# how long is a memory address typically in bits

I am confused with so many terminologies that my instructor talks about such as `word`,`byte addressing` and `memory location`.

I was under the impression that for a `32-bit processor`, it can address upto `2^32 bits`, which is `4.29 X 10^9 bits (NOT BYTES)`.

The way I think now is:

The `memory` is like an `array` of `buckets` each of `1 byte length`.

when we say `byte addressing` (which I guess is the most common ones), each `char` is `1 byte` and is retrieved from the first bucket (say for example). for `int` the next `4 bytes` are put together in `little-endian ordering` to compute the `Integer` value.

so each memory, I see it as, `8 bits` or `1 byte`, which can give upto `2^8 locations`, this is far less than what `cpu` can address.

There is some very basic mis-understanding here on my part which if some experts can explain in simple terms that a prosepective CS-major student can it in once forever.

I have read various pages including this one on word and here the `unit of address resolution` is given as `8b` for `ARM`, which adds more to my confusion.

• Byte addressable, not byte addressing. Memory locations are 8-bits, but pointers are 32 bits (or 64 or whatever), not 8. Jan 29, 2018 at 16:23

The processor uses 32 bits to store an address. With 32 bits, you can store 2^32 distinct numbers, ranging from 0 to 2^32 - 1. "Byte addressing" means that each byte in memory is individually addressable, i.e. there is an address x which points to that specific byte. Since there are 2^32 different numbers you can put into a 32-bit address, we can address up to 2^32 bytes, or 4 GB.

It sounds like the key misconception is the meaning of "byte addressing." That only means that each individual byte has its own address. Addresses themselves are still composed of multiple bytes (4, in this case, since four 8-bit bytes are taken together and interpreted as a single 32-bit number).

I was under the impression that for a 32-bit processor, it can address upto 2^32 bits, which is 4.29 X 10^9 bits (NOT BYTES).

This is typically not the case -- bit-level addressing is quite rare. Byte addressing is far more common. You could design a CPU that worked this way, though. In that case as you said, you would be able to address up to 2^32 bits = 2^29 bytes (512 MiB).

• I read this 3 times and each time I am understanding it better. how does the `word size` come into play here? Jan 17, 2014 at 22:30
• @eagertoLearn The "word size" is the size of the numbers that the processor operates on. When it (say) adds two numbers together, the word size is the size of those numbers. Word size is commonly, but not always, the same as the address size. Jan 17, 2014 at 22:35
• is there any advantage of using byte addressing. since the technology has grown so much, why the addressing has not gone up? Jan 17, 2014 at 22:43
• @eagertoLearn The advantage would be being able to address more total memory. The disadvantage is that any code that needs to deal with individual bytes becomes much more complex, since it has to separate the bytes from each addressable word. These days, with 64-bit machines allowing (currently) up to 2^44 = 16 TB (current 64-bit implementations do not use all address bits), and (eventually) up to 2^64 = 16 exabytes, there is no motivation to move away from byte addressing. Jan 17, 2014 at 22:47
• @ViníciusPJ Quite right. Well spotted - I've edited the answer. Thanks! Sep 25, 2019 at 20:41