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https://github.com/edk2-porting/linux-next.git
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e18b890bb0
Replace all uses of kmem_cache_t with struct kmem_cache. The patch was generated using the following script: #!/bin/sh # # Replace one string by another in all the kernel sources. # set -e for file in `find * -name "*.c" -o -name "*.h"|xargs grep -l $1`; do quilt add $file sed -e "1,\$s/$1/$2/g" $file >/tmp/$$ mv /tmp/$$ $file quilt refresh done The script was run like this sh replace kmem_cache_t "struct kmem_cache" Signed-off-by: Christoph Lameter <clameter@sgi.com> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
394 lines
9.7 KiB
C
394 lines
9.7 KiB
C
/*
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* Generic pidhash and scalable, time-bounded PID allocator
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*
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* (C) 2002-2003 William Irwin, IBM
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* (C) 2004 William Irwin, Oracle
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* (C) 2002-2004 Ingo Molnar, Red Hat
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*
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* pid-structures are backing objects for tasks sharing a given ID to chain
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* against. There is very little to them aside from hashing them and
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* parking tasks using given ID's on a list.
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*
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* The hash is always changed with the tasklist_lock write-acquired,
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* and the hash is only accessed with the tasklist_lock at least
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* read-acquired, so there's no additional SMP locking needed here.
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*
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* We have a list of bitmap pages, which bitmaps represent the PID space.
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* Allocating and freeing PIDs is completely lockless. The worst-case
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* allocation scenario when all but one out of 1 million PIDs possible are
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* allocated already: the scanning of 32 list entries and at most PAGE_SIZE
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* bytes. The typical fastpath is a single successful setbit. Freeing is O(1).
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*/
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#include <linux/mm.h>
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#include <linux/module.h>
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#include <linux/slab.h>
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#include <linux/init.h>
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#include <linux/bootmem.h>
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#include <linux/hash.h>
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#include <linux/pspace.h>
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#define pid_hashfn(nr) hash_long((unsigned long)nr, pidhash_shift)
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static struct hlist_head *pid_hash;
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static int pidhash_shift;
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static struct kmem_cache *pid_cachep;
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int pid_max = PID_MAX_DEFAULT;
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#define RESERVED_PIDS 300
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int pid_max_min = RESERVED_PIDS + 1;
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int pid_max_max = PID_MAX_LIMIT;
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#define BITS_PER_PAGE (PAGE_SIZE*8)
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#define BITS_PER_PAGE_MASK (BITS_PER_PAGE-1)
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static inline int mk_pid(struct pspace *pspace, struct pidmap *map, int off)
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{
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return (map - pspace->pidmap)*BITS_PER_PAGE + off;
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}
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#define find_next_offset(map, off) \
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find_next_zero_bit((map)->page, BITS_PER_PAGE, off)
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/*
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* PID-map pages start out as NULL, they get allocated upon
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* first use and are never deallocated. This way a low pid_max
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* value does not cause lots of bitmaps to be allocated, but
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* the scheme scales to up to 4 million PIDs, runtime.
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*/
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struct pspace init_pspace = {
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.pidmap = {
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[ 0 ... PIDMAP_ENTRIES-1] = { ATOMIC_INIT(BITS_PER_PAGE), NULL }
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},
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.last_pid = 0
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};
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/*
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* Note: disable interrupts while the pidmap_lock is held as an
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* interrupt might come in and do read_lock(&tasklist_lock).
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*
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* If we don't disable interrupts there is a nasty deadlock between
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* detach_pid()->free_pid() and another cpu that does
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* spin_lock(&pidmap_lock) followed by an interrupt routine that does
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* read_lock(&tasklist_lock);
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*
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* After we clean up the tasklist_lock and know there are no
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* irq handlers that take it we can leave the interrupts enabled.
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* For now it is easier to be safe than to prove it can't happen.
