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[FreeBSD/FreeBSD.git] / sys / sys / proc.h

/*-
 * Copyright (c) 1986, 1989, 1991, 1993
 *      The Regents of the University of California.  All rights reserved.
 * (c) UNIX System Laboratories, Inc.
 * All or some portions of this file are derived from material licensed
 * to the University of California by American Telephone and Telegraph
 * Co. or Unix System Laboratories, Inc. and are reproduced herein with
 * the permission of UNIX System Laboratories, Inc.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 * 4. Neither the name of the University nor the names of its contributors
 *    may be used to endorse or promote products derived from this software
 *    without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 * SUCH DAMAGE.
 *
 *      @(#)proc.h      8.15 (Berkeley) 5/19/95
 * $FreeBSD$
 */

#ifndef _SYS_PROC_H_
#define _SYS_PROC_H_

#include <sys/callout.h>                /* For struct callout. */
#include <sys/event.h>                  /* For struct klist. */
#ifndef _KERNEL
#include <sys/filedesc.h>
#endif
#include <sys/queue.h>
#include <sys/_lock.h>
#include <sys/_mutex.h>
#include <sys/priority.h>
#include <sys/rtprio.h>                 /* XXX. */
#include <sys/runq.h>
#include <sys/sigio.h>
#include <sys/signal.h>
#ifndef _KERNEL
#include <sys/time.h>                   /* For structs itimerval, timeval. */
#else
#include <sys/pcpu.h>
#endif
#include <sys/ucontext.h>
#include <sys/ucred.h>
#include <machine/proc.h>               /* Machine-dependent proc substruct. */

/*
 * One structure allocated per session.
 *
 * List of locks
 * (m)          locked by s_mtx mtx
 * (e)          locked by proctree_lock sx
 * (c)          const until freeing
 */
struct session {
        int             s_count;        /* (m) Ref cnt; pgrps in session. */
        struct proc     *s_leader;      /* (m + e) Session leader. */
        struct vnode    *s_ttyvp;       /* (m) Vnode of controlling tty. */
        struct tty      *s_ttyp;        /* (m) Controlling tty. */
        pid_t           s_sid;          /* (c) Session ID. */
                                        /* (m) Setlogin() name: */
        char            s_login[roundup(MAXLOGNAME, sizeof(long))];
        struct mtx      s_mtx;          /* Mutex to protect members. */
};

/*
 * One structure allocated per process group.
 *
 * List of locks
 * (m)          locked by pg_mtx mtx
 * (e)          locked by proctree_lock sx
 * (c)          const until freeing
 */
struct pgrp {
        LIST_ENTRY(pgrp) pg_hash;       /* (e) Hash chain. */
        LIST_HEAD(, proc) pg_members;   /* (m + e) Pointer to pgrp members. */
        struct session  *pg_session;    /* (c) Pointer to session. */
        struct sigiolst pg_sigiolst;    /* (m) List of sigio sources. */
        pid_t           pg_id;          /* (c) Process group id. */
        int             pg_jobc;        /* (m) Job control process count. */
        struct mtx      pg_mtx;         /* Mutex to protect members */
};

/*
 * pargs, used to hold a copy of the command line, if it had a sane length.
 */
struct pargs {
        u_int   ar_ref;         /* Reference count. */
        u_int   ar_length;      /* Length. */
        u_char  ar_args[1];     /* Arguments. */
};

/*-
 * Description of a process.
 *
 * This structure contains the information needed to manage a thread of
 * control, known in UN*X as a process; it has references to substructures
 * containing descriptions of things that the process uses, but may share
 * with related processes.  The process structure and the substructures
 * are always addressable except for those marked "(CPU)" below,
 * which might be addressable only on a processor on which the process
 * is running.
 *
 * Below is a key of locks used to protect each member of struct proc.  The
 * lock is indicated by a reference to a specific character in parens in the
 * associated comment.
 *      * - not yet protected
 *      a - only touched by curproc or parent during fork/wait
 *      b - created at fork, never changes
 *              (exception aiods switch vmspaces, but they are also
 *              marked 'P_SYSTEM' so hopefully it will be left alone)
 *      c - locked by proc mtx
 *      d - locked by allproc_lock lock
 *      e - locked by proctree_lock lock
 *      f - session mtx
 *      g - process group mtx
 *      h - callout_lock mtx
 *      i - by curproc or the master session mtx
 *      j - locked by sched_lock mtx
 *      k - only accessed by curthread
 *      k*- only accessed by curthread and from an interrupt
 *      l - the attaching proc or attaching proc parent
 *      m - Giant
 *      n - not locked, lazy
 *      o - ktrace lock
 *      p - select lock (sellock)
 *      q - td_contested lock
 *      r - p_peers lock
 *      x - created at fork, only changes during single threading in exec
 *      z - zombie threads/ksegroup lock
 *
 * If the locking key specifies two identifiers (for example, p_pptr) then
 * either lock is sufficient for read access, but both locks must be held
 * for write access.
 */
struct ithd;
struct kg_sched;
struct nlminfo;
struct kaioinfo;
struct p_sched;
struct sleepqueue;
struct td_sched;
struct trapframe;
struct turnstile;

/*
 * Here we define the three structures used for process information.
 *
 * The first is the thread. It might be thought of as a "Kernel
 * Schedulable Entity Context".
 * This structure contains all the information as to where a thread of
 * execution is now, or was when it was suspended, why it was suspended,
 * and anything else that will be needed to restart it when it is
 * rescheduled. Always associated with a KSE when running, but can be
 * reassigned to an equivalent KSE when being restarted for
 * load balancing. Each of these is associated with a kernel stack
 * and a pcb.
 *
 * It is important to remember that a particular thread structure may only
 * exist as long as the system call or kernel entrance (e.g. by pagefault)
 * which it is currently executing. It should therefore NEVER be referenced
 * by pointers in long lived structures that live longer than a single
 * request. If several threads complete their work at the same time,
 * they will all rewind their stacks to the user boundary, report their
 * completion state, and all but one will be freed. That last one will
 * be kept to provide a kernel stack and pcb for the NEXT syscall or kernel
 * entrance (basically to save freeing and then re-allocating it).  The existing
 * thread keeps a cached spare thread available to allow it to quickly
 * get one when it needs a new one. There is also a system
 * cache of free threads. Threads have priority and partake in priority
 * inheritance schemes.
 */
struct thread;

