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Convert files to LF eol

This commit is contained in:
Kelebek1 2023-11-04 18:25:40 +00:00
parent 940618a64d
commit 90aa937593
16 changed files with 884 additions and 884 deletions

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// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#include "audio_core/adsp/apps/opus/opus_decode_object.h" #include "audio_core/adsp/apps/opus/opus_decode_object.h"
#include "common/assert.h" #include "common/assert.h"
namespace AudioCore::ADSP::OpusDecoder { namespace AudioCore::ADSP::OpusDecoder {
namespace { namespace {
bool IsValidChannelCount(u32 channel_count) { bool IsValidChannelCount(u32 channel_count) {
return channel_count == 1 || channel_count == 2; return channel_count == 1 || channel_count == 2;
} }
} // namespace } // namespace
u32 OpusDecodeObject::GetWorkBufferSize(u32 channel_count) { u32 OpusDecodeObject::GetWorkBufferSize(u32 channel_count) {
if (!IsValidChannelCount(channel_count)) { if (!IsValidChannelCount(channel_count)) {
return 0; return 0;
} }
return static_cast<u32>(sizeof(OpusDecodeObject)) + opus_decoder_get_size(channel_count); return static_cast<u32>(sizeof(OpusDecodeObject)) + opus_decoder_get_size(channel_count);
} }
OpusDecodeObject& OpusDecodeObject::Initialize(u64 buffer, u64 buffer2) { OpusDecodeObject& OpusDecodeObject::Initialize(u64 buffer, u64 buffer2) {
auto* new_decoder = reinterpret_cast<OpusDecodeObject*>(buffer); auto* new_decoder = reinterpret_cast<OpusDecodeObject*>(buffer);
auto* comparison = reinterpret_cast<OpusDecodeObject*>(buffer2); auto* comparison = reinterpret_cast<OpusDecodeObject*>(buffer2);
if (new_decoder->magic == DecodeObjectMagic) { if (new_decoder->magic == DecodeObjectMagic) {
if (!new_decoder->initialized || if (!new_decoder->initialized ||
(new_decoder->initialized && new_decoder->self == comparison)) { (new_decoder->initialized && new_decoder->self == comparison)) {
new_decoder->state_valid = true; new_decoder->state_valid = true;
} }
} else { } else {
new_decoder->initialized = false; new_decoder->initialized = false;
new_decoder->state_valid = true; new_decoder->state_valid = true;
} }
return *new_decoder; return *new_decoder;
} }
s32 OpusDecodeObject::InitializeDecoder(u32 sample_rate, u32 channel_count) { s32 OpusDecodeObject::InitializeDecoder(u32 sample_rate, u32 channel_count) {
if (!state_valid) { if (!state_valid) {
return OPUS_INVALID_STATE; return OPUS_INVALID_STATE;
} }
if (initialized) { if (initialized) {
return OPUS_OK; return OPUS_OK;
} }
// Unfortunately libopus does not expose the OpusDecoder struct publicly, so we can't include // Unfortunately libopus does not expose the OpusDecoder struct publicly, so we can't include
// it in this class. Nintendo does not allocate memory, which is why we have a workbuffer // it in this class. Nintendo does not allocate memory, which is why we have a workbuffer
// provided. // provided.
// We could use _create and have libopus allocate it for us, but then we have to separately // We could use _create and have libopus allocate it for us, but then we have to separately
// track which decoder is being used between this and multistream in order to call the correct // track which decoder is being used between this and multistream in order to call the correct
// destroy from the host side. // destroy from the host side.
// This is a bit cringe, but is safe as these objects are only ever initialized inside the given // This is a bit cringe, but is safe as these objects are only ever initialized inside the given
// workbuffer, and GetWorkBufferSize will guarantee there's enough space to follow. // workbuffer, and GetWorkBufferSize will guarantee there's enough space to follow.
decoder = (LibOpusDecoder*)(this + 1); decoder = (LibOpusDecoder*)(this + 1);
s32 ret = opus_decoder_init(decoder, sample_rate, channel_count); s32 ret = opus_decoder_init(decoder, sample_rate, channel_count);
if (ret == OPUS_OK) { if (ret == OPUS_OK) {
magic = DecodeObjectMagic; magic = DecodeObjectMagic;
initialized = true; initialized = true;
state_valid = true; state_valid = true;
self = this; self = this;
final_range = 0; final_range = 0;
} }
return ret; return ret;
} }
s32 OpusDecodeObject::Shutdown() { s32 OpusDecodeObject::Shutdown() {
if (!state_valid) { if (!state_valid) {
return OPUS_INVALID_STATE; return OPUS_INVALID_STATE;
} }
if (initialized) { if (initialized) {
magic = 0x0; magic = 0x0;
initialized = false; initialized = false;
state_valid = false; state_valid = false;
self = nullptr; self = nullptr;
final_range = 0; final_range = 0;
decoder = nullptr; decoder = nullptr;
} }
return OPUS_OK; return OPUS_OK;
} }
s32 OpusDecodeObject::ResetDecoder() { s32 OpusDecodeObject::ResetDecoder() {
return opus_decoder_ctl(decoder, OPUS_RESET_STATE); return opus_decoder_ctl(decoder, OPUS_RESET_STATE);
} }
s32 OpusDecodeObject::Decode(u32& out_sample_count, u64 output_data, u64 output_data_size, s32 OpusDecodeObject::Decode(u32& out_sample_count, u64 output_data, u64 output_data_size,
u64 input_data, u64 input_data_size) { u64 input_data, u64 input_data_size) {
ASSERT(initialized); ASSERT(initialized);
out_sample_count = 0; out_sample_count = 0;
if (!state_valid) { if (!state_valid) {
return OPUS_INVALID_STATE; return OPUS_INVALID_STATE;
} }
auto ret_code_or_samples = opus_decode( auto ret_code_or_samples = opus_decode(
decoder, reinterpret_cast<const u8*>(input_data), static_cast<opus_int32>(input_data_size), decoder, reinterpret_cast<const u8*>(input_data), static_cast<opus_int32>(input_data_size),
reinterpret_cast<opus_int16*>(output_data), static_cast<opus_int32>(output_data_size), 0); reinterpret_cast<opus_int16*>(output_data), static_cast<opus_int32>(output_data_size), 0);
if (ret_code_or_samples < OPUS_OK) { if (ret_code_or_samples < OPUS_OK) {
return ret_code_or_samples; return ret_code_or_samples;
} }
out_sample_count = ret_code_or_samples; out_sample_count = ret_code_or_samples;
return opus_decoder_ctl(decoder, OPUS_GET_FINAL_RANGE_REQUEST, &final_range); return opus_decoder_ctl(decoder, OPUS_GET_FINAL_RANGE_REQUEST, &final_range);
} }
} // namespace AudioCore::ADSP::OpusDecoder } // namespace AudioCore::ADSP::OpusDecoder

