darling-gdb/gdb/event-loop.c
2005-04-25 23:51:33 +00:00

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/* Event loop machinery for GDB, the GNU debugger.
Copyright 1999, 2000, 2001, 2002 Free Software Foundation, Inc.
Written by Elena Zannoni <ezannoni@cygnus.com> of Cygnus Solutions.
This file is part of GDB.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA. */
#include "defs.h"
#include "event-loop.h"
#include "event-top.h"
#ifdef HAVE_POLL
#if defined (HAVE_POLL_H)
#include <poll.h>
#elif defined (HAVE_SYS_POLL_H)
#include <sys/poll.h>
#endif
#endif
#include <sys/types.h>
#include "gdb_string.h"
#include <errno.h>
#include <sys/time.h>
#include "exceptions.h"
#include "gdb_assert.h"
typedef struct gdb_event gdb_event;
typedef void (event_handler_func) (int);
/* Event for the GDB event system. Events are queued by calling
async_queue_event and serviced later on by gdb_do_one_event. An
event can be, for instance, a file descriptor becoming ready to be
read. Servicing an event simply means that the procedure PROC will
be called. We have 2 queues, one for file handlers that we listen
to in the event loop, and one for the file handlers+events that are
ready. The procedure PROC associated with each event is always the
same (handle_file_event). Its duty is to invoke the handler
associated with the file descriptor whose state change generated
the event, plus doing other cleanups and such. */
struct gdb_event
{
event_handler_func *proc; /* Procedure to call to service this event. */
int fd; /* File descriptor that is ready. */
struct gdb_event *next_event; /* Next in list of events or NULL. */
};
/* Information about each file descriptor we register with the event
loop. */
typedef struct file_handler
{
int fd; /* File descriptor. */
int mask; /* Events we want to monitor: POLLIN, etc. */
int ready_mask; /* Events that have been seen since
the last time. */
handler_func *proc; /* Procedure to call when fd is ready. */
gdb_client_data client_data; /* Argument to pass to proc. */
int error; /* Was an error detected on this fd? */
struct file_handler *next_file; /* Next registered file descriptor. */
}
file_handler;
/* PROC is a function to be invoked when the READY flag is set. This
happens when there has been a signal and the corresponding signal
handler has 'triggered' this async_signal_handler for
execution. The actual work to be done in response to a signal will
be carried out by PROC at a later time, within process_event. This
provides a deferred execution of signal handlers.
Async_init_signals takes care of setting up such an
asyn_signal_handler for each interesting signal. */
typedef struct async_signal_handler
{
int ready; /* If ready, call this handler from the main event loop,
using invoke_async_handler. */
struct async_signal_handler *next_handler; /* Ptr to next handler */
sig_handler_func *proc; /* Function to call to do the work */
gdb_client_data client_data; /* Argument to async_handler_func */
}
async_signal_handler;
/* Event queue:
- the first event in the queue is the head of the queue.
It will be the next to be serviced.
- the last event in the queue
Events can be inserted at the front of the queue or at the end of
the queue. Events will be extracted from the queue for processing
starting from the head. Therefore, events inserted at the head of
the queue will be processed in a last in first out fashion, while
those inserted at the tail of the queue will be processed in a first
in first out manner. All the fields are NULL if the queue is
empty. */
static struct
{
gdb_event *first_event; /* First pending event */
gdb_event *last_event; /* Last pending event */
}
event_queue;
/* Gdb_notifier is just a list of file descriptors gdb is interested in.
These are the input file descriptor, and the target file
descriptor. We have two flavors of the notifier, one for platforms
that have the POLL function, the other for those that don't, and
only support SELECT. Each of the elements in the gdb_notifier list is
basically a description of what kind of events gdb is interested
in, for each fd. */
/* As of 1999-04-30 only the input file descriptor is registered with the
event loop. */
/* Do we use poll or select ? */
#ifdef HAVE_POLL
#define USE_POLL 1
#else
#define USE_POLL 0
#endif /* HAVE_POLL */
static unsigned char use_poll = USE_POLL;
#ifdef USE_WIN32API
#include <windows.h>
#include <io.h>
#endif
static struct
{
/* Ptr to head of file handler list. */
file_handler *first_file_handler;
#ifdef HAVE_POLL
/* Ptr to array of pollfd structures. */
struct pollfd *poll_fds;
/* Timeout in milliseconds for calls to poll(). */
int poll_timeout;
#endif
/* Masks to be used in the next call to select.
