llvm-project/clang/lib/CodeGen/CodeGenFunction.h

2662 lines
107 KiB
C++

//===-- CodeGenFunction.h - Per-Function state for LLVM CodeGen -*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This is the internal per-function state used for llvm translation.
//
//===----------------------------------------------------------------------===//
#ifndef CLANG_CODEGEN_CODEGENFUNCTION_H
#define CLANG_CODEGEN_CODEGENFUNCTION_H
#include "clang/AST/Type.h"
#include "clang/AST/ExprCXX.h"
#include "clang/AST/ExprObjC.h"
#include "clang/AST/CharUnits.h"
#include "clang/Frontend/CodeGenOptions.h"
#include "clang/Basic/ABI.h"
#include "clang/Basic/TargetInfo.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/Support/ValueHandle.h"
#include "llvm/Support/Debug.h"
#include "CodeGenModule.h"
#include "CGBuilder.h"
#include "CGDebugInfo.h"
#include "CGValue.h"
namespace llvm {
class BasicBlock;
class LLVMContext;
class MDNode;
class Module;
class SwitchInst;
class Twine;
class Value;
class CallSite;
}
namespace clang {
class ASTContext;
class BlockDecl;
class CXXDestructorDecl;
class CXXForRangeStmt;
class CXXTryStmt;
class Decl;
class LabelDecl;
class EnumConstantDecl;
class FunctionDecl;
class FunctionProtoType;
class LabelStmt;
class ObjCContainerDecl;
class ObjCInterfaceDecl;
class ObjCIvarDecl;
class ObjCMethodDecl;
class ObjCImplementationDecl;
class ObjCPropertyImplDecl;
class TargetInfo;
class TargetCodeGenInfo;
class VarDecl;
class ObjCForCollectionStmt;
class ObjCAtTryStmt;
class ObjCAtThrowStmt;
class ObjCAtSynchronizedStmt;
class ObjCAutoreleasePoolStmt;
namespace CodeGen {
class CodeGenTypes;
class CGFunctionInfo;
class CGRecordLayout;
class CGBlockInfo;
class CGCXXABI;
class BlockFlags;
class BlockFieldFlags;
/// A branch fixup. These are required when emitting a goto to a
/// label which hasn't been emitted yet. The goto is optimistically
/// emitted as a branch to the basic block for the label, and (if it
/// occurs in a scope with non-trivial cleanups) a fixup is added to
/// the innermost cleanup. When a (normal) cleanup is popped, any
/// unresolved fixups in that scope are threaded through the cleanup.
struct BranchFixup {
/// The block containing the terminator which needs to be modified
/// into a switch if this fixup is resolved into the current scope.
/// If null, LatestBranch points directly to the destination.
llvm::BasicBlock *OptimisticBranchBlock;
/// The ultimate destination of the branch.
///
/// This can be set to null to indicate that this fixup was
/// successfully resolved.
llvm::BasicBlock *Destination;
/// The destination index value.
unsigned DestinationIndex;
/// The initial branch of the fixup.
llvm::BranchInst *InitialBranch;
};
template <class T> struct InvariantValue {
typedef T type;
typedef T saved_type;
static bool needsSaving(type value) { return false; }
static saved_type save(CodeGenFunction &CGF, type value) { return value; }
static type restore(CodeGenFunction &CGF, saved_type value) { return value; }
};
/// A metaprogramming class for ensuring that a value will dominate an
/// arbitrary position in a function.
template <class T> struct DominatingValue : InvariantValue<T> {};
template <class T, bool mightBeInstruction =
llvm::is_base_of<llvm::Value, T>::value &&
!llvm::is_base_of<llvm::Constant, T>::value &&
!llvm::is_base_of<llvm::BasicBlock, T>::value>
struct DominatingPointer;
template <class T> struct DominatingPointer<T,false> : InvariantValue<T*> {};
// template <class T> struct DominatingPointer<T,true> at end of file
template <class T> struct DominatingValue<T*> : DominatingPointer<T> {};
enum CleanupKind {
EHCleanup = 0x1,
NormalCleanup = 0x2,
NormalAndEHCleanup = EHCleanup | NormalCleanup,
InactiveCleanup = 0x4,
InactiveEHCleanup = EHCleanup | InactiveCleanup,
InactiveNormalCleanup = NormalCleanup | InactiveCleanup,
InactiveNormalAndEHCleanup = NormalAndEHCleanup | InactiveCleanup
};
/// A stack of scopes which respond to exceptions, including cleanups
/// and catch blocks.
class EHScopeStack {
public:
/// A saved depth on the scope stack. This is necessary because
/// pushing scopes onto the stack invalidates iterators.
class stable_iterator {
friend class EHScopeStack;
/// Offset from StartOfData to EndOfBuffer.
ptrdiff_t Size;
stable_iterator(ptrdiff_t Size) : Size(Size) {}
public:
static stable_iterator invalid() { return stable_iterator(-1); }
stable_iterator() : Size(-1) {}
bool isValid() const { return Size >= 0; }
/// Returns true if this scope encloses I.
/// Returns false if I is invalid.
/// This scope must be valid.
bool encloses(stable_iterator I) const { return Size <= I.Size; }
/// Returns true if this scope strictly encloses I: that is,
/// if it encloses I and is not I.
/// Returns false is I is invalid.
/// This scope must be valid.
bool strictlyEncloses(stable_iterator I) const { return Size < I.Size; }
friend bool operator==(stable_iterator A, stable_iterator B) {
return A.Size == B.Size;
}
friend bool operator!=(stable_iterator A, stable_iterator B) {
return A.Size != B.Size;
}
};
/// Information for lazily generating a cleanup. Subclasses must be
/// POD-like: cleanups will not be destructed, and they will be
/// allocated on the cleanup stack and freely copied and moved
/// around.
///
/// Cleanup implementations should generally be declared in an
/// anonymous namespace.
class Cleanup {
// Anchor the construction vtable.
virtual void anchor();
public:
/// Generation flags.
class Flags {
enum {
F_IsForEH = 0x1,
F_IsNormalCleanupKind = 0x2,
F_IsEHCleanupKind = 0x4
};
unsigned flags;
public:
Flags() : flags(0) {}
/// isForEH - true if the current emission is for an EH cleanup.
bool isForEHCleanup() const { return flags & F_IsForEH; }
bool isForNormalCleanup() const { return !isForEHCleanup(); }
void setIsForEHCleanup() { flags |= F_IsForEH; }
bool isNormalCleanupKind() const { return flags & F_IsNormalCleanupKind; }
void setIsNormalCleanupKind() { flags |= F_IsNormalCleanupKind; }
/// isEHCleanupKind - true if the cleanup was pushed as an EH
/// cleanup.
bool isEHCleanupKind() const { return flags & F_IsEHCleanupKind; }
void setIsEHCleanupKind() { flags |= F_IsEHCleanupKind; }
};
// Provide a virtual destructor to suppress a very common warning
// that unfortunately cannot be suppressed without this. Cleanups
// should not rely on this destructor ever being called.
virtual ~Cleanup() {}
/// Emit the cleanup. For normal cleanups, this is run in the
/// same EH context as when the cleanup was pushed, i.e. the
/// immediately-enclosing context of the cleanup scope. For
/// EH cleanups, this is run in a terminate context.
///
// \param IsForEHCleanup true if this is for an EH cleanup, false
/// if for a normal cleanup.
virtual void Emit(CodeGenFunction &CGF, Flags flags) = 0;
};
/// ConditionalCleanupN stores the saved form of its N parameters,
/// then restores them and performs the cleanup.
template <class T, class A0>
class ConditionalCleanup1 : public Cleanup {
typedef typename DominatingValue<A0>::saved_type A0_saved;
A0_saved a0_saved;
void Emit(CodeGenFunction &CGF, Flags flags) {
A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
T(a0).Emit(CGF, flags);
}
public:
ConditionalCleanup1(A0_saved a0)
: a0_saved(a0) {}
};
template <class T, class A0, class A1>
class ConditionalCleanup2 : public Cleanup {
typedef typename DominatingValue<A0>::saved_type A0_saved;
typedef typename DominatingValue<A1>::saved_type A1_saved;
A0_saved a0_saved;
A1_saved a1_saved;
void Emit(CodeGenFunction &CGF, Flags flags) {
A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
T(a0, a1).Emit(CGF, flags);
}
public:
ConditionalCleanup2(A0_saved a0, A1_saved a1)
: a0_saved(a0), a1_saved(a1) {}
};
template <class T, class A0, class A1, class A2>
class ConditionalCleanup3 : public Cleanup {
typedef typename DominatingValue<A0>::saved_type A0_saved;
typedef typename DominatingValue<A1>::saved_type A1_saved;
typedef typename DominatingValue<A2>::saved_type A2_saved;
A0_saved a0_saved;
A1_saved a1_saved;
A2_saved a2_saved;
void Emit(CodeGenFunction &CGF, Flags flags) {
A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
A2 a2 = DominatingValue<A2>::restore(CGF, a2_saved);
T(a0, a1, a2).Emit(CGF, flags);
}
public:
ConditionalCleanup3(A0_saved a0, A1_saved a1, A2_saved a2)
: a0_saved(a0), a1_saved(a1), a2_saved(a2) {}
};
template <class T, class A0, class A1, class A2, class A3>
class ConditionalCleanup4 : public Cleanup {
typedef typename DominatingValue<A0>::saved_type A0_saved;
typedef typename DominatingValue<A1>::saved_type A1_saved;
typedef typename DominatingValue<A2>::saved_type A2_saved;
typedef typename DominatingValue<A3>::saved_type A3_saved;
A0_saved a0_saved;
A1_saved a1_saved;
A2_saved a2_saved;
A3_saved a3_saved;
void Emit(CodeGenFunction &CGF, Flags flags) {
A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
A2 a2 = DominatingValue<A2>::restore(CGF, a2_saved);
A3 a3 = DominatingValue<A3>::restore(CGF, a3_saved);
T(a0, a1, a2, a3).Emit(CGF, flags);
}
public:
ConditionalCleanup4(A0_saved a0, A1_saved a1, A2_saved a2, A3_saved a3)
: a0_saved(a0), a1_saved(a1), a2_saved(a2), a3_saved(a3) {}
};
private:
// The implementation for this class is in CGException.h and
// CGException.cpp; the definition is here because it's used as a
// member of CodeGenFunction.
/// The start of the scope-stack buffer, i.e. the allocated pointer
/// for the buffer. All of these pointers are either simultaneously
/// null or simultaneously valid.
char *StartOfBuffer;
/// The end of the buffer.
char *EndOfBuffer;
/// The first valid entry in the buffer.
char *StartOfData;
/// The innermost normal cleanup on the stack.
stable_iterator InnermostNormalCleanup;
/// The innermost EH scope on the stack.
stable_iterator InnermostEHScope;
/// The current set of branch fixups. A branch fixup is a jump to
/// an as-yet unemitted label, i.e. a label for which we don't yet
/// know the EH stack depth. Whenever we pop a cleanup, we have
/// to thread all the current branch fixups through it.
///
/// Fixups are recorded as the Use of the respective branch or
/// switch statement. The use points to the final destination.
/// When popping out of a cleanup, these uses are threaded through
/// the cleanup and adjusted to point to the new cleanup.
///
/// Note that branches are allowed to jump into protected scopes
/// in certain situations; e.g. the following code is legal:
/// struct A { ~A(); }; // trivial ctor, non-trivial dtor
/// goto foo;
/// A a;
/// foo:
/// bar();
SmallVector<BranchFixup, 8> BranchFixups;
char *allocate(size_t Size);
void *pushCleanup(CleanupKind K, size_t DataSize);
public:
EHScopeStack() : StartOfBuffer(0), EndOfBuffer(0), StartOfData(0),
InnermostNormalCleanup(stable_end()),
InnermostEHScope(stable_end()) {}
~EHScopeStack() { delete[] StartOfBuffer; }
// Variadic templates would make this not terrible.
/// Push a lazily-created cleanup on the stack.
template <class T>
void pushCleanup(CleanupKind Kind) {
void *Buffer = pushCleanup(Kind, sizeof(T));
Cleanup *Obj = new(Buffer) T();
(void) Obj;
}
/// Push a lazily-created cleanup on the stack.
template <class T, class A0>
void pushCleanup(CleanupKind Kind, A0 a0) {
void *Buffer = pushCleanup(Kind, sizeof(T));
Cleanup *Obj = new(Buffer) T(a0);
(void) Obj;
}
/// Push a lazily-created cleanup on the stack.
template <class T, class A0, class A1>
void pushCleanup(CleanupKind Kind, A0 a0, A1 a1) {
void *Buffer = pushCleanup(Kind, sizeof(T));
Cleanup *Obj = new(Buffer) T(a0, a1);
(void) Obj;
}
/// Push a lazily-created cleanup on the stack.
template <class T, class A0, class A1, class A2>
void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2) {
void *Buffer = pushCleanup(Kind, sizeof(T));
Cleanup *Obj = new(Buffer) T(a0, a1, a2);
(void) Obj;
}
/// Push a lazily-created cleanup on the stack.
template <class T, class A0, class A1, class A2, class A3>
void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2, A3 a3) {
void *Buffer = pushCleanup(Kind, sizeof(T));
Cleanup *Obj = new(Buffer) T(a0, a1, a2, a3);
(void) Obj;
}
/// Push a lazily-created cleanup on the stack.
template <class T, class A0, class A1, class A2, class A3, class A4>
void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2, A3 a3, A4 a4) {
void *Buffer = pushCleanup(Kind, sizeof(T));
Cleanup *Obj = new(Buffer) T(a0, a1, a2, a3, a4);
(void) Obj;
}
// Feel free to add more variants of the following:
/// Push a cleanup with non-constant storage requirements on the
/// stack. The cleanup type must provide an additional static method:
/// static size_t getExtraSize(size_t);
/// The argument to this method will be the value N, which will also
/// be passed as the first argument to the constructor.
