Merge pull request #160 from SysRay/work

Work
2024-11-23 14:29:39 +00:00 · 2024-05-18 16:21:27 +02:00 · 2024-05-18 16:21:27 +02:00 · 0a3c8a49dd
commit 0a3c8a49dd
parent bea5f0621d 35b87ae625
22 changed files with 1601 additions and 470 deletions
--- a/asm/entry.asm
+++ b/asm/entry.asm
@ -15,7 +15,9 @@ jmpEntry PROC
  AND RSP, -10h
  ; copy entry param to stack
-  ADD RSP, 24
+  ADD RSP, 40
  push [RSI+24]
  push [RSI+16]
  push [RSI+8]
  push [RSI]
  ; -
--- a/core/dmem/types/directmem.cpp
+++ b/core/dmem/types/directmem.cpp
@ -255,7 +255,7 @@ int DirectMemory::free(off_t start, size_t len) {
    return Ok;
  }
-  if (itHeap->first != addr || itHeap->second.size != len) {
+  if (len != 0 && (itHeap->first != addr || itHeap->second.size != len)) {
    LOG_ERR(L"free Error| start:0x%08llx len:0x%08llx != start:0x%08llx len:0x%08llx", addr, len, itHeap->first, itHeap->second.size);
  }
@ -313,8 +313,9 @@ int DirectMemory::map(uint64_t vaddr, off_t offset, size_t len, int prot, int fl
  MemoryInfo* info = nullptr;
  if (flags & (int)filesystem::SceMapMode::FIXED) {
    for (auto& item: m_objects) {
-      if (item.second.state == MemoryState::Reserved && item.first <= vaddr && (item.first + item.second.size) > (vaddr + len)) {
+      if (item.second.state == MemoryState::Reserved && item.first <= vaddr && item.second.size >= len) {
-        info = &item.second;
+        info     = &item.second;
        desVaddr = info->addr;
      }
    }
  }
@ -324,7 +325,7 @@ int DirectMemory::map(uint64_t vaddr, off_t offset, size_t len, int prot, int fl
  // -
  // Check if Commit needed
-  if (info->state == MemoryState::Free) {
+  if (info->state == MemoryState::Free || info->state == MemoryState::Reserved) {
    MEM_ADDRESS_REQUIREMENTS addressReqs    = {0};
    MEM_EXTENDED_PARAMETER   extendedParams = {0};
@ -335,8 +336,11 @@ int DirectMemory::map(uint64_t vaddr, off_t offset, size_t len, int prot, int fl
    extendedParams.Type    = MemExtendedParameterAddressRequirements;
    extendedParams.Pointer = &addressReqs;
-    void* ptr = VirtualAlloc2(NULL, (void*)desVaddr, info->size, MEM_RESERVE | MEM_COMMIT | MEM_WRITE_WATCH, convProtection(prot),
+    uint32_t flags = MEM_COMMIT;
-                              desVaddr != 0 ? 0 : &extendedParams, desVaddr != 0 ? 0 : 1);
+    if (info->state != MemoryState::Reserved) {
      flags |= MEM_RESERVE | MEM_WRITE_WATCH;
    }
    void* ptr = VirtualAlloc2(NULL, (void*)desVaddr, info->size, flags, convProtection(prot), desVaddr != 0 ? 0 : &extendedParams, desVaddr != 0 ? 0 : 1);
    if (ptr == 0) {
      auto const err = GetLastError();
      LOG_ERR(L"Commit Error| addr:0x%08llx len:0x%08llx err:%d", info->addr, info->size, GetLastError());
@ -432,10 +436,32 @@ uint64_t DirectMemory::size() const {
 int DirectMemory::getAvailableSize(uint32_t start, uint32_t end, size_t alignment, uint32_t* startOut, size_t* sizeOut) const {
  LOG_USE_MODULE(DirectMemory);
-  LOG_DEBUG(L"availableSize: start:0x%08llx end:0x%08llx alignment:0x%08llx", start, end, alignment);
+  LOG_DEBUG(L"availableSize: start:0x%lx end:0x%lx alignment:0x%08llx", start, end, alignment);
-  *startOut = m_usedSize;
+  auto itItem = m_objects.lower_bound(DIRECTMEM_START + start);
-  *sizeOut  = SCE_KERNEL_MAIN_DMEM_SIZE - m_usedSize;
+  if (m_objects.empty() || itItem == m_objects.end()) {
    *startOut = start;
    *sizeOut  = std::min(SCE_KERNEL_MAIN_DMEM_SIZE, (uint64_t)end - start);
    return Ok;
  }
  *startOut = start;
  *sizeOut  = (itItem->second.addr - DIRECTMEM_START) - start;
  // if (itItem->second.addr + itItem->second.size >= DIRECTMEM_START + end) {
  //   *startOut = end;
  //   *sizeOut  = 0;
  //   return Ok;
  // }
  // *startOut = start;
  // *sizeOut  = 0;
  // auto itEnd = m_objects.lower_bound(DIRECTMEM_START + end);
  // for (; itItem != itEnd; ++itItem) {
  //   *startOut = (itItem->second.addr + itItem->second.size) - DIRECTMEM_START;
  // }
  // if (*startOut > end) *sizeOut = end - *startOut;
  return Ok;
 }
--- a/core/fileManager/fileManager.cpp
+++ b/core/fileManager/fileManager.cpp
@ -220,6 +220,8 @@ class FileManager: public IFileManager {
    if ((*dir->m_file) == endDir) return 0;
 #pragma pack(push, 1)
    struct DataStruct {
      uint32_t fileno;
      uint16_t reclen;
@ -228,6 +230,8 @@ class FileManager: public IFileManager {
      char     name[256];
    };
 #pragma pack(pop, 1)
    auto count = dir->count;
    int  n     = 0;
@ -237,7 +241,7 @@ class FileManager: public IFileManager {
      auto const filename = (*dir->m_file)->path().filename().string();
      if (sizeof(DataStruct) + std::min(filename.size(), 255llu) >= nbytes) break;
-      item->fileno             = 0;
+      item->fileno             = count;
      item->type               = ((*dir->m_file)->is_regular_file() ? 8 : 4);
      item->namlen             = filename.copy(item->name, 255);
      item->name[item->namlen] = '\0';
@ -245,7 +249,7 @@ class FileManager: public IFileManager {
      n += sizeof(DataStruct);
      item->reclen = sizeof(DataStruct);
-      LOG_DEBUG(L"KernelGetdirentries[%d]: %S %u offset:%u count:%u", handle, item->name, item->type, item->reclen, count);
+      LOG_DEBUG(L"KernelGetdirentries[%d]: %S %u offset:%u count:%u", handle, item->name, item->type, n, count);
      std::error_code err;
      (*dir->m_file).increment(err);
--- a/core/kernel/pthread.cpp
+++ b/core/kernel/pthread.cpp
@ -400,11 +400,13 @@ int join(ScePthread_obj obj, void** value) {
  auto thread = getPthread(obj);
  thread->p.join();
-  LOG_USE_MODULE(pthread);
+  if (!thread->detached) {
-  LOG_DEBUG(L"Delete thread:%d", thread->unique_id);
+    LOG_USE_MODULE(pthread);
-  // Cleanup thread
+    LOG_DEBUG(L"Delete thread:%d", thread->unique_id);
-  thread->~PthreadPrivate();
+    // Cleanup thread
-  delete[] obj;
+    thread->~PthreadPrivate();
    delete[] obj;
  }
  // -
  return Ok;
 }
@ -802,10 +804,7 @@ int cancel(ScePthread_obj obj) {
  auto thread = getPthread(obj);
  // todo cancel
  // int  result = ::pthread_cancel(thread->p);
-
+  thread->p.interrupt();
  LOG_USE_MODULE(pthread);
  LOG_ERR(L" todo cancel| %S id:%d", thread->name.data(), thread->unique_id);
  // LOG_TRACE(L"thread cancel| threadId:%d name:%S result:%d", thread->unique_id, thread->name.c_str(), result);
  return Ok;
 }
@ -1219,6 +1218,7 @@ void cleanup_thread() {
    func(arg);
    thread->cleanupFuncs.pop_back();
  }
  accessRuntimeLinker().destroyTLSKeys(getSelf());
  auto thread_dtors = *getThreadDtors();
@ -1226,8 +1226,6 @@ void cleanup_thread() {
    thread_dtors();
  }
  accessRuntimeLinker().destroyTLSKeys(getSelf());
  accessMemoryManager()->unregisterStack((uint64_t)thread->attr.getStackAddr());
  // Delete here if detached, else in join()
--- a/core/runtime/runtimeLinker.cpp
+++ b/core/runtime/runtimeLinker.cpp
@ -691,13 +691,13 @@ void RuntimeLinker::destroyTLSKeys(uint8_t* obj) {
  std::unique_lock const lock(m_mutex_int);
  m_threadList.erase(pthread::getThreadId(obj));
  for (uint64_t n = m_countcreatePrograms; n < m_dtvKeys.size(); ++n, ++pDtvKey) {
    if (m_dtvKeys[n].destructor != nullptr) {
-      m_dtvKeys[n].destructor((void*)pDtvKey[n]);
+      if (pDtvKey[n] != 0) m_dtvKeys[n].destructor((void*)pDtvKey[n]);
    }
  }
  m_threadList.erase(pthread::getThreadId(obj));
 }
 void RuntimeLinker::stopModules() {
--- a/modules/libSceAudioOut/entry.cpp
+++ b/modules/libSceAudioOut/entry.cpp
@ -19,8 +19,8 @@ struct PortOut {
  int                    userId         = 0;
  SceAudioOutPortType    type           = SceAudioOutPortType::MAIN;
  uint8_t                sampleSize     = 0;
  uint32_t               sampleRate     = 0;
  uint32_t               samplesNum     = 0;
  uint32_t               freq           = 0;
  uint32_t               queued         = 0;
  SceAudioOutParamFormat format         = SceAudioOutParamFormat::FLOAT_MONO;
  uint64_t               lastOutputTime = 0;
@ -31,6 +31,8 @@ struct PortOut {
  float                  volumeModifier = 0.5f;
  std::vector<uint8_t>   mixedAudio;
  std::string            deviceName;
  SDL_AudioSpec audioSpec;
 };
 class PortsOut {
@ -70,16 +72,7 @@ class PortsOut {
       */
      if (port.deviceName.compare(0, std::string::npos, devName, 0, port.deviceName.length()) != 0) continue;
-      SDL_AudioSpec fmt {
+      if ((port.device = SDL_OpenAudioDevice(devName, 0, &port.audioSpec, NULL, 0)) == 0) {
          .freq     = static_cast<int>(port.freq),
          .format   = port.sdlFormat,
          .channels = static_cast<uint8_t>(port.channelsNum),
          .samples  = static_cast<uint16_t>(port.samplesNum),
          .callback = nullptr,
          .userdata = nullptr,
      };
      if ((port.device = SDL_OpenAudioDevice(devName, 0, &fmt, NULL, 0)) == 0) {
        LOG_ERR(L"Failed to reopen %S audio device: %S", devName, SDL_GetError());
        return;
      }
@ -167,7 +160,7 @@ void syncPort(PortOut* port) {
  const uint32_t bytesize     = bytesize_1ch * port->channelsNum;
  if (port->device == 0) {
-    float duration = bytesize_1ch / float(port->freq * port->sampleSize);
+    float duration = bytesize_1ch / float(port->sampleRate * port->sampleSize);
    SDL_Delay(int(duration * 1000)); // Pretending that we playing something
    return;
  }
@ -200,12 +193,11 @@ int writeOut(PortOut* port, const void* ptr, bool sync = true) {
    return port->samplesNum;
  }
-  const uint32_t bytesize  = bytesize_1ch * port->channelsNum;
+  const int maxVolume = SDL_MIX_MAXVOLUME * port->volumeModifier;
-  const int      maxVolume = SDL_MIX_MAXVOLUME * port->volumeModifier;
+  auto&     mixed     = port->mixedAudio;
  auto&          mixed     = port->mixedAudio;
  std::fill(mixed.begin(), mixed.end(), 0);
-  for (int i = 0; i < port->channelsNum; i++) {
+  for (int i = 0; i < port->audioSpec.channels; i++) {
    auto ch_offset = i * bytesize_1ch;
    SDL_MixAudioFormat(mixed.data() + ch_offset, ((const uint8_t*)ptr) + ch_offset, port->sdlFormat, bytesize_1ch,
                       maxVolume * ((float)port->volume[i] / AudioOut::VOLUME_0DB));
@ -213,7 +205,7 @@ int writeOut(PortOut* port, const void* ptr, bool sync = true) {
  if (SDL_GetAudioDeviceStatus(port->device) != SDL_AUDIO_PLAYING) SDL_PauseAudioDevice(port->device, 0);
-  int ret = SDL_QueueAudio(port->device, mixed.data(), bytesize);
+  int ret = SDL_QueueAudio(port->device, mixed.data(), port->audioSpec.size);
  if (ret == 0) port->queued = SDL_GetQueuedAudioSize(port->device);
  if (sync) syncPort(port);
@ -237,7 +229,7 @@ EXPORT SYSV_ABI int32_t sceAudioOutInit(void) {
  return Err::AudioOut::OUT_OF_MEMORY;
 }
-EXPORT SYSV_ABI int32_t sceAudioOutOpen(int32_t userId, SceAudioOutPortType type, int32_t index, uint32_t len, uint32_t freq, uint32_t param) {
+EXPORT SYSV_ABI int32_t sceAudioOutOpen(int32_t userId, SceAudioOutPortType type, int32_t index, uint32_t numSamples, uint32_t sampleRate, uint32_t param) {
  if (!audioInited) return Err::AudioOut::NOT_INIT;
  LOG_USE_MODULE(libSceAudioOut);
  LOG_TRACE(L"%S", __FUNCTION__);
@ -260,8 +252,8 @@ EXPORT SYSV_ABI int32_t sceAudioOutOpen(int32_t userId, SceAudioOutPortType type
  int handle;
  if (auto port = pimpl->portsOut.AcquirePort(type, &handle)) {
    port->userId     = userId;
-    port->samplesNum = len;
+    port->samplesNum = numSamples;
-    port->freq       = freq;
+    port->sampleRate = sampleRate;
    port->format     = SceAudioOutParamFormat(param & 0x0000007F);
    if ((param & 0x000F0000) != 0) {
@ -322,6 +314,15 @@ EXPORT SYSV_ABI int32_t sceAudioOutOpen(int32_t userId, SceAudioOutPortType type
      port->volumeModifier = 0.5f;
    }
    SDL_AudioSpec audioSpec = {
        .freq     = static_cast<int>(sampleRate),
        .format   = port->sdlFormat,
        .channels = static_cast<uint8_t>(port->channelsNum),
        .samples  = static_cast<uint16_t>(port->samplesNum),
        .callback = nullptr,
        .userdata = nullptr,
    };
    if (type == SceAudioOutPortType::PADSPK) {
      auto& devn = (*jData)["padspeakers"][userId - 1];
@ -344,9 +345,8 @@ EXPORT SYSV_ABI int32_t sceAudioOutOpen(int32_t userId, SceAudioOutPortType type
        port->volume[i] = AudioOut::MIXLEVEL_PADSPK_0DB;
      }
    } else {
      SDL_AudioSpec fmt_curr;
      if ((*jData)["device"] == "[default]") {
-        if (SDL_GetDefaultAudioInfo((char**)&dname, &fmt_curr, 0) != 0) {
+        if (SDL_GetDefaultAudioInfo((char**)&dname, &port->audioSpec, 0) != 0) {
          LOG_ERR(L"Failed to get the default audio device, port #%d is nulled! (%S)", handle, SDL_GetError());
          port->device = 0;
          return handle;
@ -362,7 +362,7 @@ EXPORT SYSV_ABI int32_t sceAudioOutOpen(int32_t userId, SceAudioOutPortType type
        } catch (const json::exception& e) {
          LOG_ERR(L"Invalid audio device name: %S, falling back to default", e.what());
          dname = NULL;
-          if (SDL_GetDefaultAudioInfo((char**)&dname, &fmt_curr, 0) != 0) {
+          if (SDL_GetDefaultAudioInfo((char**)&dname, &port->audioSpec, 0) != 0) {
            LOG_ERR(L"Falling back to default device failed, port #%d is nulled! (%S)", handle, SDL_GetError());
            port->device = 0;
            return handle;
@ -375,16 +375,7 @@ EXPORT SYSV_ABI int32_t sceAudioOutOpen(int32_t userId, SceAudioOutPortType type
      }
    }
-    SDL_AudioSpec fmt {
+    if ((port->device = SDL_OpenAudioDevice(dname, 0, &audioSpec, &port->audioSpec, 0)) == 0) {
        .freq     = static_cast<int>(freq),
        .format   = port->sdlFormat,
        .channels = static_cast<uint8_t>(port->channelsNum),
        .samples  = static_cast<uint16_t>(port->samplesNum),
        .callback = nullptr,
        .userdata = nullptr,
    };
    if ((port->device = SDL_OpenAudioDevice(dname, 0, &fmt, NULL, 0)) == 0) {
      LOG_ERR(L"Failed to open %S audio device: %S", getDevName(type), SDL_GetError());
      // Since audio connect/disconnect event is implemented now, we can fall through there.
