# Natural Language Toolkit: Context Free Grammars # # Copyright (C) 2001-2023 NLTK Project # Author: Steven Bird # Edward Loper # Jason Narad # Peter Ljunglöf # Tom Aarsen <> # URL: # For license information, see LICENSE.TXT # """ Basic data classes for representing context free grammars. A "grammar" specifies which trees can represent the structure of a given text. Each of these trees is called a "parse tree" for the text (or simply a "parse"). In a "context free" grammar, the set of parse trees for any piece of a text can depend only on that piece, and not on the rest of the text (i.e., the piece's context). Context free grammars are often used to find possible syntactic structures for sentences. In this context, the leaves of a parse tree are word tokens; and the node values are phrasal categories, such as ``NP`` and ``VP``. The ``CFG`` class is used to encode context free grammars. Each ``CFG`` consists of a start symbol and a set of productions. The "start symbol" specifies the root node value for parse trees. For example, the start symbol for syntactic parsing is usually ``S``. Start symbols are encoded using the ``Nonterminal`` class, which is discussed below. A Grammar's "productions" specify what parent-child relationships a parse tree can contain. Each production specifies that a particular node can be the parent of a particular set of children. For example, the production `` -> `` specifies that an ``S`` node can be the parent of an ``NP`` node and a ``VP`` node. Grammar productions are implemented by the ``Production`` class. Each ``Production`` consists of a left hand side and a right hand side. The "left hand side" is a ``Nonterminal`` that specifies the node type for a potential parent; and the "right hand side" is a list that specifies allowable children for that parent. This lists consists of ``Nonterminals`` and text types: each ``Nonterminal`` indicates that the corresponding child may be a ``TreeToken`` with the specified node type; and each text type indicates that the corresponding child may be a ``Token`` with the with that type. The ``Nonterminal`` class is used to distinguish node values from leaf values. This prevents the grammar from accidentally using a leaf value (such as the English word "A") as the node of a subtree. Within a ``CFG``, all node values are wrapped in the ``Nonterminal`` class. Note, however, that the trees that are specified by the grammar do *not* include these ``Nonterminal`` wrappers. Grammars can also be given a more procedural interpretation. According to this interpretation, a Grammar specifies any tree structure *tree* that can be produced by the following procedure: | Set tree to the start symbol | Repeat until tree contains no more nonterminal leaves: | Choose a production prod with whose left hand side | lhs is a nonterminal leaf of tree. | Replace the nonterminal leaf with a subtree, whose node | value is the value wrapped by the nonterminal lhs, and | whose children are the right hand side of prod. The operation of replacing the left hand side (*lhs*) of a production with the right hand side (*rhs*) in a tree (*tree*) is known as "expanding" *lhs* to *rhs* in *tree*. """ import re from functools import total_ordering from nltk.featstruct import SLASH, TYPE, FeatDict, FeatStruct, FeatStructReader from nltk.internals import raise_unorderable_types from nltk.probability import ImmutableProbabilisticMixIn from nltk.util import invert_graph, transitive_closure ################################################################# # Nonterminal ################################################################# @total_ordering class Nonterminal: """ A non-terminal symbol for a context free grammar. ``Nonterminal`` is a wrapper class for node values; it is used by ``Production`` objects to distinguish node values from leaf values. The node value that is wrapped by a ``Nonterminal`` is known as its "symbol". Symbols are typically strings representing phrasal categories (such as ``"NP"`` or ``"VP"``). However, more complex symbol types are sometimes used (e.g., for lexicalized grammars). Since symbols are node values, they must be immutable and hashable. Two ``Nonterminals`` are considered equal if their symbols are equal. :see: ``CFG``, ``Production`` :type _symbol: any :ivar _symbol: The node value corresponding to this ``Nonterminal``. This value must be immutable and hashable. """ def __init__(self, symbol): """ Construct a new non-terminal from the given symbol. :type symbol: any :param symbol: The node value corresponding to this ``Nonterminal``. This value must be immutable and hashable. """ self._symbol = symbol def symbol(self): """ Return the node value corresponding to this ``Nonterminal``. :rtype: (any) """ return self._symbol def __eq__(self, other): """ Return True if this non-terminal is equal to ``other``. In particular, return True if ``other`` is a ``Nonterminal`` and this non-terminal's symbol is equal to ``other`` 's symbol. :rtype: bool """ return type(self) == type(other) and self._symbol == other._symbol def __ne__(self, other): return not self == other def __lt__(self, other): if not isinstance(other, Nonterminal): raise_unorderable_types("<", self, other) return self._symbol < other._symbol def __hash__(self): return hash(self._symbol) def __repr__(self): """ Return a string representation for this ``Nonterminal``. :rtype: str """ if isinstance(self._symbol, str): return "%s" % self._symbol else: return "%s" % repr(self._symbol) def __str__(self): """ Return a string representation for this ``Nonterminal``. :rtype: str """ if isinstance(self._symbol, str): return "%s" % self._symbol else: return "%s" % repr(self._symbol) def __div__(self, rhs): """ Return a new nonterminal whose symbol is ``A/B``, where ``A`` is the symbol for this nonterminal, and ``B`` is the symbol for rhs. :param rhs: The nonterminal used to form the right hand side of the new nonterminal. :type rhs: Nonterminal :rtype: Nonterminal """ return Nonterminal(f"{self._symbol}/{rhs._symbol}") def __truediv__(self, rhs): """ Return a new nonterminal whose symbol is ``A/B``, where ``A`` is the symbol for this nonterminal, and ``B`` is the symbol for rhs. This function allows use of the slash ``/`` operator with the future import of division. :param rhs: The nonterminal used to form the right hand side of the new nonterminal. :type rhs: Nonterminal :rtype: Nonterminal """ return self.