#include #include #include #include // Use native C99 complex type for fftw3 #include #include #ifdef MS_WINDOWS #include #include static int cleanupWSA = 0; // Must we call WSACleanup() ? HWND quisk_mainwin_handle; // Handle of the main window on Windows #else #include #include #include #include #endif #include "quisk.h" #include "filter.h" #define DEBUG 0 // These are used for input/output of radio samples from/to a file. The SAMPLES_FROM_FILE is 0 for // normal operation, 1 to record samples to a file, 2 to play samples from a file. Rate must be 48k. #define SAMPLES_FROM_FILE 0 #define FM_FILTER_DEMPH 300.0 // Frequency of FM lowpass de-emphasis filter #define AGC_DELAY 15 // Delay in AGC buffer in milliseconds #define FFT_ARRAY_SIZE 4 // Number of FFTs #define MULTIRX_FFT_MULT 8 // multirx FFT size is a multiple of graph size #define MAX_RX_CHANNELS 3 // maximum paths to decode audio #define MAX_RX_FILTERS 3 // maximum number of receiver filters #define DGT_NARROW_FREQ 3000 // Use 6 ksps rate below this bandwidth #define SQUELCH_FFT_SIZE 512 static int fft_error; // fft error count typedef struct fftd { fftw_complex * samples; // complex data for fft int index; // position of next fft sample int filled; // whether the fft is ready to run int block; // block number 0, 1, ... } fft_data; typedef struct mrx_fftd { // FFT data for sub-receivers fftw_complex * samples; // complex data for fft of size multirx_fft_width int index; // position of next fft sample } mrx_fft_data; struct AgcState { // Store state information for the AGC double max_out; // Must initialize to maximum output level 0.0 to 1.0. int sample_rate; // Must initialize this to the sample rate or zero. int buf_size; // Must initialize this to zero. int index_read; int index_start; int is_clipping; double themax; double gain; double delta; double target_gain; double time_release; complex double * c_samp; }; static fft_data fft_data_array[FFT_ARRAY_SIZE]; // Data for several FFTs static int fft_data_index = 0; // Write the current samples to this FFT static fftw_plan quisk_fft_plan; static double * fft_window; // Window for FFT data static double * current_graph; // current graph data as returned static PyObject * QuiskError; // Exception for this module static PyObject * pyApp; // Application instance static int fft_size; // size of fft, e.g. 1024 int data_width; // number of points to return as graph data; fft_size * n static int graph_width; // width of the graph in pixels rx_mode_type rxMode; // 0 to 13: CWL, CWU, LSB, USB, AM, FM, EXT, DGT-U, DGT-L, DGT-IQ, IMD, FDV-U, FDV-L, DGT-FM int quisk_noise_blanker; // noise blanker level, 0 for off int quiskTxHoldState; // hold Tx until the repeater frequency shift is complete int quisk_is_vna; // zero for normal program, one for the VNA program static int py_sample_rx_bytes=2; // number of bytes in each I or Q sample: 1, 2, 3, or 4 static int py_sample_rx_endian; // order of sample array: 0 == little endian; 1 == big endian static int py_bscope_bytes; static int py_bscope_endian; static int quisk_auto_notch; // auto notch control PyObject * quisk_pyConfig=NULL; // Configuration module instance static int graphX; // Origin of first X value for graph data static int graphY; // Origin of 0 dB for graph data static double graphScale; // Scale factor for graph static complex double testtonePhase; // Phase increment for test tone double quisk_audioVolume; // Audio output level, 0.0 to 1.0 double quisk_ctcss_freq; // CTCSS repeater access tone frequency in Hertz, or zero static double cFilterI[MAX_RX_FILTERS][MAX_FILTER_SIZE]; // Digital filter coefficients for receivers static double cFilterQ[MAX_RX_FILTERS][MAX_FILTER_SIZE]; // Digital filter coefficients static int sizeFilter; // Number of coefficients for filters static int isFDX; // Are we in full duplex mode? static int filter_bandwidth[MAX_RX_FILTERS]; // Current filter bandwidth in Hertz static int filter_start_offset; // Current filter +/- start offset frequency from rx_tune_freq in Hertz for filter zero static int quisk_decim_srate; // Sample rate after decimation static int quisk_filter_srate=48000; // Frequency for filters static int split_rxtx; // Are we in split rx/tx mode? static int kill_audio; // Replace radio sound with silence static int quisk_transmit_mode; // Are we in transmit mode for semi-break-in CW? static int fft_sample_rate; // Sample rate on the graph (not the audio channel) -fft_srate/2 < freq < +fft_srate/2 static int scan_blocks=0; // Number of FFT blocks for scan; or zero static int scan_sample_rate=1; // Sample rate to use while scanning static double scan_valid=0.84; // Fraction of each FFT block that is valid static int scan_vfo0; static int scan_deltaf; static int graph_refresh; // Graph refresh rate from the config file static int multiple_sample_rates=0; // Hardware supports multiple different sample rates static int vfo_screen; // The VFO (center) frequency on the FFT screen static int vfo_audio; // VFO frequency for the audio channel static int is_PTT_down; // state 0/1 of PTT button static int sample_bytes=3; // number of bytes in each I or Q sample static complex double PySampleBuf[SAMP_BUFFER_SIZE]; // buffer for samples returned from Python static int PySampleCount; // count of samples in buffer static int multirx_data_width; // width of graph data to return static int multirx_fft_width; // size of FFT samples int quisk_multirx_count; // number of additional receivers zero or 1, 2, 3, ... static int quisk_multirx_state; // state of hermes receivers static mrx_fft_data multirx_fft_data[QUISK_MAX_RECEIVERS]; // FFT data for the sub-receivers static int multirx_fft_next_index; // index of the receiver for the next FFT to return static double multirx_fft_next_time; // timing interval for multirx FFT static int multirx_fft_next_state; // state of multirx FFT: 0 == filling, 1 == ready, 2 == done static fftw_plan multirx_fft_next_plan; // fftw3 plan for multirx FFTs static fftw_complex * multirx_fft_next_samples; // sample buffer for multirx FFT static int multirx_play_method; // 0== both, 1==left, 2==right static int multirx_play_channel = -1; // index of the channel to play; or -1 static int multirx_freq[QUISK_MAX_RECEIVERS]; // tune frequency for channel static int multirx_mode[QUISK_MAX_RECEIVERS]; // mode CW, SSB, etc. for channel static complex double * multirx_cSamples[QUISK_MAX_RECEIVERS]; // samples for the sub-receivers static int multirx_sample_size; // current size of the sub-receiver sample array static double sidetoneVolume; // Audio output level of the CW sidetone, 0.0 to 1.0 int quiskKeyupDelay=0; // key-up delay from config file static int keyupDelayCode; // Play silence after sidetone ends, milliseconds static complex double sidetonePhase; // Phase increment for sidetone int quisk_sidetoneCtrl; // sidetone control value 0 to 1000 static double agcReleaseGain=80; // AGC maximum gain static double agc_release_time = 1.0; // Release time in seconds static double squelch_level=-999.0; // setting of FM squelch control static int ssb_squelch_enabled; static int ssb_squelch_level; static int quisk_invert_spectrum = 0; // Invert the input RF spectrum static void process_agc(struct AgcState *, complex double *, int, int); static double Smeter; // Measured RMS signal strength static int rx_tune_freq; // Receive tuning frequency as +/- sample_rate / 2, including RIT int quisk_tx_tune_freq; // Transmit tuning frequency as +/- sample_rate / 2 static int rit_freq; // RIT frequency in Hertz #define RX_UDP_SIZE 1442 // Expected size of UDP samples packet static SOCKET rx_udp_socket = INVALID_SOCKET; // Socket for receiving ADC samples from UDP int quisk_rx_udp_started = 0; // Have we received any data yet? int quisk_using_udp = 0; // Are we using rx_udp_socket? No longer used, but provided for backward compatibility. static double rx_udp_gain_correct = 0; // Small correction for different decimation rates static double rx_udp_clock; // Clock frequency for UDP samples int quisk_use_rx_udp; // from the config file static int is_little_endian; // Test byte order; is it little-endian? unsigned char quisk_pc_to_hermes[17 * 4]; // data to send from PC to Hermes hardware unsigned char quisk_hermeslite_writequeue[4 * 5]; // One-time writes to Hermes-Lite unsigned int quisk_hermeslite_writepointer = 0; unsigned int quisk_hermeslite_writeattempts = 0; static unsigned char quisk_hermes_to_pc[5 * 4]; // data received from the Hermes hardware static unsigned char quisk_hermeslite_response[5]; // response from Hermes-Lite commands unsigned int quisk_hermes_code_version = -1; // code version returned by the Hermes hardware unsigned int quisk_hermes_board_id = -1; // board ID returned by the Hermes hardware static double hermes_temperature; // average temperature static double hermes_fwd_power; // average forward power static double hermes_rev_power; // average reverse power static double hermes_pa_current; // average power amp current static int hermes_count_temperature; // number of temperature samples static int hermes_count_current; // number of current samples static int hardware_ptt = -1; // hardware PTT switch static int hardware_cwkey = -1; // hardware CW key enum quisk_rec_state quisk_record_state = IDLE; static float * quisk_record_buffer; static int quisk_record_bufsize; static int quisk_record_index; static int quisk_play_index; static int quisk_mic_index; static int quisk_record_full; // These are used to measure the frequency of a continuous RF signal. static void measure_freq(complex double *, int, int); static double measured_frequency; static int measure_freq_mode=0; //These are used to measure the demodulated audio voltage static double measured_audio; static double measure_audio_sum; static int measure_audio_count; static int measure_audio_time=1; // This is used to measure the squelch level static struct _MeasureSquelch { int squelch_active; // These are used for FM squelch double rf_sum; double squelch; int rf_count; // These are used for SSB squelch double * in_fft; int index; int sq_open; } MeasureSquelch[MAX_RX_CHANNELS]; // These are used for playback of a WAV file. static int wavStart; // Sound data starts at this offset // Two wavFp are needed because the same file is used twice on asynchronous streams. static FILE * wavFpSound; // File pointer for audio WAV file input static FILE * wavFpMic; // File pointer for microphone WAV file input // These are used for bandscope data from Hermes static int enable_bandscope = 1; static fftw_plan bandscopePlan=NULL; static int bandscopeState = 0; static int bandscopeBlockCount = 4; static int bandscope_size = 0; static double * bandscopeSamples = NULL; // bandscope samples are normalized to max 1.0 with bandscopeScale static double bandscopeScale = 32768; // maximum value of the samples sent to the bandscope static double * bandscopeWindow = NULL; static double * bandscopeAverage = NULL; static complex double * bandscopeFFT = NULL; static double hermes_adc_level = 0.0; // maximum bandscope sample from the ADC, 0.0 to 1.0 #if SAMPLES_FROM_FILE static struct QuiskWav hWav; int QuiskWavWriteOpen(struct QuiskWav * hWav, char * file_name, short format, short nChan, short bytes, int rate, double scale) { unsigned int u; // must be 4 bytes unsigned short s; // must be 2 bytes hWav->format = format; hWav->nChan = nChan; hWav->bytes_per_sample = bytes; hWav->sample_rate = rate; hWav->scale = scale; hWav->samples = 0; // number of samples written hWav->fp = fopen(file_name, "wb"); if ( ! hWav->fp) return 0; if (format == 0) // RAW format - no header return 1; if (fwrite("RIFF", 1, 4, hWav->fp) != 4) { fclose(hWav->fp); hWav->fp = NULL; return 0; } if (format == 1) // PCM u = 36; else u = 50; fwrite(&u, 4, 1, hWav->fp); fwrite("WAVE", 1, 4, hWav->fp); fwrite("fmt ", 1, 4, hWav->fp); if (format == 1) // PCM u = 16; else u = 18; fwrite(&u, 4, 1, hWav->fp); fwrite(&format, 2, 1, hWav->fp); // format fwrite(&nChan, 2, 1, hWav->fp); // number of channels fwrite(&rate, 4, 1, hWav->fp); // sample rate u = rate * bytes * nChan; fwrite(&u, 4, 1, hWav->fp); s = bytes * nChan; fwrite(&s, 2, 1, hWav->fp); s = bytes * 8; fwrite(&s, 2, 1, hWav->fp); if (format != 1) { s = 0; fwrite(&s, 2, 1, hWav->fp); fwrite("fact", 1, 4, hWav->fp); u = 4; fwrite(&u, 4, 1, hWav->fp); u = 0; fwrite(&u, 4, 1, hWav->fp); } fwrite("data", 1, 4, hWav->fp); u = 0; fwrite(&u, 4, 1, hWav->fp); return 1; } void QuiskWavWriteC(struct QuiskWav * hWav, complex double * cSamples, int nSamples) { // Record the samples to a WAV file, two float samples I/Q. Always use IEEE format 3. int j; // TODO: add other formats float samp; // must be 4 bytes if ( ! hWav->fp) return; // append the samples hWav->samples += (unsigned int)nSamples; fseek(hWav->fp, 0, SEEK_END); // seek to the end for (j = 0; j < nSamples; j++) { samp = creal(cSamples[j]) * hWav->scale; fwrite(&samp, 4, 1, hWav->fp); samp = cimag(cSamples[j]) * hWav->scale; fwrite(&samp, 4, 1, hWav->fp); } // write the sizes to the header QuiskWavWriteD(hWav, NULL, 0); } void QuiskWavWriteD(struct QuiskWav * hWav, double * dSamples, int nSamples) { // Record the samples to a file, one channel. int j; float samp; // must be 4 bytes unsigned int u; // must be 4 bytes int i; // must be 4 bytes char c; // must be 1 byte short s; // must be 2 bytes if ( ! hWav->fp) return; // append the samples hWav->samples += (unsigned int)nSamples; fseek(hWav->fp, 0, SEEK_END); // seek to the end if ( ! dSamples) { ; // Only update the header } else if (hWav->format == 3) { // float for (j = 0; j < nSamples; j++) { samp = dSamples[j] * hWav->scale; fwrite(&samp, 4, 1, hWav->fp); } } else { // PCM integer switch (hWav->bytes_per_sample) { case 1: for (j = 0; j < nSamples; j++) { c = (char)(dSamples[j] * hWav->scale); fwrite(&c, 1, 1, hWav->fp); } break; case 2: for (j = 0; j < nSamples; j++) { s = (short)(dSamples[j] * hWav->scale); fwrite(&s, 2, 1, hWav->fp); } break; case 4: for (j = 0; j < nSamples; j++) { i = (int)(dSamples[j] * hWav->scale); fwrite(&i, 4, 1, hWav->fp); } break; } } // write the sizes to the header if (hWav->format == 0) { // RAW format ; } else if (hWav->format == 3) { // float fseek(hWav->fp, 54, SEEK_SET); // seek from the beginning u = hWav->bytes_per_sample * hWav->nChan * hWav->samples; fwrite(&u, 4, 1, hWav->fp); fseek(hWav->fp, 4, SEEK_SET); u += 50 ; fwrite(&u, 4, 1, hWav->fp); fseek(hWav->fp, 46, SEEK_SET); u = hWav->samples * hWav->nChan; fwrite(&u, 4, 1, hWav->fp); } else { fseek(hWav->fp, 40, SEEK_SET); u = hWav->bytes_per_sample * hWav->nChan * hWav->samples; fwrite(&u, 4, 1, hWav->fp); fseek(hWav->fp, 4, SEEK_SET); u += 36 ; fwrite(&u, 4, 1, hWav->fp); } if (hWav->samples > 536870000) // 2**32 / 8 QuiskWavClose(hWav); } int QuiskWavReadOpen(struct QuiskWav * hWav, char * file_name, short format, short nChan, short bytes, int rate, double scale) { // TODO: Get parameters from the WAV file header. char name[5]; int size; hWav->format = format; hWav->nChan = nChan; hWav->bytes_per_sample = bytes; hWav->sample_rate = rate; hWav->scale = scale; hWav->fp = fopen(file_name, "rb"); if (!hWav->fp) return 0; if (hWav->format == 0) { // RAW format fseek(hWav->fp, 0, SEEK_END); // seek to the end hWav->fpEnd = ftell(hWav->fp); hWav->fpStart = hWav->fpPos = 0; return 1; } hWav->fpEnd = 0; while (1) { // WAV format if (fread (name, 4, 1, hWav->fp) != 1) return 0; if (fread (&size, 4, 1, hWav->fp) != 1) return 0; name[4] = 0; //printf("name %s size %d\n", name, size); if (!strncmp(name, "RIFF", 4)) fseek (hWav->fp, 4, SEEK_CUR); // Skip "WAVE" else if (!strncmp(name, "data", 4)) { // sound data starts here hWav->fpStart = ftell(hWav->fp); hWav->fpEnd = hWav->fpStart + size; hWav->fpPos = hWav->fpStart; break; } else // Skip other records fseek (hWav->fp, size, SEEK_CUR); } //printf("start %d end %d\n", hWav->fpStart, hWav->fpEnd); if (!hWav->fpEnd) { // Failure to find "data" record fclose(hWav->fp); hWav->fp = NULL; return 0; } return 1; } void QuiskWavReadC(struct QuiskWav * hWav, complex double * cSamples, int nSamples) { // Always uses format 3. TODO: add other formats. int i; float fi, fq; double di, dq; #if 0 double noise; noise = 1.6E6; for (i = 0; i < nSamples; i++) { di = ((float)random() / RAND_MAX - 0.5) * noise; dq = ((float)random() / RAND_MAX - 0.5) * noise; cSamples[i] = di + I * dq; } #endif if (hWav->fp && nSamples > 0) { fseek (hWav->fp, hWav->fpPos, SEEK_SET); for (i = 0; i < nSamples; i++) { if (fread(&fi, 4, 1, hWav->fp) != 1) break; if (fread(&fq, 4, 1, hWav->fp) != 1) break; di = fi * hWav->scale; dq = fq * hWav->scale; cSamples[i] += di + I * dq; hWav->fpPos += hWav->bytes_per_sample * hWav->nChan; if (hWav->fpPos >= hWav->fpEnd) hWav->fpPos = hWav->fpStart; } } } void QuiskWavReadD(struct QuiskWav * hWav, double * dSamples, int nSamples) { int j; float samp; int i; // must be 4 bytes char c; // must be 1 byte short s; // must be 2 bytes if (hWav->fp && nSamples > 0) { fseek (hWav->fp, hWav->fpPos, SEEK_SET); for (j = 0; j < nSamples; j++) { if (hWav->format == 3) { // float if (fread(&samp, 4, 1, hWav->fp) != 1) return; } else { // PCM integer switch (hWav->bytes_per_sample) { case 1: if (fread(&c, 1, 1, hWav->fp) != 1) return; samp = c; break; case 2: if (fread(&s, 2, 1, hWav->fp) != 1) return; samp = s; break; case 4: if (fread(&i, 4, 1, hWav->fp) != 1) return; samp = i; break; } } dSamples[j] = samp * hWav->scale; hWav->fpPos += hWav->bytes_per_sample * hWav->nChan; if (hWav->fpPos >= hWav->fpEnd) hWav->fpPos = hWav->fpStart; } } } void QuiskWavClose(struct QuiskWav * hWav) { if (hWav->fp) { fclose(hWav->fp); hWav->fp = NULL; } } #endif // These are used for digital voice codecs ty_dvoice_codec_rx pt_quisk_freedv_rx; ty_dvoice_codec_tx pt_quisk_freedv_tx; void quisk_dvoice_freedv(ty_dvoice_codec_rx rx, ty_dvoice_codec_tx tx) { pt_quisk_freedv_rx = rx; pt_quisk_freedv_tx = tx; } #if 0 static int fFracDecim(double * dSamples, int nSamples, double fdecim) { // fractional decimation by fdecim > 1.0 int i, nout; double xm0, xm1, xm2, xm3; static double dindex = 1; static double y0=0, y1=0, y2=0, y3=0; static int in=0, out=0; in += nSamples; nout = 0; for (i = 0; i < nSamples; i++) { y3 = dSamples[i]; if (dindex < 1 || dindex >= 2.4) printf ("dindex %.5f fdecim %.8f\n", dindex, fdecim); if (dindex < 2) { #if 0 dSamples[nout++] = (1 - (dindex - 1)) * y1 + (dindex - 1) * y2; #else xm0 = dindex - 0; xm1 = dindex - 1; xm2 = dindex - 2; xm3 = dindex - 3; dSamples[nout++] = xm1 * xm2 * xm3 * y0 / -6.0 + xm0 * xm2 * xm3 * y1 / 2.0 + xm0 * xm1 * xm3 * y2 / -2.0 + xm0 * xm1 * xm2 * y3 / 6.0; #endif out++; dindex += fdecim - 1; y0 = y1; y1 = y2; y2 = y3; } else { if (dindex > 2.5) printf ("Skip at %.2f\n", dindex); y0 = y1; y1 = y2; y2 = y3; dindex -= 1; } } //printf ("in %d out %d\n", in, out); return nout; } #endif static int cFracDecim(complex double * cSamples, int nSamples, double fdecim) { // Fractional decimation of I/Q signals works poorly because it introduces aliases and birdies. int i, nout; double xm0, xm1, xm2, xm3; static double dindex = 1; static complex double c0=0, c1=0, c2=0, c3=0; static int in=0, out=0; in += nSamples; nout = 0; for (i = 0; i < nSamples; i++) { c3 = cSamples[i]; if (dindex < 1 || dindex >= 2.4) printf ("dindex %.5f fdecim %.8f\n", dindex, fdecim); if (dindex < 2) { #if 0 cSamples[nout++] = (1 - (dindex - 1)) * c1 + (dindex - 1) * c2; #else xm0 = dindex - 0; xm1 = dindex - 1; xm2 = dindex - 2; xm3 = dindex - 3; cSamples[nout++] = (xm1 * xm2 * xm3 * c0 / -6.0 + xm0 * xm2 * xm3 * c1 / 2.0 + xm0 * xm1 * xm3 * c2 / -2.0 + xm0 * xm1 * xm2 * c3 / 6.0); #endif out++; dindex += fdecim - 1; c0 = c1; c1 = c2; c2 = c3; } else { if (dindex > 2.5) printf ("Skip at %.2f\n", dindex); c0 = c1; c1 = c2; c2 = c3; dindex -= 1; } } //printf ("in %d out %d\n", in, out); return nout; } #define QUISK_NB_HWINDOW_SECS 500.E-6 // half-size of blanking window in seconds static void NoiseBlanker(complex double * cSamples, int nSamples) { static complex double * cSaved = NULL; static double * dSaved = NULL; static double save_sum; static int save_size, hwindow_size, state, index, win_index; static int sample_rate = -1; int i, j, k, is_pulse; double mag, limit; complex double samp; #if DEBUG static time_t time0 = 0; static int debug_count = 0; #endif if (quisk_noise_blanker <= 0) return; if (quisk_sound_state.sample_rate != sample_rate) { // Initialization sample_rate = quisk_sound_state.sample_rate; state = 0; index = 0; win_index = 0; save_sum = 0.0; hwindow_size = (int)(sample_rate * QUISK_NB_HWINDOW_SECS + 0.5); save_size = hwindow_size * 3; // number of samples in the average i = save_size * sizeof(double); dSaved = (double *) realloc(dSaved, i); memset (dSaved, 0, i); i = save_size * sizeof(complex double); cSaved = (complex double *)realloc(cSaved, i); memset (cSaved, 0, i); #if DEBUG printf ("Noise blanker: save_size %d hwindow_size %d\n", save_size, hwindow_size); #endif } switch(quisk_noise_blanker) { case 1: default: limit = 6.0; break; case 2: limit = 4.0; break; case 3: limit = 2.5; break; } for (i = 0; i < nSamples; i++) { // output oldest sample, save newest samp = cSamples[i]; // newest sample cSamples[i] = cSaved[index]; // oldest sample cSaved[index] = samp; // use newest sample mag = cabs(samp); save_sum -= dSaved[index]; // remove oldest sample magnitude dSaved[index] = mag; // save newest sample magnitude save_sum += mag; // update sum of samples if (mag <= save_sum / save_size * limit) // see if we have a large pulse is_pulse = 0; else is_pulse = 1; switch (state) { case 0: // Normal state if (is_pulse) { // wait for a pulse state = 1; k = index; for (j = 0; j < hwindow_size; j++) { // apply window to prior samples cSaved[k--] *= (double)j / hwindow_size; if (k < 0) k = save_size - 1; } } else if (win_index) { // pulses have stopped, increase window to 1.0 cSaved[index] *= (double)win_index / hwindow_size; if (++win_index >= hwindow_size) win_index = 0; // no more window } break; case 1: // we got a pulse cSaved[index] = 0; // zero samples until the pulses stop if ( ! is_pulse) { // start raising the window, but be prepared to window another pulse state = 0; win_index = 1; } break; } #if DEBUG if (debug_count) { printf ("%d", is_pulse); if (--debug_count == 0) printf ("\n"); } else if (is_pulse && time(NULL) != time0) { time0 = time(NULL); debug_count = hwindow_size * 2; printf ("%d", is_pulse); } #endif if (++index >= save_size) index = 0; } return; } #define NOTCH_DEBUG 0 #define NOTCH_DATA_SIZE 2048 #define NOTCH_FILTER_DESIGN_SIZE NOTCH_DATA_SIZE / 4 #define NOTCH_FILTER_SIZE (NOTCH_FILTER_DESIGN_SIZE - 1) #define NOTCH_FILTER_FFT_SIZE (NOTCH_FILTER_SIZE / 2 + 1) #define NOTCH_DATA_START_SIZE (NOTCH_FILTER_SIZE - 1) #define NOTCH_DATA_OUTPUT_SIZE (NOTCH_DATA_SIZE - NOTCH_DATA_START_SIZE) #define NOTCH_FFT_SIZE (NOTCH_DATA_SIZE / 2 + 1) static void dAutoNotch(double * dsamples, int nSamples, int sidetone, int rate) { int i, j, k, i1, i2, inp, signal, delta_sig, delta_i1, half_width; double d, d1, d2, avg; static int old1, count1, old2, count2; static int index; static fftw_plan planFwd=NULL; static fftw_plan planRev,fltrFwd, fltrRev; static double data_in[NOTCH_DATA_SIZE]; static double data_out[NOTCH_DATA_SIZE]; static complex double notch_fft[NOTCH_FFT_SIZE]; static double fft_window[NOTCH_DATA_SIZE]; static double fltr_in[NOTCH_DATA_SIZE]; static double fltr_out[NOTCH_FILTER_DESIGN_SIZE]; static complex double fltr_fft[NOTCH_FFT_SIZE]; static double average_fft[NOTCH_FFT_SIZE]; static int fltrSig; #if NOTCH_DEBUG static char * txt; double dmax; #endif if ( ! planFwd) { // set up FFT plans planFwd = fftw_plan_dft_r2c_1d(NOTCH_DATA_SIZE, data_in, notch_fft, FFTW_MEASURE); planRev = fftw_plan_dft_c2r_1d(NOTCH_DATA_SIZE, notch_fft, data_out, FFTW_MEASURE); // destroys notch_fft fltrFwd = fftw_plan_dft_r2c_1d(NOTCH_DATA_SIZE, fltr_in, fltr_fft, FFTW_MEASURE); fltrRev = fftw_plan_dft_c2r_1d(NOTCH_FILTER_DESIGN_SIZE, fltr_fft, fltr_out, FFTW_MEASURE); for (i = 0; i < NOTCH_FILTER_SIZE; i++) fft_window[i] = 0.50 - 0.50 * cos(2. * M_PI * i / (NOTCH_FILTER_SIZE)); // Hanning //fft_window[i] = 0.54 - 0.46 * cos(2. * M_PI * i / (NOTCH_FILTER_SIZE)); // Hamming } if ( ! dsamples) { // initialize index = NOTCH_DATA_START_SIZE; fltrSig = -1; old1 = old2 = 0; count1 = count2 = -4; memset(data_out, 0, sizeof(double) * NOTCH_DATA_SIZE); memset(data_in, 0, sizeof(double) * NOTCH_DATA_SIZE); memset(average_fft, 0, sizeof(double) * NOTCH_FFT_SIZE); return; } if ( ! quisk_auto_notch) return; // index into FFT data = frequency * 2 * NOTCH_FFT_SIZE / rate // index into filter design = frequency * 2 * NOTCH_FILTER_FFT_SIZE / rate for (inp = 0; inp < nSamples; inp++) { data_in[index] = dsamples[inp]; dsamples[inp] = data_out[index]; if (++index >= NOTCH_DATA_SIZE) { // we have a full FFT of samples index = NOTCH_DATA_START_SIZE; fftw_execute(planFwd); // Calculate forward FFT // Find maximum FFT bins delta_sig = (300 * 2 * NOTCH_FFT_SIZE + rate / 2) / rate; // small frequency interval delta_i1 = (400 * 2 * NOTCH_FFT_SIZE + rate / 2) / rate; // small frequency interval if (sidetone != 0) // For CW, accept a signal at the frequency of the RIT signal = (abs(sidetone) * 2 * NOTCH_FFT_SIZE + rate / 2) / rate; else signal = -999; avg = 1; #if NOTCH_DEBUG dmax = 0; #endif d1 = 0; i1 = 0; // First maximum signal for (i = 0; i < NOTCH_FFT_SIZE; i++) { d = cabs(notch_fft[i]); avg += d; //average_fft[i] = 0.9 * average_fft[i] + 0.1 * d; average_fft[i] = 0.5 * average_fft[i] + 0.5 * d; if (abs(i - signal) > delta_sig && average_fft[i] > d1) { d1 = average_fft[i]; i1 = i; #if NOTCH_DEBUG dmax = d; #endif } } if (abs(i1 - old1) < 3) // See if the maximum bin i1 is changing count1++; else count1--; if (count1 > 4) count1 = 4; else if (count1 < -1) count1 = -1; if (count1 < 0) old1 = i1; avg /= NOTCH_FFT_SIZE; d2 = 0; i2 = 0; // Next maximum signal not near the first for (i = 0; i < NOTCH_FFT_SIZE; i++) { if (abs(i - signal) > delta_sig && abs(i - i1) > delta_i1 && average_fft[i] > d2) { d2 = average_fft[i]; i2 = i; } } if (abs(i2 - old2) < 3) // See if the maximum bin i2 is changing count2++; else count2--; if (count2 > 4) count2 = 4; else if (count2 < -2) count2 = -2; if (count2 < 0) old2 = i2; if (count1 > 0 && count2 > 0) k = i1 + 10000 * i2; // trial filter index else if(count1 > 0) k = i1; else k = 0; // Make the filter if it is different if (fltrSig != k) { fltrSig = k; half_width = (100 * 2 * NOTCH_FILTER_FFT_SIZE + rate / 2) / rate; // half the width of the notch if (half_width < 3) half_width = 3; for (i = 0; i < NOTCH_FILTER_FFT_SIZE; i++) fltr_fft[i] = 1.0; k = (i1 + 2) / 4; // Ratio of index values is 4 #if NOTCH_DEBUG txt = "Fxx"; #endif if (count1 > 0) { #if NOTCH_DEBUG txt = "F1"; #endif for (i = -half_width; i <= half_width; i++) { j = k + i; if (j >= 0 && j < NOTCH_FILTER_FFT_SIZE) fltr_fft[j] = 0.0; } } k = (i2 + 2) / 4; // Ratio of index values is 4 if (count1 > 0 && count2 > 0) { #if NOTCH_DEBUG txt = "F12"; #endif for (i = -half_width; i <= half_width; i++) { j = k + i; if (j >= 0 && j < NOTCH_FILTER_FFT_SIZE) fltr_fft[j] = 0.0; } } fftw_execute(fltrRev); // center the coefficient zero, make the filter symetric, reduce the size by one memmove(fltr_out + NOTCH_FILTER_DESIGN_SIZE / 2 - 1, fltr_out, sizeof(double) * (NOTCH_FILTER_SIZE / 2 - 1)); for (i = NOTCH_FILTER_DESIGN_SIZE / 2 - 2, j = NOTCH_FILTER_DESIGN_SIZE / 2; i >= 0; i--, j++) fltr_out[i] = fltr_out[j]; for (i = 0; i < NOTCH_FILTER_SIZE; i++) fltr_in[i] = fltr_out[i] * fft_window[i] / NOTCH_FILTER_DESIGN_SIZE; for (i = NOTCH_FILTER_SIZE; i < NOTCH_DATA_SIZE; i++) fltr_in[i] = 0.0; fftw_execute(fltrFwd); // The filter is fltr_fft[] } #if NOTCH_DEBUG printf("Max %12.0lf frequency index1 %3d %5d %12.0lf index2 %3d %5d %12.0lf avg %12.0lf %s\n", dmax, count1, i1, d1, count2, i2, d2, avg, txt); #endif for (i = 0; i < NOTCH_FFT_SIZE; i++) // Apply the filter notch_fft[i] *= fltr_fft[i]; fftw_execute(planRev); // Calculate inverse FFT memmove(data_in, data_in + NOTCH_DATA_OUTPUT_SIZE, NOTCH_DATA_START_SIZE * sizeof(double)); for (i = NOTCH_DATA_START_SIZE; i < NOTCH_DATA_SIZE; i++) data_out[i] /= NOTCH_DATA_SIZE / 20; // Empirical } } return; } static int audio_fft_ready=0; static double * audio_average_fft; void quisk_calc_audio_graph(double scale, complex double * csamples, double * dsamples, int nSamples, int real) { // Calculate an FFT for the audio data. Samples are either csamples or dsamples; the other is NULL. // The "scale" is the 0 dB reference. If "real", use the real part of csamples. int i, k, inp; static int index; static int count_fft; static int audio_fft_size; static int audio_fft_count; static fftw_plan plan = NULL; static double * fft_window; static complex double * audio_fft; if ( ! plan) { // malloc new space and initialize index = 0; count_fft = 0; audio_fft_size = data_width; //audio_fft_count = 48000 / audio_fft_size / 5; // Display refresh rate. audio_fft_count = 8000 / audio_fft_size / 5; // Display refresh rate. if (audio_fft_count <= 0) audio_fft_count = 1; fft_window = (double *)malloc(audio_fft_size * sizeof(double)); audio_average_fft = (double *)malloc(audio_fft_size * sizeof(double)); audio_fft = (complex double *)malloc(audio_fft_size * sizeof(complex double)); plan = fftw_plan_dft_1d(audio_fft_size, audio_fft, audio_fft, FFTW_FORWARD, FFTW_MEASURE); for (i = 0; i < audio_fft_size; i++) { audio_average_fft[i] = 0; fft_window[i] = 0.50 - 0.50 * cos(2. * M_PI * i / audio_fft_size); // Hanning window loss 50% } return; } if (audio_fft_ready == 0) { // calculate a new audio FFT if (dsamples || real) // Lyons 2Ed p61 scale *= audio_fft_size / 2.0; else scale *= audio_fft_size; scale *= audio_fft_count; scale *= 0.5; // correct for Hanning window loss for (inp = 0; inp < nSamples; inp++) { if (dsamples) audio_fft[index] = dsamples[inp] / scale; else if (real) audio_fft[index] = creal(csamples[inp]) / scale; else audio_fft[index] = csamples[inp] / scale; if (++index >= audio_fft_size) { // we have a full FFT of samples index = 0; for (i = 0; i < audio_fft_size; i++) audio_fft[i] *= fft_window[i]; // multiply by window fftw_execute(plan); // Calculate forward FFT count_fft++; k = 0; for (i = audio_fft_size / 2; i < audio_fft_size; i++) // Negative frequencies audio_average_fft[k++] += cabs(audio_fft[i]); for (i = 0; i < audio_fft_size / 2; i++) // Positive frequencies audio_average_fft[k++] += cabs(audio_fft[i]); if (count_fft >= audio_fft_count) { audio_fft_ready = 1; count_fft = 0; } } } } } static PyObject * get_audio_graph(PyObject * self, PyObject * args) { int i; double d2; PyObject * tuple2; if (!PyArg_ParseTuple (args, "")) return NULL; if ( ! audio_fft_ready) { // a new graph is not yet available Py_INCREF (Py_None); return Py_None; } tuple2 = PyTuple_New(data_width); for (i = 0; i < data_width; i++) { d2 = audio_average_fft[i]; if (d2 < 1E-10) d2 = 1E-10; d2 = 20.0 * log10(d2); PyTuple_SetItem(tuple2, i, PyFloat_FromDouble(d2)); audio_average_fft[i] = 0; } audio_fft_ready = 0; return tuple2; } static void d_delay(double * dsamples, int nSamples, int bank, int samp_delay) { // delay line (FIFO) to delay dsamples by samp_delay samples int i; double sample; static struct { double * buffer; int index; int buf_size; } delay[MAX_RX_CHANNELS] = {{NULL, 0, 0}}; if ( ! delay[0].buffer) for (i = 1; i < MAX_RX_CHANNELS; i++) delay[i].buffer = NULL; if ( ! delay[bank].buffer) { delay[bank].buffer = (double *)malloc(samp_delay * sizeof(double)); delay[bank].index = 0; delay[bank].buf_size = samp_delay; for (i = 0; i < samp_delay; i++) delay[bank].buffer[i] = 0; } for (i = 0; i < nSamples; i++) { sample = delay[bank].buffer[delay[bank].index]; delay[bank].buffer[delay[bank].index] = dsamples[i]; dsamples[i] = sample; if (++delay[bank].index >= delay[bank].buf_size) delay[bank].index = 0; } } static void ssb_squelch(double * dsamples, int nSamples, int samp_rate, struct _MeasureSquelch * MS) { int i, bw, bw1, bw2, inp; double d, arith_avg, geom_avg, ratio; complex double c; static fftw_plan plan = NULL; static double * fft_window; static complex double * out_fft; #ifdef QUISK_PRINT_LEVELS static int timer = 0; timer += nSamples; #endif if ( ! MS->in_fft) { MS->in_fft = (double *)fftw_malloc(SQUELCH_FFT_SIZE * sizeof(double)); MS->index = 0; MS->sq_open = 0; } if ( ! plan) { // malloc new space and initialize fft_window = (double *)malloc(SQUELCH_FFT_SIZE * sizeof(double)); out_fft = (complex double *)fftw_malloc((SQUELCH_FFT_SIZE / 2 + 1) * sizeof(complex double)); // out_fft[0] is DC, then positive frequencies, then out_fft[N/2] is Nyquist. plan = fftw_plan_dft_r2c_1d(SQUELCH_FFT_SIZE, MS->in_fft, out_fft, FFTW_MEASURE); for (i = 0; i < SQUELCH_FFT_SIZE; i++) fft_window[i] = 0.50 - 0.50 * cos(2. * M_PI * i / SQUELCH_FFT_SIZE); // Hanning window return; } for (inp = 0; inp < nSamples; inp++) { MS->in_fft[MS->index++] = dsamples[inp]; if (MS->index >= SQUELCH_FFT_SIZE) { // we have a full FFT of samples MS->index = 0; for (i = 0; i < SQUELCH_FFT_SIZE; i++) MS->in_fft[i] *= fft_window[i]; // multiply by window fftw_execute_dft_r2c(plan, MS->in_fft, out_fft); // Calculate forward FFT bw = filter_bandwidth[0]; // Calculate the FFT bins within the filter bandwidth if (bw > 3000) bw = 3000; bw1 = 300 * SQUELCH_FFT_SIZE / samp_rate; // start 300 Hz bw2 = (bw + 300) * SQUELCH_FFT_SIZE / samp_rate; // end 300 Hz + bw arith_avg = 0.0; geom_avg = 0.0; for (i = bw1; i < bw2; i++) { c = out_fft[i] / CLIP16; d = creal(c) * creal(c) + cimag(c) * cimag(c); if (d > 1E-4) { arith_avg += d; geom_avg += log(d); } } #ifdef QUISK_PRINT_SPECTRUM // Combine FFT into spectral bands int j; for (i = 0; i < 128; i += 16) { d = 0; for (j = i; j < i + 16; j++) { c = out_fft[i] / CLIP16; d += creal(c) * creal(c) + cimag(c) * cimag(c); } d = log(d / 16); printf ("%12.3f", d); if (i == 112) printf("\n"); } #endif if (arith_avg > 1E-4) { bw = bw2 - bw1; arith_avg = log(arith_avg / bw); geom_avg /= bw; ratio = arith_avg - geom_avg; } else { ratio = 1.0; } // For band noise, ratio is 0.57 if (ratio > ssb_squelch_level * 0.005) MS->sq_open = samp_rate; // one second timer #ifdef QUISK_PRINT_LEVELS if (timer >= samp_rate / 2) { timer = 0; printf ("squelch %6d A %6.3f G %6.3f A-G %6.3f\n", MS->sq_open, arith_avg, geom_avg, ratio); #ifdef QUISK_PRINT_SPECTRUM for (i = 0; i < 128; i += 16) printf ("%5d - %4d", i * samp_rate / SQUELCH_FFT_SIZE, (i + 16) * samp_rate / SQUELCH_FFT_SIZE); printf ("\n"); #endif } #endif } } MS->sq_open -= nSamples; if (MS->sq_open < 0) MS->sq_open = 0; MS->squelch_active = MS->sq_open == 0; } static complex double dRxFilterOut(complex double sample, int bank, int nFilter) { // Rx FIR filter; bank is the static storage index, and must be different for different data streams. // Multiple filters are at nFilter. complex double cx; int j, k; static int init = 0; static struct stStorage { int indexFilter; // current index into sample buffer complex double bufFilterC[MAX_FILTER_SIZE]; // Digital filter sample buffer } Storage[MAX_RX_CHANNELS]; struct stStorage * ptBuf = Storage + bank; double * filtI; if ( ! init) { init = 1; for (j = 0; j < MAX_RX_CHANNELS; j++) memset(Storage + j, 0, sizeof(struct stStorage)); } if ( ! sizeFilter) return sample; if (ptBuf->indexFilter >= sizeFilter) ptBuf->indexFilter = 0; ptBuf->bufFilterC[ptBuf->indexFilter] = sample; cx = 0; filtI = cFilterI[nFilter]; j = ptBuf->indexFilter; for (k = 0; k < sizeFilter; k++) { cx += ptBuf->bufFilterC[j] * filtI[k]; if (++j >= sizeFilter) j = 0; } ptBuf->indexFilter++; return cx; } complex double cRxFilterOut(complex double sample, int bank, int nFilter) { // Rx FIR filter; bank is the static storage index, and must be different for different data streams. // Multiple filters are at nFilter. double accI, accQ; double * filtI, * filtQ; int j, k; static int init = 0; static struct stStorage { int indexFilter; // current index into sample buffer double bufFilterI[MAX_FILTER_SIZE]; // Digital filter sample buffer double bufFilterQ[MAX_FILTER_SIZE]; // Digital filter sample buffer } Storage[MAX_RX_CHANNELS]; struct stStorage * ptBuf = Storage + bank; if ( ! init) { init = 1; for (j = 0; j < MAX_RX_CHANNELS; j++) memset(Storage + j, 0, sizeof(struct stStorage)); } if ( ! sizeFilter) return sample; if (ptBuf->indexFilter >= sizeFilter) ptBuf->indexFilter = 0; ptBuf->bufFilterI[ptBuf->indexFilter] = creal(sample); ptBuf->bufFilterQ[ptBuf->indexFilter] = cimag(sample); filtI = cFilterI[nFilter]; filtQ = cFilterQ[nFilter]; accI = accQ = 0; j = ptBuf->indexFilter; for (k = 0; k < sizeFilter; k++) { accI += ptBuf->bufFilterI[j] * filtI[k]; accQ += ptBuf->bufFilterQ[j] * filtQ[k]; if (++j >= sizeFilter) j = 0; } ptBuf->indexFilter++; return accI + I * accQ; } static void AddTestTone(complex double * cSamples, int nSamples) { int i; static complex double testtoneVector = 21474836.47; // -40 dB static complex double audioVector = 1.0; complex double audioPhase; switch (rxMode) { default: //testtonePhase = cexp(I * 2 * M_PI * (quisk_sidetoneCtrl - 500) / 1000.0); for (i = 0; i < nSamples; i++) { cSamples[i] += testtoneVector; testtoneVector *= testtonePhase; } break; case AM: // AM //audioPhase = cexp(I * 2 * M_PI * quisk_sidetoneCtrl * 5 / sample_rate); audioPhase = cexp(I * 2.0 * M_PI * 1000 / quisk_sound_state.sample_rate); for (i = 0; i < nSamples; i++) { cSamples[i] += testtoneVector * (1.0 + creal(audioVector)); testtoneVector *= testtonePhase; audioVector *= audioPhase; } break; case FM: // FM case DGT_FM: //audioPhase = cexp(I * 2 * M_PI * quisk_sidetoneCtrl * 5 / sample_rate); audioPhase = cexp(I * 2.0 * M_PI * 1000 / quisk_sound_state.sample_rate); for (i = 0; i < nSamples; i++) { cSamples[i] += testtoneVector * cexp(I * creal(audioVector)); testtoneVector *= testtonePhase; audioVector *= audioPhase; } break; } } static int IsSquelch(int freq) { // measure the signal level for squelch int i, i1, i2, iBandwidth; double meter; // This uses current_graph with width data_width iBandwidth = 5000 * data_width / fft_sample_rate; // bandwidth determines number of pixels to average if (iBandwidth < 1) iBandwidth = 1; i1 = (int)((double)freq * data_width / fft_sample_rate + data_width / 2.0 - iBandwidth / 2.0 + 0.5); i2 = i1 + iBandwidth; meter = 0; if (i1 >= 0 && i2 < data_width) { // too close to edge? for (i = i1; i < i2; i++) meter += current_graph[i]; } meter /= iBandwidth; if (meter == 0 || meter < squelch_level) return 1; // meter == 0 means Rx freq is off-screen so squelch is on else return 0; } static PyObject * set_record_state(PyObject * self, PyObject * args) { // called when a Record or Play button is pressed, or with -1 to poll int button; if (!PyArg_ParseTuple (args, "i", &button)) return NULL; switch (button) { case 0: // press record radio case 4: // press record microphone if ( ! quisk_record_buffer) { // initialize quisk_record_bufsize = (int)(QuiskGetConfigDouble("max_record_minutes", 0.25) * quisk_sound_state.playback_rate * 60.0 + 0.2); quisk_record_buffer = (float *)malloc(sizeof(float) * quisk_record_bufsize); } quisk_record_index = 0; quisk_play_index = 0; quisk_mic_index = 0; quisk_record_full = 0; if (button == 0) quisk_record_state = RECORD_RADIO; else quisk_record_state = RECORD_MIC; break; case 1: // release record quisk_record_state = IDLE; break; case 2: // press play if (quisk_record_full) { quisk_play_index = quisk_record_index + 1; if (quisk_play_index >= quisk_record_bufsize) quisk_play_index = 0; } else { quisk_play_index = 0; } quisk_mic_index = quisk_play_index; quisk_record_state = PLAYBACK; break; case 3: // release play quisk_record_state = IDLE; break; case 5: // press play file fseek (wavFpSound, wavStart, SEEK_SET); fseek (wavFpMic, wavStart, SEEK_SET); quisk_record_state = PLAY_FILE; break; case 6: // press play samples file fseek (wavFpSound, wavStart, SEEK_SET); quisk_record_state = PLAY_SAMPLES; break; } return PyInt_FromLong(quisk_record_state != PLAYBACK && quisk_record_state != PLAY_FILE && quisk_record_state != PLAY_SAMPLES); } void quisk_tmp_record(complex double * cSamples, int nSamples, double scale) // save sound { int i; for (i = 0; i < nSamples; i++) { quisk_record_buffer[quisk_record_index++] = creal(cSamples[i]) * scale; if (quisk_record_index >= quisk_record_bufsize) { quisk_record_index = 0; quisk_record_full = 1; } } } void quisk_tmp_playback(complex double * cSamples, int nSamples, double volume) { // replace radio sound with saved sound int i; double d; for (i = 0; i < nSamples; i++) { d = quisk_record_buffer[quisk_play_index++] * volume; cSamples[i] = d + I * d; if (quisk_play_index >= quisk_record_bufsize) quisk_play_index = 0; if (quisk_play_index == quisk_record_index) { quisk_record_state = IDLE; return; } } } void quisk_tmp_microphone(complex double * cSamples, int nSamples) { // replace microphone samples with saved sound int i; double d; for (i = 0; i < nSamples; i++) { d = quisk_record_buffer[quisk_mic_index++]; cSamples[i] = d + I * d; if (quisk_mic_index >= quisk_record_bufsize) quisk_mic_index = 0; if (quisk_mic_index == quisk_record_index) { quisk_record_state = IDLE; return; } } } static PyObject * open_wav_file_play(PyObject * self, PyObject * args) { // The WAV file must be recorded at 48000 Hertz in S16_LE format monophonic for audio files. // The WAV file must be recorded at the sample_rate in IEEE format stereo for the I/Q samples file. const char * fname; char name[5]; int size, rate=0; if (!PyArg_ParseTuple (args, "s", &fname)) return NULL; if (wavFpMic) fclose(wavFpMic); if (wavFpSound) fclose(wavFpSound); wavFpSound = wavFpMic = NULL; wavFpSound = fopen(fname, "rb"); if (!wavFpSound) { printf("open wav file failed\n"); return PyInt_FromLong(-1); } wavStart = 0; while (1) { if (fread (name, 4, 1, wavFpSound) != 1) break; if (fread (&size, 4, 1, wavFpSound) != 1) break; name[4] = 0; // printf("name %s size %d\n", name, size); if (!strncmp(name, "RIFF", 4)) fseek (wavFpSound, 4, SEEK_CUR); // Skip "WAVE" else if (!strncmp(name, "fmt ", 4)) { // format data starts here if (fread (&rate, 4, 1, wavFpSound) != 1) // skip these fields break; if (fread (&rate, 4, 1, wavFpSound) != 