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