| //===-- lib/Evaluate/fold-integer.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" |
| #include "flang/Evaluate/check-expression.h" |
| |
| namespace Fortran::evaluate { |
| |
| // Class to retrieve the constant lower bound of an expression which is an |
| // array that devolves to a type of Constant<T> |
| class GetConstantArrayLboundHelper { |
| public: |
| GetConstantArrayLboundHelper(ConstantSubscript dim) : dim_{dim} {} |
| |
| template <typename T> ConstantSubscript GetLbound(const T &) { |
| // The method is needed for template expansion, but we should never get |
| // here in practice. |
| CHECK(false); |
| return 0; |
| } |
| |
| template <typename T> ConstantSubscript GetLbound(const Constant<T> &x) { |
| // Return the lower bound |
| return x.lbounds()[dim_]; |
| } |
| |
| template <typename T> ConstantSubscript GetLbound(const Parentheses<T> &x) { |
| // Strip off the parentheses |
| return GetLbound(x.left()); |
| } |
| |
| template <typename T> ConstantSubscript GetLbound(const Expr<T> &x) { |
| // recurse through Expr<T>'a until we hit a constant |
| return std::visit([&](const auto &inner) { return GetLbound(inner); }, |
| // [&](const auto &) { return 0; }, |
| x.u); |
| } |
| |
| private: |
| ConstantSubscript dim_; |
| }; |
| |
| template <int KIND> |
| Expr<Type<TypeCategory::Integer, KIND>> LBOUND(FoldingContext &context, |
| FunctionRef<Type<TypeCategory::Integer, KIND>> &&funcRef) { |
| using T = Type<TypeCategory::Integer, KIND>; |
| ActualArguments &args{funcRef.arguments()}; |
| if (const auto *array{UnwrapExpr<Expr<SomeType>>(args[0])}) { |
| if (int rank{array->Rank()}; rank > 0) { |
| std::optional<int> dim; |
| if (funcRef.Rank() == 0) { |
| // Optional DIM= argument is present: result is scalar. |
| if (auto dim64{GetInt64Arg(args[1])}) { |
| if (*dim64 < 1 || *dim64 > rank) { |
| context.messages().Say("DIM=%jd dimension is out of range for " |
| "rank-%d array"_err_en_US, |
| *dim64, rank); |
| return MakeInvalidIntrinsic<T>(std::move(funcRef)); |
| } else { |
| dim = *dim64 - 1; // 1-based to 0-based |
| } |
| } else { |
| // DIM= is present but not constant |
| return Expr<T>{std::move(funcRef)}; |
| } |
| } |
| bool lowerBoundsAreOne{true}; |
| if (auto named{ExtractNamedEntity(*array)}) { |
| const Symbol &symbol{named->GetLastSymbol()}; |
| if (symbol.Rank() == rank) { |
| lowerBoundsAreOne = false; |
| if (dim) { |
| return Fold(context, |
| ConvertToType<T>(GetLowerBound(context, *named, *dim))); |
| } else if (auto extents{ |
| AsExtentArrayExpr(GetLowerBounds(context, *named))}) { |
| return Fold(context, |
| ConvertToType<T>(Expr<ExtentType>{std::move(*extents)})); |
| } |
| } else { |
| lowerBoundsAreOne = symbol.Rank() == 0; // LBOUND(array%component) |
| } |
| } |
| if (IsActuallyConstant(*array)) { |
| return Expr<T>{GetConstantArrayLboundHelper{*dim}.GetLbound(*array)}; |
| } |
| if (lowerBoundsAreOne) { |
| if (dim) { |
| return Expr<T>{1}; |
| } else { |
| std::vector<Scalar<T>> ones(rank, Scalar<T>{1}); |
| return Expr<T>{ |
| Constant<T>{std::move(ones), ConstantSubscripts{rank}}}; |
| } |
| } |
| } |
| } |
| return Expr<T>{std::move(funcRef)}; |
| } |
| |
| template <int KIND> |
| Expr<Type<TypeCategory::Integer, KIND>> UBOUND(FoldingContext &context, |
| FunctionRef<Type<TypeCategory::Integer, KIND>> &&funcRef) { |
