// SPDX-FileCopyrightText: Copyright 2022 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#include <chrono>
#include <span>
#include "audio_core/audio_core.h"
#include "audio_core/common/audio_renderer_parameter.h"
#include "audio_core/common/common.h"
#include "audio_core/common/feature_support.h"
#include "audio_core/common/workbuffer_allocator.h"
#include "audio_core/renderer/adsp/adsp.h"
#include "audio_core/renderer/behavior/info_updater.h"
#include "audio_core/renderer/command/command_buffer.h"
#include "audio_core/renderer/command/command_generator.h"
#include "audio_core/renderer/command/command_list_header.h"
#include "audio_core/renderer/effect/effect_info_base.h"
#include "audio_core/renderer/effect/effect_result_state.h"
#include "audio_core/renderer/memory/memory_pool_info.h"
#include "audio_core/renderer/memory/pool_mapper.h"
#include "audio_core/renderer/mix/mix_info.h"
#include "audio_core/renderer/nodes/edge_matrix.h"
#include "audio_core/renderer/nodes/node_states.h"
#include "audio_core/renderer/sink/sink_info_base.h"
#include "audio_core/renderer/system.h"
#include "audio_core/renderer/upsampler/upsampler_info.h"
#include "audio_core/renderer/voice/voice_channel_resource.h"
#include "audio_core/renderer/voice/voice_info.h"
#include "audio_core/renderer/voice/voice_state.h"
#include "common/alignment.h"
#include "core/core.h"
#include "core/core_timing.h"
#include "core/hle/kernel/k_event.h"
#include "core/hle/kernel/k_transfer_memory.h"
#include "core/memory.h"
namespace AudioCore::AudioRenderer {
u64 System::GetWorkBufferSize(const AudioRendererParameterInternal& params) {
BehaviorInfo behavior;
behavior.SetUserLibRevision(params.revision);
u64 size{0};
size += Common::AlignUp(params.mixes * sizeof(s32), 0x40);
size += params.sub_mixes * MaxEffects * sizeof(s32);
size += (params.sub_mixes + 1) * sizeof(MixInfo);
size += params.voices * (sizeof(VoiceInfo) + sizeof(VoiceChannelResource) + sizeof(VoiceState));
size += Common::AlignUp((params.sub_mixes + 1) * sizeof(MixInfo*), 0x10);
size += Common::AlignUp(params.voices * sizeof(VoiceInfo*), 0x10);
size += Common::AlignUp(((params.sinks + params.sub_mixes) * TargetSampleCount * sizeof(s32) +
params.sample_count * sizeof(s32)) *
(params.mixes + MaxChannels),
0x40);
if (behavior.IsSplitterSupported()) {
const auto node_size{NodeStates::GetWorkBufferSize(params.sub_mixes + 1)};
const auto edge_size{EdgeMatrix::GetWorkBufferSize(params.sub_mixes + 1)};
size += Common::AlignUp(node_size + edge_size, 0x10);
}
size += SplitterContext::CalcWorkBufferSize(behavior, params);
size += (params.effects + params.voices * MaxWaveBuffers) * sizeof(MemoryPoolInfo);
if (behavior.IsEffectInfoVersion2Supported()) {
size += params.effects * sizeof(EffectResultState);
}
size += 0x50;
size = Common::AlignUp(size, 0x40);
size += (params.sinks + params.sub_mixes) * sizeof(UpsamplerInfo);
size += params.effects * sizeof(EffectInfoBase);
size += Common::AlignUp(params.voices * sizeof(VoiceState), 0x40);
size += params.sinks * sizeof(SinkInfoBase);
if (behavior.IsEffectInfoVersion2Supported()) {
size += params.effects * sizeof(EffectResultState);
}
if (params.perf_frames > 0) {
auto perf_size{PerformanceManager::GetRequiredBufferSizeForPerformanceMetricsPerFrame(
behavior, params)};
size += Common::AlignUp(perf_size * (params.perf_frames + 1) + 0xC0, 0x100);
}
if (behavior.IsVariadicCommandBufferSizeSupported()) {
size += CommandGenerator::CalculateCommandBufferSize(behavior, params) + (0x40 - 1) * 2;
} else {
size += 0x18000 + (0x40 - 1) * 2;
}
size = Common::AlignUp(size, 0x1000);
return size;
}
