl::desc("Disable Machine LICM"));
static cl::opt<bool> DisableMachineCSE("disable-machine-cse", cl::Hidden,
cl::desc("Disable Machine Common Subexpression Elimination"));
static cl::opt<cl::boolOrDefault>
OptimizeRegAlloc("optimize-regalloc", cl::Hidden,
cl::desc("Enable optimized register allocation compilation path."));
static cl::opt<cl::boolOrDefault>
EnableMachineSched("enable-misched",
cl::desc("Enable the machine instruction scheduling pass."));
static cl::opt<bool> DisablePostRAMachineLICM("disable-postra-machine-licm",
cl::Hidden,
cl::desc("Disable Machine LICM"));
static cl::opt<bool> DisableMachineSink("disable-machine-sink", cl::Hidden,
cl::desc("Disable Machine Sinking"));
static cl::opt<bool> DisableLSR("disable-lsr", cl::Hidden,
cl::desc("Disable Loop Strength Reduction Pass"));
static cl::opt<bool> DisableConstantHoisting("disable-constant-hoisting",
cl::Hidden, cl::desc("Disable ConstantHoisting"));
static cl::opt<bool> DisableCGP("disable-cgp", cl::Hidden,
cl::desc("Disable Codegen Prepare"));
static cl::opt<bool> DisableCopyProp("disable-copyprop", cl::Hidden,
cl::desc("Disable Copy Propagation pass"));
static cl::opt<bool> DisablePartialLibcallInlining("disable-partial-libcall-inlining",
cl::Hidden, cl::desc("Disable Partial Libcall Inlining"));
static cl::opt<bool> PrintLSR("print-lsr-output", cl::Hidden,
cl::desc("Print LLVM IR produced by the loop-reduce pass"));
static cl::opt<bool> PrintISelInput("print-isel-input", cl::Hidden,
cl::desc("Print LLVM IR input to isel pass"));
static cl::opt<bool> PrintGCInfo("print-gc", cl::Hidden,
cl::desc("Dump garbage collector data"));
static cl::opt<bool> VerifyMachineCode("verify-machineinstrs", cl::Hidden,
cl::desc("Verify generated machine code"),
cl::init(getenv("LLVM_VERIFY_MACHINEINSTRS")!=nullptr));
static cl::opt<std::string>
PrintMachineInstrs("print-machineinstrs", cl::ValueOptional,
cl::desc("Print machine instrs"),
cl::value_desc("pass-name"), cl::init("option-unspecified"));
// Temporary option to allow experimenting with MachineScheduler as a post-RA
// scheduler. Targets can "properly" enable this with
// substitutePass(&PostRASchedulerID, &PostMachineSchedulerID); Ideally it
// wouldn't be part of the standard pass pipeline, and the target would just add
// a PostRA scheduling pass wherever it wants.
static cl::opt<bool> MISchedPostRA("misched-postra", cl::Hidden,
cl::desc("Run MachineScheduler post regalloc (independent of preRA sched)"));
// Experimental option to run live interval analysis early.
static cl::opt<bool> EarlyLiveIntervals("early-live-intervals", cl::Hidden,
cl::desc("Run live interval analysis earlier in the pipeline"));
/// Allow standard passes to be disabled by command line options. This supports
/// simple binary flags that either suppress the pass or do nothing.
/// i.e. -disable-mypass=false has no effect.
/// These should be converted to boolOrDefault in order to use applyOverride.
static IdentifyingPassPtr applyDisable(IdentifyingPassPtr PassID,
bool Override) {
if (Override)
return IdentifyingPassPtr();
return PassID;
}
/// Allow Pass selection to be overriden by command line options. This supports
/// flags with ternary conditions. TargetID is passed through by default. The
/// pass is suppressed when the option is false. When the option is true, the
/// StandardID is selected if the target provides no default.
static IdentifyingPassPtr applyOverride(IdentifyingPassPtr TargetID,
cl::boolOrDefault Override,
AnalysisID StandardID) {
switch (Override) {
case cl::BOU_UNSET:
return TargetID;
case cl::BOU_TRUE:
if (TargetID.isValid())
return TargetID;
if (StandardID == nullptr)
report_fatal_error("Target cannot enable pass");
return StandardID;
case cl::BOU_FALSE:
return IdentifyingPassPtr();
}
llvm_unreachable("Invalid command line option state");
}
/// Allow standard passes to be disabled by the command line, regardless of who
/// is adding the pass.
