ssi_point_t Painter::pointf2point(ssi_pointf_t point, ssi_rect_t area) {
ssi_point_t p;
p.x = ssi_cast(ssi_int_t, point.x * area.width + 0.5f);
p.y = ssi_cast(ssi_int_t, point.y * area.height + 0.5f);
return p;
}
void QRSDetection::sendEvent_h(ITransformer::info &info, ssi_time_t sample_rate, ssi_size_t frame_count, ssi_size_t sample_number){
ssi_size_t samples_per_frame = info.frame_num;
ssi_size_t frame_time = ssi_sec2ms (info.time);
ssi_real_t time_per_sample = 1000.0f / (ssi_real_t) sample_rate;
ssi_size_t current_sample = frame_count * samples_per_frame + sample_number;
ssi_size_t current_sample_time = ssi_cast (ssi_size_t, current_sample * time_per_sample + 0.5);
if (_listener) {
_r_event.time = current_sample_time;
_r_event.dur = ssi_cast (ssi_size_t, time_per_sample + 0.5);
if(_send_etuple) {
ssi_event_map_t *ptr = ssi_pcast (ssi_event_map_t, _r_event.ptr);
ptr[0].value = ssi_real_t (current_sample_time - _last_R);
} else {
ssi_real_t *ptr = ssi_pcast (ssi_real_t, _r_event.ptr);
ptr[0] = ssi_real_t(current_sample_time - _last_R);
}
_listener->update (_r_event);
} else {
ssi_print("\nR-spike detected in \n\tframe number %u with starting time %u ms", frame_count, frame_time);
ssi_print("\n\tat sample number %u at time %u ms", current_sample, current_sample_time);
}
_last_R = current_sample_time;
}
ssi_point_t Painter::pointf2point(ssi_pointf_t point) {
ssi_point_t p;
p.x = ssi_cast(ssi_int_t, point.x + 0.5f);
p.y = ssi_cast(ssi_int_t, point.y + 0.5f);
return p;
}
void AudioConvert::transform (ITransformer::info info,
ssi_stream_t &stream_in,
ssi_stream_t &stream_out,
ssi_size_t xtra_stream_in_num,
ssi_stream_t xtra_stream_in[]) {
if (_short_to_float) {
int16_t *srcptr = ssi_pcast (int16_t, stream_in.ptr);
ssi_real_t *dstptr = ssi_pcast (ssi_real_t, stream_out.ptr);
ssi_size_t N = stream_in.num * stream_in.dim;
for (ssi_size_t i = 0; i < N; i++) {
*dstptr++ = ssi_cast (ssi_real_t, *srcptr++) / 32768.0f;
}
} else {
ssi_real_t *srcptr = ssi_pcast (ssi_real_t, stream_in.ptr);
int16_t *dstptr = ssi_pcast (int16_t, stream_out.ptr);
ssi_size_t N = stream_in.num * stream_in.dim;
for (ssi_size_t i = 0; i < N; i++) {
*dstptr++ = ssi_cast (int16_t, *srcptr++ * 32768.0f);
}
}
}
void SignalTools::Series (ssi_stream_t &series,
ssi_time_t duration,
ssi_real_t offset) {
/* matlab code:
t = 0:1/sr:dur-1/sr;
*/
ssi_real_t delta = ssi_cast (ssi_real_t, 1.0 / series.sr);
ssi_size_t number = ssi_cast (ssi_size_t, duration / delta);
SSI_ASSERT (number > 0);
ssi_stream_adjust (series, number);
ssi_real_t *out = ssi_pcast (ssi_real_t, series.ptr);
ssi_real_t *outptr_new = out;
ssi_real_t *outptr_old = out;
for (ssi_size_t i = 0; i < series.dim; ++i) {
*outptr_new++ = offset;
}
for (ssi_size_t i = series.dim; i < series.dim * series.num; ++i) {
*outptr_new++ = *outptr_old++ + delta;
}
}
ssi_real_t Statistics::calculateSkewness(ssi_size_t dim_idx)
{
running_stat_t * rs = &(_running_stats[dim_idx]);
if (rs->M2 == 0.0){
return 0.0f;
}
