// Copyright 2016 Citra Emulator Project // Licensed under GPLv2 or any later version // Refer to the license.txt file included. #include #include "audio_core/hle/mixers.h" #include "common/assert.h" #include "common/logging/log.h" #include "common/math_util.h" namespace AudioCore { namespace HLE { void Mixers::Reset() { current_frame.fill({}); state = {}; } DspStatus Mixers::Tick(DspConfiguration& config, const IntermediateMixSamples& read_samples, IntermediateMixSamples& write_samples, const std::array& input) { ParseConfig(config); AuxReturn(read_samples); AuxSend(write_samples, input); MixCurrentFrame(); return GetCurrentStatus(); } void Mixers::ParseConfig(DspConfiguration& config) { if (!config.dirty_raw) { return; } if (config.mixer1_enabled_dirty) { config.mixer1_enabled_dirty.Assign(0); state.mixer1_enabled = config.mixer1_enabled != 0; LOG_TRACE(Audio_DSP, "mixers mixer1_enabled = {}", config.mixer1_enabled); } if (config.mixer2_enabled_dirty) { config.mixer2_enabled_dirty.Assign(0); state.mixer2_enabled = config.mixer2_enabled != 0; LOG_TRACE(Audio_DSP, "mixers mixer2_enabled = {}", config.mixer2_enabled); } if (config.volume_0_dirty) { config.volume_0_dirty.Assign(0); state.intermediate_mixer_volume[0] = config.volume[0]; LOG_TRACE(Audio_DSP, "mixers volume[0] = {}", config.volume[0]); } if (config.volume_1_dirty) { config.volume_1_dirty.Assign(0); state.intermediate_mixer_volume[1] = config.volume[1]; LOG_TRACE(Audio_DSP, "mixers volume[1] = {}", config.volume[1]); } if (config.volume_2_dirty) { config.volume_2_dirty.Assign(0); state.intermediate_mixer_volume[2] = config.volume[2]; LOG_TRACE(Audio_DSP, "mixers volume[2] = {}", config.volume[2]); } if (config.output_format_dirty) { config.output_format_dirty.Assign(0); state.output_format = config.output_format; LOG_TRACE(Audio_DSP, "mixers output_format = {}", static_cast(config.output_format)); } if (config.headphones_connected_dirty) { config.headphones_connected_dirty.Assign(0); // Do nothing. (Note: Whether headphones are connected does affect coefficients used for // surround sound.) LOG_TRACE(Audio_DSP, "mixers headphones_connected={}", config.headphones_connected); } if (config.dirty_raw) { LOG_DEBUG(Audio_DSP, "mixers remaining_dirty={:x}", config.dirty_raw); } config.dirty_raw = 0; } static s16 ClampToS16(s32 value) { return static_cast(MathUtil::Clamp(value, -32768, 32767)); } static std::array AddAndClampToS16(const std::array& a, const std::array& b) { return {ClampToS16(static_cast(a[0]) + static_cast(b[0])), ClampToS16(static_cast(a[1]) + static_cast(b[1]))}; } void Mixers::DownmixAndMixIntoCurrentFrame(float gain, const QuadFrame32& samples) { // TODO(merry): Limiter. (Currently we're performing final mixing assuming a disabled limiter.) switch (state.output_format) { case OutputFormat::Mono: std::transform( current_frame.begin(), current_frame.end(), samples.begin(), current_frame.begin(), [gain](const std::array& accumulator, const std::array& sample) -> std::array { // Downmix to mono s16 mono = ClampToS16(static_cast( (gain * sample[0] + gain * sample[1] + gain * sample[2] + gain * sample[3]) / 2)); // Mix into current frame return AddAndClampToS16(accumulator, {mono, mono}); }); return; case OutputFormat::Surround: // TODO(merry): Implement surround sound. // fallthrough case OutputFormat::Stereo: std::transform( current_frame.begin(), current_frame.end(), samples.begin(), current_frame.begin(), [gain](const std::array& accumulator, const std::array& sample) -> std::array { // Downmix to stereo s16 left = ClampToS16(static_cast(gain * sample[0] + gain * sample[2])); s16 right = ClampToS16(static_cast(gain * sample[1] + gain * sample[3])); // Mix into current frame return AddAndClampToS16(accumulator, {left, right}); }); return; } UNREACHABLE_MSG("Invalid output_format {}", static_cast(state.output_format)); } void Mixers::AuxReturn(const IntermediateMixSamples& read_samples) { // NOTE: read_samples.mix{1,2}.pcm32 annoyingly have their dimensions in reverse order to // QuadFrame32. if (state.mixer1_enabled) { for (size_t sample = 0; sample < samples_per_frame; sample++) { for (size_t channel = 0; channel < 4; channel++) { state.intermediate_mix_buffer[1][sample][channel] = read_samples.mix1.pcm32[channel][sample]; } } } if (state.mixer2_enabled) { for (size_t sample = 0; sample < samples_per_frame; sample++) { for (size_t channel = 0; channel < 4; channel++) { state.intermediate_mix_buffer[2][sample][channel] = read_samples.mix2.pcm32[channel][sample]; } } } } void Mixers::AuxSend(IntermediateMixSamples& write_samples, const std::array& input) { // NOTE: read_samples.mix{1,2}.pcm32 annoyingly have their dimensions in reverse order to // QuadFrame32. state.intermediate_mix_buffer[0] = input[0]; if (state.mixer1_enabled) { for (size_t sample = 0; sample < samples_per_frame; sample++) { for (size_t channel = 0; channel < 4; channel++) { write_samples.mix1.pcm32[channel][sample] = input[1][sample][channel]; } } } else { state.intermediate_mix_buffer[1] = input[1]; } if (state.mixer2_enabled) { for (size_t sample = 0; sample < samples_per_frame; sample++) { for (size_t channel = 0; channel < 4; channel++) { write_samples.mix2.pcm32[channel][sample] = input[2][sample][channel]; } } } else { state.intermediate_mix_buffer[2] = input[2]; } } void Mixers::MixCurrentFrame() { current_frame.fill({}); for (size_t mix = 0; mix < 3; mix++) { DownmixAndMixIntoCurrentFrame(state.intermediate_mixer_volume[mix], state.intermediate_mix_buffer[mix]); } // TODO(merry): Compressor. (We currently assume a disabled compressor.) } DspStatus Mixers::GetCurrentStatus() const { DspStatus status; status.unknown = 0; status.dropped_frames = 0; return status; } } // namespace HLE } // namespace AudioCore