# sql/operators.py # Copyright (C) 2005-2013 the SQLAlchemy authors and contributors # # This module is part of SQLAlchemy and is released under # the MIT License: http://www.opensource.org/licenses/mit-license.php # This module is part of SQLAlchemy and is released under # the MIT License: http://www.opensource.org/licenses/mit-license.php """Defines operators used in SQL expressions.""" from operator import ( and_, or_, inv, add, mul, sub, mod, truediv, lt, le, ne, gt, ge, eq, neg, getitem, lshift, rshift ) # Py2K from operator import (div,) # end Py2K from ..util import symbol class Operators(object): """Base of comparison and logical operators. Implements base methods :meth:`operate` and :meth:`reverse_operate`, as well as :meth:`__and__`, :meth:`__or__`, :meth:`__invert__`. Usually is used via its most common subclass :class:`.ColumnOperators`. """ def __and__(self, other): """Implement the ``&`` operator. When used with SQL expressions, results in an AND operation, equivalent to :func:`~.expression.and_`, that is:: a & b is equivalent to:: from sqlalchemy import and_ and_(a, b) Care should be taken when using ``&`` regarding operator precedence; the ``&`` operator has the highest precedence. The operands should be enclosed in parenthesis if they contain further sub expressions:: (a == 2) & (b == 4) """ return self.operate(and_, other) def __or__(self, other): """Implement the ``|`` operator. When used with SQL expressions, results in an OR operation, equivalent to :func:`~.expression.or_`, that is:: a | b is equivalent to:: from sqlalchemy import or_ or_(a, b) Care should be taken when using ``|`` regarding operator precedence; the ``|`` operator has the highest precedence. The operands should be enclosed in parenthesis if they contain further sub expressions:: (a == 2) | (b == 4) """ return self.operate(or_, other) def __invert__(self): """Implement the ``~`` operator. When used with SQL expressions, results in a NOT operation, equivalent to :func:`~.expression.not_`, that is:: ~a is equivalent to:: from sqlalchemy import not_ not_(a) """ return self.operate(inv) def op(self, opstring, precedence=0): """produce a generic operator function. e.g.:: somecolumn.op("*")(5) produces:: somecolumn * 5 This function can also be used to make bitwise operators explicit. For example:: somecolumn.op('&')(0xff) is a bitwise AND of the value in ``somecolumn``. :param operator: a string which will be output as the infix operator between this element and the expression passed to the generated function. :param precedence: precedence to apply to the operator, when parenthesizing expressions. A lower number will cause the expression to be parenthesized when applied against another operator with higher precedence. The default value of ``0`` is lower than all operators except for the comma (``,``) and ``AS`` operators. A value of 100 will be higher or equal to all operators, and -100 will be lower than or equal to all operators. .. versionadded:: 0.8 - added the 'precedence' argument. .. seealso:: :ref:`types_operators` """ operator = custom_op(opstring, precedence) def against(other): return operator(self, other) return against def operate(self, op, *other, **kwargs): """Operate on an argument. This is the lowest level of operation, raises :class:`NotImplementedError` by default. Overriding this on a subclass can allow common behavior to be applied to all operations. For example, overriding :class:`.ColumnOperators` to apply ``func.lower()`` to the left and right side:: class MyComparator(ColumnOperators): def operate(self, op, other): return op(func.lower(self), func.lower(other)) :param op: Operator callable. :param \*other: the 'other' side of the operation. Will be a single scalar for most operations. :param \**kwargs: modifiers. These may be passed by special operators such as :meth:`ColumnOperators.contains`. """ raise NotImplementedError(str(op)) def reverse_operate(self, op, other, **kwargs): """Reverse operate on an argument. Usage is the same as :meth:`operate`. """ raise NotImplementedError(str(op)) class custom_op(object): """Represent a 'custom' operator. :class:`.custom_op` is normally instantitated when the :meth:`.ColumnOperators.op` method is used to create a custom operator callable. The