Hash :
17752a6c
Author :
Thomas de Grivel
Date :
2020-03-04T14:03:48
Downgrade to C89 = ANSI C
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/*
* Copyright 2018 Thomas de Grivel <thoxdg@gmail.com> +33614550127
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include <math.h>
#include <stdio.h>
#include <strings.h>
#include "rtbuf.h"
#include "rtbuf_lib.h"
#include "rtbuf_signal.h"
#include "rtbuf_signal_type.h"
const double g_rtbuf_signal_sample_zero = 0.0;
const double g_rtbuf_signal_sample_half = 0.5;
const double g_rtbuf_signal_sample_one = 1.0;
const double g_rtbuf_signal_default_frequency = 220.0;
s_rtbuf_lib_proc_in g_rtbuf_signal_bandpass2_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 400.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ "qfactor", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 1000.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_bandpass2_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_delay_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "delay", RTBUF_SIGNAL_TYPE, 0.4, 0.0, RTBUF_SIGNAL_DELAY_MAX },
{ "feedback", RTBUF_SIGNAL_TYPE, 0.5, 0.0, 1.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_delay_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "in", RTBUF_SIGNAL_DELAY_TYPE },
{ "pos", "unsigned int" },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_equalizer10_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "amp32", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp64", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp128", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp256", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp512", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp1k", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp2k", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp4k", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp8k", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ "amp16k", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_equalizer10_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "signal32", RTBUF_SIGNAL_TYPE },
{ "signal64", RTBUF_SIGNAL_TYPE },
{ "signal128", RTBUF_SIGNAL_TYPE },
{ "signal256", RTBUF_SIGNAL_TYPE },
{ "signal512", RTBUF_SIGNAL_TYPE },
{ "signal1k", RTBUF_SIGNAL_TYPE },
{ "signal2k", RTBUF_SIGNAL_TYPE },
{ "signal4k", RTBUF_SIGNAL_TYPE },
{ "signal8k", RTBUF_SIGNAL_TYPE },
{ "signal16k", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y0_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y0_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y0_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y0_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y5_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y5_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y5_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y5_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y6_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y6_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y6_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y6_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y7_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y7_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y7_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y7_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y8_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y8_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y8_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y8_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y9_1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y9_2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y9_3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y9_4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_flanger_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "frequency", RTBUF_SIGNAL_TYPE, 0.5, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ "amplitude", RTBUF_SIGNAL_TYPE, 0.02, 0.0, 1.0 },
{ "delay", RTBUF_SIGNAL_TYPE, 0.0001, 0.0, 1.0 },
{ "feedback", RTBUF_SIGNAL_TYPE, 0.01, 0.0, 1.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_flanger_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "phase", "double" },
{ "in", RTBUF_SIGNAL_FLANGER_TYPE },
{ "pos", "unsigned int" },
{ "ds", "unsigned int" },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_hipass_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 8000.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_hipass_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_hipass2_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 8000.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_hipass2_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_hipass3_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 8000.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_hipass3_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_hipass4_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 8000.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_hipass4_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_hipass5_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 400.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_hipass5_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x5", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y5", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_lowpass_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 400.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_lowpass_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_lowpass2_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 400.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_lowpass2_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_lowpass3_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 400.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_lowpass3_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_lowpass4_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 400.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_lowpass4_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_lowpass5_in[] = {
