class nltk.ViterbiParser(grammar, trace=0)[source]

A bottom-up PCFG parser that uses dynamic programming to find the single most likely parse for a text. The ViterbiParser parser parses texts by filling in a “most likely constituent table”. This table records the most probable tree representation for any given span and node value. In particular, it has an entry for every start index, end index, and node value, recording the most likely subtree that spans from the start index to the end index, and has the given node value.

The ViterbiParser parser fills in this table incrementally. It starts by filling in all entries for constituents that span one element of text (i.e., entries where the end index is one greater than the start index). After it has filled in all table entries for constituents that span one element of text, it fills in the entries for constitutants that span two elements of text. It continues filling in the entries for constituents spanning larger and larger portions of the text, until the entire table has been filled. Finally, it returns the table entry for a constituent spanning the entire text, whose node value is the grammar’s start symbol.

In order to find the most likely constituent with a given span and node value, the ViterbiParser parser considers all productions that could produce that node value. For each production, it finds all children that collectively cover the span and have the node values specified by the production’s right hand side. If the probability of the tree formed by applying the production to the children is greater than the probability of the current entry in the table, then the table is updated with this new tree.

A pseudo-code description of the algorithm used by ViterbiParser is:

Create an empty most likely constituent table, MLC.
For width in 1...len(text):
For start in 1...len(text)-width:
For prod in
For each sequence of subtrees [t[1], t[2], ..., t[n]] in MLC,
where t[i].label()==prod.rhs[i],
and the sequence covers [start:start+width]:
old_p = MLC[start, start+width, prod.lhs]
new_p = P(t[1])P(t[1])...P(t[n])P(prod)
if new_p > old_p:
new_tree = Tree(prod.lhs, t[1], t[2], ..., t[n])
MLC[start, start+width, prod.lhs] = new_tree
Return MLC[0, len(text), start_symbol]
  • _grammar – The grammar used to parse sentences.
  • _trace – The level of tracing output that should be generated when parsing a text.


__init__(grammar[, trace]) Create a new ViterbiParser parser, that uses grammar to parse texts.
parse_all(sent, *args, **kwargs)
parse_one(sent, *args, **kwargs)
rtype:Tree or None
parse_sents(sents, *args, **kwargs) Apply self.parse() to each element of sents.
trace([trace]) Set the level of tracing output that should be generated when parsing a text.