rpcs3/rpcs3/Emu/SysCalls/Modules/cellAudio.cpp
2014-09-06 02:12:10 +04:00

907 lines
24 KiB
C++

#include "stdafx.h"
#include "Emu/Memory/Memory.h"
#include "Emu/System.h"
#include "Emu/SysCalls/Modules.h"
#include "rpcs3/Ini.h"
#include "Utilities/SQueue.h"
#include "Emu/Event.h"
#include "Emu/SysCalls/lv2/sys_time.h"
#include "Emu/Audio/AudioManager.h"
#include "Emu/Audio/AudioDumper.h"
#include "Emu/Audio/cellAudio.h"
//void cellAudio_init();
//Module cellAudio(0x0011, cellAudio_init);
Module *cellAudio = nullptr;
static std::mutex audioMutex;
AudioConfig m_config;
static const bool g_is_u16 = Ini.AudioConvertToU16.GetValue();
// libaudio Functions
#define BUFFER_NUM 32
#define BUFFER_SIZE 256
int cellAudioInit()
{
cellAudio->Warning("cellAudioInit()");
if (m_config.m_is_audio_initialized)
{
return CELL_AUDIO_ERROR_ALREADY_INIT;
}
m_config.m_is_audio_initialized = true;
m_config.start_time = 0;
m_config.counter = 0;
// alloc memory
m_config.m_buffer = (u32)Memory.Alloc(128 * 1024 * m_config.AUDIO_PORT_COUNT, 1024);
memset(vm::get_ptr<void>(m_config.m_buffer), 0, 128 * 1024 * m_config.AUDIO_PORT_COUNT);
m_config.m_indexes = (u32)Memory.Alloc(sizeof(u64) * m_config.AUDIO_PORT_COUNT, 16);
memset(vm::get_ptr<void>(m_config.m_indexes), 0, sizeof(u64) * m_config.AUDIO_PORT_COUNT);
thread t("Audio Thread", []()
{
AudioDumper m_dump(8); // WAV file header (8 ch)
bool do_dump = Ini.AudioDumpToFile.GetValue();
if (do_dump && !m_dump.Init())
{
cellAudio->Error("cellAudioInit(): AudioDumper::Init() failed");
return;
}
cellAudio->Notice("Audio thread started");
if (Ini.AudioDumpToFile.GetValue())
m_dump.WriteHeader();
float buf2ch[2 * BUFFER_SIZE]; // intermediate buffer for 2 channels
float buf8ch[8 * BUFFER_SIZE]; // intermediate buffer for 8 channels
uint oal_buffer_offset = 0;
const uint oal_buffer_size = 2 * BUFFER_SIZE;
std::unique_ptr<s16[]> oal_buffer[BUFFER_NUM];
std::unique_ptr<float[]> oal_buffer_float[BUFFER_NUM];
for (u32 i = 0; i < BUFFER_NUM; i++)
{
oal_buffer[i] = std::unique_ptr<s16[]>(new s16[oal_buffer_size] {} );
oal_buffer_float[i] = std::unique_ptr<float[]>(new float[oal_buffer_size] {} );
}
SQueue<s16*, 31> queue;
queue.Clear();
SQueue<float*, 31> queue_float;
queue_float.Clear();
std::vector<u64> keys;
if(m_audio_out)
{
m_audio_out->Init();
// Note: What if the ini value changes?
