bfd/doc/syms.texi - binutils-gdb - Git at Google

 @section Symbols
 BFD tries to maintain as much symbol information as it can when
 it moves information from file to file. BFD passes information
 to applications though the @code{asymbol} structure. When the
 application requests the symbol table, BFD reads the table in
 the native form and translates parts of it into the internal
 format. To maintain more than the information passed to
 applications, some targets keep some information ``behind the
 scenes'' in a structure only the particular back end knows
 about. For example, the coff back end keeps the original
 symbol table structure as well as the canonical structure when
 a BFD is read in. On output, the coff back end can reconstruct
 the output symbol table so that no information is lost, even
 information unique to coff which BFD doesn't know or
 understand. If a coff symbol table were read, but were written
 through an a.out back end, all the coff specific information
 would be lost. The symbol table of a BFD
 is not necessarily read in until a canonicalize request is
 made. Then the BFD back end fills in a table provided by the
 application with pointers to the canonical information.  To
 output symbols, the application provides BFD with a table of
 pointers to pointers to @code{asymbol}s. This allows applications
 like the linker to output a symbol as it was read, since the ``behind
 the scenes'' information will be still available.
 @menu
 * Reading Symbols::
 * Writing Symbols::
 * Mini Symbols::
 * typedef asymbol::
 * symbol handling functions::
 @end menu

 @node Reading Symbols, Writing Symbols, Symbols, Symbols
 @subsection Reading symbols
 There are two stages to reading a symbol table from a BFD:
 allocating storage, and the actual reading process. This is an
 excerpt from an application which reads the symbol table:

 @example
          long storage_needed;
          asymbol **symbol_table;
          long number_of_symbols;
          long i;

          storage_needed = bfd_get_symtab_upper_bound (abfd);

          if (storage_needed < 0)
            FAIL

          if (storage_needed == 0) @{
             return ;
          @}
          symbol_table = (asymbol **) xmalloc (storage_needed);
            ...
          number_of_symbols =
             bfd_canonicalize_symtab (abfd, symbol_table);

          if (number_of_symbols < 0)
            FAIL

          for (i = 0; i < number_of_symbols; i++) @{
             process_symbol (symbol_table[i]);
          @}
 @end example

 All storage for the symbols themselves is in an objalloc
 connected to the BFD; it is freed when the BFD is closed.

 @node Writing Symbols, Mini Symbols, Reading Symbols, Symbols
 @subsection Writing symbols
 Writing of a symbol table is automatic when a BFD open for
 writing is closed. The application attaches a vector of
 pointers to pointers to symbols to the BFD being written, and
 fills in the symbol count. The close and cleanup code reads
 through the table provided and performs all the necessary
 operations. The BFD output code must always be provided with an
 ``owned'' symbol: one which has come from another BFD, or one
 which has been created using @code{bfd_make_empty_symbol}.  Here is an
 example showing the creation of a symbol table with only one element:

 @example
        #include "bfd.h"
        main()
        @{
          bfd *abfd;
          asymbol *ptrs[2];
          asymbol *new;

          abfd = bfd_openw("foo","a.out-sunos-big");
          bfd_set_format(abfd, bfd_object);
          new = bfd_make_empty_symbol(abfd);
          new->name = "dummy_symbol";
          new->section = bfd_make_section_old_way(abfd, ".text");
          new->flags = BSF_GLOBAL;
          new->value = 0x12345;

          ptrs[0] = new;
          ptrs[1] = (asymbol *)0;

          bfd_set_symtab(abfd, ptrs, 1);
          bfd_close(abfd);
        @}

        ./makesym
        nm foo
        00012345 A dummy_symbol
 @end example

 Many formats cannot represent arbitary symbol information; for
 instance, the @code{a.out} object format does not allow an
 arbitary number of sections. A symbol pointing to a section
 which is not one  of @code{.text}, @code{.data} or @code{.bss} cannot
 be described.

 @node Mini Symbols, typedef asymbol, Writing Symbols, Symbols
 @subsection Mini Symbols
 Mini symbols provide read-only access to the symbol table.
 They use less memory space, but require more time to access.
 They can be useful for tools like nm or objdump, which may
 have to handle symbol tables of extremely large executables.

