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|
/* Interface between GDB and target environments, including files and processes
Copyright 1990, 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999,
2000, 2001 Free Software Foundation, Inc.
Contributed by Cygnus Support. Written by John Gilmore.
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. */
#if !defined (TARGET_H)
#define TARGET_H
/* This include file defines the interface between the main part
of the debugger, and the part which is target-specific, or
specific to the communications interface between us and the
target.
A TARGET is an interface between the debugger and a particular
kind of file or process. Targets can be STACKED in STRATA,
so that more than one target can potentially respond to a request.
In particular, memory accesses will walk down the stack of targets
until they find a target that is interested in handling that particular
address. STRATA are artificial boundaries on the stack, within
which particular kinds of targets live. Strata exist so that
people don't get confused by pushing e.g. a process target and then
a file target, and wondering why they can't see the current values
of variables any more (the file target is handling them and they
never get to the process target). So when you push a file target,
it goes into the file stratum, which is always below the process
stratum. */
#include "bfd.h"
#include "symtab.h"
#include "dcache.h"
#include "memattr.h"
enum strata
{
dummy_stratum, /* The lowest of the low */
file_stratum, /* Executable files, etc */
core_stratum, /* Core dump files */
download_stratum, /* Downloading of remote targets */
process_stratum, /* Executing processes */
thread_stratum /* Executing threads */
};
enum thread_control_capabilities
{
tc_none = 0, /* Default: can't control thread execution. */
tc_schedlock = 1, /* Can lock the thread scheduler. */
tc_switch = 2 /* Can switch the running thread on demand. */
};
/* Stuff for target_wait. */
/* Generally, what has the program done? */
enum target_waitkind
{
/* The program has exited. The exit status is in value.integer. */
TARGET_WAITKIND_EXITED,
/* The program has stopped with a signal. Which signal is in
value.sig. */
TARGET_WAITKIND_STOPPED,
/* The program has terminated with a signal. Which signal is in
value.sig. */
TARGET_WAITKIND_SIGNALLED,
/* The program is letting us know that it dynamically loaded something
(e.g. it called load(2) on AIX). */
TARGET_WAITKIND_LOADED,
/* The program has forked. A "related" process' ID is in
value.related_pid. I.e., if the child forks, value.related_pid
is the parent's ID. */
TARGET_WAITKIND_FORKED,
/* The program has vforked. A "related" process's ID is in
value.related_pid. */
TARGET_WAITKIND_VFORKED,
/* The program has exec'ed a new executable file. The new file's
pathname is pointed to by value.execd_pathname. */
TARGET_WAITKIND_EXECD,
/* The program has entered or returned from a system call. On
HP-UX, this is used in the hardware watchpoint implementation.
The syscall's unique integer ID number is in value.syscall_id */
TARGET_WAITKIND_SYSCALL_ENTRY,
TARGET_WAITKIND_SYSCALL_RETURN,
/* Nothing happened, but we stopped anyway. This perhaps should be handled
within target_wait, but I'm not sure target_wait should be resuming the
inferior. */
TARGET_WAITKIND_SPURIOUS,
/* This is used for target async and extended-async
only. Remote_async_wait() returns this when there is an event
on the inferior, but the rest of the world is not interested in
it. The inferior has not stopped, but has just sent some output
to the console, for instance. In this case, we want to go back
to the event loop and wait there for another event from the
inferior, rather than being stuck in the remote_async_wait()
function. This way the event loop is responsive to other events,
like for instance the user typing. */
TARGET_WAITKIND_IGNORE
};
struct target_waitstatus
{
enum target_waitkind kind;
/* Forked child pid, execd pathname, exit status or signal number. */
union
{
int integer;
enum target_signal sig;
int related_pid;
char *execd_pathname;
int syscall_id;
}
value;
};
/* Possible types of events that the inferior handler will have to
deal with. */
enum inferior_event_type
{
/* There is a request to quit the inferior, abandon it. */
INF_QUIT_REQ,
/* Process a normal inferior event which will result in target_wait
being called. */
INF_REG_EVENT,
/* Deal with an error on the inferior. */
INF_ERROR,
/* We are called because a timer went off. */
INF_TIMER,
/* We are called to do stuff after the inferior stops. */
INF_EXEC_COMPLETE,
/* We are called to do some stuff after the inferior stops, but we
are expected to reenter the proceed() and
handle_inferior_event() functions. This is used only in case of
'step n' like commands. */
INF_EXEC_CONTINUE
};
/* Return the string for a signal. */
extern char *target_signal_to_string (enum target_signal);
/* Return the name (SIGHUP, etc.) for a signal. */
extern char *target_signal_to_name (enum target_signal);
/* Given a name (SIGHUP, etc.), return its signal. */
enum target_signal target_signal_from_name (char *);
/* If certain kinds of activity happen, target_wait should perform
callbacks. */
/* Right now we just call (*TARGET_ACTIVITY_FUNCTION) if I/O is possible
on TARGET_ACTIVITY_FD. */
extern int target_activity_fd;
/* Returns zero to leave the inferior alone, one to interrupt it. */
extern int (*target_activity_function) (void);
struct thread_info; /* fwd decl for parameter list below: */
struct target_ops
{
char *to_shortname; /* Name this target type */
char *to_longname; /* Name for printing */
char *to_doc; /* Documentation. Does not include trailing
newline, and starts with a one-line descrip-
tion (probably similar to to_longname). */
void (*to_open) (char *, int);
void (*to_close) (int);
void (*to_attach) (char *, int);
void (*to_post_attach) (int);
void (*to_require_attach) (char *, int);
void (*to_detach) (char *, int);
void (*to_require_detach) (int, char *, int);
void (*to_resume) (int, int, enum target_signal);
int (*to_wait) (int, struct target_waitstatus *);
void (*to_post_wait) (int, int);
void (*to_fetch_registers) (int);
void (*to_store_registers) (int);
void (*to_prepare_to_store) (void);
/* Transfer LEN bytes of memory between GDB address MYADDR and
target address MEMADDR. If WRITE, transfer them to the target, else
transfer them from the target. TARGET is the target from which we
get this function.
