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Does anyone know if there's a python builtin for computing transitive closure of tuples?

I have tuples of the form (1,2),(2,3),(3,4) and I'm trying to get (1,2),(2,3),(3,4),(1,3)(2,4)


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What do mean 'transitive' and 'closure' here ? What is the principle of the appearance of (1,3) and (2,4) ? Are your tuples always the same length ? What does mean 'computing tuples' ? – eyquem Dec 29 '11 at 21:19
More on transitive closure here transitive_closure. Essentially, the principle is if in the original list of tuples we have two tuples of the form (a,b) and (c,z), and b equals c, then we add tuple (a,z) Tuples will always have two entries since it's a binary relation. By 'computing tuples' I mean extending the original list of tuples to become the transitive closure. – Duke Dec 29 '11 at 21:21
Thank you. I was totally ignorant of this notion. – eyquem Dec 29 '11 at 21:25
Since it appears (2,4) , should (1,4) appear too from (1,2) and the new (2,4) ? – eyquem Dec 29 '11 at 21:30
If there was something builtin for this, it would be in, but it appears no such thing exists (built-in, that is). – Adam Wagner Dec 29 '11 at 21:49

There's no builtin for transitive closures.

They're quite simple to implement though.

Here's my take on it:

def transitive_closure(a):
    closure = set(a)
    while True:
        new_relations = set((x,w) for x,y in closure for q,w in closure if q == y)

        closure_until_now = closure | new_relations

        if closure_until_now == closure:

        closure = closure_until_now

    return closure

call: transitive_closure([(1,2),(2,3),(3,4)])

result: set([(1, 2), (1, 3), (1, 4), (2, 3), (3, 4), (2, 4)])

call: transitive_closure([(1,2),(2,1)])

result: set([(1, 2), (1, 1), (2, 1), (2, 2)])

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+1, very elegant. Never mind my previous comment :) Btw., new_relations strictly hold relationships in set-theoretic parlance, or edges in graph terms. – larsmans Dec 29 '11 at 22:17
we should not have (2,2) in the 2nd call's result. – Duke Dec 29 '11 at 23:00
@Duke yes you should (2,2) = (2,1) * (1,2) – soulcheck Dec 29 '11 at 23:12
@Duke: if xRy and yRz, then the transitive closure of R includes (x,z). In this situation, x=z=2 and y=1, so (2,2) should be included. – larsmans Dec 30 '11 at 11:36
my bad. you're right – Duke Mar 28 '12 at 14:58

Just a quick attempt:

def transitive_closure(elements):
    elements = set([(x,y) if x < y else (y,x) for x,y in elements])

    relations = {}
    for x,y in elements:
        if x not in relations:
            relations[x] = []

    closure = set()
    def build_closure(n):
        def f(k):
            for y in relations.get(k, []):
                closure.add((n, y))

    for k in relations.keys():

    return closure

Executing it, we'll get

In [3]: transitive_closure([(1,2),(2,3),(3,4)])
Out[3]: set([(1, 2), (1, 3), (1, 4), (2, 3), (2, 4), (3, 4)])
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this works, thanks! – Duke Dec 29 '11 at 21:49
maybe relations is not the correct name; it just stores, for each number, the other "reachable" numbers, building a DAG. The recursive function build_closure creates all the matches visiting the graph (this solution has however strong input assumptions, a more flexible (and complex) may be more suitable for other inputs) [duh, comment removed.. leaving this answer for reference] – StefanoP Dec 29 '11 at 22:00
This will run into infinite recursion if there is a cycle in the input. (I misinterpreted the code the first time, somehow thinking you were iterating over pairs of elements rather than tuple-unpacking individual elements while building relations.) – Karl Knechtel Dec 29 '11 at 22:01
I'd expect transitive_closure([(1,2),(2,1)]) to include (as mine does) (1,1) and (2,2) in the output, but I don't know exactly what OP wants... – Karl Knechtel Dec 29 '11 at 22:22
@KarlKnechtel: that's the transitive and reflexive closure. – larsmans Dec 29 '11 at 22:29

We can perform the "closure" operation from a given "start node" by repeatedly taking a union of "graph edges" from the current "endpoints" until no new endpoints are found. We need to do this at most (number of nodes - 1) times, since this is the maximum length of a path. (Doing things this way avoids getting stuck in infinite recursion if there is a cycle; it will waste iterations in the general case, but avoids the work of checking whether we are done i.e. that no changes were made in a given iteration.)

from collections import defaultdict

def transitive_closure(elements):
    edges = defaultdict(set)
    # map from first element of input tuples to "reachable" second elements
    for x, y in elements: edges[x].add(y)

    for _ in range(len(elements) - 1):
        edges = defaultdict(set, (
            (k, v.union(*(edges[i] for i in v)))
            for (k, v) in edges.items()

    return set((k, i) for (k, v) in edges.items() for i in v)

(I actually tested it for once ;) )

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this works as well. – Duke Dec 29 '11 at 23:06

Suboptimal, but conceptually simple solution:

def transitive_closure(a):
    closure = set()
    for x, _ in a:
        closure |= set((x, y) for y in dfs(x, a))
    return closure

def dfs(x, a):
    """Yields single elements from a in depth-first order, starting from x"""
    for y in [y for w, y in a if w == x]:
        yield y
        for z in dfs(y, a):
            yield z

This won't work when there's a cycle in the relation, i.e. a reflexive point.

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+1 was about to post the dfs solution as well :) – soulcheck Dec 29 '11 at 22:41
it does flop on cycles though. – soulcheck Dec 29 '11 at 22:50
@soulcheck: you're right. Documented that; there's plenty of better solutions posted already. – larsmans Dec 29 '11 at 22:52
it's easy to correct, as in typical dfs. once you see a cycle, return the node that creates it and backtrack. – soulcheck Dec 29 '11 at 23:17

Here's one essentially the same as the one from @soulcheck that works on adjacency lists rather than edge lists:

def inplace_transitive_closure(g):
    """g is an adjacency list graph implemented as a dict of sets"""
    done = False
    while not done:
        done = True
        for v0, v1s in g.items():
            old_len = len(v1s)
            for v2s in [g[v1] for v1 in v1s]:
                v1s |= v2s
            done = done and len(v1s) == old_len
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