import sigrokdecode as srd
# Annotation feed formats
-ANN_ASCII = 0
-ANN_DEC = 1
-ANN_HEX = 2
-ANN_OCT = 3
-ANN_BITS = 4
+ANN_LINK = 0
+ANN_NETWORK = 1
+ANN_TRANSPORT = 2
+
+# a dictionary of ROM commands and their names
+rom_command = {0x33: "READ ROM",
+ 0x0f: "CONDITIONAL READ ROM",
+ 0xcc: "SKIP ROM",
+ 0x55: "MATCH ROM",
+ 0xf0: "SEARCH ROM",
+ 0xec: "CONDITIONAL SEARCH ROM",
+ 0x3c: "OVERDRIVE SKIP ROM",
+ 0x6d: "OVERDRIVE MATCH ROM"}
class Decoder(srd.Decoder):
api_version = 1
{'id': 'pwr', 'name': 'PWR', 'desc': '1-Wire power'},
]
options = {
- 'overdrive': ['Overdrive', 0],
+ 'overdrive' : ['Overdrive', 1],
+ 'cnt_normal_bit' : ['Time (in samplerate periods) for normal mode sample bit' , 0],
+ 'cnt_normal_presence' : ['Time (in samplerate periods) for normal mode sample presence', 0],
+ 'cnt_normal_reset' : ['Time (in samplerate periods) for normal mode reset' , 0],
+ 'cnt_overdrive_bit' : ['Time (in samplerate periods) for overdrive mode sample bit' , 0],
+ 'cnt_overdrive_presence': ['Time (in samplerate periods) for overdrive mode sample presence', 0],
+ 'cnt_overdrive_reset' : ['Time (in samplerate periods) for overdrive mode reset' , 0],
}
annotations = [
- ['ASCII', 'Data bytes as ASCII characters'],
- ['Decimal', 'Databytes as decimal, integer values'],
- ['Hex', 'Data bytes in hex format'],
- ['Octal', 'Data bytes as octal numbers'],
- ['Bits', 'Data bytes in bit notation (sequence of 0/1 digits)'],
+ ['Link', 'Link layer events (reset, presence, bit slots)'],
+ ['Network', 'Network layer events (device addressing)'],
+ ['Transport', 'Transport layer events'],
]
- def putx(self, data):
- self.put(self.startsample, self.samplenum - 1, self.out_ann, data)
-
def __init__(self, **kwargs):
# Common variables
self.samplenum = 0
# Link layer variables
- self.lnk_state = 'WAIT FOR EVENT'
- self.lnk_event = 'NONE'
- self.lnk_start = -1
- self.lnk_bit = -1
- self.lnk_cnt = 0
- self.lnk_byte = -1
+ self.lnk_state = 'WAIT FOR FALLING EDGE'
+ self.lnk_event = 'NONE'
+ self.lnk_present = 0
+ self.lnk_bit = 0
+ self.lnk_overdrive = 0
+ # Event timing variables
+ self.lnk_fall = 0
+ self.lnk_rise = 0
+ self.net_beg = 0
+ self.net_end = 0
+ self.net_len = 0
# Network layer variables
- self.net_state = 'WAIT FOR EVENT'
- self.net_event = 'NONE'
- self.net_command = -1
- # Transport layer variables
- self.trn_state = 'WAIT FOR EVENT'
- self.trn_event = 'NONE'
-
- self.data_sample = -1
- self.cur_data_bit = 0
- self.databyte = 0
- self.startsample = -1
+ self.net_state = 'IDLE'
+ self.net_cnt = 0
+ self.net_search = "P"
+ self.net_data_p = 0x0
+ self.net_data_n = 0x0
+ self.net_data = 0x0
+ self.net_rom = 0x0000000000000000
def start(self, metadata):
- self.samplerate = metadata['samplerate']
self.out_proto = self.add(srd.OUTPUT_PROTO, 'onewire')
- self.out_ann = self.add(srd.OUTPUT_ANN, 'onewire')
+ self.out_ann = self.add(srd.OUTPUT_ANN , 'onewire')
- # The width of the 1-Wire time base (30us) in number of samples.
- # TODO: optimize this value
- self.time_base = float(self.samplerate) / float(0.000030)
-
- def report(self):
- pass
+ # check if samplerate is appropriate
+ self.samplerate = metadata['samplerate']
+ if (self.options['overdrive']):
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['NOTE: Sample rate checks assume overdrive mode.']])
+ if (self.samplerate < 2000000):
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['ERROR: Sampling rate is too low must be above 2MHz for proper overdrive mode decoding.']])
