/*
* FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application
* Copyright (C) 2005/2006, Anthony Minessale II <anthmct@yahoo.com>
*
* Version: MPL 1.1
*
* The contents of this file are subject to the Mozilla Public License Version
* 1.1 (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.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS IS" basis,
* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
* for the specific language governing rights and limitations under the
* License.
*
* The Original Code is FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application
*
* The Initial Developer of the Original Code is
* Anthony Minessale II <anthmct@yahoo.com>
* Portions created by the Initial Developer are Copyright (C)
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
*
* Anthony Minessale II <anthmct@yahoo.com>
* Michael Jerris <mike@jerris.com>
* Paul D. Tinsley <pdt at jackhammer.org>
*
*
* switch_core_io.c -- Main Core Library (Media I/O)
*
*/
#include <switch.h>
#include "private/switch_core_pvt.h"
SWITCH_DECLARE(switch_status_t) switch_core_session_write_video_frame(switch_core_session_t *session, switch_frame_t *frame, switch_io_flag_t flags,
int stream_id)
{
switch_io_event_hook_video_write_frame_t *ptr;
switch_status_t status = SWITCH_STATUS_FALSE;
if (switch_channel_get_state(session->channel) >= CS_HANGUP) {
return SWITCH_STATUS_FALSE;
}
if (session->endpoint_interface->io_routines->write_video_frame) {
if ((status = session->endpoint_interface->io_routines->write_video_frame(session, frame, flags, stream_id)) == SWITCH_STATUS_SUCCESS) {
for (ptr = session->event_hooks.video_write_frame; ptr; ptr = ptr->next) {
if ((status = ptr->video_write_frame(session, frame, flags, stream_id)) != SWITCH_STATUS_SUCCESS) {
break;
}
}
}
}
return status;
}
SWITCH_DECLARE(switch_status_t) switch_core_session_read_video_frame(switch_core_session_t *session, switch_frame_t **frame, switch_io_flag_t flags,
int stream_id)
{
switch_status_t status = SWITCH_STATUS_FALSE;
switch_io_event_hook_video_read_frame_t *ptr;
switch_assert(session != NULL);
if (switch_channel_get_state(session->channel) >= CS_HANGUP) {
return SWITCH_STATUS_FALSE;
}
if (session->endpoint_interface->io_routines->read_video_frame) {
if ((status = session->endpoint_interface->io_routines->read_video_frame(session, frame, flags, stream_id)) == SWITCH_STATUS_SUCCESS) {
for (ptr = session->event_hooks.video_read_frame; ptr; ptr = ptr->next) {
if ((status = ptr->video_read_frame(session, frame, flags, stream_id)) != SWITCH_STATUS_SUCCESS) {
break;
}
}
}
}
if (status != SWITCH_STATUS_SUCCESS) {
goto done;
}
if (!(*frame)) {
goto done;
}
switch_assert(*frame != NULL);
if (switch_test_flag(*frame, SFF_CNG)) {
status = SWITCH_STATUS_SUCCESS;
goto done;
}
done:
return status;
}
SWITCH_DECLARE(switch_status_t) switch_core_session_read_frame(switch_core_session_t *session, switch_frame_t **frame, switch_io_flag_t flags,
int stream_id)
{
switch_io_event_hook_read_frame_t *ptr;
switch_status_t status;
int need_codec, perfect, do_bugs = 0, do_resample = 0, is_cng = 0;
unsigned int flag = 0;
switch_assert(session != NULL);
top:
if (switch_channel_get_state(session->channel) >= CS_HANGUP) {
*frame = NULL;
return SWITCH_STATUS_FALSE;
}
status = SWITCH_STATUS_FALSE;
need_codec = perfect = 0;
*frame = NULL;
if (session->read_codec && session->track_duration) {
if (session->read_frame_count == 0) {
switch_event_t *event;
session->read_frame_count = (session->read_codec->implementation->actual_samples_per_second /
session->read_codec->implementation->samples_per_frame) * session->track_duration;
switch_event_create(&event, SWITCH_EVENT_SESSION_HEARTBEAT);
switch_channel_event_set_data(session->channel, event);
switch_event_fire(&event);
} else {
session->read_frame_count--;
}
}
if (switch_channel_test_flag(session->channel, CF_HOLD)) {
status = SWITCH_STATUS_BREAK;
goto even_more_done;
}
if (session->endpoint_interface->io_routines->read_frame) {
if ((status = session->endpoint_interface->io_routines->read_frame(session, frame, flags, stream_id)) == SWITCH_STATUS_SUCCESS) {
for (ptr = session->event_hooks.read_frame; ptr; ptr = ptr->next) {
if ((status = ptr->read_frame(session, frame, flags, stream_id)) != SWITCH_STATUS_SUCCESS) {