/*
 * The KSEGRP is allocated resources across a number of CPUs.
 * (Including a number of CPUxQUANTA. It parcels these QUANTA up among
 * its threads, each of which should be running in a different CPU.
 * BASE priority and total available quanta are properties of a KSEGRP.
 * Multiple KSEGRPs in a single process compete against each other
 * for total quanta in the same way that a forked child competes against
 * it's parent process.
 */
struct ksegrp;

/*
 * A process is the owner of all system resources allocated to a task
 * except CPU quanta.
 * All KSEGs under one process see, and have the same access to, these
 * resources (e.g. files, memory, sockets, credential, kqueues).
 * A process may compete for CPU cycles on the same basis as a
 * forked process cluster by spawning several KSEGRPs.
 */
struct proc;

/***************
 * In pictures:
 With a single run queue used by all processors:

 RUNQ: --->KSE---KSE--...               SLEEPQ:[]---THREAD---THREAD---THREAD
             \      \                          []---THREAD
      KSEG---THREAD--THREAD--THREAD            []
                                               []---THREAD---THREAD

  (processors run THREADs from the KSEG until they are exhausted or
  the KSEG exhausts its quantum)

With PER-CPU run queues:
KSEs on the separate run queues directly
They would be given priorities calculated from the KSEG.

 *
 *****************/

/*
 * Kernel runnable context (thread).
 * This is what is put to sleep and reactivated.
 * The first KSE available in the correct group will run this thread.
 * If several are available, use the one on the same CPU as last time.
 * When waiting to be run, threads are hung off the KSEGRP in priority order.
 * With N runnable and queued KSEs in the KSEGRP, the first N threads
 * are linked to them. Other threads are not yet assigned.
 */
struct thread {
        struct proc     *td_proc;       /* (*) Associated process. */
        struct ksegrp   *td_ksegrp;     /* (*) Associated KSEG. */
        TAILQ_ENTRY(thread) td_plist;   /* (*) All threads in this proc. */
        TAILQ_ENTRY(thread) td_kglist;  /* (*) All threads in this ksegrp. */

        /* The two queues below should someday be merged. */
        TAILQ_ENTRY(thread) td_slpq;    /* (j) Sleep queue. */
        TAILQ_ENTRY(thread) td_lockq;   /* (j) Lock queue. */
        TAILQ_ENTRY(thread) td_runq;    /* (j/z) Run queue(s). XXXKSE */

        TAILQ_HEAD(, selinfo) td_selq;  /* (p) List of selinfos. */
        struct sleepqueue *td_sleepqueue; /* (k) Associated sleep queue. */
        struct turnstile *td_turnstile; /* (k) Associated turnstile. */
        struct umtx_q   *td_umtxq;      /* (c?) Link for when we're blocked. */
        lwpid_t         td_tid;         /* (b) Thread ID. */

/* Cleared during fork1() or thread_schedule_upcall(). */
#define td_startzero td_flags
        int             td_flags;       /* (j) TDF_* flags. */
        int             td_inhibitors;  /* (j) Why can not run. */
        int             td_pflags;      /* (k) Private thread (TDP_*) flags. */
        int             td_dupfd;       /* (k) Ret value from fdopen. XXX */
        void            *td_wchan;      /* (j) Sleep address. */
        const char      *td_wmesg;      /* (j) Reason for sleep. */
        u_char          td_lastcpu;     /* (j) Last cpu we were on. */
        u_char          td_oncpu;       /* (j) Which cpu we are on. */
        volatile u_char td_owepreempt;  /* (k*) Preempt on last critical_exit */
        short           td_locks;       /* (k) DEBUG: lockmgr count of locks. */
        struct turnstile *td_blocked;   /* (j) Lock process is blocked on. */
        struct ithd     *td_ithd;       /* (b) For interrupt threads only. */
        const char      *td_lockname;   /* (j) Name of lock blocked on. */
        LIST_HEAD(, turnstile) td_contested;    /* (q) Contested locks. */
        struct lock_list_entry *td_sleeplocks; /* (k) Held sleep locks. */
        int             td_intr_nesting_level; /* (k) Interrupt recursion. */
        int             td_pinned;      /* (k) Temporary cpu pin count. */
        struct kse_thr_mailbox *td_mailbox; /* (*) Userland mailbox address. */
        struct ucred    *td_ucred;      /* (k) Reference to credentials. */
        struct thread   *td_standin;    /* (k + a) Use this for an upcall. */
        struct kse_upcall *td_upcall;   /* (k + j) Upcall structure. */
        u_int64_t       td_sticks;      /* (k) Statclock hits in system mode. */
        u_int           td_uuticks;     /* (k) Statclock hits (usr), for UTS. */
        u_int           td_usticks;     /* (k) Statclock hits (sys), for UTS. */
        int             td_intrval;     /* (j) Return value of TDF_INTERRUPT. */
        sigset_t        td_oldsigmask;  /* (k) Saved mask from pre sigpause. */
        sigset_t        td_sigmask;     /* (c) Current signal mask. */
        sigset_t        td_siglist;     /* (c) Sigs arrived, not delivered. */
        volatile u_int  td_generation;  /* (k) For detection of preemption */
        stack_t         td_sigstk;      /* (k) Stack ptr and on-stack flag. */
        int             td_kflags;      /* (c) Flags for KSE threading. */
        int             td_xsig;        /* (c) Signal for ptrace */
        u_long          td_profil_addr; /* (k) Temporary addr until AST. */
        u_int           td_profil_ticks; /* (k) Temporary ticks until AST. */
#define td_endzero td_base_pri

/* Copied during fork1() or thread_sched_upcall(). */
#define td_startcopy td_endzero
        u_char          td_base_pri;    /* (j) Thread base kernel priority. */
        u_char          td_priority;    /* (j) Thread active priority. */
#define td_endcopy td_pcb

