Пример #1
0
def test_rewrite_MaxMin_as_Piecewise():
    from sympy import symbols, Piecewise
    x, y, z, a, b = symbols('x y z a b', real=True)
    vx, vy, va = symbols('vx vy va')
    assert Max(a, b).rewrite(Piecewise) == Piecewise((a, a >= b), (b, True))
    assert Max(x, y, z).rewrite(Piecewise) == Piecewise(
        (x, (x >= y) & (x >= z)), (y, y >= z), (z, True))
    assert Max(x, y, a, b).rewrite(Piecewise) == Piecewise(
        (a, (a >= b) & (a >= x) & (a >= y)), (b, (b >= x) & (b >= y)),
        (x, x >= y), (y, True))
    assert Min(a, b).rewrite(Piecewise) == Piecewise((a, a <= b), (b, True))
    assert Min(x, y, z).rewrite(Piecewise) == Piecewise(
        (x, (x <= y) & (x <= z)), (y, y <= z), (z, True))
    assert Min(x, y, a, b).rewrite(Piecewise) == Piecewise(
        (a, (a <= b) & (a <= x) & (a <= y)), (b, (b <= x) & (b <= y)),
        (x, x <= y), (y, True))

    # Piecewise rewriting of Min/Max does also takes place for not explicitly real arguments
    assert Max(vx, vy).rewrite(Piecewise) == Piecewise((vx, vx >= vy),
                                                       (vy, True))
    assert Min(va, vx, vy).rewrite(Piecewise) == Piecewise(
        (va, (va <= vx) & (va <= vy)), (vx, vx <= vy), (vy, True))
Пример #2
0
    def _eval_imageset(self, f):
        # Cut out 0, perform image, add back in image of 0
        if self.contains(0) == True:
            return imageset(f, self - FiniteSet(0)) + imageset(f, FiniteSet(0))

        from sympy.functions.elementary.miscellaneous import Min, Max
        # TODO: manage left_open and right_open better in case of
        # non-comparable left/right (e.g. Interval(x, y))
        _left, _right = f(self.left), f(self.right)
        left, right = Min(_left, _right), Max(_left, _right)
        if _right == left:  # switch happened
            left_open, right_open = self.right_open, self.left_open
        else:
            left_open, right_open = self.left_open, self.right_open
        return Interval(left, right, left_open, right_open)
Пример #3
0
def test_Max():
    from sympy.abc import x, y, z
    n = Symbol('n', negative=True)
    n_ = Symbol('n_', negative=True)
    nn = Symbol('nn', nonnegative=True)
    nn_ = Symbol('nn_', nonnegative=True)
    p = Symbol('p', positive=True)
    p_ = Symbol('p_', positive=True)
    np = Symbol('np', nonpositive=True)
    np_ = Symbol('np_', nonpositive=True)

    assert Max(5, 4) == 5

    # lists

    raises(ValueError, lambda: Max())
    assert Max(x, y) == Max(y, x)
    assert Max(x, y, z) == Max(z, y, x)
    assert Max(x, Max(y, z)) == Max(z, y, x)
    assert Max(x, Min(y, oo)) == Max(x, y)
    assert Max(n, -oo, n_, p, 2) == Max(p, 2)
    assert Max(n, -oo, n_, p) == p
    assert Max(2, x, p, n, -oo, S.NegativeInfinity, n_, p, 2) == Max(2, x, p)
    assert Max(0, x, 1, y) == Max(1, x, y)
    assert Max(x, x + 1, x - 1) == 1 + x
    assert Max(1000, 100, -100, x, p, n) == Max(p, x, 1000)
    assert Max(cos(x), sin(x)) == Max(sin(x), cos(x))
    assert Max(cos(x), sin(x)).subs(x, 1) == sin(1)
    assert Max(cos(x), sin(x)).subs(x, S(1)/2) == cos(S(1)/2)
    raises(ValueError, lambda: Max(cos(x), sin(x)).subs(x, I))
    raises(ValueError, lambda: Max(I))
    raises(ValueError, lambda: Max(I, x))
    raises(ValueError, lambda: Max(S.ComplexInfinity, 1))
    # interesting:
    # Max(n, -oo, n_,  p, 2) == Max(p, 2)
    # True
    # Max(n, -oo, n_,  p, 1000) == Max(p, 1000)
    # False

    from sympy.functions.special.delta_functions import Heaviside
    assert Max(1,x).diff(x) == Heaviside(x-1)
    assert Max(x,1).diff(x) == Heaviside(x-1)
    assert Max(x**2, 1+x, 1).diff(x) == 2*x*Heaviside(x**2 - Max(1,x+1)) \
        + Heaviside(x - Max(1,x**2) + 1)

    a, b = Symbol('a', real=True), Symbol('b', real=True)
    # a and b are both real, Max(a, b) should be real
    assert Max(a, b).is_real
Пример #4
0
def test_issue_18770():
    numpy = import_module('numpy')
    if not numpy:
        skip("numpy not installed.")

    from sympy.functions.elementary.miscellaneous import (Max, Min)
    from sympy.utilities.lambdify import lambdify

    expr1 = Min(0.1 * x + 3, x + 1, 0.5 * x + 1)
    func = lambdify(x, expr1, "numpy")
    assert (func(numpy.linspace(0, 3, 3)) == [1.0, 1.75, 2.5]).all()
    assert func(4) == 3

    expr1 = Max(x**2, x**3)
    func = lambdify(x, expr1, "numpy")
    assert (func(numpy.linspace(-1, 2, 4)) == [1, 0, 1, 8]).all()
    assert func(4) == 64
Пример #5
0
 def __mul__(self, other):
     if isinstance(other, Expr):
         if isinstance(other, AccumBounds):
             return AccumBounds(Min(Mul(self.min, other.min),
                                    Mul(self.min, other.max),
                                    Mul(self.max, other.min),
                                    Mul(self.max, other.max)),
                                Max(Mul(self.min, other.min),
                                    Mul(self.min, other.max),
                                    Mul(self.max, other.min),
                                    Mul(self.max, other.max)))
         if other is S.Infinity:
             if self.min.is_zero:
                 return AccumBounds(0, oo)
             if self.max.is_zero:
                 return AccumBounds(-oo, 0)
         if other is S.NegativeInfinity:
             if self.min.is_zero:
                 return AccumBounds(-oo, 0)
             if self.max.is_zero:
                 return AccumBounds(0, oo)
         if other.is_real:
             if other.is_zero:
                 if self == AccumBounds(-oo, oo):
                     return AccumBounds(-oo, oo)
                 if self.max is S.Infinity:
                     return AccumBounds(0, oo)
                 if self.min is S.NegativeInfinity:
                     return AccumBounds(-oo, 0)
                 return S.Zero
             if other.is_positive:
                 return AccumBounds(
                     Mul(self.min, other),
                     Mul(self.max, other))
             elif other.is_negative:
                 return AccumBounds(
                     Mul(self.max, other),
                     Mul(self.min, other))
         if isinstance(other, Order):
             return other
         return Mul(self, other, evaluate=False)
     return NotImplemented
Пример #6
0
 def __mul__(self, other):
     if self.args == (-oo, oo):
         return self
     if isinstance(other, Expr):
         if isinstance(other, AccumBounds):
             if other.args == (-oo, oo):
                 return other
             v = set()
             for a in self.args:
                 vi = other * a
                 for i in vi.args or (vi, ):
                     v.add(i)
             return AccumBounds(Min(*v), Max(*v))
         if other is S.Infinity:
             if self.min.is_zero:
                 return AccumBounds(0, oo)
             if self.max.is_zero:
                 return AccumBounds(-oo, 0)
         if other is S.NegativeInfinity:
             if self.min.is_zero:
                 return AccumBounds(-oo, 0)
             if self.max.is_zero:
                 return AccumBounds(0, oo)
         if other.is_extended_real:
             if other.is_zero:
                 if self.max is S.Infinity:
                     return AccumBounds(0, oo)
                 if self.min is S.NegativeInfinity:
                     return AccumBounds(-oo, 0)
                 return S.Zero
             if other.is_extended_positive:
                 return AccumBounds(Mul(self.min, other),
                                    Mul(self.max, other))
             elif other.is_extended_negative:
                 return AccumBounds(Mul(self.max, other),
                                    Mul(self.min, other))
         if isinstance(other, Order):
             return other
         return Mul(self, other, evaluate=False)
     return NotImplemented
Пример #7
0
    def minor(self):
        """Shorter axis of the ellipse (if it can be determined) else vradius.