 The @code{bfd_read_minisymbols} function will read the symbols
 into memory in an internal form.  It will return a @code{void *}
 pointer to a block of memory, a symbol count, and the size of
 each symbol.  The pointer is allocated using @code{malloc}, and
 should be freed by the caller when it is no longer needed.

 The function @code{bfd_minisymbol_to_symbol} will take a pointer
 to a minisymbol, and a pointer to a structure returned by
 @code{bfd_make_empty_symbol}, and return a @code{asymbol} structure.
 The return value may or may not be the same as the value from
 @code{bfd_make_empty_symbol} which was passed in.


 @node typedef asymbol, symbol handling functions, Mini Symbols, Symbols
 @subsection typedef asymbol
 An @code{asymbol} has the form:


 @example

 typedef struct symbol_cache_entry
 @{
        /* A pointer to the BFD which owns the symbol. This information
           is necessary so that a back end can work out what additional
           information (invisible to the application writer) is carried
           with the symbol.

           This field is *almost* redundant, since you can use section->owner
           instead, except that some symbols point to the global sections
           bfd_@{abs,com,und@}_section.  This could be fixed by making
           these globals be per-bfd (or per-target-flavor).  FIXME. */

   struct _bfd *the_bfd; /* Use bfd_asymbol_bfd(sym) to access this field. */

        /* The text of the symbol. The name is left alone, and not copied; the
           application may not alter it. */
   CONST char *name;

        /* The value of the symbol.  This really should be a union of a
           numeric value with a pointer, since some flags indicate that
           a pointer to another symbol is stored here.  */
   symvalue value;

        /* Attributes of a symbol: */

 #define BSF_NO_FLAGS    0x00

        /* The symbol has local scope; @code{static} in @code{C}. The value
           is the offset into the section of the data. */
 #define BSF_LOCAL      0x01

        /* The symbol has global scope; initialized data in @code{C}. The
           value is the offset into the section of the data. */
 #define BSF_GLOBAL     0x02

        /* The symbol has global scope and is exported. The value is
           the offset into the section of the data. */
 #define BSF_EXPORT     BSF_GLOBAL /* no real difference */

        /* A normal C symbol would be one of:
           @code{BSF_LOCAL}, @code{BSF_FORT_COMM},  @code{BSF_UNDEFINED} or
           @code{BSF_GLOBAL} */

        /* The symbol is a debugging record. The value has an arbitary
           meaning, unless BSF_DEBUGGING_RELOC is also set.  */
 #define BSF_DEBUGGING  0x08

        /* The symbol denotes a function entry point.  Used in ELF,
           perhaps others someday.  */
 #define BSF_FUNCTION    0x10

        /* Used by the linker. */
 #define BSF_KEEP        0x20
 #define BSF_KEEP_G      0x40

        /* A weak global symbol, overridable without warnings by
           a regular global symbol of the same name.  */
 #define BSF_WEAK        0x80

        /* This symbol was created to point to a section, e.g. ELF's
           STT_SECTION symbols.  */
 #define BSF_SECTION_SYM 0x100

        /* The symbol used to be a common symbol, but now it is
           allocated. */
 #define BSF_OLD_COMMON  0x200

        /* The default value for common data. */
 #define BFD_FORT_COMM_DEFAULT_VALUE 0

        /* In some files the type of a symbol sometimes alters its
           location in an output file - ie in coff a @code{ISFCN} symbol
           which is also @code{C_EXT} symbol appears where it was
           declared and not at the end of a section.  This bit is set
           by the target BFD part to convey this information. */

 #define BSF_NOT_AT_END    0x400

        /* Signal that the symbol is the label of constructor section. */
 #define BSF_CONSTRUCTOR   0x800

        /* Signal that the symbol is a warning symbol.  The name is a
           warning.  The name of the next symbol is the one to warn about;
           if a reference is made to a symbol with the same name as the next
           symbol, a warning is issued by the linker. */
 #define BSF_WARNING       0x1000

        /* Signal that the symbol is indirect.  This symbol is an indirect
           pointer to the symbol with the same name as the next symbol. */
 #define BSF_INDIRECT      0x2000

        /* BSF_FILE marks symbols that contain a file name.  This is used
           for ELF STT_FILE symbols.  */
 #define BSF_FILE          0x4000

        /* Symbol is from dynamic linking information.  */
 #define BSF_DYNAMIC       0x8000