/*
 * Fields that must be manually set in fork1() or thread_sched_upcall()
 * or already have been set in the allocator, constructor, etc.
 */
        struct pcb      *td_pcb;        /* (k) Kernel VA of pcb and kstack. */
        enum {
                TDS_INACTIVE = 0x0,
                TDS_INHIBITED,
                TDS_CAN_RUN,
                TDS_RUNQ,
                TDS_RUNNING
        } td_state;
        register_t      td_retval[2];   /* (k) Syscall aux returns. */
        struct callout  td_slpcallout;  /* (h) Callout for sleep. */
        struct trapframe *td_frame;     /* (k) */
        struct vm_object *td_kstack_obj;/* (a) Kstack object. */
        vm_offset_t     td_kstack;      /* (a) Kernel VA of kstack. */
        int             td_kstack_pages; /* (a) Size of the kstack. */
        struct vm_object *td_altkstack_obj;/* (a) Alternate kstack object. */
        vm_offset_t     td_altkstack;   /* (a) Kernel VA of alternate kstack. */
        int             td_altkstack_pages; /* (a) Size of alternate kstack. */
        volatile u_int  td_critnest;    /* (k*) Critical section nest level. */
        struct mdthread td_md;          /* (k) Any machine-dependent fields. */
        struct td_sched *td_sched;      /* (*) Scheduler-specific data. */
};

/*
 * Flags kept in td_flags:
 * To change these you MUST have the scheduler lock.
 */
#define TDF_BORROWING   0x00000001 /* Thread is borrowing pri from another. */
#define TDF_INPANIC     0x00000002 /* Caused a panic, let it drive crashdump. */
#define TDF_SINTR       0x00000008 /* Sleep is interruptible. */
#define TDF_TIMEOUT     0x00000010 /* Timing out during sleep. */
#define TDF_IDLETD      0x00000020 /* This is a per-CPU idle thread. */
#define TDF_SELECT      0x00000040 /* Selecting; wakeup/waiting danger. */
#define TDF_UNUSED7     0x00000080 /* --available -- */
#define TDF_TSNOBLOCK   0x00000100 /* Don't block on a turnstile due to race. */
#define TDF_UNUSED9     0x00000200 /* --available -- */
#define TDF_BOUNDARY    0x00000400 /* Thread suspended at user boundary */
#define TDF_ASTPENDING  0x00000800 /* Thread has some asynchronous events. */
#define TDF_TIMOFAIL    0x00001000 /* Timeout from sleep after we were awake. */
#define TDF_INTERRUPT   0x00002000 /* Thread is marked as interrupted. */
#define TDF_UNUSED14    0x00004000 /* --available -- */
#define TDF_UNUSED15    0x00008000 /* --available -- */
#define TDF_NEEDRESCHED 0x00010000 /* Thread needs to yield. */
#define TDF_NEEDSIGCHK  0x00020000 /* Thread may need signal delivery. */
#define TDF_XSIG        0x00040000 /* Thread is exchanging signal under trace */
#define TDF_UMTXQ       0x00080000 /* Thread is sleeping on a umtx. */
#define TDF_THRWAKEUP   0x00100000 /* Libthr thread must not suspend itself. */
#define TDF_DBSUSPEND   0x00200000 /* Thread is suspended by debugger */
#define TDF_UNUSED22    0x00400000 /* --available -- */
#define TDF_UNUSED23    0x00800000 /* --available -- */
#define TDF_SCHED0      0x01000000 /* Reserved for scheduler private use */
#define TDF_SCHED1      0x02000000 /* Reserved for scheduler private use */
#define TDF_SCHED2      0x04000000 /* Reserved for scheduler private use */
#define TDF_SCHED3      0x08000000 /* Reserved for scheduler private use */

/*
 * "Private" flags kept in td_pflags:
 * These are only accessed by curthread and thus need no locking.
 */
#define TDP_OLDMASK     0x00000001 /* Need to restore mask after suspend. */
#define TDP_INKTR       0x00000002 /* Thread is currently in KTR code. */
#define TDP_INKTRACE    0x00000004 /* Thread is currently in KTRACE code. */
#define TDP_UPCALLING   0x00000008 /* This thread is doing an upcall. */
#define TDP_COWINPROGRESS 0x00000010 /* Snapshot copy-on-write in progress. */
#define TDP_ALTSTACK    0x00000020 /* Have alternate signal stack. */
#define TDP_DEADLKTREAT 0x00000040 /* Lock aquisition - deadlock treatment. */
#define TDP_SA          0x00000080 /* A scheduler activation based thread. */
#define TDP_UNUSED8     0x00000100 /* --available -- */
#define TDP_OWEUPC      0x00000200 /* Call addupc() at next AST. */
#define TDP_WAKEPROC0   0x00000400 /* Wants caller to wakeup(&proc0) */
#define TDP_CAN_UNBIND  0x00000800 /* Only temporarily bound. */
#define TDP_SCHED1      0x00001000 /* Reserved for scheduler private use */
#define TDP_SCHED2      0x00002000 /* Reserved for scheduler private use */
#define TDP_SCHED3      0x00004000 /* Reserved for scheduler private use */
#define TDP_SCHED4      0x00008000 /* Reserved for scheduler private use */
#define TDP_GEOM        0x00010000 /* Settle GEOM before finishing syscall */
#define TDP_SOFTDEP     0x00020000 /* Stuck processing softdep worklist */

/*
 * Reasons that the current thread can not be run yet.
 * More than one may apply.
 */
#define TDI_SUSPENDED   0x0001  /* On suspension queue. */
#define TDI_SLEEPING    0x0002  /* Actually asleep! (tricky). */
#define TDI_SWAPPED     0x0004  /* Stack not in mem.  Bad juju if run. */
#define TDI_LOCK        0x0008  /* Stopped on a lock. */
#define TDI_IWAIT       0x0010  /* Awaiting interrupt. */