      // The audio device will be opened automatically when available.
@ -392,7 +383,7 @@ EXPORT SYSV_ABI int32_t sceAudioOutOpen(int32_t userId, SceAudioOutPortType type
      LOG_INFO(L"%S audio device %S opened for user #%d", getDevName(type), dname, userId);
    }
-    port->mixedAudio.resize(port->sampleSize * port->samplesNum * port->channelsNum);
+    port->mixedAudio.resize(port->audioSpec.size);
    port->deviceName.assign(dname);
    return handle;
  }
--- a/modules/libSceAvPlayer/avplayer.cpp
+++ b/modules/libSceAvPlayer/avplayer.cpp
@ -79,7 +79,8 @@ class Avplayer: public IAvplayer {
  std::array<int, 4>   m_videoStride;
  std::array<void*, 4> m_videoPlane;
-  int64_t m_startTime = 0;
+  int64_t  m_startTime       = 0;
  uint64_t m_latestTimestamp = 0;
  // Avplayer Data
  AVFormatContext* m_pFmtCtx = nullptr;
@ -172,6 +173,8 @@ class Avplayer: public IAvplayer {
    return m_isVideoActive || m_isAudioActive;
  }
  uint64_t getCurrentTime() const final { return m_latestTimestamp; }
  void stop() final {
    LOG_USE_MODULE(AvPlayer);
    LOG_DEBUG(L"stop");
@ -279,7 +282,9 @@ bool Avplayer::getVideoData(void* info, bool isEx) {
    if (retRecv < 0) {
      if (retRecv == AVERROR(EAGAIN)) {
        if (!m_isStop) {
          LOG_TRACE(L"-> wait video frame");
          m_video.m_cond.wait(lock);
          LOG_TRACE(L"<- wait video frame");
          continue;
        }
      } else if (retRecv != AVERROR_EOF) {
@ -310,10 +315,13 @@ bool Avplayer::getVideoData(void* info, bool isEx) {
  auto const timestamp = (int64_t)(1000.0 * av_q2d(m_video.stream->time_base) * m_video.frame->best_effort_timestamp); // timestamp[seconds] to [ms]
  auto const curTime = (av_gettime() - m_startTime) / 1000; // [us] to [ms]
  LOG_TRACE(L"video frame timestamp:%lld", curTime);
  if (timestamp > curTime) {
    return false;
  }
  m_latestTimestamp = timestamp;
  LOG_DEBUG(L"Received video frame, timestamp:%lld", m_video.frame->pts);
  m_video.getNewFrame = true;
@ -385,7 +393,9 @@ bool Avplayer::getAudioData(SceAvPlayerFrameInfo* info) {
    if (retRecv < 0) {
      if (retRecv == AVERROR(EAGAIN)) {
        if (!m_isStop) {
          LOG_TRACE(L"-> wait audio frame");
          m_audio.m_cond.wait(lock);
          LOG_TRACE(L"<- wait audio frame");
          continue;
        }
      } else if (retRecv != AVERROR_EOF) {
@ -410,6 +420,7 @@ bool Avplayer::getAudioData(SceAvPlayerFrameInfo* info) {
  }
  auto const timestamp = (int64_t)(1000.0 * av_q2d(m_audio.stream->time_base) * m_audio.frame->best_effort_timestamp); // timestamp[seconds] to [ms]
  m_latestTimestamp    = timestamp;
  //  Convert and copy
  int const outNumSamples = swr_get_out_samples(m_swrCtx, m_audio.frame->nb_samples);
@ -522,7 +533,7 @@ std::unique_ptr<std::thread> Avplayer::threadFunc() {
          LOG_DEBUG(L"Queue Video Packet: numItems:%llu pts:%lld", m_video.decodeQueue.size(), packet->pts);
        } else if (packet->stream_index == m_audio.streamIndex) {
          m_audio.decodeQueue.push(packet);
-          LOG_DEBUG(L"Queue Video Packet: numItems:%llu pts:%lld", m_video.decodeQueue.size(), packet->pts);
+          LOG_DEBUG(L"Queue Audio Packet: numItems:%llu pts:%lld", m_audio.decodeQueue.size(), packet->pts);
        } else
          continue;
      }
--- a/modules/libSceAvPlayer/avplayer.h
+++ b/modules/libSceAvPlayer/avplayer.h
@ -20,6 +20,13 @@ class IAvplayer {
  virtual bool isPlaying() = 0;
  virtual void stop()      = 0;
  /**
   * @brief Get the latest timestamp
   *
   * @return uint64_t [ms]
   */
  virtual uint64_t getCurrentTime() const = 0;
  virtual ~IAvplayer() = default;
 };
--- a/modules/libSceAvPlayer/entry.cpp
+++ b/modules/libSceAvPlayer/entry.cpp
@ -30,39 +30,57 @@ EXPORT SYSV_ABI int32_t sceAvPlayerAddSource(IAvplayer* avPlayer, const char* fi
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerStreamCount(IAvplayer* avPlayer) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerGetStreamInfo(IAvplayer* avPlayer, uint32_t argStreamID, SceAvPlayerStreamInfo* argInfo) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerEnableStream(IAvplayer* avPlayer, uint32_t argStreamID) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerDisableStream(IAvplayer* avPlayer, uint32_t argStreamID) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerChangeStream(IAvplayer* avPlayer, uint32_t argOldStreamID, uint32_t argNewStreamID) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerStart(IAvplayer* avPlayer) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerStop(IAvplayer* avPlayer) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  avPlayer->stop();
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerPause(IAvplayer* avPlayer) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerResume(IAvplayer* avPlayer) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
@ -85,18 +103,24 @@ EXPORT SYSV_ABI bool sceAvPlayerGetVideoData(IAvplayer* avPlayer, SceAvPlayerFra
 }
 EXPORT SYSV_ABI uint64_t sceAvPlayerCurrentTime(IAvplayer* avPlayer) {
-  return Ok;
+  return avPlayer->getCurrentTime();
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerJumpToTime(IAvplayer* avPlayer, uint64_t argJumpTimeMsec) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerSetTrickSpeed(IAvplayer* avPlayer, int32_t argTrickSpeed) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceAvPlayerSetAvSyncMode(IAvplayer* avPlayer, SceAvPlayerAvSyncMode argSyncMode) {
  LOG_USE_MODULE(libSceAvPlayer);
  LOG_ERR(L"todo %S", __FUNCTION__);
  return Ok;
 }
--- a/modules/libSceNgs2/CMakeLists.txt
+++ b/modules/libSceNgs2/CMakeLists.txt
@ -1,10 +1,14 @@
 cmake_minimum_required(VERSION 3.24)
 include(../setupModule.cmake)
 add_compile_definitions(
  BOOST_ALL_NO_LIB
 )
 set(libName libSceNgs2)
 project(${libName})
-add_library(${libName} SHARED entry.cpp)
+add_library(${libName} SHARED entry.cpp readFuncs.cpp reader.cpp)
 set(FFMPEG_LIBS
  avformat
@ -15,6 +19,6 @@ set(FFMPEG_LIBS
 )
 add_dependencies(${libName} core)
-target_link_libraries(${libName} PRIVATE core.lib ${FFMPEG_LIBS})
+target_link_libraries(${libName} PRIVATE core.lib ${FFMPEG_LIBS} libboost_thread libboost_chrono)
 setupModule(${libName})
--- a/modules/libSceNgs2/codes.h
+++ b/modules/libSceNgs2/codes.h
@ -7,6 +7,7 @@ constexpr int32_t INVALID_WAVEFORM_DATA     = -2142632952;
 constexpr int32_t INVALID_BUFFER_ADDRESS    = -2142633465;
 constexpr int32_t INVALID_BUFFER_SIZE       = -2142633466;
 constexpr int32_t INVALID_SYSTEM_HANDLE     = -2142633424;
 constexpr int32_t INVALID_VOICE_HANDLE      = -2142633216;
 constexpr int32_t INVALID_RACK_HANDLE       = -2142633375;
 constexpr int32_t INVALID_VOICE_INDEX       = -2142633214;
 constexpr int32_t INVALID_BUFFER_ALLOCATOR  = -2142633462;
@ -25,4 +26,14 @@ constexpr int32_t SCE_NGS2_MAX_MATRIX_LEVELS  = 64;
 constexpr int32_t SCE_NGS2_RACK_NAME_LENGTH   = 16;
 constexpr int32_t SCE_NGS2_SYSTEM_NAME_LENGTH = 16;
-constexpr int32_t SCE_NGS2_SAMPLER_VOICE_ADD_WAVEFORM_BLOCKS = 0x10000001;
+constexpr uint16_t SCE_NGS2_RACK_ID_VOICE     = 0x0000;
 constexpr uint16_t SCE_NGS2_RACK_ID_SAMPLER   = 0x1000;
 constexpr uint16_t SCE_NGS2_RACK_ID_SUBMIXER  = 0x2000;
 constexpr uint16_t SCE_NGS2_RACK_ID_MASTERING = 0x3000;
 constexpr uint16_t SCE_NGS2_RACK_ID_REVERB = 0x2001;
 constexpr uint16_t SCE_NGS2_RACK_ID_EQ     = 0x2002;
 constexpr uint16_t SCE_NGS2_RACK_ID_CUSTOM_SAMPLER   = 0x4001;
 constexpr uint16_t SCE_NGS2_RACK_ID_CUSTOM_SUBMIXER  = 0x4002;
 constexpr uint16_t SCE_NGS2_RACK_ID_CUSTOM_MASTERING = 0x4003;
--- a/modules/libSceNgs2/entry.cpp
+++ b/modules/libSceNgs2/entry.cpp
@ -1,178 +1,358 @@
-#include "codes.h"
+#include "core/fileManager/ifile.h"
 #include "common.h"
 extern "C" {
 #include "libavformat/avformat.h"
 }
 #include "core/kernel/filesystem.h"
 #include "core/kernel/pthread.h"
 #include "logging.h"
 #include "readFuncs.h"
 #include "reader.h"
 #include "types.h"
 #include <boost/thread.hpp>
 #include <set>
 LOG_DEFINE_MODULE(libSceNgs2);
 namespace {
-enum WaveformInfoType {
+static boost::mutex MUTEX_INT;
-  WAVEFORM_FILE,
+
-  WAVEFORM_DATA,
+struct Impl {
-  WAVEFORM_USER,
+  std::set<SceNgs2Handle*> handles;
 };
-struct WaveformInfo {
+Impl* getPimpl() {
-  WaveformInfoType type;
+  static Impl pimpl;
-  char             pad[4];
+  return &pimpl;
 }
-  union WaveformPtr {
+int32_t _voiceControlWaveformBlock(SceNgs2Handle* voh, const SceNgs2SamplerVoiceWaveformBlocksParam* svwfbp) {
    int                  fileHandle;
    SceWaveformUserFunc* userFunc;
    const void*          dataPtr;
  } ud;
  size_t size;
  long   offset;
 };
 static SceNgs2ChannelsCount ParseChanCount(int num) {
  LOG_USE_MODULE(libSceNgs2);
-  switch (num) {
+  LOG_TRACE(L"waveblock: %d\n", svwfbp->numBlocks);
-    case 1: return SceNgs2ChannelsCount::CH_1_0;
+  LOG_TRACE(L"waveptr: %llx\n", svwfbp->data);
-    case 2: return SceNgs2ChannelsCount::CH_2_0;
+  if (voh->type != SceNgs2HandleType::Voice) return Err::Ngs2::INVALID_VOICE_HANDLE;
  auto voice = (SceNgs2Handle_voice*)voh;
-    case 6: return SceNgs2ChannelsCount::CH_5_1;
+  if (voice->reader == nullptr) voice->reader = std::make_unique<Reader>(voice).release();
-    case 8: return SceNgs2ChannelsCount::CH_7_1;
+  // svwfbp->data can be nullptr!