break;
}
}
}
}
if (status != SWITCH_STATUS_SUCCESS) {
goto done;
}
if (!(*frame)) {
goto done;
}
switch_assert(*frame != NULL);
if (switch_test_flag(*frame, SFF_PROXY_PACKET)) {
/* Fast PASS! */
status = SWITCH_STATUS_SUCCESS;
goto done;
}
if (switch_test_flag(*frame, SFF_CNG)) {
status = SWITCH_STATUS_SUCCESS;
if (!session->bugs) {
goto done;
}
is_cng = 1;
}
switch_assert((*frame)->codec != NULL);
if (!(session->read_codec && session->read_codec->implementation)) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "%s has no read codec.\n", switch_channel_get_name(session->channel));
return SWITCH_STATUS_FALSE;
}
if (((*frame)->codec && session->read_codec->implementation != (*frame)->codec->implementation)) {
need_codec = TRUE;
}
if (session->read_codec && !(*frame)->codec) {
need_codec = TRUE;
}
if (!session->read_codec && (*frame)->codec) {
status = SWITCH_STATUS_FALSE;
goto done;
}
if ((*frame)->codec->implementation->actual_samples_per_second != session->read_codec->implementation->actual_samples_per_second) {
do_resample = 1;
}
if (session->bugs && !need_codec) {
do_bugs = 1;
need_codec = 1;
}
if (status == SWITCH_STATUS_SUCCESS && need_codec) {
switch_frame_t *enc_frame, *read_frame = *frame;
if (!switch_test_flag(session, SSF_WARN_TRANSCODE)) {
switch_core_session_message_t msg = { 0 };
msg.message_id = SWITCH_MESSAGE_INDICATE_TRANSCODING_NECESSARY;
switch_core_session_receive_message(session, &msg);
switch_set_flag(session, SSF_WARN_TRANSCODE);
}
if (read_frame->codec || is_cng) {
session->raw_read_frame.datalen = session->raw_read_frame.buflen;
if (is_cng) {
memset(session->raw_read_frame.data, 255, read_frame->codec->implementation->bytes_per_frame);
session->raw_read_frame.datalen = read_frame->codec->implementation->bytes_per_frame;
session->raw_read_frame.samples = session->raw_read_frame.datalen / sizeof(int16_t);
read_frame = &session->raw_read_frame;
status = SWITCH_STATUS_SUCCESS;
} else {
switch_codec_t *use_codec = read_frame->codec;
if (do_bugs) {
if (!session->bug_codec.implementation) {
switch_core_codec_copy(read_frame->codec, &session->bug_codec, switch_core_session_get_pool(session));
}
use_codec = &session->bug_codec;
}
status = switch_core_codec_decode(use_codec,
session->read_codec,
read_frame->data,
read_frame->datalen,
session->read_codec->implementation->actual_samples_per_second,
session->raw_read_frame.data, &session->raw_read_frame.datalen, &session->raw_read_frame.rate, &flag);
}
if (do_resample && ((status == SWITCH_STATUS_SUCCESS) || is_cng)) {
status = SWITCH_STATUS_RESAMPLE;
}
switch (status) {
case SWITCH_STATUS_RESAMPLE:
if (!session->read_resampler) {
switch_mutex_lock(session->resample_mutex);
status = switch_resample_create(&session->read_resampler,
read_frame->codec->implementation->actual_samples_per_second,
read_frame->codec->implementation->bytes_per_frame,
session->read_codec->implementation->actual_samples_per_second,
session->read_codec->implementation->bytes_per_frame, session->pool);
switch_mutex_unlock(session->resample_mutex);
if (status != SWITCH_STATUS_SUCCESS) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Unable to allocate resampler\n");
status = SWITCH_STATUS_FALSE;
goto done;
}
}
case SWITCH_STATUS_SUCCESS:
session->raw_read_frame.samples = session->raw_read_frame.datalen / sizeof(int16_t);
session->raw_read_frame.rate = read_frame->rate;
session->raw_read_frame.timestamp = read_frame->timestamp;
session->raw_read_frame.ssrc = read_frame->ssrc;
session->raw_read_frame.seq = read_frame->seq;
session->raw_read_frame.m = read_frame->m;
session->raw_read_frame.payload = read_frame->payload;
read_frame = &session->raw_read_frame;
break;
case SWITCH_STATUS_NOOP:
if (session->read_resampler) {
switch_mutex_lock(session->resample_mutex);
switch_resample_destroy(&session->read_resampler);
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_NOTICE, "Deactivating read resampler\n");
switch_mutex_unlock(session->resample_mutex);
}
status = SWITCH_STATUS_SUCCESS;
break;
case SWITCH_STATUS_BREAK:
memset(session->raw_read_frame.data, 255, read_frame->codec->implementation->bytes_per_frame);
session->raw_read_frame.datalen = read_frame->codec->implementation->bytes_per_frame;
