elf(5) - c7

1ELF(5)                     Linux Programmer's Manual                    ELF(5)
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3
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NAME

6       elf - format of Executable and Linking Format (ELF) files
7

SYNOPSIS

9       #include <elf.h>
10

DESCRIPTION

12       The  header  file  <elf.h>  defines the format of ELF executable binary
13       files.  Amongst these files are normal  executable  files,  relocatable
14       object files, core files and shared libraries.
15
16       An executable file using the ELF file format consists of an ELF header,
17       followed by a program header table or a section header table, or  both.
18       The  ELF  header  is  always  at  offset zero of the file.  The program
19       header table and the section header table's  offset  in  the  file  are
20       defined  in  the  ELF  header.  The two tables describe the rest of the
21       particularities of the file.
22
23       This header file describes the above mentioned headers as C  structures
24       and  also includes structures for dynamic sections, relocation sections
25       and symbol tables.
26
27       The following types are used for  N-bit  architectures  (N=32,64,  ElfN
28       stands for Elf32 or Elf64, uintN_t stands for uint32_t or uint64_t):
29
30           ElfN_Addr       Unsigned program address, uintN_t
31           ElfN_Off        Unsigned file offset, uintN_t
32           ElfN_Section    Unsigned section index, uint16_t
33           ElfN_Versym     Unsigned version symbol information, uint16_t
34           Elf_Byte        unsigned char
35           ElfN_Half       uint16_t
36           ElfN_Sword      int32_t
37           ElfN_Word       uint32_t
38           ElfN_Sxword     int64_t
39           ElfN_Xword      uint64_t
40
41       (Note:  The  *BSD  terminology is a bit different.  There Elf64_Half is
42       twice as large as Elf32_Half, and Elf64Quarter is  used  for  uint16_t.
43       In  order  to avoid confusion these types are replaced by explicit ones
44       in the below.)
45
46       All data structures that the file format defines follow  the  "natural"
47       size  and  alignment  guidelines for the relevant class.  If necessary,
48       data structures contain explicit padding to ensure 4-byte alignment for
49       4-byte objects, to force structure sizes to a multiple of 4, etc.
50
51       The ELF header is described by the type Elf32_Ehdr or Elf64_Ehdr:
52
53           #define EI_NIDENT 16
54
55           typedef struct {
56               unsigned char e_ident[EI_NIDENT];
57               uint16_t      e_type;
58               uint16_t      e_machine;
59               uint32_t      e_version;
60               ElfN_Addr     e_entry;
61               ElfN_Off      e_phoff;
62               ElfN_Off      e_shoff;
63               uint32_t      e_flags;
64               uint16_t      e_ehsize;
65               uint16_t      e_phentsize;
66               uint16_t      e_phnum;
67               uint16_t      e_shentsize;
68               uint16_t      e_shnum;
69               uint16_t      e_shstrndx;
70           } ElfN_Ehdr;
71
72       The fields have the following meanings:
73
74       e_ident     This  array of bytes specifies to interpret the file, inde‐
75                   pendent of the processor or the file's remaining  contents.
76                   Within  this  array  everything  is  named by macros, which
77                   start with the prefix EI_  and  may  contain  values  which
78                   start  with  the  prefix  ELF.   The  following  macros are
79                   defined:
80
81                   EI_MAG0     The first byte of the magic number.  It must be
82                               filled with ELFMAG0.  (0: 0x7f)
83
84                   EI_MAG1     The  second  byte of the magic number.  It must
85                               be filled with ELFMAG1.  (1: 'E')
86
87                   EI_MAG2     The third byte of the magic number.  It must be
88                               filled with ELFMAG2.  (2: 'L')
89
90                   EI_MAG3     The  fourth  byte of the magic number.  It must
91                               be filled with ELFMAG3.  (3: 'F')
92
93                   EI_CLASS    The fifth byte identifies the architecture  for
94                               this binary:
95
96                               ELFCLASSNONE  This class is invalid.
97                               ELFCLASS32    This defines the 32-bit architec‐
98                                             ture.  It supports machines  with
99                                             files  and virtual address spaces
100                                             up to 4 Gigabytes.
101                               ELFCLASS64    This defines the 64-bit architec‐
102                                             ture.
103
104                   EI_DATA     The  sixth  byte specifies the data encoding of
105                               the processor-specific data in the file.   Cur‐
106                               rently these encodings are supported:
107
108                               ELFDATANONE   Unknown data format.
109                               ELFDATA2LSB   Two's complement, little-endian.
110                               ELFDATA2MSB   Two's complement, big-endian.
111
112                   EI_VERSION  The  seventh  byte is the version number of the
113                               ELF specification:
114                               EV_NONE       Invalid version.
115                               EV_CURRENT    Current version.
116
117                   EI_OSABI    The eighth byte identifies the operating system
118                               and  ABI to which the object is targeted.  Some
119                               fields in other ELF structures have  flags  and
120                               values  that  have  platform-specific meanings;
121                               the interpretation of those  fields  is  deter‐
122                               mined by the value of this byte.  E.g.:
123
124                               ELFOSABI_NONE       Same as ELFOSABI_SYSV
125                               ELFOSABI_SYSV       UNIX System V ABI.
126                               ELFOSABI_HPUX       HP-UX ABI.
127                               ELFOSABI_NETBSD     NetBSD ABI.
128                               ELFOSABI_LINUX      Linux ABI.
129                               ELFOSABI_SOLARIS    Solaris ABI.
130                               ELFOSABI_IRIX       IRIX ABI.
131                               ELFOSABI_FREEBSD    FreeBSD ABI.
132                               ELFOSABI_TRU64      TRU64 UNIX ABI.
133                               ELFOSABI_ARM        ARM architecture ABI.
134                               ELFOSABI_STANDALONE Stand-alone (embedded) ABI.
135
136                   EI_ABIVERSION
137                               The  ninth  byte  identifies the version of the
138                               ABI to which  the  object  is  targeted.   This
139                               field is used to distinguish among incompatible
140                               versions of an ABI.  The interpretation of this
141                               version  number is dependent on the ABI identi‐
142                               fied by the EI_OSABI field.  Applications  con‐
143                               forming to this specification use the value 0.
