[libsigrokdecode.git] / decoders / atsha204a / pd.py

##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2018 Michalis Pappas <mpappas@fastmail.fm>
##
## 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

WORD_ADDR_RESET         = 0x00
WORD_ADDR_SLEEP         = 0x01
WORD_ADDR_IDLE          = 0x02
WORD_ADDR_COMMAND       = 0x03

WORD_ADDR = {0x00: 'RESET', 0x01: 'SLEEP', 0x02: 'IDLE', 0x03: 'COMMAND'}

OPCODE_COUNTER          = 0x24
OPCODE_DERIVE_KEY       = 0x1c
OPCODE_DEV_REV          = 0x30
OPCODE_ECDH             = 0x43
OPCODE_GEN_DIG          = 0x15
OPCODE_GEN_KEY          = 0x40
OPCODE_HMAC             = 0x11
OPCODE_CHECK_MAC        = 0x28
OPCODE_LOCK             = 0x17
OPCODE_MAC              = 0x08
OPCODE_NONCE            = 0x16
OPCODE_PAUSE            = 0x01
OPCODE_PRIVWRITE        = 0x46
OPCODE_RANDOM           = 0x1b
OPCODE_READ             = 0x02
OPCODE_SHA              = 0x47
OPCODE_SIGN             = 0x41
OPCODE_UPDATE_EXTRA     = 0x20
OPCODE_VERIFY           = 0x45
OPCODE_WRITE            = 0x12

OPCODES = {
    0x01: 'Pause',
    0x02: 'Read',
    0x08: 'MAC',
    0x11: 'HMAC',
    0x12: 'Write',
    0x15: 'GenDig',
    0x16: 'Nonce',
    0x17: 'Lock',
    0x1b: 'Random',
    0x1c: 'DeriveKey',
    0x20: 'UpdateExtra',
    0x24: 'Counter',
    0x28: 'CheckMac',
    0x30: 'DevRev',
    0x40: 'GenKey',
    0x41: 'Sign',
    0x43: 'ECDH',
    0x45: 'Verify',
    0x46: 'PrivWrite',
    0x47: 'SHA',
}

ZONE_CONFIG             = 0x00
ZONE_OTP                = 0x01
ZONE_DATA               = 0x02

ZONES = {0x00: 'CONFIG', 0x01: 'OTP', 0x02: 'DATA'}

STATUS_SUCCESS          = 0x00
STATUS_CHECKMAC_FAIL    = 0x01
STATUS_PARSE_ERROR      = 0x03
STATUS_EXECUTION_ERROR  = 0x0f
STATUS_READY            = 0x11
STATUS_CRC_COMM_ERROR   = 0xff

STATUS = {
    0x00: 'Command success',
    0x01: 'Checkmac failure',
    0x03: 'Parse error',
    0x0f: 'Execution error',
    0x11: 'Ready',
    0xff: 'CRC / communications error',
}

class Decoder(srd.Decoder):
    api_version = 3
    id = 'atsha204a'
    name = 'ATSHA204A'
    longname = 'Microchip ATSHA204A'
    desc = 'Microchip ATSHA204A family crypto authentication protocol.'
    license = 'gplv2+'
    inputs = ['i2c']
    outputs = []
    tags = ['Security/crypto', 'IC', 'Memory']
    annotations = (
        ('waddr', 'Word address'),
        ('count', 'Count'),
        ('opcode', 'Opcode'),
        ('param1', 'Param1'),
        ('param2', 'Param2'),
        ('data', 'Data'),
        ('crc', 'CRC'),
        ('status', 'Status'),
        ('warning', 'Warning'),
    )
    annotation_rows = (
        ('frame', 'Frame', (0, 1, 2, 3, 4, 5, 6)),
        ('status', 'Status', (7,)),
        ('warnings', 'Warnings', (8,)),
    )

    def __init__(self):
        self.reset()

    def reset(self):
        self.state = 'IDLE'
        self.waddr = self.opcode = -1
        self.ss_block = self.es_block = 0
        self.bytes = []