///
/// The data stored in the extra storage must obey the same
/// restrictions as normal cleanup member data.
///
/// The pointer returned from this method is valid until the cleanup
/// stack is modified.
template <class T, class A0, class A1, class A2>
T *pushCleanupWithExtra(CleanupKind Kind, size_t N, A0 a0, A1 a1, A2 a2) {
void *Buffer = pushCleanup(Kind, sizeof(T) + T::getExtraSize(N));
return new (Buffer) T(N, a0, a1, a2);
}
/// Pops a cleanup scope off the stack. This is private to CGCleanup.cpp.
void popCleanup();
/// Push a set of catch handlers on the stack. The catch is
/// uninitialized and will need to have the given number of handlers
/// set on it.
class EHCatchScope *pushCatch(unsigned NumHandlers);
/// Pops a catch scope off the stack. This is private to CGException.cpp.
void popCatch();
/// Push an exceptions filter on the stack.
class EHFilterScope *pushFilter(unsigned NumFilters);
/// Pops an exceptions filter off the stack.
void popFilter();
/// Push a terminate handler on the stack.
void pushTerminate();
/// Pops a terminate handler off the stack.
void popTerminate();
/// Determines whether the exception-scopes stack is empty.
bool empty() const { return StartOfData == EndOfBuffer; }
bool requiresLandingPad() const {
return InnermostEHScope != stable_end();
}
/// Determines whether there are any normal cleanups on the stack.
bool hasNormalCleanups() const {
return InnermostNormalCleanup != stable_end();
}
/// Returns the innermost normal cleanup on the stack, or
/// stable_end() if there are no normal cleanups.
stable_iterator getInnermostNormalCleanup() const {
return InnermostNormalCleanup;
}
stable_iterator getInnermostActiveNormalCleanup() const;
stable_iterator getInnermostEHScope() const {
return InnermostEHScope;
}
stable_iterator getInnermostActiveEHScope() const;
/// An unstable reference to a scope-stack depth. Invalidated by
/// pushes but not pops.
class iterator;
/// Returns an iterator pointing to the innermost EH scope.
iterator begin() const;
/// Returns an iterator pointing to the outermost EH scope.
iterator end() const;
/// Create a stable reference to the top of the EH stack. The
/// returned reference is valid until that scope is popped off the
/// stack.
stable_iterator stable_begin() const {
return stable_iterator(EndOfBuffer - StartOfData);
}
/// Create a stable reference to the bottom of the EH stack.
static stable_iterator stable_end() {
return stable_iterator(0);
}
/// Translates an iterator into a stable_iterator.
stable_iterator stabilize(iterator it) const;
/// Turn a stable reference to a scope depth into a unstable pointer
/// to the EH stack.
iterator find(stable_iterator save) const;
/// Removes the cleanup pointed to by the given stable_iterator.
void removeCleanup(stable_iterator save);
/// Add a branch fixup to the current cleanup scope.
BranchFixup &addBranchFixup() {
assert(hasNormalCleanups() && "adding fixup in scope without cleanups");
BranchFixups.push_back(BranchFixup());
return BranchFixups.back();
}
unsigned getNumBranchFixups() const { return BranchFixups.size(); }
BranchFixup &getBranchFixup(unsigned I) {
assert(I < getNumBranchFixups());
return BranchFixups[I];
}
/// Pops lazily-removed fixups from the end of the list. This
/// should only be called by procedures which have just popped a
/// cleanup or resolved one or more fixups.
void popNullFixups();
/// Clears the branch-fixups list. This should only be called by
/// ResolveAllBranchFixups.
void clearFixups() { BranchFixups.clear(); }
};
/// CodeGenFunction - This class organizes the per-function state that is used
/// while generating LLVM code.
class CodeGenFunction : public CodeGenTypeCache {
CodeGenFunction(const CodeGenFunction&); // DO NOT IMPLEMENT
void operator=(const CodeGenFunction&); // DO NOT IMPLEMENT
friend class CGCXXABI;
public:
/// A jump destination is an abstract label, branching to which may
/// require a jump out through normal cleanups.
struct JumpDest {
JumpDest() : Block(0), ScopeDepth(), Index(0) {}
JumpDest(llvm::BasicBlock *Block,
EHScopeStack::stable_iterator Depth,
unsigned Index)
: Block(Block), ScopeDepth(Depth), Index(Index) {}
bool isValid() const { return Block != 0; }
llvm::BasicBlock *getBlock() const { return Block; }
EHScopeStack::stable_iterator getScopeDepth() const { return ScopeDepth; }
unsigned getDestIndex() const { return Index; }
private:
llvm::BasicBlock *Block;
EHScopeStack::stable_iterator ScopeDepth;
unsigned Index;
};
CodeGenModule &CGM; // Per-module state.
const TargetInfo &Target;
typedef std::pair<llvm::Value *, llvm::Value *> ComplexPairTy;
CGBuilderTy Builder;
/// CurFuncDecl - Holds the Decl for the current function or ObjC method.
/// This excludes BlockDecls.
const Decl *CurFuncDecl;
/// CurCodeDecl - This is the inner-most code context, which includes blocks.
const Decl *CurCodeDecl;
const CGFunctionInfo *CurFnInfo;
QualType FnRetTy;
llvm::Function *CurFn;
/// CurGD - The GlobalDecl for the current function being compiled.
GlobalDecl CurGD;
/// PrologueCleanupDepth - The cleanup depth enclosing all the
/// cleanups associated with the parameters.
EHScopeStack::stable_iterator PrologueCleanupDepth;
/// ReturnBlock - Unified return block.
JumpDest ReturnBlock;
/// ReturnValue - The temporary alloca to hold the return value. This is null
/// iff the function has no return value.
llvm::Value *ReturnValue;
/// AllocaInsertPoint - This is an instruction in the entry block before which
/// we prefer to insert allocas.
llvm::AssertingVH<llvm::Instruction> AllocaInsertPt;
bool CatchUndefined;
/// In ARC, whether we should autorelease the return value.
bool AutoreleaseResult;
const CodeGen::CGBlockInfo *BlockInfo;
llvm::Value *BlockPointer;
llvm::DenseMap<const VarDecl *, FieldDecl *> LambdaCaptureFields;
FieldDecl *LambdaThisCaptureField;
/// \brief A mapping from NRVO variables to the flags used to indicate
/// when the NRVO has been applied to this variable.
llvm::DenseMap<const VarDecl *, llvm::Value *> NRVOFlags;
EHScopeStack EHStack;
/// i32s containing the indexes of the cleanup destinations.
llvm::AllocaInst *NormalCleanupDest;
unsigned NextCleanupDestIndex;
/// FirstBlockInfo - The head of a singly-linked-list of block layouts.
CGBlockInfo *FirstBlockInfo;
/// EHResumeBlock - Unified block containing a call to llvm.eh.resume.
llvm::BasicBlock *EHResumeBlock;
/// The exception slot. All landing pads write the current exception pointer
/// into this alloca.
llvm::Value *ExceptionSlot;
/// The selector slot. Under the MandatoryCleanup model, all landing pads
/// write the current selector value into this alloca.
llvm::AllocaInst *EHSelectorSlot;
/// Emits a landing pad for the current EH stack.
llvm::BasicBlock *EmitLandingPad();
llvm::BasicBlock *getInvokeDestImpl();
template <class T>
typename DominatingValue<T>::saved_type saveValueInCond(T value) {
return DominatingValue<T>::save(*this, value);
}
public:
/// ObjCEHValueStack - Stack of Objective-C exception values, used for
/// rethrows.
SmallVector<llvm::Value*, 8> ObjCEHValueStack;
/// A class controlling the emission of a finally block.
class FinallyInfo {
/// Where the catchall's edge through the cleanup should go.
JumpDest RethrowDest;
/// A function to call to enter the catch.
llvm::Constant *BeginCatchFn;
/// An i1 variable indicating whether or not the @finally is
/// running for an exception.
llvm::AllocaInst *ForEHVar;
/// An i8* variable into which the exception pointer to rethrow
/// has been saved.
llvm::AllocaInst *SavedExnVar;
public:
void enter(CodeGenFunction &CGF, const Stmt *Finally,
llvm::Constant *beginCatchFn, llvm::Constant *endCatchFn,
llvm::Constant *rethrowFn);
void exit(CodeGenFunction &CGF);
};
/// pushFullExprCleanup - Push a cleanup to be run at the end of the
/// current full-expression. Safe against the possibility that
/// we're currently inside a conditionally-evaluated expression.
template <class T, class A0>
void pushFullExprCleanup(CleanupKind kind, A0 a0) {
// If we're not in a conditional branch, or if none of the
// arguments requires saving, then use the unconditional cleanup.
if (!isInConditionalBranch())
return EHStack.pushCleanup<T>(kind, a0);
typename DominatingValue<A0>::saved_type a0_saved = saveValueInCond(a0);
typedef EHScopeStack::ConditionalCleanup1<T, A0> CleanupType;
EHStack.pushCleanup<CleanupType>(kind, a0_saved);
initFullExprCleanup();
}
/// pushFullExprCleanup - Push a cleanup to be run at the end of the
/// current full-expression. Safe against the possibility that
/// we're currently inside a conditionally-evaluated expression.
template <class T, class A0, class A1>
void pushFullExprCleanup(CleanupKind kind, A0 a0, A1 a1) {
// If we're not in a conditional branch, or if none of the
// arguments requires saving, then use the unconditional cleanup.
if (!isInConditionalBranch())
return EHStack.pushCleanup<T>(kind, a0, a1);
typename DominatingValue<A0>::saved_type a0_saved = saveValueInCond(a0);
typename DominatingValue<A1>::saved_type a1_saved = saveValueInCond(a1);
typedef EHScopeStack::ConditionalCleanup2<T, A0, A1> CleanupType;
EHStack.pushCleanup<CleanupType>(kind, a0_saved, a1_saved);
initFullExprCleanup();
}
/// pushFullExprCleanup - Push a cleanup to be run at the end of the
/// current full-expression. Safe against the possibility that
/// we're currently inside a conditionally-evaluated expression.
template <class T, class A0, class A1, class A2>
void pushFullExprCleanup(CleanupKind kind, A0 a0, A1 a1, A2 a2) {
// If we're not in a conditional branch, or if none of the
// arguments requires saving, then use the unconditional cleanup.
if (!isInConditionalBranch()) {
return EHStack.pushCleanup<T>(kind, a0, a1, a2);
}
typename DominatingValue<A0>::saved_type a0_saved = saveValueInCond(a0);
typename DominatingValue<A1>::saved_type a1_saved = saveValueInCond(a1);
typename DominatingValue<A2>::saved_type a2_saved = saveValueInCond(a2);
typedef EHScopeStack::ConditionalCleanup3<T, A0, A1, A2> CleanupType;
EHStack.pushCleanup<CleanupType>(kind, a0_saved, a1_saved, a2_saved);
initFullExprCleanup();
}
/// pushFullExprCleanup - Push a cleanup to be run at the end of the
/// current full-expression. Safe against the possibility that
/// we're currently inside a conditionally-evaluated expression.
template <class T, class A0, class A1, class A2, class A3>
void pushFullExprCleanup(CleanupKind kind, A0 a0, A1 a1, A2 a2, A3 a3) {
// If we're not in a conditional branch, or if none of the
// arguments requires saving, then use the unconditional cleanup.
if (!isInConditionalBranch()) {
return EHStack.pushCleanup<T>(kind, a0, a1, a2, a3);
}
typename DominatingValue<A0>::saved_type a0_saved = saveValueInCond(a0);
typename DominatingValue<A1>::saved_type a1_saved = saveValueInCond(a1);
typename DominatingValue<A2>::saved_type a2_saved = saveValueInCond(a2);
typename DominatingValue<A3>::saved_type a3_saved = saveValueInCond(a3);
typedef EHScopeStack::ConditionalCleanup4<T, A0, A1, A2, A3> CleanupType;
EHStack.pushCleanup<CleanupType>(kind, a0_saved, a1_saved,
a2_saved, a3_saved);
initFullExprCleanup();
}
/// Set up the last cleaup that was pushed as a conditional
/// full-expression cleanup.
void initFullExprCleanup();
/// PushDestructorCleanup - Push a cleanup to call the
/// complete-object destructor of an object of the given type at the
/// given address. Does nothing if T is not a C++ class type with a
/// non-trivial destructor.
void PushDestructorCleanup(QualType T, llvm::Value *Addr);
/// PushDestructorCleanup - Push a cleanup to call the
/// complete-object variant of the given destructor on the object at
/// the given address.
void PushDestructorCleanup(const CXXDestructorDecl *Dtor,
llvm::Value *Addr);
/// PopCleanupBlock - Will pop the cleanup entry on the stack and
/// process all branch fixups.
void PopCleanupBlock(bool FallThroughIsBranchThrough = false);
/// DeactivateCleanupBlock - Deactivates the given cleanup block.
