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

##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2012-2013 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
##

# CAN protocol decoder

import sigrokdecode as srd

class Decoder(srd.Decoder):
    api_version = 1
    id = 'can'
    name = 'CAN'
    longname = 'Controller Area Network'
    desc = 'Field bus protocol for distributed realtime control.'
    license = 'gplv2+'
    inputs = ['logic']
    outputs = ['can']
    probes = [
        {'id': 'can_rx', 'name': 'CAN RX', 'desc': 'CAN bus line'},
    ]
    optional_probes = []
    options = {
        'bitrate': ['Bitrate', 1000000], # 1Mbit/s
        'sample_point': ['Sample point', 70], # 70%
    }
    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'],
    ]

    def __init__(self, **kwargs):
        self.samplerate = None
        self.reset_variables()

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

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

    def report(self):
        pass

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

    # 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_databytebits = []

    # Return True if we reached the desired bit position, False otherwise.
    def reached_bit(self, bitnum):
        bitpos = int(self.sof + (self.bit_width * bitnum) + self.bitpos)
        if self.samplenum >= bitpos:
            return True
        return False

    def is_stuff_bit(self):
        # CAN uses NRZ encoding and bit stuffing.
        # After 5 identical bits, a stuff bit of opposite value is added.
        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.putx([15, ['Stuff bit: %d' % self.rawbits[-1],
                        'SB: %d' % self.rawbits[-1], 'SB']])
        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

        # CRC sequence (15 bits)
        elif bitnum == (self.last_databit + 15):
            x = self.last_databit + 1
            crc_bits = self.bits[x:x + 15 + 1]
            self.crc = int(''.join(str(d) for d in crc_bits), 2)
            self.putb([11, ['CRC sequence: 0x%04x' % self.crc,
                            'CRC: 0x%04x' % self.crc, 'CRC']])
            if not self.is_valid_crc(crc_bits):
                self.putb([16, ['CRC is invalid']])

        # CRC delimiter bit (recessive)
        elif bitnum == (self.last_databit + 16):
            self.putx([12, ['CRC delimiter: %d' % can_rx,
                            'CRC d: %d' % can_rx, 'CRC d']])

        # ACK slot bit (dominant: ACK, recessive: NACK)
        elif bitnum == (self.last_databit + 17):
            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 + 18):
            self.putx([14, ['ACK delimiter: %d' % can_rx,
                            'ACK d: %d' % can_rx, 'ACK d']])

        # Remember start of EOF (see below).
        elif bitnum == (self.last_databit + 19):
            self.ss_block = self.samplenum

        # End of frame (EOF), 7 recessive bits
        elif bitnum == (self.last_databit + 25):
            self.putb([2, ['End of frame', 'EOF', 'E']])
            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: RB0 (reserved bit)
        # Has to be sent dominant, but receivers should accept recessive too.
        if bitnum == 14:
            self.putx([7, ['Reserved bit 0: %d' % can_rx,
                           'RB0: %d' % can_rx, 'RB0']])

            # 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']])

        # Remember start of DLC (see below).
        elif bitnum == 15:
            self.ss_block = self.samplenum

        # Bits 15-18: Data length code (DLC), in number of bytes (0-8).
        elif bitnum == 18:
            self.dlc = int(''.join(str(d) for d in self.bits[15:18 + 1]), 2)
            self.putb([10, ['Data length code: %d' % self.dlc,
                            'DLC: %d' % self.dlc, 'DLC']])
            self.last_databit = 18 + (self.dlc * 8)

        # Remember all databyte bits, except the very last one.
        elif bitnum in range(19, 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(self.dlc):
                x = 18 + (8 * i) + 1
                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

        # 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.
        if bitnum == 32:
            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.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']])

        # Remember start of DLC (see below).
        elif bitnum == 35:
            self.ss_block = self.samplenum

        # Bits 35-38: Data length code (DLC), in number of bytes (0-8).
        elif bitnum == 38:
            self.dlc = int(''.join(str(d) for d in self.bits[35:38 + 1]), 2)
            self.putb([10, ['Data length code: %d' % self.dlc,
                            'DLC: %d' % self.dlc, 'DLC']])
            self.last_databit = 38 + (self.dlc * 8)

