void SILCombiner::eraseApply(FullApplySite FAS, const UserListTy &Users) {
// Make sure to release and destroy any owned or in-arguments.
auto FuncType = FAS.getOrigCalleeType();
assert(FuncType->getParameters().size() == FAS.getNumArguments() &&
"mismatching number of arguments");
for (int i = 0, e = FAS.getNumArguments(); i < e; ++i) {
SILParameterInfo PI = FuncType->getParameters()[i];
auto Arg = FAS.getArgument(i);
switch (PI.getConvention()) {
case ParameterConvention::Indirect_In:
Builder.createDestroyAddr(FAS.getLoc(), Arg);
break;
case ParameterConvention::Direct_Owned:
Builder.createReleaseValue(FAS.getLoc(), Arg, Atomicity::Atomic);
break;
case ParameterConvention::Indirect_In_Guaranteed:
case ParameterConvention::Indirect_Inout:
case ParameterConvention::Indirect_InoutAliasable:
case ParameterConvention::Direct_Unowned:
case ParameterConvention::Direct_Deallocating:
case ParameterConvention::Direct_Guaranteed:
break;
}
}
// Erase all of the reference counting instructions (in reverse order to have
// no dangling uses).
for (auto rit = Users.rbegin(), re = Users.rend(); rit != re; ++rit)
eraseInstFromFunction(**rit);
// And the Apply itself.
eraseInstFromFunction(*FAS.getInstruction());
}
// A utility function for cloning the apply instruction.
static FullApplySite CloneApply(FullApplySite AI, SILBuilder &Builder) {
// Clone the Apply.
Builder.setCurrentDebugScope(AI.getDebugScope());
Builder.addOpenedArchetypeOperands(AI.getInstruction());
auto Args = AI.getArguments();
SmallVector<SILValue, 8> Ret(Args.size());
for (unsigned i = 0, e = Args.size(); i != e; ++i)
Ret[i] = Args[i];
FullApplySite NAI;
switch (AI.getInstruction()->getKind()) {
case SILInstructionKind::ApplyInst:
NAI = Builder.createApply(AI.getLoc(), AI.getCallee(),
AI.getSubstitutions(),
Ret,
cast<ApplyInst>(AI)->isNonThrowing());
break;
case SILInstructionKind::TryApplyInst: {
auto *TryApplyI = cast<TryApplyInst>(AI.getInstruction());
NAI = Builder.createTryApply(AI.getLoc(), AI.getCallee(),
AI.getSubstitutions(),
Ret,
TryApplyI->getNormalBB(),
TryApplyI->getErrorBB());
}
break;
default:
llvm_unreachable("Trying to clone an unsupported apply instruction");
}
NAI.getInstruction();
return NAI;
}
SILValue SILInliner::borrowFunctionArgument(SILValue callArg,
FullApplySite AI) {
if (!AI.getFunction()->hasQualifiedOwnership()
|| callArg.getOwnershipKind() != ValueOwnershipKind::Owned) {
return callArg;
}
auto *borrow = getBuilder().createBeginBorrow(AI.getLoc(), callArg);
if (auto *tryAI = dyn_cast<TryApplyInst>(AI)) {
SILBuilder returnBuilder(tryAI->getNormalBB()->begin());
returnBuilder.createEndBorrow(AI.getLoc(), borrow, callArg);
SILBuilder throwBuilder(tryAI->getErrorBB()->begin());
throwBuilder.createEndBorrow(AI.getLoc(), borrow, callArg);
} else {
SILBuilder returnBuilder(std::next(AI.getInstruction()->getIterator()));
returnBuilder.createEndBorrow(AI.getLoc(), borrow, callArg);
}
return borrow;
}
void ArgumentDescriptor::addCallerArgs(
SILBuilder &B, FullApplySite FAS,
llvm::SmallVectorImpl<SILValue> &NewArgs) const {
if (IsDead)
return;
SILValue Arg = FAS.getArgument(Index);
if (!shouldExplode()) {
NewArgs.push_back(Arg);
return;
}
ProjTree.createTreeFromValue(B, FAS.getLoc(), Arg, NewArgs);
}
/// Inlines all mandatory inlined functions into the body of a function,
/// first recursively inlining all mandatory apply instructions in those
/// functions into their bodies if necessary.
///
/// \param F the function to be processed
/// \param AI nullptr if this is being called from the top level; the relevant
/// ApplyInst requiring the recursive call when non-null
/// \param FullyInlinedSet the set of all functions already known to be fully
/// processed, to avoid processing them over again
/// \param SetFactory an instance of ImmutableFunctionSet::Factory
/// \param CurrentInliningSet the set of functions currently being inlined in
/// the current call stack of recursive calls
///
/// \returns true if successful, false if failed due to circular inlining.
static bool
runOnFunctionRecursively(SILOptFunctionBuilder &FuncBuilder,
SILFunction *F, FullApplySite AI,
DenseFunctionSet &FullyInlinedSet,
ImmutableFunctionSet::Factory &SetFactory,
ImmutableFunctionSet CurrentInliningSet,
ClassHierarchyAnalysis *CHA) {
// Avoid reprocessing functions needlessly.
if (FullyInlinedSet.count(F))
return true;
// Prevent attempt to circularly inline.
if (CurrentInliningSet.contains(F)) {
// This cannot happen on a top-level call, so AI should be non-null.
assert(AI && "Cannot have circular inline without apply");
SILLocation L = AI.getLoc();
assert(L && "Must have location for transparent inline apply");
diagnose(F->getModule().getASTContext(), L.getStartSourceLoc(),
diag::circular_transparent);
return false;
}
// Add to the current inlining set (immutably, so we only affect the set
// during this call and recursive subcalls).
CurrentInliningSet = SetFactory.add(CurrentInliningSet, F);
SmallVector<std::pair<SILValue, ParameterConvention>, 16> CaptureArgs;
SmallVector<SILValue, 32> FullArgs;
// Visiting blocks in reverse order avoids revisiting instructions after block
// splitting, which would be quadratic.
for (auto BI = F->rbegin(), BE = F->rend(), nextBB = BI; BI != BE;
BI = nextBB) {
// After inlining, the block iterator will be adjusted to point to the last
// block containing inlined instructions. This way, the inlined function
// body will be reprocessed within the caller's context without revisiting
// any original instructions.
nextBB = std::next(BI);
// While iterating over this block, instructions are inserted and deleted.
// To avoid quadratic block splitting, instructions must be processed in
// reverse order (block splitting reassigned the parent pointer of all
// instructions below the split point).
for (auto II = BI->rbegin(); II != BI->rend(); ++II) {
FullApplySite InnerAI = FullApplySite::isa(&*II);
if (!InnerAI)
continue;
// *NOTE* If devirtualization succeeds, devirtInst may not be InnerAI,
// but a casted result of InnerAI or even a block argument due to
// abstraction changes when calling the witness or class method.
auto *devirtInst = tryDevirtualizeApplyHelper(InnerAI, CHA);
// Restore II to the current apply site.
II = devirtInst->getReverseIterator();
// If the devirtualized call result is no longer a invalid FullApplySite,
// then it has succeeded, but the result is not immediately inlinable.
InnerAI = FullApplySite::isa(devirtInst);
if (!InnerAI)
continue;
SILValue CalleeValue = InnerAI.getCallee();
bool IsThick;
PartialApplyInst *PAI;
SILFunction *CalleeFunction = getCalleeFunction(
F, InnerAI, IsThick, CaptureArgs, FullArgs, PAI);
if (!CalleeFunction)
continue;
// Then recursively process it first before trying to inline it.
if (!runOnFunctionRecursively(FuncBuilder, CalleeFunction, InnerAI,
FullyInlinedSet, SetFactory,
CurrentInliningSet, CHA)) {
// If we failed due to circular inlining, then emit some notes to
// trace back the failure if we have more information.
// FIXME: possibly it could be worth recovering and attempting other
// inlines within this same recursive call rather than simply
// propagating the failure.
if (AI) {
SILLocation L = AI.getLoc();
assert(L && "Must have location for transparent inline apply");
diagnose(F->getModule().getASTContext(), L.getStartSourceLoc(),
diag::note_while_inlining);
}
return false;
}
// Get our list of substitutions.
auto Subs = (PAI
? PAI->getSubstitutionMap()
: InnerAI.getSubstitutionMap());
SILOpenedArchetypesTracker OpenedArchetypesTracker(F);
F->getModule().registerDeleteNotificationHandler(
&OpenedArchetypesTracker);
// The callee only needs to know about opened archetypes used in
// the substitution list.
