2 ## This file is part of the libsigrokdecode project.
4 ## Copyright (C) 2012-2014 Uwe Hermann <uwe@hermann-uwe.de>
5 ## Copyright (C) 2013 Matt Ranostay <mranostay@gmail.com>
7 ## This program is free software; you can redistribute it and/or modify
8 ## it under the terms of the GNU General Public License as published by
9 ## the Free Software Foundation; either version 2 of the License, or
10 ## (at your option) any later version.
12 ## This program is distributed in the hope that it will be useful,
13 ## but WITHOUT ANY WARRANTY; without even the implied warranty of
14 ## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 ## GNU General Public License for more details.
17 ## You should have received a copy of the GNU General Public License
18 ## along with this program; if not, write to the Free Software
19 ## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
23 import sigrokdecode as srd
26 'Sunday', 'Monday', 'Tuesday', 'Wednesday',
27 'Thursday', 'Friday', 'Saturday',
31 'Seconds', 'Minutes', 'Hours', 'Day', 'Date', 'Month', 'Year',
36 'Clock halt', 'Seconds', 'Reserved', 'Minutes', '12/24 hours', 'AM/PM',
37 'Hours', 'Day', 'Date', 'Month', 'Year', 'OUT', 'SQWE', 'RS', 'RAM',
48 l = [('reg-' + r.lower(), r + ' register') for r in regs]
49 l += [('bit-' + re.sub('\/| ', '-', b).lower(), b + ' bit') for b in bits]
52 # Return the specified BCD number (max. 8 bits) as integer.
54 return (b & 0x0f) + ((b >> 4) * 10)
56 class Decoder(srd.Decoder):
60 longname = 'Dallas DS1307'
61 desc = 'Realtime clock module protocol.'
65 annotations = regs_and_bits() + (
66 ('read-datetime', 'Read date/time'),
67 ('write-datetime', 'Write date/time'),
68 ('reg-read', 'Register read'),
69 ('reg-write', 'Register write'),
72 ('bits', 'Bits', tuple(range(9, 24))),
73 ('regs', 'Registers', tuple(range(9))),
74 ('date-time', 'Date/time', (24, 25, 26, 27)),
77 def __init__(self, **kwargs):
89 self.out_ann = self.register(srd.OUTPUT_ANN)
92 self.put(self.ss, self.es, self.out_ann, data)
94 def putd(self, bit1, bit2, data):
95 self.put(self.bits[bit1][1], self.bits[bit2][2], self.out_ann, data)
98 self.put(self.bits[bit][1], self.bits[bit][2], self.out_ann,
99 [11, ['Reserved bit', 'Reserved', 'Rsvd', 'R']])
101 def handle_reg_0x00(self, b): # Seconds (0-59) / Clock halt bit
102 self.putd(7, 0, [0, ['Seconds', 'Sec', 'S']])
103 ch = 1 if (b & (1 << 7)) else 0
104 self.putd(7, 7, [9, ['Clock halt: %d' % ch, 'Clk hlt: %d' % ch,
105 'CH: %d' % ch, 'CH']])
106 s = self.seconds = bcd2int(b & 0x7f)
107 self.putd(6, 0, [10, ['Second: %d' % s, 'Sec: %d' % s, 'S: %d' % s, 'S']])
109 def handle_reg_0x01(self, b): # Minutes (0-59)
110 self.putd(7, 0, [1, ['Minutes', 'Min', 'M']])
112 m = self.minutes = bcd2int(b & 0x7f)
113 self.putd(6, 0, [12, ['Minute: %d' % m, 'Min: %d' % m, 'M: %d' % m, 'M']])
115 def handle_reg_0x02(self, b): # Hours (1-12+AM/PM or 0-23)
116 self.putd(7, 0, [2, ['Hours', 'H']])
118 ampm_mode = True if (b & (1 << 6)) else False
120 self.putd(6, 6, [13, ['12-hour mode', '12h mode', '12h']])
121 a = 'AM' if (b & (1 << 6)) else 'PM'
122 self.putd(5, 5, [14, [a, a[0]]])
123 h = self.hours = bcd2int(b & 0x1f)
124 self.putd(4, 0, [15, ['Hour: %d' % h, 'H: %d' % h, 'H']])
126 self.putd(6, 6, [13, ['24-hour mode', '24h mode', '24h']])
127 h = self.hours = bcd2int(b & 0x3f)
128 self.putd(5, 0, [15, ['Hour: %d' % h, 'H: %d' % h, 'H']])
130 def handle_reg_0x03(self, b): # Day / day of week (1-7)
131 self.putd(7, 0, [3, ['Day of week', 'Day', 'D']])
