unittests/ExecutionEngine/Orc/ObjectTransformLayerTest.cpp - llvm - Git at Google

 //===- ObjectTransformLayerTest.cpp - Unit tests for ObjectTransformLayer -===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ExecutionEngine/Orc/ObjectTransformLayer.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ExecutionEngine/Orc/IRCompileLayer.h"
 #include "llvm/ExecutionEngine/Orc/NullResolver.h"
 #include "llvm/ExecutionEngine/Orc/RTDyldObjectLinkingLayer.h"
 #include "llvm/ExecutionEngine/SectionMemoryManager.h"
 #include "llvm/IR/Module.h"
 #include "llvm/Object/ObjectFile.h"
 #include "gtest/gtest.h"

 using namespace llvm::orc;

 namespace {

 // stand-in for object::ObjectFile
 typedef int MockObjectFile;

 // stand-in for llvm::MemoryBuffer set
 typedef int MockMemoryBuffer;

 // Mock transform that operates on unique pointers to object files, and
 // allocates new object files rather than mutating the given ones.
 struct AllocatingTransform {
   std::shared_ptr<MockObjectFile>
   operator()(std::shared_ptr<MockObjectFile> Obj) const {
     return std::make_shared<MockObjectFile>(*Obj + 1);
   }
 };

 // Mock base layer for verifying behavior of transform layer.
 // Each method "T foo(args)" is accompanied by two auxiliary methods:
 //  - "void expectFoo(args)", to be called before calling foo on the transform
 //      layer; saves values of args, which mock layer foo then verifies against.
 // - "void verifyFoo(T)", to be called after foo, which verifies that the
 //      transform layer called the base layer and forwarded any return value.
 class MockBaseLayer {
 public:
   MockBaseLayer() : MockSymbol(nullptr) { resetExpectations(); }

   template <typename ObjPtrT> llvm::Error addObject(VModuleKey K, ObjPtrT Obj) {
     EXPECT_EQ(MockKey, K) << "Key should pass through";
     EXPECT_EQ(MockObject + 1, *Obj) << "Transform should be applied";
     LastCalled = "addObject";
     return llvm::Error::success();
   }

   template <typename ObjPtrT> void expectAddObject(VModuleKey K, ObjPtrT Obj) {
     MockKey = K;
     MockObject = *Obj;
   }

   void verifyAddObject() {
     EXPECT_EQ("addObject", LastCalled);
     resetExpectations();
   }

   llvm::Error removeObject(VModuleKey K) {
     EXPECT_EQ(MockKey, K);
     LastCalled = "removeObject";
     return llvm::Error::success();
   }

   void expectRemoveObject(VModuleKey K) { MockKey = K; }
   void verifyRemoveObject() {
     EXPECT_EQ("removeObject", LastCalled);
     resetExpectations();
   }

   llvm::JITSymbol findSymbol(const std::string &Name,
                              bool ExportedSymbolsOnly) {
     EXPECT_EQ(MockName, Name) << "Name should pass through";
     EXPECT_EQ(MockBool, ExportedSymbolsOnly) << "Flag should pass through";
     LastCalled = "findSymbol";
     MockSymbol = llvm::JITSymbol(122, llvm::JITSymbolFlags::None);
     return llvm::JITSymbol(122, llvm::JITSymbolFlags::None);
   }
   void expectFindSymbol(const std::string &Name, bool ExportedSymbolsOnly) {
     MockName = Name;
     MockBool = ExportedSymbolsOnly;
   }
   void verifyFindSymbol(llvm::JITSymbol Returned) {
     EXPECT_EQ("findSymbol", LastCalled);
     EXPECT_EQ(cantFail(MockSymbol.getAddress()),
               cantFail(Returned.getAddress()))
         << "Return should pass through";
     resetExpectations();
   }

