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Why is %EAX = %AX and %AX = (%AH + %AL). Why isn't there a counterpart to %AX to equal %EAX?

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1  
Could you elaborate? –  BCS Oct 23 '08 at 1:36
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minor correction, EAX doesn't equal AX, more accurately, AX represents the lower 16-bits (half) of EAX. likewise, AH and AL are the two halves of AX. –  Evan Teran Oct 23 '08 at 2:40
    
@EvanTeran Is it possible to obtain the upper half of EAX as well as the lower half? –  Anderson Green Mar 5 '13 at 15:27
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@AndersonGreen: not directly (see the chart in Mike Thompson's answer). The only way to get the upper half of EAX would be to do some shifting/rotating. For example: ROR EAX, 16; MOV DX AX; ROR EAX, 16. This will put the upper 16-bits of EAX into DX and then restore EAX back to it's original value. Personally, I would have loved to have seen register aliases for the upper halves as well. I think it would have made a lot of code more concise. –  Evan Teran Mar 5 '13 at 15:57

2 Answers 2

up vote 111 down vote accepted

Just for some clarification. In the early microprocessor days of the 1970's, CPUs had only a small number of registers and a very limited instruction set. Typically, the arithmetic unit could only operate on a single CPU register, often referred to as the "accumulator". The accumulator on the 8 bit 8080 & Z80 processors was called "A". There were 6 other general purpose 8 bit registers: B, C, D, E, H & L. These six registers could be paired up to form 3 16 bit registers: BC, DE & HL. Internally, the accumulator was combined with the Flags register to form the AF 16 bit register.

When Intel developed the 16 bit 8086 family they wanted to be able to port 8080 code, so they kept the same basic register structure:

8080/Z80  8086
A         AX
BC        BX
DE        CX
HL        DX
IX        SI    
IY        DI

Because of the need to port 8 bit code they needed to be able to refer to the individual 8 bit parts of AX, BX, CX & DX. These are called AL, AH for the low & high bytes of AX and so on for BL/BH, CL/CH & DL/DH. IX & IY on the Z80 were only ever used as 16 bit pointer registers so there was no need to access the two halves of SI & DI.

When the 80386 was released in the mid 1980s they created "extended" versions of all the registers. So, AX became EAX, BX became EBX etc. There was no need to access to top 16 bits of these new extended registers, so they didn't create an EAXH pseudo register.

AMD applied the same trick when they produced the first 64 bit processors. The 64 bit version of the AX register is called RAX. So, now you have something that looks like this:

|63..32|31..16|15-8|7-0|
               |AH.|AL.|
               |AX.....|
       |EAX............|
|RAX...................|
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There's generally no explanation as to why there isn't a pseudo-register for say 31..16 portion of EAX. I suppose it was not needed... –  Calyth Jan 7 '09 at 21:44
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Actually, there's an undocumented 'feature' in the Z80 (which isn't actually an Intel chip anyway) that allows you to address the IX and IY as high and low bytes. The opcode is a prefix + an HL opcode; if you use an H or L opcode, you get the half-word effect. –  ijw Sep 16 '12 at 0:30
    
I'd say, register correspondence is more like this: 8080/Z80, 8086, x86 Encoding: A AX 000 BC CX 001 DE DX 010 HL BX 011 IX SI 110 IY DI 111 –  noop Oct 1 '12 at 8:10
    
For anyone wanting more information, this is a fairly helpful and concise overview cs.virginia.edu/~evans/cs216/guides/x86.html –  SullX Jun 28 '13 at 19:55
    
Although the splitting registers were no doubt inspired by the 8080, splitting the registers meant that the processor could be viewed as having eight 16-bit registers and no 8-bit registers, or 7+2, or 6+4, or 5+6, or 4+8. In hand-written assembly it might have been helpful if one of the 32-bit registers was separate from the 16-bit ones, and DX:AX together behaved as a 32-bit register (thus allowing 7+2+0, 7+1+2, or 7+0+4 registers of 32/16/8 bits each) but the benefits would probably not have justified the complexity. –  supercat Nov 19 at 23:10

In the old 8-bit days, there was the A register.

In the 16-bit days, there was the 16 bit AX register, which was split into two 8 bit parts, AH and AL, for those times when you still wanted to work with 8 bit values.

In the 32-bit days, the 32 bit EAX register was introduced, but the AX, AH, and AL registers were all kept. The designers did not feel it necessary to introduce a new 16 bit register that addressed bits 16 through 31 of EAX.

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23  
Revenge. Revenge of EAX. –  Paul Nathan Oct 23 '08 at 2:33
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"R"egister, presumably. There are additional new registers that are just named R+number. –  Curt Hagenlocher Oct 23 '08 at 2:33
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Which register is :-P? :D –  Jeff Yates Oct 23 '08 at 3:19
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@Austin - or shift right 16, saving yourself both an opcode and, more importantly, a divide instruction. Not to mention the divide is by 2^16. Otherwise, spot on ;) –  ijw Sep 16 '12 at 0:32
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@HughAllen, Paul Nathan, and Curt Hagenlocher: the "R" in "RAX", "RBX", etc. is itself an abbreviation for "Register Extension". Think "Register Extension for BX = RBX". See section 1.2.7 of the AMD programmer's manual: ptlsim.org/papers/x86-64/Opteron-InstructionSet-24594.pdf –  William Leara Dec 21 '12 at 0:22

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