Bits are set in response to calls to create_file_handler. */
fd_set check_masks[3];
/* What file descriptors were found ready by select. */
fd_set ready_masks[3];
/* Number of file descriptors to monitor. (for poll) */
/* Number of valid bits (highest fd value + 1). (for select) */
int num_fds;
/* Time structure for calls to select(). */
struct timeval select_timeout;
/* Flag to tell whether the timeout should be used. */
int timeout_valid;
}
gdb_notifier;
/* Structure associated with a timer. PROC will be executed at the
first occasion after WHEN. */
struct gdb_timer
{
struct timeval when;
int timer_id;
struct gdb_timer *next;
timer_handler_func *proc; /* Function to call to do the work */
gdb_client_data client_data; /* Argument to async_handler_func */
}
gdb_timer;
/* List of currently active timers. It is sorted in order of
increasing timers. */
static struct
{
/* Pointer to first in timer list. */
struct gdb_timer *first_timer;
/* Id of the last timer created. */
int num_timers;
}
timer_list;
/* All the async_signal_handlers gdb is interested in are kept onto
this list. */
static struct
{
/* Pointer to first in handler list. */
async_signal_handler *first_handler;
/* Pointer to last in handler list. */
async_signal_handler *last_handler;
}
sighandler_list;
/* Are any of the handlers ready? Check this variable using
check_async_ready. This is used by process_event, to determine
whether or not to invoke the invoke_async_signal_handler
function. */
static int async_handler_ready = 0;
static void create_file_handler (int fd, int mask, handler_func * proc, gdb_client_data client_data);
static void invoke_async_signal_handler (void);
static void handle_file_event (int event_file_desc);
static int gdb_wait_for_event (void);
static int check_async_ready (void);
static void async_queue_event (gdb_event * event_ptr, queue_position position);
static gdb_event *create_file_event (int fd);
static int process_event (void);
static void handle_timer_event (int dummy);
static void poll_timers (void);
/* Insert an event object into the gdb event queue at
the specified position.
POSITION can be head or tail, with values TAIL, HEAD.
EVENT_PTR points to the event to be inserted into the queue.
The caller must allocate memory for the event. It is freed
after the event has ben handled.
Events in the queue will be processed head to tail, therefore,
events inserted at the head of the queue will be processed
as last in first out. Event appended at the tail of the queue
will be processed first in first out. */
static void
async_queue_event (gdb_event * event_ptr, queue_position position)
{
if (position == TAIL)
{
/* The event will become the new last_event. */
event_ptr->next_event = NULL;
if (event_queue.first_event == NULL)
event_queue.first_event = event_ptr;
else
event_queue.last_event->next_event = event_ptr;
event_queue.last_event = event_ptr;
}
else if (position == HEAD)
{
/* The event becomes the new first_event. */
event_ptr->next_event = event_queue.first_event;
if (event_queue.first_event == NULL)
event_queue.last_event = event_ptr;
event_queue.first_event = event_ptr;
}
}
/* Create a file event, to be enqueued in the event queue for
processing. The procedure associated to this event is always
handle_file_event, which will in turn invoke the one that was
associated to FD when it was registered with the event loop. */
static gdb_event *
create_file_event (int fd)
{
gdb_event *file_event_ptr;
file_event_ptr = (gdb_event *) xmalloc (sizeof (gdb_event));
file_event_ptr->proc = handle_file_event;
file_event_ptr->fd = fd;
return (file_event_ptr);
}
/* Process one event.
The event can be the next one to be serviced in the event queue,
or an asynchronous event handler can be invoked in response to
the reception of a signal.
If an event was processed (either way), 1 is returned otherwise
0 is returned.