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

    def output_tx_bytes(self):
        b = self.bytes
        if len(b) < 1: # Ignore wakeup.
            return
        self.waddr = b[0][2]
        self.put_waddr(b[0])
        if self.waddr == WORD_ADDR_COMMAND:
            count = b[1][2]
            self.put_count(b[1])
            if len(b) - 1 != count:
                self.put_warning(b[0][0], b[-1][1],
                    'Invalid frame length: Got {}, expecting {} '.format(
                    len(b) - 1, count))
                return
            self.opcode = b[2][2]
            self.put_opcode(b[2])
            self.put_param1(b[3])
            self.put_param2([b[4], b[5]])
            self.put_data(b[6:-2])
            self.put_crc([b[-2], b[-1]])

    def output_rx_bytes(self):
        b = self.bytes
        count = b[0][2]
        self.put_count(b[0])
        if self.waddr == WORD_ADDR_RESET:
            self.put_data([b[1]])
            self.put_crc([b[2], b[3]])
            self.put_status(b[0][0], b[-1][1], b[1][2])
        elif self.waddr == WORD_ADDR_COMMAND:
            if count == 4: # Status / Error.
                self.put_data([b[1]])
                self.put_crc([b[2], b[3]])
                self.put_status(b[0][0], b[-1][1], b[1][2])
            else:
                self.put_data(b[1:-2])
                self.put_crc([b[-2], b[-1]])

    def putx(self, s, data):
        self.put(s[0], s[1], self.out_ann, data)

    def puty(self, s, data):
        self.put(s[0][0], s[1][1], self.out_ann, data)

    def putz(self, ss, es, data):
        self.put(ss, es, self.out_ann, data)

    def put_waddr(self, s):
        self.putx(s, [0, ['Word addr: %s' % WORD_ADDR[s[2]]]])

    def put_count(self, s):
        self.putx(s, [1, ['Count: %s' % s[2]]])

    def put_opcode(self, s):
        self.putx(s, [2, ['Opcode: %s' % OPCODES[s[2]]]])

    def put_param1(self, s):
        op = self.opcode
        if op in (OPCODE_CHECK_MAC, OPCODE_COUNTER, OPCODE_DEV_REV,     \
                  OPCODE_ECDH, OPCODE_GEN_KEY, OPCODE_HMAC, OPCODE_MAC, \
                  OPCODE_NONCE, OPCODE_RANDOM, OPCODE_SHA, OPCODE_SIGN, \
                  OPCODE_VERIFY):
            self.putx(s, [3, ['Mode: %02X' % s[2]]])
        elif op == OPCODE_DERIVE_KEY:
            self.putx(s, [3, ['Random: %s' % s[2]]])
        elif op == OPCODE_PRIVWRITE:
            self.putx(s, [3, ['Encrypted: {}'.format('Yes' if s[2] & 0x40 else 'No')]])
        elif op == OPCODE_GEN_DIG:
            self.putx(s, [3, ['Zone: %s' % ZONES[s[2]]]])
        elif op == OPCODE_LOCK:
            self.putx(s, [3, ['Zone: {}, Summary: {}'.format(
                'DATA/OTP' if s[2] else 'CONFIG',
                'Ignored' if s[2] & 0x80 else 'Used')]])
        elif op == OPCODE_PAUSE:
            self.putx(s, [3, ['Selector: %02X' % s[2]]])
        elif op == OPCODE_READ:
            self.putx(s, [3, ['Zone: {}, Length: {}'.format(ZONES[s[2] & 0x03],
                '32 bytes' if s[2] & 0x90 else '4 bytes')]])
        elif op == OPCODE_WRITE:
            self.putx(s, [3, ['Zone: {}, Encrypted: {}, Length: {}'.format(ZONES[s[2] & 0x03],
                'Yes' if s[2] & 0x40 else 'No', '32 bytes' if s[2] & 0x90 else '4 bytes')]])
        else:
            self.putx(s, [3, ['Param1: %02X' % s[2]]])

