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fuchsia / third_party / swift / f2cf0510d6e25911e9babada46e0025862bd00cd / . / lib / SIL / IR / SILFunction.cpp
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//===--- SILFunction.cpp - Defines the SILFunction data structure ---------===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See https://swift.org/LICENSE.txt for license information
// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//
#include "swift/SIL/SILArgument.h"
#include "swift/SIL/SILBasicBlock.h"
#include "swift/SIL/SILFunction.h"
#include "swift/SIL/SILInstruction.h"
#include "swift/SIL/SILModule.h"
#include "swift/SIL/SILProfiler.h"
#include "swift/SIL/CFG.h"
#include "swift/SIL/PrettyStackTrace.h"
#include "swift/AST/Availability.h"
#include "swift/AST/GenericEnvironment.h"
#include "swift/AST/Module.h"
#include "swift/Basic/OptimizationMode.h"
#include "swift/Basic/Statistic.h"
#include "llvm/ADT/Optional.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/GraphWriter.h"
#include "clang/AST/Decl.h"
using namespace swift;
using namespace Lowering;
SILSpecializeAttr::SILSpecializeAttr(bool exported, SpecializationKind kind,
GenericSignature specializedSig,
SILFunction *target, Identifier spiGroup,
const ModuleDecl *spiModule)
: kind(kind), exported(exported), specializedSignature(specializedSig),
spiGroup(spiGroup), spiModule(spiModule), targetFunction(target) {
if (targetFunction)
targetFunction->incrementRefCount();
}
SILSpecializeAttr *
SILSpecializeAttr::create(SILModule &M, GenericSignature specializedSig,
bool exported, SpecializationKind kind,
SILFunction *target, Identifier spiGroup,
const ModuleDecl *spiModule) {
void *buf = M.allocate(sizeof(SILSpecializeAttr), alignof(SILSpecializeAttr));
return ::new (buf) SILSpecializeAttr(exported, kind, specializedSig, target,
spiGroup, spiModule);
}
void SILFunction::addSpecializeAttr(SILSpecializeAttr *Attr) {
if (getLoweredFunctionType()->getInvocationGenericSignature()) {
Attr->F = this;
SpecializeAttrSet.push_back(Attr);
}
}
void SILFunction::removeSpecializeAttr(SILSpecializeAttr *attr) {
// Drop the reference to the _specialize(target:) function.
if (auto *targetFun = attr->getTargetFunction()) {
targetFun->decrementRefCount();
}
SpecializeAttrSet.erase(std::remove_if(SpecializeAttrSet.begin(),
SpecializeAttrSet.end(),
[attr](SILSpecializeAttr *member) {
return member == attr;
}),
SpecializeAttrSet.end());
}
SILFunction *
SILFunction::create(SILModule &M, SILLinkage linkage, StringRef name,
CanSILFunctionType loweredType,
GenericEnvironment *genericEnv, Optional<SILLocation> loc,
IsBare_t isBareSILFunction, IsTransparent_t isTrans,
IsSerialized_t isSerialized, ProfileCounter entryCount,
IsDynamicallyReplaceable_t isDynamic,
IsExactSelfClass_t isExactSelfClass,
IsThunk_t isThunk,
SubclassScope classSubclassScope, Inline_t inlineStrategy,
EffectsKind E, SILFunction *insertBefore,
const SILDebugScope *debugScope) {
// Get a StringMapEntry for the function. As a sop to error cases,
// allow the name to have an empty string.
llvm::StringMapEntry<SILFunction*> *entry = nullptr;
if (!name.empty()) {
entry = &*M.FunctionTable.insert(std::make_pair(name, nullptr)).first;
PrettyStackTraceSILFunction trace("creating", entry->getValue());
if (entry->getValue()) {
entry->getValue()->dump();
}
assert(!entry->getValue() && "function already exists");
name = entry->getKey();
}
SILFunction *fn = M.removeFromZombieList(name);
if (fn) {
// Resurrect a zombie function.