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// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#include "audio_core/adsp/apps/opus/opus_multistream_decode_object.h" #include "audio_core/adsp/apps/opus/opus_multistream_decode_object.h"
#include "common/assert.h" #include "common/assert.h"
namespace AudioCore::ADSP::OpusDecoder { namespace AudioCore::ADSP::OpusDecoder {
namespace { namespace {
bool IsValidChannelCount(u32 channel_count) { bool IsValidChannelCount(u32 channel_count) {
return channel_count == 1 || channel_count == 2; return channel_count == 1 || channel_count == 2;
} }
bool IsValidStreamCounts(u32 total_stream_count, u32 stereo_stream_count) { bool IsValidStreamCounts(u32 total_stream_count, u32 stereo_stream_count) {
return total_stream_count > 0 && stereo_stream_count > 0 && return total_stream_count > 0 && stereo_stream_count > 0 &&
stereo_stream_count <= total_stream_count && IsValidChannelCount(total_stream_count); stereo_stream_count <= total_stream_count && IsValidChannelCount(total_stream_count);
} }
} // namespace } // namespace
u32 OpusMultiStreamDecodeObject::GetWorkBufferSize(u32 total_stream_count, u32 OpusMultiStreamDecodeObject::GetWorkBufferSize(u32 total_stream_count,
u32 stereo_stream_count) { u32 stereo_stream_count) {
if (IsValidStreamCounts(total_stream_count, stereo_stream_count)) { if (IsValidStreamCounts(total_stream_count, stereo_stream_count)) {
return static_cast<u32>(sizeof(OpusMultiStreamDecodeObject)) + return static_cast<u32>(sizeof(OpusMultiStreamDecodeObject)) +
opus_multistream_decoder_get_size(total_stream_count, stereo_stream_count); opus_multistream_decoder_get_size(total_stream_count, stereo_stream_count);
} }
return 0; return 0;
} }
OpusMultiStreamDecodeObject& OpusMultiStreamDecodeObject::Initialize(u64 buffer, u64 buffer2) { OpusMultiStreamDecodeObject& OpusMultiStreamDecodeObject::Initialize(u64 buffer, u64 buffer2) {
auto* new_decoder = reinterpret_cast<OpusMultiStreamDecodeObject*>(buffer); auto* new_decoder = reinterpret_cast<OpusMultiStreamDecodeObject*>(buffer);
auto* comparison = reinterpret_cast<OpusMultiStreamDecodeObject*>(buffer2); auto* comparison = reinterpret_cast<OpusMultiStreamDecodeObject*>(buffer2);
if (new_decoder->magic == DecodeMultiStreamObjectMagic) { if (new_decoder->magic == DecodeMultiStreamObjectMagic) {
if (!new_decoder->initialized || if (!new_decoder->initialized ||
(new_decoder->initialized && new_decoder->self == comparison)) { (new_decoder->initialized && new_decoder->self == comparison)) {
new_decoder->state_valid = true; new_decoder->state_valid = true;
} }
} else { } else {
new_decoder->initialized = false; new_decoder->initialized = false;
new_decoder->state_valid = true; new_decoder->state_valid = true;
} }
return *new_decoder; return *new_decoder;
} }
s32 OpusMultiStreamDecodeObject::InitializeDecoder(u32 sample_rate, u32 total_stream_count, s32 OpusMultiStreamDecodeObject::InitializeDecoder(u32 sample_rate, u32 total_stream_count,
u32 channel_count, u32 stereo_stream_count, u32 channel_count, u32 stereo_stream_count,
u8* mappings) { u8* mappings) {
if (!state_valid) { if (!state_valid) {
return OPUS_INVALID_STATE; return OPUS_INVALID_STATE;
} }
if (initialized) { if (initialized) {
return OPUS_OK; return OPUS_OK;
} }
// See OpusDecodeObject::InitializeDecoder for an explanation of this // See OpusDecodeObject::InitializeDecoder for an explanation of this
decoder = (LibOpusMSDecoder*)(this + 1); decoder = (LibOpusMSDecoder*)(this + 1);
s32 ret = opus_multistream_decoder_init(decoder, sample_rate, channel_count, total_stream_count, s32 ret = opus_multistream_decoder_init(decoder, sample_rate, channel_count, total_stream_count,
stereo_stream_count, mappings); stereo_stream_count, mappings);
if (ret == OPUS_OK) { if (ret == OPUS_OK) {
magic = DecodeMultiStreamObjectMagic; magic = DecodeMultiStreamObjectMagic;
initialized = true; initialized = true;
state_valid = true; state_valid = true;
self = this; self = this;
final_range = 0; final_range = 0;
} }
return ret; return ret;
} }
s32 OpusMultiStreamDecodeObject::Shutdown() { s32 OpusMultiStreamDecodeObject::Shutdown() {
if (!state_valid) { if (!state_valid) {
return OPUS_INVALID_STATE; return OPUS_INVALID_STATE;
} }
if (initialized) { if (initialized) {
magic = 0x0; magic = 0x0;
initialized = false; initialized = false;
state_valid = false; state_valid = false;
self = nullptr; self = nullptr;
final_range = 0; final_range = 0;
decoder = nullptr; decoder = nullptr;
} }
return OPUS_OK; return OPUS_OK;
} }
s32 OpusMultiStreamDecodeObject::ResetDecoder() { s32 OpusMultiStreamDecodeObject::ResetDecoder() {
return opus_multistream_decoder_ctl(decoder, OPUS_RESET_STATE); return opus_multistream_decoder_ctl(decoder, OPUS_RESET_STATE);
} }
s32 OpusMultiStreamDecodeObject::Decode(u32& out_sample_count, u64 output_data, s32 OpusMultiStreamDecodeObject::Decode(u32& out_sample_count, u64 output_data,
u64 output_data_size, u64 input_data, u64 input_data_size) { u64 output_data_size, u64 input_data, u64 input_data_size) {
ASSERT(initialized); ASSERT(initialized);
out_sample_count = 0; out_sample_count = 0;
if (!state_valid) { if (!state_valid) {
return OPUS_INVALID_STATE; return OPUS_INVALID_STATE;
} }
auto ret_code_or_samples = opus_multistream_decode( auto ret_code_or_samples = opus_multistream_decode(
decoder, reinterpret_cast<const u8*>(input_data), static_cast<opus_int32>(input_data_size), decoder, reinterpret_cast<const u8*>(input_data), static_cast<opus_int32>(input_data_size),
reinterpret_cast<opus_int16*>(output_data), static_cast<opus_int32>(output_data_size), 0); reinterpret_cast<opus_int16*>(output_data), static_cast<opus_int32>(output_data_size), 0);
if (ret_code_or_samples < OPUS_OK) { if (ret_code_or_samples < OPUS_OK) {
return ret_code_or_samples; return ret_code_or_samples;
} }
out_sample_count = ret_code_or_samples; out_sample_count = ret_code_or_samples;
return opus_multistream_decoder_ctl(decoder, OPUS_GET_FINAL_RANGE_REQUEST, &final_range); return opus_multistream_decoder_ctl(decoder, OPUS_GET_FINAL_RANGE_REQUEST, &final_range);
} }
} // namespace AudioCore::ADSP::OpusDecoder } // namespace AudioCore::ADSP::OpusDecoder

