##
## This file is part of the libsigrokdecode project.
##
-## Copyright (C) 2012 Uwe Hermann <uwe@hermann-uwe.de>
+## Copyright (C) 2012-2016 Uwe Hermann <uwe@hermann-uwe.de>
##
## 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
## 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, write to the Free Software
-## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
+## along with this program; if not, see <http://www.gnu.org/licenses/>.
##
-# DCF77 protocol decoder
-
import sigrokdecode as srd
import calendar
+from common.srdhelper import bcd2int
-# Return the specified BCD number (max. 8 bits) as integer.
-def bcd2int(b):
- return (b & 0x0f) + ((b >> 4) * 10)
+class SamplerateError(Exception):
+ pass
class Decoder(srd.Decoder):
- api_version = 1
+ api_version = 3
id = 'dcf77'
name = 'DCF77'
longname = 'DCF77 time protocol'
desc = 'European longwave time signal (77.5kHz carrier signal).'
license = 'gplv2+'
inputs = ['logic']
- outputs = ['dcf77']
- probes = [
+ outputs = []
+ tags = ['Clock/timing']
+ channels = (
{'id': 'data', 'name': 'DATA', 'desc': 'DATA line'},
- ]
- optional_probes = [
- {'id': 'pon', 'name': 'PON', 'desc': 'Power on'},
- ]
- options = {}
- annotations = [
- ['Text', 'Human-readable text'],
- ['Warnings', 'Human-readable warnings'],
- ]
+ )
+ annotations = (
+ ('start-of-minute', 'Start of minute'),
+ ('special-bit', 'Special bit (civil warnings, weather forecast)'),
+ ('call-bit', 'Call bit'),
+ ('summer-time', 'Summer time announcement'),
+ ('cest', 'CEST bit'),
+ ('cet', 'CET bit'),
+ ('leap-second', 'Leap second bit'),
+ ('start-of-time', 'Start of encoded time'),
+ ('minute', 'Minute'),
+ ('minute-parity', 'Minute parity bit'),
+ ('hour', 'Hour'),
+ ('hour-parity', 'Hour parity bit'),
+ ('day', 'Day of month'),
+ ('day-of-week', 'Day of week'),
+ ('month', 'Month'),
+ ('year', 'Year'),
+ ('date-parity', 'Date parity bit'),
+ ('raw-bit', 'Raw bit'),
+ ('unknown-bit', 'Unknown bit'),
+ ('warning', 'Warning'),
+ )
+ annotation_rows = (
+ ('bits', 'Bits', (17, 18)),
+ ('fields', 'Fields', tuple(range(0, 16 + 1))),
+ ('warnings', 'Warnings', (19,)),
+ )
+
+ def __init__(self):
+ self.reset()
- def __init__(self, **kwargs):
+ def reset(self):
+ self.samplerate = None
self.state = 'WAIT FOR RISING EDGE'
- self.oldpins = None
- self.oldval = None
- self.oldpon = None
- self.samplenum = 0
- self.bit_start = 0
- self.bit_start_old = 0
+ self.ss_bit = self.ss_bit_old = self.es_bit = self.ss_block = 0
+ self.datebits = []
self.bitcount = 0 # Counter for the DCF77 bits (0..58)
self.dcf77_bitnumber_is_known = 0
- def start(self, metadata):
- self.samplerate = metadata['samplerate']
- # self.out_proto = self.add(srd.OUTPUT_PROTO, 'dcf77')
- self.out_ann = self.add(srd.OUTPUT_ANN, 'dcf77')
+ def start(self):
+ self.out_ann = self.register(srd.OUTPUT_ANN)
+
+ def metadata(self, key, value):
+ if key == srd.SRD_CONF_SAMPLERATE:
+ self.samplerate = value
- def report(self):
- pass
+ def putx(self, data):
+ # Annotation for a single DCF77 bit.
+ self.put(self.ss_bit, self.es_bit, self.out_ann, data)
+
+ def putb(self, data):
+ # Annotation for a multi-bit DCF77 field.
