## along with this program; if not, see <http://www.gnu.org/licenses/>.
##
+# Implementor's notes on the wire format:
+# - World Semi vendor, (Adafruit copy of the) datasheet
+# https://cdn-shop.adafruit.com/datasheets/WS2812.pdf
+# - reset pulse is 50us (or more) of low pin level
+# - 24bits per WS281x item, 3x 8bits, MSB first, GRB sequence,
+# cascaded WS281x items, all "excess bits" are passed through
+# - bit time starts with high period, continues with low period,
+# high to low periods' ratio determines bit value, datasheet
+# mentions 0.35us/0.8us for value 0, 0.7us/0.6us for value 1
+# (huge 150ns tolerances, un-even 0/1 value length, hmm)
+# - experience suggests the timing "is variable", rough estimation
+# often is good enough, microcontroller firmware got away with
+# four quanta per bit time, or even with three quanta (30%/60%),
+# Adafruit learn article suggests 1.2us total and 0.4/0.8 or
+# 0.8/0.4 high/low parts, four quanta are easier to handle when
+# the bit stream is sent via SPI to avoid MCU bit banging and its
+# inaccurate timing (when interrupts are used in the firmware)
+# - RGBW datasheet (Adafruit copy) for SK6812
+# https://cdn-shop.adafruit.com/product-files/2757/p2757_SK6812RGBW_REV01.pdf
+# also 1.2us total, shared across 0.3/0.9 for 0, 0.6/0.6 for 1,
+# 80us reset pulse, R8/G8/B8/W8 format per 32bits
+# - WS2815, RGB LED, uses GRB wire format, 280us RESET pulse width
+# - more vendors and models available and in popular use,
+# suggests "one third" or "two thirds" ratio would be most robust,
+# sample "a little before" the bit half? reset pulse width may need
+# to become an option? matrices and/or fast refresh environments
+# may want to experiment with back to back pixel streams
+
import sigrokdecode as srd
-from functools import reduce
+from common.srdhelper import bitpack_msb
class SamplerateError(Exception):
pass
+class DecoderError(Exception):
+ pass
+
+(
+ ANN_BIT, ANN_RESET, ANN_RGB,
+ ANN_COMP_R, ANN_COMP_G, ANN_COMP_B, ANN_COMP_W,
+) = range(7)
+
class Decoder(srd.Decoder):
api_version = 3
id = 'rgb_led_ws281x'
desc = 'RGB LED string protocol (WS281x).'
license = 'gplv3+'
inputs = ['logic']
- outputs = ['rgb_led_ws281x']
+ outputs = []
+ tags = ['Display', 'IC']
channels = (
{'id': 'din', 'name': 'DIN', 'desc': 'DIN data line'},
)
('bit', 'Bit'),
('reset', 'RESET'),
('rgb', 'RGB'),
+ ('r', 'R'),
+ ('g', 'G'),
+ ('b', 'B'),
+ ('w', 'W'),
)
annotation_rows = (
- ('bit', 'Bits', (0, 1)),
- ('rgb', 'RGB', (2,)),
+ ('bits', 'Bits', (ANN_BIT, ANN_RESET,)),
+ ('rgb-comps', 'RGB components', (ANN_COMP_R, ANN_COMP_G, ANN_COMP_B, ANN_COMP_W,)),
+ ('rgb-vals', 'RGB values', (ANN_RGB,)),
+ )
+ options = (
+ {'id': 'wireorder', 'desc': 'colour components order (wire)',
+ 'default': 'GRB',
+ 'values': ('BGR', 'BRG', 'GBR', 'GRB', 'RBG', 'RGB', 'RWBG', 'RGBW')},
+ {'id': 'textorder', 'desc': 'components output order (text)',
+ 'default': 'RGB[W]', 'values': ('wire', 'RGB[W]', 'RGB', 'RGBW', 'RGWB')},
)
def __init__(self):
def reset(self):
self.samplerate = None
- self.oldpin = None
- self.ss_packet = None
- self.ss = None
- self.es = None
self.bits = []
- self.inreset = False
def start(self):
self.out_ann = self.register(srd.OUTPUT_ANN)
if key == srd.SRD_CONF_SAMPLERATE:
self.samplerate = value
- def handle_bits(self, samplenum):
- if len(self.bits) == 24:
- grb = reduce(lambda a, b: (a << 1) | b, self.bits)
