##
-## This file is part of the sigrok project.
+## This file is part of the libsigrokdecode project.
##
-## Copyright (C) 2012 Uwe Hermann <uwe@hermann-uwe.de>
+## Copyright (C) 2012-2015 Uwe Hermann <uwe@hermann-uwe.de>
##
## 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
## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
##
-# Texas Instruments TLC5620 protocol decoder
-
import sigrokdecode as srd
dacs = {
}
class Decoder(srd.Decoder):
- api_version = 1
+ api_version = 2
id = 'tlc5620'
name = 'TI TLC5620'
longname = 'Texas Instruments TLC5620'
license = 'gplv2+'
inputs = ['logic']
outputs = ['tlc5620']
- probes = [
+ channels = (
{'id': 'clk', 'name': 'CLK', 'desc': 'Serial interface clock'},
{'id': 'data', 'name': 'DATA', 'desc': 'Serial interface data'},
- ]
- optional_probes = [
+ )
+ optional_channels = (
{'id': 'load', 'name': 'LOAD', 'desc': 'Serial interface load control'},
{'id': 'ldac', 'name': 'LDAC', 'desc': 'Load DAC'},
- ]
- options = {}
- annotations = [
- ['Text', 'Human-readable text'],
- ['Warnings', 'Human-readable warnings'],
- ]
-
- def __init__(self, **kwargs):
+ )
+ options = (
+ {'id': 'vref_a', 'desc': 'Reference voltage DACA (V)', 'default': 3.3},
+ {'id': 'vref_b', 'desc': 'Reference voltage DACB (V)', 'default': 3.3},
+ {'id': 'vref_c', 'desc': 'Reference voltage DACC (V)', 'default': 3.3},
+ {'id': 'vref_d', 'desc': 'Reference voltage DACD (V)', 'default': 3.3},
+ )
+ annotations = (
+ ('dac-select', 'DAC select'),
+ ('gain', 'Gain'),
+ ('value', 'DAC value'),
+ ('data-latch', 'Data latch point'),
+ ('ldac-fall', 'LDAC falling edge'),
+ ('bit', 'Bit'),
+ ('reg-write', 'Register write'),
+ ('voltage-update', 'Voltage update'),
+ ('voltage-update-all', 'Voltage update (all DACs)'),
+ ('invalid-cmd', 'Invalid command'),
+ )
+ annotation_rows = (
+ ('bits', 'Bits', (5,)),
+ ('fields', 'Fields', (0, 1, 2)),
+ ('registers', 'Registers', (6, 7)),
+ ('voltage-updates', 'Voltage updates', (8,)),
+ ('events', 'Events', (3, 4)),
+ ('errors', 'Errors', (9,)),
+ )
+
+ def __init__(self):
self.oldpins = self.oldclk = self.oldload = self.oldldac = None
- self.datapin = None
self.bits = []
+ self.ss_dac_first = None
self.ss_dac = self.es_dac = 0
self.ss_gain = self.es_gain = 0
self.ss_value = self.es_value = 0
self.dac_select = self.gain = self.dac_value = None
+ self.dacval = {'A': '?', 'B': '?', 'C': '?', 'D': '?'}
+ self.gains = {'A': '?', 'B': '?', 'C': '?', 'D': '?'}
- def start(self, metadata):
- # self.out_proto = self.add(srd.OUTPUT_PROTO, 'tlc5620')
- self.out_ann = self.add(srd.OUTPUT_ANN, 'tlc5620')
-
- def report(self):
- pass
+ def start(self):
+ self.out_ann = self.register(srd.OUTPUT_ANN)
def handle_11bits(self):
- s = "".join(str(i) for i in self.bits[:2])
- self.dac_select = dacs[int(s, 2)]
+ # Only look at the last 11 bits, the rest is ignored by the TLC5620.
+ if len(self.bits) > 11:
+ self.bits = self.bits[-11:]
+
+ # If there are less than 11 bits, something is probably wrong.
+ if len(self.bits) < 11:
+ ss, es = self.samplenum, self.samplenum
+ if len(self.bits) >= 2:
+ ss = self.bits[0][1]
+ es = self.bits[-1][1] + (self.bits[1][1] - self.bits[0][1])
+ self.put(ss, es, self.out_ann, [9, ['Command too short']])
+ self.bits = []
+ return False
+
+ self.ss_dac = self.bits[0][1]
+ self.es_dac = self.ss_gain = self.bits[2][1]
+ self.es_gain = self.ss_value = self.bits[3][1]
+ self.clock_width = self.es_gain - self.ss_gain
+ self.es_value = self.bits[10][1] + self.clock_width # Guessed.
