Example #1
0
    def _eval_integral(self, f, x, meijerg=None):
        """Calculate the anti-derivative to the function f(x).

        This is a powerful function that should in theory be able to integrate
        everything that can be integrated. If you find something, that it
        doesn't, it is easy to implement it.

        (1) Simple heuristics (based on pattern matching and integral table):

         - most frequently used functions (e.g. polynomials)
         - functions non-integrable by any of the following algorithms (e.g.
           exp(-x**2))

        (2) Integration of rational functions:

         (a) using apart() - apart() is full partial fraction decomposition
         procedure based on Bronstein-Salvy algorithm. It gives formal
         decomposition with no polynomial factorization at all (so it's fast
         and gives the most general results). However it needs much better
         implementation of RootsOf class (if fact any implementation).
         (b) using Trager's algorithm - possibly faster than (a) but needs
         implementation :)

        (3) Whichever implementation of pmInt (Mateusz, Kirill's or a
        combination of both).

          - this way we can handle efficiently huge class of elementary and
            special functions

        (4) Recursive Risch algorithm as described in Bronstein's integration
        tutorial.

          - this way we can handle those integrable functions for which (3)
            fails

        (5) Powerful heuristics based mostly on user defined rules.

         - handle complicated, rarely used cases
        """

        # if it is a poly(x) then let the polynomial integrate itself (fast)
        #
        # It is important to make this check first, otherwise the other code
        # will return a sympy expression instead of a Polynomial.
        #
        # see Polynomial for details.
        if isinstance(f, Poly) and not meijerg:
            return f.integrate(x)

        # Piecewise antiderivatives need to call special integrate.
        if f.func is Piecewise:
            return f._eval_integral(x)

        # let's cut it short if `f` does not depend on `x`
        if not f.has(x):
            return f*x

        # try to convert to poly(x) and then integrate if successful (fast)
        poly = f.as_poly(x)

        if poly is not None and not meijerg:
            return poly.integrate().as_expr()

        # since Integral(f=g1+g2+...) == Integral(g1) + Integral(g2) + ...
        # we are going to handle Add terms separately,
        # if `f` is not Add -- we only have one term
        parts = []
        args = Add.make_args(f)
        for g in args:
            coeff, g = g.as_independent(x)

            # g(x) = const
            if g is S.One and not meijerg:
                parts.append(coeff*x)
                continue

            # g(x) = expr + O(x**n)
            order_term = g.getO()

            if order_term is not None:
                h = self._eval_integral(g.removeO(), x)

                if h is not None:
                    h_order_expr = self._eval_integral(order_term.expr, x)

                    if h_order_expr is not None:
                        h_order_term = order_term.func(h_order_expr, *order_term.variables)
                        parts.append(coeff*(h + h_order_term))
                        continue

                # NOTE: if there is O(x**n) and we fail to integrate then there is
                # no point in trying other methods because they will fail anyway.
                return None

            #               c
            # g(x) = (a*x+b)
            if g.is_Pow and not g.exp.has(x) and not meijerg:
                a = Wild('a', exclude=[x])
                b = Wild('b', exclude=[x])

                M = g.base.match(a*x + b)

                if M is not None:
                    if g.exp == -1:
                        h = C.log(g.base)
                    else:
                        h = g.base**(g.exp + 1) / (g.exp + 1)

                    parts.append(coeff * h / M[a])
                    continue

            #        poly(x)
            # g(x) = -------
            #        poly(x)
            if g.is_rational_function(x) and not meijerg:
                parts.append(coeff * ratint(g, x))
                continue

            if not meijerg:
                # g(x) = Mul(trig)
                h = trigintegrate(g, x)
                if h is not None:
                    parts.append(coeff * h)
                    continue

                # g(x) has at least a DiracDelta term
                h = deltaintegrate(g, x)
                if h is not None:
                    parts.append(coeff * h)
                    continue

            if not meijerg:
                # fall back to the more general algorithm
                try:
                    h = heurisch(g, x, hints=[])
                except PolynomialError:
                    # XXX: this exception means there is a bug in the
                    # implementation of heuristic Risch integration
                    # algorithm.
                    h = None
            else:
                h = None

            if meijerg is not False and h is None:
                # rewrite using G functions
                h = meijerint_indefinite(g, x)
                if h is not None:
                    parts.append(coeff * h)
                    continue

