Sweden-Number/dlls/winepulse.drv/pulse.c

1984 lines
60 KiB
C

/*
* Copyright 2011-2012 Maarten Lankhorst
* Copyright 2010-2011 Maarten Lankhorst for CodeWeavers
* Copyright 2011 Andrew Eikum for CodeWeavers
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
*/
#if 0
#pragma makedep unix
#endif
#define _NTSYSTEM_
#include <stdarg.h>
#include <pthread.h>
#include <math.h>
#include <poll.h>
#include <pulse/pulseaudio.h>
#include "ntstatus.h"
#define WIN32_NO_STATUS
#include "winternl.h"
#include "mmdeviceapi.h"
#include "initguid.h"
#include "audioclient.h"
#include "unixlib.h"
#include "wine/debug.h"
WINE_DEFAULT_DEBUG_CHANNEL(pulse);
struct pulse_stream
{
EDataFlow dataflow;
pa_stream *stream;
pa_sample_spec ss;
pa_channel_map map;
pa_buffer_attr attr;
DWORD flags;
AUDCLNT_SHAREMODE share;
HANDLE event;
float vol[PA_CHANNELS_MAX];
BOOL mute;
INT32 locked;
BOOL started;
SIZE_T bufsize_frames, alloc_size, real_bufsize_bytes, period_bytes;
SIZE_T peek_ofs, read_offs_bytes, lcl_offs_bytes, pa_offs_bytes;
SIZE_T tmp_buffer_bytes, held_bytes, peek_len, peek_buffer_len, pa_held_bytes;
BYTE *local_buffer, *tmp_buffer, *peek_buffer;
void *locked_ptr;
BOOL please_quit, just_started, just_underran;
pa_usec_t last_time, mmdev_period_usec;
INT64 clock_lastpos, clock_written;
struct list packet_free_head;
struct list packet_filled_head;
};
typedef struct _ACPacket
{
struct list entry;
UINT64 qpcpos;
BYTE *data;
UINT32 discont;
} ACPacket;
static pa_context *pulse_ctx;
static pa_mainloop *pulse_ml;
/* Mixer format + period times */
static WAVEFORMATEXTENSIBLE pulse_fmt[2];
static REFERENCE_TIME pulse_min_period[2], pulse_def_period[2];
static UINT g_phys_speakers_mask = 0;
static const REFERENCE_TIME MinimumPeriod = 30000;
static const REFERENCE_TIME DefaultPeriod = 100000;
static pthread_mutex_t pulse_mutex;
static pthread_cond_t pulse_cond = PTHREAD_COND_INITIALIZER;
UINT8 mult_alaw_sample(UINT8, float);
UINT8 mult_ulaw_sample(UINT8, float);
static void pulse_lock(void)
{
pthread_mutex_lock(&pulse_mutex);
}
static void pulse_unlock(void)
{
pthread_mutex_unlock(&pulse_mutex);
}
static int pulse_cond_wait(void)
{
return pthread_cond_wait(&pulse_cond, &pulse_mutex);
}
static void pulse_broadcast(void)
{
pthread_cond_broadcast(&pulse_cond);
}
static void dump_attr(const pa_buffer_attr *attr)
{
TRACE("maxlength: %u\n", attr->maxlength);
TRACE("minreq: %u\n", attr->minreq);
TRACE("fragsize: %u\n", attr->fragsize);
TRACE("tlength: %u\n", attr->tlength);
TRACE("prebuf: %u\n", attr->prebuf);
}
/* copied from kernelbase */
static int muldiv(int a, int b, int c)
{
LONGLONG ret;
if (!c) return -1;
/* We want to deal with a positive divisor to simplify the logic. */
if (c < 0)
{
a = -a;
c = -c;
}
/* If the result is positive, we "add" to round. else, we subtract to round. */
if ((a < 0 && b < 0) || (a >= 0 && b >= 0))
ret = (((LONGLONG)a * b) + (c / 2)) / c;
else
ret = (((LONGLONG)a * b) - (c / 2)) / c;
if (ret > 2147483647 || ret < -2147483647) return -1;
return ret;
}
/* Following pulseaudio design here, mainloop has the lock taken whenever
* it is handling something for pulse, and the lock is required whenever
* doing any pa_* call that can affect the state in any way
*
* pa_cond_wait is used when waiting on results, because the mainloop needs
* the same lock taken to affect the state
*
* This is basically the same as the pa_threaded_mainloop implementation,
* but that cannot be used because it uses pthread_create directly
*
* pa_threaded_mainloop_(un)lock -> pthread_mutex_(un)lock
* pa_threaded_mainloop_signal -> pthread_cond_broadcast
* pa_threaded_mainloop_wait -> pthread_cond_wait
*/
static int pulse_poll_func(struct pollfd *ufds, unsigned long nfds, int timeout, void *userdata)
{
int r;
pulse_unlock();
r = poll(ufds, nfds, timeout);
pulse_lock();
return r;
}
static NTSTATUS pulse_process_attach(void *args)
{
pthread_mutexattr_t attr;
pthread_mutexattr_init(&attr);
pthread_mutexattr_setprotocol(&attr, PTHREAD_PRIO_INHERIT);
if (pthread_mutex_init(&pulse_mutex, &attr) != 0)
pthread_mutex_init(&pulse_mutex, NULL);
return STATUS_SUCCESS;
}
static NTSTATUS pulse_process_detach(void *args)
{
if (pulse_ctx)
{
pa_context_disconnect(pulse_ctx);
pa_context_unref(pulse_ctx);
}
if (pulse_ml)
pa_mainloop_quit(pulse_ml, 0);
return STATUS_SUCCESS;
}
static NTSTATUS pulse_main_loop(void *args)
{
struct main_loop_params *params = args;
int ret;
pulse_lock();
pulse_ml = pa_mainloop_new();
pa_mainloop_set_poll_func(pulse_ml, pulse_poll_func, NULL);
NtSetEvent(params->event, NULL);
pa_mainloop_run(pulse_ml, &ret);
pa_mainloop_free(pulse_ml);
pulse_unlock();
return STATUS_SUCCESS;
}
static void pulse_contextcallback(pa_context *c, void *userdata)
{
switch (pa_context_get_state(c)) {
default:
FIXME("Unhandled state: %i\n", pa_context_get_state(c));
return;
case PA_CONTEXT_CONNECTING:
case PA_CONTEXT_UNCONNECTED:
case PA_CONTEXT_AUTHORIZING:
case PA_CONTEXT_SETTING_NAME:
case PA_CONTEXT_TERMINATED:
TRACE("State change to %i\n", pa_context_get_state(c));
return;
case PA_CONTEXT_READY:
TRACE("Ready\n");
break;
case PA_CONTEXT_FAILED:
WARN("Context failed: %s\n", pa_strerror(pa_context_errno(c)));
break;
}
pulse_broadcast();
}
static void pulse_stream_state(pa_stream *s, void *user)
{
pa_stream_state_t state = pa_stream_get_state(s);
TRACE("Stream state changed to %i\n", state);
pulse_broadcast();
}
static void pulse_attr_update(pa_stream *s, void *user) {
const pa_buffer_attr *attr = pa_stream_get_buffer_attr(s);
TRACE("New attributes or device moved:\n");
dump_attr(attr);
}
static void pulse_underflow_callback(pa_stream *s, void *userdata)
{
struct pulse_stream *stream = userdata;
WARN("%p: Underflow\n", userdata);
stream->just_underran = TRUE;
/* re-sync */
stream->pa_offs_bytes = stream->lcl_offs_bytes;
stream->pa_held_bytes = stream->held_bytes;
}
static void pulse_started_callback(pa_stream *s, void *userdata)
{
TRACE("%p: (Re)started playing\n", userdata);
}
static void pulse_op_cb(pa_stream *s, int success, void *user)
{
TRACE("Success: %i\n", success);
*(int*)user = success;
pulse_broadcast();
}
static void silence_buffer(pa_sample_format_t format, BYTE *buffer, UINT32 bytes)
{
