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I don't know x86 ASM very well, but I'm rather comfortable with SHARP-z80, and I know by experience that each instruction (mnemonic) has a corresponding byte/word value, and by looking at the hex dump of the assembled binary file I can "read back" the same code I wrote using mnemonics.

In another SO question, somebody claimed that there are some situations where ASM instructions are not translated to their corresponding binary value, but instead are rearranged in a different way by the assembler.

I'm looking especially for cases where disassembling the binary would result in a different ASM code than the original one.

In other words, are there any cases where assembly code is not 1:1 ratio with assembled code?

MikeKwan linked to another question where GCC would modify inline ASM code (in a C project), but, even though that's an interesting topic, it doesn't answer to this question, because GCC is a compiler, and always tries to optimize code and inline ASM trnslation is affected by surrounding C code.

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Are you referring to polymorphic code? i.e. A program that rewrites its own code at runtime? –  Mike Kwan May 26 '12 at 10:12
    
@MikeKwan I'm referring to assembling/linking process. What I mean is: can the binary result of assembling some ASM code with two different assemblers or in two different times, be different (not considering addresses and offsets)? –  Nadir Sampaoli May 26 '12 at 10:16
    
Something like this? stackoverflow.com/a/6533155/712358 –  Mike Kwan May 26 '12 at 10:27
    
@MikeKwan That's not exactly what I was looking for (anyway that's an interesting reading, thanks), since GCC is a compiler it tends to behave like a compiler, rather than like an assembler. Someone told me very self-confidently that some ASM instructions are not translated literally by assemblers. –  Nadir Sampaoli May 26 '12 at 10:31
    
x86 instructions can often be encoded in several ways (special form that uses the accumulator, immediate can be sign-extended or fully specified, memory operands with only a base register can be given an offset of zero, etc). Also, condition codes have many synonyms. –  harold May 26 '12 at 13:35
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1 Answer

up vote 2 down vote accepted

To the extent that the assembler designers think it was helpful, it may substitute equivalent instructions that have other, useful properties.

First, there machines with variable length value operands fields. If an value/offset will fit into any of several variants, it is common for the assembler to substitute the shortest. (In such assemblers, it is also common to be able force a particular size). This is true of instructions that involved immediate operands and indexed addressing.

Many machines have instructions with PC-relative offsets, commonly for JMPs, sometimes for load/store/arithmetic instructions. An assembler on encountering such an instruction during the first pass can determine of the addressed operand precedes the insruction or it has not seen the instruction yet. If preceding, the assembler can choose a short relative form or a long relative form because it knows the offset. If following, the assembler doesn't know the size, and generally chooses a large offset for the instruction that it fills in during pass2. Similarly, there tend to be ways to force the assembler to choose the short form.

Some machines don't have long jump relative instructions. In this case, the assembler will insert a short jmp relative backwards if the the target precedes the jmp and is close by. If the target precedes but is far away, or the target is a forward reference, the assembler may insert a short-relative-jmp on the opposite branch conditions with target being past the next instruction, followed by a long absolute jmp. (I've personally built assemblers like this). This ensures that jmps can always get to their target.

The good news about these tricks is that if you disassemble, you still get a valid assembly program.

Now lets turn to ones that will confuse your disassembler.

A similar trick to jump relative for literal operands may be used if the machine has short-relative addressing for load/store instructions and the programmer apparantly specifies loading of a constant or value a long way away. In this case the assembler changes the instuction to refer to a literal or an address constant following an inserted short relative jmp around that constant. The dissembler thinks everything in the instruction stream is an instruction; in this case, the literal value is not and that would throw the disassembler off. At least there's an unconditional jmp around the literal to guide the disassembler.

Screwier tricks you may find in mature assemblers where every stunt ever imagined is supported. One of my favorites on an 8 bit assemblers were "psueo" instuctions SKIP1, SKIP2, which you can think of as extremely short relative branches. They were really just the opcoode byte of "CMP #8bits" and "CMP #16bits" instructions, and were used to jump around an 8 bit or 16 bit instruction respectively. So, a "one byte" relative jump rather than two. When you're squeezed for space, every byte counts :-{

      SKIP1
      INC    ; 8 bit instruction
      ...

This was also handy when trying to implement a loop where some step shouldn't be performed on loop entry, but needs to be done on further loop iterations:

      SKIP2
LOOP: SHLD  ; 16 bit instruction
      ...
      BNE LOOP

This issue here is that if you disassemble the SKIP1 or SKIP2 instructions, you won't see the INC (or the corresponding 16 bit instruction).

A trick used by assembly language programmers for passing parameters is to place them inline after the call, with the proviso that the called routine adjust the return address appropriately:

      CALL   foo
      DC     param1
      DC     param2

or CALL printstring DC "a variable length string",0

There is no practical way that a disassembler can know that such a convention is being used or what that convention is, so the dissembler is bound to handle this wrong.

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First of all, Thanks for you answer. I see, I'm not a fan of these independent assemblers. In SHARP-z80 you have two different instructions for absolute (jp 0xDDEE) or relative (jr 0xBB) jumps. The assembler then throws an error if you're trying to relative-jump to an address that is more than 0x7F bytes far (either backward or forward). And that's how it should be to me, although by your answer I take that x86 has a single mnemonic that can be translated either into a relative or into an absolute jump. It doesn't seem very handy, but it's just me. –  Nadir Sampaoli May 26 '12 at 19:29
    
The x86 doesn't have a mnemonic that translates to a relative or absolute jmp. Some assemblers do. MASM tends to use one mnemonic (eg., "MOV") to represent many different opcodes depending on operand type and syntax. The purpose of an assembler is to let you write machine instructions under tight control if that;s what you want; most of the machine instructions you write aren't that critical and where the assembler can step in and make a life a bit easier for the bulk of your code, people have augmented them to do so. –  Ira Baxter May 26 '12 at 20:02
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