OpenedArchetypesTracker.registerUsedOpenedArchetypes(
InnerAI.getInstruction());
if (PAI) {
OpenedArchetypesTracker.registerUsedOpenedArchetypes(PAI);
}
SILInliner Inliner(FuncBuilder, SILInliner::InlineKind::MandatoryInline,
Subs, OpenedArchetypesTracker);
if (!Inliner.canInlineApplySite(InnerAI))
continue;
// Inline function at I, which also changes I to refer to the first
// instruction inlined in the case that it succeeds. We purposely
// process the inlined body after inlining, because the inlining may
// have exposed new inlining opportunities beyond those present in
// the inlined function when processed independently.
LLVM_DEBUG(llvm::errs() << "Inlining @" << CalleeFunction->getName()
<< " into @" << InnerAI.getFunction()->getName()
<< "\n");
// If we intend to inline a thick function, then we need to balance the
// reference counts for correctness.
if (IsThick) {
bool IsCalleeGuaranteed =
PAI &&
PAI->getType().castTo<SILFunctionType>()->isCalleeGuaranteed();
fixupReferenceCounts(InnerAI.getInstruction(), CalleeValue, CaptureArgs,
IsCalleeGuaranteed);
}
// Register a callback to record potentially unused function values after
// inlining.
ClosureCleanup closureCleanup;
Inliner.setDeletionCallback([&closureCleanup](SILInstruction *I) {
closureCleanup.recordDeadFunction(I);
});
// Inlining deletes the apply, and can introduce multiple new basic
// blocks. After this, CalleeValue and other instructions may be invalid.
// nextBB will point to the last inlined block
auto firstInlinedInstAndLastBB =
Inliner.inlineFunction(CalleeFunction, InnerAI, FullArgs);
nextBB = firstInlinedInstAndLastBB.second->getReverseIterator();
++NumMandatoryInlines;
// The IR is now valid, and trivial dead arguments are removed. However,
// we may be able to remove dead callee computations (e.g. dead
// partial_apply closures).
closureCleanup.cleanupDeadClosures(F);
// Resume inlining within nextBB, which contains only the inlined
// instructions and possibly instructions in the original call block that
// have not yet been visited.
break;
}
}
// Keep track of full inlined functions so we don't waste time recursively
// reprocessing them.
FullyInlinedSet.insert(F);
return true;
}
/// \brief Inlines all mandatory inlined functions into the body of a function,
/// first recursively inlining all mandatory apply instructions in those
/// functions into their bodies if necessary.
///
/// \param F the function to be processed
/// \param AI nullptr if this is being called from the top level; the relevant
/// ApplyInst requiring the recursive call when non-null
/// \param FullyInlinedSet the set of all functions already known to be fully
/// processed, to avoid processing them over again
/// \param SetFactory an instance of ImmutableFunctionSet::Factory
/// \param CurrentInliningSet the set of functions currently being inlined in
/// the current call stack of recursive calls
///
/// \returns true if successful, false if failed due to circular inlining.
static bool
runOnFunctionRecursively(SILFunction *F, FullApplySite AI,
SILModule::LinkingMode Mode,
DenseFunctionSet &FullyInlinedSet,
ImmutableFunctionSet::Factory &SetFactory,
ImmutableFunctionSet CurrentInliningSet,
ClassHierarchyAnalysis *CHA) {
// Avoid reprocessing functions needlessly.
if (FullyInlinedSet.count(F))
return true;
// Prevent attempt to circularly inline.
if (CurrentInliningSet.contains(F)) {
// This cannot happen on a top-level call, so AI should be non-null.
assert(AI && "Cannot have circular inline without apply");
SILLocation L = AI.getLoc();
assert(L && "Must have location for transparent inline apply");
diagnose(F->getModule().getASTContext(), L.getStartSourceLoc(),
diag::circular_transparent);
return false;
}
// Add to the current inlining set (immutably, so we only affect the set
// during this call and recursive subcalls).
CurrentInliningSet = SetFactory.add(CurrentInliningSet, F);
SmallVector<SILValue, 16> CaptureArgs;
SmallVector<SILValue, 32> FullArgs;
for (auto FI = F->begin(), FE = F->end(); FI != FE; ++FI) {
for (auto I = FI->begin(), E = FI->end(); I != E; ++I) {
FullApplySite InnerAI = FullApplySite::isa(&*I);
if (!InnerAI)
continue;
auto *ApplyBlock = InnerAI.getParent();
auto NewInstPair = tryDevirtualizeApply(InnerAI, CHA);
if (auto *NewInst = NewInstPair.first) {
replaceDeadApply(InnerAI, NewInst);
if (auto *II = dyn_cast<SILInstruction>(NewInst))
I = II->getIterator();
else
I = NewInst->getParentBB()->begin();
auto NewAI = FullApplySite::isa(NewInstPair.second.getInstruction());
if (!NewAI)
continue;
InnerAI = NewAI;
}
SILLocation Loc = InnerAI.getLoc();
SILValue CalleeValue = InnerAI.getCallee();
bool IsThick;
PartialApplyInst *PAI;
SILFunction *CalleeFunction = getCalleeFunction(InnerAI, IsThick,
CaptureArgs, FullArgs,
PAI,
Mode);
if (!CalleeFunction ||
CalleeFunction->isTransparent() == IsNotTransparent)
continue;
// Then recursively process it first before trying to inline it.
if (!runOnFunctionRecursively(CalleeFunction, InnerAI, Mode,
FullyInlinedSet, SetFactory,
CurrentInliningSet, CHA)) {
// If we failed due to circular inlining, then emit some notes to
// trace back the failure if we have more information.
// FIXME: possibly it could be worth recovering and attempting other
// inlines within this same recursive call rather than simply
// propagating the failure.
if (AI) {
SILLocation L = AI.getLoc();
assert(L && "Must have location for transparent inline apply");
diagnose(F->getModule().getASTContext(), L.getStartSourceLoc(),
diag::note_while_inlining);
}
return false;
}
// Inline function at I, which also changes I to refer to the first
// instruction inlined in the case that it succeeds. We purposely
// process the inlined body after inlining, because the inlining may
// have exposed new inlining opportunities beyond those present in
// the inlined function when processed independently.
DEBUG(llvm::errs() << "Inlining @" << CalleeFunction->getName()
<< " into @" << InnerAI.getFunction()->getName()
<< "\n");
// Decrement our iterator (carefully, to avoid going off the front) so it
// is valid after inlining is done. Inlining deletes the apply, and can
// introduce multiple new basic blocks.
if (I != ApplyBlock->begin())
--I;
else
I = ApplyBlock->end();
TypeSubstitutionMap ContextSubs;
std::vector<Substitution> ApplySubs(InnerAI.getSubstitutions());
if (PAI) {
auto PAISubs = PAI->getSubstitutions();
ApplySubs.insert(ApplySubs.end(), PAISubs.begin(), PAISubs.end());
}
ContextSubs.copyFrom(CalleeFunction->getContextGenericParams()
->getSubstitutionMap(ApplySubs));
SILInliner Inliner(*F, *CalleeFunction,
SILInliner::InlineKind::MandatoryInline,
ContextSubs, ApplySubs);
if (!Inliner.inlineFunction(InnerAI, FullArgs)) {
I = InnerAI.getInstruction()->getIterator();
continue;
}
// Inlining was successful. Remove the apply.
InnerAI.getInstruction()->eraseFromParent();
// Reestablish our iterator if it wrapped.
if (I == ApplyBlock->end())
I = ApplyBlock->begin();
else
++I;
// If the inlined apply was a thick function, then we need to balance the
// reference counts for correctness.
if (IsThick)
fixupReferenceCounts(I, Loc, CalleeValue, CaptureArgs);
// Now that the IR is correct, see if we can remove dead callee
// computations (e.g. dead partial_apply closures).
cleanupCalleeValue(CalleeValue, CaptureArgs, FullArgs);
// Reposition iterators possibly invalidated by mutation.
FI = SILFunction::iterator(ApplyBlock);
I = ApplyBlock->begin();
E = ApplyBlock->end();
++NumMandatoryInlines;
}
}
// Keep track of full inlined functions so we don't waste time recursively
// reprocessing them.
FullyInlinedSet.insert(F);
return true;
}
/// \brief Devirtualize an apply of a class method.