  if (!voice->reader->init(svwfbp)) {
    return Err::Ngs2::INVALID_WAVEFORM_DATA;
  }
-  LOG_CRIT(L"Invalid channels count sent to ParseChanCount!");
+  LOG_DEBUG(L"waveptr voice:0x%08llx %llx", (uint64_t)voh, svwfbp->data);
-  return SceNgs2ChannelsCount::INVALID;
+  return Ok;
 }
-static SceNgs2WaveFormType ParseWaveType(AVCodecID codec) {
+int32_t voiceControl_voice(SceNgs2Handle* voh, const SceNgs2VoiceParamHead* phead) {
  switch (codec) {
    case AVCodecID::AV_CODEC_ID_PCM_S8: return SceNgs2WaveFormType::PCM_I8;
    case AVCodecID::AV_CODEC_ID_PCM_U8: return SceNgs2WaveFormType::PCM_U8;
    case AVCodecID::AV_CODEC_ID_ATRAC9: return SceNgs2WaveFormType::ATRAC9;
    default: return SceNgs2WaveFormType::NONE;
  }
 }
 struct RIFFBuf {
  const uint8_t* data;
  size_t         size;
  uint64_t       offset;
 };
 static int readbuf(void* op, uint8_t* buf, int bufsz) {
  auto rb = (RIFFBuf*)op;
  if (rb->offset > rb->size) return AVERROR_EOF;
  int read = std::min(int(rb->size - rb->offset), bufsz);
  if (read == 0) return AVERROR_EOF;
  ::memcpy(buf, rb->data + rb->offset, read);
  return read;
 }
 static int64_t seekbuf(void* op, int64_t offset, int whence) {
  auto rb = (RIFFBuf*)op;
  if (whence == AVSEEK_SIZE) return rb->size;
  if (rb->data == nullptr || rb->size == 0) return -1;
  if (whence == SEEK_SET)
    rb->offset = offset;
  else if (whence == SEEK_CUR)
    rb->offset += offset;
  else if (whence == SEEK_END)
    rb->offset = rb->size - offset;
  return offset;
 }
 static int32_t ParseData(const uint8_t* data, size_t size, SceNgs2WaveformFormat* wf) {
  LOG_USE_MODULE(libSceNgs2);
-  AVFormatContext* fmtctx = avformat_alloc_context();
+  LOG_DEBUG(L"voiceControl_voice id:%u type:%u", phead->id & 0xFFFF, voh->type);
-  auto aBufferIo = (uint8_t*)av_malloc(4096 + AV_INPUT_BUFFER_PADDING_SIZE);
+  if (voh->type != SceNgs2HandleType::Voice) return Err::Ngs2::INVALID_VOICE_HANDLE;
  auto voice = (SceNgs2Handle_voice*)voh;
-  RIFFBuf rb {
+  switch ((SceNgs2VoiceParam)(phead->id & 0xFFFF)) {
-      .data   = data,
+    case SceNgs2VoiceParam::SET_MATRIX_LEVELS: {
-      .size   = size,
+    } break;
-      .offset = 0,
+    case SceNgs2VoiceParam::SET_PORT_VOLUME: {
-  };
+      // todo
-
+    } break;
-  AVIOContext* avioctx = avio_alloc_context(aBufferIo, 4096, 0, &rb, &readbuf, nullptr, &seekbuf);
+    case SceNgs2VoiceParam::SET_PORT_MATRIX: {
-  fmtctx->pb           = avioctx;
+    } break;
-  fmtctx->flags |= AVFMT_FLAG_CUSTOM_IO;
+    case SceNgs2VoiceParam::SET_PORT_DELAY: {
-
+    } break;
-  int ret = avformat_open_input(&fmtctx, "nullptr", nullptr, nullptr);
+    case SceNgs2VoiceParam::PATCH: {
-  if (ret != 0) {
+      auto item = (SceNgs2VoicePatchParam*)phead;
-    LOG_ERR(L"ParseRIFF: ffmpeg failed to read passed data: %d", ret);
+      // todo
-    return Err::Ngs2::FAIL;
+    } break;
    case SceNgs2VoiceParam::KICK_EVENT: {
      auto item = (SceNgs2VoiceEventParam*)phead;
      voice->ev_KickEvent((SceNgs2VoiceEvent)item->eventId);
    } break;
    case SceNgs2VoiceParam::SET_CALLBACK: {
    } break;
  }
  return Ok;
 }
-  AVStream* astream = nullptr;
+int32_t voiceControl_mastering(SceNgs2Handle* voh, const SceNgs2VoiceParamHead* phead) {
-  for (int i = 0; fmtctx->nb_streams; i++) {
+  LOG_USE_MODULE(libSceNgs2);
-    if (fmtctx->streams[i]->codecpar->codec_type == AVMediaType::AVMEDIA_TYPE_AUDIO) {
+  LOG_DEBUG(L"voiceControl_mastering id:%u type:%u", phead->id & 0xFFFF, voh->type);
-      astream = fmtctx->streams[i];
+
-      break;
+  switch ((SceNgs2MasteringParam)(phead->id & 0xFFFF)) {
-    }
+    case SceNgs2MasteringParam::SETUP: {
    } break;
    case SceNgs2MasteringParam::SET_MATRIX: {
    } break;
    case SceNgs2MasteringParam::SET_LFE: {
    } break;
    case SceNgs2MasteringParam::SET_LIMITER: {
    } break;
    case SceNgs2MasteringParam::SET_GAIN: {
    } break;
    case SceNgs2MasteringParam::SET_OUTPUT: {
    } break;
    case SceNgs2MasteringParam::SET_PEAK_METER: {
    } break;
  }
  return Ok;
 }
-  if (astream == nullptr) {
+int32_t voiceControl_reverb(SceNgs2Handle* voh, const SceNgs2VoiceParamHead* phead) {
-    LOG_ERR(L"ParseRIFF: no audio stream detected!");
+  LOG_USE_MODULE(libSceNgs2);
-    return Err::Ngs2::FAIL;
+  LOG_DEBUG(L"voice_reverbid:%u type:%u", phead->id & 0xFFFF, voh->type);
-  }
+  return Ok;
 }
-  wf->info.type          = ParseWaveType(astream->codecpar->codec_id);
+int32_t voiceControl_equalizer(SceNgs2Handle* voh, const SceNgs2VoiceParamHead* phead) {
-  wf->info.sampleRate    = astream->codecpar->sample_rate;
+  LOG_USE_MODULE(libSceNgs2);
-  wf->info.channelsCount = ParseChanCount(astream->codecpar->ch_layout.nb_channels);
+  LOG_DEBUG(L"voice_equalizer id:%u type:%u", phead->id & 0xFFFF, voh->type);
  // These are unknown for now
  wf->loopBeginPos = wf->loopEndPos = 0;
  wf->samplesCount                  = 0;
  wf->offset                        = 0;
  wf->size                          = 0;
  // std::vector<AVPacket>* frames = new std::vector<AVPacket>;
  // AVPacket packet;
  // while (av_read_frame(fmtctx, &packet) >= 0) {
  //   if (packet.stream_index == astream->index) {
  //     frames->insert(frames->end(), packet);
  //   }
  //   // av_packet_unref(&packet);
  // }
  wf->numBlocks         = 0;
  wf->block[0].userData = 0;
  // wf->block[0].userData = (uintptr_t)frames;
  av_free(avioctx);
  avformat_close_input(&fmtctx);
  return Ok;
 }
-static int32_t ProcessWaveData(WaveformInfo* wi, SceNgs2WaveformFormat* wf) {
+int32_t voiceControl_sampler(SceNgs2Handle* voh, const SceNgs2VoiceParamHead* phead) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_DEBUG(L"voice_sampler id:%u type:%u", phead->id & 0xFFFF, voh->type);
-  switch (wi->type) {
+  if (voh->type != SceNgs2HandleType::Voice) return Err::Ngs2::INVALID_VOICE_HANDLE;
    case WAVEFORM_DATA: return ParseData((const uint8_t*)wi->ud.dataPtr, wi->size, wf);
-    default: LOG_ERR(L"Unimplemented waveform reader: %d", wi->type);
+  auto voice = (SceNgs2Handle_voice*)voh;
  switch ((SceNgs2SamplerParam)(phead->id & 0xFFFF)) {
    case SceNgs2SamplerParam::SETUP: {
      auto item   = (SceNgs2SamplerVoiceSetupParam*)phead;
      voice->info = item->format;
    } break;
    case SceNgs2SamplerParam::ADD_WAVEFORM_BLOCKS: {
      return _voiceControlWaveformBlock(voh, (const SceNgs2SamplerVoiceWaveformBlocksParam*)phead);
    }
    case SceNgs2SamplerParam::REPLACE_WAVEFORM_ADDRESS: {
      auto item = (SceNgs2CustomSamplerVoiceWaveformAddressParam*)phead;
      if (voice->reader != nullptr) voice->reader->setNewData(item->pDataStart, item->pDataEnd);
    } break;
    case SceNgs2SamplerParam::SET_WAVEFORM_FRAME_OFFSET: {
    } break;
    case SceNgs2SamplerParam::EXIT_LOOP: {
    } break;
    case SceNgs2SamplerParam::SET_PITCH: {
    } break;
    case SceNgs2SamplerParam::SET_ENVELOPE: {
    } break;
    case SceNgs2SamplerParam::SET_DISTORTION: {
    } break;
    case SceNgs2SamplerParam::SET_USER_FX: {
    } break;
    case SceNgs2SamplerParam::SET_PEAK_METER: {
    } break;
    case SceNgs2SamplerParam::SET_FILTER: {
    } break;
  }
-  /* todo: Deal with WAV/VAG files */
+  return Ok;
-  return Err::Ngs2::INVALID_WAVEFORM_DATA;
+}
 int32_t voiceControl_submixer(SceNgs2Handle* voh, const SceNgs2VoiceParamHead* phead) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_DEBUG(L"voice_submixer id:%u type:%u", phead->id & 0xFFFF, voh->type);
  switch ((SceNgs2SubmixerParam)(phead->id & 0xFFFF)) {
    case SceNgs2SubmixerParam::SETUP: {
    } break;
    case SceNgs2SubmixerParam::SET_ENVELOPE: {
    } break;
    case SceNgs2SubmixerParam::SET_COMPRESSOR: {
    } break;
    case SceNgs2SubmixerParam::SET_DISTORTION: {
    } break;
    case SceNgs2SubmixerParam::SET_USER_FX: {
    } break;
    case SceNgs2SubmixerParam::SET_PEAK_METER: {
    } break;
    case SceNgs2SubmixerParam::SET_FILTER: {
    } break;
  }
  return Ok;
 }
 } // namespace
 SceNgs2Handle_voice::~SceNgs2Handle_voice() {
  if (reader != nullptr) delete reader;
 }
 void SceNgs2Handle_voice::ev_KickEvent(SceNgs2VoiceEvent id) {
  state.bits.Inuse = true;
  switch (id) {
    case SceNgs2VoiceEvent::Play: {
      state.bits.Playing = true;
    } break;
    case SceNgs2VoiceEvent::Stop: {
      state.bits.Stopped = true;
      state.bits.Playing = false;
    } break;
    case SceNgs2VoiceEvent::Stop_imm: {
      state.bits.Stopped = true;
      state.bits.Playing = false;
    } break;
    case SceNgs2VoiceEvent::Kill: {
      state.bits.Stopped = true;
      state.bits.Playing = false;
    } break;
    case SceNgs2VoiceEvent::Pause: {
      state.bits.Paused = true;
    } break;
    case SceNgs2VoiceEvent::Resume: {
      state.bits.Paused = false;
    } break;
  }
  LOG_USE_MODULE(libSceNgs2);
  LOG_DEBUG(L"set state voice:0x%08llx id:%u state:%x", (uint64_t)this, id, state.data);
 }
 extern "C" {
 EXPORT const char* MODULE_NAME = "libSceNgs2";
 // ### Create
 EXPORT SYSV_ABI int32_t sceNgs2RackQueryBufferSize(uint32_t rackId, const SceNgs2RackOption* ro, SceNgs2ContextBufferInfo* cbi) {
  if (cbi == nullptr) return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  if (ro != nullptr && ro->size < sizeof(SceNgs2RackOption)) return Err::Ngs2::INVALID_OPTION_SIZE;
  auto const numVoices = ro != nullptr ? ro->maxVoices : SceNgs2RackOption().maxVoices;
  cbi->hostBufferSize  = sizeof(SceNgs2Handle_rack);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2SystemQueryBufferSize(const SceNgs2SystemOption* sysopt, SceNgs2ContextBufferInfo* cbi) {
  if (cbi == nullptr) return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  cbi->hostBufferSize = sizeof(SceNgs2Handle_system);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2SystemCreateWithAllocator(const SceNgs2SystemOption* sysopt, SceNgs2BufferAllocator* alloc, SceNgs2Handle** outh) {
  LOG_USE_MODULE(libSceNgs2);
  boost::unique_lock lock(MUTEX_INT);
  if (alloc == nullptr || alloc->allocHandler == nullptr) return Err::Ngs2::INVALID_BUFFER_ALLOCATOR;
  if (outh == nullptr) return Err::Ngs2::INVALID_OUT_ADDRESS;
  if (sysopt != nullptr && sysopt->size < sizeof(SceNgs2SystemOption)) return Err::Ngs2::INVALID_OPTION_SIZE;
  SceNgs2ContextBufferInfo cbi = {
      .hostBuffer     = nullptr,
      .hostBufferSize = sizeof(SceNgs2Handle_system),
      .userData       = alloc->userData,
  };
  if (auto ret = alloc->allocHandler(&cbi)) {
    LOG_ERR(L"Ngs2System: Allocation failed!");
    return ret;
  }
  *outh = new (cbi.hostBuffer) SceNgs2Handle_system(alloc);
  getPimpl()->handles.emplace(*outh);
  LOG_DEBUG(L"-> System: 0x%08llx", (uint64_t)*outh);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2SystemCreate(const SceNgs2SystemOption* sysopt, const SceNgs2ContextBufferInfo* cbi, SceNgs2Handle** outh) {
  LOG_USE_MODULE(libSceNgs2);
  boost::unique_lock lock(MUTEX_INT);
  if (outh == nullptr) return Err::Ngs2::INVALID_OUT_ADDRESS;
  if (sysopt != nullptr && sysopt->size < sizeof(SceNgs2SystemOption)) return Err::Ngs2::INVALID_OPTION_SIZE;
  if (cbi == nullptr || cbi->hostBuffer == nullptr || cbi->hostBufferSize < sizeof(SceNgs2Handle)) return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  *outh = new (cbi->hostBuffer) SceNgs2Handle_system(nullptr);
  getPimpl()->handles.emplace(*outh);
  LOG_DEBUG(L"-> System: 0x%08llx", (uint64_t)*outh);
  return (*outh) != nullptr ? Ok : Err::Ngs2::FAIL;
 }
 EXPORT SYSV_ABI int32_t sceNgs2RackCreate(SceNgs2Handle* sysh, uint32_t rackId, const SceNgs2RackOption* ropt, const SceNgs2ContextBufferInfo* cbi,
                                          SceNgs2Handle** outh) {
  LOG_USE_MODULE(libSceNgs2);
  boost::unique_lock lock(MUTEX_INT);
  if (outh == nullptr) return Err::Ngs2::INVALID_OUT_ADDRESS;
  if (sysh == nullptr) return Err::Ngs2::INVALID_SYSTEM_HANDLE;
  if (ropt != nullptr && ropt->size < sizeof(SceNgs2RackOption)) return Err::Ngs2::INVALID_OPTION_SIZE;
  if (cbi == nullptr || cbi->hostBuffer == nullptr || cbi->hostBufferSize < sizeof(SceNgs2Handle)) return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  auto system = (SceNgs2Handle_system*)sysh;
