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I took Computer Architecture course and I understood that processor has 32 registers each of 32 bit. Now I am studying computer architecture course in which I read that 8086 has 8 registers only. But the book I read and this website shows many registers. I am getting confused about the registers in 8086 and 8088. Please help me out. Thanks


I have a good understanding of different register sizes in different processors. I am just getting confused in the number of registers. Thanks

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you should invest in a more modern computer :p –  Antony Scott Feb 3 '12 at 14:45
But the basics are almost same for all much as I know :) –  Shen Xu Feb 3 '12 at 15:14

4 Answers 4

up vote 10 down vote accepted

The 8086 and 8088 are 16 bit processors - their registers are 16 bytes in width (AX and DX can be combined to one 32 bit register)

Note that the 8086 has 16 bit data bus; the 8088 has an 8 bit data bus (though they are both 16 bit addressable internally)


8086 CPU has 8 general purpose registers, each register has its own name:

AX - the accumulator register (divided into AH / AL):

Generates shortest machine code
Arithmetic, logic and data transfer
One number must be in AL or AX
Multiplication & Division
Input & Output

BX - the base address register (divided into BH / BL).

CX - the count register (divided into CH / CL):

Iterative code segments using the LOOP instruction
Repetitive operations on strings with the REP command
Count (in CL) of bits to shift and rotate

DX - the data register (divided into DH / DL):

DX:AX concatenated into 32-bit register for some MUL and DIV operations
Specifying ports in some IN and OUT operations

SI - source index register:

Can be used for pointer addressing of data
Used as source in some string processing instructions
Offset address relative to DS

DI - destination index register:

Can be used for pointer addressing of data
Used as destination in some string processing instructions
Offset address relative to ES

BP - base pointer:

Primarily used to access parameters passed via the stack
Offset address relative to SS

SP - stack pointer:

Always points to top item on the stack
Offset address relative to SS
Always points to word (byte at even address)
An empty stack will had SP = FFFEh


CS - points at the segment containing the current program.

DS - generally points at segment where variables are defined.

ES - extra segment register, it's up to a coder to define its usage.

SS - points at the segment containing the stack.

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 12345h (hexadecimal), we could set the DS = 1230h and SI = 0045h. This way we can access much more memory than with a single register, which is limited to 16 bit values. The CPU makes a calculation of the physical address by multiplying the segment register by 10h and adding the general purpose register to it (1230h * 10h + 45h = 12345h):

The address formed with 2 registers is called an effective address. By default BX, SI and DI registers work with DS segment register; BP and SP work with SS segment register. Other general purpose registers cannot form an effective address. Also, although BX can form an effective address, BH and BL cannot.


IP - the instruction pointer:

Always points to next instruction to be executed
Offset address relative to CS

IP register always works together with CS segment register and it points to currently executing instruction.


Flags Register - determines the current state of the processor. They 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.

Carry Flag (CF) - this flag is set to 1 when there is an unsigned overflow. For example when you add bytes 255 + 1 (result is not in range 0...255). When there is no overflow this flag is set to 0.
Parity Flag (PF) - this flag is set to 1 when there is even number of one bits in result, and to 0 when there is odd number of one bits. 
Auxiliary Flag (AF) - set to 1 when there is an unsigned overflow for low nibble (4 bits).
Zero Flag (ZF) - set to 1 when result is zero. For non-zero result this flag is set to 0.
Sign Flag (SF) - set to 1 when result is negative. When result is positive it is set to 0. (This flag takes the value of the most significant bit.)
Trap Flag (TF) - Used for on-chip debugging.
Interrupt enable Flag (IF) - when this flag is set to 1 CPU reacts to interrupts from external devices.
Direction Flag (DF) - this flag is used by some instructions to process data chains, when this flag is set to 0 - the processing is done forward, when this flag is set to 1 the processing is done backward.
Overflow Flag (OF) - set to 1 when there is a signed overflow. For example, when you add bytes 100 + 50 (result is not in range -128...127). 
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I took Computer Architecture course and I understood that processor has 32 registers each of 32 bit.

This doesn't answer your question, but if you want to communicate with annother engineer, you have to use the proper language. Saying "a (some) processor has 32 registers that are 32 bits in size" won't get you anywhere, there are countless numbers of processors.

The 8086 had eight (more or less general) 16-bit registers including the stack pointer, but excluding the instruction pointer, flag register and segment registers. Four of them, AX, BX, CX, DX, could also be accessed as twice as many 8-bit registers (see figure) while the other four, BP, SI, DI, SP, were 16-bit only.

I'm assuming the confusion comes from this sentence on the Wikipedia. Both of the sources you read are right. There are 8 general purpouse registers (in the article it's noted as "more or less general", i've no idea who could write that), they are: AX BX CX DX and SI DI BP SP. There are also segment registers, special purpouse registers and a flag register (which are noted after the "excluding" word, which, i'm guessing, is suppoused to be read as "there are registers, there's 8 of them if you exclude these 3 groups", it's vague).

The issue is in the wording. The quoted sentence is confusing and i can see where your question is comming from. It never hurts to ask, but you should understand that Wikipedia is not a reliable source of knowledge, if you're ever confused, just pick up a book.

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Thanks. I don't understand why everyone else also provides links from Wikipedia to prove their answers or to quote anything. –  Shen Xu Feb 3 '12 at 15:17

The 8086 has 14 16 bits registers. AX, BX, CX, DX, SI, DI, BP, SP, CS, DS, SS, ES, IP and the flags register. The last two are only accessed indirectly.

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-1: The question is not about i386 –  Tomasz Zielinski Feb 3 '12 at 15:55
@DanielKamilKozar: Huh? According to sources, the 80386 was the first processor in this line with FS and GS registers, and so it would be incorrect to include them in a list of the 8086 registers. –  David Cary Jan 20 at 17:56
@DavidCary : I apologise, must've been drunk. Comment deleted. –  Daniel Kamil Kozar Jan 20 at 18:03

Computer architecture books often use MIPS as example because it's rather simple and educational. MIPS has 32 registers but this does not mean that other 32-bit architectures also have 32 registers. 32-bit here only means that the computer has 32 bit address/32 bit integer registers, not related to the number of registers.

ARM, the most popular 32-bit architecture, has 16 register (although ARMv8 64 bit will double this number to 32). Many other 32-bit architectures also have register number other than 32 such as Motoroka 68k and SuperH, which all have 16 registers. For the list of architectures look at here. You see, 64-bit architectures rarely have 64 registers. Most of them will have 32 although some have 128 or 256 registers.

x86, being backward compatible with 8080 many decades ago, has only 8 registers. But in fact x86 nowadays have hundreds of registers inside and use register renaming to overcome the limit in number of registers.

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