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llvm-6502/unittests/ExecutionEngine/MCJIT/MCJITCAPITest.cpp
Juergen Ributzka ba0f991a78 [weak vtables] Place class definitions into anonymous namespaces to prevent weak vtables. 
This patch places class definitions in implementation files into anonymous
namespaces to prevent weak vtables. This eliminates the need of providing an
out-of-line definition to pin the vtable explicitly to the file.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@195092 91177308-0d34-0410-b5e6-96231b3b80d8
2013-11-19 03:08:35 +00:00

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//===- MCJITTest.cpp - Unit tests for the MCJIT ---------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This test suite verifies basic MCJIT functionality when invoked form the C
// API.
//
//===----------------------------------------------------------------------===//
#include "llvm-c/Analysis.h"
#include "llvm-c/Core.h"
#include "llvm-c/ExecutionEngine.h"
#include "llvm-c/Target.h"
#include "llvm-c/Transforms/Scalar.h"
#include "llvm/ExecutionEngine/SectionMemoryManager.h"
#include "llvm/Support/Host.h"
#include "MCJITTestAPICommon.h"
#include "gtest/gtest.h"
using namespace llvm;
static bool didCallAllocateCodeSection;
static uint8_t *roundTripAllocateCodeSection(void *object, uintptr_t size,
unsigned alignment,
unsigned sectionID,
const char *sectionName) {
didCallAllocateCodeSection = true;
return static_cast<SectionMemoryManager*>(object)->allocateCodeSection(
size, alignment, sectionID, sectionName);
}
static uint8_t *roundTripAllocateDataSection(void *object, uintptr_t size,
unsigned alignment,
unsigned sectionID,
const char *sectionName,
LLVMBool isReadOnly) {
return static_cast<SectionMemoryManager*>(object)->allocateDataSection(
size, alignment, sectionID, sectionName, isReadOnly);
}
static LLVMBool roundTripFinalizeMemory(void *object, char **errMsg) {
std::string errMsgString;
bool result =
static_cast<SectionMemoryManager*>(object)->finalizeMemory(&errMsgString);
if (result) {
*errMsg = LLVMCreateMessage(errMsgString.c_str());
return 1;
}
return 0;
}
static void roundTripDestroy(void *object) {
delete static_cast<SectionMemoryManager*>(object);
}
namespace {
class MCJITCAPITest : public testing::Test, public MCJITTestAPICommon {
protected:
MCJITCAPITest() {
// 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::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");
// The operating systems below are known to be sufficiently incompatible
// that they will fail the MCJIT C API tests.
UnsupportedOSs.push_back(Triple::Cygwin);
}
virtual void SetUp() {
didCallAllocateCodeSection = false;
Module = 0;
Function = 0;
Engine = 0;
Error = 0;
}
virtual void TearDown() {
if (Engine)
LLVMDisposeExecutionEngine(Engine);
else if (Module)
LLVMDisposeModule(Module);
}
void buildSimpleFunction() {
Module = LLVMModuleCreateWithName("simple_module");
LLVMSetTarget(Module, HostTriple.c_str());
Function = LLVMAddFunction(
Module, "simple_function", LLVMFunctionType(LLVMInt32Type(), 0, 0, 0));
LLVMSetFunctionCallConv(Function, LLVMCCallConv);
LLVMBasicBlockRef entry = LLVMAppendBasicBlock(Function, "entry");
LLVMBuilderRef builder = LLVMCreateBuilder();
LLVMPositionBuilderAtEnd(builder, entry);
LLVMBuildRet(builder, LLVMConstInt(LLVMInt32Type(), 42, 0));
LLVMVerifyModule(Module, LLVMAbortProcessAction, &Error);
LLVMDisposeMessage(Error);
LLVMDisposeBuilder(builder);
}
void buildMCJITOptions() {
LLVMInitializeMCJITCompilerOptions(&Options, sizeof(Options));
Options.OptLevel = 2;
// Just ensure that this field still exists.
Options.NoFramePointerElim = false;
}
void useRoundTripSectionMemoryManager() {
Options.MCJMM = LLVMCreateSimpleMCJITMemoryManager(
new SectionMemoryManager(),
roundTripAllocateCodeSection,
roundTripAllocateDataSection,
roundTripFinalizeMemory,
roundTripDestroy);
}
void buildMCJITEngine() {
ASSERT_EQ(
0, LLVMCreateMCJITCompilerForModule(&Engine, Module, &Options,
sizeof(Options), &Error));
}
void buildAndRunPasses() {
LLVMPassManagerRef pass = LLVMCreatePassManager();
LLVMAddTargetData(LLVMGetExecutionEngineTargetData(Engine), pass);
LLVMAddConstantPropagationPass(pass);
LLVMAddInstructionCombiningPass(pass);
LLVMRunPassManager(pass, Module);
LLVMDisposePassManager(pass);
}
LLVMModuleRef Module;
LLVMValueRef Function;
LLVMMCJITCompilerOptions Options;
LLVMExecutionEngineRef Engine;
char *Error;
};
} // end anonymous namespace
TEST_F(MCJITCAPITest, simple_function) {
SKIP_UNSUPPORTED_PLATFORM;
buildSimpleFunction();
buildMCJITOptions();
buildMCJITEngine();
buildAndRunPasses();
union {
void *raw;
int (*usable)();
} functionPointer;
functionPointer.raw = LLVMGetPointerToGlobal(Engine, Function);
EXPECT_EQ(42, functionPointer.usable());
}
TEST_F(MCJITCAPITest, custom_memory_manager) {
SKIP_UNSUPPORTED_PLATFORM;
buildSimpleFunction();
buildMCJITOptions();
useRoundTripSectionMemoryManager();
buildMCJITEngine();
buildAndRunPasses();
union {
void *raw;
int (*usable)();
} functionPointer;
functionPointer.raw = LLVMGetPointerToGlobal(Engine, Function);
EXPECT_EQ(42, functionPointer.usable());
EXPECT_TRUE(didCallAllocateCodeSection);
}
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