/*
 * flags (in kflags) related to M:N threading.
 */
#define TDK_KSEREL      0x0001  /* Blocked in msleep on kg->kg_completed. */
#define TDK_KSERELSIG   0x0002  /* Blocked in msleep on p->p_siglist. */
#define TDK_WAKEUP      0x0004  /* Thread has been woken by kse_wakeup. */

#define TD_CAN_UNBIND(td)                       \
    (((td)->td_pflags & TDP_CAN_UNBIND) &&      \
     ((td)->td_upcall != NULL))

#define TD_IS_SLEEPING(td)      ((td)->td_inhibitors & TDI_SLEEPING)
#define TD_ON_SLEEPQ(td)        ((td)->td_wchan != NULL)
#define TD_IS_SUSPENDED(td)     ((td)->td_inhibitors & TDI_SUSPENDED)
#define TD_IS_SWAPPED(td)       ((td)->td_inhibitors & TDI_SWAPPED)
#define TD_ON_LOCK(td)          ((td)->td_inhibitors & TDI_LOCK)
#define TD_AWAITING_INTR(td)    ((td)->td_inhibitors & TDI_IWAIT)
#define TD_IS_RUNNING(td)       ((td)->td_state == TDS_RUNNING)
#define TD_ON_RUNQ(td)          ((td)->td_state == TDS_RUNQ)
#define TD_CAN_RUN(td)          ((td)->td_state == TDS_CAN_RUN)
#define TD_IS_INHIBITED(td)     ((td)->td_state == TDS_INHIBITED)

#define TD_SET_INHIB(td, inhib) do {                    \
        (td)->td_state = TDS_INHIBITED;                 \
        (td)->td_inhibitors |= (inhib);                 \
} while (0)

#define TD_CLR_INHIB(td, inhib) do {                    \
        if (((td)->td_inhibitors & (inhib)) &&          \
            (((td)->td_inhibitors &= ~(inhib)) == 0))   \
                (td)->td_state = TDS_CAN_RUN;           \
} while (0)

#define TD_SET_SLEEPING(td)     TD_SET_INHIB((td), TDI_SLEEPING)
#define TD_SET_SWAPPED(td)      TD_SET_INHIB((td), TDI_SWAPPED)
#define TD_SET_LOCK(td)         TD_SET_INHIB((td), TDI_LOCK)
#define TD_SET_SUSPENDED(td)    TD_SET_INHIB((td), TDI_SUSPENDED)
#define TD_SET_IWAIT(td)        TD_SET_INHIB((td), TDI_IWAIT)
#define TD_SET_EXITING(td)      TD_SET_INHIB((td), TDI_EXITING)

#define TD_CLR_SLEEPING(td)     TD_CLR_INHIB((td), TDI_SLEEPING)
#define TD_CLR_SWAPPED(td)      TD_CLR_INHIB((td), TDI_SWAPPED)
#define TD_CLR_LOCK(td)         TD_CLR_INHIB((td), TDI_LOCK)
#define TD_CLR_SUSPENDED(td)    TD_CLR_INHIB((td), TDI_SUSPENDED)
#define TD_CLR_IWAIT(td)        TD_CLR_INHIB((td), TDI_IWAIT)

#define TD_SET_RUNNING(td)      (td)->td_state = TDS_RUNNING
#define TD_SET_RUNQ(td)         (td)->td_state = TDS_RUNQ
#define TD_SET_CAN_RUN(td)      (td)->td_state = TDS_CAN_RUN

/*
 * An upcall is used when returning to userland.  If a thread does not have
 * an upcall on return to userland the thread exports its context and exits.
 */
struct kse_upcall {
        TAILQ_ENTRY(kse_upcall) ku_link;        /* List of upcalls in KSEG. */
        struct ksegrp           *ku_ksegrp;     /* Associated KSEG. */
        struct thread           *ku_owner;      /* Owning thread. */
        int                     ku_flags;       /* KUF_* flags. */
        struct kse_mailbox      *ku_mailbox;    /* Userland mailbox address. */
        stack_t                 ku_stack;       /* Userland upcall stack. */
        void                    *ku_func;       /* Userland upcall function. */
        unsigned int            ku_mflags;      /* Cached upcall mbox flags. */
};

#define KUF_DOUPCALL    0x00001         /* Do upcall now; don't wait. */
#define KUF_EXITING     0x00002         /* Upcall structure is exiting. */

/*
 * Kernel-scheduled entity group (KSEG).  The scheduler considers each KSEG to
 * be an indivisible unit from a time-sharing perspective, though each KSEG may
 * contain multiple KSEs.
 */
struct ksegrp {
        struct proc     *kg_proc;       /* (*) Proc that contains this KSEG. */
        TAILQ_ENTRY(ksegrp) kg_ksegrp;  /* (*) Queue of KSEGs in kg_proc. */
        TAILQ_HEAD(, thread) kg_threads;/* (td_kglist) All threads. */
        TAILQ_HEAD(, thread) kg_runq;   /* (td_runq) waiting RUNNABLE threads */
        TAILQ_HEAD(, kse_upcall) kg_upcalls;    /* All upcalls in the group. */

#define kg_startzero kg_estcpu
        u_int           kg_estcpu;      /* (j) Sum of the same field in KSEs. */
        u_int           kg_slptime;     /* (j) How long completely blocked. */
        int             kg_numupcalls;  /* (j) Num upcalls. */
        int             kg_upsleeps;    /* (c) Num threads in kse_release(). */
        struct kse_thr_mailbox *kg_completed; /* (c) Completed thread mboxes. */
        int             kg_nextupcall;  /* (n) Next upcall time. */
        int             kg_upquantum;   /* (n) Quantum to schedule an upcall. */
#define kg_endzero kg_pri_class

#define kg_startcopy    kg_endzero
        u_char          kg_pri_class;   /* (j) Scheduling class. */
        u_char          kg_user_pri;    /* (j) User pri from estcpu and nice. */
#define kg_endcopy kg_numthreads
        int             kg_numthreads;  /* (j) Num threads in total. */
        struct kg_sched *kg_sched;      /* (*) Scheduler-specific data. */
};

