/* Copyright (C) 2014 CSP Innovazione nelle ICT s.c.a r.l. (http://www.csp.it/) Copyright (C) 2018 Matthias P. Braendli (http://www.opendigitalradio.org) Copyright (C) 2015 Data Path 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 . Authors: Sergio Sagliocco Matthias P. Braendli / | |- ')|) |-|_ _ (|,_ .| _ ,_ \ Data Path \(|(||_(|/_| (||_||(a)_||||(|||.(_()|||/ */ #include "figs.hpp" #include #include #include #include static std::unordered_set regions_seen; bool fig0_21_is_complete(int region_id) { bool complete = regions_seen.count(region_id); if (complete) { regions_seen.clear(); } else { regions_seen.insert(region_id); } return complete; } // FIG 0/21 Frequency Information // ETSI EN 300 401 8.1.8 fig_result_t fig0_21(fig0_common_t& fig0, const display_settings_t &disp) { uint8_t* f = fig0.f; fig_result_t r; int i = 1; while (i < fig0.figlen) { const uint16_t RegionId = (f[i] << 3) | (f[i+1] >> 5); r.complete |= fig0_21_is_complete(RegionId); const uint8_t Length_FI_list = f[i+1] & 0x1F; // in bytes r.msgs.emplace_back("-"); r.msgs.emplace_back(1, strprintf("RegionId=0x%03x", RegionId)); r.msgs.emplace_back(1, strprintf("Len=%d Bytes", Length_FI_list)); i += 2; const int FI_start_ix = i; r.msgs.emplace_back(1, "FIs:"); for (size_t FI_ix = 0; i < FI_start_ix + Length_FI_list; FI_ix++) { if (i + 3 > fig0.figlen) { r.errors.push_back("FIG0/21 too small!"); break; } const uint16_t Id_field = (f[i] << 8) | f[i+1]; const uint8_t RandM = f[i+2] >> 4; const bool Continuity_flag = (f[i+2] >> 3) & 0x01; const uint8_t Length_Freq_list = f[i+2] & 0x07; // in bytes r.msgs.emplace_back(2, "-"); r.msgs.emplace_back(3, strprintf("Length Freq list=%d", Length_Freq_list)); i += 3; std::string idfield; switch (RandM) { case 0x0: case 0x1: idfield = "EId"; break; case 0x6: idfield = "DRM Service Id"; break; case 0x8: idfield = "RDS PI"; break; case 0x9: case 0xa: case 0xc: idfield = "Dummy"; break; case 0xe: idfield = "AMSS Service Id"; break; default: idfield = "invalid"; r.errors.emplace_back("R&M invalid"); break; } r.msgs.emplace_back(3, strprintf("ID field=0x%X ", Id_field) + idfield); std::string rm_str; switch (RandM) { case 0x0: rm_str = "DAB ensemble, no local windows"; break; case 0x6: rm_str = "DRM"; break; case 0x8: rm_str = "FM with RDS"; break; case 0x9: rm_str = "FM without RDS"; break; case 0xa: rm_str = "AM (MW in 9 kHz steps & LW)"; break; case 0xc: rm_str = "AM (MW in 5 kHz steps & SW)"; break; case 0xe: rm_str = "AMSS"; break; default: rm_str = "Rfu"; r.errors.emplace_back("R&M is Rfu"); break; } r.msgs.emplace_back(3, strprintf("R&M=0x%1x ", RandM) + rm_str); std::string continuity_str; if ((fig0.oe() == 0) || ((fig0.oe() == 1) && (RandM != 0x6) && ((RandM < 0x8) || (RandM > 0xa)) && (RandM != 0xc) && (RandM != 0xe))) { if (Continuity_flag == 0) { switch (RandM) { case 0x0: case 0x1: continuity_str = ", continuous output not expected"; break; case 0x6: continuity_str = ", no compensating time delay on DRM audio signal"; break; case 0x8: case 0x9: continuity_str = ", no compensating time delay on FM audio signal"; break; case 0xa: case 0xc: case 0xe: continuity_str = ", no compensating time delay on AM audio signal"; break; default: continuity_str = ", Rfu"; break; } } else { // Continuity_flag == 1 switch (RandM) { case 0x0: case 0x1: continuity_str = ", continuous output possible"; break; case 0x6: continuity_str = ", compensating time delay on DRM audio signal"; break; case 0x8: case 0x9: continuity_str = ", compensating time delay on FM audio signal"; break; case 0xa: case 0xc: case 0xe: continuity_str = ", compensating time delay on AM audio signal"; break; default: continuity_str = ", Rfu"; break; } } } else { // fig0.oe() == 1 continuity_str = ", reserved for future addition"; r.errors.emplace_back("Rfu"); } r.msgs.emplace_back(3, strprintf("Continuity flag=%d ", Continuity_flag) + continuity_str); const uint64_t key = ((uint64_t)fig0.oe() << 32) | ((uint64_t)fig0.pd() << 31) | ((uint64_t)RegionId << 20) | ((uint64_t)Id_field << 4) | (uint64_t)RandM; r.msgs.emplace_back(3, strprintf("database key=0x%09" PRId64, key)); // CEI Change Event Indication if (Length_Freq_list == 0) { r.msgs.emplace_back(3, "CEI=true"); } r.msgs.emplace_back(3, "Frequency Information:"); // Iterate over the frequency infos switch (RandM) { case 0x0: case 0x1: { // Each entry is 24 bits (5 control + 19 