Files
clang-p2996/compiler-rt/lib/scudo/standalone/tests/release_test.cpp
Kostya Kortchinsky 2c56776a31 [scudo][standalone] Compact pointers for Caches/Batches
This CL introduces configuration options to allow pointers to be
compacted in the thread-specific caches and transfer batches. This
offers the possibility to have them use 32-bit of space instead of
64-bit for the 64-bit Primary, thus cutting the size of the caches
and batches by nearly half (and as such the memory used in size
class 0). The cost is an additional read from the region information
in the fast path.

This is not a new idea, as it's being used in the sanitizer_common
64-bit primary. The difference here is that it is configurable via
the allocator config, with the possibility of not compacting at all.

This CL enables compacting pointers in the Android and Fuchsia default
configurations.

Differential Revision: https://reviews.llvm.org/D96435
2021-02-25 12:14:38 -08:00

280 lines
9.3 KiB
C++

//===-- release_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 "list.h"
#include "release.h"
#include "size_class_map.h"
#include <string.h>
#include <algorithm>
#include <random>
#include <set>
TEST(ScudoReleaseTest, PackedCounterArray) {
for (scudo::uptr I = 0; I < SCUDO_WORDSIZE; I++) {
// Various valid counter's max values packed into one word.
scudo::PackedCounterArray Counters2N(1U, 1U, 1UL << I);
EXPECT_EQ(sizeof(scudo::uptr), Counters2N.getBufferSize());
// Check the "all bit set" values too.
scudo::PackedCounterArray Counters2N1_1(1U, 1U, ~0UL >> I);
EXPECT_EQ(sizeof(scudo::uptr), Counters2N1_1.getBufferSize());
// Verify the packing ratio, the counter is Expected to be packed into the
// closest power of 2 bits.
scudo::PackedCounterArray Counters(1U, SCUDO_WORDSIZE, 1UL << I);
EXPECT_EQ(sizeof(scudo::uptr) * scudo::roundUpToPowerOfTwo(I + 1),
Counters.getBufferSize());
}
// Go through 1, 2, 4, 8, .. {32,64} bits per counter.
for (scudo::uptr I = 0; (SCUDO_WORDSIZE >> I) != 0; I++) {
// Make sure counters request one memory page for the buffer.
const scudo::uptr NumCounters =
(scudo::getPageSizeCached() / 8) * (SCUDO_WORDSIZE >> I);
scudo::PackedCounterArray Counters(1U, NumCounters,
1UL << ((1UL << I) - 1));
Counters.inc(0U, 0U);
for (scudo::uptr C = 1; C < NumCounters - 1; C++) {
EXPECT_EQ(0UL, Counters.get(0U, C));
Counters.inc(0U, C);
EXPECT_EQ(1UL, Counters.get(0U, C - 1));
}
EXPECT_EQ(0UL, Counters.get(0U, NumCounters - 1));
Counters.inc(0U, NumCounters - 1);
if (I > 0) {
Counters.incRange(0u, 0U, NumCounters - 1);
for (scudo::uptr C = 0; C < NumCounters; C++)
EXPECT_EQ(2UL, Counters.get(0U, C));
}
}
}
class StringRangeRecorder {
public:
std::string ReportedPages;
StringRangeRecorder()
: PageSizeScaledLog(scudo::getLog2(scudo::getPageSizeCached())) {}
void releasePageRangeToOS(scudo::uptr From, scudo::uptr To) {
From >>= PageSizeScaledLog;
To >>= PageSizeScaledLog;
EXPECT_LT(From, To);
if (!ReportedPages.empty())
EXPECT_LT(LastPageReported, From);