System::System(Core::System& core_, Kernel::KEvent* adsp_rendered_event_)
: core{core_}, adsp{core.AudioCore().GetADSP()}, adsp_rendered_event{adsp_rendered_event_} {}
Result System::Initialize(const AudioRendererParameterInternal& params,
Kernel::KTransferMemory* transfer_memory, u64 transfer_memory_size,
u32 process_handle_, u64 applet_resource_user_id_, s32 session_id_) {
if (!CheckValidRevision(params.revision)) {
return Service::Audio::ResultInvalidRevision;
}
if (GetWorkBufferSize(params) > transfer_memory_size) {
return Service::Audio::ResultInsufficientBuffer;
}
if (process_handle_ == 0) {
return Service::Audio::ResultInvalidHandle;
}
behavior.SetUserLibRevision(params.revision);
process_handle = process_handle_;
applet_resource_user_id = applet_resource_user_id_;
session_id = session_id_;
sample_rate = params.sample_rate;
sample_count = params.sample_count;
mix_buffer_count = static_cast<s16>(params.mixes);
voice_channels = MaxChannels;
upsampler_count = params.sinks + params.sub_mixes;
memory_pool_count = params.effects + params.voices * MaxWaveBuffers;
render_device = params.rendering_device;
execution_mode = params.execution_mode;
core.ApplicationMemory().ZeroBlock(transfer_memory->GetSourceAddress(), transfer_memory_size);
// Note: We're not actually using the transfer memory because it's a pain to code for.
// Allocate the memory normally instead and hope the game doesn't try to read anything back
workbuffer = std::make_unique<u8[]>(transfer_memory_size);
workbuffer_size = transfer_memory_size;
PoolMapper pool_mapper(process_handle, false);
pool_mapper.InitializeSystemPool(memory_pool_info, workbuffer.get(), workbuffer_size);
WorkbufferAllocator allocator({workbuffer.get(), workbuffer_size}, workbuffer_size);
samples_workbuffer =
allocator.Allocate<s32>((voice_channels + mix_buffer_count) * sample_count, 0x10);
if (samples_workbuffer.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
auto upsampler_workbuffer{allocator.Allocate<s32>(
(voice_channels + mix_buffer_count) * TargetSampleCount * upsampler_count, 0x10)};
if (upsampler_workbuffer.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
depop_buffer =
allocator.Allocate<s32>(Common::AlignUp(static_cast<u32>(mix_buffer_count), 0x40), 0x40);
if (depop_buffer.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
// invalidate samples_workbuffer DSP cache
auto voice_infos{allocator.Allocate<VoiceInfo>(params.voices, 0x10)};
for (auto& voice_info : voice_infos) {
std::construct_at<VoiceInfo>(&voice_info);
}
if (voice_infos.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
auto sorted_voice_infos{allocator.Allocate<VoiceInfo*>(params.voices, 0x10)};
if (sorted_voice_infos.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
std::memset(sorted_voice_infos.data(), 0, sorted_voice_infos.size_bytes());
auto voice_channel_resources{allocator.Allocate<VoiceChannelResource>(params.voices, 0x10)};
u32 i{0};
for (auto& voice_channel_resource : voice_channel_resources) {
std::construct_at<VoiceChannelResource>(&voice_channel_resource, i++);
}
if (voice_channel_resources.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
auto voice_cpu_states{allocator.Allocate<VoiceState>(params.voices, 0x10)};
if (voice_cpu_states.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
for (auto& voice_state : voice_cpu_states) {
voice_state = {};
}
auto mix_infos{allocator.Allocate<MixInfo>(params.sub_mixes + 1, 0x10)};
if (mix_infos.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
u32 effect_process_order_count{0};
std::span<s32> effect_process_order_buffer{};
if (params.effects > 0) {
effect_process_order_count = params.effects * (params.sub_mixes + 1);