        Returns
        =======

        minor : number or expression

        See Also
        ========

        hradius, vradius, major

        Examples
        ========

        >>> from sympy import Point, Ellipse, Symbol
        >>> p1 = Point(0, 0)
        >>> e1 = Ellipse(p1, 3, 1)
        >>> e1.minor
        1

        >>> a = Symbol('a')
        >>> b = Symbol('b')
        >>> Ellipse(p1, a, b).minor
        b
        >>> Ellipse(p1, b, a).minor
        a

        >>> m = Symbol('m')
        >>> M = m + 1
        >>> Ellipse(p1, m, M).minor
        m

        """
        rv = Min(*self.args[1:3])
        if rv.func is Min:
            return self.vradius
        return rv
Пример #8
0
 def __rdiv__(self, other):
     if isinstance(other, Expr):
         if other.is_real:
             if other.is_zero:
                 return S.Zero
             if S.Zero in self:
                 if self.min == S.Zero:
                     if other.is_positive:
                         return AccumBounds(Mul(other, 1/self.max), oo)
                     if other.is_negative:
                         return AccumBounds(-oo, Mul(other, 1/self.max))
                 if self.max == S.Zero:
                     if other.is_positive:
                         return AccumBounds(-oo, Mul(other, 1/self.min))
                     if other.is_negative:
                         return AccumBounds(Mul(other, 1/self.min), oo)
                 return AccumBounds(-oo, oo)
             else:
                 return AccumBounds(Min(other/self.min, other/self.max),
                         Max(other/self.min, other/self.max))
         return Mul(other, 1/self, evaluate=False)
     else:
         return NotImplemented
Пример #9
0
 def __rtruediv__(self, other):
     if isinstance(other, Expr):
         if other.is_extended_real:
             if other.is_zero:
                 return S.Zero
             if (self.min.is_extended_nonpositive
                     and self.max.is_extended_nonnegative):
                 if self.min.is_zero:
                     if other.is_extended_positive:
                         return AccumBounds(Mul(other, 1 / self.max), oo)
                     if other.is_extended_negative:
                         return AccumBounds(-oo, Mul(other, 1 / self.max))
                 if self.max.is_zero:
                     if other.is_extended_positive:
                         return AccumBounds(-oo, Mul(other, 1 / self.min))
                     if other.is_extended_negative:
                         return AccumBounds(Mul(other, 1 / self.min), oo)
                 return AccumBounds(-oo, oo)
             else:
                 return AccumBounds(Min(other / self.min, other / self.max),
                                    Max(other / self.min, other / self.max))
         return Mul(other, 1 / self, evaluate=False)
     else:
         return NotImplemented
Пример #10
0
def test_instantiation_evaluation():
    from sympy.abc import v, w, x, y, z
    assert Min(1, Max(2, x)) == 1
    assert Max(3, Min(2, x)) == 3
    assert Min(Max(x, y), Max(x, z)) == Max(x, Min(y, z))
    assert set(Min(Max(w, x), Max(y, z)).args) == set([Max(w, x), Max(y, z)])
    assert Min(Max(x, y), Max(x, z), w) == Min(w, Max(x, Min(y, z)))
    A, B = Min, Max
    for i in range(2):
        assert A(x, B(x, y)) == x
        assert A(x, B(y, A(x, w, z))) == A(x, B(y, A(w, z)))
        A, B = B, A
    assert Min(w, Max(x, y), Max(v, x, z)) == Min(w, Max(x, Min(y, Max(v, z))))
Пример #11
0
def test_issue_12638():
    from sympy.abc import a, b, c, d
    assert Min(a, b, c, Max(a, b)) == Min(a, b, c)
    assert Min(a, b, Max(a, b, c)) == Min(a, b)
    assert Min(a, b, Max(a, c)) == Min(a, b)
Пример #12
0
def test_Min():
    from sympy.abc import x, y, z
    n = Symbol('n', negative=True)
    n_ = Symbol('n_', negative=True)
    nn = Symbol('nn', nonnegative=True)
    nn_ = Symbol('nn_', nonnegative=True)
    p = Symbol('p', positive=True)
    p_ = Symbol('p_', positive=True)
    np = Symbol('np', nonpositive=True)
    np_ = Symbol('np_', nonpositive=True)
    r = Symbol('r', real=True)

    assert Min(5, 4) == 4
    assert Min(-oo, -oo) == -oo
    assert Min(-oo, n) == -oo
    assert Min(n, -oo) == -oo
    assert Min(-oo, np) == -oo
    assert Min(np, -oo) == -oo
    assert Min(-oo, 0) == -oo
    assert Min(0, -oo) == -oo
    assert Min(-oo, nn) == -oo
    assert Min(nn, -oo) == -oo
    assert Min(-oo, p) == -oo
    assert Min(p, -oo) == -oo
    assert Min(-oo, oo) == -oo
    assert Min(oo, -oo) == -oo
    assert Min(n, n) == n
    assert Min(n, np) == Min(n, np)
    assert Min(np, n) == Min(np, n)
    assert Min(n, 0) == n
    assert Min(0, n) == n
    assert Min(n, nn) == n
    assert Min(nn, n) == n
    assert Min(n, p) == n
    assert Min(p, n) == n
    assert Min(n, oo) == n
    assert Min(oo, n) == n
    assert Min(np, np) == np
    assert Min(np, 0) == np
    assert Min(0, np) == np
    assert Min(np, nn) == np
    assert Min(nn, np) == np
    assert Min(np, p) == np
    assert Min(p, np) == np
    assert Min(np, oo) == np
    assert Min(oo, np) == np
    assert Min(0, 0) == 0
    assert Min(0, nn) == 0
    assert Min(nn, 0) == 0
    assert Min(0, p) == 0
    assert Min(p, 0) == 0
    assert Min(0, oo) == 0
    assert Min(oo, 0) == 0
    assert Min(nn, nn) == nn
    assert Min(nn, p) == Min(nn, p)
    assert Min(p, nn) == Min(p, nn)
    assert Min(nn, oo) == nn
    assert Min(oo, nn) == nn
    assert Min(p, p) == p
    assert Min(p, oo) == p
    assert Min(oo, p) == p
    assert Min(oo, oo) == oo

    assert Min(n, n_).func is Min
    assert Min(nn, nn_).func is Min
    assert Min(np, np_).func is Min
    assert Min(p, p_).func is Min

    # lists
    raises(ValueError, lambda: Min())
    assert Min(x, y) == Min(y, x)
    assert Min(x, y, z) == Min(z, y, x)
    assert Min(x, Min(y, z)) == Min(z, y, x)
    assert Min(x, Max(y, -oo)) == Min(x, y)
    assert Min(p, oo, n, p, p, p_) == n
    assert Min(p_, n_, p) == n_
    assert Min(n, oo, -7, p, p, 2) == Min(n, -7)
    assert Min(2, x, p, n, oo, n_, p, 2, -2, -2) == Min(-2, x, n, n_)
    assert Min(0, x, 1, y) == Min(0, x, y)
    assert Min(1000, 100, -100, x, p, n) == Min(n, x, -100)
    assert Min(cos(x), sin(x)) == Min(cos(x), sin(x))
    assert Min(cos(x), sin(x)).subs(x, 1) == cos(1)
    assert Min(cos(x), sin(x)).subs(x, S(1) / 2) == sin(S(1) / 2)
    raises(ValueError, lambda: Min(cos(x), sin(x)).subs(x, I))
    raises(ValueError, lambda: Min(I))
    raises(ValueError, lambda: Min(I, x))
    raises(ValueError, lambda: Min(S.ComplexInfinity, x))

    assert Min(1, x).diff(x) == Heaviside(1 - x)
    assert Min(x, 1).diff(x) == Heaviside(1 - x)
    assert Min(0, -x, 1 - 2*x).diff(x) == -Heaviside(x + Min(0, -2*x + 1)) \
        - 2*Heaviside(2*x + Min(0, -x) - 1)