   llvm::JITSymbol findSymbolIn(VModuleKey K, const std::string &Name,
                                bool ExportedSymbolsOnly) {
     EXPECT_EQ(MockKey, K) << "VModuleKey should pass through";
     EXPECT_EQ(MockName, Name) << "Name should pass through";
     EXPECT_EQ(MockBool, ExportedSymbolsOnly) << "Flag should pass through";
     LastCalled = "findSymbolIn";
     MockSymbol = llvm::JITSymbol(122, llvm::JITSymbolFlags::None);
     return llvm::JITSymbol(122, llvm::JITSymbolFlags::None);
   }
   void expectFindSymbolIn(VModuleKey K, const std::string &Name,
                           bool ExportedSymbolsOnly) {
     MockKey = K;
     MockName = Name;
     MockBool = ExportedSymbolsOnly;
   }
   void verifyFindSymbolIn(llvm::JITSymbol Returned) {
     EXPECT_EQ("findSymbolIn", LastCalled);
     EXPECT_EQ(cantFail(MockSymbol.getAddress()),
               cantFail(Returned.getAddress()))
         << "Return should pass through";
     resetExpectations();
   }

   llvm::Error emitAndFinalize(VModuleKey K) {
     EXPECT_EQ(MockKey, K) << "VModuleKey should pass through";
     LastCalled = "emitAndFinalize";
     return llvm::Error::success();
   }

   void expectEmitAndFinalize(VModuleKey K) { MockKey = K; }

   void verifyEmitAndFinalize() {
     EXPECT_EQ("emitAndFinalize", LastCalled);
     resetExpectations();
   }

   void mapSectionAddress(VModuleKey K, const void *LocalAddress,
                          llvm::JITTargetAddress TargetAddr) {
     EXPECT_EQ(MockKey, K);
     EXPECT_EQ(MockLocalAddress, LocalAddress);
     EXPECT_EQ(MockTargetAddress, TargetAddr);
     LastCalled = "mapSectionAddress";
   }
   void expectMapSectionAddress(VModuleKey K, const void *LocalAddress,
                                llvm::JITTargetAddress TargetAddr) {
     MockKey = K;
     MockLocalAddress = LocalAddress;
     MockTargetAddress = TargetAddr;
   }
   void verifyMapSectionAddress() {
     EXPECT_EQ("mapSectionAddress", LastCalled);
     resetExpectations();
   }

 private:
   // Backing fields for remembering parameter/return values
   std::string LastCalled;
   VModuleKey MockKey;
   MockObjectFile MockObject;
   std::string MockName;
   bool MockBool;
   llvm::JITSymbol MockSymbol;
   const void *MockLocalAddress;
   llvm::JITTargetAddress MockTargetAddress;
   MockMemoryBuffer MockBuffer;

   // Clear remembered parameters between calls
   void resetExpectations() {
     LastCalled = "nothing";
     MockKey = 0;
     MockObject = 0;
     MockName = "bogus";
     MockSymbol = llvm::JITSymbol(nullptr);
     MockLocalAddress = nullptr;
     MockTargetAddress = 0;
     MockBuffer = 0;
   }
 };

 // Test each operation on LegacyObjectTransformLayer.
 TEST(LegacyObjectTransformLayerTest, Main) {
   MockBaseLayer M;

   ExecutionSession ES(std::make_shared<SymbolStringPool>());

   // Create one object transform layer using a transform (as a functor)
   // that allocates new objects, and deals in unique pointers.
   LegacyObjectTransformLayer<MockBaseLayer, AllocatingTransform> T1(M);

   // Create a second object transform layer using a transform (as a lambda)
   // that mutates objects in place, and deals in naked pointers
   LegacyObjectTransformLayer<MockBaseLayer,
                          std::function<std::shared_ptr<MockObjectFile>(
                            std::shared_ptr<MockObjectFile>)>>
     T2(M, [](std::shared_ptr<MockObjectFile> Obj) {
     ++(*Obj);
     return Obj;
   });

   // Test addObject with T1 (allocating)
   auto K1 = ES.allocateVModule();
   auto Obj1 = std::make_shared<MockObjectFile>(211);
   M.expectAddObject(K1, Obj1);
   cantFail(T1.addObject(K1, std::move(Obj1)));
   M.verifyAddObject();

   // Test addObjectSet with T2 (mutating)
   auto K2 = ES.allocateVModule();
   auto Obj2 = std::make_shared<MockObjectFile>(222);
   M.expectAddObject(K2, Obj2);
   cantFail(T2.addObject(K2, Obj2));
   M.verifyAddObject();
   EXPECT_EQ(223, *Obj2) << "Expected mutation";

   // Test removeObjectSet
   M.expectRemoveObject(K2);
   cantFail(T1.removeObject(K2));
   M.verifyRemoveObject();