effect_process_order_buffer = allocator.Allocate<s32>(effect_process_order_count, 0x10);
if (effect_process_order_buffer.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
}
i = 0;
for (auto& mix_info : mix_infos) {
std::construct_at<MixInfo>(
&mix_info, effect_process_order_buffer.subspan(i * params.effects, params.effects),
params.effects, this->behavior);
i++;
}
auto sorted_mix_infos{allocator.Allocate<MixInfo*>(params.sub_mixes + 1, 0x10)};
if (sorted_mix_infos.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
std::memset(sorted_mix_infos.data(), 0, sorted_mix_infos.size_bytes());
if (behavior.IsSplitterSupported()) {
u64 node_state_size{NodeStates::GetWorkBufferSize(params.sub_mixes + 1)};
u64 edge_matrix_size{EdgeMatrix::GetWorkBufferSize(params.sub_mixes + 1)};
auto node_states_workbuffer{allocator.Allocate<u8>(node_state_size, 1)};
auto edge_matrix_workbuffer{allocator.Allocate<u8>(edge_matrix_size, 1)};
if (node_states_workbuffer.empty() || edge_matrix_workbuffer.size() == 0) {
return Service::Audio::ResultInsufficientBuffer;
}
mix_context.Initialize(sorted_mix_infos, mix_infos, params.sub_mixes + 1,
effect_process_order_buffer, effect_process_order_count,
node_states_workbuffer, node_state_size, edge_matrix_workbuffer,
edge_matrix_size);
} else {
mix_context.Initialize(sorted_mix_infos, mix_infos, params.sub_mixes + 1,
effect_process_order_buffer, effect_process_order_count, {}, 0, {},
0);
}
upsampler_manager = allocator.Allocate<UpsamplerManager>(1, 0x10).data();
if (upsampler_manager == nullptr) {
return Service::Audio::ResultInsufficientBuffer;
}
memory_pool_workbuffer = allocator.Allocate<MemoryPoolInfo>(memory_pool_count, 0x10);
for (auto& memory_pool : memory_pool_workbuffer) {
std::construct_at<MemoryPoolInfo>(&memory_pool, MemoryPoolInfo::Location::DSP);
}
if (memory_pool_workbuffer.empty() && memory_pool_count > 0) {
return Service::Audio::ResultInsufficientBuffer;
}
if (!splitter_context.Initialize(behavior, params, allocator)) {
return Service::Audio::ResultInsufficientBuffer;
}
std::span<EffectResultState> effect_result_states_cpu{};
if (behavior.IsEffectInfoVersion2Supported() && params.effects > 0) {
effect_result_states_cpu = allocator.Allocate<EffectResultState>(params.effects, 0x10);
if (effect_result_states_cpu.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
std::memset(effect_result_states_cpu.data(), 0, effect_result_states_cpu.size_bytes());
}
allocator.Align(0x40);
unk_2B0 = allocator.GetSize() - allocator.GetCurrentOffset();
unk_2A8 = {&workbuffer[allocator.GetCurrentOffset()], unk_2B0};
upsampler_infos = allocator.Allocate<UpsamplerInfo>(upsampler_count, 0x40);
for (auto& upsampler_info : upsampler_infos) {
std::construct_at<UpsamplerInfo>(&upsampler_info);
}
std::construct_at<UpsamplerManager>(upsampler_manager, upsampler_count, upsampler_infos,
upsampler_workbuffer);
if (upsampler_infos.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
auto effect_infos{allocator.Allocate<EffectInfoBase>(params.effects, 0x40)};
for (auto& effect_info : effect_infos) {
std::construct_at<EffectInfoBase>(&effect_info);
}
if (effect_infos.empty() && params.effects > 0) {
return Service::Audio::ResultInsufficientBuffer;
}
std::span<EffectResultState> effect_result_states_dsp{};
if (behavior.IsEffectInfoVersion2Supported() && params.effects > 0) {
effect_result_states_dsp = allocator.Allocate<EffectResultState>(params.effects, 0x40);
if (effect_result_states_dsp.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
std::memset(effect_result_states_dsp.data(), 0, effect_result_states_dsp.size_bytes());
}