///
/// StandardID is the pass identified in the standard pass pipeline and provided
/// to addPass(). It may be a target-specific ID in the case that the target
/// directly adds its own pass, but in that case we harmlessly fall through.
///
/// TargetID is the pass that the target has configured to override StandardID.
///
/// StandardID may be a pseudo ID. In that case TargetID is the name of the real
/// pass to run. This allows multiple options to control a single pass depending
/// on where in the pipeline that pass is added.
static IdentifyingPassPtr overridePass(AnalysisID StandardID,
IdentifyingPassPtr TargetID) {
if (StandardID == &PostRASchedulerID)
return applyDisable(TargetID, DisablePostRA);
if (StandardID == &BranchFolderPassID)
return applyDisable(TargetID, DisableBranchFold);
if (StandardID == &TailDuplicateID)
return applyDisable(TargetID, DisableTailDuplicate);
if (StandardID == &TargetPassConfig::EarlyTailDuplicateID)
return applyDisable(TargetID, DisableEarlyTailDup);
if (StandardID == &MachineBlockPlacementID)
return applyDisable(TargetID, DisableBlockPlacement);
if (StandardID == &StackSlotColoringID)
return applyDisable(TargetID, DisableSSC);
if (StandardID == &DeadMachineInstructionElimID)
return applyDisable(TargetID, DisableMachineDCE);
if (StandardID == &EarlyIfConverterID)
return applyDisable(TargetID, DisableEarlyIfConversion);
if (StandardID == &MachineLICMID)
return applyDisable(TargetID, DisableMachineLICM);
if (StandardID == &MachineCSEID)
return applyDisable(TargetID, DisableMachineCSE);
if (StandardID == &MachineSchedulerID)
return applyOverride(TargetID, EnableMachineSched, StandardID);
if (StandardID == &TargetPassConfig::PostRAMachineLICMID)
return applyDisable(TargetID, DisablePostRAMachineLICM);
if (StandardID == &MachineSinkingID)
return applyDisable(TargetID, DisableMachineSink);
if (StandardID == &MachineCopyPropagationID)
return applyDisable(TargetID, DisableCopyProp);
return TargetID;
}
//===---------------------------------------------------------------------===//
/// TargetPassConfig
//===---------------------------------------------------------------------===//
INITIALIZE_PASS(TargetPassConfig, "targetpassconfig",
"Target Pass Configuration", false, false)
char TargetPassConfig::ID = 0;
// Pseudo Pass IDs.
char TargetPassConfig::EarlyTailDuplicateID = 0;
char TargetPassConfig::PostRAMachineLICMID = 0;
namespace llvm {
class PassConfigImpl {
public:
// List of passes explicitly substituted by this target. Normally this is
// empty, but it is a convenient way to suppress or replace specific passes
// that are part of a standard pass pipeline without overridding the entire
// pipeline. This mechanism allows target options to inherit a standard pass's
// user interface. For example, a target may disable a standard pass by
// default by substituting a pass ID of zero, and the user may still enable
// that standard pass with an explicit command line option.
DenseMap<AnalysisID,IdentifyingPassPtr> TargetPasses;
/// Store the pairs of <AnalysisID, AnalysisID> of which the second pass
/// is inserted after each instance of the first one.
SmallVector<std::pair<AnalysisID, IdentifyingPassPtr>, 4> InsertedPasses;
};
} // namespace llvm
// Out of line virtual method.
TargetPassConfig::~TargetPassConfig() {
delete Impl;
}
// Out of line constructor provides default values for pass options and
// registers all common codegen passes.
