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

 //===-- xray_buffer_queue.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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of XRay, a dynamic runtime instrumentation system.
 //
 // Defines the interface for a buffer queue implementation.
 //
 //===----------------------------------------------------------------------===//
 #ifndef XRAY_BUFFER_QUEUE_H
 #define XRAY_BUFFER_QUEUE_H

 #include "sanitizer_common/sanitizer_atomic.h"
 #include "sanitizer_common/sanitizer_common.h"
 #include "sanitizer_common/sanitizer_mutex.h"
 #include "xray_defs.h"
 #include <cstddef>
 #include <cstdint>

 namespace __xray {

 /// BufferQueue implements a circular queue of fixed sized buffers (much like a
 /// freelist) but is concerned with making it quick to initialise, finalise, and
 /// get from or return buffers to the queue. This is one key component of the
 /// "flight data recorder" (FDR) mode to support ongoing XRay function call
 /// trace collection.
 class BufferQueue {
 public:
   /// ControlBlock represents the memory layout of how we interpret the backing
   /// store for all buffers and extents managed by a BufferQueue instance. The
   /// ControlBlock has the reference count as the first member, sized according
   /// to platform-specific cache-line size. We never use the Buffer member of
   /// the union, which is only there for compiler-supported alignment and
   /// sizing.
   ///
   /// This ensures that the `Data` member will be placed at least kCacheLineSize
   /// bytes from the beginning of the structure.
   struct ControlBlock {
     union {
       atomic_uint64_t RefCount;
       char Buffer[kCacheLineSize];
     };

     /// We need to make this size 1, to conform to the C++ rules for array data
     /// members. Typically, we want to subtract this 1 byte for sizing
     /// information.
     char Data[1];
   };

   struct Buffer {
     atomic_uint64_t *Extents = nullptr;
     uint64_t Generation{0};
     void *Data = nullptr;
     size_t Size = 0;

   private:
     friend class BufferQueue;
     ControlBlock *BackingStore = nullptr;
     ControlBlock *ExtentsBackingStore = nullptr;
     size_t Count = 0;
   };

   struct BufferRep {
     // The managed buffer.
     Buffer Buff;

     // This is true if the buffer has been returned to the available queue, and
     // is considered "used" by another thread.
     bool Used = false;
   };

 private:
   // This models a ForwardIterator. |T| Must be either a `Buffer` or `const
   // Buffer`. Note that we only advance to the "used" buffers, when
   // incrementing, so that at dereference we're always at a valid point.
   template <class T> class Iterator {
   public:
     BufferRep *Buffers = nullptr;
     size_t Offset = 0;
     size_t Max = 0;

     Iterator &operator++() {
       DCHECK_NE(Offset, Max);
       do {
         ++Offset;
       } while (!Buffers[Offset].Used && Offset != Max);
       return *this;
     }

     Iterator operator++(int) {
       Iterator C = *this;
       ++(*this);
       return C;
     }

     T &operator*() const { return Buffers[Offset].Buff; }

     T *operator->() const { return &(Buffers[Offset].Buff); }

     Iterator(BufferRep *Root, size_t O, size_t M) XRAY_NEVER_INSTRUMENT
         : Buffers(Root),
           Offset(O),
           Max(M) {
       // We want to advance to the first Offset where the 'Used' property is
       // true, or to the end of the list/queue.
       while (!Buffers[Offset].Used && Offset != Max) {
         ++Offset;
       }
     }

     Iterator() = default;
     Iterator(const Iterator &) = default;
     Iterator(Iterator &&) = default;
     Iterator &operator=(const Iterator &) = default;
     Iterator &operator=(Iterator &&) = default;
     ~Iterator() = default;

     template <class V>
     friend bool operator==(const Iterator &L, const Iterator<V> &R) {
       DCHECK_EQ(L.Max, R.Max);
       return L.Buffers == R.Buffers && L.Offset == R.Offset;
     }

     template <class V>
     friend bool operator!=(const Iterator &L, const Iterator<V> &R) {
       return !(L == R);
     }
   };

   // Size of each individual Buffer.
   size_t BufferSize;

   // Amount of pre-allocated buffers.
   size_t BufferCount;

   SpinMutex Mutex;
   atomic_uint8_t Finalizing;

   // The collocated ControlBlock and buffer storage.
   ControlBlock *BackingStore;

   // The collocated ControlBlock and extents storage.
   ControlBlock *ExtentsBackingStore;

   // A dynamically allocated array of BufferRep instances.
   BufferRep *Buffers;

   // Pointer to the next buffer to be handed out.
   BufferRep *Next;