Scan the queue from head to tail, processing therefore the high
priority events first, by invoking the associated event handler
procedure. */
static int
process_event (void)
{
gdb_event *event_ptr, *prev_ptr;
event_handler_func *proc;
int fd;
/* First let's see if there are any asynchronous event handlers that
are ready. These would be the result of invoking any of the
signal handlers. */
if (check_async_ready ())
{
invoke_async_signal_handler ();
return 1;
}
/* Look in the event queue to find an event that is ready
to be processed. */
for (event_ptr = event_queue.first_event; event_ptr != NULL;
event_ptr = event_ptr->next_event)
{
/* Call the handler for the event. */
proc = event_ptr->proc;
fd = event_ptr->fd;
/* Let's get rid of the event from the event queue. We need to
do this now because while processing the event, the proc
function could end up calling 'error' and therefore jump out
to the caller of this function, gdb_do_one_event. In that
case, we would have on the event queue an event wich has been
processed, but not deleted. */
if (event_queue.first_event == event_ptr)
{
event_queue.first_event = event_ptr->next_event;
if (event_ptr->next_event == NULL)
event_queue.last_event = NULL;
}
else
{
prev_ptr = event_queue.first_event;
while (prev_ptr->next_event != event_ptr)
prev_ptr = prev_ptr->next_event;
prev_ptr->next_event = event_ptr->next_event;
if (event_ptr->next_event == NULL)
event_queue.last_event = prev_ptr;
}
xfree (event_ptr);
/* Now call the procedure associated with the event. */
(*proc) (fd);
return 1;
}
/* this is the case if there are no event on the event queue. */
return 0;
}
/* Process one high level event. If nothing is ready at this time,
wait for something to happen (via gdb_wait_for_event), then process
it. Returns >0 if something was done otherwise returns <0 (this
can happen if there are no event sources to wait for). If an error
occurs catch_errors() which calls this function returns zero. */
int
gdb_do_one_event (void *data)
{
/* Any events already waiting in the queue? */
if (process_event ())
{
return 1;
}
/* Are any timers that are ready? If so, put an event on the queue. */
poll_timers ();
/* Wait for a new event. If gdb_wait_for_event returns -1,
we should get out because this means that there are no
event sources left. This will make the event loop stop,
and the application exit. */
if (gdb_wait_for_event () < 0)
{
return -1;
}
/* Handle any new events occurred while waiting. */
if (process_event ())
{
return 1;
}
/* If gdb_wait_for_event has returned 1, it means that one
event has been handled. We break out of the loop. */
return 1;
}
/* Start up the event loop. This is the entry point to the event loop
from the command loop. */
void
start_event_loop (void)
{
/* Loop until there is nothing to do. This is the entry point to the
event loop engine. gdb_do_one_event, called via catch_errors()
will process one event for each invocation. It blocks waits for
an event and then processes it. >0 when an event is processed, 0
when catch_errors() caught an error and <0 when there are no
longer any event sources registered. */
while (1)
{
int gdb_result;
gdb_result = catch_errors (gdb_do_one_event, 0, "", RETURN_MASK_ALL);
if (gdb_result < 0)
break;
/* If we long-jumped out of do_one_event, we probably
didn't get around to resetting the prompt, which leaves
readline in a messed-up state. Reset it here. */
if (gdb_result == 0)
{
/* FIXME: this should really be a call to a hook that is
interface specific, because interfaces can display the
prompt in their own way. */
display_gdb_prompt (0);
/* This call looks bizarre, but it is required. If the user
entered a command that caused an error,
after_char_processing_hook won't be called from
rl_callback_read_char_wrapper. Using a cleanup there
won't work, since we want this function to be called
after a new prompt is printed. */
if (after_char_processing_hook)
(*after_char_processing_hook) ();
/* Maybe better to set a flag to be checked somewhere as to
whether display the prompt or not. */
}
}
/* We are done with the event loop. There are no more event sources
to listen to. So we exit GDB. */
return;
}
/* Wrapper function for create_file_handler, so that the caller
doesn't have to know implementation details about the use of poll
vs. select. */
void
add_file_handler (int fd, handler_func * proc, gdb_client_data client_data)
{
#ifdef HAVE_POLL
struct pollfd fds;
#endif
if (use_poll)
{
#ifdef HAVE_POLL
/* Check to see if poll () is usable. If not, we'll switch to
use select. This can happen on systems like
m68k-motorola-sys, `poll' cannot be used to wait for `stdin'.
On m68k-motorola-sysv, tty's are not stream-based and not
`poll'able. */
fds.fd = fd;
fds.events = POLLIN;
if (poll (&fds, 1, 0) == 1 && (fds.revents & POLLNVAL))
use_poll = 0;
#else
internal_error (__FILE__, __LINE__,
_("use_poll without HAVE_POLL"));
#endif /* HAVE_POLL */
}
if (use_poll)
{
#ifdef HAVE_POLL
create_file_handler (fd, POLLIN, proc, client_data);
#else
internal_error (__FILE__, __LINE__,
_("use_poll without HAVE_POLL"));
#endif
}
else
create_file_handler (fd, GDB_READABLE | GDB_EXCEPTION, proc, client_data);
}
/* Add a file handler/descriptor to the list of descriptors we are
interested in.
FD is the file descriptor for the file/stream to be listened to.
For the poll case, MASK is a combination (OR) of
POLLIN, POLLRDNORM, POLLRDBAND, POLLPRI, POLLOUT, POLLWRNORM,
POLLWRBAND: these are the events we are interested in. If any of them
occurs, proc should be called.
For the select case, MASK is a combination of READABLE, WRITABLE, EXCEPTION.