return ssi_cast(ssi_real_t, sqrt(ssi_cast(ssi_stat_ultra_precision_t, rs->n)) * rs->M3 / pow(rs->M2, ssi_cast(ssi_stat_ultra_precision_t, 1.5)));
}
ssi_rect_t Painter::rectf2rect(ssi_rectf_t rect, ssi_rect_t area) {
ssi_rect_t r;
r.left = ssi_cast(ssi_int_t, rect.left * area.width + 0.5f);
r.top = ssi_cast(ssi_int_t, rect.top * area.height + 0.5f);
r.width = ssi_cast(ssi_int_t, rect.width * area.width + 0.5f);
r.height = ssi_cast(ssi_int_t, rect.height * area.height + 0.5f);
return r;
}
ssi_rect_t Painter::rectf2rect(ssi_rectf_t rect) {
ssi_rect_t r;
r.left = ssi_cast(ssi_int_t, rect.left + 0.5f);
r.top = ssi_cast(ssi_int_t, rect.top + 0.5f);
r.width = ssi_cast(ssi_int_t, rect.width + 0.5f);
r.height = ssi_cast(ssi_int_t, rect.height + 0.5f);
return r;
}
ssi_real_t Evaluation::get_class_prob (ssi_size_t index) {
ssi_size_t sum = 0;
for (ssi_size_t i = 0; i < _n_classes; ++i) {
sum += _conf_mat_ptr[index][i];
}
ssi_real_t prob = sum > 0 ? ssi_cast (ssi_real_t, _conf_mat_ptr[index][index]) / ssi_cast (ssi_real_t, sum) : 0;
return prob;
}
ssi_real_t Statistics::calculateKurtosis(ssi_size_t dim_idx)
{
running_stat_t * rs = &(_running_stats[dim_idx]);
if (rs->M2 == 0.0){
return 0.0f;
}
return ssi_cast(ssi_real_t, ssi_cast(ssi_stat_ultra_precision_t, rs->n)*rs->M4 / (rs->M2*rs->M2) - 3.0);
}
bool FileReader::prepare_file () {
if (_options.offsetInSamples > 0) {
_offset_in_samples = _options.offsetInSamples;
} else {
_offset_in_samples = ssi_cast (ssi_size_t, _stream.sr * _options.offset);
}
_offset_in_bytes = _offset_in_samples * _stream.dim * _stream.byte;
if (_offset_in_samples > _sample_number_total) {
ssi_wrn ("offset exceeds stream number");
return false;
}
if (_options.cutoffInSamples > 0) {
_cutoff_in_samples = _options.cutoffInSamples;
} else {
_cutoff_in_samples = ssi_cast (ssi_size_t, _stream.sr * _options.cutoff);
}
if (_options.blockInSamples > 0) {
_sample_number_per_step = _options.blockInSamples;
} else {
_sample_number_per_step = ssi_cast (ssi_size_t, _stream.sr * _options.block);
}
_step_counter = 0;
if (_cutoff_in_samples == 0) {
_max_steps = (_sample_number_total - _offset_in_samples) / _sample_number_per_step;
} else {
if (_cutoff_in_samples > _sample_number_total) {
ssi_wrn ("cutoff exceeds stream number");
return false;
}
if (_offset_in_samples > _cutoff_in_samples) {
ssi_wrn ("offset exceeds cutoff");
return false;
}
_max_steps = (_cutoff_in_samples - _offset_in_samples) / _sample_number_per_step;
}
if (_max_steps == 0) {
ssi_wrn ("file too short");
return false;
}
_options.block = _sample_number_per_step / _stream.sr;
ssi_stream_adjust (_stream, _sample_number_per_step);
_file_stream_in.getDataFile ()->seek (_offset_in_bytes);
return true;
}
void EmoVoicePitch::transform_enter (ssi_stream_t &stream_in,
ssi_stream_t &stream_out,
ssi_size_t xtra_stream_in_num,
ssi_stream_t xtra_stream_in[]) {
if (!_cfg) {
_cfg = pitch_create (ssi_cast (pitch_method_t, _options.method));
_cfg->minimumPitch = ssi_cast (mx_real_t, _options.minfreq);
_cfg->maximumPitch = ssi_cast (mx_real_t, _options.maxfreq);
}
