/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
* Copyright (c) 2021, kleines Filmröllchen <filmroellchen@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include "WavLoader.h"
#include "LoaderError.h"
#include <AK/Debug.h>
#include <AK/Endian.h>
#include <AK/FixedArray.h>
#include <AK/MemoryStream.h>
#include <AK/NumericLimits.h>
#include <AK/Try.h>
#include <LibCore/File.h>
namespace Audio {
static constexpr size_t const maximum_wav_size = 1 * GiB; // FIXME: is there a more appropriate size limit?
WavLoaderPlugin::WavLoaderPlugin(NonnullOwnPtr<SeekableStream> stream)
: LoaderPlugin(move(stream))
{
}
Result<NonnullOwnPtr<WavLoaderPlugin>, LoaderError> WavLoaderPlugin::create(StringView path)
{
auto stream = LOADER_TRY(Core::BufferedFile::create(LOADER_TRY(Core::File::open(path, Core::File::OpenMode::Read))));
auto loader = make<WavLoaderPlugin>(move(stream));
LOADER_TRY(loader->initialize());
return loader;
}
Result<NonnullOwnPtr<WavLoaderPlugin>, LoaderError> WavLoaderPlugin::create(Bytes buffer)
{
auto stream = LOADER_TRY(try_make<FixedMemoryStream>(buffer));
auto loader = make<WavLoaderPlugin>(move(stream));
LOADER_TRY(loader->initialize());
return loader;
}
MaybeLoaderError WavLoaderPlugin::initialize()
{
LOADER_TRY(parse_header());
return {};
}
template<typename SampleReader>
MaybeLoaderError WavLoaderPlugin::read_samples_from_stream(Stream& stream, SampleReader read_sample, FixedArray<Sample>& samples) const
{
switch (m_num_channels) {
case 1:
for (auto& sample : samples)
sample = Sample(LOADER_TRY(read_sample(stream)));
break;
case 2:
for (auto& sample : samples) {
auto left_channel_sample = LOADER_TRY(read_sample(stream));
auto right_channel_sample = LOADER_TRY(read_sample(stream));
sample = Sample(left_channel_sample, right_channel_sample);
}
break;
default:
VERIFY_NOT_REACHED();
}
return {};
}
// There's no i24 type + we need to do the endianness conversion manually anyways.
static ErrorOr<double> read_sample_int24(Stream& stream)
{
i32 sample1 = TRY(stream.read_value<u8>());
i32 sample2 = TRY(stream.read_value<u8>());
i32 sample3 = TRY(stream.read_value<u8>());
i32 value = 0;
value = sample1;
value |= sample2 << 8;
value |= sample3 << 16;
// Sign extend the value, as it can currently not have the correct sign.
value = (value << 8) >> 8;
// Range of value is now -2^23 to 2^23-1 and we can rescale normally.
return static_cast<double>(value) / static_cast<double>((1 << 23) - 1);
}
template<typename T>
static ErrorOr<double> read_sample(Stream& stream)
{
T sample { 0 };
TRY(stream.read_until_filled(Bytes { &sample, sizeof(T) }));
// Remap integer samples to normalized floating-point range of -1 to 1.
if constexpr (IsIntegral<T>) {
if constexpr (NumericLimits<T>::is_signed()) {
// Signed integer samples are centered around zero, so this division is enough.
return static_cast<double>(AK::convert_between_host_and_little_endian(sample)) / static_cast<double>(NumericLimits<T>::max());
} else {
// Unsigned integer samples, on the other hand, need to be shifted to center them around zero.
// The first division therefore remaps to the range 0 to 2.
return static_cast<double>(AK::convert_between_host_and_little_endian(sample)) / (static_cast<double>(NumericLimits<T>::max()) / 2.0) - 1.0;
}
} else {
return static_cast<double>(AK::convert_between_host_and_little_endian(sample));
}
}
LoaderSamples WavLoaderPlugin::samples_from_pcm_data(Bytes const& data, size_t samples_to_read) const
{
FixedArray<Sample> samples = LOADER_TRY(FixedArray<Sample>::create(samples_to_read));
FixedMemoryStream stream { data };
switch (m_sample_format) {
case PcmSampleFormat::Uint8:
TRY(read_samples_from_stream(stream, read_sample<u8>, samples));
break;
case PcmSampleFormat::Int16:
TRY(read_samples_from_stream(stream, read_sample<i16>, samples));
break;
case PcmSampleFormat::Int24:
TRY(read_samples_from_stream(stream, read_sample_int24, samples));
break;
case PcmSampleFormat::Float32:
TRY(read_samples_from_stream(stream, read_sample<float>, samples));
break;
case PcmSampleFormat::Float64:
TRY(read_samples_from_stream(stream, read_sample<double>, samples));
break;
default:
VERIFY_NOT_REACHED();
}
return samples;
}
ErrorOr<Vector<FixedArray<Sample>>, LoaderError> WavLoaderPlugin::load_chunks(size_t samples_to_read_from_input)
{
auto remaining_samples = m_total_samples - m_loaded_samples;
if (remaining_samples <= 0)
return Vector<FixedArray<Sample>> {};
// One "sample" contains data from all channels.