   // Test findSymbol
   std::string Name = "foo";
   bool ExportedOnly = true;
   M.expectFindSymbol(Name, ExportedOnly);
   llvm::JITSymbol Sym1 = T2.findSymbol(Name, ExportedOnly);
   M.verifyFindSymbol(std::move(Sym1));

   // Test findSymbolIn
   Name = "bar";
   ExportedOnly = false;
   M.expectFindSymbolIn(K1, Name, ExportedOnly);
   llvm::JITSymbol Sym2 = T1.findSymbolIn(K1, Name, ExportedOnly);
   M.verifyFindSymbolIn(std::move(Sym2));

   // Test emitAndFinalize
   M.expectEmitAndFinalize(K1);
   cantFail(T2.emitAndFinalize(K1));
   M.verifyEmitAndFinalize();

   // Test mapSectionAddress
   char Buffer[24];
   llvm::JITTargetAddress MockAddress = 255;
   M.expectMapSectionAddress(K1, Buffer, MockAddress);
   T1.mapSectionAddress(K1, Buffer, MockAddress);
   M.verifyMapSectionAddress();

   // Verify transform getter (non-const)
   auto Mutatee = std::make_shared<MockObjectFile>(277);
   auto Out = T2.getTransform()(Mutatee);
   EXPECT_EQ(*Mutatee, *Out) << "Expected in-place transform";
   EXPECT_EQ(278, *Mutatee) << "Expected incrementing transform";

   // Verify transform getter (const)
   auto OwnedObj = std::make_shared<MockObjectFile>(288);
   const auto &T1C = T1;
   OwnedObj = T1C.getTransform()(std::move(OwnedObj));
   EXPECT_EQ(289, *OwnedObj) << "Expected incrementing transform";

   volatile bool RunStaticChecks = false;
   if (!RunStaticChecks)
     return;

   // Make sure that LegacyObjectTransformLayer implements the object layer concept
   // correctly by sandwitching one between an ObjectLinkingLayer and an
   // LegacyIRCompileLayer, verifying that it compiles if we have a call to the
   // IRComileLayer's addModule that should call the transform layer's
   // addObject, and also calling the other public transform layer methods
   // directly to make sure the methods they intend to forward to exist on
   // the ObjectLinkingLayer.

   // We'll need a concrete MemoryManager class.
   class NullManager : public llvm::RuntimeDyld::MemoryManager {
   public:
     uint8_t *allocateCodeSection(uintptr_t, unsigned, unsigned,
                                  llvm::StringRef) override {
       return nullptr;
     }
     uint8_t *allocateDataSection(uintptr_t, unsigned, unsigned, llvm::StringRef,
                                  bool) override {
       return nullptr;
     }
     void registerEHFrames(uint8_t *, uint64_t, size_t) override {}
     void deregisterEHFrames() override {}
     bool finalizeMemory(std::string *) override { return false; }
   };

   // Construct the jit layers.
   LegacyRTDyldObjectLinkingLayer BaseLayer(ES, [](VModuleKey) {
     return LegacyRTDyldObjectLinkingLayer::Resources{
         std::make_shared<llvm::SectionMemoryManager>(),
         std::make_shared<NullResolver>()};
   });

   auto IdentityTransform = [](std::unique_ptr<llvm::MemoryBuffer> Obj) {
     return Obj;
   };
   LegacyObjectTransformLayer<decltype(BaseLayer), decltype(IdentityTransform)>
       TransformLayer(BaseLayer, IdentityTransform);
   auto NullCompiler = [](llvm::Module &) {
     return std::unique_ptr<llvm::MemoryBuffer>(nullptr);
   };
   LegacyIRCompileLayer<decltype(TransformLayer), decltype(NullCompiler)>
     CompileLayer(TransformLayer, NullCompiler);

   // Make sure that the calls from LegacyIRCompileLayer to LegacyObjectTransformLayer
   // compile.
   cantFail(CompileLayer.addModule(ES.allocateVModule(),
                                   std::unique_ptr<llvm::Module>()));