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// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#include "audio_core/opus/decoder.h" #include "audio_core/opus/decoder.h"
#include "audio_core/opus/hardware_opus.h" #include "audio_core/opus/hardware_opus.h"
#include "audio_core/opus/parameters.h" #include "audio_core/opus/parameters.h"
#include "common/alignment.h" #include "common/alignment.h"
#include "common/swap.h" #include "common/swap.h"
#include "core/core.h" #include "core/core.h"
namespace AudioCore::OpusDecoder { namespace AudioCore::OpusDecoder {
using namespace Service::Audio; using namespace Service::Audio;
namespace { namespace {
OpusPacketHeader ReverseHeader(OpusPacketHeader header) { OpusPacketHeader ReverseHeader(OpusPacketHeader header) {
OpusPacketHeader out; OpusPacketHeader out;
out.size = Common::swap32(header.size); out.size = Common::swap32(header.size);
out.final_range = Common::swap32(header.final_range); out.final_range = Common::swap32(header.final_range);
return out; return out;
} }
} // namespace } // namespace
OpusDecoder::OpusDecoder(Core::System& system_, HardwareOpus& hardware_opus_) OpusDecoder::OpusDecoder(Core::System& system_, HardwareOpus& hardware_opus_)
: system{system_}, hardware_opus{hardware_opus_} {} : system{system_}, hardware_opus{hardware_opus_} {}
OpusDecoder::~OpusDecoder() { OpusDecoder::~OpusDecoder() {
if (decode_object_initialized) { if (decode_object_initialized) {
hardware_opus.ShutdownDecodeObject(shared_buffer.get(), shared_buffer_size); hardware_opus.ShutdownDecodeObject(shared_buffer.get(), shared_buffer_size);
} }
} }
Result OpusDecoder::Initialize(OpusParametersEx& params, Kernel::KTransferMemory* transfer_memory, Result OpusDecoder::Initialize(OpusParametersEx& params, Kernel::KTransferMemory* transfer_memory,
u64 transfer_memory_size) { u64 transfer_memory_size) {
auto frame_size{params.use_large_frame_size ? 5760 : 1920}; auto frame_size{params.use_large_frame_size ? 5760 : 1920};
shared_buffer_size = transfer_memory_size; shared_buffer_size = transfer_memory_size;
shared_buffer = std::make_unique<u8[]>(shared_buffer_size); shared_buffer = std::make_unique<u8[]>(shared_buffer_size);
shared_memory_mapped = true; shared_memory_mapped = true;
buffer_size = buffer_size =
Common::AlignUp((frame_size * params.channel_count) / (48'000 / params.sample_rate), 16); Common::AlignUp((frame_size * params.channel_count) / (48'000 / params.sample_rate), 16);
out_data = {shared_buffer.get() + shared_buffer_size - buffer_size, buffer_size}; out_data = {shared_buffer.get() + shared_buffer_size - buffer_size, buffer_size};
size_t in_data_size{0x600u}; size_t in_data_size{0x600u};
in_data = {out_data.data() - in_data_size, in_data_size}; in_data = {out_data.data() - in_data_size, in_data_size};
ON_RESULT_FAILURE { ON_RESULT_FAILURE {
if (shared_memory_mapped) { if (shared_memory_mapped) {
shared_memory_mapped = false; shared_memory_mapped = false;
ASSERT(R_SUCCEEDED(hardware_opus.UnmapMemory(shared_buffer.get(), shared_buffer_size))); ASSERT(R_SUCCEEDED(hardware_opus.UnmapMemory(shared_buffer.get(), shared_buffer_size)));
} }
}; };
R_TRY(hardware_opus.InitializeDecodeObject(params.sample_rate, params.channel_count, R_TRY(hardware_opus.InitializeDecodeObject(params.sample_rate, params.channel_count,
shared_buffer.get(), shared_buffer_size)); shared_buffer.get(), shared_buffer_size));
sample_rate = params.sample_rate; sample_rate = params.sample_rate;
channel_count = params.channel_count; channel_count = params.channel_count;
use_large_frame_size = params.use_large_frame_size; use_large_frame_size = params.use_large_frame_size;
decode_object_initialized = true; decode_object_initialized = true;
R_SUCCEED(); R_SUCCEED();
} }
Result OpusDecoder::Initialize(OpusMultiStreamParametersEx& params, Result OpusDecoder::Initialize(OpusMultiStreamParametersEx& params,
Kernel::KTransferMemory* transfer_memory, u64 transfer_memory_size) { Kernel::KTransferMemory* transfer_memory, u64 transfer_memory_size) {
auto frame_size{params.use_large_frame_size ? 5760 : 1920}; auto frame_size{params.use_large_frame_size ? 5760 : 1920};
shared_buffer_size = transfer_memory_size; shared_buffer_size = transfer_memory_size;
shared_buffer = std::make_unique<u8[]>(shared_buffer_size); shared_buffer = std::make_unique<u8[]>(shared_buffer_size);
shared_memory_mapped = true; shared_memory_mapped = true;
buffer_size = buffer_size =
Common::AlignUp((frame_size * params.channel_count) / (48'000 / params.sample_rate), 16); Common::AlignUp((frame_size * params.channel_count) / (48'000 / params.sample_rate), 16);
out_data = {shared_buffer.get() + shared_buffer_size - buffer_size, buffer_size}; out_data = {shared_buffer.get() + shared_buffer_size - buffer_size, buffer_size};
size_t in_data_size{Common::AlignUp(1500ull * params.total_stream_count, 64u)}; size_t in_data_size{Common::AlignUp(1500ull * params.total_stream_count, 64u)};
in_data = {out_data.data() - in_data_size, in_data_size}; in_data = {out_data.data() - in_data_size, in_data_size};
ON_RESULT_FAILURE { ON_RESULT_FAILURE {
if (shared_memory_mapped) { if (shared_memory_mapped) {
shared_memory_mapped = false; shared_memory_mapped = false;
ASSERT(R_SUCCEEDED(hardware_opus.UnmapMemory(shared_buffer.get(), shared_buffer_size))); ASSERT(R_SUCCEEDED(hardware_opus.UnmapMemory(shared_buffer.get(), shared_buffer_size)));
} }
}; };
R_TRY(hardware_opus.InitializeMultiStreamDecodeObject( R_TRY(hardware_opus.InitializeMultiStreamDecodeObject(
params.sample_rate, params.channel_count, params.total_stream_count, params.sample_rate, params.channel_count, params.total_stream_count,
params.stereo_stream_count, params.mappings.data(), shared_buffer.get(), params.stereo_stream_count, params.mappings.data(), shared_buffer.get(),
shared_buffer_size)); shared_buffer_size));
sample_rate = params.sample_rate; sample_rate = params.sample_rate;
channel_count = params.channel_count; channel_count = params.channel_count;
total_stream_count = params.total_stream_count; total_stream_count = params.total_stream_count;
stereo_stream_count = params.stereo_stream_count; stereo_stream_count = params.stereo_stream_count;
use_large_frame_size = params.use_large_frame_size; use_large_frame_size = params.use_large_frame_size;
decode_object_initialized = true; decode_object_initialized = true;
R_SUCCEED(); R_SUCCEED();
} }
Result OpusDecoder::DecodeInterleaved(u32* out_data_size, u64* out_time_taken, Result OpusDecoder::DecodeInterleaved(u32* out_data_size, u64* out_time_taken,
u32* out_sample_count, std::span<const u8> input_data, u32* out_sample_count, std::span<const u8> input_data,
std::span<u8> output_data, bool reset) { std::span<u8> output_data, bool reset) {
u32 out_samples; u32 out_samples;
u64 time_taken{}; u64 time_taken{};
R_UNLESS(input_data.size_bytes() > sizeof(OpusPacketHeader), ResultInputDataTooSmall); R_UNLESS(input_data.size_bytes() > sizeof(OpusPacketHeader), ResultInputDataTooSmall);
auto* header_p{reinterpret_cast<const OpusPacketHeader*>(input_data.data())}; auto* header_p{reinterpret_cast<const OpusPacketHeader*>(input_data.data())};
OpusPacketHeader header{ReverseHeader(*header_p)}; OpusPacketHeader header{ReverseHeader(*header_p)};
R_UNLESS(in_data.size_bytes() >= header.size && R_UNLESS(in_data.size_bytes() >= header.size &&
header.size + sizeof(OpusPacketHeader) <= input_data.size_bytes(), header.size + sizeof(OpusPacketHeader) <= input_data.size_bytes(),
ResultBufferTooSmall); ResultBufferTooSmall);
if (!shared_memory_mapped) { if (!shared_memory_mapped) {
R_TRY(hardware_opus.MapMemory(shared_buffer.get(), shared_buffer_size)); R_TRY(hardware_opus.MapMemory(shared_buffer.get(), shared_buffer_size));
shared_memory_mapped = true; shared_memory_mapped = true;
} }
std::memcpy(in_data.data(), input_data.data() + sizeof(OpusPacketHeader), header.size); std::memcpy(in_data.data(), input_data.data() + sizeof(OpusPacketHeader), header.size);
R_TRY(hardware_opus.DecodeInterleaved(out_samples, out_data.data(), out_data.size_bytes(), R_TRY(hardware_opus.DecodeInterleaved(out_samples, out_data.data(), out_data.size_bytes(),
channel_count, in_data.data(), header.size, channel_count, in_data.data(), header.size,
shared_buffer.get(), time_taken, reset)); shared_buffer.get(), time_taken, reset));
std::memcpy(output_data.data(), out_data.data(), out_samples * channel_count * sizeof(s16)); std::memcpy(output_data.data(), out_data.data(), out_samples * channel_count * sizeof(s16));
*out_data_size = header.size + sizeof(OpusPacketHeader); *out_data_size = header.size + sizeof(OpusPacketHeader);
*out_sample_count = out_samples; *out_sample_count = out_samples;
if (out_time_taken) { if (out_time_taken) {
*out_time_taken = time_taken / 1000; *out_time_taken = time_taken / 1000;
} }
R_SUCCEED(); R_SUCCEED();
} }
Result OpusDecoder::SetContext([[maybe_unused]] std::span<const u8> context) { Result OpusDecoder::SetContext([[maybe_unused]] std::span<const u8> context) {
R_SUCCEED_IF(shared_memory_mapped); R_SUCCEED_IF(shared_memory_mapped);
shared_memory_mapped = true; shared_memory_mapped = true;
R_RETURN(hardware_opus.MapMemory(shared_buffer.get(), shared_buffer_size)); R_RETURN(hardware_opus.MapMemory(shared_buffer.get(), shared_buffer_size));
} }
Result OpusDecoder::DecodeInterleavedForMultiStream(u32* out_data_size, u64* out_time_taken, Result OpusDecoder::DecodeInterleavedForMultiStream(u32* out_data_size, u64* out_time_taken,
u32* out_sample_count, u32* out_sample_count,
std::span<const u8> input_data, std::span<const u8> input_data,
std::span<u8> output_data, bool reset) { std::span<u8> output_data, bool reset) {
u32 out_samples; u32 out_samples;
u64 time_taken{}; u64 time_taken{};
R_UNLESS(input_data.size_bytes() > sizeof(OpusPacketHeader), ResultInputDataTooSmall); R_UNLESS(input_data.size_bytes() > sizeof(OpusPacketHeader), ResultInputDataTooSmall);
auto* header_p{reinterpret_cast<const OpusPacketHeader*>(input_data.data())}; auto* header_p{reinterpret_cast<const OpusPacketHeader*>(input_data.data())};
OpusPacketHeader header{ReverseHeader(*header_p)}; OpusPacketHeader header{ReverseHeader(*header_p)};
LOG_ERROR(Service_Audio, "header size 0x{:X} input data size 0x{:X} in_data size 0x{:X}", LOG_ERROR(Service_Audio, "header size 0x{:X} input data size 0x{:X} in_data size 0x{:X}",
header.size, input_data.size_bytes(), in_data.size_bytes()); header.size, input_data.size_bytes(), in_data.size_bytes());
R_UNLESS(in_data.size_bytes() >= header.size && R_UNLESS(in_data.size_bytes() >= header.size &&
header.size + sizeof(OpusPacketHeader) <= input_data.size_bytes(), header.size + sizeof(OpusPacketHeader) <= input_data.size_bytes(),
ResultBufferTooSmall); ResultBufferTooSmall);
if (!shared_memory_mapped) { if (!shared_memory_mapped) {
R_TRY(hardware_opus.MapMemory(shared_buffer.get(), shared_buffer_size)); R_TRY(hardware_opus.MapMemory(shared_buffer.get(), shared_buffer_size));
shared_memory_mapped = true; shared_memory_mapped = true;
} }
std::memcpy(in_data.data(), input_data.data() + sizeof(OpusPacketHeader), header.size); std::memcpy(in_data.data(), input_data.data() + sizeof(OpusPacketHeader), header.size);
R_TRY(hardware_opus.DecodeInterleavedForMultiStream( R_TRY(hardware_opus.DecodeInterleavedForMultiStream(
out_samples, out_data.data(), out_data.size_bytes(), channel_count, in_data.data(), out_samples, out_data.data(), out_data.size_bytes(), channel_count, in_data.data(),
header.size, shared_buffer.get(), time_taken, reset)); header.size, shared_buffer.get(), time_taken, reset));
std::memcpy(output_data.data(), out_data.data(), out_samples * channel_count * sizeof(s16)); std::memcpy(output_data.data(), out_data.data(), out_samples * channel_count * sizeof(s16));
*out_data_size = header.size + sizeof(OpusPacketHeader); *out_data_size = header.size + sizeof(OpusPacketHeader);
*out_sample_count = out_samples; *out_sample_count = out_samples;
if (out_time_taken) { if (out_time_taken) {
*out_time_taken = time_taken / 1000; *out_time_taken = time_taken / 1000;
} }
R_SUCCEED(); R_SUCCEED();
} }
} // namespace AudioCore::OpusDecoder } // namespace AudioCore::OpusDecoder

