Beispiel #1
0
def leastsqbound(func, x0, args=(), bounds=None, Dfun=None, full_output=0,
            col_deriv=0, ftol=1.49012e-8, xtol=1.49012e-8,
            gtol=0.0, maxfev=0, epsfcn=0.0, factor=100, diag=None):
    """
    Bounded minimization of the sum of squares of a set of equations.

    ::

        x = arg min(sum(func(y)**2,axis=0))
                 y

    Parameters
    ----------
    func : callable
        should take at least one (possibly length N vector) argument and
        returns M floating point numbers.
    x0 : ndarray
        The starting estimate for the minimization.
    args : tuple
        Any extra arguments to func are placed in this tuple.
    bounds : list
        ``(min, max)`` pairs for each element in ``x``, defining
        the bounds on that parameter. Use None for one of ``min`` or
        ``max`` when there is no bound in that direction.
    Dfun : callable
        A function or method to compute the Jacobian of func with derivatives
        across the rows. If this is None, the Jacobian will be estimated.
    full_output : bool
        non-zero to return all optional outputs.
    col_deriv : bool
        non-zero to specify that the Jacobian function computes derivatives
        down the columns (faster, because there is no transpose operation).
    ftol : float
        Relative error desired in the sum of squares.
    xtol : float
        Relative error desired in the approximate solution.
    gtol : float
        Orthogonality desired between the function vector and the columns of
        the Jacobian.
    maxfev : int
        The maximum number of calls to the function. If zero, then 100*(N+1) is
        the maximum where N is the number of elements in x0.
    epsfcn : float
        A suitable step length for the forward-difference approximation of the
        Jacobian (for Dfun=None). If epsfcn is less than the machine precision,
        it is assumed that the relative errors in the functions are of the
        order of the machine precision.
    factor : float
        A parameter determining the initial step bound
        (``factor * || diag * x||``). Should be in interval ``(0.1, 100)``.
    diag : sequence
        N positive entries that serve as a scale factors for the variables.

    Returns
    -------
    x : ndarray
        The solution (or the result of the last iteration for an unsuccessful
        call).
    cov_x : ndarray
        Uses the fjac and ipvt optional outputs to construct an
        estimate of the jacobian around the solution.  ``None`` if a
        singular matrix encountered (indicates very flat curvature in
        some direction).  This matrix must be multiplied by the
        residual standard deviation to get the covariance of the
        parameter estimates -- see curve_fit.
    infodict : dict
        a dictionary of optional outputs with the key s::

            - 'nfev' : the number of function calls
            - 'fvec' : the function evaluated at the output
            - 'fjac' : A permutation of the R matrix of a QR
                     factorization of the final approximate
                     Jacobian matrix, stored column wise.
                     Together with ipvt, the covariance of the
                     estimate can be approximated.
            - 'ipvt' : an integer array of length N which defines
                     a permutation matrix, p, such that
                     fjac*p = q*r, where r is upper triangular
                     with diagonal elements of nonincreasing
                     magnitude. Column j of p is column ipvt(j)
                     of the identity matrix.
            - 'qtf'  : the vector (transpose(q) * fvec).

    mesg : str
        A string message giving information about the cause of failure.
    ier : int
        An integer flag.  If it is equal to 1, 2, 3 or 4, the solution was
        found.  Otherwise, the solution was not found. In either case, the
        optional output variable 'mesg' gives more information.

    Notes
    -----
    "leastsq" is a wrapper around MINPACK's lmdif and lmder algorithms.

    cov_x is a Jacobian approximation to the Hessian of the least squares
    objective function.
    This approximation assumes that the objective function is based on the
    difference between some observed target data (ydata) and a (non-linear)
    function of the parameters `f(xdata, params)` ::

           func(params) = ydata - f(xdata, params)

    so that the objective function is ::

           min   sum((ydata - f(xdata, params))**2, axis=0)
         params

    Contraints on the parameters are enforced using an internal parameter list 
    with appropiate transformations such that these internal parameters can be
    optimized without constraints. The transfomation between a given internal 
    parameter, p_i, and a external parameter, p_e, are as follows:

    With ``min`` and ``max`` bounds defined ::

        p_i = arcsin((2 * (p_e - min) / (max - min)) - 1.)
        p_e = min + ((max - min) / 2.) * (sin(p_i) + 1.)