/// The block cannot be reactivated. Pops it if it's the top of the
/// stack.
///
/// \param DominatingIP - An instruction which is known to
/// dominate the current IP (if set) and which lies along
/// all paths of execution between the current IP and the
/// the point at which the cleanup comes into scope.
void DeactivateCleanupBlock(EHScopeStack::stable_iterator Cleanup,
llvm::Instruction *DominatingIP);
/// ActivateCleanupBlock - Activates an initially-inactive cleanup.
/// Cannot be used to resurrect a deactivated cleanup.
///
/// \param DominatingIP - An instruction which is known to
/// dominate the current IP (if set) and which lies along
/// all paths of execution between the current IP and the
/// the point at which the cleanup comes into scope.
void ActivateCleanupBlock(EHScopeStack::stable_iterator Cleanup,
llvm::Instruction *DominatingIP);
/// \brief Enters a new scope for capturing cleanups, all of which
/// will be executed once the scope is exited.
class RunCleanupsScope {
EHScopeStack::stable_iterator CleanupStackDepth;
bool OldDidCallStackSave;
bool PerformCleanup;
RunCleanupsScope(const RunCleanupsScope &); // DO NOT IMPLEMENT
RunCleanupsScope &operator=(const RunCleanupsScope &); // DO NOT IMPLEMENT
protected:
CodeGenFunction& CGF;
public:
/// \brief Enter a new cleanup scope.
explicit RunCleanupsScope(CodeGenFunction &CGF)
: PerformCleanup(true), CGF(CGF)
{
CleanupStackDepth = CGF.EHStack.stable_begin();
OldDidCallStackSave = CGF.DidCallStackSave;
CGF.DidCallStackSave = false;
}
/// \brief Exit this cleanup scope, emitting any accumulated
/// cleanups.
~RunCleanupsScope() {
if (PerformCleanup) {
CGF.DidCallStackSave = OldDidCallStackSave;
CGF.PopCleanupBlocks(CleanupStackDepth);
}
}
/// \brief Determine whether this scope requires any cleanups.
bool requiresCleanups() const {
return CGF.EHStack.stable_begin() != CleanupStackDepth;
}
/// \brief Force the emission of cleanups now, instead of waiting
/// until this object is destroyed.
void ForceCleanup() {
assert(PerformCleanup && "Already forced cleanup");
CGF.DidCallStackSave = OldDidCallStackSave;
CGF.PopCleanupBlocks(CleanupStackDepth);
PerformCleanup = false;
}
};
class LexicalScope: protected RunCleanupsScope {
SourceRange Range;
bool PopDebugStack;
LexicalScope(const LexicalScope &); // DO NOT IMPLEMENT THESE
LexicalScope &operator=(const LexicalScope &);
public:
/// \brief Enter a new cleanup scope.
explicit LexicalScope(CodeGenFunction &CGF, SourceRange Range)
: RunCleanupsScope(CGF), Range(Range), PopDebugStack(true) {
if (CGDebugInfo *DI = CGF.getDebugInfo())
DI->EmitLexicalBlockStart(CGF.Builder, Range.getBegin());
}
/// \brief Exit this cleanup scope, emitting any accumulated
/// cleanups.
~LexicalScope() {
if (PopDebugStack) {
CGDebugInfo *DI = CGF.getDebugInfo();
if (DI) DI->EmitLexicalBlockEnd(CGF.Builder, Range.getEnd());
}
}
/// \brief Force the emission of cleanups now, instead of waiting
/// until this object is destroyed.
void ForceCleanup() {
RunCleanupsScope::ForceCleanup();
if (CGDebugInfo *DI = CGF.getDebugInfo()) {
DI->EmitLexicalBlockEnd(CGF.Builder, Range.getEnd());
PopDebugStack = false;
}
}
};
/// PopCleanupBlocks - Takes the old cleanup stack size and emits
/// the cleanup blocks that have been added.
void PopCleanupBlocks(EHScopeStack::stable_iterator OldCleanupStackSize);
void ResolveBranchFixups(llvm::BasicBlock *Target);
/// The given basic block lies in the current EH scope, but may be a
/// target of a potentially scope-crossing jump; get a stable handle
/// to which we can perform this jump later.
JumpDest getJumpDestInCurrentScope(llvm::BasicBlock *Target) {
return JumpDest(Target,
EHStack.getInnermostNormalCleanup(),
NextCleanupDestIndex++);
}
/// The given basic block lies in the current EH scope, but may be a
/// target of a potentially scope-crossing jump; get a stable handle
/// to which we can perform this jump later.
JumpDest getJumpDestInCurrentScope(StringRef Name = StringRef()) {
return getJumpDestInCurrentScope(createBasicBlock(Name));
}
/// EmitBranchThroughCleanup - Emit a branch from the current insert
/// block through the normal cleanup handling code (if any) and then
/// on to \arg Dest.
void EmitBranchThroughCleanup(JumpDest Dest);
/// isObviouslyBranchWithoutCleanups - Return true if a branch to the
/// specified destination obviously has no cleanups to run. 'false' is always
/// a conservatively correct answer for this method.
bool isObviouslyBranchWithoutCleanups(JumpDest Dest) const;
/// popCatchScope - Pops the catch scope at the top of the EHScope
/// stack, emitting any required code (other than the catch handlers
/// themselves).
void popCatchScope();
llvm::BasicBlock *getEHResumeBlock();
llvm::BasicBlock *getEHDispatchBlock(EHScopeStack::stable_iterator scope);
/// An object to manage conditionally-evaluated expressions.
class ConditionalEvaluation {
llvm::BasicBlock *StartBB;
public:
ConditionalEvaluation(CodeGenFunction &CGF)
: StartBB(CGF.Builder.GetInsertBlock()) {}
void begin(CodeGenFunction &CGF) {
assert(CGF.OutermostConditional != this);
if (!CGF.OutermostConditional)
CGF.OutermostConditional = this;
}
void end(CodeGenFunction &CGF) {
assert(CGF.OutermostConditional != 0);
if (CGF.OutermostConditional == this)
CGF.OutermostConditional = 0;
}
/// Returns a block which will be executed prior to each
/// evaluation of the conditional code.
llvm::BasicBlock *getStartingBlock() const {
return StartBB;
}
};
/// isInConditionalBranch - Return true if we're currently emitting
/// one branch or the other of a conditional expression.
bool isInConditionalBranch() const { return OutermostConditional != 0; }
void setBeforeOutermostConditional(llvm::Value *value, llvm::Value *addr) {
assert(isInConditionalBranch());
llvm::BasicBlock *block = OutermostConditional->getStartingBlock();
new llvm::StoreInst(value, addr, &block->back());
}
/// An RAII object to record that we're evaluating a statement
/// expression.
class StmtExprEvaluation {
CodeGenFunction &CGF;
/// We have to save the outermost conditional: cleanups in a
/// statement expression aren't conditional just because the
/// StmtExpr is.
ConditionalEvaluation *SavedOutermostConditional;
public:
StmtExprEvaluation(CodeGenFunction &CGF)
: CGF(CGF), SavedOutermostConditional(CGF.OutermostConditional) {
CGF.OutermostConditional = 0;
}
~StmtExprEvaluation() {
CGF.OutermostConditional = SavedOutermostConditional;
CGF.EnsureInsertPoint();
}
};
/// An object which temporarily prevents a value from being
/// destroyed by aggressive peephole optimizations that assume that
/// all uses of a value have been realized in the IR.
class PeepholeProtection {
llvm::Instruction *Inst;
friend class CodeGenFunction;
public:
PeepholeProtection() : Inst(0) {}
};
/// A non-RAII class containing all the information about a bound
/// opaque value. OpaqueValueMapping, below, is a RAII wrapper for
/// this which makes individual mappings very simple; using this
/// class directly is useful when you have a variable number of
/// opaque values or don't want the RAII functionality for some
/// reason.
class OpaqueValueMappingData {
const OpaqueValueExpr *OpaqueValue;
bool BoundLValue;
CodeGenFunction::PeepholeProtection Protection;
OpaqueValueMappingData(const OpaqueValueExpr *ov,
bool boundLValue)
: OpaqueValue(ov), BoundLValue(boundLValue) {}
public:
OpaqueValueMappingData() : OpaqueValue(0) {}
static bool shouldBindAsLValue(const Expr *expr) {
// gl-values should be bound as l-values for obvious reasons.
// Records should be bound as l-values because IR generation
// always keeps them in memory. Expressions of function type
// act exactly like l-values but are formally required to be
// r-values in C.
return expr->isGLValue() ||
expr->getType()->isRecordType() ||
expr->getType()->isFunctionType();
}
static OpaqueValueMappingData bind(CodeGenFunction &CGF,
const OpaqueValueExpr *ov,
const Expr *e) {
if (shouldBindAsLValue(ov))
return bind(CGF, ov, CGF.EmitLValue(e));
return bind(CGF, ov, CGF.EmitAnyExpr(e));
}
static OpaqueValueMappingData bind(CodeGenFunction &CGF,
const OpaqueValueExpr *ov,
const LValue &lv) {
assert(shouldBindAsLValue(ov));
CGF.OpaqueLValues.insert(std::make_pair(ov, lv));
return OpaqueValueMappingData(ov, true);
}
static OpaqueValueMappingData bind(CodeGenFunction &CGF,
const OpaqueValueExpr *ov,
const RValue &rv) {
assert(!shouldBindAsLValue(ov));
CGF.OpaqueRValues.insert(std::make_pair(ov, rv));
OpaqueValueMappingData data(ov, false);
// Work around an extremely aggressive peephole optimization in
// EmitScalarConversion which assumes that all other uses of a
// value are extant.
data.Protection = CGF.protectFromPeepholes(rv);
return data;
}
bool isValid() const { return OpaqueValue != 0; }
void clear() { OpaqueValue = 0; }
void unbind(CodeGenFunction &CGF) {
assert(OpaqueValue && "no data to unbind!");
if (BoundLValue) {
CGF.OpaqueLValues.erase(OpaqueValue);
} else {
CGF.OpaqueRValues.erase(OpaqueValue);
CGF.unprotectFromPeepholes(Protection);
}
}
};
/// An RAII object to set (and then clear) a mapping for an OpaqueValueExpr.
class OpaqueValueMapping {
CodeGenFunction &CGF;
OpaqueValueMappingData Data;
public:
static bool shouldBindAsLValue(const Expr *expr) {
return OpaqueValueMappingData::shouldBindAsLValue(expr);
}
/// Build the opaque value mapping for the given conditional
/// operator if it's the GNU ?: extension. This is a common
/// enough pattern that the convenience operator is really
/// helpful.
///
OpaqueValueMapping(CodeGenFunction &CGF,
const AbstractConditionalOperator *op) : CGF(CGF) {
if (isa<ConditionalOperator>(op))
// Leave Data empty.
return;
const BinaryConditionalOperator *e = cast<BinaryConditionalOperator>(op);
Data = OpaqueValueMappingData::bind(CGF, e->getOpaqueValue(),
e->getCommon());
}
OpaqueValueMapping(CodeGenFunction &CGF,
const OpaqueValueExpr *opaqueValue,
LValue lvalue)
: CGF(CGF), Data(OpaqueValueMappingData::bind(CGF, opaqueValue, lvalue)) {
}
OpaqueValueMapping(CodeGenFunction &CGF,
const OpaqueValueExpr *opaqueValue,
RValue rvalue)
: CGF(CGF), Data(OpaqueValueMappingData::bind(CGF, opaqueValue, rvalue)) {
}
void pop() {
Data.unbind(CGF);
Data.clear();
}
~OpaqueValueMapping() {
if (Data.isValid()) Data.unbind(CGF);
}
};
/// getByrefValueFieldNumber - Given a declaration, returns the LLVM field
/// number that holds the value.
unsigned getByRefValueLLVMField(const ValueDecl *VD) const;
/// BuildBlockByrefAddress - Computes address location of the
/// variable which is declared as __block.
llvm::Value *BuildBlockByrefAddress(llvm::Value *BaseAddr,
const VarDecl *V);
private:
CGDebugInfo *DebugInfo;
bool DisableDebugInfo;
/// DidCallStackSave - Whether llvm.stacksave has been called. Used to avoid
/// calling llvm.stacksave for multiple VLAs in the same scope.
bool DidCallStackSave;
/// IndirectBranch - The first time an indirect goto is seen we create a block
/// with an indirect branch. Every time we see the address of a label taken,
/// we add the label to the indirect goto. Every subsequent indirect goto is
/// codegen'd as a jump to the IndirectBranch's basic block.
llvm::IndirectBrInst *IndirectBranch;
/// LocalDeclMap - This keeps track of the LLVM allocas or globals for local C
/// decls.
typedef llvm::DenseMap<const Decl*, llvm::Value*> DeclMapTy;
DeclMapTy LocalDeclMap;
/// LabelMap - This keeps track of the LLVM basic block for each C label.
llvm::DenseMap<const LabelDecl*, JumpDest> LabelMap;
// BreakContinueStack - This keeps track of where break and continue
// statements should jump to.
struct BreakContinue {
BreakContinue(JumpDest Break, JumpDest Continue)
: BreakBlock(Break), ContinueBlock(Continue) {}
JumpDest BreakBlock;
JumpDest ContinueBlock;
};
SmallVector<BreakContinue, 8> BreakContinueStack;
/// SwitchInsn - This is nearest current switch instruction. It is null if
/// current context is not in a switch.
llvm::SwitchInst *SwitchInsn;
/// CaseRangeBlock - This block holds if condition check for last case
/// statement range in current switch instruction.
llvm::BasicBlock *CaseRangeBlock;
/// OpaqueLValues - Keeps track of the current set of opaque value
/// expressions.
llvm::DenseMap<const OpaqueValueExpr *, LValue> OpaqueLValues;
llvm::DenseMap<const OpaqueValueExpr *, RValue> OpaqueRValues;
// VLASizeMap - This keeps track of the associated size for each VLA type.
