Can someone explain what's the different between
Byte addressable? How is it related to memory size etc.?
Memory units are addressable. That is the only way we can use memory.
In reality, memory is only byte addressable. It means:
- A binary address always points to
a singlebyte only.
- A word is just
a group ofbytes –
8depending upon the data bus
size ofthe CPU.
To understand the memory operation fully, you must be familiar with the various registers of the CPU and the memory ports of the RAM. I assume you know their meaning:
- MAR(memory address register)
- MDR(memory data register)
- PC(program counter register)
- MBR(memory buffer register)
two kinds of memory ports:
Suppose CPU wants to read
a word (say
4 bytes) from the address
xyz onwards. CPU would put the address on the MAR, sends a memory read signal to the memory controller chip. On receiving the address and read signal, memory controller would connect the data bus to
32-bit port and
4 bytes starting from the address
xyz would flow out of the port to the MDR.
If the CPU wants to fetch the next instruction, it would put the address onto the PC register and sends a fetch signal to the memory controller. On receiving the address and fetch signal, memory controller would connect the data bus to
8-bit port and
a single byte long opcode located at the address received would flow out of the RAM into the CPU's MDR.
So that is what it means when we say a certain register is memory addressable or byte addressable. Now what will happen when you put, say
decimal 2 in
binary on the MAR with an intention to read the word
2, not (byte no
2 means bytes
32-bit machine. In real physical memory is byte addressable only. So there is a trick to handle word addressing.
When MAR is placed on the address bus, its
32-bits do not map onto the
32 address lines(
0-31 respectively). Instead, MAR
bit 0 is wired to address bus
line 2, MAR
bit 1 is wired to address bus
line 3 and so on. The upper
2 bits of MAR are discarded since they are only needed for word addresses above
2^32 none of which are legal for our
32 bit machine.
Using this mapping, when MAR is
address 4 is put on the bus, when MAR is
address 8 is put on the bus and so forth.
This image should make it easy to understand: http://i.stack.imgur.com/rpB7N.png
• In the byte addressing scheme, the first word starts at address 0, and the second word starts at address 4.
• In the word addressing scheme, all bytes of the first word are located in address 0, and all bytes of the second word are located in address 1.
The advantage of byte-addressability are clear when we consider applications that process data one byte at a time. Access of a single byte in a byte-addressable system requires only the issuing of a single address. In a 16–bit word addressable system, it is necessary first to compute the address of the word containing the byte, fetch that word, and then extract the byte from the two-byte word. Although the processes for byte extraction are well understood, they are less efficient than directly accessing the byte. For this reason, many modern machines are byte addressable.
Addressability is the size of a unit of memory that has its own address. It's also the smallest chunk of memory that you can modify without affecting its neighbours.
For example: a machine where bytes are the normal 8 bits, and the word-size = 4 bytes. If it's a word-addressable machine, there's no such thing as the address of the second byte of an
int. Dealing with strings (e.g. an array like
char str) becomes inconvenient, because you still store characters packed together. Modifying just
str means loading the word that contains it, doing some shift/and/or operations to apply the change, then doing a word store.
Note that this is different from a machine that doesn't allow unaligned word load/stores (where the low 2 bits of a word address have to be 0). Such machines usually have a byte load/store instruction. We're talking about machines without even that.
CPU addresses might actually still include the low bits, but require them to always be zero (or ignore them). However, after checking that they're zero, the could be discarded, so the rest of the memory system only sees the word address, where two adjacent words have an address that differs by 1 (not 4). However, on a 16-bit CPU where a register can only hold 64k different addresses, you wouldn't likely do this. Each separate CPU address would refer to a different 2 bytes of memory, instead of discarding the low bit. 2B word-addressable memory would let you address 128kiB of memory, instead of just 64kiB with byte-addressable memory.
Fun fact: ARM used to use the low 2 bits of an address as a shuffle control for unaligned word loads. (But it always had byte load/store instructions.)
Note that bit-addressable memory could exist, but doesn't. 8-bit bytes are nearly universally standard now. (Ancient computers sometimes had larger bytes, see the history section of wikipedia's Byte article.)