            # if we failed maybe it was because we had
            # a product that could have been expanded,
            # so let's try an expansion of the whole
            # thing before giving up; we don't try this
            # out the outset because there are things
            # that cannot be solved unless they are
            # NOT expanded e.g., x**x*(1+log(x)). There
            # should probably be a checker somewhere in this
            # routine to look for such cases and try to do
            # collection on the expressions if they are already
            # in an expanded form
            if not h and len(args) == 1:
                f = f.expand(mul=True, deep=False)
                if f.is_Add:
                    return self._eval_integral(f, x, meijerg)


            if h is not None:
                parts.append(coeff * h)
            else:
                return None

        return Add(*parts)
def test_deltaintegrate():
    assert deltaintegrate(x, x) is None
    assert deltaintegrate(x + DiracDelta(x), x) is None
    assert deltaintegrate(DiracDelta(x, 0), x) == Heaviside(x)
    for n in range(10):
        assert deltaintegrate(DiracDelta(x, n + 1), x) == DiracDelta(x, n)
    assert deltaintegrate(DiracDelta(x), x) == Heaviside(x)
    assert deltaintegrate(DiracDelta(-x), x) == Heaviside(x)
    assert deltaintegrate(DiracDelta(x - y), x) == Heaviside(x - y)
    assert deltaintegrate(DiracDelta(y - x), x) == Heaviside(x - y)

    assert deltaintegrate(x * DiracDelta(x), x) == 0
    assert deltaintegrate((x - y) * DiracDelta(x - y), x) == 0

    assert deltaintegrate(DiracDelta(x)**2, x) == DiracDelta(0) * Heaviside(x)
    assert deltaintegrate(y*DiracDelta(x)**2, x) == \
        y*DiracDelta(0)*Heaviside(x)
    assert deltaintegrate(DiracDelta(x, 1), x) == DiracDelta(x, 0)
    assert deltaintegrate(y * DiracDelta(x, 1), x) == y * DiracDelta(x, 0)
    assert deltaintegrate(DiracDelta(x, 1)**2,
                          x) == -DiracDelta(0, 2) * Heaviside(x)
    assert deltaintegrate(y * DiracDelta(x, 1)**2,
                          x) == -y * DiracDelta(0, 2) * Heaviside(x)

    assert deltaintegrate(DiracDelta(x) * f(x), x) == f(0) * Heaviside(x)
    assert deltaintegrate(DiracDelta(-x) * f(x), x) == f(0) * Heaviside(x)
    assert deltaintegrate(DiracDelta(x - 1) * f(x),
                          x) == f(1) * Heaviside(x - 1)
    assert deltaintegrate(DiracDelta(1 - x) * f(x),
                          x) == f(1) * Heaviside(x - 1)
    assert deltaintegrate(DiracDelta(x**2 + x - 2), x) == \
        Heaviside(x - 1)/3 + Heaviside(x + 2)/3

    p = cos(x) * (DiracDelta(x) + DiracDelta(x**2 - 1)) * sin(x) * (x - pi)
    assert deltaintegrate(p, x) - (-pi*(cos(1)*Heaviside(-1 + x)*sin(1)/2 - \
        cos(1)*Heaviside(1 + x)*sin(1)/2) + \
        cos(1)*Heaviside(1 + x)*sin(1)/2 + \
        cos(1)*Heaviside(-1 + x)*sin(1)/2) == 0

    p = x_2 * DiracDelta(x - x_2) * DiracDelta(x_2 - x_1)
    assert deltaintegrate(p,
                          x_2) == x * DiracDelta(x - x_1) * Heaviside(x_2 - x)

    p = x * y**2 * z * DiracDelta(y - x) * DiracDelta(y - z) * DiracDelta(x -
                                                                          z)
    assert deltaintegrate(
        p, y) == x**3 * z * DiracDelta(x - z)**2 * Heaviside(y - x)
    assert deltaintegrate((x + 1) * DiracDelta(2 * x),
                          x) == S.Half * Heaviside(x)
    assert deltaintegrate((x + 1)*DiracDelta(x*Rational(2, 3) + Rational(4, 9)), x) == \
        S.Half * Heaviside(x + Rational(2, 3))

    a, b, c = symbols('a b c', commutative=False)
    assert deltaintegrate(DiracDelta(x - y)*f(x - b)*f(x - a), x) == \
        f(y - b)*f(y - a)*Heaviside(x - y)

    p = f(x - a) * DiracDelta(x - y) * f(x - c) * f(x - b)
    assert deltaintegrate(
        p, x) == f(y - a) * f(y - c) * f(y - b) * Heaviside(x - y)

    p = DiracDelta(x - z) * f(x - b) * f(x - a) * DiracDelta(x - y)
    assert deltaintegrate(p, x) == DiracDelta(y - z)*f(y - b)*f(y - a) * \
        Heaviside(x - y)
Example #3
0
    def _eval_integral(self, f, x, meijerg=None, risch=None, manual=None,
                       conds='piecewise'):
        """
        Calculate the anti-derivative to the function f(x).

        The following algorithms are applied (roughly in this order):

        1. Simple heuristics (based on pattern matching and integral table):

           - most frequently used functions (e.g. polynomials, products of trig functions)

        2. Integration of rational functions:

           - A complete algorithm for integrating rational functions is
             implemented (the Lazard-Rioboo-Trager algorithm).  The algorithm
             also uses the partial fraction decomposition algorithm
             implemented in apart() as a preprocessor to make this process
             faster.  Note that the integral of a rational function is always
             elementary, but in general, it may include a RootSum.

