/* $OpenBSD: uvm_addr.c,v 1.30 2021/03/20 10:24:21 mpi Exp $ */ /* * Copyright (c) 2011 Ariane van der Steldt * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ /* #define DEBUG */ #include #include #include #include #include /* Max gap between hint allocations. */ #define UADDR_HINT_MAXGAP (4 * PAGE_SIZE) /* Number of pivots in pivot allocator. */ #define NUM_PIVOTS 16 /* * Max number (inclusive) of pages the pivot allocator * will place between allocations. * * The uaddr_pivot_random() function attempts to bias towards * small space between allocations, so putting a large number here is fine. */ #define PIVOT_RND 8 /* * Number of allocations that a pivot can supply before expiring. * When a pivot expires, a new pivot has to be found. * * Must be at least 1. */ #define PIVOT_EXPIRE 1024 /* Pool with uvm_addr_state structures. */ struct pool uaddr_pool; struct pool uaddr_bestfit_pool; struct pool uaddr_pivot_pool; struct pool uaddr_rnd_pool; /* uvm_addr state for bestfit selector. */ struct uaddr_bestfit_state { struct uvm_addr_state ubf_uaddr; struct uaddr_free_rbtree ubf_free; }; /* uvm_addr state for rnd selector. */ struct uaddr_rnd_state { struct uvm_addr_state ur_uaddr; #if 0 TAILQ_HEAD(, vm_map_entry) ur_free; #endif }; /* * Definition of a pivot in pivot selector. */ struct uaddr_pivot { vaddr_t addr; /* End of prev. allocation. */ int expire;/* Best before date. */ int dir; /* Direction. */ struct vm_map_entry *entry; /* Will contain next alloc. */ }; /* uvm_addr state for pivot selector. */ struct uaddr_pivot_state { struct uvm_addr_state up_uaddr; /* Free space tree, for fast pivot selection. */ struct uaddr_free_rbtree up_free; /* List of pivots. The pointers point to after the last allocation. */ struct uaddr_pivot up_pivots[NUM_PIVOTS]; }; /* Forward declaration (see below). */ extern const struct uvm_addr_functions uaddr_kernel_functions; struct uvm_addr_state uaddr_kbootstrap; /* * Support functions. */ #ifndef SMALL_KERNEL struct vm_map_entry *uvm_addr_entrybyspace(struct uaddr_free_rbtree*, vsize_t); #endif /* !SMALL_KERNEL */ void uaddr_kinsert(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry *); void uaddr_kremove(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry *); void uaddr_kbootstrapdestroy(struct uvm_addr_state *); void uaddr_destroy(struct uvm_addr_state *); void uaddr_kbootstrap_destroy(struct uvm_addr_state *); void uaddr_rnd_destroy(struct uvm_addr_state *); void uaddr_bestfit_destroy(struct uvm_addr_state *); void uaddr_pivot_destroy(struct uvm_addr_state *); #if 0 int uaddr_lin_select(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry **, vaddr_t *, vsize_t, vaddr_t, vaddr_t, vm_prot_t, vaddr_t); #endif int uaddr_kbootstrap_select(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry **, vaddr_t *, vsize_t, vaddr_t, vaddr_t, vm_prot_t, vaddr_t); int uaddr_rnd_select(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry **, vaddr_t *, vsize_t, vaddr_t, vaddr_t, vm_prot_t, vaddr_t); int uaddr_bestfit_select(struct vm_map *, struct uvm_addr_state*, struct vm_map_entry **, vaddr_t *, vsize_t, vaddr_t, vaddr_t, vm_prot_t, vaddr_t); #ifndef SMALL_KERNEL int uaddr_pivot_select(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry **, vaddr_t *, vsize_t, vaddr_t, vaddr_t, vm_prot_t, vaddr_t); int uaddr_stack_brk_select(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry **, vaddr_t *, vsize_t, vaddr_t, vaddr_t, vm_prot_t, vaddr_t); #endif /* !SMALL_KERNEL */ void uaddr_rnd_insert(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry *); void uaddr_rnd_remove(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry *); void uaddr_bestfit_insert(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry *); void uaddr_bestfit_remove(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry *); void uaddr_pivot_insert(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry *); void uaddr_pivot_remove(struct vm_map *, struct uvm_addr_state *, struct vm_map_entry *); #ifndef SMALL_KERNEL vsize_t uaddr_pivot_random(void); int uaddr_pivot_newpivot(struct vm_map *, struct uaddr_pivot_state *, struct uaddr_pivot *, struct vm_map_entry **, vaddr_t *, vsize_t, vaddr_t, vaddr_t, vsize_t, vsize_t); #endif /* !SMALL_KERNEL */ #if defined(DEBUG) || defined(DDB) void uaddr_pivot_print(struct uvm_addr_state *, boolean_t, int (*)(const char *, ...)); #if 0 void uaddr_rnd_print(struct uvm_addr_state *, boolean_t, int (*)(const char *, ...)); #endif #endif /* DEBUG || DDB */ #ifndef SMALL_KERNEL /* * Find smallest entry in tree that will fit sz bytes. */ struct vm_map_entry * uvm_addr_entrybyspace(struct uaddr_free_rbtree *free, vsize_t sz) { struct vm_map_entry *tmp, *res; tmp = RBT_ROOT(uaddr_free_rbtree, free); res = NULL; while (tmp) { if (tmp->fspace >= sz) { res = tmp; tmp = RBT_LEFT(uaddr_free_rbtree, tmp); } else if (tmp->fspace < sz) tmp = RBT_RIGHT(uaddr_free_rbtree, tmp); } return res; } #endif /* !SMALL_KERNEL */ static inline vaddr_t uvm_addr_align_forward(vaddr_t addr, vaddr_t align, vaddr_t offset) { vaddr_t adjusted; KASSERT(offset < align || (align == 0 && offset == 0)); KASSERT((align & (align - 1)) == 0); KASSERT((offset & PAGE_MASK) == 0); align = MAX(align, PAGE_SIZE); adjusted = addr & ~(align - 1); adjusted += offset; return (adjusted < addr ? adjusted + align : adjusted); } static inline vaddr_t uvm_addr_align_backward(vaddr_t addr, vaddr_t align, vaddr_t offset) { vaddr_t adjusted; KASSERT(offset < align || (align == 0 && offset == 0)); KASSERT((align & (align - 1)) == 0); KASSERT((offset & PAGE_MASK) == 0); align = MAX(align, PAGE_SIZE); adjusted = addr & ~(align - 1); adjusted += offset; return (adjusted > addr ? adjusted - align : adjusted); } /* * Try to fit the requested space into the entry. */ int uvm_addr_fitspace(vaddr_t *min_result, vaddr_t *max_result, vaddr_t low_addr, vaddr_t high_addr, vsize_t sz, vaddr_t align, vaddr_t offset, vsize_t before_gap, vsize_t after_gap) { vaddr_t tmp; vsize_t fspace; if (low_addr > high_addr) return ENOMEM; fspace = high_addr - low_addr; if (fspace < before_gap + after_gap) return ENOMEM; if (fspace - before_gap - after_gap < sz) return ENOMEM; /* * Calculate lowest address. */ low_addr += before_gap; low_addr = uvm_addr_align_forward(tmp = low_addr, align, offset); if (low_addr < tmp) /* Overflow during alignment. */ return ENOMEM; if (high_addr - after_gap - sz < low_addr) return ENOMEM; /* * Calculate highest address. */ high_addr -= after_gap + sz; high_addr = uvm_addr_align_backward(tmp = high_addr, align, offset); if (high_addr > tmp) /* Overflow during alignment. */ return ENOMEM; if (low_addr > high_addr) return ENOMEM; *min_result = low_addr; *max_result = high_addr; return 0; } /* * Initialize uvm_addr. */ void uvm_addr_init(void) { pool_init(&uaddr_pool, sizeof(struct uvm_addr_state), 0, IPL_VM, PR_WAITOK, "uaddr", NULL); pool_init(&uaddr_bestfit_pool, sizeof(struct uaddr_bestfit_state), 0, IPL_VM, PR_WAITOK, "uaddrbest", NULL); pool_init(&uaddr_pivot_pool, sizeof(struct uaddr_pivot_state), 0, IPL_VM, PR_WAITOK, "uaddrpivot", NULL); pool_init(&uaddr_rnd_pool, sizeof(struct uaddr_rnd_state), 0, IPL_VM, PR_WAITOK, "uaddrrnd", NULL); uaddr_kbootstrap.uaddr_minaddr = PAGE_SIZE; uaddr_kbootstrap.uaddr_maxaddr = -(vaddr_t)PAGE_SIZE; uaddr_kbootstrap.uaddr_functions = &uaddr_kernel_functions; } /* * Invoke destructor function of uaddr. */ void uvm_addr_destroy(struct uvm_addr_state *uaddr) { if (uaddr) (*uaddr->uaddr_functions->uaddr_destroy)(uaddr); } /* * Move address forward to satisfy align, offset. */ vaddr_t uvm_addr_align(vaddr_t addr, vaddr_t align, vaddr_t offset) { vaddr_t result = (addr & ~(align - 1)) + offset; if (result < addr) result += align; return result; } /* * Move address backwards to satisfy align, offset. */ vaddr_t uvm_addr_align_back(vaddr_t addr, vaddr_t align, vaddr_t offset) { vaddr_t result = (addr & ~(align - 1)) + offset; if (result > addr) result -= align; return result; } /* * Directional first fit. * * Do a linear search for free space, starting at addr in entry. * direction == 1: search forward * direction == -1: search backward * * Output: low <= addr <= high and entry will contain addr. * 0 will be returned if no space is available. * * gap describes the space that must appear between the preceding entry. */ int uvm_addr_linsearch(struct vm_map *map, struct uvm_addr_state *uaddr, struct vm_map_entry **entry_out, vaddr_t *addr_out, vaddr_t hint, vsize_t sz, vaddr_t align, vaddr_t offset, int direction, vaddr_t low, vaddr_t high, vsize_t before_gap, vsize_t after_gap) { struct vm_map_entry *entry; vaddr_t low_addr, high_addr; KASSERT(entry_out != NULL && addr_out != NULL); KASSERT(direction == -1 || direction == 1); KASSERT((hint & PAGE_MASK) == 0 && (high & PAGE_MASK) == 0 && (low & PAGE_MASK) == 0 && (before_gap & PAGE_MASK) == 0 && (after_gap & PAGE_MASK) == 0); KASSERT(high + sz > high); /* Check for overflow. */ /* * Hint magic. */ if (hint == 0) hint = (direction == 1 ? low : high); else if (hint > high) { if (direction != -1) return ENOMEM; hint = high; } else if (hint < low) { if (direction != 1) return ENOMEM; hint = low; } for (entry = uvm_map_entrybyaddr(&map->addr, hint - (direction == -1 ? 