1) // sample rate break; //printf ("rate %d\n", rate); fseek (wavFpSound, size - 8, SEEK_CUR); // skip remainder } else if (!strncmp(name, "data", 4)) { // sound data starts here wavStart = ftell(wavFpSound); break; } else // Skip other records fseek (wavFpSound, size, SEEK_CUR); } if (!wavStart) { // Failure to find "data" record fclose(wavFpSound); wavFpSound = NULL; printf("open wav failed to find the data chunk\n"); return PyInt_FromLong(-2); } wavFpMic = fopen(fname, "rb"); if (!wavFpMic) { printf("open microphone wav file failed\n"); wavFpSound = NULL; return PyInt_FromLong(-4); } return PyInt_FromLong(rate); } void quisk_file_playback(complex double * cSamples, int nSamples, double volume) { // Replace radio sound by file samples. // The sample rate must equal quisk_sound_state.mic_sample_rate. int i; short sh; double d; if (wavFpSound) { for (i = 0; i < nSamples; i++) { if (fread(&sh, 2, 1, wavFpSound) != 1) { quisk_record_state = IDLE; break; } d = sh * ((double)CLIP32 / CLIP16) * volume; cSamples[i] = d + I * d; } } } void quisk_play_samples(complex double * cSamples, int nSamples) { int i; float fre, fim; if (wavFpSound) { for (i = 0; i < nSamples; i++) { if (fread(&fre, 4, 1, wavFpSound) != 1 || fread(&fim, 4, 1, wavFpSound) != 1) { quisk_record_state = IDLE; break; } fre *= CLIP32; fim *= CLIP32; cSamples[i] = fre + I * fim; } } } #define BUF2CHAN_SIZE 12000 static int Buffer2Chan(double * samp1, int count1, double * samp2, int count2) { // return the minimum of count1 and count2, buffering as necessary int nout; static int nbuf1=0, nbuf2=0; static double buf1[BUF2CHAN_SIZE], buf2[BUF2CHAN_SIZE]; if (samp1 == NULL) { // initialize nbuf1 = nbuf2 = 0; return 0; } if (nbuf1 == 0 && nbuf2 == 0 && count1 == count2) // nothing to do return count1; if (count1 + nbuf1 >= BUF2CHAN_SIZE || count2 + nbuf2 >= BUF2CHAN_SIZE) { // overflow if (DEBUG || DEBUG_IO) printf("Overflow in Buffer2Chan nbuf1 %d nbuf2 %d size %d\n", nbuf1, nbuf2, BUF2CHAN_SIZE); nbuf1 = nbuf2 = 0; } memcpy(buf1 + nbuf1, samp1, count1 * sizeof(double)); // add samples to buffer nbuf1 += count1; memcpy(buf2 + nbuf2, samp2, count2 * sizeof(double)); nbuf2 += count2; if (nbuf1 <= nbuf2) nout = nbuf1; // number of samples to output else nout = nbuf2; //if (count1 + nbuf1 >= 2000 || count2 + nbuf2 >= 2000) // printf("Buffer2Chan nbuf1 %d nbuf2 %d nout %d\n", nbuf1, nbuf2, nout); memcpy(samp1, buf1, nout * sizeof(double)); // output samples nbuf1 -= nout; memmove(buf1, buf1 + nout, nbuf1 * sizeof(double)); memcpy(samp2, buf2, nout * sizeof(double)); nbuf2 -= nout; memmove(buf2, buf2 + nout, nbuf2 * sizeof(double)); return nout; } void quisk_file_microphone(complex double * cSamples, int nSamples) { // Replace mic samples by file samples. // The sample rate must equal quisk_sound_state.mic_sample_rate. int i; short sh; double d; if (wavFpMic) { for (i = 0; i < nSamples; i++) { if (fread(&sh, 2, 1, wavFpMic) != 1) { quisk_record_state = IDLE; break; } d = sh * ((double)CLIP32 / CLIP16); cSamples[i] = d + I * d; } } } int PlanDecimation(int * pt2, int * pt3, int * pt5) // search for a suitable decimation scheme { int i, best, try, i2, i3, i5, decim2, decim3, decim5; best = quisk_sound_state.sample_rate; decim2 = decim3 = decim5 = 0; for (i2 = 0; i2 <= 6; i2++) { // limit to number of /2 filters, currently 6 for (i3 = 0; i3 <= 3; i3++) { // limit to number of /3 filters, currently 3 for (i5 = 0; i5 <= 3; i5++) { // limit to number of /5 filters, currently 3 try = quisk_sound_state.sample_rate; for (i = 0; i < i2; i++) try /= 2; for (i = 0; i < i3; i++) try /= 3; for (i = 0; i < i5; i++) try /= 5; if (try >= 48000 && try < best) { decim2 = i2; decim3 = i3; decim5 = i5; best = try; } } } } if (best >= 50000) // special rate converter best = best * 24 / 25; if (DEBUG) printf ("Plan Decimation: rate %i, best %i, decim2 %i, decim3 %i, decim5 %i\n", quisk_sound_state.sample_rate, best, decim2, decim3, decim5); if (best > 72000) printf("Failure to plan a suitable decimation in quisk_process_decimate\n"); if (pt2) { // return decimations *pt2 = decim2; *pt3 = decim3; *pt5 = decim5; } return best; } static int quisk_process_decimate(complex double * cSamples, int nSamples, int bank, rx_mode_type rx_mode) { // Changes here will require changes to get_filter_rate(); int i, i2, i3, i5; static int decim2, decim3, decim5; static int old_rate = 0; static struct stStorage { struct quisk_cHB45Filter HalfBand1; struct quisk_cHB45Filter HalfBand2; struct quisk_cHB45Filter HalfBand3; struct quisk_cHB45Filter HalfBand4; struct quisk_cHB45Filter HalfBand5; struct quisk_cFilter filtSdriq111; struct quisk_cFilter filtSdriq53; struct quisk_cFilter filtSdriq133; struct quisk_cFilter filtSdriq167; struct quisk_cFilter filtSdriq185; struct quisk_cFilter filtDecim3; struct quisk_cFilter filtDecim3B; struct quisk_cFilter filtDecim3C; struct quisk_cFilter filtDecim5; struct quisk_cFilter filtDecim5B; struct quisk_cFilter filtDecim5S; struct quisk_cFilter filtDecim48to24; struct quisk_cFilter filtI3D25; struct quisk_cFilter filt300D5; } Storage[MAX_RX_CHANNELS] ; if ( ! cSamples) { // Initialize all filters for (i = 0; i < MAX_RX_CHANNELS; i++) { memset(&Storage[i].HalfBand1, 0, sizeof(struct quisk_cHB45Filter)); memset(&Storage[i].HalfBand2, 0, sizeof(struct quisk_cHB45Filter)); memset(&Storage[i].HalfBand3, 0, sizeof(struct quisk_cHB45Filter)); memset(&Storage[i].HalfBand4, 0, sizeof(struct quisk_cHB45Filter)); memset(&Storage[i].HalfBand5, 0, sizeof(struct quisk_cHB45Filter)); quisk_filt_cInit(&Storage[i].filtSdriq111, quiskFilt111D2Coefs, sizeof(quiskFilt111D2Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtSdriq53, quiskFilt53D1Coefs, sizeof(quiskFilt53D1Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtSdriq133, quiskFilt133D2Coefs, sizeof(quiskFilt133D2Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtSdriq167, quiskFilt167D3Coefs, sizeof(quiskFilt167D3Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtSdriq185, quiskFilt185D3Coefs, sizeof(quiskFilt185D3Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim3, quiskFilt144D3Coefs, sizeof(quiskFilt144D3Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim3B, quiskFilt144D3Coefs, sizeof(quiskFilt144D3Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim3C, quiskFilt144D3Coefs, sizeof(quiskFilt144D3Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim5, quiskFilt240D5CoefsSharp, sizeof(quiskFilt240D5CoefsSharp)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim5B, quiskFilt240D5CoefsSharp, sizeof(quiskFilt240D5CoefsSharp)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim5S, quiskFilt240D5CoefsSharp, sizeof(quiskFilt240D5CoefsSharp)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim48to24, quiskFilt48dec24Coefs, sizeof(quiskFilt48dec24Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtI3D25, quiskFiltI3D25Coefs, sizeof(quiskFiltI3D25Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filt300D5, quiskFilt300D5Coefs, sizeof(quiskFilt300D5Coefs)/sizeof(double)); } return 0; } if (quisk_sound_state.sample_rate != old_rate) { old_rate = quisk_sound_state.sample_rate; PlanDecimation(&decim2, &decim3, &decim5); } // Decimate: Lower the sample rate to 48000 sps (or approx). Filters are designed for // a pass bandwidth of 20 kHz and a stop bandwidth of 24 kHz. // We use 48 ksps to accommodate wide digital modes. switch((quisk_sound_state.sample_rate + 100) / 1000) { case 41: quisk_decim_srate = 48000; break; case 53: // SDR-IQ quisk_decim_srate = quisk_sound_state.sample_rate; nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtSdriq53, 1); break; case 111: // SDR-IQ quisk_decim_srate = quisk_sound_state.sample_rate / 2; nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtSdriq111, 2); break; case 133: // SDR-IQ quisk_decim_srate = quisk_sound_state.sample_rate / 2; nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtSdriq133, 2); break; case 185: // SDR-IQ quisk_decim_srate = quisk_sound_state.sample_rate / 3; nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtSdriq185, 3); break; case 370: quisk_decim_srate = quisk_sound_state.sample_rate / 6; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand2); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtSdriq185, 3); break; case 740: quisk_decim_srate = quisk_sound_state.sample_rate / 12; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand2); nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand3); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtSdriq185, 3); break; case 1333: quisk_decim_srate = quisk_sound_state.sample_rate / 24; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand1); nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand2); nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand3); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtSdriq167, 3); break; default: quisk_decim_srate = quisk_sound_state.sample_rate; i2 = decim2; // decimate by 2 except for the final /2 filter if (i2 > 1) { nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand1); quisk_decim_srate /= 2; i2--; } if (i2 > 1) { nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand2); quisk_decim_srate /= 2; i2--; } if (i2 > 1) { nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand3); quisk_decim_srate /= 2; i2--; } if (i2 > 1) { nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand4); quisk_decim_srate /= 2; i2--; } if (i2 > 1) { nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand5); quisk_decim_srate /= 2; i2--; } i3 = decim3; // decimate by 3 if (i3 > 0) { nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim3, 3); quisk_decim_srate /= 3; i3--; } if (i3 > 0) { nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim3B, 3); quisk_decim_srate /= 3; i3--; } if (i3 > 0) { nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim3C, 3); quisk_decim_srate /= 3; i3--; } i5 = decim5; // decimate by 5 if (i5 > 0) { nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim5, 5); quisk_decim_srate /= 5; i5--; } if (i5 > 0) { nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim5B, 5); quisk_decim_srate /= 5; i5--; } if (i5 > 0) { nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim5S, 5); quisk_decim_srate /= 5; i5--; } if (i2 > 0) { // decimate by 2 last - Unnecessary??? nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to24, 2); quisk_decim_srate /= 2; i2--; } if (quisk_decim_srate >= 50000) { quisk_decim_srate = quisk_decim_srate * 24 / 25; nSamples = quisk_cInterpDecim(cSamples, nSamples, &Storage[bank].filt300D5, 6, 5); // 60 kSps nSamples = quisk_cInterpDecim(cSamples, nSamples, &Storage[bank].filtDecim5S, 4, 5); // 48 kSps } if (i2 != 0 || i3 != 0 || i5 != 0) printf ("Failure in quisk.c in integer decimation for rate %d\n", quisk_sound_state.sample_rate); if (DEBUG && quisk_decim_srate != 48000) printf("Failure to achieve rate 48000. Rate is %i\n", quisk_decim_srate); break; } return nSamples; } static int quisk_process_demodulate(complex double * cSamples, double * dsamples, int nSamples, int bank, int nFilter, rx_mode_type rx_mode) { // Changes here will require changes to get_filter_rate(); int i; complex double cx, cpx; double d, di, dd; static struct AgcState Agc1 = {0.3, 16000, 0}, Agc2 = {0.3, 16000, 0}; static struct stStorage { complex double fm_1; // Sample delayed by one double dc_remove; // DC removal for AM double FM_www; double FM_nnn, FM_a_0, FM_a_1, FM_b_1, FM_x_1, FM_y_1; // filter for FM struct quisk_cHB45Filter HalfBand4; struct quisk_cHB45Filter HalfBand5; struct quisk_dHB45Filter HalfBand6; struct quisk_dHB45Filter HalfBand7; struct quisk_dFilter filtAudio24p3; struct quisk_dFilter filtAudio24p4; struct quisk_dFilter filtAudio12p2; struct quisk_dFilter filtAudio24p6; struct quisk_dFilter filtAudioFmHp; struct quisk_cFilter filtDecim16to8; struct quisk_cFilter filtDecim48to24; struct quisk_cFilter filtDecim48to16; } Storage[MAX_RX_CHANNELS] ; if ( ! cSamples) { // Initialize all filters for (i = 0; i < MAX_RX_CHANNELS; i++) { memset(&Storage[i].HalfBand4, 0, sizeof(struct quisk_cHB45Filter)); memset(&Storage[i].HalfBand5, 0, sizeof(struct quisk_cHB45Filter)); memset(&Storage[i].HalfBand6, 0, sizeof(struct quisk_dHB45Filter)); memset(&Storage[i].HalfBand7, 0, sizeof(struct quisk_dHB45Filter)); quisk_filt_dInit(&Storage[i].filtAudio24p3, quiskAudio24p3Coefs, sizeof(quiskAudio24p3Coefs)/sizeof(double)); quisk_filt_dInit(&Storage[i].filtAudio24p4, quiskAudio24p4Coefs, sizeof(quiskAudio24p4Coefs)/sizeof(double)); quisk_filt_dInit(&Storage[i].filtAudio12p2, quiskAudio24p4Coefs, sizeof(quiskAudio24p4Coefs)/sizeof(double)); quisk_filt_dInit(&Storage[i].filtAudio24p6, quiskAudio24p6Coefs, sizeof(quiskAudio24p6Coefs)/sizeof(double)); quisk_filt_dInit(&Storage[i].filtAudioFmHp, quiskAudioFmHpCoefs, sizeof(quiskAudioFmHpCoefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim16to8, quiskFilt16dec8Coefs, sizeof(quiskFilt16dec8Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim48to24, quiskFilt48dec24Coefs, sizeof(quiskFilt48dec24Coefs)/sizeof(double)); quisk_filt_cInit(&Storage[i].filtDecim48to16, quiskAudio24p3Coefs, sizeof(quiskAudio24p3Coefs)/sizeof(double)); Storage[i].fm_1 = 10; Storage[i].FM_www = tan(M_PI * FM_FILTER_DEMPH / 48000); // filter for FM at 48 ksps Storage[i].FM_nnn = 1.0 / (1.0 + Storage[i].FM_www); Storage[i].FM_a_0 = Storage[i].FM_www * Storage[i].FM_nnn; Storage[i].FM_a_1 = Storage[i].FM_a_0; Storage[i].FM_b_1 = Storage[i].FM_nnn * (Storage[i].FM_www - 1.0); //printf ("dsamples[i] = y_1 = di * %12.6lf + x_1 * %12.6lf - y_1 * %12.6lf\n", FM_a_0, FM_a_1, FM_b_1); } return 0; } //quisk_calc_audio_graph(pow(2, 31) - 1, cSamples, NULL, nSamples, 0); // Filter and demodulate signal, copy capture buffer cSamples to play buffer dsamples. // quisk_decim_srate is the sample rate after integer decimation. MeasureSquelch[bank].squelch_active = 0; switch(rx_mode) { case CWL: // lower sideband CW at 6 ksps quisk_filter_srate = quisk_decim_srate / 8; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand5); nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand4); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to24, 2); for (i = 0; i < nSamples; i++) { cx = cRxFilterOut(cSamples[i], bank, nFilter); dsamples[i] = dd = creal(cx) + cimag(cx); if(bank == 0) { measure_audio_sum += dd * dd; measure_audio_count += 1; } } if(bank == 0) dAutoNotch(dsamples, nSamples, rit_freq, quisk_filter_srate); nSamples = quisk_dInterpolate(dsamples, nSamples, &Storage[bank].filtAudio12p2, 2); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand6); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand7); break; case CWU: // upper sideband CW at 6 ksps quisk_filter_srate = quisk_decim_srate / 8; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand5); nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand4); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to24, 2); for (i = 0; i < nSamples; i++) { cx = cRxFilterOut(cSamples[i], bank, nFilter); dsamples[i] = dd = creal(cx) - cimag(cx); if(bank == 0) { measure_audio_sum += dd * dd; measure_audio_count += 1; } } if(bank == 0) dAutoNotch(dsamples, nSamples, rit_freq, quisk_filter_srate); nSamples = quisk_dInterpolate(dsamples, nSamples, &Storage[bank].filtAudio12p2, 2); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand6); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand7); break; case LSB: // lower sideband SSB at 12 ksps quisk_filter_srate = quisk_decim_srate / 4; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand5); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to24, 2); for (i = 0; i < nSamples; i++) { cx = cRxFilterOut(cSamples[i], bank, nFilter); dsamples[i] = dd = creal(cx) + cimag(cx); if(bank == 0) { measure_audio_sum += dd * dd; measure_audio_count += 1; } } if(bank == 0) dAutoNotch(dsamples, nSamples, 0, quisk_filter_srate); if (ssb_squelch_enabled) { ssb_squelch(dsamples, nSamples, quisk_filter_srate, MeasureSquelch + bank); d_delay(dsamples, nSamples, bank, SQUELCH_FFT_SIZE); } quisk_calc_audio_graph(pow(2, 31) - 1, NULL, dsamples, nSamples, 1); nSamples = quisk_dInterpolate(dsamples, nSamples, &Storage[bank].filtAudio24p4, 2); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand7); //quisk_calc_audio_graph(pow(2, 31) - 1, NULL, dsamples, nSamples, 1); break; case USB: // upper sideband SSB at 12 ksps default: quisk_filter_srate = quisk_decim_srate / 4; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand5); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to24, 2); for (i = 0; i < nSamples; i++) { cx = cRxFilterOut(cSamples[i], bank, nFilter); dsamples[i] = dd = creal(cx) - cimag(cx); if(bank == 0) { measure_audio_sum += dd * dd; measure_audio_count += 1; } } if(bank == 0) dAutoNotch(dsamples, nSamples, 0, quisk_filter_srate); if (ssb_squelch_enabled) { ssb_squelch(dsamples, nSamples, quisk_filter_srate, MeasureSquelch + bank); d_delay(dsamples, nSamples, bank, SQUELCH_FFT_SIZE); } nSamples = quisk_dInterpolate(dsamples, nSamples, &Storage[bank].filtAudio24p4, 2); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand7); //quisk_calc_audio_graph(pow(2, 31) - 1, NULL, dsamples, nSamples, 1); break; case AM: // AM at 24 ksps quisk_filter_srate = quisk_decim_srate / 2; nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to24, 2); for (i = 0; i < nSamples; i++) { cx = dRxFilterOut(cSamples[i], bank, nFilter); di = cabs(cx); d = di + Storage[bank].dc_remove * 0.99; // DC removal; R.G. Lyons page 553 di = d - Storage[bank].dc_remove; Storage[bank].dc_remove = d; dsamples[i] = di; if(bank == 0) { measure_audio_sum += di * di; measure_audio_count += 1; } } nSamples = quisk_dFilter(dsamples, nSamples, &Storage[bank].filtAudio24p6); if(bank == 0) dAutoNotch(dsamples, nSamples, 0, quisk_filter_srate); if (ssb_squelch_enabled) { ssb_squelch(dsamples, nSamples, quisk_filter_srate, MeasureSquelch + bank); d_delay(dsamples, nSamples, bank, SQUELCH_FFT_SIZE); } nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand7); break; case FM: // FM at 48 ksps case DGT_FM: quisk_filter_srate = quisk_decim_srate; for (i = 0; i < nSamples; i++) { cx = dRxFilterOut(cSamples[i], bank, nFilter); MeasureSquelch[bank].rf_sum += cabs(cx); MeasureSquelch[bank].rf_count += 1; cpx = cx * conj(Storage[bank].fm_1); Storage[bank].fm_1 = cx; di = quisk_filter_srate * carg(cpx); // FM de-emphasis dsamples[i] = dd = Storage[bank].FM_y_1 = di * Storage[bank].FM_a_0 + Storage[bank].FM_x_1 * Storage[bank].FM_a_1 - Storage[bank].FM_y_1 * Storage[bank].FM_b_1; Storage[bank].FM_x_1 = di; if(bank == 0) { measure_audio_sum += dd * dd; measure_audio_count += 1; } } nSamples = quisk_dDecimate(dsamples, nSamples, &Storage[bank].filtAudio24p3, 2); nSamples = quisk_dFilter(dsamples, nSamples, &Storage[bank].filtAudioFmHp); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand6); if(bank == 0) dAutoNotch(dsamples, nSamples, 0, quisk_filter_srate); if (MeasureSquelch[bank].rf_count >= 2400) { MeasureSquelch[bank].squelch = MeasureSquelch[bank].rf_sum / MeasureSquelch[bank].rf_count / CLIP32; if (MeasureSquelch[bank].squelch > 1.E-10) MeasureSquelch[bank].squelch = 20 * log10(MeasureSquelch[bank].squelch); else MeasureSquelch[bank].squelch = -200.0; MeasureSquelch[bank].rf_sum = MeasureSquelch[bank].rf_count = 0; //if (bank == 0) printf("MeasureSquelch %.5f\n", MeasureSquelch[0].squelch); } MeasureSquelch[bank].squelch_active = MeasureSquelch[bank].squelch < squelch_level; break; case DGT_U: // digital mode DGT-U at 48 ksps if (filter_bandwidth[nFilter] < DGT_NARROW_FREQ) { // filter at 6 ksps quisk_filter_srate = quisk_decim_srate / 8; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand5); nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand4); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to24, 2); } else { // filter at 48 ksps quisk_filter_srate = quisk_decim_srate; } for (i = 0; i < nSamples; i++) { cx = cRxFilterOut(cSamples[i], bank, nFilter); dsamples[i] = dd = creal(cx) - cimag(cx); if(bank == 0) { measure_audio_sum += dd * dd; measure_audio_count += 1; } } if(bank == 0) dAutoNotch(dsamples, nSamples, 0, quisk_filter_srate); if (filter_bandwidth[nFilter] < DGT_NARROW_FREQ) { nSamples = quisk_dInterpolate(dsamples, nSamples, &Storage[bank].filtAudio12p2, 2); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand6); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand7); } break; case DGT_L: // digital mode DGT-L if (filter_bandwidth[nFilter] < DGT_NARROW_FREQ) { // filter at 6 ksps quisk_filter_srate = quisk_decim_srate / 8; nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand5); nSamples = quisk_cDecim2HB45(cSamples, nSamples, &Storage[bank].HalfBand4); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to24, 2); } else { // filter at 48 ksps quisk_filter_srate = quisk_decim_srate; } for (i = 0; i < nSamples; i++) { cx = cRxFilterOut(cSamples[i], bank, nFilter); dsamples[i] = dd = creal(cx) + cimag(cx); if(bank == 0) { measure_audio_sum += dd * dd; measure_audio_count += 1; } } if(bank == 0) dAutoNotch(dsamples, nSamples, 0, quisk_filter_srate); if (filter_bandwidth[nFilter] < DGT_NARROW_FREQ) { nSamples = quisk_dInterpolate(dsamples, nSamples, &Storage[bank].filtAudio12p2, 2); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand6); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand7); } break; case DGT_IQ: // digital mode DGT-IQ at 48 ksps quisk_filter_srate = quisk_decim_srate; if (filter_bandwidth[nFilter] < 19000) { // No filtering for wide bandwidth for (i = 0; i < nSamples; i++) cSamples[i] = dRxFilterOut(cSamples[i], bank, nFilter); } if(bank == 0) { for (i = 0; i < nSamples; i++) { measure_audio_sum = measure_audio_sum + cSamples[i] * conj(cSamples[i]); measure_audio_count += 1; } } break; case FDV_U: // digital voice at 8 ksps case FDV_L: quisk_check_freedv_mode(); nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim48to16, 3); if (bank == 0) process_agc(&Agc1, cSamples, nSamples, 1); else process_agc(&Agc2, cSamples, nSamples, 1); if(bank == 0) dAutoNotch(dsamples, nSamples, 0, quisk_decim_srate / 3); // Perhaps decimate by an additional fraction if (quisk_decim_srate != 48000) { dd = quisk_decim_srate / 48000.0; nSamples = cFracDecim(cSamples, nSamples, dd); quisk_decim_srate = 48000; } quisk_filter_srate =8000; nSamples = quisk_cDecimate(cSamples, nSamples, &Storage[bank].filtDecim16to8, 2); if (pt_quisk_freedv_rx) nSamples = (* pt_quisk_freedv_rx)(cSamples, dsamples, nSamples, bank); if(bank == 0) { for (i = 0; i < nSamples; i++) { measure_audio_sum += dsamples[i] * dsamples[i]; measure_audio_count += 1; } } nSamples = quisk_dInterpolate(dsamples, nSamples, &Storage[bank].filtAudio24p3, 3); nSamples = quisk_dInterp2HB45(dsamples, nSamples, &Storage[bank].HalfBand7); break; } if (bank == 0 && measure_audio_count >= quisk_filter_srate * measure_audio_time) { measured_audio = sqrt(measure_audio_sum / measure_audio_count) / CLIP32 * 1e6; measure_audio_sum = measure_audio_count = 0; } return nSamples; } static void process_agc(struct AgcState * dat, complex double * csamples, int count, int is_cpx) { int i; double out_magn, buf_magn, dtmp, clip_gain; complex double csample; #if DEBUG static int printit=0; static double maxout=1; char * clip; #endif if ( ! dat->buf_size) { // initialize if (dat->sample_rate == 0) dat->sample_rate = quisk_sound_state.playback_rate; dat->buf_size = dat->sample_rate * AGC_DELAY / 1000; // total delay in samples //printf("play rate %d buf_size %d\n", dat->sample_rate, dat->buf_size); dat->index_read = 0; // Index to output; and then write a new sample here dat->index_start = 0; // Start index for measure of maximum sample dat->is_clipping = 0; // Are we decreasing gain to handle a clipping condition? dat->themax = 1.0; // Maximum sample in the buffer dat->gain = 100; // Current output gain dat->delta = 0; // Amount to change dat->gain at each sample dat->target_gain = 100; // Move to this gain unless we clip dat->time_release = 1.0 - exp( - 1.0 / dat->sample_rate / agc_release_time); // long time constant for AGC release dat->c_samp = (complex double *) malloc(dat->buf_size * sizeof(complex double)); // buffer for complex samples for (i = 0; i < dat->buf_size; i++) dat->c_samp[i] = 0; return; } for (i = 0; i < count; i++) { csample = csamples[i]; csamples[i] = dat->c_samp[dat->index_read] * dat->gain; // FIFO output if (is_cpx) out_magn = cabs(csamples[i]); else out_magn = fabs(creal(csamples[i])); //if(dat->is_clipping == 1) //printf(" index %5d out_magn %.5lf gain %.2lf delta %.5lf\n",dat->index_read, out_magn / CLIP32, dat->gain, dat->delta); #if DEBUG if (out_magn > maxout) maxout = out_magn; #endif if (out_magn > CLIP32) { csamples[i] /= out_magn; #if DEBUG printf("Clip out_magn %8.5lf is_clipping %d index_read %5d index_start %5d gain %8.5lf\n", out_magn / CLIP32, dat->is_clipping, dat->index_read, dat->index_start, dat->gain); #endif } dat->c_samp[dat->index_read] = csample; // write new sample at read index if (is_cpx) buf_magn = cabs(csample); else buf_magn = fabs(creal(csample)); if (dat->is_clipping == 0) { if (buf_magn * dat->gain > dat->max_out * CLIP32) { dat->target_gain = dat->max_out * CLIP32 / buf_magn; dat->delta = (dat->gain - dat->target_gain) / dat->buf_size; dat->is_clipping = 1; dat->themax = buf_magn; // printf("Start index %5d buf_magn %10.8lf target %8.2lf gain %8.2lf delta %8.5lf\n", // dat->index_read, buf_magn / CLIP32, dat->target_gain, dat->gain, dat->delta); dat->gain -= dat->delta; } else if (dat->index_read == dat->index_start) { clip_gain = dat->max_out * CLIP32 / dat->themax; // clip gain based on the maximum sample in the buffer if (rxMode == FM || rxMode == DGT_FM) // mode is FM dat->target_gain = clip_gain; else if (agcReleaseGain > clip_gain) dat->target_gain = clip_gain; else dat->target_gain = agcReleaseGain; dat->themax = buf_magn; dat->gain = dat->gain * (1.0 - dat->time_release) + dat->target_gain * dat->time_release; // printf("New index %5d themax %7.5lf clip_gain %5.0lf agcReleaseGain %5.0lf\n", // dat->index_start, dat->themax / CLIP32, clip_gain, agcReleaseGain); } else { if (dat->themax < buf_magn) dat->themax = buf_magn; dat->gain = dat->gain * (1.0 - dat->time_release) + dat->target_gain * dat->time_release; } } else { // dat->is_clipping == 1; we are handling a clip condition if (buf_magn > dat->themax) { dat->themax = buf_magn; dat->target_gain = dat->max_out * CLIP32 / buf_magn; dtmp = (dat->gain - dat->target_gain) / dat->buf_size; // new value of delta if (dtmp > dat->delta) { dat->delta = dtmp; // printf(" Strt index %5d buf_magn %10.8lf target %8.2lf gain %8.2lf delta %8.5lf\n", // dat->index_read, buf_magn / CLIP32, dat->target_gain, dat->gain, dat->delta); } else { // printf(" Plus index %5d buf_magn %10.8lf target %8.2lf gain %8.2lf delta %8.5lf\n", // dat->index_read, buf_magn / CLIP32, dat->target_gain, dat->gain, dat->delta); } } dat->gain -= dat->delta; if (dat->gain <= dat->target_gain) { dat->is_clipping = 0; dat->gain = dat->target_gain; // printf("End index %5d buf_magn %10.8lf target %8.2lf gain %8.2lf delta %8.5lf themax %10.8lf\n", // dat->index_read, buf_magn / CLIP32, dat->target_gain, dat->gain, dat->delta, dat->themax / CLIP32); dat->themax = buf_magn; dat->index_start = dat->index_read; } } if (++dat->index_read >= dat->buf_size) dat->index_read = 0; #if DEBUG if (printit++ >= dat->sample_rate * 500 / 1000) { printit = 0; dtmp = 20 * log10(maxout / CLIP32); if (dtmp >= 0) clip = "Clip"; else clip = ""; printf("Out agcGain %5.0lf target_gain %9.0lf gain %9.0lf output %7.2lf %s\n", agcReleaseGain, dat->target_gain, dat->gain, dtmp, clip); maxout = 1; } #endif } return; } int quisk_process_samples(complex double * cSamples, int nSamples) { // Called when samples are available. // Samples range from about 2^16 to a max of 2^31. int i, n, nout, is_key_down, squelch_real=0, squelch_imag=0; double d, di, tune; double double_filter_decim; complex double phase; int orig_nSamples; fft_data * ptFFT; rx_mode_type rx_mode; static int size_dsamples = 0; // Current dimension of dsamples, dsamples2, orig_cSamples, buf_cSamples static int old_split_rxtx = 0; // Prior value of split_rxtx static int old_multirx_play_channel = 0; // Prior value of multirx_play_channel static double * dsamples = NULL; static double * dsamples2 = NULL; static complex double * orig_cSamples = NULL; static complex double * buf_cSamples = NULL; static complex double rxTuneVector = 1; static complex double txTuneVector = 1; static complex double aux1TuneVector = 1; static complex double aux2TuneVector = 1; static complex double sidetoneVector = BIG_VOLUME; static double dOutCounter = 0; // Cumulative net output samples for sidetone etc. static int sidetoneIsOn = 0; // The status of the sidetone static double sidetoneEnvelope; // Shape the rise and fall times of the sidetone static double keyupEnvelope = 1.0; // Shape the rise time on key up static int playSilence; static struct quisk_cHB45Filter HalfBand7 = {NULL, 0, 0}; static struct quisk_cHB45Filter HalfBand8 = {NULL, 0, 0}; static struct quisk_cHB45Filter HalfBand9 = {NULL, 0, 0}; static struct AgcState Agc1 = {0.7, 0, 0}, Agc2 = {0.7, 0, 0}, Agc3 = {0.7, 0, 0}; #if DEBUG static int printit; static time_t time0; static double levelA=0, levelB=0, levelC=0, levelD=0, levelE=0; if (time(NULL) != time0) { time0 = time(NULL); printit = 1; } else { printit = 0; } #endif if (nSamples <= 0) return nSamples; if (nSamples > size_dsamples) { if (dsamples) free(dsamples); if (dsamples2) free(dsamples2); if (orig_cSamples) free(orig_cSamples); if (buf_cSamples) free(buf_cSamples); size_dsamples = nSamples * 2; dsamples = (double *)malloc(size_dsamples * sizeof(double)); dsamples2 = (double *)malloc(size_dsamples * sizeof(double)); orig_cSamples = (complex double *)malloc(size_dsamples * sizeof(complex double)); buf_cSamples = (complex double *)malloc(size_dsamples * sizeof(complex double)); } #if SAMPLES_FROM_FILE == 1 QuiskWavWriteC(&hWav, cSamples, nSamples); #elif SAMPLES_FROM_FILE == 2 QuiskWavReadC(&hWav, cSamples, nSamples); #endif if (rxMode == CWL || rxMode == CWU) // Thanks to Robert, DM4RW is_key_down = quisk_is_key_down(); else is_key_down = quisk_transmit_mode || quisk_is_key_down(); orig_nSamples = nSamples; if (split_rxtx) { memcpy(orig_cSamples, cSamples, nSamples * sizeof(complex double)); if ( ! old_split_rxtx) // start of new split mode Buffer2Chan(NULL, 0, NULL, 0); } if (multirx_play_channel != old_multirx_play_channel) // change in play channel Buffer2Chan(NULL, 0, NULL, 0); old_split_rxtx = split_rxtx; old_multirx_play_channel = multirx_play_channel; if (is_key_down && !isFDX) { // The key is down; replace this data block dOutCounter += (double)nSamples * quisk_sound_state.playback_rate / quisk_sound_state.sample_rate; nout = (int)dOutCounter; // number of samples to output dOutCounter -= nout; playSilence = keyupDelayCode; keyupEnvelope = 0; i = 0; // whether to play the sidetone if (rxMode == CWL || rxMode == CWU) { if (quisk_use_rx_udp == 10) { if (hardware_cwkey == 1) i = 1; } else { i = 1; } } if (i) { // Play sidetone instead of radio for CW if (! sidetoneIsOn) { // turn on sidetone sidetoneIsOn = 1; sidetoneEnvelope = 0; sidetoneVector = BIG_VOLUME; } for (i = 0 ; i < nout; i++) { if (sidetoneEnvelope < 1.0) { sidetoneEnvelope += 1. / (quisk_sound_state.playback_rate * 5e-3); // 5 milliseconds if (sidetoneEnvelope > 1.0) sidetoneEnvelope = 1.0; } d = creal(sidetoneVector) * sidetoneVolume * sidetoneEnvelope; cSamples[i] = d + I * d; sidetoneVector *= sidetonePhase; } } else { // Otherwise play silence for (i = 0 ; i < nout; i++) cSamples[i] = 0; } return nout; } // Key is up if(sidetoneIsOn) { // decrease sidetone until it is off dOutCounter += (double)nSamples * quisk_sound_state.playback_rate / quisk_sound_state.sample_rate; nout = (int)dOutCounter; // number of samples to output dOutCounter -= nout; for (i = 0; i < nout; i++) { sidetoneEnvelope -= 1. / (quisk_sound_state.playback_rate * 5e-3); // 5 milliseconds if (sidetoneEnvelope < 0) { sidetoneIsOn = 0; sidetoneEnvelope = 0; break; // sidetone is zero } d = creal(sidetoneVector) * sidetoneVolume * sidetoneEnvelope; cSamples[i] = d + I * d; sidetoneVector *= sidetonePhase; } for ( ; i < nout; i++) { // continue with playSilence, even if zero cSamples[i] = 0; playSilence--; } return nout; } if (playSilence > 0) { // Continue to play silence after the key is up dOutCounter += (double)nSamples * quisk_sound_state.playback_rate / quisk_sound_state.sample_rate; nout = (int)dOutCounter; // number of samples to output dOutCounter -= nout; for (i = 0; i < nout; i++) cSamples[i] = 0; playSilence -= nout; return nout; } // We are done replacing sound with a sidetone or silence. Filter and // demodulate the samples as radio sound. // Add a test tone to the data if (testtonePhase) AddTestTone(cSamples, nSamples); // Invert spectrum if (quisk_invert_spectrum) { for (i = 0; i < nSamples; i++) { cSamples[i] = conj(cSamples[i]); } } NoiseBlanker(cSamples, nSamples); // Put samples into the fft input array. // Thanks to WB4JFI for the code to add a third FFT buffer, July 2010. // Changed to multiple FFTs May 2014. if (multiple_sample_rates == 0) { ptFFT = fft_data_array + fft_data_index; for (i = 0; i < nSamples; i++) { ptFFT->samples[ptFFT->index] = cSamples[i]; if (++(ptFFT->index) >= fft_size) { // check sample count n = fft_data_index + 1; // next FFT data location if (n >= FFT_ARRAY_SIZE) n = 0; if (fft_data_array[n].filled == 0) { // Is the next buffer empty? fft_data_array[n].index = 0; fft_data_array[n].block = 0; fft_data_array[fft_data_index].filled = 1; // Mark the previous buffer ready. fft_data_index = n; // Write samples into the new buffer. ptFFT = fft_data_array + fft_data_index; } else { // no place to write samples ptFFT->index = 0; fft_error++; } } } } // Tune the data to frequency if (multiple_sample_rates == 0) tune = rx_tune_freq; else tune = rx_tune_freq + vfo_screen - vfo_audio; if (tune != 0) { phase = cexp((I * -2.0 * M_PI * tune) / quisk_sound_state.sample_rate); for (i = 0; i < nSamples; i++) { cSamples[i] *= rxTuneVector; rxTuneVector *= phase; } } if (rxMode == EXT) { // External filter and demodulate d = (double)quisk_sound_state.sample_rate / quisk_sound_state.playback_rate; // total decimation needed nSamples = quisk_extern_demod(cSamples, nSamples, d); goto start_agc; } // Perhaps write sample data to the soundcard output without decimation if (TEST_AUDIO == 1) { // Copy I channel capture to playback di = 1.e4 * quisk_audioVolume; for (i = 0; i < nSamples; i++) cSamples[i] = creal(cSamples[i]) * di; return nSamples; } else if (TEST_AUDIO == 2) { // Copy Q channel capture to playback di = 1.e4 * quisk_audioVolume; for (i = 0; i < nSamples; i++) cSamples[i] = cimag(cSamples[i]) * di; return nSamples; } #if DEBUG for (i = 0; i < nSamples; i++) { d = cabs(cSamples[i]); if (levelA < d) levelA = d; } #endif nSamples = quisk_process_decimate(cSamples, nSamples, 0, rxMode); #if DEBUG for (i = 0; i < nSamples; i++) { d = cabs(cSamples[i]); if (levelB < d) levelB = d; } #endif if (measure_freq_mode) measure_freq(cSamples, nSamples, quisk_decim_srate); nSamples = quisk_process_demodulate(cSamples, dsamples, nSamples, 0, 0, rxMode); squelch_real = 0; // keep track of the squelch for the two play channels squelch_imag = 0; if (rxMode == DGT_IQ) { ; // This mode is already stereo } else if (split_rxtx) { // Demodulate a second channel from the same receiver phase = cexp((I * -2.0 * M_PI * (quisk_tx_tune_freq + rit_freq)) / quisk_sound_state.sample_rate); // Tune the second channel to frequency for (i = 0; i < orig_nSamples; i++) { orig_cSamples[i] *= txTuneVector; txTuneVector *= phase; } n = quisk_process_decimate(orig_cSamples, orig_nSamples, 1, rxMode); n = quisk_process_demodulate(orig_cSamples, dsamples2, n, 1, 0, rxMode); nSamples = Buffer2Chan(dsamples, nSamples, dsamples2, n); // buffer dsamples and dsamples2 so the count is equal // dsamples was demodulated on bank 0, dsamples2 on bank 1 switch(split_rxtx) { default: case 1: // stereo, higher frequency is real if (quisk_tx_tune_freq < rx_tune_freq) { squelch_real = MeasureSquelch[0].squelch_active; squelch_imag = MeasureSquelch[1].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples[i] + I * dsamples2[i]; } else { squelch_real = MeasureSquelch[1].squelch_active; squelch_imag = MeasureSquelch[0].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples2[i] + I * dsamples[i]; } break; case 2: // stereo, lower frequency is real if (quisk_tx_tune_freq >= rx_tune_freq) { squelch_real = MeasureSquelch[0].squelch_active; squelch_imag = MeasureSquelch[1].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples[i] + I * dsamples2[i]; } else { squelch_real = MeasureSquelch[1].squelch_active; squelch_imag = MeasureSquelch[0].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples2[i] + I * dsamples[i]; } break; case 3: // mono receive channel squelch_real = squelch_imag = MeasureSquelch[0].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples[i] + I * dsamples[i]; break; case 4: // mono transmit channel squelch_real = squelch_imag = MeasureSquelch[1].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples2[i] + I * dsamples2[i]; break; } } else if (multirx_play_channel >= 0) { // Demodulate a second channel from a different receiver memcpy(buf_cSamples, multirx_cSamples[multirx_play_channel], orig_nSamples * sizeof(complex double)); phase = cexp((I * -2.0 * M_PI * (multirx_freq[multirx_play_channel])) / quisk_sound_state.sample_rate); // Tune the second channel to frequency for (i = 0; i < orig_nSamples; i++) { buf_cSamples[i] *= aux1TuneVector; aux1TuneVector *= phase; } n = quisk_process_decimate(buf_cSamples, orig_nSamples, 1, multirx_mode[multirx_play_channel]); n = quisk_process_demodulate(buf_cSamples, dsamples2, n, 1, 1, multirx_mode[multirx_play_channel]); nSamples = Buffer2Chan(dsamples, nSamples, dsamples2, n); // buffer dsamples and dsamples2 so the count is equal switch(multirx_play_method) { default: case 0: // play both squelch_real = squelch_imag = MeasureSquelch[1].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples2[i] + I * dsamples2[i]; break; case 1: // play left squelch_real = MeasureSquelch[0].squelch_active; squelch_imag = MeasureSquelch[1].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples[i] + I * dsamples2[i]; break; case 2: // play right squelch_real = MeasureSquelch[1].squelch_active; squelch_imag = MeasureSquelch[0].squelch_active; for (i = 0; i < nSamples; i++) cSamples[i] = dsamples2[i] + I * dsamples[i]; break; } } else { // monophonic sound played on both channels squelch_real = squelch_imag = MeasureSquelch[0].squelch_active; for (i = 0; i < nSamples; i++) { d = dsamples[i]; cSamples[i] = d + I * d; } } // play sub-receiver 1 audio on a digital output device rx_mode = multirx_mode[0]; if (quisk_multirx_count > 0 && (rx_mode == DGT_U || rx_mode == DGT_L || rx_mode == DGT_IQ || rx_mode == DGT_FM) && quisk_DigitalRx1Output.driver) { phase = cexp((I * -2.0 * M_PI * (multirx_freq[0])) / quisk_sound_state.sample_rate); // Tune the channel to frequency for (i = 0; i < orig_nSamples; i++) { multirx_cSamples[0][i] *= aux2TuneVector; aux2TuneVector *= phase; } n = quisk_process_decimate(multirx_cSamples[0], orig_nSamples, 2, rx_mode); n = quisk_process_demodulate(multirx_cSamples[0], dsamples2, n, 2, 2, rx_mode); if (rx_mode == DGT_IQ) { // DGT-IQ process_agc(&Agc3, multirx_cSamples[0], n, 1); } else { for (i = 0; i < n; i++) multirx_cSamples[0][i] = dsamples2[i] + I * dsamples2[i]; process_agc(&Agc3, multirx_cSamples[0], n, 0); } play_sound_interface(&quisk_DigitalRx1Output, n, multirx_cSamples[0], 1, 1.0); } // Perhaps decimate by an additional fraction if (quisk_decim_srate != 48000) { double_filter_decim = quisk_decim_srate / 48000.0; nSamples = cFracDecim(cSamples, nSamples, double_filter_decim); quisk_decim_srate = 48000; } // Interpolate the samples from 48000 sps to the play rate. switch (quisk_sound_state.playback_rate / 48000) { case 1: break; case 2: nSamples = quisk_cInterp2HB45(cSamples, nSamples, &HalfBand7); break; case 4: nSamples = quisk_cInterp2HB45(cSamples, nSamples, &HalfBand7); nSamples = quisk_cInterp2HB45(cSamples, nSamples, &HalfBand8); break; case 8: nSamples = quisk_cInterp2HB45(cSamples, nSamples, &HalfBand7); nSamples = quisk_cInterp2HB45(cSamples, nSamples, &HalfBand8); nSamples = quisk_cInterp2HB45(cSamples, nSamples, &HalfBand9); break; default: printf ("Failure in quisk.c in integer interpolation %d %d\n", quisk_decim_srate, quisk_sound_state.playback_rate); break; } // Find the peak signal amplitude start_agc: if (rxMode == EXT || rxMode == DGT_IQ) { // Ext and DGT-IQ stereo sound process_agc(&Agc1, cSamples, nSamples, 1); } else if (rxMode == FDV_U || rxMode == FDV_L) { // Agc already done ; } else if (split_rxtx || multirx_play_channel >= 0) { // separate AGC for left and right channels for (i = 0; i < nSamples; i++) { orig_cSamples[i] = cimag(cSamples[i]); cSamples[i] = creal(cSamples[i]); } process_agc(&Agc1, cSamples, nSamples, 0); process_agc(&Agc2, orig_cSamples, nSamples, 0); for (i = 0; i < nSamples; i++) cSamples[i] = creal(cSamples[i]) + I * creal(orig_cSamples[i]); } else { // monophonic sound process_agc(&Agc1, cSamples, nSamples, 0); } #if DEBUG if (printit) { d = CLIP32; //printf ("Levels: %12.8lf %12.8lf %12.8lf %12.8lf %12.8lf\n", // levelA/d, levelB/d, levelC/d, levelD/d, levelE/d); levelA = levelB = levelC = levelD = levelE = 0; } #endif if (kill_audio) { squelch_real = squelch_imag = 1; for (i = 0; i < nSamples; i++) cSamples[i] = 0; } else if (squelch_real && squelch_imag) { for (i = 0; i < nSamples; i++) cSamples[i] = 0; } else if (squelch_imag) { for (i = 0; i < nSamples; i++) cSamples[i] = creal(cSamples[i]); } else if (squelch_real) { for (i = 0; i < nSamples; i++) cSamples[i] = I * cimag(cSamples[i]); } if (keyupEnvelope < 1.0) { // raise volume slowly after the key goes up di = 1. / (quisk_sound_state.playback_rate * 5e-3); // 5 milliseconds for (i = 0; i < nSamples; i++) { keyupEnvelope += di; if (keyupEnvelope > 1.0) { keyupEnvelope = 