##
## This file is part of the libsigrokdecode project.
-##
-## Copyright (C) 2012 Uwe Hermann <uwe@hermann-uwe.de>
+##
+## Copyright (C) 2012-2020 Uwe Hermann <uwe@hermann-uwe.de>
## Copyright (C) 2013 Matt Ranostay <mranostay@gmail.com>
##
## This program is free software; you can redistribute it and/or modify
## 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/>.
##
-# Dallas DS1307 RTC protocol decoder
-
+import re
import sigrokdecode as srd
+from common.srdhelper import bcd2int, SrdIntEnum
+
+days_of_week = (
+ 'Sunday', 'Monday', 'Tuesday', 'Wednesday',
+ 'Thursday', 'Friday', 'Saturday',
+)
+
+regs = (
+ 'Seconds', 'Minutes', 'Hours', 'Day', 'Date', 'Month', 'Year',
+ 'Control', 'RAM',
+)
+
+bits = (
+ 'Clock halt', 'Seconds', 'Reserved', 'Minutes', '12/24 hours', 'AM/PM',
+ 'Hours', 'Day', 'Date', 'Month', 'Year', 'OUT', 'SQWE', 'RS', 'RAM',
+)
+
+rates = {
+ 0b00: '1Hz',
+ 0b01: '4096Hz',
+ 0b10: '8192Hz',
+ 0b11: '32768Hz',
+}
-days_of_week = [
- 'Sunday',
- 'Monday',
- 'Tuesday',
- 'Wednesday',
- 'Thursday',
- 'Friday',
- 'Saturday',
-]
+DS1307_I2C_ADDRESS = 0x68
-# Return the specified BCD number (max. 8 bits) as integer.
-def bcd2int(b):
- return (b & 0x0f) + ((b >> 4) * 10)
+def regs_and_bits():
+ l = [('reg_' + r.lower(), r + ' register') for r in regs]
+ l += [('bit_' + re.sub('\/| ', '_', b).lower(), b + ' bit') for b in bits]
+ return tuple(l)
+
+a = ['REG_' + r.upper() for r in regs] + \
+ ['BIT_' + re.sub('\/| ', '_', b).upper() for b in bits] + \
+ ['READ_DATE_TIME', 'WRITE_DATE_TIME', 'READ_REG', 'WRITE_REG', 'WARNING']
+Ann = SrdIntEnum.from_list('Ann', a)
class Decoder(srd.Decoder):
- api_version = 1
+ api_version = 3
id = 'ds1307'
name = 'DS1307'
longname = 'Dallas DS1307'
- desc = 'Realtime clock module protocol.'
+ desc = 'Dallas DS1307 realtime clock module protocol.'
license = 'gplv2+'
inputs = ['i2c']
- outputs = ['ds1307']
- probes = []
- optional_probes = []
- options = {}
- annotations = [
- ['Text', 'Human-readable text'],
- ]
-
- def __init__(self, **kwargs):
+ outputs = []
+ tags = ['Clock/timing', 'IC']
+ annotations = regs_and_bits() + (
+ ('read_date_time', 'Read date/time'),
+ ('write_date_time', 'Write date/time'),
+ ('read_reg', 'Register read'),
+ ('write_reg', 'Register write'),
+ ('warning', 'Warning'),
+ )
+ annotation_rows = (
+ ('bits', 'Bits', Ann.prefixes('BIT_')),
+ ('regs', 'Registers', Ann.prefixes('REG_')),
+ ('date_time', 'Date/time', Ann.prefixes('READ_ WRITE_')),
+ ('warnings', 'Warnings', (Ann.WARNING,)),
+ )
+
+ def __init__(self):
+ self.reset()
+
+ def reset(self):