    def put_param2(self, s):
        op = self.opcode
        if op == OPCODE_DERIVE_KEY:
            self.puty(s, [4, ['TargetKey: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
        elif op in (OPCODE_COUNTER, OPCODE_ECDH, OPCODE_GEN_KEY, OPCODE_PRIVWRITE, \
                    OPCODE_SIGN, OPCODE_VERIFY):
            self.puty(s, [4, ['KeyID: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
        elif op in (OPCODE_NONCE, OPCODE_PAUSE, OPCODE_RANDOM):
            self.puty(s, [4, ['Zero: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
        elif op in (OPCODE_HMAC, OPCODE_MAC, OPCODE_CHECK_MAC, OPCODE_GEN_DIG):
            self.puty(s, [4, ['SlotID: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
        elif op == OPCODE_LOCK:
            self.puty(s, [4, ['Summary: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
        elif op in (OPCODE_READ, OPCODE_WRITE):
            self.puty(s, [4, ['Address: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
        elif op == OPCODE_UPDATE_EXTRA:
            self.puty(s, [4, ['NewValue: {:02x}'.format(s[0][2])]])
        else:
            self.puty(s, [4, ['-']])

    def put_data(self, s):
        if len(s) == 0:
            return
        op = self.opcode
        if op == OPCODE_CHECK_MAC:
            self.putz(s[0][0], s[31][1], [5, ['ClientChal: %s' % ' '.join(format(i[2], '02x') for i in s[0:32])]])
            self.putz(s[32][0], s[63][1], [5, ['ClientResp: %s' % ' '.join(format(i[2], '02x') for i in s[32:64])]])
            self.putz(s[64][0], s[76][1], [5, ['OtherData: %s' % ' '.join(format(i[2], '02x') for i in s[64:77])]])
        elif op == OPCODE_DERIVE_KEY:
            self.putz(s[0][0], s[31][1], [5, ['MAC: %s' % ' '.join(format(i[2], '02x') for i in s)]])
        elif op == OPCODE_ECDH:
            self.putz(s[0][0], s[31][1], [5, ['Pub X: %s' % ' '.join(format(i[2], '02x') for i in s[0:32])]])
            self.putz(s[32][0], s[63][1], [5, ['Pub Y: %s' % ' '.join(format(i[2], '02x') for i in s[32:64])]])
        elif op in (OPCODE_GEN_DIG, OPCODE_GEN_KEY):
            self.putz(s[0][0], s[3][1], [5, ['OtherData: %s' % ' '.join(format(i[2], '02x') for i in s)]])
        elif op == OPCODE_MAC:
            self.putz(s[0][0], s[31][1], [5, ['Challenge: %s' % ' '.join(format(i[2], '02x') for i in s)]])
        elif op == OPCODE_PRIVWRITE:
            if len(s) > 36: # Key + MAC.
                self.putz(s[0][0], s[-35][1], [5, ['Value: %s' % ' '.join(format(i[2], '02x') for i in s)]])
                self.putz(s[-32][0], s[-1][1], [5, ['MAC: %s' % ' '.join(format(i[2], '02x') for i in s)]])
            else: # Just value.
                self.putz(s[0][0], s[-1][1], [5, ['Value: %s' % ' '.join(format(i[2], '02x') for i in s)]])
        elif op == OPCODE_VERIFY:
            if len(s) >= 64: # ECDSA components (always present)
                self.putz(s[0][0], s[31][1], [5, ['ECDSA R: %s' % ' '.join(format(i[2], '02x') for i in s[0:32])]])
                self.putz(s[32][0], s[63][1], [5, ['ECDSA S: %s' % ' '.join(format(i[2], '02x') for i in s[32:64])]])
            if len(s) == 83: # OtherData (follow ECDSA components in validate / invalidate mode)
                self.putz(s[64][0], s[82][1], [5, ['OtherData: %s' % ' '.join(format(i[2], '02x') for i in s[64:83])]])
            if len(s) == 128: # Public key components (follow ECDSA components in external mode)
                self.putz(s[64][0], s[95][1], [5, ['Pub X: %s' % ' '.join(format(i[2], '02x') for i in s[64:96])]])
                self.putz(s[96][0], s[127][1], [5, ['Pub Y: %s' % ' '.join(format(i[2], '02x') for i in s[96:128])]])
        elif op == OPCODE_WRITE:
            if len(s) > 32: # Value + MAC.
                self.putz(s[0][0], s[-31][1], [5, ['Value: %s' % ' '.join(format(i[2], '02x') for i in s)]])
                self.putz(s[-32][0], s[-1][1], [5, ['MAC: %s' % ' '.join(format(i[2], '02x') for i in s)]])
            else: # Just value.
                self.putz(s[0][0], s[-1][1], [5, ['Value: %s' % ' '.join(format(i[2], '02x') for i in s)]])
        else:
            self.putz(s[0][0], s[-1][1], [5, ['Data: %s' % ' '.join(format(i[2], '02x') for i in s)]])

