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421 lines
8.2 KiB
C
421 lines
8.2 KiB
C
/*
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* BIRD Resource Manager -- A SLAB-like Memory Allocator
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*
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* Heavily inspired by the original SLAB paper by Jeff Bonwick.
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*
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* (c) 1998--2000 Martin Mares <mj@ucw.cz>
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* (c) 2020 Maria Matejka <mq@jmq.cz>
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*
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* Can be freely distributed and used under the terms of the GNU GPL.
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*/
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/**
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* DOC: Slabs
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*
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* Slabs are collections of memory blocks of a fixed size.
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* They support very fast allocation and freeing of such blocks, prevent memory
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* fragmentation and optimize L2 cache usage. Slabs have been invented by Jeff Bonwick
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* and published in USENIX proceedings as `The Slab Allocator: An Object-Caching Kernel
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* Memory Allocator'. Our implementation follows this article except that we don't use
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* constructors and destructors.
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*
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* When the |DEBUGGING| switch is turned on, we automatically fill all
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* newly allocated and freed blocks with a special pattern to make detection
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* of use of uninitialized or already freed memory easier.
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*
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* Example: Nodes of a FIB are allocated from a per-FIB Slab.
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*/
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#include <stdlib.h>
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#include <stdint.h>
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#include "nest/bird.h"
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#include "lib/resource.h"
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#include "lib/string.h"
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#undef FAKE_SLAB /* Turn on if you want to debug memory allocations */
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#ifdef DEBUGGING
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#define POISON /* Poison all regions after they are freed */
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#endif
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static void slab_free(resource *r);
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static void slab_dump(resource *r);
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static resource *slab_lookup(resource *r, unsigned long addr);
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static struct resmem slab_memsize(resource *r);
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#ifdef FAKE_SLAB
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/*
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* Fake version used for debugging.
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*/
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struct slab {
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resource r;
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uint size;
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list objs;
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};
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static struct resclass sl_class = {
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"FakeSlab",
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sizeof(struct slab),
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slab_free,
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slab_dump,
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NULL,
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slab_memsize
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};
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struct sl_obj {
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node n;
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uintptr_t data_align[0];
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byte data[0];
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};
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slab *
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sl_new(pool *p, uint size)
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{
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slab *s = ralloc(p, &sl_class);
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s->size = size;
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init_list(&s->objs);
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return s;
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}
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void *
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sl_alloc(slab *s)
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{
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struct sl_obj *o = xmalloc(sizeof(struct sl_obj) + s->size);
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add_tail(&s->objs, &o->n);
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return o->data;
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}
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void *
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sl_allocz(slab *s)
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{
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void *obj = sl_alloc(s);
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memset(obj, 0, s->size);
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return obj;
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}
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void
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sl_free(slab *s, void *oo)
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{
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struct sl_obj *o = SKIP_BACK(struct sl_obj, data, oo);
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rem_node(&o->n);
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xfree(o);
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}
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static void
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slab_free(resource *r)
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{
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slab *s = (slab *) r;
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struct sl_obj *o, *p;
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for(o = HEAD(s->objs); p = (struct sl_obj *) o->n.next; o = p)
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xfree(o);
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}
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static void
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slab_dump(resource *r)
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{
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slab *s = (slab *) r;
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int cnt = 0;
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struct sl_obj *o;
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WALK_LIST(o, s->objs)
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cnt++;
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debug("(%d objects per %d bytes)\n", cnt, s->size);
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}
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static struct resmem
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slab_memsize(resource *r)
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{
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slab *s = (slab *) r;
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size_t cnt = 0;
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struct sl_obj *o;
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WALK_LIST(o, s->objs)
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cnt++;
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return (struct resmem) {
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.effective = cnt * s->size,
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.overhead = ALLOC_OVERHEAD + sizeof(struct slab) + cnt * ALLOC_OVERHEAD,
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};
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}
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#else
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/*
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* Real efficient version.
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*/
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#define MAX_EMPTY_HEADS 1
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struct slab {
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resource r;
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uint obj_size, head_size, head_bitfield_len;
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uint objs_per_slab, num_empty_heads, data_size;
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list empty_heads, partial_heads, full_heads;
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};
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static struct resclass sl_class = {
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"Slab",
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sizeof(struct slab),
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slab_free,
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slab_dump,
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slab_lookup,
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slab_memsize
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};
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struct sl_head {
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node n;
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u32 num_full;
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u32 used_bits[0];
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};
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struct sl_alignment { /* Magic structure for testing of alignment */
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byte data;
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int x[0];
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};
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#define SL_GET_HEAD(x) ((struct sl_head *) (((uintptr_t) (x)) & ~(page_size-1)))
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/**
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* sl_new - create a new Slab
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* @p: resource pool
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* @size: block size
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*
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* This function creates a new Slab resource from which
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* objects of size @size can be allocated.
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*/
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slab *
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sl_new(pool *p, uint size)
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{
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slab *s = ralloc(p, &sl_class);
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uint align = sizeof(struct sl_alignment);
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if (align < sizeof(void *))
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align = sizeof(void *);
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s->data_size = size;
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size = (size + align - 1) / align * align;
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s->obj_size = size;
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s->head_size = sizeof(struct sl_head);
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do {
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s->objs_per_slab = (page_size - s->head_size) / size;
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s->head_bitfield_len = (s->objs_per_slab + 31) / 32;
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s->head_size = (
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sizeof(struct sl_head)
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+ sizeof(u32) * s->head_bitfield_len
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+ align - 1)
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/ align * align;
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} while (s->objs_per_slab * size + s->head_size > page_size);
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if (!s->objs_per_slab)
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bug("Slab: object too large");
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s->num_empty_heads = 0;
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init_list(&s->empty_heads);
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init_list(&s->partial_heads);
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init_list(&s->full_heads);
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return s;
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}
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/**
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* sl_alloc - allocate an object from Slab
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* @s: slab
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*
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* sl_alloc() allocates space for a single object from the
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* Slab and returns a pointer to the object.