self.state = 'IDLE'
self.hours = -1
self.minutes = -1
self.date = -1
self.months = -1
self.years = -1
+ self.bits = []
def start(self):
self.out_ann = self.register(srd.OUTPUT_ANN)
def putx(self, data):
self.put(self.ss, self.es, self.out_ann, data)
- def handle_reg_0x00(self, b): # Seconds
- self.seconds = bcd2int(b & 0x7f)
- self.putx([0, ['Seconds: %d' % self.seconds]])
+ def putd(self, bit1, bit2, data):
+ self.put(self.bits[bit1][1], self.bits[bit2][2], self.out_ann, data)
- def handle_reg_0x01(self, b): # Minutes
- self.minutes = bcd2int(b & 0x7f)
- self.putx([0, ['Minutes: %d' % self.minutes]])
+ def putr(self, bit):
+ self.put(self.bits[bit][1], self.bits[bit][2], self.out_ann,
+ [Ann.BIT_RESERVED, ['Reserved bit', 'Reserved', 'Rsvd', 'R']])
- def handle_reg_0x02(self, b): # Hours
- self.hours = bcd2int(b & 0x3f)
- self.putx([0, ['Hours: %d' % self.hours]])
+ def handle_reg_0x00(self, b): # Seconds (0-59) / Clock halt bit
+ self.putd(7, 0, [Ann.REG_SECONDS, ['Seconds', 'Sec', 'S']])
+ ch = 1 if (b & (1 << 7)) else 0
+ self.putd(7, 7, [Ann.BIT_CLOCK_HALT, ['Clock halt: %d' % ch,
+ 'Clk hlt: %d' % ch, 'CH: %d' % ch, 'CH']])
+ s = self.seconds = bcd2int(b & 0x7f)
+ self.putd(6, 0, [Ann.BIT_SECONDS, ['Second: %d' % s, 'Sec: %d' % s,
+ 'S: %d' % s, 'S']])
+
+ def handle_reg_0x01(self, b): # Minutes (0-59)
+ self.putd(7, 0, [Ann.REG_MINUTES, ['Minutes', 'Min', 'M']])
+ self.putr(7)
+ m = self.minutes = bcd2int(b & 0x7f)
+ self.putd(6, 0, [Ann.BIT_MINUTES, ['Minute: %d' % m, 'Min: %d' % m, 'M: %d' % m, 'M']])
+
+ def handle_reg_0x02(self, b): # Hours (1-12+AM/PM or 0-23)
+ self.putd(7, 0, [Ann.REG_HOURS, ['Hours', 'H']])
+ self.putr(7)
+ ampm_mode = True if (b & (1 << 6)) else False
+ if ampm_mode:
+ self.putd(6, 6, [Ann.BIT_12_24_HOURS, ['12-hour mode', '12h mode', '12h']])
+ a = 'PM' if (b & (1 << 5)) else 'AM'
+ self.putd(5, 5, [Ann.BIT_AM_PM, [a, a[0]]])
+ h = self.hours = bcd2int(b & 0x1f)
+ self.putd(4, 0, [Ann.BIT_HOURS, ['Hour: %d' % h, 'H: %d' % h, 'H']])
+ else:
+ self.putd(6, 6, [Ann.BIT_12_24_HOURS, ['24-hour mode', '24h mode', '24h']])
+ h = self.hours = bcd2int(b & 0x3f)
+ self.putd(5, 0, [Ann.BIT_HOURS, ['Hour: %d' % h, 'H: %d' % h, 'H']])
- def handle_reg_0x03(self, b): # Day of week
- self.days = bcd2int(b & 0x7)
- self.putx([0, ['Day of Week: %s' % days_of_week[self.days - 1]]])
+ def handle_reg_0x03(self, b): # Day / day of week (1-7)
+ self.putd(7, 0, [Ann.REG_DAY, ['Day of week', 'Day', 'D']])
+ for i in (7, 6, 5, 4, 3):
+ self.putr(i)
+ w = self.days = bcd2int(b & 0x07)
+ ws = days_of_week[self.days - 1]
