forked from OSchip/llvm-project
209 lines
8.7 KiB
C++
209 lines
8.7 KiB
C++
//===-- lib/Evaluate/fold-real.cpp ----------------------------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "fold-implementation.h"
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#include "fold-reduction.h"
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namespace Fortran::evaluate {
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template <int KIND>
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Expr<Type<TypeCategory::Real, KIND>> FoldIntrinsicFunction(
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FoldingContext &context,
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FunctionRef<Type<TypeCategory::Real, KIND>> &&funcRef) {
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using T = Type<TypeCategory::Real, KIND>;
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using ComplexT = Type<TypeCategory::Complex, KIND>;
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ActualArguments &args{funcRef.arguments()};
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auto *intrinsic{std::get_if<SpecificIntrinsic>(&funcRef.proc().u)};
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CHECK(intrinsic);
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std::string name{intrinsic->name};
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if (name == "acos" || name == "acosh" || name == "asin" || name == "asinh" ||
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(name == "atan" && args.size() == 1) || name == "atanh" ||
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name == "bessel_j0" || name == "bessel_j1" || name == "bessel_y0" ||
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name == "bessel_y1" || name == "cos" || name == "cosh" || name == "erf" ||
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name == "erfc" || name == "erfc_scaled" || name == "exp" ||
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name == "gamma" || name == "log" || name == "log10" ||
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name == "log_gamma" || name == "sin" || name == "sinh" || name == "tan" ||
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name == "tanh") {
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CHECK(args.size() == 1);
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if (auto callable{GetHostRuntimeWrapper<T, T>(name)}) {
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return FoldElementalIntrinsic<T, T>(
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context, std::move(funcRef), *callable);
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} else {
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context.messages().Say(
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"%s(real(kind=%d)) cannot be folded on host"_en_US, name, KIND);
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}
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} else if (name == "amax0" || name == "amin0" || name == "amin1" ||
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name == "amax1" || name == "dmin1" || name == "dmax1") {
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return RewriteSpecificMINorMAX(context, std::move(funcRef));
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} else if (name == "atan" || name == "atan2" || name == "mod") {
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std::string localName{name == "atan" ? "atan2" : name};
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CHECK(args.size() == 2);
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if (auto callable{GetHostRuntimeWrapper<T, T, T>(localName)}) {
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return FoldElementalIntrinsic<T, T, T>(
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context, std::move(funcRef), *callable);
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} else {
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context.messages().Say(
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"%s(real(kind=%d), real(kind%d)) cannot be folded on host"_en_US,
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name, KIND, KIND);
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}
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} else if (name == "bessel_jn" || name == "bessel_yn") {
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if (args.size() == 2) { // elemental
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// runtime functions use int arg
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using Int4 = Type<TypeCategory::Integer, 4>;
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if (auto callable{GetHostRuntimeWrapper<T, Int4, T>(name)}) {
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return FoldElementalIntrinsic<T, Int4, T>(
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context, std::move(funcRef), *callable);
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} else {
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context.messages().Say(
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"%s(integer(kind=4), real(kind=%d)) cannot be folded on host"_en_US,
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name, KIND);
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}
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}
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} else if (name == "abs") { // incl. zabs & cdabs
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// Argument can be complex or real
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if (auto *x{UnwrapExpr<Expr<SomeReal>>(args[0])}) {
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return FoldElementalIntrinsic<T, T>(
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context, std::move(funcRef), &Scalar<T>::ABS);
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} else if (auto *z{UnwrapExpr<Expr<SomeComplex>>(args[0])}) {
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return FoldElementalIntrinsic<T, ComplexT>(context, std::move(funcRef),
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ScalarFunc<T, ComplexT>([](const Scalar<ComplexT> &z) -> Scalar<T> {
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return z.ABS().value;
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}));
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} else {
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common::die(" unexpected argument type inside abs");
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}
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} else if (name == "aimag") {
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return FoldElementalIntrinsic<T, ComplexT>(
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context, std::move(funcRef), &Scalar<ComplexT>::AIMAG);
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} else if (name == "aint" || name == "anint") {
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// ANINT rounds ties away from zero, not to even
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common::RoundingMode mode{name == "aint"
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? common::RoundingMode::ToZero
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: common::RoundingMode::TiesAwayFromZero};
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return FoldElementalIntrinsic<T, T>(context, std::move(funcRef),
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ScalarFunc<T, T>([&name, &context, mode](
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const Scalar<T> &x) -> Scalar<T> {
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ValueWithRealFlags<Scalar<T>> y{x.ToWholeNumber(mode)};
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if (y.flags.test(RealFlag::Overflow)) {
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context.messages().Say("%s intrinsic folding overflow"_en_US, name);
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}
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return y.value;
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}));
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} else if (name == "dprod") {
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if (auto scalars{GetScalarConstantArguments<T, T>(context, args)}) {
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return Fold(context,
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Expr<T>{Multiply<T>{
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Expr<T>{std::get<0>(*scalars)}, Expr<T>{std::get<1>(*scalars)}}});
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}
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} else if (name == "epsilon") {
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return Expr<T>{Scalar<T>::EPSILON()};
