/* LMS6 (403 MHz) gcc lms6ecc.c -lm -o lms6ecc ./lms6ecc -v -b --ecc2 */ #include #include #include typedef unsigned char ui8_t; typedef unsigned short ui16_t; typedef unsigned int ui32_t; #include "bch_ecc.c" // RS/ecc/ int option_verbose = 0, // ausfuehrliche Anzeige option_raw = 0, // rohe Frames option_ecc = 0, option_b = 0, option_inv = 0, // invertiert Signal option_res = 0, // genauere Bitmessung wavloaded = 0; /* -------------------------------------------------------------------------- */ #define BAUD_RATE 4800 int sample_rate = 0, bits_sample = 0, channels = 0; float samples_per_bit = 0; int findstr(char *buf, char *str, int pos) { int i; for (i = 0; i < 4; i++) { if (buf[(pos+i)%4] != str[i]) break; } return i; } int read_wav_header(FILE *fp) { char txt[4+1] = "\0\0\0\0"; unsigned char dat[4]; int byte, p=0; if (fread(txt, 1, 4, fp) < 4) return -1; if (strncmp(txt, "RIFF", 4)) return -1; if (fread(txt, 1, 4, fp) < 4) return -1; // pos_WAVE = 8L if (fread(txt, 1, 4, fp) < 4) return -1; if (strncmp(txt, "WAVE", 4)) return -1; // pos_fmt = 12L for ( ; ; ) { if ( (byte=fgetc(fp)) == EOF ) return -1; txt[p % 4] = byte; p++; if (p==4) p=0; if (findstr(txt, "fmt ", p) == 4) break; } if (fread(dat, 1, 4, fp) < 4) return -1; if (fread(dat, 1, 2, fp) < 2) return -1; if (fread(dat, 1, 2, fp) < 2) return -1; channels = dat[0] + (dat[1] << 8); if (fread(dat, 1, 4, fp) < 4) return -1; memcpy(&sample_rate, dat, 4); //sample_rate = dat[0]|(dat[1]<<8)|(dat[2]<<16)|(dat[3]<<24); if (fread(dat, 1, 4, fp) < 4) return -1; if (fread(dat, 1, 2, fp) < 2) return -1; //byte = dat[0] + (dat[1] << 8); if (fread(dat, 1, 2, fp) < 2) return -1; bits_sample = dat[0] + (dat[1] << 8); // pos_dat = 36L + info for ( ; ; ) { if ( (byte=fgetc(fp)) == EOF ) return -1; txt[p % 4] = byte; p++; if (p==4) p=0; if (findstr(txt, "data", p) == 4) break; } if (fread(dat, 1, 4, fp) < 4) return -1; fprintf(stderr, "sample_rate: %d\n", sample_rate); fprintf(stderr, "bits : %d\n", bits_sample); fprintf(stderr, "channels : %d\n", channels); if ((bits_sample != 8) && (bits_sample != 16)) return -1; samples_per_bit = sample_rate/(float)BAUD_RATE; fprintf(stderr, "samples/bit: %.2f\n", samples_per_bit); return 0; } #define EOF_INT 0x1000000 unsigned long sample_count = 0; int read_signed_sample(FILE *fp) { // int = i32_t int byte, i, ret; // EOF -> 0x1000000 for (i = 0; i < channels; i++) { // i = 0: links bzw. mono byte = fgetc(fp); if (byte == EOF) return EOF_INT; if (i == 0) ret = byte; if (bits_sample == 16) { byte = fgetc(fp); if (byte == EOF) return EOF_INT; if (i == 0) ret += byte << 8; } } sample_count++; if (bits_sample == 8) return ret-128; // 8bit: 00..FF, centerpoint 0x80=128 if (bits_sample == 16) return (short)ret; return ret; } int par=1, par_alt=1; int read_bits_fsk(FILE *fp, int *bit, int *len) { static int sample; int n, y0; float l, x1; static float x0; n = 0; do{ y0 = sample; sample = read_signed_sample(fp); if (sample == EOF_INT) return EOF; //sample_count++; par_alt = par; par = (sample >= 0) ? 