averello/swift-mirror
1
0
Fork 0
mirror of https://github.com/apple/swift.git synced 2025-12-14 20:36:38 +01:00
Code Issues Packages Projects Releases Wiki Activity
Files
22d37eccd818b51fbbefda5b6f13d2bc8f44f757
swift-mirror/lib/SIL/SILFunction.cpp
Slava Pestov 16d5716e71 SIL: Use the best resilience expansion when lowering types 
This is a large patch; I couldn't split it up further while still
keeping things working. There are four things being changed at
once here:

- Places that call SILType::isAddressOnly()/isLoadable() now call
  the SILFunction overload and not the SILModule one.

- SILFunction's overloads of getTypeLowering() and getLoweredType()
  now pass the function's resilience expansion down, instead of
  hardcoding ResilienceExpansion::Minimal.

- Various other places with '// FIXME: Expansion' now use a better
  resilience expansion.

- A few tests were updated to reflect SILGen's improved code
  generation, and some new tests are added to cover more code paths
  that previously were uncovered and only manifested themselves as
  standard library build failures while I was working on this change.
2019-04-26 22:47:59 -04:00

614 lines
21 KiB
C++
Raw Blame History

//===--- 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/GenericEnvironment.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"
using namespace swift;
using namespace Lowering;
ArrayRef<Requirement> SILSpecializeAttr::getRequirements() const {
return {const_cast<SILSpecializeAttr *>(this)->getRequirementsData(),
numRequirements};
}
SILSpecializeAttr::SILSpecializeAttr(ArrayRef<Requirement> requirements,
bool exported, SpecializationKind kind)
: numRequirements(requirements.size()), kind(kind), exported(exported) {
std::copy(requirements.begin(), requirements.end(), getRequirementsData());
}
SILSpecializeAttr *SILSpecializeAttr::create(SILModule &M,
ArrayRef<Requirement> requirements,
bool exported,
SpecializationKind kind) {
unsigned size =
sizeof(SILSpecializeAttr) + sizeof(Requirement) * requirements.size();
void *buf = M.allocate(size, alignof(SILSpecializeAttr));
return ::new (buf) SILSpecializeAttr(requirements, exported, kind);
}
void SILFunction::addSpecializeAttr(SILSpecializeAttr *Attr) {
if (getLoweredFunctionType()->getGenericSignature()) {
Attr->F = this;
SpecializeAttrSet.push_back(Attr);
}
}
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, 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());
assert(!entry->getValue() && "function already exists");
name = entry->getKey();
}
auto fn = new (M) SILFunction(M, linkage, name, loweredType, genericEnv, loc,
isBareSILFunction, isTrans, isSerialized,
entryCount, isThunk, classSubclassScope,
inlineStrategy, E, insertBefore, debugScope, isDynamic);
if (entry) entry->setValue(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,
SILFunction *InsertBefore,
const SILDebugScope *DebugScope,
IsDynamicallyReplaceable_t isDynamic)
: Module(Module), Name(Name), LoweredType(LoweredType),
GenericEnv(genericEnv), SpecializationInfo(nullptr),
DebugScope(DebugScope), Bare(isBareSILFunction), Transparent(isTrans),
Serialized(isSerialized), Thunk(isThunk),
ClassSubclassScope(unsigned(classSubclassScope)), GlobalInitFlag(false),
InlineStrategy(inlineStrategy), Linkage(unsigned(Linkage)),
HasCReferences(false), IsWeakLinked(false),
IsDynamicReplaceable(isDynamic), OptMode(OptimizationMode::NotSet),
EffectsKindAttr(E), EntryCount(entryCount) {
assert(!Transparent || !IsDynamicReplaceable);
validateSubclassScope(classSubclassScope, isThunk, nullptr);
if (InsertBefore)
Module.functions.insert(SILModule::iterator(InsertBefore), this);
else
Module.functions.push_back(this);
Module.removeFromZombieList(Name);
// 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;
}
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, ForDefinition_t forDefinition) {
assert(!Profiler && "Function already has a profiler");
Profiler = SILProfiler::create(Module, forDefinition, Root);
}
bool SILFunction::hasForeignBody() const {
if (!hasClangNode()) return false;
return SILDeclRef::isClangGenerated(getClangNode());
}
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 (OptMode != OptimizationMode::NotSet)
return 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 {
assert(!type.hasArchetype());
auto genericSig = getGenericSignature()->getCanonicalSignature();
return type.subst(M,
QueryInterfaceTypeSubstitutions(this),
LookUpConformanceInSignature(*genericSig),
genericSig);
}
bool SILFunction::isNoReturnFunction() const {
return SILType::getPrimitiveObjectType(getLoweredFunctionType())
.isNoReturnFunction();
}
const TypeLowering &
SILFunction::getTypeLowering(AbstractionPattern orig, Type subst) {
return getModule().Types.getTypeLowering(orig, subst,
getResilienceExpansion());
}
const TypeLowering &SILFunction::getTypeLowering(Type t) const {
return getModule().Types.getTypeLowering(t, getResilienceExpansion());
}
SILType
SILFunction::getLoweredType(AbstractionPattern orig, Type subst) const {
return getModule().Types.getLoweredType(orig, subst,
getResilienceExpansion());
}
SILType SILFunction::getLoweredType(Type t) const {
return getModule().Types.getLoweredType(t, getResilienceExpansion());
}
SILType SILFunction::getLoweredLoadableType(Type t) const {
return getModule().Types.getLoweredLoadableType(t, getResilienceExpansion());
}
const TypeLowering &SILFunction::getTypeLowering(SILType type) const {
return getModule().Types.getTypeLowering(type, getResilienceExpansion());
}
bool SILFunction::isTypeABIAccessible(SILType type) const {
return getModule().isTypeABIAccessible(type, getResilienceExpansion());
}
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->getFullName();
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->getFullName();
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::hasSelfMetadataParam() const {
auto paramTypes = getConventions().getParameterSILTypes();
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 {
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 {
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;
}
Reference in New Issue View Git Blame Copy Permalink