[libsigrokdecode.git] / decoders / onewire_link / pd.py

##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2012 Iztok Jeras <iztok.jeras@gmail.com>
##
## 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 <http://www.gnu.org/licenses/>.
##

import sigrokdecode as srd

class SamplerateError(Exception):
    pass

class Decoder(srd.Decoder):
    api_version = 3
    id = 'onewire_link'
    name = '1-Wire link layer'
    longname = '1-Wire serial communication bus (link layer)'
    desc = 'Bidirectional, half-duplex, asynchronous serial bus.'
    license = 'gplv2+'
    inputs = ['logic']
    outputs = ['onewire_link']
    channels = (
        {'id': 'owr', 'name': 'OWR', 'desc': '1-Wire signal line'},
    )
    optional_channels = (
        {'id': 'pwr', 'name': 'PWR', 'desc': '1-Wire power supply pin'},
    )
    options = (
        {'id': 'overdrive',
            'desc': 'Overdrive mode', 'default': 'no', 'values': ('yes', 'no')},
        # Time options (specified in microseconds):
        {'id': 'cnt_normal_bit',
            'desc': 'Normal mode sample bit time (μs)', 'default': 15},
        {'id': 'cnt_normal_slot',
            'desc': 'Normal mode data slot time (μs)', 'default': 60},
        {'id': 'cnt_normal_presence',
            'desc': 'Normal mode sample presence time (μs)', 'default': 75},
        {'id': 'cnt_normal_reset',
            'desc': 'Normal mode reset time (μs)', 'default': 480},
        {'id': 'cnt_overdrive_bit',
            'desc': 'Overdrive mode sample bit time (μs)', 'default': 2},
        {'id': 'cnt_overdrive_slot',
            'desc': 'Overdrive mode data slot time (μs)', 'default': 7.3},
        {'id': 'cnt_overdrive_presence',
            'desc': 'Overdrive mode sample presence time (μs)', 'default': 10},
        {'id': 'cnt_overdrive_reset',
            'desc': 'Overdrive mode reset time (μs)', 'default': 48},
    )
    annotations = (
        ('bit', 'Bit'),
        ('warnings', 'Warnings'),
        ('reset', 'Reset'),
        ('presence', 'Presence'),
        ('overdrive', 'Overdrive mode notifications'),
    )
    annotation_rows = (
        ('bits', 'Bits', (0, 2, 3)),
        ('info', 'Info', (4,)),
        ('warnings', 'Warnings', (1,)),
    )

    def putm(self, data):
        self.put(0, 0, self.out_ann, data)

    def putpb(self, data):
        self.put(self.fall, self.samplenum, self.out_python, data)

    def putb(self, data):
        self.put(self.fall, self.samplenum, self.out_ann, data)

    def putx(self, data):
        self.put(self.fall, self.cnt_bit[self.overdrive], self.out_ann, data)

    def putfr(self, data):
        self.put(self.fall, self.rise, self.out_ann, data)

    def putprs(self, data):
        self.put(self.rise, self.samplenum, self.out_python, data)

    def putrs(self, data):
        self.put(self.rise, self.samplenum, self.out_ann, data)

    def __init__(self):
        self.samplerate = None
        self.state = 'WAIT FOR FALLING EDGE'
        self.present = 0
        self.bit = 0
        self.bit_cnt = 0
        self.command = 0
        self.overdrive = 0
        self.fall = 0
        self.rise = 0

    def start(self):
        self.out_python = self.register(srd.OUTPUT_PYTHON)
        self.out_ann = self.register(srd.OUTPUT_ANN)

        self.initial_pins = [1, 1]

    def checks(self):
        # Check if samplerate is appropriate.
        if self.options['overdrive'] == 'yes':
            if self.samplerate < 2000000:
                self.putm([1, ['Sampling rate is too low. Must be above ' +
                               '2MHz for proper overdrive mode decoding.']])
            elif self.samplerate < 5000000:
                self.putm([1, ['Sampling rate is suggested to be above 5MHz ' +
                               'for proper overdrive mode decoding.']])
        else:
            if self.samplerate < 400000:
                self.putm([1, ['Sampling rate is too low. Must be above ' +
                               '400kHz for proper normal mode decoding.']])
            elif self.samplerate < 1000000:
                self.putm([1, ['Sampling rate is suggested to be above ' +
                               '1MHz for proper normal mode decoding.']])