1 : -1; // 8bit: 0..127,128..255 (-128..-1,0..127) n++; } while (par*par_alt > 0); if (!option_res) l = (float)n / samples_per_bit; else { // genauere Bitlaengen-Messung x1 = sample/(float)(sample-y0); // hilft bei niedriger sample rate l = (n+x0-x1) / samples_per_bit; // meist mehr frames (nicht immer) x0 = x1; } *len = (int)(l+0.5); if (!option_inv) *bit = (1+par_alt)/2; // oben 1, unten -1 else *bit = (1-par_alt)/2; // sdr#= 0) ? 1 : -1; // 8bit: 0..127,128..255 (-128..-1,0..127) sum += sample; n++; } while (sample_count < bitgrenze); // n < samples_per_bit if (sum >= 0) *bit = 1; else *bit = 0; if (option_inv) *bit ^= 1; return 0; } /* -------------------------------------------------------------------------- */ #define BITS 8 #define HEADOFS 0 #define HEADLEN ((3*16)-HEADOFS) // RS-ECC-block kann dazwischenfunken... // (pp pp 24) 54 00 00 00 (7A..: SondeID, GPS, ...) char header[] = /*"0000110110011000"*/"0011101100100000""0000000000000000""0000000000000000";//"0010010011110001"; // SondeID (?0x00?) 0x7A #define FRAMESTART 0 #define FRAME_LEN (300) // 4800baud, 16bits/byte #define BITFRAME_LEN (FRAME_LEN*BITS) #define RAWBITFRAME_LEN (BITFRAME_LEN*2) #define OVERLAP 64 #define FRM_MINLEN (255+3) #define OFS 4 char frm_rawbits[RAWBITFRAME_LEN+OVERLAP*BITS*2+16 +8] = "0000000000000000"; char *frame_rawbits = frm_rawbits+16; char frame_bits[BITFRAME_LEN+OVERLAP*BITS +8]; // init L-1 bits mit 0 ui8_t frame[FRAME_LEN+OVERLAP+5 +8] = { 0x24, 0x54, 0x00, 0x00, 0x00}; // header ui8_t *frame_bytes = frame+OFS; // { 0x00, 0x7A, ... } ui8_t *p_frame = frame; // RS-SYNC // (00) 58 f3 3f b8 // ................ 0000001011110011 1110110100100011 0110100000001011 0101110001011110 ui8_t rs_sync[] = { 0x00, 0x58, 0xf3, 0x3f, 0xb8}; char buf[HEADLEN]; int bufpos = -1; #define L 8 char polyA[] = "10010101"; // 0x95: x^7+x^4+x^2+1 = (x+1)(x^6+x^5+x^4+x+1) = (x+1)qA char polyB[] = "00100010"; // 0x22: x^5+x = (x+1)(x^4+x^3+x^2+x)=x(x+1)^3 = (x+1)qB #define K 7 // d_f=6 char qA[] = "1110011"; // 0x73: x^6+x^5+x^4+x+1 char qB[] = "0011110"; // 0x1e: x^4+x^3+x^2+x char vit_rawbits[RAWBITFRAME_LEN+OVERLAP*BITS*2 +8]; #define N (1 << K) #define M (1 << (K-1)) typedef struct { int bIn; int codeIn; int w; int prevState; } states_t; states_t vit_state[RAWBITFRAME_LEN+OVERLAP +8][M]; states_t vit_d[N]; char vit_code[N]; int vit_initCodes() { int cA, cB; int i, bits; for (bits = 0; bits < N; bits++) { cA = 0; cB = 0; for (i = 0; i < K; i++) { cA ^= (qA[K-1-i]&1) & ((bits >> i)&1); cB ^= (qB[K-1-i]&1) & ((bits >> i)&1); } vit_code[bits] = (cA<<1) | cB; } return 0; } int vit_dist(int c, char *rc) { return (((c>>1)^rc[0])&1) + ((c^rc[1])&1); } int vit_start(char *rc) { int t, m, j, c, d; t = K-1; m = M; while ( t > 0 ) { // t=0..K-2: nextState 0) { c = vit_state[t][j].codeIn; vit_rawbits[2*t -2] = 0x30 + ((c>>1) & 1); vit_rawbits[2*t -1] = 0x30 + (c & 1); j = vit_state[t][j].prevState; t--; } return 0; } int viterbi(char *rc) { int t, tmax; int j, j_min, w_min; vit_start(rc); tmax = strlen(rc)/2; for (t = K-1; t < tmax; t++) { vit_next(t, rc+2*t); } w_min = -1; for (j = 0; j < M; j++) { if (w_min < 0) { w_min = vit_state[tmax][j].w; j_min = j; } if (vit_state[tmax][j].w < w_min) { w_min = vit_state[tmax][j].w; j_min = j; } } vit_path(j_min, tmax); return 0; } // ------------------------------------------------------------------------ int deconv(char* rawbits, char *bits) { int j, n, bitA, bitB; char *p; int len; int errors = 0; int m = L-1; len = strlen(rawbits); for (j = 0; j < m; j++) bits[j] = '0'; n = 0; while ( 2*(m+n) < len ) { p = rawbits+2*(m+n); bitA = bitB = 0; for (j = 0; j < m; j++) { bitA ^= (bits[n+j]&1) & (polyA[j]&1); bitB ^= (bits[n+j]&1) & (polyB[j]&1); } if ( (bitA^(p[0]&1))==(polyA[m]&1) && (bitB^(p[1]&1))==(polyB[m]&1) ) bits[n+m] = '1'; else if ( (bitA^(p[0]&1))==0 && (bitB^(p[1]&1))==0 ) bits[n+m] = '0'; else { // error: no error correction... if ( (bitA^(p[0]&1))!=(polyA[m]&1) && (bitB^(p[1]&1))==(polyB[m]&1) ) bits[n+m] = 0x39; else bits[n+m] = 0x38; //if (n < 256) errors++; // nur bis Ende GPS-vel; alternativ: return pos 1. error errors = n; break; } n += 1; } bits[n+m] = '\0'; return errors; } // ------------------------------------------------------------------------ int crc16_0(ui8_t frame[], int len) { int crc16poly = 0x1021; int rem = 0x0, i, j; int byte; for (i = 0; i < len; i++) { byte = frame[i]; rem = rem ^ (byte << 8); for (j = 0; j < 8; j++) { if (rem & 0x8000) { rem = (rem << 1) ^ crc16poly; } else { rem = (rem << 1); } rem &= 0xFFFF; } } return rem; } int check_CRC(ui8_t frame[]) { ui32_t crclen = 0, crcdat = 0; crclen = 221; crcdat = (frame[crclen]<<8) | frame[crclen+1]; if ( crcdat != crc16_0(frame, crclen) ) { return 1; // CRC NO } else return 0; // CRC OK } // ------------------------------------------------------------------------ void inc_bufpos() { bufpos = (bufpos+1) % HEADLEN; } char cb_inv(char c) { if (c == '0') return '1'; if (c == '1') return '0'; return c; } int compare2() { int i, j; i = 0; j = bufpos; while (i < HEADLEN) { if (j < 0) j = HEADLEN-1; if (buf[j] != header[HEADOFS+HEADLEN-1-i]) break; j--; i++; } if (i == HEADLEN) return 1; i = 0; j = bufpos; while (i < HEADLEN) { if (j < 0) j = HEADLEN-1; if (buf[j] != cb_inv(header[HEADOFS+HEADLEN-1-i])) break; j--; i++; } if (i == HEADLEN) return -1; return 0; } int bits2bytes(char *bitstr, ui8_t *bytes) { int i, bit, d, byteval; int len = strlen(bitstr)/8; int bitpos, bytepos; bitpos = 0; bytepos = 0; while (bytepos < len) { byteval = 0; d = 1; for (i = 0; i < BITS; i++) { bit=*(bitstr+bitpos+i); /* little endian */ //bit=*(bitstr+bitpos+7-i); /* big endian */ if ((bit == '1') || (bit == '9')) byteval += d; else /*if ((bit == '0') || (bit == '8'))*/ byteval += 0; d <<= 1; } bitpos += BITS; bytes[bytepos++] = byteval & 0xFF; } //while (bytepos < FRAME_LEN+OVERLAP) bytes[bytepos++] = 0; return 0; } /* -------------------------------------------------------------------------- */ typedef struct { int frnr; int sn; int week; int gpstow; int jahr; int monat; int tag; int wday; int std; int min; float sek; double lat; double lon; double h; double vH; double vD; double vV; double vE; double vN; double vU; //int freq; } gpx_t; gpx_t gpx; gpx_t gpx0 = { 0 }; #define pos_SondeSN (OFS+0x00) // ?4 byte 00 7A.... #define pos_FrameNb (OFS+0x04) // 2 byte //GPS Position #define pos_GPSTOW (OFS+0x06) // 4 byte #define pos_GPSlat (OFS+0x0E) // 4 byte #define pos_GPSlon (OFS+0x12) // 4 byte #define pos_GPSalt (OFS+0x16) // 4 byte //#define pos_GPSweek 0x20 // 2 byte //GPS Velocity East-North-Up (ENU) #define pos_GPSvO (OFS+0x1A) // 3 byte #define pos_GPSvN (OFS+0x1D) // 3 byte #define pos_GPSvV (OFS+0x20) // 3 byte int get_SondeSN() { unsigned byte; byte = (p_frame[pos_SondeSN]<<24) | (p_frame[pos_SondeSN+1]<<16) | (p_frame[pos_SondeSN+2]<<8) | p_frame[pos_SondeSN+3]; gpx.sn = byte & 0xFFFFFF; return 0; } int get_FrameNb() { int i; unsigned byte; ui8_t frnr_bytes[2]; int frnr; gpx = gpx0; for (i = 0; i < 2; i++) { byte = p_frame[pos_FrameNb + i]; frnr_bytes[i] = byte; } frnr = (frnr_bytes[0] << 8) + frnr_bytes[1] ; gpx.frnr = frnr; return 0; } char weekday[7][3] = { "So", "Mo", "Di", "Mi", "Do", "Fr", "Sa"}; //char weekday[7][4] = { "Sun", "Mon", "Tue", "Wed", "Thu", "Fri", "Sat"}; int get_GPStime() { int i; unsigned byte; ui8_t gpstime_bytes[4]; int gpstime = 0, // 32bit day; float ms; for (i = 0; i < 4; i++) { byte = p_frame[pos_GPSTOW + i]; gpstime_bytes[i] = byte; } gpstime = 0; for (i = 0; i < 4; i++) { gpstime |= gpstime_bytes[i] << (8*(3-i)); } gpx.gpstow = gpstime; ms = gpstime % 1000; gpstime /= 1000; day = gpstime / (24 * 3600); gpstime %= (24*3600); if ((day < 0) || (day > 6)) return -1; gpx.wday = day; gpx.std = gpstime / 3600; gpx.min = (gpstime % 3600) / 60; gpx.sek = gpstime % 60 + ms/1000.0; return 0; } double B60B60 = 0xB60B60; // 2^32/360 = 0xB60B60.xxx int get_GPSlat() { int i; unsigned byte; ui8_t gpslat_bytes[4]; int gpslat; double lat; for (i = 0; i < 4; i++) { byte = p_frame[pos_GPSlat + i]; if (byte > 0xFF) return -1; gpslat_bytes[i] = byte; } gpslat = 0; for (i = 0; i < 4; i++) { gpslat |= gpslat_bytes[i] << (8*(3-i)); } lat = gpslat / B60B60; gpx.lat = lat; return 0; } int get_GPSlon() { int i; unsigned byte; ui8_t gpslon_bytes[4]; int gpslon; double lon; for (i = 0; i < 4; i++) { byte = p_frame[pos_GPSlon + i]; if (byte > 0xFF) return -1; gpslon_bytes[i] = byte; } gpslon = 0; for (i = 0; i < 4; i++) { gpslon |= gpslon_bytes[i] << (8*(3-i)); } lon = gpslon / B60B60; gpx.lon = lon; return 0; } int get_GPSalt() { int i; unsigned byte; ui8_t gpsheight_bytes[4]; int gpsheight; double height; for (i = 0; i < 4; i++) { byte = p_frame[pos_GPSalt + i]; if (byte > 0xFF) return -1; gpsheight_bytes[i] = byte; } gpsheight = 0; for (i = 0; i < 4; i++) { gpsheight |= gpsheight_bytes[i] << (8*(3-i)); } height = gpsheight / 1000.0; gpx.h = height; if (height < -100 || height > 60000) return -1; return 0; } int get_GPSvel24() { int i; unsigned byte; ui8_t gpsVel_bytes[3]; int vel24; double vx, vy, vz, dir; //, alpha; for (i = 0; i < 3; i++) { byte = p_frame[pos_GPSvO + i]; if (byte > 0xFF) return -1; gpsVel_bytes[i] = byte; } vel24 = gpsVel_bytes[0] << 16 | gpsVel_bytes[1] << 8 | gpsVel_bytes[2]; if (vel24 > (0x7FFFFF)) vel24 -= 0x1000000; vx = vel24 / 1e3; // ost for (i = 0; i < 3; i++) { byte = p_frame[pos_GPSvN + i]; if (byte > 0xFF) return -1; gpsVel_bytes[i] = byte; } vel24 = gpsVel_bytes[0] << 16 | gpsVel_bytes[1] << 8 | gpsVel_bytes[2]; if (vel24 > (0x7FFFFF)) vel24 -= 0x1000000; vy= vel24 / 1e3; // nord for (i = 0; i < 3; i++) { byte = p_frame[pos_GPSvV + i]; if (byte > 0xFF) return -1; gpsVel_bytes[i] = byte; } vel24 = gpsVel_bytes[0] << 16 | gpsVel_bytes[1] << 8 | gpsVel_bytes[2]; if (vel24 > (0x7FFFFF)) vel24 -= 0x1000000; vz = vel24 / 1e3; // hoch gpx.vE = vx; gpx.vN = vy; gpx.vU = vz; gpx.vH = sqrt(vx*vx+vy*vy); /* alpha = atan2(vy, vx)*180/M_PI; // ComplexPlane (von x-Achse nach links) - GeoMeteo (von y-Achse nach rechts) dir = 90-alpha; // z=x+iy= -> i*conj(z)=y+ix=re(i(pi/2-t)), Achsen und Drehsinn vertauscht if (dir < 0) dir += 360; // atan2(y,x)=atan(y/x)=pi/2-atan(x/y) , atan(1/t) = pi/2 - atan(t) gpx.vD2 = dir; */ dir = atan2(vx, vy) * 180 / M_PI; if (dir < 0) dir += 360; gpx.vD = dir; gpx.vV = vz; return 0; } #define rs_N 255 #define rs_K 223 #define rs_R (rs_N-rs_K) // 32 ui8_t rs_cw[rs_N]; #define ECCBUF_LEN (3*FRAME_LEN+32) ui8_t ecc_buf[ECCBUF_LEN]; int bufidx = 0; ui8_t frm_bytes[FRAME_LEN+OVERLAP +8]; typedef struct { int pos; ui8_t bytes[FRAME_LEN+OVERLAP+5 +8]; } efb_t; efb_t f0 = { 263, { 0x0 , 0x54, 0x00, 0x00, 0x00} }; efb_t f1 = { 0, { 0x24, 0x54, 0x00, 0x00, 0x00} }; #define kMAX 2 typedef struct { int errs; int fpos; int epos; } rs_bf_t; rs_bf_t rsbf[kMAX]; int lms6_ecc(ui8_t *cw) { int errors; ui8_t err_pos[rs_R], err_val[rs_R]; errors = rs_decode(cw, err_pos, err_val); return errors; } void print_frame(int crc_err, int len, int pos) { int i ,err=0; if (p_frame[0] != 0) { if (option_raw) { //if ( err==0 || err>8*(pos_GPSTOW+8) ) { if (option_raw == 1) { for (i = 0; i < pos+OFS; i++) printf("%02x ", p_frame[i]); if (crc_err==0) printf(" [OK]"); else printf(" [NO]"); printf("\n"); } else if (option_raw == 8) { if (option_ecc) { for (i = 0; i < len; i++) printf("%c", vit_rawbits[i]); printf("\n"); } else { for (i = 0; i < len; i++) printf("%c", frame_rawbits[i]); printf("\n"); } } } } else { //if ((p_frame[pos_SondeSN+1] & 0xF0) == 0x70) // ? beginnen alle SNs mit 0x7A.... bzw 80..... ? if ( p_frame[pos_SondeSN+1] ) { get_FrameNb(); get_GPStime(); get_SondeSN(); if (option_verbose) printf(" (%7d) ", gpx.sn); printf(" [%5d] ", gpx.frnr); printf("%s ", weekday[gpx.wday]); printf("(%02d:%02d:%06.3f) ", gpx.std, gpx.min, gpx.sek); // falls Rundung auf 60s: Ueberlauf get_GPSlat(); get_GPSlon(); err = get_GPSalt(); if (!err) { printf(" lat: %.6f° ", gpx.lat); printf(" lon: %.6f° ", gpx.lon); printf(" alt: %.2fm ", gpx.h); //if (option_verbose) { get_GPSvel24(); //if (option_verbose == 2) printf(" (%.1f ,%.1f,%.1f) ", gpx.vE, gpx.vN, gpx.vU); printf(" vH: %.1fm/s D: %.1f° vV: %.1fm/s ", gpx.vH, gpx.vD, gpx.vV); } } if (crc_err==0) printf(" [OK]"); else printf(" [NO]"); printf("\n"); } } } } void proc_frame(int len) { char *rawbits = NULL; int i, j, k, n; int err = 0; int errs = 0; int crc_err = 0; int flen; int pos; memset(rsbf, 0, sizeof(rsbf)); if ((len % 8) > 4) { while (len % 8) frame_rawbits[len++] = '0'; } //if (len > RAWBITFRAME_LEN+OVERLAP*BITS*2) len = RAWBITFRAME_LEN+OVERLAP*BITS*2; //for (i = len; i < RAWBITFRAME_LEN+OVERLAP*BITS*2; i++) frame_rawbits[i] = 0; // oder: '0' frame_rawbits[len] = '\0'; flen = len / (2*BITS); if (option_ecc) { viterbi(frm_rawbits); rawbits = vit_rawbits; } else rawbits = frm_rawbits; err = deconv(rawbits, frame_bits); if (err) { for (i=err; i < BITFRAME_LEN+OVERLAP*BITS; i++) frame_bits[i] = 0; } bits2bytes(frame_bits, frm_bytes); if (option_raw == 2) { for (i = 0; i < flen; i++) printf("%02x ", frm_bytes[i]); printf("\n"); } for (i = 0; i < flen; i++) { ecc_buf[bufidx] = frm_bytes[i]; bufidx = (bufidx+1) % ECCBUF_LEN; } k = 0; pos = 0; for (n = 0; n < flen-rs_R-5; n++) { int bf = 0; for (j = 0; j < 5; j++) bf += (frm_bytes[n+rs_R+j] == rs_sync[j]); if (bf == 5) { if (k < kMAX) { rsbf[k].epos = rs_R + n; rsbf[k].fpos = rs_R + pos; k++; } n += rs_R+5; } frame_bytes[pos] = frm_bytes[n]; pos++; } while (n < flen) frame_bytes[pos++] = frm_bytes[n++]; if (option_ecc == 2) { for (j = 0; j < pos; j++) f1.bytes[OFS+j] = frame_bytes[j]; for (i = 0; i < k; i++) { for (j = 0; j < rs_N; j++) rs_cw[j] = ecc_buf[ (bufidx-1-flen+rsbf[i].epos-j +ECCBUF_LEN) % ECCBUF_LEN ]; errs = lms6_ecc(rs_cw); for (j = rs_R; j < rs_N; j++) { int idx = rsbf[i].fpos-j; if (f1.pos-1 + idx < 0) f0.bytes[OFS+ f0.pos-1 + idx ] = rs_cw[j]; else f1.bytes[OFS+ f1.pos-1 + idx ] = rs_cw[j]; } // delay 1 frame due to overlap rsbf[i].errs = errs; if (option_raw == 4) { for (j = 0; j < rs_N; j++) printf("%02x", rs_cw[rs_N-1-j]); printf(" (%d)\n", errs); } } } f1.pos = pos; if (option_ecc == 2) { p_frame = f0.bytes; pos = f0.pos; } else { p_frame = frame; } crc_err = check_CRC(p_frame); print_frame(crc_err, len, pos); f0 = f1; f1.pos = 0; } int main(int argc, char **argv) { FILE *fp; char *fpname; int i, bit, len, rbit, rbit0; int pos; int header_found = 0; int next_header = 0; fpname = argv[0]; ++argv; while ((*argv) && (!wavloaded)) { if ( (strcmp(*argv, "-h") == 0) || (strcmp(*argv, "--help") == 0) ) { fprintf(stderr, "%s [options] audio.wav\n", fpname); fprintf(stderr, " options:\n"); fprintf(stderr, " -v, --verbose\n"); fprintf(stderr, " -r, --raw\n"); return 0; } else if ( (strcmp(*argv, "-v") == 0) || (strcmp(*argv, "--verbose") == 0) ) { option_verbose = 1; } //else if ( (strcmp(*argv, "-vv") == 0) ) option_verbose = 2; else if ( (strcmp(*argv, "-r") == 0) || (strcmp(*argv, "--raw") == 0) ) { option_raw = 1; // bytes - rs_ecc_codewords } else if ( (strcmp(*argv, "-r0") == 0) || (strcmp(*argv, "--raw0") == 0) ) { option_raw = 2; // bytes: info + codewords } else if ( (strcmp(*argv, "-rc") == 0) || (strcmp(*argv, "--rawecc") == 0) ) { option_raw = 4; // rs_ecc_codewords } else if ( (strcmp(*argv, "-R") == 0) || (strcmp(*argv, "--RAW") == 0) ) { option_raw = 8; // rawbits } else if (strcmp(*argv, "--ecc" ) == 0) { option_ecc = 1; } // viterbi else if (strcmp(*argv, "--ecc2") == 0) { option_ecc = 2; } // RS-ECC (+viterbi) else if ( (strcmp(*argv, "-i") == 0) || (strcmp(*argv, "--invert") == 0) ) { option_inv = 1; // unnoetig, NRZ-S... } else if (strcmp(*argv, "--res") == 0) { option_res = 1; } else if (strcmp(*argv, "-b") == 0) { option_b = 1; } else { fp = fopen(*argv, "rb"); if (fp == NULL) { fprintf(stderr, "%s konnte nicht geoeffnet werden\n", *argv); return -1; } wavloaded = 1; } ++argv; } if (!wavloaded) fp = stdin; i = read_wav_header(fp); if (i) { fclose(fp); return -1; } if (option_raw == 4) option_ecc = 2; if (option_ecc) { vit_initCodes(); } if (option_ecc == 2) { rs_init_RS255ccsds(); // bch_ecc.c } pos = FRAMESTART; rbit0 = 0; //idle while (!read_bits_fsk(fp, &rbit, &len)) { if (len == 0) { // reset_frame(); /*if (pos > 8*2*pos_GPSlon) { //for (i = pos; i < RAWBITFRAME_LEN+OVERLAP*BITS*2; i++) frame_rawbits[i] = '0'; proc_frame(pos); //header_found = 0; pos = FRAMESTART; }*/ //inc_bufpos(); //buf[bufpos] = 'x'; //fprintf(stderr, "len==0\n"); continue; // ... } for (i = 0; i < len; i++) { inc_bufpos(); bit = 0x30 + (rbit==rbit0); // Ascii, NRZ-S buf[bufpos] = bit; rbit0 = rbit; if (!header_found) { header_found = compare2(); } else { if (pos < RAWBITFRAME_LEN+OVERLAP*BITS*2) { frame_rawbits[pos] = bit; pos++; } } if (pos > FRM_MINLEN*(2*BITS)) { next_header = compare2(); } if (pos >= RAWBITFRAME_LEN+OVERLAP*BITS*2 || next_header) { frame_rawbits[pos] = '\0'; proc_frame(pos); pos = FRAMESTART; header_found = next_header; next_header = 0; } } if (header_found && option_b) { bitstart = 1; while ( pos < FRM_MINLEN*(2*BITS) ) { if (read_rawbit(fp, &rbit) == EOF) break; bit = 0x30 + (rbit==rbit0); // Ascii, NRZ-S rbit0 = rbit; frame_rawbits[pos] = bit; pos++; } } } printf("\n"); fclose(fp); return 0; }