binutils-gdb/gdb/solib-frv.c
Pedro Alves 492d29ea1c Split TRY_CATCH into TRY + CATCH
This patch splits the TRY_CATCH macro into three, so that we go from
this:

~~~
  volatile gdb_exception ex;

  TRY_CATCH (ex, RETURN_MASK_ERROR)
    {
    }
  if (ex.reason < 0)
    {
    }
~~~

to this:

~~~
  TRY
    {
    }
  CATCH (ex, RETURN_MASK_ERROR)
    {
    }
  END_CATCH
~~~

Thus, we'll be getting rid of the local volatile exception object, and
declaring the caught exception in the catch block.

This allows reimplementing TRY/CATCH in terms of C++ exceptions when
building in C++ mode, while still allowing to build GDB in C mode
(using setjmp/longjmp), as a transition step.

TBC, after this patch, is it _not_ valid to have code between the TRY
and the CATCH blocks, like:

  TRY
    {
    }

  // some code here.

  CATCH (ex, RETURN_MASK_ERROR)
    {
    }
  END_CATCH

Just like it isn't valid to do that with C++'s native try/catch.

By switching to creating the exception object inside the CATCH block
scope, we can get rid of all the explicitly allocated volatile
exception objects all over the tree, and map the CATCH block more
directly to C++'s catch blocks.

The majority of the TRY_CATCH -> TRY+CATCH+END_CATCH conversion was
done with a script, rerun from scratch at every rebase, no manual
editing involved.  After the mechanical conversion, a few places
needed manual intervention, to fix preexisting cases where we were
using the exception object outside of the TRY_CATCH block, and cases
where we were using "else" after a 'if (ex.reason) < 0)' [a CATCH
after this patch].  The result was folded into this patch so that GDB
still builds at each incremental step.

END_CATCH is necessary for two reasons:

First, because we name the exception object in the CATCH block, which
requires creating a scope, which in turn must be closed somewhere.
Declaring the exception variable in the initializer field of a for
block, like:

  #define CATCH(EXCEPTION, mask) \
    for (struct gdb_exception EXCEPTION; \
         exceptions_state_mc_catch (&EXCEPTION, MASK); \
	 EXCEPTION = exception_none)

would avoid needing END_CATCH, but alas, in C mode, we build with C90,
which doesn't allow mixed declarations and code.

Second, because when TRY/CATCH are wired to real C++ try/catch, as
long as we need to handle cleanup chains, even if there's no CATCH
block that wants to catch the exception, we need for stop at every
frame in the unwind chain and run cleanups, then rethrow.  That will
be done in END_CATCH.

After we require C++, we'll still need TRY/CATCH/END_CATCH until
cleanups are completely phased out -- TRY/CATCH in C++ mode will
save/restore the current cleanup chain, like in C mode, and END_CATCH
catches otherwise uncaugh exceptions, runs cleanups and rethrows, so
that C++ cleanups and exceptions can coexist.

IMO, this still makes the TRY/CATCH code look a bit more like a
newcomer would expect, so IMO worth it even if we weren't considering
C++.

gdb/ChangeLog.
2015-03-07  Pedro Alves  <palves@redhat.com>

	* common/common-exceptions.c (struct catcher) <exception>: No
	longer a pointer to volatile exception.  Now an exception value.
	<mask>: Delete field.
	(exceptions_state_mc_init): Remove all parameters.  Adjust.
	(exceptions_state_mc): No longer pop the catcher here.
	(exceptions_state_mc_catch): New function.
	(throw_exception): Adjust.
	* common/common-exceptions.h (exceptions_state_mc_init): Remove
	all parameters.
	(exceptions_state_mc_catch): Declare.
	(TRY_CATCH): Rename to ...
	(TRY): ... this.  Remove EXCEPTION and MASK parameters.
	(CATCH, END_CATCH): New.
	All callers adjusted.

gdb/gdbserver/ChangeLog:
2015-03-07  Pedro Alves  <palves@redhat.com>

	Adjust all callers of TRY_CATCH to use TRY/CATCH/END_CATCH
	instead.
2015-03-07 15:14:14 +00:00

