compiler-rt/lib/xray/xray_buffer_queue.cpp - llvm-project - Git at Google

 //===-- xray_buffer_queue.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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of XRay, a dynamic runtime instruementation system.
 //
 // Defines the interface for a buffer queue implementation.
 //
 //===----------------------------------------------------------------------===//
 #include "xray_buffer_queue.h"
 #include "sanitizer_common/sanitizer_atomic.h"
 #include "sanitizer_common/sanitizer_common.h"
 #include "sanitizer_common/sanitizer_libc.h"
 #if !SANITIZER_FUCHSIA
 #include "sanitizer_common/sanitizer_posix.h"
 #endif
 #include "xray_allocator.h"
 #include "xray_defs.h"
 #include <memory>
 #include <sys/mman.h>

 using namespace __xray;

 namespace {

 BufferQueue::ControlBlock *allocControlBlock(size_t Size, size_t Count) {
   auto B =
       allocateBuffer((sizeof(BufferQueue::ControlBlock) - 1) + (Size * Count));
   return B == nullptr ? nullptr
                       : reinterpret_cast<BufferQueue::ControlBlock *>(B);
 }

 void deallocControlBlock(BufferQueue::ControlBlock *C, size_t Size,
                          size_t Count) {
   deallocateBuffer(reinterpret_cast<unsigned char *>(C),
                    (sizeof(BufferQueue::ControlBlock) - 1) + (Size * Count));
 }

 void decRefCount(BufferQueue::ControlBlock *C, size_t Size, size_t Count) {
   if (C == nullptr)
     return;
   if (atomic_fetch_sub(&C->RefCount, 1, memory_order_acq_rel) == 1)
     deallocControlBlock(C, Size, Count);
 }

 void incRefCount(BufferQueue::ControlBlock *C) {
   if (C == nullptr)
     return;
   atomic_fetch_add(&C->RefCount, 1, memory_order_acq_rel);
 }

 // We use a struct to ensure that we are allocating one atomic_uint64_t per
 // cache line. This allows us to not worry about false-sharing among atomic
 // objects being updated (constantly) by different threads.
 struct ExtentsPadded {
   union {
     atomic_uint64_t Extents;
     unsigned char Storage[kCacheLineSize];
   };
 };

 constexpr size_t kExtentsSize = sizeof(ExtentsPadded);

 } // namespace

 BufferQueue::ErrorCode BufferQueue::init(size_t BS, size_t BC) {
   SpinMutexLock Guard(&Mutex);

   if (!finalizing())
     return BufferQueue::ErrorCode::AlreadyInitialized;

   cleanupBuffers();

   bool Success = false;
   BufferSize = BS;
   BufferCount = BC;

   BackingStore = allocControlBlock(BufferSize, BufferCount);
   if (BackingStore == nullptr)
     return BufferQueue::ErrorCode::NotEnoughMemory;

   auto CleanupBackingStore = at_scope_exit([&, this] {
     if (Success)
       return;
     deallocControlBlock(BackingStore, BufferSize, BufferCount);
     BackingStore = nullptr;
   });

   // Initialize enough atomic_uint64_t instances, each
   ExtentsBackingStore = allocControlBlock(kExtentsSize, BufferCount);
   if (ExtentsBackingStore == nullptr)
     return BufferQueue::ErrorCode::NotEnoughMemory;

   auto CleanupExtentsBackingStore = at_scope_exit([&, this] {
     if (Success)
       return;
     deallocControlBlock(ExtentsBackingStore, kExtentsSize, BufferCount);
     ExtentsBackingStore = nullptr;
   });

   Buffers = initArray<BufferRep>(BufferCount);
   if (Buffers == nullptr)
     return BufferQueue::ErrorCode::NotEnoughMemory;

   // At this point we increment the generation number to associate the buffers
   // to the new generation.
   atomic_fetch_add(&Generation, 1, memory_order_acq_rel);

   // First, we initialize the refcount in the ControlBlock, which we treat as
   // being at the start of the BackingStore pointer.
   atomic_store(&BackingStore->RefCount, 1, memory_order_release);
   atomic_store(&ExtentsBackingStore->RefCount, 1, memory_order_release);

