/* * Copyright (c) 2000, 2001, 2002, 2003, 2004, 2005, 2008, 2009 * The President and Fellows of Harvard College. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. 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. * 3. Neither the name of the University 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 UNIVERSITY 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 UNIVERSITY 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. */ /* * Test code for kmalloc. */ #include <types.h> #include <kern/errno.h> #include <lib.h> #include <thread.h> #include <synch.h> #include <vm.h> /* for PAGE_SIZE */ #include <test.h> #include "opt-dumbvm.h" //////////////////////////////////////////////////////////// // km1/km2 /* * Test kmalloc; allocate ITEMSIZE bytes NTRIES times, freeing * somewhat later. * * The total of ITEMSIZE * NTRIES is intended to exceed the size of * available memory. * * mallocstress does the same thing, but from NTHREADS different * threads at once. */ #define NTRIES 1200 #define ITEMSIZE 997 #define NTHREADS 8 static void mallocthread(void *sm, unsigned long num) { struct semaphore *sem = sm; void *ptr; void *oldptr=NULL; void *oldptr2=NULL; int i; for (i=0; i<NTRIES; i++) { ptr = kmalloc(ITEMSIZE); if (ptr==NULL) { if (sem) { kprintf("thread %lu: kmalloc returned NULL\n", num); V(sem); return; } kprintf("kmalloc returned null; test failed.\n"); return; } if (oldptr2) { kfree(oldptr2); } oldptr2 = oldptr; oldptr = ptr; } if (oldptr2) { kfree(oldptr2); } if (oldptr) { kfree(oldptr); } if (sem) { V(sem); } } int malloctest(int nargs, char **args) { (void)nargs; (void)args; kprintf("Starting kmalloc test...\n"); mallocthread(NULL, 0); kprintf("kmalloc test done\n"); return 0; } int mallocstress(int nargs, char **args) { struct semaphore *sem; int i, result; (void)nargs; (void)args; sem = sem_create("mallocstress", 0); if (sem == NULL) { panic("mallocstress: sem_create failed\n"); } kprintf("Starting kmalloc stress test...\n"); for (i=0; i<NTHREADS; i++) { result = thread_fork("mallocstress", NULL, mallocthread, sem, i); if (result) { panic("mallocstress: thread_fork failed: %s\n", strerror(result)); } } for (i=0; i<NTHREADS; i++) { P(sem); } sem_destroy(sem); kprintf("kmalloc stress test done\n"); return 0; } //////////////////////////////////////////////////////////// // km3 /* * Larger kmalloc test. Or at least, potentially larger. The size is * an argument. * * The argument specifies the number of objects to allocate; the size * of each allocation rotates through sizes[]. (FUTURE: should there * be a mode that allocates random sizes?) In order to hold the * pointers returned by kmalloc we first allocate a two-level radix * tree whose lower tier is made up of blocks of size PAGE_SIZE/4. * (This is so they all go to the subpage allocator rather than being * whole-page allocations.) * * Since PAGE_SIZE is commonly 4096, each of these blocks holds 1024 * pointers (on a 32-bit machine) or 512 (on a 64-bit machine) and so * we can store considerably more pointers than we have memory for * before the upper tier becomes a whole page or otherwise gets * uncomfortably large. * * Having set this up, the test just allocates and then frees all the * pointers in order, setting and checking the contents. */ int malloctest3(int nargs, char **args) { #define NUM_KM3_SIZES 5 static const unsigned sizes[NUM_KM3_SIZES] = { 32, 41, 109, 86, 9 }; unsigned numptrs; size_t ptrspace; size_t blocksize; unsigned numptrblocks; void ***ptrblocks; unsigned curblock, curpos, cursizeindex, cursize; size_t totalsize; unsigned i, j; unsigned char *ptr; if (nargs != 2) { kprintf("malloctest3: usage: malloctest3 numobjects\n"); return EINVAL; } /* Figure out how many pointers we'll get and the space they need. */ numptrs = atoi(args[1]); ptrspace = numptrs * sizeof(void *); /* Figure out how