## ## This file is part of the libsigrokdecode project. ## ## Copyright (C) 2016 Benjamin Larsson ## ## 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. ## ## You should have received a copy of the GNU General Public License ## along with this program; if not, see . ## import sigrokdecode as srd class SamplerateError(Exception): pass class Decoder(srd.Decoder): api_version = 3 id = 'em4305' name = 'EM4305' longname = 'RFID EM4205/EM4305' desc = 'EM4205/EM4305 100-150kHz RFID protocol.' license = 'gplv2+' inputs = ['logic'] outputs = [] tags = ['IC', 'RFID'] channels = ( {'id': 'data', 'name': 'Data', 'desc': 'Data line'}, ) options = ( {'id': 'coilfreq', 'desc': 'Coil frequency', 'default': 125000}, {'id': 'first_field_stop', 'desc': 'First field stop min', 'default': 40}, {'id': 'w_gap', 'desc': 'Write gap min', 'default': 12}, {'id': 'w_one_max', 'desc': 'Write one max', 'default': 32}, {'id': 'w_zero_on_min', 'desc': 'Write zero on min', 'default': 15}, {'id': 'w_zero_off_max', 'desc': 'Write zero off max', 'default': 27}, {'id': 'em4100_decode', 'desc': 'EM4100 decode', 'default': 'on', 'values': ('on', 'off')}, ) annotations = ( ('bit_value', 'Bit value'), ('first_field_stop', 'First field stop'), ('write_gap', 'Write gap'), ('write_mode_exit', 'Write mode exit'), ('bit', 'Bit'), ('opcode', 'Opcode'), ('lock', 'Lock'), ('data', 'Data'), ('password', 'Password'), ('address', 'Address'), ('bitrate', 'Bitrate'), ) annotation_rows = ( ('bits', 'Bits', (0,)), ('structure', 'Structure', (1, 2, 3, 4)), ('fields', 'Fields', (5, 6, 7, 8, 9)), ('decode', 'Decode', (10,)), ) def __init__(self): self.reset() def reset(self): self.samplerate = None self.last_samplenum = None self.state = 'FFS_SEARCH' self.bits_pos = [[0 for col in range(3)] for row in range(70)] self.br_string = ['RF/8', 'RF/16', 'Unused', 'RF/32', 'RF/40', 'Unused', 'Unused', 'RF/64',] self.encoder = ['not used', 'Manchester', 'Bi-phase', 'not used'] self.delayed_on = ['No delay', 'Delayed on - BP/8', 'Delayed on - BP/4', 'No delay'] self.em4100_decode1_partial = 0 self.cmds = ['Invalid', 'Login', 'Write word', 'Invalid', 'Read word', 'Disable', 'Protect', 'Invalid'] def metadata(self, key, value): if key == srd.SRD_CONF_SAMPLERATE: self.samplerate = value self.field_clock = self.samplerate / self.options['coilfreq'] self.wzmax = self.options['w_zero_off_max'] * self.field_clock self.wzmin = self.options['w_zero_on_min'] * self.field_clock self.womax = self.options['w_one_max'] * self.field_clock self.ffs = self.options['first_field_stop'] * self.field_clock self.writegap = self.options['w_gap'] * self.field_clock self.nogap = 300 * self.field_clock def start(self): self.out_ann = self.register(srd.OUTPUT_ANN) def decode_config(self, idx): bitrate = self.get_3_bits(idx+2) self.put(self.bits_pos[idx][1], self.bits_pos[idx+5][2], self.out_ann, [10, ['Data rate: ' + \ self.br_string[bitrate], self.br_string[bitrate]]]) encoding = self.bits_pos[idx+6][0]<<0 | self.bits_pos[idx+7][0]<<1 self.put(self.bits_pos[idx+6][1], self.bits_pos[idx+10][2], self.out_ann, [10, ['Encoder: ' + \ self.encoder[encoding], self.encoder[encoding]]]) self.put(self.bits_pos[idx+11][1], self.bits_pos[idx+12][2], self.out_ann, [10, ['Zero bits', 'ZB']]) delay_on = self.bits_pos[idx+13][0]<<0 | self.bits_pos[idx+14][0]<<1 self.put(self.bits_pos[idx+13][1], self.bits_pos[idx+14][2], self.out_ann, [10, ['Delayed on: ' + \ self.delayed_on[delay_on], self.delayed_on[delay_on]]]) lwr = self.bits_pos[idx+15][0]<<3 | self.bits_pos[idx+16][0]<<2 | \ self.bits_pos[idx+18][0]<<1 | self.bits_pos[idx+19][0]<<0 self.put(self.bits_pos[idx+15][1], self.bits_pos[idx+19][2], self.out_ann, [10, ['Last default read word: %d' % lwr, 'LWR: %d' % lwr, '%d' % lwr]]) self.put(self.bits_pos[idx+20][1], self.bits_pos[idx+20][2], self.out_ann, [10, ['Read login: %d' % self.bits_pos[idx+20][0], '%d' % self.bits_pos[idx+20][0]]]) self.put(self.bits_pos[idx+21][1], self.bits_pos[idx+21][2], self.out_ann, [10, ['Zero bits', 'ZB']]) self.put(self.bits_pos[idx+22][1], self.bits_pos[idx+22][2], self.out_ann, [10, ['Write login: %d' % self.bits_pos[idx+22][0], '%d' % self.bits_pos[idx+22][0]]]) self.put(self.bits_pos[idx+23][1], self.bits_pos[idx+24][2], self.out_ann, [10, ['Zero bits', 'ZB']]) self.put(self.bits_pos[idx+25][1], self.bits_pos[idx+25][2], self.out_ann, [10, ['Disable: %d' % self.bits_pos[idx+25][0], '%d' % self.bits_pos[idx+25][0]]]) self.put(self.bits_pos[idx+27][1], self.bits_pos[idx+27][2], self.out_ann, [10, ['Reader talk first: %d' % self.bits_pos[idx+27][0], 'RTF: %d' % self.bits_pos[idx+27][0]]]) self.put(self.bits_pos[idx+28][1], self.bits_pos[idx+28][2], self.out_ann, [10, ['Zero bits', 'ZB']]) self.put(self.bits_pos[idx+29][1], self.bits_pos[idx+29][2], self.out_ann, [10, ['Pigeon mode: %d' % self.bits_pos[idx+29][0], '%d' % self.bits_pos[idx+29][0]]]) self.put(self.bits_pos[idx+30][1], self.bits_pos[idx+34][2], self.out_ann, [10, ['Reserved', 'Res', 'R']]) def put4bits(self, idx): bits = self.bits_pos[idx][0]<<3 | self.bits_pos[idx+1][0]<<2 | \ self.bits_pos[idx+2][0]<<1 | self.bits_pos[idx+3][0] self.put(self.bits_pos[idx][1], self.bits_pos[idx+3][2], self.out_ann, [10, ['%X' % bits]]) def em4100_decode1(self, idx): self.put(self.bits_pos[idx][1], self.bits_pos[idx+9][2], self.out_ann, [10, ['EM4100 header', 'EM header', 'Header', 'H']]) self.put4bits(idx+10) bits = self.bits_pos[idx+15][0]<<3 | self.bits_pos[idx+16][0]<<2 | \ self.bits_pos[idx+18][0]<<1 | self.bits_pos[idx+19][0]<<0 self.put(self.bits_pos[idx+15][1], self.bits_pos[idx+19][2], self.out_ann, [10, ['%X' % bits]]) self.put4bits(idx+21) self.put4bits(idx+27) self.em4100_decode1_partial = self.bits_pos[idx+32][0]<<3 | \ self.bits_pos[idx+33][0]<<2 | self.bits_pos[idx+34][0]<<1 self.put(self.bits_pos[idx+32][1], self.bits_pos[idx+34][2], self.out_ann, [10, ['Partial nibble']]) def em4100_decode2(self, idx): if self.em4100_decode1_partial != 0: bits = self.em4100_decode1_partial + self.bits_pos[idx][0] self.put(self.bits_pos[idx][1], self.bits_pos[idx][2], self.out_ann, [10, ['%X' % bits]]) self.em4100_decode1_partial = 0 else: self.put(self.bits_pos[idx][1], self.bits_pos[idx][2], self.out_ann, [10, ['Partial nibble']]) self.put4bits(idx+2) bits = self.bits_pos[idx+7][0]<<3 | self.bits_pos[idx+9][0]<<2 | \ self.bits_pos[idx+10][0]<<1 | self.bits_pos[idx+11][0]<<0 self.put(self.bits_pos[idx+7][1], self.bits_pos[idx+11][2], self.out_ann, [10, ['%X' % bits]]) self.put4bits(idx+13) self.put4bits(idx+19) bits = self.bits_pos[idx+24][0]<<3 | self.bits_pos[idx+25][0]<<2 | \ self.bits_pos[idx+27][0]<<1 | self.bits_pos[idx+28][0]<<0 self.put(self.bits_pos[idx+24][1], self.bits_pos[idx+28][2], self.out_ann, [10, ['%X' % bits]]) self.put(self.bits_pos[idx+30][1], self.bits_pos[idx+34][2], self.out_ann, [10, ['EM4100 trailer']]) def