| using T = Type<TypeCategory::Integer, KIND>; |
| ActualArguments &args{funcRef.arguments()}; |
| if (auto *array{UnwrapExpr<Expr<SomeType>>(args[0])}) { |
| if (int rank{array->Rank()}; rank > 0) { |
| std::optional<int> dim; |
| if (funcRef.Rank() == 0) { |
| // Optional DIM= argument is present: result is scalar. |
| if (auto dim64{GetInt64Arg(args[1])}) { |
| if (*dim64 < 1 || *dim64 > rank) { |
| context.messages().Say("DIM=%jd dimension is out of range for " |
| "rank-%d array"_err_en_US, |
| *dim64, rank); |
| return MakeInvalidIntrinsic<T>(std::move(funcRef)); |
| } else { |
| dim = *dim64 - 1; // 1-based to 0-based |
| } |
| } else { |
| // DIM= is present but not constant |
| return Expr<T>{std::move(funcRef)}; |
| } |
| } |
| bool takeBoundsFromShape{true}; |
| if (auto named{ExtractNamedEntity(*array)}) { |
| const Symbol &symbol{named->GetLastSymbol()}; |
| if (symbol.Rank() == rank) { |
| takeBoundsFromShape = false; |
| if (dim) { |
| if (semantics::IsAssumedSizeArray(symbol) && *dim == rank - 1) { |
| context.messages().Say("DIM=%jd dimension is out of range for " |
| "rank-%d assumed-size array"_err_en_US, |
| rank, rank); |
| return MakeInvalidIntrinsic<T>(std::move(funcRef)); |
| } else if (auto ub{GetUpperBound(context, *named, *dim)}) { |
| return Fold(context, ConvertToType<T>(std::move(*ub))); |
| } |
| } else { |
| Shape ubounds{GetUpperBounds(context, *named)}; |
| if (semantics::IsAssumedSizeArray(symbol)) { |
| CHECK(!ubounds.back()); |
| ubounds.back() = ExtentExpr{-1}; |
| } |
| if (auto extents{AsExtentArrayExpr(ubounds)}) { |
| return Fold(context, |
| ConvertToType<T>(Expr<ExtentType>{std::move(*extents)})); |
| } |
| } |
| } else { |
| takeBoundsFromShape = symbol.Rank() == 0; // UBOUND(array%component) |
| } |
| } |
| if (takeBoundsFromShape) { |
| if (auto shape{GetShape(context, *array)}) { |
| if (dim) { |
| if (auto &dimSize{shape->at(*dim)}) { |
| return Fold(context, |
| ConvertToType<T>(Expr<ExtentType>{std::move(*dimSize)})); |
| } |
| } else if (auto shapeExpr{AsExtentArrayExpr(*shape)}) { |
| return Fold(context, ConvertToType<T>(std::move(*shapeExpr))); |
| } |
| } |
| } |
| } |
| } |
| return Expr<T>{std::move(funcRef)}; |
| } |
| |
| // COUNT() |
| template <typename T> |
| static Expr<T> FoldCount(FoldingContext &context, FunctionRef<T> &&ref) { |
| static_assert(T::category == TypeCategory::Integer); |
| ActualArguments &arg{ref.arguments()}; |
| if (const Constant<LogicalResult> *mask{arg.empty() |
| ? nullptr |
| : Folder<LogicalResult>{context}.Folding(arg[0])}) { |
| std::optional<ConstantSubscript> dim; |
| if (arg.size() > 1 && arg[1]) { |
| dim = CheckDIM(context, arg[1], mask->Rank()); |
| if (!dim) { |
| mask = nullptr; |
| } |
| } |
| if (mask) { |
| auto accumulator{[&](Scalar<T> &element, const ConstantSubscripts &at) { |
| if (mask->At(at).IsTrue()) { |
| element = element.AddSigned(Scalar<T>{1}).value; |
| } |
| }}; |
| return Expr<T>{DoReduction<T>(*mask, dim, Scalar<T>{}, accumulator)}; |
| } |
| } |
| return Expr<T>{std::move(ref)}; |
| } |
| |
| // for IALL, IANY, & IPARITY |
| template <typename T> |
| static Expr<T> FoldBitReduction(FoldingContext &context, FunctionRef<T> &&ref, |
| Scalar<T> (Scalar<T>::*operation)(const Scalar<T> &) const, |
