507 lines
16 KiB
C
507 lines
16 KiB
C
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/*
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* August 24, 1998
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* Copyright (C) 1998 Juergen Mueller And Sundry Contributors
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* This source code is freely redistributable and may be used for
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* any purpose. This copyright notice must be maintained.
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* Juergen Mueller And Sundry Contributors are not responsible for
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* the consequences of using this software.
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*/
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/*
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CHANGES
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- Adapted for fluidsynth, Peter Hanappe, March 2002
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- Variable delay line implementation using bandlimited
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interpolation, code reorganization: Markus Nentwig May 2002
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*/
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/*
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* Chorus effect.
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*
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* Flow diagram scheme for n delays ( 1 <= n <= MAX_CHORUS ):
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*
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* * gain-in ___
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* ibuff -----+--------------------------------------------->| |
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* | _________ | |
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* | | | * level 1 | |
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* +---->| delay 1 |----------------------------->| |
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* | |_________| | |
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* | /|\ | |
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* : | | |
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* : +-----------------+ +--------------+ | + |
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* : | Delay control 1 |<--| mod. speed 1 | | |
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* : +-----------------+ +--------------+ | |
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* | _________ | |
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* | | | * level n | |
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* +---->| delay n |----------------------------->| |
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* |_________| | |
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* /|\ |___|
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* | |
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* +-----------------+ +--------------+ | * gain-out
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* | Delay control n |<--| mod. speed n | |
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* +-----------------+ +--------------+ +----->obuff
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*
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*
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* The delay i is controlled by a sine or triangle modulation i ( 1 <= i <= n).
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*
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* The delay of each block is modulated between 0..depth ms
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*
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*/
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/* Variable delay line implementation
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* ==================================
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*
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* The modulated delay needs the value of the delayed signal between
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* samples. A lowpass filter is used to obtain intermediate values
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* between samples (bandlimited interpolation). The sample pulse
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* train is convoluted with the impulse response of the low pass
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* filter (sinc function). To make it work with a small number of
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* samples, the sinc function is windowed (Hamming window).
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*
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*/
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#include "fluid_chorus.h"
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#include "fluid_sys.h"
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#define MAX_CHORUS 99
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#define MAX_DELAY 100
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#define MAX_DEPTH 10
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#define MIN_SPEED_HZ 0.29
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#define MAX_SPEED_HZ 5
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/* Length of one delay line in samples:
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* Set through MAX_SAMPLES_LN2.
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* For example:
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* MAX_SAMPLES_LN2=12
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* => MAX_SAMPLES=pow(2,12)=4096
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* => MAX_SAMPLES_ANDMASK=4095
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*/
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#define MAX_SAMPLES_LN2 12
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#define MAX_SAMPLES (1 << (MAX_SAMPLES_LN2-1))
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#define MAX_SAMPLES_ANDMASK (MAX_SAMPLES-1)
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/* Interpolate how many steps between samples? Must be power of two
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For example: 8 => use a resolution of 256 steps between any two
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samples
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*/
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#define INTERPOLATION_SUBSAMPLES_LN2 8
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#define INTERPOLATION_SUBSAMPLES (1 << (INTERPOLATION_SUBSAMPLES_LN2-1))
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#define INTERPOLATION_SUBSAMPLES_ANDMASK (INTERPOLATION_SUBSAMPLES-1)
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/* Use how many samples for interpolation? Must be odd. '7' sounds
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relatively clean, when listening to the modulated delay signal
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alone. For a demo on aliasing try '1' With '3', the aliasing is
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still quite pronounced for some input frequencies
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*/
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#define INTERPOLATION_SAMPLES 5
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/* Private data for SKEL file */
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struct _fluid_chorus_t {
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int type;
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fluid_real_t depth_ms;
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fluid_real_t level;
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fluid_real_t speed_Hz;
