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So obviously the number 399137 in and of its self doesn't cause a segmentation fault, but my program consistently crashes on the same computation. It calculates the values of Euler's totient (phi function) from 2 to a given limit (default 1,000,000). It does so by keeping a linearly ordered list of primes from previously computed values of Euler's totient. When attempting to add the 33791st prime number (339137) to the list of primes it results in a segmentation fault. Note memory isn't realloc'd on this computation. I tried using gdb to locate the problem and it pointed to the line where the the prime number is added to the list (see below).

To store all the primes below 1 million my program would dynamically allocate 8192*10*4 bytes (320KB). Requiring that much contiguous memory doesn't seem problematic to me.

So why does the my program consistently have a segmentation fault when attempting to add 339137 to the list of primes? What is the cause of this segmentation fault?

C Code:

#include <math.h>
#include <stdio.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>

uint32_t phi       (uint32_t n, uint32_t *primes, uint32_t *count, uint32_t *size);
uint32_t gcd_bin   (uint32_t u, uint32_t v);
uint32_t isPrime   (uint32_t n, uint32_t *primes, uint32_t *count, uint32_t *size);
void     addPrime  (uint32_t n, uint32_t *primes, uint32_t *count, uint32_t *size);
uint32_t isInArr   (uint32_t n, uint32_t *primes, uint32_t count);
uint32_t expand_arr(uint32_t **arr, uint32_t *size);
void     print_arr (uint32_t  *arr, uint32_t count);
uint32_t print_help(char* str);

int main(int argc, char* argv[]) {
  uint32_t z=1000000;         //default
  uint32_t count=0,size = 10; //default
  uint32_t i,n;
//  uint32_t x,y; //max numerator & denominator of ratio
  uint32_t *primes = malloc(size * sizeof(uint32_t));

  if(argc > 1 && !strcmp(argv[1],"--help")) { return print_help(argv[0]); }
  if(argc > 1) {  sscanf(argv[1],"%u",&z); }

  uint32_t old=size;
  for(i=2,/*x=y=1,*/count=0; i<=z; ++i) {
    n = phi(i,primes,&count,&size);
    fprintf(stderr,"\ni=%u phi(i)=%u\t: c=%u s=%u ",i,n,count,size);
  }
//  printf("%u/%u\n",x,y);
  return 0;
}

uint32_t phi(uint32_t n, uint32_t *primes, uint32_t *count, uint32_t *size) {
  uint32_t i,bound;
  // Base case
  if(n < 2)
    return 0;
  // Is Prime? (Lehmer's conjecture)
  if(isPrime(n,primes,count,size))
    return n-1;
  // Even number?
  if((n & 1) == 0 ) {
    int m = n >> 1;
    return ~m & 1 ? phi(m,primes,count,size)<<1 : phi(m,primes,count,size);
  }
  // Find (smallest) prime factor using list of primes
  for(i=0,bound=(uint32_t)sqrt(n); primes[i] < bound && i<*count && (n%primes[i])!=0; ++i);
  uint32_t m = primes[i];
  uint32_t o = n/m;
  uint32_t d = gcd_bin(m, o);
  return d==1 ? phi(m,primes,count,size)*phi(o,primes,count,size)
              : phi(m,primes,count,size)*phi(o,primes,count,size)*(d/phi(d,primes,count,size));
}

uint32_t isPrime(uint32_t n, uint32_t *primes, uint32_t *count, uint32_t *size) {
  uint32_t i,prime,bound;
  for(i=0,prime=1,bound=(uint32_t)sqrt(n)+1; prime && i<*count && primes[i]<=bound; ++i)
    prime = n%primes[i];
  if(prime)
    addPrime(n,primes,count,size);
  return prime;
}

void addPrime(uint32_t n, uint32_t *primes, uint32_t *count, uint32_t *size) {
  if(*count >= *size) {
    if(!expand_arr(&primes,size)) {
      fprintf(stderr,"dying gracefully!");
      exit(1); //realloc failure
    }
  }
  if(!isInArr(n,primes,*count))
    primes[(*count)++] = n; /* ERROR IS HERE APPARENTLY */
}

uint32_t expand_arr(uint32_t **primes, uint32_t *size) {
  *size  *= 2;
  *primes = realloc(*primes, *size * sizeof(uint32_t));
  return *primes!=NULL;
}

uint32_t isInArr(uint32_t n, uint32_t *primes, uint32_t count) {
  uint32_t hi,low,mid,val;
  low = 0; hi = count; // set bounds
  while(low < hi) {    // binary search
    mid = low/2 + hi/2;
    val = primes[mid];
    if(val == n) return  1;
    if(val >  n) hi  = mid;
    if(val <  n) low = mid+1;
  }
  return 0;
}

void print_arr(uint32_t *arr, uint32_t count) {
  uint32_t i;
  for(i=0; i<count; ++i)
    printf("%u,",arr[i]);
  printf("\n");
}