        3. Full Risch algorithm:

           - The Risch algorithm is a complete decision
             procedure for integrating elementary functions, which means that
             given any elementary function, it will either compute an
             elementary antiderivative, or else prove that none exists.
             Currently, part of transcendental case is implemented, meaning
             elementary integrals containing exponentials, logarithms, and
             (soon!) trigonometric functions can be computed.  The algebraic
             case, e.g., functions containing roots, is much more difficult
             and is not implemented yet.

           - If the routine fails (because the integrand is not elementary, or
             because a case is not implemented yet), it continues on to the
             next algorithms below.  If the routine proves that the integrals
             is nonelementary, it still moves on to the algorithms below,
             because we might be able to find a closed-form solution in terms
             of special functions.  If risch=True, however, it will stop here.

        4. The Meijer G-Function algorithm:

           - This algorithm works by first rewriting the integrand in terms of
             very general Meijer G-Function (meijerg in SymPy), integrating
             it, and then rewriting the result back, if possible.  This
             algorithm is particularly powerful for definite integrals (which
             is actually part of a different method of Integral), since it can
             compute closed-form solutions of definite integrals even when no
             closed-form indefinite integral exists.  But it also is capable
             of computing many indefinite integrals as well.

           - Another advantage of this method is that it can use some results
             about the Meijer G-Function to give a result in terms of a
             Piecewise expression, which allows to express conditionally
             convergent integrals.

           - Setting meijerg=True will cause integrate() to use only this
             method.

        5. The "manual integration" algorithm:

           - This algorithm tries to mimic how a person would find an
             antiderivative by hand, for example by looking for a
             substitution or applying integration by parts. This algorithm
             does not handle as many integrands but can return results in a
             more familiar form.

           - Sometimes this algorithm can evaluate parts of an integral; in
             this case integrate() will try to evaluate the rest of the
             integrand using the other methods here.

           - Setting manual=True will cause integrate() to use only this
             method.

        6. The Heuristic Risch algorithm:

           - This is a heuristic version of the Risch algorithm, meaning that
             it is not deterministic.  This is tried as a last resort because
             it can be very slow.  It is still used because not enough of the
             full Risch algorithm is implemented, so that there are still some
             integrals that can only be computed using this method.  The goal
             is to implement enough of the Risch and Meijer G methods so that
             this can be deleted.

        """
        from sympy.integrals.risch import risch_integrate

        manual = True # force manual integration
        if risch:
            try:
                return risch_integrate(f, x, conds=conds)
            except NotImplementedError:
                return None

        if manual:
            try:
                result = manualintegrate(f, x)
                if result is not None and result.func != Integral:
                    return result
            except (ValueError, PolynomialError):
                pass


        # if it is a poly(x) then let the polynomial integrate itself (fast)
        #
        # It is important to make this check first, otherwise the other code
        # will return a sympy expression instead of a Polynomial.
        #
        # see Polynomial for details.
        if isinstance(f, Poly) and not meijerg:
            return f.integrate(x)

        # Piecewise antiderivatives need to call special integrate.
        if f.func is Piecewise:
            return f._eval_integral(x)

        # let's cut it short if `f` does not depend on `x`
        if not f.has(x):
            return f*x

        # try to convert to poly(x) and then integrate if successful (fast)
        poly = f.as_poly(x)

        if poly is not None and not meijerg:
            add_comment("The function is a polinomial therefore the antiderivative is")
            ad = poly.integrate().as_expr()
            add_exp(ad)
            return ad

        if risch is not False:
            try:
                result, i = risch_integrate(f, x, separate_integral=True, conds=conds)
            except NotImplementedError:
                pass
            else:
                if i:
                    # There was a nonelementary integral. Try integrating it.
                    return result + i.doit(risch=False)
                else:
                    return result

        # since Integral(f=g1+g2+...) == Integral(g1) + Integral(g2) + ...
        # we are going to handle Add terms separately,
        # if `f` is not Add -- we only have one term

        # Note that in general, this is a bad idea, because Integral(g1) +
        # Integral(g2) might not be computable, even if Integral(g1 + g2) is.
        # For example, Integral(x**x + x**x*log(x)).  But many heuristics only
        # work term-wise.  So we compute this step last, after trying
        # risch_integrate.  We also try risch_integrate again in this loop,
        # because maybe the integral is a sum of an elementary part and a
        # nonelementary part (like erf(x) + exp(x)).  risch_integrate() is
        # quite fast, so this is acceptable.
        parts = []
        args = Add.make_args(f)
        for g in args:
            coeff, g = g.as_independent(x)

            # g(x) = const
            if g is S.One and not meijerg:
                parts.append(coeff*x)
                continue

            # g(x) = expr + O(x**n)
            order_term = g.getO()

            if order_term is not None:
                h = self._eval_integral(g.removeO(), x)

                if h is not None:
                    h_order_expr = self._eval_integral(order_term.expr, x)

                    if h_order_expr is not None:
                        h_order_term = order_term.func(
                            h_order_expr, *order_term.variables)
                        parts.append(coeff*(h + h_order_term))
                        continue

                # NOTE: if there is O(x**n) and we fail to integrate then there is
                # no point in trying other methods because they will fail anyway.
                return None