get_32_bits(self, idx): return self.get_8_bits(idx+27)<<24 | self.get_8_bits(idx+18)<<16 | \ self.get_8_bits(idx+9)<<8 | self.get_8_bits(idx) def get_8_bits(self, idx): retval = 0 for i in range(0, 8): retval <<= 1 retval |= self.bits_pos[i+idx][0] return retval def get_3_bits(self, idx): return self.bits_pos[idx][0]<<2 | self.bits_pos[idx+1][0]<<1 | \ self.bits_pos[idx+2][0] def get_4_bits(self, idx): return self.bits_pos[idx][0]<<0 | self.bits_pos[idx+1][0]<<1 | \ self.bits_pos[idx+2][0]<<2 | self.bits_pos[idx+3][0]<<3 def print_row_parity(self, idx, length): parity = 0 for i in range(0, length): parity += self.bits_pos[i+idx][0] parity = parity & 0x1 if parity == self.bits_pos[idx+length][0]: self.put(self.bits_pos[idx+length][1], self.bits_pos[idx+length][2], self.out_ann, [5, ['Row parity OK', 'Parity OK', 'OK']]) else: self.put(self.bits_pos[idx+length][1], self.bits_pos[idx+length][2], self.out_ann, [5, ['Row parity failed', 'Parity failed', 'Fail']]) def print_col_parity(self, idx): data_1 = self.get_8_bits(idx) data_2 = self.get_8_bits(idx+9) data_3 = self.get_8_bits(idx+9+9) data_4 = self.get_8_bits(idx+9+9+9) col_par = self.get_8_bits(idx+9+9+9+9) col_par_calc = data_1^data_2^data_3^data_4 if col_par == col_par_calc: self.put(self.bits_pos[idx+9+9+9+9][1], self.bits_pos[idx+9+9+9+9+7][2], self.out_ann, [5, ['Column parity OK', 'Parity OK', 'OK']]) else: self.put(self.bits_pos[idx+9+9+9+9][1], self.bits_pos[idx+9+9+9+9+7][2], self.out_ann, [5, ['Column parity failed', 'Parity failed', 'Fail']]) def print_8bit_data(self, idx): data = self.get_8_bits(idx) self.put(self.bits_pos[idx][1], self.bits_pos[idx+7][2], self.out_ann, [9, ['Data' + ': %X' % data, '%X' % data]]) def put_fields(self): if self.bit_nr == 50: self.put(self.bits_pos[0][1], self.bits_pos[0][2], self.out_ann, [4, ['Logic zero']]) self.put(self.bits_pos[1][1], self.bits_pos[4][2], self.out_ann, [4, ['Command', 'Cmd', 'C']]) self.put(self.bits_pos[5][1], self.bits_pos[49][2], self.out_ann, [4, ['Password', 'Passwd', 'Pass', 'P']]) # Get command. cmd = self.get_3_bits(1) self.put(self.bits_pos[1][1], self.bits_pos[3][2], self.out_ann, [5, [self.cmds[cmd]]]) self.print_row_parity(1, 3) # Print data. self.print_8bit_data(5) self.print_row_parity(5, 8) self.print_8bit_data(14) self.print_row_parity(14, 8) self.print_8bit_data(23) self.print_row_parity(23, 8) self.print_8bit_data(32) self.print_row_parity(32, 8) self.print_col_parity(5) if self.bits_pos[49][0] == 0: self.put(self.bits_pos[49][1], self.bits_pos[49][2], self.out_ann, [5, ['Stop bit', 'Stop', 'SB']]) else: self.put(self.bits_pos[49][1], self.bits_pos[49][2], self.out_ann, [5, ['Stop bit error', 'Error']]) if cmd == 1: password = self.get_32_bits(5) self.put(self.bits_pos[12][1], self.bits_pos[46][2], self.out_ann, [10, ['Login password: %X' % password]]) if self.bit_nr == 57: self.put(self.bits_pos[0][1], self.bits_pos[0][2], self.out_ann, [4, ['Logic zero', 'LZ']]) self.put(self.bits_pos[1][1], self.bits_pos[4][2], self.out_ann, [4, ['Command', 'Cmd', 'C']]) self.put(self.bits_pos[5][1], self.bits_pos[11][2], self.out_ann, [4, ['Address', 'Addr', 'A']]) self.put(self.bits_pos[12][1], self.bits_pos[56][2], self.out_ann, [4, ['Data', 'Da', 'D']]) # Get command. cmd = self.get_3_bits(1) self.put(self.bits_pos[1][1], self.bits_pos[3][2], self.out_ann, [5, [self.cmds[cmd]]]) self.print_row_parity(1, 3) # Get address. addr = self.get_4_bits(5) self.put(self.bits_pos[5][1], self.bits_pos[8][2], self.out_ann, [9, ['Addr' + ': %d' % addr, '%d' % addr]]) self.put(self.bits_pos[9][1], self.bits_pos[10][2], self.out_ann, [5, ['Zero bits', 'ZB']]) self.print_row_parity(5, 6) # Print data. self.print_8bit_data(12) self.print_row_parity(12, 8) self.print_8bit_data(21) self.print_row_parity(21, 8) self.print_8bit_data(30) self.print_row_parity(30, 8) self.print_8bit_data(39) self.print_row_parity(39, 8) self.print_col_parity(12) if self.bits_pos[56][0] == 0: self.put(self.bits_pos[56][1], self.bits_pos[56][2], self.out_ann, [5, ['Stop bit', 'Stop', 'SB']]) else: self.put(self.bits_pos[56][1], self.bits_pos[56][2], self.out_ann, [5, ['Stop bit error', 'Error']]) if addr == 4: self.decode_config(12) if addr == 2: password = self.get_32_bits(12) self.put(self.bits_pos[12][1], self.bits_pos[46][2], self.out_ann, [10, ['Write password: %X' % password]]) # If we are programming EM4100 data we can decode it halfway. if addr == 5 and self.options['em4100_decode'] == 'on': self.em4100_decode1(12) if addr == 6 and self.options['em4100_decode'] == 'on': self.em4100_decode2(12) self.bit_nr = 0 def add_bits_pos(self, bit, ss_bit, es_bit): if self.bit_nr < 70: self.bits_pos[self.bit_nr][0] = bit self.bits_pos[self.bit_nr][1] = ss_bit self.bits_pos[self.bit_nr][2] = es_bit self.bit_nr += 1 def decode(self): if not self.samplerate: raise SamplerateError('Cannot decode without samplerate.') # Initialize internal state. self.last_samplenum = self.samplenum self.oldsamplenum = 0 self.old_gap_end = 0 self.gap_detected = 0 self.bit_nr = 0 while True: # Ignore identical samples, only process edges. (pin,) = self.wait({0: 'e'}) pl = self.samplenum - self.oldsamplenum pp = pin samples = self.samplenum - self.last_samplenum if self.state == 'FFS_DETECTED': if pl > self.writegap: self.gap_detected = 1 if (self.last_samplenum - self.old_gap_end) > self.nogap: self.gap_detected = 0 self.state = 'FFS_SEARCH' self.put(self.old_gap_end, self.last_samplenum, self.out_ann, [3, ['Write mode exit']]) self.put_fields() if self.state == 'FFS_SEARCH': if pl > self.ffs: self.gap_detected = 1 self.put(self.last_samplenum, self.samplenum, self.out_ann, [1, ['First field stop', 'Field stop', 'FFS']]) self.state = 'FFS_DETECTED' if self.gap_detected == 1: self.gap_detected = 0 if (self.last_samplenum - self.old_gap_end) > self.wzmin \ and (self.last_samplenum - self.old_gap_end) < self.wzmax: self.put(self.old_gap_end, self.samplenum, self.out_ann, [0, ['0']]) self.add_bits_pos(0, self.old_gap_end, self.samplenum) if (self.last_samplenum - self.old_gap_end) > self.womax \ and (self.last_samplenum-self.old_gap_end) < self.nogap: # One or more 1 bits one_bits = (int)((self.last_samplenum - self.old_gap_end) / self.womax) for ox in range(0, one_bits): bs = (int)(self.old_gap_end+ox*self.womax) be = (int)(self.old_gap_end+ox*self.womax + self.womax) self.put(bs, be, self.out_ann, [0, ['1']]) self.add_bits_pos(1, bs, be) if (self.samplenum - self.last_samplenum) > self.wzmin \ and (self.samplenum - self.last_samplenum) < self.wzmax: bs = (int)(self.old_gap_end+one_bits*self.womax) self.put(bs, self.samplenum, self.out_ann, [0, ['0']]) self.add_bits_pos(0, bs, self.samplenum) self.old_gap_end = self.samplenum if self.state == 'SKIP': self.state = 'FFS_SEARCH' self.oldsamplenum = self.samplenum self.last_samplenum = self.samplenum