+ self.put(self.ss_block, self.samplenum, self.out_ann, data)
# TODO: Which range to use? Only the 100ms/200ms or full second?
def handle_dcf77_bit(self, bit):
c = self.bitcount
- a = self.out_ann
- ss = es = 0 # FIXME
# Create one annotation for each DCF77 bit (containing the 0/1 value).
# Use 'Unknown DCF77 bit x: val' if we're not sure yet which of the
# 0..58 bits it is (because we haven't seen a 'new minute' marker yet).
# Otherwise, use 'DCF77 bit x: val'.
- s = '' if self.dcf77_bitnumber_is_known else 'Unknown '
- self.put(ss, es, a, [0, ['%sDCF77 bit %d: %d' % (s, c, bit)]])
+ s = 'B' if self.dcf77_bitnumber_is_known else 'Unknown b'
+ ann = 17 if self.dcf77_bitnumber_is_known else 18
+ self.putx([ann, ['%sit %d: %d' % (s, c, bit), '%d' % bit]])
# If we're not sure yet which of the 0..58 DCF77 bits we have, return.
# We don't want to decode bogus data.
if not self.dcf77_bitnumber_is_known:
return
+ # Collect bits 36-58, we'll need them for a parity check later.
+ if c in range(36, 58 + 1):
+ self.datebits.append(bit)
+
# Output specific "decoded" annotations for the respective DCF77 bits.
if c == 0:
# Start of minute: DCF bit 0.
if bit == 0:
- self.put(ss, es, a, [0, ['Start of minute (always 0)']])
+ self.putx([0, ['Start of minute (always 0)',
+ 'Start of minute', 'SoM']])
else:
- self.put(ss, es, a, [0, ['ERROR: Start of minute != 0']])
+ self.putx([19, ['Start of minute != 0', 'SoM != 0']])
elif c in range(1, 14 + 1):
# Special bits (civil warnings, weather forecast): DCF77 bits 1-14.
if c == 1:
self.tmp = bit
+ self.ss_block = self.ss_bit
else:
self.tmp |= (bit << (c - 1))
if c == 14:
- self.put(ss, es, a, [0, ['Special bits: %s' % bin(self.tmp)]])
+ s = '{:014b}'.format(self.tmp)
+ self.putb([1, ['Special bits: %s' % s, 'SB: %s' % s]])
elif c == 15:
s = '' if (bit == 1) else 'not '
- self.put(ss, es, a, [0, ['Call bit is %sset' % s]])
+ self.putx([2, ['Call bit: %sset' % s, 'CB: %sset' % s]])
# TODO: Previously this bit indicated use of the backup antenna.
elif c == 16:
s = '' if (bit == 1) else 'not '
- self.put(ss, es, a, [0, ['Summer time announcement %sactive' % s]])
+ x = 'yes' if (bit == 1) else 'no'
+ self.putx([3, ['Summer time announcement: %sactive' % s,
+ 'Summer time: %sactive' % s,
+ 'Summer time: %s' % x, 'ST: %s' % x]])
elif c == 17:
s = '' if (bit == 1) else 'not '
- self.put(ss, es, a, [0, ['CEST is %sin effect' % s]])
+ x = 'yes' if (bit == 1) else 'no'
+ self.putx([4, ['CEST: %sin effect' % s, 'CEST: %s' % x]])
elif c == 18:
s = '' if (bit == 1) else 'not '
- self.put(ss, es, a, [0, ['CET is %sin effect' % s]])
+ x = 'yes' if (bit == 1) else 'no'
+ self.putx([5, ['CET: %sin effect' % s, 'CET: %s' % x]])
elif c == 19:
s = '' if (bit == 1) else 'not '
- self.put(ss, es, a, [0, ['Leap second announcement %sactive' % s]])
+ x = 'yes' if (bit == 1) else 'no'
+ self.putx([6, ['Leap second announcement: %sactive' % s,
+ 'Leap second: %sactive' % s,
+ 'Leap second: %s' % x, 'LS: %s' % x]])
elif c == 20:
# Start of encoded time: DCF bit 20.
if bit == 1:
- self.put(ss, es, a, [0, ['Start of encoded time (always 1)']])
+ self.putx([7, ['Start of encoded time (always 1)',
+ 'Start of encoded time', 'SoeT']])
else:
- self.put(ss, es, a,
- [0, ['ERROR: Start of encoded time != 1']])
+ self.putx([19, ['Start of encoded time != 1', 'SoeT != 1']])
elif c in range(21, 27 + 1):
# Minutes (0-59): DCF77 bits 21-27 (BCD format).
if c == 21:
self.tmp = bit
+ self.ss_block = self.ss_bit
else:
self.tmp |= (bit << (c - 21))
if c == 27:
- self.put(ss, es, a, [0, ['Minutes: %d' % bcd2int(self.tmp)]])
+ m = bcd2int(self.tmp)
+ self.putb([8, ['Minutes: %d' % m, 'Min: %d' % m]])
elif c == 28:
# Even parity over minute bits (21-28): DCF77 bit 28.
self.tmp |= (bit << (c - 21))
parity = bin(self.tmp).count('1')
s = 'OK' if ((parity % 2) == 0) else 'INVALID!'