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} else if (name == "huge") {
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return Expr<T>{Scalar<T>::HUGE()};
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} else if (name == "hypot") {
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CHECK(args.size() == 2);
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return FoldElementalIntrinsic<T, T, T>(context, std::move(funcRef),
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ScalarFunc<T, T, T>(
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[](const Scalar<T> &x, const Scalar<T> &y) -> Scalar<T> {
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return x.HYPOT(y).value;
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}));
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} else if (name == "max") {
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return FoldMINorMAX(context, std::move(funcRef), Ordering::Greater);
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} else if (name == "maxval") {
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return FoldMaxvalMinval<T>(context, std::move(funcRef),
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RelationalOperator::GT, T::Scalar::HUGE().Negate());
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} else if (name == "merge") {
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return FoldMerge<T>(context, std::move(funcRef));
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} else if (name == "min") {
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return FoldMINorMAX(context, std::move(funcRef), Ordering::Less);
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} else if (name == "minval") {
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return FoldMaxvalMinval<T>(
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context, std::move(funcRef), RelationalOperator::LT, T::Scalar::HUGE());
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} else if (name == "product") {
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auto one{Scalar<T>::FromInteger(value::Integer<8>{1}).value};
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return FoldProduct<T>(context, std::move(funcRef), one);
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} else if (name == "real") {
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if (auto *expr{args[0].value().UnwrapExpr()}) {
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return ToReal<KIND>(context, std::move(*expr));
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}
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} else if (name == "scale") {
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if (const auto *byExpr{UnwrapExpr<Expr<SomeInteger>>(args[1])}) {
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return std::visit(
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[&](const auto &byVal) {
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using TBY = ResultType<decltype(byVal)>;
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return FoldElementalIntrinsic<T, T, TBY>(context,
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std::move(funcRef),
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ScalarFunc<T, T, TBY>(
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[&](const Scalar<T> &x, const Scalar<TBY> &y) -> Scalar<T> {
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ValueWithRealFlags<Scalar<T>> result{x.
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// MSVC chokes on the keyword "template" here in a call to a
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// member function template.
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#ifndef _MSC_VER
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template
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#endif
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SCALE(y)};
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if (result.flags.test(RealFlag::Overflow)) {
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context.messages().Say(
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"SCALE intrinsic folding overflow"_en_US);
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}
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return result.value;
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}));
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},
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byExpr->u);
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}
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} else if (name == "sign") {
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return FoldElementalIntrinsic<T, T, T>(
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context, std::move(funcRef), &Scalar<T>::SIGN);
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} else if (name == "sqrt") {
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return FoldElementalIntrinsic<T, T>(context, std::move(funcRef),
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ScalarFunc<T, T>(
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[](const Scalar<T> &x) -> Scalar<T> { return x.SQRT().value; }));
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} else if (name == "sum") {
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return FoldSum<T>(context, std::move(funcRef));
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} else if (name == "tiny") {
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return Expr<T>{Scalar<T>::TINY()};
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}
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// TODO: dim, dot_product, fraction, matmul,
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// modulo, nearest, norm2, rrspacing,
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// __builtin_next_after/down/up,
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// set_exponent, spacing, transfer,
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// bessel_jn (transformational) and bessel_yn (transformational)
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return Expr<T>{std::move(funcRef)};
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}
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template <int KIND>
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Expr<Type<TypeCategory::Real, KIND>> FoldOperation(
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FoldingContext &context, ComplexComponent<KIND> &&x) {
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using Operand = Type<TypeCategory::Complex, KIND>;
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using Result = Type<TypeCategory::Real, KIND>;
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if (auto array{ApplyElementwise(context, x,
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std::function<Expr<Result>(Expr<Operand> &&)>{
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[=](Expr<Operand> &&operand) {
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return Expr<Result>{ComplexComponent<KIND>{
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x.isImaginaryPart, std::move(operand)}};
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}})}) {
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return *array;
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}
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using Part = Type<TypeCategory::Real, KIND>;
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auto &operand{x.left()};
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if (auto value{GetScalarConstantValue<Operand>(operand)}) {
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if (x.isImaginaryPart) {
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return Expr<Part>{Constant<Part>{value->AIMAG()}};
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} else {
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return Expr<Part>{Constant<Part>{value->REAL()}};
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}
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}
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return Expr<Part>{std::move(x)};
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}
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#ifdef _MSC_VER // disable bogus warning about missing definitions
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#pragma warning(disable : 4661)
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#endif
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FOR_EACH_REAL_KIND(template class ExpressionBase, )
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template class ExpressionBase<SomeReal>;
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} // namespace Fortran::evaluate
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