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# What are 16, 32 and 64-bit architectures?

What do 16-bit, 32-bit and 64-bit architectures mean in case of Microprocessors and/or Operating Systems?

In case of Microprocessors, does it mean maximum size of `General Purpose Register`s or size of `Integer` or number of `Address-line`s or number of `Data Bus line`s or what?

What do we mean by saying "`DOS is a 16-bit OS`", "`Windows in a 32-bit OS`", etc...?

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My original answer is below, if you want to understand the comments.

As you say, there are a variety of measures. Luckily for many CPUs a lot of the measures are the same, so there is no confusion. Let's look at some data (Sorry for image upload, I couldn't see a good way to do a table in markdown).

As you can see, many columns are good candidates. However, I would argue that the size of the general purpose registers (green) is the most commonly understood answer.

When a processor is very varied in size for different registers, it will often be described in more detail, eg the Motorola 68k being described as a 16/32bit chip.

Others have argued it is the instruction bus width (yellow) which also matches in the table. However, in today's world of pipelining I would argue this is a much less relevant measure for most applications than the size of the general purpose registers.

Different people can mean different things, because as you say there are several measures. So for example someone talking about memory addressing might mean something different to someone talking about integer arithmetic. However, I'll try and define what i think is the common understanding.

My take is that for a CPU it means "The size of the typical register used for standard operations" or "the size of the data bus" (the two are normally equivalent).

I justify this with the following logic. The Z80 has an 8bit accumulator and an 8 bit databus, while having 16bit memory addressing registers (IX, IY, SP, PC), and a 16bit memory address bus. And the Z80 is called an 8bit microprocessor. This means people must normally mean the main integer arithmetic size, or databus size, not the memory addressing size.

It is not the size of instructions, as the Z80 (again) had 1,2 and 3 byte instructions, though of course the multi-byte were read in multiple reads. In the other direction, the 8086 is a 16bit microprocessor and can read 8 or 16bit instructions. So I would have to disagree with the answers that say it is instruction size.

For Operating systems, I would define it as "the code is compiled to run on a CPU of that size", so a 32bit OS has code compiled to run on a 32 bit CPU (as per the definition above).

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Can you please elaborate, what do you mean by "Language is sloppy"? – anonymous Aug 29 '10 at 10:52
@JMSA I believe Nick is pointing to the fact that the terms 16-bit, 32-bit, and 64-bit are ambiguous. Their meaning changes slightly depending on what you are describing. – JBirch Aug 29 '10 at 11:01
It isn't the terms that are ambiguous, it's the actual processor designs. The various widths were all optimized separately and thus only loosely related. The rise of C has "encouraged" the data and address widths to be the same, but it wasn't always that way. The actual bus widths were often completely different from either. – hotpaw2 Aug 29 '10 at 11:07
The bit count of CPU's is quite accurately described at Wikipedia, it's not as sloppy as you describe it... – polemon Aug 29 '10 at 13:50
Thanks for comments, hopefully the wording is better now. – Nick Fortescue Aug 29 '10 at 16:39

How many bits a CPU "is", means what it's instruction word length is. On a 32 bit CPU, the word length of such instruction is 32 bit, meaning that this is the width what a CPU can handle as instructions or data, often resulting in a bus line with that width. For a similar reason, registers have the size of the CPU's word length, but you often have larger registers for different purposes.

Take the PDP-8 computer as an example. This was a 12 bit computer. Each instruction was 12 bit long. To handle data of the same width, the accumulator was also 12 bit. But what makes the 12-bit computer a 12 bit machine, was its instruction word length. It had twelve switches on the front panel with which it could be programmed, instruction by instruction.

This is a good example to break out of the 8/16/32 bit focus.

The bit count is also typically the size of the address bus. It therefore usually tells the maximum addressable memory.