memset(buffer, format == PA_SAMPLE_U8 ? 0x80 : 0, bytes);
}
static BOOL pulse_stream_valid(struct pulse_stream *stream)
{
return pa_stream_get_state(stream->stream) == PA_STREAM_READY;
}
static HRESULT pulse_connect(const char *name)
{
if (pulse_ctx && PA_CONTEXT_IS_GOOD(pa_context_get_state(pulse_ctx)))
return S_OK;
if (pulse_ctx)
pa_context_unref(pulse_ctx);
pulse_ctx = pa_context_new(pa_mainloop_get_api(pulse_ml), name);
if (!pulse_ctx) {
ERR("Failed to create context\n");
return E_FAIL;
}
pa_context_set_state_callback(pulse_ctx, pulse_contextcallback, NULL);
TRACE("libpulse protocol version: %u. API Version %u\n", pa_context_get_protocol_version(pulse_ctx), PA_API_VERSION);
if (pa_context_connect(pulse_ctx, NULL, 0, NULL) < 0)
goto fail;
/* Wait for connection */
while (pulse_cond_wait()) {
pa_context_state_t state = pa_context_get_state(pulse_ctx);
if (state == PA_CONTEXT_FAILED || state == PA_CONTEXT_TERMINATED)
goto fail;
if (state == PA_CONTEXT_READY)
break;
}
TRACE("Connected to server %s with protocol version: %i.\n",
pa_context_get_server(pulse_ctx),
pa_context_get_server_protocol_version(pulse_ctx));
return S_OK;
fail:
pa_context_unref(pulse_ctx);
pulse_ctx = NULL;
return E_FAIL;
}
static DWORD pulse_channel_map_to_channel_mask(const pa_channel_map *map)
{
int i;
DWORD mask = 0;
for (i = 0; i < map->channels; ++i) {
switch (map->map[i]) {
default: FIXME("Unhandled channel %s\n", pa_channel_position_to_string(map->map[i])); break;
case PA_CHANNEL_POSITION_FRONT_LEFT: mask |= SPEAKER_FRONT_LEFT; break;
case PA_CHANNEL_POSITION_MONO:
case PA_CHANNEL_POSITION_FRONT_CENTER: mask |= SPEAKER_FRONT_CENTER; break;
case PA_CHANNEL_POSITION_FRONT_RIGHT: mask |= SPEAKER_FRONT_RIGHT; break;
case PA_CHANNEL_POSITION_REAR_LEFT: mask |= SPEAKER_BACK_LEFT; break;
case PA_CHANNEL_POSITION_REAR_CENTER: mask |= SPEAKER_BACK_CENTER; break;
case PA_CHANNEL_POSITION_REAR_RIGHT: mask |= SPEAKER_BACK_RIGHT; break;
case PA_CHANNEL_POSITION_LFE: mask |= SPEAKER_LOW_FREQUENCY; break;
case PA_CHANNEL_POSITION_SIDE_LEFT: mask |= SPEAKER_SIDE_LEFT; break;
case PA_CHANNEL_POSITION_SIDE_RIGHT: mask |= SPEAKER_SIDE_RIGHT; break;
case PA_CHANNEL_POSITION_TOP_CENTER: mask |= SPEAKER_TOP_CENTER; break;
case PA_CHANNEL_POSITION_TOP_FRONT_LEFT: mask |= SPEAKER_TOP_FRONT_LEFT; break;
case PA_CHANNEL_POSITION_TOP_FRONT_CENTER: mask |= SPEAKER_TOP_FRONT_CENTER; break;
case PA_CHANNEL_POSITION_TOP_FRONT_RIGHT: mask |= SPEAKER_TOP_FRONT_RIGHT; break;
case PA_CHANNEL_POSITION_TOP_REAR_LEFT: mask |= SPEAKER_TOP_BACK_LEFT; break;
case PA_CHANNEL_POSITION_TOP_REAR_CENTER: mask |= SPEAKER_TOP_BACK_CENTER; break;
case PA_CHANNEL_POSITION_TOP_REAR_RIGHT: mask |= SPEAKER_TOP_BACK_RIGHT; break;
case PA_CHANNEL_POSITION_FRONT_LEFT_OF_CENTER: mask |= SPEAKER_FRONT_LEFT_OF_CENTER; break;
case PA_CHANNEL_POSITION_FRONT_RIGHT_OF_CENTER: mask |= SPEAKER_FRONT_RIGHT_OF_CENTER; break;
}
}
return mask;
}
/* For default PulseAudio render device, OR together all of the
* PKEY_AudioEndpoint_PhysicalSpeakers values of the sinks. */
static void pulse_phys_speakers_cb(pa_context *c, const pa_sink_info *i, int eol, void *userdata)
{
if (i)
g_phys_speakers_mask |= pulse_channel_map_to_channel_mask(&i->channel_map);
}
/* For most hardware on Windows, users must choose a configuration with an even
* number of channels (stereo, quad, 5.1, 7.1). Users can then disable
* channels, but those channels are still reported to applications from
* GetMixFormat! Some applications behave badly if given an odd number of
* channels (e.g. 2.1). Here, we find the nearest configuration that Windows
* would report for a given channel layout. */
static void convert_channel_map(const pa_channel_map *pa_map, WAVEFORMATEXTENSIBLE *fmt)
{
DWORD pa_mask = pulse_channel_map_to_channel_mask(pa_map);
TRACE("got mask for PA: 0x%x\n", pa_mask);
if (pa_map->channels == 1)
{
fmt->Format.nChannels = 1;
fmt->dwChannelMask = pa_mask;
return;
}
/* compare against known configurations and find smallest configuration
* which is a superset of the given speakers */
if (pa_map->channels <= 2 &&
(pa_mask & ~KSAUDIO_SPEAKER_STEREO) == 0)
{
fmt->Format.nChannels = 2;
fmt->dwChannelMask = KSAUDIO_SPEAKER_STEREO;
return;
}
if (pa_map->channels <= 4 &&
(pa_mask & ~KSAUDIO_SPEAKER_QUAD) == 0)
{
fmt->Format.nChannels = 4;
fmt->dwChannelMask = KSAUDIO_SPEAKER_QUAD;
return;
}
if (pa_map->channels <= 4 &&
(pa_mask & ~KSAUDIO_SPEAKER_SURROUND) == 0)
{
fmt->Format.nChannels = 4;
fmt->dwChannelMask = KSAUDIO_SPEAKER_SURROUND;
return;
}
if (pa_map->channels <= 6 &&
(pa_mask & ~KSAUDIO_SPEAKER_5POINT1) == 0)
{
fmt->Format.nChannels = 6;
fmt->dwChannelMask = KSAUDIO_SPEAKER_5POINT1;
return;
}
if (pa_map->channels <= 6 &&
(pa_mask & ~KSAUDIO_SPEAKER_5POINT1_SURROUND) == 0)
{
fmt->Format.nChannels = 6;
fmt->dwChannelMask = KSAUDIO_SPEAKER_5POINT1_SURROUND;
return;
}
if (pa_map->channels <= 8 &&
(pa_mask & ~KSAUDIO_SPEAKER_7POINT1) == 0)
{
fmt->Format.nChannels = 8;
fmt->dwChannelMask = KSAUDIO_SPEAKER_7POINT1;
return;
}
if (pa_map->channels <= 8 &&
(pa_mask & ~KSAUDIO_SPEAKER_7POINT1_SURROUND) == 0)
{
fmt->Format.nChannels = 8;
fmt->dwChannelMask = KSAUDIO_SPEAKER_7POINT1_SURROUND;
return;
}
/* oddball format, report truthfully */
fmt->Format.nChannels = pa_map->channels;
fmt->dwChannelMask = pa_mask;
}
static void pulse_probe_settings(int render, WAVEFORMATEXTENSIBLE *fmt) {
WAVEFORMATEX *wfx = &fmt->Format;
pa_stream *stream;
pa_channel_map map;
pa_sample_spec ss;
pa_buffer_attr attr;
int ret;
unsigned int length = 0;
pa_channel_map_init_auto(&map, 2, PA_CHANNEL_MAP_ALSA);
ss.rate = 48000;
ss.format = PA_SAMPLE_FLOAT32LE;
ss.channels = map.channels;
attr.maxlength = -1;
attr.tlength = -1;
attr.minreq = attr.fragsize = pa_frame_size(&ss);
attr.prebuf = 0;
stream = pa_stream_new(pulse_ctx, "format test stream", &ss, &map);
if (stream)
pa_stream_set_state_callback(stream, pulse_stream_state, NULL);
if (!stream)
ret = -1;
else if (render)
ret = pa_stream_connect_playback(stream, NULL, &attr,
PA_STREAM_START_CORKED|PA_STREAM_FIX_RATE|PA_STREAM_FIX_CHANNELS|PA_STREAM_EARLY_REQUESTS, NULL, NULL);
else
ret = pa_stream_connect_record(stream, NULL, &attr, PA_STREAM_START_CORKED|PA_STREAM_FIX_RATE|PA_STREAM_FIX_CHANNELS|PA_STREAM_EARLY_REQUESTS);