effect_context.Initialize(effect_infos, params.effects, effect_result_states_cpu,
effect_result_states_dsp, effect_result_states_dsp.size());
auto sinks{allocator.Allocate<SinkInfoBase>(params.sinks, 0x10)};
for (auto& sink : sinks) {
std::construct_at<SinkInfoBase>(&sink);
}
if (sinks.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
sink_context.Initialize(sinks, params.sinks);
auto voice_dsp_states{allocator.Allocate<VoiceState>(params.voices, 0x40)};
if (voice_dsp_states.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
for (auto& voice_state : voice_dsp_states) {
voice_state = {};
}
voice_context.Initialize(sorted_voice_infos, voice_infos, voice_channel_resources,
voice_cpu_states, voice_dsp_states, params.voices);
if (params.perf_frames > 0) {
const auto perf_workbuffer_size{
PerformanceManager::GetRequiredBufferSizeForPerformanceMetricsPerFrame(behavior,
params) *
(params.perf_frames + 1) +
0xC};
performance_workbuffer = allocator.Allocate<u8>(perf_workbuffer_size, 0x40);
if (performance_workbuffer.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
std::memset(performance_workbuffer.data(), 0, performance_workbuffer.size_bytes());
performance_manager.Initialize(performance_workbuffer, performance_workbuffer.size_bytes(),
params, behavior, memory_pool_info);
}
render_time_limit_percent = 100;
drop_voice = params.voice_drop_enabled && params.execution_mode == ExecutionMode::Auto;
drop_voice_param = 1.0f;
num_voices_dropped = 0;
allocator.Align(0x40);
command_workbuffer_size = allocator.GetRemainingSize();
command_workbuffer = allocator.Allocate<u8>(command_workbuffer_size, 0x40);
if (command_workbuffer.empty()) {
return Service::Audio::ResultInsufficientBuffer;
}
command_buffer_size = 0;
reset_command_buffers = true;
// nn::audio::dsp::FlushDataCache(transferMemory, transferMemorySize);
if (behavior.IsCommandProcessingTimeEstimatorVersion5Supported()) {
command_processing_time_estimator =
std::make_unique<CommandProcessingTimeEstimatorVersion5>(sample_count,
mix_buffer_count);
} else if (behavior.IsCommandProcessingTimeEstimatorVersion4Supported()) {
command_processing_time_estimator =
std::make_unique<CommandProcessingTimeEstimatorVersion4>(sample_count,
mix_buffer_count);
} else if (behavior.IsCommandProcessingTimeEstimatorVersion3Supported()) {
command_processing_time_estimator =
std::make_unique<CommandProcessingTimeEstimatorVersion3>(sample_count,
mix_buffer_count);
} else if (behavior.IsCommandProcessingTimeEstimatorVersion2Supported()) {
command_processing_time_estimator =
std::make_unique<CommandProcessingTimeEstimatorVersion2>(sample_count,
mix_buffer_count);
} else {
command_processing_time_estimator =
std::make_unique<CommandProcessingTimeEstimatorVersion1>(sample_count,
mix_buffer_count);
}
initialized = true;
return ResultSuccess;
}
void System::Finalize() {
if (!initialized) {
return;
}
if (active) {
Stop();
}
applet_resource_user_id = 0;
PoolMapper pool_mapper(process_handle, false);
pool_mapper.Unmap(memory_pool_info);
if (process_handle) {
pool_mapper.ClearUseState(memory_pool_workbuffer, memory_pool_count);
for (auto& memory_pool : memory_pool_workbuffer) {
if (memory_pool.IsMapped()) {
pool_mapper.Unmap(memory_pool);
}
}
// dsp::ProcessCleanup
// close handle
}
initialized = false;
}
void System::Start() {
std::scoped_lock l{lock};
frames_elapsed = 0;
state = State::Started;
active = true;
}
void System::Stop() {
{
std::scoped_lock l{lock};
state = State::Stopped;
active = false;
}
if (execution_mode == ExecutionMode::Auto) {
// Should wait for the system to terminate here, but core timing (should have) already
// stopped, so this isn't needed. Find a way to make this definite.