1197 lines
36 KiB
C

/* Handle FR-V (FDPIC) shared libraries for GDB, the GNU Debugger.
Copyright (C) 2004-2015 Free Software Foundation, Inc.
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 3 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, see <http://www.gnu.org/licenses/>. */
#include "defs.h"
#include "inferior.h"
#include "gdbcore.h"
#include "solib.h"
#include "solist.h"
#include "frv-tdep.h"
#include "objfiles.h"
#include "symtab.h"
#include "language.h"
#include "command.h"
#include "gdbcmd.h"
#include "elf/frv.h"
#include "gdb_bfd.h"
/* Flag which indicates whether internal debug messages should be printed. */
static unsigned int solib_frv_debug;
/* FR-V pointers are four bytes wide. */
enum { FRV_PTR_SIZE = 4 };
/* Representation of loadmap and related structs for the FR-V FDPIC ABI. */
/* External versions; the size and alignment of the fields should be
the same as those on the target. When loaded, the placement of
the bits in each field will be the same as on the target. */
typedef gdb_byte ext_Elf32_Half[2];
typedef gdb_byte ext_Elf32_Addr[4];
typedef gdb_byte ext_Elf32_Word[4];
struct ext_elf32_fdpic_loadseg
{
/* Core address to which the segment is mapped. */
ext_Elf32_Addr addr;
/* VMA recorded in the program header. */
ext_Elf32_Addr p_vaddr;
/* Size of this segment in memory. */
ext_Elf32_Word p_memsz;
};
struct ext_elf32_fdpic_loadmap {
/* Protocol version number, must be zero. */
ext_Elf32_Half version;
/* Number of segments in this map. */
ext_Elf32_Half nsegs;
/* The actual memory map. */
struct ext_elf32_fdpic_loadseg segs[1 /* nsegs, actually */];
};
/* Internal versions; the types are GDB types and the data in each
of the fields is (or will be) decoded from the external struct
for ease of consumption. */
struct int_elf32_fdpic_loadseg
{
/* Core address to which the segment is mapped. */
CORE_ADDR addr;
/* VMA recorded in the program header. */
CORE_ADDR p_vaddr;
/* Size of this segment in memory. */
long p_memsz;
};
struct int_elf32_fdpic_loadmap {
/* Protocol version number, must be zero. */
int version;
/* Number of segments in this map. */
int nsegs;
/* The actual memory map. */
struct int_elf32_fdpic_loadseg segs[1 /* nsegs, actually */];
};
/* Given address LDMADDR, fetch and decode the loadmap at that address.
Return NULL if there is a problem reading the target memory or if
there doesn't appear to be a loadmap at the given address. The
allocated space (representing the loadmap) returned by this
function may be freed via a single call to xfree(). */
static struct int_elf32_fdpic_loadmap *
fetch_loadmap (CORE_ADDR ldmaddr)
{
enum bfd_endian byte_order = gdbarch_byte_order (target_gdbarch ());
struct ext_elf32_fdpic_loadmap ext_ldmbuf_partial;
struct ext_elf32_fdpic_loadmap *ext_ldmbuf;
struct int_elf32_fdpic_loadmap *int_ldmbuf;
int ext_ldmbuf_size, int_ldmbuf_size;
int version, seg, nsegs;
/* Fetch initial portion of the loadmap. */
if (target_read_memory (ldmaddr, (gdb_byte *) &ext_ldmbuf_partial,
sizeof ext_ldmbuf_partial))
{
/* Problem reading the target's memory. */
return NULL;
}
/* Extract the version. */
version = extract_unsigned_integer (ext_ldmbuf_partial.version,
sizeof ext_ldmbuf_partial.version,
byte_order);
if (version != 0)
{
/* We only handle version 0. */
return NULL;
}
/* Extract the number of segments. */
nsegs = extract_unsigned_integer (ext_ldmbuf_partial.nsegs,
sizeof ext_ldmbuf_partial.nsegs,
byte_order);
if (nsegs <= 0)
return NULL;
/* Allocate space for the complete (external) loadmap. */
ext_ldmbuf_size = sizeof (struct ext_elf32_fdpic_loadmap)
+ (nsegs - 1) * sizeof (struct ext_elf32_fdpic_loadseg);
ext_ldmbuf = xmalloc (ext_ldmbuf_size);
/* Copy over the portion of the loadmap that's already been read. */
memcpy (ext_ldmbuf, &ext_ldmbuf_partial, sizeof ext_ldmbuf_partial);
/* Read the rest of the loadmap from the target. */
if (target_read_memory (ldmaddr + sizeof ext_ldmbuf_partial,
(gdb_byte *) ext_ldmbuf + sizeof ext_ldmbuf_partial,
ext_ldmbuf_size - sizeof ext_ldmbuf_partial))
{
/* Couldn't read rest of the loadmap. */
xfree (ext_ldmbuf);
return NULL;
}
/* Allocate space into which to put information extract from the
external loadsegs. I.e, allocate the internal loadsegs. */
int_ldmbuf_size = sizeof (struct int_elf32_fdpic_loadmap)
+ (nsegs - 1) * sizeof (struct int_elf32_fdpic_loadseg);
int_ldmbuf = xmalloc (int_ldmbuf_size);
/* Place extracted information in internal structs. */
int_ldmbuf->version = version;
int_ldmbuf->nsegs = nsegs;
for (seg = 0; seg < nsegs; seg++)
{