1 : 0)); entry != NULL; entry = (direction == 1 ? RBT_NEXT(uvm_map_addr, entry) : RBT_PREV(uvm_map_addr, entry))) { if ((direction == 1 && VMMAP_FREE_START(entry) > high) || (direction == -1 && VMMAP_FREE_END(entry) < low)) { break; } if (uvm_addr_fitspace(&low_addr, &high_addr, MAX(low, VMMAP_FREE_START(entry)), MIN(high, VMMAP_FREE_END(entry)), sz, align, offset, before_gap, after_gap) == 0) { *entry_out = entry; if (hint >= low_addr && hint <= high_addr) { *addr_out = hint; } else { *addr_out = (direction == 1 ? low_addr : high_addr); } return 0; } } return ENOMEM; } /* * Invoke address selector of uaddr. * uaddr may be NULL, in which case the algorithm will fail with ENOMEM. * * Will invoke uvm_addr_isavail to fill in last_out. */ int uvm_addr_invoke(struct vm_map *map, struct uvm_addr_state *uaddr, struct vm_map_entry **entry_out, struct vm_map_entry **last_out, vaddr_t *addr_out, vsize_t sz, vaddr_t align, vaddr_t offset, vm_prot_t prot, vaddr_t hint) { int error; if (uaddr == NULL) return ENOMEM; hint &= ~((vaddr_t)PAGE_MASK); if (hint != 0 && !(hint >= uaddr->uaddr_minaddr && hint < uaddr->uaddr_maxaddr)) return ENOMEM; error = (*uaddr->uaddr_functions->uaddr_select)(map, uaddr, entry_out, addr_out, sz, align, offset, prot, hint); if (error == 0) { KASSERT(*entry_out != NULL); *last_out = NULL; if (!uvm_map_isavail(map, uaddr, entry_out, last_out, *addr_out, sz)) { panic("uvm_addr_invoke: address selector %p " "(%s 0x%lx-0x%lx) " "returned unavailable address 0x%lx sz 0x%lx", uaddr, uaddr->uaddr_functions->uaddr_name, uaddr->uaddr_minaddr, uaddr->uaddr_maxaddr, *addr_out, sz); } } return error; } #if defined(DEBUG) || defined(DDB) void uvm_addr_print(struct uvm_addr_state *uaddr, const char *slot, boolean_t full, int (*pr)(const char *, ...)) { if (uaddr == NULL) { (*pr)("- uvm_addr %s: NULL\n", slot); return; } (*pr)("- uvm_addr %s: %p (%s 0x%lx-0x%lx)\n", slot, uaddr, uaddr->uaddr_functions->uaddr_name, uaddr->uaddr_minaddr, uaddr->uaddr_maxaddr); if (uaddr->uaddr_functions->uaddr_print == NULL) return; (*uaddr->uaddr_functions->uaddr_print)(uaddr, full, pr); } #endif /* DEBUG || DDB */ /* * Destroy a uvm_addr_state structure. * The uaddr must have been previously allocated from uaddr_state_pool. */ void uaddr_destroy(struct uvm_addr_state *uaddr) { pool_put(&uaddr_pool, uaddr); } #if 0 /* * Linear allocator. * This allocator uses a first-fit algorithm. * * If hint is set, search will start at the hint position. * Only searches forward. */ const struct uvm_addr_functions uaddr_lin_functions = { .uaddr_select = &uaddr_lin_select, .uaddr_destroy = &uaddr_destroy, .uaddr_name = "uaddr_lin" }; struct uvm_addr_state * uaddr_lin_create(vaddr_t minaddr, vaddr_t maxaddr) { struct uvm_addr_state *uaddr; uaddr = pool_get(&uaddr_pool, PR_WAITOK); uaddr->uaddr_minaddr = minaddr; uaddr->uaddr_maxaddr = maxaddr; uaddr->uaddr_functions = &uaddr_lin_functions; return uaddr; } int uaddr_lin_select(struct vm_map *map, struct uvm_addr_state *uaddr, struct vm_map_entry **entry_out, vaddr_t *addr_out, vsize_t sz, vaddr_t align, vaddr_t offset, vm_prot_t prot, vaddr_t hint) { vaddr_t guard_sz; /* * Deal with guardpages: search for space with one extra page. */ guard_sz = ((map->flags & VM_MAP_GUARDPAGES) == 0 ? 0 : PAGE_SIZE); if (uaddr->uaddr_maxaddr - uaddr->uaddr_minaddr - guard_sz < sz) return ENOMEM; return uvm_addr_linsearch(map, uaddr, entry_out, addr_out, 0, sz, align, offset, 1, uaddr->uaddr_minaddr, uaddr->uaddr_maxaddr - sz, 0, guard_sz); } #endif /* * Randomized allocator. * This allocator use uvm_map_hint to acquire a random address and searches * from there. */ const struct uvm_addr_functions uaddr_rnd_functions = { .uaddr_select = &uaddr_rnd_select, .uaddr_free_insert = &uaddr_rnd_insert, .uaddr_free_remove = &uaddr_rnd_remove, .uaddr_destroy = &uaddr_rnd_destroy, #if defined(DEBUG) || defined(DDB) #if 0 .uaddr_print = &uaddr_rnd_print, #endif #endif /* DEBUG || DDB */ .uaddr_name = "uaddr_rnd" }; struct uvm_addr_state * uaddr_rnd_create(vaddr_t minaddr, vaddr_t maxaddr) { struct uaddr_rnd_state *uaddr; uaddr = pool_get(&uaddr_rnd_pool, PR_WAITOK); uaddr->ur_uaddr.uaddr_minaddr = minaddr; uaddr->ur_uaddr.uaddr_maxaddr = maxaddr; uaddr->ur_uaddr.uaddr_functions = &uaddr_rnd_functions; #if 0 TAILQ_INIT(&uaddr->ur_free); #endif return &uaddr->ur_uaddr; } int uaddr_rnd_select(struct vm_map *map, struct uvm_addr_state *uaddr, struct vm_map_entry **entry_out, vaddr_t *addr_out, vsize_t sz, vaddr_t align, vaddr_t offset, vm_prot_t prot, vaddr_t hint) { struct vmspace *vm; vaddr_t minaddr, maxaddr; vaddr_t guard_sz; vaddr_t low_addr, high_addr; struct vm_map_entry *entry, *next; vsize_t before_gap, after_gap; vaddr_t tmp; KASSERT((map->flags & VM_MAP_ISVMSPACE) != 0); vm = (struct vmspace *)map; /* Deal with guardpages: search for space with one extra page. */ guard_sz = ((map->flags & VM_MAP_GUARDPAGES) == 0 ? 