  *outh = new (cbi->hostBuffer) SceNgs2Handle_rack(system, ropt, rackId);
  getPimpl()->handles.emplace(*outh);
  auto rack = (SceNgs2Handle_rack*)(*outh);
  // Add to system
  if (rackId == SCE_NGS2_RACK_ID_MASTERING || rackId == SCE_NGS2_RACK_ID_CUSTOM_MASTERING) {
    system->mastering = rack;
  } else if (rackId == SCE_NGS2_RACK_ID_SAMPLER || rackId == SCE_NGS2_RACK_ID_CUSTOM_SAMPLER) {
    system->sampler = rack;
  } else if (rackId == SCE_NGS2_RACK_ID_SUBMIXER || rackId == SCE_NGS2_RACK_ID_CUSTOM_SUBMIXER) {
    system->submixer = rack;
  } else if (rackId == SCE_NGS2_RACK_ID_REVERB) {
    system->reverb = rack;
  } else if (rackId == SCE_NGS2_RACK_ID_EQ) {
    system->equalizer = rack;
  } else {
    LOG_ERR(L"-> Rack: undefined rackid %u", rackId);
    return Err::Ngs2::FAIL;
  }
  LOG_DEBUG(L"-> Rack: system:0x%08llx rack:0x%08llx id:0x%x", (uint64_t)sysh, (uint64_t)*outh, rackId);
  return (*outh) != nullptr ? Ok : Err::Ngs2::FAIL;
 }
 EXPORT SYSV_ABI int32_t sceNgs2RackCreateWithAllocator(SceNgs2Handle* sysh, uint32_t rackId, const SceNgs2RackOption* ro, const SceNgs2BufferAllocator* alloc,
                                                       SceNgs2Handle** outh) {
  if (sysh == nullptr) return Err::Ngs2::INVALID_SYSTEM_HANDLE;
  if (alloc == nullptr) return Err::Ngs2::INVALID_BUFFER_ALLOCATOR;
  LOG_USE_MODULE(libSceNgs2);
  boost::unique_lock lock(MUTEX_INT);
  auto system = (SceNgs2Handle_system*)sysh;
  SceNgs2ContextBufferInfo cbi = {
      .hostBuffer     = nullptr,
      .hostBufferSize = sizeof(SceNgs2Handle_rack),
      .userData       = alloc->userData,
  };
  if (auto ret = alloc->allocHandler(&cbi)) {
    LOG_ERR(L"Ngs2Rack: Allocation failed!");
    return ret;
  }
  *outh = new (cbi.hostBuffer) SceNgs2Handle_rack(system, ro, rackId);
  getPimpl()->handles.emplace(*outh);
  auto rack = (SceNgs2Handle_rack*)(*outh);
  // Add to system
  if (rackId == SCE_NGS2_RACK_ID_MASTERING || rackId == SCE_NGS2_RACK_ID_CUSTOM_MASTERING) {
    system->mastering = rack;
  } else if (rackId == SCE_NGS2_RACK_ID_SAMPLER || rackId == SCE_NGS2_RACK_ID_CUSTOM_SAMPLER) {
    system->sampler = rack;
  } else if (rackId == SCE_NGS2_RACK_ID_SUBMIXER || rackId == SCE_NGS2_RACK_ID_CUSTOM_SUBMIXER) {
    system->submixer = rack;
  } else if (rackId == SCE_NGS2_RACK_ID_REVERB) {
    system->reverb = rack;
  } else if (rackId == SCE_NGS2_RACK_ID_EQ) {
    system->equalizer = rack;
  } else {
    LOG_ERR(L"-> Rack: undefined rackid %u", rackId);
    return Err::Ngs2::FAIL;
  }
  LOG_DEBUG(L"-> Rack: system:0x%08llx rack:0x%08llx id:0x%x", (uint64_t)sysh, (uint64_t)*outh, rackId);
  return (*outh) != nullptr ? Ok : Err::Ngs2::FAIL;
 }
 // --- create
 EXPORT SYSV_ABI int32_t sceNgs2ReportRegisterHandler(uint32_t type, SceNgs2ReportHandler func, uintptr_t userData, SceNgs2Handle** outh) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_TRACE(L"todo %S", __FUNCTION__);
@ -197,27 +377,77 @@ EXPORT SYSV_ABI int32_t sceNgs2CustomRackGetModuleInfo(SceNgs2Handle* rh, uint32
  return Ok;
 }
-EXPORT SYSV_ABI int32_t sceNgs2ParseWaveformData(const void* ptr, size_t size, SceNgs2WaveformFormat* wf) {
+// ### WAVE File parsing
  LOG_USE_MODULE(libSceNgs2);
  LOG_TRACE(L"todo %S", __FUNCTION__);
 /**
 * @brief Parse the wave (file) data
 *
 * @param ptr Game/Application reads (file) and exposes the data pointer
 * @param size size of data(file)
 * @param wf
 * @return result
 */
 EXPORT SYSV_ABI int32_t sceNgs2ParseWaveformData(const void* ptr, size_t size, SceNgs2WaveformFormat* wf) {
  if (ptr == nullptr) {
    return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  }
  boost::unique_lock lock(MUTEX_INT);
-  WaveformInfo wi {
+  userData_inerBuffer userData {ptr, size, 0};
-      .type = WAVEFORM_DATA,
+  return parseRiffWave(readFunc_linearBuffer, seekFunc_linearBuffer, &userData, wf);
-      .ud   = {.dataPtr = ptr},
+}
-      .size = size,
+
 /**
 * @brief Parse the wave file
 *
 * @param ptr Game/Application reads file and exposes the data pointer
 * @param offset offset of file
 * @param wf
 * @return result
 */
 EXPORT SYSV_ABI int32_t sceNgs2ParseWaveformFile(const char* path, long offset, SceNgs2WaveformFormat* wf) {
  boost::unique_lock lock(MUTEX_INT);
  filesystem::SceOpen const fileFlags {
      .mode = filesystem::SceOpenMode::RDONLY,
  };
-  return ProcessWaveData(&wi, wf);
+  auto fileHandle = filesystem::open(path, fileFlags, 0);
  if (fileHandle < 0) return Err::Ngs2::INVALID_WAVEFORM_DATA;
  if (offset != 0) filesystem::lseek(fileHandle, offset, (int)SceWhence::beg);
  return parseRiffWave(readFunc_file, seekFunc_file, reinterpret_cast<void*>(fileHandle), wf);
 }
 /**
 * @brief Parse the wave file using the provided function
 *
 * @param func Game/Application reads file and exposes the data pointer
 * @param userData_ offset of file
 * @param wf
 * @return result
 */
 EXPORT SYSV_ABI int32_t sceNgs2ParseWaveformUser(SceWaveformUserFunc func, uintptr_t userData_, SceNgs2WaveformFormat* wf) {
  if (func == nullptr) {
    return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  }
  boost::unique_lock lock(MUTEX_INT);
  userData_user userData {func, userData_, 0};
  return parseRiffWave(readFunc_user, seekFunc_user, (void*)&userData, wf);
 }
 // - wave parsing
 EXPORT SYSV_ABI int32_t sceNgs2GetWaveformFrameInfo(const SceNgs2WaveformInfo* fmt, uint32_t* outFrameSize, uint32_t* outNumFrameSamples,
                                                    uint32_t* outUnitsPerFrame, uint32_t* outNumDelaySamples) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_TRACE(L"todo %S", __FUNCTION__);
  boost::unique_lock lock(MUTEX_INT);
  if (outFrameSize) *outFrameSize = 1; // Some games crashes with divide by zero exception if we set 0 here
  if (outNumFrameSamples) *outNumFrameSamples = 0;
  if (outUnitsPerFrame) *outUnitsPerFrame = 0;
@ -238,44 +468,6 @@ EXPORT SYSV_ABI int32_t sceNgs2PanInit() {
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2ParseWaveformFile(const char* path, long offset, SceNgs2WaveformFormat* wf) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_ERR(L"todo %S", __FUNCTION__);
  filesystem::SceOpen flags {
      .mode = filesystem::SceOpenMode::RDONLY,
  };
  WaveformInfo wi {
      .type   = WAVEFORM_DATA,
      .ud     = {.fileHandle = filesystem::open(path, flags, {})},
      .offset = offset,
  };
  if (wi.ud.fileHandle == 0) {
    return Err::Ngs2::INVALID_WAVEFORM_DATA;
  }
  return ProcessWaveData(&wi, wf);
 }
 EXPORT SYSV_ABI int32_t sceNgs2ParseWaveformUser(SceWaveformUserFunc* user, size_t size, SceNgs2WaveformFormat* wf) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_ERR(L"todo %S", __FUNCTION__);
  if (user == nullptr) {
    return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  }
  WaveformInfo wi {
      .type = WAVEFORM_USER,
      .ud   = {.userFunc = user},
      .size = size,
  };
  return ProcessWaveData(&wi, wf);
 }
 EXPORT SYSV_ABI int32_t sceNgs2RackGetInfo(SceNgs2Handle* rh, SceNgs2RackInfo* outi, size_t infosz) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_ERR(L"todo %S", __FUNCTION__);
@ -296,12 +488,18 @@ EXPORT SYSV_ABI int32_t sceNgs2RackGetUserData(SceNgs2Handle* rh, uintptr_t* use
 }
 EXPORT SYSV_ABI int32_t sceNgs2RackGetVoiceHandle(SceNgs2Handle* rh, uint32_t voiceId, SceNgs2Handle** outh) {
  if (rh == nullptr) return Err::Ngs2::INVALID_RACK_HANDLE;
  if (voiceId > rh->un.rack.info.maxVoices) return Err::Ngs2::INVALID_VOICE_INDEX;
  LOG_USE_MODULE(libSceNgs2);
-  LOG_TRACE(L"todo %S", __FUNCTION__);
+  boost::unique_lock lock(MUTEX_INT);
-  // todo: write to outh voice handle from rack
+
-  *outh = &rh->un.rack.voices[voiceId];
+  if (rh == nullptr || rh->type != SceNgs2HandleType::Rack) return Err::Ngs2::INVALID_RACK_HANDLE;
  auto rack = (SceNgs2Handle_rack*)rh;
  if (voiceId > rack->options.maxVoices) return Err::Ngs2::INVALID_VOICE_INDEX;
  *outh = &rack->voices.emplace(std::make_pair(voiceId, rack)).first->second;
  getPimpl()->handles.emplace(*outh);
  LOG_DEBUG(L"-> GetVoiceHandle: rack:0x%08llx id:%u @0x%08llx", (uint64_t)rh, voiceId, (uint64_t)*outh);
  return Ok;
 }
@ -359,22 +557,36 @@ EXPORT SYSV_ABI int32_t sceNgs2SystemUnlock(SceNgs2Handle* sysh) {
 }
 EXPORT SYSV_ABI int32_t sceNgs2SystemRender(SceNgs2Handle* sysh, SceNgs2RenderBufferInfo* rbi, int32_t count) {
-  LOG_USE_MODULE(libSceNgs2);
+  boost::unique_lock lock(MUTEX_INT);
-  LOG_TRACE(L"todo %S", __FUNCTION__);
+  auto               system = (SceNgs2Handle_system*)sysh;
-  if (sysh == nullptr) return Err::Ngs2::INVALID_SYSTEM_HANDLE;
+  if (system == nullptr) return Err::Ngs2::INVALID_SYSTEM_HANDLE;
  if (rbi->bufferPtr == nullptr) return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  if (rbi->bufferSize == 0) return Err::Ngs2::INVALID_BUFFER_SIZE;
  if (rbi->waveType >= SceNgs2WaveFormType::MAX_TYPES) return Err::Ngs2::INVALID_WAVEFORM_TYPE;
  if (rbi->channelsCount > SceNgs2ChannelsCount::CH_7_1) return Err::Ngs2::INVALID_NUM_CHANNELS;
-  for (int32_t i = 0; i < count; i++) {
+  uint32_t const numSamples = rbi->bufferSize / ((uint32_t)rbi->channelsCount * getSampleBytes(rbi->waveType));
-    if (rbi[i].bufferPtr != nullptr) {
+
-      std::memset(rbi[i].bufferPtr, 0, rbi[i].bufferSize);
+  if (system->sampler == nullptr) {
    //
    for (int32_t i = 0; i < count; i++) {
      if (rbi[i].bufferPtr != nullptr) {
        std::memset(rbi[i].bufferPtr, 0, rbi[i].bufferSize);
      }
    }
  } else {
    for (int32_t i = 0; i < count; i++) {
      if (rbi[i].bufferPtr != nullptr) {
        std::memset(rbi[i].bufferPtr, 0, rbi[i].bufferSize);
        for (auto& voice: system->sampler->voices) {
          if (voice.second.reader != nullptr) {
            // voice.second.reader->getAudio(&rbi[i], numSamples);
          }
        }
      }
    }
  }
  // todo: ffmpeg should convert all the wave data to `rbi->waveType`
  return Ok;
 }
@ -408,36 +620,80 @@ EXPORT SYSV_ABI int32_t sceNgs2VoiceGetPortInfo(SceNgs2Handle** vh, uint32_t por
  return Ok;
 }
 static int32_t _voiceControlWaveformBlock(SceNgs2Handle* voh, const SceNgs2SamplerVoiceWaveformBlocksParam* svwfbp) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_TRACE(L"waveblock: %d\n", svwfbp->numBlocks);
  if (svwfbp->aBlock) LOG_TRACE(L"waveptr: %llx\n", svwfbp->aBlock[0].userData);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2VoiceControl(SceNgs2Handle* voh, const SceNgs2VoiceParamHead* phead) {
  LOG_USE_MODULE(libSceNgs2);
-  LOG_TRACE(L"todo %S", __FUNCTION__);
+  boost::unique_lock lock(MUTEX_INT);
  switch (phead->id) {
    case SCE_NGS2_SAMPLER_VOICE_ADD_WAVEFORM_BLOCKS: return _voiceControlWaveformBlock(voh, (const SceNgs2SamplerVoiceWaveformBlocksParam*)phead);
-    case (uint32_t)SceNgs2VoiceParam::SET_PORT_VOLUME: break;
+  if (voh == nullptr) return getErr(ErrCode::_EINVAL);
  uint16_t const rackId_ = phead->id >> 16;
-    default: LOG_TRACE(L"Unhandled voice control command: (%p, %08x)", voh, phead->id);
+  auto    curItem = phead;
  int32_t ret     = Ok;
  while (true) {
    uint16_t const rackId = curItem->id >> 16;
    if (rackId == SCE_NGS2_RACK_ID_VOICE)
      ret = voiceControl_voice(voh, curItem);
    else if (rackId == SCE_NGS2_RACK_ID_MASTERING || rackId == SCE_NGS2_RACK_ID_CUSTOM_MASTERING)
      ret = voiceControl_mastering(voh, curItem);
    else if (rackId == SCE_NGS2_RACK_ID_SAMPLER || rackId == SCE_NGS2_RACK_ID_CUSTOM_SAMPLER)
      ret = voiceControl_sampler(voh, curItem);
    else if (rackId == SCE_NGS2_RACK_ID_SUBMIXER || rackId == SCE_NGS2_RACK_ID_CUSTOM_SUBMIXER)
      ret = voiceControl_submixer(voh, curItem);
    else if (rackId == SCE_NGS2_RACK_ID_REVERB)
      ret = voiceControl_reverb(voh, curItem);
    else if (rackId == SCE_NGS2_RACK_ID_EQ)
      ret = voiceControl_equalizer(voh, curItem);
    else
      LOG_ERR(L"Unhandled rackId: %08x", rackId);
    if (curItem->next == 0 || ret != Ok) break;
    curItem = (SceNgs2VoiceParamHead*)((uint64_t)curItem + curItem->next);
