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freeswitch/libs/freetdm/src/ftdm_io.c

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/*
* Copyright (c) 2007-2014, Anthony Minessale II
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* * Neither the name of the original author; nor the names of any contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
* OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* Contributors:
*
* Moises Silva <moy@sangoma.com>
* David Yat Sin <dyatsin@sangoma.com>
*
*/
#define _GNU_SOURCE
#include "private/ftdm_core.h"
#include <stdarg.h>
#include <ctype.h>
#ifdef WIN32
#include <io.h>
#endif
#ifdef FTDM_PIKA_SUPPORT
#include "ftdm_pika.h"
#endif
#include "ftdm_cpu_monitor.h"
#ifndef localtime_r
struct tm *localtime_r(const time_t *clock, struct tm *result);
#endif
#define FORCE_HANGUP_TIMER 30000
#define FTDM_READ_TRACE_INDEX 0
#define FTDM_WRITE_TRACE_INDEX 1
#define MAX_CALLIDS 6000
#define FTDM_HALF_DTMF_PAUSE 500
#define FTDM_FULL_DTMF_PAUSE 1000
ftdm_time_t time_last_throttle_log = 0;
ftdm_time_t time_current_throttle_log = 0;
typedef struct val_str {
const char *str;
unsigned long long val;
} val_str_t;
static val_str_t channel_flag_strs[] = {
{ "configured" , FTDM_CHANNEL_CONFIGURED},
{ "ready", FTDM_CHANNEL_READY},
{ "open", FTDM_CHANNEL_OPEN},
{ "dtmf-detect", FTDM_CHANNEL_DTMF_DETECT},
{ "suppress-dtmf", FTDM_CHANNEL_SUPRESS_DTMF},
{ "transcode", FTDM_CHANNEL_TRANSCODE},
{ "buffer", FTDM_CHANNEL_BUFFER},
{ "in-thread", FTDM_CHANNEL_INTHREAD},
{ "wink", FTDM_CHANNEL_WINK},
{ "flash", FTDM_CHANNEL_FLASH},
{ "state-change", FTDM_CHANNEL_STATE_CHANGE},
{ "hold", FTDM_CHANNEL_HOLD},
{ "in-use", FTDM_CHANNEL_INUSE},
{ "off-hook", FTDM_CHANNEL_OFFHOOK},
{ "ringing", FTDM_CHANNEL_RINGING},
{ "progress-detect", FTDM_CHANNEL_PROGRESS_DETECT},
{ "callerid-detect", FTDM_CHANNEL_CALLERID_DETECT},
{ "outbound", FTDM_CHANNEL_OUTBOUND},
{ "suspended", FTDM_CHANNEL_SUSPENDED},
{ "3-way", FTDM_CHANNEL_3WAY},
{ "progress", FTDM_CHANNEL_PROGRESS},
{ "media", FTDM_CHANNEL_MEDIA},
{ "answered", FTDM_CHANNEL_ANSWERED},
{ "mute", FTDM_CHANNEL_MUTE},
{ "use-rx-gain", FTDM_CHANNEL_USE_RX_GAIN},
{ "use-tx-gain", FTDM_CHANNEL_USE_TX_GAIN},
{ "in-alarm", FTDM_CHANNEL_IN_ALARM},
{ "sig-up", FTDM_CHANNEL_SIG_UP},
{ "user-hangup", FTDM_CHANNEL_USER_HANGUP},
{ "rx-disabled", FTDM_CHANNEL_RX_DISABLED},
{ "tx-disabled", FTDM_CHANNEL_TX_DISABLED},
{ "call-started", FTDM_CHANNEL_CALL_STARTED},
{ "non-block", FTDM_CHANNEL_NONBLOCK},
{ "ind-ack-pending", FTDM_CHANNEL_IND_ACK_PENDING},
{ "blocking", FTDM_CHANNEL_BLOCKING},
{ "media", FTDM_CHANNEL_DIGITAL_MEDIA},
{ "native-sigbridge", FTDM_CHANNEL_NATIVE_SIGBRIDGE},
{ "invalid", FTDM_CHANNEL_MAX_FLAG},
};
static val_str_t span_flag_strs[] = {
{ "configured", FTDM_SPAN_CONFIGURED},
{ "started", FTDM_SPAN_STARTED},
{ "state-change", FTDM_SPAN_STATE_CHANGE},
{ "suspended", FTDM_SPAN_SUSPENDED},
{ "in-thread", FTDM_SPAN_IN_THREAD},
{ "stop-thread", FTDM_SPAN_STOP_THREAD},
{ "use-chan-queue", FTDM_SPAN_USE_CHAN_QUEUE},
{ "suggest-chan-id", FTDM_SPAN_SUGGEST_CHAN_ID},
{ "use-av-rate", FTDM_SPAN_USE_AV_RATE},
{ "power-saving", FTDM_SPAN_PWR_SAVING},
{ "signals-queue", FTDM_SPAN_USE_SIGNALS_QUEUE},
{ "proceed-state", FTDM_SPAN_USE_PROCEED_STATE},
{ "skip-state", FTDM_SPAN_USE_SKIP_STATES},
{ "non-stoppable", FTDM_SPAN_NON_STOPPABLE},
{ "use-transfer", FTDM_SPAN_USE_TRANSFER},
};
static ftdm_status_t ftdm_call_set_call_id(ftdm_channel_t *fchan, ftdm_caller_data_t *caller_data);
static ftdm_status_t ftdm_call_clear_call_id(ftdm_caller_data_t *caller_data);
static ftdm_status_t ftdm_channel_done(ftdm_channel_t *ftdmchan);
static ftdm_status_t ftdm_channel_sig_indicate(ftdm_channel_t *ftdmchan, ftdm_channel_indication_t indication, ftdm_usrmsg_t *usrmsg);
static const char *ftdm_val2str(unsigned long long val, val_str_t *val_str_table, ftdm_size_t array_size, const char *default_str);
static unsigned long long ftdm_str2val(const char *str, val_str_t *val_str_table, ftdm_size_t array_size, unsigned long long default_val);
static int time_is_init = 0;
static void time_init(void)
{
#ifdef WIN32
timeBeginPeriod(1);
#endif
time_is_init = 1;
}
static void time_end(void)
{
#ifdef WIN32
timeEndPeriod(1);
#endif
time_is_init = 0;
}
FT_DECLARE(ftdm_time_t) ftdm_current_time_in_ms(void)
{
#ifdef WIN32
return timeGetTime();
#else
struct timeval tv;
gettimeofday(&tv, NULL);
return ((tv.tv_sec * 1000) + (tv.tv_usec / 1000));
#endif
}
static void write_chan_io_dump(ftdm_io_dump_t *dump, char *dataptr, int dlen)
{
int windex = dump->windex;
int avail = (int)dump->size - windex;
if (!dump->buffer) {
return;
}
if (dlen > avail) {
int diff = dlen - avail;
ftdm_assert(diff < (int)dump->size, "Very small buffer or very big IO chunk!\n");
/* write only what we can and the rest at the beginning of the buffer */
memcpy(&dump->buffer[windex], dataptr, avail);
memcpy(&dump->buffer[0], &dataptr[avail], diff);
windex = diff;
/*ftdm_log_chan(fchan, FTDM_LOG_DEBUG, "wrapping around dump buffer %p up to index %d\n\n", dump, windex);*/
dump->wrapped = 1;
} else {
memcpy(&dump->buffer[windex], dataptr, dlen);
windex += dlen;
}
if (windex == (int)dump->size) {
/*ftdm_log_chan(fchan, FTDM_LOG_DEBUG, "wrapping around dump buffer %p\n", dump);*/
windex = 0;
dump->wrapped = 1;
}
dump->windex = windex;
}
static void dump_chan_io_to_file(ftdm_channel_t *fchan, ftdm_io_dump_t *dump, FILE *file)
{
/* write the saved audio buffer */
ftdm_size_t rc = 0;
ftdm_size_t towrite = 0;
if (!dump->buffer) {
return;
}
towrite = dump->size - dump->windex;
if (dump->wrapped) {
rc = fwrite(&dump->buffer[dump->windex], 1, towrite, file);
if (rc != towrite) {
ftdm_log_chan(fchan, FTDM_LOG_ERROR, "only wrote %"FTDM_SIZE_FMT" out of %"FTDM_SIZE_FMT" bytes in io dump buffer: %s\n",
rc, towrite, strerror(errno));
}
}
if (dump->windex) {
towrite = dump->windex;
rc = fwrite(&dump->buffer[0], 1, towrite, file);
if (rc != towrite) {
ftdm_log_chan(fchan, FTDM_LOG_ERROR, "only wrote %"FTDM_SIZE_FMT" out of %"FTDM_SIZE_FMT" bytes in io dump buffer: %s\n",
rc, towrite, strerror(errno));
}
}
dump->windex = 0;
dump->wrapped = 0;
}
static void stop_chan_io_dump(ftdm_io_dump_t *dump)
{
if (!dump->buffer) {
return;
}
ftdm_safe_free(dump->buffer);
memset(dump, 0, sizeof(*dump));
}
static ftdm_status_t start_chan_io_dump(ftdm_channel_t *chan, ftdm_io_dump_t *dump, ftdm_size_t size)
{
if (dump->buffer) {
ftdm_log_chan_msg(chan, FTDM_LOG_ERROR, "IO dump is already started\n");
return FTDM_FAIL;
}
memset(dump, 0, sizeof(*dump));
dump->buffer = ftdm_malloc(size);
if (!dump->buffer) {
return FTDM_FAIL;
}
dump->size = size;
return FTDM_SUCCESS;
}
static void close_dtmf_debug_file(ftdm_channel_t *ftdmchan)
{
if (ftdmchan->dtmfdbg.file) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "closing debug dtmf file\n");
fclose(ftdmchan->dtmfdbg.file);
ftdmchan->dtmfdbg.file = NULL;
}
}
static ftdm_status_t disable_dtmf_debug(ftdm_channel_t *ftdmchan)
{
if (!ftdmchan->dtmfdbg.enabled) {
return FTDM_SUCCESS;
}
if (!ftdmchan->rxdump.buffer) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "DTMF debug enabled but no rx dump?\n");
return FTDM_FAIL;
}
close_dtmf_debug_file(ftdmchan);
stop_chan_io_dump(&ftdmchan->rxdump);
ftdmchan->dtmfdbg.enabled = 0;
return FTDM_SUCCESS;
}
typedef struct {
uint8_t enabled;
uint8_t running;
uint8_t alarm;
uint32_t interval;
uint8_t alarm_action_flags;
uint8_t set_alarm_threshold;
uint8_t clear_alarm_threshold;
ftdm_interrupt_t *interrupt;
} cpu_monitor_t;
static struct {
ftdm_hash_t *interface_hash;
ftdm_hash_t *module_hash;
ftdm_hash_t *span_hash;
ftdm_hash_t *group_hash;
ftdm_mutex_t *mutex;
ftdm_mutex_t *span_mutex;
ftdm_mutex_t *group_mutex;
ftdm_sched_t *timingsched;
uint32_t span_index;
uint32_t group_index;
uint32_t running;
ftdm_span_t *spans;
ftdm_group_t *groups;
cpu_monitor_t cpu_monitor;
ftdm_caller_data_t *call_ids[MAX_CALLIDS+1];
ftdm_mutex_t *call_id_mutex;
uint32_t last_call_id;
char dtmfdebug_directory[1024];
} globals;
enum ftdm_enum_cpu_alarm_action_flags
{
FTDM_CPU_ALARM_ACTION_WARN = (1 << 0),
FTDM_CPU_ALARM_ACTION_REJECT = (1 << 1)
};
/* enum lookup funcs */
FTDM_ENUM_NAMES(TONEMAP_NAMES, TONEMAP_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_tonemap, ftdm_tonemap2str, ftdm_tonemap_t, TONEMAP_NAMES, FTDM_TONEMAP_INVALID)
FTDM_ENUM_NAMES(OOB_NAMES, OOB_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_oob_event, ftdm_oob_event2str, ftdm_oob_event_t, OOB_NAMES, FTDM_OOB_INVALID)
FTDM_ENUM_NAMES(TRUNK_TYPE_NAMES, TRUNK_TYPE_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_trunk_type, ftdm_trunk_type2str, ftdm_trunk_type_t, TRUNK_TYPE_NAMES, FTDM_TRUNK_NONE)
FTDM_ENUM_NAMES(TRUNK_MODE_NAMES, TRUNK_MODE_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_trunk_mode, ftdm_trunk_mode2str, ftdm_trunk_mode_t, TRUNK_MODE_NAMES, FTDM_TRUNK_MODE_INVALID)
FTDM_ENUM_NAMES(START_TYPE_NAMES, START_TYPE_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_analog_start_type, ftdm_analog_start_type2str, ftdm_analog_start_type_t, START_TYPE_NAMES, FTDM_ANALOG_START_NA)
FTDM_ENUM_NAMES(SIGNAL_NAMES, SIGNAL_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_signal_event, ftdm_signal_event2str, ftdm_signal_event_t, SIGNAL_NAMES, FTDM_SIGEVENT_INVALID)
FTDM_ENUM_NAMES(MDMF_TYPE_NAMES, MDMF_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_mdmf_type, ftdm_mdmf_type2str, ftdm_mdmf_type_t, MDMF_TYPE_NAMES, MDMF_INVALID)
FTDM_ENUM_NAMES(CHAN_TYPE_NAMES, CHAN_TYPE_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_chan_type, ftdm_chan_type2str, ftdm_chan_type_t, CHAN_TYPE_NAMES, FTDM_CHAN_TYPE_COUNT)
FTDM_ENUM_NAMES(SIGNALING_STATUS_NAMES, SIGSTATUS_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_signaling_status, ftdm_signaling_status2str, ftdm_signaling_status_t, SIGNALING_STATUS_NAMES, FTDM_SIG_STATE_INVALID)
FTDM_ENUM_NAMES(TRACE_DIR_NAMES, TRACE_DIR_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_trace_dir, ftdm_trace_dir2str, ftdm_trace_dir_t, TRACE_DIR_NAMES, FTDM_TRACE_DIR_INVALID)
FTDM_ENUM_NAMES(TRACE_TYPE_NAMES, TRACE_TYPE_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_trace_type, ftdm_trace_type2str, ftdm_trace_type_t, TRACE_TYPE_NAMES, FTDM_TRACE_TYPE_INVALID)
FTDM_ENUM_NAMES(TON_NAMES, TON_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_ton, ftdm_ton2str, ftdm_ton_t, TON_NAMES, FTDM_TON_INVALID)
FTDM_ENUM_NAMES(NPI_NAMES, NPI_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_npi, ftdm_npi2str, ftdm_npi_t, NPI_NAMES, FTDM_NPI_INVALID)
FTDM_ENUM_NAMES(PRESENTATION_NAMES, PRESENTATION_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_presentation, ftdm_presentation2str, ftdm_presentation_t, PRESENTATION_NAMES, FTDM_PRES_INVALID)
FTDM_ENUM_NAMES(SCREENING_NAMES, SCREENING_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_screening, ftdm_screening2str, ftdm_screening_t, SCREENING_NAMES, FTDM_SCREENING_INVALID)
FTDM_ENUM_NAMES(BEARER_CAP_NAMES, BEARER_CAP_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_bearer_cap, ftdm_bearer_cap2str, ftdm_bearer_cap_t, BEARER_CAP_NAMES, FTDM_BEARER_CAP_INVALID)
FTDM_ENUM_NAMES(USER_LAYER1_PROT_NAMES, USER_LAYER1_PROT_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_usr_layer1_prot, ftdm_user_layer1_prot2str, ftdm_user_layer1_prot_t, USER_LAYER1_PROT_NAMES, FTDM_USER_LAYER1_PROT_INVALID)
FTDM_ENUM_NAMES(CALLING_PARTY_CATEGORY_NAMES, CALLING_PARTY_CATEGORY_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_calling_party_category, ftdm_calling_party_category2str, ftdm_calling_party_category_t, CALLING_PARTY_CATEGORY_NAMES, FTDM_CPC_INVALID)
FTDM_ENUM_NAMES(INDICATION_NAMES, INDICATION_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_channel_indication, ftdm_channel_indication2str, ftdm_channel_indication_t, INDICATION_NAMES, FTDM_CHANNEL_INDICATE_INVALID)
FTDM_ENUM_NAMES(TRANSFER_RESPONSE_NAMES, TRANSFER_RESPONSE_STRINGS)
FTDM_STR2ENUM(ftdm_str2ftdm_transfer_response, ftdm_transfer_response2str, ftdm_transfer_response_t, TRANSFER_RESPONSE_NAMES, FTDM_TRANSFER_RESPONSE_INVALID)
static ftdm_status_t ftdm_group_add_channels(ftdm_span_t* span, int currindex, const char* name);
static void null_logger(const char *file, const char *func, int line, int level, const char *fmt, ...)
{
ftdm_unused_arg(file);
ftdm_unused_arg(func);
ftdm_unused_arg(line);
ftdm_unused_arg(level);
ftdm_unused_arg(fmt);
}
const char *FTDM_LEVEL_NAMES[9] = {
"EMERG",
"ALERT",
"CRIT",
"ERROR",
"WARNING",
"NOTICE",
"INFO",
"DEBUG",
NULL
};
static int ftdm_log_level = FTDM_LOG_LEVEL_DEBUG;
static void default_logger(const char *file, const char *func, int line, int level, const char *fmt, ...)
{
char data[1024];
va_list ap;
if (level < 0 || level > 7) {
level = 7;
}
if (level > ftdm_log_level) {
return;
}
va_start(ap, fmt);
vsnprintf(data, sizeof(data), fmt, ap);
fprintf(stderr, "[%s] %s:%d %s() %s", FTDM_LEVEL_NAMES[level], file, line, func, data);
va_end(ap);
}
static __inline__ void *ftdm_std_malloc(void *pool, ftdm_size_t size)
{
void *ptr = malloc(size);
ftdm_unused_arg(pool);
ftdm_assert_return(ptr != NULL, NULL, "Out of memory\n");
return ptr;
}
static __inline__ void *ftdm_std_calloc(void *pool, ftdm_size_t elements, ftdm_size_t size)
{
void *ptr = calloc(elements, size);
ftdm_unused_arg(pool);
ftdm_assert_return(ptr != NULL, NULL, "Out of memory\n");
return ptr;
}
static __inline__ void *ftdm_std_realloc(void *pool, void *buff, ftdm_size_t size)
{
buff = realloc(buff, size);
ftdm_unused_arg(pool);
ftdm_assert_return(buff != NULL, NULL, "Out of memory\n");
return buff;
}
static __inline__ void ftdm_std_free(void *pool, void *ptr)
{
ftdm_unused_arg(pool);
ftdm_assert_return(ptr != NULL, , "Attempted to free null pointer");
free(ptr);
}
FT_DECLARE(void) ftdm_set_echocancel_call_begin(ftdm_channel_t *chan)
{
ftdm_caller_data_t *caller_data = ftdm_channel_get_caller_data(chan);
if (ftdm_channel_test_feature(chan, FTDM_CHANNEL_FEATURE_HWEC)) {
if (ftdm_channel_test_feature(chan, FTDM_CHANNEL_FEATURE_HWEC_DISABLED_ON_IDLE)) {
/* If the ec is disabled on idle, we need to enable it unless is a digital call */
if (caller_data->bearer_capability != FTDM_BEARER_CAP_UNRESTRICTED) {
ftdm_log_chan(chan, FTDM_LOG_DEBUG, "Enabling ec for call in channel state %s\n", ftdm_channel_state2str(chan->state));
ftdm_channel_command(chan, FTDM_COMMAND_ENABLE_ECHOCANCEL, NULL);
}
} else {
/* If the ec is enabled on idle, we do nothing unless is a digital call that needs it disabled */
if (caller_data->bearer_capability == FTDM_BEARER_CAP_UNRESTRICTED) {
ftdm_log_chan(chan, FTDM_LOG_DEBUG, "Disabling ec for digital call in channel state %s\n", ftdm_channel_state2str(chan->state));
ftdm_channel_command(chan, FTDM_COMMAND_DISABLE_ECHOCANCEL, NULL);
}
}
}
}
FT_DECLARE(void) ftdm_set_echocancel_call_end(ftdm_channel_t *chan)
{
if (ftdm_channel_test_feature(chan, FTDM_CHANNEL_FEATURE_HWEC)) {
if (ftdm_channel_test_feature(chan, FTDM_CHANNEL_FEATURE_HWEC_DISABLED_ON_IDLE)) {
ftdm_log_chan(chan, FTDM_LOG_DEBUG, "Disabling ec on call end in channel state %s\n", ftdm_channel_state2str(chan->state));
ftdm_channel_command(chan, FTDM_COMMAND_DISABLE_ECHOCANCEL, NULL);
} else {
ftdm_log_chan(chan, FTDM_LOG_DEBUG, "Enabling ec back on call end in channel state %s\n", ftdm_channel_state2str(chan->state));
ftdm_channel_command(chan, FTDM_COMMAND_ENABLE_ECHOCANCEL, NULL);
}
}
}
FT_DECLARE_DATA ftdm_memory_handler_t g_ftdm_mem_handler =
{
/*.pool =*/ NULL,
/*.malloc =*/ ftdm_std_malloc,
/*.calloc =*/ ftdm_std_calloc,
/*.realloc =*/ ftdm_std_realloc,
/*.free =*/ ftdm_std_free
};
FT_DECLARE_DATA ftdm_crash_policy_t g_ftdm_crash_policy = FTDM_CRASH_NEVER;
static ftdm_status_t ftdm_set_caller_data(ftdm_span_t *span, ftdm_caller_data_t *caller_data)
{
if (!caller_data) {
ftdm_log(FTDM_LOG_CRIT, "Error: trying to set caller data, but no caller_data!\n");
return FTDM_FAIL;
}
if (caller_data->dnis.plan >= FTDM_NPI_INVALID) {
caller_data->dnis.plan = span->default_caller_data.dnis.plan;
}
if (caller_data->dnis.type >= FTDM_TON_INVALID) {
caller_data->dnis.type = span->default_caller_data.dnis.type;
}
if (caller_data->cid_num.plan >= FTDM_NPI_INVALID) {
caller_data->cid_num.plan = span->default_caller_data.cid_num.plan;
}
if (caller_data->cid_num.type >= FTDM_TON_INVALID) {
caller_data->cid_num.type = span->default_caller_data.cid_num.type;
}
if (caller_data->ani.plan >= FTDM_NPI_INVALID) {
caller_data->ani.plan = span->default_caller_data.ani.plan;
}
if (caller_data->ani.type >= FTDM_TON_INVALID) {
caller_data->ani.type = span->default_caller_data.ani.type;
}
if (caller_data->rdnis.plan >= FTDM_NPI_INVALID) {
caller_data->rdnis.plan = span->default_caller_data.rdnis.plan;
}
if (caller_data->rdnis.type >= FTDM_NPI_INVALID) {
caller_data->rdnis.type = span->default_caller_data.rdnis.type;
}
if (caller_data->bearer_capability >= FTDM_INVALID_INT_PARM) {
caller_data->bearer_capability = span->default_caller_data.bearer_capability;
}
if (caller_data->bearer_layer1 >= FTDM_INVALID_INT_PARM) {
caller_data->bearer_layer1 = span->default_caller_data.bearer_layer1;
}
if (FTDM_FAIL == ftdm_is_number(caller_data->cid_num.digits)) {
ftdm_log(FTDM_LOG_DEBUG, "dropping caller id number %s since we only accept digits\n", caller_data->cid_num.digits);
caller_data->cid_num.digits[0] = '\0';
}
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_set_caller_data(ftdm_channel_t *ftdmchan, ftdm_caller_data_t *caller_data)
{
ftdm_status_t err = FTDM_SUCCESS;
if (!ftdmchan) {
ftdm_log(FTDM_LOG_CRIT, "trying to set caller data, but no ftdmchan!\n");
return FTDM_FAIL;
}
if ((err = ftdm_set_caller_data(ftdmchan->span, caller_data)) != FTDM_SUCCESS) {
return err;
}
ftdmchan->caller_data = *caller_data;
if (ftdmchan->caller_data.bearer_capability == FTDM_BEARER_CAP_UNRESTRICTED) {
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_DIGITAL_MEDIA);
}
return FTDM_SUCCESS;
}
FT_DECLARE_DATA ftdm_logger_t ftdm_log = null_logger;
FT_DECLARE(void) ftdm_global_set_crash_policy(ftdm_crash_policy_t policy)
{
g_ftdm_crash_policy |= policy;
}
FT_DECLARE(ftdm_status_t) ftdm_global_set_memory_handler(ftdm_memory_handler_t *handler)
{
if (!handler) {
return FTDM_FAIL;
}
if (!handler->malloc) {
return FTDM_FAIL;
}
if (!handler->calloc) {
return FTDM_FAIL;
}
if (!handler->free) {
return FTDM_FAIL;
}
memcpy(&g_ftdm_mem_handler, handler, sizeof(*handler));
return FTDM_SUCCESS;
}
FT_DECLARE(void) ftdm_global_set_logger(ftdm_logger_t logger)
{
if (logger) {
ftdm_log = logger;
} else {
ftdm_log = null_logger;
}
}
FT_DECLARE(void) ftdm_global_set_default_logger(int level)
{
if (level < 0 || level > 7) {
level = 7;
}
ftdm_log = default_logger;
ftdm_log_level = level;
}
FT_DECLARE_NONSTD(int) ftdm_hash_equalkeys(void *k1, void *k2)
{
return strcmp((char *) k1, (char *) k2) ? 0 : 1;
}
FT_DECLARE_NONSTD(uint32_t) ftdm_hash_hashfromstring(void *ky)
{
unsigned char *str = (unsigned char *) ky;
uint32_t hash = 0;
int c;
while ((c = *str++)) {
hash = c + (hash << 6) + (hash << 16) - hash;
}
return hash;
}
static ftdm_status_t ftdm_channel_destroy(ftdm_channel_t *ftdmchan)
{
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_CONFIGURED)) {
while (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_INTHREAD)) {
ftdm_log(FTDM_LOG_INFO, "Waiting for thread to exit on channel %u:%u\n", ftdmchan->span_id, ftdmchan->chan_id);
ftdm_sleep(500);
}
ftdm_mutex_lock(ftdmchan->pre_buffer_mutex);
ftdm_buffer_destroy(&ftdmchan->pre_buffer);
ftdm_mutex_unlock(ftdmchan->pre_buffer_mutex);
ftdm_buffer_destroy(&ftdmchan->digit_buffer);
ftdm_buffer_destroy(&ftdmchan->gen_dtmf_buffer);
ftdm_buffer_destroy(&ftdmchan->dtmf_buffer);
ftdm_buffer_destroy(&ftdmchan->fsk_buffer);
ftdmchan->pre_buffer_size = 0;
ftdm_safe_free(ftdmchan->dtmf_hangup_buf);
if (ftdmchan->tone_session.buffer) {
teletone_destroy_session(&ftdmchan->tone_session);
memset(&ftdmchan->tone_session, 0, sizeof(ftdmchan->tone_session));
}
if (ftdmchan->span->fio->channel_destroy) {
ftdm_log(FTDM_LOG_INFO, "Closing channel %s:%u:%u fd:%d\n", ftdmchan->span->type, ftdmchan->span_id, ftdmchan->chan_id, ftdmchan->sockfd);
if (ftdmchan->span->fio->channel_destroy(ftdmchan) == FTDM_SUCCESS) {
ftdm_clear_flag_locked(ftdmchan, FTDM_CHANNEL_CONFIGURED);
} else {
ftdm_log(FTDM_LOG_ERROR, "Error Closing channel %u:%u fd:%d\n", ftdmchan->span_id, ftdmchan->chan_id, ftdmchan->sockfd);
}
}
ftdm_mutex_destroy(&ftdmchan->mutex);
ftdm_mutex_destroy(&ftdmchan->pre_buffer_mutex);
if (ftdmchan->state_completed_interrupt) {
ftdm_interrupt_destroy(&ftdmchan->state_completed_interrupt);
}
}
return FTDM_SUCCESS;
}
static ftdm_status_t ftdm_span_destroy(ftdm_span_t *span)
{
ftdm_status_t status = FTDM_SUCCESS;
unsigned j;
ftdm_mutex_lock(span->mutex);
/* stop the signaling */
/* This is a forced stopped */
ftdm_clear_flag(span, FTDM_SPAN_NON_STOPPABLE);
ftdm_span_stop(span);
/* destroy the channels */
ftdm_clear_flag(span, FTDM_SPAN_CONFIGURED);
for(j = 1; j <= span->chan_count && span->channels[j]; j++) {
ftdm_channel_t *cur_chan = span->channels[j];
if (cur_chan) {
if (ftdm_test_flag(cur_chan, FTDM_CHANNEL_CONFIGURED)) {
ftdm_channel_destroy(cur_chan);
}
ftdm_safe_free(cur_chan);
cur_chan = NULL;
}
}
/* destroy the I/O for the span */
if (span->fio && span->fio->span_destroy) {
ftdm_log(FTDM_LOG_INFO, "Destroying span %u type (%s)\n", span->span_id, span->type);
if (span->fio->span_destroy(span) != FTDM_SUCCESS) {
status = FTDM_FAIL;
}
}
/* destroy final basic resources of the span data structure */
if (span->pendingchans) {
ftdm_queue_destroy(&span->pendingchans);
}
if (span->pendingsignals) {
ftdm_queue_destroy(&span->pendingsignals);
}
ftdm_mutex_unlock(span->mutex);
ftdm_mutex_destroy(&span->mutex);
ftdm_safe_free(span->signal_data);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_get_alarms(ftdm_channel_t *ftdmchan, ftdm_alarm_flag_t *alarmbits)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(alarmbits != NULL, FTDM_EINVAL, "null alarmbits argument\n");
ftdm_assert_return(ftdmchan != NULL, FTDM_EINVAL, "null channel argument\n");
ftdm_assert_return(ftdmchan->span != NULL, FTDM_EINVAL, "null span\n");
ftdm_assert_return(ftdmchan->span->fio != NULL, FTDM_EINVAL, "null io\n");
*alarmbits = FTDM_ALARM_NONE;
if (!ftdmchan->span->fio->get_alarms) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "No get_alarms interface for this channel\n");
return FTDM_ENOSYS;
}
if (!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_CONFIGURED)) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Cannot get alarms from an unconfigured channel\n");
return FTDM_EINVAL;
}
ftdm_channel_lock(ftdmchan);
if ((status = ftdmchan->span->fio->get_alarms(ftdmchan)) != FTDM_SUCCESS) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Failed to get alarms from channel\n");
goto done;
}
*ftdmchan->last_error = '\0';
*alarmbits = ftdmchan->alarm_flags;
if (ftdm_test_alarm_flag(ftdmchan, FTDM_ALARM_RED)) {
snprintf(ftdmchan->last_error + strlen(ftdmchan->last_error), sizeof(ftdmchan->last_error) - strlen(ftdmchan->last_error), "RED/");
}
if (ftdm_test_alarm_flag(ftdmchan, FTDM_ALARM_YELLOW)) {
snprintf(ftdmchan->last_error + strlen(ftdmchan->last_error), sizeof(ftdmchan->last_error) - strlen(ftdmchan->last_error), "YELLOW/");
}
if (ftdm_test_alarm_flag(ftdmchan, FTDM_ALARM_RAI)) {
snprintf(ftdmchan->last_error + strlen(ftdmchan->last_error), sizeof(ftdmchan->last_error) - strlen(ftdmchan->last_error), "RAI/");
}
if (ftdm_test_alarm_flag(ftdmchan, FTDM_ALARM_BLUE)) {
snprintf(ftdmchan->last_error + strlen(ftdmchan->last_error), sizeof(ftdmchan->last_error) - strlen(ftdmchan->last_error), "BLUE/");