int_ldmbuf->segs[seg].addr
= extract_unsigned_integer (ext_ldmbuf->segs[seg].addr,
sizeof (ext_ldmbuf->segs[seg].addr),
byte_order);
int_ldmbuf->segs[seg].p_vaddr
= extract_unsigned_integer (ext_ldmbuf->segs[seg].p_vaddr,
sizeof (ext_ldmbuf->segs[seg].p_vaddr),
byte_order);
int_ldmbuf->segs[seg].p_memsz
= extract_unsigned_integer (ext_ldmbuf->segs[seg].p_memsz,
sizeof (ext_ldmbuf->segs[seg].p_memsz),
byte_order);
}
xfree (ext_ldmbuf);
return int_ldmbuf;
}
/* External link_map and elf32_fdpic_loadaddr struct definitions. */
typedef gdb_byte ext_ptr[4];
struct ext_elf32_fdpic_loadaddr
{
ext_ptr map; /* struct elf32_fdpic_loadmap *map; */
ext_ptr got_value; /* void *got_value; */
};
struct ext_link_map
{
struct ext_elf32_fdpic_loadaddr l_addr;
/* Absolute file name object was found in. */
ext_ptr l_name; /* char *l_name; */
/* Dynamic section of the shared object. */
ext_ptr l_ld; /* ElfW(Dyn) *l_ld; */
/* Chain of loaded objects. */
ext_ptr l_next, l_prev; /* struct link_map *l_next, *l_prev; */
};
/* Link map info to include in an allocated so_list entry. */
struct lm_info
{
/* The loadmap, digested into an easier to use form. */
struct int_elf32_fdpic_loadmap *map;
/* The GOT address for this link map entry. */
CORE_ADDR got_value;
/* The link map address, needed for frv_fetch_objfile_link_map(). */
CORE_ADDR lm_addr;
/* Cached dynamic symbol table and dynamic relocs initialized and
used only by find_canonical_descriptor_in_load_object().
Note: kevinb/2004-02-26: It appears that calls to
bfd_canonicalize_dynamic_reloc() will use the same symbols as
those supplied to the first call to this function. Therefore,
it's important to NOT free the asymbol ** data structure
supplied to the first call. Thus the caching of the dynamic
symbols (dyn_syms) is critical for correct operation. The
caching of the dynamic relocations could be dispensed with. */
asymbol **dyn_syms;
arelent **dyn_relocs;
int dyn_reloc_count; /* Number of dynamic relocs. */
};
/* The load map, got value, etc. are not available from the chain
of loaded shared objects. ``main_executable_lm_info'' provides
a way to get at this information so that it doesn't need to be
frequently recomputed. Initialized by frv_relocate_main_executable(). */
static struct lm_info *main_executable_lm_info;
static void frv_relocate_main_executable (void);
static CORE_ADDR main_got (void);
static int enable_break2 (void);
/* Implement the "open_symbol_file_object" target_so_ops method. */
static int
open_symbol_file_object (void *from_ttyp)
{
/* Unimplemented. */
return 0;
}
/* Cached value for lm_base(), below. */
static CORE_ADDR lm_base_cache = 0;
/* Link map address for main module. */
static CORE_ADDR main_lm_addr = 0;
/* Return the address from which the link map chain may be found. On
the FR-V, this may be found in a number of ways. Assuming that the
main executable has already been relocated, the easiest way to find
this value is to look up the address of _GLOBAL_OFFSET_TABLE_. A
pointer to the start of the link map will be located at the word found
at _GLOBAL_OFFSET_TABLE_ + 8. (This is part of the dynamic linker
reserve area mandated by the ABI.) */
static CORE_ADDR
lm_base (void)
{
enum bfd_endian byte_order = gdbarch_byte_order (target_gdbarch ());
struct bound_minimal_symbol got_sym;
CORE_ADDR addr;
gdb_byte buf[FRV_PTR_SIZE];
/* One of our assumptions is that the main executable has been relocated.
Bail out if this has not happened. (Note that post_create_inferior()
in infcmd.c will call solib_add prior to solib_create_inferior_hook().
If we allow this to happen, lm_base_cache will be initialized with
a bogus value. */
if (main_executable_lm_info == 0)
return 0;
/* If we already have a cached value, return it. */
if (lm_base_cache)
return lm_base_cache;
got_sym = lookup_minimal_symbol ("_GLOBAL_OFFSET_TABLE_", NULL,
symfile_objfile);
if (got_sym.minsym == 0)
{
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"lm_base: _GLOBAL_OFFSET_TABLE_ not found.\n");
return 0;
}
addr = BMSYMBOL_VALUE_ADDRESS (got_sym) + 8;
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"lm_base: _GLOBAL_OFFSET_TABLE_ + 8 = %s\n",
hex_string_custom (addr, 8));
if (target_read_memory (addr, buf, sizeof buf) != 0)
return 0;
lm_base_cache = extract_unsigned_integer (buf, sizeof buf, byte_order);
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"lm_base: lm_base_cache = %s\n",
hex_string_custom (lm_base_cache, 8));
return lm_base_cache;
}
/* Implement the "current_sos" target_so_ops method. */
static struct so_list *
frv_current_sos (void)
