# Copyright 2011 Matt Chaput. All rights reserved. # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions are met: # # 1. Redistributions of source code must retain the above copyright notice, # this list of conditions and the following disclaimer. # # 2. Redistributions in binary form must reproduce the above copyright # notice, this list of conditions and the following disclaimer in the # documentation and/or other materials provided with the distribution. # # THIS SOFTWARE IS PROVIDED BY MATT CHAPUT ``AS IS'' AND ANY EXPRESS OR # IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF # MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO # EVENT SHALL MATT CHAPUT OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, # INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, # OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF # LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING # NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, # EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. # # The views and conclusions contained in the software and documentation are # those of the authors and should not be interpreted as representing official # policies, either expressed or implied, of Matt Chaput. import sys, weakref from whoosh import query from whoosh.qparser.common import get_single_text, QueryParserError, attach class SyntaxNode(object): """Base class for nodes that make up the abstract syntax tree (AST) of a parsed user query string. The AST is an intermediate step, generated from the query string, then converted into a :class:`whoosh.query.Query` tree by calling the ``query()`` method on the nodes. Instances have the following required attributes: ``has_fieldname`` True if this node has a ``fieldname`` attribute. ``has_text`` True if this node has a ``text`` attribute ``has_boost`` True if this node has a ``boost`` attribute. ``startchar`` The character position in the original text at which this node started. ``endchar`` The character position in the original text at which this node ended. """ has_fieldname = False has_text = False has_boost = False _parent = None def __repr__(self): r = "<" if self.has_fieldname: r += "%r:" % self.fieldname r += self.r() if self.has_boost and self.boost != 1.0: r += " ^%s" % self.boost r += ">" return r def r(self): """Returns a basic representation of this node. The base class's ``__repr__`` method calls this, then does the extra busy work of adding fieldname and boost where appropriate. """ return "%s %r" % (self.__class__.__name__, self.__dict__) def apply(self, fn): return self def accept(self, fn): def fn_wrapper(n): return fn(n.apply(fn_wrapper)) return fn_wrapper(self) def query(self, parser): """Returns a :class:`whoosh.query.Query` instance corresponding to this syntax tree node. """ raise NotImplementedError(self.__class__.__name__) def is_ws(self): """Returns True if this node is ignorable whitespace. """ return False def is_text(self): return False def set_fieldname(self, name, override=False): """Sets the fieldname associated with this node. If ``override`` is False (the default), the fieldname will only be replaced if this node does not already have a fieldname set. For nodes that don't have a fieldname, this is a no-op. """ if not self.has_fieldname: return if self.fieldname is None or override: self.fieldname = name return self def set_boost(self, boost): """Sets the boost associated with this node. For nodes that don't have a boost, this is a no-op. """ if not self.has_boost: return self.boost = boost return self def set_range(self, startchar, endchar): """Sets the character range associated with this node. """ self.startchar = startchar self.endchar = endchar return self # Navigation methods def parent(self): if self._parent: return self._parent() def next_sibling(self): p = self.parent() if p: return p.node_after(self) def prev_sibling(self): p = self.parent() if p: return p.node_before(self) def bake(self, parent): self._parent = weakref.ref(parent) class MarkerNode(SyntaxNode): """Base class for nodes that only exist to mark places in the tree. """ def r(self): return self.__class__.__name__ class Whitespace(MarkerNode): """Abstract syntax tree node for ignorable whitespace. """ def r(self): return " " def is_ws(self): return True class FieldnameNode(SyntaxNode): """Abstract syntax tree node for field name assignments. """ has_fieldname = True def __init__(self, fieldname, original): self.fieldname = fieldname self.original = original def __repr__(self): return "<%r:>" % self.fieldname class GroupNode(SyntaxNode): """Base class for abstract syntax tree node types that group together sub-nodes. Instances have the following attributes: ``merging`` True if side-by-side instances of this group can be merged into a single group. ``qclass`` If a subclass doesn't override ``query()``, the base class will simply wrap this class around the queries returned by the subnodes. This class implements a number of list methods for operating on the subnodes. """ has_boost = True merging = True qclass = None def __init__(self, nodes=None, boost=1.0, **kwargs): self.nodes = nodes or [] self.boost = boost self.kwargs = kwargs def r(self): return "%s %s" % (self.