    # issue 7619
    f = Function('f')
    assert Min(1, 2 * Min(f(1), 2))  # doesn't fail

    # issue 7233
    e = Min(0, x)
    assert e.evalf == e.n
    assert e.n().args == (0, x)

    # issue 8643
    m = Min(n, p_, n_, r)
    assert m.is_positive is False
    assert m.is_nonnegative is False
    assert m.is_negative is True

    m = Min(p, p_)
    assert m.is_positive is True
    assert m.is_nonnegative is True
    assert m.is_negative is False

    m = Min(p, nn_, p_)
    assert m.is_positive is None
    assert m.is_nonnegative is True
    assert m.is_negative is False

    m = Min(nn, p, r)
    assert m.is_positive is None
    assert m.is_nonnegative is None
    assert m.is_negative is None
Пример #13
0
def test_Max():
    from sympy.abc import x, y, z
    n = Symbol('n', negative=True)
    n_ = Symbol('n_', negative=True)
    nn = Symbol('nn', nonnegative=True)
    nn_ = Symbol('nn_', nonnegative=True)
    p = Symbol('p', positive=True)
    p_ = Symbol('p_', positive=True)
    np = Symbol('np', nonpositive=True)
    np_ = Symbol('np_', nonpositive=True)
    r = Symbol('r', real=True)

    assert Max(5, 4) == 5

    # lists

    raises(ValueError, lambda: Max())
    assert Max(x, y) == Max(y, x)
    assert Max(x, y, z) == Max(z, y, x)
    assert Max(x, Max(y, z)) == Max(z, y, x)
    assert Max(x, Min(y, oo)) == Max(x, y)
    assert Max(n, -oo, n_, p, 2) == Max(p, 2)
    assert Max(n, -oo, n_, p) == p
    assert Max(2, x, p, n, -oo, S.NegativeInfinity, n_, p, 2) == Max(2, x, p)
    assert Max(0, x, 1, y) == Max(1, x, y)
    assert Max(r, r + 1, r - 1) == 1 + r
    assert Max(1000, 100, -100, x, p, n) == Max(p, x, 1000)
    assert Max(cos(x), sin(x)) == Max(sin(x), cos(x))
    assert Max(cos(x), sin(x)).subs(x, 1) == sin(1)
    assert Max(cos(x), sin(x)).subs(x, S(1) / 2) == cos(S(1) / 2)
    raises(ValueError, lambda: Max(cos(x), sin(x)).subs(x, I))
    raises(ValueError, lambda: Max(I))
    raises(ValueError, lambda: Max(I, x))
    raises(ValueError, lambda: Max(S.ComplexInfinity, 1))
    assert Max(n, -oo, n_, p, 2) == Max(p, 2)
    assert Max(n, -oo, n_, p, 1000) == Max(p, 1000)

    assert Max(1, x).diff(x) == Heaviside(x - 1)
    assert Max(x, 1).diff(x) == Heaviside(x - 1)
    assert Max(x**2, 1 + x, 1).diff(x) == \
        2*x*Heaviside(x**2 - Max(1, x + 1)) \
        + Heaviside(x - Max(1, x**2) + 1)

    e = Max(0, x)
    assert e.evalf == e.n
    assert e.n().args == (0, x)

    # issue 8643
    m = Max(p, p_, n, r)
    assert m.is_positive is True
    assert m.is_nonnegative is True
    assert m.is_negative is False

    m = Max(n, n_)
    assert m.is_positive is False
    assert m.is_nonnegative is False
    assert m.is_negative is True

    m = Max(n, n_, r)
    assert m.is_positive is None
    assert m.is_nonnegative is None
    assert m.is_negative is None

    m = Max(n, nn, r)
    assert m.is_positive is None
    assert m.is_nonnegative is True
    assert m.is_negative is False
Пример #14
0
def test_sympy__functions__elementary__miscellaneous__Min():
    from sympy.functions.elementary.miscellaneous import Min
    assert _test_args(Min(x, 2))
Пример #15
0
def test_issue_21399():
    from sympy.abc import a, b, c
    assert Max(Min(a, b), Min(a, b, c)) == Min(a, b)
Пример #16
0
    def _eval_imageset(self, f):
        from sympy.functions.elementary.miscellaneous import Min, Max
        from sympy.solvers import solve
        from sympy.core.function import diff
        from sympy.series import limit
        from sympy.calculus.singularities import singularities
        # TODO: handle piecewise defined functions
        # TODO: handle functions with infinitely many solutions (eg, sin, tan)
        # TODO: handle multivariate functions

        expr = f.expr
        if len(expr.free_symbols) > 1 or len(f.variables) != 1:
            return
        var = f.variables[0]

        if not self.start.is_comparable or not self.end.is_comparable:
            return

        try:
            sing = [
                x for x in singularities(expr, var) if x.is_real and x in self
            ]
        except NotImplementedError:
            return

        if self.left_open:
            _start = limit(expr, var, self.start, dir="+")
        elif self.start not in sing:
            _start = f(self.start)
        if self.right_open:
            _end = limit(expr, var, self.end, dir="-")
        elif self.end not in sing:
            _end = f(self.end)

        if len(sing) == 0:
            solns = solve(diff(expr, var), var)

            extr = [_start, _end
                    ] + [f(x) for x in solns if x.is_real and x in self]
            start, end = Min(*extr), Max(*extr)

            left_open, right_open = False, False
            if _start <= _end:
                # the minimum or maximum value can occur simultaneously
                # on both the edge of the interval and in some interior
                # point
                if start == _start and start not in solns:
                    left_open = self.left_open
                if end == _end and end not in solns:
                    right_open = self.right_open
            else:
                if start == _end and start not in solns:
                    left_open = self.right_open
                if end == _start and end not in solns:
                    right_open = self.left_open

            return Interval(start, end, left_open, right_open)
        else:
            return imageset(f, Interval(self.start, sing[0],
                                        self.left_open, True)) + \
                Union(*[imageset(f, Interval(sing[i], sing[i + 1]), True, True)
                        for i in range(1, len(sing) - 1)]) + \
                imageset(f, Interval(sing[-1], self.end, True, self.right_open))
Пример #17
0
 def _print_Min(self, expr):
     from sympy.functions.elementary.miscellaneous import Min
     if len(expr.args) == 1:
         return self._print(expr.args[0])
     return "%smin(%s, %s)" % (self._ns, self._print(expr.args[0]),
                               self._print(Min(*expr.args[1:])))
Пример #18
0
    def _intervals(self, sym):
        """Return a list of unique tuples, (a, b, e, i), where a and b
        are the lower and upper bounds in which the expression e of
        argument i in self is defined and a < b (when involving
        numbers) or a <= b when involving symbols.

        If there are any relationals not involving sym, or any
        relational cannot be solved for sym, NotImplementedError is
        raised. The calling routine should have removed such
        relationals before calling this routine.

        The evaluated conditions will be returned as ranges.
        Discontinuous ranges will be returned separately with
        identical expressions. The first condition that evaluates to
        True will be returned as the last tuple with a, b = -oo, oo.
        """
        from sympy.solvers.inequalities import _solve_inequality
        from sympy.logic.boolalg import to_cnf, distribute_or_over_and

        assert isinstance(self, Piecewise)

        def _solve_relational(r):
            if sym not in r.free_symbols:
                nonsymfail(r)
            rv = _solve_inequality(r, sym)
            if isinstance(rv, Relational):
                free = rv.args[1].free_symbols
                if rv.args[0] != sym or sym in free:
                    raise NotImplementedError(
                        filldedent('''
                        Unable to solve relational
                        %s for %s.''' % (r, sym)))
                if rv.rel_op == '==':
                    # this equality has been affirmed to have the form
                    # Eq(sym, rhs) where rhs is sym-free; it represents
                    # a zero-width interval which will be ignored
                    # whether it is an isolated condition or contained
                    # within an And or an Or
                    rv = S.false
                elif rv.rel_op == '!=':
                    try:
                        rv = Or(sym < rv.rhs, sym > rv.rhs)
                    except TypeError:
                        # e.g. x != I ==> all real x satisfy
                        rv = S.true
            elif rv == (S.NegativeInfinity < sym) & (sym < S.Infinity):
                rv = S.true
            return rv

        def nonsymfail(cond):
            raise NotImplementedError(
                filldedent('''
                A condition not involving
                %s appeared: %s''' % (sym, cond)))

        # make self canonical wrt Relationals
        reps = dict([(r, _solve_relational(r))
                     for r in self.atoms(Relational)])
        # process args individually so if any evaluate, their position
        # in the original Piecewise will be known
        args = [i.xreplace(reps) for i in self.args]

        # precondition args
        expr_cond = []
        default = idefault = None
        for i, (expr, cond) in enumerate(args):
            if cond is S.false:
                continue
            elif cond is S.true:
                default = expr
                idefault = i
                break

            cond = to_cnf(cond)
            if isinstance(cond, And):
                cond = distribute_or_over_and(cond)

            if isinstance(cond, Or):
                expr_cond.extend([(i, expr, o) for o in cond.args
                                  if not isinstance(o, Equality)])
            elif cond is not S.false:
                expr_cond.append((i, expr, cond))

