v8/test/unittests/base/region-allocator-unittest.cc

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// Copyright 2018 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "src/base/region-allocator.h"
#include "test/unittests/test-utils.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace v8 {
namespace base {
using Address = RegionAllocator::Address;
using v8::internal::KB;
using v8::internal::MB;
class RegionAllocatorTest : public ::testing::TestWithParam<int> {};
TEST(RegionAllocatorTest, SimpleAllocateRegionAt) {
const size_t kPageSize = 4 * KB;
const size_t kPageCount = 16;
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(kPageSize * 153);
const Address kEnd = kBegin + kSize;
RegionAllocator ra(kBegin, kSize, kPageSize);
// Allocate the whole region.
for (Address address = kBegin; address < kEnd; address += kPageSize) {
CHECK_EQ(ra.free_size(), kEnd - address);
CHECK(ra.AllocateRegionAt(address, kPageSize));
}
// No free regions left, the allocation should fail.
CHECK_EQ(ra.free_size(), 0);
CHECK_EQ(ra.AllocateRegion(kPageSize), RegionAllocator::kAllocationFailure);
// Free one region and then the allocation should succeed.
CHECK_EQ(ra.FreeRegion(kBegin), kPageSize);
CHECK_EQ(ra.free_size(), kPageSize);
CHECK(ra.AllocateRegionAt(kBegin, kPageSize));
// Free all the pages.
for (Address address = kBegin; address < kEnd; address += kPageSize) {
CHECK_EQ(ra.FreeRegion(address), kPageSize);
}
// Check that the whole region is free and can be fully allocated.
CHECK_EQ(ra.free_size(), kSize);
CHECK_EQ(ra.AllocateRegion(kSize), kBegin);
}
TEST(RegionAllocatorTest, SimpleAllocateRegion) {
const size_t kPageSize = 4 * KB;
const size_t kPageCount = 16;
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(kPageSize * 153);
const Address kEnd = kBegin + kSize;
RegionAllocator ra(kBegin, kSize, kPageSize);
// Allocate the whole region.
for (size_t i = 0; i < kPageCount; i++) {
CHECK_EQ(ra.free_size(), kSize - kPageSize * i);
Address address = ra.AllocateRegion(kPageSize);
CHECK_NE(address, RegionAllocator::kAllocationFailure);
CHECK_EQ(address, kBegin + kPageSize * i);
}
// No free regions left, the allocation should fail.
CHECK_EQ(ra.free_size(), 0);
CHECK_EQ(ra.AllocateRegion(kPageSize), RegionAllocator::kAllocationFailure);
// Try to free one page and ensure that we are able to allocate it again.
for (Address address = kBegin; address < kEnd; address += kPageSize) {
CHECK_EQ(ra.FreeRegion(address), kPageSize);
CHECK_EQ(ra.AllocateRegion(kPageSize), address);
}
CHECK_EQ(ra.free_size(), 0);
}
TEST_P(RegionAllocatorTest, AllocateRegionRandom) {
const size_t kPageSize = 8 * KB;
const size_t kPageCountLog = 16;
const size_t kPageCount = (size_t{1} << kPageCountLog);
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(153 * MB);
const Address kEnd = kBegin + kSize;
base::RandomNumberGenerator rng(GetParam());
RegionAllocator ra(kBegin, kSize, kPageSize);
std::set<Address> allocated_pages;
// The page addresses must be randomized this number of allocated pages.
const size_t kRandomizationLimit = ra.max_load_for_randomization_ / kPageSize;
CHECK_LT(kRandomizationLimit, kPageCount);
Address last_address = kBegin;
bool saw_randomized_pages = false;
for (size_t i = 0; i < kPageCount; i++) {
Address address = ra.AllocateRegion(&rng, kPageSize);
CHECK_NE(address, RegionAllocator::kAllocationFailure);
CHECK(IsAligned(address, kPageSize));
CHECK_LE(kBegin, address);
CHECK_LT(address, kEnd);
CHECK_EQ(allocated_pages.find(address), allocated_pages.end());
allocated_pages.insert(address);
saw_randomized_pages |= (address < last_address);
last_address = address;
if (i == kRandomizationLimit) {
// We must evidence allocation randomization till this point.
// The rest of the allocations may still be randomized depending on
// the free ranges distribution, however it is not guaranteed.
CHECK(saw_randomized_pages);
}
}
// No free regions left, the allocation should fail.
