## 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, write to the Free Software
-## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
+## along with this program; if not, see <http://www.gnu.org/licenses/>.
##
import sigrokdecode as srd
pass
class Decoder(srd.Decoder):
- api_version = 2
+ api_version = 3
id = 'jitter'
name = 'Jitter'
longname = 'Timing jitter calculation'
desc = 'Retrieves the timing jitter between two digital signals.'
license = 'gplv2+'
inputs = ['logic']
- outputs = ['jitter']
+ outputs = []
+ tags = ['Clock/timing', 'Util']
channels = (
{'id': 'clk', 'name': 'Clock', 'desc': 'Clock reference channel'},
{'id': 'sig', 'name': 'Resulting signal', 'desc': 'Resulting signal controlled by the clock'},
('clk_missed', 'Clock missed', (1,)),
('sig_missed', 'Signal missed', (2,)),
)
+ binary = (
+ ('ascii-float', 'Jitter values as newline-separated ASCII floats'),
+ )
+
+ def __init__(self):
+ self.reset()
- def __init__(self, **kwargs):
+ def reset(self):
self.state = 'CLK'
self.samplerate = None
- self.oldpin = None
- self.oldclk = self.oldsig = None
+ self.oldclk, self.oldsig = 0, 0
self.clk_start = None
self.sig_start = None
self.clk_missed = 0
self.clk_edge = edge_detector[self.options['clk_polarity']]
self.sig_edge = edge_detector[self.options['sig_polarity']]
self.out_ann = self.register(srd.OUTPUT_ANN)
+ self.out_binary = self.register(srd.OUTPUT_BINARY)
self.out_clk_missed = self.register(srd.OUTPUT_META,
meta=(int, 'Clock missed', 'Clock transition missed'))
self.out_sig_missed = self.register(srd.OUTPUT_META,
def putx(self, delta):
# Adjust granularity.
if delta == 0 or delta >= 1:
- delta_s = u"%us" % (delta)
+ delta_s = '%.1fs' % (delta)
elif delta <= 1e-12:
- delta_s = u"%.1ffs" % (delta * 1e15)
+ delta_s = '%.1ffs' % (delta * 1e15)
elif delta <= 1e-9:
- delta_s = u"%.1fps" % (delta * 1e12)
+ delta_s = '%.1fps' % (delta * 1e12)
elif delta <= 1e-6:
- delta_s = u"%.1fns" % (delta * 1e9)
+ delta_s = '%.1fns' % (delta * 1e9)
elif delta <= 1e-3:
- delta_s = u"%.1fμs" % (delta * 1e6)
+ delta_s = '%.1fμs' % (delta * 1e6)
else:
- delta_s = u"%.1fms" % (delta * 1e3)
+ delta_s = '%.1fms' % (delta * 1e3)
self.put(self.clk_start, self.sig_start, self.out_ann, [0, [delta_s]])
+ # Helper function for ASCII float jitter values (one value per line).
+ def putb(self, delta):
+ if delta is None:
+ return
+ # Format the delta to an ASCII float value terminated by a newline.
+ x = str(delta) + '\n'
+ self.put(self.clk_start, self.sig_start, self.out_binary,
+ [0, x.encode('UTF-8')])
+
# Helper function for missed clock and signal annotations.
def putm(self, data):
self.put(self.samplenum, self.samplenum, self.out_ann, data)
- def decode(self, ss, es, data):
+ def handle_clk(self, clk, sig):
+ if self.clk_start == self.samplenum:
+ # Clock transition already treated.
+ # We have done everything we can with this sample.
+ return True
+
+ if self.clk_edge(self.oldclk, clk):
+ # Clock edge found.
+ # We note the sample and move to the next state.
+ self.clk_start = self.samplenum
+ self.state = 'SIG'
+ return False
+ else:
+ if self.sig_start is not None \
+ and self.sig_start != self.samplenum \
+ and self.sig_edge(self.oldsig, sig):
+ # If any transition in the resulting signal
+ # occurs while we are waiting for a clock,
+ # we increase the missed signal counter.