session->raw_read_frame.samples = session->raw_read_frame.datalen / sizeof(int16_t);
session->raw_read_frame.timestamp = read_frame->timestamp;
session->raw_read_frame.rate = read_frame->rate;
session->raw_read_frame.ssrc = read_frame->ssrc;
session->raw_read_frame.seq = read_frame->seq;
session->raw_read_frame.m = read_frame->m;
session->raw_read_frame.payload = read_frame->payload;
read_frame = &session->raw_read_frame;
status = SWITCH_STATUS_SUCCESS;
break;
default:
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Codec %s decoder error!\n", session->read_codec->codec_interface->interface_name);
goto done;
}
}
if (session->bugs) {
switch_media_bug_t *bp, *dp, *last = NULL;
switch_bool_t ok = SWITCH_TRUE;
switch_thread_rwlock_rdlock(session->bug_rwlock);
for (bp = session->bugs; bp; bp = bp->next) {
if (bp->ready && switch_test_flag(bp, SMBF_READ_STREAM)) {
switch_mutex_lock(bp->read_mutex);
switch_buffer_write(bp->raw_read_buffer, read_frame->data, read_frame->datalen);
if (bp->callback) {
if (bp->callback(bp, bp->user_data, SWITCH_ABC_TYPE_READ) == SWITCH_FALSE
|| (bp->stop_time && bp->stop_time <= switch_timestamp(NULL))) {
ok = SWITCH_FALSE;
}
}
switch_mutex_unlock(bp->read_mutex);
}
if (switch_test_flag(bp, SMBF_READ_REPLACE)) {
do_bugs = 0;
if (bp->callback) {
bp->read_replace_frame_in = read_frame;
bp->read_replace_frame_out = read_frame;
if ((ok = bp->callback(bp, bp->user_data, SWITCH_ABC_TYPE_READ_REPLACE)) == SWITCH_TRUE) {
read_frame = bp->read_replace_frame_out;
}
}
}
if (ok == SWITCH_FALSE) {
bp->ready = 0;
if (last) {
last->next = bp->next;
} else {
session->bugs = bp->next;
}
dp = bp;
bp = last;
switch_core_media_bug_close(&dp);
if (!bp) {
break;
}
continue;
}
last = bp;
}
switch_thread_rwlock_unlock(session->bug_rwlock);
}
if (do_bugs) {
goto done;
}
if (session->read_codec) {
if (session->read_resampler) {
short *data = read_frame->data;
switch_mutex_lock(session->resample_mutex);
session->read_resampler->from_len = switch_short_to_float(data, session->read_resampler->from, (int) read_frame->datalen / 2);
session->read_resampler->to_len =
switch_resample_process(session->read_resampler, session->read_resampler->from,
session->read_resampler->from_len, session->read_resampler->to, session->read_resampler->to_size, 0);
switch_float_to_short(session->read_resampler->to, data, read_frame->datalen);
read_frame->samples = session->read_resampler->to_len;
read_frame->datalen = session->read_resampler->to_len * 2;
read_frame->rate = session->read_resampler->to_rate;
switch_mutex_unlock(session->resample_mutex);
}
if (read_frame->datalen == session->read_codec->implementation->bytes_per_frame) {
perfect = TRUE;
} else {
if (!session->raw_read_buffer) {
switch_size_t bytes = session->read_codec->implementation->bytes_per_frame;
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "Engaging Read Buffer at %u bytes vs %u\n",
(uint32_t) bytes, (uint32_t) (*frame)->datalen);
switch_buffer_create_dynamic(&session->raw_read_buffer, bytes * SWITCH_BUFFER_BLOCK_FRAMES, bytes * SWITCH_BUFFER_START_FRAMES, 0);
}
if (!switch_buffer_write(session->raw_read_buffer, read_frame->data, read_frame->datalen)) {
status = SWITCH_STATUS_MEMERR;
goto done;
}
}
if (perfect || switch_buffer_inuse(session->raw_read_buffer) >= session->read_codec->implementation->bytes_per_frame) {
if (perfect) {
enc_frame = read_frame;
session->raw_read_frame.rate = read_frame->rate;
} else {
session->raw_read_frame.datalen = (uint32_t) switch_buffer_read(session->raw_read_buffer,
session->raw_read_frame.data,
session->read_codec->implementation->bytes_per_frame);
session->raw_read_frame.rate = session->read_codec->implementation->actual_samples_per_second;
enc_frame = &session->raw_read_frame;
}
session->enc_read_frame.datalen = session->enc_read_frame.buflen;
switch_assert(session->read_codec != NULL);
switch_assert(enc_frame != NULL);
switch_assert(enc_frame->data != NULL);
status = switch_core_codec_encode(session->read_codec,
enc_frame->codec,
enc_frame->data,
enc_frame->datalen,
session->read_codec->implementation->actual_samples_per_second,
session->enc_read_frame.data, &session->enc_read_frame.datalen, &session->enc_read_frame.rate, &flag);
switch (status) {
case SWITCH_STATUS_RESAMPLE:
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "Fixme 1\n");
