I played with 8-bit machines (C64), I used 16-bit machines (Win 3.1), I enjoyed flat 32-bit address space (Linux).

Every time as a user (which was also means being a developer for fun or profit) I felt the need for more bits and welcomed the next wider bit architecture. Accessing to bigger memory space got easier, graphics got better and sound was a bliss after 8-bit.

However when marketing drums started to kick in for 64-bit some years ago I thought, "ok, this is Internet age, they can use this kind of power to do more calculations easier and commodity hardware manufacturers want to spread their portfolio for this kind of market".

Professionally I became a "system programmer" working for mobile devices which some what means being an "embedded programmer" as well. Working mostly on 32-bit from the start ARM architecture based products, it was a while I forgot about different architectures other than being 32-bit.

Also when ARM announced a new 64-bit architecture towards end of 2011, I read it as ARM wants to go into server market, increasing their portfolio. Which makes sense.

Now with new iPhone 5S claiming to be the first 64-bit processor ever used on a smartphone, thoughts became a little bit unsettled in my head again. Mobile devices, being the ultimate personal devices are becoming 64-bit.

So I wonder, is there something I'm missing? What does being 64-bit offers to the users including programmers?

  • 1
    Hmm may be it can be considered as a duplicate, but I would like to see my question as a broader one about visible/senseable features 64-bit architectures, rather than iPhone 5S's 64-bit promotion. And please see my answer there.
    – auselen
    Sep 13, 2013 at 9:05
  • 1
    it's broader, but again, for desktop PCs and servers, the benefits of x64 are obvious. Sep 13, 2013 at 9:07
  • 3
    @MainMa obvious how for end users? You can get more than 4GB of memory on 32-bit architectures. Heard of PAE?
    – auselen
    Sep 13, 2013 at 9:20
  • 3
    PAE is an ugly kludge (i don't even call it a hack). mmap()'ing big files is a great way to do databases, no way to do it with PAE
    – Javier
    Sep 13, 2013 at 13:56
  • 1
    Everyone needs to distinguish between address width from data processing width. On state-of-the-art servers, such as the 60-core Xeon Phi, address width remain at 64-bit, but data processing width has gone to 512-bits. Mobile processors might take a similar turn, with data-processing width expected to increase to take advantage of silicon and energy efficiency improves.
    – rwong
    Sep 13, 2013 at 19:37

3 Answers 3


It's important to distinguish between 64-bit architectures in general and the 64-bit architectures we commonly see. In an abstract sense, a 64-bit architecture just gives you wider registers (bigger numbers and more addressable memory). Looking at concrete examples of architectures, you see that the 32 to 64-bit jump was used as an opportunity to make significant, incompatible, improvements in processor design.

The first one that comes to mind, looking at both x86_64 and ARMv8, you see a significant increase in the number of registers available. Both architectures have doubled the number of general-purpose registers on the processor. This greatly increases the opportunities for optimization of software. Similarly, they have improved vector processing capabilities. Moving to a new, incompatible, architecture gives designers to opportunity to remove little used features that were dragged along through the years for the sake of backwards compatibility.


One major benefit of having a huge address space is that you can represent all storage simply as an address. For example, my laptop has 16 GiByte of RAM and 1 TiByte HDD. With 64 bit addresses, you can easily address all that storage using a unified API. 32 bit wouldn't be enough. I could even individually address all of my USB key fobs, SD cards, microSD cards, external HDDs, NAS, DropBox, Google Drive etc.

Even my phone has 1 GiByte RAM, 4 GiByte internal flash and a 32 GiByte microSD card.

Unfortunately, no operating system does this yet (with the exception of OS/400, which has been doing exactly this since 1989, although it actually has 128 bit addressing), but that would be one benefit.

Even without such futuristic changes, there is a rather simple reason: at the rate RAM capacity in smartphones is growing, we're going to hit the "4 GiByte wall" real soon now.

  • 3
    There is no 4GB wall. You'll get more than 4GB on 32-bit mobiles. It is called "Large Physical Address Extension architecture" on ARM. See infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.ddi0438c/…
    – auselen
    Sep 13, 2013 at 9:22
  • exactly, with LPAE there is "1TB RAM wall" :-P
    – vartec
    Sep 13, 2013 at 10:42
  • 6
    @vartec The 4GiB wall is real and not misleading LPAE is just a workaround.
    – Pieter B
    Sep 13, 2013 at 10:54
  • also when talking about addressing filesystems, flash sizes... systems use pages to address them and that gives you at least 10 bits extra.
    – auselen
    Sep 13, 2013 at 12:43
  • PAE won't let a single process more than 4GB. it doesn't allow you to mmap() a file bigger than 4GB, much less a whole device.
    – Javier
    Sep 13, 2013 at 13:54

The fundamental advantage is larger register size ( and ALU capability ).

Basially, I can now multiply 10 trillion million billion by 7 in one step. Before with 32 bit I had to split the operands into two pieces that could fit in 32 bit registers and use off die memory to store intermediate results.

This doesn't seem like a big deal, until you look at how many time code written for a 32 bit processor has to split a math operand or split a four word hash key ( or high precision floating point ) or something into two pieces to sort or branch on it.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.