        # Remember all databyte bits, except the very last one.
        elif bitnum in range(39, 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(self.dlc):
                x = 38 + (8 * i) + 1
                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

        # For debugging.
        # self.putx([0, ['Bit %d (CAN bit %d): %d' % \
        #           (self.curbit, bitnum, can_rx)]])

        # If this is a stuff bit, remove it from self.bits and ignore it.
        if self.is_stuff_bit():
            self.curbit += 1 # Increase self.curbit (bitnum is not affected).
            return

        # Bit 0: Start of frame (SOF) bit
        if bitnum == 0:
            if can_rx == 0:
                self.putx([1, ['Start of frame', 'SOF', 'S']])
            else:
                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']])

        # 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, ss, es, data):
        if self.samplerate is None:
            raise Exception("Cannot decode without samplerate.")
        for (self.samplenum, pins) in data:

            (can_rx,) = pins

            # State machine.
            if self.state == 'IDLE':
                # Wait for a dominant state (logic 0) on the bus.
                if can_rx == 1:
                    continue
                self.sof = self.samplenum
                self.state = 'GET BITS'
            elif self.state == 'GET BITS':
                # Wait until we're in the correct bit/sampling position.
                if not self.reached_bit(self.curbit):
                    continue
                self.handle_bit(can_rx)
            else:
                raise Exception("Invalid state: %s" % self.state)
Commit	Line	Data
702fa251	1	##
50bd5d25	2	## This file is part of the libsigrokdecode project.
702fa251	3	##
e20f455c	4	## Copyright (C) 2012-2013 Uwe Hermann <uwe@hermann-uwe.de>
702fa251 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	# CAN protocol decoder
	22
	23	import sigrokdecode as srd
	24
	25	class Decoder(srd.Decoder):
	26	api_version = 1
	27	id = 'can'
	28	name = 'CAN'
9e1437a0	29	longname = 'Controller Area Network'
702fa251 UH	30	desc = 'Field bus protocol for distributed realtime control.'
	31	license = 'gplv2+'
	32	inputs = ['logic']
	33	outputs = ['can']
	34	probes = [
	35	{'id': 'can_rx', 'name': 'CAN RX', 'desc': 'CAN bus line'},
	36	]
	37	optional_probes = []
	38	options = {
	39	'bitrate': ['Bitrate', 1000000], # 1Mbit/s
	40	'sample_point': ['Sample point', 70], # 70%
	41	}
	42	annotations = [
74c9bb3c UH	43	['Data', 'CAN payload data'],
	44	['SOF', 'Start of frame'],
	45	['EOF', 'End of frame'],
	46	['ID', 'Identifier'],
	47	['Ext. ID', 'Extended identifier'],
	48	['Full ID', 'Full identifier'],
	49	['IDE', 'Identifier extension bit'],
	50	['Reserved bit', 'Reserved bit 0 and 1'],
	51	['RTR', 'Remote transmission request'],
	52	['SRR', 'Substitute remote request'],
	53	['DLC', 'Data length count'],
	54	['CRC sequence', 'CRC sequence'],
	55	['CRC delimiter', 'CRC delimiter'],
	56	['ACK slot', 'ACK slot'],
	57	['ACK delimiter', 'ACK delimiter'],
	58	['Stuff bit', 'Stuff bit'],
702fa251 UH	59	['Warnings', 'Human-readable warnings'],
	60	]
	61
	62	def __init__(self, **kwargs):
