I am teaching myself to debug assembly language; I am new to assembly. I have a very simple C++ program and I disassembled it 3 times using different disassemblers: GDB, otool, and godbolt.org. GDB and godbolt.org produced approximately the same amount of code (1 page in a word processor), though many lines differ. The otool -tv command produced about 14 pages of code so there are many differences with respect to the GDB and godbolt.org outputs. The assembly code is too long to post. I was expecting the assembly code outputs to be the same as each other. Why are they different and which disassembler is best?

Here is my C++ program:

#include <iostream>

int main () {

int a = 1;
int b = 2;
int c = 3;

a += b;
a = a + c;

std::cout << "Value of A is " << a << std::endl;

return 0;


An example of assembly differences:


0x0000000100000f44 <+4>:    sub    $0x30,%rsp
0x0000000100000f48 <+8>:    mov    0x10c1(%rip),%rdi        # 0x100002010
0x0000000100000f4f <+15>:   lea    0xfb6(%rip),%rsi


sub rsp, 16
mov DWORD PTR [rbp-4], 1
mov DWORD PTR [rbp-8], 2

Otool -tv gave 13 more pages of code than the others so there is an obvious difference there.

  • You should at least post an excerpt of the disassembly, preferably something that shows excess things not in the other versions. I expect it's something trivial, such as disassembling data or libraries. Also make sure you disassemble the same binary, otherwise you are really looking at compiler differences, not disassembler. – Jester Jan 22 '18 at 18:08
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    you can get very different assembly from this c++ code if you just play a bit with compiler flags, that is the different direction, but still I dont really understand why you expect to get identical assembly from different disassembler – formerlyknownas_463035818 Jan 22 '18 at 18:09
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    Using std::cout makes the assembly much longer. You might find it better to remove the std::cout line (and the #include <iostream>), and just do return a from main – Justin Jan 22 '18 at 18:09
  • I posted an example. I don't know why I suppose they would be the same, perhaps because from the same program I assume they have the same binary code and that translates upwards to assembly? My understanding is not solid though. I will learn more about compilers. – Mr Berry Jan 22 '18 at 18:21
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    @MrBerry OllyDBG and IDA are Intel-syntax (IIRC), so picking gcc and gdb is a bit unfortunate (unless you plan to use intel-syntax option switch rigorously). In linux around Intel syntax the common tools are: nasm (assembler, has also ndisasm disassembler), edb-debugger (needs to be compiled form sources), gcc and tools around with intel syntax switch... BTW about std::cout large code -> that stream handler can format almost any type value into human readable string, with many options like precision or filler-chars, so indeed that takes hundreds/thousands of instructions in machine code. – Ped7g Jan 22 '18 at 23:13

The differences you are experiencing are not in the disassembled program, but rather in the syntax used to represent machine instructions.

Assembly is a very low-level language, in which there is a 1-to-1 mapping between machine instructions and mnemonics. The former are sequences of bits, possibly of variable length---as in the case of x86 architectures. This representation is directly interpreted by the CPU to carry out the work associated with the semantic of the instruction. Assembly language is a "human readable" representation of such sequences.

Basically, you can find any way to represent the same machine instruction. This is the assembly syntax.

Notoriously, for x86 architectures there exist two different syntaxes: AT&T and Intel. The output which you obtained from GBD is generated according to the AT&T syntax, while the output you got from Godbolt.org is Intel's.

Intel and AT&T syntax are very different from each other in appearance, and possibly this is why you have been thinking that the outcome is not the same. Actually, it's just a different way to represent the very same instructions.

These two "dialects" for the same architecture's assembly were born with different goals in mind. AT&T syntax was developed at AT&T labs to support the generation of programs for many different CPUs (see the book: Jeff Duntermann, Assembly Language Step-by-Step). At the time, AT&T was playing a major role in the history of computers. AT&T (Bell Labs) has been the source of Unix---its paradigm is currently (although partially) committed to by Linux---the C programming language, and many other fundamental tools that we continue to use today.

On the other hand, Intel syntax has been developed, well... by Intel for their own CPUs. Many adopters of the Intel syntax say that it is much neater when prorgamming on Intel CPUs. This might well be the case, as the syntax has been carefully crafted exactly for what the CPU supports.

While the AT&T syntax is no longer used at present days (at least, to the best of my knowledge) to write programs for CPUs other than x86, some of the "culprits" of the syntax are generated from it being more "general".

Then, which one to learn? My choice would be driven by the environment you work on. The whole Unix ecosystem (comprising Linux and Mac Os) has a toolchain (such as gas) which directly use that syntax. In the Linux kernel (and other low-level pieces of software) you will definitely find inlined assembly code in AT&T syntax to interact with the hardware. Windows systems, on the other hand, have toolchains (such as nasm) which speak the Intel syntax. While compile-time flags can ask these tools to switch to the other syntax (such as the -M flag for objdump), the habit is to adopt the "native" syntax.