0 : PAGE_SIZE); if (uaddr->uaddr_maxaddr - guard_sz < sz) return ENOMEM; minaddr = uvm_addr_align_forward(uaddr->uaddr_minaddr, align, offset); maxaddr = uvm_addr_align_backward(uaddr->uaddr_maxaddr - sz - guard_sz, align, offset); /* Quick fail if the allocation won't fit. */ if (minaddr >= maxaddr) return ENOMEM; /* Select a hint. */ if (hint == 0) hint = uvm_map_hint(vm, prot, minaddr, maxaddr); /* Clamp hint to uaddr range. */ hint = MIN(MAX(hint, minaddr), maxaddr); /* Align hint to align,offset parameters. */ tmp = hint; hint = uvm_addr_align_forward(tmp, align, offset); /* Check for overflow during alignment. */ if (hint < tmp || hint > maxaddr) return ENOMEM; /* Compatibility mode: never look backwards. */ before_gap = 0; after_gap = guard_sz; hint -= MIN(hint, before_gap); /* * Use the augmented address tree to look up the first entry * at or after hint with sufficient space. * * This code is the original optimized code, but will fail if the * subtree it looks at does have sufficient space, but fails to meet * the align constraint. * * Guard: subtree is not exhausted and max(fspace) >= required. */ entry = uvm_map_entrybyaddr(&map->addr, hint); /* Walk up the tree, until there is at least sufficient space. */ while (entry != NULL && entry->fspace_augment < before_gap + after_gap + sz) entry = RBT_PARENT(uvm_map_addr, entry); while (entry != NULL) { /* Test if this fits. */ if (VMMAP_FREE_END(entry) > hint && uvm_map_uaddr_e(map, entry) == uaddr && uvm_addr_fitspace(&low_addr, &high_addr, MAX(uaddr->uaddr_minaddr, VMMAP_FREE_START(entry)), MIN(uaddr->uaddr_maxaddr, VMMAP_FREE_END(entry)), sz, align, offset, before_gap, after_gap) == 0) { *entry_out = entry; if (hint >= low_addr && hint <= high_addr) *addr_out = hint; else *addr_out = low_addr; return 0; } /* RBT_NEXT, but skip subtrees that cannot possible fit. */ next = RBT_RIGHT(uvm_map_addr, entry); if (next != NULL && next->fspace_augment >= before_gap + after_gap + sz) { entry = next; while ((next = RBT_LEFT(uvm_map_addr, entry)) != NULL) entry = next; } else { do_parent: next = RBT_PARENT(uvm_map_addr, entry); if (next == NULL) entry = NULL; else if (RBT_LEFT(uvm_map_addr, next) == entry) entry = next; else { entry = next; goto do_parent; } } } /* Lookup failed. */ return ENOMEM; } /* * Destroy a uaddr_rnd_state structure. */ void uaddr_rnd_destroy(struct uvm_addr_state *uaddr) { pool_put(&uaddr_rnd_pool, uaddr); } /* * Add entry to tailq. */ void uaddr_rnd_insert(struct vm_map *map, struct uvm_addr_state *uaddr_p, struct vm_map_entry *entry) { return; } /* * Remove entry from tailq. */ void uaddr_rnd_remove(struct vm_map *map, struct uvm_addr_state *uaddr_p, struct vm_map_entry *entry) { return; } #if 0 #if defined(DEBUG) || defined(DDB) void uaddr_rnd_print(struct uvm_addr_state *uaddr_p, boolean_t full, int (*pr)(const char*, ...)) { struct vm_map_entry *entry; struct uaddr_rnd_state *uaddr; vaddr_t addr; size_t count; vsize_t space; uaddr = (struct uaddr_rnd_state *)uaddr_p; addr = 0; count = 0; space = 0; TAILQ_FOREACH(entry, &uaddr->ur_free, dfree.tailq) { count++; space += entry->fspace; if (full) { (*pr)("\tentry %p: 0x%lx-0x%lx G=0x%lx F=0x%lx\n", entry, entry->start, entry->end, entry->guard, entry->fspace); (*pr)("\t\tfree: 0x%lx-0x%lx\n", VMMAP_FREE_START(entry), VMMAP_FREE_END(entry)); } if (entry->start < addr) { if (!full) (*pr)("\tentry %p: 0x%lx-0x%lx " "G=0x%lx F=0x%lx\n", entry, entry->start, entry->end, entry->guard, entry->fspace); (*pr)("\t\tstart=0x%lx, expected at least 0x%lx\n", entry->start, addr); } addr = VMMAP_FREE_END(entry); } (*pr)("\t0x%lu entries, 0x%lx free bytes\n", count, space); } #endif /* DEBUG || DDB */ #endif /* * Kernel allocation bootstrap logic. */ const struct uvm_addr_functions uaddr_kernel_functions = { .uaddr_select = &uaddr_kbootstrap_select, .uaddr_destroy = &uaddr_kbootstrap_destroy, .uaddr_name = "uaddr_kbootstrap" }; /* * Select an address from the map. * * This function ignores the uaddr spec and instead uses the map directly. * Because of that property, the uaddr algorithm can be shared across all * kernel maps. */ int uaddr_kbootstrap_select(struct vm_map *map, struct uvm_addr_state *uaddr, struct vm_map_entry **entry_out, vaddr_t *addr_out, vsize_t