f372d597	63	self.samplerate = None
702fa251 UH	64	self.reset_variables()
702fa251 UH	65
f372d597	66	def start(self):
be465111 BV	67	# self.out_proto = self.register(srd.OUTPUT_PYTHON)
be465111 BV	68	self.out_ann = self.register(srd.OUTPUT_ANN)
702fa251	69
f372d597 BV	70	def metadata(self, key, value):
	71	if key == srd.SRD_CONF_SAMPLERATE:
	72	self.samplerate = value
	73	self.bit_width = float(self.samplerate) / float(self.options['bitrate'])
	74	self.bitpos = (self.bit_width / 100.0) * self.options['sample_point']
702fa251 UH	75
	76	def report(self):
	77	pass
	78
4b1813b4 UH	79	# Generic helper for CAN bit annotations.
	80	def putg(self, ss, es, data):
	81	left, right = int(self.bitpos), int(self.bit_width - self.bitpos)
	82	self.put(ss - left, es + right, self.out_ann, data)
	83
	84	# Single-CAN-bit annotation using the current samplenum.
e20f455c	85	def putx(self, data):
4b1813b4 UH	86	self.putg(self.samplenum, self.samplenum, data)
	87
	88	# Single-CAN-bit annotation using the samplenum of CAN bit 12.
	89	def put12(self, data):
	90	self.putg(self.ss_bit12, self.ss_bit12, data)
	91
	92	# Multi-CAN-bit annotation from self.ss_block to current samplenum.
	93	def putb(self, data):
	94	self.putg(self.ss_block, self.samplenum, data)
e20f455c	95
702fa251 UH	96	def reset_variables(self):
	97	self.state = 'IDLE'
	98	self.sof = self.frame_type = self.dlc = None
	99	self.rawbits = [] # All bits, including stuff bits
	100	self.bits = [] # Only actual CAN frame bits (no stuff bits)
	101	self.curbit = 0 # Current bit of CAN frame (bit 0 == SOF)
	102	self.last_databit = 999 # Positive value that bitnum+x will never match
4b1813b4 UH	103	self.ss_block = None
	104	self.ss_bit12 = None
	105	self.ss_databytebits = []
702fa251 UH	106
	107	# Return True if we reached the desired bit position, False otherwise.
	108	def reached_bit(self, bitnum):
	109	bitpos = int(self.sof + (self.bit_width * bitnum) + self.bitpos)
	110	if self.samplenum >= bitpos:
	111	return True
	112	return False
	113
	114	def is_stuff_bit(self):
	115	# CAN uses NRZ encoding and bit stuffing.
	116	# After 5 identical bits, a stuff bit of opposite value is added.
	117	last_6_bits = self.rawbits[-6:]
	118	if last_6_bits not in ([0, 0, 0, 0, 0, 1], [1, 1, 1, 1, 1, 0]):
	119	return False
	120
	121	# Stuff bit. Keep it in self.rawbits, but drop it from self.bits.
74c9bb3c UH	122	self.putx([15, ['Stuff bit: %d' % self.rawbits[-1],
74c9bb3c UH	123	'SB: %d' % self.rawbits[-1], 'SB']])
702fa251 UH	124	self.bits.pop() # Drop last bit.
	125	return True
	126
	127	def is_valid_crc(self, crc_bits):
	128	return True # TODO
	129
	130	def decode_error_frame(self, bits):
	131	pass # TODO
	132
	133	def decode_overload_frame(self, bits):
	134	pass # TODO
	135
	136	# Both standard and extended frames end with CRC, CRC delimiter, ACK,
	137	# ACK delimiter, and EOF fields. Handle them in a common function.
	138	# Returns True if the frame ended (EOF), False otherwise.
	139	def decode_frame_end(self, can_rx, bitnum):
	140
4b1813b4 UH	141	# Remember start of CRC sequence (see below).
	142	if bitnum == (self.last_databit + 1):
	143	self.ss_block = self.samplenum
	144
702fa251	145	# CRC sequence (15 bits)
4b1813b4	146	elif bitnum == (self.last_databit + 15):
