[libsigrokdecode.git] / decoders / rtc8564 / pd.py

##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2012-2014 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
## 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
from common.srdhelper import bcd2int

def reg_list():
    l = []
    for i in range(8 + 1):
        l.append(('reg-0x%02x' % i, 'Register 0x%02x' % i))

    return tuple(l)

class Decoder(srd.Decoder):
    api_version = 3
    id = 'rtc8564'
    name = 'RTC-8564'
    longname = 'Epson RTC-8564 JE/NB'
    desc = 'Realtime clock module protocol.'
    license = 'gplv2+'
    inputs = ['i2c']
    outputs = ['rtc8564']
    tags = ['Clock/timing']
    annotations = reg_list() + (
        ('read', 'Read date/time'),
        ('write', 'Write date/time'),
        ('bit-reserved', 'Reserved bit'),
        ('bit-vl', 'VL bit'),
        ('bit-century', 'Century bit'),
        ('reg-read', 'Register read'),
        ('reg-write', 'Register write'),
    )
    annotation_rows = (
        ('bits', 'Bits', tuple(range(0, 8 + 1)) + (11, 12, 13)),
        ('regs', 'Register access', (14, 15)),
        ('date-time', 'Date/time', (9, 10)),
    )

    def __init__(self):
        self.reset()

    def reset(self):
        self.state = 'IDLE'
        self.hours = -1
        self.minutes = -1
        self.seconds = -1
        self.days = -1
        self.weekdays = -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 putd(self, bit1, bit2, data):
        self.put(self.bits[bit1][1], self.bits[bit2][2], self.out_ann, data)

    def putr(self, bit):
        self.put(self.bits[bit][1], self.bits[bit][2], self.out_ann,
                 [11, ['Reserved bit', 'Reserved', 'Rsvd', 'R']])

    def handle_reg_0x00(self, b): # Control register 1
        pass

    def handle_reg_0x01(self, b): # Control register 2
        ti_tp = 1 if (b & (1 << 4)) else 0
        af = 1 if (b & (1 << 3)) else 0
        tf = 1 if (b & (1 << 2)) else 0
        aie = 1 if (b & (1 << 1)) else 0
        tie = 1 if (b & (1 << 0)) else 0

        ann = ''

        s = 'repeated' if ti_tp else 'single-shot'
        ann += 'TI/TP = %d: %s operation upon fixed-cycle timer interrupt '\
               'events\n' % (ti_tp, s)
        s = '' if af else 'no '
        ann += 'AF = %d: %salarm interrupt detected\n' % (af, s)
        s = '' if tf else 'no '
        ann += 'TF = %d: %sfixed-cycle timer interrupt detected\n' % (tf, s)
        s = 'enabled' if aie else 'prohibited'
        ann += 'AIE = %d: INT# pin output %s when an alarm interrupt '\
               'occurs\n' % (aie, s)
        s = 'enabled' if tie else 'prohibited'
        ann += 'TIE = %d: INT# pin output %s when a fixed-cycle interrupt '\
               'event occurs\n' % (tie, s)

        self.putx([1, [ann]])

    def handle_reg_0x02(self, b): # Seconds / Voltage-low bit
        vl = 1 if (b & (1 << 7)) else 0
        self.putd(7, 7, [12, ['Voltage low: %d' % vl, 'Volt. low: %d' % vl,
                        'VL: %d' % vl, 'VL']])
        s = self.seconds = bcd2int(b & 0x7f)
        self.putd(6, 0, [2, ['Second: %d' % s, 'Sec: %d' % s, 'S: %d' % s, 'S']])

    def handle_reg_0x03(self, b): # Minutes
        self.putr(7)
        m = self.minutes = bcd2int(b & 0x7f)
        self.putd(6, 0, [3, ['Minute: %d' % m, 'Min: %d' % m, 'M: %d' % m, 'M']])

    def handle_reg_0x04(self, b): # Hours
        self.putr(7)
        self.putr(6)
        h = self.hours = bcd2int(b & 0x3f)
        self.putd(5, 0, [4, ['Hour: %d' % h, 'H: %d' % h, 'H']])

    def handle_reg_0x05(self, b): # Days
        self.putr(7)
        self.putr(6)
        d = self.days = bcd2int(b & 0x3f)
        self.putd(5, 0, [5, ['Day: %d' % d, 'D: %d' % d, 'D']])

