mergerfs/libfuse/lib/fmp.h

381 lines
6.5 KiB
C

/*
ISC License
Copyright (c) 2021, Antonio SJ Musumeci <trapexit@spawn.link>
Permission to use, copy, modify, and/or 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.
*/
#pragma once
#include "kvec.h"
#include <errno.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <sys/mman.h>
#include <unistd.h>
#define ROUND_UP(N,S) ((((N) + (S) - 1) / (S)) * (S))
typedef kvec_t(void*) slab_kvec_t;
typedef struct mem_stack_t mem_stack_t;
struct mem_stack_t
{
mem_stack_t *next;
};
typedef struct fmp_t fmp_t;
struct fmp_t
{
mem_stack_t *objs;
slab_kvec_t slabs;
uint64_t avail_objs;
uint64_t obj_size;
uint64_t page_size;
uint64_t slab_size;
};
static
inline
uint64_t
fmp_page_size()
{
return sysconf(_SC_PAGESIZE);
}
static
inline
void
fmp_init(fmp_t *fmp_,
const uint64_t obj_size_,
const uint64_t page_multiple_)
{
kv_init(fmp_->slabs);
fmp_->objs = NULL;
fmp_->avail_objs = 0;
fmp_->obj_size = ROUND_UP(obj_size_,sizeof(void*));
fmp_->page_size = fmp_page_size();
fmp_->slab_size = (fmp_->page_size * page_multiple_);
}
static
inline
uint64_t
fmp_slab_count(fmp_t *fmp_)
{
return kv_size(fmp_->slabs);
}
static
inline
void*
fmp_slab_alloc_posix_memalign(fmp_t *fmp_)
{
int rv;
void *mem;
const size_t alignment = fmp_->page_size;
const size_t size = fmp_->slab_size;
rv = posix_memalign(&mem,alignment,size);
if(rv != 0)
return NULL;
return NULL;
}
static
inline
void*
fmp_slab_alloc_mmap(fmp_t *fmp_)
{
void *mem;
void *address = NULL;
const size_t length = fmp_->slab_size;
const int protect = PROT_READ|PROT_WRITE;
const int flags = MAP_PRIVATE|MAP_ANONYMOUS;
const int filedes = -1;
const off_t offset = 0;
mem = mmap(address,length,protect,flags,filedes,offset);
if(mem == MAP_FAILED)
return NULL;
return mem;
}
static
inline
void
fmp_slab_free_posix_memalign(fmp_t* fmp_,
void *mem_)
{
(void)fmp_;
free(mem_);
}
static
inline
void
fmp_slab_free_mmap(fmp_t* fmp_,
void *mem_)
{
void *addr = mem_;
size_t length = fmp_->slab_size;
(void)munmap(addr,length);
}
static
inline
int
fmp_slab_alloc(fmp_t *fmp_)
{
char *i;
void *mem;
mem = fmp_slab_alloc_mmap(fmp_);
if(mem == NULL)
return -ENOMEM;
kv_push(void*,fmp_->slabs,mem);
i = ((char*)mem + fmp_->slab_size - fmp_->obj_size);
while(i >= (char*)mem)
{
mem_stack_t *obj = (mem_stack_t*)i;
obj->next = fmp_->objs;
fmp_->objs = obj;
fmp_->avail_objs++;
i -= fmp_->obj_size;
}
return 0;
}
static
inline
void*
fmp_alloc(fmp_t *fmp_)
{
void *rv;
if(fmp_->objs == NULL)
fmp_slab_alloc(fmp_);
if(fmp_->objs == NULL)
return NULL;
rv = fmp_->objs;
fmp_->objs = fmp_->objs->next;
fmp_->avail_objs--;
return rv;
}
static
inline
void*
