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authorUwe Hermann <uwe@hermann-uwe.de>2014-11-19 18:57:56 +0100
committerUwe Hermann <uwe@hermann-uwe.de>2014-12-28 16:09:07 +0100
commitc4d5221077ef95488325dd104a806eadb5b5f13b (patch)
tree895178357ca1cea96056642566b1485cda48fcfb
parent49d0e05ce73b2b8e47714b5d95e66e9b27aeaa4d (diff)
downloadlibsigrokdecode-c4d5221077ef95488325dd104a806eadb5b5f13b.tar.gz
libsigrokdecode-c4d5221077ef95488325dd104a806eadb5b5f13b.zip
Add 24xx I2C EEPROM protocol decoder.
-rw-r--r--decoders/eeprom24xx/__init__.py26
-rw-r--r--decoders/eeprom24xx/lists.py171
-rw-r--r--decoders/eeprom24xx/pd.py430
3 files changed, 627 insertions, 0 deletions
diff --git a/decoders/eeprom24xx/__init__.py b/decoders/eeprom24xx/__init__.py
new file mode 100644
index 0000000..de19da4
--- /dev/null
+++ b/decoders/eeprom24xx/__init__.py
@@ -0,0 +1,26 @@
+##
+## This file is part of the libsigrokdecode project.
+##
+## Copyright (C) 2014 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
+##
+
+'''
+This decoder stacks on top of the 'i2c' PD and decodes the
+industry standard 24xx series serial EEPROM protocol.
+'''
+
+from .pd import Decoder
diff --git a/decoders/eeprom24xx/lists.py b/decoders/eeprom24xx/lists.py
new file mode 100644
index 0000000..ff4b3ed
--- /dev/null
+++ b/decoders/eeprom24xx/lists.py
@@ -0,0 +1,171 @@
+##
+## This file is part of the libsigrokdecode project.
+##
+## Copyright (C) 2014 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
+##
+
+#
+# Chip specific properties:
+#
+# - vendor: chip manufacturer
+# - model: chip model
+# - size: total EEPROM size (in number of bytes)
+# - page_size: page size (in number of bytes)
+# - page_wraparound: Whether writes wrap-around at page boundaries
+# - addr_bytes: number of EEPROM address bytes used
+# - addr_pins: number of address pins (A0/A1/A2) on this chip
+# - max_speed: max. supported I²C speed (in kHz)
+#
+chips = {
+ # Generic chip (128 bytes, 8 bytes page size)
+ 'generic': {
+ 'vendor': '',
+ 'model': 'Generic',
+ 'size': 128,
+ 'page_size': 8,
+ 'page_wraparound': True,
+ 'addr_bytes': 1,
+ 'addr_pins': 3,
+ 'max_speed': 400,
+ },
+
+ # Microchip
+ 'microchip_24aa65': {
+ 'vendor': 'Microchip',
+ 'model': '24AA65',
+ 'size': 8 * 1024,
+ 'page_size': 64, # Actually 8, but there are 8 pages of "input cache"
+ 'page_wraparound': True,
+ 'addr_bytes': 2,
+ 'addr_pins': 3,
+ 'max_speed': 400,
+ },
+ 'microchip_24lc65': {
+ 'vendor': 'Microchip',
+ 'model': '24LC65',
+ 'size': 8 * 1024,
+ 'page_size': 64, # Actually 8, but there are 8 pages of "input cache"
+ 'page_wraparound': True,
+ 'addr_bytes': 2,
+ 'addr_pins': 3,
+ 'max_speed': 400,
+ },
+ 'microchip_24c65': {
+ 'vendor': 'Microchip',
+ 'model': '24C65',
