unittests/ExecutionEngine/MCJIT/MCJITTestBase.h - external/github.com/emscripten-core/emscripten-fastcomp - Git at Google

 //===- MCJITTestBase.h - Common base class for MCJIT Unit tests -*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This class implements common functionality required by the MCJIT unit tests,
 // as well as logic to skip tests on unsupported architectures and operating
 // systems.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_UNITTESTS_EXECUTIONENGINE_MCJIT_MCJITTESTBASE_H
 #define LLVM_UNITTESTS_EXECUTIONENGINE_MCJIT_MCJITTESTBASE_H

 #include "MCJITTestAPICommon.h"
 #include "llvm/Config/config.h"
 #include "llvm/ExecutionEngine/ExecutionEngine.h"
 #include "llvm/ExecutionEngine/SectionMemoryManager.h"
 #include "llvm/IR/Function.h"
 #include "llvm/IR/IRBuilder.h"
 #include "llvm/IR/LLVMContext.h"
 #include "llvm/IR/Module.h"
 #include "llvm/IR/TypeBuilder.h"
 #include "llvm/Support/CodeGen.h"

 namespace llvm {

 /// Helper class that can build very simple Modules
 class TrivialModuleBuilder {
 protected:
   LLVMContext Context;
   IRBuilder<> Builder;
   std::string BuilderTriple;

   TrivialModuleBuilder(const std::string &Triple)
     : Builder(Context), BuilderTriple(Triple) {}

   Module *createEmptyModule(StringRef Name = StringRef()) {
     Module * M = new Module(Name, Context);
     M->setTargetTriple(Triple::normalize(BuilderTriple));
     return M;
   }

   template<typename FuncType>
   Function *startFunction(Module *M, StringRef Name) {
     Function *Result = Function::Create(
       TypeBuilder<FuncType, false>::get(Context),
       GlobalValue::ExternalLinkage, Name, M);

     BasicBlock *BB = BasicBlock::Create(Context, Name, Result);
     Builder.SetInsertPoint(BB);

     return Result;
   }

   void endFunctionWithRet(Function *Func, Value *RetValue) {
     Builder.CreateRet(RetValue);
   }

   // Inserts a simple function that invokes Callee and takes the same arguments:
   //    int Caller(...) { return Callee(...); }
   template<typename Signature>
   Function *insertSimpleCallFunction(Module *M, Function *Callee) {
     Function *Result = startFunction<Signature>(M, "caller");

     SmallVector<Value*, 1> CallArgs;

     for (Argument &A : Result->args())
       CallArgs.push_back(&A);

     Value *ReturnCode = Builder.CreateCall(Callee, CallArgs);
     Builder.CreateRet(ReturnCode);
     return Result;
   }

   // Inserts a function named 'main' that returns a uint32_t:
   //    int32_t main() { return X; }
   // where X is given by returnCode
   Function *insertMainFunction(Module *M, uint32_t returnCode) {
     Function *Result = startFunction<int32_t(void)>(M, "main");

     Value *ReturnVal = ConstantInt::get(Context, APInt(32, returnCode));
     endFunctionWithRet(Result, ReturnVal);

     return Result;
   }

   // Inserts a function
   //    int32_t add(int32_t a, int32_t b) { return a + b; }
   // in the current module and returns a pointer to it.
   Function *insertAddFunction(Module *M, StringRef Name = "add") {
     Function *Result = startFunction<int32_t(int32_t, int32_t)>(M, Name);

     Function::arg_iterator args = Result->arg_begin();
     Value *Arg1 = &*args;
     Value *Arg2 = &*++args;
     Value *AddResult = Builder.CreateAdd(Arg1, Arg2);

     endFunctionWithRet(Result, AddResult);

     return Result;
   }

   // Inserts a declaration to a function defined elsewhere
   template <typename FuncType>
   Function *insertExternalReferenceToFunction(Module *M, StringRef Name) {
     Function *Result = Function::Create(
                          TypeBuilder<FuncType, false>::get(Context),
                          GlobalValue::ExternalLinkage, Name, M);
     return Result;
   }

   // Inserts an declaration to a function defined elsewhere
   Function *insertExternalReferenceToFunction(Module *M, StringRef Name,
                                               FunctionType *FuncTy) {
     Function *Result = Function::Create(FuncTy,
                                         GlobalValue::ExternalLinkage,
                                         Name, M);
     return Result;
   }

