libsanitizer/sanitizer_common/sanitizer_quarantine.h - gcc - Git at Google

 //===-- sanitizer_quarantine.h ----------------------------------*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // Memory quarantine for AddressSanitizer and potentially other tools.
 // Quarantine caches some specified amount of memory in per-thread caches,
 // then evicts to global FIFO queue. When the queue reaches specified threshold,
 // oldest memory is recycled.
 //
 //===----------------------------------------------------------------------===//

 #ifndef SANITIZER_QUARANTINE_H
 #define SANITIZER_QUARANTINE_H

 #include "sanitizer_internal_defs.h"
 #include "sanitizer_mutex.h"
 #include "sanitizer_list.h"

 namespace __sanitizer {

 template<typename Node> class QuarantineCache;

 struct QuarantineBatch {
   static const uptr kSize = 1021;
   QuarantineBatch *next;
   uptr size;
   uptr count;
   void *batch[kSize];

   void init(void *ptr, uptr size) {
     count = 1;
     batch[0] = ptr;
     this->size = size + sizeof(QuarantineBatch);  // Account for the batch size.
   }

   // The total size of quarantined nodes recorded in this batch.
   uptr quarantined_size() const {
     return size - sizeof(QuarantineBatch);
   }

   void push_back(void *ptr, uptr size) {
     CHECK_LT(count, kSize);
     batch[count++] = ptr;
     this->size += size;
   }

   bool can_merge(const QuarantineBatch* const from) const {
     return count + from->count <= kSize;
   }

   void merge(QuarantineBatch* const from) {
     CHECK_LE(count + from->count, kSize);
     CHECK_GE(size, sizeof(QuarantineBatch));

     for (uptr i = 0; i < from->count; ++i)
       batch[count + i] = from->batch[i];
     count += from->count;
     size += from->quarantined_size();

     from->count = 0;
     from->size = sizeof(QuarantineBatch);
   }
 };

 COMPILER_CHECK(sizeof(QuarantineBatch) <= (1 << 13));  // 8Kb.

 // The callback interface is:
 // void Callback::Recycle(Node *ptr);
 // void *cb.Allocate(uptr size);
 // void cb.Deallocate(void *ptr);
 template<typename Callback, typename Node>
 class Quarantine {
  public:
   typedef QuarantineCache<Callback> Cache;

   explicit Quarantine(LinkerInitialized)
       : cache_(LINKER_INITIALIZED) {
   }

   void Init(uptr size, uptr cache_size) {
     // Thread local quarantine size can be zero only when global quarantine size
     // is zero (it allows us to perform just one atomic read per Put() call).
     CHECK((size == 0 && cache_size == 0) || cache_size != 0);

     atomic_store_relaxed(&max_size_, size);
     atomic_store_relaxed(&min_size_, size / 10 * 9);  // 90% of max size.
     atomic_store_relaxed(&max_cache_size_, cache_size);

     cache_mutex_.Init();
     recycle_mutex_.Init();
   }

   uptr GetSize() const { return atomic_load_relaxed(&max_size_); }
   uptr GetCacheSize() const {
     return atomic_load_relaxed(&max_cache_size_);
   }

   void Put(Cache *c, Callback cb, Node *ptr, uptr size) {
     uptr cache_size = GetCacheSize();
     if (cache_size) {
       c->Enqueue(cb, ptr, size);
     } else {
       // GetCacheSize() == 0 only when GetSize() == 0 (see Init).
       cb.Recycle(ptr);
     }
     // Check cache size anyway to accommodate for runtime cache_size change.
     if (c->Size() > cache_size)
       Drain(c, cb);
   }

   void NOINLINE Drain(Cache *c, Callback cb) {
     {
       SpinMutexLock l(&cache_mutex_);
       cache_.Transfer(c);
     }
     if (cache_.Size() > GetSize() && recycle_mutex_.TryLock())
       Recycle(atomic_load_relaxed(&min_size_), cb);
   }

   void NOINLINE DrainAndRecycle(Cache *c, Callback cb) {
     {
       SpinMutexLock l(&cache_mutex_);
       cache_.Transfer(c);
     }
     recycle_mutex_.Lock();
     Recycle(0, cb);
   }

   void PrintStats() const {
     // It assumes that the world is stopped, just as the allocator's PrintStats.
     Printf("Quarantine limits: global: %zdMb; thread local: %zdKb\n",
            GetSize() >> 20, GetCacheSize() >> 10);
     cache_.PrintStats();
   }