freq) const size_t bytes_per_entry = 3; const int num_freqs = Length_Freq_list / bytes_per_entry; if (Length_Freq_list % bytes_per_entry != 0) { r.errors.push_back("Length of freq list incorrect size"); } for (int freq_ix = 0; freq_ix < num_freqs; freq_ix++) { r.msgs.emplace_back(4, "-"); if (i + bytes_per_entry > fig0.figlen) { r.errors.push_back(strprintf( "FIG 0/21 too small for" " FI %d, freq %d", FI_ix, freq_ix)); break; } const uint8_t Control_field = (f[i] >> 3); const uint32_t freq = 16 * (((uint32_t)(f[i] & 0x07) << 16) | ((uint32_t)f[i+1] << 8) | (uint32_t)f[i+2]); i += bytes_per_entry; if (freq == 0) { r.errors.emplace_back(strprintf( "Frequency not to be used (0) in" " FI %d, freq %d", FI_ix, freq_ix)); continue; } const uint8_t Control_field_trans_mode = (Control_field >> 1) & 0x07; if ((Control_field & 0x10) == 0) { r.msgs.emplace_back(5, strprintf("%d kHz", freq)); if ((Control_field & 0x01) == 0) { r.msgs.emplace_back(5, "geographically adjacent area"); } else { // (Control_field & 0x01) == 1 r.msgs.emplace_back(5, "no geographically adjacent area"); } if (Control_field_trans_mode == 0) { r.msgs.emplace_back(5, "no transmission mode signalled"); } else if (Control_field_trans_mode <= 4) { r.msgs.emplace_back(5, strprintf("transmission mode %d", Control_field_trans_mode)); } else { // Control_field_trans_mode > 4 r.msgs.emplace_back(5, strprintf("invalid transmission mode 0x%x", Control_field_trans_mode)); } } else { // (Control_field & 0x10) == 0x10 r.msgs.emplace_back(5, strprintf("%d kHz," "invalid Control field b23 0x%x", freq, Control_field)); } } } break; case 0x8: case 0x9: case 0xA: { // entries are 8-bit freq const size_t bytes_per_entry = 1; const int num_freqs = Length_Freq_list / bytes_per_entry; for (int freq_ix = 0; freq_ix < num_freqs; freq_ix++) { r.msgs.emplace_back(4, "-"); if (i + bytes_per_entry > fig0.figlen) { r.errors.push_back(strprintf( "FIG 0/21 too small for" " FI %d, freq %d", FI_ix, freq_ix)); } const uint8_t freq = f[i]; i++; if (freq == 0) { r.errors.emplace_back( "Frequency not to be used (0)"); continue; } if (RandM == 0xA) { if (freq < 16) { r.msgs.emplace_back(5, strprintf("%d kHz", 144 + ((uint32_t)freq * 9))); } else { // f[k] >= 16 r.msgs.emplace_back(5, strprintf("%d kHz", 387 + ((uint32_t)freq * 9))); } } else { // RandM == 8 or 9 r.msgs.emplace_back(5, strprintf("%.1f MHz", 87.5 + ((float)freq * 0.1))); } } } break; case 0xC: { // freqs are 16-bit const size_t bytes_per_entry = 2; const int num_freqs = Length_Freq_list / bytes_per_entry; if (Length_Freq_list % bytes_per_entry != 0) { r.errors.push_back("Length of freq list incorrect size"); } for (int freq_ix = 0; freq_ix < num_freqs; freq_ix++) { r.msgs.emplace_back(4, "-"); if (i + bytes_per_entry > fig0.figlen) { r.errors.push_back(strprintf( "FIG 0/21 too small for" " FI %d, freq %d", FI_ix, freq_ix)); } // freqs are 16-bit const uint16_t freq = 5 * (((uint16_t)f[i] << 8) | (uint32_t)f[i+1]); i += bytes_per_entry; if (freq != 0) { r.msgs.emplace_back(5, strprintf("%d kHz", freq)); } else { r.errors.emplace_back( "Frequency not to be used (0)"); } } } break; case 0x6: case 0xE: { // There is a first 8-bit entry, and the // list contains 16-bit freqs if (i + 1 > fig0.figlen) { r.errors.push_back(strprintf( "FIG 0/21 too small for" " control of" " FI %d", FI_ix)); } const size_t bytes_per_entry = 2; const int num_freqs = (Length_Freq_list-1) / bytes_per_entry; if ((Length_Freq_list-1) % bytes_per_entry != 0) { r.errors.push_back("Length of freq list incorrect size"); } const uint32_t Id_field2 = f[i]; i++; for (int freq_ix = 0; freq_ix < num_freqs; freq_ix++) { r.msgs.emplace_back(4, "-"); if (i + bytes_per_entry > fig0.figlen) { r.errors.push_back(strprintf( "FIG 0/21 too small for" " FI %d, freq %d", FI_ix, freq_ix)); } // entries are 16bit freq const uint16_t freq = ((((uint16_t)f[i] & 0x7f) << 8) | (uint16_t)f[i+1]); i += bytes_per_entry; if (freq != 0) { r.msgs.emplace_back(5, strprintf("%d kHz", freq)); } else { r.errors.emplace_back( "Frequency not to be used (0)"); } const uint32_t srv_id = (Id_field2 << 16) | Id_field; if (RandM == 0x6) { r.msgs.emplace_back(5, strprintf("DRM Service Id 0x%X", srv_id)); } else if (RandM == 0xE) { r.msgs.emplace_back(5, strprintf("AMSS Service Id 0x%X", srv_id)); } } } break; default: r.errors.push_back(strprintf("Invalid R&M")); break; } } } return r; }