Current Path : /usr/src/crypto/openssh/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/crypto/openssh/monitor_mm.c |
/* $OpenBSD: monitor_mm.c,v 1.16 2009/06/22 05:39:28 dtucker Exp $ */ /* * Copyright 2002 Niels Provos <provos@citi.umich.edu> * All rights reserved. * * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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 "includes.h" #include <sys/types.h> #ifdef HAVE_SYS_MMAN_H #include <sys/mman.h> #endif #include <sys/param.h> #include "openbsd-compat/sys-tree.h" #include <errno.h> #include <stdarg.h> #include <string.h> #include "xmalloc.h" #include "ssh.h" #include "log.h" #include "monitor_mm.h" static int mm_compare(struct mm_share *a, struct mm_share *b) { long diff = (char *)a->address - (char *)b->address; if (diff == 0) return (0); else if (diff < 0) return (-1); else return (1); } RB_GENERATE(mmtree, mm_share, next, mm_compare) static struct mm_share * mm_make_entry(struct mm_master *mm, struct mmtree *head, void *address, size_t size) { struct mm_share *tmp, *tmp2; if (mm->mmalloc == NULL) tmp = xmalloc(sizeof(struct mm_share)); else tmp = mm_xmalloc(mm->mmalloc, sizeof(struct mm_share)); tmp->address = address; tmp->size = size; tmp2 = RB_INSERT(mmtree, head, tmp); if (tmp2 != NULL) fatal("mm_make_entry(%p): double address %p->%p(%lu)", mm, tmp2, address, (u_long)size); return (tmp); } /* Creates a shared memory area of a certain size */ struct mm_master * mm_create(struct mm_master *mmalloc, size_t size) { void *address; struct mm_master *mm; if (mmalloc == NULL) mm = xmalloc(sizeof(struct mm_master)); else mm = mm_xmalloc(mmalloc, sizeof(struct mm_master)); /* * If the memory map has a mm_master it can be completely * shared including authentication between the child * and the client. */ mm->mmalloc = mmalloc; address = xmmap(size); if (address == (void *)MAP_FAILED) fatal("mmap(%lu): %s", (u_long)size, strerror(errno)); mm->address = address; mm->size = size; RB_INIT(&mm->rb_free); RB_INIT(&mm->rb_allocated); mm_make_entry(mm, &mm->rb_free, address, size); return (mm); } /* Frees either the allocated or the free list */ static void mm_freelist(struct mm_master *mmalloc, struct mmtree *head) { struct mm_share *mms, *next; for (mms = RB_ROOT(head); mms; mms = next) { next = RB_NEXT(mmtree, head, mms); RB_REMOVE(mmtree, head, mms); if (mmalloc == NULL) xfree(mms); else mm_free(mmalloc, mms); } } /* Destroys a memory mapped area */ void mm_destroy(struct mm_master *mm) { mm_freelist(mm->mmalloc, &mm->rb_free); mm_freelist(mm->mmalloc, &mm->rb_allocated); #ifdef HAVE_MMAP if (munmap(mm->address, mm->size) == -1) fatal("munmap(%p, %lu): %s", mm->address, (u_long)mm->size, strerror(errno)); #else fatal("%s: UsePrivilegeSeparation=yes and Compression=yes not supported", __func__); #endif if (mm->mmalloc == NULL) xfree(mm); else mm_free(mm->mmalloc, mm); } void * mm_xmalloc(struct mm_master *mm, size_t size) { void *address; address = mm_malloc(mm, size); if (address == NULL) fatal("%s: mm_malloc(%lu)", __func__, (u_long)size); return (address); } /* Allocates data from a memory mapped area */ void * mm_malloc(struct mm_master *mm, size_t size) { struct mm_share *mms, *tmp; if (size == 0) fatal("mm_malloc: try to allocate 0 space"); if (size > SIZE_T_MAX - MM_MINSIZE + 1) fatal("mm_malloc: size too big"); size = ((size + (MM_MINSIZE - 1)) / MM_MINSIZE) * MM_MINSIZE; RB_FOREACH(mms, mmtree, &mm->rb_free) { if (mms->size >= size) break; } if (mms == NULL) return (NULL); /* Debug */ memset(mms->address, 0xd0, size); tmp = mm_make_entry(mm, &mm->rb_allocated, mms->address, size); /* Does not change order in RB tree */ mms->size -= size; mms->address = (u_char *)mms->address + size; if (mms->size == 0) { RB_REMOVE(mmtree, &mm->rb_free, mms); if (mm->mmalloc == NULL) xfree(mms); else mm_free(mm->mmalloc, mms); } return (tmp->address); } /* Frees memory in a memory mapped area */ void mm_free(struct mm_master *mm, void *address) { struct mm_share *mms, *prev, tmp; tmp.address = address; mms = RB_FIND(mmtree, &mm->rb_allocated, &tmp); if (mms == NULL) fatal("mm_free(%p): can not find %p", mm, address); /* Debug */ memset(mms->address, 0xd0, mms->size); /* Remove from allocated list and insert in free list */ RB_REMOVE(mmtree, &mm->rb_allocated, mms); if (RB_INSERT(mmtree, &mm->rb_free, mms) != NULL) fatal("mm_free(%p): double address %p", mm, address); /* Find previous entry */ prev = mms; if (RB_LEFT(prev, next)) { prev = RB_LEFT(prev, next); while (RB_RIGHT(prev, next)) prev = RB_RIGHT(prev, next); } else { if (RB_PARENT(prev, next) && (prev == RB_RIGHT(RB_PARENT(prev, next), next))) prev = RB_PARENT(prev, next); else { while (RB_PARENT(prev, next) && (prev == RB_LEFT(RB_PARENT(prev, next), next))) prev = RB_PARENT(prev, next); prev = RB_PARENT(prev, next); } } /* Check if range does not overlap */ if (prev != NULL && MM_ADDRESS_END(prev) > address) fatal("mm_free: memory corruption: %p(%lu) > %p", prev->address, (u_long)prev->size, address); /* See if we can merge backwards */ if (prev != NULL && MM_ADDRESS_END(prev) == address) { prev->size += mms->size; RB_REMOVE(mmtree, &mm->rb_free, mms); if (mm->mmalloc == NULL) xfree(mms); else mm_free(mm->mmalloc, mms); } else prev = mms; if (prev == NULL) return; /* Check if we can merge forwards */ mms = RB_NEXT(mmtree, &mm->rb_free, prev); if (mms == NULL) return; if (MM_ADDRESS_END(prev) > mms->address) fatal("mm_free: memory corruption: %p < %p(%lu)", mms->address, prev->address, (u_long)prev->size); if (MM_ADDRESS_END(prev) != mms->address) return; prev->size += mms->size; RB_REMOVE(mmtree, &mm->rb_free, mms); if (mm->mmalloc == NULL) xfree(mms); else mm_free(mm->mmalloc, mms); } static void mm_sync_list(struct mmtree *oldtree, struct mmtree *newtree, struct mm_master *mm, struct mm_master *mmold) { struct mm_master *mmalloc = mm->mmalloc; struct mm_share *mms, *new; /* Sync free list */ RB_FOREACH(mms, mmtree, oldtree) { /* Check the values */ mm_memvalid(mmold, mms, sizeof(struct mm_share)); mm_memvalid(mm, mms->address, mms->size); new = mm_xmalloc(mmalloc, sizeof(struct mm_share)); memcpy(new, mms, sizeof(struct mm_share)); RB_INSERT(mmtree, newtree, new); } } void mm_share_sync(struct mm_master **pmm, struct mm_master **pmmalloc) { struct mm_master *mm; struct mm_master *mmalloc; struct mm_master *mmold; struct mmtree rb_free, rb_allocated; debug3("%s: Share sync", __func__); mm = *pmm; mmold = mm->mmalloc; mm_memvalid(mmold, mm, sizeof(*mm)); mmalloc = mm_create(NULL, mm->size); mm = mm_xmalloc(mmalloc, sizeof(struct mm_master)); memcpy(mm, *pmm, sizeof(struct mm_master)); mm->mmalloc = mmalloc; rb_free = mm->rb_free; rb_allocated = mm->rb_allocated; RB_INIT(&mm->rb_free); RB_INIT(&mm->rb_allocated); mm_sync_list(&rb_free, &mm->rb_free, mm, mmold); mm_sync_list(&rb_allocated, &mm->rb_allocated, mm, mmold); mm_destroy(mmold); *pmm = mm; *pmmalloc = mmalloc; debug3("%s: Share sync end", __func__); } void mm_memvalid(struct mm_master *mm, void *address, size_t size) { void *end = (u_char *)address + size; if (address < mm->address) fatal("mm_memvalid: address too small: %p", address); if (end < address) fatal("mm_memvalid: end < address: %p < %p", end, address); if (end > (void *)((u_char *)mm->address + mm->size)) fatal("mm_memvalid: address too large: %p", address); }