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0e1327e4aa
CodeModel: It's now possible to create an MCJIT instance with any CodeModel you like. Previously it was only possible to create an MCJIT that used CodeModel::JITDefault. EnableFastISel: It's now possible to turn on the fast instruction selector. The CodeModel option required some trickery. The problem is that previously, we were ensuring future binary compatibility in the MCJITCompilerOptions by mandating that the user bzero's the options struct and passes the sizeof() that he saw; the bindings then bzero the remaining bits. This works great but assumes that the bitwise zero equivalent of any field is a sensible default value. But this is not the case for LLVMCodeModel, or its internal equivalent, llvm::CodeModel::Model. In both of those, the default for a JIT is CodeModel::JITDefault (or LLVMCodeModelJITDefault), which is not bitwise zero. Hence this change introduces LLVMInitializeMCJITCompilerOptions(), which will initialize the user's options struct with defaults. The user will use this in the same way that they would have previously used memset() or bzero(). MCJITCAPITest.cpp illustrates the change, as does the comment in ExecutionEngine.h. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@180893 91177308-0d34-0410-b5e6-96231b3b80d8
335 lines
11 KiB
C++
335 lines
11 KiB
C++
//===-- ExecutionEngineBindings.cpp - C bindings for EEs ------------------===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines the C bindings for the ExecutionEngine library.
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//
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//===----------------------------------------------------------------------===//
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#define DEBUG_TYPE "jit"
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#include "llvm-c/ExecutionEngine.h"
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#include "llvm/ExecutionEngine/ExecutionEngine.h"
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#include "llvm/ExecutionEngine/GenericValue.h"
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#include "llvm/IR/DerivedTypes.h"
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#include "llvm/IR/Module.h"
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#include "llvm/Support/ErrorHandling.h"
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#include <cstring>
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using namespace llvm;
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// Wrapping the C bindings types.
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DEFINE_SIMPLE_CONVERSION_FUNCTIONS(GenericValue, LLVMGenericValueRef)
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inline DataLayout *unwrap(LLVMTargetDataRef P) {
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return reinterpret_cast<DataLayout*>(P);
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}
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inline LLVMTargetDataRef wrap(const DataLayout *P) {
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return reinterpret_cast<LLVMTargetDataRef>(const_cast<DataLayout*>(P));
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}
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inline TargetLibraryInfo *unwrap(LLVMTargetLibraryInfoRef P) {
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return reinterpret_cast<TargetLibraryInfo*>(P);
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}
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inline LLVMTargetLibraryInfoRef wrap(const TargetLibraryInfo *P) {
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TargetLibraryInfo *X = const_cast<TargetLibraryInfo*>(P);
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return reinterpret_cast<LLVMTargetLibraryInfoRef>(X);
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}
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/*===-- Operations on generic values --------------------------------------===*/
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LLVMGenericValueRef LLVMCreateGenericValueOfInt(LLVMTypeRef Ty,
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unsigned long long N,
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LLVMBool IsSigned) {
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GenericValue *GenVal = new GenericValue();
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GenVal->IntVal = APInt(unwrap<IntegerType>(Ty)->getBitWidth(), N, IsSigned);
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return wrap(GenVal);
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}
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LLVMGenericValueRef LLVMCreateGenericValueOfPointer(void *P) {
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GenericValue *GenVal = new GenericValue();
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GenVal->PointerVal = P;
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return wrap(GenVal);
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}
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LLVMGenericValueRef LLVMCreateGenericValueOfFloat(LLVMTypeRef TyRef, double N) {
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GenericValue *GenVal = new GenericValue();
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switch (unwrap(TyRef)->getTypeID()) {
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case Type::FloatTyID:
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GenVal->FloatVal = N;
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break;
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case Type::DoubleTyID:
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GenVal->DoubleVal = N;
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break;
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default:
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llvm_unreachable("LLVMGenericValueToFloat supports only float and double.");
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}
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return wrap(GenVal);
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}
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unsigned LLVMGenericValueIntWidth(LLVMGenericValueRef GenValRef) {
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return unwrap(GenValRef)->IntVal.getBitWidth();
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}
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unsigned long long LLVMGenericValueToInt(LLVMGenericValueRef GenValRef,
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LLVMBool IsSigned) {
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GenericValue *GenVal = unwrap(GenValRef);
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if (IsSigned)
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return GenVal->IntVal.getSExtValue();
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else
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return GenVal->IntVal.getZExtValue();
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}
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void *LLVMGenericValueToPointer(LLVMGenericValueRef GenVal) {
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return unwrap(GenVal)->PointerVal;