        /* The symbol denotes a data object.  Used in ELF, and perhaps
           others someday.  */
 #define BSF_OBJECT        0x10000

        /* This symbol is a debugging symbol.  The value is the offset
           into the section of the data.  BSF_DEBUGGING should be set
           as well.  */
 #define BSF_DEBUGGING_RELOC 0x20000

   flagword flags;

        /* A pointer to the section to which this symbol is
           relative.  This will always be non NULL, there are special
           sections for undefined and absolute symbols.  */
   struct sec *section;

        /* Back end special data.  */
   union
     @{
       PTR p;
       bfd_vma i;
     @} udata;

 @} asymbol;
 @end example

 @node symbol handling functions,  , typedef asymbol, Symbols
 @subsection Symbol handling functions


 @findex bfd_get_symtab_upper_bound
 @subsubsection @code{bfd_get_symtab_upper_bound}
 @strong{Description}@*
 Return the number of bytes required to store a vector of pointers
 to @code{asymbols} for all the symbols in the BFD @var{abfd},
 including a terminal NULL pointer. If there are no symbols in
 the BFD, then return 0.  If an error occurs, return -1.
 @example
 #define bfd_get_symtab_upper_bound(abfd) \
      BFD_SEND (abfd, _bfd_get_symtab_upper_bound, (abfd))
 @end example

 @findex bfd_is_local_label
 @subsubsection @code{bfd_is_local_label}
 @strong{Synopsis}
 @example
 boolean bfd_is_local_label(bfd *abfd, asymbol *sym);
 @end example
 @strong{Description}@*
 Return true if the given symbol @var{sym} in the BFD @var{abfd} is
 a compiler generated local label, else return false.

 @findex bfd_is_local_label_name
 @subsubsection @code{bfd_is_local_label_name}
 @strong{Synopsis}
 @example
 boolean bfd_is_local_label_name(bfd *abfd, const char *name);
 @end example
 @strong{Description}@*
 Return true if a symbol with the name @var{name} in the BFD
 @var{abfd} is a compiler generated local label, else return
 false.  This just checks whether the name has the form of a
 local label.
 @example
 #define bfd_is_local_label_name(abfd, name) \
      BFD_SEND (abfd, _bfd_is_local_label_name, (abfd, name))
 @end example

 @findex bfd_canonicalize_symtab
 @subsubsection @code{bfd_canonicalize_symtab}
 @strong{Description}@*
 Read the symbols from the BFD @var{abfd}, and fills in
 the vector @var{location} with pointers to the symbols and
 a trailing NULL.
 Return the actual number of symbol pointers, not
 including the NULL.
 @example
 #define bfd_canonicalize_symtab(abfd, location) \
      BFD_SEND (abfd, _bfd_canonicalize_symtab,\
                   (abfd, location))
 @end example

 @findex bfd_set_symtab
 @subsubsection @code{bfd_set_symtab}
 @strong{Synopsis}
 @example
 boolean bfd_set_symtab (bfd *abfd, asymbol **location, unsigned int count);
 @end example
 @strong{Description}@*
 Arrange that when the output BFD @var{abfd} is closed,
 the table @var{location} of @var{count} pointers to symbols
 will be written.

 @findex bfd_print_symbol_vandf
 @subsubsection @code{bfd_print_symbol_vandf}
 @strong{Synopsis}
 @example
 void bfd_print_symbol_vandf(PTR file, asymbol *symbol);
 @end example
 @strong{Description}@*
 Print the value and flags of the @var{symbol} supplied to the
 stream @var{file}.

 @findex bfd_make_empty_symbol
 @subsubsection @code{bfd_make_empty_symbol}
 @strong{Description}@*
 Create a new @code{asymbol} structure for the BFD @var{abfd}
 and return a pointer to it.

 This routine is necessary because each back end has private
 information surrounding the @code{asymbol}. Building your own
 @code{asymbol} and pointing to it will not create the private
 information, and will cause problems later on.
 @example
 #define bfd_make_empty_symbol(abfd) \
      BFD_SEND (abfd, _bfd_make_empty_symbol, (abfd))
 @end example

 @findex bfd_make_debug_symbol
 @subsubsection @code{bfd_make_debug_symbol}
 @strong{Description}@*
 Create a new @code{asymbol} structure for the BFD @var{abfd},
 to be used as a debugging symbol.  Further details of its use have
 yet to be worked out.
 @example
 #define bfd_make_debug_symbol(abfd,ptr,size) \
         BFD_SEND (abfd, _bfd_make_debug_symbol, (abfd, ptr, size))
 @end example

 @findex bfd_decode_symclass
 @subsubsection @code{bfd_decode_symclass}
 @strong{Description}@*
 Return a character corresponding to the symbol
 class of @var{symbol}, or '?' for an unknown class.