    def put_crc(self, s):
        self.puty(s, [6, ['CRC: {:02X} {:02X}'.format(s[0][2], s[1][2])]])

    def put_status(self, ss, es, status):
        self.putz(ss, es, [7, ['Status: %s' % STATUS[status]]])

    def put_warning(self, ss, es, msg):
        self.putz(ss, es, [8, ['Warning: %s' % msg]])

    def decode(self, ss, es, data):
        cmd, databyte = data
        # State machine.
        if self.state == 'IDLE':
            # Wait for an I²C START condition.
            if cmd != 'START':
                return
            self.state = 'GET SLAVE ADDR'
            self.ss_block = ss
        elif self.state == 'GET SLAVE ADDR':
            # Wait for an address read/write operation.
            if cmd == 'ADDRESS READ':
                self.state = 'READ REGS'
            elif cmd == 'ADDRESS WRITE':
                self.state = 'WRITE REGS'
        elif self.state == 'READ REGS':
            if cmd == 'DATA READ':
                self.bytes.append([ss, es, databyte])
            elif cmd == 'STOP':
                self.es_block = es
                # Reset the opcode before received data, as this causes
                # responses to be displayed incorrectly.
                self.opcode = -1
                if len(self.bytes) > 0:
                    self.output_rx_bytes()
                self.waddr = -1
                self.bytes = []
                self.state = 'IDLE'
        elif self.state == 'WRITE REGS':
            if cmd == 'DATA WRITE':
                self.bytes.append([ss, es, databyte])
            elif cmd == 'STOP':
                self.es_block = es
                self.output_tx_bytes()
                self.bytes = []
                self.state = 'IDLE'
Commit	Line	Data
fb249641 UH	1	##
	2	## This file is part of the libsigrokdecode project.
	3	##
	4	## Copyright (C) 2018 Michalis Pappas <mpappas@fastmail.fm>
	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, see <http://www.gnu.org/licenses/>.
	18	##
	19
	20	import sigrokdecode as srd
	21
	22	WORD_ADDR_RESET = 0x00
	23	WORD_ADDR_SLEEP = 0x01
	24	WORD_ADDR_IDLE = 0x02
	25	WORD_ADDR_COMMAND = 0x03
	26
	27	WORD_ADDR = {0x00: 'RESET', 0x01: 'SLEEP', 0x02: 'IDLE', 0x03: 'COMMAND'}
	28
3f5f3a92	29	OPCODE_COUNTER = 0x24
fb249641 UH	30	OPCODE_DERIVE_KEY = 0x1c
fb249641 UH	31	OPCODE_DEV_REV = 0x30
3f5f3a92	32	OPCODE_ECDH = 0x43
fb249641	33	OPCODE_GEN_DIG = 0x15
3f5f3a92	34	OPCODE_GEN_KEY = 0x40
fb249641 UH	35	OPCODE_HMAC = 0x11
	36	OPCODE_CHECK_MAC = 0x28
	37	OPCODE_LOCK = 0x17
	38	OPCODE_MAC = 0x08
	39	OPCODE_NONCE = 0x16
	40	OPCODE_PAUSE = 0x01
3f5f3a92	41	OPCODE_PRIVWRITE = 0x46
fb249641 UH	42	OPCODE_RANDOM = 0x1b