        # determine intervals represented by conditions
        int_expr = []
        for iarg, expr, cond in expr_cond:
            if isinstance(cond, And):
                lower = S.NegativeInfinity
                upper = S.Infinity
                for cond2 in cond.args:
                    if isinstance(cond2, Equality):
                        lower = upper  # ignore
                        break
                    elif cond2.lts == sym:
                        upper = Min(cond2.gts, upper)
                    elif cond2.gts == sym:
                        lower = Max(cond2.lts, lower)
                    else:
                        nonsymfail(cond2)  # should never get here
            elif isinstance(cond, Relational):
                lower, upper = cond.lts, cond.gts  # part 1: initialize with givens
                if cond.lts == sym:  # part 1a: expand the side ...
                    lower = S.NegativeInfinity  # e.g. x <= 0 ---> -oo <= 0
                elif cond.gts == sym:  # part 1a: ... that can be expanded
                    upper = S.Infinity  # e.g. x >= 0 --->  oo >= 0
                else:
                    nonsymfail(cond)
            else:
                raise NotImplementedError('unrecognized condition: %s' % cond)

            lower, upper = lower, Max(lower, upper)
            if (lower >= upper) is not S.true:
                int_expr.append((lower, upper, expr, iarg))

        if default is not None:
            int_expr.append(
                (S.NegativeInfinity, S.Infinity, default, idefault))

        return list(uniq(int_expr))
Пример #19
0
    def __pow__(self, other):
        from sympy.functions.elementary.miscellaneous import real_root
        if isinstance(other, Expr):
            if other is S.Infinity:
                if self.min.is_nonnegative:
                    if self.max < 1:
                        return S.Zero
                    if self.min > 1:
                        return S.Infinity
                    return AccumBounds(0, oo)
                elif self.max.is_negative:
                    if self.min > -1:
                        return S.Zero
                    if self.max < -1:
                        return FiniteSet(-oo, oo)
                    return AccumBounds(-oo, oo)
                else:
                    if self.min > -1:
                        if self.max < 1:
                            return S.Zero
                        return AccumBounds(0, oo)
                    return AccumBounds(-oo, oo)

            if other is S.NegativeInfinity:
                return (1/self)**oo

            if other.is_real and other.is_number:
                if other.is_zero:
                    return S.One

                if other.is_Integer:
                    if self.min.is_positive:
                        return AccumBounds(Min(self.min**other, self.max**other),
                            Max(self.min**other, self.max**other))
                    elif self.max.is_negative:
                        return AccumBounds(Min(self.max**other, self.min**other),
                                    Max(self.max**other, self.min**other))

                    if other % 2 == 0:
                        if other.is_negative:
                            if self.min.is_zero:
                                return AccumBounds(self.max**other, oo)
                            if self.max.is_zero:
                                return AccumBounds(self.min**other, oo)
                            return AccumBounds(0, oo)
                        return AccumBounds(S.Zero,
                            Max(self.min**other, self.max**other))
                    else:
                        if other.is_negative:
                            if self.min.is_zero:
                                return AccumBounds(self.max**other, oo)
                            if self.max.is_zero:
                                return AccumBounds(-oo, self.min**other)
                            return AccumBounds(-oo, oo)
                        return AccumBounds(self.min**other, self.max**other)

                num, den = other.as_numer_denom()
                if num == S(1):
                    if den % 2 == 0:
                        if S.Zero in self:
                            if self.min.is_negative:
                                return AccumBounds(0, real_root(self.max, den))
                    return AccumBounds(real_root(self.min, den),
                                    real_root(self.max, den))
                num_pow = self**num
                return num_pow**(1/den)
            return Pow(self, other, evaluate=False)

        return NotImplemented
Пример #20
0
def test_Min():
    from sympy.abc import x, y, z
    n = Symbol('n', negative=True)
    n_ = Symbol('n_', negative=True)
    nn = Symbol('nn', nonnegative=True)
    nn_ = Symbol('nn_', nonnegative=True)
    p = Symbol('p', positive=True)
    p_ = Symbol('p_', positive=True)
    np = Symbol('np', nonpositive=True)
    np_ = Symbol('np_', nonpositive=True)
    r = Symbol('r', real=True)

    assert Min(5, 4) == 4
    assert Min(-oo, -oo) == -oo
    assert Min(-oo, n) == -oo
    assert Min(n, -oo) == -oo
    assert Min(-oo, np) == -oo
    assert Min(np, -oo) == -oo
    assert Min(-oo, 0) == -oo
    assert Min(0, -oo) == -oo
    assert Min(-oo, nn) == -oo
    assert Min(nn, -oo) == -oo
    assert Min(-oo, p) == -oo
    assert Min(p, -oo) == -oo
    assert Min(-oo, oo) == -oo
    assert Min(oo, -oo) == -oo
    assert Min(n, n) == n
    assert Min(n, np) == Min(n, np)
    assert Min(np, n) == Min(np, n)
    assert Min(n, 0) == n
    assert Min(0, n) == n
    assert Min(n, nn) == n
    assert Min(nn, n) == n
    assert Min(n, p) == n
    assert Min(p, n) == n
    assert Min(n, oo) == n
    assert Min(oo, n) == n
    assert Min(np, np) == np
    assert Min(np, 0) == np
    assert Min(0, np) == np
    assert Min(np, nn) == np
    assert Min(nn, np) == np
    assert Min(np, p) == np
    assert Min(p, np) == np
    assert Min(np, oo) == np
    assert Min(oo, np) == np
    assert Min(0, 0) == 0
    assert Min(0, nn) == 0
    assert Min(nn, 0) == 0
    assert Min(0, p) == 0
    assert Min(p, 0) == 0
    assert Min(0, oo) == 0
    assert Min(oo, 0) == 0
    assert Min(nn, nn) == nn
    assert Min(nn, p) == Min(nn, p)
    assert Min(p, nn) == Min(p, nn)
    assert Min(nn, oo) == nn
    assert Min(oo, nn) == nn
    assert Min(p, p) == p
    assert Min(p, oo) == p
    assert Min(oo, p) == p
    assert Min(oo, oo) == oo

    assert Min(n, n_).func is Min
    assert Min(nn, nn_).func is Min
    assert Min(np, np_).func is Min
    assert Min(p, p_).func is Min

    # lists
    raises(ValueError, lambda: Min())
    assert Min(x, y) == Min(y, x)
    assert Min(x, y, z) == Min(z, y, x)
    assert Min(x, Min(y, z)) == Min(z, y, x)
    assert Min(x, Max(y, -oo)) == Min(x, y)
    assert Min(p, oo, n, p, p, p_) == n
    assert Min(p_, n_, p) == n_
    assert Min(n, oo, -7, p, p, 2) == Min(n, -7)
    assert Min(2, x, p, n, oo, n_, p, 2, -2, -2) == Min(-2, x, n, n_)
    assert Min(0, x, 1, y) == Min(0, x, y)
    assert Min(1000, 100, -100, x, p, n) == Min(n, x, -100)
    assert Min(cos(x), sin(x)) == Min(cos(x), sin(x))
    assert Min(cos(x), sin(x)).subs(x, 1) == cos(1)
    assert Min(cos(x), sin(x)).subs(x, S(1)/2) == sin(S(1)/2)
    raises(ValueError, lambda: Min(cos(x), sin(x)).subs(x, I))
    raises(ValueError, lambda: Min(I))
    raises(ValueError, lambda: Min(I, x))
    raises(ValueError, lambda: Min(S.ComplexInfinity, x))

    assert Min(1, x).diff(x) == Heaviside(1 - x)
    assert Min(x, 1).diff(x) == Heaviside(1 - x)
    assert Min(0, -x, 1 - 2*x).diff(x) == -Heaviside(x + Min(0, -2*x + 1)) \
        - 2*Heaviside(2*x + Min(0, -x) - 1)

    a, b = Symbol('a', real=True), Symbol('b', real=True)
    # a and b are both real, Min(a, b) should be real
    assert Min(a, b).is_real

    # issue 7619
    f = Function('f')
    assert Min(1, 2*Min(f(1), 2))  # doesn't fail

    # issue 7233
    e = Min(0, x)
    assert e.evalf == e.n
    assert e.n().args == (0, x)

    # issue 8643
    m = Min(n, p_, n_, r)
    assert m.is_positive is False
    assert m.is_nonnegative is False
    assert m.is_negative is True

    m = Min(p, p_)
    assert m.is_positive is True
    assert m.is_nonnegative is True
    assert m.is_negative is False

    m = Min(p, nn_, p_)
    assert m.is_positive is None
    assert m.is_nonnegative is True
    assert m.is_negative is False

    m = Min(nn, p, r)
    assert m.is_positive is None
    assert m.is_nonnegative is None
    assert m.is_negative is None
Пример #21
0
def sum_limit(r, w, n0, di, i0, index=0):
    return slice(
        di, Max(0, -(i0 // r[index])),
        Min(-1 // r[index] + w.shape[index], (n0 - i0 - 1) // r[index]) + 1)
Пример #22
0
 def _inf(self):
     # We use Min so that sup is meaningful in combination with symbolic
     # interval end points.
     from sympy.functions.elementary.miscellaneous import Min
     return Min(*[set.inf for set in self.args])
Пример #23
0
    def _sort_expr_cond(self, sym, a, b, targetcond=None):
        """Determine what intervals the expr, cond pairs affect.