///
/// \p AI is the apply to devirtualize.
/// \p ClassOrMetatype is a class value or metatype value that is the
/// self argument of the apply we will devirtualize.
/// return the result value of the new ApplyInst if created one or null.
DevirtualizationResult swift::devirtualizeClassMethod(FullApplySite AI,
SILValue ClassOrMetatype) {
DEBUG(llvm::dbgs() << " Trying to devirtualize : " << *AI.getInstruction());
SILModule &Mod = AI.getModule();
auto *CMI = cast<ClassMethodInst>(AI.getCallee());
auto ClassOrMetatypeType = ClassOrMetatype.getType();
auto *F = getTargetClassMethod(Mod, ClassOrMetatypeType, CMI->getMember());
CanSILFunctionType GenCalleeType = F->getLoweredFunctionType();
auto Subs = getSubstitutionsForCallee(Mod, GenCalleeType,
ClassOrMetatypeType, AI);
CanSILFunctionType SubstCalleeType = GenCalleeType;
if (GenCalleeType->isPolymorphic())
SubstCalleeType = GenCalleeType->substGenericArgs(Mod, Mod.getSwiftModule(), Subs);
SILBuilderWithScope B(AI.getInstruction());
FunctionRefInst *FRI = B.createFunctionRef(AI.getLoc(), F);
// Create the argument list for the new apply, casting when needed
// in order to handle covariant indirect return types and
// contravariant argument types.
llvm::SmallVector<SILValue, 8> NewArgs;
auto Args = AI.getArguments();
auto ParamTypes = SubstCalleeType->getParameterSILTypes();
for (unsigned i = 0, e = Args.size() - 1; i != e; ++i)
NewArgs.push_back(castValueToABICompatibleType(&B, AI.getLoc(), Args[i],
Args[i].getType(),
ParamTypes[i]).getValue());
// Add the self argument, upcasting if required because we're
// calling a base class's method.
auto SelfParamTy = SubstCalleeType->getSelfParameter().getSILType();
NewArgs.push_back(castValueToABICompatibleType(&B, AI.getLoc(),
ClassOrMetatype,
ClassOrMetatypeType,
SelfParamTy).getValue());
// If we have a direct return type, make sure we use the subst callee return
// type. If we have an indirect return type, AI's return type of the empty
// tuple should be ok.
SILType ResultTy = AI.getType();
if (!SubstCalleeType->hasIndirectResult()) {
ResultTy = SubstCalleeType->getSILResult();
}
SILType SubstCalleeSILType =
SILType::getPrimitiveObjectType(SubstCalleeType);
FullApplySite NewAI;
SILBasicBlock *ResultBB = nullptr;
SILBasicBlock *NormalBB = nullptr;
SILValue ResultValue;
bool ResultCastRequired = false;
SmallVector<Operand *, 4> OriginalResultUses;
if (!isa<TryApplyInst>(AI)) {
NewAI = B.createApply(AI.getLoc(), FRI, SubstCalleeSILType, ResultTy,
Subs, NewArgs, cast<ApplyInst>(AI)->isNonThrowing());
ResultValue = SILValue(NewAI.getInstruction(), 0);
} else {
auto *TAI = cast<TryApplyInst>(AI);
// Create new normal and error BBs only if:
// - re-using a BB would create a critical edge
// - or, the result of the new apply would be of different
// type than the argument of the original normal BB.
if (TAI->getNormalBB()->getSinglePredecessor())
ResultBB = TAI->getNormalBB();
else {
ResultBB = B.getFunction().createBasicBlock();
ResultBB->createBBArg(ResultTy);
}
NormalBB = TAI->getNormalBB();
SILBasicBlock *ErrorBB = nullptr;
if (TAI->getErrorBB()->getSinglePredecessor())
ErrorBB = TAI->getErrorBB();
else {
ErrorBB = B.getFunction().createBasicBlock();
ErrorBB->createBBArg(TAI->getErrorBB()->getBBArg(0)->getType());
}
NewAI = B.createTryApply(AI.getLoc(), FRI, SubstCalleeSILType,
Subs, NewArgs,
ResultBB, ErrorBB);
if (ErrorBB != TAI->getErrorBB()) {
B.setInsertionPoint(ErrorBB);
B.createBranch(TAI->getLoc(), TAI->getErrorBB(),
{ErrorBB->getBBArg(0)});
}
// Does the result value need to be casted?
ResultCastRequired = ResultTy != NormalBB->getBBArg(0)->getType();
if (ResultBB != NormalBB)
B.setInsertionPoint(ResultBB);
else if (ResultCastRequired) {
B.setInsertionPoint(NormalBB->begin());
// Collect all uses, before casting.
for (auto *Use : NormalBB->getBBArg(0)->getUses()) {
OriginalResultUses.push_back(Use);
}
NormalBB->getBBArg(0)->replaceAllUsesWith(SILUndef::get(AI.getType(), Mod));
NormalBB->replaceBBArg(0, ResultTy, nullptr);
}
// The result value is passed as a parameter to the normal block.
ResultValue = ResultBB->getBBArg(0);
}
// Check if any casting is required for the return value.
ResultValue = castValueToABICompatibleType(&B, NewAI.getLoc(), ResultValue,
ResultTy, AI.getType()).getValue();
DEBUG(llvm::dbgs() << " SUCCESS: " << F->getName() << "\n");
NumClassDevirt++;
if (NormalBB) {
if (NormalBB != ResultBB) {
// If artificial normal BB was introduced, branch
// to the original normal BB.
B.createBranch(NewAI.getLoc(), NormalBB, { ResultValue });
} else if (ResultCastRequired) {
// Update all original uses by the new value.
for(auto *Use: OriginalResultUses) {
Use->set(ResultValue);
}
}
return std::make_pair(NewAI.getInstruction(), NewAI);
}
// We need to return a pair of values here:
// - the first one is the actual result of the devirtualized call, possibly
// casted into an appropriate type. This SILValue may be a BB arg, if it
// was a cast between optional types.
// - the second one is the new apply site.
return std::make_pair(ResultValue.getDef(), NewAI);
}
/// \brief Inlines all mandatory inlined functions into the body of a function,
/// first recursively inlining all mandatory apply instructions in those
/// functions into their bodies if necessary.
///
/// \param F the function to be processed
/// \param AI nullptr if this is being called from the top level; the relevant
/// ApplyInst requiring the recursive call when non-null
/// \param FullyInlinedSet the set of all functions already known to be fully
/// processed, to avoid processing them over again
/// \param SetFactory an instance of ImmutableFunctionSet::Factory
/// \param CurrentInliningSet the set of functions currently being inlined in
/// the current call stack of recursive calls
///
/// \returns true if successful, false if failed due to circular inlining.
static bool
runOnFunctionRecursively(SILFunction *F, FullApplySite AI,
DenseFunctionSet &FullyInlinedSet,
ImmutableFunctionSet::Factory &SetFactory,
ImmutableFunctionSet CurrentInliningSet,
ClassHierarchyAnalysis *CHA) {
// Avoid reprocessing functions needlessly.
if (FullyInlinedSet.count(F))
return true;
// Prevent attempt to circularly inline.
if (CurrentInliningSet.contains(F)) {
// This cannot happen on a top-level call, so AI should be non-null.
assert(AI && "Cannot have circular inline without apply");
SILLocation L = AI.getLoc();
assert(L && "Must have location for transparent inline apply");
diagnose(F->getModule().getASTContext(), L.getStartSourceLoc(),
diag::circular_transparent);
return false;
}
// Add to the current inlining set (immutably, so we only affect the set
// during this call and recursive subcalls).
CurrentInliningSet = SetFactory.add(CurrentInliningSet, F);
SmallVector<std::pair<SILValue, ParameterConvention>, 16> CaptureArgs;
SmallVector<SILValue, 32> FullArgs;
for (auto BI = F->begin(), BE = F->end(); BI != BE; ++BI) {
for (auto II = BI->begin(), IE = BI->end(); II != IE; ++II) {
FullApplySite InnerAI = FullApplySite::isa(&*II);
if (!InnerAI)
continue;
auto *ApplyBlock = InnerAI.getParent();
// *NOTE* If devirtualization succeeds, sometimes II will not be InnerAI,
// but a casted result of InnerAI or even a block argument due to
// abstraction changes when calling the witness or class method. We still
// know that InnerAI dominates II though.
std::tie(InnerAI, II) = tryDevirtualizeApplyHelper(InnerAI, II, CHA);
if (!InnerAI)
continue;
SILValue CalleeValue = InnerAI.getCallee();
bool IsThick;
PartialApplyInst *PAI;
SILFunction *CalleeFunction = getCalleeFunction(
F, InnerAI, IsThick, CaptureArgs, FullArgs, PAI);
if (!CalleeFunction)
continue;
// Then recursively process it first before trying to inline it.
if (!runOnFunctionRecursively(CalleeFunction, InnerAI,
FullyInlinedSet, SetFactory,
CurrentInliningSet, CHA)) {
// If we failed due to circular inlining, then emit some notes to
// trace back the failure if we have more information.