if (g_is_u16)
m_audio_out->Open(oal_buffer[0].get(), oal_buffer_size * sizeof(s16));
else
m_audio_out->Open(oal_buffer_float[0].get(), oal_buffer_size * sizeof(float));
}
m_config.start_time = get_system_time();
volatile bool internal_finished = false;
thread iat("Internal Audio Thread", [oal_buffer_size, &queue, &queue_float, &internal_finished]()
{
while (true)
{
s16* oal_buffer = nullptr;
float* oal_buffer_float = nullptr;
if (g_is_u16)
queue.Pop(oal_buffer);
else
queue_float.Pop(oal_buffer_float);
if (g_is_u16)
{
if (oal_buffer)
{
m_audio_out->AddData(oal_buffer, oal_buffer_size * sizeof(s16));
continue;
}
}
else
{
if (oal_buffer_float)
{
m_audio_out->AddData(oal_buffer_float, oal_buffer_size * sizeof(float));
continue;
}
}
internal_finished = true;
return;
}
});
iat.detach();
while (m_config.m_is_audio_initialized)
{
if (Emu.IsStopped())
{
cellAudio->Warning("Audio thread aborted");
goto abort;
}
const u64 stamp0 = get_system_time();
// TODO: send beforemix event (in ~2,6 ms before mixing)
// precise time of sleeping: 5,(3) ms (or 256/48000 sec)
if (m_config.counter * 256000000 / 48000 >= stamp0 - m_config.start_time)
{
std::this_thread::sleep_for(std::chrono::milliseconds(1));
continue;
}
m_config.counter++;
const u32 oal_pos = m_config.counter % BUFFER_NUM;
const u32 oal_pos_float = m_config.counter % BUFFER_NUM;
if (Emu.IsPaused())
{
continue;
}
bool first_mix = true;
// mixing:
for (u32 i = 0; i < m_config.AUDIO_PORT_COUNT; i++)
{
if (!m_config.m_ports[i].m_is_audio_port_started) continue;
AudioPortConfig& port = m_config.m_ports[i];
const u32 block_size = port.channel * 256;
const u32 position = port.tag % port.block; // old value
const u32 buf_addr = m_config.m_buffer + (i * 128 * 1024) + (position * block_size * sizeof(float));
auto buf = vm::get_ptr<be_t<float>>(buf_addr);
static const float k = 1.0f; // may be 1.0f
const float m = port.level;
if (port.channel == 2)
{
if (first_mix)
{
for (u32 i = 0; i < (sizeof(buf2ch) / sizeof(float)); i += 2)
{
// reverse byte order
const float left = buf[i + 0] * m;
const float right = buf[i + 1] * m;
buf2ch[i + 0] = left;
buf2ch[i + 1] = right;
buf8ch[i * 4 + 0] = left;
buf8ch[i * 4 + 1] = right;
buf8ch[i * 4 + 2] = 0.0f;
buf8ch[i * 4 + 3] = 0.0f;
buf8ch[i * 4 + 4] = 0.0f;
buf8ch[i * 4 + 5] = 0.0f;
buf8ch[i * 4 + 6] = 0.0f;
buf8ch[i * 4 + 7] = 0.0f;
}
first_mix = false;
}
else
{
for (u32 i = 0; i < (sizeof(buf2ch) / sizeof(float)); i += 2)
{
const float left = buf[i + 0] * m;
const float right = buf[i + 1] * m;
buf2ch[i + 0] += left;
buf2ch[i + 1] += right;
buf8ch[i * 4 + 0] += left;
buf8ch[i * 4 + 1] += right;
}
}
}
else if (port.channel == 6)
{
if (first_mix)
{
for (u32 i = 0; i < (sizeof(buf2ch) / sizeof(float)); i += 2)
{
const float left = buf[i * 3 + 0] * m;
const float right = buf[i * 3 + 1] * m;
const float center = buf[i * 3 + 2] * m;
const float low_freq = buf[i * 3 + 3] * m;
