Decompile a NASM hello world and understand every byte in it
Version of this answer with a nice TOC and more content: http://www.cirosantilli.com/elf-hello-world (hitting the 30k char limit here)
Standards
ELF is specified by the LSB:
- core generic: http://refspecs.linuxfoundation.org/LSB_4.1.0/LSB-Core-generic/LSB-Core-generic/elf-generic.html
- core AMD64: http://refspecs.linuxfoundation.org/LSB_4.1.0/LSB-Core-AMD64/LSB-Core-AMD64/book1.html
The LSB basically links to other standards with minor extensions, in particular:
generic (both by SCO):
- System V ABI 4.1 (1997) http://www.sco.com/developers/devspecs/gabi41.pdf, no 64 bit, although a magic number is reserved for it. Same for core files.
- System V ABI Update DRAFT 17 (2003) http://www.sco.com/developers/gabi/2003-12-17/contents.html, adds 64 bit. Only updates chapters 4 and 5 of the previous document: the others remain valid and are still referenced.
architecture specific:
- IA-32: http://refspecs.linuxfoundation.org/LSB_4.1.0/LSB-Core-IA32/LSB-Core-IA32/elf-ia32.html, points mostly to http://www.sco.com/developers/devspecs/abi386-4.pdf
- AMD64: http://refspecs.linuxfoundation.org/LSB_4.1.0/LSB-Core-AMD64/LSB-Core-AMD64/elf-amd64.html, points mostly to http://www.x86-64.org/documentation/abi.pdf
A handy summary can be found at:
man elf
Its structure can be examined in a human readable way via utilities like readelf
and objdump
.
Generate the example
Let's break down a minimal runnable Linux x86-64 example:
section .data
hello_world db "Hello world!", 10
hello_world_len equ $ - hello_world
section .text
global _start
_start:
mov rax, 1
mov rdi, 1
mov rsi, hello_world
mov rdx, hello_world_len
syscall
mov rax, 60
mov rdi, 0
syscall
Compiled with:
nasm -w+all -f elf64 -o 'hello_world.o' 'hello_world.asm'
ld -o 'hello_world.out' 'hello_world.o'
Versions:
- NASM 2.10.09
- Binutils version 2.24 (contains
ld
)
- Ubuntu 14.04
We don't use a C program as that would complicate the analysis, that will be level 2 :-)
Hexdumps
hd hello_world.o
hd hello_world.out
Output at: https://gist.github.com/cirosantilli/7b03f6df2d404c0862c6
Global file structure
An ELF file contains the following parts:
ELF header. Points to the position of the section header table and the program header table.
Section header table (optional on executable). Each has e_shnum
section headers, each pointing to the position of a section.
N sections, with N <= e_shnum
(optional on executable)
Program header table (only on executable). Each has e_phnum
program headers, each pointing to the position of a segment.