__class__.__name__, ", ".join(repr(n) for n in self.nodes)) @property def startchar(self): if not self.nodes: return None return self.nodes[0].startchar @property def endchar(self): if not self.nodes: return None return self.nodes[-1].endchar def apply(self, fn): return self.__class__(self.type, [fn(node) for node in self.nodes], boost=self.boost, **self.kwargs) def query(self, parser): subs = [] for node in self.nodes: subq = node.query(parser) if subq is not None: subs.append(subq) q = self.qclass(subs, boost=self.boost, **self.kwargs) return attach(q, self) def empty_copy(self): """Returns an empty copy of this group. This is used in the common pattern where a filter creates an new group and then adds nodes from the input group to it if they meet certain criteria, then returns the new group:: def remove_whitespace(parser, group): newgroup = group.empty_copy() for node in group: if not node.is_ws(): newgroup.append(node) return newgroup """ c = self.__class__(**self.kwargs) if self.has_boost: c.boost = self.boost if self.has_fieldname: c.fieldname = self.fieldname if self.has_text: c.text = self.text return c def set_fieldname(self, name, override=False): SyntaxNode.set_fieldname(self, name, override=override) for node in self.nodes: node.set_fieldname(name, override=override) def set_range(self, startchar, endchar): for node in self.nodes: node.set_range(startchar, endchar) return self # List-like methods def __nonzero__(self): return bool(self.nodes) __bool__ = __nonzero__ def __iter__(self): return iter(self.nodes) def __len__(self): return len(self.nodes) def __getitem__(self, n): return self.nodes.__getitem__(n) def __setitem__(self, n, v): self.nodes.__setitem__(n, v) def __delitem__(self, n): self.nodes.__delitem__(n) def insert(self, n, v): self.nodes.insert(n, v) def append(self, v): self.nodes.append(v) def extend(self, vs): self.nodes.extend(vs) def pop(self, *args, **kwargs): return self.nodes.pop(*args, **kwargs) def reverse(self): self.nodes.reverse() def index(self, v): return self.nodes.index(v) # Navigation methods def bake(self, parent): SyntaxNode.bake(self, parent) for node in self.nodes: node.bake(self) def node_before(self, n): try: i = self.nodes.index(n) except ValueError: return if i > 0: return self.nodes[i - 1] def node_after(self, n): try: i = self.nodes.index(n) except ValueError: return if i < len(self.nodes) - 2: return self.nodes[i + 1] class BinaryGroup(GroupNode): """Intermediate base class for group nodes that have two subnodes and whose ``qclass`` initializer takes two arguments instead of a list. """ merging = False has_boost = False def query(self, parser): assert len(self.nodes) == 2 qa = self.nodes[0].query(parser) qb = self.nodes[1].query(parser) if qa is None and qb is None: q = query.NullQuery elif qa is None: q = qb elif qb is None: q = qa else: q = self.qclass(self.nodes[0].query(parser), self.nodes[1].query(parser)) return attach(q, self) class Wrapper(GroupNode): """Intermediate base class for nodes that wrap a single sub-node. """ merging = False def query(self, parser): q = self.nodes[0].query(parser) if q: return attach(self.qclass(q), self) class ErrorNode(SyntaxNode): def __init__(self, message, node=None): self.message = message self.node = node def r(self): return "ERR %r %r" % (self.node, self.message) @property def startchar(self): return self.node.startchar @property def endchar(self): return self.node.endchar def query(self, parser): if self.node: q = self.node.query(parser) else: q = query.NullQuery return attach(query.error_query(self.message, q), self) class AndGroup(GroupNode): qclass = query.And class OrGroup(GroupNode): qclass = query.Or @classmethod def factory(cls, scale=1.0): class ScaledOrGroup(OrGroup): def __init__(self, nodes=None, **kwargs): if "scale" in kwargs: del kwargs["scale"] super(ScaledOrGroup, self).