// This file is part of LeanSDR Copyright (C) 2016-2019 . // See the toplevel README for more information. // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see . // Latest updates: // | S2: Revert to tracking all symbols. pabr committed on Mar 6, 2019 // | Cleanup: Remove debug code. pabr committed on Mar 6, 2019 // | S2: Dummy PLFRAME handling pabr committed on Mar 26, 2019 // | S2: Preliminary support for GSE pabr committed on Mar 26, 2019 // | leandvbtx: Signal S2 MATYPE as TS. pabr committed on Mar 26, 2019 // | DVB-S2 VCM support, suitable for ACM reception (not MIS). pabr committed on Nov 24, 2019 // | Remove unused constants. pabr committed on Dec 4, 2019 // | S2 RX: Capture TED decision history in sampler_state. pabr committed on Dec 5, 2019 // | S2 RX: Print error rate on PLS symbols. pabr committed on Dec 5, 2019 // | New DVB-S2 receiver with PL-based carrier recovery. modcod/framesize filtering for VCM. pabr committed on Jan 9, 2020 // skip Soft-decoding of S2 PLSCODE. pabr committed on Jan 16, 2020 // skip Validate PLHEADER soft-decoding when DEBUG_CARRIER==1. pabr committed on Jan 17, 2020 // | Cleanup scope of some S2 constants. pabr committed on Apr 29, 2020 // skip Fix overflow to state_out stream. pabr committed on Apr 29, 2020 // | S2 deframer: Set TEI bit on TS packets with bad CRC8. pabr committed on Jul 29, 2020 #ifndef LEANSDR_DVBS2_H #define LEANSDR_DVBS2_H /* #include "leansdr/bch.h" #include "leansdr/crc.h" #include "leansdr/dvb.h" #include "leansdr/ldpc.h" #include "leansdr/sdr.h" #include "leansdr/softword.h" */ #include #include #include #include "bch.h" #include "crc.h" #include "dvb.h" #include "softword.h" #include "ldpc.h" #include "sdr.h" #ifdef LINUX #include #include #include "ldpctool/layered_decoder.h" #include "ldpctool/testbench.h" #include "ldpctool/algorithms.h" #endif namespace leansdr { // S2 THRESHOLDS (for comparing demodulators) static const uint32_t S2_MAX_ERR_SOF = 13; // 26 bits static const uint64_t S2_MAX_ERR_PLSCODE = 8; // 64 bits, dmin=32 static const int pilot_length = 36; // S2 SOF // EN 302 307-1 section 5.5.2.1 SOF field template struct s2_sof { static const uint32_t VALUE = 0x18d2e82; static const uint32_t MASK = 0x3ffffff; static const int LENGTH = 26; std::complex symbols[LENGTH]; s2_sof() { for (int s = 0; s < LENGTH; ++s) { int angle = ((VALUE >> (LENGTH - 1 - s)) & 1) * 2 + (s & 1); // pi/2-BPSK symbols[s].real(cstln_amp * cosf(M_PI / 4 + 2 * M_PI * angle / 4)); symbols[s].imag(cstln_amp * sinf(M_PI / 4 + 2 * M_PI * angle / 4)); } } }; // s2_sof // S2 PLS CODES // Precomputes the PLS code sequences. // EN 302 307-1 section 5.5.2.4 PLS code template struct s2_plscodes { // PLS index format MODCOD[4:0]|SHORTFRAME|PILOTS static const int COUNT = 128; static const int LENGTH = 64; uint64_t codewords[COUNT]; std::complex symbols[COUNT][LENGTH]; s2_plscodes() { uint32_t G[6] = {0x55555555, 0x33333333, 0x0f0f0f0f, 0x00ff00ff, 0x0000ffff, 0xffffffff}; for (int index = 0; index < COUNT; ++index) { uint32_t y = 0; for (int row = 0; row < 6; ++row) { if ((index >> (6 - row)) & 1) { y ^= G[row]; } } uint64_t code = 0; for (int bit = 31; bit >= 0; --bit) { int yi = (y >> bit) & 1; if (index & 1) { code = (code << 2) | (yi << 1) | (yi ^ 1); } else { code = (code << 2) | (yi << 1) | yi; } } // Scrambling code ^= SCRAMBLING; // Store precomputed codeword. codewords[index] = code; // Also store as symbols. for (int i = 0; i < LENGTH; ++i) { int yi = (code >> (LENGTH - 1 - i)) & 1; int nyi = yi ^ (i & 1); symbols[index][i].real(cstln_amp * (1 - 2 * nyi) / sqrtf(2)); symbols[index][i].imag(cstln_amp * (1 - 2 * yi) / sqrtf(2)); } } } static const uint64_t SCRAMBLING = 0x719d83c953422dfa; }; // s2_plscodes static const int PILOT_LENGTH = 36; // Date about pilots. // Mostly for consistency with s2_sof and s2_plscodes. template struct s2_pilot { static const int LENGTH = PILOT_LENGTH; std::complex symbol; s2_pilot() { symbol.real(cstln_amp*0.707107); symbol.imag(cstln_amp*0.707107); } }; // s2_pilot // S2 SCRAMBLING // Precomputes the symbol rotations for PL scrambling. // EN 302 307-1 section 5.5.4 Physical layer scrambling struct s2_scrambling { uint8_t Rn[131072]; // 0..3 (* 2pi/4) s2_scrambling(int codenum = 0) { uint32_t stx = 0x00001, sty = 0x3ffff; // x starts at codenum, wraps at index 2^18-1 by design for (int i = 0; i < codenum; ++i) { stx = lfsr_x(stx); } // First half of sequence is LSB of scrambling angle for (int i = 0; i < 131072; ++i) { int zn = (stx ^ sty) & 1; Rn[i] = zn; stx = lfsr_x(stx); sty = lfsr_y(sty); } // Second half is MSB for (int i = 0; i < 131072; ++i) { int zn = (stx ^ sty) & 1; Rn[i] |= zn << 1; stx = lfsr_x(stx); sty = lfsr_y(sty); } } uint32_t lfsr_x(uint32_t X) { int bit = ((X >> 7) ^ X) & 1; return ((bit << 18) | X) >> 1; } uint32_t lfsr_y(uint32_t Y) { int bit = ((Y >> 10) ^ (Y >> 7) ^ (Y >> 5) ^ Y) & 1; return ((bit << 18) | Y) >> 1; } }; // s2_scrambling // S2 BBSCRAMBLING // Precomputes the xor pattern for baseband scrambling. // EN 302 307-1 section 5.2.2 BB scrambling struct s2_bbscrambling { s2_bbscrambling() { uint16_t st = 0x00a9; // 000 0000 1010 1001 (Fig 5 reversed) for (unsigned int i = 0; i < sizeof(pattern); ++i) { uint8_t out = 0; for (int n = 8; n--;) { int bit = ((st >> 13) ^ (st >> 14)) & 1; // Taps out = (out << 1) | bit; // MSB first st = (st << 1) | bit; // Feedback } pattern[i] = out; } } void transform(const uint8_t *in, int bbsize, uint8_t *out) { for (int i = 0; i < bbsize; ++i) { out[i] = in[i] ^ pattern[i]; } } private: uint8_t pattern[58192]; // Values 0..3 }; // s2_bbscrambling // S2 PHYSICAL LAYER SIGNALLING struct s2_pls { int modcod; // 0..31 bool sf; bool pilots; int framebits() const { return sf ? 16200 : 64800; } bool is_dummy() { return (modcod==0); } }; static const int PLSLOT_LENGTH = 90; template struct plslot { static const int LENGTH = PLSLOT_LENGTH; bool is_pls; union { s2_pls pls; SOFTSYMB symbols[LENGTH]; }; }; // EN 302 307-1 section 5.5.2.2 MODCOD field // EN 302 307-1 section 6 Error performance const struct modcod_info { static const int MIN_SLOTS_PER_FRAME = 144; static const int MIN_SYMBOLS_PER_FRAME = (1+MIN_SLOTS_PER_FRAME) * PLSLOT_LENGTH; static const int MAX_SLOTS_PER_FRAME = 360; static const int MAX_SYMBOLS_PER_FRAME = (1 + MAX_SLOTS_PER_FRAME) * PLSLOT_LENGTH + ((MAX_SLOTS_PER_FRAME - 1) / 16) * PILOT_LENGTH; int nslots_nf; // Number of 90-symbol slots per normal frame int nsymbols; // Symbols in the constellation cstln_base::predef c; code_rate rate; // Ideal Es/N0 for normal frames // EN 302 307 section 6 Error performance float esn0_nf; // Radii for APSK // EN 302 307, section 5.4.3, Table 9 // EN 302 307, section 5.4.4, Table 10 float g1, g2, g3; } modcod_infos[32] = { {0, 0, cstln_base::BPSK, FEC12, 0.0, 0.0, 0.0, 0.0}, // 1 - 11 {360, 4, cstln_base::QPSK, FEC14, -2.35, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC13, -1.24, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC25, -0.30, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC12, 1.00, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC35, 2.23, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC23, 3.10, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC34, 4.03, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC45, 4.68, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC56, 5.18, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC89, 6.20, 0.0, 0.0, 0.0}, {360, 4, cstln_base::QPSK, FEC910, 6.42, 0.0, 0.0, 0.0}, // 12 - 17 {240, 8, cstln_base::PSK8, FEC35, 5.50, 0.0, 0.0, 0.0}, {240, 8, cstln_base::PSK8, FEC23, 6.62, 0.0, 0.0, 0.0}, {240, 8, cstln_base::PSK8, FEC34, 7.91, 0.0, 0.0, 0.0}, {240, 8, cstln_base::PSK8, FEC56, 9.35, 0.0, 0.0, 0.0}, {240, 8, cstln_base::PSK8, FEC89, 10.69, 0.0, 0.0, 0.0}, {240, 8, cstln_base::PSK8, FEC910, 10.98, 0.0, 0.0, 0.0}, // 18 - 23 {180, 16, cstln_base::APSK16, FEC23, 8.97, 3.15, 0.0, 0.0}, {180, 16, cstln_base::APSK16, FEC34, 10.21, 2.85, 0.0, 0.0}, {180, 16, cstln_base::APSK16, FEC45, 11.03, 2.75, 0.0, 0.0}, {180, 16, cstln_base::APSK16, FEC56, 11.61, 2.70, 0.0, 0.0}, {180, 16, cstln_base::APSK16, FEC89, 12.89, 2.60, 0.0, 0.0}, {180, 16, cstln_base::APSK16, FEC910, 13.13, 2.57, 0.0, 0.0}, // 24 - 28 {144, 32, cstln_base::APSK32, FEC34, 12.73, 2.84, 5.27, 0.0}, {144, 32, cstln_base::APSK32, FEC45, 13.64, 2.72, 4.87, 0.0}, {144, 32, cstln_base::APSK32, FEC56, 14.28, 2.64, 4.64, 0.0}, {144, 32, cstln_base::APSK32, FEC89, 15.69, 2.54, 4.33, 0.0}, {144, 32, cstln_base::APSK32, FEC910, 16.05, 2.53, 4.30, 0.0}, // 29 - 31 {0, 0, cstln_base::BPSK, FEC12, 0.0, 0.0, 0.0, 0.0}, {0, 0, cstln_base::BPSK, FEC12, 0.0, 0.0, 0.0, 0.0}, {0, 0, cstln_base::BPSK, FEC12, 0.0, 0.0, 0.0, 0.0} }; // Assert that a MODCOD number is valid const modcod_info *check_modcod(int m) { if (m < 0 || m > 31) { fail("Invalid MODCOD number"); } const modcod_info *r = &modcod_infos[m]; if (!r->nslots_nf) { fail("Unsupported MODCOD"); } return r; } // S2 FRAME TRANSMITTER template struct s2_frame_transmitter : runnable { s2_frame_transmitter( scheduler *sch, pipebuf> &_in, pipebuf> &_out ) : runnable(sch, "S2 frame transmitter"), in(_in), out(_out, modcod_info::MAX_SYMBOLS_PER_FRAME) { float amp = cstln_amp / sqrtf(2); qsymbols[0].real() = +amp; qsymbols[0].imag() = +amp; qsymbols[1].real() = +amp; qsymbols[1].imag() = -amp; qsymbols[2].real() = -amp; qsymbols[2].imag() = +amp; qsymbols[3].real() = -amp; qsymbols[3].imag() = -amp; // Clear the constellation cache. for (int i = 0; i < 32; ++i) { pcsymbols[i] = nullptr; } } ~s2_frame_transmitter() { } void run() { while (in.readable() >= 1) { plslot *pin = in.rd(); if (!pin->is_pls) { fail("Expected PLS pseudo-slot"); } s2_pls *pls = &pin->pls; const modcod_info *mcinfo = check_modcod(pls->modcod); int nslots = (pls->sf ? mcinfo->nslots_nf / 4 : mcinfo->nslots_nf); if (in.readable() < 1 + nslots) { break; } // Require room for BBHEADER + slots + optional pilots. int nsymbols = ((1 + nslots) * plslot::LENGTH + (pls->pilots ? ((nslots - 1) / 16) * pilot_length : 0)); if (out.writable() < nsymbols) { break; } int nw = run_frame(pls, mcinfo, pin + 1, nslots, out.wr()); if (nw != nsymbols) { fail("Bug: s2_frame_transmitter overflow"); } in.read(1 + nslots); out.written(nsymbols); } } int run_frame( s2_pls *pls, const modcod_info *mcinfo, const plslot *pin, int nslots, std::complex *pout ) { std::complex *pout0 = pout; // For sanity check // PLHEADER: SOF AND PLSCODE // EN 302 307-1 section 5.5.2 PL signalling memcpy(pout, sof.symbols, sof.LENGTH * sizeof(*pout)); pout += sof.LENGTH; int pls_index = (pls->modcod << 2) | (pls->sf << 1) | pls->pilots; memcpy(pout, plscodes.symbols[pls_index], plscodes.LENGTH * sizeof(*pout)); pout += plscodes.LENGTH; std::complex *csymbols = get_csymbols(pls->modcod); // Slots and pilots int till_next_pilot = pls->pilots ? 