def parser(args, **kwargs):
token_sep = re.compile('(?:([{}])\s*|\s+)'.format(''.join(decorations.keys())))
parsers = [ split_parser(token_sep, compact=False) ]
fields = list(starmap(parser_from_header, enumerate(args.header))) # starmap(fn, iterable) ~ [ fn(*args) for args in iterable ]
parsers.append(field_parser(fields))
parsers.append(lambda m: filter(lambda n: n.unit, m)) # get rid of mesaurements without unit set, in this case, the time field
parsers.reverse()
return compose(*parsers)
result = map(fn, data)
logger.log(logging.DEBUG, 'result: {}'.format(result))
return result
return inner
# 0R5,Th=25.4242C,Vh=12.4242N,Vs=15.4242V
parse_match = re.compile(r'^0R[1-3],(.*)$')
# Th=25.4242C,Vh=12.4242N,Vs=15.4242V
parsers = [split_parser(',')]
# [ 'Th=25.4242C', 'Vh=12.4242N', 'Vs=15.4242V' ]
value_sep = re.compile(r'(?:=|([a-zA-Z/]+))') # split on a single , or = and strings of one or more letters. group the latter.
# [ '', 'Th', '', None, '25.4242', 'C',
parsers.append(map_parser(split_parser(value_sep)))
# [ [ 'Th', '25.4242', 'C' ], [ 'Vh', '12.4242', 'N' ], [ 'Vs', '15.4242', 'V' ] ]
fields = [ (ig_float(1), metric_getter(0), unit_getter(0,2)) ]
parsers.append(map_parser(field_parser(fields, container=False)))
# [ [measurement], [measurement], [measurement] ]
parsers.append(flatten)
parsers.reverse()
def parser(args, **kwargs):
return { parse_match: compose(*parsers) }
class WeatherStation(Instrument):
__name__ = 'weather_station'
## let's just use the output of the sensor to determine metrics: one parser to rule them all.
parsers = parser([])
def start(self):
pass
return inner
# 0R5,Th=25.4242C,Vh=12.4242N,Vs=15.4242V
parse_match = re.compile(r'^0R[1-3],(.*)$')
# Th=25.4242C,Vh=12.4242N,Vs=15.4242V
parsers = [split_parser(',')]
# [ 'Th=25.4242C', 'Vh=12.4242N', 'Vs=15.4242V' ]
value_sep = re.compile(
r'(?:=|([a-zA-Z/]+))'
) # split on a single , or = and strings of one or more letters. group the latter.
# [ '', 'Th', '', None, '25.4242', 'C',
parsers.append(map_parser(split_parser(value_sep)))
# [ [ 'Th', '25.4242', 'C' ], [ 'Vh', '12.4242', 'N' ], [ 'Vs', '15.4242', 'V' ] ]
fields = [(ig_float(1), metric_getter(0), unit_getter(0, 2))]
parsers.append(map_parser(field_parser(fields, container=False)))
# [ [measurement], [measurement], [measurement] ]
parsers.append(flatten)
parsers.reverse()
def parser(args, **kwargs):
return {parse_match: compose(*parsers)}
class WeatherStation(Instrument):
__name__ = 'weather_station'
## let's just use the output of the sensor to determine metrics: one parser to rule them all.
parsers = parser([])
def start(self):
(ig_float(8), ('beam', 'signal strength 3'), 'counts'),
# (float, 'pings', 'good', None),
# (stderr_float, 'package', 'heading', None),
# (stderr_float, 'package', 'pitch', None),
# (stderr_float, 'package', 'roll', None),
(ig_float(16), ('water', 'temperature'), 'C'),
# (stderr_float, 'water', 'pressure', None),
(ig_float(19), ('battery', 'voltage'), 'V'),
(ig_float(20), ('beam', 'vertical sample start'), 'm'),
(ig_float(21), ('beam', 'vertical sample end'), 'm'),
(ig_float(22), ('beam', 'noise level 1'), 'counts'),
(ig_float(23), ('beam', 'noise level 2'), 'counts'),
(ig_float(24), ('beam', 'noise level 3'), 'counts'),
]
start_parsers.append(field_parser(fields))
# Cell parsing
# an integer, followed by 4 floating points, followed by 2 integers
cell_re = re.compile(
r'^\s?([1-9][0-9]?\s+(?:-?[0-9]+(?:\.[0-9]+)?\s+){4}[1-9][0-9]{0,2}\s+[1-9][0-9]{0,2})\s*$'
)
# split by whitespace
cell_parsers = [split_parser()]
def cell_offset(idx):
return lambda data: ('cell', data[idx])
(ig_float(8), ("beam", "signal strength 3"), "counts"),
# (float, 'pings', 'good', None),
# (stderr_float, 'package', 'heading', None),
# (stderr_float, 'package', 'pitch', None),
# (stderr_float, 'package', 'roll', None),
(ig_float(16), ("water", "temperature"), "C"),
# (stderr_float, 'water', 'pressure', None),
(ig_float(19), ("battery", "voltage"), "V"),
(ig_float(20), ("beam", "vertical sample start"), "m"),
(ig_float(21), ("beam", "vertical sample end"), "m"),
(ig_float(22), ("beam", "noise level 1"), "counts"),
(ig_float(23), ("beam", "noise level 2"), "counts"),
(ig_float(24), ("beam", "noise level 3"), "counts"),
]
start_parsers.append(field_parser(fields))
# Cell parsing
# an integer, followed by 4 floating points, followed by 2 integers
cell_re = re.compile(r"^\s?([1-9][0-9]?\s+(?:-?[0-9]+(?:\.[0-9]+)?\s+){4}[1-9][0-9]{0,2}\s+[1-9][0-9]{0,2})\s*$")
# split by whitespace
cell_parsers = [split_parser()]
def cell_offset(idx):
return lambda data: ("cell", data[idx])
co = cell_offset(0)