        # Check if sample times are in the allowed range.

        time_min = float(self.cnt_normal_bit) / self.samplerate
        time_max = float(self.cnt_normal_bit + 1) / self.samplerate
        if (time_min < 0.000005) or (time_max > 0.000015):
            self.putm([1, ['The normal mode data sample time interval ' +
                 '(%2.1fus-%2.1fus) should be inside (5.0us, 15.0us).'
                 % (time_min * 1000000, time_max * 1000000)]])

        time_min = float(self.cnt_normal_presence) / self.samplerate
        time_max = float(self.cnt_normal_presence + 1) / self.samplerate
        if (time_min < 0.0000681) or (time_max > 0.000075):
            self.putm([1, ['The normal mode presence sample time interval ' +
                 '(%2.1fus-%2.1fus) should be inside (68.1us, 75.0us).'
                 % (time_min * 1000000, time_max * 1000000)]])

        time_min = float(self.cnt_overdrive_bit) / self.samplerate
        time_max = float(self.cnt_overdrive_bit + 1) / self.samplerate
        if (time_min < 0.000001) or (time_max > 0.000002):
            self.putm([1, ['The overdrive mode data sample time interval ' +
                 '(%2.1fus-%2.1fus) should be inside (1.0us, 2.0us).'
                 % (time_min * 1000000, time_max * 1000000)]])

        time_min = float(self.cnt_overdrive_presence) / self.samplerate
        time_max = float(self.cnt_overdrive_presence + 1) / self.samplerate
        if (time_min < 0.0000073) or (time_max > 0.000010):
            self.putm([1, ['The overdrive mode presence sample time interval ' +
                 '(%2.1fus-%2.1fus) should be inside (7.3us, 10.0us).'
                 % (time_min * 1000000, time_max * 1000000)]])


    def metadata(self, key, value):
        if key != srd.SRD_CONF_SAMPLERATE:
            return
        self.samplerate = value

        # The default 1-Wire time base is 30us. This is used to calculate
        # sampling times.
        samplerate = float(self.samplerate)

        x = float(self.options['cnt_normal_bit']) / 1000000.0
        self.cnt_normal_bit = int(samplerate * x) - 1
        x = float(self.options['cnt_normal_slot']) / 1000000.0
        self.cnt_normal_slot = int(samplerate * x) - 1
        x = float(self.options['cnt_normal_presence']) / 1000000.0
        self.cnt_normal_presence = int(samplerate * x) - 1
        x = float(self.options['cnt_normal_reset']) / 1000000.0
        self.cnt_normal_reset = int(samplerate * x) - 1
        x = float(self.options['cnt_overdrive_bit']) / 1000000.0
        self.cnt_overdrive_bit = int(samplerate * x) - 1
        x = float(self.options['cnt_overdrive_slot']) / 1000000.0
        self.cnt_overdrive_slot = int(samplerate * x) - 1
        x = float(self.options['cnt_overdrive_presence']) / 1000000.0
        self.cnt_overdrive_presence = int(samplerate * x) - 1
        x = float(self.options['cnt_overdrive_reset']) / 1000000.0
        self.cnt_overdrive_reset = int(samplerate * x) - 1

        # Organize values into lists.
        self.cnt_bit = [self.cnt_normal_bit, self.cnt_overdrive_bit]
        self.cnt_presence = [self.cnt_normal_presence, self.cnt_overdrive_presence]
        self.cnt_reset = [self.cnt_normal_reset, self.cnt_overdrive_reset]
        self.cnt_slot = [self.cnt_normal_slot, self.cnt_overdrive_slot]

    def decode(self):
        if not self.samplerate:
            raise SamplerateError('Cannot decode without samplerate.')
        self.checks()
        while True:
            # State machine.
            if self.state == 'WAIT FOR FALLING EDGE':
                # The start of a cycle is a falling edge on OWR.
                self.wait({0: 'f'})
                # Save the sample number for the falling edge.
                self.fall = self.samplenum
                self.state = 'WAIT FOR DATA SAMPLE'
            elif self.state == 'WAIT FOR DATA SAMPLE':
                # Sample data bit.
                t = self.fall + self.cnt_bit[self.overdrive]
                self.bit, pwr = self.wait({'skip': t - self.samplenum})
                self.state = 'WAIT FOR DATA SLOT END'
            elif self.state == 'WAIT FOR DATA SLOT END':
                # A data slot ends in a recovery period, otherwise, this is
                # probably a reset.
                t = self.fall + self.cnt_slot[self.overdrive]
                owr, pwr = self.wait({'skip': t - self.samplenum})

