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llvm / scudo / 71643ae310099d24b7d9344f5a96c2d5615111ed / . / tests / primary_test.cpp
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//===-- primary_test.cpp ----------------------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "tests/scudo_unit_test.h"
#include "primary32.h"
#include "primary64.h"
#include "size_class_map.h"
#include <condition_variable>
#include <mutex>
#include <stdlib.h>
#include <thread>
#include <vector>
// Note that with small enough regions, the SizeClassAllocator64 also works on
// 32-bit architectures. It's not something we want to encourage, but we still
// should ensure the tests pass.
struct TestConfig1 {
static const scudo::uptr PrimaryRegionSizeLog = 18U;
static const scudo::s32 PrimaryMinReleaseToOsIntervalMs = INT32_MIN;
static const scudo::s32 PrimaryMaxReleaseToOsIntervalMs = INT32_MAX;
static const bool MaySupportMemoryTagging = false;
typedef scudo::uptr PrimaryCompactPtrT;
static const scudo::uptr PrimaryCompactPtrScale = 0;
static const bool PrimaryEnableRandomOffset = true;
static const scudo::uptr PrimaryMapSizeIncrement = 1UL << 18;
};
struct TestConfig2 {
#if defined(__mips__)
// Unable to allocate greater size on QEMU-user.
static const scudo::uptr PrimaryRegionSizeLog = 23U;
#else
static const scudo::uptr PrimaryRegionSizeLog = 24U;
#endif
static const scudo::s32 PrimaryMinReleaseToOsIntervalMs = INT32_MIN;
static const scudo::s32 PrimaryMaxReleaseToOsIntervalMs = INT32_MAX;
static const bool MaySupportMemoryTagging = false;
typedef scudo::uptr PrimaryCompactPtrT;
static const scudo::uptr PrimaryCompactPtrScale = 0;
static const bool PrimaryEnableRandomOffset = true;
static const scudo::uptr PrimaryMapSizeIncrement = 1UL << 18;
};
struct TestConfig3 {
#if defined(__mips__)
// Unable to allocate greater size on QEMU-user.
static const scudo::uptr PrimaryRegionSizeLog = 23U;
#else
static const scudo::uptr PrimaryRegionSizeLog = 24U;
#endif
static const scudo::s32 PrimaryMinReleaseToOsIntervalMs = INT32_MIN;
static const scudo::s32 PrimaryMaxReleaseToOsIntervalMs = INT32_MAX;
static const bool MaySupportMemoryTagging = true;
typedef scudo::uptr PrimaryCompactPtrT;
static const scudo::uptr PrimaryCompactPtrScale = 0;
static const bool PrimaryEnableRandomOffset = true;
static const scudo::uptr PrimaryMapSizeIncrement = 1UL << 18;
};
template <typename BaseConfig, typename SizeClassMapT>
struct Config : public BaseConfig {
using SizeClassMap = SizeClassMapT;
};
template <typename BaseConfig, typename SizeClassMapT>
struct SizeClassAllocator
: public scudo::SizeClassAllocator64<Config<BaseConfig, SizeClassMapT>> {};
template <typename SizeClassMapT>
struct SizeClassAllocator<TestConfig1, SizeClassMapT>
: public scudo::SizeClassAllocator32<Config<TestConfig1, SizeClassMapT>> {};
template <typename BaseConfig, typename SizeClassMapT>
struct TestAllocator : public SizeClassAllocator<BaseConfig, SizeClassMapT> {
~TestAllocator() { this->unmapTestOnly(); }
void *operator new(size_t size) {
void *p = nullptr;
EXPECT_EQ(0, posix_memalign(&p, alignof(TestAllocator), size));
return p;
}
void operator delete(void *ptr) { free(ptr); }
};
template <class BaseConfig> struct ScudoPrimaryTest : public Test {};
#if SCUDO_FUCHSIA