702fa251 UH	147	x = self.last_databit + 1
	148	crc_bits = self.bits[x:x + 15 + 1]
	149	self.crc = int(''.join(str(d) for d in crc_bits), 2)
74c9bb3c UH	150	self.putb([11, ['CRC sequence: 0x%04x' % self.crc,
74c9bb3c UH	151	'CRC: 0x%04x' % self.crc, 'CRC']])
702fa251	152	if not self.is_valid_crc(crc_bits):
74c9bb3c	153	self.putb([16, ['CRC is invalid']])
702fa251 UH	154
	155	# CRC delimiter bit (recessive)
	156	elif bitnum == (self.last_databit + 16):
74c9bb3c UH	157	self.putx([12, ['CRC delimiter: %d' % can_rx,
74c9bb3c UH	158	'CRC d: %d' % can_rx, 'CRC d']])
702fa251 UH	159
	160	# ACK slot bit (dominant: ACK, recessive: NACK)
	161	elif bitnum == (self.last_databit + 17):
	162	ack = 'ACK' if can_rx == 0 else 'NACK'
74c9bb3c	163	self.putx([13, ['ACK slot: %s' % ack, 'ACK s: %s' % ack, 'ACK s']])
702fa251 UH	164
	165	# ACK delimiter bit (recessive)
	166	elif bitnum == (self.last_databit + 18):
74c9bb3c UH	167	self.putx([14, ['ACK delimiter: %d' % can_rx,
74c9bb3c UH	168	'ACK d: %d' % can_rx, 'ACK d']])
702fa251	169
4b1813b4 UH	170	# Remember start of EOF (see below).
	171	elif bitnum == (self.last_databit + 19):
	172	self.ss_block = self.samplenum
	173
702fa251 UH	174	# End of frame (EOF), 7 recessive bits
702fa251 UH	175	elif bitnum == (self.last_databit + 25):
74c9bb3c	176	self.putb([2, ['End of frame', 'EOF', 'E']])
702fa251 UH	177	self.reset_variables()
	178	return True
	179
	180	return False
	181
	182	# Returns True if the frame ended (EOF), False otherwise.
	183	def decode_standard_frame(self, can_rx, bitnum):
	184
	185	# Bit 14: RB0 (reserved bit)
	186	# Has to be sent dominant, but receivers should accept recessive too.
	187	if bitnum == 14:
74c9bb3c	188	self.putx([7, ['Reserved bit 0: %d' % can_rx,
534ae912	189	'RB0: %d' % can_rx, 'RB0']])
702fa251 UH	190
	191	# Bit 12: Remote transmission request (RTR) bit
	192	# Data frame: dominant, remote frame: recessive
	193	# Remote frames do not contain a data field.
	194	rtr = 'remote' if self.bits[12] == 1 else 'data'
74c9bb3c	195	self.put12([8, ['Remote transmission request: %s frame' % rtr,
534ae912	196	'RTR: %s frame' % rtr, 'RTR']])
4b1813b4 UH	197
	198	# Remember start of DLC (see below).
	199	elif bitnum == 15:
	200	self.ss_block = self.samplenum
702fa251 UH	201
	202	# Bits 15-18: Data length code (DLC), in number of bytes (0-8).
	203	elif bitnum == 18:
	204	self.dlc = int(''.join(str(d) for d in self.bits[15:18 + 1]), 2)
74c9bb3c UH	205	self.putb([10, ['Data length code: %d' % self.dlc,
74c9bb3c UH	206	'DLC: %d' % self.dlc, 'DLC']])
702fa251 UH	207	self.last_databit = 18 + (self.dlc * 8)
702fa251 UH	208
4b1813b4 UH	209	# Remember all databyte bits, except the very last one.
	210	elif bitnum in range(19, self.last_databit):
	211	self.ss_databytebits.append(self.samplenum)
	212
702fa251 UH	213	# Bits 19-X: Data field (0-8 bytes, depending on DLC)
	214	# The bits within a data byte are transferred MSB-first.
	215	elif bitnum == self.last_databit:
4b1813b4	216	self.ss_databytebits.append(self.samplenum) # Last databyte bit.
702fa251 UH	217	for i in range(self.dlc):
	218	x = 18 + (8 * i) + 1
	219	b = int(''.join(str(d) for d in self.bits[x:x + 8]), 2)
4b1813b4 UH	220	ss = self.ss_databytebits[i * 8]
4b1813b4 UH	221	es = self.ss_databytebits[((i + 1) * 8) - 1]