| Scalar<T> identity) { |
| static_assert(T::category == TypeCategory::Integer); |
| std::optional<ConstantSubscript> dim; |
| if (std::optional<Constant<T>> array{ |
| ProcessReductionArgs<T>(context, ref.arguments(), dim, identity, |
| /*ARRAY=*/0, /*DIM=*/1, /*MASK=*/2)}) { |
| auto accumulator{[&](Scalar<T> &element, const ConstantSubscripts &at) { |
| element = (element.*operation)(array->At(at)); |
| }}; |
| return Expr<T>{DoReduction<T>(*array, dim, identity, accumulator)}; |
| } |
| return Expr<T>{std::move(ref)}; |
| } |
| |
| template <int KIND> |
| Expr<Type<TypeCategory::Integer, KIND>> FoldIntrinsicFunction( |
| FoldingContext &context, |
| FunctionRef<Type<TypeCategory::Integer, KIND>> &&funcRef) { |
| using T = Type<TypeCategory::Integer, KIND>; |
| using Int4 = Type<TypeCategory::Integer, 4>; |
| ActualArguments &args{funcRef.arguments()}; |
| auto *intrinsic{std::get_if<SpecificIntrinsic>(&funcRef.proc().u)}; |
| CHECK(intrinsic); |
| std::string name{intrinsic->name}; |
| if (name == "abs") { |
| return FoldElementalIntrinsic<T, T>(context, std::move(funcRef), |
| ScalarFunc<T, T>([&context](const Scalar<T> &i) -> Scalar<T> { |
| typename Scalar<T>::ValueWithOverflow j{i.ABS()}; |
| if (j.overflow) { |
| context.messages().Say( |
| "abs(integer(kind=%d)) folding overflowed"_en_US, KIND); |
| } |
| return j.value; |
| })); |
| } else if (name == "bit_size") { |
| return Expr<T>{Scalar<T>::bits}; |
| } else if (name == "ceiling" || name == "floor" || name == "nint") { |
| if (const auto *cx{UnwrapExpr<Expr<SomeReal>>(args[0])}) { |
| // NINT rounds ties away from zero, not to even |
| common::RoundingMode mode{name == "ceiling" ? common::RoundingMode::Up |
| : name == "floor" ? common::RoundingMode::Down |
| : common::RoundingMode::TiesAwayFromZero}; |
| return std::visit( |
| [&](const auto &kx) { |
| using TR = ResultType<decltype(kx)>; |
| return FoldElementalIntrinsic<T, TR>(context, std::move(funcRef), |
| ScalarFunc<T, TR>([&](const Scalar<TR> &x) { |
| auto y{x.template ToInteger<Scalar<T>>(mode)}; |
| if (y.flags.test(RealFlag::Overflow)) { |
| context.messages().Say( |
| "%s intrinsic folding overflow"_en_US, name); |
| } |
| return y.value; |
| })); |
| }, |
| cx->u); |
| } |
| } else if (name == "count") { |
| return FoldCount<T>(context, std::move(funcRef)); |
| } else if (name == "digits") { |
| if (const auto *cx{UnwrapExpr<Expr<SomeInteger>>(args[0])}) { |
| return Expr<T>{std::visit( |
| [](const auto &kx) { |
| return Scalar<ResultType<decltype(kx)>>::DIGITS; |
| }, |
| cx->u)}; |
| } else if (const auto *cx{UnwrapExpr<Expr<SomeReal>>(args[0])}) { |
| return Expr<T>{std::visit( |
| [](const auto &kx) { |
| return Scalar<ResultType<decltype(kx)>>::DIGITS; |
| }, |
| cx->u)}; |
| } else if (const auto *cx{UnwrapExpr<Expr<SomeComplex>>(args[0])}) { |
| return Expr<T>{std::visit( |
| [](const auto &kx) { |
| return Scalar<typename ResultType<decltype(kx)>::Part>::DIGITS; |
| }, |
| cx->u)}; |
| } |
| } else if (name == "dim") { |
| return FoldElementalIntrinsic<T, T, T>( |
| context, std::move(funcRef), &Scalar<T>::DIM); |
| } else if (name == "dshiftl" || name == "dshiftr") { |
| const auto fptr{ |
| name == "dshiftl" ? &Scalar<T>::DSHIFTL : &Scalar<T>::DSHIFTR}; |
| // Third argument can be of any kind. However, it must be smaller or equal |
