[libsigrokdecode.git] / decoders / i2c.py

##
## This file is part of the sigrok project.
##
## Copyright (C) 2010-2011 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, write to the Free Software
## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301 USA
##

#
# I2C protocol decoder
#

#
# The Inter-Integrated Circuit (I2C) bus is a bidirectional, multi-master
# bus using two signals (SCL = serial clock line, SDA = serial data line).
#
# There can be many devices on the same bus. Each device can potentially be
# master or slave (and that can change during runtime). Both slave and master
# can potentially play the transmitter or receiver role (this can also
# change at runtime).
#
# Possible maximum data rates:
#  - Standard mode: 100 kbit/s
#  - Fast mode: 400 kbit/s
#  - Fast-mode Plus: 1 Mbit/s
#  - High-speed mode: 3.4 Mbit/s
#
# START condition (S): SDA = falling, SCL = high
# Repeated START condition (Sr): same as S
# Data bit sampling: SCL = rising
# STOP condition (P): SDA = rising, SCL = high
#
# All data bytes on SDA are exactly 8 bits long (transmitted MSB-first).
# Each byte has to be followed by a 9th ACK/NACK bit. If that bit is low,
# that indicates an ACK, if it's high that indicates a NACK.
#
# After the first START condition, a master sends the device address of the
# slave it wants to talk to. Slave addresses are 7 bits long (MSB-first).
# After those 7 bits, a data direction bit is sent. If the bit is low that
# indicates a WRITE operation, if it's high that indicates a READ operation.
#
# Later an optional 10bit slave addressing scheme was added.
#
# Documentation:
# http://www.nxp.com/acrobat/literature/9398/39340011.pdf (v2.1 spec)
# http://www.nxp.com/acrobat/usermanuals/UM10204_3.pdf (v3 spec)
# http://en.wikipedia.org/wiki/I2C
#

# TODO: Look into arbitration, collision detection, clock synchronisation, etc.
# TODO: Handle clock stretching.
# TODO: Handle combined messages / repeated START.
# TODO: Implement support for 7bit and 10bit slave addresses.
# TODO: Implement support for inverting SDA/SCL levels (0->1 and 1->0).
# TODO: Implement support for detecting various bus errors.
# TODO: I2C address of slaves.
# TODO: Handle multiple different I2C devices on same bus
#       -> we need to decode multiple protocols at the same time.

'''
Protocol output format:

I2C packet:
[<i2c_command>, <data>, <ack_bit>]

<i2c_command> is one of:
  - 'START' (START condition)
  - 'START REPEAT' (Repeated START)
  - 'ADDRESS READ' (Address, read)
  - 'ADDRESS WRITE' (Address, write)
  - 'DATA READ' (Data, read)
  - 'DATA WRITE' (Data, write)
  - 'STOP' (STOP condition)

<data> is the data or address byte associated with the 'ADDRESS*' and 'DATA*'
command. For 'START', 'START REPEAT' and 'STOP', this is None.

<ack_bit> is either 'ACK' or 'NACK', but may also be None.
'''

import sigrokdecode as srd

# Annotation feed formats
ANN_SHIFTED       = 0
ANN_SHIFTED_SHORT = 1
ANN_RAW           = 2

# Values are verbose and short annotation, respectively.
protocol = {
    'START':           ['START',         'S'],
    'START REPEAT':    ['START REPEAT',  'Sr'],
    'STOP':            ['STOP',          'P'],
    'ACK':             ['ACK',           'A'],
    'NACK':            ['NACK',          'N'],
    'ADDRESS READ':    ['ADDRESS READ',  'AR'],
    'ADDRESS WRITE':   ['ADDRESS WRITE', 'AW'],
    'DATA READ':       ['DATA READ',     'DR'],
    'DATA WRITE':      ['DATA WRITE',    'DW'],
}