144
145                   EI_PAD      Start of padding.  These bytes are reserved and
146                               set to zero.  Programs which read  them  should
147                               ignore  them.  The value for EI_PAD will change
148                               in the future if  currently  unused  bytes  are
149                               given meanings.
150
151                   EI_NIDENT   The size of the e_ident array.
152
153       e_type      This  member  of  the  structure identifies the object file
154                   type:
155
156                   ET_NONE     An unknown type.
157                   ET_REL      A relocatable file.
158                   ET_EXEC     An executable file.
159                   ET_DYN      A shared object.
160                   ET_CORE     A core file.
161
162       e_machine   This member specifies  the  required  architecture  for  an
163                   individual file.  E.g.:
164
165                   EM_NONE     An unknown machine.
166                   EM_M32      AT&T WE 32100.
167                   EM_SPARC    Sun Microsystems SPARC.
168                   EM_386      Intel 80386.
169                   EM_68K      Motorola 68000.
170                   EM_88K      Motorola 88000.
171                   EM_860      Intel 80860.
172                   EM_MIPS     MIPS RS3000 (big-endian only).
173                   EM_PARISC   HP/PA.
174                   EM_SPARC32PLUS
175                               SPARC with enhanced instruction set.
176                   EM_PPC      PowerPC.
177                   EM_PPC64    PowerPC 64-bit.
178                   EM_S390     IBM S/390
179                   EM_ARM      Advanced RISC Machines
180                   EM_SH       Renesas SuperH
181                   EM_SPARCV9  SPARC v9 64-bit.
182                   EM_IA_64    Intel Itanium
183                   EM_X86_64   AMD x86-64
184                   EM_VAX      DEC Vax.
185
186       e_version   This member identifies the file version:
187
188                   EV_NONE     Invalid version.
189                   EV_CURRENT  Current version.
190
191       e_entry     This  member  gives the virtual address to which the system
192                   first transfers control, thus starting the process.  If the
193                   file has no associated entry point, this member holds zero.
194
195       e_phoff     This member holds the program header table's file offset in
196                   bytes.  If the file has no program header table, this  mem‐
197                   ber holds zero.
198
199       e_shoff     This member holds the section header table's file offset in
200                   bytes.  If the file has no section header table this member
201                   holds zero.
202
203       e_flags     This  member holds processor-specific flags associated with
204                   the file.  Flag  names  take  the  form  EF_`machine_flag'.
205                   Currently no flags have been defined.
206
207       e_ehsize    This member holds the ELF header's size in bytes.
208
209       e_phentsize This  member  holds  the  size in bytes of one entry in the
210                   file's program header table; all entries are the same size.
211
212       e_phnum     This member holds the number  of  entries  in  the  program
213                   header  table.  Thus the product of e_phentsize and e_phnum
214                   gives the table's size in bytes.  If a file has no  program
215                   header, e_phnum holds the value zero.
216
217                   If  the  number  of  entries in the program header table is
218                   larger than or equal to PN_XNUM (0xffff), this member holds
219                   PN_XNUM (0xffff) and the real number of entries in the pro‐
220                   gram header table is held in the sh_info member of the ini‐
221                   tial entry in section header table.  Otherwise, the sh_info
222                   member of the initial entry contains the value zero.
223
224                   PN_XNUM  This is defined  as  0xffff,  the  largest  number
225                            e_phnum can have, specifying where the actual num‐
226                            ber of program headers is assigned.
227
228       e_shentsize This member holds a sections header's  size  in  bytes.   A
229                   section  header  is  one entry in the section header table;
230                   all entries are the same size.
231
232       e_shnum     This member holds the number  of  entries  in  the  section
233                   header  table.  Thus the product of e_shentsize and e_shnum
234                   gives the section header table's size in bytes.  If a  file
235                   has  no  section  header  table, e_shnum holds the value of
236                   zero.
237
238                   If the number of entries in the  section  header  table  is
239                   larger  than  or  equal  to SHN_LORESERVE (0xff00), e_shnum
240                   holds the value zero and the real number of entries in  the
241                   section  header  table is held in the sh_size member of the
242                   initial entry in  section  header  table.   Otherwise,  the
243                   sh_size  member  of the initial entry in the section header
244                   table holds the value zero.
245
246       e_shstrndx  This member holds the section header  table  index  of  the
247                   entry  associated  with  the section name string table.  If
248                   the file has no section  name  string  table,  this  member
249                   holds the value SHN_UNDEF.
250
251                   If the index of section name string table section is larger
252                   than or equal to SHN_LORESERVE (0xff00), this member  holds
253                   SHN_XINDEX  [22m(0xffff) and the real index of the section name
254                   string table section is held in the sh_link member  of  the
255                   initial  entry  in  section  header  table.  Otherwise, the
256                   sh_link member of the initial entry in section header table
257                   contains the value zero.
