I'm new to assembly and from what I learned the .code is same with .text, but the code below will crash using the .code.

segment .data
    msg db "hello, world", 0xa
    len equ $ - msg

section .text
    global _start

    mov edx, len
    mov ecx, msg

    mov ebx, 1
    mov eax, 4
    int 0x80

    mov ebx, 0
    mov eax, 1
    int 0x80

nasm -f elf64 -o hello.o hello.s 
ld -s -o hello hello.o
hello, world

sed -i s/.text/.code/ ./hello.s
nasm -f elf64 -o hello.o hello.s 
ld -s -o hello hello.o
./stack.sh: line 8:  4621 Segmentation fault      (core dumped) ./hello

Actually, I don't think it's different. Why this happen ?

  • 2
    You learned it wrong. In nasm .code is not recognized. See the manual. Notice in particular that unrecognized sections are noexec.
    – Jester
    Apr 14, 2021 at 0:41
  • section .text is the NASM / Linux equivalent of Windows MASM .code, i.e. where you put your instructions. section .code doesn't actually do what you want in NASM. Apr 14, 2021 at 3:40

1 Answer 1


On Linux with the standard toolchain (GNU Binutils ld), .text is a "special" section name that gets special treatment (exec permission by default), but .code isn't. (Other special sections include .data (writeable) and .bss (writable nobits), and all with a default alignment > 1.)

section .text is the NASM ELF/Linux equivalent of Windows MASM .code directive, but that does not mean that Linux tools recognize a .code directive or section name1.

section .code is no different from section xyz123; it just uses the defaults which are noexec nowrite. See the other entry at the bottom of the table in the NASM docs.

Use readelf -a hello to see the section (linking) and segment (program-loader) attributes, with a distinct lack of an X anywhere.

Footnote 1: In fact, I think Windows executables still use the actual section name .text. At least GNU objdump -d still says the code is in the .text section. So the MASM .code directive is a shortcut for switching to the .text section.

Fun fact: this does happen to run correctly "by accident" if you build it as 32-bit code (which you should because it's using only 32-bit int 0x80 system calls), like in this case that used section .code when incorrectly porting from 16-bit MASM code to Linux NASM.
Or if you'd run your 64-bit code on an older kernel.

The reason is that without explicitly specifying a PT_GNU_STACK note, the kernel uses backwards-compat assumptions for 32-bit executables and uses READ_IMPLIES_EXEC which affects every single page: Linux default behavior of executable .data section changed between 5.4 and 5.9?. Older kernels do this even for 64-bit executables, newer kernels only make the stack itself executable in this case.

Adding section .note.GNU-stack noalloc noexec nowrite progbits to your source makes it segfault as it should, even when build into a 32-bit executable. (nasm -felf32 / ld -melf_i386 -o foo foo.o). See this answer.

See also Unexpected exec permission from mmap when assembly files included in the project about the old situation.

  • 1
    Side note: Peter, if you haven't already seen this one: stackoverflow.com/questions/67098983/… you're gonna love it. For content/questions. And, OP's question is as detailed as one of your answers. And, the formatting style looks very much like one of your answers. Apr 14, 2021 at 22:10

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.