PROC is the procedure that will be called when an event occurs for
FD. CLIENT_DATA is the argument to pass to PROC. */
static void
create_file_handler (int fd, int mask, handler_func * proc, gdb_client_data client_data)
{
file_handler *file_ptr;
/* Do we already have a file handler for this file? (We may be
changing its associated procedure). */
for (file_ptr = gdb_notifier.first_file_handler; file_ptr != NULL;
file_ptr = file_ptr->next_file)
{
if (file_ptr->fd == fd)
break;
}
/* It is a new file descriptor. Add it to the list. Otherwise, just
change the data associated with it. */
if (file_ptr == NULL)
{
file_ptr = (file_handler *) xmalloc (sizeof (file_handler));
file_ptr->fd = fd;
file_ptr->ready_mask = 0;
file_ptr->next_file = gdb_notifier.first_file_handler;
gdb_notifier.first_file_handler = file_ptr;
if (use_poll)
{
#ifdef HAVE_POLL
gdb_notifier.num_fds++;
if (gdb_notifier.poll_fds)
gdb_notifier.poll_fds =
(struct pollfd *) xrealloc (gdb_notifier.poll_fds,
(gdb_notifier.num_fds
* sizeof (struct pollfd)));
else
gdb_notifier.poll_fds =
(struct pollfd *) xmalloc (sizeof (struct pollfd));
(gdb_notifier.poll_fds + gdb_notifier.num_fds - 1)->fd = fd;
(gdb_notifier.poll_fds + gdb_notifier.num_fds - 1)->events = mask;
(gdb_notifier.poll_fds + gdb_notifier.num_fds - 1)->revents = 0;
#else
internal_error (__FILE__, __LINE__,
_("use_poll without HAVE_POLL"));
#endif /* HAVE_POLL */
}
else
{
if (mask & GDB_READABLE)
FD_SET (fd, &gdb_notifier.check_masks[0]);
else
FD_CLR (fd, &gdb_notifier.check_masks[0]);
if (mask & GDB_WRITABLE)
FD_SET (fd, &gdb_notifier.check_masks[1]);
else
FD_CLR (fd, &gdb_notifier.check_masks[1]);
if (mask & GDB_EXCEPTION)
FD_SET (fd, &gdb_notifier.check_masks[2]);
else
FD_CLR (fd, &gdb_notifier.check_masks[2]);
if (gdb_notifier.num_fds <= fd)
gdb_notifier.num_fds = fd + 1;
}
}
file_ptr->proc = proc;
file_ptr->client_data = client_data;
file_ptr->mask = mask;
}
/* Remove the file descriptor FD from the list of monitored fd's:
i.e. we don't care anymore about events on the FD. */
void
delete_file_handler (int fd)
{
file_handler *file_ptr, *prev_ptr = NULL;
int i;
#ifdef HAVE_POLL
int j;
struct pollfd *new_poll_fds;
#endif
/* Find the entry for the given file. */
for (file_ptr = gdb_notifier.first_file_handler; file_ptr != NULL;
file_ptr = file_ptr->next_file)
{
if (file_ptr->fd == fd)
break;
}
if (file_ptr == NULL)
return;
if (use_poll)
{
#ifdef HAVE_POLL
/* Create a new poll_fds array by copying every fd's information but the
one we want to get rid of. */
new_poll_fds =
(struct pollfd *) xmalloc ((gdb_notifier.num_fds - 1) * sizeof (struct pollfd));
for (i = 0, j = 0; i < gdb_notifier.num_fds; i++)
{
if ((gdb_notifier.poll_fds + i)->fd != fd)
{
(new_poll_fds + j)->fd = (gdb_notifier.poll_fds + i)->fd;
(new_poll_fds + j)->events = (gdb_notifier.poll_fds + i)->events;
(new_poll_fds + j)->revents = (gdb_notifier.poll_fds + i)->revents;
j++;
}
}
xfree (gdb_notifier.poll_fds);
gdb_notifier.poll_fds = new_poll_fds;
gdb_notifier.num_fds--;
#else
internal_error (__FILE__, __LINE__,
_("use_poll without HAVE_POLL"));
#endif /* HAVE_POLL */
}
else
{
if (file_ptr->mask & GDB_READABLE)
FD_CLR (fd, &gdb_notifier.check_masks[0]);
if (file_ptr->mask & GDB_WRITABLE)
FD_CLR (fd, &gdb_notifier.check_masks[1]);
if (file_ptr->mask & GDB_EXCEPTION)
FD_CLR (fd, &gdb_notifier.check_masks[2]);
/* Find current max fd. */
if ((fd + 1) == gdb_notifier.num_fds)
{
gdb_notifier.num_fds--;
for (i = gdb_notifier.num_fds; i; i--)
{
if (FD_ISSET (i - 1, &gdb_notifier.check_masks[0])
|| FD_ISSET (i - 1, &gdb_notifier.check_masks[1])
|| FD_ISSET (i - 1, &gdb_notifier.check_masks[2]))
break;
}
gdb_notifier.num_fds = i;
}
}
/* Deactivate the file descriptor, by clearing its mask,
so that it will not fire again. */
file_ptr->mask = 0;
/* Get rid of the file handler in the file handler list. */
if (file_ptr == gdb_notifier.first_file_handler)
gdb_notifier.first_file_handler = file_ptr->next_file;
else
{
for (prev_ptr = gdb_notifier.first_file_handler;
prev_ptr->next_file != file_ptr;
prev_ptr = prev_ptr->next_file)
;
prev_ptr->next_file = file_ptr->next_file;
}
xfree (file_ptr);
}
/* Handle the given event by calling the procedure associated to the
corresponding file handler. Called by process_event indirectly,
through event_ptr->proc. EVENT_FILE_DESC is file descriptor of the
event in the front of the event queue. */