Return value, N, is one of the following:
0 means that we can't handle this. If errno has been set, it is the
error which prevented us from doing it (FIXME: What about bfd_error?).
positive (call it N) means that we have transferred N bytes
starting at MEMADDR. We might be able to handle more bytes
beyond this length, but no promises.
negative (call its absolute value N) means that we cannot
transfer right at MEMADDR, but we could transfer at least
something at MEMADDR + N. */
int (*to_xfer_memory) (CORE_ADDR memaddr, char *myaddr,
int len, int write,
struct mem_attrib *attrib,
struct target_ops *target);
#if 0
/* Enable this after 4.12. */
/* Search target memory. Start at STARTADDR and take LEN bytes of
target memory, and them with MASK, and compare to DATA. If they
match, set *ADDR_FOUND to the address we found it at, store the data
we found at LEN bytes starting at DATA_FOUND, and return. If
not, add INCREMENT to the search address and keep trying until
the search address is outside of the range [LORANGE,HIRANGE).
If we don't find anything, set *ADDR_FOUND to (CORE_ADDR)0 and
return. */
void (*to_search) (int len, char *data, char *mask,
CORE_ADDR startaddr, int increment,
CORE_ADDR lorange, CORE_ADDR hirange,
CORE_ADDR * addr_found, char *data_found);
#define target_search(len, data, mask, startaddr, increment, lorange, hirange, addr_found, data_found) \
(*current_target.to_search) (len, data, mask, startaddr, increment, \
lorange, hirange, addr_found, data_found)
#endif /* 0 */
void (*to_files_info) (struct target_ops *);
int (*to_insert_breakpoint) (CORE_ADDR, char *);
int (*to_remove_breakpoint) (CORE_ADDR, char *);
void (*to_terminal_init) (void);
void (*to_terminal_inferior) (void);
void (*to_terminal_ours_for_output) (void);
void (*to_terminal_ours) (void);
void (*to_terminal_info) (char *, int);
void (*to_kill) (void);
void (*to_load) (char *, int);
int (*to_lookup_symbol) (char *, CORE_ADDR *);
void (*to_create_inferior) (char *, char *, char **);
void (*to_post_startup_inferior) (int);
void (*to_acknowledge_created_inferior) (int);
void (*to_clone_and_follow_inferior) (int, int *);
void (*to_post_follow_inferior_by_clone) (void);
int (*to_insert_fork_catchpoint) (int);
int (*to_remove_fork_catchpoint) (int);
int (*to_insert_vfork_catchpoint) (int);
int (*to_remove_vfork_catchpoint) (int);
int (*to_has_forked) (int, int *);
int (*to_has_vforked) (int, int *);
int (*to_can_follow_vfork_prior_to_exec) (void);
void (*to_post_follow_vfork) (int, int, int, int);
int (*to_insert_exec_catchpoint) (int);
int (*to_remove_exec_catchpoint) (int);
int (*to_has_execd) (int, char **);
int (*to_reported_exec_events_per_exec_call) (void);
int (*to_has_syscall_event) (int, enum target_waitkind *, int *);
int (*to_has_exited) (int, int, int *);
void (*to_mourn_inferior) (void);
int (*to_can_run) (void);
void (*to_notice_signals) (int pid);
int (*to_thread_alive) (int pid);
void (*to_find_new_threads) (void);
char *(*to_pid_to_str) (int);
char *(*to_extra_thread_info) (struct thread_info *);
void (*to_stop) (void);
int (*to_query) (int /*char */ , char *, char *, int *);
void (*to_rcmd) (char *command, struct ui_file *output);
struct symtab_and_line *(*to_enable_exception_callback) (enum
exception_event_kind,
int);
struct exception_event_record *(*to_get_current_exception_event) (void);
char *(*to_pid_to_exec_file) (int pid);
char *(*to_core_file_to_sym_file) (char *);
enum strata to_stratum;
struct target_ops
*DONT_USE; /* formerly to_next */
int to_has_all_memory;
int to_has_memory;
int to_has_stack;
int to_has_registers;
int to_has_execution;
int to_has_thread_control; /* control thread execution */
struct section_table
*to_sections;
struct section_table
*to_sections_end;
/* ASYNC target controls */
int (*to_can_async_p) (void);
int (*to_is_async_p) (void);
void (*to_async) (void (*cb) (enum inferior_event_type, void *context),
void *context);
int to_async_mask_value;
int to_magic;
/* Need sub-structure for target machine related rather than comm related?