case SWITCH_STATUS_SUCCESS:
session->enc_read_frame.samples = session->read_codec->implementation->bytes_per_frame / sizeof(int16_t);
if (perfect) {
session->enc_read_frame.timestamp = read_frame->timestamp;
session->enc_read_frame.rate = read_frame->rate;
session->enc_read_frame.ssrc = read_frame->ssrc;
session->enc_read_frame.seq = read_frame->seq;
session->enc_read_frame.m = read_frame->m;
session->enc_read_frame.payload = session->read_codec->implementation->ianacode;
}
*frame = &session->enc_read_frame;
break;
case SWITCH_STATUS_NOOP:
session->raw_read_frame.samples = enc_frame->codec->implementation->samples_per_frame;
session->raw_read_frame.timestamp = read_frame->timestamp;
session->raw_read_frame.payload = enc_frame->codec->implementation->ianacode;
session->raw_read_frame.m = read_frame->m;
session->raw_read_frame.ssrc = read_frame->ssrc;
session->raw_read_frame.seq = read_frame->seq;
*frame = &session->raw_read_frame;
status = SWITCH_STATUS_SUCCESS;
break;
default:
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Codec %s encoder error!\n",
session->read_codec->codec_interface->interface_name);
*frame = NULL;
status = SWITCH_STATUS_GENERR;
break;
}
} else {
goto top;
}
}
}
done:
if (!(*frame)) {
status = SWITCH_STATUS_FALSE;
} else {
if (flag & SFF_CNG) {
switch_set_flag((*frame), SFF_CNG);
}
if (session->bugs) {
switch_media_bug_t *bp, *dp, *last = NULL;
switch_bool_t ok = SWITCH_TRUE;
switch_thread_rwlock_rdlock(session->bug_rwlock);
for (bp = session->bugs; bp; bp = bp->next) {
if (bp->ready && switch_test_flag(bp, SMBF_READ_PING)) {
switch_mutex_lock(bp->read_mutex);
if (bp->callback) {
if (bp->callback(bp, bp->user_data, SWITCH_ABC_TYPE_READ_PING) == SWITCH_FALSE
|| (bp->stop_time && bp->stop_time <= switch_timestamp(NULL))) {
ok = SWITCH_FALSE;
}
}
switch_mutex_unlock(bp->read_mutex);
}
if (ok == SWITCH_FALSE) {
bp->ready = 0;
if (last) {
last->next = bp->next;
} else {
session->bugs = bp->next;
}
dp = bp;
bp = last;
switch_core_media_bug_close(&dp);
if (!bp) {
break;
}
continue;
}
last = bp;
}
switch_thread_rwlock_unlock(session->bug_rwlock);
}
}
even_more_done:
if (!*frame || !(*frame)->codec || !(*frame)->codec->implementation) {
*frame = &runtime.dummy_cng_frame;
}
return status;
}
static switch_status_t perform_write(switch_core_session_t *session, switch_frame_t *frame, switch_io_flag_t flags, int stream_id)
{
switch_io_event_hook_write_frame_t *ptr;
switch_status_t status = SWITCH_STATUS_FALSE;
if (session->endpoint_interface->io_routines->write_frame) {
if ((status = session->endpoint_interface->io_routines->write_frame(session, frame, flags, stream_id)) == SWITCH_STATUS_SUCCESS) {
for (ptr = session->event_hooks.write_frame; ptr; ptr = ptr->next) {
if ((status = ptr->write_frame(session, frame, flags, stream_id)) != SWITCH_STATUS_SUCCESS) {
break;
}
}
}
}
return status;
}
SWITCH_DECLARE(switch_status_t) switch_core_session_write_frame(switch_core_session_t *session, switch_frame_t *frame, switch_io_flag_t flags,
int stream_id)
{
switch_status_t status = SWITCH_STATUS_FALSE;
switch_frame_t *enc_frame = NULL, *write_frame = frame;
unsigned int flag = 0, need_codec = 0, perfect = 0, do_bugs = 0, do_write = 0, do_resample = 0, ptime_mismatch = 0, pass_cng = 0;
switch_assert(session != NULL);
switch_assert(frame != NULL);
if (switch_channel_get_state(session->channel) >= CS_HANGUP) {
return SWITCH_STATUS_FALSE;
}
if (switch_test_flag(frame, SFF_CNG)) {
if (switch_channel_test_flag(session->channel, CF_ACCEPT_CNG)) {
pass_cng = 1;
}
return SWITCH_STATUS_SUCCESS;
}
if (!(session->write_codec && session->write_codec->implementation) && !pass_cng) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "%s has no write codec.\n", switch_channel_get_name(session->channel));
return SWITCH_STATUS_FALSE;
}
if (switch_channel_test_flag(session->channel, CF_HOLD)) {
return SWITCH_STATUS_SUCCESS;
}
if (switch_test_flag(frame, SFF_PROXY_PACKET) || pass_cng) {
/* Fast PASS! */
return perform_write(session, frame, flag, stream_id);
}
switch_assert(frame->codec != NULL);
switch_assert(frame->codec->implementation != NULL);
if ((session->write_codec && frame->codec && session->write_codec->implementation != frame->codec->implementation)) {
need_codec = TRUE;
