| |
| // These #defines attempt to ensure that posix_memalign() is declared, and |
| // so no spurious warning is given about using it. |
| |
| // Advertise compliance of the code to the XSI (a POSIX superset that |
| // defines what a system must be like to be called "UNIX") |
| #undef _XOPEN_SOURCE |
| #define _XOPEN_SOURCE 600 |
| |
| // Advertise compliance to POSIX |
| #undef _POSIX_C_SOURCE |
| #define _POSIX_C_SOURCE 200112L |
| |
| #include <stdlib.h> |
| #include <stdio.h> |
| #include <assert.h> |
| #include "tests/malloc.h" |
| #include <errno.h> |
| |
| int main ( void ) |
| { |
| # if defined(VGO_darwin) |
| // Mac OS X has neither memalign() nor posix_memalign(); do nothing. |
| // Still true for 10.6 / 10.7 ? |
| |
| # else |
| // Nb: assuming VG_MIN_MALLOC_SZB is 8 or more... |
| int* p; |
| int* piece; |
| int res; |
| assert(sizeof(long int) == sizeof(void*)); |
| |
| // Check behaviour of memalign/free for big alignment. |
| // In particular, the below aims at checking that a |
| // superblock with a big size is not marked as reclaimable |
| // if the superblock is used to provide a big aligned block |
| // (see bug 250101, comment #14). |
| // Valgrind m_mallocfree.c will allocate a big superblock for the memalign |
| // call and will split it in two. This splitted superblock was |
| // wrongly marked as reclaimable, which was then causing |
| // assert failures (as reclaimable blocks cannot be splitted). |
| p = memalign(1024 * 1024, 4 * 1024 * 1024 + 1); assert(0 == (long)p % (1024 * 1024)); |
| // We allocate (and then free) a piece of memory smaller than |
| // the hole created in the big superblock. |
| // If the superblock is marked as reclaimable, the below free(s) will cause |
| // an assert. Note that the test has to be run with a --free-list-vol |
| // parameter smaller than the released blocks size to ensure the free is directly |
| // executed (otherwise memcheck does not really release the memory and so |
| // the bug is not properly tested). |
| piece = malloc(1024 * 1000); assert (piece); |
| free (piece); |
| free (p); |
| |
| // Same as above but do the free in the reverse order. |
| p = memalign(1024 * 1024, 4 * 1024 * 1024 + 1); assert(0 == (long)p % (1024 * 1024)); |
| piece = malloc(1024 * 100); assert (piece); |
| free (p); |
| free (piece); |
| |
| p = memalign(0, 100); assert(0 == (long)p % 8); |
| p = memalign(1, 100); assert(0 == (long)p % 8); |
| p = memalign(2, 100); assert(0 == (long)p % 8); |
| p = memalign(3, 100); assert(0 == (long)p % 8); |
| p = memalign(4, 100); assert(0 == (long)p % 8); |
| p = memalign(5, 100); assert(0 == (long)p % 8); |
| |
| p = memalign(7, 100); assert(0 == (long)p % 8); |
| p = memalign(8, 100); assert(0 == (long)p % 8); |
| p = memalign(9, 100); assert(0 == (long)p % 16); |
| |
| p = memalign(31, 100); assert(0 == (long)p % 32); |
| p = memalign(32, 100); assert(0 == (long)p % 32); |
| p = memalign(33, 100); assert(0 == (long)p % 64); |
| |
| p = memalign(4095, 100); assert(0 == (long)p % 4096); |
| p = memalign(4096, 100); assert(0 == (long)p % 4096); |
| p = memalign(4097, 100); assert(0 == (long)p % 8192); |
| |
| p = memalign(4 * 1024 * 1024, 100); assert(0 == (long)p % (4 * 1024 * 1024)); |
| p = memalign(16 * 1024 * 1024, 100); assert(0 == (long)p % (16 * 1024 * 1024)); |
| |
| # define PM(a,b,c) posix_memalign((void**)a, b, c) |
| |
| res = PM(&p, -1,100); assert(EINVAL == res); |
| res = PM(&p, 0, 100); assert(0 == res && 0 == (long)p % 8); |
| res = PM(&p, 1, 100); assert(EINVAL == res); |
| res = PM(&p, 2, 100); assert(EINVAL == res); |
| res = PM(&p, 3, 100); assert(EINVAL == res); |
| res = PM(&p, sizeof(void*), 100); |
| assert(0 == res && 0 == (long)p % sizeof(void*)); |
| |
| res = PM(&p, 31, 100); assert(EINVAL == res); |
| res = PM(&p, 32, 100); assert(0 == res && 0 == (long)p % 32); |
| res = PM(&p, 33, 100); assert(EINVAL == res); |
| |
| res = PM(&p, 4095, 100); assert(EINVAL == res); |
| res = PM(&p, 4096, 100); assert(0 == res && 0 == (long)p % 4096); |
| res = PM(&p, 4097, 100); assert(EINVAL == res); |
| |
| res = PM(&p, 4 * 1024 * 1024, 100); assert(0 == res |
| && 0 == (long)p % (4 * 1024 * 1024)); |
| res = PM(&p, 16 * 1024 * 1024, 100); assert(0 == res |
| && 0 == (long)p % (16 * 1024 * 1024)); |
| # endif |
| |
| return 0; |
| } |