llvm-project/compiler-rt/lib/asan/asan_allocator.cc

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//===-- asan_allocator.cc -------------------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file is a part of AddressSanitizer, an address sanity checker.
//
// Implementation of ASan's memory allocator.
// Evey piece of memory (AsanChunk) allocated by the allocator
// has a left redzone of REDZONE bytes and
// a right redzone such that the end of the chunk is aligned by REDZONE
// (i.e. the right redzone is between 0 and REDZONE-1).
// The left redzone is always poisoned.
// The right redzone is poisoned on malloc, the body is poisoned on free.
// Once freed, a chunk is moved to a quarantine (fifo list).
// After quarantine, a chunk is returned to freelists.
//
// The left redzone contains ASan's internal data and the stack trace of
// the malloc call.
// Once freed, the body of the chunk contains the stack trace of the free call.
//
//===----------------------------------------------------------------------===//
#include "asan_allocator.h"
#if ASAN_ALLOCATOR_VERSION == 1
#include "asan_interceptors.h"
#include "asan_internal.h"
#include "asan_lock.h"
#include "asan_mapping.h"
#include "asan_stats.h"
#include "asan_report.h"
#include "asan_thread.h"
#include "asan_thread_registry.h"
#include "sanitizer/asan_interface.h"
#include "sanitizer_common/sanitizer_atomic.h"
namespace __asan {
#define REDZONE ((uptr)(flags()->redzone))
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static const uptr kMinAllocSize = REDZONE * 2;
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static const u64 kMaxAvailableRam = 128ULL << 30; // 128G
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static const uptr kMaxThreadLocalQuarantine = 1 << 20; // 1M
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static const uptr kMinMmapSize = (ASAN_LOW_MEMORY) ? 4UL << 17 : 4UL << 20;
static const uptr kMaxSizeForThreadLocalFreeList =
(ASAN_LOW_MEMORY) ? 1 << 15 : 1 << 17;
// Size classes less than kMallocSizeClassStep are powers of two.
// All other size classes are multiples of kMallocSizeClassStep.
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static const uptr kMallocSizeClassStepLog = 26;
static const uptr kMallocSizeClassStep = 1UL << kMallocSizeClassStepLog;
static const uptr kMaxAllowedMallocSize =
(SANITIZER_WORDSIZE == 32) ? 3UL << 30 : 8UL << 30;
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static inline uptr SizeClassToSize(u8 size_class) {
CHECK(size_class < kNumberOfSizeClasses);
if (size_class <= kMallocSizeClassStepLog) {
return 1UL << size_class;
} else {
return (size_class - kMallocSizeClassStepLog) * kMallocSizeClassStep;
}
}
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static inline u8 SizeToSizeClass(uptr size) {
u8 res = 0;
if (size <= kMallocSizeClassStep) {
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uptr rounded = RoundUpToPowerOfTwo(size);
res = Log2(rounded);
} else {
res = ((size + kMallocSizeClassStep - 1) / kMallocSizeClassStep)
+ kMallocSizeClassStepLog;
}
CHECK(res < kNumberOfSizeClasses);
CHECK(size <= SizeClassToSize(res));
return res;
}
// Given REDZONE bytes, we need to mark first size bytes
// as addressable and the rest REDZONE-size bytes as unaddressable.
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static void PoisonHeapPartialRightRedzone(uptr mem, uptr size) {
CHECK(size <= REDZONE);
CHECK(IsAligned(mem, REDZONE));
CHECK(IsPowerOfTwo(SHADOW_GRANULARITY));
CHECK(IsPowerOfTwo(REDZONE));
CHECK(REDZONE >= SHADOW_GRANULARITY);
PoisonShadowPartialRightRedzone(mem, size, REDZONE,
kAsanHeapRightRedzoneMagic);
}
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static u8 *MmapNewPagesAndPoisonShadow(uptr size) {
CHECK(IsAligned(size, GetPageSizeCached()));
u8 *res = (u8*)MmapOrDie(size, __FUNCTION__);
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PoisonShadow((uptr)res, size, kAsanHeapLeftRedzoneMagic);
if (flags()->debug) {
Printf("ASAN_MMAP: [%p, %p)\n", res, res + size);
}
return res;
}
// Every chunk of memory allocated by this allocator can be in one of 3 states:
// CHUNK_AVAILABLE: the chunk is in the free list and ready to be allocated.