// We track this by the size expression rather than the type itself because
// in certain situations, like a const qualifier applied to an VLA typedef,
// multiple VLA types can share the same size expression.
// FIXME: Maybe this could be a stack of maps that is pushed/popped as we
// enter/leave scopes.
llvm::DenseMap<const Expr*, llvm::Value*> VLASizeMap;
/// A block containing a single 'unreachable' instruction. Created
/// lazily by getUnreachableBlock().
llvm::BasicBlock *UnreachableBlock;
/// CXXThisDecl - When generating code for a C++ member function,
/// this will hold the implicit 'this' declaration.
ImplicitParamDecl *CXXABIThisDecl;
llvm::Value *CXXABIThisValue;
llvm::Value *CXXThisValue;
/// CXXVTTDecl - When generating code for a base object constructor or
/// base object destructor with virtual bases, this will hold the implicit
/// VTT parameter.
ImplicitParamDecl *CXXVTTDecl;
llvm::Value *CXXVTTValue;
/// OutermostConditional - Points to the outermost active
/// conditional control. This is used so that we know if a
/// temporary should be destroyed conditionally.
ConditionalEvaluation *OutermostConditional;
/// ByrefValueInfoMap - For each __block variable, contains a pair of the LLVM
/// type as well as the field number that contains the actual data.
llvm::DenseMap<const ValueDecl *, std::pair<llvm::Type *,
unsigned> > ByRefValueInfo;
llvm::BasicBlock *TerminateLandingPad;
llvm::BasicBlock *TerminateHandler;
llvm::BasicBlock *TrapBB;
public:
CodeGenFunction(CodeGenModule &cgm);
~CodeGenFunction();
CodeGenTypes &getTypes() const { return CGM.getTypes(); }
ASTContext &getContext() const { return CGM.getContext(); }
CGDebugInfo *getDebugInfo() {
if (DisableDebugInfo)
return NULL;
return DebugInfo;
}
void disableDebugInfo() { DisableDebugInfo = true; }
void enableDebugInfo() { DisableDebugInfo = false; }
bool shouldUseFusedARCCalls() {
return CGM.getCodeGenOpts().OptimizationLevel == 0;
}
const LangOptions &getLangOptions() const { return CGM.getLangOptions(); }
/// Returns a pointer to the function's exception object and selector slot,
/// which is assigned in every landing pad.
llvm::Value *getExceptionSlot();
llvm::Value *getEHSelectorSlot();
/// Returns the contents of the function's exception object and selector
/// slots.
llvm::Value *getExceptionFromSlot();
llvm::Value *getSelectorFromSlot();
llvm::Value *getNormalCleanupDestSlot();
llvm::BasicBlock *getUnreachableBlock() {
if (!UnreachableBlock) {
UnreachableBlock = createBasicBlock("unreachable");
new llvm::UnreachableInst(getLLVMContext(), UnreachableBlock);
}
return UnreachableBlock;
}
llvm::BasicBlock *getInvokeDest() {
if (!EHStack.requiresLandingPad()) return 0;
return getInvokeDestImpl();
}
llvm::LLVMContext &getLLVMContext() { return CGM.getLLVMContext(); }
//===--------------------------------------------------------------------===//
// Cleanups
//===--------------------------------------------------------------------===//
typedef void Destroyer(CodeGenFunction &CGF, llvm::Value *addr, QualType ty);
void pushIrregularPartialArrayCleanup(llvm::Value *arrayBegin,
llvm::Value *arrayEndPointer,
QualType elementType,
Destroyer *destroyer);
void pushRegularPartialArrayCleanup(llvm::Value *arrayBegin,
llvm::Value *arrayEnd,
QualType elementType,
Destroyer *destroyer);
void pushDestroy(QualType::DestructionKind dtorKind,
llvm::Value *addr, QualType type);
void pushDestroy(CleanupKind kind, llvm::Value *addr, QualType type,
Destroyer *destroyer, bool useEHCleanupForArray);
void emitDestroy(llvm::Value *addr, QualType type, Destroyer *destroyer,
bool useEHCleanupForArray);
llvm::Function *generateDestroyHelper(llvm::Constant *addr,
QualType type,
Destroyer *destroyer,
bool useEHCleanupForArray);
void emitArrayDestroy(llvm::Value *begin, llvm::Value *end,
QualType type, Destroyer *destroyer,
bool checkZeroLength, bool useEHCleanup);
Destroyer *getDestroyer(QualType::DestructionKind destructionKind);
/// Determines whether an EH cleanup is required to destroy a type
/// with the given destruction kind.
bool needsEHCleanup(QualType::DestructionKind kind) {
switch (kind) {
case QualType::DK_none:
return false;
case QualType::DK_cxx_destructor:
case QualType::DK_objc_weak_lifetime:
return getLangOptions().Exceptions;
case QualType::DK_objc_strong_lifetime:
return getLangOptions().Exceptions &&
CGM.getCodeGenOpts().ObjCAutoRefCountExceptions;
}
llvm_unreachable("bad destruction kind");
}
CleanupKind getCleanupKind(QualType::DestructionKind kind) {
return (needsEHCleanup(kind) ? NormalAndEHCleanup : NormalCleanup);
}
//===--------------------------------------------------------------------===//
// Objective-C
//===--------------------------------------------------------------------===//
void GenerateObjCMethod(const ObjCMethodDecl *OMD);
void StartObjCMethod(const ObjCMethodDecl *MD,
const ObjCContainerDecl *CD,
SourceLocation StartLoc);
/// GenerateObjCGetter - Synthesize an Objective-C property getter function.
void GenerateObjCGetter(ObjCImplementationDecl *IMP,
const ObjCPropertyImplDecl *PID);
void generateObjCGetterBody(const ObjCImplementationDecl *classImpl,
const ObjCPropertyImplDecl *propImpl,
llvm::Constant *AtomicHelperFn);
void GenerateObjCCtorDtorMethod(ObjCImplementationDecl *IMP,
ObjCMethodDecl *MD, bool ctor);
/// GenerateObjCSetter - Synthesize an Objective-C property setter function
/// for the given property.
void GenerateObjCSetter(ObjCImplementationDecl *IMP,
const ObjCPropertyImplDecl *PID);
void generateObjCSetterBody(const ObjCImplementationDecl *classImpl,
const ObjCPropertyImplDecl *propImpl,
llvm::Constant *AtomicHelperFn);
bool IndirectObjCSetterArg(const CGFunctionInfo &FI);
bool IvarTypeWithAggrGCObjects(QualType Ty);
//===--------------------------------------------------------------------===//
// Block Bits
//===--------------------------------------------------------------------===//
llvm::Value *EmitBlockLiteral(const BlockExpr *);
llvm::Value *EmitBlockLiteral(const CGBlockInfo &Info);
static void destroyBlockInfos(CGBlockInfo *info);
llvm::Constant *BuildDescriptorBlockDecl(const BlockExpr *,
const CGBlockInfo &Info,
llvm::StructType *,
llvm::Constant *BlockVarLayout);
llvm::Function *GenerateBlockFunction(GlobalDecl GD,
const CGBlockInfo &Info,
const Decl *OuterFuncDecl,
const DeclMapTy &ldm,
bool IsLambdaConversionToBlock);
llvm::Constant *GenerateCopyHelperFunction(const CGBlockInfo &blockInfo);
llvm::Constant *GenerateDestroyHelperFunction(const CGBlockInfo &blockInfo);
llvm::Constant *GenerateObjCAtomicSetterCopyHelperFunction(
const ObjCPropertyImplDecl *PID);
llvm::Constant *GenerateObjCAtomicGetterCopyHelperFunction(
const ObjCPropertyImplDecl *PID);
llvm::Value *EmitBlockCopyAndAutorelease(llvm::Value *Block, QualType Ty);
void BuildBlockRelease(llvm::Value *DeclPtr, BlockFieldFlags flags);
class AutoVarEmission;
void emitByrefStructureInit(const AutoVarEmission &emission);
void enterByrefCleanup(const AutoVarEmission &emission);
llvm::Value *LoadBlockStruct() {
assert(BlockPointer && "no block pointer set!");
return BlockPointer;
}
void AllocateBlockCXXThisPointer(const CXXThisExpr *E);
void AllocateBlockDecl(const BlockDeclRefExpr *E);
llvm::Value *GetAddrOfBlockDecl(const BlockDeclRefExpr *E) {
return GetAddrOfBlockDecl(E->getDecl(), E->isByRef());
}
llvm::Value *GetAddrOfBlockDecl(const VarDecl *var, bool ByRef);
llvm::Type *BuildByRefType(const VarDecl *var);
void GenerateCode(GlobalDecl GD, llvm::Function *Fn,
const CGFunctionInfo &FnInfo);
void StartFunction(GlobalDecl GD, QualType RetTy,
llvm::Function *Fn,
const CGFunctionInfo &FnInfo,
const FunctionArgList &Args,
SourceLocation StartLoc);
void EmitConstructorBody(FunctionArgList &Args);
void EmitDestructorBody(FunctionArgList &Args);
void EmitFunctionBody(FunctionArgList &Args);
void EmitForwardingCallToLambda(const CXXRecordDecl *Lambda,
CallArgList &CallArgs);
void EmitLambdaToBlockPointerBody(FunctionArgList &Args);
void EmitLambdaBlockInvokeBody();
void EmitLambdaDelegatingInvokeBody(const CXXMethodDecl *MD);
void EmitLambdaStaticInvokeFunction(const CXXMethodDecl *MD);
/// EmitReturnBlock - Emit the unified return block, trying to avoid its
/// emission when possible.
void EmitReturnBlock();
/// FinishFunction - Complete IR generation of the current function. It is
/// legal to call this function even if there is no current insertion point.
void FinishFunction(SourceLocation EndLoc=SourceLocation());
/// GenerateThunk - Generate a thunk for the given method.
void GenerateThunk(llvm::Function *Fn, const CGFunctionInfo &FnInfo,
GlobalDecl GD, const ThunkInfo &Thunk);
void GenerateVarArgsThunk(llvm::Function *Fn, const CGFunctionInfo &FnInfo,
GlobalDecl GD, const ThunkInfo &Thunk);
void EmitCtorPrologue(const CXXConstructorDecl *CD, CXXCtorType Type,
FunctionArgList &Args);
void EmitInitializerForField(FieldDecl *Field, LValue LHS, Expr *Init,
ArrayRef<VarDecl *> ArrayIndexes);
/// InitializeVTablePointer - Initialize the vtable pointer of the given
/// subobject.
///
void InitializeVTablePointer(BaseSubobject Base,
const CXXRecordDecl *NearestVBase,
CharUnits OffsetFromNearestVBase,
llvm::Constant *VTable,
const CXXRecordDecl *VTableClass);
typedef llvm::SmallPtrSet<const CXXRecordDecl *, 4> VisitedVirtualBasesSetTy;
void InitializeVTablePointers(BaseSubobject Base,
const CXXRecordDecl *NearestVBase,
CharUnits OffsetFromNearestVBase,
bool BaseIsNonVirtualPrimaryBase,
llvm::Constant *VTable,
const CXXRecordDecl *VTableClass,
VisitedVirtualBasesSetTy& VBases);
void InitializeVTablePointers(const CXXRecordDecl *ClassDecl);
/// GetVTablePtr - Return the Value of the vtable pointer member pointed
/// to by This.
llvm::Value *GetVTablePtr(llvm::Value *This, llvm::Type *Ty);
/// EnterDtorCleanups - Enter the cleanups necessary to complete the
/// given phase of destruction for a destructor. The end result
/// should call destructors on members and base classes in reverse
/// order of their construction.
void EnterDtorCleanups(const CXXDestructorDecl *Dtor, CXXDtorType Type);
/// ShouldInstrumentFunction - Return true if the current function should be
/// instrumented with __cyg_profile_func_* calls
bool ShouldInstrumentFunction();
/// EmitFunctionInstrumentation - Emit LLVM code to call the specified
/// instrumentation function with the current function and the call site, if
/// function instrumentation is enabled.
void EmitFunctionInstrumentation(const char *Fn);
/// EmitMCountInstrumentation - Emit call to .mcount.
void EmitMCountInstrumentation();
/// EmitFunctionProlog - Emit the target specific LLVM code to load the
/// arguments for the given function. This is also responsible for naming the
/// LLVM function arguments.
void EmitFunctionProlog(const CGFunctionInfo &FI,
llvm::Function *Fn,
const FunctionArgList &Args);
/// EmitFunctionEpilog - Emit the target specific LLVM code to return the
/// given temporary.
void EmitFunctionEpilog(const CGFunctionInfo &FI);
/// EmitStartEHSpec - Emit the start of the exception spec.
void EmitStartEHSpec(const Decl *D);
/// EmitEndEHSpec - Emit the end of the exception spec.
void EmitEndEHSpec(const Decl *D);
/// getTerminateLandingPad - Return a landing pad that just calls terminate.
llvm::BasicBlock *getTerminateLandingPad();
/// getTerminateHandler - Return a handler (not a landing pad, just
/// a catch handler) that just calls terminate. This is used when
/// a terminate scope encloses a try.
llvm::BasicBlock *getTerminateHandler();
llvm::Type *ConvertTypeForMem(QualType T);
llvm::Type *ConvertType(QualType T);
llvm::Type *ConvertType(const TypeDecl *T) {
return ConvertType(getContext().getTypeDeclType(T));
}
/// LoadObjCSelf - Load the value of self. This function is only valid while
/// generating code for an Objective-C method.
llvm::Value *LoadObjCSelf();
/// TypeOfSelfObject - Return type of object that this self represents.
