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Is there any good reason to supply a 32-bit version along with a 64-bit version of any software targeted at modern desktop machines, running modern 64-bit operating systems on 64-bit hardware?

It seems that 64-bit software would be more efficient, allow for higher memory usage if needed, etc. Apple even uses 64-bit processors for their phones, even though they only have 1-2 GB of RAM, way below the 4 GB limit for 32-bit CPU's.

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    Not every modern machine runs 64 bit OS
    – Bálint
    Apr 15, 2016 at 9:54
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    Do you have any examples? Apr 15, 2016 at 9:57
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    Ask your customers.
    – Murphy
    Apr 15, 2016 at 9:59
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    Rhetorical question: is there a reason to supply a 64 bit version of any software since most modern 64bit operating systems allow to run 32bit and 64bit applications as well?
    – Doc Brown
    Apr 15, 2016 at 10:03
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    Not a duplicate @gnat. That question is about fitting a timestamp, and a developer id in the error code returned when a program exits. Apr 15, 2016 at 10:05

4 Answers 4

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Benefits of 32-bit software in 64-bit environments

  • Lower memory footprint, especially in pointer-heavy applications, 64-bit vs 32-bit can easily double the memory requirements.
  • Object files are smaller as well.
  • Compatibility with 32-bit environments.
  • Memory leaks are hard capped to 2 GB, 3 GB, or 4 GB and won't swamp the entire system.

Drawbacks of 32-bit software in 64-bit environments

  • 2 GB, 3 GB, or 4 GB memory limit per process. (Just per process, in sum multiple 32-bit processes may use the full available system memory.)
  • Not using additional registers and instruction set extensions depending on x64. This is highly compiler and CPU specific.
  • May require 32-bit versions of all (most Linux distributions) or uncommon (most Windows versions) libraries and run time environments. If a 32-bit version of a shared library is loaded exclusively for your application, and that counts towards your footprint. No difference at all if you are linking statically.

Other aspects

  • Drivers are usually not an issue. Only user-space libraries should differ between 32-bit and 64-bit, not the API of kernel modules.
  • Beware of different default widths for integer datatypes, additional testing needed.
  • The 64-bit CPU architecture may not even support 32-bit at all.
  • Certain techniques like ASLR and others depending on a much larger address space than physical memory won't work well (or at all) in a 32-bit execution mode.

Unless comparing a very specific CPU architecture, operating system and library infrastructure here, I won't be able to go into more details.

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    "The 64bit CPU architecture may not even support 32bit at all." Is this more of a theoretical concern, or does this exist in the world?
    – mucaho
    Apr 15, 2016 at 15:54
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    @mucaho There certainly have been 64-bit-only CPU architectures, such as the Alpha and the IA64. Both of those are moribund, though. I don't know off the top of my head whether there are any currently produced 64-bit-only architectures - AArch64, maybe? Does anyone know whether 32-bit ARM is a mandatory component of that?
    – zwol
    Apr 15, 2016 at 16:13
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    @zwol No, 32-bit is not mandatory for ARM, and neither is 64-bit. There are 64-bit only ARM CPUs, while others support both 32-bit and 64-bit processes.
    – Ext3h
    Apr 15, 2016 at 16:16
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    @Joshua Always existed? Did the pharaohs know this? Apr 15, 2016 at 22:05
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    "64bit vs 32bit can easily double the memory requirements", not quite easily... Most programs have things other than pointers (such as code, strings and so on).
    – hyde
    Apr 16, 2016 at 8:12
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The difference between 32 bit software and 64 bit software is the size of the pointers, and maybe the size of the integer registers. That's it.

That means all pointers in your program are twice the size. And (at least on an ILP32/LP64 architecture) your longs are twice the size as well. This typically works out to about a 30% increase in object code size. This means that …

  • your object code will take ~30% longer to load from disk into RAM
  • your object code will take up ~30% more space in memory
  • you have effectively lowered your memory bandwidth (for object code) by ~20%
  • you have effectively lowered the size of the instruction cache by ~20%

This has a non-negligible negative effect on performance.

Doing this only makes sense if you can "buy back" those performance costs somehow. Basically, there are two ways to do this: you do a lot of 64 bit integer math, or you need more than 4 GiByte mapped memory. If one or both of those is true, it makes sense to use 64 bit software, otherwise it doesn't.

Note: there are some architectures where there are no corresponding 32 or 64 bit variants. In that case, the question obviously doesn't make sense. The most well-known are IA64, which is only 64 bit and has no 32 bit variant, and x86/AMD64 which are, albeit closely related, different architectures, x86 being 32 bit only, AMD64 being 64 bit only.