                if owr == 0:
                    # This seems to be a reset slot, wait for its end.
                    self.state = 'WAIT FOR RISING EDGE'
                    continue

                self.putb([0, ['Bit: %d' % self.bit, '%d' % self.bit]])
                self.putpb(['BIT', self.bit])

                # Checking the first command to see if overdrive mode
                # should be entered.
                if self.bit_cnt <= 8:
                    self.command |= (self.bit << self.bit_cnt)
                elif self.bit_cnt == 8 and self.command in [0x3c, 0x69]:
                    self.putx([4, ['Entering overdrive mode', 'Overdrive on']])
                # Increment the bit counter.
                self.bit_cnt += 1
                # Wait for next slot.
                self.state = 'WAIT FOR FALLING EDGE'
            elif self.state == 'WAIT FOR RISING EDGE':
                # The end of a cycle is a rising edge.
                self.wait({0: 'r'})

                # Check if this was a reset cycle.
                t = self.samplenum - self.fall
                if t > self.cnt_normal_reset:
                    # Save the sample number for the rising edge.
                    self.rise = self.samplenum
                    self.putfr([2, ['Reset', 'Rst', 'R']])
                    self.state = 'WAIT FOR PRESENCE DETECT'
                    # Exit overdrive mode.
                    if self.overdrive:
                        self.putx([4, ['Exiting overdrive mode', 'Overdrive off']])
                        self.overdrive = 0
                    # Clear command bit counter and data register.
                    self.bit_cnt = 0
                    self.command = 0
                elif (t > self.cnt_overdrive_reset) and self.overdrive:
                    # Save the sample number for the rising edge.
                    self.rise = self.samplenum
                    self.putfr([2, ['Reset', 'Rst', 'R']])
                    self.state = 'WAIT FOR PRESENCE DETECT'
                # Otherwise this is assumed to be a data bit.
                else:
                    self.state = 'WAIT FOR FALLING EDGE'
            elif self.state == 'WAIT FOR PRESENCE DETECT':
                # Sample presence status.
                t = self.rise + self.cnt_presence[self.overdrive]
                owr, pwr = self.wait({'skip': t - self.samplenum})
                self.present = owr
                self.state = 'WAIT FOR RESET SLOT END'
            elif self.state == 'WAIT FOR RESET SLOT END':
                # A reset slot ends in a long recovery period.
                t = self.rise + self.cnt_reset[self.overdrive]
                owr, pwr = self.wait({'skip': t - self.samplenum})

                if owr == 0:
                    # This seems to be a reset slot, wait for its end.
                    self.state = 'WAIT FOR RISING EDGE'
                    continue

                p = 'false' if self.present else 'true'
                self.putrs([3, ['Presence: %s' % p, 'Presence', 'Pres', 'P']])
                self.putprs(['RESET/PRESENCE', not self.present])