QualType TypeOfSelfObject();
/// hasAggregateLLVMType - Return true if the specified AST type will map into
/// an aggregate LLVM type or is void.
static bool hasAggregateLLVMType(QualType T);
/// createBasicBlock - Create an LLVM basic block.
llvm::BasicBlock *createBasicBlock(StringRef name = "",
llvm::Function *parent = 0,
llvm::BasicBlock *before = 0) {
#ifdef NDEBUG
return llvm::BasicBlock::Create(getLLVMContext(), "", parent, before);
#else
return llvm::BasicBlock::Create(getLLVMContext(), name, parent, before);
#endif
}
/// getBasicBlockForLabel - Return the LLVM basicblock that the specified
/// label maps to.
JumpDest getJumpDestForLabel(const LabelDecl *S);
/// SimplifyForwardingBlocks - If the given basic block is only a branch to
/// another basic block, simplify it. This assumes that no other code could
/// potentially reference the basic block.
void SimplifyForwardingBlocks(llvm::BasicBlock *BB);
/// EmitBlock - Emit the given block \arg BB and set it as the insert point,
/// adding a fall-through branch from the current insert block if
/// necessary. It is legal to call this function even if there is no current
/// insertion point.
///
/// IsFinished - If true, indicates that the caller has finished emitting
/// branches to the given block and does not expect to emit code into it. This
/// means the block can be ignored if it is unreachable.
void EmitBlock(llvm::BasicBlock *BB, bool IsFinished=false);
/// EmitBlockAfterUses - Emit the given block somewhere hopefully
/// near its uses, and leave the insertion point in it.
void EmitBlockAfterUses(llvm::BasicBlock *BB);
/// EmitBranch - Emit a branch to the specified basic block from the current
/// insert block, taking care to avoid creation of branches from dummy
/// blocks. It is legal to call this function even if there is no current
/// insertion point.
///
/// This function clears the current insertion point. The caller should follow
/// calls to this function with calls to Emit*Block prior to generation new
/// code.
void EmitBranch(llvm::BasicBlock *Block);
/// HaveInsertPoint - True if an insertion point is defined. If not, this
/// indicates that the current code being emitted is unreachable.
bool HaveInsertPoint() const {
return Builder.GetInsertBlock() != 0;
}
/// EnsureInsertPoint - Ensure that an insertion point is defined so that
/// emitted IR has a place to go. Note that by definition, if this function
/// creates a block then that block is unreachable; callers may do better to
/// detect when no insertion point is defined and simply skip IR generation.
void EnsureInsertPoint() {
if (!HaveInsertPoint())
EmitBlock(createBasicBlock());
}
/// ErrorUnsupported - Print out an error that codegen doesn't support the
/// specified stmt yet.
void ErrorUnsupported(const Stmt *S, const char *Type,
bool OmitOnError=false);
//===--------------------------------------------------------------------===//
// Helpers
//===--------------------------------------------------------------------===//
LValue MakeAddrLValue(llvm::Value *V, QualType T,
CharUnits Alignment = CharUnits()) {
return LValue::MakeAddr(V, T, Alignment, getContext(),
CGM.getTBAAInfo(T));
}
LValue MakeNaturalAlignAddrLValue(llvm::Value *V, QualType T) {
CharUnits Alignment;
if (!T->isIncompleteType())
Alignment = getContext().getTypeAlignInChars(T);
return LValue::MakeAddr(V, T, Alignment, getContext(),
CGM.getTBAAInfo(T));
}
/// CreateTempAlloca - This creates a alloca and inserts it into the entry
/// block. The caller is responsible for setting an appropriate alignment on
/// the alloca.
llvm::AllocaInst *CreateTempAlloca(llvm::Type *Ty,
const Twine &Name = "tmp");
/// InitTempAlloca - Provide an initial value for the given alloca.
void InitTempAlloca(llvm::AllocaInst *Alloca, llvm::Value *Value);
/// CreateIRTemp - Create a temporary IR object of the given type, with
/// appropriate alignment. This routine should only be used when an temporary
/// value needs to be stored into an alloca (for example, to avoid explicit
/// PHI construction), but the type is the IR type, not the type appropriate
/// for storing in memory.
llvm::AllocaInst *CreateIRTemp(QualType T, const Twine &Name = "tmp");
/// CreateMemTemp - Create a temporary memory object of the given type, with
/// appropriate alignment.
llvm::AllocaInst *CreateMemTemp(QualType T, const Twine &Name = "tmp");
/// CreateAggTemp - Create a temporary memory object for the given
/// aggregate type.
AggValueSlot CreateAggTemp(QualType T, const Twine &Name = "tmp") {
CharUnits Alignment = getContext().getTypeAlignInChars(T);
return AggValueSlot::forAddr(CreateMemTemp(T, Name), Alignment,
T.getQualifiers(),
AggValueSlot::IsNotDestructed,
AggValueSlot::DoesNotNeedGCBarriers,
AggValueSlot::IsNotAliased);
}
/// Emit a cast to void* in the appropriate address space.
llvm::Value *EmitCastToVoidPtr(llvm::Value *value);
/// EvaluateExprAsBool - Perform the usual unary conversions on the specified
/// expression and compare the result against zero, returning an Int1Ty value.
llvm::Value *EvaluateExprAsBool(const Expr *E);
/// EmitIgnoredExpr - Emit an expression in a context which ignores the result.
void EmitIgnoredExpr(const Expr *E);
/// EmitAnyExpr - Emit code to compute the specified expression which can have
/// any type. The result is returned as an RValue struct. If this is an
/// aggregate expression, the aggloc/agglocvolatile arguments indicate where
/// the result should be returned.
///
/// \param IgnoreResult - True if the resulting value isn't used.
RValue EmitAnyExpr(const Expr *E,
AggValueSlot AggSlot = AggValueSlot::ignored(),
bool IgnoreResult = false);
// EmitVAListRef - Emit a "reference" to a va_list; this is either the address
// or the value of the expression, depending on how va_list is defined.
llvm::Value *EmitVAListRef(const Expr *E);
/// EmitAnyExprToTemp - Similary to EmitAnyExpr(), however, the result will
/// always be accessible even if no aggregate location is provided.
RValue EmitAnyExprToTemp(const Expr *E);
/// EmitAnyExprToMem - Emits the code necessary to evaluate an
/// arbitrary expression into the given memory location.
void EmitAnyExprToMem(const Expr *E, llvm::Value *Location,
Qualifiers Quals, bool IsInitializer);
/// EmitExprAsInit - Emits the code necessary to initialize a
/// location in memory with the given initializer.
void EmitExprAsInit(const Expr *init, const ValueDecl *D,
LValue lvalue, bool capturedByInit);
/// EmitAggregateCopy - Emit an aggrate copy.
///
/// \param isVolatile - True iff either the source or the destination is
/// volatile.
void EmitAggregateCopy(llvm::Value *DestPtr, llvm::Value *SrcPtr,
QualType EltTy, bool isVolatile=false,
unsigned Alignment = 0);
/// StartBlock - Start new block named N. If insert block is a dummy block
/// then reuse it.
void StartBlock(const char *N);
/// GetAddrOfStaticLocalVar - Return the address of a static local variable.
llvm::Constant *GetAddrOfStaticLocalVar(const VarDecl *BVD) {
return cast<llvm::Constant>(GetAddrOfLocalVar(BVD));
}
/// GetAddrOfLocalVar - Return the address of a local variable.
llvm::Value *GetAddrOfLocalVar(const VarDecl *VD) {
llvm::Value *Res = LocalDeclMap[VD];
assert(Res && "Invalid argument to GetAddrOfLocalVar(), no decl!");
return Res;
}
/// getOpaqueLValueMapping - Given an opaque value expression (which
/// must be mapped to an l-value), return its mapping.
const LValue &getOpaqueLValueMapping(const OpaqueValueExpr *e) {
assert(OpaqueValueMapping::shouldBindAsLValue(e));
llvm::DenseMap<const OpaqueValueExpr*,LValue>::iterator
it = OpaqueLValues.find(e);
assert(it != OpaqueLValues.end() && "no mapping for opaque value!");
return it->second;
}
/// getOpaqueRValueMapping - Given an opaque value expression (which
/// must be mapped to an r-value), return its mapping.
const RValue &getOpaqueRValueMapping(const OpaqueValueExpr *e) {
assert(!OpaqueValueMapping::shouldBindAsLValue(e));
llvm::DenseMap<const OpaqueValueExpr*,RValue>::iterator
it = OpaqueRValues.find(e);
assert(it != OpaqueRValues.end() && "no mapping for opaque value!");
return it->second;
}
/// getAccessedFieldNo - Given an encoded value and a result number, return
/// the input field number being accessed.
static unsigned getAccessedFieldNo(unsigned Idx, const llvm::Constant *Elts);
llvm::BlockAddress *GetAddrOfLabel(const LabelDecl *L);
llvm::BasicBlock *GetIndirectGotoBlock();
/// EmitNullInitialization - Generate code to set a value of the given type to
/// null, If the type contains data member pointers, they will be initialized
/// to -1 in accordance with the Itanium C++ ABI.
void EmitNullInitialization(llvm::Value *DestPtr, QualType Ty);
// EmitVAArg - Generate code to get an argument from the passed in pointer
// and update it accordingly. The return value is a pointer to the argument.
// FIXME: We should be able to get rid of this method and use the va_arg
// instruction in LLVM instead once it works well enough.
llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty);
/// emitArrayLength - Compute the length of an array, even if it's a
/// VLA, and drill down to the base element type.
llvm::Value *emitArrayLength(const ArrayType *arrayType,
QualType &baseType,
llvm::Value *&addr);
/// EmitVLASize - Capture all the sizes for the VLA expressions in
/// the given variably-modified type and store them in the VLASizeMap.
///
/// This function can be called with a null (unreachable) insert point.
void EmitVariablyModifiedType(QualType Ty);
/// getVLASize - Returns an LLVM value that corresponds to the size,
/// in non-variably-sized elements, of a variable length array type,
/// plus that largest non-variably-sized element type. Assumes that
/// the type has already been emitted with EmitVariablyModifiedType.
std::pair<llvm::Value*,QualType> getVLASize(const VariableArrayType *vla);
std::pair<llvm::Value*,QualType> getVLASize(QualType vla);
/// LoadCXXThis - Load the value of 'this'. This function is only valid while
/// generating code for an C++ member function.
llvm::Value *LoadCXXThis() {
assert(CXXThisValue && "no 'this' value for this function");
return CXXThisValue;
}
/// LoadCXXVTT - Load the VTT parameter to base constructors/destructors have
/// virtual bases.
llvm::Value *LoadCXXVTT() {
assert(CXXVTTValue && "no VTT value for this function");
return CXXVTTValue;
}
/// GetAddressOfBaseOfCompleteClass - Convert the given pointer to a
/// complete class to the given direct base.
llvm::Value *
GetAddressOfDirectBaseInCompleteClass(llvm::Value *Value,
const CXXRecordDecl *Derived,
const CXXRecordDecl *Base,
bool BaseIsVirtual);
/// GetAddressOfBaseClass - This function will add the necessary delta to the
/// load of 'this' and returns address of the base class.
llvm::Value *GetAddressOfBaseClass(llvm::Value *Value,
const CXXRecordDecl *Derived,
CastExpr::path_const_iterator PathBegin,
CastExpr::path_const_iterator PathEnd,
bool NullCheckValue);
llvm::Value *GetAddressOfDerivedClass(llvm::Value *Value,
const CXXRecordDecl *Derived,
CastExpr::path_const_iterator PathBegin,
CastExpr::path_const_iterator PathEnd,
bool NullCheckValue);
llvm::Value *GetVirtualBaseClassOffset(llvm::Value *This,
const CXXRecordDecl *ClassDecl,
const CXXRecordDecl *BaseClassDecl);
void EmitDelegateCXXConstructorCall(const CXXConstructorDecl *Ctor,
CXXCtorType CtorType,
const FunctionArgList &Args);
// It's important not to confuse this and the previous function. Delegating
// constructors are the C++0x feature. The constructor delegate optimization
// is used to reduce duplication in the base and complete consturctors where
// they are substantially the same.
