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llvm-mirror/tools/llvm-c-test/echo.cpp

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//===-- echo.cpp - tool for testing libLLVM and llvm-c API ----------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements the --echo command in llvm-c-test.
//
// This command uses the C API to read a module and output an exact copy of it
// as output. It is used to check that the resulting module matches the input
// to validate that the C API can read and write modules properly.
//
//===----------------------------------------------------------------------===//
#include "llvm-c-test.h"
#include "llvm-c/Target.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/Support/ErrorHandling.h"
#include <stdio.h>
#include <stdlib.h>
using namespace llvm;
// Provide DenseMapInfo for C API opaque types.
template<typename T>
struct CAPIDenseMap {};
// The default DenseMapInfo require to know about pointer alignement.
// Because the C API uses opaques pointer types, their alignement is unknown.
// As a result, we need to roll out our own implementation.
template<typename T>
struct CAPIDenseMap<T*> {
struct CAPIDenseMapInfo {
static inline T* getEmptyKey() {
uintptr_t Val = static_cast<uintptr_t>(-1);
return reinterpret_cast<T*>(Val);
}
static inline T* getTombstoneKey() {
uintptr_t Val = static_cast<uintptr_t>(-2);
return reinterpret_cast<T*>(Val);
}
static unsigned getHashValue(const T *PtrVal) {
return hash_value(PtrVal);
}
static bool isEqual(const T *LHS, const T *RHS) { return LHS == RHS; }
};
typedef DenseMap<T*, T*, CAPIDenseMapInfo> Map;
};
typedef CAPIDenseMap<LLVMValueRef>::Map ValueMap;
typedef CAPIDenseMap<LLVMBasicBlockRef>::Map BasicBlockMap;
struct TypeCloner {
LLVMModuleRef M;
LLVMContextRef Ctx;
TypeCloner(LLVMModuleRef M): M(M), Ctx(LLVMGetModuleContext(M)) {}
LLVMTypeRef Clone(LLVMValueRef Src) {
return Clone(LLVMTypeOf(Src));
}
LLVMTypeRef Clone(LLVMTypeRef Src) {
LLVMTypeKind Kind = LLVMGetTypeKind(Src);
switch (Kind) {
case LLVMVoidTypeKind:
return LLVMVoidTypeInContext(Ctx);
case LLVMHalfTypeKind:
return LLVMHalfTypeInContext(Ctx);
case LLVMFloatTypeKind:
return LLVMFloatTypeInContext(Ctx);
case LLVMDoubleTypeKind:
return LLVMDoubleTypeInContext(Ctx);
case LLVMX86_FP80TypeKind:
return LLVMX86FP80TypeInContext(Ctx);
case LLVMFP128TypeKind:
return LLVMFP128TypeInContext(Ctx);
case LLVMPPC_FP128TypeKind:
return LLVMPPCFP128TypeInContext(Ctx);
case LLVMLabelTypeKind:
return LLVMLabelTypeInContext(Ctx);
case LLVMIntegerTypeKind:
return LLVMIntTypeInContext(Ctx, LLVMGetIntTypeWidth(Src));
case LLVMFunctionTypeKind: {
unsigned ParamCount = LLVMCountParamTypes(Src);
LLVMTypeRef* Params = nullptr;
if (ParamCount > 0) {
Report fatal error in the case of out of memory This is the second part of recommit of r325224. The previous part was committed in r325426, which deals with C++ memory allocation. Solution for C memory allocation involved functions `llvm::malloc` and similar. This was a fragile solution because it caused ambiguity errors in some cases. In this commit the new functions have names like `llvm::safe_malloc`. The relevant part of original comment is below, updated for new function names. Analysis of fails in the case of out of memory errors can be tricky on Windows. Such error emerges at the point where memory allocation function fails, but manifests itself when null pointer is used. These two points may be distant from each other. Besides, next runs may not exhibit allocation error. In some cases memory is allocated by a call to some of C allocation functions, malloc, calloc and realloc. They are used for interoperability with C code, when allocated object has variable size and when it is necessary to avoid call of constructors. In many calls the result is not checked for null pointer. To simplify checks, new functions are defined in the namespace 'llvm': `safe_malloc`, `safe_calloc` and `safe_realloc`. They behave as corresponding standard functions but produce fatal error if allocation fails. This change replaces the standard functions like 'malloc' in the cases when the result of the allocation function is not checked for null pointer. Finally, there are plain C code, that uses malloc and similar functions. If the result is not checked, assert statement is added. Differential Revision: https://reviews.llvm.org/D43010 llvm-svn: 325551