   // Inserts an declaration to a function defined elsewhere
   Function *insertExternalReferenceToFunction(Module *M, Function *Func) {
     Function *Result = Function::Create(Func->getFunctionType(),
                                         GlobalValue::ExternalLinkage,
                                         Func->getName(), M);
     return Result;
   }

   // Inserts a global variable of type int32
   // FIXME: make this a template function to support any type
   GlobalVariable *insertGlobalInt32(Module *M,
                                     StringRef name,
                                     int32_t InitialValue) {
     Type *GlobalTy = TypeBuilder<types::i<32>, true>::get(Context);
     Constant *IV = ConstantInt::get(Context, APInt(32, InitialValue));
     GlobalVariable *Global = new GlobalVariable(*M,
                                                 GlobalTy,
                                                 false,
                                                 GlobalValue::ExternalLinkage,
                                                 IV,
                                                 name);
     return Global;
   }

   // Inserts a function
   //   int32_t recursive_add(int32_t num) {
   //     if (num == 0) {
   //       return num;
   //     } else {
   //       int32_t recursive_param = num - 1;
   //       return num + Helper(recursive_param);
   //     }
   //   }
   // NOTE: if Helper is left as the default parameter, Helper == recursive_add.
   Function *insertAccumulateFunction(Module *M,
                                      Function *Helper = nullptr,
                                      StringRef Name = "accumulate") {
     Function *Result = startFunction<int32_t(int32_t)>(M, Name);
     if (!Helper)
       Helper = Result;

     BasicBlock *BaseCase = BasicBlock::Create(Context, "", Result);
     BasicBlock *RecursiveCase = BasicBlock::Create(Context, "", Result);

     // if (num == 0)
     Value *Param = &*Result->arg_begin();
     Value *Zero = ConstantInt::get(Context, APInt(32, 0));
     Builder.CreateCondBr(Builder.CreateICmpEQ(Param, Zero),
                          BaseCase, RecursiveCase);

     //   return num;
     Builder.SetInsertPoint(BaseCase);
     Builder.CreateRet(Param);

     //   int32_t recursive_param = num - 1;
     //   return Helper(recursive_param);
     Builder.SetInsertPoint(RecursiveCase);
     Value *One = ConstantInt::get(Context, APInt(32, 1));
     Value *RecursiveParam = Builder.CreateSub(Param, One);
     Value *RecursiveReturn = Builder.CreateCall(Helper, RecursiveParam);
     Value *Accumulator = Builder.CreateAdd(Param, RecursiveReturn);
     Builder.CreateRet(Accumulator);

     return Result;
   }

   // Populates Modules A and B:
   // Module A { Extern FB1, Function FA which calls FB1 },
   // Module B { Extern FA, Function FB1, Function FB2 which calls FA },
   void createCrossModuleRecursiveCase(std::unique_ptr<Module> &A, Function *&FA,
                                       std::unique_ptr<Module> &B,
                                       Function *&FB1, Function *&FB2) {
     // Define FB1 in B.
     B.reset(createEmptyModule("B"));
     FB1 = insertAccumulateFunction(B.get(), nullptr, "FB1");

     // Declare FB1 in A (as an external).
     A.reset(createEmptyModule("A"));
     Function *FB1Extern = insertExternalReferenceToFunction(A.get(), FB1);

     // Define FA in A (with a call to FB1).
     FA = insertAccumulateFunction(A.get(), FB1Extern, "FA");

     // Declare FA in B (as an external)
     Function *FAExtern = insertExternalReferenceToFunction(B.get(), FA);

     // Define FB2 in B (with a call to FA)
     FB2 = insertAccumulateFunction(B.get(), FAExtern, "FB2");
   }

   // Module A { Function FA },
   // Module B { Extern FA, Function FB which calls FA },
   // Module C { Extern FB, Function FC which calls FB },
   void
   createThreeModuleChainedCallsCase(std::unique_ptr<Module> &A, Function *&FA,
                                     std::unique_ptr<Module> &B, Function *&FB,
                                     std::unique_ptr<Module> &C, Function *&FC) {
     A.reset(createEmptyModule("A"));
     FA = insertAddFunction(A.get());

     B.reset(createEmptyModule("B"));
     Function *FAExtern_in_B = insertExternalReferenceToFunction(B.get(), FA);
     FB = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(B.get(), FAExtern_in_B);

     C.reset(createEmptyModule("C"));
     Function *FBExtern_in_C = insertExternalReferenceToFunction(C.get(), FB);
     FC = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(C.get(), FBExtern_in_C);
   }