void EmitDelegatingCXXConstructorCall(const CXXConstructorDecl *Ctor,
const FunctionArgList &Args);
void EmitCXXConstructorCall(const CXXConstructorDecl *D, CXXCtorType Type,
bool ForVirtualBase, llvm::Value *This,
CallExpr::const_arg_iterator ArgBeg,
CallExpr::const_arg_iterator ArgEnd);
void EmitSynthesizedCXXCopyCtorCall(const CXXConstructorDecl *D,
llvm::Value *This, llvm::Value *Src,
CallExpr::const_arg_iterator ArgBeg,
CallExpr::const_arg_iterator ArgEnd);
void EmitCXXAggrConstructorCall(const CXXConstructorDecl *D,
const ConstantArrayType *ArrayTy,
llvm::Value *ArrayPtr,
CallExpr::const_arg_iterator ArgBeg,
CallExpr::const_arg_iterator ArgEnd,
bool ZeroInitialization = false);
void EmitCXXAggrConstructorCall(const CXXConstructorDecl *D,
llvm::Value *NumElements,
llvm::Value *ArrayPtr,
CallExpr::const_arg_iterator ArgBeg,
CallExpr::const_arg_iterator ArgEnd,
bool ZeroInitialization = false);
static Destroyer destroyCXXObject;
void EmitCXXDestructorCall(const CXXDestructorDecl *D, CXXDtorType Type,
bool ForVirtualBase, llvm::Value *This);
void EmitNewArrayInitializer(const CXXNewExpr *E, QualType elementType,
llvm::Value *NewPtr, llvm::Value *NumElements);
void EmitCXXTemporary(const CXXTemporary *Temporary, QualType TempType,
llvm::Value *Ptr);
llvm::Value *EmitCXXNewExpr(const CXXNewExpr *E);
void EmitCXXDeleteExpr(const CXXDeleteExpr *E);
void EmitDeleteCall(const FunctionDecl *DeleteFD, llvm::Value *Ptr,
QualType DeleteTy);
llvm::Value* EmitCXXTypeidExpr(const CXXTypeidExpr *E);
llvm::Value *EmitDynamicCast(llvm::Value *V, const CXXDynamicCastExpr *DCE);
void MaybeEmitStdInitializerListCleanup(llvm::Value *loc, const Expr *init);
void EmitStdInitializerListCleanup(llvm::Value *loc,
const InitListExpr *init);
void EmitCheck(llvm::Value *, unsigned Size);
llvm::Value *EmitScalarPrePostIncDec(const UnaryOperator *E, LValue LV,
bool isInc, bool isPre);
ComplexPairTy EmitComplexPrePostIncDec(const UnaryOperator *E, LValue LV,
bool isInc, bool isPre);
//===--------------------------------------------------------------------===//
// Declaration Emission
//===--------------------------------------------------------------------===//
/// EmitDecl - Emit a declaration.
///
/// This function can be called with a null (unreachable) insert point.
void EmitDecl(const Decl &D);
/// EmitVarDecl - Emit a local variable declaration.
///
/// This function can be called with a null (unreachable) insert point.
void EmitVarDecl(const VarDecl &D);
void EmitScalarInit(const Expr *init, const ValueDecl *D,
LValue lvalue, bool capturedByInit);
void EmitScalarInit(llvm::Value *init, LValue lvalue);
typedef void SpecialInitFn(CodeGenFunction &Init, const VarDecl &D,
llvm::Value *Address);
/// EmitAutoVarDecl - Emit an auto variable declaration.
///
/// This function can be called with a null (unreachable) insert point.
void EmitAutoVarDecl(const VarDecl &D);
class AutoVarEmission {
friend class CodeGenFunction;
const VarDecl *Variable;
/// The alignment of the variable.
CharUnits Alignment;
/// The address of the alloca. Null if the variable was emitted
/// as a global constant.
llvm::Value *Address;
llvm::Value *NRVOFlag;
/// True if the variable is a __block variable.
bool IsByRef;
/// True if the variable is of aggregate type and has a constant
/// initializer.
bool IsConstantAggregate;
struct Invalid {};
AutoVarEmission(Invalid) : Variable(0) {}
AutoVarEmission(const VarDecl &variable)
: Variable(&variable), Address(0), NRVOFlag(0),
IsByRef(false), IsConstantAggregate(false) {}
bool wasEmittedAsGlobal() const { return Address == 0; }
public:
static AutoVarEmission invalid() { return AutoVarEmission(Invalid()); }
/// Returns the address of the object within this declaration.
/// Note that this does not chase the forwarding pointer for
/// __block decls.
llvm::Value *getObjectAddress(CodeGenFunction &CGF) const {
if (!IsByRef) return Address;
return CGF.Builder.CreateStructGEP(Address,
CGF.getByRefValueLLVMField(Variable),
Variable->getNameAsString());
}
};
AutoVarEmission EmitAutoVarAlloca(const VarDecl &var);
void EmitAutoVarInit(const AutoVarEmission &emission);
void EmitAutoVarCleanups(const AutoVarEmission &emission);
void emitAutoVarTypeCleanup(const AutoVarEmission &emission,
QualType::DestructionKind dtorKind);
void EmitStaticVarDecl(const VarDecl &D,
llvm::GlobalValue::LinkageTypes Linkage);
/// EmitParmDecl - Emit a ParmVarDecl or an ImplicitParamDecl.
void EmitParmDecl(const VarDecl &D, llvm::Value *Arg, unsigned ArgNo);
/// protectFromPeepholes - Protect a value that we're intending to
/// store to the side, but which will probably be used later, from
/// aggressive peepholing optimizations that might delete it.
///
/// Pass the result to unprotectFromPeepholes to declare that
/// protection is no longer required.
///
/// There's no particular reason why this shouldn't apply to
/// l-values, it's just that no existing peepholes work on pointers.
PeepholeProtection protectFromPeepholes(RValue rvalue);
void unprotectFromPeepholes(PeepholeProtection protection);
//===--------------------------------------------------------------------===//
// Statement Emission
//===--------------------------------------------------------------------===//
/// EmitStopPoint - Emit a debug stoppoint if we are emitting debug info.
void EmitStopPoint(const Stmt *S);
/// EmitStmt - Emit the code for the statement \arg S. It is legal to call
/// this function even if there is no current insertion point.
///
/// This function may clear the current insertion point; callers should use
/// EnsureInsertPoint if they wish to subsequently generate code without first
/// calling EmitBlock, EmitBranch, or EmitStmt.
void EmitStmt(const Stmt *S);
/// EmitSimpleStmt - Try to emit a "simple" statement which does not
/// necessarily require an insertion point or debug information; typically
/// because the statement amounts to a jump or a container of other
/// statements.
///
/// \return True if the statement was handled.
bool EmitSimpleStmt(const Stmt *S);
RValue EmitCompoundStmt(const CompoundStmt &S, bool GetLast = false,
AggValueSlot AVS = AggValueSlot::ignored());
/// EmitLabel - Emit the block for the given label. It is legal to call this
/// function even if there is no current insertion point.
void EmitLabel(const LabelDecl *D); // helper for EmitLabelStmt.
void EmitLabelStmt(const LabelStmt &S);
void EmitGotoStmt(const GotoStmt &S);
void EmitIndirectGotoStmt(const IndirectGotoStmt &S);
void EmitIfStmt(const IfStmt &S);
void EmitWhileStmt(const WhileStmt &S);
void EmitDoStmt(const DoStmt &S);
void EmitForStmt(const ForStmt &S);
void EmitReturnStmt(const ReturnStmt &S);
void EmitDeclStmt(const DeclStmt &S);
void EmitBreakStmt(const BreakStmt &S);
void EmitContinueStmt(const ContinueStmt &S);
void EmitSwitchStmt(const SwitchStmt &S);
void EmitDefaultStmt(const DefaultStmt &S);
void EmitCaseStmt(const CaseStmt &S);
void EmitCaseStmtRange(const CaseStmt &S);
void EmitAsmStmt(const AsmStmt &S);
void EmitObjCForCollectionStmt(const ObjCForCollectionStmt &S);
void EmitObjCAtTryStmt(const ObjCAtTryStmt &S);
void EmitObjCAtThrowStmt(const ObjCAtThrowStmt &S);
void EmitObjCAtSynchronizedStmt(const ObjCAtSynchronizedStmt &S);
void EmitObjCAutoreleasePoolStmt(const ObjCAutoreleasePoolStmt &S);
llvm::Constant *getUnwindResumeFn();
llvm::Constant *getUnwindResumeOrRethrowFn();
void EnterCXXTryStmt(const CXXTryStmt &S, bool IsFnTryBlock = false);
void ExitCXXTryStmt(const CXXTryStmt &S, bool IsFnTryBlock = false);
void EmitCXXTryStmt(const CXXTryStmt &S);
void EmitCXXForRangeStmt(const CXXForRangeStmt &S);
//===--------------------------------------------------------------------===//
// LValue Expression Emission
//===--------------------------------------------------------------------===//
/// GetUndefRValue - Get an appropriate 'undef' rvalue for the given type.
RValue GetUndefRValue(QualType Ty);
/// EmitUnsupportedRValue - Emit a dummy r-value using the type of E
/// and issue an ErrorUnsupported style diagnostic (using the
/// provided Name).
RValue EmitUnsupportedRValue(const Expr *E,
const char *Name);
/// EmitUnsupportedLValue - Emit a dummy l-value using the type of E and issue
/// an ErrorUnsupported style diagnostic (using the provided Name).
LValue EmitUnsupportedLValue(const Expr *E,
const char *Name);
/// EmitLValue - Emit code to compute a designator that specifies the location
/// of the expression.
///
/// This can return one of two things: a simple address or a bitfield
/// reference. In either case, the LLVM Value* in the LValue structure is
/// guaranteed to be an LLVM pointer type.
///
/// If this returns a bitfield reference, nothing about the pointee type of
/// the LLVM value is known: For example, it may not be a pointer to an
/// integer.
///
/// If this returns a normal address, and if the lvalue's C type is fixed
/// size, this method guarantees that the returned pointer type will point to
/// an LLVM type of the same size of the lvalue's type. If the lvalue has a
/// variable length type, this is not possible.
///
LValue EmitLValue(const Expr *E);
/// EmitCheckedLValue - Same as EmitLValue but additionally we generate
/// checking code to guard against undefined behavior. This is only
/// suitable when we know that the address will be used to access the
/// object.
LValue EmitCheckedLValue(const Expr *E);
/// EmitToMemory - Change a scalar value from its value
/// representation to its in-memory representation.
llvm::Value *EmitToMemory(llvm::Value *Value, QualType Ty);
/// EmitFromMemory - Change a scalar value from its memory
/// representation to its value representation.
llvm::Value *EmitFromMemory(llvm::Value *Value, QualType Ty);
/// EmitLoadOfScalar - Load a scalar value from an address, taking
/// care to appropriately convert from the memory representation to
/// the LLVM value representation.
llvm::Value *EmitLoadOfScalar(llvm::Value *Addr, bool Volatile,
unsigned Alignment, QualType Ty,
llvm::MDNode *TBAAInfo = 0);
/// EmitLoadOfScalar - Load a scalar value from an address, taking
/// care to appropriately convert from the memory representation to
/// the LLVM value representation. The l-value must be a simple
/// l-value.
llvm::Value *EmitLoadOfScalar(LValue lvalue);
/// EmitStoreOfScalar - Store a scalar value to an address, taking
/// care to appropriately convert from the memory representation to
/// the LLVM value representation.
void EmitStoreOfScalar(llvm::Value *Value, llvm::Value *Addr,
bool Volatile, unsigned Alignment, QualType Ty,
llvm::MDNode *TBAAInfo = 0, bool isInit=false);
/// EmitStoreOfScalar - Store a scalar value to an address, taking
/// care to appropriately convert from the memory representation to
/// the LLVM value representation. The l-value must be a simple
/// l-value. The isInit flag indicates whether this is an initialization.
/// If so, atomic qualifiers are ignored and the store is always non-atomic.
void EmitStoreOfScalar(llvm::Value *value, LValue lvalue, bool isInit=false);
/// EmitLoadOfLValue - Given an expression that represents a value lvalue,
/// this method emits the address of the lvalue, then loads the result as an
/// rvalue, returning the rvalue.
RValue EmitLoadOfLValue(LValue V);
RValue EmitLoadOfExtVectorElementLValue(LValue V);
RValue EmitLoadOfBitfieldLValue(LValue LV);
/// EmitStoreThroughLValue - Store the specified rvalue into the specified
/// lvalue, where both are guaranteed to the have the same type, and that type
/// is 'Ty'.
void EmitStoreThroughLValue(RValue Src, LValue Dst, bool isInit=false);
void EmitStoreThroughExtVectorComponentLValue(RValue Src, LValue Dst);
/// EmitStoreThroughLValue - Store Src into Dst with same constraints as
/// EmitStoreThroughLValue.