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}
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double LLVMGenericValueToFloat(LLVMTypeRef TyRef, LLVMGenericValueRef GenVal) {
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switch (unwrap(TyRef)->getTypeID()) {
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case Type::FloatTyID:
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return unwrap(GenVal)->FloatVal;
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case Type::DoubleTyID:
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return unwrap(GenVal)->DoubleVal;
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default:
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llvm_unreachable("LLVMGenericValueToFloat supports only float and double.");
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}
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}
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void LLVMDisposeGenericValue(LLVMGenericValueRef GenVal) {
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delete unwrap(GenVal);
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}
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/*===-- Operations on execution engines -----------------------------------===*/
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LLVMBool LLVMCreateExecutionEngineForModule(LLVMExecutionEngineRef *OutEE,
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LLVMModuleRef M,
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char **OutError) {
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std::string Error;
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EngineBuilder builder(unwrap(M));
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builder.setEngineKind(EngineKind::Either)
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.setErrorStr(&Error);
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if (ExecutionEngine *EE = builder.create()){
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*OutEE = wrap(EE);
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return 0;
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}
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*OutError = strdup(Error.c_str());
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return 1;
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}
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LLVMBool LLVMCreateInterpreterForModule(LLVMExecutionEngineRef *OutInterp,
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LLVMModuleRef M,
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char **OutError) {
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std::string Error;
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EngineBuilder builder(unwrap(M));
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builder.setEngineKind(EngineKind::Interpreter)
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.setErrorStr(&Error);
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if (ExecutionEngine *Interp = builder.create()) {
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*OutInterp = wrap(Interp);
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return 0;
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}
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*OutError = strdup(Error.c_str());
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return 1;
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}
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LLVMBool LLVMCreateJITCompilerForModule(LLVMExecutionEngineRef *OutJIT,
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LLVMModuleRef M,
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unsigned OptLevel,
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char **OutError) {
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std::string Error;
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EngineBuilder builder(unwrap(M));
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builder.setEngineKind(EngineKind::JIT)
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.setErrorStr(&Error)
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.setOptLevel((CodeGenOpt::Level)OptLevel);
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if (ExecutionEngine *JIT = builder.create()) {
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*OutJIT = wrap(JIT);
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return 0;
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}
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*OutError = strdup(Error.c_str());
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return 1;
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}
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void LLVMInitializeMCJITCompilerOptions(LLVMMCJITCompilerOptions *PassedOptions,
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size_t SizeOfPassedOptions) {
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LLVMMCJITCompilerOptions options;
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options.OptLevel = 0;
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options.CodeModel = LLVMCodeModelJITDefault;
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options.NoFramePointerElim = false;
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options.EnableFastISel = false;
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memcpy(PassedOptions, &options,
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std::min(sizeof(options), SizeOfPassedOptions));
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}
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LLVMBool LLVMCreateMCJITCompilerForModule(
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LLVMExecutionEngineRef *OutJIT, LLVMModuleRef M,
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LLVMMCJITCompilerOptions *PassedOptions, size_t SizeOfPassedOptions,
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char **OutError) {
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LLVMMCJITCompilerOptions options;
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// If the user passed a larger sized options struct, then they were compiled
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// against a newer LLVM. Tell them that something is wrong.
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if (SizeOfPassedOptions > sizeof(options)) {
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*OutError = strdup(
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"Refusing to use options struct that is larger than my own; assuming "
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"LLVM library mismatch.");
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return 1;
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}
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// Defend against the user having an old version of the API by ensuring that
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// any fields they didn't see are cleared. We must defend against fields being
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// set to the bitwise equivalent of zero, and assume that this means "do the
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// default" as if that option hadn't been available.
