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Released: Mar 9, 2021
Python abstraction around Binary Decision Diagrams to implement Multivalued Decision Diagrams.
Python abstraction around Binary Decision Diagrams to implement Multi-valued Decision Diagrams.
Table of Contents
DecisionDiagram
Multi-valued Decision Diagrams (MDD) are a way to represent discrete function:
f : A₁ × A₂ × … × Aₙ → B.
Conceptually, a MDD for f can be thought of as a compressed decision tree (in the form of a directed acyclc graph).
f
For example, if we have a function over two variables,
x ∈ {1,2,3,4,5}, y ∈ {'a','b'}
with possible outputs f(x, y) ∈ {-1, 0, 1}, then the following diagram represents the function:
f(x, y) ∈ {-1, 0, 1}
f(x, y) = 1 if (x ≡ 1 and y ≡ 'a') else 0
This library provides abstractions to easily create and manipulate MDDs.
If you just need to use py-mdd, you can just run:
py-mdd
$ pip install mdd
For developers, note that this project uses the poetry python package/dependency management tool. Please familarize yourself with it and then run:
$ poetry install
For the impatient, here is a basic usage example:
import mdd interface = mdd.Interface( inputs={ "x": [1, 2, 3], "y": [6, 'w'], "z": [7, True, 8], }, output=[-1, 0, 1], ) func = interface.constantly(-1) assert func({'x': 1, 'y': 'w', 'z': 8}) == -1 # Can access underlying BDD from `dd` library. # Note: This BDD encodes both the function's output # *and* domain (valid inputs). assert func.bdd.dag_size == 33
If 33 seems very large to you, this is just a constant function after all, note that as the following sections illustrate, its easy to implement alternative encodings which can be much more compact. [0]
The mdd api centers around three objects:
mdd
Variable
Interface
By default, variables use one-hot encoding, but all input variables can use arbitrary encodings by defining a bit-vector expression describing valid inputs and a encode/decoder pair from ints to the variable's domain.
int
# One hot encoded by default. var1 = mdd.to_var(domain=["x", "y", "z"], name="myvar1") # Hand crafted encoding using `py-aiger`. import aiger_bv # Named 2-length bitvector circuit. bvexpr = aiger_bv.uatom(2, 'myvar3') domain = ('a', 'b', 'c') var2 = mdd.Variable( encode=domain.index, # Any -> int decode=domain.__getitem__, # int -> Any valid=bvexpr < 4, # 0b11 is invalid! ) # Can create new variable using same encoding, but different name. var3 = var2.with_name("myvar3") var4 = mdd.to_var(domain=[-1, 0, 1], name='output')
A useful feature of variables is that they can generate an aiger_bv BitVector object to describe circuits in terms of a variable.
aiger_bv
a_int = var2.encode('a') y_int = var1.encode('y') # BitVector Expression testing if var2 is 'a' and var1 is 'y'. expr = (var2.expr() == a_int) & (var1.expr() == y_int)
Given these variables, we can define an input/output interface.
# All variables must have distinct names. interface = mdd.Interface(inputs=[var1, var2, var3], output=var4)
Further, as the first example showed, if the default encoding is fine, then we can simply pass a dictionary inplace of inputs and/or a iterable in place of the output. In this case, a 1-hot encoding will be created using the order of the variables.
interface = mdd.Interface( inputs={ "x": [1, 2, 3], # These are "y": [6, 'w'], # 1-hot "z": [7, True, 8], # Encoded. }, output=[-1, 0, 1], # uuid based output name. )
Finally, given an interface we can create a Multi-valued Decision Diagram. There are five main ways to create a DecisionDiagram:
Given an interface, create a constant function:
func = interface.constantly(1)
Wrap an py-aiger compatible object:
py-aiger
import aiger_bv as BV x = interface.var('x') # Access 'x' variable. out = interface.output # Access output variable. expr = BV.ite( x.expr() == x.encode(2), # Test. out.expr() == out.encode(0), # True branch. out.expr() == out.encode(-1), # False branch. ) func = interface.lift(expr) assert func({'x': 2, 'y': 6, 'z': True}) == 0 assert func({'x': 1, 'y': 6, 'z': True}) == -1
Wrap an existing Binary Decision Diagram:
bdd = mdd.to_bdd(expr) # Convert `aiger` expression to bdd. func = interface.lift(bdd) # bdd type comes from `dd` library. assert func({'x': 2, 'y': 6, 'z': True}) == 0 assert func({'x': 1, 'y': 6, 'z': True}) == -1
Partially Evaluate an existing DecisionDiagram:
constantly_0 = func.let({'x': 2}) assert func({'y': 6, 'z': True}) == 0
Override an existing DecisionDiagram given a predicate:
# Can be a BDD or and py-aiger compatible object. test = x.expr() == x.encode(1) # If x = 1, then return 1, otherwise return using func. func2 = func.override(test=test, value=1) assert func2({'x': 1, 'y': 6, 'z': True}) == 1
The py-mdd library uses a Binary Decision Diagram to represent a multi-valued function. The encoding slighly differs from the standard reduction [1] from mdds to bdds by assuming the following:
0
bdd
Any bdd that conforms to this encoding can be wrapped up by an approriate Interface.
The underlying BDD can be reordered to respect variable ordering by providing a complete list of variable names to the order method.
order
func.order(['x', 'y', 'z', func.output.name])
If the networkx python package is installed:
networkx
$ pip install networkx
or the nx option is added when installing py-mdd:
nx
$ pip install mdd[nx]
then one can export a DecisionDiagram as a directed graph.
note: for now, this graph is only partially reduced. In the future, the plan is to guarantee that the exported DAG is fulled reduced.
from mdd.nx import to_nx graph = to_nx(func) # Has BitVector expressions on edges to represent guards. graph2 = to_nx(func, symbolic_edges=False) # Has explicit sets of values on edges to represent guards.
[0]: To get a sense for how much overhead is introduced, consider the corresponding Zero Suppressed Decision Diagram (ZDD) of a 1-hot encoding. A classic result (see Art of Computer Programming vol 4a) is the ZDD size bounds the BDD size via O(#variables*|size of ZDD|).
[1]: Srinivasan, Arvind, et al. "Algorithms for discrete function manipulation." 1990 IEEE international conference on computer-aided design. IEEE Computer Society, 1990.
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