With respect to the specific examples given in the question, they are "incompatible", in the sense that they refer to different portions of the disassembled code, so there is a higher degree of difference across the two. Indeed, with respect to this GDB output:

sub    $0x30, %rsp
mov    0x10c1(%rip), %rdi
lea    0xfb6(%rip), %rsi

the corresponding Intel disassembly would be:

sub    rsp, 0x30
mov    rdi, QWORD PTR [rip+0x10c1]
lea    rsi, [rip+0xfb6]

On the other hand, with respect to the Godbolt.org output:

sub rsp, 16
mov DWORD PTR [rbp-4], 1
mov DWORD PTR [rbp-8], 2

the corresponding AT&T disassembly would be:

sub    $0x10,%rsp
movl   $0x1,-0x4(%rbp)
movl   $0x2,-0x8(%rbp)

As you can see, the greatest difference, which might cause a lot of headaches, is related to the fact that the AT&T syntax places the source first and then the destination, while Intel syntax works the other way round.

  • This explanation elucidates the matter for me. Different syntax is used to represent the same instructions on different systems. I do not know why I assumed asm was standardized, like binary. I am going to look up the book; that is the type of information I am looking for at the moment. – Mr Berry Jan 22 '18 at 19:53
  • Assembly language is defined by the assembler, the tool that you use (or disassembler in this case) for x86 it is not just limited to ATT vs Intel, result on the left or right, but things like DWORD PTR, and the rest of the language, do labels have a colon or not do they have to be preceded by a specific character/symbol. There are many intel dialect assemblers and disassemblers with incompatible to each other assembly languages, likewise for ATT style. – old_timer Jan 22 '18 at 20:06
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    To downvoters: my explanation is general, and not specifically bound to the two examples which the OP gave. These, since are randomly cut&pasted code snippets which do not refer to the original higher-level code, should not be taken too much into consideration when replying to the question, IMO. I have anyhow updated my answer showing the corresponding "translations" of both code snippets. – ilpelle Jan 23 '18 at 12:20

The assembly sequences are not equivalents with different syntax, they are just different, probably due to using different compilers.

First pair:

sub $0x30,%rsp             ;rsp -= 0x30
sub rsp,16                 ;rsp -= 0x10

Next pair:

mov 0x10c1(%rip),%rdi      ;rdi = [rip+0x10c1]  (loads a value)
mov DWORD PTR [rbp-4],1    ;[rbp+4] = 1  (stores an immediate value)

Next pair:

lea    0xfb6(%rip),%rsi    ;rsi = rip+0xfb6   (loads an offset)
mov DWORD PTR [rbp-8],2    ;[rbp+8] = 2 (stores an immediate value)

Both sequences are incomplete, but I don't think it matter much, as the shown sequences already show the differences.

  • Apparently the OP just cut&pasted random portions of the disassembly he got! I believe he was not interested in the actual disassembled instructions, rather on why the syntax looked so different. – ilpelle Jan 23 '18 at 12:08
  • @ilpelle - ok, but still there is the difference of rsp -= 48 versus rsp -= 16, at function entry, which would indicate a different compiler and/or build environment. – rcgldr Jan 23 '18 at 14:29
  • or they could be different functions with a different number of local variables. We're not sure the OP picked the actual disassembly of main. In particular, the GDB disasm is using RIP-relative to load global variables, which are not present in the example provided. These could be library internal variables. The address 0x100002010 doesn't sound to me as if it's the address of the constant string used in the program. I'm just guessing from a 3-lines example :-) – ilpelle Jan 23 '18 at 16:10

Because there is not a 1 to 1 relationship between source code and assembly. The compiler would likely generate the same assembly for the following statements:

x = x + 1



both of which would be compiled to something like

add dword ptr [rdi], 1

So, when we dissassemble that, which one should it be disassembled to? x = x+1 or x++? This applies to virtually every statement of your program - if there is more than one way of expressing what happens in the source language, and the effects are the same, the compiler may choose to translate both of them to the same output. After which, you have no way of knowing which one was used.

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    A disassembler is applied to compiled code, not source code. – Neil Butterworth Jan 22 '18 at 18:14
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    @tobi303 I believe you misunderstood what dave was saying. Basically, if you have x = x + 1 and you have x++, they could both compile down to something like add dword ptr [rdi], 1. If you only have the assembly, you have no way of knowing whether it was originally x = x + 1 or x++ – Justin Jan 22 '18 at 18:18
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    Not my DV either - a disassembler produces something like assembly source code, not C++ source code. Suppose you have a wood sculpture and ask someone to describe the log from which it was carved. There are many answers. – Weather Vane Jan 22 '18 at 18:18
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    @dave No it doesn't - I don't think you understand what a disassembler does. It produces assembly language mnemonics, not C++ code. What you are talking about would be a decompiler. – Neil Butterworth Jan 22 '18 at 18:42
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    @dave There is a one-to-one mapping (in both directions) between machine code and assembly language. – Neil Butterworth Jan 22 '18 at 18:49

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