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Say you've got a toy grammar, like: (updated so the output looks more natural)

S -> ${NP} ${VP} | ${S} and ${S} | ${S}, after which ${S}

NP -> the ${N} | the ${A} ${N} | the ${A} ${A} ${N}

VP -> ${V} ${NP}

N -> dog | fish | bird | wizard

V -> kicks | meets | marries

A -> red | striped | spotted

e.g., "the dog kicks the red wizard", "the bird meets the spotted fish or the wizard marries the striped dog"

How can you produce a sentence from this grammar according to the constraint that it must contain a total of n Vs + As + Ns. Given an integer the sentence must contain that many terminals. (note of course in this grammar the minimum possible n is 3).

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Is there a specific random distribution that you're trying to achieve over all sentences with n terminals? – Dave Jun 8 '09 at 19:41
The minimum is 5, and you can't do 10 or 11. – UncleO Jun 8 '09 at 19:46
The sentences can be pretty strange. "either either the dog kicks the bird or the dog kicks the bird or the dog kicks the bird". Do you want to restrict the grammar to be more like English? – UncleO Jun 8 '09 at 19:54
@ucleo#1: Correct me if I'm wrong but I think the minimum is N + V + N, 3. I don't care about the 'the' determiner, I'm counting that as part of the NP non-terminal (perhaps I've used the term incorrectly). – ʞɔıu Jun 8 '09 at 20:05
I agree minimum is 3, but given rules for S I don't see a maximum? Unless terminal duplication is prohibited? – John Pirie Jun 8 '09 at 20:09
up vote 3 down vote accepted

The following Python code will generate a random sentence with the given number of terminals. It works by counting the number of ways to produce a sentence of a given length, generating a large random number, and computing the indicated sentence. The count is done recursively, with memoization. An empty right hand side produces 1 sentence if n is 0 and 0 sentences otherwise. To count the number of sentences produced by a nonempty right hand side, sum over i, the number of terminals used by the first symbol in the right hand side. For each i, multiply the number of possibilities for the rest of the right hand side by the number of possibilities for the first symbol. If the first symbol is a terminal, there is 1 possibility if i is 1 and 0 otherwise. If the first symbol is a nonterminal, sum the possibilities over each alternative. To avoid infinite loops, we have to be careful to prune the recursive calls when a quantity is 0. This may still loop infinitely if the grammar has infinitely many derivations of one sentence. For example, in the grammar

S -> S S
S ->

there are infinitely many derivations of the empty sentence: S => , S => S S => , S => S S => S S S => , etc. The code to find a particular sentence is a straightforward modification of the code to count them. This code is reasonably efficient, generating 100 sentences with 100 terminals each in less than a second.

import collections
import random

class Grammar:
    def __init__(self):
        self.prods = collections.defaultdict(list)
        self.numsent = {}
        self.weight = {}

    def prod(self, lhs, *rhs):

    def countsent(self, rhs, n):
        if n < 0:
            return 0
        elif not rhs:
            return 1 if n == 0 else 0
        args = (rhs, n)
        if args not in self.numsent:
            sym = rhs[0]
            rest = rhs[1:]
            total = 0
            if sym in self.prods:
                for i in xrange(1, n + 1):
                    numrest = self.countsent(rest, n - i)
                    if numrest > 0:
                        for rhs1 in self.prods[sym]:
                            total += self.countsent(rhs1, i) * numrest
                total += self.countsent(rest, n - self.weight.get(sym, 1))
            self.numsent[args] = total
        return self.numsent[args]

    def getsent(self, rhs, n, j):
        assert 0 <= j < self.countsent(rhs, n)
        if not rhs:
            return ()
        sym = rhs[0]
        rest = rhs[1:]
        if sym in self.prods:
            for i in xrange(1, n + 1):
                numrest = self.countsent(rest, n - i)
                if numrest > 0:
                    for rhs1 in self.prods[sym]:
                        dj = self.countsent(rhs1, i) * numrest
                        if dj > j:
                            j1, j2 = divmod(j, numrest)
                            return self.getsent(rhs1, i, j1) + self.getsent(rest, n - i, j2)
                        j -= dj
            assert False
            return (sym,) + self.getsent(rest, n - self.weight.get(sym, 1), j)

    def randsent(self, sym, n):
        return self.getsent((sym,), n, random.randrange(self.countsent((sym,), n)))

if __name__ == '__main__':
    g = Grammar()'S', 'NP', 'VP')'S', 'S', 'and', 'S')'S', 'S', 'after', 'which', 'S')'NP', 'the', 'N')'NP', 'the', 'A', 'N')'NP', 'the', 'A', 'A', 'N')'VP', 'V', 'NP')'N', 'dog')'N', 'fish')'N', 'bird')'N', 'wizard')'V', 'kicks')'V', 'meets')'V', 'marries')'A', 'red')'A', 'striped')'A', 'spotted')
    g.weight.update({'and': 0, 'after': 0, 'which': 0, 'the': 0})
    for i in xrange(100):
        print ' '.join(g.randsent('S', 3))
share|improve this answer
if I vary the size of n it seems to 'splode... – ʞɔıu Jun 8 '09 at 22:42
If it's an "empty range" error, it means that there aren't any sentences of that length. – Dave Jun 9 '09 at 0:34
Ah, I see... this is close but not quite right, though. It looks like it's going on the total number of words output, rather than the terminals, the N's, V's and A's only. 'the' and 'and' are part of non-terminals and shouldn't count, in other words. – ʞɔıu Jun 9 '09 at 2:10
I updated the code to allow weights to be specified. For simplicity, I made the assumption that no nonterminal is nullable. – Dave Jun 9 '09 at 2:35
Hmm, I've seen the terms 'rhs' and 'lhs' before.... here: . Can I ask you where I can learn more about this stuff? I'm still learning this stuff and it's not something I necessarily always find intuitive. – ʞɔıu Jun 9 '09 at 14:47

Perhaps not the best solution, but I'd recursively work my way through each rule of the grammar until I've exceeded the constraint, then pop back and explore another path along the grammar. Keep all the sentences that meet the constraint and throw out all the sentences that don't.

For example, with n = 3:

S -> (${NP} ${VP}) -> ( (the ${N}) ${VP}) -> ( (the (dog) ${VP}) -> ... -> ( (the (dog) ( (kicks) (the ${NP} ) ) ) ) -> ( (the (dog) ( (kicks) (the (dog) ) ) ) )

And then pop back

( (the (dog) ( (kicks) (the ${N} ) ) ) ) -> ( (the (dog) ( (kicks) (the (fish) ) ) ) )

and a little while later...

( (the (dog) ( ${V} ${N} ) ) ) -> ( (the (dog) ( (meets) ${N} ) ) ) -> ( (the (dog) ( (meets) the (dog) ) ) )


Essentially a depth-first graph search, only you are building the graph as you are searching it (and you stop building parts that exceed the constraints).

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This question contains a category error. The grammar you've specified has the appearance of a context free grammar, but the requirement that there be a specific number of terminal nodes requires a recursively enumerable grammar.

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you may be right but I can only find a handful of hits on google for "recursively enumerable grammar" that aren't obscure conference papers – ʞɔıu Jun 9 '09 at 19:20

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