{
enum bfd_endian byte_order = gdbarch_byte_order (target_gdbarch ());
CORE_ADDR lm_addr, mgot;
struct so_list *sos_head = NULL;
struct so_list **sos_next_ptr = &sos_head;
/* Make sure that the main executable has been relocated. This is
required in order to find the address of the global offset table,
which in turn is used to find the link map info. (See lm_base()
for details.)
Note that the relocation of the main executable is also performed
by solib_create_inferior_hook(), however, in the case of core
files, this hook is called too late in order to be of benefit to
solib_add. solib_add eventually calls this this function,
frv_current_sos, and also precedes the call to
solib_create_inferior_hook(). (See post_create_inferior() in
infcmd.c.) */
if (main_executable_lm_info == 0 && core_bfd != NULL)
frv_relocate_main_executable ();
/* Fetch the GOT corresponding to the main executable. */
mgot = main_got ();
/* Locate the address of the first link map struct. */
lm_addr = lm_base ();
/* We have at least one link map entry. Fetch the lot of them,
building the solist chain. */
while (lm_addr)
{
struct ext_link_map lm_buf;
CORE_ADDR got_addr;
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"current_sos: reading link_map entry at %s\n",
hex_string_custom (lm_addr, 8));
if (target_read_memory (lm_addr, (gdb_byte *) &lm_buf,
sizeof (lm_buf)) != 0)
{
warning (_("frv_current_sos: Unable to read link map entry. "
"Shared object chain may be incomplete."));
break;
}
got_addr
= extract_unsigned_integer (lm_buf.l_addr.got_value,
sizeof (lm_buf.l_addr.got_value),
byte_order);
/* If the got_addr is the same as mgotr, then we're looking at the
entry for the main executable. By convention, we don't include
this in the list of shared objects. */
if (got_addr != mgot)
{
int errcode;
char *name_buf;
struct int_elf32_fdpic_loadmap *loadmap;
struct so_list *sop;
CORE_ADDR addr;
/* Fetch the load map address. */
addr = extract_unsigned_integer (lm_buf.l_addr.map,
sizeof lm_buf.l_addr.map,
byte_order);
loadmap = fetch_loadmap (addr);
if (loadmap == NULL)
{
warning (_("frv_current_sos: Unable to fetch load map. "
"Shared object chain may be incomplete."));
break;
}
sop = xcalloc (1, sizeof (struct so_list));
sop->lm_info = xcalloc (1, sizeof (struct lm_info));
sop->lm_info->map = loadmap;
sop->lm_info->got_value = got_addr;
sop->lm_info->lm_addr = lm_addr;
/* Fetch the name. */
addr = extract_unsigned_integer (lm_buf.l_name,
sizeof (lm_buf.l_name),
byte_order);
target_read_string (addr, &name_buf, SO_NAME_MAX_PATH_SIZE - 1,
&errcode);
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog, "current_sos: name = %s\n",
name_buf);
if (errcode != 0)
warning (_("Can't read pathname for link map entry: %s."),
safe_strerror (errcode));
else
{
strncpy (sop->so_name, name_buf, SO_NAME_MAX_PATH_SIZE - 1);
sop->so_name[SO_NAME_MAX_PATH_SIZE - 1] = '\0';
xfree (name_buf);
strcpy (sop->so_original_name, sop->so_name);
}
*sos_next_ptr = sop;
sos_next_ptr = &sop->next;
}
else
{
main_lm_addr = lm_addr;
}
lm_addr = extract_unsigned_integer (lm_buf.l_next,
sizeof (lm_buf.l_next), byte_order);
}
enable_break2 ();
return sos_head;
}
/* Return 1 if PC lies in the dynamic symbol resolution code of the
run time loader. */
static CORE_ADDR interp_text_sect_low;
static CORE_ADDR interp_text_sect_high;
static CORE_ADDR interp_plt_sect_low;
static CORE_ADDR interp_plt_sect_high;
static int
frv_in_dynsym_resolve_code (CORE_ADDR pc)
{
return ((pc >= interp_text_sect_low && pc < interp_text_sect_high)
|| (pc >= interp_plt_sect_low && pc < interp_plt_sect_high)
|| in_plt_section (pc));
}
/* Given a loadmap and an address, return the displacement needed
to relocate the address. */
static CORE_ADDR
displacement_from_map (struct int_elf32_fdpic_loadmap *map,
CORE_ADDR addr)
{
int seg;
for (seg = 0; seg < map->nsegs; seg++)
{
if (map->segs[seg].p_vaddr <= addr
&& addr < map->segs[seg].p_vaddr + map->segs[seg].p_memsz)
{
return map->segs[seg].addr - map->segs[seg].p_vaddr;
}
}
return 0;
}
/* Print a warning about being unable to set the dynamic linker
breakpoint. */
static void
enable_break_failure_warning (void)
{
warning (_("Unable to find dynamic linker breakpoint function.\n"
"GDB will be unable to debug shared library initializers\n"
"and track explicitly loaded dynamic code."));
}
/* Helper function for gdb_bfd_lookup_symbol. */
static int
cmp_name (asymbol *sym, void *data)
{
return (strcmp (sym->name, (const char *) data) == 0);
}
/* Arrange for dynamic linker to hit breakpoint.