/*
 * XXX: Does this belong in resource.h or resourcevar.h instead?
 * Resource usage extension.  The times in rusage structs in the kernel are
 * never up to date.  The actual times are kept as runtimes and tick counts
 * (with control info in the "previous" times), and are converted when
 * userland asks for rusage info.  Backwards compatibility prevents putting
 * this directly in the user-visible rusage struct.
 *
 * Locking: (cj) means (j) for p_rux and (c) for p_crux.
 */
struct rusage_ext {
        struct bintime  rux_runtime;    /* (cj) Real time. */
        u_int64_t       rux_uticks;     /* (cj) Statclock hits in user mode. */
        u_int64_t       rux_sticks;     /* (cj) Statclock hits in sys mode. */
        u_int64_t       rux_iticks;     /* (cj) Statclock hits in intr mode. */
        u_int64_t       rux_uu;         /* (c) Previous user time in usec. */
        u_int64_t       rux_su;         /* (c) Previous sys time in usec. */
        u_int64_t       rux_iu;         /* (c) Previous intr time in usec. */
};

/*
 * The old fashionned process. May have multiple threads, KSEGRPs
 * and KSEs. Starts off with a single embedded KSEGRP and THREAD.
 */
struct proc {
        LIST_ENTRY(proc) p_list;        /* (d) List of all processes. */
        TAILQ_HEAD(, ksegrp) p_ksegrps; /* (c)(kg_ksegrp) All KSEGs. */
        TAILQ_HEAD(, thread) p_threads; /* (j)(td_plist) Threads. (shortcut) */
        TAILQ_HEAD(, thread) p_suspended; /* (td_runq) Suspended threads. */
        struct ucred    *p_ucred;       /* (c) Process owner's identity. */
        struct filedesc *p_fd;          /* (b) Open files. */
        struct filedesc_to_leader *p_fdtol; /* (b) Tracking node */
                                        /* Accumulated stats for all threads? */
        struct pstats   *p_stats;       /* (b) Accounting/statistics (CPU). */
        struct plimit   *p_limit;       /* (c) Process limits. */
        struct sigacts  *p_sigacts;     /* (x) Signal actions, state (CPU). */

        /*
         * The following don't make too much sense.
         * See the td_ or ke_ versions of the same flags.
         */
        int             p_flag;         /* (c) P_* flags. */
        int             p_sflag;        /* (j) PS_* flags. */
        enum {
                PRS_NEW = 0,            /* In creation */
                PRS_NORMAL,             /* threads can be run. */
                PRS_ZOMBIE
        } p_state;                      /* (j/c) S* process status. */

        pid_t           p_pid;          /* (b) Process identifier. */
        LIST_ENTRY(proc) p_hash;        /* (d) Hash chain. */
        LIST_ENTRY(proc) p_pglist;      /* (g + e) List of processes in pgrp. */
        struct proc     *p_pptr;        /* (c + e) Pointer to parent process. */
        LIST_ENTRY(proc) p_sibling;     /* (e) List of sibling processes. */
        LIST_HEAD(, proc) p_children;   /* (e) Pointer to list of children. */
        struct mtx      p_mtx;          /* (n) Lock for this struct. */

/* The following fields are all zeroed upon creation in fork. */
#define p_startzero     p_oppid
        pid_t           p_oppid;        /* (c + e) Save ppid in ptrace. XXX */
        struct vmspace  *p_vmspace;     /* (b) Address space. */
        u_int           p_swtime;       /* (j) Time swapped in or out. */
        struct itimerval p_realtimer;   /* (c) Alarm timer. */
        struct rusage_ext p_rux;        /* (cj) Internal resource usage. */
        struct rusage_ext p_crux;       /* (c) Internal child resource usage. */
        int             p_profthreads;  /* (c) Num threads in addupc_task. */
        int             p_maxthrwaits;  /* (c) Max threads num waiters */
        int             p_traceflag;    /* (o) Kernel trace points. */
        struct vnode    *p_tracevp;     /* (c + o) Trace to vnode. */
        struct ucred    *p_tracecred;   /* (o) Credentials to trace with. */
        struct vnode    *p_textvp;      /* (b) Vnode of executable. */
        sigset_t        p_siglist;      /* (c) Sigs not delivered to a td. */
        char            p_lock;         /* (c) Proclock (prevent swap) count. */
        struct sigiolst p_sigiolst;     /* (c) List of sigio sources. */
        int             p_sigparent;    /* (c) Signal to parent on exit. */
        int             p_sig;          /* (n) For core dump/debugger XXX. */
        u_long          p_code;         /* (n) For core dump/debugger XXX. */
        u_int           p_stops;        /* (c) Stop event bitmask. */
        u_int           p_stype;        /* (c) Stop event type. */
        char            p_step;         /* (c) Process is stopped. */
        u_char          p_pfsflags;     /* (c) Procfs flags. */
        struct nlminfo  *p_nlminfo;     /* (?) Only used by/for lockd. */
        struct kaioinfo *p_aioinfo;     /* (?) ASYNC I/O info. */
        struct thread   *p_singlethread;/* (c + j) If single threading this is it */
        int             p_suspcount;    /* (c) Num threads in suspended mode. */
        struct thread   *p_xthread;     /* (c) Trap thread */
        int             p_boundary_count;/* (c) Num threads at user boundary */
        struct ksegrp   *p_procscopegrp;
/* End area that is zeroed on creation. */
#define p_endzero       p_magic

