# -*- coding: utf-8 -*- # TRX Toolkit # Common GSM constants and helpers # # (C) 2018-2020 by Vadim Yanitskiy # Contributions by sysmocom - s.f.m.c. GmbH # # All Rights Reserved # # 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 2 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. from enum import Enum # TDMA definitions GSM_SUPERFRAME = 26 * 51 GSM_HYPERFRAME = 2048 * GSM_SUPERFRAME # Burst length GMSK_BURST_LEN = 148 EDGE_BURST_LEN = GMSK_BURST_LEN * 3 class BurstType(Enum): """ Burst types defined in 3GPP TS 45.002 """ DUMMY = ("DB") # Dummy burst (5.2.6) SYNC = ("SB") # Synchronization Burst (5.2.5) FREQ = ("FB") # Frequency correction Burst (5.2.4) ACCESS = ("AB") # Access Burst (5.2.7) NORMAL = ("NB") # Normal Burst (5.2.3) # HSR = ("HB") # Higher symbol rate burst (5.2.3a) class TrainingSeqGMSK(Enum): """ Training Sequences defined in 3GPP TS 45.002 """ # Training Sequences for Access Burst (table 5.2.7-3) AB_TS0 = (0, BurstType.ACCESS, "01001011011111111001100110101010001111000") AB_TS1 = (1, BurstType.ACCESS, "01010100111110001000011000101111001001101") AB_TS2 = (2, BurstType.ACCESS, "11101111001001110101011000001101101110111") AB_TS4 = (4, BurstType.ACCESS, "11001001110001001110000000001101010110010") # Training Sequences for Access Burst (table 5.2.7-4) AB_TS3 = (3, BurstType.ACCESS, "10001000111010111011010000010000101100010") AB_TS5 = (5, BurstType.ACCESS, "01010000111111110101110101101100110010100") AB_TS6 = (6, BurstType.ACCESS, "01011110011101011110110100010011000010111") AB_TS7 = (7, BurstType.ACCESS, "01000010110000011101001010111011100010000") # Training Sequences for Synchronization Burst (table 5.2.5-3) SB_TS0 = (0, BurstType.SYNC, "1011100101100010000001000000111100101101010001010111011000011011") SB_TS1 = (1, BurstType.SYNC, "1110111001101011001010000011111011110100011111101100101100010101") SB_TS2 = (2, BurstType.SYNC, "1110110000110111010100010101101001111000000100000010001101001110") SB_TS3 = (3, BurstType.SYNC, "1011101000111101110101101111010010001011010000001000111010011000") # Training Sequences for Normal Burst (table 5.2.3a, TSC set 1) NB_TS0 = (0, BurstType.NORMAL, "00100101110000100010010111") NB_TS1 = (1, BurstType.NORMAL, "00101101110111100010110111") NB_TS2 = (2, BurstType.NORMAL, "01000011101110100100001110") NB_TS3 = (3, BurstType.NORMAL, "01000111101101000100011110") NB_TS4 = (4, BurstType.NORMAL, "00011010111001000001101011") NB_TS5 = (5, BurstType.NORMAL, "01001110101100000100111010") NB_TS6 = (6, BurstType.NORMAL, "10100111110110001010011111") NB_TS7 = (7, BurstType.NORMAL, "11101111000100101110111100") # TODO: more TSC sets from tables 5.2.3b-d def __init__(self, tsc, bt, seq_str, tsc_set = 0): # Training Sequence Code self.tsc = tsc # Burst type self.bt = bt # Training Sequence Code set # NOTE: unlike the specs. we count from zero self.tsc_set = tsc_set # Generate Training Sequence bits self.seq = [int(x) for x in seq_str] @classmethod def pick(self, burst): # Normal burst TS (26 bits) nb_seq = burst[3 + 57 + 1:][:26] # Access burst TS (41 bits) ab_seq = burst[8:][:41] # Sync Burst TS (64 bits) sb_seq = burst[3 + 39:][:64] for ts in list(self): # Ugly Python way of writing 'switch' statement if ts.bt is BurstType.NORMAL and ts.seq == nb_seq: return ts elif ts.bt is BurstType.ACCESS and ts.seq == ab_seq: return ts elif ts.bt is BurstType.SYNC and ts.seq == sb_seq: return ts return None class HoppingParams: """ Hopping sequence generation as per 3GPP TS 45.002, section 6.2.3. Based on firmware/layer1/rfch.c:rfch_hop_seq_gen() by Sylvain Munaut. """ # Magic numbers for pseudo-random hopping sequence generation RNTABLE = [ 48, 98, 63, 1, 36, 95, 78, 102, 94, 73, 0, 64, 25, 81, 76, 59, 124, 23, 104, 100, 101, 47, 118, 85, 18, 56, 96, 86, 54, 2, 80, 34, 127, 13, 6, 89, 57, 103, 12, 74, 55, 111, 75, 38, 109, 71, 112, 29, 11, 88, 87, 19, 3, 68, 110, 26, 33, 31, 8, 45, 82, 58, 40, 107, 32, 5, 106, 92, 62, 67, 77, 108, 122, 37, 60, 66, 121, 42, 51, 126, 117, 114, 4, 90, 43, 52, 53, 113, 120, 72, 16, 49, 7, 79, 119, 61, 22, 84, 9, 97, 91, 15, 21, 24, 46, 39, 93, 105, 65, 70, 125, 99, 17, 123, ] def __init__(self, hsn, maio, ma): # Make sure MA is not empty ma_len = len(ma) if ma_len == 0: # TODO: or rather > 1? raise ValueError("Mobile Allocation is empty") self.hsn = hsn self.maio = maio self.ma = ma # Pre-calculate 2 ** NBIN in advance self._pnm = (ma_len >> 0) | (ma_len >> 1) \ | (ma_len >> 2) | (ma_len >> 3) \ | (ma_len >> 4) | (ma_len >> 5) \ | (ma_len >> 6) def __str__(self): fmt = "hsn=%u, maio=%u, ma_len=%u" return fmt % (self.hsn, self.maio, len(self.ma)) @staticmethod def fn2gsm_time(fn): t1 = fn // (26 * 51) t2 = fn % 26 t3 = fn % 51 tc = (fn // 51) % 8 return (t1, t2, t3, tc) # Resolve current ARFCN using the given TDMA frame number def resolve(self, fn): # Cyclic hopping if self.hsn == 0: mai = (fn + self.maio) % len(self.ma) return self.ma[mai] # Pseudo random hopping (t1, t2, t3, tc) = self.fn2gsm_time(fn) ma_len = len(self.ma) rn_idx = (self.hsn ^ (t1 & 63)) + t3 m = t2 + self.RNTABLE[rn_idx] mp = m & self._pnm s = mp if mp < ma_len else (mp + t3 & self._pnm) % ma_len mai = (s + self.maio) % ma_len return self.ma[mai]