Sweden-Number/server/thread.c

756 lines
21 KiB
C

/*
* Server-side thread management
*
* Copyright (C) 1998 Alexandre Julliard
*/
#include "config.h"
#include <assert.h>
#include <fcntl.h>
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#ifdef HAVE_SYS_MMAN_H
#include <sys/mman.h>
#endif
#include <sys/ptrace.h>
#include <sys/types.h>
#include <sys/uio.h>
#include <sys/wait.h>
#include <unistd.h>
#include <stdarg.h>
#include "winbase.h"
#include "winerror.h"
#include "handle.h"
#include "process.h"
#include "thread.h"
#include "request.h"
/* thread queues */
struct wait_queue_entry
{
struct wait_queue_entry *next;
struct wait_queue_entry *prev;
struct object *obj;
struct thread *thread;
};
struct thread_wait
{
int count; /* count of objects */
int flags;
struct timeval timeout;
struct timeout_user *user;
struct wait_queue_entry queues[1];
};
/* asynchronous procedure calls */
struct thread_apc
{
void *func; /* function to call in client */
void *param; /* function param */
};
#define MAX_THREAD_APC 16 /* Max outstanding APCs for a thread */
/* thread operations */
static void dump_thread( struct object *obj, int verbose );
static int thread_signaled( struct object *obj, struct thread *thread );
static void destroy_thread( struct object *obj );
static const struct object_ops thread_ops =
{
sizeof(struct thread),
dump_thread,
add_queue,
remove_queue,
thread_signaled,
no_satisfied,
no_read_fd,
no_write_fd,
no_flush,
no_get_file_info,
destroy_thread
};
static const int use_ptrace = 1; /* set to 0 to disable ptrace */
static struct thread *first_thread;
/* allocate the buffer for the communication with the client */
static int alloc_client_buffer( struct thread *thread )
{
int fd;
if ((fd = create_anonymous_file()) == -1) return -1;
if (ftruncate( fd, MAX_REQUEST_LENGTH ) == -1) goto error;
if ((thread->buffer = mmap( 0, MAX_REQUEST_LENGTH, PROT_READ | PROT_WRITE,
MAP_SHARED, fd, 0 )) == (void*)-1) goto error;
return fd;
error:
file_set_error();
if (fd != -1) close( fd );
return -1;
}
/* create a new thread */
static struct thread *create_thread( int fd, struct process *process, int suspend )
{
struct thread *thread;
int buf_fd;
if (!(thread = alloc_object( &thread_ops ))) return NULL;
thread->client = NULL;
thread->unix_pid = 0; /* not known yet */
thread->teb = NULL;
thread->mutex = NULL;
thread->debug_ctx = NULL;
thread->debug_first = NULL;
thread->debug_event = NULL;
thread->wait = NULL;
thread->apc = NULL;
thread->apc_count = 0;
thread->error = 0;
thread->state = RUNNING;
thread->attached = 0;
thread->exit_code = 0x103; /* STILL_ACTIVE */
thread->next = NULL;
thread->prev = NULL;
thread->priority = THREAD_PRIORITY_NORMAL;
thread->affinity = 1;
thread->suspend = (suspend != 0);
thread->buffer = (void *)-1;
thread->last_req = REQ_GET_THREAD_BUFFER;
if (!first_thread) /* creating the first thread */
{
current = thread;
thread->process = process = create_initial_process();
assert( process );
}
else thread->process = (struct process *)grab_object( process );
if ((thread->next = first_thread) != NULL) thread->next->prev = thread;
first_thread = thread;
add_process_thread( process, thread );
if ((buf_fd = alloc_client_buffer( thread )) == -1) goto error;
if (!(thread->client = add_client( fd, thread )))
{
close( buf_fd );
goto error;
}
set_reply_fd( thread, buf_fd ); /* send the fd to the client */
send_reply( thread );
return thread;
error:
remove_process_thread( process, thread );
release_object( thread );
return NULL;
}
/* create the initial thread and start the main server loop */
void create_initial_thread( int fd )
{
create_thread( fd, NULL, 0 );
select_loop();
}
/* destroy a thread when its refcount is 0 */