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int number_blocks;
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fluid_real_t *chorusbuf;
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int counter;
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long phase[MAX_CHORUS];
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long modulation_period_samples;
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int *lookup_tab;
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fluid_real_t sample_rate;
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/* sinc lookup table */
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fluid_real_t sinc_table[INTERPOLATION_SAMPLES][INTERPOLATION_SUBSAMPLES];
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};
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static void fluid_chorus_triangle(int *buf, int len, int depth);
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static void fluid_chorus_sine(int *buf, int len, int depth);
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fluid_chorus_t*
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new_fluid_chorus(fluid_real_t sample_rate)
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{
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int i; int ii;
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fluid_chorus_t* chorus;
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chorus = FLUID_NEW(fluid_chorus_t);
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if (chorus == NULL) {
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fluid_log(FLUID_PANIC, "chorus: Out of memory");
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return NULL;
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}
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FLUID_MEMSET(chorus, 0, sizeof(fluid_chorus_t));
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chorus->sample_rate = sample_rate;
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/* Lookup table for the SI function (impulse response of an ideal low pass) */
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/* i: Offset in terms of whole samples */
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for (i = 0; i < INTERPOLATION_SAMPLES; i++){
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/* ii: Offset in terms of fractional samples ('subsamples') */
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for (ii = 0; ii < INTERPOLATION_SUBSAMPLES; ii++){
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/* Move the origin into the center of the table */
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double i_shifted = ((double) i- ((double) INTERPOLATION_SAMPLES) / 2.
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+ (double) ii / (double) INTERPOLATION_SUBSAMPLES);
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if (fabs(i_shifted) < 0.000001) {
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/* sinc(0) cannot be calculated straightforward (limit needed
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for 0/0) */
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chorus->sinc_table[i][ii] = (fluid_real_t)1.;
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} else {
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chorus->sinc_table[i][ii] = (fluid_real_t)sin(i_shifted * M_PI) / (M_PI * i_shifted);
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/* Hamming window */
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chorus->sinc_table[i][ii] *= (fluid_real_t)0.5 * (1.0 + cos(2.0 * M_PI * i_shifted / (fluid_real_t)INTERPOLATION_SAMPLES));
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};
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};
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};
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/* allocate lookup tables */
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chorus->lookup_tab = FLUID_ARRAY(int, (int) (chorus->sample_rate / MIN_SPEED_HZ));
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if (chorus->lookup_tab == NULL) {
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fluid_log(FLUID_PANIC, "chorus: Out of memory");
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goto error_recovery;
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}
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/* allocate sample buffer */
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chorus->chorusbuf = FLUID_ARRAY(fluid_real_t, MAX_SAMPLES);
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if (chorus->chorusbuf == NULL) {
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fluid_log(FLUID_PANIC, "chorus: Out of memory");
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goto error_recovery;
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}
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if (fluid_chorus_init(chorus) != FLUID_OK){
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goto error_recovery;
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};
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return chorus;
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error_recovery:
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delete_fluid_chorus(chorus);
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return NULL;
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}
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void
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delete_fluid_chorus(fluid_chorus_t* chorus)
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{
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if (chorus == NULL) {
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return;
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}
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if (chorus->chorusbuf != NULL) {
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FLUID_FREE(chorus->chorusbuf);
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}
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if (chorus->lookup_tab != NULL) {
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FLUID_FREE(chorus->lookup_tab);
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}
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FLUID_FREE(chorus);
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}
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int
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fluid_chorus_init(fluid_chorus_t* chorus)
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{
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int i;
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for (i = 0; i < MAX_SAMPLES; i++) {
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chorus->chorusbuf[i] = 0.0;
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}
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/* initialize the chorus with the default settings */
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fluid_chorus_set (chorus, FLUID_CHORUS_SET_ALL, FLUID_CHORUS_DEFAULT_N,
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FLUID_CHORUS_DEFAULT_LEVEL, FLUID_CHORUS_DEFAULT_SPEED,
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FLUID_CHORUS_DEFAULT_DEPTH, FLUID_CHORUS_MOD_SINE);
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return FLUID_OK;
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}
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void
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fluid_chorus_reset(fluid_chorus_t* chorus)
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{
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fluid_chorus_init(chorus);
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}
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/**
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* Set one or more chorus parameters.
