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// Copyright (c) 2011 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.

// Software adjust volume of samples, allows each audio stream its own
// volume without impacting master volume for chrome and other applications.

// Implemented as templates to allow 8, 16 and 32 bit implementations.
// 8 bit is unsigned and biased by 128.

#include <algorithm>

#include "base/atomicops.h"
#include "base/basictypes.h"
#include "base/logging.h"
#include "base/shared_memory.h"
#if defined(OS_WIN)
#include "base/win/windows_version.h"
#endif
#include "media/audio/audio_util.h"
#if defined(OS_MACOSX)
#include "media/audio/mac/audio_low_latency_input_mac.h"
#include "media/audio/mac/audio_low_latency_output_mac.h"
#endif
#if defined(OS_WIN)
#include "media/audio/win/audio_low_latency_input_win.h"
#endif

using base::subtle::Atomic32;

const uint32 kUnknownDataSize = static_cast<uint32>(-1);

namespace media {

// TODO(fbarchard): Convert to intrinsics for better efficiency.
template<class Fixed>
static int ScaleChannel(int channel, int volume) {
  return static_cast<int>((static_cast<Fixed>(channel) * volume) >> 16);
}

template<class Format, class Fixed, int bias>
static void AdjustVolume(Format* buf_out,
                         int sample_count,
                         int fixed_volume) {
  for (int i = 0; i < sample_count; ++i) {
    buf_out[i] = static_cast<Format>(ScaleChannel<Fixed>(buf_out[i] - bias,
                                                         fixed_volume) + bias);
  }
}

static const int kChannel_L = 0;
static const int kChannel_R = 1;
static const int kChannel_C = 2;

template<class Fixed, int min_value, int max_value>
static int AddChannel(int val, int adder) {
  Fixed sum = static_cast<Fixed>(val) + static_cast<Fixed>(adder);
  if (sum > max_value)
    return max_value;
  if (sum < min_value)
    return min_value;
  return static_cast<int>(sum);
}

// FoldChannels() downmixes multichannel (ie 5.1 Surround Sound) to Stereo.
// Left and Right channels are preserved asis, and Center channel is
// distributed equally to both sides.  To be perceptually 1/2 volume on
// both channels, 1/sqrt(2) is used instead of 1/2.
// Fixed point math is used for efficiency.  16 bits of fraction and 8,16 or 32
// bits of integer are used.
// 8 bit samples are unsigned and 128 represents 0, so a bias is removed before
// doing calculations, then readded for the final output.
template<class Format, class Fixed, int min_value, int max_value, int bias>
static void FoldChannels(Format* buf_out,
                         int sample_count,
                         const float volume,
                         int channels) {
  Format* buf_in = buf_out;
  const int center_volume = static_cast<int>(volume * 0.707f * 65536);
  const int fixed_volume = static_cast<int>(volume * 65536);

  for (int i = 0; i < sample_count; ++i) {
    int center = static_cast<int>(buf_in[kChannel_C] - bias);
    int left = static_cast<int>(buf_in[kChannel_L] - bias);
    int right = static_cast<int>(buf_in[kChannel_R] - bias);

    center = ScaleChannel<Fixed>(center, center_volume);
    left = ScaleChannel<Fixed>(left, fixed_volume);
    right = ScaleChannel<Fixed>(right, fixed_volume);

    buf_out[0] = static_cast<Format>(
        AddChannel<Fixed, min_value, max_value>(left, center) + bias);
    buf_out[1] = static_cast<Format>(
        AddChannel<Fixed, min_value, max_value>(right, center) + bias);