static void destroy_thread( struct object *obj )
{
struct thread *thread = (struct thread *)obj;
assert( obj->ops == &thread_ops );
assert( !thread->debug_ctx ); /* cannot still be debugging something */
release_object( thread->process );
if (thread->next) thread->next->prev = thread->prev;
if (thread->prev) thread->prev->next = thread->next;
else first_thread = thread->next;
if (thread->apc) free( thread->apc );
if (thread->buffer != (void *)-1) munmap( thread->buffer, MAX_REQUEST_LENGTH );
}
/* dump a thread on stdout for debugging purposes */
static void dump_thread( struct object *obj, int verbose )
{
struct thread *thread = (struct thread *)obj;
assert( obj->ops == &thread_ops );
fprintf( stderr, "Thread pid=%d teb=%p state=%d\n",
thread->unix_pid, thread->teb, thread->state );
}
static int thread_signaled( struct object *obj, struct thread *thread )
{
struct thread *mythread = (struct thread *)obj;
return (mythread->state == TERMINATED);
}
/* get a thread pointer from a thread id (and increment the refcount) */
struct thread *get_thread_from_id( void *id )
{
struct thread *t = first_thread;
while (t && (t != id)) t = t->next;
if (t) grab_object( t );
return t;
}
/* get a thread from a handle (and increment the refcount) */
struct thread *get_thread_from_handle( int handle, unsigned int access )
{
return (struct thread *)get_handle_obj( current->process, handle,
access, &thread_ops );
}
/* set all information about a thread */
static void set_thread_info( struct thread *thread,
struct set_thread_info_request *req )
{
if (req->mask & SET_THREAD_INFO_PRIORITY)
thread->priority = req->priority;
if (req->mask & SET_THREAD_INFO_AFFINITY)
{
if (req->affinity != 1) set_error( ERROR_INVALID_PARAMETER );
else thread->affinity = req->affinity;
}
}
/* find a thread from a Unix pid */
static struct thread *get_thread_from_pid( int pid )
{
struct thread *t = first_thread;
while (t && (t->unix_pid != pid)) t = t->next;
return t;
}
/* wait for a ptraced child to get a certain signal */
/* if the signal is 0, we simply check if anything is pending and return at once */
void wait4_thread( struct thread *thread, int signal )
{
int status;
int pid;
restart:
pid = thread ? thread->unix_pid : -1;
if ((pid = wait4( pid, &status, WUNTRACED | (signal ? 0 : WNOHANG), NULL )) == -1)
{
perror( "wait4" );
return;
}
if (WIFSTOPPED(status))
{
int sig = WSTOPSIG(status);
if (debug_level) fprintf( stderr, "ptrace: pid %d got sig %d\n", pid, sig );
switch(sig)
{
case SIGSTOP: /* continue at once if not suspended */
if (!thread)
if (!(thread = get_thread_from_pid( pid ))) break;
if (!(thread->process->suspend + thread->suspend))
ptrace( PTRACE_CONT, pid, 0, sig );
break;
default: /* ignore other signals for now */
ptrace( PTRACE_CONT, pid, 0, sig );
break;
}
if (signal && sig != signal) goto restart;
}
else if (WIFSIGNALED(status))
{
int exit_code = WTERMSIG(status);
if (debug_level)
fprintf( stderr, "ptrace: pid %d killed by sig %d\n", pid, exit_code );
if (!thread)
if (!(thread = get_thread_from_pid( pid ))) return;
if (thread->client) remove_client( thread->client, exit_code );
}
else if (WIFEXITED(status))
{
int exit_code = WEXITSTATUS(status);
if (debug_level)
fprintf( stderr, "ptrace: pid %d exited with status %d\n", pid, exit_code );
if (!thread)
if (!(thread = get_thread_from_pid( pid ))) return;
if (thread->client) remove_client( thread->client, exit_code );
}
else fprintf( stderr, "wait4: pid %d unknown status %x\n", pid, status );
}
/* attach to a Unix thread */
static int attach_thread( struct thread *thread )
{
/* this may fail if the client is already being debugged */