if (ret >= 0) {
while (pa_mainloop_iterate(pulse_ml, 1, &ret) >= 0 &&
pa_stream_get_state(stream) == PA_STREAM_CREATING)
{}
if (pa_stream_get_state(stream) == PA_STREAM_READY) {
ss = *pa_stream_get_sample_spec(stream);
map = *pa_stream_get_channel_map(stream);
if (render)
length = pa_stream_get_buffer_attr(stream)->minreq;
else
length = pa_stream_get_buffer_attr(stream)->fragsize;
pa_stream_disconnect(stream);
while (pa_mainloop_iterate(pulse_ml, 1, &ret) >= 0 &&
pa_stream_get_state(stream) == PA_STREAM_READY)
{}
}
}
if (stream)
pa_stream_unref(stream);
if (length)
pulse_def_period[!render] = pulse_min_period[!render] = pa_bytes_to_usec(10 * length, &ss);
if (pulse_min_period[!render] < MinimumPeriod)
pulse_min_period[!render] = MinimumPeriod;
if (pulse_def_period[!render] < DefaultPeriod)
pulse_def_period[!render] = DefaultPeriod;
wfx->wFormatTag = WAVE_FORMAT_EXTENSIBLE;
wfx->cbSize = sizeof(WAVEFORMATEXTENSIBLE) - sizeof(WAVEFORMATEX);
convert_channel_map(&map, fmt);
wfx->wBitsPerSample = 8 * pa_sample_size_of_format(ss.format);
wfx->nSamplesPerSec = ss.rate;
wfx->nBlockAlign = wfx->nChannels * wfx->wBitsPerSample / 8;
wfx->nAvgBytesPerSec = wfx->nSamplesPerSec * wfx->nBlockAlign;
if (ss.format != PA_SAMPLE_S24_32LE)
fmt->Samples.wValidBitsPerSample = wfx->wBitsPerSample;
else
fmt->Samples.wValidBitsPerSample = 24;
if (ss.format == PA_SAMPLE_FLOAT32LE)
fmt->SubFormat = KSDATAFORMAT_SUBTYPE_IEEE_FLOAT;
else
fmt->SubFormat = KSDATAFORMAT_SUBTYPE_PCM;
}
/* some poorly-behaved applications call audio functions during DllMain, so we
* have to do as much as possible without creating a new thread. this function
* sets up a synchronous connection to verify the server is running and query
* static data. */
static NTSTATUS pulse_test_connect(void *args)
{
struct test_connect_params *params = args;
struct pulse_config *config = params->config;
pa_operation *o;
int ret;
pulse_lock();
pulse_ml = pa_mainloop_new();
pa_mainloop_set_poll_func(pulse_ml, pulse_poll_func, NULL);
pulse_ctx = pa_context_new(pa_mainloop_get_api(pulse_ml), params->name);
if (!pulse_ctx) {
ERR("Failed to create context\n");
pa_mainloop_free(pulse_ml);
pulse_ml = NULL;
pulse_unlock();
params->result = E_FAIL;
return STATUS_SUCCESS;
}
pa_context_set_state_callback(pulse_ctx, pulse_contextcallback, NULL);
TRACE("libpulse protocol version: %u. API Version %u\n", pa_context_get_protocol_version(pulse_ctx), PA_API_VERSION);
if (pa_context_connect(pulse_ctx, NULL, 0, NULL) < 0)
goto fail;
/* Wait for connection */
while (pa_mainloop_iterate(pulse_ml, 1, &ret) >= 0) {
pa_context_state_t state = pa_context_get_state(pulse_ctx);
if (state == PA_CONTEXT_FAILED || state == PA_CONTEXT_TERMINATED)
goto fail;
if (state == PA_CONTEXT_READY)
break;
}
if (pa_context_get_state(pulse_ctx) != PA_CONTEXT_READY)
goto fail;
TRACE("Test-connected to server %s with protocol version: %i.\n",
pa_context_get_server(pulse_ctx),
pa_context_get_server_protocol_version(pulse_ctx));
pulse_probe_settings(1, &pulse_fmt[0]);
pulse_probe_settings(0, &pulse_fmt[1]);
g_phys_speakers_mask = 0;
o = pa_context_get_sink_info_list(pulse_ctx, &pulse_phys_speakers_cb, NULL);
if (o) {
while (pa_mainloop_iterate(pulse_ml, 1, &ret) >= 0 &&
pa_operation_get_state(o) == PA_OPERATION_RUNNING)
{}
pa_operation_unref(o);
}
pa_context_unref(pulse_ctx);
pulse_ctx = NULL;
pa_mainloop_free(pulse_ml);
pulse_ml = NULL;
config->speakers_mask = g_phys_speakers_mask;
config->modes[0].format = pulse_fmt[0];
config->modes[0].def_period = pulse_def_period[0];
config->modes[0].min_period = pulse_min_period[0];
config->modes[1].format = pulse_fmt[1];
config->modes[1].def_period = pulse_def_period[1];
config->modes[1].min_period = pulse_min_period[1];
pulse_unlock();
params->result = S_OK;
return STATUS_SUCCESS;
fail:
pa_context_unref(pulse_ctx);
pulse_ctx = NULL;
pa_mainloop_free(pulse_ml);
pulse_ml = NULL;
pulse_unlock();
params->result = E_FAIL;
return STATUS_SUCCESS;
}
static DWORD get_channel_mask(unsigned int channels)
{
switch(channels) {
case 0:
return 0;
case 1:
return KSAUDIO_SPEAKER_MONO;
case 2:
return KSAUDIO_SPEAKER_STEREO;
case 3:
return KSAUDIO_SPEAKER_STEREO | SPEAKER_LOW_FREQUENCY;
case 4:
return KSAUDIO_SPEAKER_QUAD; /* not _SURROUND */
case 5:
return KSAUDIO_SPEAKER_QUAD | SPEAKER_LOW_FREQUENCY;
case 6:
return KSAUDIO_SPEAKER_5POINT1; /* not 5POINT1_SURROUND */
case 7:
return KSAUDIO_SPEAKER_5POINT1 | SPEAKER_BACK_CENTER;
case 8:
return KSAUDIO_SPEAKER_7POINT1_SURROUND; /* Vista deprecates 7POINT1 */
}
FIXME("Unknown speaker configuration: %u\n", channels);
return 0;
}
static const enum pa_channel_position pulse_pos_from_wfx[] = {
PA_CHANNEL_POSITION_FRONT_LEFT,
PA_CHANNEL_POSITION_FRONT_RIGHT,
PA_CHANNEL_POSITION_FRONT_CENTER,
PA_CHANNEL_POSITION_LFE,
PA_CHANNEL_POSITION_REAR_LEFT,
PA_CHANNEL_POSITION_REAR_RIGHT,
PA_CHANNEL_POSITION_FRONT_LEFT_OF_CENTER,
PA_CHANNEL_POSITION_FRONT_RIGHT_OF_CENTER,
PA_CHANNEL_POSITION_REAR_CENTER,
PA_CHANNEL_POSITION_SIDE_LEFT,
PA_CHANNEL_POSITION_SIDE_RIGHT,
PA_CHANNEL_POSITION_TOP_CENTER,
PA_CHANNEL_POSITION_TOP_FRONT_LEFT,
PA_CHANNEL_POSITION_TOP_FRONT_CENTER,
PA_CHANNEL_POSITION_TOP_FRONT_RIGHT,
PA_CHANNEL_POSITION_TOP_REAR_LEFT,
PA_CHANNEL_POSITION_TOP_REAR_CENTER,
PA_CHANNEL_POSITION_TOP_REAR_RIGHT
};
static HRESULT pulse_spec_from_waveformat(struct pulse_stream *stream, const WAVEFORMATEX *fmt)
{
pa_channel_map_init(&stream->map);
stream->ss.rate = fmt->nSamplesPerSec;
stream->ss.format = PA_SAMPLE_INVALID;
switch(fmt->wFormatTag) {
case WAVE_FORMAT_IEEE_FLOAT:
if (!fmt->nChannels || fmt->nChannels > 2 || fmt->wBitsPerSample != 32)
break;
stream->ss.format = PA_SAMPLE_FLOAT32LE;
pa_channel_map_init_auto(&stream->map, fmt->nChannels, PA_CHANNEL_MAP_ALSA);
break;
case WAVE_FORMAT_PCM:
if (!fmt->nChannels || fmt->nChannels > 2)
break;
if (fmt->wBitsPerSample == 8)
stream->ss.format = PA_SAMPLE_U8;
else if (fmt->wBitsPerSample == 16)
stream->ss.format = PA_SAMPLE_S16LE;
else
return AUDCLNT_E_UNSUPPORTED_FORMAT;
pa_channel_map_init_auto(&stream->map, fmt->nChannels, PA_CHANNEL_MAP_ALSA);
break;
case WAVE_FORMAT_EXTENSIBLE: {
WAVEFORMATEXTENSIBLE *wfe = (WAVEFORMATEXTENSIBLE*)fmt;