The dynamic linkers has, as part of its debugger interface, support
for arranging for the inferior to hit a breakpoint after mapping in
the shared libraries. This function enables that breakpoint.
On the FR-V, using the shared library (FDPIC) ABI, the symbol
_dl_debug_addr points to the r_debug struct which contains
a field called r_brk. r_brk is the address of the function
descriptor upon which a breakpoint must be placed. Being a
function descriptor, we must extract the entry point in order
to set the breakpoint.
Our strategy will be to get the .interp section from the
executable. This section will provide us with the name of the
interpreter. We'll open the interpreter and then look up
the address of _dl_debug_addr. We then relocate this address
using the interpreter's loadmap. Once the relocated address
is known, we fetch the value (address) corresponding to r_brk
and then use that value to fetch the entry point of the function
we're interested in. */
static int enable_break2_done = 0;
static int
enable_break2 (void)
{
enum bfd_endian byte_order = gdbarch_byte_order (target_gdbarch ());
int success = 0;
char **bkpt_namep;
asection *interp_sect;
if (enable_break2_done)
return 1;
interp_text_sect_low = interp_text_sect_high = 0;
interp_plt_sect_low = interp_plt_sect_high = 0;
/* Find the .interp section; if not found, warn the user and drop
into the old breakpoint at symbol code. */
interp_sect = bfd_get_section_by_name (exec_bfd, ".interp");
if (interp_sect)
{
unsigned int interp_sect_size;
char *buf;
bfd *tmp_bfd = NULL;
int status;
CORE_ADDR addr, interp_loadmap_addr;
gdb_byte addr_buf[FRV_PTR_SIZE];
struct int_elf32_fdpic_loadmap *ldm;
/* Read the contents of the .interp section into a local buffer;
the contents specify the dynamic linker this program uses. */
interp_sect_size = bfd_section_size (exec_bfd, interp_sect);
buf = alloca (interp_sect_size);
bfd_get_section_contents (exec_bfd, interp_sect,
buf, 0, interp_sect_size);
/* Now we need to figure out where the dynamic linker was
loaded so that we can load its symbols and place a breakpoint
in the dynamic linker itself.
This address is stored on the stack. However, I've been unable
to find any magic formula to find it for Solaris (appears to
be trivial on GNU/Linux). Therefore, we have to try an alternate
mechanism to find the dynamic linker's base address. */
TRY
{
tmp_bfd = solib_bfd_open (buf);
}
CATCH (ex, RETURN_MASK_ALL)
{
}
END_CATCH
if (tmp_bfd == NULL)
{
enable_break_failure_warning ();
return 0;
}
status = frv_fdpic_loadmap_addresses (target_gdbarch (),
&interp_loadmap_addr, 0);
if (status < 0)
{
warning (_("Unable to determine dynamic linker loadmap address."));
enable_break_failure_warning ();
gdb_bfd_unref (tmp_bfd);
return 0;
}
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: interp_loadmap_addr = %s\n",
hex_string_custom (interp_loadmap_addr, 8));
ldm = fetch_loadmap (interp_loadmap_addr);
if (ldm == NULL)
{
warning (_("Unable to load dynamic linker loadmap at address %s."),
hex_string_custom (interp_loadmap_addr, 8));
enable_break_failure_warning ();
gdb_bfd_unref (tmp_bfd);
return 0;
}
/* Record the relocated start and end address of the dynamic linker
text and plt section for svr4_in_dynsym_resolve_code. */
interp_sect = bfd_get_section_by_name (tmp_bfd, ".text");
if (interp_sect)
{
interp_text_sect_low
= bfd_section_vma (tmp_bfd, interp_sect);
interp_text_sect_low
+= displacement_from_map (ldm, interp_text_sect_low);
interp_text_sect_high
= interp_text_sect_low + bfd_section_size (tmp_bfd, interp_sect);
}
interp_sect = bfd_get_section_by_name (tmp_bfd, ".plt");
if (interp_sect)
{
interp_plt_sect_low =
bfd_section_vma (tmp_bfd, interp_sect);
interp_plt_sect_low
+= displacement_from_map (ldm, interp_plt_sect_low);
interp_plt_sect_high =
interp_plt_sect_low + bfd_section_size (tmp_bfd, interp_sect);
}
addr = gdb_bfd_lookup_symbol (tmp_bfd, cmp_name, "_dl_debug_addr");
if (addr == 0)
{
warning (_("Could not find symbol _dl_debug_addr "
"in dynamic linker"));
enable_break_failure_warning ();
gdb_bfd_unref (tmp_bfd);
return 0;
}
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: _dl_debug_addr "
"(prior to relocation) = %s\n",
hex_string_custom (addr, 8));
addr += displacement_from_map (ldm, addr);
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: _dl_debug_addr "
"(after relocation) = %s\n",
hex_string_custom (addr, 8));
/* Fetch the address of the r_debug struct. */
if (target_read_memory (addr, addr_buf, sizeof addr_buf) != 0)
{
warning (_("Unable to fetch contents of _dl_debug_addr "