	43	OPCODE_READ = 0x02
	44	OPCODE_SHA = 0x47
3f5f3a92	45	OPCODE_SIGN = 0x41
fb249641	46	OPCODE_UPDATE_EXTRA = 0x20
3f5f3a92	47	OPCODE_VERIFY = 0x45
fb249641 UH	48	OPCODE_WRITE = 0x12
	49
	50	OPCODES = {
	51	0x01: 'Pause',
	52	0x02: 'Read',
	53	0x08: 'MAC',
	54	0x11: 'HMAC',
	55	0x12: 'Write',
	56	0x15: 'GenDig',
	57	0x16: 'Nonce',
	58	0x17: 'Lock',
	59	0x1b: 'Random',
	60	0x1c: 'DeriveKey',
	61	0x20: 'UpdateExtra',
3f5f3a92	62	0x24: 'Counter',
fb249641 UH	63	0x28: 'CheckMac',
fb249641 UH	64	0x30: 'DevRev',
3f5f3a92 UH	65	0x40: 'GenKey',
	66	0x41: 'Sign',
	67	0x43: 'ECDH',
	68	0x45: 'Verify',
	69	0x46: 'PrivWrite',
fb249641 UH	70	0x47: 'SHA',
	71	}
	72
	73	ZONE_CONFIG = 0x00
	74	ZONE_OTP = 0x01
	75	ZONE_DATA = 0x02
	76
	77	ZONES = {0x00: 'CONFIG', 0x01: 'OTP', 0x02: 'DATA'}
	78
	79	STATUS_SUCCESS = 0x00
	80	STATUS_CHECKMAC_FAIL = 0x01
	81	STATUS_PARSE_ERROR = 0x03
	82	STATUS_EXECUTION_ERROR = 0x0f
	83	STATUS_READY = 0x11
	84	STATUS_CRC_COMM_ERROR = 0xff
	85
	86	STATUS = {
	87	0x00: 'Command success',
	88	0x01: 'Checkmac failure',
	89	0x03: 'Parse error',
	90	0x0f: 'Execution error',
	91	0x11: 'Ready',
	92	0xff: 'CRC / communications error',
	93	}
	94
	95	class Decoder(srd.Decoder):
	96	api_version = 3
	97	id = 'atsha204a'
	98	name = 'ATSHA204A'
	99	longname = 'Microchip ATSHA204A'
3f5f3a92	100	desc = 'Microchip ATSHA204A family crypto authentication protocol.'
fb249641 UH	101	license = 'gplv2+'
fb249641 UH	102	inputs = ['i2c']
3f5f3a92 UH	103	outputs = []
3f5f3a92 UH	104	tags = ['Security/crypto', 'IC', 'Memory']
fb249641 UH	105	annotations = (
	106	('waddr', 'Word address'),
	107	('count', 'Count'),
	108	('opcode', 'Opcode'),
	109	('param1', 'Param1'),
	110	('param2', 'Param2'),
	111	('data', 'Data'),
	112	('crc', 'CRC'),
	113	('status', 'Status'),
	114	('warning', 'Warning'),
	115	)
	116	annotation_rows = (
	117	('frame', 'Frame', (0, 1, 2, 3, 4, 5, 6)),
	118	('status', 'Status', (7,)),
	119	('warnings', 'Warnings', (8,)),
	120	)
	121
	122	def __init__(self):
	123	self.reset()
	124
	125	def reset(self):
	126	self.state = 'IDLE'
	127	self.waddr = self.opcode = -1
	128	self.ss_block = self.es_block = 0
	129	self.bytes = []
	130
	131	def start(self):
	132	self.out_ann = self.register(srd.OUTPUT_ANN)
	133
	134	def output_tx_bytes(self):
	135	b = self.bytes
	136	if len(b) < 1: # Ignore wakeup.
	137	return
	138	self.waddr = b[0][2]
	139	self.put_waddr(b[0])
	140	if self.waddr == WORD_ADDR_COMMAND:
	141	count = b[1][2]
	142	self.put_count(b[1])
	143	if len(b) - 1 != count:
	144	self.put_warning(b[0][0], b[-1][1],
	145	'Invalid frame length: Got {}, expecting {} '.format(
	146	len(b) - 1, count))
