20

I have a (large) list of parsed sentences (which were parsed using the Stanford parser), for example, the sentence "Now you can be entertained" has the following tree:

(ROOT
  (S
    (ADVP (RB Now))
    (, ,)
    (NP (PRP you))
    (VP (MD can)
      (VP (VB be)
        (VP (VBN entertained))))
    (. .)))

I am using the set of sentence trees to induce a grammar using nltk:

import nltk

# ... for each sentence tree t, add its production to allProductions
allProductions += t.productions()

# Induce the grammar
S = nltk.Nonterminal('S')
grammar = nltk.induce_pcfg(S, allProductions)

Now I would like to use grammar to generate new, random sentences. My hope is that since the grammar was learned from a specific set of input examples, then the generated sentences will be semantically similar. Can I do this in nltk?

If I can't use nltk to do this, do any other tools exist that can take the (possibly reformatted) grammar and generate sentences?

1

5 Answers 5

14

In NLTK 2.0 you can use nltk.parse.generate to generate all possible sentences for a given grammar.

This code defines a function which should generate a single sentence based on the production rules in a (P)CFG.

# This example uses choice to choose from possible expansions
from random import choice
# This function is based on _generate_all() in nltk.parse.generate
# It therefore assumes the same import environment otherwise.
def generate_sample(grammar, items=["S"]):
    frags = []
    if len(items) == 1:
        if isinstance(items[0], Nonterminal):
            for prod in grammar.productions(lhs=items[0]):
                frags.append(generate_sample(grammar, prod.rhs()))
        else:
            frags.append(items[0])
    else:
        # This is where we need to make our changes
        chosen_expansion = choice(items)
        frags.append(generate_sample,chosen_expansion)
    return frags

To make use of the weights in your PCFG, you'll obviously want to use a better sampling method than choice(), which implicitly assumes all expansions of the current node are equiprobable.

4

First of all, if you generate random sentences, they may be semantically correct, but they will probably lose their sense.

(It sounds to me a bit like those MIT students did with their SCIgen program which is auto-generating scientific paper. Very interesting btw.)

Anyway, I never did it myself, but it seems possible with nltk.bigrams, you may way to have a look there under Generating Random Text with Bigrams.

You can also generate all subtrees of a current tree, I'm not sure if it is what you want either.

3

My solution to generate a random sentence from an existing nltk.CFG grammar:

def generate_sample(grammar, prod, frags):        
    if prod in grammar._lhs_index: # Derivation
        derivations = grammar._lhs_index[prod]            
        derivation = random.choice(derivations)            
        for d in derivation._rhs:            
            generate_sample(grammar, d, frags)
    elif prod in grammar._rhs_index:
        # terminal
        frags.append(str(prod))

And now it can be used:

frags = []  
generate_sample(grammar, grammar.start(), frags)
print( ' '.join(frags) )
1
  • 1
    The line generate_sample(d, frags) should read generate_sample(grammar, d, frags). Dec 13, 2017 at 20:13
2

With an nltk Text object you can call 'generate()' on it which will "Print random text, generated using a trigram language model."http://nltk.org/_modules/nltk/text.html

2
2

Inspired by the above, here's one which uses iteration instead of recursion.

import random

def rewrite_at(index, replacements, the_list):
    del the_list[index]
    the_list[index:index] = replacements

def generate_sentence(grammar):
    sentence_list = [grammar.start()]
    all_terminals = False
    while not all_terminals:
        all_terminals = True
        for position, symbol in enumerate(sentence_list):
            if symbol in grammar._lhs_index:
                all_terminals = False
                derivations = grammar._lhs_index[symbol]
                derivation = random.choice(derivations) # or weighted_choice(derivations) if you have a function for that
                rewrite_at(position, derivation.rhs(), sentence_list)
    return sentence_list

Or if you want the tree of the derivation, this one.

from nltk.tree import Tree

def tree_from_production(production):
    return Tree(production.lhs(), production.rhs())

def leaf_positions(the_tree):
    return [the_tree.leaf_treeposition(i) for i in range(len(the_tree.leaves()))]

def generate_tree(grammar):
    initial_derivations = grammar._lhs_index[grammar.start()]
    initial_derivation = random.choice(initial_derivations) # or weighed_choice if you have that function
    running_tree = tree_from_production(initial_derivation)
    all_terminals = False
    while not all_terminals:
        all_terminals = True
        for position in leaf_positions(running_tree):
            node_label = running_tree[position]
            if node_label in grammar._lhs_index:
                all_terminals = False
                derivations = grammar._lhs_index[node_label]
                derivation = random.choice(derivations) # or weighed_choice if you have that function
                running_tree[position] = tree_from_production(derivation)
    return running_tree

Here's a weighted_choice function for NLTK PCFG production rules to use with the above, adapted from Ned Batchelder's answer here for weighted choice functions in general:

def weighted_choice(productions):
    prods_with_probs = [(prod, prod.prob()) for prod in productions]
    total = sum(prob for prod, prob in prods_with_probs)
    r = random.uniform(0, total)
    upto = 0
    for prod, prob in prods_with_probs:
        if upto + prob >= r:
            return prod
        upto += prob
    assert False, "Shouldn't get here"

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