/* The following fields are all copied upon creation in fork. */
#define p_startcopy     p_endzero
        u_int           p_magic;        /* (b) Magic number. */
        char            p_comm[MAXCOMLEN + 1];  /* (b) Process name. */
        struct pgrp     *p_pgrp;        /* (c + e) Pointer to process group. */
        struct sysentvec *p_sysent;     /* (b) Syscall dispatch info. */
        struct pargs    *p_args;        /* (c) Process arguments. */
        rlim_t          p_cpulimit;     /* (j) Current CPU limit in seconds. */
        signed char     p_nice;         /* (c + j) Process "nice" value. */
/* End area that is copied on creation. */
#define p_endcopy       p_xstat

        u_short         p_xstat;        /* (c) Exit status; also stop sig. */
        struct knlist   p_klist;        /* (c) Knotes attached to this proc. */
        int             p_numthreads;   /* (j) Number of threads. */
        int             p_numksegrps;   /* (c) Number of ksegrps. */
        struct mdproc   p_md;           /* Any machine-dependent fields. */
        struct callout  p_itcallout;    /* (h + c) Interval timer callout. */
        u_short         p_acflag;       /* (c) Accounting flags. */
        struct rusage   *p_ru;          /* (a) Exit information. XXX */
        struct proc     *p_peers;       /* (r) */
        struct proc     *p_leader;      /* (b) */
        void            *p_emuldata;    /* (c) Emulator state data. */
        struct label    *p_label;       /* (*) Proc (not subject) MAC label. */
        struct p_sched  *p_sched;       /* (*) Scheduler-specific data. */
};

#define p_session       p_pgrp->pg_session
#define p_pgid          p_pgrp->pg_id

#define NOCPU   0xff            /* For when we aren't on a CPU. */


/* These flags are kept in p_flag. */
#define P_ADVLOCK       0x00001 /* Process may hold a POSIX advisory lock. */
#define P_CONTROLT      0x00002 /* Has a controlling terminal. */
#define P_KTHREAD       0x00004 /* Kernel thread (*). */
#define P_NOLOAD        0x00008 /* Ignore during load avg calculations. */
#define P_PPWAIT        0x00010 /* Parent is waiting for child to exec/exit. */
#define P_PROFIL        0x00020 /* Has started profiling. */
#define P_STOPPROF      0x00040 /* Has thread requesting to stop profiling. */
#define P_HADTHREADS    0x00080 /* Has had threads (no cleanup shortcuts) */
#define P_SUGID         0x00100 /* Had set id privileges since last exec. */
#define P_SYSTEM        0x00200 /* System proc: no sigs, stats or swapping. */
#define P_SINGLE_EXIT   0x00400 /* Threads suspending should exit, not wait. */
#define P_TRACED        0x00800 /* Debugged process being traced. */
#define P_WAITED        0x01000 /* Someone is waiting for us. */
#define P_WEXIT         0x02000 /* Working on exiting. */
#define P_EXEC          0x04000 /* Process called exec. */
#define P_SA            0x08000 /* Using scheduler activations. */
#define P_CONTINUED     0x10000 /* Proc has continued from a stopped state. */
#define P_STOPPED_SIG   0x20000 /* Stopped due to SIGSTOP/SIGTSTP. */
#define P_STOPPED_TRACE 0x40000 /* Stopped because of tracing. */
#define P_STOPPED_SINGLE 0x80000 /* Only 1 thread can continue (not to user). */
#define P_PROTECTED     0x100000 /* Do not kill on memory overcommit. */
#define P_SIGEVENT      0x200000 /* Process pending signals changed. */
#define P_SINGLE_BOUNDARY 0x400000 /* Threads should suspend at user boundary. */
#define P_HWPMC         0x800000 /* Process is using HWPMCs */

#define P_JAILED        0x1000000 /* Process is in jail. */
#define P_INEXEC        0x4000000 /* Process is in execve(). */
#define P_STATCHILD     0x8000000 /* Child process stopped or exited. */

#define P_STOPPED       (P_STOPPED_SIG|P_STOPPED_SINGLE|P_STOPPED_TRACE)
#define P_SHOULDSTOP(p) ((p)->p_flag & P_STOPPED)

/* These flags are kept in p_sflag and are protected with sched_lock. */
#define PS_INMEM        0x00001 /* Loaded into memory. */
#define PS_XCPU         0x00002 /* Exceeded CPU limit. */
#define PS_ALRMPEND     0x00020 /* Pending SIGVTALRM needs to be posted. */
#define PS_PROFPEND     0x00040 /* Pending SIGPROF needs to be posted. */
#define PS_SWAPINREQ    0x00100 /* Swapin request due to wakeup. */
#define PS_SWAPPINGOUT  0x00200 /* Process is being swapped out. */
#define PS_SWAPPINGIN   0x04000 /* Process is being swapped in. */
#define PS_MACPEND      0x08000 /* AST-based MAC event pending. */

/*
 * These were process status values (p_stat), now they are only used in
 * legacy conversion code.
 */
#define SIDL    1               /* Process being created by fork. */
#define SRUN    2               /* Currently runnable. */
#define SSLEEP  3               /* Sleeping on an address. */
#define SSTOP   4               /* Process debugging or suspension. */
#define SZOMB   5               /* Awaiting collection by parent. */
#define SWAIT   6               /* Waiting for interrupt. */
#define SLOCK   7               /* Blocked on a lock. */

#define P_MAGIC         0xbeefface

#ifdef _KERNEL

/* Flags for mi_switch(). */
#define SW_VOL          0x0001          /* Voluntary switch. */
#define SW_INVOL        0x0002          /* Involuntary switch. */
#define SW_PREEMPT      0x0004          /* The invol switch is a preemption */

/* Flags for setrunqueue().  Why are we setting this thread on the run queue? */
#define SRQ_BORING      0x0000          /* No special circumstances. */
#define SRQ_YIELDING    0x0001          /* We are yielding (from mi_switch). */
#define SRQ_OURSELF     0x0002          /* It is ourself (from mi_switch). */
#define SRQ_INTR        0x0004          /* It is probably urgent. */
#define SRQ_PREEMPTED   0x0008          /* has been preempted.. be kind */

/* How values for thread_single(). */
#define SINGLE_NO_EXIT  0
#define SINGLE_EXIT     1
#define SINGLE_BOUNDARY 2

/* XXXKSE: Missing values for thread_suspsend_check(). */

#ifdef MALLOC_DECLARE
MALLOC_DECLARE(M_PARGS);
MALLOC_DECLARE(M_PGRP);
MALLOC_DECLARE(M_SESSION);
MALLOC_DECLARE(M_SUBPROC);
MALLOC_DECLARE(M_ZOMBIE);
#endif