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// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once
#include <span> #include <span>
#include "audio_core/opus/parameters.h" #include "audio_core/opus/parameters.h"
#include "common/common_types.h" #include "common/common_types.h"
#include "core/hle/kernel/k_transfer_memory.h" #include "core/hle/kernel/k_transfer_memory.h"
#include "core/hle/service/audio/errors.h" #include "core/hle/service/audio/errors.h"
namespace Core { namespace Core {
class System; class System;
} }
namespace AudioCore::OpusDecoder { namespace AudioCore::OpusDecoder {
class HardwareOpus; class HardwareOpus;
class OpusDecoder { class OpusDecoder {
public: public:
explicit OpusDecoder(Core::System& system, HardwareOpus& hardware_opus_); explicit OpusDecoder(Core::System& system, HardwareOpus& hardware_opus_);
~OpusDecoder(); ~OpusDecoder();
Result Initialize(OpusParametersEx& params, Kernel::KTransferMemory* transfer_memory, Result Initialize(OpusParametersEx& params, Kernel::KTransferMemory* transfer_memory,
u64 transfer_memory_size); u64 transfer_memory_size);
Result Initialize(OpusMultiStreamParametersEx& params, Kernel::KTransferMemory* transfer_memory, Result Initialize(OpusMultiStreamParametersEx& params, Kernel::KTransferMemory* transfer_memory,
u64 transfer_memory_size); u64 transfer_memory_size);
Result DecodeInterleaved(u32* out_data_size, u64* out_time_taken, u32* out_sample_count, Result DecodeInterleaved(u32* out_data_size, u64* out_time_taken, u32* out_sample_count,
std::span<const u8> input_data, std::span<u8> output_data, bool reset); std::span<const u8> input_data, std::span<u8> output_data, bool reset);
Result SetContext([[maybe_unused]] std::span<const u8> context); Result SetContext([[maybe_unused]] std::span<const u8> context);
Result DecodeInterleavedForMultiStream(u32* out_data_size, u64* out_time_taken, Result DecodeInterleavedForMultiStream(u32* out_data_size, u64* out_time_taken,
u32* out_sample_count, std::span<const u8> input_data, u32* out_sample_count, std::span<const u8> input_data,
std::span<u8> output_data, bool reset); std::span<u8> output_data, bool reset);
private: private:
Core::System& system; Core::System& system;
HardwareOpus& hardware_opus; HardwareOpus& hardware_opus;
std::unique_ptr<u8[]> shared_buffer{}; std::unique_ptr<u8[]> shared_buffer{};
u64 shared_buffer_size; u64 shared_buffer_size;
std::span<u8> in_data{}; std::span<u8> in_data{};
std::span<u8> out_data{}; std::span<u8> out_data{};
u64 buffer_size{}; u64 buffer_size{};
s32 sample_rate{}; s32 sample_rate{};
s32 channel_count{}; s32 channel_count{};
bool use_large_frame_size{false}; bool use_large_frame_size{false};
s32 total_stream_count{}; s32 total_stream_count{};
s32 stereo_stream_count{}; s32 stereo_stream_count{};
bool shared_memory_mapped{false}; bool shared_memory_mapped{false};
bool decode_object_initialized{false}; bool decode_object_initialized{false};
}; };
} // namespace AudioCore::OpusDecoder } // namespace AudioCore::OpusDecoder