static void
handle_file_event (int event_file_desc)
{
file_handler *file_ptr;
int mask;
#ifdef HAVE_POLL
int error_mask;
int error_mask_returned;
#endif
/* Search the file handler list to find one that matches the fd in
the event. */
for (file_ptr = gdb_notifier.first_file_handler; file_ptr != NULL;
file_ptr = file_ptr->next_file)
{
if (file_ptr->fd == event_file_desc)
{
/* With poll, the ready_mask could have any of three events
set to 1: POLLHUP, POLLERR, POLLNVAL. These events cannot
be used in the requested event mask (events), but they
can be returned in the return mask (revents). We need to
check for those event too, and add them to the mask which
will be passed to the handler. */
/* See if the desired events (mask) match the received
events (ready_mask). */
if (use_poll)
{
#ifdef HAVE_POLL
error_mask = POLLHUP | POLLERR | POLLNVAL;
mask = (file_ptr->ready_mask & file_ptr->mask) |
(file_ptr->ready_mask & error_mask);
error_mask_returned = mask & error_mask;
if (error_mask_returned != 0)
{
/* Work in progress. We may need to tell somebody what
kind of error we had. */
if (error_mask_returned & POLLHUP)
printf_unfiltered (_("Hangup detected on fd %d\n"), file_ptr->fd);
if (error_mask_returned & POLLERR)
printf_unfiltered (_("Error detected on fd %d\n"), file_ptr->fd);
if (error_mask_returned & POLLNVAL)
printf_unfiltered (_("Invalid or non-`poll'able fd %d\n"), file_ptr->fd);
file_ptr->error = 1;
}
else
file_ptr->error = 0;
#else
internal_error (__FILE__, __LINE__,
_("use_poll without HAVE_POLL"));
#endif /* HAVE_POLL */
}
else
{
if (file_ptr->ready_mask & GDB_EXCEPTION)
{
printf_unfiltered (_("Exception condition detected on fd %d\n"), file_ptr->fd);
file_ptr->error = 1;
}
else
file_ptr->error = 0;
mask = file_ptr->ready_mask & file_ptr->mask;
}
/* Clear the received events for next time around. */
file_ptr->ready_mask = 0;
/* If there was a match, then call the handler. */
if (mask != 0)
(*file_ptr->proc) (file_ptr->error, file_ptr->client_data);
break;
}
}
}
/* Wrapper for select. This function is not yet exported from this
file because it is not sufficiently general. For example,
ser-base.c uses select to check for socket activity, and this
function does not support sockets under Windows, so we do not want
to use gdb_select in ser-base.c. */
static int
gdb_select (int n, fd_set *readfds, fd_set *writefds, fd_set *exceptfds,
struct timeval *timeout)
{
#ifdef USE_WIN32API
HANDLE handles[MAXIMUM_WAIT_OBJECTS];
HANDLE h;
DWORD event;
DWORD num_handles;
int fd;
int num_ready;
num_handles = 0;
for (fd = 0; fd < n; ++fd)
{
/* EXCEPTFDS is silently ignored. GDB always sets GDB_EXCEPTION
when calling add_file_handler, but there is no natural analog
under Windows. */
/* There is no support yet for WRITEFDS. At present, this isn't
used by GDB -- but we do not want to silently ignore WRITEFDS
if something starts using it. */
gdb_assert (!FD_ISSET (fd, writefds));
if (FD_ISSET (fd, readfds))
{
gdb_assert (num_handles < MAXIMUM_WAIT_OBJECTS);
handles[num_handles++] = (HANDLE) _get_osfhandle (fd);
}
}
event = WaitForMultipleObjects (num_handles,
handles,
FALSE,
timeout
? (timeout->tv_sec * 1000 + timeout->tv_usec)
: INFINITE);
/* EVENT can only be a value in the WAIT_ABANDONED_0 range if the
HANDLES included an abandoned mutex. Since GDB doesn't use
mutexes, that should never occur. */
gdb_assert (!(WAIT_ABANDONED_0 <= event
&& event < WAIT_ABANDONED_0 + num_handles));
if (event == WAIT_FAILED)
return -1;
if (event == WAIT_TIMEOUT)
return 0;
/* Run through the READFDS, clearing bits corresponding to descriptors
for which input is unavailable. */
num_ready = num_handles;
h = handles[event - WAIT_OBJECT_0];
for (fd = 0; fd < n; ++fd)
{
HANDLE fd_h;
if (!FD_ISSET (fd, readfds))
continue;
fd_h = (HANDLE) _get_osfhandle (fd);
/* This handle might be ready, even though it wasn't the handle
returned by WaitForMultipleObjects. */
if (fd_h != h && WaitForSingleObject (fd_h, 0) != WAIT_OBJECT_0)
{
FD_CLR (fd, readfds);
--num_ready;
}
}
/* We never report any descriptors available for writing or with
exceptional conditions. */
FD_ZERO (writefds);
FD_ZERO (exceptfds);
return num_ready;
#else
return select (n, readfds, writefds, exceptfds, timeout);
#endif
}
/* Called by gdb_do_one_event to wait for new events on the
monitored file descriptors. Queue file events as they are
detected by the poll.
