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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-07 15:24:08 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-07 15:24:08 +0000 |
commit | f449f278dd3c70e479a035f50a9bb817a9b433ba (patch) | |
tree | 8ca2bfb785dda9bb4d573acdf9b42aea9cd51383 /src/contrib/ucw | |
parent | Initial commit. (diff) | |
download | knot-f449f278dd3c70e479a035f50a9bb817a9b433ba.tar.xz knot-f449f278dd3c70e479a035f50a9bb817a9b433ba.zip |
Adding upstream version 3.2.6.upstream/3.2.6upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to '')
-rw-r--r-- | src/contrib/ucw/LICENSE | 1 | ||||
-rw-r--r-- | src/contrib/ucw/array-sort.h | 195 | ||||
-rw-r--r-- | src/contrib/ucw/binsearch.h | 50 | ||||
-rw-r--r-- | src/contrib/ucw/heap.c | 153 | ||||
-rw-r--r-- | src/contrib/ucw/heap.h | 46 | ||||
-rw-r--r-- | src/contrib/ucw/lists.c | 264 | ||||
-rw-r--r-- | src/contrib/ucw/lists.h | 74 | ||||
-rw-r--r-- | src/contrib/ucw/mempool.c | 323 | ||||
-rw-r--r-- | src/contrib/ucw/mempool.h | 124 |
9 files changed, 1230 insertions, 0 deletions
diff --git a/src/contrib/ucw/LICENSE b/src/contrib/ucw/LICENSE new file mode 100644 index 0000000..b463d57 --- /dev/null +++ b/src/contrib/ucw/LICENSE @@ -0,0 +1 @@ +../licenses/LGPL-2.0
\ No newline at end of file diff --git a/src/contrib/ucw/array-sort.h b/src/contrib/ucw/array-sort.h new file mode 100644 index 0000000..1ff1377 --- /dev/null +++ b/src/contrib/ucw/array-sort.h @@ -0,0 +1,195 @@ +/* + * UCW Library -- Universal Simple Array Sorter + * + * (c) 2003--2008 Martin Mares <mj@ucw.cz> + * + * This software may be freely distributed and used according to the terms + * of the GNU Lesser General Public License. + */ + +#pragma once + +#include "contrib/macros.h" + +/* + * This is not a normal header file, it's a generator of sorting + * routines. Each time you include it with parameters set in the + * corresponding preprocessor macros, it generates an array sorter + * with the parameters given. + * + * You might wonder why the heck do we implement our own array sorter + * instead of using qsort(). The primary reason is that qsort handles + * only continuous arrays, but we need to sort array-like data structures + * where the only way to access elements is by using an indexing macro. + * Besides that, we are more than 2 times faster. + * + * So much for advocacy, there are the parameters (those marked with [*] + * are mandatory): + * + * ASORT_PREFIX(x) [*] add a name prefix (used on all global names + * defined by the sorter) + * ASORT_KEY_TYPE [*] data type of a single array entry key + * ASORT_ELT(i) returns the key of i-th element; if this macro is not + * defined, the function gets a pointer to an array to be sorted + * ASORT_LT(x,y) x < y for ASORT_KEY_TYPE (default: "x<y") + * ASORT_SWAP(i,j) swap i-th and j-th element (default: assume _ELT + * is an l-value and swap just the keys) + * ASORT_THRESHOLD threshold for switching between quicksort and insertsort + * ASORT_EXTRA_ARGS extra arguments for the sort function (they are always + * visible in all the macros supplied above), starts with comma + * + * After including this file, a function ASORT_PREFIX(sort)(unsigned array_size) + * or ASORT_PREFIX(sort)(ASORT_KEY_TYPE *array, unsigned array_size) [if ASORT_ELT + * is not defined] is declared and all parameter macros are automatically + * undef'd. + */ + +#ifndef ASORT_LT +#define ASORT_LT(x,y) ((x) < (y)) +#endif + +#ifndef ASORT_SWAP +#define ASORT_SWAP(i,j) do { ASORT_KEY_TYPE tmp = ASORT_ELT(i); ASORT_ELT(i)=ASORT_ELT(j); ASORT_ELT(j)=tmp; } while (0) +#endif + +#ifndef ASORT_THRESHOLD +#define ASORT_THRESHOLD 8 /* Guesswork and experimentation */ +#endif + +#ifndef ASORT_EXTRA_ARGS +#define ASORT_EXTRA_ARGS +#endif + +#ifndef ASORT_ELT +#define ASORT_ARRAY_ARG ASORT_KEY_TYPE *array, +#define ASORT_ELT(i) array[i] +#else +#define ASORT_ARRAY_ARG +#endif + +/** + * The generated sorting function. If `ASORT_ELT` macro is not provided, the + * @ASORT_ARRAY_ARG is equal to `ASORT_KEY_TYPE *array` and is the array to be + * sorted. If the macro is provided, this parameter is omitted. In that case, + * you can sort global variables or pass your structure by @ASORT_EXTRA_ARGS. + **/ +static void ASORT_PREFIX(sort)(ASORT_ARRAY_ARG unsigned