N segments, with N <= e_phnum
(optional on executable)
The order of those parts is not fixed: the only fixed thing is the ELF header that must be the first thing on the file: Generic docs say:
ELF header
The easiest way to observe the header is:
readelf -h hello_world.o
readelf -h hello_world.out
Output at: https://gist.github.com/cirosantilli/7b03f6df2d404c0862c6
Bytes in the object file:
00000000 7f 45 4c 46 02 01 01 00 00 00 00 00 00 00 00 00 |.ELF............|
00000010 01 00 3e 00 01 00 00 00 00 00 00 00 00 00 00 00 |..>.............|
00000020 00 00 00 00 00 00 00 00 40 00 00 00 00 00 00 00 |........@.......|
00000030 00 00 00 00 40 00 00 00 00 00 40 00 07 00 03 00 |....@.....@.....|
Executable:
00000000 7f 45 4c 46 02 01 01 00 00 00 00 00 00 00 00 00 |.ELF............|
00000010 02 00 3e 00 01 00 00 00 b0 00 40 00 00 00 00 00 |..>.......@.....|
00000020 40 00 00 00 00 00 00 00 10 01 00 00 00 00 00 00 |@...............|
00000030 00 00 00 00 40 00 38 00 02 00 40 00 06 00 03 00 |....@.8...@.....|
Structure represented:
typedef struct {
unsigned char e_ident[EI_NIDENT];
Elf64_Half e_type;
Elf64_Half e_machine;
Elf64_Word e_version;
Elf64_Addr e_entry;
Elf64_Off e_phoff;
Elf64_Off e_shoff;
Elf64_Word e_flags;
Elf64_Half e_ehsize;
Elf64_Half e_phentsize;
Elf64_Half e_phnum;
Elf64_Half e_shentsize;
Elf64_Half e_shnum;
Elf64_Half e_shstrndx;
} Elf64_Ehdr;
Manual breakdown:
0 0: EI_MAG
= 7f 45 4c 46
= 0x7f 'E', 'L', 'F'
: ELF magic number
0 4: EI_CLASS
= 02
= ELFCLASS64
: 64 bit elf
0 5: EI_DATA
= 01
= ELFDATA2LSB
: big endian data
0 6: EI_VERSION
= 01
: format version
0 7: EI_OSABI
(only in 2003 Update) = 00
= ELFOSABI_NONE
: no extensions.
0 8: EI_PAD
= 8x 00
: reserved bytes. Must be set to 0.
1 0: e_type
= 01 00
= 1 (big endian) = ET_REl
: relocatable format
On the executable it is 02 00
for ET_EXEC
.
1 2: e_machine
= 3e 00
= 62
= EM_X86_64
: AMD64 architecture
1 4: e_version
= 01 00 00 00
: must be 1
1 8: e_entry
= 8x 00
: execution address entry point, or 0 if not applicable like for the object file since there is no entry point.
On the executable, it is b0 00 40 00 00 00 00 00
. TODO: what else can we set this to? The kernel seems to put the IP directly on that value, it is not hardcoded.
2 0: e_phoff
= 8x 00
: program header table offset, 0 if not present.
40 00 00 00
on the executable, i.e. it starts immediately after the ELF header.
2 8: e_shoff
= 40
7x 00
= 0x40
: section header table file offset, 0 if not present.
3 0: e_flags
= 00 00 00 00
TODO. Arch specific.
3 4: e_ehsize
= 40 00
: size of this elf header. TODO why this field? How can it vary?
3 6: e_phentsize
= 00 00
: size of each program header, 0 if not present.
38 00
on executable: it is 56 bytes long
3 8: e_phnum
= 00 00
: number of program header entries, 0 if not present.
02 00
on executable: there are 2 entries.
3 A: e_shentsize
and e_shnum
= 40 00 07 00
: section header size and number of entries
3 E: e_shstrndx
(Section Header STRing iNDeX
) = 03 00
: index of the .shstrtab
section.
Section header table
Array of Elf64_Shdr
structs.
Each entry contains metadata about a given section.
e_shoff
of the ELF header gives the starting position, 0x40 here.
e_shentsize
and e_shnum
from the ELF header say that we have 7 entries, each 0x40
bytes long.
So the table takes bytes from 0x40 to 0x40 + 7 + 0x40 - 1
= 0x1FF.