}
ssi_real_t Evaluation::get_accuracy_prob () {
ssi_size_t sum_correct = 0;
for (ssi_size_t i = 0; i < _n_classes; ++i) {
sum_correct += _conf_mat_ptr[i][i];
}
ssi_real_t prob = _n_classified > 0 ? ssi_cast (ssi_real_t, sum_correct) / ssi_cast (ssi_real_t, _n_classified) : 0;
return prob;
}
void MyEventSender::consume(IConsumer::info consume_info,
ssi_size_t stream_in_num,
ssi_stream_t stream_in[]) {
ssi_real_t *in = ssi_pcast(ssi_real_t, stream_in[0].ptr);
ssi_real_t *out = ssi_pcast(ssi_real_t, _event.ptr);
ssi_mean(stream_in[0].num, stream_in[0].dim, in, out);
_event.time = ssi_cast(ssi_size_t, consume_info.time * 1000);
_event.dur = ssi_cast(ssi_size_t, consume_info.dur * 1000);
_elistener->update(_event);
}
void TupleEventSender::consume (IConsumer::info consume_info,
ssi_size_t stream_in_num,
ssi_stream_t stream_in[]) {
ssi_size_t dim = stream_in[0].dim;
ssi_size_t num = stream_in[0].num;
ssi_real_t *src = ssi_pcast(ssi_real_t, stream_in[0].ptr);
ssi_event_tuple_t *dst = ssi_pcast(ssi_event_tuple_t, _event.ptr);
_event.time = ssi_cast (ssi_size_t, 1000 * consume_info.time + 0.5);
_event.dur = ssi_cast (ssi_size_t, 1000 * consume_info.dur + 0.5);
_event.state = consume_info.status == IConsumer::COMPLETED ? SSI_ESTATE_COMPLETED : SSI_ESTATE_CONTINUED;
if (_options.mean) {
ssi_real_t *mean = new ssi_real_t[dim];
ssi_mean(num, dim, src, mean);
for (ssi_size_t i = 0; i < dim; i++) {
dst++->value = mean[i];
}
}
if (_options.var) {
ssi_real_t *var = new ssi_real_t[dim];
ssi_var(num, dim, src, var);
for (ssi_size_t i = 0; i < dim; i++) {
dst++->value = var[i];
}
}
if (_options.minval || _options.maxval) {
ssi_real_t *minval = new ssi_real_t[dim];
ssi_size_t *minpos = new ssi_size_t[dim];
ssi_real_t *maxval = new ssi_real_t[dim];
ssi_size_t *maxpos = new ssi_size_t[dim];
ssi_minmax(num, dim, src, minval, minpos, maxval, maxpos);
if (_options.minval) {
for (ssi_size_t i = 0; i < dim; i++) {
dst++->value = minval[i];
}
}
if (_options.maxval) {
for (ssi_size_t i = 0; i < dim; i++) {
dst++->value = maxval[i];
}
}
}
_listener->update(_event);
}
bool ISTrigger::setTriggerStream (ssi_size_t index, ssi_stream_t &trigger, ssi_real_t thres) {
if (trigger.type != SSI_REAL) {
ssi_wrn ("ISTrigger::setTriggerStream () -> stream.type != SSI_REAL");
return false;
}
if (trigger.dim != 1) {
ssi_wrn ("ISTrigger::setTriggerStream () -> stream.dim != 1");
return false;
}
_samples.reset ();
ssi_sample_t *sample;
ssi_size_t count = 0;
ssi_real_t *ptr = 0;
ssi_real_t sum = 0;
ssi_size_t from, to;
while (sample = _samples.next ()) {
if (sample->streams[index] == 0) {
_trigger[index][count] = false;
++count;
continue;
}
from = ssi_cast (ssi_size_t, sample->time * trigger.sr + 0.5);
to = from + ssi_cast (ssi_size_t, sample->streams[index]->num / sample->streams[index]->sr * trigger.sr + 0.5) - 1;
if (to >= trigger.num) {
ssi_wrn ("sample#%u exceeds trigger stream, setting remaining samples to false", count);
for (; count < _samples.getSize (); count++) {
_trigger[index][count] = false;
}