258
259                   SHN_UNDEF     This   value  marks  an  undefined,  missing,
260                                 irrelevant, or otherwise meaningless  section
261                                 reference.   For  example, a symbol "defined"
262                                 relative to section number  SHN_UNDEF  is  an
263                                 undefined symbol.
264
265                   SHN_LORESERVE This  value  specifies the lower bound of the
266                                 range of reserved indices.
267
268                   SHN_LOPROC    Values greater than or  equal  to  SHN_HIPROC
269                                 are  reserved  for  processor-specific seman‐
270                                 tics.
271
272                   SHN_HIPROC    Values less than or equal to  SHN_LOPROC  are
273                                 reserved for processor-specific semantics.
274
275                   SHN_ABS       This  value specifies absolute values for the
276                                 corresponding reference.  For  example,  sym‐
277                                 bols   defined  relative  to  section  number
278                                 SHN_ABS have  absolute  values  and  are  not
279                                 affected by relocation.
280
281                   SHN_COMMON    Symbols  defined relative to this section are
282                                 common symbols, such  as  Fortran  COMMON  or
283                                 unallocated C external variables.
284
285                   SHN_HIRESERVE This  value  specifies the upper bound of the
286                                 range of reserved indices  between  SHN_LORE‐
287                                 SERVE  and SHN_HIRESERVE, inclusive; the val‐
288                                 ues do not reference the section  header  ta‐
289                                 ble.   That is, the section header table does
290                                 not contain entries for the reserved indices.
291
292       An executable or shared object file's program header table is an  array
293       of  structures, each describing a segment or other information the sys‐
294       tem needs to prepare the program for execution.  An object file segment
295       contains one or more sections.  Program headers are meaningful only for
296       executable and shared object files.  A file specifies its  own  program
297       header size with the ELF header's e_phentsize and e_phnum members.  The
298       ELF program header is described by the type  Elf32_Phdr  or  Elf64_Phdr
299       depending on the architecture:
300
301           typedef struct {
302               uint32_t   p_type;
303               Elf32_Off  p_offset;
304               Elf32_Addr p_vaddr;
305               Elf32_Addr p_paddr;
306               uint32_t   p_filesz;
307               uint32_t   p_memsz;
308               uint32_t   p_flags;
309               uint32_t   p_align;
310           } Elf32_Phdr;
311
312           typedef struct {
313               uint32_t   p_type;
314               uint32_t   p_flags;
315               Elf64_Off  p_offset;
316               Elf64_Addr p_vaddr;
317               Elf64_Addr p_paddr;
318               uint64_t   p_filesz;
319               uint64_t   p_memsz;
320               uint64_t   p_align;
321           } Elf64_Phdr;
322
323       The  main  difference  between the 32-bit and the 64-bit program header
324       lies in the location of the p_flags member in the total struct.
325
326       p_type      This member of the Phdr struct tells what kind  of  segment
327                   this  array element describes or how to interpret the array
328                   element's information.
329
330                   PT_NULL     The array element is unused and the other  mem‐
331                               bers' values are undefined.  This lets the pro‐
332                               gram header have ignored entries.
333
334                   PT_LOAD     The array element specifies a loadable segment,
335                               described  by  p_filesz and p_memsz.  The bytes
336                               from the file are mapped to  the  beginning  of
337                               the  memory  segment.   If the segment's memory
338                               size p_memsz  is  larger  than  the  file  size
339                               p_filesz, the "extra" bytes are defined to hold
340                               the value 0 and to follow  the  segment's  ini‐
341                               tialized area.  The file size may not be larger
342                               than the memory size.  Loadable segment entries
343                               in the program header table appear in ascending
344                               order, sorted on the p_vaddr member.
345
346                   PT_DYNAMIC  The array  element  specifies  dynamic  linking
347                               information.
348
349                   PT_INTERP   The  array  element  specifies the location and
350                               size of a null-terminated pathname to invoke as
351                               an  interpreter.  This segment type is meaning‐
352                               ful only for executable files  (though  it  may
353                               occur  for shared objects).  However it may not
354                               occur more than once  in  a  file.   If  it  is
355                               present,  it  must precede any loadable segment
356                               entry.
357
358                   PT_NOTE     The array element specifies  the  location  and
359                               size for auxiliary information.
360
361                   PT_SHLIB    This  segment type is reserved but has unspeci‐
362                               fied semantics.  Programs that contain an array
363                               element of this type do not conform to the ABI.
364
365                   PT_PHDR     The  array  element,  if present, specifies the
366                               location and size of the program  header  table
367                               itself,  both  in  the  file  and in the memory
368                               image of the program.  This  segment  type  may
369                               not  occur more than once in a file.  Moreover,
370                               it may occur only if the program  header  table
371                               is part of the memory image of the program.  If
372                               it is present, it  must  precede  any  loadable
373                               segment entry.
374
375                   PT_LOPROC   Values  greater  than or equal to PT_HIPROC are
376                               reserved for processor-specific semantics.
377
378                   PT_HIPROC   Values less than  or  equal  to  PT_LOPROC  are
379                               reserved for processor-specific semantics.
380
381                   PT_GNU_STACK
382                               GNU extension which is used by the Linux kernel
383                               to control the state of the stack via the flags
384                               set in the p_flags member.
385
386       p_offset    This member holds the offset from the beginning of the file
387                   at which the first byte of the segment resides.
388
389       p_vaddr     This member holds the virtual address at  which  the  first
390                   byte of the segment resides in memory.