   // Module A { Function FA },
   // Populates Modules A and B:
   // Module B { Function FB }
   void createTwoModuleCase(std::unique_ptr<Module> &A, Function *&FA,
                            std::unique_ptr<Module> &B, Function *&FB) {
     A.reset(createEmptyModule("A"));
     FA = insertAddFunction(A.get());

     B.reset(createEmptyModule("B"));
     FB = insertAddFunction(B.get());
   }

   // Module A { Function FA },
   // Module B { Extern FA, Function FB which calls FA }
   void createTwoModuleExternCase(std::unique_ptr<Module> &A, Function *&FA,
                                  std::unique_ptr<Module> &B, Function *&FB) {
     A.reset(createEmptyModule("A"));
     FA = insertAddFunction(A.get());

     B.reset(createEmptyModule("B"));
     Function *FAExtern_in_B = insertExternalReferenceToFunction(B.get(), FA);
     FB = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(B.get(),
                                                              FAExtern_in_B);
   }

   // Module A { Function FA },
   // Module B { Extern FA, Function FB which calls FA },
   // Module C { Extern FB, Function FC which calls FA },
   void createThreeModuleCase(std::unique_ptr<Module> &A, Function *&FA,
                              std::unique_ptr<Module> &B, Function *&FB,
                              std::unique_ptr<Module> &C, Function *&FC) {
     A.reset(createEmptyModule("A"));
     FA = insertAddFunction(A.get());

     B.reset(createEmptyModule("B"));
     Function *FAExtern_in_B = insertExternalReferenceToFunction(B.get(), FA);
     FB = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(B.get(), FAExtern_in_B);

     C.reset(createEmptyModule("C"));
     Function *FAExtern_in_C = insertExternalReferenceToFunction(C.get(), FA);
     FC = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(C.get(), FAExtern_in_C);
   }
 };

 class MCJITTestBase : public MCJITTestAPICommon, public TrivialModuleBuilder {
 protected:
   MCJITTestBase()
       : TrivialModuleBuilder(HostTriple), OptLevel(CodeGenOpt::None),
         CodeModel(CodeModel::Small), MArch(""), MM(new SectionMemoryManager) {
     // The architectures below are known to be compatible with MCJIT as they
     // are copied from test/ExecutionEngine/MCJIT/lit.local.cfg and should be
     // kept in sync.
     SupportedArchs.push_back(Triple::aarch64);
     SupportedArchs.push_back(Triple::arm);
     SupportedArchs.push_back(Triple::mips);
     SupportedArchs.push_back(Triple::mipsel);
     SupportedArchs.push_back(Triple::mips64);
     SupportedArchs.push_back(Triple::mips64el);
     SupportedArchs.push_back(Triple::x86);
     SupportedArchs.push_back(Triple::x86_64);

     // Some architectures have sub-architectures in which tests will fail, like
     // ARM. These two vectors will define if they do have sub-archs (to avoid
     // extra work for those who don't), and if so, if they are listed to work
     HasSubArchs.push_back(Triple::arm);
     SupportedSubArchs.push_back("armv6");
     SupportedSubArchs.push_back("armv7");

     UnsupportedEnvironments.push_back(Triple::Cygnus);
   }

   void createJIT(std::unique_ptr<Module> M) {

     // Due to the EngineBuilder constructor, it is required to have a Module
     // in order to construct an ExecutionEngine (i.e. MCJIT)
     assert(M != 0 && "a non-null Module must be provided to create MCJIT");

     EngineBuilder EB(std::move(M));
     std::string Error;
     TheJIT.reset(EB.setEngineKind(EngineKind::JIT)
                  .setMCJITMemoryManager(std::move(MM))
                  .setErrorStr(&Error)
                  .setOptLevel(CodeGenOpt::None)
                  .setMArch(MArch)
                  .setMCPU(sys::getHostCPUName())
                  //.setMAttrs(MAttrs)
                  .create());
     // At this point, we cannot modify the module any more.
     assert(TheJIT.get() != NULL && "error creating MCJIT with EngineBuilder");
   }

   CodeGenOpt::Level OptLevel;
   CodeModel::Model CodeModel;
   StringRef MArch;
   SmallVector<std::string, 1> MAttrs;
   std::unique_ptr<ExecutionEngine> TheJIT;
   std::unique_ptr<RTDyldMemoryManager> MM;

   std::unique_ptr<Module> M;
 };