+ 'size': 8 * 1024,
+ 'page_size': 64, # Actually 8, but there are 8 pages of "input cache"
+ 'page_wraparound': True,
+ 'addr_bytes': 2,
+ 'addr_pins': 3,
+ 'max_speed': 400,
+ },
+ 'microchip_24aa64': {
+ 'vendor': 'Microchip',
+ 'model': '24AA64',
+ 'size': 8 * 1024,
+ 'page_size': 32,
+ 'page_wraparound': True,
+ 'addr_bytes': 2,
+ 'addr_pins': 3,
+ 'max_speed': 400, # 100 for VCC < 2.5V
+ },
+ 'microchip_24lc64': {
+ 'vendor': 'Microchip',
+ 'model': '24LC64',
+ 'size': 8 * 1024,
+ 'page_size': 32,
+ 'page_wraparound': True,
+ 'addr_bytes': 2,
+ 'addr_pins': 3,
+ 'max_speed': 400,
+ },
+ 'microchip_24aa02uid': {
+ 'vendor': 'Microchip',
+ 'model': '24AA02UID',
+ 'size': 256,
+ 'page_size': 8,
+ 'page_wraparound': True,
+ 'addr_bytes': 1,
+ 'addr_pins': 0, # Pins A0, A1, A2 not used
+ 'max_speed': 400,
+ },
+ 'microchip_24aa025uid': {
+ 'vendor': 'Microchip',
+ 'model': '24AA025UID',
+ 'size': 256,
+ 'page_size': 16,
+ 'page_wraparound': True,
+ 'addr_bytes': 1,
+ 'addr_pins': 3,
+ 'max_speed': 400,
+ },
+ 'microchip_24aa025uid_sot23': {
+ 'vendor': 'Microchip',
+ 'model': '24AA025UID (SOT-23)',
+ 'size': 256,
+ 'page_size': 16,
+ 'page_wraparound': True,
+ 'addr_bytes': 1,
+ 'addr_pins': 2, # SOT-23 package: A2 not available
+ 'max_speed': 400,
+ },
+
+ # Siemens
+ 'siemens_slx_24c01': {
+ 'vendor': 'Siemens',
+ 'model': 'SLx 24C01',
+ 'size': 128,
+ 'page_size': 8,
+ 'page_wraparound': True,
+ 'addr_bytes': 1,
+ 'addr_pins': 0, # Pins A0, A1, A2 are not connected (NC)
+ 'max_speed': 400,
+ },
+ 'siemens_slx_24c02': {
+ 'vendor': 'Siemens',
+ 'model': 'SLx 24C02',
+ 'size': 256,
+ 'page_size': 8,
+ 'page_wraparound': True,
+ 'addr_bytes': 1,
+ 'addr_pins': 0, # Pins A0, A1, A2 are not connected (NC)
+ 'max_speed': 400,
+ },
+
+ # ST
+ 'st_m24c01': {
+ 'vendor': 'ST',
+ 'model': 'M24C01',
+ 'size': 128,
+ 'page_size': 16,
+ 'page_wraparound': True,
+ 'addr_bytes': 1,
+ 'addr_pins': 3, # Called E0, E1, E2 on this chip.
+ 'max_speed': 400,
+ },
+ 'st_m24c02': {
+ 'vendor': 'ST',
+ 'model': 'M24C02',
+ 'size': 256,
+ 'page_size': 16,
+ 'page_wraparound': True,
+ 'addr_bytes': 1,
+ 'addr_pins': 3, # Called E0, E1, E2 on this chip.
+ 'max_speed': 400,
+ },
+}
diff --git a/decoders/eeprom24xx/pd.py b/decoders/eeprom24xx/pd.py
new file mode 100644
index 0000000..0738c06
--- /dev/null
+++ b/decoders/eeprom24xx/pd.py
@@ -0,0 +1,430 @@
+##
+## This file is part of the libsigrokdecode project.
+##
+## Copyright (C) 2014 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
+##
+
+import sigrokdecode as srd
+from .lists import *
+
+class Decoder(srd.Decoder):
+ api_version = 2
+ id = 'eeprom24xx'
+ name = '24xx EEPROM'
+ longname = '24xx I²C EEPROM'
+ desc = '24xx series I²C EEPROM protocol.'