// FIXME: possibly it could be worth recovering and attempting other
// inlines within this same recursive call rather than simply
// propagating the failure.
if (AI) {
SILLocation L = AI.getLoc();
assert(L && "Must have location for transparent inline apply");
diagnose(F->getModule().getASTContext(), L.getStartSourceLoc(),
diag::note_while_inlining);
}
return false;
}
// Get our list of substitutions.
auto Subs = (PAI
? PAI->getSubstitutionMap()
: InnerAI.getSubstitutionMap());
SILOpenedArchetypesTracker OpenedArchetypesTracker(F);
F->getModule().registerDeleteNotificationHandler(
&OpenedArchetypesTracker);
// The callee only needs to know about opened archetypes used in
// the substitution list.
OpenedArchetypesTracker.registerUsedOpenedArchetypes(
InnerAI.getInstruction());
if (PAI) {
OpenedArchetypesTracker.registerUsedOpenedArchetypes(PAI);
}
SILInliner Inliner(*F, *CalleeFunction,
SILInliner::InlineKind::MandatoryInline, Subs,
OpenedArchetypesTracker);
if (!Inliner.canInlineFunction(InnerAI)) {
// See comment above about casting when devirtualizing and how this
// sometimes causes II and InnerAI to be different and even in different
// blocks.
II = InnerAI.getInstruction()->getIterator();
continue;
}
// Inline function at I, which also changes I to refer to the first
// instruction inlined in the case that it succeeds. We purposely
// process the inlined body after inlining, because the inlining may
// have exposed new inlining opportunities beyond those present in
// the inlined function when processed independently.
LLVM_DEBUG(llvm::errs() << "Inlining @" << CalleeFunction->getName()
<< " into @" << InnerAI.getFunction()->getName()
<< "\n");
// If we intend to inline a thick function, then we need to balance the
// reference counts for correctness.
if (IsThick) {
bool IsCalleeGuaranteed =
PAI &&
PAI->getType().castTo<SILFunctionType>()->isCalleeGuaranteed();
fixupReferenceCounts(II, CalleeValue, CaptureArgs, IsCalleeGuaranteed);
}
// Decrement our iterator (carefully, to avoid going off the front) so it
// is valid after inlining is done. Inlining deletes the apply, and can
// introduce multiple new basic blocks.
II = prev_or_default(II, ApplyBlock->begin(), ApplyBlock->end());
Inliner.inlineFunction(InnerAI, FullArgs);
// We were able to inline successfully. Remove the apply.
InnerAI.getInstruction()->eraseFromParent();
// Reestablish our iterator if it wrapped.
if (II == ApplyBlock->end())
II = ApplyBlock->begin();
// Update the iterator when instructions are removed.
DeleteInstructionsHandler DeletionHandler(II);
// Now that the IR is correct, see if we can remove dead callee
// computations (e.g. dead partial_apply closures).
cleanupCalleeValue(CalleeValue, FullArgs);
// Reposition iterators possibly invalidated by mutation.
BI = SILFunction::iterator(ApplyBlock);
IE = ApplyBlock->end();
assert(BI == SILFunction::iterator(II->getParent()) &&
"Mismatch between the instruction and basic block");
++NumMandatoryInlines;
}
}
// Keep track of full inlined functions so we don't waste time recursively
// reprocessing them.
FullyInlinedSet.insert(F);
return true;
}
/// Update the callsite to pass in the correct arguments.
static void rewriteApplyInst(const CallSiteDescriptor &CSDesc,
SILFunction *NewF) {
FullApplySite AI = CSDesc.getApplyInst();
SingleValueInstruction *Closure = CSDesc.getClosure();
SILBuilderWithScope Builder(Closure);
FunctionRefInst *FRI = Builder.createFunctionRef(AI.getLoc(), NewF);
// Create the args for the new apply by removing the closure argument...
llvm::SmallVector<SILValue, 8> NewArgs;
unsigned Index = 0;
for (auto Arg : AI.getArguments()) {
if (Index != CSDesc.getClosureIndex())
NewArgs.push_back(Arg);
Index++;
}
// ... and appending the captured arguments. We also insert retains here at
// the location of the original closure. This is needed to balance the
// implicit release of all captured arguments that occurs when the partial
// apply is destroyed.
SILModule &M = NewF->getModule();
auto ClosureCalleeConv = CSDesc.getClosureCallee()->getConventions();
unsigned ClosureArgIdx =
ClosureCalleeConv.getNumSILArguments() - CSDesc.getNumArguments();
for (auto Arg : CSDesc.getArguments()) {
SILType ArgTy = Arg->getType();
// If our argument is of trivial type, continue...
if (ArgTy.isTrivial(M)) {
NewArgs.push_back(Arg);
++ClosureArgIdx;
continue;
}
auto ArgConvention =
ClosureCalleeConv.getSILArgumentConvention(ClosureArgIdx);
// Non-inout indirect arguments are not supported yet.
assert(ArgTy.isObject() ||
!isNonInoutIndirectSILArgument(Arg, ArgConvention));
// If argument is not an object and it is an inout parameter,
// continue...
if (!ArgTy.isObject() &&
!isNonInoutIndirectSILArgument(Arg, ArgConvention)) {
NewArgs.push_back(Arg);
++ClosureArgIdx;
continue;
}
// TODO: When we support address types, this code path will need to be
// updated.
// We need to balance the consumed argument of the new partial_apply in the
// specialized callee by a retain. If both the original partial_apply and
// the apply of the callee are in the same basic block we can assume they
// are executed the same number of times. Therefore it is sufficient to just
// retain the argument at the site of the original partial_apply.
//
// %closure = partial_apply (%arg)
// = apply %callee(%closure)
// =>
// retain %arg
// %closure = partial_apply (%arg)
// apply %specialized_callee(..., %arg)
//
// However, if they are not in the same basic block the callee might be
// executed more frequently than the closure (for example, if the closure is
// created in a loop preheader and the callee taking the closure is executed
// in the loop). In such a case we must keep the argument live across the
// call site of the callee and emit a matching retain for every invocation
// of the callee.
//
// %closure = partial_apply (%arg)
//
// while () {
// = %callee(%closure)
// }
// =>
// retain %arg
// %closure = partial_apply (%arg)
//
// while () {
// retain %arg
// apply %specialized_callee(.., %arg)
// }
// release %arg
//
if (AI.getParent() != Closure->getParent()) {
// Emit the retain and release that keeps the argument life across the
// callee using the closure.
CSDesc.extendArgumentLifetime(Arg, ArgConvention);
// Emit the retain that matches the captured argument by the
// partial_apply
// in the callee that is consumed by the partial_apply.