# States
FIND_START = 0
FIND_ADDRESS = 1
FIND_DATA = 2

class Decoder(srd.Decoder):
    id = 'i2c'
    name = 'I2C'
    longname = 'Inter-Integrated Circuit'
    desc = 'I2C is a two-wire, multi-master, serial bus.'
    longdesc = '...'
    author = 'Uwe Hermann'
    email = 'uwe@hermann-uwe.de'
    license = 'gplv2+'
    inputs = ['logic']
    outputs = ['i2c']
    probes = [
        {'id': 'scl', 'name': 'SCL', 'desc': 'Serial clock line'},
        {'id': 'sda', 'name': 'SDA', 'desc': 'Serial data line'},
    ]
    options = {
        'addressing': ['Slave addressing (in bits)', 7], # 7 or 10
    }
    annotations = [
        # ANN_SHIFTED
        ['7-bit shifted hex',
         'Read/write bit shifted out from the 8-bit I2C slave address'],
        # ANN_SHIFTED_SHORT
        ['7-bit shifted hex (short)',
         'Read/write bit shifted out from the 8-bit I2C slave address'],
        # ANN_RAW
        ['Raw hex', 'Unaltered raw data'],
    ]

    def __init__(self, **kwargs):
        self.samplecnt = 0
        self.bitcount = 0
        self.databyte = 0
        self.wr = -1
        self.startsample = -1
        self.is_repeat_start = 0
        self.state = FIND_START
        self.oldscl = None
        self.oldsda = None

        # Set protocol decoder option defaults.
        self.addressing = Decoder.options['addressing'][1]

    def start(self, metadata):
        self.out_proto = self.add(srd.OUTPUT_PROTO, 'i2c')
        self.out_ann = self.add(srd.OUTPUT_ANN, 'i2c')

    def report(self):
        pass

    def is_start_condition(self, scl, sda):
        # START condition (S): SDA = falling, SCL = high
        if (self.oldsda == 1 and sda == 0) and scl == 1:
            return True
        return False

    def is_data_bit(self, scl, sda):
        # Data sampling of receiver: SCL = rising
        if self.oldscl == 0 and scl == 1:
            return True
        return False

    def is_stop_condition(self, scl, sda):
        # STOP condition (P): SDA = rising, SCL = high
        if (self.oldsda == 0 and sda == 1) and scl == 1:
            return True
        return False

    def found_start(self, scl, sda):
        cmd = 'START REPEAT' if (self.is_repeat_start == 1) else 'START'

        self.put(self.out_proto, [cmd, None, None])
        self.put(self.out_ann, [ANN_SHIFTED, [protocol[cmd][0]]])
        self.put(self.out_ann, [ANN_SHIFTED_SHORT, [protocol[cmd][1]]])

        self.state = FIND_ADDRESS
        self.bitcount = self.databyte = 0
        self.is_repeat_start = 1
        self.wr = -1

    def found_address_or_data(self, scl, sda):
        # Gather 8 bits of data plus the ACK/NACK bit.

        if self.startsample == -1:
            # TODO: Should be samplenum, as received from the feed.
            self.startsample = self.samplecnt
        self.bitcount += 1

        # Address and data are transmitted MSB-first.
        self.databyte <<= 1
        self.databyte |= sda

        # Return if we haven't collected all 8 + 1 bits, yet.
        if self.bitcount != 9:
            return

        # Send raw output annotation before we start shifting out
        # read/write and ack/nack bits.
        self.put(self.out_ann, [ANN_RAW, ['0x%.2x' % self.databyte]])

        # We received 8 address/data bits and the ACK/NACK bit.
        self.databyte >>= 1 # Shift out unwanted ACK/NACK bit here.

        if self.state == FIND_ADDRESS:
            # The READ/WRITE bit is only in address bytes, not data bytes.
            self.wr = 0 if (self.databyte & 1) else 1
            d = self.databyte >> 1
        elif self.state == FIND_DATA:
            d = self.databyte
        else:
            # TODO: Error?
            pass

        # Last bit that came in was the ACK/NACK bit (1 = NACK).
        ack_bit = 'NACK' if (sda == 1) else 'ACK'

        if self.state == FIND_ADDRESS and self.wr == 1:
            cmd = 'ADDRESS WRITE'
        elif self.state == FIND_ADDRESS and self.wr == 0:
            cmd = 'ADDRESS READ'
        elif self.state == FIND_DATA and self.wr == 1:
            cmd = 'DATA WRITE'
        elif self.state == FIND_DATA and self.wr == 0:
            cmd = 'DATA READ'

        self.put(self.out_proto, [cmd, d, ack_bit])
        self.put(self.out_ann, [ANN_SHIFTED,
                 [protocol[cmd][0], '0x%02x' % d, protocol[ack_bit][0]]])
        self.put(self.out_ann, [ANN_SHIFTED_SHORT,
                 [protocol[cmd][1], '0x%02x' % d, protocol[ack_bit][1]]])