                # Wait for next slot.
                self.state = 'WAIT FOR FALLING EDGE'
Commit	Line	Data
	1	##
	2	## This file is part of the libsigrokdecode project.
	3	##
	4	## Copyright (C) 2012 Iztok Jeras <iztok.jeras@gmail.com>
	5	##
	6	## This program is free software; you can redistribute it and/or modify
	7	## it under the terms of the GNU General Public License as published by
	8	## the Free Software Foundation; either version 2 of the License, or
	9	## (at your option) any later version.
	10	##
	11	## This program is distributed in the hope that it will be useful,
	12	## but WITHOUT ANY WARRANTY; without even the implied warranty of
	13	## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	14	## GNU General Public License for more details.
	15	##
	16	## You should have received a copy of the GNU General Public License
	17	## along with this program; if not, see <http://www.gnu.org/licenses/>.
	18	##
	19
	20	import sigrokdecode as srd
	21
	22	class SamplerateError(Exception):
	23	pass
	24
	25	class Decoder(srd.Decoder):
	26	api_version = 3
	27	id = 'onewire_link'
	28	name = '1-Wire link layer'
	29	longname = '1-Wire serial communication bus (link layer)'
	30	desc = 'Bidirectional, half-duplex, asynchronous serial bus.'
	31	license = 'gplv2+'
	32	inputs = ['logic']
	33	outputs = ['onewire_link']
	34	channels = (
	35	{'id': 'owr', 'name': 'OWR', 'desc': '1-Wire signal line'},
	36	)
	37	optional_channels = (
	38	{'id': 'pwr', 'name': 'PWR', 'desc': '1-Wire power supply pin'},
	39	)
	40	options = (
	41	{'id': 'overdrive',
	42	'desc': 'Overdrive mode', 'default': 'no', 'values': ('yes', 'no')},
	43	# Time options (specified in microseconds):
	44	{'id': 'cnt_normal_bit',
	45	'desc': 'Normal mode sample bit time (μs)', 'default': 15},
	46	{'id': 'cnt_normal_slot',
	47	'desc': 'Normal mode data slot time (μs)', 'default': 60},
	48	{'id': 'cnt_normal_presence',
	49	'desc': 'Normal mode sample presence time (μs)', 'default': 75},
	50	{'id': 'cnt_normal_reset',
	51	'desc': 'Normal mode reset time (μs)', 'default': 480},
	52	{'id': 'cnt_overdrive_bit',
	53	'desc': 'Overdrive mode sample bit time (μs)', 'default': 2},
	54	{'id': 'cnt_overdrive_slot',
	55	'desc': 'Overdrive mode data slot time (μs)', 'default': 7.3},
	56	{'id': 'cnt_overdrive_presence',
	57	'desc': 'Overdrive mode sample presence time (μs)', 'default': 10},
	58	{'id': 'cnt_overdrive_reset',
	59	'desc': 'Overdrive mode reset time (μs)', 'default': 48},
	60	)
	61	annotations = (
	62	('bit', 'Bit'),
	63	('warnings', 'Warnings'),
	64	('reset', 'Reset'),
	65	('presence', 'Presence'),
	66	('overdrive', 'Overdrive mode notifications'),
	67	)
	68	annotation_rows = (
	69	('bits', 'Bits', (0, 2, 3)),
	70	('info', 'Info', (4,)),
	71	('warnings', 'Warnings', (1,)),
	72	)
	73
	74	def putm(self, data):
	75	self.put(0, 0, self.out_ann, data)
	76
	77	def putpb(self, data):
	78	self.put(self.fall, self.samplenum, self.out_python, data)
	79
	80	def putb(self, data):
	81	self.put(self.fall, self.samplenum, self.out_ann, data)
	82
	83	def putx(self, data):
	84	self.put(self.fall, self.cnt_bit[self.overdrive], self.out_ann, data)
	85
	86	def putfr(self, data):
	87	self.put(self.fall, self.rise, self.out_ann, data)
	88
	89	def putprs(self, data):
	90	self.put(self.rise, self.samplenum, self.out_python, data)
	91
	92	def putrs(self, data):
	93	self.put(self.rise, self.samplenum, self.out_ann, data)
	94
	95	def __init__(self):
	96	self.samplerate = None
	97	self.state = 'WAIT FOR FALLING EDGE'
	98	self.present = 0
	99	self.bit = 0
	100	self.bit_cnt = 0
	101	self.command = 0
	102	self.overdrive = 0
	103	self.fall = 0
	104	self.rise = 0
	105
	106	def start(self):