array_size ASORT_EXTRA_ARGS) +{ + struct stk { int l, r; } stack[8*sizeof(unsigned)]; + int l, r, left, right, m; + unsigned sp = 0; + ASORT_KEY_TYPE pivot; + + if (array_size <= 1) + return; + + /* QuickSort with optimizations a'la Sedgewick, but stop at ASORT_THRESHOLD */ + + left = 0; + right = array_size - 1; + for(;;) + { + l = left; + r = right; + m = (l+r)/2; + if (ASORT_LT(ASORT_ELT(m), ASORT_ELT(l))) + ASORT_SWAP(l,m); + if (ASORT_LT(ASORT_ELT(r), ASORT_ELT(m))) + { + ASORT_SWAP(m,r); + if (ASORT_LT(ASORT_ELT(m), ASORT_ELT(l))) + ASORT_SWAP(l,m); + } + pivot = ASORT_ELT(m); + do + { + while (ASORT_LT(ASORT_ELT(l), pivot)) + l++; + while (ASORT_LT(pivot, ASORT_ELT(r))) + r--; + if (l < r) + { + ASORT_SWAP(l,r); + l++; + r--; + } + else if (l == r) + { + l++; + r--; + } + } + while (l <= r); + if ((r - left) >= ASORT_THRESHOLD && (right - l) >= ASORT_THRESHOLD) + { + /* Both partitions ok => push the larger one */ + if ((r - left) > (right - l)) + { + stack[sp].l = left; + stack[sp].r = r; + left = l; + } + else + { + stack[sp].l = l; + stack[sp].r = right; + right = r; + } + sp++; + } + else if ((r - left) >= ASORT_THRESHOLD) + { + /* Left partition OK, right undersize */ + right = r; + } + else if ((right - l) >= ASORT_THRESHOLD) + { + /* Right partition OK, left undersize */ + left = l; + } + else + { + /* Both partitions undersize => pop */ + if (!sp) + break; + sp--; + left = stack[sp].l; + right = stack[sp].r; + } + } + + /* + * We have a partially sorted array, finish by insertsort. Inspired + * by qsort() in GNU libc. + */ + + /* Find minimal element which will serve as a barrier */ + r = MIN(array_size, ASORT_THRESHOLD); + m = 0; + for (l=1; l<r; l++) + if (ASORT_LT(ASORT_ELT(l),ASORT_ELT(m))) + m = l; + ASORT_SWAP(0,m); + + /* Insertion sort */ + for (m=1; m<(int)array_size; m++) + { + l=m; + while (ASORT_LT(ASORT_ELT(m),ASORT_ELT(l-1))) + l--; + while (l < m) + { + ASORT_SWAP(l,m); + l++; + } + } +} + +#undef ASORT_PREFIX +#undef ASORT_KEY_TYPE +#undef ASORT_ELT +#undef ASORT_LT +#undef ASORT_SWAP +#undef ASORT_THRESHOLD +#undef ASORT_EXTRA_ARGS +#undef ASORT_ARRAY_ARG diff --git a/src/contrib/ucw/binsearch.h b/src/contrib/ucw/binsearch.h new file mode 100644 index 0000000..b791d39 --- /dev/null +++ b/src/contrib/ucw/binsearch.h @@ -0,0 +1,50 @@ +/* + * UCW Library -- Generic Binary Search + * + * (c) 2005 Martin Mares <mj@ucw.cz> + * + * This software may be freely distributed and used according to the terms + * of the GNU Lesser General Public License. + */ + +#pragma once + +/*** + * [[defs]] + * Definitions + * ----------- + ***/ + +/** + * Find the first element not lower than \p x in the sorted array \p ary of \p N elements (non-decreasing order). + * Returns the index of the found element or \p N if no exists. Uses `ary_lt_x(ary,i,x)` to compare the i'th element with \p x. + * The time complexity is `O(log(N))`. + **/ +#define BIN_SEARCH_FIRST_GE_CMP(ary, N, ary_lt_x, x, ...) ({ \ + unsigned l = 0, r = (N); \ + while (l < r) \ + { \ + unsigned m = (l+r)/2; \ + if (ary_lt_x(ary, m, x, __VA_ARGS__)) \ + l = m+1; \ + else \ + r = m; \ + } \ + l; \ +}) + +/** + * The default comparison macro for \ref BIN_SEARCH_FIRST_GE_CMP(). + **/ +#define ARY_LT_NUM(ary,i,x) (ary)[i] < (x) + +/** + * Same as \ref BIN_SEARCH_FIRST_GE_CMP(), but uses the default `<` operator for comparisons. + **/ +#define BIN_SEARCH_FIRST_GE(ary,N,x) BIN_SEARCH_FIRST_GE_CMP(ary,N,ARY_LT_NUM,x) + +/** + * Search the sorted array \p ary of \p N elements (non-decreasing) for the first occurrence of \p x. + * Returns the index or -1 if no such element exists. Uses the `<` operator for comparisons. + **/ +#define BIN_SEARCH_EQ(ary,N,x) ({ int i = BIN_SEARCH_FIRST_GE(ary,N,x); if (i >= (N) || (ary)[i] != (x)) i=-1; i; }) diff --git a/src/contrib/ucw/heap.c b/src/contrib/ucw/heap.c new file mode 100644 index 0000000..7d74aeb --- /dev/null +++ b/src/contrib/ucw/heap.c @@ -0,0 +1,153 @@ +/* + * Binary heap + * + * (c) 2012 Ondrej Filip <feela@network.cz> + * + * This software may be freely distributed and used according to the terms + * of the GNU Lesser General Public License. + */ + +/*** + * Introduction + * ------------ + * + * Binary heap is a simple data structure, which for example supports efficient insertions, deletions + * and access to the minimal inserted item. We define several macros for such operations. + * Note that because of simplicity of heaps, we have decided to define direct macros instead + * of a <<generic:,macro generator>> as for several other data structures in the Libucw. + * + * A heap is represented by a number of elements and by an array of values. Beware that we + * index this array from one, not from zero as do the standard C arrays. + * + * Most macros use these parameters: + * + * - @num - a variable (signed or unsigned integer) with the number of elements + * - @heap - a C array of type @type; the heap is stored in `heap[1] .. heap[num]`; `heap[0]` is unused + * + * A valid heap must follow these rules: + * + * - `num >= 0` + * - `heap[i] >= heap[i / 2]` for each `i` in `[2, num]` + * + * The first element `heap[1]` is always lower or equal to all other elements. + ***/ + +#include <string.h> +#include <stdlib.h> +#include "contrib/ucw/heap.h" + +static inline void heap_swap(heap_val_t **e1, heap_val_t **e2) +{ + if (e1 == e2) return; /* Stack tmp should be faster than tmpelem. */ + heap_val_t *tmp = *e1; /* Even faster than 2-XOR nowadays. */ + *e1 = *e2; + *e2 = tmp; + int pos = (*e1)->pos; + (*e1)->pos = (*e2)->pos; + (*e2)->pos = pos; +} + +int heap_init(struct heap *h, int (*cmp)(void *, void *), int init_size) +{ + int isize = init_size ? init_size : INITIAL_HEAP_SIZE; + + h->num = 0; + h->max_size = isize; + h->cmp = cmp; + h->data = malloc((isize + 1) * sizeof(heap_val_t*)); /* Temp element unused. */ + + return h->data ? 1 : 0; +} + +void heap_deinit(struct heap *h) +{ + free(h->data); + memset(h, 0, sizeof(*h)); +} + +static inline void _heap_bubble_down(struct heap *h, int e) +{ + int e1; + for (;;) { + e1 = 2 * e; + if (e1 > h->num) break; + if ((h->cmp(*HELEMENT(h, e), *HELEMENT(h, e1)) < 0) && + (e1 == h->num || (h->cmp(*HELEMENT(h, e), *HELEMENT(h, e1 + 1)) < 0))) break; + if ((e1 != h->num) && (h->cmp(*HELEMENT(h, e1 + 1), *HELEMENT(h, e1)) < 0)) e1++; + heap_swap(HELEMENT(h, e), HELEMENT(h, e1)); + e = e1; + } +} + +static inline void _heap_bubble_up(struct heap *h, int e) +{ + int e1; + while (e > 1) { + e1 = e / 2; + if (h->cmp(*HELEMENT(h, e1), *HELEMENT(h, e)) < 0) break; + heap_swap(HELEMENT(h, e), HELEMENT(h, e1)); + e = e1; + } +} + +void heap_replace(struct heap *h, int pos, heap_val_t *e) +{ + *HELEMENT(h, pos) = e; + e->pos = pos; + + if (pos == 1 || h->cmp(*HELEMENT(h, pos / 2), e) < 0) { + _heap_bubble_down(h, pos); + } else { + _heap_bubble_up(h, pos); + } +} + +void heap_delmin(struct heap *h) +{ + if (h->num == 0) return; + if (h->num > 1) { + heap_swap(HHEAD(h), HELEMENT(h, h->num)); + } + (*HELEMENT(h, h->num))->pos = 0; + h->num--; + _heap_bubble_down(h, 1); +} + +int heap_insert(struct heap *h, heap_val_t *e) +{ + if (h->num == h->max_size) { + h->max_size = h->max_size * HEAP_INCREASE_STEP; + h->data = realloc(h->data, (h->max_size + 1) * sizeof(heap_val_t*)); + if (!h->data) { + return 0; + } + } + + h->num++; + *HELEMENT(h, h->num) = e; + e->pos = h->num; + _heap_bubble_up(h, h->num); + return 1; +} + +int heap_find(struct heap *h, heap_val_t *elm) +{ + return ((struct heap_val *) elm)->pos; +} + +void heap_delete(struct heap *h, int e) +{ + heap_swap(HELEMENT(h, e), HELEMENT(h, h->num)); + (*HELEMENT(h, h->num))->pos = 0; + h->num--; + if (h->cmp(*HELEMENT(h, e), *HELEMENT(h, h->num + 1)) < 0) { + _heap_bubble_up(h, e); + } else { + _heap_bubble_down(h, e); + } + + if ((h->num > INITIAL_HEAP_SIZE) && (h->num < h->max_size / HEAP_DECREASE_THRESHOLD)) { + h->max_size = h->max_size / HEAP_INCREASE_STEP; + h->data = realloc(h->data, (h->max_size + 1) * sizeof(heap_val_t*)); + } +} diff --git a/src/contrib/ucw/heap.h b/src/contrib/ucw/heap.h new file mode 100644 index 0000000..f85bb82 --- /dev/null +++ b/src/contrib/ucw/heap.h @@ -0,0 +1,46 @@ +/* Copyright (C) 2022 CZ.NIC, z.s.p.o. <knot-dns@labs.nic.cz> + + This program is free software: you can redistribute it and/or modify + it under the terms of the GNU General Public License as published by + the Free Software Foundation, either version 3 of the License, or + (at your option) any later version. + + This program is distributed in the hope that it will be useful, + but WITHOUT ANY WARRANTY; without even the implied