# 'data': (actual data as integer ???) TODO: This can be very variable...
# 'ann': (string; additional annotations / comments)
#
-# Example output:
-# [{'type': 'S', 'range': (150, 160), 'data': None, 'ann': 'Foobar'},
-# {'type': 'AW', 'range': (200, 300), 'data': 0x50, 'ann': 'Slave 4'},
-# {'type': 'DW', 'range': (310, 370), 'data': 0x00, 'ann': 'Init cmd'},
-# {'type': 'AR', 'range': (500, 560), 'data': 0x50, 'ann': 'Get stat'},
-# {'type': 'DR', 'range': (580, 640), 'data': 0xfe, 'ann': 'OK'},
-# {'type': 'P', 'range': (650, 660), 'data': None, 'ann': None}]
-#
-# Possible other events:
-# - Error event in case protocol looks broken:
-# [{'type': 'ERROR', 'range': (min, max),
-# 'data': TODO, 'ann': 'This is not a Microchip 24XX64 EEPROM'},
-# [{'type': 'ERROR', 'range': (min, max),
-# 'data': TODO, 'ann': 'TODO'},
-# - TODO: Make list of possible errors accessible as metadata?
-#
# TODO: I2C address of slaves.
# TODO: Handle multiple different I2C devices on same bus
# -> we need to decode multiple protocols at the same time.
-# TODO: range: Always contiguous? Splitted ranges? Multiple per event?
#
#
# 'signals': [{'SCL': }]}
#
-import sigrok
-
-# symbols for i2c decoders up the stack
-START = 1
-START_REPEAT = 2
-STOP = 3
-ACK = 4
-NACK = 5
-ADDRESS_READ = 6
-ADDRESS_WRITE = 7
-DATA_READ = 8
-DATA_WRITE = 9
+import sigrokdecode
+
+# values are verbose and short annotation, respectively
+protocol = {
+ 'START': ['START', 'S'],
+ 'START_REPEAT': ['START REPEAT', 'Sr'],
+ 'STOP': ['STOP', 'P'],
+ 'ACK': ['ACK', 'A'],
+ 'NACK': ['NACK', 'N'],
+ 'ADDRESS_READ': ['ADDRESS READ', 'AR'],
+ 'ADDRESS_WRITE': ['ADDRESS WRITE','AW'],
+ 'DATA_READ': ['DATA READ', 'DR'],
+ 'DATA_WRITE': ['DATA WRITE', 'DW'],
+}
+# export protocol keys as symbols for i2c decoders up the stack
+EXPORT = [ protocol.keys() ]
# States
FIND_START = 0
FIND_ADDRESS = 1
FIND_DATA = 2
-class Sample():
- def __init__(self, data):
- self.data = data
- def probe(self, probe):
- s = ord(self.data[probe / 8]) & (1 << (probe % 8))
- return True if s else False
+# annotation feed formats
+ANN_SHIFTED = 0
+ANN_SHIFTED_SHORT = 1
+ANN_RAW = 2
-def sampleiter(data, unitsize):
- for i in range(0, len(data), unitsize):
- yield(Sample(data[i:i+unitsize]))
-class Decoder(sigrok.Decoder):
+class Decoder(sigrokdecode.Decoder):
id = 'i2c'
name = 'I2C'
longname = 'Inter-Integrated Circuit (I2C) bus'
license = 'gplv2+'
inputs = ['logic']
outputs = ['i2c']
- probes = {
- 'scl': {'ch': 0, 'name': 'SCL', 'desc': 'Serial clock line'},
- 'sda': {'ch': 1, 'name': 'SDA', 'desc': 'Serial data line'},
- }
+ probes = [
+ {'id': 'scl', 'name': 'SCL', 'desc': 'Serial clock line'},
+ {'id': 'sda', 'name': 'SDA', 'desc': 'Serial data line'},
+ ]
options = {
'address-space': ['Address space (in bits)', 7],
}
+ annotation = [
+ # ANN_SHIFTED
+ ["7-bit shifted hex",
+ "Read/Write bit shifted out from the 8-bit i2c slave address"],
+ # ANN_SHIFTED_SHORT
+ ["7-bit shifted hex (short)",
+ "Read/Write bit shifted out from the 8-bit i2c slave address"],
+ # ANN_RAW
+ ["Raw hex", "Unaltered raw data"]
+ ]
def __init__(self, **kwargs):
- self.probes = Decoder.probes.copy()
self.output_protocol = None
self.output_annotation = None
-
- # TODO: Don't hardcode the number of channels.
- self.channels = 8
-
- self.samplenum = 0
+ self.samplecnt = 0
self.bitcount = 0
self.databyte = 0
self.wr = -1
self.startsample = -1
self.is_repeat_start = 0
-
self.state = FIND_START
-
- # Get the channel/probe number of the SCL/SDA signals.