DWORD mask = wfe->dwChannelMask;
DWORD i = 0, j;
if (fmt->cbSize != (sizeof(*wfe) - sizeof(*fmt)) && fmt->cbSize != sizeof(*wfe))
break;
if (IsEqualGUID(&wfe->SubFormat, &KSDATAFORMAT_SUBTYPE_IEEE_FLOAT) &&
(!wfe->Samples.wValidBitsPerSample || wfe->Samples.wValidBitsPerSample == 32) &&
fmt->wBitsPerSample == 32)
stream->ss.format = PA_SAMPLE_FLOAT32LE;
else if (IsEqualGUID(&wfe->SubFormat, &KSDATAFORMAT_SUBTYPE_PCM)) {
DWORD valid = wfe->Samples.wValidBitsPerSample;
if (!valid)
valid = fmt->wBitsPerSample;
if (!valid || valid > fmt->wBitsPerSample)
break;
switch (fmt->wBitsPerSample) {
case 8:
if (valid == 8)
stream->ss.format = PA_SAMPLE_U8;
break;
case 16:
if (valid == 16)
stream->ss.format = PA_SAMPLE_S16LE;
break;
case 24:
if (valid == 24)
stream->ss.format = PA_SAMPLE_S24LE;
break;
case 32:
if (valid == 24)
stream->ss.format = PA_SAMPLE_S24_32LE;
else if (valid == 32)
stream->ss.format = PA_SAMPLE_S32LE;
break;
default:
return AUDCLNT_E_UNSUPPORTED_FORMAT;
}
}
stream->map.channels = fmt->nChannels;
if (!mask || (mask & (SPEAKER_ALL|SPEAKER_RESERVED)))
mask = get_channel_mask(fmt->nChannels);
for (j = 0; j < ARRAY_SIZE(pulse_pos_from_wfx) && i < fmt->nChannels; ++j) {
if (mask & (1 << j))
stream->map.map[i++] = pulse_pos_from_wfx[j];
}
/* Special case for mono since pulse appears to map it differently */
if (mask == SPEAKER_FRONT_CENTER)
stream->map.map[0] = PA_CHANNEL_POSITION_MONO;
if (i < fmt->nChannels || (mask & SPEAKER_RESERVED)) {
stream->map.channels = 0;
ERR("Invalid channel mask: %i/%i and %x(%x)\n", i, fmt->nChannels, mask, wfe->dwChannelMask);
break;
}
break;
}
case WAVE_FORMAT_ALAW:
case WAVE_FORMAT_MULAW:
if (fmt->wBitsPerSample != 8) {
FIXME("Unsupported bpp %u for LAW\n", fmt->wBitsPerSample);
return AUDCLNT_E_UNSUPPORTED_FORMAT;
}
if (fmt->nChannels != 1 && fmt->nChannels != 2) {
FIXME("Unsupported channels %u for LAW\n", fmt->nChannels);
return AUDCLNT_E_UNSUPPORTED_FORMAT;
}
stream->ss.format = fmt->wFormatTag == WAVE_FORMAT_MULAW ? PA_SAMPLE_ULAW : PA_SAMPLE_ALAW;
pa_channel_map_init_auto(&stream->map, fmt->nChannels, PA_CHANNEL_MAP_ALSA);
break;
default:
WARN("Unhandled tag %x\n", fmt->wFormatTag);
return AUDCLNT_E_UNSUPPORTED_FORMAT;
}
stream->ss.channels = stream->map.channels;
if (!pa_channel_map_valid(&stream->map) || stream->ss.format == PA_SAMPLE_INVALID) {
ERR("Invalid format! Channel spec valid: %i, format: %i\n",
pa_channel_map_valid(&stream->map), stream->ss.format);
return AUDCLNT_E_UNSUPPORTED_FORMAT;
}
return S_OK;
}
static HRESULT pulse_stream_connect(struct pulse_stream *stream, UINT32 period_bytes)
{
int ret;
char buffer[64];
static LONG number;
pa_buffer_attr attr;
ret = InterlockedIncrement(&number);
sprintf(buffer, "audio stream #%i", ret);
stream->stream = pa_stream_new(pulse_ctx, buffer, &stream->ss, &stream->map);
if (!stream->stream) {
WARN("pa_stream_new returned error %i\n", pa_context_errno(pulse_ctx));
return AUDCLNT_E_ENDPOINT_CREATE_FAILED;
}
pa_stream_set_state_callback(stream->stream, pulse_stream_state, stream);
pa_stream_set_buffer_attr_callback(stream->stream, pulse_attr_update, stream);
pa_stream_set_moved_callback(stream->stream, pulse_attr_update, stream);
/* PulseAudio will fill in correct values */
attr.minreq = attr.fragsize = period_bytes;
attr.tlength = period_bytes * 3;
attr.maxlength = stream->bufsize_frames * pa_frame_size(&stream->ss);
attr.prebuf = pa_frame_size(&stream->ss);
dump_attr(&attr);
if (stream->dataflow == eRender)
ret = pa_stream_connect_playback(stream->stream, NULL, &attr,
PA_STREAM_START_CORKED|PA_STREAM_START_UNMUTED|PA_STREAM_ADJUST_LATENCY, NULL, NULL);
else
ret = pa_stream_connect_record(stream->stream, NULL, &attr,
PA_STREAM_START_CORKED|PA_STREAM_START_UNMUTED|PA_STREAM_ADJUST_LATENCY);
if (ret < 0) {
WARN("Returns %i\n", ret);
return AUDCLNT_E_ENDPOINT_CREATE_FAILED;
}
while (pa_stream_get_state(stream->stream) == PA_STREAM_CREATING)
pulse_cond_wait();
if (pa_stream_get_state(stream->stream) != PA_STREAM_READY)
return AUDCLNT_E_ENDPOINT_CREATE_FAILED;
if (stream->dataflow == eRender) {
pa_stream_set_underflow_callback(stream->stream, pulse_underflow_callback, stream);
pa_stream_set_started_callback(stream->stream, pulse_started_callback, stream);
}
return S_OK;
}
static NTSTATUS pulse_create_stream(void *args)
{
struct create_stream_params *params = args;
REFERENCE_TIME period, duration = params->duration;
struct pulse_stream *stream;
unsigned int i, bufsize_bytes;
HRESULT hr;
pulse_lock();
if (FAILED(params->result = pulse_connect(params->name)))
{
pulse_unlock();
return STATUS_SUCCESS;
}
if (!(stream = calloc(1, sizeof(*stream))))
{
pulse_unlock();
params->result = E_OUTOFMEMORY;
return STATUS_SUCCESS;
}
stream->dataflow = params->dataflow;
for (i = 0; i < ARRAY_SIZE(stream->vol); ++i)
stream->vol[i] = 1.f;
hr = pulse_spec_from_waveformat(stream, params->fmt);
TRACE("Obtaining format returns %08x\n", hr);
if (FAILED(hr))
goto exit;
period = pulse_def_period[stream->dataflow == eCapture];
if (duration < 3 * period)
duration = 3 * period;
stream->period_bytes = pa_frame_size(&stream->ss) * muldiv(period, stream->ss.rate, 10000000);
stream->bufsize_frames = ceil((duration / 10000000.) * params->fmt->nSamplesPerSec);
bufsize_bytes = stream->bufsize_frames * pa_frame_size(&stream->ss);
stream->mmdev_period_usec = period / 10;
stream->share = params->mode;
stream->flags = params->flags;
hr = pulse_stream_connect(stream, stream->period_bytes);
if (SUCCEEDED(hr)) {
UINT32 unalign;
const pa_buffer_attr *attr = pa_stream_get_buffer_attr(stream->stream);
stream->attr = *attr;
/* Update frames according to new size */
dump_attr(attr);
if (stream->dataflow == eRender) {
stream->alloc_size = stream->real_bufsize_bytes =
stream->bufsize_frames * 2 * pa_frame_size(&stream->ss);
if (NtAllocateVirtualMemory(GetCurrentProcess(), (void **)&stream->local_buffer,
0, &stream->real_bufsize_bytes, MEM_COMMIT, PAGE_READWRITE))
hr = E_OUTOFMEMORY;
} else {
UINT32 i, capture_packets;
if ((unalign = bufsize_bytes % stream->period_bytes))
bufsize_bytes += stream->period_bytes - unalign;
stream->bufsize_frames = bufsize_bytes / pa_frame_size(&stream->ss);
stream->real_bufsize_bytes = bufsize_bytes;