   // Pointer to the entry in the array where the next released buffer will be
   // placed.
   BufferRep *First;

   // Count of buffers that have been handed out through 'getBuffer'.
   size_t LiveBuffers;

   // We use a generation number to identify buffers and which generation they're
   // associated with.
   atomic_uint64_t Generation;

   /// Releases references to the buffers backed by the current buffer queue.
   void cleanupBuffers();

 public:
   enum class ErrorCode : unsigned {
     Ok,
     NotEnoughMemory,
     QueueFinalizing,
     UnrecognizedBuffer,
     AlreadyFinalized,
     AlreadyInitialized,
   };

   static const char *getErrorString(ErrorCode E) {
     switch (E) {
     case ErrorCode::Ok:
       return "(none)";
     case ErrorCode::NotEnoughMemory:
       return "no available buffers in the queue";
     case ErrorCode::QueueFinalizing:
       return "queue already finalizing";
     case ErrorCode::UnrecognizedBuffer:
       return "buffer being returned not owned by buffer queue";
     case ErrorCode::AlreadyFinalized:
       return "queue already finalized";
     case ErrorCode::AlreadyInitialized:
       return "queue already initialized";
     }
     return "unknown error";
   }

   /// Initialise a queue of size |N| with buffers of size |B|. We report success
   /// through |Success|.
   BufferQueue(size_t B, size_t N, bool &Success);

   /// Updates |Buf| to contain the pointer to an appropriate buffer. Returns an
   /// error in case there are no available buffers to return when we will run
   /// over the upper bound for the total buffers.
   ///
   /// Requirements:
   ///   - BufferQueue is not finalising.
   ///
   /// Returns:
   ///   - ErrorCode::NotEnoughMemory on exceeding MaxSize.
   ///   - ErrorCode::Ok when we find a Buffer.
   ///   - ErrorCode::QueueFinalizing or ErrorCode::AlreadyFinalized on
   ///     a finalizing/finalized BufferQueue.
   ErrorCode getBuffer(Buffer &Buf);

   /// Updates |Buf| to point to nullptr, with size 0.
   ///
   /// Returns:
   ///   - ErrorCode::Ok when we successfully release the buffer.
   ///   - ErrorCode::UnrecognizedBuffer for when this BufferQueue does not own
   ///     the buffer being released.
   ErrorCode releaseBuffer(Buffer &Buf);

   /// Initializes the buffer queue, starting a new generation. We can re-set the
   /// size of buffers with |BS| along with the buffer count with |BC|.
   ///
   /// Returns:
   ///   - ErrorCode::Ok when we successfully initialize the buffer. This
   ///   requires that the buffer queue is previously finalized.
   ///   - ErrorCode::AlreadyInitialized when the buffer queue is not finalized.
   ErrorCode init(size_t BS, size_t BC);

   bool finalizing() const {
     return atomic_load(&Finalizing, memory_order_acquire);
   }

   uint64_t generation() const {
     return atomic_load(&Generation, memory_order_acquire);
   }

   /// Returns the configured size of the buffers in the buffer queue.
   size_t ConfiguredBufferSize() const { return BufferSize; }

   /// Sets the state of the BufferQueue to finalizing, which ensures that:
   ///
   ///   - All subsequent attempts to retrieve a Buffer will fail.
   ///   - All releaseBuffer operations will not fail.
   ///
   /// After a call to finalize succeeds, all subsequent calls to finalize will
   /// fail with ErrorCode::QueueFinalizing.
   ErrorCode finalize();

   /// Applies the provided function F to each Buffer in the queue, only if the
   /// Buffer is marked 'used' (i.e. has been the result of getBuffer(...) and a
   /// releaseBuffer(...) operation).
   template <class F> void apply(F Fn) XRAY_NEVER_INSTRUMENT {
     SpinMutexLock G(&Mutex);
     for (auto I = begin(), E = end(); I != E; ++I)
       Fn(*I);
   }

   using const_iterator = Iterator<const Buffer>;
   using iterator = Iterator<Buffer>;

   /// Provides iterator access to the raw Buffer instances.
   iterator begin() const { return iterator(Buffers, 0, BufferCount); }
   const_iterator cbegin() const {
     return const_iterator(Buffers, 0, BufferCount);
   }
   iterator end() const { return iterator(Buffers, BufferCount, BufferCount); }
   const_iterator cend() const {
     return const_iterator(Buffers, BufferCount, BufferCount);
   }

   // Cleans up allocated buffers.
   ~BufferQueue();
 };