+ elif (self.samplerate < 5000000):
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['WARNING: Sampling rate is suggested to be above 5MHz for proper overdrive mode decoding.']])
+ else:
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['NOTE: Sample rate checks assume normal mode only.']])
+ if (self.samplerate < 400000):
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['ERROR: Sampling rate is too low must be above 400kHz for proper normal mode decoding.']])
+ elif (self.samplerate < 1000000):
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['WARNING: Sampling rate is suggested to be above 1MHz for proper normal mode decoding.']])
- def get_data_sample(self, owr):
- # Skip samples until we're in the middle of the start bit.
- if not self.reached_data_sample():
- return
-
- self.data_sample = owr
-
- self.cur_data_bit = 0
- self.databyte = 0
- self.startsample = -1
-
- self.state = 'GET DATA BITS'
-
- self.put(self.cycle_start, self.samplenum, self.out_proto,
- ['STARTBIT', self.startbit])
- self.put(self.cycle_start, self.samplenum, self.out_ann,
- [ANN_ASCII, ['Start bit', 'Start', 'S']])
-
- def get_data_bits(self, owr):
- # Skip samples until we're in the middle of the desired data bit.
- if not self.reached_bit(self.cur_data_bit + 1):
- return
-
- # Save the sample number where the data byte starts.
- if self.startsample == -1:
- self.startsample = self.samplenum
-
- # Get the next data bit in LSB-first or MSB-first fashion.
- if self.options['bit_order'] == 'lsb-first':
- self.databyte >>= 1
- self.databyte |= \
- (owr << (self.options['num_data_bits'] - 1))
- elif self.options['bit_order'] == 'msb-first':
- self.databyte <<= 1
- self.databyte |= (owr << 0)
+ # The default 1-Wire time base is 30us, this is used to calculate sampling times.
+ if (self.options['cnt_normal_bit']):
+ self.cnt_normal_bit = self.options['cnt_normal_bit']
+ else:
+ self.cnt_normal_bit = int(float(self.samplerate) * 0.000015) - 1 # 15ns
+ if (self.options['cnt_normal_presence']):
+ self.cnt_normal_presence = self.options['cnt_normal_presence']
+ else:
+ self.cnt_normal_presence = int(float(self.samplerate) * 0.000075) - 1 # 75ns
+ if (self.options['cnt_normal_reset']):
+ self.cnt_normal_reset = self.options['cnt_normal_reset']
+ else:
+ self.cnt_normal_reset = int(float(self.samplerate) * 0.000480) - 1 # 480ns
+ if (self.options['cnt_overdrive_bit']):
+ self.cnt_overdrive_bit = self.options['cnt_overdrive_bit']
else:
- raise Exception('Invalid bit order value: %s',
- self.options['bit_order'])
+ self.cnt_overdrive_bit = int(float(self.samplerate) * 0.000002) - 1 # 2ns
+ if (self.options['cnt_overdrive_presence']):
+ self.cnt_overdrive_presence = self.options['cnt_overdrive_presence']
+ else:
+ self.cnt_overdrive_presence = int(float(self.samplerate) * 0.000010) - 1 # 10ns
+ if (self.options['cnt_overdrive_reset']):
+ self.cnt_overdrive_reset = self.options['cnt_overdrive_reset']
+ else:
+ self.cnt_overdrive_reset = int(float(self.samplerate) * 0.000048) - 1 # 48ns
- # Return here, unless we already received all data bits.
- # TODO? Off-by-one?
- if self.cur_data_bit < self.options['num_data_bits'] - 1:
- self.cur_data_bit += 1
- return
+ # calculating the slot size
+ self.cnt_normal_slot = int(float(self.samplerate) * 0.000060) - 1 # 60ns
+ self.cnt_overdrive_slot = int(float(self.samplerate) * 0.000006) - 1 # 6ns
- self.state = 'GET PARITY BIT'
+ # organize values into lists
+ self.cnt_bit = [self.cnt_normal_bit , self.cnt_overdrive_bit ]
+ self.cnt_presence = [self.cnt_normal_presence, self.cnt_overdrive_presence]
+ self.cnt_reset = [self.cnt_normal_reset , self.cnt_overdrive_reset ]
+ self.cnt_slot = [self.cnt_normal_slot , self.cnt_overdrive_slot ]
- self.put(self.startsample, self.samplenum - 1, self.out_proto,
- ['DATA', self.databyte])
+ # Check if sample times are in the allowed range
+ time_min = float(self.cnt_normal_bit ) / self.samplerate
+ time_max = float(self.cnt_normal_bit+1) / self.samplerate
+ if ( (time_min < 0.000005) or (time_max > 0.000015) ) :
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['WARNING: The normal mode data sample time interval (%2.1fus-%2.1fus) should be inside (5.0us, 15.0us).'