        self.bitcount = self.databyte = 0
        self.startsample = -1

        if self.state == FIND_ADDRESS:
            self.state = FIND_DATA
        elif self.state == FIND_DATA:
            # There could be multiple data bytes in a row.
            # So, either find a STOP condition or another data byte next.
            pass

    def found_stop(self, scl, sda):
        self.put(self.out_proto, ['STOP', None, None])
        self.put(self.out_ann, [ANN_SHIFTED, [protocol['STOP'][0]]])
        self.put(self.out_ann, [ANN_SHIFTED_SHORT, [protocol['STOP'][1]]])

        self.state = FIND_START
        self.is_repeat_start = 0
        self.wr = -1

    def put(self, output_id, data):
        # Inject sample range into the call up to sigrok.
        # TODO: 0-0 sample range for now.
        super(Decoder, self).put(0, 0, output_id, data)

    def decode(self, ss, es, data):
        for samplenum, (scl, sda) in data:
            self.samplecnt += 1

            # First sample: Save SCL/SDA value.
            if self.oldscl == None:
                self.oldscl = scl
                self.oldsda = sda
                continue

            # TODO: Wait until the bus is idle (SDA = SCL = 1) first?

            # State machine.
            if self.state == FIND_START:
                if self.is_start_condition(scl, sda):
                    self.found_start(scl, sda)
            elif self.state == FIND_ADDRESS:
                if self.is_data_bit(scl, sda):
                    self.found_address_or_data(scl, sda)
            elif self.state == FIND_DATA:
                if self.is_data_bit(scl, sda):
                    self.found_address_or_data(scl, sda)
                elif self.is_start_condition(scl, sda):
                    self.found_start(scl, sda)
                elif self.is_stop_condition(scl, sda):
                    self.found_stop(scl, sda)
            else:
                # TODO: Error?
                pass