*/
};
/* Magic number for checking ops size. If a struct doesn't end with this
number, somebody changed the declaration but didn't change all the
places that initialize one. */
#define OPS_MAGIC 3840
/* The ops structure for our "current" target process. This should
never be NULL. If there is no target, it points to the dummy_target. */
extern struct target_ops current_target;
/* An item on the target stack. */
struct target_stack_item
{
struct target_stack_item *next;
struct target_ops *target_ops;
};
/* The target stack. */
extern struct target_stack_item *target_stack;
/* Define easy words for doing these operations on our current target. */
#define target_shortname (current_target.to_shortname)
#define target_longname (current_target.to_longname)
/* The open routine takes the rest of the parameters from the command,
and (if successful) pushes a new target onto the stack.
Targets should supply this routine, if only to provide an error message. */
#define target_open(name, from_tty) \
do { \
dcache_invalidate (target_dcache); \
(*current_target.to_open) (name, from_tty); \
} while (0)
/* Does whatever cleanup is required for a target that we are no longer
going to be calling. Argument says whether we are quitting gdb and
should not get hung in case of errors, or whether we want a clean
termination even if it takes a while. This routine is automatically
always called just before a routine is popped off the target stack.
Closing file descriptors and freeing memory are typical things it should
do. */
#define target_close(quitting) \
(*current_target.to_close) (quitting)
/* Attaches to a process on the target side. Arguments are as passed
to the `attach' command by the user. This routine can be called
when the target is not on the target-stack, if the target_can_run
routine returns 1; in that case, it must push itself onto the stack.
Upon exit, the target should be ready for normal operations, and
should be ready to deliver the status of the process immediately
(without waiting) to an upcoming target_wait call. */
#define target_attach(args, from_tty) \
(*current_target.to_attach) (args, from_tty)
/* The target_attach operation places a process under debugger control,
and stops the process.
This operation provides a target-specific hook that allows the
necessary bookkeeping to be performed after an attach completes. */
#define target_post_attach(pid) \
(*current_target.to_post_attach) (pid)
/* Attaches to a process on the target side, if not already attached.
(If already attached, takes no action.)
This operation can be used to follow the child process of a fork.
On some targets, such child processes of an original inferior process
are automatically under debugger control, and thus do not require an
actual attach operation. */
#define target_require_attach(args, from_tty) \
(*current_target.to_require_attach) (args, from_tty)
/* Takes a program previously attached to and detaches it.
The program may resume execution (some targets do, some don't) and will
no longer stop on signals, etc. We better not have left any breakpoints
in the program or it'll die when it hits one. ARGS is arguments
typed by the user (e.g. a signal to send the process). FROM_TTY
says whether to be verbose or not. */
extern void target_detach (char *, int);
/* Detaches from a process on the target side, if not already dettached.
(If already detached, takes no action.)
This operation can be used to follow the parent process of a fork.
On some targets, such child processes of an original inferior process
are automatically under debugger control, and thus do require an actual
detach operation.
PID is the process id of the child to detach from.
ARGS is arguments typed by the user (e.g. a signal to send the process).
FROM_TTY says whether to be verbose or not. */
#define target_require_detach(pid, args, from_tty) \
(*current_target.to_require_detach) (pid, args, from_tty)
/* Resume execution of the target process PID. STEP says whether to
single-step or to run free; SIGGNAL is the signal to be given to
the target, or TARGET_SIGNAL_0 for no signal. The caller may not
pass TARGET_SIGNAL_DEFAULT. */
#define target_resume(pid, step, siggnal) \
do { \
dcache_invalidate(target_dcache); \
(*current_target.to_resume) (pid, step, siggnal); \
} while (0)
/* Wait for process pid to do something. Pid = -1 to wait for any pid
to do something. Return pid of child, or -1 in case of error;
store status through argument pointer STATUS. Note that it is
*not* OK to return_to_top_level out of target_wait without popping
the debugging target from the stack; GDB isn't prepared to get back
to the prompt with a debugging target but without the frame cache,
stop_pc, etc., set up. */
#define target_wait(pid, status) \
(*current_target.to_wait) (pid, status)
/* The target_wait operation waits for a process event to occur, and
thereby stop the process.
On some targets, certain events may happen in sequences. gdb's
correct response to any single event of such a sequence may require
knowledge of what earlier events in the sequence have been seen.
This operation provides a target-specific hook that allows the
necessary bookkeeping to be performed to track such sequences. */
#define target_post_wait(pid, status) \
(*current_target.to_post_wait) (pid, status)
/* Fetch at least register REGNO, or all regs if regno == -1. No result. */
#define target_fetch_registers(regno) \
(*current_target.to_fetch_registers) (regno)
/* Store at least register REGNO, or all regs if REGNO == -1.