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// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#include "audio_core/adsp/apps/opus/opus_decoder.h" #include "audio_core/adsp/apps/opus/opus_decoder.h"
#include "audio_core/opus/decoder_manager.h" #include "audio_core/opus/decoder_manager.h"
#include "common/alignment.h" #include "common/alignment.h"
#include "core/core.h" #include "core/core.h"
namespace AudioCore::OpusDecoder { namespace AudioCore::OpusDecoder {
using namespace Service::Audio; using namespace Service::Audio;
namespace { namespace {
bool IsValidChannelCount(u32 channel_count) { bool IsValidChannelCount(u32 channel_count) {
return channel_count == 1 || channel_count == 2; return channel_count == 1 || channel_count == 2;
} }
bool IsValidMultiStreamChannelCount(u32 channel_count) { bool IsValidMultiStreamChannelCount(u32 channel_count) {
return channel_count > 0 && channel_count <= OpusStreamCountMax; return channel_count > 0 && channel_count <= OpusStreamCountMax;
} }
bool IsValidSampleRate(u32 sample_rate) { bool IsValidSampleRate(u32 sample_rate) {
return sample_rate == 8'000 || sample_rate == 12'000 || sample_rate == 16'000 || return sample_rate == 8'000 || sample_rate == 12'000 || sample_rate == 16'000 ||
sample_rate == 24'000 || sample_rate == 48'000; sample_rate == 24'000 || sample_rate == 48'000;
} }
bool IsValidStreamCount(u32 channel_count, u32 total_stream_count, u32 stereo_stream_count) { bool IsValidStreamCount(u32 channel_count, u32 total_stream_count, u32 stereo_stream_count) {
return total_stream_count > 0 && static_cast<s32>(stereo_stream_count) >= 0 && return total_stream_count > 0 && static_cast<s32>(stereo_stream_count) >= 0 &&
stereo_stream_count <= total_stream_count && stereo_stream_count <= total_stream_count &&
total_stream_count + stereo_stream_count <= channel_count; total_stream_count + stereo_stream_count <= channel_count;
} }
} // namespace } // namespace
OpusDecoderManager::OpusDecoderManager(Core::System& system_) OpusDecoderManager::OpusDecoderManager(Core::System& system_)
: system{system_}, hardware_opus{system} { : system{system_}, hardware_opus{system} {
for (u32 i = 0; i < MaxChannels; i++) { for (u32 i = 0; i < MaxChannels; i++) {
required_workbuffer_sizes[i] = hardware_opus.GetWorkBufferSize(1 + i); required_workbuffer_sizes[i] = hardware_opus.GetWorkBufferSize(1 + i);
} }
} }
Result OpusDecoderManager::GetWorkBufferSize(OpusParameters& params, u64& out_size) { Result OpusDecoderManager::GetWorkBufferSize(OpusParameters& params, u64& out_size) {
OpusParametersEx ex{ OpusParametersEx ex{
.sample_rate = params.sample_rate, .sample_rate = params.sample_rate,
.channel_count = params.channel_count, .channel_count = params.channel_count,
.use_large_frame_size = false, .use_large_frame_size = false,
}; };
R_RETURN(GetWorkBufferSizeExEx(ex, out_size)); R_RETURN(GetWorkBufferSizeExEx(ex, out_size));
} }
Result OpusDecoderManager::GetWorkBufferSizeEx(OpusParametersEx& params, u64& out_size) { Result OpusDecoderManager::GetWorkBufferSizeEx(OpusParametersEx& params, u64& out_size) {
R_RETURN(GetWorkBufferSizeExEx(params, out_size)); R_RETURN(GetWorkBufferSizeExEx(params, out_size));
} }
Result OpusDecoderManager::GetWorkBufferSizeExEx(OpusParametersEx& params, u64& out_size) { Result OpusDecoderManager::GetWorkBufferSizeExEx(OpusParametersEx& params, u64& out_size) {
R_UNLESS(IsValidChannelCount(params.channel_count), ResultInvalidOpusChannelCount); R_UNLESS(IsValidChannelCount(params.channel_count), ResultInvalidOpusChannelCount);
R_UNLESS(IsValidSampleRate(params.sample_rate), ResultInvalidOpusSampleRate); R_UNLESS(IsValidSampleRate(params.sample_rate), ResultInvalidOpusSampleRate);
auto work_buffer_size{required_workbuffer_sizes[params.channel_count - 1]}; auto work_buffer_size{required_workbuffer_sizes[params.channel_count - 1]};
auto frame_size{params.use_large_frame_size ? 5760 : 1920}; auto frame_size{params.use_large_frame_size ? 5760 : 1920};
work_buffer_size += work_buffer_size +=
Common::AlignUp((frame_size * params.channel_count) / (48'000 / params.sample_rate), 64); Common::AlignUp((frame_size * params.channel_count) / (48'000 / params.sample_rate), 64);
out_size = work_buffer_size + 0x600; out_size = work_buffer_size + 0x600;
R_SUCCEED(); R_SUCCEED();
} }
Result OpusDecoderManager::GetWorkBufferSizeForMultiStream(OpusMultiStreamParameters& params, Result OpusDecoderManager::GetWorkBufferSizeForMultiStream(OpusMultiStreamParameters& params,
u64& out_size) { u64& out_size) {
OpusMultiStreamParametersEx ex{ OpusMultiStreamParametersEx ex{
.sample_rate = params.sample_rate, .sample_rate = params.sample_rate,
.channel_count = params.channel_count, .channel_count = params.channel_count,
.total_stream_count = params.total_stream_count, .total_stream_count = params.total_stream_count,
.stereo_stream_count = params.stereo_stream_count, .stereo_stream_count = params.stereo_stream_count,
.use_large_frame_size = false, .use_large_frame_size = false,
.mappings = {}, .mappings = {},
}; };
R_RETURN(GetWorkBufferSizeForMultiStreamExEx(ex, out_size)); R_RETURN(GetWorkBufferSizeForMultiStreamExEx(ex, out_size));
} }
Result OpusDecoderManager::GetWorkBufferSizeForMultiStreamEx(OpusMultiStreamParametersEx& params, Result OpusDecoderManager::GetWorkBufferSizeForMultiStreamEx(OpusMultiStreamParametersEx& params,
u64& out_size) { u64& out_size) {
R_RETURN(GetWorkBufferSizeForMultiStreamExEx(params, out_size)); R_RETURN(GetWorkBufferSizeForMultiStreamExEx(params, out_size));
} }
Result OpusDecoderManager::GetWorkBufferSizeForMultiStreamExEx(OpusMultiStreamParametersEx& params, Result OpusDecoderManager::GetWorkBufferSizeForMultiStreamExEx(OpusMultiStreamParametersEx& params,
u64& out_size) { u64& out_size) {
R_UNLESS(IsValidMultiStreamChannelCount(params.channel_count), ResultInvalidOpusChannelCount); R_UNLESS(IsValidMultiStreamChannelCount(params.channel_count), ResultInvalidOpusChannelCount);
R_UNLESS(IsValidSampleRate(params.sample_rate), ResultInvalidOpusSampleRate); R_UNLESS(IsValidSampleRate(params.sample_rate), ResultInvalidOpusSampleRate);
R_UNLESS(IsValidStreamCount(params.channel_count, params.total_stream_count, R_UNLESS(IsValidStreamCount(params.channel_count, params.total_stream_count,
params.stereo_stream_count), params.stereo_stream_count),
ResultInvalidOpusSampleRate); ResultInvalidOpusSampleRate);
auto work_buffer_size{hardware_opus.GetWorkBufferSizeForMultiStream( auto work_buffer_size{hardware_opus.GetWorkBufferSizeForMultiStream(
params.total_stream_count, params.stereo_stream_count)}; params.total_stream_count, params.stereo_stream_count)};
auto frame_size{params.use_large_frame_size ? 5760 : 1920}; auto frame_size{params.use_large_frame_size ? 5760 : 1920};
work_buffer_size += Common::AlignUp(1500 * params.total_stream_count, 64); work_buffer_size += Common::AlignUp(1500 * params.total_stream_count, 64);
work_buffer_size += work_buffer_size +=
Common::AlignUp((frame_size * params.channel_count) / (48'000 / params.sample_rate), 64); Common::AlignUp((frame_size * params.channel_count) / (48'000 / params.sample_rate), 64);
out_size = work_buffer_size; out_size = work_buffer_size;
R_SUCCEED(); R_SUCCEED();
} }
} // namespace AudioCore::OpusDecoder } // namespace AudioCore::OpusDecoder

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@ -1,38 +1,38 @@
// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once
#include "audio_core/opus/hardware_opus.h" #include "audio_core/opus/hardware_opus.h"
#include "audio_core/opus/parameters.h" #include "audio_core/opus/parameters.h"
#include "common/common_types.h" #include "common/common_types.h"
#include "core/hle/service/audio/errors.h" #include "core/hle/service/audio/errors.h"
namespace Core { namespace Core {
class System; class System;
} }
namespace AudioCore::OpusDecoder { namespace AudioCore::OpusDecoder {
class OpusDecoderManager { class OpusDecoderManager {
public: public:
OpusDecoderManager(Core::System& system); OpusDecoderManager(Core::System& system);
HardwareOpus& GetHardwareOpus() { HardwareOpus& GetHardwareOpus() {
return hardware_opus; return hardware_opus;
} }
Result GetWorkBufferSize(OpusParameters& params, u64& out_size); Result GetWorkBufferSize(OpusParameters& params, u64& out_size);
Result GetWorkBufferSizeEx(OpusParametersEx& params, u64& out_size); Result GetWorkBufferSizeEx(OpusParametersEx& params, u64& out_size);
Result GetWorkBufferSizeExEx(OpusParametersEx& params, u64& out_size); Result GetWorkBufferSizeExEx(OpusParametersEx& params, u64& out_size);
Result GetWorkBufferSizeForMultiStream(OpusMultiStreamParameters& params, u64& out_size); Result GetWorkBufferSizeForMultiStream(OpusMultiStreamParameters& params, u64& out_size);
Result GetWorkBufferSizeForMultiStreamEx(OpusMultiStreamParametersEx& params, u64& out_size); Result GetWorkBufferSizeForMultiStreamEx(OpusMultiStreamParametersEx& params, u64& out_size);
Result GetWorkBufferSizeForMultiStreamExEx(OpusMultiStreamParametersEx& params, u64& out_size); Result GetWorkBufferSizeForMultiStreamExEx(OpusMultiStreamParametersEx& params, u64& out_size);
private: private:
Core::System& system; Core::System& system;
HardwareOpus hardware_opus; HardwareOpus hardware_opus;
std::array<u64, MaxChannels> required_workbuffer_sizes{}; std::array<u64, MaxChannels> required_workbuffer_sizes{};
}; };
} // namespace AudioCore::OpusDecoder } // namespace AudioCore::OpusDecoder