 @strong{Synopsis}
 @example
 int bfd_decode_symclass(asymbol *symbol);
 @end example
 @findex bfd_is_undefined_symclass
 @subsubsection @code{bfd_is_undefined_symclass}
 @strong{Description}@*
 Returns non-zero if the class symbol returned by
 bfd_decode_symclass represents an undefined symbol.
 Returns zero otherwise.

 @strong{Synopsis}
 @example
 boolean bfd_is_undefined_symclass (int symclass);
 @end example
 @findex bfd_symbol_info
 @subsubsection @code{bfd_symbol_info}
 @strong{Description}@*
 Fill in the basic info about symbol that nm needs.
 Additional info may be added by the back-ends after
 calling this function.

 @strong{Synopsis}
 @example
 void bfd_symbol_info(asymbol *symbol, symbol_info *ret);
 @end example
 @findex bfd_copy_private_symbol_data
 @subsubsection @code{bfd_copy_private_symbol_data}
 @strong{Synopsis}
 @example
 boolean bfd_copy_private_symbol_data(bfd *ibfd, asymbol *isym, bfd *obfd, asymbol *osym);
 @end example
 @strong{Description}@*
 Copy private symbol information from @var{isym} in the BFD
 @var{ibfd} to the symbol @var{osym} in the BFD @var{obfd}.
 Return @code{true} on success, @code{false} on error.  Possible error
 returns are:

 @itemize @bullet

 @item
 @code{bfd_error_no_memory} -
 Not enough memory exists to create private data for @var{osec}.
 @end itemize
 @example
 #define bfd_copy_private_symbol_data(ibfd, isymbol, obfd, osymbol) \
      BFD_SEND (obfd, _bfd_copy_private_symbol_data, \
                (ibfd, isymbol, obfd, osymbol))
 @end example
	@section Symbols
	BFD tries to maintain as much symbol information as it can when
	it moves information from file to file. BFD passes information
	to applications though the @code{asymbol} structure. When the
	application requests the symbol table, BFD reads the table in
	the native form and translates parts of it into the internal
	format. To maintain more than the information passed to
	applications, some targets keep some information ``behind the
	scenes'' in a structure only the particular back end knows
	about. For example, the coff back end keeps the original
	symbol table structure as well as the canonical structure when
	a BFD is read in. On output, the coff back end can reconstruct
	the output symbol table so that no information is lost, even
	information unique to coff which BFD doesn't know or
	understand. If a coff symbol table were read, but were written
	through an a.out back end, all the coff specific information
	would be lost. The symbol table of a BFD
	is not necessarily read in until a canonicalize request is
	made. Then the BFD back end fills in a table provided by the
	application with pointers to the canonical information. To
	output symbols, the application provides BFD with a table of
	pointers to pointers to @code{asymbol}s. This allows applications
	like the linker to output a symbol as it was read, since the ``behind
	the scenes'' information will be still available.
	@menu
	* Reading Symbols::
	* Writing Symbols::
	* Mini Symbols::
	* typedef asymbol::
	* symbol handling functions::
	@end menu

	@node Reading Symbols, Writing Symbols, Symbols, Symbols
	@subsection Reading symbols
	There are two stages to reading a symbol table from a BFD:
	allocating storage, and the actual reading process. This is an
	excerpt from an application which reads the symbol table:

	@example
	long storage_needed;
	asymbol **symbol_table;
	long number_of_symbols;
	long i;

	storage_needed = bfd_get_symtab_upper_bound (abfd);

	if (storage_needed < 0)
	FAIL

	if (storage_needed == 0) @{
	return ;
	@}
	symbol_table = (asymbol **) xmalloc (storage_needed);
	...
	number_of_symbols =
	bfd_canonicalize_symtab (abfd, symbol_table);

	if (number_of_symbols < 0)
	FAIL

	for (i = 0; i < number_of_symbols; i++) @{
	process_symbol (symbol_table[i]);
	@}
	@end example

	All storage for the symbols themselves is in an objalloc
	connected to the BFD; it is freed when the BFD is closed.

