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b9580b812c
Except for the two m32r modules, this checkin is for overlay support. * blockframe.c: blockvector_for_pc_sect(), block_for_pc_sect(), find_pc_sect_function(), find_pc_sect_partial_function(): new functions for debugging overlays; pc without section is ambiguous. * breakpoint.[ch]: add section pointer to breakpoint struct; add section argument to check_duplicates(); check section as well as pc in [breakpoint_here_p(), breakpoint_inserted_here_p(), breakpoint_thread_match(), bpstat_stop_status()]; add section argument to describe_other_breakpoints(); use INIT_SAL() macro to zero-out new sal structures; make resolve_sal_pc() fix up the sal's section as well as its pc; match on section + pc in clear_command() and delete_breakpoint(); account for overlay sections in insert_breakpoints(), remove_breakpoint() and breakpoint_re_set_one(); all this to support overlays where a PC is not unique. * exec.c: change xfer_memory() to handle overlay sections. * findvar.c: change read_var_value() to handle overlay sections. * frame.h: declaration for block_for_pc_sect() [blockframe.c]. * infcmd.c: jump_command() warns against jumping into an overlay that's not in memory. Also use INIT_SAL() to initialize sals. * infrun.c: wait_for_inferior() sets a flag to invalidate cached overlay state information; Also use INIT_SAL() to init sals. * m32r-rom.c: modify load routines to use LMA instead of VMA. * m32r-stub.c: mask exit value down to 8 bits; screen out any memory read/writes in the range 600000 to a00000, and ff680000 to ff800000 (hangs because nothing is mapped there); fix strcpy(). * maint.c: maintenance command "translate-address" supports overlays. * minsyms.c: lookup_minimal_symbol_by_pc_sect() supports overlays. * objfiles.[ch]: add ovly_mapped field to the obj_section struct; this constitutes gdb's internal overlay mapping table. Add macro ALL_OBJSECTIONS() to loop thru the obj_structs and look at overlays. Add function find_pc_sect_section(). * printcmd.c: modify print_address_symbolic() with overlay smarts; modify address_info() with overlay smarts; add function sym_info() to support the INFO SYMBOL command (translate address to symbol(s)); modify disassemble_command() to work on unmapped overlays. * source.c: use INIT_SAL() to initialize sals. * symfile.[ch]: change generic_load() to use section's LMA address instead of VMA address, for overlay sections. Add numerous functions for finding a PC's section / overlay, translating between VMA and LMA address ranges, determining if an overlay section is mapped, etc. Add several user commands for overlay debugging. Add support for a "generic" form of automatically reading overlay mapping info from the inferior (based on the default (simple) overlay manager which Cygnus provides as an example). * symtab.[ch]: add functions find_pc_sect_symtab(), find_pc_sect_psymtab(), find_pc_sect_psymbol(), find_pc_sect_line() for lookup; modify lookup_symbol and decode_line_1() to use them; modify find_function_start_sal() to account for overlay sections; add macro INIT_SAL() for initializing struct symtab_and_line. * target.c: fix a comment in the declaration of target_ops.
519 lines
20 KiB
C
519 lines
20 KiB
C
/* Definitions for symbol file management in GDB.
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Copyright (C) 1992, 1993, 1994, 1995 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 2 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, write to the Free Software
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Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
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#if !defined (OBJFILES_H)
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#define OBJFILES_H
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/* This structure maintains information on a per-objfile basis about the
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"entry point" of the objfile, and the scope within which the entry point
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exists. It is possible that gdb will see more than one objfile that is
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executable, each with its own entry point.
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For example, for dynamically linked executables in SVR4, the dynamic linker
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code is contained within the shared C library, which is actually executable
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and is run by the kernel first when an exec is done of a user executable
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that is dynamically linked. The dynamic linker within the shared C library
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then maps in the various program segments in the user executable and jumps
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to the user executable's recorded entry point, as if the call had been made
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directly by the kernel.
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The traditional gdb method of using this info is to use the recorded entry
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point to set the variables entry_file_lowpc and entry_file_highpc from
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the debugging information, where these values are the starting address
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(inclusive) and ending address (exclusive) of the instruction space in the
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executable which correspond to the "startup file", I.E. crt0.o in most
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cases. This file is assumed to be a startup file and frames with pc's
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inside it are treated as nonexistent. Setting these variables is necessary
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so that backtraces do not fly off the bottom of the stack.