391
392       p_paddr     On  systems for which physical addressing is relevant, this
393                   member is reserved  for  the  segment's  physical  address.
394                   Under BSD this member is not used and must be zero.
395
396       p_filesz    This  member holds the number of bytes in the file image of
397                   the segment.  It may be zero.
398
399       p_memsz     This member holds the number of bytes in the  memory  image
400                   of the segment.  It may be zero.
401
402       p_flags     This  member holds a bit mask of flags relevant to the seg‐
403                   ment:
404
405                   PF_X   An executable segment.
406                   PF_W   A writable segment.
407                   PF_R   A readable segment.
408
409                   A text segment commonly has the flags  PF_X  and  PF_R.   A
410                   data segment commonly has PF_X, PF_W and PF_R.
411
412       p_align     This  member  holds  the  value  to  which the segments are
413                   aligned in memory and in the file.  Loadable  process  seg‐
414                   ments  must have congruent values for p_vaddr and p_offset,
415                   modulo the page size.  Values  of  zero  and  one  mean  no
416                   alignment is required.  Otherwise, p_align should be a pos‐
417                   itive, integral power of  two,  and  p_vaddr  should  equal
418                   p_offset, modulo p_align.
419
420       A  file's section header table lets one locate all the file's sections.
421       The section header table is an array of Elf32_Shdr or Elf64_Shdr struc‐
422       tures.   The ELF header's e_shoff member gives the byte offset from the
423       beginning of the file to the section header table.  e_shnum  holds  the
424       number of entries the section header table contains.  e_shentsize holds
425       the size in bytes of each entry.
426
427       A section header table index is a subscript into this array.  Some sec‐
428       tion  header  table  indices  are  reserved:  the initial entry and the
429       indices between SHN_LORESERVE and SHN_HIRESERVE.  The initial entry  is
430       used  in  ELF  extensions  for  e_phnum, e_shnum and e_strndx; in other
431       cases, each field in the initial entry is set to zero.  An object  file
432       does not have sections for these special indices:
433
434              SHN_UNDEF     This value marks an undefined, missing, irrelevant
435                            or otherwise meaningless section reference.
436
437              SHN_LORESERVE This value specifies the lower bound of the  range
438                            of reserved indices.
439
440              SHN_LOPROC    Values  greater  than  or  equal to SHN_HIPROC are
441                            reserved for processor-specific semantics.
442
443              SHN_HIPROC    Values  less  than  or  equal  to  SHN_LOPROC  are
444                            reserved for processor-specific semantics.
445
446              SHN_ABS       This  value  specifies  the absolute value for the
447                            corresponding reference.  For  example,  a  symbol
448                            defined  relative to section number SHN_ABS has an
449                            absolute value and is not affected by relocation.
450
451              SHN_COMMON    Symbols defined relative to this section are  com‐
452                            mon symbols, such as FORTRAN COMMON or unallocated
453                            C external variables.
454
455              SHN_HIRESERVE This value specifies the upper bound of the  range
456                            of  reserved indices.  The system reserves indices
457                            between SHN_LORESERVE  and  SHN_HIRESERVE,  inclu‐
458                            sive.   The  section header table does not contain
459                            entries for the reserved indices.
460
461       The section header has the following structure:
462
463           typedef struct {
464               uint32_t   sh_name;
465               uint32_t   sh_type;
466               uint32_t   sh_flags;
467               Elf32_Addr sh_addr;
468               Elf32_Off  sh_offset;
469               uint32_t   sh_size;
470               uint32_t   sh_link;
471               uint32_t   sh_info;
472               uint32_t   sh_addralign;
473               uint32_t   sh_entsize;
474           } Elf32_Shdr;
475
476           typedef struct {
477               uint32_t   sh_name;
478               uint32_t   sh_type;
479               uint64_t   sh_flags;
480               Elf64_Addr sh_addr;
481               Elf64_Off  sh_offset;
482               uint64_t   sh_size;
483               uint32_t   sh_link;
484               uint32_t   sh_info;
485               uint64_t   sh_addralign;
486               uint64_t   sh_entsize;
487           } Elf64_Shdr;
488
489       No real differences exist between the 32-bit and 64-bit  section  head‐
490       ers.
491
492       sh_name   This  member specifies the name of the section.  Its value is
493                 an index into the section header string table section, giving
494                 the location of a null-terminated string.
495
496       sh_type   This member categorizes the section's contents and semantics.
497
498                 SHT_NULL       This  value  marks the section header as inac‐
499                                tive.  It does not have an associated section.
500                                Other members of the section header have unde‐
501                                fined values.
502
503                 SHT_PROGBITS   This section holds information defined by  the
504                                program,  whose  format and meaning are deter‐
505                                mined solely by the program.
506
507                 SHT_SYMTAB     This section holds a symbol table.  Typically,
508                                SHT_SYMTAB  provides symbols for link editing,
509                                though it may also be used for  dynamic  link‐
510                                ing.   As a complete symbol table, it may con‐
511                                tain  many  symbols  unnecessary  for  dynamic
512                                linking.   An  object  file can also contain a
513                                SHT_DYNSYM section.
514
515                 SHT_STRTAB     This section holds a string table.  An  object
516                                file may have multiple string table sections.
517
518                 SHT_RELA       This  section  holds  relocation  entries with
519                                explicit addends, such as type Elf32_Rela  for
520                                the  32-bit  class of object files.  An object
521                                may have multiple relocation sections.
522
523                 SHT_HASH       This section holds a symbol  hash  table.   An
524                                object  participating  in dynamic linking must
525                                contain a symbol hash table.  An  object  file
526                                may have only one hash table.