            # Save current SDA/SCL values for the next round.
            self.oldscl = scl
            self.oldsda = sda
Commit	Line	Data
0588ed70 UH	1	##
	2	## This file is part of the sigrok project.
	3	##
7b86f0bc	4	## Copyright (C) 2010-2011 Uwe Hermann <uwe@hermann-uwe.de>
0588ed70 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
	17	## along with this program; if not, write to the Free Software
	18	## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
	19	##
	20
	21	#
	22	# I2C protocol decoder
	23	#
	24
9e587cc9	25	#
0588ed70 UH	26	# The Inter-Integrated Circuit (I2C) bus is a bidirectional, multi-master
	27	# bus using two signals (SCL = serial clock line, SDA = serial data line).
	28	#
	29	# There can be many devices on the same bus. Each device can potentially be
	30	# master or slave (and that can change during runtime). Both slave and master
	31	# can potentially play the transmitter or receiver role (this can also
	32	# change at runtime).
	33	#
	34	# Possible maximum data rates:
	35	# - Standard mode: 100 kbit/s
	36	# - Fast mode: 400 kbit/s
	37	# - Fast-mode Plus: 1 Mbit/s
	38	# - High-speed mode: 3.4 Mbit/s
	39	#
	40	# START condition (S): SDA = falling, SCL = high
	41	# Repeated START condition (Sr): same as S
7b86f0bc	42	# Data bit sampling: SCL = rising
0588ed70 UH	43	# STOP condition (P): SDA = rising, SCL = high
0588ed70 UH	44	#
33e72c54	45	# All data bytes on SDA are exactly 8 bits long (transmitted MSB-first).
0588ed70 UH	46	# Each byte has to be followed by a 9th ACK/NACK bit. If that bit is low,
	47	# that indicates an ACK, if it's high that indicates a NACK.
	48	#
	49	# After the first START condition, a master sends the device address of the
	50	# slave it wants to talk to. Slave addresses are 7 bits long (MSB-first).
33e72c54	51	# After those 7 bits, a data direction bit is sent. If the bit is low that
0588ed70 UH	52	# indicates a WRITE operation, if it's high that indicates a READ operation.
	53	#
	54	# Later an optional 10bit slave addressing scheme was added.
	55	#
	56	# Documentation:
	57	# http://www.nxp.com/acrobat/literature/9398/39340011.pdf (v2.1 spec)
	58	# http://www.nxp.com/acrobat/usermanuals/UM10204_3.pdf (v3 spec)
	59	# http://en.wikipedia.org/wiki/I2C
	60	#
	61
	62	# TODO: Look into arbitration, collision detection, clock synchronisation, etc.
	63	# TODO: Handle clock stretching.
	64	# TODO: Handle combined messages / repeated START.
	65	# TODO: Implement support for 7bit and 10bit slave addresses.
	66	# TODO: Implement support for inverting SDA/SCL levels (0->1 and 1->0).
	67	# TODO: Implement support for detecting various bus errors.
23fb2e12 UH	68	# TODO: I2C address of slaves.
	69	# TODO: Handle multiple different I2C devices on same bus
	70	# -> we need to decode multiple protocols at the same time.
23fb2e12	71
9e587cc9 UH	72	'''
9e587cc9 UH	73	Protocol output format:
87998e97	74
9e587cc9 UH	75	I2C packet:
9e587cc9 UH	76	[<i2c_command>, <data>, <ack_bit>]
87998e97	77
9e587cc9	78	<i2c_command> is one of:
87998e97	79	- 'START' (START condition)
9e587cc9 UH	80	- 'START REPEAT' (Repeated START)
	81	- 'ADDRESS READ' (Address, read)
	82	- 'ADDRESS WRITE' (Address, write)
	83	- 'DATA READ' (Data, read)
	84	- 'DATA WRITE' (Data, write)
87998e97 BV	85	- 'STOP' (STOP condition)
87998e97 BV	86
9e587cc9 UH	87	<data> is the data or address byte associated with the 'ADDRESS' and 'DATA'
9e587cc9 UH	88	command. For 'START', 'START REPEAT' and 'STOP', this is None.
87998e97	89
9e587cc9 UH	90	<ack_bit> is either 'ACK' or 'NACK', but may also be None.
9e587cc9 UH	91	'''
23fb2e12	92
677d597b	93	import sigrokdecode as srd
b2c19614	94
eb7082c9	95	# Annotation feed formats
7ce7775c BV	96	ANN_SHIFTED = 0
	97	ANN_SHIFTED_SHORT = 1
	98	ANN_RAW = 2
	99
eb7082c9	100	# Values are verbose and short annotation, respectively.