if (session->write_codec->implementation->codec_id == frame->codec->implementation->codec_id) {
ptime_mismatch = TRUE;
}
}
if (session->write_codec && !frame->codec) {
need_codec = TRUE;
}
if (!session->write_codec && frame->codec) {
return SWITCH_STATUS_FALSE;
}
if (session->bugs && !need_codec) {
do_bugs = TRUE;
need_codec = TRUE;
}
if (frame->codec->implementation->actual_samples_per_second != session->write_codec->implementation->actual_samples_per_second) {
need_codec = TRUE;
do_resample = TRUE;
}
if (need_codec) {
if (!switch_test_flag(session, SSF_WARN_TRANSCODE)) {
switch_core_session_message_t msg = { 0 };
msg.message_id = SWITCH_MESSAGE_INDICATE_TRANSCODING_NECESSARY;
switch_core_session_receive_message(session, &msg);
switch_set_flag(session, SSF_WARN_TRANSCODE);
}
if (frame->codec) {
session->raw_write_frame.datalen = session->raw_write_frame.buflen;
status = switch_core_codec_decode(frame->codec,
session->write_codec,
frame->data,
frame->datalen,
session->write_codec->implementation->actual_samples_per_second,
session->raw_write_frame.data, &session->raw_write_frame.datalen, &session->raw_write_frame.rate, &flag);
if (do_resample && status == SWITCH_STATUS_SUCCESS) {
status = SWITCH_STATUS_RESAMPLE;
}
switch (status) {
case SWITCH_STATUS_RESAMPLE:
write_frame = &session->raw_write_frame;
if (!session->write_resampler) {
switch_mutex_lock(session->resample_mutex);
status = switch_resample_create(&session->write_resampler,
frame->codec->implementation->actual_samples_per_second,
frame->codec->implementation->bytes_per_frame,
session->write_codec->implementation->actual_samples_per_second,
session->write_codec->implementation->bytes_per_frame, session->pool);
switch_mutex_unlock(session->resample_mutex);
if (status != SWITCH_STATUS_SUCCESS) {
goto done;
}
}
break;
case SWITCH_STATUS_SUCCESS:
session->raw_write_frame.samples = session->raw_write_frame.datalen / sizeof(int16_t);
session->raw_write_frame.timestamp = frame->timestamp;
session->raw_write_frame.rate = frame->rate;
session->raw_write_frame.m = frame->m;
session->raw_write_frame.ssrc = frame->ssrc;
session->raw_write_frame.seq = frame->seq;
session->raw_write_frame.payload = frame->payload;
write_frame = &session->raw_write_frame;
break;
case SWITCH_STATUS_BREAK:
return SWITCH_STATUS_SUCCESS;
case SWITCH_STATUS_NOOP:
if (session->write_resampler) {
switch_mutex_lock(session->resample_mutex);
switch_resample_destroy(&session->write_resampler);
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_NOTICE, "Deactivating write resampler\n");
switch_mutex_unlock(session->resample_mutex);
}
write_frame = frame;
status = SWITCH_STATUS_SUCCESS;
break;
default:
if (ptime_mismatch) {
status = perform_write(session, frame, flags, stream_id);
return SWITCH_STATUS_SUCCESS;
}
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Codec %s decoder error!\n", frame->codec->codec_interface->interface_name);
return status;
}
}
if (session->write_resampler) {
short *data = write_frame->data;
switch_mutex_lock(session->resample_mutex);
session->write_resampler->from_len = write_frame->datalen / 2;
switch_short_to_float(data, session->write_resampler->from, session->write_resampler->from_len);
session->write_resampler->to_len = (uint32_t)
switch_resample_process(session->write_resampler, session->write_resampler->from,
session->write_resampler->from_len, session->write_resampler->to, session->write_resampler->to_size, 0);
switch_float_to_short(session->write_resampler->to, data, session->write_resampler->to_len);
write_frame->samples = session->write_resampler->to_len;
write_frame->datalen = write_frame->samples * 2;
write_frame->rate = session->write_resampler->to_rate;
switch_mutex_unlock(session->resample_mutex);
}
if (session->bugs) {
switch_media_bug_t *bp, *dp, *last = NULL;
switch_thread_rwlock_rdlock(session->bug_rwlock);
for (bp = session->bugs; bp; bp = bp->next) {
switch_bool_t ok = SWITCH_TRUE;
if (!bp->ready) {
continue;
}
if (switch_test_flag(bp, SMBF_WRITE_STREAM)) {
switch_mutex_lock(bp->write_mutex);
switch_buffer_write(bp->raw_write_buffer, write_frame->data, write_frame->datalen);
switch_mutex_unlock(bp->write_mutex);
if (bp->callback) {
ok = bp->callback(bp, bp->user_data, SWITCH_ABC_TYPE_WRITE);
}
}
if (switch_test_flag(bp, SMBF_WRITE_REPLACE)) {
