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

##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2012-2013 Uwe Hermann <uwe@hermann-uwe.de>
## Copyright (C) 2019 Stephan Thiele <stephan.thiele@mailbox.org>
##
## 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

class SamplerateError(Exception):
    pass

def dlc2len(dlc):
    return [0, 1, 2, 3, 4, 5, 6, 7, 8, 12, 16, 20, 24, 32, 48, 64][dlc]

class Decoder(srd.Decoder):
    api_version = 3
    id = 'can'
    name = 'CAN'
    longname = 'Controller Area Network'
    desc = 'Field bus protocol for distributed realtime control.'
    license = 'gplv2+'
    inputs = ['logic']
    outputs = []
    tags = ['Automotive']
    channels = (
        {'id': 'can_rx', 'name': 'CAN RX', 'desc': 'CAN bus line'},
    )
    options = (
        {'id': 'nominal_bitrate', 'desc': 'Nominal bitrate (bits/s)', 'default': 1000000},
        {'id': 'fast_bitrate', 'desc': 'Fast bitrate (bits/s)', 'default': 2000000},
        {'id': 'sample_point', 'desc': 'Sample point (%)', 'default': 70.0},
    )
    annotations = (
        ('data', 'CAN payload data'),
        ('sof', 'Start of frame'),
        ('eof', 'End of frame'),
        ('id', 'Identifier'),
        ('ext-id', 'Extended identifier'),
        ('full-id', 'Full identifier'),
        ('ide', 'Identifier extension bit'),
        ('reserved-bit', 'Reserved bit 0 and 1'),
        ('rtr', 'Remote transmission request'),
        ('srr', 'Substitute remote request'),
        ('dlc', 'Data length count'),
        ('crc-sequence', 'CRC sequence'),
        ('crc-delimiter', 'CRC delimiter'),
        ('ack-slot', 'ACK slot'),
        ('ack-delimiter', 'ACK delimiter'),
        ('stuff-bit', 'Stuff bit'),
        ('warnings', 'Human-readable warnings'),
        ('bit', 'Bit'),
    )
    annotation_rows = (
        ('bits', 'Bits', (15, 17)),
        ('fields', 'Fields', tuple(range(15))),
        ('warnings', 'Warnings', (16,)),
    )

    def __init__(self):
        self.reset()

    def reset(self):
        self.samplerate = None
        self.reset_variables()

    def start(self):
        self.out_ann = self.register(srd.OUTPUT_ANN)

    def set_bit_rate(self, bitrate):
        self.bit_width = float(self.samplerate) / float(bitrate)
        self.sample_point = (self.bit_width / 100.0) * self.options['sample_point']

    def set_nominal_bitrate(self):
        self.set_bit_rate(self.options['nominal_bitrate'])

    def set_fast_bitrate(self):
        self.set_bit_rate(self.options['fast_bitrate'])

    def metadata(self, key, value):
        if key == srd.SRD_CONF_SAMPLERATE:
            self.samplerate = value
            self.bit_width = float(self.samplerate) / float(self.options['nominal_bitrate'])
            self.sample_point = (self.bit_width / 100.0) * self.options['sample_point']

    # Generic helper for CAN bit annotations.
    def putg(self, ss, es, data):
        left, right = int(self.sample_point), int(self.bit_width - self.sample_point)
        self.put(ss - left, es + right, self.out_ann, data)

    # Single-CAN-bit annotation using the current samplenum.
    def putx(self, data):
        self.putg(self.samplenum, self.samplenum, data)

    # Single-CAN-bit annotation using the samplenum of CAN bit 12.
    def put12(self, data):
        self.putg(self.ss_bit12, self.ss_bit12, data)

    # Single-CAN-bit annotation using the samplenum of CAN bit 32.
    def put32(self, data):
        self.putg(self.ss_bit32, self.ss_bit32, data)

    # Multi-CAN-bit annotation from self.ss_block to current samplenum.
    def putb(self, data):
        self.putg(self.ss_block, self.samplenum, data)

    def reset_variables(self):
        self.state = 'IDLE'
        self.sof = self.frame_type = self.dlc = None
        self.rawbits = [] # All bits, including stuff bits
        self.bits = [] # Only actual CAN frame bits (no stuff bits)
        self.curbit = 0 # Current bit of CAN frame (bit 0 == SOF)
        self.last_databit = 999 # Positive value that bitnum+x will never match
        self.ss_block = None
        self.ss_bit12 = None
        self.ss_bit32 = None
        self.ss_databytebits = []
        self.fd = False
        self.rtr = None

    # Poor man's clock synchronization. Use signal edges which change to
    # dominant state in rather simple ways. This naive approach is neither
    # aware of the SYNC phase's width nor the specific location of the edge,
    # but improves the decoder's reliability when the input signal's bitrate
    # does not exactly match the nominal rate.
    def dom_edge_seen(self, force = False):
        self.dom_edge_snum = self.samplenum
        self.dom_edge_bcount = self.curbit

    # Determine the position of the next desired bit's sample point.
    def get_sample_point(self, bitnum):
        samplenum = self.dom_edge_snum
        samplenum += self.bit_width * (bitnum - self.dom_edge_bcount)
        samplenum += self.sample_point
        return int(samplenum)

    def is_stuff_bit(self):
        # CAN uses NRZ encoding and bit stuffing.
        # After 5 identical bits, a stuff bit of opposite value is added.
        # But not in the CRC delimiter, ACK, and end of frame fields.
        if len(self.bits) > self.last_databit + 17:
            return False
        last_6_bits = self.rawbits[-6:]
        if last_6_bits not in ([0, 0, 0, 0, 0, 1], [1, 1, 1, 1, 1, 0]):
            return False

