From: Steve R Date: Mon, 10 Sep 2018 16:21:19 +0000 (+0100) Subject: added ook X-Git-Url: https://sigrok.org/gitweb/?p=libsigrokdecode.git;a=commitdiff_plain;h=538d386b86dbb46448cd71941fa28cfe3d4b9d5a added ook --- diff --git a/decoders/ook/__init__.py b/decoders/ook/__init__.py new file mode 100644 index 0000000..24e493b --- /dev/null +++ b/decoders/ook/__init__.py @@ -0,0 +1,36 @@ +## +## This file is part of the libsigrokdecode project. +## +## Copyright (C) 2018 Steve R +## +## 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 . +## + +''' +OOK decodes On-off keying based remote control protocols. + +It is aimed at 433MHz but should also work with other common RC frequencies. +The input can be captured directly from a transmitter (before the modulation +stage) or demodulated by an RF receiver. + +Over the air captured traces will be a lot noisier and will probably need the +area of interest to be zoomed onto, then selected with the "Cursors" and the +"Save Selected Range As" feature to be used to extract it from the noise. + +There is a limited amount of pre-filtering and garbage removal built into the +decoder which can sometimes extract signals directly from a larger over the air +trace. It depends heavily on your environment. +''' + +from .pd import Decoder diff --git a/decoders/ook/pd.py b/decoders/ook/pd.py new file mode 100644 index 0000000..f8f7452 --- /dev/null +++ b/decoders/ook/pd.py @@ -0,0 +1,499 @@ +## +## This file is part of the libsigrokdecode project. +## +## Copyright (C) 2018 Steve R +## +## 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 + +''' +OUTPUT_PYTHON format: +Samples: The Samples array is sent when a DECODE_TIMEOUT occurs. +[, , ] + is the sample number of the start of the decoded bit. This may not line +up with the pulses that were converted into the decoded bit particularly for +Manchester encoding. + is the sample number of the end of the decoded bit. + is a single character string which is the state of the decoded bit. +This can be +'0' zero or low +'1' one or high +'E' Error or invalid. This can be caused by missing transitions or the wrong +pulse lengths according to the rules for the particular encoding. In some cases +this is intentional (Oregon 1 preamble) and is part of the sync pattern. In +other cases the signal could simply be broken. + +If there are more than self.max_errors (default 5) in decoding then the +OUTPUT_PYTHON is not sent as the data is assumed to be worthless. +There also needs to be a low for five times the preamble period at the end of +each set of pulses to trigger a DECODE_TIMEOUT and get the OUTPUT_PYTHON sent. +''' + +class SamplerateError(Exception): + pass + +class Decoder(srd.Decoder): + api_version = 3 + id = 'ook' + name = 'OOK' + longname = 'On-off keying' + desc = 'On-off keying protocol.' + license = 'gplv2+' + inputs = ['logic'] + outputs = ['ook'] + channels = ( + {'id': 'data', 'name': 'Data', 'desc': 'Data line'}, + ) + annotations = ( + ('frame', 'Frame'), + ('info', 'Info'), + ('1111', '1111'), + ('1010', '1010'), + ('diffman', 'Diff Man'), + ('nrz', 'NRZ'), + ) + annotation_rows = ( + ('frame', 'Framing',(0,)), + ('info', 'Info', (1,)), + ('man1111', 'Man 1111', (2,)), + ('man1010', 'Man 1010', (3,)), + ('diffman', 'Diff Man', (4,)), + ('nrz', 'NRZ', (5,)), + ) + binary = ( + ('pulse-lengths', 'Pulse lengths'), + ) + options = ( + {'id': 'invert', 'desc': 'Invert data', 'default': 'no', + 'values': ('no', 'yes')}, + {'id': 'decodeas', 'desc': 'Decode type', 'default': 'Manchester', + 'values': ('NRZ', 'Manchester', 'Diff Manchester')}, + {'id': 'preamble', 'desc': 'Preamble', 'default': 'auto', + 'values': ('auto', '1010', '1111')}, + {'id': 'preamlen', 'desc': 'Filter length', 'default': '7', + 'values': ('0', '3', '4', '5', '6', '7', '8', '9', '10')}, + {'id': 'diffmanvar', 'desc': 'Transition at start', 'default': '1', + 'values': ('1', '0')}, + ) + + def __init__(self): + self.reset() + + def reset(self): + self.samplerate = None + self.ss = self.es = -1 + self.ss_1111 = self.ss_1010 = -1 + self.samplenumber_last = None + self.sample_first = None + self.sample_high = 0 + self.sample_low = 0 + self.edge_count = 0 + self.word_first = None + self.word_count = 0 + self.state = 'IDLE' + self.lstate = None + self.lstate_1010 = None + self.insync = 0 # Preamble in sync flag + self.man_errors = 0 + self.man_errors_1010 = 0 + self.preamble = [] # Preamble buffer + self.half_time = -1 # Half time for man 1111 + self.half_time_1010 = 0 # Half time for man 1010 + self.pulse_lengths = [] # Pulse lengths + self.decoded = [] # Decoded stream + self.decoded_1010 = [] # Decoded stream + self.diff_man_trans = '0' # Transition + self.diff_man_len = 1 # Length of pulse in half clock periods + self.max_errors = 5 # Max number of errors to output OOK + + def metadata(self, key, value): + if key == srd.SRD_CONF_SAMPLERATE: + self.samplerate = value + + def start(self): + self.out_ann = self.register(srd.OUTPUT_ANN) + self.out_python = self.register(srd.OUTPUT_PYTHON) + self.out_binary = self.register(srd.OUTPUT_BINARY) + self.invert = self.options['invert'] + self.decodeas = self.options['decodeas'] + self.preamble_val = self.options['preamble'] + self.preamble_len = self.options['preamlen'] + self.diffmanvar = self.options['diffmanvar'] + + def putx(self, data): + self.put(self.ss, self.es, self.out_ann, data) + + def putp(self, data): + self.put(self.ss, self.es, self.out_python, data) + + def dump_pulse_lengths(self): + if self.samplerate: + self.pulse_lengths[-1] = self.sample_first # Fix final pulse length. + mystring = 'Pulses(us)=' + mystring += ','.join(str(int(int(x) * 1000000 / self.samplerate)) + for x in self.pulse_lengths) + mystring += '\n' + self.put(self.samplenum - 10, self.samplenum, self.out_binary, + [0, bytes([ord(c) for c in mystring])]) + + def decode_nrz(self, start, samples, state): + self.pulse_lengths.append(samples) + # Use different high and low widths to compensate skewed waveforms. + if state == '1': + dsamples = self.sample_high + else: + dsamples = self.sample_low + self.ss = start + self.es = start + samples + while samples > dsamples * 0.5: + if samples >= dsamples * 1.5: # More than one bit. + self.es = self.ss + dsamples + self.putx([5, [state]]) + self.decoded.append([self.ss, self.es, state]) + self.edge_count += 1 + elif samples >= dsamples * 0.5 and samples < dsamples * 1.5: # Last bit. + self.putx([5, [state]]) + self.decoded.append([self.ss, self.es, state]) + self.edge_count += 1 + else: + self.edge_count += 1 + samples -= dsamples + self.ss += dsamples + self.es += dsamples + + # Ensure 2nd row doesn't go past end of 1st row. + if self.es > self.samplenum: + self.es = self.samplenum + + if self.state == 'DECODE_TIMEOUT': # Five bits - reset. + self.ss = self.decoded[0][0] + self.es = self.decoded[len(self.decoded) - 1][1] + self.dump_pulse_lengths() + self.putp(self.decoded) + self.decode_timeout() + break + + def lock_onto_preamble(self, samples, state): # Filters and recovers clock. + self.edge_count += 1 + l2s = 5 # Max ratio of long to short pulses. + + # Filter incoming pulses to remove random noise. + if self.state == 'DECODE_TIMEOUT': + self.preamble = [] + self.edge_count == 0 + self.word_first = self.samplenum + self.sample_first = self.samplenum - self.samplenumber_last + self.state = 'WAITING_FOR_PREAMBLE' + self.man_errors = 0 + + pre_detect = int(self.preamble_len) # Number of valid pulses to detect. + pre_samples = self.samplenum - self.samplenumber_last + if len(self.preamble) > 0: + if (pre_samples * l2s < self.preamble[-1][1] or + self.preamble[-1][1] * l2s < pre_samples): # Garbage in. + self.put(self.samplenum, self.samplenum, + self.out_ann, [0, ['R']]) # Display resets. + self.preamble = [] # Clear buffer. + self.preamble.append([self.samplenumber_last, + pre_samples, state]) + self.edge_count == 0 + self.samplenumber_last = self.samplenum + self.word_first = self.samplenum + else: + self.preamble.append([self.samplenumber_last, + pre_samples, state]) + else: + self.preamble.append([self.samplenumber_last, + pre_samples, state]) + + pre = self.preamble + if len(self.preamble) == pre_detect: # Have a valid series of pulses. + if self.preamble[0][2] == '1': + self.sample_high = self.preamble[0][1] # Allows skewed pulses. + self.sample_low = self.preamble[1][1] + else: + self.sample_high = self.preamble[1][1] + self.sample_low = self.preamble[0][1] + + self.edge_count = 0 + + for i in range(len(self.preamble)): + if i > 1: + if (pre[i][1] > pre[i - 2][1] * 