const float rear_left = buf[i * 3 + 4] * m;
const float rear_right = buf[i * 3 + 5] * m;
const float mid = (center + low_freq) * 0.708f;
buf2ch[i + 0] = (left + rear_left + mid) * k;
buf2ch[i + 1] = (right + rear_right + mid) * k;
buf8ch[i * 4 + 0] = left;
buf8ch[i * 4 + 1] = right;
buf8ch[i * 4 + 2] = center;
buf8ch[i * 4 + 3] = low_freq;
buf8ch[i * 4 + 4] = rear_left;
buf8ch[i * 4 + 5] = rear_right;
buf8ch[i * 4 + 6] = 0.0f;
buf8ch[i * 4 + 7] = 0.0f;
}
first_mix = false;
}
else
{
for (u32 i = 0; i < (sizeof(buf2ch) / sizeof(float)); i += 2)
{
const float left = buf[i * 3 + 0] * m;
const float right = buf[i * 3 + 1] * m;
const float center = buf[i * 3 + 2] * m;
const float low_freq = buf[i * 3 + 3] * m;
const float rear_left = buf[i * 3 + 4] * m;
const float rear_right = buf[i * 3 + 5] * m;
const float mid = (center + low_freq) * 0.708f;
buf2ch[i + 0] += (left + rear_left + mid) * k;
buf2ch[i + 1] += (right + rear_right + mid) * k;
buf8ch[i * 4 + 0] += left;
buf8ch[i * 4 + 1] += right;
buf8ch[i * 4 + 2] += center;
buf8ch[i * 4 + 3] += low_freq;
buf8ch[i * 4 + 4] += rear_left;
buf8ch[i * 4 + 5] += rear_right;
}
}
}
else if (port.channel == 8)
{
if (first_mix)
{
for (u32 i = 0; i < (sizeof(buf2ch) / sizeof(float)); i += 2)
{
const float left = buf[i * 4 + 0] * m;
const float right = buf[i * 4 + 1] * m;
const float center = buf[i * 4 + 2] * m;
const float low_freq = buf[i * 4 + 3] * m;
const float rear_left = buf[i * 4 + 4] * m;
const float rear_right = buf[i * 4 + 5] * m;
const float side_left = buf[i * 4 + 6] * m;
const float side_right = buf[i * 4 + 7] * m;
const float mid = (center + low_freq) * 0.708f;
buf2ch[i + 0] = (left + rear_left + side_left + mid) * k;
buf2ch[i + 1] = (right + rear_right + side_right + mid) * k;
buf8ch[i * 4 + 0] = left;
buf8ch[i * 4 + 1] = right;
buf8ch[i * 4 + 2] = center;
buf8ch[i * 4 + 3] = low_freq;
buf8ch[i * 4 + 4] = rear_left;
buf8ch[i * 4 + 5] = rear_right;
buf8ch[i * 4 + 6] = side_left;
buf8ch[i * 4 + 7] = side_right;
}
first_mix = false;
}
else
{
for (u32 i = 0; i < (sizeof(buf2ch) / sizeof(float)); i += 2)
{
const float left = buf[i * 4 + 0] * m;
const float right = buf[i * 4 + 1] * m;
const float center = buf[i * 4 + 2] * m;
const float low_freq = buf[i * 4 + 3] * m;
const float rear_left = buf[i * 4 + 4] * m;
const float rear_right = buf[i * 4 + 5] * m;
const float side_left = buf[i * 4 + 6] * m;
const float side_right = buf[i * 4 + 7] * m;
const float mid = (center + low_freq) * 0.708f;
buf2ch[i + 0] += (left + rear_left + side_left + mid) * k;
buf2ch[i + 1] += (right + rear_right + side_right + mid) * k;
buf8ch[i * 4 + 0] += left;
buf8ch[i * 4 + 1] += right;
buf8ch[i * 4 + 2] += center;
buf8ch[i * 4 + 3] += low_freq;
buf8ch[i * 4 + 4] += rear_left;
buf8ch[i * 4 + 5] += rear_right;
buf8ch[i * 4 + 6] += side_left;
buf8ch[i * 4 + 7] += side_right;
}
}
}
