/* * Copyright (c) 2004, 2005 Topspin Communications. All rights reserved. * Copyright (c) 2006 Cisco Systems, Inc. All rights reserved. * * This software is available to you under a choice of one of two * licenses. You may choose to be licensed under the terms of the GNU * General Public License (GPL) Version 2, available from the file * COPYING in the main directory of this source tree, or the * OpenIB.org BSD license below: * * 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. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include "ibverbs.h" #include "util/rdma_nl.h" struct ibv_mem_node { enum { IBV_RED, IBV_BLACK } color; struct ibv_mem_node *parent; struct ibv_mem_node *left, *right; uintptr_t start, end; int refcnt; }; static struct ibv_mem_node *mm_root; static pthread_mutex_t mm_mutex = PTHREAD_MUTEX_INITIALIZER; static int page_size; static int huge_page_enabled; static int too_late; static unsigned long smaps_page_size(FILE *file) { int n; unsigned long size = page_size; char buf[1024]; while (fgets(buf, sizeof(buf), file) != NULL) { if (!strstr(buf, "KernelPageSize:")) continue; n = sscanf(buf, "%*s %lu", &size); if (n < 1) continue; /* page size is printed in Kb */ size = size * 1024; break; } return size; } static unsigned long get_page_size(void *base) { unsigned long ret = page_size; pid_t pid; FILE *file; char buf[1024]; pid = getpid(); snprintf(buf, sizeof(buf), "/proc/%d/smaps", pid); file = fopen(buf, "r" STREAM_CLOEXEC); if (!file) goto out; while (fgets(buf, sizeof(buf), file) != NULL) { int n; uintptr_t range_start, range_end; n = sscanf(buf, "%" SCNxPTR "-%" SCNxPTR, &range_start, &range_end); if (n < 2) continue; if ((uintptr_t) base >= range_start && (uintptr_t) base < range_end) { ret = smaps_page_size(file); break; } } fclose(file); out: return ret; } int ibv_fork_init(void) { void *tmp, *tmp_aligned; int ret; unsigned long size; if (getenv("RDMAV_HUGEPAGES_SAFE")) huge_page_enabled = 1; if (mm_root) return 0; if (ibv_is_fork_initialized() == IBV_FORK_UNNEEDED) return 0; if (too_late) return EINVAL; page_size = sysconf(_SC_PAGESIZE); if (page_size < 0) return errno; if (posix_memalign(&tmp, page_size, page_size)) return ENOMEM; if (huge_page_enabled) { size = get_page_size(tmp); tmp_aligned = (void *) ((uintptr_t) tmp & ~(size - 1)); } else { size = page_size; tmp_aligned = tmp; } ret = madvise(tmp_aligned, size, MADV_DONTFORK) || madvise(tmp_aligned, size, MADV_DOFORK); free(tmp); if (ret) return ENOSYS; mm_root = malloc(sizeof *mm_root); if (!mm_root) return ENOMEM; mm_root->parent = NULL; mm_root->left = NULL; mm_root->right = NULL; mm_root->color = IBV_BLACK; mm_root->start = 0; mm_root->end = UINTPTR_MAX; mm_root->refcnt = 0; return 0; } enum ibv_fork_status ibv_is_fork_initialized(void) { if (get_copy_on_fork()) return IBV_FORK_UNNEEDED; return mm_root ? IBV_FORK_ENABLED : IBV_FORK_DISABLED; } static struct ibv_mem_node *__mm_prev(struct ibv_mem_node *node) { if (node->left) { node = node->left; while (node->right) node = node->right; } else { while (node->parent && node == node->parent->left) node = node->parent; node = node->parent; } return node; } static struct ibv_mem_node *__mm_next(struct ibv_mem_node *node) { if (node->right) { node = node->right; while (node->left) node = node->left; } else { while (node->parent && node == node->parent->right) node = node->parent; node = node->parent; } return node; } static void __mm_rotate_right(struct ibv_mem_node *node) { struct ibv_mem_node *tmp; tmp = node->left; node->left = tmp->right; if (node->left) node->left->parent = node; if (node->parent) { if (node->parent->right == node) node->parent->right = tmp; else node->parent->left = tmp; } else mm_root = tmp; tmp->parent = node->parent; tmp->right = node; node->parent = tmp; } static void __mm_rotate_left(struct ibv_mem_node *node) { struct ibv_mem_node *tmp; tmp = node->right; node->right = tmp->left; if (node->right) node->right->parent = node; if (node->parent) { if (node->parent->right == node) node->parent->right = tmp; else node->parent->left = tmp; } else mm_root = tmp; tmp->parent = node->parent; tmp->left = node; node->parent = tmp; } #if 0 static int verify(struct ibv_mem_node *node) { int