2018-02-20 06:41:26 +01:00
Params = static_cast<LLVMTypeRef*>(
safe_malloc(ParamCount * sizeof(LLVMTypeRef)));
LLVMGetParamTypes(Src, Params);
for (unsigned i = 0; i < ParamCount; i++)
Params[i] = Clone(Params[i]);
}
LLVMTypeRef FunTy = LLVMFunctionType(Clone(LLVMGetReturnType(Src)),
Params, ParamCount,
LLVMIsFunctionVarArg(Src));
if (ParamCount > 0)
free(Params);
return FunTy;
}
case LLVMStructTypeKind: {
LLVMTypeRef S = nullptr;
const char *Name = LLVMGetStructName(Src);
if (Name) {
S = LLVMGetTypeByName(M, Name);
if (S)
return S;
S = LLVMStructCreateNamed(Ctx, Name);
if (LLVMIsOpaqueStruct(Src))
return S;
}
unsigned EltCount = LLVMCountStructElementTypes(Src);
SmallVector<LLVMTypeRef, 8> Elts;
for (unsigned i = 0; i < EltCount; i++)
Elts.push_back(Clone(LLVMStructGetTypeAtIndex(Src, i)));
if (Name)
LLVMStructSetBody(S, Elts.data(), EltCount, LLVMIsPackedStruct(Src));
else
S = LLVMStructTypeInContext(Ctx, Elts.data(), EltCount,
LLVMIsPackedStruct(Src));
return S;
}
case LLVMArrayTypeKind:
return LLVMArrayType(
Clone(LLVMGetElementType(Src)),
LLVMGetArrayLength(Src)
);
case LLVMPointerTypeKind:
return LLVMPointerType(
Clone(LLVMGetElementType(Src)),
LLVMGetPointerAddressSpace(Src)
);
case LLVMVectorTypeKind:
return LLVMVectorType(
Clone(LLVMGetElementType(Src)),
LLVMGetVectorSize(Src)
);
case LLVMMetadataTypeKind:
return LLVMMetadataTypeInContext(Ctx);
case LLVMX86_MMXTypeKind:
return LLVMX86MMXTypeInContext(Ctx);
case LLVMTokenTypeKind:
return LLVMTokenTypeInContext(Ctx);
}
fprintf(stderr, "%d is not a supported typekind\n", Kind);
exit(-1);
}
};
static ValueMap clone_params(LLVMValueRef Src, LLVMValueRef Dst) {
unsigned Count = LLVMCountParams(Src);
if (Count != LLVMCountParams(Dst))
report_fatal_error("Parameter count mismatch");
ValueMap VMap;
if (Count == 0)
return VMap;
LLVMValueRef SrcFirst = LLVMGetFirstParam(Src);
LLVMValueRef DstFirst = LLVMGetFirstParam(Dst);
LLVMValueRef SrcLast = LLVMGetLastParam(Src);
LLVMValueRef DstLast = LLVMGetLastParam(Dst);
LLVMValueRef SrcCur = SrcFirst;
LLVMValueRef DstCur = DstFirst;
LLVMValueRef SrcNext = nullptr;
LLVMValueRef DstNext = nullptr;
while (true) {
size_t NameLen;
const char *Name = LLVMGetValueName2(SrcCur, &NameLen);
LLVMSetValueName2(DstCur, Name, NameLen);
VMap[SrcCur] = DstCur;
Count--;
SrcNext = LLVMGetNextParam(SrcCur);
DstNext = LLVMGetNextParam(DstCur);
if (SrcNext == nullptr && DstNext == nullptr) {
if (SrcCur != SrcLast)
report_fatal_error("SrcLast param does not match End");
if (DstCur != DstLast)
report_fatal_error("DstLast param does not match End");
break;
}
if (SrcNext == nullptr)
report_fatal_error("SrcNext was unexpectedly null");
if (DstNext == nullptr)
report_fatal_error("DstNext was unexpectedly null");
LLVMValueRef SrcPrev = LLVMGetPreviousParam(SrcNext);
if (SrcPrev != SrcCur)
report_fatal_error("SrcNext.Previous param is not Current");
LLVMValueRef DstPrev = LLVMGetPreviousParam(DstNext);
if (DstPrev != DstCur)
report_fatal_error("DstNext.Previous param is not Current");
SrcCur = SrcNext;
DstCur = DstNext;
}
if (Count != 0)
report_fatal_error("Parameter count does not match iteration");
return VMap;
}
static void check_value_kind(LLVMValueRef V, LLVMValueKind K) {
if (LLVMGetValueKind(V) != K)
report_fatal_error("LLVMGetValueKind returned incorrect type");
}
static LLVMValueRef clone_constant_impl(LLVMValueRef Cst, LLVMModuleRef M);
static LLVMValueRef clone_constant(LLVMValueRef Cst, LLVMModuleRef M) {