  private:
   // Read-only data.
   char pad0_[kCacheLineSize];
   atomic_uintptr_t max_size_;
   atomic_uintptr_t min_size_;
   atomic_uintptr_t max_cache_size_;
   char pad1_[kCacheLineSize];
   StaticSpinMutex cache_mutex_;
   StaticSpinMutex recycle_mutex_;
   Cache cache_;
   char pad2_[kCacheLineSize];

   void NOINLINE Recycle(uptr min_size, Callback cb)
       SANITIZER_REQUIRES(recycle_mutex_) SANITIZER_RELEASE(recycle_mutex_) {
     Cache tmp;
     {
       SpinMutexLock l(&cache_mutex_);
       // Go over the batches and merge partially filled ones to
       // save some memory, otherwise batches themselves (since the memory used
       // by them is counted against quarantine limit) can overcome the actual
       // user's quarantined chunks, which diminishes the purpose of the
       // quarantine.
       uptr cache_size = cache_.Size();
       uptr overhead_size = cache_.OverheadSize();
       CHECK_GE(cache_size, overhead_size);
       // Do the merge only when overhead exceeds this predefined limit (might
       // require some tuning). It saves us merge attempt when the batch list
       // quarantine is unlikely to contain batches suitable for merge.
       const uptr kOverheadThresholdPercents = 100;
       if (cache_size > overhead_size &&
           overhead_size * (100 + kOverheadThresholdPercents) >
               cache_size * kOverheadThresholdPercents) {
         cache_.MergeBatches(&tmp);
       }
       // Extract enough chunks from the quarantine to get below the max
       // quarantine size and leave some leeway for the newly quarantined chunks.
       while (cache_.Size() > min_size) {
         tmp.EnqueueBatch(cache_.DequeueBatch());
       }
     }
     recycle_mutex_.Unlock();
     DoRecycle(&tmp, cb);
   }

   void NOINLINE DoRecycle(Cache *c, Callback cb) {
     while (QuarantineBatch *b = c->DequeueBatch()) {
       const uptr kPrefetch = 16;
       CHECK(kPrefetch <= ARRAY_SIZE(b->batch));
       for (uptr i = 0; i < kPrefetch; i++)
         PREFETCH(b->batch[i]);
       for (uptr i = 0, count = b->count; i < count; i++) {
         if (i + kPrefetch < count)
           PREFETCH(b->batch[i + kPrefetch]);
         cb.Recycle((Node*)b->batch[i]);
       }
       cb.Deallocate(b);
     }
   }
 };

 // Per-thread cache of memory blocks.
 template<typename Callback>
 class QuarantineCache {
  public:
   explicit QuarantineCache(LinkerInitialized) {
   }

   QuarantineCache()
       : size_() {
     list_.clear();
   }

   // Total memory used, including internal accounting.
   uptr Size() const {
     return atomic_load_relaxed(&size_);
   }

   // Memory used for internal accounting.
   uptr OverheadSize() const {
     return list_.size() * sizeof(QuarantineBatch);
   }

   void Enqueue(Callback cb, void *ptr, uptr size) {
     if (list_.empty() || list_.back()->count == QuarantineBatch::kSize) {
       QuarantineBatch *b = (QuarantineBatch *)cb.Allocate(sizeof(*b));
       CHECK(b);
       b->init(ptr, size);
       EnqueueBatch(b);
     } else {
       list_.back()->push_back(ptr, size);
       SizeAdd(size);
     }
   }

   void Transfer(QuarantineCache *from_cache) {
     list_.append_back(&from_cache->list_);
     SizeAdd(from_cache->Size());

     atomic_store_relaxed(&from_cache->size_, 0);
   }

   void EnqueueBatch(QuarantineBatch *b) {
     list_.push_back(b);
     SizeAdd(b->size);
   }