+ license = 'gplv2+'
+ inputs = ['i2c']
+ outputs = ['eeprom24xx']
+ options = (
+ {'id': 'chip', 'desc': 'Chip', 'default': 'generic',
+ 'values': tuple(chips.keys())},
+ {'id': 'addr_counter', 'desc': 'Initial address counter value',
+ 'default': 0},
+ )
+ annotations = (
+ # Warnings
+ ('warnings', 'Warnings'),
+ # Bits/bytes
+ ('control-code', 'Control code'),
+ ('address-pin', 'Address pin (A0/A1/A2)'),
+ ('rw-bit', 'Read/write bit'),
+ ('word-addr-byte', 'Word address byte'),
+ ('data-byte', 'Data byte'),
+ # Fields
+ ('control-word', 'Control word'),
+ ('word-addr', 'Word address'),
+ ('data', 'Data'),
+ # Operations
+ ('byte-write', 'Byte write'),
+ ('page-write', 'Page write'),
+ ('cur-addr-read', 'Current address read'),
+ ('random-read', 'Random read'),
+ ('seq-random-read', 'Sequential random read'),
+ ('seq-cur-addr-read', 'Sequential current address read'),
+ ('ack-polling', 'Acknowledge polling'),
+ ('set-bank-addr', 'Set bank address'), # SBA. Only 34AA04.
+ ('read-bank-addr', 'Read bank address'), # RBA. Only 34AA04.
+ ('set-wp', 'Set write protection'), # SWP
+ ('clear-all-wp', 'Clear all write protection'), # CWP
+ ('read-wp', 'Read write protection status'), # RPS
+ )
+ annotation_rows = (
+ ('bits-bytes', 'Bits/bytes', (1, 2, 3, 4, 5)),
+ ('fields', 'Fields', (6, 7, 8)),
+ ('ops', 'Operations', tuple(range(9, 21))),
+ ('warnings', 'Warnings', (0,)),
+ )
+ binary = (
+ ('binary', 'Binary'),
+ )
+
+ def __init__(self, **kwargs):
+ self.reset()
+
+ def start(self):
+ self.out_ann = self.register(srd.OUTPUT_ANN)
+ self.out_bin = self.register(srd.OUTPUT_BINARY)
+ self.chip = chips[self.options['chip']]
+ self.addr_counter = self.options['addr_counter']
+
+ def putb(self, data):
+ self.put(self.ss_block, self.es_block, self.out_ann, data)
+
+ def putbin(self, data):
+ self.put(self.ss_block, self.es_block, self.out_bin, data)
+
+ def putbits(self, bit1, bit2, bits, data):
+ self.put(bits[bit1][1], bits[bit2][2], self.out_ann, data)
+
+ def reset(self):
+ self.state = 'WAIT FOR START'
+ self.packets = []
+ self.bytebuf = []
+ self.is_cur_addr_read = False
+ self.is_random_access_read = False
+ self.is_seq_random_read = False
+ self.is_byte_write = False
+ self.is_page_write = False
+
+ def packet_append(self):
+ self.packets.append([self.ss, self.es, self.cmd, self.databyte, self.bits])
+ if self.cmd in ('DATA READ', 'DATA WRITE'):
+ self.bytebuf.append(self.databyte)
+
+ def hexbytes(self, idx):
+ return ' '.join(['%02X' % b for b in self.bytebuf[idx:]])
+
+ def put_control_word(self, bits):
+ s = ''.join(['%d' % b[0] for b in reversed(bits[4:])])
+ self.putbits(7, 4, bits, [1, ['Control code bits: ' + s,
+ 'Control code: ' + s, 'Ctrl code: ' + s, 'Ctrl code', 'Ctrl', 'C']])
+ for i in reversed(range(self.chip['addr_pins'])):
+ self.putbits(i + 1, i + 1, bits,
+ [2, ['Address bit %d: %d' % (i, bits[i + 1][0]),
+ 'Addr bit %d' % i, 'A%d' % i, 'A']])
+ s1 = 'read' if bits[0][0] == 1 else 'write'
+ s2 = 'R' if bits[0][0] == 1 else 'W'
+ self.putbits(0, 0, bits, [3, ['R/W bit: ' + s1, 'R/W', 'RW', s2]])
+ self.putbits(7, 0, bits, [6, ['Control word', 'Control', 'CW', 'C']])
+
