x86 is an architecture derived from the Intel 8086 CPU. The x86 family includes the 32bit IA-32 and 64bit x86-64 architectures, as well as 16bit code. See the tag wiki page for many useful links for programming and optimizing. Use the DOS and/or emu8086 tags as well as this, if applicable.
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 x86-64 tag for things specific to that architecture, but most links will apply 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.
- Suggestions on how to learn asm, with a recommendation against 16bit DOS. Questions should use the dos and/or emu8086 tags if applicable, as x86 includes all platforms.
- OSdev.org: a great resource if you want to understand / modify OS internals or make your own toy OS. Not useful for writing / debugging normal programs that run under existing OSes.
- course material from 2002, for NASM. Still relevant: NASM style guide (code formatting), and NASM local labels. Also: Loops (16bit examples, but 32/64bit loops work identically.) Data structures (arrays, lists, etc.) in asm: how they're laid out in memory, with some code.
- Quick guide to what's different in x86-64. AT&T syntax. NASM and YASM behave differently (from each other) in choice of encoding for
mov rax, 1, and don't use a separate
movabsmnemonic for the 64bit-immediate form.
- x86 on Wikipedia
- x86 Assembly wikibook
- Assembly Language for x86 Processors (website for Kip Irvine's book)
- Assembly tutorial - Dr. Paul Carter
Understanding Carry vs. Overflow conditions/flags for signed vs. unsigned.
- Using GNU C/C++ inline ASM, and why it's not a good way to learn asm in the first place. A collection of links to other good inline-asm guides and Q&As. Don't try to "get your feet wet" with asm by using inline asm. You have to understand everything to write correct input/output operand constraints and clobbers.
- Why do functions have to save some registers, but not others? See below for links to guides & docs for specific calling conventions.
- Linux x86 Program Start Up or - How the heck do we get to main()
- A Whirlwind Tutorial on Creating Really Teensy ELF Executables for Linux
Guides for performance tuning / optimisation:
- Agner Fog's optimization guides and resources. Includes latency/throughput tables for P5 onwards. Also much qualitative discussion of how to go about making your code faster. Also has a good guide to the different calling conventions across OSes, and covers linking / symbols / relocation.
- What Every Programmer Should Know About Memory. Cache behaviour of recent CPUs. A bit outdated; SW prefetch is useful in far fewer cases now.
xor same,sameis better than
mov reg, 0There are several reasons, some simple and some subtle (e.g. avoiding partial-register stalls on P6/SnB family).
- Intel's IACA (Intel Architecture Code Analyzer): analyze marked sections of code for throughput (e.g. cycles per iteration) or latency of the critical path. Assumes perfect cache, and other simplifications, and isn't always correct, but can be useful for Nehalem through Haswell.
- Haswell microarchitecture. David Kanter's analysis.
- Broadwell vs. Skylake instruction performance. New CPUs will usually have AIDA64 results like that before Agner Fog can test and publish updated tables.
Instruction set / asm syntax references:
- Intel's vector intrinsics finder/search (very good): search by asm mnemonic or C intrinsic name
- Intel's manuals, including instruction set reference manual. Extremely detailed description of everything every instruction does to the architectural state. Big, but has a decent index / table of contents. Also on that page: Intel's optimization manual. Some of the same advice as Agner Fog's guides, but sometimes without explaining exactly why in terms of microarch execution ports and other under-the-hood reasons. Also sometimes obsolete, for example recommending against
declong after P4 is irrelevant.
- Simply FPU: x87 tutorial. Helpful for understanding old x87 code. (Use SSE for new code.)
- The NASM manual
- x86 Instruction Reference from an old version of the NASM manual, including descriptions, and which generation (8086, 186, 286, ...) introduced each form of each insn. This table comes in handy for people still developing for 8086. Even lists some undocumented and Cyrix-only MMX instructions. The similar wikipedia page doesn't mention that 386 is required for the faster 2-operand form of
imul r16, r/m16that doesn't have to calculate the upper half of the result. The current NASM manual removed the English summaries of the instructions, probably since the page got too long with SSE instructions.
- YASM manual: describes NASM syntax and macros.
- This answer lists all the available addressing modes (Intel syntax, with a note about NASM vs. MASM for
mov reg, symbol), with links to further guides.
- TODO: find a good link for AMD's XOP instruction set. (Not recommended for general use; even AMD is dropping XOP support in their Zen architecture.)
- x86 Opcode reference guide
- Cheat sheet PDF
- Win32-specific cheat sheet
OS-specific stuff: ABIs and system-call tables:
- x86 ABIs: calling conventions for functions, including x86-64 Windows and System V (Linux). See also Agner Fog's nice calling convention guide
- SystemV (all but Windows) x86-64 ABI
- SystemV x86-32 (i386) ABI, used by Linux and Unix
- TODO: a good link for current Windows ABIs?
- Linux system call tables. 64bit syscall numbers, with parameter->register mapping (derived from the kernel source code, and the standard rule for order of args).
- FreeBSD system calls: question has FreeBSD syscalls, answer has Linux and others.
- What are the calling conventions for UNIX & Linux system calls on x86-64: Note that 32bit
int 0x80restores all registers (including flags) except
eax, while 64bit
r11as well as putting the return value in
Machine architecture / memory ordering and out-of-order execution:
- Weak vs. Strong Memory Models: what it means when people say x86 has a "strongly ordered memory model". See also the c++ info page for many good links if you're using C11/C++11 atomics.
- Memory Reordering Caught in the Act: A test case that demonstrates memory reordering in practice on a multicore x86 CPU.
- A better x86 memory model: x86-TSO (extended version) A formal definition of the x86 memory model which hopefully matches how real hardware behaves.
- TLB and Pagewalk Coherence in x86 Processors. Many x86 microarchitectures, especially Intel's, provide stronger ordering guarantees than the ISA requires for modifying a page-table entry that's not already cached in the TLB. Win95 even depended on this. (Don't write new code that depends on this.)
- Measuring Reorder Buffer Capacity Another experimental test that demonstrates the capabilities and limits of out-of-order execution in real hardware.
Q&As with good links, or directly useful answers:
- Micro fusion and addressing modes: the Intel Sandybridge microarchitecture family appears to have changed micro-fusion: it now works only on single-register addressing modes. Agner Fog's re-testing shows the the uop-cache can still micro-fuse 2-register effective addresses, but there is reason to believe that the OOO pipeline can't. Testing on newer HW would be useful. Also note that Haswell's extra store-address unit on port7 only works with simple effective addresses. Complex effective addresses need the AGU on a load port.
- Parallel programming using Haswell architecture
- How can I run this assembly code on OS X?: OS X getting-started guide. (Symbol names are prepended with
_on OS X, unlike for Linux ELF systems.)
add/sub/LEA can be used with garbage in high bits, so
LEA eax, [rdi + rsi*2 - 15]to compute
a + 2*b - 15works fine, even if
bare only supposed to be 8 or 16 bits.
TODO: find a question about how to use a profiler to measure uops and stuff.
perfcomes with most Linux distros, and
ocperf.pyis a wrapper for it that provides more symbolic names for stuff like micro-arch-specific uop counters.
How to get started:
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.
One widely-available debugger is gdb. With
layout asm and
layout reg enabled, it's fairly useful. 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).
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.