__div__(rhs) def nonterminals(symbols): """ Given a string containing a list of symbol names, return a list of ``Nonterminals`` constructed from those symbols. :param symbols: The symbol name string. This string can be delimited by either spaces or commas. :type symbols: str :return: A list of ``Nonterminals`` constructed from the symbol names given in ``symbols``. The ``Nonterminals`` are sorted in the same order as the symbols names. :rtype: list(Nonterminal) """ if "," in symbols: symbol_list = symbols.split(",") else: symbol_list = symbols.split() return [Nonterminal(s.strip()) for s in symbol_list] class FeatStructNonterminal(FeatDict, Nonterminal): """A feature structure that's also a nonterminal. It acts as its own symbol, and automatically freezes itself when hashed.""" def __hash__(self): self.freeze() return FeatStruct.__hash__(self) def symbol(self): return self def is_nonterminal(item): """ :return: True if the item is a ``Nonterminal``. :rtype: bool """ return isinstance(item, Nonterminal) ################################################################# # Terminals ################################################################# def is_terminal(item): """ Return True if the item is a terminal, which currently is if it is hashable and not a ``Nonterminal``. :rtype: bool """ return hasattr(item, "__hash__") and not isinstance(item, Nonterminal) ################################################################# # Productions ################################################################# @total_ordering class Production: """ A grammar production. Each production maps a single symbol on the "left-hand side" to a sequence of symbols on the "right-hand side". (In the case of context-free productions, the left-hand side must be a ``Nonterminal``, and the right-hand side is a sequence of terminals and ``Nonterminals``.) "terminals" can be any immutable hashable object that is not a ``Nonterminal``. Typically, terminals are strings representing words, such as ``"dog"`` or ``"under"``. :see: ``CFG`` :see: ``DependencyGrammar`` :see: ``Nonterminal`` :type _lhs: Nonterminal :ivar _lhs: The left-hand side of the production. :type _rhs: tuple(Nonterminal, terminal) :ivar _rhs: The right-hand side of the production. """ def __init__(self, lhs, rhs): """ Construct a new ``Production``. :param lhs: The left-hand side of the new ``Production``. :type lhs: Nonterminal :param rhs: The right-hand side of the new ``Production``. :type rhs: sequence(Nonterminal and terminal) """ if isinstance(rhs, str): raise TypeError( "production right hand side should be a list, " "not a string" ) self._lhs = lhs self._rhs = tuple(rhs) def lhs(self): """ Return the left-hand side of this ``Production``. :rtype: Nonterminal """ return self._lhs def rhs(self): """ Return the right-hand side of this ``Production``. :rtype: sequence(Nonterminal and terminal) """ return self._rhs def __len__(self): """ Return the length of the right-hand side. :rtype: int """ return len(self._rhs) def is_nonlexical(self): """ Return True if the right-hand side only contains ``Nonterminals`` :rtype: bool """ return all(is_nonterminal(n) for n in self._rhs) def is_lexical(self): """ Return True if the right-hand contain at least one terminal token. :rtype: bool """ return not self.is_nonlexical() def __str__(self): """ Return a verbose string representation of the ``Production``. :rtype: str """ result = "%s -> " % repr(self._lhs) result += " ".join(repr(el) for el in self._rhs) return result def __repr__(self): """ Return a concise string representation of the ``Production``. :rtype: str """ return "%s" % self def __eq__(self, other): """ Return True if this ``Production`` is equal to ``other``. :rtype: bool """ return ( type(self) == type(other) and self._lhs == other._lhs and self._rhs == other._rhs ) def __ne__(self, other): return not self == other def __lt__(self, other): if not isinstance(other, Production): raise_unorderable_types("<", self, other) return (self._lhs, self._rhs) < (other._lhs, other._rhs) def __hash__(self): """ Return a hash value for the ``Production``. :rtype: int """ return hash((self._lhs, self._rhs)) class DependencyProduction(Production): """ A dependency grammar production. Each production maps a single head word to an unordered list of one or more modifier words. """ def __str__(self): """ Return a verbose string representation of the ``DependencyProduction``. :rtype: str """ result = f"'{self._lhs}' ->" for elt in self._rhs: result += f" '{elt}'" return result class ProbabilisticProduction(Production, ImmutableProbabilisticMixIn): """ A probabilistic context free grammar production. A PCFG ``ProbabilisticProduction`` is essentially just a ``Production`` that has an associated probability, which represents how likely it is that this production will be used. In particular, the probability of a ``ProbabilisticProduction`` records the likelihood that its right-hand side is the correct instantiation for any given occurrence of its left-hand side. :see: ``Production`` """ def __init__(self, lhs, rhs, **prob): """ Construct a new ``ProbabilisticProduction``. :param lhs: The left-hand side of the new ``ProbabilisticProduction``. :type lhs: Nonterminal :param rhs: The right-hand side of the new ``ProbabilisticProduction``. :type rhs: sequence(Nonterminal and terminal) :param prob: Probability parameters of the new ``ProbabilisticProduction``. """ ImmutableProbabilisticMixIn.