// CHUNK_ALLOCATED: the chunk is allocated and not yet freed.
// CHUNK_QUARANTINE: the chunk was freed and put into quarantine zone.
//
// The pseudo state CHUNK_MEMALIGN is used to mark that the address is not
// the beginning of a AsanChunk (in which the actual chunk resides at
// this - this->used_size).
//
// The magic numbers for the enum values are taken randomly.
enum {
CHUNK_AVAILABLE = 0x57,
CHUNK_ALLOCATED = 0x32,
CHUNK_QUARANTINE = 0x19,
CHUNK_MEMALIGN = 0xDC
};
struct ChunkBase {
// First 8 bytes.
uptr chunk_state : 8;
uptr alloc_tid : 24;
uptr size_class : 8;
uptr free_tid : 24;
// Second 8 bytes.
uptr alignment_log : 8;
uptr alloc_type : 2;
uptr used_size : FIRST_32_SECOND_64(32, 54); // Size requested by the user.
// This field may overlap with the user area and thus should not
// be used while the chunk is in CHUNK_ALLOCATED state.
AsanChunk *next;
// Typically the beginning of the user-accessible memory is 'this'+REDZONE
// and is also aligned by REDZONE. However, if the memory is allocated
// by memalign, the alignment might be higher and the user-accessible memory
// starts at the first properly aligned address after 'this'.
uptr Beg() { return RoundUpTo((uptr)this + 1, 1 << alignment_log); }
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uptr Size() { return SizeClassToSize(size_class); }
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u8 SizeClass() { return size_class; }
};
struct AsanChunk: public ChunkBase {
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u32 *compressed_alloc_stack() {
return (u32*)((uptr)this + sizeof(ChunkBase));
}
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u32 *compressed_free_stack() {
return (u32*)((uptr)this + Max((uptr)REDZONE, (uptr)sizeof(ChunkBase)));
}
// The left redzone after the ChunkBase is given to the alloc stack trace.
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uptr compressed_alloc_stack_size() {
if (REDZONE < sizeof(ChunkBase)) return 0;
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return (REDZONE - sizeof(ChunkBase)) / sizeof(u32);
}
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uptr compressed_free_stack_size() {
if (REDZONE < sizeof(ChunkBase)) return 0;
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return (REDZONE) / sizeof(u32);
}
};
uptr AsanChunkView::Beg() { return chunk_->Beg(); }
uptr AsanChunkView::End() { return Beg() + UsedSize(); }
uptr AsanChunkView::UsedSize() { return chunk_->used_size; }
uptr AsanChunkView::AllocTid() { return chunk_->alloc_tid; }
uptr AsanChunkView::FreeTid() { return chunk_->free_tid; }
void AsanChunkView::GetAllocStack(StackTrace *stack) {
StackTrace::UncompressStack(stack, chunk_->compressed_alloc_stack(),
chunk_->compressed_alloc_stack_size());
}
void AsanChunkView::GetFreeStack(StackTrace *stack) {
StackTrace::UncompressStack(stack, chunk_->compressed_free_stack(),
chunk_->compressed_free_stack_size());
}
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static AsanChunk *PtrToChunk(uptr ptr) {
AsanChunk *m = (AsanChunk*)(ptr - REDZONE);
if (m->chunk_state == CHUNK_MEMALIGN) {
m = (AsanChunk*)((uptr)m - m->used_size);
}
return m;
}
void AsanChunkFifoList::PushList(AsanChunkFifoList *q) {
CHECK(q->size() > 0);
size_ += q->size();
append_back(q);
q->clear();
}
void AsanChunkFifoList::Push(AsanChunk *n) {
push_back(n);
size_ += n->Size();
}
// Interesting performance observation: this function takes up to 15% of overal
// allocator time. That's because *first_ has been evicted from cache long time
// ago. Not sure if we can or want to do anything with this.