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// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#include <array> #include <array>
#include "audio_core/audio_core.h" #include "audio_core/audio_core.h"
#include "audio_core/opus/hardware_opus.h" #include "audio_core/opus/hardware_opus.h"
#include "core/core.h" #include "core/core.h"
namespace AudioCore::OpusDecoder { namespace AudioCore::OpusDecoder {
namespace { namespace {
using namespace Service::Audio; using namespace Service::Audio;
static constexpr Result ResultCodeFromLibOpusErrorCode(u64 error_code) { static constexpr Result ResultCodeFromLibOpusErrorCode(u64 error_code) {
s32 error{static_cast<s32>(error_code)}; s32 error{static_cast<s32>(error_code)};
ASSERT(error <= OPUS_OK); ASSERT(error <= OPUS_OK);
switch (error) { switch (error) {
case OPUS_ALLOC_FAIL: case OPUS_ALLOC_FAIL:
R_THROW(ResultLibOpusAllocFail); R_THROW(ResultLibOpusAllocFail);
case OPUS_INVALID_STATE: case OPUS_INVALID_STATE:
R_THROW(ResultLibOpusInvalidState); R_THROW(ResultLibOpusInvalidState);
case OPUS_UNIMPLEMENTED: case OPUS_UNIMPLEMENTED:
R_THROW(ResultLibOpusUnimplemented); R_THROW(ResultLibOpusUnimplemented);
case OPUS_INVALID_PACKET: case OPUS_INVALID_PACKET:
R_THROW(ResultLibOpusInvalidPacket); R_THROW(ResultLibOpusInvalidPacket);
case OPUS_INTERNAL_ERROR: case OPUS_INTERNAL_ERROR:
R_THROW(ResultLibOpusInternalError); R_THROW(ResultLibOpusInternalError);
case OPUS_BUFFER_TOO_SMALL: case OPUS_BUFFER_TOO_SMALL:
R_THROW(ResultBufferTooSmall); R_THROW(ResultBufferTooSmall);
case OPUS_BAD_ARG: case OPUS_BAD_ARG:
R_THROW(ResultLibOpusBadArg); R_THROW(ResultLibOpusBadArg);
case OPUS_OK: case OPUS_OK:
R_RETURN(ResultSuccess); R_RETURN(ResultSuccess);
} }
UNREACHABLE(); UNREACHABLE();
} }
} // namespace } // namespace
HardwareOpus::HardwareOpus(Core::System& system_) HardwareOpus::HardwareOpus(Core::System& system_)
: system{system_}, opus_decoder{system.AudioCore().ADSP().OpusDecoder()} { : system{system_}, opus_decoder{system.AudioCore().ADSP().OpusDecoder()} {
opus_decoder.SetSharedMemory(shared_memory); opus_decoder.SetSharedMemory(shared_memory);
} }
u64 HardwareOpus::GetWorkBufferSize(u32 channel) { u64 HardwareOpus::GetWorkBufferSize(u32 channel) {
if (!opus_decoder.IsRunning()) { if (!opus_decoder.IsRunning()) {
return 0; return 0;
} }
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = channel; shared_memory.host_send_data[0] = channel;
opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::GetWorkBufferSize); opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::GetWorkBufferSize);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
if (msg != ADSP::OpusDecoder::Message::GetWorkBufferSizeOK) { if (msg != ADSP::OpusDecoder::Message::GetWorkBufferSizeOK) {
LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}", LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}",
ADSP::OpusDecoder::Message::GetWorkBufferSizeOK, msg); ADSP::OpusDecoder::Message::GetWorkBufferSizeOK, msg);
return 0; return 0;
} }
return shared_memory.dsp_return_data[0]; return shared_memory.dsp_return_data[0];
} }
u64 HardwareOpus::GetWorkBufferSizeForMultiStream(u32 total_stream_count, u32 stereo_stream_count) { u64 HardwareOpus::GetWorkBufferSizeForMultiStream(u32 total_stream_count, u32 stereo_stream_count) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = total_stream_count; shared_memory.host_send_data[0] = total_stream_count;
shared_memory.host_send_data[1] = stereo_stream_count; shared_memory.host_send_data[1] = stereo_stream_count;
opus_decoder.Send(ADSP::Direction::DSP, opus_decoder.Send(ADSP::Direction::DSP,
ADSP::OpusDecoder::Message::GetWorkBufferSizeForMultiStream); ADSP::OpusDecoder::Message::GetWorkBufferSizeForMultiStream);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
if (msg != ADSP::OpusDecoder::Message::GetWorkBufferSizeForMultiStreamOK) { if (msg != ADSP::OpusDecoder::Message::GetWorkBufferSizeForMultiStreamOK) {
LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}", LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}",
ADSP::OpusDecoder::Message::GetWorkBufferSizeForMultiStreamOK, msg); ADSP::OpusDecoder::Message::GetWorkBufferSizeForMultiStreamOK, msg);
return 0; return 0;
} }
return shared_memory.dsp_return_data[0]; return shared_memory.dsp_return_data[0];
} }
Result HardwareOpus::InitializeDecodeObject(u32 sample_rate, u32 channel_count, void* buffer, Result HardwareOpus::InitializeDecodeObject(u32 sample_rate, u32 channel_count, void* buffer,
u64 buffer_size) { u64 buffer_size) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = (u64)buffer; shared_memory.host_send_data[0] = (u64)buffer;
shared_memory.host_send_data[1] = buffer_size; shared_memory.host_send_data[1] = buffer_size;
shared_memory.host_send_data[2] = sample_rate; shared_memory.host_send_data[2] = sample_rate;
shared_memory.host_send_data[3] = channel_count; shared_memory.host_send_data[3] = channel_count;
opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::InitializeDecodeObject); opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::InitializeDecodeObject);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
if (msg != ADSP::OpusDecoder::Message::InitializeDecodeObjectOK) { if (msg != ADSP::OpusDecoder::Message::InitializeDecodeObjectOK) {
LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}", LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}",
ADSP::OpusDecoder::Message::InitializeDecodeObjectOK, msg); ADSP::OpusDecoder::Message::InitializeDecodeObjectOK, msg);
R_THROW(ResultInvalidOpusDSPReturnCode); R_THROW(ResultInvalidOpusDSPReturnCode);
} }
R_RETURN(ResultCodeFromLibOpusErrorCode(shared_memory.dsp_return_data[0])); R_RETURN(ResultCodeFromLibOpusErrorCode(shared_memory.dsp_return_data[0]));
} }
Result HardwareOpus::InitializeMultiStreamDecodeObject(u32 sample_rate, u32 channel_count, Result HardwareOpus::InitializeMultiStreamDecodeObject(u32 sample_rate, u32 channel_count,
u32 total_stream_count, u32 total_stream_count,
u32 stereo_stream_count, void* mappings, u32 stereo_stream_count, void* mappings,
void* buffer, u64 buffer_size) { void* buffer, u64 buffer_size) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = (u64)buffer; shared_memory.host_send_data[0] = (u64)buffer;
shared_memory.host_send_data[1] = buffer_size; shared_memory.host_send_data[1] = buffer_size;
shared_memory.host_send_data[2] = sample_rate; shared_memory.host_send_data[2] = sample_rate;
shared_memory.host_send_data[3] = channel_count; shared_memory.host_send_data[3] = channel_count;
shared_memory.host_send_data[4] = total_stream_count; shared_memory.host_send_data[4] = total_stream_count;
shared_memory.host_send_data[5] = stereo_stream_count; shared_memory.host_send_data[5] = stereo_stream_count;
ASSERT(channel_count <= MaxChannels); ASSERT(channel_count <= MaxChannels);
std::memcpy(shared_memory.channel_mapping.data(), mappings, channel_count * sizeof(u8)); std::memcpy(shared_memory.channel_mapping.data(), mappings, channel_count * sizeof(u8));
opus_decoder.Send(ADSP::Direction::DSP, opus_decoder.Send(ADSP::Direction::DSP,
ADSP::OpusDecoder::Message::InitializeMultiStreamDecodeObject); ADSP::OpusDecoder::Message::InitializeMultiStreamDecodeObject);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
if (msg != ADSP::OpusDecoder::Message::InitializeMultiStreamDecodeObjectOK) { if (msg != ADSP::OpusDecoder::Message::InitializeMultiStreamDecodeObjectOK) {
LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}", LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}",
ADSP::OpusDecoder::Message::InitializeMultiStreamDecodeObjectOK, msg); ADSP::OpusDecoder::Message::InitializeMultiStreamDecodeObjectOK, msg);
R_THROW(ResultInvalidOpusDSPReturnCode); R_THROW(ResultInvalidOpusDSPReturnCode);
} }
R_RETURN(ResultCodeFromLibOpusErrorCode(shared_memory.dsp_return_data[0])); R_RETURN(ResultCodeFromLibOpusErrorCode(shared_memory.dsp_return_data[0]));
} }
Result HardwareOpus::ShutdownDecodeObject(void* buffer, u64 buffer_size) { Result HardwareOpus::ShutdownDecodeObject(void* buffer, u64 buffer_size) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = (u64)buffer; shared_memory.host_send_data[0] = (u64)buffer;
shared_memory.host_send_data[1] = buffer_size; shared_memory.host_send_data[1] = buffer_size;
opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::ShutdownDecodeObject); opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::ShutdownDecodeObject);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
