/* * Copyright (c) 2018-2020, Andreas Kling * Copyright (c) 2021, kleines Filmröllchen * * SPDX-License-Identifier: BSD-2-Clause */ #include "Buffer.h" #include #include #include #include namespace Audio { u16 pcm_bits_per_sample(PcmSampleFormat format) { switch (format) { case Uint8: return 8; case Int16: return 16; case Int24: return 24; case Int32: case Float32: return 32; case Float64: return 64; default: VERIFY_NOT_REACHED(); } } String sample_format_name(PcmSampleFormat format) { bool is_float = format == Float32 || format == Float64; return String::formatted("PCM {}bit {}", pcm_bits_per_sample(format), is_float ? "Float" : "LE"); } i32 Buffer::allocate_id() { static Atomic next_id; return next_id++; } template static void read_samples_from_stream(InputMemoryStream& stream, SampleReader read_sample, Vector& samples, int num_channels) { double left_channel_sample = 0; double right_channel_sample = 0; switch (num_channels) { case 1: for (;;) { left_channel_sample = read_sample(stream); samples.append(Sample(left_channel_sample)); if (stream.handle_any_error()) { break; } } break; case 2: for (;;) { left_channel_sample = read_sample(stream); right_channel_sample = read_sample(stream); samples.append(Sample(left_channel_sample, right_channel_sample)); if (stream.handle_any_error()) { break; } } break; default: VERIFY_NOT_REACHED(); } } static double read_float_sample_64(InputMemoryStream& stream) { LittleEndian sample; stream >> sample; return double(sample); } static double read_float_sample_32(InputMemoryStream& stream) { LittleEndian sample; stream >> sample; return double(sample); } static double read_norm_sample_24(InputMemoryStream& stream) { u8 byte = 0; stream >> byte; u32 sample1 = byte; stream >> byte; u32 sample2 = byte; stream >> byte; u32 sample3 = byte; i32 value = 0; value = sample1 << 8; value |= (sample2 << 16); value |= (sample3 << 24); return double(value) / NumericLimits::max(); } static double read_norm_sample_16(InputMemoryStream& stream) { LittleEndian sample; stream >> sample; return double(sample) / NumericLimits::max(); } static double read_norm_sample_8(InputMemoryStream& stream) { u8 sample = 0; stream >> sample; return double(sample) / NumericLimits::max(); } ErrorOr> Buffer::from_pcm_data(ReadonlyBytes data, int num_channels, PcmSampleFormat sample_format) { InputMemoryStream stream { data }; return from_pcm_stream(stream, num_channels, sample_format, data.size() / (pcm_bits_per_sample(sample_format) / 8)); } ErrorOr> Buffer::from_pcm_stream(InputMemoryStream& stream, int num_channels, PcmSampleFormat sample_format, int num_samples) { Vector fdata; fdata.ensure_capacity(num_samples); switch (sample_format) { case PcmSampleFormat::Uint8: read_samples_from_stream(stream, read_norm_sample_8, fdata, num_channels); break; case PcmSampleFormat::Int16: read_samples_from_stream(stream, read_norm_sample_16, fdata, num_channels); break; case PcmSampleFormat::Int24: read_samples_from_stream(stream, read_norm_sample_24, fdata, num_channels); break; case PcmSampleFormat::Float32: read_samples_from_stream(stream, read_float_sample_32, fdata, num_channels); break; case PcmSampleFormat::Float64: read_samples_from_stream(stream, read_float_sample_64, fdata, num_channels); break; default: VERIFY_NOT_REACHED(); } // We should handle this in a better way above, but for now -- // just make sure we're good. Worst case we just write some 0s where they // don't belong. VERIFY(!stream.handle_any_error()); return Buffer::create_with_samples(move(fdata)); } template ResampleHelper::ResampleHelper(u32 source, u32 target) : m_source(source) , m_target(target) { VERIFY(source > 0); VERIFY(target > 0); } template ResampleHelper::ResampleHelper(u32, u32); template ResampleHelper::ResampleHelper(u32, u32); template Vector ResampleHelper::resample(Vector to_resample) { Vector resampled; resampled.ensure_capacity(to_resample.size() * ceil_div(m_source, m_target)); for (auto sample : to_resample) { process_sample(sample, sample); while (read_sample(sample, sample)) resampled.unchecked_append(sample); } return resampled; } template Vector ResampleHelper::resample(Vector); template Vector ResampleHelper::resample(Vector); ErrorOr> resample_buffer(ResampleHelper& resampler, Buffer const& to_resample) { Vector resampled; resampled.ensure_capacity(to_resample.sample_count() * ceil_div(resampler.source(), resampler.target())); for (size_t i = 0; i < static_cast(to_resample.sample_count()); ++i) { auto sample = to_resample.samples()[i]; resampler.process_sample(sample.left, sample.right); while (resampler.read_sample(sample.left, sample.right)) resampled.append(sample); } return Buffer::create_with_samples(move(resampled)); } template void ResampleHelper::process_sample(SampleType sample_l, SampleType sample_r) { m_last_sample_l = sample_l; m_last_sample_r = sample_r; m_current_ratio += m_target; } template void ResampleHelper::process_sample(i32, i32); template void ResampleHelper::process_sample(double, double); template bool ResampleHelper::read_sample(SampleType& next_l, SampleType& next_r) { if (m_current_ratio >= m_source) { m_current_ratio -= m_source; next_l = m_last_sample_l; next_r = m_last_sample_r; return true; } return false; } template bool ResampleHelper::read_sample(i32&, i32&); template bool ResampleHelper::read_sample(double&, double&); template void ResampleHelper::reset() { m_current_ratio = 0; m_last_sample_l = {}; m_last_sample_r = {}; } template void ResampleHelper::reset(); template void ResampleHelper::reset(); }