 } // namespace __xray

 #endif // XRAY_BUFFER_QUEUE_H
	//===-- xray_buffer_queue.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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of XRay, a dynamic runtime instrumentation system.
	//
	// Defines the interface for a buffer queue implementation.
	//
	//===----------------------------------------------------------------------===//
	#ifndef XRAY_BUFFER_QUEUE_H
	#define XRAY_BUFFER_QUEUE_H

	#include "sanitizer_common/sanitizer_atomic.h"
	#include "sanitizer_common/sanitizer_common.h"
	#include "sanitizer_common/sanitizer_mutex.h"
	#include "xray_defs.h"
	#include <cstddef>
	#include <cstdint>

	namespace __xray {

	/// BufferQueue implements a circular queue of fixed sized buffers (much like a
	/// freelist) but is concerned with making it quick to initialise, finalise, and
	/// get from or return buffers to the queue. This is one key component of the
	/// "flight data recorder" (FDR) mode to support ongoing XRay function call
	/// trace collection.
	class BufferQueue {
	public:
	/// ControlBlock represents the memory layout of how we interpret the backing
	/// store for all buffers and extents managed by a BufferQueue instance. The
	/// ControlBlock has the reference count as the first member, sized according
	/// to platform-specific cache-line size. We never use the Buffer member of
	/// the union, which is only there for compiler-supported alignment and
	/// sizing.
	///
	/// This ensures that the `Data` member will be placed at least kCacheLineSize
	/// bytes from the beginning of the structure.
	struct ControlBlock {
	union {
	atomic_uint64_t RefCount;
	char Buffer[kCacheLineSize];
	};

	/// We need to make this size 1, to conform to the C++ rules for array data
	/// members. Typically, we want to subtract this 1 byte for sizing
	/// information.
	char Data[1];
	};

	struct Buffer {
	atomic_uint64_t *Extents = nullptr;
	uint64_t Generation{0};
	void *Data = nullptr;
	size_t Size = 0;

	private:
	friend class BufferQueue;
	ControlBlock *BackingStore = nullptr;
	ControlBlock *ExtentsBackingStore = nullptr;
	size_t Count = 0;
	};

	struct BufferRep {
	// The managed buffer.
	Buffer Buff;

	// This is true if the buffer has been returned to the available queue, and
	// is considered "used" by another thread.
	bool Used = false;
	};

	private:
	// This models a ForwardIterator. \|T\| Must be either a `Buffer` or `const
	// Buffer`. Note that we only advance to the "used" buffers, when
	// incrementing, so that at dereference we're always at a valid point.
	template <class T> class Iterator {
	public:
	BufferRep *Buffers = nullptr;
	size_t Offset = 0;
	size_t Max = 0;

	Iterator &operator++() {
	DCHECK_NE(Offset, Max);
	do {
	++Offset;
	} while (!Buffers[Offset].Used && Offset != Max);
	return *this;
	}

	Iterator operator++(int) {
	Iterator C = *this;
	++(*this);
	return C;
	}

	T &operator*() const { return Buffers[Offset].Buff; }

	T *operator->() const { return &(Buffers[Offset].Buff); }

	Iterator(BufferRep *Root, size_t O, size_t M) XRAY_NEVER_INSTRUMENT
	: Buffers(Root),
	Offset(O),
	Max(M) {
	// We want to advance to the first Offset where the 'Used' property is
	// true, or to the end of the list/queue.
	while (!Buffers[Offset].Used && Offset != Max) {
	++Offset;
	}
	}

	Iterator() = default;
	Iterator(const Iterator &) = default;
	Iterator(Iterator &&) = default;
	Iterator &operator=(const Iterator &) = default;
	Iterator &operator=(Iterator &&) = default;
	~Iterator() = default;

	template <class V>
	friend bool operator==(const Iterator &L, const Iterator<V> &R) {
	DCHECK_EQ(L.Max, R.Max);
	return L.Buffers == R.Buffers && L.Offset == R.Offset;
	}

	template <class V>
	friend bool operator!=(const Iterator &L, const Iterator<V> &R) {
	return !(L == R);
	}
	};

	// Size of each individual Buffer.
	size_t BufferSize;

	// Amount of pre-allocated buffers.
	size_t BufferCount;

	SpinMutex Mutex;
	atomic_uint8_t Finalizing;

	// The collocated ControlBlock and buffer storage.
	ControlBlock *BackingStore;

	// The collocated ControlBlock and extents storage.
	ControlBlock *ExtentsBackingStore;

	// A dynamically allocated array of BufferRep instances.
	BufferRep *Buffers;

	// Pointer to the next buffer to be handed out.
	BufferRep *Next;