It can store as many registers as it wants to, so target_prepare_to_store
must have been previously called. Calls error() if there are problems. */
#define target_store_registers(regs) \
(*current_target.to_store_registers) (regs)
/* Get ready to modify the registers array. On machines which store
individual registers, this doesn't need to do anything. On machines
which store all the registers in one fell swoop, this makes sure
that REGISTERS contains all the registers from the program being
debugged. */
#define target_prepare_to_store() \
(*current_target.to_prepare_to_store) ()
extern DCACHE *target_dcache;
extern int do_xfer_memory (CORE_ADDR memaddr, char *myaddr, int len, int write,
struct mem_attrib *attrib);
extern int target_read_string (CORE_ADDR, char **, int, int *);
extern int target_read_memory (CORE_ADDR memaddr, char *myaddr, int len);
extern int target_write_memory (CORE_ADDR memaddr, char *myaddr, int len);
extern int xfer_memory (CORE_ADDR, char *, int, int,
struct mem_attrib *, struct target_ops *);
extern int child_xfer_memory (CORE_ADDR, char *, int, int,
struct mem_attrib *, struct target_ops *);
/* Make a single attempt at transfering LEN bytes. On a successful
transfer, the number of bytes actually transfered is returned and
ERR is set to 0. When a transfer fails, -1 is returned (the number
of bytes actually transfered is not defined) and ERR is set to a
non-zero error indication. */
extern int
target_read_memory_partial (CORE_ADDR addr, char *buf, int len, int *err);
extern int
target_write_memory_partial (CORE_ADDR addr, char *buf, int len, int *err);
extern char *child_pid_to_exec_file (int);
extern char *child_core_file_to_sym_file (char *);
#if defined(CHILD_POST_ATTACH)
extern void child_post_attach (int);
#endif
extern void child_post_wait (int, int);
extern void child_post_startup_inferior (int);
extern void child_acknowledge_created_inferior (int);
extern void child_clone_and_follow_inferior (int, int *);
extern void child_post_follow_inferior_by_clone (void);
extern int child_insert_fork_catchpoint (int);
extern int child_remove_fork_catchpoint (int);
extern int child_insert_vfork_catchpoint (int);
extern int child_remove_vfork_catchpoint (int);
extern int child_has_forked (int, int *);
extern int child_has_vforked (int, int *);
extern void child_acknowledge_created_inferior (int);
extern int child_can_follow_vfork_prior_to_exec (void);
extern void child_post_follow_vfork (int, int, int, int);
extern int child_insert_exec_catchpoint (int);
extern int child_remove_exec_catchpoint (int);
extern int child_has_execd (int, char **);
extern int child_reported_exec_events_per_exec_call (void);
extern int child_has_syscall_event (int, enum target_waitkind *, int *);
extern int child_has_exited (int, int, int *);
extern int child_thread_alive (int);
/* From exec.c */
extern void print_section_info (struct target_ops *, bfd *);
/* Print a line about the current target. */
#define target_files_info() \
(*current_target.to_files_info) (¤t_target)
/* Insert a breakpoint at address ADDR in the target machine.
SAVE is a pointer to memory allocated for saving the
target contents. It is guaranteed by the caller to be long enough
to save "sizeof BREAKPOINT" bytes. Result is 0 for success, or
an errno value. */
#define target_insert_breakpoint(addr, save) \
(*current_target.to_insert_breakpoint) (addr, save)
/* Remove a breakpoint at address ADDR in the target machine.
SAVE is a pointer to the same save area
that was previously passed to target_insert_breakpoint.
Result is 0 for success, or an errno value. */
#define target_remove_breakpoint(addr, save) \
(*current_target.to_remove_breakpoint) (addr, save)
/* Initialize the terminal settings we record for the inferior,
before we actually run the inferior. */
#define target_terminal_init() \
(*current_target.to_terminal_init) ()
/* Put the inferior's terminal settings into effect.
This is preparation for starting or resuming the inferior. */
#define target_terminal_inferior() \
(*current_target.to_terminal_inferior) ()
/* Put some of our terminal settings into effect,
enough to get proper results from our output,
but do not change into or out of RAW mode
so that no input is discarded.
After doing this, either terminal_ours or terminal_inferior
should be called to get back to a normal state of affairs. */
#define target_terminal_ours_for_output() \
(*current_target.to_terminal_ours_for_output) ()
/* Put our terminal settings into effect.
First record the inferior's terminal settings
so they can be restored properly later. */
#define target_terminal_ours() \
(*current_target.to_terminal_ours) ()
/* Print useful information about our terminal status, if such a thing
exists. */
#define target_terminal_info(arg, from_tty) \
(*current_target.to_terminal_info) (arg, from_tty)
/* Kill the inferior process. Make it go away. */
#define target_kill() \
(*current_target.to_kill) ()
/* Load an executable file into the target process. This is expected
to not only bring new code into the target process, but also to
update GDB's symbol tables to match. */
extern void target_load (char *arg, int from_tty);
/* Look up a symbol in the target's symbol table. NAME is the symbol
name. ADDRP is a CORE_ADDR * pointing to where the value of the
symbol should be returned. The result is 0 if successful, nonzero
if the symbol does not exist in the target environment. This
function should not call error() if communication with the target
is interrupted, since it is called from symbol reading, but should
return nonzero, possibly doing a complain(). */
#define target_lookup_symbol(name, addrp) \
(*current_target.to_lookup_symbol) (name, addrp)
/* Start an inferior process and set inferior_pid to its pid.
EXEC_FILE is the file to run.
ALLARGS is a string containing the arguments to the program.
ENV is the environment vector to pass. Errors reported with error().
On VxWorks and various standalone systems, we ignore exec_file. */
#define target_create_inferior(exec_file, args, env) \
(*current_target.to_create_inferior) (exec_file, args, env)
/* Some targets (such as ttrace-based HPUX) don't allow us to request
notification of inferior events such as fork and vork immediately
after the inferior is created. (This because of how gdb gets an
inferior created via invoking a shell to do it. In such a scenario,
if the shell init file has commands in it, the shell will fork and
exec for each of those commands, and we will see each such fork
event. Very bad.)
