EDIT: New example that explode without changing the ulimit, and it does not matter what is in the c part.

I am a python user (I learned from an edX course), and I have been working with ctypes and c (but I dont really know c). I have a "Segmentation fault: 11" problem with my code when I run it with some specific parameters (basically, a big array size), here is a small example that replicates what my code do:


import numpy as np
from numpy.ctypeslib import ndpointer
import ctypes as cy

Lib_Path = './lib.so'

class Simulacion:
    def __init__(self, ss,tm):
        self.tm    = tm;
        self.ss    = ss;

    def ejecutar(self):
        self.data   = np.empty((int(self.ss), self.tm), dtype = float)
        lib   = cy.CDLL(Lib_Path)
        dblc = cy.c_double; pntrc = ndpointer(dblc);  intc = cy.c_long
        lib.trisolve.argtypes = [intc, pntrc, intc]
        lib.trisolve(self.tm, self.data, self.ss)
        return self.data

ss = 10
tm  = int(1e6);

sim = Simulacion(ss,tm)
data = sim.ejecutar()


void trisolve(int tm, double* data, int ss){



    $(GCC) -fPIC -fopenmp -lm -c -O3 $(SRC).c
    $(GCC) -shared -lgomp -o lib.so $(SRC).o
    rm lib.so
    rm $(SRC).o

This code explode without changing the ulimit.

for my real code, i am using "ulimit -s 65532" which is the maximum stack size in my mac. This limit the size of the arrays that I am using, and currently I need to duplicate the size of it. For what I have found, the problem is that the arrays are being stored in the stack instead of the heap, so I have this hard limit due to the SO. So my question is, how I can pass that big array to C, store it in the heap and then bring it back to python ?

I mostly use python, and the c part of the code I did it without a good formation in this lenguaje, so "stacks", "heap" and probably "malloc" are new terms for me.


  • "but I dont really know c" - well, you should probably go learn it. You're trying to do something moderately advanced, but you're making basic errors like mixing up int and long, let alone the more complex parts of working with NumPy arrays in C. – user2357112 supports Monica Apr 28 '17 at 17:07
  • I really don't need to learn it more that what I already know (except for what i am asking here). since I am using c only to solve a matrix (since is much faster than python) probably I can make mayor edition to the code and bypass my problem, but I want to know how to fix the code like it is now. thanks. – Ardemion Apr 28 '17 at 23:51
  • 2
    "I am using c only to solve a matrix" - what, as in solving systems of linear equations? NumPy has that built in, and it'll already automatically delegate to LAPACK. – user2357112 supports Monica Apr 28 '17 at 23:55
  • As written this isn't using the stack to store the array. It's allocated on the heap, and then you iterate over it. I don't see why omp parallel for would cause that problem either. But CPython itself needs at least 32K of stack. – Eryk Sun Apr 29 '17 at 0:59
  • Is more complex than that, but I don't want to explain everything here xD, in the code I have a big while, inside it a few for to set the terms of the matrix, then the solution of it, then some modification of the result, and then the iteration again. @eryksun if is not using the stack, why when I use ulimit -s 16, I got a segmentation fault, but if I set it to, for example, 65532, the code works without a problem?. the omp parallel for is not the problem here, the program doesn't even start running the c code. (if I put print there, the segmentation fault occurs before it). – Ardemion Apr 29 '17 at 4:46

Finally I found the problem, which had nothing to do with ctypes. Inside my real c code, I defined an array with array[tm], but tm was to big for the stack. Why I was able to replicate the problem with the code above? I really don't know, but when I tried today (since @eryksun told that the code worked for him) it did not exploded. Thanks for the help; I will try to learn a bit more of C in the future.

  • If you declared that array as an automatic variable, then it does use the stack. To use the heap you need to malloc memory, which returns a void * pointer. In this case, to prevent memory leaks you have to carefully control the return paths of the function to ensure that you free the pointer. – Eryk Sun May 3 '17 at 3:14

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