# f2py, Python function that returns an array (vector-valued function)

In the following Python I have five functions contained in the array returned by `func` which I have to integrate. The code calls an external Fortran module generated using `f2py`:

``````import numpy as np
from numpy import cos, sin , exp
from trapzdv import trapzdv
def func(x):
return np.array([x**2, x**3, cos(x), sin(x), exp(x)])

if __name__ == '__main__':
xs = np.linspace(0.,20.,100)
ans =  trapzdv(func,xs,5)
print 'from Fortran:', ans
print 'exact:', np.array([20**3/3., 20**4/4., sin(20.), -cos(20.), exp(20.)])
``````

The Fortran routine is:

``````      subroutine trapzdv(f,xs,nf,nxs,result)
integer :: I
double precision :: x1,x2
integer, intent(in) :: nf, nxs
double precision, dimension(nf) :: fx1,fx2
double precision, intent(in), dimension(nxs) :: xs
double precision, intent(out), dimension(nf) :: result
external :: f
result = 0.0
do I = 2,nxs
x1 = xs(I-1)
x2 = xs(I)
fx1 = f(x1)
fx2 = f(x2)
result = result + (fx1+fx2)*(x2-x1)/2
enddo
return
end
``````

The problem is that Fortran is only integrating the first function in `func(x)`. See the print result:

``````from Fortran: [ 2666.80270721  2666.80270721  2666.80270721  2666.80270721  2666.80270721]
exact: [  2.66666667e+03   4.00000000e+04   9.12945251e-01  -4.08082062e-01 4.85165195e+08]
``````

One way to workarond that is to modify `func(x)` to return the value of a given position in the array of functions:

``````def func(x,i):
return np.array([x**2, x**3, cos(x), sin(x), exp(x)])[i-1]
``````

And then change the Fortran routine to call the function with two parameters:

``````      subroutine trapzdv(f,xs,nf,nxs,result)
integer :: I
double precision :: x1,x2,fx1,fx2
integer, intent(in) :: nf, nxs
double precision, intent(in), dimension(nxs) :: xs
double precision, intent(out), dimension(nf) :: result
external :: f
result = 0.0
do I = 2,nxs
x1 = xs(I-1)
x2 = xs(I)
do J = 1,nf
fx1 = f(x1,J)
fx2 = f(x2,J)
result(J) = result(J) + (fx1+fx2)*(x2-x1)/2
enddo
enddo
return
end
``````

Which works:

``````from Fortran: [  2.66680271e+03   4.00040812e+04   9.09838195e-01   5.89903440e-01 4.86814128e+08]
exact: [  2.66666667e+03   4.00000000e+04   9.12945251e-01  -4.08082062e-01 4.85165195e+08]
``````

But here `func` is called 5 times more than necessary (in the real case `func` has above 300 functions, so it will be called 300 times more than necessary).

• Does anyone know a better solution to make Fortran recognizes all the array returned by `func(x)`? In other words, make Fortran build `fx1 = f(x1)` as an array with 5 elements corresponding to the functions in `func(x)`.

OBS: I am compiling using `f2py -c --compiler=mingw32 -m trapzdv trapzdv.f90`

-

Unfortunately, you cannot return the array from the python function into Fortran. You would need a subroutine for that (meaning it is called with the `call` statement), and this is something that `f2py` does not let you do.

In Fortran 90 you can create functions that return arrays, but again this is not something that `f2py` can do, especially since your function is not a Fortran function.

Your only option is to use your looping workaround, or a redesign of how you want python and Fortran to interact.

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Despite this answer does not solve the question, it is a workaround doing the same in Cython. Here the trapezoidal rule and a polynomial integrator are implemented for a vector-valued function. The code below I put in a `integratev.pyx`:

``````import numpy as np
from numpy.linalg import inv
cimport numpy as np
FLOAT = np.float32
ctypedef np.float_t FLOAT_t

def trapzv(f, np.ndarray xs, int nf):
cdef int nxs = xs.shape[0]
cdef np.ndarray ans = np.zeros(nf, dtype=FLOAT)
cdef double x1, x2
for i in range(1,nxs):
x1 = xs[i-1]
x2 = xs[i]
ans += (f(x2)+f(x1))*(x2-x1)/2.
return ans

def poly(f, np.ndarray xs, int nf, int order=2):
cdef int nxs = xs.shape[0]
cdef np.ndarray ans = np.zeros(nf, dtype=FLOAT)
cdef np.ndarray xis = np.zeros(order+1, dtype=FLOAT)
cdef np.ndarray ais
if nxs % (order+1) != 0:
raise ValueError("poly: The size of xs must be a multiple of 'order+1'")
for i in range(order,nxs,order):
xis = xs[i-order:i+1]
X = np.concatenate([(xis**i)[:,None] for i in range(order+1)], axis=1)
ais = np.dot( inv(X), f(xis).transpose() )
for k in range(1,order+2):
ans += ais[k-1,:]/k * (xis[-1]**k - xis[0]**k)
return ans
``````

The following test was used:

``````import numpy as np
from numpy import cos, sin , exp
import pyximport; pyximport.install()
import integratev
from subprocess import Popen
def func(x):
return np.array([x**2, x**3, cos(x), sin(x), exp(x)])

if __name__ == '__main__':
xs = np.linspace(0.,20.,33)
print 'exact:', np.array([20**3/3., 20**4/4., sin(20.), -cos(20.)+1, exp(20.)-1])
ans =  integratev.trapzv(func,xs,5)
print 'trapzv:', ans
ans =  integratev.poly(func,xs,5,2)
print 'poly:', ans
``````

Giving:

``````exact: [  2.66666667e+03   4.00000000e+04   9.12945251e-01   5.91917938e-01 4.85165194e+08]
trapzv: [  2.66796875e+03   4.00390625e+04   8.83031547e-01   5.72522998e-01 5.00856448e+08]
poly: [  2.66666675e+03   4.00000000e+04   9.13748980e-01   5.92435718e-01 4.85562144e+08]
``````

The poly can be of any order, which will probably give better results for most of the cases...

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