+ def put_word_addr(self, p):
+ if self.chip['addr_bytes'] == 1:
+ a = p[1][3]
+ self.put(p[1][0], p[1][1], self.out_ann,
+ [4, ['Word address byte: %02X' % a, 'Word addr byte: %02X' % a,
+ 'Addr: %02X' % a, 'A: %02X' % a, '%02X' % a]])
+ self.put(p[1][0], p[1][1], self.out_ann, [7, ['Word address',
+ 'Word addr', 'Addr', 'A']])
+ self.addr_counter = a
+ else:
+ a = p[1][3]
+ self.put(p[1][0], p[1][1], self.out_ann,
+ [4, ['Word address high byte: %02X' % a,
+ 'Word addr high byte: %02X' % a,
+ 'Addr high: %02X' % a, 'AH: %02X' % a, '%02X' % a]])
+ a = p[2][3]
+ self.put(p[2][0], p[2][1], self.out_ann,
+ [4, ['Word address low byte: %02X' % a,
+ 'Word addr low byte: %02X' % a,
+ 'Addr low: %02X' % a, 'AL: %02X' % a, '%02X' % a]])
+ self.put(p[1][0], p[2][1], self.out_ann, [7, ['Word address',
+ 'Word addr', 'Addr', 'A']])
+ self.addr_counter = (p[1][3] << 8) | p[2][3]
+
+ def put_data_byte(self, p):
+ if self.chip['addr_bytes'] == 1:
+ s = '%02X' % self.addr_counter
+ else:
+ s = '%04X' % self.addr_counter
+ self.put(p[0], p[1], self.out_ann, [5, ['Data byte %s: %02X' % \
+ (s, p[3]), 'Data byte: %02X' % p[3], \
+ 'Byte: %02X' % p[3], 'DB: %02X' % p[3], '%02X' % p[3]]])
+
+ def put_data_bytes(self, idx, cls, s):
+ for p in self.packets[idx:]:
+ self.put_data_byte(p)
+ self.addr_counter += 1
+ self.put(self.packets[idx][0], self.packets[-1][1], self.out_ann,
+ [8, ['Data', 'D']])
+ a = ''.join(['%s' % c[0] for c in s.split()]).upper()
+ self.putb([cls, ['%s (%s): %s' % (s, self.addr_and_len(), \
+ self.hexbytes(self.chip['addr_bytes'])),
+ '%s (%s)' % (s, self.addr_and_len()), s, a, s[0]]])
+ self.putbin((0, bytes(self.bytebuf[self.chip['addr_bytes']:])))
+
+ def addr_and_len(self):
+ if self.chip['addr_bytes'] == 1:
+ a = '%02X' % self.bytebuf[0]
+ else:
+ a = '%02X%02X' % tuple(self.bytebuf[:2])
+ num_data_bytes = len(self.bytebuf) - self.chip['addr_bytes']
+ d = '%d bytes' % num_data_bytes
+ if num_data_bytes <= 1:
+ d = d[:-1]
+ return 'addr=%s, %s' % (a, d)
+
+ def decide_on_seq_or_rnd_read(self):
+ if len(self.bytebuf) < 2:
+ self.reset()
+ return
+ if len(self.bytebuf) == 2:
+ self.is_random_access_read = True
+ else:
+ self.is_seq_random_read = True
+
+ def put_operation(self):
+ idx = 1 + self.chip['addr_bytes']
+ if self.is_byte_write:
+ # Byte write: word address, one data byte.
+ self.put_word_addr(self.packets)
+ self.put_data_bytes(idx, 9, 'Byte write')
+ elif self.is_page_write:
+ # Page write: word address, two or more data bytes.
+ self.put_word_addr(self.packets)
+ intitial_addr = self.addr_counter
+ self.put_data_bytes(idx, 10, 'Page write')
+ num_bytes_to_write = len(self.packets[idx:])
+ if num_bytes_to_write > self.chip['page_size']:
+ self.putb([0, ['Warning: Wrote %d bytes but page size is '
+ 'only %d bytes!' % (num_bytes_to_write,
+ self.chip['page_size'])]])
+ page1 = int(intitial_addr / self.chip['page_size'])
+ page2 = int((self.addr_counter - 1) / self.chip['page_size'])
+ if page1 != page2:
+ self.putb([0, ['Warning: Page write crossed page boundary '
+ 'from page %d to %d!' % (page1, page2)]])
+ elif self.is_cur_addr_read:
+ # Current address read: no word address, one data byte.