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Gdb also supports an alternate method to avoid running off the bottom
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of the stack.
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There are two frames that are "special", the frame for the function
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containing the process entry point, since it has no predecessor frame,
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and the frame for the function containing the user code entry point
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(the main() function), since all the predecessor frames are for the
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process startup code. Since we have no guarantee that the linked
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in startup modules have any debugging information that gdb can use,
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we need to avoid following frame pointers back into frames that might
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have been built in the startup code, as we might get hopelessly
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confused. However, we almost always have debugging information
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available for main().
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These variables are used to save the range of PC values which are valid
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within the main() function and within the function containing the process
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entry point. If we always consider the frame for main() as the outermost
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frame when debugging user code, and the frame for the process entry
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point function as the outermost frame when debugging startup code, then
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all we have to do is have FRAME_CHAIN_VALID return false whenever a
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frame's current PC is within the range specified by these variables.
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In essence, we set "ceilings" in the frame chain beyond which we will
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not proceed when following the frame chain back up the stack.
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A nice side effect is that we can still debug startup code without
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running off the end of the frame chain, assuming that we have usable
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debugging information in the startup modules, and if we choose to not
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use the block at main, or can't find it for some reason, everything
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still works as before. And if we have no startup code debugging
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information but we do have usable information for main(), backtraces
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from user code don't go wandering off into the startup code.
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To use this method, define your FRAME_CHAIN_VALID macro like:
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#define FRAME_CHAIN_VALID(chain, thisframe) \
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(chain != 0 \
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&& !(inside_main_func ((thisframe)->pc)) \
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&& !(inside_entry_func ((thisframe)->pc)))
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and add initializations of the four scope controlling variables inside
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the object file / debugging information processing modules. */
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struct entry_info
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{
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/* The value we should use for this objects entry point.
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The illegal/unknown value needs to be something other than 0, ~0
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for instance, which is much less likely than 0. */
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CORE_ADDR entry_point;
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#define INVALID_ENTRY_POINT (~0) /* ~0 will not be in any file, we hope. */
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/* Start (inclusive) and end (exclusive) of function containing the
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entry point. */
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CORE_ADDR entry_func_lowpc;
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CORE_ADDR entry_func_highpc;
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/* Start (inclusive) and end (exclusive) of object file containing the
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entry point. */
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CORE_ADDR entry_file_lowpc;
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CORE_ADDR entry_file_highpc;
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/* Start (inclusive) and end (exclusive) of the user code main() function. */
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CORE_ADDR main_func_lowpc;
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CORE_ADDR main_func_highpc;
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/* Use these values when any of the above ranges is invalid. */
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/* We use these values because it guarantees that there is no number that is
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both >= LOWPC && < HIGHPC. It is also highly unlikely that 3 is a valid
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module or function start address (as opposed to 0). */
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#define INVALID_ENTRY_LOWPC (3)
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#define INVALID_ENTRY_HIGHPC (1)
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};
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/* Sections in an objfile.
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It is strange that we have both this notion of "sections"
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and the one used by section_offsets. Section as used
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here, (currently at least) means a BFD section, and the sections
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are set up from the BFD sections in allocate_objfile.
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The sections in section_offsets have their meaning determined by
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the symbol format, and they are set up by the sym_offsets function
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for that symbol file format.
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I'm not sure this could or should be changed, however. */
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struct obj_section {
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CORE_ADDR addr; /* lowest address in section */
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CORE_ADDR endaddr; /* 1+highest address in section */
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/* This field is being used for nefarious purposes by syms_from_objfile.
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It is said to be redundant with section_offsets; it's not really being
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used that way, however, it's some sort of hack I don't understand
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and am not going to try to eliminate (yet, anyway). FIXME.