Such targets will supply an appropriate definition for this function. */
#define target_post_startup_inferior(pid) \
(*current_target.to_post_startup_inferior) (pid)
/* On some targets, the sequence of starting up an inferior requires
some synchronization between gdb and the new inferior process, PID. */
#define target_acknowledge_created_inferior(pid) \
(*current_target.to_acknowledge_created_inferior) (pid)
/* An inferior process has been created via a fork() or similar
system call. This function will clone the debugger, then ensure
that CHILD_PID is attached to by that debugger.
FOLLOWED_CHILD is set TRUE on return *for the clone debugger only*,
and FALSE otherwise. (The original and clone debuggers can use this
to determine which they are, if need be.)
(This is not a terribly useful feature without a GUI to prevent
the two debuggers from competing for shell input.) */
#define target_clone_and_follow_inferior(child_pid,followed_child) \
(*current_target.to_clone_and_follow_inferior) (child_pid, followed_child)
/* This operation is intended to be used as the last in a sequence of
steps taken when following both parent and child of a fork. This
is used by a clone of the debugger, which will follow the child.
The original debugger has detached from this process, and the
clone has attached to it.
On some targets, this requires a bit of cleanup to make it work
correctly. */
#define target_post_follow_inferior_by_clone() \
(*current_target.to_post_follow_inferior_by_clone) ()
/* On some targets, we can catch an inferior fork or vfork event when
it occurs. These functions insert/remove an already-created
catchpoint for such events. */
#define target_insert_fork_catchpoint(pid) \
(*current_target.to_insert_fork_catchpoint) (pid)
#define target_remove_fork_catchpoint(pid) \
(*current_target.to_remove_fork_catchpoint) (pid)
#define target_insert_vfork_catchpoint(pid) \
(*current_target.to_insert_vfork_catchpoint) (pid)
#define target_remove_vfork_catchpoint(pid) \
(*current_target.to_remove_vfork_catchpoint) (pid)
/* Returns TRUE if PID has invoked the fork() system call. And,
also sets CHILD_PID to the process id of the other ("child")
inferior process that was created by that call. */
#define target_has_forked(pid,child_pid) \
(*current_target.to_has_forked) (pid,child_pid)
/* Returns TRUE if PID has invoked the vfork() system call. And,
also sets CHILD_PID to the process id of the other ("child")
inferior process that was created by that call. */
#define target_has_vforked(pid,child_pid) \
(*current_target.to_has_vforked) (pid,child_pid)
/* Some platforms (such as pre-10.20 HP-UX) don't allow us to do
anything to a vforked child before it subsequently calls exec().
On such platforms, we say that the debugger cannot "follow" the
child until it has vforked.
This function should be defined to return 1 by those targets
which can allow the debugger to immediately follow a vforked
child, and 0 if they cannot. */
#define target_can_follow_vfork_prior_to_exec() \
(*current_target.to_can_follow_vfork_prior_to_exec) ()
/* An inferior process has been created via a vfork() system call.
The debugger has followed the parent, the child, or both. The
process of setting up for that follow may have required some
target-specific trickery to track the sequence of reported events.
If so, this function should be defined by those targets that
require the debugger to perform cleanup or initialization after
the vfork follow. */
#define target_post_follow_vfork(parent_pid,followed_parent,child_pid,followed_child) \
(*current_target.to_post_follow_vfork) (parent_pid,followed_parent,child_pid,followed_child)
/* On some targets, we can catch an inferior exec event when it
occurs. These functions insert/remove an already-created
catchpoint for such events. */
#define target_insert_exec_catchpoint(pid) \
(*current_target.to_insert_exec_catchpoint) (pid)
#define target_remove_exec_catchpoint(pid) \
(*current_target.to_remove_exec_catchpoint) (pid)
/* Returns TRUE if PID has invoked a flavor of the exec() system call.
And, also sets EXECD_PATHNAME to the pathname of the executable
file that was passed to exec(), and is now being executed. */
#define target_has_execd(pid,execd_pathname) \
(*current_target.to_has_execd) (pid,execd_pathname)
/* Returns the number of exec events that are reported when a process
invokes a flavor of the exec() system call on this target, if exec
events are being reported. */
#define target_reported_exec_events_per_exec_call() \
(*current_target.to_reported_exec_events_per_exec_call) ()
/* Returns TRUE if PID has reported a syscall event. And, also sets
KIND to the appropriate TARGET_WAITKIND_, and sets SYSCALL_ID to
the unique integer ID of the syscall. */
#define target_has_syscall_event(pid,kind,syscall_id) \
(*current_target.to_has_syscall_event) (pid,kind,syscall_id)
/* Returns TRUE if PID has exited. And, also sets EXIT_STATUS to the
exit code of PID, if any. */
#define target_has_exited(pid,wait_status,exit_status) \
(*current_target.to_has_exited) (pid,wait_status,exit_status)
/* The debugger has completed a blocking wait() call. There is now
some process event that must be processed. This function should
be defined by those targets that require the debugger to perform
cleanup or internal state changes in response to the process event. */
/* The inferior process has died. Do what is right. */
#define target_mourn_inferior() \
(*current_target.to_mourn_inferior) ()
/* Does target have enough data to do a run or attach command? */
#define target_can_run(t) \
((t)->to_can_run) ()
/* post process changes to signal handling in the inferior. */
#define target_notice_signals(pid) \
(*current_target.to_notice_signals) (pid)
/* Check to see if a thread is still alive. */
#define target_thread_alive(pid) \
(*current_target.to_thread_alive) (pid)
/* Query for new threads and add them to the thread list. */
#define target_find_new_threads() \
(*current_target.to_find_new_threads) (); \
/* Make target stop in a continuable fashion. (For instance, under
Unix, this should act like SIGSTOP). This function is normally
used by GUIs to implement a stop button. */
#define target_stop current_target.to_stop
/* Queries the target side for some information. The first argument is a
letter specifying the type of the query, which is used to determine who
should process it. The second argument is a string that specifies which
information is desired and the third is a buffer that carries back the
response from the target side. The fourth parameter is the size of the
output buffer supplied. */
#define target_query(query_type, query, resp_buffer, bufffer_size) \
(*current_target.to_query) (query_type, query, resp_buffer, bufffer_size)
/* Send the specified COMMAND to the target's monitor
(shell,interpreter) for execution. The result of the query is
placed in OUTBUF. */
#define target_rcmd(command, outbuf) \
(*current_target.to_rcmd) (command, outbuf)
/* Get the symbol information for a breakpointable routine called when
an exception event occurs.