AsanChunk *AsanChunkFifoList::Pop() {
CHECK(first_);
AsanChunk *res = front();
size_ -= res->Size();
pop_front();
return res;
}
// All pages we ever allocated.
struct PageGroup {
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uptr beg;
uptr end;
uptr size_of_chunk;
uptr last_chunk;
bool InRange(uptr addr) {
return addr >= beg && addr < end;
}
};
class MallocInfo {
public:
explicit MallocInfo(LinkerInitialized x) : mu_(x) { }
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AsanChunk *AllocateChunks(u8 size_class, uptr n_chunks) {
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AsanChunk *m = 0;
AsanChunk **fl = &free_lists_[size_class];
{
ScopedLock lock(&mu_);
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for (uptr i = 0; i < n_chunks; i++) {
if (!(*fl)) {
*fl = GetNewChunks(size_class);
}
AsanChunk *t = *fl;
*fl = t->next;
t->next = m;
CHECK(t->chunk_state == CHUNK_AVAILABLE);
m = t;
}
}
return m;
}
void SwallowThreadLocalMallocStorage(AsanThreadLocalMallocStorage *x,
bool eat_free_lists) {
CHECK(flags()->quarantine_size > 0);
ScopedLock lock(&mu_);
AsanChunkFifoList *q = &x->quarantine_;
if (q->size() > 0) {
quarantine_.PushList(q);
while (quarantine_.size() > (uptr)flags()->quarantine_size) {
QuarantinePop();
}
}
if (eat_free_lists) {
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for (uptr size_class = 0; size_class < kNumberOfSizeClasses;
size_class++) {
AsanChunk *m = x->free_lists_[size_class];
while (m) {
AsanChunk *t = m->next;
m->next = free_lists_[size_class];
free_lists_[size_class] = m;
m = t;
}
x->free_lists_[size_class] = 0;
}
}
}
void BypassThreadLocalQuarantine(AsanChunk *chunk) {
ScopedLock lock(&mu_);
quarantine_.Push(chunk);
}
AsanChunk *FindChunkByAddr(uptr addr) {
ScopedLock lock(&mu_);
return FindChunkByAddrUnlocked(addr);
}
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uptr AllocationSize(uptr ptr) {
if (!ptr) return 0;
ScopedLock lock(&mu_);
// Make sure this is our chunk and |ptr| actually points to the beginning
// of the allocated memory.
AsanChunk *m = FindChunkByAddrUnlocked(ptr);
if (!m || m->Beg() != ptr) return 0;
if (m->chunk_state == CHUNK_ALLOCATED) {
return m->used_size;
} else {
return 0;
}
}
void ForceLock() {
mu_.Lock();
}
void ForceUnlock() {
mu_.Unlock();
}
void PrintStatus() {
ScopedLock lock(&mu_);
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uptr malloced = 0;
Printf(" MallocInfo: in quarantine: %zu malloced: %zu; ",
quarantine_.size() >> 20, malloced >> 20);
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for (uptr j = 1; j < kNumberOfSizeClasses; j++) {
AsanChunk *i = free_lists_[j];
if (!i) continue;
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uptr t = 0;
for (; i; i = i->next) {
t += i->Size();
}
Printf("%zu:%zu ", j, t >> 20);
}
Printf("\n");
}
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PageGroup *FindPageGroup(uptr addr) {
ScopedLock lock(&mu_);
return FindPageGroupUnlocked(addr);
}
private:
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PageGroup *FindPageGroupUnlocked(uptr addr) {
int n = atomic_load(&n_page_groups_, memory_order_relaxed);
// If the page groups are not sorted yet, sort them.
if (n_sorted_page_groups_ < n) {
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SortArray((uptr*)page_groups_, n);
n_sorted_page_groups_ = n;
}
// Binary search over the page groups.
int beg = 0, end = n;
while (beg < end) {
int med = (beg + end) / 2;
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uptr g = (uptr)page_groups_[med];
if (addr > g) {
// 'g' points to the end of the group, so 'addr'
// may not belong to page_groups_[med] or any previous group.
beg = med + 1;
} else {
// 'addr' may belong to page_groups_[med] or a previous group.
end = med;
}
}
if (beg >= n)
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return 0;
PageGroup *g = page_groups_[beg];
CHECK(g);
if (g->InRange(addr))
return g;
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return 0;
}
// We have an address between two chunks, and we want to report just one.
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AsanChunk *ChooseChunk(uptr addr,
AsanChunk *left_chunk, AsanChunk *right_chunk) {
// Prefer an allocated chunk or a chunk from quarantine.
if (left_chunk->chunk_state == CHUNK_AVAILABLE &&
right_chunk->chunk_state != CHUNK_AVAILABLE)
return right_chunk;
if (right_chunk->chunk_state == CHUNK_AVAILABLE &&
left_chunk->chunk_state != CHUNK_AVAILABLE)
return left_chunk;
// Choose based on offset.