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It was documented as "offset between (end)addr and actual memory
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addresses", but that's not true; addr & endaddr are actual memory
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addresses. */
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CORE_ADDR offset;
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sec_ptr the_bfd_section; /* BFD section pointer */
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/* Objfile this section is part of. */
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struct objfile *objfile;
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/* True if this "overlay section" is mapped into an "overlay region". */
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int ovly_mapped;
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};
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/* The "objstats" structure provides a place for gdb to record some
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interesting information about its internal state at runtime, on a
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per objfile basis, such as information about the number of symbols
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read, size of string table (if any), etc. */
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#if MAINTENANCE_CMDS
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struct objstats {
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int n_minsyms; /* Number of minimal symbols read */
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int n_psyms; /* Number of partial symbols read */
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int n_syms; /* Number of full symbols read */
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int n_stabs; /* Number of ".stabs" read (if applicable) */
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int n_types; /* Number of types */
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int sz_strtab; /* Size of stringtable, (if applicable) */
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};
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#define OBJSTAT(objfile, expr) (objfile -> stats.expr)
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#define OBJSTATS struct objstats stats
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extern void print_objfile_statistics PARAMS ((void));
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extern void print_symbol_bcache_statistics PARAMS ((void));
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#else
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#define OBJSTAT(objfile, expr) /* Nothing */
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#define OBJSTATS /* Nothing */
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#endif /* MAINTENANCE_CMDS */
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/* Master structure for keeping track of each file from which
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gdb reads symbols. There are several ways these get allocated: 1.
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The main symbol file, symfile_objfile, set by the symbol-file command,
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2. Additional symbol files added by the add-symbol-file command,
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3. Shared library objfiles, added by ADD_SOLIB, 4. symbol files
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for modules that were loaded when GDB attached to a remote system
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(see remote-vx.c). */
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struct objfile
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{
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/* All struct objfile's are chained together by their next pointers.
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The global variable "object_files" points to the first link in this
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chain.
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FIXME: There is a problem here if the objfile is reusable, and if
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multiple users are to be supported. The problem is that the objfile
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list is linked through a member of the objfile struct itself, which
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is only valid for one gdb process. The list implementation needs to
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be changed to something like:
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struct list {struct list *next; struct objfile *objfile};
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where the list structure is completely maintained separately within
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each gdb process. */
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struct objfile *next;
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/* The object file's name. Malloc'd; free it if you free this struct. */
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char *name;
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/* Some flag bits for this objfile. */
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unsigned short flags;
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/* Each objfile points to a linked list of symtabs derived from this file,
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one symtab structure for each compilation unit (source file). Each link
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in the symtab list contains a backpointer to this objfile. */
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struct symtab *symtabs;
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/* Each objfile points to a linked list of partial symtabs derived from
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this file, one partial symtab structure for each compilation unit
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(source file). */
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struct partial_symtab *psymtabs;
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/* List of freed partial symtabs, available for re-use */
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struct partial_symtab *free_psymtabs;
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/* The object file's BFD. Can be null if the objfile contains only
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minimal symbols, e.g. the run time common symbols for SunOS4. */
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bfd *obfd;
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/* The modification timestamp of the object file, as of the last time
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we read its symbols. */
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long mtime;
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/* Obstacks to hold objects that should be freed when we load a new symbol
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table from this object file. */
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struct obstack psymbol_obstack; /* Partial symbols */
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struct obstack symbol_obstack; /* Full symbols */
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struct obstack type_obstack; /* Types */
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/* A byte cache where we can stash arbitrary "chunks" of bytes that
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will not change. */
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struct bcache psymbol_cache; /* Byte cache for partial syms */
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/* Vectors of all partial symbols read in from file. The actual data
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is stored in the psymbol_obstack. */
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struct psymbol_allocation_list global_psymbols;
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struct psymbol_allocation_list static_psymbols;
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/* Each file contains a pointer to an array of minimal symbols for all
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global symbols that are defined within the file. The array is terminated
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by a "null symbol", one that has a NULL pointer for the name and a zero
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value for the address. This makes it easy to walk through the array
