Index: lib/Transforms/Utils/SimplifyCFG.cpp =================================================================== --- lib/Transforms/Utils/SimplifyCFG.cpp +++ lib/Transforms/Utils/SimplifyCFG.cpp @@ -5544,25 +5544,23 @@ // Now we have signed numbers that have been shifted so that, given enough // precision, there are no negative values. Since the rest of the transform // is bitwise only, we switch now to an unsigned representation. - uint64_t GCD = 0; - for (auto &V : Values) - GCD = GreatestCommonDivisor64(GCD, (uint64_t)V); // This transform can be done speculatively because it is so cheap - it - // results in a single rotate operation being inserted. This can only happen - // if the factor extracted is a power of 2. - // FIXME: If the GCD is an odd number we can multiply by the multiplicative - // inverse of GCD and then perform this transform. + // results in a single rotate operation being inserted. // FIXME: It's possible that optimizing a switch on powers of two might also // be beneficial - flag values are often powers of two and we could use a CLZ // as the key function. - if (GCD <= 1 || !isPowerOf2_64(GCD)) - // No common divisor found or too expensive to compute key function. - return false; - unsigned Shift = Log2_64(GCD); + // countTrailingZeros(0) returns 64. As Values is guaranteed to have more than + // one element and LLVM disallows duplicate cases, Shift is guaranteed to be + // less than 64. + unsigned Shift = 64; for (auto &V : Values) - V = (int64_t)((uint64_t)V >> Shift); + Shift = std::min(Shift, countTrailingZeros((uint64_t)V); + assert(Shift < 64); + if (Shift > 0) + for (auto &V : Values) + V = (int64_t)((uint64_t)V >> Shift); if (!isSwitchDense(Values)) // Transform didn't create a dense switch.