What is the difference between object code, machine code and assembly code?

Can you give a visual example of their difference?

  • I'm also curious about where did the "object code" name came from? What does the "object" word supposed to mean in it? Is it somehow related to object-oriented programming or just a coincidence of names? – SasQ Apr 4 '16 at 1:52
  • @SasQ: Object code. – Jesse Good Aug 22 '16 at 1:18
  • I'm not asking about what is an object code, Captain Obvious. I'm asking about where did the name come from and why is it called "object" code. – BarbaraKwarc Aug 23 '16 at 8:14

Machine code is binary (1's and 0's) code that can be executed directly by the CPU. If you were to open a machine code file in a text editor you would see garbage, including unprintable characters (no, not those unprintable characters ;) ).

Object code is a portion of machine code that hasn't yet been linked into a complete program. It's the machine code for one particular library or module that will make up the completed product. It may also contain placeholders or offsets not found in the machine code of a completed program. The linker will use these placeholders and offsets to connect everything together.

Assembly code is plain-text and (somewhat) human read-able source code that mostly has a direct 1:1 analog with machine instructions. This is accomplished using mnemonics for the actual instructions, registers, or other resources. Examples include JMP and MULT for the CPU's jump and multiplication instructions. Unlike machine code, the CPU does not understand assembly code. You convert assembly code to machine with the use of an assembler or a compiler, though we usually think of compilers in association with high-level programming language that are abstracted further from the CPU instructions.

Building a complete program involves writing source code for the program in either assembly or a higher level language like C++. The source code is assembled (for assembly code) or compiled (for higher level languages) to object code, and individual modules are linked together to become the machine code for the final program. In the case of very simple programs the linking step may not be needed. In other cases, such as with an IDE (integrated development environment) the linker and compiler may be invoked together. In other cases, a complicated make script or solution file may be used to tell the environment how to build the final application.

There are also interpreted languages that behave differently. Interpreted languages rely on the machine code of a special interpreter program. At the basic level, an interpreter parses the source code and immediately converts the commands to new machine code and executes them. Modern interpreters, sometimes also called a runtime-environment or virtual machine, are much more complicated: evaluating whole sections of source code at a time, caching and optimizing where possible, and handling complex memory management tasks. An interpreted language may also be pre-compiled to a lower-level intermediate language or bytecode, similar to assembly code.

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    +1: nice, but somewhat simplifying answer - not all assembly instructions are translated 1:1 to machine instructions, and object files may also contain other data (relocation information, symbol tables, ...) – Christoph Jan 21 '09 at 20:25
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    Added a weasel word for your first issue, edited to make the 2nd clearer. – Joel Coehoorn Jan 21 '09 at 20:35
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    @Christoph: you say "not all assembly instructions are translated 1:1 to machine instructions" please give an example. – Olof Forshell Feb 22 '11 at 17:47
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    @Olof: RISC architectures sometimes provide an assembly-level virtual instruction set - eg MIPS pseudo-instructions ( en.wikipedia.org/wiki/MIPS_architecture#Pseudo_instructions ) – Christoph Feb 23 '11 at 19:39
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    @Panzercrisis Nothing get's added by the assembler. It's a directly translation of what you wrote to actual machine instructions. And I wouldn't call the extra code put in by compilers "unecessary" – Joel Coehoorn Mar 22 '13 at 20:54

The other answers gave a good description of the difference, but you asked for a visual also. Here is a diagram showing they journey from C code to an executable.

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    I find this really helpful, but it is missing the "Machine code" label – Alexx Roche Aug 6 '13 at 9:12
  • So when it's at the executable code level, is that equivalent to machine code? – CMCDragonkai Dec 14 '14 at 6:39
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    In the context of this diagram, the "object code" is the machine code. – Graphics Noob Dec 14 '14 at 23:36
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    Actually, both the object code and executable code are machine codes. the difference is that object code is not the completed program. It needs to be combined with other helper library/module codes as indicated in the diagram to form a complete executable program/code. – okey_on Mar 26 '16 at 20:24
  • @okeyxyz at what level would it be correct to say it is directly executed by the processor? After the assembler, after the linker, after the loader, after it gets converted to microcontroller? – Celeritas Jul 27 '16 at 3:45

Assembly code is a human readable representation of machine code:

mov eax, 77
jmp anywhere

Machine code is pure hexadecimal code:

5F 3A E3 F1

I assume you mean object code as in an object file. This is a variant of machine code, with a difference that the jumps are sort of parameterized such that a linker can fill them in.

An assembler is used to convert assembly code into machine code (object code) A linker links several object (and library) files to generate an executable.

I have once written an assembler program in pure hex (no assembler available) luckily this was way back on the good old (ancient) 6502. But I'm glad there are assemblers for the pentium opcodes.