    buf_out += 2;
    buf_in += channels;
  }
}

// AdjustVolume() does an in place audio sample change.
bool AdjustVolume(void* buf,
                  size_t buflen,
                  int channels,
                  int bytes_per_sample,
                  float volume) {
  DCHECK(buf);
  if (volume < 0.0f || volume > 1.0f)
    return false;
  if (volume == 1.0f) {
    return true;
  } else if (volume == 0.0f) {
    memset(buf, 0, buflen);
    return true;
  }
  if (channels > 0 && channels <= 8 && bytes_per_sample > 0) {
    int sample_count = buflen / bytes_per_sample;
    const int fixed_volume = static_cast<int>(volume * 65536);
    if (bytes_per_sample == 1) {
      AdjustVolume<uint8, int32, 128>(reinterpret_cast<uint8*>(buf),
                                      sample_count,
                                      fixed_volume);
      return true;
    } else if (bytes_per_sample == 2) {
      AdjustVolume<int16, int32, 0>(reinterpret_cast<int16*>(buf),
                                    sample_count,
                                    fixed_volume);
      return true;
    } else if (bytes_per_sample == 4) {
      AdjustVolume<int32, int64, 0>(reinterpret_cast<int32*>(buf),
                                    sample_count,
                                    fixed_volume);
      return true;
    }
  }
  return false;
}

bool FoldChannels(void* buf,
                  size_t buflen,
                  int channels,
                  int bytes_per_sample,
                  float volume) {
  DCHECK(buf);
  if (volume < 0.0f || volume > 1.0f)
    return false;
  if (channels > 2 && channels <= 8 && bytes_per_sample > 0) {
    int sample_count = buflen / (channels * bytes_per_sample);
    if (bytes_per_sample == 1) {
      FoldChannels<uint8, int32, -128, 127, 128>(
          reinterpret_cast<uint8*>(buf),
          sample_count,
          volume,
          channels);
      return true;
    } else if (bytes_per_sample == 2) {
      FoldChannels<int16, int32, -32768, 32767, 0>(
          reinterpret_cast<int16*>(buf),
          sample_count,
          volume,
          channels);
      return true;
    } else if (bytes_per_sample == 4) {
      FoldChannels<int32, int64, 0x80000000, 0x7fffffff, 0>(
          reinterpret_cast<int32*>(buf),
          sample_count,
          volume,
          channels);
      return true;
    }
  }
  return false;
}

bool DeinterleaveAudioChannel(void* source,
                              float* destination,
                              int channels,
                              int channel_index,
                              int bytes_per_sample,
                              size_t number_of_frames) {
  switch (bytes_per_sample) {
    case 1:
    {
      uint8* source8 = static_cast<uint8*>(source) + channel_index;
      const float kScale = 1.0f / 128.0f;
      for (unsigned i = 0; i < number_of_frames; ++i) {
        destination[i] = kScale * (static_cast<int>(*source8) - 128);
        source8 += channels;
      }
      return true;
    }

    case 2:
    {
      int16* source16 = static_cast<int16*>(source) + channel_index;
      const float kScale = 1.0f / 32768.0f;
      for (unsigned i = 0; i < number_of_frames; ++i) {
        destination[i] = kScale * *source16;
        source16 += channels;
      }
      return true;
    }

    case 4:
    {
      int32* source32 = static_cast<int32*>(source) + channel_index;
      const float kScale = 1.0f / (1L << 31);
      for (unsigned i = 0; i < number_of_frames; ++i) {
        destination[i] = kScale * *source32;
        source32 += channels;
      }
      return true;
    }

    default:
     break;
  }
  return false;
}

void InterleaveFloatToInt16(const std::vector<float*>& source,
                            int16* destination,
                            size_t number_of_frames) {
  const float kScale = 32768.0f;
  int channels = source.size();
  for (int i = 0; i < channels; ++i) {
    float* channel_data = source[i];
    for (size_t j = 0; j < number_of_frames; ++j) {
      float sample = kScale * channel_data[j];
      if (sample < -32768.0)
        sample = -32768.0;
      else if (sample > 32767.0)
        sample = 32767.0;