}
if (ftdm_test_alarm_flag(ftdmchan, FTDM_ALARM_AIS)) {
snprintf(ftdmchan->last_error + strlen(ftdmchan->last_error), sizeof(ftdmchan->last_error) - strlen(ftdmchan->last_error), "AIS/");
}
if (ftdm_test_alarm_flag(ftdmchan, FTDM_ALARM_GENERAL)) {
snprintf(ftdmchan->last_error + strlen(ftdmchan->last_error), sizeof(ftdmchan->last_error) - strlen(ftdmchan->last_error), "GENERAL");
}
*(ftdmchan->last_error + strlen(ftdmchan->last_error) - 1) = '\0';
done:
ftdm_channel_unlock(ftdmchan);
return status;
}
static void ftdm_span_add(ftdm_span_t *span)
{
ftdm_span_t *sp;
ftdm_mutex_lock(globals.span_mutex);
for (sp = globals.spans; sp && sp->next; sp = sp->next);
if (sp) {
sp->next = span;
} else {
globals.spans = span;
}
hashtable_insert(globals.span_hash, (void *)span->name, span, HASHTABLE_FLAG_FREE_VALUE);
ftdm_mutex_unlock(globals.span_mutex);
}
FT_DECLARE(ftdm_status_t) ftdm_span_stop(ftdm_span_t *span)
{
ftdm_status_t status = FTDM_SUCCESS;
ftdm_mutex_lock(span->mutex);
if (ftdm_test_flag(span, FTDM_SPAN_NON_STOPPABLE)) {
status = FTDM_NOTIMPL;
goto done;
}
if (!ftdm_test_flag(span, FTDM_SPAN_STARTED)) {
status = FTDM_EINVAL;
goto done;
}
if (!span->stop) {
status = FTDM_ENOSYS;
goto done;
}
/* Stop SIG */
status = span->stop(span);
if (status == FTDM_SUCCESS) {
ftdm_clear_flag(span, FTDM_SPAN_STARTED);
}
/* Stop I/O */
if (span->fio && span->fio->span_stop) {
status = span->fio->span_stop(span);
}
done:
ftdm_mutex_unlock(span->mutex);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_span_create(const char *iotype, const char *name, ftdm_span_t **span)
{
ftdm_span_t *new_span = NULL;
ftdm_io_interface_t *fio = NULL;
ftdm_status_t status = FTDM_FAIL;
char buf[128] = "";
ftdm_assert_return(iotype != NULL, FTDM_FAIL, "No IO type provided\n");
ftdm_assert_return(name != NULL, FTDM_FAIL, "No span name provided\n");
*span = NULL;
fio = ftdm_global_get_io_interface(iotype, FTDM_TRUE);
if (!fio) {
ftdm_log(FTDM_LOG_CRIT, "failure creating span, no such I/O type '%s'\n", iotype);
return FTDM_FAIL;
}
if (!fio->configure_span) {
ftdm_log(FTDM_LOG_CRIT, "failure creating span, no configure_span method for I/O type '%s'\n", iotype);
return FTDM_FAIL;
}
ftdm_mutex_lock(globals.mutex);
if (globals.span_index < FTDM_MAX_SPANS_INTERFACE) {
new_span = ftdm_calloc(sizeof(*new_span), 1);
ftdm_assert(new_span, "allocating span failed\n");
status = ftdm_mutex_create(&new_span->mutex);
ftdm_assert(status == FTDM_SUCCESS, "mutex creation failed\n");
ftdm_set_flag(new_span, FTDM_SPAN_CONFIGURED);
new_span->span_id = ++globals.span_index;
new_span->fio = fio;
ftdm_copy_string(new_span->tone_map[FTDM_TONEMAP_DIAL], "%(1000,0,350,440)", FTDM_TONEMAP_LEN);
ftdm_copy_string(new_span->tone_map[FTDM_TONEMAP_RING], "%(2000,4000,440,480)", FTDM_TONEMAP_LEN);
ftdm_copy_string(new_span->tone_map[FTDM_TONEMAP_BUSY], "%(500,500,480,620)", FTDM_TONEMAP_LEN);
ftdm_copy_string(new_span->tone_map[FTDM_TONEMAP_ATTN], "%(100,100,1400,2060,2450,2600)", FTDM_TONEMAP_LEN);
new_span->trunk_type = FTDM_TRUNK_NONE;
new_span->trunk_mode = FTDM_TRUNK_MODE_CPE;
new_span->data_type = FTDM_TYPE_SPAN;
ftdm_mutex_lock(globals.span_mutex);
if (!ftdm_strlen_zero(name) && hashtable_search(globals.span_hash, (void *)name)) {
ftdm_log(FTDM_LOG_WARNING, "name %s is already used, substituting 'span%d' as the name\n", name, new_span->span_id);
name = NULL;
}
ftdm_mutex_unlock(globals.span_mutex);
if (!name) {
snprintf(buf, sizeof(buf), "span%d", new_span->span_id);
name = buf;
}
new_span->name = ftdm_strdup(name);
new_span->type = ftdm_strdup(iotype);
ftdm_span_add(new_span);
*span = new_span;
status = FTDM_SUCCESS;
}
ftdm_mutex_unlock(globals.mutex);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_span_close_all(void)
{
ftdm_span_t *span;
uint32_t i = 0, j;
ftdm_mutex_lock(globals.span_mutex);
for (span = globals.spans; span; span = span->next) {
if (ftdm_test_flag(span, FTDM_SPAN_CONFIGURED)) {
for(j = 1; j <= span->chan_count && span->channels[j]; j++) {
ftdm_channel_t *toclose = span->channels[j];
if (ftdm_test_flag(toclose, FTDM_CHANNEL_INUSE)) {
ftdm_channel_close(&toclose);
}
i++;
}
}
}
ftdm_mutex_unlock(globals.span_mutex);
return i ? FTDM_SUCCESS : FTDM_FAIL;
}
FT_DECLARE(ftdm_status_t) ftdm_span_load_tones(ftdm_span_t *span, const char *mapname)
{
ftdm_config_t cfg;
char *var, *val;
int x = 0;
if (!ftdm_config_open_file(&cfg, "tones.conf")) {
snprintf(span->last_error, sizeof(span->last_error), "error loading tones.");
return FTDM_FAIL;
}
while (ftdm_config_next_pair(&cfg, &var, &val)) {
int detect = 0;
if (!strcasecmp(cfg.category, mapname) && var && val) {
uint32_t index;
char *name = NULL;
if (!strncasecmp(var, "detect-", 7)) {
name = var + 7;
detect = 1;
} else if (!strncasecmp(var, "generate-", 9)) {
name = var + 9;
} else {
ftdm_log(FTDM_LOG_WARNING, "Unknown tone name %s\n", var);
continue;
}
index = ftdm_str2ftdm_tonemap(name);
if (index >= FTDM_TONEMAP_INVALID || index == FTDM_TONEMAP_NONE) {
ftdm_log(FTDM_LOG_WARNING, "Unknown tone name %s\n", name);
} else {
if (detect) {
char *p = val, *next;
int i = 0;
do {
teletone_process_t this;
next = strchr(p, ',');
this = (teletone_process_t)atof(p);
span->tone_detect_map[index].freqs[i++] = this;
if (next) {
p = next + 1;
}
} while (next);
ftdm_log(FTDM_LOG_DEBUG, "added tone detect [%s] = [%s]\n", name, val);
} else {
ftdm_log(FTDM_LOG_DEBUG, "added tone generation [%s] = [%s]\n", name, val);
ftdm_copy_string(span->tone_map[index], val, sizeof(span->tone_map[index]));
}
x++;
}
}
}
ftdm_config_close_file(&cfg);
if (!x) {
snprintf(span->last_error, sizeof(span->last_error), "error loading tones.");
return FTDM_FAIL;
}
return FTDM_SUCCESS;
}
#define FTDM_SLINEAR_MAX_VALUE 32767
#define FTDM_SLINEAR_MIN_VALUE -32767
static void reset_gain_table(uint8_t *gain_table, float new_gain, ftdm_codec_t codec_gain)
{
/* sample value */
uint8_t sv = 0;
/* linear gain factor */
float lingain = 0;
/* linear value for each table sample */
float linvalue = 0;
/* amplified (or attenuated in case of negative amplification) sample value */
int ampvalue = 0;
/* gain tables are only for alaw and ulaw */
if (codec_gain != FTDM_CODEC_ALAW && codec_gain != FTDM_CODEC_ULAW) {
ftdm_log(FTDM_LOG_WARNING, "Not resetting gain table because codec is not ALAW or ULAW but %d\n", codec_gain);
return;
}
if (!new_gain) {
/* for a 0.0db gain table, each alaw/ulaw sample value is left untouched (0 ==0, 1 == 1, 2 == 2 etc)*/
sv = 0;
while (1) {
gain_table[sv] = sv;
if (sv == (FTDM_GAINS_TABLE_SIZE-1)) {
break;
}
sv++;
}
return;
}
/* use the 20log rule to increase the gain: http://en.wikipedia.org/wiki/Gain, http:/en.wipedia.org/wiki/20_log_rule#Definitions */
lingain = (float)pow(10.0, new_gain/ 20.0);
sv = 0;
while (1) {
/* get the linear value for this alaw/ulaw sample value */
linvalue = codec_gain == FTDM_CODEC_ALAW ? (float)alaw_to_linear(sv) : (float)ulaw_to_linear(sv);
/* multiply the linear value and the previously calculated linear gain */
ampvalue = (int)(linvalue * lingain);
/* chop it if goes beyond the limits */
if (ampvalue > FTDM_SLINEAR_MAX_VALUE) {
ampvalue = FTDM_SLINEAR_MAX_VALUE;
}
if (ampvalue < FTDM_SLINEAR_MIN_VALUE) {
ampvalue = FTDM_SLINEAR_MIN_VALUE;
}
gain_table[sv] = codec_gain == FTDM_CODEC_ALAW ? linear_to_alaw(ampvalue) : linear_to_ulaw(ampvalue);
if (sv == (FTDM_GAINS_TABLE_SIZE-1)) {
break;
}
sv++;
}
}
FT_DECLARE(ftdm_status_t) ftdm_span_add_channel(ftdm_span_t *span, ftdm_socket_t sockfd, ftdm_chan_type_t type, ftdm_channel_t **chan)
{
unsigned char i = 0;
if (span->chan_count < FTDM_MAX_CHANNELS_SPAN) {
ftdm_channel_t *new_chan = span->channels[++span->chan_count];
if (!new_chan) {
#ifdef FTDM_DEBUG_CHAN_MEMORY
void *chanmem = NULL;
int pages = 1;
int pagesize = sysconf(_SC_PAGE_SIZE);
if (sizeof(*new_chan) > pagesize) {
pages = sizeof(*new_chan)/pagesize;
pages++;
}
ftdm_log(FTDM_LOG_DEBUG, "Allocating %d pages of %d bytes for channel of size %d\n", pages, pagesize, sizeof(*new_chan));
if (posix_memalign(&chanmem, pagesize, pagesize*pages)) {
return FTDM_FAIL;
}
ftdm_log(FTDM_LOG_DEBUG, "Channel pages allocated start at mem %p\n", chanmem);
memset(chanmem, 0, sizeof(*new_chan));
new_chan = chanmem;
#else
if (!(new_chan = ftdm_calloc(1, sizeof(*new_chan)))) {
return FTDM_FAIL;
}
#endif
span->channels[span->chan_count] = new_chan;
}
new_chan->type = type;
new_chan->sockfd = sockfd;
new_chan->fio = span->fio;
new_chan->span_id = span->span_id;
new_chan->chan_id = span->chan_count;
new_chan->span = span;
new_chan->fds[FTDM_READ_TRACE_INDEX] = -1;
new_chan->fds[FTDM_WRITE_TRACE_INDEX] = -1;
new_chan->data_type = FTDM_TYPE_CHANNEL;
if (!new_chan->dtmf_on) {
new_chan->dtmf_on = FTDM_DEFAULT_DTMF_ON;
}
if (!new_chan->dtmf_off) {
new_chan->dtmf_off = FTDM_DEFAULT_DTMF_OFF;
}
ftdm_mutex_create(&new_chan->mutex);
ftdm_mutex_create(&new_chan->pre_buffer_mutex);
ftdm_buffer_create(&new_chan->digit_buffer, 128, 128, 0);
ftdm_buffer_create(&new_chan->gen_dtmf_buffer, 128, 128, 0);
new_chan->dtmf_hangup_buf = ftdm_calloc (span->dtmf_hangup_len + 1, sizeof (char));
/* set 0.0db gain table */
i = 0;
while (1) {
new_chan->txgain_table[i] = i;
new_chan->rxgain_table[i] = i;
if (i == (sizeof(new_chan->txgain_table)-1)) {
break;
}
i++;
}
ftdm_set_flag(new_chan, FTDM_CHANNEL_CONFIGURED | FTDM_CHANNEL_READY);
new_chan->state = FTDM_CHANNEL_STATE_DOWN;
new_chan->state_status = FTDM_STATE_STATUS_COMPLETED;
*chan = new_chan;
return FTDM_SUCCESS;
}
return FTDM_FAIL;
}
FT_DECLARE(ftdm_status_t) ftdm_span_find_by_name(const char *name, ftdm_span_t **span)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_mutex_lock(globals.span_mutex);
if (!ftdm_strlen_zero(name)) {
if ((*span = hashtable_search(globals.span_hash, (void *)name))) {
status = FTDM_SUCCESS;
} else {
int span_id = atoi(name);
ftdm_span_find(span_id, span);
if (*span) {
status = FTDM_SUCCESS;
}
}
}
ftdm_mutex_unlock(globals.span_mutex);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_span_find(uint32_t id, ftdm_span_t **span)
{
ftdm_span_t *fspan = NULL, *sp;
if (id > FTDM_MAX_SPANS_INTERFACE) {
return FTDM_FAIL;
}
ftdm_mutex_lock(globals.span_mutex);
for (sp = globals.spans; sp; sp = sp->next) {
if (sp->span_id == id) {
fspan = sp;
break;
}
}
ftdm_mutex_unlock(globals.span_mutex);
if (!fspan || !ftdm_test_flag(fspan, FTDM_SPAN_CONFIGURED)) {
return FTDM_FAIL;
}
*span = fspan;
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_span_poll_event(ftdm_span_t *span, uint32_t ms, short *poll_events)
{
assert(span->fio != NULL);
if (span->fio->poll_event) {
return span->fio->poll_event(span, ms, poll_events);
} else {
ftdm_log(FTDM_LOG_ERROR, "poll_event method not implemented in module %s!", span->fio->name);
}
return FTDM_NOTIMPL;
}
/* handle oob events and send the proper SIGEVENT signal to user, when applicable */
static __inline__ ftdm_status_t ftdm_event_handle_oob(ftdm_event_t *event)
{
ftdm_sigmsg_t sigmsg;
ftdm_status_t status = FTDM_SUCCESS;
ftdm_channel_t *fchan = event->channel;
ftdm_span_t *span = fchan->span;
memset(&sigmsg, 0, sizeof(sigmsg));
sigmsg.span_id = span->span_id;
sigmsg.chan_id = fchan->chan_id;
sigmsg.channel = fchan;
switch (event->enum_id) {
case FTDM_OOB_ALARM_CLEAR:
{
sigmsg.event_id = FTDM_SIGEVENT_ALARM_CLEAR;
ftdm_clear_flag_locked(fchan, FTDM_CHANNEL_IN_ALARM);
status = ftdm_span_send_signal(span, &sigmsg);
}
break;
case FTDM_OOB_ALARM_TRAP:
{
sigmsg.event_id = FTDM_SIGEVENT_ALARM_TRAP;
ftdm_set_flag_locked(fchan, FTDM_CHANNEL_IN_ALARM);
status = ftdm_span_send_signal(span, &sigmsg);
}
break;
default:
/* NOOP */
break;
}
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_span_next_event(ftdm_span_t *span, ftdm_event_t **event)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(span->fio != NULL, FTDM_FAIL, "No I/O module attached to this span!\n");
if (!span->fio->next_event) {
ftdm_log(FTDM_LOG_ERROR, "next_event method not implemented in module %s!", span->fio->name);
return FTDM_NOTIMPL;
}
status = span->fio->next_event(span, event);
if (status != FTDM_SUCCESS) {
return status;
}
status = ftdm_event_handle_oob(*event);
if (status != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_ERROR, "failed to handle event %d\n", (*event)->e_type);
}
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_read_event(ftdm_channel_t *ftdmchan, ftdm_event_t **event)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_span_t *span = ftdmchan->span;
ftdm_assert_return(span->fio != NULL, FTDM_FAIL, "No I/O module attached to this span!\n");
ftdm_channel_lock(ftdmchan);
if (!span->fio->channel_next_event) {
ftdm_log(FTDM_LOG_ERROR, "channel_next_event method not implemented in module %s!\n", span->fio->name);
status = FTDM_NOTIMPL;
goto done;
}
if (ftdm_test_io_flag(ftdmchan, FTDM_CHANNEL_IO_EVENT)) {
ftdm_clear_io_flag(ftdmchan, FTDM_CHANNEL_IO_EVENT);
}
status = span->fio->channel_next_event(ftdmchan, event);
if (status != FTDM_SUCCESS) {
goto done;
}
status = ftdm_event_handle_oob(*event);
if (status != FTDM_SUCCESS) {
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "failed to handle event %d\n", (*event)->e_type);
}
done:
ftdm_channel_unlock(ftdmchan);
return status;
}
static ftdm_status_t ftdmchan_fsk_write_sample(int16_t *buf, ftdm_size_t buflen, void *user_data)
{
ftdm_channel_t *ftdmchan = (ftdm_channel_t *) user_data;
ftdm_buffer_write(ftdmchan->fsk_buffer, buf, buflen * 2);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_send_fsk_data(ftdm_channel_t *ftdmchan, ftdm_fsk_data_state_t *fsk_data, float db_level)
{
struct ftdm_fsk_modulator fsk_trans;
if (!ftdmchan->fsk_buffer) {
ftdm_buffer_create(&ftdmchan->fsk_buffer, 128, 128, 0);
} else {
ftdm_buffer_zero(ftdmchan->fsk_buffer);
}
if (ftdmchan->token_count > 1) {
ftdm_fsk_modulator_init(&fsk_trans, FSK_BELL202, ftdmchan->rate, fsk_data, db_level, 80, 5, 0, ftdmchan_fsk_write_sample, ftdmchan);
ftdm_fsk_modulator_send_all((&fsk_trans));
} else {
ftdm_fsk_modulator_init(&fsk_trans, FSK_BELL202, ftdmchan->rate, fsk_data, db_level, 180, 5, 300, ftdmchan_fsk_write_sample, ftdmchan);
ftdm_fsk_modulator_send_all((&fsk_trans));
ftdmchan->buffer_delay = 3500 / ftdmchan->effective_interval;
}
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_clear_token(ftdm_channel_t *ftdmchan, const char *token)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_mutex_lock(ftdmchan->mutex);
if (token == NULL) {
memset(ftdmchan->tokens, 0, sizeof(ftdmchan->tokens));
ftdmchan->token_count = 0;
} else if (*token != '\0') {
char tokens[FTDM_MAX_TOKENS][FTDM_TOKEN_STRLEN];
int32_t i, count = ftdmchan->token_count;
memcpy(tokens, ftdmchan->tokens, sizeof(tokens));
memset(ftdmchan->tokens, 0, sizeof(ftdmchan->tokens));
ftdmchan->token_count = 0;
for (i = 0; i < count; i++) {
if (strcmp(tokens[i], token)) {
ftdm_copy_string(ftdmchan->tokens[ftdmchan->token_count], tokens[i], sizeof(ftdmchan->tokens[ftdmchan->token_count]));
ftdmchan->token_count++;
}
}
status = FTDM_SUCCESS;
}
ftdm_mutex_unlock(ftdmchan->mutex);
return status;
}
FT_DECLARE(void) ftdm_channel_rotate_tokens(ftdm_channel_t *ftdmchan)
{
if (ftdmchan->token_count) {
memmove(ftdmchan->tokens[1], ftdmchan->tokens[0], ftdmchan->token_count * FTDM_TOKEN_STRLEN);
ftdm_copy_string(ftdmchan->tokens[0], ftdmchan->tokens[ftdmchan->token_count], FTDM_TOKEN_STRLEN);
*ftdmchan->tokens[ftdmchan->token_count] = '\0';
}
}
FT_DECLARE(void) ftdm_channel_replace_token(ftdm_channel_t *ftdmchan, const char *old_token, const char *new_token)
{
unsigned int i;
if (ftdmchan->token_count) {
for(i = 0; i < ftdmchan->token_count; i++) {
if (!strcmp(ftdmchan->tokens[i], old_token)) {
ftdm_copy_string(ftdmchan->tokens[i], new_token, FTDM_TOKEN_STRLEN);
break;
}
}
}
}
FT_DECLARE(void) ftdm_channel_set_private(ftdm_channel_t *ftdmchan, void *pvt)
{
ftdmchan->user_private = pvt;
}
FT_DECLARE(void *) ftdm_channel_get_private(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->user_private;
}
FT_DECLARE(uint32_t) ftdm_channel_get_token_count(const ftdm_channel_t *ftdmchan)
{
uint32_t count;
ftdm_mutex_lock(ftdmchan->mutex);
count = ftdmchan->token_count;
ftdm_mutex_unlock(ftdmchan->mutex);
return count;
}
FT_DECLARE(uint32_t) ftdm_channel_get_io_interval(const ftdm_channel_t *ftdmchan)
{
uint32_t count;
ftdm_mutex_lock(ftdmchan->mutex);
count = ftdmchan->effective_interval;
ftdm_mutex_unlock(ftdmchan->mutex);
return count;
}
FT_DECLARE(uint32_t) ftdm_channel_get_io_packet_len(const ftdm_channel_t *ftdmchan)
{
uint32_t count;
ftdm_mutex_lock(ftdmchan->mutex);
count = ftdmchan->packet_len;
ftdm_mutex_unlock(ftdmchan->mutex);
return count;
}
FT_DECLARE(uint32_t) ftdm_channel_get_type(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->type;
}
FT_DECLARE(ftdm_codec_t) ftdm_channel_get_codec(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->effective_codec;
}
FT_DECLARE(const char *) ftdm_channel_get_token(const ftdm_channel_t *ftdmchan, uint32_t tokenid)
{
const char *token = NULL;
ftdm_mutex_lock(ftdmchan->mutex);
if (ftdmchan->token_count <= tokenid) {
ftdm_mutex_unlock(ftdmchan->mutex);
return NULL;
}
token = ftdmchan->tokens[tokenid];
ftdm_mutex_unlock(ftdmchan->mutex);
return token;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_add_token(ftdm_channel_t *ftdmchan, char *token, int end)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_mutex_lock(ftdmchan->mutex);
if (ftdmchan->token_count < FTDM_MAX_TOKENS) {
if (end) {
ftdm_copy_string(ftdmchan->tokens[ftdmchan->token_count++], token, FTDM_TOKEN_STRLEN);
} else {
memmove(ftdmchan->tokens[1], ftdmchan->tokens[0], ftdmchan->token_count * FTDM_TOKEN_STRLEN);
ftdm_copy_string(ftdmchan->tokens[0], token, FTDM_TOKEN_STRLEN);
ftdmchan->token_count++;
}
status = FTDM_SUCCESS;
}
ftdm_mutex_unlock(ftdmchan->mutex);
return status;
}
FT_DECLARE(uint32_t) ftdm_group_get_id(const ftdm_group_t *group)
{
return group->group_id;
}
FT_DECLARE(ftdm_status_t) ftdm_group_channel_use_count(ftdm_group_t *group, uint32_t *count)
{
uint32_t j;
*count = 0;
if (!group) {
return FTDM_FAIL;
}
for(j = 0; j < group->chan_count && group->channels[j]; j++) {
if (group->channels[j]) {
if (ftdm_test_flag(group->channels[j], FTDM_CHANNEL_INUSE)) {
(*count)++;
}
}
}
return FTDM_SUCCESS;
}
static __inline__ int chan_is_avail(ftdm_channel_t *check)
{
if ((check->span->signal_type == FTDM_SIGTYPE_M2UA) ||
(check->span->signal_type == FTDM_SIGTYPE_NONE)) {
if (!ftdm_test_flag(check, FTDM_CHANNEL_READY) ||
ftdm_test_flag(check, FTDM_CHANNEL_INUSE) ||
ftdm_test_flag(check, FTDM_CHANNEL_SUSPENDED) ||
ftdm_test_flag(check, FTDM_CHANNEL_IN_ALARM) ||
check->state != FTDM_CHANNEL_STATE_DOWN) {
return 0;
}
} else {
if (!ftdm_test_flag(check, FTDM_CHANNEL_READY) ||
!ftdm_test_flag(check, FTDM_CHANNEL_SIG_UP) ||
ftdm_test_flag(check, FTDM_CHANNEL_INUSE) ||
ftdm_test_flag(check, FTDM_CHANNEL_SUSPENDED) ||
ftdm_test_flag(check, FTDM_CHANNEL_IN_ALARM) ||
check->state != FTDM_CHANNEL_STATE_DOWN) {
return 0;
}
}
return 1;
}
static __inline__ int chan_voice_is_avail(ftdm_channel_t *check)
{
if (!FTDM_IS_VOICE_CHANNEL(check)) {
return 0;
}
return chan_is_avail(check);
}
static __inline__ int request_voice_channel(ftdm_channel_t *check, ftdm_channel_t **ftdmchan,
ftdm_caller_data_t *caller_data, ftdm_hunt_direction_t direction)
{
ftdm_status_t status;
if (chan_voice_is_avail(check)) {
/* unlocked testing passed, try again with the channel locked */
ftdm_mutex_lock(check->mutex);
if (chan_voice_is_avail(check)) {
if (check->span && check->span->channel_request) {
/* I am only unlocking here cuz this function is called
* sometimes with the group or span lock held and were
* blocking anyone hunting for channels available and
* I believe teh channel_request() function may take
* a bit of time. However channel_request is a callback
* used by boost and may be only a few other old sig mods
* and it should be deprecated */
ftdm_mutex_unlock(check->mutex);
ftdm_set_caller_data(check->span, caller_data);
status = check->span->channel_request(check->span, check->chan_id,
direction, caller_data, ftdmchan);
if (status == FTDM_SUCCESS) {
return 1;
}
} else {
status = ftdm_channel_open_chan(check);
if (status == FTDM_SUCCESS) {
*ftdmchan = check;
ftdm_set_flag(check, FTDM_CHANNEL_OUTBOUND);
#if 0
ftdm_mutex_unlock(check->mutex);
#endif
return 1;
}
}
}
ftdm_mutex_unlock(check->mutex);
}
return 0;
}
static void __inline__ calculate_best_rate(ftdm_channel_t *check, ftdm_channel_t **best_rated, int *best_rate)
{
if (ftdm_test_flag(check->span, FTDM_SPAN_USE_AV_RATE)) {
ftdm_mutex_lock(check->mutex);
if (ftdm_test_flag(check, FTDM_CHANNEL_INUSE)) {
/* twiddle */
} else if (ftdm_test_flag(check, FTDM_CHANNEL_SIG_UP)) {
/* twiddle */
} else if (check->availability_rate > *best_rate){
/* the channel is not in use and the signaling status is down,
* it is a potential candidate to place a call */
*best_rated = check;
*best_rate = check->availability_rate;
}
ftdm_mutex_unlock(check->mutex);
}
}
static ftdm_status_t __inline__ get_best_rated(ftdm_channel_t **fchan, ftdm_channel_t *best_rated)
{
ftdm_status_t status;
if (!best_rated) {
return FTDM_FAIL;
}
ftdm_mutex_lock(best_rated->mutex);
if (ftdm_test_flag(best_rated, FTDM_CHANNEL_INUSE)) {
ftdm_mutex_unlock(best_rated->mutex);
return FTDM_FAIL;
}
ftdm_log_chan_msg(best_rated, FTDM_LOG_DEBUG, "I may not be available but I had the best availability rate, trying to open I/O now\n");
status = ftdm_channel_open_chan(best_rated);
if (status != FTDM_SUCCESS) {
ftdm_mutex_unlock(best_rated->mutex);
return FTDM_FAIL;
}
*fchan = best_rated;
ftdm_set_flag(best_rated, FTDM_CHANNEL_OUTBOUND);
#if 0
ftdm_mutex_unlock(best_rated->mutex);
#endif
return FTDM_SUCCESS;
}
static uint32_t __inline__ rr_next(uint32_t last, uint32_t min, uint32_t max, ftdm_hunt_direction_t direction)
{
uint32_t next = min;
ftdm_log(FTDM_LOG_DEBUG, "last = %d, min = %d, max = %d\n", last, min, max);
if (direction == FTDM_HUNT_RR_UP) {
next = (last >= max) ? min : ++last;
} else {
next = (last <= min) ? max : --last;
}
return next;
}
FT_DECLARE(int) ftdm_channel_get_availability(ftdm_channel_t *ftdmchan)
{
int availability = -1;
ftdm_channel_lock(ftdmchan);
if (ftdm_test_flag(ftdmchan->span, FTDM_SPAN_USE_AV_RATE)) {
availability = ftdmchan->availability_rate;
}
ftdm_channel_unlock(ftdmchan);
return availability;
}
static ftdm_status_t _ftdm_channel_open_by_group(uint32_t group_id, ftdm_hunt_direction_t direction, ftdm_caller_data_t *caller_data, ftdm_channel_t **ftdmchan)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_channel_t *check = NULL;
ftdm_channel_t *best_rated = NULL;
ftdm_group_t *group = NULL;
int best_rate = 0;
uint32_t i = 0;
uint32_t count = 0;
uint32_t first_channel = 0;
if (group_id) {
ftdm_group_find(group_id, &group);
}
if (!group) {
ftdm_log(FTDM_LOG_ERROR, "Group %d not defined!\n", group_id);
*ftdmchan = NULL;
return FTDM_FAIL;
}
ftdm_group_channel_use_count(group, &count);
if (count >= group->chan_count) {
ftdm_log(FTDM_LOG_WARNING, "All circuits are busy (%d channels used out of %d available).\n", count, group->chan_count);
*ftdmchan = NULL;
return FTDM_FAIL;
}
if (direction == FTDM_HUNT_BOTTOM_UP) {
i = 0;
} else if (direction == FTDM_HUNT_RR_DOWN || direction == FTDM_HUNT_RR_UP) {
i = rr_next(group->last_used_index, 0, group->chan_count - 1, direction);
first_channel = i;
} else {
i = group->chan_count-1;
}
ftdm_mutex_lock(group->mutex);
for (;;) {
if (!(check = group->channels[i])) {
status = FTDM_FAIL;
break;
}
if (request_voice_channel(check, ftdmchan, caller_data, direction)) {
status = FTDM_SUCCESS;
