Nikita Popov 322e2dbee1 [ValueTracking] Use ConstantRange overflow check for signed add; NFC
This is the same change as rL356290, but for signed add. It replaces
the existing ripple logic with the overflow logic in ConstantRange.

This is NFC in that it should return NeverOverflow in exactly the
same cases as the previous implementation. However, it does make
computeOverflowForSignedAdd() more powerful by now also determining
AlwaysOverflows conditions. As none of its consumers handle this yet,
this has no impact on optimization. Making use of AlwaysOverflows
in with.overflow folding will be handled as a followup.

Differential Revision: https://reviews.llvm.org/D59450

llvm-svn: 356345
2019-03-17 21:25:26 +00:00
..
2019-03-08 21:03:06 +00:00

Analysis Opportunities:

//===---------------------------------------------------------------------===//

In test/Transforms/LoopStrengthReduce/quadradic-exit-value.ll, the
ScalarEvolution expression for %r is this:

  {1,+,3,+,2}<loop>

Outside the loop, this could be evaluated simply as (%n * %n), however
ScalarEvolution currently evaluates it as

  (-2 + (2 * (trunc i65 (((zext i64 (-2 + %n) to i65) * (zext i64 (-1 + %n) to i65)) /u 2) to i64)) + (3 * %n))

In addition to being much more complicated, it involves i65 arithmetic,
which is very inefficient when expanded into code.

//===---------------------------------------------------------------------===//

In formatValue in test/CodeGen/X86/lsr-delayed-fold.ll,

ScalarEvolution is forming this expression:

((trunc i64 (-1 * %arg5) to i32) + (trunc i64 %arg5 to i32) + (-1 * (trunc i64 undef to i32)))

This could be folded to

(-1 * (trunc i64 undef to i32))

//===---------------------------------------------------------------------===//