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when passed a pointer to somewhere in the middle of it. There is also
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a count of the number of symbols, which does not include the terminating
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null symbol. The array itself, as well as all the data that it points
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to, should be allocated on the symbol_obstack for this file. */
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struct minimal_symbol *msymbols;
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int minimal_symbol_count;
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/* For object file formats which don't specify fundamental types, gdb
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can create such types. For now, it maintains a vector of pointers
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to these internally created fundamental types on a per objfile basis,
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however it really should ultimately keep them on a per-compilation-unit
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basis, to account for linkage-units that consist of a number of
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compilation units that may have different fundamental types, such as
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linking C modules with ADA modules, or linking C modules that are
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compiled with 32-bit ints with C modules that are compiled with 64-bit
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ints (not inherently evil with a smarter linker). */
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struct type **fundamental_types;
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/* The mmalloc() malloc-descriptor for this objfile if we are using
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the memory mapped malloc() package to manage storage for this objfile's
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data. NULL if we are not. */
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PTR md;
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/* The file descriptor that was used to obtain the mmalloc descriptor
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for this objfile. If we call mmalloc_detach with the malloc descriptor
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we should then close this file descriptor. */
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int mmfd;
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/* Structure which keeps track of functions that manipulate objfile's
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of the same type as this objfile. I.E. the function to read partial
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symbols for example. Note that this structure is in statically
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allocated memory, and is shared by all objfiles that use the
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object module reader of this type. */
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struct sym_fns *sf;
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/* The per-objfile information about the entry point, the scope (file/func)
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containing the entry point, and the scope of the user's main() func. */
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struct entry_info ei;
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/* Information about stabs. Will be filled in with a dbx_symfile_info
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struct by those readers that need it. */
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struct dbx_symfile_info *sym_stab_info;
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/* Hook for information for use by the symbol reader (currently used
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for information shared by sym_init and sym_read). It is
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typically a pointer to malloc'd memory. The symbol reader's finish
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function is responsible for freeing the memory thusly allocated. */
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PTR sym_private;
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/* Hook for target-architecture-specific information. This must
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point to memory allocated on one of the obstacks in this objfile,
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so that it gets freed automatically when reading a new object
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file. */
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PTR obj_private;
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/* Set of relocation offsets to apply to each section.
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Currently on the psymbol_obstack (which makes no sense, but I'm
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not sure it's harming anything).
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These offsets indicate that all symbols (including partial and
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minimal symbols) which have been read have been relocated by this
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much. Symbols which are yet to be read need to be relocated by
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it. */
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struct section_offsets *section_offsets;
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int num_sections;
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/* set of section begin and end addresses used to map pc addresses
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into sections. Currently on the psymbol_obstack (which makes no
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sense, but I'm not sure it's harming anything). */
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struct obj_section
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*sections,
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*sections_end;
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/* two auxiliary fields, used to hold the fp of separate symbol files */
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FILE *auxf1, *auxf2;
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/* Place to stash various statistics about this objfile */
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OBJSTATS;
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};
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/* Defines for the objfile flag word. */
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/* Gdb can arrange to allocate storage for all objects related to a
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particular objfile in a designated section of its address space,
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managed at a low level by mmap() and using a special version of
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malloc that handles malloc/free/realloc on top of the mmap() interface.
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This allows the "internal gdb state" for a particular objfile to be
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dumped to a gdb state file and subsequently reloaded at a later time. */
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#define OBJF_MAPPED (1 << 0) /* Objfile data is mmap'd */
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/* When using mapped/remapped predigested gdb symbol information, we need
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a flag that indicates that we have previously done an initial symbol
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table read from this particular objfile. We can't just look for the
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absence of any of the three symbol tables (msymbols, psymtab, symtab)
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because if the file has no symbols for example, none of these will
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exist. */
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#define OBJF_SYMS (1 << 1) /* Have tried to read symbols */
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/* When an object file has its functions reordered (currently Irix-5.2
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shared libraries exhibit this behaviour), we will need an expensive
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algorithm to locate a partial symtab or symtab via an address.