   QuarantineBatch *DequeueBatch() {
     if (list_.empty())
       return nullptr;
     QuarantineBatch *b = list_.front();
     list_.pop_front();
     SizeSub(b->size);
     return b;
   }

   void MergeBatches(QuarantineCache *to_deallocate) {
     uptr extracted_size = 0;
     QuarantineBatch *current = list_.front();
     while (current && current->next) {
       if (current->can_merge(current->next)) {
         QuarantineBatch *extracted = current->next;
         // Move all the chunks into the current batch.
         current->merge(extracted);
         CHECK_EQ(extracted->count, 0);
         CHECK_EQ(extracted->size, sizeof(QuarantineBatch));
         // Remove the next batch from the list and account for its size.
         list_.extract(current, extracted);
         extracted_size += extracted->size;
         // Add it to deallocation list.
         to_deallocate->EnqueueBatch(extracted);
       } else {
         current = current->next;
       }
     }
     SizeSub(extracted_size);
   }

   void PrintStats() const {
     uptr batch_count = 0;
     uptr total_overhead_bytes = 0;
     uptr total_bytes = 0;
     uptr total_quarantine_chunks = 0;
     for (List::ConstIterator it = list_.begin(); it != list_.end(); ++it) {
       batch_count++;
       total_bytes += (*it).size;
       total_overhead_bytes += (*it).size - (*it).quarantined_size();
       total_quarantine_chunks += (*it).count;
     }
     uptr quarantine_chunks_capacity = batch_count * QuarantineBatch::kSize;
     int chunks_usage_percent = quarantine_chunks_capacity == 0 ?
         0 : total_quarantine_chunks * 100 / quarantine_chunks_capacity;
     uptr total_quarantined_bytes = total_bytes - total_overhead_bytes;
     int memory_overhead_percent = total_quarantined_bytes == 0 ?
         0 : total_overhead_bytes * 100 / total_quarantined_bytes;
     Printf("Global quarantine stats: batches: %zd; bytes: %zd (user: %zd); "
            "chunks: %zd (capacity: %zd); %d%% chunks used; %d%% memory overhead"
            "\n",
            batch_count, total_bytes, total_quarantined_bytes,
            total_quarantine_chunks, quarantine_chunks_capacity,
            chunks_usage_percent, memory_overhead_percent);
   }

  private:
   typedef IntrusiveList<QuarantineBatch> List;

   List list_;
   atomic_uintptr_t size_;

   void SizeAdd(uptr add) {
     atomic_store_relaxed(&size_, Size() + add);
   }
   void SizeSub(uptr sub) {
     atomic_store_relaxed(&size_, Size() - sub);
   }
 };

 } // namespace __sanitizer

 #endif // SANITIZER_QUARANTINE_H
	//===-- sanitizer_quarantine.h ----------------------------------- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Memory quarantine for AddressSanitizer and potentially other tools.
	// Quarantine caches some specified amount of memory in per-thread caches,
	// then evicts to global FIFO queue. When the queue reaches specified threshold,
	// oldest memory is recycled.
	//
	//===----------------------------------------------------------------------===//

	#ifndef SANITIZER_QUARANTINE_H
	#define SANITIZER_QUARANTINE_H

	#include "sanitizer_internal_defs.h"
	#include "sanitizer_mutex.h"
	#include "sanitizer_list.h"

	namespace __sanitizer {

	template<typename Node> class QuarantineCache;

	struct QuarantineBatch {
	static const uptr kSize = 1021;
	QuarantineBatch *next;
	uptr size;
	uptr count;
	void *batch[kSize];

	void init(void *ptr, uptr size) {
	count = 1;
	batch[0] = ptr;
	this->size = size + sizeof(QuarantineBatch); // Account for the batch size.
	}

	// The total size of quarantined nodes recorded in this batch.
	uptr quarantined_size() const {
	return size - sizeof(QuarantineBatch);
	}

	void push_back(void *ptr, uptr size) {
	CHECK_LT(count, kSize);
	batch[count++] = ptr;
	this->size += size;
	}

	bool can_merge(const QuarantineBatch* const from) const {
	return count + from->count <= kSize;
	}

	void merge(QuarantineBatch* const from) {
	CHECK_LE(count + from->count, kSize);
	CHECK_GE(size, sizeof(QuarantineBatch));

	for (uptr i = 0; i < from->count; ++i)
	batch[count + i] = from->batch[i];
	count += from->count;
	size += from->quarantined_size();

	from->count = 0;
	from->size = sizeof(QuarantineBatch);
	}
	};

	COMPILER_CHECK(sizeof(QuarantineBatch) <= (1 << 13)); // 8Kb.