            #               c
            # g(x) = (a*x+b)
            if g.is_Pow and not g.exp.has(x) and not meijerg:
                a = Wild('a', exclude=[x])
                b = Wild('b', exclude=[x])

                M = g.base.match(a*x + b)

                if M is not None:
                    if g.exp == -1:
                        h = C.log(g.base)
                    elif conds != 'piecewise':
                        h = g.base**(g.exp + 1) / (g.exp + 1)
                    else:
                        h1 = C.log(g.base)
                        h2 = g.base**(g.exp + 1) / (g.exp + 1)
                        h = Piecewise((h1, Eq(g.exp, -1)), (h2, True))

                    parts.append(coeff * h / M[a])
                    continue

            #        poly(x)
            # g(x) = -------
            #        poly(x)
            if g.is_rational_function(x) and not meijerg:
                parts.append(coeff * ratint(g, x))
                continue

            if not meijerg:
                # g(x) = Mul(trig)
                h = trigintegrate(g, x, conds=conds)
                if h is not None:
                    parts.append(coeff * h)
                    continue

                # g(x) has at least a DiracDelta term
                h = deltaintegrate(g, x)
                if h is not None:
                    parts.append(coeff * h)
                    continue

                # Try risch again.
                if risch is not False:
                    try:
                        h, i = risch_integrate(g, x, separate_integral=True, conds=conds)
                    except NotImplementedError:
                        h = None
                    else:
                        if i:
                            h = h + i.doit(risch=False)

                        parts.append(coeff*h)
                        continue

                # fall back to heurisch
                try:
                    if conds == 'piecewise':
                        h = heurisch_wrapper(g, x, hints=[])
                    else:
                        h = heurisch(g, x, hints=[])
                except PolynomialError:
                    # XXX: this exception means there is a bug in the
                    # implementation of heuristic Risch integration
                    # algorithm.
                    h = None
            else:
                h = None

            if meijerg is not False and h is None:
                # rewrite using G functions
                try:
                    h = meijerint_indefinite(g, x)
                except NotImplementedError:
                    from sympy.integrals.meijerint import _debug
                    _debug('NotImplementedError from meijerint_definite')
                    res = None
                if h is not None:
                    parts.append(coeff * h)
                    continue

            if h is None and manual is not False:
                try:
                    result = manualintegrate(g, x)
                    if result is not None and not isinstance(result, Integral):
                        if result.has(Integral):
                            # try to have other algorithms do the integrals
                            # manualintegrate can't handle
                            result = result.func(*[
                                arg.doit(manual=False) if arg.has(Integral) else arg
                                for arg in result.args
                            ]).expand(multinomial=False,
                                      log=False,
                                      power_exp=False,
                                      power_base=False)
                        if not result.has(Integral):
                            parts.append(coeff * result)
                            continue
                except (ValueError, PolynomialError):
                    # can't handle some SymPy expressions
                    pass

            # if we failed maybe it was because we had
            # a product that could have been expanded,
            # so let's try an expansion of the whole
            # thing before giving up; we don't try this
            # out the outset because there are things
            # that cannot be solved unless they are
            # NOT expanded e.g., x**x*(1+log(x)). There
            # should probably be a checker somewhere in this
            # routine to look for such cases and try to do
            # collection on the expressions if they are already
            # in an expanded form
            if not h and len(args) == 1:
                f = f.expand(mul=True, deep=False)
                if f.is_Add:
                    # Note: risch will be identical on the expanded
                    # expression, but maybe it will be able to pick out parts,
                    # like x*(exp(x) + erf(x)).
                    return self._eval_integral(f, x, meijerg=meijerg, risch=risch, conds=conds)

            if h is not None:
                parts.append(coeff * h)
            else:
                return None

        return Add(*parts)
Example #4
0
    def _eval_integral(self, f, x):
        """Calculate the anti-derivative to the function f(x).

        This is a powerful function that should in theory be able to integrate
        everything that can be integrated. If you find something, that it
        doesn't, it is easy to implement it.

        (1) Simple heuristics (based on pattern matching and integral table):

         - most frequently used functions (e.g. polynomials)
         - functions non-integrable by any of the following algorithms (e.g.
           exp(-x**2))

        (2) Integration of rational functions:

         (a) using apart() - apart() is full partial fraction decomposition
         procedure based on Bronstein-Salvy algorithm. It gives formal
         decomposition with no polynomial factorization at all (so it's fast
         and gives the most general results). However it needs much better
         implementation of RootsOf class (if fact any implementation).
         (b) using Trager's algorithm - possibly faster than (a) but needs
         implementation :)

        (3) Whichever implementation of pmInt (Mateusz, Kirill's or a
        combination of both).

          - this way we can handle efficiently huge class of elementary and
            special functions

        (4) Recursive Risch algorithm as described in Bronstein's integration
        tutorial.

          - this way we can handle those integrable functions for which (3)
            fails

        (5) Powerful heuristics based mostly on user defined rules.