Intended mainly for C++, and for those
platforms/implementations where such a callback mechanism is available,
e.g. HP-UX with ANSI C++ (aCC). Some compilers (e.g. g++) support
different mechanisms for debugging exceptions. */
#define target_enable_exception_callback(kind, enable) \
(*current_target.to_enable_exception_callback) (kind, enable)
/* Get the current exception event kind -- throw or catch, etc. */
#define target_get_current_exception_event() \
(*current_target.to_get_current_exception_event) ()
/* Pointer to next target in the chain, e.g. a core file and an exec file. */
#define target_next \
(current_target.to_next)
/* Does the target include all of memory, or only part of it? This
determines whether we look up the target chain for other parts of
memory if this target can't satisfy a request. */
#define target_has_all_memory \
(current_target.to_has_all_memory)
/* Does the target include memory? (Dummy targets don't.) */
#define target_has_memory \
(current_target.to_has_memory)
/* Does the target have a stack? (Exec files don't, VxWorks doesn't, until
we start a process.) */
#define target_has_stack \
(current_target.to_has_stack)
/* Does the target have registers? (Exec files don't.) */
#define target_has_registers \
(current_target.to_has_registers)
/* Does the target have execution? Can we make it jump (through
hoops), or pop its stack a few times? FIXME: If this is to work that
way, it needs to check whether an inferior actually exists.
remote-udi.c and probably other targets can be the current target
when the inferior doesn't actually exist at the moment. Right now
this just tells us whether this target is *capable* of execution. */
#define target_has_execution \
(current_target.to_has_execution)
/* Can the target support the debugger control of thread execution?
a) Can it lock the thread scheduler?
b) Can it switch the currently running thread? */
#define target_can_lock_scheduler \
(current_target.to_has_thread_control & tc_schedlock)
#define target_can_switch_threads \
(current_target.to_has_thread_control & tc_switch)
/* Can the target support asynchronous execution? */
#define target_can_async_p() (current_target.to_can_async_p ())
/* Is the target in asynchronous execution mode? */
#define target_is_async_p() (current_target.to_is_async_p())
/* Put the target in async mode with the specified callback function. */
#define target_async(CALLBACK,CONTEXT) \
(current_target.to_async((CALLBACK), (CONTEXT)))
/* This is to be used ONLY within run_stack_dummy(). It
provides a workaround, to have inferior function calls done in
sychronous mode, even though the target is asynchronous. After
target_async_mask(0) is called, calls to target_can_async_p() will
return FALSE , so that target_resume() will not try to start the
target asynchronously. After the inferior stops, we IMMEDIATELY
restore the previous nature of the target, by calling
target_async_mask(1). After that, target_can_async_p() will return
TRUE. ANY OTHER USE OF THIS FEATURE IS DEPRECATED.
FIXME ezannoni 1999-12-13: we won't need this once we move
the turning async on and off to the single execution commands,
from where it is done currently, in remote_resume(). */
#define target_async_mask_value \
(current_target.to_async_mask_value)
extern int target_async_mask (int mask);
extern void target_link (char *, CORE_ADDR *);
/* Converts a process id to a string. Usually, the string just contains
`process xyz', but on some systems it may contain
`process xyz thread abc'. */
#undef target_pid_to_str
#define target_pid_to_str(PID) current_target.to_pid_to_str (PID)
#ifndef target_tid_to_str
#define target_tid_to_str(PID) \
target_pid_to_str (PID)
extern char *normal_pid_to_str (int pid);
#endif
/* Return a short string describing extra information about PID,
e.g. "sleeping", "runnable", "running on LWP 3". Null return value
is okay. */
#define target_extra_thread_info(TP) \
(current_target.to_extra_thread_info (TP))
/*
* New Objfile Event Hook:
*
* Sometimes a GDB component wants to get notified whenever a new
* objfile is loaded. Mainly this is used by thread-debugging
* implementations that need to know when symbols for the target
* thread implemenation are available.