ReportedPages.append(From - LastPageReported, '.');
ReportedPages.append(To - From, 'x');
LastPageReported = To;
}
private:
const scudo::uptr PageSizeScaledLog;
scudo::uptr LastPageReported = 0;
};
TEST(ScudoReleaseTest, FreePagesRangeTracker) {
// 'x' denotes a page to be released, '.' denotes a page to be kept around.
const char *TestCases[] = {
"",
".",
"x",
"........",
"xxxxxxxxxxx",
"..............xxxxx",
"xxxxxxxxxxxxxxxxxx.....",
"......xxxxxxxx........",
"xxx..........xxxxxxxxxxxxxxx",
"......xxxx....xxxx........",
"xxx..........xxxxxxxx....xxxxxxx",
"x.x.x.x.x.x.x.x.x.x.x.x.",
".x.x.x.x.x.x.x.x.x.x.x.x",
".x.x.x.x.x.x.x.x.x.x.x.x.",
"x.x.x.x.x.x.x.x.x.x.x.x.x",
};
typedef scudo::FreePagesRangeTracker<StringRangeRecorder> RangeTracker;
for (auto TestCase : TestCases) {
StringRangeRecorder Recorder;
RangeTracker Tracker(&Recorder);
for (scudo::uptr I = 0; TestCase[I] != 0; I++)
Tracker.processNextPage(TestCase[I] == 'x');
Tracker.finish();
// Strip trailing '.'-pages before comparing the results as they are not
// going to be reported to range_recorder anyway.
const char *LastX = strrchr(TestCase, 'x');
std::string Expected(TestCase,
LastX == nullptr ? 0 : (LastX - TestCase + 1));
EXPECT_STREQ(Expected.c_str(), Recorder.ReportedPages.c_str());
}
}
class ReleasedPagesRecorder {
public:
std::set<scudo::uptr> ReportedPages;
void releasePageRangeToOS(scudo::uptr From, scudo::uptr To) {
const scudo::uptr PageSize = scudo::getPageSizeCached();
for (scudo::uptr I = From; I < To; I += PageSize)
ReportedPages.insert(I);
}
scudo::uptr getBase() const { return 0; }
};
// Simplified version of a TransferBatch.
template <class SizeClassMap> struct FreeBatch {
static const scudo::u32 MaxCount = SizeClassMap::MaxNumCachedHint;
void clear() { Count = 0; }
void add(scudo::uptr P) {
DCHECK_LT(Count, MaxCount);
Batch[Count++] = P;
}
scudo::u32 getCount() const { return Count; }
scudo::uptr get(scudo::u32 I) const {
DCHECK_LE(I, Count);
return Batch[I];
}
FreeBatch *Next;
private:
scudo::u32 Count;
scudo::uptr Batch[MaxCount];
};
template <class SizeClassMap> void testReleaseFreeMemoryToOS() {
typedef FreeBatch<SizeClassMap> Batch;
const scudo::uptr PagesCount = 1024;
const scudo::uptr PageSize = scudo::getPageSizeCached();
std::mt19937 R;
scudo::u32 RandState = 42;
for (scudo::uptr I = 1; I <= SizeClassMap::LargestClassId; I++) {
const scudo::uptr BlockSize = SizeClassMap::getSizeByClassId(I);
const scudo::uptr MaxBlocks = PagesCount * PageSize / BlockSize;
// Generate the random free list.
std::vector<scudo::uptr> FreeArray;
bool InFreeRange = false;
scudo::uptr CurrentRangeEnd = 0;
for (scudo::uptr I = 0; I < MaxBlocks; I++) {
if (I == CurrentRangeEnd) {
InFreeRange = (scudo::getRandomU32(&RandState) & 1U) == 1;
CurrentRangeEnd += (scudo::getRandomU32(&RandState) & 0x7f) + 1;
}
if (InFreeRange)
FreeArray.push_back(I * BlockSize);
}
if (FreeArray.empty())
continue;
// Shuffle the array to ensure that the order is irrelevant.
std::shuffle(FreeArray.begin(), FreeArray.end(), R);
