#define _XOPEN_SOURCE_EXTENDED #include #ifdef HAVE_ALLOCA_H #include #else #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "debug.h" #include "util.h" #ifdef NCURSES #include "output/terminal_bcircle.h" #include "output/terminal_ncurses.h" #include #endif #include "output/raw.h" #include "output/terminal_noncurses.h" #include "input/alsa.h" #include "input/common.h" #include "input/fifo.h" #include "input/portaudio.h" #include "input/pulse.h" #include "input/shmem.h" #include "input/sndio.h" #include "config.h" #ifdef __GNUC__ // curses.h or other sources may already define #undef GCC_UNUSED #define GCC_UNUSED __attribute__((unused)) #else #define GCC_UNUSED /* nothing */ #endif #define LEFT_CHANNEL 1 #define RIGHT_CHANNEL 2 // struct termios oldtio, newtio; // int M = 8 * 1024; // used by sig handler // needs to know output mode in orer to clean up terminal int output_mode; // whether we should reload the config or not int should_reload = 0; // whether we should only reload colors or not int reload_colors = 0; // these variables are used only in main, but making them global // will allow us to not free them on exit without ASan complaining struct config_params p; fftw_complex *out_bass_l, *out_bass_r; fftw_plan p_bass_l, p_bass_r; fftw_complex *out_mid_l, *out_mid_r; fftw_plan p_mid_l, p_mid_r; fftw_complex *out_treble_l, *out_treble_r; fftw_plan p_treble_l, p_treble_r; // general: cleanup void cleanup(void) { if (output_mode == 1 || output_mode == 2) { #ifdef NCURSES cleanup_terminal_ncurses(); #else ; #endif } else if (output_mode == 3) { cleanup_terminal_noncurses(); } } // general: handle signals void sig_handler(int sig_no) { if (sig_no == SIGUSR1) { should_reload = 1; return; } if (sig_no == SIGUSR2) { reload_colors = 1; return; } cleanup(); if (sig_no == SIGINT) { printf("CTRL-C pressed -- goodbye\n"); } signal(sig_no, SIG_DFL); raise(sig_no); } #ifdef ALSA static bool is_loop_device_for_sure(const char *text) { const char *const LOOPBACK_DEVICE_PREFIX = "hw:Loopback,"; return strncmp(text, LOOPBACK_DEVICE_PREFIX, strlen(LOOPBACK_DEVICE_PREFIX)) == 0; } static bool directory_exists(const char *path) { DIR *const dir = opendir(path); if (dir == NULL) return false; closedir(dir); return true; } #endif int *separate_freq_bands(int FFTbassbufferSize, fftw_complex out_bass[FFTbassbufferSize / 2 + 1], int FFTmidbufferSize, fftw_complex out_mid[FFTmidbufferSize / 2 + 1], int FFTtreblebufferSize, fftw_complex out_treble[FFTtreblebufferSize / 2 + 1], int bass_cut_off_bar, int treble_cut_off_bar, int bars, int lcf[200], int hcf[200], double k[200], int channel, double sens, double ignore) { int o, i; double peak[201]; static int fl[200]; static int fr[200]; double y[FFTbassbufferSize / 2 + 1]; double temp; // process: separate frequency bands for (o = 0; o < bars; o++) { peak[o] = 0; i = 0; // process: get peaks for (i = lcf[o]; i <= hcf[o]; i++) { if (o <= bass_cut_off_bar) { y[i] = hypot(out_bass[i][0], out_bass[i][1]); } else if (o > bass_cut_off_bar && o <= treble_cut_off_bar) { y[i] = hypot(out_mid[i][0], out_mid[i][1]); } else if (o > treble_cut_off_bar) { y[i] = hypot(out_treble[i][0], out_treble[i][1]); } peak[o] += y[i]; // adding upp band } peak[o] = peak[o] / (hcf[o] - lcf[o] + 1); // getting average temp = peak[o] * sens * k[o]; // multiplying with k and sens // printf("%d peak o: %f * sens: %f * k: %f = f: %f\n", o, peak[o], sens, k[o], temp); if (temp <= ignore) temp = 0; if (channel == LEFT_CHANNEL) fl[o] = temp; else fr[o] = temp; } if (channel == LEFT_CHANNEL) return fl; else return fr; } int *monstercat_filter(int *f, int bars, int waves, double monstercat) { int z; // process [smoothing]: monstercat-style "average" int m_y, de; if (waves > 0) { for (z = 0; z < bars; z++) { // waves f[z] = f[z] / 1.25; // if (f[z] < 1) f[z] = 1; for (m_y = z - 1; m_y >= 0; m_y--) { de = z - m_y; f[m_y] = max(f[z] - pow(de, 2), f[m_y]); } for (m_y = z + 1; m_y < bars; m_y++) { de = m_y - z; f[m_y] = max(f[z] - pow(de, 2), f[m_y]); } } } else if (monstercat > 0) { for (z = 0; z < bars; z++) { // if (f[z] < 1)f[z] = 1; for (m_y = z - 1; m_y >= 0; m_y--) { de = z - m_y; f[m_y] = max(f[z] / pow(monstercat, de), f[m_y]); } for (m_y = z + 1; m_y < bars; m_y++) { de = m_y - z; f[m_y] = max(f[z] / pow(monstercat, de), f[m_y]); } } } return f; } // general: entry point int main(int argc, char **argv) { // general: define variables pthread_t p_thread; int thr_id GCC_UNUSED; float fc[200]; float fre[200]; int f[200], lcf[200], hcf[200]; int *fl, *fr; int fmem[200]; int flast[200]; int flastd[200]; int sleep = 0; int i, n, o, height, h, w, c, rest, inAtty, fp, fptest, rc; bool silence; // int cont = 1; int fall[200]; // float temp; float fpeak[200]; double k[200]; float g; struct timespec req = {.tv_sec = 0, .tv_nsec = 0}; char configPath[PATH_MAX]; char *usage = "\n\ Usage : " PACKAGE " [options]\n\ Visualize audio input in terminal. \n\ \n\ Options:\n\ -p path to config file\n\ -v print version\n\ \n\ Keys:\n\ Up Increase sensitivity\n\ Down Decrease sensitivity\n\ Left Decrease number of bars\n\ Right Increase number of bars\n\ r Reload config\n\ c Reload colors only\n\ f Cycle foreground color\n\ b Cycle background color\n\ q Quit\n\ \n\ as of 0.4.0 all options are specified in config file, see in '/home/username/.config/cava/' \n"; char ch = '\0'; int bars = 25; int sourceIsAuto = 1; double smh; struct audio_data audio; memset(&audio, 0, sizeof(audio)); // int maxvalue = 0; // general: console title printf("%c]0;%s%c", '\033', PACKAGE, '\007'); configPath[0] = '\0'; setlocale(LC_ALL, ""); // general: handle Ctrl+C struct sigaction action; memset(&action, 0, sizeof(action)); action.sa_handler = &sig_handler; sigaction(SIGINT, &action, NULL); sigaction(SIGTERM, &action, NULL); sigaction(SIGUSR1, &action, NULL); sigaction(SIGUSR2, &action, NULL); // general: handle command-line arguments while ((c = getopt(argc, argv, "p:vh")) != -1) { switch (c) { case 'p': // argument: fifo path snprintf(configPath, sizeof(configPath), "%s", optarg); break; case 