+ self.sig_missed += 1
+ self.put(self.samplenum, self.samplenum, self.out_sig_missed, self.sig_missed)
+ self.putm([2, ['Missed signal', 'MS']])
+ # No clock edge found, we have done everything we
+ # can with this sample.
+ return True
+
+ def handle_sig(self, clk, sig):
+ if self.sig_start == self.samplenum:
+ # Signal transition already treated.
+ # We have done everything we can with this sample.
+ return True
+
+ if self.sig_edge(self.oldsig, sig):
+ # Signal edge found.
+ # We note the sample, calculate the jitter
+ # and move to the next state.
+ self.sig_start = self.samplenum
+ self.state = 'CLK'
+ # Calculate and report the timing jitter.
+ delta = (self.sig_start - self.clk_start) / self.samplerate
+ self.putx(delta)
+ self.putb(delta)
+ return False
+ else:
+ if self.clk_start != self.samplenum \
+ and self.clk_edge(self.oldclk, clk):
+ # If any transition in the clock signal
+ # occurs while we are waiting for a resulting
+ # signal, we increase the missed clock counter.
+ self.clk_missed += 1
+ self.put(self.samplenum, self.samplenum, self.out_clk_missed, self.clk_missed)
+ self.putm([1, ['Missed clock', 'MC']])
+ # No resulting signal edge found, we have done
+ # everything we can with this sample.
+ return True
+
+ def decode(self):
if not self.samplerate:
raise SamplerateError('Cannot decode without samplerate.')
-
- for (self.samplenum, pins) in data:
- # We are only interested in transitions.
- if self.oldpin == pins:
- continue
-
- self.oldpin, (clk, sig) = pins, pins
-
- if self.oldclk is None and self.oldsig is None:
- self.oldclk, self.oldsig = clk, sig
+ while True:
+ # Wait for a transition on CLK and/or SIG.
+ clk, sig = self.wait([{0: 'e'}, {1: 'e'}])
# State machine:
# For each sample we can move 2 steps forward in the state machine.
while True:
-
# Clock state has the lead.
if self.state == 'CLK':
- if self.clk_start == self.samplenum:
- # Clock transition already treated.
- # We have done everything we can with this sample.
+ if self.handle_clk(clk, sig):
break
- else:
- if self.clk_edge(self.oldclk, clk) is True:
- # Clock edge found.
- # We note the sample and move to the next state.
- self.clk_start = self.samplenum
- self.state = 'SIG'
- else:
- if self.sig_start is not None \
- and self.sig_start != self.samplenum \
- and self.sig_edge(self.oldsig, sig) is True:
- # If any transition in the resulting signal
- # occurs while we are waiting for a clock,
- # we increase the missed signal counter.
- self.sig_missed += 1
- self.put(ss, self.samplenum, self.out_sig_missed, self.sig_missed)
- self.putm([2, ['Missed signal', 'MS']])
- # No clock edge found, we have done everything we
- # can with this sample.
- break
if self.state == 'SIG':
- if self.sig_start == self.samplenum:
- # Signal transition already treated.
- # We have done everything we can with this sample.
+ if self.handle_sig(clk, sig):
break
- else:
- if self.sig_edge(self.oldsig, sig) is True:
- # Signal edge found.
- # We note the sample, calculate the jitter
- # and move to the next state.
- self.sig_start = self.samplenum
- self.state = 'CLK'
- # Calculate and report the timing jitter.
- self.putx((self.sig_start - self.clk_start) / self.samplerate)
- else:
- if self.clk_start != self.samplenum \
- and self.clk_edge(self.oldclk, clk) is True:
- # If any transition in the clock signal
- # occurs while we are waiting for a resulting
- # signal, we increase the missed clock counter.
- self.clk_missed += 1
- self.put(ss, self.samplenum, self.out_clk_missed, self.clk_missed)
- self.putm([1, ['Missed clock', 'MC']])
- # No resulting signal edge found, we have done
- # everything we can with this sample.
- break
# Save current CLK/SIG values for the next round.
self.oldclk, self.oldsig = clk, sig