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I'm attempting to convert RR0D Rasta Ring 0 Debugger from 32-bit mode to 64-bit mode (long mode) in Linux, using gcc. I'm familiar with x86 32-bit assembly (in MS-DOS environment) but I'm a beginner in x86 64-bit assembly and in Linux assembly programming in general.

This project is for production use (I need a working non-source debugger), but I also attempt to learn how to do the 32-bit to 64-bit conversion. If possible, I attempt to find a universal way to do 32-bit to 64-bit conversion that could be done on any 32-bit program using regular expressions (so that it can be automatized). I'm aware that no general solution exists (64-bit code may take more space than 32-bit code etc. and consume more stack etc.), but even in that case automatically converted code would serve as a starting point.

The idea would be to keep 8-bit and 16-bit operands as is, and replace 32-bit operands with 64-bit operands. This approach will naturally fail if pushw %ax; pushw %bx; popl %ecx is replaced with pushw %ax; pushw %bx; popq %rcx, but well-behaved programs usually don't push two 16-bit operands and then pop one 32-bit operand, or do they?.

These are the conversions so far:

Edit: Fix: pusha / pushad can be replaced with consecutive push'es, because pusha / pushad commands push the value of sp / esp before the actual push of sp, and push sp works the same way in 286+, but differently in 8088/8086 The Assembly Language database. This difference not an issue here (for 386+ code). pusha and pushad can thus be replaced with consecutive push commands.

An alternative is similar as in OpenSolaris' privregs.h code.

Edit: Fix: use 64-bit memory addressing for all commands.

  1. pusha -> push %ax; push %cx; push %dx; push %bx; push %sp; push %bp; push %si; push %di.

    Edit: Fix: A valid alternative (using lea), note that x86 processors are little-endian: pusha -> movq %rax, -8(%rsp); lea -8(%rsp), %rax; mov %ax, -10(%rsp); movq -8(%rsp), %rax; movw %cx, -4(%rsp); movw %dx, -6(%rsp); movw %bx, -8(%rsp); movw %bp, -12(%rsp); movw %si, -14(%rsp); movw %di, -16(%rsp); lea -16(%rsp), %rsp.

  2. pushad -> push %rax; push %rcx; push %rdx; push %rbx; push %rsp; push %rbp; push %rsi; push %rdi.

    Edit: Fix: A valid alternative (using lea): pushad -> movq %rax, -8(%rsp); movq %rcx, -16(%rsp); movq %rdx, -24(%rsp); movq %rbx, -32(%rsp); lea -32(%rsp), %rax; movq %rax, -40(%rsp); movq -8(%rsp), %rax; movq %rbp, -48(%rsp); movq %rsi, -56(%rsp); movq %rdi, -64(%rsp); lea -64(%rsp), %rsp.

    Edit: Fix: popa and popad pop the value of sp / esp but discard it (Intel instruction set - popa/popad) . Let's pop it into bx / rbx.

  3. popa -> popw %di; popw %si; popw %bp; popw %bx; popw %bx; popw %dx; popw %cx; popw %ax.

  4. popad -> popq %rdi; popq %rsi; popq %rbp; popq %rbx; popq %rbx; popq %rdx; popq %rcx; popq %rax.

  5. pushfd -> pushfq.

  6. popfd -> popfq.

  7. Edit: push of segment registers, eg. pushw %ds -> pushw %ax; pushw %ax; movw %ds, %ax; movw %ax, 2(%rsp); popw %ax.

  8. Edit: pop of segment registers, eg. popw %ds -> pushw %ax; movw 2(%rsp), %ax; movw %ax, %ds; popw %ax.

  9. Edit: inc %reg16 -> add $1, %reg16, eg. inc %ax -> add $1, %ax.

  10. Edit: dec %reg16 -> sub $1, %reg16, eg. dec %ax -> sub $1, %ax.

  11. Edit: inc %reg32 -> add $1, %reg64, eg. inc %eax -> add $1, %rax.

  12. Edit: dec %reg32 -> sub $1, %reg64, eg. dec %eax -> sub $1, %rax.

  13. Edit: aaa -> ?

  14. Edit: aad -> ?

  15. Edit: aam -> ?

  16. Edit: aas -> ?

  17. Edit: arpl -> ?

  18. Edit: bound -> ?

  19. Edit: daa -> ?

  20. Edit: das -> ?

  21. Edit: lahf -> ?

  22. Edit: sahf -> ?

  23. Edit Fix: any command with direct operand that does not fit in 32-bit operand size in 64-bit mode, eg. pushl $0xDEADBEEF -> pushq %rax; pushq %rax; movq $0xDEADBEEF, %rax; movq %rax, 8(%rsp); popq %rax.

  24. ret with immediate operand: I think in this case the source code must be backtraced to see the sizes of last pushed operands, and act accordingly, eg. pushl %eax; ret 4 -> pushq %rax; ret 8.

  25. Edit:: syscalls: int $0x80 -> pushq %rdi; movq %rbp, %r9; movq %rdi, %r8; movq %rbx, %rdi; xchgq %rcx, %rsi; -- replace %rax value using a substitution list --; syscall; popq %rdi; xchgq %rcx, %rsi (note: 32-bit syscalls may have more than 6 parameters, 6 in registers and the rest in stack, 64-bit syscalls may never have more than 6 parameters).

Edit: What else should be taken into account? What other conversions would be needed to convert 32-bit code to 64-bit code (to be run in long mode) ?

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closed as not a real question by duskwuff, Mat, Griwes, j0k, Maerlyn Aug 14 '12 at 12:54

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

did you see llvm ? may it will be usefull for your needs. – Zagorulkin Dmitry Aug 10 '12 at 7:25
@ZagorulkinDmitry I haven't tried llvm, I'll check it. Thanks. – nrz Aug 10 '12 at 8:16
I'm not sure that'll be sufficient. There are deeper differences between x86 and x86_64 than just the size of registers. – duskwuff Aug 10 '12 at 20:20
Indeed -- standard calling convention is very different. – ephemient Aug 10 '12 at 21:55
@H2CO3 Ha ha ha no. Not only does that technique not work reliably even for simple userland code, but the code that nrz is working with here is an insanely low-level debugger, so a lot of what it's doing is probably not even representable in C. Performing a "blind idiot translation" like that will definitely not work. – duskwuff Aug 13 '12 at 22:23