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#include <libelf.h>
Elf_Data *elf_getdata(Elf_Scn *scn, Elf_Data *data);
Elf_Data *elf_newdata(Elf_Scn *scn);
Elf_Data *elf_rawdata(Elf_Scn *scn, Elf_Data *data);
elf_newdata- creates a new data descriptor for a section.
elf_rawdata- retrieves data from a section without interpreting it.
These functions access and manipulate the data associated with a section descriptor, scn. When the function is reading an existing file, each section has a single data buffer associated with it. However, a program may build a new section in pieces, composing the new data from several data buffers. Therefore, think of the data for a section as a list of buffers, each available through a data descriptor.
elf_getdata(S-osr5) lets a program step through a section's data list. If the incoming data descriptor, data, is null, elf_getdata( ) returns the first buffer associated with the section. If not null, data is a data descriptor associated with scn, and elf_getdata( ) gives the program access by returning a pointer to the next data element for the section. If scn is null or an error occurs, elf_getdata( ) returns a null pointer.
elf_getdata( ) translates the data from file representations into memory representations (see elf_xlate(S-osr5)). Then it presents objects with memory data types to the program, based on the file's class (see elf(S-osr5)). The working library version (see elf_version(S-osr5)) specifies which version of the memory structures to present to the program.
elf_newdata(S-osr5)) creates a new data descriptor for a section and appends it to any data elements already associated with the section. As described below, the new data descriptor appears empty, indicating that the element holds no data.
For convenience, the descriptor's type
(d_type
below)
is set to
ELF_T_BYTE,
and the version
(d_version
below) is set to the working version.
The program must set or change the descriptor members as needed.
This function implicitly sets the bit
ELF_F_DIRTY
for the section's data (see
elf_flag(S-osr5)).
If
scn
is null or an error occurs,
elf_newdata( )
returns a null pointer.
elf_rawdata(S-osr5) differs from elf_getdata( ) by returning only uninterpreted bytes, regardless of the section type. Generally, use this function only to retrieve a section image from a file being read, and then only when a program must avoid the automatic data translation described below.
Moreover, a program can not close or disable (see elf_cntl(S-osr5)) the file descriptor associated with elf before the initial raw operation, because elf_rawdata( ) might read the data from the file to ensure it doesn't interfere with elf_getdata( ).
For a related routine that applies to the entire file, see elf_rawfile(S-osr5).
If elf_getdata( ) provides the right translation, use it instead of elf_rawdata( ).
If scn is null or an error occurs, elf_rawdata( ) returns a null pointer.
The Elf_Data(S-osr5) structure includes the following members:
void *d_buf; Elf_Type d_type; size_t d_size; off_t d_off; size_t d_align; unsigned d_version;These members are available for direct manipulation by the program. Descriptions appear below.
d_buf
d_type
d_size
d_off
d_align
d_off
is a multiple of this value.
For example, if the value is four,
the beginning of the buffer is four-byte-aligned within the section.
Moreover, the entire section is aligned to the maximum of its constituents,
thus ensuring proper alignment for a buffer
within the section and within the file.
d_version
First, the program can use elf_fill(S-osr5) to tell the library how to set the intervening bytes. When the library must generate gaps in the file, it uses the fill byte to initialize the data there. The library's initial fill value is zero, but elf_fill( ) lets the application change that.
Second, the application can generate its own data buffers to occupy the gaps, filling the gaps with values appropriate for the section being created. A program can use different fill values for different sections. For example, it can set text sections' bytes to no-operation instructions, while filling data section holes with zero. When you use this technique, the library finds no holes to fill, because the application has eliminated them.
Section Type | Elf_Type | 32-Bit Type |
---|---|---|
SHT_DYNAMIC | ELF_T_DYN | Elf32_Dyn |
SHT_DYNSYM | ELF_T_SYM | Elf32_Sym |
SHT_HASH | ELF_T_WORD | Elf32_Word |
SHT_NOBITS | ELF_T_BYTE | unsigned char |
SHT_NOTE | ELF_T_BYTE | unsigned char |
SHT_NULL | none | none |
SHT_PROGBITS | ELF_T_BYTE | unsigned char |
SHT_REL | ELF_T_REL | Elf32_Rel |
SHT_RELA | ELF_T_RELA | Elf32_Rela |
SHT_STRTAB | ELF_T_BYTE | unsigned char |
SHT_SYMTAB | ELF_T_SYM | Elf32_Sym |
other | ELF_T_BYTE | unsigned char |
As mentioned above, the program's working version controls what structures the library creates for the application. The library similarly interprets section types according to the versions.
If the library does not recognize the section type, it presents an untranslated buffer of type ELF_T_BYTE.
If a section type belongs to a version newer than the application's working version, the library does not translate the section data. The application cannot know the data format, so the library presents an untranslated buffer of type ELF_T_BYTE.
A section with a special type,
SHT_NOBITS,
occupies no space in an object file, even when
the section header indicates a non-zero size.
elf_getdata( )
and
elf_rawdata( )
work properly on such a section, setting the
data
structure to have a null buffer pointer and the type
SHT_NOBITS.
Although no data is present, the
d_size
value is set to the size specified in the section header.
If your program creates a new section of type
SHT_NOBITS,
use
elf_newdata( )
to add data buffers to the section.
For these ``empty'' data buffers, set the
d_size
members to the desired size and the
d_buf
members to null.
ehdr = elf32_getehdr(elf); scn = elf_getscn(elf, (size_t)ehdr->e_shstrndx); shdr = elf32_getshdr(scn); if (shdr->sh_type != SHT_STRTAB) { /* not a string table */ } data = 0; if ((data = elf_getdata(scn, data)) == 0 || data->d_size == 0) { /* error or no data */ }
The
e_shstrndx
(S-osr5)
member in an
ELF
header holds the section table index of the string table.
The program gets a section descriptor for that section,
verifies that it is a string table,
and then retrieves the data.
When this fragment finishes,
data->d_buf
points at the
first byte of the string table, and
data->d_size
holds
the string table's size in bytes.