    def handle_reg_0x06(self, b): # Weekdays
        for i in (7, 6, 5, 4, 3):
            self.putr(i)
        w = self.weekdays = bcd2int(b & 0x07)
        self.putd(2, 0, [6, ['Weekday: %d' % w, 'WD: %d' % w, 'WD', 'W']])

    def handle_reg_0x07(self, b): # Months / century bit
        c = 1 if (b & (1 << 7)) else 0
        self.putd(7, 7, [13, ['Century bit: %d' % c, 'Century: %d' % c,
                              'Cent: %d' % c, 'C: %d' % c, 'C']])
        self.putr(6)
        self.putr(5)
        m = self.months = bcd2int(b & 0x1f)
        self.putd(4, 0, [7, ['Month: %d' % m, 'Mon: %d' % m, 'M: %d' % m, 'M']])

    def handle_reg_0x08(self, b): # Years
        y = self.years = bcd2int(b & 0xff)
        self.putx([8, ['Year: %d' % y, 'Y: %d' % y, 'Y']])

    def handle_reg_0x09(self, b): # Alarm, minute
        pass

    def handle_reg_0x0a(self, b): # Alarm, hour
        pass

    def handle_reg_0x0b(self, b): # Alarm, day
        pass

    def handle_reg_0x0c(self, b): # Alarm, weekday
        pass

    def handle_reg_0x0d(self, b): # CLKOUT output
        pass

    def handle_reg_0x0e(self, b): # Timer setting
        pass

    def handle_reg_0x0f(self, b): # Down counter for fixed-cycle timer
        pass

    def decode(self, ss, es, data):
        cmd, databyte = data

        # 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.
            if cmd != 'START':
                return
            self.state = 'GET SLAVE ADDR'
            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 (0xa2/0xa3).
            if cmd != 'ADDRESS WRITE':
                return
            self.state = 'GET REG ADDR'
        elif self.state == 'GET REG ADDR':
            # Wait for a data write (master selects the slave register).
            if cmd != 'DATA WRITE':
                return
            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 cmd == 'START REPEAT':
                self.state = 'READ RTC REGS'
                return
            # Otherwise: Get data bytes until a STOP condition occurs.
            if cmd == 'DATA WRITE':
                r, s = self.reg, '%02X: %02X' % (self.reg, databyte)
                self.putx([15, ['Write register %s' % s, 'Write reg %s' % s,
                                'WR %s' % s, 'WR', 'W']])
                handle_reg = getattr(self, 'handle_reg_0x%02x' % self.reg)
                handle_reg(databyte)
                self.reg += 1
                # TODO: Check for NACK!
            elif cmd == 'STOP':
                # TODO: Handle read/write of only parts of these items.
                d = '%02d.%02d.%02d %02d:%02d:%02d' % (self.days, self.months,
                    self.years, self.hours, self.minutes, self.seconds)
                self.put(self.ss_block, es, self.out_ann,
                         [9, ['Write date/time: %s' % d, 'Write: %s' % d,
                              'W: %s' % d]])
                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 (0xa2/0xa3).
            if cmd == 'ADDRESS READ':
                self.state = 'READ RTC REGS2'
                return
            else:
                pass # TODO
        elif self.state == 'READ RTC REGS2':
            if cmd == 'DATA READ':
                r, s = self.reg, '%02X: %02X' % (self.reg, databyte)