LLVMValueRef Ret = clone_constant_impl(Cst, M);
check_value_kind(Ret, LLVMGetValueKind(Cst));
return Ret;
}
static LLVMValueRef clone_constant_impl(LLVMValueRef Cst, LLVMModuleRef M) {
if (!LLVMIsAConstant(Cst))
report_fatal_error("Expected a constant");
// Maybe it is a symbol
if (LLVMIsAGlobalValue(Cst)) {
size_t NameLen;
const char *Name = LLVMGetValueName2(Cst, &NameLen);
// Try function
if (LLVMIsAFunction(Cst)) {
check_value_kind(Cst, LLVMFunctionValueKind);
LLVMValueRef Dst = LLVMGetNamedFunction(M, Name);
if (Dst)
return Dst;
report_fatal_error("Could not find function");
}
// Try global variable
if (LLVMIsAGlobalVariable(Cst)) {
check_value_kind(Cst, LLVMGlobalVariableValueKind);
LLVMValueRef Dst = LLVMGetNamedGlobal(M, Name);
if (Dst)
return Dst;
report_fatal_error("Could not find function");
}
fprintf(stderr, "Could not find @%s\n", Name);
exit(-1);
}
// Try integer literal
if (LLVMIsAConstantInt(Cst)) {
check_value_kind(Cst, LLVMConstantIntValueKind);
return LLVMConstInt(TypeCloner(M).Clone(Cst),
LLVMConstIntGetZExtValue(Cst), false);
}
// Try zeroinitializer
if (LLVMIsAConstantAggregateZero(Cst)) {
check_value_kind(Cst, LLVMConstantAggregateZeroValueKind);
return LLVMConstNull(TypeCloner(M).Clone(Cst));
}
// Try constant array
if (LLVMIsAConstantArray(Cst)) {
check_value_kind(Cst, LLVMConstantArrayValueKind);
LLVMTypeRef Ty = TypeCloner(M).Clone(Cst);
unsigned EltCount = LLVMGetArrayLength(Ty);
SmallVector<LLVMValueRef, 8> Elts;
for (unsigned i = 0; i < EltCount; i++)
Elts.push_back(clone_constant(LLVMGetOperand(Cst, i), M));
return LLVMConstArray(LLVMGetElementType(Ty), Elts.data(), EltCount);
}
// Try contant data array
if (LLVMIsAConstantDataArray(Cst)) {
check_value_kind(Cst, LLVMConstantDataArrayValueKind);
LLVMTypeRef Ty = TypeCloner(M).Clone(Cst);
unsigned EltCount = LLVMGetArrayLength(Ty);
SmallVector<LLVMValueRef, 8> Elts;
for (unsigned i = 0; i < EltCount; i++)
Elts.push_back(clone_constant(LLVMGetElementAsConstant(Cst, i), M));
return LLVMConstArray(LLVMGetElementType(Ty), Elts.data(), EltCount);
}
// Try constant struct
if (LLVMIsAConstantStruct(Cst)) {
check_value_kind(Cst, LLVMConstantStructValueKind);
LLVMTypeRef Ty = TypeCloner(M).Clone(Cst);
unsigned EltCount = LLVMCountStructElementTypes(Ty);
SmallVector<LLVMValueRef, 8> Elts;
for (unsigned i = 0; i < EltCount; i++)
Elts.push_back(clone_constant(LLVMGetOperand(Cst, i), M));
if (LLVMGetStructName(Ty))
return LLVMConstNamedStruct(Ty, Elts.data(), EltCount);
return LLVMConstStructInContext(LLVMGetModuleContext(M), Elts.data(),
EltCount, LLVMIsPackedStruct(Ty));
}
// Try undef
if (LLVMIsUndef(Cst)) {
check_value_kind(Cst, LLVMUndefValueValueKind);
return LLVMGetUndef(TypeCloner(M).Clone(Cst));
}
// Try null
if (LLVMIsNull(Cst)) {
check_value_kind(Cst, LLVMConstantTokenNoneValueKind);
LLVMTypeRef Ty = TypeCloner(M).Clone(Cst);
return LLVMConstNull(Ty);
}
// Try float literal
if (LLVMIsAConstantFP(Cst)) {
check_value_kind(Cst, LLVMConstantFPValueKind);
report_fatal_error("ConstantFP is not supported");
}
// This kind of constant is not supported
if (!LLVMIsAConstantExpr(Cst))
report_fatal_error("Expected a constant expression");
// At this point, it must be a constant expression
check_value_kind(Cst, LLVMConstantExprValueKind);
LLVMOpcode Op = LLVMGetConstOpcode(Cst);
switch(Op) {
case LLVMBitCast:
return LLVMConstBitCast(clone_constant(LLVMGetOperand(Cst, 0), M),
TypeCloner(M).Clone(Cst));
default:
fprintf(stderr, "%d is not a supported opcode\n", Op);
exit(-1);
}
}
struct FunCloner {
LLVMValueRef Fun;
LLVMModuleRef M;
ValueMap VMap;
BasicBlockMap BBMap;
FunCloner(LLVMValueRef Src, LLVMValueRef Dst): Fun(Dst),
M(LLVMGetGlobalParent(Fun)), VMap(clone_params(Src, Dst)) {}
LLVMTypeRef CloneType(LLVMTypeRef Src) {
return TypeCloner(M).Clone(Src);
}
LLVMTypeRef CloneType(LLVMValueRef Src) {
return TypeCloner(M).Clone(Src);
}
// Try to clone everything in the llvm::Value hierarchy.