TargetPassConfig::TargetPassConfig(TargetMachine *tm, PassManagerBase &pm)
: ImmutablePass(ID), PM(&pm), StartAfter(nullptr), StopAfter(nullptr),
Started(true), Stopped(false), TM(tm), Impl(nullptr), Initialized(false),
DisableVerify(false),
EnableTailMerge(true) {
Impl = new PassConfigImpl();
// Register all target independent codegen passes to activate their PassIDs,
// including this pass itself.
initializeCodeGen(*PassRegistry::getPassRegistry());
// Substitute Pseudo Pass IDs for real ones.
substitutePass(&EarlyTailDuplicateID, &TailDuplicateID);
substitutePass(&PostRAMachineLICMID, &MachineLICMID);
// Temporarily disable experimental passes.
const TargetSubtargetInfo &ST = TM->getSubtarget<TargetSubtargetInfo>();
if (!ST.useMachineScheduler())
disablePass(&MachineSchedulerID);
}
/// Insert InsertedPassID pass after TargetPassID.
void TargetPassConfig::insertPass(AnalysisID TargetPassID,
IdentifyingPassPtr InsertedPassID) {
assert(((!InsertedPassID.isInstance() &&
TargetPassID != InsertedPassID.getID()) ||
(InsertedPassID.isInstance() &&
TargetPassID != InsertedPassID.getInstance()->getPassID())) &&
"Insert a pass after itself!");
std::pair<AnalysisID, IdentifyingPassPtr> P(TargetPassID, InsertedPassID);
Impl->InsertedPasses.push_back(P);
}
/// createPassConfig - Create a pass configuration object to be used by
/// addPassToEmitX methods for generating a pipeline of CodeGen passes.
///
/// Targets may override this to extend TargetPassConfig.
TargetPassConfig *LLVMTargetMachine::createPassConfig(PassManagerBase &PM) {
return new TargetPassConfig(this, PM);
}
TargetPassConfig::TargetPassConfig()
: ImmutablePass(ID), PM(nullptr) {
llvm_unreachable("TargetPassConfig should not be constructed on-the-fly");
}
// Helper to verify the analysis is really immutable.
void TargetPassConfig::setOpt(bool &Opt, bool Val) {
assert(!Initialized && "PassConfig is immutable");
Opt = Val;
}
void TargetPassConfig::substitutePass(AnalysisID StandardID,
IdentifyingPassPtr TargetID) {
Impl->TargetPasses[StandardID] = TargetID;
}
IdentifyingPassPtr TargetPassConfig::getPassSubstitution(AnalysisID ID) const {
DenseMap<AnalysisID, IdentifyingPassPtr>::const_iterator
I = Impl->TargetPasses.find(ID);
if (I == Impl->TargetPasses.end())
return ID;
return I->second;
}
/// Add a pass to the PassManager if that pass is supposed to be run. If the
/// Started/Stopped flags indicate either that the compilation should start at
/// a later pass or that it should stop after an earlier pass, then do not add
/// the pass. Finally, compare the current pass against the StartAfter
/// and StopAfter options and change the Started/Stopped flags accordingly.
void TargetPassConfig::addPass(Pass *P) {
assert(!Initialized && "PassConfig is immutable");
// Cache the Pass ID here in case the pass manager finds this pass is
// redundant with ones already scheduled / available, and deletes it.
// Fundamentally, once we add the pass to the manager, we no longer own it
// and shouldn't reference it.
AnalysisID PassID = P->getPassID();
if (Started && !Stopped)
PM->add(P);
else
delete P;
if (StopAfter == PassID)
Stopped = true;
if (StartAfter == PassID)
Started = true;
if (Stopped && !Started)
report_fatal_error("Cannot stop compilation after pass that is not run");
}
/// Add a CodeGen pass at this point in the pipeline after checking for target
/// and command line overrides.
///
/// addPass cannot return a pointer to the pass instance because is internal the
/// PassManager and the instance we create here may already be freed.
AnalysisID TargetPassConfig::addPass(AnalysisID PassID) {
IdentifyingPassPtr TargetID = getPassSubstitution(PassID);
IdentifyingPassPtr FinalPtr = overridePass(PassID, TargetID);
if (!FinalPtr.isValid())
return nullptr;
Pass *P;
if (FinalPtr.isInstance())
P = FinalPtr.getInstance();
else {
P = Pass::createPass(FinalPtr.getID());
if (!P)
llvm_unreachable("Pass ID not registered");
}
AnalysisID FinalID = P->getPassID();
addPass(P); // Ends the lifetime of P.
