x86 is an architecture derived from the Intel 8086 CPU. The x86 family includes the 32-bit IA-32 and 64-bit x86-64 architectures, as well as legacy 16-bit architectures. Questions about the latter should be tagged [x86-16] and/or [emu8086]. Use the [x86-64] tag if your question is specific to 64-bit x86-64. For the x86 FPU, use the tag [x87]. For SSE1/2/3/4 / AVX* also use [sse], and any of [avx] / [avx2] / [avx512] that apply

The x86 family of CPUs contains 16-, 32-, and 64-bit processors from several manufacturers, with backward-compatible instruction sets, going back to the Intel 8086 introduced in 1978.

There is an tag for things specific to that architecture, but most of the info here applies to both. It makes more sense to collect everything here. Questions can be tagged with either or both. Questions specific to features only found in the x86-64 architecture, like RIP-relative addressing, clearly belong in x86-64. Questions like "how to speed up this code with vectors or any other tricks" are fine for x86, even if the intention is to compile for 64bit.

Related tag with tag-wikis:

  • wiki (some good SIMD guides), and (not much there)
  • wiki for guides specific to interfacing with a compiler that way.
  • wiki and wiki have more details about the differences between the two major x86 assembly syntaxes. And for Intel, how to spot which flavour of Intel syntax it is, like NASM vs. MASM/TASM.

Learning resources

If you don't know how to do something in asm, write a simple C function that does it and see what an optimizing compiler does. e.g. int foo(char *p) { return *p; } shows you how to use movsx. See also How to remove "noise" from GCC/clang assembly output?


Guides for performance tuning / optimisation:

Instruction set / asm syntax references:

A fork of an older version includes English descriptions. The original had some errors in which generation introduced each form of each insn but this version keeps the nice formatting while fixing those. Handy for people still developing for . The similar wikipedia page doesn't mention that 386 is required for the faster 2-operand form of imul r16, r/m16 that doesn't have to calculate the upper half of the result.

Possible canonical duplicates for register subsets: Assembly registers in 64-bit architecture includes some calling-convention / usage stuff. How do AX, AH, AL map onto EAX? is a good one for bugs where AL and RAX were used for different things, corrupting each other.

OS-specific stuff: ABIs and system-call tables:






  • 16bit interrupt list: PC BIOS system calls (int 10h / int 16h / etc, AH=callnumber), DOS system calls (int 21h/AH=callnumber), and more.

memory ordering:

Specific behaviour of specific implementations

Q&As with good links, or directly useful answers:


FAQs / canonical answers:

If you have a problem involving one of these issues, don't ask a new question until you've read and understood the relevant Q&A.

(TODO: find better question links for these. Ideally questions that make a good duplicate target for new dups. Also, expand this.)

8-bit operand size like div dl is the special case where dx isn't involved, just AX and AH/AL. It still faults if the quotient overflows 8 bits.

string-to-integer (32-bit NASM, algorithm works everywhere). (multiply by 10 for place value) Also includes an int-to-string loop.

Printing integers: 16-bit code to print 16 or 32-bit integers (in dx:ax) (1 digit at a time with MS-DOS int 21h, but could be adapted to store into a string or use a different output method.) Another example for unsigned 16b numbers in DOS that calculates digits and stores them into a string in memory.

2-digit decimal numbers (00-99), using BIOS int 10h for each digit: Displaying Time in Assembly. (Just a special case of the general algorithm, not looping.)

NASM x86-64 function to convert and print a 32-bit unsigned integer (using a single Linux write system call on a buffer). Other answers on the same question show printing one character at a time. AT&T version of the same function, also showing a 5x faster version that uses a multiplicative inverse instead of div to divide by the compile-time constant 10.

How to convert a binary integer number to a hex string? (32-bit NASM code. Scalar, SSE2, SSSE3, AVX512F, and AVX512VBMI versions.)


How to get started / Debugging tools + guides

Find a debugger that will let you single-step through your code, and display registers while that happens. This is essential. We get many questions on here that are something like "why doesn't this code work" that could have been solved with a debugger.

On Windows, Visual Studio has a built-in debugger. See Debugging ASM with Visual Studio - Register content will not display. And see Assembly programming - WinAsm vs Visual Studio 2017 for a walk-through of setting up a Visual Studio project for a MASM 32-bit or 64-bit Hello World console application.

On Linux: A widely-available debugger is gdb. See Debugging assembly for some basic stuff about using it on Linux. Also How can one see content of stack with GDB?

There are various GDB front-ends, including GDBgui. Also guides for vanilla GDB:

With layout asm and layout reg enabled, GDB will highlight which registers changes since the last stop. Use stepi to single-step by instructions. Use x to examine memory at a given address (useful when trying to figure out why your code crashed while trying to read or write at a given address). In a binary without symbols (or even sections), you can use starti instead of run to stop before the first instruction. (On older GDB without starti, you can use b *0 as a hack to get gdb to stop on an error.) Use help x or whatever for help on any command.

GNU tools have an Intel-syntax mode that's similar to MASM, which is nice to read but is rarely used for hand-written source (NASM/YASM is nice for that if you want to stick with open-source tools but avoid AT&T syntax):

Another key tool for debugging is tracing system calls. e.g. on a Unix system, strace ./a.out will show you the args and return values of all the system calls your code makes. It knows how to decode the args into symbolic values like O_RDWR, so it's much more convenient (and likely to catch brain-farts or wrong values for constants) than using a debugger to look at registers before/after an int or syscall instruction. Note that it doesn't work correctly on Linux int 0x80 32-bit ABI system calls in 64-bit processes: What happens if you use the 32-bit int 0x80 Linux ABI in 64-bit code?.

To debug boot or kernel code, boot it in a bochs, qemu, or maybe even DOSBOX, or any other virtual machine / simulator / emulator. Use the debugging facilities of the VM to get way better information than the usual "it locks up" you will experience with buggy privileged code.

BOCHS is generally recommended for debugging real-mode bootloaders, especially ones that switch to protected mode; BOCHS's built-in debugger understands segmentation (unlike GDB), and can parse a GDT or IDT to make sure you got the fields right.