memset(buf, 0, block_size * sizeof(float));
}
// convert the data from float to u16 with clipping:
if (!first_mix)
{
// 2x MULPS
// 2x MAXPS (optional)
// 2x MINPS (optional)
// 2x CVTPS2DQ (converts float to s32)
// PACKSSDW (converts s32 to s16 with clipping)
if (g_is_u16)
{
for (u32 i = 0; i < (sizeof(buf2ch) / sizeof(float)); i += 8)
{
static const __m128 float2u16 = { 0x8000, 0x8000, 0x8000, 0x8000 };
(__m128i&)(oal_buffer[oal_pos][oal_buffer_offset + i]) = _mm_packs_epi32(
_mm_cvtps_epi32(_mm_mul_ps((__m128&)(buf2ch[i]), float2u16)),
_mm_cvtps_epi32(_mm_mul_ps((__m128&)(buf2ch[i + 4]), float2u16)));
}
}
for (u32 i = 0; i < (sizeof(buf2ch) / sizeof(float)); i++)
{
oal_buffer_float[oal_pos_float][oal_buffer_offset + i] = buf2ch[i];
}
}
//const u64 stamp1 = get_system_time();
if (first_mix)
{
memset(&oal_buffer[oal_pos][0], 0, oal_buffer_size * sizeof(s16));
memset(&oal_buffer_float[oal_pos_float][0], 0, oal_buffer_size * sizeof(float));
}
oal_buffer_offset += sizeof(buf2ch) / sizeof(float);
if(oal_buffer_offset >= oal_buffer_size)
{
if(m_audio_out)
{
if (g_is_u16)
queue.Push(&oal_buffer[oal_pos][0]);
queue_float.Push(&oal_buffer_float[oal_pos_float][0]);
}
oal_buffer_offset = 0;
}
//const u64 stamp2 = get_system_time();
// send aftermix event (normal audio event)
{
std::lock_guard<std::mutex> lock(audioMutex);
// update indexes:
auto indexes = vm::ptr<be_t<u64>>::make(m_config.m_indexes);
for (u32 i = 0; i < m_config.AUDIO_PORT_COUNT; i++)
{
if (!m_config.m_ports[i].m_is_audio_port_started) continue;
AudioPortConfig& port = m_config.m_ports[i];
u32 position = port.tag % port.block; // old value
port.counter = m_config.counter;
port.tag++; // absolute index of block that will be read
indexes[i] = (position + 1) % port.block; // write new value
}
// load keys:
keys.resize(m_config.m_keys.size());
memcpy(keys.data(), m_config.m_keys.data(), sizeof(u64) * keys.size());
}
for (u32 i = 0; i < keys.size(); i++)
{
// TODO: check event source
Emu.GetEventManager().SendEvent(keys[i], 0x10103000e010e07, 0, 0, 0);
}
//const u64 stamp3 = get_system_time();
if (do_dump && !first_mix)
{
if (m_dump.GetCh() == 8)
{
if (m_dump.WriteData(&buf8ch, sizeof(buf8ch)) != sizeof(buf8ch)) // write file data
{
cellAudio->Error("cellAudioInit(): AudioDumper::WriteData() failed");
goto abort;
}
}
else if (m_dump.GetCh() == 2)
{
if (m_dump.WriteData(&buf2ch, sizeof(buf2ch)) != sizeof(buf2ch)) // write file data
{
cellAudio->Error("cellAudioInit(): AudioDumper::WriteData() failed");
goto abort;
}
}
else
{
cellAudio->Error("cellAudioInit(): unknown AudioDumper::GetCh() value (%d)", m_dump.GetCh());
goto abort;
}
}
//LOG_NOTICE(HLE, "Audio perf: start=%d (access=%d, AddData=%d, events=%d, dump=%d)",
//stamp0 - m_config.start_time, stamp1 - stamp0, stamp2 - stamp1, stamp3 - stamp2, get_system_time() - stamp3);
}
cellAudio->Notice("Audio thread ended");
abort:
queue.Push(nullptr);
queue_float.Push(nullptr);
if(do_dump)
m_dump.Finalize();
m_config.m_is_audio_initialized = false;
m_config.m_keys.clear();
for (u32 i = 0; i < m_config.AUDIO_PORT_COUNT; i++)
{
AudioPortConfig& port = m_config.m_ports[i];
port.m_is_audio_port_opened = false;
port.m_is_audio_port_started = false;
}
m_config.m_port_in_use = 0;
while (!internal_finished)
{
std::this_thread::sleep_for(std::chrono::milliseconds(1));
}
m_config.m_is_audio_finalized = true;
});
t.detach();
while (!m_config.start_time) // waiting for initialization
{
if (Emu.IsStopped())
{
cellAudio->Warning("cellAudioInit() aborted");
return CELL_OK;
}
std::this_thread::sleep_for(std::chrono::milliseconds(1));
}
return CELL_OK;
}
int cellAudioQuit()
{
cellAudio->Warning("cellAudioQuit()");
if (!m_config.m_is_audio_initialized)
{
return CELL_AUDIO_ERROR_NOT_INIT;
}
m_config.m_is_audio_initialized = false;
while (!m_config.m_is_audio_finalized)
{
std::this_thread::sleep_for(std::chrono::milliseconds(1));
if (Emu.IsStopped())
{
cellAudio->Warning("cellAudioQuit(): aborted");
return CELL_OK;
}
}
Memory.Free(m_config.m_buffer);
Memory.Free(m_config.m_indexes);
return CELL_OK;
}
int cellAudioPortOpen(vm::ptr<CellAudioPortParam> audioParam, vm::ptr<be_t<u32>> portNum)
{
cellAudio->Warning("cellAudioPortOpen(audioParam_addr=0x%x, portNum_addr=0x%x)", audioParam.addr(), portNum.addr());
if (audioParam->nChannel > 8 || audioParam->nBlock > 16)
{
return CELL_AUDIO_ERROR_PARAM;
}
if (m_config.m_port_in_use >= m_config.AUDIO_PORT_COUNT)
{
return CELL_AUDIO_ERROR_PORT_FULL;
}
for (u32 i = 0; i < m_config.AUDIO_PORT_COUNT; i++)
{
if (!m_config.m_ports[i].m_is_audio_port_opened)
{
AudioPortConfig& port = m_config.m_ports[i];
port.channel = (u8)audioParam->nChannel;
port.block = (u8)audioParam->nBlock;
port.attr = audioParam->attr;
if (port.attr & CELL_AUDIO_PORTATTR_INITLEVEL)
{
port.level = audioParam->level;
}
else
{
port.level = 1.0f;
}
*portNum = i;
cellAudio->Warning("*** audio port opened(nChannel=%d, nBlock=%d, attr=0x%llx, level=%f): port = %d",
port.channel, port.block, port.attr, port.level, i);
port.m_is_audio_port_opened = true;
port.m_is_audio_port_started = false;
port.tag = 0;
m_config.m_port_in_use++;
return CELL_OK;
}
}
return CELL_AUDIO_ERROR_PORT_FULL;
}
int cellAudioGetPortConfig(u32 portNum, vm::ptr<CellAudioPortConfig> portConfig)
{
cellAudio->Warning("cellAudioGetPortConfig(portNum=0x%x, portConfig_addr=0x%x)", portNum, portConfig.addr());
if (portNum >= m_config.AUDIO_PORT_COUNT)
{
return CELL_AUDIO_ERROR_PARAM;
}
if (!m_config.m_ports[portNum].m_is_audio_port_opened)
{
portConfig->status = CELL_AUDIO_STATUS_CLOSE;
}
else if (m_config.m_ports[portNum].m_is_audio_port_started)
{
portConfig->status = CELL_AUDIO_STATUS_RUN;
}
else
{
portConfig->status = CELL_AUDIO_STATUS_READY;
}
AudioPortConfig& port = m_config.m_ports[portNum];