        1) If cond is True, then log it as default
        1.1) Currently if cond can't be evaluated, throw NotImplementedError.
        2) For each inequality, if previous cond defines part of the interval
           update the new conds interval.
           -  eg x < 1, x < 3 -> [oo,1],[1,3] instead of [oo,1],[oo,3]
        3) Sort the intervals to make it easier to find correct exprs

        Under normal use, we return the expr,cond pairs in increasing order
        along the real axis corresponding to the symbol sym.  If targetcond
        is given, we return a list of (lowerbound, upperbound) pairs for
        this condition."""
        default = None
        int_expr = []
        expr_cond = []
        or_cond = False
        or_intervals = []
        for expr, cond in self.args:
            if isinstance(cond, Or):
                for cond2 in sorted(cond.args, key=default_sort_key):
                    expr_cond.append((expr, cond2))
            else:
                expr_cond.append((expr, cond))
            if cond is True:
                break
        for expr, cond in expr_cond:
            if cond is True:
                default = expr
                break
            elif isinstance(cond, Equality):
                continue
            elif isinstance(cond, And):
                lower = S.NegativeInfinity
                upper = S.Infinity
                for cond2 in cond.args:
                    if cond2.lts.has(sym):
                        upper = Min(cond2.gts, upper)
                    elif cond2.gts.has(sym):
                        lower = Max(cond2.lts, lower)
            else:
                lower, upper = cond.lts, cond.gts  # part 1: initialize with givens
                if cond.lts.has(sym):  # part 1a: expand the side ...
                    lower = S.NegativeInfinity  # e.g. x <= 0 ---> -oo <= 0
                elif cond.gts.has(sym):  # part 1a: ... that can be expanded
                    upper = S.Infinity  # e.g. x >= 0 --->  oo >= 0
                else:
                    raise NotImplementedError(
                        "Unable to handle interval evaluation of expression.")

            # part 1b: Reduce (-)infinity to what was passed in.
            lower, upper = Max(a, lower), Min(b, upper)

            for n in xrange(len(int_expr)):
                # Part 2: remove any interval overlap.  For any conflicts, the
                # iterval already there wins, and the incoming interval updates
                # its bounds accordingly.
                if self.__eval_cond(lower < int_expr[n][1]) and \
                        self.__eval_cond(lower >= int_expr[n][0]):
                    lower = int_expr[n][1]
                elif len(int_expr[n][1].free_symbols) and \
                        self.__eval_cond(lower >= int_expr[n][0]):
                    if self.__eval_cond(lower == int_expr[n][0]):
                        lower = int_expr[n][1]
                    else:
                        int_expr[n][1] = Min(lower, int_expr[n][1])
                elif len(int_expr[n][1].free_symbols) and \
                        lower < int_expr[n][0] is not True:
                    upper = Min(upper, int_expr[n][0])
                elif self.__eval_cond(upper > int_expr[n][0]) and \
                        self.__eval_cond(upper <= int_expr[n][1]):
                    upper = int_expr[n][0]
                elif len(int_expr[n][0].free_symbols) and \
                        self.__eval_cond(upper < int_expr[n][1]):
                    int_expr[n][0] = Max(upper, int_expr[n][0])

            if self.__eval_cond(
                    lower >= upper) is not True:  # Is it still an interval?
                int_expr.append([lower, upper, expr])
            if cond is targetcond:
                return [(lower, upper)]
            elif isinstance(targetcond, Or) and cond in targetcond.args:
                or_cond = Or(or_cond, cond)
                or_intervals.append((lower, upper))
                if or_cond == targetcond:
                    or_intervals.sort(key=lambda x: x[0])
                    return or_intervals

        int_expr.sort(key=lambda x: x[1].sort_key()
                      if x[1].is_number else S.NegativeInfinity.sort_key())
        int_expr.sort(key=lambda x: x[0].sort_key()
                      if x[0].is_number else S.Infinity.sort_key())
        from sympy.functions.elementary.miscellaneous import MinMaxBase
        for n in xrange(len(int_expr)):
            if len(int_expr[n][0].free_symbols) or len(
                    int_expr[n][1].free_symbols):
                if isinstance(int_expr[n][1], Min) or int_expr[n][1] == b:
                    newval = Min(*int_expr[n][:-1])
                    if n > 0 and int_expr[n][0] == int_expr[n - 1][1]:
                        int_expr[n - 1][1] = newval
                    int_expr[n][0] = newval
                else:
                    newval = Max(*int_expr[n][:-1])
                    if n < len(int_expr) - 1 and int_expr[n][1] == int_expr[
                            n + 1][0]:
                        int_expr[n + 1][0] = newval
                    int_expr[n][1] = newval

        # Add holes to list of intervals if there is a default value,
        # otherwise raise a ValueError.
        holes = []
        curr_low = a
        for int_a, int_b, expr in int_expr:
            if (curr_low < int_a) is True:
                holes.append([curr_low, Min(b, int_a), default])
            elif (curr_low >= int_a) is not True:
                holes.append([curr_low, Min(b, int_a), default])
            curr_low = Min(b, int_b)
        if (curr_low < b) is True:
            holes.append([Min(b, curr_low), b, default])
        elif (curr_low >= b) is not True:
            holes.append([Min(b, curr_low), b, default])

        if holes and default is not None:
            int_expr.extend(holes)
            if targetcond is True:
                return [(h[0], h[1]) for h in holes]
        elif holes and default is None:
            raise ValueError("Called interval evaluation over piecewise "
                             "function on undefined intervals %s" %
                             ", ".join([str((h[0], h[1])) for h in holes]))

        return int_expr
Пример #24
0
 def _inf(self):
     from sympy.functions.elementary.miscellaneous import Min
     return Min(*self)
Пример #25
0
def _LUdecomposition_Simple(M, iszerofunc=_iszero, simpfunc=None,
        rankcheck=False):
    r"""Compute the PLU decomposition of the matrix.

    Parameters
    ==========

    rankcheck : bool, optional
        Determines if this function should detect the rank
        deficiency of the matrixis and should raise a
        ``ValueError``.

    iszerofunc : function, optional
        A function which determines if a given expression is zero.

        The function should be a callable that takes a single
        sympy expression and returns a 3-valued boolean value
        ``True``, ``False``, or ``None``.

        It is internally used by the pivot searching algorithm.
        See the notes section for a more information about the
        pivot searching algorithm.

    simpfunc : function or None, optional
        A function that simplifies the input.

        If this is specified as a function, this function should be
        a callable that takes a single sympy expression and returns
        an another sympy expression that is algebraically
        equivalent.

        If ``None``, it indicates that the pivot search algorithm
        should not attempt to simplify any candidate pivots.

        It is internally used by the pivot searching algorithm.
        See the notes section for a more information about the
        pivot searching algorithm.

    Returns
    =======

    (lu, row_swaps) : (Matrix, list)
        If the original matrix is a $m, n$ matrix:

        *lu* is a $m, n$ matrix, which contains result of the
        decomposition in a compresed form. See the notes section
        to see how the matrix is compressed.

        *row_swaps* is a $m$-element list where each element is a
        pair of row exchange indices.

        ``A = (L*U).permute_backward(perm)``, and the row
        permutation matrix $P$ from the formula $P A = L U$ can be
        computed by ``P=eye(A.row).permute_forward(perm)``.

    Raises
    ======

    ValueError
        Raised if ``rankcheck=True`` and the matrix is found to
        be rank deficient during the computation.

    Notes
    =====

    About the PLU decomposition:

    PLU decomposition is a generalization of a LU decomposition
    which can be extended for rank-deficient matrices.

    It can further be generalized for non-square matrices, and this
    is the notation that SymPy is using.

    PLU decomposition is a decomposition of a $m, n$ matrix $A$ in
    the form of $P A = L U$ where

    * $L$ is a $m, m$ lower triangular matrix with unit diagonal
        entries.
    * $U$ is a $m, n$ upper triangular matrix.
    * $P$ is a $m, m$ permutation matrix.

    So, for a square matrix, the decomposition would look like:

    .. math::
        L = \begin{bmatrix}
        1 & 0 & 0 & \cdots & 0 \\
        L_{1, 0} & 1 & 0 & \cdots & 0 \\
        L_{2, 0} & L_{2, 1} & 1 & \cdots & 0 \\
        \vdots & \vdots & \vdots & \ddots & \vdots \\
        L_{n-1, 0} & L_{n-1, 1} & L_{n-1, 2} & \cdots & 1
        \end{bmatrix}

    .. math::
        U = \begin{bmatrix}
        U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, n-1} \\
        0 & U_{1, 1} & U_{1, 2} & \cdots & U_{1, n-1} \\
        0 & 0 & U_{2, 2} & \cdots & U_{2, n-1} \\
        \vdots & \vdots & \vdots & \ddots & \vdots \\
        0 & 0 & 0 & \cdots & U_{n-1, n-1}
        \end{bmatrix}

    And for a matrix with more rows than the columns,
    the decomposition would look like:

    .. math::
        L = \begin{bmatrix}
        1 & 0 & 0 & \cdots & 0 & 0 & \cdots & 0 \\
        L_{1, 0} & 1 & 0 & \cdots & 0 & 0 & \cdots & 0 \\
        L_{2, 0} & L_{2, 1} & 1 & \cdots & 0 & 0 & \cdots & 0 \\
        \vdots & \vdots & \vdots & \ddots & \vdots & \vdots & \ddots
        & \vdots \\
        L_{n-1, 0} & L_{n-1, 1} & L_{n-1, 2} & \cdots & 1 & 0
        & \cdots & 0 \\
        L_{n, 0} & L_{n, 1} & L_{n, 2} & \cdots & L_{n, n-1} & 1
        & \cdots & 0 \\
        \vdots & \vdots & \vdots & \ddots & \vdots & \vdots
        & \ddots & \vdots \\
        L_{m-1, 0} & L_{m-1, 1} & L_{m-1, 2} & \cdots & L_{m-1, n-1}
        & 0 & \cdots & 1 \\
        \end{bmatrix}

    .. math::
        U = \begin{bmatrix}
        U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, n-1} \\
        0 & U_{1, 1} & U_{1, 2} & \cdots & U_{1, n-1} \\
        0 & 0 & U_{2, 2} & \cdots & U_{2, n-1} \\
        \vdots & \vdots & \vdots & \ddots & \vdots \\
        0 & 0 & 0 & \cdots & U_{n-1, n-1} \\
        0 & 0 & 0 & \cdots & 0 \\
        \vdots & \vdots & \vdots & \ddots & \vdots \\
        0 & 0 & 0 & \cdots & 0
        \end{bmatrix}

    Finally, for a matrix with more columns than the rows, the
    decomposition would look like:

    .. math::
        L = \begin{bmatrix}
        1 & 0 & 0 & \cdots & 0 \\
        L_{1, 0} & 1 & 0 & \cdots & 0 \\
        L_{2, 0} & L_{2, 1} & 1 & \cdots & 0 \\
        \vdots & \vdots & \vdots & \ddots & \vdots \\
        L_{m-1, 0} & L_{m-1, 1} & L_{m-1, 2} & \cdots & 1
        \end{bmatrix}

    .. math::
        U = \begin{bmatrix}
        U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, m-1}
        & \cdots & U_{0, n-1} \\
        0 & U_{1, 1} & U_{1, 2} & \cdots & U_{1, m-1}
        & \cdots & U_{1, n-1} \\
        0 & 0 & U_{2, 2} & \cdots & U_{2, m-1}
        & \cdots & U_{2, n-1} \\
        \vdots & \vdots & \vdots & \ddots & \vdots
        & \cdots & \vdots \\
        0 & 0 & 0 & \cdots & U_{m-1, m-1}
        & \cdots & U_{m-1, n-1} \\
        \end{bmatrix}

    About the compressed LU storage:

    The results of the decomposition are often stored in compressed
    forms rather than returning $L$ and $U$ matrices individually.

    It may be less intiuitive, but it is commonly used for a lot of
    numeric libraries because of the efficiency.

    The storage matrix is defined as following for this specific
    method:

    * The subdiagonal elements of $L$ are stored in the subdiagonal
        portion of $LU$, that is $LU_{i, j} = L_{i, j}$ whenever
        $i > j$.
    * The elements on the diagonal of $L$ are all 1, and are not
        explicitly stored.
    * $U$ is stored in the upper triangular portion of $LU$, that is
        $LU_{i, j} = U_{i, j}$ whenever $i <= j$.
    * For a case of $m > n$, the right side of the $L$ matrix is
        trivial to store.
    * For a case of $m < n$, the below side of the $U$ matrix is
        trivial to store.

    So, for a square matrix, the compressed output matrix would be:

    .. math::
        LU = \begin{bmatrix}
        U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, n-1} \\
        L_{1, 0} & U_{1, 1} & U_{1, 2} & \cdots & U_{1, n-1} \\
        L_{2, 0} & L_{2, 1} & U_{2, 2} & \cdots & U_{2, n-1} \\
        \vdots & \vdots & \vdots & \ddots & \vdots \\
        L_{n-1, 0} & L_{n-1, 1} & L_{n-1, 2} & \cdots & U_{n-1, n-1}
        \end{bmatrix}

    For a matrix with more rows than the columns, the compressed
    output matrix would be:

    .. math::
        LU = \begin{bmatrix}
        U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, n-1} \\
        L_{1, 0} & U_{1, 1} & U_{1, 2} & \cdots & U_{1, n-1} \\
        L_{2, 0} & L_{2, 1} & U_{2, 2} & \cdots & U_{2, n-1} \\
        \vdots & \vdots & \vdots & \ddots & \vdots \\
        L_{n-1, 0} & L_{n-1, 1} & L_{n-1, 2} & \cdots
        & U_{n-1, n-1} \\
        \vdots & \vdots & \vdots & \ddots & \vdots \\
        L_{m-1, 0} & L_{m-1, 1} & L_{m-1, 2} & \cdots
        & L_{m-1, n-1} \\
        \end{bmatrix}

    For a matrix with more columns than the rows, the compressed
    output matrix would be:

    .. math::
        LU = \begin{bmatrix}
        U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, m-1}
        & \cdots & U_{0, n-1} \\
        L_{1, 0} & U_{1, 1} & U_{1, 2} & \cdots & U_{1, m-1}
        & \cdots & U_{1, n-1} \\
        L_{2, 0} & L_{2, 1} & U_{2, 2} & \cdots & U_{2, m-1}
        & \cdots & U_{2, n-1} \\
        \vdots & \vdots & \vdots & \ddots & \vdots
        & \cdots & \vdots \\
        L_{m-1, 0} & L_{m-1, 1} & L_{m-1, 2} & \cdots & U_{m-1, m-1}
        & \cdots & U_{m-1, n-1} \\
        \end{bmatrix}

    About the pivot searching algorithm:

    When a matrix contains symbolic entries, the pivot search algorithm
    differs from the case where every entry can be categorized as zero or
    nonzero.
    The algorithm searches column by column through the submatrix whose
    top left entry coincides with the pivot position.
    If it exists, the pivot is the first entry in the current search
    column that iszerofunc guarantees is nonzero.
    If no such candidate exists, then each candidate pivot is simplified
    if simpfunc is not None.
    The search is repeated, with the difference that a candidate may be
    the pivot if ``iszerofunc()`` cannot guarantee that it is nonzero.
    In the second search the pivot is the first candidate that
    iszerofunc can guarantee is nonzero.
    If no such candidate exists, then the pivot is the first candidate
    for which iszerofunc returns None.
    If no such candidate exists, then the search is repeated in the next
    column to the right.
    The pivot search algorithm differs from the one in ``rref()``, which
    relies on ``_find_reasonable_pivot()``.
    Future versions of ``LUdecomposition_simple()`` may use
    ``_find_reasonable_pivot()``.

    See Also
    ========

    sympy.matrices.matrices.MatrixBase.LUdecomposition
    LUdecompositionFF
    LUsolve
    """

    if rankcheck:
        # https://github.com/sympy/sympy/issues/9796
        pass

    if M.rows == 0 or M.cols == 0:
        # Define LU decomposition of a matrix with no entries as a matrix
        # of the same dimensions with all zero entries.
        return M.zeros(M.rows, M.cols), []

    dps       = _get_intermediate_simp()
    lu        = M.as_mutable()
    row_swaps = []

    pivot_col = 0

    for pivot_row in range(0, lu.rows - 1):
        # Search for pivot. Prefer entry that iszeropivot determines
        # is nonzero, over entry that iszeropivot cannot guarantee
        # is  zero.
        # XXX ``_find_reasonable_pivot`` uses slow zero testing. Blocked by bug #10279
        # Future versions of LUdecomposition_simple can pass iszerofunc and simpfunc
        # to _find_reasonable_pivot().
        # In pass 3 of _find_reasonable_pivot(), the predicate in ``if x.equals(S.Zero):``
        # calls sympy.simplify(), and not the simplification function passed in via
        # the keyword argument simpfunc.
        iszeropivot = True

        while pivot_col != M.cols and iszeropivot:
            sub_col = (lu[r, pivot_col] for r in range(pivot_row, M.rows))

            pivot_row_offset, pivot_value, is_assumed_non_zero, ind_simplified_pairs =\
                _find_reasonable_pivot_naive(sub_col, iszerofunc, simpfunc)

            iszeropivot = pivot_value is None

            if iszeropivot:
                # All candidate pivots in this column are zero.
                # Proceed to next column.
                pivot_col += 1

        if rankcheck and pivot_col != pivot_row:
            # All entries including and below the pivot position are
            # zero, which indicates that the rank of the matrix is
            # strictly less than min(num rows, num cols)
            # Mimic behavior of previous implementation, by throwing a
            # ValueError.
            raise ValueError("Rank of matrix is strictly less than"
                                " number of rows or columns."
                                " Pass keyword argument"
                                " rankcheck=False to compute"
                                " the LU decomposition of this matrix.")