1.0; break; } cSamples[i] *= keyupEnvelope; } } if (quisk_record_state == RECORD_RADIO && ! (squelch_real && squelch_imag)) quisk_tmp_record(cSamples, nSamples, 1.0); // save radio sound return nSamples; } static PyObject * get_state(PyObject * self, PyObject * args) { int unused = 0; if (args && !PyArg_ParseTuple (args, "")) // args=NULL internal call return NULL; return Py_BuildValue("iiiiiNiNiiiiiiiii", quisk_sound_state.rate_min, quisk_sound_state.rate_max, quisk_sound_state.sample_rate, quisk_sound_state.chan_min, quisk_sound_state.chan_max, PyUnicode_DecodeUTF8(quisk_sound_state.msg1, strlen(quisk_sound_state.msg1), "replace"), unused, PyUnicode_DecodeUTF8(quisk_sound_state.err_msg, strlen(quisk_sound_state.err_msg), "replace"), quisk_sound_state.read_error, quisk_sound_state.write_error, quisk_sound_state.underrun_error, quisk_sound_state.latencyCapt, quisk_sound_state.latencyPlay, quisk_sound_state.interupts, fft_error, mic_max_display, quisk_sound_state.data_poll_usec ); } static PyObject * get_squelch(PyObject * self, PyObject * args) { int freq; if (!PyArg_ParseTuple (args, "i", &freq)) return NULL; return PyInt_FromLong(IsSquelch(freq)); } static PyObject * get_overrange(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; return PyInt_FromLong(quisk_get_overrange()); } static PyObject * get_filter_rate(PyObject * self, PyObject * args) { // Return the filter sample rate as used by quisk_process_samples. // Changes to quisk_process_decimate or quisk_process_demodulate will require changes here. int rate, decim_srate, filter_srate, mode, bandwidth; // mode is -1 to use the rxMode if (!PyArg_ParseTuple (args, "ii", &mode, &bandwidth)) return NULL; rate = quisk_sound_state.sample_rate; switch((rate + 100) / 1000) { case 41: decim_srate = 48000; case 53: // SDR-IQ decim_srate = rate; break; case 111: // SDR-IQ decim_srate = rate / 2; break; case 133: // SDR-IQ decim_srate = rate / 2; break; case 185: // SDR-IQ decim_srate = rate / 3; break; case 370: decim_srate = rate / 6; break; case 740: decim_srate = rate / 12; break; case 1333: decim_srate = rate / 24; break; default: decim_srate = PlanDecimation(NULL, NULL, NULL); break; } if (mode < 0) { mode = rxMode; bandwidth = filter_bandwidth[0]; } switch(mode) { case CWL: // lower sideband CW at 6 ksps case CWU: // upper sideband CW at 6 ksps filter_srate = decim_srate / 8; break; case LSB: // lower sideband SSB at 12 ksps case USB: // upper sideband SSB at 12 ksps default: filter_srate = decim_srate / 4; break; case AM: // AM at 24 ksps filter_srate = decim_srate / 2; break; case FM: // FM at 48 ksps case DGT_FM: // digital FM at 48 ksps filter_srate = decim_srate; break; case DGT_U: // digital modes DGT-* case DGT_L: if (bandwidth < DGT_NARROW_FREQ) filter_srate = decim_srate / 8; else filter_srate = decim_srate; break; case DGT_IQ: // digital mode at 48 ksps filter_srate = decim_srate; break; case FDV_U: // digital voice at 8 ksps case FDV_L: filter_srate = 8000; break; } //printf("Filter rate %d\n", filter_srate); return PyInt_FromLong(filter_srate); } static PyObject * get_smeter(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; return PyFloat_FromDouble(Smeter); } static PyObject * get_hardware_ptt(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; return PyInt_FromLong(hardware_ptt); } static PyObject * get_hermes_adc(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; return PyFloat_FromDouble(hermes_adc_level); } static void init_bandscope(void) { int i, j; if (bandscope_size > 0) { bandscopeSamples = (double *)malloc(bandscope_size * sizeof(double)); bandscopeWindow = (double *)malloc(bandscope_size * sizeof(double)); bandscopeAverage = (double *)malloc((bandscope_size / 2 + 1 + 1) * sizeof(double)); bandscopeFFT = (complex double *)malloc((bandscope_size / 2 + 1) * sizeof(complex double)); bandscopePlan = fftw_plan_dft_r2c_1d(bandscope_size, bandscopeSamples, bandscopeFFT, FFTW_MEASURE); // Create the fft window for (i = 0, j = -bandscope_size / 2; i < bandscope_size; i++, j++) bandscopeWindow[i] = 0.5 + 0.5 * cos(2. * M_PI * j / bandscope_size); // Hanning // zero the average array for (i = 0; i < bandscope_size / 2 + 1; i++) bandscopeAverage[i] = 0; } } static PyObject * add_rx_samples(PyObject * self, PyObject * args) { int i; int ii, qq; // ii, qq must be four bytes unsigned char * pt_ii; unsigned char * pt_qq; Py_buffer view; PyObject * samples; if (!PyArg_ParseTuple (args, "O", &samples)) return NULL; if ( ! PyObject_CheckBuffer(samples)) { printf("add_rx_samples: Invalid object sent as samples\n"); Py_INCREF (Py_None); return Py_None; } if (PyObject_GetBuffer(samples, &view, PyBUF_SIMPLE) != 0) { printf("add_rx_samples: Can not view sample buffer\n"); Py_INCREF (Py_None); return Py_None; } if (view.len % (py_sample_rx_bytes * 2) != 0) { printf ("add_rx_samples: Odd number of bytes in sample buffer\n"); } else if (PySampleCount + view.len / py_sample_rx_bytes / 2 > SAMP_BUFFER_SIZE * 8 / 10) { printf ("add_rx_samples: buffer is too full\n"); } else if (py_sample_rx_endian == 0) { // byte order of samples is little-endian void * buf; void * buf_end; buf = view.buf; buf_end = buf + view.len; pt_ii = (unsigned char *)&ii + 4 - py_sample_rx_bytes; pt_qq = (unsigned char *)&qq + 4 - py_sample_rx_bytes; while (buf < buf_end) { ii = qq = 0; memcpy(pt_ii, buf, py_sample_rx_bytes); buf += py_sample_rx_bytes; memcpy(pt_qq, buf, py_sample_rx_bytes); buf += py_sample_rx_bytes; PySampleBuf[PySampleCount++] = ii + qq * I; } } else { // byte order of samples is big-endian unsigned char * buf; unsigned char * buf_end; buf = view.buf; buf_end = buf + view.len; while (buf < buf_end) { ii = qq = 0; pt_ii = (unsigned char *)&ii + 3; pt_qq = (unsigned char *)&qq + 3; for (i = 0; i < py_sample_rx_bytes; i++) *pt_ii-- = *buf++; for (i = 0; i < py_sample_rx_bytes; i++) *pt_qq-- = *buf++; PySampleBuf[PySampleCount++] = ii + qq * I; } } PyBuffer_Release(&view); Py_INCREF (Py_None); return Py_None; } static PyObject * add_bscope_samples(PyObject * self, PyObject * args) { int i, count; int ii; // ii must be four bytes unsigned char * pt_ii; Py_buffer view; PyObject * samples; if (!PyArg_ParseTuple (args, "O", &samples)) return NULL; if (bandscope_size <= 0) { printf("add_bscope_samples: The bandscope was not initialized with InitBscope()\n"); Py_INCREF (Py_None); return Py_None; } if ( ! PyObject_CheckBuffer(samples)) { printf("add_bscope_samples: Invalid object sent as samples\n"); Py_INCREF (Py_None); return Py_None; } if (PyObject_GetBuffer(samples, &view, PyBUF_SIMPLE) != 0) { printf("add_bscope_samples: Can not view sample buffer\n"); Py_INCREF (Py_None); return Py_None; } count = 0; if (view.len != bandscope_size * py_bscope_bytes) { printf ("add_bscope_samples: Wrong number of bytes in sample buffer\n"); } else if (py_bscope_endian == 0) { // byte order of samples is little-endian void * buf; void * buf_end; buf = view.buf; buf_end = buf + view.len; pt_ii = (unsigned char *)&ii + 4 - py_bscope_bytes; while (buf < buf_end) { ii = 0; memcpy(pt_ii, buf, py_bscope_bytes); buf += py_bscope_bytes; bandscopeSamples[count++] = (double)ii / CLIP32; } } else { // byte order of samples is big-endian unsigned char * buf; unsigned char * buf_end; buf = view.buf; buf_end = buf + view.len; while (buf < buf_end) { ii = 0; pt_ii = (unsigned char *)&ii + 3; for (i = 0; i < py_bscope_bytes; i++) *pt_ii-- = *buf++; bandscopeSamples[count++] = (double)ii / CLIP32; } } PyBuffer_Release(&view); bandscopeState = 99; Py_INCREF (Py_None); return Py_None; } static void py_sample_start(void) { } static void py_sample_stop(void) { if (bandscopePlan) { fftw_destroy_plan(bandscopePlan); bandscopePlan = NULL; } } static int py_sample_read(complex double * cSamples) { int n; memcpy(cSamples, PySampleBuf, PySampleCount * sizeof(complex double)); n = PySampleCount; PySampleCount = 0; return n; } static PyObject * set_params(PyObject * self, PyObject * args, PyObject * keywds) { /* Call with keyword arguments ONLY; change local parameters */ static char * kwlist[] = {"quisk_is_vna", "rx_bytes", "rx_endian", "read_error", "clip", "bscope_bytes", "bscope_endian", "bscope_size", "bandscopeScale", "hermes_pause", NULL} ; int i, nbytes, read_error, clip, bscope_size, hermes_pause; nbytes = read_error = clip = bscope_size = hermes_pause = -1; if (!PyArg_ParseTupleAndKeywords (args, keywds, "|iiiiiiiidi", kwlist, &quisk_is_vna, &nbytes, &py_sample_rx_endian, &read_error, &clip, &py_bscope_bytes, &py_bscope_endian, &bscope_size, &bandscopeScale, &hermes_pause)) return NULL; if (nbytes != -1) { py_sample_rx_bytes = nbytes; quisk_sample_source4(py_sample_start, py_sample_stop, py_sample_read, NULL); } if (read_error != -1) quisk_sound_state.read_error++; if (clip != -1) quisk_sound_state.overrange++; if (bscope_size > 0) { if (bandscope_size == 0) { bandscope_size = bscope_size; init_bandscope(); } else if (bscope_size != bandscope_size) { printf ("Illegal attempt to change bscope_size\n"); } } if (hermes_pause != -1) { i = quisk_multirx_state; if (hermes_pause) { // pause the hermes samples if (quisk_multirx_state < 20) quisk_multirx_state = 20; } else { // resume the hermes samples if (quisk_multirx_state >= 20) quisk_multirx_state = 0; } return PyInt_FromLong(i); } Py_INCREF (Py_None); return Py_None; } static PyObject * get_hermes_TFRC(PyObject * self, PyObject * args) { // return average temperature, forward and reverse power and current PyObject * ret; if (!PyArg_ParseTuple (args, "")) return NULL; if (hermes_count_temperature > 0) { hermes_temperature /= hermes_count_temperature; hermes_fwd_power /= hermes_count_temperature; } else { hermes_temperature = 0.0; hermes_fwd_power = 0.0; } if (hermes_count_current > 0) { hermes_rev_power /= hermes_count_current; hermes_pa_current /= hermes_count_current; } else { hermes_rev_power = 0.0; hermes_pa_current = 0.0; } ret = Py_BuildValue("dddd", hermes_temperature, hermes_fwd_power, hermes_rev_power, hermes_pa_current); hermes_temperature = 0; hermes_fwd_power = 0; hermes_rev_power = 0; hermes_pa_current = 0; hermes_count_temperature = 0; hermes_count_current = 0; return ret; } static PyObject * measure_frequency(PyObject * self, PyObject * args) { int mode; if (!PyArg_ParseTuple (args, "i", &mode)) return NULL; if (mode >= 0) // mode >= 0 set the mode; mode < 0, just return the frequency measure_freq_mode = mode; return PyFloat_FromDouble(measured_frequency); } static PyObject * measure_audio(PyObject * self, PyObject * args) { int time; if (!PyArg_ParseTuple (args, "i", &time)) return NULL; if (time > 0) // set the average time measure_audio_time = time; return PyFloat_FromDouble(measured_audio); } static PyObject * add_tone(PyObject * self, PyObject * args) { /* Add a test tone to the captured audio data */ int freq; if (!PyArg_ParseTuple (args, "i", &freq)) return NULL; if (freq && quisk_sound_state.sample_rate) testtonePhase = cexp((I * 2.0 * M_PI * freq) / quisk_sound_state.sample_rate); else testtonePhase = 0; Py_INCREF (Py_None); return Py_None; } static PyObject * open_key(PyObject * self, PyObject * args) { const char * name; if (!PyArg_ParseTuple (args, "s", &name)) return NULL; return PyInt_FromLong(quisk_open_key(name)); } static void close_udp(void) { short msg = 0x7373; // shutdown quisk_using_udp = 0; if (rx_udp_socket != INVALID_SOCKET) { shutdown(rx_udp_socket, QUISK_SHUT_RD); send(rx_udp_socket, (char *)&msg, 2, 0); send(rx_udp_socket, (char *)&msg, 2, 0); QuiskSleepMicrosec(3000000); close(rx_udp_socket); rx_udp_socket = INVALID_SOCKET; } quisk_rx_udp_started = 0; #ifdef MS_WINDOWS if (cleanupWSA) { cleanupWSA = 0; WSACleanup(); } #endif } static void close_udp10(void) // Metis-Hermes protocol { int i; unsigned char buf[64]; quisk_using_udp = 0; if (rx_udp_socket != INVALID_SOCKET) { shutdown(rx_udp_socket, QUISK_SHUT_RD); buf[0] = 0xEF; buf[1] = 0xFE; buf[2] = 0x04; buf[3] = 0x00; for (i = 4; i < 64; i++) buf[i] = 0; send(rx_udp_socket, (char *)buf, 64, 0); QuiskSleepMicrosec(5000); send(rx_udp_socket, (char *)buf, 64, 0); QuiskSleepMicrosec(2000000); close(rx_udp_socket); rx_udp_socket = INVALID_SOCKET; } quisk_rx_udp_started = 0; quisk_multirx_state = 0; if (bandscopePlan) { fftw_destroy_plan(bandscopePlan); bandscopePlan = NULL; } #ifdef MS_WINDOWS if (cleanupWSA) { cleanupWSA = 0; WSACleanup(); } #endif } static PyObject * close_rx_udp(PyObject * self, PyObject * args) { // Not necessary to call from Python because close_udp() is called from sound.c if (!PyArg_ParseTuple (args, "")) return NULL; //close_udp(); Py_INCREF (Py_None); return Py_None; } static int quisk_read_rx_udp(complex double * samp) // Read samples from UDP { // Size of complex sample array is SAMP_BUFFER_SIZE ssize_t bytes; unsigned char buf[1500]; // Maximum Ethernet is 1500 bytes. static unsigned char seq0; // must be 8 bits int i, nSamples, xr, xi, index, want_samples; unsigned char * ptxr, * ptxi; struct timeval tm_wait; fd_set fds; // Data from the receiver is little-endian if ( ! rx_udp_gain_correct) { int dec; dec = (int)(rx_udp_clock / quisk_sound_state.sample_rate + 0.5); if ((dec / 5) * 5 == dec) // Decimation by a factor of 5 rx_udp_gain_correct = 1.31072; else // Decimation by factors of two rx_udp_gain_correct = 1.0; } if ( ! quisk_rx_udp_started) { // we never received any data // send our return address until we receive UDP blocks tm_wait.tv_sec = 0; tm_wait.tv_usec = 5000; FD_ZERO (&fds); FD_SET (rx_udp_socket, &fds); if (select (rx_udp_socket + 1, &fds, NULL, NULL, &tm_wait) == 1) { // see if data is available bytes = recv(rx_udp_socket, (char *)buf, 1500, 0); // throw away the first block seq0 = buf[0] + 1; // Next expected sequence number quisk_rx_udp_started = 1; #if DEBUG_IO printf("Udp data started\n"); #endif } else { // send our return address to the sample source buf[0] = buf[1] = 0x72; // UDP command "register return address" send(rx_udp_socket, (char *)buf, 2, 0); return 0; } } nSamples = 0; want_samples = (int)(quisk_sound_state.data_poll_usec * 1e-6 * quisk_sound_state.sample_rate + 0.5); while (nSamples < want_samples) { // read several UDP blocks tm_wait.tv_sec = 0; tm_wait.tv_usec = 100000; // Linux seems to have problems with very small time intervals FD_ZERO (&fds); FD_SET (rx_udp_socket, &fds); i = select (rx_udp_socket + 1, &fds, NULL, NULL, &tm_wait); if (i == 1) ; else if (i == 0) { #if DEBUG_IO printf("Udp socket timeout\n"); #endif return 0; } else { #if DEBUG_IO printf("Udp select error %d\n", i); #endif return 0; } bytes = recv(rx_udp_socket, (char *)buf, 1500, 0); // blocking read if (bytes != RX_UDP_SIZE) { // Known size of sample block quisk_sound_state.read_error++; #if DEBUG_IO printf("read_rx_udp: Bad block size\n"); #endif continue; } // buf[0] is the sequence number // buf[1] is the status: // bit 0: key up/down state // bit 1: set for ADC overrange (clip) if (buf[0] != seq0) { #if DEBUG_IO printf("read_rx_udp: Bad sequence want %3d got %3d\n", (unsigned int)seq0, (unsigned int)buf[0]); #endif quisk_sound_state.read_error++; } seq0 = buf[0] + 1; // Next expected sequence number quisk_set_key_down(buf[1] & 0x01); // bit zero is key state if (buf[1] & 0x02) // bit one is ADC overrange quisk_sound_state.overrange++; index = 2; ptxr = (unsigned char *)&xr; ptxi = (unsigned char *)ξ // convert 24-bit samples to 32-bit samples; int must be 32 bits. if (is_little_endian) { while (index < bytes) { // This works for 3, 2, 1 byte samples xr = xi = 0; memcpy (ptxr + (4 - sample_bytes), buf + index, sample_bytes); index += sample_bytes; memcpy (ptxi + (4 - sample_bytes), buf + index, sample_bytes); index += sample_bytes; samp[nSamples++] = (xr + xi * I) * rx_udp_gain_correct; xr = xi = 0; memcpy (ptxr + (4 - sample_bytes), buf + index, sample_bytes); index += sample_bytes; memcpy (ptxi + (4 - sample_bytes), buf + index, sample_bytes); index += sample_bytes; samp[nSamples++] = (xr + xi * I) * rx_udp_gain_correct; } } else { // big-endian while (index < bytes) { // This works for 3-byte samples only *(ptxr ) = buf[index + 2]; *(ptxr + 1) = buf[index + 1]; *(ptxr + 2) = buf[index ]; *(ptxr + 3) = 0; index += 3; *(ptxi ) = buf[index + 2]; *(ptxi + 1) = buf[index + 1]; *(ptxi + 2) = buf[index ]; *(ptxi + 3) = 0; index += 3; samp[nSamples++] = (xr + xi * I) * rx_udp_gain_correct;; *(ptxr ) = buf[index + 2]; *(ptxr + 1) = buf[index + 1]; *(ptxr + 2) = buf[index ]; *(ptxr + 3) = 0; index += 3; *(ptxi ) = buf[index + 2]; *(ptxi + 1) = buf[index + 1]; *(ptxi + 2) = buf[index ]; *(ptxi + 3) = 0; index += 3; samp[nSamples++] = (xr + xi * I) * rx_udp_gain_correct;; } } } return nSamples; } static int quisk_hermes_is_ready(int rx_udp_socket) { // Start Hermes; return 1 when we are ready to receive data unsigned char buf[1500]; int i, dummy; struct timeval tm_wait; fd_set fds; if (rx_udp_socket == INVALID_SOCKET) return 0; switch (quisk_multirx_state) { case 0: // Start or restart case 20: // Temporary shutdown quisk_rx_udp_started = 0; buf[0] = 0xEF; buf[1] = 0xFE; buf[2] = 0x04; buf[3] = 0x00; for (i = 4; i < 64; i++) buf[i] = 0; send(rx_udp_socket, (char *)buf, 64, 0); // send Stop quisk_multirx_state++; QuiskSleepMicrosec(2000); return 0; case 1: case 21: buf[0] = 0xEF; buf[1] = 0xFE; buf[2] = 0x04; buf[3] = 0x00; for (i = 4; i < 64; i++) buf[i] = 0; send(rx_udp_socket, (char *)buf, 64, 0); // send Stop quisk_multirx_state++; QuiskSleepMicrosec(9000); return 0; case 2: case 22: while (1) { tm_wait.tv_sec = 0; // throw away all pending records tm_wait.tv_usec = 0; FD_ZERO (&fds); FD_SET (rx_udp_socket, &fds); if (select (rx_udp_socket + 1, &fds, NULL, NULL, &tm_wait) != 1) break; recv(rx_udp_socket, (char *)buf, 1500, 0); } // change to state 3 for startup // change to state 23 for temporary shutdown quisk_multirx_state++; return 0; case 3: quisk_multirx_count = quisk_pc_to_hermes[3] >> 3 & 0x7; // number of receivers for (i = 0; i < quisk_multirx_count; i++) if ( ! multirx_fft_data[i].samples) // Check that buffer exists multirx_fft_data[i].samples = (fftw_complex *)malloc(multirx_fft_width * sizeof(fftw_complex)); quisk_hermes_tx_send(0, NULL); quisk_multirx_state++; return 0; case 4: case 5: case 6: case 7: dummy = 999999; // enable transmit quisk_hermes_tx_send(rx_udp_socket, &dummy); // send packets with number of receivers quisk_multirx_state++; QuiskSleepMicrosec(2000); return 0; case 8: if (quisk_rx_udp_started) { quisk_multirx_state++; } else { // send our return address until we receive UDP blocks buf[0] = 0xEF; buf[1] = 0xFE; buf[2] = 0x04; if (enable_bandscope) buf[3] = 0x03; else buf[3] = 0x01; for (i = 4; i < 64; i++) buf[i] = 0; send(rx_udp_socket, (char *)buf, 64, 0); QuiskSleepMicrosec(2000); } return 1; case 9: // running state; we have received UDP blocks default: return 1; case 23: // we are in a temporary shutdown return 0; } } static int read_rx_udp10(complex double * samp) // Read samples from UDP using the Hermes protocol. { // Size of complex sample array is SAMP_BUFFER_SIZE. Called from the sound thread. ssize_t bytes; unsigned char buf[1500]; unsigned int seq; unsigned int hlwp = 0; static unsigned int seq0; static int key_state; static int tx_records; static int max_multirx_count=0; int i, j, nSamples, xr, xi, index, start, want_samples, dindex, state, num_records; complex double c; struct timeval tm_wait; fd_set fds; if ( ! quisk_hermes_is_ready(rx_udp_socket)) { seq0 = 0; key_state = 0; tx_records = 0; quisk_rx_udp_started = 0; multirx_fft_next_index = 0; multirx_fft_next_state = 0; for (i = 0; i < QUISK_MAX_RECEIVERS; i++) multirx_fft_data[i].index = 0; return 0; } nSamples = 0; want_samples = (int)(quisk_sound_state.data_poll_usec * 1e-6 * quisk_sound_state.sample_rate + 0.5); num_records = 504 / ((quisk_multirx_count + 1) * 6 + 2); // number of samples in each of two blocks for each receiver if (quisk_multirx_count) { if (multirx_sample_size < want_samples + 2000) { multirx_sample_size = want_samples * 2 + 2000; for (i = 0; i < max_multirx_count; i++) { free(multirx_cSamples[i]); multirx_cSamples[i] = (complex double *)malloc(multirx_sample_size * sizeof(complex double)); } } if (quisk_multirx_count > max_multirx_count) { for (i = max_multirx_count; i < quisk_multirx_count; i++) multirx_cSamples[i] = (complex double *)malloc(multirx_sample_size * sizeof(complex double)); max_multirx_count = quisk_multirx_count; } } while (nSamples < want_samples) { // read several UDP blocks tm_wait.tv_sec = 0; tm_wait.tv_usec = 100000; // Linux seems to have problems with very small time intervals FD_ZERO (&fds); FD_SET (rx_udp_socket, &fds); i = select (rx_udp_socket + 1, &fds, NULL, NULL, &tm_wait); // blocking wait if (i == 1) ; else if (i == 0) { #if DEBUG_IO printf("Udp socket timeout\n"); #endif return 0; } else { #if DEBUG_IO printf("Udp select error %d\n", i); #endif return 0; } bytes = recv(rx_udp_socket, (char *)buf, 1500, 0); // blocking read if (bytes != 1032 || buf[0] != 0xEF || buf[1] != 0xFE || buf[2] != 0x01) { // Known size of sample block quisk_sound_state.read_error++; #if DEBUG_IO printf("read_rx_udp10: Bad block size %d or header\n", (int)bytes); #endif