public static DataQueue NewDataQueue(size_t _packetlen, size_t initialslack)
{
DataQueue queue = new DataQueue();
size_t packetlen = _packetlen > 0 ? _packetlen : 1024;
size_t wantpackets = (initialslack + (packetlen - 1)) / packetlen;
queue.packet_size = packetlen;
for (size_t i = 0; i < wantpackets; i++)
{
DataQueuePacket packet = new DataQueuePacket((int)packetlen);
// don't care if this fails, we'll deal later.
if (packet.data != null)
{
packet.datalen = 0;
packet.startpos = 0;
packet.next = queue.pool;
queue.pool = packet;
}
}
return(queue);
}
public void Close()
{
if (!Initialized)
{
return;
}
_shutdown = true;
_enabled = false;
if (_thread != null)
{
_thread.Join();
_thread = null;
}
if (_workbuf != null)
{
Marshal.FreeHGlobal((IntPtr)_workbuf);
_workbuf = null;
}
DataQueuePacket.FreeDataQueue(_queue);
CloseDevice();
}
static void FreeDataQueueList(DataQueuePacket packet)
{
while (packet != null)
{
packet.Dispose();
packet = packet.next;
}
}
public void ClearQueuedAudio()
{
if (!Initialized)
{
return;// nothing to do.
}
// Blank out the device and release the mutex. Free it afterwards.
lock (_lock)
{
// Keep up to two packets in the pool to reduce future malloc pressure.
DataQueuePacket.ClearDataQueue(_queue, SDL_AUDIOBUFFERQUEUE_PACKETLEN * 2);
}
}
public static void ClearDataQueue(DataQueue queue, size_t slack)
{
size_t packet_size = queue != null ? queue.packet_size : 1;
size_t slackpackets = (slack + (packet_size - 1)) / packet_size;
DataQueuePacket packet;
DataQueuePacket prev = null;
if (queue == null)
{
return;
}
packet = queue.head;
// merge the available pool and the current queue into one list.
if (packet != null)
{
queue.tail.next = queue.pool;
}
else
{
packet = queue.pool;
}
// Remove the queued packets from the device.
queue.tail = null;
queue.head = null;
queue.queued_bytes = 0;
queue.pool = packet;
// Optionally keep some slack in the pool to reduce malloc pressure.
for (size_t i = 0; packet != null && i < slackpackets; i++)
{
prev = packet;
packet = packet.next;
}
if (prev != null)
{
prev.next = null;
}
else
{
queue.pool = null;
}
FreeDataQueueList(packet);// free extra packets
}
void BufferQueueDrainCallback(byte *stream, size_t len)
{
// this function always holds the mixer lock before being called.
size_t dequeued;
Debug.Assert(Initialized);// this shouldn't ever happen, right?!
dequeued = DataQueuePacket.ReadFromDataQueue(_queue, stream, len);
stream += dequeued;
len -= dequeued;
if (len > 0)// fill any remaining space in the stream with silence.
{
Debug.Assert(DataQueuePacket.CountDataQueue(_queue) == 0);
Native.SetMemory(stream, _waveFormat.Silence, len);
}
}
int QueueAudio(void *data, size_t len)
{
if (!Initialized)
{
Debug.WriteLine("XAudio2 not initialized yet...");
return(-1);
}
if (len > 0)
{
lock (_lock)
{
return(DataQueuePacket.WriteToDataQueue(_queue, data, len));
}
}
return(0);
}
/*
* 这个samples是指样本帧中音频缓存区的大小。
* 样本帧是一块音频数据,其大小指定为 format * channels
* 其中format指的是每个样本的位数,这里使用WAVE_FORMAT_IEEE_FLOAT即4字节(32位)浮点型。
* 在PCM中format等同于sampleSize
*
* @see: https://my.oschina.net/u/4365632/blog/3319770
* https://wiki.libsdl.org/SDL_AudioSpec#Remarks
*/
public int Initialize(Xstream f, int samples)
{
_window = f;
_samples = samples;
_shutdown = false;// just in case.
_paused = true;
_enabled = true;
try
{
OpenDevice();
// pool a few packets to start. Enough for two callbacks.
_queue = DataQueuePacket.NewDataQueue(SDL_AUDIOBUFFERQUEUE_PACKETLEN, (size_t)(_bufferSize * 2));
// Allocate a scratch audio buffer
_worklen = _bufferSize;
_workbuf = (byte *)Marshal.AllocHGlobal(_worklen);
_thread = new Thread(RunAudio);
// The audio mixing is always a high priority thread
_thread.Priority = ThreadPriority.Highest;
// Start the audio thread
_thread.Start();
}
catch (Exception e)
{
Debug.WriteLine($"Failed to open audio: {e.Message}");
Close();
return(1);
}
Pause(0);// start audio playing.
return(0);
}
static DataQueuePacket AllocateDataQueuePacket(DataQueue queue)
{
DataQueuePacket packet;
Debug.Assert(queue != null);
packet = queue.pool;
if (packet != null)
{
// we have one available in the pool.
queue.pool = packet.next;
}
else
{
// Have to allocate a new one!
packet = new DataQueuePacket((int)queue.packet_size);
if (packet.data == null)
{
return(null);
}
}
packet.datalen = 0;
packet.startpos = 0;
packet.next = null;
Debug.Assert((queue.head != null) == (queue.queued_bytes != 0));
if (queue.tail == null)
{
queue.head = packet;
}
else
{
queue.tail.next = packet;
}
queue.tail = packet;
return(packet);
}
public static int WriteToDataQueue(DataQueue queue, void *_data, size_t _len)
{
/*
* 有些变量看似是多余的,这里参考以下几点,请慎重考虑后再作修改!
*
* 1.访问静态变量和实例变量将会比访问局部变量多耗费2-3个时钟周期。
* 2.修改参数通常会使代码的可读性更差,并且可能需要更多的时间来了解函数中实际发生的事情。
* 因此,通常不建议修改参数。将此优化留给编译器。
*/
size_t len = _len;
byte * data = (byte *)_data;
size_t packet_size = queue != null ? queue.packet_size : 0;
DataQueuePacket orighead;
DataQueuePacket origtail;
size_t origlen;
size_t datalen;
if (queue == null)
{
// 连queue都没了,错误没地方存,根本无法返回HResult,还不如直接throw
throw new InvalidParameterException("queue");
}
orighead = queue.head;
origtail = queue.tail;
origlen = origtail != null ? origtail.datalen : 0;
while (len > 0)
{
DataQueuePacket packet = queue.tail;
Debug.Assert(packet == null || packet.datalen <= queue.packet_size);
if (packet == null || packet.datalen >= queue.packet_size)
{
// tail packet missing or completely full; we need a new packet.
packet = AllocateDataQueuePacket(queue);
if (packet.data == null)
{
OutOfMemoryException err = packet.err;
// uhoh, reset so we've queued nothing new, free what we can.
if (origtail == null)
{
packet = queue.head;// whole queue.
}
else
{
packet = origtail.next;// what we added to existing queue.
origtail.next = null;
origtail.datalen = origlen;
}
queue.head = orighead;
queue.tail = origtail;
queue.pool = null;
FreeDataQueueList(packet);// give back what we can.
return(err.HResult);
}
}
datalen = Math.Min(len, packet_size - packet.datalen);
Native.CopyMemory(packet.data + packet.datalen, data, datalen);
data += datalen;
len -= datalen;
packet.datalen += datalen;
queue.queued_bytes += datalen;
}
return(0);
}