+ self.putd(2, 0, [Ann.BIT_DAY, ['Weekday: %s' % ws, 'WD: %s' % ws, 'WD', 'W']])
- def handle_reg_0x04(self, b): # Date
- self.date = bcd2int(b & 0x3f)
- self.putx([0, ['Days: %d' % self.date]])
+ def handle_reg_0x04(self, b): # Date (1-31)
+ self.putd(7, 0, [Ann.REG_DATE, ['Date', 'D']])
+ for i in (7, 6):
+ self.putr(i)
+ d = self.date = bcd2int(b & 0x3f)
+ self.putd(5, 0, [Ann.BIT_DATE, ['Date: %d' % d, 'D: %d' % d, 'D']])
- def handle_reg_0x05(self, b): # Month
- self.months = bcd2int(b & 0x1f)
- self.putx([0, ['Months: %d' % self.months]])
+ def handle_reg_0x05(self, b): # Month (1-12)
+ self.putd(7, 0, [Ann.REG_MONTH, ['Month', 'Mon', 'M']])
+ for i in (7, 6, 5):
+ self.putr(i)
+ m = self.months = bcd2int(b & 0x1f)
+ self.putd(4, 0, [Ann.BIT_MONTH, ['Month: %d' % m, 'Mon: %d' % m, 'M: %d' % m, 'M']])
- def handle_reg_0x06(self, b): # Year
- self.years = bcd2int(b & 0xff) + 2000;
- self.putx([0, ['Years: %d' % self.years]])
+ def handle_reg_0x06(self, b): # Year (0-99)
+ self.putd(7, 0, [Ann.REG_YEAR, ['Year', 'Y']])
+ y = self.years = bcd2int(b & 0xff)
+ self.years += 2000
+ self.putd(7, 0, [Ann.BIT_YEAR, ['Year: %d' % y, 'Y: %d' % y, 'Y']])
def handle_reg_0x07(self, b): # Control Register
- pass
+ self.putd(7, 0, [Ann.REG_CONTROL, ['Control', 'Ctrl', 'C']])
+ for i in (6, 5, 3, 2):
+ self.putr(i)
+ o = 1 if (b & (1 << 7)) else 0
+ s = 1 if (b & (1 << 4)) else 0
+ s2 = 'en' if (b & (1 << 4)) else 'dis'
+ r = rates[b & 0x03]
+ self.putd(7, 7, [Ann.BIT_OUT, ['Output control: %d' % o,
+ 'OUT: %d' % o, 'O: %d' % o, 'O']])
+ self.putd(4, 4, [Ann.BIT_SQWE, ['Square wave output: %sabled' % s2,
+ 'SQWE: %sabled' % s2, 'SQWE: %d' % s, 'S: %d' % s, 'S']])
+ self.putd(1, 0, [Ann.BIT_RS, ['Square wave output rate: %s' % r,
+ 'Square wave rate: %s' % r, 'SQW rate: %s' % r, 'Rate: %s' % r,
+ 'RS: %s' % s, 'RS', 'R']])
+
+ def handle_reg_0x3f(self, b): # RAM (bytes 0x08-0x3f)
+ self.putd(7, 0, [Ann.REG_RAM, ['RAM', 'R']])
+ self.putd(7, 0, [Ann.BIT_RAM, ['SRAM: 0x%02X' % b, '0x%02X' % b]])
+
+ def output_datetime(self, cls, rw):
+ # TODO: Handle read/write of only parts of these items.
+ d = '%s, %02d.%02d.%4d %02d:%02d:%02d' % (
+ days_of_week[self.days - 1], self.date, self.months,
+ self.years, self.hours, self.minutes, self.seconds)
+ self.put(self.ss_block, self.es, self.out_ann,
+ [cls, ['%s date/time: %s' % (rw, d)]])
+
+ def handle_reg(self, b):
+ r = self.reg if self.reg < 8 else 0x3f
+ fn = getattr(self, 'handle_reg_0x%02x' % r)
+ fn(b)
+ # Honor address auto-increment feature of the DS1307. When the
+ # address reaches 0x3f, it will wrap around to address 0.
