[IR] LangRef: state explicitly that floats generally behave according to IEEE-754 #102140
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@@ -3572,6 +3572,44 @@ or ``syncscope("<target-scope>")`` *synchronizes with* and participates in the | |
| seq\_cst total orderings of other operations that are not marked | ||
| ``syncscope("singlethread")`` or ``syncscope("<target-scope>")``. | ||
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| .. _floatsem: | ||
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| Floating-Point Semantics | ||
| ------------------------ | ||
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| LLVM floating-point types fall into two categories: | ||
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| - half, float, double, and fp128, which correspond to the binary16, binary32, | ||
| binary64, and binary128 formats described in the IEEE-754 specification. | ||
| - The remaining types, which do not directly correspond to a standard IEEE | ||
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There was a problem hiding this comment. Also the denormal exception There was a problem hiding this comment. What is the denormal exception? Is this about what happens when Given that IEEE says that denormals are not flushed and LLVM assumes the same by default, I don't think this is an exception from "IR float ops behave according to IEEE". |
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| format. | ||
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| For floating-point operations acting on types with a corresponding IEEE format, | ||
| unless otherwise specified the value returned by that operation matches that of | ||
| the corresponding IEEE-754 operation executed in the :ref:`default | ||
| floating-point environment <floatenv>`, except that the behavior of NaN results | ||
| is instead :ref:`as specified here <floatnan>`. (This statement concerns only | ||
| the returned *value*; we make no statement about status flags or | ||
| traps/exceptions.) In particular, a floating-point instruction returning a | ||
| non-NaN value is guaranteed to always return the same bit-identical result on | ||
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There was a problem hiding this comment. What do you mean by "floating-point instruction" here? Is sqrt included? I understand that the main point here is to say that without further IR constructs an instruction like fdiv is assumed to be correctly rounded. IEEE-754 also assumes this of sqrt. I believe the latest version specifies that other math functions should also return correctly rounded results. That's why I think it needs to be explicit here which ones you mean. There was a problem hiding this comment. I meant all the operations that have an equivalent IEEE-754 operation. So yes that would include sqrt, though I was under the impression that it does not include transcendental functions. I am not sure what is the best way to say that. Having a list seems awkward? Should each such operation have a comment, like "This corresponds to <op> in IEEE-754, so if the argument is an IEEE float format then the :ref: There was a problem hiding this comment. This is something that is hard to come up with a good term for. IEEE 754 has a core list of operations in section 5 which is a good starting point, but these omit the minimum/maximum operations (which are section 9.6). Section 9 is "recommended operations", and 9.2 is the main list of transcendental functions you're thinking of; IEEE 754 requires that they be correctly rounded, but C explicitly disclaims that requirement in Annex F. There's also a few functions in C that aren't in IEEE 754, notably ldexp and frexp. (Note too that it was recently brought up in the Discourse forums that the libm intrinsics are meant to correspond to libm semantics, not IEEE 754 semantics.) There was a problem hiding this comment. minimum/maximum don't do any rounding, and already seem to unambiguously describe their semantics in the existing docs, making this clarification much less relevant. So maybe we should just say that this is about the core operations listed in section 5? |
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| all machines and optimization levels. | ||
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There was a problem hiding this comment. Do we need to specify "all machines that support IEEE-754 arithmetic"? I don't know if we support any targets that don't support IEEE-754, but it seems like there should be some provision for that. The C standard, for instance, talks about some transformations that are legal on "IEC 60559 machines." Or are we saying that architectures that don't support IEEE-754 should indicate the differences in the IR or use a different type? There was a problem hiding this comment. Right now, LLVM assumes that all backends implement IEEE-754 arithmetic, and will miscompile code if the backend doesn't do that. One example of a target that does not implement IEEE-754 arithmetic is x86 without SSE, and #89885 has examples of code that gets micompiled due to that. The point of this PR is to make that more explicit. If instead the goal is to make LLVM work with backends and targets that do not implement IEEE-754 arithmetic, that will require changes to optimization passes. There was a problem hiding this comment. We're already at the point where we expect The only hardware deviation from IEEE 754 that we're prepared to accept at this point is denormal handling. I'm reluctant to offer too many guarantees on denormal handling because I'm not up to speed on the diversity of common FP hardware with respect to denormals, but I'm pretty sure there is hardware in use that mandates denormal flushing (e.g., the AVX512-BF16 stuff is unconditionally default RM+DAZ+FTZ, with changing MXCSR having no effect). In short, we already require that hardware supporting LLVM be IEEE 754-ish; this is tightening up the definition in the LangRef to cover what we already agree to be the case. In the putative future that we start talking about cases where There was a problem hiding this comment.