- self.put(ss, es, a, [0, ['Minute parity: %s' % s]])
+ self.putx([9, ['Minute parity: %s' % s, 'Min parity: %s' % s]])
elif c in range(29, 34 + 1):
# Hours (0-23): DCF77 bits 29-34 (BCD format).
if c == 29:
self.tmp = bit
+ self.ss_block = self.ss_bit
else:
self.tmp |= (bit << (c - 29))
if c == 34:
- self.put(ss, es, a, [0, ['Hours: %d' % bcd2int(self.tmp)]])
+ self.putb([10, ['Hours: %d' % bcd2int(self.tmp)]])
elif c == 35:
# Even parity over hour bits (29-35): DCF77 bit 35.
self.tmp |= (bit << (c - 29))
parity = bin(self.tmp).count('1')
s = 'OK' if ((parity % 2) == 0) else 'INVALID!'
- self.put(ss, es, a, [0, ['Hour parity: %s' % s]])
+ self.putx([11, ['Hour parity: %s' % s]])
elif c in range(36, 41 + 1):
# Day of month (1-31): DCF77 bits 36-41 (BCD format).
if c == 36:
self.tmp = bit
+ self.ss_block = self.ss_bit
else:
self.tmp |= (bit << (c - 36))
if c == 41:
- self.put(ss, es, a, [0, ['Day: %d' % bcd2int(self.tmp)]])
+ self.putb([12, ['Day: %d' % bcd2int(self.tmp)]])
elif c in range(42, 44 + 1):
# Day of week (1-7): DCF77 bits 42-44 (BCD format).
# A value of 1 means Monday, 7 means Sunday.
if c == 42:
self.tmp = bit
+ self.ss_block = self.ss_bit
else:
self.tmp |= (bit << (c - 42))
if c == 44:
d = bcd2int(self.tmp)
- dn = calendar.day_name[d - 1] # day_name[0] == Monday
- self.put(ss, es, a, [0, ['Day of week: %d (%s)' % (d, dn)]])
+ try:
+ dn = calendar.day_name[d - 1] # day_name[0] == Monday
+ self.putb([13, ['Day of week: %d (%s)' % (d, dn),
+ 'DoW: %d (%s)' % (d, dn)]])
+ except IndexError:
+ self.putb([19, ['Day of week: %d (%s)' % (d, 'invalid'),
+ 'DoW: %d (%s)' % (d, 'inv')]])
elif c in range(45, 49 + 1):
# Month (1-12): DCF77 bits 45-49 (BCD format).
if c == 45:
self.tmp = bit
+ self.ss_block = self.ss_bit
else:
self.tmp |= (bit << (c - 45))
if c == 49:
m = bcd2int(self.tmp)
- mn = calendar.month_name[m] # month_name[1] == January
- self.put(ss, es, a, [0, ['Month: %d (%s)' % (m, mn)]])
+ try:
+ mn = calendar.month_name[m] # month_name[1] == January
+ self.putb([14, ['Month: %d (%s)' % (m, mn),
+ 'Mon: %d (%s)' % (m, mn)]])
+ except IndexError:
+ self.putb([19, ['Month: %d (%s)' % (m, 'invalid'),
+ 'Mon: %d (%s)' % (m, 'inv')]])
elif c in range(50, 57 + 1):
# Year (0-99): DCF77 bits 50-57 (BCD format).
if c == 50:
self.tmp = bit
+ self.ss_block = self.ss_bit
else:
self.tmp |= (bit << (c - 50))
if c == 57:
- self.put(ss, es, a, [0, ['Year: %d' % bcd2int(self.tmp)]])
+ self.putb([15, ['Year: %d' % bcd2int(self.tmp)]])
elif c == 58:
# Even parity over date bits (36-58): DCF77 bit 58.
- self.tmp |= (bit << (c - 50))
- parity = bin(self.tmp).count('1')
+ parity = self.datebits.count(1)
s = 'OK' if ((parity % 2) == 0) else 'INVALID!'
