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[/] [openrisc/] [trunk/] [gnu-src/] [gdb-7.1/] [gdb/] [progspace.h] - Blame information for rev 365

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/* Program and address space management, for GDB, the GNU debugger.
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   Copyright (C) 2009, 2010 Free Software Foundation, Inc.
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   This file is part of GDB.
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   This program is free software; you can redistribute it and/or modify
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   it under the terms of the GNU General Public License as published by
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   the Free Software Foundation; either version 3 of the License, or
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   (at your option) any later version.
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   This program is distributed in the hope that it will be useful,
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   but WITHOUT ANY WARRANTY; without even the implied warranty of
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   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
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   GNU General Public License for more details.
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   You should have received a copy of the GNU General Public License
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   along with this program.  If not, see <http://www.gnu.org/licenses/>.  */
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#ifndef PROGSPACE_H
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#define PROGSPACE_H
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#include "target.h"
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#include "vec.h"
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struct target_ops;
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struct bfd;
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struct objfile;
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struct inferior;
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struct exec;
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struct address_space;
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struct program_space_data;
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/* A program space represents a symbolic view of an address space.
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   Roughly speaking, it holds all the data associated with a
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   non-running-yet program (main executable, main symbols), and when
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   an inferior is running and is bound to it, includes the list of its
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   mapped in shared libraries.
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   In the traditional debugging scenario, there's a 1-1 correspondence
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   among program spaces, inferiors and address spaces, like so:
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     pspace1 (prog1) <--> inf1(pid1) <--> aspace1
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   In the case of debugging more than one traditional unix process or
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   program, we still have:
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     |-----------------+------------+---------|
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     | pspace1 (prog1) | inf1(pid1) | aspace1 |
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     |----------------------------------------|
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     | pspace2 (prog1) | no inf yet | aspace2 |
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     |-----------------+------------+---------|
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     | pspace3 (prog2) | inf2(pid2) | aspace3 |
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     |-----------------+------------+---------|
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   In the former example, if inf1 forks (and GDB stays attached to
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   both processes), the new child will have its own program and
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   address spaces.  Like so:
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     |-----------------+------------+---------|
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     | pspace1 (prog1) | inf1(pid1) | aspace1 |
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     |-----------------+------------+---------|
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     | pspace2 (prog1) | inf2(pid2) | aspace2 |
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     |-----------------+------------+---------|
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   However, had inf1 from the latter case vforked instead, it would
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   share the program and address spaces with its parent, until it
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   execs or exits, like so:
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     |-----------------+------------+---------|
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     | pspace1 (prog1) | inf1(pid1) | aspace1 |
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     |                 | inf2(pid2) |         |
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     |-----------------+------------+---------|
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   When the vfork child execs, it is finally given new program and
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   address spaces.
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     |-----------------+------------+---------|
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     | pspace1 (prog1) | inf1(pid1) | aspace1 |
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     |-----------------+------------+---------|
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     | pspace2 (prog1) | inf2(pid2) | aspace2 |
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     |-----------------+------------+---------|
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   There are targets where the OS (if any) doesn't provide memory
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   management or VM protection, where all inferiors share the same
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   address space --- e.g. uClinux.  GDB models this by having all
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   inferiors share the same address space, but, giving each its own
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   program space, like so:
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     |-----------------+------------+---------|
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     | pspace1 (prog1) | inf1(pid1) |         |
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     |-----------------+------------+         |
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     | pspace2 (prog1) | inf2(pid2) | aspace1 |
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     |-----------------+------------+         |
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     | pspace3 (prog2) | inf3(pid3) |         |
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     |-----------------+------------+---------|
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   The address space sharing matters for run control and breakpoints
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   management.  E.g., did we just hit a known breakpoint that we need
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   to step over?  Is this breakpoint a duplicate of this other one, or
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   do I need to insert a trap?
