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llvm-6502/unittests/ExecutionEngine/MCJIT/MCJITObjectCacheTest.cpp
David Blaikie 453f4f0130 Use only explicit bool conversion operators 
BitVector/SmallBitVector::reference::operator bool remain implicit since
they model more exactly a bool, rather than something else that can be
boolean tested.

The most common (non-buggy) case are where such objects are used as
return expressions in bool-returning functions or as boolean function
arguments. In those cases I've used (& added if necessary) a named
function to provide the equivalent (or sometimes negative, depending on
convenient wording) test.

One behavior change (YAMLParser) was made, though no test case is
included as I'm not sure how to reach that code path. Essentially any
comparison of llvm::yaml::document_iterators would be invalid if neither
iterator was at the end.

This helped uncover a couple of bugs in Clang - test cases provided for
those in a separate commit along with similar changes to `operator bool`
instances in Clang.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@181868 91177308-0d34-0410-b5e6-96231b3b80d8
2013-05-15 07:36:59 +00:00

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//===- MCJITObjectCacheTest.cpp - Unit tests for MCJIT object caching -----===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/ADT/OwningPtr.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/StringSet.h"
#include "llvm/ExecutionEngine/JIT.h"
#include "llvm/ExecutionEngine/MCJIT.h"
#include "llvm/ExecutionEngine/ObjectCache.h"
#include "llvm/ExecutionEngine/SectionMemoryManager.h"
#include "MCJITTestBase.h"
#include "gtest/gtest.h"
using namespace llvm;
namespace {
class TestObjectCache : public ObjectCache {
public:
TestObjectCache() : DuplicateInserted(false) { }
virtual ~TestObjectCache() {
// Free any buffers we've allocated.
SmallVector<MemoryBuffer *, 2>::iterator it, end;
end = AllocatedBuffers.end();
for (it = AllocatedBuffers.begin(); it != end; ++it) {
delete *it;
}
AllocatedBuffers.clear();
}
virtual void notifyObjectCompiled(const Module *M, const MemoryBuffer *Obj) {
// If we've seen this module before, note that.
const std::string ModuleID = M->getModuleIdentifier();
if (ObjMap.find(ModuleID) != ObjMap.end())
DuplicateInserted = true;
// Store a copy of the buffer in our map.
ObjMap[ModuleID] = copyBuffer(Obj);
}
// Test-harness-specific functions
bool wereDuplicatesInserted() { return DuplicateInserted; }
bool wasModuleLookedUp(const Module *M) {
return ModulesLookedUp.find(M->getModuleIdentifier())
!= ModulesLookedUp.end();
}
const MemoryBuffer* getObjectInternal(const Module* M) {
// Look for the module in our map.
const std::string ModuleID = M->getModuleIdentifier();
StringMap<const MemoryBuffer *>::iterator it = ObjMap.find(ModuleID);
if (it == ObjMap.end())
return 0;
return it->second;
}
protected:
virtual const MemoryBuffer* getObject(const Module* M) {
const MemoryBuffer* BufferFound = getObjectInternal(M);
ModulesLookedUp.insert(M->getModuleIdentifier());
return BufferFound;
}
private:
MemoryBuffer *copyBuffer(const MemoryBuffer *Buf) {
// Create a local copy of the buffer.
MemoryBuffer *NewBuffer = MemoryBuffer::getMemBufferCopy(Buf->getBuffer());
AllocatedBuffers.push_back(NewBuffer);
return NewBuffer;
}
StringMap<const MemoryBuffer *> ObjMap;
StringSet<> ModulesLookedUp;
SmallVector<MemoryBuffer *, 2> AllocatedBuffers;
bool DuplicateInserted;
};
class MCJITObjectCacheTest : public testing::Test, public MCJITTestBase {
protected:
enum {
OriginalRC = 6,
ReplacementRC = 7
};
virtual void SetUp() {
M.reset(createEmptyModule("<main>"));
Main = insertMainFunction(M.get(), OriginalRC);
}
void compileAndRun(int ExpectedRC = OriginalRC) {
// This function shouldn't be called until after SetUp.
ASSERT_TRUE(TheJIT.isValid());
ASSERT_TRUE(0 != Main);
TheJIT->finalizeObject();