    With only ``max`` defined ::

        p_i = sqrt((p_e - max + 1.)**2 - 1.)
        p_e = max + 1. - sqrt(p_i**2 + 1.)

    With only ``min`` defined ::

        p_i = sqrt((p_e - min + 1.)**2 - 1.)
        p_e = min - 1. + sqrt(p_i**2 + 1.)

    These transfomations are used in the MINUIT package, and described in 
    detail in the section 1.3.1 of the MINUIT User's Guide.

    To Do
    -----
    Currently the ``factor`` and ``diag`` parameters scale the 
    internal parameter list, but should scale the external parameter list.

    The `qtf` vector in the infodic dictionary reflects internal parameter 
    list, it should be correct to reflect the external parameter list.

    References
    ----------
    * F. James and M. Winkler. MINUIT User's Guide, July 16, 2004.

    """
    # use leastsq if no bounds are present
    if bounds is None:
        return leastsq(func, x0, args, Dfun, full_output, col_deriv, 
                        ftol, xtol, gtol, maxfev, epsfcn, factor, diag)
    
    # create function which convert between internal and external parameters
    i2e = _internal2external_func(bounds)
    e2i = _external2internal_func(bounds)

    x0 = array(x0, ndmin=1)
    i0 = e2i(x0)
    n = len(x0)
    if len(bounds) != n:
        raise ValueError('length of x0 != length of bounds')
    if type(args) != type(()):
        args = (args,)
    m = _check_func('leastsq', 'func', func, x0, args, n)[0]
    if n > m:
        raise TypeError('Improper input: N=%s must not exceed M=%s' % (n,m))
    
    # define a wrapped func which accept internal parameters, converts them
    # to external parameters and calls func
    def wfunc(x, *args): return func(i2e(x), *args)
    
    if Dfun is None:
        if (maxfev == 0):
            maxfev = 200*(n + 1)
        retval = _minpack._lmdif(wfunc, i0, args, full_output, ftol, xtol,
                gtol, maxfev, epsfcn, factor, diag)
    else:
        if col_deriv:
            _check_func('leastsq', 'Dfun', Dfun, x0, args, n, (n,m))
        else:
            _check_func('leastsq', 'Dfun', Dfun, x0, args, n, (m,n))
        if (maxfev == 0):
            maxfev = 100*(n + 1)
        def wDfun(x, *args): return Dfun(i2e(x), *args) # wrapped Dfun
        retval = _minpack._lmder(func, wDfun, i0, args, full_output, 
                col_deriv, ftol, xtol, gtol, maxfev, factor, diag)

    errors = {0:["Improper input parameters.", TypeError],
              1:["Both actual and predicted relative reductions "
                 "in the sum of squares\n  are at most %f" % ftol, None],
              2:["The relative error between two consecutive "
                 "iterates is at most %f" % xtol, None],
              3:["Both actual and predicted relative reductions in "
                 "the sum of squares\n  are at most %f and the "
                 "relative error between two consecutive "
                 "iterates is at \n  most %f" % (ftol,xtol), None],
              4:["The cosine of the angle between func(x) and any "
                 "column of the\n  Jacobian is at most %f in "
                 "absolute value" % gtol, None],
              5:["Number of calls to function has reached "
                 "maxfev = %d." % maxfev, ValueError],
              6:["ftol=%f is too small, no further reduction "
                 "in the sum of squares\n  is possible.""" % ftol, ValueError],
              7:["xtol=%f is too small, no further improvement in "
                 "the approximate\n  solution is possible." % xtol, ValueError],
              8:["gtol=%f is too small, func(x) is orthogonal to the "
                 "columns of\n  the Jacobian to machine "
                 "precision." % gtol, ValueError],
              'unknown':["Unknown error.", TypeError]}

    info = retval[-1]    # The FORTRAN return value

    if (info not in [1,2,3,4] and not full_output):
        if info in [5,6,7,8]:
            warnings.warn(errors[info][0], RuntimeWarning)
        else:
            try:
                raise errors[info][1](errors[info][0])
            except KeyError:
                raise errors['unknown'][1](errors['unknown'][0])

    mesg = errors[info][0]
    x = i2e(retval[0])  # internal params to external params
    