534ae912 UH	222	self.putg(ss, es, [0, ['Data byte %d: 0x%02x' % (i, b),
534ae912 UH	223	'DB %d: 0x%02x' % (i, b), 'DB']])
4b1813b4	224	self.ss_databytebits = []
702fa251 UH	225
	226	elif bitnum > self.last_databit:
	227	return self.decode_frame_end(can_rx, bitnum)
	228
	229	return False
	230
	231	# Returns True if the frame ended (EOF), False otherwise.
	232	def decode_extended_frame(self, can_rx, bitnum):
	233
4b1813b4 UH	234	# Remember start of EID (see below).
	235	if bitnum == 14:
	236	self.ss_block = self.samplenum
	237
702fa251	238	# Bits 14-31: Extended identifier (EID[17..0])
4b1813b4	239	elif bitnum == 31:
702fa251	240	self.eid = int(''.join(str(d) for d in self.bits[14:]), 2)
534ae912	241	s = '%d (0x%x)' % (self.eid, self.eid)
74c9bb3c	242	self.putb([4, ['Extended Identifier: %s' % s,
534ae912	243	'Extended ID: %s' % s, 'Extended ID', 'EID']])
702fa251 UH	244
702fa251 UH	245	self.fullid = self.id << 18 \| self.eid
534ae912	246	s = '%d (0x%x)' % (self.fullid, self.fullid)
74c9bb3c	247	self.putb([5, ['Full Identifier: %s' % s, 'Full ID: %s' % s,
534ae912	248	'Full ID', 'FID']])
702fa251 UH	249
702fa251 UH	250	# Bit 12: Substitute remote request (SRR) bit
74c9bb3c	251	self.put12([9, ['Substitute remote request: %d' % self.bits[12],
534ae912	252	'SRR: %d' % self.bits[12], 'SRR']])
702fa251 UH	253
	254	# Bit 32: Remote transmission request (RTR) bit
	255	# Data frame: dominant, remote frame: recessive
	256	# Remote frames do not contain a data field.
	257	if bitnum == 32:
	258	rtr = 'remote' if can_rx == 1 else 'data'
74c9bb3c	259	self.putx([8, ['Remote transmission request: %s frame' % rtr,
534ae912	260	'RTR: %s frame' % rtr, 'RTR']])
702fa251 UH	261
	262	# Bit 33: RB1 (reserved bit)
	263	elif bitnum == 33:
74c9bb3c	264	self.putx([7, ['Reserved bit 1: %d' % can_rx,
534ae912	265	'RB1: %d' % can_rx, 'RB1']])
702fa251 UH	266
	267	# Bit 34: RB0 (reserved bit)
	268	elif bitnum == 34:
74c9bb3c	269	self.putx([7, ['Reserved bit 0: %d' % can_rx,
534ae912	270	'RB0: %d' % can_rx, 'RB0']])
702fa251	271
4b1813b4 UH	272	# Remember start of DLC (see below).
	273	elif bitnum == 35:
	274	self.ss_block = self.samplenum
	275
702fa251 UH	276	# Bits 35-38: Data length code (DLC), in number of bytes (0-8).
	277	elif bitnum == 38:
	278	self.dlc = int(''.join(str(d) for d in self.bits[35:38 + 1]), 2)
74c9bb3c UH	279	self.putb([10, ['Data length code: %d' % self.dlc,
74c9bb3c UH	280	'DLC: %d' % self.dlc, 'DLC']])
702fa251 UH	281	self.last_databit = 38 + (self.dlc * 8)
702fa251 UH	282
4b1813b4 UH	283	# Remember all databyte bits, except the very last one.
	284	elif bitnum in range(39, self.last_databit):
	285	self.ss_databytebits.append(self.samplenum)
	286
702fa251 UH	287	# Bits 39-X: Data field (0-8 bytes, depending on DLC)
	288	# The bits within a data byte are transferred MSB-first.
	289	elif bitnum == self.last_databit:
4b1813b4	290	self.ss_databytebits.append(self.samplenum) # Last databyte bit.
702fa251 UH	291	for i in range(self.dlc):
	292	x = 38 + (8 * i) + 1
	293	b = int(''.join(str(d) for d in self.bits[x:x + 8]), 2)
4b1813b4 UH	294	ss = self.ss_databytebits[i * 8]
4b1813b4 UH	295	es = self.ss_databytebits[((i + 1) * 8) - 1]
534ae912 UH	296	self.putg(ss, es, [0, ['Data byte %d: 0x%02x' % (i, b),