 } // namespace llvm

 #endif // LLVM_UNITTESTS_EXECUTIONENGINE_MCJIT_MCJITTESTBASE_H
	//===- MCJITTestBase.h - Common base class for MCJIT Unit tests -- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This class implements common functionality required by the MCJIT unit tests,
	// as well as logic to skip tests on unsupported architectures and operating
	// systems.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_UNITTESTS_EXECUTIONENGINE_MCJIT_MCJITTESTBASE_H
	#define LLVM_UNITTESTS_EXECUTIONENGINE_MCJIT_MCJITTESTBASE_H

	#include "MCJITTestAPICommon.h"
	#include "llvm/Config/config.h"
	#include "llvm/ExecutionEngine/ExecutionEngine.h"
	#include "llvm/ExecutionEngine/SectionMemoryManager.h"
	#include "llvm/IR/Function.h"
	#include "llvm/IR/IRBuilder.h"
	#include "llvm/IR/LLVMContext.h"
	#include "llvm/IR/Module.h"
	#include "llvm/IR/TypeBuilder.h"
	#include "llvm/Support/CodeGen.h"

	namespace llvm {

	/// Helper class that can build very simple Modules
	class TrivialModuleBuilder {
	protected:
	LLVMContext Context;
	IRBuilder<> Builder;
	std::string BuilderTriple;

	TrivialModuleBuilder(const std::string &Triple)
	: Builder(Context), BuilderTriple(Triple) {}

	Module *createEmptyModule(StringRef Name = StringRef()) {
	Module * M = new Module(Name, Context);
	M->setTargetTriple(Triple::normalize(BuilderTriple));
	return M;
	}

	template<typename FuncType>
	Function startFunction(Module M, StringRef Name) {
	Function *Result = Function::Create(
	TypeBuilder<FuncType, false>::get(Context),
	GlobalValue::ExternalLinkage, Name, M);

	BasicBlock *BB = BasicBlock::Create(Context, Name, Result);
	Builder.SetInsertPoint(BB);

	return Result;
	}

	void endFunctionWithRet(Function Func, Value RetValue) {
	Builder.CreateRet(RetValue);
	}

	// Inserts a simple function that invokes Callee and takes the same arguments:
	// int Caller(...) { return Callee(...); }
	template<typename Signature>
	Function insertSimpleCallFunction(Module M, Function *Callee) {
	Function *Result = startFunction<Signature>(M, "caller");

	SmallVector<Value*, 1> CallArgs;

	for (Argument &A : Result->args())
	CallArgs.push_back(&A);

	Value *ReturnCode = Builder.CreateCall(Callee, CallArgs);
	Builder.CreateRet(ReturnCode);
	return Result;
	}

	// Inserts a function named 'main' that returns a uint32_t:
	// int32_t main() { return X; }
	// where X is given by returnCode
	Function insertMainFunction(Module M, uint32_t returnCode) {
	Function *Result = startFunction<int32_t(void)>(M, "main");

	Value *ReturnVal = ConstantInt::get(Context, APInt(32, returnCode));
	endFunctionWithRet(Result, ReturnVal);

	return Result;
	}

	// Inserts a function
	// int32_t add(int32_t a, int32_t b) { return a + b; }
	// in the current module and returns a pointer to it.
	Function insertAddFunction(Module M, StringRef Name = "add") {
	Function *Result = startFunction<int32_t(int32_t, int32_t)>(M, Name);

	Function::arg_iterator args = Result->arg_begin();
	Value Arg1 = &args;
	Value Arg2 = &++args;
	Value *AddResult = Builder.CreateAdd(Arg1, Arg2);

	endFunctionWithRet(Result, AddResult);

	return Result;
	}

	// Inserts a declaration to a function defined elsewhere
	template <typename FuncType>
	Function insertExternalReferenceToFunction(Module M, StringRef Name) {
	Function *Result = Function::Create(
	TypeBuilder<FuncType, false>::get(Context),
	GlobalValue::ExternalLinkage, Name, M);
	return Result;
	}

	// Inserts an declaration to a function defined elsewhere
	Function insertExternalReferenceToFunction(Module M, StringRef Name,
	FunctionType *FuncTy) {
	Function *Result = Function::Create(FuncTy,
	GlobalValue::ExternalLinkage,
	Name, M);
	return Result;
	}

