2 ## This file is part of the sigrok project.
4 ## Copyright (C) 2010-2011 Uwe Hermann <uwe@hermann-uwe.de>
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.
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.
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
22 # I2C protocol decoder
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).
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
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
40 # START condition (S): SDA = falling, SCL = high
41 # Repeated START condition (Sr): same as S
42 # Data bit sampling: SCL = rising
43 # STOP condition (P): SDA = rising, SCL = high
45 # All data bytes on SDA are exactly 8 bits long (transmitted MSB-first).
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.
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).
51 # After those 7 bits, a data direction bit is sent. If the bit is low that
52 # indicates a WRITE operation, if it's high that indicates a READ operation.
54 # Later an optional 10bit slave addressing scheme was added.
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
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.
72 # The output consists of a (Python) list of I2C "packets", each of which
73 # has an (implicit) index number (its index in the list).
74 # Each packet consists of a Python dict with certain key/value pairs.
76 # TODO: Make this a list later instead of a dict?
79 # - 'S' (START condition)
80 # - 'Sr' (Repeated START)
81 # - 'AR' (Address, read)
82 # - 'AW' (Address, write)
84 # - 'DW' (Data, write)
85 # - 'P' (STOP condition)
86 # 'range': (tuple of 2 integers, the min/max samplenumber of this range)
88 # - min/max can also be identical.
89 # 'data': (actual data as integer ???) TODO: This can be very variable...
90 # 'ann': (string; additional annotations / comments)
93 # [{'type': 'S', 'range': (150, 160), 'data': None, 'ann': 'Foobar'},
94 # {'type': 'AW', 'range': (200, 300), 'data': 0x50, 'ann': 'Slave 4'},
95 # {'type': 'DW', 'range': (310, 370), 'data': 0x00, 'ann': 'Init cmd'},
96 # {'type': 'AR', 'range': (500, 560), 'data': 0x50, 'ann': 'Get stat'},
97 # {'type': 'DR', 'range': (580, 640), 'data': 0xfe, 'ann': 'OK'},
98 # {'type': 'P', 'range': (650, 660), 'data': None, 'ann': None}]
100 # Possible other events:
101 # - Error event in case protocol looks broken:
102 # [{'type': 'ERROR', 'range': (min, max),
103 # 'data': TODO, 'ann': 'This is not a Microchip 24XX64 EEPROM'},
104 # [{'type': 'ERROR', 'range': (min, max),
105 # 'data': TODO, 'ann': 'TODO'},
106 # - TODO: Make list of possible errors accessible as metadata?
108 # TODO: I2C address of slaves.
109 # TODO: Handle multiple different I2C devices on same bus
110 # -> we need to decode multiple protocols at the same time.
111 # TODO: range: Always contiguous? Splitted ranges? Multiple per event?
118 # [[id, channel, description], ...] # TODO
121 # {'id': 'SCL', 'ch': 5, 'desc': 'Serial clock line'}
122 # {'id': 'SDA', 'ch': 7, 'desc': 'Serial data line'}
126 # 'signals': [{'SCL': }]}
130 def __init__(self, data):
132 def probe(self, probe):
133 s = ord(self.data[probe / 8]) & (1 << (probe % 8))
134 return True if s else False
136 def sampleiter(data, unitsize):
137 for i in range(0, len(data), unitsize):
138 yield(Sample(data[i:i+unitsize]))
142 longname = 'Inter-Integrated Circuit (I2C) bus'
143 desc = 'I2C is a two-wire, multi-master, serial bus.'
145 author = 'Uwe Hermann'
146 email = 'uwe@hermann-uwe.de'
151 'scl': {'ch': 0, 'name': 'SCL', 'desc': 'Serial clock line'},
152 'sda': {'ch': 1, 'name': 'SDA', 'desc': 'Serial data line'},
155 'address-space': ['Address space (in bits)', 7],
158 def __init__(self, **kwargs):
159 self.probes = Decoder.probes.copy()
161 # TODO: Don't hardcode the number of channels.
168 self.startsample = -1
169 self.is_repeat_start = 0
171 self.FIND_START, self.FIND_ADDRESS, self.FIND_DATA = range(3)
172 self.state = self.FIND_START
174 # Get the channel/probe number of the SCL/SDA signals.