warranty of + MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + GNU General Public License for more details. + + You should have received a copy of the GNU General Public License + along with this program. If not, see <https://www.gnu.org/licenses/>. + */ + +#pragma once + +struct heap_val { + int pos; +}; + +typedef struct heap_val heap_val_t; + +struct heap { + int num; /* Number of elements */ + int max_size; /* Size of allocated memory */ + int (*cmp)(void *, void *); + heap_val_t **data; +}; /* Array follows */ + +#define INITIAL_HEAP_SIZE 512 /* initial heap size */ +#define HEAP_INCREASE_STEP 2 /* multiplier for each inflation, keep conservative */ +#define HEAP_DECREASE_THRESHOLD 2 /* threshold for deflation, keep conservative */ +#define HELEMENT(h,num) ((h)->data + (num)) +#define HHEAD(h) HELEMENT((h), 1) +#define EMPTY_HEAP(h) ((h)->num == 0) + +int heap_init(struct heap *, int (*cmp)(void *, void *), int); +void heap_deinit(struct heap *); + +void heap_delmin(struct heap *); +int heap_insert(struct heap *, heap_val_t *); +int heap_find(struct heap *, heap_val_t *); +void heap_delete(struct heap *, int); +void heap_replace(struct heap *, int, heap_val_t *); diff --git a/src/contrib/ucw/lists.c b/src/contrib/ucw/lists.c new file mode 100644 index 0000000..01af28f --- /dev/null +++ b/src/contrib/ucw/lists.c @@ -0,0 +1,264 @@ +/* + * BIRD Library -- Linked Lists + * + * (c) 1998 Martin Mares <mj@ucw.cz> + * (c) 2015, 2020-2022 CZ.NIC, z.s.p.o. <knot-dns@labs.nic.cz> + * + * Can be freely distributed and used under the terms of the GNU GPL. + */ + +/** + * DOC: Linked lists + * + * The BIRD library provides a set of functions for operating on linked + * lists. The lists are internally represented as standard doubly linked + * lists with synthetic head and tail which makes all the basic operations + * run in constant time and contain no extra end-of-list checks. Each list + * is described by a &list structure, nodes can have any format as long + * as they start with a &node structure. If you want your nodes to belong + * to multiple lists at once, you can embed multiple &node structures in them + * and use the SKIP_BACK() macro to calculate a pointer to the start of the + * structure from a &node pointer, but beware of obscurity. + * + * There also exist safe linked lists (&slist, &snode and all functions + * being prefixed with |s_|) which support asynchronous walking very + * similar to that used in the &fib structure. + */ + +#include <assert.h> +#include <stdlib.h> +#include <string.h> + +#include "contrib/ucw/lists.h" +#include "contrib/mempattern.h" + +/** + * add_tail - append a node to a list + * \p l: linked list + * \p n: list node + * + * add_tail() takes a node \p n and appends it at the end of the list \p l. + */ +void +add_tail(list_t *l, node_t *n) +{ + node_t *z = &l->tail; + + n->next = z; + n->prev = z->prev; + z->prev->next = n; + z->prev = n; + assert(z->next == NULL); +} + +/** + * add_head - prepend a node to a list + * \p l: linked list + * \p n: list node + * + * add_head() takes a node \p n and prepends it at the start of the list \p l. + */ +void +add_head(list_t *l, node_t *n) +{ + node_t *z = &l->head; + + n->next = z->next; + n->prev = z; + z->next->prev = n; + z->next = n; + assert(z->prev == NULL); +} + +/** + * insert_node - insert a node to a list + * \p n: a new list node + * \p after: a node of a list + * + * Inserts a node \p n to a linked list after an already inserted + * node \p after. + */ +void +insert_node(node_t *n, node_t *after) +{ + node_t *z = after->next; + + n->next = z; + n->prev = after; + after->next = n; + z->prev = n; +} + +/** + * rem_node - remove a node from a list + * \p n: node to be removed + * + * Removes a node \p n from the list it's linked in. + */ +void +rem_node(node_t *n) +{ + node_t *z = n->prev; + node_t *x = n->next; + + z->next = x; + x->prev = z; + n->prev = 0; + n->next = 0; +} + +/** + * init_list - create an empty list + * \p l: list + * + * init_list() takes a &list structure and initializes its + * fields, so that it represents an empty list. + */ +void +init_list(list_t *l) +{ + l->head.next = &l->tail; + l->head.prev = NULL; + l->tail.next = NULL; + l->tail.prev = &l->head; +} + +/** + * add_tail_list - concatenate