/* * Copyright (c) 2001 Daniel Eischen * Copyright (c) 2000-2001 Jason Evans * 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 AUTHORS 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 AUTHORS 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. * * $FreeBSD$ */ #include "namespace.h" #include #include #include #include #include #include "un-namespace.h" #include "thr_private.h" /* Spare thread stack. */ struct stack { LIST_ENTRY(stack) qe; /* Stack queue linkage. */ size_t stacksize; /* Stack size (rounded up). */ size_t guardsize; /* Guard size. */ void *stackaddr; /* Stack address. */ }; /* * Default sized (stack and guard) spare stack queue. Stacks are cached * to avoid additional complexity managing mmap()ed stack regions. Spare * stacks are used in LIFO order to increase cache locality. */ static LIST_HEAD(, stack) dstackq = LIST_HEAD_INITIALIZER(dstackq); /* * Miscellaneous sized (non-default stack and/or guard) spare stack queue. * Stacks are cached to avoid additional complexity managing mmap()ed * stack regions. This list is unordered, since ordering on both stack * size and guard size would be more trouble than it's worth. Stacks are * allocated from this cache on a first size match basis. */ static LIST_HEAD(, stack) mstackq = LIST_HEAD_INITIALIZER(mstackq); /** * Base address of the last stack allocated (including its red zone, if * there is one). Stacks are allocated contiguously, starting beyond the * top of the main stack. When a new stack is created, a red zone is * typically created (actually, the red zone is mapped with PROT_NONE) above * the top of the stack, such that the stack will not be able to grow all * the way to the bottom of the next stack. This isn't fool-proof. It is * possible for a stack to grow by a large amount, such that it grows into * the next stack, and as long as the memory within the red zone is never * accessed, nothing will prevent one thread stack from trouncing all over * the next. * * low memory * . . . . . . . . . . . . . . . . . . * | | * | stack 3 | start of 3rd thread stack * +-----------------------------------+ * | | * | Red Zone (guard page) | red zone for 2nd thread * | | * +-----------------------------------+ * | stack 2 - PTHREAD_STACK_DEFAULT | top of 2nd thread stack * | | * | | * | | * | | * | stack 2 | * +-----------------------------------+ <-- start of 2nd thread stack * | | * | Red Zone | red zone for 1st thread * | | * +-----------------------------------+ * | stack 1 - PTHREAD_STACK_DEFAULT | top of 1st thread stack * | | * | | * | | * | | * | stack 1 | * +-----------------------------------+ <-- start of 1st thread stack * | | (initial value of last_stack) * | Red Zone | * | | red zone for main thread * +-----------------------------------+ * | USRSTACK - PTHREAD_STACK_INITIAL | top of main thread stack * | | ^ * | | | * | | | * | | | stack growth * | | * +-----------------------------------+ <-- start of main thread stack * (USRSTACK) * high memory * */ static void *last_stack = NULL; /* * Round size up to the nearest multiple of * _thr_page_size. */ static inline size_t round_up(size_t size) { if (size % _thr_page_size != 0) size = ((size / _thr_page_size) + 1) * _thr_page_size; return (size); } int _thr_stack_alloc(struct pthread_attr *attr) { struct stack *spare_stack; struct kse *curkse; kse_critical_t crit; size_t stacksize; size_t guardsize; char *stackaddr; /* * Round up stack size to nearest multiple of _thr_page_size so * that mmap() * will work. If the stack size is not an even * multiple, we end up initializing things such that there is * unused space above the beginning of the stack, so the stack * sits snugly against its guard. */ stacksize = round_up(attr->stacksize_attr); guardsize = round_up(attr->guardsize_attr); attr->stackaddr_attr = NULL; attr->flags &= ~THR_STACK_USER; /* * Use the garbage collector lock for synchronization of the * spare stack lists and allocations from usrstack. */ crit = _kse_critical_enter(); curkse = _get_curkse(); KSE_LOCK_ACQUIRE(curkse, &_thread_list_lock); /* * If the stack and guard sizes are default, try to allocate a stack * from the default-size stack cache: */ if ((stacksize == _thr_stack_default) && (guardsize == _thr_guard_default)) { if ((spare_stack = LIST_FIRST(&dstackq)) != NULL) { /* Use the spare stack. */ LIST_REMOVE(spare_stack, qe); attr->stackaddr_attr = spare_stack->stackaddr; } } /* * The user specified a non-default stack and/or guard size, so try to * allocate a stack from the non-default size stack cache, using the * rounded up stack size (stack_size) in the search: */ else { LIST_FOREACH(spare_stack, &mstackq, qe) { if (spare_stack->stacksize == stacksize && spare_stack->guardsize == guardsize) { LIST_REMOVE(spare_stack, qe); attr->stackaddr_attr = spare_stack->stackaddr; break; } } } if (attr->stackaddr_attr != NULL) { /* A cached stack was found. Release the lock. */ KSE_LOCK_RELEASE(curkse, &_thread_list_lock); _kse_critical_leave(crit); } else { /* Allocate a stack from usrstack. */ if (last_stack == NULL) last_stack = (void *)((uintptr_t)_usrstack - (uintptr_t)_thr_stack_initial - (uintptr_t)_thr_guard_default); /* Allocate a new stack. */ stackaddr = (void *)((uintptr_t)last_stack - (uintptr_t)stacksize - (uintptr_t)guardsize); /* * Even if stack allocation fails, we don't want to try to * use this location again, so unconditionally decrement * last_stack. Under normal operating conditions, the most * likely reason for an mmap() error is a stack overflow of * the adjacent thread stack. */ last_stack = (void *)((uintptr_t)last_stack - (uintptr_t)(stacksize + guardsize)); /* Release the lock before mmap'ing it. */ KSE_LOCK_RELEASE(curkse, &_thread_list_lock); _kse_critical_leave(crit); /* Map the stack and guard page together, and split guard page from allocated space: */ if ((stackaddr = mmap(stackaddr, stacksize+guardsize, PROT_READ | PROT_WRITE, MAP_STACK, -1, 0)) != MAP_FAILED && (guardsize == 0 || mprotect(stackaddr, guardsize, PROT_NONE) == 0)) { stackaddr += guardsize; } else { if (stackaddr != MAP_FAILED) munmap(stackaddr, stacksize + guardsize); stackaddr = NULL; } attr->stackaddr_attr = stackaddr; } if (attr->stackaddr_attr != NULL) return (0); else return (-1); } /* This function must be called with _thread_list_lock held. */ void _thr_stack_free(struct pthread_attr *attr) { struct stack *spare_stack; if ((attr != NULL) && ((attr->flags & THR_STACK_USER) == 0) && (attr->stackaddr_attr != NULL)) { spare_stack = (struct stack *)((uintptr_t)attr->stackaddr_attr + (uintptr_t)attr->stacksize_attr - sizeof(struct stack)); spare_stack->stacksize = round_up(attr->stacksize_attr); spare_stack->guardsize = round_up(attr->guardsize_attr); spare_stack->stackaddr = attr->stackaddr_attr; if (spare_stack->stacksize == _thr_stack_default && spare_stack->guardsize == _thr_guard_default) { /* Default stack/guard size. */ LIST_INSERT_HEAD(&dstackq, spare_stack, qe); } else { /* Non-default stack/guard size. */ LIST_INSERT_HEAD(&mstackq, spare_stack, qe); } attr->stackaddr_attr = NULL; } }