15969949	101	protocol = {
eb7082c9	102	'START': ['START', 'S'],
a2d2aff2	103	'START REPEAT': ['START REPEAT', 'Sr'],
eb7082c9 UH	104	'STOP': ['STOP', 'P'],
	105	'ACK': ['ACK', 'A'],
	106	'NACK': ['NACK', 'N'],
a2d2aff2 UH	107	'ADDRESS READ': ['ADDRESS READ', 'AR'],
	108	'ADDRESS WRITE': ['ADDRESS WRITE', 'AW'],
	109	'DATA READ': ['DATA READ', 'DR'],
	110	'DATA WRITE': ['DATA WRITE', 'DW'],
15969949	111	}
e5080882	112
400f9ae7 UH	113	# States
	114	FIND_START = 0
	115	FIND_ADDRESS = 1
	116	FIND_DATA = 2
	117
677d597b	118	class Decoder(srd.Decoder):
67e847fd	119	id = 'i2c'
f39d2404	120	name = 'I2C'
9a12a6e7	121	longname = 'Inter-Integrated Circuit'
f39d2404 UH	122	desc = 'I2C is a two-wire, multi-master, serial bus.'
	123	longdesc = '...'
	124	author = 'Uwe Hermann'
	125	email = 'uwe@hermann-uwe.de'
	126	license = 'gplv2+'
	127	inputs = ['logic']
	128	outputs = ['i2c']
bc5f5a43 BV	129	probes = [
	130	{'id': 'scl', 'name': 'SCL', 'desc': 'Serial clock line'},
	131	{'id': 'sda', 'name': 'SDA', 'desc': 'Serial data line'},
	132	]
f39d2404	133	options = {
ea90233e	134	'addressing': ['Slave addressing (in bits)', 7], # 7 or 10
ad2dc0de	135	}
e97b6ef5	136	annotations = [
15969949	137	# ANN_SHIFTED
eb7082c9 UH	138	['7-bit shifted hex',
eb7082c9 UH	139	'Read/write bit shifted out from the 8-bit I2C slave address'],
15969949	140	# ANN_SHIFTED_SHORT
eb7082c9 UH	141	['7-bit shifted hex (short)',
eb7082c9 UH	142	'Read/write bit shifted out from the 8-bit I2C slave address'],
15969949	143	# ANN_RAW
eb7082c9	144	['Raw hex', 'Unaltered raw data'],
15969949	145	]
0588ed70	146
3643fc3f	147	def __init__(self, **kwargs):
bc5f5a43	148	self.samplecnt = 0
f39d2404 UH	149	self.bitcount = 0
	150	self.databyte = 0
	151	self.wr = -1
	152	self.startsample = -1
5dd9af5b	153	self.is_repeat_start = 0
400f9ae7	154	self.state = FIND_START
f39d2404 UH	155	self.oldscl = None
	156	self.oldsda = None
	157
ea90233e UH	158	# Set protocol decoder option defaults.
	159	self.addressing = Decoder.options['addressing'][1]
	160
3643fc3f	161	def start(self, metadata):
56202222 UH	162	self.out_proto = self.add(srd.OUTPUT_PROTO, 'i2c')
56202222 UH	163	self.out_ann = self.add(srd.OUTPUT_ANN, 'i2c')
3643fc3f	164
f39d2404 UH	165	def report(self):
	166	pass
	167
7b86f0bc	168	def is_start_condition(self, scl, sda):
eb7082c9	169	# START condition (S): SDA = falling, SCL = high
7b86f0bc UH	170	if (self.oldsda == 1 and sda == 0) and scl == 1:
	171	return True
	172	return False
	173
	174	def is_data_bit(self, scl, sda):
eb7082c9	175	# Data sampling of receiver: SCL = rising
7b86f0bc UH	176	if self.oldscl == 0 and scl == 1:
	177	return True
	178	return False
	179
	180	def is_stop_condition(self, scl, sda):
eb7082c9	181	# STOP condition (P): SDA = rising, SCL = high
7b86f0bc UH	182	if (self.oldsda == 0 and sda == 1) and scl == 1:
	183	return True
	184	return False
	185
e5080882	186	def found_start(self, scl, sda):
ba24aaf7	187	cmd = 'START REPEAT' if (self.is_repeat_start == 1) else 'START'
eb7082c9 UH	188
	189	self.put(self.out_proto, [cmd, None, None])
	190	self.put(self.out_ann, [ANN_SHIFTED, [protocol[cmd][0]]])
	191	self.put(self.out_ann, [ANN_SHIFTED_SHORT, [protocol[cmd][1]]])
e5080882	192
400f9ae7	193	self.state = FIND_ADDRESS
7b86f0bc	194	self.bitcount = self.databyte = 0
5dd9af5b	195	self.is_repeat_start = 1
7b86f0bc	196	self.wr = -1
7b86f0bc	197
e5080882	198	def found_address_or_data(self, scl, sda):
eb7082c9	199	# Gather 8 bits of data plus the ACK/NACK bit.
7b86f0bc UH	200
7b86f0bc UH	201	if self.startsample == -1:
eb7082c9	202	# TODO: Should be samplenum, as received from the feed.
bc5f5a43	203	self.startsample = self.samplecnt
7b86f0bc UH	204	self.bitcount += 1
	205
	206	# Address and data are transmitted MSB-first.
	207	self.databyte <<= 1