16 : nslots; uint8_t *scr = &scrambling.Rn[0]; for (int S = 0; S < nslots; ++S, ++pin, --till_next_pilot) { if (till_next_pilot == 0) { // Send pilot for (int s = 0; s < pilot_length; ++s, ++scr, ++pout) { scramble(&qsymbols[0], *scr, pout); } till_next_pilot = 16; } // Send slot if (pin->is_pls) { fail("s2_frame_transmitter: bad input sequence"); } const hard_ss *ps = pin->symbols; for (int s = 0; s < pin->LENGTH; ++s, ++ps, ++scr, ++pout) { scramble(&csymbols[*ps], *scr, pout); } } return pout - pout0; } inline void scramble(const std::complex *src, uint8_t r, std::complex *dst) { switch (r) { case 3: dst->re = src->im; dst->im = -src->re; break; case 2: dst->re = -src->re; dst->im = -src->im; break; case 1: dst->re = -src->im; dst->im = src->re; break; default: *dst = *src; } } private: pipereader> in; pipewriter> out; std::complex *pcsymbols[32]; // Constellations in use, indexed by modcod std::complex *get_csymbols(int modcod) { if (!pcsymbols[modcod]) { const modcod_info *mcinfo = check_modcod(modcod); if (sch->debug) { fprintf( stderr, "Building constellation %s ratecode %d\n", cstln_base::names[mcinfo->c], mcinfo->rate ); } // TBD Different Es/N0 for short frames ? cstln_lut cstln( mcinfo->c, mcinfo->esn0_nf, mcinfo->g1, mcinfo->g2, mcinfo->g3 ); pcsymbols[modcod] = new std::complex[cstln.nsymbols]; for ( int s=0; s qsymbols[4]; // RMS cstln_amp s2_sof sof; s2_plscodes plscodes; s2_scrambling scrambling; }; // s2_frame_transmitter // S2 FRAME RECEIVER #define TEST_DIVERSITY 0 template struct s2_frame_receiver : runnable { sampler_interface *sampler; int meas_decimation; float Ftune; // Tuning bias in cycles per symbol bool allow_drift; // Unbounded carrier tracking float omega0; // Samples per symbol bool strongpls; // PL symbols at max amplitude (default: RMS) uint32_t modcods; // Bitmask of desired modcods uint8_t framesizes; // Bitmask of desired frame sizes bool fastlock; // Synchronize more agressively bool fastdrift; // Carrier drift faster than pilots float freq_tol; // Tolerance on carrier frequency float sr_tol; // Tolerance on symbol rate s2_frame_receiver( scheduler *sch, sampler_interface *_sampler, pipebuf< std::complex > &_in, pipebuf< plslot > &_out, pipebuf *_freq_out=NULL, pipebuf *_ss_out=NULL, pipebuf *_mer_out=NULL, pipebuf< std::complex > *_cstln_out=NULL, pipebuf< std::complex > *_cstln_pls_out=NULL, pipebuf< std::complex > *_symbols_out=NULL, pipebuf *_state_out=NULL ) : runnable(sch, "S2 frame receiver"), sampler(_sampler), meas_decimation(1048576), Ftune(0), allow_drift(false), strongpls(false), modcods(0xffffffff), framesizes(0x03), fastlock(false), fastdrift(false), freq_tol(0.25), sr_tol(100e-6), cstln(NULL), in(_in), out(_out,1+modcod_info::MAX_SLOTS_PER_FRAME), meas_count(0), freq_out(opt_writer(_freq_out)), ss_out(opt_writer(_ss_out)), mer_out(opt_writer(_mer_out)), cstln_out(opt_writer(_cstln_out,1024)), cstln_pls_out(opt_writer(_cstln_pls_out,1024)), symbols_out(opt_writer(_symbols_out, modcod_info::MAX_SYMBOLS_PER_FRAME)), state_out(opt_writer(_state_out)), first_run(true), scrambling(0), pls_total_errors(0), pls_total_count(0), m_modcodType(-1), m_modcodRate(-1), m_locked(false), diffs(nullptr), sspilots(nullptr) { // Constellation for PLS qpsk = new cstln_lut(cstln_base::QPSK); // Clear the constellation cache. for (int i=0; i<32; ++i) { cstlns[i] = NULL; } #if TEST_DIVERSITY fprintf(stderr, "** DEBUG: Diversity test mode (slower)\n"); #endif } ~s2_frame_receiver() { delete qpsk; for (int i=0; i<32; ++i) { if (cstlns[i]) { delete cstlns[i]; } } if (diffs) { delete[] diffs; } if (sspilots) { delete[] sspilots; } } enum { FRAME_DETECT, // Looking for PLHEADER FRAME_PROBE, // Aligned with PLHEADER, ready to recover carrier FRAME_LOCKED, // Demodulating } state; // sampler_state holds the entire state of the PLL. // Useful for looking ahead (e.g. next pilots/SOF) then rewinding. struct sampler_state { std::complex *p; // Pointer to samples (update when entering run()) float mu; // Time of next symbol, counted from p float omega; // Samples per symbol float gain; // Scaling factor toward cstln_amp float ph16; // Carrier phase at next symbol (cycles * 65536) float fw16; // Carrier frequency (cycles per symbol * 65536) uint8_t *scr; // Position in scrambling sequence for next symbol void normalize() { ph16 = fmodf(ph16, 65536.0f); // Rounding direction irrelevant } void skip_symbols(int ns) { mu += omega * ns; p += (int)floorf(mu); mu -= floorf(mu); ph16 += fw16 * ns; normalize(); scr += ns; } char *format() { static char buf[256]; sprintf( buf, "%9.2lf %+6.0f ppm %+3.0f ° %f", (double)((p-(std::complex*)NULL)&262143)+mu, // Arbitrary wrap fw16*1e6/65536, fmodfs(ph16,65536.0f)*360/65536, gain ); return buf; } }; float min_freqw16, max_freqw16; // State during FRAME_SEARCH and FRAME_LOCKED sampler_state ss_cache; void run() { if (strongpls) { fail("--strongpls is broken."); } // Require enough samples to detect one plheader, // TBD margin ? int min_samples = (1 + modcod_info::MAX_SYMBOLS_PER_FRAME + sof.LENGTH+plscodes.LENGTH)*omega0 * 2; while (in.readable() >= min_samples + sampler->readahead() && out.writable() >= 1+modcod_info::MAX_SLOTS_PER_FRAME && opt_writable(freq_out, 1) && opt_writable(ss_out, 1) && opt_writable(mer_out, 1) && opt_writable(symbols_out, modcod_info::MAX_SYMBOLS_PER_FRAME) && opt_writable(state_out, 1)) { if (first_run) { enter_frame_detect(); first_run = false; } switch ( state ) { case FRAME_DETECT: run_frame_detect(); break; case FRAME_PROBE: run_frame_probe(); break; case FRAME_LOCKED: run_frame_locked(); break; } } } // State transtion void enter_frame_detect() { state = FRAME_DETECT; // Setup sampler for interpolation only. ss_cache.fw16 = 65536 * Ftune; ss_cache.ph16 = 0; ss_cache.mu = 0; ss_cache.gain = 1; ss_cache.omega = omega0; // Set frequency tracking boundaries around tuning frequency. if (allow_drift) { // Track across the whole baseband. min_freqw16 = ss_cache.fw16 - omega0*65536; max_freqw16 = ss_cache.fw16 + omega0*65536; } else { min_freqw16 = ss_cache.fw16 - freq_tol*65536.0; max_freqw16 = ss_cache.fw16 + freq_tol*65536.0; } opt_write(state_out, 0); if (sch->debug) { fprintf(stderr, "enter_frame_detect\n"); } if (fastlock || first_run) { discard = 0; } else { // Discard some data so that CPU usage during PLHEADER detection // is at same level as during steady-state demodulation. // This has no effect if the first detection is successful. float duty_factor = 5; discard = modcod_info::MAX_SYMBOLS_PER_FRAME * omega0 * (duty_factor+rand_compat()-0.5); } } long discard; void run_frame_detect() { if ( discard ) { size_t d = std::min(discard, in.readable()); in.read(d); discard -= d; return; } sampler->update_freq(ss_cache.fw16/omega0); const int search_range = modcod_info::MAX_SYMBOLS_PER_FRAME; ss_cache.p = in.rd(); find_plheader(&ss_cache, search_range); #if DEBUG_CARRIER fprintf(stderr, "CARRIER diffcorr: %.0f%% %s\n", q*100, ss_cache.format()); #endif in.read(ss_cache.p-in.rd()); enter_frame_probe(); } void enter_frame_probe() { if (sch->debug) { fprintf(stderr, "PROBE\n"); } if (m_locked) { fprintf(stderr, "UNLOCKED\n"); m_locked = false; } state = FRAME_PROBE; } void run_frame_probe() { return run_frame_probe_locked(); } void enter_frame_locked() { state = FRAME_LOCKED; if (sch->debug) { fprintf(stderr, "LOCKED\n"); } if (!m_locked) { fprintf(stderr, "LOCKED\n"); m_locked = true; } opt_write(state_out, 1); } void run_frame_locked() { return run_frame_probe_locked(); } // Process one frame. // Perform additional carrier estimation if state==FRAME_PROBE. void run_frame_probe_locked() { std::complex *psampled; // Data symbols (one per slot) if (cstln_out && cstln_out->writable()>=1024) { psampled = cstln_out->wr(); } else { psampled = NULL; } std::complex *psampled_pls; // PLHEADER symbols if (cstln_pls_out && cstln_pls_out->writable()>=1024) { psampled_pls = cstln_pls_out->wr(); } else { psampled_pls = NULL; } #if TEST_DIVERSITY std::complex *psymbols = symbols_out ? symbols_out->wr() : NULL; float scale_symbols = 1.0 / cstln_amp; #endif sampler_state ss = ss_cache; ss.p = in.rd(); ss.normalize(); sampler->update_freq(ss.fw16/omega0); #if DEBUG_CARRIER fprintf(stderr, "CARRIER frame: %s\n", ss.format()); #endif // Interpolate PLHEADER. const int PLH_LENGTH = sof.LENGTH + plscodes.LENGTH; std::complex plh_symbols[PLH_LENGTH]; for (int s=0; s p = interp_next(&ss) * ss.gain; plh_symbols[s] = p; if (psampled_pls) { *psampled_pls++ = p; } } // Decode SOF. uint32_t sof_bits = 0; // Optimization with half loop and even/odd processing in a single step for (int i = 0; i < sof.LENGTH/2; ++i) { std::complex p0 = plh_symbols[2*i]; std::complex p1 = plh_symbols[2*i+1]; float d0 = p0.imag() + p0.real(); float d1 = p1.imag() - p1.real(); sof_bits = (sof_bits<<2) | ((d0<0)<<1) | (d1<0); } uint32_t sof_errors = hamming_weight(sof_bits ^ sof.VALUE); pls_total_errors += sof_errors; pls_total_count += sof.LENGTH; if (sof_errors >= S2_MAX_ERR_SOF) { if (sch->debug2) { fprintf(stderr, "Too many errors in SOF (%u/26)\n", sof_errors); } in.read(ss.p-in.rd()); enter_frame_detect(); return; } // Decode PLSCODE. uint64_t plscode = 0; // Optimization with half loop and even/odd processing in a single step for (int i=0; i p0 = plh_symbols[sof.LENGTH+2*i]; std::complex p1 = plh_symbols[sof.LENGTH+2*i+1]; float d0 = p0.imag() + p0.real(); float d1 = p1.imag() - p1.real(); plscode = (plscode<<2) | ((d0<0)<<1) | (d1<0); } uint32_t plscode_errors = plscodes.LENGTH + 1; int plscode_index = -1; // Avoid compiler warning. // TBD: Optimization? #if 1 for (int i = 0; i < plscodes.COUNT; ++i) { // number of different bits from codeword uint32_t e = std::bitset<64>(plscode ^ plscodes.codewords[i]).count(); if (e < plscode_errors ) { plscode_errors = e; plscode_index = i; } } #else uint64_t pls_candidates[plscodes.COUNT]; std::fill(pls_candidates, pls_candidates + plscodes.COUNT, plscode); std::transform(pls_candidates, pls_candidates + plscodes.COUNT, plscodes.codewords, pls_candidates, [](uint64_t x, uint64_t y) { return hamming_weight(x^y); // number of different bits with codeword }); uint64_t *pls_elected = std::min_element(pls_candidates, pls_candidates + plscodes.COUNT); // choose the one with lowest difference plscode_errors = *pls_elected; plscode_index = pls_elected - pls_candidates; #endif pls_total_errors += plscode_errors; pls_total_count += plscodes.LENGTH; if (plscode_errors >= S2_MAX_ERR_PLSCODE) { if (sch->debug2) { fprintf(stderr, "Too many errors in plscode (%u/%lu)\n", plscode_errors, S2_MAX_ERR_PLSCODE); } in.read(ss.p-in.rd()); enter_frame_detect(); return; } // ss now points to first data slot. ss.scr = scrambling.Rn; std::complex plh_expected[PLH_LENGTH]; std::copy(sof.symbols, sof.symbols + sof.LENGTH, plh_expected); std::copy(plscodes.symbols[plscode_index], plscodes.symbols[plscode_index] + plscodes.LENGTH, &plh_expected[sof.LENGTH]); if ( state == FRAME_PROBE ) { // Carrier frequency from differential detector is still not reliable. // Use known PLH symbols to improve. match_freq(plh_expected, plh_symbols, PLH_LENGTH, &ss); #if DEBUG_CARRIER fprintf(stderr, "CARRIER freq: %s\n", ss.format()); #endif } // Use known PLH symbols to estimate carrier phase and amplitude. float mer2 = match_ph_amp(plh_expected, plh_symbols, PLH_LENGTH, &ss); float mer = 10*log10f(mer2); #if DEBUG_CARRIER fprintf(stderr, "CARRIER plheader: %s MER %.1f dB\n", ss.format(), mer); #endif // Parse PLSCODE. s2_pls pls; pls.modcod = plscode_index >> 2; // Guaranteed 0..31 pls.sf = plscode_index & 2; pls.pilots = plscode_index & 1; plslot *pout=out.wr(), *pout0 = pout; if (sch->debug2) { fprintf( stderr, "PLS: mc=%2d, sf=%d, pilots=%d (%2u/90) %4.1f dB ", pls.modcod, pls.sf, pls.pilots, sof_errors + plscode_errors, mer ); } // Determine contents of frame. int S; // Data slots in this frame cstln_lut *dcstln; // Constellation for data slots if (pls.is_dummy()) { S = 36; dcstln = qpsk; } else { const modcod_info *mcinfo = &modcod_infos[pls.modcod]; if (! mcinfo->nslots_nf) { fprintf(stderr, "Unsupported or corrupted MODCOD\n"); in.read(ss.p-in.rd()); enter_frame_detect(); return; } if (mer < mcinfo->esn0_nf - 3.0f) // was -1.0f { // False positive from PLHEADER detection. if (sch->debug) { fprintf(stderr, "Insufficient MER (%f/%f)\n", mer, mcinfo->esn0_nf - 3.0f); } in.read(ss.p-in.rd()); enter_frame_detect(); return; } if (pls.sf && mcinfo->rate == FEC910) { // TBD use fec_infos fprintf(stderr, "Unsupported or corrupted FEC\n"); in.read(ss.p-in.rd()); enter_frame_detect(); return; } // Store current MODCOD info if (mcinfo->c != m_modcodType) { m_modcodType = mcinfo->c < cstln_base::predef::COUNT ? mcinfo->c : -1; } if (mcinfo->rate != m_modcodRate) { m_modcodRate = mcinfo->rate < code_rate::FEC_COUNT ? mcinfo->rate : -1; } S = pls.sf ? mcinfo->nslots_nf/4 : mcinfo->nslots_nf; // Constellation for data slots. dcstln = get_cstln(pls.modcod); cstln = dcstln; // Used by GUI cstln->m_rateCode = mcinfo->rate < code_rate::FEC_COUNT ? mcinfo->rate : -1; cstln->m_typeCode = mcinfo->c < cstln_base::predef::COUNT ? mcinfo->c : -1; cstln->m_setByModcod = true; // Output special slot with PLS information. pout->is_pls = true; pout->pls = pls; ++pout; } // Now we know the frame structure. // Estimate carrier over known symbols. #if DEBUG_LOOKAHEAD static int plh_counter = 0; // For debugging only fprintf(stderr, "\nLOOKAHEAD %d PLH sr %+3.0f %s %.1f dB\n", plh_counter, (1-ss.omega/omega0)*1e6, ss.format(), 10*log10f(mer2)); #endif // Next SOF sampler_state ssnext; { ssnext = ss; int ns = (S*PLSLOT_LENGTH + (pls.pilots?((S-1)/16)*pilot.LENGTH:0)); // Find next SOP at expected position +- tolerance on symbol rate. int ns_tol = lrintf(ns*sr_tol); ssnext.omega = omega0; ssnext.skip_symbols(ns-ns_tol); find_plheader(&ssnext, ns_tol*2); // Don't trust frequency from differential correlator. // Our current estimate should be better. ssnext.fw16 = ss.fw16; interp_match_sof(&ssnext); #if DEBUG_CARRIER fprintf(stderr, "\nCARRIER next: %.0f%% %s %.1f dB\n", q*100, ssnext.format(), 10*log10f(m2)); #endif // Estimate symbol rate (considered stable over whole frame) float dist = (ssnext.p-ss.p) + (ssnext.mu-ss.mu); // Set symbol period accordingly. ss.omega = dist / (ns+sof.LENGTH); } // Pilots int npilots = (S-1) / 16; if (sspilots) { delete[] sspilots; } sspilots = new sampler_state[npilots]; // Detect pilots if (pls.pilots) { sampler_state ssp = ss; for ( int i=0; i::LENGTH + sof.LENGTH; float dph = ssnext.ph16 - (ss.ph16+ss.fw16*span); ss.fw16 += fmodfs(dph,65536.0f) / span; } #if DEBUG_LOOKAHEAD fprintf(stderr, "LOOKAHEAD %d NEXTSOF sr %+3.0f %s %.1f dB\n", plh_counter, (1-ssnext.omega/omega0)*1e6, ssnext.format(), 10*log10f(mer2)); ++plh_counter; #endif if (state == FRAME_PROBE) { float fw0 = ss.fw16; match_frame(&ss, &pls, S, dcstln); // Apply retroactively from midpoint of pilots and next SOF. float fw_adj = ss.fw16 - fw0; if (pls.pilots) { for (int i=0; i freq_stats; // Read slots and pilots #if DEBUG_CARRIER fprintf(stderr, "CARRIER data: %s\n", ss.format()); #endif // int pilot_errors = 0; for (int slot=0; slotLENGTH + pilot.LENGTH; float dph = ssp->ph16 - (ss.ph16+ss.fw16*span); ss.fw16 += fmodfs(dph,65536.0f) / span; } else if (( pls.pilots && !(slot&15) && slot+16>=S) || (!pls.pilots && !slot )) { // Sequence of data slots followed by SOF int span = (S-slot)*pout->LENGTH + sof.LENGTH; float dph = ssnext.ph16 - (ss.ph16+ss.fw16*span); ss.fw16 += fmodfs(dph,65536.0f) / span; } // Read slot. freq_stats.add(ss.fw16); pout->is_pls = false; std::complex p; // Export last symbols for cstln_out for (int s=0; sLENGTH; ++s) { p = interp_next(&ss) * ss.gain; #if TEST_DIVERSITY if ( psymbols ) *psymbols++ = p * scale_symbols; #endif if (!pls.pilots || fastdrift) { (void) track_symbol(&ss, p, dcstln); // SLOW } std::complex d = descramble(&ss, p); #if 1 // Slow SOFTSYMB *symb = &dcstln->lookup(d.real(), d.imag())->ss; #else // Avoid scaling floats. May wrap at very low SNR. SOFTSYMB *symb = &dcstln->lookup((int)d.real(), (int)d.imag())->ss; #endif pout->symbols[s] = *symb; } ss.normalize(); if (psampled) { *psampled++ = p; } } // slot if (sch->debug2) { fprintf( stderr, "sr%+.0f fs=%.0f\n", (1-ss.omega/omega0)*1e6, (freq_stats.max()-freq_stats.min())*1e6/65536.0f ); } // Commit whole frame after final SOF. if (! pls.is_dummy()) { if ((modcods&(1<debug2) { fprintf(stderr, "modcod %d size %d rejected\n", pls.modcod, pls.sf); } } } // Write back sampler progress meas_count += ss.p - in.rd(); in.read(ss.p-in.rd()); ss_cache = ss; // Measurements if (psampled) { cstln_out->written(psampled-cstln_out->wr()); } if (psampled_pls) { cstln_pls_out->written(psampled_pls-cstln_pls_out->wr()); } #if TEST_DIVERSITY if ( psymbols ) symbols_out->written(psymbols-symbols_out->wr()); #endif if (meas_count >= meas_decimation) { opt_write(freq_out, ss_cache.fw16/65536/ss_cache.omega); opt_write(ss_out, cstln_amp / ss_cache.gain); opt_write(mer_out, mer2 ? 10*log10f(mer2) : -99); meas_count -= meas_decimation; } if (state == FRAME_PROBE) { // First frame completed successfully. Validate the lock. enter_frame_locked(); } if (ss_cache.fw16max_freqw16) { fprintf(stderr, "Carrier out of bounds\n"); enter_frame_detect(); } } // run_frame_probe_locked // Find most likely PLHEADER between *pss and *pss+search_range // by differential correlation. // Align symbol timing. // Estimate carrier frequency (to about +-10kppm). // Estimate carrier phase (to about +-PI/4). // Adjust *ss accordingly. // Initialize AGC. // Return confidence (unbounded, 0=bad, 1=nominal). float find_plheader(sampler_state *pss, int search_range) { std::complex best_corr = 0; int best_imu = 0; // Avoid compiler warning. int best_pos = 0; // Avoid compiler warning. // Symbol clock is not recovered yet, so we try fractional symbols. const int interp = 8; for (int imu=0; imu[ndiffs]; sampler_state ss = *pss; ss.mu += imu * ss.omega / interp; // Compute rotation between consecutive symbols. std::complex prev = 0; for (int i=0; i p = interp_next(&ss); diffs[i] = conjprod(prev, p); prev = p; } // Find best PLHEADER candidate position. const int ncorrs = search_range; for (int i=0; i c = correlate_plheader_diff(&diffs[i]); //if ( cnorm2(c) > cnorm2(best_corr) ) { // c.imag()>0 enforces frequency error +-Fm/4 if (cnorm2(c)>cnorm2(best_corr) && c.imag()>0) { best_corr = c; best_imu = imu; best_pos = i; } } } // imu // Setup sampler according to best match. pss->mu += best_imu * pss->omega / interp; pss->skip_symbols(best_pos); pss->normalize(); #if 0 // Lowpass-filter the differential correlator. // (Does not help much.) static std::complex acc = 0; static const float k = 0.05; acc = best_corr*k + acc*(1-k); best_corr = acc; #endif // Get rough estimate of carrier frequency from differential correlator. // (best_corr is nominally +j). float freqw = atan2f(-best_corr.real(), best_corr.imag()); pss->fw16 += freqw * 65536 / (2*M_PI); // Force refresh because correction may be large. sampler->update_freq(pss->fw16/omega0); // Interpolate SOF with initial frequency estimation. // Estimate phase by correlation. // Initialize AGC (naive). float q; { sampler_state ss = *pss; float power = 0; std::complex symbs[sof.LENGTH]; for (int i=0; i c = conjprod(sof.symbols, symbs, sof.LENGTH); c *= 1.0f / sof.LENGTH; align_phase(pss, c); float signal_amp = sqrtf(power/sof.LENGTH); q = sqrtf(cnorm2(c)) / (cstln_amp*signal_amp); pss->gain = cstln_amp / signal_amp; } return q; } // Correlate PLHEADER. std::complex correlate_plheader_diff(std::complex *diffs) { std::complex csof = correlate_sof_diff(diffs); std::complex cplsc = correlate_plscode_diff(&diffs[sof.LENGTH]); // Use csof+cplsc or csof-cplsc, whichever maximizes likelihood. std::complex c0 = csof + cplsc; // Best when b7==0 (pilots off) std::complex c1 = csof - cplsc; // Best when b7==1 (pilots on) std::complex c = (cnorm2(c0)>cnorm2(c1)) ? c0 : c1; return c * (1.0f/(26-1+64/2)); } // Correlate 25 differential transitions in SOF. std::complex correlate_sof_diff(std::complex *diffs) { std::complex c = 0; const uint32_t dsof = sof.VALUE ^ (sof.VALUE>>1); for (int i=0; i +PI/4 // Constant even bit => -PI/4 // Toggled odd bit => -PI/4 // Toggled even bit => +PI/4 if (((dsof>>(sof.LENGTH-1-i)) ^ i) & 1) { c += diffs[i]; } else { c -= diffs[i]; } } return c; } // Correlate 32 data-independent transitions in PLSCODE. std::complex correlate_plscode_diff(std::complex *diffs) { std::complex c = 0; uint64_t dscr = plscodes.SCRAMBLING ^ (plscodes.SCRAMBLING>>1); for (int i=1; i>(plscodes.LENGTH-1-i)) & 1 ) { c -= diffs[i]; } else { c += diffs[i]; } } return c; } // Adjust carrier frequency in *pss to match target phase after ns symbols. void adjust_freq(sampler_state *pss, int ns, const sampler_state *pnext) { // Note: Minimum deviation from current estimate. float adj = fmodfs(pnext->ph16-(pss->ph16+pss->fw16*ns),65536.0f) / ns; // 2sps vcm avec adj 10711K // 2sps vcm avec adj/2 10265k // 2sps vcm sans adj 8060K // 5sps 2MS1 avec adj 2262K // 5sps 2MS1 avec adj/2 3109K // 5sps 2MS1 avec adj/3 3254K // 5sps 2MS1 sans adj 3254K // 1.2sps oldbeacon avec adj 5774K // 1.2sps oldbeacon avec adj/2 15M // 1.2sps oldbeacon avec adj/3 15.6M max 17M // 1.2sps oldbeacon sans adj 14M malgré drift pss->fw16 += adj; } // Estimate frequency from known symbols by differential correlation. // Adjust *ss accordingly. // Retroactively frequency-shift the samples in-place. // // *ss must point after the sampled symbols. // expect[] must be PSK with amplitude cstln_amp. // Idempotent. // Not affected by phase error nor by gain mismatch. // Can handle +-25% error. // Result is typically such that residual phase error over a PLHEADER // spans less than 90°. void match_freq( std::complex *expect, std::complex *recv, int ns, sampler_state *ss) { if (sch->debug) { fprintf(stderr, "match_freq\n"); } std::complex diff = 0; for (int i=0; i de = conjprod(expect[i], expect[i+1]); std::complex dr = conjprod(recv[i], recv[i+1]); diff += conjprod(de, dr); } float dfw16 = atan2f(diff.imag(),diff.real()) * 65536 / (2*M_PI); // Derotate. for (int i=0; ifw16 += dfw16; ss->ph16 += dfw16 * ns; // Retroactively } // Interpolate a pilot block. // Perform ML match. float interp_match_pilot(sampler_state *pss) { std::complex symbols[pilot.LENGTH]; std::complex expected[pilot.LENGTH]; for (int i=0; i p = interp_next(pss) * pss->gain; symbols[i] = descramble(pss, p); expected[i] = pilot.symbol; //fprintf(stderr, "%f %f\n", symbols[i].real(), symbols[i].imag()); } return match_ph_amp(expected, symbols, pilot.LENGTH, pss); } // Interpolate a SOF. // Perform ML match. float interp_match_sof(sampler_state *pss) { std::complex symbols[pilot.LENGTH]; for (int i=0; igain; } return match_ph_amp(sof.symbols, symbols, sof.LENGTH, pss); } // Estimate phase and amplitude from known symbols. // Adjust *ss accordingly. // Retroactively derotate and scale the samples in-place. // Return MER^2. // // *ss must point after the sampled symbols, with gain applied. // expect[] must be PSK (not APSK) with amplitude cstln_amp. // Idempotent. float match_ph_amp( std::complex *expect, std::complex *recv, int ns, sampler_state *ss ) { std::complex rr = 0; for (int i=0; iph16 += dph16; rr *= trig.expi(-dph16); // rr.real() is now the modulation amplitude. float dgain = cstln_amp / rr.real(); ss->gain *= dgain; // Rotate and scale. Compute error power. std::complex adj = trig.expi(-dph16) * dgain; float ev2 = 0; for (int i=0; i *dcstln ) { if (sch->debug) { fprintf(stderr, "match_frame\n"); } // With pilots: Use first block of data slots. // Without pilots: Use whole frame. int ns = pls->pilots ? 16*90 : S*90; // Pilots: steps of ~700 ppm (= 1 cycle between pilots) // No pilots, normal frames: steps of ~30(QPSK) - ~80(32APSK) ppm // No pilots, short frames: steps of ~120(QPSK) - 300(32APSK) ppm int nwrap = pls->pilots ? 16*90+pilot.LENGTH : S*90+sof.LENGTH; // Frequency search range. int sliprange = pls->pilots ? 10 : 50; // TBD Customizable ? float besterr = 1e99; float bestslip = 0; // Avoid compiler warning for (int slip = -sliprange; slip <= sliprange; ++slip) { sampler_state ssl = *pss; float dfw = slip * 65536.0f / nwrap; ssl.fw16 += dfw; // Apply retroactively from midpoint of preceeding PLHEADER, // where the phase from match_ph_amp is most reliable. ssl.ph16 += dfw * (plscodes.LENGTH + sof.LENGTH) / 2; float err = 0; for (int s = 0; s < ns; ++s) { std::complex p = interp_next(&ssl) * ssl.gain; typename cstln_lut::result *cr = dcstln->lookup(p.real(), p.imag()); std::complex &cp = dcstln->symbols[cr->symbol]; std::complex ev(p.real()-cp.real(), p.imag()-cp.imag()); err += cnorm2(ev); } err /= ns * cstln_amp * cstln_amp; if (err < besterr) { besterr = err; bestslip = slip; } #if DEBUG_CARRIER fprintf(stderr, "slip %+3d %6.0f ppm err=%f\n", slip, ssl.fw16*1e6/65536, err); #endif } pss->fw16 += bestslip * 65536.0f / nwrap; } // match_frame void shutdown() { if (sch->verbose) { fprintf( stderr, "PL errors: %d/%d (%.0f ppm)\n", pls_total_errors, pls_total_count, 1e6 * pls_total_errors / pls_total_count ); } } std::complex descramble(sampler_state *ss, const std::complex &p) { int r = *ss->scr++; std::complex res; switch (r) { case 3: res.real(-p.imag()); res.imag(p.real()); break; case 2: res.real(-p.real()); res.imag(-p.imag()); break; case 1: res.real(p.imag()); res.imag(-p.real()); break; default: res = p; } return res; } // Interpolator inline std::complex interp_next(sampler_state *ss) { // Skip to next sample while (ss->mu >= 1) { ++ss->p; ss->mu-=1.0f; } // Interpolate #if 0 // Interpolate linearly then derotate. // This will fail with large carrier offsets (e.g. --tune). float cmu = 1.0f - ss->mu; std::complex s(ss->p[0].real()*cmu + ss->p[1].real()*ss->mu, ss->p[0].imag()*cmu + ss->p[1].imag()*ss->mu); ss->mu += ss->omega; // Derotate const std::complex &rot = trig.expi(-ss->ph16); ss->ph16 += ss->fw16; return rot * s; #else // Use generic interpolator std::complex s = sampler->interp(ss->p, ss->mu, ss->ph16); ss->mu += ss->omega; ss->ph16 += ss->fw16; return s; #endif } // Adjust phase in [ss] to cancel offset observed as [c]. void align_phase(sampler_state *ss, const std::complex &c) { float err = atan2f(c.imag(),c.real()) * 65536 / (2*M_PI); ss->ph16 += err; } inline uint8_t track_symbol( sampler_state *ss, const std::complex &p, cstln_lut *c ) { static const float kph = 4e-2; static const float kfw = 1e-4; // Decision typename cstln_lut::result *cr = c->lookup(p.real(), p.imag()); // Carrier tracking ss->ph16 += cr->phase_error * kph; ss->fw16 += cr->phase_error * kfw; if (ss->fw16 < min_freqw16) { ss->fw16 = min_freqw16; } if (ss->fw16 > max_freqw16) { ss->fw16 = max_freqw16; } return cr->symbol; } public: cstln_lut *qpsk; s2_plscodes plscodes; cstln_lut *cstlns[32]; // Constellations in use, by modcod cstln_lut *get_cstln(int modcod) { if (!cstlns[modcod]) { const modcod_info *mcinfo = &modcod_infos[modcod]; if (sch->debug) { fprintf( stderr, "Creating LUT for %s ratecode %d\n", cstln_base::names[mcinfo->c], mcinfo->rate ); } cstlns[modcod] = new cstln_lut( mcinfo->c, mcinfo->esn0_nf, mcinfo->g1, mcinfo->g2, mcinfo->g3 ); #if 0 fprintf(stderr, "Dumping constellation LUT to stdout.\n"); cstlns[modcod]->dump(stdout); exit(0); #endif } return cstlns[modcod]; } cstln_lut *cstln; // Last seen, or NULL (legacy) trig16 trig; pipereader< std::complex > in; pipewriter< plslot > out; int meas_count; pipewriter *freq_out, *ss_out, *mer_out; pipewriter< std::complex > *cstln_out; pipewriter< std::complex > *cstln_pls_out; pipewriter< std::complex > *symbols_out; pipewriter *state_out; bool first_run; // S2 constants s2_scrambling scrambling; s2_sof sof; s2_pilot pilot; // Performance stats on PL signalling uint32_t pls_total_errors, pls_total_count; int m_modcodType; int m_modcodRate; bool m_locked; private: std::complex *diffs; sampler_state *sspilots; }; // s2_frame_receiver template struct fecframe { s2_pls pls; SOFTBYTE bytes[64800 / 8]; // Contains 16200/8 or 64800/8 bytes. }; // S2 INTERLEAVER // EN 302 307-1 section 5.3.3 Bit Interleaver struct s2_interleaver : runnable { s2_interleaver( scheduler *sch, pipebuf> &_in, pipebuf> &_out ) : runnable(sch, "S2 interleaver"), in(_in), out(_out, 1 + 360) { } void run() { while (in.readable() >= 1) { const s2_pls *pls = &in.rd()->pls; const modcod_info *mcinfo = check_modcod(pls->modcod); int nslots = pls->sf ? mcinfo->nslots_nf / 4 : mcinfo->nslots_nf; if (out.writable() < 1 + nslots) { return; } const hard_sb *pbytes = in.rd()->bytes; // Output pseudo slot with PLS. plslot *ppls = out.wr(); ppls->is_pls = true; ppls->pls = *pls; out.written(1); // Interleave plslot *pout = out.wr(); if (mcinfo->nsymbols == 4) { serialize_qpsk(pbytes, nslots, pout); } else { int bps = log2(mcinfo->nsymbols); int rows = pls->framebits() / bps; if (mcinfo->nsymbols == 8 && mcinfo->rate == FEC35) { interleave(bps, rows, pbytes, nslots, false, pout); } else { interleave(bps, rows, pbytes, nslots, true, pout); } } in.read(1); out.written(nslots); } } private: // Fill slots with serialized QPSK symbols, MSB first. static void serialize_qpsk(const hard_sb *pin, int nslots, plslot *pout) { #if 0 // For reference hard_sb acc; int nacc = 0; for ( ; nslots; --nslots,++pout ) { pout->is_pls = false; hard_ss *ps = pout->symbols; for ( int ns=pout->LENGTH; ns--; ++ps ) { if ( nacc < 2 ) { acc=*pin++; nacc=8; } *ps = acc>>6; acc <<= 2; nacc -= 2; } } if ( nacc ) fail("Bug: s2_interleaver"); #else if (nslots % 2) { fatal("Bug: Truncated byte"); } for (; nslots; nslots -= 2) { hard_sb b; hard_ss *ps; // Slot 0 (mod 2) pout->is_pls = false; ps = pout->symbols; for (int i = 0; i < 22; ++i) { b = *pin++; *ps++ = (b >> 6); *ps++ = (b >> 4) & 3; *ps++ = (b >> 2) & 3; *ps++ = (b)&3; } b = *pin++; *ps++ = (b >> 6); *ps++ = (b >> 4) & 3; // Slot 1 (mod 2) ++pout; pout->is_pls = false; ps = pout->symbols; *ps++ = (b >> 2) & 3; *ps++ = (b)&3; for (int i = 0; i < 22; ++i) { b = *pin++; *ps++ = (b >> 6); *ps++ = (b >> 4) & 3; *ps++ = (b >> 2) & 3; *ps++ = (b)&3; } ++pout; } #endif } // Fill slots with interleaved symbols. // EN 302 307-1 figures 7 and 8 #if 0 // For reference static void interleave(int bps, int rows, const hard_sb *pin, int nslots, bool msb_first, plslot *pout) { if ( bps==4 && rows==4050 && msb_first ) return interleave4050(pin, nslots, pout); if ( rows % 8 ) fatal("modcod/framesize combination not supported\n"); int stride = rows/8; // Offset to next column, in bytes hard_sb accs[bps]; // One accumulator per column int nacc = 0; // Bits in each column accumulator for ( ; nslots; --nslots,++pout ) { pout->is_pls = false; hard_ss *ps = pout->symbols; for ( int ns=pout->LENGTH; ns--; ++ps ) { if ( ! nacc ) { const hard_sb *pi = pin; for ( int b=0; b>7); accs[b] <<= 1; } else for ( int b=bps; b--; ) { symb = (symb<<1) | (accs[b]>>7); accs[b] <<= 1; } --nacc; *ps = symb; } } if ( nacc ) fail("Bug: s2_interleaver"); } #else // reference static void interleave(int bps, int rows, const hard_sb *pin, int nslots, bool msb_first, plslot *pout) { void (*func)(int rows, const hard_sb *pin, int nslots, plslot *pout) = 0; if (msb_first) { switch (bps) { case 2: func = interleave<1, 2>; break; case 3: func = interleave<1, 3>; break; case 4: func = interleave<1, 4>; break; case 5: func = interleave<1, 5>; break; default: fail("Bad bps"); } } else { switch (bps) { case 2: func = interleave<0, 2>; break; case 3: func = interleave<0, 3>; break; case 4: func = interleave<0, 4>; break; case 5: func = interleave<0, 5>; break; default: fail("Bad bps"); } } (*func)(rows, pin, nslots, pout); } template static void interleave(int rows, const hard_sb *pin, int nslots, plslot *pout) { if (BPS == 4 && rows == 4050 && MSB_FIRST) { return interleave4050(pin, nslots, pout); } if (rows % 8) { fatal("modcod/framesize combination not supported\n"); } int stride = rows / 8; // Offset to next column, in bytes if (nslots % 4) { fatal("Bug: Truncated byte"); } // plslot::symbols[] are not packed across slots, // so we need tos split bytes at boundaries. for (; nslots; nslots -= 4) { hard_sb accs[BPS]; // One accumulator per column hard_ss *ps; // Slot 0 (mod 4): 88+2 pout->is_pls = false; ps = pout->symbols; for (int i = 0; i < 11; ++i) { split_byte(pin++, stride, accs); pop_symbols(accs, &ps, 8); } split_byte(pin++, stride, accs); pop_symbols(accs, &ps, 2); ++pout; // Slot 1 (mod 4): 6+80+4 pout->is_pls = false; ps = pout->symbols; pop_symbols(accs, &ps, 6); for (int i = 0; i < 10; ++i) { split_byte(pin++, stride, accs); pop_symbols(accs, &ps, 8); } split_byte(pin++, stride, accs); pop_symbols(accs, &ps, 4); ++pout; // Slot 2 (mod 4): 4+80+6 pout->is_pls = false; ps = pout->symbols; pop_symbols(accs, &ps, 4); for (int i = 0; i < 10; ++i) { split_byte(pin++, stride, accs); pop_symbols(accs, &ps, 8); } split_byte(pin++, stride, accs); pop_symbols(accs, &ps, 6); ++pout; // Slot 3 (mod 4): 2+88 pout->is_pls = false; ps = pout->symbols; pop_symbols(accs, &ps, 2); for (int i = 0; i < 11; ++i) { split_byte(pin++, stride, accs); pop_symbols(accs, &ps, 8); } ++pout; } } template static inline void split_byte(const hard_sb *pi, int stride, hard_sb accs[BPS]) { // TBD Pass stride as template parameter. for (int b = 0; b < BPS; ++b, pi += stride) { accs[b] = *pi; } } template static void pop_symbols(hard_sb accs[BPS], hard_ss **ps, int ns) { for (int i = 0; i < ns; ++i) { hard_ss symb = 0; // Check unrolling and constant propagation. for (int b = 0; b < BPS; ++b) { if (MSB_FIRST) { symb = (symb << 1) | (accs[b] >> 7); } else { symb = (symb << 1) | (accs[BPS - 1 - b] >> 7); } } for (int b = 0; b < BPS; ++b) { accs[b] <<= 1; } *(*ps)++ = symb; } } #endif // reference // Special case for 16APSK short frames. // 4050 rows is not a multiple of 8. static void interleave4050(const hard_sb *pin, int nslots, plslot *pout) { hard_sb accs[4]; // One accumulator per column int nacc = 0; // Bits in each column accumulator for (; nslots; --nslots, ++pout) { pout->is_pls = false; hard_ss *ps = pout->symbols; for (int ns = pout->LENGTH; ns--; ++ps) { if (!nacc) { if (nslots == 1 && ns == 1) { // Special case just to avoid reading beyond end of buffer accs[0] = pin[0]; accs[1] = (pin[506] << 2) | (pin[507] >> 6); accs[2] = (pin[1012] << 4) | (pin[1013] >> 4); accs[3] = (pin[1518] << 6); } else { accs[0] = pin[0]; accs[1] = (pin[506] << 2) | (pin[507] >> 6); accs[2] = (pin[1012] << 4) | (pin[1013] >> 4); accs[3] = (pin[1518] << 6) | (pin[1519] >> 2); } ++pin; nacc = 8; } hard_ss symb = 0; for (int b = 0; b < 4; ++b) { symb = (symb << 1) | (accs[b] >> 7); accs[b] <<= 1; } --nacc; *ps = symb; } } } pipereader> in; pipewriter> out; }; // s2_interleaver // S2 DEINTERLEAVER // EN 302 307-1 section 5.3.3 Bit Interleaver template struct s2_deinterleaver : runnable { s2_deinterleaver( scheduler *sch, pipebuf> &_in, pipebuf> &_out ) : runnable(sch, "S2 deinterleaver"), in(_in), out(_out) { } void run() { while (in.readable() >= 1 && out.writable() >= 1) { plslot *pin = in.rd(); if (!pin->is_pls) { fail("s2_deinterleaver: bad input sequence"); } s2_pls *pls = &pin->pls; const modcod_info *mcinfo = check_modcod(pls->modcod); int nslots = pls->sf ? mcinfo->nslots_nf / 4 : mcinfo->nslots_nf; if (in.readable() < 1 + nslots) { return; } fecframe *pout = out.wr(); pout->pls = *pls; SOFTBYTE *pbytes = pout->bytes; if (mcinfo->nsymbols == 4) { deserialize_qpsk(pin + 1, nslots, pbytes); } else { int bps = log2(mcinfo->nsymbols); int rows = pls->framebits() / bps; if ((mcinfo->nsymbols == 8) && (mcinfo->rate == FEC35)) { deinterleave(bps, rows, pin + 1, nslots, false, pbytes); } else { deinterleave(bps, rows, pin + 1, nslots, true, pbytes); } } in.read(1 + nslots); out.written(1); } } private: // Deserialize slots of QPSK symbols, MSB first. static void deserialize_qpsk(plslot *pin, int nslots, SOFTBYTE *pout) { SOFTBYTE acc; softword_clear(&acc); // gcc warning int nacc = 0; for (; nslots; --nslots, ++pin) { SOFTSYMB *ps = pin->symbols; for (int ns = pin->LENGTH; ns--; ++ps) { pack_qpsk_symbol(*ps, &acc, nacc); nacc += 2; if (nacc == 8) { // TBD unroll *pout++ = acc; nacc = 0; } } } } // Deinterleave slots of symbols. // EN 302 307-1 figures 7 and 8 #if 0 // For reference static void deinterleave(int bps, int rows, const plslot *pin, int nslots, bool msb_first, SOFTBYTE *pout) { if ( bps==4 && rows==4050 && msb_first ) return deinterleave4050(pin, nslots, pout); if ( rows % 8 ) fatal("modcod/framesize combination not supported\n"); int stride = rows/8; // Offset to next column, in bytes SOFTBYTE accs[bps]; for ( int b=0; bsymbols; for ( int ns=pin->LENGTH; ns--; ++ps ) { split_symbol(*ps, bps, accs, nacc, msb_first); ++nacc; if ( nacc == 8 ) { SOFTBYTE *po = pout; for ( int b=0; b *pin, int nslots, bool msb_first, SOFTBYTE *pout) { void (*func)(int rows, const plslot *pin, int nslots, SOFTBYTE *pout) = 0; if (msb_first) { switch (bps) { case 2: func = deinterleave<1, 2>; break; case 3: func = deinterleave<1, 3>; break; case 4: func = deinterleave<1, 4>; break; case 5: func = deinterleave<1, 5>; break; default: fail("Bad bps"); } } else { switch (bps) { case 2: func = deinterleave<0, 2>; break; case 3: func = deinterleave<0, 3>; break; case 4: func = deinterleave<0, 4>; break; case 5: func = deinterleave<0, 5>; break; default: fail("Bad bps"); } } (*func)(rows, pin, nslots, pout); } template static void deinterleave(int rows, const plslot *pin, int nslots, SOFTBYTE *pout) { if (BPS == 4 && rows == 4050 && MSB_FIRST) { return deinterleave4050(pin, nslots, pout); } if (rows % 8) { fatal("modcod/framesize combination not supported\n"); } int stride = rows / 8; // Offset to next column, in bytes SOFTBYTE accs[BPS]; for (int b = 0; b < BPS; ++b) { softword_clear(&accs[b]); // gcc warning } int nacc = 0; for (; nslots; --nslots, ++pin) { const SOFTSYMB *ps = pin->symbols; for (int ns = pin->LENGTH; ns--; ++ps) { split_symbol(*ps, BPS, accs, nacc, MSB_FIRST); ++nacc; if (nacc == 8) { // TBD Unroll, same as interleave() SOFTBYTE *po = pout; // TBD Pass stride as template parameter. for (int b = 0; b < BPS; ++b, po += stride) { *po = accs[b]; } ++pout; nacc = 0; } } } if (nacc) { fail("Bug: s2_deinterleaver"); } } #endif // reference // Special case for 16APSK short frames. // 4050 rows is not a multiple of 8 // so we process rows one at a time rather than in chunks of 8. static void deinterleave4050(const plslot *pin, int nslots, SOFTBYTE *pout) { const int rows = 4050; SOFTBYTE accs[4]; for (int b = 0; b < 4; ++b) { softword_clear(&accs[b]); // gcc warning } int nacc = 0; for (; nslots; --nslots, ++pin) { const SOFTSYMB *ps = pin->symbols; for (int ns = pin->LENGTH; ns--; ++ps) { split_symbol(*ps, 4, accs, nacc, true); ++nacc; if (nacc == 8) { for (int b = 0; b < 8; ++b) { softwords_set(pout, rows * 0 + b, softword_get(accs[0], b)); softwords_set(pout, rows * 1 + b, softword_get(accs[1], b)); softwords_set(pout, rows * 2 + b, softword_get(accs[2], b)); softwords_set(pout, rows * 3 + b, softword_get(accs[3], b)); } ++pout; nacc = 0; } } } if (nacc != 2) { fatal("Bug: Expected 2 leftover rows\n"); } // Pad with random symbol so that we can use accs[]. for (int b = nacc; b < 8; ++b) { split_symbol(pin->symbols[0], 4, accs, b, true); } for (int b = 0; b < nacc; ++b) { softwords_set(pout, rows * 0 + b, softword_get(accs[0], b)); softwords_set(pout, rows * 1 + b, softword_get(accs[1], b)); softwords_set(pout, rows * 2 + b, softword_get(accs[2], b)); softwords_set(pout, rows * 3 + b, softword_get(accs[3], b)); } } // Spread LLR symbol across hard columns. // Must call 8 times before using result because we use bit shifts. static inline void split_symbol(const llr_ss &ps, int bps, hard_sb accs[/*bps*/], int nacc, bool msb_first) { (void) nacc; if (msb_first) { for (int b = 0; b < bps; ++b) { accs[b] = (accs[b] << 1) | llr_harden(ps.bits[bps - 1 - b]); } } else { for (int b = 0; b < bps; ++b) { accs[b] = (accs[b] << 1) | llr_harden(ps.bits[b]); } } } // Fast variant template static inline void split_symbol(const llr_ss &ps, hard_sb accs[/*bps*/], int nacc) { if (MSB_FIRST) { for (int b = 0; b < BPS; ++b) { accs[b] = (accs[b] << 1) | llr_harden(ps.bits[BPS - 1 - b]); } } else { for (int b = 0; b < BPS; ++b) { accs[b] = (accs[b] << 1) | llr_harden(ps.bits[b]); } } } // Spread LLR symbol across LLR columns. static inline void split_symbol( const llr_ss &ps, int bps, llr_sb accs[/*bps*/], int nacc, bool msb_first ) { if (msb_first) { for (int b = 0; b < bps; ++b) { accs[b].bits[nacc] = ps.bits[bps - 1 - b]; } } else { for (int b = 0; b < bps; ++b) { accs[b].bits[nacc] = ps.bits[b]; } } } // Fast variant template static inline void split_symbol( const llr_ss &ps, llr_sb accs[/*bps*/], int nacc) { if (MSB_FIRST) { for (int b = 0; b < BPS; ++b) { accs[b].bits[nacc] = ps.bits[BPS - 1 - b]; } } else { for (int b = 0; b < BPS; ++b) { accs[b].bits[nacc] = ps.bits[b]; } } } // Merge QPSK LLR symbol into hard byte. static inline void pack_qpsk_symbol( const llr_ss &ps, hard_sb *acc, int nacc ) { (void) nacc; // TBD Must match LLR law, see softsymb_harden. uint8_t s = llr_harden(ps.bits[0]) | (llr_harden(ps.bits[1]) << 1); *acc = (*acc << 2) | s; } // Merge QPSK LLR symbol into LLR byte. static inline void pack_qpsk_symbol( const llr_ss &ps, llr_sb *acc, int nacc ) { acc->bits[nacc] = ps.bits[1]; acc->bits[nacc + 1] = ps.bits[0]; } pipereader> in; pipewriter> out; }; // s2_deinterleaver typedef ldpc_table s2_ldpc_table; typedef ldpc_engine s2_ldpc_engine; #include "dvbs2_data.h" static const struct fec_info { static const int KBCH_MAX = 58192; int Kbch; // BCH message size (bits) int kldpc; // LDPC message size (= BCH codeword size) (bits) int t; // BCH error correction const s2_ldpc_table *ldpc; } fec_infos[2][FEC_COUNT] = { { // Normal frames - must respect enum code_rate order {32208, 32400, 12, &ldpc_nf_fec12}, // FEC12 (was [FEC12] = {...} and so on. Does not compile with MSVC) {43040, 43200, 10, &ldpc_nf_fec23}, // FEC23 {0, 0, 0, nullptr}, // FEC46 {48408, 48600, 12, &ldpc_nf_fec34}, // FEC34 {53840, 54000, 10, &ldpc_nf_fec56}, // FEC56 {0, 0, 0, nullptr}, // FEC78 {51648, 51840, 12, &ldpc_nf_fec45}, // FEC45 {57472, 57600, 8, &ldpc_nf_fec89}, // FEC89 {58192, 58320, 8, &ldpc_nf_fec910}, // FEC910 {16008, 16200, 12, &ldpc_nf_fec14}, // FEC14 {21408, 21600, 12, &ldpc_nf_fec13}, // FEC13 {25728, 25920, 12, &ldpc_nf_fec25}, // FEC25 {38688, 38880, 12, &ldpc_nf_fec35}, // FEC35 }, { // Short frames - must respect enum code_rate order {7032, 7200, 12, &ldpc_sf_fec12}, // FEC12 (was [FEC12] = {...} and so on. Does not compile with MSVC) {10632, 10800, 12, &ldpc_sf_fec23}, // FEC23 {0, 0, 0, nullptr}, // FEC46 {11712, 11880, 12, &ldpc_sf_fec34}, // FEC34 {13152, 13320, 12, &ldpc_sf_fec56}, // FEC56 {0, 0, 0, nullptr}, // FEC78 {12432, 12600, 12, &ldpc_sf_fec45}, // FEC45 {14232, 14400, 12, &ldpc_sf_fec89}, // FEC89 {0, 0, 0, nullptr}, // FEC910 {3072, 3240, 12, &ldpc_sf_fec14}, // FEC14 {5232, 5400, 12, &ldpc_sf_fec13}, // FEC13 {6312, 6480, 12, &ldpc_sf_fec25}, // FEC25 {9552, 9720, 12, &ldpc_sf_fec35}, // FEC35 }, }; struct bbframe { s2_pls pls; uint8_t bytes[58192 / 8]; // Kbch/8 max }; // S2_LDPC_ENGINES // Initializes LDPC engines for all DVB-S2 FEC settings. template struct s2_ldpc_engines { typedef ldpc_engine s2_ldpc_engine; s2_ldpc_engine *ldpcs[2][FEC_COUNT]; // [shortframes][fec] s2_ldpc_engines() { // memset(ldpcs, 0, sizeof(ldpcs)); // useless as initialization comes next for (int sf = 0; sf <= 1; ++sf) { for (int fec = 0; fec < FEC_COUNT; ++fec) { const fec_info *fi = &fec_infos[sf][fec]; if (!fi->ldpc) { ldpcs[sf][fec] = nullptr; } else { int n = (sf ? 64800 / 4 : 64800); int k = fi->kldpc; ldpcs[sf][fec] = new s2_ldpc_engine(fi->ldpc, k, n); } } } } ~s2_ldpc_engines() { for (int sf = 0; sf <= 1; ++sf) { for (int fec = 0; fec < FEC_COUNT; ++fec) { if (ldpcs[sf][fec]) { delete ldpcs[sf][fec]; } } } } void print_node_stats() { for (int sf = 0; sf <= 1; ++sf) { for (int fec = 0; fec < FEC_COUNT; ++fec) { s2_ldpc_engine *ldpc = ldpcs[sf][fec]; if (ldpc) { ldpc->print_node_stats(); } } } } }; // s2_ldpc_engines // S2_BCH_ENGINES // Initializes BCH engines for all DVB-S2 FEC settings. struct s2_bch_engines { bch_interface *bchs[2][FEC_COUNT]; // N=t*m // The generator of GF(2^m) is always g1. // Normal frames with 8, 10 or 12 polynomials. typedef bch_engine s2_bch_engine_nf12; typedef bch_engine s2_bch_engine_nf10; typedef bch_engine s2_bch_engine_nf8; // Short frames with 12 polynomials. typedef bch_engine s2_bch_engine_sf12; s2_bch_engines() { bitvect bch_polys[2][12]; // [shortframes][polyindex] // EN 302 307-1 5.3.1 Table 6a (polynomials for normal frames) bch_polys[0][0] = bitvect(0x1002d); // g1 bch_polys[0][1] = bitvect(0x10173); // g2 bch_polys[0][2] = bitvect(0x10fbd); // g3 bch_polys[0][3] = bitvect(0x15a55); // g4 bch_polys[0][4] = bitvect(0x11f2f); // g5 bch_polys[0][5] = bitvect(0x1f7b5); // g6 bch_polys[0][6] = bitvect(0x1af65); // g7 bch_polys[0][7] = bitvect(0x17367); // g8 bch_polys[0][8] = bitvect(0x10ea1); // g9 bch_polys[0][9] = bitvect(0x175a7); // g10 bch_polys[0][10] = bitvect(0x13a2d); // g11 bch_polys[0][11] = bitvect(0x11ae3); // g12 // EN 302 307-1 5.3.1 Table 6b (polynomials for short frames) bch_polys[1][0] = bitvect(0x402b); // g1 bch_polys[1][1] = bitvect(0x4941); // g2 bch_polys[1][2] = bitvect(0x4647); // g3 bch_polys[1][3] = bitvect(0x5591); // g4 bch_polys[1][4] = bitvect(0x6b55); // g5 bch_polys[1][5] = bitvect(0x6389); // g6 bch_polys[1][6] = bitvect(0x6ce5); // g7 bch_polys[1][7] = bitvect(0x4f21); // g8 bch_polys[1][8] = bitvect(0x460f); // g9 bch_polys[1][9] = bitvect(0x5a49); // g10 bch_polys[1][10] = bitvect(0x5811); // g11 bch_polys[1][11] = bitvect(0x65ef); // g12 // Redundant with fec_infos[], but needs static template argument. for (int sf = 0; sf <= 1; ++sf) { for (int fec = 0; fec < FEC_COUNT; ++fec) { bchs[sf][fec] = nullptr; } } bchs[0][FEC12] = new s2_bch_engine_nf12(bch_polys[0], 12); bchs[0][FEC23] = new s2_bch_engine_nf10(bch_polys[0], 10); bchs[0][FEC34] = new s2_bch_engine_nf12(bch_polys[0], 12); bchs[0][FEC56] = new s2_bch_engine_nf10(bch_polys[0], 10); bchs[0][FEC45] = new s2_bch_engine_nf12(bch_polys[0], 12); bchs[0][FEC89] = new s2_bch_engine_nf8(bch_polys[0], 8); bchs[0][FEC910] = new s2_bch_engine_nf8(bch_polys[0], 8); bchs[0][FEC14] = new s2_bch_engine_nf12(bch_polys[0], 12); bchs[0][FEC13] = new s2_bch_engine_nf12(bch_polys[0], 12); bchs[0][FEC25] = new s2_bch_engine_nf12(bch_polys[0], 12); bchs[0][FEC35] = new s2_bch_engine_nf12(bch_polys[0], 12); bchs[1][FEC12] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC23] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC34] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC56] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC45] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC89] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC14] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC13] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC25] = new s2_bch_engine_sf12(bch_polys[1], 12); bchs[1][FEC35] = new s2_bch_engine_sf12(bch_polys[1], 12); } ~s2_bch_engines() { for (int sf = 0; sf <= 1; ++sf) { for (int fec = 0; fec < FEC_COUNT; ++fec) { if (bchs[sf][fec]) { delete bchs[sf][fec]; } } } } }; // s2_bch_engines // S2 BASEBAND DESCRAMBLER AND FEC ENCODER // EN 302 307-1 section 5.2.2 // EN 302 307-1 section 5.3 struct s2_fecenc : runnable { typedef ldpc_engine s2_ldpc_engine; s2_fecenc( scheduler *sch, pipebuf &_in, pipebuf> &_out ) : runnable(sch, "S2 fecenc"), in(_in), out(_out) { if (sch->debug) { s2ldpc.print_node_stats(); } } void run() { while (in.readable() >= 1 && out.writable() >= 1) { run_frame(in.rd(), out.wr()); in.read(1); out.written(1); } } private: void run_frame(const bbframe *pin, fecframe *pout) { const modcod_info *mcinfo = check_modcod(pin->pls.modcod); const fec_info *fi = &fec_infos[pin->pls.sf][mcinfo->rate]; pout->pls = pin->pls; hard_sb *pbytes = pout->bytes; bbscrambling.transform(pin->bytes, fi->Kbch / 8, pbytes); { // BCH size_t msgbytes = fi->Kbch / 8; bch_interface *bch = s2bch.bchs[pin->pls.sf][mcinfo->rate]; bch->encode(pbytes, msgbytes, pbytes + msgbytes); } { // LDPC size_t msgbits = fi->kldpc; size_t cwbits = pin->pls.framebits(); s2_ldpc_engine *ldpc = s2ldpc.ldpcs[pin->pls.sf][mcinfo->rate]; ldpc->encode(fi->ldpc, pbytes, msgbits, cwbits, pbytes + msgbits / 8); } } pipereader in; pipewriter> out; s2_bbscrambling bbscrambling; s2_bch_engines s2bch; s2_ldpc_engines s2ldpc; }; // s2_fecenc // S2 FEC DECODER AND BASEBAND DESCRAMBLER // EN 302 307-1 section 5.3 // EN 302 307-1 section 5.2.2 template struct s2_fecdec : runnable { int bitflips; s2_fecdec( scheduler *sch, pipebuf> &_in, pipebuf &_out, pipebuf *_bitcount = nullptr, pipebuf *_errcount = nullptr ) : runnable(sch, "S2 fecdec"), bitflips(0), in(_in), out(_out), bitcount(opt_writer(_bitcount, 1)), errcount(opt_writer(_errcount, 1)) { if (sch->debug) { s2ldpc.print_node_stats(); } } void run() { while (in.readable() >= 1 && out.writable() >= 1 && opt_writable(bitcount, 1) && opt_writable(errcount, 1)) { fecframe *pin = in.rd(); const modcod_info *mcinfo = check_modcod(pin->pls.modcod); const fec_info *fi = &fec_infos[pin->pls.sf][mcinfo->rate]; bool corrupted = false; bool residual_errors; if (true) { // LDPC decode size_t cwbits = pin->pls.framebits(); size_t msgbits = fi->kldpc; s2_ldpc_engine *ldpc = s2ldpc.ldpcs[pin->pls.sf][mcinfo->rate]; int ncorr = ldpc->decode_bitflip(fi->ldpc, pin->bytes, msgbits, cwbits, bitflips); if (sch->debug2) { fprintf(stderr, "LDPCCORR = %d\n", ncorr); } } uint8_t *hardbytes = softbytes_harden(pin->bytes, fi->kldpc / 8, bch_buf); if (true) { // BCH decode size_t cwbytes = fi->kldpc / 8; // Decode with suitable BCH decoder for this MODCOD bch_interface *bch = s2bch.bchs[pin->pls.sf][mcinfo->rate]; int ncorr = bch->decode(hardbytes, cwbytes); if (sch->debug2) { fprintf(stderr, "BCHCORR = %d\n", ncorr); } corrupted = (ncorr < 0); residual_errors = (ncorr != 0); // Report VER opt_write(bitcount, fi->Kbch); opt_write(errcount, (ncorr >= 0) ? ncorr : fi->Kbch); } int bbsize = fi->Kbch / 8; // TBD Some decoders want the bad packets. #if 0 if ( corrupted ) { fprintf(stderr, "Passing bad frame\n"); corrupted = false; } #endif if (!corrupted) { // Descramble and output bbframe *pout = out.wr(); pout->pls = pin->pls; bbscrambling.transform(hardbytes, bbsize, pout->bytes); out.written(1); } if (sch->debug) { fprintf(stderr, "%c", corrupted ? ':' : residual_errors ? '.' : '_'); } in.read(1); } } private: s2_ldpc_engines s2ldpc; uint8_t bch_buf[64800 / 8]; // Temp storage for hardening before BCH s2_bch_engines s2bch; s2_bbscrambling bbscrambling; pipereader> in; pipewriter out; pipewriter *bitcount, *errcount; }; // s2_fecdec #ifdef LINUX // Soft LDPC decoder // Internally implemented LDPC tool. Replaces external LDPC decoder template struct s2_fecdec_soft : runnable { s2_fecdec_soft( scheduler *sch, pipebuf> &_in, pipebuf &_out, int _modcod, bool _shortframes = true, int _max_trials = 25, pipebuf *_bitcount = nullptr, pipebuf *_errcount = nullptr ) : runnable(sch, "S2 fecdec soft"), in(_in), out(_out), modcod(_modcod < 0 ? 