#include <string.h>
#include <kogata/slab_alloc.h>
typedef struct object {
struct object *next;
} object_t;
typedef struct cache {
void* region_addr;
uint32_t n_free_objs;
object_t* first_free_obj;
struct cache *next_cache; // next cache in this slab
} cache_t;
typedef struct region {
void* region_addr;
size_t region_size;
struct region *next_region;
bool contains_descriptors;
} region_t;
typedef union descriptor {
cache_t c;
region_t r;
union descriptor *next_free;
} descriptor_t;
typedef struct slab {
cache_t *first_cache; // linked list of caches
} slab_t;
struct mem_allocator {
const slab_type_t *types;
slab_t *slabs;
descriptor_t *first_free_descriptor;
region_t *all_regions;
page_alloc_fun_t alloc_fun;
page_free_fun_t free_fun;
};
// ============================================== //
// Helper functions for the manipulation of lists //
// ============================================== //
void add_free_descriptor(mem_allocator_t *a, descriptor_t *c) {
c->next_free = a->first_free_descriptor;
a->first_free_descriptor = c;
}
descriptor_t *take_descriptor(mem_allocator_t *a) {
if (a->first_free_descriptor == 0) {
void* p = a->alloc_fun(PAGE_SIZE);
if (p == 0) return 0;
const void* end = p + PAGE_SIZE;
for (descriptor_t *i = (descriptor_t*)p; i + 1 <= (descriptor_t*)end; i++) {
add_free_descriptor(a, i);
}
// register the descriptor region
descriptor_t *dd = a->first_free_descriptor;
ASSERT(dd != 0);
a->first_free_descriptor = dd->next_free;
region_t *drd = &dd->r;
drd->region_addr = p;
drd->region_size = PAGE_SIZE;
drd->contains_descriptors = true;
drd->next_region = a->all_regions;
a->all_regions = drd;
}
descriptor_t *x = a->first_free_descriptor;
ASSERT(x != 0);
a->first_free_descriptor = x->next_free;
return x;
}
// ============================== //
// The actual allocator functions //
// ============================== //
mem_allocator_t* create_slab_allocator(const slab_type_t *types, page_alloc_fun_t af, page_free_fun_t ff) {
union {
void* addr;
mem_allocator_t *a;
slab_t *s;
descriptor_t *d;
} ptr;
ptr.addr = af(PAGE_SIZE);
if (ptr.addr == 0) return 0; // could not allocate
const void* end_addr = ptr.addr + PAGE_SIZE;
mem_allocator_t *a = ptr.a;
ptr.a++;
a->all_regions = 0;
a->alloc_fun = af;
a->free_fun = ff;
a->types = types;
a->slabs = ptr.s;
for (const slab_type_t *t = types; t->obj_size != 0; t++) {
ASSERT(t->obj_size >= sizeof(object_t));
ptr.s->first_cache = 0;
ptr.s++;
}
a->first_free_descriptor = 0;
while (ptr.d + 1 <= (descriptor_t*)end_addr) {
add_free_descriptor(a, ptr.d);
ptr.d++;
}
return a;
}
void stack_and_destroy_regions(page_free_fun_t ff, region_t *r) {
if (r == 0) return;
void* addr = r->region_addr;
ASSERT(r != r->next_region);
stack_and_destroy_regions(ff, r->next_region);
ff(addr);
}
void destroy_slab_allocator(mem_allocator_t *a) {
for (int i = 0; a->types[i].obj_size != 0; i++) {
for (cache_t *c = a->slabs[i].first_cache; c != 0; c = c->next_cache) {
a->free_fun(c->region_addr);
}
}
region_t *dr = 0;
region_t *i = a->all_regions;
while (i != 0) {
region_t *r = i;
i = r->next_region;
if (r->contains_descriptors) {
r->next_region = dr;
dr = r;
} else {
a->free_fun(r->region_addr);
}
}
stack_and_destroy_regions(a->free_fun, dr);
a->free_fun(a);
}
void* slab_alloc(mem_allocator_t* a, size_t sz) {
for (int i = 0; a->types[i].obj_size != 0; i++) {
const size_t obj_size = a->types[i].obj_size;
if (sz > obj_size) continue;
// find a cache with free space
cache_t *fc = a->slabs[i].first_cache;
while (fc != 0 && fc->n_free_objs == 0) {
// make sure n_free == 0 iff no object in the free stack
ASSERT((fc->first_free_obj == 0) == (fc->n_free_objs == 0));
fc = fc->next_cache;
}
// if none found, try to allocate a new one
if (fc == 0) {
descriptor_t *fcd = take_descriptor(a);
if (fcd == 0) return 0;
fc = &fcd->c;
ASSERT((descriptor_t*)fc == fcd);
const size_t cache_size = a->types[i].pages_per_cache * PAGE_SIZE;
fc->region_addr = a->alloc_fun(cache_size);
if (fc->region_addr == 0) {
add_free_descriptor(a, fcd);
return 0;
}
/*dbg_printf("New cache 0x%p\n", fc->region_addr);*/
fc->n_free_objs = 0;
fc->first_free_obj = 0;
for (void* p = fc->region_addr; p + obj_size <= fc->region_addr + cache_size; p += obj_size) {