return 0; } //// Bandscope data - reversed byte order ????? if (buf[3] == 0x04 && bandscopeSamples) { // ADC samples for bandscope seq = buf[7]; // sequence number seq = seq & (bandscopeBlockCount - 1); // 0, 1, 2, ... switch (bandscopeState) { case 0: // Start - wait for the start of a block and record block one if (seq == 0) { for (i = 0, j = 8; i < 512; i++, j+= 2) bandscopeSamples[i] = ((double)(short)(buf[j + 1] << 8 | buf[j])) / bandscopeScale; bandscopeState = 1; } break; default: case 1: // Record blocks if (seq == bandscopeState) { for (i = 0, j = 8; i < 512; i++, j+= 2) bandscopeSamples[i + 512 * seq] = ((double)(short)(buf[j + 1] << 8 | buf[j])) / bandscopeScale; if (++bandscopeState >= bandscopeBlockCount) bandscopeState = 99; } else { bandscopeState = 0; // Error } break; case 99: // wait until the complete block is used break; } continue; } //// ADC Rx samples if (buf[3] != 0x06) // End point 6: I/Q and mic samples return 0; seq = buf[4] << 24 | buf[5] << 16 | buf[6] << 8 | buf[7]; // sequence number quisk_rx_udp_started = 1; tx_records += num_records * 2; // total samples for each receiver quisk_hermes_tx_send(rx_udp_socket, &tx_records); // send Tx samples, decrement tx_records if (seq != seq0) { #if DEBUG_IO printf("read_rx_udp10: Bad sequence want %d got %d\n", seq0, seq); #endif quisk_sound_state.read_error++; } seq0 = seq + 1; // Next expected sequence number for (start = 11; start < 1000; start += 512) { // check the sync bytes if (buf[start - 3] != 0x7F || buf[start - 2] != 0x7F || buf[start - 1] != 0x7F) { #if DEBUG_IO printf("read_rx_udp10: Bad sync byte\n"); #endif quisk_sound_state.read_error++; } // read five bytes of control information. start is the index of C0. // Changes for HermesLite v2 thanks to Steve, KF7O dindex = buf[start] >> 1; if (dindex & 0x40) { // the ACK bit C0[7] is set if (quisk_hermeslite_writepointer > 0) { // Save response quisk_hermeslite_response[0] = buf[start]; quisk_hermeslite_response[1] = buf[start+1]; quisk_hermeslite_response[2] = buf[start+2]; quisk_hermeslite_response[3] = buf[start+3]; quisk_hermeslite_response[4] = buf[start+4]; // Look for match hlwp = 5*(quisk_hermeslite_writepointer-1); if (dindex == 0x7f) { printf("ERROR: Hermes-Lite did not process command\n"); } else if (dindex != (quisk_hermeslite_writequeue[hlwp])) { printf("ERROR: Nonmatching Hermes-Lite response %d seen\n",dindex); } else { //printf("Response %d received\n",dindex); quisk_hermeslite_writepointer--; quisk_hermeslite_writeattempts = 0; } } else { printf("ERROR: Unexpected Hermes-Lite response %d seen\n",dindex); } } else { dindex = dindex >> 2; } // this does not save data for Hermes-Lite ACK if (dindex >= 0 && dindex <= 4) { // Save the data returned by the hardware quisk_hermes_to_pc[dindex * 4 ] = buf[start + 1]; // C1 to C4 quisk_hermes_to_pc[dindex * 4 + 1] = buf[start + 2]; quisk_hermes_to_pc[dindex * 4 + 2] = buf[start + 3]; quisk_hermes_to_pc[dindex * 4 + 3] = buf[start + 4]; } if (dindex == 0) { // C0 is 0b00000xxx //code_version = quisk_hermes_to_pc[3]; if ((quisk_hermes_to_pc[0] & 0x01) != 0) // C1 quisk_sound_state.overrange++; if (quisk_hermes_code_version >= 62) { hardware_ptt = buf[start] & 0x01; // C0 bit zero is PTT hardware_cwkey = (buf[start] & 0x02) >> 1; // C0 bit one is CW key state } else { hardware_cwkey = buf[start] & 0x01; // C0 bit zero is CW key state } if (rxMode == CWL || rxMode == CWU) { state = hardware_cwkey | is_PTT_down; } else { state = is_PTT_down; } if (state != key_state) { key_state = state; quisk_set_key_down(state); } } else if(dindex == 1) { // temperature and forward power hermes_temperature += quisk_hermes_to_pc[4] << 8 | quisk_hermes_to_pc[5]; hermes_fwd_power += quisk_hermes_to_pc[6] << 8 | quisk_hermes_to_pc[7]; hermes_count_temperature++; } else if (dindex == 2) { // reverse power and current hermes_rev_power += quisk_hermes_to_pc[8] << 8 | quisk_hermes_to_pc[9]; hermes_pa_current += quisk_hermes_to_pc[10] << 8 | quisk_hermes_to_pc[11]; hermes_count_current++; } // convert 24-bit samples to 32-bit samples; int must be 32 bits. index = start + 5; for (i = 0; i < num_records; i++) { // read records xi = buf[index ] << 24 | buf[index + 1] << 16 | buf[index + 2] << 8; xr = buf[index + 3] << 24 | buf[index + 4] << 16 | buf[index + 5] << 8; samp[nSamples] = xr + xi * I; // first receiver index += 6; for (j = 0; j < quisk_multirx_count; j++) { // multirx receivers xi = buf[index ] << 24 | buf[index + 1] << 16 | buf[index + 2] << 8; xr = buf[index + 3] << 24 | buf[index + 4] << 16 | buf[index + 5] << 8; c = xr + xi * I; multirx_cSamples[j][nSamples] = c; if (multirx_fft_data[j].index < multirx_fft_width) multirx_fft_data[j].samples[multirx_fft_data[j].index++] = c; index += 6; } nSamples++; index += 2; } } } if ((quisk_pc_to_hermes[3] >> 3 & 0x7) != quisk_multirx_count && // change in number of receivers ( ! quisk_multirx_count || multirx_fft_next_state == 2)) { // wait until the current FFT is finished quisk_multirx_state = 0; // Do not change receiver count without stopping Hermes and restarting } if (multirx_fft_next_state == 2) { // previous FFT is done if (++multirx_fft_next_index >= quisk_multirx_count) multirx_fft_next_index = 0; multirx_fft_next_state = 0; } if (quisk_multirx_count && multirx_fft_next_state == 0 && multirx_fft_data[multirx_fft_next_index].index >= multirx_fft_width) { // FFT is read to run memcpy(multirx_fft_next_samples, multirx_fft_data[multirx_fft_next_index].samples, multirx_fft_width * sizeof(fftw_complex)); multirx_fft_data[multirx_fft_next_index].index = 0; multirx_fft_next_time = 1.0 / graph_refresh / quisk_multirx_count; multirx_fft_next_state = 1; // this FFT is ready to run } return nSamples; } static int read_rx_udp17(complex double * cSamples0) // Read samples from UDP { // Size of complex sample array is SAMP_BUFFER_SIZE ssize_t bytes; unsigned char buf[1500]; // Maximum Ethernet is 1500 bytes. static unsigned char seq0; // must be 8 bits int i, n, nSamples0, xr, xi, index, want_samples, key_down; complex double sample; unsigned char * ptxr, * ptxi; struct timeval tm_wait; fft_data * ptFFT; fd_set fds; static int block_number=0; // Data from the receiver is little-endian if ( ! rx_udp_gain_correct) { // correct for second stage CIC decimation JIM JIM int dec; dec = (int)(rx_udp_clock / 30.0 / fft_sample_rate + 0.5); if ((dec / 3) * 3 == dec) // Decimation by a factor of 3 rx_udp_gain_correct = 1.053497942; else // Decimation by factors of two rx_udp_gain_correct = 1.0; //printf ("Gain %d %.8lf\n", dec, rx_udp_gain_correct); } if ( ! quisk_rx_udp_started) { // we never received any data // send our return address until we receive UDP blocks tm_wait.tv_sec = 0; tm_wait.tv_usec = 5000; FD_ZERO (&fds); FD_SET (rx_udp_socket, &fds); if (select (rx_udp_socket + 1, &fds, NULL, NULL, &tm_wait) == 1) { // see if data is available bytes = recv(rx_udp_socket, (char *)buf, 1500, 0); // throw away the first block seq0 = buf[0] + 1; // Next expected sequence number quisk_rx_udp_started = 1; #if DEBUG_IO || DEBUG printf("Udp data started\n"); #endif } else { // send our return address to the sample source buf[0] = buf[1] = 0x72; // UDP command "register return address" send(rx_udp_socket, (char *)buf, 2, 0); return 0; } } nSamples0 = 0; want_samples = (int)(quisk_sound_state.data_poll_usec * 1e-6 * quisk_sound_state.sample_rate + 0.5); key_down = quisk_is_key_down(); while (nSamples0 < want_samples) { // read several UDP blocks tm_wait.tv_sec = 0; tm_wait.tv_usec = 100000; // Linux seems to have problems with very small time intervals FD_ZERO (&fds); FD_SET (rx_udp_socket, &fds); i = select (rx_udp_socket + 1, &fds, NULL, NULL, &tm_wait); if (i == 1) ; else if (i == 0) { #if DEBUG_IO || DEBUG printf("Udp socket timeout\n"); #endif return 0; } else { #if DEBUG_IO || DEBUG printf("Udp select error %d\n", i); #endif return 0; } bytes = recv(rx_udp_socket, (char *)buf, 1500, 0); // blocking read if (bytes != RX_UDP_SIZE) { // Known size of sample block quisk_sound_state.read_error++; #if DEBUG_IO || DEBUG printf("read_rx_udp: Bad block size\n"); #endif continue; } // buf[0] is the sequence number // buf[1] is the status: // bit 0: key up/down state // bit 1: set for ADC overrange (clip) if (buf[0] != seq0) { #if DEBUG_IO || DEBUG printf("read_rx_udp: Bad sequence want %3d got %3d\n", (unsigned int)seq0, (unsigned int)buf[0]); #endif quisk_sound_state.read_error++; } seq0 = buf[0] + 1; // Next expected sequence number //quisk_set_key_down(buf[1] & 0x01); // bit zero is key state if (buf[1] & 0x02) // bit one is ADC overrange quisk_sound_state.overrange++; index = 2; ptxr = (unsigned char *)&xr; ptxi = (unsigned char *)ξ // convert 24-bit samples to 32-bit samples; int must be 32 bits. while (index < bytes) { if (is_little_endian) { xr = xi = 0; memcpy (ptxr + 1, buf + index, 3); index += 3; memcpy (ptxi + 1, buf + index, 3); index += 3; sample = (xr + xi * I) * rx_udp_gain_correct; } else { // big-endian *(ptxr ) = buf[index + 2]; *(ptxr + 1) = buf[index + 1]; *(ptxr + 2) = buf[index ]; *(ptxr + 3) = 0; index += 3; *(ptxi ) = buf[index + 2]; *(ptxi + 1) = buf[index + 1]; *(ptxi + 2) = buf[index ]; *(ptxi + 3) = 0; index += 3; sample = (xr + xi * I) * rx_udp_gain_correct; } if (xr & 0x100) { // channel 1 if (quisk_invert_spectrum) // Invert spectrum sample = conj(sample); // Put samples into the fft input array. ptFFT = fft_data_array + fft_data_index; if ( ! (xi & 0x100)) { // zero marker for start of first block if (ptFFT->index != 0) { //printf("Resync block\n"); fft_error++; ptFFT->index = 0; } ptFFT->block = block_number = 0; } else if (ptFFT->index == 0) { if (scan_blocks) { if (++block_number < scan_blocks) ptFFT->block = block_number; else ptFFT->block = block_number = 0; } else { ptFFT->block = block_number = 0; } if (scan_blocks && block_number >= scan_blocks) printf("Bad block_number %d\n", block_number); } ptFFT->samples[ptFFT->index] = sample; if ((isFDX || ! key_down) && ++(ptFFT->index) >= fft_size) { // check sample count n = fft_data_index + 1; // next FFT data location if (n >= FFT_ARRAY_SIZE) n = 0; if (fft_data_array[n].filled == 0) { // Is the next buffer empty? fft_data_array[n].index = 0; fft_data_array[n].block = 0; fft_data_array[fft_data_index].filled = 1; // Mark the previous buffer ready. fft_data_index = n; // Write samples into the new buffer. ptFFT = fft_data_array + fft_data_index; } else { // no place to write samples ptFFT->index = 0; ptFFT->block = 0; fft_error++; } } } else { // channel 0 cSamples0[nSamples0++] = sample; } } } return nSamples0; } static PyObject * open_rx_udp(PyObject * self, PyObject * args) { const char * ip; int port; char buf[128]; struct sockaddr_in Addr; int recvsize; #if DEBUG_IO int intbuf; #ifdef MS_WINDOWS int bufsize = sizeof(int); #else socklen_t bufsize = sizeof(int); #endif #endif #ifdef MS_WINDOWS WORD wVersionRequested; WSADATA wsaData; #endif if (!PyArg_ParseTuple (args, "si", &ip, &port)) return NULL; #ifdef MS_WINDOWS wVersionRequested = MAKEWORD(2, 2); if (WSAStartup(wVersionRequested, &wsaData) != 0) { sprintf(buf, "Failed to initialize Winsock (WSAStartup)"); return PyString_FromString(buf); } else { cleanupWSA = 1; } #endif #if DEBUG_IO printf("open_rx_udp to IP %s port 0x%X\n", ip, port); #endif quisk_using_udp = 1; rx_udp_socket = socket(PF_INET, SOCK_DGRAM, 0); if (rx_udp_socket != INVALID_SOCKET) { recvsize = 256000; setsockopt(rx_udp_socket, SOL_SOCKET, SO_RCVBUF, (char *)&recvsize, sizeof(recvsize)); memset(&Addr, 0, sizeof(Addr)); Addr.sin_family = AF_INET; Addr.sin_port = htons(port); #ifdef MS_WINDOWS Addr.sin_addr.S_un.S_addr = inet_addr(ip); #else inet_aton(ip, &Addr.sin_addr); #endif if (connect(rx_udp_socket, (const struct sockaddr *)&Addr, sizeof(Addr)) != 0) { shutdown(rx_udp_socket, QUISK_SHUT_BOTH); close(rx_udp_socket); rx_udp_socket = INVALID_SOCKET; sprintf(buf, "Failed to connect to UDP %s port 0x%X", ip, port); } else { sprintf(buf, "Capture from UDP %s port 0x%X", ip, port); if (quisk_use_rx_udp == 17) quisk_sample_source(NULL, close_udp, read_rx_udp17); else if (quisk_use_rx_udp == 10) { quisk_sample_source(NULL, close_udp10, read_rx_udp10); init_bandscope(); } else quisk_sample_source(NULL, close_udp, quisk_read_rx_udp); #if DEBUG_IO if (getsockopt(rx_udp_socket, SOL_SOCKET, SO_RCVBUF, (char *)&intbuf, &bufsize) == 0) printf("UDP socket receive buffer size %d\n", intbuf); else printf ("Failure SO_RCVBUF\n"); #endif } } else { sprintf(buf, "Failed to open socket"); } return PyString_FromString(buf); } static PyObject * open_sound(PyObject * self, PyObject * args) { int rate; char * capt, * play, * mname, * mip, * mpname; const char * utf8 = "utf-8"; if (!PyArg_ParseTuple (args, "esesiiiessiiiidesi", utf8, &capt, utf8, &play, &rate, &quisk_sound_state.data_poll_usec, &quisk_sound_state.latency_millisecs, utf8, &mname, &mip, &quisk_sound_state.tx_audio_port, &quisk_sound_state.mic_sample_rate, &quisk_sound_state.mic_channel_I, &quisk_sound_state.mic_channel_Q, &quisk_sound_state.mic_out_volume, utf8, &mpname, &quisk_sound_state.mic_playback_rate )) return NULL; #if SAMPLES_FROM_FILE == 1 QuiskWavWriteOpen(&hWav, "band.wav", 3, 2, 4, 48000, 1E3 / CLIP32); #elif SAMPLES_FROM_FILE == 2 QuiskWavReadOpen(&hWav, "band.wav", 3, 2, 4, 48000, CLIP32 / 1E6); #endif if (quisk_sound_state.mic_out_volume > 0.7) // maximum value must leave headroom for quisk_sound_state.mic_out_volume = 0.7; // the amplitude and phase adjustments quisk_sound_state.playback_rate = QuiskGetConfigInt("playback_rate", 48000); quisk_mic_preemphasis = QuiskGetConfigDouble("mic_preemphasis", 0.6); //if (quisk_mic_preemphasis < 0.0 || quisk_mic_preemphasis > 1.0) // quisk_mic_preemphasis = 1.0; quisk_mic_clip = QuiskGetConfigDouble("mic_clip", 3.0); agc_release_time = QuiskGetConfigDouble("agc_release_time", 1.0); strncpy(quisk_sound_state.dev_capt_name, capt, QUISK_SC_SIZE); strncpy(quisk_sound_state.dev_play_name, play, QUISK_SC_SIZE); strncpy(quisk_sound_state.mic_dev_name, mname, QUISK_SC_SIZE); strncpy(quisk_sound_state.name_of_mic_play, mpname, QUISK_SC_SIZE); strncpy(quisk_sound_state.mic_ip, mip, IP_SIZE); strncpy(quisk_sound_state.IQ_server, QuiskGetConfigString("IQ_Server_IP", ""), IP_SIZE); quisk_sound_state.verbose_pulse = QuiskGetConfigInt("pulse_audio_verbose_output", 0); fft_error = 0; PyMem_Free(capt); PyMem_Free(play); PyMem_Free(mname); PyMem_Free(mpname); quisk_open_sound(); quisk_open_mic(); return get_state(NULL, NULL); } static PyObject * close_sound(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; quisk_close_mic(); quisk_close_sound(); quisk_close_key(); #if SAMPLES_FROM_FILE QuiskWavClose(&hWav); #endif Py_INCREF (Py_None); return Py_None; } static PyObject * change_scan(PyObject * self, PyObject * args) // Called from GUI thread { // Change to a new FFT rate if (!PyArg_ParseTuple (args, "iidii", &scan_blocks, &scan_sample_rate, &scan_valid, &scan_vfo0, &scan_deltaf)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * change_rates(PyObject * self, PyObject * args) // Called from GUI thread { // Change to new sample rates multiple_sample_rates = 1; if (!PyArg_ParseTuple (args, "iiii", &quisk_sound_state.sample_rate, &vfo_audio, &fft_sample_rate, &vfo_screen)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * change_rate(PyObject * self, PyObject * args) // Called from GUI thread { // Change to a new sample rate int rate, avg; if (!PyArg_ParseTuple (args, "ii", &rate, &avg)) return NULL; if (multiple_sample_rates) { fft_sample_rate = rate; } else { quisk_sound_state.sample_rate = rate; fft_sample_rate = rate; } rx_udp_gain_correct = 0; // re-calculate JIM Py_INCREF (Py_None); return Py_None; } static PyObject * read_sound(PyObject * self, PyObject * args) { int n; if (!PyArg_ParseTuple (args, "")) return NULL; Py_BEGIN_ALLOW_THREADS n = quisk_read_sound(); Py_END_ALLOW_THREADS return PyInt_FromLong(n); } static PyObject * start_sound(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; quisk_start_sound(); Py_INCREF (Py_None); return Py_None; } static PyObject * mixer_set(PyObject * self, PyObject * args) { char * card_name; int numid; PyObject * value; char err_msg[QUISK_SC_SIZE]; if (!PyArg_ParseTuple (args, "siO", &card_name, &numid, &value)) return NULL; quisk_mixer_set(card_name, numid, value, err_msg, QUISK_SC_SIZE); return PyString_FromString(err_msg); } static PyObject * pc_to_hermes(PyObject * self, PyObject * args) { PyObject * byteArray; if (!PyArg_ParseTuple (args, "O", &byteArray)) return NULL; if ( ! PyByteArray_Check(byteArray)) { PyErr_SetString (QuiskError, "Object is not a bytearray."); return NULL; } if (PyByteArray_Size(byteArray) != 17 * 4) { PyErr_SetString (QuiskError, "Bytearray size must be 17 * 4."); return NULL; } memmove(quisk_pc_to_hermes, PyByteArray_AsString(byteArray), 17 * 4); Py_INCREF (Py_None); return Py_None; } // Changes for HermesLite v2 thanks to Steve, KF7O static PyObject * pc_to_hermeslite_writequeue(PyObject * self, PyObject * args) { PyObject * byteArray; if (!PyArg_ParseTuple (args, "O", &byteArray)) return NULL; if ( ! PyByteArray_Check(byteArray)) { PyErr_SetString (QuiskError, "Object is not a bytearray."); return NULL; } if (PyByteArray_Size(byteArray) != 4 * 5) { PyErr_SetString (QuiskError, "Bytearray size must be 4 * 5."); return NULL; } memmove(quisk_hermeslite_writequeue, PyByteArray_AsString(byteArray), 4 * 5); Py_INCREF (Py_None); return Py_None; } static PyObject * set_hermeslite_writepointer(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "I", &quisk_hermeslite_writepointer)) return NULL; if (quisk_hermeslite_writepointer > 4 || quisk_hermeslite_writepointer < 0) { PyErr_SetString (QuiskError, "Hermeslite writepointer must be >=0 and <=4."); return NULL; } Py_INCREF (Py_None); return Py_None; } static PyObject * get_hermeslite_writepointer(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; return Py_BuildValue("I",quisk_hermeslite_writepointer); } static PyObject * get_hermeslite_response(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; return PyByteArray_FromStringAndSize((char *)quisk_hermeslite_response, 5); } static PyObject * clear_hermeslite_response(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; memset(quisk_hermeslite_response, 0, 5*sizeof(char)); Py_INCREF (Py_None); return Py_None; } static PyObject * hermes_to_pc(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; return PyByteArray_FromStringAndSize((char *)quisk_hermes_to_pc, 5 * 4); } static PyObject * set_hermes_id(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "ii", &quisk_hermes_code_version, &quisk_hermes_board_id)) return NULL; switch(quisk_hermes_board_id) { default: case 3: // Angelia and Odyssey-2 bandscopeBlockCount = 32; break; case 6: // Hermes Lite bandscopeBlockCount = 4; break; } bandscope_size = bandscopeBlockCount * 512; Py_INCREF (Py_None); return Py_None; } #ifdef MS_WINDOWS static const char * Win_NtoA(unsigned long addr) { static char buf32[32]; if (addr > 0) snprintf(buf32, 32, "%li.%li.%li.%li", (addr>>24)&0xFF, (addr>>16)&0xFF, (addr>>8)&0xFF, (addr>>0)&0xFF); else buf32[0] = 0; return buf32; } #else static const char * Lin_NtoA(struct sockaddr * a) { static char buf32[32]; unsigned long addr; if (a && (addr = ntohl(((struct sockaddr_in *)a)->sin_addr.s_addr)) > 0) snprintf(buf32, 32, "%li.%li.%li.