175 self.scl_bit = self.probes['scl']['ch']
176 self.sda_bit = self.probes['sda']['ch']
181 def start(self, metadata):
182 self.unitsize = metadata["unitsize"]
187 def is_start_condition(self, scl, sda):
188 '''START condition (S): SDA = falling, SCL = high'''
189 if (self.oldsda == 1 and sda == 0) and scl == 1:
193 def is_data_bit(self, scl, sda):
194 '''Data sampling of receiver: SCL = rising'''
195 if self.oldscl == 0 and scl == 1:
199 def is_stop_condition(self, scl, sda):
200 '''STOP condition (P): SDA = rising, SCL = high'''
201 if (self.oldsda == 0 and sda == 1) and scl == 1:
205 def find_start(self, scl, sda):
207 # o = {'type': 'S', 'range': (self.samplenum, self.samplenum),
208 # 'data': None, 'ann': None},
209 o = (self.is_repeat_start == 1) and 'Sr' or 'S'
211 self.state = self.FIND_ADDRESS
212 self.bitcount = self.databyte = 0
213 self.is_repeat_start = 1
217 def find_address_or_data(self, scl, sda):
218 '''Gather 8 bits of data plus the ACK/NACK bit.'''
221 if self.startsample == -1:
222 self.startsample = self.samplenum
225 # Address and data are transmitted MSB-first.
229 # Return if we haven't collected all 8 + 1 bits, yet.
230 if self.bitcount != 9:
233 # We received 8 address/data bits and the ACK/NACK bit.
234 self.databyte >>= 1 # Shift out unwanted ACK/NACK bit here.
236 ack = (sda == 1) and 'N' or 'A'
238 if self.state == self.FIND_ADDRESS:
239 d = self.databyte & 0xfe
240 # The READ/WRITE bit is only in address bytes, not data bytes.
241 self.wr = (self.databyte & 1) and 1 or 0
242 elif self.state == self.FIND_DATA:
248 # o = {'type': self.state,
249 # 'range': (self.startsample, self.samplenum - 1),
250 # 'data': d, 'ann': None}
252 o = {'data': "0x%02x" % d}
255 if self.state == self.FIND_ADDRESS and self.wr == 1:
257 elif self.state == self.FIND_ADDRESS and self.wr == 0:
259 elif self.state == self.FIND_DATA and self.wr == 1:
261 elif self.state == self.FIND_DATA and self.wr == 0:
266 # o = {'type': ack, 'range': (self.samplenum, self.samplenum),
267 # 'data': None, 'ann': None}
270 self.bitcount = self.databyte = 0
271 self.startsample = -1
273 if self.state == self.FIND_ADDRESS:
274 self.state = self.FIND_DATA
275 elif self.state == self.FIND_DATA:
276 # There could be multiple data bytes in a row.
277 # So, either find a STOP condition or another data byte next.
282 def find_stop(self, scl, sda):
285 # o = {'type': 'P', 'range': (self.samplenum, self.samplenum),
286 # 'data': None, 'ann': None},
289 self.state = self.FIND_START
290 self.is_repeat_start = 0
295 def decode(self, data):
296 """I2C protocol decoder"""
301 # We should accept a list of samples and iterate...
302 for sample in sampleiter(data["data"], self.unitsize):
304 # TODO: Eliminate the need for ord().
307 # TODO: Start counting at 0 or 1?
310 # First sample: Save SCL/SDA value.
311 if self.oldscl == None:
312 # Get SCL/SDA bit values (0/1 for low/high) of the first sample.
313 self.oldscl = (s & (1 << self.scl_bit)) >> self.scl_bit
314 self.oldsda = (s & (1 << self.sda_bit)) >> self.sda_bit
317 # Get SCL/SDA bit values (0/1 for low/high).
318 scl = (s & (1 << self.scl_bit)) >> self.scl_bit
319 sda = (s & (1 << self.sda_bit)) >> self.sda_bit
321 # TODO: Wait until the bus is idle (SDA = SCL = 1) first?
324 if self.state == self.FIND_START:
325 if self.is_start_condition(scl, sda):
326 out += self.find_start(scl, sda)
327 elif self.state == self.FIND_ADDRESS:
328 if self.is_data_bit(scl, sda):
329 out += self.find_address_or_data(scl, sda)
330 elif self.state == self.FIND_DATA:
331 if self.is_data_bit(scl, sda):
332 out += self.find_address_or_data(scl, sda)
333 elif self.is_start_condition(scl, sda):
334 out += self.find_start(scl, sda)
335 elif self.is_stop_condition(scl, sda):
336 out += self.find_stop(scl, sda)
341 # Save current SDA/SCL values for the next round.
348 # Use psyco (if available) as it results in huge performance improvements.