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* @param chorus Chorus instance
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* @param set Flags indicating which chorus parameters to set (#fluid_chorus_set_t)
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* @param nr Chorus voice count (0-99, CPU time consumption proportional to
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* this value)
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* @param level Chorus level (0.0-10.0)
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* @param speed Chorus speed in Hz (0.29-5.0)
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* @param depth_ms Chorus depth (max value depends on synth sample rate,
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* 0.0-21.0 is safe for sample rate values up to 96KHz)
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* @param type Chorus waveform type (#fluid_chorus_mod)
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*/
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void
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fluid_chorus_set(fluid_chorus_t* chorus, int set, int nr, float level,
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float speed, float depth_ms, int type)
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{
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int modulation_depth_samples;
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int i;
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if (set & FLUID_CHORUS_SET_NR) chorus->number_blocks = nr;
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if (set & FLUID_CHORUS_SET_LEVEL) chorus->level = level;
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if (set & FLUID_CHORUS_SET_SPEED) chorus->speed_Hz = speed;
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if (set & FLUID_CHORUS_SET_DEPTH) chorus->depth_ms = depth_ms;
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if (set & FLUID_CHORUS_SET_TYPE) chorus->type = type;
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if (chorus->number_blocks < 0) {
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fluid_log(FLUID_WARN, "chorus: number blocks must be >=0! Setting value to 0.");
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chorus->number_blocks = 0;
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} else if (chorus->number_blocks > MAX_CHORUS) {
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fluid_log(FLUID_WARN, "chorus: number blocks larger than max. allowed! Setting value to %d.",
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MAX_CHORUS);
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chorus->number_blocks = MAX_CHORUS;
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}
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if (chorus->speed_Hz < MIN_SPEED_HZ) {
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fluid_log(FLUID_WARN, "chorus: speed is too low (min %f)! Setting value to min.",
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(double) MIN_SPEED_HZ);
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chorus->speed_Hz = MIN_SPEED_HZ;
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} else if (chorus->speed_Hz > MAX_SPEED_HZ) {
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fluid_log(FLUID_WARN, "chorus: speed must be below %f Hz! Setting value to max.",
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(double) MAX_SPEED_HZ);
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chorus->speed_Hz = MAX_SPEED_HZ;
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}
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if (chorus->depth_ms < 0.0) {
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fluid_log(FLUID_WARN, "chorus: depth must be positive! Setting value to 0.");
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chorus->depth_ms = 0.0;
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}
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/* Depth: Check for too high value through modulation_depth_samples. */
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if (chorus->level < 0.0) {
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fluid_log(FLUID_WARN, "chorus: level must be positive! Setting value to 0.");
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chorus->level = 0.0;
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} else if (chorus->level > 10) {
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fluid_log(FLUID_WARN, "chorus: level must be < 10. A reasonable level is << 1! "
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"Setting it to 0.1.");
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chorus->level = 0.1;
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}
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/* The modulating LFO goes through a full period every x samples: */
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chorus->modulation_period_samples = chorus->sample_rate / chorus->speed_Hz;
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/* The variation in delay time is x: */
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modulation_depth_samples = (int)
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(chorus->depth_ms / 1000.0 /* convert modulation depth in ms to s*/
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* chorus->sample_rate);
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if (modulation_depth_samples > MAX_SAMPLES) {
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fluid_log(FLUID_WARN, "chorus: Too high depth. Setting it to max (%d).", MAX_SAMPLES);