LLVMValueRef CloneValue(LLVMValueRef Src) {
// First, the value may be constant.
if (LLVMIsAConstant(Src))
return clone_constant(Src, M);
// Function argument should always be in the map already.
auto i = VMap.find(Src);
if (i != VMap.end())
return i->second;
if (!LLVMIsAInstruction(Src))
report_fatal_error("Expected an instruction");
auto Ctx = LLVMGetModuleContext(M);
auto Builder = LLVMCreateBuilderInContext(Ctx);
auto BB = DeclareBB(LLVMGetInstructionParent(Src));
LLVMPositionBuilderAtEnd(Builder, BB);
auto Dst = CloneInstruction(Src, Builder);
LLVMDisposeBuilder(Builder);
return Dst;
}
void CloneAttrs(LLVMValueRef Src, LLVMValueRef Dst) {
auto Ctx = LLVMGetModuleContext(M);
int ArgCount = LLVMGetNumArgOperands(Src);
for (int i = LLVMAttributeReturnIndex; i <= ArgCount; i++) {
for (unsigned k = 0, e = LLVMGetLastEnumAttributeKind(); k < e; ++k) {
if (auto SrcA = LLVMGetCallSiteEnumAttribute(Src, i, k)) {
auto Val = LLVMGetEnumAttributeValue(SrcA);
auto A = LLVMCreateEnumAttribute(Ctx, k, Val);
LLVMAddCallSiteAttribute(Dst, i, A);
}
}
}
}
LLVMValueRef CloneInstruction(LLVMValueRef Src, LLVMBuilderRef Builder) {
check_value_kind(Src, LLVMInstructionValueKind);
if (!LLVMIsAInstruction(Src))
report_fatal_error("Expected an instruction");
size_t NameLen;
const char *Name = LLVMGetValueName2(Src, &NameLen);
// Check if this is something we already computed.
{
auto i = VMap.find(Src);
if (i != VMap.end()) {
// If we have a hit, it means we already generated the instruction
// as a dependancy to somethign else. We need to make sure
// it is ordered properly.
auto I = i->second;
LLVMInstructionRemoveFromParent(I);
LLVMInsertIntoBuilderWithName(Builder, I, Name);
return I;
}
}
// We tried everything, it must be an instruction
// that hasn't been generated already.
LLVMValueRef Dst = nullptr;
LLVMOpcode Op = LLVMGetInstructionOpcode(Src);
switch(Op) {
case LLVMRet: {
int OpCount = LLVMGetNumOperands(Src);
if (OpCount == 0)
Dst = LLVMBuildRetVoid(Builder);
else
Dst = LLVMBuildRet(Builder, CloneValue(LLVMGetOperand(Src, 0)));
break;
}
case LLVMBr: {
if (!LLVMIsConditional(Src)) {
LLVMValueRef SrcOp = LLVMGetOperand(Src, 0);
LLVMBasicBlockRef SrcBB = LLVMValueAsBasicBlock(SrcOp);
Dst = LLVMBuildBr(Builder, DeclareBB(SrcBB));
break;
}
LLVMValueRef Cond = LLVMGetCondition(Src);
LLVMValueRef Else = LLVMGetOperand(Src, 1);
LLVMBasicBlockRef ElseBB = DeclareBB(LLVMValueAsBasicBlock(Else));
LLVMValueRef Then = LLVMGetOperand(Src, 2);
LLVMBasicBlockRef ThenBB = DeclareBB(LLVMValueAsBasicBlock(Then));
Dst = LLVMBuildCondBr(Builder, CloneValue(Cond), ThenBB, ElseBB);
break;
}
case LLVMSwitch:
case LLVMIndirectBr:
break;
case LLVMInvoke: {
SmallVector<LLVMValueRef, 8> Args;
int ArgCount = LLVMGetNumArgOperands(Src);
for (int i = 0; i < ArgCount; i++)
Args.push_back(CloneValue(LLVMGetOperand(Src, i)));
LLVMValueRef Fn = CloneValue(LLVMGetCalledValue(Src));
LLVMBasicBlockRef Then = DeclareBB(LLVMGetNormalDest(Src));
LLVMBasicBlockRef Unwind = DeclareBB(LLVMGetUnwindDest(Src));
Dst = LLVMBuildInvoke(Builder, Fn, Args.data(), ArgCount,
Then, Unwind, Name);
CloneAttrs(Src, Dst);
break;
}
case LLVMUnreachable:
Dst = LLVMBuildUnreachable(Builder);
break;
case LLVMAdd: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildAdd(Builder, LHS, RHS, Name);
break;
}
case LLVMSub: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildSub(Builder, LHS, RHS, Name);
break;
}
case LLVMMul: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildMul(Builder, LHS, RHS, Name);
break;
}
case LLVMUDiv: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildUDiv(Builder, LHS, RHS, Name);
break;
}
case LLVMSDiv: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildSDiv(Builder, LHS, RHS, Name);
break;
}