	107	self.out_python = self.register(srd.OUTPUT_PYTHON)
	108	self.out_ann = self.register(srd.OUTPUT_ANN)
	109
	110	self.initial_pins = [1, 1]
	111
	112	def checks(self):
	113	# Check if samplerate is appropriate.
	114	if self.options['overdrive'] == 'yes':
	115	if self.samplerate < 2000000:
	116	self.putm([1, ['Sampling rate is too low. Must be above ' +
	117	'2MHz for proper overdrive mode decoding.']])
	118	elif self.samplerate < 5000000:
	119	self.putm([1, ['Sampling rate is suggested to be above 5MHz ' +
	120	'for proper overdrive mode decoding.']])
	121	else:
	122	if self.samplerate < 400000:
	123	self.putm([1, ['Sampling rate is too low. Must be above ' +
	124	'400kHz for proper normal mode decoding.']])
	125	elif self.samplerate < 1000000:
	126	self.putm([1, ['Sampling rate is suggested to be above ' +
	127	'1MHz for proper normal mode decoding.']])
	128
	129	# Check if sample times are in the allowed range.
	130
	131	time_min = float(self.cnt_normal_bit) / self.samplerate
	132	time_max = float(self.cnt_normal_bit + 1) / self.samplerate
	133	if (time_min < 0.000005) or (time_max > 0.000015):
	134	self.putm([1, ['The normal mode data sample time interval ' +
	135	'(%2.1fus-%2.1fus) should be inside (5.0us, 15.0us).'
	136	% (time_min * 1000000, time_max * 1000000)]])
	137
	138	time_min = float(self.cnt_normal_presence) / self.samplerate
	139	time_max = float(self.cnt_normal_presence + 1) / self.samplerate
	140	if (time_min < 0.0000681) or (time_max > 0.000075):
	141	self.putm([1, ['The normal mode presence sample time interval ' +
	142	'(%2.1fus-%2.1fus) should be inside (68.1us, 75.0us).'
	143	% (time_min * 1000000, time_max * 1000000)]])
	144
	145	time_min = float(self.cnt_overdrive_bit) / self.samplerate
	146	time_max = float(self.cnt_overdrive_bit + 1) / self.samplerate
	147	if (time_min < 0.000001) or (time_max > 0.000002):
	148	self.putm([1, ['The overdrive mode data sample time interval ' +
	149	'(%2.1fus-%2.1fus) should be inside (1.0us, 2.0us).'
	150	% (time_min * 1000000, time_max * 1000000)]])
	151
	152	time_min = float(self.cnt_overdrive_presence) / self.samplerate
	153	time_max = float(self.cnt_overdrive_presence + 1) / self.samplerate
	154	if (time_min < 0.0000073) or (time_max > 0.000010):
	155	self.putm([1, ['The overdrive mode presence sample time interval ' +
	156	'(%2.1fus-%2.1fus) should be inside (7.3us, 10.0us).'
	157	% (time_min * 1000000, time_max * 1000000)]])
	158
	159
	160	def metadata(self, key, value):
	161	if key != srd.SRD_CONF_SAMPLERATE:
	162	return
	163	self.samplerate = value
	164
	165	# The default 1-Wire time base is 30us. This is used to calculate
	166	# sampling times.
	167	samplerate = float(self.samplerate)
	168
	169	x = float(self.options['cnt_normal_bit']) / 1000000.0
	170	self.cnt_normal_bit = int(samplerate * x) - 1
	171	x = float(self.options['cnt_normal_slot']) / 1000000.0
	172	self.cnt_normal_slot = int(samplerate * x) - 1
	173	x = float(self.options['cnt_normal_presence']) / 1000000.0
	174	self.cnt_normal_presence = int(samplerate * x) - 1
	175	x = float(self.options['cnt_normal_reset']) / 1000000.0
	176	self.cnt_normal_reset = int(samplerate * x) - 1
	177	x = float(self.options['cnt_overdrive_bit']) / 1000000.0
	178	self.cnt_overdrive_bit = int(samplerate * x) - 1
	179	x = float(self.options['cnt_overdrive_slot']) / 1000000.0
	180	self.cnt_overdrive_slot = int(samplerate * x) - 1
	181	x = float(self.options['cnt_overdrive_presence']) / 1000000.0
	182	self.cnt_overdrive_presence = int(samplerate * x) - 1
	183	x = float(self.options['cnt_overdrive_reset']) / 1000000.0
	184	self.cnt_overdrive_reset = int(samplerate * x) - 1
	185
	186	# Organize values into lists.
