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##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2018 Jorge Solla Rubiales <jorgesolla@gmail.com>
##
## 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
from .protocoldata import *
# Pulse types
class Pulse:
INVALID, START, ZERO, ONE = range(4)
# Protocol stats
class Stat:
WAIT_START, GET_BITS, WAIT_EOM, WAIT_ACK = range(4)
# Pulse times in milliseconds
timing = {
Pulse.START: {
'low': { 'min': 3.5, 'max': 3.9 },
'total': { 'min': 4.3, 'max': 4.7 }
},
Pulse.ZERO: {
'low': { 'min': 1.3, 'max': 1.7 },
'total': { 'min': 2.05, 'max': 2.75 }
},
Pulse.ONE: {
'low': { 'min': 0.4, 'max': 0.8 },
'total': { 'min': 2.05, 'max': 2.75 }
}
}
class ChannelError(Exception):
pass
class Decoder(srd.Decoder):
api_version = 3
id = 'cec'
name = 'CEC'
longname = 'HDMI-CEC'
desc = 'HDMI Consumer Electronics Control (CEC) protocol.'
license = 'gplv2+'
inputs = ['logic']
outputs = ['cec']
channels = (
{'id': 'cec', 'name': 'CEC', 'desc': 'CEC bus data'},
)
annotations = (
('st', 'Start'),
('eom-0', 'End of message'),
('eom-1', 'Message continued'),
('nack', 'ACK not set'),
('ack', 'ACK set'),
('bits', 'Bits'),
('bytes', 'Bytes'),
('frames', 'Frames'),
('sections', 'Sections'),
('warnings', 'Warnings')
)
annotation_rows = (
('bits', 'Bits', (0, 1, 2, 3, 4, 5)),
('bytes', 'Bytes', (6,)),
('frames', 'Frames', (7,)),
('sections', 'Sections', (8,)),
('warnings', 'Warnings', (9,))
)
def __init__(self):
self.reset()
def precalculate(self):
# Restrict max length of ACK/NACK labels to 2 BIT pulses.
bit_time = timing[Pulse.ZERO]['total']['min']
bit_time = bit_time * 2
self.max_ack_len_samples = round((bit_time / 1000) * self.samplerate)
def reset(self):
self.stat = Stat.WAIT_START
self.samplerate = None
self.fall_start = None
self.fall_end = None
self.rise = None
self.reset_frame_vars()
def reset_frame_vars(self):
self.eom = None
self.bit_count = 0
self.byte_count = 0
self.byte = 0
self.byte_start = None
self.frame_start = None
self.frame_end = None
self.is_nack = 0
self.cmd_bytes = []
def metadata(self, key, value):
if key == srd.SRD_CONF_SAMPLERATE:
self.samplerate = value
self.precalculate()
def set_stat(self, stat):
self.stat = stat
def handle_frame(self, is_nack):
if self.fall_start is None or self.fall_end is None:
return
i = 0
str = ''
while i < len(self.cmd_bytes):
str += '{:02x}'.format(self.cmd_bytes[i]['val'])
if i != (len(self.cmd_bytes) - 1):
str += ':'
i += 1
self.put(self.frame_start, self.frame_end, self.out_ann, [7, [str]])
i = 0
operands = 0
str = ''
while i < len(self.cmd_bytes):
if i == 0: # Parse header
(src, dst) = decode_header(self.cmd_bytes[i]['val'])
str = 'HDR: ' + src + ', ' + dst
elif i == 1: # Parse opcode
str += ' | OPC: ' + decode_opcode(self.cmd_bytes[i]['val'])
else: # Parse operands
if operands == 0:
str += ' | OPS: '
operands += 1
str += '0x{:02x}'.format(self.cmd_bytes[i]['val'])
if i != len(self.cmd_bytes) - 1:
str += ', '
i += 1
# Header only commands are PINGS
if i == 1:
if self.eom:
str += ' | OPC: PING'
else:
str += ' | OPC: NONE. Aborted cmd'
# Add extra information (ack of the command from the destination)
if is_nack:
str += ' | R: NACK'
else:
str += ' | R: ACK'
self.put(self.frame_start, self.frame_end, self.out_ann, [8, [str]])
def process(self):
zero_time = ((self.rise - self.fall_start) / self.samplerate) * 1000.0
total_time = ((self.fall_end - self.fall_start) / self.samplerate) * 1000.0
pulse = Pulse.INVALID
# VALIDATION: Identify pulse based on length of the low period
for key in timing:
if zero_time >= timing[key]['low']['min'] and zero_time <= timing[key]['low']['max']:
pulse = key
break
# VALIDATION: Invalid pulse
if pulse == Pulse.INVALID:
self.set_stat(Stat.WAIT_START)
self.put(self.fall_start, self.fall_end, self.out_ann, [9, ['Invalid pulse: Wrong timing']])
return
# VALIDATION: If waiting for start, discard everything else
if self.stat == Stat.WAIT_START and pulse != Pulse.START:
self.put(self.fall_start, self.fall_end, self.out_ann, [9, ['Expected START: BIT found']])
return
# VALIDATION: If waiting for ACK or EOM, only BIT pulses (0/1) are expected
if (self.stat == Stat.WAIT_ACK or self.stat == Stat.WAIT_EOM) and pulse == Pulse.START:
self.put(self.fall_start, self.fall_end, self.out_ann, [9, ['Expected BIT: START received)']])
self.set_stat(Stat.WAIT_START)
# VALIDATION: ACK bit pulse remains high till the next frame (if any): Validate only min time of the low period
if self.stat == Stat.WAIT_ACK and pulse != Pulse.START:
if total_time < timing[pulse]['total']['min']:
pulse = Pulse.INVALID
self.put(self.fall_start, self.fall_end, self.out_ann, [9, ['ACK pulse below minimun time']])
self.set_stat(Stat.WAIT_START)
return
# VALIDATION / PING FRAME DETECTION: Initiator doesn't sets the EOM = 1 but stops sending when ack doesn't arrive
if self.stat == Stat.GET_BITS and pulse == Pulse.START:
# Make sure we received a complete byte to consider it a valid ping
if self.bit_count == 0:
self.handle_frame(self.is_nack)
else:
self.put(self.frame_start, self.samplenum, self.out_ann, [9, ['ERROR: Incomplete byte received']])
# Set wait start so we receive next frame
self.set_stat(Stat.WAIT_START)
# VALIDATION: Check timing of the BIT (0/1) pulse in any other case (not waiting for ACK)
if self.stat != Stat.WAIT_ACK and pulse != Pulse.START:
if total_time < timing[pulse]['total']['min'] or total_time > timing[pulse]['total']['max']:
self.put(self.fall_start, self.fall_end, self.out_ann, [9, ['Bit pulse exceeds total pulse timespan']])
pulse = Pulse.INVALID
self.set_stat(Stat.WAIT_START)
return
if pulse == Pulse.ZERO:
bit = 0
elif pulse == Pulse.ONE:
bit = 1
# STATE: WAIT START
if self.stat == Stat.WAIT_START:
self.set_stat(Stat.GET_BITS)
self.reset_frame_vars()
self.put(self.fall_start, self.fall_end, self.out_ann, [0, ['ST']])
# STATE: GET BITS
elif self.stat == Stat.GET_BITS:
# Reset stats on first bit
if self.bit_count == 0:
self.byte_start = self.fall_start
self.byte = 0
# If 1st byte of the datagram save its sample num
if len(self.cmd_bytes) == 0:
self.frame_start = self.fall_start
self.byte += (bit << (7 - self.bit_count))
self.bit_count += 1
self.put(self.fall_start, self.fall_end, self.out_ann, [5, [str(bit)]])
if self.bit_count == 8:
self.bit_count = 0
self.byte_count += 1
self.set_stat(Stat.WAIT_EOM)
self.put(self.byte_start, self.samplenum, self.out_ann, [6, ['0x{:02x}'.format(self.byte)]])
self.cmd_bytes.append({'st': self.byte_start, 'ed': self.samplenum, 'val': self.byte})
# STATE: WAIT EOM
elif self.stat == Stat.WAIT_EOM:
self.eom = bit
self.frame_end = self.fall_end
if self.eom:
self.put(self.fall_start, self.fall_end, self.out_ann, [2, ['EOM=Y']])
else:
self.put(self.fall_start, self.fall_end, self.out_ann, [1, ['EOM=N']])
self.set_stat(Stat.WAIT_ACK)
# STATE: WAIT ACK
elif self.stat == Stat.WAIT_ACK:
# If a frame with broadcast destination is being sent, the ACK is
# inverted: a 0 is considered a NACK, therefore we invert the value
# of the bit here, so we match the real meaning of it.
if (self.cmd_bytes[0]['val'] & 0x0F) == 0x0F:
bit = ~bit & 0x01
if (self.fall_end - self.fall_start) > self.max_ack_len_samples:
ann_end = self.fall_start + self.max_ack_len_samples
else:
ann_end = self.fall_end
if bit:
# Any NACK detected in the frame is enough to consider the
# whole frame NACK'd.
self.is_nack = 1
self.put(self.fall_start, ann_end, self.out_ann, [3, ['NACK']])
else:
self.put(self.fall_start, ann_end, self.out_ann, [4, ['ACK']])
# After ACK bit, wait for new datagram or continue reading current
# one based on EOM value.
if self.eom or self.is_nack:
self.set_stat(Stat.WAIT_START)
self.handle_frame(self.is_nack)
else:
self.set_stat(Stat.GET_BITS)
def start(self):
self.out_ann = self.register(srd.OUTPUT_ANN)
def decode(self):
if not self.samplerate:
raise SamplerateError('Cannot decode without samplerate.')
# Wait for first falling edge.
self.wait({0: 'f'})
self.fall_end = self.samplenum
while True:
self.wait({0: 'r'})
self.rise = self.samplenum
if self.stat == Stat.WAIT_ACK:
self.wait([{0: 'f'}, {'skip': self.max_ack_len_samples}])
else:
self.wait([{0: 'f'}])
self.fall_start = self.fall_end
self.fall_end = self.samplenum
self.process()
# If there was a timeout while waiting for ACK: RESYNC.
# Note: This is an expected situation as no new falling edge will
# happen until next frame is transmitted.
if self.matched == (False, True):
self.wait({0: 'f'})
self.fall_end = self.samplenum
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