527
528                 SHT_DYNAMIC    This  section  holds  information  for dynamic
529                                linking.  An object file  may  have  only  one
530                                dynamic section.
531
532                 SHT_NOTE       This  section holds information that marks the
533                                file in some way.
534
535                 SHT_NOBITS     A section of this type occupies  no  space  in
536                                the file but otherwise resembles SHT_PROGBITS.
537                                Although this section contains no  bytes,  the
538                                sh_offset  member contains the conceptual file
539                                offset.
540
541                 SHT_REL        This section holds relocation offsets  without
542                                explicit  addends,  such as type Elf32_Rel for
543                                the 32-bit class of object files.   An  object
544                                file may have multiple relocation sections.
545
546                 SHT_SHLIB      This  section  is reserved but has unspecified
547                                semantics.
548
549                 SHT_DYNSYM     This section holds a minimal  set  of  dynamic
550                                linking symbols.  An object file can also con‐
551                                tain a SHT_SYMTAB section.
552
553                 SHT_LOPROC     This value up to and including  SHT_HIPROC  is
554                                reserved for processor-specific semantics.
555
556                 SHT_HIPROC     This value down to and including SHT_LOPROC is
557                                reserved for processor-specific semantics.
558
559                 SHT_LOUSER     This value specifies the lower  bound  of  the
560                                range of indices reserved for application pro‐
561                                grams.
562
563                 SHT_HIUSER     This value specifies the upper  bound  of  the
564                                range of indices reserved for application pro‐
565                                grams.  Section types between  SHT_LOUSER  and
566                                SHT_HIUSER  may  be  used  by the application,
567                                without conflicting  with  current  or  future
568                                system-defined section types.
569
570       sh_flags  Sections  support  one-bit  flags that describe miscellaneous
571                 attributes.  If a flag bit is set in sh_flags, the  attribute
572                 is  "on"  for the section.  Otherwise, the attribute is "off"
573                 or does not apply.  Undefined attributes are set to zero.
574
575                 SHF_WRITE      This section  contains  data  that  should  be
576                                writable during process execution.
577
578                 SHF_ALLOC      This  section  occupies  memory during process
579                                execution.   Some  control  sections  do   not
580                                reside  in the memory image of an object file.
581                                This attribute is off for those sections.
582
583                 SHF_EXECINSTR  This  section  contains   executable   machine
584                                instructions.
585
586                 SHF_MASKPROC   All  bits  included  in this mask are reserved
587                                for processor-specific semantics.
588
589       sh_addr   If this section appears in the memory  image  of  a  process,
590                 this  member  holds  the address at which the section's first
591                 byte should reside.  Otherwise, the member contains zero.
592
593       sh_offset This member's value holds the byte offset from the  beginning
594                 of  the  file  to the first byte in the section.  One section
595                 type, SHT_NOBITS, occupies no space  in  the  file,  and  its
596                 sh_offset  member  locates  the  conceptual  placement in the
597                 file.
598
599       sh_size   This member holds the section's size in  bytes.   Unless  the
600                 section  type  is  SHT_NOBITS,  the  section occupies sh_size
601                 bytes in the file.  A section of type SHT_NOBITS may  have  a
602                 nonzero size, but it occupies no space in the file.
603
604       sh_link   This  member  holds  a section header table index link, whose
605                 interpretation depends on the section type.
606
607       sh_info   This member holds  extra  information,  whose  interpretation
608                 depends on the section type.
609
610       sh_addralign
611                 Some  sections have address alignment constraints.  If a sec‐
612                 tion holds a doubleword, the system  must  ensure  doubleword
613                 alignment  for  the  entire  section.   That is, the value of
614                 sh_addr must be  congruent  to  zero,  modulo  the  value  of
615                 sh_addralign.   Only zero and positive integral powers of two
616                 are allowed.  Values of zero or one mean the section  has  no
617                 alignment constraints.
618
619       sh_entsize
620                 Some  sections hold a table of fixed-sized entries, such as a
621                 symbol table.  For such a section, this member gives the size
622                 in  bytes  for  each entry.  This member contains zero if the
623                 section does not hold a table of fixed-size entries.
624
625       Various sections hold program and control information:
626
627       .bss      This section holds uninitialized data that contributes to the
628                 program's  memory  image.  By definition, the system initial‐
629                 izes the data with zeros when  the  program  begins  to  run.
630                 This  section is of type SHT_NOBITS.  The attribute types are
631                 SHF_ALLOC and SHF_WRITE.
632
633       .comment  This section holds version control information.  This section
634                 is of type SHT_PROGBITS.  No attribute types are used.
635
636       .ctors    This  section holds initialized pointers to the C++ construc‐
637                 tor functions.  This section is of  type  SHT_PROGBITS.   The
638                 attribute types are SHF_ALLOC and SHF_WRITE.
639
640       .data     This  section  holds  initialized data that contribute to the
641                 program's memory image.  This section is  of  type  SHT_PROG‐
642                 BITS.  The attribute types are SHF_ALLOC and SHF_WRITE.
643
644       .data1    This  section  holds  initialized data that contribute to the
645                 program's memory image.  This section is  of  type  SHT_PROG‐
646                 BITS.  The attribute types are SHF_ALLOC and SHF_WRITE.
647
648       .debug    This  section  holds information for symbolic debugging.  The
649                 contents are unspecified.  This section is of type  SHT_PROG‐
650                 BITS.  No attribute types are used.
651
652       .dtors    This section holds initialized pointers to the C++ destructor
653                 functions.   This  section  is  of  type  SHT_PROGBITS.   The
654                 attribute types are SHF_ALLOC and SHF_WRITE.