      destination[j * channels + i] = static_cast<int16>(sample);
    }
  }
}

double GetAudioHardwareSampleRate() {
#if defined(OS_MACOSX)
    // Hardware sample-rate on the Mac can be configured, so we must query.
    return AUAudioOutputStream::HardwareSampleRate();
#else
    // Hardware for Windows and Linux is nearly always 48KHz.
    // TODO(crogers) : return correct value in rare non-48KHz cases.
    return 48000.0;
#endif
}

double GetAudioInputHardwareSampleRate() {
#if defined(OS_MACOSX)
  // Hardware sample-rate on the Mac can be configured, so we must query.
  return AUAudioInputStream::HardwareSampleRate();
#elif defined(OS_WIN)
  if (base::win::GetVersion() <= base::win::VERSION_XP) {
    // Fall back to Windows Wave implementation on Windows XP or lower
    // and use 48kHz as default input sample rate.
    return 48000.0;
  } else {
    // Hardware sample-rate on Windows can be configured, so we must query.
    // TODO(henrika): improve possibility to specify audio endpoint.
    // Use the default device (same as for Wave) for now to be compatible.
    return WASAPIAudioInputStream::HardwareSampleRate(eConsole);
  }
#else
  // Hardware for Linux is nearly always 48KHz.
  // TODO(henrika): return correct value in rare non-48KHz cases.
  return 48000.0;
#endif
}

size_t GetAudioHardwareBufferSize() {
  // The sizes here were determined by experimentation and are roughly
  // the lowest value (for low latency) that still allowed glitch-free
  // audio under high loads.
  //
  // For Mac OS X the chromium audio backend uses a low-latency
  // CoreAudio API, so a low buffer size is possible.  For other OSes,
  // further tuning may be needed.
#if defined(OS_MACOSX)
  return 128;
#elif defined(OS_LINUX)
  return 2048;
#else
  return 2048;
#endif
}

// When transferring data in the shared memory, first word is size of data
// in bytes. Actual data starts immediately after it.

uint32 TotalSharedMemorySizeInBytes(uint32 packet_size) {
  // Need to reserve extra 4 bytes for size of data.
  return packet_size + sizeof(Atomic32);
}

uint32 PacketSizeSizeInBytes(uint32 shared_memory_created_size) {
  return shared_memory_created_size - sizeof(Atomic32);
}

uint32 GetActualDataSizeInBytes(base::SharedMemory* shared_memory,
                                uint32 shared_memory_size) {
  char* ptr = static_cast<char*>(shared_memory->memory()) + shared_memory_size;
  DCHECK_EQ(0u, reinterpret_cast<size_t>(ptr) & 3);

  // Actual data size stored at the end of the buffer.
  uint32 actual_data_size =
      base::subtle::Acquire_Load(reinterpret_cast<volatile Atomic32*>(ptr));
  return std::min(actual_data_size, shared_memory_size);
}

void SetActualDataSizeInBytes(base::SharedMemory* shared_memory,
                              uint32 shared_memory_size,
                              uint32 actual_data_size) {
  char* ptr = static_cast<char*>(shared_memory->memory()) + shared_memory_size;
  DCHECK_EQ(0u, reinterpret_cast<size_t>(ptr) & 3);

  // Set actual data size at the end of the buffer.
  base::subtle::Release_Store(reinterpret_cast<volatile Atomic32*>(ptr),
                              actual_data_size);
}

void SetUnknownDataSize(base::SharedMemory* shared_memory,
                        uint32 shared_memory_size) {
  SetActualDataSizeInBytes(shared_memory, shared_memory_size, kUnknownDataSize);
}

bool IsUnknownDataSize(base::SharedMemory* shared_memory,
                       uint32 shared_memory_size) {
  char* ptr = static_cast<char*>(shared_memory->memory()) + shared_memory_size;
  DCHECK_EQ(0u, reinterpret_cast<size_t>(ptr) & 3);

  // Actual data size stored at the end of the buffer.
  uint32 actual_data_size =
      base::subtle::Acquire_Load(reinterpret_cast<volatile Atomic32*>(ptr));
  return actual_data_size == kUnknownDataSize;
}

}  // namespace media