/* * Copyright (c) 2009-2012, Salvatore Sanfilippo * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Redis nor the names of its contributors may be used * to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #if defined(__sun) #include #endif #include "config.h" #if (ULONG_MAX == 4294967295UL) #define MEMTEST_32BIT #elif (ULONG_MAX == 18446744073709551615ULL) #define MEMTEST_64BIT #else #error "ULONG_MAX value not supported." #endif #ifdef MEMTEST_32BIT #define ULONG_ONEZERO 0xaaaaaaaaUL #define ULONG_ZEROONE 0x55555555UL #else #define ULONG_ONEZERO 0xaaaaaaaaaaaaaaaaUL #define ULONG_ZEROONE 0x5555555555555555UL #endif static struct winsize ws; size_t progress_printed; /* Printed chars in screen-wide progress bar. */ size_t progress_full; /* How many chars to write to fill the progress bar. */ void memtest_progress_start(char *title, int pass) { int j; printf("\x1b[H\x1b[2J"); /* Cursor home, clear screen. */ /* Fill with dots. */ for (j = 0; j < ws.ws_col*(ws.ws_row-2); j++) printf("."); printf("Please keep the test running several minutes per GB of memory.\n"); printf("Also check http://www.memtest86.com/ and http://pyropus.ca/software/memtester/"); printf("\x1b[H\x1b[2K"); /* Cursor home, clear current line. */ printf("%s [%d]\n", title, pass); /* Print title. */ progress_printed = 0; progress_full = (size_t)ws.ws_col*(ws.ws_row-3); fflush(stdout); } void memtest_progress_end(void) { printf("\x1b[H\x1b[2J"); /* Cursor home, clear screen. */ } void memtest_progress_step(size_t curr, size_t size, char c) { size_t chars = ((unsigned long long)curr*progress_full)/size, j; for (j = 0; j < chars-progress_printed; j++) printf("%c",c); progress_printed = chars; fflush(stdout); } /* Test that addressing is fine. Every location is populated with its own * address, and finally verified. This test is very fast but may detect * ASAP big issues with the memory subsystem. */ int memtest_addressing(unsigned long *l, size_t bytes, int interactive) { unsigned long words = bytes/sizeof(unsigned long); unsigned long j, *p; /* Fill */ p = l; for (j = 0; j < words; j++) { *p = (unsigned long)p; p++; if ((j & 0xffff) == 0 && interactive) memtest_progress_step(j,words*2,'A'); } /* Test */ p = l; for (j = 0; j < words; j++) { if (*p != (unsigned long)p) { if (interactive) { printf("\n*** MEMORY ADDRESSING ERROR: %p contains %lu\n", (void*) p, *p); exit(1); } return 1; } p++; if ((j & 0xffff) == 0 && interactive) memtest_progress_step(j+words,words*2,'A'); } return 0; } /* Fill words stepping a single page at every write, so we continue to * touch all the pages in the smallest amount of time reducing the * effectiveness of caches, and making it hard for the OS to transfer * pages on the swap. * * In this test we can't call rand() since the system may be completely * unable to handle library calls, so we have to resort to our own * PRNG that only uses local state. We use an xorshift* PRNG. */ #define xorshift64star_next() do { \ rseed ^= rseed >> 12; \ rseed ^= rseed << 25; \ rseed ^= rseed >> 27; \ rout = rseed * UINT64_C(2685821657736338717); \ } while(0) void memtest_fill_random(unsigned long *l, size_t bytes, int interactive) { unsigned long step = 4096/sizeof(unsigned long); unsigned long words = bytes/sizeof(unsigned long)/2; unsigned long iwords = words/step; /* words per iteration */ unsigned long off, w, *l1, *l2; uint64_t rseed = UINT64_C(0xd13133de9afdb566); /* Just a random seed. */ uint64_t rout = 0; assert((bytes & 4095) == 0); for (off = 0; off < step; off++) { l1 = l+off; l2 = l1+words; for (w = 0; w < iwords; w++) { xorshift64star_next(); *l1 = *l2 = (unsigned long) rout; l1 += step; l2 += step; if ((w & 0xffff) == 0 && interactive) memtest_progress_step(w+iwords*off,words,'R'); } } } /* Like memtest_fill_random() but uses the two specified values to fill * memory, in an alternated way (v1|v2|v1|v2|...) */ void memtest_fill_value(unsigned long *l, size_t bytes, unsigned long v1, unsigned long v2, char sym, int interactive) { unsigned long step = 4096/sizeof(unsigned long); unsigned long words = bytes/sizeof(unsigned long)/2; unsigned long iwords = words/step; /* words per iteration */ unsigned long off, w, *l1, *l2, v; assert((bytes & 4095) == 0); for (off = 0; off < step; off++) { l1 = l+off; l2 = l1+words; v = (off & 1) ? v2 : v1; for (w = 0; w < iwords; w++) { #ifdef MEMTEST_32BIT *l1 = *l2 = ((unsigned long) v) | (((unsigned long) v) << 16); #else *l1 = *l2 = ((unsigned long) v) | (((unsigned long) v) << 16) | (((unsigned long) v) << 32) | (((unsigned long) v) << 48); #endif l1 += step; l2 += step; if ((w & 0xffff) == 0 && interactive) memtest_progress_step(w+iwords*off,words,sym); } } } int memtest_compare(unsigned long *l, size_t bytes, int interactive) { unsigned long words = bytes/sizeof(unsigned long)/2; unsigned long w, *l1, *l2; assert((bytes & 4095) == 0); l1 = l; l2 = l1+words; for (w = 0; w < words; w++) { if (*l1 != *l2) { if (interactive) { printf("\n*** MEMORY ERROR DETECTED: %p != %p (%lu vs %lu)\n", (void*)l1, (void*)l2, *l1, *l2); exit(1); } return 1; } l1 ++; l2 ++; if ((w & 0xffff) == 0 && interactive) memtest_progress_step(w,words,'='); } return 0; } int memtest_compare_times(unsigned long *m, size_t bytes, int pass, int times, int interactive) { int j; int errors = 0; for (j = 0; j < times; j++) { if (interactive) memtest_progress_start("Compare",pass); errors += memtest_compare(m,bytes,interactive); if (interactive) memtest_progress_end(); } return errors; } /* Test the specified memory. The number of bytes must be multiple of 4096. * If interactive is true the program exists with an error and prints * ASCII arts to show progresses. Instead when interactive is 0, it can * be used as an API call, and returns 1 if memory errors were found or * 0 if there were no errors detected. */ int memtest_test(unsigned long *m, size_t bytes, int passes, int interactive) { int pass = 0; int errors = 0; while (pass != passes) { pass++; if (interactive) memtest_progress_start("Addressing test",pass); errors += memtest_addressing(m,bytes,interactive); if (interactive) memtest_progress_end(); if (interactive) memtest_progress_start("Random fill",pass); memtest_fill_random(m,bytes,interactive); if (interactive) memtest_progress_end(); errors += memtest_compare_times(m,bytes,pass,4,interactive); if (interactive) memtest_progress_start("Solid fill",pass); memtest_fill_value(m,bytes,0,(unsigned long)-1,'S',interactive); if (interactive) memtest_progress_end(); errors += memtest_compare_times(m,bytes,pass,4,interactive); if (interactive) memtest_progress_start("Checkerboard fill",pass); memtest_fill_value(m,bytes,ULONG_ONEZERO,ULONG_ZEROONE,'C',interactive); if (interactive) memtest_progress_end(); errors += memtest_compare_times(m,bytes,pass,4,interactive); } return errors; } /* A version of memtest_test() that tests memory in small pieces * in order to restore the memory content at exit. * * One problem we have with this approach, is that the cache can avoid * real memory accesses, and we can't test big chunks of memory at the * same time, because we need to backup them on the stack (the allocator * may not be usable or we may be already in an out of memory condition). * So what we do is to try to trash the cache with useless memory accesses * between the fill and compare cycles. */ #define MEMTEST_BACKUP_WORDS (1024*(1024/sizeof(long))) /* Random accesses of MEMTEST_DECACHE_SIZE are performed at the start and * end of the region between fill and compare cycles in order to trash * the cache. */ #define MEMTEST_DECACHE_SIZE (1024*8) int memtest_preserving_test(unsigned long *m, size_t bytes, int passes) { unsigned long backup[MEMTEST_BACKUP_WORDS]; unsigned long *p = m; unsigned long *end = (unsigned long*) (((unsigned char*)m)+(bytes-MEMTEST_DECACHE_SIZE)); size_t left = bytes; int errors = 0; if (bytes & 4095) return 0; /* Can't test across 4k page boundaries. */ if (bytes < 4096*2) return 0; /* Can't test a single page. */ while(left) { /* If we have to test a single final page, go back a single page * so that we can test two pages, since the code can't test a single * page but at least two. */ if (left == 4096) { left += 4096; p -= 4096/sizeof(unsigned long); } int pass = 0; size_t len = (left > sizeof(backup)) ? sizeof(backup) : left; /* Always test an even number of pages. */ if (len/4096 % 2) len -= 4096; memcpy(backup,p,len); /* Backup. */ while(pass != passes) { pass++; errors += memtest_addressing(p,len,0); memtest_fill_random(p,len,0); if (bytes >= MEMTEST_DECACHE_SIZE) { memtest_compare_times(m,MEMTEST_DECACHE_SIZE,pass,1,0); memtest_compare_times(end,MEMTEST_DECACHE_SIZE,pass,1,0); } errors += memtest_compare_times(p,len,pass,4,0); memtest_fill_value(p,len,0,(unsigned long)-1,'S',0); if (bytes >= MEMTEST_DECACHE_SIZE) { memtest_compare_times(m,MEMTEST_DECACHE_SIZE,pass,1,0); memtest_compare_times(end,MEMTEST_DECACHE_SIZE,pass,1,0); } errors += memtest_compare_times(p,len,pass,4,0); memtest_fill_value(p,len,ULONG_ONEZERO,ULONG_ZEROONE,'C',0); if (bytes >= MEMTEST_DECACHE_SIZE) { memtest_compare_times(m,MEMTEST_DECACHE_SIZE,pass,1,0); memtest_compare_times(end,MEMTEST_DECACHE_SIZE,pass,1,0); } errors += memtest_compare_times(p,len,pass,4,0); } memcpy(p,backup,len); /* Restore. */ left -= len; p += len/sizeof(unsigned long); } return errors; } /* Perform an interactive test allocating the specified number of megabytes. */ void memtest_alloc_and_test(size_t megabytes, int passes) { size_t bytes = megabytes*1024*1024; unsigned long *m = malloc(bytes); if (m == NULL) { fprintf(stderr,"Unable to allocate %zu megabytes: %s", megabytes, strerror(errno)); exit(1); } memtest_test(m,bytes,passes,1); free(m); } void memtest(size_t megabytes, int passes) { #if !defined(__HAIKU__) if (ioctl(1, TIOCGWINSZ, &ws) == -1) { ws.ws_col = 80; ws.ws_row = 20; } #else ws.ws_col = 80; ws.ws_row = 20; #endif memtest_alloc_and_test(megabytes,passes); printf("\nYour memory passed this test.\n"); printf("Please if you are still in doubt use the following two tools:\n"); printf("1) memtest86: http://www.memtest86.com/\n"); printf("2) memtester: http://pyropus.ca/software/memtester/\n"); exit(0); }