ASSERT_MSG(msg == ADSP::OpusDecoder::Message::ShutdownDecodeObjectOK, ASSERT_MSG(msg == ADSP::OpusDecoder::Message::ShutdownDecodeObjectOK,
"Expected Opus shutdown code {}, got {}", "Expected Opus shutdown code {}, got {}",
ADSP::OpusDecoder::Message::ShutdownDecodeObjectOK, msg); ADSP::OpusDecoder::Message::ShutdownDecodeObjectOK, msg);
R_RETURN(ResultCodeFromLibOpusErrorCode(shared_memory.dsp_return_data[0])); R_RETURN(ResultCodeFromLibOpusErrorCode(shared_memory.dsp_return_data[0]));
} }
Result HardwareOpus::ShutdownMultiStreamDecodeObject(void* buffer, u64 buffer_size) { Result HardwareOpus::ShutdownMultiStreamDecodeObject(void* buffer, u64 buffer_size) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = (u64)buffer; shared_memory.host_send_data[0] = (u64)buffer;
shared_memory.host_send_data[1] = buffer_size; shared_memory.host_send_data[1] = buffer_size;
opus_decoder.Send(ADSP::Direction::DSP, opus_decoder.Send(ADSP::Direction::DSP,
ADSP::OpusDecoder::Message::ShutdownMultiStreamDecodeObject); ADSP::OpusDecoder::Message::ShutdownMultiStreamDecodeObject);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
ASSERT_MSG(msg == ADSP::OpusDecoder::Message::ShutdownMultiStreamDecodeObjectOK, ASSERT_MSG(msg == ADSP::OpusDecoder::Message::ShutdownMultiStreamDecodeObjectOK,
"Expected Opus shutdown code {}, got {}", "Expected Opus shutdown code {}, got {}",
ADSP::OpusDecoder::Message::ShutdownMultiStreamDecodeObjectOK, msg); ADSP::OpusDecoder::Message::ShutdownMultiStreamDecodeObjectOK, msg);
R_RETURN(ResultCodeFromLibOpusErrorCode(shared_memory.dsp_return_data[0])); R_RETURN(ResultCodeFromLibOpusErrorCode(shared_memory.dsp_return_data[0]));
} }
Result HardwareOpus::DecodeInterleaved(u32& out_sample_count, void* output_data, Result HardwareOpus::DecodeInterleaved(u32& out_sample_count, void* output_data,
u64 output_data_size, u32 channel_count, void* input_data, u64 output_data_size, u32 channel_count, void* input_data,
u64 input_data_size, void* buffer, u64& out_time_taken, u64 input_data_size, void* buffer, u64& out_time_taken,
bool reset) { bool reset) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = (u64)buffer; shared_memory.host_send_data[0] = (u64)buffer;
shared_memory.host_send_data[1] = (u64)input_data; shared_memory.host_send_data[1] = (u64)input_data;
shared_memory.host_send_data[2] = input_data_size; shared_memory.host_send_data[2] = input_data_size;
shared_memory.host_send_data[3] = (u64)output_data; shared_memory.host_send_data[3] = (u64)output_data;
shared_memory.host_send_data[4] = output_data_size; shared_memory.host_send_data[4] = output_data_size;
shared_memory.host_send_data[5] = 0; shared_memory.host_send_data[5] = 0;
shared_memory.host_send_data[6] = reset; shared_memory.host_send_data[6] = reset;
opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::DecodeInterleaved); opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::DecodeInterleaved);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
if (msg != ADSP::OpusDecoder::Message::DecodeInterleavedOK) { if (msg != ADSP::OpusDecoder::Message::DecodeInterleavedOK) {
LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}", LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}",
ADSP::OpusDecoder::Message::DecodeInterleavedOK, msg); ADSP::OpusDecoder::Message::DecodeInterleavedOK, msg);
R_THROW(ResultInvalidOpusDSPReturnCode); R_THROW(ResultInvalidOpusDSPReturnCode);
} }
auto error_code{static_cast<s32>(shared_memory.dsp_return_data[0])}; auto error_code{static_cast<s32>(shared_memory.dsp_return_data[0])};
if (error_code == OPUS_OK) { if (error_code == OPUS_OK) {
out_sample_count = static_cast<u32>(shared_memory.dsp_return_data[1]); out_sample_count = static_cast<u32>(shared_memory.dsp_return_data[1]);
out_time_taken = 1000 * shared_memory.dsp_return_data[2]; out_time_taken = 1000 * shared_memory.dsp_return_data[2];
} }
R_RETURN(ResultCodeFromLibOpusErrorCode(error_code)); R_RETURN(ResultCodeFromLibOpusErrorCode(error_code));
} }
Result HardwareOpus::DecodeInterleavedForMultiStream(u32& out_sample_count, void* output_data, Result HardwareOpus::DecodeInterleavedForMultiStream(u32& out_sample_count, void* output_data,
u64 output_data_size, u32 channel_count, u64 output_data_size, u32 channel_count,
void* input_data, u64 input_data_size, void* input_data, u64 input_data_size,
void* buffer, u64& out_time_taken, void* buffer, u64& out_time_taken,
bool reset) { bool reset) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = (u64)buffer; shared_memory.host_send_data[0] = (u64)buffer;
shared_memory.host_send_data[1] = (u64)input_data; shared_memory.host_send_data[1] = (u64)input_data;
shared_memory.host_send_data[2] = input_data_size; shared_memory.host_send_data[2] = input_data_size;
shared_memory.host_send_data[3] = (u64)output_data; shared_memory.host_send_data[3] = (u64)output_data;
shared_memory.host_send_data[4] = output_data_size; shared_memory.host_send_data[4] = output_data_size;
shared_memory.host_send_data[5] = 0; shared_memory.host_send_data[5] = 0;
shared_memory.host_send_data[6] = reset; shared_memory.host_send_data[6] = reset;
opus_decoder.Send(ADSP::Direction::DSP, opus_decoder.Send(ADSP::Direction::DSP,
ADSP::OpusDecoder::Message::DecodeInterleavedForMultiStream); ADSP::OpusDecoder::Message::DecodeInterleavedForMultiStream);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
if (msg != ADSP::OpusDecoder::Message::DecodeInterleavedForMultiStreamOK) { if (msg != ADSP::OpusDecoder::Message::DecodeInterleavedForMultiStreamOK) {
LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}", LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}",
ADSP::OpusDecoder::Message::DecodeInterleavedForMultiStreamOK, msg); ADSP::OpusDecoder::Message::DecodeInterleavedForMultiStreamOK, msg);
R_THROW(ResultInvalidOpusDSPReturnCode); R_THROW(ResultInvalidOpusDSPReturnCode);
} }
auto error_code{static_cast<s32>(shared_memory.dsp_return_data[0])}; auto error_code{static_cast<s32>(shared_memory.dsp_return_data[0])};
if (error_code == OPUS_OK) { if (error_code == OPUS_OK) {
out_sample_count = static_cast<u32>(shared_memory.dsp_return_data[1]); out_sample_count = static_cast<u32>(shared_memory.dsp_return_data[1]);
out_time_taken = 1000 * shared_memory.dsp_return_data[2]; out_time_taken = 1000 * shared_memory.dsp_return_data[2];
} }
R_RETURN(ResultCodeFromLibOpusErrorCode(error_code)); R_RETURN(ResultCodeFromLibOpusErrorCode(error_code));
} }
Result HardwareOpus::MapMemory(void* buffer, u64 buffer_size) { Result HardwareOpus::MapMemory(void* buffer, u64 buffer_size) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = (u64)buffer; shared_memory.host_send_data[0] = (u64)buffer;
shared_memory.host_send_data[1] = buffer_size; shared_memory.host_send_data[1] = buffer_size;
opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::MapMemory); opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::MapMemory);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
if (msg != ADSP::OpusDecoder::Message::MapMemoryOK) { if (msg != ADSP::OpusDecoder::Message::MapMemoryOK) {
LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}", LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}",
ADSP::OpusDecoder::Message::MapMemoryOK, msg); ADSP::OpusDecoder::Message::MapMemoryOK, msg);
R_THROW(ResultInvalidOpusDSPReturnCode); R_THROW(ResultInvalidOpusDSPReturnCode);
} }
R_SUCCEED(); R_SUCCEED();
} }
Result HardwareOpus::UnmapMemory(void* buffer, u64 buffer_size) { Result HardwareOpus::UnmapMemory(void* buffer, u64 buffer_size) {
std::scoped_lock l{mutex}; std::scoped_lock l{mutex};
shared_memory.host_send_data[0] = (u64)buffer; shared_memory.host_send_data[0] = (u64)buffer;
shared_memory.host_send_data[1] = buffer_size; shared_memory.host_send_data[1] = buffer_size;
opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::UnmapMemory); opus_decoder.Send(ADSP::Direction::DSP, ADSP::OpusDecoder::Message::UnmapMemory);
auto msg = opus_decoder.Receive(ADSP::Direction::Host); auto msg = opus_decoder.Receive(ADSP::Direction::Host);
if (msg != ADSP::OpusDecoder::Message::UnmapMemoryOK) { if (msg != ADSP::OpusDecoder::Message::UnmapMemoryOK) {
LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}", LOG_ERROR(Service_Audio, "OpusDecoder returned invalid message. Expected {} got {}",
ADSP::OpusDecoder::Message::UnmapMemoryOK, msg); ADSP::OpusDecoder::Message::UnmapMemoryOK, msg);
R_THROW(ResultInvalidOpusDSPReturnCode); R_THROW(ResultInvalidOpusDSPReturnCode);
} }
R_SUCCEED(); R_SUCCEED();
} }
} // namespace AudioCore::OpusDecoder } // namespace AudioCore::OpusDecoder