	208	self.databyte \|= sda
	209
	210	# Return if we haven't collected all 8 + 1 bits, yet.
	211	if self.bitcount != 9:
eb7082c9	212	return
7b86f0bc	213
eb7082c9 UH	214	# Send raw output annotation before we start shifting out
	215	# read/write and ack/nack bits.
	216	self.put(self.out_ann, [ANN_RAW, ['0x%.2x' % self.databyte]])
15969949	217
7b86f0bc UH	218	# We received 8 address/data bits and the ACK/NACK bit.
	219	self.databyte >>= 1 # Shift out unwanted ACK/NACK bit here.
	220
400f9ae7	221	if self.state == FIND_ADDRESS:
7b86f0bc	222	# The READ/WRITE bit is only in address bytes, not data bytes.
bf1c3f4d	223	self.wr = 0 if (self.databyte & 1) else 1
84b81f1d	224	d = self.databyte >> 1
400f9ae7	225	elif self.state == FIND_DATA:
7b86f0bc UH	226	d = self.databyte
	227	else:
	228	# TODO: Error?
	229	pass
	230
eb7082c9	231	# Last bit that came in was the ACK/NACK bit (1 = NACK).
bf1c3f4d	232	ack_bit = 'NACK' if (sda == 1) else 'ACK'
15969949	233
400f9ae7	234	if self.state == FIND_ADDRESS and self.wr == 1:
a2d2aff2	235	cmd = 'ADDRESS WRITE'
400f9ae7	236	elif self.state == FIND_ADDRESS and self.wr == 0:
a2d2aff2	237	cmd = 'ADDRESS READ'
400f9ae7	238	elif self.state == FIND_DATA and self.wr == 1:
a2d2aff2	239	cmd = 'DATA WRITE'
400f9ae7	240	elif self.state == FIND_DATA and self.wr == 0:
a2d2aff2	241	cmd = 'DATA READ'
eb7082c9 UH	242
eb7082c9 UH	243	self.put(self.out_proto, [cmd, d, ack_bit])
957da073 UH	244	self.put(self.out_ann, [ANN_SHIFTED,
	245	[protocol[cmd][0], '0x%02x' % d, protocol[ack_bit][0]]])
	246	self.put(self.out_ann, [ANN_SHIFTED_SHORT,
	247	[protocol[cmd][1], '0x%02x' % d, protocol[ack_bit][1]]])
7b86f0bc	248
7b86f0bc UH	249	self.bitcount = self.databyte = 0
	250	self.startsample = -1
	251
400f9ae7 UH	252	if self.state == FIND_ADDRESS:
	253	self.state = FIND_DATA
	254	elif self.state == FIND_DATA:
7b86f0bc UH	255	# There could be multiple data bytes in a row.
	256	# So, either find a STOP condition or another data byte next.
	257	pass
	258
e5080882	259	def found_stop(self, scl, sda):
eb7082c9 UH	260	self.put(self.out_proto, ['STOP', None, None])
	261	self.put(self.out_ann, [ANN_SHIFTED, [protocol['STOP'][0]]])
	262	self.put(self.out_ann, [ANN_SHIFTED_SHORT, [protocol['STOP'][1]]])
7b86f0bc	263
400f9ae7	264	self.state = FIND_START
5dd9af5b	265	self.is_repeat_start = 0
7b86f0bc UH	266	self.wr = -1
7b86f0bc UH	267
1aef2f93	268	def put(self, output_id, data):
eb7082c9 UH	269	# Inject sample range into the call up to sigrok.
eb7082c9 UH	270	# TODO: 0-0 sample range for now.
bc5f5a43	271	super(Decoder, self).put(0, 0, output_id, data)
1aef2f93	272
2b9837d9	273	def decode(self, ss, es, data):
bc5f5a43 BV	274	for samplenum, (scl, sda) in data:
bc5f5a43 BV	275	self.samplecnt += 1
f39d2404 UH	276
	277	# First sample: Save SCL/SDA value.
	278	if self.oldscl == None:
bc5f5a43 BV	279	self.oldscl = scl
bc5f5a43 BV	280	self.oldsda = sda
ad2dc0de	281	continue
0588ed70	282
f39d2404 UH	283	# TODO: Wait until the bus is idle (SDA = SCL = 1) first?
f39d2404 UH	284
7b86f0bc	285	# State machine.
400f9ae7	286	if self.state == FIND_START:
7b86f0bc	287	if self.is_start_condition(scl, sda):
e5080882	288	self.found_start(scl, sda)
400f9ae7	289	elif self.state == FIND_ADDRESS:
7b86f0bc	290	if self.is_data_bit(scl, sda):
e5080882	291	self.found_address_or_data(scl, sda)
400f9ae7	292	elif self.state == FIND_DATA:
7b86f0bc	293	if self.is_data_bit(scl, sda):
e5080882	294	self.found_address_or_data(scl, sda)
7b86f0bc	295	elif self.is_start_condition(scl, sda):
e5080882	296	self.found_start(scl, sda)
7b86f0bc	297	elif self.is_stop_condition(scl, sda):
e5080882	298	self.found_stop(scl, sda)
7b86f0bc UH	299	else:
	300	# TODO: Error?
	301	pass
f39d2404 UH	302
	303	# Save current SDA/SCL values for the next round.
	304	self.oldscl = scl
	305	self.oldsda = sda
	306