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To avoid this penalty for normal object files, we use this flag,
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whose setting is determined upon symbol table read in. */
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#define OBJF_REORDERED (2 << 1) /* Functions are reordered */
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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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extern struct objfile *symfile_objfile;
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/* The object file that contains the runtime common minimal symbols
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for SunOS4. Note that this objfile has no associated BFD. */
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extern struct objfile *rt_common_objfile;
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/* When we need to allocate a new type, we need to know which type_obstack
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to allocate the type on, since there is one for each objfile. The places
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where types are allocated are deeply buried in function call hierarchies
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which know nothing about objfiles, so rather than trying to pass a
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particular objfile down to them, we just do an end run around them and
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set current_objfile to be whatever objfile we expect to be using at the
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time types are being allocated. For instance, when we start reading
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symbols for a particular objfile, we set current_objfile to point to that
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objfile, and when we are done, we set it back to NULL, to ensure that we
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never put a type someplace other than where we are expecting to put it.
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FIXME: Maybe we should review the entire type handling system and
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see if there is a better way to avoid this problem. */
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extern struct objfile *current_objfile;
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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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extern struct objfile *object_files;
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/* Declarations for functions defined in objfiles.c */
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extern struct objfile *
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allocate_objfile PARAMS ((bfd *, int));
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extern int
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build_objfile_section_table PARAMS ((struct objfile *));
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extern void objfile_to_front PARAMS ((struct objfile *));
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extern void
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unlink_objfile PARAMS ((struct objfile *));
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extern void
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free_objfile PARAMS ((struct objfile *));
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extern void
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free_all_objfiles PARAMS ((void));
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extern void
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objfile_relocate PARAMS ((struct objfile *, struct section_offsets *));
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extern int
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have_partial_symbols PARAMS ((void));
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extern int
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have_full_symbols PARAMS ((void));
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/* Functions for dealing with the minimal symbol table, really a misc
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address<->symbol mapping for things we don't have debug symbols for. */
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extern int
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have_minimal_symbols PARAMS ((void));
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extern struct obj_section *
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find_pc_section PARAMS((CORE_ADDR pc));
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extern struct obj_section *
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find_pc_sect_section PARAMS((CORE_ADDR pc, asection *section));
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extern int
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in_plt_section PARAMS ((CORE_ADDR, char *));
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/* Traverse all object files. ALL_OBJFILES_SAFE works even if you delete
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the objfile during the traversal. */
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#define ALL_OBJFILES(obj) \
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for ((obj) = object_files; (obj) != NULL; (obj) = (obj)->next)
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#define ALL_OBJFILES_SAFE(obj,nxt) \
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for ((obj) = object_files; \
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(obj) != NULL? ((nxt)=(obj)->next,1) :0; \
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(obj) = (nxt))
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/* Traverse all symtabs in one objfile. */
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#define ALL_OBJFILE_SYMTABS(objfile, s) \
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for ((s) = (objfile) -> symtabs; (s) != NULL; (s) = (s) -> next)
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/* Traverse all psymtabs in one objfile. */
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#define ALL_OBJFILE_PSYMTABS(objfile, p) \
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for ((p) = (objfile) -> psymtabs; (p) != NULL; (p) = (p) -> next)
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/* Traverse all minimal symbols in one objfile. */
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#define ALL_OBJFILE_MSYMBOLS(objfile, m) \
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for ((m) = (objfile) -> msymbols; SYMBOL_NAME(m) != NULL; (m)++)
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/* Traverse all symtabs in all objfiles. */
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#define ALL_SYMTABS(objfile, s) \
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ALL_OBJFILES (objfile) \
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ALL_OBJFILE_SYMTABS (objfile, s)
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/* Traverse all psymtabs in all objfiles. */
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#define ALL_PSYMTABS(objfile, p) \
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ALL_OBJFILES (objfile) \
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ALL_OBJFILE_PSYMTABS (objfile, p)
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/* Traverse all minimal symbols in all objfiles. */
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#define ALL_MSYMBOLS(objfile, m) \
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ALL_OBJFILES (objfile) \
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if ((objfile)->msymbols) \
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ALL_OBJFILE_MSYMBOLS (objfile, m)
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#define ALL_OBJFILE_OSECTIONS(objfile, osect) \
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for (osect = objfile->sections; osect < objfile->sections_end; osect++)
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#define ALL_OBJSECTIONS(objfile, osect) \
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ALL_OBJFILES (objfile) \
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ALL_OBJFILE_OSECTIONS (objfile, osect)
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#endif /* !defined (OBJFILES_H) */
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