csdr/fastddc.c

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/*
This software is part of libcsdr, a set of simple DSP routines for
Software Defined Radio.
Copyright (c) 2014, Andras Retzler <randras@sdr.hu>
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 copyright holder nor the
names of its 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 ANDRAS RETZLER 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.
*/
#include "fastddc.h"
//DDC implementation based on:
//http://www.3db-labs.com/01598092_MultibandFilterbank.pdf
inline int is_integer(float a) { return floorf(a) == a; }
int fastddc_init(fastddc_t* ddc, float transition_bw, int decimation, float shift_rate)
{
ddc->pre_decimation = 1; //this will be done in the frequency domain
ddc->post_decimation = decimation; //this will be done in the time domain
while( is_integer((float)ddc->post_decimation/2) && ddc->post_decimation/2 != 1)
{
ddc->post_decimation/=2;
ddc->pre_decimation*=2;
}
ddc->taps_min_length = firdes_filter_len(transition_bw); //his is the minimal number of taps to achieve the given transition_bw; we are likely to have more taps than this number.
ddc->taps_length = next_pow2(ceil(ddc->taps_min_length/(float)ddc->pre_decimation) * ddc->pre_decimation) + 1; //the number of taps must be a multiple of the decimation factor
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ddc->fft_size = next_pow2(ddc->taps_length * 4); //it is a good rule of thumb for performance (based on the article), but we should do benchmarks
while (ddc->fft_size<ddc->pre_decimation) ddc->fft_size*=2; //fft_size should be a multiple of pre_decimation.
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ddc->overlap_length = ddc->taps_length - 1;
ddc->input_size = ddc->fft_size - ddc->overlap_length;
ddc->fft_inv_size = ddc->fft_size / ddc->pre_decimation;
//Shift operation in the frequency domain: we can shift by a multiple of v.
ddc->v = ddc->fft_size/ddc->overlap_length; //overlap factor | +-1 ? (or maybe ceil() this?)
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int middlebin=ddc->fft_size / 2;
ddc->startbin = middlebin + middlebin * shift_rate * 2;
//fprintf(stderr, "ddc->startbin=%g\n",(float)ddc->startbin);
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ddc->startbin = ddc->v * round( ddc->startbin / (float)ddc->v );
//fprintf(stderr, "ddc->startbin=%g\n",(float)ddc->startbin);
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ddc->offsetbin = ddc->startbin - middlebin;
ddc->post_shift = shift_rate-((float)ddc->offsetbin/ddc->fft_size);
ddc->pre_shift = ddc->offsetbin/(float)ddc->fft_size;
ddc->dsadata = decimating_shift_addition_init(ddc->post_shift, ddc->post_decimation);
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//Overlap is scrapped, not added
ddc->scrap=ddc->overlap_length/ddc->pre_decimation; //TODO this is problematic sometimes! overlap_length = 401 :: scrap = 200
ddc->post_input_size=ddc->fft_inv_size-ddc->scrap;
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return ddc->fft_size<=2; //returns true on error
}
void fastddc_print(fastddc_t* ddc, char* source)
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{
fprintf(stderr,
"%s: fastddc_print_sizes(): (fft_size = %d) = (taps_length = %d) + (input_size = %d) - 1\n"
" overlap :: (overlap_length = %d) = taps_length - 1, taps_min_length = %d\n"
" decimation :: decimation = (pre_decimation = %d) * (post_decimation = %d), fft_inv_size = %d\n"
" shift :: startbin = %d, offsetbin = %d, v = %d, pre_shift = %g, post_shift = %g\n"
" o&s :: post_input_size = %d, scrap = %d\n"
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,
source, ddc->fft_size, ddc->taps_length, ddc->input_size,
ddc->overlap_length, ddc->taps_min_length,
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ddc->pre_decimation, ddc->post_decimation, ddc->fft_inv_size,
ddc->startbin, ddc->offsetbin, ddc->v, ddc->pre_shift, ddc->post_shift,
ddc->post_input_size, ddc->scrap );
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}
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void fft_swap_sides(complexf* io, int fft_size)
{
int middle=fft_size/2;
complexf temp;
for(int i=0;i<middle;i++)
{
iof(&temp,0)=iof(io,i);
qof(&temp,0)=qof(io,i);
iof(io,i)=iof(io,i+middle);
qof(io,i)=qof(io,i+middle);
iof(io,i+middle)=iof(&temp,0);
qof(io,i+middle)=qof(&temp,0);
}
}
decimating_shift_addition_status_t fastddc_inv_cc(complexf* input, complexf* output, fastddc_t* ddc, FFT_PLAN_T* plan_inverse, complexf* taps_fft, decimating_shift_addition_status_t shift_stat)
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{
//implements DDC by using the overlap & scrap method
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//TODO: +/-1s on overlap_size et al
//input shoud have ddc->fft_size number of elements
complexf* inv_input = plan_inverse->input;
complexf* inv_output = plan_inverse->output;
//Initialize buffers for inverse FFT to zero
for(int i=0;i<plan_inverse->size;i++)
{
iof(inv_input,i)=0;
qof(inv_input,i)=0;
}
//Alias & shift & filter at once
fft_swap_sides(input, ddc->fft_size); //TODO this is not very optimal, but now we stick with this slow solution until we got the algorithm working
//fprintf(stderr, " === fastddc_inv_cc() ===\n");
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for(int i=0;i<ddc->fft_size;i++)
{
int output_index = (ddc->fft_size+i-ddc->offsetbin)%plan_inverse->size;
int tap_index = i;
//fprintf(stderr, "output_index = %d , tap_index = %d, input index = %d\n", output_index, tap_index, i);
//cmultadd(inv_input+output_index, input+i, taps_fft+tap_index); //cmultadd(output, input1, input2): complex output += complex input1 * complex input 2
// (a+b*i)*(c+d*i) = (ac-bd)+(ad+bc)*i
// a = iof(input,i)
// b = qof(input,i)
// c = iof(taps_fft,i)
// d = qof(taps_fft,i)
iof(inv_input,output_index) += iof(input,i) * iof(taps_fft,i) - qof(input,i) * qof(taps_fft,i);
qof(inv_input,output_index) += iof(input,i) * qof(taps_fft,i) + qof(input,i) * iof(taps_fft,i);
//iof(inv_input,output_index) += iof(input,i); //no filter
//qof(inv_input,output_index) += qof(input,i);
}
//Normalize inv fft bins (now our output level is not higher than the input... but we may optimize this into the later loop when we normalize by size)
for(int i=0;i<plan_inverse->size;i++)
{
iof(inv_input,i)/=ddc->pre_decimation;
qof(inv_input,i)/=ddc->pre_decimation;
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}
fft_swap_sides(inv_input,plan_inverse->size);
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fft_execute(plan_inverse);
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//Normalize data
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for(int i=0;i<plan_inverse->size;i++) //@fastddc_inv_cc: normalize by size
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{
iof(inv_output,i)/=plan_inverse->size;
qof(inv_output,i)/=plan_inverse->size;
}
//Overlap is scrapped, not added
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//Shift correction
//shift_stat=decimating_shift_addition_cc(inv_output+ddc->scrap, output, ddc->post_input_size, ddc->dsadata, ddc->post_decimation, shift_stat);
shift_stat.output_size = ddc->post_input_size; //bypass shift correction
memcpy(output, inv_output+ddc->scrap, sizeof(complexf)*ddc->post_input_size);
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return shift_stat;
}