enc/ringbuffer.h - external/github.com/google/brotli - Git at Google

 /* Copyright 2013 Google Inc. All Rights Reserved.

    Distributed under MIT license.
    See file LICENSE for detail or copy at https://opensource.org/licenses/MIT
 */

 // Sliding window over the input data.

 #ifndef BROTLI_ENC_RINGBUFFER_H_
 #define BROTLI_ENC_RINGBUFFER_H_


 #include "./port.h"
 #include "./types.h"

 namespace brotli {

 // A RingBuffer(window_bits, tail_bits) contains `1 << window_bits' bytes of
 // data in a circular manner: writing a byte writes it to
 // `position() % (1 << window_bits)'. For convenience, the RingBuffer array
 // contains another copy of the first `1 << tail_bits' bytes:
 // buffer_[i] == buffer_[i + (1 << window_bits)] if i < (1 << tail_bits).
 class RingBuffer {
  public:
   RingBuffer(int window_bits, int tail_bits)
       : size_((size_t(1) << window_bits)),
         mask_((size_t(1) << window_bits) - 1),
         tail_size_(size_t(1) << tail_bits),
         pos_(0) {
     static const int kSlackForEightByteHashingEverywhere = 7;
     const size_t buflen = size_ + tail_size_;
     buffer_ = new uint8_t[buflen + kSlackForEightByteHashingEverywhere];
     for (int i = 0; i < kSlackForEightByteHashingEverywhere; ++i) {
       buffer_[buflen + i] = 0;
     }
   }
   ~RingBuffer() {
     delete [] buffer_;
   }

   // Push bytes into the ring buffer.
   void Write(const uint8_t *bytes, size_t n) {
     const size_t masked_pos = pos_ & mask_;
     // The length of the writes is limited so that we do not need to worry
     // about a write
     WriteTail(bytes, n);
     if (PREDICT_TRUE(masked_pos + n <= size_)) {
       // A single write fits.
       memcpy(&buffer_[masked_pos], bytes, n);
     } else {
       // Split into two writes.
       // Copy into the end of the buffer, including the tail buffer.
       memcpy(&buffer_[masked_pos], bytes,
              std::min(n, (size_ + tail_size_) - masked_pos));
       // Copy into the beginning of the buffer
       memcpy(&buffer_[0], bytes + (size_ - masked_pos),
              n - (size_ - masked_pos));
     }
     pos_ += n;
   }

   void Reset() {
     pos_ = 0;
   }

   // Logical cursor position in the ring buffer.
   size_t position() const { return pos_; }

   // Bit mask for getting the physical position for a logical position.
   size_t mask() const { return mask_; }

   uint8_t *start() { return &buffer_[0]; }
   const uint8_t *start() const { return &buffer_[0]; }

  private:
   void WriteTail(const uint8_t *bytes, size_t n) {
     const size_t masked_pos = pos_ & mask_;
     if (PREDICT_FALSE(masked_pos < tail_size_)) {
       // Just fill the tail buffer with the beginning data.
       const size_t p = size_ + masked_pos;
       memcpy(&buffer_[p], bytes, std::min(n, tail_size_ - masked_pos));
     }
   }

   // Size of the ringbuffer is (1 << window_bits) + tail_size_.
   const size_t size_;
   const size_t mask_;
   const size_t tail_size_;

   // Position to write in the ring buffer.
   size_t pos_;
   // The actual ring buffer containing the data and the copy of the beginning
   // as a tail.
   uint8_t *buffer_;
 };

 }  // namespace brotli

 #endif  // BROTLI_ENC_RINGBUFFER_H_
	/* Copyright 2013 Google Inc. All Rights Reserved.

	Distributed under MIT license.
	See file LICENSE for detail or copy at https://opensource.org/licenses/MIT
	*/

	// Sliding window over the input data.

	#ifndef BROTLI_ENC_RINGBUFFER_H_
	#define BROTLI_ENC_RINGBUFFER_H_


	#include "./port.h"
	#include "./types.h"

	namespace brotli {

	// A RingBuffer(window_bits, tail_bits) contains `1 << window_bits' bytes of
	// data in a circular manner: writing a byte writes it to
	// `position() % (1 << window_bits)'. For convenience, the RingBuffer array
	// contains another copy of the first `1 << tail_bits' bytes:
	// buffer_[i] == buffer_[i + (1 << window_bits)] if i < (1 << tail_bits).
	class RingBuffer {
	public:
	RingBuffer(int window_bits, int tail_bits)
	: size_((size_t(1) << window_bits)),
	mask_((size_t(1) << window_bits) - 1),
	tail_size_(size_t(1) << tail_bits),
	pos_(0) {
	static const int kSlackForEightByteHashingEverywhere = 7;
	const size_t buflen = size_ + tail_size_;
	buffer_ = new uint8_t[buflen + kSlackForEightByteHashingEverywhere];
	for (int i = 0; i < kSlackForEightByteHashingEverywhere; ++i) {
	buffer_[buflen + i] = 0;
	}
	}
	~RingBuffer() {
	delete [] buffer_;
	}

	// Push bytes into the ring buffer.
	void Write(const uint8_t *bytes, size_t n) {
	const size_t masked_pos = pos_ & mask_;
	// The length of the writes is limited so that we do not need to worry
	// about a write
	WriteTail(bytes, n);
	if (PREDICT_TRUE(masked_pos + n <= size_)) {
	// A single write fits.
	memcpy(&buffer_[masked_pos], bytes, n);
	} else {
	// Split into two writes.
	// Copy into the end of the buffer, including the tail buffer.
	memcpy(&buffer_[masked_pos], bytes,
	std::min(n, (size_ + tail_size_) - masked_pos));
	// Copy into the beginning of the buffer
	memcpy(&buffer_[0], bytes + (size_ - masked_pos),
	n - (size_ - masked_pos));
	}
	pos_ += n;
	}

	void Reset() {
	pos_ = 0;
	}

	// Logical cursor position in the ring buffer.
	size_t position() const { return pos_; }

	// Bit mask for getting the physical position for a logical position.
	size_t mask() const { return mask_; }

	uint8_t *start() { return &buffer_[0]; }
	const uint8_t *start() const { return &buffer_[0]; }

	private:
	void WriteTail(const uint8_t *bytes, size_t n) {
	const size_t masked_pos = pos_ & mask_;
	if (PREDICT_FALSE(masked_pos < tail_size_)) {
	// Just fill the tail buffer with the beginning data.
	const size_t p = size_ + masked_pos;
	memcpy(&buffer_[p], bytes, std::min(n, tail_size_ - masked_pos));
	}
	}

	// Size of the ringbuffer is (1 << window_bits) + tail_size_.
	const size_t size_;
	const size_t mask_;
	const size_t tail_size_;

	// Position to write in the ring buffer.
	size_t pos_;
	// The actual ring buffer containing the data and the copy of the beginning
	// as a tail.
	uint8_t *buffer_;
	};

	} // namespace brotli

	#endif // BROTLI_ENC_RINGBUFFER_H_