        # Stuff bit. Keep it in self.rawbits, but drop it from self.bits.
        self.bits.pop() # Drop last bit.
        return True

    def is_valid_crc(self, crc_bits):
        return True # TODO

    def decode_error_frame(self, bits):
        pass # TODO

    def decode_overload_frame(self, bits):
        pass # TODO

    # Both standard and extended frames end with CRC, CRC delimiter, ACK,
    # ACK delimiter, and EOF fields. Handle them in a common function.
    # Returns True if the frame ended (EOF), False otherwise.
    def decode_frame_end(self, can_rx, bitnum):

        # Remember start of CRC sequence (see below).
        if bitnum == (self.last_databit + 1):
            self.ss_block = self.samplenum
            if self.fd:
                if dlc2len(self.dlc) < 16:
                    self.crc_len = 27 # 17 + SBC + stuff bits
                else:
                    self.crc_len = 32 # 21 + SBC + stuff bits
            else:
                self.crc_len = 15

        # CRC sequence (15 bits, 17 bits or 21 bits)
        elif bitnum == (self.last_databit + self.crc_len):
            if self.fd:
                if dlc2len(self.dlc) < 16:
                    crc_type = "CRC-17"
                else:
                    crc_type = "CRC-21"
            else:
                crc_type = "CRC-15"

            x = self.last_databit + 1
            crc_bits = self.bits[x:x + self.crc_len + 1]
            self.crc = int(''.join(str(d) for d in crc_bits), 2)
            self.putb([11, ['%s sequence: 0x%04x' % (crc_type, self.crc),
                            '%s: 0x%04x' % (crc_type, self.crc), '%s' % crc_type]])
            if not self.is_valid_crc(crc_bits):
                self.putb([16, ['CRC is invalid']])

        # CRC delimiter bit (recessive)
        elif bitnum == (self.last_databit + self.crc_len + 1):
            self.putx([12, ['CRC delimiter: %d' % can_rx,
                            'CRC d: %d' % can_rx, 'CRC d']])
            if can_rx != 1:
                self.putx([16, ['CRC delimiter must be a recessive bit']])

            if self.fd:
                self.set_nominal_bitrate()

        # ACK slot bit (dominant: ACK, recessive: NACK)
        elif bitnum == (self.last_databit + self.crc_len + 2):
            ack = 'ACK' if can_rx == 0 else 'NACK'
            self.putx([13, ['ACK slot: %s' % ack, 'ACK s: %s' % ack, 'ACK s']])

        # ACK delimiter bit (recessive)
        elif bitnum == (self.last_databit + self.crc_len + 3):
            self.putx([14, ['ACK delimiter: %d' % can_rx,
                            'ACK d: %d' % can_rx, 'ACK d']])
            if can_rx != 1:
                self.putx([16, ['ACK delimiter must be a recessive bit']])

        # Remember start of EOF (see below).
        elif bitnum == (self.last_databit + self.crc_len + 4):
            self.ss_block = self.samplenum

        # End of frame (EOF), 7 recessive bits
        elif bitnum == (self.last_databit + self.crc_len + 10):
            self.putb([2, ['End of frame', 'EOF', 'E']])
            if self.rawbits[-7:] != [1, 1, 1, 1, 1, 1, 1]:
                self.putb([16, ['End of frame (EOF) must be 7 recessive bits']])
            self.reset_variables()
            return True

        return False

    # Returns True if the frame ended (EOF), False otherwise.
    def decode_standard_frame(self, can_rx, bitnum):

        # Bit 14: FDF (Flexible data format)
        # Has to be sent dominant when FD frame, has to be sent recessive
        # when classic CAN frame.
        if bitnum == 14:
            self.fd = True if can_rx else False
            if self.fd:
                self.putx([7, ['Flexible data format: %d' % can_rx,
                               'FDF: %d' % can_rx, 'FDF']])
            else:
                self.putx([7, ['Reserved bit 0: %d' % can_rx,
                               'RB0: %d' % can_rx, 'RB0']])

            if self.fd:
                # Bit 12: Substitute remote request (SRR) bit
                self.put12([8, ['Substitute remote request', 'SRR']])
                self.dlc_start = 18
            else:
                # Bit 12: Remote transmission request (RTR) bit
                # Data frame: dominant, remote frame: recessive
                # Remote frames do not contain a data field.
                rtr = 'remote' if self.bits[12] == 1 else 'data'
                self.put12([8, ['Remote transmission request: %s frame' % rtr,
                                'RTR: %s frame' % rtr, 'RTR']])
                self.dlc_start = 15

        if bitnum == 15 and self.fd:
            self.putx([7, ['Reserved: %d' % can_rx, 'R0: %d' % can_rx, 'R0']])

        if bitnum == 16 and self.fd:
            self.putx([7, ['Bit rate switch: %d' % can_rx, 'BRS: %d' % can_rx, 'BRS']])

        if bitnum == 17 and self.fd:
            self.putx([7, ['Error state indicator: %d' % can_rx, 'ESI: %d' % can_rx, 'ESI']])