if (direction == FTDM_HUNT_RR_UP || direction == FTDM_HUNT_RR_DOWN) {
group->last_used_index = i;
}
break;
}
calculate_best_rate(check, &best_rated, &best_rate);
if (direction == FTDM_HUNT_BOTTOM_UP) {
if (i >= (group->chan_count - 1)) {
break;
}
i++;
} else if (direction == FTDM_HUNT_RR_DOWN || direction == FTDM_HUNT_RR_UP) {
if (check == best_rated) {
group->last_used_index = i;
}
i = rr_next(i, 0, group->chan_count - 1, direction);
if (first_channel == i) {
break;
}
} else {
if (i == 0) {
break;
}
i--;
}
}
if (status == FTDM_FAIL) {
status = get_best_rated(ftdmchan, best_rated);
}
ftdm_mutex_unlock(group->mutex);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_open_by_group(uint32_t group_id, ftdm_hunt_direction_t direction, ftdm_caller_data_t *caller_data, ftdm_channel_t **ftdmchan)
{
ftdm_status_t status;
status = _ftdm_channel_open_by_group(group_id, direction, caller_data, ftdmchan);
if (status == FTDM_SUCCESS) {
ftdm_channel_t *fchan = *ftdmchan;
ftdm_channel_unlock(fchan);
}
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_span_channel_use_count(ftdm_span_t *span, uint32_t *count)
{
uint32_t j;
*count = 0;
if (!span || !ftdm_test_flag(span, FTDM_SPAN_CONFIGURED)) {
return FTDM_FAIL;
}
for(j = 1; j <= span->chan_count && span->channels[j]; j++) {
if (span->channels[j]) {
if (ftdm_test_flag(span->channels[j], FTDM_CHANNEL_INUSE)) {
(*count)++;
}
}
}
return FTDM_SUCCESS;
}
/* Hunt a channel by span, if successful the channel is returned locked */
static ftdm_status_t _ftdm_channel_open_by_span(uint32_t span_id, ftdm_hunt_direction_t direction, ftdm_caller_data_t *caller_data, ftdm_channel_t **ftdmchan)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_channel_t *check = NULL;
ftdm_channel_t *best_rated = NULL;
ftdm_span_t *span = NULL;
int best_rate = 0;
uint32_t i = 0;
uint32_t count = 0;
uint32_t first_channel = 0;
*ftdmchan = NULL;
if (!span_id) {
ftdm_log(FTDM_LOG_CRIT, "No span supplied\n");
return FTDM_FAIL;
}
ftdm_span_find(span_id, &span);
if (!span || !ftdm_test_flag(span, FTDM_SPAN_CONFIGURED)) {
ftdm_log(FTDM_LOG_CRIT, "span %d not defined or configured!\n", span_id);
return FTDM_FAIL;
}
ftdm_span_channel_use_count(span, &count);
if (count >= span->chan_count) {
ftdm_log(FTDM_LOG_WARNING, "All circuits are busy: active=%i max=%i.\n", count, span->chan_count);
return FTDM_FAIL;
}
if (span->channel_request && !ftdm_test_flag(span, FTDM_SPAN_SUGGEST_CHAN_ID)) {
ftdm_set_caller_data(span, caller_data);
return span->channel_request(span, 0, direction, caller_data, ftdmchan);
}
ftdm_mutex_lock(span->mutex);
if (direction == FTDM_HUNT_BOTTOM_UP) {
i = 1;
} else if (direction == FTDM_HUNT_RR_DOWN || direction == FTDM_HUNT_RR_UP) {
i = rr_next(span->last_used_index, 1, span->chan_count, direction);
first_channel = i;
} else {
i = span->chan_count;
}
for(;;) {
if (direction == FTDM_HUNT_BOTTOM_UP) {
if (i > span->chan_count) {
break;
}
} else {
if (i == 0) {
break;
}
}
if (!(check = span->channels[i])) {
status = FTDM_FAIL;
break;
}
if (request_voice_channel(check, ftdmchan, caller_data, direction)) {
status = FTDM_SUCCESS;
if (direction == FTDM_HUNT_RR_UP || direction == FTDM_HUNT_RR_DOWN) {
span->last_used_index = i;
}
break;
}
calculate_best_rate(check, &best_rated, &best_rate);
if (direction == FTDM_HUNT_BOTTOM_UP) {
i++;
} else if (direction == FTDM_HUNT_RR_DOWN || direction == FTDM_HUNT_RR_UP) {
if (check == best_rated) {
span->last_used_index = i;
}
i = rr_next(i, 1, span->chan_count, direction);
if (first_channel == i) {
break;
}
} else {
i--;
}
}
if (status == FTDM_FAIL) {
status = get_best_rated(ftdmchan, best_rated);
}
ftdm_mutex_unlock(span->mutex);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_open_by_span(uint32_t span_id, ftdm_hunt_direction_t direction, ftdm_caller_data_t *caller_data, ftdm_channel_t **ftdmchan)
{
ftdm_status_t status;
status = _ftdm_channel_open_by_span(span_id, direction, caller_data, ftdmchan);
if (status == FTDM_SUCCESS) {
ftdm_channel_t *fchan = *ftdmchan;
ftdm_channel_unlock(fchan);
}
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_open_chan(ftdm_channel_t *ftdmchan)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "invalid ftdmchan pointer\n");
ftdm_mutex_lock(ftdmchan->mutex);
if (FTDM_IS_VOICE_CHANNEL(ftdmchan)) {
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_SUSPENDED)) {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "%s", "Channel is suspended\n");
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "Cannot open channel when is suspended\n");
goto done;
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_IN_ALARM) && !ftdm_test_flag(ftdmchan->span, FTDM_SPAN_PWR_SAVING)) {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "%s", "Channel is alarmed\n");
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "Cannot open channel when is alarmed\n");
goto done;
}
if (globals.cpu_monitor.alarm &&
globals.cpu_monitor.alarm_action_flags & FTDM_CPU_ALARM_ACTION_REJECT) {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "%s", "CPU usage alarm is on - refusing to open channel\n");
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "CPU usage alarm is on - refusing to open channel\n");
ftdmchan->caller_data.hangup_cause = FTDM_CAUSE_SWITCH_CONGESTION;
goto done;
}
}
if (!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_READY)) {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "Channel is not ready");
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "Cannot open channel when is not ready\n");
goto done;
}
status = ftdmchan->fio->open(ftdmchan);
if (status == FTDM_SUCCESS) {
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_OPEN | FTDM_CHANNEL_INUSE);
} else {
ftdm_log_chan(ftdmchan, FTDM_LOG_WARNING, "IO open failed: %d\n", status);
}
done:
ftdm_mutex_unlock(ftdmchan->mutex);
return status;
}
static ftdm_status_t _ftdm_channel_open(uint32_t span_id, uint32_t chan_id, ftdm_channel_t **ftdmchan, uint8_t physical)
{
ftdm_channel_t *check = NULL;
ftdm_span_t *span = NULL;
ftdm_channel_t *best_rated = NULL;
ftdm_status_t status = FTDM_FAIL;
int best_rate = 0;
*ftdmchan = NULL;
ftdm_mutex_lock(globals.mutex);
ftdm_span_find(span_id, &span);
if (!span) {
ftdm_log(FTDM_LOG_CRIT, "Could not find span!\n");
goto done;
}
if (!ftdm_test_flag(span, FTDM_SPAN_CONFIGURED)) {
ftdm_log(FTDM_LOG_CRIT, "Span %d is not configured\n", span_id);
goto done;
}
if (span->channel_request) {
ftdm_log(FTDM_LOG_ERROR, "Individual channel selection not implemented on this span.\n");
goto done;
}
if (physical) { /* Open by physical */
ftdm_channel_t *fchan = NULL;
ftdm_iterator_t *citer = NULL;
ftdm_iterator_t *curr = NULL;
if (chan_id < 1) {
ftdm_log(FTDM_LOG_ERROR, "Invalid physical channel %d to open in span %d\n", chan_id, span_id);
status = FTDM_FAIL;
goto done;
}
citer = ftdm_span_get_chan_iterator(span, NULL);
if (!citer) {
status = ENOMEM;
goto done;
}
for (curr = citer ; curr; curr = ftdm_iterator_next(curr)) {
fchan = ftdm_iterator_current(curr);
if (fchan->physical_chan_id == chan_id) {
check = fchan;
break;
}
}
ftdm_iterator_free(citer);
if (!check) {
ftdm_log(FTDM_LOG_CRIT, "Wow, no physical channel %d in span %d\n", chan_id, span_id);
goto done;
}
} else { /* Open by logical */
if (chan_id < 1 || chan_id > span->chan_count) {
ftdm_log(FTDM_LOG_ERROR, "Invalid channel %d to open in span %d\n", chan_id, span_id);
goto done;
}
if (!(check = span->channels[chan_id])) {
ftdm_log(FTDM_LOG_CRIT, "Wow, no channel %d in span %d\n", chan_id, span_id);
goto done;
}
}
ftdm_channel_lock(check);
if (ftdm_test_flag(check, FTDM_CHANNEL_OPEN)) {
/* let them know is already open, but return the channel anyway */
status = FTDM_EBUSY;
*ftdmchan = check;
goto unlockchan;
}
/* The following if's and gotos replace a big if (this || this || this || this) else { nothing; } */
/* if it is not a voice channel, nothing else to check to open it */
if (!FTDM_IS_VOICE_CHANNEL(check)) {
goto openchan;
}
/* if it's an FXS device with a call active and has callwaiting enabled, we allow to open it twice */
if (check->type == FTDM_CHAN_TYPE_FXS
&& check->token_count == 1
&& ftdm_channel_test_feature(check, FTDM_CHANNEL_FEATURE_CALLWAITING)) {
goto openchan;
}
/* if channel is available, time to open it */
if (chan_is_avail(check)) {
goto openchan;
}
/* not available, but still might be available ... */
calculate_best_rate(check, &best_rated, &best_rate);
if (best_rated) {
goto openchan;
}
/* channel is unavailable, do not open the channel */
goto unlockchan;
openchan:
if (!ftdm_test_flag(check, FTDM_CHANNEL_OPEN)) {
status = check->fio->open(check);
if (status == FTDM_SUCCESS) {
ftdm_set_flag(check, FTDM_CHANNEL_OPEN);
}
} else {
status = FTDM_SUCCESS;
}
ftdm_set_flag(check, FTDM_CHANNEL_INUSE);
ftdm_set_flag(check, FTDM_CHANNEL_OUTBOUND);
*ftdmchan = check;
/* we've got the channel, do not unlock it */
goto done;
unlockchan:
ftdm_channel_unlock(check);
done:
ftdm_mutex_unlock(globals.mutex);
if (status != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_ERROR, "Failed to open channel %d:%d\n", span_id, chan_id);
}
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_open(uint32_t span_id, uint32_t chan_id, ftdm_channel_t **ftdmchan)
{
ftdm_status_t status;
status = _ftdm_channel_open(span_id, chan_id, ftdmchan, 0);
if (status == FTDM_SUCCESS) {
ftdm_channel_t *fchan = *ftdmchan;
ftdm_channel_unlock(fchan);
}
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_open_ph(uint32_t span_id, uint32_t chan_id, ftdm_channel_t **ftdmchan)
{
ftdm_status_t status;
status = _ftdm_channel_open(span_id, chan_id, ftdmchan, 1);
if (status == FTDM_SUCCESS) {
ftdm_channel_t *fchan = *ftdmchan;
ftdm_channel_unlock(fchan);
}
return status;
}
FT_DECLARE(uint32_t) ftdm_channel_get_id(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->chan_id;
}
FT_DECLARE(uint32_t) ftdm_channel_get_ph_id(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->physical_chan_id;
}
FT_DECLARE(uint32_t) ftdm_channel_get_span_id(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->span_id;
}
FT_DECLARE(ftdm_span_t *) ftdm_channel_get_span(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->span;
}
FT_DECLARE(const char *) ftdm_channel_get_span_name(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->span->name;
}
FT_DECLARE(void) ftdm_span_set_trunk_type(ftdm_span_t *span, ftdm_trunk_type_t type)
{
span->trunk_type = type;
}
FT_DECLARE(ftdm_status_t) ftdm_span_set_blocking_mode(const ftdm_span_t *span, ftdm_bool_t enabled)
{
ftdm_channel_t *fchan = NULL;
ftdm_iterator_t *citer = NULL;
ftdm_iterator_t *curr = NULL;
citer = ftdm_span_get_chan_iterator(span, NULL);
if (!citer) {
return FTDM_ENOMEM;
}
for (curr = citer ; curr; curr = ftdm_iterator_next(curr)) {
fchan = ftdm_iterator_current(curr);
if (enabled) {
ftdm_clear_flag_locked(fchan, FTDM_CHANNEL_NONBLOCK);
} else {
ftdm_set_flag_locked(fchan, FTDM_CHANNEL_NONBLOCK);
}
}
ftdm_iterator_free(citer);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_trunk_type_t) ftdm_span_get_trunk_type(const ftdm_span_t *span)
{
return span->trunk_type;
}
FT_DECLARE(const char *) ftdm_span_get_trunk_type_str(const ftdm_span_t *span)
{
return ftdm_trunk_type2str(span->trunk_type);
}
FT_DECLARE(void) ftdm_span_set_trunk_mode(ftdm_span_t *span, ftdm_trunk_mode_t mode)
{
span->trunk_mode = mode;
}
FT_DECLARE(ftdm_trunk_mode_t) ftdm_span_get_trunk_mode(const ftdm_span_t *span)
{
return span->trunk_mode;
}
FT_DECLARE(const char *) ftdm_span_get_trunk_mode_str(const ftdm_span_t *span)
{
return ftdm_trunk_mode2str(span->trunk_mode);
}
FT_DECLARE(uint32_t) ftdm_span_get_id(const ftdm_span_t *span)
{
return span->span_id;
}
FT_DECLARE(const char *) ftdm_span_get_name(const ftdm_span_t *span)
{
return span->name;
}
FT_DECLARE(const char *) ftdm_channel_get_name(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->chan_name;
}
FT_DECLARE(const char *) ftdm_channel_get_number(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->chan_number;
}
FT_DECLARE(ftdm_bool_t) ftdm_channel_call_check_hold(const ftdm_channel_t *ftdmchan)
{
ftdm_bool_t condition;
ftdm_channel_lock(ftdmchan);
condition = ftdm_test_flag(ftdmchan, FTDM_CHANNEL_HOLD) ? FTDM_TRUE : FTDM_FALSE;
ftdm_channel_unlock(ftdmchan);
return condition;
}
FT_DECLARE(ftdm_bool_t) ftdm_channel_call_check_answered(const ftdm_channel_t *ftdmchan)
{
ftdm_bool_t condition = FTDM_FALSE;
ftdm_channel_lock(ftdmchan);
condition = (ftdmchan->state == FTDM_CHANNEL_STATE_UP) ? FTDM_TRUE : FTDM_FALSE;
ftdm_channel_unlock(ftdmchan);
return condition;
}
FT_DECLARE(ftdm_bool_t) ftdm_channel_call_check_busy(const ftdm_channel_t *ftdmchan)
{
ftdm_bool_t condition = FTDM_FALSE;
ftdm_channel_lock(ftdmchan);
condition = (ftdmchan->state == FTDM_CHANNEL_STATE_BUSY) ? FTDM_TRUE : FTDM_FALSE;
ftdm_channel_unlock(ftdmchan);
return condition;
}
FT_DECLARE(ftdm_bool_t) ftdm_channel_call_check_hangup(const ftdm_channel_t *ftdmchan)
{
ftdm_bool_t condition = FTDM_FALSE;
ftdm_channel_lock(ftdmchan);
condition = (ftdmchan->state == FTDM_CHANNEL_STATE_HANGUP || ftdmchan->state == FTDM_CHANNEL_STATE_TERMINATING)
? FTDM_TRUE : FTDM_FALSE;
ftdm_channel_unlock(ftdmchan);
return condition;
}
FT_DECLARE(ftdm_bool_t) ftdm_channel_call_check_done(const ftdm_channel_t *ftdmchan)
{
ftdm_bool_t condition = FTDM_FALSE;
ftdm_channel_lock(ftdmchan);
condition = (ftdmchan->state == FTDM_CHANNEL_STATE_DOWN) ? FTDM_TRUE : FTDM_FALSE;
ftdm_channel_unlock(ftdmchan);
return condition;
}
FT_DECLARE(ftdm_status_t) _ftdm_channel_call_hold(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status;
ftdm_channel_lock(ftdmchan);
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_HOLD);
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_DIALTONE, 0, usrmsg);
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(ftdm_status_t) _ftdm_channel_call_unhold(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status;
ftdm_channel_lock(ftdmchan);
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_UP, 0, usrmsg);
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(void) ftdm_ack_indication(ftdm_channel_t *fchan, ftdm_channel_indication_t indication, ftdm_status_t status)
{
ftdm_sigmsg_t msg;
if (!ftdm_test_flag(fchan, FTDM_CHANNEL_IND_ACK_PENDING)) {
return;
}
ftdm_log_chan(fchan, FTDM_LOG_DEBUG, "Acknowledging indication %s in state %s (rc = %d)\n",
ftdm_channel_indication2str(indication), ftdm_channel_state2str(fchan->state), status);
ftdm_clear_flag(fchan, FTDM_CHANNEL_IND_ACK_PENDING);
memset(&msg, 0, sizeof(msg));
msg.channel = fchan;
msg.event_id = FTDM_SIGEVENT_INDICATION_COMPLETED;
msg.ev_data.indication_completed.indication = indication;
msg.ev_data.indication_completed.status = status;
ftdm_span_send_signal(fchan->span, &msg);
}
/*! Answer call without locking the channel. The caller must have locked first */
static ftdm_status_t _ftdm_channel_call_answer_nl(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status = FTDM_SUCCESS;
if (!ftdm_test_flag(ftdmchan->span, FTDM_SPAN_USE_SKIP_STATES)) {
/* We will fail RFC's if we not skip states, but some modules apart from ftmod_sangoma_isdn
* expect the call to always to go PROGRESS and PROGRESS MEDIA state before going to UP, so
* use FTDM_SPAN_USE_SKIP_STATES for now while we update the sig modules */
if (ftdmchan->state < FTDM_CHANNEL_STATE_PROGRESS) {
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_PROGRESS, 1, usrmsg);
if (status != FTDM_SUCCESS) {
status = FTDM_ECANCELED;
goto done;
}
}
/* set state unlocks the channel so we need to re-confirm that the channel hasn't gone to hell */
if (ftdmchan->state == FTDM_CHANNEL_STATE_TERMINATING) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "Ignoring answer because the call has moved to TERMINATING while we're moving to PROGRESS\n");
status = FTDM_ECANCELED;
goto done;
}
if (ftdmchan->state < FTDM_CHANNEL_STATE_PROGRESS_MEDIA) {
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_PROGRESS_MEDIA, 1, usrmsg);
if (status != FTDM_SUCCESS) {
status = FTDM_ECANCELED;
goto done;
}
}
/* set state unlocks the channel so we need to re-confirm that the channel hasn't gone to hell */
if (ftdmchan->state == FTDM_CHANNEL_STATE_TERMINATING) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "Ignoring answer because the call has moved to TERMINATING while we're moving to UP\n");
status = FTDM_ECANCELED;
goto done;
}
}
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_UP, 1, usrmsg);
if (status != FTDM_SUCCESS) {
status = FTDM_ECANCELED;
goto done;
}
done:
return status;
}
FT_DECLARE(ftdm_status_t) _ftdm_channel_call_answer(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status;
/* we leave the locking up to ftdm_channel_call_indicate, DO NOT lock here since ftdm_channel_call_indicate expects
* the lock recursivity to be 1 */
status = _ftdm_channel_call_indicate(file, func, line, ftdmchan, FTDM_CHANNEL_INDICATE_ANSWER, usrmsg);
return status;
}
FT_DECLARE(ftdm_status_t) _ftdm_channel_call_transfer(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, const char* arg, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status;
ftdm_usrmsg_t *msg = NULL;
ftdm_bool_t free_msg = FTDM_FALSE;
if (!usrmsg) {
msg = ftdm_calloc(1, sizeof(*msg));
ftdm_assert_return(msg, FTDM_FAIL, "Failed to allocate usr msg");
memset(msg, 0, sizeof(*msg));
free_msg = FTDM_TRUE;
} else {
msg = usrmsg;
}
ftdm_usrmsg_add_var(msg, "transfer_arg", arg);
/* we leave the locking up to ftdm_channel_call_indicate, DO NOT lock here since ftdm_channel_call_indicate expects
* the lock recursivity to be 1 */
status = _ftdm_channel_call_indicate(file, func, line, ftdmchan, FTDM_CHANNEL_INDICATE_TRANSFER, msg);
if (free_msg == FTDM_TRUE) {
ftdm_safe_free(msg);
}
return status;
}
/* lock must be acquired by the caller! */
static ftdm_status_t _ftdm_channel_call_hangup_nl(const char *file, const char *func, int line, ftdm_channel_t *chan, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status = FTDM_SUCCESS;
/* In native sigbridge mode we ignore hangup requests from the user and hangup only when the signaling module decides it */
if (ftdm_test_flag(chan, FTDM_CHANNEL_NATIVE_SIGBRIDGE) && chan->state != FTDM_CHANNEL_STATE_TERMINATING) {
ftdm_log_chan_ex(chan, file, func, line, FTDM_LOG_LEVEL_DEBUG,
"Ignoring hangup in channel in state %s (native bridge enabled)\n", ftdm_channel_state2str(chan->state));
ftdm_set_flag(chan, FTDM_CHANNEL_USER_HANGUP);
goto done;
}
if (chan->state != FTDM_CHANNEL_STATE_DOWN) {
if (chan->state == FTDM_CHANNEL_STATE_HANGUP) {
/* make user's life easier, and just ignore double hangup requests */
return FTDM_SUCCESS;
}
if (chan->hangup_timer) {
ftdm_sched_cancel_timer(globals.timingsched, chan->hangup_timer);
}
ftdm_set_flag(chan, FTDM_CHANNEL_USER_HANGUP);
/* if a state change requested by the user was pending, a hangup certainly cancels that request */
if (ftdm_test_flag(chan, FTDM_CHANNEL_STATE_CHANGE)) {
ftdm_channel_cancel_state(file, func, line, chan);
}
status = ftdm_channel_set_state(file, func, line, chan, FTDM_CHANNEL_STATE_HANGUP, 1, usrmsg);
} else {
/* the signaling stack did not touch the state,
* core is responsible from clearing flags and stuff, however, because ftmod_analog
* is a bitch in a serious need of refactoring, we also check whether the channel is open
* to avoid an spurious warning about the channel not being open. This is because ftmod_analog
* does not follow our convention of sending SIGEVENT_STOP and waiting for the user to move
* to HANGUP (implicitly through ftdm_channel_call_hangup(), as soon as ftmod_analog is fixed
* this check can be removed */
if (ftdm_test_flag(chan, FTDM_CHANNEL_OPEN)) {
ftdm_channel_close(&chan);
}
}
done:
return status;
}
FT_DECLARE(ftdm_status_t) _ftdm_channel_call_hangup_with_cause(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_call_cause_t cause, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status = FTDM_SUCCESS;
ftdm_channel_lock(ftdmchan);
ftdmchan->caller_data.hangup_cause = cause;
status = _ftdm_channel_call_hangup_nl(file, func, line, ftdmchan, usrmsg);
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(ftdm_status_t) _ftdm_channel_call_hangup(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status = FTDM_SUCCESS;
ftdm_channel_lock(ftdmchan);
ftdmchan->caller_data.hangup_cause = FTDM_CAUSE_NORMAL_CLEARING;
status = _ftdm_channel_call_hangup_nl(file, func, line, ftdmchan, usrmsg);
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(const char *) ftdm_channel_get_last_error(const ftdm_channel_t *ftdmchan)
{
return ftdmchan->last_error;
}
FT_DECLARE(const char *) ftdm_span_get_last_error(const ftdm_span_t *span)
{
return span->last_error;
}
FT_DECLARE(ftdm_caller_data_t *) ftdm_channel_get_caller_data(ftdm_channel_t *ftdmchan)
{
return &ftdmchan->caller_data;
}
FT_DECLARE(ftdm_channel_t *) ftdm_span_get_channel(const ftdm_span_t *span, uint32_t chanid)
{
ftdm_channel_t *chan;
ftdm_mutex_lock(span->mutex);
if (chanid == 0 || chanid > span->chan_count) {
ftdm_mutex_unlock(span->mutex);
return NULL;
}
chan = span->channels[chanid];
ftdm_mutex_unlock(span->mutex);
return chan;
}
FT_DECLARE(ftdm_channel_t *) ftdm_span_get_channel_ph(const ftdm_span_t *span, uint32_t chanid)
{
ftdm_channel_t *chan = NULL;
ftdm_channel_t *fchan = NULL;
ftdm_iterator_t *citer = NULL;
ftdm_iterator_t *curr = NULL;
ftdm_mutex_lock(span->mutex);
if (chanid == 0) {
ftdm_mutex_unlock(span->mutex);
return NULL;
}
citer = ftdm_span_get_chan_iterator(span, NULL);
if (!citer) {
ftdm_mutex_unlock(span->mutex);
return NULL;
}
for (curr = citer ; curr; curr = ftdm_iterator_next(curr)) {
fchan = ftdm_iterator_current(curr);
if (fchan->physical_chan_id == chanid) {
chan = fchan;
break;
}
}
ftdm_iterator_free(citer);
ftdm_mutex_unlock(span->mutex);
return chan;
}
FT_DECLARE(uint32_t) ftdm_span_get_chan_count(const ftdm_span_t *span)
{
uint32_t count;
ftdm_mutex_lock(span->mutex);
count = span->chan_count;
ftdm_mutex_unlock(span->mutex);
return count;
}
FT_DECLARE(uint32_t) ftdm_channel_get_ph_span_id(const ftdm_channel_t *ftdmchan)
{
uint32_t id;
ftdm_channel_lock(ftdmchan);
id = ftdmchan->physical_span_id;
ftdm_channel_unlock(ftdmchan);
return id;
}
/*
* Every user requested indication *MUST* be acknowledged with the proper status (ftdm_status_t)
* However, if the indication fails before we notify the signaling stack, we don't need to ack
* but if we already notified the signaling stack about the indication, the signaling stack is
* responsible for the acknowledge. Bottom line is, whenever this function returns FTDM_SUCCESS
* someone *MUST* acknowledge the indication, either the signaling stack, this function or the core
* at some later point
* */
FT_DECLARE(ftdm_status_t) _ftdm_channel_call_indicate(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_channel_indication_t indication, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status = FTDM_SUCCESS;
ftdm_assert_return(ftdmchan, FTDM_FAIL, "Null channel\n");
ftdm_log_chan_ex(ftdmchan, file, func, line, FTDM_LOG_LEVEL_DEBUG, "Indicating %s in state %s\n",
ftdm_channel_indication2str(indication), ftdm_channel_state2str(ftdmchan->state));
ftdm_channel_lock(ftdmchan);
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_NATIVE_SIGBRIDGE)) {
ftdm_log_chan_ex(ftdmchan, file, func, line, FTDM_LOG_LEVEL_DEBUG,
"Ignoring indication %s in channel in state %s (native bridge enabled)\n",
ftdm_channel_indication2str(indication),
ftdm_channel_state2str(ftdmchan->state));
status = FTDM_SUCCESS;
goto done;
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_IND_ACK_PENDING)) {