// terminate_event.Wait();
}
}
Result System::Update(std::span<const u8> input, std::span<u8> performance, std::span<u8> output) {
std::scoped_lock l{lock};
const auto start_time{core.CoreTiming().GetClockTicks()};
InfoUpdater info_updater(input, output, process_handle, behavior);
auto result{info_updater.UpdateBehaviorInfo(behavior)};
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update BehaviorInfo!");
return result;
}
result = info_updater.UpdateMemoryPools(memory_pool_workbuffer, memory_pool_count);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update MemoryPools!");
return result;
}
result = info_updater.UpdateVoiceChannelResources(voice_context);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update VoiceChannelResources!");
return result;
}
result = info_updater.UpdateVoices(voice_context, memory_pool_workbuffer, memory_pool_count);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update Voices!");
return result;
}
result = info_updater.UpdateEffects(effect_context, active, memory_pool_workbuffer,
memory_pool_count);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update Effects!");
return result;
}
if (behavior.IsSplitterSupported()) {
result = info_updater.UpdateSplitterInfo(splitter_context);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update SplitterInfo!");
return result;
}
}
result =
info_updater.UpdateMixes(mix_context, mix_buffer_count, effect_context, splitter_context);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update Mixes!");
return result;
}
result = info_updater.UpdateSinks(sink_context, memory_pool_workbuffer, memory_pool_count);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update Sinks!");
return result;
}
PerformanceManager* perf_manager{nullptr};
if (performance_manager.IsInitialized()) {
perf_manager = &performance_manager;
}
result =
info_updater.UpdatePerformanceBuffer(performance, performance.size_bytes(), perf_manager);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update PerformanceBuffer!");
return result;
}
result = info_updater.UpdateErrorInfo(behavior);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update ErrorInfo!");
return result;
}
if (behavior.IsElapsedFrameCountSupported()) {
result = info_updater.UpdateRendererInfo(frames_elapsed);
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Failed to update RendererInfo!");
return result;
}
}
result = info_updater.CheckConsumedSize();
if (result.IsError()) {
LOG_ERROR(Service_Audio, "Invalid consume size!");
return result;
}
adsp_rendered_event->Clear();
num_times_updated++;
const auto end_time{core.CoreTiming().GetClockTicks()};
ticks_spent_updating += end_time - start_time;
return ResultSuccess;
}
u32 System::GetRenderingTimeLimit() const {
return render_time_limit_percent;
}
void System::SetRenderingTimeLimit(u32 limit) {
render_time_limit_percent = limit;
}
u32 System::GetSessionId() const {
return session_id;
}
u32 System::GetSampleRate() const {
return sample_rate;
}
u32 System::GetSampleCount() const {
return sample_count;
}
u32 System::GetMixBufferCount() const {
return mix_buffer_count;
}
ExecutionMode System::GetExecutionMode() const {
return execution_mode;
}
u32 System::GetRenderingDevice() const {
return render_device;
}
bool System::IsActive() const {
return active;
}
void System::SendCommandToDsp() {
std::scoped_lock l{lock};
if (initialized) {
if (active) {
terminate_event.Reset();
const auto remaining_command_count{adsp.GetRemainCommandCount(session_id)};
u64 command_size{0};
if (remaining_command_count) {
adsp_behind = true;
command_size = command_buffer_size;
