I am using Visual C++ 2010 developing 32bit windows applications. There is something I really want to use inline assembly. But I just realized that visual C++ does not support inline assembly in 64bit applications. So porting to 64bit in the future is a big issue.

I have no idea how 64bit applications are different from 32bit applications. Is there a chance that 32bit applications will ALL have to be upgraded to 64bit in the future? I heard that 64bit CPUs have more registers. Since performance is not a concern for my applications, using these extra registers is not a concern to me. Are there any other reasons that a 32bit application needs to be upgraded to 64bit? Would a 64 bit application process things differently when compared with a 32bit application, apart from that the 64bit applications may use registers or instructions that are unique to 64bit CPUs?

My application needs to interact with other OS components e.g. drivers, which i know must be 64bit in 64bit windows. Would my 32bit application compatible with them?

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    just turn the assembly into C++ and you are done Commented May 29, 2011 at 9:12
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    Since performance is not a concern for my applications, why on Earth are you using inline assembly then? Commented May 29, 2011 at 14:06
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    @Hans Passant: the other common reason is programs that create code dynamically, e.g. virtual machine runtimes/JIT compilers. They can benefit from being able to rewrite code, which is a bit harder if you don't know which code was there before. But people writing such VMs would probably not need to ask this question - the statement "compilers write better assembly than humans" doesn't really apply to humans who write compilers ;)
    – MSalters
    Commented May 30, 2011 at 8:48
  • Also see Making assembly function inline in x64 Visual Studio. If you can get the Visual Studio compiler/linker to inline the freestanding ASM, then it is not a big loss in practice. And maybe How to do a naked function and inline assembler in x64 Visual C++.
    – jww
    Commented Apr 25, 2019 at 2:22
  • @MSalters the statement "compilers write better assembly than humans" doesn't really apply to humans who write compilers It actually can apply, at least sometimes. For comparison, humans who write artificial intelligence for playing chess may not be able to beat their own AI in playing chess.
    – WhatsUp
    Commented Mar 30, 2022 at 20:03

4 Answers 4


Visual C++ does not support inline assembly for x64 (or ARM) processors, because generally using inline assembly is a bad idea.

  1. Usually compilers produce better assembly than humans.
  2. Even if you can produce better assembly than the compiler, using inline assembly generally defeats code optimizers of any type. Sure, your bit of hand optimized code might be faster, but the fact that code around it can't be optimized will generally lead to a slower overall program.
  3. Compiler intrinsics are available from pretty much every major compiler that let you access advanced CPU features (e.g. SSE) in a manner that's consistent with the C and C++ languages, and does not defeat the optimizer.

I am wondering would there be a chance that 32bit applications will ALL have to be upgraded to 64bit in the future.

That depends on your target audience. If you're targeting servers, then yes, it's reasonable to allow users to not install the WOW64 subsystem because it's a server -- you know it'll probably not be running too much 32 bit code. I believe Windows Server 2008 R2 already allows this as an option if you install it as a "server core" instance.

Since performance is not a concern for my appli so using the extra 64bit registers is not a concern to me. Is there any other reasons that a 32bit appli has to be upgraded to 64bit in the future?

64 bit has nothing to do with registers. It has to do with size of addressable virtual memory.

Would a 64 bit app process different from a 32bit appl process apart from that the 64bit appli is using some registers/instructions that is unique to 64bit CPUs?

Most likely. 32 bit applications are constrained in that they can't map things more than ~2GB into memory at once. 64 bit applications don't have that problem. Even if they're not using more than 4GB of physical memory, being able to address more than 4GB of virtual memory is helpful for mapping files on disk into memory and similar.

My application needs to interact with other OS components e.g. drivers, which i know must be 64bit in 64bit windows. Would my 32bit application compatible with them?

That depends entirely on how you're communicating with those drivers. If it's through something like a "named file interface" then your app could stay as 32 bit. If you try to do something like shared memory (Yikes! Shared memory accessible from user mode with a driver?!?) then you're going to have to build your app as 64 bit.

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    One correction - 32bit apps can map ~4GB - as the 32bits declare :) It's depending on the OS that some additional limits come up - on 32bit Windows by default you get 2GB but can get 3GB using a boot switch. I think on most 64bit systems the apps can get full 4GB. ALso a 32Bit os can address more then 4GB of physical memory: msdn.microsoft.com/en-us/library/… - WS 2003 x86 == 64 GB
    – RnR
    Commented May 29, 2011 at 10:35
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    I disagree with you saying 64 bit has nothing to do with registers. X64 has twice the registers as X86.
    – Boofhead
    Commented May 29, 2011 at 11:11
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    I'm really sorry for bumping this, but... whoever (at Microsoft) decided to not include inline assembly in x64 because it's "generally a bad idea" should be shot on sight. I'm the programmer, let me face the consequences of the bad code you (Microsoft) suppose I'm going to write.
    – rev
    Commented Nov 4, 2014 at 20:30
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    They will definitely lose a customer when I switch to x64. It's my app, and for what I do, I need inline assembly (I mainly do reverse engineering). So one more GCC customer, one less MSVC customer. Just my 5 cents.
    – rev
    Commented Nov 4, 2014 at 21:09
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    there are other reasons besides speed for inline assembly Commented Nov 30, 2016 at 18:32

Apart form @Billy's great write up, if you really feel the need to use 64bit assembly, then you can use an external assembler like MASM to get that done, see this. (its also possible to speed this up with prebuild scripts).


the Intel C Compiler 15 has inline capability in 64bit too. And you could integrate the IC in Visual Studio as a toolset: then you'd have VC++ 64bit with inline assembly. One catch though -its expensive cheers


While we're at it, MinGW also has 64-bit inline assembly language; and it's pretty fast, and free. It used to be slow on some math; so I'd start out comparing performances of MSVC vs. MinGW to see if its a decent starting place for your application.

