from nodetypes import DiscoType ANY = -1 class Port: def __setattr__(self, key, value): '''Alias for __setitem___''' self[key] = value def __setitem__(self, key, value): pass def __getattr__(self, key): '''Alias for __getitem___''' return self[key] def __getitem__(self, key): pass class InputPort(Port): def __init__(self, allowedtype, required=1, maxpins=ANY): self.pins = [] class OutputPort(Port): def __init__(self): self.pins = [] class Pin: def __init__(self, connection, value=DiscoType): pass ''' Snippet Pi=3: RFC 2: New port semantics # an example of the max node's op def changed(self, inputs): # note how this function does not use stateaccess, as it doesn't use state return max(inputs.values()) # so, how the heck does this work? # we check the function to get the names of kw args in the function. # we always pass self, but everything else is optional # the node asked for inputs, which looks like this: # inputs = {'portname' : PortObj, 'portname2', PortObj} # somehow, the PortObjs are max'ible. # the node has only one output so it can just return the value to set the # output. (maybe) # alteratively, if we decide that you always return a new dict of outputs: # return {'outputportname' : max(inputs.values())} # which isn't horrible, but not great # another example: an adder. the node has ports A and B, and an output C: # C also gets capped at stateaccess[min]. def changed(self, a, b, c, stateaccess): c.set(max(stateaccess['min'], a + b)) return {} # or: def changed(self, a, b, stateaccess): c = max(stateaccess['min'], a + b) return {'c' : c} # which i think is clearer. doing all port changes at the end has some # book-keeping advantages (we can detect easily which ports are changed) # the counter node could work this way: def changed(self, someoutput): return {'someoutput' : someoutput + 1} ''' ''' type 1: a, b, d, e type 2: b, c, d, f conversion maps: a -> [ ] b -> b d -> d e -> f '''