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modulation_depth_samples = MAX_SAMPLES;
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}
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/* initialize LFO table */
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if (chorus->type == FLUID_CHORUS_MOD_SINE) {
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fluid_chorus_sine(chorus->lookup_tab, chorus->modulation_period_samples,
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modulation_depth_samples);
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} else if (chorus->type == FLUID_CHORUS_MOD_TRIANGLE) {
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fluid_chorus_triangle(chorus->lookup_tab, chorus->modulation_period_samples,
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modulation_depth_samples);
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} else {
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fluid_log(FLUID_WARN, "chorus: Unknown modulation type. Using sinewave.");
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chorus->type = FLUID_CHORUS_MOD_SINE;
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fluid_chorus_sine(chorus->lookup_tab, chorus->modulation_period_samples,
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modulation_depth_samples);
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}
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for (i = 0; i < chorus->number_blocks; i++) {
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/* Set the phase of the chorus blocks equally spaced */
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chorus->phase[i] = (int) ((double) chorus->modulation_period_samples
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* (double) i / (double) chorus->number_blocks);
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}
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/* Start of the circular buffer */
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chorus->counter = 0;
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}
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void fluid_chorus_processmix(fluid_chorus_t* chorus, fluid_real_t *in,
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fluid_real_t *left_out, fluid_real_t *right_out)
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{
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int sample_index;
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int i;
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fluid_real_t d_in, d_out;
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for (sample_index = 0; sample_index < FLUID_BUFSIZE; sample_index++) {
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d_in = in[sample_index];
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d_out = 0.0f;
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# if 0
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/* Debug: Listen to the chorus signal only */
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left_out[sample_index]=0;
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right_out[sample_index]=0;
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#endif
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/* Write the current sample into the circular buffer */
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chorus->chorusbuf[chorus->counter] = d_in;
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for (i = 0; i < chorus->number_blocks; i++) {
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int ii;
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/* Calculate the delay in subsamples for the delay line of chorus block nr. */
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/* The value in the lookup table is so, that this expression
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* will always be positive. It will always include a number of
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* full periods of MAX_SAMPLES*INTERPOLATION_SUBSAMPLES to
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* remain positive at all times. */
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int pos_subsamples = (INTERPOLATION_SUBSAMPLES * chorus->counter
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- chorus->lookup_tab[chorus->phase[i]]);
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int pos_samples = pos_subsamples/INTERPOLATION_SUBSAMPLES;
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/* modulo divide by INTERPOLATION_SUBSAMPLES */
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pos_subsamples &= INTERPOLATION_SUBSAMPLES_ANDMASK;
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for (ii = 0; ii < INTERPOLATION_SAMPLES; ii++){
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/* Add the delayed signal to the chorus sum d_out Note: The
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* delay in the delay line moves backwards for increasing
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* delay!*/
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/* The & in chorusbuf[...] is equivalent to a division modulo
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MAX_SAMPLES, only faster. */
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d_out += chorus->chorusbuf[pos_samples & MAX_SAMPLES_ANDMASK]
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* chorus->sinc_table[ii][pos_subsamples];
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pos_samples--;
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};
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/* Cycle the phase of the modulating LFO */