do_bugs = 0;
if (bp->callback) {
bp->write_replace_frame_in = write_frame;
bp->write_replace_frame_out = write_frame;
if ((ok = bp->callback(bp, bp->user_data, SWITCH_ABC_TYPE_WRITE_REPLACE)) == SWITCH_TRUE) {
write_frame = bp->write_replace_frame_out;
}
}
}
if (bp->stop_time && bp->stop_time <= switch_timestamp(NULL)) {
ok = SWITCH_FALSE;
}
if (ok == SWITCH_FALSE) {
bp->ready = 0;
if (last) {
last->next = bp->next;
} else {
session->bugs = bp->next;
}
dp = bp;
bp = last;
switch_core_media_bug_close(&dp);
if (!bp) {
break;
}
continue;
}
last = bp;
}
switch_thread_rwlock_unlock(session->bug_rwlock);
}
if (do_bugs) {
do_write = TRUE;
write_frame = frame;
goto done;
}
if (session->write_codec) {
if (write_frame->datalen == session->write_codec->implementation->bytes_per_frame) {
perfect = TRUE;
} else {
if (!session->raw_write_buffer) {
switch_size_t bytes = session->write_codec->implementation->bytes_per_frame;
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG,
"Engaging Write Buffer at %u bytes to accommodate %u->%u\n",
(uint32_t) bytes, write_frame->datalen, session->write_codec->implementation->bytes_per_frame);
if ((status = switch_buffer_create_dynamic(&session->raw_write_buffer,
bytes * SWITCH_BUFFER_BLOCK_FRAMES,
bytes * SWITCH_BUFFER_START_FRAMES, 0)) != SWITCH_STATUS_SUCCESS) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Write Buffer Failed!\n");
return status;
}
}
if (!(switch_buffer_write(session->raw_write_buffer, write_frame->data, write_frame->datalen))) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Write Buffer %u bytes Failed!\n", write_frame->datalen);
return SWITCH_STATUS_MEMERR;
}
}
if (perfect) {
enc_frame = write_frame;
session->enc_write_frame.datalen = session->enc_write_frame.buflen;
status = switch_core_codec_encode(session->write_codec,
frame->codec,
enc_frame->data,
enc_frame->datalen,
session->write_codec->implementation->actual_samples_per_second,
session->enc_write_frame.data, &session->enc_write_frame.datalen, &session->enc_write_frame.rate, &flag);
switch (status) {
case SWITCH_STATUS_RESAMPLE:
/* switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "Fixme 2\n"); */
case SWITCH_STATUS_SUCCESS:
session->enc_write_frame.codec = session->write_codec;
session->enc_write_frame.samples = enc_frame->datalen / sizeof(int16_t);
session->enc_write_frame.timestamp = frame->timestamp;
session->enc_write_frame.payload = session->write_codec->implementation->ianacode;
session->enc_write_frame.m = frame->m;
session->enc_write_frame.ssrc = frame->ssrc;
session->enc_write_frame.seq = frame->seq;
write_frame = &session->enc_write_frame;
break;
case SWITCH_STATUS_NOOP:
enc_frame->codec = session->write_codec;
enc_frame->samples = enc_frame->datalen / sizeof(int16_t);
enc_frame->timestamp = frame->timestamp;
enc_frame->m = frame->m;
enc_frame->seq = frame->seq;
enc_frame->ssrc = frame->ssrc;
enc_frame->payload = enc_frame->codec->implementation->ianacode;
write_frame = enc_frame;
status = SWITCH_STATUS_SUCCESS;
break;
default:
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Codec %s encoder error!\n",
session->read_codec->codec_interface->interface_name);
write_frame = NULL;
return status;
}
if (flag & SFF_CNG) {
switch_set_flag(write_frame, SFF_CNG);
}
status = perform_write(session, write_frame, flags, stream_id);
return status;
} else {
switch_size_t used = switch_buffer_inuse(session->raw_write_buffer);
uint32_t bytes = session->write_codec->implementation->bytes_per_frame;
switch_size_t frames = (used / bytes);
status = SWITCH_STATUS_SUCCESS;
if (!frames) {
return status;
} else {
switch_size_t x;
for (x = 0; x < frames; x++) {
if ((session->raw_write_frame.datalen = (uint32_t)
switch_buffer_read(session->raw_write_buffer, session->raw_write_frame.data, bytes)) != 0) {
int rate;
enc_frame = &session->raw_write_frame;
session->raw_write_frame.rate = session->write_codec->implementation->actual_samples_per_second;
session->enc_write_frame.datalen = session->enc_write_frame.buflen;
if (frame->codec && frame->codec->implementation) {
rate = frame->codec->implementation->actual_samples_per_second;
} else {
rate = session->write_codec->implementation->actual_samples_per_second;
}
status = switch_core_codec_encode(session->write_codec,