	// Inserts an declaration to a function defined elsewhere
	Function insertExternalReferenceToFunction(Module M, Function *Func) {
	Function *Result = Function::Create(Func->getFunctionType(),
	GlobalValue::ExternalLinkage,
	Func->getName(), M);
	return Result;
	}

	// Inserts a global variable of type int32
	// FIXME: make this a template function to support any type
	GlobalVariable insertGlobalInt32(Module M,
	StringRef name,
	int32_t InitialValue) {
	Type *GlobalTy = TypeBuilder<types::i<32>, true>::get(Context);
	Constant *IV = ConstantInt::get(Context, APInt(32, InitialValue));
	GlobalVariable Global = new GlobalVariable(M,
	GlobalTy,
	false,
	GlobalValue::ExternalLinkage,
	IV,
	name);
	return Global;
	}

	// Inserts a function
	// int32_t recursive_add(int32_t num) {
	// if (num == 0) {
	// return num;
	// } else {
	// int32_t recursive_param = num - 1;
	// return num + Helper(recursive_param);
	// }
	// }
	// NOTE: if Helper is left as the default parameter, Helper == recursive_add.
	Function insertAccumulateFunction(Module M,
	Function *Helper = nullptr,
	StringRef Name = "accumulate") {
	Function *Result = startFunction<int32_t(int32_t)>(M, Name);
	if (!Helper)
	Helper = Result;

	BasicBlock *BaseCase = BasicBlock::Create(Context, "", Result);
	BasicBlock *RecursiveCase = BasicBlock::Create(Context, "", Result);

	// if (num == 0)
	Value Param = &Result->arg_begin();
	Value *Zero = ConstantInt::get(Context, APInt(32, 0));
	Builder.CreateCondBr(Builder.CreateICmpEQ(Param, Zero),
	BaseCase, RecursiveCase);

	// return num;
	Builder.SetInsertPoint(BaseCase);
	Builder.CreateRet(Param);

	// int32_t recursive_param = num - 1;
	// return Helper(recursive_param);
	Builder.SetInsertPoint(RecursiveCase);
	Value *One = ConstantInt::get(Context, APInt(32, 1));
	Value *RecursiveParam = Builder.CreateSub(Param, One);
	Value *RecursiveReturn = Builder.CreateCall(Helper, RecursiveParam);
	Value *Accumulator = Builder.CreateAdd(Param, RecursiveReturn);
	Builder.CreateRet(Accumulator);

	return Result;
	}

	// Populates Modules A and B:
	// Module A { Extern FB1, Function FA which calls FB1 },
	// Module B { Extern FA, Function FB1, Function FB2 which calls FA },
	void createCrossModuleRecursiveCase(std::unique_ptr<Module> &A, Function *&FA,
	std::unique_ptr<Module> &B,
	Function &FB1, Function &FB2) {
	// Define FB1 in B.
	B.reset(createEmptyModule("B"));
	FB1 = insertAccumulateFunction(B.get(), nullptr, "FB1");

	// Declare FB1 in A (as an external).
	A.reset(createEmptyModule("A"));
	Function *FB1Extern = insertExternalReferenceToFunction(A.get(), FB1);

	// Define FA in A (with a call to FB1).
	FA = insertAccumulateFunction(A.get(), FB1Extern, "FA");

	// Declare FA in B (as an external)
	Function *FAExtern = insertExternalReferenceToFunction(B.get(), FA);

	// Define FB2 in B (with a call to FA)
	FB2 = insertAccumulateFunction(B.get(), FAExtern, "FB2");
	}

	// Module A { Function FA },
	// Module B { Extern FA, Function FB which calls FA },
	// Module C { Extern FB, Function FC which calls FB },
	void
	createThreeModuleChainedCallsCase(std::unique_ptr<Module> &A, Function *&FA,
	std::unique_ptr<Module> &B, Function *&FB,
	std::unique_ptr<Module> &C, Function *&FC) {
	A.reset(createEmptyModule("A"));
	FA = insertAddFunction(A.get());

	B.reset(createEmptyModule("B"));
	Function *FAExtern_in_B = insertExternalReferenceToFunction(B.get(), FA);
	FB = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(B.get(), FAExtern_in_B);

	C.reset(createEmptyModule("C"));
	Function *FBExtern_in_C = insertExternalReferenceToFunction(C.get(), FB);
	FC = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(C.get(), FBExtern_in_C);
	}