ftdm_log_chan_ex(ftdmchan, file, func, line, FTDM_LOG_LEVEL_WARNING, "Cannot indicate %s in channel with indication %s still pending in state %s\n",
ftdm_channel_indication2str(indication),
ftdm_channel_indication2str(ftdmchan->indication),
ftdm_channel_state2str(ftdmchan->state));
status = FTDM_EBUSY;
goto done;
}
ftdmchan->indication = indication;
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_NONBLOCK)) {
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_IND_ACK_PENDING);
}
if (indication != FTDM_CHANNEL_INDICATE_FACILITY &&
ftdm_test_flag(ftdmchan, FTDM_CHANNEL_OUTBOUND)) {
ftdm_log_chan_ex(ftdmchan, file, func, line, FTDM_LOG_LEVEL_WARNING, "Cannot indicate %s in outgoing channel in state %s\n",
ftdm_channel_indication2str(indication), ftdm_channel_state2str(ftdmchan->state));
status = FTDM_EINVAL;
goto done;
}
if (ftdmchan->state == FTDM_CHANNEL_STATE_TERMINATING) {
ftdm_log_chan_ex(ftdmchan, file, func, line, FTDM_LOG_LEVEL_DEBUG, "Ignoring indication %s because the call is in %s state\n",
ftdm_channel_indication2str(indication), ftdm_channel_state2str(ftdmchan->state));
status = FTDM_ECANCELED;
goto done;
}
switch (indication) {
/* FIXME: ring and busy cannot be used with all signaling stacks
* (particularly isdn stacks I think, we should emulate or just move to hangup with busy cause) */
case FTDM_CHANNEL_INDICATE_RINGING:
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_RINGING, 1, usrmsg);
break;
case FTDM_CHANNEL_INDICATE_BUSY:
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_BUSY, 1, usrmsg);
break;
case FTDM_CHANNEL_INDICATE_PROCEED:
if (!ftdm_test_flag(ftdmchan->span, FTDM_SPAN_USE_PROCEED_STATE) ||
ftdmchan->state >= FTDM_CHANNEL_STATE_PROCEED) {
ftdm_ack_indication(ftdmchan, indication, status);
goto done;
}
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_PROCEED, 1, usrmsg);
break;
case FTDM_CHANNEL_INDICATE_PROGRESS:
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_PROGRESS, 1, usrmsg);
break;
case FTDM_CHANNEL_INDICATE_PROGRESS_MEDIA:
if (!ftdm_test_flag(ftdmchan->span, FTDM_SPAN_USE_SKIP_STATES)) {
if (ftdmchan->state < FTDM_CHANNEL_STATE_PROGRESS) {
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_PROGRESS, 1, usrmsg);
if (status != FTDM_SUCCESS) {
goto done;
}
}
/* set state unlocks the channel so we need to re-confirm that the channel hasn't gone to hell */
if (ftdmchan->state == FTDM_CHANNEL_STATE_TERMINATING) {
ftdm_log_chan_ex_msg(ftdmchan, file, func, line, FTDM_LOG_LEVEL_DEBUG, "Ignoring progress media because the call is terminating\n");
goto done;
}
}
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_PROGRESS_MEDIA, 1, usrmsg);
break;
case FTDM_CHANNEL_INDICATE_ANSWER:
status = _ftdm_channel_call_answer_nl(file, func, line, ftdmchan, usrmsg);
break;
case FTDM_CHANNEL_INDICATE_TRANSFER:
if (!ftdm_test_flag(ftdmchan->span, FTDM_SPAN_USE_TRANSFER)) {
ftdm_log_chan_ex_msg(ftdmchan, file, func, line, FTDM_LOG_LEVEL_WARNING, "Transfer not supported\n");
status = FTDM_EINVAL;
goto done;
}
status = ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_TRANSFER, 1, usrmsg);
break;
default:
/* See if signalling module can provide this indication */
status = ftdm_channel_sig_indicate(ftdmchan, indication, usrmsg);
break;
}
done:
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(ftdm_status_t) _ftdm_channel_reset(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "null channel");
ftdm_channel_lock(ftdmchan);
ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_RESET, 1, usrmsg);
ftdm_channel_unlock(ftdmchan);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_get_channel_from_string(const char *string_id, ftdm_span_t **out_span, ftdm_channel_t **out_channel)
{
ftdm_status_t status = FTDM_SUCCESS;
int rc = 0;
ftdm_span_t *span = NULL;
ftdm_channel_t *ftdmchan = NULL;
unsigned span_id = 0;
unsigned chan_id = 0;
*out_span = NULL;
*out_channel = NULL;
if (!string_id) {
ftdm_log(FTDM_LOG_ERROR, "Cannot parse NULL channel id string\n");
status = FTDM_EINVAL;
goto done;
}
rc = sscanf(string_id, "%u:%u", &span_id, &chan_id);
if (rc != 2) {
ftdm_log(FTDM_LOG_ERROR, "Failed to parse channel id string '%s'\n", string_id);
status = FTDM_EINVAL;
goto done;
}
status = ftdm_span_find(span_id, &span);
if (status != FTDM_SUCCESS || !span) {
ftdm_log(FTDM_LOG_ERROR, "Failed to find span for channel id string '%s'\n", string_id);
status = FTDM_EINVAL;
goto done;
}
if (chan_id > (FTDM_MAX_CHANNELS_SPAN+1) || !(ftdmchan = span->channels[chan_id])) {
ftdm_log(FTDM_LOG_ERROR, "Invalid channel id string '%s'\n", string_id);
status = FTDM_EINVAL;
goto done;
}
status = FTDM_SUCCESS;
*out_span = span;
*out_channel = ftdmchan;
done:
return status;
}
/* this function MUST be called with the channel lock held with lock recursivity of 1 exactly,
* and the caller must be aware we might unlock the channel for a brief period of time and then lock it again */
static ftdm_status_t _ftdm_channel_call_place_nl(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
const char *var = NULL;
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "null channel");
ftdm_assert_return(ftdm_test_flag(ftdmchan, FTDM_CHANNEL_OUTBOUND), FTDM_FAIL, "Call place, but outbound flag not set\n");
if (!ftdmchan->span->outgoing_call) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "outgoing_call method not implemented in this span!\n");
status = FTDM_ENOSYS;
goto done;
}
if (!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_OPEN)) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Cannot place call in channel that is not open!\n");
goto done;
}
if (!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_OUTBOUND)) {
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "Cannot place call in non outbound channel in state %s!\n", ftdm_channel_state2str(ftdmchan->state));
goto done;
}
status = ftdmchan->span->outgoing_call(ftdmchan);
if (status == FTDM_BREAK) {
/* the signaling module detected glare on time */
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "Glare detected, you should hunt in another channel!\n");
goto done;
}
if (status != FTDM_SUCCESS) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Failed to place call!\n");
goto done;
}
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_CALL_STARTED);
ftdm_call_set_call_id(ftdmchan, &ftdmchan->caller_data);
var = ftdm_usrmsg_get_var(usrmsg, "sigbridge_peer");
if (var) {
ftdm_span_t *peer_span = NULL;
ftdm_channel_t *peer_chan = NULL;
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_NATIVE_SIGBRIDGE);
ftdm_get_channel_from_string(var, &peer_span, &peer_chan);
if (peer_chan) {
ftdm_set_flag(peer_chan, FTDM_CHANNEL_NATIVE_SIGBRIDGE);
}
}
/* if the signaling stack left the channel in state down on success, is expecting us to move to DIALING */
if (ftdmchan->state == FTDM_CHANNEL_STATE_DOWN) {
if (!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_NONBLOCK)) {
ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_DIALING, 1, usrmsg);
} else {
ftdm_channel_set_state(file, func, line, ftdmchan, FTDM_CHANNEL_STATE_DIALING, 0, usrmsg);
}
} else if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_STATE_CHANGE) &&
!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_NONBLOCK)) {
ftdm_channel_unlock(ftdmchan);
ftdm_interrupt_wait(ftdmchan->state_completed_interrupt, 500);
ftdm_channel_lock(ftdmchan);
}
done:
ftdm_unused_arg(file);
ftdm_unused_arg(func);
ftdm_unused_arg(line);
return status;
}
FT_DECLARE(ftdm_status_t) _ftdm_channel_call_place(const char *file, const char *func, int line, ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status;
ftdm_channel_lock(ftdmchan);
/* be aware that _ftdm_channl_call_place_nl can unlock/lock the channel quickly if working in blocking mode */
status = _ftdm_channel_call_place_nl(file, func, line, ftdmchan, usrmsg);
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(ftdm_status_t) _ftdm_call_place(const char *file, const char *func, int line,
ftdm_caller_data_t *caller_data, ftdm_hunting_scheme_t *hunting, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status = FTDM_SUCCESS;
ftdm_channel_t *fchan = NULL;
ftdm_assert_return(caller_data, FTDM_EINVAL, "Invalid caller data\n");
ftdm_assert_return(hunting, FTDM_EINVAL, "Invalid hunting scheme\n");
if (hunting->mode == FTDM_HUNT_SPAN) {
status = _ftdm_channel_open_by_span(hunting->mode_data.span.span_id,
hunting->mode_data.span.direction, caller_data, &fchan);
} else if (hunting->mode == FTDM_HUNT_GROUP) {
status = _ftdm_channel_open_by_group(hunting->mode_data.group.group_id,
hunting->mode_data.group.direction, caller_data, &fchan);
} else if (hunting->mode == FTDM_HUNT_CHAN) {
status = _ftdm_channel_open(hunting->mode_data.chan.span_id, hunting->mode_data.chan.chan_id, &fchan, 0);
} else {
ftdm_log(FTDM_LOG_ERROR, "Cannot make outbound call with invalid hunting mode %d\n", hunting->mode);
return FTDM_EINVAL;
}
if (status != FTDM_SUCCESS) {
return FTDM_EBUSY;
}
/* we have a locked channel and are not afraid of using it! */
if (hunting->result_cb) {
status = hunting->result_cb(fchan, caller_data);
if (status != FTDM_SUCCESS) {
status = FTDM_ECANCELED;
goto done;
}
}
ftdm_channel_set_caller_data(fchan, caller_data);
/* be aware that _ftdm_channl_call_place_nl can unlock/lock the channel quickly if working in blocking mode */
status = _ftdm_channel_call_place_nl(file, func, line, fchan, usrmsg);
if (status != FTDM_SUCCESS) {
_ftdm_channel_call_hangup_nl(file, func, line, fchan, usrmsg);
goto done;
}
/* let the user know which channel was picked and which call id was generated */
caller_data->fchan = fchan;
caller_data->call_id = fchan->caller_data.call_id;
done:
ftdm_channel_unlock(fchan);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_set_sig_status(ftdm_channel_t *fchan, ftdm_signaling_status_t sigstatus)
{
ftdm_status_t res;
ftdm_assert_return(fchan != NULL, FTDM_FAIL, "Null channel\n");
ftdm_assert_return(fchan->span != NULL, FTDM_FAIL, "Null span\n");
ftdm_assert_return(fchan->span->set_channel_sig_status != NULL, FTDM_ENOSYS, "Not implemented\n");
ftdm_channel_lock(fchan);
res = fchan->span->set_channel_sig_status(fchan, sigstatus);
ftdm_channel_unlock(fchan);
return res;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_get_sig_status(ftdm_channel_t *ftdmchan, ftdm_signaling_status_t *sigstatus)
{
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "Null channel\n");
ftdm_assert_return(ftdmchan->span != NULL, FTDM_FAIL, "Null span\n");
ftdm_assert_return(sigstatus != NULL, FTDM_FAIL, "Null sig status parameter\n");
if (ftdmchan->span->get_channel_sig_status) {
ftdm_status_t res;
ftdm_channel_lock(ftdmchan);
res = ftdmchan->span->get_channel_sig_status(ftdmchan, sigstatus);
ftdm_channel_unlock(ftdmchan);
return res;
} else {
/* don't log error here, it can be called just to test if its supported */
return FTDM_NOTIMPL;
}
}
FT_DECLARE(ftdm_status_t) ftdm_span_set_sig_status(ftdm_span_t *span, ftdm_signaling_status_t sigstatus)
{
ftdm_assert_return(span != NULL, FTDM_FAIL, "Null span\n");
if (sigstatus == FTDM_SIG_STATE_DOWN) {
ftdm_log(FTDM_LOG_WARNING, "The user is not allowed to set the signaling status to DOWN, valid states are UP or SUSPENDED\n");
return FTDM_FAIL;
}
if (span->set_span_sig_status) {
return span->set_span_sig_status(span, sigstatus);
} else {
ftdm_log(FTDM_LOG_ERROR, "set_span_sig_status method not implemented!\n");
return FTDM_FAIL;
}
}
FT_DECLARE(ftdm_status_t) ftdm_span_get_sig_status(ftdm_span_t *span, ftdm_signaling_status_t *sigstatus)
{
ftdm_assert_return(span != NULL, FTDM_FAIL, "Null span\n");
ftdm_assert_return(sigstatus != NULL, FTDM_FAIL, "Null sig status parameter\n");
if (span->get_span_sig_status) {
return span->get_span_sig_status(span, sigstatus);
} else {
return FTDM_FAIL;
}
}
static ftdm_status_t ftdm_channel_sig_indicate(ftdm_channel_t *ftdmchan, ftdm_channel_indication_t indication, ftdm_usrmsg_t *usrmsg)
{
ftdm_status_t status = FTDM_FAIL;
if (ftdmchan->span->indicate) {
ftdm_channel_save_usrmsg(ftdmchan, usrmsg);
status = ftdmchan->span->indicate(ftdmchan, indication);
if (status == FTDM_NOTIMPL) {
ftdm_log(FTDM_LOG_WARNING, "Do not know how to indicate %s\n", ftdm_channel_indication2str(indication));
} else if (status != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_WARNING, "Failed to indicate %s\n", ftdm_channel_indication2str(indication));
} else { /* SUCCESS */
ftdm_ack_indication(ftdmchan, indication, FTDM_SUCCESS);
}
ftdm_usrmsg_free(&ftdmchan->usrmsg);
} else {
return FTDM_NOTIMPL;
}
return status;
}
/* this function must be called with the channel lock */
static ftdm_status_t ftdm_channel_done(ftdm_channel_t *ftdmchan)
{
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "Null channel can't be done!\n");
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_OPEN);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_DTMF_DETECT);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_SUPRESS_DTMF);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_INUSE);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_OUTBOUND);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_WINK);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_FLASH);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_STATE_CHANGE);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_HOLD);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_OFFHOOK);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_RINGING);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_PROGRESS_DETECT);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_CALLERID_DETECT);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_3WAY);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_PROGRESS);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_MEDIA);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_ANSWERED);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_USER_HANGUP);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_DIGITAL_MEDIA);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_NATIVE_SIGBRIDGE);
ftdm_mutex_lock(ftdmchan->pre_buffer_mutex);
ftdm_buffer_destroy(&ftdmchan->pre_buffer);
ftdmchan->pre_buffer_size = 0;
ftdm_mutex_unlock(ftdmchan->pre_buffer_mutex);
if (ftdmchan->hangup_timer) {
ftdm_sched_cancel_timer(globals.timingsched, ftdmchan->hangup_timer);
}
ftdmchan->init_state = FTDM_CHANNEL_STATE_DOWN;
ftdmchan->state = FTDM_CHANNEL_STATE_DOWN;
ftdmchan->state_status = FTDM_STATE_STATUS_COMPLETED;
ftdm_channel_command(ftdmchan, FTDM_COMMAND_DISABLE_DEBUG_DTMF, NULL);
ftdm_channel_command(ftdmchan, FTDM_COMMAND_DISABLE_INPUT_DUMP, NULL);
ftdm_channel_command(ftdmchan, FTDM_COMMAND_DISABLE_OUTPUT_DUMP, NULL);
if (FTDM_IS_VOICE_CHANNEL(ftdmchan) && ftdm_test_flag(ftdmchan, FTDM_CHANNEL_CALL_STARTED)) {
ftdm_sigmsg_t sigmsg;
memset(&sigmsg, 0, sizeof(sigmsg));
sigmsg.span_id = ftdmchan->span_id;
sigmsg.chan_id = ftdmchan->chan_id;
sigmsg.channel = ftdmchan;
sigmsg.event_id = FTDM_SIGEVENT_RELEASED;
ftdm_span_send_signal(ftdmchan->span, &sigmsg);
ftdm_call_clear_call_id(&ftdmchan->caller_data);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_CALL_STARTED);
}
if (ftdmchan->txdrops || ftdmchan->rxdrops) {
ftdm_log_chan(ftdmchan, FTDM_LOG_WARNING, "channel dropped data: txdrops = %d, rxdrops = %d\n",
ftdmchan->txdrops, ftdmchan->rxdrops);
}
memset(&ftdmchan->caller_data, 0, sizeof(ftdmchan->caller_data));
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_HOLD);
memset(ftdmchan->tokens, 0, sizeof(ftdmchan->tokens));
ftdmchan->token_count = 0;
ftdm_channel_flush_dtmf(ftdmchan);
if (ftdmchan->gen_dtmf_buffer) {
ftdm_buffer_zero(ftdmchan->gen_dtmf_buffer);
}
if (ftdmchan->dtmf_buffer) {
ftdm_buffer_zero(ftdmchan->dtmf_buffer);
}
if (ftdmchan->digit_buffer) {
ftdm_buffer_zero(ftdmchan->digit_buffer);
}
if (!ftdmchan->dtmf_on) {
ftdmchan->dtmf_on = FTDM_DEFAULT_DTMF_ON;
}
if (!ftdmchan->dtmf_off) {
ftdmchan->dtmf_off = FTDM_DEFAULT_DTMF_OFF;
}
memset(ftdmchan->dtmf_hangup_buf, '\0', ftdmchan->span->dtmf_hangup_len);
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_TRANSCODE)) {
ftdmchan->effective_codec = ftdmchan->native_codec;
ftdmchan->packet_len = ftdmchan->native_interval * (ftdmchan->effective_codec == FTDM_CODEC_SLIN ? 16 : 8);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_TRANSCODE);
}
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "channel done\n");
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_use(ftdm_channel_t *ftdmchan)
{
ftdm_assert(ftdmchan != NULL, "Null channel\n");
ftdm_set_flag_locked(ftdmchan, FTDM_CHANNEL_INUSE);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_close(ftdm_channel_t **ftdmchan)
{
ftdm_channel_t *check;
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "null channel double pointer provided!\n");
ftdm_assert_return(*ftdmchan != NULL, FTDM_FAIL, "null channel pointer provided!\n");
check = *ftdmchan;
*ftdmchan = NULL;
if (ftdm_test_flag(check, FTDM_CHANNEL_CONFIGURED)) {
ftdm_mutex_lock(check->mutex);
if (!ftdm_test_flag(check, FTDM_CHANNEL_OPEN)) {
ftdm_log_chan_msg(check, FTDM_LOG_WARNING, "Channel not opened, proceeding anyway\n");
}
status = check->fio->close(check);
ftdm_assert(status == FTDM_SUCCESS, "Failed to close channel!\n");
ftdm_channel_done(check);
*ftdmchan = NULL;
check->ring_count = 0;
ftdm_mutex_unlock(check->mutex);
}
return status;
}
static ftdm_status_t ftdmchan_activate_dtmf_buffer(ftdm_channel_t *ftdmchan)
{
if (!ftdmchan->dtmf_buffer) {
if (ftdm_buffer_create(&ftdmchan->dtmf_buffer, 1024, 3192, 0) != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_ERROR, "Failed to allocate DTMF Buffer!\n");
return FTDM_FAIL;
} else {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "Created DTMF buffer\n");
}
}
if (!ftdmchan->tone_session.buffer) {
memset(&ftdmchan->tone_session, 0, sizeof(ftdmchan->tone_session));
teletone_init_session(&ftdmchan->tone_session, 0, NULL, NULL);
}
ftdmchan->tone_session.rate = ftdmchan->rate;
ftdmchan->tone_session.duration = ftdmchan->dtmf_on * (ftdmchan->tone_session.rate / 1000);
ftdmchan->tone_session.wait = ftdmchan->dtmf_off * (ftdmchan->tone_session.rate / 1000);
ftdmchan->tone_session.volume = -7;
/*
ftdmchan->tone_session.debug = 1;
ftdmchan->tone_session.debug_stream = stdout;
*/
return FTDM_SUCCESS;
}
/*
* ftdmchan_activate_dtmf_buffer to initialize ftdmchan->dtmf_buffer should be called prior to
* calling ftdm_insert_dtmf_pause
*/
static ftdm_status_t ftdm_insert_dtmf_pause(ftdm_channel_t *ftdmchan, ftdm_size_t pausems)
{
void *data = NULL;
ftdm_size_t datalen = pausems * sizeof(uint16_t);
data = ftdm_malloc(datalen);
ftdm_assert(data, "Failed to allocate memory\n");
memset(data, FTDM_SILENCE_VALUE(ftdmchan), datalen);
ftdm_buffer_write(ftdmchan->dtmf_buffer, data, datalen);
ftdm_safe_free(data);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_command(ftdm_channel_t *ftdmchan, ftdm_command_t command, void *obj)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "No channel\n");
ftdm_assert_return(ftdmchan->fio != NULL, FTDM_FAIL, "No IO attached to channel\n");
ftdm_channel_lock(ftdmchan);
switch (command) {
case FTDM_COMMAND_ENABLE_CALLERID_DETECT:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_CALLERID)) {
if (ftdm_fsk_demod_init(&ftdmchan->fsk, ftdmchan->rate, ftdmchan->fsk_buf, sizeof(ftdmchan->fsk_buf)) != FTDM_SUCCESS) {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "%s", strerror(errno));
GOTO_STATUS(done, FTDM_FAIL);
}
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_CALLERID_DETECT);
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_DISABLE_CALLERID_DETECT:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_CALLERID)) {
ftdm_fsk_demod_destroy(&ftdmchan->fsk);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_CALLERID_DETECT);
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_TRACE_INPUT:
{
char *path = FTDM_COMMAND_OBJ_CHAR_P;
if (ftdmchan->fds[FTDM_READ_TRACE_INDEX] > 0) {
close(ftdmchan->fds[FTDM_READ_TRACE_INDEX]);
ftdmchan->fds[FTDM_READ_TRACE_INDEX] = -1;
}
if ((ftdmchan->fds[FTDM_READ_TRACE_INDEX] = open(path, O_WRONLY | O_CREAT | O_TRUNC
| FTDM_O_BINARY, S_IRUSR | S_IWUSR)) > -1) {
ftdm_log(FTDM_LOG_DEBUG, "Tracing channel %u:%u input to [%s]\n", ftdmchan->span_id, ftdmchan->chan_id, path);
GOTO_STATUS(done, FTDM_SUCCESS);
}
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "%s", strerror(errno));
GOTO_STATUS(done, FTDM_FAIL);
}
break;
case FTDM_COMMAND_TRACE_OUTPUT:
{
char *path = (char *) obj;
if (ftdmchan->fds[FTDM_WRITE_TRACE_INDEX] > 0) {
close(ftdmchan->fds[FTDM_WRITE_TRACE_INDEX]);
ftdmchan->fds[FTDM_WRITE_TRACE_INDEX] = -1;
}
if ((ftdmchan->fds[FTDM_WRITE_TRACE_INDEX] = open(path, O_WRONLY | O_CREAT | O_TRUNC
| FTDM_O_BINARY, S_IRUSR | S_IWUSR)) > -1) {
ftdm_log(FTDM_LOG_DEBUG, "Tracing channel %u:%u output to [%s]\n", ftdmchan->span_id, ftdmchan->chan_id, path);
GOTO_STATUS(done, FTDM_SUCCESS);
}
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "%s", strerror(errno));
GOTO_STATUS(done, FTDM_FAIL);
}
break;
case FTDM_COMMAND_TRACE_END_ALL:
{
if (ftdmchan->fds[FTDM_READ_TRACE_INDEX] > 0) {
close(ftdmchan->fds[FTDM_READ_TRACE_INDEX]);
ftdmchan->fds[FTDM_READ_TRACE_INDEX] = -1;
}
if (ftdmchan->fds[FTDM_WRITE_TRACE_INDEX] > 0) {
close(ftdmchan->fds[FTDM_WRITE_TRACE_INDEX]);
ftdmchan->fds[FTDM_WRITE_TRACE_INDEX] = -1;
}
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
/*!< Enable DTMF debugging */
case FTDM_COMMAND_ENABLE_DEBUG_DTMF:
{
if (ftdmchan->dtmfdbg.enabled) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Cannot enable debug DTMF again\n");
GOTO_STATUS(done, FTDM_FAIL);
}
if (ftdmchan->rxdump.buffer) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Cannot debug DTMF if Rx dumping is already enabled\n");
GOTO_STATUS(done, FTDM_FAIL);
}
if (start_chan_io_dump(ftdmchan, &ftdmchan->rxdump, FTDM_IO_DUMP_DEFAULT_BUFF_SIZE) != FTDM_SUCCESS) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Failed to enable rx dump for DTMF debugging\n");
GOTO_STATUS(done, FTDM_FAIL);
}
ftdmchan->dtmfdbg.enabled = 1;
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "Enabled DTMF debugging\n");
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
/*!< Disable DTMF debugging (if not disabled explicitly, it is disabled automatically when calls hangup) */
case FTDM_COMMAND_DISABLE_DEBUG_DTMF:
{
if (!ftdmchan->dtmfdbg.enabled) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "DTMF debug is already disabled\n");
GOTO_STATUS(done, FTDM_SUCCESS);
}
if (disable_dtmf_debug(ftdmchan) != FTDM_SUCCESS) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Failed to disable DTMF debug\n");
GOTO_STATUS(done, FTDM_FAIL);
}
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
/*!< Start dumping all input to a circular buffer. The size of the circular buffer can be specified, default used otherwise */
case FTDM_COMMAND_ENABLE_INPUT_DUMP:
{
ftdm_size_t size = obj ? FTDM_COMMAND_OBJ_SIZE : FTDM_IO_DUMP_DEFAULT_BUFF_SIZE;
if (ftdmchan->rxdump.buffer) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Input dump is already enabled\n");
GOTO_STATUS(done, FTDM_FAIL);
}
if (start_chan_io_dump(ftdmchan, &ftdmchan->rxdump, size) != FTDM_SUCCESS) {
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "Failed to enable input dump of size %"FTDM_SIZE_FMT"\n", size);
GOTO_STATUS(done, FTDM_FAIL);
}
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Enabled input dump with size %"FTDM_SIZE_FMT"\n", size);
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
/*!< Stop dumping all input to a circular buffer. */