__init__(nodes=nodes, scale=scale, **kwargs) return ScaledOrGroup class DisMaxGroup(GroupNode): qclass = query.DisjunctionMax class OrderedGroup(GroupNode): qclass = query.Ordered class AndNotGroup(BinaryGroup): qclass = query.AndNot class AndMaybeGroup(BinaryGroup): qclass = query.AndMaybe class RequireGroup(BinaryGroup): qclass = query.Require class NotGroup(Wrapper): qclass = query.Not class RangeNode(SyntaxNode): """Syntax node for range queries. """ has_fieldname = True def __init__(self, start, end, startexcl, endexcl): self.start = start self.end = end self.startexcl = startexcl self.endexcl = endexcl self.boost = 1.0 self.fieldname = None self.kwargs = {} def r(self): b1 = "{" if self.startexcl else "[" b2 = "}" if self.endexcl else "]" return "%s%r %r%s" % (b1, self.start, self.end, b2) def query(self, parser): fieldname = self.fieldname or parser.fieldname start = self.start end = self.end if parser.schema and fieldname in parser.schema: field = parser.schema[fieldname] if field.self_parsing(): try: q = field.parse_range(fieldname, start, end, self.startexcl, self.endexcl, boost=self.boost) if q is not None: return attach(q, self) except QueryParserError: e = sys.exc_info()[1] return attach(query.error_query(e), self) if start: start = get_single_text(field, start, tokenize=False, removestops=False) if end: end = get_single_text(field, end, tokenize=False, removestops=False) q = query.TermRange(fieldname, start, end, self.startexcl, self.endexcl, boost=self.boost) return attach(q, self) class TextNode(SyntaxNode): """Intermediate base class for basic nodes that search for text, such as term queries, wildcards, prefixes, etc. Instances have the following attributes: ``qclass`` If a subclass does not override ``query()``, the base class will use this class to construct the query. ``tokenize`` If True and the subclass does not override ``query()``, the node's text will be tokenized before constructing the query ``removestops`` If True and the subclass does not override ``query()``, and the field's analyzer has a stop word filter, stop words will be removed from the text before constructing the query. """ has_fieldname = True has_text = True has_boost = True qclass = None tokenize = False removestops = False def __init__(self, text): self.fieldname = None self.text = text self.boost = 1.0 def r(self): return "%s %r" % (self.__class__.__name__, self.text) def is_text(self): return True def query(self, parser): fieldname = self.fieldname or parser.fieldname termclass = self.qclass or parser.termclass q = parser.term_query(fieldname, self.text, termclass, boost=self.boost, tokenize=self.tokenize, removestops=self.removestops) return attach(q, self) class WordNode(TextNode): """Syntax node for term queries. """ tokenize = True removestops = True def r(self): return repr(self.text) # Operators class Operator(SyntaxNode): """Base class for PrefixOperator, PostfixOperator, and InfixOperator. Operators work by moving the nodes they apply to (e.g. for prefix operator, the previous node, for infix operator, the nodes on either side, etc.) into a group node. The group provides the code for what to do with the nodes. """ def __init__(self, text, grouptype, leftassoc=True): """ :param text: the text of the operator in the query string. :param grouptype: the type of group to create in place of the operator and the node(s) it operates on. :param leftassoc: for infix opeators, whether the operator is left associative. use ``leftassoc=False`` for right-associative infix operators. """ self.text = text self.grouptype = grouptype self.leftassoc = leftassoc def r(self): return "OP %r" % self.text def replace_self(self, parser, group, position): """Called with the parser, a group, and the position at which the operator occurs in that group. Should return a group with the operator replaced by whatever effect the operator has (e.g. for an infix op, replace the op and the nodes on either side with a sub-group). """ raise NotImplementedError class PrefixOperator(Operator): def replace_self(self, parser, group, position): length = len(group) del group[position] if position < length - 1: group[position] = self.grouptype([group[position]]) return position class PostfixOperator(Operator): def replace_self(self, parser, group, position): del group[position] if position > 0: group[position - 1] = self.grouptype([group[position - 1]]) return position class InfixOperator(Operator): def replace_self(self, parser, group, position): la = self.leftassoc gtype = self.grouptype merging = gtype.merging if position > 0 and position < len(group) - 1: left = group[position - 1] right = group[position + 1] # The first two clauses check whether the "strong" side is already # a group of the type we are going to create. If it is, we just # append the "weak" side to the "strong" side instead of creating # a new group inside the existing one. This is necessary because # we can quickly run into Python's recursion limit otherwise. if merging and la and isinstance(left, gtype): left.append(right) del group[position:position + 2] elif merging and not la and isinstance(right, gtype): right.insert(0, left) del group[position - 1:position + 1] return position - 1 else: # Replace the operator and the two surrounding objects group[position - 1:position + 2] = [gtype([left, right])] else: del group[position] return position # Functions def to_word(n): node = WordNode(n.original) node.startchar = n.startchar node.endchar = n.endchar return node