/** * xrdp: A Remote Desktop Protocol server. * * Copyright (C) Jay Sorg 2009-2013 * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "sound.h" #include "thread_calls.h" #include "defines.h" extern int g_rdpsnd_chan_id; /* in chansrv.c */ extern int g_display_num; /* in chansrv.c */ static struct trans *g_audio_l_trans = 0; /* listener */ static struct trans *g_audio_c_trans = 0; /* connection */ static int g_training_sent_time = 0; static int g_cBlockNo = 0; #define BBUF_SIZE (1024 * 8) char g_buffer[BBUF_SIZE]; int g_buf_index = 0; int g_sent_time[256]; #if defined(XRDP_SIMPLESOUND) static void *DEFAULT_CC read_raw_audio_data(void *arg); #endif #define CHANSRV_PORT_STR "/tmp/.xrdp/xrdp_chansrv_audio_socket_%d" struct xr_wave_format_ex { int wFormatTag; int nChannels; int nSamplesPerSec; int nAvgBytesPerSec; int nBlockAlign; int wBitsPerSample; int cbSize; char *data; }; static char g_pmc_22050_data[] = { 0 }; static struct xr_wave_format_ex g_pmc_22050 = { 1, /* wFormatTag - WAVE_FORMAT_PCM */ 2, /* num of channels */ 22050, /* samples per sec */ 88200, /* avg bytes per sec */ 4, /* block align */ 16, /* bits per sample */ 0, /* data size */ g_pmc_22050_data /* data */ }; static char g_pmc_44100_data[] = { 0 }; static struct xr_wave_format_ex g_pmc_44100 = { 1, /* wFormatTag - WAVE_FORMAT_PCM */ 2, /* num of channels */ 44100, /* samples per sec */ 176400, /* avg bytes per sec */ 4, /* block align */ 16, /* bits per sample */ 0, /* data size */ g_pmc_44100_data /* data */ }; #define NUM_BUILT_IN 2 static struct xr_wave_format_ex *g_wave_formats[NUM_BUILT_IN] = { &g_pmc_44100, &g_pmc_22050 }; /* index into list from client */ static int g_current_client_format_index = 0; /* index into list from server */ static int g_current_server_format_index = 0; /*****************************************************************************/ static int APP_CC sound_send_server_formats(void) { struct stream *s; int bytes; int index; char *size_ptr; make_stream(s); init_stream(s, 8182); out_uint16_le(s, SNDC_FORMATS); size_ptr = s->p; out_uint16_le(s, 0); /* size, set later */ out_uint32_le(s, 0); /* dwFlags */ out_uint32_le(s, 0); /* dwVolume */ out_uint32_le(s, 0); /* dwPitch */ out_uint16_le(s, 0); /* wDGramPort */ out_uint16_le(s, NUM_BUILT_IN); /* wNumberOfFormats */ out_uint8(s, g_cBlockNo); /* cLastBlockConfirmed */ out_uint16_le(s, 2); /* wVersion */ out_uint8(s, 0); /* bPad */ /* sndFormats */ /* wFormatTag 2 byte offset 0 nChannels 2 byte offset 2 nSamplesPerSec 4 byte offset 4 nAvgBytesPerSec 4 byte offset 8 nBlockAlign 2 byte offset 12 wBitsPerSample 2 byte offset 14 cbSize 2 byte offset 16 data variable offset 18 */ /* examples 01 00 02 00 44 ac 00 00 10 b1 02 00 04 00 10 00 ....D........... 00 00 01 00 02 00 22 56 00 00 88 58 01 00 04 00 10 00 ...."V...X...... 00 00 */ for (index = 0; index < NUM_BUILT_IN; index++) { out_uint16_le(s, g_wave_formats[index]->wFormatTag); out_uint16_le(s, g_wave_formats[index]->nChannels); out_uint32_le(s, g_wave_formats[index]->nSamplesPerSec); out_uint32_le(s, g_wave_formats[index]->nAvgBytesPerSec); out_uint16_le(s, g_wave_formats[index]->nBlockAlign); out_uint16_le(s, g_wave_formats[index]->wBitsPerSample); bytes = g_wave_formats[index]->cbSize; out_uint16_le(s, bytes); if (bytes > 0) { out_uint8p(s, g_wave_formats[index]->data, bytes); } } s_mark_end(s); bytes = (int)((s->end - s->data) - 4); size_ptr[0] = bytes; size_ptr[1] = bytes >> 8; bytes = (int)(s->end - s->data); send_channel_data(g_rdpsnd_chan_id, s->data, bytes); free_stream(s); return 0; } /*****************************************************************************/ static int sound_send_training(void) { struct stream *s; int bytes; int time; char *size_ptr; make_stream(s); init_stream(s, 8182); out_uint16_le(s, SNDC_TRAINING); size_ptr = s->p; out_uint16_le(s, 0); /* size, set later */ time = g_time2(); g_training_sent_time = time; out_uint16_le(s, time); out_uint16_le(s, 1024); out_uint8s(s, (1024 - 4)); s_mark_end(s); bytes = (int)((s->end - s->data) - 4); size_ptr[0] = bytes; size_ptr[1] = bytes >> 8; bytes = (int)(s->end - s->data); send_channel_data(g_rdpsnd_chan_id, s->data, bytes); free_stream(s); return 0; } /*****************************************************************************/ static int APP_CC sound_process_format(int aindex, int wFormatTag, int nChannels, int nSamplesPerSec, int nAvgBytesPerSec, int nBlockAlign, int wBitsPerSample, int cbSize, char *data) { int lindex; LOG(0, ("sound_process_format:")); LOG(0, (" wFormatTag %d", wFormatTag)); LOG(0, (" nChannels %d", nChannels)); LOG(0, (" nSamplesPerSec %d", nSamplesPerSec)); LOG(0, (" nAvgBytesPerSec %d", nAvgBytesPerSec)); LOG(0, (" nBlockAlign %d", nBlockAlign)); LOG(0, (" wBitsPerSample %d", wBitsPerSample)); LOG(0, (" cbSize %d", cbSize)); g_hexdump(data, cbSize); if (wFormatTag == g_pmc_44100.wFormatTag && nChannels == g_pmc_44100.nChannels && nSamplesPerSec == g_pmc_44100.nSamplesPerSec && nAvgBytesPerSec == g_pmc_44100.nAvgBytesPerSec && nBlockAlign == g_pmc_44100.nBlockAlign && wBitsPerSample == g_pmc_44100.wBitsPerSample) { g_current_client_format_index = aindex; g_current_server_format_index = 0; } #if 0 for (lindex = 0; lindex < NUM_BUILT_IN; lindex++) { if (wFormatTag == g_wave_formats[lindex]->wFormatTag && nChannels == g_wave_formats[lindex]->nChannels && nSamplesPerSec == g_wave_formats[lindex]->nSamplesPerSec && nAvgBytesPerSec == g_wave_formats[lindex]->nAvgBytesPerSec && nBlockAlign == g_wave_formats[lindex]->nBlockAlign && wBitsPerSample == g_wave_formats[lindex]->wBitsPerSample) { g_current_client_format_index = aindex; g_current_server_format_index = lindex; } } #endif return 0; } /*****************************************************************************/ /* 0000 07 02 26 00 03 00 80 00 ff ff ff ff 00 00 00 00 ..&............. 0010 00 00 01 00 00 02 00 00 01 00 02 00 44 ac 00 00 ............D... 0020 10 b1 02 00 04 00 10 00 00 00 */ static int APP_CC sound_process_formats(struct stream *s, int size) { int num_formats; int index; int wFormatTag; int nChannels; int nSamplesPerSec; int nAvgBytesPerSec; int nBlockAlign; int wBitsPerSample; int cbSize; char *data; LOG(0, ("sound_process_formats:")); if (size < 16) { return 1; } in_uint8s(s, 14); in_uint16_le(s, num_formats); in_uint8s(s, 4); if (num_formats > 0) { for (index = 0; index < num_formats; index++) { in_uint16_le(s, wFormatTag); in_uint16_le(s, nChannels); in_uint32_le(s, nSamplesPerSec); in_uint32_le(s, nAvgBytesPerSec); in_uint16_le(s, nBlockAlign); in_uint16_le(s, wBitsPerSample); in_uint16_le(s, cbSize); in_uint8p(s, data, cbSize); sound_process_format(index, wFormatTag, nChannels, nSamplesPerSec, nAvgBytesPerSec, nBlockAlign, wBitsPerSample, cbSize, data); } sound_send_training(); } return 0; } /*****************************************************************************/ /* send wave message to client */ static int sound_send_wave_data_chunk(char *data, int data_bytes) { struct stream *s; int bytes; int time; char *size_ptr; LOG(10, ("sound_send_wave_data_chunk: data_bytes %d", data_bytes)); if ((data_bytes < 4) || (data_bytes > 128 * 1024)) { LOG(0, ("sound_send_wave_data_chunk: bad data_bytes %d", data_bytes)); return 0; } /* part one of 2 PDU wave info */ LOG(10, ("sound_send_wave_data_chunk: sending %d bytes", data_bytes)); make_stream(s); init_stream(s, 16 + data_bytes); /* some extra space */ out_uint16_le(s, SNDC_WAVE); size_ptr = s->p; out_uint16_le(s, 0); /* size, set later */ time = g_time2(); out_uint16_le(s, time); out_uint16_le(s, g_current_client_format_index); /* wFormatNo */ g_cBlockNo++; out_uint8(s, g_cBlockNo); g_sent_time[g_cBlockNo & 0xff] = time; LOG(10, ("sound_send_wave_data_chunk: sending time %d, g_cBlockNo %d", time & 0xffff, g_cBlockNo & 0xff)); out_uint8s(s, 3); out_uint8a(s, data, 4); s_mark_end(s); bytes = (int)((s->end - s->data) - 4); bytes += data_bytes; bytes -= 4; size_ptr[0] = bytes; size_ptr[1] = bytes >> 8; bytes = (int)(s->end - s->data); send_channel_data(g_rdpsnd_chan_id, s->data, bytes); /* part two of 2 PDU wave info even is zero, we have to send this */ init_stream(s, data_bytes); out_uint32_le(s, 0); out_uint8a(s, data + 4, data_bytes - 4); s_mark_end(s); bytes = (int)(s->end - s->data); send_channel_data(g_rdpsnd_chan_id, s->data, bytes); free_stream(s); return 0; } /*****************************************************************************/ /* send wave message to client, buffer first */ static int sound_send_wave_data(char *data, int data_bytes) { int space_left; int chunk_bytes; int data_index; LOG(10, ("sound_send_wave_data: sending %d bytes", data_bytes)); data_index = 0; while (data_bytes > 0) { space_left = BBUF_SIZE - g_buf_index; chunk_bytes = MIN(space_left, data_bytes); if (chunk_bytes < 1) { LOG(10, ("sound_send_wave_data: error")); break; } g_memcpy(g_buffer + g_buf_index, data + data_index, chunk_bytes); g_buf_index += chunk_bytes; if (g_buf_index >= BBUF_SIZE) { sound_send_wave_data_chunk(g_buffer, BBUF_SIZE); g_buf_index = 0; } data_bytes -= chunk_bytes; data_index += chunk_bytes; } return 0; } /*****************************************************************************/ /* send close message to client */ static int sound_send_close(void) { struct stream *s; int bytes; char *size_ptr; LOG(10, ("sound_send_close:")); /* send any left over data */ sound_send_wave_data_chunk(g_buffer, g_buf_index); g_buf_index = 0; make_stream(s); init_stream(s, 8182); out_uint16_le(s, SNDC_CLOSE); size_ptr = s->p; out_uint16_le(s, 0); /* size, set later */ s_mark_end(s); bytes = (int)((s->end - s->data) - 4); size_ptr[0] = bytes; size_ptr[1] = bytes >> 8; bytes = (int)(s->end - s->data); send_channel_data(g_rdpsnd_chan_id, s->data, bytes); free_stream(s); return 0; } /*****************************************************************************/ /* from client */ static int APP_CC sound_process_training(struct stream *s, int size) { int time_diff; time_diff = g_time2() - g_training_sent_time; LOG(0, ("sound_process_training: round trip time %u", time_diff)); return 0; } /*****************************************************************************/ /* from client */ static int APP_CC sound_process_wave_confirm(struct stream *s, int size) { int wTimeStamp; int cConfirmedBlockNo; int time; int time_diff; time = g_time2(); in_uint16_le(s, wTimeStamp); in_uint8(s, cConfirmedBlockNo); time_diff = time - g_sent_time[cConfirmedBlockNo]; LOG(10, ("sound_process_wave_confirm: wTimeStamp %d, " "cConfirmedBlockNo %d time diff %d", wTimeStamp, cConfirmedBlockNo, time_diff)); return 0; } /*****************************************************************************/ /* process message in from the audio source, eg pulse, alsa on it's way to the client */ static int APP_CC process_pcm_message(int id, int size, struct stream *s) { switch (id) { case 0: sound_send_wave_data(s->p, size); break; case 1: sound_send_close(); break; default: LOG(0, ("process_pcm_message: unknown id %d", id)); break; } return 0; } /*****************************************************************************/ /* data in from audio source, eg pulse, alsa */ static int DEFAULT_CC sound_trans_audio_data_in(struct trans *trans) { struct stream *s; int id; int size; int error; if (trans == 0) { return 0; } if (trans != g_audio_c_trans) { return 1; } s = trans_get_in_s(trans); in_uint32_le(s, id); in_uint32_le(s, size); if ((id & ~3) || (size > 128 * 1024 + 8) || (size < 8)) { LOG(0, ("sound_trans_audio_data_in: bad message id %d size %d", id, size)); return 1; } LOG(10, ("sound_trans_audio_data_in: good message id %d size %d", id, size)); error = trans_force_read(trans, size - 8); if (error == 0) { /* here, the entire message block is read in, process it */ error = process_pcm_message(id, size - 8, s); } return error; } /*****************************************************************************/ /* this is a connection in on the unix domain socket */ static int DEFAULT_CC sound_trans_audio_conn_in(struct trans *trans, struct trans *new_trans) { LOG(0, ("sound_trans_audio_conn_in:")); if (trans == 0) { return 1; } if (trans != g_audio_l_trans) { return 1; } if (g_audio_c_trans != 0) /* if already set, error */ { return 1; } if (new_trans == 0) { return 1; } g_audio_c_trans = new_trans; g_audio_c_trans->trans_data_in = sound_trans_audio_data_in; g_audio_c_trans->header_size = 8; trans_delete(g_audio_l_trans); g_audio_l_trans = 0; return 0; } /*****************************************************************************/ int APP_CC sound_init(void) { char port[256]; int error; LOG(0, ("sound_init:")); sound_send_server_formats(); g_audio_l_trans = trans_create(2, 128 * 1024, 8192); g_snprintf(port, 255, CHANSRV_PORT_STR, g_display_num); g_audio_l_trans->trans_conn_in = sound_trans_audio_conn_in; error = trans_listen(g_audio_l_trans, port); if (error != 0) { LOG(0, ("sound_init: trans_listen failed")); } #if defined(XRDP_SIMPLESOUND) /* start thread to read raw audio data from pulseaudio device */ tc_thread_create(read_raw_audio_data, 0); #endif return 0; } /*****************************************************************************/ int APP_CC sound_deinit(void) { if (g_audio_l_trans != 0) { trans_delete(g_audio_l_trans); g_audio_l_trans = 0; } if (g_audio_c_trans != 0) { trans_delete(g_audio_c_trans); g_audio_c_trans = 0; } return 0; } /*****************************************************************************/ /* data in from client ( client -> xrdp -> chansrv ) */ int APP_CC sound_data_in(struct stream *s, int chan_id, int chan_flags, int length, int total_length) { int code; int size; in_uint8(s, code); in_uint8s(s, 1); in_uint16_le(s, size); switch (code) { case SNDC_WAVECONFIRM: sound_process_wave_confirm(s, size); break; case SNDC_TRAINING: sound_process_training(s, size); break; case SNDC_FORMATS: sound_process_formats(s, size); break; default: LOG(0, ("sound_data_in: unknown code %d size %d", code, size)); break; } return 0; } /*****************************************************************************/ int APP_CC sound_get_wait_objs(tbus *objs, int *count, int *timeout) { int lcount; lcount = *count; if (g_audio_l_trans != 0) { objs[lcount] = g_audio_l_trans->sck; lcount++; } if (g_audio_c_trans != 0) { objs[lcount] = g_audio_c_trans->sck; lcount++; } *count = lcount; return 0; } /*****************************************************************************/ int APP_CC sound_check_wait_objs(void) { if (g_audio_l_trans != 0) { trans_check_wait_objs(g_audio_l_trans); } if (g_audio_c_trans != 0) { trans_check_wait_objs(g_audio_c_trans); } return 0; } #if defined(XRDP_SIMPLESOUND) #define AUDIO_BUF_SIZE 2048 static int DEFAULT_CC sttrans_data_in(struct trans *self) { LOG(0, ("sttrans_data_in:\n")); return 0; } /** * read raw audio data from pulseaudio device and write it * to a unix domain socket on which trans server is listening */ static void *DEFAULT_CC read_raw_audio_data(void *arg) { pa_sample_spec samp_spec; pa_simple *simple = NULL; uint32_t bytes_read; char *cptr; int i; int error; struct trans *strans; char path[256]; struct stream *outs; strans = trans_create(TRANS_MODE_UNIX, 8192, 8192); if (strans == 0) { LOG(0, ("read_raw_audio_data: trans_create failed\n")); return 0; } strans->trans_data_in = sttrans_data_in; g_snprintf(path, 255, "/tmp/xrdp_chansrv_audio_socket_%d", g_display_num); if (trans_connect(strans, "", path, 100) != 0) { LOG(0, ("read_raw_audio_data: trans_connect failed\n")); trans_delete(strans); return 0; } /* setup audio format */ samp_spec.format = PA_SAMPLE_S16LE; samp_spec.rate = 44100; samp_spec.channels = 2; /* if we are root, then for first 8 seconds connection to pulseaudo server fails; if we are non-root, then connection succeeds on first attempt; for now we have changed code to be non-root, but this may change in the future - so pretend we are root and try connecting to pulseaudio server for upto one minute */ for (i = 0; i < 60; i++) { simple = pa_simple_new(NULL, "xrdp", PA_STREAM_RECORD, NULL, "record", &samp_spec, NULL, NULL, &error); if (simple) { /* connected to pulseaudio server */ LOG(0, ("read_raw_audio_data: connected to pulseaudio server\n")); break; } LOG(0, ("read_raw_audio_data: ERROR creating PulseAudio async interface\n")); LOG(0, ("read_raw_audio_data: %s\n", pa_strerror(error))); g_sleep(1000); } if (i == 60) { /* failed to connect to audio server */ trans_delete(strans); return NULL; } /* insert header just once */ outs = trans_get_out_s(strans, 8192); out_uint32_le(outs, 0); out_uint32_le(outs, AUDIO_BUF_SIZE + 8); cptr = outs->p; out_uint8s(outs, AUDIO_BUF_SIZE); s_mark_end(outs); while (1) { /* read a block of raw audio data... */ g_memset(cptr, 0, 4); bytes_read = pa_simple_read(simple, cptr, AUDIO_BUF_SIZE, &error); if (bytes_read < 0) { LOG(0, ("read_raw_audio_data: ERROR reading from pulseaudio stream\n")); LOG(0, ("read_raw_audio_data: %s\n", pa_strerror(error))); break; } /* bug workaround: even when there is no audio data, pulseaudio is returning without errors but the data itself is zero; we use this zero data to determine that there is no audio data present */ if (*cptr == 0 && *(cptr + 1) == 0 && *(cptr + 2) == 0 && *(cptr + 3) == 0) { g_sleep(10); continue; } if (trans_force_write_s(strans, outs) != 0) { LOG(0, ("read_raw_audio_data: ERROR writing audio data to server\n")); break; } } pa_simple_free(simple); trans_delete(strans); return NULL; } #endif