Some section names are reserved for certain section types: http://www.sco.com/developers/gabi/2003-12-17/ch4.sheader.html#special_sections e.g. .text
requires a SHT_PROGBITS
type and SHF_ALLOC
+ SHF_EXECINSTR
readelf -S hello_world.o
:
There are 7 section headers, starting at offset 0x40:
Section Headers:
[Nr] Name Type Address Offset
Size EntSize Flags Link Info Align
[ 0] NULL 0000000000000000 00000000
0000000000000000 0000000000000000 0 0 0
[ 1] .data PROGBITS 0000000000000000 00000200
000000000000000d 0000000000000000 WA 0 0 4
[ 2] .text PROGBITS 0000000000000000 00000210
0000000000000027 0000000000000000 AX 0 0 16
[ 3] .shstrtab STRTAB 0000000000000000 00000240
0000000000000032 0000000000000000 0 0 1
[ 4] .symtab SYMTAB 0000000000000000 00000280
00000000000000a8 0000000000000018 5 6 4
[ 5] .strtab STRTAB 0000000000000000 00000330
0000000000000034 0000000000000000 0 0 1
[ 6] .rela.text RELA 0000000000000000 00000370
0000000000000018 0000000000000018 4 2 4
Key to Flags:
W (write), A (alloc), X (execute), M (merge), S (strings), l (large)
I (info), L (link order), G (group), T (TLS), E (exclude), x (unknown)
O (extra OS processing required) o (OS specific), p (processor specific)
struct
represented by each entry:
typedef struct {
Elf64_Word sh_name;
Elf64_Word sh_type;
Elf64_Xword sh_flags;
Elf64_Addr sh_addr;
Elf64_Off sh_offset;
Elf64_Xword sh_size;
Elf64_Word sh_link;
Elf64_Word sh_info;
Elf64_Xword sh_addralign;
Elf64_Xword sh_entsize;
} Elf64_Shdr;
Sections
Index 0 section
Contained in bytes 0x40 to 0x7F.
The first section is always magic: http://www.sco.com/developers/gabi/2003-12-17/ch4.sheader.html says:
If the number of sections is greater than or equal to SHN_LORESERVE (0xff00), e_shnum has the value SHN_UNDEF (0) and the actual number of section header table entries is contained in the sh_size field of the section header at index 0 (otherwise, the sh_size member of the initial entry contains 0).
There are also other magic sections detailed in Figure 4-7: Special Section Indexes
.
SHT_NULL
In index 0, SHT_NULL
is mandatory. Are there any other uses for it: What is the use of the SHT_NULL section in ELF? ?
.data section
.data
is section 1:
00000080 01 00 00 00 01 00 00 00 03 00 00 00 00 00 00 00 |................|
00000090 00 00 00 00 00 00 00 00 00 02 00 00 00 00 00 00 |................|
000000a0 0d 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 |................|
000000b0 04 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 |................|
80 0: sh_name
= 01 00 00 00
: index 1 in the .shstrtab
string table
Here, 1
says the name of this section starts at the first character of that section, and ends at the first NUL character, making up the string .data
.
.data
is one of the section names which has a predefined meaning http://www.sco.com/developers/gabi/2003-12-17/ch4.strtab.html
These sections hold initialized data that contribute to the program's memory image.
80 4: sh_type
= 01 00 00 00
: SHT_PROGBITS
: the section content is not specified by ELF, only by how the program interprets it. Normal since a .data
section.
80 8: sh_flags
= 03
7x 00
: SHF_ALLOC
and SHF_EXECINSTR
: http://www.sco.com/developers/gabi/2003-12-17/ch4.sheader.html#sh_flags, as required from a .data
section
90 0: sh_addr
= 8x 00
: in what virtual address the section will be placed during execution, 0
if not placed
90 8: sh_offset
= 00 02 00 00 00 00 00 00
= 0x200
: number of bytes from the start of the program to the first byte in this section
a0 0: sh_size
= 0d 00 00 00 00 00 00 00
If we take 0xD bytes starting at sh_offset
200, we see:
00000200 48 65 6c 6c 6f 20 77 6f 72 6c 64 21 0a 00 |Hello world!.. |
AHA! So our "Hello world!"
string is in the data section like we told it to be on the NASM.
Once we graduate from hd
, we will look this up like:
readelf -x .data hello_world.o
which outputs:
Hex dump of section '.data':
0x00000000 48656c6c 6f20776f 726c6421 0a Hello world!.
