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7096a6e5727674959ef0266b8f6c38b7477cb024
fm95/satire/stereo_sca_mod.c
KubaPro010 7096a6e572 light changes
2025-01-23 10:03:39 +01:00

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#include <stdio.h>
#include <pulse/simple.h>
#include <pulse/error.h>
#include <stdlib.h>
#include <math.h>
#include <stdint.h>
#include <signal.h>
#include <string.h>
#include "../lib/constants.h"
#include "../lib/oscillator.h"
#include "../lib/filters.h"
#include "../lib/fm_modulator.h"
#include "options.h"
#define SAMPLE_RATE 192000
#define INPUT_DEVICE "SCA.monitor"
#define OUTPUT_DEVICE "alsa_output.platform-soc_sound.stereo-fallback"
#define BUFFER_SIZE 512
#define CLIPPER_THRESHOLD 0.75 // Adjust this as needed, this also limits deviation, so if you set this to 0.5 then the deviation will be limited to half
#define MONO_VOLUME 0.075f // Mono Volume
#define STEREO_VOLUME 0.025f // Stereo Volume
#ifdef PREEMPHASIS
#define PREEMPHASIS_TAU 0.00005 // 50 microseconds, use 0.000075 if in america
#endif
#ifdef LPF
#define LPF_CUTOFF 8000
#endif
volatile sig_atomic_t to_run = 1;
void uninterleave(const float *input, float *left, float *right, size_t num_samples) {
// For stereo, usually it is like this: LEFT RIGHT LEFT RIGHT LEFT RIGHT so this is used to get LEFT LEFT LEFT and RIGHT RIGHT RIGHT
for (size_t i = 0; i < num_samples/2; i++) {
left[i] = input[i * 2];
right[i] = input[i * 2 + 1];
}
}
float clip(float sample) {
if (sample > CLIPPER_THRESHOLD) {
return CLIPPER_THRESHOLD; // Clip to the upper threshold
} else if (sample < -CLIPPER_THRESHOLD) {
return -CLIPPER_THRESHOLD; // Clip to the lower threshold
} else {
return sample; // No clipping
}
}
static void stop(int signum) {
(void)signum;
printf("\nReceived stop signal. Cleaning up...\n");
to_run = 0;
}
int main() {
printf("StereoSCAMod : Stereo SCA Modulator (based on the SCA encoder SCAMod) made by radio95 (with help of ChatGPT and Claude, thanks!)\n");
// Define formats and buffer atributes
pa_sample_spec mono_audio_format = {
.format = PA_SAMPLE_FLOAT32LE,
.channels = 1,
.rate = SAMPLE_RATE // Same sample rate makes it easy, leave the resampling to pipewire, it should know better
};
pa_sample_spec stereo_audio_format = {
.format = PA_SAMPLE_FLOAT32LE,
.channels = 2,
.rate = SAMPLE_RATE // Same sample rate makes it easy, leave the resampling to pipewire, it should know better
};
pa_buffer_attr input_buffer_atr = {
.maxlength = buffer_maxlength,
.fragsize = buffer_tlength_fragsize
};
pa_buffer_attr output_buffer_atr = {
.maxlength = buffer_maxlength,
.tlength = buffer_tlength_fragsize,
.prebuf = buffer_prebuf
};
printf("Connecting to input device... (%s)\n", INPUT_DEVICE);
pa_simple *input_device = pa_simple_new(
NULL,
"StereoSCAMod",
PA_STREAM_RECORD,
INPUT_DEVICE,
"Audio Input",
&stereo_audio_format,
NULL,
&input_buffer_atr,
NULL
);
if (!input_device) {
fprintf(stderr, "Error: cannot open input device.\n");
return 1;
}
printf("Connecting to output device... (%s)\n", OUTPUT_DEVICE);
pa_simple *output_device = pa_simple_new(
NULL,
"StereoSCAMod",
PA_STREAM_PLAYBACK,
OUTPUT_DEVICE,
"Signal",
&mono_audio_format,
NULL,
&output_buffer_atr,
NULL
);
if (!output_device) {
fprintf(stderr, "Error: cannot open output device.\n");
pa_simple_free(input_device);
return 1;
}
FMModulator mod_mono, mod_stereo;
init_fm_modulator(&mod_mono, 67000, 6000, SAMPLE_RATE);
init_fm_modulator(&mod_stereo, 80000, 6000, SAMPLE_RATE);
#ifdef PREEMPHASIS
ResistorCapacitor preemp_l, preemp_r;
init_rc_tau(&preemp_l, PREEMPHASIS_TAU, SAMPLE_RATE);
init_rc_tau(&preemp_r, PREEMPHASIS_TAU, SAMPLE_RATE);
#endif
#ifdef LPF
ResistorCapacitor lpf_l, lpf_r;
init_low_pass_filter(&lpf_l, LPF_CUTOFF, SAMPLE_RATE);
init_low_pass_filter(&lpf_r, LPF_CUTOFF, SAMPLE_RATE);
#endif
signal(SIGINT, stop);
signal(SIGTERM, stop);
int pulse_error;
float input[BUFFER_SIZE*2]; // Input from device
float left[BUFFER_SIZE+64], right[BUFFER_SIZE+64]; // Audio, same thing as in input but ininterleaved, ai told be there could be a buffer overflow here
float signal[BUFFER_SIZE]; // this goes to the output
while (to_run) {
if (pa_simple_read(input_device, input, sizeof(input), &pulse_error) < 0) {
fprintf(stderr, "Error reading from input device: %s\n", pa_strerror(pulse_error));
to_run = 0;
break;
}
uninterleave(input, left, right, BUFFER_SIZE*2);
for (int i = 0; i < BUFFER_SIZE; i++) {
float l_in = left[i];
float r_in = right[i];
#ifdef PREEMPHASIS
#ifdef LPF
float lowpassed_left = apply_low_pass_filter(&lpf_l, l_in);
float lowpassed_right = apply_low_pass_filter(&lpf_r, r_in);
float preemphasized_left = apply_pre_emphasis(&preemp_l, lowpassed_left);
float preemphasized_right = apply_pre_emphasis(&preemp_r, lowpassed_right);
float current_left_input = clip(preemphasized_left);
float current_right_input = clip(preemphasized_right);
#else
float preemphasized_left = apply_pre_emphasis(&preemp_l, l_in);
float preemphasized_right = apply_pre_emphasis(&preemp_r, r_in);
float current_left_input = clip(preemphasized_left);
float current_right_input = clip(preemphasized_right);
#endif
#else
#ifdef LPF
float lowpassed_left = apply_low_pass_filter(&lpf_l, l_in);
float lowpassed_right = apply_low_pass_filter(&lpf_r, r_in);
float current_left_input = clip(lowpassed_left);
float current_right_input = clip(lowpassed_right);
#else
float current_left_input = clip(l_in);
float current_right_input = clip(r_in);
#endif
#endif
float mono = (current_left_input+current_right_input)/2.0f;
float stereo = (current_left_input-current_right_input)/2.0f;
signal[i] = modulate_fm(&mod_mono, mono)*MONO_VOLUME+
modulate_fm(&mod_stereo, stereo)*STEREO_VOLUME;
}
if (pa_simple_write(output_device, signal, sizeof(signal), &pulse_error) < 0) {
fprintf(stderr, "Error writing to output device: %s\n", pa_strerror(pulse_error));
to_run = 0;
break;
}
}
printf("Cleaning up...\n");
pa_simple_free(input_device);
pa_simple_free(output_device);
return 0;
}
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