CHECK_EQ(ra.free_size(), 0);
CHECK_EQ(ra.AllocateRegion(kPageSize), RegionAllocator::kAllocationFailure);
}
TEST(RegionAllocatorTest, AllocateBigRegions) {
const size_t kPageSize = 4 * KB;
const size_t kPageCountLog = 10;
const size_t kPageCount = (size_t{1} << kPageCountLog) - 1;
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(kPageSize * 153);
RegionAllocator ra(kBegin, kSize, kPageSize);
// Allocate the whole region.
for (size_t i = 0; i < kPageCountLog; i++) {
Address address = ra.AllocateRegion(kPageSize * (size_t{1} << i));
CHECK_NE(address, RegionAllocator::kAllocationFailure);
CHECK_EQ(address, kBegin + kPageSize * ((size_t{1} << i) - 1));
}
// No free regions left, the allocation should fail.
CHECK_EQ(ra.free_size(), 0);
CHECK_EQ(ra.AllocateRegion(kPageSize), RegionAllocator::kAllocationFailure);
// Try to free one page and ensure that we are able to allocate it again.
for (size_t i = 0; i < kPageCountLog; i++) {
const size_t size = kPageSize * (size_t{1} << i);
Address address = kBegin + kPageSize * ((size_t{1} << i) - 1);
CHECK_EQ(ra.FreeRegion(address), size);
CHECK_EQ(ra.AllocateRegion(size), address);
}
CHECK_EQ(ra.free_size(), 0);
}
TEST(RegionAllocatorTest, MergeLeftToRightCoalecsingRegions) {
const size_t kPageSize = 4 * KB;
const size_t kPageCountLog = 10;
const size_t kPageCount = (size_t{1} << kPageCountLog);
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(kPageSize * 153);
RegionAllocator ra(kBegin, kSize, kPageSize);
// Allocate the whole region using the following page size pattern:
// |0|1|22|3333|...
CHECK_EQ(ra.AllocateRegion(kPageSize), kBegin);
for (size_t i = 0; i < kPageCountLog; i++) {
Address address = ra.AllocateRegion(kPageSize * (size_t{1} << i));
CHECK_NE(address, RegionAllocator::kAllocationFailure);
CHECK_EQ(address, kBegin + kPageSize * (size_t{1} << i));
}
// No free regions left, the allocation should fail.
CHECK_EQ(ra.free_size(), 0);
CHECK_EQ(ra.AllocateRegion(kPageSize), RegionAllocator::kAllocationFailure);
// Try to free two coalescing regions and ensure the new page of bigger size
// can be allocated.
size_t current_size = kPageSize;
for (size_t i = 0; i < kPageCountLog; i++) {
CHECK_EQ(ra.FreeRegion(kBegin), current_size);
CHECK_EQ(ra.FreeRegion(kBegin + current_size), current_size);
current_size += current_size;
CHECK_EQ(ra.AllocateRegion(current_size), kBegin);
}
CHECK_EQ(ra.free_size(), 0);
}
TEST_P(RegionAllocatorTest, MergeRightToLeftCoalecsingRegions) {
base::RandomNumberGenerator rng(GetParam());
const size_t kPageSize = 4 * KB;
const size_t kPageCountLog = 10;
const size_t kPageCount = (size_t{1} << kPageCountLog);
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(kPageSize * 153);
RegionAllocator ra(kBegin, kSize, kPageSize);
// Allocate the whole region.
for (size_t i = 0; i < kPageCount; i++) {
Address address = ra.AllocateRegion(kPageSize);
CHECK_NE(address, RegionAllocator::kAllocationFailure);
CHECK_EQ(address, kBegin + kPageSize * i);
}
// No free regions left, the allocation should fail.
CHECK_EQ(ra.free_size(), 0);
CHECK_EQ(ra.AllocateRegion(kPageSize), RegionAllocator::kAllocationFailure);
// Free pages with even indices left-to-right.
for (size_t i = 0; i < kPageCount; i += 2) {
Address address = kBegin + kPageSize * i;
CHECK_EQ(ra.FreeRegion(address), kPageSize);
}
// Free pages with odd indices right-to-left.
for (size_t i = 1; i < kPageCount; i += 2) {
Address address = kBegin + kPageSize * (kPageCount - i);
CHECK_EQ(ra.FreeRegion(address), kPageSize);
// Now we should be able to allocate a double-sized page.
CHECK_EQ(ra.AllocateRegion(kPageSize * 2), address - kPageSize);
// .. but there's a window for only one such page.
CHECK_EQ(ra.AllocateRegion(kPageSize * 2),
RegionAllocator::kAllocationFailure);
}
// Free all the double-sized pages.
for (size_t i = 0; i < kPageCount; i += 2) {
Address address = kBegin + kPageSize * i;
CHECK_EQ(ra.FreeRegion(address), kPageSize * 2);
}
// Check that the whole region is free and can be fully allocated.