"(at address %s) from dynamic linker"),
hex_string_custom (addr, 8));
}
addr = extract_unsigned_integer (addr_buf, sizeof addr_buf, byte_order);
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: _dl_debug_addr[0..3] = %s\n",
hex_string_custom (addr, 8));
/* If it's zero, then the ldso hasn't initialized yet, and so
there are no shared libs yet loaded. */
if (addr == 0)
{
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: ldso not yet initialized\n");
/* Do not warn, but mark to run again. */
return 0;
}
/* Fetch the r_brk field. It's 8 bytes from the start of
_dl_debug_addr. */
if (target_read_memory (addr + 8, addr_buf, sizeof addr_buf) != 0)
{
warning (_("Unable to fetch _dl_debug_addr->r_brk "
"(at address %s) from dynamic linker"),
hex_string_custom (addr + 8, 8));
enable_break_failure_warning ();
gdb_bfd_unref (tmp_bfd);
return 0;
}
addr = extract_unsigned_integer (addr_buf, sizeof addr_buf, byte_order);
/* Now fetch the function entry point. */
if (target_read_memory (addr, addr_buf, sizeof addr_buf) != 0)
{
warning (_("Unable to fetch _dl_debug_addr->.r_brk entry point "
"(at address %s) from dynamic linker"),
hex_string_custom (addr, 8));
enable_break_failure_warning ();
gdb_bfd_unref (tmp_bfd);
return 0;
}
addr = extract_unsigned_integer (addr_buf, sizeof addr_buf, byte_order);
/* We're done with the temporary bfd. */
gdb_bfd_unref (tmp_bfd);
/* We're also done with the loadmap. */
xfree (ldm);
/* Remove all the solib event breakpoints. Their addresses
may have changed since the last time we ran the program. */
remove_solib_event_breakpoints ();
/* Now (finally!) create the solib breakpoint. */
create_solib_event_breakpoint (target_gdbarch (), addr);
enable_break2_done = 1;
return 1;
}
/* Tell the user we couldn't set a dynamic linker breakpoint. */
enable_break_failure_warning ();
/* Failure return. */
return 0;
}
static int
enable_break (void)
{
asection *interp_sect;
CORE_ADDR entry_point;
if (symfile_objfile == NULL)
{
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: No symbol file found.\n");
return 0;
}
if (!entry_point_address_query (&entry_point))
{
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: Symbol file has no entry point.\n");
return 0;
}
/* Check for the presence of a .interp section. If there is no
such section, the executable is statically linked. */
interp_sect = bfd_get_section_by_name (exec_bfd, ".interp");
if (interp_sect == NULL)
{
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: No .interp section found.\n");
return 0;
}
create_solib_event_breakpoint (target_gdbarch (), entry_point);
if (solib_frv_debug)
fprintf_unfiltered (gdb_stdlog,
"enable_break: solib event breakpoint "
"placed at entry point: %s\n",
hex_string_custom (entry_point, 8));
return 1;
}
/* Implement the "special_symbol_handling" target_so_ops method. */
static void
frv_special_symbol_handling (void)
{
/* Nothing needed for FRV. */
}
static void
frv_relocate_main_executable (void)
{
int status;
CORE_ADDR exec_addr, interp_addr;
struct int_elf32_fdpic_loadmap *ldm;
struct cleanup *old_chain;
struct section_offsets *new_offsets;
int changed;
struct obj_section *osect;
status = frv_fdpic_loadmap_addresses (target_gdbarch (),
&interp_addr, &exec_addr);
if (status < 0 || (exec_addr == 0 && interp_addr == 0))
{
/* Not using FDPIC ABI, so do nothing. */
return;
}
/* Fetch the loadmap located at ``exec_addr''. */
ldm = fetch_loadmap (exec_addr);
if (ldm == NULL)
error (_("Unable to load the executable's loadmap."));
if (main_executable_lm_info)
xfree (main_executable_lm_info);
main_executable_lm_info = xcalloc (1, sizeof (struct lm_info));
main_executable_lm_info->map = ldm;
new_offsets = xcalloc (symfile_objfile->num_sections,
sizeof (struct section_offsets));
old_chain = make_cleanup (xfree, new_offsets);
changed = 0;
ALL_OBJFILE_OSECTIONS (symfile_objfile, osect)
{
CORE_ADDR orig_addr, addr, offset;
int osect_idx;
int seg;
osect_idx = osect - symfile_objfile->sections;
/* Current address of section. */
addr = obj_section_addr (osect);
/* Offset from where this section started. */
offset = ANOFFSET (symfile_objfile->section_offsets, osect_idx);
/* Original address prior to any past relocations. */
orig_addr = addr - offset;
for (seg = 0; seg < ldm->nsegs; seg++)
{
if (ldm->segs[seg].p_vaddr <= orig_addr
&& orig_addr < ldm->segs[seg].p_vaddr + ldm->segs[seg].p_memsz)
{
new_offsets->offsets[osect_idx]
= ldm->segs[seg].addr - ldm->segs[seg].p_vaddr;
if (new_offsets->offsets[osect_idx] != offset)
changed = 1;
break;
}
}
}
if (changed)