} else {
command_size = GenerateCommand(command_workbuffer, command_workbuffer_size);
}
auto translated_addr{
memory_pool_info.Translate(CpuAddr(command_workbuffer.data()), command_size)};
auto time_limit_percent{70.0f};
if (behavior.IsAudioRendererProcessingTimeLimit80PercentSupported()) {
time_limit_percent = 80.0f;
} else if (behavior.IsAudioRendererProcessingTimeLimit75PercentSupported()) {
time_limit_percent = 75.0f;
} else {
// result ignored and 70 is used anyway
behavior.IsAudioRendererProcessingTimeLimit70PercentSupported();
time_limit_percent = 70.0f;
}
ADSP::CommandBuffer command_buffer{
.buffer{translated_addr},
.size{command_size},
.time_limit{
static_cast<u64>((time_limit_percent / 100) * 2'880'000.0 *
(static_cast<f32>(render_time_limit_percent) / 100.0f))},
.remaining_command_count{remaining_command_count},
.reset_buffers{reset_command_buffers},
.applet_resource_user_id{applet_resource_user_id},
.render_time_taken{adsp.GetRenderTimeTaken(session_id)},
};
adsp.SendCommandBuffer(session_id, command_buffer);
reset_command_buffers = false;
command_buffer_size = command_size;
if (remaining_command_count == 0) {
adsp_rendered_event->Signal();
}
} else {
adsp.ClearRemainCount(session_id);
terminate_event.Set();
}
}
}
u64 System::GenerateCommand(std::span<u8> in_command_buffer,
[[maybe_unused]] u64 command_buffer_size_) {
PoolMapper::ClearUseState(memory_pool_workbuffer, memory_pool_count);
const auto start_time{core.CoreTiming().GetClockTicks()};
auto command_list_header{reinterpret_cast<CommandListHeader*>(in_command_buffer.data())};
command_list_header->buffer_count = static_cast<s16>(voice_channels + mix_buffer_count);
command_list_header->sample_count = sample_count;
command_list_header->sample_rate = sample_rate;
command_list_header->samples_buffer = samples_workbuffer;
const auto performance_initialized{performance_manager.IsInitialized()};
if (performance_initialized) {
performance_manager.TapFrame(adsp_behind, num_voices_dropped, render_start_tick);
adsp_behind = false;
num_voices_dropped = 0;
render_start_tick = 0;
}
s8 channel_count{2};
if (execution_mode == ExecutionMode::Auto) {
const auto& sink{core.AudioCore().GetOutputSink()};
channel_count = static_cast<s8>(sink.GetDeviceChannels());
}
AudioRendererSystemContext render_context{
.session_id{session_id},
.channels{channel_count},
.mix_buffer_count{mix_buffer_count},
.behavior{&behavior},
.depop_buffer{depop_buffer},
.upsampler_manager{upsampler_manager},
.memory_pool_info{&memory_pool_info},
};
CommandBuffer command_buffer{
.command_list{in_command_buffer},
.sample_count{sample_count},
.sample_rate{sample_rate},
.size{sizeof(CommandListHeader)},
.count{0},
.estimated_process_time{0},
.memory_pool{&memory_pool_info},
.time_estimator{command_processing_time_estimator.get()},
.behavior{&behavior},
};
PerformanceManager* perf_manager{nullptr};
if (performance_initialized) {
perf_manager = &performance_manager;
}
CommandGenerator command_generator{command_buffer, *command_list_header, render_context,
voice_context, mix_context, effect_context,
sink_context, splitter_context, perf_manager};
voice_context.SortInfo();
const auto start_estimated_time{drop_voice_param *
static_cast<f32>(command_buffer.estimated_process_time)};
command_generator.GenerateVoiceCommands();
command_generator.GenerateSubMixCommands();
command_generator.GenerateFinalMixCommands();
command_generator.GenerateSinkCommands();
if (drop_voice) {
f32 time_limit_percent{70.0f};
if (render_context.behavior->IsAudioRendererProcessingTimeLimit80PercentSupported()) {
time_limit_percent = 80.0f;