132 for i in (7, 6, 5, 4, 3):
134 w = self.days = bcd2int(b & 0x07)
135 ws = days_of_week[self.days - 1]
136 self.putd(2, 0, [16, ['Weekday: %s' % ws, 'WD: %s' % ws, 'WD', 'W']])
138 def handle_reg_0x04(self, b): # Date (1-31)
139 self.putd(7, 0, [4, ['Date', 'D']])
142 d = self.date = bcd2int(b & 0x3f)
143 self.putd(5, 0, [17, ['Date: %d' % d, 'D: %d' % d, 'D']])
145 def handle_reg_0x05(self, b): # Month (1-12)
146 self.putd(7, 0, [5, ['Month', 'Mon', 'M']])
149 m = self.months = bcd2int(b & 0x1f)
150 self.putd(4, 0, [18, ['Month: %d' % m, 'Mon: %d' % m, 'M: %d' % m, 'M']])
152 def handle_reg_0x06(self, b): # Year (0-99)
153 self.putd(7, 0, [6, ['Year', 'Y']])
154 y = self.years = bcd2int(b & 0xff)
156 self.putd(7, 0, [19, ['Year: %d' % y, 'Y: %d' % y, 'Y']])
158 def handle_reg_0x07(self, b): # Control Register
159 self.putd(7, 0, [7, ['Control', 'Ctrl', 'C']])
160 for i in (6, 5, 3, 2):
162 o = 1 if (b & (1 << 7)) else 0
163 s = 1 if (b & (1 << 4)) else 0
164 s2 = 'en' if (b & (1 << 4)) else 'dis'
166 self.putd(7, 7, [20, ['Output control: %d' % o,
167 'OUT: %d' % o, 'O: %d' % o, 'O']])
168 self.putd(4, 4, [21, ['Square wave output: %sabled' % s2,
169 'SQWE: %sabled' % s2, 'SQWE: %d' % s, 'S: %d' % s, 'S']])
170 self.putd(1, 0, [22, ['Square wave output rate: %s' % r,
171 'Square wave rate: %s' % r, 'SQW rate: %s' % r, 'Rate: %s' % r,
172 'RS: %s' % s, 'RS', 'R']])
174 def handle_reg_0x3f(self, b): # RAM (bytes 0x08-0x3f)
175 self.putd(7, 0, [8, ['RAM', 'R']])
176 self.putd(7, 0, [23, ['SRAM: 0x%02X' % b, '0x%02X' % b]])
178 def output_datetime(self, cls, rw):
179 # TODO: Handle read/write of only parts of these items.
180 d = '%s, %02d.%02d.%4d %02d:%02d:%02d' % (
181 days_of_week[self.days - 1], self.date, self.months,
182 self.years, self.hours, self.minutes, self.seconds)
183 self.put(self.block_start_sample, self.es, self.out_ann,
184 [cls, ['%s date/time: %s' % (rw, d)]])
186 def handle_reg(self, b):
187 r = self.reg if self.reg < 8 else 0x3f
188 fn = getattr(self, 'handle_reg_0x%02x' % r)
192 def decode(self, ss, es, data):
195 # Collect the 'BITS' packet, then return. The next packet is
196 # guaranteed to belong to these bits we just stored.
201 # Store the start/end samples of this I²C packet.
202 self.ss, self.es = ss, es
205 if self.state == 'IDLE':
206 # Wait for an I²C START condition.
209 self.state = 'GET SLAVE ADDR'
210 self.block_start_sample = ss
211 elif self.state == 'GET SLAVE ADDR':
212 # Wait for an address write operation.
213 # TODO: We should only handle packets to the RTC slave (0x68).
214 if cmd != 'ADDRESS WRITE':
216 self.state = 'GET REG ADDR'
217 elif self.state == 'GET REG ADDR':
218 # Wait for a data write (master selects the slave register).
219 if cmd != 'DATA WRITE':
222 self.state = 'WRITE RTC REGS'
223 elif self.state == 'WRITE RTC REGS':
224 # If we see a Repeated Start here, it's an RTC read.
225 if cmd == 'START REPEAT':
226 self.state = 'READ RTC REGS'
228 # Otherwise: Get data bytes until a STOP condition occurs.
229 if cmd == 'DATA WRITE':
230 self.handle_reg(databyte)
232 self.output_datetime(25, 'Written')
234 elif self.state == 'READ RTC REGS':
235 # Wait for an address read operation.
236 # TODO: We should only handle packets to the RTC slave (0x68).
237 if cmd == 'ADDRESS READ':
238 self.state = 'READ RTC REGS2'
240 elif self.state == 'READ RTC REGS2':
241 if cmd == 'DATA READ':
242 self.handle_reg(databyte)
244 self.output_datetime(24, 'Read')