    if full_output:
        # convert fjac from internal params to external
        grad = _internal2external_grad(retval[0], bounds)
        retval[1]['fjac'] = (retval[1]['fjac'].T / take(grad, 
                            retval[1]['ipvt'] - 1)).T
        cov_x = None
        if info in [1,2,3,4]:
            from numpy.dual import inv
            from numpy.linalg import LinAlgError
            perm = take(eye(n),retval[1]['ipvt']-1,0)
            r = triu(transpose(retval[1]['fjac'])[:n,:])
            R = dot(r, perm)
            try:
                cov_x = inv(dot(transpose(R),R))
            except LinAlgError:
                pass
        return (x, cov_x) + retval[1:-1] + (mesg, info)
    else:
        return (x, info)
Beispiel #2
0
def leastsqbound(func,
                 x0,
                 args=(),
                 bounds=None,
                 Dfun=None,
                 full_output=0,
                 col_deriv=0,
                 ftol=1.49012e-8,
                 xtol=1.49012e-8,
                 gtol=0.0,
                 maxfev=0,
                 epsfcn=0.0,
                 factor=100,
                 diag=None):
    """
    Bounded minimization of the sum of squares of a set of equations.

    ::

        x = arg min(sum(func(y)**2,axis=0))
                 y

    Parameters
    ----------
    func : callable
        should take at least one (possibly length N vector) argument and
        returns M floating point numbers.
    x0 : ndarray
        The starting estimate for the minimization.
    args : tuple
        Any extra arguments to func are placed in this tuple.
    bounds : list
        ``(min, max)`` pairs for each element in ``x``, defining
        the bounds on that parameter. Use None for one of ``min`` or
        ``max`` when there is no bound in that direction.
    Dfun : callable
        A function or method to compute the Jacobian of func with derivatives
        across the rows. If this is None, the Jacobian will be estimated.
    full_output : bool
        non-zero to return all optional outputs.
    col_deriv : bool
        non-zero to specify that the Jacobian function computes derivatives
        down the columns (faster, because there is no transpose operation).
    ftol : float
        Relative error desired in the sum of squares.
    xtol : float
        Relative error desired in the approximate solution.
    gtol : float
        Orthogonality desired between the function vector and the columns of
        the Jacobian.
    maxfev : int
        The maximum number of calls to the function. If zero, then 100*(N+1) is
        the maximum where N is the number of elements in x0.
    epsfcn : float
        A suitable step length for the forward-difference approximation of the
        Jacobian (for Dfun=None). If epsfcn is less than the machine precision,
        it is assumed that the relative errors in the functions are of the
        order of the machine precision.
    factor : float
        A parameter determining the initial step bound
        (``factor * || diag * x||``). Should be in interval ``(0.1, 100)``.
    diag : sequence
        N positive entries that serve as a scale factors for the variables.

    Returns
    -------
    x : ndarray
        The solution (or the result of the last iteration for an unsuccessful
        call).
    cov_x : ndarray
        Uses the fjac and ipvt optional outputs to construct an
        estimate of the jacobian around the solution.  ``None`` if a
        singular matrix encountered (indicates very flat curvature in
        some direction).  This matrix must be multiplied by the
        residual standard deviation to get the covariance of the
        parameter estimates -- see curve_fit.
    infodict : dict
        a dictionary of optional outputs with the key s::

            - 'nfev' : the number of function calls
            - 'fvec' : the function evaluated at the output
            - 'fjac' : A permutation of the R matrix of a QR
                     factorization of the final approximate
                     Jacobian matrix, stored column wise.
                     Together with ipvt, the covariance of the
                     estimate can be approximated.
            - 'ipvt' : an integer array of length N which defines
                     a permutation matrix, p, such that
                     fjac*p = q*r, where r is upper triangular
                     with diagonal elements of nonincreasing
                     magnitude. Column j of p is column ipvt(j)
                     of the identity matrix.
            - 'qtf'  : the vector (transpose(q) * fvec).

    mesg : str
        A string message giving information about the cause of failure.
    ier : int
        An integer flag.  If it is equal to 1, 2, 3 or 4, the solution was
        found.  Otherwise, the solution was not found. In either case, the
        optional output variable 'mesg' gives more information.