                self.putx([15, ['Read register %s' % s, 'Read reg %s' % s,
                                'RR %s' % s, 'RR', 'R']])
                handle_reg = getattr(self, 'handle_reg_0x%02x' % self.reg)
                handle_reg(databyte)
                self.reg += 1
                # TODO: Check for NACK!
            elif cmd == 'STOP':
                d = '%02d.%02d.%02d %02d:%02d:%02d' % (self.days, self.months,
                    self.years, self.hours, self.minutes, self.seconds)
                self.put(self.ss_block, es, self.out_ann,
                         [10, ['Read date/time: %s' % d, 'Read: %s' % d,
                               'R: %s' % d]])
                self.state = 'IDLE'
            else:
                pass # TODO?
Commit	Line	Data
ed5f826a	1	##
50bd5d25	2	## This file is part of the libsigrokdecode project.
ed5f826a	3	##
6e256b1c	4	## Copyright (C) 2012-2014 Uwe Hermann <uwe@hermann-uwe.de>
ed5f826a UH	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
4539e9ca	17	## along with this program; if not, see <http://www.gnu.org/licenses/>.
ed5f826a UH	18	##
ed5f826a UH	19
ed5f826a	20	import sigrokdecode as srd
135b790c	21	from common.srdhelper import bcd2int
ed5f826a	22
da9bcbd9 BV	23	def reg_list():
	24	l = []
	25	for i in range(8 + 1):
	26	l.append(('reg-0x%02x' % i, 'Register 0x%02x' % i))
	27
	28	return tuple(l)
	29
ed5f826a	30	class Decoder(srd.Decoder):
b197383c	31	api_version = 3
ed5f826a UH	32	id = 'rtc8564'
	33	name = 'RTC-8564'
	34	longname = 'Epson RTC-8564 JE/NB'
a465436e	35	desc = 'Realtime clock module protocol.'
ed5f826a UH	36	license = 'gplv2+'
	37	inputs = ['i2c']
	38	outputs = ['rtc8564']
d6d8a8a4	39	tags = ['Clock/timing']
da9bcbd9 BV	40	annotations = reg_list() + (
	41	('read', 'Read date/time'),
	42	('write', 'Write date/time'),
	43	('bit-reserved', 'Reserved bit'),
	44	('bit-vl', 'VL bit'),
	45	('bit-century', 'Century bit'),
	46	('reg-read', 'Register read'),
	47	('reg-write', 'Register write'),
	48	)
3161ab5a	49	annotation_rows = (
09d09ace UH	50	('bits', 'Bits', tuple(range(0, 8 + 1)) + (11, 12, 13)),
09d09ace UH	51	('regs', 'Register access', (14, 15)),
3161ab5a UH	52	('date-time', 'Date/time', (9, 10)),
3161ab5a UH	53	)
ed5f826a	54
92b7b49f	55	def __init__(self):
10aeb8ea GS	56	self.reset()
	57
	58	def reset(self):
2b716038	59	self.state = 'IDLE'
ed5f826a UH	60	self.hours = -1
	61	self.minutes = -1
	62	self.seconds = -1
	63	self.days = -1
3d190141	64	self.weekdays = -1
ed5f826a UH	65	self.months = -1
ed5f826a UH	66	self.years = -1
09d09ace	67	self.bits = []
ed5f826a	68
8915b346	69	def start(self):
be465111	70	self.out_ann = self.register(srd.OUTPUT_ANN)
ed5f826a	71
ed5f826a UH	72	def putx(self, data):
	73	self.put(self.ss, self.es, self.out_ann, data)
	74
09d09ace UH	75	def putd(self, bit1, bit2, data):
	76	self.put(self.bits[bit1][1], self.bits[bit2][2], self.out_ann, data)
	77
	78	def putr(self, bit):
	79	self.put(self.bits[bit][1], self.bits[bit][2], self.out_ann,
	80	[11, ['Reserved bit', 'Reserved', 'Rsvd', 'R']])
	81
ed5f826a UH	82	def handle_reg_0x00(self, b): # Control register 1
	83	pass
	84
	85	def handle_reg_0x01(self, b): # Control register 2
	86	ti_tp = 1 if (b & (1 << 4)) else 0
	87	af = 1 if (b & (1 << 3)) else 0
	88	tf = 1 if (b & (1 << 2)) else 0