655
656       .dynamic  This  section  holds  dynamic  linking information.  The sec‐
657                 tion's attributes will include the  SHF_ALLOC  bit.   Whether
658                 the SHF_WRITE bit is set is processor-specific.  This section
659                 is of type SHT_DYNAMIC.  See the attributes above.
660
661       .dynstr   This section holds strings needed for dynamic  linking,  most
662                 commonly the strings that represent the names associated with
663                 symbol table entries.  This section is  of  type  SHT_STRTAB.
664                 The attribute type used is SHF_ALLOC.
665
666       .dynsym   This  section  holds  the dynamic linking symbol table.  This
667                 section  is  of  type  SHT_DYNSYM.   The  attribute  used  is
668                 SHF_ALLOC.
669
670       .fini     This section holds executable instructions that contribute to
671                 the process termination code.  When a program exits  normally
672                 the  system  arranges  to  execute  the code in this section.
673                 This section is of type SHT_PROGBITS.   The  attributes  used
674                 are SHF_ALLOC and SHF_EXECINSTR.
675
676       .gnu.version
677                 This  section  holds  the  version  symbol table, an array of
678                 ElfN_Half elements.  This section is of type  SHT_GNU_versym.
679                 The attribute type used is SHF_ALLOC.
680
681       .gnu.version_d
682                 This section holds the version symbol definitions, a table of
683                 ElfN_Verdef   structures.    This   section   is   of    type
684                 SHT_GNU_verdef.  The attribute type used is SHF_ALLOC.
685
686       .gnu.version_r
687                 This  section holds the version symbol needed elements, a ta‐
688                 ble of ElfN_Verneed structures.   This  section  is  of  type
689                 SHT_GNU_versym.  The attribute type used is SHF_ALLOC.
690
691       .got      This  section holds the global offset table.  This section is
692                 of type SHT_PROGBITS.  The attributes are processor specific.
693
694       .hash     This section holds a symbol hash table.  This section  is  of
695                 type SHT_HASH.  The attribute used is SHF_ALLOC.
696
697       .init     This section holds executable instructions that contribute to
698                 the process initialization code.  When a  program  starts  to
699                 run  the  system arranges to execute the code in this section
700                 before calling the main program entry point.  This section is
701                 of  type SHT_PROGBITS.  The attributes used are SHF_ALLOC and
702                 SHF_EXECINSTR.
703
704       .interp   This section holds the pathname of a program interpreter.  If
705                 the  file  has  a loadable segment that includes the section,
706                 the section's attributes  will  include  the  SHF_ALLOC  bit.
707                 Otherwise,  that  bit  will  be off.  This section is of type
708                 SHT_PROGBITS.
709
710       .line     This section  holds  line  number  information  for  symbolic
711                 debugging,  which  describes  the  correspondence between the
712                 program source  and  the  machine  code.   The  contents  are
713                 unspecified.   This  section  is  of  type  SHT_PROGBITS.  No
714                 attribute types are used.
715
716       .note     This section holds information in the "Note Section"  format.
717                 This  section  is  of  type SHT_NOTE.  No attribute types are
718                 used.   OpenBSD  native   executables   usually   contain   a
719                 .note.openbsd.ident  section  to identify themselves, for the
720                 kernel to bypass any compatibility ELF binary emulation tests
721                 when loading the file.
722
723       .note.GNU-stack
724                 This  section  is  used  in  Linux object files for declaring
725                 stack attributes.  This section is of type SHT_PROGBITS.  The
726                 only  attribute used is SHF_EXECINSTR.  This indicates to the
727                 GNU linker that the object file requires an executable stack.
728
729       .plt      This section holds the procedure linkage table.  This section
730                 is  of  type SHT_PROGBITS.  The attributes are processor spe‐
731                 cific.
732
733       .relNAME  This section holds relocation information as described below.
734                 If  the file has a loadable segment that includes relocation,
735                 the section's attributes  will  include  the  SHF_ALLOC  bit.
736                 Otherwise the bit will be off.  By convention, "NAME" is sup‐
737                 plied by the section to which the relocations apply.  Thus  a
738                 relocation  section  for  .text  normally would have the name
739                 .rel.text.  This section is of type SHT_REL.
740
741       .relaNAME This section holds relocation information as described below.
742                 If  the file has a loadable segment that includes relocation,
743                 the section's attributes  will  include  the  SHF_ALLOC  bit.
744                 Otherwise the bit will be off.  By convention, "NAME" is sup‐
745                 plied by the section to which the relocations apply.  Thus  a
746                 relocation  section  for  .text  normally would have the name
747                 .rela.text.  This section is of type SHT_RELA.
748
749       .rodata   This section holds read-only data that typically  contributes
750                 to  a nonwritable segment in the process image.  This section
751                 is of type SHT_PROGBITS.  The attribute used is SHF_ALLOC.
752
753       .rodata1  This section holds read-only data that typically  contributes
754                 to  a nonwritable segment in the process image.  This section
755                 is of type SHT_PROGBITS.  The attribute used is SHF_ALLOC.
756
757       .shstrtab This section holds section names.  This section  is  of  type
758                 SHT_STRTAB.  No attribute types are used.
759
760       .strtab   This  section  holds  strings, most commonly the strings that
761                 represent the names associated with symbol table entries.  If
762                 the  file  has  a  loadable  segment that includes the symbol
763                 string table,  the  section's  attributes  will  include  the
764                 SHF_ALLOC  bit.  Otherwise the bit will be off.  This section
765                 is of type SHT_STRTAB.