case FTDM_COMMAND_DISABLE_INPUT_DUMP:
{
if (!ftdmchan->rxdump.buffer) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "No need to disable input dump\n");
GOTO_STATUS(done, FTDM_SUCCESS);
}
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Disabled input dump of size %"FTDM_SIZE_FMT"\n",
ftdmchan->rxdump.size);
stop_chan_io_dump(&ftdmchan->rxdump);
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
/*!< Start dumping all output to a circular buffer. The size of the circular buffer can be specified, default used otherwise */
case FTDM_COMMAND_ENABLE_OUTPUT_DUMP:
{
ftdm_size_t size = obj ? FTDM_COMMAND_OBJ_SIZE : FTDM_IO_DUMP_DEFAULT_BUFF_SIZE;
if (ftdmchan->txdump.buffer) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "Output dump is already enabled\n");
GOTO_STATUS(done, FTDM_FAIL);
}
if (start_chan_io_dump(ftdmchan, &ftdmchan->txdump, size) != FTDM_SUCCESS) {
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "Failed to enable output dump of size %"FTDM_SIZE_FMT"\n", size);
GOTO_STATUS(done, FTDM_FAIL);
}
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Enabled output dump with size %"FTDM_SIZE_FMT"\n", size);
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
/*!< Stop dumping all output to a circular buffer. */
case FTDM_COMMAND_DISABLE_OUTPUT_DUMP:
{
if (!ftdmchan->txdump.buffer) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "No need to disable output dump\n");
GOTO_STATUS(done, FTDM_SUCCESS);
}
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Disabled output dump of size %"FTDM_SIZE_FMT"\n", ftdmchan->rxdump.size);
stop_chan_io_dump(&ftdmchan->txdump);
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
/*!< Dump the current input circular buffer to the specified FILE* structure */
case FTDM_COMMAND_DUMP_INPUT:
{
if (!obj) {
GOTO_STATUS(done, FTDM_FAIL);
}
if (!ftdmchan->rxdump.buffer) {
ftdm_log_chan(ftdmchan, FTDM_LOG_WARNING, "Not dumped input to file %p, input dump is not enabled\n", obj);
GOTO_STATUS(done, FTDM_FAIL);
}
dump_chan_io_to_file(ftdmchan, &ftdmchan->rxdump, obj);
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Dumped input of size %"FTDM_SIZE_FMT" to file %p\n", ftdmchan->rxdump.size, obj);
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
/*!< Dump the current output circular buffer to the specified FILE* structure */
case FTDM_COMMAND_DUMP_OUTPUT:
{
if (!obj) {
GOTO_STATUS(done, FTDM_FAIL);
}
if (!ftdmchan->txdump.buffer) {
ftdm_log_chan(ftdmchan, FTDM_LOG_WARNING, "Not dumped output to file %p, output dump is not enabled\n", obj);
GOTO_STATUS(done, FTDM_FAIL);
}
dump_chan_io_to_file(ftdmchan, &ftdmchan->txdump, obj);
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Dumped input of size %"FTDM_SIZE_FMT" to file %p\n", ftdmchan->txdump.size, obj);
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
case FTDM_COMMAND_SET_INTERVAL:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_INTERVAL)) {
ftdmchan->effective_interval = FTDM_COMMAND_OBJ_INT;
if (ftdmchan->effective_interval == ftdmchan->native_interval) {
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_BUFFER);
} else {
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_BUFFER);
}
ftdmchan->packet_len = ftdmchan->native_interval * (ftdmchan->effective_codec == FTDM_CODEC_SLIN ? 16 : 8);
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_GET_INTERVAL:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_INTERVAL)) {
FTDM_COMMAND_OBJ_INT = ftdmchan->effective_interval;
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_SET_CODEC:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_CODECS)) {
ftdmchan->effective_codec = FTDM_COMMAND_OBJ_INT;
if (ftdmchan->effective_codec == ftdmchan->native_codec) {
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_TRANSCODE);
} else {
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_TRANSCODE);
}
ftdmchan->packet_len = ftdmchan->native_interval * (ftdmchan->effective_codec == FTDM_CODEC_SLIN ? 16 : 8);
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_SET_NATIVE_CODEC:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_CODECS)) {
ftdmchan->effective_codec = ftdmchan->native_codec;
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_TRANSCODE);
ftdmchan->packet_len = ftdmchan->native_interval * (ftdmchan->effective_codec == FTDM_CODEC_SLIN ? 16 : 8);
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_GET_CODEC:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_CODECS)) {
FTDM_COMMAND_OBJ_INT = ftdmchan->effective_codec;
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_GET_NATIVE_CODEC:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_CODECS)) {
FTDM_COMMAND_OBJ_INT = ftdmchan->native_codec;
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_ENABLE_PROGRESS_DETECT:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_PROGRESS)) {
/* if they don't have thier own, use ours */
ftdm_channel_clear_detected_tones(ftdmchan);
ftdm_channel_clear_needed_tones(ftdmchan);
teletone_multi_tone_init(&ftdmchan->span->tone_finder[FTDM_TONEMAP_DIAL], &ftdmchan->span->tone_detect_map[FTDM_TONEMAP_DIAL]);
teletone_multi_tone_init(&ftdmchan->span->tone_finder[FTDM_TONEMAP_RING], &ftdmchan->span->tone_detect_map[FTDM_TONEMAP_RING]);
teletone_multi_tone_init(&ftdmchan->span->tone_finder[FTDM_TONEMAP_BUSY], &ftdmchan->span->tone_detect_map[FTDM_TONEMAP_BUSY]);
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_PROGRESS_DETECT);
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_DISABLE_PROGRESS_DETECT:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_PROGRESS)) {
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_PROGRESS_DETECT);
ftdm_channel_clear_detected_tones(ftdmchan);
ftdm_channel_clear_needed_tones(ftdmchan);
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_ENABLE_DTMF_DETECT:
{
/* if they don't have thier own, use ours */
if (FTDM_IS_VOICE_CHANNEL(ftdmchan)) {
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_DTMF_DETECT)) {
teletone_dtmf_detect_init (&ftdmchan->dtmf_detect, ftdmchan->rate);
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_DTMF_DETECT);
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_SUPRESS_DTMF);
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "Enabled software DTMF detector\n");
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
}
break;
case FTDM_COMMAND_DISABLE_DTMF_DETECT:
{
if (FTDM_IS_VOICE_CHANNEL(ftdmchan)) {
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_DTMF_DETECT)) {
teletone_dtmf_detect_init (&ftdmchan->dtmf_detect, ftdmchan->rate);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_DTMF_DETECT);
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_SUPRESS_DTMF);
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_DEBUG, "Disabled software DTMF detector\n");
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
}
break;
case FTDM_COMMAND_SET_PRE_BUFFER_SIZE:
{
int val = FTDM_COMMAND_OBJ_INT;
if (val < 0) {
val = 0;
}
ftdmchan->pre_buffer_size = val * 8;
ftdm_mutex_lock(ftdmchan->pre_buffer_mutex);
if (!ftdmchan->pre_buffer_size) {
ftdm_buffer_destroy(&ftdmchan->pre_buffer);
} else if (!ftdmchan->pre_buffer) {
ftdm_buffer_create(&ftdmchan->pre_buffer, 1024, ftdmchan->pre_buffer_size, 0);
}
ftdm_mutex_unlock(ftdmchan->pre_buffer_mutex);
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
case FTDM_COMMAND_GET_DTMF_ON_PERIOD:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_DTMF_GENERATE)) {
FTDM_COMMAND_OBJ_INT = ftdmchan->dtmf_on;
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_GET_DTMF_OFF_PERIOD:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_DTMF_GENERATE)) {
FTDM_COMMAND_OBJ_INT = ftdmchan->dtmf_on;
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_SET_DTMF_ON_PERIOD:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_DTMF_GENERATE)) {
int val = FTDM_COMMAND_OBJ_INT;
if (val > 10 && val < 1000) {
ftdmchan->dtmf_on = val;
GOTO_STATUS(done, FTDM_SUCCESS);
} else {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "invalid value %d range 10-1000", val);
GOTO_STATUS(done, FTDM_FAIL);
}
}
}
break;
case FTDM_COMMAND_SET_DTMF_OFF_PERIOD:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_DTMF_GENERATE)) {
int val = FTDM_COMMAND_OBJ_INT;
if (val > 10 && val < 1000) {
ftdmchan->dtmf_off = val;
GOTO_STATUS(done, FTDM_SUCCESS);
} else {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "invalid value %d range 10-1000", val);
GOTO_STATUS(done, FTDM_FAIL);
}
}
}
break;
case FTDM_COMMAND_SEND_DTMF:
{
if (!ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_DTMF_GENERATE)) {
char *digits = FTDM_COMMAND_OBJ_CHAR_P;
if ((status = ftdmchan_activate_dtmf_buffer(ftdmchan)) != FTDM_SUCCESS) {
GOTO_STATUS(done, status);
}
ftdm_buffer_write(ftdmchan->gen_dtmf_buffer, digits, strlen(digits));
GOTO_STATUS(done, FTDM_SUCCESS);
}
}
break;
case FTDM_COMMAND_DISABLE_ECHOCANCEL:
{
ftdm_mutex_lock(ftdmchan->pre_buffer_mutex);
ftdm_buffer_destroy(&ftdmchan->pre_buffer);
ftdmchan->pre_buffer_size = 0;
ftdm_mutex_unlock(ftdmchan->pre_buffer_mutex);
}
break;
case FTDM_COMMAND_SET_RX_GAIN:
{
if (!FTDM_IS_VOICE_CHANNEL(ftdmchan)) {
ftdm_log(FTDM_LOG_ERROR, "Cannot set rx gain in non-voice channel of type: %s\n", ftdm_chan_type2str(ftdmchan->type));
GOTO_STATUS(done, FTDM_FAIL);
}
ftdmchan->rxgain = FTDM_COMMAND_OBJ_FLOAT;
reset_gain_table(ftdmchan->rxgain_table, ftdmchan->rxgain, ftdmchan->native_codec);
if (ftdmchan->rxgain == 0.0) {
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_USE_RX_GAIN);
} else {
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_USE_RX_GAIN);
}
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
case FTDM_COMMAND_GET_RX_GAIN:
{
FTDM_COMMAND_OBJ_FLOAT = ftdmchan->rxgain;
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
case FTDM_COMMAND_SET_TX_GAIN:
{
if (!FTDM_IS_VOICE_CHANNEL(ftdmchan)) {
ftdm_log(FTDM_LOG_ERROR, "Cannot set tx gain in non-voice channel of type: %s\n", ftdm_chan_type2str(ftdmchan->type));
GOTO_STATUS(done, FTDM_FAIL);
}
ftdmchan->txgain = FTDM_COMMAND_OBJ_FLOAT;
reset_gain_table(ftdmchan->txgain_table, ftdmchan->txgain, ftdmchan->native_codec);
if (ftdmchan->txgain == 0.0) {
ftdm_clear_flag(ftdmchan, FTDM_CHANNEL_USE_TX_GAIN);
} else {
ftdm_set_flag(ftdmchan, FTDM_CHANNEL_USE_TX_GAIN);
}
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
case FTDM_COMMAND_GET_TX_GAIN:
{
FTDM_COMMAND_OBJ_FLOAT = ftdmchan->txgain;
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
case FTDM_COMMAND_GET_IOSTATS:
{
if (!obj) {
GOTO_STATUS(done, FTDM_EINVAL);
}
memcpy(obj, &ftdmchan->iostats, sizeof(ftdmchan->iostats));
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
case FTDM_COMMAND_SWITCH_IOSTATS:
{
ftdm_bool_t enable = *(ftdm_bool_t *)obj;
if (enable) {
ftdm_channel_set_feature(ftdmchan, FTDM_CHANNEL_FEATURE_IO_STATS);
} else {
ftdm_channel_clear_feature(ftdmchan, FTDM_CHANNEL_FEATURE_IO_STATS);
}
GOTO_STATUS(done, FTDM_SUCCESS);
}
break;
default:
break;
}
if (!ftdmchan->fio->command) {
ftdm_log(FTDM_LOG_ERROR, "no command function defined by the I/O freetdm module!\n");
GOTO_STATUS(done, FTDM_FAIL);
}
status = ftdmchan->fio->command(ftdmchan, command, obj);
if (status == FTDM_NOTIMPL) {
ftdm_log(FTDM_LOG_ERROR, "I/O backend does not support command %d!\n", command);
}
done:
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_wait(ftdm_channel_t *ftdmchan, ftdm_wait_flag_t *flags, int32_t to)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "Null channel\n");
ftdm_assert_return(ftdmchan->fio != NULL, FTDM_FAIL, "Null io interface\n");
ftdm_assert_return(ftdmchan->fio->wait != NULL, FTDM_NOTIMPL, "wait method not implemented\n");
status = ftdmchan->fio->wait(ftdmchan, flags, to);
if (status == FTDM_TIMEOUT) {
/* make sure the flags are cleared on timeout */
*flags = 0;
}
return status;
}
/*******************************/
FIO_CODEC_FUNCTION(fio_slin2ulaw)
{
int16_t sln_buf[512] = {0}, *sln = sln_buf;
uint8_t *lp = data;
uint32_t i;
ftdm_size_t len = *datalen;
if (max > len) {
max = len;
}
memcpy(sln, data, max);
for(i = 0; i < max; i++) {
*lp++ = linear_to_ulaw(*sln++);
}
*datalen = max / 2;
return FTDM_SUCCESS;
}
FIO_CODEC_FUNCTION(fio_ulaw2slin)
{
int16_t *sln = data;
uint8_t law[1024] = {0}, *lp = law;
uint32_t i;
ftdm_size_t len = *datalen;
if (max > len) {
max = len;
}
memcpy(law, data, max);
for(i = 0; i < max; i++) {
*sln++ = ulaw_to_linear(*lp++);
}
*datalen = max * 2;
return FTDM_SUCCESS;
}
FIO_CODEC_FUNCTION(fio_slin2alaw)
{
int16_t sln_buf[512] = {0}, *sln = sln_buf;
uint8_t *lp = data;
uint32_t i;
ftdm_size_t len = *datalen;
if (max > len) {
max = len;
}
memcpy(sln, data, max);
for(i = 0; i < max; i++) {
*lp++ = linear_to_alaw(*sln++);
}
*datalen = max / 2;
return FTDM_SUCCESS;
}
FIO_CODEC_FUNCTION(fio_alaw2slin)
{
int16_t *sln = data;
uint8_t law[1024] = {0}, *lp = law;
uint32_t i;
ftdm_size_t len = *datalen;
if (max > len) {
max = len;
}
memcpy(law, data, max);
for(i = 0; i < max; i++) {
*sln++ = alaw_to_linear(*lp++);
}
*datalen = max * 2;
return FTDM_SUCCESS;
}
FIO_CODEC_FUNCTION(fio_ulaw2alaw)
{
ftdm_size_t len = *datalen;
uint32_t i;
uint8_t *lp = data;
if (max > len) {
max = len;
}
for(i = 0; i < max; i++) {
*lp = ulaw_to_alaw(*lp);
lp++;
}
return FTDM_SUCCESS;
}
FIO_CODEC_FUNCTION(fio_alaw2ulaw)
{
ftdm_size_t len = *datalen;
uint32_t i;
uint8_t *lp = data;
if (max > len) {
max = len;
}
for(i = 0; i < max; i++) {
*lp = alaw_to_ulaw(*lp);
lp++;
}
return FTDM_SUCCESS;
}
/******************************/
FT_DECLARE(void) ftdm_channel_clear_detected_tones(ftdm_channel_t *ftdmchan)
{
uint32_t i;
memset(ftdmchan->detected_tones, 0, sizeof(ftdmchan->detected_tones[0]) * FTDM_TONEMAP_INVALID);
for (i = 1; i < FTDM_TONEMAP_INVALID; i++) {
ftdmchan->span->tone_finder[i].tone_count = 0;
}
}
FT_DECLARE(void) ftdm_channel_clear_needed_tones(ftdm_channel_t *ftdmchan)
{
memset(ftdmchan->needed_tones, 0, sizeof(ftdmchan->needed_tones[0]) * FTDM_TONEMAP_INVALID);
}
FT_DECLARE(ftdm_size_t) ftdm_channel_dequeue_dtmf(ftdm_channel_t *ftdmchan, char *dtmf, ftdm_size_t len)
{
ftdm_size_t bytes = 0;
assert(ftdmchan != NULL);
if (!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_READY)) {
return 0;
}
if (ftdmchan->digit_buffer && ftdm_buffer_inuse(ftdmchan->digit_buffer)) {
ftdm_mutex_lock(ftdmchan->mutex);
if ((bytes = ftdm_buffer_read(ftdmchan->digit_buffer, dtmf, len)) > 0) {
*(dtmf + bytes) = '\0';
}
ftdm_mutex_unlock(ftdmchan->mutex);
}
return bytes;
}
FT_DECLARE(void) ftdm_channel_flush_dtmf(ftdm_channel_t *ftdmchan)
{
if (ftdmchan->digit_buffer && ftdm_buffer_inuse(ftdmchan->digit_buffer)) {
ftdm_mutex_lock(ftdmchan->mutex);
ftdm_buffer_zero(ftdmchan->digit_buffer);
ftdm_mutex_unlock(ftdmchan->mutex);
}
}
FT_DECLARE(ftdm_status_t) ftdm_channel_queue_dtmf(ftdm_channel_t *ftdmchan, const char *dtmf)
{
ftdm_status_t status;
register ftdm_size_t len, inuse;
ftdm_size_t wr = 0;
const char *p;
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "No channel\n");
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Queuing DTMF %s (debug = %d)\n", dtmf, ftdmchan->dtmfdbg.enabled);
if (ftdmchan->span->sig_dtmf && (ftdmchan->span->sig_dtmf(ftdmchan, dtmf) == FTDM_BREAK)) {
/* Signalling module wants to absorb this DTMF event */
return FTDM_SUCCESS;
}
if (!ftdmchan->dtmfdbg.enabled) {
goto skipdebug;
}
if (!ftdmchan->dtmfdbg.file) {
struct tm currtime;
time_t currsec;
char dfile[1024];
currsec = time(NULL);
#ifdef WIN32
_tzset();
_localtime64_s(&currtime, &currsec);
#else
localtime_r(&currsec, &currtime);
#endif
if (ftdm_strlen_zero(globals.dtmfdebug_directory)) {
snprintf(dfile, sizeof(dfile), "dtmf-s%dc%d-20%d-%d-%d-%d%d%d.%s",
ftdmchan->span_id, ftdmchan->chan_id,
currtime.tm_year-100, currtime.tm_mon+1, currtime.tm_mday,
currtime.tm_hour, currtime.tm_min, currtime.tm_sec, ftdmchan->native_codec == FTDM_CODEC_ULAW ? "ulaw" : ftdmchan->native_codec == FTDM_CODEC_ALAW ? "alaw" : "sln");
} else {
snprintf(dfile, sizeof(dfile), "%s/dtmf-s%dc%d-20%d-%d-%d-%d%d%d.%s",
globals.dtmfdebug_directory,
ftdmchan->span_id, ftdmchan->chan_id,
currtime.tm_year-100, currtime.tm_mon+1, currtime.tm_mday,
currtime.tm_hour, currtime.tm_min, currtime.tm_sec, ftdmchan->native_codec == FTDM_CODEC_ULAW ? "ulaw" : ftdmchan->native_codec == FTDM_CODEC_ALAW ? "alaw" : "sln");
}
ftdmchan->dtmfdbg.file = fopen(dfile, "wb");
if (!ftdmchan->dtmfdbg.file) {
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "failed to open debug dtmf file %s\n", dfile);
} else {
ftdmchan->dtmfdbg.closetimeout = DTMF_DEBUG_TIMEOUT;
ftdm_channel_command(ftdmchan, FTDM_COMMAND_DUMP_INPUT, ftdmchan->dtmfdbg.file);
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Dumped initial DTMF output to %s\n", dfile);
}
} else {
ftdmchan->dtmfdbg.closetimeout = DTMF_DEBUG_TIMEOUT;
}
skipdebug:
if (ftdmchan->pre_buffer) {
ftdm_buffer_zero(ftdmchan->pre_buffer);
}
ftdm_mutex_lock(ftdmchan->mutex);
inuse = ftdm_buffer_inuse(ftdmchan->digit_buffer);
len = strlen(dtmf);
if (len + inuse > ftdm_buffer_len(ftdmchan->digit_buffer)) {
ftdm_buffer_toss(ftdmchan->digit_buffer, strlen(dtmf));
}
if (ftdmchan->span->dtmf_hangup_len) {
for (p = dtmf; ftdm_is_dtmf(*p); p++) {
memmove (ftdmchan->dtmf_hangup_buf, ftdmchan->dtmf_hangup_buf + 1, ftdmchan->span->dtmf_hangup_len - 1);
ftdmchan->dtmf_hangup_buf[ftdmchan->span->dtmf_hangup_len - 1] = *p;
if (!strcmp(ftdmchan->dtmf_hangup_buf, ftdmchan->span->dtmf_hangup)) {
ftdm_log(FTDM_LOG_DEBUG, "DTMF hangup detected.\n");
ftdm_channel_set_state(__FILE__, __FUNCTION__, __LINE__, ftdmchan, FTDM_CHANNEL_STATE_HANGUP, 0, NULL);
break;
}
}
}
p = dtmf;
while (wr < len && p) {
if (ftdm_is_dtmf(*p)) {
wr++;
} else {
break;
}
p++;
}
status = ftdm_buffer_write(ftdmchan->digit_buffer, dtmf, wr) ? FTDM_SUCCESS : FTDM_FAIL;
ftdm_mutex_unlock(ftdmchan->mutex);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_raw_write (ftdm_channel_t *ftdmchan, void *data, ftdm_size_t *datalen)
{
int dlen = (int) *datalen;
if (ftdm_test_io_flag(ftdmchan, FTDM_CHANNEL_IO_WRITE)) {
ftdm_clear_io_flag(ftdmchan, FTDM_CHANNEL_IO_WRITE);
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_TX_DISABLED)) {
ftdmchan->txdrops++;
if (ftdmchan->txdrops <= 10) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "cannot write in channel with tx disabled\n");
}
if (ftdmchan->txdrops == 10) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "Too many tx drops, not printing anymore\n");
}
return FTDM_FAIL;
}
if (ftdmchan->fds[FTDM_WRITE_TRACE_INDEX] > -1) {
if ((write(ftdmchan->fds[FTDM_WRITE_TRACE_INDEX], data, dlen)) != dlen) {
ftdm_log(FTDM_LOG_WARNING, "Raw output trace failed to write all of the %d bytes\n", dlen);
}
}
write_chan_io_dump(&ftdmchan->txdump, data, dlen);
return ftdmchan->fio->write(ftdmchan, data, datalen);
}
FT_DECLARE(ftdm_status_t) ftdm_raw_read (ftdm_channel_t *ftdmchan, void *data, ftdm_size_t *datalen)
{
ftdm_status_t status;
if (ftdm_test_io_flag(ftdmchan, FTDM_CHANNEL_IO_READ)) {
ftdm_clear_io_flag(ftdmchan, FTDM_CHANNEL_IO_READ);
}
status = ftdmchan->fio->read(ftdmchan, data, datalen);
if (status == FTDM_SUCCESS && ftdm_test_flag(ftdmchan, FTDM_CHANNEL_USE_RX_GAIN)
&& (ftdmchan->native_codec == FTDM_CODEC_ALAW || ftdmchan->native_codec == FTDM_CODEC_ULAW)) {
ftdm_size_t i = 0;
unsigned char *rdata = data;
for (i = 0; i < *datalen; i++) {
rdata[i] = ftdmchan->rxgain_table[rdata[i]];
}
}
if (status == FTDM_SUCCESS && ftdmchan->fds[FTDM_READ_TRACE_INDEX] > -1) {
ftdm_size_t dlen = *datalen;
if ((ftdm_size_t)write(ftdmchan->fds[FTDM_READ_TRACE_INDEX], data, (int)dlen) != dlen) {
ftdm_log(FTDM_LOG_WARNING, "Raw input trace failed to write all of the %"FTDM_SIZE_FMT" bytes\n", dlen);
}
}
if (status == FTDM_SUCCESS && ftdmchan->span->sig_read) {
ftdmchan->span->sig_read(ftdmchan, data, *datalen);
}
if (status == FTDM_SUCCESS) {
ftdm_size_t dlen = *datalen;
ftdm_size_t rc = 0;
write_chan_io_dump(&ftdmchan->rxdump, data, (int)dlen);
/* if dtmf debug is enabled and initialized, write there too */
if (ftdmchan->dtmfdbg.file) {
rc = fwrite(data, 1, dlen, ftdmchan->dtmfdbg.file);
if (rc != dlen) {
ftdm_log(FTDM_LOG_WARNING, "DTMF debugger wrote only %"FTDM_SIZE_FMT" out of %"FTDM_SIZE_FMT" bytes: %s\n",
rc, *datalen, strerror(errno));
}
ftdmchan->dtmfdbg.closetimeout--;
if (!ftdmchan->dtmfdbg.closetimeout) {
close_dtmf_debug_file(ftdmchan);
}
}
}
return status;
}
/* This function takes care of automatically generating DTMF or FSK tones when needed */
static ftdm_status_t handle_tone_generation(ftdm_channel_t *ftdmchan)
{
/*
* datalen: size in bytes of the chunk of data the user requested to read (this function
* is called from the ftdm_channel_read function)
* dblen: size currently in use in any of the tone generation buffers (data available in the buffer)
* gen_dtmf_buffer: buffer holding the raw ASCII digits that the user requested to generate
* dtmf_buffer: raw linear tone data generated by teletone to be written to the devices
* fsk_buffer: raw linear FSK modulated data for caller id
*/
ftdm_buffer_t *buffer = NULL;
ftdm_size_t dblen = 0;
int wrote = 0;
if (ftdmchan->gen_dtmf_buffer && (dblen = ftdm_buffer_inuse(ftdmchan->gen_dtmf_buffer))) {
char digits[128] = "";
char *cur;
int x = 0;
if (dblen > sizeof(digits) - 1) {
dblen = sizeof(digits) - 1;
}
if (ftdm_buffer_read(ftdmchan->gen_dtmf_buffer, digits, dblen) && !ftdm_strlen_zero_buf(digits)) {
ftdm_log_chan(ftdmchan, FTDM_LOG_DEBUG, "Generating DTMF [%s]\n", digits);
cur = digits;
for (; *cur; cur++) {
if (*cur == 'F') {
ftdm_channel_command(ftdmchan, FTDM_COMMAND_FLASH, NULL);
} else if (*cur == 'w') {
ftdm_insert_dtmf_pause(ftdmchan, FTDM_HALF_DTMF_PAUSE);
} else if (*cur == 'W') {
ftdm_insert_dtmf_pause(ftdmchan, FTDM_FULL_DTMF_PAUSE);
} else {
if ((wrote = teletone_mux_tones(&ftdmchan->tone_session, &ftdmchan->tone_session.TONES[(int)*cur]))) {
ftdm_buffer_write(ftdmchan->dtmf_buffer, ftdmchan->tone_session.buffer, wrote * 2);
x++;
} else {
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "Problem adding DTMF sequence [%s]\n", digits);
return FTDM_FAIL;
}
}
if (x) {
ftdmchan->skip_read_frames = (wrote / (ftdmchan->effective_interval * 8)) + 4;
}
}
}
}
if (!ftdmchan->buffer_delay || --ftdmchan->buffer_delay == 0) {
/* time to pick a buffer, either the dtmf or fsk buffer */
if (ftdmchan->dtmf_buffer && (dblen = ftdm_buffer_inuse(ftdmchan->dtmf_buffer))) {
buffer = ftdmchan->dtmf_buffer;
} else if (ftdmchan->fsk_buffer && (dblen = ftdm_buffer_inuse(ftdmchan->fsk_buffer))) {
buffer = ftdmchan->fsk_buffer;
}
}
/* if we picked a buffer, time to read from it and write the linear data to the device */
if (buffer) {
uint8_t auxbuf[1024];
ftdm_size_t dlen = ftdmchan->packet_len;
ftdm_size_t len, br, max = sizeof(auxbuf);
/* if the codec is not linear, then data is really twice as much cuz
tone generation is done in linear (we assume anything different than linear is G.711) */
if (ftdmchan->native_codec != FTDM_CODEC_SLIN) {
dlen *= 2;
}
/* we do not expect the user chunks to be bigger than auxbuf */
ftdm_assert((dlen <= sizeof(auxbuf)), "Unexpected size for user data chunk size\n");
/* dblen is the size in use for dtmf_buffer or fsk_buffer, and dlen is the size
* of the io chunks to write, we pick the smaller one */
len = dblen > dlen ? dlen : dblen;
/* we can't read more than the size of our auxiliary buffer */
ftdm_assert((len <= sizeof(auxbuf)), "Unexpected size to read into auxbuf\n");
br = ftdm_buffer_read(buffer, auxbuf, len);
/* the amount read can't possibly be bigger than what we requested */
ftdm_assert((br <= len), "Unexpected size read from tone generation buffer\n");