if (!use_ptrace || (ptrace( PTRACE_ATTACH, thread->unix_pid, 0, 0 ) == -1)) return 0;
if (debug_level) fprintf( stderr, "ptrace: attached to pid %d\n", thread->unix_pid );
thread->attached = 1;
wait4_thread( thread, SIGSTOP );
return 1;
}
/* detach from a Unix thread and kill it */
static void detach_thread( struct thread *thread )
{
if (!thread->unix_pid) return;
kill( thread->unix_pid, SIGTERM );
if (thread->suspend + thread->process->suspend) continue_thread( thread );
if (thread->attached)
{
wait4_thread( thread, SIGTERM );
if (debug_level) fprintf( stderr, "ptrace: detaching from %d\n", thread->unix_pid );
ptrace( PTRACE_DETACH, thread->unix_pid, 0, SIGTERM );
thread->attached = 0;
}
}
/* stop a thread (at the Unix level) */
void stop_thread( struct thread *thread )
{
if (!thread->unix_pid) return;
/* first try to attach to it */
if (!thread->attached)
if (attach_thread( thread )) return; /* this will have stopped it */
/* attached already, or attach failed -> send a signal */
kill( thread->unix_pid, SIGSTOP );
if (thread->attached) wait4_thread( thread, SIGSTOP );
}
/* make a thread continue (at the Unix level) */
void continue_thread( struct thread *thread )
{
if (!thread->unix_pid) return;
if (!thread->attached) kill( thread->unix_pid, SIGCONT );
else ptrace( PTRACE_CONT, thread->unix_pid, 0, SIGSTOP );
}
/* suspend a thread */
static int suspend_thread( struct thread *thread )
{
int old_count = thread->suspend;
if (thread->suspend < MAXIMUM_SUSPEND_COUNT)
{
if (!(thread->process->suspend + thread->suspend++)) stop_thread( thread );
}
return old_count;
}
/* resume a thread */
static int resume_thread( struct thread *thread )
{
int old_count = thread->suspend;
if (thread->suspend > 0)
{
if (!(--thread->suspend + thread->process->suspend)) continue_thread( thread );
}
return old_count;
}
/* suspend all threads but the current */
void suspend_all_threads( void )
{
struct thread *thread;
for ( thread = first_thread; thread; thread = thread->next )
if ( thread != current )
suspend_thread( thread );
}
/* resume all threads but the current */
void resume_all_threads( void )
{
struct thread *thread;
for ( thread = first_thread; thread; thread = thread->next )
if ( thread != current )
resume_thread( thread );
}
/* add a thread to an object wait queue; return 1 if OK, 0 on error */
int add_queue( struct object *obj, struct wait_queue_entry *entry )
{
grab_object( obj );
entry->obj = obj;
entry->prev = obj->tail;
entry->next = NULL;
if (obj->tail) obj->tail->next = entry;
else obj->head = entry;
obj->tail = entry;
return 1;
}
/* remove a thread from an object wait queue */
void remove_queue( struct object *obj, struct wait_queue_entry *entry )
{
if (entry->next) entry->next->prev = entry->prev;
else obj->tail = entry->prev;
if (entry->prev) entry->prev->next = entry->next;
else obj->head = entry->next;
release_object( obj );
}
/* finish waiting */
static void end_wait( struct thread *thread )
{
struct thread_wait *wait = thread->wait;
struct wait_queue_entry *entry;
int i;
assert( wait );
for (i = 0, entry = wait->queues; i < wait->count; i++, entry++)
entry->obj->ops->remove_queue( entry->obj, entry );
if (wait->user) remove_timeout_user( wait->user );
free( wait );
thread->wait = NULL;
}
/* build the thread wait structure */
static int wait_on( struct thread *thread, int count,
int *handles, int flags, int timeout )
{
struct thread_wait *wait;
struct wait_queue_entry *entry;
struct object *obj;
int i;
if ((count < 0) || (count > MAXIMUM_WAIT_OBJECTS))
{
set_error( ERROR_INVALID_PARAMETER );
return 0;
}
if (!(wait = mem_alloc( sizeof(*wait) + (count-1) * sizeof(*entry) ))) return 0;
thread->wait = wait;
wait->count = count;