sz, vaddr_t align, vaddr_t offset, vm_prot_t prot, vaddr_t hint) { vaddr_t tmp; RBT_FOREACH(*entry_out, uvm_map_addr, &map->addr) { if (VMMAP_FREE_END(*entry_out) <= uvm_maxkaddr && uvm_addr_fitspace(addr_out, &tmp, VMMAP_FREE_START(*entry_out), VMMAP_FREE_END(*entry_out), sz, align, offset, 0, 0) == 0) return 0; } return ENOMEM; } /* * Don't destroy the kernel bootstrap allocator. */ void uaddr_kbootstrap_destroy(struct uvm_addr_state *uaddr) { KASSERT(uaddr == (struct uvm_addr_state *)&uaddr_kbootstrap); } #ifndef SMALL_KERNEL /* * Best fit algorithm. */ const struct uvm_addr_functions uaddr_bestfit_functions = { .uaddr_select = &uaddr_bestfit_select, .uaddr_free_insert = &uaddr_bestfit_insert, .uaddr_free_remove = &uaddr_bestfit_remove, .uaddr_destroy = &uaddr_bestfit_destroy, .uaddr_name = "uaddr_bestfit" }; struct uvm_addr_state * uaddr_bestfit_create(vaddr_t minaddr, vaddr_t maxaddr) { struct uaddr_bestfit_state *uaddr; uaddr = pool_get(&uaddr_bestfit_pool, PR_WAITOK); uaddr->ubf_uaddr.uaddr_minaddr = minaddr; uaddr->ubf_uaddr.uaddr_maxaddr = maxaddr; uaddr->ubf_uaddr.uaddr_functions = &uaddr_bestfit_functions; RBT_INIT(uaddr_free_rbtree, &uaddr->ubf_free); return &uaddr->ubf_uaddr; } void uaddr_bestfit_destroy(struct uvm_addr_state *uaddr) { pool_put(&uaddr_bestfit_pool, uaddr); } void uaddr_bestfit_insert(struct vm_map *map, struct uvm_addr_state *uaddr_p, struct vm_map_entry *entry) { struct uaddr_bestfit_state *uaddr; struct vm_map_entry *rb_rv; uaddr = (struct uaddr_bestfit_state *)uaddr_p; if ((rb_rv = RBT_INSERT(uaddr_free_rbtree, &uaddr->ubf_free, entry)) != NULL) { panic("%s: duplicate insertion: state %p " "interting %p, colliding with %p", __func__, uaddr, entry, rb_rv); } } void uaddr_bestfit_remove(struct vm_map *map, struct uvm_addr_state *uaddr_p, struct vm_map_entry *entry) { struct uaddr_bestfit_state *uaddr; uaddr = (struct uaddr_bestfit_state *)uaddr_p; if (RBT_REMOVE(uaddr_free_rbtree, &uaddr->ubf_free, entry) != entry) panic("%s: entry was not in tree", __func__); } int uaddr_bestfit_select(struct vm_map *map, struct uvm_addr_state *uaddr_p, struct vm_map_entry **entry_out, vaddr_t *addr_out, vsize_t sz, vaddr_t align, vaddr_t offset, vm_prot_t prot, vaddr_t hint) { vaddr_t min, max; struct uaddr_bestfit_state *uaddr; struct vm_map_entry *entry; vsize_t guardsz; uaddr = (struct uaddr_bestfit_state *)uaddr_p; guardsz = ((map->flags & VM_MAP_GUARDPAGES) ? PAGE_SIZE : 0); if (sz + guardsz < sz) return ENOMEM; /* * Find smallest item on freelist capable of holding item. * Deal with guardpages: search for space with one extra page. */ entry = uvm_addr_entrybyspace(&uaddr->ubf_free, sz + guardsz); if (entry == NULL) return ENOMEM; /* * Walk the tree until we find an entry that fits. */ while (uvm_addr_fitspace(&min, &max, VMMAP_FREE_START(entry), VMMAP_FREE_END(entry), sz, align, offset, 0, guardsz) != 0) { entry = RBT_NEXT(uaddr_free_rbtree, entry); if (entry == NULL) return ENOMEM; } /* * Return the address that generates the least fragmentation. */ *entry_out = entry; *addr_out = (min - VMMAP_FREE_START(entry) <= VMMAP_FREE_END(entry) - guardsz - sz - max ? min : max); return 0; } #endif /* !SMALL_KERNEL */ #ifndef SMALL_KERNEL /* * A userspace allocator based on pivots. */ const struct uvm_addr_functions uaddr_pivot_functions = { .uaddr_select = &uaddr_pivot_select, .uaddr_free_insert = &uaddr_pivot_insert, .uaddr_free_remove = &uaddr_pivot_remove, .uaddr_destroy = &uaddr_pivot_destroy, #if defined(DEBUG) || defined(DDB) .uaddr_print = &uaddr_pivot_print, #endif /* DEBUG || DDB */ .uaddr_name = "uaddr_pivot" }; /* * A special random function for pivots. * * This function will return: * - a random number * - a multiple of PAGE_SIZE * - at least PAGE_SIZE * * The random function has a slightly higher change to return a small number. */ vsize_t uaddr_pivot_random(void) { int r; /* * The sum of two six-sided dice will have a normal distribution. * We map the highest probable number to 1, by folding the curve * (think of a graph on a piece of paper, that you fold). * * Because the fold happens at PIVOT_RND - 1, the numbers 0 and 1 * have the same and highest probability of happening. */ r = arc4random_uniform(PIVOT_RND) + arc4random_uniform(PIVOT_RND) - (PIVOT_RND - 1); if (r < 0) r = -r; /* * Make the returned value at least PAGE_SIZE and a multiple of * PAGE_SIZE. */ return (vaddr_t)(1 + r) << PAGE_SHIFT; } /* * Select a new pivot. * * A pivot must: * - be chosen random * - have a randomly chosen gap before it, where the uaddr_state starts * - have a randomly chosen gap after it, before the