// Protocol Buffers - Google's data interchange format // Copyright 2022 Google Inc. All rights reserved. // https://developers.google.com/protocol-buffers/ // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // // This file defines the internal class SerialArena #ifndef GOOGLE_PROTOBUF_SERIAL_ARENA_H__ #define GOOGLE_PROTOBUF_SERIAL_ARENA_H__ #include #include #include #include #include #include #include #include "google/protobuf/stubs/common.h" #include "absl/base/attributes.h" #include "absl/log/absl_check.h" #include "absl/numeric/bits.h" #include "google/protobuf/arena_align.h" #include "google/protobuf/arena_cleanup.h" #include "google/protobuf/arenaz_sampler.h" #include "google/protobuf/port.h" #include "google/protobuf/string_block.h" // Must be included last. #include "google/protobuf/port_def.inc" namespace google { namespace protobuf { namespace internal { // Arena blocks are variable length malloc-ed objects. The following structure // describes the common header for all blocks. struct ArenaBlock { // For the sentry block with zero-size where ptr_, limit_, cleanup_nodes all // point to "this". constexpr ArenaBlock() : next(nullptr), cleanup_nodes(this), size(0) {} ArenaBlock(ArenaBlock* next, size_t size) : next(next), cleanup_nodes(nullptr), size(size) { ABSL_DCHECK_GT(size, sizeof(ArenaBlock)); } char* Pointer(size_t n) { ABSL_DCHECK_LE(n, size); return reinterpret_cast(this) + n; } char* Limit() { return Pointer(size & static_cast(-8)); } bool IsSentry() const { return size == 0; } ArenaBlock* const next; void* cleanup_nodes; const size_t size; // data follows }; enum class AllocationClient { kDefault, kArray }; class ThreadSafeArena; // Tag type used to invoke the constructor of the first SerialArena. struct FirstSerialArena { explicit FirstSerialArena() = default; }; // A simple arena allocator. Calls to allocate functions must be properly // serialized by the caller, hence this class cannot be used as a general // purpose allocator in a multi-threaded program. It serves as a building block // for ThreadSafeArena, which provides a thread-safe arena allocator. // // This class manages // 1) Arena bump allocation + owning memory blocks. // 2) Maintaining a cleanup list. // It delegates the actual memory allocation back to ThreadSafeArena, which // contains the information on block growth policy and backing memory allocation // used. class PROTOBUF_EXPORT SerialArena { public: void CleanupList(); size_t FreeStringBlocks() { // On the active block delete all strings skipping the unused instances. size_t unused_bytes = string_block_unused_.load(std::memory_order_relaxed); if (string_block_ != nullptr) { return FreeStringBlocks(string_block_, unused_bytes); } return 0; } uint64_t SpaceAllocated() const { return space_allocated_.load(std::memory_order_relaxed); } uint64_t SpaceUsed() const; bool HasSpace(size_t n) const { return n <= static_cast(limit_ - ptr()); } // See comments on `cached_blocks_` member for details. PROTOBUF_ALWAYS_INLINE void* TryAllocateFromCachedBlock(size_t size) { if (PROTOBUF_PREDICT_FALSE(size < 16)) return nullptr; // We round up to the next larger block in case the memory doesn't match // the pattern we are looking for. const size_t index = absl::bit_width(size - 1) - 4; if (index >= cached_block_length_) return nullptr; auto& cached_head = cached_blocks_[index]; if (cached_head == nullptr) return nullptr; void* ret = cached_head; PROTOBUF_UNPOISON_MEMORY_REGION(ret, size); cached_head = cached_head->next; return ret; } // In kArray mode we look through cached blocks. // We do not do this by default because most non-array allocations will not // have the right size and will fail to find an appropriate cached block. // // TODO(sbenza): Evaluate if we should use cached blocks for message types of // the right size. We can statically know if the allocation size can benefit // from it. template void* AllocateAligned(size_t n) { ABSL_DCHECK(internal::ArenaAlignDefault::IsAligned(n)); ABSL_DCHECK_GE(limit_, ptr()); if (alloc_client == AllocationClient::kArray) { if (void* res = TryAllocateFromCachedBlock(n)) { return res; } } if (PROTOBUF_PREDICT_FALSE(!HasSpace(n))) { return AllocateAlignedFallback(n); } return AllocateFromExisting(n); } private: static inline PROTOBUF_ALWAYS_INLINE constexpr size_t AlignUpTo(size_t n, size_t a) { // We are wasting space by over allocating align - 8 bytes. Compared to a // dedicated function that takes current alignment in consideration. Such a // scheme would only waste (align - 8)/2 bytes on average, but requires a // dedicated function in the outline arena allocation functions. Possibly // re-evaluate tradeoffs later. return a <= 8 ? ArenaAlignDefault::Ceil(n) : ArenaAlignAs(a).Padded(n); } static inline PROTOBUF_ALWAYS_INLINE void* AlignTo(void* p, size_t a) { return (a <= ArenaAlignDefault::align) ? ArenaAlignDefault::CeilDefaultAligned(p) : ArenaAlignAs(a).CeilDefaultAligned(p); } void* AllocateFromExisting(size_t n) { PROTOBUF_UNPOISON_MEMORY_REGION(ptr(), n); void* ret = ptr(); set_ptr(static_cast(ret) + n); return ret; } // See comments on `cached_blocks_` member for details. void ReturnArrayMemory(void* p, size_t size) { // We only need to check for 32-bit platforms. // In 64-bit platforms the minimum allocation size from Repeated*Field will // be 16 guaranteed. if (sizeof(void*) < 8) { if (PROTOBUF_PREDICT_FALSE(size < 16)) return; } else { PROTOBUF_ASSUME(size >= 16); } // We round down to the next smaller block in case the memory doesn't match // the pattern we are looking for. eg, someone might have called Reserve() // on the repeated field. const size_t index = absl::bit_width(size) - 5; if (PROTOBUF_PREDICT_FALSE(index >= cached_block_length_)) { // We can't put this object on the freelist so make this object the // freelist. It is guaranteed it is larger than the one we have, and // large enough to hold another allocation of `size`. CachedBlock** new_list = static_cast(p); size_t new_size = size / sizeof(CachedBlock*); std::copy(cached_blocks_, cached_blocks_ + cached_block_length_, new_list); // We need to unpoison this memory before filling it in case it has been // poisoned by another santizer client. PROTOBUF_UNPOISON_MEMORY_REGION( new_list + cached_block_length_, (new_size - cached_block_length_) * sizeof(CachedBlock*)); std::fill(new_list + cached_block_length_, new_list + new_size, nullptr); cached_blocks_ = new_list; // Make the size fit in uint8_t. This is the power of two, so we don't // need anything larger. cached_block_length_ = static_cast(std::min(size_t{64}, new_size)); return; } auto& cached_head = cached_blocks_[index]; auto* new_node = static_cast(p); new_node->next = cached_head; cached_head = new_node; PROTOBUF_POISON_MEMORY_REGION(p, size); } public: // Allocate space if the current region provides enough space. bool MaybeAllocateAligned(size_t n, void** out) { ABSL_DCHECK(internal::ArenaAlignDefault::IsAligned(n)); ABSL_DCHECK_GE(limit_, ptr()); if (PROTOBUF_PREDICT_FALSE(!HasSpace(n))) return false; *out = AllocateFromExisting(n); return true; } // If there is enough space in the current block, allocate space for one `T` // object and register for destruction. The object has not been constructed // and the memory returned is uninitialized. template PROTOBUF_ALWAYS_INLINE void* MaybeAllocateWithCleanup() { ABSL_DCHECK_GE(limit_, ptr()); static_assert(!std::is_trivially_destructible::value, "This function is only for non-trivial types."); constexpr int aligned_size = ArenaAlignDefault::Ceil(sizeof(T)); constexpr auto destructor = cleanup::arena_destruct_object; size_t required = aligned_size + cleanup::Size(destructor); if (PROTOBUF_PREDICT_FALSE(!HasSpace(required))) { return nullptr; } void* ptr = AllocateFromExistingWithCleanupFallback(aligned_size, alignof(T), destructor); PROTOBUF_ASSUME(ptr != nullptr); return ptr; } PROTOBUF_ALWAYS_INLINE void* AllocateAlignedWithCleanup(size_t n, size_t align, void (*destructor)(void*)) { size_t required = AlignUpTo(n, align) + cleanup::Size(destructor); if (PROTOBUF_PREDICT_FALSE(!HasSpace(required))) { return AllocateAlignedWithCleanupFallback(n, align, destructor); } return AllocateFromExistingWithCleanupFallback(n, align, destructor); } PROTOBUF_ALWAYS_INLINE void AddCleanup(void* elem, void (*destructor)(void*)) { size_t required = cleanup::Size(destructor); if (PROTOBUF_PREDICT_FALSE(!HasSpace(required))) { return AddCleanupFallback(elem, destructor); } AddCleanupFromExisting(elem, destructor); } ABSL_ATTRIBUTE_RETURNS_NONNULL void* AllocateFromStringBlock(); std::vector PeekCleanupListForTesting(); private: bool MaybeAllocateString(void*& p); ABSL_ATTRIBUTE_RETURNS_NONNULL void* AllocateFromStringBlockFallback(); void* AllocateFromExistingWithCleanupFallback(size_t n, size_t align, void (*destructor)(void*)) { n = AlignUpTo(n, align); PROTOBUF_UNPOISON_MEMORY_REGION(ptr(), n); void* ret = ArenaAlignAs(align).CeilDefaultAligned(ptr()); set_ptr(ptr() + n); ABSL_DCHECK_GE(limit_, ptr()); AddCleanupFromExisting(ret, destructor); return ret; } PROTOBUF_ALWAYS_INLINE void AddCleanupFromExisting(void* elem, void (*destructor)(void*)) { cleanup::Tag tag = cleanup::Type(destructor); size_t n = cleanup::Size(tag); PROTOBUF_UNPOISON_MEMORY_REGION(limit_ - n, n); limit_ -= n; ABSL_DCHECK_GE(limit_, ptr()); cleanup::CreateNode(tag, limit_, elem, destructor); } private: friend class ThreadSafeArena; // Creates a new SerialArena inside mem using the remaining memory as for // future allocations. // The `parent` arena must outlive the serial arena, which is guaranteed // because the parent manages the lifetime of the serial arenas. static SerialArena* New(SizedPtr mem, ThreadSafeArena& parent); // Free SerialArena returning the memory passed in to New template SizedPtr Free(Deallocator deallocator); static size_t FreeStringBlocks(StringBlock* string_block, size_t unused); // Adds 'used` to space_used_ in relaxed atomic order. void AddSpaceUsed(size_t space_used) { space_used_.store(space_used_.load(std::memory_order_relaxed) + space_used, std::memory_order_relaxed); } // Adds 'allocated` to space_allocated_ in relaxed atomic order. void AddSpaceAllocated(size_t space_allocated) { space_allocated_.store( space_allocated_.load(std::memory_order_relaxed) + space_allocated, std::memory_order_relaxed); } // Members are declared here to track sizeof(SerialArena) and hotness // centrally. They are (roughly) laid out in descending order of hotness. // Next pointer to allocate from. Always 8-byte aligned. Points inside // head_ (and head_->pos will always be non-canonical). We keep these // here to reduce indirection. std::atomic ptr_{nullptr}; // Limiting address up to which memory can be allocated from the head block. char* limit_ = nullptr; // The active string block. StringBlock* string_block_ = nullptr; // The number of unused bytes in string_block_. // We allocate from `effective_size()` down to 0 inside `string_block_`. // `unused == 0` means that `string_block_` is exhausted. (or null). std::atomic string_block_unused_{0}; std::atomic head_{nullptr}; // Head of linked list of blocks. std::atomic space_used_{0}; // Necessary for metrics. std::atomic space_allocated_{0}; ThreadSafeArena& parent_; // Repeated*Field and Arena play together to reduce memory consumption by // reusing blocks. Currently, natural growth of the repeated field types makes // them allocate blocks of size `8 + 2^N, N>=3`. // When the repeated field grows returns the previous block and we put it in // this free list. // `cached_blocks_[i]` points to the free list for blocks of size `8+2^(i+3)`. // The array of freelists is grown when needed in `ReturnArrayMemory()`. struct CachedBlock { // Simple linked list. CachedBlock* next; }; uint8_t cached_block_length_ = 0; CachedBlock** cached_blocks_ = nullptr; // Helper getters/setters to handle relaxed operations on atomic variables. ArenaBlock* head() { return head_.load(std::memory_order_relaxed); } const ArenaBlock* head() const { return head_.load(std::memory_order_relaxed); } char* ptr() { return ptr_.load(std::memory_order_relaxed); } const char* ptr() const { return ptr_.load(std::memory_order_relaxed); } void set_ptr(char* ptr) { return ptr_.store(ptr, std::memory_order_relaxed); } // Constructor is private as only New() should be used. inline SerialArena(ArenaBlock* b, ThreadSafeArena& parent); // Constructors to handle the first SerialArena. inline explicit SerialArena(ThreadSafeArena& parent); inline SerialArena(FirstSerialArena, ArenaBlock* b, ThreadSafeArena& parent); void* AllocateAlignedFallback(size_t n); void* AllocateAlignedWithCleanupFallback(size_t n, size_t align, void (*destructor)(void*)); void AddCleanupFallback(void* elem, void (*destructor)(void*)); inline void AllocateNewBlock(size_t n); inline void Init(ArenaBlock* b, size_t offset); public: static constexpr size_t kBlockHeaderSize = ArenaAlignDefault::Ceil(sizeof(ArenaBlock)); }; inline PROTOBUF_ALWAYS_INLINE bool SerialArena::MaybeAllocateString(void*& p) { // Check how many unused instances are in the current block. size_t unused_bytes = string_block_unused_.load(std::memory_order_relaxed); if (PROTOBUF_PREDICT_TRUE(unused_bytes != 0)) { unused_bytes -= sizeof(std::string); string_block_unused_.store(unused_bytes, std::memory_order_relaxed); p = string_block_->AtOffset(unused_bytes); return true; } return false; } template <> inline PROTOBUF_ALWAYS_INLINE void* SerialArena::MaybeAllocateWithCleanup() { void* p; return MaybeAllocateString(p) ? p : nullptr; } ABSL_ATTRIBUTE_RETURNS_NONNULL inline PROTOBUF_ALWAYS_INLINE void* SerialArena::AllocateFromStringBlock() { void* p; if (ABSL_PREDICT_TRUE(MaybeAllocateString(p))) return p; return AllocateFromStringBlockFallback(); } } // namespace internal } // namespace protobuf } // namespace google #include "google/protobuf/port_undef.inc" #endif // GOOGLE_PROTOBUF_SERIAL_ARENA_H__