	147	return
	148	self.opcode = b[2][2]
	149	self.put_opcode(b[2])
	150	self.put_param1(b[3])
	151	self.put_param2([b[4], b[5]])
	152	self.put_data(b[6:-2])
	153	self.put_crc([b[-2], b[-1]])
	154
	155	def output_rx_bytes(self):
	156	b = self.bytes
	157	count = b[0][2]
	158	self.put_count(b[0])
	159	if self.waddr == WORD_ADDR_RESET:
	160	self.put_data([b[1]])
	161	self.put_crc([b[2], b[3]])
	162	self.put_status(b[0][0], b[-1][1], b[1][2])
	163	elif self.waddr == WORD_ADDR_COMMAND:
	164	if count == 4: # Status / Error.
	165	self.put_data([b[1]])
	166	self.put_crc([b[2], b[3]])
	167	self.put_status(b[0][0], b[-1][1], b[1][2])
	168	else:
169	self.put_data(b[1:-2])
170	self.put_crc([b[-2], b[-1]])
171
172	def putx(self, s, data):
173	self.put(s[0], s[1], self.out_ann, data)
174
175	def puty(self, s, data):
176	self.put(s[0][0], s[1][1], self.out_ann, data)
177
178	def putz(self, ss, es, data):
179	self.put(ss, es, self.out_ann, data)
180
181	def put_waddr(self, s):
182	self.putx(s, [0, ['Word addr: %s' % WORD_ADDR[s[2]]]])
183
184	def put_count(self, s):
185	self.putx(s, [1, ['Count: %s' % s[2]]])
186
187	def put_opcode(self, s):
188	self.putx(s, [2, ['Opcode: %s' % OPCODES[s[2]]]])
189
190	def put_param1(self, s):
191	op = self.opcode
3f5f3a92 UH	192	if op in (OPCODE_CHECK_MAC, OPCODE_COUNTER, OPCODE_DEV_REV, \
	193	OPCODE_ECDH, OPCODE_GEN_KEY, OPCODE_HMAC, OPCODE_MAC, \
	194	OPCODE_NONCE, OPCODE_RANDOM, OPCODE_SHA, OPCODE_SIGN, \
	195	OPCODE_VERIFY):
fb249641 UH	196	self.putx(s, [3, ['Mode: %02X' % s[2]]])
	197	elif op == OPCODE_DERIVE_KEY:
	198	self.putx(s, [3, ['Random: %s' % s[2]]])
3f5f3a92 UH	199	elif op == OPCODE_PRIVWRITE:
3f5f3a92 UH	200	self.putx(s, [3, ['Encrypted: {}'.format('Yes' if s[2] & 0x40 else 'No')]])
fb249641 UH	201	elif op == OPCODE_GEN_DIG:
	202	self.putx(s, [3, ['Zone: %s' % ZONES[s[2]]]])
	203	elif op == OPCODE_LOCK:
	204	self.putx(s, [3, ['Zone: {}, Summary: {}'.format(
	205	'DATA/OTP' if s[2] else 'CONFIG',
	206	'Ignored' if s[2] & 0x80 else 'Used')]])
	207	elif op == OPCODE_PAUSE:
	208	self.putx(s, [3, ['Selector: %02X' % s[2]]])
	209	elif op == OPCODE_READ:
	210	self.putx(s, [3, ['Zone: {}, Length: {}'.format(ZONES[s[2] & 0x03],
	211	'32 bytes' if s[2] & 0x90 else '4 bytes')]])
	212	elif op == OPCODE_WRITE:
	213	self.putx(s, [3, ['Zone: {}, Encrypted: {}, Length: {}'.format(ZONES[s[2] & 0x03],
	214	'Yes' if s[2] & 0x40 else 'No', '32 bytes' if s[2] & 0x90 else '4 bytes')]])
	215	else:
	216	self.putx(s, [3, ['Param1: %02X' % s[2]]])
	217
	218	def put_param2(self, s):
	219	op = self.opcode
	220	if op == OPCODE_DERIVE_KEY:
	221	self.puty(s, [4, ['TargetKey: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
3f5f3a92 UH	222	elif op in (OPCODE_COUNTER, OPCODE_ECDH, OPCODE_GEN_KEY, OPCODE_PRIVWRITE, \
	223	OPCODE_SIGN, OPCODE_VERIFY):
	224	self.puty(s, [4, ['KeyID: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
fb249641 UH	225	elif op in (OPCODE_NONCE, OPCODE_PAUSE, OPCODE_RANDOM):
	226	self.puty(s, [4, ['Zero: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
	227	elif op in (OPCODE_HMAC, OPCODE_MAC, OPCODE_CHECK_MAC, OPCODE_GEN_DIG):
	228	self.puty(s, [4, ['SlotID: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
	229	elif op == OPCODE_LOCK:
	230	self.puty(s, [4, ['Summary: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
	231	elif op in (OPCODE_READ, OPCODE_WRITE):
	232	self.puty(s, [4, ['Address: {:02x} {:02x}'.format(s[1][2], s[0][2])]])
	233	elif op == OPCODE_UPDATE_EXTRA:
	234	self.puty(s, [4, ['NewValue: {:02x}'.format(s[0][2])]])
	235	else:
	236	self.puty(s, [4, ['-']])
	237
	238	def put_data(self, s):
	239	if len(s) == 0:
	240	return
	241	op = self.opcode
	242	if op == OPCODE_CHECK_MAC:
3f5f3a92 UH	243	self.putz(s[0][0], s[31][1], [5, ['ClientChal: %s' % ' '.join(format(i[2], '02x') for i in s[0:32])]])
	244	self.putz(s[32][0], s[63][1], [5, ['ClientResp: %s' % ' '.join(format(i[2], '02x') for i in s[32:64])]])
	245	self.putz(s[64][0], s[76][1], [5, ['OtherData: %s' % ' '.join(format(i[2], '02x') for i in s[64:77])]])
fb249641 UH	246	elif op == OPCODE_DERIVE_KEY:
fb249641 UH	247	self.putz(s[0][0], s[31][1], [5, ['MAC: %s' % ' '.join(format(i[2], '02x') for i in s)]])
3f5f3a92 UH	248	elif op == OPCODE_ECDH:
	249	self.putz(s[0][0], s[31][1], [5, ['Pub X: %s' % ' '.join(format(i[2], '02x') for i in s[0:32])]])
	250	self.putz(s[32][0], s[63][1], [5, ['Pub Y: %s' % ' '.join(format(i[2], '02x') for i in s[32:64])]])
	251	elif op in (OPCODE_GEN_DIG, OPCODE_GEN_KEY):
fb249641 UH	252	self.putz(s[0][0], s[3][1], [5, ['OtherData: %s' % ' '.join(format(i[2], '02x') for i in s)]])
	253	elif op == OPCODE_MAC:
	254	self.putz(s[0][0], s[31][1], [5, ['Challenge: %s' % ' '.join(format(i[2], '02x') for i in s)]])
3f5f3a92 UH	255	elif op == OPCODE_PRIVWRITE:
	256	if len(s) > 36: # Key + MAC.
	257	self.putz(s[0][0], s[-35][1], [5, ['Value: %s' % ' '.join(format(i[2], '02x') for i in s)]])
	258	self.putz(s[-32][0], s[-1][1], [5, ['MAC: %s' % ' '.join(format(i[2], '02x') for i in s)]])
	259	else: # Just value.
	260	self.putz(s[0][0], s[-1][1], [5, ['Value: %s' % ' '.join(format(i[2], '02x') for i in s)]])
	261	elif op == OPCODE_VERIFY:
	262	if len(s) >= 64: # ECDSA components (always present)