+ % (time_min*1000000, time_max*1000000)]])
+ time_min = float(self.cnt_normal_presence ) / self.samplerate
+ time_max = float(self.cnt_normal_presence+1) / self.samplerate
+ if ( (time_min < 0.0000681) or (time_max > 0.000075) ) :
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['WARNING: The normal mode presence sample time interval (%2.1fus-%2.1fus) should be inside (68.1us, 75.0us).'
+ % (time_min*1000000, time_max*1000000)]])
+ time_min = float(self.cnt_overdrive_bit ) / self.samplerate
+ time_max = float(self.cnt_overdrive_bit+1) / self.samplerate
+ if ( (time_min < 0.000001) or (time_max > 0.000002) ) :
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['WARNING: The overdrive mode data sample time interval (%2.1fus-%2.1fus) should be inside (1.0us, 2.0us).'
+ % (time_min*1000000, time_max*1000000)]])
+ time_min = float(self.cnt_overdrive_presence ) / self.samplerate
+ time_max = float(self.cnt_overdrive_presence+1) / self.samplerate
+ if ( (time_min < 0.0000073) or (time_max > 0.000010) ) :
+ self.put(0, 0, self.out_ann, [ANN_LINK,
+ ['WARNING: The overdrive mode presence sample time interval (%2.1fus-%2.1fus) should be inside (7.3us, 10.0us).'
+ % (time_min*1000000, time_max*1000000)]])
- self.putx([ANN_ASCII, [chr(self.databyte)]])
- self.putx([ANN_DEC, [str(self.databyte)]])
- self.putx([ANN_HEX, [hex(self.databyte),
- hex(self.databyte)[2:]]])
- self.putx([ANN_OCT, [oct(self.databyte),
- oct(self.databyte)[2:]]])
- self.putx([ANN_BITS, [bin(self.databyte),
- bin(self.databyte)[2:]]])
+ def report(self):
+ pass
def decode(self, ss, es, data):
- for (self.samplenum, owr) in data:
-
- # First sample: Save OWR value.
- if self.oldbit == None:
- self.oldbit = owr
- continue
+ for (self.samplenum, (owr, pwr)) in data:
# Data link layer
+
+ # Clear events.
+ self.lnk_event = "NONE"
+ # State machine.
if self.lnk_state == 'WAIT FOR FALLING EDGE':
# The start of a cycle is a falling edge.
- if (old_owr == 1 and owr == 0):
- # Save the sample number where the start bit begins.
- self.lnk_start = self.samplenum
+ if (owr == 0):
+ # Save the sample number for the falling edge.
+ self.lnk_fall = self.samplenum
# Go to waiting for sample time
- self.lnk_state = 'WAIT FOR SAMPLE'
- elif self.lnk_state == 'WAIT FOR SAMPLE':
- # Data should be sample one 'time unit' after a falling edge
- if (self.samplenum == self.lnk_start + self.time_base):
+ self.lnk_state = 'WAIT FOR DATA SAMPLE'
+ elif self.lnk_state == 'WAIT FOR DATA SAMPLE':
+ # Sample data bit
+ if (self.samplenum - self.lnk_fall == self.cnt_bit[self.lnk_overdrive]):
self.lnk_bit = owr & 0x1
- self.lnk_cnt = self.lnk_cnt + 1
- self.lnk_byte = (self.lnk_byte << 1) & self.lnk_bit
- self.lnk_state = 'WAIT FOR RISING EDGE'
+ self.lnk_event = "DATA BIT"
+ if (self.lnk_bit): self.lnk_state = 'WAIT FOR FALLING EDGE'
+ else : self.lnk_state = 'WAIT FOR RISING EDGE'
+ self.put(self.lnk_fall, self.cnt_bit[self.lnk_overdrive], self.out_ann, [ANN_LINK, ['BIT: %01x' % self.lnk_bit]])
elif self.lnk_state == 'WAIT FOR RISING EDGE':
# The end of a cycle is a rising edge.
- if (old_owr == 0 and owr == 1):
- # Data bit cycle length should be between 2*T and
- if (self.samplenum < self.lnk_start + 2*self.time_base):
- if (self.lnk_cnt == 8)
- self.put(self.startsample, self.samplenum - 1, self.out_proto, ['BYTE', self.lnk_byte])
- self.lnk_cnt = 0
- if (self.samplenum == self.lnk_start + 8*self.time_base):
- self.put(self.startsample, self.samplenum - 1, self.out_proto, ['RESET'])
-
- # Go to waiting for sample time
- self.lnk_state = 'WAIT FOR SAMPLE'
+ if (owr == 1):
+ # Check if this was a reset cycle
+ if (self.samplenum - self.lnk_fall > self.cnt_normal_reset):
+ # Save the sample number for the falling edge.