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uptr l_offset = 0, r_offset = 0;
CHECK(AsanChunkView(left_chunk).AddrIsAtRight(addr, 1, &l_offset));
CHECK(AsanChunkView(right_chunk).AddrIsAtLeft(addr, 1, &r_offset));
if (l_offset < r_offset)
return left_chunk;
return right_chunk;
}
AsanChunk *FindChunkByAddrUnlocked(uptr addr) {
PageGroup *g = FindPageGroupUnlocked(addr);
if (!g) return 0;
CHECK(g->size_of_chunk);
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uptr offset_from_beg = addr - g->beg;
uptr this_chunk_addr = g->beg +
(offset_from_beg / g->size_of_chunk) * g->size_of_chunk;
CHECK(g->InRange(this_chunk_addr));
AsanChunk *m = (AsanChunk*)this_chunk_addr;
CHECK(m->chunk_state == CHUNK_ALLOCATED ||
m->chunk_state == CHUNK_AVAILABLE ||
m->chunk_state == CHUNK_QUARANTINE);
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uptr offset = 0;
AsanChunkView m_view(m);
if (m_view.AddrIsInside(addr, 1, &offset))
return m;
if (m_view.AddrIsAtRight(addr, 1, &offset)) {
if (this_chunk_addr == g->last_chunk) // rightmost chunk
return m;
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uptr right_chunk_addr = this_chunk_addr + g->size_of_chunk;
CHECK(g->InRange(right_chunk_addr));
return ChooseChunk(addr, m, (AsanChunk*)right_chunk_addr);
} else {
CHECK(m_view.AddrIsAtLeft(addr, 1, &offset));
if (this_chunk_addr == g->beg) // leftmost chunk
return m;
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uptr left_chunk_addr = this_chunk_addr - g->size_of_chunk;
CHECK(g->InRange(left_chunk_addr));
return ChooseChunk(addr, (AsanChunk*)left_chunk_addr, m);
}
}
void QuarantinePop() {
CHECK(quarantine_.size() > 0);
AsanChunk *m = quarantine_.Pop();
CHECK(m);
// if (F_v >= 2) Printf("MallocInfo::pop %p\n", m);
CHECK(m->chunk_state == CHUNK_QUARANTINE);
m->chunk_state = CHUNK_AVAILABLE;
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PoisonShadow((uptr)m, m->Size(), kAsanHeapLeftRedzoneMagic);
CHECK(m->alloc_tid >= 0);
CHECK(m->free_tid >= 0);
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uptr size_class = m->SizeClass();
m->next = free_lists_[size_class];
free_lists_[size_class] = m;
// Statistics.
AsanStats &thread_stats = asanThreadRegistry().GetCurrentThreadStats();
thread_stats.real_frees++;
thread_stats.really_freed += m->used_size;
thread_stats.really_freed_redzones += m->Size() - m->used_size;
thread_stats.really_freed_by_size[m->SizeClass()]++;
}
// Get a list of newly allocated chunks.
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AsanChunk *GetNewChunks(u8 size_class) {
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uptr size = SizeClassToSize(size_class);
CHECK(IsPowerOfTwo(kMinMmapSize));
CHECK(size < kMinMmapSize || (size % kMinMmapSize) == 0);
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uptr mmap_size = Max(size, kMinMmapSize);
uptr n_chunks = mmap_size / size;
CHECK(n_chunks * size == mmap_size);
uptr PageSize = GetPageSizeCached();
if (size < PageSize) {
// Size is small, just poison the last chunk.
n_chunks--;
} else {
// Size is large, allocate an extra page at right and poison it.
mmap_size += PageSize;
}
CHECK(n_chunks > 0);
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u8 *mem = MmapNewPagesAndPoisonShadow(mmap_size);
// Statistics.
AsanStats &thread_stats = asanThreadRegistry().GetCurrentThreadStats();
thread_stats.mmaps++;
thread_stats.mmaped += mmap_size;
thread_stats.mmaped_by_size[size_class] += n_chunks;
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AsanChunk *res = 0;
for (uptr i = 0; i < n_chunks; i++) {
AsanChunk *m = (AsanChunk*)(mem + i * size);
m->chunk_state = CHUNK_AVAILABLE;
m->size_class = size_class;
m->next = res;
res = m;
}
PageGroup *pg = (PageGroup*)(mem + n_chunks * size);
// This memory is already poisoned, no need to poison it again.