case LLVMURem: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildURem(Builder, LHS, RHS, Name);
break;
}
case LLVMSRem: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildSRem(Builder, LHS, RHS, Name);
break;
}
case LLVMShl: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildShl(Builder, LHS, RHS, Name);
break;
}
case LLVMLShr: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildLShr(Builder, LHS, RHS, Name);
break;
}
case LLVMAShr: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildAShr(Builder, LHS, RHS, Name);
break;
}
case LLVMAnd: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildAnd(Builder, LHS, RHS, Name);
break;
}
case LLVMOr: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildOr(Builder, LHS, RHS, Name);
break;
}
case LLVMXor: {
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildXor(Builder, LHS, RHS, Name);
break;
}
case LLVMAlloca: {
LLVMTypeRef Ty = CloneType(LLVMGetAllocatedType(Src));
Dst = LLVMBuildAlloca(Builder, Ty, Name);
break;
}
case LLVMLoad: {
LLVMValueRef Ptr = CloneValue(LLVMGetOperand(Src, 0));
Dst = LLVMBuildLoad(Builder, Ptr, Name);
LLVMSetAlignment(Dst, LLVMGetAlignment(Src));
break;
}
case LLVMStore: {
LLVMValueRef Val = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef Ptr = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildStore(Builder, Val, Ptr);
LLVMSetAlignment(Dst, LLVMGetAlignment(Src));
break;
}
case LLVMGetElementPtr: {
LLVMValueRef Ptr = CloneValue(LLVMGetOperand(Src, 0));
SmallVector<LLVMValueRef, 8> Idx;
int NumIdx = LLVMGetNumIndices(Src);
for (int i = 1; i <= NumIdx; i++)
Idx.push_back(CloneValue(LLVMGetOperand(Src, i)));
if (LLVMIsInBounds(Src))
Dst = LLVMBuildInBoundsGEP(Builder, Ptr, Idx.data(), NumIdx, Name);
else
Dst = LLVMBuildGEP(Builder, Ptr, Idx.data(), NumIdx, Name);
break;
}
case LLVMAtomicCmpXchg: {
LLVMValueRef Ptr = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef Cmp = CloneValue(LLVMGetOperand(Src, 1));
LLVMValueRef New = CloneValue(LLVMGetOperand(Src, 2));
LLVMAtomicOrdering Succ = LLVMGetCmpXchgSuccessOrdering(Src);
LLVMAtomicOrdering Fail = LLVMGetCmpXchgFailureOrdering(Src);
LLVMBool SingleThread = LLVMIsAtomicSingleThread(Src);
Dst = LLVMBuildAtomicCmpXchg(Builder, Ptr, Cmp, New, Succ, Fail,
SingleThread);
} break;
case LLVMBitCast: {
LLVMValueRef V = CloneValue(LLVMGetOperand(Src, 0));
Dst = LLVMBuildBitCast(Builder, V, CloneType(Src), Name);
break;
}
case LLVMICmp: {
LLVMIntPredicate Pred = LLVMGetICmpPredicate(Src);
LLVMValueRef LHS = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef RHS = CloneValue(LLVMGetOperand(Src, 1));
Dst = LLVMBuildICmp(Builder, Pred, LHS, RHS, Name);
break;
}
case LLVMPHI: {
// We need to aggressively set things here because of loops.
VMap[Src] = Dst = LLVMBuildPhi(Builder, CloneType(Src), Name);
SmallVector<LLVMValueRef, 8> Values;
SmallVector<LLVMBasicBlockRef, 8> Blocks;
unsigned IncomingCount = LLVMCountIncoming(Src);
for (unsigned i = 0; i < IncomingCount; ++i) {
Blocks.push_back(DeclareBB(LLVMGetIncomingBlock(Src, i)));
Values.push_back(CloneValue(LLVMGetIncomingValue(Src, i)));
}
LLVMAddIncoming(Dst, Values.data(), Blocks.data(), IncomingCount);
return Dst;
}
case LLVMCall: {
SmallVector<LLVMValueRef, 8> Args;
int ArgCount = LLVMGetNumArgOperands(Src);
for (int i = 0; i < ArgCount; i++)
Args.push_back(CloneValue(LLVMGetOperand(Src, i)));
LLVMValueRef Fn = CloneValue(LLVMGetCalledValue(Src));
Dst = LLVMBuildCall(Builder, Fn, Args.data(), ArgCount, Name);
LLVMSetTailCall(Dst, LLVMIsTailCall(Src));
CloneAttrs(Src, Dst);
break;
}
case LLVMResume: {
Dst = LLVMBuildResume(Builder, CloneValue(LLVMGetOperand(Src, 0)));
break;
}
case LLVMLandingPad: {
// The landing pad API is a bit screwed up for historical reasons.