} else if (render_context.behavior
->IsAudioRendererProcessingTimeLimit75PercentSupported()) {
time_limit_percent = 75.0f;
} else {
// result is ignored
render_context.behavior->IsAudioRendererProcessingTimeLimit70PercentSupported();
time_limit_percent = 70.0f;
}
const auto end_estimated_time{drop_voice_param *
static_cast<f32>(command_buffer.estimated_process_time)};
const auto estimated_time{start_estimated_time - end_estimated_time};
const auto time_limit{static_cast<u32>(
estimated_time + (((time_limit_percent / 100.0f) * 2'880'000.0) *
(static_cast<f32>(render_time_limit_percent) / 100.0f)))};
num_voices_dropped =
DropVoices(command_buffer, static_cast<u32>(start_estimated_time), time_limit);
}
command_list_header->buffer_size = command_buffer.size;
command_list_header->command_count = command_buffer.count;
voice_context.UpdateStateByDspShared();
if (render_context.behavior->IsEffectInfoVersion2Supported()) {
effect_context.UpdateStateByDspShared();
}
const auto end_time{core.CoreTiming().GetClockTicks()};
total_ticks_elapsed += end_time - start_time;
num_command_lists_generated++;
render_start_tick = adsp.GetRenderingStartTick(session_id);
frames_elapsed++;
return command_buffer.size;
}
f32 System::GetVoiceDropParameter() const {
return drop_voice_param;
}
void System::SetVoiceDropParameter(f32 voice_drop_) {
drop_voice_param = voice_drop_;
}
u32 System::DropVoices(CommandBuffer& command_buffer, u32 estimated_process_time, u32 time_limit) {
u32 i{0};
auto command_list{command_buffer.command_list.data() + sizeof(CommandListHeader)};
ICommand* cmd{nullptr};
// Find a first valid voice to drop
while (i < command_buffer.count) {
cmd = reinterpret_cast<ICommand*>(command_list);
if (cmd->type == CommandId::Performance ||
cmd->type == CommandId::DataSourcePcmInt16Version1 ||
cmd->type == CommandId::DataSourcePcmInt16Version2 ||
cmd->type == CommandId::DataSourcePcmFloatVersion1 ||
cmd->type == CommandId::DataSourcePcmFloatVersion2 ||
cmd->type == CommandId::DataSourceAdpcmVersion1 ||
cmd->type == CommandId::DataSourceAdpcmVersion2) {
break;
}
command_list += cmd->size;
i++;
}
if (cmd == nullptr || command_buffer.count == 0 || i >= command_buffer.count) {
return 0;
}
auto voices_dropped{0};
while (i < command_buffer.count) {
const auto node_id{cmd->node_id};
const auto node_id_type{cmd->node_id >> 28};
const auto node_id_base{cmd->node_id & 0xFFF};
// If the new estimated process time falls below the limit, we're done dropping.
if (estimated_process_time <= time_limit) {
break;
}
if (node_id_type != 1) {
break;
}
// Don't drop voices marked with the highest priority.
auto& voice_info{voice_context.GetInfo(node_id_base)};
if (voice_info.priority == HighestVoicePriority) {
break;
}
voices_dropped++;
voice_info.voice_dropped = true;
// First iteration should drop the voice, and then iterate through all of the commands tied
// to the voice. We don't need reverb on a voice which we've just removed, for example.
// Depops can't be removed otherwise we'll introduce audio popping, and we don't
// remove perf commands. Lower the estimated time for each command dropped.
while (i < command_buffer.count && cmd->node_id == node_id) {
if (cmd->type == CommandId::DepopPrepare) {
cmd->enabled = true;
} else if (cmd->enabled && cmd->type != CommandId::Performance) {
cmd->enabled = false;
estimated_process_time -= static_cast<u32>(
drop_voice_param * static_cast<f32>(cmd->estimated_process_time));
}
command_list += cmd->size;
cmd = reinterpret_cast<ICommand*>(command_list);
i++;
}
i++;
}
return voices_dropped;
}
} // namespace AudioCore::AudioRenderer