portConfig->nChannel = port.channel;
portConfig->nBlock = port.block;
portConfig->portSize = port.channel * port.block * 256 * sizeof(float);
portConfig->portAddr = m_config.m_buffer + (128 * 1024 * portNum); // 0x20020000
portConfig->readIndexAddr = m_config.m_indexes + (sizeof(u64) * portNum); // 0x20010010 on ps3
cellAudio->Log("*** port config: nChannel=%d, nBlock=%d, portSize=0x%x, portAddr=0x%x, readIndexAddr=0x%x",
(u32)portConfig->nChannel, (u32)portConfig->nBlock, (u32)portConfig->portSize, (u32)portConfig->portAddr, (u32)portConfig->readIndexAddr);
// portAddr - readIndexAddr == 0xFFF0 on ps3
return CELL_OK;
}
int cellAudioPortStart(u32 portNum)
{
cellAudio->Warning("cellAudioPortStart(portNum=0x%x)", portNum);
if (portNum >= m_config.AUDIO_PORT_COUNT)
{
return CELL_AUDIO_ERROR_PARAM;
}
if (!m_config.m_ports[portNum].m_is_audio_port_opened)
{
return CELL_AUDIO_ERROR_PORT_OPEN;
}
if (m_config.m_ports[portNum].m_is_audio_port_started)
{
return CELL_AUDIO_ERROR_PORT_ALREADY_RUN;
}
m_config.m_ports[portNum].m_is_audio_port_started = true;
return CELL_OK;
}
int cellAudioPortClose(u32 portNum)
{
cellAudio->Warning("cellAudioPortClose(portNum=0x%x)", portNum);
if (portNum >= m_config.AUDIO_PORT_COUNT)
{
return CELL_AUDIO_ERROR_PARAM;
}
if (!m_config.m_ports[portNum].m_is_audio_port_opened)
{
return CELL_AUDIO_ERROR_PORT_NOT_OPEN;
}
m_config.m_ports[portNum].m_is_audio_port_started = false;
m_config.m_ports[portNum].m_is_audio_port_opened = false;
m_config.m_port_in_use--;
return CELL_OK;
}
int cellAudioPortStop(u32 portNum)
{
cellAudio->Warning("cellAudioPortStop(portNum=0x%x)",portNum);
if (portNum >= m_config.AUDIO_PORT_COUNT)
{
return CELL_AUDIO_ERROR_PARAM;
}
if (!m_config.m_ports[portNum].m_is_audio_port_opened)
{
return CELL_AUDIO_ERROR_PORT_NOT_OPEN;
}
if (!m_config.m_ports[portNum].m_is_audio_port_started)
{
return CELL_AUDIO_ERROR_PORT_NOT_RUN;
}
m_config.m_ports[portNum].m_is_audio_port_started = false;
return CELL_OK;
}
int cellAudioGetPortTimestamp(u32 portNum, u64 tag, vm::ptr<be_t<u64>> stamp)
{
cellAudio->Log("cellAudioGetPortTimestamp(portNum=0x%x, tag=0x%llx, stamp_addr=0x%x)", portNum, tag, stamp.addr());
if (portNum >= m_config.AUDIO_PORT_COUNT)
{
return CELL_AUDIO_ERROR_PARAM;
}
if (!m_config.m_ports[portNum].m_is_audio_port_opened)
{
return CELL_AUDIO_ERROR_PORT_NOT_OPEN;
}
if (!m_config.m_ports[portNum].m_is_audio_port_started)
{
return CELL_AUDIO_ERROR_PORT_NOT_RUN;
}
AudioPortConfig& port = m_config.m_ports[portNum];
std::lock_guard<std::mutex> lock(audioMutex);
*stamp = m_config.start_time + (port.counter + (tag - port.tag)) * 256000000 / 48000;
return CELL_OK;
}
int cellAudioGetPortBlockTag(u32 portNum, u64 blockNo, vm::ptr<be_t<u64>> tag)
{
cellAudio->Log("cellAudioGetPortBlockTag(portNum=0x%x, blockNo=0x%llx, tag_addr=0x%x)", portNum, blockNo, tag.addr());
if (portNum >= m_config.AUDIO_PORT_COUNT)