// Add the passes after the pass P if there is any.
for (SmallVectorImpl<std::pair<AnalysisID, IdentifyingPassPtr> >::iterator
I = Impl->InsertedPasses.begin(), E = Impl->InsertedPasses.end();
I != E; ++I) {
if ((*I).first == PassID) {
assert((*I).second.isValid() && "Illegal Pass ID!");
Pass *NP;
if ((*I).second.isInstance())
NP = (*I).second.getInstance();
else {
NP = Pass::createPass((*I).second.getID());
assert(NP && "Pass ID not registered");
}
addPass(NP);
}
}
return FinalID;
}
void TargetPassConfig::printAndVerify(const char *Banner) {
if (TM->shouldPrintMachineCode())
addPass(createMachineFunctionPrinterPass(dbgs(), Banner));
if (VerifyMachineCode)
addPass(createMachineVerifierPass(Banner));
}
/// Add common target configurable passes that perform LLVM IR to IR transforms
/// following machine independent optimization.
void TargetPassConfig::addIRPasses() {
// Basic AliasAnalysis support.
// Add TypeBasedAliasAnalysis before BasicAliasAnalysis so that
// BasicAliasAnalysis wins if they disagree. This is intended to help
// support "obvious" type-punning idioms.
addPass(createTypeBasedAliasAnalysisPass());
addPass(createScopedNoAliasAAPass());
addPass(createBasicAliasAnalysisPass());
// Before running any passes, run the verifier to determine if the input
// coming from the front-end and/or optimizer is valid.
if (!DisableVerify) {
addPass(createVerifierPass());
addPass(createDebugInfoVerifierPass());
}
// Run loop strength reduction before anything else.
if (getOptLevel() != CodeGenOpt::None && !DisableLSR) {
addPass(createLoopStrengthReducePass());
if (PrintLSR)
addPass(createPrintFunctionPass(dbgs(), "\n\n*** Code after LSR ***\n"));
}
addPass(createGCLoweringPass());
// Make sure that no unreachable blocks are instruction selected.
addPass(createUnreachableBlockEliminationPass());
// Prepare expensive constants for SelectionDAG.
if (getOptLevel() != CodeGenOpt::None && !DisableConstantHoisting)
addPass(createConstantHoistingPass());
if (getOptLevel() != CodeGenOpt::None && !DisablePartialLibcallInlining)
addPass(createPartiallyInlineLibCallsPass());
}
/// Turn exception handling constructs into something the code generators can
/// handle.
void TargetPassConfig::addPassesToHandleExceptions() {
switch (TM->getMCAsmInfo()->getExceptionHandlingType()) {
case ExceptionHandling::SjLj:
// SjLj piggy-backs on dwarf for this bit. The cleanups done apply to both
// Dwarf EH prepare needs to be run after SjLj prepare. Otherwise,
// catch info can get misplaced when a selector ends up more than one block
// removed from the parent invoke(s). This could happen when a landing
// pad is shared by multiple invokes and is also a target of a normal
// edge from elsewhere.
addPass(createSjLjEHPreparePass(TM));
// FALLTHROUGH
case ExceptionHandling::DwarfCFI:
case ExceptionHandling::ARM:
case ExceptionHandling::WinEH:
addPass(createDwarfEHPass(TM));
break;
case ExceptionHandling::None:
addPass(createLowerInvokePass());
// The lower invoke pass may create unreachable code. Remove it.
addPass(createUnreachableBlockEliminationPass());
break;
}
}
/// Add pass to prepare the LLVM IR for code generation. This should be done
/// before exception handling preparation passes.
void TargetPassConfig::addCodeGenPrepare() {
if (getOptLevel() != CodeGenOpt::None && !DisableCGP)
addPass(createCodeGenPreparePass(TM));
}
/// Add common passes that perform LLVM IR to IR transforms in preparation for
/// instruction selection.
void TargetPassConfig::addISelPrepare() {
addPreISel();
// Need to verify DebugInfo *before* creating the stack protector analysis.
