DSView/libsigrokdecode4DSL/decoders/graycode/pd.py

##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2017 Christoph Rackwitz <christoph.rackwitz@rwth-aachen.de>
## Copyright (C) 2019 DreamSourceLab <support@dreamsourcelab.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 math
import sigrokdecode as srd
from collections import deque
from common.srdhelper import bitpack, bitunpack

def gray_encode(plain):
    return plain & (plain >> 1)

def gray_decode(gray):
    temp = gray
    temp ^= (temp >> 8)
    temp ^= (temp >> 4)
    temp ^= (temp >> 2)
    temp ^= (temp >> 1)
    return temp

def prefix_fmt(value, emin=None):
    sgn = (value > 0) - (value < 0)
    value = abs(value)
    p = math.log10(value) if value else 0
    value = sgn * math.floor(value * 10**int(3 - p)) * 10**-int(3 - p)
    e = p // 3 * 3
    if emin is not None and e < emin:
        e = emin
    value *= 10**-e
    p -= e
    decimals = 2 - int(p)
    prefixes = {-9: 'n', -6: 'µ', -3: 'm', 0: '', 3: 'k', 6: 'M', 9: 'G'}
    return '{0:.{1}f} {2}'.format(value, decimals, prefixes[e])

class ChannelMapError(Exception):
    pass

class Value:
    def __init__(self, onchange):
        self.onchange = onchange
        self.timestamp = None
        self.value = None

    def get(self):
        return self.value

    def set(self, timestamp, newval):
        if newval != self.value:
            if self.value is not None:
                self.onchange(self.timestamp, self.value, timestamp, newval)

            self.value = newval
            self.timestamp = timestamp
        elif False:
            if self.value is not None:
                self.onchange(self.timestamp, self.value, timestamp, newval)

MAX_CHANNELS = 8 # 10 channels causes some weird problems...

class Decoder(srd.Decoder):
    api_version = 3
    id = 'graycode'
    name = 'Gray code'
    longname = 'Gray code and rotary encoder'
    desc = 'Accumulate rotary encoder increments, provide statistics.'
    license = 'gplv2+'
    inputs = ['logic']
    outputs = []
    tags = ['Encoding']
    optional_channels = tuple(
        {'id': 'd{}'.format(i), 'name': 'D{}'.format(i), 'desc': 'Data line {}'.format(i)}
        for i in range(MAX_CHANNELS)
    )
    options = (
        {'id': 'edges', 'desc': 'Edges per rotation', 'default': 0},
        {'id': 'avg_period', 'desc': 'Averaging period', 'default': 10},
    )
    annotations = (
        ('phase', 'Phase'),
        ('increment', 'Increment'),
        ('count', 'Count'),
        ('turns', 'Turns'),
        ('interval', 'Interval'),
        ('average', 'Average'),
        ('rpm', 'Rate'),
    )
    annotation_rows = tuple((u, v, (i,)) for i, (u, v) in enumerate(annotations))

    def __init__(self):
        self.reset()

    def reset(self):
        self.num_channels = 0
        self.samplerate = None
        self.last_n = deque()

        self.phase = Value(self.on_phase)
        self.increment = Value(self.on_increment)
        self.count = Value(self.on_count)
        self.turns = Value(self.on_turns)

    def on_phase(self, told, vold, tnew, vnew):
        self.put(told, tnew, self.out_ann, [0, ['{}'.format(vold)]])

    def on_increment(self, told, vold, tnew, vnew):
        if vold == 0:
            message = '0'
        elif abs(vold) == self.ENCODER_STEPS // 2:
            message = '±π'
        else:
            message = '{:+d}'.format(vold)
        self.put(told, tnew, self.out_ann, [1, [message]])

    def on_count(self, told, vold, tnew, vnew):
        self.put(told, tnew, self.out_ann, [2, ['{}'.format(vold)]])

    def on_turns(self, told, vold, tnew, vnew):
        self.put(told, tnew, self.out_ann, [3, ['{:+d}'.format(vold)]])

    def metadata(self, key, value):
        if key == srd.SRD_CONF_SAMPLERATE:
            self.samplerate = value

    def start(self):
        self.out_ann = self.register(srd.OUTPUT_ANN)

    def decode(self):
        chmask = [self.has_channel(i) for i in range(MAX_CHANNELS)]
        self.num_channels = sum(chmask)
        if chmask != [i < self.num_channels for i in range(MAX_CHANNELS)]:
            raise ChannelMapError('Assigned channels need to be contiguous')

        self.ENCODER_STEPS = 1 << self.num_channels

        (d0, d1, d2, d3, d4, d5, d6, d7) = self.wait()
        startbits = (d0, d1, d2, d3, d4, d5, d6, d7)
        curtime = self.samplenum

        self.turns.set(self.samplenum, 0)
        self.count.set(self.samplenum, 0)
        self.phase.set(self.samplenum, gray_decode(bitpack(startbits[:self.num_channels])))