	// Module A { Function FA },
	// Populates Modules A and B:
	// Module B { Function FB }
	void createTwoModuleCase(std::unique_ptr<Module> &A, Function *&FA,
	std::unique_ptr<Module> &B, Function *&FB) {
	A.reset(createEmptyModule("A"));
	FA = insertAddFunction(A.get());

	B.reset(createEmptyModule("B"));
	FB = insertAddFunction(B.get());
	}

	// Module A { Function FA },
	// Module B { Extern FA, Function FB which calls FA }
	void createTwoModuleExternCase(std::unique_ptr<Module> &A, Function *&FA,
	std::unique_ptr<Module> &B, Function *&FB) {
	A.reset(createEmptyModule("A"));
	FA = insertAddFunction(A.get());

	B.reset(createEmptyModule("B"));
	Function *FAExtern_in_B = insertExternalReferenceToFunction(B.get(), FA);
	FB = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(B.get(),
	FAExtern_in_B);
	}

	// Module A { Function FA },
	// Module B { Extern FA, Function FB which calls FA },
	// Module C { Extern FB, Function FC which calls FA },
	void createThreeModuleCase(std::unique_ptr<Module> &A, Function *&FA,
	std::unique_ptr<Module> &B, Function *&FB,
	std::unique_ptr<Module> &C, Function *&FC) {
	A.reset(createEmptyModule("A"));
	FA = insertAddFunction(A.get());

	B.reset(createEmptyModule("B"));
	Function *FAExtern_in_B = insertExternalReferenceToFunction(B.get(), FA);
	FB = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(B.get(), FAExtern_in_B);

	C.reset(createEmptyModule("C"));
	Function *FAExtern_in_C = insertExternalReferenceToFunction(C.get(), FA);
	FC = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(C.get(), FAExtern_in_C);
	}
	};

	class MCJITTestBase : public MCJITTestAPICommon, public TrivialModuleBuilder {
	protected:
	MCJITTestBase()
	: TrivialModuleBuilder(HostTriple), OptLevel(CodeGenOpt::None),
	CodeModel(CodeModel::Small), MArch(""), MM(new SectionMemoryManager) {
	// The architectures below are known to be compatible with MCJIT as they
	// are copied from test/ExecutionEngine/MCJIT/lit.local.cfg and should be
	// kept in sync.
	SupportedArchs.push_back(Triple::aarch64);
	SupportedArchs.push_back(Triple::arm);
	SupportedArchs.push_back(Triple::mips);
	SupportedArchs.push_back(Triple::mipsel);
	SupportedArchs.push_back(Triple::mips64);
	SupportedArchs.push_back(Triple::mips64el);
	SupportedArchs.push_back(Triple::x86);
	SupportedArchs.push_back(Triple::x86_64);

	// Some architectures have sub-architectures in which tests will fail, like
	// ARM. These two vectors will define if they do have sub-archs (to avoid
	// extra work for those who don't), and if so, if they are listed to work
	HasSubArchs.push_back(Triple::arm);
	SupportedSubArchs.push_back("armv6");
	SupportedSubArchs.push_back("armv7");

	UnsupportedEnvironments.push_back(Triple::Cygnus);
	}

	void createJIT(std::unique_ptr<Module> M) {

	// Due to the EngineBuilder constructor, it is required to have a Module
	// in order to construct an ExecutionEngine (i.e. MCJIT)
	assert(M != 0 && "a non-null Module must be provided to create MCJIT");

	EngineBuilder EB(std::move(M));
	std::string Error;
	TheJIT.reset(EB.setEngineKind(EngineKind::JIT)
	.setMCJITMemoryManager(std::move(MM))
	.setErrorStr(&Error)
	.setOptLevel(CodeGenOpt::None)
	.setMArch(MArch)
	.setMCPU(sys::getHostCPUName())
	//.setMAttrs(MAttrs)
	.create());
	// At this point, we cannot modify the module any more.
	assert(TheJIT.get() != NULL && "error creating MCJIT with EngineBuilder");
	}

	CodeGenOpt::Level OptLevel;
	CodeModel::Model CodeModel;
	StringRef MArch;
	SmallVector<std::string, 1> MAttrs;
	std::unique_ptr<ExecutionEngine> TheJIT;
	std::unique_ptr<RTDyldMemoryManager> MM;

	std::unique_ptr<Module> M;
	};

	} // namespace llvm

	#endif // LLVM_UNITTESTS_EXECUTIONENGINE_MCJIT_MCJITTESTBASE_H