    Notes
    -----
    "leastsq" is a wrapper around MINPACK's lmdif and lmder algorithms.

    cov_x is a Jacobian approximation to the Hessian of the least squares
    objective function.
    This approximation assumes that the objective function is based on the
    difference between some observed target data (ydata) and a (non-linear)
    function of the parameters `f(xdata, params)` ::

           func(params) = ydata - f(xdata, params)

    so that the objective function is ::

           min   sum((ydata - f(xdata, params))**2, axis=0)
         params

    Contraints on the parameters are enforced using an internal parameter list
    with appropiate transformations such that these internal parameters can be
    optimized without constraints. The transfomation between a given internal
    parameter, p_i, and a external parameter, p_e, are as follows:

    With ``min`` and ``max`` bounds defined ::

        p_i = arcsin((2 * (p_e - min) / (max - min)) - 1.)
        p_e = min + ((max - min) / 2.) * (sin(p_i) + 1.)

    With only ``max`` defined ::

        p_i = sqrt((max - p_e + 1.)**2 - 1.)
        p_e = max + 1. - sqrt(p_i**2 + 1.)

    With only ``min`` defined ::

        p_i = sqrt((p_e - min + 1.)**2 - 1.)
        p_e = min - 1. + sqrt(p_i**2 + 1.)

    These transfomations are used in the MINUIT package, and described in
    detail in the section 1.3.1 of the MINUIT User's Guide.

    To Do
    -----
    Currently the ``factor`` and ``diag`` parameters scale the
    internal parameter list, but should scale the external parameter list.

    The `qtf` vector in the infodic dictionary reflects internal parameter
    list, it should be correct to reflect the external parameter list.

    References
    ----------
    * F. James and M. Winkler. MINUIT User's Guide, July 16, 2004.

    """
    # use leastsq if no bounds are present
    if bounds is None:
        return leastsq(func, x0, args, Dfun, full_output, col_deriv, ftol,
                       xtol, gtol, maxfev, epsfcn, factor, diag)

    # create function which convert between internal and external parameters
    i2e = _internal2external_func(bounds)
    e2i = _external2internal_func(bounds)

    x0 = array(x0, ndmin=1)
    i0 = e2i(x0)
    n = len(x0)
    if len(bounds) != n:
        raise ValueError('length of x0 != length of bounds')
    if type(args) != type(()):
        args = (args, )
    m = _check_func('leastsq', 'func', func, x0, args, n)[0]
    if n > m:
        raise TypeError('Improper input: N=%s must not exceed M=%s' % (n, m))

    # define a wrapped func which accept internal parameters, converts them
    # to external parameters and calls func
    def wfunc(x, *args):
        return func(i2e(x), *args)

    if Dfun is None:
        if (maxfev == 0):
            maxfev = 200 * (n + 1)
        retval = _minpack._lmdif(wfunc, i0, args, full_output, ftol, xtol,
                                 gtol, maxfev, epsfcn, factor, diag)
    else:
        if col_deriv:
            _check_func('leastsq', 'Dfun', Dfun, x0, args, n, (n, m))
        else:
            _check_func('leastsq', 'Dfun', Dfun, x0, args, n, (m, n))
        if (maxfev == 0):
            maxfev = 100 * (n + 1)

        def wDfun(x, *args):  # wrapped Dfun
            return Dfun(i2e(x), *args)

        retval = _minpack._lmder(func, wDfun, i0, args, full_output, col_deriv,
                                 ftol, xtol, gtol, maxfev, factor, diag)

    errors = {
        0: ["Improper input parameters.", TypeError],
        1: [
            "Both actual and predicted relative reductions "
            "in the sum of squares\n  are at most %f" % ftol, None
        ],
        2: [
            "The relative error between two consecutive "
            "iterates is at most %f" % xtol, None
        ],
        3: [
            "Both actual and predicted relative reductions in "
            "the sum of squares\n  are at most %f and the "
            "relative error between two consecutive "
            "iterates is at \n  most %f" % (ftol, xtol), None
        ],
        4: [
            "The cosine of the angle between func(x) and any "
            "column of the\n  Jacobian is at most %f in "
            "absolute value" % gtol, None
        ],
        5: [
            "Number of calls to function has reached "
            "maxfev = %d." % maxfev, ValueError
        ],
        6: [
            "ftol=%f is too small, no further reduction "
            "in the sum of squares\n  is possible."
            "" % ftol, ValueError
        ],
        7: [
            "xtol=%f is too small, no further improvement in "
            "the approximate\n  solution is possible." % xtol, ValueError
        ],
        8: [
            "gtol=%f is too small, func(x) is orthogonal to the "
            "columns of\n  the Jacobian to machine "
            "precision." % gtol, ValueError
        ],
        'unknown': ["Unknown error.", TypeError]
    }