        # Remember start of DLC (see below).
        elif bitnum == self.dlc_start:
            self.ss_block = self.samplenum

        # Bits 15-18: Data length code (DLC), in number of bytes (0-8).
        elif bitnum == self.dlc_start + 3:
            self.dlc = int(''.join(str(d) for d in self.bits[self.dlc_start:self.dlc_start + 4]), 2)
            self.putb([10, ['Data length code: %d' % self.dlc,
                            'DLC: %d' % self.dlc, 'DLC']])
            self.last_databit = self.dlc_start + 3 + (dlc2len(self.dlc) * 8)
            if self.dlc > 8 and not self.fd:
                self.putb([16, ['Data length code (DLC) > 8 is not allowed']])

        # Remember all databyte bits, except the very last one.
        elif bitnum in range(self.dlc_start + 4, self.last_databit):
            self.ss_databytebits.append(self.samplenum)

        # Bits 19-X: Data field (0-8 bytes, depending on DLC)
        # The bits within a data byte are transferred MSB-first.
        elif bitnum == self.last_databit:
            self.ss_databytebits.append(self.samplenum) # Last databyte bit.
            for i in range(dlc2len(self.dlc)):
                x = self.dlc_start + 4 + (8 * i)
                b = int(''.join(str(d) for d in self.bits[x:x + 8]), 2)
                ss = self.ss_databytebits[i * 8]
                es = self.ss_databytebits[((i + 1) * 8) - 1]
                self.putg(ss, es, [0, ['Data byte %d: 0x%02x' % (i, b),
                                       'DB %d: 0x%02x' % (i, b), 'DB']])
            self.ss_databytebits = []

        elif bitnum > self.last_databit:
            return self.decode_frame_end(can_rx, bitnum)

        return False

    # Returns True if the frame ended (EOF), False otherwise.
    def decode_extended_frame(self, can_rx, bitnum):

        # Remember start of EID (see below).
        if bitnum == 14:
            self.ss_block = self.samplenum
            self.fd = False
            self.dlc_start = 35

        # Bits 14-31: Extended identifier (EID[17..0])
        elif bitnum == 31:
            self.eid = int(''.join(str(d) for d in self.bits[14:]), 2)
            s = '%d (0x%x)' % (self.eid, self.eid)
            self.putb([4, ['Extended Identifier: %s' % s,
                           'Extended ID: %s' % s, 'Extended ID', 'EID']])

            self.fullid = self.id << 18 | self.eid
            s = '%d (0x%x)' % (self.fullid, self.fullid)
            self.putb([5, ['Full Identifier: %s' % s, 'Full ID: %s' % s,
                           'Full ID', 'FID']])

            # Bit 12: Substitute remote request (SRR) bit
            self.put12([9, ['Substitute remote request: %d' % self.bits[12],
                            'SRR: %d' % self.bits[12], 'SRR']])

        # Bit 32: Remote transmission request (RTR) bit
        # Data frame: dominant, remote frame: recessive
        # Remote frames do not contain a data field.

        # Remember start of RTR (see below).
        if bitnum == 32:
            self.ss_bit32 = self.samplenum
            self.rtr = can_rx

            if not self.fd:
               rtr = 'remote' if can_rx == 1 else 'data'
               self.putx([8, ['Remote transmission request: %s frame' % rtr,
                              'RTR: %s frame' % rtr, 'RTR']])

        # Bit 33: RB1 (reserved bit)
        elif bitnum == 33:
            self.fd = True if can_rx else False
            if self.fd:
                self.dlc_start = 37
                self.putx([7, ['Flexible data format: %d' % can_rx,
                               'FDF: %d' % can_rx, 'FDF']])
                self.put32([7, ['Reserved bit 1: %d' % self.rtr,
                                'RB1: %d' % self.rtr, 'RB1']])
            else:
                self.putx([7, ['Reserved bit 1: %d' % can_rx,
                               'RB1: %d' % can_rx, 'RB1']])

        # Bit 34: RB0 (reserved bit)
        elif bitnum == 34:
            self.putx([7, ['Reserved bit 0: %d' % can_rx,
                           'RB0: %d' % can_rx, 'RB0']])

        elif bitnum == 35 and self.fd:
            self.putx([7, ['Bit rate switch: %d' % can_rx,
                           'BRS: %d' % can_rx, 'BRS']])

        elif bitnum == 36 and self.fd:
            self.putx([7, ['Error state indicator: %d' % can_rx,
                           'ESI: %d' % can_rx, 'ESI']])

        # Remember start of DLC (see below).
        elif bitnum == self.dlc_start:
            self.ss_block = self.samplenum

        # Bits 35-38: Data length code (DLC), in number of bytes (0-8).
        elif bitnum == self.dlc_start + 3:
            self.dlc = int(''.join(str(d) for d in self.bits[self.dlc_start:self.dlc_start + 4]), 2)
            self.putb([10, ['Data length code: %d' % self.dlc,
                            'DLC: %d' % self.dlc, 'DLC']])
            self.last_databit = self.dlc_start + 3 + (dlc2len(self.dlc) * 8)

        # Remember all databyte bits, except the very last one.
        elif bitnum in range(self.dlc_start + 4, self.last_databit):
            self.ss_databytebits.append(self.samplenum)