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chorus->phase[i]++;
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chorus->phase[i] %= (chorus->modulation_period_samples);
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} /* foreach chorus block */
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d_out *= chorus->level;
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/* Add the chorus sum d_out to output */
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left_out[sample_index] += d_out;
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right_out[sample_index] += d_out;
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/* Move forward in circular buffer */
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chorus->counter++;
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chorus->counter %= MAX_SAMPLES;
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} /* foreach sample */
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}
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/* Duplication of code ... (replaces sample data instead of mixing) */
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void fluid_chorus_processreplace(fluid_chorus_t* chorus, fluid_real_t *in,
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fluid_real_t *left_out, fluid_real_t *right_out)
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{
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int sample_index;
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int i;
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fluid_real_t d_in, d_out;
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for (sample_index = 0; sample_index < FLUID_BUFSIZE; sample_index++) {
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d_in = in[sample_index];
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d_out = 0.0f;
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# if 0
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/* Debug: Listen to the chorus signal only */
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left_out[sample_index]=0;
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right_out[sample_index]=0;
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#endif
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/* Write the current sample into the circular buffer */
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chorus->chorusbuf[chorus->counter] = d_in;
|
||
|
|
||
|
for (i = 0; i < chorus->number_blocks; i++) {
|
||
|
int ii;
|
||
|
/* Calculate the delay in subsamples for the delay line of chorus block nr. */
|
||
|
|
||
|
/* The value in the lookup table is so, that this expression
|
||
|
* will always be positive. It will always include a number of
|
||
|
* full periods of MAX_SAMPLES*INTERPOLATION_SUBSAMPLES to
|
||
|
* remain positive at all times. */
|
||
|
int pos_subsamples = (INTERPOLATION_SUBSAMPLES * chorus->counter
|
||
|
- chorus->lookup_tab[chorus->phase[i]]);
|
||
|
|
||
|
int pos_samples = pos_subsamples / INTERPOLATION_SUBSAMPLES;
|
||
|
|
||
|
/* modulo divide by INTERPOLATION_SUBSAMPLES */
|
||
|
pos_subsamples &= INTERPOLATION_SUBSAMPLES_ANDMASK;
|
||
|
|
||
|
for (ii = 0; ii < INTERPOLATION_SAMPLES; ii++){
|
||
|
/* Add the delayed signal to the chorus sum d_out Note: The
|
||
|
* delay in the delay line moves backwards for increasing
|
||
|
* delay!*/
|
||
|
|
||
|
/* The & in chorusbuf[...] is equivalent to a division modulo
|
||
|
MAX_SAMPLES, only faster. */
|
||
|
d_out += chorus->chorusbuf[pos_samples & MAX_SAMPLES_ANDMASK]
|
||
|
* chorus->sinc_table[ii][pos_subsamples];
|
||
|
|
||
|
pos_samples--;
|
||
|
};
|
||
|
/* Cycle the phase of the modulating LFO */
|
||
|
chorus->phase[i]++;
|
||
|
chorus->phase[i] %= (chorus->modulation_period_samples);
|
||
|
} /* foreach chorus block */
|
||
|
|
||
|
d_out *= chorus->level;
|
||
|
|
||
|
/* Store the chorus sum d_out to output */
|
||
|
left_out[sample_index] = d_out;
|
||
|
right_out[sample_index] = d_out;
|
||
|
|
||
|
/* Move forward in circular buffer */
|
||
|
chorus->counter++;
|
||
|
chorus->counter %= MAX_SAMPLES;
|
||
|
|
||
|
} /* foreach sample */
|
||
|
}
|
||
|
|
||
|
/* Purpose:
|
||
|
*
|
||
|
* Calculates a modulation waveform (sine) Its value ( modulo
|
||
|
* MAXSAMPLES) varies between 0 and depth*INTERPOLATION_SUBSAMPLES.
|
||
|
* Its period length is len. The waveform data will be used modulo
|
||
|
* MAXSAMPLES only. Since MAXSAMPLES is substracted from the waveform
|
||
|
* a couple of times here, the resulting (current position in
|
||
|
* buffer)-(waveform sample) will always be positive.
|
||
|
*/
|
||
|
static void
|
||
|
fluid_chorus_sine(int *buf, int len, int depth)
|
||
|
{
|
||
|
int i;
|
||
|
double val;
|
||
|
|
||
|
for (i = 0; i < len; i++) {
|
||
|
val = sin((double) i / (double)len * 2.0 * M_PI);
|
||
|
buf[i] = (int) ((1.0 + val) * (double) depth / 2.0 * (double) INTERPOLATION_SUBSAMPLES);
|
||
|
buf[i] -= 3* MAX_SAMPLES * INTERPOLATION_SUBSAMPLES;
|
||
|
// printf("%i %i\n",i,buf[i]);
|
||
|
}
|
||
|
}
|
||
|
|
||
|
/* Purpose:
|
||
|
* Calculates a modulation waveform (triangle)
|
||
|
* See fluid_chorus_sine for comments.
|
||
|
*/
|
||
|
static void
|
||
|
fluid_chorus_triangle(int *buf, int len, int depth)
|
||
|
{
|
||
|
int i=0;
|
||
|
int ii=len-1;
|
||
|
double val;
|
||
|
double val2;
|
||
|
|
||
|
while (i <= ii){
|
||
|
val = i * 2.0 / len * (double)depth * (double) INTERPOLATION_SUBSAMPLES;
|
||
|
val2= (int) (val + 0.5) - 3 * MAX_SAMPLES * INTERPOLATION_SUBSAMPLES;
|
||
|
buf[i++] = (int) val2;
|
||
|
buf[ii--] = (int) val2;
|
||
|
}
|
||
|
}
|