*
* The old way of doing this is to define a macro 'target_new_objfile'
* that points to the function that you want to be called on every
* objfile/shlib load.
*
* The new way is to grab the function pointer, 'target_new_objfile_hook',
* and point it to the function that you want to be called on every
* objfile/shlib load.
*
* If multiple clients are willing to be cooperative, they can each
* save a pointer to the previous value of target_new_objfile_hook
* before modifying it, and arrange for their function to call the
* previous function in the chain. In that way, multiple clients
* can receive this notification (something like with signal handlers).
*/
extern void (*target_new_objfile_hook) (struct objfile *);
#ifndef target_pid_or_tid_to_str
#define target_pid_or_tid_to_str(ID) \
target_pid_to_str (ID)
#endif
/* Attempts to find the pathname of the executable file
that was run to create a specified process.
The process PID must be stopped when this operation is used.
If the executable file cannot be determined, NULL is returned.
Else, a pointer to a character string containing the pathname
is returned. This string should be copied into a buffer by
the client if the string will not be immediately used, or if
it must persist. */
#define target_pid_to_exec_file(pid) \
(current_target.to_pid_to_exec_file) (pid)
/* Hook to call target-dependent code after reading in a new symbol table. */
#ifndef TARGET_SYMFILE_POSTREAD
#define TARGET_SYMFILE_POSTREAD(OBJFILE)
#endif
/* Hook to call target dependent code just after inferior target process has
started. */
#ifndef TARGET_CREATE_INFERIOR_HOOK
#define TARGET_CREATE_INFERIOR_HOOK(PID)
#endif
/* Hardware watchpoint interfaces. */
/* Returns non-zero if we were stopped by a hardware watchpoint (memory read or
write). */
#ifndef STOPPED_BY_WATCHPOINT
#define STOPPED_BY_WATCHPOINT(w) 0
#endif
/* HP-UX supplies these operations, which respectively disable and enable
the memory page-protections that are used to implement hardware watchpoints
on that platform. See wait_for_inferior's use of these. */
#if !defined(TARGET_DISABLE_HW_WATCHPOINTS)
#define TARGET_DISABLE_HW_WATCHPOINTS(pid)
#endif
#if !defined(TARGET_ENABLE_HW_WATCHPOINTS)
#define TARGET_ENABLE_HW_WATCHPOINTS(pid)
#endif
/* Provide defaults for systems that don't support hardware watchpoints. */
#ifndef TARGET_HAS_HARDWARE_WATCHPOINTS
/* Returns non-zero if we can set a hardware watchpoint of type TYPE. TYPE is
one of bp_hardware_watchpoint, bp_read_watchpoint, bp_write_watchpoint, or
bp_hardware_breakpoint. CNT is the number of such watchpoints used so far
(including this one?). OTHERTYPE is who knows what... */
#define TARGET_CAN_USE_HARDWARE_WATCHPOINT(TYPE,CNT,OTHERTYPE) 0
#if !defined(TARGET_REGION_SIZE_OK_FOR_HW_WATCHPOINT)
#define TARGET_REGION_SIZE_OK_FOR_HW_WATCHPOINT(byte_count) \
((LONGEST)(byte_count) <= REGISTER_SIZE)
#endif
/* However, some addresses may not be profitable to use hardware to watch,
or may be difficult to understand when the addressed object is out of
scope, and hence should be unwatched. On some targets, this may have
severe performance penalties, such that we might as well use regular
watchpoints, and save (possibly precious) hardware watchpoints for other
locations. */
#if !defined(TARGET_RANGE_PROFITABLE_FOR_HW_WATCHPOINT)
#define TARGET_RANGE_PROFITABLE_FOR_HW_WATCHPOINT(pid,start,len) 0
#endif
/* Set/clear a hardware watchpoint starting at ADDR, for LEN bytes. TYPE is 0
for write, 1 for read, and 2 for read/write accesses. Returns 0 for
success, non-zero for failure. */
#define target_remove_watchpoint(ADDR,LEN,TYPE) -1
#define target_insert_watchpoint(ADDR,LEN,TYPE) -1
#endif /* TARGET_HAS_HARDWARE_WATCHPOINTS */
#ifndef target_insert_hw_breakpoint
#define target_remove_hw_breakpoint(ADDR,SHADOW) -1
#define target_insert_hw_breakpoint(ADDR,SHADOW) -1
#endif
#ifndef target_stopped_data_address
#define target_stopped_data_address() 0
#endif
/* If defined, then we need to decr pc by this much after a hardware break-
point. Presumably this overrides DECR_PC_AFTER_BREAK... */
#ifndef DECR_PC_AFTER_HW_BREAK
#define DECR_PC_AFTER_HW_BREAK 0
#endif
/* Sometimes gdb may pick up what appears to be a valid target address
from a minimal symbol, but the value really means, essentially,
"This is an index into a table which is populated when the inferior
is run. Therefore, do not attempt to use this as a PC." */
#if !defined(PC_REQUIRES_RUN_BEFORE_USE)
#define PC_REQUIRES_RUN_BEFORE_USE(pc) (0)
#endif
/* This will only be defined by a target that supports catching vfork events,
such as HP-UX.
