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Improvements to mod_bert 

* Use digital milliwatt as the test sequence pattern
* Add debug IO files (enabled using bert_debug_io_file variable)
This commit is contained in:
Moises Silva 2013-08-13 17:35:35 -04:00
parent a60876b165
commit d3b214a672
1 changed files with 113 additions and 57 deletions
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170
src/mod/applications/mod_bert/mod_bert.c
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@ -34,18 +34,36 @@ SWITCH_MODULE_LOAD_FUNCTION(mod_bert_load);
SWITCH_MODULE_SHUTDOWN_FUNCTION(mod_bert_shutdown);
SWITCH_MODULE_DEFINITION(mod_bert, mod_bert_load, mod_bert_shutdown, NULL);
static int16_t bert_next_sample(int16_t sample, uint8_t *going_up)
{
if (sample == INT16_MAX || !(*going_up)) {
*going_up = 0;
return --sample;
}
if (sample == INT16_MIN || *going_up) {
*going_up = 1;
return ++sample;
}
switch_assert(0);
}
/* http://en.wikipedia.org/wiki/Digital_milliwatt */
unsigned char ulaw_digital_milliwatt[8] = { 0x1e, 0x0b, 0x0b, 0x1e, 0x9e, 0x8b, 0x8b, 0x9e };
typedef struct {
uint32_t processed_samples;
uint32_t err_samples;
uint32_t window_ms;
uint32_t window_samples;
uint8_t sequence_sample;
uint8_t predicted_sample;
float max_err;
float max_err_hit;
float max_err_ever;
uint8_t in_sync;
uint8_t hangup_on_error;
uint8_t milliwatt_index;
uint8_t milliwatt_prediction_index;
switch_time_t timeout;
FILE *input_debug_f;
FILE *output_debug_f;
} bert_t;
#define bert_increase_milliwatt_index(index) \
do { \
if ((index) == (switch_arraylen(ulaw_digital_milliwatt)-1)) { \
(index) = 0; \
} else { \
(index) = ((index) + 1); \
} \
} while (0);
#define BERT_DEFAULT_WINDOW_MS 1000
#define BERT_DEFAULT_MAX_ERR 10.0
@ -59,25 +77,11 @@ SWITCH_STANDARD_APP(bert_test_function)
const char *var = NULL;
int i = 0;
int synced = 0;
uint32_t ts = 0;
uint32_t write_ts = 0;
int32_t timeout_ms = 0;
struct {
uint32_t processed_samples;
uint32_t err_samples;
uint32_t window_ms;
uint32_t window_samples;
int16_t sequence_sample;
int16_t predicted_sample;
int16_t previous_sample;
float max_err;
float max_err_hit;
float max_err_ever;
uint8_t in_sync;
uint8_t hangup_on_error;
uint8_t sequence_going_up;
uint8_t prediction_going_up;
switch_time_t timeout;
} bert;
bert_t bert = { 0 };
memset(&bert, 0, sizeof(bert));
channel = switch_core_session_get_channel(session);
@ -85,11 +89,14 @@ SWITCH_STANDARD_APP(bert_test_function)
switch_core_session_get_read_impl(session, &read_impl);
memset(&bert, 0, sizeof(bert));
if (read_impl.ianacode != 0) {
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_ERROR, "This application only works when using ulaw codec\n");
goto done;
}
bert.window_ms = BERT_DEFAULT_WINDOW_MS;
bert.window_samples = switch_samples_per_packet(read_impl.samples_per_second, bert.window_ms);
bert.max_err = BERT_DEFAULT_MAX_ERR;
bert.sequence_going_up = 1;
timeout_ms = BERT_DEFAULT_TIMEOUT_MS;
/* check if there are user-defined overrides */
@ -117,6 +124,19 @@ SWITCH_STANDARD_APP(bert_test_function)
bert.hangup_on_error = 1;
}
}
if ((var = switch_channel_get_variable(channel, "bert_debug_io_file"))) {
char debug_file[1024];
snprintf(debug_file, sizeof(debug_file), "%s.in", var);
bert.input_debug_f = fopen(debug_file, "w");
if (!bert.input_debug_f) {
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_ERROR, "Failed to open input debug file %s\n", debug_file);
}
snprintf(debug_file, sizeof(debug_file), "%s.out", var);
bert.output_debug_f = fopen(debug_file, "w");
if (!bert.output_debug_f) {
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_ERROR, "Failed to open output debug file %s\n", debug_file);
}
}
bert.timeout = (switch_micro_time_now() + (timeout_ms * 1000));
@ -124,22 +144,50 @@ SWITCH_STANDARD_APP(bert_test_function)
write_frame.data = switch_core_session_alloc(session, SWITCH_RECOMMENDED_BUFFER_SIZE);
write_frame.buflen = SWITCH_RECOMMENDED_BUFFER_SIZE;
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_DEBUG, "BERT Test Window=%ums/%u MaxErr=%f%%\n", bert.window_ms, bert.window_samples, bert.max_err);
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_DEBUG, "BERT Test Window=%ums/%u, MaxErr=%f%%, Timeout=%dms\n", bert.window_ms, bert.window_samples, bert.max_err, timeout_ms);