two lists + * \p to: destination list + * \p l: source list + * + * This function appends all elements of the list \p l to + * the list \p to in constant time. + */ +void +add_tail_list(list_t *to, list_t *l) +{ + node_t *p = to->tail.prev; + node_t *q = l->head.next; + + p->next = q; + q->prev = p; + to->tail.prev = l->tail.prev; +} + +/** + * list_dup - duplicate list + * \p to: destination list + * \p l: source list + * + * This function duplicates all elements of the list \p l to + * the list \p to in linear time. + * + * This function only works with a homogenous item size. + */ +void list_dup(list_t *dst, list_t *src, size_t itemsz) +{ + node_t *n; + WALK_LIST(n, *src) { + node_t *i = malloc(itemsz); + memcpy(i, n, itemsz); + add_tail(dst, i); + } +} + +/** + * list_size - gets number of nodes + * \p l: list + * + * This function counts nodes in list \p l and returns this number. + */ +size_t list_size(const list_t *l) +{ + size_t count = 0; + + node_t *n; + WALK_LIST(n, *l) { + count++; + } + + return count; +} + +/** + * fix_list - correction of head/tail pointers when list had been memmove'd + * \p l: list + * + * WARNING: must not be called on empty list + */ +void fix_list(list_t *l) +{ + node_t *n = HEAD(*l); + assert(n->next != NULL); + n->prev = &l->head; + + n = TAIL(*l); + assert(n->prev != NULL); + n->next = &l->tail; +} + +/** + * ptrlist_add - add pointer to pointer list + * \p to: destination list + * \p val: added pointer + * \p mm: memory context + */ +ptrnode_t *ptrlist_add(list_t *to, void *val, knot_mm_t *mm) +{ + ptrnode_t *node = mm_alloc(mm , sizeof(ptrnode_t)); + if (node == NULL) { + return NULL; + } else { + node->d = val; + } + add_tail(to, &node->n); + return node; +} + +/** + * ptrlist_free - free all nodes in pointer list + * \p list: list nodes + * \p mm: memory context + */ +void ptrlist_free(list_t *list, knot_mm_t *mm) +{ + node_t *n, *nxt; + WALK_LIST_DELSAFE(n, nxt, *list) { + mm_free(mm, n); + } + init_list(list); +} + +/** + * ptrlist_rem - remove pointer node + * \p val: pointer to remove + * \p mm: memory context + */ +void ptrlist_rem(ptrnode_t *node, knot_mm_t *mm) +{ + rem_node(&node->n); + mm_free(mm, node); +} + +/** + * ptrlist_deep_free - free all nodes incl referenced data + * \p list: list nodes + * \p mm: memory context + */ +void ptrlist_deep_free(list_t *l, knot_mm_t *mm) +{ + ptrnode_t *n; + WALK_LIST(n, *l) { + mm_free(mm, n->d); + } + ptrlist_free(l, mm); +} + +void ptrlist_free_custom(list_t *l, knot_mm_t *mm, ptrlist_free_cb free_cb) +{ + ptrnode_t *n; + WALK_LIST(n, *l) { + free_cb(n->d); + } + ptrlist_free(l, mm); +} diff --git a/src/contrib/ucw/lists.h b/src/contrib/ucw/lists.h new file mode 100644 index 0000000..1a3ca95 --- /dev/null +++ b/src/contrib/ucw/lists.h @@ -0,0 +1,74 @@ +/* + * BIRD Library -- Linked Lists + * + * (c) 1998 Martin Mares <mj@ucw.cz> + * (c) 2015, 2020-2022 CZ.NIC, z.s.p.o. <knot-dns@labs.nic.cz> + * + * Can be freely distributed and used under the terms of the GNU GPL. + */ + +#pragma once + +#include <string.h> +#include "libknot/mm_ctx.h" + +typedef struct node { + struct node *next, *prev; +} node_t; + +typedef struct list { + node_t head, tail; +} list_t; + +#define NODE (node_t *) +#define HEAD(list) ((void *)((list).head.next)) +#define TAIL(list) ((void *)((list).tail.prev)) +#define WALK_LIST(n,list) for(n=HEAD(list);(NODE (n))->next; \ + n=(void *)((NODE (n))->next)) +#define WALK_LIST_DELSAFE(n,nxt,list) \ + for(n=HEAD(list); (nxt=(void *)((NODE (n))->next)); n=(void *) nxt) +/* WALK_LIST_FIRST supposes that called code removes each processed node */ +#define WALK_LIST_FIRST(n,list) \ + while(n=HEAD(list), (NODE (n))->next) +#define WALK_LIST_BACKWARDS(n,list) for(n=TAIL(list);(NODE (n))->prev; \ + n=(void *)((NODE (n))->prev)) +#define WALK_LIST_BACKWARDS_DELSAFE(n,prv,list) \ + for(n=TAIL(list); prv=(void *)((NODE (n))->prev); n=(void *) prv) + +#define EMPTY_LIST(list) (!