| // than BIT_SIZE. It can be converted to Int4 to simplify. |
| return FoldElementalIntrinsic<T, T, T, Int4>(context, std::move(funcRef), |
| ScalarFunc<T, T, T, Int4>( |
| [&fptr](const Scalar<T> &i, const Scalar<T> &j, |
| const Scalar<Int4> &shift) -> Scalar<T> { |
| return std::invoke(fptr, i, j, static_cast<int>(shift.ToInt64())); |
| })); |
| } else if (name == "exponent") { |
| if (auto *sx{UnwrapExpr<Expr<SomeReal>>(args[0])}) { |
| return std::visit( |
| [&funcRef, &context](const auto &x) -> Expr<T> { |
| using TR = typename std::decay_t<decltype(x)>::Result; |
| return FoldElementalIntrinsic<T, TR>(context, std::move(funcRef), |
| &Scalar<TR>::template EXPONENT<Scalar<T>>); |
| }, |
| sx->u); |
| } else { |
| DIE("exponent argument must be real"); |
| } |
| } else if (name == "huge") { |
| return Expr<T>{Scalar<T>::HUGE()}; |
| } else if (name == "iachar" || name == "ichar") { |
| auto *someChar{UnwrapExpr<Expr<SomeCharacter>>(args[0])}; |
| CHECK(someChar); |
| if (auto len{ToInt64(someChar->LEN())}) { |
| if (len.value() != 1) { |
| // Do not die, this was not checked before |
| context.messages().Say( |
| "Character in intrinsic function %s must have length one"_en_US, |
| name); |
| } else { |
| return std::visit( |
| [&funcRef, &context](const auto &str) -> Expr<T> { |
| using Char = typename std::decay_t<decltype(str)>::Result; |
| return FoldElementalIntrinsic<T, Char>(context, |
| std::move(funcRef), |
| ScalarFunc<T, Char>([](const Scalar<Char> &c) { |
| return Scalar<T>{CharacterUtils<Char::kind>::ICHAR(c)}; |
| })); |
| }, |
| someChar->u); |
| } |
| } |
| } else if (name == "iand" || name == "ior" || name == "ieor") { |
| auto fptr{&Scalar<T>::IAND}; |
| if (name == "iand") { // done in fptr declaration |
| } else if (name == "ior") { |
| fptr = &Scalar<T>::IOR; |
| } else if (name == "ieor") { |
| fptr = &Scalar<T>::IEOR; |
| } else { |
| common::die("missing case to fold intrinsic function %s", name.c_str()); |
| } |
| return FoldElementalIntrinsic<T, T, T>( |
| context, std::move(funcRef), ScalarFunc<T, T, T>(fptr)); |
| } else if (name == "iall") { |
| return FoldBitReduction( |
| context, std::move(funcRef), &Scalar<T>::IAND, Scalar<T>{}.NOT()); |
| } else if (name == "iany") { |
| return FoldBitReduction( |
| context, std::move(funcRef), &Scalar<T>::IOR, Scalar<T>{}); |
| } else if (name == "ibclr" || name == "ibset" || name == "ishft" || |
| name == "shifta" || name == "shiftr" || name == "shiftl") { |
| // Second argument can be of any kind. However, it must be smaller or |
| // equal than BIT_SIZE. It can be converted to Int4 to simplify. |
| auto fptr{&Scalar<T>::IBCLR}; |
| if (name == "ibclr") { // done in fprt definition |
| } else if (name == "ibset") { |
| fptr = &Scalar<T>::IBSET; |
| } else if (name == "ishft") { |
| fptr = &Scalar<T>::ISHFT; |
| } else if (name == "shifta") { |
| fptr = &Scalar<T>::SHIFTA; |
| } else if (name == "shiftr") { |
| fptr = &Scalar<T>::SHIFTR; |
| } else if (name == "shiftl") { |
| fptr = &Scalar<T>::SHIFTL; |
| } else { |
| common::die("missing case to fold intrinsic function %s", name.c_str()); |
| } |
| return FoldElementalIntrinsic<T, T, Int4>(context, std::move(funcRef), |
| ScalarFunc<T, T, Int4>( |
| [&fptr](const Scalar<T> &i, const Scalar<Int4> &pos) -> Scalar<T> { |
