2f13517a1a
LibAudio now supports pausing playback, clearing the buffer queue, retrieving the played samples since the last clear and retrieving the currently playing shared buffer id
280 lines
8.2 KiB
C++
280 lines
8.2 KiB
C++
#include <AK/BufferStream.h>
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#include <LibAudio/AWavLoader.h>
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#include <LibCore/CFile.h>
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#include <LibCore/CIODeviceStreamReader.h>
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#include <limits>
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AWavLoader::AWavLoader(const StringView& path)
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: m_file(CFile::construct(path))
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{
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if (!m_file->open(CIODevice::ReadOnly)) {
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m_error_string = String::format("Can't open file: %s", m_file->error_string());
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return;
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}
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parse_header();
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m_resampler = make<AResampleHelper>(m_sample_rate, 44100);
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}
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RefPtr<ABuffer> AWavLoader::get_more_samples(size_t max_bytes_to_read_from_input)
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{
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#ifdef AWAVLOADER_DEBUG
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dbgprintf("Read WAV of format PCM with num_channels %u sample rate %u, bits per sample %u\n", m_num_channels, m_sample_rate, m_bits_per_sample);
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#endif
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auto raw_samples = m_file->read(max_bytes_to_read_from_input);
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if (raw_samples.is_empty())
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return nullptr;
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auto buffer = ABuffer::from_pcm_data(raw_samples, *m_resampler, m_num_channels, m_bits_per_sample);
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m_loaded_samples += buffer->sample_count();
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return buffer;
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}
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void AWavLoader::seek(const int position)
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{
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if (position < 0 || position > m_total_samples)
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return;
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m_loaded_samples = position;
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m_file->seek(position * m_num_channels * (m_bits_per_sample / 8));
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}
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void AWavLoader::reset()
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{
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seek(0);
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}
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bool AWavLoader::parse_header()
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{
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CIODeviceStreamReader stream(*m_file);
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#define CHECK_OK(msg) \
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do { \
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ASSERT(ok); \
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if (stream.handle_read_failure()) { \
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m_error_string = String::format("Premature stream EOF at %s", msg); \
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return {}; \
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} \
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if (!ok) { \
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m_error_string = String::format("Parsing failed: %s", msg); \
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return {}; \
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} else { \
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dbgprintf("%s is OK!\n", msg); \
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} \
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} while (0);
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bool ok = true;
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u32 riff;
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stream >> riff;
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ok = ok && riff == 0x46464952; // "RIFF"
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CHECK_OK("RIFF header");
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u32 sz;
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stream >> sz;
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ok = ok && sz < 1024 * 1024 * 1024; // arbitrary
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CHECK_OK("File size");
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ASSERT(sz < 1024 * 1024 * 1024);
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u32 wave;
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stream >> wave;
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ok = ok && wave == 0x45564157; // "WAVE"
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CHECK_OK("WAVE header");
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u32 fmt_id;
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stream >> fmt_id;
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ok = ok && fmt_id == 0x20746D66; // "FMT"
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CHECK_OK("FMT header");
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u32 fmt_size;
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stream >> fmt_size;
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ok = ok && fmt_size == 16;
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CHECK_OK("FMT size");
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ASSERT(fmt_size == 16);
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u16 audio_format;
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stream >> audio_format;
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CHECK_OK("Audio format"); // incomplete read check
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ok = ok && audio_format == 1; // WAVE_FORMAT_PCM
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ASSERT(audio_format == 1);
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CHECK_OK("Audio format"); // value check
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stream >> m_num_channels;
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ok = ok && (m_num_channels == 1 || m_num_channels == 2);
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CHECK_OK("Channel count");
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stream >> m_sample_rate;
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CHECK_OK("Sample rate");
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u32 byte_rate;
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stream >> byte_rate;
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CHECK_OK("Byte rate");
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u16 block_align;
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stream >> block_align;
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CHECK_OK("Block align");
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stream >> m_bits_per_sample;
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CHECK_OK("Bits per sample"); // incomplete read check
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ok = ok && (m_bits_per_sample == 8 || m_bits_per_sample == 16 || m_bits_per_sample == 24);
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ASSERT(m_bits_per_sample == 8 || m_bits_per_sample == 16 || m_bits_per_sample == 24);
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CHECK_OK("Bits per sample"); // value check
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// Read chunks until we find DATA
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bool found_data = false;
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u32 data_sz = 0;
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while (true) {
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u32 chunk_id;
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stream >> chunk_id;
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CHECK_OK("Reading chunk ID searching for data");
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stream >> data_sz;
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CHECK_OK("Reading chunk size searching for data");
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if (chunk_id == 0x61746164) { // DATA
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found_data = true;
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break;
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}
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}
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ok = ok && found_data;
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CHECK_OK("Found no data chunk");
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ASSERT(found_data);
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ok = ok && data_sz < INT32_MAX;
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CHECK_OK("Data was too large");
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int bytes_per_sample = (m_bits_per_sample / 8) * m_num_channels;
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m_total_samples = data_sz / bytes_per_sample;
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// Just make sure we're good before we read the data...