#define SCUDO_TYPED_TEST_ALL_TYPES(FIXTURE, NAME) \
SCUDO_TYPED_TEST_TYPE(FIXTURE, NAME, TestConfig2) \
SCUDO_TYPED_TEST_TYPE(FIXTURE, NAME, TestConfig3)
#else
#define SCUDO_TYPED_TEST_ALL_TYPES(FIXTURE, NAME) \
SCUDO_TYPED_TEST_TYPE(FIXTURE, NAME, TestConfig1) \
SCUDO_TYPED_TEST_TYPE(FIXTURE, NAME, TestConfig2) \
SCUDO_TYPED_TEST_TYPE(FIXTURE, NAME, TestConfig3)
#endif
#define SCUDO_TYPED_TEST_TYPE(FIXTURE, NAME, TYPE) \
using FIXTURE##NAME##_##TYPE = FIXTURE##NAME<TYPE>; \
TEST_F(FIXTURE##NAME##_##TYPE, NAME) { Run(); }
#define SCUDO_TYPED_TEST(FIXTURE, NAME) \
template <class TypeParam> \
struct FIXTURE##NAME : public FIXTURE<TypeParam> { \
void Run(); \
}; \
SCUDO_TYPED_TEST_ALL_TYPES(FIXTURE, NAME) \
template <class TypeParam> void FIXTURE##NAME<TypeParam>::Run()
SCUDO_TYPED_TEST(ScudoPrimaryTest, BasicPrimary) {
using Primary = TestAllocator<TypeParam, scudo::DefaultSizeClassMap>;
std::unique_ptr<Primary> Allocator(new Primary);
Allocator->init(/*ReleaseToOsInterval=*/-1);
typename Primary::CacheT Cache;
Cache.init(nullptr, Allocator.get());
const scudo::uptr NumberOfAllocations = 32U;
for (scudo::uptr I = 0; I <= 16U; I++) {
const scudo::uptr Size = 1UL << I;
if (!Primary::canAllocate(Size))
continue;
const scudo::uptr ClassId = Primary::SizeClassMap::getClassIdBySize(Size);
void *Pointers[NumberOfAllocations];
for (scudo::uptr J = 0; J < NumberOfAllocations; J++) {
void *P = Cache.allocate(ClassId);
memset(P, 'B', Size);
Pointers[J] = P;
}
for (scudo::uptr J = 0; J < NumberOfAllocations; J++)
Cache.deallocate(ClassId, Pointers[J]);
}
Cache.destroy(nullptr);
Allocator->releaseToOS();
scudo::ScopedString Str;
Allocator->getStats(&Str);
Str.output();
}
struct SmallRegionsConfig {
using SizeClassMap = scudo::DefaultSizeClassMap;
static const scudo::uptr PrimaryRegionSizeLog = 20U;
static const scudo::s32 PrimaryMinReleaseToOsIntervalMs = INT32_MIN;
static const scudo::s32 PrimaryMaxReleaseToOsIntervalMs = INT32_MAX;
static const bool MaySupportMemoryTagging = false;
typedef scudo::uptr PrimaryCompactPtrT;
static const scudo::uptr PrimaryCompactPtrScale = 0;
static const bool PrimaryEnableRandomOffset = true;
static const scudo::uptr PrimaryMapSizeIncrement = 1UL << 18;
};
// The 64-bit SizeClassAllocator can be easily OOM'd with small region sizes.
// For the 32-bit one, it requires actually exhausting memory, so we skip it.
TEST(ScudoPrimaryTest, Primary64OOM) {
using Primary = scudo::SizeClassAllocator64<SmallRegionsConfig>;
using TransferBatch = Primary::CacheT::TransferBatch;
Primary Allocator;
Allocator.init(/*ReleaseToOsInterval=*/-1);
typename Primary::CacheT Cache;
scudo::GlobalStats Stats;
Stats.init();
Cache.init(&Stats, &Allocator);
bool AllocationFailed = false;
std::vector<TransferBatch *> Batches;
const scudo::uptr ClassId = Primary::SizeClassMap::LargestClassId;
const scudo::uptr Size = Primary::getSizeByClassId(ClassId);
for (scudo::uptr I = 0; I < 10000U; I++) {
TransferBatch *B = Allocator.popBatch(&Cache, ClassId);
if (!B) {
AllocationFailed = true;
break;
}
for (scudo::u32 J = 0; J < B->getCount(); J++)
memset(Allocator.decompactPtr(ClassId, B->get(J)), 'B', Size);
Batches.push_back(B);
}
while (!Batches.empty()) {
Allocator.pushBatch(ClassId, Batches.back());
Batches.pop_back();
}
Cache.destroy(nullptr);