	89	aie = 1 if (b & (1 << 1)) else 0
	90	tie = 1 if (b & (1 << 0)) else 0
	91
	92	ann = ''
	93
	94	s = 'repeated' if ti_tp else 'single-shot'
	95	ann += 'TI/TP = %d: %s operation upon fixed-cycle timer interrupt '\
	96	'events\n' % (ti_tp, s)
	97	s = '' if af else 'no '
	98	ann += 'AF = %d: %salarm interrupt detected\n' % (af, s)
	99	s = '' if tf else 'no '
	100	ann += 'TF = %d: %sfixed-cycle timer interrupt detected\n' % (tf, s)
	101	s = 'enabled' if aie else 'prohibited'
	102	ann += 'AIE = %d: INT# pin output %s when an alarm interrupt '\
	103	'occurs\n' % (aie, s)
	104	s = 'enabled' if tie else 'prohibited'
	105	ann += 'TIE = %d: INT# pin output %s when a fixed-cycle interrupt '\
	106	'event occurs\n' % (tie, s)
	107
a4289441	108	self.putx([1, [ann]])
ed5f826a	109
64134a4c	110	def handle_reg_0x02(self, b): # Seconds / Voltage-low bit
ed5f826a	111	vl = 1 if (b & (1 << 7)) else 0
09d09ace	112	self.putd(7, 7, [12, ['Voltage low: %d' % vl, 'Volt. low: %d' % vl,
bff3a0a0	113	'VL: %d' % vl, 'VL']])
09d09ace	114	s = self.seconds = bcd2int(b & 0x7f)
bff3a0a0	115	self.putd(6, 0, [2, ['Second: %d' % s, 'Sec: %d' % s, 'S: %d' % s, 'S']])
ed5f826a UH	116
ed5f826a UH	117	def handle_reg_0x03(self, b): # Minutes
09d09ace	118	self.putr(7)
6e256b1c	119	m = self.minutes = bcd2int(b & 0x7f)
bff3a0a0	120	self.putd(6, 0, [3, ['Minute: %d' % m, 'Min: %d' % m, 'M: %d' % m, 'M']])
ed5f826a UH	121
ed5f826a UH	122	def handle_reg_0x04(self, b): # Hours
09d09ace UH	123	self.putr(7)
09d09ace UH	124	self.putr(6)
6e256b1c	125	h = self.hours = bcd2int(b & 0x3f)
bff3a0a0	126	self.putd(5, 0, [4, ['Hour: %d' % h, 'H: %d' % h, 'H']])
ed5f826a UH	127
ed5f826a UH	128	def handle_reg_0x05(self, b): # Days
09d09ace UH	129	self.putr(7)
09d09ace UH	130	self.putr(6)
6e256b1c	131	d = self.days = bcd2int(b & 0x3f)
bff3a0a0	132	self.putd(5, 0, [5, ['Day: %d' % d, 'D: %d' % d, 'D']])
ed5f826a	133
3d190141	134	def handle_reg_0x06(self, b): # Weekdays
09d09ace UH	135	for i in (7, 6, 5, 4, 3):
09d09ace UH	136	self.putr(i)
6e256b1c	137	w = self.weekdays = bcd2int(b & 0x07)
bff3a0a0	138	self.putd(2, 0, [6, ['Weekday: %d' % w, 'WD: %d' % w, 'WD', 'W']])
ed5f826a	139
64134a4c	140	def handle_reg_0x07(self, b): # Months / century bit
64134a4c	141	c = 1 if (b & (1 << 7)) else 0
bff3a0a0 UH	142	self.putd(7, 7, [13, ['Century bit: %d' % c, 'Century: %d' % c,
bff3a0a0 UH	143	'Cent: %d' % c, 'C: %d' % c, 'C']])
09d09ace UH	144	self.putr(6)
	145	self.putr(5)
	146	m = self.months = bcd2int(b & 0x1f)
bff3a0a0	147	self.putd(4, 0, [7, ['Month: %d' % m, 'Mon: %d' % m, 'M: %d' % m, 'M']])
ed5f826a UH	148
ed5f826a UH	149	def handle_reg_0x08(self, b): # Years
6e256b1c	150	y = self.years = bcd2int(b & 0xff)
bff3a0a0	151	self.putx([8, ['Year: %d' % y, 'Y: %d' % y, 'Y']])
ed5f826a UH	152
	153	def handle_reg_0x09(self, b): # Alarm, minute
	154	pass
	155
	156	def handle_reg_0x0a(self, b): # Alarm, hour
	157	pass
	158
	159	def handle_reg_0x0b(self, b): # Alarm, day
	160	pass
	161
	162	def handle_reg_0x0c(self, b): # Alarm, weekday
	163	pass
	164
	165	def handle_reg_0x0d(self, b): # CLKOUT output
	166	pass
	167
	168	def handle_reg_0x0e(self, b): # Timer setting
	169	pass
	170
	171	def handle_reg_0x0f(self, b): # Down counter for fixed-cycle timer
	172	pass
	173
	174	def decode(self, ss, es, data):