class can also be used directly when programmatically constructing expressions. E.g. to represent the "factorial" operation:: from sqlalchemy.sql import UnaryExpression from sqlalchemy.sql import operators from sqlalchemy import Numeric unary = UnaryExpression(table.c.somecolumn, modifier=operators.custom_op("!"), type_=Numeric) """ __name__ = 'custom_op' def __init__(self, opstring, precedence=0): self.opstring = opstring self.precedence = precedence def __eq__(self, other): return isinstance(other, custom_op) and \ other.opstring == self.opstring def __hash__(self): return id(self) def __call__(self, left, right, **kw): return left.operate(self, right, **kw) class ColumnOperators(Operators): """Defines boolean, comparison, and other operators for :class:`.ColumnElement` expressions. By default, all methods call down to :meth:`.operate` or :meth:`.reverse_operate`, passing in the appropriate operator function from the Python builtin ``operator`` module or a SQLAlchemy-specific operator function from :mod:`sqlalchemy.expression.operators`. For example the ``__eq__`` function:: def __eq__(self, other): return self.operate(operators.eq, other) Where ``operators.eq`` is essentially:: def eq(a, b): return a == b The core column expression unit :class:`.ColumnElement` overrides :meth:`.Operators.operate` and others to return further :class:`.ColumnElement` constructs, so that the ``==`` operation above is replaced by a clause construct. See also: :ref:`types_operators` :attr:`.TypeEngine.comparator_factory` :class:`.ColumnOperators` :class:`.PropComparator` """ timetuple = None """Hack, allows datetime objects to be compared on the LHS.""" def __lt__(self, other): """Implement the ``<`` operator. In a column context, produces the clause ``a < b``. """ return self.operate(lt, other) def __le__(self, other): """Implement the ``<=`` operator. In a column context, produces the clause ``a <= b``. """ return self.operate(le, other) __hash__ = Operators.__hash__ def __eq__(self, other): """Implement the ``==`` operator. In a column context, produces the clause ``a = b``. If the target is ``None``, produces ``a IS NULL``. """ return self.operate(eq, other) def __ne__(self, other): """Implement the ``!=`` operator. In a column context, produces the clause ``a != b``. If the target is ``None``, produces ``a IS NOT NULL``. """ return self.operate(ne, other) def __gt__(self, other): """Implement the ``>`` operator. In a column context, produces the clause ``a > b``. """ return self.operate(gt, other) def __ge__(self, other): """Implement the ``>=`` operator. In a column context, produces the clause ``a >= b``. """ return self.operate(ge, other) def __neg__(self): """Implement the ``-`` operator. In a column context, produces the clause ``-a``. """ return self.operate(neg) def __getitem__(self, index): """Implement the [] operator. This can be used by some database-specific types such as Postgresql ARRAY and HSTORE. """ return self.operate(getitem, index) def __lshift__(self, other): """implement the << operator. Not used by SQLAlchemy core, this is provided for custom operator systems which want to use << as an extension point. """ return self.operate(lshift, other) def __rshift__(self, other): """implement the >> operator. Not used by SQLAlchemy core, this is provided for custom operator systems which want to use >> as an extension point. """ return self.operate(rshift, other) def concat(self, other): """Implement the 'concat' operator. In a column context, produces the clause ``a || b``, or uses the ``concat()`` operator on MySQL. """ return self.operate(concat_op, other) def like(self, other, escape=None): """Implement the ``like`` operator. In a column context, produces the clause ``a LIKE other``. E.g.:: select([sometable]).where(sometable.c.column.like("%foobar%")) :param other: expression to be compared :param escape: optional escape character, renders the ``ESCAPE`` keyword, e.g.:: somecolumn.like("foo/%bar", escape="/") .. seealso:: :meth:`.ColumnOperators.ilike` """ return self.operate(like_op, other, escape=escape) def ilike(self, other, escape=None): """Implement the ``ilike`` operator. In a column context, produces the clause ``a ILIKE other``. E.g.:: select([sometable]).where(sometable.c.column.ilike("%foobar%")) :param