Builder.setInsertionPoint(AI.getInstruction());
Builder.createRetainValue(Closure->getLoc(), Arg,
Builder.getDefaultAtomicity());
} else {
Builder.createRetainValue(Closure->getLoc(), Arg,
Builder.getDefaultAtomicity());
}
NewArgs.push_back(Arg);
++ClosureArgIdx;
}
Builder.setInsertionPoint(AI.getInstruction());
FullApplySite NewAI;
switch (AI.getKind()) {
case FullApplySiteKind::TryApplyInst: {
auto *TAI = cast<TryApplyInst>(AI);
NewAI = Builder.createTryApply(AI.getLoc(), FRI,
SubstitutionMap(), NewArgs,
TAI->getNormalBB(), TAI->getErrorBB());
// If we passed in the original closure as @owned, then insert a release
// right after NewAI. This is to balance the +1 from being an @owned
// argument to AI.
if (!CSDesc.isClosureConsumed() || !CSDesc.closureHasRefSemanticContext()) {
break;
}
Builder.setInsertionPoint(TAI->getNormalBB()->begin());
Builder.createReleaseValue(Closure->getLoc(), Closure,
Builder.getDefaultAtomicity());
Builder.setInsertionPoint(TAI->getErrorBB()->begin());
Builder.createReleaseValue(Closure->getLoc(), Closure,
Builder.getDefaultAtomicity());
Builder.setInsertionPoint(AI.getInstruction());
break;
}
case FullApplySiteKind::ApplyInst: {
auto oldApply = cast<ApplyInst>(AI);
auto newApply = Builder.createApply(oldApply->getLoc(), FRI,
SubstitutionMap(),
NewArgs, oldApply->isNonThrowing());
// If we passed in the original closure as @owned, then insert a release
// right after NewAI. This is to balance the +1 from being an @owned
// argument to AI.
if (CSDesc.isClosureConsumed() && CSDesc.closureHasRefSemanticContext())
Builder.createReleaseValue(Closure->getLoc(), Closure,
Builder.getDefaultAtomicity());
// Replace all uses of the old apply with the new apply.
oldApply->replaceAllUsesWith(newApply);
break;
}
case FullApplySiteKind::BeginApplyInst:
llvm_unreachable("Unhandled case");
}
// Erase the old apply.
AI.getInstruction()->eraseFromParent();
// TODO: Maybe include invalidation code for CallSiteDescriptor after we erase
// AI from parent?
}
/// Process an apply instruction which uses a partial_apply
/// as its callee.
/// Returns true on success.
bool PartialApplyCombiner::processSingleApply(FullApplySite AI) {
Builder.setInsertionPoint(AI.getInstruction());
Builder.setCurrentDebugScope(AI.getDebugScope());
// Prepare the args.
SmallVector<SILValue, 8> Args;
// First the ApplyInst args.
for (auto Op : AI.getArguments())
Args.push_back(Op);
SILInstruction *InsertionPoint = &*Builder.getInsertionPoint();
// Next, the partial apply args.
// Pre-process partial_apply arguments only once, lazily.
if (isFirstTime) {
isFirstTime = false;
if (!allocateTemporaries())
return false;
}
// Now, copy over the partial apply args.
for (auto Op : PAI->getArguments()) {
auto Arg = Op;
// If there is new temporary for this argument, use it instead.
if (isa<AllocStackInst>(Arg)) {
if (ArgToTmp.count(Arg)) {
Op = ArgToTmp.lookup(Arg);
}
}
Args.push_back(Op);
}
Builder.setInsertionPoint(InsertionPoint);
Builder.setCurrentDebugScope(AI.getDebugScope());
// The thunk that implements the partial apply calls the closure function
// that expects all arguments to be consumed by the function. However, the
// captured arguments are not arguments of *this* apply, so they are not
// pre-incremented. When we combine the partial_apply and this apply into
// a new apply we need to retain all of the closure non-address type
// arguments.
auto ParamInfo = PAI->getSubstCalleeType()->getParameters();
auto PartialApplyArgs = PAI->getArguments();
// Set of arguments that need to be released after each invocation.
SmallVector<SILValue, 8> ToBeReleasedArgs;
for (unsigned i = 0, e = PartialApplyArgs.size(); i < e; ++i) {
SILValue Arg = PartialApplyArgs[i];
if (!Arg->getType().isAddress()) {
// Retain the argument as the callee may consume it.
Builder.emitRetainValueOperation(PAI->getLoc(), Arg);
// For non consumed parameters (e.g. guaranteed), we also need to
// insert releases after each apply instruction that we create.
if (!ParamInfo[ParamInfo.size() - PartialApplyArgs.size() + i].
isConsumed())
ToBeReleasedArgs.push_back(Arg);
}
}
auto *F = FRI->getReferencedFunction();
SILType FnType = F->getLoweredType();
SILType ResultTy = F->getLoweredFunctionType()->getSILResult();
ArrayRef<Substitution> Subs = PAI->getSubstitutions();
if (!Subs.empty()) {
FnType = FnType.substGenericArgs(PAI->getModule(), Subs);
ResultTy = FnType.getAs<SILFunctionType>()->getSILResult();
}
FullApplySite NAI;
if (auto *TAI = dyn_cast<TryApplyInst>(AI))
NAI =
Builder.createTryApply(AI.getLoc(), FRI, FnType, Subs, Args,
TAI->getNormalBB(), TAI->getErrorBB());
else
NAI =
Builder.createApply(AI.getLoc(), FRI, FnType, ResultTy, Subs, Args,
cast<ApplyInst>(AI)->isNonThrowing());
// We also need to release the partial_apply instruction itself because it
// is consumed by the apply_instruction.
if (auto *TAI = dyn_cast<TryApplyInst>(AI)) {
Builder.setInsertionPoint(TAI->getNormalBB()->begin());
for (auto Arg : ToBeReleasedArgs) {
Builder.emitReleaseValueOperation(PAI->getLoc(), Arg);
}
Builder.createStrongRelease(AI.getLoc(), PAI, Atomicity::Atomic);
Builder.setInsertionPoint(TAI->getErrorBB()->begin());
// Release the non-consumed parameters.
for (auto Arg : ToBeReleasedArgs) {
Builder.emitReleaseValueOperation(PAI->getLoc(), Arg);
}
Builder.createStrongRelease(AI.getLoc(), PAI, Atomicity::Atomic);
Builder.setInsertionPoint(AI.getInstruction());
} else {
// Release the non-consumed parameters.
for (auto Arg : ToBeReleasedArgs) {
Builder.emitReleaseValueOperation(PAI->getLoc(), Arg);
}
Builder.createStrongRelease(AI.getLoc(), PAI, Atomicity::Atomic);
}
SilCombiner->replaceInstUsesWith(*AI.getInstruction(), NAI.getInstruction());
SilCombiner->eraseInstFromFunction(*AI.getInstruction());
return true;
}
/// \brief Inlines the callee of a given ApplyInst (which must be the value of a
/// FunctionRefInst referencing a function with a known body), into the caller
/// containing the ApplyInst, which must be the same function as provided to the
/// constructor of SILInliner. It only performs one step of inlining: it does
/// not recursively inline functions called by the callee.
///
/// It is the responsibility of the caller of this function to delete
/// the given ApplyInst when inlining is successful.
///
/// \returns true on success or false if it is unable to inline the function
/// (for any reason).
bool SILInliner::inlineFunction(FullApplySite AI, ArrayRef<SILValue> Args) {
SILFunction *CalleeFunction = &Original;
this->CalleeFunction = CalleeFunction;
// Do not attempt to inline an apply into its parent function.
if (AI.getFunction() == CalleeFunction)
return false;
SILFunction &F = getBuilder().getFunction();
if (CalleeFunction->getName() == "_TTSg5Vs4Int8___TFVs12_ArrayBufferg9_isNativeSb"
&& F.getName() == "_TTSg5Vs4Int8___TFVs12_ArrayBufferg8endIndexSi")
llvm::errs();
assert(AI.getFunction() && AI.getFunction() == &F &&
"Inliner called on apply instruction in wrong function?");
assert(((CalleeFunction->getRepresentation()
!= SILFunctionTypeRepresentation::ObjCMethod &&
CalleeFunction->getRepresentation()
!= SILFunctionTypeRepresentation::CFunctionPointer) ||
IKind == InlineKind::PerformanceInline) &&
"Cannot inline Objective-C methods or C functions in mandatory "
"inlining");
CalleeEntryBB = &*CalleeFunction->begin();
// Compute the SILLocation which should be used by all the inlined
// instructions.
if (IKind == InlineKind::PerformanceInline) {
Loc = InlinedLocation::getInlinedLocation(AI.getLoc());
} else {
assert(IKind == InlineKind::MandatoryInline && "Unknown InlineKind.");
Loc = MandatoryInlinedLocation::getMandatoryInlinedLocation(AI.getLoc());
}
auto AIScope = AI.getDebugScope();
// FIXME: Turn this into an assertion instead.
if (!AIScope)
AIScope = AI.getFunction()->getDebugScope();
if (IKind == InlineKind::MandatoryInline) {
// Mandatory inlining: every instruction inherits scope/location
// from the call site.
CallSiteScope = AIScope;
} else {
// Performance inlining. Construct a proper inline scope pointing
// back to the call site.
CallSiteScope = new (F.getModule())
SILDebugScope(AI.getLoc(), &F, AIScope);
assert(CallSiteScope->getParentFunction() == &F);
}
assert(CallSiteScope && "call site has no scope");
// Increment the ref count for the inlined function, so it doesn't
// get deleted before we can emit abstract debug info for it.