        # Bits 39-X: Data field (0-8 bytes, depending on DLC)
        # The bits within a data byte are transferred MSB-first.
        elif bitnum == self.last_databit:
            self.ss_databytebits.append(self.samplenum) # Last databyte bit.
            for i in range(dlc2len(self.dlc)):
                x = self.dlc_start + 4 + (8 * i)
                b = int(''.join(str(d) for d in self.bits[x:x + 8]), 2)
                ss = self.ss_databytebits[i * 8]
                es = self.ss_databytebits[((i + 1) * 8) - 1]
                self.putg(ss, es, [0, ['Data byte %d: 0x%02x' % (i, b),
                                       'DB %d: 0x%02x' % (i, b), 'DB']])
            self.ss_databytebits = []

        elif bitnum > self.last_databit:
            return self.decode_frame_end(can_rx, bitnum)

        return False

    def handle_bit(self, can_rx):
        self.rawbits.append(can_rx)
        self.bits.append(can_rx)

        # Get the index of the current CAN frame bit (without stuff bits).
        bitnum = len(self.bits) - 1

        if self.fd and can_rx:
            if bitnum == 16 and self.frame_type == 'standard' \
                    or bitnum == 35 and self.frame_type == 'extended':
                self.dom_edge_seen(force=True)
                self.set_fast_bitrate()

        # If this is a stuff bit, remove it from self.bits and ignore it.
        if self.is_stuff_bit():
            self.putx([15, [str(can_rx)]])
            self.curbit += 1 # Increase self.curbit (bitnum is not affected).
            return
        else:
            self.putx([17, [str(can_rx)]])

        # Bit 0: Start of frame (SOF) bit
        if bitnum == 0:
            self.putx([1, ['Start of frame', 'SOF', 'S']])
            if can_rx != 0:
                self.putx([16, ['Start of frame (SOF) must be a dominant bit']])

        # Remember start of ID (see below).
        elif bitnum == 1:
            self.ss_block = self.samplenum

        # Bits 1-11: Identifier (ID[10..0])
        # The bits ID[10..4] must NOT be all recessive.
        elif bitnum == 11:
            self.id = int(''.join(str(d) for d in self.bits[1:]), 2)
            s = '%d (0x%x)' % (self.id, self.id),
            self.putb([3, ['Identifier: %s' % s, 'ID: %s' % s, 'ID']])
            if (self.id & 0x7f0) == 0x7f0:
                self.putb([16, ['Identifier bits 10..4 must not be all recessive']])

        # RTR or SRR bit, depending on frame type (gets handled later).
        elif bitnum == 12:
            # self.putx([0, ['RTR/SRR: %d' % can_rx]]) # Debug only.
            self.ss_bit12 = self.samplenum

        # Bit 13: Identifier extension (IDE) bit
        # Standard frame: dominant, extended frame: recessive
        elif bitnum == 13:
            ide = self.frame_type = 'standard' if can_rx == 0 else 'extended'
            self.putx([6, ['Identifier extension bit: %s frame' % ide,
                           'IDE: %s frame' % ide, 'IDE']])

        # Bits 14-X: Frame-type dependent, passed to the resp. handlers.
        elif bitnum >= 14:
            if self.frame_type == 'standard':
                done = self.decode_standard_frame(can_rx, bitnum)
            else:
                done = self.decode_extended_frame(can_rx, bitnum)

            # The handlers return True if a frame ended (EOF).
            if done:
                return

        # After a frame there are 3 intermission bits (recessive).
        # After these bits, the bus is considered free.

        self.curbit += 1

    def decode(self):
        if not self.samplerate:
            raise SamplerateError('Cannot decode without samplerate.')