%li", (addr>>24)&0xFF, (addr>>16)&0xFF, (addr>>8)&0xFF, (addr>>0)&0xFF); else buf32[0] = 0; return buf32; } #endif static PyObject * ip_interfaces(PyObject * self, PyObject * args) { #ifdef MS_WINDOWS int i; MIB_IPADDRTABLE * ipTable = NULL; IP_ADAPTER_INFO * pAdapterInfo; PyObject * pylist, * tup; MIB_IPADDRROW row; ULONG bufLen; DWORD ipRet, apRet; const char * name; unsigned long ipAddr, netmask, baddr; if (!PyArg_ParseTuple (args, "")) return NULL; pylist = PyList_New(0); bufLen = 0; for (i=0; i<5; i++) { ipRet = GetIpAddrTable(ipTable, &bufLen, 0); if (ipRet == ERROR_INSUFFICIENT_BUFFER) { free(ipTable); // in case we had previously allocated it ipTable = (MIB_IPADDRTABLE *) malloc(bufLen); } else if (ipRet == NO_ERROR) break; else { free(ipTable); ipTable = NULL; break; } } if (ipTable) { pAdapterInfo = NULL; bufLen = 0; for (i=0; i<5; i++) { apRet = GetAdaptersInfo(pAdapterInfo, &bufLen); if (apRet == ERROR_BUFFER_OVERFLOW) { free(pAdapterInfo); // in case we had previously allocated it pAdapterInfo = (IP_ADAPTER_INFO *) malloc(bufLen); } else if (apRet == ERROR_SUCCESS) break; else { free(pAdapterInfo); pAdapterInfo = NULL; break; } } for (i=0; idwNumEntries; i++) { row = ipTable->table[i]; // Now lookup the appropriate adaptor-name in the pAdaptorInfos, if we can find it name = NULL; if (pAdapterInfo) { IP_ADAPTER_INFO * next = pAdapterInfo; while((next)&&(name==NULL)) { IP_ADDR_STRING * ipAddr = &next->IpAddressList; while(ipAddr) { if (inet_addr(ipAddr->IpAddress.String) == row.dwAddr) { name = next->AdapterName; break; } ipAddr = ipAddr->Next; } next = next->Next; } } ipAddr = ntohl(row.dwAddr); netmask = ntohl(row.dwMask); baddr = ipAddr & netmask; if (row.dwBCastAddr) baddr |= ~netmask; tup = PyTuple_New(4); if (name == NULL) PyTuple_SetItem(tup, 0, PyString_FromString("unnamed")); else PyTuple_SetItem(tup, 0, PyString_FromString(name)); PyTuple_SetItem(tup, 1, PyString_FromString(Win_NtoA(ipAddr))); PyTuple_SetItem(tup, 2, PyString_FromString(Win_NtoA(netmask))); PyTuple_SetItem(tup, 3, PyString_FromString(Win_NtoA(baddr))); PyList_Append(pylist, tup); Py_DECREF(tup); } free(pAdapterInfo); free(ipTable); } #else PyObject * pylist, * tup; struct ifaddrs * ifap, * p; if (!PyArg_ParseTuple (args, "")) return NULL; pylist = PyList_New(0); if (getifaddrs(&ifap) == 0) { p = ifap; while(p) { if ((p->ifa_addr) && p->ifa_addr->sa_family == AF_INET) { tup = PyTuple_New(4); PyTuple_SetItem(tup, 0, PyString_FromString(p->ifa_name)); PyTuple_SetItem(tup, 1, PyString_FromString(Lin_NtoA(p->ifa_addr))); PyTuple_SetItem(tup, 2, PyString_FromString(Lin_NtoA(p->ifa_netmask))); PyTuple_SetItem(tup, 3, PyString_FromString(Lin_NtoA(p->ifa_broadaddr))); PyList_Append(pylist, tup); Py_DECREF(tup); } p = p->ifa_next; } freeifaddrs(ifap); } #endif return pylist; } static PyObject * invert_spectrum(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &quisk_invert_spectrum)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_agc(PyObject * self, PyObject * args) { /* Change the AGC level */ if (!PyArg_ParseTuple (args, "d", &agcReleaseGain)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_filters(PyObject * self, PyObject * args) { // Enter the coefficients of the I and Q digital filters. The storage for // filters is not malloc'd because filters may be changed while being used. // Multiple filters are available at nFilter. PyObject * filterI, * filterQ; int i, size, nFilter, bw, start_offset; PyObject * obj; char buf98[98]; if (!PyArg_ParseTuple (args, "OOiii", &filterI, &filterQ, &bw, &start_offset, &nFilter)) return NULL; if (PySequence_Check(filterI) != 1) { PyErr_SetString (QuiskError, "Filter I is not a sequence"); return NULL; } if (PySequence_Check(filterQ) != 1) { PyErr_SetString (QuiskError, "Filter Q is not a sequence"); return NULL; } size = PySequence_Size(filterI); if (size != PySequence_Size(filterQ)) { PyErr_SetString (QuiskError, "The size of filters I and Q must be equal"); return NULL; } if (size >= MAX_FILTER_SIZE) { snprintf(buf98, 98, "Filter size must be less than %d", MAX_FILTER_SIZE); PyErr_SetString (QuiskError, buf98); return NULL; } filter_bandwidth[nFilter] = bw; if (nFilter == 0) filter_start_offset = start_offset; for (i = 0; i < size; i++) { obj = PySequence_GetItem(filterI, i); cFilterI[nFilter][i] = PyFloat_AsDouble(obj); Py_XDECREF(obj); obj = PySequence_GetItem(filterQ, i); cFilterQ[nFilter][i] = PyFloat_AsDouble(obj); Py_XDECREF(obj); } sizeFilter = size; Py_INCREF (Py_None); return Py_None; } static PyObject * set_auto_notch(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &quisk_auto_notch)) return NULL; dAutoNotch(NULL, 0, 0, 0); Py_INCREF (Py_None); return Py_None; } static PyObject * set_noise_blanker(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &quisk_noise_blanker)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_enable_bandscope(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &enable_bandscope)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_rx_mode(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &rxMode)) return NULL; quisk_set_tx_mode(); Py_INCREF (Py_None); return Py_None; } static PyObject * set_spot_level(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &quiskSpotLevel)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_imd_level(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &quiskImdLevel)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_mic_out_volume(PyObject * self, PyObject * args) { int level; if (!PyArg_ParseTuple (args, "i", &level)) return NULL; quisk_sound_state.mic_out_volume = level / 100.0; Py_INCREF (Py_None); return Py_None; } static PyObject * ImmediateChange(PyObject * self, PyObject * args) // called from the GUI thread { char * name; int keyupDelay; if (!PyArg_ParseTuple (args, "s", &name)) return NULL; if ( ! strcmp(name, "keyupDelay")) { keyupDelay = quiskKeyupDelay = QuiskGetConfigInt("keyupDelay", 23); if (quisk_use_rx_udp == 10) keyupDelay += 30; keyupDelayCode = (int)(quisk_sound_state.playback_rate *1e-3 * keyupDelay + 0.5); } Py_INCREF (Py_None); return Py_None; } static PyObject * set_split_rxtx(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &split_rxtx)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_tune(PyObject * self, PyObject * args) { /* Change the tuning frequency */ if (!PyArg_ParseTuple (args, "ii", &rx_tune_freq, &quisk_tx_tune_freq)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_sidetone(PyObject * self, PyObject * args) { int keyupDelay; // Add a silent period after key up to remove reception of CW by the receiver. if (!PyArg_ParseTuple (args, "idii", &quisk_sidetoneCtrl, &sidetoneVolume, &rit_freq, &keyupDelay)) return NULL; quiskKeyupDelay = keyupDelay; sidetonePhase = cexp((I * 2.0 * M_PI * abs(rit_freq)) / quisk_sound_state.playback_rate); if (quisk_use_rx_udp == 10) keyupDelay += 30; // Extra delay needed because the CW waveform is transmitted after key up. keyupDelayCode = (int)(quisk_sound_state.playback_rate *1e-3 * keyupDelay + 0.5); if (rxMode == CWL || rxMode == CWU) dAutoNotch(NULL, 0, 0, 0); // for CW, changing the RIT affects autonotch Py_INCREF (Py_None); return Py_None; } static PyObject * set_squelch(PyObject * self, PyObject * args) // Set level for FM squelch { if (!PyArg_ParseTuple (args, "d", &squelch_level)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_ssb_squelch(PyObject * self, PyObject * args) // Set level for SSB squelch { if (!PyArg_ParseTuple (args, "ii", &ssb_squelch_enabled, &ssb_squelch_level)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_kill_audio(PyObject * self, PyObject * args) { /* replace radio sound with silence */ if (!PyArg_ParseTuple (args, "i", &kill_audio)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * tx_hold_state(PyObject * self, PyObject * args) { // Query or set the transmit hold state int i; if (!PyArg_ParseTuple (args, "i", &i)) return NULL; if (i >= 0) // arg < 0 is a Query for the current value quiskTxHoldState = i; return PyInt_FromLong(quiskTxHoldState); } static PyObject * set_transmit_mode(PyObject * self, PyObject * args) { /* Set the radio to transmit mode */ if (!PyArg_ParseTuple (args, "i", &quisk_transmit_mode)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_volume(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "d", &quisk_audioVolume)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_ctcss(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "d", &quisk_ctcss_freq)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_key_down(PyObject * self, PyObject * args) { int down; if (!PyArg_ParseTuple (args, "i", &down)) return NULL; quisk_set_key_down(down); Py_INCREF (Py_None); return Py_None; } static PyObject * set_PTT(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &is_PTT_down)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_multirx_mode(PyObject * self, PyObject * args) { int index, mode; if (!PyArg_ParseTuple (args, "ii", &index, &mode)) return NULL; if (index < QUISK_MAX_RECEIVERS) multirx_mode[index] = mode; Py_INCREF (Py_None); return Py_None; } static PyObject * set_multirx_freq(PyObject * self, PyObject * args) { int index, freq; if (!PyArg_ParseTuple (args, "ii", &index, &freq)) return NULL; if (index < QUISK_MAX_RECEIVERS) multirx_freq[index] = freq; Py_INCREF (Py_None); return Py_None; } static PyObject * set_multirx_play_method(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &multirx_play_method)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_multirx_play_channel(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &multirx_play_channel)) return NULL; if (multirx_play_channel >= QUISK_MAX_RECEIVERS) multirx_play_channel = -1; Py_INCREF (Py_None); return Py_None; } static PyObject * get_multirx_graph(PyObject * self, PyObject * args) // Called by the GUI thread { int i, j, k; double d1, d2, scale; static double * fft_window=NULL; // Window for FFT data PyObject * retrn, * data; static double time0=0; // time of last graph if (!PyArg_ParseTuple (args, "")) return NULL; if ( ! fft_window) { // Create the fft window fft_window = (double *) malloc(sizeof(double) * multirx_fft_width); for (i = 0, j = -multirx_fft_width / 2; i < multirx_fft_width; i++, j++) fft_window[i] = 0.5 + 0.5 * cos(2. * M_PI * j / multirx_fft_width); // Hanning } retrn = PyTuple_New(2); if (multirx_fft_next_state == 1 && QuiskTimeSec() - time0 >= multirx_fft_next_time) { time0 = QuiskTimeSec(); // The FFT is ready to run. Calculate FFT. for (i = 0; i < multirx_fft_width; i++) // multiply by window multirx_fft_next_samples[i] *= fft_window[i]; fftw_execute(multirx_fft_next_plan); // Average the fft data into the graph in order of frequency data = PyTuple_New(multirx_data_width); scale = log10(multirx_fft_width) + 31.0 * log10(2.0); scale *= 20.0; j = MULTIRX_FFT_MULT; k = 0; d1 = 0; for (i = multirx_fft_width / 2; i < multirx_fft_width; i++) { // Negative frequencies d1 += cabs(multirx_fft_next_samples[i]); if (--j == 0) { d2 = 20.0 * log10(d1) - scale; if (d2 < -200) d2 = -200; PyTuple_SetItem(data, k++, PyFloat_FromDouble(d2)); d1 = 0; j = MULTIRX_FFT_MULT; } } for (i = 0; i < multirx_fft_width / 2; i++) { // Positive frequencies d1 += cabs(multirx_fft_next_samples[i]); if (--j == 0) { d2 = 20.0 * log10(d1) - scale; if (d2 < -200) d2 = -200; PyTuple_SetItem(data, k++, PyFloat_FromDouble(d2)); d1 = 0; j = MULTIRX_FFT_MULT; } } PyTuple_SetItem(retrn, 0, data); PyTuple_SetItem(retrn, 1, PyInt_FromLong(multirx_fft_next_index)); multirx_fft_next_state = 2; // This FFT is done. } else { data = PyTuple_New(0); PyTuple_SetItem(retrn, 0, data); PyTuple_SetItem(retrn, 1, PyInt_FromLong(-1)); } return retrn; } static PyObject * get_bandscope(void) // Called by the GUI thread { int i, j, j1, j2, L; static int fft_count = 0; static double the_max = 0; static double time0=0; // time of last graph double d1, d2, sample, frac, scale; PyObject * tuple2; if (bandscopeState == 99 && bandscopePlan) { // bandscope samples are ready for (i = 0; i < bandscope_size; i++) { d1 = fabs(bandscopeSamples[i]); if (d1 > the_max) the_max = d1; bandscopeSamples[i] *= bandscopeWindow[i]; // multiply by window } fftw_execute(bandscopePlan); // Calculate forward FFT // The return FFT has length bandscope_size / 2 + 1 L = bandscope_size / 2 + 1; for (i = 0; i < L; i++) bandscopeAverage[i] += cabs(bandscopeFFT[i]); bandscopeState = 0; fft_count++; if (QuiskTimeSec() - time0 >= 1.0 / graph_refresh) { // return FFT data bandscopeAverage[L] = 0.0; // in case we run off the end // Average the return FFT into the data width tuple2 = PyTuple_New(graph_width); frac = (double)L / graph_width; scale = 1.0 / frac / fft_count / bandscope_size; for (i = 0; i < graph_width; i++) { // for each pixel d1 = i * frac; d2 = (i + 1) * frac; j1 = floor(d1); j2 = floor(d2); if (j1 == j2) { sample = (d2 - d1) * bandscopeAverage[j1]; } else { sample = (j1 + 1 - d1) * bandscopeAverage[j1]; for (j = j1 + 1; j < j2; j++) sample += bandscopeAverage[j]; sample += (d2 - j2) * bandscopeAverage[j2]; } sample = sample * scale; if (sample <= 1E-10) sample = -200.0; else sample = 20.0 * log10(sample); PyTuple_SetItem(tuple2, i, PyFloat_FromDouble(sample)); } fft_count = 0; time0 = QuiskTimeSec(); hermes_adc_level = the_max; the_max = 0; for (i = 0; i < L; i++) bandscopeAverage[i] = 0; return tuple2; } } Py_INCREF(Py_None); // No data yet return Py_None; } static PyObject * get_graph(PyObject * self, PyObject * args) // Called by the GUI thread { int i, j, k, m, n, index, ffts, ii, mm, m0, deltam; fft_data * ptFft; PyObject * tuple2; double d1, d2, scale, zoom, deltaf; complex double c; static double meter = 0; // RMS s-meter static int use_fft = 1; // Use the FFT, or return raw data static double * fft_avg=NULL; // Array to average the FFT static double * fft_tmp; static int count_fft=0; // how many fft's have occurred (for average) static double time0=0; // time of last graph if (!PyArg_ParseTuple (args, "idd", &k, &zoom, &deltaf)) return NULL; if (k == 2) { return get_bandscope(); } if (k != use_fft) { // change in data return type; re-initialize use_fft = k; count_fft = 0; } if ( ! fft_avg) { fft_avg = (double *) malloc(sizeof(double) * fft_size); fft_tmp = (double *) malloc(sizeof(double) * fft_size); for (i = 0; i < fft_size; i++) fft_avg[i] = 0; } // Process all FFTs that are ready to run. index = fft_data_index; // oldest data first - FIFO for (ffts = 0; ffts < FFT_ARRAY_SIZE; ffts++) { if (++index >= FFT_ARRAY_SIZE) index = 0; if (fft_data_array[index].filled) ptFft = fft_data_array + index; else continue; if (scan_blocks && ptFft->block >= scan_blocks) { //printf("Reject block %d\n", ptFft->block); ptFft->filled = 0; continue; } if ( ! use_fft) { // return raw data, not FFT tuple2 = PyTuple_New(data_width); for (i = 0; i < data_width; i++) PyTuple_SetItem(tuple2, i, PyComplex_FromDoubles(creal(ptFft->samples[i]), cimag(ptFft->samples[i]))); ptFft->filled = 0; return tuple2; } // Continue with FFT calculation for (i = 0; i < fft_size; i++) // multiply by window ptFft->samples[i] *= fft_window[i]; fftw_execute_dft(quisk_fft_plan, ptFft->samples, ptFft->samples); // Calculate FFT // Create RMS s-meter value at known bandwidth // The pass band is (rx_tune_freq + filter_start_offset) to += bandwidth // d1 is the tune frequency // d2 is the number of FFT bins required for the bandwidth // i is the starting bin number from - sample_rate / 2 to + sample_rate / 2 d2 = (double)filter_bandwidth[0] * fft_size / fft_sample_rate; if (scan_blocks) { // Use tx, not rx?? ERROR: d1 = ((double)quisk_tx_tune_freq + vfo_screen - scan_vfo0 - scan_deltaf * ptFft->block) * fft_size / scan_sample_rate; i = (int)(d1 - d2 / 2 + 0.5); } else i = (int)((double)(rx_tune_freq + filter_start_offset) * fft_size / fft_sample_rate + 0.5); n = (int)(floor(d2) + 0.01); // number of whole bins to add if (i > - fft_size / 2 && i + n + 1 < fft_size / 2) { // too close to edge? for (j = 0; j < n; i++, j++) { if (i < 0) c = ptFft->samples[fft_size + i]; // negative frequencies else c = ptFft->samples[i]; // positive frequencies meter = meter + c * conj(c); // add square of amplitude } if (i < 0) // add fractional next bin c = ptFft->samples[fft_size + i]; else c = ptFft->samples[i]; meter = meter + c * conj(c) * (d2 - n); // fractional part of next bin } // Average the fft data into the graph in order of frequency if (scan_blocks) { if (ptFft->block == (scan_blocks - 1)) count_fft++; k = 0; for (i = fft_size / 2; i < fft_size; i++) // Negative frequencies fft_tmp[k++] = cabs(ptFft->samples[i]); for (i = 0; i < fft_size / 2; i++) // Positive frequencies fft_tmp[k++] = cabs(ptFft->samples[i]); // Average this block into its correct position m0 = (int)(fft_size * ((1.0 - scan_valid) / 2.0)); deltam = (int)(fft_size * scan_valid / scan_blocks); m = mm = m0 + ptFft->block * deltam; // target position i = ii = (int)(fft_size * ((1.0 - scan_valid) / 2.0)); // start of valid data for (j = 0; j < deltam; j++) { d2 = 0; for (n = 0; n < scan_blocks; n++) d2 += fft_tmp[i++]; fft_avg[m++] = d2; } //printf(" %d %.4lf At %5d to %5d place %5d to %5d for block %d\n", fft_size, scan_valid, mm, m, ii, i, ptFft->block); } else { count_fft++; k = 0; for (i = fft_size / 2; i < fft_size; i++) // Negative frequencies fft_avg[k++] += cabs(ptFft->samples[i]); for (i = 0; i < fft_size / 2; i++) // Positive frequencies fft_avg[k++] += cabs(ptFft->samples[i]); } ptFft->filled = 0; if (count_fft > 0 && QuiskTimeSec() - time0 >= 1.0 / graph_refresh) { // We have averaged enough fft's to return the graph data. // Average the fft data of size fft_size into the size of data_width. n = (int)(zoom * (double)fft_size / data_width + 0.5); if (n < 1) n = 1; for (i = 0; i < data_width; i++) { // For each graph pixel // find k, the starting index into the FFT data k = (int)(fft_size * ( deltaf / fft_sample_rate + zoom * ((double)i / data_width - 0.5) + 0.5) + 0.1); d2 = 0.0; for (j = 0; j < n; j++, k++) if (k >= 0 && k < fft_size) d2 += fft_avg[k]; fft_avg[i] = d2; } scale = 1.0 / 2147483647.0 / fft_size; Smeter = meter * scale * scale / count_fft; // record the new s-meter value meter = 0; if (Smeter > 0) Smeter = 10.0 * log10(Smeter); else Smeter = -160.0; // This correction is for a -40 dB strong signal, and is caused by FFT leakage // into adjacent bins. It is the amplitude that is spread out, not the squared amplitude. Smeter += 4.25969; tuple2 = PyTuple_New(data_width); // scale = 1.0 / count_fft / fft_size; // Divide by sample count // scale /= pow(2.0, 31); // Normalize to max == 1 scale = log10(count_fft) + log10(fft_size) + 31.0 * log10(2.0); scale *= 20.0; for (i = 0; i < data_width; i++) { d2 = 20.0 * log10(fft_avg[i]) - scale; if (d2 < -200) d2 = -200; current_graph[i] = d2; PyTuple_SetItem(tuple2, i, PyFloat_FromDouble(d2)); } for (i = 0; i < fft_size; i++) fft_avg[i] = 0; count_fft = 0; time0 = QuiskTimeSec(); return tuple2; } } Py_INCREF(Py_None); // No data yet return Py_None; } static PyObject * get_filter(PyObject * self, PyObject * args) { int i, j, k, n; int freq, time; PyObject * tuple2; complex double cx; double d2, scale, accI, accQ; double * average, * bufI, * bufQ; double phase, delta; static fftw_complex * samples; static fftw_plan plan; if (!PyArg_ParseTuple (args, "")) return NULL; // Create space for the fft of size data_width samples = (fftw_complex *) fftw_malloc(sizeof(fftw_complex) * data_width); plan = fftw_plan_dft_1d(data_width, samples, samples, FFTW_FORWARD, FFTW_MEASURE); average = (double *) malloc(sizeof(double) * (data_width + sizeFilter)); bufI = (double *) malloc(sizeof(double) * sizeFilter); bufQ = (double *) malloc(sizeof(double) * sizeFilter); for (i = 0; i < data_width + sizeFilter; i++) average[i] = 0.5; // Value for freq == 0 for (freq = 1; freq < data_width / 2.0 - 10.0; freq++) { delta = 2 * M_PI / data_width * freq; phase = 0; // generate some initial samples to fill the filter pipeline for (time = 0; time < data_width + sizeFilter; time++) { average[time] += cos(phase); // current sample phase += delta; if (phase > 2 * M_PI) phase -= 2 * M_PI; } } // now filter the signal n = 0; for (time = 0; time < data_width + sizeFilter; time++) { d2 = average[time]; bufI[n] = d2; bufQ[n] = d2; accI = accQ = 0; j = n; for (k = 0; k < sizeFilter; k++) { accI += bufI[j] * cFilterI[0][k]; accQ += bufQ[j] * cFilterQ[0][k]; if (++j >= sizeFilter) j = 0; } cx = accI + I * accQ; // Filter output if (++n >= sizeFilter) n = 0; if (time >= sizeFilter) samples[time - sizeFilter] = cx; } for (i = 0; i < data_width; i++) // multiply by window samples[i] *= fft_window[i]; fftw_execute(plan); // Calculate FFT // Normalize and convert to log10 scale = 1. / data_width; for (k = 0; k < data_width; k++) { cx = samples[k]; average[k] = cabs(cx) * scale; if (average[k] <= 1e-7) // limit to -140 dB average[k] = -7; else average[k] = log10(average[k]); } // Return the graph data tuple2 = PyTuple_New(data_width); i = 0; // Negative frequencies: for (k = data_width / 2; k < data_width; k++, i++) PyTuple_SetItem(tuple2, i, PyFloat_FromDouble(20.0 * average[k])); // Positive frequencies: for (k = 0; k < data_width / 2; k++, i++) PyTuple_SetItem(tuple2, i, PyFloat_FromDouble(20.0 * average[k])); free(bufQ); free(bufI); free(average); fftw_destroy_plan(plan); fftw_free(samples); return tuple2; } static void measure_freq(complex double * cSamples, int nSamples, int srate) { int i, k, center, ipeak; double dmax, c3, freq; complex double cBuffer[SAMP_BUFFER_SIZE]; static int index = 0; // current index of samples static int fft_size=12000; // size of fft data static int fft_count=0; // number of ffts for the average static fftw_complex * samples; // complex data for fft static fftw_plan planA; // fft plan for fft static double * fft_window; // window function static double * fft_average; // average amplitudes static struct quisk_cHB45Filter HalfBand1 = {NULL, 0, 0}; static struct quisk_cHB45Filter HalfBand2 = {NULL, 0, 0}; static struct quisk_cHB45Filter HalfBand3 = {NULL, 0, 0}; if ( ! cSamples) { // malloc new space and initialize samples = (fftw_complex *) fftw_malloc(sizeof(fftw_complex) * fft_size); planA = fftw_plan_dft_1d(fft_size, samples, samples, FFTW_FORWARD, FFTW_MEASURE); fft_window = (double *) malloc(sizeof(double) * (fft_size + 1)); fft_average = (double *) malloc(sizeof(double) * fft_size); memset(fft_average, 0, sizeof(double) * fft_size); for (i = 0; i < fft_size; i++) // Hanning fft_window[i] = 0.50 - 0.50 * cos(2. * M_PI * i / (fft_size - 1)); return; } memcpy(cBuffer, cSamples, nSamples * sizeof(complex double)); // do not destroy cSamples nSamples = quisk_cDecim2HB45(cBuffer, nSamples, &HalfBand1); nSamples = quisk_cDecim2HB45(cBuffer, nSamples, &HalfBand2); nSamples = quisk_cDecim2HB45(cBuffer, nSamples, &HalfBand3); srate /= 