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The title says everything. I am talking about C/C++ specifically, because both consider this as "implementation issue". I think, defining a standard interface can ease building a module system on top of it, and many other good things.
What could C/C++ "lose" if they defined a standard ABI?

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What does ABI stand for? Seems like a known acronym, but I wasn't able to find a definition. –  0xA3 Jan 17 '10 at 23:42
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ABI is application binary interface. en.wikipedia.org/wiki/Application_binary_interface –  Amuck Jan 17 '10 at 23:43
    
Even C does not have a fully fledged standard ABI. It has a standard ABI for each system based on the standard lib for that system. –  Loki Astari Jan 18 '10 at 1:14
    
Martin: what did you mean when you typed "C" in that comment? I presume you meant something else, maybe something like "a compiler"? –  Justin Smith Jan 18 '10 at 3:57
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@MSalters: That is what I was trying to say. The compiler does not define it, the compiler inherits it from the standard lib (which may not even be written in C). But the compiler must generate code that is binary compatible (and thus conform to the ABI used by the standard lib). I was not aware it was defined by the platform, but that makes sense as the platform (I assume Hardware/OS) then determines how the standard lib is built. In summary I was trying to say (but badly) the compiler implements the C ABI defined by the platform. –  Loki Astari Jan 18 '10 at 8:24

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The freedom to implement things in the most natural way on each processor.

I imagine that c in particular has conforming implementations on more different architectures than any other language. Abiding by a ABI optimized for the currently common, high-end, general-purpose CPUs would require unnatural contortions on some the odder machines out there.

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Very much agreed. On many platforms, you'd like to pass arguments in registers for speed, but you don't want to use all the registers for argument passing. But different platforms have different numbers of registers. Some platforms have no floating-point registers at all. Any completely general ABI would be suboptimal on nearly every platform. –  Stephen Canon Jan 17 '10 at 23:32
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One of the reasons C became so popular was because it didn't specify a standard ABI (IIRC, Pascal did). Thus, compiler writers could do whatever worked best. Initially, everyone did pretty much the same thing in terms of stack framing, but later, for architectures like DSPs, they started to specify ways to pack function arguments into registers, greatly reducing the number of instructions and memory transactions needed for a function call. –  Mike DeSimone Jan 17 '10 at 23:44
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I remember an architecture which had a 32-register file visible to the programmer, but implemented it in hardware as a 512-register block with a sliding window. r0-r7 were parameters passed to a called function, r8-r15 were function locals, r16-r23 were parameters passed in from the function's caller, and r24-r31 were globals, including the stack pointer. r24-31 would always point to the same place, but the others were mapped through a window that would slide down 16 registers with a function call (mapping the caller's r0-7 to the callee's r16-r23), then slide back 16 on return. –  Mike DeSimone Jan 17 '10 at 23:48
    
@Mike @Stephan: Great comments. –  dmckee Jan 17 '10 at 23:57
    
@Mike: That sounds very much like SPARC, but different generations had different amounts of HW registers before they spilled over to RAM. –  MSalters Jan 18 '10 at 8:13

Backwards compatibility on every platform except for the one whose ABI was chosen.

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Alternately, whoever standardizes this could refuse to choose any existing ABI (presumably because nobody could agree on a competitor's), and then nobody would have backward compatibility. –  David Thornley Jan 17 '10 at 23:33
    
And then nobody would adhere to the standard. –  Stephen Canon Jan 17 '10 at 23:38
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We don't have backward compatibility now. Every time a compiler is updated you may be required to re-compile all your libs to conform to the new ABI it defines. –  Loki Astari Jan 18 '10 at 1:10
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@Stephen: GCC did 3 times in the previous version. 2.9x -> 3.0 (break: New ABI) 3.0 -> 3.1 (break Bug Fix) 3.1 -> 3.2 (break Something else) –  Loki Astari Jan 18 '10 at 2:24
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There may have been problems in C++ with GCC, but I don't recall any problems with C. –  Jonathan Leffler Jan 18 '10 at 5:15

Rather than a generic ABI for all platforms (which would be disastrous as it would only be optimal for only one platform). The standard's committee could say that each platform will conform to a specific ABI.

But: Who defines it (the first compiler through the door?). In which case they get an excessive competitive advantage. Or a committee after 5 years of compilers (which would be another horrible idea).

Also it does not give the compiler leaway to do further research into new optimization strategies, you would be stuck with the tricks available at the point where the standard was defined.

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Execution speed would suffer drastically on a majority of platforms. So much so that it would likely no longer be reasonable to use the C language for a number of embedded platforms. The standards body could be liable for an antitrust suit brought by the makers of the various chips not compatible with the ABI.

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Run for your life, they've got Lawyers! –  dmckee Jan 17 '10 at 23:38

The C (or C++) language specifications define the source language. They don't care about the processor running it (A C program could even be interpreted by a human slave, but that would be unethical and not cost-effective).

The ABI is by definition something about the target system. It is related to the processor and the system (and the existing libraries following the ABI).

In the past, it did happen that some processors had proprietary (i.e. undisclosed) specification (even their machine instruction set was not public), and they had a non-public ABI which was followed by a compiler (respecting more or less the language standard).

Defining a programming language don't require the same skill sets as defining the ABI.

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Well, there wouldn't be one standard ABI, but about 1000. You would need one for every combination of OS and processor architecture.

Initially, nothing would be lost. But eventually, somebody would find some horrible bug and they would either fix it, breaking the ABI, or leave it, causing problems.

I think that the situation right now is fine. Any OS is free to define an ABI for itself (and they do), which makes sense. It should be the job of the OS to define its ABI, not the C/C++ standard.

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Or the developer, for those developing code that runs without an OS. –  Justin Smith Jan 17 '10 at 23:49

C always had a standard ABI, which is even the one used for any most standard ABI (I mean, the C ABI is the ABI of choice, when different languages or systems has to bind to each others). The C ABI is kind of common ABI of others ABIs. C++ is more complex although extending and thus based on C, and indeed, a standard ABI for C++ is more challenging and may present issues to the freedom a C++ compiler have for its own implementation of the target machine code. However, it seems to actually have a standard ABI; see Itanium C++ ABI.

So the question may not be that much “what could they loose?”, but rather “what do they loose?” (if ever they really loose something).

Side note: needed to keep in mind ABIs are always architecture and OS dependant. So if what was meant by “Standard ABI” is “standard across architectures and platforms”, then there may never has been or be such thing, but communication protocols.

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