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ASSERT(!stream.handle_read_failure());
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return true;
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}
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AResampleHelper::AResampleHelper(float source, float target)
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: m_ratio(source / target)
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{
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}
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void AResampleHelper::process_sample(float sample_l, float sample_r)
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{
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m_last_sample_l = sample_l;
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m_last_sample_r = sample_r;
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m_current_ratio += 1;
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}
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bool AResampleHelper::read_sample(float& next_l, float& next_r)
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{
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if (m_current_ratio > 0) {
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m_current_ratio -= m_ratio;
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next_l = m_last_sample_l;
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next_r = m_last_sample_r;
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return true;
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}
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return false;
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}
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template<typename SampleReader>
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static void read_samples_from_stream(BufferStream& stream, SampleReader read_sample, Vector<ASample>& samples, AResampleHelper& resampler, int num_channels)
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{
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float norm_l = 0;
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float norm_r = 0;
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switch (num_channels) {
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case 1:
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for (;;) {
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while (resampler.read_sample(norm_l, norm_r)) {
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samples.append(ASample(norm_l));
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}
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norm_l = read_sample(stream);
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if (stream.handle_read_failure()) {
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break;
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}
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resampler.process_sample(norm_l, norm_r);
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}
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break;
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case 2:
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for (;;) {
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while (resampler.read_sample(norm_l, norm_r)) {
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samples.append(ASample(norm_l, norm_r));
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}
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norm_l = read_sample(stream);
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norm_r = read_sample(stream);
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if (stream.handle_read_failure()) {
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break;
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}
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resampler.process_sample(norm_l, norm_r);
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}
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break;
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default:
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ASSERT_NOT_REACHED();
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}
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}
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static float read_norm_sample_24(BufferStream& stream)
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{
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u8 byte = 0;
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stream >> byte;
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u32 sample1 = byte;
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stream >> byte;
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u32 sample2 = byte;
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stream >> byte;
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u32 sample3 = byte;
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i32 value = 0;
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value = sample1 << 8;
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value |= (sample2 << 16);
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value |= (sample3 << 24);
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return float(value) / std::numeric_limits<i32>::max();
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}
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static float read_norm_sample_16(BufferStream& stream)
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{
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i16 sample = 0;
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stream >> sample;
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return float(sample) / std::numeric_limits<i16>::max();
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}
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static float read_norm_sample_8(BufferStream& stream)
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{
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u8 sample = 0;
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stream >> sample;
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return float(sample) / std::numeric_limits<u8>::max();
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}
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// ### can't const this because BufferStream is non-const
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// perhaps we need a reading class separate from the writing one, that can be
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// entirely consted.
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RefPtr<ABuffer> ABuffer::from_pcm_data(ByteBuffer& data, AResampleHelper& resampler, int num_channels, int bits_per_sample)
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{
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BufferStream stream(data);
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Vector<ASample> fdata;
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fdata.ensure_capacity(data.size() / (bits_per_sample / 8));
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#ifdef AWAVLOADER_DEBUG
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dbg() << "Reading " << bits_per_sample << " bits and " << num_channels << " channels, total bytes: " << data.size();
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#endif
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switch (bits_per_sample) {
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case 8:
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read_samples_from_stream(stream, read_norm_sample_8, fdata, resampler, num_channels);
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break;
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case 16:
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read_samples_from_stream(stream, read_norm_sample_16, fdata, resampler, num_channels);
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break;
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case 24:
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read_samples_from_stream(stream, read_norm_sample_24, fdata, resampler, num_channels);
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break;
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default:
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ASSERT_NOT_REACHED();
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}
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// We should handle this in a better way above, but for now --
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// just make sure we're good. Worst case we just write some 0s where they
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// don't belong.
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ASSERT(!stream.handle_read_failure());
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return ABuffer::create_with_samples(move(fdata));
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}
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