  }
-  return Ok;
+  return ret;
 }
 EXPORT SYSV_ABI int32_t sceNgs2VoiceGetState(SceNgs2Handle* voh, SceNgs2VoiceState* state, size_t size) {
  LOG_USE_MODULE(libSceNgs2);
-  LOG_TRACE(L"todo %S", __FUNCTION__);
+
  boost::unique_lock lock(MUTEX_INT);
  if (voh == nullptr || state == nullptr) return getErr(ErrCode::_EINVAL);
  auto pimpl = getPimpl();
  if (auto it = pimpl->handles.find(voh); it == pimpl->handles.end()) return Err::Ngs2::INVALID_VOICE_HANDLE;
  if (voh->type != SceNgs2HandleType::Voice) return Err::Ngs2::INVALID_VOICE_HANDLE;
  auto voice = (SceNgs2Handle_voice*)voh;
  if (voice->reader != nullptr) {
    if (size != sizeof(SceNgs2SamplerVoiceState)) return getErr(ErrCode::_EINVAL);
    voice->reader->getState((SceNgs2SamplerVoiceState*)state);
    return Ok;
  }
  state->stateFlags = voice->state.data;
  // LOG_DEBUG(L"state voice:0x%08llx state:%x", (uint64_t)voh, state->stateFlags);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2VoiceGetStateFlags(SceNgs2Handle* voh, uint32_t* flags) {
  LOG_USE_MODULE(libSceNgs2);
-  LOG_TRACE(L"todo %S", __FUNCTION__);
+
  boost::unique_lock lock(MUTEX_INT);
  if (voh == nullptr || flags == nullptr) return getErr(ErrCode::_EINVAL);
  auto pimpl = getPimpl();
  if (auto it = pimpl->handles.find(voh); it == pimpl->handles.end()) return Err::Ngs2::INVALID_VOICE_HANDLE;
  if (voh->type != SceNgs2HandleType::Voice) return Err::Ngs2::INVALID_VOICE_HANDLE;
  auto voice = (SceNgs2Handle_voice*)voh;
  *flags     = voice->state.data;
  // LOG_DEBUG(L"state voice:0x%08llx state:%x", (uint64_t)voh, *flags);
  return Ok;
 }
@ -449,7 +705,7 @@ EXPORT SYSV_ABI int32_t sceNgs2GeomApply() {
 EXPORT SYSV_ABI int32_t sceNgs2GeomCalcListener() {
  LOG_USE_MODULE(libSceNgs2);
-  LOG_ERR(L"todo %S", __FUNCTION__);
+  LOG_TRACE(L"todo %S", __FUNCTION__);
  return Ok;
 }
@ -465,158 +721,54 @@ EXPORT SYSV_ABI int32_t sceNgs2GeomResetSourceParam(SceNgs2GeomSourceParam* para
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2RackCreate(SceNgs2Handle* sysh, uint32_t rackId, const SceNgs2RackOption* ropt, const SceNgs2ContextBufferInfo* cbi,
                                          SceNgs2Handle** outh) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_ERR(L"todo %S(%p, %d, %p, %p, %p)", __FUNCTION__, sysh, rackId, ropt, cbi, outh);
  if (outh == nullptr) return Err::Ngs2::INVALID_OUT_ADDRESS;
  if (sysh == nullptr) return Err::Ngs2::INVALID_SYSTEM_HANDLE;
  if (ropt != nullptr && ropt->size < sizeof(SceNgs2RackOption)) return Err::Ngs2::INVALID_OPTION_SIZE;
  if (cbi == nullptr || cbi->hostBuffer == nullptr || cbi->hostBufferSize < sizeof(SceNgs2Handle)) return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  *outh                       = (SceNgs2Handle*)cbi->hostBuffer;
  (*outh)->allocSet           = false;
  (*outh)->alloc.allocHandler = nullptr;
  (*outh)->alloc.freeHandler  = nullptr;
  (*outh)->alloc.userData     = nullptr;
  (*outh)->owner              = sysh;
  if (ropt != nullptr) {
    (*outh)->un.rack.info.maxPorts        = ropt->maxPorts;
    (*outh)->un.rack.info.maxMatrices     = ropt->maxMatrices;
    (*outh)->un.rack.info.maxGrainSamples = ropt->maxGrainSamples;
    (*outh)->un.rack.info.maxVoices       = ropt->maxVoices;
  } else {
    (*outh)->un.rack.info.maxPorts        = 1;
    (*outh)->un.rack.info.maxMatrices     = 1;
    (*outh)->un.rack.info.maxGrainSamples = 1;
    (*outh)->un.rack.info.maxVoices       = 1;
  }
  auto vo = (*outh)->un.rack.voices = new SceNgs2Handle;
  vo->allocSet                      = false;
  vo->alloc.allocHandler            = nullptr;
  vo->alloc.freeHandler             = nullptr;
  vo->alloc.userData                = nullptr;
  return (*outh) != nullptr ? Ok : Err::Ngs2::FAIL;
 }
 EXPORT SYSV_ABI int32_t sceNgs2RackCreateWithAllocator(SceNgs2Handle* sysh, uint32_t rackId, const SceNgs2RackOption* ro, const SceNgs2BufferAllocator* alloc,
                                                       SceNgs2Handle** outh) {
  if (sysh == nullptr) return Err::Ngs2::INVALID_SYSTEM_HANDLE;
  if (alloc == nullptr) return Err::Ngs2::INVALID_BUFFER_ALLOCATOR;
  LOG_USE_MODULE(libSceNgs2);
  LOG_TRACE(L"todo %S", __FUNCTION__);
  SceNgs2ContextBufferInfo cbi = {
      .hostBuffer     = nullptr,
      .hostBufferSize = sizeof(SceNgs2Handle),
      .userData       = alloc->userData,
  };
  if (auto ret = alloc->allocHandler(&cbi)) {
    LOG_ERR(L"Ngs2Rack: Allocation failed!");
    return ret;
  }
  *outh             = (SceNgs2Handle*)cbi.hostBuffer;
  (*outh)->owner    = sysh;
  (*outh)->allocSet = true;
  (*outh)->alloc    = *alloc;
  (*outh)->cbi      = cbi;
  cbi.hostBufferSize = sizeof(SceNgs2Handle) * ((ro != nullptr) ? ro->maxVoices : 1);
  if (auto ret = alloc->allocHandler(&cbi)) {
    LOG_ERR(L"Ngs2Rack: Voice allocation failed");
    return ret;
  }
  auto vo = (*outh)->un.rack.voices = (SceNgs2Handle*)cbi.hostBuffer;
  vo->allocSet                      = true;
  vo->alloc                         = *alloc;
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2RackDestroy(SceNgs2Handle* rh, SceNgs2ContextBufferInfo* cbi) {
-  if (rh == nullptr) return Err::Ngs2::INVALID_SYSTEM_HANDLE;
+  if (rh == nullptr) return Err::Ngs2::INVALID_RACK_HANDLE;
-  if (rh->allocSet) {
+  boost::unique_lock lock(MUTEX_INT);
-    cbi->hostBufferSize = sizeof(SceNgs2Handle);
+
-    cbi->hostBuffer     = rh->un.rack.voices;
+  auto rack = (SceNgs2Handle_rack*)rh;
-    if (auto ret = rh->alloc.freeHandler(cbi)) return ret;
+
-    cbi->hostBuffer = rh;
+  auto freeHandler = rack->parent->alloc.freeHandler;
-    if (auto ret = rh->alloc.freeHandler(cbi)) return ret;
+
-  } else {
+  int32_t ret = Ok;
-    if (rh->un.rack.voices != nullptr) delete rh->un.rack.voices;
+
  for (auto voice: rack->voices) {
    getPimpl()->handles.erase(&voice.second);
  }
-  return Ok;
+  getPimpl()->handles.erase(rh);
-}
+  if (freeHandler != nullptr) {
    SceNgs2ContextBufferInfo cbi = {
        .hostBuffer     = rack,
        .hostBufferSize = sizeof(SceNgs2Handle_rack),
    };
    rack->~SceNgs2Handle_rack();
    ret = freeHandler(&cbi);
  } else
    rack->~SceNgs2Handle_rack();
-EXPORT SYSV_ABI int32_t sceNgs2RackQueryBufferSize(uint32_t rackId, const SceNgs2RackOption* ro, SceNgs2ContextBufferInfo* cbi) {
+  return ret;
  cbi->hostBufferSize = sizeof(SceNgs2Handle);
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2SystemCreateWithAllocator(const SceNgs2SystemOption* sysopt, SceNgs2BufferAllocator* alloc, SceNgs2Handle** outh) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_ERR(L"todo %S(%p, %p, %p)", __FUNCTION__, sysopt, alloc, outh);
  if (alloc == nullptr || alloc->allocHandler == nullptr) return Err::Ngs2::INVALID_BUFFER_ALLOCATOR;
  if (outh == nullptr) return Err::Ngs2::INVALID_OUT_ADDRESS;
  if (sysopt != nullptr && sysopt->size < sizeof(SceNgs2SystemOption)) return Err::Ngs2::INVALID_OPTION_SIZE;
  SceNgs2ContextBufferInfo cbi = {
      .hostBuffer     = nullptr,
      .hostBufferSize = sizeof(SceNgs2Handle),
      .userData       = alloc->userData,
  };
  if (auto ret = alloc->allocHandler(&cbi)) {
    LOG_ERR(L"Ngs2System: Allocation failed!");
    return ret;
  }
  *outh             = (SceNgs2Handle*)cbi.hostBuffer;
  (*outh)->owner    = nullptr;
  (*outh)->allocSet = true;
  (*outh)->alloc    = *alloc;
  (*outh)->cbi      = cbi;
  return Ok;
 }
 EXPORT SYSV_ABI int32_t sceNgs2SystemCreate(const SceNgs2SystemOption* sysopt, const SceNgs2ContextBufferInfo* cbi, SceNgs2Handle** outh) {
  LOG_USE_MODULE(libSceNgs2);
  LOG_ERR(L"todo %S(%p, %p, %p)", __FUNCTION__, sysopt, cbi, outh);
  if (outh == nullptr) return Err::Ngs2::INVALID_OUT_ADDRESS;
  if (sysopt != nullptr && sysopt->size < sizeof(SceNgs2SystemOption)) return Err::Ngs2::INVALID_OPTION_SIZE;
  if (cbi == nullptr || cbi->hostBuffer == nullptr || cbi->hostBufferSize < sizeof(SceNgs2Handle)) return Err::Ngs2::INVALID_BUFFER_ADDRESS;
  *outh             = (SceNgs2Handle*)cbi->hostBuffer;
  (*outh)->allocSet = false;
  (*outh)->owner    = nullptr;
  return (*outh) != nullptr ? Ok : Err::Ngs2::FAIL;
 }
 EXPORT SYSV_ABI int32_t sceNgs2SystemDestroy(SceNgs2Handle* sysh, SceNgs2ContextBufferInfo* cbi) {
  if (sysh == nullptr) return Err::Ngs2::INVALID_SYSTEM_HANDLE;
-  if (sysh->allocSet) {
+  boost::unique_lock lock(MUTEX_INT);
    cbi->hostBuffer     = sysh;
    cbi->hostBufferSize = sizeof(SceNgs2Handle);
    if (auto ret = sysh->alloc.freeHandler(cbi)) return ret;
  } else {
    delete sysh;
  }
-  return Ok;
+  auto system = (SceNgs2Handle_system*)sysh;
-}
+  getPimpl()->handles.erase(system);
-EXPORT SYSV_ABI int32_t sceNgs2SystemQueryBufferSize(const SceNgs2SystemOption* sysopt, SceNgs2ContextBufferInfo* cbi) {
+  auto freeHandler = system->alloc.freeHandler;
-  if (cbi == nullptr) return Err::Ngs2::INVALID_BUFFER_ADDRESS;
+
-  cbi->hostBufferSize = sizeof(SceNgs2Handle);
+  int32_t ret = Ok;
-  return Ok;
+  if (freeHandler != nullptr) {
    SceNgs2ContextBufferInfo cbi = {
        .hostBuffer     = system,
        .hostBufferSize = sizeof(SceNgs2Handle_system),
    };
    system->~SceNgs2Handle_system();
    ret = freeHandler(&cbi);
  } else
    system->~SceNgs2Handle_system();
  return ret;
 }
 }
--- a/modules/libSceNgs2/readFuncs.cpp
+++ b/modules/libSceNgs2/readFuncs.cpp
@ -0,0 +1,225 @@
 #include "readFuncs.h"
 #include "core/fileManager/ifile.h"
 #include "core/kernel/filesystem.h"
 #include "logging.h"
 #include "riffTypes.h"
 extern "C" {
 #include <libavcodec/avcodec.h>
 #include <libavformat/avformat.h>
 }
 #include <functional>
 #include <list>
 #include <sstream>
 LOG_DEFINE_MODULE(libSceNgs2);
 namespace {
 static SceNgs2ChannelsCount convChanCount(int num) {
  LOG_USE_MODULE(libSceNgs2);
  switch (num) {
    case 1: return SceNgs2ChannelsCount::CH_1_0;
    case 2: return SceNgs2ChannelsCount::CH_2_0;
    case 6: return SceNgs2ChannelsCount::CH_5_1;
    case 8: return SceNgs2ChannelsCount::CH_7_1;
  }
  LOG_CRIT(L"Invalid channels count sent to ParseChanCount!");
  return SceNgs2ChannelsCount::INVALID;
 }
 static SceNgs2WaveFormType convWaveType(AVCodecID codec) {
  switch (codec) {
    case AVCodecID::AV_CODEC_ID_PCM_S8: return SceNgs2WaveFormType::PCM_I8;
    case AVCodecID::AV_CODEC_ID_PCM_U8: return SceNgs2WaveFormType::PCM_U8;
    case AVCodecID::AV_CODEC_ID_ATRAC9: return SceNgs2WaveFormType::ATRAC9;
    default: return SceNgs2WaveFormType::NONE;
  }
 }
 } // namespace
 int readFunc_linearBuffer(void* userData_, uint8_t* buf, int size) {
  auto rb = (userData_inerBuffer*)userData_;
  auto len = std::min(int(rb->size - rb->curOffset), size);
  if (len == 0) return AVERROR_EOF;
  ::memcpy(buf, (uint8_t*)rb->ptr + rb->curOffset, len);
  rb->curOffset += len;
  return len;
 }
 int64_t seekFunc_linearBuffer(void* userData_, int64_t pos, int whence) {
  auto rb = (userData_inerBuffer*)userData_;
  if (whence == AVSEEK_SIZE) return rb->size;
  if (whence == SEEK_SET) {
    rb->curOffset = pos;
  } else if (whence == SEEK_CUR) {
    rb->curOffset += pos;
  } else if (whence == SEEK_END) {
    rb->curOffset = rb->size - pos;
  }
  return rb->curOffset;
 }
 int readFunc_file(void* userData_, uint8_t* buf, int size) {
  auto handle = (int&)userData_;
  return filesystem::read(handle, buf, size);
 }
 int64_t seekFunc_file(void* userData_, int64_t offset, int whence) {
  auto handle = (int&)userData_;
  return filesystem::lseek(handle, offset, whence);
 }
 int readFunc_user(void* userData_, uint8_t* buf, int size) {
  auto userData = (userData_user*)userData_;
  auto read = userData->func(userData->userData, userData->curOffset, buf, size);
  userData->curOffset += read;
  return read;
 }
 int64_t seekFunc_user(void* userData_, int64_t offset, int whence) {
  auto userData = (userData_user*)userData_;
  return 0; // undefined
 }
 int32_t parseRiffWave(funcReadBuf_t readFunc, funcSeekBuf_t seekFunc, void* userData, SceNgs2WaveformFormat* wf) {
  LOG_USE_MODULE(libSceNgs2);
  // Load headers and check magic
  // todo use ffmeg, get the correct type (pcm, at9...)