| return std::invoke(fptr, i, static_cast<int>(pos.ToInt64())); |
| })); |
| } else if (name == "index" || name == "scan" || name == "verify") { |
| if (auto *charExpr{UnwrapExpr<Expr<SomeCharacter>>(args[0])}) { |
| return std::visit( |
| [&](const auto &kch) -> Expr<T> { |
| using TC = typename std::decay_t<decltype(kch)>::Result; |
| if (UnwrapExpr<Expr<SomeLogical>>(args[2])) { // BACK= |
| return FoldElementalIntrinsic<T, TC, TC, LogicalResult>(context, |
| std::move(funcRef), |
| ScalarFunc<T, TC, TC, LogicalResult>{ |
| [&name](const Scalar<TC> &str, const Scalar<TC> &other, |
| const Scalar<LogicalResult> &back) -> Scalar<T> { |
| return name == "index" |
| ? CharacterUtils<TC::kind>::INDEX( |
| str, other, back.IsTrue()) |
| : name == "scan" ? CharacterUtils<TC::kind>::SCAN( |
| str, other, back.IsTrue()) |
| : CharacterUtils<TC::kind>::VERIFY( |
| str, other, back.IsTrue()); |
| }}); |
| } else { |
| return FoldElementalIntrinsic<T, TC, TC>(context, |
| std::move(funcRef), |
| ScalarFunc<T, TC, TC>{ |
| [&name](const Scalar<TC> &str, |
| const Scalar<TC> &other) -> Scalar<T> { |
| return name == "index" |
| ? CharacterUtils<TC::kind>::INDEX(str, other) |
| : name == "scan" |
| ? CharacterUtils<TC::kind>::SCAN(str, other) |
| : CharacterUtils<TC::kind>::VERIFY(str, other); |
| }}); |
| } |
| }, |
| charExpr->u); |
| } else { |
| DIE("first argument must be CHARACTER"); |
| } |
| } else if (name == "int") { |
| if (auto *expr{UnwrapExpr<Expr<SomeType>>(args[0])}) { |
| return std::visit( |
| [&](auto &&x) -> Expr<T> { |
| using From = std::decay_t<decltype(x)>; |
| if constexpr (std::is_same_v<From, BOZLiteralConstant> || |
| IsNumericCategoryExpr<From>()) { |
| return Fold(context, ConvertToType<T>(std::move(x))); |
| } |
| DIE("int() argument type not valid"); |
| }, |
| std::move(expr->u)); |
| } |
| } else if (name == "int_ptr_kind") { |
| return Expr<T>{8}; |
| } else if (name == "kind") { |
| if constexpr (common::HasMember<T, IntegerTypes>) { |
| return Expr<T>{args[0].value().GetType()->kind()}; |
| } else { |
| DIE("kind() result not integral"); |
| } |
| } else if (name == "iparity") { |
| return FoldBitReduction( |
| context, std::move(funcRef), &Scalar<T>::IEOR, Scalar<T>{}); |
| } else if (name == "lbound") { |
| return LBOUND(context, std::move(funcRef)); |
| } else if (name == "leadz" || name == "trailz" || name == "poppar" || |
| name == "popcnt") { |
| if (auto *sn{UnwrapExpr<Expr<SomeInteger>>(args[0])}) { |
| return std::visit( |
| [&funcRef, &context, &name](const auto &n) -> Expr<T> { |
| using TI = typename std::decay_t<decltype(n)>::Result; |
| if (name == "poppar") { |
| return FoldElementalIntrinsic<T, TI>(context, std::move(funcRef), |
| ScalarFunc<T, TI>([](const Scalar<TI> &i) -> Scalar<T> { |
| return Scalar<T>{i.POPPAR() ? 1 : 0}; |
| })); |
| } |
| auto fptr{&Scalar<TI>::LEADZ}; |
| if (name == "leadz") { // done in fptr definition |
| } else if (name == "trailz") { |
| fptr = &Scalar<TI>::TRAILZ; |
| } else if (name == "popcnt") { |
| fptr = &Scalar<TI>::POPCNT; |
| } else { |
| common::die( |
| "missing case to fold intrinsic function %s", name.c_str()); |
| } |
| return FoldElementalIntrinsic<T, TI>(context, std::move(funcRef), |
| ScalarFunc<T, TI>([&fptr](const Scalar<TI> &i) -> Scalar<T> { |