capture_packets = stream->real_bufsize_bytes / stream->period_bytes;
stream->alloc_size = stream->real_bufsize_bytes + capture_packets * sizeof(ACPacket);
if (NtAllocateVirtualMemory(GetCurrentProcess(), (void **)&stream->local_buffer,
0, &stream->alloc_size, MEM_COMMIT, PAGE_READWRITE))
hr = E_OUTOFMEMORY;
else {
ACPacket *cur_packet = (ACPacket*)((char*)stream->local_buffer + stream->real_bufsize_bytes);
BYTE *data = stream->local_buffer;
silence_buffer(stream->ss.format, stream->local_buffer, stream->real_bufsize_bytes);
list_init(&stream->packet_free_head);
list_init(&stream->packet_filled_head);
for (i = 0; i < capture_packets; ++i, ++cur_packet) {
list_add_tail(&stream->packet_free_head, &cur_packet->entry);
cur_packet->data = data;
data += stream->period_bytes;
}
}
}
}
*params->channel_count = stream->ss.channels;
*params->stream = stream;
exit:
if (FAILED(params->result = hr)) {
free(stream->local_buffer);
if (stream->stream) {
pa_stream_disconnect(stream->stream);
pa_stream_unref(stream->stream);
free(stream);
}
}
pulse_unlock();
return STATUS_SUCCESS;
}
static NTSTATUS pulse_release_stream(void *args)
{
struct release_stream_params *params = args;
struct pulse_stream *stream = params->stream;
if(params->timer) {
stream->please_quit = TRUE;
NtWaitForSingleObject(params->timer, FALSE, NULL);
NtClose(params->timer);
}
pulse_lock();
if (PA_STREAM_IS_GOOD(pa_stream_get_state(stream->stream))) {
pa_stream_disconnect(stream->stream);
while (PA_STREAM_IS_GOOD(pa_stream_get_state(stream->stream)))
pulse_cond_wait();
}
pa_stream_unref(stream->stream);
pulse_unlock();
if (stream->tmp_buffer)
NtFreeVirtualMemory(GetCurrentProcess(), (void **)&stream->tmp_buffer,
&stream->tmp_buffer_bytes, MEM_RELEASE);
if (stream->local_buffer)
NtFreeVirtualMemory(GetCurrentProcess(), (void **)&stream->local_buffer,
&stream->alloc_size, MEM_RELEASE);
free(stream->peek_buffer);
free(stream);
return STATUS_SUCCESS;
}
static int write_buffer(const struct pulse_stream *stream, BYTE *buffer, UINT32 bytes)
{
const float *vol = stream->vol;
UINT32 i, channels, mute = 0;
BOOL adjust = FALSE;
BYTE *end;
if (!bytes) return 0;
/* Adjust the buffer based on the volume for each channel */
channels = stream->ss.channels;
for (i = 0; i < channels; i++)
{
adjust |= vol[i] != 1.0f;
if (vol[i] == 0.0f)
mute++;
}
if (mute == channels)
{
silence_buffer(stream->ss.format, buffer, bytes);
goto write;
}
if (!adjust) goto write;
end = buffer + bytes;
switch (stream->ss.format)
{
#ifndef WORDS_BIGENDIAN
#define PROCESS_BUFFER(type) do \
{ \
type *p = (type*)buffer; \
do \
{ \
for (i = 0; i < channels; i++) \
p[i] = p[i] * vol[i]; \
p += i; \
} while ((BYTE*)p != end); \
} while (0)
case PA_SAMPLE_S16LE:
PROCESS_BUFFER(INT16);
break;
case PA_SAMPLE_S32LE:
PROCESS_BUFFER(INT32);
break;
case PA_SAMPLE_FLOAT32LE:
PROCESS_BUFFER(float);
break;
#undef PROCESS_BUFFER
case PA_SAMPLE_S24_32LE:
{
UINT32 *p = (UINT32*)buffer;
do
{
for (i = 0; i < channels; i++)
{
p[i] = (INT32)((INT32)(p[i] << 8) * vol[i]);
p[i] >>= 8;
}
p += i;
} while ((BYTE*)p != end);
break;
}
case PA_SAMPLE_S24LE:
{
/* do it 12 bytes at a time until it is no longer possible */
UINT32 *q = (UINT32*)buffer;
BYTE *p;
i = 0;
while (end - (BYTE*)q >= 12)
{
UINT32 v[4], k;
v[0] = q[0] << 8;
v[1] = q[1] << 16 | (q[0] >> 16 & ~0xff);
v[2] = q[2] << 24 | (q[1] >> 8 & ~0xff);
v[3] = q[2] & ~0xff;
for (k = 0; k < 4; k++)
{
v[k] = (INT32)((INT32)v[k] * vol[i]);
if (++i == channels) i = 0;
}
*q++ = v[0] >> 8 | (v[1] & ~0xff) << 16;
*q++ = v[1] >> 16 | (v[2] & ~0xff) << 8;
*q++ = v[2] >> 24 | (v[3] & ~0xff);
}
p = (BYTE*)q;
while (p != end)
{
UINT32 v = (INT32)((INT32)(p[0] << 8 | p[1] << 16 | p[2] << 24) * vol[i]);
*p++ = v >> 8 & 0xff;
*p++ = v >> 16 & 0xff;
*p++ = v >> 24;
if (++i == channels) i = 0;
}
break;
}
#endif
case PA_SAMPLE_U8:
{
UINT8 *p = (UINT8*)buffer;
do
{
for (i = 0; i < channels; i++)
p[i] = (int)((p[i] - 128) * vol[i]) + 128;
p += i;
} while ((BYTE*)p != end);
break;
}
case PA_SAMPLE_ALAW:
{
UINT8 *p = (UINT8*)buffer;
do
{
for (i = 0; i < channels; i++)
p[i] = mult_alaw_sample(p[i], vol[i]);
p += i;
} while ((BYTE*)p != end);
break;
}
case PA_SAMPLE_ULAW:
{
UINT8 *p = (UINT8*)buffer;
do
{
for (i = 0; i < channels; i++)
p[i] = mult_ulaw_sample(p[i], vol[i]);
p += i;
} while ((BYTE*)p != end);
break;
}
default:
TRACE("Unhandled format %i, not adjusting volume.\n", stream->ss.format);
break;
}
write:
return pa_stream_write(stream->stream, buffer, bytes, NULL, 0, PA_SEEK_RELATIVE);
}
static void pulse_write(struct pulse_stream *stream)
{
/* write as much data to PA as we can */
UINT32 to_write;
BYTE *buf = stream->local_buffer + stream->pa_offs_bytes;
UINT32 bytes = pa_stream_writable_size(stream->stream);
if (stream->just_underran)
{
/* prebuffer with silence if needed */
if(stream->pa_held_bytes < bytes){
to_write = bytes - stream->pa_held_bytes;
TRACE("prebuffering %u frames of silence\n",
(int)(to_write / pa_frame_size(&stream->ss)));
buf = calloc(1, to_write);
pa_stream_write(stream->stream, buf, to_write, NULL, 0, PA_SEEK_RELATIVE);
free(buf);
}
stream->just_underran = FALSE;
}
buf = stream->local_buffer + stream->pa_offs_bytes;
TRACE("held: %lu, avail: %u\n", stream->pa_held_bytes, bytes);
bytes = min(stream->pa_held_bytes, bytes);
if (stream->pa_offs_bytes + bytes > stream->real_bufsize_bytes)
{
to_write = stream->real_bufsize_bytes - stream->pa_offs_bytes;
TRACE("writing small chunk of %u bytes\n", to_write);
write_buffer(stream, buf, to_write);
stream->pa_held_bytes -= to_write;
to_write = bytes - to_write;
stream->pa_offs_bytes = 0;
buf = stream->local_buffer;
}
else
to_write = bytes;
TRACE("writing main chunk of %u bytes\n", to_write);
write_buffer(stream, buf, to_write);
stream->pa_offs_bytes += to_write;
stream->pa_offs_bytes %= stream->real_bufsize_bytes;
stream->pa_held_bytes -= to_write;
}
static void pulse_read(struct pulse_stream *stream)
{
size_t bytes = pa_stream_readable_size(stream->stream);
TRACE("Readable total: %zu, fragsize: %u\n", bytes, pa_stream_get_buffer_attr(stream->stream)->fragsize);
bytes += stream->peek_len - stream->peek_ofs;
while (bytes >= stream->period_bytes)
{
BYTE *dst = NULL, *src;