        while True:
            # State machine.
            if self.state == 'IDLE':
                # Wait for a dominant state (logic 0) on the bus.
                (can_rx,) = self.wait({0: 'l'})
                self.sof = self.samplenum
                self.dom_edge_seen(force = True)
                self.state = 'GET BITS'
            elif self.state == 'GET BITS':
                # Wait until we're in the correct bit/sampling position.
                pos = self.get_sample_point(self.curbit)
                (can_rx,) = self.wait([{'skip': pos - self.samplenum}, {0: 'f'}])
                if self.matched[1]:
                    self.dom_edge_seen()
                if self.matched[0]:
                    self.handle_bit(can_rx)
Commit	Line	Data
	1	##
	2	## This file is part of the libsigrokdecode project.
	3	##
	4	## Copyright (C) 2012-2013 Uwe Hermann <uwe@hermann-uwe.de>
	5	## Copyright (C) 2019 Stephan Thiele <stephan.thiele@mailbox.org>
	6	##
	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.
	11	##
	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.
	16	##
	17	## You should have received a copy of the GNU General Public License
	18	## along with this program; if not, see <http://www.gnu.org/licenses/>.
	19	##
	20
	21	import sigrokdecode as srd
	22
	23	class SamplerateError(Exception):
	24	pass
	25
	26	def dlc2len(dlc):
	27	return [0, 1, 2, 3, 4, 5, 6, 7, 8, 12, 16, 20, 24, 32, 48, 64][dlc]
	28
	29	class Decoder(srd.Decoder):
	30	api_version = 3
	31	id = 'can'
	32	name = 'CAN'
	33	longname = 'Controller Area Network'
	34	desc = 'Field bus protocol for distributed realtime control.'
	35	license = 'gplv2+'
	36	inputs = ['logic']
	37	outputs = []
	38	tags = ['Automotive']
	39	channels = (
	40	{'id': 'can_rx', 'name': 'CAN RX', 'desc': 'CAN bus line'},
	41	)
	42	options = (
	43	{'id': 'nominal_bitrate', 'desc': 'Nominal bitrate (bits/s)', 'default': 1000000},
	44	{'id': 'fast_bitrate', 'desc': 'Fast bitrate (bits/s)', 'default': 2000000},
	45	{'id': 'sample_point', 'desc': 'Sample point (%)', 'default': 70.0},
	46	)
	47	annotations = (
	48	('data', 'CAN payload data'),
	49	('sof', 'Start of frame'),
	50	('eof', 'End of frame'),
	51	('id', 'Identifier'),
	52	('ext-id', 'Extended identifier'),
	53	('full-id', 'Full identifier'),
	54	('ide', 'Identifier extension bit'),
	55	('reserved-bit', 'Reserved bit 0 and 1'),
	56	('rtr', 'Remote transmission request'),
	57	('srr', 'Substitute remote request'),
	58	('dlc', 'Data length count'),
	59	('crc-sequence', 'CRC sequence'),
	60	('crc-delimiter', 'CRC delimiter'),
	61	('ack-slot', 'ACK slot'),
	62	('ack-delimiter', 'ACK delimiter'),
	63	('stuff-bit', 'Stuff bit'),
	64	('warnings', 'Human-readable warnings'),
	65	('bit', 'Bit'),
	66	)
	67	annotation_rows = (
	68	('bits', 'Bits', (15, 17)),
	69	('fields', 'Fields', tuple(range(15))),
	70	('warnings', 'Warnings', (16,)),
	71	)
	72
	73	def __init__(self):
	74	self.reset()
	75
	76	def reset(self):
	77	self.samplerate = None
	78	self.reset_variables()
	79
	80	def start(self):
	81	self.out_ann = self.register(srd.OUTPUT_ANN)
	82
	83	def set_bit_rate(self, bitrate):
	84	self.bit_width = float(self.samplerate) / float(bitrate)
	85	self.sample_point = (self.bit_width / 100.0) * self.options['sample_point']
	86
	87	def set_nominal_bitrate(self):
	88	self.set_bit_rate(self.options['nominal_bitrate'])
	89
	90	def set_fast_bitrate(self):
	91	self.set_bit_rate(self.options['fast_bitrate'])
	92
	93	def metadata(self, key, value):
	94	if key == srd.SRD_CONF_SAMPLERATE:
	95	self.samplerate = value
	96	self.bit_width = float(self.samplerate) / float(self.options['nominal_bitrate'])
	97	self.sample_point = (self.bit_width / 100.0) * self.options['sample_point']
	98
	99	# Generic helper for CAN bit annotations.
	100	def putg(self, ss, es, data):
	101	left, right = int(self.sample_point), int(self.bit_width - self.sample_point)
	102	self.put(ss - left, es + right, self.out_ann, data)
	103
	104	# Single-CAN-bit annotation using the current samplenum.
	105	def putx(self, data):
	106	self.putg(self.samplenum, self.samplenum, data)
	107
	108	# Single-CAN-bit annotation using the samplenum of CAN bit 12.
	109	def put12(self, data):
	110	self.putg(self.ss_bit12, self.ss_bit12, data)
	111
	112	# Single-CAN-bit annotation using the samplenum of CAN bit 32.
	113	def put32(self, data):
	114	self.putg(self.ss_bit32, self.ss_bit32, data)
	115
	116	# Multi-CAN-bit annotation from self.ss_block to current samplenum.
	117	def putb(self, data):
	118	self.putg(self.ss_block, self.samplenum, data)
	119
	120	def reset_variables(self):
	121	self.state = 'IDLE'
	122	self.sof = self.frame_type = self.dlc = None