+ self.put_data_byte(self.packets[1])
+ self.put(self.packets[1][0], self.packets[-1][1], self.out_ann,
+ [8, ['Data', 'D']])
+ self.putb([11, ['Current address read: %02X' % self.bytebuf[0],
+ 'Current address read', 'Cur addr read', 'CAR', 'C']])
+ self.putbin((0, bytes([self.bytebuf[0]])))
+ self.addr_counter += 1
+ elif self.is_random_access_read:
+ # Random access read: word address, one data byte.
+ self.put_control_word(self.packets[idx][4])
+ self.put_word_addr(self.packets)
+ self.put_data_bytes(idx + 1, 12, 'Random access read')
+ elif self.is_seq_random_read:
+ # Sequential random read: word address, two or more data bytes.
+ self.put_control_word(self.packets[idx][4])
+ self.put_word_addr(self.packets)
+ self.put_data_bytes(idx + 1, 13, 'Sequential random read')
+
+ def handle_wait_for_start(self):
+ # Wait for an I²C START condition.
+ if self.cmd not in ('START', 'START REPEAT'):
+ return
+ self.ss_block = self.ss
+ self.state = 'GET CONTROL WORD'
+
+ def handle_get_control_word(self):
+ # The packet after START must be an ADDRESS READ or ADDRESS WRITE.
+ if self.cmd not in ('ADDRESS READ', 'ADDRESS WRITE'):
+ self.reset()
+ return
+ self.packet_append()
+ self.put_control_word(self.bits)
+ self.state = '%s GET ACK NACK AFTER CONTROL WORD' % self.cmd[8]
+
+ def handle_r_get_ack_nack_after_control_word(self):
+ if self.cmd == 'ACK':
+ self.state = 'R GET WORD ADDR OR BYTE'
+ elif self.cmd == 'NACK':
+ self.es_block = self.es
+ self.putb([0, ['Warning: No reply from slave!']])
+ self.reset()
+ else:
+ self.reset()
+
+ def handle_r_get_word_addr_or_byte(self):
+ if self.cmd == 'STOP':
+ self.es_block = self.es
+ self.putb([0, ['Warning: Slave replied, but master aborted!']])
+ self.reset()
+ return
+ elif self.cmd != 'DATA READ':
+ self.reset()
+ return
+ self.packet_append()
+ self.state = 'R GET ACK NACK AFTER WORD ADDR OR BYTE'
+
+ def handle_r_get_ack_nack_after_word_addr_or_byte(self):
+ if self.cmd == 'ACK':
+ self.state = 'R GET RESTART'
+ elif self.cmd == 'NACK':
+ self.is_cur_addr_read = True
+ self.state = 'GET STOP AFTER LAST BYTE'
+ else:
+ self.reset()
+
+ def handle_r_get_restart(self):
+ if self.cmd == 'RESTART':
+ self.state = 'R READ BYTE'
+ else:
+ self.reset()
+
+ def handle_r_read_byte(self):
+ if self.cmd == 'DATA READ':
+ self.packet_append()
+ self.state = 'R GET ACK NACK AFTER BYTE WAS READ'
+ else:
+ self.reset()
+
+ def handle_r_get_ack_nack_after_byte_was_read(self):
+ if self.cmd == 'ACK':
+ self.state = 'R READ BYTE'
+ elif self.cmd == 'NACK':
+ # It's either a RANDOM READ or a SEQUENTIAL READ.
+ self.state = 'GET STOP AFTER LAST BYTE'
+ else:
+ self.reset()
+
+ def handle_w_get_ack_nack_after_control_word(self):
+ if self.cmd == 'ACK':
+ self.state = 'W GET WORD ADDR'
+ elif self.cmd == 'NACK':
+ self.es_block = self.es
+ self.putb([0, ['Warning: No reply from slave!']])
+ self.reset()
+ else:
+ self.reset()
+
+ def handle_w_get_word_addr(self):
+ if self.cmd == 'STOP':
+ self.es_block = self.es
+ self.putb([0, ['Warning: Slave replied, but master aborted!']])