(NODE HEAD(list))->next) + +/*! \brief Free every node in the list. */ +#define WALK_LIST_FREE(list) \ + do { \ + node_t *n=0,*nxt=0; \ + WALK_LIST_DELSAFE(n,nxt,list) { \ + free(n); \ + } \ + init_list(&list); \ + } while(0) + +void add_tail(list_t *, node_t *); +void add_head(list_t *, node_t *); +void rem_node(node_t *); +void add_tail_list(list_t *, list_t *); +void init_list(list_t *); +void insert_node(node_t *, node_t *); +void list_dup(list_t *dst, list_t *src, size_t itemsz); +size_t list_size(const list_t *); +void fix_list(list_t *); + +/*! + * \brief Generic pointer list implementation. + */ +typedef struct ptrnode { + node_t n; + void *d; +} ptrnode_t; + +ptrnode_t *ptrlist_add(list_t *, void *, knot_mm_t *); +void ptrlist_free(list_t *, knot_mm_t *); +void ptrlist_rem(ptrnode_t *node, knot_mm_t *mm); +void ptrlist_deep_free(list_t *, knot_mm_t *); + +typedef void (*ptrlist_free_cb)(void *); +void ptrlist_free_custom(list_t *l, knot_mm_t *mm, ptrlist_free_cb free_cb); diff --git a/src/contrib/ucw/mempool.c b/src/contrib/ucw/mempool.c new file mode 100644 index 0000000..8e835c1 --- /dev/null +++ b/src/contrib/ucw/mempool.c @@ -0,0 +1,323 @@ +/* + * UCW Library -- Memory Pools (One-Time Allocation) + * + * (c) 1997--2001 Martin Mares <mj@ucw.cz> + * (c) 2007 Pavel Charvat <pchar@ucw.cz> + * (c) 2015, 2017 CZ.NIC, z.s.p.o. <knot-dns@labs.nic.cz> + * + * This software may be freely distributed and used according to the terms + * of the GNU Lesser General Public License. + */ + +#undef LOCAL_DEBUG + +#include <string.h> +#include <strings.h> +#include <stdlib.h> +#include <stdio.h> +#include <assert.h> +#include "contrib/asan.h" +#include "contrib/macros.h" +#include "contrib/ucw/mempool.h" + +/** \todo This shouldn't be precalculated, but computed on load. */ +#define CPU_PAGE_SIZE 4096 + +/** Align an integer \p s to the nearest higher multiple of \p a (which should be a power of two) **/ +#define ALIGN_TO(s, a) (((s)+a-1)&~(a-1)) +#define MP_CHUNK_TAIL ALIGN_TO(sizeof(struct mempool_chunk), CPU_STRUCT_ALIGN) +#define MP_SIZE_MAX (~0U - MP_CHUNK_TAIL - CPU_PAGE_SIZE) +#define DBG(s, ...) + +/** \note Imported MMAP backend from bigalloc.c */ +#define CONFIG_UCW_POOL_IS_MMAP +#ifdef CONFIG_UCW_POOL_IS_MMAP +#include <sys/mman.h> +static void * +page_alloc(uint64_t len) +{ + if (!len) { + return NULL; + } + if (len > SIZE_MAX) { + return NULL; + } + assert(!(len & (CPU_PAGE_SIZE-1))); + uint8_t *p = mmap(NULL, len, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANON, -1, 0); + if (p == (uint8_t*) MAP_FAILED) { + return NULL; + } + return p; +} + +static void +page_free(void *start, uint64_t len) +{ + assert(!(len & (CPU_PAGE_SIZE-1))); + assert(!((uintptr_t) start & (CPU_PAGE_SIZE-1))); + munmap(start, len); +} +#endif + +struct mempool_chunk { + struct mempool_chunk *next; + unsigned size; +}; + +static unsigned +mp_align_size(unsigned size) +{ +#ifdef CONFIG_UCW_POOL_IS_MMAP + return ALIGN_TO(size + MP_CHUNK_TAIL, CPU_PAGE_SIZE) - MP_CHUNK_TAIL; +#else + return ALIGN_TO(size, CPU_STRUCT_ALIGN); +#endif +} + +void +mp_init(struct mempool *pool, unsigned chunk_size) +{ + chunk_size = mp_align_size(MAX(sizeof(struct mempool), chunk_size)); + *pool = (struct mempool) { + .chunk_size = chunk_size, + .threshold = chunk_size >> 1, + .last_big = &pool->last_big + }; +} + +static void * +mp_new_big_chunk(unsigned size) +{ + uint8_t *data = malloc(size + MP_CHUNK_TAIL); + if (!data) { + return NULL; + } + ASAN_POISON_MEMORY_REGION(data, size); + struct mempool_chunk *chunk = (struct mempool_chunk *)(data + size); + chunk->size = size; + return chunk; +} + +static void +mp_free_big_chunk(struct mempool_chunk *chunk) +{ + void *ptr = (uint8_t *)chunk - chunk->size; + ASAN_UNPOISON_MEMORY_REGION(ptr, chunk->size); + free(ptr); +} + +static void * +mp_new_chunk(unsigned size) +{ +#ifdef CONFIG_UCW_POOL_IS_MMAP + uint8_t *data = page_alloc(size + MP_CHUNK_TAIL); + if (!data) { + return NULL; + } + ASAN_POISON_MEMORY_REGION(data, size); + struct mempool_chunk *chunk = (struct mempool_chunk *)(data + size); + chunk->size = size; + return chunk; +#else + return mp_new_big_chunk(size); +#endif +} + +static void +mp_free_chunk(struct mempool_chunk *chunk) +{ +#ifdef CONFIG_UCW_POOL_IS_MMAP + uint8_t *data = (uint8_t *)chunk - chunk->size; + ASAN_UNPOISON_MEMORY_REGION(data, chunk->size); + page_free(data, chunk->size + MP_CHUNK_TAIL); +#else + mp_free_big_chunk(chunk); +#endif +} + +struct mempool * +mp_new(unsigned chunk_size) +{ + chunk_size = mp_align_size(MAX(sizeof(struct mempool), chunk_size)); + struct mempool_chunk *chunk = mp_new_chunk(chunk_size); + struct