| return Scalar<T>{std::invoke(fptr, i)}; |
| })); |
| }, |
| sn->u); |
| } else { |
| DIE("leadz argument must be integer"); |
| } |
| } else if (name == "len") { |
| if (auto *charExpr{UnwrapExpr<Expr<SomeCharacter>>(args[0])}) { |
| return std::visit( |
| [&](auto &kx) { |
| if (auto len{kx.LEN()}) { |
| return Fold(context, ConvertToType<T>(*std::move(len))); |
| } else { |
| return Expr<T>{std::move(funcRef)}; |
| } |
| }, |
| charExpr->u); |
| } else { |
| DIE("len() argument must be of character type"); |
| } |
| } else if (name == "len_trim") { |
| if (auto *charExpr{UnwrapExpr<Expr<SomeCharacter>>(args[0])}) { |
| return std::visit( |
| [&](const auto &kch) -> Expr<T> { |
| using TC = typename std::decay_t<decltype(kch)>::Result; |
| return FoldElementalIntrinsic<T, TC>(context, std::move(funcRef), |
| ScalarFunc<T, TC>{[](const Scalar<TC> &str) -> Scalar<T> { |
| return CharacterUtils<TC::kind>::LEN_TRIM(str); |
| }}); |
| }, |
| charExpr->u); |
| } else { |
| DIE("len_trim() argument must be of character type"); |
| } |
| } else if (name == "maskl" || name == "maskr") { |
| // Argument can be of any kind but value has to be smaller than BIT_SIZE. |
| // It can be safely converted to Int4 to simplify. |
| const auto fptr{name == "maskl" ? &Scalar<T>::MASKL : &Scalar<T>::MASKR}; |
| return FoldElementalIntrinsic<T, Int4>(context, std::move(funcRef), |
| ScalarFunc<T, Int4>([&fptr](const Scalar<Int4> &places) -> Scalar<T> { |
| return fptr(static_cast<int>(places.ToInt64())); |
| })); |
| } else if (name == "max") { |
| return FoldMINorMAX(context, std::move(funcRef), Ordering::Greater); |
| } else if (name == "max0" || name == "max1") { |
| return RewriteSpecificMINorMAX(context, std::move(funcRef)); |
| } else if (name == "maxexponent") { |
| if (auto *sx{UnwrapExpr<Expr<SomeReal>>(args[0])}) { |
| return std::visit( |
| [](const auto &x) { |
| using TR = typename std::decay_t<decltype(x)>::Result; |
| return Expr<T>{Scalar<TR>::MAXEXPONENT}; |
| }, |
| sx->u); |
| } |
| } else if (name == "maxval") { |
| return FoldMaxvalMinval<T>(context, std::move(funcRef), |
| RelationalOperator::GT, T::Scalar::Least()); |
| } else if (name == "merge") { |
| return FoldMerge<T>(context, std::move(funcRef)); |
| } else if (name == "merge_bits") { |
| return FoldElementalIntrinsic<T, T, T, T>( |
| context, std::move(funcRef), &Scalar<T>::MERGE_BITS); |
| } else if (name == "minexponent") { |
| if (auto *sx{UnwrapExpr<Expr<SomeReal>>(args[0])}) { |
| return std::visit( |
| [](const auto &x) { |
| using TR = typename std::decay_t<decltype(x)>::Result; |
| return Expr<T>{Scalar<TR>::MINEXPONENT}; |
| }, |
| sx->u); |
| } |
| } else if (name == "min") { |
| return FoldMINorMAX(context, std::move(funcRef), Ordering::Less); |
| } else if (name == "min0" || name == "min1") { |
| return RewriteSpecificMINorMAX(context, std::move(funcRef)); |
| } else if (name == "minval") { |
| return FoldMaxvalMinval<T>( |
| context, std::move(funcRef), RelationalOperator::LT, T::Scalar::HUGE()); |
| } else if (name == "mod") { |
| return FoldElementalIntrinsic<T, T, T>(context, std::move(funcRef), |
| ScalarFuncWithContext<T, T, T>( |
| [](FoldingContext &context, const Scalar<T> &x, |
| const Scalar<T> &y) -> Scalar<T> { |
| auto quotRem{x.DivideSigned(y)}; |
| if (quotRem.divisionByZero) { |
