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git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@103219 91177308-0d34-0410-b5e6-96231b3b80d8
134 lines
4.9 KiB
Plaintext
134 lines
4.9 KiB
Plaintext
//===----------------------------------------------------------------------===//
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// Representing sign/zero extension of function results
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//===----------------------------------------------------------------------===//
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Mar 25, 2009 - Initial Revision
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Most ABIs specify that functions which return small integers do so in a
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specific integer GPR. This is an efficient way to go, but raises the question:
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if the returned value is smaller than the register, what do the high bits hold?
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There are three (interesting) possible answers: undefined, zero extended, or
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sign extended. The number of bits in question depends on the data-type that
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the front-end is referencing (typically i1/i8/i16/i32).
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Knowing the answer to this is important for two reasons: 1) we want to be able
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to implement the ABI correctly. If we need to sign extend the result according
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to the ABI, we really really do need to do this to preserve correctness. 2)
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this information is often useful for optimization purposes, and we want the
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mid-level optimizers to be able to process this (e.g. eliminate redundant
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extensions).
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For example, lets pretend that X86 requires the caller to properly extend the
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result of a return (I'm not sure this is the case, but the argument doesn't
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depend on this). Given this, we should compile this:
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int a();
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short b() { return a(); }
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into:
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_b:
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subl $12, %esp
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call L_a$stub
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addl $12, %esp
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cwtl
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ret
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An optimization example is that we should be able to eliminate the explicit
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sign extension in this example:
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short y();
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int z() {
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return ((int)y() << 16) >> 16;
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}
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_z:
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subl $12, %esp
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call _y
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;; movswl %ax, %eax -> not needed because eax is already sext'd
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addl $12, %esp
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ret
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//===----------------------------------------------------------------------===//
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// What we have right now.
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//===----------------------------------------------------------------------===//
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Currently, these sorts of things are modelled by compiling a function to return
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the small type and a signext/zeroext marker is used. For example, we compile
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Z into:
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define i32 @z() nounwind {
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entry:
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%0 = tail call signext i16 (...)* @y() nounwind
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%1 = sext i16 %0 to i32
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ret i32 %1
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}
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and b into:
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define signext i16 @b() nounwind {
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entry:
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%0 = tail call i32 (...)* @a() nounwind ; <i32> [#uses=1]
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%retval12 = trunc i32 %0 to i16 ; <i16> [#uses=1]
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ret i16 %retval12
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}
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This has some problems: 1) the actual precise semantics are really poorly
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defined (see PR3779). 2) some targets might want the caller to extend, some
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might want the callee to extend 3) the mid-level optimizer doesn't know the
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size of the GPR, so it doesn't know that %0 is sign extended up to 32-bits
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here, and even if it did, it could not eliminate the sext. 4) the code
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generator has historically assumed that the result is extended to i32, which is
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a problem on PIC16 (and is also probably wrong on alpha and other 64-bit
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targets).
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//===----------------------------------------------------------------------===//
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// The proposal
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//===----------------------------------------------------------------------===//
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I suggest that we have the front-end fully lower out the ABI issues here to
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LLVM IR. This makes it 100% explicit what is going on and means that there is
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no cause for confusion. For example, the cases above should compile into:
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define i32 @z() nounwind {
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entry:
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%0 = tail call i32 (...)* @y() nounwind
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%1 = trunc i32 %0 to i16
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%2 = sext i16 %1 to i32
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ret i32 %2
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}
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define i32 @b() nounwind {
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entry:
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%0 = tail call i32 (...)* @a() nounwind
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%retval12 = trunc i32 %0 to i16
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%tmp = sext i16 %retval12 to i32
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ret i32 %tmp
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}
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In this model, no functions will return an i1/i8/i16 (and on a x86-64 target
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that extends results to i64, no i32). This solves the ambiguity issue, allows us
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to fully describe all possible ABIs, and now allows the optimizers to reason
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about and eliminate these extensions.
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The one thing that is missing is the ability for the front-end and optimizer to
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specify/infer the guarantees provided by the ABI to allow other optimizations.
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For example, in the y/z case, since y is known to return a sign extended value,
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the trunc/sext in z should be eliminable.
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This can be done by introducing new sext/zext attributes which mean "I know
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that the result of the function is sign extended at least N bits. Given this,
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and given that it is stuck on the y function, the mid-level optimizer could
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easily eliminate the extensions etc with existing functionality.
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The major disadvantage of doing this sort of thing is that it makes the ABI
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lowering stuff even more explicit in the front-end, and that we would like to
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eventually move to having the code generator do more of this work. However,
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the sad truth of the matter is that this is a) unlikely to happen anytime in
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the near future, and b) this is no worse than we have now with the existing
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attributes.
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C compilers fundamentally have to reason about the target in many ways.
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This is ugly and horrible, but a fact of life.
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