        while True:
            prevtime = curtime
            (d0, d1, d2, d3, d4, d5, d6, d7) = self.wait([{i: 'e'} for i in range(self.num_channels)])
            bits = (d0, d1, d2, d3, d4, d5, d6, d7)
            curtime = self.samplenum

            oldcount = self.count.get()
            oldphase = self.phase.get()

            newphase = gray_decode(bitpack(bits[:self.num_channels]))
            self.phase.set(self.samplenum, newphase)

            phasedelta_raw = (newphase - oldphase + (self.ENCODER_STEPS // 2 - 1)) % self.ENCODER_STEPS - (self.ENCODER_STEPS // 2 - 1)
            phasedelta = phasedelta_raw
            self.increment.set(self.samplenum, phasedelta)
            if abs(phasedelta) == self.ENCODER_STEPS // 2:
                phasedelta = 0

            self.count.set(self.samplenum, self.count.get() + phasedelta)

            if self.options['edges']:
                self.turns.set(self.samplenum, self.count.get() // self.options['edges'])

            if self.samplerate:
                period = (curtime - prevtime) / self.samplerate
                freq = abs(phasedelta_raw) / period

                self.put(prevtime, curtime, self.out_ann, [4, [
                    '{}s, {}Hz'.format(prefix_fmt(period), prefix_fmt(freq))]])

                if self.options['avg_period']:
                    self.last_n.append((abs(phasedelta_raw), period))
                    if len(self.last_n) > self.options['avg_period']:
                        self.last_n.popleft()

                    avg_period = sum(v for u, v in self.last_n) / (sum(u for u, v in self.last_n) or 1)
                    self.put(prevtime, curtime, self.out_ann, [5, [
                        '{}s, {}Hz'.format(prefix_fmt(avg_period),
                            prefix_fmt(1 / avg_period))]])

                if self.options['edges']:
                    self.put(prevtime, curtime, self.out_ann, [6, ['{}rpm'.format(prefix_fmt(60 * freq / self.options['edges'], emin=0))]])
Bump version to v1.00 2019-09-09 00:07:19 -07:00			`##`
			`## This file is part of the libsigrokdecode project.`
			`##`
			`## Copyright (C) 2017 Christoph Rackwitz <christoph.rackwitz@rwth-aachen.de>`
			`## Copyright (C) 2019 DreamSourceLab <support@dreamsourcelab.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 math`
			`import sigrokdecode as srd`
			`from collections import deque`
			`from common.srdhelper import bitpack, bitunpack`

			`def gray_encode(plain):`
			`return plain & (plain >> 1)`

			`def gray_decode(gray):`
			`temp = gray`
			`temp ^= (temp >> 8)`
			`temp ^= (temp >> 4)`
			`temp ^= (temp >> 2)`
			`temp ^= (temp >> 1)`
			`return temp`

			`def prefix_fmt(value, emin=None):`
			`sgn = (value > 0) - (value < 0)`
			`value = abs(value)`
			`p = math.log10(value) if value else 0`
			`value = sgn * math.floor(value * 10*int(3 - p)) 10**-int(3 - p)`
			`e = p // 3 * 3`
			`if emin is not None and e < emin:`
			`e = emin`
			`value = 10*-e`
			`p -= e`
			`decimals = 2 - int(p)`
			`prefixes = {-9: 'n', -6: 'µ', -3: 'm', 0: '', 3: 'k', 6: 'M', 9: 'G'}`
			`return '{0:.{1}f} {2}'.format(value, decimals, prefixes[e])`

			`class ChannelMapError(Exception):`
			`pass`

			`class Value:`
			`def __init__(self, onchange):`
			`self.onchange = onchange`
			`self.timestamp = None`
			`self.value = None`

			`def get(self):`
			`return self.value`

			`def set(self, timestamp, newval):`
			`if newval != self.value:`
			`if self.value is not None:`
			`self.onchange(self.timestamp, self.value, timestamp, newval)`

			`self.value = newval`
			`self.timestamp = timestamp`
			`elif False:`
			`if self.value is not None:`
			`self.onchange(self.timestamp, self.value, timestamp, newval)`

			`MAX_CHANNELS = 8 # 10 channels causes some weird problems...`

			`class Decoder(srd.Decoder):`
			`api_version = 3`
			`id = 'graycode'`
			`name = 'Gray code'`
			`longname = 'Gray code and rotary encoder'`
			`desc = 'Accumulate rotary encoder increments, provide statistics.'`
			`license = 'gplv2+'`
			`inputs = ['logic']`
			`outputs = []`
			`tags = ['Encoding']`
			`optional_channels = tuple(`
			`{'id': 'd{}'.format(i), 'name': 'D{}'.format(i), 'desc': 'Data line {}'.format(i)}`
			`for i in range(MAX_CHANNELS)`
			`)`
			`options = (`
			`{'id': 'edges', 'desc': 'Edges per rotation', 'default': 0},`
			`{'id': 'avg_period', 'desc': 'Averaging period', 'default': 10},`
			`)`
			`annotations = (`
			`('phase', 'Phase'),`
			`('increment', 'Increment'),`
			`('count', 'Count'),`
			`('turns', 'Turns'),`
			`('interval', 'Interval'),`
			`('average', 'Average'),`
			`('rpm', 'Rate'),`
			`)`
			`annotation_rows = tuple((u, v, (i,)) for i, (u, v) in enumerate(annotations))`