Allocator.releaseToOS();
scudo::ScopedString Str;
Allocator.getStats(&Str);
Str.output();
EXPECT_EQ(AllocationFailed, true);
Allocator.unmapTestOnly();
}
SCUDO_TYPED_TEST(ScudoPrimaryTest, PrimaryIterate) {
using Primary = TestAllocator<TypeParam, scudo::DefaultSizeClassMap>;
std::unique_ptr<Primary> Allocator(new Primary);
Allocator->init(/*ReleaseToOsInterval=*/-1);
typename Primary::CacheT Cache;
Cache.init(nullptr, Allocator.get());
std::vector<std::pair<scudo::uptr, void *>> V;
for (scudo::uptr I = 0; I < 64U; I++) {
const scudo::uptr Size = std::rand() % Primary::SizeClassMap::MaxSize;
const scudo::uptr ClassId = Primary::SizeClassMap::getClassIdBySize(Size);
void *P = Cache.allocate(ClassId);
V.push_back(std::make_pair(ClassId, P));
}
scudo::uptr Found = 0;
auto Lambda = [V, &Found](scudo::uptr Block) {
for (const auto &Pair : V) {
if (Pair.second == reinterpret_cast<void *>(Block))
Found++;
}
};
Allocator->disable();
Allocator->iterateOverBlocks(Lambda);
Allocator->enable();
EXPECT_EQ(Found, V.size());
while (!V.empty()) {
auto Pair = V.back();
Cache.deallocate(Pair.first, Pair.second);
V.pop_back();
}
Cache.destroy(nullptr);
Allocator->releaseToOS();
scudo::ScopedString Str;
Allocator->getStats(&Str);
Str.output();
}
SCUDO_TYPED_TEST(ScudoPrimaryTest, PrimaryThreaded) {
using Primary = TestAllocator<TypeParam, scudo::SvelteSizeClassMap>;
std::unique_ptr<Primary> Allocator(new Primary);
Allocator->init(/*ReleaseToOsInterval=*/-1);
std::mutex Mutex;
std::condition_variable Cv;
bool Ready = false;
std::thread Threads[32];
for (scudo::uptr I = 0; I < ARRAY_SIZE(Threads); I++)
Threads[I] = std::thread([&]() {
static thread_local typename Primary::CacheT Cache;
Cache.init(nullptr, Allocator.get());
std::vector<std::pair<scudo::uptr, void *>> V;
{
std::unique_lock<std::mutex> Lock(Mutex);
while (!Ready)
Cv.wait(Lock);
}
for (scudo::uptr I = 0; I < 256U; I++) {
const scudo::uptr Size =
std::rand() % Primary::SizeClassMap::MaxSize / 4;
const scudo::uptr ClassId =
Primary::SizeClassMap::getClassIdBySize(Size);
void *P = Cache.allocate(ClassId);
if (P)
V.push_back(std::make_pair(ClassId, P));
}
while (!V.empty()) {
auto Pair = V.back();
Cache.deallocate(Pair.first, Pair.second);
V.pop_back();
}
Cache.destroy(nullptr);
});
{
std::unique_lock<std::mutex> Lock(Mutex);
Ready = true;
Cv.notify_all();
}
for (auto &T : Threads)
T.join();
Allocator->releaseToOS();
scudo::ScopedString Str;
Allocator->getStats(&Str);
Str.output();
}
// Through a simple allocation that spans two pages, verify that releaseToOS
// actually releases some bytes (at least one page worth). This is a regression
// test for an error in how the release criteria were computed.
SCUDO_TYPED_TEST(ScudoPrimaryTest, ReleaseToOS) {
using Primary = TestAllocator<TypeParam, scudo::DefaultSizeClassMap>;
std::unique_ptr<Primary> Allocator(new Primary);
Allocator->init(/*ReleaseToOsInterval=*/-1);
typename Primary::CacheT Cache;
Cache.init(nullptr, Allocator.get());
const scudo::uptr Size = scudo::getPageSizeCached() * 2;
EXPECT_TRUE(Primary::canAllocate(Size));
const scudo::uptr ClassId = Primary::SizeClassMap::getClassIdBySize(Size);
void *P = Cache.allocate(ClassId);
EXPECT_NE(P, nullptr);
Cache.deallocate(ClassId, P);
Cache.destroy(nullptr);
EXPECT_GT(Allocator->releaseToOS(), 0U);
}