CalleeFunction->setInlined();
// If the caller's BB is not the last BB in the calling function, then keep
// track of the next BB so we always insert new BBs before it; otherwise,
// we just leave the new BBs at the end as they are by default.
auto IBI = std::next(SILFunction::iterator(AI.getParent()));
InsertBeforeBB = IBI != F.end() ? &*IBI : nullptr;
// Clear argument map and map ApplyInst arguments to the arguments of the
// callee's entry block.
ValueMap.clear();
assert(CalleeEntryBB->bbarg_size() == Args.size() &&
"Unexpected number of arguments to entry block of function?");
auto BAI = CalleeEntryBB->bbarg_begin();
for (auto AI = Args.begin(), AE = Args.end(); AI != AE; ++AI, ++BAI)
ValueMap.insert(std::make_pair(*BAI, *AI));
InstructionMap.clear();
BBMap.clear();
// Do not allow the entry block to be cloned again
SILBasicBlock::iterator InsertPoint =
SILBasicBlock::iterator(AI.getInstruction());
BBMap.insert(std::make_pair(CalleeEntryBB, AI.getParent()));
getBuilder().setInsertionPoint(InsertPoint);
// Recursively visit callee's BB in depth-first preorder, starting with the
// entry block, cloning all instructions other than terminators.
visitSILBasicBlock(CalleeEntryBB);
// If we're inlining into a normal apply and the callee's entry
// block ends in a return, then we can avoid a split.
if (auto nonTryAI = dyn_cast<ApplyInst>(AI)) {
if (ReturnInst *RI = dyn_cast<ReturnInst>(CalleeEntryBB->getTerminator())) {
// Replace all uses of the apply instruction with the operands of the
// return instruction, appropriately mapped.
nonTryAI->replaceAllUsesWith(remapValue(RI->getOperand()));
return true;
}
}
// If we're inlining into a try_apply, we already have a return-to BB.
SILBasicBlock *ReturnToBB;
if (auto tryAI = dyn_cast<TryApplyInst>(AI)) {
ReturnToBB = tryAI->getNormalBB();
// Otherwise, split the caller's basic block to create a return-to BB.
} else {
SILBasicBlock *CallerBB = AI.getParent();
// Split the BB and do NOT create a branch between the old and new
// BBs; we will create the appropriate terminator manually later.
ReturnToBB = CallerBB->splitBasicBlock(InsertPoint);
// Place the return-to BB after all the other mapped BBs.
if (InsertBeforeBB)
F.getBlocks().splice(SILFunction::iterator(InsertBeforeBB), F.getBlocks(),
SILFunction::iterator(ReturnToBB));
else
F.getBlocks().splice(F.getBlocks().end(), F.getBlocks(),
SILFunction::iterator(ReturnToBB));
// Create an argument on the return-to BB representing the returned value.
auto *RetArg = new (F.getModule()) SILArgument(ReturnToBB,
AI.getInstruction()->getType());
// Replace all uses of the ApplyInst with the new argument.
AI.getInstruction()->replaceAllUsesWith(RetArg);
}
// Now iterate over the callee BBs and fix up the terminators.
for (auto BI = BBMap.begin(), BE = BBMap.end(); BI != BE; ++BI) {
getBuilder().setInsertionPoint(BI->second);
// Modify return terminators to branch to the return-to BB, rather than
// trying to clone the ReturnInst.
if (ReturnInst *RI = dyn_cast<ReturnInst>(BI->first->getTerminator())) {
auto thrownValue = remapValue(RI->getOperand());
getBuilder().createBranch(Loc.getValue(), ReturnToBB,
thrownValue);
continue;
}
// Modify throw terminators to branch to the error-return BB, rather than
// trying to clone the ThrowInst.
if (ThrowInst *TI = dyn_cast<ThrowInst>(BI->first->getTerminator())) {
if (auto *A = dyn_cast<ApplyInst>(AI)) {
(void)A;
assert(A->isNonThrowing() &&
"apply of a function with error result must be non-throwing");
getBuilder().createUnreachable(Loc.getValue());
continue;
}
auto tryAI = cast<TryApplyInst>(AI);
auto returnedValue = remapValue(TI->getOperand());
getBuilder().createBranch(Loc.getValue(), tryAI->getErrorBB(),
returnedValue);
continue;
}
// Otherwise use normal visitor, which clones the existing instruction
// but remaps basic blocks and values.
visit(BI->first->getTerminator());
}
return true;
}
/// Update the callsite to pass in the correct arguments.
static void rewriteApplyInst(const CallSiteDescriptor &CSDesc,
SILFunction *NewF) {
FullApplySite AI = CSDesc.getApplyInst();
SILInstruction *Closure = CSDesc.getClosure();
SILBuilderWithScope Builder(Closure);
FunctionRefInst *FRI = Builder.createFunctionRef(AI.getLoc(), NewF);
// Create the args for the new apply by removing the closure argument...
llvm::SmallVector<SILValue, 8> NewArgs;
unsigned Index = 0;
for (auto Arg : AI.getArguments()) {
if (Index != CSDesc.getClosureIndex())
NewArgs.push_back(Arg);
Index++;
}
// ... and appending the captured arguments. We also insert retains here at
// the location of the original closure. This is needed to balance the
// implicit release of all captured arguments that occurs when the partial
// apply is destroyed.
SILModule &M = NewF->getModule();
for (auto Arg : CSDesc.getArguments()) {
NewArgs.push_back(Arg);
SILType ArgTy = Arg->getType();
// If our argument is of trivial type, continue...
if (ArgTy.isTrivial(M))
continue;
// TODO: When we support address types, this code path will need to be
// updated.
// We need to balance the consumed argument of the new partial_apply in the
// specialized callee by a retain. If both the original partial_apply and
// the apply of the callee are in the same basic block we can assume they
// are executed the same number of times. Therefore it is sufficient to just
// retain the argument at the site of the original partial_apply.
//
// %closure = partial_apply (%arg)
// = apply %callee(%closure)
// =>
// retain %arg
// %closure = partial_apply (%arg)
// apply %specialized_callee(..., %arg)
//
// However, if they are not in the same basic block the callee might be
// executed more frequently than the closure (for example, if the closure is
// created in a loop preheader and the callee taking the closure is executed
// in the loop). In such a case we must keep the argument live across the
// call site of the callee and emit a matching retain for every invocation
// of the callee.
//
// %closure = partial_apply (%arg)
//
// while () {
// = %callee(%closure)
// }
// =>
// retain %arg
// %closure = partial_apply (%arg)
//
// while () {
// retain %arg
// apply %specialized_callee(.., %arg)
// }
// release %arg
//
if (AI.getParent() != Closure->getParent()) {
// Emit the retain and release that keeps the argument life across the
// callee using the closure.
CSDesc.extendArgumentLifetime(Arg);
// Emit the retain that matches the captured argument by the partial_apply
// in the callee that is consumed by the partial_apply.
Builder.setInsertionPoint(AI.getInstruction());
Builder.createRetainValue(Closure->getLoc(), Arg, Atomicity::Atomic);
} else {
Builder.createRetainValue(Closure->getLoc(), Arg, Atomicity::Atomic);
}
}
SILType LoweredType = NewF->getLoweredType();
SILType ResultType = LoweredType.castTo<SILFunctionType>()->getSILResult();
Builder.setInsertionPoint(AI.getInstruction());
FullApplySite NewAI;
if (auto *TAI = dyn_cast<TryApplyInst>(AI)) {
NewAI = Builder.createTryApply(AI.getLoc(), FRI, LoweredType,
ArrayRef<Substitution>(),
NewArgs,
TAI->getNormalBB(), TAI->getErrorBB());
// If we passed in the original closure as @owned, then insert a release
// right after NewAI. This is to balance the +1 from being an @owned
// argument to AI.
if (CSDesc.isClosureConsumed() && CSDesc.closureHasRefSemanticContext()) {
Builder.setInsertionPoint(TAI->getNormalBB()->begin());
Builder.createReleaseValue(Closure->getLoc(), Closure, Atomicity::Atomic);
Builder.setInsertionPoint(TAI->getErrorBB()->begin());
Builder.createReleaseValue(Closure->getLoc(), Closure, Atomicity::Atomic);
Builder.setInsertionPoint(AI.getInstruction());
}
} else {
NewAI = Builder.createApply(AI.getLoc(), FRI, LoweredType,
ResultType, ArrayRef<Substitution>(),
NewArgs, cast<ApplyInst>(AI)->isNonThrowing());
// If we passed in the original closure as @owned, then insert a release
// right after NewAI. This is to balance the +1 from being an @owned
// argument to AI.
if (CSDesc.isClosureConsumed() && CSDesc.closureHasRefSemanticContext())
Builder.createReleaseValue(Closure->getLoc(), Closure, Atomicity::Atomic);
}
// Replace all uses of the old apply with the new apply.
if (isa<ApplyInst>(AI))
AI.getInstruction()->replaceAllUsesWith(NewAI.getInstruction());
// Erase the old apply.