    info = retval[-1]  # The FORTRAN return value

    if (info not in [1, 2, 3, 4] and not full_output):
        if info in [5, 6, 7, 8]:
            warnings.warn(errors[info][0], RuntimeWarning)
        else:
            try:
                raise errors[info][1](errors[info][0])
            except KeyError:
                raise errors['unknown'][1](errors['unknown'][0])

    mesg = errors[info][0]
    x = i2e(retval[0])  # internal params to external params

    if full_output:
        # convert fjac from internal params to external
        grad = _internal2external_grad(retval[0], bounds)
        retval[1]['fjac'] = (retval[1]['fjac'].T /
                             take(grad, retval[1]['ipvt'] - 1)).T
        cov_x = None
        if info in [1, 2, 3, 4]:
            from numpy.dual import inv
            from numpy.linalg import LinAlgError
            perm = take(eye(n), retval[1]['ipvt'] - 1, 0)
            r = triu(transpose(retval[1]['fjac'])[:n, :])
            R = dot(r, perm)
            try:
                cov_x = inv(dot(transpose(R), R))
            except LinAlgError:
                pass
        return (x, cov_x) + retval[1:-1] + (mesg, info)
    else:
        return (x, info)
Beispiel #3
0
def leastsq(func, x0, args=(), Dfun=None, full_output=0,
            col_deriv=0, ftol=1.49012e-8, xtol=1.49012e-8,
            gtol=0.0, maxfev=0, epsfcn=None, factor=100, diag=None):
    """
    Minimize the sum of squares of a set of equations.

    ::

        x = arg min(sum(func(y)**2,axis=0))
                 y

    Parameters
    ----------
    func : callable
        should take at least one (possibly length N vector) argument and
        returns M floating point numbers. It must not return NaNs or
        fitting might fail.
    x0 : ndarray
        The starting estimate for the minimization.
    args : tuple, optional
        Any extra arguments to func are placed in this tuple.
    Dfun : callable, optional
        A function or method to compute the Jacobian of func with derivatives
        across the rows. If this is None, the Jacobian will be estimated.
    full_output : bool, optional
        non-zero to return all optional outputs.
    col_deriv : bool, optional
        non-zero to specify that the Jacobian function computes derivatives
        down the columns (faster, because there is no transpose operation).
    ftol : float, optional
        Relative error desired in the sum of squares.
    xtol : float, optional
        Relative error desired in the approximate solution.
    gtol : float, optional
        Orthogonality desired between the function vector and the columns of
        the Jacobian.
    maxfev : int, optional
        The maximum number of calls to the function. If `Dfun` is provided
        then the default `maxfev` is 100*(N+1) where N is the number of elements
        in x0, otherwise the default `maxfev` is 200*(N+1).
    epsfcn : float, optional
        A variable used in determining a suitable step length for the forward-
        difference approximation of the Jacobian (for Dfun=None).
        Normally the actual step length will be sqrt(epsfcn)*x
        If epsfcn is less than the machine precision, it is assumed that the
        relative errors are of the order of the machine precision.
    factor : float, optional
        A parameter determining the initial step bound
        (``factor * || diag * x||``). Should be in interval ``(0.1, 100)``.
    diag : sequence, optional
        N positive entries that serve as a scale factors for the variables.

    Returns
    -------
    x : ndarray
        The solution (or the result of the last iteration for an unsuccessful
        call).
    cov_x : ndarray
        Uses the fjac and ipvt optional outputs to construct an
        estimate of the jacobian around the solution. None if a
        singular matrix encountered (indicates very flat curvature in
        some direction).  This matrix must be multiplied by the
        residual variance to get the covariance of the
        parameter estimates -- see curve_fit.
    infodict : dict
        a dictionary of optional outputs with the key s:

        ``nfev``
            The number of function calls
        ``fvec``
            The function evaluated at the output
        ``fjac``
            A permutation of the R matrix of a QR
            factorization of the final approximate
            Jacobian matrix, stored column wise.
            Together with ipvt, the covariance of the
            estimate can be approximated.
        ``ipvt``
            An integer array of length N which defines
            a permutation matrix, p, such that
            fjac*p = q*r, where r is upper triangular
            with diagonal elements of nonincreasing
            magnitude. Column j of p is column ipvt(j)
            of the identity matrix.
        ``qtf``
            The vector (transpose(q) * fvec).

    mesg : str
        A string message giving information about the cause of failure.
    ier : int
        An integer flag.  If it is equal to 1, 2, 3 or 4, the solution was
        found.  Otherwise, the solution was not found. In either case, the
        optional output variable 'mesg' gives more information.

