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I'm learning assembly programming. Below is the simple program that prints 'Hello, World!'. While the program runs perfectly, I'm getting the warning message while loading

ld: warning: cannot find entry symbol _start; defaulting to 0000000008048080

Here is the code :

section .data
    msg db 'Hello, world!', 0xa
    len equ $ - msg

section .text
    global main

main:

    mov ebx, 1
    mov ecx, msg
    mov edx, len
    mov eax, 4
    int 0x80

    mov eax, 1
    int 0x80

Can anybody explain the meaning of this warning. I'm using nasm with ubuntu 14.

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  • 3
    I'm not an assembly guru, but I believe the assembler is looking for an entry point called _start (which it cannot find because it isn't there). Stack Overflow seems pretty ripe with questions similar to this one, so please have a search around. Jan 13, 2016 at 5:13
  • 1
    @TimBiegeleisen Actually I also thought that. But what I'm not getting here is that why is it working with main. Why nasm throughs warning instead of error, if it want start_ explicitly. I've googled it and found everyone is using start_ keyword in their assembly code, But why is it working with main keyword.
    – Atinesh
    Jan 13, 2016 at 5:23
  • 5
    "Why nasm throughs warning instead of error". From what I can see the warning comes from the linker, not from nasm. The linker couldn't find the entrypoint, so it probably defaults to the beginning of the .text section.
    – Michael
    Jan 13, 2016 at 6:44

7 Answers 7

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Use the label _start instead of main for the ELF entry point. main implies it's like the C main function, but this isn't even a function (e.g. you can't ret).


You don't say, but from the warning messages and code I assume you're building your 32-bit code with nasm -felf32 hello32.asm && ld -melf_i386 -o hello32 hello32.o

(If you're actually building 64-bit code, you're lucky that it happens to work, but it'll break as soon as you do anything with esp instead of rsp.)

The warning message is from ld, not from nasm. It says so right in the message. Tim's comment is correct: ld looks for a _start symbol in the files it links, but sets the entry point to the beginning of the text segment if it doesn't find one. (That's why this is a warning, not an error. If you had put some other code earlier in the file, execution would start there without global _start / _start:)

It doesn't matter what other global/external symbols you define. main has no relevance at all here, and could point anywhere you want. It's only useful for a disassembly output and stuff like that. Your code would work exactly the same if you took out the global main / main: lines, or changed them to any other name.


Labelling that as main is unwise because the ELF entry point is not a function. It's not main(), and doesn't receive argc and argv arguments in the standard way, and can't ret because ESP is pointing at argc instead of a return address.


Only use main if you link with gcc / glibc's CRT startup code that looks for a main symbol and calls it after initializing libc. (So functions like printf work. Technically dynamic linker hooks let libc initialize itself before your _start if you linked it, but generally don't do that unless you understand exactly what you're doing). Related: Assembling 32-bit binaries on a 64-bit system (GNU toolchain)

e.g. gcc -m32 -no-pie -o hello main.o if you do define a main:
instead of gcc -m32 -static -nostdlib -o hello start.o
(which is equivalent to your bare ld).

(For the past few years, Linux distros have configured GCC with -pie as the default, which wants position-independent code. But that's really inconvenient in 32-bit mode where you don't have x86-64 RIP-relative addressing (look at GCC asm output for example), and means ld won't convert call printf into call printf@plt for you. So for most hand-written asm following most tutorials, you want traditional non-PIE executables so no text relocations are needed.)