uaddr_state ends * * Furthermore, the pivot must provide sufficient space for the allocation. * The addr will be set to the selected address. * * Returns ENOMEM on failure. */ int uaddr_pivot_newpivot(struct vm_map *map, struct uaddr_pivot_state *uaddr, struct uaddr_pivot *pivot, struct vm_map_entry **entry_out, vaddr_t *addr_out, vsize_t sz, vaddr_t align, vaddr_t offset, vsize_t before_gap, vsize_t after_gap) { struct vm_map_entry *entry, *found; vaddr_t minaddr, maxaddr; vsize_t dist; vaddr_t found_minaddr, found_maxaddr; vaddr_t min, max; vsize_t arc4_arg; int fit_error; u_int32_t path; minaddr = uaddr->up_uaddr.uaddr_minaddr; maxaddr = uaddr->up_uaddr.uaddr_maxaddr; KASSERT(minaddr < maxaddr); #ifdef DIAGNOSTIC if (minaddr + 2 * PAGE_SIZE > maxaddr) { panic("uaddr_pivot_newpivot: cannot grant random pivot " "in area less than 2 pages (size = 0x%lx)", maxaddr - minaddr); } #endif /* DIAGNOSTIC */ /* * Gap calculation: 1/32 of the size of the managed area. * * At most: sufficient to not get truncated at arc4random. * At least: 2 PAGE_SIZE * * minaddr and maxaddr will be changed according to arc4random. */ dist = MAX((maxaddr - minaddr) / 32, 2 * (vaddr_t)PAGE_SIZE); if (dist >> PAGE_SHIFT > 0xffffffff) { minaddr += (vsize_t)arc4random() << PAGE_SHIFT; maxaddr -= (vsize_t)arc4random() << PAGE_SHIFT; } else { minaddr += (vsize_t)arc4random_uniform(dist >> PAGE_SHIFT) << PAGE_SHIFT; maxaddr -= (vsize_t)arc4random_uniform(dist >> PAGE_SHIFT) << PAGE_SHIFT; } /* * A very fast way to find an entry that will be large enough * to hold the allocation, but still is found more or less * randomly: the tree path selector has a 50% chance to go for * a bigger or smaller entry. * * Note that the memory may actually be available, * but the fragmentation may be so bad and the gaps chosen * so unfortunately, that the allocation will not succeed. * Or the alignment can only be satisfied by an entry that * is not visited in the randomly selected path. * * This code finds an entry with sufficient space in O(log n) time. */ path = arc4random(); found = NULL; entry = RBT_ROOT(uaddr_free_rbtree, &uaddr->up_free); while (entry != NULL) { fit_error = uvm_addr_fitspace(&min, &max, MAX(VMMAP_FREE_START(entry), minaddr), MIN(VMMAP_FREE_END(entry), maxaddr), sz, align, offset, before_gap, after_gap); /* It fits, save this entry. */ if (fit_error == 0) { found = entry; found_minaddr = min; found_maxaddr = max; } /* Next. */ if (fit_error != 0) entry = RBT_RIGHT(uaddr_free_rbtree, entry); else if ((path & 0x1) == 0) { path >>= 1; entry = RBT_RIGHT(uaddr_free_rbtree, entry); } else { path >>= 1; entry = RBT_LEFT(uaddr_free_rbtree, entry); } } if (found == NULL) return ENOMEM; /* Not found a large enough region. */ /* * Calculate a random address within found. * * found_minaddr and found_maxaddr are already aligned, so be sure * to select a multiple of align as the offset in the entry. * Preferably, arc4random_uniform is used to provide no bias within * the entry. * However if the size of the entry exceeds arc4random_uniforms * argument limit, we simply use arc4random (thus limiting ourselves * to 4G * PAGE_SIZE bytes offset). */ if (found_maxaddr == found_minaddr) *addr_out = found_minaddr; else { KASSERT(align >= PAGE_SIZE && (align & (align - 1)) == 0); arc4_arg = found_maxaddr - found_minaddr; if (arc4_arg > 0xffffffff) { *addr_out = found_minaddr + (arc4random() & ~(align - 1)); } else { *addr_out = found_minaddr + (arc4random_uniform(arc4_arg) & ~(align - 1)); } } /* Address was found in this entry. */ *entry_out = found; /* * Set up new pivot and return selected address. * * Depending on the direction of the pivot, the pivot must be placed * at the bottom or the top of the allocation: * - if the pivot moves upwards, place the pivot at the top of the * allocation, * - if the pivot moves downwards, place the pivot at the bottom * of the allocation. */ pivot->entry = found; pivot->dir = (arc4random() & 0x1 ? 