0 : _modcod > 31 ? 31 : _modcod), shortframes(_shortframes ? 1 : 0), max_trials(_max_trials), bitcount(opt_writer(_bitcount, 1)), errcount(opt_writer(_errcount, 1)) { const char *tabname = ldpctool::LDPCInterface::mc_tabnames[shortframes][modcod]; fprintf(stderr, "s2_fecdec_soft::s2_fecdec_soft: tabname: %s\n", tabname); if (tabname) { ldpc = ldpctool::create_ldpc((char *)"S2", tabname[0], atoi(tabname + 1)); code = new ldpctool::code_type[ldpc->code_len()]; aligned_buffer = aligned_alloc(sizeof(ldpctool::simd_type), sizeof(ldpctool::simd_type) * ldpc->code_len()); simd = reinterpret_cast(aligned_buffer); } else { ldpc = nullptr; aligned_buffer = nullptr; code = nullptr; } } ~s2_fecdec_soft() { if (ldpc) { delete ldpc; } if (aligned_buffer) { free(aligned_buffer); } if (code) { delete[] code; } } void run() { while (in.readable() >= 1 && out.writable() >= 1 && opt_writable(bitcount, 1) && opt_writable(errcount, 1)) { fecframe *pin = in.rd(); const modcod_info *mcinfo = check_modcod(pin->pls.modcod); const fec_info *fi = &fec_infos[pin->pls.sf][mcinfo->rate]; bool corrupted = false; bool residual_errors; if (ldpc) { decode.init(ldpc); int count = decode(simd, simd + ldpc->data_len(), max_trials, 1); if (count < 0) { fprintf(stderr, "s2_fecdec_soft::run: decoder failed at converging to a code word in %d trials\n", max_trials); } for (int i = 0; i < ldpc->code_len(); ++i) { code[i] = reinterpret_cast(simd + i)[0]; } SOFTBYTE *ldpc_buf = reinterpret_cast(code); uint8_t *hardbytes = softbytes_harden(ldpc_buf, fi->kldpc / 8, bch_buf); // BCH decode size_t cwbytes = fi->kldpc / 8; // Decode with suitable BCH decoder for this MODCOD bch_interface *bch = s2bch.bchs[pin->pls.sf][mcinfo->rate]; int ncorr = bch->decode(hardbytes, cwbytes); if (sch->debug2) { fprintf(stderr, "BCHCORR = %d\n", ncorr); } corrupted = (ncorr < 0); residual_errors = (ncorr != 0); // Report VER opt_write(bitcount, fi->Kbch); opt_write(errcount, (ncorr >= 0) ? ncorr : fi->Kbch); int bbsize = fi->Kbch / 8; if (!corrupted) { // Descramble and output bbframe *pout = out.wr(); pout->pls = pin->pls; bbscrambling.transform(hardbytes, bbsize, pout->bytes); out.written(1); } if (sch->debug) { fprintf(stderr, "%c", corrupted ? ':' : residual_errors ? '.' : '_'); } } // ldpc engine allocated in.read(1); } } private: pipereader> in; pipewriter out; int modcod; int shortframes; int max_trials; pipewriter *bitcount, *errcount; typedef ldpctool::NormalUpdate update_type; //typedef SelfCorrectedUpdate update_type; //typedef MinSumAlgorithm algorithm_type; //typedef OffsetMinSumAlgorithm algorithm_type; typedef ldpctool::MinSumCAlgorithm algorithm_type; //typedef LogDomainSPA algorithm_type; //typedef LambdaMinAlgorithm algorithm_type; //typedef SumProductAlgorithm algorithm_type; ldpctool::LDPCDecoder decode; ldpctool::LDPCInterface *ldpc; ldpctool::code_type *code; void *aligned_buffer; ldpctool::simd_type *simd; uint8_t bch_buf[64800 / 8]; // Temp storage for hardening before BCH s2_bch_engines s2bch; s2_bbscrambling bbscrambling; }; // s2_fecdec_soft // External LDPC decoder // Spawns a user-specified command, FEC frames on stdin/stdout. template struct simplequeue { static const int SIZE = _SIZE; simplequeue() { rd = wr = count = 0; } bool full() { return count == SIZE; } T *put() { T *res = &q[wr]; wr = (wr + 1) % SIZE; ++count; return res; } bool empty() { return count == 0; } const T *peek() { return &q[rd]; } const T *get() { const T *res = &q[rd]; rd = (rd + 1) % SIZE; --count; return res; } private: int rd, wr, count; T q[SIZE]; }; template struct s2_fecdec_helper : runnable { int batch_size; int nhelpers; bool must_buffer; int max_trials; s2_fecdec_helper( scheduler *sch, pipebuf> &_in, pipebuf &_out, const char *_command, pipebuf *_bitcount = nullptr, pipebuf *_errcount = nullptr ) : runnable(sch, "S2 fecdec io"), batch_size(16), nhelpers(1), must_buffer(false), max_trials(8), in(_in), out(_out), bitcount(opt_writer(_bitcount, 1)), errcount(opt_writer(_errcount, 1)) { command = strdup(_command); for (int mc = 0; mc < 32; ++mc) { for (int sf = 0; sf < 2; ++sf) { pools[mc][sf].procs = nullptr; } } } ~s2_fecdec_helper() { free(command); killall(); // also deletes pools[mc][sf].procs if necessary } void run() { // Send work until all helpers block. while (in.readable() >= 1 && !jobs.full()) { if ((bbframe_q.size() != 0) && (out.writable() >= 1)) { bbframe *pout = out.wr(); pout->pls = bbframe_q.front().pls; std::copy(bbframe_q.front().bytes, bbframe_q.front().bytes + (58192 / 8), pout->bytes); bbframe_q.pop_front(); out.written(1); } if ((bitcount_q.size() != 0) && opt_writable(bitcount, 1)) { opt_write(bitcount, bitcount_q.front()); bitcount_q.pop_front(); } if ((errcount_q.size() != 0) && opt_writable(errcount, 1)) { opt_write(errcount, errcount_q.front()); errcount_q.pop_front(); } if (!jobs.empty() && jobs.peek()->h->b_out) { receive_frame(jobs.get()); } send_frame(in.rd()); in.read(1); } } private: struct helper_instance { int fd_tx; // To helper int fd_rx; // From helper int batch_size; // Latency int b_in; // Jobs in input queue int b_out; // Jobs in output queue int pid; // PID of the child }; struct pool { helper_instance *procs; // nullptr or [nprocs] int nprocs; int shift; } pools[32][2]; // [modcod][sf] struct helper_job { s2_pls pls; helper_instance *h; }; simplequeue jobs; // Try to send a frame. Return false if helper was busy. bool send_frame(fecframe *pin) { pool *p = get_pool(&pin->pls); for (int j = 0; j < p->nprocs; ++j) { int i = (p->shift + j) % p->nprocs; helper_instance *h = &p->procs[i]; int iosize = (pin->pls.framebits() / 8) * sizeof(SOFTBYTE); // fprintf(stderr, "Writing %lu to fd %d\n", iosize, h->fd_tx); int nw = write(h->fd_tx, pin->bytes, iosize); if (nw < 0 && errno == EWOULDBLOCK) { //lseek(h->fd_tx, 0, SEEK_SET); // allow new writes on this worker //fprintf(stderr, "s2_fecdec_helper::send_frame: %d worker is busy\n", h->pid); continue; // next worker } if (nw < 0) { fatal("write(LDPC helper"); } else if (nw != iosize) { fatal("partial write(LDPC helper)"); } p->shift = i; helper_job *job = jobs.put(); job->pls = pin->pls; job->h = h; ++h->b_in; if (h->b_in >= h->batch_size) { h->b_in -= h->batch_size; h->b_out += h->batch_size; } return true; // done sent to worker } fprintf(stderr, "s2_fecdec_helper::send_frame: WARNING: all %d workers were busy: modcod=%d sf=%d)\n", p->nprocs, pin->pls.modcod, pin->pls.sf); return false; // all workers were busy } // Return a pool of running helpers for a given modcod. pool *get_pool(const s2_pls *pls) { pool *p = &pools[pls->modcod][pls->sf]; if (!p->procs) { fprintf(stderr, "s2_fecdec_helper::get_pool: allocate %d workers: modcod=%d sf=%d\n", nhelpers, pls->modcod, pls->sf); p->procs = new helper_instance[nhelpers]; for (int i = 0; i < nhelpers; ++i) { spawn_helper(&p->procs[i], pls); } p->nprocs = nhelpers; p->shift = 0; } return p; } void killall() { fprintf(stderr, "s2_fecdec_helper::killall\n"); for (int i = 0; i < 32; i++) // all MODCODs { for (int j = 0; j < 2; j++) // long and short frames { pool *p = &pools[i][j]; if (p->procs) { for (int i = 0; i < p->nprocs; ++i) { helper_instance *h = &p->procs[i]; fprintf(stderr, "s2_fecdec_helper::killall: killing %d\n", h->pid); int rc = kill(h->pid, SIGKILL); if (rc < 0) { fatal("s2_fecdec_helper::killall"); } else { int cs; waitpid(h->pid, &cs, 0); } // close pipes close(h->fd_tx); close(h->fd_rx); } delete p->procs; p->procs = nullptr; p->nprocs = 0; } } // long and short frames } // all MODCODs } // Spawn a helper process. void spawn_helper(helper_instance *h, const s2_pls *pls) { if (sch->debug) { fprintf(stderr, "Spawning LDPC helper: modcod=%d sf=%d\n", pls->modcod, pls->sf); } int tx[2], rx[2]; if (pipe(tx) || pipe(rx)) { fatal("pipe"); } // Size the pipes so that the helper never runs out of work to do. int pipesize = 64800 * batch_size; // macOS does not have F_SETPIPE_SZ and there // is no way to change the buffer size #ifndef __APPLE__ long min_pipe_size = (long) fcntl(tx[0], F_GETPIPE_SZ); long pipe_size = (long) fcntl(rx[0], F_GETPIPE_SZ); min_pipe_size = std::min(min_pipe_size, pipe_size); pipe_size = (long) fcntl(tx[1], F_GETPIPE_SZ); min_pipe_size = std::min(min_pipe_size, pipe_size); pipe_size = (long) fcntl(rx[1], F_GETPIPE_SZ); min_pipe_size = std::min(min_pipe_size, pipe_size); if (min_pipe_size < pipesize) { if (fcntl(tx[0], F_SETPIPE_SZ, pipesize) < 0 || fcntl(rx[0], F_SETPIPE_SZ, pipesize) < 0 || fcntl(tx[1], F_SETPIPE_SZ, pipesize) < 0 || fcntl(rx[1], F_SETPIPE_SZ, pipesize) < 0) { fprintf(stderr, "*** Failed to increase pipe size from %ld.\n" "*** Try echo %d > /proc/sys/fs/pipe-max-size\n", min_pipe_size, pipesize); if (must_buffer) { fatal("F_SETPIPE_SZ"); } else { fprintf(stderr, "*** Throughput will be suboptimal.