+ self.lnk_rise = self.samplenum
+ # Send a reset event to the next protocol layer.
+ self.lnk_event = "RESET"
+ self.lnk_state = "WAIT FOR PRESENCE DETECT"
+ self.put(self.lnk_fall, self.lnk_rise, self.out_proto, ['RESET'])
+ self.put(self.lnk_fall, self.lnk_rise, self.out_ann, [ANN_LINK , ['RESET']])
+ self.put(self.lnk_fall, self.lnk_rise, self.out_ann, [ANN_NETWORK , ['RESET']])
+ # Reset the timer.
+ self.lnk_fall = self.samplenum
+ elif ((self.samplenum - self.lnk_fall > self.cnt_overdrive_reset) and (self.lnk_overdrive)):
+ # Save the sample number for the falling edge.
+ self.lnk_rise = self.samplenum
+ # Send a reset event to the next protocol layer.
+ self.lnk_event = "RESET"
+ self.lnk_state = "WAIT FOR PRESENCE DETECT"
+ self.put(self.lnk_fall, self.lnk_rise, self.out_proto, ['RESET OVERDRIVE'])
+ self.put(self.lnk_fall, self.lnk_rise, self.out_ann, [ANN_LINK , ['RESET OVERDRIVE']])
+ self.put(self.lnk_fall, self.lnk_rise, self.out_ann, [ANN_NETWORK , ['RESET OVERDRIVE']])
+ # Reset the timer.
+ self.lnk_fall = self.samplenum
+ # Otherwise this is assumed to be a data bit.
+ else :
+ self.lnk_state = "WAIT FOR FALLING EDGE"
+ elif self.lnk_state == 'WAIT FOR PRESENCE DETECT':
+ # Sample presence status
+ if (self.samplenum - self.lnk_rise == self.cnt_presence[self.lnk_overdrive]):
+ self.lnk_present = owr & 0x1
+ # Save the sample number for the falling edge.
+ if not (self.lnk_present) : self.lnk_fall = self.samplenum
+ # create presence detect event
+ #self.lnk_event = "PRESENCE DETECT"
+ if (self.lnk_present) : self.lnk_state = 'WAIT FOR FALLING EDGE'
+ else : self.lnk_state = 'WAIT FOR RISING EDGE'
+ present_str = "False" if self.lnk_present else "True"
+ self.put(self.samplenum, 0, self.out_ann, [ANN_LINK , ['PRESENCE: ' + present_str]])
+ self.put(self.samplenum, 0, self.out_ann, [ANN_NETWORK, ['PRESENCE: ' + present_str]])
+ else:
+ raise Exception('Invalid lnk_state: %d' % self.lnk_state)
+
+ # Network layer
- elif self.state_lnk == 'GET DATA BITS' : self.get_data_bits(owr)
- else : raise Exception('Invalid state: %d' % self.state)
+ # State machine.