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pg->beg = (uptr)mem;
pg->end = pg->beg + mmap_size;
pg->size_of_chunk = size;
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pg->last_chunk = (uptr)(mem + size * (n_chunks - 1));
int idx = atomic_fetch_add(&n_page_groups_, 1, memory_order_relaxed);
CHECK(idx < (int)ARRAY_SIZE(page_groups_));
page_groups_[idx] = pg;
return res;
}
AsanChunk *free_lists_[kNumberOfSizeClasses];
AsanChunkFifoList quarantine_;
AsanLock mu_;
PageGroup *page_groups_[kMaxAvailableRam / kMinMmapSize];
atomic_uint32_t n_page_groups_;
int n_sorted_page_groups_;
};
static MallocInfo malloc_info(LINKER_INITIALIZED);
void AsanThreadLocalMallocStorage::CommitBack() {
malloc_info.SwallowThreadLocalMallocStorage(this, true);
}
AsanChunkView FindHeapChunkByAddress(uptr address) {
return AsanChunkView(malloc_info.FindChunkByAddr(address));
}
static u8 *Allocate(uptr alignment, uptr size, StackTrace *stack,
AllocType alloc_type) {
__asan_init();
CHECK(stack);
if (size == 0) {
size = 1; // TODO(kcc): do something smarter
}
CHECK(IsPowerOfTwo(alignment));
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uptr rounded_size = RoundUpTo(size, REDZONE);
uptr needed_size = rounded_size + REDZONE;
if (alignment > REDZONE) {
needed_size += alignment;
}
CHECK(IsAligned(needed_size, REDZONE));
if (size > kMaxAllowedMallocSize || needed_size > kMaxAllowedMallocSize) {
Report("WARNING: AddressSanitizer failed to allocate %p bytes\n",
(void*)size);
return 0;
}
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u8 size_class = SizeToSizeClass(needed_size);
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uptr size_to_allocate = SizeClassToSize(size_class);
CHECK(size_to_allocate >= kMinAllocSize);
CHECK(size_to_allocate >= needed_size);
CHECK(IsAligned(size_to_allocate, REDZONE));
if (flags()->verbosity >= 3) {
Printf("Allocate align: %zu size: %zu class: %u real: %zu\n",
alignment, size, size_class, size_to_allocate);
}
AsanThread *t = asanThreadRegistry().GetCurrent();
AsanStats &thread_stats = asanThreadRegistry().GetCurrentThreadStats();
// Statistics
thread_stats.mallocs++;
thread_stats.malloced += size;
thread_stats.malloced_redzones += size_to_allocate - size;
thread_stats.malloced_by_size[size_class]++;
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AsanChunk *m = 0;
if (!t || size_to_allocate >= kMaxSizeForThreadLocalFreeList) {
// get directly from global storage.
m = malloc_info.AllocateChunks(size_class, 1);
thread_stats.malloc_large++;
} else {
// get from the thread-local storage.
AsanChunk **fl = &t->malloc_storage().free_lists_[size_class];
if (!*fl) {
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uptr n_new_chunks = kMaxSizeForThreadLocalFreeList / size_to_allocate;
*fl = malloc_info.AllocateChunks(size_class, n_new_chunks);
thread_stats.malloc_small_slow++;
}
m = *fl;
*fl = (*fl)->next;
}
CHECK(m);
CHECK(m->chunk_state == CHUNK_AVAILABLE);
m->chunk_state = CHUNK_ALLOCATED;
m->alloc_type = alloc_type;
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m->next = 0;
CHECK(m->Size() == size_to_allocate);
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uptr addr = (uptr)m + REDZONE;
CHECK(addr <= (uptr)m->compressed_free_stack());
if (alignment > REDZONE && (addr & (alignment - 1))) {
addr = RoundUpTo(addr, alignment);
CHECK((addr & (alignment - 1)) == 0);
AsanChunk *p = (AsanChunk*)(addr - REDZONE);
p->chunk_state = CHUNK_MEMALIGN;
p->used_size = (uptr)p - (uptr)m;
m->alignment_log = Log2(alignment);
CHECK(m->Beg() == addr);
} else {
m->alignment_log = Log2(REDZONE);
}
CHECK(m == PtrToChunk(addr));
m->used_size = size;
CHECK(m->Beg() == addr);
m->alloc_tid = t ? t->tid() : 0;
m->free_tid = kInvalidTid;
StackTrace::CompressStack(stack, m->compressed_alloc_stack(),
m->compressed_alloc_stack_size());
PoisonShadow(addr, rounded_size, 0);
if (size < rounded_size) {
PoisonHeapPartialRightRedzone(addr + rounded_size - REDZONE,
size & (REDZONE - 1));
}
if (size <= (uptr)(flags()->max_malloc_fill_size)) {
REAL(memset)((void*)addr, 0, rounded_size);
}
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return (u8*)addr;
}
static void Deallocate(u8 *ptr, StackTrace *stack, AllocType alloc_type) {
if (!ptr) return;
CHECK(stack);
if (flags()->debug) {
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CHECK(malloc_info.FindPageGroup((uptr)ptr));
}
// Printf("Deallocate %p\n", ptr);
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AsanChunk *m = PtrToChunk((uptr)ptr);
// Flip the chunk_state atomically to avoid race on double-free.