break;
}
sum = 0;
ptr = ssi_pcast (ssi_real_t, trigger.ptr) + from;
for (ssi_size_t i = from; i <= to; i++) {
sum += *ptr++;
}
_trigger[index][count] = sum / (to - from + 1) > thres;
++count;
}
return true;
}
void SignalTools::Random(ssi_stream_t &stream) {
ssi_real_t *ptr = ssi_pcast(ssi_real_t, stream.ptr);
for (ssi_size_t i = 0; i < stream.dim * stream.num; i++) {
*ptr++ = ssi_cast (ssi_real_t, ssi_random());
}
}
ssi_size_t FileBinary::writeLine (const ssi_char_t *string) {
if (!_is_open) {
ssi_wrn ("file not open (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
if (!_write_mode) {
ssi_wrn ("file not in write mode (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
ssi_size_t result_1 = 0;
ssi_size_t result_2 = 0;
ssi_size_t len = ssi_cast (ssi_size_t, strlen (string));
result_1 = write (&len, sizeof (ssi_size_t), 1);
if (!result_1)
{
ssi_wrn ("write() failed (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
result_2 = write (string, sizeof (ssi_char_t), len);
if (!result_2)
{
ssi_wrn ("write() failed (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
return result_1 + result_2;
}
bool Fisher::transform (ssi_stream_t &stream, ssi_stream_t &stream_t) {
ae_state state;
ae_vector feature_v;
ae_vector_init (&feature_v, 0, DT_REAL, &state, ae_true);
AlgLibTools::Stream2vector (stream, &feature_v, &state);
ae_vector reduced_v;
ae_vector_init (&reduced_v, _basis->rows, DT_REAL, &state, ae_true);
rmatrixmv (_basis->cols, _basis->rows, _basis, 0, 0, 1, &feature_v, 0, &reduced_v, 0, &state);
ae_int_t cnt = reduced_v.cnt;
if (_options.n > 0 && ssi_cast (ssi_size_t, reduced_v.cnt) >= _options.n) {
reduced_v.cnt = _options.n;
}
AlgLibTools::Vector2stream (&reduced_v, stream_t, &state);
reduced_v.cnt = cnt;
ae_vector_clear (&feature_v);
ae_vector_clear (&reduced_v);
return true;
}
ssi_real_t Statistics::calculateVariance(ssi_size_t dim_idx)
{
running_stat_t * rs = &(_running_stats[dim_idx]);
if (rs->n == 1){
return 0.0f;
}
return ssi_cast(ssi_real_t, rs->M2 / (rs->n - 1.0));
}
void Thread::sleep_s (ssi_time_t seconds) {
#if hasCXX11threads
std::chrono::milliseconds dura((int)(seconds*1000 +0.5));
std::this_thread::sleep_for( dura );
#else
::Sleep (ssi_cast (DWORD, 1000.0*seconds + 0.5));
#endif // hasCXX11threads
}
void Evaluation::evalSplit (Trainer *trainer, ISamples &samples, ssi_real_t split) {
if (split <= 0 || split >= 1) {
ssi_err ("split must be a value between 0 and 1");
}
_trainer = trainer;
destroy_conf_mat ();
init_conf_mat (samples);
ssi_size_t *indices = new ssi_size_t[samples.getSize ()];
ssi_size_t *indices_count_lab = new ssi_size_t[samples.getClassSize ()];
ssi_size_t indices_count_all;
indices_count_all = 0;
for (ssi_size_t j = 0; j < samples.getClassSize (); j++) {
indices_count_lab[j] = 0;
}
ssi_size_t label;
ssi_size_t label_size;
for (ssi_size_t j = 0; j < samples.getSize (); j++) {
label = samples.get (j)->class_id;
label_size = samples.getSize (label);
if (++indices_count_lab[label] <= ssi_cast (ssi_size_t, label_size * split + 0.5f)) {