NASM sets decent properties for that section because it treats .data
magically: http://www.nasm.us/doc/nasmdoc7.html#section-7.9.2
Also note that this was a bad section choice: a good C compiler would put the string in .rodata
instead, because it is read-only and it would allow for further OS optimizations.
a0 8: sh_link
and sh_info
= 8x 0: do not apply to this section type. http://www.sco.com/developers/gabi/2003-12-17/ch4.sheader.html#special_sections
b0 0: sh_addralign
= 04
= TODO: why is this alignment necessary? Is it only for sh_addr
, or also for symbols inside sh_addr
?
b0 8: sh_entsize
= 00
= the section does not contain a table. If != 0, it means that the section contains a table of fixed size entries. In this file, we see from the readelf
output that this is the case for the .symtab
and .rela.text
sections.
.text section
Now that we've done one section manually, let's graduate and use the readelf -S
of the other sections.
[Nr] Name Type Address Offset
Size EntSize Flags Link Info Align
[ 2] .text PROGBITS 0000000000000000 00000210
0000000000000027 0000000000000000 AX 0 0 16
.text
is executable but not writable: if we try to write to it Linux segfaults. Let's see if we really have some code there:
objdump -d hello_world.o
gives:
hello_world.o: file format elf64-x86-64
Disassembly of section .text:
0000000000000000 <_start>:
0: b8 01 00 00 00 mov $0x1,%eax
5: bf 01 00 00 00 mov $0x1,%edi
a: 48 be 00 00 00 00 00 movabs $0x0,%rsi
11: 00 00 00
14: ba 0d 00 00 00 mov $0xd,%edx
19: 0f 05 syscall
1b: b8 3c 00 00 00 mov $0x3c,%eax
20: bf 00 00 00 00 mov $0x0,%edi
25: 0f 05 syscall
If we grep b8 01 00 00
on the hd
, we see that this only occurs at 00000210
, which is what the section says. And the Size is 27, which matches as well. So we must be talking about the right section.
This looks like the right code: a write
followed by an exit
.
The most interesting part is line a
which does:
movabs $0x0,%rsi
to pass the address of the string to the system call. Currently, the 0x0
is just a placeholder. After linking happens, it will be modified to contain:
4000ba: 48 be d8 00 60 00 00 movabs $0x6000d8,%rsi
This modification is possible because of the data of the .rela.text
section.
SHT_STRTAB
Sections with sh_type == SHT_STRTAB
are called string tables.
They hold a null separated array of strings.
Such sections are used by other sections when string names are to be used. The using section says:
- which string table they are using
- what is the index on the target string table where the string starts
So for example, we could have a string table containing: TODO: does it have to start with \0
?
Data: \0 a b c \0 d e f \0
Index: 0 1 2 3 4 5 6 7 8
And if another section wants to use the string d e f
, they have to point to index 5
of this section (letter d
).
Notable string table sections:
.shstrtab
Section type: sh_type == SHT_STRTAB
.
Common name: section header string table.
The section name .shstrtab
is reserved. The standard says:
This section holds section names.
This section gets pointed to by the e_shstrnd
field of the ELF header itself.
String indexes of this section are are pointed to by the sh_name
field of section headers, which denote strings.
This section does not have SHF_ALLOC
marked, so it will not appear on the executing program.
readelf -x .shstrtab hello_world.o
Gives:
Hex dump of section '.shstrtab':
0x00000000 002e6461 7461002e 74657874 002e7368 ..data..text..sh
0x00000010 73747274 6162002e 73796d74 6162002e strtab..symtab..
0x00000020 73747274 6162002e 72656c61 2e746578 strtab..rela.tex
0x00000030 7400 t.
The data in this section has a fixed format: http://www.sco.com/developers/gabi/2003-12-17/ch4.strtab.html
If we look at the names of other sections, we see that they all contain numbers, e.g. the .text
section is number 7
.
Then each string ends when the first NUL character is found, e.g. character 12
is \0
just after .text\0
.
.symtab
Section type: sh_type == SHT_SYMTAB
.
Common name: symbol table.