'h': // argument: print usage printf("%s", usage); return 1; case '?': // argument: print usage printf("%s", usage); return 1; case 'v': // argument: print version printf(PACKAGE " " VERSION "\n"); return 0; default: // argument: no arguments; exit abort(); } n = 0; } // general: main loop while (1) { debug("loading config\n"); // config: load struct error_s error; error.length = 0; if (!load_config(configPath, &p, 0, &error)) { fprintf(stderr, "Error loading config. %s", error.message); exit(EXIT_FAILURE); } output_mode = p.om; if (p.om != 4) { // Check if we're running in a tty inAtty = 0; if (strncmp(ttyname(0), "/dev/tty", 8) == 0 || strcmp(ttyname(0), "/dev/console") == 0) inAtty = 1; // in macos vitual terminals are called ttys(xyz) and there are no ttys if (strncmp(ttyname(0), "/dev/ttys", 9) == 0) inAtty = 0; if (inAtty) { system("setfont cava.psf >/dev/null 2>&1"); system("setterm -blank 0"); } } // input: init int bass_cut_off = 150; int treble_cut_off = 1500; audio.source = malloc(1 + strlen(p.audio_source)); strcpy(audio.source, p.audio_source); audio.format = -1; audio.rate = 0; audio.FFTbassbufferSize = 4096; audio.FFTmidbufferSize = 1024; audio.FFTtreblebufferSize = 512; audio.terminate = 0; if (p.stereo) audio.channels = 2; if (!p.stereo) audio.channels = 1; audio.average = false; audio.left = false; audio.right = false; if (strcmp(p.mono_option, "average") == 0) audio.average = true; if (strcmp(p.mono_option, "left") == 0) audio.left = true; if (strcmp(p.mono_option, "right") == 0) audio.right = true; audio.bass_index = 0; audio.mid_index = 0; audio.treble_index = 0; // BASS // audio.FFTbassbufferSize = audio.rate / 20; // audio.FFTbassbufferSize; audio.in_bass_r = fftw_alloc_real(2 * (audio.FFTbassbufferSize / 2 + 1)); audio.in_bass_l = fftw_alloc_real(2 * (audio.FFTbassbufferSize / 2 + 1)); memset(audio.in_bass_r, 0, 2 * (audio.FFTbassbufferSize / 2 + 1) * sizeof(double)); memset(audio.in_bass_l, 0, 2 * (audio.FFTbassbufferSize / 2 + 1) * sizeof(double)); out_bass_l = fftw_alloc_complex(2 * (audio.FFTbassbufferSize / 2 + 1)); out_bass_r = fftw_alloc_complex(2 * (audio.FFTbassbufferSize / 2 + 1)); memset(out_bass_l, 0, 2 * (audio.FFTbassbufferSize / 2 + 1) * sizeof(fftw_complex)); memset(out_bass_r, 0, 2 * (audio.FFTbassbufferSize / 2 + 1) * sizeof(fftw_complex)); p_bass_l = fftw_plan_dft_r2c_1d(audio.FFTbassbufferSize, audio.in_bass_l, out_bass_l, FFTW_MEASURE); p_bass_r = fftw_plan_dft_r2c_1d(audio.FFTbassbufferSize, audio.in_bass_r, out_bass_r, FFTW_MEASURE); // MID // audio.FFTmidbufferSize = audio.rate / bass_cut_off; // audio.FFTbassbufferSize; audio.in_mid_r = fftw_alloc_real(2 * (audio.FFTmidbufferSize / 2 + 1)); audio.in_mid_l = fftw_alloc_real(2 * (audio.FFTmidbufferSize / 2 + 1)); memset(audio.in_mid_r, 0, 2 * (audio.FFTmidbufferSize / 2 + 1) * sizeof(double)); memset(audio.in_mid_l, 0, 2 * (audio.FFTmidbufferSize / 2 + 1) * sizeof(double)); out_mid_l = fftw_alloc_complex(2 * (audio.FFTmidbufferSize / 2 + 1)); out_mid_r = fftw_alloc_complex(2 * (audio.FFTmidbufferSize / 2 + 1)); memset(out_mid_l, 0, 2 * (audio.FFTmidbufferSize / 2 + 1) * sizeof(fftw_complex)); memset(out_mid_r, 0, 2 * (audio.FFTmidbufferSize / 2 + 1) * sizeof(fftw_complex)); p_mid_l = fftw_plan_dft_r2c_1d(audio.FFTmidbufferSize, audio.in_mid_l, out_mid_l, FFTW_MEASURE); p_mid_r = fftw_plan_dft_r2c_1d(audio.FFTmidbufferSize, audio.in_mid_r, out_mid_r, FFTW_MEASURE); // TRIEBLE // audio.FFTtreblebufferSize = audio.rate / treble_cut_off; // audio.FFTbassbufferSize; audio.in_treble_r = fftw_alloc_real(2 * (audio.FFTtreblebufferSize / 2 + 1)); audio.in_treble_l = fftw_alloc_real(2 * (audio.FFTtreblebufferSize / 2 + 1)); memset(audio.in_treble_r, 0, 2 * (audio.FFTtreblebufferSize / 2 + 1) * sizeof(double)); memset(audio.in_treble_l, 0, 2 * (audio.FFTtreblebufferSize / 2 + 1) * sizeof(double)); out_treble_l = fftw_alloc_complex(2 * (audio.FFTtreblebufferSize / 2 + 1)); out_treble_r = fftw_alloc_complex(2 * (audio.FFTtreblebufferSize / 2 + 1)); memset(out_treble_l, 0, 2 * (audio.FFTtreblebufferSize / 2 + 1) * sizeof(fftw_complex)); memset(out_treble_r, 0, 2 * (audio.FFTtreblebufferSize / 2 + 1) * sizeof(fftw_complex)); p_treble_l = fftw_plan_dft_r2c_1d(audio.FFTtreblebufferSize, audio.in_treble_l, out_treble_l, FFTW_MEASURE); p_treble_r = fftw_plan_dft_r2c_1d(audio.FFTtreblebufferSize, audio.in_treble_r, out_treble_r, FFTW_MEASURE); debug("got buffer size: %d, %d, %d", audio.FFTbassbufferSize, audio.FFTmidbufferSize, audio.FFTtreblebufferSize); reset_output_buffers(&audio); debug("starting audio thread\n"); switch (p.im) { #ifdef ALSA case INPUT_ALSA: // input_alsa: wait for the input to be ready if (is_loop_device_for_sure(audio.source)) { if (directory_exists("/sys/")) { if (!directory_exists("/sys/module/snd_aloop/")) { cleanup(); fprintf(stderr, "Linux kernel module \"snd_aloop\" does not seem to be loaded.\n" "Maybe run \"sudo modprobe snd_aloop\".\n"); exit(EXIT_FAILURE); } } } thr_id = pthread_create(&p_thread, NULL, input_alsa, (void *)&audio); // starting alsamusic listener n = 0; while (audio.format == -1 || audio.rate == 0) { req.tv_sec = 0; req.tv_nsec = 1000000; nanosleep(&req, NULL); n++; if (n > 2000) { cleanup(); fprintf(stderr, "could not get rate and/or format, problems with audio thread? " "quiting...\n"); exit(EXIT_FAILURE); } } debug("got format: %d and rate %d\n", audio.format, audio.rate); break; #endif case INPUT_FIFO: // starting fifomusic listener thr_id = pthread_create(&p_thread, NULL, input_fifo, (void *)&audio); audio.rate = p.fifoSample; audio.format = p.fifoSampleBits; break; #ifdef PULSE case INPUT_PULSE: if (strcmp(audio.source, "auto") == 0) { getPulseDefaultSink((void *)&audio); sourceIsAuto = 1; } else sourceIsAuto = 0; // starting pulsemusic listener thr_id = pthread_create(&p_thread, NULL, input_pulse, (void *)&audio); audio.rate = 44100; break; #endif #ifdef SNDIO case INPUT_SNDIO: thr_id = pthread_create(&p_thread, NULL, input_sndio, (void *)&audio); audio.rate = 44100; break; #endif #ifdef SHMEM case INPUT_SHMEM: thr_id = pthread_create(&p_thread, NULL, input_shmem, (void *)&audio); // audio.rate = 44100; break; #endif #ifdef PORTAUDIO case INPUT_PORTAUDIO: thr_id = pthread_create(&p_thread, NULL, input_portaudio, (void *)&audio); audio.rate = 44100; break; #endif default: exit(EXIT_FAILURE); // Can't happen. } if (p.highcf > audio.rate / 2) { cleanup(); fprintf(stderr, "higher cuttoff frequency can't be higher then sample rate / 2"); exit(EXIT_FAILURE); } bool reloadConf = false; while (!reloadConf) { // jumbing back to this loop means that you resized the screen for (i = 0; i < 200; i++) { flast[i] = 0; flastd[i] = 0; fall[i] = 0; fpeak[i] = 0; fmem[i] = 0; f[i] = 0; } #ifdef NCURSES // output: start ncurses mode if (p.om == 1 || p.om == 2) { init_terminal_ncurses(p.color, p.bcolor, p.col, p.bgcol, p.gradient, p.gradient_count, p.gradient_colors, &w, &h); // get_terminal_dim_ncurses(&w, &h); } #endif if (p.om == 3) get_terminal_dim_noncurses(&w, &h); height = (h - 1) * 8; // output open file/fifo for raw output if (p.om == 4) { if (strcmp(p.raw_target, "/dev/stdout") != 0) { // checking if file exists if (access(p.raw_target, F_OK) != -1) { // testopening in case it's a fifo fptest = open(p.raw_target, O_RDONLY | O_NONBLOCK, 0644); if (fptest == -1) { printf("could not open file %s for writing\n", p.raw_target); exit(1); } } else { printf("creating fifo %s\n", p.raw_target); if (mkfifo(p.raw_target, 0664) == -1) { printf("could not create fifo %s\n", p.raw_target); exit(1); } // fifo needs to be open for reading in order to write to it fptest = open(p.raw_target, O_RDONLY | O_NONBLOCK, 0644); } } fp = open(p.raw_target, O_WRONLY | O_NONBLOCK | O_CREAT, 0644); if (fp == -1) { printf("could not open file %s for writing\n", p.raw_target); exit(1); } printf("open file %s for writing raw ouput\n", p.raw_target); // width must be hardcoded for raw output. w = 200; if (strcmp(p.data_format, "binary") == 0) { height = pow(2, p.bit_format) - 1; } else { height = p.ascii_range; } } // handle for user setting too many bars if (p.fixedbars) { p.autobars = 0; if (p.fixedbars * p.bw + p.fixedbars * p.bs - p.bs > w) p.autobars = 1; } // getting orignial numbers of barss incase of resize if (p.autobars == 1) { bars = (w + p.bs) / (p.bw + p.bs); // if (p.bs != 0) bars = (w - bars * p.bs + p.bs) / bw; } else bars = p.fixedbars; if (bars < 1) bars = 1; // must have at least 1 bars if (bars > 200) bars = 200; // cant have more than 200 bars if (p.stereo) { // stereo must have even numbers of bars if (bars % 2 != 0) bars--; } // process [smoothing]: calculate gravity g = p.gravity * ((float)height / 2160) * pow((60 / (float)p.framerate), 2.5); // calculate integral value double integral = p.integral * sqrt(log10(h / 3 + 1)); // checks if there is stil extra room, will use this to center rest = (w - bars * p.bw - bars * p.bs + p.bs) / 2; if (rest < 0) rest = 0; #ifndef NDEBUG printw("height: %d width: %d bars:%d bar width: %d rest: %d\n", w, h, bars, p.bw, rest); #endif // output: start noncurses mode if (p.om == 3) init_terminal_noncurses(p.col, p.bgcol, w, h, p.bw); if (p.stereo) bars = bars / 2; // in stereo onle half number of bars per channel if ((p.smcount > 0) && (bars > 0)) { smh = (double)(((double)p.smcount) / ((double)bars)); } double freqconst = log10((float)p.lowcf / (float)p.highcf) / ((float)1 / ((float)bars + (float)1) - 1); // freqconst = -2; // process: calculate cutoff frequencies int bass_cut_off_bar = -1; int treble_cut_off_bar = -1; bool first_bar = false; int first_treble_bar = 0; for (n = 0; n < bars + 1; n++) { double pot = freqconst * (-1); pot += ((float)n + 1) / ((float)bars + 1) * freqconst; fc[n] = p.highcf * pow(10, pot); fre[n] = fc[n] / (audio.rate / 2); // remember nyquist!, pr my calculations this should be rate/2 // and nyquist freq in M/2 but testing shows it is not... // or maybe the nq freq is in M/4 k[n] = pow(fc[n], 1); k[n] *= (float)height / pow(2, 28); k[n] *= p.smooth[(int)floor(((double)n) * smh)]; k[n] /= log2(audio.FFTbassbufferSize); // lfc stores the lower cut frequency foo each bar in the fft out buffer if (fc[n] < bass_cut_off) { lcf[n] = fre[n] * (audio.FFTbassbufferSize / 2) + 1; bass_cut_off_bar++; treble_cut_off_bar++; k[n] *= log2(audio.FFTbassbufferSize); } else if (fc[n] > bass_cut_off && fc[n] < treble_cut_off) { lcf[n] = fre[n] * (audio.FFTmidbufferSize / 2) + 1; treble_cut_off_bar++; if ((treble_cut_off_bar - bass_cut_off_bar) == 1) { first_bar = true; hcf[n - 1] = fre[n] * (audio.FFTbassbufferSize / 2); if (hcf[n - 1] < lcf[n - 1]) hcf[n - 1] = lcf[n - 1]; } else { first_bar = false; } k[n] *= log2(audio.FFTmidbufferSize); } else { lcf[n] = fre[n] * (audio.FFTtreblebufferSize / 2) + 1; first_treble_bar++; if (first_treble_bar == 1) { first_bar = true; hcf[n - 1] = fre[n] * (audio.FFTmidbufferSize / 2); if (hcf[n - 1] < lcf[n - 1]) hcf[n - 1] = lcf[n - 1]; } else { first_bar = false; } k[n] *= log2(audio.FFTtreblebufferSize); } if (n != 0 && !first_bar) { hcf[n - 1] = lcf[n] - 1; // pushing the spectrum up if the expe function gets "clumped" if (lcf[n] <= lcf[n - 1]) lcf[n] = lcf[n - 1] + 1; hcf[n - 1] = lcf[n] - 1; } #ifndef NDEBUG if (n != 0) { mvprintw(n, 0, "%d: %f -> %f (%d -> %d) bass: %d, treble:%d \n", n, fc[n - 1], fc[n], lcf[n - 1], hcf[n - 1], bass_cut_off_bar, treble_cut_off_bar); } #endif } // process: weigh signal to frequencies height and EQ for (n = 0; n < bars; n++) { } if (p.stereo) bars = bars * 2; bool resizeTerminal = false; while (!resizeTerminal) { // general: keyboard controls #ifdef NCURSES if (p.om == 1 || p.om == 2) ch = getch(); #endif switch (ch) { case 65: // key up p.sens = p.sens * 1.05; break; case 66: // key down p.sens = p.sens * 0.95; break; case 68: // key right p.bw++; resizeTerminal = true; break; case 67: // key left if (p.bw > 1) p.bw--; resizeTerminal = true; break; case 'r': // reload config should_reload = 1; break; case 'c': // reload colors reload_colors = 1; break; case 