   // Then we initialise the individual buffers that sub-divide the whole backing
   // store. Each buffer will start at the `Data` member of the ControlBlock, and
   // will be offsets from these locations.
   for (size_t i = 0; i < BufferCount; ++i) {
     auto &T = Buffers[i];
     auto &Buf = T.Buff;
     auto *E = reinterpret_cast<ExtentsPadded *>(&ExtentsBackingStore->Data +
                                                 (kExtentsSize * i));
     Buf.Extents = &E->Extents;
     atomic_store(Buf.Extents, 0, memory_order_release);
     Buf.Generation = generation();
     Buf.Data = &BackingStore->Data + (BufferSize * i);
     Buf.Size = BufferSize;
     Buf.BackingStore = BackingStore;
     Buf.ExtentsBackingStore = ExtentsBackingStore;
     Buf.Count = BufferCount;
     T.Used = false;
   }

   Next = Buffers;
   First = Buffers;
   LiveBuffers = 0;
   atomic_store(&Finalizing, 0, memory_order_release);
   Success = true;
   return BufferQueue::ErrorCode::Ok;
 }

 BufferQueue::BufferQueue(size_t B, size_t N,
                          bool &Success) XRAY_NEVER_INSTRUMENT
     : BufferSize(B),
       BufferCount(N),
       Mutex(),
       Finalizing{1},
       BackingStore(nullptr),
       ExtentsBackingStore(nullptr),
       Buffers(nullptr),
       Next(Buffers),
       First(Buffers),
       LiveBuffers(0),
       Generation{0} {
   Success = init(B, N) == BufferQueue::ErrorCode::Ok;
 }

 BufferQueue::ErrorCode BufferQueue::getBuffer(Buffer &Buf) {
   if (atomic_load(&Finalizing, memory_order_acquire))
     return ErrorCode::QueueFinalizing;

   BufferRep *B = nullptr;
   {
     SpinMutexLock Guard(&Mutex);
     if (LiveBuffers == BufferCount)
       return ErrorCode::NotEnoughMemory;
     B = Next++;
     if (Next == (Buffers + BufferCount))
       Next = Buffers;
     ++LiveBuffers;
   }

   incRefCount(BackingStore);
   incRefCount(ExtentsBackingStore);
   Buf = B->Buff;
   Buf.Generation = generation();
   B->Used = true;
   return ErrorCode::Ok;
 }

 BufferQueue::ErrorCode BufferQueue::releaseBuffer(Buffer &Buf) {
   // Check whether the buffer being referred to is within the bounds of the
   // backing store's range.
   BufferRep *B = nullptr;
   {
     SpinMutexLock Guard(&Mutex);
     if (Buf.Generation != generation() || LiveBuffers == 0) {
       Buf = {};
       decRefCount(Buf.BackingStore, Buf.Size, Buf.Count);
       decRefCount(Buf.ExtentsBackingStore, kExtentsSize, Buf.Count);
       return BufferQueue::ErrorCode::Ok;
     }

     if (Buf.Data < &BackingStore->Data ||
         Buf.Data > &BackingStore->Data + (BufferCount * BufferSize))
       return BufferQueue::ErrorCode::UnrecognizedBuffer;

     --LiveBuffers;
     B = First++;
     if (First == (Buffers + BufferCount))
       First = Buffers;
   }

   // Now that the buffer has been released, we mark it as "used".
   B->Buff = Buf;
   B->Used = true;
   decRefCount(Buf.BackingStore, Buf.Size, Buf.Count);
   decRefCount(Buf.ExtentsBackingStore, kExtentsSize, Buf.Count);
   atomic_store(B->Buff.Extents, atomic_load(Buf.Extents, memory_order_acquire),
                memory_order_release);
   Buf = {};
   return ErrorCode::Ok;
 }

 BufferQueue::ErrorCode BufferQueue::finalize() {
   if (atomic_exchange(&Finalizing, 1, memory_order_acq_rel))
     return ErrorCode::QueueFinalizing;
   return ErrorCode::Ok;
 }

 void BufferQueue::cleanupBuffers() {
   for (auto B = Buffers, E = Buffers + BufferCount; B != E; ++B)
     B->~BufferRep();
   deallocateBuffer(Buffers, BufferCount);
   decRefCount(BackingStore, BufferSize, BufferCount);
   decRefCount(ExtentsBackingStore, kExtentsSize, BufferCount);
   BackingStore = nullptr;
   ExtentsBackingStore = nullptr;
   Buffers = nullptr;
   BufferCount = 0;
   BufferSize = 0;
 }