On some targets (such as HP-UX 10.20 and earlier), resuming a newly vforked
child process after it has exec'd, causes the parent process to resume as
well. To prevent the parent from running spontaneously, such targets should
define this to a function that prevents that from happening. */
#if !defined(ENSURE_VFORKING_PARENT_REMAINS_STOPPED)
#define ENSURE_VFORKING_PARENT_REMAINS_STOPPED(PID) (0)
#endif
/* This will only be defined by a target that supports catching vfork events,
such as HP-UX.
On some targets (such as HP-UX 10.20 and earlier), a newly vforked child
process must be resumed when it delivers its exec event, before the parent
vfork event will be delivered to us. */
#if !defined(RESUME_EXECD_VFORKING_CHILD_TO_GET_PARENT_VFORK)
#define RESUME_EXECD_VFORKING_CHILD_TO_GET_PARENT_VFORK() (0)
#endif
/* Routines for maintenance of the target structures...
add_target: Add a target to the list of all possible targets.
push_target: Make this target the top of the stack of currently used
targets, within its particular stratum of the stack. Result
is 0 if now atop the stack, nonzero if not on top (maybe
should warn user).
unpush_target: Remove this from the stack of currently used targets,
no matter where it is on the list. Returns 0 if no
change, 1 if removed from stack.
pop_target: Remove the top thing on the stack of current targets. */
extern void add_target (struct target_ops *);
extern int push_target (struct target_ops *);
extern int unpush_target (struct target_ops *);
extern void target_preopen (int);
extern void pop_target (void);
/* Struct section_table maps address ranges to file sections. It is
mostly used with BFD files, but can be used without (e.g. for handling
raw disks, or files not in formats handled by BFD). */
struct section_table
{
CORE_ADDR addr; /* Lowest address in section */
CORE_ADDR endaddr; /* 1+highest address in section */
sec_ptr the_bfd_section;
bfd *bfd; /* BFD file pointer */
};
/* Builds a section table, given args BFD, SECTABLE_PTR, SECEND_PTR.
Returns 0 if OK, 1 on error. */
extern int
build_section_table (bfd *, struct section_table **, struct section_table **);
/* From mem-break.c */
extern int memory_remove_breakpoint (CORE_ADDR, char *);
extern int memory_insert_breakpoint (CORE_ADDR, char *);
extern int default_memory_remove_breakpoint (CORE_ADDR, char *);
extern int default_memory_insert_breakpoint (CORE_ADDR, char *);
extern breakpoint_from_pc_fn memory_breakpoint_from_pc;
/* From target.c */
extern void initialize_targets (void);
extern void noprocess (void);
extern void find_default_attach (char *, int);
extern void find_default_require_attach (char *, int);
extern void find_default_require_detach (int, char *, int);
extern void find_default_create_inferior (char *, char *, char **);
extern void find_default_clone_and_follow_inferior (int, int *);
extern struct target_ops *find_run_target (void);
extern struct target_ops *find_core_target (void);
extern struct target_ops *find_target_beneath (struct target_ops *);
extern int
target_resize_to_sections (struct target_ops *target, int num_added);
extern void remove_target_sections (bfd *abfd);
/* Stuff that should be shared among the various remote targets. */
/* Debugging level. 0 is off, and non-zero values mean to print some debug
information (higher values, more information). */
extern int remote_debug;
/* Speed in bits per second, or -1 which means don't mess with the speed. */
extern int baud_rate;
/* Timeout limit for response from target. */
extern int remote_timeout;
/* Functions for helping to write a native target. */
/* This is for native targets which use a unix/POSIX-style waitstatus. */
extern void store_waitstatus (struct target_waitstatus *, int);
/* Predicate to target_signal_to_host(). Return non-zero if the enum
targ_signal SIGNO has an equivalent ``host'' representation. */
/* FIXME: cagney/1999-11-22: The name below was chosen in preference
to the shorter target_signal_p() because it is far less ambigious.
In this context ``target_signal'' refers to GDB's internal
representation of the target's set of signals while ``host signal''
refers to the target operating system's signal. Confused? */
extern int target_signal_to_host_p (enum target_signal signo);
/* Convert between host signal numbers and enum target_signal's.
target_signal_to_host() returns 0 and prints a warning() on GDB's
console if SIGNO has no equivalent host representation. */
/* FIXME: cagney/1999-11-22: Here ``host'' is used incorrectly, it is
refering to the target operating system's signal numbering.
Similarly, ``enum target_signal'' is named incorrectly, ``enum
gdb_signal'' would probably be better as it is refering to GDB's
internal representation of a target operating system's signal. */
extern enum target_signal target_signal_from_host (int);
extern int target_signal_to_host (enum target_signal);
/* Convert from a number used in a GDB command to an enum target_signal. */
extern enum target_signal target_signal_from_command (int);
/* Any target can call this to switch to remote protocol (in remote.c). */
extern void push_remote_target (char *name, int from_tty);
/* Imported from machine dependent code */
/* Blank target vector entries are initialized to target_ignore. */
void target_ignore (void);
/* Macro for getting target's idea of a frame pointer.
FIXME: GDB's whole scheme for dealing with "frames" and
"frame pointers" needs a serious shakedown. */
#ifndef TARGET_VIRTUAL_FRAME_POINTER
#define TARGET_VIRTUAL_FRAME_POINTER(ADDR, REGP, OFFP) \
do { *(REGP) = FP_REGNUM; *(OFFP) = 0; } while (0)
#endif /* TARGET_VIRTUAL_FRAME_POINTER */
#endif /* !defined (TARGET_H) */
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