+ if (self.lnk_event == "RESET"):
+ self.net_state = "COMMAND"
+ self.net_search = "P"
+ self.net_cnt = 0
+ elif (self.net_state == "IDLE"):
+ pass
+ elif (self.net_state == "COMMAND"):
+ # Receiving and decoding a ROM command
+ if (self.onewire_collect(8)):
+ self.put(self.net_beg, self.net_len, self.out_ann, [ANN_NETWORK,
+ ['ROM COMMAND: 0x%02x \'%s\'' % (self.net_data, rom_command[self.net_data])]])
+ if (self.net_data == 0x33): # READ ROM
+ self.net_state = "GET ROM"
+ elif (self.net_data == 0x0f): # CONDITIONAL READ ROM
+ self.net_state = "GET ROM"
+ elif (self.net_data == 0xcc): # SKIP ROM
+ self.net_state = "TRANSPORT"
+ elif (self.net_data == 0x55): # MATCH ROM
+ self.net_state = "GET ROM"
+ elif (self.net_data == 0xf0): # SEARCH ROM
+ self.net_state = "SEARCH ROM"
+ elif (self.net_data == 0xec): # CONDITIONAL SEARCH ROM
+ self.net_state = "SEARCH ROM"
+ elif (self.net_data == 0x3c): # OVERDRIVE SKIP ROM
+ self.lnk_overdrive = 1
+ self.net_state = "TRANSPORT"
+ elif (self.net_data == 0x69): # OVERDRIVE MATCH ROM
+ self.lnk_overdrive = 1
+ self.net_state = "GET ROM"
+ elif (self.net_state == "GET ROM"):
+ # A 64 bit device address is selected
+ # family code (1B) + serial number (6B) + CRC (1B)
+ if (self.onewire_collect(64)):
+ self.net_rom = self.net_data & 0xffffffffffffffff
+ self.put(self.net_beg, self.net_len, self.out_ann, [ANN_NETWORK, ['ROM: 0x%016x' % self.net_rom]])
+ self.net_state = "TRANSPORT"
+ elif (self.net_state == "SEARCH ROM"):
+ # A 64 bit device address is searched for
+ # family code (1B) + serial number (6B) + CRC (1B)
+ if (self.onewire_search(64)):
+ self.net_rom = self.net_data & 0xffffffffffffffff
+ self.put(self.net_beg, self.net_len, self.out_ann, [ANN_NETWORK, ['ROM: 0x%016x' % self.net_rom]])
+ self.net_state = "TRANSPORT"
+ elif (self.net_state == "TRANSPORT"):
+ # The transport layer is handled in byte sized units
+ if (self.onewire_collect(8)):
+ self.put(self.net_beg, self.net_len, self.out_ann, [ANN_NETWORK , ['TRANSPORT: 0x%02x' % self.net_data]])
+ self.put(self.net_beg, self.net_len, self.out_ann, [ANN_TRANSPORT, ['TRANSPORT: 0x%02x' % self.net_data]])
+ self.put(self.net_beg, self.net_len, self.out_proto, ['transfer', self.net_data])
+ # TODO: Sending translort layer data to 1-Wire device models
+ else:
+ raise Exception('Invalid net_state: %s' % self.net_state)
- # Save current RX/TX values for the next round.
- self.oldbit = owr
+ # Link/Network layer data collector
+ def onewire_collect (self, length):
+ if (self.lnk_event == "DATA BIT"):
+ # Storing the sampe this sequence begins with
+ if (self.net_cnt == 1):
+ self.net_beg = self.lnk_fall
+ self.net_data = self.net_data & ~(1 << self.net_cnt) | (self.lnk_bit << self.net_cnt)
+ self.net_cnt = self.net_cnt + 1
+ # Storing the sampe this sequence ends with
+ # In case the full length of the sequence is received, return 1
+ if (self.net_cnt == length):
+ self.net_end = self.lnk_fall + self.cnt_slot[self.lnk_overdrive]
+ self.net_len = self.net_end - self.net_beg
+ self.net_data = self.net_data & ((1<<length)-1)
+ self.net_cnt = 0
+ return (1)
+ else:
+ return (0)
+ else:
+ return (0)
+
+ # Link/Network layer search collector
+ def onewire_search (self, length):
+ if (self.lnk_event == "DATA BIT"):
+ # Storing the sampe this sequence begins with
+ if ((self.net_cnt == 0) and (self.net_search == "P")):
+ self.net_beg = self.lnk_fall
+ # Master receives an original address bit
+ if (self.net_search == "P"):
+ self.net_data_p = self.net_data_p & ~(1 << self.net_cnt) | (self.lnk_bit << self.net_cnt)
+ self.net_search = "N"
+ # Master receives a complemented address bit
+ elif (self.net_search == "N"):
+ self.net_data_n = self.net_data_n & ~(1 << self.net_cnt) | (self.lnk_bit << self.net_cnt)
+ self.net_search = "D"
+ # Master transmits an address bit
+ elif (self.net_search == "D"):
+ self.net_data = self.net_data & ~(1 << self.net_cnt) | (self.lnk_bit << self.net_cnt)
+ self.net_search = "P"
+ self.net_cnt = self.net_cnt + 1
+ # Storing the sampe this sequence ends with
+ # In case the full length of the sequence is received, return 1
+ if (self.net_cnt == length):
+ self.net_end = self.lnk_fall + self.cnt_slot[self.lnk_overdrive]
+ self.net_len = self.net_end - self.net_beg
+ self.net_data_p = self.net_data_p & ((1<<length)-1)
+ self.net_data_n = self.net_data_n & ((1<<length)-1)
+ self.net_data = self.net_data & ((1<<length)-1)
+ self.net_search = "P"
+ self.net_cnt = 0
+ return (1)
+ else:
+ return (0)
+ else:
+ return (0)