indices[indices_count_all++] = j;
}
}
SampleList strain;
SampleList stest;
// split off samples
ModelTools::SelectSampleList (samples, strain, stest, indices_count_all, indices);
_n_total = stest.getSize ();
_result_vec = new ssi_size_t[2*_n_total];
_result_vec_ptr = _result_vec;
// train with remaining samples
_trainer->release ();
if (_preproc_mode) {
_trainer->setPreprocMode (_preproc_mode, _n_streams_refs, _stream_refs);
} else if (_fselmethod) {
_trainer->setSelection (strain, _fselmethod, _pre_fselmethod, _n_pre_feature);
}
_trainer->train (strain);
// test with remaining samples
eval_h (stest);
delete[] indices;
delete[] indices_count_lab;
}
void EmoVoicePitch::transform (ITransformer::info info,
ssi_stream_t &stream_in,
ssi_stream_t &stream_out,
ssi_size_t xtra_stream_in_num,
ssi_stream_t xtra_stream_in[]) {
ssi_size_t sample_number = stream_in.num;
short *srcptr = ssi_pcast (short, stream_in.ptr);
mx_real_t *dstptr = ssi_pcast (mx_real_t, stream_out.ptr);
mx_real_t *p = pitch_calc (_cfg, srcptr, sample_number);
memcpy (dstptr, p, _cfg->nframes * sizeof (mx_real_t));
pitch_destroy (_cfg);
_cfg = pitch_create (ssi_cast (pitch_method_t, _options.method));
_cfg->minimumPitch = ssi_cast (mx_real_t, _options.minfreq);
_cfg->maximumPitch = ssi_cast (mx_real_t, _options.maxfreq);
free (p);
}
void MapEventSender::consume (IConsumer::info consume_info,
ssi_size_t stream_in_num,
ssi_stream_t stream_in[]) {
ssi_size_t dim = stream_in[0].dim;
ssi_size_t num = stream_in[0].num;
_event.time = ssi_cast (ssi_size_t, 1000 * consume_info.time + 0.5);
_event.dur = ssi_cast (ssi_size_t, 1000 * consume_info.dur + 0.5);
_event.state = consume_info.status == IConsumer::COMPLETED ? SSI_ESTATE_COMPLETED : SSI_ESTATE_CONTINUED;
if (_options.mean) {
ssi_real_t *src = ssi_pcast(ssi_real_t, stream_in[0].ptr);
ssi_event_map_t *dst = ssi_pcast(ssi_event_map_t, _event.ptr);
ssi_real_t *mean = new ssi_real_t[dim];
ssi_mean(num, dim, src, mean);
for (ssi_size_t i = 0; i < dim; i++) {
dst++->value = mean[i];
}
if (_listener) {
_listener->update(_event);
}
delete[] mean;
} else {
ssi_real_t *src = ssi_pcast(ssi_real_t, stream_in[0].ptr);
ssi_event_map_t *dst = ssi_pcast(ssi_event_map_t, _event.ptr);
for (ssi_size_t i = 0; i < num; i++) {
for (ssi_size_t j = 0; j < dim; j++) {
dst++->value = *src++;
}
if (_listener) {
_listener->update(_event);
}
}
}
}
ssi_size_t EmoVoicePitch::getSampleNumberOut (ssi_size_t sample_number_in) {
// check if we already know the result
if (sample_number_in == _sample_number_in) {
return _sample_number_out;
}
if (!_cfg) {
_cfg = pitch_create (ssi_cast (pitch_method_t, _options.method));
_cfg->minimumPitch = ssi_cast (mx_real_t, _options.minfreq);
_cfg->maximumPitch = ssi_cast (mx_real_t, _options.maxfreq);
}
// calculate new sample number
pitch_method_t method = _cfg->method;
mx_real_t minimumPitch = _cfg->minimumPitch;
mx_real_t dt = _cfg->dt;
int periodsPerWindow = _cfg->periodsPerWindow;
if (method == AC_GAUSS)
periodsPerWindow *= 2;