many blocks in the lower tier. */ blocksize = PAGE_SIZE / 4; numptrblocks = DIVROUNDUP(ptrspace, blocksize); kprintf("malloctest3: %u objects, %u pointer blocks\n", numptrs, numptrblocks); /* Allocate the upper tier. */ ptrblocks = kmalloc(numptrblocks * sizeof(ptrblocks[0])); if (ptrblocks == NULL) { panic("malloctest3: failed on pointer block array\n"); } /* Allocate the lower tier. */ for (i=0; i<numptrblocks; i++) { ptrblocks[i] = kmalloc(blocksize); if (ptrblocks[i] == NULL) { panic("malloctest3: failed on pointer block %u\n", i); } } /* Allocate the objects. */ curblock = 0; curpos = 0; cursizeindex = 0; totalsize = 0; for (i=0; i<numptrs; i++) { cursize = sizes[cursizeindex]; ptr = kmalloc(cursize); if (ptr == NULL) { kprintf("malloctest3: failed on object %u size %u\n", i, cursize); kprintf("malloctest3: pos %u in pointer block %u\n", curpos, curblock); kprintf("malloctest3: total so far %zu\n", totalsize); panic("malloctest3: failed.\n"); } /* Fill the object with its number. */ for (j=0; j<cursize; j++) { ptr[j] = (unsigned char) i; } /* Move to the next slot in the tree. */ ptrblocks[curblock][curpos] = ptr; curpos++; if (curpos >= blocksize / sizeof(void *)) { curblock++; curpos = 0; } /* Update the running total, and rotate the size. */ totalsize += cursize; cursizeindex = (cursizeindex + 1) % NUM_KM3_SIZES; } kprintf("malloctest3: %zu bytes allocated\n", totalsize); /* Free the objects. */ curblock = 0; curpos = 0; cursizeindex = 0; for (i=0; i<numptrs; i++) { cursize = sizes[cursizeindex]; ptr = ptrblocks[curblock][curpos]; KASSERT(ptr != NULL); for (j=0; j<cursize; j++) { if (ptr[j] == (unsigned char) i) { continue; } kprintf("malloctest3: failed on object %u size %u\n", i, cursize); kprintf("malloctest3: pos %u in pointer block %u\n", curpos, curblock); kprintf("malloctest3: at object offset %u\n", j); kprintf("malloctest3: expected 0x%x, found 0x%x\n", ptr[j], (unsigned char) i); panic("malloctest3: failed.\n"); } kfree(ptr); curpos++; if (curpos >= blocksize / sizeof(void *)) { curblock++; curpos = 0; } KASSERT(totalsize > 0); totalsize -= cursize; cursizeindex = (cursizeindex + 1) % NUM_KM3_SIZES; } KASSERT(totalsize == 0); /* Free the lower tier. */ for (i=0; i<numptrblocks; i++) { KASSERT(ptrblocks[i] != NULL); kfree(ptrblocks[i]); } /* Free the upper tier. */ kfree(ptrblocks); kprintf("malloctest3: passed\n"); return 0; } //////////////////////////////////////////////////////////// // km4 static void malloctest4thread(void *sm, unsigned long num) { #define NUM_KM4_SIZES 5 static const unsigned sizes[NUM_KM4_SIZES] = { 1, 3, 5, 2, 4 }; struct semaphore *sem = sm; void *ptrs[NUM_KM4_SIZES]; unsigned p, q; unsigned i; for (i=0; i<NUM_KM4_SIZES; i++) { ptrs[i] = NULL; } p = 0; q = NUM_KM4_SIZES / 2; for (i=0; i<NTRIES; i++) { if (ptrs[q] != NULL) { kfree(ptrs[q]); ptrs[q] = NULL; } ptrs[p] = kmalloc(sizes[p] * PAGE_SIZE); if (ptrs[p] == NULL) { panic("malloctest4: thread %lu: " "allocating %u pages failed\n", num, sizes[p]); } p = (p + 1) % NUM_KM4_SIZES; q = (q + 1) % NUM_KM4_SIZES; } for (i=0; i<NUM_KM4_SIZES; i++) { if (ptrs[i] != NULL) { kfree(ptrs[i]); } } V(sem); } int malloctest4(int nargs, char **args) { struct semaphore *sem; unsigned nthreads; unsigned i; int result; (void)nargs; (void)args; kprintf("Starting multipage kmalloc test...\n"); #if OPT_DUMBVM kprintf("(This test will not work with dumbvm)\n"); #endif sem = sem_create("malloctest4", 0); if (sem == NULL) { panic("malloctest4: sem_create failed\n"); } /* use 6 instead of 8 threads */ nthreads = (3*NTHREADS)/4; for (i=0; i<nthreads; i++) { result = thread_fork("malloctest4", NULL, malloctest4thread, sem, i); if (result) { panic("mallocstress: thread_fork failed: %s\n", strerror(result)); } } for (i=0; i<nthreads; i++) { P(sem); } sem_destroy(sem); kprintf("Multipage kmalloc test done\n"); return 0; }