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6eb43d2956
It's useful for the memory managers that are allocating a section to know what the name of the section is. At a minimum, this is useful for low-level debugging - it's customary for JITs to be able to tell you what memory they allocated, and as part of any such dump, they should be able to tell you some meta-data about what each allocation is for. This allows clients that supply their own memory managers to do this. Additionally, we also envision the SectionName being useful for passing meta-data from within LLVM to an LLVM client. This changes both the C and C++ APIs, and all of the clients of those APIs within LLVM. I'm assuming that it's safe to change the C++ API because that API is allowed to change. I'm assuming that it's safe to change the C API because we haven't shipped the API in a release yet (LLVM 3.3 doesn't include the MCJIT memory management C API). git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@191804 91177308-0d34-0410-b5e6-96231b3b80d8
304 lines
11 KiB
C++
304 lines
11 KiB
C++
//===- JITMemoryManagerTest.cpp - Unit tests for the JIT memory manager ---===//
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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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#include "llvm/ExecutionEngine/JITMemoryManager.h"
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#include "llvm/ADT/ArrayRef.h"
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#include "llvm/ADT/OwningPtr.h"
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#include "llvm/IR/DerivedTypes.h"
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#include "llvm/IR/Function.h"
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#include "llvm/IR/GlobalValue.h"
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#include "llvm/IR/LLVMContext.h"
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#include "gtest/gtest.h"
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using namespace llvm;
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namespace {
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Function *makeFakeFunction() {
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std::vector<Type*> params;
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FunctionType *FTy =
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FunctionType::get(Type::getVoidTy(getGlobalContext()), params, false);
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return Function::Create(FTy, GlobalValue::ExternalLinkage);
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}
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// Allocate three simple functions that fit in the initial slab. This exercises
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// the code in the case that we don't have to allocate more memory to store the
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// function bodies.
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TEST(JITMemoryManagerTest, NoAllocations) {
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OwningPtr<JITMemoryManager> MemMgr(
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JITMemoryManager::CreateDefaultMemManager());
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uintptr_t size;
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std::string Error;
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// Allocate the functions.
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OwningPtr<Function> F1(makeFakeFunction());
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size = 1024;
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uint8_t *FunctionBody1 = MemMgr->startFunctionBody(F1.get(), size);
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memset(FunctionBody1, 0xFF, 1024);
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MemMgr->endFunctionBody(F1.get(), FunctionBody1, FunctionBody1 + 1024);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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OwningPtr<Function> F2(makeFakeFunction());
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size = 1024;
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uint8_t *FunctionBody2 = MemMgr->startFunctionBody(F2.get(), size);
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memset(FunctionBody2, 0xFF, 1024);
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MemMgr->endFunctionBody(F2.get(), FunctionBody2, FunctionBody2 + 1024);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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OwningPtr<Function> F3(makeFakeFunction());
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size = 1024;
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uint8_t *FunctionBody3 = MemMgr->startFunctionBody(F3.get(), size);
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memset(FunctionBody3, 0xFF, 1024);
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MemMgr->endFunctionBody(F3.get(), FunctionBody3, FunctionBody3 + 1024);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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// Deallocate them out of order, in case that matters.
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MemMgr->deallocateFunctionBody(FunctionBody2);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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MemMgr->deallocateFunctionBody(FunctionBody1);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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MemMgr->deallocateFunctionBody(FunctionBody3);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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}
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// Make three large functions that take up most of the space in the slab. Then
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// try allocating three smaller functions that don't require additional slabs.
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TEST(JITMemoryManagerTest, TestCodeAllocation) {
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OwningPtr<JITMemoryManager> MemMgr(
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JITMemoryManager::CreateDefaultMemManager());
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uintptr_t size;
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std::string Error;
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// Big functions are a little less than the largest block size.
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const uintptr_t smallFuncSize = 1024;
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const uintptr_t bigFuncSize = (MemMgr->GetDefaultCodeSlabSize() -
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smallFuncSize * 2);
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// Allocate big functions
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OwningPtr<Function> F1(makeFakeFunction());
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size = bigFuncSize;
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uint8_t *FunctionBody1 = MemMgr->startFunctionBody(F1.get(), size);
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ASSERT_LE(bigFuncSize, size);
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memset(FunctionBody1, 0xFF, bigFuncSize);
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MemMgr->endFunctionBody(F1.get(), FunctionBody1, FunctionBody1 + bigFuncSize);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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OwningPtr<Function> F2(makeFakeFunction());
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size = bigFuncSize;
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uint8_t *FunctionBody2 = MemMgr->startFunctionBody(F2.get(), size);
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ASSERT_LE(bigFuncSize, size);
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memset(FunctionBody2, 0xFF, bigFuncSize);
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MemMgr->endFunctionBody(F2.get(), FunctionBody2, FunctionBody2 + bigFuncSize);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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OwningPtr<Function> F3(makeFakeFunction());
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size = bigFuncSize;
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uint8_t *FunctionBody3 = MemMgr->startFunctionBody(F3.get(), size);
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ASSERT_LE(bigFuncSize, size);
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memset(FunctionBody3, 0xFF, bigFuncSize);
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MemMgr->endFunctionBody(F3.get(), FunctionBody3, FunctionBody3 + bigFuncSize);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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// Check that each large function took it's own slab.