There's a good explanation of this at Wikipedia:

In computer architecture, 32-bit integers, memory addresses, or other data units are those that are at most 32 bits (4 octets) wide. Also, 32-bit CPU and ALU architectures are those that are based on registers, address buses, or data buses of that size. 32-bit is also a term given to a generation of computers in which 32-bit processors were the norm.

With OS-es, this is way less bound to the actual "bitty-ness" of the CPU, it usually reflects how opcodes are assembled (for which word length of the CPU) and how registers are adressed (you can't load a 32 bit value in a 16 bit register) and how memory is adressed. Think of it as the completed, compiled program. It is stored as binary instructions and has therefore to fit into the CPUs word length. Task-wise, it has to be able to address the whole memory, otherwise it couldn't do proper memory management.

But what come's down to it, is whether a program is 32 or 64 bit (an OS is essentially a program here) it how its binary instructions are stored and how registers and memory are addressed. All in all, this applies to all kinds of programs, not just OS-es. That's why you have programs compiled for 32 bit or 64 bit.

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Instruction word length is partially internal, sometimes an instruction can be longer than the bus the CPU is connected to program memory (in a von-Neumann design, there is just one address space for both program memory and working memory with stack, etc.), now, especially when using pipelining that instruction can be longer that your bus line. Internally, that opcode has a certain width. Most CPU's use microcode to decode that opcode, this microcode can handle a certain width the instruction can have. That is the instruction word width. – polemon Aug 29 '10 at 17:14
I'm not talking about microcode instructions. A CPU instruction is decoded by the microcode. Now this CPU instruction has a (maximum) length. This length is defined by hardware design of the CPU, and its microcode. – polemon Aug 30 '10 at 4:18
"I always thought the "bits" referred to the bus width." Counter example: the first macs were m68000s (definitely a 32bit chip) but ran on 16bin main buses. It took two cycles to perform a full width fetch or store, but this was invisible to the programmer (abstracted out by the cache architecture) except in terms of sustained memory access speed. – dmckee Aug 30 '10 at 15:16
@Marting: Yes, but keep in mind, the opcode can be longer than the bus line's width! It is very likley, that opcode + data take multiple cylces to be read and then decoded. – polemon Aug 31 '10 at 1:36
@polemon Sorry if I'm extremely slow but I still don't get it... afaik a Pentium 4 is a 32-bit processor, but certainly has opcodes longer than 4 bytes. Or do you mean only the maximum opcode size internally, i.e. after it has been decoded? If so, does that maximum decoded size really matter to a programmer at all? – Martin Aug 31 '10 at 19:15

"x is a y-bit OS" means that "x is written for a y-bit CPU". And "y-bit CPU" means that given CPU has y-bit word length. Contrary to the popular belief it does not have any direct meaning over the maximum physical memory an OS can use.

For instance 16-bit DOS can address up to 640KB, not 64KB (16-bit upper limit for 8086 series) because 16-bit offset registers are complemented with 16-bit segment registers. It can even address more by using memory extending APIs like XMS and EMS.

Similarly 32-bit operating systems can map more than 4GB of physical memory by using techniques like "sliding window"s (such as AWE in Windows). But the OS code is based on 80386 architecture which is 32-bit. (32-bit address registers).

64-bit OS code are written for 64-bit CPUs (AMD64, SPARC, IA-64 etc), but they usually can address FAR LESS than 64-bit register limit because of the reserved bits in physical addresses used.

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A y-bit CPU doesn't mean it's how large the address register is, it is not dependent on it. It depends on the word length it can process in one microcode instruction. A y-bit CPU handles a y-bit width instruction or data at one time in whatever active component it uses, for instance ALU. – polemon Aug 29 '10 at 13:19
Isn't that why address register length is equal to word length? Do you have any example that differs? – Sedat Kapanoglu Aug 30 '10 at 7:32
the Zilog Z80 has an 8-bit arithmetic unit but 16-bit addressing. – dreamlax Aug 30 '10 at 21:55
I stand corrected, thanks folks. I'll edit this out if I can. – Sedat Kapanoglu Aug 30 '10 at 23:25
Should be ok now. – Sedat Kapanoglu Aug 30 '10 at 23:27

http://en.wikipedia.org/wiki/64-bit#64-bit_data_models the data models mean bitness for the language.