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*/
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static __cacheline_aligned_in_smp DEFINE_SPINLOCK(pidmap_lock);
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static fastcall void free_pidmap(struct pspace *pspace, int pid)
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{
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struct pidmap *map = pspace->pidmap + pid / BITS_PER_PAGE;
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int offset = pid & BITS_PER_PAGE_MASK;
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clear_bit(offset, map->page);
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atomic_inc(&map->nr_free);
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}
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static int alloc_pidmap(struct pspace *pspace)
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{
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int i, offset, max_scan, pid, last = pspace->last_pid;
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struct pidmap *map;
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pid = last + 1;
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if (pid >= pid_max)
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pid = RESERVED_PIDS;
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offset = pid & BITS_PER_PAGE_MASK;
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map = &pspace->pidmap[pid/BITS_PER_PAGE];
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max_scan = (pid_max + BITS_PER_PAGE - 1)/BITS_PER_PAGE - !offset;
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for (i = 0; i <= max_scan; ++i) {
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if (unlikely(!map->page)) {
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void *page = kzalloc(PAGE_SIZE, GFP_KERNEL);
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/*
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* Free the page if someone raced with us
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* installing it:
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*/
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spin_lock_irq(&pidmap_lock);
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if (map->page)
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kfree(page);
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else
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map->page = page;
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spin_unlock_irq(&pidmap_lock);
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if (unlikely(!map->page))
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break;
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}
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if (likely(atomic_read(&map->nr_free))) {
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do {
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if (!test_and_set_bit(offset, map->page)) {
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atomic_dec(&map->nr_free);
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pspace->last_pid = pid;
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return pid;
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}
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offset = find_next_offset(map, offset);
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pid = mk_pid(pspace, map, offset);
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/*
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* find_next_offset() found a bit, the pid from it
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* is in-bounds, and if we fell back to the last
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* bitmap block and the final block was the same
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* as the starting point, pid is before last_pid.
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*/
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} while (offset < BITS_PER_PAGE && pid < pid_max &&
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(i != max_scan || pid < last ||
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!((last+1) & BITS_PER_PAGE_MASK)));
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}
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if (map < &pspace->pidmap[(pid_max-1)/BITS_PER_PAGE]) {
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++map;
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offset = 0;
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} else {
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map = &pspace->pidmap[0];
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offset = RESERVED_PIDS;
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if (unlikely(last == offset))
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break;
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}
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pid = mk_pid(pspace, map, offset);
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}
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return -1;
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}
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static int next_pidmap(struct pspace *pspace, int last)
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{
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int offset;
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struct pidmap *map, *end;
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offset = (last + 1) & BITS_PER_PAGE_MASK;
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map = &pspace->pidmap[(last + 1)/BITS_PER_PAGE];
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end = &pspace->pidmap[PIDMAP_ENTRIES];
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for (; map < end; map++, offset = 0) {
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if (unlikely(!map->page))
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continue;
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offset = find_next_bit((map)->page, BITS_PER_PAGE, offset);
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if (offset < BITS_PER_PAGE)
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return mk_pid(pspace, map, offset);
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}
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return -1;
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}
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fastcall void put_pid(struct pid *pid)
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{
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if (!pid)
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return;
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if ((atomic_read(&pid->count) == 1) ||
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atomic_dec_and_test(&pid->count))
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kmem_cache_free(pid_cachep, pid);
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}
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EXPORT_SYMBOL_GPL(put_pid);
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static void delayed_put_pid(struct rcu_head *rhp)
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{
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struct pid *pid = container_of(rhp, struct pid, rcu);
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put_pid(pid);
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}
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fastcall void free_pid(struct pid *pid)
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{
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/* We can be called with write_lock_irq(&tasklist_lock) held */
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unsigned long flags;
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spin_lock_irqsave(&pidmap_lock, flags);
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hlist_del_rcu(&pid->pid_chain);
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spin_unlock_irqrestore(&pidmap_lock, flags);
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free_pidmap(&init_pspace, pid->nr);
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call_rcu(&pid->rcu, delayed_put_pid);
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}
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struct pid *alloc_pid(void)
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{
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struct pid *pid;
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enum pid_type type;
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int nr = -1;
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pid = kmem_cache_alloc(pid_cachep, GFP_KERNEL);
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if (!pid)
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goto out;
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nr = alloc_pidmap(&init_pspace);
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if (nr < 0)
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goto out_free;
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atomic_set(&pid->count, 1);
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pid->nr = nr;
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for (type = 0; type < PIDTYPE_MAX; ++type)
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INIT_HLIST_HEAD(&pid->tasks[type]);
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spin_lock_irq(&pidmap_lock);
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hlist_add_head_rcu(&pid->pid_chain, &pid_hash[pid_hashfn(pid->nr)]);
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spin_unlock_irq(&pidmap_lock);
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out:
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return pid;
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out_free:
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kmem_cache_free(pid_cachep, pid);
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pid = NULL;
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goto out;
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}
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struct pid * fastcall find_pid(int nr)
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{
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struct hlist_node *elem;