	263	self.putz(s[0][0], s[31][1], [5, ['ECDSA R: %s' % ' '.join(format(i[2], '02x') for i in s[0:32])]])
	264	self.putz(s[32][0], s[63][1], [5, ['ECDSA S: %s' % ' '.join(format(i[2], '02x') for i in s[32:64])]])
	265	if len(s) == 83: # OtherData (follow ECDSA components in validate / invalidate mode)
	266	self.putz(s[64][0], s[82][1], [5, ['OtherData: %s' % ' '.join(format(i[2], '02x') for i in s[64:83])]])
	267	if len(s) == 128: # Public key components (follow ECDSA components in external mode)
	268	self.putz(s[64][0], s[95][1], [5, ['Pub X: %s' % ' '.join(format(i[2], '02x') for i in s[64:96])]])
	269	self.putz(s[96][0], s[127][1], [5, ['Pub Y: %s' % ' '.join(format(i[2], '02x') for i in s[96:128])]])
fb249641 UH	270	elif op == OPCODE_WRITE:
	271	if len(s) > 32: # Value + MAC.
	272	self.putz(s[0][0], s[-31][1], [5, ['Value: %s' % ' '.join(format(i[2], '02x') for i in s)]])
	273	self.putz(s[-32][0], s[-1][1], [5, ['MAC: %s' % ' '.join(format(i[2], '02x') for i in s)]])
	274	else: # Just value.
	275	self.putz(s[0][0], s[-1][1], [5, ['Value: %s' % ' '.join(format(i[2], '02x') for i in s)]])
	276	else:
	277	self.putz(s[0][0], s[-1][1], [5, ['Data: %s' % ' '.join(format(i[2], '02x') for i in s)]])
	278
	279	def put_crc(self, s):
	280	self.puty(s, [6, ['CRC: {:02X} {:02X}'.format(s[0][2], s[1][2])]])
	281
	282	def put_status(self, ss, es, status):
	283	self.putz(ss, es, [7, ['Status: %s' % STATUS[status]]])
	284
	285	def put_warning(self, ss, es, msg):
	286	self.putz(ss, es, [8, ['Warning: %s' % msg]])
	287
	288	def decode(self, ss, es, data):
	289	cmd, databyte = data
fb249641 UH	290	# State machine.
	291	if self.state == 'IDLE':
	292	# Wait for an I²C START condition.
	293	if cmd != 'START':
	294	return
	295	self.state = 'GET SLAVE ADDR'
	296	self.ss_block = ss
	297	elif self.state == 'GET SLAVE ADDR':
	298	# Wait for an address read/write operation.
	299	if cmd == 'ADDRESS READ':
	300	self.state = 'READ REGS'
	301	elif cmd == 'ADDRESS WRITE':
	302	self.state = 'WRITE REGS'
	303	elif self.state == 'READ REGS':
	304	if cmd == 'DATA READ':
	305	self.bytes.append([ss, es, databyte])
	306	elif cmd == 'STOP':
	307	self.es_block = es
	308	# Reset the opcode before received data, as this causes
	309	# responses to be displayed incorrectly.
	310	self.opcode = -1
3f5f3a92 UH	311	if len(self.bytes) > 0:
3f5f3a92 UH	312	self.output_rx_bytes()
fb249641 UH	313	self.waddr = -1
	314	self.bytes = []
	315	self.state = 'IDLE'
	316	elif self.state == 'WRITE REGS':
	317	if cmd == 'DATA WRITE':
	318	self.bytes.append([ss, es, databyte])
	319	elif cmd == 'STOP':
	320	self.es_block = es
	321	self.output_tx_bytes()
	322	self.bytes = []
	323	self.state = 'IDLE'