	187	self.cnt_bit = [self.cnt_normal_bit, self.cnt_overdrive_bit]
	188	self.cnt_presence = [self.cnt_normal_presence, self.cnt_overdrive_presence]
	189	self.cnt_reset = [self.cnt_normal_reset, self.cnt_overdrive_reset]
	190	self.cnt_slot = [self.cnt_normal_slot, self.cnt_overdrive_slot]
	191
	192	def decode(self):
	193	if not self.samplerate:
	194	raise SamplerateError('Cannot decode without samplerate.')
	195	self.checks()
	196	while True:
	197	# State machine.
	198	if self.state == 'WAIT FOR FALLING EDGE':
	199	# The start of a cycle is a falling edge on OWR.
	200	self.wait({0: 'f'})
	201	# Save the sample number for the falling edge.
	202	self.fall = self.samplenum
	203	self.state = 'WAIT FOR DATA SAMPLE'
	204	elif self.state == 'WAIT FOR DATA SAMPLE':
	205	# Sample data bit.
	206	t = self.fall + self.cnt_bit[self.overdrive]
	207	self.bit, pwr = self.wait({'skip': t - self.samplenum})
	208	self.state = 'WAIT FOR DATA SLOT END'
	209	elif self.state == 'WAIT FOR DATA SLOT END':
	210	# A data slot ends in a recovery period, otherwise, this is
	211	# probably a reset.
	212	t = self.fall + self.cnt_slot[self.overdrive]
	213	owr, pwr = self.wait({'skip': t - self.samplenum})
	214
	215	if owr == 0:
	216	# This seems to be a reset slot, wait for its end.
	217	self.state = 'WAIT FOR RISING EDGE'
	218	continue
	219
	220	self.putb([0, ['Bit: %d' % self.bit, '%d' % self.bit]])
	221	self.putpb(['BIT', self.bit])
	222
	223	# Checking the first command to see if overdrive mode
	224	# should be entered.
	225	if self.bit_cnt <= 8:
	226	self.command \|= (self.bit << self.bit_cnt)
	227	elif self.bit_cnt == 8 and self.command in [0x3c, 0x69]:
	228	self.putx([4, ['Entering overdrive mode', 'Overdrive on']])
	229	# Increment the bit counter.
	230	self.bit_cnt += 1
	231	# Wait for next slot.
	232	self.state = 'WAIT FOR FALLING EDGE'
	233	elif self.state == 'WAIT FOR RISING EDGE':
	234	# The end of a cycle is a rising edge.
	235	self.wait({0: 'r'})
	236
	237	# Check if this was a reset cycle.
	238	t = self.samplenum - self.fall
	239	if t > self.cnt_normal_reset:
	240	# Save the sample number for the rising edge.
	241	self.rise = self.samplenum
	242	self.putfr([2, ['Reset', 'Rst', 'R']])
	243	self.state = 'WAIT FOR PRESENCE DETECT'
	244	# Exit overdrive mode.
	245	if self.overdrive:
	246	self.putx([4, ['Exiting overdrive mode', 'Overdrive off']])
	247	self.overdrive = 0
	248	# Clear command bit counter and data register.
	249	self.bit_cnt = 0
	250	self.command = 0
	251	elif (t > self.cnt_overdrive_reset) and self.overdrive:
	252	# Save the sample number for the rising edge.
	253	self.rise = self.samplenum
	254	self.putfr([2, ['Reset', 'Rst', 'R']])
	255	self.state = 'WAIT FOR PRESENCE DETECT'
	256	# Otherwise this is assumed to be a data bit.
	257	else:
	258	self.state = 'WAIT FOR FALLING EDGE'
	259	elif self.state == 'WAIT FOR PRESENCE DETECT':
	260	# Sample presence status.
	261	t = self.rise + self.cnt_presence[self.overdrive]
	262	owr, pwr = self.wait({'skip': t - self.samplenum})
	263	self.present = owr
	264	self.state = 'WAIT FOR RESET SLOT END'
	265	elif self.state == 'WAIT FOR RESET SLOT END':
	266	# A reset slot ends in a long recovery period.
	267	t = self.rise + self.cnt_reset[self.overdrive]
	268	owr, pwr = self.wait({'skip': t - self.samplenum})
	269
	270	if owr == 0:
	271	# This seems to be a reset slot, wait for its end.
	272	self.state = 'WAIT FOR RISING EDGE'
	273	continue
	274
	275	p = 'false' if self.present else 'true'
	276	self.putrs([3, ['Presence: %s' % p, 'Presence', 'Pres', 'P']])
	277	self.putprs(['RESET/PRESENCE', not self.present])
	278
	279	# Wait for next slot.
	280	self.state = 'WAIT FOR FALLING EDGE'