object_t *x = (object_t*)p;
x->next = fc->first_free_obj;
fc->first_free_obj = x;
fc->n_free_objs++;
}
ASSERT(fc->n_free_objs == cache_size / obj_size);
fc->next_cache = a->slabs[i].first_cache;
a->slabs[i].first_cache = fc;
}
// allocate on fc
ASSERT(fc != 0);
ASSERT(fc->n_free_objs > 0);
ASSERT(fc->first_free_obj != 0);
object_t *x = fc->first_free_obj;
/*dbg_printf("Alloc 0x%p\n", x);*/
fc->first_free_obj = x->next;
fc->n_free_objs--;
ASSERT((fc->n_free_objs == 0) == (fc->first_free_obj == 0));
// TODO : if fc is full, put it at the end
return x;
}
// otherwise directly allocate using a->alloc_fun
descriptor_t *rd = take_descriptor(a);
if (rd == 0) return 0;
region_t *r = &rd->r;
ASSERT((descriptor_t*)r == rd);
r->region_addr = a->alloc_fun(sz);
if (r->region_addr == 0) {
add_free_descriptor(a, rd);
return 0;
} else {
r->region_size = sz;
r->contains_descriptors = false;
r->next_region = a->all_regions;
a->all_regions = r;
return (void*)r->region_addr;
}
}
void slab_free(mem_allocator_t* a, void* addr) {
for (int i = 0; a->types[i].obj_size != 0; i++) {
size_t region_size = PAGE_SIZE * a->types[i].pages_per_cache;
for (cache_t *r = a->slabs[i].first_cache; r != 0; r = r->next_cache) {
if (addr >= r->region_addr && addr < r->region_addr + region_size) {
ASSERT((addr - r->region_addr) % a->types[i].obj_size == 0);
object_t *o = (object_t*)addr;
// check the object is not already on the free list (double-free error)
for (object_t *i = r->first_free_obj; i != 0; i = i->next) {
ASSERT((void*)i >= r->region_addr && (void*)i < r->region_addr + region_size);
ASSERT(o != i);
}
/*dbg_printf("Put back 0x%p in 0x%p\n", o, r->region_addr);*/
o->next = r->first_free_obj;
r->first_free_obj = o;
r->n_free_objs++;
if (r->n_free_objs == region_size / a->types[i].obj_size) {
// region is completely unused, free it.
if (a->slabs[i].first_cache == r) {
a->slabs[i].first_cache = r->next_cache;
} else {
for (cache_t *it = a->slabs[i].first_cache; it->next_cache != 0; it = it->next_cache) {
if (it->next_cache == r) {
it->next_cache = r->next_cache;
break;
}
}
}
a->free_fun(r->region_addr);
add_free_descriptor(a, (descriptor_t*)r);
}
return;
}
}
}
// otherwise the block was directly allocated : look for it in regions.
ASSERT(a->all_regions != 0);
if (a->all_regions->region_addr == addr) {
a->free_fun(addr); // found it, free it
region_t *r = a->all_regions;
a->all_regions = r->next_region;
add_free_descriptor(a, (descriptor_t*)r);
} else {
for (region_t *i = a->all_regions; i->next_region != 0; i = i->next_region) {
if (i->next_region->region_addr == addr) {
a->free_fun(addr); // found it, free it
region_t *r = i->next_region;
ASSERT(!r->contains_descriptors);
i->next_region = r->next_region;
add_free_descriptor(a, (descriptor_t*)r);
return;
}
}
ASSERT(false);
}
}
size_t slab_find_getsize(mem_allocator_t *a, void* addr) {
// look for block in caches
for (int i = 0; a->types[i].obj_size != 0; i++) {
size_t region_size = PAGE_SIZE * a->types[i].pages_per_cache;
for (cache_t *r = a->slabs[i].first_cache; r != 0; r = r->next_cache) {
if (addr >= r->region_addr && addr < r->region_addr + region_size) {
ASSERT((addr - r->region_addr) % a->types[i].obj_size == 0);
return a->types[i].obj_size;
}
}
}
// otherwise the block was directly allocated : look for it in regions.
for (region_t *i = a->all_regions; i != 0; i = i->next_region) {
if (i->region_addr == addr) {
return i->region_size;
}
}
ASSERT(false);
}
void* slab_realloc(mem_allocator_t* a, void* ptr, size_t sz) {
if (ptr == 0) return slab_alloc(a, sz);
if (sz == 0) {
slab_free(a, ptr);
return NULL;
}
size_t old_sz = slab_find_getsize(a, ptr);
// What size will be allocated ?
size_t new_sz = 0;
for (int i = 0; a->types[i].obj_size != 0; i++) {
const size_t obj_size = a->types[i].obj_size;
if (sz <= obj_size) {
new_sz = obj_size;
break;
}
}
if (new_sz == 0) new_sz = sz;
// If the space is already big enough, do nothing
if (old_sz == new_sz) return ptr;
// Reallocate
void* ptr2 = slab_alloc(a, sz);
if (ptr2 == NULL) return NULL;
size_t min_sz = (old_sz < sz ? old_sz : sz);
memcpy(ptr2, ptr, min_sz);
slab_free(a, ptr);
return ptr2;
}
/* vim: set ts=4 sw=4 tw=0 noet :*/