	@node Writing Symbols, Mini Symbols, Reading Symbols, Symbols
	@subsection Writing symbols
	Writing of a symbol table is automatic when a BFD open for
	writing is closed. The application attaches a vector of
	pointers to pointers to symbols to the BFD being written, and
	fills in the symbol count. The close and cleanup code reads
	through the table provided and performs all the necessary
	operations. The BFD output code must always be provided with an
	``owned'' symbol: one which has come from another BFD, or one
	which has been created using @code{bfd_make_empty_symbol}. Here is an
	example showing the creation of a symbol table with only one element:

	@example
	#include "bfd.h"
	main()
	@{
	bfd *abfd;
	asymbol *ptrs[2];
	asymbol *new;

	abfd = bfd_openw("foo","a.out-sunos-big");
	bfd_set_format(abfd, bfd_object);
	new = bfd_make_empty_symbol(abfd);
	new->name = "dummy_symbol";
	new->section = bfd_make_section_old_way(abfd, ".text");
	new->flags = BSF_GLOBAL;
	new->value = 0x12345;

	ptrs[0] = new;
	ptrs[1] = (asymbol *)0;

	bfd_set_symtab(abfd, ptrs, 1);
	bfd_close(abfd);
	@}

	./makesym
	nm foo
	00012345 A dummy_symbol
	@end example

	Many formats cannot represent arbitary symbol information; for
	instance, the @code{a.out} object format does not allow an
	arbitary number of sections. A symbol pointing to a section
	which is not one of @code{.text}, @code{.data} or @code{.bss} cannot
	be described.

	@node Mini Symbols, typedef asymbol, Writing Symbols, Symbols
	@subsection Mini Symbols
	Mini symbols provide read-only access to the symbol table.
	They use less memory space, but require more time to access.
	They can be useful for tools like nm or objdump, which may
	have to handle symbol tables of extremely large executables.

	The @code{bfd_read_minisymbols} function will read the symbols
	into memory in an internal form. It will return a @code{void *}
	pointer to a block of memory, a symbol count, and the size of
	each symbol. The pointer is allocated using @code{malloc}, and
	should be freed by the caller when it is no longer needed.

	The function @code{bfd_minisymbol_to_symbol} will take a pointer
	to a minisymbol, and a pointer to a structure returned by
	@code{bfd_make_empty_symbol}, and return a @code{asymbol} structure.
	The return value may or may not be the same as the value from
	@code{bfd_make_empty_symbol} which was passed in.


	@node typedef asymbol, symbol handling functions, Mini Symbols, Symbols
	@subsection typedef asymbol
	An @code{asymbol} has the form:


	@example

	typedef struct symbol_cache_entry
	@{
	/* A pointer to the BFD which owns the symbol. This information
	is necessary so that a back end can work out what additional
	information (invisible to the application writer) is carried
	with the symbol.

	This field is almost redundant, since you can use section->owner
	instead, except that some symbols point to the global sections
	bfd_@{abs,com,und@}_section. This could be fixed by making
	these globals be per-bfd (or per-target-flavor). FIXME. */

	struct _bfd the_bfd; / Use bfd_asymbol_bfd(sym) to access this field. */

	/* The text of the symbol. The name is left alone, and not copied; the
	application may not alter it. */
	CONST char *name;

	/* The value of the symbol. This really should be a union of a
	numeric value with a pointer, since some flags indicate that
	a pointer to another symbol is stored here. */
	symvalue value;

	/* Attributes of a symbol: */

	#define BSF_NO_FLAGS 0x00

	/* The symbol has local scope; @code{static} in @code{C}. The value
	is the offset into the section of the data. */
	#define BSF_LOCAL 0x01

	/* The symbol has global scope; initialized data in @code{C}. The
	value is the offset into the section of the data. */
	#define BSF_GLOBAL 0x02

	/* The symbol has global scope and is exported. The value is
	the offset into the section of the data. */
	#define BSF_EXPORT BSF_GLOBAL /* no real difference */

	/* A normal C symbol would be one of:
	@code{BSF_LOCAL}, @code{BSF_FORT_COMM}, @code{BSF_UNDEFINED} or
	@code{BSF_GLOBAL} */