{
return CELL_AUDIO_ERROR_PARAM;
}
if (!m_config.m_ports[portNum].m_is_audio_port_opened)
{
return CELL_AUDIO_ERROR_PORT_NOT_OPEN;
}
if (!m_config.m_ports[portNum].m_is_audio_port_started)
{
return CELL_AUDIO_ERROR_PORT_NOT_RUN;
}
AudioPortConfig& port = m_config.m_ports[portNum];
if (blockNo >= port.block)
{
cellAudio->Error("cellAudioGetPortBlockTag: wrong blockNo(%lld)", blockNo);
return CELL_AUDIO_ERROR_PARAM;
}
std::lock_guard<std::mutex> lock(audioMutex);
u64 tag_base = port.tag;
if (tag_base % port.block > blockNo)
{
tag_base &= ~(port.block-1);
tag_base += port.block;
}
else
{
tag_base &= ~(port.block-1);
}
*tag = tag_base + blockNo;
return CELL_OK;
}
int cellAudioSetPortLevel(u32 portNum, float level)
{
cellAudio->Todo("cellAudioSetPortLevel(portNum=0x%x, level=%f)", portNum, level);
return CELL_OK;
}
// Utility Functions
int cellAudioCreateNotifyEventQueue(vm::ptr<be_t<u32>> id, vm::ptr<be_t<u64>> key)
{
cellAudio->Warning("cellAudioCreateNotifyEventQueue(id_addr=0x%x, key_addr=0x%x)", id.addr(), key.addr());
std::lock_guard<std::mutex> lock(audioMutex);
u64 event_key = 0;
while (Emu.GetEventManager().CheckKey((event_key << 48) | 0x80004d494f323221))
{
event_key++; // experimental
//return CELL_AUDIO_ERROR_EVENT_QUEUE;
}
event_key = (event_key << 48) | 0x80004d494f323221; // left part: 0x8000, 0x8001, 0x8002 ...
EventQueue* eq = new EventQueue(SYS_SYNC_FIFO, SYS_PPU_QUEUE, event_key, event_key, 32);
if (!Emu.GetEventManager().RegisterKey(eq, event_key))
{
delete eq;
return CELL_AUDIO_ERROR_EVENT_QUEUE;
}
*id = cellAudio->GetNewId(eq);
*key = event_key;
return CELL_OK;
}
int cellAudioCreateNotifyEventQueueEx(vm::ptr<be_t<u32>> id, vm::ptr<be_t<u64>> key, u32 iFlags)
{
cellAudio->Todo("cellAudioCreateNotifyEventQueueEx(id_addr=0x%x, key_addr=0x%x, iFlags=0x%x)", id.addr(), key.addr(), iFlags);
return CELL_OK;
}
int cellAudioSetNotifyEventQueue(u64 key)
{
cellAudio->Warning("cellAudioSetNotifyEventQueue(key=0x%llx)", key);
std::lock_guard<std::mutex> lock(audioMutex);
for (u32 i = 0; i < m_config.m_keys.size(); i++) // check for duplicates
{
if (m_config.m_keys[i] == key)
{
return CELL_AUDIO_ERROR_PARAM;
}
}
m_config.m_keys.push_back(key);
/*EventQueue* eq;
if (!Emu.GetEventManager().GetEventQueue(key, eq))
{
return CELL_AUDIO_ERROR_PARAM;
}*/
// TODO: connect port (?????)
return CELL_OK;
}
int cellAudioSetNotifyEventQueueEx(u64 key, u32 iFlags)
{
cellAudio->Todo("cellAudioSetNotifyEventQueueEx(key=0x%llx, iFlags=0x%x)", key, iFlags);
return CELL_OK;
}
int cellAudioRemoveNotifyEventQueue(u64 key)
{
cellAudio->Warning("cellAudioRemoveNotifyEventQueue(key=0x%llx)", key);
std::lock_guard<std::mutex> lock(audioMutex);
bool found = false;
for (u32 i = 0; i < m_config.m_keys.size(); i++)
{
if (m_config.m_keys[i] == key)
{
m_config.m_keys.erase(m_config.m_keys.begin() + i);
found = true;
break;
}
}
if (!found)
{
// ???