	// The callback interface is:
	// void Callback::Recycle(Node *ptr);
	// void *cb.Allocate(uptr size);
	// void cb.Deallocate(void *ptr);
	template<typename Callback, typename Node>
	class Quarantine {
	public:
	typedef QuarantineCache<Callback> Cache;

	explicit Quarantine(LinkerInitialized)
	: cache_(LINKER_INITIALIZED) {
	}

	void Init(uptr size, uptr cache_size) {
	// Thread local quarantine size can be zero only when global quarantine size
	// is zero (it allows us to perform just one atomic read per Put() call).
	CHECK((size == 0 && cache_size == 0) \|\| cache_size != 0);

	atomic_store_relaxed(&max_size_, size);
	atomic_store_relaxed(&min_size_, size / 10 * 9); // 90% of max size.
	atomic_store_relaxed(&max_cache_size_, cache_size);

	cache_mutex_.Init();
	recycle_mutex_.Init();
	}

	uptr GetSize() const { return atomic_load_relaxed(&max_size_); }
	uptr GetCacheSize() const {
	return atomic_load_relaxed(&max_cache_size_);
	}

	void Put(Cache c, Callback cb, Node ptr, uptr size) {
	uptr cache_size = GetCacheSize();
	if (cache_size) {
	c->Enqueue(cb, ptr, size);
	} else {
	// GetCacheSize() == 0 only when GetSize() == 0 (see Init).
	cb.Recycle(ptr);
	}
	// Check cache size anyway to accommodate for runtime cache_size change.
	if (c->Size() > cache_size)
	Drain(c, cb);
	}

	void NOINLINE Drain(Cache *c, Callback cb) {
	{
	SpinMutexLock l(&cache_mutex_);
	cache_.Transfer(c);
	}
	if (cache_.Size() > GetSize() && recycle_mutex_.TryLock())
	Recycle(atomic_load_relaxed(&min_size_), cb);
	}

	void NOINLINE DrainAndRecycle(Cache *c, Callback cb) {
	{
	SpinMutexLock l(&cache_mutex_);
	cache_.Transfer(c);
	}
	recycle_mutex_.Lock();
	Recycle(0, cb);
	}

	void PrintStats() const {
	// It assumes that the world is stopped, just as the allocator's PrintStats.
	Printf("Quarantine limits: global: %zdMb; thread local: %zdKb\n",
	GetSize() >> 20, GetCacheSize() >> 10);
	cache_.PrintStats();
	}

	private:
	// Read-only data.
	char pad0_[kCacheLineSize];
	atomic_uintptr_t max_size_;
	atomic_uintptr_t min_size_;
	atomic_uintptr_t max_cache_size_;
	char pad1_[kCacheLineSize];
	StaticSpinMutex cache_mutex_;
	StaticSpinMutex recycle_mutex_;
	Cache cache_;
	char pad2_[kCacheLineSize];

	void NOINLINE Recycle(uptr min_size, Callback cb)
	SANITIZER_REQUIRES(recycle_mutex_) SANITIZER_RELEASE(recycle_mutex_) {
	Cache tmp;
	{
	SpinMutexLock l(&cache_mutex_);
	// Go over the batches and merge partially filled ones to
	// save some memory, otherwise batches themselves (since the memory used
	// by them is counted against quarantine limit) can overcome the actual
	// user's quarantined chunks, which diminishes the purpose of the
	// quarantine.
	uptr cache_size = cache_.Size();
	uptr overhead_size = cache_.OverheadSize();
	CHECK_GE(cache_size, overhead_size);
	// Do the merge only when overhead exceeds this predefined limit (might
	// require some tuning). It saves us merge attempt when the batch list
	// quarantine is unlikely to contain batches suitable for merge.
	const uptr kOverheadThresholdPercents = 100;
	if (cache_size > overhead_size &&
	overhead_size * (100 + kOverheadThresholdPercents) >
	cache_size * kOverheadThresholdPercents) {
	cache_.MergeBatches(&tmp);
	}
	// Extract enough chunks from the quarantine to get below the max
	// quarantine size and leave some leeway for the newly quarantined chunks.
	while (cache_.Size() > min_size) {
	tmp.EnqueueBatch(cache_.DequeueBatch());
	}
	}
	recycle_mutex_.Unlock();
	DoRecycle(&tmp, cb);
	}

	void NOINLINE DoRecycle(Cache *c, Callback cb) {
	while (QuarantineBatch *b = c->DequeueBatch()) {
	const uptr kPrefetch = 16;
	CHECK(kPrefetch <= ARRAY_SIZE(b->batch));
	for (uptr i = 0; i < kPrefetch; i++)
	PREFETCH(b->batch[i]);
	for (uptr i = 0, count = b->count; i < count; i++) {
	if (i + kPrefetch < count)
	PREFETCH(b->batch[i + kPrefetch]);
	cb.Recycle((Node*)b->batch[i]);
	}
	cb.Deallocate(b);
	}
	}
	};