1.25 or + pre[i][1] * 1.25 < pre[i - 2][1]): # Adjust ref width. + if pre[i][2] == '1': + self.sample_high = pre[i][1] + else: + self.sample_low = pre[i][1] + + # Display start of preamble. + if self.decodeas == 'NRZ': + self.decode_nrz(pre[i][0], pre[i][1], pre[i][2]) + if self.decodeas == 'Manchester': + self.decode_manchester(pre[i][0], pre[i][1], pre[i][2]) + if self.decodeas == 'Diff Manchester': + self.es = pre[i][0] + pre[i][1] + self.decode_diff_manchester(pre[i][0], pre[i][1], pre[i][2]) + + # Used to timeout signal. + self.sample_first = int((self.sample_high + self.sample_low)/2) + self.insync = 1 + self.state = 'DECODING' + self.lstate = state + self.lstate_1010 = state + + def decode_diff_manchester(self, start, samples, state): + self.pulse_lengths.append(samples) + + # Use different high and low widths to compensate skewed waveforms. + if state == '1': + dsamples = self.sample_high + else: + dsamples = self.sample_low + + self.es = start + samples + p_length = round(samples / dsamples) # Find relative pulse length. + + if self.edge_count == 0: + self.diff_man_trans = '1' # Very first pulse must be a transition. + self.diff_man_len = 1 # Must also be a half pulse. + self.ss = start + elif self.edge_count % 2 == 1: # Time to make a decision. + if self.diffmanvar == '0': # Transition at self.ss is a zero. + self.diff_man_trans = '0' if self.diff_man_trans == '1' else '1' + if self.diff_man_len == 1 and p_length == 1: + self.putx([4, [self.diff_man_trans]]) + self.decoded.append([self.ss, self.es, self.diff_man_trans]) + self.diff_man_trans = '1' + elif self.diff_man_len == 1 and p_length == 2: + self.es -= int(samples / 2) + self.putx([4, [self.diff_man_trans]]) + self.decoded.append([self.ss, self.es, self.diff_man_trans]) + self.diff_man_trans = '0' + self.edge_count += 1 # Add a virt edge to keep in sync with clk. + elif self.diff_man_len == 2 and p_length == 1: + self.putx([4, [self.diff_man_trans]]) + self.decoded.append([self.ss, self.es, self.diff_man_trans]) + self.diff_man_trans = '1' + elif self.diff_man_len == 2 and p_length == 2: # Double illegal E E. + self.es -= samples + self.putx([4, ['E']]) + self.decoded.append([self.ss, self.es, 'E']) + self.ss = self.es + self.es += samples + self.putx([4, ['E']]) + self.decoded.append([self.ss, self.es, 'E']) + self.diff_man_trans = '1' + elif self.diff_man_len == 1 and p_length > 4: + if self.state == 'DECODE_TIMEOUT': + self.es = self.ss + 2 * self.sample_first + self.putx([4, [self.diff_man_trans]]) # Write error. + self.decoded.append([self.ss, self.es, self.diff_man_trans]) + self.ss = self.decoded[0][0] + self.es = self.decoded[len(self.decoded) - 1][1] + self.dump_pulse_lengths() + if self.man_errors < self.max_errors: + self.putp(self.decoded) + else: + error_message = 'Probably not Diff Manchester encoded' + self.ss = self.word_first + self.putx([1, [error_message]]) + self.decode_timeout() + self.diff_man_trans = '1' + self.ss = self.es + self.diff_man_len = p_length # Save the previous length. + self.edge_count += 1 + + def decode_manchester_sim(self, start, samples, state, + dsamples, half_time, lstate, ss, pream): + ook_bit = [] + errors = 0 + if self.edge_count == 0: + half_time += 1 + if samples > 0.75 * dsamples and samples <= 1.5 * dsamples: # Long p. + half_time += 2 + if half_time % 2 == 0: # Transition. + es = start + else: + es = start + int(samples / 2) + if ss == start: + lstate = 'E' + es = start + samples + if not (self.edge_count == 0 and pream == '1010'): # Skip first p. + ook_bit = [ss, es, lstate] + lstate = state + ss = es + elif samples > 0.25 * dsamples and samples <= 0.75 * dsamples: # Short p. + half_time += 1 + if (half_time % 2 == 0): # Transition. + es = start + samples + ook_bit = [ss, es, lstate] + lstate = state + ss = es + else: # 1st half. + ss = start + lstate = state + else: # Too long or too short - error. + errors = 1 + if self.state != 'DECODE_TIMEOUT': # Error condition. + lstate = 'E' + es = ss + samples + else: # Assume final half bit buried in timeout pulse. + es = ss + self.sample_first + ook_bit = [ss, es, lstate] + ss = es + + return (half_time, lstate, ss, ook_bit, errors) + + def decode_manchester(self, start, samples, state): + self.pulse_lengths.append(samples) + + # Use different