size_t src_len, copy, rem = stream->period_bytes;
if (stream->started)
{
LARGE_INTEGER stamp, freq;
ACPacket *p, *next;
if (!(p = (ACPacket*)list_head(&stream->packet_free_head)))
{
p = (ACPacket*)list_head(&stream->packet_filled_head);
if (!p) return;
if (!p->discont) {
next = (ACPacket*)p->entry.next;
next->discont = 1;
} else
p = (ACPacket*)list_tail(&stream->packet_filled_head);
}
else
{
stream->held_bytes += stream->period_bytes;
}
NtQueryPerformanceCounter(&stamp, &freq);
p->qpcpos = (stamp.QuadPart * (INT64)10000000) / freq.QuadPart;
p->discont = 0;
list_remove(&p->entry);
list_add_tail(&stream->packet_filled_head, &p->entry);
dst = p->data;
}
while (rem)
{
if (stream->peek_len)
{
copy = min(rem, stream->peek_len - stream->peek_ofs);
if (dst)
{
memcpy(dst, stream->peek_buffer + stream->peek_ofs, copy);
dst += copy;
}
rem -= copy;
stream->peek_ofs += copy;
if(stream->peek_len == stream->peek_ofs)
stream->peek_len = stream->peek_ofs = 0;
}
else if (pa_stream_peek(stream->stream, (const void**)&src, &src_len) == 0 && src_len)
{
copy = min(rem, src_len);
if (dst) {
if(src)
memcpy(dst, src, copy);
else
silence_buffer(stream->ss.format, dst, copy);
dst += copy;
}
rem -= copy;
if (copy < src_len)
{
if (src_len > stream->peek_buffer_len)
{
free(stream->peek_buffer);
stream->peek_buffer = malloc(src_len);
stream->peek_buffer_len = src_len;
}
if(src)
memcpy(stream->peek_buffer, src + copy, src_len - copy);
else
silence_buffer(stream->ss.format, stream->peek_buffer, src_len - copy);
stream->peek_len = src_len - copy;
stream->peek_ofs = 0;
}
pa_stream_drop(stream->stream);
}
}
bytes -= stream->period_bytes;
}
}
static NTSTATUS pulse_timer_loop(void *args)
{
struct timer_loop_params *params = args;
struct pulse_stream *stream = params->stream;
LARGE_INTEGER delay;
UINT32 adv_bytes;
int success;
pa_operation *o;
pulse_lock();
delay.QuadPart = -stream->mmdev_period_usec * 10;
pa_stream_get_time(stream->stream, &stream->last_time);
pulse_unlock();
while (!stream->please_quit)
{
pa_usec_t now, adv_usec = 0;
int err;
NtDelayExecution(FALSE, &delay);
pulse_lock();
delay.QuadPart = -stream->mmdev_period_usec * 10;
o = pa_stream_update_timing_info(stream->stream, pulse_op_cb, &success);
if (o)
{
while (pa_operation_get_state(o) == PA_OPERATION_RUNNING)
pulse_cond_wait();
pa_operation_unref(o);
}
err = pa_stream_get_time(stream->stream, &now);
if (err == 0)
{
TRACE("got now: %s, last time: %s\n", wine_dbgstr_longlong(now), wine_dbgstr_longlong(stream->last_time));
if (stream->started && (stream->dataflow == eCapture || stream->held_bytes))
{
if(stream->just_underran)
{
stream->last_time = now;
stream->just_started = TRUE;
}
if (stream->just_started)
{
/* let it play out a period to absorb some latency and get accurate timing */
pa_usec_t diff = now - stream->last_time;
if (diff > stream->mmdev_period_usec)
{
stream->just_started = FALSE;
stream->last_time = now;
}
}
else
{
INT32 adjust = stream->last_time + stream->mmdev_period_usec - now;
adv_usec = now - stream->last_time;
if(adjust > ((INT32)(stream->mmdev_period_usec / 2)))
adjust = stream->mmdev_period_usec / 2;
else if(adjust < -((INT32)(stream->mmdev_period_usec / 2)))
adjust = -1 * stream->mmdev_period_usec / 2;
delay.QuadPart = -(stream->mmdev_period_usec + adjust) * 10;
stream->last_time += stream->mmdev_period_usec;
}
if (stream->dataflow == eRender)
{
pulse_write(stream);
/* regardless of what PA does, advance one period */
adv_bytes = min(stream->period_bytes, stream->held_bytes);
stream->lcl_offs_bytes += adv_bytes;
stream->lcl_offs_bytes %= stream->real_bufsize_bytes;
stream->held_bytes -= adv_bytes;
}
else if(stream->dataflow == eCapture)
{
pulse_read(stream);
}
}
else
{
stream->last_time = now;
delay.QuadPart = -stream->mmdev_period_usec * 10;
}
}
if (stream->event)
NtSetEvent(stream->event, NULL);
TRACE("%p after update, adv usec: %d, held: %u, delay usec: %u\n",
stream, (int)adv_usec,
(int)(stream->held_bytes/ pa_frame_size(&stream->ss)),
(unsigned int)(-delay.QuadPart / 10));
pulse_unlock();
}
return STATUS_SUCCESS;
}
static NTSTATUS pulse_start(void *args)
{
struct start_params *params = args;
struct pulse_stream *stream = params->stream;
int success;
pa_operation *o;
params->result = S_OK;
pulse_lock();
if (!pulse_stream_valid(stream))
{
pulse_unlock();
params->result = S_OK;
return STATUS_SUCCESS;
}
if ((stream->flags & AUDCLNT_STREAMFLAGS_EVENTCALLBACK) && !stream->event)
{
pulse_unlock();
params->result = AUDCLNT_E_EVENTHANDLE_NOT_SET;
return STATUS_SUCCESS;
}
if (stream->started)
{
pulse_unlock();
params->result = AUDCLNT_E_NOT_STOPPED;
return STATUS_SUCCESS;
}
pulse_write(stream);
if (pa_stream_is_corked(stream->stream))
{
o = pa_stream_cork(stream->stream, 0, pulse_op_cb, &success);
if (o)
{
while(pa_operation_get_state(o) == PA_OPERATION_RUNNING)
pulse_cond_wait();
pa_operation_unref(o);
}
else
success = 0;
if (!success)
params->result = E_FAIL;
}
if (SUCCEEDED(params->result))
{
stream->started = TRUE;
stream->just_started = TRUE;
}
pulse_unlock();
return STATUS_SUCCESS;
}
static NTSTATUS pulse_stop(void *args)
{
struct stop_params *params = args;
struct pulse_stream *stream = params->stream;
pa_operation *o;
int success;
pulse_lock();
if (!pulse_stream_valid(stream))
{
pulse_unlock();
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
return STATUS_SUCCESS;
}
if (!stream->started)
{
pulse_unlock();
params->result = S_FALSE;
return STATUS_SUCCESS;
}
params->result = S_OK;
if (stream->dataflow == eRender)
{
o = pa_stream_cork(stream->stream, 1, pulse_op_cb, &success);
if (o)
{
while(pa_operation_get_state(o) == PA_OPERATION_RUNNING)
pulse_cond_wait();
pa_operation_unref(o);
}
else
success = 0;
if (!success)
params->result = E_FAIL;
}
if (SUCCEEDED(params->result))
stream->started = FALSE;
pulse_unlock();
return STATUS_SUCCESS;
}
static NTSTATUS pulse_reset(void *args)
{
struct reset_params *params = args;
struct pulse_stream *stream = params->stream;
pulse_lock();
if (!pulse_stream_valid(stream))
{
pulse_unlock();
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
return STATUS_SUCCESS;
}
if (stream->started)
{
pulse_unlock();
params->result = AUDCLNT_E_NOT_STOPPED;
return STATUS_SUCCESS;
}
if (stream->locked)
{