/* if we read less than the chunk size, we must fill in with silence the rest */
if (br < dlen) {
memset(auxbuf + br, 0, dlen - br);
}
/* finally we convert to the native format for the channel if necessary */
if (ftdmchan->native_codec != FTDM_CODEC_SLIN) {
if (ftdmchan->native_codec == FTDM_CODEC_ULAW) {
fio_slin2ulaw(auxbuf, max, &dlen);
} else if (ftdmchan->native_codec == FTDM_CODEC_ALAW) {
fio_slin2alaw(auxbuf, max, &dlen);
}
}
/* write the tone to the channel */
return ftdm_raw_write(ftdmchan, auxbuf, &dlen);
}
return FTDM_SUCCESS;
}
FT_DECLARE(void) ftdm_generate_sln_silence(int16_t *data, uint32_t samples, uint32_t divisor)
{
int16_t x;
uint32_t i;
int sum_rnd = 0;
int16_t rnd2 = (int16_t) ftdm_current_time_in_ms() * (int16_t) (intptr_t) data;
assert(divisor);
for (i = 0; i < samples; i++, sum_rnd = 0) {
for (x = 0; x < 6; x++) {
rnd2 = rnd2 * 31821U + 13849U;
sum_rnd += rnd2 ;
}
//switch_normalize_to_16bit(sum_rnd);
*data = (int16_t) ((int16_t) sum_rnd / (int) divisor);
data++;
}
}
FT_DECLARE(ftdm_status_t) ftdm_channel_process_media(ftdm_channel_t *ftdmchan, void *data, ftdm_size_t *datalen)
{
fio_codec_t codec_func = NULL;
ftdm_size_t max = *datalen;
handle_tone_generation(ftdmchan);
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_DIGITAL_MEDIA)) {
goto done;
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_TRANSCODE) && ftdmchan->effective_codec != ftdmchan->native_codec) {
if (ftdmchan->native_codec == FTDM_CODEC_ULAW && ftdmchan->effective_codec == FTDM_CODEC_SLIN) {
codec_func = fio_ulaw2slin;
} else if (ftdmchan->native_codec == FTDM_CODEC_ULAW && ftdmchan->effective_codec == FTDM_CODEC_ALAW) {
codec_func = fio_ulaw2alaw;
} else if (ftdmchan->native_codec == FTDM_CODEC_ALAW && ftdmchan->effective_codec == FTDM_CODEC_SLIN) {
codec_func = fio_alaw2slin;
} else if (ftdmchan->native_codec == FTDM_CODEC_ALAW && ftdmchan->effective_codec == FTDM_CODEC_ULAW) {
codec_func = fio_alaw2ulaw;
}
if (codec_func) {
codec_func(data, max, datalen);
} else {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "codec error!");
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "no codec function to perform transcoding from %d to %d\n", ftdmchan->native_codec, ftdmchan->effective_codec);
}
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_DTMF_DETECT) ||
ftdm_test_flag(ftdmchan, FTDM_CHANNEL_PROGRESS_DETECT) ||
ftdm_test_flag(ftdmchan, FTDM_CHANNEL_CALLERID_DETECT)) {
uint8_t sln_buf[1024] = {0};
int16_t *sln;
ftdm_size_t slen = 0;
if (ftdmchan->effective_codec == FTDM_CODEC_SLIN) {
sln = data;
slen = *datalen / 2;
} else {
ftdm_size_t len = *datalen;
uint32_t i;
uint8_t *lp = data;
slen = sizeof(sln_buf) / 2;
if (len > slen) {
len = slen;
}
sln = (int16_t *) sln_buf;
for(i = 0; i < len; i++) {
if (ftdmchan->effective_codec == FTDM_CODEC_ULAW) {
*sln++ = ulaw_to_linear(*lp++);
} else if (ftdmchan->effective_codec == FTDM_CODEC_ALAW) {
*sln++ = alaw_to_linear(*lp++);
} else {
snprintf(ftdmchan->last_error, sizeof(ftdmchan->last_error), "codec error!");
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "invalid effective codec %d\n", ftdmchan->effective_codec);
goto done;
}
}
sln = (int16_t *) sln_buf;
slen = len;
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_CALLERID_DETECT)) {
if (ftdm_fsk_demod_feed(&ftdmchan->fsk, sln, slen) != FTDM_SUCCESS) {
ftdm_size_t type, mlen;
char str[128], *sp;
while(ftdm_fsk_data_parse(&ftdmchan->fsk, &type, &sp, &mlen) == FTDM_SUCCESS) {
*(str+mlen) = '\0';
ftdm_copy_string(str, sp, ++mlen);
ftdm_clean_string(str);
ftdm_log(FTDM_LOG_DEBUG, "FSK: TYPE %s LEN %"FTDM_SIZE_FMT" VAL [%s]\n",
ftdm_mdmf_type2str(type), mlen-1, str);
switch(type) {
case MDMF_DDN:
case MDMF_PHONE_NUM:
{
if (mlen > sizeof(ftdmchan->caller_data.ani)) {
mlen = sizeof(ftdmchan->caller_data.ani);
}
ftdm_set_string(ftdmchan->caller_data.ani.digits, str);
ftdm_set_string(ftdmchan->caller_data.cid_num.digits, ftdmchan->caller_data.ani.digits);
}
break;
case MDMF_NO_NUM:
{
ftdm_set_string(ftdmchan->caller_data.ani.digits, *str == 'P' ? "private" : "unknown");
ftdm_set_string(ftdmchan->caller_data.cid_name, ftdmchan->caller_data.ani.digits);
}
break;
case MDMF_PHONE_NAME:
{
if (mlen > sizeof(ftdmchan->caller_data.cid_name)) {
mlen = sizeof(ftdmchan->caller_data.cid_name);
}
ftdm_set_string(ftdmchan->caller_data.cid_name, str);
}
break;
case MDMF_NO_NAME:
{
ftdm_set_string(ftdmchan->caller_data.cid_name, *str == 'P' ? "private" : "unknown");
}
case MDMF_DATETIME:
{
if (mlen > sizeof(ftdmchan->caller_data.cid_date)) {
mlen = sizeof(ftdmchan->caller_data.cid_date);
}
ftdm_set_string(ftdmchan->caller_data.cid_date, str);
}
break;
}
}
ftdm_channel_command(ftdmchan, FTDM_COMMAND_DISABLE_CALLERID_DETECT, NULL);
}
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_PROGRESS_DETECT) && !ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_PROGRESS)) {
uint32_t i;
for (i = 1; i < FTDM_TONEMAP_INVALID; i++) {
if (ftdmchan->span->tone_finder[i].tone_count) {
if (ftdmchan->needed_tones[i] && teletone_multi_tone_detect(&ftdmchan->span->tone_finder[i], sln, (int)slen)) {
if (++ftdmchan->detected_tones[i]) {
ftdmchan->needed_tones[i] = 0;
ftdmchan->detected_tones[0]++;
}
}
}
}
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_DTMF_DETECT) && !ftdm_channel_test_feature(ftdmchan, FTDM_CHANNEL_FEATURE_DTMF_DETECT)) {
teletone_hit_type_t hit;
char digit_char;
uint32_t dur;
if ((hit = teletone_dtmf_detect(&ftdmchan->dtmf_detect, sln, (int)slen)) == TT_HIT_END) {
teletone_dtmf_get(&ftdmchan->dtmf_detect, &digit_char, &dur);
if (ftdmchan->state == FTDM_CHANNEL_STATE_CALLWAITING && (digit_char == 'D' || digit_char == 'A')) {
ftdmchan->detected_tones[FTDM_TONEMAP_CALLWAITING_ACK]++;
} else {
char digit_str[2] = { 0 };
digit_str[0] = digit_char;
ftdm_channel_queue_dtmf(ftdmchan, digit_str);
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_SUPRESS_DTMF)) {
ftdmchan->skip_read_frames = 20;
}
}
}
}
}
if (ftdmchan->skip_read_frames > 0 || ftdm_test_flag(ftdmchan, FTDM_CHANNEL_MUTE)) {
ftdm_mutex_lock(ftdmchan->pre_buffer_mutex);
if (ftdmchan->pre_buffer && ftdm_buffer_inuse(ftdmchan->pre_buffer)) {
ftdm_buffer_zero(ftdmchan->pre_buffer);
}
ftdm_mutex_unlock(ftdmchan->pre_buffer_mutex);
memset(data, FTDM_SILENCE_VALUE(ftdmchan), *datalen);
if (ftdmchan->skip_read_frames > 0) {
ftdmchan->skip_read_frames--;
}
} else {
ftdm_mutex_lock(ftdmchan->pre_buffer_mutex);
if (ftdmchan->pre_buffer_size && ftdmchan->pre_buffer) {
ftdm_buffer_write(ftdmchan->pre_buffer, data, *datalen);
if (ftdm_buffer_inuse(ftdmchan->pre_buffer) >= ftdmchan->pre_buffer_size) {
ftdm_buffer_read(ftdmchan->pre_buffer, data, *datalen);
} else {
memset(data, FTDM_SILENCE_VALUE(ftdmchan), *datalen);
}
}
ftdm_mutex_unlock(ftdmchan->pre_buffer_mutex);
}
done:
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_read(ftdm_channel_t *ftdmchan, void *data, ftdm_size_t *datalen)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "ftdmchan is null\n");
ftdm_assert_return(ftdmchan->fio != NULL, FTDM_FAIL, "No I/O module attached to ftdmchan\n");
ftdm_channel_lock(ftdmchan);
if (!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_OPEN)) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "cannot read from channel that is not open\n");
status = FTDM_FAIL;
goto done;
}
if (!ftdmchan->fio->read) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "read method not implemented\n");
status = FTDM_FAIL;
goto done;
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_RX_DISABLED)) {
ftdmchan->rxdrops++;
if (ftdmchan->rxdrops <= 10) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "cannot read from channel with rx disabled\n");
}
if (ftdmchan->rxdrops == 10) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "too many rx drops, not logging anymore\n");
}
status = FTDM_FAIL;
goto done;
}
status = ftdm_raw_read(ftdmchan, data, datalen);
if (status != FTDM_SUCCESS) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "raw I/O read filed\n");
goto done;
}
status = ftdm_channel_process_media(ftdmchan, data, datalen);
if (status != FTDM_SUCCESS) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "Failed to process media\n");
}
done:
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_write(ftdm_channel_t *ftdmchan, void *data, ftdm_size_t datasize, ftdm_size_t *datalen)
{
ftdm_status_t status = FTDM_SUCCESS;
fio_codec_t codec_func = NULL;
ftdm_size_t max = datasize;
unsigned int i = 0;
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "null channel on write!\n");
ftdm_assert_return(ftdmchan->fio != NULL, FTDM_FAIL, "null I/O on write!\n");
ftdm_channel_lock(ftdmchan);
if (!ftdmchan->buffer_delay &&
((ftdmchan->dtmf_buffer && ftdm_buffer_inuse(ftdmchan->dtmf_buffer)) ||
(ftdmchan->fsk_buffer && ftdm_buffer_inuse(ftdmchan->fsk_buffer)))) {
/* generating some kind of tone at the moment (see handle_tone_generation),
* we ignore user data ... */
goto done;
}
if (!ftdm_test_flag(ftdmchan, FTDM_CHANNEL_OPEN)) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_WARNING, "cannot write in channel not open\n");
status = FTDM_FAIL;
goto done;
}
if (!ftdmchan->fio->write) {
ftdm_log_chan_msg(ftdmchan, FTDM_LOG_ERROR, "write method not implemented\n");
status = FTDM_FAIL;
goto done;
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_DIGITAL_MEDIA)) {
goto do_write;
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_TRANSCODE) && ftdmchan->effective_codec != ftdmchan->native_codec) {
if (ftdmchan->native_codec == FTDM_CODEC_ULAW && ftdmchan->effective_codec == FTDM_CODEC_SLIN) {
codec_func = fio_slin2ulaw;
} else if (ftdmchan->native_codec == FTDM_CODEC_ULAW && ftdmchan->effective_codec == FTDM_CODEC_ALAW) {
codec_func = fio_alaw2ulaw;
} else if (ftdmchan->native_codec == FTDM_CODEC_ALAW && ftdmchan->effective_codec == FTDM_CODEC_SLIN) {
codec_func = fio_slin2alaw;
} else if (ftdmchan->native_codec == FTDM_CODEC_ALAW && ftdmchan->effective_codec == FTDM_CODEC_ULAW) {
codec_func = fio_ulaw2alaw;
}
if (codec_func) {
status = codec_func(data, max, datalen);
} else {
ftdm_log_chan(ftdmchan, FTDM_LOG_ERROR, "Do not know how to handle transcoding from %d to %d\n",
ftdmchan->effective_codec, ftdmchan->native_codec);
status = FTDM_FAIL;
goto done;
}
}
if (ftdm_test_flag(ftdmchan, FTDM_CHANNEL_USE_TX_GAIN)
&& (ftdmchan->native_codec == FTDM_CODEC_ALAW || ftdmchan->native_codec == FTDM_CODEC_ULAW)) {
unsigned char *wdata = data;
for (i = 0; i < *datalen; i++) {
wdata[i] = ftdmchan->txgain_table[wdata[i]];
}
}
do_write:
if (ftdmchan->span->sig_write) {
status = ftdmchan->span->sig_write(ftdmchan, data, *datalen);
if (status == FTDM_BREAK) {
/* signaling module decided to drop user frame */
status = FTDM_SUCCESS;
goto done;
}
}
status = ftdm_raw_write(ftdmchan, data, datalen);
done:
ftdm_channel_unlock(ftdmchan);
return status;
}
FT_DECLARE(ftdm_iterator_t *) ftdm_get_iterator(ftdm_iterator_type_t type, ftdm_iterator_t *iter)
{
int allocated = 0;
if (iter) {
if (iter->type != type) {
ftdm_log(FTDM_LOG_ERROR, "Cannot switch iterator types\n");
return NULL;
}
allocated = iter->allocated;
memset(iter, 0, sizeof(*iter));
iter->type = type;
iter->allocated = allocated;
return iter;
}
iter = ftdm_calloc(1, sizeof(*iter));
if (!iter) {
return NULL;
}
iter->type = type;
iter->allocated = 1;
return iter;
}
FT_DECLARE(ftdm_iterator_t *) ftdm_get_span_iterator(ftdm_iterator_t *iter)
{
if (!(iter = ftdm_get_iterator(FTDM_ITERATOR_SPANS, iter))) {
return NULL;
}
iter->pvt.hashiter = hashtable_first(globals.span_hash);
return iter;
}
FT_DECLARE(ftdm_iterator_t *) ftdm_span_get_chan_iterator(const ftdm_span_t *span, ftdm_iterator_t *iter)
{
if (!span->chan_count) {
return NULL;
}
if (!(iter = ftdm_get_iterator(FTDM_ITERATOR_CHANS, iter))) {
return NULL;
}
iter->pvt.chaniter.index = 1;
iter->pvt.chaniter.span = span;
return iter;
}
FT_DECLARE(ftdm_iterator_t *) ftdm_iterator_next(ftdm_iterator_t *iter)
{
ftdm_assert_return(iter && iter->type, NULL, "Invalid iterator\n");
switch (iter->type) {
case FTDM_ITERATOR_VARS:
case FTDM_ITERATOR_SPANS:
if (!iter->pvt.hashiter) {
return NULL;
}
iter->pvt.hashiter = hashtable_next(iter->pvt.hashiter);
if (!iter->pvt.hashiter) {
return NULL;
}
return iter;
case FTDM_ITERATOR_CHANS:
ftdm_assert_return(iter->pvt.chaniter.index, NULL, "channel iterator index cannot be zero!\n");
if (iter->pvt.chaniter.index == iter->pvt.chaniter.span->chan_count) {
return NULL;
}
iter->pvt.chaniter.index++;
return iter;
default:
break;
}
ftdm_assert_return(0, NULL, "Unknown iterator type\n");
return NULL;
}
FT_DECLARE(void *) ftdm_iterator_current(ftdm_iterator_t *iter)
{
const void *key = NULL;
void *val = NULL;
ftdm_assert_return(iter && iter->type, NULL, "Invalid iterator\n");
switch (iter->type) {
case FTDM_ITERATOR_VARS:
hashtable_this(iter->pvt.hashiter, &key, NULL, &val);
/* I decided to return the key instead of the value since the value can be retrieved using the key */
return (void *)key;
case FTDM_ITERATOR_SPANS:
hashtable_this(iter->pvt.hashiter, &key, NULL, &val);
return (void *)val;
case FTDM_ITERATOR_CHANS:
ftdm_assert_return(iter->pvt.chaniter.index, NULL, "channel iterator index cannot be zero!\n");
ftdm_assert_return(iter->pvt.chaniter.index <= iter->pvt.chaniter.span->chan_count, NULL, "channel iterator index bigger than span chan count!\n");
return iter->pvt.chaniter.span->channels[iter->pvt.chaniter.index];
default:
break;
}
ftdm_assert_return(0, NULL, "Unknown iterator type\n");
return NULL;
}
FT_DECLARE(ftdm_status_t) ftdm_iterator_free(ftdm_iterator_t *iter)
{
/* it's valid to pass a NULL iterator, do not return failure */
if (!iter) {
return FTDM_SUCCESS;
}
if (!iter->allocated) {
memset(iter, 0, sizeof(*iter));
return FTDM_SUCCESS;
}
ftdm_assert_return(iter->type, FTDM_FAIL, "Cannot free invalid iterator\n");
ftdm_safe_free(iter);
return FTDM_SUCCESS;
}
static const char *print_neg_char[] = { "", "!" };
static const char *print_flag_state[] = { "OFF", "ON" };
static void print_channels_by_flag(ftdm_stream_handle_t *stream, ftdm_span_t *inspan, uint32_t inchan_id, uint64_t flagval, int not, int *count)
{
ftdm_bool_t neg = !!not;
const char *negind = print_neg_char[neg];
const char *flagname;
uint64_t flag = ((uint64_t)1 << flagval);
int mycount = 0;
flagname = ftdm_val2str(flag, channel_flag_strs, ftdm_array_len(channel_flag_strs), "invalid");
ftdm_mutex_lock(globals.mutex);
if (inspan) {
ftdm_iterator_t *c_iter, *c_cur;
c_iter = ftdm_span_get_chan_iterator(inspan, NULL);
for (c_cur = c_iter; c_cur; c_cur = ftdm_iterator_next(c_cur)) {
ftdm_channel_t *fchan;
ftdm_bool_t cond;
fchan = ftdm_iterator_current(c_cur);
if (inchan_id && inchan_id != fchan->chan_id) {
continue;
}
cond = !!ftdm_test_flag(fchan, flag);
if (neg ^ cond) {
mycount++;
}
stream->write_function(stream, "[s%dc%d][%d:%d] flag %s%"FTDM_UINT64_FMT"(%s%s) %s\n",
fchan->span_id, fchan->chan_id,
fchan->physical_span_id, fchan->physical_chan_id,
negind, flagval, negind, flagname,
print_flag_state[cond]);
}
ftdm_iterator_free(c_iter);
} else {
ftdm_iterator_t *s_iter, *s_cur;
s_iter = ftdm_get_span_iterator(NULL);
for (s_cur = s_iter; s_cur; s_cur = ftdm_iterator_next(s_cur)) {
ftdm_iterator_t *c_iter, *c_cur;
ftdm_span_t *span;
span = ftdm_iterator_current(s_cur);
if (!span) {
break;
}
c_iter = ftdm_span_get_chan_iterator(span, NULL);
for (c_cur = c_iter; c_cur; c_cur = ftdm_iterator_next(c_cur)) {
ftdm_channel_t *fchan;
fchan = ftdm_iterator_current(c_cur);
if (neg ^ !!ftdm_test_flag(fchan, flag)) {
stream->write_function(stream, "[s%dc%d][%d:%d] flag %s%"FTDM_UINT64_FMT"(%s%s)\n",
fchan->span_id, fchan->chan_id,
fchan->physical_span_id, fchan->physical_chan_id,
negind, flagval, negind, flagname);
mycount++;
}
}
ftdm_iterator_free(c_iter);
}
ftdm_iterator_free(s_iter);
}
*count = mycount;
ftdm_mutex_unlock(globals.mutex);
}
static void print_spans_by_flag(ftdm_stream_handle_t *stream, ftdm_span_t *inspan, uint64_t flagval, int not, int *count)
{
ftdm_bool_t neg = !!not;
const char *negind = print_neg_char[neg];
const char *flagname;
uint64_t flag = ((uint64_t)1 << flagval);
int mycount = 0;
flagname = ftdm_val2str(flag, span_flag_strs, ftdm_array_len(span_flag_strs), "invalid");
ftdm_mutex_lock(globals.mutex);
if (inspan) {
ftdm_bool_t cond;
cond = !!ftdm_test_flag(inspan, flag);
if (neg ^ cond) {
mycount++;
}
stream->write_function(stream, "[s%d] flag %s%"FTDM_UINT64_FMT"(%s%s) %s\n",
inspan->span_id, negind, flagval, negind, flagname,
print_flag_state[cond]);
} else {
ftdm_iterator_t *s_iter, *s_cur;
s_iter = ftdm_get_span_iterator(NULL);
for (s_cur = s_iter; s_cur; s_cur = ftdm_iterator_next(s_cur)) {
ftdm_span_t *span;
span = ftdm_iterator_current(s_cur);
if (!span) {
break;
}
if (neg ^ !!ftdm_test_flag(span, flag)) {
stream->write_function(stream, "[s%d] flag %s%"FTDM_UINT64_FMT"(%s%s)\n",
span->span_id, negind, flagval, negind, flagname);
mycount++;
}
}
ftdm_iterator_free(s_iter);
}
*count = mycount;
ftdm_mutex_unlock(globals.mutex);
}
static void print_channels_by_state(ftdm_stream_handle_t *stream, ftdm_channel_state_t state, int not, int *count)
{
ftdm_iterator_t *s_iter, *s_cur;
ftdm_bool_t neg = !!not;
int mycount = 0;
s_iter = ftdm_get_span_iterator(NULL);
ftdm_mutex_lock(globals.mutex);
for (s_cur = s_iter; s_cur; s_cur = ftdm_iterator_next(s_cur)) {
ftdm_iterator_t *c_iter, *c_cur;
ftdm_span_t *span;
span = ftdm_iterator_current(s_cur);
if (!span) {
break;
}
c_iter = ftdm_span_get_chan_iterator(span, NULL);
for (c_cur = c_iter ; c_cur; c_cur = ftdm_iterator_next(c_cur)) {
ftdm_channel_t *fchan = ftdm_iterator_current(c_cur);
if (neg ^ (fchan->state == state)) {
stream->write_function(stream, "[s%dc%d][%d:%d] in state %s\n",
fchan->span_id, fchan->chan_id,
fchan->physical_span_id, fchan->physical_chan_id, ftdm_channel_state2str(fchan->state));
mycount++;
}
}
ftdm_iterator_free(c_iter);
}
*count = mycount;
ftdm_mutex_unlock(globals.mutex);
ftdm_iterator_free(s_iter);
}
static void print_core_usage(ftdm_stream_handle_t *stream)
{
stream->write_function(stream,
"--------------------------------------------------------------------------------\n"
"ftdm core state [!]<state-name> - List all channels in or not in the given state\n"
"ftdm core flag [!]<flag-int-value|flag-name> [<span_id|span_name>] [<chan_id>] - List all channels with the given flag value set\n"
"ftdm core spanflag [!]<flag-int-value|flag-name> [<span_id|span_name>] - List all spans with the given span flag value set\n"
"ftdm core calls - List all known calls to the FreeTDM core\n"
"--------------------------------------------------------------------------------\n");
}
static unsigned long long ftdm_str2val(const char *str, val_str_t *val_str_table, ftdm_size_t array_size, unsigned long long default_val)
{
ftdm_size_t i;
for (i = 0; i < array_size; i++) {
if (!strcasecmp(val_str_table[i].str, str)) {
return val_str_table[i].val;
}
}
return default_val;
}
static const char *ftdm_val2str(unsigned long long val, val_str_t *val_str_table, ftdm_size_t array_size, const char *default_str)
{
ftdm_size_t i;
for (i = 0; i < array_size; i++) {
if (val_str_table[i].val == val) {
return val_str_table[i].str;
}
}
return default_str;
}
static void print_channel_flag_values(ftdm_stream_handle_t *stream)
{
int i;
for (i = 0; i < ftdm_array_len(channel_flag_strs); i++) {
stream->write_function(stream, "%s\n", channel_flag_strs[i].str);
}
}
static void print_span_flag_values(ftdm_stream_handle_t *stream)
{
int i;
for (i = 0; i < ftdm_array_len(span_flag_strs); i++) {
stream->write_function(stream, "%s\n", span_flag_strs[i].str);
}
}
/**
* Compute log2 of 64bit integer v
*
* Bit Twiddling Hacks
* http://graphics.stanford.edu/~seander/bithacks.html#IntegerLog
*/
static int ftdm_log2_64(uint64_t v)
{
unsigned int shift;
uint64_t r;
r = (v > 0xFFFFFFFF) << 5; v >>= r;
shift = (v > 0xFFFF ) << 4; v >>= shift; r |= shift;
shift = (v > 0xFF ) << 3; v >>= shift; r |= shift;
shift = (v > 0xF ) << 2; v >>= shift; r |= shift;
shift = (v > 0x3 ) << 1; v >>= shift; r |= shift;
return ((int)(r | (v >> 1)));
}
static char *handle_core_command(const char *cmd)
{
char *mycmd = NULL;
int argc = 0;
int count = 0;
int not = 0;
char *argv[10] = { 0 };
char *flag = NULL;
uint64_t flagval = 0;
ftdm_channel_t *fchan = NULL;
ftdm_span_t *fspan = NULL;
ftdm_stream_handle_t stream = { 0 };
FTDM_STANDARD_STREAM(stream);
if (!ftdm_strlen_zero(cmd)) {
mycmd = ftdm_strdup(cmd);
argc = ftdm_separate_string(mycmd, ' ', argv, ftdm_array_len(argv));
} else {
print_core_usage(&stream);
goto done;
}
if (!argc) {
print_core_usage(&stream);
goto done;
}
if (!strcasecmp(argv[0], "state")) {
ftdm_channel_state_t st = FTDM_CHANNEL_STATE_INVALID;
char *state = NULL;
if (argc < 2) {
stream.write_function(&stream, "core state command requires an argument\n");
print_core_usage(&stream);
goto done;
}
state = argv[1];
if (state[0] == '!') {
not = 1;
state++;
}
for (st = FTDM_CHANNEL_STATE_DOWN; st < FTDM_CHANNEL_STATE_INVALID; st++) {
if (!strcasecmp(state, ftdm_channel_state2str(st))) {
break;
}
}
if (st == FTDM_CHANNEL_STATE_INVALID) {
stream.write_function(&stream, "invalid state %s\n", state);
goto done;
}
print_channels_by_state(&stream, st, not, &count);
stream.write_function(&stream, "\nTotal channels %s state %s: %d\n",
not ? "not in" : "in", ftdm_channel_state2str(st), count);
} else if (!strcasecmp(argv[0], "flag")) {
uint32_t chan_id = 0;
if (argc < 2) {
stream.write_function(&stream, "core flag command requires an argument\n");
print_core_usage(&stream);
goto done;
}
flag = argv[1];
if (flag[0] == '!') {
not = 1;
flag++;
}
if (isalpha(flag[0])) {
flagval = ftdm_str2val(flag, channel_flag_strs, ftdm_array_len(channel_flag_strs), FTDM_CHANNEL_MAX_FLAG);
if (flagval == FTDM_CHANNEL_MAX_FLAG) {
stream.write_function(&stream, "\nInvalid channel flag value. Possible channel flags:\n");
print_channel_flag_values(&stream);
goto done;
}
flagval = ftdm_log2_64(flagval);
} else {
flagval = atoi(flag);
}
/* Specific span specified */
if (argv[2]) {
ftdm_span_find_by_name(argv[2], &fspan);
if (!fspan) {
stream.write_function(&stream, "-ERR span:%s not found\n", argv[2]);
goto done;
}
}
/* Specific channel specified */
if (argv[3]) {
chan_id = atoi(argv[3]);
if (chan_id == 0 || chan_id >= ftdm_span_get_chan_count(fspan)) {
stream.write_function(&stream, "-ERR invalid channel %u\n", chan_id);
goto done;
}
}
print_channels_by_flag(&stream, fspan, chan_id, flagval, not, &count);
stream.write_function(&stream, "\nTotal channels %s flag %"FTDM_UINT64_FMT": %d\n", not ? "without" : "with", flagval, count);
} else if (!strcasecmp(argv[0], "spanflag")) {
if (argc < 2) {
stream.write_function(&stream, "core spanflag command requires an argument\n");
print_core_usage(&stream);
goto done;
}
flag = argv[1];
if (flag[0] == '!') {
not = 1;
flag++;
}
if (isalpha(flag[0])) {
flagval = ftdm_str2val(flag, span_flag_strs, ftdm_array_len(span_flag_strs), FTDM_SPAN_MAX_FLAG);
if (flagval == FTDM_SPAN_MAX_FLAG) {
stream.write_function(&stream, "\nInvalid span flag value. Possible span flags\n");
print_span_flag_values(&stream);
goto done;
}
flagval = ftdm_log2_64(flagval);
} else {
flagval = atoi(flag);
}
/* Specific span specified */
if (argv[2]) {
ftdm_span_find_by_name(argv[2], &fspan);
if (!fspan) {
stream.write_function(&stream, "-ERR span:%s not found\n", argv[2]);
goto done;
}
}
print_spans_by_flag(&stream, fspan, flagval, not, &count);
if (!fspan) {
stream.write_function(&stream, "\nTotal spans %s flag %"FTDM_UINT64_FMT": %d\n", not ? "without" : "with", flagval, count);
}
} else if (!strcasecmp(argv[0], "calls")) {
uint32_t current_call_id = 0;