Dst = LLVMBuildLandingPad(Builder, CloneType(Src), nullptr, 0, Name);
unsigned NumClauses = LLVMGetNumClauses(Src);
for (unsigned i = 0; i < NumClauses; ++i)
LLVMAddClause(Dst, CloneValue(LLVMGetClause(Src, i)));
LLVMSetCleanup(Dst, LLVMIsCleanup(Src));
break;
}
case LLVMCleanupRet: {
LLVMValueRef CatchPad = CloneValue(LLVMGetOperand(Src, 0));
LLVMBasicBlockRef Unwind = nullptr;
if (LLVMBasicBlockRef UDest = LLVMGetUnwindDest(Src))
Unwind = DeclareBB(UDest);
Dst = LLVMBuildCleanupRet(Builder, CatchPad, Unwind);
break;
}
case LLVMCatchRet: {
LLVMValueRef CatchPad = CloneValue(LLVMGetOperand(Src, 0));
LLVMBasicBlockRef SuccBB = DeclareBB(LLVMGetSuccessor(Src, 0));
Dst = LLVMBuildCatchRet(Builder, CatchPad, SuccBB);
break;
}
case LLVMCatchPad: {
LLVMValueRef ParentPad = CloneValue(LLVMGetParentCatchSwitch(Src));
SmallVector<LLVMValueRef, 8> Args;
int ArgCount = LLVMGetNumArgOperands(Src);
for (int i = 0; i < ArgCount; i++)
Args.push_back(CloneValue(LLVMGetOperand(Src, i)));
Dst = LLVMBuildCatchPad(Builder, ParentPad,
Args.data(), ArgCount, Name);
break;
}
case LLVMCleanupPad: {
LLVMValueRef ParentPad = CloneValue(LLVMGetOperand(Src, 0));
SmallVector<LLVMValueRef, 8> Args;
int ArgCount = LLVMGetNumArgOperands(Src);
for (int i = 0; i < ArgCount; i++)
Args.push_back(CloneValue(LLVMGetArgOperand(Src, i)));
Dst = LLVMBuildCleanupPad(Builder, ParentPad,
Args.data(), ArgCount, Name);
break;
}
case LLVMCatchSwitch: {
LLVMValueRef ParentPad = CloneValue(LLVMGetOperand(Src, 0));
LLVMBasicBlockRef UnwindBB = nullptr;
if (LLVMBasicBlockRef UDest = LLVMGetUnwindDest(Src)) {
UnwindBB = DeclareBB(UDest);
}
unsigned NumHandlers = LLVMGetNumHandlers(Src);
Dst = LLVMBuildCatchSwitch(Builder, ParentPad, UnwindBB, NumHandlers, Name);
if (NumHandlers > 0) {
LLVMBasicBlockRef *Handlers = static_cast<LLVMBasicBlockRef*>(
safe_malloc(NumHandlers * sizeof(LLVMBasicBlockRef)));
LLVMGetHandlers(Src, Handlers);
for (unsigned i = 0; i < NumHandlers; i++)
LLVMAddHandler(Dst, DeclareBB(Handlers[i]));
free(Handlers);
}
break;
}
case LLVMExtractValue: {
LLVMValueRef Agg = CloneValue(LLVMGetOperand(Src, 0));
if (LLVMGetNumIndices(Src) != 1)
report_fatal_error("Expected only one indice");
auto I = LLVMGetIndices(Src)[0];
Dst = LLVMBuildExtractValue(Builder, Agg, I, Name);
break;
}
case LLVMInsertValue: {
LLVMValueRef Agg = CloneValue(LLVMGetOperand(Src, 0));
LLVMValueRef V = CloneValue(LLVMGetOperand(Src, 1));
if (LLVMGetNumIndices(Src) != 1)
report_fatal_error("Expected only one indice");
auto I = LLVMGetIndices(Src)[0];
Dst = LLVMBuildInsertValue(Builder, Agg, V, I, Name);
break;
}
default:
break;
}
if (Dst == nullptr) {
fprintf(stderr, "%d is not a supported opcode\n", Op);
exit(-1);
}
check_value_kind(Dst, LLVMInstructionValueKind);
return VMap[Src] = Dst;
}
LLVMBasicBlockRef DeclareBB(LLVMBasicBlockRef Src) {
// Check if this is something we already computed.
{
auto i = BBMap.find(Src);
if (i != BBMap.end()) {
return i->second;
}
}
LLVMValueRef V = LLVMBasicBlockAsValue(Src);
if (!LLVMValueIsBasicBlock(V) || LLVMValueAsBasicBlock(V) != Src)
report_fatal_error("Basic block is not a basic block");
const char *Name = LLVMGetBasicBlockName(Src);
size_t NameLen;
const char *VName = LLVMGetValueName2(V, &NameLen);
if (Name != VName)
report_fatal_error("Basic block name mismatch");
LLVMBasicBlockRef BB = LLVMAppendBasicBlock(Fun, Name);
return BBMap[Src] = BB;
}
LLVMBasicBlockRef CloneBB(LLVMBasicBlockRef Src) {
LLVMBasicBlockRef BB = DeclareBB(Src);
// Make sure ordering is correct.