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*/
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void *
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sl_alloc(slab *s)
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{
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struct sl_head *h;
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redo:
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h = HEAD(s->partial_heads);
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if (!h->n.next)
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goto no_partial;
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okay:
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for (uint i=0; i<s->head_bitfield_len; i++)
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if (~h->used_bits[i])
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{
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uint pos = u32_ctz(~h->used_bits[i]);
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if (i * 32 + pos >= s->objs_per_slab)
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break;
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h->used_bits[i] |= 1 << pos;
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h->num_full++;
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void *out = ((void *) h) + s->head_size + (i * 32 + pos) * s->obj_size;
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#ifdef POISON
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memset(out, 0xcd, s->data_size);
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#endif
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return out;
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}
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rem_node(&h->n);
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add_tail(&s->full_heads, &h->n);
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goto redo;
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no_partial:
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h = HEAD(s->empty_heads);
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if (h->n.next)
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{
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rem_node(&h->n);
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add_head(&s->partial_heads, &h->n);
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s->num_empty_heads--;
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goto okay;
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}
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h = alloc_page();
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#ifdef POISON
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memset(h, 0xba, page_size);
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#endif
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ASSERT_DIE(SL_GET_HEAD(h) == h);
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memset(h, 0, s->head_size);
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add_head(&s->partial_heads, &h->n);
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goto okay;
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}
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/**
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* sl_allocz - allocate an object from Slab and zero it
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* @s: slab
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*
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* sl_allocz() allocates space for a single object from the
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* Slab and returns a pointer to the object after zeroing out
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* the object memory.
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*/
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void *
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sl_allocz(slab *s)
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{
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void *obj = sl_alloc(s);
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memset(obj, 0, s->data_size);
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return obj;
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}
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/**
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* sl_free - return a free object back to a Slab
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* @s: slab
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* @oo: object returned by sl_alloc()
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*
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* This function frees memory associated with the object @oo
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* and returns it back to the Slab @s.
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*/
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void
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sl_free(slab *s, void *oo)
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{
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struct sl_head *h = SL_GET_HEAD(oo);
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#ifdef POISON
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memset(oo, 0xdb, s->data_size);
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#endif
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uint offset = oo - ((void *) h) - s->head_size;
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ASSERT_DIE(offset % s->obj_size == 0);
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uint pos = offset / s->obj_size;
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ASSERT_DIE(pos < s->objs_per_slab);
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h->used_bits[pos / 32] &= ~(1 << (pos % 32));
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if (h->num_full-- == s->objs_per_slab)
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{
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rem_node(&h->n);
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add_head(&s->partial_heads, &h->n);
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}
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else if (!h->num_full)
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{
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rem_node(&h->n);
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if (s->num_empty_heads >= MAX_EMPTY_HEADS)
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{
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#ifdef POISON
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memset(h, 0xde, page_size);
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#endif
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free_page(h);
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}
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else
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{
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add_head(&s->empty_heads, &h->n);
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s->num_empty_heads++;
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}
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}
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}
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static void
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slab_free(resource *r)
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{
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slab *s = (slab *) r;
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struct sl_head *h, *g;
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WALK_LIST_DELSAFE(h, g, s->empty_heads)
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free_page(h);
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WALK_LIST_DELSAFE(h, g, s->partial_heads)
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free_page(h);
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WALK_LIST_DELSAFE(h, g, s->full_heads)
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free_page(h);
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}
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static void
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slab_dump(resource *r)
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{
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slab *s = (slab *) r;
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int ec=0, pc=0, fc=0;
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struct sl_head *h;
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WALK_LIST(h, s->empty_heads)
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ec++;
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WALK_LIST(h, s->partial_heads)
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pc++;
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WALK_LIST(h, s->full_heads)
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fc++;
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debug("(%de+%dp+%df blocks per %d objs per %d bytes)\n", ec, pc, fc, s->objs_per_slab, s->obj_size);
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}
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static struct resmem
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slab_memsize(resource *r)
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{
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slab *s = (slab *) r;
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size_t heads = 0;
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struct sl_head *h;
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WALK_LIST(h, s->full_heads)
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heads++;
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size_t items = heads * s->objs_per_slab;
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WALK_LIST(h, s->partial_heads)
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{
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heads++;
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items += h->num_full;
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}
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WALK_LIST(h, s->empty_heads)
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heads++;
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size_t eff = items * s->obj_size;
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return (struct resmem) {
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.effective = eff,
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.overhead = ALLOC_OVERHEAD + sizeof(struct slab) + heads * page_size - eff,
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};
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}
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static resource *
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slab_lookup(resource *r, unsigned long a)
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{
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slab *s = (slab *) r;
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struct sl_head *h;
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WALK_LIST(h, s->partial_heads)
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if ((unsigned long) h < a && (unsigned long) h + page_size < a)
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return r;
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WALK_LIST(h, s->full_heads)
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if ((unsigned long) h < a && (unsigned long) h + page_size < a)
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return r;
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return NULL;
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}
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#endif
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