766
767       .symtab   This section holds a symbol table.  If the file has  a  load‐
768                 able  segment  that  includes the symbol table, the section's
769                 attributes will include the SHF_ALLOC bit.  Otherwise the bit
770                 will be off.  This section is of type SHT_SYMTAB.
771
772       .text     This section holds the "text", or executable instructions, of
773                 a program.   This  section  is  of  type  SHT_PROGBITS.   The
774                 attributes used are SHF_ALLOC and SHF_EXECINSTR.
775
776       String  table  sections  hold null-terminated character sequences, com‐
777       monly called strings.  The object file uses these strings to  represent
778       symbol and section names.  One references a string as an index into the
779       string table section.  The first byte, which is index zero, is  defined
780       to  hold  a null byte ('\0').  Similarly, a string table's last byte is
781       defined to hold a null byte, ensuring null termination for all strings.
782
783       An object file's symbol table holds information needed  to  locate  and
784       relocate a program's symbolic definitions and references.  A symbol ta‐
785       ble index is a subscript into this array.
786
787           typedef struct {
788               uint32_t      st_name;
789               Elf32_Addr    st_value;
790               uint32_t      st_size;
791               unsigned char st_info;
792               unsigned char st_other;
793               uint16_t      st_shndx;
794           } Elf32_Sym;
795
796           typedef struct {
797               uint32_t      st_name;
798               unsigned char st_info;
799               unsigned char st_other;
800               uint16_t      st_shndx;
801               Elf64_Addr    st_value;
802               uint64_t      st_size;
803           } Elf64_Sym;
804
805       The 32-bit and 64-bit versions have the same members, just in a differ‐
806       ent order.
807
808       st_name   This  member  holds  an  index  into the object file's symbol
809                 string table, which holds character  representations  of  the
810                 symbol  names.   If  the  value  is  nonzero, it represents a
811                 string table index that gives the  symbol  name.   Otherwise,
812                 the symbol table has no name.
813
814       st_value  This member gives the value of the associated symbol.
815
816       st_size   Many  symbols  have associated sizes.  This member holds zero
817                 if the symbol has no size or an unknown size.
818
819       st_info   This  member  specifies  the  symbol's   type   and   binding
820                 attributes:
821
822                 STT_NOTYPE  The symbol's type is not defined.
823
824                 STT_OBJECT  The symbol is associated with a data object.
825
826                 STT_FUNC    The symbol is associated with a function or other
827                             executable code.
828
829                 STT_SECTION The symbol is associated with a section.   Symbol
830                             table  entries  of  this type exist primarily for
831                             relocation and normally have STB_LOCAL bindings.
832
833                 STT_FILE    By convention, the symbol's name gives  the  name
834                             of  the  source  file  associated with the object
835                             file.  A file symbol has STB_LOCAL bindings,  its
836                             section  index  is  SHN_ABS,  and it precedes the
837                             other STB_LOCAL symbols of the  file,  if  it  is
838                             present.
839
840                 STT_LOPROC  This  value  up  to  and  including STT_HIPROC is
841                             reserved for processor-specific semantics.
842
843                 STT_HIPROC  This value down to and  including  STT_LOPROC  is
844                             reserved for processor-specific semantics.
845
846                 STB_LOCAL   Local  symbols are not visible outside the object
847                             file containing their definition.  Local  symbols
848                             of  the  same  name  may  exist in multiple files
849                             without interfering with each other.
850
851                 STB_GLOBAL  Global symbols are visible to  all  object  files
852                             being  combined.   One  file's  definition  of  a
853                             global symbol will satisfy another  file's  unde‐
854                             fined reference to the same symbol.
855
856                 STB_WEAK    Weak  symbols  resemble global symbols, but their
857                             definitions have lower precedence.
858
859                 STB_LOPROC  This value up  to  and  including  STB_HIPROC  is
860                             reserved for processor-specific semantics.
861
862                 STB_HIPROC  This  value  down  to and including STB_LOPROC is
863                             reserved for processor-specific semantics.
864
865                             There are macros for packing  and  unpacking  the
866                             binding and type fields:
867
868                             ELF32_ST_BIND(info)     or    ELF64_ST_BIND(info)
869                             extract a binding from an st_info value.
870
871                             ELF32_ST_TYPE(info) or ELF64_ST_TYPE(info)
872                             extract a type from an st_info value.
873
874                             ELF32_ST_INFO(bind, type) or  ELF64_ST_INFO(bind,
875                             type)
876                             convert  a  binding  and  a  type into an st_info
877                             value.
878
879       st_other  This member defines the symbol visibility.
880
881                 STV_DEFAULT     Default symbol visibility rules.
882                 STV_INTERNAL    Processor-specific hidden class.
883                 STV_HIDDEN      Symbol is unavailable in other modules.
884                 STV_PROTECTED   Not preemptible, not exported.
885
886                 There are macros for extracting the visibility type:
887
888                 ELF32_ST_VISIBILITY(other) or ELF64_ST_VISIBILITY(other)
889
890       st_shndx  Every symbol table entry is "defined"  in  relation  to  some
891                 section.  This member holds the relevant section header table
892                 index.
893
894       Relocation is the process of connecting symbolic references  with  sym‐
895       bolic  definitions.   Relocatable  files  must  have  information  that
896       describes how to modify their  section  contents,  thus  allowing  exe‐
897       cutable  and  shared  object  files to hold the right information for a
898       process's program image.  Relocation entries are these data.