1 : -1); if (pivot->dir > 0) pivot->addr = *addr_out + sz; else pivot->addr = *addr_out; pivot->expire = PIVOT_EXPIRE - 1; /* First use is right now. */ return 0; } /* * Pivot selector. * * Each time the selector is invoked, it will select a random pivot, which * it will use to select memory with. The memory will be placed at the pivot, * with a randomly sized gap between the allocation and the pivot. * The pivot will then move so it will never revisit this address. * * Each allocation, the pivot expiry timer ticks. Once the pivot becomes * expired, it will be replaced with a newly created pivot. Pivots also * automatically expire if they fail to provide memory for an allocation. * * Expired pivots are replaced using the uaddr_pivot_newpivot() function, * which will ensure the pivot points at memory in such a way that the * allocation will succeed. * As an added bonus, the uaddr_pivot_newpivot() function will perform the * allocation immediately and move the pivot as appropriate. * * If uaddr_pivot_newpivot() fails to find a new pivot that will allow the * allocation to succeed, it will not create a new pivot and the allocation * will fail. * * A pivot running into used memory will automatically expire (because it will * fail to allocate). * * Characteristics of the allocator: * - best case, an allocation is O(log N) * (it would be O(1), if it werent for the need to check if the memory is * free; although that can be avoided...) * - worst case, an allocation is O(log N) * (the uaddr_pivot_newpivot() function has that complexity) * - failed allocations always take O(log N) * (the uaddr_pivot_newpivot() function will walk that deep into the tree). */ int uaddr_pivot_select(struct vm_map *map, struct uvm_addr_state *uaddr_p, struct vm_map_entry **entry_out, vaddr_t *addr_out, vsize_t sz, vaddr_t align, vaddr_t offset, vm_prot_t prot, vaddr_t hint) { struct uaddr_pivot_state *uaddr; struct vm_map_entry *entry; struct uaddr_pivot *pivot; vaddr_t min, max; vsize_t before_gap, after_gap; int err; /* * When we have a hint, use the rnd allocator that finds the * area that is closest to the hint, if there is such an area. */ if (hint != 0) { if (uaddr_rnd_select(map, uaddr_p, entry_out, addr_out, sz, align, offset, prot, hint) == 0) return 0; return ENOMEM; } /* * Select a random pivot and a random gap sizes around the allocation. */ uaddr = (struct uaddr_pivot_state *)uaddr_p; pivot = &uaddr->up_pivots[ arc4random_uniform(nitems(uaddr->up_pivots))]; before_gap = uaddr_pivot_random(); after_gap = uaddr_pivot_random(); if (pivot->addr == 0 || pivot->entry == NULL || pivot->expire == 0) goto expired; /* Pivot is invalid (null or expired). */ /* * Attempt to use the pivot to map the entry. */ entry = pivot->entry; if (pivot->dir > 0) { if (uvm_addr_fitspace(&min, &max, MAX(VMMAP_FREE_START(entry), pivot->addr), VMMAP_FREE_END(entry), sz, align, offset, before_gap, after_gap) == 0) { *addr_out = min; *entry_out = entry; pivot->addr = min + sz; pivot->expire--; return 0; } } else { if (uvm_addr_fitspace(&min, &max, VMMAP_FREE_START(entry), MIN(VMMAP_FREE_END(entry), pivot->addr), sz, align, offset, before_gap, after_gap) == 0) { *addr_out = max; *entry_out = entry; pivot->addr = max; pivot->expire--; return 0; } } expired: /* * Pivot expired or allocation failed. * Use pivot selector to do the allocation and find a new pivot. */ err = uaddr_pivot_newpivot(map, uaddr, pivot, entry_out, addr_out, sz, align, offset, before_gap, after_gap); return err; } /* * Free the pivot. */ void uaddr_pivot_destroy(struct uvm_addr_state *uaddr) { pool_put(&uaddr_pivot_pool, uaddr); } /* * Insert an entry with free space in the space tree. */ void uaddr_pivot_insert(struct vm_map *map, struct uvm_addr_state *uaddr_p, struct vm_map_entry *entry) { struct uaddr_pivot_state *uaddr; struct vm_map_entry *rb_rv; struct uaddr_pivot *p; vaddr_t check_addr; vaddr_t start, end; uaddr = (struct uaddr_pivot_state *)uaddr_p; if ((rb_rv = RBT_INSERT(uaddr_free_rbtree, &uaddr->up_free, entry)) != NULL) { panic("%s: duplicate insertion: state %p " "inserting entry %p which collides with %p", __func__, uaddr, entry, rb_rv); } start = VMMAP_FREE_START(entry); end = VMMAP_FREE_END(entry); /* * Update all pivots that are contained in this entry. */ for (p = &uaddr->up_pivots[0]; p != &uaddr->up_pivots[nitems(uaddr->up_pivots)]; p++) { check_addr = p->addr; if (check_addr == 0) continue; if (p->dir < 0) check_addr--; if (start <= check_addr && check_addr < end) { KASSERT(p->entry == NULL); p->entry = entry; } } } /* * Remove an entry with free space from the space tree. */ void uaddr_pivot_remove(struct vm_map *map, struct uvm_addr_state *uaddr_p, struct vm_map_entry *entry) { struct uaddr_pivot_state *uaddr; struct uaddr_pivot *p; uaddr = (struct uaddr_pivot_state *)uaddr_p; if (RBT_REMOVE(uaddr_free_rbtree, &uaddr->up_free, entry) != entry) panic("%s: entry was not in tree", __func__); /* * Inform any pivot with this entry that the entry is gone. * Note that this does not automatically invalidate the pivot. */ for (p = &uaddr->up_pivots[0]; p != &uaddr->up_pivots[nitems(uaddr->up_pivots)]; p++) { if (p->entry == entry) p->entry = NULL; } } /* * Create a new pivot selector. * * Initially, all