        candidate_pivot_row = None if pivot_row_offset is None else pivot_row + pivot_row_offset

        if candidate_pivot_row is None and iszeropivot:
            # If candidate_pivot_row is None and iszeropivot is True
            # after pivot search has completed, then the submatrix
            # below and to the right of (pivot_row, pivot_col) is
            # all zeros, indicating that Gaussian elimination is
            # complete.
            return lu, row_swaps

        # Update entries simplified during pivot search.
        for offset, val in ind_simplified_pairs:
            lu[pivot_row + offset, pivot_col] = val

        if pivot_row != candidate_pivot_row:
            # Row swap book keeping:
            # Record which rows were swapped.
            # Update stored portion of L factor by multiplying L on the
            # left and right with the current permutation.
            # Swap rows of U.
            row_swaps.append([pivot_row, candidate_pivot_row])

            # Update L.
            lu[pivot_row, 0:pivot_row], lu[candidate_pivot_row, 0:pivot_row] = \
                lu[candidate_pivot_row, 0:pivot_row], lu[pivot_row, 0:pivot_row]

            # Swap pivot row of U with candidate pivot row.
            lu[pivot_row, pivot_col:lu.cols], lu[candidate_pivot_row, pivot_col:lu.cols] = \
                lu[candidate_pivot_row, pivot_col:lu.cols], lu[pivot_row, pivot_col:lu.cols]

        # Introduce zeros below the pivot by adding a multiple of the
        # pivot row to a row under it, and store the result in the
        # row under it.
        # Only entries in the target row whose index is greater than
        # start_col may be nonzero.
        start_col = pivot_col + 1

        for row in range(pivot_row + 1, lu.rows):
            # Store factors of L in the subcolumn below
            # (pivot_row, pivot_row).
            lu[row, pivot_row] = \
                dps(lu[row, pivot_col]/lu[pivot_row, pivot_col])

            # Form the linear combination of the pivot row and the current
            # row below the pivot row that zeros the entries below the pivot.
            # Employing slicing instead of a loop here raises
            # NotImplementedError: Cannot add Zero to MutableSparseMatrix
            # in sympy/matrices/tests/test_sparse.py.
            # c = pivot_row + 1 if pivot_row == pivot_col else pivot_col
            for c in range(start_col, lu.cols):
                lu[row, c] = dps(lu[row, c] - lu[row, pivot_row]*lu[pivot_row, c])

        if pivot_row != pivot_col:
            # matrix rank < min(num rows, num cols),
            # so factors of L are not stored directly below the pivot.
            # These entries are zero by construction, so don't bother
            # computing them.
            for row in range(pivot_row + 1, lu.rows):
                lu[row, pivot_col] = M.zero

        pivot_col += 1

        if pivot_col == lu.cols:
            # All candidate pivots are zero implies that Gaussian
            # elimination is complete.
            return lu, row_swaps

    if rankcheck:
        if iszerofunc(
                lu[Min(lu.rows, lu.cols) - 1, Min(lu.rows, lu.cols) - 1]):
            raise ValueError("Rank of matrix is strictly less than"
                                " number of rows or columns."
                                " Pass keyword argument"
                                " rankcheck=False to compute"
                                " the LU decomposition of this matrix.")

    return lu, row_swaps
Пример #26
0
    def __pow__(self, other):
        if isinstance(other, Expr):
            if other is S.Infinity:
                if self.min.is_extended_nonnegative:
                    if self.max < 1:
                        return S.Zero
                    if self.min > 1:
                        return S.Infinity
                    return AccumBounds(0, oo)
                elif self.max.is_extended_negative:
                    if self.min > -1:
                        return S.Zero
                    if self.max < -1:
                        return zoo
                    return S.NaN
                else:
                    if self.min > -1:
                        if self.max < 1:
                            return S.Zero
                        return AccumBounds(0, oo)
                    return AccumBounds(-oo, oo)

            if other is S.NegativeInfinity:
                return (1 / self)**oo

            # generically true
            if (self.max - self.min).is_nonnegative:
                # well defined
                if self.min.is_nonnegative:
                    # no 0 to worry about
                    if other.is_nonnegative:
                        # no infinity to worry about
                        return self.func(self.min**other, self.max**other)

            if other.is_zero:
                return S.One  # x**0 = 1

            if other.is_Integer or other.is_integer:
                if self.min.is_extended_positive:
                    return AccumBounds(Min(self.min**other, self.max**other),
                                       Max(self.min**other, self.max**other))
                elif self.max.is_extended_negative:
                    return AccumBounds(Min(self.max**other, self.min**other),
                                       Max(self.max**other, self.min**other))

                if other % 2 == 0:
                    if other.is_extended_negative:
                        if self.min.is_zero:
                            return AccumBounds(self.max**other, oo)
                        if self.max.is_zero:
                            return AccumBounds(self.min**other, oo)
                        return AccumBounds(0, oo)
                    return AccumBounds(S.Zero,
                                       Max(self.min**other, self.max**other))
                elif other % 2 == 1:
                    if other.is_extended_negative:
                        if self.min.is_zero:
                            return AccumBounds(self.max**other, oo)
                        if self.max.is_zero:
                            return AccumBounds(-oo, self.min**other)
                        return AccumBounds(-oo, oo)
                    return AccumBounds(self.min**other, self.max**other)

            # non-integer exponent
            # 0**neg or neg**frac yields complex
            if (other.is_number or other.is_rational) and (
                    self.min.is_extended_nonnegative or
                (other.is_extended_nonnegative
                 and self.min.is_extended_nonnegative)):
                num, den = other.as_numer_denom()
                if num is S.One:
                    return AccumBounds(*[i**(1 / den) for i in self.args])

                elif den is not S.One:  # e.g. if other is not Float
                    return (self**num)**(1 / den)  # ok for non-negative base

            if isinstance(other, AccumBounds):
                if (self.min.is_extended_positive
                        or self.min.is_extended_nonnegative
                        and other.min.is_extended_nonnegative):
                    p = [self**i for i in other.args]
                    if not any(i.is_Pow for i in p):
                        a = [j for i in p for j in i.args or (i, )]
                        try:
                            return self.func(min(a), max(a))
                        except TypeError:  # can't sort
                            pass

            return Pow(self, other, evaluate=False)

        return NotImplemented
Пример #27
0
def test_Min_Max():
    # see gh-10375
    assert lambdify((x, y, z), Min(x, y, z))(1, 2, 3) == 1
    assert lambdify((x, y, z), Max(x, y, z))(1, 2, 3) == 3
Пример #28
0
def limit_seq(expr, n=None, trials=5):
    """Finds the limit of a sequence as index ``n`` tends to infinity.

    Parameters
    ==========

    expr : Expr
        SymPy expression for the ``n-th`` term of the sequence
    n : Symbol, optional
        The index of the sequence, an integer that tends to positive
        infinity. If None, inferred from the expression unless it has
        multiple symbols.
    trials: int, optional
        The algorithm is highly recursive. ``trials`` is a safeguard from
        infinite recursion in case the limit is not easily computed by the
        algorithm. Try increasing ``trials`` if the algorithm returns ``None``.

    Admissible Terms
    ================

    The algorithm is designed for sequences built from rational functions,
    indefinite sums, and indefinite products over an indeterminate n. Terms of
    alternating sign are also allowed, but more complex oscillatory behavior is
    not supported.

    Examples
    ========

    >>> from sympy import limit_seq, Sum, binomial
    >>> from sympy.abc import n, k, m
    >>> limit_seq((5*n**3 + 3*n**2 + 4) / (3*n**3 + 4*n - 5), n)
    5/3
    >>> limit_seq(binomial(2*n, n) / Sum(binomial(2*k, k), (k, 1, n)), n)
    3/4
    >>> limit_seq(Sum(k**2 * Sum(2**m/m, (m, 1, k)), (k, 1, n)) / (2**n*n), n)
    4

    See Also
    ========

    sympy.series.limitseq.dominant

    References
    ==========

    .. [1] Computing Limits of Sequences - Manuel Kauers
    """

    from sympy.concrete.summations import Sum
    if n is None:
        free = expr.free_symbols
        if len(free) == 1:
            n = free.pop()
        elif not free:
            return expr
        else:
            raise ValueError("Expression has more than one variable. "
                             "Please specify a variable.")
    elif n not in expr.free_symbols:
        return expr

    expr = expr.rewrite(fibonacci, S.GoldenRatio)
    expr = expr.rewrite(factorial, subfactorial, gamma)
    n_ = Dummy("n", integer=True, positive=True)
    n1 = Dummy("n", odd=True, positive=True)
    n2 = Dummy("n", even=True, positive=True)