	/* The symbol is a debugging record. The value has an arbitary
	meaning, unless BSF_DEBUGGING_RELOC is also set. */
	#define BSF_DEBUGGING 0x08

	/* The symbol denotes a function entry point. Used in ELF,
	perhaps others someday. */
	#define BSF_FUNCTION 0x10

	/* Used by the linker. */
	#define BSF_KEEP 0x20
	#define BSF_KEEP_G 0x40

	/* A weak global symbol, overridable without warnings by
	a regular global symbol of the same name. */
	#define BSF_WEAK 0x80

	/* This symbol was created to point to a section, e.g. ELF's
	STT_SECTION symbols. */
	#define BSF_SECTION_SYM 0x100

	/* The symbol used to be a common symbol, but now it is
	allocated. */
	#define BSF_OLD_COMMON 0x200

	/* The default value for common data. */
	#define BFD_FORT_COMM_DEFAULT_VALUE 0

	/* In some files the type of a symbol sometimes alters its
	location in an output file - ie in coff a @code{ISFCN} symbol
	which is also @code{C_EXT} symbol appears where it was
	declared and not at the end of a section. This bit is set
	by the target BFD part to convey this information. */

	#define BSF_NOT_AT_END 0x400

	/* Signal that the symbol is the label of constructor section. */
	#define BSF_CONSTRUCTOR 0x800

	/* Signal that the symbol is a warning symbol. The name is a
	warning. The name of the next symbol is the one to warn about;
	if a reference is made to a symbol with the same name as the next
	symbol, a warning is issued by the linker. */
	#define BSF_WARNING 0x1000

	/* Signal that the symbol is indirect. This symbol is an indirect
	pointer to the symbol with the same name as the next symbol. */
	#define BSF_INDIRECT 0x2000

	/* BSF_FILE marks symbols that contain a file name. This is used
	for ELF STT_FILE symbols. */
	#define BSF_FILE 0x4000

	/* Symbol is from dynamic linking information. */
	#define BSF_DYNAMIC 0x8000

	/* The symbol denotes a data object. Used in ELF, and perhaps
	others someday. */
	#define BSF_OBJECT 0x10000

	/* This symbol is a debugging symbol. The value is the offset
	into the section of the data. BSF_DEBUGGING should be set
	as well. */
	#define BSF_DEBUGGING_RELOC 0x20000

	flagword flags;

	/* A pointer to the section to which this symbol is
	relative. This will always be non NULL, there are special
	sections for undefined and absolute symbols. */
	struct sec *section;

	/* Back end special data. */
	union
	@{
	PTR p;
	bfd_vma i;
	@} udata;

	@} asymbol;
	@end example

	@node symbol handling functions, , typedef asymbol, Symbols
	@subsection Symbol handling functions


	@findex bfd_get_symtab_upper_bound
	@subsubsection @code{bfd_get_symtab_upper_bound}
	@strong{Description}@*
	Return the number of bytes required to store a vector of pointers
	to @code{asymbols} for all the symbols in the BFD @var{abfd},
	including a terminal NULL pointer. If there are no symbols in
	the BFD, then return 0. If an error occurs, return -1.
	@example
	#define bfd_get_symtab_upper_bound(abfd) \
	BFD_SEND (abfd, _bfd_get_symtab_upper_bound, (abfd))
	@end example

	@findex bfd_is_local_label
	@subsubsection @code{bfd_is_local_label}
	@strong{Synopsis}
	@example
	boolean bfd_is_local_label(bfd abfd, asymbol sym);
	@end example
	@strong{Description}@*
	Return true if the given symbol @var{sym} in the BFD @var{abfd} is
	a compiler generated local label, else return false.