u8 old_chunk_state = atomic_exchange((atomic_uint8_t*)m, CHUNK_QUARANTINE,
memory_order_acq_rel);
if (old_chunk_state == CHUNK_QUARANTINE) {
ReportDoubleFree((uptr)ptr, stack);
} else if (old_chunk_state != CHUNK_ALLOCATED) {
ReportFreeNotMalloced((uptr)ptr, stack);
}
CHECK(old_chunk_state == CHUNK_ALLOCATED);
if (m->alloc_type != alloc_type && flags()->alloc_dealloc_mismatch)
ReportAllocTypeMismatch((uptr)ptr, stack,
(AllocType)m->alloc_type, (AllocType)alloc_type);
// With REDZONE==16 m->next is in the user area, otherwise it should be 0.
CHECK(REDZONE <= 16 || !m->next);
CHECK(m->free_tid == kInvalidTid);
CHECK(m->alloc_tid >= 0);
AsanThread *t = asanThreadRegistry().GetCurrent();
m->free_tid = t ? t->tid() : 0;
StackTrace::CompressStack(stack, m->compressed_free_stack(),
m->compressed_free_stack_size());
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uptr rounded_size = RoundUpTo(m->used_size, REDZONE);
PoisonShadow((uptr)ptr, rounded_size, kAsanHeapFreeMagic);
// Statistics.
AsanStats &thread_stats = asanThreadRegistry().GetCurrentThreadStats();
thread_stats.frees++;
thread_stats.freed += m->used_size;
thread_stats.freed_by_size[m->SizeClass()]++;
CHECK(m->chunk_state == CHUNK_QUARANTINE);
if (t) {
AsanThreadLocalMallocStorage *ms = &t->malloc_storage();
ms->quarantine_.Push(m);
if (ms->quarantine_.size() > kMaxThreadLocalQuarantine) {
malloc_info.SwallowThreadLocalMallocStorage(ms, false);
}
} else {
malloc_info.BypassThreadLocalQuarantine(m);
}
}
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static u8 *Reallocate(u8 *old_ptr, uptr new_size,
StackTrace *stack) {
CHECK(old_ptr && new_size);
// Statistics.
AsanStats &thread_stats = asanThreadRegistry().GetCurrentThreadStats();
thread_stats.reallocs++;
thread_stats.realloced += new_size;
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AsanChunk *m = PtrToChunk((uptr)old_ptr);
CHECK(m->chunk_state == CHUNK_ALLOCATED);
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uptr old_size = m->used_size;
uptr memcpy_size = Min(new_size, old_size);
u8 *new_ptr = Allocate(0, new_size, stack, FROM_MALLOC);
if (new_ptr) {
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CHECK(REAL(memcpy) != 0);
REAL(memcpy)(new_ptr, old_ptr, memcpy_size);
Deallocate(old_ptr, stack, FROM_MALLOC);
}
return new_ptr;
}
} // namespace __asan
#if !SANITIZER_SUPPORTS_WEAK_HOOKS
// Provide default (no-op) implementation of malloc hooks.