// This happens for example if a specialized function gets dead and gets
// deleted. And afterwards the same specialization is created again.
fn->init(linkage, name, loweredType, genericEnv, loc, isBareSILFunction,
isTrans, isSerialized, entryCount, isThunk, classSubclassScope,
inlineStrategy, E, debugScope, isDynamic, isExactSelfClass);
assert(fn->empty());
} else {
fn = new (M) SILFunction(M, linkage, name, loweredType, genericEnv, loc,
isBareSILFunction, isTrans, isSerialized,
entryCount, isThunk, classSubclassScope,
inlineStrategy, E, debugScope,
isDynamic, isExactSelfClass);
}
if (entry) entry->setValue(fn);
if (insertBefore)
M.functions.insert(SILModule::iterator(insertBefore), fn);
else
M.functions.push_back(fn);
return fn;
}
SILFunction::SILFunction(SILModule &Module, SILLinkage Linkage, StringRef Name,
CanSILFunctionType LoweredType,
GenericEnvironment *genericEnv,
Optional<SILLocation> Loc, IsBare_t isBareSILFunction,
IsTransparent_t isTrans, IsSerialized_t isSerialized,
ProfileCounter entryCount, IsThunk_t isThunk,
SubclassScope classSubclassScope,
Inline_t inlineStrategy, EffectsKind E,
const SILDebugScope *DebugScope,
IsDynamicallyReplaceable_t isDynamic,
IsExactSelfClass_t isExactSelfClass)
: Module(Module), Availability(AvailabilityContext::alwaysAvailable()) {
init(Linkage, Name, LoweredType, genericEnv, Loc, isBareSILFunction, isTrans,
isSerialized, entryCount, isThunk, classSubclassScope, inlineStrategy,
E, DebugScope, isDynamic, isExactSelfClass);
// Set our BB list to have this function as its parent. This enables us to
// splice efficiently basic blocks in between functions.
BlockList.Parent = this;
}
void SILFunction::init(SILLinkage Linkage, StringRef Name,
CanSILFunctionType LoweredType,
GenericEnvironment *genericEnv,
Optional<SILLocation> Loc, IsBare_t isBareSILFunction,
IsTransparent_t isTrans, IsSerialized_t isSerialized,
ProfileCounter entryCount, IsThunk_t isThunk,
SubclassScope classSubclassScope,
Inline_t inlineStrategy, EffectsKind E,
const SILDebugScope *DebugScope,
IsDynamicallyReplaceable_t isDynamic,
IsExactSelfClass_t isExactSelfClass) {
this->Name = Name;
this->LoweredType = LoweredType;
this->GenericEnv = genericEnv;
this->SpecializationInfo = nullptr;
this->EntryCount = entryCount;
this->Availability = AvailabilityContext::alwaysAvailable();
this->Bare = isBareSILFunction;
this->Transparent = isTrans;
this->Serialized = isSerialized;
this->Thunk = isThunk;
this->ClassSubclassScope = unsigned(classSubclassScope);
this->GlobalInitFlag = false;
this->InlineStrategy = inlineStrategy;
this->Linkage = unsigned(Linkage);
this->HasCReferences = false;
this->IsWeakImported = false;
this->IsDynamicReplaceable = isDynamic;
this->ExactSelfClass = isExactSelfClass;
this->Inlined = false;
this->Zombie = false;
this->HasOwnership = true,
this->WasDeserializedCanonical = false;
this->IsWithoutActuallyEscapingThunk = false;
this->OptMode = unsigned(OptimizationMode::NotSet);
this->EffectsKindAttr = unsigned(E);
// SWIFT_ENABLE_TENSORFLOW
// Function type cannot be @differentiable.
assert(!LoweredType->isDifferentiable() &&
"SIL function declarations cannot have an @differentiable type");
assert(!Transparent || !IsDynamicReplaceable);
validateSubclassScope(classSubclassScope, isThunk, nullptr);
setDebugScope(DebugScope);
}
SILFunction::~SILFunction() {
// If the function is recursive, a function_ref inst inside of the function
// will give the function a non-zero ref count triggering the assertion. Thus
// we drop all instruction references before we erase.
// We also need to drop all references if instructions are allocated using
// an allocator that may recycle freed memory.
dropAllReferences();
if (ReplacedFunction) {
ReplacedFunction->decrementRefCount();
ReplacedFunction = nullptr;
}
auto &M = getModule();
for (auto &BB : *this) {
for (auto I = BB.begin(), E = BB.end(); I != E;) {
auto Inst = &*I;
++I;
SILInstruction::destroy(Inst);
// TODO: It is only safe to directly deallocate an
// instruction if this BB is being removed in scope
// of destructing a SILFunction.