///
/// \param Result [out] - If non-null, this will be set to a Value* for the
/// bit-field contents after the store, appropriate for use as the result of
/// an assignment to the bit-field.
void EmitStoreThroughBitfieldLValue(RValue Src, LValue Dst,
llvm::Value **Result=0);
/// Emit an l-value for an assignment (simple or compound) of complex type.
LValue EmitComplexAssignmentLValue(const BinaryOperator *E);
LValue EmitComplexCompoundAssignmentLValue(const CompoundAssignOperator *E);
// Note: only available for agg return types
LValue EmitBinaryOperatorLValue(const BinaryOperator *E);
LValue EmitCompoundAssignmentLValue(const CompoundAssignOperator *E);
// Note: only available for agg return types
LValue EmitCallExprLValue(const CallExpr *E);
// Note: only available for agg return types
LValue EmitVAArgExprLValue(const VAArgExpr *E);
LValue EmitDeclRefLValue(const DeclRefExpr *E);
LValue EmitStringLiteralLValue(const StringLiteral *E);
LValue EmitObjCEncodeExprLValue(const ObjCEncodeExpr *E);
LValue EmitPredefinedLValue(const PredefinedExpr *E);
LValue EmitUnaryOpLValue(const UnaryOperator *E);
LValue EmitArraySubscriptExpr(const ArraySubscriptExpr *E);
LValue EmitExtVectorElementExpr(const ExtVectorElementExpr *E);
LValue EmitMemberExpr(const MemberExpr *E);
LValue EmitObjCIsaExpr(const ObjCIsaExpr *E);
LValue EmitCompoundLiteralLValue(const CompoundLiteralExpr *E);
LValue EmitConditionalOperatorLValue(const AbstractConditionalOperator *E);
LValue EmitCastLValue(const CastExpr *E);
LValue EmitNullInitializationLValue(const CXXScalarValueInitExpr *E);
LValue EmitMaterializeTemporaryExpr(const MaterializeTemporaryExpr *E);
LValue EmitOpaqueValueLValue(const OpaqueValueExpr *e);
RValue EmitPseudoObjectRValue(const PseudoObjectExpr *e,
AggValueSlot slot = AggValueSlot::ignored());
LValue EmitPseudoObjectLValue(const PseudoObjectExpr *e);
llvm::Value *EmitIvarOffset(const ObjCInterfaceDecl *Interface,
const ObjCIvarDecl *Ivar);
LValue EmitLValueForAnonRecordField(llvm::Value* Base,
const IndirectFieldDecl* Field,
unsigned CVRQualifiers);
LValue EmitLValueForField(llvm::Value* Base, const FieldDecl* Field,
unsigned CVRQualifiers);
/// EmitLValueForFieldInitialization - Like EmitLValueForField, except that
/// if the Field is a reference, this will return the address of the reference
/// and not the address of the value stored in the reference.
LValue EmitLValueForFieldInitialization(llvm::Value* Base,
const FieldDecl* Field,
unsigned CVRQualifiers);
LValue EmitLValueForIvar(QualType ObjectTy,
llvm::Value* Base, const ObjCIvarDecl *Ivar,
unsigned CVRQualifiers);
LValue EmitLValueForBitfield(llvm::Value* Base, const FieldDecl* Field,
unsigned CVRQualifiers);
LValue EmitBlockDeclRefLValue(const BlockDeclRefExpr *E);
LValue EmitCXXConstructLValue(const CXXConstructExpr *E);
LValue EmitCXXBindTemporaryLValue(const CXXBindTemporaryExpr *E);
LValue EmitLambdaLValue(const LambdaExpr *E);
LValue EmitCXXTypeidLValue(const CXXTypeidExpr *E);
LValue EmitObjCMessageExprLValue(const ObjCMessageExpr *E);
LValue EmitObjCIvarRefLValue(const ObjCIvarRefExpr *E);
LValue EmitStmtExprLValue(const StmtExpr *E);
LValue EmitPointerToDataMemberBinaryExpr(const BinaryOperator *E);
LValue EmitObjCSelectorLValue(const ObjCSelectorExpr *E);
void EmitDeclRefExprDbgValue(const DeclRefExpr *E, llvm::Constant *Init);
//===--------------------------------------------------------------------===//
// Scalar Expression Emission
//===--------------------------------------------------------------------===//
/// EmitCall - Generate a call of the given function, expecting the given
/// result type, and using the given argument list which specifies both the
/// LLVM arguments and the types they were derived from.
///
/// \param TargetDecl - If given, the decl of the function in a direct call;
/// used to set attributes on the call (noreturn, etc.).
RValue EmitCall(const CGFunctionInfo &FnInfo,
llvm::Value *Callee,
ReturnValueSlot ReturnValue,
const CallArgList &Args,
const Decl *TargetDecl = 0,
llvm::Instruction **callOrInvoke = 0);
RValue EmitCall(QualType FnType, llvm::Value *Callee,
ReturnValueSlot ReturnValue,
CallExpr::const_arg_iterator ArgBeg,
CallExpr::const_arg_iterator ArgEnd,
const Decl *TargetDecl = 0);
RValue EmitCallExpr(const CallExpr *E,
ReturnValueSlot ReturnValue = ReturnValueSlot());
llvm::CallSite EmitCallOrInvoke(llvm::Value *Callee,
ArrayRef<llvm::Value *> Args,
const Twine &Name = "");
llvm::CallSite EmitCallOrInvoke(llvm::Value *Callee,
const Twine &Name = "");
llvm::Value *BuildVirtualCall(const CXXMethodDecl *MD, llvm::Value *This,
llvm::Type *Ty);
llvm::Value *BuildVirtualCall(const CXXDestructorDecl *DD, CXXDtorType Type,
llvm::Value *This, llvm::Type *Ty);
llvm::Value *BuildAppleKextVirtualCall(const CXXMethodDecl *MD,
NestedNameSpecifier *Qual,
llvm::Type *Ty);
llvm::Value *BuildAppleKextVirtualDestructorCall(const CXXDestructorDecl *DD,
CXXDtorType Type,
const CXXRecordDecl *RD);
RValue EmitCXXMemberCall(const CXXMethodDecl *MD,
llvm::Value *Callee,
ReturnValueSlot ReturnValue,
llvm::Value *This,
llvm::Value *VTT,
CallExpr::const_arg_iterator ArgBeg,
CallExpr::const_arg_iterator ArgEnd);
RValue EmitCXXMemberCallExpr(const CXXMemberCallExpr *E,
ReturnValueSlot ReturnValue);
RValue EmitCXXMemberPointerCallExpr(const CXXMemberCallExpr *E,
ReturnValueSlot ReturnValue);
llvm::Value *EmitCXXOperatorMemberCallee(const CXXOperatorCallExpr *E,
const CXXMethodDecl *MD,
llvm::Value *This);
RValue EmitCXXOperatorMemberCallExpr(const CXXOperatorCallExpr *E,
const CXXMethodDecl *MD,
ReturnValueSlot ReturnValue);
RValue EmitCUDAKernelCallExpr(const CUDAKernelCallExpr *E,
ReturnValueSlot ReturnValue);
RValue EmitBuiltinExpr(const FunctionDecl *FD,
unsigned BuiltinID, const CallExpr *E);
RValue EmitBlockCallExpr(const CallExpr *E, ReturnValueSlot ReturnValue);
/// EmitTargetBuiltinExpr - Emit the given builtin call. Returns 0 if the call
/// is unhandled by the current target.
llvm::Value *EmitTargetBuiltinExpr(unsigned BuiltinID, const CallExpr *E);
llvm::Value *EmitARMBuiltinExpr(unsigned BuiltinID, const CallExpr *E);
llvm::Value *EmitNeonCall(llvm::Function *F,
SmallVectorImpl<llvm::Value*> &O,
const char *name,
unsigned shift = 0, bool rightshift = false);
llvm::Value *EmitNeonSplat(llvm::Value *V, llvm::Constant *Idx);
llvm::Value *EmitNeonShiftVector(llvm::Value *V, llvm::Type *Ty,
bool negateForRightShift);
llvm::Value *BuildVector(ArrayRef<llvm::Value*> Ops);
llvm::Value *EmitX86BuiltinExpr(unsigned BuiltinID, const CallExpr *E);
llvm::Value *EmitHexagonBuiltinExpr(unsigned BuiltinID, const CallExpr *E);
llvm::Value *EmitPPCBuiltinExpr(unsigned BuiltinID, const CallExpr *E);
llvm::Value *EmitObjCProtocolExpr(const ObjCProtocolExpr *E);
llvm::Value *EmitObjCStringLiteral(const ObjCStringLiteral *E);
llvm::Value *EmitObjCSelectorExpr(const ObjCSelectorExpr *E);
RValue EmitObjCMessageExpr(const ObjCMessageExpr *E,
ReturnValueSlot Return = ReturnValueSlot());
/// Retrieves the default cleanup kind for an ARC cleanup.
/// Except under -fobjc-arc-eh, ARC cleanups are normal-only.
CleanupKind getARCCleanupKind() {
return CGM.getCodeGenOpts().ObjCAutoRefCountExceptions
? NormalAndEHCleanup : NormalCleanup;
}
// ARC primitives.
void EmitARCInitWeak(llvm::Value *value, llvm::Value *addr);
void EmitARCDestroyWeak(llvm::Value *addr);
llvm::Value *EmitARCLoadWeak(llvm::Value *addr);
llvm::Value *EmitARCLoadWeakRetained(llvm::Value *addr);
llvm::Value *EmitARCStoreWeak(llvm::Value *value, llvm::Value *addr,
bool ignored);
void EmitARCCopyWeak(llvm::Value *dst, llvm::Value *src);
void EmitARCMoveWeak(llvm::Value *dst, llvm::Value *src);
llvm::Value *EmitARCRetainAutorelease(QualType type, llvm::Value *value);
llvm::Value *EmitARCRetainAutoreleaseNonBlock(llvm::Value *value);
llvm::Value *EmitARCStoreStrong(LValue lvalue, llvm::Value *value,
bool ignored);
llvm::Value *EmitARCStoreStrongCall(llvm::Value *addr, llvm::Value *value,
bool ignored);
llvm::Value *EmitARCRetain(QualType type, llvm::Value *value);
llvm::Value *EmitARCRetainNonBlock(llvm::Value *value);
llvm::Value *EmitARCRetainBlock(llvm::Value *value, bool mandatory);
void EmitARCRelease(llvm::Value *value, bool precise);
llvm::Value *EmitARCAutorelease(llvm::Value *value);
llvm::Value *EmitARCAutoreleaseReturnValue(llvm::Value *value);
llvm::Value *EmitARCRetainAutoreleaseReturnValue(llvm::Value *value);
llvm::Value *EmitARCRetainAutoreleasedReturnValue(llvm::Value *value);
std::pair<LValue,llvm::Value*>
EmitARCStoreAutoreleasing(const BinaryOperator *e);
std::pair<LValue,llvm::Value*>
EmitARCStoreStrong(const BinaryOperator *e, bool ignored);
llvm::Value *EmitObjCThrowOperand(const Expr *expr);
llvm::Value *EmitObjCProduceObject(QualType T, llvm::Value *Ptr);
llvm::Value *EmitObjCConsumeObject(QualType T, llvm::Value *Ptr);
llvm::Value *EmitObjCExtendObjectLifetime(QualType T, llvm::Value *Ptr);
llvm::Value *EmitARCExtendBlockObject(const Expr *expr);
llvm::Value *EmitARCRetainScalarExpr(const Expr *expr);
llvm::Value *EmitARCRetainAutoreleaseScalarExpr(const Expr *expr);
static Destroyer destroyARCStrongImprecise;
static Destroyer destroyARCStrongPrecise;
static Destroyer destroyARCWeak;
void EmitObjCAutoreleasePoolPop(llvm::Value *Ptr);
llvm::Value *EmitObjCAutoreleasePoolPush();
llvm::Value *EmitObjCMRRAutoreleasePoolPush();
void EmitObjCAutoreleasePoolCleanup(llvm::Value *Ptr);
void EmitObjCMRRAutoreleasePoolPop(llvm::Value *Ptr);
/// EmitReferenceBindingToExpr - Emits a reference binding to the passed in
/// expression. Will emit a temporary variable if E is not an LValue.
RValue EmitReferenceBindingToExpr(const Expr* E,
const NamedDecl *InitializedDecl);
//===--------------------------------------------------------------------===//
// Expression Emission
//===--------------------------------------------------------------------===//
// Expressions are broken into three classes: scalar, complex, aggregate.
/// EmitScalarExpr - Emit the computation of the specified expression of LLVM
/// scalar type, returning the result.
llvm::Value *EmitScalarExpr(const Expr *E , bool IgnoreResultAssign = false);
/// EmitScalarConversion - Emit a conversion from the specified type to the
/// specified destination type, both of which are LLVM scalar types.
llvm::Value *EmitScalarConversion(llvm::Value *Src, QualType SrcTy,
QualType DstTy);
/// EmitComplexToScalarConversion - Emit a conversion from the specified
/// complex type to the specified destination type, where the destination type
/// is an LLVM scalar type.
llvm::Value *EmitComplexToScalarConversion(ComplexPairTy Src, QualType SrcTy,
QualType DstTy);
/// EmitAggExpr - Emit the computation of the specified expression
/// of aggregate type. The result is computed into the given slot,
/// which may be null to indicate that the value is not needed.
void EmitAggExpr(const Expr *E, AggValueSlot AS, bool IgnoreResult = false);
/// EmitAggExprToLValue - Emit the computation of the specified expression of
/// aggregate type into a temporary LValue.