The "OS is x-bit" phrase usually means that the OS was written for x-bit cpu mode, that is, 64-bit Windows uses long mode on x86-64, where registers are 64 bits and address space is 64-bits large and there are other distinct differences from 32-bits mode, where typically registers are 32-bits wide and address space is 32-bits large. On x86 a major difference between 32 and 64 bits modes is presence of segmentation in 32-bits for historical compatibility.

Usually the OS is written with CPU bitness in mind, x86-64 being a notable example of decades of backwards compatibility - you can have everything from 16-bit real-mode programs through 32-bits protected-mode programs to 64-bits long-mode programs.

Plus there are different ways to virtualise, so your program may run as if in 32-bits mode, but in reality it is executed by a non-x86 core at all.

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To add, many architectures have only one bitness and therefore only language data models have meaning when talking about bitness on these architectures. Other architectures, such as ARM, are 32-bits per se, but have additional modes, so-called Thumb/Thumb2 which increase instruction density by encoding some instructions in 16 bits instead of 32. They are still considered 32-bits CPUs and OS they run are usually 32 bits. – berkus Aug 30 '10 at 22:22

The difference comes down to the bit width of an instruction set passed to a general purpose register for operating on. 16 bits can operate on 2 bytes, 64 on 8 bytes of instruction at a time. You can often increase throughput of a processor by executing more dense instructions per clock cycle.

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Felt this needed a short explanation rather than 7 long, inaccurate ones. – htmldrum Dec 27 '12 at 18:27

When we talk about 2^n bit architectures in computer science then we are basically talking about memory registers, address buses size or data buses size. The basic concept behind term of 2^n bit architecture is to signify that this here 2^n bit of data can be made use to address/transport the data of size 2^n by processes.

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Very fuzzy!!!!! – anonymous Aug 29 '10 at 10:55
Architectures are not limited to 2^n. 18, 24, and 36 bit architectures were widely used during the mini-computer era. – dmckee Aug 30 '10 at 15:18

The definitions are marketing terms more than precise technical terms.

In fuzzy technical term they are more related to architecturally visible widths than any real implementation register or bus width. For instance the 68008 was classed as a 32-bit CPU, but had 16-bit registers in the silicon and only an 8-bit data bus and 20-odd address bits.

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The 6502 was classed as an 8-bit processor, but had 16-bit address registers, a 16-bit address bus, and 8, 16,and 24-bit instructions. The MIPS architecture had option for 64-bit data and 32-bit addresses or 64-bits for both, but the early implementations only had 32-bit busses. etc. Marketing usually preferred the biggest number possible, unless targeting the extremely low cost embedded market. – hotpaw2 Aug 29 '10 at 11:01

As far as I know, technically, it's the width of the integer pathways. I've heard of 16bit chips that have 32bit addressing. However, in reality, it is the address width. sizeof(void*) is 16bit on a 16bit chip, 32bit on a 32bit, and 64bit on a 64bit.

This leads to problems because C and C++ allow conversions between void* and integral types, and it's safe if the integral type is large enough (the same size as the pointer). This lead to all sorts of unsafe stuff in terms of

``````void* p = something;
int i = (int)p;
``````

Which will horrifically crash and burn on 64bit code (works on 32bit) because void* is now twice as big as int.

In most languages, you have to work hard to care about the width of the system you're working on.

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"Which will horrifically crash and burn on 64bit code (only works on 16bit) because void* is now twice as big as int." This applies to 64-bit Windows, but not x64-Linux where sizeof(int) == 8. – kusma Aug 29 '10 at 11:35
The special cases in which terrible code might actually work should be ignored, not posted. Also, fixed 16bit to 32bit. – Puppy Aug 29 '10 at 12:07