#define FOREACH_PROC_IN_SYSTEM(p)                                       \
        LIST_FOREACH((p), &allproc, p_list)
#define FOREACH_KSEGRP_IN_PROC(p, kg)                                   \
        TAILQ_FOREACH((kg), &(p)->p_ksegrps, kg_ksegrp)
#define FOREACH_THREAD_IN_GROUP(kg, td)                                 \
        TAILQ_FOREACH((td), &(kg)->kg_threads, td_kglist)
#define FOREACH_UPCALL_IN_GROUP(kg, ku)                                 \
        TAILQ_FOREACH((ku), &(kg)->kg_upcalls, ku_link)
#define FOREACH_THREAD_IN_PROC(p, td)                                   \
        TAILQ_FOREACH((td), &(p)->p_threads, td_plist)

/* XXXKSE the following lines should probably only be used in 1:1 code: */
#define FIRST_THREAD_IN_PROC(p) TAILQ_FIRST(&(p)->p_threads)
#define FIRST_KSEGRP_IN_PROC(p) TAILQ_FIRST(&(p)->p_ksegrps)

/*
 * We use process IDs <= PID_MAX; PID_MAX + 1 must also fit in a pid_t,
 * as it is used to represent "no process group".
 */
#define PID_MAX         99999
#define NO_PID          100000

#define SESS_LEADER(p)  ((p)->p_session->s_leader == (p))
#define SESSHOLD(s)     ((s)->s_count++)
#define SESSRELE(s)     sessrele(s)


#define STOPEVENT(p, e, v) do {                                         \
        if ((p)->p_stops & (e)) {                                       \
                PROC_LOCK(p);                                           \
                stopevent((p), (e), (v));                               \
                PROC_UNLOCK(p);                                         \
        }                                                               \
} while (0)
#define _STOPEVENT(p, e, v) do {                                        \
        PROC_LOCK_ASSERT(p, MA_OWNED);                                  \
        WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, &p->p_mtx.mtx_object, \
            "checking stopevent %d", (e));                              \
        if ((p)->p_stops & (e))                                         \
                stopevent((p), (e), (v));                               \
} while (0)

/* Lock and unlock a process. */
#define PROC_LOCK(p)    mtx_lock(&(p)->p_mtx)
#define PROC_TRYLOCK(p) mtx_trylock(&(p)->p_mtx)
#define PROC_UNLOCK(p)  mtx_unlock(&(p)->p_mtx)
#define PROC_LOCKED(p)  mtx_owned(&(p)->p_mtx)
#define PROC_LOCK_ASSERT(p, type)       mtx_assert(&(p)->p_mtx, (type))

/* Lock and unlock a process group. */
#define PGRP_LOCK(pg)   mtx_lock(&(pg)->pg_mtx)
#define PGRP_UNLOCK(pg) mtx_unlock(&(pg)->pg_mtx)
#define PGRP_LOCKED(pg) mtx_owned(&(pg)->pg_mtx)
#define PGRP_LOCK_ASSERT(pg, type)      mtx_assert(&(pg)->pg_mtx, (type))

#define PGRP_LOCK_PGSIGNAL(pg) do {                                     \
        if ((pg) != NULL)                                               \
                PGRP_LOCK(pg);                                          \
} while (0)
#define PGRP_UNLOCK_PGSIGNAL(pg) do {                                   \
        if ((pg) != NULL)                                               \
                PGRP_UNLOCK(pg);                                        \
} while (0)

/* Lock and unlock a session. */
#define SESS_LOCK(s)    mtx_lock(&(s)->s_mtx)
#define SESS_UNLOCK(s)  mtx_unlock(&(s)->s_mtx)
#define SESS_LOCKED(s)  mtx_owned(&(s)->s_mtx)
#define SESS_LOCK_ASSERT(s, type)       mtx_assert(&(s)->s_mtx, (type))

/* Hold process U-area in memory, normally for ptrace/procfs work. */
#define PHOLD(p) do {                                                   \
        PROC_LOCK(p);                                                   \
        _PHOLD(p);                                                      \
        PROC_UNLOCK(p);                                                 \
} while (0)
#define _PHOLD(p) do {                                                  \
        PROC_LOCK_ASSERT((p), MA_OWNED);                                \
        (p)->p_lock++;                                                  \
        if (((p)->p_sflag & PS_INMEM) == 0)                             \
                faultin((p));                                           \
} while (0)

#define PRELE(p) do {                                                   \
        PROC_LOCK((p));                                                 \
        _PRELE((p));                                                    \
        PROC_UNLOCK((p));                                               \
} while (0)
#define _PRELE(p) do {                                                  \
        PROC_LOCK_ASSERT((p), MA_OWNED);                                \
        (--(p)->p_lock);                                                \
} while (0)

/* Check whether a thread is safe to be swapped out. */
#define thread_safetoswapout(td) (TD_IS_SLEEPING(td) || TD_IS_SUSPENDED(td))

/* Lock and unlock process arguments. */
#define PARGS_LOCK(p)           mtx_lock(&pargs_ref_lock)
#define PARGS_UNLOCK(p)         mtx_unlock(&pargs_ref_lock)

#define PIDHASH(pid)    (&pidhashtbl[(pid) & pidhash])
extern LIST_HEAD(pidhashhead, proc) *pidhashtbl;
extern u_long pidhash;

#define PGRPHASH(pgid)  (&pgrphashtbl[(pgid) & pgrphash])
extern LIST_HEAD(pgrphashhead, pgrp) *pgrphashtbl;
extern u_long pgrphash;

extern struct sx allproc_lock;
extern struct sx proctree_lock;
extern struct mtx pargs_ref_lock;
extern struct mtx ppeers_lock;
extern struct ksegrp ksegrp0;           /* Primary ksegrp in proc0. */
extern struct proc proc0;               /* Process slot for swapper. */
extern struct thread thread0;           /* Primary thread in proc0. */
extern struct vmspace vmspace0;         /* VM space for proc0. */
extern int hogticks;                    /* Limit on kernel cpu hogs. */
extern int lastpid;
extern int nprocs, maxproc;             /* Current and max number of procs. */
extern int maxprocperuid;               /* Max procs per uid. */
extern u_long ps_arg_cache_limit;
extern int sched_quantum;               /* Scheduling quantum in ticks. */

