----------------------------------------------------------------------------

Symbol table

An object file's symbol table holds information needed to locate and
relocate a program's symbolic definitions and references. A symbol table
index is a subscript into this array. Index 0 both designates the first
entry in the table and serves as the undefined symbol index.

 ---------------------------------------------------------------------
 Name         Value
 ---------------------------------------------------------------------
 STN_UNDEF    0

A symbol table entry has the following format.

   typedef struct {
        Elf32_Word      st_name;
        Elf32_Addr      st_value;
        Elf32_Word      st_size;
        unsigned char   st_info;
        unsigned char   st_other;
        Elf32_Half      st_shndx;
   } Elf32_Sym;

Figure 8-6 Symbol table entry

st_name
     This member holds an index into the object file's symbol string table,
     which holds the character representations of the symbol names. If the
     value is non-zero, it represents a string table index that gives the
     symbol name. Otherwise, the symbol table entry has no name.

     -----------------------------------------------------------------------
     NOTE: External C symbols have the same names in C and object files'
     symbol tables.
     -----------------------------------------------------------------------

st_value
     This member gives the value of the associated symbol. Depending on the
     context, this may be an absolute value, or an address.

st_size
     Many symbols have associated sizes. For example, a data object's size
     is the number of bytes contained in the object. This member holds 0 if
     the symbol has no size or an unknown size.

st_info
     This member specifies the symbol's type and binding attributes. A list
     of the values and meanings appears below. The following code shows how
     to manipulate the values.

     #define ELF32_ST_BIND(i)   ((i)>>4)
     #define ELF32_ST_TYPE(i)   ((i)&0xf)
     #define ELF32_ST_INFO(b,t) (((b)<<4)+((t)&0xf))

st_other
     This member currently holds 0 and has no defined meaning.

st_shndx
     Every symbol table entry is defined in relation to some section. This
     member holds the relevant section header table index. Some section
     indexes indicate special meanings.

A symbol's binding determines the linkage visibility and behavior.

Table 8-10 Symbol binding, ELF32_ST_BIND

 ------------------------------------------------------------------
 Name                      Value
 ------------------------------------------------------------------
 STB_LOCAL                 0
 STB_GLOBAL                1
 STB_WEAK                  2
 STB_LOPROC                13
 STB_HIPROC                15



STB_LOCAL
     Local symbols are not visible outside the object file containing their
     definition. Local symbols of the same name may exist in multiple files
     without interfering with each other.

STB_GLOBAL
     Global symbols are visible to all object files being combined. One
     file's definition of a global symbol will satisfy another file's
     undefined reference to the same global symbol.

STB_WEAK
     Weak symbols resemble global symbols, but their definitions have lower
     precedence.

STB_LOPROC through STB_HIPROC
     Values in this inclusive range are reserved for processor-specific
     semantics.

Global and weak symbols differ in two major ways, as described in ``Multiply
defined symbols'' in the Programming Tools Guide.

   * When the link editor combines several relocatable object files, it does
     not allow multiple definitions of STB_GLOBAL symbols with the same
     name. On the other hand, if a defined global symbol exists, the
     appearance of a weak symbol with the same name will not cause an error.
     The link editor honors the global definition and ignores the weak ones.
     Similarly, if a common symbol exists (for example, a symbol whose
     st_shndx field holds SHN_COMMON), the appearance of a weak symbol with
     the same name will not cause an error. The link editor honors the
     common definition and ignores the weak one.

   * When the link editor searches archive libraries, it extracts archive
     members that contain definitions of undefined global symbols. The
     member's definition may be either a global or a weak symbol. The link
     editor does not extract archive members to resolve undefined weak
     symbols. Unresolved weak symbols have a zero value.

In each symbol table, all symbols with STB_LOCAL binding precede the weak
and global symbols. As described in ``Section header'', a symbol table
section's sh_info section header member holds the symbol table index for the
first non-local symbol.

A symbol's type provides a general classification for the associated entity.


Table 8-11 Symbol types, ELF32_ST_TYPE

 ------------------------------------------------------------------
 Name                      Value
 ------------------------------------------------------------------
 STT_NOTYPE                0
 STT_OBJECT                1
 STT_FUNC                  2
 STT_SECTION               3
 STT_FILE                  4
 STT_LOPROC                13
 STT_HIPROC                15

STT_NOTYPE
     The symbol's type is not specified.

STT_OBJECT
     The symbol is associated with a data object, such as a variable, an
     array, and so forth.

STT_FUNC
     The symbol is associated with a function or other executable code.

STT_SECTION
     The symbol is associated with a section. Symbol table entries of this
     type exist primarily for relocation and normally have STB_LOCAL
     binding.

STT_FILE
     Conventionally, the symbol's name gives the name of the source file
     associated with the object file. A file symbol has STB_LOCAL binding,
     its section index is SHN_ABS, and it precedes the other STB_LOCAL
     symbols for the file, if it is present.

STT_LOPROC through STT_HIPROC
     Values in this inclusive range are reserved for processor-specific
     semantics.

Function symbols (those with type STT_FUNC) in shared object files have
special significance. When another object file references a function from a
shared object, the link editor automatically creates a procedure linkage
table entry for the referenced symbol. Shared object symbols with types
other than STT_FUNC will not be referenced automatically through the
procedure linkage table.

If a symbol's value refers to a specific location within a section, its
section index member, st_shndx, holds an index into the section header
table. As the section moves during relocation, the symbol's value changes as
well, and references to the symbol continue to ``point'' to the same
location in the program. Some special section index values give other
semantics.

SHN_ABS
     The symbol has an absolute value that will not change because of
     relocation.

SHN_COMMON
     The symbol labels a common block that has not yet been allocated. The
     symbol's value gives alignment constraints, similar to a section's
     sh_addralign member. The link editor will allocate the storage for the
     symbol at an address that is a multiple of st_value. The symbol's size
     tells how many bytes are required.

SHN_UNDEF
     This section table index means the symbol is undefined. When the link
     editor combines this object file with another that defines the
     indicated symbol, this file's references to the symbol will be linked
     to the actual definition.

The symbol table entry for index 0 (STN_UNDEF) is reserved and holds the
following values:

Table 8-12 Symbol table entry: index 0

 ------------------------------------------------------------------
 Name         Value           Note
 ------------------------------------------------------------------
 st_name      0               No name
 st_value     0               Zero value
 st_size      0               No size
 st_info      0               No type, local binding
 st_other     0
 st_shndx     SHN_UNDEF       No section