frame->codec,
enc_frame->data,
enc_frame->datalen,
rate,
session->enc_write_frame.data,
&session->enc_write_frame.datalen, &session->enc_write_frame.rate, &flag);
switch (status) {
case SWITCH_STATUS_RESAMPLE:
session->enc_write_frame.codec = session->write_codec;
session->enc_write_frame.samples = enc_frame->datalen / sizeof(int16_t);
session->enc_write_frame.m = frame->m;
session->enc_write_frame.ssrc = frame->ssrc;
session->enc_write_frame.payload = session->write_codec->implementation->ianacode;
write_frame = &session->enc_write_frame;
if (!session->write_resampler) {
switch_mutex_lock(session->resample_mutex);
status = switch_resample_create(&session->write_resampler,
frame->codec->implementation->actual_samples_per_second,
frame->codec->implementation->bytes_per_frame,
session->write_codec->implementation->actual_samples_per_second,
session->write_codec->implementation->bytes_per_frame, session->pool);
switch_mutex_unlock(session->resample_mutex);
if (status != SWITCH_STATUS_SUCCESS) {
goto done;
}
}
break;
case SWITCH_STATUS_SUCCESS:
session->enc_write_frame.codec = session->write_codec;
session->enc_write_frame.samples = enc_frame->datalen / sizeof(int16_t);
session->enc_write_frame.m = frame->m;
session->enc_write_frame.ssrc = frame->ssrc;
session->enc_write_frame.payload = session->write_codec->implementation->ianacode;
write_frame = &session->enc_write_frame;
break;
case SWITCH_STATUS_NOOP:
if (session->write_resampler) {
switch_mutex_lock(session->resample_mutex);
switch_resample_destroy(&session->write_resampler);
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_NOTICE, "Deactivating write resampler\n");
switch_mutex_unlock(session->resample_mutex);
}
enc_frame->codec = session->write_codec;
enc_frame->samples = enc_frame->datalen / sizeof(int16_t);
enc_frame->m = frame->m;
enc_frame->ssrc = frame->ssrc;
enc_frame->payload = enc_frame->codec->implementation->ianacode;
write_frame = enc_frame;
status = SWITCH_STATUS_SUCCESS;
break;
default:
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Codec %s encoder error %d!\n",
session->read_codec->codec_interface->interface_name, status);
write_frame = NULL;
return status;
}
if (session->read_resampler) {
short *data = write_frame->data;
switch_mutex_lock(session->resample_mutex);
session->read_resampler->from_len =
switch_short_to_float(data, session->read_resampler->from, (int) write_frame->datalen / 2);
session->read_resampler->to_len = (uint32_t)
switch_resample_process(session->read_resampler, session->read_resampler->from,
session->read_resampler->from_len,
session->read_resampler->to, session->read_resampler->to_size, 0);
switch_float_to_short(session->read_resampler->to, data, write_frame->datalen * 2);
write_frame->samples = session->read_resampler->to_len;
write_frame->datalen = session->read_resampler->to_len * 2;
write_frame->rate = session->read_resampler->to_rate;
switch_mutex_unlock(session->resample_mutex);
}
if (flag & SFF_CNG) {
switch_set_flag(write_frame, SFF_CNG);
}
if ((status = perform_write(session, write_frame, flags, stream_id)) != SWITCH_STATUS_SUCCESS) {
break;
}
}
}
return status;
}
}
}
} else {
do_write = TRUE;
}
done:
if (do_write) {
return perform_write(session, frame, flags, stream_id);
}
return status;
}
static char *SIG_NAMES[] = {
"NONE",
"KILL",
"XFER",
"BREAK",
NULL
};
SWITCH_DECLARE(switch_status_t) switch_core_session_perform_kill_channel(switch_core_session_t *session,
const char *file, const char *func, int line, switch_signal_t sig)
{
switch_io_event_hook_kill_channel_t *ptr;
switch_status_t status = SWITCH_STATUS_FALSE;
switch_log_printf(SWITCH_CHANNEL_ID_LOG, file, func, line, NULL, SWITCH_LOG_DEBUG, "Send signal %s [%s]\n", switch_channel_get_name(session->channel),
SIG_NAMES[sig]);
if (session->endpoint_interface->io_routines->kill_channel) {
if ((status = session->endpoint_interface->io_routines->kill_channel(session, sig)) == SWITCH_STATUS_SUCCESS) {
for (ptr = session->event_hooks.kill_channel; ptr; ptr = ptr->next) {
if ((status = ptr->kill_channel(session, sig)) != SWITCH_STATUS_SUCCESS) {
break;
}
}
}
}
return status;
}
SWITCH_DECLARE(switch_status_t) switch_core_session_recv_dtmf(switch_core_session_t *session, const switch_dtmf_t *dtmf)
{