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EXPECT_EQ(3U, MemMgr->GetNumCodeSlabs());
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// Allocate small functions
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OwningPtr<Function> F4(makeFakeFunction());
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size = smallFuncSize;
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uint8_t *FunctionBody4 = MemMgr->startFunctionBody(F4.get(), size);
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ASSERT_LE(smallFuncSize, size);
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memset(FunctionBody4, 0xFF, smallFuncSize);
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MemMgr->endFunctionBody(F4.get(), FunctionBody4,
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FunctionBody4 + smallFuncSize);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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OwningPtr<Function> F5(makeFakeFunction());
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size = smallFuncSize;
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uint8_t *FunctionBody5 = MemMgr->startFunctionBody(F5.get(), size);
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ASSERT_LE(smallFuncSize, size);
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memset(FunctionBody5, 0xFF, smallFuncSize);
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MemMgr->endFunctionBody(F5.get(), FunctionBody5,
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FunctionBody5 + smallFuncSize);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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OwningPtr<Function> F6(makeFakeFunction());
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size = smallFuncSize;
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uint8_t *FunctionBody6 = MemMgr->startFunctionBody(F6.get(), size);
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ASSERT_LE(smallFuncSize, size);
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memset(FunctionBody6, 0xFF, smallFuncSize);
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MemMgr->endFunctionBody(F6.get(), FunctionBody6,
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FunctionBody6 + smallFuncSize);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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// Check that the small functions didn't allocate any new slabs.
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EXPECT_EQ(3U, MemMgr->GetNumCodeSlabs());
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// Deallocate them out of order, in case that matters.
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MemMgr->deallocateFunctionBody(FunctionBody2);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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MemMgr->deallocateFunctionBody(FunctionBody1);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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MemMgr->deallocateFunctionBody(FunctionBody4);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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MemMgr->deallocateFunctionBody(FunctionBody3);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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MemMgr->deallocateFunctionBody(FunctionBody5);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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MemMgr->deallocateFunctionBody(FunctionBody6);
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EXPECT_TRUE(MemMgr->CheckInvariants(Error)) << Error;
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}
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// Allocate five global ints of varying widths and alignment, and check their
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// alignment and overlap.
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TEST(JITMemoryManagerTest, TestSmallGlobalInts) {
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OwningPtr<JITMemoryManager> MemMgr(
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JITMemoryManager::CreateDefaultMemManager());
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uint8_t *a = (uint8_t *)MemMgr->allocateGlobal(8, 0);
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uint16_t *b = (uint16_t*)MemMgr->allocateGlobal(16, 2);
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uint32_t *c = (uint32_t*)MemMgr->allocateGlobal(32, 4);
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uint64_t *d = (uint64_t*)MemMgr->allocateGlobal(64, 8);
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// Check the alignment.
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EXPECT_EQ(0U, ((uintptr_t)b) & 0x1);
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EXPECT_EQ(0U, ((uintptr_t)c) & 0x3);
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EXPECT_EQ(0U, ((uintptr_t)d) & 0x7);
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// Initialize them each one at a time and make sure they don't overlap.
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*a = 0xff;
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*b = 0U;
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*c = 0U;
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*d = 0U;
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EXPECT_EQ(0xffU, *a);
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EXPECT_EQ(0U, *b);
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EXPECT_EQ(0U, *c);
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EXPECT_EQ(0U, *d);
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*a = 0U;
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*b = 0xffffU;
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EXPECT_EQ(0U, *a);
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EXPECT_EQ(0xffffU, *b);
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EXPECT_EQ(0U, *c);
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EXPECT_EQ(0U, *d);
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*b = 0U;
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*c = 0xffffffffU;
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EXPECT_EQ(0U, *a);
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EXPECT_EQ(0U, *b);
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EXPECT_EQ(0xffffffffU, *c);
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EXPECT_EQ(0U, *d);
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*c = 0U;
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*d = 0xffffffffffffffffULL;
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EXPECT_EQ(0U, *a);
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EXPECT_EQ(0U, *b);
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EXPECT_EQ(0U, *c);
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EXPECT_EQ(0xffffffffffffffffULL, *d);
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// Make sure we didn't allocate any extra slabs for this tiny amount of data.
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EXPECT_EQ(1U, MemMgr->GetNumDataSlabs());
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}
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// Allocate a small global, a big global, and a third global, and make sure we
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// only use two slabs for that.