- self.put(ss, es, a, [0, ['Date parity: %s' % s]])
+ self.putx([16, ['Date parity: %s' % s, 'DP: %s' % s]])
+ self.datebits = []
else:
- raise Exception('Invalid DCF77 bit: %d' % c)
-
- def decode(self, ss, es, data):
- for (self.samplenum, pins) in data:
-
- # Ignore identical samples early on (for performance reasons).
- if self.oldpins == pins:
- continue
- self.oldpins, (val, pon) = pins, pins
-
- # Always remember the old PON state.
- if self.oldpon != pon:
- self.oldpon = pon
-
- # Warn if PON goes low.
- if self.oldpon == 1 and pon == 0:
- self.pon_ss = self.samplenum
- self.put(self.samplenum, self.samplenum, self.out_ann,
- [1, ['Warning: PON goes low, DCF77 reception '
- 'no longer possible']])
- elif self.oldpon == 0 and pon == 1:
- self.put(self.samplenum, self.samplenum, self.out_ann,
- [0, ['PON goes high, DCF77 reception now possible']])
- self.put(self.pon_ss, self.samplenum, self.out_ann,
- [1, ['Warning: PON low, DCF77 reception disabled']])
-
- # Ignore samples where PON == 0, they can't contain DCF77 signals.
- if pon == 0:
- continue
+ self.putx([19, ['Invalid DCF77 bit: %d' % c,
+ 'Invalid bit: %d' % c, 'Inv: %d' % c]])
+ def decode(self):
+ if not self.samplerate:
+ raise SamplerateError('Cannot decode without samplerate.')
+ while True:
if self.state == 'WAIT FOR RISING EDGE':
# Wait until the next rising edge occurs.
- if not (self.oldval == 0 and val == 1):
- self.oldval = val
- continue
+ self.wait({0: 'r'})
# Save the sample number where the DCF77 bit begins.
- self.bit_start = self.samplenum
+ self.ss_bit = self.samplenum
# Calculate the length (in ms) between two rising edges.
- len_edges = self.bit_start - self.bit_start_old
+ len_edges = self.ss_bit - self.ss_bit_old
len_edges_ms = int((len_edges / self.samplerate) * 1000)
# The time between two rising edges is usually around 1000ms.
# 2000ms distance to the last one, this edge marks the
# beginning of a new minute (and DCF77 bit 0 of that minute).
if len_edges_ms in range(1600, 2400 + 1):
- self.put(ss, es, self.out_ann, [0, ['New minute starts']])
self.bitcount = 0
- self.bit_start_old = self.bit_start
+ self.ss_bit_old = self.ss_bit
self.dcf77_bitnumber_is_known = 1
- # Don't switch to 'GET BIT' state this time.
- continue
- self.bit_start_old = self.bit_start
+ self.ss_bit_old = self.ss_bit
self.state = 'GET BIT'
elif self.state == 'GET BIT':
# Wait until the next falling edge occurs.
- if not (self.oldval == 1 and val == 0):
- self.oldval = val
- continue
+ self.wait({0: 'f'})
+
+ # Save the sample number where the DCF77 bit ends.
+ self.es_bit = self.samplenum
# Calculate the length (in ms) of the current high period.
- len_high = self.samplenum - self.bit_start
+ len_high = self.samplenum - self.ss_bit
len_high_ms = int((len_high / self.samplerate) * 1000)
# If the high signal was 100ms long, that encodes a 0 bit.
elif len_high_ms in range(161, 260 + 1):
bit = 1
else:
- bit = -1 # TODO: Error?
+ bit = -1
- # There's no bit 59, make sure none is decoded.
- if bit in (0, 1) and self.bitcount in range(0, 58 + 1):
+ if bit in (0, 1):
self.handle_dcf77_bit(bit)
self.bitcount += 1
+ else:
+ self.putx([19, ['Invalid bit timing', 'Inv timing', 'Inv']])
self.state = 'WAIT FOR RISING EDGE'
-
- else:
- raise Exception('Invalid state: %s' % self.state)
-
- self.oldval = val
-