__init__(self, **prob) Production.__init__(self, lhs, rhs) def __str__(self): return super().__str__() + ( " [1.0]" if (self.prob() == 1.0) else " [%g]" % self.prob() ) def __eq__(self, other): return ( type(self) == type(other) and self._lhs == other._lhs and self._rhs == other._rhs and self.prob() == other.prob() ) def __ne__(self, other): return not self == other def __hash__(self): return hash((self._lhs, self._rhs, self.prob())) ################################################################# # Grammars ################################################################# class CFG: """ A context-free grammar. A grammar consists of a start state and a set of productions. The set of terminals and nonterminals is implicitly specified by the productions. If you need efficient key-based access to productions, you can use a subclass to implement it. """ def __init__(self, start, productions, calculate_leftcorners=True): """ Create a new context-free grammar, from the given start state and set of ``Production`` instances. :param start: The start symbol :type start: Nonterminal :param productions: The list of productions that defines the grammar :type productions: list(Production) :param calculate_leftcorners: False if we don't want to calculate the leftcorner relation. In that case, some optimized chart parsers won't work. :type calculate_leftcorners: bool """ if not is_nonterminal(start): raise TypeError( "start should be a Nonterminal object," " not a %s" % type(start).__name__ ) self._start = start self._productions = productions self._categories = {prod.lhs() for prod in productions} self._calculate_indexes() self._calculate_grammar_forms() if calculate_leftcorners: self._calculate_leftcorners() def _calculate_indexes(self): self._lhs_index = {} self._rhs_index = {} self._empty_index = {} self._lexical_index = {} for prod in self._productions: # Left hand side. lhs = prod._lhs if lhs not in self._lhs_index: self._lhs_index[lhs] = [] self._lhs_index[lhs].append(prod) if prod._rhs: # First item in right hand side. rhs0 = prod._rhs[0] if rhs0 not in self._rhs_index: self._rhs_index[rhs0] = [] self._rhs_index[rhs0].append(prod) else: # The right hand side is empty. self._empty_index[prod.lhs()] = prod # Lexical tokens in the right hand side. for token in prod._rhs: if is_terminal(token): self._lexical_index.setdefault(token, set()).add(prod) def _calculate_leftcorners(self): # Calculate leftcorner relations, for use in optimized parsing. self._immediate_leftcorner_categories = {cat: {cat} for cat in self._categories} self._immediate_leftcorner_words = {cat: set() for cat in self._categories} for prod in self.productions(): if len(prod) > 0: cat, left = prod.lhs(), prod.rhs()[0] if is_nonterminal(left): self._immediate_leftcorner_categories[cat].add(left) else: self._immediate_leftcorner_words[cat].add(left) lc = transitive_closure(self._immediate_leftcorner_categories, reflexive=True) self._leftcorners = lc self._leftcorner_parents = invert_graph(lc) nr_leftcorner_categories = sum( map(len, self._immediate_leftcorner_categories.values()) ) nr_leftcorner_words = sum(map(len, self._immediate_leftcorner_words.values())) if nr_leftcorner_words > nr_leftcorner_categories > 10000: # If the grammar is big, the leftcorner-word dictionary will be too large. # In that case it is better to calculate the relation on demand. self._leftcorner_words = None return self._leftcorner_words = {} for cat in self._leftcorners: lefts = self._leftcorners[cat] lc = self._leftcorner_words[cat] = set() for left in lefts: lc.update(self._immediate_leftcorner_words.get(left, set())) @classmethod def fromstring(cls, input, encoding=None): """ Return the grammar instance corresponding to the input string(s). :param input: a grammar, either in the form of a string or as a list of strings. """ start, productions = read_grammar( input, standard_nonterm_parser, encoding=encoding ) return cls(start, productions) def start(self): """ Return the start symbol of the grammar :rtype: Nonterminal """ return self._start # tricky to balance readability and efficiency here! # can't use set operations as they don't preserve ordering def productions(self, lhs=None, rhs=None, empty=False): """ Return the grammar productions, filtered by the left-hand side or the first item in the right-hand side. :param lhs: Only return productions with the given left-hand side. :param rhs: Only return productions with the given first item in the right-hand side. :param empty: Only return productions with an empty right-hand side. :return: A list of productions matching the given constraints. :rtype: list(Production) """ if rhs and empty: raise ValueError( "You cannot select empty and non-empty " "productions at the same time." ) # no constraints so return everything if not lhs and not rhs: if not empty: return self._productions else: return self._empty_index.values() # only lhs specified so look up its index elif lhs and not rhs: if not empty: return self._lhs_index.get(lhs, []) elif lhs in self._empty_index: return [self._empty_index[lhs]] else: return [] # only rhs specified so look up its index elif rhs and not lhs: return self._rhs_index.get(rhs, []) # intersect else: return [ prod for prod in self._lhs_index.get(lhs, []) if prod in self._rhs_index.get(rhs, []) ] def leftcorners(self, cat): """ Return the set of all nonterminals that the given nonterminal can start with, including itself. This is the reflexive, transitive closure of the immediate leftcorner relation: (A > B) iff (A -> B beta) :param cat: the parent of the leftcorners :type cat: Nonterminal :return: the set of all leftcorners :rtype: set(Nonterminal) """ return self._leftcorners.get(cat, {cat}) def is_leftcorner(self, cat, left): """ True if left is a leftcorner of cat, where left can be a terminal or a nonterminal. :param cat: the parent of the leftcorner :type cat: Nonterminal :param left: the suggested leftcorner :type left: Terminal or Nonterminal :rtype: bool """ if is_nonterminal(left): return left in self.leftcorners(cat) elif self._leftcorner_words: return left in self._leftcorner_words.get(cat, set()) else: return any( left in self._immediate_leftcorner_words.get(parent, set()) for parent in self.leftcorners(cat) ) def leftcorner_parents(self, cat): """ Return the set of all nonterminals for which the given category is a left corner. This is the inverse of the leftcorner relation. :param cat: the suggested leftcorner :type cat: Nonterminal :return: the set of all parents to the leftcorner :rtype: set(Nonterminal) """ return self._leftcorner_parents.get(cat, {cat}) def check_coverage(self, tokens): """ Check whether the grammar rules cover the given list of tokens. If not, then raise an exception. :type tokens: list(str) """ missing = [tok for tok in tokens if not self._lexical_index.get(tok)] if missing: missing = ", ".join(f"{w!r}" for w in missing) raise ValueError( "Grammar does not cover some of the " "input words: %r." % missing ) def _calculate_grammar_forms(self): """ Pre-calculate of which form(s) the grammar is. """ prods = self._productions self._is_lexical = all(p.is_lexical() for p in prods) self._is_nonlexical = all(p.is_nonlexical() for p in prods if len(p) != 1) self._min_len = min(len(p) for p in prods) self._max_len = max(len(p) for p in prods) self._all_unary_are_lexical = all(p.is_lexical() for p in prods if len(p) == 1) def is_lexical(self): """ Return True if all productions are lexicalised. """ return self._is_lexical def is_nonlexical(self): """ Return True if all lexical rules are "preterminals", that is, unary rules which can be separated in a preprocessing step. This means that all productions are of the forms A -> B1 ... Bn (n>=0), or A -> "s". Note: is_lexical() and is_nonlexical() are not opposites. There are grammars which are neither, and grammars which are both. """ return self._is_nonlexical def min_len(self): """ Return the right-hand side length of the shortest grammar production. """ return self._min_len def max_len(self): """ Return the right-hand side length of the longest grammar production. """ return self._max_len def is_nonempty(self): """ Return True if there are no empty productions. """ return self._min_len > 0 def is_binarised(self): """ Return True if all productions are at most binary. Note that there can still be empty and unary productions. """ return self._max_len <= 2 def is_flexible_chomsky_normal_form(self): """ Return True if all productions are of the forms A -> B C, A -> B, or A -> "s". """ return self.is_nonempty() and self.is_nonlexical() and self.is_binarised() def is_chomsky_normal_form(self): """ Return True if the grammar is of Chomsky Normal Form, i.e. all productions are of the form A -> B C, or A -> "s". """ return self.is_flexible_chomsky_normal_form() and self._all_unary_are_lexical def chomsky_normal_form(self, new_token_padding="@$@", flexible=False): """ Returns a new Grammar that is in chomsky normal :param: new_token_padding Customise new rule formation during binarisation """ if self.is_chomsky_normal_form(): return self if self.productions(empty=True): raise ValueError( "Grammar has Empty rules. " "Cannot deal with them at the moment" ) # check for mixed rules for rule in self.productions(): if rule.is_lexical() and len(rule.rhs()) > 1: raise ValueError( f"Cannot handled mixed rule {rule.lhs()} => {rule.rhs()}" ) step1 = CFG.eliminate_start(self) step2 = CFG.binarize(step1, new_token_padding) if flexible: return step2 step3 = CFG.remove_unitary_rules(step2) step4 = CFG(step3.start(), list(set(step3.productions()))) return step4 @classmethod def remove_unitary_rules(cls, grammar): """ Remove nonlexical unitary rules and convert them to lexical """ result = [] unitary = [] for rule in grammar.productions(): if len(rule) == 1 and rule.is_nonlexical(): unitary.append(rule) else: result.append(rule) while unitary: rule = unitary.pop(0) for item in grammar.productions(lhs=rule.rhs()[0]): new_rule = Production(rule.lhs(), item.rhs()) if len(new_rule) != 1 or new_rule.is_lexical(): result.append(new_rule) else: unitary.append(new_rule) n_grammar = CFG(grammar.start(), result) return n_grammar @classmethod def binarize(cls, grammar, padding="@$@"): """ Convert all non-binary rules into binary by introducing new tokens. Example:: Original: A => B C D After Conversion: A => B A@$@B A@$@B => C D """ result = [] for rule in grammar.productions(): if len(rule.rhs()) > 2: # this rule needs to be broken down left_side = rule.lhs() for k in range(0, len(rule.rhs()) - 2): tsym = rule.rhs()[k] new_sym = Nonterminal(left_side.symbol() + padding + tsym.symbol()) new_production = Production(left_side, (tsym, new_sym)) left_side = new_sym result.append(new_production) last_prd = Production(left_side, rule.rhs()[-2:]) result.append(last_prd) else: result.append(rule) n_grammar = CFG(grammar.start(), result) return n_grammar @classmethod def eliminate_start(cls, grammar): """ Eliminate start rule in case it appears on RHS Example: S -> S0 S1 and S0 -> S1 S Then another rule S0_Sigma -> S is added """ start = grammar.start() result = [] need_to_add = None for rule in grammar.productions(): if start in rule.rhs(): need_to_add = True result.append(rule) if need_to_add: start = Nonterminal("S0_SIGMA") result.append(Production(start, [grammar.start()])) n_grammar = CFG(start, result) return n_grammar return grammar def __repr__(self): return "" % len(self._productions) def __str__(self): result = "Grammar with %d productions" % len(self._productions) result += " (start state = %r)" % self._start for production in self._productions: result += "\n %s" % production return result class FeatureGrammar(CFG): """ A feature-based grammar. This is equivalent to a ``CFG`` whose nonterminals are all ``FeatStructNonterminal``. A grammar consists of a start state and a set of productions. The set of terminals and nonterminals is implicitly specified by the productions. """ def __init__(self, start, productions): """ Create a new feature-based grammar, from the given start state and set of ``Productions``. :param start: The start symbol :type start: FeatStructNonterminal :param productions: The list of productions that defines the grammar :type productions: list(Production) """ CFG.__init__(self, start, productions) # The difference with CFG is that the productions are # indexed on the TYPE feature of the nonterminals. # This is calculated by the method _get_type_if_possible(). def _calculate_indexes(self): self._lhs_index = {} self._rhs_index = {} self._empty_index = {} self._empty_productions = [] self._lexical_index = {} for prod in self._productions: # Left hand side. lhs = self._get_type_if_possible(prod._lhs) if lhs not in self._lhs_index: self._lhs_index[lhs] = [] self._lhs_index[lhs].append(prod) if prod._rhs: # First item in right hand side. rhs0 = self._get_type_if_possible(prod._rhs[0]) if rhs0 not in self._rhs_index: self._rhs_index[rhs0] = [] self._rhs_index[rhs0].append(prod) else: # The right hand side is empty. if lhs not in self._empty_index: self._empty_index[lhs] = [] self._empty_index[lhs].append(prod) self._empty_productions.append(prod) # Lexical tokens in the right hand side. for token in prod._rhs: if is_terminal(token): self._lexical_index.setdefault(token, set()).add(prod) @classmethod def fromstring( cls, input, features=None, logic_parser=None, fstruct_reader=None, encoding=None ): """ Return a feature structure based grammar. :param input: a grammar, either in the form of a string or else as a list of strings. :param features: a tuple of features (default: SLASH, TYPE) :param logic_parser: a parser for lambda-expressions, by default, ``LogicParser()`` :param fstruct_reader: a feature structure parser (only if features and logic_parser is None) """ if features is None: features = (SLASH, TYPE) if fstruct_reader is None: fstruct_reader = FeatStructReader( features, FeatStructNonterminal, logic_parser=logic_parser ) elif logic_parser is not None: raise Exception( "'logic_parser' and 'fstruct_reader' must " "not both be set" ) start, productions = read_grammar( input, fstruct_reader.read_partial, encoding=encoding ) return cls(start, productions) def productions(self, lhs=None, rhs=None, empty=False): """ Return the grammar productions, filtered by the left-hand side or the first item in the right-hand side. :param lhs: Only return productions with the given left-hand side. :param rhs: Only return productions with the given first item in the right-hand side. :param empty: Only return productions with an empty right-hand side. :rtype: list(Production) """ if rhs and empty: raise ValueError( "You cannot select empty and non-empty " "productions at the same time." ) # no constraints so return everything if not lhs and not rhs: if empty: return self._empty_productions else: return self._productions # only lhs specified so look up its index elif lhs and not rhs: if empty: return self._empty_index.get(self._get_type_if_possible(lhs), []) else: return self._lhs_index.get(self._get_type_if_possible(lhs), []) # only rhs specified so look up its index elif rhs and not lhs: return self._rhs_index.get(self._get_type_if_possible(rhs), []) # intersect else: return [ prod for prod in self._lhs_index.get(self._get_type_if_possible(lhs), []) if prod in self._rhs_index.get(self._get_type_if_possible(rhs), []) ] def leftcorners(self, cat): """ Return the set of all words that the given category can start with. Also called the "first set" in compiler construction. """ raise NotImplementedError("Not implemented yet") def leftcorner_parents(self, cat): """ Return the set of all categories for which the given category is a left corner. """ raise NotImplementedError("Not implemented yet") def _get_type_if_possible(self, item): """ Helper function which returns the ``TYPE`` feature of the ``item``, if it exists, otherwise it returns the ``item`` itself """ if isinstance(item, dict) and TYPE in item: return FeatureValueType(item[TYPE]) else: return item @total_ordering class FeatureValueType: """ A helper class for ``FeatureGrammars``, designed to be different from ordinary strings. This is to stop the ``FeatStruct`` ``FOO[]`` from being compare equal to the terminal "FOO". """ def __init__(self, value): self._value = value def __repr__(self): return "<%s>" % self._value def __eq__(self, other): return type(self) == type(other) and self._value == other._value def __ne__(self, other): return not self == other def __lt__(self, other): if not isinstance(other, FeatureValueType): raise_unorderable_types("<", self, other) return self._value < other._value def __hash__(self): return hash(self._value) class DependencyGrammar: """ A dependency grammar. A DependencyGrammar consists of a set of productions. Each production specifies a head/modifier relationship between a pair of words. """ def __init__(self, productions): """ Create a new dependency grammar, from the set of ``Productions``. :param productions: The list of productions that defines the grammar :type productions: list(Production) """ self._productions = productions @classmethod def fromstring(cls, input): productions = [] for linenum, line in enumerate(input.split("\n")): line = line.strip() if line.startswith("#") or line == "": continue try: productions += _read_dependency_production(line) except ValueError as e: raise ValueError(f"Unable to parse line {linenum}: {line}") from e if len(productions) == 0: raise ValueError("No productions found!") return cls(productions) def contains(self, head, mod): """ :param head: A head word. :type head: str :param mod: A mod word, to test as a modifier of 'head'. :type mod: str :return: true if this ``DependencyGrammar`` contains a ``DependencyProduction`` mapping 'head' to 'mod'. :rtype: bool """ for production in self._productions: for possibleMod in production._rhs: if production._lhs == head and possibleMod == mod: return True return False def __contains__(self, head_mod): """ Return True if this ``DependencyGrammar`` contains a ``DependencyProduction`` mapping 'head' to 'mod'. :param head_mod: A tuple of a head word and a mod word, to test as a modifier of 'head'. :type head: Tuple[str, str] :rtype: bool """ try: head, mod = head_mod except ValueError as e: raise ValueError( "Must use a tuple of strings, e.g. `('price', 'of') in grammar`" ) from e return self.contains(head, mod) # # should be rewritten, the set comp won't work in all comparisons # def contains_exactly(self, head, modlist): # for production in self._productions: # if(len(production._rhs) == len(modlist)): # if(production._lhs == head): # set1 = Set(production._rhs) # set2 = Set(modlist) # if(set1 == set2): # return True # return False def __str__(self): """ Return a verbose string representation of the ``DependencyGrammar`` :rtype: str """ str = "Dependency grammar with %d productions" % len(self._productions) for production in self._productions: str += "\n %s" % production return str def __repr__(self): """ Return a concise string representation of the ``DependencyGrammar`` """ return "Dependency grammar with %d productions" % len(self._productions) class ProbabilisticDependencyGrammar: """ """ def __init__(self, productions, events, tags): self._productions = productions self._events = events self._tags = tags def contains(self, head, mod): """ Return True if this ``DependencyGrammar`` contains a ``DependencyProduction`` mapping 'head' to 'mod'. :param head: A head word. :type head: str :param mod: A mod word, to test as a modifier of 'head'. :type mod: str :rtype: bool """ for production in self._productions: for possibleMod in production._rhs: if production._lhs == head and possibleMod == mod: return True return False def __str__(self): """ Return a verbose string representation of the ``ProbabilisticDependencyGrammar`` :rtype: str """ str = "Statistical dependency grammar with %d productions" % len( self._productions ) for production in self._productions: str += "\n %s" % production str += "\nEvents:" for event in self._events: str += "\n %d:%s" % (self._events[event], event) str += "\nTags:" for tag_word in self._tags: str += f"\n {tag_word}:\t({self._tags[tag_word]})" return str def __repr__(self): """ Return a concise string representation of the ``ProbabilisticDependencyGrammar`` """ return "Statistical Dependency grammar with %d productions" % len( self._productions ) class PCFG(CFG): """ A probabilistic context-free grammar. A PCFG consists of a start state and a set of productions with probabilities. The set of terminals and nonterminals is implicitly specified by the productions. PCFG productions use the ``ProbabilisticProduction`` class. ``PCFGs`` impose the constraint that the set of productions with any given left-hand-side must have probabilities that sum to 1 (allowing for a small margin of error). If you need efficient key-based access to productions, you can use a subclass to implement it. :type EPSILON: float :cvar EPSILON: The acceptable margin of error for checking that productions with a given left-hand side have probabilities that sum to 1. """ EPSILON = 0.01 def __init__(self, start, productions, calculate_leftcorners=True): """ Create a new context-free grammar, from the given start state and set of ``ProbabilisticProductions``. :param start: The start symbol :type start: Nonterminal :param productions: The list of productions that defines the grammar :type productions: list(Production) :raise ValueError: if the set of productions with any left-hand-side do not have probabilities that sum to a value within EPSILON of 1. :param calculate_leftcorners: False if we don't want to calculate the leftcorner relation. In that case, some optimized chart parsers won't work. :type calculate_leftcorners: bool """ CFG.