\n"); } } } #endif // vfork() differs from fork(2) in that the calling thread is // suspended until the child terminates int child = fork(); if (!child) { // Child process close(tx[1]); dup2(tx[0], 0); close(rx[0]); dup2(rx[1], 1); char max_trials_arg[16]; sprintf(max_trials_arg, "%d", max_trials); char batch_size_arg[16]; sprintf(batch_size_arg, "%d", batch_size); char mc_arg[16]; sprintf(mc_arg, "%d", pls->modcod); const char *sf_arg = pls->sf ? "--shortframes" : nullptr; const char *argv[] = { command, "--trials", max_trials_arg, "--batch-size", batch_size_arg, "--modcod", mc_arg, sf_arg, nullptr }; execve(command, (char *const *)argv, nullptr); fatal(command); } h->pid = child; h->fd_tx = tx[1]; close(tx[0]); h->fd_rx = rx[0]; close(rx[1]); h->batch_size = batch_size; // TBD h->b_in = h->b_out = 0; int flags_tx = fcntl(h->fd_tx, F_GETFL); if (fcntl(h->fd_tx, F_SETFL, flags_tx | O_NONBLOCK)) { fatal("fcntl_tx(helper)"); } int flags_rx = fcntl(h->fd_rx, F_GETFL); if (fcntl(h->fd_rx, F_SETFL, flags_rx | O_NONBLOCK)) { fatal("fcntl_rx(helper)"); } } // Receive a finished job. void receive_frame(const helper_job *job) { // Read corrected frame from helper const s2_pls *pls = &job->pls; int iosize = (pls->framebits() / 8) * sizeof(ldpc_buf[0]); int nr = read(job->h->fd_rx, ldpc_buf, iosize); if (nr < 0) { if (errno != EAGAIN) { // if no data then try again next time fatal("s2_fecdec_helper::receive_frame read error"); } } else if (nr != iosize) { fprintf(stderr, "s2_fecdec_helper::receive_frame: %d bytes read vs %d\n", nr, iosize); } --job->h->b_out; // Decode BCH. const modcod_info *mcinfo = check_modcod(job->pls.modcod); const fec_info *fi = &fec_infos[job->pls.sf][mcinfo->rate]; uint8_t *hardbytes = softbytes_harden(ldpc_buf, fi->kldpc / 8, bch_buf); size_t cwbytes = fi->kldpc / 8; //size_t msgbytes = fi->Kbch / 8; //size_t chkbytes = cwbytes - msgbytes; bch_interface *bch = s2bch.bchs[job->pls.sf][mcinfo->rate]; int ncorr = bch->decode(hardbytes, cwbytes); if (sch->debug2) { fprintf(stderr, "BCHCORR = %d\n", ncorr); } bool corrupted = (ncorr < 0); // Report VBER bitcount_q.push_back(fi->Kbch); //opt_write(bitcount, fi->Kbch); errcount_q.push_front((ncorr >= 0) ? ncorr : fi->Kbch); //opt_write(errcount, (ncorr >= 0) ? ncorr : fi->Kbch); #if 0 // TBD Some decoders want the bad packets. if ( corrupted ) { fprintf(stderr, "Passing bad frame\n"); corrupted = false; } #endif if (!corrupted) { // Descramble and output bbframe_q.emplace_back(); //bbframe *pout = out.wr(); bbframe_q.back().pls = job->pls; bbscrambling.transform(hardbytes, fi->Kbch / 8, bbframe_q.back().bytes); //out.written(1); } if (sch->debug) { fprintf(stderr, "%c", corrupted ? '!' : ncorr ? '.' : '_'); } } pipereader> in; pipewriter out; char *command; SOFTBYTE ldpc_buf[64800 / 8]; uint8_t bch_buf[64800 / 8]; // Temp storage for hardening before BCH s2_bch_engines s2bch; s2_bbscrambling bbscrambling; std::deque bbframe_q; std::deque bitcount_q; std::deque errcount_q; pipewriter *bitcount, *errcount; }; // s2_fecdec_helper #endif // S2 FRAMER // EN 302 307-1 section 5.1 Mode adaptation struct s2_framer : runnable { uint8_t rolloff_code; // 0=0.35, 1=0.25, 2=0.20, 3=reserved // User must provide pls_seq[n_pls_seq]. // For ACM, user can change pls_seq[0] at runtime. // For VCM with a repeating pattern, use n_pls_seq>=2. s2_pls *pls_seq; int n_pls_seq; s2_framer( scheduler *sch, pipebuf &_in, pipebuf &_out ) : runnable(sch, "S2 framer"), n_pls_seq(0), pls_index(0), in(_in), out(_out) { nremain = 0; remcrc = 0; // CRC for nonexistent previous packet } void run() { while (out.writable() >= 1) { if (!n_pls_seq ) { fail("PLS not specified"); } s2_pls *pls = &pls_seq[pls_index]; const modcod_info *mcinfo = check_modcod(pls->modcod); const fec_info *fi = &fec_infos[pls->sf][mcinfo->rate]; int framebytes = fi->Kbch / 8; if (!framebytes) { fail("MODCOD/framesize combination not allowed"); } if (10 + nremain + 188 * in.readable() < framebytes) { break; // Not enough data to fill a frame } bbframe *pout = out.wr(); pout->pls = *pls; uint8_t *buf = pout->bytes; uint8_t *end = buf + framebytes; // EN 302 307-1 section 5.1.6 Base-Band Header insertion uint8_t *bbheader = buf; uint8_t matype1 = 0; matype1 |= 0xc0; // TS matype1 |= 0x20; // SIS matype1 |= (n_pls_seq==1) ? 0x10 : 0x00; // CCM/ACM // TBD ISSY/NPD required for ACM ? matype1 |= rolloff_code; *buf++ = matype1; // MATYPE-1 *buf++ = 0; // MATYPE-2 uint16_t upl = 188 * 8; *buf++ = upl >> 8; // UPL MSB *buf++ = upl; // UPL LSB uint16_t dfl = (framebytes - 10) * 8; *buf++ = dfl >> 8; // DFL MSB *buf++ = dfl; // DFL LSB *buf++ = 0x47; // SYNC uint16_t syncd = nremain * 8; *buf++ = syncd >> 8; // SYNCD MSB *buf++ = syncd; // SYNCD LSB *buf++ = crc8.compute(bbheader, 9); // Data field memcpy(buf, rembuf, nremain); // Leftover from previous runs buf += nremain; while (buf < end) { tspacket *tsp = in.rd(); if (tsp->data[0] != MPEG_SYNC) { fail("Invalid TS"); } *buf++ = remcrc; // Replace SYNC with CRC of previous. remcrc = crc8.compute(tsp->data + 1, tspacket::SIZE - 1); int nused = end - buf; if (nused > tspacket::SIZE - 1) { nused = tspacket::SIZE - 1; } memcpy(buf, tsp->data + 1, nused); buf += nused; if (buf == end) { nremain = (tspacket::SIZE - 1) - nused; memcpy(rembuf, tsp->data + 1 + nused, nremain); } in.read(1); } if (buf != end) { fail("Bug: s2_framer"); } out.written(1); ++pls_index; if (pls_index == n_pls_seq) { pls_index = 0; } } } private: int pls_index; // Next slot to use in pls_seq pipereader in; pipewriter out; crc8_engine crc8; int nremain; uint8_t rembuf[tspacket::SIZE]; uint8_t remcrc; }; // s2_framer // S2 DEFRAMER // EN 302 307-1 section 5.1 Mode adaptation struct s2_deframer : runnable { int fd_gse; // FD for generic streams, or -1 s2_deframer( scheduler *sch, pipebuf &_in, pipebuf &_out, pipebuf *_state_out = nullptr, pipebuf *_locktime_out = nullptr ) : runnable(sch, "S2 deframer"), fd_gse(-1), nleftover(-1), in(_in), out(_out, MAX_TS_PER_BBFRAME), current_state(false), state_out(opt_writer(_state_out, 2)), report_state(true), locktime(0), locktime_out(opt_writer(_locktime_out, MAX_TS_PER_BBFRAME)) { } void run() { while (in.readable() >= 1 && out.writable() >= MAX_TS_PER_BBFRAME && opt_writable(state_out, 2) && opt_writable(locktime_out, MAX_TS_PER_BBFRAME)) { if (report_state) { // Report unlocked state on first invocation. opt_write(state_out, 0); report_state = false; } run_bbframe(in.rd()); in.read(1); } } private: void run_bbframe(bbframe *pin) { uint8_t *bbh = pin->bytes; // EN 302 307 section 5.1.6 Base-Band Header Insertion uint8_t streamtype = bbh[0] >> 6; bool sis = bbh[0] & 32; bool ccm = bbh[0] & 16; bool issyi = bbh[0] & 8; bool npd = bbh[0] & 4; int ro_code = bbh[0] & 3; uint8_t isi = bbh[1]; // if !sis uint16_t upl = (bbh[2] << 8) | bbh[3]; uint16_t dfl = (bbh[4] << 8) | bbh[5]; uint8_t sync = bbh[6]; uint16_t syncd = (bbh[7] << 8) | bbh[8]; uint8_t crcexp = crc8.compute(bbh, 9); uint8_t crc = bbh[9]; uint8_t *data = bbh + 10; if (sch->debug2) { static const char *stnames[] = { "GP", "GC", "??", "TS" }; static float ro_values[] = {0.35, 0.25, 0.20, 0}; fprintf(stderr, "BBH: crc %02x/%02x(%s) %s %s(ISI=%d) %s%s%s ro=%.2f" " upl=%d dfl=%d sync=%02x syncd=%d\n", crc, crcexp, (crc == crcexp) ? "OK" : "KO", stnames[streamtype], (sis ? "SIS" : "MIS"), isi, (ccm ? "CCM" : "ACM"), (issyi ? " ISSYI": ""), (npd ? " NPD" : ""), ro_values[ro_code], upl, dfl, sync, syncd ); } if (crc != crcexp || dfl > fec_info::KBCH_MAX) { // Note: Maybe accept syncd=65535 if (sch->debug) { fprintf(stderr, "Bad bbframe\n"); } nleftover = -1; info_unlocked(); return; // Max one state_out per loop } // TBD: Supporting byte-oriented payloads only. if ((dfl&7) || (syncd&7)) { fprintf(stderr, "Unsupported bbframe\n"); nleftover = -1; info_unlocked(); return; // Max one state_out per loop } if (streamtype==3 && upl==188*8 && sync==0x47 && syncd<=dfl) { handle_ts(data, dfl, syncd, sync); } #ifdef LINUX else if (streamtype == 1) { if (fd_gse >= 0) { ssize_t nw = write(fd_gse, data, dfl/8); if (nw < 0) { fatal("write(gse)"); } if (nw != dfl/8) { fail("partial write(gse"); } } else { fprintf(stderr, "Unrecognized bbframe\n"); } } #endif } void handle_ts(uint8_t *data, uint16_t dfl, uint16_t syncd, uint8_t sync) { int pos; // Start of useful data in this bbframe if (nleftover < 0) { // Not synced. Skip unusable data at beginning of bbframe pos = syncd / 8; if (sch->debug) { fprintf(stderr, "Start TS at %d\n", pos); } nleftover = 0; } else { // Sanity check if (syncd / 8 != 188 - nleftover) { if (sch->debug) { fprintf(stderr, "Lost a bbframe ?\n"); } nleftover = -1; info_unlocked(); return; // Max one state_out per loop } pos = 0; } while ( pos+(188-nleftover)+1 <= dfl/8 ) { // Enough data available for one packet and its CRC. tspacket *pout = out.wr(); memcpy(pout->data, leftover, nleftover); // NOP most of the time memcpy(pout->data+nleftover, data+pos, 188-nleftover); pout->data[0] = sync; // Replace CRC uint8_t crc = crc8.compute(pout->data+1, 188-1); if (data[pos+(188-nleftover)] == crc) { info_good_packet(); } else { pout->data[1] |= 0x80; // Set TEI bit if (sch->debug) { fprintf(stderr, "C"); } } out.written(1); pos += 188 - nleftover; nleftover = 0; } int remain = dfl / 8 - pos; if (nleftover + remain > (int) sizeof(leftover)) { fail("Bug: TS deframer"); } memcpy(leftover+nleftover, data+pos, remain); nleftover += remain; } void info_unlocked() { info_is_locked(false); locktime = 0; } void info_good_packet() { info_is_locked(true); ++locktime; opt_write(locktime_out, locktime); } void info_is_locked(bool newstate) { if (newstate != current_state) { opt_write(state_out, newstate ? 1 : 0); current_state = newstate; } } crc8_engine crc8; int nleftover; // Bytes in leftover[]: // -1 = not synced. // 0 = no leftover data // 1 - 187 = incomplete packet // 188 = waiting for CRC uint8_t leftover[188]; static const int MAX_TS_PER_BBFRAME = fec_info::KBCH_MAX / 8 / 188 + 1; bool locked; pipereader in; pipewriter out; int current_state; pipewriter *state_out; bool report_state; unsigned long locktime; pipewriter *locktime_out; }; // s2_deframer } // namespace leansdr #endif // LEANSDR_DVBS2_H