8; // sample rate as decimated for (i = 0; i < nSamples && index < fft_size; i++, index++) samples[index] = cBuffer[i]; if (index < fft_size) return; // wait for a full array of samples for (i = 0; i < fft_size; i++) // multiply by window samples[i] *= fft_window[i]; fftw_execute(planA); // Calculate FFT index = 0; fft_count++; // Average the fft data into the graph in order of frequency k = 0; for (i = fft_size / 2; i < fft_size; i++) // Negative frequencies fft_average[k++] += cabs(samples[i]); for (i = 0; i < fft_size / 2; i++) // Positive frequencies fft_average[k++] += cabs(samples[i]); if (fft_count < measure_freq_mode / 2) return; // continue with average // time for a calculation fft_count = 0; dmax = 1.e-20; ipeak = 0; center = fft_size / 2 - rit_freq * fft_size / srate; k = 500; // desired +/- half-bandwidth to search for a peak k = k * fft_size / srate; // convert to index for (i = center - k; i <= center + k; i++) { // search for a peak near the RX freq if (fft_average[i] > dmax) { dmax = fft_average[i]; ipeak = i; } } c3 = 1.36 * (fft_average[ipeak+1] - fft_average[ipeak - 1]) / (fft_average[ipeak-1] + fft_average[ipeak] + fft_average[ipeak+1]); freq = srate * (2 * (ipeak + c3) - fft_size) / 2 / fft_size; freq += rx_tune_freq; //printf("freq %.0f rx_tune_freq %d vfo_screen %d vfo_audio %d\n", freq, rx_tune_freq, vfo_screen, vfo_audio); // printf("\n%5d %.4lf %.2lf k=%d\n", ipeak, c3, freq, k); measured_frequency = freq; //for (i = ipeak - 10; i <= ipeak + 10 && i >= 0 && i < fft_size; i++) // printf("%4d %12.5f\n", i, fft_average[i] / dmax); memset(fft_average, 0, sizeof(double) * fft_size); } static PyObject * Xdft(PyObject * pyseq, int inverse, int window) { // Native spectral order is 0 Hz to (Fs - 1). Change this to // - (Fs - 1)/2 to + Fs/2. For even Fs==32, there are 15 negative // frequencies, a zero, and 16 positive frequencies. For odd Fs==31, // there are 15 negative and positive frequencies plus zero frequency. // Note that zero frequency is always index (Fs - 1) / 2. PyObject * obj; int i, j, size; static int fft_size = -1; // size of fft data static fftw_complex * samples; // complex data for fft static fftw_plan planF, planB; // fft plan for fftW static double * fft_window; // window function Py_complex pycx; // Python C complex value if (PySequence_Check(pyseq) != 1) { PyErr_SetString (QuiskError, "DFT input data is not a sequence"); return NULL; } size = PySequence_Size(pyseq); if (size <= 0) return PyTuple_New(0); if (size != fft_size) { // Change in previous size; malloc new space if (fft_size > 0) { fftw_destroy_plan(planF); fftw_destroy_plan(planB); fftw_free(samples); free (fft_window); } fft_size = size; // Create space for one fft samples = (fftw_complex *) fftw_malloc(sizeof(fftw_complex) * fft_size); planF = fftw_plan_dft_1d(fft_size, samples, samples, FFTW_FORWARD, FFTW_MEASURE); planB = fftw_plan_dft_1d(fft_size, samples, samples, FFTW_BACKWARD, FFTW_MEASURE); fft_window = (double *) malloc(sizeof(double) * (fft_size + 1)); for (i = 0; i <= size/2; i++) { if (1) // Blackman window fft_window[i] = fft_window[size - i] = 0.42 + 0.50 * cos(2. * M_PI * i / size) + 0.08 * cos(4. * M_PI * i / size); else if (1) // Hamming fft_window[i] = fft_window[size - i] = 0.54 + 0.46 * cos(2. * M_PI * i / size); else // Hanning fft_window[i] = fft_window[size - i] = 0.50 + 0.50 * cos(2. * M_PI * i / size); } } j = (size - 1) / 2; // zero frequency in input for (i = 0; i < size; i++) { obj = PySequence_GetItem(pyseq, j); if (PyComplex_Check(obj)) { pycx = PyComplex_AsCComplex(obj); } else if (PyFloat_Check(obj)) { pycx.real = PyFloat_AsDouble(obj); pycx.imag = 0; } else if (PyInt_Check(obj)) { pycx.real = PyInt_AsLong(obj); pycx.imag = 0; } else { Py_XDECREF(obj); PyErr_SetString (QuiskError, "DFT input data is not a complex/float/int number"); return NULL; } samples[i] = pycx.real + I * pycx.imag; if (++j >= size) j = 0; Py_XDECREF(obj); } if (inverse) { // Normalize using 1/N fftw_execute(planB); // Calculate inverse FFT / N if (window) { for (i = 0; i < fft_size; i++) // multiply by window / N samples[i] *= fft_window[i] / size; } else { for (i = 0; i < fft_size; i++) // divide by N samples[i] /= size; } } else { if (window) { for (i = 0; i < fft_size; i++) // multiply by window samples[i] *= fft_window[i]; } fftw_execute(planF); // Calculate FFT } pyseq = PyList_New(fft_size); j = (size - 1) / 2; // zero frequency in input for (i = 0; i < fft_size; i++) { pycx.real = creal(samples[i]); pycx.imag = cimag(samples[i]); PyList_SetItem(pyseq, j, PyComplex_FromCComplex(pycx)); if (++j >= size) j = 0; } return pyseq; } static PyObject * dft(PyObject * self, PyObject * args) { PyObject * tuple2; int window; window = 0; if (!PyArg_ParseTuple (args, "O|i", &tuple2, &window)) return NULL; return Xdft(tuple2, 0, window); } static PyObject * is_key_down(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; return PyInt_FromLong(quisk_is_key_down()); } static PyObject * idft(PyObject * self, PyObject * args) { PyObject * tuple2; int window; window = 0; if (!PyArg_ParseTuple (args, "O|i", &tuple2, &window)) return NULL; return Xdft(tuple2, 1, window); } static PyObject * record_app(PyObject * self, PyObject * args) { // Record the Python object for the application instance, malloc space for fft's. int i, j, rate; unsigned long handle; fftw_complex * pt; if (!PyArg_ParseTuple (args, "OOiiiiik", &pyApp, &quisk_pyConfig, &data_width, &graph_width, &fft_size, &multirx_data_width, &rate, &handle)) return NULL; Py_INCREF(quisk_pyConfig); #ifdef MS_WINDOWS #ifdef _WIN64 quisk_mainwin_handle = (HWND)(unsigned long long)handle; #else quisk_mainwin_handle = (HWND)handle; #endif #endif rx_udp_clock = QuiskGetConfigDouble("rx_udp_clock", 122.88e6); graph_refresh = QuiskGetConfigInt("graph_refresh", 7); quisk_use_rx_udp = QuiskGetConfigInt("use_rx_udp", 0); quisk_sound_state.sample_rate = rate; fft_sample_rate = rate; is_little_endian = 1; // Test machine byte order if (*(char *)&is_little_endian == 1) is_little_endian = 1; else is_little_endian = 0; strncpy (quisk_sound_state.err_msg, CLOSED_TEXT, QUISK_SC_SIZE); // Initialize space for the FFTs for (i = 0; i < FFT_ARRAY_SIZE; i++) { fft_data_array[i].filled = 0; fft_data_array[i].index = 0; fft_data_array[i].block = 0; fft_data_array[i].samples = (fftw_complex *) fftw_malloc(sizeof(fftw_complex) * fft_size); } pt = fft_data_array[0].samples; quisk_fft_plan = fftw_plan_dft_1d(fft_size, pt, pt, FFTW_FORWARD, FFTW_MEASURE); // Create space for the fft average and window if (fft_window) free(fft_window); fft_window = (double *) malloc(sizeof(double) * fft_size); for (i = 0, j = -fft_size / 2; i < fft_size; i++, j++) { if (0) // Hamming fft_window[i] = 0.54 + 0.46 * cos(2. * M_PI * j / fft_size); else // Hanning fft_window[i] = 0.5 + 0.5 * cos(2. * M_PI * j / fft_size); } // Initialize plan for multirx FFT multirx_fft_width = multirx_data_width * MULTIRX_FFT_MULT; // Use larger FFT than graph size multirx_fft_next_samples = (fftw_complex *)malloc(multirx_fft_width * sizeof(fftw_complex)); multirx_fft_next_plan = fftw_plan_dft_1d(multirx_fft_width, multirx_fft_next_samples, multirx_fft_next_samples, FFTW_FORWARD, FFTW_MEASURE); if (current_graph) free(current_graph); current_graph = (double *) malloc(sizeof(double) * data_width); measure_freq(NULL, 0, 0); dAutoNotch(NULL, 0, 0, 0); quisk_process_decimate(NULL, 0, 0, 0); quisk_process_demodulate(NULL, NULL, 0, 0, 0, 0); #if DEBUG_IO QuiskPrintTime(NULL, 0); #endif Py_INCREF (Py_None); return Py_None; } static PyObject * record_graph(PyObject * self, PyObject * args) { /* record the Python object for the application instance */ if (!PyArg_ParseTuple (args, "iid", &graphX, &graphY, &graphScale)) return NULL; graphScale *= 2; Py_INCREF (Py_None); return Py_None; } static PyObject * test_1(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * test_2(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * test_3(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "")) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_fdx(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &isFDX)) return NULL; Py_INCREF (Py_None); return Py_None; } static PyObject * set_sample_bytes(PyObject * self, PyObject * args) { if (!PyArg_ParseTuple (args, "i", &sample_bytes)) return NULL; Py_INCREF (Py_None); return Py_None; } #if defined(ENABLE_GPIO_KEYER) static PyObject * set_gpio_keyer_mode(PyObject * self, PyObject * args) { int mode; if (!PyArg_ParseTuple (args, "i", &mode)) return NULL; quisk_set_gpio_keyer_mode(mode); Py_INCREF (Py_None); return Py_None; } static PyObject * set_gpio_keyer_speed(PyObject * self, PyObject * args) { int wpm; fprintf(stderr, "Trying to set keyer speed\n"); if (!PyArg_ParseTuple (args, "i", &wpm)) return NULL; quisk_set_gpio_keyer_speed(wpm); Py_INCREF (Py_None); return Py_None; } static PyObject * set_gpio_keyer_weight(PyObject * self, PyObject * args) { int weight; if (!PyArg_ParseTuple (args, "i", &weight)) return NULL; quisk_set_gpio_keyer_weight(weight); Py_INCREF (Py_None); return Py_None; } static PyObject * set_gpio_keyer_reversed(PyObject * self, PyObject * args) { int rev; if (!PyArg_ParseTuple (args, "i", &rev)) return NULL; quisk_set_gpio_keyer_reversed(rev); Py_INCREF (Py_None); return Py_None; } static PyObject * set_gpio_keyer_strict(PyObject * self, PyObject * args) { int strict; if (!PyArg_ParseTuple (args, "i", &strict)) return NULL; quisk_set_gpio_keyer_strict(strict); Py_INCREF (Py_None); return Py_None; } static PyObject * set_gpio_keyer_enabled(PyObject * self, PyObject * args) { int enabled; if (!PyArg_ParseTuple (args, "i", &enabled)) return NULL; quisk_set_gpio_keyer_enabled(enabled); Py_INCREF (Py_None); return Py_None; } #endif static PyMethodDef QuiskMethods[] = { {"add_tone", add_tone, METH_VARARGS, "Add a test tone to the data."}, {"dft", dft, METH_VARARGS, "Calculate the discrete Fourier transform."}, {"idft", idft, METH_VARARGS, "Calculate the inverse discrete Fourier transform."}, {"is_key_down", is_key_down, METH_VARARGS, "Check whether the key is down; return 0 or 1."}, {"get_state", get_state, METH_VARARGS, "Return a count of read and write errors."}, {"get_graph", get_graph, METH_VARARGS, "Return a tuple of graph data."}, {"set_multirx_mode", set_multirx_mode, METH_VARARGS, "Select demodulation mode for sub-receivers."}, {"set_multirx_freq", set_multirx_freq, METH_VARARGS, "Select how to play audio from sub-receivers."}, {"set_multirx_play_method", set_multirx_play_method, METH_VARARGS, "Select how to play audio from sub-receivers."}, {"set_multirx_play_channel", set_multirx_play_channel, METH_VARARGS, "Select which sub-receiver to play audio."}, {"get_multirx_graph", get_multirx_graph, METH_VARARGS, "Return a tuple of sub-receiver graph data."}, {"get_filter", get_filter, METH_VARARGS, "Return the frequency response of the receive filter."}, {"get_filter_rate", get_filter_rate, METH_VARARGS, "Return the sample rate used for the filters."}, {"get_tx_filter", quisk_get_tx_filter, METH_VARARGS, "Return the frequency response of the transmit filter."}, {"get_audio_graph", get_audio_graph, METH_VARARGS, "Return a tuple of the audio graph data."}, {"measure_frequency", measure_frequency, METH_VARARGS, "Set the method, return the measured frequency."}, {"measure_audio", measure_audio, METH_VARARGS, "Set the method, return the measured audio voltage."}, {"get_hardware_ptt", get_hardware_ptt, METH_VARARGS, "Return the state of the hardware PTT switch."}, {"get_overrange", get_overrange, METH_VARARGS, "Return the count of overrange (clip) for the ADC."}, {"get_smeter", get_smeter, METH_VARARGS, "Return the S meter reading."}, {"get_hermes_adc", get_hermes_adc, METH_VARARGS, "Return the ADC peak level."}, {"get_hermes_TFRC", get_hermes_TFRC, METH_VARARGS, "Return the temperature, forward and reverse power and PA current."}, {"set_hermes_id", set_hermes_id, METH_VARARGS, "Set the Hermes hardware code version and board ID."}, {"set_hermes_filters", quisk_set_hermes_filter, METH_VARARGS, "Set the Hermes filter to use for Rx and Tx."}, {"set_alex_hpf", quisk_set_alex_hpf, METH_VARARGS, "Set the Alex HP filter to use for Rx and Tx."}, {"set_alex_lpf", quisk_set_alex_lpf, METH_VARARGS, "Set the Alex LP filter to use for Rx and Tx."}, {"invert_spectrum", invert_spectrum, METH_VARARGS, "Invert the input RF spectrum"}, {"ip_interfaces", ip_interfaces, METH_VARARGS, "Return a list of interface data"}, {"pc_to_hermes", pc_to_hermes, METH_VARARGS, "Send this block of control data to the Hermes device"}, {"pc_to_hermeslite_writequeue", pc_to_hermeslite_writequeue, METH_VARARGS, "Fill Hermes-Lite write queue"}, {"set_hermeslite_writepointer", set_hermeslite_writepointer, METH_VARARGS, "Set Hermes-Lite write pointer"}, {"get_hermeslite_writepointer", get_hermeslite_writepointer, METH_VARARGS, "Return Hermes-Lite write pointer"}, {"clear_hermeslite_response", clear_hermeslite_response, METH_VARARGS, "Clear the Hermes-Lite response array"}, {"get_hermeslite_response", get_hermeslite_response, METH_VARARGS, "Get the Hermes-Lite response array"}, {"hermes_to_pc", hermes_to_pc, METH_VARARGS, "Get the block of control data from the Hermes device"}, {"record_app", record_app, METH_VARARGS, "Save the App instance."}, {"record_graph", record_graph, METH_VARARGS, "Record graph parameters."}, {"ImmediateChange", ImmediateChange, METH_VARARGS, "Call this to notify the program of changes."}, {"set_ampl_phase", quisk_set_ampl_phase, METH_VARARGS, "Set the sound card amplitude and phase corrections."}, {"set_udp_tx_correct", quisk_set_udp_tx_correct, METH_VARARGS, "Set the UDP transmit corrections."}, {"set_agc", set_agc, METH_VARARGS, "Set the AGC parameters."}, {"set_squelch", set_squelch, METH_VARARGS, "Set the FM squelch parameter."}, {"get_squelch", get_squelch, METH_VARARGS, "Get the FM squelch state, 0 or 1."}, {"set_ssb_squelch", set_ssb_squelch, METH_VARARGS, "Set the SSB squelch parameters."}, {"set_ctcss", set_ctcss, METH_VARARGS, "Set the frequency of the repeater access tone."}, {"set_file_name", (PyCFunction)quisk_set_file_name, METH_VARARGS|METH_KEYWORDS, "Set the names and state of the recording and playback files."}, {"set_params", (PyCFunction)set_params, METH_VARARGS|METH_KEYWORDS, "Set miscellaneous parameters in quisk.c."}, {"set_sparams", (PyCFunction)quisk_set_sparams, METH_VARARGS|METH_KEYWORDS, "Set miscellaneous parameters in sound.c."}, {"set_filters", set_filters, METH_VARARGS, "Set the receive audio I and Q channel filters."}, {"set_auto_notch", set_auto_notch, METH_VARARGS, "Set the auto notch on or off."}, {"set_kill_audio", set_kill_audio, METH_VARARGS, "Replace radio sound with silence."}, {"set_enable_bandscope", set_enable_bandscope, METH_VARARGS, "Enable or disable sending bandscope data."}, {"set_noise_blanker", set_noise_blanker, METH_VARARGS, "Set the noise blanker level."}, {"set_record_state", set_record_state, METH_VARARGS, "Set the temp buffer record and playback state."}, {"set_rx_mode", set_rx_mode, METH_VARARGS, "Set the receive mode: CWL, USB, AM, etc."}, {"set_mic_out_volume", set_mic_out_volume, METH_VARARGS, "Set the level of the mic output for SoftRock transmit"}, {"set_spot_level", set_spot_level, METH_VARARGS, "Set the spot level, or -1 for no spot"}, {"set_imd_level", set_imd_level, METH_VARARGS, "Set the imd level 0 to 1000."}, {"set_sidetone", set_sidetone, METH_VARARGS, "Set the sidetone volume and frequency."}, {"set_sample_bytes", set_sample_bytes, METH_VARARGS, "Set the number of bytes for each I or Q sample."}, {"set_transmit_mode", set_transmit_mode, METH_VARARGS, "Change the radio to transmit mode independent of key_down."}, {"set_volume", set_volume, METH_VARARGS, "Set the audio output volume."}, {"set_tx_audio", (PyCFunction)quisk_set_tx_audio, METH_VARARGS|METH_KEYWORDS, "Set the transmit audio parameters."}, {"is_vox", quisk_is_vox, METH_VARARGS, "return the VOX state zero or one."}, {"set_split_rxtx", set_split_rxtx, METH_VARARGS, "Set split for rx/tx."}, {"set_tune", set_tune, METH_VARARGS, "Set the tuning frequency."}, {"test_1", test_1, METH_VARARGS, "Test 1 function."}, {"test_2", test_2, METH_VARARGS, "Test 2 function."}, {"test_3", test_3, METH_VARARGS, "Test 3 function."}, {"tx_hold_state", tx_hold_state, METH_VARARGS, "Query or set the transmit hold state."}, {"set_fdx", set_fdx, METH_VARARGS, "Set full duplex mode; ignore the key status."}, {"sound_devices", quisk_sound_devices, METH_VARARGS, "Return a list of available sound device names."}, {"pa_sound_devices", quisk_pa_sound_devices, METH_VARARGS, "Return a list of available PulseAudio sound device names."}, {"sound_errors", quisk_sound_errors, METH_VARARGS, "Return a list of text strings with sound devices and error counts"}, {"open_sound", open_sound, METH_VARARGS, "Open the soundcard device."}, {"open_wav_file_play", open_wav_file_play, METH_VARARGS, "Open a WAV file to play instead of the microphone."}, {"close_sound", close_sound, METH_VARARGS, "Stop the soundcard and release resources."}, {"capt_channels", quisk_capt_channels, METH_VARARGS, "Set the I and Q capture channel numbers"}, {"play_channels", quisk_play_channels, METH_VARARGS, "Set the I and Q playback channel numbers"}, {"micplay_channels", quisk_micplay_channels, METH_VARARGS, "Set the I and Q microphone playback channel numbers"}, {"change_scan", change_scan, METH_VARARGS, "Change to a new FFT rate and multiplier"}, {"change_rate", change_rate, METH_VARARGS, "Change to a new sample rate"}, {"change_rates", change_rates, METH_VARARGS, "Change to multiple new sample rates"}, {"read_sound", read_sound, METH_VARARGS, "Read from the soundcard."}, {"start_sound", start_sound, METH_VARARGS, "Start the soundcard."}, {"mixer_set", mixer_set, METH_VARARGS, "Set microphone mixer parameters such as volume."}, {"open_key", open_key, METH_VARARGS, "Open access to the state of the key (CW or PTT)."}, {"open_rx_udp", open_rx_udp, METH_VARARGS, "Open a UDP port for capture."}, {"close_rx_udp", close_rx_udp, METH_VARARGS, "Close the UDP port used for capture."}, {"add_rx_samples", add_rx_samples, METH_VARARGS, "Record the Rx samples received by Python code."}, {"add_bscope_samples", add_bscope_samples, METH_VARARGS, "Record the bandscope samples received by Python code."}, {"set_key_down", set_key_down, METH_VARARGS, "Change the key up/down state."}, {"set_PTT", set_PTT, METH_VARARGS, "Change the PTT button state."}, {"freedv_open", quisk_freedv_open, METH_VARARGS, "Open FreeDV."}, {"freedv_close", quisk_freedv_close, METH_VARARGS, "Close FreeDV."}, {"freedv_get_snr", quisk_freedv_get_snr, METH_VARARGS, "Return the signal to noise ratio in dB."}, {"freedv_get_version", quisk_freedv_get_version, METH_VARARGS, "Return the codec2 API version."}, {"freedv_get_rx_char", quisk_freedv_get_rx_char, METH_VARARGS, "Get text characters received from freedv."}, {"freedv_set_options", (PyCFunction)quisk_freedv_set_options, METH_VARARGS|METH_KEYWORDS, "Set the freedv parameters."}, #if defined(ENABLE_GPIO_KEYER) {"set_gpio_keyer_mode", set_gpio_keyer_mode, METH_VARARGS, "Change the CW keyer mode."}, {"set_gpio_keyer_speed", set_gpio_keyer_speed, METH_VARARGS, "Change the CW keyer speed."}, {"set_gpio_keyer_weight", set_gpio_keyer_weight, METH_VARARGS, "Change the CW keyer symbol weight."}, {"set_gpio_keyer_reversed", set_gpio_keyer_reversed, METH_VARARGS, "Enabled/disable reversed paddles."}, {"set_gpio_keyer_strict", set_gpio_keyer_strict, METH_VARARGS, "Enable/disable strict character spacing."}, {"set_gpio_keyer_enabled", set_gpio_keyer_enabled, METH_VARARGS, "Enable/disable the CW keyer"}, #endif {NULL, NULL, 0, NULL} /* Sentinel */ }; #if PY_MAJOR_VERSION < 3 // Python 2.7: PyMODINIT_FUNC init_quisk (void) { PyObject * m; PyObject * c_api_object; static void * Quisk_API[] = QUISK_API_INIT; m = Py_InitModule ("_quisk", QuiskMethods); if (m == NULL) { printf("Py_InitModule of _quisk failed!\n"); return; } QuiskError = PyErr_NewException ("quisk.error", NULL, NULL); Py_INCREF (QuiskError); PyModule_AddObject (m, "error", QuiskError); /* Create Capsules for handing _quisk symbols to C extensions in other Python modules. */ c_api_object = PyCapsule_New(Quisk_API, "_quisk.QUISK_C_API", NULL); if (c_api_object != NULL) PyModule_AddObject(m, "QUISK_C_API", c_api_object); } // Python 3: #else static struct PyModuleDef _quiskmodule = { PyModuleDef_HEAD_INIT, "_quisk", NULL, -1, QuiskMethods } ; PyMODINIT_FUNC PyInit__quisk(void) { PyObject * m; PyObject * c_api_object; static void * Quisk_API[] = QUISK_API_INIT; m = PyModule_Create(&_quiskmodule); if (m == NULL) return NULL; QuiskError = PyErr_NewException("_quisk.error", NULL, NULL); if (QuiskError == NULL) { Py_DECREF(m); return NULL; } Py_INCREF (QuiskError); PyModule_AddObject (m, "error", QuiskError); /* Create Capsules for handing _quisk symbols to C extensions in other Python modules. */ c_api_object = PyCapsule_New(Quisk_API, "_quisk.QUISK_C_API", NULL); if (c_api_object != NULL) PyModule_AddObject(m, "QUISK_C_API", c_api_object); return m; } #endif