if self.saved_word is not None:
if self.options['wordsize'] > 0:
self.es_word = self.samplenum
- self.putw([1, ['%X' % self.saved_word]])
+ self.putw([1, [self.fmt_word.format(self.saved_word)]])
self.putpw(['WORD', self.saved_word])
self.saved_word = None
# Output the saved item (from the last CLK edge to the current).
self.es_item = self.samplenum
self.putpb(['ITEM', self.saved_item])
- self.putb([0, ['%X' % self.saved_item]])
+ self.putb([0, [self.fmt_item.format(self.saved_item)]])
self.ss_item = self.samplenum
self.saved_item = item
if not has_channels:
raise ChannelError('At least one channel has to be supplied.')
max_connected = max(has_channels)
- idx_strip = max_connected + 1
# Determine .wait() conditions, depending on the presence of a
# clock signal. Either inspect samples on the configured edge of
else:
conds = [{idx: 'e'} for idx in has_channels]
+ # Pre-determine which input data to strip off, the width of
+ # individual items and multiplexed words, as well as format
+ # strings here. This simplifies call sites which run in tight
+ # loops later.
+ idx_strip = max_connected + 1
+ num_item_bits = idx_strip - 1
+ num_word_items = self.options['wordsize']
+ num_word_bits = num_item_bits * num_word_items
+ num_digits = (num_item_bits + 3) // 4
+ self.fmt_item = "{{:0{}x}}".format(num_digits)
+ num_digits = (num_word_bits + 3) // 4
+ self.fmt_word = "{{:0{}x}}".format(num_digits)
+
# Keep processing the input stream. Assume "always zero" for
# not-connected input lines. Pass data bits (all inputs except
# clock) to the handle_bits() method.
while True:
pins = self.wait(conds)
bits = [0 if idx is None else pins[idx] for idx in idx_channels]
- bits = bits[1:idx_strip]
- self.handle_bits(bitpack(bits), len(bits))
+ item = bitpack(bits[1:idx_strip])
+ self.handle_bits(item, num_item_bits)