pivots are in the expired state. * Two reasons for this: * - it means this allocator will not take a huge amount of time * - pivots select better on demand, because the pivot selection will be * affected by preceding allocations: * the next pivots will likely end up in different segments of free memory, * that was segmented by an earlier allocation; better spread. */ struct uvm_addr_state * uaddr_pivot_create(vaddr_t minaddr, vaddr_t maxaddr) { struct uaddr_pivot_state *uaddr; uaddr = pool_get(&uaddr_pivot_pool, PR_WAITOK); uaddr->up_uaddr.uaddr_minaddr = minaddr; uaddr->up_uaddr.uaddr_maxaddr = maxaddr; uaddr->up_uaddr.uaddr_functions = &uaddr_pivot_functions; RBT_INIT(uaddr_free_rbtree, &uaddr->up_free); memset(uaddr->up_pivots, 0, sizeof(uaddr->up_pivots)); return &uaddr->up_uaddr; } #if defined(DEBUG) || defined(DDB) /* * Print the uaddr_pivot_state. * * If full, a listing of all entries in the state will be provided. */ void uaddr_pivot_print(struct uvm_addr_state *uaddr_p, boolean_t full, int (*pr)(const char *, ...)) { struct uaddr_pivot_state *uaddr; struct uaddr_pivot *pivot; struct vm_map_entry *entry; int i; vaddr_t check_addr; uaddr = (struct uaddr_pivot_state *)uaddr_p; for (i = 0; i < NUM_PIVOTS; i++) { pivot = &uaddr->up_pivots[i]; (*pr)("\tpivot 0x%lx, epires in %d, direction %d\n", pivot->addr, pivot->expire, pivot->dir); } if (!full) return; if (RBT_EMPTY(uaddr_free_rbtree, &uaddr->up_free)) (*pr)("\tempty\n"); /* Print list of free space. */ RBT_FOREACH(entry, uaddr_free_rbtree, &uaddr->up_free) { (*pr)("\t0x%lx - 0x%lx free (0x%lx bytes)\n", VMMAP_FREE_START(entry), VMMAP_FREE_END(entry), VMMAP_FREE_END(entry) - VMMAP_FREE_START(entry)); for (i = 0; i < NUM_PIVOTS; i++) { pivot = &uaddr->up_pivots[i]; check_addr = pivot->addr; if (check_addr == 0) continue; if (pivot->dir < 0) check_addr--; if (VMMAP_FREE_START(entry) <= check_addr && check_addr < VMMAP_FREE_END(entry)) { (*pr)("\t\tcontains pivot %d (0x%lx)\n", i, pivot->addr); } } } } #endif /* DEBUG || DDB */ #endif /* !SMALL_KERNEL */ #ifndef SMALL_KERNEL /* * Stack/break allocator. * * Stack area is grown into in the opposite direction of the stack growth, * brk area is grown downward (because sbrk() grows upward). * * Both areas are grown into proportially: a weighted chance is used to * select which one (stack or brk area) to try. If the allocation fails, * the other one is tested. */ const struct uvm_addr_functions uaddr_stack_brk_functions = { .uaddr_select = &uaddr_stack_brk_select, .uaddr_destroy = &uaddr_destroy, .uaddr_name = "uaddr_stckbrk" }; /* * Stack/brk address selector. */ int uaddr_stack_brk_select(struct vm_map *map, struct uvm_addr_state *uaddr, struct vm_map_entry **entry_out, vaddr_t *addr_out, vsize_t sz, vaddr_t align, vaddr_t offset, vm_prot_t prot, vaddr_t hint) { vaddr_t start; vaddr_t end; vsize_t before_gap; vsize_t after_gap; int dir; /* Set up brk search strategy. */ start = MAX(map->b_start, uaddr->uaddr_minaddr); end = MIN(map->b_end, uaddr->uaddr_maxaddr); before_gap = 0; after_gap = 0; dir = -1; /* Opposite of brk() growth. */ if (end - start >= sz) { if (uvm_addr_linsearch(map, uaddr, entry_out, addr_out, 0, sz, align, offset, dir, start, end - sz, before_gap, after_gap) == 0) return 0; } /* Set up stack search strategy. */ start = MAX(map->s_start, uaddr->uaddr_minaddr); end = MIN(map->s_end, uaddr->uaddr_maxaddr); before_gap = ((arc4random() & 0x3) + 1) << PAGE_SHIFT; after_gap = ((arc4random() & 0x3) + 1) << PAGE_SHIFT; #ifdef MACHINE_STACK_GROWS_UP dir = -1; #else dir = 1; #endif if (end - start >= before_gap + after_gap && end - start - before_gap - after_gap >= sz) { if (uvm_addr_linsearch(map, uaddr, entry_out, addr_out, 0, sz, align, offset, dir, start, end - sz, before_gap, after_gap) == 0) return 0; } return ENOMEM; } struct uvm_addr_state * uaddr_stack_brk_create(vaddr_t minaddr, vaddr_t maxaddr) { struct uvm_addr_state* uaddr; uaddr = pool_get(&uaddr_pool, PR_WAITOK); uaddr->uaddr_minaddr = minaddr; uaddr->uaddr_maxaddr = maxaddr; uaddr->uaddr_functions = &uaddr_stack_brk_functions; return uaddr; } #endif /* !SMALL_KERNEL */ #ifndef SMALL_KERNEL /* * Free space comparison. * Compares smaller free-space before larger free-space. */ static inline int uvm_mapent_fspace_cmp(const struct vm_map_entry *e1, const struct vm_map_entry *e2) { if (e1->fspace != e2->fspace) return (e1->fspace < e2->fspace ? -1 : 1); return (e1->start < e2->start ? -1 : e1->start > e2->start); } RBT_GENERATE(uaddr_free_rbtree, vm_map_entry, dfree.rbtree, uvm_mapent_fspace_cmp); #endif /* !SMALL_KERNEL */