First the we note that:
For SHT_SYMTAB
sections, those numbers mean that:
- strings that give symbol names are in section 5,
.strtab
- the relocation data is in section 6,
.rela.text
A good high level tool to disassemble that section is:
nm hello_world.o
which gives:
0000000000000000 T _start
0000000000000000 d hello_world
000000000000000d a hello_world_len
This is however a high level view that omits some types of symbols and in which the symbol types . A more detailed disassembly can be obtained with:
readelf -s hello_world.o
which gives:
Symbol table '.symtab' contains 7 entries:
Num: Value Size Type Bind Vis Ndx Name
0: 0000000000000000 0 NOTYPE LOCAL DEFAULT UND
1: 0000000000000000 0 FILE LOCAL DEFAULT ABS hello_world.asm
2: 0000000000000000 0 SECTION LOCAL DEFAULT 1
3: 0000000000000000 0 SECTION LOCAL DEFAULT 2
4: 0000000000000000 0 NOTYPE LOCAL DEFAULT 1 hello_world
5: 000000000000000d 0 NOTYPE LOCAL DEFAULT ABS hello_world_len
6: 0000000000000000 0 NOTYPE GLOBAL DEFAULT 2 _start
The binary format of the table is documented at http://www.sco.com/developers/gabi/2003-12-17/ch4.symtab.html
The data is:
readelf -x .symtab hello_world.o
Which gives:
Hex dump of section '.symtab':
0x00000000 00000000 00000000 00000000 00000000 ................
0x00000010 00000000 00000000 01000000 0400f1ff ................
0x00000020 00000000 00000000 00000000 00000000 ................
0x00000030 00000000 03000100 00000000 00000000 ................
0x00000040 00000000 00000000 00000000 03000200 ................
0x00000050 00000000 00000000 00000000 00000000 ................
0x00000060 11000000 00000100 00000000 00000000 ................
0x00000070 00000000 00000000 1d000000 0000f1ff ................
0x00000080 0d000000 00000000 00000000 00000000 ................
0x00000090 2d000000 10000200 00000000 00000000 -...............
0x000000a0 00000000 00000000 ........
The entries are of type:
typedef struct {
Elf64_Word st_name;
unsigned char st_info;
unsigned char st_other;
Elf64_Half st_shndx;
Elf64_Addr st_value;
Elf64_Xword st_size;
} Elf64_Sym;
Like in the section table, the first entry is magical and set to a fixed meaningless values.
STT_FILE
Entry 1 has ELF64_R_TYPE == STT_FILE
. ELF64_R_TYPE
is continued inside of st_info
.
Byte analysis:
10 8: st_name
= 01000000
= character 1 in the .strtab
, which until the following \0
makes hello_world.asm
This piece of information file may be used by the linker to decide on which segment sections go.
10 12: st_info
= 04
Bits 0-3 = ELF64_R_TYPE
= Type = 4
= STT_FILE
: the main purpose of this entry is to use st_name
to indicate the name of the file which generated this object file.
Bits 4-7 = ELF64_ST_BIND
= Binding = 0
= STB_LOCAL
. Required value for STT_FILE
.
10 13: st_shndx
= Symbol Table Section header Index = f1ff
= SHN_ABS
. Required for STT_FILE
.
20 0: st_value
= 8x 00
: required for value for STT_FILE
20 8: st_size
= 8x 00
: no allocated size
Now from the readelf
, we interpret the others quickly.
STT_SECTION
There are two such entries, one pointing to .data
and the other to .text
(section indexes 1
and 2
).
Num: Value Size Type Bind Vis Ndx Name
2: 0000000000000000 0 SECTION LOCAL DEFAULT 1
3: 0000000000000000 0 SECTION LOCAL DEFAULT 2
TODO what is their purpose?
STT_NOTYPE
Then come the most important symbols:
Num: Value Size Type Bind Vis Ndx Name
4: 0000000000000000 0 NOTYPE LOCAL DEFAULT 1 hello_world
5: 000000000000000d 0 NOTYPE LOCAL DEFAULT ABS hello_world_len
6: 0000000000000000 0 NOTYPE GLOBAL DEFAULT 2 _start
hello_world
string is in the .data
section (index 1). It's value is 0: it points to the first byte of that section.