AI.getInstruction()->eraseFromParent();
// TODO: Maybe include invalidation code for CallSiteDescriptor after we erase
// AI from parent?
}
/// Insert monomorphic inline caches for a specific class or metatype
/// type \p SubClassTy.
static FullApplySite speculateMonomorphicTarget(FullApplySite AI,
SILType SubType,
CheckedCastBranchInst *&CCBI) {
CCBI = nullptr;
// Bail if this class_method cannot be devirtualized.
if (!canDevirtualizeClassMethod(AI, SubType))
return FullApplySite();
// Create a diamond shaped control flow and a checked_cast_branch
// instruction that checks the exact type of the object.
// This cast selects between two paths: one that calls the slow dynamic
// dispatch and one that calls the specific method.
auto It = AI.getInstruction()->getIterator();
SILFunction *F = AI.getFunction();
SILBasicBlock *Entry = AI.getParent();
// Iden is the basic block containing the direct call.
SILBasicBlock *Iden = F->createBasicBlock();
// Virt is the block containing the slow virtual call.
SILBasicBlock *Virt = F->createBasicBlock();
Iden->createBBArg(SubType);
SILBasicBlock *Continue = Entry->splitBasicBlock(It);
SILBuilderWithScope Builder(Entry, AI.getInstruction());
// Create the checked_cast_branch instruction that checks at runtime if the
// class instance is identical to the SILType.
ClassMethodInst *CMI = cast<ClassMethodInst>(AI.getCallee());
CCBI = Builder.createCheckedCastBranch(AI.getLoc(), /*exact*/ true,
CMI->getOperand(), SubType, Iden,
Virt);
It = CCBI->getIterator();
SILBuilderWithScope VirtBuilder(Virt, AI.getInstruction());
SILBuilderWithScope IdenBuilder(Iden, AI.getInstruction());
// This is the class reference downcasted into subclass SubType.
SILValue DownCastedClassInstance = Iden->getBBArg(0);
// Copy the two apply instructions into the two blocks.
FullApplySite IdenAI = CloneApply(AI, IdenBuilder);
FullApplySite VirtAI = CloneApply(AI, VirtBuilder);
// See if Continue has a release on self as the instruction right after the
// apply. If it exists, move it into position in the diamond.
if (auto *Release =
dyn_cast<StrongReleaseInst>(std::next(Continue->begin()))) {
if (Release->getOperand() == CMI->getOperand()) {
VirtBuilder.createStrongRelease(Release->getLoc(), CMI->getOperand());
IdenBuilder.createStrongRelease(Release->getLoc(),
DownCastedClassInstance);
Release->eraseFromParent();
}
}
// Create a PHInode for returning the return value from both apply
// instructions.
SILArgument *Arg = Continue->createBBArg(AI.getType());
if (!isa<TryApplyInst>(AI)) {
IdenBuilder.createBranch(AI.getLoc(), Continue,
ArrayRef<SILValue>(IdenAI.getInstruction()));
VirtBuilder.createBranch(AI.getLoc(), Continue,
ArrayRef<SILValue>(VirtAI.getInstruction()));
}
// Remove the old Apply instruction.
if (!isa<TryApplyInst>(AI))
AI.getInstruction()->replaceAllUsesWith(Arg);
auto *OriginalBB = AI.getParent();
AI.getInstruction()->eraseFromParent();
if (OriginalBB->empty())
OriginalBB->removeFromParent();
// Update the stats.
NumTargetsPredicted++;
// Devirtualize the apply instruction on the identical path.
auto NewInstPair = devirtualizeClassMethod(IdenAI, DownCastedClassInstance);
assert(NewInstPair.first && "Expected to be able to devirtualize apply!");
replaceDeadApply(IdenAI, NewInstPair.first);
// Split critical edges resulting from VirtAI.
if (auto *TAI = dyn_cast<TryApplyInst>(VirtAI)) {
auto *ErrorBB = TAI->getFunction()->createBasicBlock();
ErrorBB->createBBArg(TAI->getErrorBB()->getBBArg(0)->getType());
Builder.setInsertionPoint(ErrorBB);
Builder.createBranch(TAI->getLoc(), TAI->getErrorBB(),
{ErrorBB->getBBArg(0)});
auto *NormalBB = TAI->getFunction()->createBasicBlock();
NormalBB->createBBArg(TAI->getNormalBB()->getBBArg(0)->getType());
Builder.setInsertionPoint(NormalBB);
Builder.createBranch(TAI->getLoc(), TAI->getNormalBB(),
{NormalBB->getBBArg(0) });
Builder.setInsertionPoint(VirtAI.getInstruction());
SmallVector<SILValue, 4> Args;
for (auto Arg : VirtAI.getArguments()) {
Args.push_back(Arg);
}
FullApplySite NewVirtAI = Builder.createTryApply(VirtAI.getLoc(), VirtAI.getCallee(),
VirtAI.getSubstCalleeSILType(), VirtAI.getSubstitutions(),
Args, NormalBB, ErrorBB);
VirtAI.getInstruction()->eraseFromParent();
VirtAI = NewVirtAI;
}
return VirtAI;
}
/// \brief Devirtualize an apply of a class method.
///
/// \p AI is the apply to devirtualize.
/// \p ClassOrMetatype is a class value or metatype value that is the
/// self argument of the apply we will devirtualize.
/// return the result value of the new ApplyInst if created one or null.
FullApplySite swift::devirtualizeClassMethod(FullApplySite AI,
SILValue ClassOrMetatype,
OptRemark::Emitter *ORE) {
LLVM_DEBUG(llvm::dbgs() << " Trying to devirtualize : "
<< *AI.getInstruction());
SILModule &Mod = AI.getModule();
auto *MI = cast<MethodInst>(AI.getCallee());
auto ClassOrMetatypeType = ClassOrMetatype->getType();
auto *F = getTargetClassMethod(Mod, ClassOrMetatypeType, MI);
CanSILFunctionType GenCalleeType = F->getLoweredFunctionType();
SubstitutionMap Subs =
getSubstitutionsForCallee(Mod, GenCalleeType,
ClassOrMetatypeType.getASTType(),
AI);
CanSILFunctionType SubstCalleeType = GenCalleeType;
if (GenCalleeType->isPolymorphic())
SubstCalleeType = GenCalleeType->substGenericArgs(Mod, Subs);
SILFunctionConventions substConv(SubstCalleeType, Mod);
SILBuilderWithScope B(AI.getInstruction());
SILLocation Loc = AI.getLoc();
FunctionRefInst *FRI = B.createFunctionRef(Loc, F);
// Create the argument list for the new apply, casting when needed
// in order to handle covariant indirect return types and
// contravariant argument types.
llvm::SmallVector<SILValue, 8> NewArgs;
auto IndirectResultArgIter = AI.getIndirectSILResults().begin();
for (auto ResultTy : substConv.getIndirectSILResultTypes()) {
NewArgs.push_back(
castValueToABICompatibleType(&B, Loc, *IndirectResultArgIter,
IndirectResultArgIter->getType(), ResultTy));
++IndirectResultArgIter;
}
auto ParamArgIter = AI.getArgumentsWithoutIndirectResults().begin();
// Skip the last parameter, which is `self`. Add it below.
for (auto param : substConv.getParameters().drop_back()) {
auto paramType = substConv.getSILType(param);
NewArgs.push_back(
castValueToABICompatibleType(&B, Loc, *ParamArgIter,
ParamArgIter->getType(), paramType));
++ParamArgIter;
}
// Add the self argument, upcasting if required because we're
// calling a base class's method.
auto SelfParamTy = substConv.getSILType(SubstCalleeType->getSelfParameter());
NewArgs.push_back(castValueToABICompatibleType(&B, Loc,
ClassOrMetatype,
ClassOrMetatypeType,
SelfParamTy));
ApplySite NewAS = replaceApplySite(B, Loc, AI, FRI, Subs, NewArgs, substConv);
FullApplySite NewAI = FullApplySite::isa(NewAS.getInstruction());
assert(NewAI);
LLVM_DEBUG(llvm::dbgs() << " SUCCESS: " << F->getName() << "\n");
if (ORE)
ORE->emit([&]() {
using namespace OptRemark;
return RemarkPassed("ClassMethodDevirtualized", *AI.getInstruction())
<< "Devirtualized call to class method " << NV("Method", F);
});
NumClassDevirt++;
return NewAI;
}
/// \brief Inlines all mandatory inlined functions into the body of a function,
/// first recursively inlining all mandatory apply instructions in those
/// functions into their bodies if necessary.