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// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once
#include <mutex> #include <mutex>
#include <opus.h> #include <opus.h>
#include "audio_core/adsp/apps/opus/opus_decoder.h" #include "audio_core/adsp/apps/opus/opus_decoder.h"
#include "audio_core/adsp/apps/opus/shared_memory.h" #include "audio_core/adsp/apps/opus/shared_memory.h"
#include "audio_core/adsp/mailbox.h" #include "audio_core/adsp/mailbox.h"
#include "core/hle/service/audio/errors.h" #include "core/hle/service/audio/errors.h"
namespace AudioCore::OpusDecoder { namespace AudioCore::OpusDecoder {
class HardwareOpus { class HardwareOpus {
public: public:
HardwareOpus(Core::System& system); HardwareOpus(Core::System& system);
u64 GetWorkBufferSize(u32 channel); u64 GetWorkBufferSize(u32 channel);
u64 GetWorkBufferSizeForMultiStream(u32 total_stream_count, u32 stereo_stream_count); u64 GetWorkBufferSizeForMultiStream(u32 total_stream_count, u32 stereo_stream_count);
Result InitializeDecodeObject(u32 sample_rate, u32 channel_count, void* buffer, Result InitializeDecodeObject(u32 sample_rate, u32 channel_count, void* buffer,
u64 buffer_size); u64 buffer_size);
Result InitializeMultiStreamDecodeObject(u32 sample_rate, u32 channel_count, Result InitializeMultiStreamDecodeObject(u32 sample_rate, u32 channel_count,
u32 totaL_stream_count, u32 stereo_stream_count, u32 totaL_stream_count, u32 stereo_stream_count,
void* mappings, void* buffer, u64 buffer_size); void* mappings, void* buffer, u64 buffer_size);
Result ShutdownDecodeObject(void* buffer, u64 buffer_size); Result ShutdownDecodeObject(void* buffer, u64 buffer_size);
Result ShutdownMultiStreamDecodeObject(void* buffer, u64 buffer_size); Result ShutdownMultiStreamDecodeObject(void* buffer, u64 buffer_size);
Result DecodeInterleaved(u32& out_sample_count, void* output_data, u64 output_data_size, Result DecodeInterleaved(u32& out_sample_count, void* output_data, u64 output_data_size,
u32 channel_count, void* input_data, u64 input_data_size, void* buffer, u32 channel_count, void* input_data, u64 input_data_size, void* buffer,
u64& out_time_taken, bool reset); u64& out_time_taken, bool reset);
Result DecodeInterleavedForMultiStream(u32& out_sample_count, void* output_data, Result DecodeInterleavedForMultiStream(u32& out_sample_count, void* output_data,
u64 output_data_size, u32 channel_count, u64 output_data_size, u32 channel_count,
void* input_data, u64 input_data_size, void* buffer, void* input_data, u64 input_data_size, void* buffer,
u64& out_time_taken, bool reset); u64& out_time_taken, bool reset);
Result MapMemory(void* buffer, u64 buffer_size); Result MapMemory(void* buffer, u64 buffer_size);
Result UnmapMemory(void* buffer, u64 buffer_size); Result UnmapMemory(void* buffer, u64 buffer_size);
private: private:
Core::System& system; Core::System& system;
std::mutex mutex; std::mutex mutex;
ADSP::OpusDecoder::OpusDecoder& opus_decoder; ADSP::OpusDecoder::OpusDecoder& opus_decoder;
ADSP::OpusDecoder::SharedMemory shared_memory; ADSP::OpusDecoder::SharedMemory shared_memory;
}; };
} // namespace AudioCore::OpusDecoder } // namespace AudioCore::OpusDecoder

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// SPDX-FileCopyrightText: 2014 Citra Emulator Project // SPDX-FileCopyrightText: 2014 Citra Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once

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// Text : Copyright 2022 yuzu Emulator Project // Text : Copyright 2022 yuzu Emulator Project
// SPDX-License-Identifier: GPL-3.0-or-later // SPDX-License-Identifier: GPL-3.0-or-later
#pragma once #pragma once

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// SPDX-FileCopyrightText: 2016 Citra Emulator Project // SPDX-FileCopyrightText: 2016 Citra Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once

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// SPDX-FileCopyrightText: 2016 Citra Emulator Project // SPDX-FileCopyrightText: 2016 Citra Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once

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// SPDX-FileCopyrightText: Copyright 2020 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2020 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once

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// SPDX-FileCopyrightText: Copyright 2022 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2022 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once

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@ -1,4 +1,4 @@
// SPDX-FileCopyrightText: Copyright 2021 yuzu Emulator Project // SPDX-FileCopyrightText: Copyright 2021 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once

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@ -1,4 +1,4 @@
// SPDX-FileCopyrightText: 2016 Citra Emulator Project // SPDX-FileCopyrightText: 2016 Citra Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later // SPDX-License-Identifier: GPL-2.0-or-later
#pragma once #pragma once