_start
is marked with GLOBAL
visibility since we wrote:
global _start
in NASM. This is necessary since it must be seen as the entry point. Unlike in C, by default NASM labels are local.
SHN_ABS
hello_world_len
points to the special st_shndx == SHN_ABS == 0xF1FF
.
0xF1FF
is chosen so as to not conflict with other sections.
st_value == 0xD == 13
which is the value we have stored there on the assembly: the length of the string Hello World!
.
This means that relocation will not affect this value: it is a constant.
This is small optimization that our assembler does for us and which has ELF support.
If we had used the address of hello_world_len
anywhere, the assembler would not have been able to mark it as SHN_ABS
, and the linker would have extra relocation work on it later.
SHT_SYMTAB on the executable
By default, NASM places a .symtab
on the executable as well.
This is only used for debugging. Without the symbols, we are completely blind, and must reverse engineer everything.
You can strip it with objcopy
, and the executable will still run. Such executables are called stripped executables.
.strtab
Holds strings for the symbol table.
This section has sh_type == SHT_STRTAB
.
It is pointed to by sh_link == 5
of the .symtab
section.
readelf -x .strtab hello_world.o
Gives:
Hex dump of section '.strtab':
0x00000000 0068656c 6c6f5f77 6f726c64 2e61736d .hello_world.asm
0x00000010 0068656c 6c6f5f77 6f726c64 0068656c .hello_world.hel
0x00000020 6c6f5f77 6f726c64 5f6c656e 005f7374 lo_world_len._st
0x00000030 61727400 art.
This implies that it is an ELF level limitation that global variables cannot contain NUL characters.
.rela.text
Section type: sh_type == SHT_RELA
.
Common name: relocation section.
.rela.text
holds relocation data which says how the address should be modified when the final executable is linked. This points to bytes of the text area that must be modified when linking happens to point to the correct memory locations.
Basically, it translates the object text containing the placeholder 0x0 address:
a: 48 be 00 00 00 00 00 movabs $0x0,%rsi
11: 00 00 00
to the actual executable code containing the final 0x6000d8:
4000ba: 48 be d8 00 60 00 00 movabs $0x6000d8,%rsi
4000c1: 00 00 00
It was pointed to by sh_info
= 6
of the .symtab
section.
readelf -r hello_world.o
gives:
Relocation section '.rela.text' at offset 0x3b0 contains 1 entries:
Offset Info Type Sym. Value Sym. Name + Addend
00000000000c 000200000001 R_X86_64_64 0000000000000000 .data + 0
The section does not exist in the executable.
The actual bytes are:
00000370 0c 00 00 00 00 00 00 00 01 00 00 00 02 00 00 00 |................|
00000380 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 |................|
The struct
represented is:
typedef struct {
Elf64_Addr r_offset;
Elf64_Xword r_info;
Elf64_Sxword r_addend;
} Elf64_Rela;
So:
370 0: r_offset
= 0xC: address into the .text
whose address this relocation will modify
370 8: r_info
= 0x200000001. Contains 2 fields:
ELF64_R_TYPE
= 0x1: meaning depends on the exact architecture.
ELF64_R_SYM
= 0x2: index of the section to which the address points, so .data
which is at index 2.
The AMD64 ABI says that type 1
is called R_X86_64_64
and that it represents the operation S + A
where:
S
: the value of the symbol on the object file, here 0
because we point to the 00 00 00 00 00 00 00 00
of movabs $0x0,%rsi
A
: the addend, present in field r_added
This address is added to the section on which the relocation operates.
This relocation operation acts on a total 8 bytes.
380 0: r_addend
= 0
So in our example we conclude that the new address will be: S + A
= .data + 0
, and thus the first thing in the data section.