1b75abfd	175	cmd, databyte = data
ed5f826a	176
09d09ace UH	177	# Collect the 'BITS' packet, then return. The next packet is
	178	# guaranteed to belong to these bits we just stored.
	179	if cmd == 'BITS':
	180	self.bits = databyte
	181	return
	182
00197484	183	# Store the start/end samples of this I²C packet.
ed5f826a UH	184	self.ss, self.es = ss, es
	185
	186	# State machine.
2b716038	187	if self.state == 'IDLE':
00197484	188	# Wait for an I²C START condition.
ed5f826a UH	189	if cmd != 'START':
ed5f826a UH	190	return
2b716038	191	self.state = 'GET SLAVE ADDR'
486b19ce	192	self.ss_block = ss
2b716038	193	elif self.state == 'GET SLAVE ADDR':
ed5f826a UH	194	# Wait for an address write operation.
	195	# TODO: We should only handle packets to the RTC slave (0xa2/0xa3).
	196	if cmd != 'ADDRESS WRITE':
	197	return
2b716038 UH	198	self.state = 'GET REG ADDR'
2b716038 UH	199	elif self.state == 'GET REG ADDR':
ed5f826a UH	200	# Wait for a data write (master selects the slave register).
	201	if cmd != 'DATA WRITE':
	202	return
	203	self.reg = databyte
2b716038 UH	204	self.state = 'WRITE RTC REGS'
2b716038 UH	205	elif self.state == 'WRITE RTC REGS':
ed5f826a UH	206	# If we see a Repeated Start here, it's probably an RTC read.
ed5f826a UH	207	if cmd == 'START REPEAT':
2b716038	208	self.state = 'READ RTC REGS'
ed5f826a UH	209	return
	210	# Otherwise: Get data bytes until a STOP condition occurs.
	211	if cmd == 'DATA WRITE':
09d09ace UH	212	r, s = self.reg, '%02X: %02X' % (self.reg, databyte)
	213	self.putx([15, ['Write register %s' % s, 'Write reg %s' % s,
	214	'WR %s' % s, 'WR', 'W']])
ed5f826a UH	215	handle_reg = getattr(self, 'handle_reg_0x%02x' % self.reg)
	216	handle_reg(databyte)
	217	self.reg += 1
	218	# TODO: Check for NACK!
	219	elif cmd == 'STOP':
	220	# TODO: Handle read/write of only parts of these items.
	221	d = '%02d.%02d.%02d %02d:%02d:%02d' % (self.days, self.months,
	222	self.years, self.hours, self.minutes, self.seconds)
486b19ce	223	self.put(self.ss_block, es, self.out_ann,
6e256b1c UH	224	[9, ['Write date/time: %s' % d, 'Write: %s' % d,
6e256b1c UH	225	'W: %s' % d]])
2b716038	226	self.state = 'IDLE'
ed5f826a UH	227	else:
ed5f826a UH	228	pass # TODO
2b716038	229	elif self.state == 'READ RTC REGS':
ed5f826a UH	230	# Wait for an address read operation.
	231	# TODO: We should only handle packets to the RTC slave (0xa2/0xa3).
	232	if cmd == 'ADDRESS READ':
2b716038	233	self.state = 'READ RTC REGS2'
ed5f826a UH	234	return
ed5f826a UH	235	else:
e4f82268	236	pass # TODO
2b716038	237	elif self.state == 'READ RTC REGS2':
ed5f826a	238	if cmd == 'DATA READ':
09d09ace UH	239	r, s = self.reg, '%02X: %02X' % (self.reg, databyte)
	240	self.putx([15, ['Read register %s' % s, 'Read reg %s' % s,
	241	'RR %s' % s, 'RR', 'R']])
ed5f826a UH	242	handle_reg = getattr(self, 'handle_reg_0x%02x' % self.reg)
	243	handle_reg(databyte)
	244	self.reg += 1
	245	# TODO: Check for NACK!
	246	elif cmd == 'STOP':
	247	d = '%02d.%02d.%02d %02d:%02d:%02d' % (self.days, self.months,
	248	self.years, self.hours, self.minutes, self.seconds)
486b19ce	249	self.put(self.ss_block, es, self.out_ann,
6e256b1c UH	250	[10, ['Read date/time: %s' % d, 'Read: %s' % d,
6e256b1c UH	251	'R: %s' % d]])
2b716038	252	self.state = 'IDLE'
ed5f826a UH	253	else:
ed5f826a UH	254	pass # TODO?