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TEST(JITMemoryManagerTest, TestLargeGlobalArray) {
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OwningPtr<JITMemoryManager> MemMgr(
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JITMemoryManager::CreateDefaultMemManager());
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size_t Size = 4 * MemMgr->GetDefaultDataSlabSize();
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uint64_t *a = (uint64_t*)MemMgr->allocateGlobal(64, 8);
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uint8_t *g = MemMgr->allocateGlobal(Size, 8);
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uint64_t *b = (uint64_t*)MemMgr->allocateGlobal(64, 8);
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// Check the alignment.
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EXPECT_EQ(0U, ((uintptr_t)a) & 0x7);
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EXPECT_EQ(0U, ((uintptr_t)g) & 0x7);
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EXPECT_EQ(0U, ((uintptr_t)b) & 0x7);
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// Initialize them to make sure we don't segfault and make sure they don't
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// overlap.
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memset(a, 0x1, 8);
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memset(g, 0x2, Size);
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memset(b, 0x3, 8);
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EXPECT_EQ(0x0101010101010101ULL, *a);
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// Just check the edges.
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EXPECT_EQ(0x02U, g[0]);
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EXPECT_EQ(0x02U, g[Size - 1]);
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EXPECT_EQ(0x0303030303030303ULL, *b);
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// Check the number of slabs.
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EXPECT_EQ(2U, MemMgr->GetNumDataSlabs());
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}
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// Allocate lots of medium globals so that we can test moving the bump allocator
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// to a new slab.
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TEST(JITMemoryManagerTest, TestManyGlobals) {
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OwningPtr<JITMemoryManager> MemMgr(
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JITMemoryManager::CreateDefaultMemManager());
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size_t SlabSize = MemMgr->GetDefaultDataSlabSize();
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size_t Size = 128;
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int Iters = (SlabSize / Size) + 1;
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// We should start with no slabs.
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EXPECT_EQ(0U, MemMgr->GetNumDataSlabs());
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// After allocating a bunch of globals, we should have two.
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for (int I = 0; I < Iters; ++I)
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MemMgr->allocateGlobal(Size, 8);
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EXPECT_EQ(2U, MemMgr->GetNumDataSlabs());
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// And after much more, we should have three.
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for (int I = 0; I < Iters; ++I)
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MemMgr->allocateGlobal(Size, 8);
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EXPECT_EQ(3U, MemMgr->GetNumDataSlabs());
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}
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// Allocate lots of function stubs so that we can test moving the stub bump
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// allocator to a new slab.
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TEST(JITMemoryManagerTest, TestManyStubs) {
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OwningPtr<JITMemoryManager> MemMgr(
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JITMemoryManager::CreateDefaultMemManager());
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size_t SlabSize = MemMgr->GetDefaultStubSlabSize();
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size_t Size = 128;
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int Iters = (SlabSize / Size) + 1;
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// We should start with no slabs.
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EXPECT_EQ(0U, MemMgr->GetNumDataSlabs());
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// After allocating a bunch of stubs, we should have two.
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for (int I = 0; I < Iters; ++I)
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MemMgr->allocateStub(NULL, Size, 8);
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EXPECT_EQ(2U, MemMgr->GetNumStubSlabs());
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// And after much more, we should have three.
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for (int I = 0; I < Iters; ++I)
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MemMgr->allocateStub(NULL, Size, 8);
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EXPECT_EQ(3U, MemMgr->GetNumStubSlabs());
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}
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// Check section allocation and alignment
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TEST(JITMemoryManagerTest, AllocateSection) {
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OwningPtr<JITMemoryManager> MemMgr(
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JITMemoryManager::CreateDefaultMemManager());
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uint8_t *code1 = MemMgr->allocateCodeSection(256, 0, 1, StringRef());
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uint8_t *data1 = MemMgr->allocateDataSection(256, 16, 2, StringRef(), true);
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uint8_t *code2 = MemMgr->allocateCodeSection(257, 32, 3, StringRef());
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uint8_t *data2 = MemMgr->allocateDataSection(256, 64, 4, StringRef(), false);
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uint8_t *code3 = MemMgr->allocateCodeSection(258, 64, 5, StringRef());
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EXPECT_NE((uint8_t*)0, code1);
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EXPECT_NE((uint8_t*)0, code2);
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EXPECT_NE((uint8_t*)0, data1);
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EXPECT_NE((uint8_t*)0, data2);
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// Check alignment
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EXPECT_EQ((uint64_t)code1 & 0xf, 0u);
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EXPECT_EQ((uint64_t)code2 & 0x1f, 0u);
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EXPECT_EQ((uint64_t)code3 & 0x3f, 0u);
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EXPECT_EQ((uint64_t)data1 & 0xf, 0u);
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EXPECT_EQ((uint64_t)data2 & 0x3f, 0u);
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}
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}
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