  // Check if correct file
  RiffWaveHeader riffHeader;
  readFunc(userData, (uint8_t*)&riffHeader, sizeof(RiffWaveHeader));
  if (memcmp(riffHeader.chunkID, "RIFF", 4) != 0 || memcmp(riffHeader.riffType, "WAVE", 4) != 0) {
    LOG_ERR(L"wrong riff 0x%lx 0x%lx", riffHeader.chunkID, riffHeader.riffType);
    return Err::Ngs2::FAIL;
  }
  // -
  // Format header
  RiffFormatHeader formatHeader;
  readFunc(userData, (uint8_t*)&formatHeader, sizeof(RiffFormatHeader));
  if (memcmp(formatHeader.chunkID, "fmt ", 4) != 0) {
    return Err::Ngs2::FAIL;
  }
  if ((8 + formatHeader.chunkSize) > sizeof(RiffFormatHeader)) {
    std::vector<uint8_t> extraFmt(8 + formatHeader.chunkSize - sizeof(RiffFormatHeader));
    readFunc(userData, extraFmt.data(), extraFmt.size());
  }
  // -
  // parse rest
  uint32_t offset = sizeof(RiffWaveHeader) + 8 + formatHeader.chunkSize;
  uint32_t dataSize     = 0;
  uint32_t numOfSamples = 1;
  // Data header
  while (offset < riffHeader.chunkSize) {
    RiffHeader header;
    readFunc(userData, (uint8_t*)&header, sizeof(RiffHeader));
    auto readBytes = sizeof(RiffHeader);
    if (memcmp(header.chunkID, "fact", 4) == 0) {
      readFunc(userData, (uint8_t*)&numOfSamples, 4);
      readBytes += 4;
    } else if (memcmp(header.chunkID, "data", 4) == 0) {
      dataSize = header.chunkSize;
      break;
    } // Dump read data
    if ((8 + header.chunkSize) > readBytes) {
      std::vector<uint8_t> extra(8 + header.chunkSize - readBytes);
      readFunc(userData, extra.data(), extra.size());
    }
    // -
    offset += 8 + header.chunkSize;
  }
  if (dataSize == 0) return Err::Ngs2::FAIL;
  // Fill data
  wf->info.type          = (SceNgs2WaveFormType)formatHeader.audioFormat;
  wf->info.channelsCount = (SceNgs2ChannelsCount)formatHeader.numChannels;
  wf->info.sampleRate    = formatHeader.sampleRate;
  wf->info.frameOffset   = formatHeader.frameSize;
  wf->info.frameMargin   = 0; // todo
  wf->offset          = offset;
  wf->size            = dataSize;
  wf->loopBeginPos    = 0;                      // todo
  wf->loopEndPos      = 0;                      // todo
  wf->samplesCount    = 1;                      // todo
  wf->dataPerFrame    = 1;                      // todo
  wf->frameSize       = formatHeader.frameSize; // todo
  wf->numframeSamples = 1;                      // todo
  wf->samplesDelay    = 0;                      // todo
  auto& block       = wf->block[0];
  block.offset      = wf->offset;
  block.size        = dataSize;
  block.numRepeat   = 1;
  block.skipSamples = 1;
  block.numSamples  = numOfSamples;
  wf->numBlocks     = 1;
  return Ok;
 }
 AVChannelLayout convChannelLayout(SceNgs2ChannelsCount count) {
  LOG_USE_MODULE(libSceNgs2);
  switch (count) {
    case SceNgs2ChannelsCount::CH_1_0: {
      return AV_CHANNEL_LAYOUT_MONO;
    } break;
    case SceNgs2ChannelsCount::CH_2_0: {
      return AV_CHANNEL_LAYOUT_STEREO;
    } break;
    case SceNgs2ChannelsCount::CH_5_1: {
      return AV_CHANNEL_LAYOUT_5POINT1;
    } break;
    case SceNgs2ChannelsCount::CH_7_1: {
      return AV_CHANNEL_LAYOUT_CUBE;
    } break;
    default: {
      LOG_ERR(L"channel layout not set");
    } break;
  }
  return AV_CHANNEL_LAYOUT_MASK(1, AV_CHANNEL_ORDER_UNSPEC);
 }
 uint32_t getSampleBytes(SceNgs2WaveFormType type) {
  switch (type) {
    case SceNgs2WaveFormType::PCM_U8: return 1;
    case SceNgs2WaveFormType::PCM_I16LITTLE: return 2;
    case SceNgs2WaveFormType::PCM_I16BIG: return 2;
    case SceNgs2WaveFormType::PCM_I24LITTLE: return 3;
    case SceNgs2WaveFormType::PCM_I24BIG: return 3;
    case SceNgs2WaveFormType::PCM_I32LITTLE: return 4;
    case SceNgs2WaveFormType::PCM_I32BIG: return 4;
    case SceNgs2WaveFormType::PCM_F32LITTLE: return 4;
    case SceNgs2WaveFormType::PCM_F32BIG: return 4;
    case SceNgs2WaveFormType::PCM_F64LITTLE: return 8;
    case SceNgs2WaveFormType::PCM_F64BIG: return 8;
    case SceNgs2WaveFormType::VAG: return 4;
    case SceNgs2WaveFormType::ATRAC9: return 4;
    default: break;
  }
  return 2;
 }
--- a/modules/libSceNgs2/readFuncs.h
+++ b/modules/libSceNgs2/readFuncs.h
@ -0,0 +1,30 @@
 #pragma once
 #include "types.h"
 using funcReadBuf_t = int (*)(void*, uint8_t*, int);
 using funcSeekBuf_t = int64_t (*)(void*, int64_t, int);
 struct userData_user {
  SceWaveformUserFunc func;
  uintptr_t           userData;
  size_t              curOffset;
 };
 struct userData_inerBuffer {
  const void* ptr;
  size_t      size;
  size_t      curOffset;
 };
 int     readFunc_linearBuffer(void* userData_, uint8_t* buf, int size);
 int64_t seekFunc_linearBuffer(void* userData_, int64_t offset, int whence);
 int     readFunc_file(void* userData_, uint8_t* buf, int size);
 int64_t seekFunc_file(void* userData_, int64_t offset, int whence);
 int     readFunc_user(void* userData_, uint8_t* buf, int size);
 int64_t seekFunc_user(void* userData_, int64_t offset, int whence);
 int32_t parseRiffWave(funcReadBuf_t readFunc, funcSeekBuf_t seekFunc, void* userData, SceNgs2WaveformFormat* wf);
 struct AVChannelLayout;
 AVChannelLayout convChannelLayout(SceNgs2ChannelsCount);
 uint32_t        getSampleBytes(SceNgs2WaveFormType);
--- a/modules/libSceNgs2/reader.cpp
+++ b/modules/libSceNgs2/reader.cpp
@ -0,0 +1,437 @@
 #include "reader.h"
 extern "C" {
 #include <libavcodec/avcodec.h>
 #include <libavformat/avformat.h>
 #include <libswresample/swresample.h>
 }
 #include "logging.h"
 #include "readFuncs.h"
 #include "riffTypes.h"
 #include "types.h"
 #include <functional>
 #include <list>
 LOG_DEFINE_MODULE(libSceNgs2);
 namespace {
 std::pair<AVSampleFormat, uint8_t> convFormat(SceNgs2WaveFormType type) {
  switch (type) {
    case SceNgs2WaveFormType::PCM_U8: return {AVSampleFormat::AV_SAMPLE_FMT_U8, 1};
    case SceNgs2WaveFormType::PCM_I16LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_S16, 2};
    case SceNgs2WaveFormType::PCM_I16BIG: return {AVSampleFormat::AV_SAMPLE_FMT_S16, 2};
    case SceNgs2WaveFormType::PCM_I24LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_NONE, 3};
    case SceNgs2WaveFormType::PCM_I24BIG: return {AVSampleFormat::AV_SAMPLE_FMT_NONE, 3};
    case SceNgs2WaveFormType::PCM_I32LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_S32, 4};
    case SceNgs2WaveFormType::PCM_I32BIG: return {AVSampleFormat::AV_SAMPLE_FMT_S32, 4};
    case SceNgs2WaveFormType::PCM_F32LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_FLT, 4};
    case SceNgs2WaveFormType::PCM_F32BIG: return {AVSampleFormat::AV_SAMPLE_FMT_FLT, 4};
    case SceNgs2WaveFormType::PCM_F64LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_DBL, 8};
    case SceNgs2WaveFormType::PCM_F64BIG: return {AVSampleFormat::AV_SAMPLE_FMT_DBL, 8};
    case SceNgs2WaveFormType::VAG: return {AVSampleFormat::AV_SAMPLE_FMT_FLT, 4};
    case SceNgs2WaveFormType::ATRAC9: return {AVSampleFormat::AV_SAMPLE_FMT_FLT, 4};
    default: break;
  }
  return {AVSampleFormat::AV_SAMPLE_FMT_NONE, 0};
 }
 std::pair<AVSampleFormat, uint8_t> convFormatPlanar(SceNgs2WaveFormType type) {
  switch (type) {
    case SceNgs2WaveFormType::PCM_U8: return {AVSampleFormat::AV_SAMPLE_FMT_U8P, 1};
    case SceNgs2WaveFormType::PCM_I16LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_S16P, 2};
    case SceNgs2WaveFormType::PCM_I16BIG: return {AVSampleFormat::AV_SAMPLE_FMT_S16P, 2};
    case SceNgs2WaveFormType::PCM_I24LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_NONE, 3};
    case SceNgs2WaveFormType::PCM_I24BIG: return {AVSampleFormat::AV_SAMPLE_FMT_NONE, 3};
    case SceNgs2WaveFormType::PCM_I32LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_S32P, 4};
    case SceNgs2WaveFormType::PCM_I32BIG: return {AVSampleFormat::AV_SAMPLE_FMT_S32P, 4};
    case SceNgs2WaveFormType::PCM_F32LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_FLTP, 4};
    case SceNgs2WaveFormType::PCM_F32BIG: return {AVSampleFormat::AV_SAMPLE_FMT_FLTP, 4};
    case SceNgs2WaveFormType::PCM_F64LITTLE: return {AVSampleFormat::AV_SAMPLE_FMT_DBLP, 8};
    case SceNgs2WaveFormType::PCM_F64BIG: return {AVSampleFormat::AV_SAMPLE_FMT_DBLP, 8};
    case SceNgs2WaveFormType::VAG: return {AVSampleFormat::AV_SAMPLE_FMT_FLTP, 4};
    case SceNgs2WaveFormType::ATRAC9: return {AVSampleFormat::AV_SAMPLE_FMT_FLTP, 4};
    default: break;
  }
  return {AVSampleFormat::AV_SAMPLE_FMT_NONE, 0};
 }
 constexpr bool operator==(AVChannelLayout const& rhs, AVChannelLayout const& lhs) {
  return rhs.nb_channels == lhs.nb_channels && rhs.u.mask == lhs.u.mask;
 }
 constexpr bool operator!=(AVChannelLayout const& rhs, AVChannelLayout const& lhs) {
  return !(rhs == lhs);
 }
 struct PImpl {
  std::list<std::function<void(void)>> cleanup;
  uint8_t const*       data = nullptr;
  SceNgs2WaveformBlock block;
  uint32_t curOffset = 0;
  userData_inerBuffer userData   = {};
  AVFormatContext*    fmtctx     = nullptr;
  AVStream*           astream    = nullptr;
  AVCodec const*      codec      = nullptr;
  int                 stream_idx = 0;
  AVCodecContext* codecContext = nullptr;
  AVFrame*  frame     = nullptr;
  AVPacket* packet    = nullptr;
  bool      newPacket = true;
  SwrContext* swrCtx = nullptr;
  AVChannelLayout curChannelLayoutIn;
  AVChannelLayout curChannelLayoutOut;
 };
 } // namespace
 Reader::Reader(SceNgs2Handle_voice* voice): voice(voice) {
  m_pimpl = std::make_unique<PImpl>().release();
 }
 Reader::~Reader() {
  delete (PImpl*)m_pimpl;
 }
 bool Reader::init(SceNgs2SamplerVoiceWaveformBlocksParam const* param) {
  LOG_USE_MODULE(libSceNgs2);
  auto pimpl = (PImpl*)m_pimpl;
  if (param->data == nullptr) {
    // Reset
    voice->state.bits.Empty = true;
    return true;