if (bert.window_samples <= 0) {
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_ERROR, "Failed to compute BERT window samples!\n");
goto done;
}
while (switch_channel_ready(channel)) {
int16_t *read_samples = NULL;
int16_t *write_samples = NULL;
uint8_t *read_samples = NULL;
uint8_t *write_samples = NULL;
status = switch_core_session_read_frame(session, &read_frame, SWITCH_IO_FLAG_NONE, 0);
if (!SWITCH_READ_ACCEPTABLE(status)) {
break;
}
/* BERT Sync */
if (bert.timeout && !synced) {
switch_time_t now = switch_micro_time_now();
if (now >= bert.timeout) {
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_WARNING, "BERT Timeout (read_samples=%d, read_bytes=%d, expected_samples=%d, %s)\n",
read_frame->samples, read_frame->datalen, read_impl.samples_per_packet, switch_core_session_get_uuid(session));
if (bert.hangup_on_error) {
switch_channel_hangup(channel, SWITCH_CAUSE_MEDIA_TIMEOUT);
}
}
}
if (!read_frame->datalen) {
continue;
}
if (read_frame->samples != read_impl.samples_per_packet) {
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_DEBUG, "Only read %d samples, expected %d!\n", read_frame->samples, read_impl.samples_per_packet);
continue;
}
read_samples = read_frame->data;
write_samples = write_frame.data;
for (i = 0; i < (read_frame->datalen / 2); i++) {
if (read_frame->samples) {
if (bert.input_debug_f) {
fwrite(read_frame->data, read_frame->datalen, 1, bert.input_debug_f);
}
}
/* BERT Sync Loop */
for (i = 0; i < read_frame->samples; i++) {
if (bert.window_samples == bert.processed_samples) {
/* Calculate error rate */
float err = ((float)((float)bert.err_samples / (float)bert.processed_samples) * 100.0);
@ -166,44 +214,52 @@ SWITCH_STANDARD_APP(bert_test_function)
}
bert.processed_samples = 0;
bert.err_samples = 0;
if (bert.timeout && !synced) {
switch_time_t now = switch_micro_time_now();
if (now >= bert.timeout) {
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_WARNING, "BERT Timeout\n");
if (bert.hangup_on_error) {
switch_channel_hangup(channel, SWITCH_CAUSE_MEDIA_TIMEOUT);
}
}
}
}
if (bert.predicted_sample != read_samples[i]) {
bert.err_samples++;
if (!bert.in_sync) {
/* If we're not in sync, we must reset the index on error to start the pattern detection again */
bert.milliwatt_prediction_index = 0;
}
}
if (bert.previous_sample > read_samples[i]) {
bert.prediction_going_up = 0;
} else {
bert.prediction_going_up = 1;
}
bert.predicted_sample = bert_next_sample(read_samples[i], &bert.prediction_going_up);
bert.sequence_sample = bert_next_sample(bert.sequence_sample, &bert.sequence_going_up);
/* Calculate our next sequence sample to write */
bert.sequence_sample = ulaw_digital_milliwatt[bert.milliwatt_index];
//switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_ERROR, "[%d] 0x%X\n", bert.milliwatt_index, bert.sequence_sample);
bert_increase_milliwatt_index(bert.milliwatt_index);
//switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_ERROR, "[%d] 0x%X\n", bert.milliwatt_index, bert.sequence_sample);
write_samples[i] = bert.sequence_sample;
bert.previous_sample = read_samples[i];
/* Try to guess what the next sample will be in the milliwatt sequence */
bert.predicted_sample = ulaw_digital_milliwatt[bert.milliwatt_prediction_index];
bert_increase_milliwatt_index(bert.milliwatt_prediction_index);
bert.processed_samples++;
}
write_frame.datalen = read_frame->datalen;
write_frame.samples = i;
write_frame.timestamp = ts;
write_frame.timestamp = write_ts;
if (bert.output_debug_f) {
fwrite(write_frame.data, write_frame.datalen, 1, bert.output_debug_f);
}
status = switch_core_session_write_frame(session, &write_frame, SWITCH_IO_FLAG_NONE, 0);
if (!SWITCH_READ_ACCEPTABLE(status)) {
break;
}
ts += read_impl.samples_per_packet;
write_ts += read_impl.samples_per_packet;
}
done:
if (bert.input_debug_f) {
fclose(bert.input_debug_f);
}
if (bert.output_debug_f) {
fclose(bert.output_debug_f);
}
switch_log_printf(SWITCH_CHANNEL_SESSION_LOG(session), SWITCH_LOG_DEBUG, "BERT Test Completed. MaxErr=%f%%\n", synced ? bert.max_err_hit : bert.max_err_ever);
}
SWITCH_MODULE_LOAD_FUNCTION(mod_bert_load)