[MLIR][KernelGen] Add `tf.Asinh` kernels and complete their lowerings

PiperOrigin-RevId: 352604725

include/mlir-hlo/Dialect/mhlo/IR/chlo_ops.h

@@ -66,8 +66,6 @@ static Value getConstantLike(OpBuilder& b, Location loc, T constant,
   return b.create<ConstantLikeOp>(loc, getAttr(), val);
 }
 
-Value getConstantLikeMaxFiniteValue(OpBuilder& b, Location loc, Value val);
-
 }  // namespace chlo
 }  // namespace mlir
 

include/mlir-hlo/Dialect/mhlo/IR/chlo_ops.td

@@ -372,18 +372,6 @@ def HLOClient_AsinOp : HLOClient_UnaryElementwiseOp<"asin", [],
   }];
 }
 
-def HLOClient_AsinhOp : HLOClient_UnaryElementwiseOp<"asinh", [],
-    HLO_FpOrComplexTensor> {
-  let summary = "Asinh operation";
-
-  let description = [{
-    Returns `Asinh(operand)` element-wise.
-
-    $$
-    \asinh(x) = log(x + sqrt(x^2 + 1))
-    $$
-  }];
-}
 def HLOClient_AtanOp : HLOClient_UnaryElementwiseOp<"atan", [],
     HLO_FpOrComplexTensor> {
   let summary = "Atan operator";

include/mlir-hlo/Dialect/mhlo/IR/hlo_utils.td

@@ -30,9 +30,6 @@ class ConstantSplat<string value> : NativeCodeCall<
 class HLO_ConstantLike<string value> : NativeCodeCall<
     "chlo::getConstantLike($_builder, $_loc, " # value # ", $0)">;
 
-def HLO_ConstantLikeMaxFiniteValue : NativeCodeCall<
-    "chlo::getConstantLikeMaxFiniteValue($_builder, $_loc, $0)">;
-
 def NullDenseIntElementsAttr : NativeCodeCall<"DenseIntElementsAttr()">;
 
 def BinBroadcastDimensions : NativeCodeCall<

lib/Dialect/mhlo/IR/chlo_ops.cc

@@ -32,20 +32,6 @@ static LogicalResult Verify(T op) {
   return success();
 }
 
-static constexpr float kF16MaxFiniteValue = 0x1.ffcP15;
-
-Value getConstantLikeMaxFiniteValue(OpBuilder& b, Location loc, Value val) {
-  Type ty = getElementTypeOrSelf(val.getType());
-  if (ty.isF16()) {
-    return getConstantLike(b, loc, kF16MaxFiniteValue, val);
-  } else if (ty.isF32()) {
-    return getConstantLike(b, loc, std::numeric_limits<float>::max(), val);
-  } else if (ty.isF64()) {
-    return getConstantLike(b, loc, std::numeric_limits<double>::max(), val);
-  }
-  llvm_unreachable("unhandled type");
-}
-
 //===----------------------------------------------------------------------===//
 // BinaryOps
 //===----------------------------------------------------------------------===//

lib/Dialect/mhlo/transforms/chlo_legalize_to_hlo_patterns.td

@@ -79,94 +79,6 @@ def : Pat<(HLOClient_AsinOp NonComplexElementType:$input),
     )
   )>;
 