Also, as to hand-coded assembly being slower:

  1. Actually, humans very often do code assembly that runs more efficiently than compilers - or at least that was always the common wisdom when I was learning programming in the 70's and 80's and continued to be the case through ~2000.
  2. You can always code it in "C" or C++, compile that to assembly, and tweak it to see if you can improve that. That way, you can learn from optimizations; and see if you can improve on them.

Assembly very much can have a place in code that needs high optimization, no matter what M$ says. You won't really know if assembly will or won't speed up code until you try it. Everything else is just pontificating.

As above, I favor the approach of compiling c++ code into assembly, and then hand-optimizing that. It saves you the trouble of writing much of it; and with a little experimentation, you may get something that tests out faster. FWIW, I've never needed to with a modern program. Often, other things can speed it up just as much or more - e.g. such as multi-threading, using look-up tables, moving time-expensive operations out of loops, using static analyzers, using real-time analyzers such as valgrind (if you're on Linux), etc. However, for performance-critical applications, I see no reason not to try; and just use it if it works. M$ is just being lazy by dropping inline assembly.

As to is 64-bit or 32-bit faster, this is similar to the situation with 16-bit vs. 32-bit. The wider bandwidth can sling huge amounts of data faster. If both run on a 64-bit OS, they run at exactly the same clock speed; so the 32-bit program shouldn't be faster. Yet, I've observed the CPU clock on 32-bit Win7 to run slightly faster than 64-bit Win7. Thus for the same number of threads, and for more CPU intensive operations, a 32-bit app on 32-bit Win7 would be faster. However, the difference isn't much; and 64-bit instructions can really make a difference. However, a given user will only have one OS installed; and so the 64-bit app will be either faster for that OS; or at best the same speed if running a 32-bit app on a 64-bit OS. It will be a larger download, however. You might as well go for the possibly faster speed with 64-bits; unless you are dealing with a dedicated system running code you know won't be moving large amounts of data.

Also, note that I benchmarked a 64-bit and a 32-bit app on OSs of the respective sizes, using the respective versions of MinGW. It did a lot of 64-bit floating point number crunching, and I was sure the 64-bit version would have the edge. It didn't!! My guess is that the floating point registers in the built-in math coprocessor run in equal numbers of clock cycles on both OSs, and perhaps slightly slower on 64-bit Win7. My benchmarks were so close in both versions, that one was not clearly faster. Perhaps long number-crunching operations were slower on 64-bit, but the 64-bit program code ran a little faster - causing nearly equal results.

Basically, the only time 32-bits makes sense, IMHO, is when you think you might have an in-house app that would run faster on a 32-bit OS; you want a really small executable, or when you are delivering to users on 32-bit OS machines (many developers still offer both versions), or a 32-bit embedded system.

Edited to reflect that some of my remarks pertain to my specific experience with Win7 x86 vs. x64.

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    Compilers are much better than they were in the 80s. Constant-propagation after inlining often allows simplifications that inline asm would defeat. Also, modern superscalar out-of-order CPUs are better compiler targets (especially x86-64 with its 16 registers vs. 8 in 32-bit mode is a nice improvement), and the things that slow CPUs down have become more obscure. But compilers are still far from perfect. Commented Apr 26, 2019 at 18:59
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    It's very easy to write code that's slower than a compiler (C++ code for testing the Collatz conjecture faster than hand-written assembly - why?), but yes start with compiler output and benchmarking your changes normally avoids that danger, at least for the microarchitectures you test on. If you're familiar with Agner Fog's microarch PDF (agner.org/optimize) and instruction tables for a range of modern CPUs, then sure have a go at beating the compiler if you really want to. Commented Apr 26, 2019 at 19:02
  • Hand-written code tuned for one uarch might not be perfect for a future uarch, and in theory a compiler 10 years down the road with -march=native on some future CPU could do better. So make sure you maintain a decent C version, for testing and portability as well as to test against compiler-generated asm on future CPUs. Commented Apr 26, 2019 at 19:03
  • I can't say that I disagree with any of that; but I am pointing out that defeating optimizations can be a much smaller issue than improving the performance of CPU Intensive code, depending on the situation. After all, "C++ code for testing the Collatz conjecture faster than hand-written assembly - why?" does indicate some ways humans can think of to optimize assembly that the compiler didn't; e.g. in "Beating the Compiler". I guess we are saying inline assembly can be done with some effort; but make sure you're really beating it in the larger context, and keep around a C++ version.
    – CodeLurker
    Commented Apr 29, 2019 at 10:58
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    the CPU clock on 32-bit OSs runs faster than on 64-bit ones. I've never heard this claim before for either Intel or AMD CPUs, or seen any evidence of it. Max turbo clocks are not limited by running in long mode (full 64-bit mode or compat 32-bit user-space under 64-bit kernel) instead of legacy (pure 32-bit) mode. Neither Agner Fog's optimization guide or microarch guide (agner.org/optimize) nor Intel's own optimization manual says anything about any kind of effect like that. Commented Nov 30, 2019 at 9:40

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