Even there, the pass that causes trouble in #89885 would lead to miscompilations. So non-standard denormal handling is only supported with an explicit marker, which works very similar to the markers required for non-default FP exception handling. |
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There was a problem hiding this comment. I would add "This also means that backends are not allowed to implement floating-point instructions using larger floating-point types unless they take care to consistently narrow the results back to the original range without inducing double-rounding." or some similar text that makes it clear that mapping There was a problem hiding this comment. IMO that is covered by "backends cannot change the precision of these operations". If we start listing all the consequences of that statement, we'll never be done... |
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| This means that optimizations and backends may not change the observed bitwise | ||
| result of these operations in any way (unless NaNs are returned), and frontends | ||
| can rely on these operations providing perfectly rounded results as described in | ||
| the standard. | ||
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| Various flags and attributes can alter the behavior of these operations and thus | ||
| make them not bit-identical across machines and optimization levels any more: | ||
| most notably, the :ref:`fast-math flags <fastmath>` as well as the ``strictfp`` | ||
| and ``denormal-fp-math`` attributes. See their corresponding documentation for | ||
| details. | ||
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| If the compiled code is executed in a non-default floating-point environment | ||
| (this includes non-standard behavior such as subnormal flushing), the result is | ||
| typically undefined behavior unless attributes like ``strictfp`` and | ||
| ``denormal-fp-math`` or :ref:`constrained intrinsics <constrainedfp>` are used. | ||
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There was a problem hiding this comment. This paragraph is basically an exact duplicate of the second paragraph in the The way I view it, the |
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| .. _floatenv: | ||
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| Floating-Point Environment | ||
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@@ -3608,10 +3646,11 @@ are not "floating-point math operations": ``fneg``, ``llvm.fabs``, and | |
| ``llvm.copysign``. These operations act directly on the underlying bit | ||
| representation and never change anything except possibly for the sign bit. | ||
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| Floating-point math operations that return a NaN are an exception from the | ||
| general principle that LLVM implements IEEE-754 semantics. Unless specified | ||
| otherwise, the following rules apply whenever the IEEE-754 semantics say that a | ||
| NaN value is returned: the result has a non-deterministic sign; the quiet bit | ||
| and payload are non-deterministically chosen from the following set of options: | ||
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| - The quiet bit is set and the payload is all-zero. ("Preferred NaN" case) | ||
| - The quiet bit is set and the payload is copied from any input operand that is | ||
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@@ -3943,7 +3982,7 @@ Floating-Point Types | |
| - Description | ||
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| * - ``half`` | ||
| - 16-bit floating-point value (IEEE-754 binary16) | ||
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| * - ``bfloat`` | ||
| - 16-bit "brain" floating-point value (7-bit significand). Provides the | ||
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@@ -3952,24 +3991,20 @@ Floating-Point Types | |
| extensions and Arm's ARMv8.6-A extensions, among others. | ||
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| * - ``float`` | ||
| - 32-bit floating-point value (IEEE-754 binary32) | ||
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| * - ``double`` | ||
| - 64-bit floating-point value (IEEE-754 binary64) | ||
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| * - ``fp128`` | ||
| - 128-bit floating-point value (IEEE-754 binary128) | ||
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| * - ``x86_fp80`` | ||
| - 80-bit floating-point value (X87) | ||
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| * - ``ppc_fp128`` | ||
| - 128-bit floating-point value (two 64-bits) | ||
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| X86_amx Type | ||
| """""""""""" | ||
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