LValue EmitAggExprToLValue(const Expr *E);
/// EmitGCMemmoveCollectable - Emit special API for structs with object
/// pointers.
void EmitGCMemmoveCollectable(llvm::Value *DestPtr, llvm::Value *SrcPtr,
QualType Ty);
/// EmitExtendGCLifetime - Given a pointer to an Objective-C object,
/// make sure it survives garbage collection until this point.
void EmitExtendGCLifetime(llvm::Value *object);
/// EmitComplexExpr - Emit the computation of the specified expression of
/// complex type, returning the result.
ComplexPairTy EmitComplexExpr(const Expr *E,
bool IgnoreReal = false,
bool IgnoreImag = false);
/// EmitComplexExprIntoAddr - Emit the computation of the specified expression
/// of complex type, storing into the specified Value*.
void EmitComplexExprIntoAddr(const Expr *E, llvm::Value *DestAddr,
bool DestIsVolatile);
/// StoreComplexToAddr - Store a complex number into the specified address.
void StoreComplexToAddr(ComplexPairTy V, llvm::Value *DestAddr,
bool DestIsVolatile);
/// LoadComplexFromAddr - Load a complex number from the specified address.
ComplexPairTy LoadComplexFromAddr(llvm::Value *SrcAddr, bool SrcIsVolatile);
/// CreateStaticVarDecl - Create a zero-initialized LLVM global for
/// a static local variable.
llvm::GlobalVariable *CreateStaticVarDecl(const VarDecl &D,
const char *Separator,
llvm::GlobalValue::LinkageTypes Linkage);
/// AddInitializerToStaticVarDecl - Add the initializer for 'D' to the
/// global variable that has already been created for it. If the initializer
/// has a different type than GV does, this may free GV and return a different
/// one. Otherwise it just returns GV.
llvm::GlobalVariable *
AddInitializerToStaticVarDecl(const VarDecl &D,
llvm::GlobalVariable *GV);
/// EmitCXXGlobalVarDeclInit - Create the initializer for a C++
/// variable with global storage.
void EmitCXXGlobalVarDeclInit(const VarDecl &D, llvm::Constant *DeclPtr,
bool PerformInit);
/// EmitCXXGlobalDtorRegistration - Emits a call to register the global ptr
/// with the C++ runtime so that its destructor will be called at exit.
void EmitCXXGlobalDtorRegistration(llvm::Constant *DtorFn,
llvm::Constant *DeclPtr);
/// Emit code in this function to perform a guarded variable
/// initialization. Guarded initializations are used when it's not
/// possible to prove that an initialization will be done exactly
/// once, e.g. with a static local variable or a static data member
/// of a class template.
void EmitCXXGuardedInit(const VarDecl &D, llvm::GlobalVariable *DeclPtr,
bool PerformInit);
/// GenerateCXXGlobalInitFunc - Generates code for initializing global
/// variables.
void GenerateCXXGlobalInitFunc(llvm::Function *Fn,
llvm::Constant **Decls,
unsigned NumDecls);
/// GenerateCXXGlobalDtorFunc - Generates code for destroying global
/// variables.
void GenerateCXXGlobalDtorFunc(llvm::Function *Fn,
const std::vector<std::pair<llvm::WeakVH,
llvm::Constant*> > &DtorsAndObjects);
void GenerateCXXGlobalVarDeclInitFunc(llvm::Function *Fn,
const VarDecl *D,
llvm::GlobalVariable *Addr,
bool PerformInit);
void EmitCXXConstructExpr(const CXXConstructExpr *E, AggValueSlot Dest);
void EmitSynthesizedCXXCopyCtor(llvm::Value *Dest, llvm::Value *Src,
const Expr *Exp);
void enterFullExpression(const ExprWithCleanups *E) {
if (E->getNumObjects() == 0) return;
enterNonTrivialFullExpression(E);
}
void enterNonTrivialFullExpression(const ExprWithCleanups *E);
void EmitCXXThrowExpr(const CXXThrowExpr *E);
void EmitLambdaExpr(const LambdaExpr *E, AggValueSlot Dest);
RValue EmitAtomicExpr(AtomicExpr *E, llvm::Value *Dest = 0);
//===--------------------------------------------------------------------===//
// Annotations Emission
//===--------------------------------------------------------------------===//
/// Emit an annotation call (intrinsic or builtin).
llvm::Value *EmitAnnotationCall(llvm::Value *AnnotationFn,
llvm::Value *AnnotatedVal,
llvm::StringRef AnnotationStr,
SourceLocation Location);
/// Emit local annotations for the local variable V, declared by D.
void EmitVarAnnotations(const VarDecl *D, llvm::Value *V);
/// Emit field annotations for the given field & value. Returns the
/// annotation result.
llvm::Value *EmitFieldAnnotations(const FieldDecl *D, llvm::Value *V);
//===--------------------------------------------------------------------===//
// Internal Helpers
//===--------------------------------------------------------------------===//
/// ContainsLabel - Return true if the statement contains a label in it. If
/// this statement is not executed normally, it not containing a label means
/// that we can just remove the code.
static bool ContainsLabel(const Stmt *S, bool IgnoreCaseStmts = false);
/// containsBreak - Return true if the statement contains a break out of it.
/// If the statement (recursively) contains a switch or loop with a break
/// inside of it, this is fine.
static bool containsBreak(const Stmt *S);
/// ConstantFoldsToSimpleInteger - If the specified expression does not fold
/// to a constant, or if it does but contains a label, return false. If it
/// constant folds return true and set the boolean result in Result.
bool ConstantFoldsToSimpleInteger(const Expr *Cond, bool &Result);
/// ConstantFoldsToSimpleInteger - If the specified expression does not fold
/// to a constant, or if it does but contains a label, return false. If it
/// constant folds return true and set the folded value.
bool ConstantFoldsToSimpleInteger(const Expr *Cond, llvm::APInt &Result);
/// EmitBranchOnBoolExpr - Emit a branch on a boolean condition (e.g. for an
/// if statement) to the specified blocks. Based on the condition, this might
/// try to simplify the codegen of the conditional based on the branch.
void EmitBranchOnBoolExpr(const Expr *Cond, llvm::BasicBlock *TrueBlock,
llvm::BasicBlock *FalseBlock);
/// getTrapBB - Create a basic block that will call the trap intrinsic. We'll
/// generate a branch around the created basic block as necessary.
llvm::BasicBlock *getTrapBB();
/// EmitCallArg - Emit a single call argument.
void EmitCallArg(CallArgList &args, const Expr *E, QualType ArgType);
/// EmitDelegateCallArg - We are performing a delegate call; that
/// is, the current function is delegating to another one. Produce
/// a r-value suitable for passing the given parameter.
void EmitDelegateCallArg(CallArgList &args, const VarDecl *param);
/// SetFPAccuracy - Set the minimum required accuracy of the given floating
/// point operation, expressed as the maximum relative error in ulp.
void SetFPAccuracy(llvm::Value *Val, unsigned AccuracyN,
unsigned AccuracyD = 1);
private:
void EmitReturnOfRValue(RValue RV, QualType Ty);
/// ExpandTypeFromArgs - Reconstruct a structure of type \arg Ty
/// from function arguments into \arg Dst. See ABIArgInfo::Expand.
///
/// \param AI - The first function argument of the expansion.
/// \return The argument following the last expanded function
/// argument.
llvm::Function::arg_iterator
ExpandTypeFromArgs(QualType Ty, LValue Dst,
llvm::Function::arg_iterator AI);
/// ExpandTypeToArgs - Expand an RValue \arg Src, with the LLVM type for \arg
/// Ty, into individual arguments on the provided vector \arg Args. See
/// ABIArgInfo::Expand.
void ExpandTypeToArgs(QualType Ty, RValue Src,
SmallVector<llvm::Value*, 16> &Args,
llvm::FunctionType *IRFuncTy);
llvm::Value* EmitAsmInput(const AsmStmt &S,
const TargetInfo::ConstraintInfo &Info,
const Expr *InputExpr, std::string &ConstraintStr);
llvm::Value* EmitAsmInputLValue(const AsmStmt &S,
const TargetInfo::ConstraintInfo &Info,
LValue InputValue, QualType InputType,
std::string &ConstraintStr);
/// EmitCallArgs - Emit call arguments for a function.
/// The CallArgTypeInfo parameter is used for iterating over the known
/// argument types of the function being called.
template<typename T>
void EmitCallArgs(CallArgList& Args, const T* CallArgTypeInfo,
CallExpr::const_arg_iterator ArgBeg,
CallExpr::const_arg_iterator ArgEnd) {
CallExpr::const_arg_iterator Arg = ArgBeg;
// First, use the argument types that the type info knows about
if (CallArgTypeInfo) {
for (typename T::arg_type_iterator I = CallArgTypeInfo->arg_type_begin(),
E = CallArgTypeInfo->arg_type_end(); I != E; ++I, ++Arg) {
assert(Arg != ArgEnd && "Running over edge of argument list!");
QualType ArgType = *I;
#ifndef NDEBUG
QualType ActualArgType = Arg->getType();
if (ArgType->isPointerType() && ActualArgType->isPointerType()) {
QualType ActualBaseType =
ActualArgType->getAs<PointerType>()->getPointeeType();
QualType ArgBaseType =
ArgType->getAs<PointerType>()->getPointeeType();
if (ArgBaseType->isVariableArrayType()) {
if (const VariableArrayType *VAT =
getContext().getAsVariableArrayType(ActualBaseType)) {
if (!VAT->getSizeExpr())
ActualArgType = ArgType;
}
}
}
assert(getContext().getCanonicalType(ArgType.getNonReferenceType()).
getTypePtr() ==
getContext().getCanonicalType(ActualArgType).getTypePtr() &&
"type mismatch in call argument!");
#endif
EmitCallArg(Args, *Arg, ArgType);
}
// Either we've emitted all the call args, or we have a call to a
// variadic function.
assert((Arg == ArgEnd || CallArgTypeInfo->isVariadic()) &&
"Extra arguments in non-variadic function!");
}
// If we still have any arguments, emit them using the type of the argument.
for (; Arg != ArgEnd; ++Arg)
EmitCallArg(Args, *Arg, Arg->getType());
}
const TargetCodeGenInfo &getTargetHooks() const {
return CGM.getTargetCodeGenInfo();
}
void EmitDeclMetadata();
CodeGenModule::ByrefHelpers *
buildByrefHelpers(llvm::StructType &byrefType,
const AutoVarEmission &emission);
void AddObjCARCExceptionMetadata(llvm::Instruction *Inst);
};
/// Helper class with most of the code for saving a value for a
/// conditional expression cleanup.
struct DominatingLLVMValue {
typedef llvm::PointerIntPair<llvm::Value*, 1, bool> saved_type;
/// Answer whether the given value needs extra work to be saved.
static bool needsSaving(llvm::Value *value) {
// If it's not an instruction, we don't need to save.
if (!isa<llvm::Instruction>(value)) return false;
// If it's an instruction in the entry block, we don't need to save.
llvm::BasicBlock *block = cast<llvm::Instruction>(value)->getParent();
return (block != &block->getParent()->getEntryBlock());
}
/// Try to save the given value.
static saved_type save(CodeGenFunction &CGF, llvm::Value *value) {
if (!needsSaving(value)) return saved_type(value, false);
// Otherwise we need an alloca.
llvm::Value *alloca =
CGF.CreateTempAlloca(value->getType(), "cond-cleanup.save");
CGF.Builder.CreateStore(value, alloca);
return saved_type(alloca, true);
}
static llvm::Value *restore(CodeGenFunction &CGF, saved_type value) {
if (!value.getInt()) return value.getPointer();
return CGF.Builder.CreateLoad(value.getPointer());
}
};
/// A partial specialization of DominatingValue for llvm::Values that
/// might be llvm::Instructions.
template <class T> struct DominatingPointer<T,true> : DominatingLLVMValue {
typedef T *type;
static type restore(CodeGenFunction &CGF, saved_type value) {
return static_cast<T*>(DominatingLLVMValue::restore(CGF, value));
}
};
/// A specialization of DominatingValue for RValue.
template <> struct DominatingValue<RValue> {
typedef RValue type;
class saved_type {
enum Kind { ScalarLiteral, ScalarAddress, AggregateLiteral,
AggregateAddress, ComplexAddress };
llvm::Value *Value;
Kind K;
saved_type(llvm::Value *v, Kind k) : Value(v), K(k) {}
public:
static bool needsSaving(RValue value);
static saved_type save(CodeGenFunction &CGF, RValue value);
RValue restore(CodeGenFunction &CGF);
// implementations in CGExprCXX.cpp
};
static bool needsSaving(type value) {
return saved_type::needsSaving(value);
}
static saved_type save(CodeGenFunction &CGF, type value) {
return saved_type::save(CGF, value);
}
static type restore(CodeGenFunction &CGF, saved_type value) {
return value.restore(CGF);
}
};
} // end namespace CodeGen
} // end namespace clang
#endif