Program header table
Only appears in the executable.
Contains information of how the executable should be put into the process virtual memory.
The executable is generated from object files by the linker. The main jobs that the linker does are:
determine which sections of the object files will go into which segments of the executable.
In Binutils, this comes down to parsing a linker script, and dealing with a bunch of defaults.
You can get the linker script used with ld --verbose
, and set a custom one with ld -T
.
do relocation on text sections. This depends on how the multiple sections are put into memory.
readelf -l hello_world.out
gives:
Elf file type is EXEC (Executable file)
Entry point 0x4000b0
There are 2 program headers, starting at offset 64
Program Headers:
Type Offset VirtAddr PhysAddr
FileSiz MemSiz Flags Align
LOAD 0x0000000000000000 0x0000000000400000 0x0000000000400000
0x00000000000000d7 0x00000000000000d7 R E 200000
LOAD 0x00000000000000d8 0x00000000006000d8 0x00000000006000d8
0x000000000000000d 0x000000000000000d RW 200000
Section to Segment mapping:
Segment Sections...
00 .text
01 .data
On the ELF header, e_phoff
, e_phnum
and e_phentsize
told us that there are 2 program headers, which start at 0x40
and are 0x38
bytes long each, so they are:
00000040 01 00 00 00 05 00 00 00 00 00 00 00 00 00 00 00 |................|
00000050 00 00 40 00 00 00 00 00 00 00 40 00 00 00 00 00 |..@.......@.....|
00000060 d7 00 00 00 00 00 00 00 d7 00 00 00 00 00 00 00 |................|
00000070 00 00 20 00 00 00 00 00 |.. ..... |
and:
00000070 01 00 00 00 06 00 00 00 | ........|
00000080 d8 00 00 00 00 00 00 00 d8 00 60 00 00 00 00 00 |..........`.....|
00000090 d8 00 60 00 00 00 00 00 0d 00 00 00 00 00 00 00 |..`.............|
000000a0 0d 00 00 00 00 00 00 00 00 00 20 00 00 00 00 00 |.......... .....|
Structure represented http://www.sco.com/developers/gabi/2003-12-17/ch5.pheader.html:
typedef struct {
Elf64_Word p_type;
Elf64_Word p_flags;
Elf64_Off p_offset;
Elf64_Addr p_vaddr;
Elf64_Addr p_paddr;
Elf64_Xword p_filesz;
Elf64_Xword p_memsz;
Elf64_Xword p_align;
} Elf64_Phdr;
Breakdown of the first one:
- 40 0:
p_type
= 01 00 00 00
= PT_LOAD
: TODO. I think it means it will be actually loaded into memory. Other types may not necessarily be.
- 40 4:
p_flags
= 05 00 00 00
= execute and read permissions, no write TODO
- 40 8:
p_offset
= 8x 00
TODO: what is this? Looks like offsets from the beginning of segments. But this would mean that some segments are intertwined? It is possible to play with it a bit with: gcc -Wl,-Ttext-segment=0x400030 hello_world.c
- 50 0:
p_vaddr
= 00 00 40 00 00 00 00 00
: initial virtual memory address to load this segment to
- 50 8:
p_paddr
= 00 00 40 00 00 00 00 00
: initial physical address to load in memory. Only matters for systems in which the program can set it's physical address. Otherwise, as in System V like systems, can be anything. NASM seems to just copy p_vaddrr
- 60 0:
p_filesz
= d7 00 00 00 00 00 00 00
: TODO vs p_memsz
- 60 8:
p_memsz
= d7 00 00 00 00 00 00 00
: TODO
- 70 0:
p_align
= 00 00 20 00 00 00 00 00
: 0 or 1 mean no alignment required TODO what does that mean? otherwise redundant with other fields
The second is analogous.
Then the:
Section to Segment mapping:
section of the readelf
tells us that:
- 0 is the
.text
segment. Aha, so this is why it is executable, and not writable
- 1 is the
.data
segment.