Actually, that latter statement is not 100% true anymore. Linux recently added the x32 ABI, which allows you to run AMD64 code with 32 bit pointers, so even though that's not a "proper" CPU architecture, it is a way of using the AMD64 architecture in such a way as if it had a native 32 bit variant. This was done precisely because the performance overhead I mentioned above was causing real measurable, quantifiable problems for real-world users running real-world code in real-world systems.

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    What about the extra registers and instructions in amd64 compared to x86? How much does that improve performance? Apr 15, 2016 at 11:44
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    Google for "tagged pointers" used in Objective-C on MacOS X and iOS. Very substantial amounts of objects have no memory allocated whatsoever but the whole object is faked within the pointer on 64 bit systems. (I heard Java does something similar). In C++, std::string on 64 bit often contains up to 22 characters in the object itself without any memory allocation. Substantial memory savings and speed improvements.
    – gnasher729
    Apr 15, 2016 at 13:53
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    Size of pointers and integers is it? What about the larger address space and additional registers in most 64 bit architectures?
    – user22815
    Apr 15, 2016 at 14:18
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    "you've [reduced] the instruction cache by ~20%" is moot since the instruction set is completely different (and often more efficient) Apr 15, 2016 at 16:26
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    "This has a non-negligible negative effect on performance." While this statement is true in an absolute sense, it ignores the fact that the vast, vast majority of applications' performance bottlenecks are not in load time, or memory usage/bandwidth, or number of instructions in the cache.
    – Ian Kemp
    Apr 15, 2016 at 22:26
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If the software needs to interface directly with legacy systems, drivers or libraries, then you may need to supply a 32-bit version, since AFAIK the OS generally (definitely Windows and Linux AFAIK) doesn't allow mixing of 64-bit and 32-bit code within a process.

For example, if your software needs to access specialty hardware, it's not uncommon for customers to operate older models for which only 32-bit drivers are available.

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    You can mix 32 bit and 64 bit in the same process in both Windows and Linux: stackoverflow.com/q/12716419/703382
    – Navin
    Apr 16, 2016 at 8:28
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    @Navin: But is it practical? Could you use a COM component in a 64-bit Windows application (e.g. a .NET application marked as Any CPU running on a 64-bit version of Windows)? Apr 16, 2016 at 11:34
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If your software is a DLL, you MUST provide both 32-bit and 64-bit versions. You have no idea whether the customer will be using 32-bit or 64-bit software to talk to the DLL, and the DLL has to use the same bit-length as the application. This is non-negotiable.

If your software is a standalone executable, it's less clear. If you don't need your software to run on older OSes, you may not need to provide a 32-bit version. Just stick to 64-bit, specify that it requires a 64-bit OS, and job done.

However if you do need your software to run on older OSes then you may actively NOT want to provide a 64-bit version. If you have two versions then you have double the testing, and properly testing software across a range of OS versions and languages is not a quick process. Since 32-bit software runs perfectly happily on a 64-bit platform, it's still fairly common for software to be released only as 32-bit, especially by smaller developers.

Also note that most mobiles are 32-bit. Maybe some high-end ones are 64-bit now, but there's little compelling reason to make that step. So if you're developing cross-platform and might want your code to run on Android as well, staying 32-bit is a safe option.

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    I would argue against your position on reduced testing. I would Instead argue to test on multiple platforms particularly with not only different register sizes but with different byte orders just as an easy way to increase testing and catch subtle errors. In addition I would also do testing on computers that do not meet your recommended minimum hardware requirements as that will also expose additional issues that might not show up otherwise except with very large data sets.
    – hildred
    Apr 15, 2016 at 15:55
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    @hildred With unlimited testing resource, I'd agree. In practise though, if you are in more control over your target then you may not need to do this testing immediately. It's not at all an "easy way" either - for sure you can simulate some of these platforms in a VM, but if you need physical hardware set up then this is involves large amounts of manual (non-automatable) work. It may save you from writing a test harness to test this explicitly, but it's not free by any means.
    – Graham
    Apr 15, 2016 at 16:47
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    Not free, but downright cheap. If you limit your off platform testing to automated tests, the occasional idiot test, used hardware Aside from your setup your costs for successful tests after your initial setup would be limited to power and about 7 man minutes per test pass. The cost for failed tests would of course be higher, but those would usually be worth more (there is always hardware failure). This type of setup is particularly useful to c programmers because it readily exposes a certain class of pointer problems that are otherwise hard to track down.
    – hildred
    Apr 15, 2016 at 17:00

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