+ self.reset()
+ return
+ elif self.cmd != 'DATA WRITE':
+ self.reset()
+ return
+ self.packet_append()
+ self.state = 'W GET ACK AFTER WORD ADDR'
+
+ def handle_w_get_ack_after_word_addr(self):
+ if self.cmd == 'ACK':
+ self.state = 'W DETERMINE EEPROM READ OR WRITE'
+ else:
+ self.reset()
+
+ def handle_w_determine_eeprom_read_or_write(self):
+ if self.cmd == 'START REPEAT':
+ # It's either a RANDOM ACCESS READ or SEQUENTIAL RANDOM READ.
+ self.state = 'R2 GET CONTROL WORD'
+ elif self.cmd == 'DATA WRITE':
+ self.packet_append()
+ self.state = 'W GET ACK NACK AFTER BYTE WAS WRITTEN'
+ else:
+ self.reset()
+
+ def handle_w_write_byte(self):
+ if self.cmd == 'DATA WRITE':
+ self.packet_append()
+ self.state = 'W GET ACK NACK AFTER BYTE WAS WRITTEN'
+ elif self.cmd == 'STOP':
+ if len(self.bytebuf) < 2:
+ self.reset()
+ return
+ self.es_block = self.es
+ if len(self.bytebuf) == 2:
+ self.is_byte_write = True
+ else:
+ self.is_page_write = True
+ self.put_operation()
+ self.reset()
+ elif self.cmd == 'START REPEAT':
+ # It's either a RANDOM ACCESS READ or SEQUENTIAL RANDOM READ.
+ self.state = 'R2 GET CONTROL WORD'
+ else:
+ self.reset()
+
+ def handle_w_get_ack_nack_after_byte_was_written(self):
+ if self.cmd == 'ACK':
+ self.state = 'W WRITE BYTE'
+ else:
+ self.reset()
+
+ def handle_r2_get_control_word(self):
+ if self.cmd == 'ADDRESS READ':
+ self.packet_append()
+ self.state = 'R2 GET ACK AFTER ADDR READ'
+ else:
+ self.reset()
+
+ def handle_r2_get_ack_after_addr_read(self):
+ if self.cmd == 'ACK':
+ self.state = 'R2 READ BYTE'
+ else:
+ self.reset()
+
+ def handle_r2_read_byte(self):
+ if self.cmd == 'DATA READ':
+ self.packet_append()
+ self.state = 'R2 GET ACK NACK AFTER BYTE WAS READ'
+ elif self.cmd == 'STOP':
+ self.decide_on_seq_or_rnd_read()
+ self.es_block = self.es
+ self.putb([0, ['Warning: STOP expected after a NACK (not ACK)']])
+ self.put_operation()
+ self.reset()
+ else:
+ self.reset()
+
+ def handle_r2_get_ack_nack_after_byte_was_read(self):
+ if self.cmd == 'ACK':
+ self.state = 'R2 READ BYTE'
+ elif self.cmd == 'NACK':
+ self.decide_on_seq_or_rnd_read()
+ self.state = 'GET STOP AFTER LAST BYTE'
+ else:
+ self.reset()
+
+ def handle_get_stop_after_last_byte(self):
+ if self.cmd == 'STOP':
+ self.es_block = self.es
+ self.put_operation()
+ self.reset()
+ elif self.cmd == 'START REPEAT':
+ self.es_block = self.es
+ self.putb([0, ['Warning: STOP expected (not RESTART)']])
+ self.put_operation()
+ self.reset()
+ self.ss_block = self.ss
+ self.state = 'GET CONTROL WORD'
+ else:
+ self.reset()
+
+ def decode(self, ss, es, data):
+ self.cmd, self.databyte = data
+
+ # Collect the 'BITS' packet, then return. The next packet is
+ # guaranteed to belong to these bits we just stored.
+ if self.cmd == 'BITS':
+ self.bits = self.databyte
+ return
+
+ # Store the start/end samples of this I²C packet.
+ self.ss, self.es = ss, es
+
+ # State machine.
+ s = 'handle_%s' % self.state.lower().replace(' ', '_')
+ handle_state = getattr(self, s)
+ handle_state()