- self.scl_bit = self.probes['scl']['ch']
- self.sda_bit = self.probes['sda']['ch']
-
self.oldscl = None
self.oldsda = None
def start(self, metadata):
- self.unitsize = metadata["unitsize"]
- self.output_protocol = self.output_new(2)
- self.output_annotation = self.output_new(1)
+ self.output_protocol = self.output_new(1)
+ self.output_annotation = self.output_new(0)
def report(self):
pass
def found_start(self, scl, sda):
if self.is_repeat_start == 1:
- out_proto = [ START_REPEAT ]
- out_ann = [ "START REPEAT" ]
+ cmd = 'START_REPEAT'
else:
- out_proto = [ START ]
- out_ann = [ "START" ]
- self.put(self.output_protocol, out_proto)
- self.put(self.output_annotation, out_ann)
+ cmd = 'START'
+ self.put(self.output_protocol, [ cmd ])
+ self.put(self.output_annotation, [ ANN_SHIFTED, [protocol[cmd][0]] ])
+ self.put(self.output_annotation, [ ANN_SHIFTED_SHORT, [protocol[cmd][1]] ])
self.state = FIND_ADDRESS
self.bitcount = self.databyte = 0
"""Gather 8 bits of data plus the ACK/NACK bit."""
if self.startsample == -1:
- self.startsample = self.samplenum
+ # TODO: should be samplenum, as received from the feed
+ self.startsample = self.samplecnt
self.bitcount += 1
# Address and data are transmitted MSB-first.
if self.bitcount != 9:
return []
+ # send raw output annotation before we start shifting out
+ # read/write and ack/nack bits
+ self.put(self.output_annotation, [ANN_RAW, ["0x%.2x" % self.databyte]])
+
# We received 8 address/data bits and the ACK/NACK bit.
self.databyte >>= 1 # Shift out unwanted ACK/NACK bit here.
# TODO: Error?
pass
- out_proto = []
- out_ann = []
+ # last bit that came in was the ACK/NACK bit (1 = NACK)
+ if sda == 1:
+ ack_bit = 'NACK'
+ else:
+ ack_bit = 'ACK'
+
# TODO: Simplify.
if self.state == FIND_ADDRESS and self.wr == 1:
- cmd = ADDRESS_WRITE
- ann = 'ADDRESS WRITE'
+ cmd = 'ADDRESS_WRITE'
elif self.state == FIND_ADDRESS and self.wr == 0:
- cmd = ADDRESS_READ
- ann = 'ADDRESS READ'
+ cmd = 'ADDRESS_READ'
elif self.state == FIND_DATA and self.wr == 1:
- cmd = DATA_WRITE
- ann = 'DATA WRITE'
+ cmd = 'DATA_WRITE'
elif self.state == FIND_DATA and self.wr == 0:
- cmd = DATA_READ
- ann = 'DATA READ'
- out_proto.append( [cmd, d] )
- out_ann.append( ["%s" % ann, "0x%02x" % d] )
-
- if sda == 1:
- out_proto.append( [NACK] )
- out_ann.append( ["NACK"] )
- else:
- out_proto.append( [ACK] )
- out_ann.append( ["ACK"] )
-
- self.put(self.output_protocol, out_proto)
- self.put(self.output_annotation, out_ann)
+ cmd = 'DATA_READ'
+ self.put(self.output_protocol, [ [cmd, d], [ack_bit] ] )
+ self.put(self.output_annotation, [ANN_SHIFTED, [
+ "%s" % protocol[cmd][0],
+ "0x%02x" % d,
+ "%s" % protocol[ack_bit][0]]
+ ] )
+ self.put(self.output_annotation, [ANN_SHIFTED_SHORT, [
+ "%s" % protocol[cmd][1],
+ "0x%02x" % d,
+ "%s" % protocol[ack_bit][1]]
+ ] )
self.bitcount = self.databyte = 0
self.startsample = -1
pass
def found_stop(self, scl, sda):
- self.put(self.output_protocol, [ STOP ])
- self.put(self.output_annotation, [ "STOP" ])
+ self.put(self.output_protocol, [ 'STOP' ])
+ self.put(self.output_annotation, [ ANN_SHIFTED, [protocol['STOP'][0]] ])
+ self.put(self.output_annotation, [ ANN_SHIFTED_SHORT, [protocol['STOP'][1]] ])
self.state = FIND_START
self.is_repeat_start = 0
self.wr = -1
- def decode(self, data):
- """I2C protocol decoder"""
-
- # We should accept a list of samples and iterate...
- for sample in sampleiter(data['data'], self.unitsize):
-
- # TODO: Eliminate the need for ord().
- s = ord(sample.data)
+ def put(self, output_id, data):
+ # inject sample range into the call up to sigrok
+ # TODO: 0-0 sample range for now
+ super(Decoder, self).put(0, 0, output_id, data)
- # TODO: Start counting at 0 or 1?
- self.samplenum += 1
+ def decode(self, timeoffset, duration, data):
+ for samplenum, (scl, sda) in data:
+ self.samplecnt += 1
# First sample: Save SCL/SDA value.
if self.oldscl == None:
- # Get SCL/SDA bit values (0/1 for low/high) of the first sample.
- self.oldscl = (s & (1 << self.scl_bit)) >> self.scl_bit
- self.oldsda = (s & (1 << self.sda_bit)) >> self.sda_bit
+ self.oldscl = scl
+ self.oldsda = sda
continue
- # Get SCL/SDA bit values (0/1 for low/high).
- scl = (s & (1 << self.scl_bit)) >> self.scl_bit
- sda = (s & (1 << self.sda_bit)) >> self.sda_bit
-
# TODO: Wait until the bus is idle (SDA = SCL = 1) first?
# State machine.
self.oldscl = scl
self.oldsda = sda
-