/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * The structure of the sbrk backend: * * +-----------+ * | sbrk_top | * +-----------+ * | (vmem_sbrk_alloc(), vmem_free()) * | * +-----------+ * | sbrk_heap | * +-----------+ * | | ... | (vmem_alloc(), vmem_free()) * * * The sbrk_top arena holds all controlled memory. vmem_sbrk_alloc() handles * allocations from it, including growing the heap when we run low. * * Growing the heap is complicated by the fact that we have to extend the * sbrk_top arena (using _vmem_extend_alloc()), and that can fail. Since * other threads may be actively allocating, we can't return the memory. * * Instead, we put it on a doubly-linked list, sbrk_fails, which we search * before calling sbrk(). */ #include "mtlib.h" #include #include #include #include #include #include "vmem_base.h" #include "misc.h" size_t vmem_sbrk_pagesize = 0; /* the preferred page size of the heap */ #define MIN_ALLOC (64*1024) static size_t real_pagesize; static vmem_t *sbrk_heap; typedef struct sbrk_fail { struct sbrk_fail *sf_next; struct sbrk_fail *sf_prev; void *sf_base; /* == the sbrk_fail's address */ size_t sf_size; /* the size of this buffer */ } sbrk_fail_t; static sbrk_fail_t sbrk_fails = { &sbrk_fails, &sbrk_fails, NULL, 0 }; static mutex_t sbrk_faillock = DEFAULTMUTEX; /* * Try to extend src with [pos, pos + size). * * If it fails, add the block to the sbrk_fails list. */ static void * vmem_sbrk_extend_alloc(vmem_t *src, void *pos, size_t size, size_t alloc, int vmflags) { sbrk_fail_t *fnext, *fprev, *fp; void *ret; ret = _vmem_extend_alloc(src, pos, size, alloc, vmflags); if (ret != NULL) return (ret); fp = (sbrk_fail_t *)pos; ASSERT(sizeof (sbrk_fail_t) <= size); fp->sf_base = pos; fp->sf_size = size; (void) mutex_lock(&sbrk_faillock); fp->sf_next = fnext = &sbrk_fails; fp->sf_prev = fprev = sbrk_fails.sf_prev; fnext->sf_prev = fp; fprev->sf_next = fp; (void) mutex_unlock(&sbrk_faillock); return (NULL); } /* * Try to add at least size bytes to src, using the sbrk_fails list */ static void * vmem_sbrk_tryfail(vmem_t *src, size_t size, int vmflags) { sbrk_fail_t *fp; (void) mutex_lock(&sbrk_faillock); for (fp = sbrk_fails.sf_next; fp != &sbrk_fails; fp = fp->sf_next) { if (fp->sf_size >= size) { fp->sf_next->sf_prev = fp->sf_prev; fp->sf_prev->sf_next = fp->sf_next; fp->sf_next = fp->sf_prev = NULL; break; } } (void) mutex_unlock(&sbrk_faillock); if (fp != &sbrk_fails) { ASSERT(fp->sf_base == (void *)fp); return (vmem_sbrk_extend_alloc(src, fp, fp->sf_size, size, vmflags)); } /* * nothing of the right size on the freelist */ return (NULL); } static void * vmem_sbrk_alloc(vmem_t *src, size_t size, int vmflags) { extern void *_sbrk_grow_aligned(size_t min_size, size_t low_align, size_t high_align, size_t *actual_size); void *ret; void *buf; size_t buf_size; int old_errno = errno; ret = vmem_alloc(src, size, VM_NOSLEEP); if (ret != NULL) { errno = old_errno; return (ret); } /* * The allocation failed. We need to grow the heap. * * First, try to use any buffers which failed earlier. */ if (sbrk_fails.sf_next != &sbrk_fails && (ret = vmem_sbrk_tryfail(src, size, vmflags)) != NULL) return (ret); buf_size = MAX(size, MIN_ALLOC); /* * buf_size gets overwritten with the actual allocated size */ buf = _sbrk_grow_aligned(buf_size, real_pagesize, vmem_sbrk_pagesize, &buf_size); if (buf != MAP_FAILED) { ret = vmem_sbrk_extend_alloc(src, buf, buf_size, size, vmflags); if (ret != NULL) { errno = old_errno; return (ret); } } /* * Growing the heap failed. The vmem_alloc() above called umem_reap(). */ ASSERT((vmflags & VM_NOSLEEP) == VM_NOSLEEP); errno = old_errno; return (NULL); } /* * fork1() support */ void vmem_sbrk_lockup(void) { (void) mutex_lock(&sbrk_faillock); } void vmem_sbrk_release(void) { (void) mutex_unlock(&sbrk_faillock); } vmem_t * vmem_sbrk_arena(vmem_alloc_t **a_out, vmem_free_t **f_out) { if (sbrk_heap == NULL) { size_t heap_size; real_pagesize = sysconf(_SC_PAGESIZE); heap_size = vmem_sbrk_pagesize; if (issetugid()) { heap_size = 0; } else if (heap_size != 0 && !ISP2(heap_size)) { heap_size = 0; log_message("ignoring bad pagesize: 0x%p\n", heap_size); } if (heap_size <= real_pagesize) { heap_size = real_pagesize; } else { struct memcntl_mha mha; mha.mha_cmd = MHA_MAPSIZE_BSSBRK; mha.mha_flags = 0; mha.mha_pagesize = heap_size; if (memcntl(NULL, 0, MC_HAT_ADVISE, (char *)&mha, 0, 0) == -1) { log_message("unable to set MAPSIZE_BSSBRK to " "0x%p\n", heap_size); heap_size = real_pagesize; } } vmem_sbrk_pagesize = heap_size; sbrk_heap = vmem_init("sbrk_top", real_pagesize, vmem_sbrk_alloc, vmem_free, "sbrk_heap", NULL, 0, real_pagesize, vmem_alloc, vmem_free); } if (a_out != NULL) *a_out = vmem_alloc; if (f_out != NULL) *f_out = vmem_free; return (sbrk_heap); }