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    No no no no. Machine code is not hex code. it's pure binary. Hex code is just a convenient representation of binary. – Breton Jan 21 '09 at 21:05
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    If we are really going into extremes, its not binary, it is an amount of stored electricity in a circuit. ;-) – Toon Krijthe Jan 21 '09 at 21:13
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    Yes of course. There is a relationship between the hexidecimal, and what you would call "Machine Code", but it's not quite accurate to say hexidecimal is machine code. That's all I'm trying to say. – Breton Feb 23 '11 at 3:41
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    @Breton In that sense, there is no such thing as "hex code" right? "Hex code" is just a way of viewing the machine code. You can view the machine code in hexadecimal, binary, octal, decimal, or however you like. Also again in that sense, there is no "binary code" as well. Again, "binary code" is just a way of viewing the machine code. – Utku Nov 15 '15 at 11:22
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    @Breton What you say does not really make much sense.. Binary is a way of representation, just like hex. If it is not hex, it is not binary either. – Koray Tugay Mar 9 '16 at 6:12

8B 5D 32 is machine code

mov ebx, [ebp+32h] is assembly

lmylib.so containing 8B 5D 32 is object code


One point not yet mentioned is that there are a few different types of assembly code. In the most basic form, all numbers used in instructions must be specified as constants. For example:

$1902: BD 37 14 : LDA $1437,X
$1905: 85 03    : STA $03
$1907: 85 09    : STA $09
$1909: CA       : DEX
$190A: 10       : BPL $1902

The above bit of code, if stored at address $1900 in an Atari 2600 cartridge, will display a number of lines in different colors fetched from a table which starts at address $1437. On some tools, typing in an address, along with the rightmost part of the line above, would store to memory the values shown in the middle column, and start the next line with the following address. Typing code in that form was much more convenient than typing in hex, but one had to know the precise addresses of everything.

Most assemblers allow one to use symbolic addresses. The above code would be written more like:

  lda ColorTbl,x
  sta WSYNC
  sta COLUBK
  bpl rainbow_lp

The assembler would automatically adjust the LDA instruction so it would refer to whatever address was mapped to the label ColorTbl. Using this style of assembler makes it much easier to write and edit code than would be possible if one had to hand-key and hand-maintain all addresses.

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    +1. One more additional point: there are also different assembly language syntaxes, most famous being Intel and AT&T. – informatik01 Jan 7 '14 at 15:40
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    @informatik01: How about Intel 8080 mnemonics vs Zilog Z80? I would guess that predates the Intel vs AT&T syntax war. – supercat Jan 7 '14 at 16:39
  • Not arguing, I just mentioned that aspect (different syntax) and gave an example of two most popular/well known/famous syntaxes. – informatik01 Jan 7 '14 at 16:46

Source code, Assembly code, Machine code, Object code, Byte code, Executable file and Library file.

All these terms are often very confusing for most people for the fact that they think they are mutually exclusive. See the diagram to understand their relations. The description of each term is given below.

Types of code

Source code

Instructions in human readable (programming) language

High-level code

Instructions written in a high level (programming) language
e.g., C, C++ and Java programs

Assembly code

Instructions written in an assembly language (kind of low-level programming language). As the first step of the compilation process, high-level code is converted into this form. It is the assembly code which is then being converted into actual machine code. On most systems, these two steps are performed automatically as a part of the compilation process.
e.g., program.asm

Object code

The product of a compilation process. It may be in the form of machine code or byte code.
e.g., file.o

Machine code

Instructions in machine language.
e.g., a.out

Byte code

Instruction in an intermediate form which can be executed by an interpreter such as JVM.
e.g., Java class file

Executable file

The product of linking proccess. They are machine code which can be directly executed by the CPU.
e.g., an .exe file.

Note that in some contexts a file containing byte-code or scripting language instructions may also be considered executable.

Library file

Some code is compiled into this form for different reasons such as re-usability and later used by executable files.

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    I would argue that not all assembly is truly source in the strictest sense of code written and/or maintained by humans. Often it's machine-generated from source, and never intended for human consumption (for example, gcc really does create asm text that it feeds to a separate assembler, instead of having a built-in assembler inside the cc1 executable). I think the asm circle should stick out the left side of the "source" circle, because some asm is just asm, not source. It's never object code, of course, but some asm is a step on the way from source to object files. – Peter Cordes Apr 8 at 23:25
  • @PeterCordes Thank you very much for the comment. I wasn't aware of what you said about the working of gcc. However, I am afraid if I can agree with you completely. What I mean is, source code is something written using a human-readable programming language. It may or may not be written or maintained by humans. I am sure that you will be aware of transcompilers. From your point of view, to which category will you put the product of such a compiler? Source code or something else? Please correct me if i'm wrong. Further comments are always welcome. – Anees Apr 9 at 13:07

Assembly code is discussed here.

"An assembly language is a low-level language for programming computers. It implements a symbolic representation of the numeric machine codes and other constants needed to program a particular CPU architecture."

Machine code is discussed here.

"Machine code or machine language is a system of instructions and data executed directly by a computer's central processing unit."

Basically, assembler code is the language and it is translated to object code (the native code that the CPU runs) by an assembler (analogous to a compiler).


I think these are the main differences

  • readability of the code
  • control over what is your code doing

Readability can make the code improved or substituted 6 months after it was created with litte effort, on the other hand, if performance is critical you may want to use a low level language to target the specific hardware you will have in production, so to get faster execution.

IMO today computers are fast enough to let a programmer gain fast execution with OOP.


Assembly is short descriptive terms humans can understand that can be directly translated into the machine code that a CPU actually uses.

While somewhat understandable by humans, Assembler is still low level. It takes a lot of code to do anything useful.

So instead we use higher level languages such as C, BASIC, FORTAN (OK I know I've dated myself). When compiled these produce object code. Early languages had machine language as their object code.

Many languages today such a JAVA and C# usually compile into a bytecode that is not machine code, but one that easily be interpreted at run time to produce machine code.

  • Your comment about Java and C# - both use Just In Time compilation so that bytecodes are not interpretted. C# (.NET generally) compiles to Intermediate Language (IL) which is then JITed into native machine language for the target CPU. – Craig Shearer Jan 21 '09 at 20:52

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