M.deallocateInst(Inst);
}
BB.InstList.clearAndLeakNodesUnsafely();
}
assert(RefCount == 0 &&
"Function cannot be deleted while function_ref's still exist");
}
void SILFunction::createProfiler(ASTNode Root, SILDeclRef forDecl,
ForDefinition_t forDefinition) {
assert(!Profiler && "Function already has a profiler");
Profiler = SILProfiler::create(Module, forDefinition, Root, forDecl);
}
bool SILFunction::hasForeignBody() const {
if (!hasClangNode()) return false;
return SILDeclRef::isClangGenerated(getClangNode());
}
const SILFunction *SILFunction::getOriginOfSpecialization() const {
if (!isSpecialization())
return nullptr;
const SILFunction *p = getSpecializationInfo()->getParent();
while (p->isSpecialization()) {
p = p->getSpecializationInfo()->getParent();
}
return p;
}
void SILFunction::numberValues(llvm::DenseMap<const SILNode*, unsigned> &
ValueToNumberMap) const {
unsigned idx = 0;
for (auto &BB : *this) {
for (auto I = BB.args_begin(), E = BB.args_end(); I != E; ++I)
ValueToNumberMap[*I] = idx++;
for (auto &I : BB) {
auto results = I.getResults();
if (results.empty()) {
ValueToNumberMap[&I] = idx++;
} else {
// Assign the instruction node the first result ID.
ValueToNumberMap[&I] = idx;
for (auto result : results) {
ValueToNumberMap[result] = idx++;
}
}
}
}
}
ASTContext &SILFunction::getASTContext() const {
return getModule().getASTContext();
}
OptimizationMode SILFunction::getEffectiveOptimizationMode() const {
if (OptimizationMode(OptMode) != OptimizationMode::NotSet)
return OptimizationMode(OptMode);
return getModule().getOptions().OptMode;
}
bool SILFunction::shouldOptimize() const {
return getEffectiveOptimizationMode() != OptimizationMode::NoOptimization;
}
Type SILFunction::mapTypeIntoContext(Type type) const {
return GenericEnvironment::mapTypeIntoContext(
getGenericEnvironment(), type);
}
SILType SILFunction::mapTypeIntoContext(SILType type) const {
if (auto *genericEnv = getGenericEnvironment())
return genericEnv->mapTypeIntoContext(getModule(), type);
return type;
}
SILType GenericEnvironment::mapTypeIntoContext(SILModule &M,
SILType type) const {
if (type.hasArchetype()) {
llvm::errs() << "TYPE HAS ARCHETYPE\n";
type.dump();
}
assert(!type.hasArchetype());
auto genericSig = getGenericSignature().getCanonicalSignature();
return type.subst(M,
QueryInterfaceTypeSubstitutions(this),
LookUpConformanceInSignature(genericSig.getPointer()),
genericSig);
}
bool SILFunction::isNoReturnFunction(TypeExpansionContext context) const {
return SILType::getPrimitiveObjectType(getLoweredFunctionType())
.isNoReturnFunction(getModule(), context);
}
const TypeLowering &
SILFunction::getTypeLowering(AbstractionPattern orig, Type subst) {
return getModule().Types.getTypeLowering(orig, subst,
TypeExpansionContext(*this));
}
const TypeLowering &SILFunction::getTypeLowering(Type t) const {
return getModule().Types.getTypeLowering(t, TypeExpansionContext(*this));
}
SILType
SILFunction::getLoweredType(AbstractionPattern orig, Type subst) const {
return getModule().Types.getLoweredType(orig, subst,
TypeExpansionContext(*this));
}
SILType SILFunction::getLoweredType(Type t) const {
return getModule().Types.getLoweredType(t, TypeExpansionContext(*this));
}
SILType SILFunction::getLoweredLoadableType(Type t) const {
auto &M = getModule();
return M.Types.getLoweredLoadableType(t, TypeExpansionContext(*this), M);
}
const TypeLowering &SILFunction::getTypeLowering(SILType type) const {
return getModule().Types.getTypeLowering(type, *this);
}
SILType SILFunction::getLoweredType(SILType t) const {
return getTypeLowering(t).getLoweredType().getCategoryType(t.getCategory());
}
bool SILFunction::isTypeABIAccessible(SILType type) const {
return getModule().isTypeABIAccessible(type, TypeExpansionContext(*this));
}
bool SILFunction::isWeakImported() const {
// For imported functions check the Clang declaration.