LLVMBasicBlockRef Prev = LLVMGetPreviousBasicBlock(Src);
if (Prev)
LLVMMoveBasicBlockAfter(BB, DeclareBB(Prev));
LLVMValueRef First = LLVMGetFirstInstruction(Src);
LLVMValueRef Last = LLVMGetLastInstruction(Src);
if (First == nullptr) {
if (Last != nullptr)
report_fatal_error("Has no first instruction, but last one");
return BB;
}
auto Ctx = LLVMGetModuleContext(M);
LLVMBuilderRef Builder = LLVMCreateBuilderInContext(Ctx);
LLVMPositionBuilderAtEnd(Builder, BB);
LLVMValueRef Cur = First;
LLVMValueRef Next = nullptr;
while(true) {
CloneInstruction(Cur, Builder);
Next = LLVMGetNextInstruction(Cur);
if (Next == nullptr) {
if (Cur != Last)
report_fatal_error("Final instruction does not match Last");
break;
}
LLVMValueRef Prev = LLVMGetPreviousInstruction(Next);
if (Prev != Cur)
report_fatal_error("Next.Previous instruction is not Current");
Cur = Next;
}
LLVMDisposeBuilder(Builder);
return BB;
}
void CloneBBs(LLVMValueRef Src) {
unsigned Count = LLVMCountBasicBlocks(Src);
if (Count == 0)
return;
LLVMBasicBlockRef First = LLVMGetFirstBasicBlock(Src);
LLVMBasicBlockRef Last = LLVMGetLastBasicBlock(Src);
LLVMBasicBlockRef Cur = First;
LLVMBasicBlockRef Next = nullptr;
while(true) {
CloneBB(Cur);
Count--;
Next = LLVMGetNextBasicBlock(Cur);
if (Next == nullptr) {
if (Cur != Last)
report_fatal_error("Final basic block does not match Last");
break;
}
LLVMBasicBlockRef Prev = LLVMGetPreviousBasicBlock(Next);
if (Prev != Cur)
report_fatal_error("Next.Previous basic bloc is not Current");
Cur = Next;
}
if (Count != 0)
report_fatal_error("Basic block count does not match iterration");
}
};
static void declare_symbols(LLVMModuleRef Src, LLVMModuleRef M) {
LLVMValueRef Begin = LLVMGetFirstGlobal(Src);
LLVMValueRef End = LLVMGetLastGlobal(Src);
LLVMValueRef Cur = Begin;
LLVMValueRef Next = nullptr;
if (!Begin) {
if (End != nullptr)
report_fatal_error("Range has an end but no beginning");
goto FunDecl;
}
while (true) {
size_t NameLen;
const char *Name = LLVMGetValueName2(Cur, &NameLen);
if (LLVMGetNamedGlobal(M, Name))
report_fatal_error("GlobalVariable already cloned");
LLVMAddGlobal(M, LLVMGetElementType(TypeCloner(M).Clone(Cur)), Name);
Next = LLVMGetNextGlobal(Cur);
if (Next == nullptr) {
if (Cur != End)
report_fatal_error("");
break;
}
LLVMValueRef Prev = LLVMGetPreviousGlobal(Next);
if (Prev != Cur)
report_fatal_error("Next.Previous global is not Current");
Cur = Next;
}
FunDecl:
Begin = LLVMGetFirstFunction(Src);
End = LLVMGetLastFunction(Src);
if (!Begin) {
if (End != nullptr)
report_fatal_error("Range has an end but no beginning");
return;
}
auto Ctx = LLVMGetModuleContext(M);
Cur = Begin;
Next = nullptr;
while (true) {
size_t NameLen;
const char *Name = LLVMGetValueName2(Cur, &NameLen);
if (LLVMGetNamedFunction(M, Name))
report_fatal_error("Function already cloned");
auto Ty = LLVMGetElementType(TypeCloner(M).Clone(Cur));
auto F = LLVMAddFunction(M, Name, Ty);
// Copy attributes
for (int i = LLVMAttributeFunctionIndex, c = LLVMCountParams(F);
i <= c; ++i) {
for (unsigned k = 0, e = LLVMGetLastEnumAttributeKind(); k < e; ++k) {
if (auto SrcA = LLVMGetEnumAttributeAtIndex(Cur, i, k)) {
auto Val = LLVMGetEnumAttributeValue(SrcA);
auto DstA = LLVMCreateEnumAttribute(Ctx, k, Val);
LLVMAddAttributeAtIndex(F, i, DstA);
}
}
}
Next = LLVMGetNextFunction(Cur);
if (Next == nullptr) {
if (Cur != End)
report_fatal_error("Last function does not match End");
break;
}
LLVMValueRef Prev = LLVMGetPreviousFunction(Next);
if (Prev != Cur)
report_fatal_error("Next.Previous function is not Current");
Cur = Next;
}
}
static void clone_symbols(LLVMModuleRef Src, LLVMModuleRef M) {
LLVMValueRef Begin = LLVMGetFirstGlobal(Src);
LLVMValueRef End = LLVMGetLastGlobal(Src);
