I've got to learn assembly and I'm very confused as to what the different registers do/point to.
On some architectures, AFAIK, all registers are created equal, and there is really no difference beyond the name of the register. On x86 you can mostly use any registers for general-purpose computing, but some registers are implicitly bound to the instruction set.
Lots of information about special purposes for registers can be found here.
The x86 instruction set is a complex beast, really. Many instructions have shorter forms that implicitly use one register or another. Some registers can be used to do certain addressing while others cannot.
The Intel 80386 Programmer's Reference Manual is a irreplaceable resource, it basically tells you everything there is to know about x86 assembly, except for newer extensions.
The PC Assembly (e)book is a great resource for learning assembly.
The stack is known as a LIFO structure (last-in, first-out), meaning that the last thing pushed on is the fist thing popped off. It's used, among other things, to implement the ability to call functions.
This means that it's a fixed reference to locate local variables, passed parameters and so forth on the stack, for a given level (while
If you're looking at assembly language like:
you're seeing the code access a stack-level-specific variable.
Perhaps the simplest place to start is here. It's specific to the 8086 but the concepts haven't changed that much. The simplicity of the 8086 compared to the current crop will be a good starting point for your education. Once you've learned the basics, it will be much easier to move up to the later members of the x86 family.
Transcribed here and edited quite a bit, to make the answer self-contained.
GENERAL PURPOSE REGISTERS
8086 CPU has 8 general purpose registers, each register has its own name:
Although it is possible to store any data in the segment registers, this is never a good idea. The segment registers have a very special purpose - pointing at accessible blocks of memory.
Segment registers work together with general purpose register to access any memory value. For example, if we would like to access memory at the physical address
The CPU makes a calculation of the physical address by multiplying the segment register by
The address formed with 2 registers is called an effective address.
This usage is for real mode only (which is the only mode the 8086 had). Later processors changed these registers from segments to selectors and they are used to lookup addresses in a table, rather than having a fixed calculation performed on them.
SPECIAL PURPOSE REGISTERS
Determines the current state of the processor. These flags are modified automatically by CPU after mathematical operations, this allows to determine the type of the result, and to determine conditions to transfer control to other parts of the program.
Generally you cannot access these registers directly.
Here's a simplified summary:
ESP is the current stack pointer, so you generally only update it to manipulate stack, and EBP is intended for stack manipulation too, for example saving the value of ESP before allocating stack space for local variables. But you can use EBP as a general purpose register too.
ESI is the Extended Source Index register, "string" (different from C-string, and I don't mean the type of C-string women wear either) instructions like MOVS use ESI and EDI.
x86 CPUs have these special registers called "segment registers", each of them can point to different address, for example DS (commonly called data segment) may point to 0x1000000, and SS (commonly called stack segment) may point to 0x2000000.
When you use EBP and ESP, the default segment register used is SS, for ESI (and other general purpose registers), it's DS. For example, let's say DS=0x1000000, SS=0x2000000, EBP=0x10, ESI=0x10, so:
You can also specify a segment register to use, overriding the default:
In terms of addition, subtraction, logical operations, etc, there's no real difference between them.