   // Make sure that the calls from LegacyObjectTransformLayer to ObjectLinkingLayer
   // compile.
   VModuleKey DummyKey = ES.allocateVModule();
   cantFail(TransformLayer.emitAndFinalize(DummyKey));
   TransformLayer.findSymbolIn(DummyKey, Name, false);
   TransformLayer.findSymbol(Name, true);
   TransformLayer.mapSectionAddress(DummyKey, nullptr, 0);
   cantFail(TransformLayer.removeObject(DummyKey));
 }
 }
	//===- ObjectTransformLayerTest.cpp - Unit tests for ObjectTransformLayer -===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ExecutionEngine/Orc/ObjectTransformLayer.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ExecutionEngine/Orc/IRCompileLayer.h"
	#include "llvm/ExecutionEngine/Orc/NullResolver.h"
	#include "llvm/ExecutionEngine/Orc/RTDyldObjectLinkingLayer.h"
	#include "llvm/ExecutionEngine/SectionMemoryManager.h"
	#include "llvm/IR/Module.h"
	#include "llvm/Object/ObjectFile.h"
	#include "gtest/gtest.h"

	using namespace llvm::orc;

	namespace {

	// stand-in for object::ObjectFile
	typedef int MockObjectFile;

	// stand-in for llvm::MemoryBuffer set
	typedef int MockMemoryBuffer;

	// Mock transform that operates on unique pointers to object files, and
	// allocates new object files rather than mutating the given ones.
	struct AllocatingTransform {
	std::shared_ptr<MockObjectFile>
	operator()(std::shared_ptr<MockObjectFile> Obj) const {
	return std::make_shared<MockObjectFile>(*Obj + 1);
	}
	};

	// Mock base layer for verifying behavior of transform layer.
	// Each method "T foo(args)" is accompanied by two auxiliary methods:
	// - "void expectFoo(args)", to be called before calling foo on the transform
	// layer; saves values of args, which mock layer foo then verifies against.
	// - "void verifyFoo(T)", to be called after foo, which verifies that the
	// transform layer called the base layer and forwarded any return value.
	class MockBaseLayer {
	public:
	MockBaseLayer() : MockSymbol(nullptr) { resetExpectations(); }

	template <typename ObjPtrT> llvm::Error addObject(VModuleKey K, ObjPtrT Obj) {
	EXPECT_EQ(MockKey, K) << "Key should pass through";
	EXPECT_EQ(MockObject + 1, *Obj) << "Transform should be applied";
	LastCalled = "addObject";
	return llvm::Error::success();
	}

	template <typename ObjPtrT> void expectAddObject(VModuleKey K, ObjPtrT Obj) {
	MockKey = K;
	MockObject = *Obj;
	}

	void verifyAddObject() {
	EXPECT_EQ("addObject", LastCalled);
	resetExpectations();
	}

	llvm::Error removeObject(VModuleKey K) {
	EXPECT_EQ(MockKey, K);
	LastCalled = "removeObject";
	return llvm::Error::success();
	}

	void expectRemoveObject(VModuleKey K) { MockKey = K; }
	void verifyRemoveObject() {
	EXPECT_EQ("removeObject", LastCalled);
	resetExpectations();
	}

	llvm::JITSymbol findSymbol(const std::string &Name,
	bool ExportedSymbolsOnly) {
	EXPECT_EQ(MockName, Name) << "Name should pass through";
	EXPECT_EQ(MockBool, ExportedSymbolsOnly) << "Flag should pass through";
	LastCalled = "findSymbol";
	MockSymbol = llvm::JITSymbol(122, llvm::JITSymbolFlags::None);
	return llvm::JITSymbol(122, llvm::JITSymbolFlags::None);
	}
	void expectFindSymbol(const std::string &Name, bool ExportedSymbolsOnly) {
	MockName = Name;
	MockBool = ExportedSymbolsOnly;
	}
	void verifyFindSymbol(llvm::JITSymbol Returned) {
	EXPECT_EQ("findSymbol", LastCalled);
	EXPECT_EQ(cantFail(MockSymbol.getAddress()),
	cantFail(Returned.getAddress()))
	<< "Return should pass through";
	resetExpectations();
	}

	llvm::JITSymbol findSymbolIn(VModuleKey K, const std::string &Name,
	bool ExportedSymbolsOnly) {
	EXPECT_EQ(MockKey, K) << "VModuleKey should pass through";
	EXPECT_EQ(MockName, Name) << "Name should pass through";
	EXPECT_EQ(MockBool, ExportedSymbolsOnly) << "Flag should pass through";
	LastCalled = "findSymbolIn";
	MockSymbol = llvm::JITSymbol(122, llvm::JITSymbolFlags::None);
	return llvm::JITSymbol(122, llvm::JITSymbolFlags::None);
	}
	void expectFindSymbolIn(VModuleKey K, const std::string &Name,
	bool ExportedSymbolsOnly) {
	MockKey = K;
	MockName = Name;
	MockBool = ExportedSymbolsOnly;
	}
	void verifyFindSymbolIn(llvm::JITSymbol Returned) {
	EXPECT_EQ("findSymbolIn", LastCalled);
	EXPECT_EQ(cantFail(MockSymbol.getAddress()),
	cantFail(Returned.getAddress()))
	<< "Return should pass through";
	resetExpectations();
	}