if (ClangNodeOwner)
return ClangNodeOwner->getClangDecl()->isWeakImported();
// For native functions check a flag on the SILFunction
// itself.
if (!isAvailableExternally())
return false;
if (isAlwaysWeakImported())
return true;
if (Availability.isAlwaysAvailable())
return false;
auto fromContext = AvailabilityContext::forDeploymentTarget(
getASTContext());
return !fromContext.isContainedIn(Availability);
}
SILBasicBlock *SILFunction::createBasicBlock() {
return new (getModule()) SILBasicBlock(this, nullptr, false);
}
SILBasicBlock *SILFunction::createBasicBlockAfter(SILBasicBlock *afterBB) {
assert(afterBB);
return new (getModule()) SILBasicBlock(this, afterBB, /*after*/ true);
}
SILBasicBlock *SILFunction::createBasicBlockBefore(SILBasicBlock *beforeBB) {
assert(beforeBB);
return new (getModule()) SILBasicBlock(this, beforeBB, /*after*/ false);
}
//===----------------------------------------------------------------------===//
// View CFG Implementation
//===----------------------------------------------------------------------===//
#ifndef NDEBUG
static llvm::cl::opt<unsigned>
MaxColumns("view-cfg-max-columns", llvm::cl::init(80),
llvm::cl::desc("Maximum width of a printed node"));
namespace {
enum class LongLineBehavior { None, Truncate, Wrap };
} // end anonymous namespace
static llvm::cl::opt<LongLineBehavior>
LLBehavior("view-cfg-long-line-behavior",
llvm::cl::init(LongLineBehavior::Truncate),
llvm::cl::desc("Behavior when line width is greater than the "
"value provided my -view-cfg-max-columns "
"option"),
llvm::cl::values(
clEnumValN(LongLineBehavior::None, "none", "Print everything"),
clEnumValN(LongLineBehavior::Truncate, "truncate",
"Truncate long lines"),
clEnumValN(LongLineBehavior::Wrap, "wrap", "Wrap long lines")));
static llvm::cl::opt<bool>
RemoveUseListComments("view-cfg-remove-use-list-comments",
llvm::cl::init(false),
llvm::cl::desc("Should use list comments be removed"));
template <typename InstTy, typename CaseValueTy>
inline CaseValueTy getCaseValueForBB(const InstTy *Inst,
const SILBasicBlock *BB) {
for (unsigned i = 0, e = Inst->getNumCases(); i != e; ++i) {
auto P = Inst->getCase(i);
if (P.second != BB)
continue;
return P.first;
}
llvm_unreachable("Error! should never pass in BB that is not a successor");
}
namespace llvm {
template <>
struct DOTGraphTraits<SILFunction *> : public DefaultDOTGraphTraits {
DOTGraphTraits(bool isSimple = false) : DefaultDOTGraphTraits(isSimple) {}
static std::string getGraphName(SILFunction *F) {
return "CFG for '" + F->getName().str() + "' function";
}
static std::string getSimpleNodeLabel(SILBasicBlock *Node, SILFunction *F) {
std::string OutStr;
raw_string_ostream OSS(OutStr);
const_cast<SILBasicBlock *>(Node)->printAsOperand(OSS, false);
return OSS.str();
}
static std::string getCompleteNodeLabel(SILBasicBlock *Node, SILFunction *F) {
std::string Str;
raw_string_ostream OS(Str);
OS << *Node;
std::string OutStr = OS.str();
if (OutStr[0] == '\n')
OutStr.erase(OutStr.begin());
// Process string output to make it nicer...
unsigned ColNum = 0;
unsigned LastSpace = 0;
for (unsigned i = 0; i != OutStr.length(); ++i) {
if (OutStr[i] == '\n') { // Left justify
OutStr[i] = '\\';
OutStr.insert(OutStr.begin() + i + 1, 'l');
ColNum = 0;
LastSpace = 0;
} else if (RemoveUseListComments && OutStr[i] == '/' &&
i != (OutStr.size() - 1) && OutStr[i + 1] == '/') {
unsigned Idx = OutStr.find('\n', i + 1); // Find end of line
OutStr.erase(OutStr.begin() + i, OutStr.begin() + Idx);
--i;
} else if (ColNum == MaxColumns) { // Handle long lines.
if (LLBehavior == LongLineBehavior::Wrap) {
if (!LastSpace)
LastSpace = i;
OutStr.insert(LastSpace, "\\l...");
ColNum = i - LastSpace;
LastSpace = 0;
i += 3; // The loop will advance 'i' again.