-// Expand asinh to MHLO dialect as
-//   asinh(x) = log(x + sqrt(x^2 + 1))
-//
-// If x^2 will overflow and x is positive, we can approximate x + sqrt(x^2 + 1)
-// as 2*x and return log(2) + log(x).
-//
-// For small x, sqrt(x^2 + 1) will evaluate to 1 due to floating point
-// arithmetic. However, we would like to retain the low order term of this,
-// which is around 0.5 * x^2 using a binomial expansion.
-// Let z = sqrt(a^2 + 1)
-// The following rewrite retains the lower order term.
-// log(a + sqrt(a^2 + 1))
-//   = log((a + sqrt(a^2 + 1)) * (1 + sqrt(a^2 + 1)) / (1 + sqrt(a^2 + 1)))
-//   = log((a + a^2 + 1 + a * z + z) / (1 + z))
-//   = log(1 + a + a^2 / (1 + z))
-//   = log(1 + a + a^2 / (1 + sqrt(a^2 + 1)))
-//
-// If x is negative, the above would give us some trouble; we can't approximate
-// the result as x + abs(x) = 0 but we are saved by the fact that asinh(-x) =
-// -asinh(x).
-def : Pat<(HLOClient_AsinhOp NonComplexElementType:$input),
-  (HLO_MulOp
-    (HLO_SignOp $input),
-    (HLO_SelectOp
-      (HLO_CompareOp
-        (HLO_AbsOp $input),
-        (HLO_SqrtOp
-          (HLO_ConstantLikeMaxFiniteValue $input)
-        ),
-        HLO_COMPARISON_DIRECTION_GE,
-        (HLO_DEFAULT_COMPARISON_TYPE)
-      ),
-      (HLO_AddOp
-        (HLO_LogOp
-          (HLO_AbsOp $input)
-        ),
-        (HLO_LogOp
-          (HLO_ConstantLike<"2"> $input)
-        )
-      ),
-      (HLO_SelectOp
-        (HLO_CompareOp
-          (HLO_AbsOp $input),
-          (HLO_ConstantLike<"1"> $input),
-          HLO_COMPARISON_DIRECTION_LE,
-          (HLO_DEFAULT_COMPARISON_TYPE)
-        ),
-        (HLO_Log1pOp
-          (HLO_AddOp
-            (HLO_AbsOp $input),
-            (HLO_MulOp
-              (HLO_AbsOp $input),
-              (HLO_DivOp
-                (HLO_AbsOp $input),
-                (HLO_AddOp
-                  (HLO_ConstantLike<"1"> $input),
-                  (HLO_SqrtOp
-                    (HLO_AddOp
-                      (HLO_MulOp
-                        (HLO_AbsOp $input),
-                        (HLO_AbsOp $input)
-                      ),
-                      (HLO_ConstantLike<"1"> $input)
-                    )
-                  )
-                )
-              )
-            )
-          )
-        ),
-        (HLO_LogOp
-          (HLO_AddOp
-            (HLO_AbsOp $input),
-            (HLO_SqrtOp
-              (HLO_AddOp
-                (HLO_MulOp
-                  (HLO_AbsOp $input),
-                  (HLO_AbsOp $input)
-                ),
-                (HLO_ConstantLike<"1"> $input)
-              )
-            )
-          )
-        )
-      )
-    )
-  )>;
-
 // Express `atan` as
 //   atan(x) = atan2(x, 1)
 def : Pat<(HLOClient_AtanOp $input),

lib/Dialect/mhlo/transforms/transform_unranked_hlo.cc

@@ -51,9 +51,8 @@ namespace {
 
 // TODO(herhut): Generate these out of op definitions.
 #define MAP_CHLO_OPERATION_CWISE_UNARY(fn, sep)                           \
-  fn(AcosOp) sep fn(AsinOp) sep fn(AsinhOp) sep fn(AtanOp) sep fn(AtanhOp) \
-      sep fn(ConjOp) sep fn(CoshOp) sep fn(ErfOp) sep fn(ErfcOp)           \
-          sep fn(SinhOp) sep fn(TanOp)
+  fn(AcosOp) sep fn(AsinOp) sep fn(AtanOp) sep fn(AtanhOp) sep fn(ConjOp) \
+      sep fn(CoshOp) sep fn(ErfOp) sep fn(ErfcOp) sep fn(SinhOp) sep fn(TanOp)
 
 template <typename OpTy>
 inline void AddLegalOpOnRankedTensor(ConversionTarget *target) {