	// Per-thread cache of memory blocks.
	template<typename Callback>
	class QuarantineCache {
	public:
	explicit QuarantineCache(LinkerInitialized) {
	}

	QuarantineCache()
	: size_() {
	list_.clear();
	}

	// Total memory used, including internal accounting.
	uptr Size() const {
	return atomic_load_relaxed(&size_);
	}

	// Memory used for internal accounting.
	uptr OverheadSize() const {
	return list_.size() * sizeof(QuarantineBatch);
	}

	void Enqueue(Callback cb, void *ptr, uptr size) {
	if (list_.empty() \|\| list_.back()->count == QuarantineBatch::kSize) {
	QuarantineBatch b = (QuarantineBatch )cb.Allocate(sizeof(*b));
	CHECK(b);
	b->init(ptr, size);
	EnqueueBatch(b);
	} else {
	list_.back()->push_back(ptr, size);
	SizeAdd(size);
	}
	}

	void Transfer(QuarantineCache *from_cache) {
	list_.append_back(&from_cache->list_);
	SizeAdd(from_cache->Size());

	atomic_store_relaxed(&from_cache->size_, 0);
	}

	void EnqueueBatch(QuarantineBatch *b) {
	list_.push_back(b);
	SizeAdd(b->size);
	}

	QuarantineBatch *DequeueBatch() {
	if (list_.empty())
	return nullptr;
	QuarantineBatch *b = list_.front();
	list_.pop_front();
	SizeSub(b->size);
	return b;
	}

	void MergeBatches(QuarantineCache *to_deallocate) {
	uptr extracted_size = 0;
	QuarantineBatch *current = list_.front();
	while (current && current->next) {
	if (current->can_merge(current->next)) {
	QuarantineBatch *extracted = current->next;
	// Move all the chunks into the current batch.
	current->merge(extracted);
	CHECK_EQ(extracted->count, 0);
	CHECK_EQ(extracted->size, sizeof(QuarantineBatch));
	// Remove the next batch from the list and account for its size.
	list_.extract(current, extracted);
	extracted_size += extracted->size;
	// Add it to deallocation list.
	to_deallocate->EnqueueBatch(extracted);
	} else {
	current = current->next;
	}
	}
	SizeSub(extracted_size);
	}

	void PrintStats() const {
	uptr batch_count = 0;
	uptr total_overhead_bytes = 0;
	uptr total_bytes = 0;
	uptr total_quarantine_chunks = 0;
	for (List::ConstIterator it = list_.begin(); it != list_.end(); ++it) {
	batch_count++;
	total_bytes += (*it).size;
	total_overhead_bytes += (it).size - (it).quarantined_size();
	total_quarantine_chunks += (*it).count;
	}
	uptr quarantine_chunks_capacity = batch_count * QuarantineBatch::kSize;
	int chunks_usage_percent = quarantine_chunks_capacity == 0 ?
	0 : total_quarantine_chunks * 100 / quarantine_chunks_capacity;
	uptr total_quarantined_bytes = total_bytes - total_overhead_bytes;
	int memory_overhead_percent = total_quarantined_bytes == 0 ?
	0 : total_overhead_bytes * 100 / total_quarantined_bytes;
	Printf("Global quarantine stats: batches: %zd; bytes: %zd (user: %zd); "
	"chunks: %zd (capacity: %zd); %d%% chunks used; %d%% memory overhead"
	"\n",
	batch_count, total_bytes, total_quarantined_bytes,
	total_quarantine_chunks, quarantine_chunks_capacity,
	chunks_usage_percent, memory_overhead_percent);
	}

	private:
	typedef IntrusiveList<QuarantineBatch> List;

	List list_;
	atomic_uintptr_t size_;

	void SizeAdd(uptr add) {
	atomic_store_relaxed(&size_, Size() + add);
	}
	void SizeSub(uptr sub) {
	atomic_store_relaxed(&size_, Size() - sub);
	}
	};

	} // namespace __sanitizer

	#endif // SANITIZER_QUARANTINE_H