899
900       Relocation structures that do not need an addend:
901
902           typedef struct {
903               Elf32_Addr r_offset;
904               uint32_t   r_info;
905           } Elf32_Rel;
906
907           typedef struct {
908               Elf64_Addr r_offset;
909               uint64_t   r_info;
910           } Elf64_Rel;
911
912       Relocation structures that need an addend:
913
914           typedef struct {
915               Elf32_Addr r_offset;
916               uint32_t   r_info;
917               int32_t    r_addend;
918           } Elf32_Rela;
919
920           typedef struct {
921               Elf64_Addr r_offset;
922               uint64_t   r_info;
923               int64_t    r_addend;
924           } Elf64_Rela;
925
926       r_offset    This member gives the location at which to apply the  relo‐
927                   cation  action.   For  a relocatable file, the value is the
928                   byte offset from the beginning of the section to the  stor‐
929                   age  unit  affected  by  the relocation.  For an executable
930                   file or shared object, the value is the virtual address  of
931                   the storage unit affected by the relocation.
932
933       r_info      This  member gives both the symbol table index with respect
934                   to which the relocation must be made and the type of  relo‐
935                   cation  to apply.  Relocation types are processor specific.
936                   When the text refers to  a  relocation  entry's  relocation
937                   type or symbol table index, it means the result of applying
938                   ELF[32|64]_R_TYPE or ELF[32|64]_R_SYM, respectively, to the
939                   entry's r_info member.
940
941       r_addend    This member specifies a constant addend used to compute the
942                   value to be stored into the relocatable field.
943
944       The .dynamic section contains a series of structures that hold relevant
945       dynamic linking information.  The d_tag member controls the interpreta‐
946       tion of d_un.
947
948           typedef struct {
949               Elf32_Sword    d_tag;
950               union {
951                   Elf32_Word d_val;
952                   Elf32_Addr d_ptr;
953               } d_un;
954           } Elf32_Dyn;
955           extern Elf32_Dyn _DYNAMIC[];
956
957           typedef struct {
958               Elf64_Sxword    d_tag;
959               union {
960                   Elf64_Xword d_val;
961                   Elf64_Addr  d_ptr;
962               } d_un;
963           } Elf64_Dyn;
964           extern Elf64_Dyn _DYNAMIC[];
965
966       d_tag     This member may have any of the following values:
967
968                 DT_NULL     Marks end of dynamic section
969
970                 DT_NEEDED   String table offset to name of a needed library
971
972                 DT_PLTRELSZ Size in bytes of PLT relocs
973
974                 DT_PLTGOT   Address of PLT and/or GOT
975
976                 DT_HASH     Address of symbol hash table
977
978                 DT_STRTAB   Address of string table
979
980                 DT_SYMTAB   Address of symbol table
981
982                 DT_RELA     Address of Rela relocs table
983
984                 DT_RELASZ   Size in bytes of Rela table
985
986                 DT_RELAENT  Size in bytes of a Rela table entry
987
988                 DT_STRSZ    Size in bytes of string table
989
990                 DT_SYMENT   Size in bytes of a symbol table entry
991
992                 DT_INIT     Address of the initialization function
993
994                 DT_FINI     Address of the termination function
995
996                 DT_SONAME   String table offset to name of shared object
997
998                 DT_RPATH    String table offset to library search path  (dep‐
999                             recated)
1000
1001                 DT_SYMBOLIC Alert  linker to search this shared object before
1002                             the executable for symbols
1003
1004                 DT_REL      Address of Rel relocs table
1005
1006                 DT_RELSZ    Size in bytes of Rel table
1007
1008                 DT_RELENT   Size in bytes of a Rel table entry
1009
1010                 DT_PLTREL   Type of reloc the PLT refers (Rela or Rel)
1011
1012                 DT_DEBUG    Undefined use for debugging
1013
1014                 DT_TEXTREL  Absence of this indicates no relocs should  apply
1015                             to a nonwritable segment
1016
1017                 DT_JMPREL   Address of reloc entries solely for the PLT
1018
1019                 DT_BIND_NOW Instruct  dynamic  linker  to  process all relocs
1020                             before transferring control to the executable
1021
1022                 DT_RUNPATH  String table offset to library search path
1023
1024                 DT_LOPROC   Start of processor-specific semantics
1025
1026                 DT_HIPROC   End of processor-specific semantics
1027
1028       d_val     This member represents integer values with various  interpre‐
1029                 tations.
1030
1031       d_ptr     This  member  represents  program  virtual  addresses.   When
1032                 interpreting these addresses, the actual  address  should  be
1033                 computed  based  on  the  original file value and memory base
1034                 address.  Files do not contain relocation  entries  to  fixup
1035                 these addresses.
1036
1037       _DYNAMIC  Array  containing  all the dynamic structures in the .dynamic
1038                 section.  This is automatically populated by the linker.
1039

NOTES

1041       ELF first appeared in System V.  The ELF format is an adopted standard.
1042
1043       The extensions for e_phnum, e_shnum and e_strndx respectively are Linux
1044       extensions.  Sun, BSD and AMD64 also support them; for further informa‐
1045       tion, look under SEE ALSO.
1046

COLOPHON

1063       This page is part of release 3.53 of the Linux  man-pages  project.   A
1064       description  of  the project, and information about reporting bugs, can
1065       be found at http://www.kernel.org/doc/man-pages/.
1066
1067
1068
1069Linux                             2013-04-17                            ELF(5)