         - handle complicated, rarely used cases
        """

        # if it is a poly(x) then let the polynomial integrate itself (fast)
        #
        # It is important to make this check first, otherwise the other code
        # will return a sympy expression instead of a Polynomial.
        #
        # see Polynomial for details.
        if isinstance(f, Poly):
            return f.integrate(x)

        # Piecewise antiderivatives need to call special integrate.
        if f.func is Piecewise:
            return f._eval_integral(x)

        # let's cut it short if `f` does not depend on `x`
        if not f.has(x):
            return f*x

        # try to convert to poly(x) and then integrate if successful (fast)
        poly = f.as_poly(x)

        if poly is not None:
            return poly.integrate().as_basic()

        # since Integral(f=g1+g2+...) == Integral(g1) + Integral(g2) + ...
        # we are going to handle Add terms separately,
        # if `f` is not Add -- we only have one term
        parts = []
        args = Add.make_args(f)
        for g in args:
            coeff, g = g.as_independent(x)

            # g(x) = const
            if g is S.One:
                parts.append(coeff*x)
                continue

            #               c
            # g(x) = (a*x+b)
            if g.is_Pow and not g.exp.has(x):
                a = Wild('a', exclude=[x])
                b = Wild('b', exclude=[x])

                M = g.base.match(a*x + b)

                if M is not None:
                    if g.exp == -1:
                        h = C.log(g.base)
                    else:
                        h = g.base**(g.exp + 1) / (g.exp + 1)

                    parts.append(coeff * h / M[a])
                    continue

            #        poly(x)
            # g(x) = -------
            #        poly(x)
            if g.is_rational_function(x):
                parts.append(coeff * ratint(g, x))
                continue

            # g(x) = Mul(trig)
            h = trigintegrate(g, x)
            if h is not None:
                parts.append(coeff * h)
                continue

            # g(x) has at least a DiracDelta term
            h = deltaintegrate(g, x)
            if h is not None:
                parts.append(coeff * h)
                continue

            # fall back to the more general algorithm
            h = heurisch(g, x, hints=[])

            # if we failed maybe it was because we had
            # a product that could have been expanded,
            # so let's try an expansion of the whole
            # thing before giving up; we don't try this
            # out the outset because there are things
            # that cannot be solved unless they are
            # NOT expanded e.g., x**x*(1+log(x)). There
            # should probably be a checker somewhere in this
            # routine to look for such cases and try to do
            # collection on the expressions if they are already
            # in an expanded form
            if not h and len(args) == 1:
                f = f.expand(mul=True, deep=False)
                if f.is_Add:
                    return self._eval_integral(f, x)


            if h is not None:
                parts.append(coeff * h)
            else:
                return None

        return Add(*parts)
Example #5
0
def test_J17():
    assert deltaintegrate(f((x + 2)/5)*DiracDelta((x - 2)/3) - g(x)*diff(DiracDelta(x - 1), x), (x, 0, 3))
Example #6
0
    def _eval_integral(self,
                       f,
                       x,
                       meijerg=None,
                       risch=None,
                       manual=None,
                       conds='piecewise'):
        """
        Calculate the anti-derivative to the function f(x).

        The following algorithms are applied (roughly in this order):

        1. Simple heuristics (based on pattern matching and integral table):

           - most frequently used functions (e.g. polynomials, products of trig functions)

        2. Integration of rational functions:

           - A complete algorithm for integrating rational functions is
             implemented (the Lazard-Rioboo-Trager algorithm).  The algorithm
             also uses the partial fraction decomposition algorithm
             implemented in apart() as a preprocessor to make this process
             faster.  Note that the integral of a rational function is always
             elementary, but in general, it may include a RootSum.

        3. Full Risch algorithm:

           - The Risch algorithm is a complete decision
             procedure for integrating elementary functions, which means that
             given any elementary function, it will either compute an
             elementary antiderivative, or else prove that none exists.
             Currently, part of transcendental case is implemented, meaning
             elementary integrals containing exponentials, logarithms, and
             (soon!) trigonometric functions can be computed.  The algebraic
             case, e.g., functions containing roots, is much more difficult
             and is not implemented yet.

           - If the routine fails (because the integrand is not elementary, or
             because a case is not implemented yet), it continues on to the
             next algorithms below.  If the routine proves that the integrals
             is nonelementary, it still moves on to the algorithms below,
             because we might be able to find a closed-form solution in terms
             of special functions.  If risch=True, however, it will stop here.

        4. The Meijer G-Function algorithm:

           - This algorithm works by first rewriting the integrand in terms of
             very general Meijer G-Function (meijerg in SymPy), integrating
             it, and then rewriting the result back, if possible.  This
             algorithm is particularly powerful for definite integrals (which
             is actually part of a different method of Integral), since it can
             compute closed-form solutions of definite integrals even when no
             closed-form indefinite integral exists.  But it also is capable
             of computing many indefinite integrals as well.

           - Another advantage of this method is that it can use some results
             about the Meijer G-Function to give a result in terms of a
             Piecewise expression, which allows to express conditionally
             convergent integrals.

           - Setting meijerg=True will cause integrate() to use only this
             method.