pulse_unlock();
params->result = AUDCLNT_E_BUFFER_OPERATION_PENDING;
return STATUS_SUCCESS;
}
if (stream->dataflow == eRender)
{
/* If there is still data in the render buffer it needs to be removed from the server */
int success = 0;
if (stream->held_bytes)
{
pa_operation *o = pa_stream_flush(stream->stream, pulse_op_cb, &success);
if (o)
{
while (pa_operation_get_state(o) == PA_OPERATION_RUNNING)
pulse_cond_wait();
pa_operation_unref(o);
}
}
if (success || !stream->held_bytes)
{
stream->clock_lastpos = stream->clock_written = 0;
stream->pa_offs_bytes = stream->lcl_offs_bytes = 0;
stream->held_bytes = stream->pa_held_bytes = 0;
}
}
else
{
ACPacket *p;
stream->clock_written += stream->held_bytes;
stream->held_bytes = 0;
if ((p = stream->locked_ptr))
{
stream->locked_ptr = NULL;
list_add_tail(&stream->packet_free_head, &p->entry);
}
list_move_tail(&stream->packet_free_head, &stream->packet_filled_head);
}
pulse_unlock();
params->result = S_OK;
return STATUS_SUCCESS;
}
static BOOL alloc_tmp_buffer(struct pulse_stream *stream, SIZE_T bytes)
{
if (stream->tmp_buffer_bytes >= bytes)
return TRUE;
if (stream->tmp_buffer)
{
NtFreeVirtualMemory(GetCurrentProcess(), (void **)&stream->tmp_buffer,
&stream->tmp_buffer_bytes, MEM_RELEASE);
stream->tmp_buffer = NULL;
stream->tmp_buffer_bytes = 0;
}
if (NtAllocateVirtualMemory(GetCurrentProcess(), (void **)&stream->tmp_buffer,
0, &bytes, MEM_COMMIT, PAGE_READWRITE))
return FALSE;
stream->tmp_buffer_bytes = bytes;
return TRUE;
}
static UINT32 pulse_render_padding(struct pulse_stream *stream)
{
return stream->held_bytes / pa_frame_size(&stream->ss);
}
static UINT32 pulse_capture_padding(struct pulse_stream *stream)
{
ACPacket *packet = stream->locked_ptr;
if (!packet && !list_empty(&stream->packet_filled_head))
{
packet = (ACPacket*)list_head(&stream->packet_filled_head);
stream->locked_ptr = packet;
list_remove(&packet->entry);
}
return stream->held_bytes / pa_frame_size(&stream->ss);
}
static NTSTATUS pulse_get_render_buffer(void *args)
{
struct get_render_buffer_params *params = args;
struct pulse_stream *stream = params->stream;
size_t bytes;
UINT32 wri_offs_bytes;
pulse_lock();
if (!pulse_stream_valid(stream))
{
pulse_unlock();
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
return STATUS_SUCCESS;
}
if (stream->locked)
{
pulse_unlock();
params->result = AUDCLNT_E_OUT_OF_ORDER;
return STATUS_SUCCESS;
}
if (!params->frames)
{
pulse_unlock();
*params->data = NULL;
params->result = S_OK;
return STATUS_SUCCESS;
}
if (stream->held_bytes / pa_frame_size(&stream->ss) + params->frames > stream->bufsize_frames)
{
pulse_unlock();
params->result = AUDCLNT_E_BUFFER_TOO_LARGE;
return STATUS_SUCCESS;
}
bytes = params->frames * pa_frame_size(&stream->ss);
wri_offs_bytes = (stream->lcl_offs_bytes + stream->held_bytes) % stream->real_bufsize_bytes;
if (wri_offs_bytes + bytes > stream->real_bufsize_bytes)
{
if (!alloc_tmp_buffer(stream, bytes))
{
pulse_unlock();
params->result = E_OUTOFMEMORY;
return STATUS_SUCCESS;
}
*params->data = stream->tmp_buffer;
stream->locked = -bytes;
}
else
{
*params->data = stream->local_buffer + wri_offs_bytes;
stream->locked = bytes;
}
silence_buffer(stream->ss.format, *params->data, bytes);
pulse_unlock();
params->result = S_OK;
return STATUS_SUCCESS;
}
static void pulse_wrap_buffer(struct pulse_stream *stream, BYTE *buffer, UINT32 written_bytes)
{
UINT32 wri_offs_bytes = (stream->lcl_offs_bytes + stream->held_bytes) % stream->real_bufsize_bytes;
UINT32 chunk_bytes = stream->real_bufsize_bytes - wri_offs_bytes;
if (written_bytes <= chunk_bytes)
{
memcpy(stream->local_buffer + wri_offs_bytes, buffer, written_bytes);
}
else
{
memcpy(stream->local_buffer + wri_offs_bytes, buffer, chunk_bytes);
memcpy(stream->local_buffer, buffer + chunk_bytes, written_bytes - chunk_bytes);
}
}
static NTSTATUS pulse_release_render_buffer(void *args)
{
struct release_render_buffer_params *params = args;
struct pulse_stream *stream = params->stream;
UINT32 written_bytes;
BYTE *buffer;
pulse_lock();
if (!stream->locked || !params->written_frames)
{
stream->locked = 0;
pulse_unlock();
params->result = params->written_frames ? AUDCLNT_E_OUT_OF_ORDER : S_OK;
return STATUS_SUCCESS;
}
if (params->written_frames * pa_frame_size(&stream->ss) >
(stream->locked >= 0 ? stream->locked : -stream->locked))
{
pulse_unlock();
params->result = AUDCLNT_E_INVALID_SIZE;
return STATUS_SUCCESS;
}
if (stream->locked >= 0)
buffer = stream->local_buffer + (stream->lcl_offs_bytes + stream->held_bytes) % stream->real_bufsize_bytes;
else
buffer = stream->tmp_buffer;
written_bytes = params->written_frames * pa_frame_size(&stream->ss);
if (params->flags & AUDCLNT_BUFFERFLAGS_SILENT)
silence_buffer(stream->ss.format, buffer, written_bytes);
if (stream->locked < 0)
pulse_wrap_buffer(stream, buffer, written_bytes);
stream->held_bytes += written_bytes;
stream->pa_held_bytes += written_bytes;
if (stream->pa_held_bytes > stream->real_bufsize_bytes)
{
stream->pa_offs_bytes += stream->pa_held_bytes - stream->real_bufsize_bytes;
stream->pa_offs_bytes %= stream->real_bufsize_bytes;
stream->pa_held_bytes = stream->real_bufsize_bytes;
}
stream->clock_written += written_bytes;
stream->locked = 0;
TRACE("Released %u, held %lu\n", params->written_frames, stream->held_bytes / pa_frame_size(&stream->ss));
pulse_unlock();
params->result = S_OK;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_get_capture_buffer(void *args)
{
struct get_capture_buffer_params *params = args;
struct pulse_stream *stream = params->stream;
ACPacket *packet;
pulse_lock();
if (!pulse_stream_valid(stream))
{
pulse_unlock();
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
return STATUS_SUCCESS;
}
if (stream->locked)
{
pulse_unlock();
params->result = AUDCLNT_E_OUT_OF_ORDER;
return STATUS_SUCCESS;
}
pulse_capture_padding(stream);
if ((packet = stream->locked_ptr))
{
*params->frames = stream->period_bytes / pa_frame_size(&stream->ss);
*params->flags = 0;
if (packet->discont)
*params->flags |= AUDCLNT_BUFFERFLAGS_DATA_DISCONTINUITY;
if (params->devpos)
{
if (packet->discont)
*params->devpos = (stream->clock_written + stream->period_bytes) / pa_frame_size(&stream->ss);
else