LLVMValueRef Cur = Begin;
LLVMValueRef Next = nullptr;
if (!Begin) {
if (End != nullptr)
report_fatal_error("Range has an end but no beginning");
goto FunClone;
}
while (true) {
size_t NameLen;
const char *Name = LLVMGetValueName2(Cur, &NameLen);
LLVMValueRef G = LLVMGetNamedGlobal(M, Name);
if (!G)
report_fatal_error("GlobalVariable must have been declared already");
if (auto I = LLVMGetInitializer(Cur))
LLVMSetInitializer(G, clone_constant(I, M));
LLVMSetGlobalConstant(G, LLVMIsGlobalConstant(Cur));
LLVMSetThreadLocal(G, LLVMIsThreadLocal(Cur));
LLVMSetExternallyInitialized(G, LLVMIsExternallyInitialized(Cur));
LLVMSetLinkage(G, LLVMGetLinkage(Cur));
LLVMSetSection(G, LLVMGetSection(Cur));
LLVMSetVisibility(G, LLVMGetVisibility(Cur));
LLVMSetUnnamedAddress(G, LLVMGetUnnamedAddress(Cur));
LLVMSetAlignment(G, LLVMGetAlignment(Cur));
Next = LLVMGetNextGlobal(Cur);
if (Next == nullptr) {
if (Cur != End)
report_fatal_error("");
break;
}
LLVMValueRef Prev = LLVMGetPreviousGlobal(Next);
if (Prev != Cur)
report_fatal_error("Next.Previous global is not Current");
Cur = Next;
}
FunClone:
Begin = LLVMGetFirstFunction(Src);
End = LLVMGetLastFunction(Src);
if (!Begin) {
if (End != nullptr)
report_fatal_error("Range has an end but no beginning");
return;
}
Cur = Begin;
Next = nullptr;
while (true) {
size_t NameLen;
const char *Name = LLVMGetValueName2(Cur, &NameLen);
LLVMValueRef Fun = LLVMGetNamedFunction(M, Name);
if (!Fun)
report_fatal_error("Function must have been declared already");
if (LLVMHasPersonalityFn(Cur)) {
size_t FNameLen;
const char *FName = LLVMGetValueName2(LLVMGetPersonalityFn(Cur),
&FNameLen);
LLVMValueRef P = LLVMGetNamedFunction(M, FName);
if (!P)
report_fatal_error("Could not find personality function");
LLVMSetPersonalityFn(Fun, P);
}
FunCloner FC(Cur, Fun);
FC.CloneBBs(Cur);
Next = LLVMGetNextFunction(Cur);
if (Next == nullptr) {
if (Cur != End)
report_fatal_error("Last function does not match End");
break;
}
LLVMValueRef Prev = LLVMGetPreviousFunction(Next);
if (Prev != Cur)
report_fatal_error("Next.Previous function is not Current");
Cur = Next;
}
}
int llvm_echo(void) {
LLVMEnablePrettyStackTrace();
LLVMModuleRef Src = llvm_load_module(false, true);
size_t SourceFileLen;
const char *SourceFileName = LLVMGetSourceFileName(Src, &SourceFileLen);
size_t ModuleIdentLen;
const char *ModuleName = LLVMGetModuleIdentifier(Src, &ModuleIdentLen);
LLVMContextRef Ctx = LLVMContextCreate();
LLVMModuleRef M = LLVMModuleCreateWithNameInContext(ModuleName, Ctx);
LLVMSetSourceFileName(M, SourceFileName, SourceFileLen);
LLVMSetModuleIdentifier(M, ModuleName, ModuleIdentLen);
size_t SourceFlagsLen;
LLVMModuleFlagEntry *ModuleFlags =
LLVMCopyModuleFlagsMetadata(Src, &SourceFlagsLen);
for (unsigned i = 0; i < SourceFlagsLen; ++i) {
size_t EntryNameLen;
const char *EntryName =
LLVMModuleFlagEntriesGetKey(ModuleFlags, i, &EntryNameLen);
LLVMAddModuleFlag(M, LLVMModuleFlagEntriesGetFlagBehavior(ModuleFlags, i),
EntryName, EntryNameLen,
LLVMModuleFlagEntriesGetMetadata(ModuleFlags, i));
}
LLVMSetTarget(M, LLVMGetTarget(Src));
LLVMSetModuleDataLayout(M, LLVMGetModuleDataLayout(Src));
if (strcmp(LLVMGetDataLayoutStr(M), LLVMGetDataLayoutStr(Src)))
report_fatal_error("Inconsistent DataLayout string representation");
size_t ModuleInlineAsmLen;
const char *ModuleAsm = LLVMGetModuleInlineAsm(Src, &ModuleInlineAsmLen);
LLVMSetModuleInlineAsm2(M, ModuleAsm, ModuleInlineAsmLen);
declare_symbols(Src, M);
clone_symbols(Src, M);
char *Str = LLVMPrintModuleToString(M);
fputs(Str, stdout);
LLVMDisposeModuleFlagsMetadata(ModuleFlags);
LLVMDisposeMessage(Str);
LLVMDisposeModule(Src);
LLVMDisposeModule(M);
LLVMContextDispose(Ctx);
return 0;
}