If there are no events, this function will block in the
call to poll.
Return -1 if there are no files descriptors to monitor,
otherwise return 0. */
static int
gdb_wait_for_event (void)
{
file_handler *file_ptr;
gdb_event *file_event_ptr;
int num_found = 0;
int i;
/* Make sure all output is done before getting another event. */
gdb_flush (gdb_stdout);
gdb_flush (gdb_stderr);
if (gdb_notifier.num_fds == 0)
return -1;
if (use_poll)
{
#ifdef HAVE_POLL
num_found =
poll (gdb_notifier.poll_fds,
(unsigned long) gdb_notifier.num_fds,
gdb_notifier.timeout_valid ? gdb_notifier.poll_timeout : -1);
/* Don't print anything if we get out of poll because of a
signal. */
if (num_found == -1 && errno != EINTR)
perror_with_name (("poll"));
#else
internal_error (__FILE__, __LINE__,
_("use_poll without HAVE_POLL"));
#endif /* HAVE_POLL */
}
else
{
gdb_notifier.ready_masks[0] = gdb_notifier.check_masks[0];
gdb_notifier.ready_masks[1] = gdb_notifier.check_masks[1];
gdb_notifier.ready_masks[2] = gdb_notifier.check_masks[2];
num_found = gdb_select (gdb_notifier.num_fds,
&gdb_notifier.ready_masks[0],
&gdb_notifier.ready_masks[1],
&gdb_notifier.ready_masks[2],
gdb_notifier.timeout_valid
? &gdb_notifier.select_timeout : NULL);
/* Clear the masks after an error from select. */
if (num_found == -1)
{
FD_ZERO (&gdb_notifier.ready_masks[0]);
FD_ZERO (&gdb_notifier.ready_masks[1]);
FD_ZERO (&gdb_notifier.ready_masks[2]);
/* Dont print anything is we got a signal, let gdb handle it. */
if (errno != EINTR)
perror_with_name (("select"));
}
}
/* Enqueue all detected file events. */
if (use_poll)
{
#ifdef HAVE_POLL
for (i = 0; (i < gdb_notifier.num_fds) && (num_found > 0); i++)
{
if ((gdb_notifier.poll_fds + i)->revents)
num_found--;
else
continue;
for (file_ptr = gdb_notifier.first_file_handler;
file_ptr != NULL;
file_ptr = file_ptr->next_file)
{
if (file_ptr->fd == (gdb_notifier.poll_fds + i)->fd)
break;
}
if (file_ptr)
{
/* Enqueue an event only if this is still a new event for
this fd. */
if (file_ptr->ready_mask == 0)
{
file_event_ptr = create_file_event (file_ptr->fd);
async_queue_event (file_event_ptr, TAIL);
}
}
file_ptr->ready_mask = (gdb_notifier.poll_fds + i)->revents;
}
#else
internal_error (__FILE__, __LINE__,
_("use_poll without HAVE_POLL"));
#endif /* HAVE_POLL */
}
else
{
for (file_ptr = gdb_notifier.first_file_handler;
(file_ptr != NULL) && (num_found > 0);
file_ptr = file_ptr->next_file)
{
int mask = 0;
if (FD_ISSET (file_ptr->fd, &gdb_notifier.ready_masks[0]))
mask |= GDB_READABLE;
if (FD_ISSET (file_ptr->fd, &gdb_notifier.ready_masks[1]))
mask |= GDB_WRITABLE;
if (FD_ISSET (file_ptr->fd, &gdb_notifier.ready_masks[2]))
mask |= GDB_EXCEPTION;
if (!mask)
continue;
else
num_found--;
/* Enqueue an event only if this is still a new event for
this fd. */
if (file_ptr->ready_mask == 0)
{
file_event_ptr = create_file_event (file_ptr->fd);
async_queue_event (file_event_ptr, TAIL);
}
file_ptr->ready_mask = mask;
}
}
return 0;
}
/* Create an asynchronous handler, allocating memory for it.