			`def __init__(self):`
			`self.reset()`

			`def reset(self):`
			`self.num_channels = 0`
			`self.samplerate = None`
			`self.last_n = deque()`

			`self.phase = Value(self.on_phase)`
			`self.increment = Value(self.on_increment)`
			`self.count = Value(self.on_count)`
			`self.turns = Value(self.on_turns)`

			`def on_phase(self, told, vold, tnew, vnew):`
			`self.put(told, tnew, self.out_ann, [0, ['{}'.format(vold)]])`

			`def on_increment(self, told, vold, tnew, vnew):`
			`if vold == 0:`
			`message = '0'`
			`elif abs(vold) == self.ENCODER_STEPS // 2:`
			`message = '±π'`
			`else:`
			`message = '{:+d}'.format(vold)`
			`self.put(told, tnew, self.out_ann, [1, [message]])`

			`def on_count(self, told, vold, tnew, vnew):`
			`self.put(told, tnew, self.out_ann, [2, ['{}'.format(vold)]])`

			`def on_turns(self, told, vold, tnew, vnew):`
			`self.put(told, tnew, self.out_ann, [3, ['{:+d}'.format(vold)]])`

			`def metadata(self, key, value):`
			`if key == srd.SRD_CONF_SAMPLERATE:`
			`self.samplerate = value`

			`def start(self):`
			`self.out_ann = self.register(srd.OUTPUT_ANN)`

			`def decode(self):`
			`chmask = [self.has_channel(i) for i in range(MAX_CHANNELS)]`
			`self.num_channels = sum(chmask)`
			`if chmask != [i < self.num_channels for i in range(MAX_CHANNELS)]:`
			`raise ChannelMapError('Assigned channels need to be contiguous')`

			`self.ENCODER_STEPS = 1 << self.num_channels`

			`(d0, d1, d2, d3, d4, d5, d6, d7) = self.wait()`
			`startbits = (d0, d1, d2, d3, d4, d5, d6, d7)`
			`curtime = self.samplenum`

			`self.turns.set(self.samplenum, 0)`
			`self.count.set(self.samplenum, 0)`
			`self.phase.set(self.samplenum, gray_decode(bitpack(startbits[:self.num_channels])))`

			`while True:`
			`prevtime = curtime`
			`(d0, d1, d2, d3, d4, d5, d6, d7) = self.wait([{i: 'e'} for i in range(self.num_channels)])`
			`bits = (d0, d1, d2, d3, d4, d5, d6, d7)`
			`curtime = self.samplenum`

			`oldcount = self.count.get()`
			`oldphase = self.phase.get()`

			`newphase = gray_decode(bitpack(bits[:self.num_channels]))`
			`self.phase.set(self.samplenum, newphase)`

			`phasedelta_raw = (newphase - oldphase + (self.ENCODER_STEPS // 2 - 1)) % self.ENCODER_STEPS - (self.ENCODER_STEPS // 2 - 1)`
			`phasedelta = phasedelta_raw`
			`self.increment.set(self.samplenum, phasedelta)`
			`if abs(phasedelta) == self.ENCODER_STEPS // 2:`
			`phasedelta = 0`

			`self.count.set(self.samplenum, self.count.get() + phasedelta)`

			`if self.options['edges']:`
			`self.turns.set(self.samplenum, self.count.get() // self.options['edges'])`

			`if self.samplerate:`
			`period = (curtime - prevtime) / self.samplerate`
			`freq = abs(phasedelta_raw) / period`

			`self.put(prevtime, curtime, self.out_ann, [4, [`
			`'{}s, {}Hz'.format(prefix_fmt(period), prefix_fmt(freq))]])`

			`if self.options['avg_period']:`
			`self.last_n.append((abs(phasedelta_raw), period))`
			`if len(self.last_n) > self.options['avg_period']:`
			`self.last_n.popleft()`

			`avg_period = sum(v for u, v in self.last_n) / (sum(u for u, v in self.last_n) or 1)`
			`self.put(prevtime, curtime, self.out_ann, [5, [`
			`'{}s, {}Hz'.format(prefix_fmt(avg_period),`
			`prefix_fmt(1 / avg_period))]])`

			`if self.options['edges']:`
			`self.put(prevtime, curtime, self.out_ann, [6, ['{}rpm'.format(prefix_fmt(60 * freq / self.options['edges'], emin=0))]])`