	llvm::Error emitAndFinalize(VModuleKey K) {
	EXPECT_EQ(MockKey, K) << "VModuleKey should pass through";
	LastCalled = "emitAndFinalize";
	return llvm::Error::success();
	}

	void expectEmitAndFinalize(VModuleKey K) { MockKey = K; }

	void verifyEmitAndFinalize() {
	EXPECT_EQ("emitAndFinalize", LastCalled);
	resetExpectations();
	}

	void mapSectionAddress(VModuleKey K, const void *LocalAddress,
	llvm::JITTargetAddress TargetAddr) {
	EXPECT_EQ(MockKey, K);
	EXPECT_EQ(MockLocalAddress, LocalAddress);
	EXPECT_EQ(MockTargetAddress, TargetAddr);
	LastCalled = "mapSectionAddress";
	}
	void expectMapSectionAddress(VModuleKey K, const void *LocalAddress,
	llvm::JITTargetAddress TargetAddr) {
	MockKey = K;
	MockLocalAddress = LocalAddress;
	MockTargetAddress = TargetAddr;
	}
	void verifyMapSectionAddress() {
	EXPECT_EQ("mapSectionAddress", LastCalled);
	resetExpectations();
	}

	private:
	// Backing fields for remembering parameter/return values
	std::string LastCalled;
	VModuleKey MockKey;
	MockObjectFile MockObject;
	std::string MockName;
	bool MockBool;
	llvm::JITSymbol MockSymbol;
	const void *MockLocalAddress;
	llvm::JITTargetAddress MockTargetAddress;
	MockMemoryBuffer MockBuffer;

	// Clear remembered parameters between calls
	void resetExpectations() {
	LastCalled = "nothing";
	MockKey = 0;
	MockObject = 0;
	MockName = "bogus";
	MockSymbol = llvm::JITSymbol(nullptr);
	MockLocalAddress = nullptr;
	MockTargetAddress = 0;
	MockBuffer = 0;
	}
	};

	// Test each operation on LegacyObjectTransformLayer.
	TEST(LegacyObjectTransformLayerTest, Main) {
	MockBaseLayer M;

	ExecutionSession ES(std::make_shared<SymbolStringPool>());

	// Create one object transform layer using a transform (as a functor)
	// that allocates new objects, and deals in unique pointers.
	LegacyObjectTransformLayer<MockBaseLayer, AllocatingTransform> T1(M);

	// Create a second object transform layer using a transform (as a lambda)
	// that mutates objects in place, and deals in naked pointers
	LegacyObjectTransformLayer<MockBaseLayer,
	std::function<std::shared_ptr<MockObjectFile>(
	std::shared_ptr<MockObjectFile>)>>
	T2(M, [](std::shared_ptr<MockObjectFile> Obj) {
	++(*Obj);
	return Obj;
	});

	// Test addObject with T1 (allocating)
	auto K1 = ES.allocateVModule();
	auto Obj1 = std::make_shared<MockObjectFile>(211);
	M.expectAddObject(K1, Obj1);
	cantFail(T1.addObject(K1, std::move(Obj1)));
	M.verifyAddObject();

	// Test addObjectSet with T2 (mutating)
	auto K2 = ES.allocateVModule();
	auto Obj2 = std::make_shared<MockObjectFile>(222);
	M.expectAddObject(K2, Obj2);
	cantFail(T2.addObject(K2, Obj2));
	M.verifyAddObject();
	EXPECT_EQ(223, *Obj2) << "Expected mutation";

	// Test removeObjectSet
	M.expectRemoveObject(K2);
	cantFail(T1.removeObject(K2));
	M.verifyRemoveObject();

	// Test findSymbol
	std::string Name = "foo";
	bool ExportedOnly = true;
	M.expectFindSymbol(Name, ExportedOnly);
	llvm::JITSymbol Sym1 = T2.findSymbol(Name, ExportedOnly);
	M.verifyFindSymbol(std::move(Sym1));