CHECK_EQ(ra.free_size(), kSize);
CHECK_EQ(ra.AllocateRegion(kSize), kBegin);
}
TEST(RegionAllocatorTest, Fragmentation) {
const size_t kPageSize = 64 * KB;
const size_t kPageCount = 9;
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(kPageSize * 153);
RegionAllocator ra(kBegin, kSize, kPageSize);
// Allocate the whole region.
for (size_t i = 0; i < kPageCount; i++) {
Address address = ra.AllocateRegion(kPageSize);
CHECK_NE(address, RegionAllocator::kAllocationFailure);
CHECK_EQ(address, kBegin + kPageSize * i);
}
// No free regions left, the allocation should fail.
CHECK_EQ(ra.free_size(), 0);
CHECK_EQ(ra.AllocateRegion(kPageSize), RegionAllocator::kAllocationFailure);
// Free pages in the following order and check the freed size.
struct {
size_t page_index_to_free;
size_t expected_page_count;
} testcase[] = { // .........
{0, 9}, // x........
{2, 9}, // x.x......
{4, 9}, // x.x.x....
{6, 9}, // x.x.x.x..
{8, 9}, // x.x.x.x.x
{1, 7}, // xxx.x.x.x
{7, 5}, // xxx.x.xxx
{3, 3}, // xxxxx.xxx
{5, 1}}; // xxxxxxxxx
CHECK_EQ(kPageCount, arraysize(testcase));
CHECK_EQ(ra.all_regions_.size(), kPageCount);
for (size_t i = 0; i < kPageCount; i++) {
Address address = kBegin + kPageSize * testcase[i].page_index_to_free;
CHECK_EQ(ra.FreeRegion(address), kPageSize);
CHECK_EQ(ra.all_regions_.size(), testcase[i].expected_page_count);
}
// Check that the whole region is free and can be fully allocated.
CHECK_EQ(ra.free_size(), kSize);
CHECK_EQ(ra.AllocateRegion(kSize), kBegin);
}
TEST(RegionAllocatorTest, FindRegion) {
const size_t kPageSize = 4 * KB;
const size_t kPageCount = 16;
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(kPageSize * 153);
const Address kEnd = kBegin + kSize;
RegionAllocator ra(kBegin, kSize, kPageSize);
// Allocate the whole region.
for (Address address = kBegin; address < kEnd; address += kPageSize) {
CHECK_EQ(ra.free_size(), kEnd - address);
CHECK(ra.AllocateRegionAt(address, kPageSize));
}
// No free regions left, the allocation should fail.
CHECK_EQ(ra.free_size(), 0);
CHECK_EQ(ra.AllocateRegion(kPageSize), RegionAllocator::kAllocationFailure);
// The out-of region requests must return end iterator.
CHECK_EQ(ra.FindRegion(kBegin - 1), ra.all_regions_.end());
CHECK_EQ(ra.FindRegion(kBegin - kPageSize), ra.all_regions_.end());
CHECK_EQ(ra.FindRegion(kBegin / 2), ra.all_regions_.end());
CHECK_EQ(ra.FindRegion(kEnd), ra.all_regions_.end());
CHECK_EQ(ra.FindRegion(kEnd + kPageSize), ra.all_regions_.end());
CHECK_EQ(ra.FindRegion(kEnd * 2), ra.all_regions_.end());
for (Address address = kBegin; address < kEnd; address += kPageSize / 4) {
RegionAllocator::AllRegionsSet::iterator region_iter =
ra.FindRegion(address);
CHECK_NE(region_iter, ra.all_regions_.end());
RegionAllocator::Region* region = *region_iter;
Address region_start = RoundDown(address, kPageSize);
CHECK_EQ(region->begin(), region_start);
CHECK_LE(region->begin(), address);
CHECK_LT(address, region->end());
}
}
TEST(RegionAllocatorTest, TrimRegion) {
const size_t kPageSize = 4 * KB;
const size_t kPageCount = 64;
const size_t kSize = kPageSize * kPageCount;
const Address kBegin = static_cast<Address>(kPageSize * 153);
RegionAllocator ra(kBegin, kSize, kPageSize);
Address address = kBegin + 13 * kPageSize;
size_t size = 37 * kPageSize;
size_t free_size = kSize - size;
CHECK(ra.AllocateRegionAt(address, size));
size_t trim_size = kPageSize;
do {
CHECK_EQ(ra.CheckRegion(address), size);
CHECK_EQ(ra.free_size(), free_size);
trim_size = std::min(size, trim_size);
size -= trim_size;
free_size += trim_size;
CHECK_EQ(ra.TrimRegion(address, size), trim_size);
trim_size *= 2;
} while (size != 0);
// Check that the whole region is free and can be fully allocated.
CHECK_EQ(ra.free_size(), kSize);
CHECK_EQ(ra.AllocateRegion(kSize), kBegin);
}
} // namespace base
} // namespace v8