+
+ if self.ss_dac_first is None:
+ self.ss_dac_first = self.ss_dac
+
+ s = ''.join(str(i[0]) for i in self.bits[:2])
+ self.dac_select = s = dacs[int(s, 2)]
self.put(self.ss_dac, self.es_dac, self.out_ann,
- [0, ['DAC select: %s' % self.dac_select]])
+ [0, ['DAC select: %s' % s, 'DAC sel: %s' % s,
+ 'DAC: %s' % s, 'D: %s' % s, s, s[3]]])
- self.gain = 1 + self.bits[2]
+ self.gain = g = 1 + self.bits[2][0]
self.put(self.ss_gain, self.es_gain, self.out_ann,
- [0, ['Gain: x%d' % self.gain]])
+ [1, ['Gain: x%d' % g, 'G: x%d' % g, 'x%d' % g]])
- s = "".join(str(i) for i in self.bits[3:])
- self.dac_value = int(s, 2)
+ s = ''.join(str(i[0]) for i in self.bits[3:])
+ self.dac_value = v = int(s, 2)
self.put(self.ss_value, self.es_value, self.out_ann,
- [0, ['DAC value: %d' % self.dac_value]])
+ [2, ['DAC value: %d' % v, 'Value: %d' % v, 'Val: %d' % v,
+ 'V: %d' % v, '%d' % v]])
+
+ # Emit an annotation for each bit.
+ for i in range(1, 11):
+ self.put(self.bits[i - 1][1], self.bits[i][1], self.out_ann,
+ [5, [str(self.bits[i - 1][0])]])
+ self.put(self.bits[10][1], self.bits[10][1] + self.clock_width,
+ self.out_ann, [5, [str(self.bits[10][0])]])
+
+ self.bits = []
+
+ return True
def handle_falling_edge_load(self):
+ if not self.handle_11bits():
+ return
+ s, v, g = self.dac_select, self.dac_value, self.gain
self.put(self.samplenum, self.samplenum, self.out_ann,
- [0, ['Setting %s value to %d (x%d gain)' % \
- (self.dac_select, self.dac_value, self.gain)]])
+ [3, ['Falling edge on LOAD', 'LOAD fall', 'F']])
+ vref = self.options['vref_%s' % self.dac_select[3].lower()]
+ v = '%.2fV' % (vref * (v / 256) * self.gain)
+ if self.ldac == 0:
+ # If LDAC is low, the voltage is set immediately.
+ self.put(self.ss_dac, self.es_value, self.out_ann,
+ [7, ['Setting %s voltage to %s' % (s, v),
+ '%s=%s' % (s, v)]])
+ else:
+ # If LDAC is high, the voltage is not set immediately, but rather
+ # stored in a register. When LDAC goes low all four DAC voltages
+ # (DAC A/B/C/D) will be set at the same time.
+ self.put(self.ss_dac, self.es_value, self.out_ann,
+ [6, ['Setting %s register value to %s' % \
+ (s, v), '%s=%s' % (s, v)]])
+ # Save the last value the respective DAC was set to.
+ self.dacval[self.dac_select[-1]] = str(self.dac_value)
+ self.gains[self.dac_select[-1]] = self.gain
def handle_falling_edge_ldac(self):
self.put(self.samplenum, self.samplenum, self.out_ann,
- [0, ['Falling edge on LDAC pin']])
+ [4, ['Falling edge on LDAC', 'LDAC fall', 'LDAC', 'L']])
+
+ # Don't emit any annotations if we didn't see any register writes.
+ if self.ss_dac_first is None:
+ return
+
+ # Calculate voltages based on Vref and the per-DAC gain.
+ dacval = {}
+ for key, val in self.dacval.items():
+ if val == '?':
+ dacval[key] = '?'
+ else:
+ vref = self.options['vref_%s' % key.lower()]
+ v = vref * (int(val) / 256) * self.gains[key]
+ dacval[key] = '%.2fV' % v
+
+ s = ''.join(['DAC%s=%s ' % (d, dacval[d]) for d in 'ABCD']).strip()
+ self.put(self.ss_dac_first, self.samplenum, self.out_ann,
+ [8, ['Updating voltages: %s' % s, s, s.replace('DAC', '')]])
+ self.ss_dac_first = None
def handle_new_dac_bit(self):
- self.bits.append(self.datapin)
-
- # Wait until we have read 11 bits, then parse them.
- l, s = len(self.bits), self.samplenum
- if l == 1:
- self.ss_dac = s
- elif l == 2:
- self.es_dac = self.ss_gain = s
- elif l == 3:
- self.es_gain = self.ss_value = s
- elif l == 11:
- self.es_value = s
- self.handle_11bits()
- self.bits = []
+ self.bits.append([self.datapin, self.samplenum])
def decode(self, ss, es, data):
for (self.samplenum, pins) in data:
if self.oldpins == pins:
continue
self.oldpins, (clk, self.datapin, load, ldac) = pins, pins
+ self.ldac = ldac
# DATA is shifted in the DAC on the falling CLK edge (MSB-first).
# A falling edge of LOAD will latch the data.
self.oldclk = clk
self.oldload = load
self.oldldac = ldac
-