	123	self.rawbits = [] # All bits, including stuff bits
	124	self.bits = [] # Only actual CAN frame bits (no stuff bits)
	125	self.curbit = 0 # Current bit of CAN frame (bit 0 == SOF)
	126	self.last_databit = 999 # Positive value that bitnum+x will never match
	127	self.ss_block = None
	128	self.ss_bit12 = None
	129	self.ss_bit32 = None
	130	self.ss_databytebits = []
	131	self.fd = False
	132	self.rtr = None
	133
	134	# Poor man's clock synchronization. Use signal edges which change to
	135	# dominant state in rather simple ways. This naive approach is neither
	136	# aware of the SYNC phase's width nor the specific location of the edge,
	137	# but improves the decoder's reliability when the input signal's bitrate
	138	# does not exactly match the nominal rate.
	139	def dom_edge_seen(self, force = False):
	140	self.dom_edge_snum = self.samplenum
	141	self.dom_edge_bcount = self.curbit
	142
	143	# Determine the position of the next desired bit's sample point.
	144	def get_sample_point(self, bitnum):
	145	samplenum = self.dom_edge_snum
	146	samplenum += self.bit_width * (bitnum - self.dom_edge_bcount)
	147	samplenum += self.sample_point
	148	return int(samplenum)
	149
	150	def is_stuff_bit(self):
	151	# CAN uses NRZ encoding and bit stuffing.
	152	# After 5 identical bits, a stuff bit of opposite value is added.
	153	# But not in the CRC delimiter, ACK, and end of frame fields.
	154	if len(self.bits) > self.last_databit + 17:
	155	return False
	156	last_6_bits = self.rawbits[-6:]
	157	if last_6_bits not in ([0, 0, 0, 0, 0, 1], [1, 1, 1, 1, 1, 0]):
	158	return False
	159
	160	# Stuff bit. Keep it in self.rawbits, but drop it from self.bits.
	161	self.bits.pop() # Drop last bit.
	162	return True
	163
	164	def is_valid_crc(self, crc_bits):
	165	return True # TODO
	166
	167	def decode_error_frame(self, bits):
	168	pass # TODO
	169
	170	def decode_overload_frame(self, bits):
	171	pass # TODO
	172
	173	# Both standard and extended frames end with CRC, CRC delimiter, ACK,
	174	# ACK delimiter, and EOF fields. Handle them in a common function.
	175	# Returns True if the frame ended (EOF), False otherwise.
	176	def decode_frame_end(self, can_rx, bitnum):
	177
	178	# Remember start of CRC sequence (see below).
	179	if bitnum == (self.last_databit + 1):
	180	self.ss_block = self.samplenum
	181	if self.fd:
	182	if dlc2len(self.dlc) < 16:
	183	self.crc_len = 27 # 17 + SBC + stuff bits
	184	else:
	185	self.crc_len = 32 # 21 + SBC + stuff bits
	186	else:
	187	self.crc_len = 15
	188
	189	# CRC sequence (15 bits, 17 bits or 21 bits)
	190	elif bitnum == (self.last_databit + self.crc_len):
	191	if self.fd:
	192	if dlc2len(self.dlc) < 16:
	193	crc_type = "CRC-17"
	194	else:
	195	crc_type = "CRC-21"
	196	else:
	197	crc_type = "CRC-15"
	198
	199	x = self.last_databit + 1
	200	crc_bits = self.bits[x:x + self.crc_len + 1]
	201	self.crc = int(''.join(str(d) for d in crc_bits), 2)
	202	self.putb([11, ['%s sequence: 0x%04x' % (crc_type, self.crc),
	203	'%s: 0x%04x' % (crc_type, self.crc), '%s' % crc_type]])
	204	if not self.is_valid_crc(crc_bits):
	205	self.putb([16, ['CRC is invalid']])
	206
	207	# CRC delimiter bit (recessive)
	208	elif bitnum == (self.last_databit + self.crc_len + 1):
	209	self.putx([12, ['CRC delimiter: %d' % can_rx,
	210	'CRC d: %d' % can_rx, 'CRC d']])
	211	if can_rx != 1:
	212	self.putx([16, ['CRC delimiter must be a recessive bit']])
	213
	214	if self.fd:
	215	self.set_nominal_bitrate()
	216
	217	# ACK slot bit (dominant: ACK, recessive: NACK)
	218	elif bitnum == (self.last_databit + self.crc_len + 2):
	219	ack = 'ACK' if can_rx == 0 else 'NACK'
	220	self.putx([13, ['ACK slot: %s' % ack, 'ACK s: %s' % ack, 'ACK s']])
	221
	222	# ACK delimiter bit (recessive)
	223	elif bitnum == (self.last_databit + self.crc_len + 3):
	224	self.putx([14, ['ACK delimiter: %d' % can_rx,
	225	'ACK d: %d' % can_rx, 'ACK d']])
	226	if can_rx != 1:
	227	self.putx([16, ['ACK delimiter must be a recessive bit']])
	228
	229	# Remember start of EOF (see below).
	230	elif bitnum == (self.last_databit + self.crc_len + 4):
	231	self.ss_block = self.samplenum
	232
	233	# End of frame (EOF), 7 recessive bits
	234	elif bitnum == (self.last_databit + self.crc_len + 10):
	235	self.putb([2, ['End of frame', 'EOF', 'E']])
	236	if self.rawbits[-7:] != [1, 1, 1, 1, 1, 1, 1]:
	237	self.putb([16, ['End of frame (EOF) must be 7 recessive bits']])
	238	self.reset_variables()
	239	return True
	240
	241	return False
	242
	243	# Returns True if the frame ended (EOF), False otherwise.
	244	def decode_standard_frame(self, can_rx, bitnum):
	245
	246	# Bit 14: FDF (Flexible data format)
	247	# Has to be sent dominant when FD frame, has to be sent recessive