high and low widths to compensate skewed waveforms. + if state == '1': + dsamples = self.sample_high + else: + dsamples = self.sample_low + + if self.preamble_val != '1010': # 1111 preamble is half clock T. + (self.half_time, self.lstate, self.ss_1111, ook_bit, errors) = ( + self.decode_manchester_sim(start, samples, state, dsamples * 2, + self.half_time, self.lstate, + self.ss_1111, '1111')) + self.man_errors += errors + if ook_bit != []: + self.decoded.append([ook_bit[0], ook_bit[1], ook_bit[2]]) + + if self.preamble_val != '1111': # 1010 preamble is clock T. + (self.half_time_1010, self.lstate_1010, self.ss_1010, + ook_bit, errors) = ( + self.decode_manchester_sim(start, samples, state, dsamples, + self.half_time_1010, self.lstate_1010, + self.ss_1010, '1010')) + self.man_errors_1010 += errors + if ook_bit != []: + self.decoded_1010.append([ook_bit[0], ook_bit[1], ook_bit[2]]) + + self.edge_count += 1 + + # Stream display and save ook_bit. + if ook_bit != []: + self.ss = ook_bit[0] + self.es = ook_bit[1] + if self.preamble_val == '1111': + self.putx([2, [ook_bit[2]]]) + if self.preamble_val == '1010': + self.putx([3, [ook_bit[2]]]) + + if self.state == 'DECODE_TIMEOUT': # End of packet. + self.dump_pulse_lengths() + + decoded = [] + # If 1010 preamble has less errors use it. + if (self.preamble_val == '1010' or + (self.man_errors_1010 < self.max_errors and + self.man_errors_1010 < self.man_errors and + len(self.decoded_1010) > 0)): + decoded = self.decoded_1010 + man_errors = self.man_errors_1010 + d_row = 3 + else: + decoded = self.decoded + man_errors = self.man_errors + d_row = 2 + + if self.preamble_val == 'auto': # Display OOK packet. + for i in range(len(decoded)): + self.ss = decoded[i][0] + self.es = decoded[i][1] + self.putx([d_row, [decoded[i][2]]]) + + if (man_errors < self.max_errors and len(decoded) > 0): + self.ss = decoded[0][0] + self.es = decoded[len(decoded) - 1][1] + self.putp(decoded) + else: + error_message = 'Not Manchester encoded or wrong preamble' + self.ss = self.word_first + self.putx([1, [error_message]]) + + self.put(self.es, self.es, self.out_ann, [0, ['T']]) # Mark timeout. + self.decode_timeout() + + def decode_timeout(self): + self.word_count = 0 + self.samplenumber_last = None + self.edge_count = 0 + self.man_errors = 0 # Clear the bit error counters. + self.man_errors_1010 = 0 + self.state = 'IDLE' + self.wait({0: 'e'}) # Get rid of long pulse. + self.samplenumber_last = self.samplenum + self.word_first = self.samplenum + self.insync = 0 # Preamble in sync flag + self.preamble = [] # Preamble buffer + self.half_time = -1 # Half time for man 1111 + self.half_time_1010 = 0 # Half time for man 1010 + self.decoded = [] # Decoded bits + self.decoded_1010 = [] # Decoded bits for man 1010 + self.pulse_lengths = [] + + def decode(self): + while True: + if self.edge_count == 0: # Waiting for a signal. + pin = self.wait({0: 'e'}) + self.state = 'DECODING' + else: + pin = self.wait([{0: 'e'}, {'skip': 5 * self.sample_first}]) + if self.matched[1] and not self.matched[0]: # No edges for 5 p's. + self.state = 'DECODE_TIMEOUT' + + if not self.samplenumber_last: # Set counters to start of signal. + self.samplenumber_last = self.samplenum + self.word_first = self.samplenum + continue + samples = self.samplenum - self.samplenumber_last + if not self.sample_first: # Get number of samples for first pulse. + self.sample_first = samples + + pinstate = pin[0] + if self.state == 'DECODE_TIMEOUT': # No edge so flip the state. + pinstate = int(not pinstate) + if self.invert == 'yes': # Invert signal. + pinstate = int(not pinstate) + if pinstate: + state = '0' + else: + state = '1' + + # No preamble filtering or checking and no skew correction. + if self.preamble_len == '0': + self.sample_high = self.sample_first + self.sample_low = self.sample_first + self.insync = 0 + + if self.insync == 0: + self.lock_onto_preamble(samples, state) + else: + if self.decodeas == 'NRZ': + self.decode_nrz(self.samplenumber_last, samples, state) + if self.decodeas == 'Manchester': + self.decode_manchester(self.samplenumber_last, + samples, state) + if self.decodeas == 'Diff Manchester': + self.decode_diff_manchester(self.samplenumber_last, + samples, state) + + self.samplenumber_last = self.samplenum