from sympy.assumptions import Predicate
from sympy.multipledispatch import Dispatcher
class NegativePredicate(Predicate):
r"""
Negative number predicate.
Explanation
===========
``Q.negative(x)`` is true iff ``x`` is a real number and :math:`x < 0`, that is,
it is in the interval :math:`(-\infty, 0)`. Note in particular that negative
infinity is not negative.
A few important facts about negative numbers:
- Note that ``Q.nonnegative`` and ``~Q.negative`` are *not* the same
thing. ``~Q.negative(x)`` simply means that ``x`` is not negative,
whereas ``Q.nonnegative(x)`` means that ``x`` is real and not
negative, i.e., ``Q.nonnegative(x)`` is logically equivalent to
``Q.zero(x) | Q.positive(x)``. So for example, ``~Q.negative(I)`` is
true, whereas ``Q.nonnegative(I)`` is false.
- See the documentation of ``Q.real`` for more information about
related facts.
Examples
========
>>> from sympy import Q, ask, symbols, I
>>> x = symbols('x')
>>> ask(Q.negative(x), Q.real(x) & ~Q.positive(x) & ~Q.zero(x))
True
>>> ask(Q.negative(-1))
True
>>> ask(Q.nonnegative(I))
False
>>> ask(~Q.negative(I))
True
"""
name = 'negative'
handler = Dispatcher(
"NegativeHandler",
doc=("Handler for Q.negative. Test that an expression is strictly less"
" than zero.")
)
class NonNegativePredicate(Predicate):
"""
Nonnegative real number predicate.
Explanation
===========
``ask(Q.nonnegative(x))`` is true iff ``x`` belongs to the set of
positive numbers including zero.
- Note that ``Q.nonnegative`` and ``~Q.negative`` are *not* the same
thing. ``~Q.negative(x)`` simply means that ``x`` is not negative,
whereas ``Q.nonnegative(x)`` means that ``x`` is real and not
negative, i.e., ``Q.nonnegative(x)`` is logically equivalent to
``Q.zero(x) | Q.positive(x)``. So for example, ``~Q.negative(I)`` is
true, whereas ``Q.nonnegative(I)`` is false.
Examples
========
>>> from sympy import Q, ask, I
>>> ask(Q.nonnegative(1))
True
>>> ask(Q.nonnegative(0))
True
>>> ask(Q.nonnegative(-1))
False
>>> ask(Q.nonnegative(I))
False
>>> ask(Q.nonnegative(-I))
False
"""
name = 'nonnegative'
handler = Dispatcher(
"NonNegativeHandler",
doc=("Handler for Q.nonnegative.")
)
class NonZeroPredicate(Predicate):
"""
Nonzero real number predicate.
Explanation
===========
``ask(Q.nonzero(x))`` is true iff ``x`` is real and ``x`` is not zero. Note in
particular that ``Q.nonzero(x)`` is false if ``x`` is not real. Use
``~Q.zero(x)`` if you want the negation of being zero without any real
assumptions.
A few important facts about nonzero numbers:
- ``Q.nonzero`` is logically equivalent to ``Q.positive | Q.negative``.
- See the documentation of ``Q.real`` for more information about
related facts.
Examples
========
>>> from sympy import Q, ask, symbols, I, oo
>>> x = symbols('x')
>>> print(ask(Q.nonzero(x), ~Q.zero(x)))
None
>>> ask(Q.nonzero(x), Q.positive(x))
True
>>> ask(Q.nonzero(x), Q.zero(x))
False
>>> ask(Q.nonzero(0))
False
>>> ask(Q.nonzero(I))
False
>>> ask(~Q.zero(I))
True
>>> ask(Q.nonzero(oo))
False
"""
name = 'nonzero'
handler = Dispatcher(
"NonZeroHandler",
doc=("Handler for key 'zero'. Test that an expression is not identically"
" zero.")
)
class ZeroPredicate(Predicate):
"""
Zero number predicate.
Explanation
===========
``ask(Q.zero(x))`` is true iff the value of ``x`` is zero.
Examples
========
>>> from sympy import ask, Q, oo, symbols
>>> x, y = symbols('x, y')
>>> ask(Q.zero(0))
True
>>> ask(Q.zero(1/oo))
True
>>> print(ask(Q.zero(0*oo)))
None
>>> ask(Q.zero(1))
False
>>> ask(Q.zero(x*y), Q.zero(x) | Q.zero(y))
True
"""
name = 'zero'
handler = Dispatcher(
"ZeroHandler",
doc="Handler for key 'zero'."
)
class NonPositivePredicate(Predicate):
"""
Nonpositive real number predicate.
Explanation
===========
``ask(Q.nonpositive(x))`` is true iff ``x`` belongs to the set of
negative numbers including zero.
- Note that ``Q.nonpositive`` and ``~Q.positive`` are *not* the same
thing. ``~Q.positive(x)`` simply means that ``x`` is not positive,
whereas ``Q.nonpositive(x)`` means that ``x`` is real and not
positive, i.e., ``Q.nonpositive(x)`` is logically equivalent to
`Q.negative(x) | Q.zero(x)``. So for example, ``~Q.positive(I)`` is
true, whereas ``Q.nonpositive(I)`` is false.