 BufferQueue::~BufferQueue() { cleanupBuffers(); }
	//===-- xray_buffer_queue.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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of XRay, a dynamic runtime instruementation system.
	//
	// Defines the interface for a buffer queue implementation.
	//
	//===----------------------------------------------------------------------===//
	#include "xray_buffer_queue.h"
	#include "sanitizer_common/sanitizer_atomic.h"
	#include "sanitizer_common/sanitizer_common.h"
	#include "sanitizer_common/sanitizer_libc.h"
	#if !SANITIZER_FUCHSIA
	#include "sanitizer_common/sanitizer_posix.h"
	#endif
	#include "xray_allocator.h"
	#include "xray_defs.h"
	#include <memory>
	#include <sys/mman.h>

	using namespace __xray;

	namespace {

	BufferQueue::ControlBlock *allocControlBlock(size_t Size, size_t Count) {
	auto B =
	allocateBuffer((sizeof(BufferQueue::ControlBlock) - 1) + (Size * Count));
	return B == nullptr ? nullptr
	: reinterpret_cast<BufferQueue::ControlBlock *>(B);
	}

	void deallocControlBlock(BufferQueue::ControlBlock *C, size_t Size,
	size_t Count) {
	deallocateBuffer(reinterpret_cast<unsigned char *>(C),
	(sizeof(BufferQueue::ControlBlock) - 1) + (Size * Count));
	}

	void decRefCount(BufferQueue::ControlBlock *C, size_t Size, size_t Count) {
	if (C == nullptr)
	return;
	if (atomic_fetch_sub(&C->RefCount, 1, memory_order_acq_rel) == 1)
	deallocControlBlock(C, Size, Count);
	}

	void incRefCount(BufferQueue::ControlBlock *C) {
	if (C == nullptr)
	return;
	atomic_fetch_add(&C->RefCount, 1, memory_order_acq_rel);
	}

	// We use a struct to ensure that we are allocating one atomic_uint64_t per
	// cache line. This allows us to not worry about false-sharing among atomic
	// objects being updated (constantly) by different threads.
	struct ExtentsPadded {
	union {
	atomic_uint64_t Extents;
	unsigned char Storage[kCacheLineSize];
	};
	};

	constexpr size_t kExtentsSize = sizeof(ExtentsPadded);

	} // namespace

	BufferQueue::ErrorCode BufferQueue::init(size_t BS, size_t BC) {
	SpinMutexLock Guard(&Mutex);

	if (!finalizing())
	return BufferQueue::ErrorCode::AlreadyInitialized;

	cleanupBuffers();

	bool Success = false;
	BufferSize = BS;
	BufferCount = BC;

	BackingStore = allocControlBlock(BufferSize, BufferCount);
	if (BackingStore == nullptr)
	return BufferQueue::ErrorCode::NotEnoughMemory;

	auto CleanupBackingStore = at_scope_exit([&, this] {
	if (Success)
	return;
	deallocControlBlock(BackingStore, BufferSize, BufferCount);
	BackingStore = nullptr;
	});

	// Initialize enough atomic_uint64_t instances, each
	ExtentsBackingStore = allocControlBlock(kExtentsSize, BufferCount);
	if (ExtentsBackingStore == nullptr)
	return BufferQueue::ErrorCode::NotEnoughMemory;

	auto CleanupExtentsBackingStore = at_scope_exit([&, this] {
	if (Success)
	return;
	deallocControlBlock(ExtentsBackingStore, kExtentsSize, BufferCount);
	ExtentsBackingStore = nullptr;
	});

	Buffers = initArray<BufferRep>(BufferCount);
	if (Buffers == nullptr)
	return BufferQueue::ErrorCode::NotEnoughMemory;

	// At this point we increment the generation number to associate the buffers
	// to the new generation.
	atomic_fetch_add(&Generation, 1, memory_order_acq_rel);

	// First, we initialize the refcount in the ControlBlock, which we treat as
	// being at the start of the BackingStore pointer.
	atomic_store(&BackingStore->RefCount, 1, memory_order_release);
	atomic_store(&ExtentsBackingStore->RefCount, 1, memory_order_release);