534ae912 UH	297	'DB %d: 0x%02x' % (i, b), 'DB']])
4b1813b4	298	self.ss_databytebits = []
702fa251 UH	299
	300	elif bitnum > self.last_databit:
	301	return self.decode_frame_end(can_rx, bitnum)
	302
	303	return False
	304
	305	def handle_bit(self, can_rx):
	306	self.rawbits.append(can_rx)
	307	self.bits.append(can_rx)
	308
	309	# Get the index of the current CAN frame bit (without stuff bits).
	310	bitnum = len(self.bits) - 1
	311
	312	# For debugging.
e20f455c UH	313	# self.putx([0, ['Bit %d (CAN bit %d): %d' % \
e20f455c UH	314	# (self.curbit, bitnum, can_rx)]])
702fa251 UH	315
	316	# If this is a stuff bit, remove it from self.bits and ignore it.
	317	if self.is_stuff_bit():
	318	self.curbit += 1 # Increase self.curbit (bitnum is not affected).
	319	return
	320
	321	# Bit 0: Start of frame (SOF) bit
	322	if bitnum == 0:
	323	if can_rx == 0:
74c9bb3c	324	self.putx([1, ['Start of frame', 'SOF', 'S']])
702fa251	325	else:
74c9bb3c	326	self.putx([16, ['Start of frame (SOF) must be a dominant bit']])
702fa251	327
4b1813b4 UH	328	# Remember start of ID (see below).
	329	elif bitnum == 1:
	330	self.ss_block = self.samplenum
	331
702fa251 UH	332	# Bits 1-11: Identifier (ID[10..0])
	333	# The bits ID[10..4] must NOT be all recessive.
	334	elif bitnum == 11:
	335	self.id = int(''.join(str(d) for d in self.bits[1:]), 2)
534ae912	336	s = '%d (0x%x)' % (self.id, self.id),
74c9bb3c	337	self.putb([3, ['Identifier: %s' % s, 'ID: %s' % s, 'ID']])
702fa251 UH	338
	339	# RTR or SRR bit, depending on frame type (gets handled later).
	340	elif bitnum == 12:
4b1813b4 UH	341	# self.putx([0, ['RTR/SRR: %d' % can_rx]]) # Debug only.
4b1813b4 UH	342	self.ss_bit12 = self.samplenum
702fa251 UH	343
	344	# Bit 13: Identifier extension (IDE) bit
	345	# Standard frame: dominant, extended frame: recessive
	346	elif bitnum == 13:
	347	ide = self.frame_type = 'standard' if can_rx == 0 else 'extended'
74c9bb3c	348	self.putx([6, ['Identifier extension bit: %s frame' % ide,
534ae912	349	'IDE: %s frame' % ide, 'IDE']])
702fa251 UH	350
	351	# Bits 14-X: Frame-type dependent, passed to the resp. handlers.
	352	elif bitnum >= 14:
	353	if self.frame_type == 'standard':
	354	done = self.decode_standard_frame(can_rx, bitnum)
	355	else:
	356	done = self.decode_extended_frame(can_rx, bitnum)
	357
	358	# The handlers return True if a frame ended (EOF).
	359	if done:
	360	return
	361
	362	# After a frame there are 3 intermission bits (recessive).
	363	# After these bits, the bus is considered free.
	364
	365	self.curbit += 1
	366
	367	def decode(self, ss, es, data):
f372d597 BV	368	if self.samplerate is None:
f372d597 BV	369	raise Exception("Cannot decode without samplerate.")
702fa251 UH	370	for (self.samplenum, pins) in data:
	371
	372	(can_rx,) = pins
	373
	374	# State machine.
	375	if self.state == 'IDLE':
	376	# Wait for a dominant state (logic 0) on the bus.
	377	if can_rx == 1:
	378	continue
	379	self.sof = self.samplenum
702fa251 UH	380	self.state = 'GET BITS'
	381	elif self.state == 'GET BITS':
	382	# Wait until we're in the correct bit/sampling position.
	383	if not self.reached_bit(self.curbit):
	384	continue
	385	self.handle_bit(can_rx)
	386	else:
	387	raise Exception("Invalid state: %s" % self.state)
	388