server/mutex.c

   1 /*
   2  * Server-side mutex management
   3  *
   4  * Copyright (C) 1998 Alexandre Julliard
   5  */
   6
   7 #include <assert.h>
   8 #include <stdio.h>
   9 #include <stdlib.h>
  10
  11 #include "winnt.h"
  12
  13 #include "handle.h"
  14 #include "thread.h"
  15 #include "request.h"
  16
  17 struct mutex
  18 {
  19     struct object  obj;             /* object header */
  20     struct thread *owner;           /* mutex owner */
  21     unsigned int   count;           /* recursion count */
  22     int            abandoned;       /* has it been abandoned? */
  23     struct mutex  *next;
  24     struct mutex  *prev;
  25 };
  26
  27 static void mutex_dump( struct object *obj, int verbose );
  28 static int mutex_signaled( struct object *obj, struct thread *thread );
  29 static int mutex_satisfied( struct object *obj, struct thread *thread );
  30 static void mutex_destroy( struct object *obj );
  31
  32 static const struct object_ops mutex_ops =
  33 {
  34     sizeof(struct mutex),      /* size */
  35     mutex_dump,                /* dump */
  36     add_queue,                 /* add_queue */
  37     remove_queue,              /* remove_queue */
  38     mutex_signaled,            /* signaled */
  39     mutex_satisfied,           /* satisfied */
  40     NULL,                      /* get_poll_events */
  41     NULL,                      /* poll_event */
  42     no_get_fd,                 /* get_fd */
  43     no_flush,                  /* flush */
  44     no_get_file_info,          /* get_file_info */
  45     mutex_destroy              /* destroy */
  46 };
  47
  48
  49 static struct mutex *create_mutex( const WCHAR *name, size_t len, int owned )
  50 {
  51     struct mutex *mutex;
  52
  53     if ((mutex = create_named_object( &mutex_ops, name, len )))
  54     {
  55         if (get_error() != STATUS_OBJECT_NAME_COLLISION)
  56         {
  57             /* initialize it if it didn't already exist */
  58             mutex->count = 0;
  59             mutex->owner = NULL;
  60             mutex->abandoned = 0;
  61             mutex->next = mutex->prev = NULL;
  62             if (owned) mutex_satisfied( &mutex->obj, current );
  63         }
  64     }
  65     return mutex;
  66 }
  67
  68 /* release a mutex once the recursion count is 0 */
  69 static void do_release( struct mutex *mutex )
  70 {
  71     assert( !mutex->count );
  72     /* remove the mutex from the thread list of owned mutexes */
  73     if (mutex->next) mutex->next->prev = mutex->prev;
  74     if (mutex->prev) mutex->prev->next = mutex->next;
  75     else mutex->owner->mutex = mutex->next;
  76     mutex->owner = NULL;
  77     mutex->next = mutex->prev = NULL;
  78     wake_up( &mutex->obj, 0 );
  79 }
  80
  81 void abandon_mutexes( struct thread *thread )
  82 {
  83     while (thread->mutex)
  84     {
  85         struct mutex *mutex = thread->mutex;
  86         assert( mutex->owner == thread );
  87         mutex->count = 0;
  88         mutex->abandoned = 1;
  89         do_release( mutex );
  90     }
  91 }
  92
  93 static void mutex_dump( struct object *obj, int verbose )
  94 {
  95     struct mutex *mutex = (struct mutex *)obj;
  96     assert( obj->ops == &mutex_ops );
  97     fprintf( stderr, "Mutex count=%u owner=%p ", mutex->count, mutex->owner );
  98     dump_object_name( &mutex->obj );
  99     fputc( '\n', stderr );
 100 }
 101
 102 static int mutex_signaled( struct object *obj, struct thread *thread )
 103 {
 104     struct mutex *mutex = (struct mutex *)obj;
 105     assert( obj->ops == &mutex_ops );
 106     return (!mutex->count || (mutex->owner == thread));
 107 }
 108
 109 static int mutex_satisfied( struct object *obj, struct thread *thread )
 110 {
 111     struct mutex *mutex = (struct mutex *)obj;
 112     assert( obj->ops == &mutex_ops );
 113     assert( !mutex->count || (mutex->owner == thread) );
 114
 115     if (!mutex->count++)  /* FIXME: avoid wrap-around */
 116     {
 117         assert( !mutex->owner );
 118         mutex->owner = thread;
 119         mutex->prev  = NULL;
 120         if ((mutex->next = thread->mutex)) mutex->next->prev = mutex;
 121         thread->mutex = mutex;
 122     }
 123     if (!mutex->abandoned) return 0;
 124     mutex->abandoned = 0;
 125     return 1;
 126 }
 127
 128 static void mutex_destroy( struct object *obj )
 129 {
 130     struct mutex *mutex = (struct mutex *)obj;
 131     assert( obj->ops == &mutex_ops );
 132
 133     if (!mutex->count) return;
 134     mutex->count = 0;
 135     do_release( mutex );
 136 }
 137
 138 /* create a mutex */
 139 DECL_HANDLER(create_mutex)
 140 {
 141     struct mutex *mutex;
 142
 143     req->handle = 0;
 144     if ((mutex = create_mutex( get_req_data(req), get_req_data_size(req), req->owned )))
 145     {
 146         req->handle = alloc_handle( current->process, mutex, MUTEX_ALL_ACCESS, req->inherit );
 147         release_object( mutex );
 148     }
 149 }
 150
 151 /* open a handle to a mutex */
 152 DECL_HANDLER(open_mutex)
 153 {
 154     req->handle = open_object( get_req_data(req), get_req_data_size(req),
 155                                &mutex_ops, req->access, req->inherit );
 156 }
 157
 158 /* release a mutex */
 159 DECL_HANDLER(release_mutex)
 160 {
 161     struct mutex *mutex;
 162
 163     if ((mutex = (struct mutex *)get_handle_obj( current->process, req->handle,
 164                                                  MUTEX_MODIFY_STATE, &mutex_ops )))
 165     {
 166         if (!mutex->count || (mutex->owner != current)) set_error( STATUS_MUTANT_NOT_OWNED );
 167         else if (!--mutex->count) do_release( mutex );
 168         release_object( mutex );
 169     }
 170 }