///
/// \param F the function to be processed
/// \param AI nullptr if this is being called from the top level; the relevant
/// ApplyInst requiring the recursive call when non-null
/// \param FullyInlinedSet the set of all functions already known to be fully
/// processed, to avoid processing them over again
/// \param SetFactory an instance of ImmutableFunctionSet::Factory
/// \param CurrentInliningSet the set of functions currently being inlined in
/// the current call stack of recursive calls
///
/// \returns true if successful, false if failed due to circular inlining.
static bool
runOnFunctionRecursively(SILFunction *F, FullApplySite AI,
SILModule::LinkingMode Mode,
DenseFunctionSet &FullyInlinedSet,
ImmutableFunctionSet::Factory &SetFactory,
ImmutableFunctionSet CurrentInliningSet,
ClassHierarchyAnalysis *CHA) {
// Avoid reprocessing functions needlessly.
if (FullyInlinedSet.count(F))
return true;
// Prevent attempt to circularly inline.
if (CurrentInliningSet.contains(F)) {
// This cannot happen on a top-level call, so AI should be non-null.
assert(AI && "Cannot have circular inline without apply");
SILLocation L = AI.getLoc();
assert(L && "Must have location for transparent inline apply");
diagnose(F->getModule().getASTContext(), L.getStartSourceLoc(),
diag::circular_transparent);
return false;
}
// Add to the current inlining set (immutably, so we only affect the set
// during this call and recursive subcalls).
CurrentInliningSet = SetFactory.add(CurrentInliningSet, F);
SmallVector<SILValue, 16> CaptureArgs;
SmallVector<SILValue, 32> FullArgs;
for (auto FI = F->begin(), FE = F->end(); FI != FE; ++FI) {
for (auto I = FI->begin(), E = FI->end(); I != E; ++I) {
FullApplySite InnerAI = FullApplySite::isa(&*I);
if (!InnerAI)
continue;
auto *ApplyBlock = InnerAI.getParent();
auto NewInstPair = tryDevirtualizeApply(InnerAI, CHA);
if (auto *NewInst = NewInstPair.first) {
replaceDeadApply(InnerAI, NewInst);
if (auto *II = dyn_cast<SILInstruction>(NewInst))
I = II->getIterator();
else
I = NewInst->getParentBlock()->begin();
auto NewAI = FullApplySite::isa(NewInstPair.second.getInstruction());
if (!NewAI)
continue;
InnerAI = NewAI;
}
SILLocation Loc = InnerAI.getLoc();
SILValue CalleeValue = InnerAI.getCallee();
bool IsThick;
PartialApplyInst *PAI;
SILFunction *CalleeFunction = getCalleeFunction(InnerAI, IsThick,
CaptureArgs, FullArgs,
PAI,
Mode);
if (!CalleeFunction ||
CalleeFunction->isTransparent() == IsNotTransparent)
continue;
if (F->isFragile() &&
!CalleeFunction->hasValidLinkageForFragileRef()) {
if (!CalleeFunction->hasValidLinkageForFragileInline()) {
llvm::errs() << "caller: " << F->getName() << "\n";
llvm::errs() << "callee: " << CalleeFunction->getName() << "\n";
llvm_unreachable("Should never be inlining a resilient function into "
"a fragile function");
}
continue;
}
// Then recursively process it first before trying to inline it.
if (!runOnFunctionRecursively(CalleeFunction, InnerAI, Mode,
FullyInlinedSet, SetFactory,
CurrentInliningSet, CHA)) {
// If we failed due to circular inlining, then emit some notes to
// trace back the failure if we have more information.
// FIXME: possibly it could be worth recovering and attempting other
// inlines within this same recursive call rather than simply
// propagating the failure.
if (AI) {
SILLocation L = AI.getLoc();
assert(L && "Must have location for transparent inline apply");
diagnose(F->getModule().getASTContext(), L.getStartSourceLoc(),
diag::note_while_inlining);
}
return false;
}
// Inline function at I, which also changes I to refer to the first
// instruction inlined in the case that it succeeds. We purposely
// process the inlined body after inlining, because the inlining may
// have exposed new inlining opportunities beyond those present in
// the inlined function when processed independently.
DEBUG(llvm::errs() << "Inlining @" << CalleeFunction->getName()
<< " into @" << InnerAI.getFunction()->getName()
<< "\n");
// If we intend to inline a thick function, then we need to balance the
// reference counts for correctness.
if (IsThick && I != ApplyBlock->begin()) {
// We need to find an appropriate location for our fix up code
// We used to do this after inlining Without any modifications
// This caused us to add a release in a wrong place:
// It would release a value *before* retaining it!
// It is really problematic to do this after inlining -
// Finding a valid insertion point is tricky:
// Inlining might add new basic blocks and/or remove the apply
// We want to add the fix up *just before* where the current apply is!
// Unfortunately, we *can't* add the fix up code here:
// Inlining might fail for any reason -
// If that occurred we'd need to undo our fix up code.
// Instead, we split the current basic block -
// Making sure we have a basic block that starts with our apply.
SILBuilderWithScope B(I);
ApplyBlock = splitBasicBlockAndBranch(B, &*I, nullptr, nullptr);
I = ApplyBlock->begin();
}
// Decrement our iterator (carefully, to avoid going off the front) so it
// is valid after inlining is done. Inlining deletes the apply, and can
// introduce multiple new basic blocks.
if (I != ApplyBlock->begin())
--I;
else
I = ApplyBlock->end();
std::vector<Substitution> ApplySubs(InnerAI.getSubstitutions());
if (PAI) {
auto PAISubs = PAI->getSubstitutions();
ApplySubs.insert(ApplySubs.end(), PAISubs.begin(), PAISubs.end());
}
SILOpenedArchetypesTracker OpenedArchetypesTracker(*F);
F->getModule().registerDeleteNotificationHandler(
&OpenedArchetypesTracker);
// The callee only needs to know about opened archetypes used in
// the substitution list.
OpenedArchetypesTracker.registerUsedOpenedArchetypes(InnerAI.getInstruction());
if (PAI) {
OpenedArchetypesTracker.registerUsedOpenedArchetypes(PAI);
}
SILInliner Inliner(*F, *CalleeFunction,
SILInliner::InlineKind::MandatoryInline,
ApplySubs, OpenedArchetypesTracker);
if (!Inliner.inlineFunction(InnerAI, FullArgs)) {
I = InnerAI.getInstruction()->getIterator();
continue;
}
// Inlining was successful. Remove the apply.
InnerAI.getInstruction()->eraseFromParent();
// Reestablish our iterator if it wrapped.
if (I == ApplyBlock->end())
I = ApplyBlock->begin();
// Update the iterator when instructions are removed.
DeleteInstructionsHandler DeletionHandler(I);
// If the inlined apply was a thick function, then we need to balance the
// reference counts for correctness.
if (IsThick)
fixupReferenceCounts(I, Loc, CalleeValue, CaptureArgs);
// Now that the IR is correct, see if we can remove dead callee
// computations (e.g. dead partial_apply closures).
cleanupCalleeValue(CalleeValue, CaptureArgs, FullArgs);
// Reposition iterators possibly invalidated by mutation.
FI = SILFunction::iterator(ApplyBlock);
E = ApplyBlock->end();
assert(FI == SILFunction::iterator(I->getParent()) &&
"Mismatch between the instruction and basic block");
++NumMandatoryInlines;
}
}
// Keep track of full inlined functions so we don't waste time recursively
// reprocessing them.
FullyInlinedSet.insert(F);
return true;
}