Return a pointer to the newly created handler.
This pointer will be used to invoke the handler by
invoke_async_signal_handler.
PROC is the function to call with CLIENT_DATA argument
whenever the handler is invoked. */
async_signal_handler *
create_async_signal_handler (sig_handler_func * proc, gdb_client_data client_data)
{
async_signal_handler *async_handler_ptr;
async_handler_ptr =
(async_signal_handler *) xmalloc (sizeof (async_signal_handler));
async_handler_ptr->ready = 0;
async_handler_ptr->next_handler = NULL;
async_handler_ptr->proc = proc;
async_handler_ptr->client_data = client_data;
if (sighandler_list.first_handler == NULL)
sighandler_list.first_handler = async_handler_ptr;
else
sighandler_list.last_handler->next_handler = async_handler_ptr;
sighandler_list.last_handler = async_handler_ptr;
return async_handler_ptr;
}
/* Mark the handler (ASYNC_HANDLER_PTR) as ready. This information will
be used when the handlers are invoked, after we have waited for
some event. The caller of this function is the interrupt handler
associated with a signal. */
void
mark_async_signal_handler (async_signal_handler * async_handler_ptr)
{
((async_signal_handler *) async_handler_ptr)->ready = 1;
async_handler_ready = 1;
}
/* Call all the handlers that are ready. */
static void
invoke_async_signal_handler (void)
{
async_signal_handler *async_handler_ptr;
if (async_handler_ready == 0)
return;
async_handler_ready = 0;
/* Invoke ready handlers. */
while (1)
{
for (async_handler_ptr = sighandler_list.first_handler;
async_handler_ptr != NULL;
async_handler_ptr = async_handler_ptr->next_handler)
{
if (async_handler_ptr->ready)
break;
}
if (async_handler_ptr == NULL)
break;
async_handler_ptr->ready = 0;
(*async_handler_ptr->proc) (async_handler_ptr->client_data);
}
return;
}
/* Delete an asynchronous handler (ASYNC_HANDLER_PTR).
Free the space allocated for it. */
void
delete_async_signal_handler (async_signal_handler ** async_handler_ptr)
{
async_signal_handler *prev_ptr;
if (sighandler_list.first_handler == (*async_handler_ptr))
{
sighandler_list.first_handler = (*async_handler_ptr)->next_handler;
if (sighandler_list.first_handler == NULL)
sighandler_list.last_handler = NULL;
}
else
{
prev_ptr = sighandler_list.first_handler;
while (prev_ptr->next_handler != (*async_handler_ptr) && prev_ptr)
prev_ptr = prev_ptr->next_handler;
prev_ptr->next_handler = (*async_handler_ptr)->next_handler;
if (sighandler_list.last_handler == (*async_handler_ptr))
sighandler_list.last_handler = prev_ptr;
}
xfree ((*async_handler_ptr));
(*async_handler_ptr) = NULL;
}
/* Is it necessary to call invoke_async_signal_handler? */
static int
check_async_ready (void)
{
return async_handler_ready;
}
/* Create a timer that will expire in MILLISECONDS from now. When the
timer is ready, PROC will be executed. At creation, the timer is
aded to the timers queue. This queue is kept sorted in order of
increasing timers. Return a handle to the timer struct. */
int
create_timer (int milliseconds, timer_handler_func * proc, gdb_client_data client_data)
{
struct gdb_timer *timer_ptr, *timer_index, *prev_timer;
struct timeval time_now, delta;
/* compute seconds */
delta.tv_sec = milliseconds / 1000;
/* compute microseconds */
delta.tv_usec = (milliseconds % 1000) * 1000;
gettimeofday (&time_now, NULL);
timer_ptr = (struct gdb_timer *) xmalloc (sizeof (gdb_timer));
timer_ptr->when.tv_sec = time_now.tv_sec + delta.tv_sec;
timer_ptr->when.tv_usec = time_now.tv_usec + delta.tv_usec;
/* carry? */
if (timer_ptr->when.tv_usec >= 1000000)
{
timer_ptr->when.tv_sec += 1;
timer_ptr->when.tv_usec -= 1000000;
}
timer_ptr->proc = proc;
timer_ptr->client_data = client_data;
timer_list.num_timers++;
timer_ptr->timer_id = timer_list.num_timers;
/* Now add the timer to the timer queue, making sure it is sorted in
increasing order of expiration. */
for (timer_index = timer_list.first_timer;
timer_index != NULL;
timer_index = timer_index->next)
{
/* If the seconds field is greater or if it is the same, but the
microsecond field is greater. */