// It's a function pass, and verifying between it and its users causes a
// crash.
if (!DisableVerify)
addPass(createDebugInfoVerifierPass());
addPass(createStackProtectorPass(TM));
if (PrintISelInput)
addPass(createPrintFunctionPass(
dbgs(), "\n\n*** Final LLVM Code input to ISel ***\n"));
// All passes which modify the LLVM IR are now complete; run the verifier
// to ensure that the IR is valid.
if (!DisableVerify)
addPass(createVerifierPass());
}
/// Add the complete set of target-independent postISel code generator passes.
///
/// This can be read as the standard order of major LLVM CodeGen stages. Stages
/// with nontrivial configuration or multiple passes are broken out below in
/// add%Stage routines.
///
/// Any TargetPassConfig::addXX routine may be overriden by the Target. The
/// addPre/Post methods with empty header implementations allow injecting
/// target-specific fixups just before or after major stages. Additionally,
/// targets have the flexibility to change pass order within a stage by
/// overriding default implementation of add%Stage routines below. Each
/// technique has maintainability tradeoffs because alternate pass orders are
/// not well supported. addPre/Post works better if the target pass is easily
/// tied to a common pass. But if it has subtle dependencies on multiple passes,
/// the target should override the stage instead.
///
/// TODO: We could use a single addPre/Post(ID) hook to allow pass injection
/// before/after any target-independent pass. But it's currently overkill.
void TargetPassConfig::addMachinePasses() {
// Insert a machine instr printer pass after the specified pass.
// If -print-machineinstrs specified, print machineinstrs after all passes.
if (StringRef(PrintMachineInstrs.getValue()).equals(""))
TM->Options.PrintMachineCode = true;
else if (!StringRef(PrintMachineInstrs.getValue())
.equals("option-unspecified")) {
const PassRegistry *PR = PassRegistry::getPassRegistry();
const PassInfo *TPI = PR->getPassInfo(PrintMachineInstrs.getValue());
const PassInfo *IPI = PR->getPassInfo(StringRef("print-machineinstrs"));
assert (TPI && IPI && "Pass ID not registered!");
const char *TID = (const char *)(TPI->getTypeInfo());
const char *IID = (const char *)(IPI->getTypeInfo());
insertPass(TID, IID);
}
// Print the instruction selected machine code...
printAndVerify("After Instruction Selection");
// Expand pseudo-instructions emitted by ISel.
if (addPass(&ExpandISelPseudosID))
printAndVerify("After ExpandISelPseudos");
// Add passes that optimize machine instructions in SSA form.
if (getOptLevel() != CodeGenOpt::None) {
addMachineSSAOptimization();
} else {
// If the target requests it, assign local variables to stack slots relative
// to one another and simplify frame index references where possible.
addPass(&LocalStackSlotAllocationID);
}
// Run pre-ra passes.
if (addPreRegAlloc())
printAndVerify("After PreRegAlloc passes");
// Run register allocation and passes that are tightly coupled with it,
// including phi elimination and scheduling.
if (getOptimizeRegAlloc())
addOptimizedRegAlloc(createRegAllocPass(true));
else
addFastRegAlloc(createRegAllocPass(false));
// Run post-ra passes.
if (addPostRegAlloc())
printAndVerify("After PostRegAlloc passes");
// Insert prolog/epilog code. Eliminate abstract frame index references...
addPass(&PrologEpilogCodeInserterID);
printAndVerify("After PrologEpilogCodeInserter");
/// Add passes that optimize machine instructions after register allocation.
if (getOptLevel() != CodeGenOpt::None)
addMachineLateOptimization();
// Expand pseudo instructions before second scheduling pass.
addPass(&ExpandPostRAPseudosID);
printAndVerify("After ExpandPostRAPseudos");
// Run pre-sched2 passes.
if (addPreSched2())
printAndVerify("After PreSched2 passes");
// Second pass scheduler.
if (getOptLevel() != CodeGenOpt::None) {
if (MISchedPostRA)
addPass(&PostMachineSchedulerID);
else
addPass(&PostRASchedulerID);
printAndVerify("After PostRAScheduler");
}
// GC
if (addGCPasses()) {
if (PrintGCInfo)
addPass(createGCInfoPrinter(dbgs()));
}
// Basic block placement.