uint32_t gcd_bin(uint32_t u, uint32_t v) {
    /* simple cases (termination) */
    if(u == v)  return u;
    if(u == 0)  return v;
    if(v == 0)  return u;
    /* look for even numbers  */
    if( ~u & 1) {
      if(v & 1) return gcd_bin(u >> 1, v);           /* u is even, v is odd  */
      else      return gcd_bin(u >> 1, v >> 1) << 1; /* u is even, v is even */
    }
    if( ~v & 1) return gcd_bin(u, v >> 1);           /* u is odd,  v is even */
    /* reduce larger argument */                     /* u is odd,  v is odd  */
    return (u > v) ? gcd_bin((u - v) >> 1, v)
                   : gcd_bin((v - u) >> 1, u);
}

uint32_t print_help(char* str) {
  printf("  Usage: %s <limit> \n",str);
  printf("  Calculates the values of euler's totient (phi fnction) \n");
  printf("  from 2 to <limit> inclusively\n");
  printf("  * limit : a decimal number\n");
  printf("          : default = 1000000\n");
  return 0;
}
share|improve this question
3  
tried starting "later" in the prime sequence, e.g. starting at 2 instead of 1, and see if the 33792nd prime causes the segfault then? If it does, then you've got a memory overrun error somewhere. –  Marc B Jun 11 '13 at 17:05
    
What would happen if you recoded this to pre-allocate your prime buffer one time to a size larger than where to crash is occurring. It might help isolate the area to that portion of the code and make things simpler to manage. I personally am not a fan of realloc schemes and would rather see a single buffer made big enough to hold all your primes, but I also understand there are times when it is necessary. –  Michael Dorgan Jun 11 '13 at 17:14
    
I'd suggest using valgrind to run your application. It shows 605 errors in 59 contexts. I think you've got something to chew on. –  Bryan Olivier Jun 11 '13 at 17:15
    
@MarcB I edited the primality test to include the following at the beginning: if(~n & 1) return 0; to skip 2 as a prime number. The program crashes when the count reaches 337991; trying to compute the 33792nd prime (399149). –  awashburn Jun 11 '13 at 17:16
1  
@awashburn Valgrind tells you where the problems are... Which manual are you reading? –  undefined behaviour Jun 11 '13 at 17:21

1 Answer 1

up vote 4 down vote accepted

First off, the best tool for finding a bug of this type is valgrind. Ignore all the options and just run it as valgrind ./a.out, then fix the very first problem it reports. Repeat until program runs correctly.

Now, in this case the problem is apparent to me from code inspection because I know what to look for. I learned what to look for by debugging a gazillion of these problems, with the aid of valgrind. Valgrind is your friend. Use it.

uint32_t expand_arr(uint32_t **arr, uint32_t *size);

This function expands the array pointed to by the pointer pointed to by the arr argument, overwriting the old pointer with the new one.

void addPrime(uint32_t n, uint32_t *primes, uint32_t *count, uint32_t *size) {
  if(*count >= *size) {
    if(!expand_arr(&primes,size)) {

This function invokes expand_arr on the primes pointer, which is a function parameter, and therefore a copy of the pointer known to the caller. When expand_arr changes primes, that only affects the copy here in addPrime, not the copy in its caller; the caller's pointer is left pointing to freed memory.

In fact, primes is threaded as a function argument all the way back up through isPrime and phi to main. All of those functions need to pass primes around as a pointer to a pointer, as expand_arr already does, so that no stale pointers are left behind when expand_arr calls realloc.

Here's how valgrind would have told you that this is the problem:

i=29 phi(i)=28  : c=10 s=10 ==17052== Invalid read of size 4
==17052==    at 0x4009D5: isPrime (test.c:59)
==17052==    by 0x400BC4: phi (test.c:41)
==17052==    by 0x400DCB: main (test.c:28)
==17052==  Address 0x54de040 is 0 bytes inside a block of size 40 free'd
==17052==    at 0x4C2C03E: realloc (vg_replace_malloc.c:662)
==17052==    by 0x4008C9: expand_arr (test.c:79)
==17052==    by 0x400968: addPrime (test.c:68)
==17052==    by 0x400A07: isPrime (test.c:62)
==17052==    by 0x400BC4: phi (test.c:41)
==17052==    by 0x400C50: phi (test.c:53)
==17052==    by 0x400DCB: main (test.c:28)

Notice how it's pointing you at isPrime as the location of the "invalid read", and that it tells you straight off that what you have is a stale pointer to deallocated memory ("0 bytes inside a block of size 40 free'd") -- and that it caught the problem at iteration 29 of the main loop.

share|improve this answer
    
Iteration 29 --> 29 is the 10th prime --> the memory was just expanded! Makes sense! Thanks very much for your experienced look at the problem. I will try using pointers to the array throughout the program functions and see if that fixes the runtime errors. –  awashburn Jun 11 '13 at 17:31
    
Right. One of the things valgrind does for you is make sure realloc always invalidates the old pointer, instead of just sometimes. You were probably getting crashes on prime 33791 because your C library was avoiding moving the block of memory until it absolutely had to, which happened at approximately 132kB allocated (33791 * 4 = 132 * 1024 - 4). –  Zack Jun 11 '13 at 17:51
    
Pointers to the array for all the function calls was the solution. I changed the function signatures to contain a double de-referenced pointers (uint32_t **primes) and I changed the array access code to specifically de-reference the array prior to modification ((*primes)[ (*count)++ ] = n). That was the solution! No segmentation faults and valgrind's analysis is clean! –  awashburn Jun 11 '13 at 18:34

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