other: expression to be compared :param escape: optional escape character, renders the ``ESCAPE`` keyword, e.g.:: somecolumn.ilike("foo/%bar", escape="/") .. seealso:: :meth:`.ColumnOperators.like` """ return self.operate(ilike_op, other, escape=escape) def in_(self, other): """Implement the ``in`` operator. In a column context, produces the clause ``a IN other``. "other" may be a tuple/list of column expressions, or a :func:`~.expression.select` construct. """ return self.operate(in_op, other) def notin_(self, other): """implement the ``NOT IN`` operator. This is equivalent to using negation with :meth:`.ColumnOperators.in_`, i.e. ``~x.in_(y)``. .. versionadded:: 0.8 .. seealso:: :meth:`.ColumnOperators.in_` """ return self.operate(notin_op, other) def notlike(self, other, escape=None): """implement the ``NOT LIKE`` operator. This is equivalent to using negation with :meth:`.ColumnOperators.like`, i.e. ``~x.like(y)``. .. versionadded:: 0.8 .. seealso:: :meth:`.ColumnOperators.like` """ return self.operate(notlike_op, other, escape=escape) def notilike(self, other, escape=None): """implement the ``NOT ILIKE`` operator. This is equivalent to using negation with :meth:`.ColumnOperators.ilike`, i.e. ``~x.ilike(y)``. .. versionadded:: 0.8 .. seealso:: :meth:`.ColumnOperators.ilike` """ return self.operate(notilike_op, other, escape=escape) def is_(self, other): """Implement the ``IS`` operator. Normally, ``IS`` is generated automatically when comparing to a value of ``None``, which resolves to ``NULL``. However, explicit usage of ``IS`` may be desirable if comparing to boolean values on certain platforms. .. versionadded:: 0.7.9 .. seealso:: :meth:`.ColumnOperators.isnot` """ return self.operate(is_, other) def isnot(self, other): """Implement the ``IS NOT`` operator. Normally, ``IS NOT`` is generated automatically when comparing to a value of ``None``, which resolves to ``NULL``. However, explicit usage of ``IS NOT`` may be desirable if comparing to boolean values on certain platforms. .. versionadded:: 0.7.9 .. seealso:: :meth:`.ColumnOperators.is_` """ return self.operate(isnot, other) def startswith(self, other, **kwargs): """Implement the ``startwith`` operator. In a column context, produces the clause ``LIKE '%'`` """ return self.operate(startswith_op, other, **kwargs) def endswith(self, other, **kwargs): """Implement the 'endswith' operator. In a column context, produces the clause ``LIKE '%'`` """ return self.operate(endswith_op, other, **kwargs) def contains(self, other, **kwargs): """Implement the 'contains' operator. In a column context, produces the clause ``LIKE '%%'`` """ return self.operate(contains_op, other, **kwargs) def match(self, other, **kwargs): """Implements the 'match' operator. In a column context, this produces a MATCH clause, i.e. ``MATCH ''``. The allowed contents of ``other`` are database backend specific. """ return self.operate(match_op, other, **kwargs) def desc(self): """Produce a :func:`~.expression.desc` clause against the parent object.""" return self.operate(desc_op) def asc(self): """Produce a :func:`~.expression.asc` clause against the parent object.""" return self.operate(asc_op) def nullsfirst(self): """Produce a :func:`~.expression.nullsfirst` clause against the parent object.""" return self.operate(nullsfirst_op) def nullslast(self): """Produce a :func:`~.expression.nullslast` clause against the parent object.""" return self.operate(nullslast_op) def collate(self, collation): """Produce a :func:`~.expression.collate` clause against the parent object, given the collation string.""" return self.operate(collate, collation) def __radd__(self, other): """Implement the ``+`` operator in reverse. See :meth:`.ColumnOperators.__add__`. """ return self.reverse_operate(add, other) def __rsub__(self, other): """Implement the ``-`` operator in reverse. See :meth:`.ColumnOperators.__sub__`. """ return self.reverse_operate(sub, other) def __rmul__(self, other): """Implement the ``*`` operator in reverse. See :meth:`.ColumnOperators.__mul__`. """ return self.reverse_operate(mul, other) def __rdiv__(self, other): """Implement the ``/`` operator in reverse. See :meth:`.ColumnOperators.