// Build the FreeList from the FreeArray.
scudo::SinglyLinkedList<Batch> FreeList;
FreeList.clear();
Batch *CurrentBatch = nullptr;
for (auto const &Block : FreeArray) {
if (!CurrentBatch) {
CurrentBatch = new Batch;
CurrentBatch->clear();
FreeList.push_back(CurrentBatch);
}
CurrentBatch->add(Block);
if (CurrentBatch->getCount() == Batch::MaxCount)
CurrentBatch = nullptr;
}
// Release the memory.
auto SkipRegion = [](UNUSED scudo::uptr RegionIndex) { return false; };
auto DecompactPtr = [](scudo::uptr P) { return P; };
ReleasedPagesRecorder Recorder;
releaseFreeMemoryToOS(FreeList, MaxBlocks * BlockSize, 1U, BlockSize,
&Recorder, DecompactPtr, SkipRegion);
// Verify that there are no released pages touched by used chunks and all
// ranges of free chunks big enough to contain the entire memory pages had
// these pages released.
scudo::uptr VerifiedReleasedPages = 0;
std::set<scudo::uptr> FreeBlocks(FreeArray.begin(), FreeArray.end());
scudo::uptr CurrentBlock = 0;
InFreeRange = false;
scudo::uptr CurrentFreeRangeStart = 0;
for (scudo::uptr I = 0; I < MaxBlocks; I++) {
const bool IsFreeBlock =
FreeBlocks.find(CurrentBlock) != FreeBlocks.end();
if (IsFreeBlock) {
if (!InFreeRange) {
InFreeRange = true;
CurrentFreeRangeStart = CurrentBlock;
}
} else {
// Verify that this used chunk does not touch any released page.
const scudo::uptr StartPage = CurrentBlock / PageSize;
const scudo::uptr EndPage = (CurrentBlock + BlockSize - 1) / PageSize;
for (scudo::uptr J = StartPage; J <= EndPage; J++) {
const bool PageReleased = Recorder.ReportedPages.find(J * PageSize) !=
Recorder.ReportedPages.end();
EXPECT_EQ(false, PageReleased);
}
if (InFreeRange) {
InFreeRange = false;
// Verify that all entire memory pages covered by this range of free
// chunks were released.
scudo::uptr P = scudo::roundUpTo(CurrentFreeRangeStart, PageSize);
while (P + PageSize <= CurrentBlock) {
const bool PageReleased =
Recorder.ReportedPages.find(P) != Recorder.ReportedPages.end();
EXPECT_EQ(true, PageReleased);
VerifiedReleasedPages++;
P += PageSize;
}
}
}
CurrentBlock += BlockSize;
}
if (InFreeRange) {
scudo::uptr P = scudo::roundUpTo(CurrentFreeRangeStart, PageSize);
const scudo::uptr EndPage =
scudo::roundUpTo(MaxBlocks * BlockSize, PageSize);
while (P + PageSize <= EndPage) {
const bool PageReleased =
Recorder.ReportedPages.find(P) != Recorder.ReportedPages.end();
EXPECT_EQ(true, PageReleased);
VerifiedReleasedPages++;
P += PageSize;
}
}
EXPECT_EQ(Recorder.ReportedPages.size(), VerifiedReleasedPages);
while (!FreeList.empty()) {
CurrentBatch = FreeList.front();
FreeList.pop_front();
delete CurrentBatch;
}
}
}
TEST(ScudoReleaseTest, ReleaseFreeMemoryToOSDefault) {
testReleaseFreeMemoryToOS<scudo::DefaultSizeClassMap>();
}
TEST(ScudoReleaseTest, ReleaseFreeMemoryToOSAndroid) {
testReleaseFreeMemoryToOS<scudo::AndroidSizeClassMap>();
}
TEST(ScudoReleaseTest, ReleaseFreeMemoryToOSSvelte) {
testReleaseFreeMemoryToOS<scudo::SvelteSizeClassMap>();
}