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Study guide question: I have no idea what the difference is between writing it in 16bit and 32 bit, though. Can someone clarify how that changes things?

Write an 80x86 assembly program that will add word size signed integers in memory and stop when it sees a zero. The sum will always be greater than -32768 and less than 32767. The sum should be written to memory. If only a zero is in the string of integers place a 0 in total. Use the JNZ command. (If the last operation results in a zero jump to a label.)

16bit integs DW 2,-300, 54, 30, 8,,-240, 0 total DW ?

32bit integs WORD 2,-300, 54, 30, 8,,-240, 0 total WORD ?

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I don't get why I receive -1 sometimes. This is a perfectly legitimate question: how do you account for the difference between 16bit and 32bit when programming in x86? sometimes people here confuse me. – Aerovistae Mar 23 '12 at 17:26
up vote 3 down vote accepted

There are several differences in 32-bit code as opposed to 16-bit:

  • First and foremost, of course, your registers and indexes and data reads are typically 32 bits wide. (You can change this with address-size and operand-size prefixes. Typically you won't use the address-size prefix, but for 32-bit code reading 16-bit words, i can see the operand-size prefix being used pretty extensively. Some assemblers will take care of that for you.)

  • The 32-bit registers have names starting with E, and are basically extensions of the 16-bit registers. (For example, AX is the low word of EAX. Unfortunately, there's no built-in way to access the high word. You'll have to rotate or shift the register to get to the upper 16 bits.)

  • Indexing is different as well. 16-bit code is far more limited in how it can combine registers. You'll see a lot of [BX+SI], but IIRC [AX+BX] isn't even legal. It is in 32-bit code. Plus, 32-bit code can scale the first term (times 1, 2, 4...i forget whether 8 is allowed). For example, [EBX*4+ECX].

  • In 16-bit code, the registers have rather strict purposes; for example, CX is a counter, BX is basically a base pointer, SI and DI are indexes -- hence their names. Working against that tends to mean jumping through hoops. In 32-bit code, this is noticeably relaxed; while the registers still mostly retain their special purposes, the more flexible indexing lets just about any free register serve as an index.

  • Protected mode is pretty much always on. (There's special cases, but they're not common anymore. You'd have to be writing a DOS game or something to see it; every decent OS jumps into protected mode as soon as it can.) There's a bunch of restrictions and such that go along with it. Most will be invisible to you unless you try to do kernel-level stuff, though. Most 16-bit code is intended to run in "real mode" or "virtual 8086" mode, where the CPU basically acts like a really fast 8086, funky addressing and all.

  • Oh yeah, addressing. 16-bit code uses "segments", where the segment registers (CS, DS, etc) are simply shifted left by 4 bits and added to the "offset" to give you a 20-bit value (max: 1MB). 32-bit code is nowhere near that regular, but also nowhere near that limited; it repurposes the segment registers as "selectors", which can point just about anywhere in the CPU's address space, but have to be set up in a descriptor table (GDT or LDT). In practice, 32-bit code almost always sets all the segments to point to the same region of memory. That's called a "flat model", and is by far the most common setup. 16-bit code has like a half dozen different memory models, depending on how big the code and data need to be.

The directives/instructions for raw data are typically the same; DW still typically means "this is a word", DD means "this is a dword", etc.

By the way, "x86" and "80x86" typically imply "32-bit" -- mostly because the term wasn't common til 32-bit CPUs came about.

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The assembler code is different and the generated object code is different. Your study guide is prehistoric, forget about 16-bit and write it in 32-bit, (or 64!). When your prof/tutor says that the limits on the sum strongly suggest that 16-bit code was being requested, say "Only dinosaurs remember 16-bit code", (you may want to consider a backup course :).

It seems that I misunderstood your question? If you are given no choice by the study guide, then yes, you are stuck with 16-bit instructions and the old 16-bit registers - AX, BX, CX, DX, PC, SP, SI, DI and possibly the segment registers as well.

I have no idea how to actually generate 16-bit code these days, especially on a 64-bit box that has problems running 16-bit code at all. On a 32-bit box, or with some utility like DosBox, you could run the old MASM assembler and then the executable.

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Haha yes I thought of that as well, but what I'm concerned with here is how is the assembler code different? – Aerovistae Mar 23 '12 at 13:32
BTW, you can use 16-bit instructions in a 32-bit assembly - the assembler inserts a prefix to the instruction to force a 16-bit operation. – Martin James Mar 23 '12 at 13:32
That's really not helpful at all. – adelphus Mar 23 '12 at 13:32
It doesn't matter one bit how out of date you think the study guides are. If that is the curriculum, you need to follow it. You may just as well tell the prof that assembly language is so out of date you've decided to code it in Python. Let's see how well that works out when you get your marks back :-) – paxdiablo Mar 23 '12 at 13:33
I assumed from the question that the study guide gave a choice! – Martin James Mar 23 '12 at 13:39

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