Examples
========
>>> from sympy import Q, ask, I
>>> ask(Q.nonpositive(-1))
True
>>> ask(Q.nonpositive(0))
True
>>> ask(Q.nonpositive(1))
False
>>> ask(Q.nonpositive(I))
False
>>> ask(Q.nonpositive(-I))
False
"""
name = 'nonpositive'
handler = Dispatcher(
"NonPositiveHandler",
doc="Handler for key 'nonpositive'."
)
class PositivePredicate(Predicate):
r"""
Positive real number predicate.
Explanation
===========
``Q.positive(x)`` is true iff ``x`` is real and `x > 0`, that is if ``x``
is in the interval `(0, \infty)`. In particular, infinity is not
positive.
A few important facts about positive numbers:
- Note that ``Q.nonpositive`` and ``~Q.positive`` are *not* the same
thing. ``~Q.positive(x)`` simply means that ``x`` is not positive,
whereas ``Q.nonpositive(x)`` means that ``x`` is real and not
positive, i.e., ``Q.nonpositive(x)`` is logically equivalent to
`Q.negative(x) | Q.zero(x)``. So for example, ``~Q.positive(I)`` is
true, whereas ``Q.nonpositive(I)`` is false.
- See the documentation of ``Q.real`` for more information about
related facts.
Examples
========
>>> from sympy import Q, ask, symbols, I
>>> x = symbols('x')
>>> ask(Q.positive(x), Q.real(x) & ~Q.negative(x) & ~Q.zero(x))
True
>>> ask(Q.positive(1))
True
>>> ask(Q.nonpositive(I))
False
>>> ask(~Q.positive(I))
True
"""
name = 'positive'
handler = Dispatcher(
"PositiveHandler",
doc=("Handler for key 'positive'. Test that an expression is strictly"
" greater than zero.")
)
class ExtendedPositivePredicate(Predicate):
r"""
Positive extended real number predicate.
Explanation
===========
``Q.extended_positive(x)`` is true iff ``x`` is extended real and
`x > 0`, that is if ``x`` is in the interval `(0, \infty]`.
Examples
========
>>> from sympy import ask, I, oo, Q
>>> ask(Q.extended_positive(1))
True
>>> ask(Q.extended_positive(oo))
True
>>> ask(Q.extended_positive(I))
False
"""
name = 'extended_positive'
handler = Dispatcher("ExtendedPositiveHandler")
class ExtendedNegativePredicate(Predicate):
r"""
Negative extended real number predicate.
Explanation
===========
``Q.extended_negative(x)`` is true iff ``x`` is extended real and
`x < 0`, that is if ``x`` is in the interval `[-\infty, 0)`.
Examples
========
>>> from sympy import ask, I, oo, Q
>>> ask(Q.extended_negative(-1))
True
>>> ask(Q.extended_negative(-oo))
True
>>> ask(Q.extended_negative(-I))
False
"""
name = 'extended_negative'
handler = Dispatcher("ExtendedNegativeHandler")
class ExtendedNonZeroPredicate(Predicate):
"""
Nonzero extended real number predicate.
Explanation
===========
``ask(Q.extended_nonzero(x))`` is true iff ``x`` is extended real and
``x`` is not zero.
Examples
========
>>> from sympy import ask, I, oo, Q
>>> ask(Q.extended_nonzero(-1))
True
>>> ask(Q.extended_nonzero(oo))
True
>>> ask(Q.extended_nonzero(I))
False
"""
name = 'extended_nonzero'
handler = Dispatcher("ExtendedNonZeroHandler")
class ExtendedNonPositivePredicate(Predicate):
"""
Nonpositive extended real number predicate.
Explanation
===========
``ask(Q.extended_nonpositive(x))`` is true iff ``x`` is extended real and
``x`` is not positive.
Examples
========
>>> from sympy import ask, I, oo, Q
>>> ask(Q.extended_nonpositive(-1))
True
>>> ask(Q.extended_nonpositive(oo))
False
>>> ask(Q.extended_nonpositive(0))
True
>>> ask(Q.extended_nonpositive(I))
False
"""
name = 'extended_nonpositive'
handler = Dispatcher("ExtendedNonPositiveHandler")
class ExtendedNonNegativePredicate(Predicate):
"""
Nonnegative extended real number predicate.
Explanation
===========
``ask(Q.extended_nonnegative(x))`` is true iff ``x`` is extended real and
``x`` is not negative.
Examples
========
>>> from sympy import ask, I, oo, Q
>>> ask(Q.extended_nonnegative(-1))
False
>>> ask(Q.extended_nonnegative(oo))
True
>>> ask(Q.extended_nonnegative(0))
True
>>> ask(Q.extended_nonnegative(I))
False
"""
name = 'extended_nonnegative'
handler = Dispatcher("ExtendedNonNegativeHandler")