{ "signal", RTBUF_SIGNAL_TYPE, 0.0, -1.0, 1.0 },
{ "cutoff", RTBUF_SIGNAL_TYPE, 400.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_lowpass5_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "x1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "x5", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y1", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y2", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y3", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y4", RTBUF_SIGNAL_SAMPLE_TYPE },
{ "y5", RTBUF_SIGNAL_SAMPLE_TYPE },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_sinus_in[] = {
{ "frequency", RTBUF_SIGNAL_TYPE, 220.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ "amplitude", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 1.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_sinus_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "phase", "double" },
{ 0, 0 } };
s_rtbuf_lib_proc_in g_rtbuf_signal_square_in[] = {
{ "frequency", RTBUF_SIGNAL_TYPE, 220.0, 0.0, RTBUF_SIGNAL_SAMPLERATE / 2.0 },
{ "amplitude", RTBUF_SIGNAL_TYPE, 1.0, 0.0, 1.0 },
{ "pulse", RTBUF_SIGNAL_TYPE, 0.5, 0.0, 1.0 },
{ 0, 0, 0.0, 0.0, 0.0 } };
s_rtbuf_lib_proc_out g_rtbuf_signal_square_out[] = {
{ "signal", RTBUF_SIGNAL_TYPE },
{ "phase", "double" },
{ 0, 0 } };
const char *rtbuf_lib_name = "signal";
unsigned long rtbuf_lib_ver = RTBUF_LIB_VER;
s_rtbuf_lib_proc rtbuf_lib_proc[] = {
{ "bandpass2", rtbuf_signal_bandpass2, rtbuf_signal_bandpass2_start, 0,
g_rtbuf_signal_bandpass2_in, g_rtbuf_signal_bandpass2_out },
{ "delay", rtbuf_signal_delay, rtbuf_signal_delay_start, 0,
g_rtbuf_signal_delay_in, g_rtbuf_signal_delay_out },
{ "equalizer10", rtbuf_signal_equalizer10, rtbuf_signal_equalizer10_start, 0,
g_rtbuf_signal_equalizer10_in, g_rtbuf_signal_equalizer10_out },
{ "flanger", rtbuf_signal_flanger, rtbuf_signal_flanger_start, 0,
g_rtbuf_signal_flanger_in, g_rtbuf_signal_flanger_out },
{ "hipass", rtbuf_signal_hipass, rtbuf_signal_hipass_start, 0,
g_rtbuf_signal_hipass_in, g_rtbuf_signal_hipass_out },
{ "hipass2", rtbuf_signal_hipass2, rtbuf_signal_hipass2_start, 0,
g_rtbuf_signal_hipass2_in, g_rtbuf_signal_hipass2_out },
{ "hipass3", rtbuf_signal_hipass3, rtbuf_signal_hipass3_start, 0,
g_rtbuf_signal_hipass3_in, g_rtbuf_signal_hipass3_out },
{ "hipass4", rtbuf_signal_hipass4, rtbuf_signal_hipass4_start, 0,
g_rtbuf_signal_hipass4_in, g_rtbuf_signal_hipass4_out },
{ "hipass5", rtbuf_signal_hipass5, rtbuf_signal_hipass5_start, 0,
g_rtbuf_signal_hipass5_in, g_rtbuf_signal_hipass5_out },
{ "lowpass", rtbuf_signal_lowpass, rtbuf_signal_lowpass_start, 0,
g_rtbuf_signal_lowpass_in, g_rtbuf_signal_lowpass_out },
{ "lowpass2", rtbuf_signal_lowpass2, rtbuf_signal_lowpass2_start, 0,
g_rtbuf_signal_lowpass2_in, g_rtbuf_signal_lowpass2_out },
{ "lowpass3", rtbuf_signal_lowpass3, rtbuf_signal_lowpass3_start, 0,
g_rtbuf_signal_lowpass3_in, g_rtbuf_signal_lowpass3_out },
{ "lowpass4", rtbuf_signal_lowpass4, rtbuf_signal_lowpass4_start, 0,
g_rtbuf_signal_lowpass4_in, g_rtbuf_signal_lowpass4_out },
{ "lowpass5", rtbuf_signal_lowpass5, rtbuf_signal_lowpass5_start, 0,
g_rtbuf_signal_lowpass5_in, g_rtbuf_signal_lowpass5_out },
{ "sinus", rtbuf_signal_sinus, rtbuf_signal_sinus_start, 0,
g_rtbuf_signal_sinus_in, g_rtbuf_signal_sinus_out },
{ "square", rtbuf_signal_square, rtbuf_signal_square_start, 0,
g_rtbuf_signal_square_in, g_rtbuf_signal_square_out },
{ 0, 0, 0, 0, 0, 0 } };
void rtbuf_signal_zero (t_rtbuf_signal_sample *signal)
{
assert(signal);
bzero(signal, sizeof(t_rtbuf_signal));
}
t_rtbuf_signal_sample
rtbuf_signal_sample (s_rtbuf *rtb,
unsigned int in,
t_rtbuf_signal_sample default_value)
{
s_rtbuf_binding *v;
assert(rtb);
assert(rtb->proc);
assert(in < rtb->proc->in_n);
v = &rtb->in[in];
if (v->rtb >= 0) {
s_rtbuf *src;
s_rtbuf_proc_out *out;
assert(v->rtb < RTBUF_MAX);
src = &g_rtbuf[v->rtb];
assert(src->data);
assert(src->proc);
assert(v->out < src->proc->out_n);
out = &src->proc->out[v->out];
assert(out->type);
if (out->type->t.bits >= sizeof(t_rtbuf_signal_sample) * 8) {
t_rtbuf_signal_sample *sample = (t_rtbuf_signal_sample*)
((char*) src->data + out->offset);
return *sample;
}
}
return default_value;
}
double rtbuf_signal_sample_from_sample (const double *signal,
unsigned int i)
{
(void) i;
assert(signal);
return *signal;
}
double rtbuf_signal_sample_from_signal (const double *signal,
unsigned int i)
{
assert(signal);
assert(i < RTBUF_SIGNAL_SAMPLES);
return signal[i];
}
void rtbuf_signal_fun (s_rtbuf *rtb,
unsigned int in,
s_rtbuf_signal_fun *rsf)
{
s_rtbuf_binding *v;
const double *default_value;
assert(rtb);
assert(rtb->proc);
assert(in < rtb->proc->in_n);
assert(rsf);
default_value = &rtb->proc->in[in].def;
rsf->signal = default_value;
rsf->sample_fun = rtbuf_signal_sample_from_sample;
v = &rtb->in[in];
if (v->rtb >= 0) {
s_rtbuf *dest;
s_rtbuf_proc_out *out;
assert(v->rtb < RTBUF_MAX);
dest = &g_rtbuf[v->rtb];
assert(dest->data);
assert(dest->proc);
assert(v->out < dest->proc->out_n);
out = &dest->proc->out[v->out];
assert(out->type);
if (out->type->t.bits >= sizeof(t_rtbuf_signal_sample) * 8)
rsf->signal = (double*)((char*) dest->data + out->offset);
if (out->type->t.bits >= sizeof(t_rtbuf_signal) * 8)
rsf->sample_fun = rtbuf_signal_sample_from_signal;
}
}
const double sqrt2_2 = M_SQRT2 * M_SQRT2;