// Copyright 2020 yuzu Emulator Project // Licensed under GPLv2 or any later version // Refer to the license.txt file included. #include "audio_core/behavior_info.h" #include "audio_core/effect_context.h" #include "audio_core/info_updater.h" #include "audio_core/memory_pool.h" #include "audio_core/mix_context.h" #include "audio_core/sink_context.h" #include "audio_core/splitter_context.h" #include "audio_core/voice_context.h" #include "common/logging/log.h" namespace AudioCore { InfoUpdater::InfoUpdater(const std::vector& in_params_, std::vector& out_params_, BehaviorInfo& behavior_info_) : in_params(in_params_), out_params(out_params_), behavior_info(behavior_info_) { ASSERT( AudioCommon::CanConsumeBuffer(in_params.size(), 0, sizeof(AudioCommon::UpdateDataHeader))); std::memcpy(&input_header, in_params.data(), sizeof(AudioCommon::UpdateDataHeader)); output_header.total_size = sizeof(AudioCommon::UpdateDataHeader); } InfoUpdater::~InfoUpdater() = default; bool InfoUpdater::UpdateBehaviorInfo(BehaviorInfo& in_behavior_info) { if (input_header.size.behavior != sizeof(BehaviorInfo::InParams)) { LOG_ERROR(Audio, "Behavior info is an invalid size, expecting 0x{:X} but got 0x{:X}", sizeof(BehaviorInfo::InParams), input_header.size.behavior); return false; } if (!AudioCommon::CanConsumeBuffer(in_params.size(), input_offset, sizeof(BehaviorInfo::InParams))) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } BehaviorInfo::InParams behavior_in{}; std::memcpy(&behavior_in, in_params.data() + input_offset, sizeof(BehaviorInfo::InParams)); input_offset += sizeof(BehaviorInfo::InParams); // Make sure it's an audio revision we can actually support if (!AudioCommon::IsValidRevision(behavior_in.revision)) { LOG_ERROR(Audio, "Invalid input revision, revision=0x{:08X}", behavior_in.revision); return false; } // Make sure that our behavior info revision matches the input if (in_behavior_info.GetUserRevision() != behavior_in.revision) { LOG_ERROR(Audio, "User revision differs from input revision, expecting 0x{:08X} but got 0x{:08X}", in_behavior_info.GetUserRevision(), behavior_in.revision); return false; } // Update behavior info flags in_behavior_info.ClearError(); in_behavior_info.UpdateFlags(behavior_in.flags); return true; } bool InfoUpdater::UpdateMemoryPools(std::vector& memory_pool_info) { const auto memory_pool_count = memory_pool_info.size(); const auto total_memory_pool_in = sizeof(ServerMemoryPoolInfo::InParams) * memory_pool_count; const auto total_memory_pool_out = sizeof(ServerMemoryPoolInfo::OutParams) * memory_pool_count; if (input_header.size.memory_pool != total_memory_pool_in) { LOG_ERROR(Audio, "Memory pools are an invalid size, expecting 0x{:X} but got 0x{:X}", total_memory_pool_in, input_header.size.memory_pool); return false; } if (!AudioCommon::CanConsumeBuffer(in_params.size(), input_offset, total_memory_pool_in)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } std::vector mempool_in(memory_pool_count); std::vector mempool_out(memory_pool_count); std::memcpy(mempool_in.data(), in_params.data() + input_offset, total_memory_pool_in); input_offset += total_memory_pool_in; // Update our memory pools for (std::size_t i = 0; i < memory_pool_count; i++) { if (!memory_pool_info[i].Update(mempool_in[i], mempool_out[i])) { LOG_ERROR(Audio, "Failed to update memory pool {}!", i); return false; } } if (!AudioCommon::CanConsumeBuffer(out_params.size(), output_offset, sizeof(BehaviorInfo::InParams))) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } std::memcpy(out_params.data() + output_offset, mempool_out.data(), total_memory_pool_out); output_offset += total_memory_pool_out; output_header.size.memory_pool = static_cast(total_memory_pool_out); return true; } bool InfoUpdater::UpdateVoiceChannelResources(VoiceContext& voice_context) { const auto voice_count = voice_context.GetVoiceCount(); const auto voice_size = voice_count * sizeof(VoiceChannelResource::InParams); std::vector resources_in(voice_count); if (input_header.size.voice_channel_resource != voice_size) { LOG_ERROR(Audio, "VoiceChannelResource is an invalid size, expecting 0x{:X} but got 0x{:X}", voice_size, input_header.size.voice_channel_resource); return false; } if (!AudioCommon::CanConsumeBuffer(in_params.size(), input_offset, voice_size)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } std::memcpy(resources_in.data(), in_params.data() + input_offset, voice_size); input_offset += voice_size; // Update our channel resources for (std::size_t i = 0; i < voice_count; i++) { // Grab our channel resource auto& resource = voice_context.GetChannelResource(i); resource.Update(resources_in[i]); } return true; } bool InfoUpdater::UpdateVoices(VoiceContext& voice_context, [[maybe_unused]] std::vector& memory_pool_info, [[maybe_unused]] VAddr audio_codec_dsp_addr) { const auto voice_count = voice_context.GetVoiceCount(); std::vector voice_in(voice_count); std::vector voice_out(voice_count); const auto voice_in_size = voice_count * sizeof(VoiceInfo::InParams); const auto voice_out_size = voice_count * sizeof(VoiceInfo::OutParams); if (input_header.size.voice != voice_in_size) { LOG_ERROR(Audio, "Voices are an invalid size, expecting 0x{:X} but got 0x{:X}", voice_in_size, input_header.size.voice); return false; } if (!AudioCommon::CanConsumeBuffer(in_params.size(), input_offset, voice_in_size)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } std::memcpy(voice_in.data(), in_params.data() + input_offset, voice_in_size); input_offset += voice_in_size; // Set all voices to not be in use for (std::size_t i = 0; i < voice_count; i++) { voice_context.GetInfo(i).GetInParams().in_use = false; } // Update our voices for (std::size_t i = 0; i < voice_count; i++) { auto& voice_in_params = voice_in[i]; const auto channel_count = static_cast(voice_in_params.channel_count); // Skip if it's not currently in use // TODO: in-use voices shouldn't have 0 channels, investigate why this happens if (!voice_in_params.is_in_use || channel_count == 0) { continue; } // Voice states for each channel std::array voice_states{}; ASSERT(static_cast(voice_in_params.id) < voice_count); // Grab our current voice info auto& voice_info = voice_context.GetInfo(static_cast(voice_in_params.id)); ASSERT(channel_count <= AudioCommon::MAX_CHANNEL_COUNT); // Get all our channel voice states for (std::size_t channel = 0; channel < channel_count; channel++) { voice_states[channel] = &voice_context.GetState(voice_in_params.voice_channel_resource_ids[channel]); } if (voice_in_params.is_new) { // Default our values for our voice voice_info.Initialize(); if (channel_count == 0 || channel_count > AudioCommon::MAX_CHANNEL_COUNT) { continue; } // Zero out our voice states for (std::size_t channel = 0; channel < channel_count; channel++) { std::memset(voice_states[channel], 0, sizeof(VoiceState)); } } // Update our voice voice_info.UpdateParameters(voice_in_params, behavior_info); // TODO(ogniK): Handle mapping errors with behavior info based on in params response // Update our wave buffers voice_info.UpdateWaveBuffers(voice_in_params, voice_states, behavior_info); voice_info.WriteOutStatus(voice_out[i], voice_in_params, voice_states); } if (!AudioCommon::CanConsumeBuffer(out_params.size(), output_offset, voice_out_size)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } std::memcpy(out_params.data() + output_offset, voice_out.data(), voice_out_size); output_offset += voice_out_size; output_header.size.voice = static_cast(voice_out_size); return true; } bool InfoUpdater::UpdateEffects(EffectContext& effect_context, bool is_active) { const auto effect_count = effect_context.GetCount(); std::vector effect_in(effect_count); std::vector effect_out(effect_count); const auto total_effect_in = effect_count * sizeof(EffectInfo::InParams); const auto total_effect_out = effect_count * sizeof(EffectInfo::OutParams); if (input_header.size.effect != total_effect_in) { LOG_ERROR(Audio, "Effects are an invalid size, expecting 0x{:X} but got 0x{:X}", total_effect_in, input_header.size.effect); return false; } if (!AudioCommon::CanConsumeBuffer(in_params.size(), input_offset, total_effect_in)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } std::memcpy(effect_in.data(), in_params.data() + input_offset, total_effect_in); input_offset += total_effect_in; // Update effects for (std::size_t i = 0; i < effect_count; i++) { auto* info = effect_context.GetInfo(i); if (effect_in[i].type != info->GetType()) { info = effect_context.RetargetEffect(i, effect_in[i].type); } info->Update(effect_in[i]); if ((!is_active && info->GetUsage() != UsageState::Initialized) || info->GetUsage() == UsageState::Stopped) { effect_out[i].status = UsageStatus::Removed; } else { effect_out[i].status = UsageStatus::Used; } } if (!AudioCommon::CanConsumeBuffer(out_params.size(), output_offset, total_effect_out)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } std::memcpy(out_params.data() + output_offset, effect_out.data(), total_effect_out); output_offset += total_effect_out; output_header.size.effect = static_cast(total_effect_out); return true; } bool InfoUpdater::UpdateSplitterInfo(SplitterContext& splitter_context) { std::size_t start_offset = input_offset; std::size_t bytes_read{}; // Update splitter context if (!splitter_context.Update(in_params, input_offset, bytes_read)) { LOG_ERROR(Audio, "Failed to update splitter context!"); return false; } const auto consumed = input_offset - start_offset; if (input_header.size.splitter != consumed) { LOG_ERROR(Audio, "Splitters is an invalid size, expecting 0x{:X} but got 0x{:X}", bytes_read, input_header.size.splitter); return false; } return true; } ResultCode InfoUpdater::UpdateMixes(MixContext& mix_context, std::size_t mix_buffer_count, SplitterContext& splitter_context, EffectContext& effect_context) { std::vector mix_in_params; if (!behavior_info.IsMixInParameterDirtyOnlyUpdateSupported()) { // If we're not dirty, get ALL mix in parameters const auto context_mix_count = mix_context.GetCount(); const auto total_mix_in = context_mix_count * sizeof(MixInfo::InParams); if (input_header.size.mixer != total_mix_in) { LOG_ERROR(Audio, "Mixer is an invalid size, expecting 0x{:X} but got 0x{:X}", total_mix_in, input_header.size.mixer); return AudioCommon::Audren::ERR_INVALID_PARAMETERS; } if (!AudioCommon::CanConsumeBuffer(in_params.size(), input_offset, total_mix_in)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return AudioCommon::Audren::ERR_INVALID_PARAMETERS; } mix_in_params.resize(context_mix_count); std::memcpy(mix_in_params.data(), in_params.data() + input_offset, total_mix_in); input_offset += total_mix_in; } else { // Only update the "dirty" mixes MixInfo::DirtyHeader dirty_header{}; if (!AudioCommon::CanConsumeBuffer(in_params.size(), input_offset, sizeof(MixInfo::DirtyHeader))) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return AudioCommon::Audren::ERR_INVALID_PARAMETERS; } std::memcpy(&dirty_header, in_params.data() + input_offset, sizeof(MixInfo::DirtyHeader)); input_offset += sizeof(MixInfo::DirtyHeader); const auto total_mix_in = dirty_header.mixer_count * sizeof(MixInfo::InParams) + sizeof(MixInfo::DirtyHeader); if (input_header.size.mixer != total_mix_in) { LOG_ERROR(Audio, "Mixer is an invalid size, expecting 0x{:X} but got 0x{:X}", total_mix_in, input_header.size.mixer); return AudioCommon::Audren::ERR_INVALID_PARAMETERS; } if (dirty_header.mixer_count != 0) { mix_in_params.resize(dirty_header.mixer_count); std::memcpy(mix_in_params.data(), in_params.data() + input_offset, mix_in_params.size() * sizeof(MixInfo::InParams)); input_offset += mix_in_params.size() * sizeof(MixInfo::InParams); } } // Get our total input count const auto mix_count = mix_in_params.size(); if (!behavior_info.IsMixInParameterDirtyOnlyUpdateSupported()) { // Only verify our buffer count if we're not dirty std::size_t total_buffer_count{}; for (std::size_t i = 0; i < mix_count; i++) { const auto& in = mix_in_params[i]; total_buffer_count += in.buffer_count; if (static_cast(in.dest_mix_id) > mix_count && in.dest_mix_id != AudioCommon::NO_MIX && in.mix_id != AudioCommon::FINAL_MIX) { LOG_ERROR( Audio, "Invalid mix destination, mix_id={:X}, dest_mix_id={:X}, mix_buffer_count={:X}", in.mix_id, in.dest_mix_id, mix_buffer_count); return AudioCommon::Audren::ERR_INVALID_PARAMETERS; } } if (total_buffer_count > mix_buffer_count) { LOG_ERROR(Audio, "Too many mix buffers used! mix_buffer_count={:X}, requesting_buffers={:X}", mix_buffer_count, total_buffer_count); return AudioCommon::Audren::ERR_INVALID_PARAMETERS; } } if (mix_buffer_count == 0) { LOG_ERROR(Audio, "No mix buffers!"); return AudioCommon::Audren::ERR_INVALID_PARAMETERS; } bool should_sort = false; for (std::size_t i = 0; i < mix_count; i++) { const auto& mix_in = mix_in_params[i]; std::size_t target_mix{}; if (behavior_info.IsMixInParameterDirtyOnlyUpdateSupported()) { target_mix = mix_in.mix_id; } else { // Non dirty supported games just use i instead of the actual mix_id target_mix = i; } auto& mix_info = mix_context.GetInfo(target_mix); auto& mix_info_params = mix_info.GetInParams(); if (mix_info_params.in_use != mix_in.in_use) { mix_info_params.in_use = mix_in.in_use; mix_info.ResetEffectProcessingOrder(); should_sort = true; } if (mix_in.in_use) { should_sort |= mix_info.Update(mix_context.GetEdgeMatrix(), mix_in, behavior_info, splitter_context, effect_context); } } if (should_sort && behavior_info.IsSplitterSupported()) { // Sort our splitter data if (!mix_context.TsortInfo(splitter_context)) { return AudioCommon::Audren::ERR_SPLITTER_SORT_FAILED; } } // TODO(ogniK): Sort when splitter is suppoorted return ResultSuccess; } bool InfoUpdater::UpdateSinks(SinkContext& sink_context) { const auto sink_count = sink_context.GetCount(); std::vector sink_in_params(sink_count); const auto total_sink_in = sink_count * sizeof(SinkInfo::InParams); if (input_header.size.sink != total_sink_in) { LOG_ERROR(Audio, "Sinks are an invalid size, expecting 0x{:X} but got 0x{:X}", total_sink_in, input_header.size.effect); return false; } if (!AudioCommon::CanConsumeBuffer(in_params.size(), input_offset, total_sink_in)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } std::memcpy(sink_in_params.data(), in_params.data() + input_offset, total_sink_in); input_offset += total_sink_in; // TODO(ogniK): Properly update sinks if (!sink_in_params.empty()) { sink_context.UpdateMainSink(sink_in_params[0]); } output_header.size.sink = static_cast(0x20 * sink_count); output_offset += 0x20 * sink_count; return true; } bool InfoUpdater::UpdatePerformanceBuffer() { output_header.size.performance = 0x10; output_offset += 0x10; return true; } bool InfoUpdater::UpdateErrorInfo([[maybe_unused]] BehaviorInfo& in_behavior_info) { const auto total_beahvior_info_out = sizeof(BehaviorInfo::OutParams); if (!AudioCommon::CanConsumeBuffer(out_params.size(), output_offset, total_beahvior_info_out)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } BehaviorInfo::OutParams behavior_info_out{}; behavior_info.CopyErrorInfo(behavior_info_out); std::memcpy(out_params.data() + output_offset, &behavior_info_out, total_beahvior_info_out); output_offset += total_beahvior_info_out; output_header.size.behavior = total_beahvior_info_out; return true; } struct RendererInfo { u64_le elasped_frame_count{}; INSERT_PADDING_WORDS(2); }; static_assert(sizeof(RendererInfo) == 0x10, "RendererInfo is an invalid size"); bool InfoUpdater::UpdateRendererInfo(std::size_t elapsed_frame_count) { const auto total_renderer_info_out = sizeof(RendererInfo); if (!AudioCommon::CanConsumeBuffer(out_params.size(), output_offset, total_renderer_info_out)) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } RendererInfo out{}; out.elasped_frame_count = elapsed_frame_count; std::memcpy(out_params.data() + output_offset, &out, total_renderer_info_out); output_offset += total_renderer_info_out; output_header.size.render_info = total_renderer_info_out; return true; } bool InfoUpdater::CheckConsumedSize() const { if (output_offset != out_params.size()) { LOG_ERROR(Audio, "Output is not consumed! Consumed {}, but requires {}. {} bytes remaining", output_offset, out_params.size(), out_params.size() - output_offset); return false; } /*if (input_offset != in_params.size()) { LOG_ERROR(Audio, "Input is not consumed!"); return false; }*/ return true; } bool InfoUpdater::WriteOutputHeader() { if (!AudioCommon::CanConsumeBuffer(out_params.size(), 0, sizeof(AudioCommon::UpdateDataHeader))) { LOG_ERROR(Audio, "Buffer is an invalid size!"); return false; } output_header.revision = AudioCommon::CURRENT_PROCESS_REVISION; const auto& sz = output_header.size; output_header.total_size += sz.behavior + sz.memory_pool + sz.voice + sz.voice_channel_resource + sz.effect + sz.mixer + sz.sink + sz.performance + sz.splitter + sz.render_info; std::memcpy(out_params.data(), &output_header, sizeof(AudioCommon::UpdateDataHeader)); return true; } } // namespace AudioCore