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RT-AC66 3.0.0.4.374.130 core
[tomato.git] / release / src-rt-6.x / linux / linux-2.6 / include / linux / pid.h
blob1e0e4e3423a628a7983520762b7364038fbbe628
1 #ifndef _LINUX_PID_H
2 #define _LINUX_PID_H
3
4 #include <linux/rcupdate.h>
5
6 enum pid_type
7 {
8 PIDTYPE_PID,
9 PIDTYPE_PGID,
10 PIDTYPE_SID,
11 PIDTYPE_MAX
12 };
13
14 /*
15 * What is struct pid?
16 *
17 * A struct pid is the kernel's internal notion of a process identifier.
18 * It refers to individual tasks, process groups, and sessions. While
19 * there are processes attached to it the struct pid lives in a hash
20 * table, so it and then the processes that it refers to can be found
21 * quickly from the numeric pid value. The attached processes may be
22 * quickly accessed by following pointers from struct pid.
23 *
24 * Storing pid_t values in the kernel and refering to them later has a
25 * problem. The process originally with that pid may have exited and the
26 * pid allocator wrapped, and another process could have come along
27 * and been assigned that pid.
28 *
29 * Referring to user space processes by holding a reference to struct
30 * task_struct has a problem. When the user space process exits
31 * the now useless task_struct is still kept. A task_struct plus a
32 * stack consumes around 10K of low kernel memory. More precisely
33 * this is THREAD_SIZE + sizeof(struct task_struct). By comparison
34 * a struct pid is about 64 bytes.
35 *
36 * Holding a reference to struct pid solves both of these problems.
37 * It is small so holding a reference does not consume a lot of
38 * resources, and since a new struct pid is allocated when the numeric pid
39 * value is reused (when pids wrap around) we don't mistakenly refer to new
40 * processes.
41 */
42
43 struct pid
44 {
45 atomic_t count;
46 /* Try to keep pid_chain in the same cacheline as nr for find_pid */
47 int nr;
48 struct hlist_node pid_chain;
49 /* lists of tasks that use this pid */
50 struct hlist_head tasks[PIDTYPE_MAX];
51 struct rcu_head rcu;
52 };
53
54 extern struct pid init_struct_pid;
55
56 struct pid_link
57 {
58 struct hlist_node node;
59 struct pid *pid;
60 };
61
62 static inline struct pid *get_pid(struct pid *pid)
63 {
64 if (pid)
65 atomic_inc(&pid->count);
66 return pid;
67 }
68
69 extern void FASTCALL(put_pid(struct pid *pid));
70 extern struct task_struct *FASTCALL(pid_task(struct pid *pid, enum pid_type));
71 extern struct task_struct *FASTCALL(get_pid_task(struct pid *pid,
72 enum pid_type));
73
74 extern struct pid *get_task_pid(struct task_struct *task, enum pid_type type);
75
76 /*
77 * attach_pid() and detach_pid() must be called with the tasklist_lock
78 * write-held.
79 */
80 extern int FASTCALL(attach_pid(struct task_struct *task,
81 enum pid_type type, struct pid *pid));
82 extern void FASTCALL(detach_pid(struct task_struct *task, enum pid_type));
83 extern void FASTCALL(transfer_pid(struct task_struct *old,
84 struct task_struct *new, enum pid_type));
85
86 /*
87 * look up a PID in the hash table. Must be called with the tasklist_lock
88 * or rcu_read_lock() held.
89 */
90 extern struct pid *FASTCALL(find_pid(int nr));
91
92 /*
93 * Lookup a PID in the hash table, and return with it's count elevated.
94 */
95 extern struct pid *find_get_pid(int nr);
96 extern struct pid *find_ge_pid(int nr);
97
98 extern struct pid *alloc_pid(void);
99 extern void FASTCALL(free_pid(struct pid *pid));
100
101 static inline pid_t pid_nr(struct pid *pid)
102 {
103 pid_t nr = 0;
104 if (pid)
105 nr = pid->nr;
106 return nr;
107 }
108
109 #define do_each_pid_task(pid, type, task) \
110 do { \
111 struct hlist_node *pos___; \
112 if (pid != NULL) \
113 hlist_for_each_entry_rcu((task), pos___, \
114 &pid->tasks[type], pids[type].node) {
115
116 #define while_each_pid_task(pid, type, task) \
117 } \
118 } while (0)
119
120 #endif /* _LINUX_PID_H */
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