*params->devpos = stream->clock_written / pa_frame_size(&stream->ss);
}
if (params->qpcpos)
*params->qpcpos = packet->qpcpos;
*params->data = packet->data;
}
else
*params->frames = 0;
stream->locked = *params->frames;
pulse_unlock();
params->result = *params->frames ? S_OK : AUDCLNT_S_BUFFER_EMPTY;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_release_capture_buffer(void *args)
{
struct release_capture_buffer_params *params = args;
struct pulse_stream *stream = params->stream;
pulse_lock();
if (!stream->locked && params->done)
{
pulse_unlock();
params->result = AUDCLNT_E_OUT_OF_ORDER;
return STATUS_SUCCESS;
}
if (params->done && stream->locked != params->done)
{
pulse_unlock();
params->result = AUDCLNT_E_INVALID_SIZE;
return STATUS_SUCCESS;
}
if (params->done)
{
ACPacket *packet = stream->locked_ptr;
stream->locked_ptr = NULL;
stream->held_bytes -= stream->period_bytes;
if (packet->discont)
stream->clock_written += 2 * stream->period_bytes;
else
stream->clock_written += stream->period_bytes;
list_add_tail(&stream->packet_free_head, &packet->entry);
}
stream->locked = 0;
pulse_unlock();
params->result = S_OK;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_get_buffer_size(void *args)
{
struct get_buffer_size_params *params = args;
params->result = S_OK;
pulse_lock();
if (!pulse_stream_valid(params->stream))
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
else
*params->size = params->stream->bufsize_frames;
pulse_unlock();
return STATUS_SUCCESS;
}
static NTSTATUS pulse_get_latency(void *args)
{
struct get_latency_params *params = args;
struct pulse_stream *stream = params->stream;
const pa_buffer_attr *attr;
REFERENCE_TIME lat;
pulse_lock();
if (!pulse_stream_valid(stream)) {
pulse_unlock();
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
return STATUS_SUCCESS;
}
attr = pa_stream_get_buffer_attr(stream->stream);
if (stream->dataflow == eRender)
lat = attr->minreq / pa_frame_size(&stream->ss);
else
lat = attr->fragsize / pa_frame_size(&stream->ss);
*params->latency = (lat * 10000000) / stream->ss.rate + pulse_def_period[0];
pulse_unlock();
TRACE("Latency: %u ms\n", (DWORD)(*params->latency / 10000));
params->result = S_OK;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_get_current_padding(void *args)
{
struct get_current_padding_params *params = args;
struct pulse_stream *stream = params->stream;
pulse_lock();
if (!pulse_stream_valid(stream))
{
pulse_unlock();
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
return STATUS_SUCCESS;
}
if (stream->dataflow == eRender)
*params->padding = pulse_render_padding(stream);
else
*params->padding = pulse_capture_padding(stream);
pulse_unlock();
TRACE("%p Pad: %u ms (%u)\n", stream, muldiv(*params->padding, 1000, stream->ss.rate),
*params->padding);
params->result = S_OK;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_get_next_packet_size(void *args)
{
struct get_next_packet_size_params *params = args;
struct pulse_stream *stream = params->stream;
pulse_lock();
pulse_capture_padding(stream);
if (stream->locked_ptr)
*params->frames = stream->period_bytes / pa_frame_size(&stream->ss);
else
*params->frames = 0;
pulse_unlock();
params->result = S_OK;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_get_frequency(void *args)
{
struct get_frequency_params *params = args;
struct pulse_stream *stream = params->stream;
pulse_lock();
if (!pulse_stream_valid(stream))
{
pulse_unlock();
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
return STATUS_SUCCESS;
}
*params->freq = stream->ss.rate;
if (stream->share == AUDCLNT_SHAREMODE_SHARED)
*params->freq *= pa_frame_size(&stream->ss);
pulse_unlock();
params->result = S_OK;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_get_position(void *args)
{
struct get_position_params *params = args;
struct pulse_stream *stream = params->stream;
pulse_lock();
if (!pulse_stream_valid(stream))
{
pulse_unlock();
params->result = AUDCLNT_E_DEVICE_INVALIDATED;
return STATUS_SUCCESS;
}
*params->pos = stream->clock_written - stream->held_bytes;
if (stream->share == AUDCLNT_SHAREMODE_EXCLUSIVE || params->device)
*params->pos /= pa_frame_size(&stream->ss);
/* Make time never go backwards */
if (*params->pos < stream->clock_lastpos)
*params->pos = stream->clock_lastpos;
else
stream->clock_lastpos = *params->pos;
pulse_unlock();
TRACE("%p Position: %u\n", stream, (unsigned)*params->pos);
if (params->qpctime)
{
LARGE_INTEGER stamp, freq;
NtQueryPerformanceCounter(&stamp, &freq);
*params->qpctime = (stamp.QuadPart * (INT64)10000000) / freq.QuadPart;
}
params->result = S_OK;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_set_volumes(void *args)
{
struct set_volumes_params *params = args;
struct pulse_stream *stream = params->stream;
unsigned int i;
for (i = 0; i < stream->ss.channels; i++)
stream->vol[i] = params->volumes[i] * params->master_volume * params->session_volumes[i];
return STATUS_SUCCESS;
}
static NTSTATUS pulse_set_event_handle(void *args)
{
struct set_event_handle_params *params = args;
struct pulse_stream *stream = params->stream;
HRESULT hr = S_OK;
pulse_lock();
if (!pulse_stream_valid(stream))
hr = AUDCLNT_E_DEVICE_INVALIDATED;
else if (!(stream->flags & AUDCLNT_STREAMFLAGS_EVENTCALLBACK))
hr = AUDCLNT_E_EVENTHANDLE_NOT_EXPECTED;
else if (stream->event)
hr = HRESULT_FROM_WIN32(ERROR_INVALID_NAME);
else
stream->event = params->event;
pulse_unlock();
params->result = hr;
return STATUS_SUCCESS;
}
static NTSTATUS pulse_is_started(void *args)
{
struct is_started_params *params = args;
struct pulse_stream *stream = params->stream;
pulse_lock();
params->started = pulse_stream_valid(stream) && stream->started;
pulse_unlock();
return STATUS_SUCCESS;
}
const unixlib_entry_t __wine_unix_call_funcs[] =
{
pulse_process_attach,
pulse_process_detach,
pulse_main_loop,
pulse_create_stream,
pulse_release_stream,
pulse_start,
pulse_stop,
pulse_reset,
pulse_timer_loop,
pulse_get_render_buffer,
pulse_release_render_buffer,
pulse_get_capture_buffer,
pulse_release_capture_buffer,
pulse_get_buffer_size,
pulse_get_latency,
pulse_get_current_padding,
pulse_get_next_packet_size,
pulse_get_frequency,
pulse_get_position,
pulse_set_volumes,
pulse_set_event_handle,
pulse_test_connect,
pulse_is_started,
};