wait->flags = flags;
wait->user = NULL;
if (flags & SELECT_TIMEOUT) make_timeout( &wait->timeout, timeout );
for (i = 0, entry = wait->queues; i < count; i++, entry++)
{
if (!(obj = get_handle_obj( thread->process, handles[i],
SYNCHRONIZE, NULL )))
{
wait->count = i - 1;
end_wait( thread );
return 0;
}
entry->thread = thread;
if (!obj->ops->add_queue( obj, entry ))
{
wait->count = i - 1;
end_wait( thread );
return 0;
}
release_object( obj );
}
return 1;
}
/* check if the thread waiting condition is satisfied */
static int check_wait( struct thread *thread, int *signaled )
{
int i;
struct thread_wait *wait = thread->wait;
struct wait_queue_entry *entry = wait->queues;
assert( wait );
if (wait->flags & SELECT_ALL)
{
int not_ok = 0;
/* Note: we must check them all anyway, as some objects may
* want to do something when signaled, even if others are not */
for (i = 0, entry = wait->queues; i < wait->count; i++, entry++)
not_ok |= !entry->obj->ops->signaled( entry->obj, thread );
if (not_ok) goto other_checks;
/* Wait satisfied: tell it to all objects */
*signaled = 0;
for (i = 0, entry = wait->queues; i < wait->count; i++, entry++)
if (entry->obj->ops->satisfied( entry->obj, thread ))
*signaled = STATUS_ABANDONED_WAIT_0;
return 1;
}
else
{
for (i = 0, entry = wait->queues; i < wait->count; i++, entry++)
{
if (!entry->obj->ops->signaled( entry->obj, thread )) continue;
/* Wait satisfied: tell it to the object */
*signaled = i;
if (entry->obj->ops->satisfied( entry->obj, thread ))
*signaled = i + STATUS_ABANDONED_WAIT_0;
return 1;
}
}
other_checks:
if ((wait->flags & SELECT_ALERTABLE) && thread->apc)
{
*signaled = STATUS_USER_APC;
return 1;
}
if (wait->flags & SELECT_TIMEOUT)
{
struct timeval now;
gettimeofday( &now, NULL );
if ((now.tv_sec > wait->timeout.tv_sec) ||
((now.tv_sec == wait->timeout.tv_sec) &&
(now.tv_usec >= wait->timeout.tv_usec)))
{
*signaled = STATUS_TIMEOUT;
return 1;
}
}
return 0;
}
/* attempt to wake up a thread */
/* return 1 if OK, 0 if the wait condition is still not satisfied */
static int wake_thread( struct thread *thread )
{
struct select_request *req = get_req_ptr( thread );
if (!check_wait( thread, &req->signaled )) return 0;
end_wait( thread );
return 1;
}
/* sleep on a list of objects */
static void sleep_on( struct thread *thread, int count, int *handles, int flags, int timeout )
{
struct select_request *req;
assert( !thread->wait );
if (!wait_on( thread, count, handles, flags, timeout )) goto error;
if (wake_thread( thread )) return;
/* now we need to wait */
if (flags & SELECT_TIMEOUT)
{
if (!(thread->wait->user = add_timeout_user( &thread->wait->timeout,
call_timeout_handler, thread )))
goto error;
}
thread->state = SLEEPING;
return;
error:
req = get_req_ptr( thread );
req->signaled = -1;
}
/* timeout for the current thread */
void thread_timeout(void)
{
struct select_request *req = get_req_ptr( current );
assert( current->wait );
current->wait->user = NULL;
end_wait( current );
req->signaled = STATUS_TIMEOUT;
send_reply( current );
}
/* attempt to wake threads sleeping on the object wait queue */
void wake_up( struct object *obj, int max )
{
struct wait_queue_entry *entry = obj->head;
while (entry)
{
struct thread *thread = entry->thread;
entry = entry->next;
if (wake_thread( thread ))
{
send_reply( thread );
if (max && !--max) break;
}
}
}
/* queue an async procedure call */
static int thread_queue_apc( struct thread *thread, void *func, void *param )
{
struct thread_apc *apc;
if (!thread->apc)
{
if (!(thread->apc = mem_alloc( MAX_THREAD_APC * sizeof(*apc) )))
return 0;
thread->apc_count = 0;
}
else if (thread->apc_count >= MAX_THREAD_APC) return 0;
thread->apc[thread->apc_count].func = func;