return CELL_AUDIO_ERROR_PARAM;
}
/*EventQueue* eq;
if (!Emu.GetEventManager().GetEventQueue(key, eq))
{
return CELL_AUDIO_ERROR_PARAM;
}*/
// TODO: disconnect port
return CELL_OK;
}
int cellAudioRemoveNotifyEventQueueEx(u64 key, u32 iFlags)
{
cellAudio->Todo("cellAudioRemoveNotifyEventQueueEx(key=0x%llx, iFlags=0x%x)", key, iFlags);
return CELL_OK;
}
int cellAudioAddData(u32 portNum, vm::ptr<be_t<float>> src, u32 samples, float volume)
{
cellAudio->Todo("cellAudioAddData(portNum=0x%x, src_addr=0x%x, samples=%d, volume=%f)", portNum, src.addr(), samples, volume);
return CELL_OK;
}
int cellAudioAdd2chData(u32 portNum, vm::ptr<be_t<float>> src, u32 samples, float volume)
{
cellAudio->Todo("cellAudioAdd2chData(portNum=0x%x, src_addr=0x%x, samples=%d, volume=%f)", portNum, src.addr(), samples, volume);
return CELL_OK;
}
int cellAudioAdd6chData(u32 portNum, vm::ptr<be_t<float>> src, float volume)
{
cellAudio->Todo("cellAudioAdd6chData(portNum=0x%x, src_addr=0x%x, volume=%f)", portNum, src.addr(), volume);
return CELL_OK;
}
int cellAudioMiscSetAccessoryVolume(u32 devNum, float volume)
{
cellAudio->Todo("cellAudioMiscSetAccessoryVolume(devNum=0x%x, volume=%f)", devNum, volume);
return CELL_OK;
}
int cellAudioSendAck(u64 data3)
{
cellAudio->Todo("cellAudioSendAck(data3=0x%llx)", data3);
return CELL_OK;
}
int cellAudioSetPersonalDevice(int iPersonalStream, int iDevice)
{
cellAudio->Todo("cellAudioSetPersonalDevice(iPersonalStream=0x%x, iDevice=0x%x)", iPersonalStream, iDevice);
return CELL_OK;
}
int cellAudioUnsetPersonalDevice(int iPersonalStream)
{
cellAudio->Todo("cellAudioUnsetPersonalDevice(iPersonalStream=0x%x)", iPersonalStream);
return CELL_OK;
}
void cellAudio_init()
{
cellAudio->AddFunc(0x0b168f92, cellAudioInit);
cellAudio->AddFunc(0x4129fe2d, cellAudioPortClose);
cellAudio->AddFunc(0x5b1e2c73, cellAudioPortStop);
cellAudio->AddFunc(0x74a66af0, cellAudioGetPortConfig);
cellAudio->AddFunc(0x89be28f2, cellAudioPortStart);
cellAudio->AddFunc(0xca5ac370, cellAudioQuit);
cellAudio->AddFunc(0xcd7bc431, cellAudioPortOpen);
cellAudio->AddFunc(0x56dfe179, cellAudioSetPortLevel);
cellAudio->AddFunc(0x04af134e, cellAudioCreateNotifyEventQueue);
cellAudio->AddFunc(0x31211f6b, cellAudioMiscSetAccessoryVolume);
cellAudio->AddFunc(0x377e0cd9, cellAudioSetNotifyEventQueue);
cellAudio->AddFunc(0x4109d08c, cellAudioGetPortTimestamp);
cellAudio->AddFunc(0x9e4b1db8, cellAudioAdd2chData);
cellAudio->AddFunc(0xdab029aa, cellAudioAddData);
cellAudio->AddFunc(0xe4046afe, cellAudioGetPortBlockTag);
cellAudio->AddFunc(0xff3626fd, cellAudioRemoveNotifyEventQueue);
}