  }
  m_isInit = false;
  pimpl->data      = (uint8_t const*)param->data;
  pimpl->block     = param->aBlock[0];
  pimpl->curOffset = 0;
  // m_state.numDecodedSamples = 0;
  // m_state.decodedDataSize   = 0;
  if (voice->info.type != SceNgs2WaveFormType::ATRAC9 && voice->info.type != SceNgs2WaveFormType::VAG) {
    m_isCompressed = false;
    m_isInit       = true;
    voice->state.bits.Empty = false;
    return true;
  }
  return false;
  // Check if riff or uncompressed
  auto riffHeader = (RiffWaveHeader const*)param->data;
  if (memcmp(riffHeader->chunkID, "RIFF", 4) != 0 || memcmp(riffHeader->riffType, "WAVE", 4) != 0) {
    m_isCompressed = false;
    return true;
  }
  // parse riff
  m_isCompressed = true;
  auto cleanup  = &pimpl->cleanup;
  auto userData = &pimpl->userData;
  userData->ptr       = param->data;
  userData->size      = param->aBlock[0].offset + param->aBlock[0].size;
  userData->curOffset = 0;
  pimpl->newPacket = true;
  // Init Setup
  auto aBufferIo = (uint8_t*)av_malloc(4096 + AV_INPUT_BUFFER_PADDING_SIZE);
  AVIOContext* avioctx = avio_alloc_context(aBufferIo, 4096, 0, userData, readFunc_linearBuffer, nullptr, seekFunc_linearBuffer);
  cleanup->emplace_back([&] { av_free(avioctx); });
  cleanup->emplace_back([&] { av_free(aBufferIo); });
  // Open the input
  pimpl->fmtctx = avformat_alloc_context();
  // pimpl->fmtctx->pb = avioctx;
  // pimpl->fmtctx->flags |= AVFMT_FLAG_CUSTOM_IO;
  int ret = avformat_open_input(&pimpl->fmtctx, "F:/down2/atrac9mem/snd0.at9", nullptr, nullptr);
  if (ret != 0) {
    LOG_ERR(L"Reader: ffmpeg failed to read passed data: %d", ret);
    return false;
  }
  cleanup->emplace_back([&] { avformat_close_input(&pimpl->fmtctx); });
  if (int res = avformat_find_stream_info(pimpl->fmtctx, NULL) < 0; res < 0) {
    LOG_ERR(L"avformat_find_stream_info result:%d", res);
    return false;
  }
  for (auto i = 0; i < pimpl->fmtctx->nb_streams; ++i) {
    if (pimpl->fmtctx->streams[i]->codecpar->codec_type == AVMediaType::AVMEDIA_TYPE_AUDIO) {
      pimpl->astream    = pimpl->fmtctx->streams[i];
      pimpl->stream_idx = i;
      break;
    }
  }
  pimpl->codec = avcodec_find_decoder(pimpl->astream->codecpar->codec_id);
  pimpl->codecContext = avcodec_alloc_context3(pimpl->codec);
  if (auto err = avcodec_parameters_to_context(pimpl->codecContext, pimpl->astream->codecpar); err != 0) {
    LOG_ERR(L"Reader: avcodec_parameters_to_context err:%d", err);
    return false;
  }
  cleanup->emplace_back([&] { avcodec_free_context(&pimpl->codecContext); });
  // Setup multithreading
  if (pimpl->codec->capabilities | AV_CODEC_CAP_FRAME_THREADS)
    pimpl->codecContext->thread_type = FF_THREAD_FRAME;
  else if (pimpl->codec->capabilities | AV_CODEC_CAP_SLICE_THREADS)
    pimpl->codecContext->thread_type = FF_THREAD_SLICE;
  else
    pimpl->codecContext->thread_count = 1; // don't use multithreading
  // -
  if (auto err = avcodec_open2(pimpl->codecContext, pimpl->codec, NULL); err < 0) {
    LOG_ERR(L"Reader: avcodec_open2 err:%d", err);
    return false;
  }
  pimpl->frame = av_frame_alloc();
  cleanup->emplace_back([&] { av_frame_free(&pimpl->frame); });
  pimpl->packet = av_packet_alloc();
  cleanup->emplace_back([&] { av_packet_free(&pimpl->packet); });
  m_isInit                = true;
  voice->state.bits.Empty = false;
  return true;
 }
 void Reader::setNewData(void const* start, void const* end) {
  LOG_USE_MODULE(libSceNgs2);
  auto pimpl = (PImpl*)m_pimpl;
  pimpl->curOffset  = 0;
  pimpl->data       = (uint8_t const*)start;
  pimpl->block.size = (uint64_t)end - (uint64_t)start;
  voice->state.bits.Empty = false;
 }
 bool Reader::getAudioUncompressed(SceNgs2RenderBufferInfo* rbi, uint32_t numOutSamples) {
  LOG_USE_MODULE(libSceNgs2);
  auto pimpl = (PImpl*)m_pimpl;
  auto const channelLayoutOut = convChannelLayout(rbi->channelsCount);
  auto const channelLayoutIn  = convChannelLayout(voice->info.channelsCount);
  if (pimpl->swrCtx == nullptr || channelLayoutOut != pimpl->curChannelLayoutOut || channelLayoutIn != pimpl->curChannelLayoutIn) {
    pimpl->curChannelLayoutOut = convChannelLayout(rbi->channelsCount);
    pimpl->curChannelLayoutIn  = convChannelLayout(voice->info.channelsCount);
    if (pimpl->curChannelLayoutOut.order == AV_CHANNEL_ORDER_UNSPEC || pimpl->curChannelLayoutIn.order == AV_CHANNEL_ORDER_UNSPEC) {
      return false;
    }
    auto const [formatOut, bytesOut] = convFormat(rbi->waveType);
    if (formatOut == AVSampleFormat::AV_SAMPLE_FMT_NONE) return false;
    auto const [formatIn, bytesIn] = convFormat(voice->info.type);
    if (formatIn == AVSampleFormat::AV_SAMPLE_FMT_NONE) return false;
    if (swr_alloc_set_opts2(&pimpl->swrCtx, &pimpl->curChannelLayoutOut, formatOut, voice->info.sampleRate, &pimpl->curChannelLayoutIn, formatIn,
                            voice->info.sampleRate, 0, NULL)) {
      LOG_ERR(L"Reader:Couldn't alloc swr");
      return false;
    }
    swr_init(pimpl->swrCtx);
    pimpl->cleanup.emplace_back([&] { swr_free(&pimpl->swrCtx); });
  }
  // Check repeat
  if (pimpl->block.size <= pimpl->curOffset) {
    if (pimpl->block.numRepeat > 0) {
      pimpl->curOffset = 0;
      --pimpl->block.numRepeat;
    } else {
      voice->state.data = 0;
      voice->state.bits.Empty = true;
      return false;
    }
  }
  // -
  uint32_t const readSize = std::min(rbi->bufferSize, (size_t)pimpl->block.size - pimpl->curOffset);
  auto const [formatIn, bytesIn]   = convFormat(voice->info.type);
  auto const [formatOut, bytesOut] = convFormat(rbi->waveType);
  std::vector<uint8_t*> audioBuffers(((int)rbi->channelsCount));
  auto const channelSizeOut = (uint32_t)rbi->channelsCount * bytesOut;
  for (uint8_t n = 0; n < audioBuffers.size(); ++n) {
    audioBuffers[n] = &((uint8_t*)rbi->bufferPtr)[0];
  }
  if (pimpl->block.numSamples > 0) {
    std::vector<uint8_t const*> audioBuffersIn(((int)voice->info.channelsCount));
    auto const channelSizeIn = (uint32_t)voice->info.channelsCount * bytesOut;
    for (uint8_t n = 0; n < audioBuffersIn.size(); ++n) {
      audioBuffersIn[n] = &((uint8_t*)pimpl->data)[0];
    }
    auto numSamples = swr_convert(pimpl->swrCtx, (uint8_t**)&rbi->bufferPtr, numOutSamples, &pimpl->data, pimpl->block.numSamples);
    pimpl->block.numSamples = 0;
  } else {
    auto numSamples = swr_convert(pimpl->swrCtx, (uint8_t**)&rbi->bufferPtr, numOutSamples, nullptr, 0);
    if (numSamples == 0) {
      m_state.numDecodedSamples += pimpl->block.numSamples;
      m_state.decodedDataSize += pimpl->block.size;
      voice->state.bits.Empty = true;
      pimpl->curOffset = pimpl->block.size;
      return false;
    }
  }
  return true;
 }
 bool Reader::getAudioCompressed(SceNgs2RenderBufferInfo* rbi) {
  LOG_USE_MODULE(libSceNgs2);
  auto pimpl = (PImpl*)m_pimpl;
  // if (pimpl->swrCtx == nullptr) {
  //   auto optDstChLayout = convChannelLayout(rbi->channelsCount);
  //   if (!optDstChLayout) {
  //     return false;
  //   }
  //   auto const [format, bytesOut] = convFormat(rbi->waveType);
  //   if (format == AVSampleFormat::AV_SAMPLE_FMT_NONE) return false;
  //   if (swr_alloc_set_opts2(&pimpl->swrCtx, &(*optDstChLayout), format, voice->info.sampleRate, &pimpl->codecContext->ch_layout,
  //                           pimpl->codecContext->sample_fmt, pimpl->codecContext->sample_rate, 0, NULL)) {
  //     LOG_ERR(L"Reader:Couldn't alloc swr");
  //     return false;
  //   }
  //   swr_init(pimpl->swrCtx);
  //   pimpl->cleanup.emplace_back([&] { swr_free(&pimpl->swrCtx); });
  // }
  // size_t offset = 0;
  // while (offset < rbi->bufferSize) {
  //   // Get a new packet
  //   if (pimpl->newPacket) {
  //     pimpl->packet->dts = AV_NOPTS_VALUE;
  //     pimpl->packet->pts = AV_NOPTS_VALUE;
  //     int state = av_read_frame(pimpl->fmtctx, pimpl->packet);
  //     if (state < 0) {
  //       if (state != AVERROR_EOF) {
  //         LOG_ERR(L"av_read_frame error %d", state);
  //       } else {
  //         voice->state.bits.Empty = true;
  //       }
  //       return false;
  //     }
  //     // Skip if not a audio packet
  //     if (pimpl->packet->stream_index != pimpl->stream_idx) {
  //       continue;
  //     }
  //     pimpl->newPacket = false;
  //   }
  //   // -
  //   // Process packet
  //   if (int ret = avcodec_send_packet(pimpl->codecContext, pimpl->packet); ret < 0) {
  //     if (ret == AVERROR(EAGAIN)) {
  //       av_packet_unref(pimpl->packet);
  //       pimpl->newPacket = true;
  //       continue; // Get new frame
  //     } else if (ret == AVERROR_EOF) {
  //       voice->state.bits.Empty = true;
  //     } else {
  //       voice->state.bits.Error = true;
  //     }
  //     return false;
  //   }
  //   av_packet_unref(pimpl->packet);
  //   //- packet
  //   // Now the frames
  //   auto const retRecv = avcodec_receive_frame(pimpl->codecContext, pimpl->frame);
  //   int outNumSamples = swr_get_out_samples(pimpl->swrCtx, pimpl->frame->nb_samples);
  //   // todo get sample size, nb_channels is zero (fix)
  //   auto const [format, bytesOut] = convFormat(rbi->waveType);
  //   auto const channelSize        = (uint32_t)outNumSamples * av_get_bytes_per_sample(format);
  //   std::vector<uint8_t*> audioBuffers(((int)rbi->channelsCount));
  //   for (uint8_t n = 0; n < audioBuffers.size(); ++n) {
  //     audioBuffers[n] = &((uint8_t*)rbi->bufferPtr)[offset + n * channelSize];
  //   }
  //   for (int i = 0; i < rbi->bufferSize / 4; ++i) { // Filling the chanels with data
  //     // We should fill all the channels with available data, it seems.
  //     // The sound plays slightly quieter if we fill only two first channels.