	// Pointer to the entry in the array where the next released buffer will be
	// placed.
	BufferRep *First;

	// Count of buffers that have been handed out through 'getBuffer'.
	size_t LiveBuffers;

	// We use a generation number to identify buffers and which generation they're
	// associated with.
	atomic_uint64_t Generation;

	/// Releases references to the buffers backed by the current buffer queue.
	void cleanupBuffers();

	public:
	enum class ErrorCode : unsigned {
	Ok,
	NotEnoughMemory,
	QueueFinalizing,
	UnrecognizedBuffer,
	AlreadyFinalized,
	AlreadyInitialized,
	};

	static const char *getErrorString(ErrorCode E) {
	switch (E) {
	case ErrorCode::Ok:
	return "(none)";
	case ErrorCode::NotEnoughMemory:
	return "no available buffers in the queue";
	case ErrorCode::QueueFinalizing:
	return "queue already finalizing";
	case ErrorCode::UnrecognizedBuffer:
	return "buffer being returned not owned by buffer queue";
	case ErrorCode::AlreadyFinalized:
	return "queue already finalized";
	case ErrorCode::AlreadyInitialized:
	return "queue already initialized";
	}
	return "unknown error";
	}

	/// Initialise a queue of size \|N\| with buffers of size \|B\|. We report success
	/// through \|Success\|.
	BufferQueue(size_t B, size_t N, bool &Success);

	/// Updates \|Buf\| to contain the pointer to an appropriate buffer. Returns an
	/// error in case there are no available buffers to return when we will run
	/// over the upper bound for the total buffers.
	///
	/// Requirements:
	/// - BufferQueue is not finalising.
	///
	/// Returns:
	/// - ErrorCode::NotEnoughMemory on exceeding MaxSize.
	/// - ErrorCode::Ok when we find a Buffer.
	/// - ErrorCode::QueueFinalizing or ErrorCode::AlreadyFinalized on
	/// a finalizing/finalized BufferQueue.
	ErrorCode getBuffer(Buffer &Buf);

	/// Updates \|Buf\| to point to nullptr, with size 0.
	///
	/// Returns:
	/// - ErrorCode::Ok when we successfully release the buffer.
	/// - ErrorCode::UnrecognizedBuffer for when this BufferQueue does not own
	/// the buffer being released.
	ErrorCode releaseBuffer(Buffer &Buf);

	/// Initializes the buffer queue, starting a new generation. We can re-set the
	/// size of buffers with \|BS\| along with the buffer count with \|BC\|.
	///
	/// Returns:
	/// - ErrorCode::Ok when we successfully initialize the buffer. This
	/// requires that the buffer queue is previously finalized.
	/// - ErrorCode::AlreadyInitialized when the buffer queue is not finalized.
	ErrorCode init(size_t BS, size_t BC);

	bool finalizing() const {
	return atomic_load(&Finalizing, memory_order_acquire);
	}

	uint64_t generation() const {
	return atomic_load(&Generation, memory_order_acquire);
	}

	/// Returns the configured size of the buffers in the buffer queue.
	size_t ConfiguredBufferSize() const { return BufferSize; }

	/// Sets the state of the BufferQueue to finalizing, which ensures that:
	///
	/// - All subsequent attempts to retrieve a Buffer will fail.
	/// - All releaseBuffer operations will not fail.
	///
	/// After a call to finalize succeeds, all subsequent calls to finalize will
	/// fail with ErrorCode::QueueFinalizing.
	ErrorCode finalize();

	/// Applies the provided function F to each Buffer in the queue, only if the
	/// Buffer is marked 'used' (i.e. has been the result of getBuffer(...) and a
	/// releaseBuffer(...) operation).
	template <class F> void apply(F Fn) XRAY_NEVER_INSTRUMENT {
	SpinMutexLock G(&Mutex);
	for (auto I = begin(), E = end(); I != E; ++I)
	Fn(*I);
	}

	using const_iterator = Iterator<const Buffer>;
	using iterator = Iterator<Buffer>;

	/// Provides iterator access to the raw Buffer instances.
	iterator begin() const { return iterator(Buffers, 0, BufferCount); }
	const_iterator cbegin() const {
	return const_iterator(Buffers, 0, BufferCount);
	}
	iterator end() const { return iterator(Buffers, BufferCount, BufferCount); }
	const_iterator cend() const {
	return const_iterator(Buffers, BufferCount, BufferCount);
	}

	// Cleans up allocated buffers.
	~BufferQueue();
	};

	} // namespace __xray

	#endif // XRAY_BUFFER_QUEUE_H