## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
##
-def decode(inbuf):
- """Counts the low->high and high->low transitions in the specified
- channel(s) of the signal."""
-
- outbuf = ''
-
- # FIXME: Get the data in the correct format in the first place.
- inbuf = [ord(x) for x in inbuf]
-
- # TODO: Don't hardcode the number of channels.
- channels = 8
-
- oldbit = [0] * channels
- transitions = [0] * channels
- rising = [0] * channels
- falling = [0] * channels
-
- # Initial values.
- oldbyte = inbuf[0]
- for i in range(channels):
- oldbit[i] = (oldbyte & (1 << i)) >> i
-
- # Loop over all samples.
- # TODO: Handle LAs with more/less than 8 channels.
- for s in inbuf:
- # Optimization: Skip identical bytes (no transitions).
- if oldbyte == s:
- continue
- for i in range(channels):
- curbit = (s & (1 << i)) >> i
- # Optimization: Skip identical bits (no transitions).
- if oldbit[i] == curbit:
- continue
- elif (oldbit[i] == 0 and curbit == 1):
- rising[i] += 1
- elif (oldbit[i] == 1 and curbit == 0):
- falling[i] += 1
- oldbit[i] = curbit
- oldbyte = s
-
- # Total number of transitions is the sum of rising and falling edges.
- for i in range(channels):
- transitions[i] = rising[i] + falling[i]
-
- outbuf += "Rising edges: "
- for i in range(channels):
- outbuf += str(rising[i]) + " "
- outbuf += "\nFalling edges: "
- for i in range(channels):
- outbuf += str(falling[i]) + " "
- outbuf += "\nTransitions: "
- for i in range(channels):
- outbuf += str(transitions[i]) + " "
- outbuf += "\n"
-
- return outbuf
-
-def register():
- return {
- 'id': 'transitioncounter',
- 'name': 'Transition counter',
- 'desc': 'Count rising/falling edges',
- 'inputformats': ['raw'],
- 'signalnames': {}, # FIXME
- 'outputformats': ['transitioncounts'],
- }
-
-# Use psyco (if available) as it results in huge performance improvements.
-try:
- import psyco
- psyco.bind(decode)
-except ImportError:
- pass
+import sigrok
+
+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
+
+def sampleiter(data, unitsize):
+ for i in range(0, len(data), unitsize):
+ yield(Sample(data[i:i+unitsize]))
+
+class Decoder(sigrok.Decoder):
+ id = 'transitioncounter'
+ name = 'Transition counter'
+ longname = '...'
+ desc = 'Counts rising/falling edges in the signal.'
+ longdesc = '...'
+ author = 'Uwe Hermann'
+ email = 'uwe@hermann-uwe.de'
+ license = 'gplv2+'
+ inputs = ['logic']
+ outputs = ['transitioncounts']
+ probes = {}
+ options = {}
+
+ def __init__(self, **kwargs):
+ self.probes = Decoder.probes.copy()
+
+ # TODO: Don't hardcode the number of channels.
+ self.channels = 8
+
+ self.lastsample = None
+ self.oldbit = [0] * self.channels
+ self.transitions = [0] * self.channels
+ self.rising = [0] * self.channels
+ self.falling = [0] * self.channels
+
+ def start(self, metadata):
+ self.unitsize = metadata['unitsize']
+
+ def report(self):
+ pass
+
+ def decode(self, data):
+ """Counts the low->high and high->low transitions in the specified
+ channel(s) of the signal."""
+
+ # 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)
+
+ # Optimization: Skip identical samples (no transitions).
+ if self.lastsample == s:
+ continue
+
+ # Upon the first sample, store the initial values.
+ if self.lastsample == None:
+ self.lastsample = s
+ for i in range(self.channels):
+ self.oldbit[i] = (self.lastsample & (1 << i)) >> i
+
+ # Iterate over all channels/probes in this sample.
+ # Count rising and falling edges for each channel.
+ for i in range(self.channels):
+ curbit = (s & (1 << i)) >> i
+ # Optimization: Skip identical bits (no transitions).
+ if self.oldbit[i] == curbit:
+ continue
+ elif (self.oldbit[i] == 0 and curbit == 1):
+ self.rising[i] += 1
+ elif (self.oldbit[i] == 1 and curbit == 0):
+ self.falling[i] += 1
+ self.oldbit[i] = curbit
+
+ # Save the current sample as 'lastsample' for the next round.
+ self.lastsample = s
+
+ # Total number of transitions = rising + falling edges.
+ for i in range(self.channels):
+ self.transitions[i] = self.rising[i] + self.falling[i]
+
+ # TODO: Which output format?
+ # TODO: How to only output something after the last chunk of data?
+ outdata = []
+ for i in range(self.channels):
+ outdata += [[self.transitions[i], self.rising[i], self.falling[i]]]
+ self.put(outdata)