  //     ((float*)rbi->bufferPtr)[offset + i] = ((float*)pimpl->frame->data[i % pimpl->frame->ch_layout.nb_channels])[i / (int)rbi->channelsCount];
  //   }
  //   // uint8_t*   audioBuffers[8] = {&((uint8_t*)rbi->bufferPtr)[offset], &((uint8_t*)rbi->bufferPtr)[offset],
  //   // &((uint8_t*)rbi->bufferPtr)[offset],&((uint8_t*)rbi->bufferPtr)[offset],&((uint8_t*)rbi->bufferPtr)[offset],&((uint8_t*)rbi->bufferPtr)[offset],};
  //   // if (outNumSamples = swr_convert(pimpl->swrCtx, audioBuffers.data(), outNumSamples, (uint8_t const**)pimpl->frame->extended_data,
  //   // pimpl->frame->nb_samples);
  //   //     outNumSamples < 0) {
  //   //   LOG_WARN(L"swr_convert");
  //   // }
  //   av_frame_unref(pimpl->frame);
  //   // -
  //   auto const bufferSize_ = (uint32_t)rbi->channelsCount * channelSize;
  //   // float* samples = (float*)(&((uint8_t*)rbi->bufferPtr)[offset]);
  //   // for (int i = 0; i < outNumSamples * (int)rbi->channelsCount; i++) {
  //   //   samples[i] *= 100000.0;
  //   // }
  //   offset += (uint32_t)rbi->channelsCount * channelSize;
  // }
  return true;
 }
 bool Reader::getAudio(SceNgs2RenderBufferInfo* rbi, uint32_t numOutSamples) {
  if (m_isInit == false || voice->state.bits.Empty || !voice->state.bits.Playing || (voice->state.bits.Playing && voice->state.bits.Paused)) {
    return true;
  }
  if (m_isCompressed) {
    return false; // getAudioCompressed(rbi);
  } else {
    return getAudioUncompressed(rbi, numOutSamples);
  }
  return true;
 }
--- a/modules/libSceNgs2/reader.h
+++ b/modules/libSceNgs2/reader.h
@ -0,0 +1,31 @@
 #pragma once
 #include "types.h"
 class Reader {
  void* m_pimpl;
  bool  m_isInit       = false;
  bool  m_isCompressed = false;
  SceNgs2Handle_voice* voice;
  SceNgs2SamplerVoiceState m_state;
  bool getAudioUncompressed(SceNgs2RenderBufferInfo*, uint32_t numOutSamples);
  bool getAudioCompressed(SceNgs2RenderBufferInfo*);
  public:
  Reader(SceNgs2Handle_voice* voice);
  ~Reader();
  bool init(SceNgs2SamplerVoiceWaveformBlocksParam const* param);
  bool getAudio(SceNgs2RenderBufferInfo*, uint32_t numOutSamples);
  void setNewData(void const* start, void const* end);
  void getState(SceNgs2SamplerVoiceState* state) const {
    *state            = m_state;
    state->voiceState = voice->state;
  }
 };
--- a/modules/libSceNgs2/riffTypes.h
+++ b/modules/libSceNgs2/riffTypes.h
@ -0,0 +1,24 @@
 #pragma once
 #include <stdint.h>
 struct RiffHeader {
  unsigned char chunkID[4]; // RIFF
  uint32_t      chunkSize;
 } __attribute__((packed));
 struct RiffWaveHeader {
  unsigned char chunkID[4]; // RIFF
  uint32_t      chunkSize;
  unsigned char riffType[4]; // WAVE
 } __attribute__((packed));
 struct RiffFormatHeader {
  unsigned char chunkID[4]; // RIFF
  uint32_t      chunkSize;
  uint16_t      audioFormat;
  uint16_t      numChannels;
  uint32_t      sampleRate;  // Sampling Frequency in Hz
  uint32_t      avgByteRate; // ~bytes per second
  uint16_t      frameSize;   // BlockAlign
  uint16_t      bitsPerSample;
 } __attribute__((packed));
--- a/modules/libSceNgs2/types.h
+++ b/modules/libSceNgs2/types.h
@ -1,6 +1,32 @@
 #pragma once
 #include "..\libSceCommonDialog\types.h"
 #include "codes.h"
 #include "utility/utility.h"
 #include <map>
 #include <memory>
 union SceNgs2VoiceStateFlags {
  uint32_t data;
  struct {
    bool Inuse   : 1 = false;
    bool Playing : 1 = false;
    bool Paused  : 1 = false;
    bool Stopped : 1 = false;
    bool Error   : 1 = false;
    bool Empty   : 1 = true;
  } bits;
 };
 enum class SceNgs2VoiceEvent : uint32_t {
  Play,
  Stop,
  Stop_imm,
  Kill,
  Pause,
  Resume,
 };
 enum class SceNgs2WaveFormType : uint32_t {
  NONE = 0,
@ -41,7 +67,8 @@ enum class SceNgs2ChannelsCount : uint32_t {
  INVALID = 0xFFFFFFFF
 };
-enum class SceNgs2VoiceParam : uint32_t {
+// Voice events
 enum class SceNgs2VoiceParam : uint16_t {
  SET_MATRIX_LEVELS = 1,
  SET_PORT_VOLUME,
  SET_PORT_MATRIX,
@ -51,6 +78,64 @@ enum class SceNgs2VoiceParam : uint32_t {
  SET_CALLBACK,
 };
 // Master events
 enum class SceNgs2MasteringParam : uint16_t {
  SETUP,
  SET_MATRIX,
  SET_LFE,
  SET_LIMITER,
  SET_GAIN,
  SET_OUTPUT,
  SET_PEAK_METER,
 };
 // sampler events
 enum class SceNgs2SamplerParam : uint16_t {
  SETUP,
  ADD_WAVEFORM_BLOCKS,
  REPLACE_WAVEFORM_ADDRESS,
  SET_WAVEFORM_FRAME_OFFSET,
  EXIT_LOOP,
  SET_PITCH,
  SET_ENVELOPE,
  SET_DISTORTION,
  SET_USER_FX,
  SET_PEAK_METER,
  SET_FILTER,
 };
 // Submixer events
 enum class SceNgs2SubmixerParam : uint16_t {
  SETUP,
  SET_ENVELOPE,
  SET_COMPRESSOR,
  SET_DISTORTION,
  SET_USER_FX,
  SET_PEAK_METER,
  SET_FILTER,
 };
 #pragma pack(push, 1)
 struct SceNgs2WaveformInfo {
  SceNgs2WaveFormType  type          = SceNgs2WaveFormType::NONE;
  SceNgs2ChannelsCount channelsCount = SceNgs2ChannelsCount::INVALID;
  uint32_t             sampleRate    = 0;
  uint32_t             configData;
  uint32_t             frameOffset;
  uint32_t             frameMargin;
 };
 class Reader;
 struct SceNgs2VoiceHandle {
  SceNgs2VoiceHandle()  = default;
  ~SceNgs2VoiceHandle() = default;
  SceNgs2VoiceStateFlags state = {0};
  Reader* reader = nullptr;
 };
 struct SceNgs2ContextBufferInfo {
  void*     hostBuffer;
  size_t    hostBufferSize;
@ -59,8 +144,8 @@ struct SceNgs2ContextBufferInfo {
 };
 struct SceNgs2BufferAllocator {
-  int32_t SYSV_ABI (*allocHandler)(SceNgs2ContextBufferInfo*);
+  int32_t SYSV_ABI (*allocHandler)(SceNgs2ContextBufferInfo*) = nullptr;
-  int32_t SYSV_ABI (*freeHandler)(SceNgs2ContextBufferInfo*);
+  int32_t SYSV_ABI (*freeHandler)(SceNgs2ContextBufferInfo*)  = nullptr;
  void*   userData;
 };
@ -105,30 +190,85 @@ struct SceNgs2SystemInfo {
  uint32_t                 numGrainSamples;
 };
-struct SceNgs2SystemHandle {
+struct SceNgs2RackOption {
-  SceNgs2SystemInfo info;
+  size_t size = sizeof(SceNgs2RackOption);
  char     name[SCE_NGS2_RACK_NAME_LENGTH] = "\0";
  uint32_t flags;
  uint32_t maxGrainSamples     = 1;
  uint32_t maxVoices           = 1;
  uint32_t maxInputDelayBlocks = 1;
  uint32_t maxMatrices         = 1;
  uint32_t maxPorts            = 1;
  uint32_t aReserved[20];
 };
-struct SceNgs2RackHandle {
+struct SceNgs2VoiceState {
-  SceNgs2RackInfo info;
+  uint32_t stateFlags = 0;
  SceNgs2Handle*  voices;
 };
-struct SceNgs2VoiceHandle {
+enum class SceNgs2HandleType { System, Rack, Voice };
-  std::vector<AVPacket>* data;
+
-};
+struct SceNgs2Handle_rack;
 struct SceNgs2Handle {
-  SceNgs2Handle*           owner;
+  SceNgs2HandleType const type;
  bool                     allocSet;
  SceNgs2BufferAllocator   alloc;
  SceNgs2ContextBufferInfo cbi;
-  union _ngsTypes {
+  SceNgs2Handle(SceNgs2HandleType type): type(type) {}
-    SceNgs2SystemHandle sys;
+
-    SceNgs2RackHandle   rack;
+  virtual ~SceNgs2Handle() = default;
-    SceNgs2VoiceHandle  voice;
+};
-  } un;
+
 struct SceNgs2Handle_system: public SceNgs2Handle {
  SceNgs2BufferAllocator alloc;
  // Racks
  SceNgs2Handle_rack* mastering = nullptr;
  SceNgs2Handle_rack* sampler   = nullptr;
  SceNgs2Handle_rack* submixer  = nullptr;
  SceNgs2Handle_rack* reverb    = nullptr;
  SceNgs2Handle_rack* equalizer = nullptr;
  // -
  SceNgs2Handle_system(SceNgs2BufferAllocator const* alloc_): SceNgs2Handle(SceNgs2HandleType::System) {
    if (alloc_ != nullptr) alloc = *alloc_;
  }
  virtual ~SceNgs2Handle_system() = default;
 };
 struct SceNgs2Handle_voice: public SceNgs2Handle {
  SceNgs2Handle_rack* parent;
  SceNgs2VoiceStateFlags state {};
  SceNgs2WaveformInfo    info;
  Reader* reader = nullptr; // optional, depends on racktype
  SceNgs2Handle_voice(SceNgs2Handle_rack* parent): SceNgs2Handle(SceNgs2HandleType::Voice), parent(parent) {}
  virtual ~SceNgs2Handle_voice();
  void ev_KickEvent(SceNgs2VoiceEvent id);
 };
 struct SceNgs2Handle_rack: public SceNgs2Handle {
  uint32_t const rackId;
  SceNgs2Handle_system* parent;
  SceNgs2RackOption options;
  std::map<int, SceNgs2Handle_voice> voices; // address of SceNgs2Handle_voice must be valid !
  SceNgs2Handle_rack(SceNgs2Handle_system* parent, SceNgs2RackOption const* options_, uint32_t rackId)
      : SceNgs2Handle(SceNgs2HandleType::Rack), rackId(rackId), parent(parent) {
    if (options_ != nullptr) memcpy(&options, options_, sizeof(SceNgs2RackOption));
  }
  virtual ~SceNgs2Handle_rack() = default;
 };
 struct SceNgs2RenderBufferInfo {
@ -138,21 +278,12 @@ struct SceNgs2RenderBufferInfo {
  SceNgs2ChannelsCount channelsCount;
 };
 struct SceNgs2WaveformInfo {
  SceNgs2WaveFormType  type;
  SceNgs2ChannelsCount channelsCount;
  uint32_t             sampleRate;
  uint32_t             configData;
  uint32_t             frameOffset;
  uint32_t             frameMargin;
 };
 struct SceNgs2WaveformBlock {
  uint32_t offset;
  uint32_t size;
-  uint32_t : 32;
+  uint32_t numRepeat;
-  uint32_t : 32;
+  uint32_t skipSamples;
-  uint32_t : 32;
+  uint32_t numSamples;
  uint32_t : 32;
  uintptr_t userData;
 };
@ -166,10 +297,11 @@ struct SceNgs2WaveformFormat {
  uint32_t            samplesCount;
  uint32_t : 32;
  uint32_t : 32;
-  uint32_t : 32;
+  uint32_t dataPerFrame;
-  uint32_t : 32;
+  uint32_t frameSize;
-  uint32_t : 32;
+  uint32_t numframeSamples;
-  uint32_t : 32;
+  uint32_t samplesDelay;
  uint32_t             numBlocks;
  SceNgs2WaveformBlock block[4];
 };
@ -252,6 +384,33 @@ struct SceNgs2SamplerVoiceWaveformBlocksParam {
  const SceNgs2WaveformBlock* aBlock;
 };
 struct SceNgs2CustomSamplerVoiceWaveformAddressParam {
  SceNgs2VoiceParamHead header;
  const void*           pDataStart;
  const void*           pDataEnd;
 };
 struct SceNgs2SamplerVoiceSetupParam {
  SceNgs2VoiceParamHead header;
  SceNgs2WaveformInfo   format;
  uint32_t              flags;
  uint32_t              reserved;
 };
 struct SceNgs2SamplerVoiceState {
  SceNgs2VoiceStateFlags voiceState = {0};
  float       envelopeHeight = 0;
  float       peakHeight     = 0;
  uint32_t    reserved;
  uint64_t    numDecodedSamples = 0;
  uint64_t    decodedDataSize   = 0;
  uint64_t    userData          = 0;
  const void* waveformData      = 0;
  SceNgs2SamplerVoiceState() = default;
 };
 struct SceNgs2VoiceCallbackInfo {
  uintptr_t      callbackData;
  SceNgs2Handle* voiceHandle;
@ -280,22 +439,6 @@ struct SceNgs2VoiceCallbackParam {
  uint32_t                    reserved;
 };
 struct SceNgs2VoiceState {
  uint32_t stateFlags;
 };
 struct SceNgs2RackOption {
  size_t   size;
  char     name[SCE_NGS2_RACK_NAME_LENGTH];
  uint32_t flags;
  uint32_t maxGrainSamples;
  uint32_t maxVoices;
  uint32_t maxInputDelayBlocks;
  uint32_t maxMatrices;
  uint32_t maxPorts;
  uint32_t aReserved[20];
 };
 struct SceNgs2CustomModuleInfo {
  uint32_t moduleId;
  uint32_t sourceBufferId;
@ -332,3 +475,5 @@ struct SceNgs2PanParam {
  float fbwLevel;
  float lfeLevel;
 };
 #pragma pack(pop)
--- a/modules/libSceNpParty/entry.cpp
+++ b/modules/libSceNpParty/entry.cpp
@ -17,7 +17,7 @@ EXPORT SYSV_ABI int32_t sceNpPartyInitialize() {
 EXPORT SYSV_ABI int32_t sceNpPartyCheckCallback() {
  LOG_USE_MODULE(libSceNpParty);
-  LOG_ERR(L"todo %S", __FUNCTION__);
+  LOG_TRACE(L"todo %S", __FUNCTION__);
  return Ok;
 }
--- a/modules/libScePlayGo/entry.cpp
+++ b/modules/libScePlayGo/entry.cpp
@ -87,6 +87,7 @@ EXPORT SYSV_ABI int32_t scePlayGoSetInstallSpeed(ScePlayGoHandle handle, ScePlay
 EXPORT SYSV_ABI int32_t scePlayGoGetInstallSpeed(ScePlayGoHandle handle, ScePlayGoInstallSpeed* speed) {
  LOG_USE_MODULE(libScePlayGo);
  LOG_ERR(L"TODO: %S", __FUNCTION__);
  *speed = 2;
  return Ok;
 }
--- a/modules/libScePosix/entry.cpp
+++ b/modules/libScePosix/entry.cpp
@ -40,6 +40,14 @@ EXPORT SYSV_ABI int __NID(sem_post)(boost::interprocess::interprocess_semaphore*
  return Ok;
 }
 EXPORT SYSV_ABI int __NID(sem_getvalue)(boost::interprocess::interprocess_semaphore** sem) {
  if (sem == nullptr || *sem == nullptr) {
    return POSIX_SET(ErrCode::_ESRCH);
  }
  return (*sem)->get_count();
  return Ok;
 }
 EXPORT SYSV_ABI int __NID(sem_reltimedwait_np)(boost::interprocess::interprocess_semaphore** sem, SceKernelTimespec* reltime) {
  auto now     = boost::posix_time::microsec_clock::universal_time();
  auto timeout = boost::posix_time::seconds(reltime->tv_sec) + boost::posix_time::microsec(reltime->tv_nsec / 1000);
--- a/modules/libkernel/entry.cpp
+++ b/modules/libkernel/entry.cpp
@ -62,7 +62,7 @@ EXPORT SYSV_ABI void __NID(__stack_chk_fail)() {
 EXPORT SYSV_ABI void __NID(_exit)(int code) {
  LOG_USE_MODULE(libkernel);
-  LOG_INFO(L"exit code:%d", code);
+  LOG_ERR(L"exit code:%d", code);
  ::exit(code);
 }