if (getOptLevel() != CodeGenOpt::None)
addBlockPlacement();
if (addPreEmitPass())
printAndVerify("After PreEmit passes");
addPass(&StackMapLivenessID);
}
/// Add passes that optimize machine instructions in SSA form.
void TargetPassConfig::addMachineSSAOptimization() {
// Pre-ra tail duplication.
if (addPass(&EarlyTailDuplicateID))
printAndVerify("After Pre-RegAlloc TailDuplicate");
// Optimize PHIs before DCE: removing dead PHI cycles may make more
// instructions dead.
addPass(&OptimizePHIsID);
// This pass merges large allocas. StackSlotColoring is a different pass
// which merges spill slots.
addPass(&StackColoringID);
// If the target requests it, assign local variables to stack slots relative
// to one another and simplify frame index references where possible.
addPass(&LocalStackSlotAllocationID);
// With optimization, dead code should already be eliminated. However
// there is one known exception: lowered code for arguments that are only
// used by tail calls, where the tail calls reuse the incoming stack
// arguments directly (see t11 in test/CodeGen/X86/sibcall.ll).
addPass(&DeadMachineInstructionElimID);
printAndVerify("After codegen DCE pass");
// Allow targets to insert passes that improve instruction level parallelism,
// like if-conversion. Such passes will typically need dominator trees and
// loop info, just like LICM and CSE below.
if (addILPOpts())
printAndVerify("After ILP optimizations");
addPass(&MachineLICMID);
addPass(&MachineCSEID);
addPass(&MachineSinkingID);
printAndVerify("After Machine LICM, CSE and Sinking passes");
addPass(&PeepholeOptimizerID);
// Clean-up the dead code that may have been generated by peephole
// rewriting.
addPass(&DeadMachineInstructionElimID);
printAndVerify("After codegen peephole optimization pass");
}
//===---------------------------------------------------------------------===//
/// Register Allocation Pass Configuration
//===---------------------------------------------------------------------===//
bool TargetPassConfig::getOptimizeRegAlloc() const {
switch (OptimizeRegAlloc) {
case cl::BOU_UNSET: return getOptLevel() != CodeGenOpt::None;
case cl::BOU_TRUE: return true;
case cl::BOU_FALSE: return false;
}
llvm_unreachable("Invalid optimize-regalloc state");
}
/// RegisterRegAlloc's global Registry tracks allocator registration.
MachinePassRegistry RegisterRegAlloc::Registry;
/// A dummy default pass factory indicates whether the register allocator is
/// overridden on the command line.
static FunctionPass *useDefaultRegisterAllocator() { return nullptr; }
static RegisterRegAlloc
defaultRegAlloc("default",
"pick register allocator based on -O option",
useDefaultRegisterAllocator);
/// -regalloc=... command line option.
static cl::opt<RegisterRegAlloc::FunctionPassCtor, false,
RegisterPassParser<RegisterRegAlloc> >
RegAlloc("regalloc",
cl::init(&useDefaultRegisterAllocator),
cl::desc("Register allocator to use"));
/// Instantiate the default register allocator pass for this target for either
/// the optimized or unoptimized allocation path. This will be added to the pass
/// manager by addFastRegAlloc in the unoptimized case or addOptimizedRegAlloc
/// in the optimized case.
///
/// A target that uses the standard regalloc pass order for fast or optimized
/// allocation may still override this for per-target regalloc
/// selection. But -regalloc=... always takes precedence.
FunctionPass *TargetPassConfig::createTargetRegisterAllocator(bool Optimized) {
if (Optimized)
return createGreedyRegisterAllocator();
else
return createFastRegisterAllocator();
}
/// Find and instantiate the register allocation pass requested by this target
/// at the current optimization level. Different register allocators are
/// defined as separate passes because they may require different analysis.
///
/// This helper ensures that the regalloc= option is always available,
/// even for targets that override the default allocator.
///
/// FIXME: When MachinePassRegistry register pass IDs instead of function ptrs,
/// this can be folded into addPass.