objfile_relocate (symfile_objfile, new_offsets);
do_cleanups (old_chain);
/* Now that symfile_objfile has been relocated, we can compute the
GOT value and stash it away. */
main_executable_lm_info->got_value = main_got ();
}
/* Implement the "create_inferior_hook" target_solib_ops method.
For the FR-V shared library ABI (FDPIC), the main executable needs
to be relocated. The shared library breakpoints also need to be
enabled. */
static void
frv_solib_create_inferior_hook (int from_tty)
{
/* Relocate main executable. */
frv_relocate_main_executable ();
/* Enable shared library breakpoints. */
if (!enable_break ())
{
warning (_("shared library handler failed to enable breakpoint"));
return;
}
}
static void
frv_clear_solib (void)
{
lm_base_cache = 0;
enable_break2_done = 0;
main_lm_addr = 0;
if (main_executable_lm_info != 0)
{
xfree (main_executable_lm_info->map);
xfree (main_executable_lm_info->dyn_syms);
xfree (main_executable_lm_info->dyn_relocs);
xfree (main_executable_lm_info);
main_executable_lm_info = 0;
}
}
static void
frv_free_so (struct so_list *so)
{
xfree (so->lm_info->map);
xfree (so->lm_info->dyn_syms);
xfree (so->lm_info->dyn_relocs);
xfree (so->lm_info);
}
static void
frv_relocate_section_addresses (struct so_list *so,
struct target_section *sec)
{
int seg;
struct int_elf32_fdpic_loadmap *map;
map = so->lm_info->map;
for (seg = 0; seg < map->nsegs; seg++)
{
if (map->segs[seg].p_vaddr <= sec->addr
&& sec->addr < map->segs[seg].p_vaddr + map->segs[seg].p_memsz)
{
CORE_ADDR displ = map->segs[seg].addr - map->segs[seg].p_vaddr;
sec->addr += displ;
sec->endaddr += displ;
break;
}
}
}
/* Return the GOT address associated with the main executable. Return
0 if it can't be found. */
static CORE_ADDR
main_got (void)
{
struct bound_minimal_symbol got_sym;
got_sym = lookup_minimal_symbol ("_GLOBAL_OFFSET_TABLE_",
NULL, symfile_objfile);
if (got_sym.minsym == 0)
return 0;
return BMSYMBOL_VALUE_ADDRESS (got_sym);
}
/* Find the global pointer for the given function address ADDR. */
CORE_ADDR
frv_fdpic_find_global_pointer (CORE_ADDR addr)
{
struct so_list *so;
so = master_so_list ();
while (so)
{
int seg;
struct int_elf32_fdpic_loadmap *map;
map = so->lm_info->map;
for (seg = 0; seg < map->nsegs; seg++)
{
if (map->segs[seg].addr <= addr
&& addr < map->segs[seg].addr + map->segs[seg].p_memsz)
return so->lm_info->got_value;
}
so = so->next;
}
/* Didn't find it in any of the shared objects. So assume it's in the
main executable. */
return main_got ();
}
/* Forward declarations for frv_fdpic_find_canonical_descriptor(). */
static CORE_ADDR find_canonical_descriptor_in_load_object
(CORE_ADDR, CORE_ADDR, const char *, bfd *, struct lm_info *);
/* Given a function entry point, attempt to find the canonical descriptor
associated with that entry point. Return 0 if no canonical descriptor
could be found. */
CORE_ADDR
frv_fdpic_find_canonical_descriptor (CORE_ADDR entry_point)
{
const char *name;
CORE_ADDR addr;
CORE_ADDR got_value;
struct int_elf32_fdpic_loadmap *ldm = 0;
struct symbol *sym;
/* Fetch the corresponding global pointer for the entry point. */
got_value = frv_fdpic_find_global_pointer (entry_point);
/* Attempt to find the name of the function. If the name is available,
it'll be used as an aid in finding matching functions in the dynamic
symbol table. */
sym = find_pc_function (entry_point);
if (sym == 0)
name = 0;
else
name = SYMBOL_LINKAGE_NAME (sym);
/* Check the main executable. */
addr = find_canonical_descriptor_in_load_object
(entry_point, got_value, name, symfile_objfile->obfd,
main_executable_lm_info);
/* If descriptor not found via main executable, check each load object
in list of shared objects. */
if (addr == 0)
{
struct so_list *so;
so = master_so_list ();
while (so)
{
addr = find_canonical_descriptor_in_load_object
(entry_point, got_value, name, so->abfd, so->lm_info);
if (addr != 0)
break;
so = so->next;
}
}
return addr;
}
static CORE_ADDR
find_canonical_descriptor_in_load_object
(CORE_ADDR entry_point, CORE_ADDR got_value, const char *name, bfd *abfd,
struct lm_info *lm)
{
enum bfd_endian byte_order = gdbarch_byte_order (target_gdbarch ());
arelent *rel;
unsigned int i;
CORE_ADDR addr = 0;
/* Nothing to do if no bfd. */
if (abfd == 0)
return 0;
/* Nothing to do if no link map. */
if (lm == 0)
return 0;
/* We want to scan the dynamic relocs for R_FRV_FUNCDESC relocations.
(More about this later.) But in order to fetch the relocs, we
need to first fetch the dynamic symbols. These symbols need to
be cached due to the way that bfd_canonicalize_dynamic_reloc()