- rgb = (grb & 0xff0000) >> 8 | (grb & 0x00ff00) << 8 | (grb & 0x0000ff)
- self.put(self.ss_packet, samplenum, self.out_ann,
- [2, ['#%06x' % rgb]])
- self.bits = []
- self.ss_packet = None
+ def putg(self, ss, es, cls, text):
+ self.put(ss, es, self.out_ann, [cls, text])
+
+ def handle_bits(self):
+ if len(self.bits) < self.need_bits:
+ return
+ ss_packet, es_packet = self.bits[0][1], self.bits[-1][2]
+ r, g, b, w = 0, 0, 0, None
+ comps = []
+ for i, c in enumerate(self.wireformat):
+ first_idx, after_idx = 8 * i, 8 * i + 8
+ comp_bits = self.bits[first_idx:after_idx]
+ comp_ss, comp_es = comp_bits[0][1], comp_bits[-1][2]
+ comp_value = bitpack_msb(comp_bits, 0)
+ comp_text = '{:02x}'.format(comp_value)
+ comp_ann = {
+ 'r': ANN_COMP_R, 'g': ANN_COMP_G,
+ 'b': ANN_COMP_B, 'w': ANN_COMP_W,
+ }.get(c.lower(), None)
+ comp_item = (comp_ss, comp_es, comp_ann, comp_value, comp_text)
+ comps.append(comp_item)
+ if c.lower() == 'r':
+ r = comp_value
+ elif c.lower() == 'g':
+ g = comp_value
+ elif c.lower() == 'b':
+ b = comp_value
+ elif c.lower() == 'w':
+ w = comp_value
+ wt = '' if w is None else '{:02x}'.format(w)
+ if self.textformat == 'wire':
+ rgb_text = '#' + ''.join([c[-1] for c in comps])
+ else:
+ rgb_text = self.textformat.format(r = r, g = g, b = b, w = w, wt = wt)
+ for ss_comp, es_comp, cls_comp, value_comp, text_comp in comps:
+ self.putg(ss_comp, es_comp, cls_comp, [text_comp])
+ if rgb_text:
+ self.putg(ss_packet, es_packet, ANN_RGB, [rgb_text])
+ self.bits.clear()
+
+ def handle_bit(self, ss, es, value, ann_late = False):
+ if not ann_late:
+ text = ['{:d}'.format(value)]
+ self.putg(ss, es, ANN_BIT, text)
+ item = (value, ss, es)
+ self.bits.append(item)
+ self.handle_bits()
+ if ann_late:
+ text = ['{:d}'.format(value)]
+ self.putg(ss, es, ANN_BIT, text)
def decode(self):
if not self.samplerate:
raise SamplerateError('Cannot decode without samplerate.')
- while True:
- # TODO: Come up with more appropriate self.wait() conditions.
- (pin,) = self.wait()
-
- if self.oldpin is None:
- self.oldpin = pin
- continue
-
- # Check RESET condition (manufacturer recommends 50 usec minimal,
- # but real minimum is ~10 usec).
- if not self.inreset and not pin and self.es is not None and \
- (self.samplenum - self.es) / self.samplerate > 50e-6:
-
- # Decode last bit value.
- tH = (self.es - self.ss) / self.samplerate
- bit_ = True if tH >= 625e-9 else False
-
- self.bits.append(bit_)
- self.handle_bits(self.es)
-
- self.put(self.ss, self.es, self.out_ann, [0, ['%d' % bit_]])
- self.put(self.es, self.samplenum, self.out_ann,
- [1, ['RESET', 'RST', 'R']])
-
- self.inreset = True
- self.bits = []
- self.ss_packet = None
- self.ss = None
-
- if not self.oldpin and pin:
- # Rising edge.
- if self.ss and self.es:
- period = self.samplenum - self.ss
- duty = self.es - self.ss
- # Ideal duty for T0H: 33%, T1H: 66%.
- bit_ = (duty / period) > 0.5
+ # Preprocess options here, to simplify logic which executes
+ # much later in loops while settings have the same values.
+ wireorder = self.options['wireorder'].lower()
+ self.wireformat = [c for c in wireorder if c in 'rgbw']
+ self.need_bits = len(self.wireformat) * 8
+ textorder = self.options['textorder'].lower()
+ if textorder == 'wire':
+ self.textformat = 'wire'
+ elif textorder == 'rgb[w]':
+ self.textformat = '#{r:02x}{g:02x}{b:02x}{wt:s}'
+ else:
+ self.textformat = {
+ # "Obvious" permutations of R/G/B.