ftdm_mutex_lock(globals.call_id_mutex);
for (current_call_id = 0; current_call_id <= MAX_CALLIDS; current_call_id++) {
ftdm_caller_data_t *calldata = NULL;
if (!globals.call_ids[current_call_id]) {
continue;
}
calldata = globals.call_ids[current_call_id];
fchan = calldata->fchan;
if (fchan) {
stream.write_function(&stream, "Call %u on channel %d:%d\n", current_call_id,
fchan->span_id, fchan->chan_id);
} else {
stream.write_function(&stream, "Call %u without a channel?\n", current_call_id);
}
count++;
}
ftdm_mutex_unlock(globals.call_id_mutex);
stream.write_function(&stream, "\nTotal calls: %d\n", count);
} else {
stream.write_function(&stream, "invalid core command %s\n", argv[0]);
print_core_usage(&stream);
}
done:
ftdm_safe_free(mycmd);
return stream.data;
}
FT_DECLARE(char *) ftdm_api_execute(const char *cmd)
{
ftdm_io_interface_t *fio = NULL;
char *dup = NULL, *p;
char *rval = NULL;
char *type = NULL;
dup = ftdm_strdup(cmd);
if ((p = strchr(dup, ' '))) {
*p++ = '\0';
cmd = p;
} else {
cmd = "";
}
type = dup;
if (!strcasecmp(type, "core")) {
return handle_core_command(cmd);
}
fio = ftdm_global_get_io_interface(type, FTDM_TRUE);
if (fio && fio->api) {
ftdm_stream_handle_t stream = { 0 };
ftdm_status_t status;
FTDM_STANDARD_STREAM(stream);
status = fio->api(&stream, cmd);
if (status != FTDM_SUCCESS) {
ftdm_safe_free(stream.data);
} else {
rval = (char *) stream.data;
}
}
ftdm_safe_free(dup);
return rval;
}
static ftdm_status_t ftdm_set_channels_gains(ftdm_span_t *span, int currindex, float rxgain, float txgain)
{
unsigned chan_index = 0;
if (!span->chan_count) {
ftdm_log(FTDM_LOG_ERROR, "Failed to set channel gains because span %s has no channels\n", span->name);
return FTDM_FAIL;
}
for (chan_index = currindex+1; chan_index <= span->chan_count; chan_index++) {
if (!FTDM_IS_VOICE_CHANNEL(span->channels[chan_index])) {
continue;
}
if (ftdm_channel_command(span->channels[chan_index], FTDM_COMMAND_SET_RX_GAIN, &rxgain) != FTDM_SUCCESS) {
return FTDM_FAIL;
}
if (ftdm_channel_command(span->channels[chan_index], FTDM_COMMAND_SET_TX_GAIN, &txgain) != FTDM_SUCCESS) {
return FTDM_FAIL;
}
}
return FTDM_SUCCESS;
}
static ftdm_status_t ftdm_report_initial_channels_alarms(ftdm_span_t *span)
{
ftdm_channel_t *fchan = NULL;
ftdm_iterator_t *curr = NULL;
ftdm_status_t status = FTDM_SUCCESS;
ftdm_alarm_flag_t alarmbits;
ftdm_event_t fake_event;
ftdm_iterator_t *citer = ftdm_span_get_chan_iterator(span, NULL);
if (!citer) {
status = FTDM_ENOMEM;
goto done;
}
memset(&fake_event, 0, sizeof(fake_event));
fake_event.e_type = FTDM_EVENT_OOB;
for (curr = citer; curr; curr = ftdm_iterator_next(curr)) {
fchan = ftdm_iterator_current(curr);
status = ftdm_channel_get_alarms(fchan, &alarmbits);
if (status != FTDM_SUCCESS) {
ftdm_log_chan_msg(fchan, FTDM_LOG_ERROR, "Failed to initialize alarms\n");
continue;
}
fake_event.channel = fchan;
fake_event.enum_id = fchan->alarm_flags ? FTDM_OOB_ALARM_TRAP : FTDM_OOB_ALARM_CLEAR;
ftdm_event_handle_oob(&fake_event);
}
done:
ftdm_iterator_free(citer);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_configure_span_channels(ftdm_span_t *span, const char* str, ftdm_channel_config_t *chan_config, unsigned *configured)
{
int currindex;
unsigned chan_index = 0;
ftdm_assert_return(span != NULL, FTDM_EINVAL, "span is null\n");
ftdm_assert_return(chan_config != NULL, FTDM_EINVAL, "config is null\n");
ftdm_assert_return(configured != NULL, FTDM_EINVAL, "configured pointer is null\n");
ftdm_assert_return(span->fio != NULL, FTDM_EINVAL, "span with no I/O configured\n");
ftdm_assert_return(span->fio->configure_span != NULL, FTDM_NOTIMPL, "span I/O with no channel configuration implemented\n");
currindex = span->chan_count;
*configured = 0;
*configured = span->fio->configure_span(span, str, chan_config->type, chan_config->name, chan_config->number);
if (!*configured) {
ftdm_log(FTDM_LOG_ERROR, "%d:Failed to configure span\n", span->span_id);
return FTDM_FAIL;
}
if (chan_config->group_name[0]) {
if (ftdm_group_add_channels(span, currindex, chan_config->group_name) != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_ERROR, "%d:Failed to add channels to group %s\n", span->span_id, chan_config->group_name);
return FTDM_FAIL;
}
}
if (ftdm_set_channels_gains(span, currindex, chan_config->rxgain, chan_config->txgain) != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_ERROR, "%d:Failed to set channel gains\n", span->span_id);
return FTDM_FAIL;
}
for (chan_index = currindex + 1; chan_index <= span->chan_count; chan_index++) {
if (chan_config->iostats) {
ftdm_channel_set_feature(span->channels[chan_index], FTDM_CHANNEL_FEATURE_IO_STATS);
}
if (!FTDM_IS_VOICE_CHANNEL(span->channels[chan_index])) {
continue;
}
if (chan_config->debugdtmf) {
span->channels[chan_index]->dtmfdbg.requested = 1;
}
span->channels[chan_index]->dtmfdetect.duration_ms = chan_config->dtmfdetect_ms;
if (chan_config->dtmf_on_start) {
span->channels[chan_index]->dtmfdetect.trigger_on_start = 1;
}
}
return FTDM_SUCCESS;
}
static ftdm_status_t load_config(void)
{
const char cfg_name[] = "freetdm.conf";
ftdm_config_t cfg;
char *var, *val;
int catno = -1;
int intparam = 0;
ftdm_span_t *span = NULL;
unsigned configured = 0, d = 0;
ftdm_analog_start_type_t tmp;
ftdm_size_t len = 0;
ftdm_channel_config_t chan_config;
ftdm_status_t ret = FTDM_SUCCESS;
memset(&chan_config, 0, sizeof(chan_config));
sprintf(chan_config.group_name, "__default");
if (!ftdm_config_open_file(&cfg, cfg_name)) {
ftdm_log(FTDM_LOG_ERROR, "Failed to open configuration file %s\n", cfg_name);
return FTDM_FAIL;
}
ftdm_log(FTDM_LOG_DEBUG, "Reading FreeTDM configuration file\n");
while (ftdm_config_next_pair(&cfg, &var, &val)) {
if (*cfg.category == '#') {
if (cfg.catno != catno) {
ftdm_log(FTDM_LOG_DEBUG, "Skipping %s\n", cfg.category);
catno = cfg.catno;
}
} else if (!strncasecmp(cfg.category, "span", 4)) {
if (cfg.catno != catno) {
char *type = cfg.category + 4;
char *name;
if (*type == ' ') {
type++;
}
ftdm_log(FTDM_LOG_DEBUG, "found config for span\n");
catno = cfg.catno;
if (ftdm_strlen_zero(type)) {
ftdm_log(FTDM_LOG_CRIT, "failure creating span, no type specified.\n");
span = NULL;
continue;
}
if ((name = strchr(type, ' '))) {
*name++ = '\0';
}
/* Verify if trunk_type was specified for previous span */
if (span && span->trunk_type == FTDM_TRUNK_NONE) {
ftdm_log(FTDM_LOG_ERROR, "trunk_type not specified for span %d (%s)\n", span->span_id, span->name);
ret = FTDM_FAIL;
goto done;
}
if (ftdm_span_create(type, name, &span) == FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_DEBUG, "created span %d (%s) of type %s\n", span->span_id, span->name, type);
d = 0;
/* it is confusing that parameters from one span affect others, so let's clear them */
memset(&chan_config, 0, sizeof(chan_config));
sprintf(chan_config.group_name, "__default");
/* default to storing iostats */
chan_config.iostats = FTDM_TRUE;
} else {
ftdm_log(FTDM_LOG_CRIT, "failure creating span of type %s\n", type);
span = NULL;
continue;
}
}
if (!span) {
continue;
}
ftdm_log(FTDM_LOG_DEBUG, "span %d [%s]=[%s]\n", span->span_id, var, val);
if (!strcasecmp(var, "trunk_type")) {
ftdm_trunk_type_t trtype = ftdm_str2ftdm_trunk_type(val);
ftdm_span_set_trunk_type(span, trtype);
ftdm_log(FTDM_LOG_DEBUG, "setting trunk type to '%s'\n", ftdm_trunk_type2str(trtype));
} else if (!strcasecmp(var, "trunk_mode")) {
ftdm_trunk_mode_t trmode = ftdm_str2ftdm_trunk_mode(val);
ftdm_span_set_trunk_mode(span, trmode);
ftdm_log(FTDM_LOG_DEBUG, "setting trunk mode to '%s'\n", ftdm_trunk_mode2str(trmode));
} else if (!strcasecmp(var, "name")) {
if (!strcasecmp(val, "undef")) {
chan_config.name[0] = '\0';
} else {
ftdm_copy_string(chan_config.name, val, FTDM_MAX_NAME_STR_SZ);
}
} else if (!strcasecmp(var, "number")) {
if (!strcasecmp(val, "undef")) {
chan_config.number[0] = '\0';
} else {
ftdm_copy_string(chan_config.number, val, FTDM_MAX_NUMBER_STR_SZ);
}
} else if (!strcasecmp(var, "analog-start-type")) {
if (span->trunk_type == FTDM_TRUNK_FXS || span->trunk_type == FTDM_TRUNK_FXO || span->trunk_type == FTDM_TRUNK_EM) {
if ((tmp = ftdm_str2ftdm_analog_start_type(val)) != FTDM_ANALOG_START_NA) {
span->start_type = tmp;
ftdm_log(FTDM_LOG_DEBUG, "changing start type to '%s'\n", ftdm_analog_start_type2str(span->start_type));
}
} else {
ftdm_log(FTDM_LOG_ERROR, "This option is only valid on analog trunks!\n");
}
} else if (!strcasecmp(var, "fxo-channel")) {
if (span->trunk_type == FTDM_TRUNK_NONE) {
span->trunk_type = FTDM_TRUNK_FXO;
span->trunk_mode = FTDM_TRUNK_MODE_CPE;
ftdm_log(FTDM_LOG_DEBUG, "setting trunk type to '%s' start(%s), mode(%s)\n", ftdm_trunk_type2str(span->trunk_type),
ftdm_analog_start_type2str(span->start_type), ftdm_trunk_mode2str(span->trunk_mode));
}
if (span->trunk_type == FTDM_TRUNK_FXO) {
unsigned chans_configured = 0;
chan_config.type = FTDM_CHAN_TYPE_FXO;
if (ftdm_configure_span_channels(span, val, &chan_config, &chans_configured) == FTDM_SUCCESS) {
configured += chans_configured;
}
} else {
ftdm_log(FTDM_LOG_WARNING, "Cannot add FXO channels to a %s trunk!\n", ftdm_trunk_type2str(span->trunk_type));
}
} else if (!strcasecmp(var, "fxs-channel")) {
if (span->trunk_type == FTDM_TRUNK_NONE) {
span->trunk_type = FTDM_TRUNK_FXS;
span->trunk_mode = FTDM_TRUNK_MODE_NET;
ftdm_log(FTDM_LOG_DEBUG, "setting trunk type to '%s' start(%s), mode(%s)\n", ftdm_trunk_type2str(span->trunk_type),
ftdm_analog_start_type2str(span->start_type), ftdm_trunk_mode2str(span->trunk_mode));
}
if (span->trunk_type == FTDM_TRUNK_FXS) {
unsigned chans_configured = 0;
chan_config.type = FTDM_CHAN_TYPE_FXS;
if (ftdm_configure_span_channels(span, val, &chan_config, &chans_configured) == FTDM_SUCCESS) {
configured += chans_configured;
}
} else {
ftdm_log(FTDM_LOG_WARNING, "Cannot add FXS channels to a %s trunk!\n", ftdm_trunk_type2str(span->trunk_type));
}
} else if (!strcasecmp(var, "em-channel")) {
if (span->trunk_type == FTDM_TRUNK_NONE) {
span->trunk_type = FTDM_TRUNK_EM;
span->trunk_mode = FTDM_TRUNK_MODE_CPE;
ftdm_log(FTDM_LOG_DEBUG, "setting trunk type to '%s' start(%s), mode(%s)\n", ftdm_trunk_type2str(span->trunk_type),
ftdm_analog_start_type2str(span->start_type), ftdm_trunk_mode2str(span->trunk_mode));
}
if (span->trunk_type == FTDM_TRUNK_EM) {
unsigned chans_configured = 0;
chan_config.type = FTDM_CHAN_TYPE_EM;
if (ftdm_configure_span_channels(span, val, &chan_config, &chans_configured) == FTDM_SUCCESS) {
configured += chans_configured;
}
} else {
ftdm_log(FTDM_LOG_WARNING, "Cannot add EM channels to a %s trunk!\n", ftdm_trunk_type2str(span->trunk_type));
}
} else if (!strcasecmp(var, "b-channel")) {
if (span->trunk_type == FTDM_TRUNK_NONE) {
ftdm_log(FTDM_LOG_ERROR, "No trunk type specified in configuration file\n");
break;
}
if (FTDM_SPAN_IS_DIGITAL(span)) {
unsigned chans_configured = 0;
chan_config.type = FTDM_CHAN_TYPE_B;
if (ftdm_configure_span_channels(span, val, &chan_config, &chans_configured) == FTDM_SUCCESS) {
configured += chans_configured;
}
} else {
ftdm_log(FTDM_LOG_WARNING, "Cannot add B channels to a %s trunk!\n", ftdm_trunk_type2str(span->trunk_type));
}
} else if (!strcasecmp(var, "d-channel")) {
if (span->trunk_type == FTDM_TRUNK_NONE) {
ftdm_log(FTDM_LOG_ERROR, "No trunk type specified in configuration file\n");
break;
}
if (FTDM_SPAN_IS_DIGITAL(span)) {
unsigned chans_configured = 0;
if (d) {
ftdm_log(FTDM_LOG_WARNING, "ignoring extra d-channel\n");
continue;
}
if (!strncasecmp(val, "lapd:", 5)) {
chan_config.type = FTDM_CHAN_TYPE_DQ931;
val += 5;
} else {
chan_config.type = FTDM_CHAN_TYPE_DQ921;
}
if (ftdm_configure_span_channels(span, val, &chan_config, &chans_configured) == FTDM_SUCCESS) {
configured += chans_configured;
}
d++;
} else {
ftdm_log(FTDM_LOG_WARNING, "Cannot add D channels to a %s trunk!\n", ftdm_trunk_type2str(span->trunk_type));
}
} else if (!strcasecmp(var, "cas-channel")) {
unsigned chans_configured = 0;
chan_config.type = FTDM_CHAN_TYPE_CAS;
if (ftdm_configure_span_channels(span, val, &chan_config, &chans_configured) == FTDM_SUCCESS) {
configured += chans_configured;
}
} else if (!strcasecmp(var, "dtmf_hangup")) {
span->dtmf_hangup = ftdm_strdup(val);
span->dtmf_hangup_len = strlen(val);
} else if (!strcasecmp(var, "txgain")) {
if (sscanf(val, "%f", &(chan_config.txgain)) != 1) {
ftdm_log(FTDM_LOG_ERROR, "invalid txgain: '%s'\n", val);
}
} else if (!strcasecmp(var, "rxgain")) {
if (sscanf(val, "%f", &(chan_config.rxgain)) != 1) {
ftdm_log(FTDM_LOG_ERROR, "invalid rxgain: '%s'\n", val);
}
} else if (!strcasecmp(var, "debugdtmf")) {
chan_config.debugdtmf = ftdm_true(val);
ftdm_log(FTDM_LOG_DEBUG, "Setting debugdtmf to '%s'\n", chan_config.debugdtmf ? "yes" : "no");
} else if (!strncasecmp(var, "dtmfdetect_ms", sizeof("dtmfdetect_ms")-1)) {
if (chan_config.dtmf_on_start == FTDM_TRUE) {
chan_config.dtmf_on_start = FTDM_FALSE;
ftdm_log(FTDM_LOG_WARNING, "dtmf_on_start parameter disabled because dtmfdetect_ms specified\n");
}
if (sscanf(val, "%d", &(chan_config.dtmfdetect_ms)) != 1) {
ftdm_log(FTDM_LOG_ERROR, "invalid dtmfdetect_ms: '%s'\n", val);
}
} else if (!strncasecmp(var, "dtmf_on_start", sizeof("dtmf_on_start")-1)) {
if (chan_config.dtmfdetect_ms) {
ftdm_log(FTDM_LOG_WARNING, "dtmf_on_start parameter ignored because dtmf_detect_ms specified\n");
} else {
if (ftdm_true(val)) {
chan_config.dtmf_on_start = FTDM_TRUE;
} else {
chan_config.dtmf_on_start = FTDM_FALSE;
}
}
} else if (!strncasecmp(var, "iostats", sizeof("iostats")-1)) {
if (ftdm_true(val)) {
chan_config.iostats = FTDM_TRUE;
} else {
chan_config.iostats = FTDM_FALSE;
}
ftdm_log(FTDM_LOG_DEBUG, "Setting iostats to '%s'\n", chan_config.iostats ? "yes" : "no");
} else if (!strcasecmp(var, "group")) {
len = strlen(val);
if (len >= FTDM_MAX_NAME_STR_SZ) {
len = FTDM_MAX_NAME_STR_SZ - 1;
ftdm_log(FTDM_LOG_WARNING, "Truncating group name %s to %"FTDM_SIZE_FMT" length\n", val, len);
}
memcpy(chan_config.group_name, val, len);
chan_config.group_name[len] = '\0';
} else {
ftdm_log(FTDM_LOG_ERROR, "unknown span variable '%s'\n", var);
}
} else if (!strncasecmp(cfg.category, "general", 7)) {
if (!strncasecmp(var, "cpu_monitor", sizeof("cpu_monitor")-1)) {
if (!strncasecmp(val, "yes", 3)) {
globals.cpu_monitor.enabled = 1;
if (!globals.cpu_monitor.alarm_action_flags) {
globals.cpu_monitor.alarm_action_flags |= FTDM_CPU_ALARM_ACTION_WARN;
}
}
} else if (!strncasecmp(var, "debugdtmf_directory", sizeof("debugdtmf_directory")-1)) {
ftdm_set_string(globals.dtmfdebug_directory, val);
ftdm_log(FTDM_LOG_DEBUG, "Debug DTMF directory set to '%s'\n", globals.dtmfdebug_directory);
} else if (!strncasecmp(var, "cpu_monitoring_interval", sizeof("cpu_monitoring_interval")-1)) {
if (atoi(val) > 0) {
globals.cpu_monitor.interval = atoi(val);
} else {
ftdm_log(FTDM_LOG_ERROR, "Invalid cpu monitoring interval %s\n", val);
}
} else if (!strncasecmp(var, "cpu_set_alarm_threshold", sizeof("cpu_set_alarm_threshold")-1)) {
intparam = atoi(val);
if (intparam > 0 && intparam < 100) {
globals.cpu_monitor.set_alarm_threshold = (uint8_t)intparam;
} else {
ftdm_log(FTDM_LOG_ERROR, "Invalid cpu alarm set threshold %s\n", val);
}
} else if (!strncasecmp(var, "cpu_reset_alarm_threshold", sizeof("cpu_reset_alarm_threshold")-1) ||
!strncasecmp(var, "cpu_clear_alarm_threshold", sizeof("cpu_clear_alarm_threshold")-1)) {
intparam = atoi(val);
if (intparam > 0 && intparam < 100) {
globals.cpu_monitor.clear_alarm_threshold = (uint8_t)intparam;
if (globals.cpu_monitor.clear_alarm_threshold > globals.cpu_monitor.set_alarm_threshold) {
globals.cpu_monitor.clear_alarm_threshold = globals.cpu_monitor.set_alarm_threshold - 10;
ftdm_log(FTDM_LOG_ERROR, "Cpu alarm clear threshold must be lower than set threshold, "
"setting clear threshold to %d\n", globals.cpu_monitor.clear_alarm_threshold);
}
} else {
ftdm_log(FTDM_LOG_ERROR, "Invalid cpu alarm reset threshold %s\n", val);
}
} else if (!strncasecmp(var, "cpu_alarm_action", sizeof("cpu_alarm_action")-1)) {
char* p = val;
do {
if (!strncasecmp(p, "reject", sizeof("reject")-1)) {
globals.cpu_monitor.alarm_action_flags |= FTDM_CPU_ALARM_ACTION_REJECT;
} else if (!strncasecmp(p, "warn", sizeof("warn")-1)) {
globals.cpu_monitor.alarm_action_flags |= FTDM_CPU_ALARM_ACTION_WARN;
}
p = strchr(p, ',');
if (p) {
while(*p++) if (*p != 0x20) break;
}
} while (p);
}
} else {
ftdm_log(FTDM_LOG_ERROR, "unknown param [%s] '%s' / '%s'\n", cfg.category, var, val);
}
}
/* Verify is trunk_type was specified for the last span */
if (span && span->trunk_type == FTDM_TRUNK_NONE) {
ftdm_log(FTDM_LOG_ERROR, "trunk_type not specified for span %d (%s)\n", span->span_id, span->name);
ret = FTDM_FAIL;
}
done:
ftdm_config_close_file(&cfg);
ftdm_log(FTDM_LOG_INFO, "Configured %u channel(s)\n", configured);
if (!configured) {
ret = FTDM_FAIL;
}
return ret;
}
static ftdm_status_t process_module_config(ftdm_io_interface_t *fio)
{
ftdm_config_t cfg;
char *var, *val;
char filename[256] = "";
ftdm_assert_return(fio != NULL, FTDM_FAIL, "fio argument is null\n");
snprintf(filename, sizeof(filename), "%s.conf", fio->name);
if (!fio->configure) {
ftdm_log(FTDM_LOG_DEBUG, "Module %s does not support configuration.\n", fio->name);
return FTDM_FAIL;
}
if (!ftdm_config_open_file(&cfg, filename)) {
ftdm_log(FTDM_LOG_ERROR, "Cannot open %s\n", filename);
return FTDM_FAIL;
}
while (ftdm_config_next_pair(&cfg, &var, &val)) {
fio->configure(cfg.category, var, val, cfg.lineno);
}
ftdm_config_close_file(&cfg);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_global_add_io_interface(ftdm_io_interface_t *interface1)
{
ftdm_status_t ret = FTDM_SUCCESS;
ftdm_mutex_lock(globals.mutex);
if (hashtable_search(globals.interface_hash, (void *)interface1->name)) {
ftdm_log(FTDM_LOG_ERROR, "Interface %s already loaded!\n", interface1->name);
} else {
hashtable_insert(globals.interface_hash, (void *)interface1->name, interface1, HASHTABLE_FLAG_NONE);
}
ftdm_mutex_unlock(globals.mutex);
return ret;
}
FT_DECLARE(ftdm_io_interface_t *) ftdm_global_get_io_interface(const char *iotype, ftdm_bool_t autoload)
{
ftdm_io_interface_t *fio = NULL;
ftdm_mutex_lock(globals.mutex);
fio = (ftdm_io_interface_t *) hashtable_search(globals.interface_hash, (void *)iotype);
if (!fio && autoload) {
ftdm_load_module_assume(iotype);
fio = (ftdm_io_interface_t *) hashtable_search(globals.interface_hash, (void *)iotype);
if (fio) {
ftdm_log(FTDM_LOG_INFO, "Auto-loaded I/O module '%s'\n", iotype);
}
}
ftdm_mutex_unlock(globals.mutex);
return fio;
}
FT_DECLARE(int) ftdm_load_module(const char *name)
{
ftdm_dso_lib_t lib;
int count = 0, x = 0;
char path[512] = "";
char *err;
ftdm_module_t *mod;
ftdm_build_dso_path(name, path, sizeof(path));
if (!(lib = ftdm_dso_open(path, &err))) {
ftdm_log(FTDM_LOG_ERROR, "Error loading %s [%s]\n", path, err);
ftdm_safe_free(err);
return 0;
}
if (!(mod = (ftdm_module_t *) ftdm_dso_func_sym(lib, "ftdm_module", &err))) {
ftdm_log(FTDM_LOG_ERROR, "Error loading %s [%s]\n", path, err);
ftdm_safe_free(err);
return 0;
}
if (mod->io_load) {
ftdm_io_interface_t *interface1 = NULL; /* name conflict w/windows here */
if (mod->io_load(&interface1) != FTDM_SUCCESS || !interface1 || !interface1->name) {
ftdm_log(FTDM_LOG_ERROR, "Error loading %s\n", path);
} else {
ftdm_log(FTDM_LOG_INFO, "Loading IO from %s [%s]\n", path, interface1->name);
if (ftdm_global_add_io_interface(interface1) == FTDM_SUCCESS) {
process_module_config(interface1);
x++;
}
}
}
if (mod->sig_load) {
if (mod->sig_load() != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_ERROR, "Error loading %s\n", path);
} else {
ftdm_log(FTDM_LOG_INFO, "Loading SIG from %s\n", path);
x++;
}
}
if (x) {
char *p;
mod->lib = lib;
ftdm_set_string(mod->path, path);
if (mod->name[0] == '\0') {
if (!(p = strrchr(path, *FTDM_PATH_SEPARATOR))) {
p = path;
}
ftdm_set_string(mod->name, p);
}
ftdm_mutex_lock(globals.mutex);
if (hashtable_search(globals.module_hash, (void *)mod->name)) {
ftdm_log(FTDM_LOG_ERROR, "Module %s already loaded!\n", mod->name);
ftdm_dso_destroy(&lib);
} else {
hashtable_insert(globals.module_hash, (void *)mod->name, mod, HASHTABLE_FLAG_NONE);
count++;
}
ftdm_mutex_unlock(globals.mutex);
} else {
ftdm_log(FTDM_LOG_ERROR, "Unloading %s\n", path);
ftdm_dso_destroy(&lib);
}
return count;
}
FT_DECLARE(int) ftdm_load_module_assume(const char *name)
{
char buf[256] = "";
snprintf(buf, sizeof(buf), "ftmod_%s", name);
return ftdm_load_module(buf);
}
FT_DECLARE(int) ftdm_load_modules(void)
{
char cfg_name[] = "modules.conf";
ftdm_config_t cfg;
char *var, *val;
int count = 0;
if (!ftdm_config_open_file(&cfg, cfg_name)) {
return FTDM_FAIL;
}
while (ftdm_config_next_pair(&cfg, &var, &val)) {
if (!strcasecmp(cfg.category, "modules")) {
if (!strcasecmp(var, "load")) {
count += ftdm_load_module(val);
}
}
}
return count;
}
FT_DECLARE(ftdm_status_t) ftdm_unload_modules(void)
{
ftdm_hash_iterator_t *i = NULL;
ftdm_dso_lib_t lib = NULL;
char modpath[255] = { 0 };
/* stop signaling interfaces first as signaling depends on I/O and not the other way around */
for (i = hashtable_first(globals.module_hash); i; i = hashtable_next(i)) {
const void *key = NULL;
void *val = NULL;
ftdm_module_t *mod = NULL;
hashtable_this(i, &key, NULL, &val);
if (!key || !val) {
continue;
}
mod = (ftdm_module_t *) val;
if (!mod->sig_unload) {
continue;
}
ftdm_log(FTDM_LOG_INFO, "Unloading signaling interface %s\n", mod->name);
if (mod->sig_unload() != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_ERROR, "Error unloading signaling interface %s\n", mod->name);
continue;
}
ftdm_log(FTDM_LOG_INFO, "Unloaded signaling interface %s\n", mod->name);
}
/* Now go ahead with I/O interfaces */
for (i = hashtable_first(globals.module_hash); i; i = hashtable_next(i)) {
const void *key = NULL;
void *val = NULL;
ftdm_module_t *mod = NULL;
hashtable_this(i, &key, NULL, &val);
if (!key || !val) {
continue;
}
mod = (ftdm_module_t *) val;
if (!mod->io_unload) {
continue;
}
ftdm_log(FTDM_LOG_INFO, "Unloading I/O interface %s\n", mod->name);
if (mod->io_unload() != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_ERROR, "Error unloading I/O interface %s\n", mod->name);
continue;
}
ftdm_log(FTDM_LOG_INFO, "Unloaded I/O interface %s\n", mod->name);
}
/* Now unload the actual shared object/dll */
for (i = hashtable_first(globals.module_hash); i; i = hashtable_next(i)) {
ftdm_module_t *mod = NULL;
const void *key = NULL;
void *val = NULL;
hashtable_this(i, &key, NULL, &val);
if (!key || !val) {
continue;
}
mod = (ftdm_module_t *) val;
lib = mod->lib;
snprintf(modpath, sizeof(modpath), "%s", mod->path);
ftdm_log(FTDM_LOG_INFO, "Unloading module %s\n", modpath);
ftdm_dso_destroy(&lib);
ftdm_log(FTDM_LOG_INFO, "Unloaded module %s\n", modpath);
}
return FTDM_SUCCESS;
}
static ftdm_status_t post_configure_span_channels(ftdm_span_t *span)
{
unsigned i = 0;
ftdm_status_t status = FTDM_SUCCESS;
ftdm_signaling_status_t sigstatus = FTDM_SIG_STATE_DOWN;
for (i = 1; i <= span->chan_count; i++) {
sigstatus = FTDM_SIG_STATE_DOWN;
ftdm_channel_get_sig_status(span->channels[i], &sigstatus);
if (sigstatus == FTDM_SIG_STATE_UP) {
ftdm_set_flag(span->channels[i], FTDM_CHANNEL_SIG_UP);
}
}
if (ftdm_test_flag(span, FTDM_SPAN_USE_CHAN_QUEUE)) {
status = ftdm_queue_create(&span->pendingchans, SPAN_PENDING_CHANS_QUEUE_SIZE);
}
if (status == FTDM_SUCCESS && ftdm_test_flag(span, FTDM_SPAN_USE_SIGNALS_QUEUE)) {
status = ftdm_queue_create(&span->pendingsignals, SPAN_PENDING_SIGNALS_QUEUE_SIZE);
}
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_configure_span(ftdm_span_t *span, const char *type, fio_signal_cb_t sig_cb, ...)