// In the Wave spec, this is also called a block.
size_t bytes_per_sample
= m_num_channels * pcm_bits_per_sample(m_sample_format) / 8;
auto samples_to_read = min(samples_to_read_from_input, remaining_samples);
auto bytes_to_read = samples_to_read * bytes_per_sample;
dbgln_if(AWAVLOADER_DEBUG, "Read {} bytes WAV with num_channels {} sample rate {}, "
"bits per sample {}, sample format {}",
bytes_to_read, m_num_channels, m_sample_rate,
pcm_bits_per_sample(m_sample_format), sample_format_name(m_sample_format));
auto sample_data = LOADER_TRY(ByteBuffer::create_zeroed(bytes_to_read));
LOADER_TRY(m_stream->read_until_filled(sample_data.bytes()));
// m_loaded_samples should contain the amount of actually loaded samples
m_loaded_samples += samples_to_read;
Vector<FixedArray<Sample>> samples;
TRY(samples.try_append(TRY(samples_from_pcm_data(sample_data.bytes(), samples_to_read))));
return samples;
}
MaybeLoaderError WavLoaderPlugin::seek(int sample_index)
{
dbgln_if(AWAVLOADER_DEBUG, "seek sample_index {}", sample_index);
if (sample_index < 0 || sample_index >= static_cast<int>(m_total_samples))
return LoaderError { LoaderError::Category::Internal, m_loaded_samples, "Seek outside the sample range" };
size_t sample_offset = m_byte_offset_of_data_samples + static_cast<size_t>(sample_index * m_num_channels * (pcm_bits_per_sample(m_sample_format) / 8));
LOADER_TRY(m_stream->seek(sample_offset, SeekMode::SetPosition));
m_loaded_samples = sample_index;
return {};
}
// Specification reference: http://www-mmsp.ece.mcgill.ca/Documents/AudioFormats/WAVE/WAVE.html
MaybeLoaderError WavLoaderPlugin::parse_header()
{
bool ok = true;
size_t bytes_read = 0;
auto read_u8 = [&]() -> ErrorOr<u8, LoaderError> {
u8 value = LOADER_TRY(m_stream->read_value<LittleEndian<u8>>());
bytes_read += 1;
return value;
};
auto read_u16 = [&]() -> ErrorOr<u16, LoaderError> {
u16 value = LOADER_TRY(m_stream->read_value<LittleEndian<u16>>());
bytes_read += 2;
return value;
};
auto read_u32 = [&]() -> ErrorOr<u32, LoaderError> {
u32 value = LOADER_TRY(m_stream->read_value<LittleEndian<u32>>());
bytes_read += 4;
return value;
};
#define CHECK_OK(category, msg) \
do { \
if (!ok) \
return LoaderError { category, DeprecatedString::formatted("Parsing failed: {}", msg) }; \
} while (0)
u32 riff = TRY(read_u32());
ok = ok && riff == 0x46464952; // "RIFF"
CHECK_OK(LoaderError::Category::Format, "RIFF header");
u32 sz = TRY(read_u32());
ok = ok && sz < maximum_wav_size;
CHECK_OK(LoaderError::Category::Format, "File size");
u32 wave = TRY(read_u32());
ok = ok && wave == 0x45564157; // "WAVE"
CHECK_OK(LoaderError::Category::Format, "WAVE header");
u32 fmt_id = TRY(read_u32());
ok = ok && fmt_id == 0x20746D66; // "fmt "
CHECK_OK(LoaderError::Category::Format, "FMT header");
u32 fmt_size = TRY(read_u32());
ok = ok && (fmt_size == 16 || fmt_size == 18 || fmt_size == 40);
CHECK_OK(LoaderError::Category::Format, "FMT size");
u16 audio_format = TRY(read_u16());
CHECK_OK(LoaderError::Category::Format, "Audio format"); // incomplete read check
ok = ok && (audio_format == WAVE_FORMAT_PCM || audio_format == WAVE_FORMAT_IEEE_FLOAT || audio_format == WAVE_FORMAT_EXTENSIBLE);
CHECK_OK(LoaderError::Category::Unimplemented, "Audio format PCM/Float"); // value check
m_num_channels = TRY(read_u16());
ok = ok && (m_num_channels == 1 || m_num_channels == 2);
CHECK_OK(LoaderError::Category::Unimplemented, "Channel count");
m_sample_rate = TRY(read_u32());
CHECK_OK(LoaderError::Category::IO, "Sample rate");
TRY(read_u32());
CHECK_OK(LoaderError::Category::IO, "Data rate");
u16 block_size_bytes = TRY(read_u16());
CHECK_OK(LoaderError::Category::IO, "Block size");
u16 bits_per_sample = TRY(read_u16());
CHECK_OK(LoaderError::Category::IO, "Bits per sample");
if (audio_format == WAVE_FORMAT_EXTENSIBLE) {
ok = ok && (fmt_size == 40);
CHECK_OK(LoaderError::Category::Format, "Extensible fmt size"); // value check
// Discard everything until the GUID.