	// Test findSymbolIn
	Name = "bar";
	ExportedOnly = false;
	M.expectFindSymbolIn(K1, Name, ExportedOnly);
	llvm::JITSymbol Sym2 = T1.findSymbolIn(K1, Name, ExportedOnly);
	M.verifyFindSymbolIn(std::move(Sym2));

	// Test emitAndFinalize
	M.expectEmitAndFinalize(K1);
	cantFail(T2.emitAndFinalize(K1));
	M.verifyEmitAndFinalize();

	// Test mapSectionAddress
	char Buffer[24];
	llvm::JITTargetAddress MockAddress = 255;
	M.expectMapSectionAddress(K1, Buffer, MockAddress);
	T1.mapSectionAddress(K1, Buffer, MockAddress);
	M.verifyMapSectionAddress();

	// Verify transform getter (non-const)
	auto Mutatee = std::make_shared<MockObjectFile>(277);
	auto Out = T2.getTransform()(Mutatee);
	EXPECT_EQ(Mutatee, Out) << "Expected in-place transform";
	EXPECT_EQ(278, *Mutatee) << "Expected incrementing transform";

	// Verify transform getter (const)
	auto OwnedObj = std::make_shared<MockObjectFile>(288);
	const auto &T1C = T1;
	OwnedObj = T1C.getTransform()(std::move(OwnedObj));
	EXPECT_EQ(289, *OwnedObj) << "Expected incrementing transform";

	volatile bool RunStaticChecks = false;
	if (!RunStaticChecks)
	return;

	// Make sure that LegacyObjectTransformLayer implements the object layer concept
	// correctly by sandwitching one between an ObjectLinkingLayer and an
	// LegacyIRCompileLayer, verifying that it compiles if we have a call to the
	// IRComileLayer's addModule that should call the transform layer's
	// addObject, and also calling the other public transform layer methods
	// directly to make sure the methods they intend to forward to exist on
	// the ObjectLinkingLayer.

	// We'll need a concrete MemoryManager class.
	class NullManager : public llvm::RuntimeDyld::MemoryManager {
	public:
	uint8_t *allocateCodeSection(uintptr_t, unsigned, unsigned,
	llvm::StringRef) override {
	return nullptr;
	}
	uint8_t *allocateDataSection(uintptr_t, unsigned, unsigned, llvm::StringRef,
	bool) override {
	return nullptr;
	}
	void registerEHFrames(uint8_t *, uint64_t, size_t) override {}
	void deregisterEHFrames() override {}
	bool finalizeMemory(std::string *) override { return false; }
	};

	// Construct the jit layers.
	LegacyRTDyldObjectLinkingLayer BaseLayer(ES, [](VModuleKey) {
	return LegacyRTDyldObjectLinkingLayer::Resources{
	std::make_shared<llvm::SectionMemoryManager>(),
	std::make_shared<NullResolver>()};
	});

	auto IdentityTransform = [](std::unique_ptr<llvm::MemoryBuffer> Obj) {
	return Obj;
	};
	LegacyObjectTransformLayer<decltype(BaseLayer), decltype(IdentityTransform)>
	TransformLayer(BaseLayer, IdentityTransform);
	auto NullCompiler = [](llvm::Module &) {
	return std::unique_ptr<llvm::MemoryBuffer>(nullptr);
	};
	LegacyIRCompileLayer<decltype(TransformLayer), decltype(NullCompiler)>
	CompileLayer(TransformLayer, NullCompiler);

	// Make sure that the calls from LegacyIRCompileLayer to LegacyObjectTransformLayer
	// compile.
	cantFail(CompileLayer.addModule(ES.allocateVModule(),
	std::unique_ptr<llvm::Module>()));

	// Make sure that the calls from LegacyObjectTransformLayer to ObjectLinkingLayer
	// compile.
	VModuleKey DummyKey = ES.allocateVModule();
	cantFail(TransformLayer.emitAndFinalize(DummyKey));
	TransformLayer.findSymbolIn(DummyKey, Name, false);
	TransformLayer.findSymbol(Name, true);
	TransformLayer.mapSectionAddress(DummyKey, nullptr, 0);
	cantFail(TransformLayer.removeObject(DummyKey));
	}
	}