	248	# when classic CAN frame.
	249	if bitnum == 14:
	250	self.fd = True if can_rx else False
	251	if self.fd:
	252	self.putx([7, ['Flexible data format: %d' % can_rx,
	253	'FDF: %d' % can_rx, 'FDF']])
	254	else:
	255	self.putx([7, ['Reserved bit 0: %d' % can_rx,
	256	'RB0: %d' % can_rx, 'RB0']])
	257
	258	if self.fd:
	259	# Bit 12: Substitute remote request (SRR) bit
	260	self.put12([8, ['Substitute remote request', 'SRR']])
	261	self.dlc_start = 18
	262	else:
	263	# Bit 12: Remote transmission request (RTR) bit
	264	# Data frame: dominant, remote frame: recessive
	265	# Remote frames do not contain a data field.
	266	rtr = 'remote' if self.bits[12] == 1 else 'data'
	267	self.put12([8, ['Remote transmission request: %s frame' % rtr,
	268	'RTR: %s frame' % rtr, 'RTR']])
	269	self.dlc_start = 15
	270
	271	if bitnum == 15 and self.fd:
	272	self.putx([7, ['Reserved: %d' % can_rx, 'R0: %d' % can_rx, 'R0']])
	273
	274	if bitnum == 16 and self.fd:
	275	self.putx([7, ['Bit rate switch: %d' % can_rx, 'BRS: %d' % can_rx, 'BRS']])
	276
	277	if bitnum == 17 and self.fd:
	278	self.putx([7, ['Error state indicator: %d' % can_rx, 'ESI: %d' % can_rx, 'ESI']])
	279
	280	# Remember start of DLC (see below).
	281	elif bitnum == self.dlc_start:
	282	self.ss_block = self.samplenum
	283
	284	# Bits 15-18: Data length code (DLC), in number of bytes (0-8).
	285	elif bitnum == self.dlc_start + 3:
	286	self.dlc = int(''.join(str(d) for d in self.bits[self.dlc_start:self.dlc_start + 4]), 2)
	287	self.putb([10, ['Data length code: %d' % self.dlc,
	288	'DLC: %d' % self.dlc, 'DLC']])
	289	self.last_databit = self.dlc_start + 3 + (dlc2len(self.dlc) * 8)
	290	if self.dlc > 8 and not self.fd:
	291	self.putb([16, ['Data length code (DLC) > 8 is not allowed']])
	292
	293	# Remember all databyte bits, except the very last one.
	294	elif bitnum in range(self.dlc_start + 4, self.last_databit):
	295	self.ss_databytebits.append(self.samplenum)
	296
	297	# Bits 19-X: Data field (0-8 bytes, depending on DLC)
	298	# The bits within a data byte are transferred MSB-first.
	299	elif bitnum == self.last_databit:
	300	self.ss_databytebits.append(self.samplenum) # Last databyte bit.
	301	for i in range(dlc2len(self.dlc)):
	302	x = self.dlc_start + 4 + (8 * i)
	303	b = int(''.join(str(d) for d in self.bits[x:x + 8]), 2)
	304	ss = self.ss_databytebits[i * 8]
	305	es = self.ss_databytebits[((i + 1) * 8) - 1]
	306	self.putg(ss, es, [0, ['Data byte %d: 0x%02x' % (i, b),
	307	'DB %d: 0x%02x' % (i, b), 'DB']])
	308	self.ss_databytebits = []
	309
	310	elif bitnum > self.last_databit:
	311	return self.decode_frame_end(can_rx, bitnum)
	312
	313	return False
	314
	315	# Returns True if the frame ended (EOF), False otherwise.
	316	def decode_extended_frame(self, can_rx, bitnum):
	317
	318	# Remember start of EID (see below).
	319	if bitnum == 14:
	320	self.ss_block = self.samplenum
	321	self.fd = False
	322	self.dlc_start = 35
	323
	324	# Bits 14-31: Extended identifier (EID[17..0])
	325	elif bitnum == 31:
	326	self.eid = int(''.join(str(d) for d in self.bits[14:]), 2)
	327	s = '%d (0x%x)' % (self.eid, self.eid)
	328	self.putb([4, ['Extended Identifier: %s' % s,
	329	'Extended ID: %s' % s, 'Extended ID', 'EID']])
	330
	331	self.fullid = self.id << 18 \| self.eid
	332	s = '%d (0x%x)' % (self.fullid, self.fullid)
	333	self.putb([5, ['Full Identifier: %s' % s, 'Full ID: %s' % s,
	334	'Full ID', 'FID']])
	335
	336	# Bit 12: Substitute remote request (SRR) bit
	337	self.put12([9, ['Substitute remote request: %d' % self.bits[12],
	338	'SRR: %d' % self.bits[12], 'SRR']])
	339
	340	# Bit 32: Remote transmission request (RTR) bit
	341	# Data frame: dominant, remote frame: recessive
	342	# Remote frames do not contain a data field.
	343
	344	# Remember start of RTR (see below).
	345	if bitnum == 32:
	346	self.ss_bit32 = self.samplenum
	347	self.rtr = can_rx
	348
	349	if not self.fd:
	350	rtr = 'remote' if can_rx == 1 else 'data'
	351	self.putx([8, ['Remote transmission request: %s frame' % rtr,
	352	'RTR: %s frame' % rtr, 'RTR']])
	353
	354	# Bit 33: RB1 (reserved bit)
	355	elif bitnum == 33:
	356	self.fd = True if can_rx else False
	357	if self.fd:
	358	self.dlc_start = 37
	359	self.putx([7, ['Flexible data format: %d' % can_rx,
	360	'FDF: %d' % can_rx, 'FDF']])
	361	self.put32([7, ['Reserved bit 1: %d' % self.rtr,
	362	'RB1: %d' % self.rtr, 'RB1']])
	363	else:
	364	self.putx([7, ['Reserved bit 1: %d' % can_rx,
	365	'RB1: %d' % can_rx, 'RB1']])
	366
	367	# Bit 34: RB0 (reserved bit)
	368	elif bitnum == 34:
	369	self.putx([7, ['Reserved bit 0: %d' % can_rx,
	370	'RB0: %d' % can_rx, 'RB0']])
	371
	372	elif bitnum == 35 and self.fd:
	373	self.putx([7, ['Bit rate switch: %d' % can_rx,
