bird/sysdep/unix/alloc.c

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/*
* BIRD Internet Routing Daemon -- Raw allocation
*
* (c) 2020 Maria Matejka <mq@ucw.cz>
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
#include "nest/bird.h"
#include "lib/resource.h"
#include "lib/lists.h"
#include "lib/event.h"
#include <errno.h>
#include <stdlib.h>
#include <unistd.h>
#ifdef HAVE_MMAP
#include <sys/mman.h>
#endif
long page_size = 0;
#ifdef HAVE_MMAP
#define KEEP_PAGES_MAIN_MAX 256
#define KEEP_PAGES_MAIN_MIN 8
#define CLEANUP_PAGES_BULK 256
STATIC_ASSERT(KEEP_PAGES_MAIN_MIN * 4 < KEEP_PAGES_MAIN_MAX);
static _Bool use_fake = 0;
#if DEBUGGING
struct free_page {
node unused[42];
node n;
};
#else
struct free_page {
node n;
};
#endif
#define EP_POS_MAX ((page_size - OFFSETOF(struct empty_pages, pages)) / sizeof (void *))
struct empty_pages {
node n;
uint pos;
void *pages[0];
};
struct free_pages {
list pages; /* List of (struct free_page) keeping free pages without releasing them (hot) */
list empty; /* List of (struct empty_pages) keeping invalidated pages mapped for us (cold) */
u16 min, max; /* Minimal and maximal number of free pages kept */
uint cnt; /* Number of free pages in list */
event cleanup;
};
static void global_free_pages_cleanup_event(void *);
static struct free_pages global_free_pages = {
.min = KEEP_PAGES_MAIN_MIN,
.max = KEEP_PAGES_MAIN_MAX,
.cleanup = { .hook = global_free_pages_cleanup_event },
};
uint *pages_kept = &global_free_pages.cnt;
static void *
alloc_sys_page(void)
{
void *ptr = mmap(NULL, page_size, PROT_WRITE | PROT_READ, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
if (ptr == MAP_FAILED)
bug("mmap(%lu) failed: %m", page_size);
return ptr;
}
extern int shutting_down; /* Shutdown requested. */
#else // ! HAVE_MMAP
#define use_fake 1
#endif
void *
alloc_page(void)
{
/* If the system page allocator is goofy, we use posix_memalign to get aligned blocks of memory. */
if (use_fake)
{
void *ptr = NULL;
int err = posix_memalign(&ptr, page_size, page_size);
if (err || !ptr)
bug("posix_memalign(%lu) failed", (long unsigned int) page_size);
return ptr;
}
#ifdef HAVE_MMAP
struct free_pages *fps = &global_free_pages;
/* If there is any free page kept hot, we use it. */
if (fps->cnt)
{
struct free_page *fp = SKIP_BACK(struct free_page, n, HEAD(fps->pages));
rem_node(&fp->n);
/* If the hot-free-page cache is getting short, request the cleanup routine to replenish the cache */
if ((--fps->cnt < fps->min) && !shutting_down)
ev_schedule(&fps->cleanup);
return fp;
}
/* If there is any free page kept cold, we use that. */
if (!EMPTY_LIST(fps->empty))
{
struct empty_pages *ep = HEAD(fps->empty);
/* Either the keeper page contains at least one cold page pointer, return that */
if (ep->pos)
return ep->pages[--ep->pos];
/* Or the keeper page has no more cold page pointer, return the keeper page */
rem_node(&ep->n);
return ep;
}
/* And in the worst case, allocate a new page by mmap() */
return alloc_sys_page();
#endif
}
void
free_page(void *ptr)
{
/* If the system page allocator is goofy, we just free the block and care no more. */
if (use_fake)
{
free(ptr);
return;
}
#ifdef HAVE_MMAP
struct free_pages *fps = &global_free_pages;
struct free_page *fp = ptr;
/* Otherwise, we add the free page to the hot-free-page list */
fp->n = (node) {};
add_tail(&fps->pages, &fp->n);
/* And if there are too many hot free pages, we ask for page cleanup */
if ((++fps->cnt > fps->max) && !shutting_down)
ev_schedule(&fps->cleanup);
#endif
}
#ifdef HAVE_MMAP
static void
global_free_pages_cleanup_event(void *data UNUSED)
{
/* Cleanup on shutdown is ignored. All pages may be kept hot, OS will take care. */
if (shutting_down)
return;
struct free_pages *fps = &global_free_pages;
/* Cleanup may get called when hot free page cache is short of pages. Replenishing. */
while (fps->cnt / 2 < fps->min)
{
struct free_page *fp = alloc_sys_page();
fp->n = (node) {};
add_tail(&fps->pages, &fp->n);
fps->cnt++;
}
/* Or the hot free page cache is too big. Moving some pages to the cold free page cache. */
for (int limit = CLEANUP_PAGES_BULK; limit && (fps->cnt > fps->max / 2); fps->cnt--, limit--)
{
struct free_page *fp = SKIP_BACK(struct free_page, n, TAIL(fps->pages));
rem_node(&fp->n);
/* Empty pages are stored as pointers. To store them, we need a pointer block. */
struct empty_pages *ep;
if (EMPTY_LIST(fps->empty) || ((ep = HEAD(fps->empty))->pos == EP_POS_MAX))
{
/* There is either no pointer block or the last block is full. We use this block as a pointer block. */
ep = (struct empty_pages *) fp;
*ep = (struct empty_pages) {};
add_head(&fps->empty, &ep->n);
}
else
{
/* We store this block as a pointer into the first free place
* and tell the OS that the underlying memory is trash. */
ep->pages[ep->pos++] = fp;
if (madvise(fp, page_size,
#ifdef CONFIG_MADV_DONTNEED_TO_FREE
MADV_DONTNEED
#else
MADV_FREE
#endif
) < 0)
bug("madvise(%p) failed: %m", fp);
}
}
/* If the hot free page cleanup hit the limit, re-schedule this routine
* to allow for other routines to run. */
if (fps->cnt > fps->max)
ev_schedule(&fps->cleanup);
}
#endif
void
resource_sys_init(void)
{
#ifdef HAVE_MMAP
ASSERT_DIE(global_free_pages.cnt == 0);
/* Check what page size the system supports */
if (!(page_size = sysconf(_SC_PAGESIZE)))
die("System page size must be non-zero");
if ((u64_popcount(page_size) == 1) && (page_size >= (1 << 10)) && (page_size <= (1 << 18)))
{
/* We assume that page size has only one bit and is between 1K and 256K (incl.).
* Otherwise, the assumptions in lib/slab.c (sl_head's num_full range) aren't met. */
struct free_pages *fps = &global_free_pages;
init_list(&fps->pages);
init_list(&fps->empty);
global_free_pages_cleanup_event(NULL);
return;
}
/* Too big or strange page, use the aligned allocator instead */
log(L_WARN "Got strange memory page size (%ld), using the aligned allocator instead", (s64) page_size);
use_fake = 1;
#endif
page_size = 4096;
}