// Copyright 2014 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.

#include "base/logging.h"
#include "media/filters/h264_bit_reader.h"

namespace media {

H264BitReader::H264BitReader()
    : data_(NULL),
      bytes_left_(0),
      curr_byte_(0),
      num_remaining_bits_in_curr_byte_(0),
      prev_two_bytes_(0),
      emulation_prevention_bytes_(0) {}

H264BitReader::~H264BitReader() {}

bool H264BitReader::Initialize(const uint8* data, off_t size) {
  DCHECK(data);

  if (size < 1)
    return false;

  data_ = data;
  bytes_left_ = size;
  num_remaining_bits_in_curr_byte_ = 0;
  // Initially set to 0xffff to accept all initial two-byte sequences.
  prev_two_bytes_ = 0xffff;
  emulation_prevention_bytes_ = 0;

  return true;
}

bool H264BitReader::UpdateCurrByte() {
  if (bytes_left_ < 1)
    return false;

  // Emulation prevention three-byte detection.
  // If a sequence of 0x000003 is found, skip (ignore) the last byte (0x03).
  if (*data_ == 0x03 && (prev_two_bytes_ & 0xffff) == 0) {
    // Detected 0x000003, skip last byte.
    ++data_;
    --bytes_left_;
    ++emulation_prevention_bytes_;
    // Need another full three bytes before we can detect the sequence again.
    prev_two_bytes_ = 0xffff;

    if (bytes_left_ < 1)
      return false;
  }

  // Load a new byte and advance pointers.
  curr_byte_ = *data_++ & 0xff;
  --bytes_left_;
  num_remaining_bits_in_curr_byte_ = 8;

  prev_two_bytes_ = (prev_two_bytes_ << 8) | curr_byte_;

  return true;
}

// Read |num_bits| (1 to 31 inclusive) from the stream and return them
// in |out|, with first bit in the stream as MSB in |out| at position
// (|num_bits| - 1).
bool H264BitReader::ReadBits(int num_bits, int* out) {
  int bits_left = num_bits;
  *out = 0;
  DCHECK(num_bits <= 31);

  while (num_remaining_bits_in_curr_byte_ < bits_left) {
    // Take all that's left in current byte, shift to make space for the rest.
    *out |= (curr_byte_ << (bits_left - num_remaining_bits_in_curr_byte_));
    bits_left -= num_remaining_bits_in_curr_byte_;

    if (!UpdateCurrByte())
      return false;
  }

  *out |= (curr_byte_ >> (num_remaining_bits_in_curr_byte_ - bits_left));
  *out &= ((1 << num_bits) - 1);
  num_remaining_bits_in_curr_byte_ -= bits_left;

  return true;
}

off_t H264BitReader::NumBitsLeft() {
  return (num_remaining_bits_in_curr_byte_ + bytes_left_ * 8);
}

bool H264BitReader::HasMoreRBSPData() {
  // Make sure we have more bits, if we are at 0 bits in current byte
  // and updating current byte fails, we don't have more data anyway.
  if (num_remaining_bits_in_curr_byte_ == 0 && !UpdateCurrByte())
    return false;

  // On last byte?
  if (bytes_left_)
    return true;

  // Last byte, look for stop bit;
  // We have more RBSP data if the last non-zero bit we find is not the
  // first available bit.
  return (curr_byte_ &
          ((1 << (num_remaining_bits_in_curr_byte_ - 1)) - 1)) != 0;
}

size_t H264BitReader::NumEmulationPreventionBytesRead() {
  return emulation_prevention_bytes_;
}

}  // namespace media