        5. The "manual integration" algorithm:

           - This algorithm tries to mimic how a person would find an
             antiderivative by hand, for example by looking for a
             substitution or applying integration by parts. This algorithm
             does not handle as many integrands but can return results in a
             more familiar form.

           - Sometimes this algorithm can evaluate parts of an integral; in
             this case integrate() will try to evaluate the rest of the
             integrand using the other methods here.

           - Setting manual=True will cause integrate() to use only this
             method.

        6. The Heuristic Risch algorithm:

           - This is a heuristic version of the Risch algorithm, meaning that
             it is not deterministic.  This is tried as a last resort because
             it can be very slow.  It is still used because not enough of the
             full Risch algorithm is implemented, so that there are still some
             integrals that can only be computed using this method.  The goal
             is to implement enough of the Risch and Meijer G methods so that
             this can be deleted.

        """
        from sympy.integrals.risch import risch_integrate

        if risch:
            try:
                return risch_integrate(f, x, conds=conds)
            except NotImplementedError:
                return None

        if manual:
            try:
                result = manualintegrate(f, x)
                if result is not None and result.func != Integral:
                    return result
            except (ValueError, PolynomialError):
                pass

        # if it is a poly(x) then let the polynomial integrate itself (fast)
        #
        # It is important to make this check first, otherwise the other code
        # will return a sympy expression instead of a Polynomial.
        #
        # see Polynomial for details.
        if isinstance(f, Poly) and not meijerg:
            return f.integrate(x)

        # Piecewise antiderivatives need to call special integrate.
        if f.func is Piecewise:
            return f._eval_integral(x)

        # let's cut it short if `f` does not depend on `x`
        if not f.has(x):
            return f * x

        # try to convert to poly(x) and then integrate if successful (fast)
        poly = f.as_poly(x)

        if poly is not None and not meijerg:
            return poly.integrate().as_expr()

        if risch is not False:
            try:
                result, i = risch_integrate(f,
                                            x,
                                            separate_integral=True,
                                            conds=conds)
            except NotImplementedError:
                pass
            else:
                if i:
                    # There was a nonelementary integral. Try integrating it.
                    return result + i.doit(risch=False)
                else:
                    return result

        # since Integral(f=g1+g2+...) == Integral(g1) + Integral(g2) + ...
        # we are going to handle Add terms separately,
        # if `f` is not Add -- we only have one term

        # Note that in general, this is a bad idea, because Integral(g1) +
        # Integral(g2) might not be computable, even if Integral(g1 + g2) is.
        # For example, Integral(x**x + x**x*log(x)).  But many heuristics only
        # work term-wise.  So we compute this step last, after trying
        # risch_integrate.  We also try risch_integrate again in this loop,
        # because maybe the integral is a sum of an elementary part and a
        # nonelementary part (like erf(x) + exp(x)).  risch_integrate() is
        # quite fast, so this is acceptable.
        parts = []
        args = Add.make_args(f)
        for g in args:
            coeff, g = g.as_independent(x)

            # g(x) = const
            if g is S.One and not meijerg:
                parts.append(coeff * x)
                continue

            # g(x) = expr + O(x**n)
            order_term = g.getO()

            if order_term is not None:
                h = self._eval_integral(g.removeO(), x)

                if h is not None:
                    h_order_expr = self._eval_integral(order_term.expr, x)

                    if h_order_expr is not None:
                        h_order_term = order_term.func(h_order_expr,
                                                       *order_term.variables)
                        parts.append(coeff * (h + h_order_term))
                        continue

                # NOTE: if there is O(x**n) and we fail to integrate then there is
                # no point in trying other methods because they will fail anyway.
                return None

            #               c
            # g(x) = (a*x+b)
            if g.is_Pow and not g.exp.has(x) and not meijerg:
                a = Wild('a', exclude=[x])
                b = Wild('b', exclude=[x])

                M = g.base.match(a * x + b)

                if M is not None:
                    if g.exp == -1:
                        h = C.log(g.base)
                    elif conds != 'piecewise':
                        h = g.base**(g.exp + 1) / (g.exp + 1)
                    else:
                        h1 = C.log(g.base)
                        h2 = g.base**(g.exp + 1) / (g.exp + 1)
                        h = Piecewise((h1, Eq(g.exp, -1)), (h2, True))

                    parts.append(coeff * h / M[a])
                    continue

            #        poly(x)
            # g(x) = -------
            #        poly(x)
            if g.is_rational_function(x) and not meijerg:
                parts.append(coeff * ratint(g, x))
                continue

            if not meijerg:
                # g(x) = Mul(trig)
                h = trigintegrate(g, x, conds=conds)
                if h is not None:
                    parts.append(coeff * h)
                    continue

                # g(x) has at least a DiracDelta term
                h = deltaintegrate(g, x)
                if h is not None:
                    parts.append(coeff * h)
                    continue

                # Try risch again.
                if risch is not False:
                    try:
                        h, i = risch_integrate(g,
                                               x,
                                               separate_integral=True,
                                               conds=conds)
                    except NotImplementedError:
                        h = None
                    else:
                        if i:
                            h = h + i.doit(risch=False)

