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The error NASM gives (dispite my working OS) is "invalid effective address".

Now i've seen many examples of how to use LEA and i think i gots it right but yet my NASM dislikes it. I tried "lea cx, [cx+9]" and it worked; "lea cx, [bx+cx]" didn't.

Now if i extended my registers to 32-bits (i.e. "lea ecx, [ecx*8+ecx]") everything would be well but i am restricted to use 16- and 8-bit registers only.

Is here anyone so knoweledgeable who could explain me WHY my assembler doesn't let me use lea the way i supposed it should be used?


Thank you for the link. How ever the 0x67 prefix confused me: It allows me to use 32-bit addresses thus overriding real mode's 1MB memory limitation??? I it still doesn't enable all possible register conbinations for e.g. LEA...


You can override real mode's 1MB memory limitation even with 16 bytes, for instance with this sequence: mov ax, 0xffff; mov ds, ax; mov bx, ds:[ax]. Now ds:[ax] = 10FFEF > 0xfffff, so you've accessed more than 1MB. – Nathan Fellman

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I think you are mistaken when you say that lea cx, [cx+9] worked. – I. J. Kennedy Apr 27 '10 at 21:41
why not? cx is a valid base register. – Nathan Fellman Apr 28 '10 at 8:26

3 Answers 3

This is because [bx+cx] isn't valid in any addressing mode on 16-bit x86, see this site for more info.

lea cx, [bx+di] or lea cx, [bx+si] should work.

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lea cx,[cx*8+cx] doesn't work because "scale-index-base" addressing is only available with 32-bit registers. It's not a limitation of the assembler--it's a limitation of the processor.

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Not true. It's available with 16-bit registers as well using the 0x67 prefix - address size override. The problem is that the you can't use all combinations of registers. – Nathan Fellman Apr 28 '10 at 4:39
Nathan, it's a bit complicated, but I really don't think you can get lea cx,[cx*8+cx]. The opcode for this instruction is 8D 0C C9. If you're using 16-bit addressing, either when running in a 16-bit code segment, or a 32-bit code segment with an address override, the instruction "devolves" into lea cx,[si] (the 8D 0C part), and the C9 byte will be interpreted as a "leave" instruction. Such is the legacy of the x86 instruction format. – I. J. Kennedy Apr 29 '10 at 2:08
You're right. There's no SIB byte in 16-bit addressing. – Nathan Fellman Apr 29 '10 at 8:01

These following tables for to build a postbyte shows which register can be used as an addressregister and which of them can be combine with a second addressregister(baseregister+indexregister and maybe scaling) to build an address with it. (Observed from the 16 bit address mode, where the D-flag is not set.)

Instruction Prefix                0 or 1 Byte
Address-Size Prefix               0 or 1 Byte
Operand-Size Prefix               0 or 1 Byte
Segment Prefix                    0 or 1 Byte
Opcode                            1 or 2 Byte
Mod R/M (Postbyte)                0 or 1 Byte
SIB, Scale Index Base (386+)      0 or 1 Byte
Displacement                      0, 1, 2 or 4 Byte (4 only 386+)
Immediate                         0, 1, 2 or 4 Byte (4 only 386+)

Format of Postbyte(Mod R/M from Intel-Manual)

MM  - Memeory addressing mode
RRR - Register operand address
MMM - Memoy operand address

RRR Register Names
Filds  8bit  16bit  32bit
000    AL     AX     EAX
001    CL     CX     ECX
010    DL     DX     EDX
011    Bl     BX     EBX
100    AH     SP     ESP
101    CH     BP     EBP
110    DH     SI     ESI
111    BH     DI     EDI


16bit memory (No 32 bit memory address prefix)
MMM   Default MM Field
Field Sreg     00        01          10             11=MMM is reg
000   DS       [BX+SI]   [BX+SI+o8]  [BX+SI+o16]
001   DS       [BX+DI]   [BX+DI+o8]  [BX+DI+o16]
010   SS       [BP+SI]   [BP+SI+o8]  [BP+SI+o16]
011   SS       [BP+DI]   [BP+DI+o8]  [BP+DI+o16]
100   DS       [SI]      [SI+o8]     [SI+o16]
101   DS       [DI]      [DI+o8]     [SI+o16]
110   SS       [o16]     [BP+o8]     [BP+o16]
111   DS       [BX]      [BX+o8]     [BX+o16]
Note: MMM=110,MM=0 Default Sreg is DS !!!!

32bit memory (Has 67h 32 bit memory address prefix)
MMM   Default MM Field
Field Sreg     00        01          10             11=MMM is reg
000   DS       [EAX]     [EAX+o8]    [EAX+o32]
001   DS       [ECX]     [ECX+o8]    [ECX+o32]
010   DS       [EDX]     [EDX+o8]    [EDX+o32]
011   DS       [EBX]     [EBX+o8]    [EBX+o32]
100   SIB      [SIB]     [SIB+o8]    [SIB+o32]
101   SS       [o32]     [EBP+o8]    [EBP+o32]
110   DS       [ESI]     [ESI+o8]    [ESI+o32]
111   DS       [EDI]     [EDI+o8]    [EDI+o32]
Note: MMM=110,MM=0 Default Sreg is DS !!!!


SIB is (Scale/Base/Index)
Note: SIB address calculated as:
<sib address>=<Base>+<Index>*(2^(Scale))

Fild   Default Base
BBB    Sreg    Register   Note
000    DS      EAX
001    DS      ECX
010    DS      EDX
011    DS      EBX
100    SS      ESP
101    DS      o32        if MM=00 (Postbyte)
SS     EBP        if MM<>00 (Postbyte)
110    SS      ESI
111    DS      EDI

Fild  Index
III   register   Note
000   EAX
001   ECX
010   EDX
011   EBX
100              never Index SS can be 00
101   EBP
110   ESI
111   EDI

Fild Scale coefficient
SS   =2^(SS)
00   1
01   2
10   4
11   8


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