'f': // change forground color if (p.col < 7) p.col++; else p.col = 0; resizeTerminal = true; break; case 'b': // change backround color if (p.bgcol < 7) p.bgcol++; else p.bgcol = 0; resizeTerminal = true; break; case 'q': if (sourceIsAuto) free(audio.source); cleanup(); return EXIT_SUCCESS; } if (should_reload) { reloadConf = true; resizeTerminal = true; should_reload = 0; } if (reload_colors) { struct error_s error; error.length = 0; if (!load_config(configPath, (void *)&p, 1, &error)) { cleanup(); fprintf(stderr, "Error loading config. %s", error.message); exit(EXIT_FAILURE); } resizeTerminal = true; reload_colors = 0; } // if (cont == 0) break; #ifndef NDEBUG // clear(); refresh(); #endif // process: populate input buffer and check if input is present silence = true; for (i = 0; i < (2 * (audio.FFTbassbufferSize / 2 + 1)); i++) { if (i < audio.FFTbassbufferSize) { if (audio.in_bass_l[i] || audio.in_bass_r[i]) silence = false; } else { audio.in_bass_l[i] = 0; if (p.stereo) audio.in_bass_r[i] = 0; } } for (i = 0; i < (2 * (audio.FFTmidbufferSize / 2 + 1)); i++) { if (i < audio.FFTmidbufferSize) { } else { audio.in_mid_l[i] = 0; if (p.stereo) audio.in_mid_r[i] = 0; } } for (i = 0; i < (2 * (audio.FFTtreblebufferSize / 2 + 1)); i++) { if (i < audio.FFTtreblebufferSize) { } else { audio.in_treble_l[i] = 0; if (p.stereo) audio.in_treble_r[i] = 0; } } if (silence) sleep++; else sleep = 0; // process: if input was present for the last 5 seconds apply FFT to it if (sleep < p.framerate * 5) { // process: execute FFT and sort frequency bands if (p.stereo) { fftw_execute(p_bass_l); fftw_execute(p_bass_r); fftw_execute(p_mid_l); fftw_execute(p_mid_r); fftw_execute(p_treble_l); fftw_execute(p_treble_r); fl = separate_freq_bands(audio.FFTbassbufferSize, out_bass_l, audio.FFTmidbufferSize, out_mid_l, audio.FFTtreblebufferSize, out_treble_l, bass_cut_off_bar, treble_cut_off_bar, bars / 2, lcf, hcf, k, LEFT_CHANNEL, p.sens, p.ignore); fr = separate_freq_bands(audio.FFTbassbufferSize, out_bass_r, audio.FFTmidbufferSize, out_mid_r, audio.FFTtreblebufferSize, out_treble_r, bass_cut_off_bar, treble_cut_off_bar, bars / 2, lcf, hcf, k, RIGHT_CHANNEL, p.sens, p.ignore); } else { fftw_execute(p_bass_l); fftw_execute(p_mid_l); fftw_execute(p_treble_l); fl = separate_freq_bands( audio.FFTbassbufferSize, out_bass_l, audio.FFTmidbufferSize, out_mid_l, audio.FFTtreblebufferSize, out_treble_l, bass_cut_off_bar, treble_cut_off_bar, bars, lcf, hcf, k, LEFT_CHANNEL, p.sens, p.ignore); } } else { //**if in sleep mode wait and continue**// #ifndef NDEBUG printw("no sound detected for 3 sec, going to sleep mode\n"); #endif // wait 1 sec, then check sound again. req.tv_sec = 1; req.tv_nsec = 0; nanosleep(&req, NULL); continue; } // process [filter] if (p.monstercat) { if (p.stereo) { fl = monstercat_filter(fl, bars / 2, p.waves, p.monstercat); fr = monstercat_filter(fr, bars / 2, p.waves, p.monstercat); } else { fl = monstercat_filter(fl, bars, p.waves, p.monstercat); } } // processing signal