#include #include #include #include #include #include #include // Features // #define PREEMPHASIS #define LPF #define SAMPLE_RATE 192000 // Don't go lower than 108 KHz, becuase it (53000*2) and (38000+15000) #define INPUT_DEVICE "real_real_tx_audio_input.monitor" #define OUTPUT_DEVICE "alsa_output.platform-soc_sound.stereo-fallback" #define BUFFER_SIZE 512 #define CLIPPER_THRESHOLD 0.425 // Adjust this as needed #define MONO_VOLUME 0.45f // L+R Signal #define PILOT_VOLUME 0.0225f // 19 KHz Pilot #define STEREO_VOLUME 0.35f // L-R signal #ifdef PREEMPHASIS #define PREEMPHASIS_TAU 0.00005 // 50 microseconds, use 0.000075 if in america #endif #ifdef LPF #define LPF_CUTOFF 15000 #endif volatile sig_atomic_t to_run = 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 } } 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]; } } #define FIR_PHASES 32 #define FIR_TAPS 32 #define PI 3.14159265358979323846 #define M_2PI (3.14159265358979323846 * 2.0) // Track phase continuously to maintain frequency accuracy typedef struct { float phase; float phase_increment; } Oscillator; void init_oscillator(Oscillator *osc, float frequency, float sample_rate) { osc->phase = 0.0f; osc->phase_increment = (M_2PI * frequency) / sample_rate; } float get_next_sample(Oscillator *osc) { float sample = sinf(osc->phase); osc->phase += osc->phase_increment; if (osc->phase >= M_2PI) { osc->phase -= M_2PI; } return sample; } #ifdef PREEMPHASIS typedef struct { float alpha; float prev_sample; } PreEmphasis; void init_pre_emphasis(PreEmphasis *pe) { pe->prev_sample = 0.0f; pe->alpha = exp(-1 / (PREEMPHASIS_TAU * SAMPLE_RATE)); } float apply_pre_emphasis(PreEmphasis *pe, float sample) { float audio = sample-pe->alpha*pe->prev_sample; pe->prev_sample = audio; return audio*2; } #endif #ifdef LPF typedef struct { float low_pass_fir[FIR_PHASES][FIR_TAPS]; float sample_buffer[FIR_TAPS]; int buffer_index; } LowPassFilter; void init_low_pass_filter(LowPassFilter *lp) { for (int i = 0; i < FIR_TAPS; i++) { for (int j = 0; j < FIR_PHASES; j++) { int mi = i * FIR_PHASES + j + 1; float sincpos = mi - (((FIR_TAPS * FIR_PHASES) + 1.0f) / 2.0f); float firlowpass = (sincpos == 0.0f) ? 1.0f : sinf(M_2PI * LPF_CUTOFF * sincpos / SAMPLE_RATE) / (PI * sincpos); float window = 0.54f - 0.46f * cosf(M_2PI * mi / (FIR_TAPS * FIR_PHASES)); // Hamming window lp->low_pass_fir[j][i] = firlowpass * window; } } memset(lp->sample_buffer, 0, sizeof(lp->sample_buffer)); lp->buffer_index = 0; } float apply_low_pass_filter(LowPassFilter *lp, float sample) { // Update the sample buffer lp->sample_buffer[lp->buffer_index] = sample; lp->buffer_index = (lp->buffer_index + 1) % FIR_TAPS; // Apply the filter float result = 0.0f; int index = lp->buffer_index; for (int i = 0; i < FIR_TAPS; i++) { result += lp->low_pass_fir[0][i] * lp->sample_buffer[index]; index = (index + 1) % FIR_TAPS; } return result*6; } #endif static void stop(int signum) { (void)signum; printf("\nReceived stop signal. Cleaning up...\n"); to_run = 0; } int main() { printf("STCode : Stereo encoder made by radio95 (with help of ChatGPT and Claude, thanks!)\n"); const float PILOT_FREQ = 19000.0f; // Don't touch this const float STEREO_FREQ = 38000.0f; // This too // Define formats and buffer atributes pa_sample_spec stereo_format = { .format = PA_SAMPLE_FLOAT32NE, //Float32 NE, or Float32 Native Endian, the float in c uses the endianess of your pc, or native endian, and float is float32, and double is float64 .channels = 2, .rate = SAMPLE_RATE // Same sample rate makes it easy, leave the resampling to pipewire, it should know better }; pa_sample_spec mono_format = { .format = PA_SAMPLE_FLOAT32NE, .channels = 1, .rate = SAMPLE_RATE }; pa_buffer_attr input_buffer_atr = { .maxlength = 4096, // You can lower this to 512, but this is fine, it's sub-second delay, you're probably not gonna notice unless you're looking for it .fragsize = 2048 }; pa_buffer_attr output_buffer_atr = { .maxlength = 4096, .tlength = 2048, .prebuf = 0 }; printf("Connecting to input device... (%s)\n", INPUT_DEVICE); pa_simple *input_device = pa_simple_new( NULL, "StereoEncoder", PA_STREAM_RECORD, INPUT_DEVICE, "Audio Input", &stereo_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, "StereoEncoder", PA_STREAM_PLAYBACK, OUTPUT_DEVICE, "MPX", &mono_format, NULL, &output_buffer_atr, NULL ); if (!output_device) { fprintf(stderr, "Error: cannot open output device.\n"); pa_simple_free(input_device); return 1; } Oscillator pilot_osc, stereo_osc; init_oscillator(&pilot_osc, PILOT_FREQ, SAMPLE_RATE); init_oscillator(&stereo_osc, STEREO_FREQ, SAMPLE_RATE); #ifdef PREEMPHASIS PreEmphasis preemp_l, preemp_r; init_pre_emphasis(&preemp_l); init_pre_emphasis(&preemp_r); #endif #ifdef LPF LowPassFilter lpf_l, lpf_r; init_low_pass_filter(&lpf_l); init_low_pass_filter(&lpf_r); #endif signal(SIGINT, stop); signal(SIGTERM, stop); float input[BUFFER_SIZE*2]; // Input from device, interleaved stereo 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 mpx[BUFFER_SIZE]; // MPX, this goes to the output while (to_run) { if (pa_simple_read(input_device, input, sizeof(input), NULL) < 0) { fprintf(stderr, "Error reading from input device.\n"); break; } uninterleave(input, left, right, BUFFER_SIZE*2); for (int i = 0; i < BUFFER_SIZE; i++) { float pilot = get_next_sample(&pilot_osc); float stereo_carrier = get_next_sample(&stereo_osc); 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; mpx[i] = mono * MONO_VOLUME + pilot * PILOT_VOLUME + (stereo * stereo_carrier) * STEREO_VOLUME; } if (pa_simple_write(output_device, mpx, sizeof(mpx), NULL) < 0) { fprintf(stderr, "Error writing to output device.\n"); break; } } printf("Cleaning up...\n"); pa_simple_free(input_device); pa_simple_free(output_device); return 0; }