const std::vector<float> &taps,
unsigned int filter_size)
{
- return gr_pfb_arb_resampler_ccf_sptr (new gr_pfb_arb_resampler_ccf (rate, taps,
- filter_size));
+ return gnuradio::get_initial_sptr(new gr_pfb_arb_resampler_ccf (rate, taps,
+ filter_size));
}
// Create an FIR filter for each channel and zero out the taps
std::vector<float> vtaps(0, d_int_rate);
- for(int i = 0; i < d_int_rate; i++) {
+ for(unsigned int i = 0; i < d_int_rate; i++) {
d_filters[i] = gr_fir_util::create_gr_fir_ccf(vtaps);
d_diff_filters[i] = gr_fir_util::create_gr_fir_ccf(vtaps);
}
create_diff_taps(taps, dtaps);
create_taps(taps, d_taps, d_filters);
create_taps(dtaps, d_dtaps, d_diff_filters);
+
+ set_relative_rate(rate);
}
gr_pfb_arb_resampler_ccf::~gr_pfb_arb_resampler_ccf ()
std::vector< std::vector<float> > &ourtaps,
std::vector<gr_fir_ccf*> &ourfilter)
{
- int i,j;
-
unsigned int ntaps = newtaps.size();
d_taps_per_filter = (unsigned int)ceil((double)ntaps/(double)d_int_rate);
}
// Partition the filter
- for(i = 0; i < d_int_rate; i++) {
+ for(unsigned int i = 0; i < d_int_rate; i++) {
// Each channel uses all d_taps_per_filter with 0's if not enough taps to fill out
ourtaps[d_int_rate-1-i] = std::vector<float>(d_taps_per_filter, 0);
- for(j = 0; j < d_taps_per_filter; j++) {
+ for(unsigned int j = 0; j < d_taps_per_filter; j++) {
ourtaps[d_int_rate - 1 - i][j] = tmp_taps[i + j*d_int_rate];
}
return 0; // history requirements may have changed.
}
- int i = 0, j, count = d_start_index;
+ int i = 0, count = d_start_index;
+ unsigned int j;
gr_complex o0, o1;
// Restore the last filter position
j = d_last_filter;
// produce output as long as we can and there are enough input samples
- while((i < noutput_items) && (count < ninput_items[0]-1)) {
+ int max_input = ninput_items[0]-(int)d_taps_per_filter;
+ while((i < noutput_items) && (count < max_input)) {
// start j by wrapping around mod the number of channels
while((j < d_int_rate) && (i < noutput_items)) {