mempool *pool = (void *)chunk - chunk_size; + ASAN_UNPOISON_MEMORY_REGION(pool, sizeof(*pool)); + DBG("Creating mempool %p with %u bytes long chunks", pool, chunk_size); + chunk->next = NULL; + ASAN_POISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + *pool = (struct mempool) { + .state = { .free = { chunk_size - sizeof(*pool) }, .last = { chunk } }, + .chunk_size = chunk_size, + .threshold = chunk_size >> 1, + .last_big = &pool->last_big + }; + return pool; +} + +static void +mp_free_chain(struct mempool_chunk *chunk) +{ + while (chunk) { + ASAN_UNPOISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + struct mempool_chunk *next = chunk->next; + mp_free_chunk(chunk); + chunk = next; + } +} + +static void +mp_free_big_chain(struct mempool_chunk *chunk) +{ + while (chunk) { + ASAN_UNPOISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + struct mempool_chunk *next = chunk->next; + mp_free_big_chunk(chunk); + chunk = next; + } +} + +void +mp_delete(struct mempool *pool) +{ + if (pool == NULL) { + return; + } + DBG("Deleting mempool %p", pool); + mp_free_big_chain(pool->state.last[1]); + mp_free_chain(pool->unused); + mp_free_chain(pool->state.last[0]); // can contain the mempool structure +} + +void +mp_flush(struct mempool *pool) +{ + mp_free_big_chain(pool->state.last[1]); + struct mempool_chunk *chunk = pool->state.last[0], *next; + while (chunk) { + ASAN_UNPOISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + if ((uint8_t *)chunk - chunk->size == (uint8_t *)pool) { + break; + } + next = chunk->next; + chunk->next = pool->unused; + ASAN_POISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + pool->unused = chunk; + chunk = next; + } + pool->state.last[0] = chunk; + if (chunk) { + pool->state.free[0] = chunk->size - sizeof(*pool); + ASAN_POISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + } else { + pool->state.free[0] = 0; + } + pool->state.last[1] = NULL; + pool->state.free[1] = 0; + pool->last_big = &pool->last_big; +} + +static void +mp_stats_chain(struct mempool_chunk *chunk, struct mempool_stats *stats, unsigned idx) +{ + struct mempool_chunk *next; + while (chunk) { + ASAN_UNPOISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + stats->chain_size[idx] += chunk->size + sizeof(*chunk); + stats->chain_count[idx]++; + next = chunk->next; + ASAN_POISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + chunk = next; + } + stats->total_size += stats->chain_size[idx]; +} + +void +mp_stats(struct mempool *pool, struct mempool_stats *stats) +{ + bzero(stats, sizeof(*stats)); + mp_stats_chain(pool->state.last[0], stats, 0); + mp_stats_chain(pool->state.last[1], stats, 1); + mp_stats_chain(pool->unused, stats, 2); +} + +uint64_t +mp_total_size(struct mempool *pool) +{ + struct mempool_stats stats; + mp_stats(pool, &stats); + return stats.total_size; +} + +static void * +mp_alloc_internal(struct mempool *pool, unsigned size) +{ + struct mempool_chunk *chunk; + if (size <= pool->threshold) { + pool->idx = 0; + if (pool->unused) { + chunk = pool->unused; + ASAN_UNPOISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + pool->unused = chunk->next; + } else { + chunk = mp_new_chunk(pool->chunk_size); + } + chunk->next = pool->state.last[0]; + ASAN_POISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + pool->state.last[0] = chunk; + pool->state.free[0] = pool->chunk_size - size; + return (uint8_t *)chunk - pool->chunk_size; + } else if (size <= MP_SIZE_MAX) { + pool->idx = 1; + unsigned aligned = ALIGN_TO(size, CPU_STRUCT_ALIGN); + chunk = mp_new_big_chunk(aligned); + if (!chunk) { + return NULL; + } + chunk->next = pool->state.last[1]; + ASAN_POISON_MEMORY_REGION(chunk, sizeof(struct mempool_chunk)); + pool->state.last[1] = chunk; + pool->state.free[1] = aligned - size; + return pool->last_big = (uint8_t *)chunk - aligned; + } else { + fprintf(stderr, "Cannot allocate %u bytes from a mempool", size); + assert(0); + return NULL; + } +} + +void * +mp_alloc(struct mempool *pool, unsigned size) +{ + unsigned avail = pool->state.free[0] & ~(CPU_STRUCT_ALIGN - 1); + void *ptr = NULL; + if (size <= avail) { + pool->state.free[0] = avail - size; + ptr = (uint8_t*)pool->state.last[0] - avail; + } else { + ptr = mp_alloc_internal(pool, size); + } + ASAN_UNPOISON_MEMORY_REGION(ptr, size); + return