mx_real_t x1 = (mx_real_t) 0.5/SAMPLERATE;
mx_real_t dt_window = periodsPerWindow / minimumPitch;
int nFrames;
mx_real_t t1;
int result = fitInFrame (method >= FCC_NORMAL ? 1 / minimumPitch + dt_window : dt_window, dt, &nFrames, &t1, x1, sample_number_in);
SSI_ASSERT (result);
if (method >= FCC_NORMAL)
nFrames = nFrames - 1;
_sample_number_out = nFrames;
return nFrames;
}
Matrix<T> *MatrixOps<T>::Rand (ssi_size_t rows, ssi_size_t cols, T maxval) {
Matrix<T> *matrix = new Matrix<T> (rows, cols);
ssi_size_t elems = rows * cols;
T *dataptr = matrix->data;
double number;
for (ssi_size_t i = 0; i < elems; i++) {
// generate random number in interval [0..1)
number = static_cast<double>(rand ()) / (static_cast<double>(RAND_MAX) + 1.0);
*dataptr++ = ssi_cast (T, number * maxval);
}
return matrix;
}
void Painter::fill(ITool &brush, ssi_rect_t rect) {
if (rect.width == 1 && rect.height == 1) {
::SetPixel(ssi_cast(HDC, _device), _area.left + rect.left, _area.top + rect.top, brush.getColor());
} else {
::RECT r;
r.left = _area.left + rect.left;
r.top = _area.top + rect.top;
r.right = _area.left + rect.left + rect.width;
r.bottom = _area.top + rect.top + rect.height;
::FillRect((HDC)_device, &r, (HBRUSH)brush.getHandle());
}
}
void Painter::rect(ITool &pen, ITool &brush, ssi_rect_t rect) {
if (rect.width == 1 && rect.height == 1) {
::SetPixel(ssi_cast(HDC, _device), _area.left + rect.left, _area.top + rect.top, pen.getColor());
} else {
::SelectObject((HDC)_device, pen.getHandle());
::SelectObject((HDC)_device, brush.getHandle());
::RECT r;
r.left = _area.left + rect.left;
r.top = _area.top + rect.top;
r.right = _area.left + rect.left + rect.width;
r.bottom = _area.top + rect.top + rect.height;
::Rectangle((HDC)_device, r.left, r.top, r.right, r.bottom);
}
}
ssi_size_t FileBinary::readLine (ssi_size_t num, ssi_char_t *string) {
if (!_is_open) {
ssi_wrn ("file not open (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
if (!_read_mode) {
ssi_wrn ("file not in read mode (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
ssi_size_t result_1 = 0;
ssi_size_t result_2 = 0;
ssi_size_t len = 0;
result_1 = read (&len, sizeof (ssi_size_t), 1);
if (!result_1)
{
return 0;
}
if (num <= len)
{
ssi_wrn ("input string too short (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
result_2 = read (string, ssi_cast (ssi_size_t, sizeof (ssi_char_t)), len);
if (!result_2)
{
return 0;
}
string[len] = '\0';
return result_1 + result_2;
}
ssi_size_t FileBinary::write (const void *ptr, ssi_size_t size, ssi_size_t count) {
if (!_is_open) {
ssi_wrn ("file not open (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
if (!_write_mode) {
ssi_wrn ("file not in write mode (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
int64_t old_pos = tell();
ssi_size_t res = ssi_cast (ssi_size_t, fwrite (ptr, size, count, _file));
if (res != count) {
ssi_wrn ("fwrite() failed (path=%s, mode=%d, type=%d, shared=false)", _path, _mode, _type);
return 0;
}
int64_t new_pos = tell();
return ssi_size_t(new_pos - old_pos);
}