void *vPtr = TheJIT->getPointerToFunction(Main);
static_cast<SectionMemoryManager*>(MM)->invalidateInstructionCache();
EXPECT_TRUE(0 != vPtr)
<< "Unable to get pointer to main() from JIT";
int (*FuncPtr)(void) = (int(*)(void))(intptr_t)vPtr;
int returnCode = FuncPtr();
EXPECT_EQ(returnCode, ExpectedRC);
}
Function *Main;
};
TEST_F(MCJITObjectCacheTest, SetNullObjectCache) {
SKIP_UNSUPPORTED_PLATFORM;
createJIT(M.take());
TheJIT->setObjectCache(NULL);
compileAndRun();
}
TEST_F(MCJITObjectCacheTest, VerifyBasicObjectCaching) {
SKIP_UNSUPPORTED_PLATFORM;
OwningPtr<TestObjectCache> Cache(new TestObjectCache);
// Save a copy of the module pointer before handing it off to MCJIT.
const Module * SavedModulePointer = M.get();
createJIT(M.take());
TheJIT->setObjectCache(Cache.get());
// Verify that our object cache does not contain the module yet.
const MemoryBuffer *ObjBuffer = Cache->getObjectInternal(SavedModulePointer);
EXPECT_EQ(0, ObjBuffer);
compileAndRun();
// Verify that MCJIT tried to look-up this module in the cache.
EXPECT_TRUE(Cache->wasModuleLookedUp(SavedModulePointer));
// Verify that our object cache now contains the module.
ObjBuffer = Cache->getObjectInternal(SavedModulePointer);
EXPECT_TRUE(0 != ObjBuffer);
// Verify that the cache was only notified once.
EXPECT_FALSE(Cache->wereDuplicatesInserted());
}
TEST_F(MCJITObjectCacheTest, VerifyLoadFromCache) {
SKIP_UNSUPPORTED_PLATFORM;
OwningPtr<TestObjectCache> Cache(new TestObjectCache);
// Compile this module with an MCJIT engine
createJIT(M.take());
TheJIT->setObjectCache(Cache.get());
TheJIT->finalizeObject();
// Destroy the MCJIT engine we just used
TheJIT.reset();
// Create a new memory manager.
MM = new SectionMemoryManager;
// Create a new module and save it. Use a different return code so we can
// tell if MCJIT compiled this module or used the cache.
M.reset(createEmptyModule("<main>"));
Main = insertMainFunction(M.get(), ReplacementRC);
const Module * SecondModulePointer = M.get();
// Create a new MCJIT instance to load this module then execute it.
createJIT(M.take());
TheJIT->setObjectCache(Cache.get());
compileAndRun();
// Verify that MCJIT tried to look-up this module in the cache.
EXPECT_TRUE(Cache->wasModuleLookedUp(SecondModulePointer));
// Verify that MCJIT didn't try to cache this again.
EXPECT_FALSE(Cache->wereDuplicatesInserted());
}
TEST_F(MCJITObjectCacheTest, VerifyNonLoadFromCache) {
SKIP_UNSUPPORTED_PLATFORM;
OwningPtr<TestObjectCache> Cache(new TestObjectCache);
// Compile this module with an MCJIT engine
createJIT(M.take());
TheJIT->setObjectCache(Cache.get());
TheJIT->finalizeObject();
// Destroy the MCJIT engine we just used
TheJIT.reset();
// Create a new memory manager.
MM = new SectionMemoryManager;
// Create a new module and save it. Use a different return code so we can
// tell if MCJIT compiled this module or used the cache. Note that we use
// a new module name here so the module shouldn't be found in the cache.
M.reset(createEmptyModule("<not-main>"));
Main = insertMainFunction(M.get(), ReplacementRC);
const Module * SecondModulePointer = M.get();
// Create a new MCJIT instance to load this module then execute it.
createJIT(M.take());
TheJIT->setObjectCache(Cache.get());
// Verify that our object cache does not contain the module yet.
const MemoryBuffer *ObjBuffer = Cache->getObjectInternal(SecondModulePointer);
EXPECT_EQ(0, ObjBuffer);
// Run the function and look for the replacement return code.
compileAndRun(ReplacementRC);
// Verify that MCJIT tried to look-up this module in the cache.
EXPECT_TRUE(Cache->wasModuleLookedUp(SecondModulePointer));
// Verify that our object cache now contains the module.
ObjBuffer = Cache->getObjectInternal(SecondModulePointer);
EXPECT_TRUE(0 != ObjBuffer);
// Verify that MCJIT didn't try to cache this again.
EXPECT_FALSE(Cache->wereDuplicatesInserted());
}
} // Namespace
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