+ self.reg += 1
+ if self.reg > 0x3f:
+ self.reg = 0
+
+ def is_correct_chip(self, addr):
+ if addr == DS1307_I2C_ADDRESS:
+ return True
+ self.put(self.ss_block, self.es, self.out_ann,
+ [Ann.WARNING, ['Ignoring non-DS1307 data (slave 0x%02X)' % addr]])
+ return False
def decode(self, ss, es, data):
cmd, databyte = data
- # Store the start/end samples of this I2C packet.
+ # Collect the 'BITS' packet, then return. The next packet is
+ # guaranteed to belong to these bits we just stored.
+ if cmd == 'BITS':
+ self.bits = databyte
+ return
+
+ # Store the start/end samples of this I²C packet.
self.ss, self.es = ss, es
# State machine.
if self.state == 'IDLE':
- # Wait for an I2C START condition.
+ # Wait for an I²C START condition.
if cmd != 'START':
return
self.state = 'GET SLAVE ADDR'
- self.block_start_sample = ss
+ self.ss_block = ss
elif self.state == 'GET SLAVE ADDR':
# Wait for an address write operation.
- # TODO: We should only handle packets to the RTC slave (0x68).
if cmd != 'ADDRESS WRITE':
return
+ if not self.is_correct_chip(databyte):
+ self.state = 'IDLE'
+ return
self.state = 'GET REG ADDR'
elif self.state == 'GET REG ADDR':
# Wait for a data write (master selects the slave register).
self.reg = databyte
self.state = 'WRITE RTC REGS'
elif self.state == 'WRITE RTC REGS':
- # If we see a Repeated Start here, it's probably an RTC read.
+ # If we see a Repeated Start here, it's an RTC read.
if cmd == 'START REPEAT':
self.state = 'READ RTC REGS'
return
# Otherwise: Get data bytes until a STOP condition occurs.
if cmd == 'DATA WRITE':
- handle_reg = getattr(self, 'handle_reg_0x%02x' % self.reg)
- handle_reg(databyte)
- self.reg += 1
- # TODO: Check for NACK!
+ self.handle_reg(databyte)
elif cmd == 'STOP':
- # TODO: Handle read/write of only parts of these items.
- d = '%s, %02d.%02d.%02d %02d:%02d:%02d' % (
- days_of_week[self.days - 1], self.date, self.months,
- self.years, self.hours, self.minutes, self.seconds)
- self.put(self.block_start_sample, es, self.out_ann,
- [0, ['Written date/time: %s' % d]])
+ self.output_datetime(Ann.WRITE_DATE_TIME, 'Written')
self.state = 'IDLE'
- else:
- pass # TODO
elif self.state == 'READ RTC REGS':
# Wait for an address read operation.
- # TODO: We should only handle packets to the RTC slave (0x68).
- if cmd == 'ADDRESS READ':
- self.state = 'READ RTC REGS2'
+ if cmd != 'ADDRESS READ':
+ return
+ if not self.is_correct_chip(databyte):
+ self.state = 'IDLE'
return
- else:
- pass # TODO
+ self.state = 'READ RTC REGS2'
elif self.state == 'READ RTC REGS2':
if cmd == 'DATA READ':
- handle_reg = getattr(self, 'handle_reg_0x%02x' % self.reg)
- handle_reg(databyte)
- self.reg += 1
- # TODO: Check for NACK!
+ self.handle_reg(databyte)
elif cmd == 'STOP':
- d = '%s, %02d.%02d.%02d %02d:%02d:%02d' % (
- days_of_week[self.days - 1], self.date, self.months,
- self.years, self.hours, self.minutes, self.seconds)
- self.put(self.block_start_sample, es, self.out_ann,
- [0, ['Read date/time: %s' % d]])
+ self.output_datetime(Ann.READ_DATE_TIME, 'Read')
self.state = 'IDLE'
- else:
- pass # TODO?
- else:
- raise Exception('Invalid state: %s' % self.state)
-