works. (See the comments in the declaration of struct lm_info
for more information.) */
if (lm->dyn_syms == NULL)
{
long storage_needed;
unsigned int number_of_symbols;
/* Determine amount of space needed to hold the dynamic symbol table. */
storage_needed = bfd_get_dynamic_symtab_upper_bound (abfd);
/* If there are no dynamic symbols, there's nothing to do. */
if (storage_needed <= 0)
return 0;
/* Allocate space for the dynamic symbol table. */
lm->dyn_syms = (asymbol **) xmalloc (storage_needed);
/* Fetch the dynamic symbol table. */
number_of_symbols = bfd_canonicalize_dynamic_symtab (abfd, lm->dyn_syms);
if (number_of_symbols == 0)
return 0;
}
/* Fetch the dynamic relocations if not already cached. */
if (lm->dyn_relocs == NULL)
{
long storage_needed;
/* Determine amount of space needed to hold the dynamic relocs. */
storage_needed = bfd_get_dynamic_reloc_upper_bound (abfd);
/* Bail out if there are no dynamic relocs. */
if (storage_needed <= 0)
return 0;
/* Allocate space for the relocs. */
lm->dyn_relocs = (arelent **) xmalloc (storage_needed);
/* Fetch the dynamic relocs. */
lm->dyn_reloc_count
= bfd_canonicalize_dynamic_reloc (abfd, lm->dyn_relocs, lm->dyn_syms);
}
/* Search the dynamic relocs. */
for (i = 0; i < lm->dyn_reloc_count; i++)
{
rel = lm->dyn_relocs[i];
/* Relocs of interest are those which meet the following
criteria:
- the names match (assuming the caller could provide
a name which matches ``entry_point'').
- the relocation type must be R_FRV_FUNCDESC. Relocs
of this type are used (by the dynamic linker) to
look up the address of a canonical descriptor (allocating
it if need be) and initializing the GOT entry referred
to by the offset to the address of the descriptor.
These relocs of interest may be used to obtain a
candidate descriptor by first adjusting the reloc's
address according to the link map and then dereferencing
this address (which is a GOT entry) to obtain a descriptor
address. */
if ((name == 0 || strcmp (name, (*rel->sym_ptr_ptr)->name) == 0)
&& rel->howto->type == R_FRV_FUNCDESC)
{
gdb_byte buf [FRV_PTR_SIZE];
/* Compute address of address of candidate descriptor. */
addr = rel->address + displacement_from_map (lm->map, rel->address);
/* Fetch address of candidate descriptor. */
if (target_read_memory (addr, buf, sizeof buf) != 0)
continue;
addr = extract_unsigned_integer (buf, sizeof buf, byte_order);
/* Check for matching entry point. */
if (target_read_memory (addr, buf, sizeof buf) != 0)
continue;
if (extract_unsigned_integer (buf, sizeof buf, byte_order)
!= entry_point)
continue;
/* Check for matching got value. */
if (target_read_memory (addr + 4, buf, sizeof buf) != 0)
continue;
if (extract_unsigned_integer (buf, sizeof buf, byte_order)
!= got_value)
continue;
/* Match was successful! Exit loop. */
break;
}
}
return addr;
}
/* Given an objfile, return the address of its link map. This value is
needed for TLS support. */
CORE_ADDR
frv_fetch_objfile_link_map (struct objfile *objfile)
{
struct so_list *so;
/* Cause frv_current_sos() to be run if it hasn't been already. */
if (main_lm_addr == 0)
solib_add (0, 0, 0, 1);
/* frv_current_sos() will set main_lm_addr for the main executable. */
if (objfile == symfile_objfile)
return main_lm_addr;
/* The other link map addresses may be found by examining the list
of shared libraries. */
for (so = master_so_list (); so; so = so->next)
{
if (so->objfile == objfile)
return so->lm_info->lm_addr;
}
/* Not found! */
return 0;
}
struct target_so_ops frv_so_ops;
/* Provide a prototype to silence -Wmissing-prototypes. */
extern initialize_file_ftype _initialize_frv_solib;
void
_initialize_frv_solib (void)
{
frv_so_ops.relocate_section_addresses = frv_relocate_section_addresses;
frv_so_ops.free_so = frv_free_so;
frv_so_ops.clear_solib = frv_clear_solib;
frv_so_ops.solib_create_inferior_hook = frv_solib_create_inferior_hook;
frv_so_ops.special_symbol_handling = frv_special_symbol_handling;
frv_so_ops.current_sos = frv_current_sos;
frv_so_ops.open_symbol_file_object = open_symbol_file_object;
frv_so_ops.in_dynsym_resolve_code = frv_in_dynsym_resolve_code;
frv_so_ops.bfd_open = solib_bfd_open;
/* Debug this file's internals. */
add_setshow_zuinteger_cmd ("solib-frv", class_maintenance,
&solib_frv_debug, _("\
Set internal debugging of shared library code for FR-V."), _("\
Show internal debugging of shared library code for FR-V."), _("\
When non-zero, FR-V solib specific internal debugging is enabled."),
NULL,
NULL, /* FIXME: i18n: */
&setdebuglist, &showdebuglist);
}