__div__`. """ return self.reverse_operate(div, other) def between(self, cleft, cright): """Produce a :func:`~.expression.between` clause against the parent object, given the lower and upper range.""" return self.operate(between_op, cleft, cright) def distinct(self): """Produce a :func:`~.expression.distinct` clause against the parent object. """ return self.operate(distinct_op) def __add__(self, other): """Implement the ``+`` operator. In a column context, produces the clause ``a + b`` if the parent object has non-string affinity. If the parent object has a string affinity, produces the concatenation operator, ``a || b`` - see :meth:`.ColumnOperators.concat`. """ return self.operate(add, other) def __sub__(self, other): """Implement the ``-`` operator. In a column context, produces the clause ``a - b``. """ return self.operate(sub, other) def __mul__(self, other): """Implement the ``*`` operator. In a column context, produces the clause ``a * b``. """ return self.operate(mul, other) def __div__(self, other): """Implement the ``/`` operator. In a column context, produces the clause ``a / b``. """ return self.operate(div, other) def __mod__(self, other): """Implement the ``%`` operator. In a column context, produces the clause ``a % b``. """ return self.operate(mod, other) def __truediv__(self, other): """Implement the ``//`` operator. In a column context, produces the clause ``a / b``. """ return self.operate(truediv, other) def __rtruediv__(self, other): """Implement the ``//`` operator in reverse. See :meth:`.ColumnOperators.__truediv__`. """ return self.reverse_operate(truediv, other) def from_(): raise NotImplementedError() def as_(): raise NotImplementedError() def exists(): raise NotImplementedError() def is_(a, b): return a.is_(b) def isnot(a, b): return a.isnot(b) def collate(a, b): return a.collate(b) def op(a, opstring, b): return a.op(opstring)(b) def like_op(a, b, escape=None): return a.like(b, escape=escape) def notlike_op(a, b, escape=None): return a.notlike(b, escape=escape) def ilike_op(a, b, escape=None): return a.ilike(b, escape=escape) def notilike_op(a, b, escape=None): return a.notilike(b, escape=escape) def between_op(a, b, c): return a.between(b, c) def in_op(a, b): return a.in_(b) def notin_op(a, b): return a.notin_(b) def distinct_op(a): return a.distinct() def startswith_op(a, b, escape=None): return a.startswith(b, escape=escape) def notstartswith_op(a, b, escape=None): return ~a.startswith(b, escape=escape) def endswith_op(a, b, escape=None): return a.endswith(b, escape=escape) def notendswith_op(a, b, escape=None): return ~a.endswith(b, escape=escape) def contains_op(a, b, escape=None): return a.contains(b, escape=escape) def notcontains_op(a, b, escape=None): return ~a.contains(b, escape=escape) def match_op(a, b): return a.match(b) def comma_op(a, b): raise NotImplementedError() def concat_op(a, b): return a.concat(b) def desc_op(a): return a.desc() def asc_op(a): return a.asc() def nullsfirst_op(a): return a.nullsfirst() def nullslast_op(a): return a.nullslast() _commutative = set([eq, ne, add, mul]) _comparison = set([eq, ne, lt, gt, ge, le, between_op]) def is_comparison(op): return op in _comparison def is_commutative(op): return op in _commutative def is_ordering_modifier(op): return op in (asc_op, desc_op, nullsfirst_op, nullslast_op) _associative = _commutative.union([concat_op, and_, or_]) _natural_self_precedent = _associative.union([getitem]) """Operators where if we have (a op b) op c, we don't want to parenthesize (a op b). """ _smallest = symbol('_smallest', canonical=-100) _largest = symbol('_largest', canonical=100) _PRECEDENCE = { from_: 15, getitem: 15, mul: 8, truediv: 8, # Py2K div: 8, # end Py2K mod: 8, neg: 8, add: 7, sub: 7, concat_op: 6, match_op: 6, ilike_op: 6, notilike_op: 6, like_op: 6, notlike_op: 6, in_op: 6, notin_op: 6, is_: 6, isnot: 6, eq: 5, ne: 5, gt: 5, lt: 5, ge: 5, le: 5, between_op: 5, distinct_op: 5, inv: 5, and_: 3, or_: 2, comma_op: -1, collate: 7, as_: -1, exists: 0, _smallest: _smallest, _largest: _largest } def is_precedent(operator, against): if operator is against and operator in _natural_self_precedent: return False else: return (_PRECEDENCE.get(operator, getattr(operator, 'precedence', _smallest)) <= _PRECEDENCE.get(against, getattr(against, 'precedence', _largest)))