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struct pid *pid;
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hlist_for_each_entry_rcu(pid, elem,
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&pid_hash[pid_hashfn(nr)], pid_chain) {
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if (pid->nr == nr)
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return pid;
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}
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return NULL;
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}
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EXPORT_SYMBOL_GPL(find_pid);
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int fastcall attach_pid(struct task_struct *task, enum pid_type type, int nr)
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{
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struct pid_link *link;
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struct pid *pid;
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link = &task->pids[type];
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link->pid = pid = find_pid(nr);
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hlist_add_head_rcu(&link->node, &pid->tasks[type]);
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return 0;
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}
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void fastcall detach_pid(struct task_struct *task, enum pid_type type)
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{
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struct pid_link *link;
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struct pid *pid;
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int tmp;
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link = &task->pids[type];
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pid = link->pid;
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hlist_del_rcu(&link->node);
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link->pid = NULL;
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for (tmp = PIDTYPE_MAX; --tmp >= 0; )
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if (!hlist_empty(&pid->tasks[tmp]))
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return;
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free_pid(pid);
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}
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/* transfer_pid is an optimization of attach_pid(new), detach_pid(old) */
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void fastcall transfer_pid(struct task_struct *old, struct task_struct *new,
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enum pid_type type)
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{
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new->pids[type].pid = old->pids[type].pid;
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hlist_replace_rcu(&old->pids[type].node, &new->pids[type].node);
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old->pids[type].pid = NULL;
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}
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struct task_struct * fastcall pid_task(struct pid *pid, enum pid_type type)
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{
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struct task_struct *result = NULL;
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if (pid) {
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struct hlist_node *first;
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first = rcu_dereference(pid->tasks[type].first);
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if (first)
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result = hlist_entry(first, struct task_struct, pids[(type)].node);
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}
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return result;
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}
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/*
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* Must be called under rcu_read_lock() or with tasklist_lock read-held.
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*/
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struct task_struct *find_task_by_pid_type(int type, int nr)
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{
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return pid_task(find_pid(nr), type);
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}
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EXPORT_SYMBOL(find_task_by_pid_type);
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struct pid *get_task_pid(struct task_struct *task, enum pid_type type)
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{
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struct pid *pid;
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rcu_read_lock();
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pid = get_pid(task->pids[type].pid);
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rcu_read_unlock();
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return pid;
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}
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struct task_struct *fastcall get_pid_task(struct pid *pid, enum pid_type type)
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{
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struct task_struct *result;
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rcu_read_lock();
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result = pid_task(pid, type);
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if (result)
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get_task_struct(result);
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rcu_read_unlock();
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return result;
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}
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struct pid *find_get_pid(pid_t nr)
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{
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struct pid *pid;
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rcu_read_lock();
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pid = get_pid(find_pid(nr));
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rcu_read_unlock();
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return pid;
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}
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/*
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* Used by proc to find the first pid that is greater then or equal to nr.
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*
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* If there is a pid at nr this function is exactly the same as find_pid.
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*/
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struct pid *find_ge_pid(int nr)
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{
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struct pid *pid;
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do {
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pid = find_pid(nr);
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if (pid)
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break;
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nr = next_pidmap(&init_pspace, nr);
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} while (nr > 0);
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return pid;
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}
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EXPORT_SYMBOL_GPL(find_get_pid);
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/*
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* The pid hash table is scaled according to the amount of memory in the
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* machine. From a minimum of 16 slots up to 4096 slots at one gigabyte or
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* more.
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*/
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void __init pidhash_init(void)
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{
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int i, pidhash_size;
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unsigned long megabytes = nr_kernel_pages >> (20 - PAGE_SHIFT);
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pidhash_shift = max(4, fls(megabytes * 4));
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pidhash_shift = min(12, pidhash_shift);
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pidhash_size = 1 << pidhash_shift;
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printk("PID hash table entries: %d (order: %d, %Zd bytes)\n",
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pidhash_size, pidhash_shift,
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pidhash_size * sizeof(struct hlist_head));
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pid_hash = alloc_bootmem(pidhash_size * sizeof(*(pid_hash)));
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if (!pid_hash)
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panic("Could not alloc pidhash!\n");
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for (i = 0; i < pidhash_size; i++)
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INIT_HLIST_HEAD(&pid_hash[i]);
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}
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void __init pidmap_init(void)
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{
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init_pspace.pidmap[0].page = kzalloc(PAGE_SIZE, GFP_KERNEL);
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/* Reserve PID 0. We never call free_pidmap(0) */
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set_bit(0, init_pspace.pidmap[0].page);
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atomic_dec(&init_pspace.pidmap[0].nr_free);
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pid_cachep = kmem_cache_create("pid", sizeof(struct pid),
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__alignof__(struct pid),
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SLAB_PANIC, NULL, NULL);
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}
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