// We've already read 16 bytes from the stream. The GUID starts in another 8 bytes.
TRY(read_u32());
TRY(read_u32());
CHECK_OK(LoaderError::Category::IO, "Discard until GUID");
// Get the underlying audio format from the first two bytes of GUID
u16 guid_subformat = TRY(read_u16());
ok = ok && (guid_subformat == WAVE_FORMAT_PCM || guid_subformat == WAVE_FORMAT_IEEE_FLOAT);
CHECK_OK(LoaderError::Category::Unimplemented, "GUID SubFormat");
audio_format = guid_subformat;
}
if (audio_format == WAVE_FORMAT_PCM) {
ok = ok && (bits_per_sample == 8 || bits_per_sample == 16 || bits_per_sample == 24);
CHECK_OK(LoaderError::Category::Unimplemented, "Bits per sample (PCM)"); // value check
// We only support 8-24 bit audio right now because other formats are uncommon
if (bits_per_sample == 8) {
m_sample_format = PcmSampleFormat::Uint8;
} else if (bits_per_sample == 16) {
m_sample_format = PcmSampleFormat::Int16;
} else if (bits_per_sample == 24) {
m_sample_format = PcmSampleFormat::Int24;
}
} else if (audio_format == WAVE_FORMAT_IEEE_FLOAT) {
ok = ok && (bits_per_sample == 32 || bits_per_sample == 64);
CHECK_OK(LoaderError::Category::Unimplemented, "Bits per sample (Float)"); // value check
// Again, only the common 32 and 64 bit
if (bits_per_sample == 32) {
m_sample_format = PcmSampleFormat::Float32;
} else if (bits_per_sample == 64) {
m_sample_format = PcmSampleFormat::Float64;
}
}
ok = ok && (block_size_bytes == (m_num_channels * (bits_per_sample / 8)));
CHECK_OK(LoaderError::Category::Format, "Block size sanity check");
dbgln_if(AWAVLOADER_DEBUG, "WAV format {} at {} bit, {} channels, rate {}Hz ",
sample_format_name(m_sample_format), pcm_bits_per_sample(m_sample_format), m_num_channels, m_sample_rate);
// Read chunks until we find DATA
bool found_data = false;
u32 data_size = 0;
u8 search_byte = 0;
while (true) {
search_byte = TRY(read_u8());
CHECK_OK(LoaderError::Category::IO, "Reading byte searching for data");
if (search_byte != 0x64) // D
continue;
search_byte = TRY(read_u8());
CHECK_OK(LoaderError::Category::IO, "Reading next byte searching for data");
if (search_byte != 0x61) // A
continue;
u16 search_remaining = TRY(read_u16());
CHECK_OK(LoaderError::Category::IO, "Reading remaining bytes searching for data");
if (search_remaining != 0x6174) // TA
continue;
data_size = TRY(read_u32());
found_data = true;
break;
}
ok = ok && found_data;
CHECK_OK(LoaderError::Category::Format, "Found no data chunk");
ok = ok && data_size < maximum_wav_size;
CHECK_OK(LoaderError::Category::Format, "Data was too large");
m_total_samples = data_size / block_size_bytes;
dbgln_if(AWAVLOADER_DEBUG, "WAV data size {}, bytes per sample {}, total samples {}",
data_size,
block_size_bytes,
m_total_samples);
m_byte_offset_of_data_samples = bytes_read;
return {};
}
}