fmp_calloc(fmp_t *fmp_)
{
void *obj;
obj = fmp_alloc(fmp_);
if(obj == NULL)
return NULL;
memset(obj,0,fmp_->obj_size);
return obj;
}
static
inline
void
fmp_free(fmp_t *fmp_,
void *obj_)
{
mem_stack_t *obj = (mem_stack_t*)obj_;
obj->next = fmp_->objs;
fmp_->objs = obj;
fmp_->avail_objs++;
}
static
inline
void
fmp_clear(fmp_t *fmp_)
{
while(kv_size(fmp_->slabs))
{
void *slab = kv_pop(fmp_->slabs);
fmp_slab_free_mmap(fmp_,slab);
}
fmp_->objs = NULL;
fmp_->avail_objs = 0;
}
static
inline
void
fmp_destroy(fmp_t *fmp_)
{
fmp_clear(fmp_);
kv_destroy(fmp_->slabs);
}
static
inline
uint64_t
fmp_avail_objs(fmp_t *fmp_)
{
return fmp_->avail_objs;
}
static
inline
uint64_t
fmp_objs_per_slab(fmp_t *fmp_)
{
return (fmp_->slab_size / fmp_->obj_size);
}
static
inline
uint64_t
fmp_objs_in_slab(fmp_t *fmp_,
void *slab_)
{
char *slab;
uint64_t objs_per_slab;
uint64_t objs_in_slab;
slab = (char*)slab_;
objs_in_slab = 0;
objs_per_slab = fmp_objs_per_slab(fmp_);
for(mem_stack_t *stack = fmp_->objs; stack != NULL; stack = stack->next)
{
char *obj = (char*)stack;
if((obj >= slab) && (obj < (slab + fmp_->slab_size)))
objs_in_slab++;
if(objs_in_slab >= objs_per_slab)
break;
}
return objs_in_slab;
}
static
inline
void
fmp_remove_objs_in_slab(fmp_t *fmp_,
void *slab_)
{
char *slab;
uint64_t objs_per_slab;
uint64_t objs_in_slab;
mem_stack_t **p;
p = &fmp_->objs;
slab = (char*)slab_;
objs_in_slab = 0;
objs_per_slab = fmp_objs_per_slab(fmp_);
while((*p) != NULL)
{
char *obj = (char*)*p;
if((obj >= slab) && (obj < (slab + fmp_->slab_size)))
{
objs_in_slab++;
*p = (*p)->next;
fmp_->avail_objs--;
if(objs_in_slab >= objs_per_slab)
break;
continue;
}
p = &(*p)->next;
}
}
static
inline
int
fmp_gc_slab(fmp_t *fmp_,
uint64_t slab_idx_)
{
char *slab;
uint64_t objs_in_slab;
uint64_t objs_per_slab;
slab_idx_ = (slab_idx_ % kv_size(fmp_->slabs));
slab = kv_A(fmp_->slabs,slab_idx_);
objs_per_slab = fmp_objs_per_slab(fmp_);
objs_in_slab = fmp_objs_in_slab(fmp_,slab);
if(objs_in_slab != objs_per_slab)
return 0;
fmp_remove_objs_in_slab(fmp_,slab);
kv_delete(fmp_->slabs,slab_idx_);
fmp_slab_free_mmap(fmp_,slab);
return 1;
}
static
inline
int
fmp_gc(fmp_t *fmp_)
{
uint64_t slab_idx;
slab_idx = rand();
return fmp_gc_slab(fmp_,slab_idx);
}
static
inline
double
fmp_slab_usage_ratio(fmp_t *fmp_)
{
double avail_objs;
double objs_per_slab;
double nums_of_slabs;
avail_objs = fmp_->avail_objs;
objs_per_slab = fmp_objs_per_slab(fmp_);
nums_of_slabs = kv_size(fmp_->slabs);
return (avail_objs / (objs_per_slab * nums_of_slabs));
}
static
inline
uint64_t
fmp_total_allocated_memory(fmp_t *fmp_)
{
return (fmp_->slab_size * kv_size(fmp_->slabs));
}