switch_io_event_hook_recv_dtmf_t *ptr;
switch_status_t status;
switch_dtmf_t new_dtmf;
if (switch_channel_get_state(session->channel) >= CS_HANGUP) {
return SWITCH_STATUS_FALSE;
}
switch_assert(dtmf);
new_dtmf = *dtmf;
if (new_dtmf.duration > switch_core_max_dtmf_duration(0)) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_WARNING, "%s EXCESSIVE DTMF DIGIT [%c] LEN [%d]\n",
switch_channel_get_name(session->channel), new_dtmf.digit, new_dtmf.duration);
new_dtmf.duration = switch_core_max_dtmf_duration(0);
} else if (!new_dtmf.duration) {
new_dtmf.duration = switch_core_default_dtmf_duration(0);
}
for (ptr = session->event_hooks.recv_dtmf; ptr; ptr = ptr->next) {
if ((status = ptr->recv_dtmf(session, &new_dtmf, SWITCH_DTMF_RECV)) != SWITCH_STATUS_SUCCESS) {
return status;
}
}
return SWITCH_STATUS_SUCCESS;
}
SWITCH_DECLARE(switch_status_t) switch_core_session_send_dtmf(switch_core_session_t *session, const switch_dtmf_t *dtmf)
{
switch_io_event_hook_send_dtmf_t *ptr;
switch_status_t status = SWITCH_STATUS_FALSE;
switch_dtmf_t new_dtmf;
if (switch_channel_get_state(session->channel) >= CS_HANGUP) {
return SWITCH_STATUS_FALSE;
}
switch_assert(dtmf);
new_dtmf = *dtmf;
if (new_dtmf.duration > switch_core_max_dtmf_duration(0)) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_WARNING, "%s EXCESSIVE DTMF DIGIT [%c] LEN [%d]\n",
switch_channel_get_name(session->channel), new_dtmf.digit, new_dtmf.duration);
new_dtmf.duration = switch_core_max_dtmf_duration(0);
} else if (!new_dtmf.duration) {
new_dtmf.duration = switch_core_default_dtmf_duration(0);
}
for (ptr = session->event_hooks.send_dtmf; ptr; ptr = ptr->next) {
if ((status = ptr->send_dtmf(session, dtmf, SWITCH_DTMF_SEND)) != SWITCH_STATUS_SUCCESS) {
return SWITCH_STATUS_SUCCESS;
}
}
if (session->endpoint_interface->io_routines->send_dtmf) {
if (dtmf->digit == 'w') {
switch_yield(500000);
} else if (dtmf->digit == 'W') {
switch_yield(1000000);
} else {
status = session->endpoint_interface->io_routines->send_dtmf(session, &new_dtmf);
}
}
return status;
}
SWITCH_DECLARE(switch_status_t) switch_core_session_send_dtmf_string(switch_core_session_t *session, const char *dtmf_string)
{
char *p;
switch_dtmf_t dtmf = { 0, switch_core_default_dtmf_duration(0) };
int sent = 0, dur;
char *string;
int i, argc;
char *argv[256];
int dur_total = 0;
switch_assert(session != NULL);
if (switch_channel_get_state(session->channel) >= CS_HANGUP) {
return SWITCH_STATUS_FALSE;
}
if (switch_strlen_zero(dtmf_string)) {
return SWITCH_STATUS_FALSE;
}
if (strlen(dtmf_string) > 99) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Attempt to send very large dtmf string ignored!\n");
return SWITCH_STATUS_FALSE;
}
string = switch_core_session_strdup(session, dtmf_string);
argc = switch_separate_string(string, '+', argv, (sizeof(argv) / sizeof(argv[0])));
if (argc) {
switch_channel_pre_answer(session->channel);
}
for (i = 0; i < argc; i++) {
dtmf.duration = switch_core_default_dtmf_duration(0);
dur = switch_core_default_dtmf_duration(0) / 8;
if ((p = strchr(argv[i], '@'))) {
*p++ = '\0';
if ((dur = atoi(p)) > 50) {
dtmf.duration = dur * 8;
}
}
if (dtmf.duration > switch_core_max_dtmf_duration(0)) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_WARNING, "%s EXCESSIVE DTMF DIGIT [%c] LEN [%d]\n",
switch_channel_get_name(session->channel), dtmf.digit, dtmf.duration);
dtmf.duration = switch_core_max_dtmf_duration(0);
} else if (!dtmf.duration) {
dtmf.duration = switch_core_default_dtmf_duration(0);
}
for (p = argv[i]; p && *p; p++) {
if (is_dtmf(*p)) {
dtmf.digit = *p;
if (switch_core_session_send_dtmf(session, &dtmf) == SWITCH_STATUS_SUCCESS) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "%s send dtmf\ndigit=%c ms=%u samples=%u\n",
switch_channel_get_name(session->channel), dtmf.digit, dur, dtmf.duration);
sent++;
dur_total += dtmf.duration + 2000; /* account for 250ms pause */
}
}
}
if (dur_total) {
char tmp[32] = "";
switch_snprintf(tmp, sizeof(tmp), "%d", dur_total / 8);
switch_channel_set_variable(session->channel, "last_dtmf_duration", tmp);
}
}
return sent ? SWITCH_STATUS_SUCCESS : SWITCH_STATUS_FALSE;
}
/* For Emacs:
* Local Variables:
* mode:c
* indent-tabs-mode:t
* tab-width:4
* c-basic-offset:4
* End:
* For VIM:
* vim:set softtabstop=4 shiftwidth=4 tabstop=4:
*/