    Notes
    -----
    "leastsq" is a wrapper around MINPACK's lmdif and lmder algorithms.

    cov_x is a Jacobian approximation to the Hessian of the least squares
    objective function.
    This approximation assumes that the objective function is based on the
    difference between some observed target data (ydata) and a (non-linear)
    function of the parameters `f(xdata, params)` ::

           func(params) = ydata - f(xdata, params)

    so that the objective function is ::

           min   sum((ydata - f(xdata, params))**2, axis=0)
         params

    """
    x0 = asarray(x0).flatten()
    n = len(x0)
    if not isinstance(args, tuple):
        args = (args,)
    shape, dtype = minpack._check_func('leastsq', 'func', func, x0, args, n)
    m = shape[0]
    # if n > m:
    #     raise TypeError('Improper input: N=%s must not exceed M=%s' % (n, m))
    if epsfcn is None:
        epsfcn = finfo(dtype).eps
    if Dfun is None:
        if maxfev == 0:
            maxfev = 200*(n + 1)
        retval = minpack._minpack._lmdif(func, x0, args, full_output, ftol, xtol,
                                 gtol, maxfev, epsfcn, factor, diag)
    else:
        if col_deriv:
            minpack._check_func('leastsq', 'Dfun', Dfun, x0, args, n, (n, m))
        else:
            minpack._check_func('leastsq', 'Dfun', Dfun, x0, args, n, (m, n))
        if maxfev == 0:
            maxfev = 100 * (n + 1)
        retval = minpack._minpack._lmder(func, Dfun, x0, args, full_output, col_deriv,
                                 ftol, xtol, gtol, maxfev, factor, diag)

    errors = {0: ["Improper input parameters.", TypeError],
              1: ["Both actual and predicted relative reductions "
                  "in the sum of squares\n  are at most %f" % ftol, None],
              2: ["The relative error between two consecutive "
                  "iterates is at most %f" % xtol, None],
              3: ["Both actual and predicted relative reductions in "
                  "the sum of squares\n  are at most %f and the "
                  "relative error between two consecutive "
                  "iterates is at \n  most %f" % (ftol, xtol), None],
              4: ["The cosine of the angle between func(x) and any "
                  "column of the\n  Jacobian is at most %f in "
                  "absolute value" % gtol, None],
              5: ["Number of calls to function has reached "
                  "maxfev = %d." % maxfev, ValueError],
              6: ["ftol=%f is too small, no further reduction "
                  "in the sum of squares\n  is possible.""" % ftol,
                  ValueError],
              7: ["xtol=%f is too small, no further improvement in "
                  "the approximate\n  solution is possible." % xtol,
                  ValueError],
              8: ["gtol=%f is too small, func(x) is orthogonal to the "
                  "columns of\n  the Jacobian to machine "
                  "precision." % gtol, ValueError],
              'unknown': ["Unknown error.", TypeError]}

    info = retval[-1]    # The FORTRAN return value

    if info not in [1, 2, 3, 4] and not full_output:
        if info in [5, 6, 7, 8]:
            minpack.warnings.warn(errors[info][0], RuntimeWarning)
        else:
            try:
                raise errors[info][1](errors[info][0])
            except KeyError:
                raise errors['unknown'][1](errors['unknown'][0])

    mesg = errors[info][0]
    if full_output:
        cov_x = None
        if info in [1, 2, 3, 4]:
            from numpy.dual import inv
            from numpy.linalg import LinAlgError
            perm = take(eye(n), retval[1]['ipvt'] - 1, 0)
            r = triu(transpose(retval[1]['fjac'])[:n, :])
            R = dot(r, perm)
            try:
                cov_x = inv(dot(transpose(R), R))
            except (LinAlgError, ValueError):
                pass
        return (retval[0], cov_x) + retval[1:-1] + (mesg, info)
    else:
        return (retval[0], info)