                        parts.append(coeff * h)
                        continue

                # fall back to heurisch
                try:
                    if conds == 'piecewise':
                        h = heurisch_wrapper(g, x, hints=[])
                    else:
                        h = heurisch(g, x, hints=[])
                except PolynomialError:
                    # XXX: this exception means there is a bug in the
                    # implementation of heuristic Risch integration
                    # algorithm.
                    h = None
            else:
                h = None

            if meijerg is not False and h is None:
                # rewrite using G functions
                try:
                    h = meijerint_indefinite(g, x)
                except NotImplementedError:
                    from sympy.integrals.meijerint import _debug
                    _debug('NotImplementedError from meijerint_definite')
                    res = None
                if h is not None:
                    parts.append(coeff * h)
                    continue

            if h is None and manual is not False:
                try:
                    result = manualintegrate(g, x)
                    if result is not None and not isinstance(result, Integral):
                        if result.has(Integral):
                            # try to have other algorithms do the integrals
                            # manualintegrate can't handle
                            result = result.func(*[
                                arg.doit(
                                    manual=False) if arg.has(Integral) else arg
                                for arg in result.args
                            ]).expand(multinomial=False,
                                      log=False,
                                      power_exp=False,
                                      power_base=False)
                        if not result.has(Integral):
                            parts.append(coeff * result)
                            continue
                except (ValueError, PolynomialError):
                    # can't handle some SymPy expressions
                    pass

            # if we failed maybe it was because we had
            # a product that could have been expanded,
            # so let's try an expansion of the whole
            # thing before giving up; we don't try this
            # at the outset because there are things
            # that cannot be solved unless they are
            # NOT expanded e.g., x**x*(1+log(x)). There
            # should probably be a checker somewhere in this
            # routine to look for such cases and try to do
            # collection on the expressions if they are already
            # in an expanded form
            if not h and len(args) == 1:
                f = f.expand(mul=True, deep=False)
                if f.is_Add:
                    # Note: risch will be identical on the expanded
                    # expression, but maybe it will be able to pick out parts,
                    # like x*(exp(x) + erf(x)).
                    return self._eval_integral(f,
                                               x,
                                               meijerg=meijerg,
                                               risch=risch,
                                               conds=conds)

            if h is not None:
                parts.append(coeff * h)
            else:
                return None

        return Add(*parts)
Example #7
0
def test_J17():
    assert deltaintegrate(
        f((x + 2) / 5) * DiracDelta(
            (x - 2) / 3) - g(x) * diff(DiracDelta(x - 1), x), (x, 0, 3))
Example #8
0
    def _eval_integral(self, f, x):
        """Calculate the anti-derivative to the function f(x).

        This is a powerful function that should in theory be able to integrate
        everything that can be integrated. If you find something, that it
        doesn't, it is easy to implement it.

        (1) Simple heuristics (based on pattern matching and integral table):

         - most frequently used functions (e.g. polynomials)
         - functions non-integrable by any of the following algorithms (e.g.
           exp(-x**2))

        (2) Integration of rational functions:

         (a) using apart() - apart() is full partial fraction decomposition
         procedure based on Bronstein-Salvy algorithm. It gives formal
         decomposition with no polynomial factorization at all (so it's fast
         and gives the most general results). However it needs much better
         implementation of RootsOf class (if fact any implementation).
         (b) using Trager's algorithm - possibly faster than (a) but needs
         implementation :)

        (3) Whichever implementation of pmInt (Mateusz, Kirill's or a
        combination of both).

          - this way we can handle efficiently huge class of elementary and
            special functions

        (4) Recursive Risch algorithm as described in Bronstein's integration
        tutorial.

          - this way we can handle those integrable functions for which (3)
            fails

        (5) Powerful heuristics based mostly on user defined rules.

         - handle complicated, rarely used cases
        """

        # if it is a poly(x) then let the polynomial integrate itself (fast)
        #
        # It is important to make this check first, otherwise the other code
        # will return a sympy expression instead of a Polynomial.
        #
        # see Polynomial for details.
        if isinstance(f, Poly):
            return f.integrate(x)

        # Piecewise antiderivatives need to call special integrate.
        if f.func is Piecewise:
            return f._eval_integral(x)

        # let's cut it short if `f` does not depend on `x`
        if not f.has(x):
            return f*x

        # try to convert to poly(x) and then integrate if successful (fast)
        poly = f.as_poly(x)

        if poly is not None:
            return poly.integrate(x).as_basic()

        # since Integral(f=g1+g2+...) == Integral(g1) + Integral(g2) + ...
        # we are going to handle Add terms separately,
        # if `f` is not Add -- we only have one term
        parts = []
        for g in make_list(f, Add):
            coeff, g = g.as_independent(x)

            # g(x) = const
            if g is S.One:
                parts.append(coeff * x)
                continue

            #               c
            # g(x) = (a*x+b)
            if g.is_Pow and not g.exp.has(x):
                a = Wild('a', exclude=[x])
                b = Wild('b', exclude=[x])