if ((timer_index->when.tv_sec > timer_ptr->when.tv_sec) ||
((timer_index->when.tv_sec == timer_ptr->when.tv_sec)
&& (timer_index->when.tv_usec > timer_ptr->when.tv_usec)))
break;
}
if (timer_index == timer_list.first_timer)
{
timer_ptr->next = timer_list.first_timer;
timer_list.first_timer = timer_ptr;
}
else
{
for (prev_timer = timer_list.first_timer;
prev_timer->next != timer_index;
prev_timer = prev_timer->next)
;
prev_timer->next = timer_ptr;
timer_ptr->next = timer_index;
}
gdb_notifier.timeout_valid = 0;
return timer_ptr->timer_id;
}
/* There is a chance that the creator of the timer wants to get rid of
it before it expires. */
void
delete_timer (int id)
{
struct gdb_timer *timer_ptr, *prev_timer = NULL;
/* Find the entry for the given timer. */
for (timer_ptr = timer_list.first_timer; timer_ptr != NULL;
timer_ptr = timer_ptr->next)
{
if (timer_ptr->timer_id == id)
break;
}
if (timer_ptr == NULL)
return;
/* Get rid of the timer in the timer list. */
if (timer_ptr == timer_list.first_timer)
timer_list.first_timer = timer_ptr->next;
else
{
for (prev_timer = timer_list.first_timer;
prev_timer->next != timer_ptr;
prev_timer = prev_timer->next)
;
prev_timer->next = timer_ptr->next;
}
xfree (timer_ptr);
gdb_notifier.timeout_valid = 0;
}
/* When a timer event is put on the event queue, it will be handled by
this function. Just call the assiciated procedure and delete the
timer event from the event queue. Repeat this for each timer that
has expired. */
static void
handle_timer_event (int dummy)
{
struct timeval time_now;
struct gdb_timer *timer_ptr, *saved_timer;
gettimeofday (&time_now, NULL);
timer_ptr = timer_list.first_timer;
while (timer_ptr != NULL)
{
if ((timer_ptr->when.tv_sec > time_now.tv_sec) ||
((timer_ptr->when.tv_sec == time_now.tv_sec) &&
(timer_ptr->when.tv_usec > time_now.tv_usec)))
break;
/* Get rid of the timer from the beginning of the list. */
timer_list.first_timer = timer_ptr->next;
saved_timer = timer_ptr;
timer_ptr = timer_ptr->next;
/* Call the procedure associated with that timer. */
(*saved_timer->proc) (saved_timer->client_data);
xfree (saved_timer);
}
gdb_notifier.timeout_valid = 0;
}
/* Check whether any timers in the timers queue are ready. If at least
one timer is ready, stick an event onto the event queue. Even in
case more than one timer is ready, one event is enough, because the
handle_timer_event() will go through the timers list and call the
procedures associated with all that have expired. Update the
timeout for the select() or poll() as well. */
static void
poll_timers (void)
{
struct timeval time_now, delta;
gdb_event *event_ptr;
if (timer_list.first_timer != NULL)
{
gettimeofday (&time_now, NULL);
delta.tv_sec = timer_list.first_timer->when.tv_sec - time_now.tv_sec;
delta.tv_usec = timer_list.first_timer->when.tv_usec - time_now.tv_usec;
/* borrow? */
if (delta.tv_usec < 0)
{
delta.tv_sec -= 1;
delta.tv_usec += 1000000;
}
/* Oops it expired already. Tell select / poll to return
immediately. (Cannot simply test if delta.tv_sec is negative
because time_t might be unsigned.) */
if (timer_list.first_timer->when.tv_sec < time_now.tv_sec
|| (timer_list.first_timer->when.tv_sec == time_now.tv_sec
&& timer_list.first_timer->when.tv_usec < time_now.tv_usec))
{
delta.tv_sec = 0;
delta.tv_usec = 0;
}
if (delta.tv_sec == 0 && delta.tv_usec == 0)
{
event_ptr = (gdb_event *) xmalloc (sizeof (gdb_event));
event_ptr->proc = handle_timer_event;
event_ptr->fd = timer_list.first_timer->timer_id;
async_queue_event (event_ptr, TAIL);
}
/* Now we need to update the timeout for select/ poll, because we
don't want to sit there while this timer is expiring. */
if (use_poll)
{
#ifdef HAVE_POLL
gdb_notifier.poll_timeout = delta.tv_sec * 1000;
#else
internal_error (__FILE__, __LINE__,
_("use_poll without HAVE_POLL"));
#endif /* HAVE_POLL */
}
else
{
gdb_notifier.select_timeout.tv_sec = delta.tv_sec;
gdb_notifier.select_timeout.tv_usec = delta.tv_usec;
}
gdb_notifier.timeout_valid = 1;
}
else
gdb_notifier.timeout_valid = 0;
}