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LLVMInitializeMCJITCompilerOptions(&options, sizeof(options));
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memcpy(&options, PassedOptions, SizeOfPassedOptions);
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TargetOptions targetOptions;
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targetOptions.NoFramePointerElim = options.NoFramePointerElim;
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targetOptions.EnableFastISel = options.EnableFastISel;
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std::string Error;
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EngineBuilder builder(unwrap(M));
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builder.setEngineKind(EngineKind::JIT)
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.setErrorStr(&Error)
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.setUseMCJIT(true)
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.setOptLevel((CodeGenOpt::Level)options.OptLevel)
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.setCodeModel(unwrap(options.CodeModel))
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.setTargetOptions(targetOptions);
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if (ExecutionEngine *JIT = builder.create()) {
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*OutJIT = wrap(JIT);
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return 0;
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}
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*OutError = strdup(Error.c_str());
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return 1;
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}
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LLVMBool LLVMCreateExecutionEngine(LLVMExecutionEngineRef *OutEE,
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LLVMModuleProviderRef MP,
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char **OutError) {
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/* The module provider is now actually a module. */
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return LLVMCreateExecutionEngineForModule(OutEE,
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reinterpret_cast<LLVMModuleRef>(MP),
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OutError);
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}
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LLVMBool LLVMCreateInterpreter(LLVMExecutionEngineRef *OutInterp,
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LLVMModuleProviderRef MP,
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char **OutError) {
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/* The module provider is now actually a module. */
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return LLVMCreateInterpreterForModule(OutInterp,
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reinterpret_cast<LLVMModuleRef>(MP),
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OutError);
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}
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LLVMBool LLVMCreateJITCompiler(LLVMExecutionEngineRef *OutJIT,
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LLVMModuleProviderRef MP,
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unsigned OptLevel,
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char **OutError) {
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/* The module provider is now actually a module. */
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return LLVMCreateJITCompilerForModule(OutJIT,
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reinterpret_cast<LLVMModuleRef>(MP),
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OptLevel, OutError);
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}
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void LLVMDisposeExecutionEngine(LLVMExecutionEngineRef EE) {
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delete unwrap(EE);
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}
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void LLVMRunStaticConstructors(LLVMExecutionEngineRef EE) {
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unwrap(EE)->runStaticConstructorsDestructors(false);
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}
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void LLVMRunStaticDestructors(LLVMExecutionEngineRef EE) {
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unwrap(EE)->runStaticConstructorsDestructors(true);
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}
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int LLVMRunFunctionAsMain(LLVMExecutionEngineRef EE, LLVMValueRef F,
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unsigned ArgC, const char * const *ArgV,
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const char * const *EnvP) {
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unwrap(EE)->finalizeObject();
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std::vector<std::string> ArgVec;
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for (unsigned I = 0; I != ArgC; ++I)
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ArgVec.push_back(ArgV[I]);
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return unwrap(EE)->runFunctionAsMain(unwrap<Function>(F), ArgVec, EnvP);
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}
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LLVMGenericValueRef LLVMRunFunction(LLVMExecutionEngineRef EE, LLVMValueRef F,
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unsigned NumArgs,
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LLVMGenericValueRef *Args) {
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unwrap(EE)->finalizeObject();
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std::vector<GenericValue> ArgVec;
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ArgVec.reserve(NumArgs);
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for (unsigned I = 0; I != NumArgs; ++I)
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ArgVec.push_back(*unwrap(Args[I]));
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GenericValue *Result = new GenericValue();
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*Result = unwrap(EE)->runFunction(unwrap<Function>(F), ArgVec);
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return wrap(Result);
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}
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void LLVMFreeMachineCodeForFunction(LLVMExecutionEngineRef EE, LLVMValueRef F) {
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unwrap(EE)->freeMachineCodeForFunction(unwrap<Function>(F));
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}
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void LLVMAddModule(LLVMExecutionEngineRef EE, LLVMModuleRef M){
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unwrap(EE)->addModule(unwrap(M));
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}
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void LLVMAddModuleProvider(LLVMExecutionEngineRef EE, LLVMModuleProviderRef MP){
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/* The module provider is now actually a module. */
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LLVMAddModule(EE, reinterpret_cast<LLVMModuleRef>(MP));
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}
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LLVMBool LLVMRemoveModule(LLVMExecutionEngineRef EE, LLVMModuleRef M,
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LLVMModuleRef *OutMod, char **OutError) {
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Module *Mod = unwrap(M);
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unwrap(EE)->removeModule(Mod);
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*OutMod = wrap(Mod);
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return 0;
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}
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LLVMBool LLVMRemoveModuleProvider(LLVMExecutionEngineRef EE,
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LLVMModuleProviderRef MP,
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LLVMModuleRef *OutMod, char **OutError) {
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/* The module provider is now actually a module. */
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return LLVMRemoveModule(EE, reinterpret_cast<LLVMModuleRef>(MP), OutMod,
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OutError);
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}
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LLVMBool LLVMFindFunction(LLVMExecutionEngineRef EE, const char *Name,
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LLVMValueRef *OutFn) {
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if (Function *F = unwrap(EE)->FindFunctionNamed(Name)) {
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*OutFn = wrap(F);
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return 0;
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}
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return 1;
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}
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void *LLVMRecompileAndRelinkFunction(LLVMExecutionEngineRef EE,
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LLVMValueRef Fn) {
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return unwrap(EE)->recompileAndRelinkFunction(unwrap<Function>(Fn));
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}
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LLVMTargetDataRef LLVMGetExecutionEngineTargetData(LLVMExecutionEngineRef EE) {
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return wrap(unwrap(EE)->getDataLayout());
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}
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void LLVMAddGlobalMapping(LLVMExecutionEngineRef EE, LLVMValueRef Global,
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void* Addr) {
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unwrap(EE)->addGlobalMapping(unwrap<GlobalValue>(Global), Addr);
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}
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void *LLVMGetPointerToGlobal(LLVMExecutionEngineRef EE, LLVMValueRef Global) {
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unwrap(EE)->finalizeObject();
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return unwrap(EE)->getPointerToGlobal(unwrap<GlobalValue>(Global));
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}
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