                M = g.base.match(a*x + b)

                if M is not None:
                    if g.exp == -1:
                        h = C.log(g.base)
                    else:
                        h = g.base**(g.exp+1) / (g.exp+1)

                    parts.append(coeff * h / M[a])
                    continue

            #        poly(x)
            # g(x) = -------
            #        poly(x)
            if g.is_rational_function(x):
                parts.append(coeff * ratint(g, x))
                continue

            # g(x) = Mul(trig)
            h = trigintegrate(g, x)
            if h is not None:
                parts.append(coeff * h)
                continue

            # g(x) has at least a DiracDelta term
            h = deltaintegrate(g,x)
            if h is not None:
                parts.append(coeff * h)
                continue

            # fall back to the more general algorithm
            h = heurisch(g, x, hints=[])

            if h is not None:
                parts.append(coeff * h)
            else:
                return None

        return C.Add(*parts)
def test_deltaintegrate():
    assert deltaintegrate(x, x) is None
    assert deltaintegrate(x + DiracDelta(x), x) is None
    assert deltaintegrate(DiracDelta(x, 0), x) == Heaviside(x)
    for n in range(10):
        assert deltaintegrate(DiracDelta(x, n + 1), x) == DiracDelta(x, n)
    assert deltaintegrate(DiracDelta(x), x) == Heaviside(x)
    assert deltaintegrate(DiracDelta(-x), x) == Heaviside(x)
    assert deltaintegrate(DiracDelta(x - y), x) == Heaviside(x - y)
    assert deltaintegrate(DiracDelta(y - x), x) == Heaviside(x - y)

    assert deltaintegrate(x*DiracDelta(x), x) == 0
    assert deltaintegrate((x - y)*DiracDelta(x - y), x) == 0

    assert deltaintegrate(DiracDelta(x)**2, x) == DiracDelta(0)*Heaviside(x)
    assert deltaintegrate(y*DiracDelta(x)**2, x) == \
        y*DiracDelta(0)*Heaviside(x)
    assert deltaintegrate(DiracDelta(x, 1), x) == DiracDelta(x, 0)
    assert deltaintegrate(y*DiracDelta(x, 1), x) == y*DiracDelta(x, 0)
    assert deltaintegrate(DiracDelta(x, 1)**2, x) == -DiracDelta(0, 2)*Heaviside(x)
    assert deltaintegrate(y*DiracDelta(x, 1)**2, x) == -y*DiracDelta(0, 2)*Heaviside(x)


    assert deltaintegrate(DiracDelta(x) * f(x), x) == f(0) * Heaviside(x)
    assert deltaintegrate(DiracDelta(-x) * f(x), x) == f(0) * Heaviside(x)
    assert deltaintegrate(DiracDelta(x - 1) * f(x), x) == f(1) * Heaviside(x - 1)
    assert deltaintegrate(DiracDelta(1 - x) * f(x), x) == f(1) * Heaviside(x - 1)
    assert deltaintegrate(DiracDelta(x**2 + x - 2), x) == \
        Heaviside(x - 1)/3 + Heaviside(x + 2)/3

    p = cos(x)*(DiracDelta(x) + DiracDelta(x**2 - 1))*sin(x)*(x - pi)
    assert deltaintegrate(p, x) - (-pi*(cos(1)*Heaviside(-1 + x)*sin(1)/2 - \
        cos(1)*Heaviside(1 + x)*sin(1)/2) + \
        cos(1)*Heaviside(1 + x)*sin(1)/2 + \
        cos(1)*Heaviside(-1 + x)*sin(1)/2) == 0

    p = x_2*DiracDelta(x - x_2)*DiracDelta(x_2 - x_1)
    assert deltaintegrate(p, x_2) == x*DiracDelta(x - x_1)*Heaviside(x_2 - x)

    p = x*y**2*z*DiracDelta(y - x)*DiracDelta(y - z)*DiracDelta(x - z)
    assert deltaintegrate(p, y) == x**3*z*DiracDelta(x - z)**2*Heaviside(y - x)
    assert deltaintegrate((x + 1)*DiracDelta(2*x), x) == S(1)/2 * Heaviside(x)
    assert deltaintegrate((x + 1)*DiracDelta(2*x/3 + 4/S(9)), x) == \
        S(1)/2 * Heaviside(x + S(2)/3)

    a, b, c = symbols('a b c', commutative=False)
    assert deltaintegrate(DiracDelta(x - y)*f(x - b)*f(x - a), x) == \
        f(y - b)*f(y - a)*Heaviside(x - y)

    p = f(x - a)*DiracDelta(x - y)*f(x - c)*f(x - b)
    assert deltaintegrate(p, x) == f(y - a)*f(y - c)*f(y - b)*Heaviside(x - y)

    p = DiracDelta(x - z)*f(x - b)*f(x - a)*DiracDelta(x - y)
    assert deltaintegrate(p, x) == DiracDelta(y - z)*f(y - b)*f(y - a) * \
        Heaviside(x - y)