    # If there is a negative term raised to a power involving n, or a
    # trigonometric function, then consider even and odd n separately.
    powers = (p.as_base_exp() for p in expr.atoms(Pow))
    if (any(b.is_negative and e.has(n) for b, e in powers)
            or expr.has(cos, sin)):
        L1 = _limit_seq(expr.xreplace({n: n1}), n1, trials)
        if L1 is not None:
            L2 = _limit_seq(expr.xreplace({n: n2}), n2, trials)
            if L1 != L2:
                if L1.is_comparable and L2.is_comparable:
                    return AccumulationBounds(Min(L1, L2), Max(L1, L2))
                else:
                    return None
    else:
        L1 = _limit_seq(expr.xreplace({n: n_}), n_, trials)
    if L1 is not None:
        return L1
    else:
        if expr.is_Add:
            limits = [limit_seq(term, n, trials) for term in expr.args]
            if any(result is None for result in limits):
                return None
            else:
                return Add(*limits)
        # Maybe the absolute value is easier to deal with (though not if
        # it has a Sum). If it tends to 0, the limit is 0.
        elif not expr.has(Sum):
            lim = _limit_seq(Abs(expr.xreplace({n: n_})), n_, trials)
            if lim is not None and lim.is_zero:
                return S.Zero
Пример #29
0
def _set_function(f, x):  # noqa:F811
    from sympy.functions.elementary.miscellaneous import Min, Max
    from sympy.solvers.solveset import solveset
    from sympy.core.function import diff, Lambda
    from sympy.series import limit
    from sympy.calculus.singularities import singularities
    from sympy.sets import Complement
    # TODO: handle functions with infinitely many solutions (eg, sin, tan)
    # TODO: handle multivariate functions

    expr = f.expr
    if len(expr.free_symbols) > 1 or len(f.variables) != 1:
        return
    var = f.variables[0]
    if not var.is_real:
        if expr.subs(var, Dummy(real=True)).is_real is False:
            return

    if expr.is_Piecewise:
        result = S.EmptySet
        domain_set = x
        for (p_expr, p_cond) in expr.args:
            if p_cond is true:
                intrvl = domain_set
            else:
                intrvl = p_cond.as_set()
                intrvl = Intersection(domain_set, intrvl)

            if p_expr.is_Number:
                image = FiniteSet(p_expr)
            else:
                image = imageset(Lambda(var, p_expr), intrvl)
            result = Union(result, image)

            # remove the part which has been `imaged`
            domain_set = Complement(domain_set, intrvl)
            if domain_set is S.EmptySet:
                break
        return result

    if not x.start.is_comparable or not x.end.is_comparable:
        return

    try:
        sing = [i for i in singularities(expr, var) if i.is_real and i in x]
    except NotImplementedError:
        return

    if x.left_open:
        _start = limit(expr, var, x.start, dir="+")
    elif x.start not in sing:
        _start = f(x.start)
    if x.right_open:
        _end = limit(expr, var, x.end, dir="-")
    elif x.end not in sing:
        _end = f(x.end)

    if len(sing) == 0:
        solns = list(solveset(diff(expr, var), var))

        extr = [_start, _end] + [f(i) for i in solns if i.is_real and i in x]
        start, end = Min(*extr), Max(*extr)

        left_open, right_open = False, False
        if _start <= _end:
            # the minimum or maximum value can occur simultaneously
            # on both the edge of the interval and in some interior
            # point
            if start == _start and start not in solns:
                left_open = x.left_open
            if end == _end and end not in solns:
                right_open = x.right_open
        else:
            if start == _end and start not in solns:
                left_open = x.right_open
            if end == _start and end not in solns:
                right_open = x.left_open

        return Interval(start, end, left_open, right_open)
    else:
        return imageset(f, Interval(x.start, sing[0],
                                    x.left_open, True)) + \
            Union(*[imageset(f, Interval(sing[i], sing[i + 1], True, True))
                    for i in range(0, len(sing) - 1)]) + \
            imageset(f, Interval(sing[-1], x.end, True, x.right_open))
Пример #30
0
def _rsolve_hypergeometric(f, x, P, Q, k, m):
    """Recursive wrapper to rsolve_hypergeometric.

    Returns a Tuple of (formula, series independent terms,
    maximum power of x in independent terms) if successful
    otherwise ``None``.

    See :func:`rsolve_hypergeometric` for details.
    """
    from sympy.polys import lcm, roots
    from sympy.integrals import integrate

    # transformation - c
    proots, qroots = roots(P, k), roots(Q, k)
    all_roots = dict(proots)
    all_roots.update(qroots)
    scale = lcm(
        [r.as_numer_denom()[1] for r, t in all_roots.items() if r.is_rational])
    f, P, Q, m = _transformation_c(f, x, P, Q, k, m, scale)

    # transformation - a
    qroots = roots(Q, k)
    if qroots:
        k_min = Min(*qroots.keys())
    else:
        k_min = S.Zero
    shift = k_min + m
    f, P, Q, m = _transformation_a(f, x, P, Q, k, m, shift)

    l = (x * f).limit(x, 0)
    if not isinstance(l, Limit) and l != 0:  # Ideally should only be l != 0
        return None

    qroots = roots(Q, k)
    if qroots:
        k_max = Max(*qroots.keys())
    else:
        k_max = S.Zero

    ind, mp = S.Zero, -oo
    for i in range(k_max + m + 1):
        r = f.diff(x, i).limit(x, 0) / factorial(i)
        if r.is_finite is False:
            old_f = f
            f, P, Q, m = _transformation_a(f, x, P, Q, k, m, i)
            f, P, Q, m = _transformation_e(f, x, P, Q, k, m)
            sol, ind, mp = _rsolve_hypergeometric(f, x, P, Q, k, m)
            sol = _apply_integrate(sol, x, k)
            sol = _apply_shift(sol, i)
            ind = integrate(ind, x)
            ind += (old_f - ind).limit(x, 0)  # constant of integration
            mp += 1
            return sol, ind, mp
        elif r:
            ind += r * x**(i + shift)
            pow_x = Rational((i + shift), scale)
            if pow_x > mp:
                mp = pow_x  # maximum power of x
    ind = ind.subs(x, x**(1 / scale))

    sol = _compute_formula(f, x, P, Q, k, m, k_max)
    sol = _apply_shift(sol, shift)
    sol = _apply_scale(sol, scale)

    return sol, ind, mp
Пример #31
0
    def _eval_interval(self, sym, a, b):
        """Evaluates the function along the sym in a given interval ab"""
        # FIXME: Currently complex intervals are not supported.  A possible
        # replacement algorithm, discussed in issue 2128, can be found in the
        # following papers;
        #     http://portal.acm.org/citation.cfm?id=281649
        #     http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.70.4127&rep=rep1&type=pdf

        if a is None or b is None:
            # In this case, it is just simple substitution
            return super(Piecewise, self)._eval_interval(sym, a, b)

        mul = 1
        if (a == b) is True:
            return S.Zero
        elif (a > b) is True:
            a, b, mul = b, a, -1
        elif (a <= b) is not True:
            newargs = []
            for e, c in self.args:
                intervals = self._sort_expr_cond(sym, S.NegativeInfinity,
                                                 S.Infinity, c)
                values = []
                for lower, upper in intervals:
                    if (a < lower) is True:
                        mid = lower
                        rep = b
                        val = e.subs(sym, b) - e.subs(sym, mid)
                        val += self._eval_interval(sym, a, mid)
                    elif (a > upper) is True:
                        mid = upper
                        rep = b
                        val = e.subs(sym, b) - e.subs(sym, mid)
                        val += self._eval_interval(sym, a, mid)
                    elif (a >= lower) is True and (a <= upper) is True:
                        rep = b
                        val = e.subs(sym, b) - e.subs(sym, a)
                    elif (b < lower) is True:
                        mid = lower
                        rep = a
                        val = e.subs(sym, mid) - e.subs(sym, a)
                        val += self._eval_interval(sym, mid, b)
                    elif (b > upper) is True:
                        mid = upper
                        rep = a
                        val = e.subs(sym, mid) - e.subs(sym, a)
                        val += self._eval_interval(sym, mid, b)
                    elif ((b >= lower) is True) and ((b <= upper) is True):
                        rep = a
                        val = e.subs(sym, b) - e.subs(sym, a)
                    else:
                        raise NotImplementedError(
                            """The evaluation of a Piecewise interval when both the lower
                            and the upper limit are symbolic is not yet implemented."""
                        )
                    values.append(val)
                if len(set(values)) == 1:
                    try:
                        c = c.subs(sym, rep)
                    except AttributeError:
                        pass
                    e = values[0]
                    newargs.append((e, c))
                else:
                    for i in range(len(values)):
                        newargs.append(
                            (values[i], (c is True and i == len(values) - 1)
                             or And(rep >= intervals[i][0],
                                    rep <= intervals[i][1])))
            return Piecewise(*newargs)

        # Determine what intervals the expr,cond pairs affect.
        int_expr = self._sort_expr_cond(sym, a, b)

        # Finally run through the intervals and sum the evaluation.
        ret_fun = 0
        for int_a, int_b, expr in int_expr:
            ret_fun += expr._eval_interval(sym, Max(a, int_a), Min(b, int_b))
        return mul * ret_fun