ptr; +} + +void * +mp_alloc_noalign(struct mempool *pool, unsigned size) +{ + void *ptr = NULL; + if (size <= pool->state.free[0]) { + ptr = (uint8_t*)pool->state.last[0] - pool->state.free[0]; + pool->state.free[0] -= size; + } else { + ptr = mp_alloc_internal(pool, size); + } + ASAN_UNPOISON_MEMORY_REGION(ptr, size); + return ptr; +} + +void * +mp_alloc_zero(struct mempool *pool, unsigned size) +{ + void *ptr = mp_alloc(pool, size); + bzero(ptr, size); + return ptr; +} diff --git a/src/contrib/ucw/mempool.h b/src/contrib/ucw/mempool.h new file mode 100644 index 0000000..c5a4fa8 --- /dev/null +++ b/src/contrib/ucw/mempool.h @@ -0,0 +1,124 @@ +/* + * UCW Library -- Memory Pools + * + * (c) 1997--2005 Martin Mares <mj@ucw.cz> + * (c) 2007 Pavel Charvat <pchar@ucw.cz> + * (c) 2015, 2017 CZ.NIC, z.s.p.o. <knot-dns@labs.nic.cz> + * + * This software may be freely distributed and used according to the terms + * of the GNU Lesser General Public License. + */ + +#pragma once + +#include <string.h> +#include <stdint.h> + +#define CPU_STRUCT_ALIGN (sizeof(void*)) + +/*** + * [[defs]] + * Definitions + * ----------- + ***/ + +/** + * Memory pool state (see mp_push(), ...). + * You should use this one as an opaque handle only, the insides are internal. + **/ +struct mempool_state { + unsigned free[2]; + void *last[2]; +}; + +/** + * Memory pool. + * You should use this one as an opaque handle only, the insides are internal. + **/ +struct mempool { + struct mempool_state state; + void *unused, *last_big; + unsigned chunk_size, threshold, idx; +}; + +struct mempool_stats { /** Mempool statistics. See mp_stats(). **/ + uint64_t total_size; /** Real allocated size in bytes. */ + unsigned chain_count[3]; /** Number of allocated chunks in small/big/unused chains. */ + unsigned chain_size[3]; /** Size of allocated chunks in small/big/unused chains. */ +}; + +/*** + * [[basic]] + * Basic manipulation + * ------------------ + ***/ + +/** + * Initialize a given mempool structure. + * \p chunk_size must be in the interval `[1, UINT_MAX / 2]`. + * It will allocate memory by this large chunks and take + * memory to satisfy requests from them. + * + * Memory pools can be treated as <<trans:respools,resources>>, see <<trans:res_mempool()>>. + **/ +void mp_init(struct mempool *pool, unsigned chunk_size); + +/** + * Allocate and initialize a new memory pool. + * See \ref mp_init() for \p chunk_size limitations. + * + * The new mempool structure is allocated on the new mempool. + * + * Memory pools can be treated as <<trans:respools,resources>>, see <<trans:res_mempool()>>. + **/ +struct mempool *mp_new(unsigned chunk_size); + +/** + * Cleanup mempool initialized by mp_init or mp_new. + * Frees all the memory allocated by this mempool and, + * if created by \ref mp_new(), the \p pool itself. + **/ +void mp_delete(struct mempool *pool); + +/** + * Frees all data on a memory pool, but leaves it working. + * It can keep some of the chunks allocated to serve + * further allocation requests. Leaves the \p pool alive, + * even if it was created with \ref mp_new(). + **/ +void mp_flush(struct mempool *pool); + +/** + * Compute some statistics for debug purposes. + * See the definition of the <<struct_mempool_stats,mempool_stats structure>>. + **/ +void mp_stats(struct mempool *pool, struct mempool_stats *stats); +uint64_t mp_total_size(struct mempool *pool); /** How many bytes were allocated by the pool. **/ + +/*** + * [[alloc]] + * Allocation routines + * ------------------- + ***/ + +/** + * The function allocates new \p size bytes on a given memory pool. + * If the \p size is zero, the resulting pointer is undefined, + * but it may be safely reallocated or used as the parameter + * to other functions below. + * + * The resulting pointer is always aligned to a multiple of + * `CPU_STRUCT_ALIGN` bytes and this condition remains true also + * after future reallocations. + **/ +void *mp_alloc(struct mempool *pool, unsigned size); + +/** + * The same as \ref mp_alloc(), but the result may be unaligned. + **/ +void *mp_alloc_noalign(struct mempool *pool, unsigned size); + +/** + * The same as \ref mp_alloc(), but fills the newly allocated memory with zeroes. + **/ +void *mp_alloc_zero(struct mempool *pool, unsigned size); |