bool senselow = true; for (o = 0; o < bars; o++) { // mirroring stereo channels if (p.stereo) { if (o < bars / 2) { f[o] = fl[bars / 2 - o - 1]; } else { f[o] = fr[o - bars / 2]; } } else { f[o] = fl[o]; } // process [smoothing]: falloff if (g > 0) { if (f[o] < flast[o]) { f[o] = fpeak[o] - (g * fall[o] * fall[o]); fall[o]++; } else { fpeak[o] = f[o]; fall[o] = 0; } flast[o] = f[o]; } // process [smoothing]: integral if (p.integral > 0) { f[o] = fmem[o] * integral + f[o]; fmem[o] = f[o]; int diff = (height + 1) - f[o]; if (diff < 0) diff = 0; double div = 1 / (diff + 1); // f[o] = f[o] - pow(div, 10) * (height + 1); fmem[o] = fmem[o] * (1 - div / 20); #ifndef NDEBUG mvprintw(o, 0, "%d: f:%f->%f (%d->%d), k-value:\ %15e, peak:%d \n", o, fc[o], fc[o + 1], lcf[o], hcf[o], k[o], f[o]); // if(f[o] > maxvalue) maxvalue = f[o]; #endif } // zero values causes divided by zero segfault (if not raw) if (f[o] < 1) { f[o] = 1; if (p.om == 4) f[o] = 0; } // autmatic sens adjustment if (p.autosens) { if (f[o] > height && senselow) { p.sens = p.sens * 0.98; senselow = false; } } } if (p.autosens && !silence && senselow) p.sens = p.sens * 1.001; // debug("%d\n",maxvalue); //checking maxvalue 10000 // output: draw processed input #ifdef NDEBUG switch (p.om) { case 1: #ifdef NCURSES rc = draw_terminal_ncurses(inAtty, h, w, bars, p.bw, p.bs, rest, f, flastd, p.gradient); break; #endif case 2: #ifdef NCURSES rc = draw_terminal_bcircle(inAtty, h, w, f); break; #endif case 3: rc = draw_terminal_noncurses(inAtty, h, w, bars, p.bw, p.bs, rest, f, flastd); break; case 4: rc = print_raw_out(bars, fp, p.is_bin, p.bit_format, p.ascii_range, p.bar_delim, p.frame_delim, f); break; } // terminal has been resized breaking to recalibrating values if (rc == -1) resizeTerminal = true; if (p.framerate <= 1) { req.tv_sec = 1 / (float)p.framerate; } else { req.tv_sec = 0; req.tv_nsec = (1 / (float)p.framerate) * 1000000000; } nanosleep(&req, NULL); #endif memcpy(flastd, f, 200 * sizeof(int)); // checking if audio thread has exited unexpectedly if (audio.terminate == 1) { cleanup(); fprintf(stderr, "Audio thread exited unexpectedly. %s\n", audio.error_message); exit(EXIT_FAILURE); } } // resize terminal } // reloading config req.tv_sec = 0; req.tv_nsec = 100; // waiting some time to make shure audio is ready nanosleep(&req, NULL); //**telling audio thread to terminate**// audio.terminate = 1; pthread_join(p_thread, NULL); if (p.customEQ) free(p.smooth); if (sourceIsAuto) free(audio.source); fftw_free(audio.in_bass_r); fftw_free(audio.in_bass_l); fftw_free(out_bass_r); fftw_free(out_bass_l); fftw_destroy_plan(p_bass_l); fftw_destroy_plan(p_bass_r); fftw_free(audio.in_mid_r); fftw_free(audio.in_mid_l); fftw_free(out_mid_r); fftw_free(out_mid_l); fftw_destroy_plan(p_mid_l); fftw_destroy_plan(p_mid_r); fftw_free(audio.in_treble_r); fftw_free(audio.in_treble_l); fftw_free(out_treble_r); fftw_free(out_treble_l); fftw_destroy_plan(p_treble_l); fftw_destroy_plan(p_treble_r); cleanup(); // fclose(fp); } }