extern "C" {
SANITIZER_WEAK_ATTRIBUTE SANITIZER_INTERFACE_ATTRIBUTE
void __asan_malloc_hook(void *ptr, uptr size) {
(void)ptr;
(void)size;
}
SANITIZER_WEAK_ATTRIBUTE SANITIZER_INTERFACE_ATTRIBUTE
void __asan_free_hook(void *ptr) {
(void)ptr;
}
} // extern "C"
#endif
namespace __asan {
void PrintInternalAllocatorStats() {
}
SANITIZER_INTERFACE_ATTRIBUTE
void *asan_memalign(uptr alignment, uptr size, StackTrace *stack,
AllocType alloc_type) {
void *ptr = (void*)Allocate(alignment, size, stack, alloc_type);
ASAN_MALLOC_HOOK(ptr, size);
return ptr;
}
SANITIZER_INTERFACE_ATTRIBUTE
void asan_free(void *ptr, StackTrace *stack, AllocType alloc_type) {
ASAN_FREE_HOOK(ptr);
Deallocate((u8*)ptr, stack, alloc_type);
}
SANITIZER_INTERFACE_ATTRIBUTE
void *asan_malloc(uptr size, StackTrace *stack) {
void *ptr = (void*)Allocate(0, size, stack, FROM_MALLOC);
ASAN_MALLOC_HOOK(ptr, size);
return ptr;
}
void *asan_calloc(uptr nmemb, uptr size, StackTrace *stack) {
void *ptr = (void*)Allocate(0, nmemb * size, stack, FROM_MALLOC);
if (ptr)
REAL(memset)(ptr, 0, nmemb * size);
ASAN_MALLOC_HOOK(ptr, size);
return ptr;
}
void *asan_realloc(void *p, uptr size, StackTrace *stack) {
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if (p == 0) {
void *ptr = (void*)Allocate(0, size, stack, FROM_MALLOC);
ASAN_MALLOC_HOOK(ptr, size);
return ptr;
} else if (size == 0) {
ASAN_FREE_HOOK(p);
Deallocate((u8*)p, stack, FROM_MALLOC);
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return 0;
}
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return Reallocate((u8*)p, size, stack);
}
void *asan_valloc(uptr size, StackTrace *stack) {
void *ptr = (void*)Allocate(GetPageSizeCached(), size, stack, FROM_MALLOC);
ASAN_MALLOC_HOOK(ptr, size);
return ptr;
}
void *asan_pvalloc(uptr size, StackTrace *stack) {
uptr PageSize = GetPageSizeCached();
size = RoundUpTo(size, PageSize);
if (size == 0) {
// pvalloc(0) should allocate one page.
size = PageSize;
}
void *ptr = (void*)Allocate(PageSize, size, stack, FROM_MALLOC);
ASAN_MALLOC_HOOK(ptr, size);
return ptr;
}
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int asan_posix_memalign(void **memptr, uptr alignment, uptr size,
StackTrace *stack) {
void *ptr = Allocate(alignment, size, stack, FROM_MALLOC);
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CHECK(IsAligned((uptr)ptr, alignment));
ASAN_MALLOC_HOOK(ptr, size);
*memptr = ptr;
return 0;
}
uptr asan_malloc_usable_size(void *ptr, StackTrace *stack) {
CHECK(stack);
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if (ptr == 0) return 0;
uptr usable_size = malloc_info.AllocationSize((uptr)ptr);
if (flags()->check_malloc_usable_size && (usable_size == 0)) {
ReportMallocUsableSizeNotOwned((uptr)ptr, stack);
}
return usable_size;
}
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uptr asan_mz_size(const void *ptr) {
return malloc_info.AllocationSize((uptr)ptr);
}
void asan_mz_force_lock() {
malloc_info.ForceLock();
}
void asan_mz_force_unlock() {
malloc_info.ForceUnlock();
}
} // namespace __asan
// ---------------------- Interface ---------------- {{{1
using namespace __asan; // NOLINT
// ASan allocator doesn't reserve extra bytes, so normally we would
// just return "size".
uptr __asan_get_estimated_allocated_size(uptr size) {
if (size == 0) return 1;
return Min(size, kMaxAllowedMallocSize);
}
bool __asan_get_ownership(const void *p) {
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return malloc_info.AllocationSize((uptr)p) > 0;
}
uptr __asan_get_allocated_size(const void *p) {
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if (p == 0) return 0;
uptr allocated_size = malloc_info.AllocationSize((uptr)p);
// Die if p is not malloced or if it is already freed.
if (allocated_size == 0) {
GET_STACK_TRACE_FATAL_HERE;
ReportAsanGetAllocatedSizeNotOwned((uptr)p, &stack);
}
return allocated_size;
}
#endif // ASAN_ALLOCATOR_VERSION