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  • Actually in the tutorial I'm using they have used main instead of start_.
    – Atinesh
    Jan 14, 2016 at 10:47
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    @Atinesh: Then you should build with gcc -m32 -o hello32 hello32.o, instead of ld directly, so the standard libc startup code runs first, and calls your main function. I assume the next step in the tutorial is going to use some libc functions or something (although you can still do that from _start by linking with libc). Or maybe the tutorial isn't very good. There's no good reason to label your entry point main. Or if you do, you should use -e main to tell the linker it's the entry point, instead of leaving a confusing warning in your tutorial. Jan 14, 2016 at 15:28
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    The 32-bit elf loader passes the parameters and environment variables on the stack but not in the way C main function would expect them. 0(esp) is argc, 4(esp) is argv[0](program name), then each subsequent value on the stack is a pointer to each of the remaining arguments,followed by a NULL pointer, and then each stack value is a pointer to each of the environment variables followed by a NULL pointer. There are other pointers and values after that, but beyond what is typically used by most assembly programs. Jan 16, 2016 at 5:05
  • Your solution with linking with crt using gcc produces a warning which i don't understand: warning: relocation in read-only section .txt. Maybe I am doing something wrong?
    – mathway
    Oct 19, 2021 at 22:38
  • @mathway: Did you omit -no-pie? (edit: I forgot this answer didn't include -no-pie; I was thinking of another) In a non-PIE executable, final load addresses are link-time constants so no runtime text-relocations are needed. (Except maybe if you use the address of a global variable that's only defined in a shared library. Function calls like call printf will get converted by the linker into call printf@plt to avoid text relocations for jumps/calls into shared-library code, but access to data would take extra instructions to load a pointer from the GOT, so the linker can't do that.) Oct 19, 2021 at 22:57
6

I would suggest that you link your object files (however they are produced) with gcc, not ld.

gcc will call ld with the appropriate options, since it knows more about the source code and will create whatever is necessary for the assumptions that ld makes.

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  • 2
    Would you care to elaborate on that? :)
    – PovilasB
    Jun 20, 2017 at 12:41
4

I do not know if this is a valid fix, but seems to work for me:

try using option

--entry main

while linking your kernel C code.

ld -o kernel.bin -Ttext 0x1000 kernel_entry.o kernel.o --oformat binary --entry main 
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  • 2
    That's the right answer to a different question. This question is about creating a Linux ELF executable to run under Linux, not a stand-alone kernel. Using --entry main would just be confusing for this, as I explained in my answer. Only call your function main if it's called by something that passes it argv and argc, and that it can ret to when it's done. Oct 4, 2020 at 8:51
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You can try to compile the assembly source file with nasm, generate the *.o file, and then use the ld link the *.o file with parameter -e main. This means that main is specified as the program entry.

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    That's just confusing because main is normally used as a name for a function that runs after the C library init functions are done, so you can use printf and so on. To do that from the ELF entry point, you need to call glibc init functions yourself (or use dynamic linking). So it's best to keep calling your ELF entry point _start, and only use main for the function called from CRT startup code. May 26, 2018 at 11:43
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Instead of main you should use _start to indicate where nasm assembler should start executing. foe eg:

section .text
global _start
_start:
mov ebx, 1
mov ecx, msg
mov edx, len
mov eax, 4
int 0x80
mov eax, 1
int 0x80
0

To compile and execute your program you can create bash script as follow:

compile64.sh

!/bin//bash
echo "Assembling with Nasm"
nasm -f elf64 -o $1.o $1.asm
echo "Linking ... "
gcc -o $1 $1.o
echo "Done !"

$ ./compile64 nameOftheFile  (without extension)
-2

there is some issue in your programs like some syntactical mistakes like you can not assign registers value to constant because constant can not hold any value, for storing constants value we use variable

while assembling your program i am getting below mentioned asseble time errors

no such instruction: msg db 72ello,world!440xa' assign.S:3: Error: no such instruction:len equ $ - msg' assign.S:4: Error: no such instruction: section .text' assign.S:5: Error: no such instruction:global main' assign.S:7: Error: too many memory references for mov' assign.S:8: Error: too many memory references formov' assign.S:9: Error: too many memory references for mov' assign.S:10: Error: too many memory references formov' assign.S:11: Error: operand size mismatch for int' assign.S:12: Error: too many memory references formov' assign.S:13: Error: operand size mismatch for `int'

Here is code which give you same output on your gnu compiler with 32bit intel processor

.section .rodata msgp: .string "Hello World"

    .section .text
    .globl  main
    .type   main,@function

main:
    pushl   $msgp
    call    printf
    addl    $4,%esp

    pushl   $0
    call    exit

save this code with some name latest take Hello.S asseble with $ as -o Hello.o Hello.S link with $ ld -o Hello.o -lc -dynamic-linker /lib.ld.linux.so.2 -e main -Hello.o To run $ ./Hello

hope it will help you

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    You got errors because as the person asking the question said they are using nasm. You are using GNU assembler (as) which uses a different syntax. Sep 4, 2019 at 23:23

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