FunctionPass *TargetPassConfig::createRegAllocPass(bool Optimized) {
RegisterRegAlloc::FunctionPassCtor Ctor = RegisterRegAlloc::getDefault();
// Initialize the global default.
if (!Ctor) {
Ctor = RegAlloc;
RegisterRegAlloc::setDefault(RegAlloc);
}
if (Ctor != useDefaultRegisterAllocator)
return Ctor();
// With no -regalloc= override, ask the target for a regalloc pass.
return createTargetRegisterAllocator(Optimized);
}
/// Add the minimum set of target-independent passes that are required for
/// register allocation. No coalescing or scheduling.
void TargetPassConfig::addFastRegAlloc(FunctionPass *RegAllocPass) {
addPass(&PHIEliminationID);
addPass(&TwoAddressInstructionPassID);
addPass(RegAllocPass);
printAndVerify("After Register Allocation");
}
/// Add standard target-independent passes that are tightly coupled with
/// optimized register allocation, including coalescing, machine instruction
/// scheduling, and register allocation itself.
void TargetPassConfig::addOptimizedRegAlloc(FunctionPass *RegAllocPass) {
addPass(&ProcessImplicitDefsID);
// LiveVariables currently requires pure SSA form.
//
// FIXME: Once TwoAddressInstruction pass no longer uses kill flags,
// LiveVariables can be removed completely, and LiveIntervals can be directly
// computed. (We still either need to regenerate kill flags after regalloc, or
// preferably fix the scavenger to not depend on them).
addPass(&LiveVariablesID);
// Edge splitting is smarter with machine loop info.
addPass(&MachineLoopInfoID);
addPass(&PHIEliminationID);
// Eventually, we want to run LiveIntervals before PHI elimination.
if (EarlyLiveIntervals)
addPass(&LiveIntervalsID);
addPass(&TwoAddressInstructionPassID);
addPass(&RegisterCoalescerID);
// PreRA instruction scheduling.
if (addPass(&MachineSchedulerID))
printAndVerify("After Machine Scheduling");
// Add the selected register allocation pass.
addPass(RegAllocPass);
printAndVerify("After Register Allocation, before rewriter");
// Allow targets to change the register assignments before rewriting.
if (addPreRewrite())
printAndVerify("After pre-rewrite passes");
// Finally rewrite virtual registers.
addPass(&VirtRegRewriterID);
printAndVerify("After Virtual Register Rewriter");
// Perform stack slot coloring and post-ra machine LICM.
//
// FIXME: Re-enable coloring with register when it's capable of adding
// kill markers.
addPass(&StackSlotColoringID);
// Run post-ra machine LICM to hoist reloads / remats.
//
// FIXME: can this move into MachineLateOptimization?
addPass(&PostRAMachineLICMID);
printAndVerify("After StackSlotColoring and postra Machine LICM");
}
//===---------------------------------------------------------------------===//
/// Post RegAlloc Pass Configuration
//===---------------------------------------------------------------------===//
/// Add passes that optimize machine instructions after register allocation.
void TargetPassConfig::addMachineLateOptimization() {
// Branch folding must be run after regalloc and prolog/epilog insertion.
if (addPass(&BranchFolderPassID))
printAndVerify("After BranchFolding");
// Tail duplication.
// Note that duplicating tail just increases code size and degrades
// performance for targets that require Structured Control Flow.
// In addition it can also make CFG irreducible. Thus we disable it.
if (!TM->requiresStructuredCFG() && addPass(&TailDuplicateID))
printAndVerify("After TailDuplicate");
// Copy propagation.
if (addPass(&MachineCopyPropagationID))
printAndVerify("After copy propagation pass");
}
/// Add standard GC passes.
bool TargetPassConfig::addGCPasses() {
addPass(&GCMachineCodeAnalysisID);
return true;
}
/// Add standard basic block placement passes.
void TargetPassConfig::addBlockPlacement() {
if (addPass(&MachineBlockPlacementID)) {
// Run a separate pass to collect block placement statistics.
if (EnableBlockPlacementStats)
addPass(&MachineBlockPlacementStatsID);
printAndVerify("After machine block placement.");
}
}