thread->apc[thread->apc_count].param = param;
thread->apc_count++;
if (thread->wait)
{
if (wake_thread( thread )) send_reply( thread );
}
return 1;
}
/* kill a thread on the spot */
void kill_thread( struct thread *thread, int exit_code )
{
if (thread->state == TERMINATED) return; /* already killed */
remove_client( thread->client, exit_code ); /* this will call thread_killed */
}
/* a thread has been killed */
void thread_killed( struct thread *thread, int exit_code )
{
thread->state = TERMINATED;
thread->exit_code = exit_code;
thread->client = NULL;
if (thread->wait) end_wait( thread );
debug_exit_thread( thread, exit_code );
abandon_mutexes( thread );
remove_process_thread( thread->process, thread );
wake_up( &thread->obj, 0 );
detach_thread( thread );
release_object( thread );
}
/* create a new thread */
DECL_HANDLER(new_thread)
{
struct thread *thread;
struct process *process;
if ((process = get_process_from_id( req->pid )))
{
if ((fd = dup(fd)) != -1)
{
if ((thread = create_thread( fd, process, req->suspend )))
{
req->tid = thread;
if ((req->handle = alloc_handle( current->process, thread,
THREAD_ALL_ACCESS, req->inherit )) == -1)
release_object( thread );
/* else will be released when the thread gets killed */
}
else close( fd );
}
else file_set_error();
release_object( process );
}
}
/* retrieve the thread buffer file descriptor */
DECL_HANDLER(get_thread_buffer)
{
fatal_protocol_error( current, "get_thread_buffer: should never get called directly\n" );
}
/* initialize a new thread */
DECL_HANDLER(init_thread)
{
if (current->unix_pid)
{
fatal_protocol_error( current, "init_thread: already running\n" );
return;
}
current->unix_pid = req->unix_pid;
current->teb = req->teb;
if (current->suspend + current->process->suspend > 0) stop_thread( current );
req->pid = current->process;
req->tid = current;
}
/* terminate a thread */
DECL_HANDLER(terminate_thread)
{
struct thread *thread;
if ((thread = get_thread_from_handle( req->handle, THREAD_TERMINATE )))
{
kill_thread( thread, req->exit_code );
release_object( thread );
}
}
/* fetch information about a thread */
DECL_HANDLER(get_thread_info)
{
struct thread *thread;
if ((thread = get_thread_from_handle( req->handle, THREAD_QUERY_INFORMATION )))
{
req->tid = thread;
req->exit_code = thread->exit_code;
req->priority = thread->priority;
release_object( thread );
}
}
/* set information about a thread */
DECL_HANDLER(set_thread_info)
{
struct thread *thread;
if ((thread = get_thread_from_handle( req->handle, THREAD_SET_INFORMATION )))
{
set_thread_info( thread, req );
release_object( thread );
}
}
/* suspend a thread */
DECL_HANDLER(suspend_thread)
{
struct thread *thread;
if ((thread = get_thread_from_handle( req->handle, THREAD_SUSPEND_RESUME )))
{
req->count = suspend_thread( thread );
release_object( thread );
}
}
/* resume a thread */
DECL_HANDLER(resume_thread)
{
struct thread *thread;
if ((thread = get_thread_from_handle( req->handle, THREAD_SUSPEND_RESUME )))
{
req->count = resume_thread( thread );
release_object( thread );
}
}
/* select on a handle list */
DECL_HANDLER(select)
{
sleep_on( current, req->count, req->handles, req->flags, req->timeout );
}
/* queue an APC for a thread */
DECL_HANDLER(queue_apc)
{
struct thread *thread;
if ((thread = get_thread_from_handle( req->handle, THREAD_SET_CONTEXT )))
{
thread_queue_apc( thread, req->func, req->param );
release_object( thread );
}
}
/* get list of APC to call */
DECL_HANDLER(get_apcs)
{
if ((req->count = current->apc_count))
{
memcpy( req->apcs, current->apc, current->apc_count * sizeof(*current->apc) );
free( current->apc );
current->apc = NULL;
current->apc_count = 0;
}
}