Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I would like to re-write a code from python to cython, and so far I cythonized all the parts which I simplified in this example by not using them. Therefore I could not keep the python shape of this function. However, I need to estimate the root of the function which before the scipy.optimize library has been used. I am wondering what I could substitute to find the roots for this function in cython. Could gsl also provide better tool to find the roots? How should it be done?

def RsMassInsideR(mass, R):
    def f(x):

        xp = R/x

        return (np.log(1+xp) - (xp/(1+xp)))*4*np.pi*delta*rho*x**3 - mass #rho and delta are constant


        rs = scipy.optimize.brenth(f, 0.01, 10.)

    except ValueError, e:
        print '!!!!!!!!!!!'
        print mass, f(0.01), f(10.)
        raise e

    return rs
share|improve this question

1 Answer 1

up vote 1 down vote accepted

I once was facing a similar problem for multidimensional root finding. Since I found a solution using GSL, I'd like to share my code here. The pyx file I used was

cdef extern from "gsl/gsl_errno.h":
    char * gsl_strerror(int gsl_errno)

cdef extern from "gsl/gsl_vector.h":
    ctypedef struct gsl_vector:
    ctypedef gsl_vector* const_gsl_vector "const gsl_vector*"
    gsl_vector* gsl_vector_alloc(size_t n)
    void gsl_vector_free(gsl_vector* v)
    void gsl_vector_set(gsl_vector* v, size_t i, double x)
    double gsl_vector_get(const_gsl_vector v, size_t i)

cdef extern from "gsl/gsl_multiroots.h":
    # structures
    ctypedef struct gsl_multiroot_function:
        int (*f) (const_gsl_vector x, void* params, gsl_vector* f)
        size_t n
        void* params
    ctypedef struct gsl_multiroot_fsolver_type:
    ctypedef gsl_multiroot_fsolver_type* const_gsl_multiroot_fsolver_type "const gsl_multiroot_fsolver_type*"
    ctypedef struct gsl_multiroot_fsolver:
        gsl_multiroot_fsolver_type* type
        gsl_multiroot_function* function
        gsl_vector* x
        gsl_vector* f
        gsl_vector* dx
        void* state

    # variables
    gsl_multiroot_fsolver_type* gsl_multiroot_fsolver_hybrids

    # functions
    gsl_multiroot_fsolver* gsl_multiroot_fsolver_alloc(
                                    gsl_multiroot_fsolver_type* T, size_t n)
    void gsl_multiroot_fsolver_free(gsl_multiroot_fsolver* s)
    int gsl_multiroot_fsolver_set(gsl_multiroot_fsolver* s, 
                                  gsl_multiroot_function* f, 
                                  const_gsl_vector x)
    int gsl_multiroot_fsolver_iterate(gsl_multiroot_fsolver* s)
    int gsl_multiroot_test_residual(const_gsl_vector f, double epsabs)


cdef size_t n = 2

cdef int rosenbrock_f(const_gsl_vector x, void* params, gsl_vector* f):
    cdef double a = 1.
    cdef double b = 10.

    cdef double x0 = gsl_vector_get(x, 0)
    cdef double x1 = gsl_vector_get(x, 1)

    cdef double y0 = a * (1 - x0)
    cdef double y1 = b * (x1 - x0 * x0)

    gsl_vector_set(f, 0, y0)
    gsl_vector_set(f, 1, y1)

    return GSL_SUCCESS

def gsl_find_root():
    #cdef const_gsl_multiroot_fsolver_type T
    cdef gsl_multiroot_fsolver* s

    cdef int status = GSL_CONTINUE
    cdef size_t i, iter = 0

    cdef gsl_multiroot_function func
    func.f = &rosenbrock_f
    func.n = n

    cdef double x_init[2]
    x_init[0] = -10.0
    x_init[1] = -5.0

    cdef gsl_vector* x = gsl_vector_alloc(n)

    gsl_vector_set (x, 0, x_init[0])
    gsl_vector_set (x, 1, x_init[1])

    s = gsl_multiroot_fsolver_alloc(gsl_multiroot_fsolver_hybrids, n)
    gsl_multiroot_fsolver_set(s, &func, x)

    while iter < 100 and status == GSL_CONTINUE:
        status = gsl_multiroot_fsolver_iterate(s)
        if status != GSL_SUCCESS:

        status = GSL_CONTINUE
        print "%d: %f, %f" % (iter, gsl_vector_get (s.x, 0), gsl_vector_get (s.x, 1))

        status = gsl_multiroot_test_residual(s.f, 1e-7)

        iter += 1

    print("status = %s" % gsl_strerror(status))


It should contain the necessary concepts and it should be easy enough to adapt it to the easier case of one-dimensional root-finding. Note that I here only work with gsl_vector and not numpy arrays. It is easy enough to copy a numpy array into a gsl_vector and it should even be possible to use a gsl_vector working directly on the data in a numpy array, although I've never tried this.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.