__init__(self, start, productions, calculate_leftcorners) # Make sure that the probabilities sum to one. probs = {} for production in productions: probs[production.lhs()] = probs.get(production.lhs(), 0) + production.prob() for (lhs, p) in probs.items(): if not ((1 - PCFG.EPSILON) < p < (1 + PCFG.EPSILON)): raise ValueError("Productions for %r do not sum to 1" % lhs) @classmethod def fromstring(cls, input, encoding=None): """ Return a probabilistic context-free grammar corresponding to the input string(s). :param input: a grammar, either in the form of a string or else as a list of strings. """ start, productions = read_grammar( input, standard_nonterm_parser, probabilistic=True, encoding=encoding ) return cls(start, productions) ################################################################# # Inducing Grammars ################################################################# # Contributed by Nathan Bodenstab def induce_pcfg(start, productions): r""" Induce a PCFG grammar from a list of productions. The probability of a production A -> B C in a PCFG is: | count(A -> B C) | P(B, C | A) = --------------- where \* is any right hand side | count(A -> \*) :param start: The start symbol :type start: Nonterminal :param productions: The list of productions that defines the grammar :type productions: list(Production) """ # Production count: the number of times a given production occurs pcount = {} # LHS-count: counts the number of times a given lhs occurs lcount = {} for prod in productions: lcount[prod.lhs()] = lcount.get(prod.lhs(), 0) + 1 pcount[prod] = pcount.get(prod, 0) + 1 prods = [ ProbabilisticProduction(p.lhs(), p.rhs(), prob=pcount[p] / lcount[p.lhs()]) for p in pcount ] return PCFG(start, prods) ################################################################# # Helper functions for reading productions ################################################################# def _read_cfg_production(input): """ Return a list of context-free ``Productions``. """ return _read_production(input, standard_nonterm_parser) def _read_pcfg_production(input): """ Return a list of PCFG ``ProbabilisticProductions``. """ return _read_production(input, standard_nonterm_parser, probabilistic=True) def _read_fcfg_production(input, fstruct_reader): """ Return a list of feature-based ``Productions``. """ return _read_production(input, fstruct_reader) # Parsing generic grammars _ARROW_RE = re.compile(r"\s* -> \s*", re.VERBOSE) _PROBABILITY_RE = re.compile(r"( \[ [\d\.]+ \] ) \s*", re.VERBOSE) _TERMINAL_RE = re.compile(r'( "[^"]*" | \'[^\']*\' ) \s*', re.VERBOSE) _DISJUNCTION_RE = re.compile(r"\| \s*", re.VERBOSE) def _read_production(line, nonterm_parser, probabilistic=False): """ Parse a grammar rule, given as a string, and return a list of productions. """ pos = 0 # Parse the left-hand side. lhs, pos = nonterm_parser(line, pos) # Skip over the arrow. m = _ARROW_RE.match(line, pos) if not m: raise ValueError("Expected an arrow") pos = m.end() # Parse the right hand side. probabilities = [0.0] rhsides = [[]] while pos < len(line): # Probability. m = _PROBABILITY_RE.match(line, pos) if probabilistic and m: pos = m.end() probabilities[-1] = float(m.group(1)[1:-1]) if probabilities[-1] > 1.0: raise ValueError( "Production probability %f, " "should not be greater than 1.0" % (probabilities[-1],) ) # String -- add terminal. elif line[pos] in "'\"": m = _TERMINAL_RE.match(line, pos) if not m: raise ValueError("Unterminated string") rhsides[-1].append(m.group(1)[1:-1]) pos = m.end() # Vertical bar -- start new rhside. elif line[pos] == "|": m = _DISJUNCTION_RE.match(line, pos) probabilities.append(0.0) rhsides.append([]) pos = m.end() # Anything else -- nonterminal. else: nonterm, pos = nonterm_parser(line, pos) rhsides[-1].append(nonterm) if probabilistic: return [ ProbabilisticProduction(lhs, rhs, prob=probability) for (rhs, probability) in zip(rhsides, probabilities) ] else: return [Production(lhs, rhs) for rhs in rhsides] ################################################################# # Reading Phrase Structure Grammars ################################################################# def read_grammar(input, nonterm_parser, probabilistic=False, encoding=None): """ Return a pair consisting of a starting category and a list of ``Productions``. :param input: a grammar, either in the form of a string or else as a list of strings. :param nonterm_parser: a function for parsing nonterminals. It should take a ``(string, position)`` as argument and return a ``(nonterminal, position)`` as result. :param probabilistic: are the grammar rules probabilistic? :type probabilistic: bool :param encoding: the encoding of the grammar, if it is a binary string :type encoding: str """ if encoding is not None: input = input.decode(encoding) if isinstance(input, str): lines = input.split("\n") else: lines = input start = None productions = [] continue_line = "" for linenum, line in enumerate(lines): line = continue_line + line.strip() if line.startswith("#") or line == "": continue if line.endswith("\\"): continue_line = line[:-1].rstrip() + " " continue continue_line = "" try: if line[0] == "%": directive, args = line[1:].split(None, 1) if directive == "start": start, pos = nonterm_parser(args, 0) if pos != len(args): raise ValueError("Bad argument to start directive") else: raise ValueError("Bad directive") else: # expand out the disjunctions on the RHS productions += _read_production(line, nonterm_parser, probabilistic) except ValueError as e: raise ValueError(f"Unable to parse line {linenum + 1}: {line}\n{e}") from e if not productions: raise ValueError("No productions found!") if not start: start = productions[0].lhs() return (start, productions) _STANDARD_NONTERM_RE = re.compile(r"( [\w/][\w/^<>-]* ) \s*", re.VERBOSE) def standard_nonterm_parser(string, pos): m = _STANDARD_NONTERM_RE.match(string, pos) if not m: raise ValueError("Expected a nonterminal, found: " + string[pos:]) return (Nonterminal(m.group(1)), m.end()) ################################################################# # Reading Dependency Grammars ################################################################# _READ_DG_RE = re.compile( r"""^\s* # leading whitespace ('[^']+')\s* # single-quoted lhs (?:[-=]+>)\s* # arrow (?:( # rhs: "[^"]+" # doubled-quoted terminal | '[^']+' # single-quoted terminal | \| # disjunction ) \s*) # trailing space *$""", # zero or more copies re.VERBOSE, ) _SPLIT_DG_RE = re.compile(r"""('[^']'|[-=]+>|"[^"]+"|'[^']+'|\|)""") def _read_dependency_production(s): if not _READ_DG_RE.match(s): raise ValueError("Bad production string") pieces = _SPLIT_DG_RE.split(s) pieces = [p for i, p in enumerate(pieces) if i % 2 == 1] lhside = pieces[0].strip("'\"") rhsides = [[]] for piece in pieces[2:]: if piece == "|": rhsides.append([]) else: rhsides[-1].append(piece.strip("'\"")) return [DependencyProduction(lhside, rhside) for rhside in rhsides] ################################################################# # Demonstration ################################################################# def cfg_demo(): """ A demonstration showing how ``CFGs`` can be created and used. """ from nltk import CFG, Production, nonterminals # Create some nonterminals S, NP, VP, PP = nonterminals("S, NP, VP, PP") N, V, P, Det = nonterminals("N, V, P, Det") VP_slash_NP = VP / NP print("Some nonterminals:", [S, NP, VP, PP, N, V, P, Det, VP / NP]) print(" S.symbol() =>", repr(S.symbol())) print() print(Production(S, [NP])) # Create some Grammar Productions grammar = CFG.fromstring( """ S -> NP VP PP -> P NP NP -> Det N | NP PP VP -> V NP | VP PP Det -> 'a' | 'the' N -> 'dog' | 'cat' V -> 'chased' | 'sat' P -> 'on' | 'in' """ ) print("A Grammar:", repr(grammar)) print(" grammar.start() =>", repr(grammar.start())) print(" grammar.productions() =>", end=" ") # Use string.replace(...) is to line-wrap the output. print(repr(grammar.productions()).replace(",", ",\n" + " " * 25)) print() def pcfg_demo(): """ A demonstration showing how a ``PCFG`` can be created and used. """ from nltk import induce_pcfg, treetransforms from nltk.corpus import treebank from nltk.parse import pchart toy_pcfg1 = PCFG.fromstring( """ S -> NP VP [1.0] NP -> Det N [0.5] | NP PP [0.25] | 'John' [0.1] | 'I' [0.15] Det -> 'the' [0.8] | 'my' [0.2] N -> 'man' [0.5] | 'telescope' [0.5] VP -> VP PP [0.1] | V NP [0.7] | V [0.2] V -> 'ate' [0.35] | 'saw' [0.65] PP -> P NP [1.0] P -> 'with' [0.61] | 'under' [0.39] """ ) toy_pcfg2 = PCFG.fromstring( """ S -> NP VP [1.0] VP -> V NP [.59] VP -> V [.40] VP -> VP PP [.01] NP -> Det N [.41] NP -> Name [.28] NP -> NP PP [.31] PP -> P NP [1.0] V -> 'saw' [.21] V -> 'ate' [.51] V -> 'ran' [.28] N -> 'boy' [.11] N -> 'cookie' [.12] N -> 'table' [.13] N -> 'telescope' [.14] N -> 'hill' [.5] Name -> 'Jack' [.52] Name -> 'Bob' [.48] P -> 'with' [.61] P -> 'under' [.39] Det -> 'the' [.41] Det -> 'a' [.31] Det -> 'my' [.28] """ ) pcfg_prods = toy_pcfg1.productions() pcfg_prod = pcfg_prods[2] print("A PCFG production:", repr(pcfg_prod)) print(" pcfg_prod.lhs() =>", repr(pcfg_prod.lhs())) print(" pcfg_prod.rhs() =>", repr(pcfg_prod.rhs())) print(" pcfg_prod.prob() =>", repr(pcfg_prod.prob())) print() grammar = toy_pcfg2 print("A PCFG grammar:", repr(grammar)) print(" grammar.start() =>", repr(grammar.start())) print(" grammar.productions() =>", end=" ") # Use .replace(...) is to line-wrap the output. print(repr(grammar.productions()).replace(",", ",\n" + " " * 26)) print() # extract productions from three trees and induce the PCFG print("Induce PCFG grammar from treebank data:") productions = [] item = treebank._fileids[0] for tree in treebank.parsed_sents(item)[:3]: # perform optional tree transformations, e.g.: tree.collapse_unary(collapsePOS=False) tree.chomsky_normal_form(horzMarkov=2) productions += tree.productions() S = Nonterminal("S") grammar = induce_pcfg(S, productions) print(grammar) print() print("Parse sentence using induced grammar:") parser = pchart.InsideChartParser(grammar) parser.trace(3) # doesn't work as tokens are different: # sent = treebank.tokenized('wsj_0001.mrg')[0] sent = treebank.parsed_sents(item)[0].leaves() print(sent) for parse in parser.parse(sent): print(parse) def fcfg_demo(): import nltk.data g = nltk.data.load("grammars/book_grammars/feat0.fcfg") print(g) print() def dg_demo(): """ A demonstration showing the creation and inspection of a ``DependencyGrammar``. """ grammar = DependencyGrammar.fromstring( """ 'scratch' -> 'cats' | 'walls' 'walls' -> 'the' 'cats' -> 'the' """ ) print(grammar) def sdg_demo(): """ A demonstration of how to read a string representation of a CoNLL format dependency tree. """ from nltk.parse import DependencyGraph dg = DependencyGraph( """ 1 Ze ze Pron Pron per|3|evofmv|nom 2 su _ _ 2 had heb V V trans|ovt|1of2of3|ev 0 ROOT _ _ 3 met met Prep Prep voor 8 mod _ _ 4 haar haar Pron Pron bez|3|ev|neut|attr 5 det _ _ 5 moeder moeder N N soort|ev|neut 3 obj1 _ _ 6 kunnen kan V V hulp|ott|1of2of3|mv 2 vc _ _ 7 gaan ga V V hulp|inf 6 vc _ _ 8 winkelen winkel V V intrans|inf 11 cnj _ _ 9 , , Punc Punc komma 8 punct _ _ 10 zwemmen zwem V V intrans|inf 11 cnj _ _ 11 of of Conj Conj neven 7 vc _ _ 12 terrassen terras N N soort|mv|neut 11 cnj _ _ 13 . . Punc Punc punt 12 punct _ _ """ ) tree = dg.tree() print(tree.pprint()) def demo(): cfg_demo() pcfg_demo() fcfg_demo() dg_demo() sdg_demo() if __name__ == "__main__": demo() __all__ = [ "Nonterminal", "nonterminals", "CFG", "Production", "PCFG", "ProbabilisticProduction", "DependencyGrammar", "DependencyProduction", "ProbabilisticDependencyGrammar", "induce_pcfg", "read_grammar", ]