+ 'bgr': '#{b:02x}{g:02x}{r:02x}',
+ 'brg': '#{b:02x}{r:02x}{g:02x}',
+ 'gbr': '#{g:02x}{b:02x}{r:02x}',
+ 'grb': '#{g:02x}{r:02x}{b:02x}',
+ 'rbg': '#{r:02x}{b:02x}{g:02x}',
+ 'rgb': '#{r:02x}{g:02x}{b:02x}',
+ # RGB plus White. Only one of them useful?
+ 'rgbw': '#{r:02x}{g:02x}{b:02x}{w:02x}',
+ # Weird RGBW permutation for compatibility to test case.
+ # Neither used RGBW nor the 'wire' order. Obsolete now?
+ 'rgwb': '#{r:02x}{g:02x}{w:02x}{b:02x}',
+ }.get(textorder, None)
+ if self.textformat is None:
+ raise DecoderError('Unsupported text output format.')
- self.put(self.ss, self.samplenum, self.out_ann,
- [0, ['%d' % bit_]])
+ # Either check for edges which communicate bit values, or for
+ # long periods of idle level which represent a reset pulse.
+ # Track the left-most, right-most, and inner edge positions of
+ # a bit. The positive period's width determines the bit's value.
+ # Initially synchronize to the input stream by searching for a
+ # low period, which preceeds a data bit or starts a reset pulse.
+ # Don't annotate the very first reset pulse, but process it. We
+ # may not see the right-most edge of a data bit when reset is
+ # adjacent to that bit time.
+ cond_bit_starts = {0: 'r'}
+ cond_inbit_edge = {0: 'f'}
+ samples_625ns = int(self.samplerate * 625e-9)
+ samples_50us = round(self.samplerate * 50e-6)
+ cond_reset_pulse = {'skip': samples_50us + 1}
+ conds = [cond_bit_starts, cond_inbit_edge, cond_reset_pulse]
+ ss_bit, inv_bit, es_bit = None, None, None
+ pin, = self.wait({0: 'l'})
+ inv_bit = self.samplenum
+ check_reset = False
+ while True:
+ pin, = self.wait(conds)
- self.bits.append(bit_)
- self.handle_bits(self.samplenum)
+ # Check RESET condition. Manufacturers may disagree on the
+ # minimal pulse width. 50us are recommended in datasheets,
+ # experiments suggest the limit is around 10us.
+ # When the RESET pulse is adjacent to the low phase of the
+ # last bit time, we have no appropriate condition for the
+ # bit time's end location. That's why this BIT's annotation
+ # is shorter (only spans the high phase), and the RESET
+ # annotation immediately follows (spans from the falling edge
+ # to the end of the minimum RESET pulse width).
+ if check_reset and self.matched[2]:
+ es_bit = inv_bit
+ ss_rst, es_rst = inv_bit, self.samplenum
- if self.ss_packet is None:
- self.ss_packet = self.samplenum
+ if ss_bit and inv_bit and es_bit:
+ # Decode last bit value. Use the last processed bit's
+ # width for comparison when available. Fallback to an
+ # arbitrary threshold otherwise (which can result in
+ # false detection of value 1 for those captures where
+ # high and low pulses are of similar width).
+ duty = inv_bit - ss_bit
+ thres = samples_625ns
+ if self.bits:
+ period = self.bits[-1][2] - self.bits[-1][1]
+ thres = period * 0.5
+ bit_value = 1 if duty >= thres else 0
+ self.handle_bit(ss_bit, inv_bit, bit_value, True)
- self.ss = self.samplenum
+ if ss_rst and es_rst:
+ text = ['RESET', 'RST', 'R']
+ self.putg(ss_rst, es_rst, ANN_RESET, text)
+ check_reset = False
- elif self.oldpin and not pin:
- # Falling edge.
- self.inreset = False
- self.es = self.samplenum
+ self.bits.clear()
+ ss_bit, inv_bit, es_bit = None, None, None
- self.oldpin = pin
+ # Rising edge starts a bit time. Falling edge ends its high
+ # period. Get the previous bit's duty cycle and thus its
+ # bit value when the next bit starts.
+ if self.matched[0]: # and pin:
+ check_reset = False
+ if ss_bit and inv_bit:
+ # Got a previous bit? Handle it.
+ es_bit = self.samplenum
+ period = es_bit - ss_bit
+ duty = inv_bit - ss_bit
+ # Ideal duty for T0H: 33%, T1H: 66%.
+ bit_value = 1 if (duty / period) > 0.5 else 0
+ self.handle_bit(ss_bit, es_bit, bit_value)
+ ss_bit, inv_bit, es_bit = self.samplenum, None, None
+ if self.matched[1]: # and not pin:
+ check_reset = True
+ inv_bit = self.samplenum