	// Then we initialise the individual buffers that sub-divide the whole backing
	// store. Each buffer will start at the `Data` member of the ControlBlock, and
	// will be offsets from these locations.
	for (size_t i = 0; i < BufferCount; ++i) {
	auto &T = Buffers[i];
	auto &Buf = T.Buff;
	auto E = reinterpret_cast<ExtentsPadded >(&ExtentsBackingStore->Data +
	(kExtentsSize * i));
	Buf.Extents = &E->Extents;
	atomic_store(Buf.Extents, 0, memory_order_release);
	Buf.Generation = generation();
	Buf.Data = &BackingStore->Data + (BufferSize * i);
	Buf.Size = BufferSize;
	Buf.BackingStore = BackingStore;
	Buf.ExtentsBackingStore = ExtentsBackingStore;
	Buf.Count = BufferCount;
	T.Used = false;
	}

	Next = Buffers;
	First = Buffers;
	LiveBuffers = 0;
	atomic_store(&Finalizing, 0, memory_order_release);
	Success = true;
	return BufferQueue::ErrorCode::Ok;
	}

	BufferQueue::BufferQueue(size_t B, size_t N,
	bool &Success) XRAY_NEVER_INSTRUMENT
	: BufferSize(B),
	BufferCount(N),
	Mutex(),
	Finalizing{1},
	BackingStore(nullptr),
	ExtentsBackingStore(nullptr),
	Buffers(nullptr),
	Next(Buffers),
	First(Buffers),
	LiveBuffers(0),
	Generation{0} {
	Success = init(B, N) == BufferQueue::ErrorCode::Ok;
	}

	BufferQueue::ErrorCode BufferQueue::getBuffer(Buffer &Buf) {
	if (atomic_load(&Finalizing, memory_order_acquire))
	return ErrorCode::QueueFinalizing;

	BufferRep *B = nullptr;
	{
	SpinMutexLock Guard(&Mutex);
	if (LiveBuffers == BufferCount)
	return ErrorCode::NotEnoughMemory;
	B = Next++;
	if (Next == (Buffers + BufferCount))
	Next = Buffers;
	++LiveBuffers;
	}

	incRefCount(BackingStore);
	incRefCount(ExtentsBackingStore);
	Buf = B->Buff;
	Buf.Generation = generation();
	B->Used = true;
	return ErrorCode::Ok;
	}

	BufferQueue::ErrorCode BufferQueue::releaseBuffer(Buffer &Buf) {
	// Check whether the buffer being referred to is within the bounds of the
	// backing store's range.
	BufferRep *B = nullptr;
	{
	SpinMutexLock Guard(&Mutex);
	if (Buf.Generation != generation() \|\| LiveBuffers == 0) {
	Buf = {};
	decRefCount(Buf.BackingStore, Buf.Size, Buf.Count);
	decRefCount(Buf.ExtentsBackingStore, kExtentsSize, Buf.Count);
	return BufferQueue::ErrorCode::Ok;
	}

	if (Buf.Data < &BackingStore->Data \|\|
	Buf.Data > &BackingStore->Data + (BufferCount * BufferSize))
	return BufferQueue::ErrorCode::UnrecognizedBuffer;

	--LiveBuffers;
	B = First++;
	if (First == (Buffers + BufferCount))
	First = Buffers;
	}

	// Now that the buffer has been released, we mark it as "used".
	B->Buff = Buf;
	B->Used = true;
	decRefCount(Buf.BackingStore, Buf.Size, Buf.Count);
	decRefCount(Buf.ExtentsBackingStore, kExtentsSize, Buf.Count);
	atomic_store(B->Buff.Extents, atomic_load(Buf.Extents, memory_order_acquire),
	memory_order_release);
	Buf = {};
	return ErrorCode::Ok;
	}

	BufferQueue::ErrorCode BufferQueue::finalize() {
	if (atomic_exchange(&Finalizing, 1, memory_order_acq_rel))
	return ErrorCode::QueueFinalizing;
	return ErrorCode::Ok;
	}

	void BufferQueue::cleanupBuffers() {
	for (auto B = Buffers, E = Buffers + BufferCount; B != E; ++B)
	B->~BufferRep();
	deallocateBuffer(Buffers, BufferCount);
	decRefCount(BackingStore, BufferSize, BufferCount);
	decRefCount(ExtentsBackingStore, kExtentsSize, BufferCount);
	BackingStore = nullptr;
	ExtentsBackingStore = nullptr;
	Buffers = nullptr;
	BufferCount = 0;
	BufferSize = 0;
	}

	BufferQueue::~BufferQueue() { cleanupBuffers(); }