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   Then, there are targets where all symbols look the same for all
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   inferiors, although each has its own address space, as e.g.,
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   Ericsson DICOS.  In such case, the model is:
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     |---------+------------+---------|
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     |         | inf1(pid1) | aspace1 |
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     |         +------------+---------|
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     | pspace  | inf2(pid2) | aspace2 |
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     |         +------------+---------|
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     |         | inf3(pid3) | aspace3 |
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     |---------+------------+---------|
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   Note however, that the DICOS debug API takes care of making GDB
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   believe that breakpoints are "global".  That is, although each
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   process does have its own private copy of data symbols (just like a
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   bunch of forks), to the breakpoints module, all processes share a
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   single address space, so all breakpoints set at the same address
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   are duplicates of each other, even breakpoints set in the data
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   space (e.g., call dummy breakpoints placed on stack).  This allows
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   a simplification in the spaces implementation: we avoid caring for
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   a many-many links between address and program spaces.  Either
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   there's a single address space bound to the program space
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   (traditional unix/uClinux), or, in the DICOS case, the address
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   space bound to the program space is mostly ignored.  */
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/* The program space structure.  */
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struct program_space
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  {
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    /* Pointer to next in linked list.  */
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    struct program_space *next;
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    /* Unique ID number.  */
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    int num;
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    /* The main executable loaded into this program space.  This is
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       managed by the exec target.  */
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    /* The BFD handle for the main executable.  */
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    bfd *ebfd;
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    /* The last-modified time, from when the exec was brought in.  */
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    long ebfd_mtime;
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    /* The address space attached to this program space.  More than one
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       program space may be bound to the same address space.  In the
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       traditional unix-like debugging scenario, this will usually
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       match the address space bound to the inferior, and is mostly
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       used by the breakpoints module for address matches.  If the
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       target shares a program space for all inferiors and breakpoints
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       are global, then this field is ignored (we don't currently
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       support inferiors sharing a program space if the target doesn't
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       make breakpoints global).  */
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    struct address_space *aspace;
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    /* True if this program space's section offsets don't yet represent
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       the final offsets of the "live" address space (that is, the
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       section addresses still require the relocation offsets to be
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       applied, and hence we can't trust the section addresses for
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       anything that pokes at live memory).  E.g., for qOffsets
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       targets, or for PIE executables, until we connect and ask the
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       target for the final relocation offsets, the symbols we've used
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       to set breakpoints point at the wrong addresses.  */
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    int executing_startup;
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    /* True if no breakpoints should be inserted in this program
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       space.  */
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    int breakpoints_not_allowed;
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    /* The object file that the main symbol table was loaded from
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       (e.g. the argument to the "symbol-file" or "file" command).  */
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    struct objfile *symfile_object_file;
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    /* All known objfiles are kept in a linked list.  This points to
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       the head of this list. */
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    struct objfile *objfiles;
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    /* The set of target sections matching the sections mapped into
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       this program space.  Managed by both exec_ops and solib.c.  */
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    struct target_section_table target_sections;
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    /* List of shared objects mapped into this space.  Managed by
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       solib.c.  */
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    struct so_list *so_list;
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    /* Per pspace data-pointers required by other GDB modules.  */
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    void **data;
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    unsigned num_data;
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  };
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/* The object file that the main symbol table was loaded from (e.g. the
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   argument to the "symbol-file" or "file" command).  */
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#define symfile_objfile current_program_space->symfile_object_file
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/* All known objfiles are kept in a linked list.  This points to the
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   root of this list. */
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#define object_files current_program_space->objfiles
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/* The set of target sections matching the sections mapped into the
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   current program space.  */
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#define current_target_sections (&current_program_space->target_sections)
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/* The list of all program spaces.  There's always at least one.  */
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extern struct program_space *program_spaces;
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/* The current program space.  This is always non-null.  */
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extern struct program_space *current_program_space;
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#define ALL_PSPACES(pspace) \
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  for ((pspace) = program_spaces; (pspace) != NULL; (pspace) = (pspace)->next)
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/* Add a new empty program space, and assign ASPACE to it.  Returns the
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   pointer to the new object.  */
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extern struct program_space *add_program_space (struct address_space *aspace);
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/* Release PSPACE and removes it from the pspace list.  */
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extern void remove_program_space (struct program_space *pspace);
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/* Returns the number of program spaces listed.  */
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extern int number_of_program_spaces (void);
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/* Copies program space SRC to DEST.  Copies the main executable file,
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   and the main symbol file.  Returns DEST.  */
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extern struct program_space *clone_program_space (struct program_space *dest,
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                                                struct program_space *src);
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/* Save the current program space so that it may be restored by a later
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   call to do_cleanups.  Returns the struct cleanup pointer needed for
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   later doing the cleanup.  */
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extern struct cleanup *save_current_program_space (void);
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/* Sets PSPACE as the current program space.  This is usually used
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   instead of set_current_space_and_thread when the current
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   thread/inferior is not important for the operations that follow.
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   E.g., when accessing the raw symbol tables.  If memory access is
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   required, then you should use switch_to_program_space_and_thread.
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   Otherwise, it is the caller's responsibility to make sure that the
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   currently selected inferior/thread matches the selected program
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   space.  */
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extern void set_current_program_space (struct program_space *pspace);
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/* Saves the current thread (may be null), frame and program space in
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   the current cleanup chain.  */
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extern struct cleanup *save_current_space_and_thread (void);
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/* Switches full context to program space PSPACE.  Switches to the
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   first thread found bound to PSPACE.  */
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extern void switch_to_program_space_and_thread (struct program_space *pspace);
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/* Create a new address space object, and add it to the list.  */
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extern struct address_space *new_address_space (void);
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/* Maybe create a new address space object, and add it to the list, or
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   return a pointer to an existing address space, in case inferiors
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   share an address space.  */
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extern struct address_space *maybe_new_address_space (void);
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/* Returns the integer address space id of ASPACE.  */
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extern int address_space_num (struct address_space *aspace);
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/* Update all program spaces matching to address spaces.  The user may
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   have created several program spaces, and loaded executables into
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   them before connecting to the target interface that will create the
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   inferiors.  All that happens before GDB has a chance to know if the
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   inferiors will share an address space or not.  Call this after
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   having connected to the target interface and having fetched the
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   target description, to fixup the program/address spaces
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   mappings.  */
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extern void update_address_spaces (void);
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/* Prune away automatically added program spaces that aren't required
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   anymore.  */
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extern void prune_program_spaces (void);
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/* Keep a registry of per-pspace data-pointers required by other GDB
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   modules.  */
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extern const struct program_space_data *register_program_space_data (void);
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extern const struct program_space_data *register_program_space_data_with_cleanup
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  (void (*cleanup) (struct program_space *, void *));
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extern void clear_program_space_data (struct program_space *pspace);
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extern void set_program_space_data (struct program_space *pspace,
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                              const struct program_space_data *data, void *value);
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extern void *program_space_data (struct program_space *pspace,
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                           const struct program_space_data *data);
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#endif

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