	374	'BRS: %d' % can_rx, 'BRS']])
	375
	376	elif bitnum == 36 and self.fd:
	377	self.putx([7, ['Error state indicator: %d' % can_rx,
	378	'ESI: %d' % can_rx, 'ESI']])
	379
	380	# Remember start of DLC (see below).
	381	elif bitnum == self.dlc_start:
	382	self.ss_block = self.samplenum
	383
	384	# Bits 35-38: Data length code (DLC), in number of bytes (0-8).
	385	elif bitnum == self.dlc_start + 3:
	386	self.dlc = int(''.join(str(d) for d in self.bits[self.dlc_start:self.dlc_start + 4]), 2)
	387	self.putb([10, ['Data length code: %d' % self.dlc,
	388	'DLC: %d' % self.dlc, 'DLC']])
	389	self.last_databit = self.dlc_start + 3 + (dlc2len(self.dlc) * 8)
	390
	391	# Remember all databyte bits, except the very last one.
	392	elif bitnum in range(self.dlc_start + 4, self.last_databit):
	393	self.ss_databytebits.append(self.samplenum)
	394
	395	# Bits 39-X: Data field (0-8 bytes, depending on DLC)
	396	# The bits within a data byte are transferred MSB-first.
	397	elif bitnum == self.last_databit:
	398	self.ss_databytebits.append(self.samplenum) # Last databyte bit.
	399	for i in range(dlc2len(self.dlc)):
	400	x = self.dlc_start + 4 + (8 * i)
	401	b = int(''.join(str(d) for d in self.bits[x:x + 8]), 2)
	402	ss = self.ss_databytebits[i * 8]
	403	es = self.ss_databytebits[((i + 1) * 8) - 1]
	404	self.putg(ss, es, [0, ['Data byte %d: 0x%02x' % (i, b),
	405	'DB %d: 0x%02x' % (i, b), 'DB']])
	406	self.ss_databytebits = []
	407
	408	elif bitnum > self.last_databit:
	409	return self.decode_frame_end(can_rx, bitnum)
	410
	411	return False
	412
	413	def handle_bit(self, can_rx):
	414	self.rawbits.append(can_rx)
	415	self.bits.append(can_rx)
	416
	417	# Get the index of the current CAN frame bit (without stuff bits).
	418	bitnum = len(self.bits) - 1
	419
	420	if self.fd and can_rx:
	421	if bitnum == 16 and self.frame_type == 'standard' \
	422	or bitnum == 35 and self.frame_type == 'extended':
	423	self.dom_edge_seen(force=True)
	424	self.set_fast_bitrate()
	425
	426	# If this is a stuff bit, remove it from self.bits and ignore it.
	427	if self.is_stuff_bit():
	428	self.putx([15, [str(can_rx)]])
	429	self.curbit += 1 # Increase self.curbit (bitnum is not affected).
	430	return
	431	else:
	432	self.putx([17, [str(can_rx)]])
	433
	434	# Bit 0: Start of frame (SOF) bit
	435	if bitnum == 0:
	436	self.putx([1, ['Start of frame', 'SOF', 'S']])
	437	if can_rx != 0:
	438	self.putx([16, ['Start of frame (SOF) must be a dominant bit']])
	439
	440	# Remember start of ID (see below).
	441	elif bitnum == 1:
	442	self.ss_block = self.samplenum
	443
	444	# Bits 1-11: Identifier (ID[10..0])
	445	# The bits ID[10..4] must NOT be all recessive.
	446	elif bitnum == 11:
	447	self.id = int(''.join(str(d) for d in self.bits[1:]), 2)
	448	s = '%d (0x%x)' % (self.id, self.id),
	449	self.putb([3, ['Identifier: %s' % s, 'ID: %s' % s, 'ID']])
	450	if (self.id & 0x7f0) == 0x7f0:
	451	self.putb([16, ['Identifier bits 10..4 must not be all recessive']])
	452
	453	# RTR or SRR bit, depending on frame type (gets handled later).
	454	elif bitnum == 12:
	455	# self.putx([0, ['RTR/SRR: %d' % can_rx]]) # Debug only.
	456	self.ss_bit12 = self.samplenum
	457
	458	# Bit 13: Identifier extension (IDE) bit
	459	# Standard frame: dominant, extended frame: recessive
	460	elif bitnum == 13:
	461	ide = self.frame_type = 'standard' if can_rx == 0 else 'extended'
	462	self.putx([6, ['Identifier extension bit: %s frame' % ide,
	463	'IDE: %s frame' % ide, 'IDE']])
	464
	465	# Bits 14-X: Frame-type dependent, passed to the resp. handlers.
	466	elif bitnum >= 14:
	467	if self.frame_type == 'standard':
	468	done = self.decode_standard_frame(can_rx, bitnum)
	469	else:
	470	done = self.decode_extended_frame(can_rx, bitnum)
	471
	472	# The handlers return True if a frame ended (EOF).
	473	if done:
	474	return
	475
	476	# After a frame there are 3 intermission bits (recessive).
	477	# After these bits, the bus is considered free.
	478
	479	self.curbit += 1
	480
	481	def decode(self):
	482	if not self.samplerate:
	483	raise SamplerateError('Cannot decode without samplerate.')
	484
	485	while True:
	486	# State machine.
	487	if self.state == 'IDLE':
	488	# Wait for a dominant state (logic 0) on the bus.
	489	(can_rx,) = self.wait({0: 'l'})
	490	self.sof = self.samplenum
	491	self.dom_edge_seen(force = True)
	492	self.state = 'GET BITS'
	493	elif self.state == 'GET BITS':
	494	# Wait until we're in the correct bit/sampling position.
	495	pos = self.get_sample_point(self.curbit)
	496	(can_rx,) = self.wait([{'skip': pos - self.samplenum}, {0: 'f'}])
	497	if self.matched[1]:
	498	self.dom_edge_seen()
	499	if self.matched[0]:
	500	self.handle_bit(can_rx)