{
ftdm_module_t *mod = (ftdm_module_t *) hashtable_search(globals.module_hash, (void *)type);
ftdm_status_t status = FTDM_FAIL;
if (!span->chan_count) {
ftdm_log(FTDM_LOG_WARNING, "Cannot configure signaling on span with no channels\n");
return FTDM_FAIL;
}
if (!mod) {
ftdm_load_module_assume(type);
if ((mod = (ftdm_module_t *) hashtable_search(globals.module_hash, (void *)type))) {
ftdm_log(FTDM_LOG_INFO, "auto-loaded '%s'\n", type);
} else {
ftdm_log(FTDM_LOG_ERROR, "can't load '%s'\n", type);
return FTDM_FAIL;
}
}
if (mod->sig_configure) {
va_list ap;
va_start(ap, sig_cb);
status = mod->sig_configure(span, sig_cb, ap);
va_end(ap);
if (status == FTDM_SUCCESS) {
status = post_configure_span_channels(span);
}
} else {
ftdm_log(FTDM_LOG_CRIT, "module '%s' did not implement the sig_configure method\n", type);
status = FTDM_FAIL;
}
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_configure_span_signaling(ftdm_span_t *span, const char *type, fio_signal_cb_t sig_cb, ftdm_conf_parameter_t *parameters)
{
ftdm_module_t *mod = (ftdm_module_t *) hashtable_search(globals.module_hash, (void *)type);
ftdm_status_t status = FTDM_FAIL;
ftdm_assert_return(type != NULL, FTDM_FAIL, "No signaling type");
ftdm_assert_return(span != NULL, FTDM_FAIL, "No span");
ftdm_assert_return(sig_cb != NULL, FTDM_FAIL, "No signaling callback");
ftdm_assert_return(parameters != NULL, FTDM_FAIL, "No parameters");
if (!span->chan_count) {
ftdm_log(FTDM_LOG_WARNING, "Cannot configure signaling on span %s with no channels\n", span->name);
return FTDM_FAIL;
}
if (!mod) {
ftdm_load_module_assume(type);
if ((mod = (ftdm_module_t *) hashtable_search(globals.module_hash, (void *)type))) {
ftdm_log(FTDM_LOG_INFO, "auto-loaded '%s'\n", type);
}
}
if (!mod) {
ftdm_log(FTDM_LOG_ERROR, "Failed to load module type: %s\n", type);
return FTDM_FAIL;
}
if (mod->configure_span_signaling) {
status = mod->configure_span_signaling(span, sig_cb, parameters);
if (status == FTDM_SUCCESS) {
status = post_configure_span_channels(span);
}
} else {
ftdm_log(FTDM_LOG_ERROR, "Module %s did not implement the signaling configuration method\n", type);
}
return status;
}
static void *ftdm_span_service_events(ftdm_thread_t *me, void *obj)
{
uint32_t i;
unsigned waitms;
ftdm_event_t *event;
ftdm_status_t status = FTDM_SUCCESS;
ftdm_span_t *span = (ftdm_span_t*) obj;
short *poll_events = ftdm_malloc(sizeof(short) * span->chan_count);
if (me == 0) {};
memset(poll_events, 0, sizeof(short) * span->chan_count);
for(i = 1; i <= span->chan_count; i++) {
poll_events[i] |= FTDM_EVENTS;
}
while (ftdm_running() && !(ftdm_test_flag(span, FTDM_SPAN_STOP_THREAD))) {
waitms = 1000;
status = ftdm_span_poll_event(span, waitms, poll_events);
switch (status) {
case FTDM_FAIL:
ftdm_log(FTDM_LOG_CRIT, "%s:Failed to poll span for events\n", span->name);
break;
case FTDM_TIMEOUT:
break;
case FTDM_SUCCESS:
/* Check if there are any channels that have events available */
while (ftdm_span_next_event(span, &event) == FTDM_SUCCESS);
break;
default:
ftdm_log(FTDM_LOG_CRIT, "%s:Unhandled IO event\n", span->name);
}
}
return NULL;
}
FT_DECLARE(ftdm_status_t) ftdm_span_register_signal_cb(ftdm_span_t *span, fio_signal_cb_t sig_cb)
{
span->signal_cb = sig_cb;
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_span_start(ftdm_span_t *span)
{
ftdm_status_t status = FTDM_FAIL;
ftdm_mutex_lock(span->mutex);
if (ftdm_test_flag(span, FTDM_SPAN_STARTED)) {
status = FTDM_EINVAL;
goto done;
}
if (span->signal_type == FTDM_SIGTYPE_NONE) {
/* If there is no signalling component, start a thread to poll events */
status = ftdm_thread_create_detached(ftdm_span_service_events, span);
if (status != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_CRIT,"Failed to start span event monitor thread!\n");
goto done;
}
//ftdm_report_initial_channels_alarms(span);
ftdm_set_flag_locked(span, FTDM_SPAN_STARTED);
goto done;
}
if (!span->start) {
status = FTDM_ENOSYS;
goto done;
}
/* Start I/O */
if (span->fio && span->fio->span_start) {
status = span->fio->span_start(span);
if (status != FTDM_SUCCESS)
goto done;
}
/* Start SIG */
status = ftdm_report_initial_channels_alarms(span);
if (status != FTDM_SUCCESS) {
goto done;
}
status = span->start(span);
if (status == FTDM_SUCCESS) {
ftdm_set_flag_locked(span, FTDM_SPAN_STARTED);
}
done:
ftdm_mutex_unlock(span->mutex);
return status;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_add_to_group(const char* name, ftdm_channel_t* ftdmchan)
{
unsigned int i;
ftdm_group_t* group = NULL;
ftdm_mutex_lock(globals.group_mutex);
ftdm_assert_return(ftdmchan != NULL, FTDM_FAIL, "Cannot add a null channel to a group\n");
if (ftdm_group_find_by_name(name, &group) != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_DEBUG, "Creating new group:%s\n", name);
ftdm_group_create(&group, name);
}
/*verify that group does not already include this channel first */
for(i = 0; i < group->chan_count; i++) {
if (group->channels[i]->physical_span_id == ftdmchan->physical_span_id &&
group->channels[i]->physical_chan_id == ftdmchan->physical_chan_id) {
ftdm_mutex_unlock(globals.group_mutex);
ftdm_log(FTDM_LOG_DEBUG, "Channel %d:%d is already added to group %s\n",
group->channels[i]->physical_span_id,
group->channels[i]->physical_chan_id,
name);
return FTDM_SUCCESS;
}
}
if (group->chan_count >= FTDM_MAX_CHANNELS_GROUP) {
ftdm_log(FTDM_LOG_ERROR, "Max number of channels exceeded (max:%d)\n", FTDM_MAX_CHANNELS_GROUP);
ftdm_mutex_unlock(globals.group_mutex);
return FTDM_FAIL;
}
group->channels[group->chan_count++] = ftdmchan;
ftdm_mutex_unlock(globals.group_mutex);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_remove_from_group(ftdm_group_t* group, ftdm_channel_t* ftdmchan)
{
unsigned int i, j;
//Need to test this function
ftdm_mutex_lock(globals.group_mutex);
for (i=0; i < group->chan_count; i++) {
if (group->channels[i]->physical_span_id == ftdmchan->physical_span_id &&
group->channels[i]->physical_chan_id == ftdmchan->physical_chan_id) {
j=i;
while(j < group->chan_count-1) {
group->channels[j] = group->channels[j+1];
j++;
}
group->channels[group->chan_count--] = NULL;
if (group->chan_count <=0) {
/* Delete group if it is empty */
hashtable_remove(globals.group_hash, (void *)group->name);
}
ftdm_mutex_unlock(globals.group_mutex);
return FTDM_SUCCESS;
}
}
ftdm_mutex_unlock(globals.group_mutex);
//Group does not contain this channel
return FTDM_FAIL;
}
static ftdm_status_t ftdm_group_add_channels(ftdm_span_t* span, int currindex, const char* name)
{
unsigned chan_index = 0;
ftdm_assert_return(strlen(name) > 0, FTDM_FAIL, "Invalid group name provided\n");
ftdm_assert_return(currindex >= 0, FTDM_FAIL, "Invalid current channel index provided\n");
if (!span->chan_count) {
return FTDM_SUCCESS;
}
for (chan_index = currindex+1; chan_index <= span->chan_count; chan_index++) {
if (!FTDM_IS_VOICE_CHANNEL(span->channels[chan_index])) {
continue;
}
if (ftdm_channel_add_to_group(name, span->channels[chan_index])) {
ftdm_log(FTDM_LOG_ERROR, "Failed to add chan:%d to group:%s\n", chan_index, name);
}
}
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_group_find(uint32_t id, ftdm_group_t **group)
{
ftdm_group_t *fgroup = NULL, *grp;
if (id > FTDM_MAX_GROUPS_INTERFACE) {
return FTDM_FAIL;
}
ftdm_mutex_lock(globals.group_mutex);
for (grp = globals.groups; grp; grp = grp->next) {
if (grp->group_id == id) {
fgroup = grp;
break;
}
}
ftdm_mutex_unlock(globals.group_mutex);
if (!fgroup) {
return FTDM_FAIL;
}
*group = fgroup;
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_group_find_by_name(const char *name, ftdm_group_t **group)
{
ftdm_status_t status = FTDM_FAIL;
*group = NULL;
ftdm_mutex_lock(globals.group_mutex);
if (!ftdm_strlen_zero(name)) {
if ((*group = hashtable_search(globals.group_hash, (void *) name))) {
status = FTDM_SUCCESS;
}
}
ftdm_mutex_unlock(globals.group_mutex);
return status;
}
static void ftdm_group_add(ftdm_group_t *group)
{
ftdm_group_t *grp;
ftdm_mutex_lock(globals.group_mutex);
for (grp = globals.groups; grp && grp->next; grp = grp->next);
if (grp) {
grp->next = group;
} else {
globals.groups = group;
}
hashtable_insert(globals.group_hash, (void *)group->name, group, HASHTABLE_FLAG_NONE);
ftdm_mutex_unlock(globals.group_mutex);
}
FT_DECLARE(ftdm_status_t) ftdm_group_create(ftdm_group_t **group, const char *name)
{
ftdm_group_t *new_group = NULL;
ftdm_status_t status = FTDM_FAIL;
ftdm_mutex_lock(globals.mutex);
if (globals.group_index < FTDM_MAX_GROUPS_INTERFACE) {
new_group = ftdm_calloc(1, sizeof(*new_group));
ftdm_assert(new_group != NULL, "Failed to create new ftdm group, expect a crash\n");
status = ftdm_mutex_create(&new_group->mutex);
ftdm_assert(status == FTDM_SUCCESS, "Failed to create group mutex, expect a crash\n");
new_group->group_id = ++globals.group_index;
new_group->name = ftdm_strdup(name);
ftdm_group_add(new_group);
*group = new_group;
status = FTDM_SUCCESS;
} else {
ftdm_log(FTDM_LOG_ERROR, "Group %s was not added, we exceeded the max number of groups\n", name);
}
ftdm_mutex_unlock(globals.mutex);
return status;
}
static ftdm_status_t ftdm_span_trigger_signal(const ftdm_span_t *span, ftdm_sigmsg_t *sigmsg)
{
if (!span->signal_cb) {
return FTDM_FAIL;
}
return span->signal_cb(sigmsg);
}
static ftdm_status_t ftdm_span_queue_signal(const ftdm_span_t *span, ftdm_sigmsg_t *sigmsg)
{
ftdm_sigmsg_t *new_sigmsg = NULL;
new_sigmsg = ftdm_calloc(1, sizeof(*sigmsg));
if (!new_sigmsg) {
return FTDM_FAIL;
}
memcpy(new_sigmsg, sigmsg, sizeof(*sigmsg));
ftdm_queue_enqueue(span->pendingsignals, new_sigmsg);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_span_trigger_signals(const ftdm_span_t *span)
{
ftdm_sigmsg_t *sigmsg = NULL;
while ((sigmsg = ftdm_queue_dequeue(span->pendingsignals))) {
ftdm_span_trigger_signal(span, sigmsg);
ftdm_sigmsg_free(&sigmsg);
}
return FTDM_SUCCESS;
}
static void execute_safety_hangup(void *data)
{
ftdm_channel_t *fchan = data;
ftdm_channel_lock(fchan);
fchan->hangup_timer = 0;
if (fchan->state == FTDM_CHANNEL_STATE_TERMINATING) {
ftdm_log_chan(fchan, FTDM_LOG_WARNING, "Forcing hangup since the user did not confirmed our hangup after %dms\n", FORCE_HANGUP_TIMER);
_ftdm_channel_call_hangup_nl(__FILE__, __FUNCTION__, __LINE__, fchan, NULL);
} else {
ftdm_log_chan(fchan, FTDM_LOG_CRIT, "Not performing safety hangup, channel state is %s\n", ftdm_channel_state2str(fchan->state));
}
ftdm_channel_unlock(fchan);
}
FT_DECLARE(ftdm_status_t) ftdm_span_send_signal(ftdm_span_t *span, ftdm_sigmsg_t *sigmsg)
{
ftdm_channel_t *fchan = NULL;
ftdm_status_t status = FTDM_SUCCESS;
if (sigmsg->channel) {
fchan = sigmsg->channel;
ftdm_channel_lock(fchan);
}
/* some core things to do on special events */
switch (sigmsg->event_id) {
case FTDM_SIGEVENT_SIGSTATUS_CHANGED:
{
if (sigmsg->ev_data.sigstatus.status == FTDM_SIG_STATE_UP) {
ftdm_set_flag(fchan, FTDM_CHANNEL_SIG_UP);
ftdm_clear_flag(fchan, FTDM_CHANNEL_SUSPENDED);
} else {
ftdm_clear_flag(fchan, FTDM_CHANNEL_SIG_UP);
if (sigmsg->ev_data.sigstatus.status == FTDM_SIG_STATE_SUSPENDED) {
ftdm_set_flag(fchan, FTDM_CHANNEL_SUSPENDED);
} else {
ftdm_clear_flag(fchan, FTDM_CHANNEL_SUSPENDED);
}
}
}
break;
case FTDM_SIGEVENT_START:
{
ftdm_assert(!ftdm_test_flag(fchan, FTDM_CHANNEL_CALL_STARTED), "Started call twice!\n");
if (ftdm_test_flag(fchan, FTDM_CHANNEL_OUTBOUND)) {
ftdm_log_chan_msg(fchan, FTDM_LOG_WARNING, "Inbound call taking over outbound channel\n");
ftdm_clear_flag(fchan, FTDM_CHANNEL_OUTBOUND);
}
ftdm_set_flag(fchan, FTDM_CHANNEL_CALL_STARTED);
ftdm_call_set_call_id(fchan, &fchan->caller_data);
/* when cleaning up the public API I added this because mod_freetdm.c on_fxs_signal was
* doing it during SIGEVENT_START, but now that flags are private they can't, wonder if
* is needed at all? */
ftdm_clear_flag(sigmsg->channel, FTDM_CHANNEL_HOLD);
if (sigmsg->channel->caller_data.bearer_capability == FTDM_BEARER_CAP_UNRESTRICTED) {
ftdm_set_flag(sigmsg->channel, FTDM_CHANNEL_DIGITAL_MEDIA);
}
}
break;
case FTDM_SIGEVENT_PROGRESS_MEDIA:
{
/* test signaling module compliance */
if (fchan->state != FTDM_CHANNEL_STATE_PROGRESS_MEDIA) {
ftdm_log_chan(fchan, FTDM_LOG_WARNING, "FTDM_SIGEVENT_PROGRESS_MEDIA sent in state %s\n", ftdm_channel_state2str(fchan->state));
}
}
break;
case FTDM_SIGEVENT_UP:
{
/* test signaling module compliance */
if (fchan->state != FTDM_CHANNEL_STATE_UP) {
ftdm_log_chan(fchan, FTDM_LOG_WARNING, "FTDM_SIGEVENT_UP sent in state %s\n", ftdm_channel_state2str(fchan->state));
}
}
break;
case FTDM_SIGEVENT_STOP:
{
/* TODO: we could test for compliance here and check the state is FTDM_CHANNEL_STATE_TERMINATING
* but several modules need to be updated first */
/* if the call was never started, do not send SIGEVENT_STOP
this happens for FXS devices in ftmod_analog which blindly send SIGEVENT_STOP, we should fix it there ... */
if (!ftdm_test_flag(fchan, FTDM_CHANNEL_CALL_STARTED)) {
ftdm_log_chan_msg(fchan, FTDM_LOG_DEBUG, "Ignoring SIGEVENT_STOP since user never knew about a call in this channel\n");
goto done;
}
if (ftdm_test_flag(fchan, FTDM_CHANNEL_USER_HANGUP)) {
ftdm_log_chan_msg(fchan, FTDM_LOG_DEBUG, "Ignoring SIGEVENT_STOP since user already requested hangup\n");
goto done;
}
if (fchan->state == FTDM_CHANNEL_STATE_TERMINATING) {
ftdm_log_chan_msg(fchan, FTDM_LOG_DEBUG, "Scheduling safety hangup timer\n");
/* if the user does not move us to hangup in 2 seconds, we will do it ourselves */
ftdm_sched_timer(globals.timingsched, "safety-hangup", FORCE_HANGUP_TIMER, execute_safety_hangup, fchan, &fchan->hangup_timer);
}
}
break;
default:
break;
}
if (fchan) {
/* set members of the sigmsg that must be present for all events */
sigmsg->chan_id = fchan->chan_id;
sigmsg->span_id = fchan->span_id;
sigmsg->call_id = fchan->caller_data.call_id;
sigmsg->call_priv = fchan->caller_data.priv;
}
/* if the signaling module uses a queue for signaling notifications, then enqueue it */
if (ftdm_test_flag(span, FTDM_SPAN_USE_SIGNALS_QUEUE)) {
ftdm_span_queue_signal(span, sigmsg);
} else {
status = ftdm_span_trigger_signal(span, sigmsg);
}
done:
if (fchan) {
ftdm_channel_unlock(fchan);
}
return status;
}
static void *ftdm_cpu_monitor_run(ftdm_thread_t *me, void *obj)
{
cpu_monitor_t *monitor = (cpu_monitor_t *)obj;
struct ftdm_cpu_monitor_stats *cpu_stats = ftdm_new_cpu_monitor();
ftdm_log(FTDM_LOG_DEBUG, "CPU monitor thread is now running\n");
if (!cpu_stats) {
goto done;
}
monitor->running = 1;
while (ftdm_running()) {
double idle_time = 0.0;
int cpu_usage = 0;
if (ftdm_cpu_get_system_idle_time(cpu_stats, &idle_time)) {
break;
}
cpu_usage = (int)(100 - idle_time);
if (monitor->alarm) {
if (cpu_usage <= monitor->clear_alarm_threshold) {
ftdm_log(FTDM_LOG_DEBUG, "CPU alarm is now OFF (cpu usage: %d)\n", cpu_usage);
monitor->alarm = 0;
} else if (monitor->alarm_action_flags & FTDM_CPU_ALARM_ACTION_WARN) {
ftdm_log(FTDM_LOG_WARNING, "CPU alarm is still ON (cpu usage: %d)\n", cpu_usage);
}
} else {
if (cpu_usage >= monitor->set_alarm_threshold) {
ftdm_log(FTDM_LOG_WARNING, "CPU alarm is now ON (cpu usage: %d)\n", cpu_usage);
monitor->alarm = 1;
}
}
ftdm_interrupt_wait(monitor->interrupt, monitor->interval);
}
ftdm_delete_cpu_monitor(cpu_stats);
monitor->running = 0;
done:
ftdm_unused_arg(me);
ftdm_log(FTDM_LOG_DEBUG, "CPU monitor thread is now terminating\n");
return NULL;
}
static ftdm_status_t ftdm_cpu_monitor_start(void)
{
if (ftdm_interrupt_create(&globals.cpu_monitor.interrupt, FTDM_INVALID_SOCKET, FTDM_NO_FLAGS) != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_CRIT, "Failed to create CPU monitor interrupt\n");
return FTDM_FAIL;
}
if (ftdm_thread_create_detached(ftdm_cpu_monitor_run, &globals.cpu_monitor) != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_CRIT, "Failed to create cpu monitor thread!!\n");
return FTDM_FAIL;
}
return FTDM_SUCCESS;
}
static void ftdm_cpu_monitor_stop(void)
{
if (!globals.cpu_monitor.interrupt) {
return;
}
if (!globals.cpu_monitor.running) {
return;
}
if (ftdm_interrupt_signal(globals.cpu_monitor.interrupt) != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_CRIT, "Failed to interrupt the CPU monitor\n");
return;
}
while (globals.cpu_monitor.running) {
ftdm_sleep(10);
}
ftdm_interrupt_destroy(&globals.cpu_monitor.interrupt);
}
FT_DECLARE(ftdm_status_t) ftdm_global_init(void)
{
memset(&globals, 0, sizeof(globals));
time_init();
ftdm_thread_override_default_stacksize(FTDM_THREAD_STACKSIZE);
globals.interface_hash = create_hashtable(16, ftdm_hash_hashfromstring, ftdm_hash_equalkeys);
globals.module_hash = create_hashtable(16, ftdm_hash_hashfromstring, ftdm_hash_equalkeys);
globals.span_hash = create_hashtable(16, ftdm_hash_hashfromstring, ftdm_hash_equalkeys);
globals.group_hash = create_hashtable(16, ftdm_hash_hashfromstring, ftdm_hash_equalkeys);
ftdm_mutex_create(&globals.mutex);
ftdm_mutex_create(&globals.span_mutex);
ftdm_mutex_create(&globals.group_mutex);
ftdm_mutex_create(&globals.call_id_mutex);
ftdm_sched_global_init();
globals.running = 1;
if (ftdm_sched_create(&globals.timingsched, "freetdm-master") != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_CRIT, "Failed to create master timing schedule context\n");
goto global_init_fail;
}
if (ftdm_sched_free_run(globals.timingsched) != FTDM_SUCCESS) {
ftdm_log(FTDM_LOG_CRIT, "Failed to run master timing schedule context\n");
goto global_init_fail;
}
return FTDM_SUCCESS;
global_init_fail:
globals.running = 0;
ftdm_mutex_destroy(&globals.mutex);
ftdm_mutex_destroy(&globals.span_mutex);
ftdm_mutex_destroy(&globals.group_mutex);
ftdm_mutex_destroy(&globals.call_id_mutex);
hashtable_destroy(globals.interface_hash);
hashtable_destroy(globals.module_hash);
hashtable_destroy(globals.span_hash);
hashtable_destroy(globals.group_hash);
return FTDM_FAIL;
}
FT_DECLARE(ftdm_status_t) ftdm_global_configuration(void)
{
int modcount = 0;
if (!globals.running) {
return FTDM_FAIL;
}
modcount = ftdm_load_modules();
ftdm_log(FTDM_LOG_NOTICE, "Modules configured: %d \n", modcount);
globals.cpu_monitor.enabled = 0;
globals.cpu_monitor.interval = 1000;
globals.cpu_monitor.alarm_action_flags = 0;
globals.cpu_monitor.set_alarm_threshold = 92;
globals.cpu_monitor.clear_alarm_threshold = 82;
if (load_config() != FTDM_SUCCESS) {
globals.running = 0;
ftdm_log(FTDM_LOG_ERROR, "FreeTDM global configuration failed!\n");
return FTDM_FAIL;
}
if (globals.cpu_monitor.enabled) {
ftdm_log(FTDM_LOG_INFO, "CPU Monitor is running interval:%d set-thres:%d clear-thres:%d\n",
globals.cpu_monitor.interval,
globals.cpu_monitor.set_alarm_threshold,
globals.cpu_monitor.clear_alarm_threshold);
if (ftdm_cpu_monitor_start() != FTDM_SUCCESS) {
return FTDM_FAIL;
}
}
return FTDM_SUCCESS;
}
FT_DECLARE(uint32_t) ftdm_running(void)
{
return globals.running;
}
FT_DECLARE(ftdm_status_t) ftdm_global_destroy(void)
{
ftdm_span_t *sp;
time_end();
/* many freetdm event loops rely on this variable to decide when to stop, do this first */
globals.running = 0;
/* stop the scheduling thread */
ftdm_free_sched_stop();
/* stop the cpu monitor thread */
ftdm_cpu_monitor_stop();
/* now destroy channels and spans */
globals.span_index = 0;
ftdm_span_close_all();
ftdm_mutex_lock(globals.span_mutex);
for (sp = globals.spans; sp;) {
ftdm_span_t *cur_span = sp;
sp = sp->next;
if (cur_span) {
if (ftdm_test_flag(cur_span, FTDM_SPAN_CONFIGURED)) {
ftdm_span_destroy(cur_span);
}
hashtable_remove(globals.span_hash, (void *)cur_span->name);
ftdm_safe_free(cur_span->dtmf_hangup);
ftdm_safe_free(cur_span->type);
ftdm_safe_free(cur_span->name);
ftdm_safe_free(cur_span);
cur_span = NULL;
}
}
globals.spans = NULL;
ftdm_mutex_unlock(globals.span_mutex);
/* destroy signaling and io modules */
ftdm_unload_modules();
ftdm_global_set_logger( NULL );
/* finally destroy the globals */
ftdm_mutex_lock(globals.mutex);
ftdm_sched_destroy(&globals.timingsched);
hashtable_destroy(globals.interface_hash);
hashtable_destroy(globals.module_hash);
hashtable_destroy(globals.span_hash);
hashtable_destroy(globals.group_hash);
ftdm_mutex_unlock(globals.mutex);
ftdm_mutex_destroy(&globals.mutex);
ftdm_mutex_destroy(&globals.span_mutex);
ftdm_mutex_destroy(&globals.group_mutex);
ftdm_mutex_destroy(&globals.call_id_mutex);
memset(&globals, 0, sizeof(globals));
return FTDM_SUCCESS;
}
FT_DECLARE(uint32_t) ftdm_separate_string(char *buf, char delim, char **array, int arraylen)
{
int argc;
char *ptr;
int quot = 0;
char qc = '\'';
int x;
if (!buf || !array || !arraylen) {
return 0;
}
memset(array, 0, arraylen * sizeof(*array));
ptr = buf;
/* we swallow separators that are contiguous */
while (*ptr == delim) ptr++;
for (argc = 0; *ptr && (argc < arraylen - 1); argc++) {
array[argc] = ptr;
for (; *ptr; ptr++) {
if (*ptr == qc) {
if (quot) {
quot--;
} else {
quot++;
}
} else if ((*ptr == delim) && !quot) {
*ptr++ = '\0';
/* we swallow separators that are contiguous */
while (*ptr == delim) ptr++;
break;
}
}
}
if (*ptr) {
array[argc++] = ptr;
}
/* strip quotes */
for (x = 0; x < argc; x++) {
char *p = array[x];
while((p = strchr(array[x], qc))) {
memmove(p, p+1, strlen(p));
p++;
}
}
return argc;
}
FT_DECLARE(void) ftdm_bitstream_init(ftdm_bitstream_t *bsp, uint8_t *data, uint32_t datalen, ftdm_endian_t endian, uint8_t ss)
{
memset(bsp, 0, sizeof(*bsp));
bsp->data = data;
bsp->datalen = datalen;
bsp->endian = endian;
bsp->ss = ss;
if (endian < 0) {
bsp->top = bsp->bit_index = 7;
bsp->bot = 0;
} else {
bsp->top = bsp->bit_index = 0;
bsp->bot = 7;
}
}
FT_DECLARE(int8_t) ftdm_bitstream_get_bit(ftdm_bitstream_t *bsp)
{
int8_t bit = -1;
if (bsp->byte_index >= bsp->datalen) {
goto done;
}
if (bsp->ss) {
if (!bsp->ssv) {
bsp->ssv = 1;
return 0;
} else if (bsp->ssv == 2) {
bsp->byte_index++;
bsp->ssv = 0;
return 1;
}
}
bit = (bsp->data[bsp->byte_index] >> (bsp->bit_index)) & 1;
if (bsp->bit_index == bsp->bot) {
bsp->bit_index = bsp->top;
if (bsp->ss) {
bsp->ssv = 2;
goto done;
}
if (++bsp->byte_index > bsp->datalen) {
bit = -1;
goto done;
}
} else {
bsp->bit_index = bsp->bit_index + bsp->endian;
}
done:
return bit;
}
FT_DECLARE(void) print_hex_bytes(uint8_t *data, ftdm_size_t dlen, char *buf, ftdm_size_t blen)
{
char *bp = buf;
uint8_t *byte = data;
uint32_t i, j = 0;
if (blen < (dlen * 3) + 2) {
return;
}
*bp++ = '[';
j++;
for(i = 0; i < dlen; i++) {
snprintf(bp, blen-j, "%02x ", *byte++);
bp += 3;
j += 3;
}
*--bp = ']';
}
FT_DECLARE(void) print_bits(uint8_t *b, int bl, char *buf, int blen, ftdm_endian_t e, uint8_t ss)
{
ftdm_bitstream_t bs;
int j = 0, c = 0;
int8_t bit;
uint32_t last;
if (blen < (bl * 10) + 2) {
return;
}
ftdm_bitstream_init(&bs, b, bl, e, ss);
last = bs.byte_index;
while((bit = ftdm_bitstream_get_bit(&bs)) > -1) {
buf[j++] = bit ? '1' : '0';
if (bs.byte_index != last) {
buf[j++] = ' ';
last = bs.byte_index;
if (++c == 8) {
buf[j++] = '\n';
c = 0;
}
}
}
}
FT_DECLARE_NONSTD(ftdm_status_t) ftdm_console_stream_raw_write(ftdm_stream_handle_t *handle, uint8_t *data, ftdm_size_t datalen)
{
ftdm_size_t need = handle->data_len + datalen;
if (need >= handle->data_size) {
void *new_data;
need += handle->alloc_chunk;
if (!(new_data = realloc(handle->data, need))) {
return FTDM_MEMERR;
}
handle->data = new_data;
handle->data_size = need;
}
memcpy((uint8_t *) (handle->data) + handle->data_len, data, datalen);
handle->data_len += datalen;
handle->end = (uint8_t *) (handle->data) + handle->data_len;
*(uint8_t *)handle->end = '\0';
return FTDM_SUCCESS;
}
FT_DECLARE(int) ftdm_vasprintf(char **ret, const char *fmt, va_list ap) /* code from switch_apr.c */
{
#ifdef HAVE_VASPRINTF
return vasprintf(ret, fmt, ap);
#else
char *buf;
int len;
size_t buflen;
va_list ap2;
char *tmp = NULL;
#ifdef _MSC_VER
#if _MSC_VER >= 1500
/* hack for incorrect assumption in msvc header files for code analysis */
__analysis_assume(tmp);
#endif
ap2 = ap;
#else
va_copy(ap2, ap);
#endif
len = vsnprintf(tmp, 0, fmt, ap2);
if (len > 0 && (buf = ftdm_malloc((buflen = (size_t) (len + 1)))) != NULL) {
len = vsnprintf(buf, buflen, fmt, ap);
*ret = buf;
} else {
*ret = NULL;
len = -1;
}
va_end(ap2);
return len;
#endif
}
FT_DECLARE_NONSTD(ftdm_status_t) ftdm_console_stream_write(ftdm_stream_handle_t *handle, const char *fmt, ...)
{
va_list ap;
char *buf = handle->data;
char *end = handle->end;
int ret = 0;
char *data = NULL;
if (handle->data_len >= handle->data_size) {
return FTDM_FAIL;
}
va_start(ap, fmt);
ret = ftdm_vasprintf(&data, fmt, ap);
va_end(ap);
if (data) {
ftdm_size_t remaining = handle->data_size - handle->data_len;
ftdm_size_t need = strlen(data) + 1;
if ((remaining < need) && handle->alloc_len) {
ftdm_size_t new_len;
void *new_data;
new_len = handle->data_size + need + handle->alloc_chunk;
if ((new_data = ftdm_realloc(handle->data, new_len))) {
handle->data_size = handle->alloc_len = new_len;
handle->data = new_data;
buf = handle->data;
remaining = handle->data_size - handle->data_len;
handle->end = (uint8_t *) (handle->data) + handle->data_len;
end = handle->end;
} else {
ftdm_log(FTDM_LOG_CRIT, "Memory Error!\n");
ftdm_safe_free(data);
return FTDM_FAIL;
}
}
if (remaining < need) {
ret = -1;
} else {
ret = 0;
snprintf(end, remaining, "%s", data);
handle->data_len = strlen(buf);
handle->end = (uint8_t *) (handle->data) + handle->data_len;
}
ftdm_safe_free(data);
}
return ret ? FTDM_FAIL : FTDM_SUCCESS;
}
FT_DECLARE(char *) ftdm_strdup(const char *str)
{
ftdm_size_t len = strlen(str) + 1;
void *new = ftdm_malloc(len);
if (!new) {
return NULL;
}
return (char *)memcpy(new, str, len);
}
FT_DECLARE(char *) ftdm_strndup(const char *str, ftdm_size_t inlen)
{
char *new = NULL;
ftdm_size_t len = strlen(str) + 1;
if (len > (inlen+1)) {
len = inlen+1;
}
new = (char *)ftdm_malloc(len);
if (!new) {
return NULL;
}
memcpy(new, str, len-1);
new[len-1] = 0;
return new;
}
static ftdm_status_t ftdm_call_set_call_id(ftdm_channel_t *fchan, ftdm_caller_data_t *caller_data)
{
uint32_t current_call_id;
ftdm_assert_return(!caller_data->call_id, FTDM_FAIL, "Overwriting non-cleared call-id\n");
ftdm_mutex_lock(globals.call_id_mutex);
current_call_id = globals.last_call_id;
for (current_call_id = globals.last_call_id + 1;
current_call_id != globals.last_call_id;
current_call_id++ ) {
if (current_call_id > MAX_CALLIDS) {
current_call_id = 1;
}
if (globals.call_ids[current_call_id] == NULL) {
break;
}
}
ftdm_assert_return(globals.call_ids[current_call_id] == NULL, FTDM_FAIL, "We ran out of call ids\n");
globals.last_call_id = current_call_id;
caller_data->call_id = current_call_id;
globals.call_ids[current_call_id] = caller_data;
caller_data->fchan = fchan;
ftdm_mutex_unlock(globals.call_id_mutex);
return FTDM_SUCCESS;
}
static ftdm_status_t ftdm_call_clear_call_id(ftdm_caller_data_t *caller_data)
{
if (caller_data->call_id) {
ftdm_assert_return((caller_data->call_id <= MAX_CALLIDS), FTDM_FAIL, "Cannot clear call with invalid call-id\n");
} else {
/* there might not be a call at all */
return FTDM_SUCCESS;
}
ftdm_mutex_lock(globals.call_id_mutex);
if (globals.call_ids[caller_data->call_id]) {
ftdm_log(FTDM_LOG_DEBUG, "Cleared call with id %u\n", caller_data->call_id);
globals.call_ids[caller_data->call_id] = NULL;
caller_data->call_id = 0;
} else {
ftdm_log(FTDM_LOG_CRIT, "call-id did not exist %u\n", caller_data->call_id);
}
ftdm_mutex_unlock(globals.call_id_mutex);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_sigmsg_get_raw_data(ftdm_sigmsg_t *sigmsg, void **data, ftdm_size_t *datalen)
{
if (!sigmsg || !sigmsg->raw.len) {
return FTDM_FAIL;
}
*data = sigmsg->raw.data;
*datalen = sigmsg->raw.len;
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_sigmsg_get_raw_data_detached(ftdm_sigmsg_t *sigmsg, void **data, ftdm_size_t *datalen)
{
if (!sigmsg || !sigmsg->raw.len) {
return FTDM_FAIL;
}
*data = sigmsg->raw.data;
*datalen = sigmsg->raw.len;
sigmsg->raw.data = NULL;
sigmsg->raw.len = 0;
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_sigmsg_set_raw_data(ftdm_sigmsg_t *sigmsg, void *data, ftdm_size_t datalen)
{
ftdm_assert_return(sigmsg, FTDM_FAIL, "Trying to set raw data on a NULL event\n");
ftdm_assert_return(!sigmsg->raw.len, FTDM_FAIL, "Overwriting existing raw data\n");
ftdm_assert_return(datalen, FTDM_FAIL, "Data length not set\n");
sigmsg->raw.data = data;
sigmsg->raw.len = datalen;
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_usrmsg_get_raw_data(ftdm_usrmsg_t *usrmsg, void **data, ftdm_size_t *datalen)
{
if (!usrmsg || !usrmsg->raw.len) {
return FTDM_FAIL;
}
*data = usrmsg->raw.data;
*datalen = usrmsg->raw.len;
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_usrmsg_set_raw_data(ftdm_usrmsg_t *usrmsg, void *data, ftdm_size_t datalen)
{
ftdm_assert_return(usrmsg, FTDM_FAIL, "Trying to set raw data on a NULL event\n");
ftdm_assert_return(!usrmsg->raw.len, FTDM_FAIL, "Overwriting existing raw data\n");
ftdm_assert_return(datalen, FTDM_FAIL, "Data length not set\n");
usrmsg->raw.data = data;
usrmsg->raw.len = datalen;
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_channel_save_usrmsg(ftdm_channel_t *ftdmchan, ftdm_usrmsg_t *usrmsg)
{
ftdm_assert_return(!ftdmchan->usrmsg, FTDM_FAIL, "Info from previous event was not cleared\n");
if (usrmsg) {
/* Copy sigmsg from user to internal copy so user can set new variables without race condition */
ftdmchan->usrmsg = ftdm_calloc(1, sizeof(ftdm_usrmsg_t));
memcpy(ftdmchan->usrmsg, usrmsg, sizeof(ftdm_usrmsg_t));
if (usrmsg->raw.data) {
usrmsg->raw.data = NULL;
usrmsg->raw.len = 0;
}
if (usrmsg->variables) {
usrmsg->variables = NULL;
}
}
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_sigmsg_free(ftdm_sigmsg_t **sigmsg)
{
if (!*sigmsg) {
return FTDM_SUCCESS;
}
if ((*sigmsg)->variables) {
hashtable_destroy((*sigmsg)->variables);
(*sigmsg)->variables = NULL;
}
if ((*sigmsg)->raw.data) {
ftdm_safe_free((*sigmsg)->raw.data);
(*sigmsg)->raw.data = NULL;
(*sigmsg)->raw.len = 0;
}
ftdm_safe_free(*sigmsg);
return FTDM_SUCCESS;
}
FT_DECLARE(ftdm_status_t) ftdm_usrmsg_free(ftdm_usrmsg_t **usrmsg)
{
if (!*usrmsg) {
return FTDM_SUCCESS;
}
if ((*usrmsg)->variables) {
hashtable_destroy((*usrmsg)->variables);
(*usrmsg)->variables = NULL;
}
if ((*usrmsg)->raw.data) {
ftdm_safe_free((*usrmsg)->raw.data);
(*usrmsg)->raw.data = NULL;
(*usrmsg)->raw.len = 0;
}
ftdm_safe_free(*usrmsg);
return FTDM_SUCCESS;
}
/* 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 noet:
*/
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