LIST_HEAD(proclist, proc);
TAILQ_HEAD(procqueue, proc);
TAILQ_HEAD(threadqueue, thread);
extern struct proclist allproc;         /* List of all processes. */
extern struct proclist zombproc;        /* List of zombie processes. */
extern struct proc *initproc, *pageproc; /* Process slots for init, pager. */
extern struct proc *updateproc;         /* Process slot for syncer (sic). */

extern struct uma_zone *proc_zone;

struct  proc *pfind(pid_t);             /* Find process by id. */
struct  pgrp *pgfind(pid_t);            /* Find process group by id. */
struct  proc *zpfind(pid_t);            /* Find zombie process by id. */

void    adjustrunqueue(struct thread *, int newpri);
void    ast(struct trapframe *framep);
struct  thread *choosethread(void);
int     cr_cansignal(struct ucred *cred, struct proc *proc, int signum);
int     enterpgrp(struct proc *p, pid_t pgid, struct pgrp *pgrp,
            struct session *sess);
int     enterthispgrp(struct proc *p, struct pgrp *pgrp);
void    faultin(struct proc *p);
void    fixjobc(struct proc *p, struct pgrp *pgrp, int entering);
int     fork1(struct thread *, int, int, struct proc **);
void    fork_exit(void (*)(void *, struct trapframe *), void *,
            struct trapframe *);
void    fork_return(struct thread *, struct trapframe *);
int     inferior(struct proc *p);
int     leavepgrp(struct proc *p);
int     maybe_preempt(struct thread *td);
void    mi_switch(int flags, struct thread *newtd);
int     p_candebug(struct thread *td, struct proc *p);
int     p_cansee(struct thread *td, struct proc *p);
int     p_cansched(struct thread *td, struct proc *p);
int     p_cansignal(struct thread *td, struct proc *p, int signum);
int     p_canwait(struct thread *td, struct proc *p);
struct  pargs *pargs_alloc(int len);
void    pargs_drop(struct pargs *pa);
void    pargs_free(struct pargs *pa);
void    pargs_hold(struct pargs *pa);
void    procinit(void);
void    proc_linkup(struct proc *p, struct ksegrp *kg, struct thread *td);
void    proc_reparent(struct proc *child, struct proc *newparent);
struct  pstats *pstats_alloc(void);
void    pstats_fork(struct pstats *src, struct pstats *dst);
void    pstats_free(struct pstats *ps);
int     securelevel_ge(struct ucred *cr, int level);
int     securelevel_gt(struct ucred *cr, int level);
void    sessrele(struct session *);
void    setrunnable(struct thread *);
void    setrunqueue(struct thread *, int flags);
void    setsugid(struct proc *p);
int     sigonstack(size_t sp);
void    sleepinit(void);
void    stopevent(struct proc *, u_int, u_int);
void    threadinit(void);
void    cpu_idle(void);
extern  void (*cpu_idle_hook)(void);    /* Hook to machdep CPU idler. */
void    cpu_switch(struct thread *old, struct thread *new);
void    cpu_throw(struct thread *old, struct thread *new) __dead2;
void    unsleep(struct thread *);
void    userret(struct thread *, struct trapframe *, u_int);

void    cpu_exit(struct thread *);
void    exit1(struct thread *, int) __dead2;
void    cpu_fork(struct thread *, struct proc *, struct thread *, int);
void    cpu_set_fork_handler(struct thread *, void (*)(void *), void *);

/* New in KSE. */
struct  ksegrp *ksegrp_alloc(void);
void    ksegrp_free(struct ksegrp *kg);
void    ksegrp_stash(struct ksegrp *kg);
void    kse_GC(void);
void    kseinit(void);
void    cpu_set_upcall(struct thread *td, struct thread *td0);
void    cpu_set_upcall_kse(struct thread *, void (*)(void *), void *, stack_t *);
void    cpu_set_user_tls(struct thread *, void *tls_base);
void    cpu_thread_clean(struct thread *);
void    cpu_thread_exit(struct thread *);
void    cpu_thread_setup(struct thread *td);
void    cpu_thread_siginfo(int sig, u_long code, siginfo_t *si);
void    cpu_thread_swapin(struct thread *);
void    cpu_thread_swapout(struct thread *);
void    ksegrp_link(struct ksegrp *kg, struct proc *p);
void    ksegrp_unlink(struct ksegrp *kg);
struct  thread *thread_alloc(void);
void    thread_continued(struct proc *p);
void    thread_exit(void) __dead2;
int     thread_export_context(struct thread *td, int willexit);
void    thread_free(struct thread *td);
void    thread_link(struct thread *td, struct ksegrp *kg);
void    thread_reap(void);
struct thread *thread_schedule_upcall(struct thread *td, struct kse_upcall *ku);
void    thread_signal_add(struct thread *td, int sig);
int     thread_single(int how);
void    thread_single_end(void);
int     thread_sleep_check(struct thread *td);
void    thread_stash(struct thread *td);
int     thread_statclock(int user);
void    thread_stopped(struct proc *p);
int     thread_suspend_check(int how);
void    thread_suspend_one(struct thread *td);
struct thread *thread_switchout(struct thread *td, int flags,
            struct thread *newtd);
void    thread_unlink(struct thread *td);
void    thread_unsuspend(struct proc *p);
void    thread_unsuspend_one(struct thread *td);
int     thread_upcall_check(struct thread *td);
void    thread_unthread(struct thread *td);
int     thread_userret(struct thread *td, struct trapframe *frame);
void    thread_user_enter(struct thread *td);
void    thread_wait(struct proc *p);
void    thr_exit1(void);
struct kse_upcall *upcall_alloc(void);
void    upcall_free(struct kse_upcall *ku);
void    upcall_link(struct kse_upcall *ku, struct ksegrp *kg);
void    upcall_unlink(struct kse_upcall *ku);
void    upcall_remove(struct thread *td);
void    upcall_stash(struct kse_upcall *ke);

#endif  /* _KERNEL */

#endif  /* !_SYS_PROC_H_ */