} else if (LLBehavior == LongLineBehavior::Truncate) {
unsigned Idx = OutStr.find('\n', i + 1); // Find end of line
OutStr.erase(OutStr.begin() + i, OutStr.begin() + Idx);
--i;
}
// Else keep trying to find a space.
} else
++ColNum;
if (OutStr[i] == ' ')
LastSpace = i;
}
return OutStr;
}
std::string getNodeLabel(SILBasicBlock *Node, SILFunction *Graph) {
if (isSimple())
return getSimpleNodeLabel(Node, Graph);
else
return getCompleteNodeLabel(Node, Graph);
}
static std::string getEdgeSourceLabel(SILBasicBlock *Node,
SILBasicBlock::succblock_iterator I) {
const SILBasicBlock *Succ = *I;
const TermInst *Term = Node->getTerminator();
// Label source of conditional branches with "T" or "F"
if (auto *CBI = dyn_cast<CondBranchInst>(Term))
return (Succ == CBI->getTrueBB()) ? "T" : "F";
// Label source of switch edges with the associated value.
if (auto *SI = dyn_cast<SwitchValueInst>(Term)) {
if (SI->hasDefault() && SI->getDefaultBB() == Succ)
return "def";
std::string Str;
raw_string_ostream OS(Str);
SILValue I = getCaseValueForBB<SwitchValueInst, SILValue>(SI, Succ);
OS << I; // TODO: or should we output the literal value of I?
return OS.str();
}
if (auto *SEIB = dyn_cast<SwitchEnumInst>(Term)) {
std::string Str;
raw_string_ostream OS(Str);
EnumElementDecl *E =
getCaseValueForBB<SwitchEnumInst, EnumElementDecl *>(SEIB, Succ);
OS << E->getName();
return OS.str();
}
if (auto *SEIB = dyn_cast<SwitchEnumAddrInst>(Term)) {
std::string Str;
raw_string_ostream OS(Str);
EnumElementDecl *E =
getCaseValueForBB<SwitchEnumAddrInst, EnumElementDecl *>(SEIB, Succ);
OS << E->getName();
return OS.str();
}
if (auto *DMBI = dyn_cast<DynamicMethodBranchInst>(Term))
return (Succ == DMBI->getHasMethodBB()) ? "T" : "F";
if (auto *CCBI = dyn_cast<CheckedCastBranchInst>(Term))
return (Succ == CCBI->getSuccessBB()) ? "T" : "F";
if (auto *CCBI = dyn_cast<CheckedCastValueBranchInst>(Term))
return (Succ == CCBI->getSuccessBB()) ? "T" : "F";
if (auto *CCBI = dyn_cast<CheckedCastAddrBranchInst>(Term))
return (Succ == CCBI->getSuccessBB()) ? "T" : "F";
return "";
}
};
} // namespace llvm
#endif
#ifndef NDEBUG
static llvm::cl::opt<std::string>
TargetFunction("view-cfg-only-for-function", llvm::cl::init(""),
llvm::cl::desc("Only print out the cfg for this function"));
#endif
static void viewCFGHelper(const SILFunction* f, bool skipBBContents) {
/// When asserts are disabled, this should be a NoOp.
#ifndef NDEBUG
// If we have a target function, only print that function out.
if (!TargetFunction.empty() && !(f->getName().str() == TargetFunction))
return;
ViewGraph(const_cast<SILFunction *>(f), "cfg" + f->getName().str(),
/*shortNames=*/skipBBContents);
#endif
}
void SILFunction::viewCFG() const {
viewCFGHelper(this, /*skipBBContents=*/false);
}
void SILFunction::viewCFGOnly() const {
viewCFGHelper(this, /*skipBBContents=*/true);
}
bool SILFunction::hasDynamicSelfMetadata() const {
auto paramTypes =
getConventions().getParameterSILTypes(TypeExpansionContext::minimal());
if (paramTypes.empty())
return false;
auto silTy = *std::prev(paramTypes.end());
if (!silTy.isObject())
return false;
auto selfTy = silTy.getASTType();
if (auto metaTy = dyn_cast<MetatypeType>(selfTy)) {
selfTy = metaTy.getInstanceType();
if (auto dynamicSelfTy = dyn_cast<DynamicSelfType>(selfTy))
selfTy = dynamicSelfTy.getSelfType();
}
return !!selfTy.getClassOrBoundGenericClass();
}
bool SILFunction::hasName(const char *Name) const {
return getName() == Name;
}
/// Returns true if this function can be referenced from a fragile function
/// body.