	@findex bfd_is_local_label_name
	@subsubsection @code{bfd_is_local_label_name}
	@strong{Synopsis}
	@example
	boolean bfd_is_local_label_name(bfd abfd, const char name);
	@end example
	@strong{Description}@*
	Return true if a symbol with the name @var{name} in the BFD
	@var{abfd} is a compiler generated local label, else return
	false. This just checks whether the name has the form of a
	local label.
	@example
	#define bfd_is_local_label_name(abfd, name) \
	BFD_SEND (abfd, _bfd_is_local_label_name, (abfd, name))
	@end example

	@findex bfd_canonicalize_symtab
	@subsubsection @code{bfd_canonicalize_symtab}
	@strong{Description}@*
	Read the symbols from the BFD @var{abfd}, and fills in
	the vector @var{location} with pointers to the symbols and
	a trailing NULL.
	Return the actual number of symbol pointers, not
	including the NULL.
	@example
	#define bfd_canonicalize_symtab(abfd, location) \
	BFD_SEND (abfd, _bfd_canonicalize_symtab,\
	(abfd, location))
	@end example

	@findex bfd_set_symtab
	@subsubsection @code{bfd_set_symtab}
	@strong{Synopsis}
	@example
	boolean bfd_set_symtab (bfd abfd, asymbol *location, unsigned int count);
	@end example
	@strong{Description}@*
	Arrange that when the output BFD @var{abfd} is closed,
	the table @var{location} of @var{count} pointers to symbols
	will be written.

	@findex bfd_print_symbol_vandf
	@subsubsection @code{bfd_print_symbol_vandf}
	@strong{Synopsis}
	@example
	void bfd_print_symbol_vandf(PTR file, asymbol *symbol);
	@end example
	@strong{Description}@*
	Print the value and flags of the @var{symbol} supplied to the
	stream @var{file}.

	@findex bfd_make_empty_symbol
	@subsubsection @code{bfd_make_empty_symbol}
	@strong{Description}@*
	Create a new @code{asymbol} structure for the BFD @var{abfd}
	and return a pointer to it.

	This routine is necessary because each back end has private
	information surrounding the @code{asymbol}. Building your own
	@code{asymbol} and pointing to it will not create the private
	information, and will cause problems later on.
	@example
	#define bfd_make_empty_symbol(abfd) \
	BFD_SEND (abfd, _bfd_make_empty_symbol, (abfd))
	@end example

	@findex bfd_make_debug_symbol
	@subsubsection @code{bfd_make_debug_symbol}
	@strong{Description}@*
	Create a new @code{asymbol} structure for the BFD @var{abfd},
	to be used as a debugging symbol. Further details of its use have
	yet to be worked out.
	@example
	#define bfd_make_debug_symbol(abfd,ptr,size) \
	BFD_SEND (abfd, _bfd_make_debug_symbol, (abfd, ptr, size))
	@end example

	@findex bfd_decode_symclass
	@subsubsection @code{bfd_decode_symclass}
	@strong{Description}@*
	Return a character corresponding to the symbol
	class of @var{symbol}, or '?' for an unknown class.

	@strong{Synopsis}
	@example
	int bfd_decode_symclass(asymbol *symbol);
	@end example
	@findex bfd_is_undefined_symclass
	@subsubsection @code{bfd_is_undefined_symclass}
	@strong{Description}@*
	Returns non-zero if the class symbol returned by
	bfd_decode_symclass represents an undefined symbol.
	Returns zero otherwise.

	@strong{Synopsis}
	@example
	boolean bfd_is_undefined_symclass (int symclass);
	@end example
	@findex bfd_symbol_info
	@subsubsection @code{bfd_symbol_info}
	@strong{Description}@*
	Fill in the basic info about symbol that nm needs.
	Additional info may be added by the back-ends after
	calling this function.

	@strong{Synopsis}
	@example
	void bfd_symbol_info(asymbol symbol, symbol_info ret);
	@end example
	@findex bfd_copy_private_symbol_data
	@subsubsection @code{bfd_copy_private_symbol_data}
	@strong{Synopsis}
	@example
	boolean bfd_copy_private_symbol_data(bfd ibfd, asymbol isym, bfd obfd, asymbol osym);
	@end example
	@strong{Description}@*
	Copy private symbol information from @var{isym} in the BFD
	@var{ibfd} to the symbol @var{osym} in the BFD @var{obfd}.
	Return @code{true} on success, @code{false} on error. Possible error
	returns are:

	@itemize @bullet

	@item
	@code{bfd_error_no_memory} -
	Not enough memory exists to create private data for @var{osec}.
	@end itemize
	@example
	#define bfd_copy_private_symbol_data(ibfd, isymbol, obfd, osymbol) \
	BFD_SEND (obfd, _bfd_copy_private_symbol_data, \
	(ibfd, isymbol, obfd, osymbol))
	@end example