hl, hr; if (!node) return 1; hl = verify(node->left); hr = verify(node->left); if (!hl || !hr) return 0; if (hl != hr) return 0; if (node->color == IBV_RED) { if (node->left && node->left->color != IBV_BLACK) return 0; if (node->right && node->right->color != IBV_BLACK) return 0; return hl; } return hl + 1; } #endif static void __mm_add_rebalance(struct ibv_mem_node *node) { struct ibv_mem_node *parent, *gp, *uncle; while (node->parent && node->parent->color == IBV_RED) { parent = node->parent; gp = node->parent->parent; if (parent == gp->left) { uncle = gp->right; if (uncle && uncle->color == IBV_RED) { parent->color = IBV_BLACK; uncle->color = IBV_BLACK; gp->color = IBV_RED; node = gp; } else { if (node == parent->right) { __mm_rotate_left(parent); node = parent; parent = node->parent; } parent->color = IBV_BLACK; gp->color = IBV_RED; __mm_rotate_right(gp); } } else { uncle = gp->left; if (uncle && uncle->color == IBV_RED) { parent->color = IBV_BLACK; uncle->color = IBV_BLACK; gp->color = IBV_RED; node = gp; } else { if (node == parent->left) { __mm_rotate_right(parent); node = parent; parent = node->parent; } parent->color = IBV_BLACK; gp->color = IBV_RED; __mm_rotate_left(gp); } } } mm_root->color = IBV_BLACK; } static void __mm_add(struct ibv_mem_node *new) { struct ibv_mem_node *node, *parent = NULL; node = mm_root; while (node) { parent = node; if (node->start < new->start) node = node->right; else node = node->left; } if (parent->start < new->start) parent->right = new; else parent->left = new; new->parent = parent; new->left = NULL; new->right = NULL; new->color = IBV_RED; __mm_add_rebalance(new); } static void __mm_remove(struct ibv_mem_node *node) { struct ibv_mem_node *child, *parent, *sib, *tmp; int nodecol; if (node->left && node->right) { tmp = node->left; while (tmp->right) tmp = tmp->right; nodecol = tmp->color; child = tmp->left; tmp->color = node->color; if (tmp->parent != node) { parent = tmp->parent; parent->right = tmp->left; if (tmp->left) tmp->left->parent = parent; tmp->left = node->left; node->left->parent = tmp; } else parent = tmp; tmp->right = node->right; node->right->parent = tmp; tmp->parent = node->parent; if (node->parent) { if (node->parent->left == node) node->parent->left = tmp; else node->parent->right = tmp; } else mm_root = tmp; } else { nodecol = node->color; child = node->left ? node->left : node->right; parent = node->parent; if (child) child->parent = parent; if (parent) { if (parent->left == node) parent->left = child; else parent->right = child; } else mm_root = child; } free(node); if (nodecol == IBV_RED) return; while ((!child || child->color == IBV_BLACK) && child != mm_root) { if (parent->left == child) { sib = parent->right; if (sib->color == IBV_RED) { parent->color = IBV_RED; sib->color = IBV_BLACK; __mm_rotate_left(parent); sib = parent->right; } if ((!sib->left || sib->left->color == IBV_BLACK) && (!sib->right || sib->right->color == IBV_BLACK)) { sib->color = IBV_RED; child = parent; parent = child->parent; } else { if (!sib->right || sib->right->color == IBV_BLACK) { if (sib->left) sib->left->color = IBV_BLACK; sib->color = IBV_RED; __mm_rotate_right(sib); sib = parent->right; } sib->color = parent->color; parent->color = IBV_BLACK; if (sib->right) sib->right->color = IBV_BLACK; __mm_rotate_left(parent); child = mm_root; break; } } else { sib = parent->left; if (sib->color == IBV_RED) { parent->color = IBV_RED; sib->color = IBV_BLACK; __mm_rotate_right(parent); sib = parent->left; } if ((!sib->left || sib->left->color == IBV_BLACK) && (!sib->right || sib->right->color == IBV_BLACK)) { sib->color = IBV_RED; child = parent; parent = child->parent; } else { if (!sib->left || sib->left->color == IBV_BLACK) { if (sib->right) sib->right->color = IBV_BLACK; sib->color = IBV_RED; __mm_rotate_left(sib); sib = parent->left; } sib->color = parent->color; parent->color = IBV_BLACK; if (sib->left) sib->left->color = IBV_BLACK; __mm_rotate_right(parent); child = mm_root; break; } } } if (child) child->color = IBV_BLACK; } static struct ibv_mem_node *__mm_find_start(uintptr_t start, uintptr_t end) { struct ibv_mem_node *node = mm_root; while (node) { if (node->start <= start && node->end >= start) break; if (node->start < start) node = node->right; else node = node->left; } return node; } static struct ibv_mem_node *merge_ranges(struct ibv_mem_node *node, struct ibv_mem_node *prev) { prev->end = node->end; prev->refcnt = node->refcnt; __mm_remove(node); return prev; } static struct ibv_mem_node *split_range(struct ibv_mem_node *node, uintptr_t cut_line) { struct ibv_mem_node *new_node = NULL; new_node = malloc(sizeof *new_node); if (!new_node) return NULL; new_node->start = cut_line; new_node->end = node->end; new_node->refcnt = node->refcnt; node->end = cut_line - 1; __mm_add(new_node); return new_node; } static struct ibv_mem_node *get_start_node(uintptr_t start, uintptr_t end, int inc) { struct ibv_mem_node *node, *tmp = NULL; node = __mm_find_start(start, end); if (node->start < start) node = split_range(node, start); else { tmp = __mm_prev(node); if (tmp && tmp->refcnt == node->refcnt + inc) node = merge_ranges(node, tmp); } return node; } /* * This function is called if madvise() fails to undo merging/splitting * operations performed on the node. */ static struct ibv_mem_node *undo_node(struct ibv_mem_node *node, uintptr_t start, int inc) { struct ibv_mem_node *tmp = NULL; /* * This condition can be true only if we merged this * node with the previous one, so we need to split them. */ if (start > node->start) { tmp = split_range(node, start); if (tmp) { node->refcnt += inc; node = tmp; } else return NULL; } tmp = __mm_prev(node); if (tmp && tmp->refcnt == node->refcnt) node = merge_ranges(node, tmp); tmp = __mm_next(node); if (tmp && tmp->refcnt == node->refcnt) node = merge_ranges(tmp, node); return node; } static int do_madvise(void *addr, size_t length, int advice, unsigned long range_page_size) { int ret; void *p; ret = madvise(addr, length, advice); if (!ret || advice == MADV_DONTFORK) return ret; if (length > range_page_size) { /* if MADV_DOFORK failed we will try to remove VM_DONTCOPY * flag from each page */ for (p = addr; p < addr + length; p += range_page_size) madvise(p, range_page_size, MADV_DOFORK); } return 0; } static int ibv_madvise_range(void *base, size_t size, int advice) { uintptr_t start, end; struct ibv_mem_node *node, *tmp; int inc; int rolling_back = 0; int ret = 0; unsigned long range_page_size; if (!size || !base) return 0; if (huge_page_enabled) range_page_size = get_page_size(base); else range_page_size = page_size; start = (uintptr_t) base & ~(range_page_size - 1); end = ((uintptr_t) (base + size + range_page_size - 1) & ~(range_page_size - 1)) - 1; pthread_mutex_lock(&mm_mutex); again: inc = advice == MADV_DONTFORK ? 1 : -1; node = get_start_node(start, end, inc); if (!node) { ret = -1; goto out; } while (node && node->start <= end) { if (node->end > end) { if (!split_range(node, end + 1)) { ret = -1; goto out; } } if ((inc == -1 && node->refcnt == 1) || (inc == 1 && node->refcnt == 0)) { /* * If this is the first time through the loop, * and we merged this node with the previous * one, then we only want to do the madvise() * on start ... node->end (rather than * starting at node->start). * * Otherwise we end up doing madvise() on * bigger region than we're being asked to, * and that may lead to a spurious failure. */ if (start > node->start) ret = do_madvise((void *) start, node->end - start + 1, advice, range_page_size); else ret = do_madvise((void *) node->start, node->end - node->start + 1, advice, range_page_size); if (ret) { node = undo_node(node, start, inc); if (rolling_back || !node) goto out; /* madvise failed, roll back previous changes */ rolling_back = 1; advice = advice == MADV_DONTFORK ? MADV_DOFORK : MADV_DONTFORK; end = node->end; goto again; } } node->refcnt += inc; node = __mm_next(node); } if (node) { tmp = __mm_prev(node); if (tmp && node->refcnt == tmp->refcnt) node = merge_ranges(node, tmp); } out: if (rolling_back) ret = -1; pthread_mutex_unlock(&mm_mutex); return ret; } int ibv_dontfork_range(void *base, size_t size) { if (mm_root) return ibv_madvise_range(base, size, MADV_DONTFORK); else { too_late = 1; return 0; } } int ibv_dofork_range(void *base, size_t size) { if (mm_root) return ibv_madvise_range(base, size, MADV_DOFORK); else { too_late = 1; return 0; } }