bool SILFunction::hasValidLinkageForFragileRef() const {
// Fragile functions can reference 'static inline' functions imported
// from C.
if (hasForeignBody())
return true;
// If we can inline it, we can reference it.
if (hasValidLinkageForFragileInline())
return true;
// If the containing module has been serialized already, we no longer
// enforce any invariants.
if (getModule().isSerialized())
return true;
// If the function has a subclass scope that limits its visibility outside
// the module despite its linkage, we cannot reference it.
if (getClassSubclassScope() == SubclassScope::Resilient &&
isAvailableExternally())
return false;
// Otherwise, only public functions can be referenced.
return hasPublicVisibility(getLinkage());
}
bool
SILFunction::isPossiblyUsedExternally() const {
auto linkage = getLinkage();
// Hidden functions may be referenced by other C code in the linkage unit.
if (linkage == SILLinkage::Hidden && hasCReferences())
return true;
if (ReplacedFunction)
return true;
return swift::isPossiblyUsedExternally(linkage, getModule().isWholeModule());
}
bool SILFunction::isExternallyUsedSymbol() const {
return swift::isPossiblyUsedExternally(getEffectiveSymbolLinkage(),
getModule().isWholeModule());
}
void SILFunction::convertToDeclaration() {
assert(isDefinition() && "Can only convert definitions to declarations");
dropAllReferences();
getBlocks().clear();
}
SubstitutionMap SILFunction::getForwardingSubstitutionMap() {
if (ForwardingSubMap)
return ForwardingSubMap;
if (auto *env = getGenericEnvironment())
ForwardingSubMap = env->getForwardingSubstitutionMap();
return ForwardingSubMap;
}
bool SILFunction::shouldVerifyOwnership() const {
return !hasSemanticsAttr("verify.ownership.sil.never");
}
static Identifier getIdentifierForObjCSelector(ObjCSelector selector, ASTContext &Ctxt) {
SmallVector<char, 64> buffer;
auto str = selector.getString(buffer);
return Ctxt.getIdentifier(str);
}
void SILFunction::setObjCReplacement(AbstractFunctionDecl *replacedFunc) {
assert(ReplacedFunction == nullptr && ObjCReplacementFor.empty());
assert(replacedFunc != nullptr);
ObjCReplacementFor = getIdentifierForObjCSelector(
replacedFunc->getObjCSelector(), getASTContext());
}
void SILFunction::setObjCReplacement(Identifier replacedFunc) {
assert(ReplacedFunction == nullptr && ObjCReplacementFor.empty());
ObjCReplacementFor = replacedFunc;
}
// See swift/Basic/Statistic.h for declaration: this enables tracing
// SILFunctions, is defined here to avoid too much layering violation / circular
// linkage dependency.
struct SILFunctionTraceFormatter : public UnifiedStatsReporter::TraceFormatter {
void traceName(const void *Entity, raw_ostream &OS) const override {
if (!Entity)
return;
const SILFunction *F = static_cast<const SILFunction *>(Entity);
F->printName(OS);
}
void traceLoc(const void *Entity, SourceManager *SM,
clang::SourceManager *CSM, raw_ostream &OS) const override {
if (!Entity)
return;
const SILFunction *F = static_cast<const SILFunction *>(Entity);
if (!F->hasLocation())
return;
F->getLocation().getSourceRange().print(OS, *SM, false);
}
};
static SILFunctionTraceFormatter TF;
template<>
const UnifiedStatsReporter::TraceFormatter*
FrontendStatsTracer::getTraceFormatter<const SILFunction *>() {
return &TF;
}
bool SILFunction::hasPrespecialization() const {
for (auto *attr : getSpecializeAttrs()) {
if (attr->isExported())
return true;
}
return false;
}
void SILFunction::forEachSpecializeAttrTargetFunction(
llvm::function_ref<void(SILFunction *)> action) {
for (auto *attr : getSpecializeAttrs()) {
if (auto *f = attr->getTargetFunction()) {
action(f);
}
}
}