| context.messages().Say("mod() by zero"_en_US); |
| } else if (quotRem.overflow) { |
| context.messages().Say("mod() folding overflowed"_en_US); |
| } |
| return quotRem.remainder; |
| })); |
| } else if (name == "modulo") { |
| return FoldElementalIntrinsic<T, T, T>(context, std::move(funcRef), |
| ScalarFuncWithContext<T, T, T>( |
| [](FoldingContext &context, const Scalar<T> &x, |
| const Scalar<T> &y) -> Scalar<T> { |
| auto result{x.MODULO(y)}; |
| if (result.overflow) { |
| context.messages().Say("modulo() folding overflowed"_en_US); |
| } |
| return result.value; |
| })); |
| } else if (name == "not") { |
| return FoldElementalIntrinsic<T, T>( |
| context, std::move(funcRef), &Scalar<T>::NOT); |
| } else if (name == "precision") { |
| if (const auto *cx{UnwrapExpr<Expr<SomeReal>>(args[0])}) { |
| return Expr<T>{std::visit( |
| [](const auto &kx) { |
| return Scalar<ResultType<decltype(kx)>>::PRECISION; |
| }, |
| cx->u)}; |
| } else if (const auto *cx{UnwrapExpr<Expr<SomeComplex>>(args[0])}) { |
| return Expr<T>{std::visit( |
| [](const auto &kx) { |
| return Scalar<typename ResultType<decltype(kx)>::Part>::PRECISION; |
| }, |
| cx->u)}; |
| } |
| } else if (name == "product") { |
| return FoldProduct<T>(context, std::move(funcRef), Scalar<T>{1}); |
| } else if (name == "radix") { |
| return Expr<T>{2}; |
| } else if (name == "range") { |
| if (const auto *cx{UnwrapExpr<Expr<SomeInteger>>(args[0])}) { |
| return Expr<T>{std::visit( |
| [](const auto &kx) { |
| return Scalar<ResultType<decltype(kx)>>::RANGE; |
| }, |
| cx->u)}; |
| } else if (const auto *cx{UnwrapExpr<Expr<SomeReal>>(args[0])}) { |
| return Expr<T>{std::visit( |
| [](const auto &kx) { |
| return Scalar<ResultType<decltype(kx)>>::RANGE; |
| }, |
| cx->u)}; |
| } else if (const auto *cx{UnwrapExpr<Expr<SomeComplex>>(args[0])}) { |
| return Expr<T>{std::visit( |
| [](const auto &kx) { |
| return Scalar<typename ResultType<decltype(kx)>::Part>::RANGE; |
| }, |
| cx->u)}; |
| } |
| } else if (name == "rank") { |
| if (const auto *array{UnwrapExpr<Expr<SomeType>>(args[0])}) { |
| if (auto named{ExtractNamedEntity(*array)}) { |
| const Symbol &symbol{named->GetLastSymbol()}; |
| if (semantics::IsAssumedRankArray(symbol)) { |
| // DescriptorInquiry can only be placed in expression of kind |
| // DescriptorInquiry::Result::kind. |
| return ConvertToType<T>(Expr< |
| Type<TypeCategory::Integer, DescriptorInquiry::Result::kind>>{ |
| DescriptorInquiry{*named, DescriptorInquiry::Field::Rank}}); |
| } |
| } |
| return Expr<T>{args[0].value().Rank()}; |
| } |
| return Expr<T>{args[0].value().Rank()}; |
| } else if (name == "selected_char_kind") { |
| if (const auto *chCon{UnwrapExpr<Constant<TypeOf<std::string>>>(args[0])}) { |
| if (std::optional<std::string> value{chCon->GetScalarValue()}) { |
| int defaultKind{ |
| context.defaults().GetDefaultKind(TypeCategory::Character)}; |
| return Expr<T>{SelectedCharKind(*value, defaultKind)}; |
| } |
| } |
| } else if (name == "selected_int_kind") { |
| if (auto p{GetInt64Arg(args[0])}) { |
| return Expr<T>{SelectedIntKind(*p)}; |
| } |
| } else if (name == "selected_real_kind" || |
| name == "__builtin_ieee_selected_real_kind") { |
| if (auto p{GetInt64ArgOr(args[0], 0)}) { |
| if (auto r{GetInt64ArgOr(args[1], 0)}) { |
| if (auto radix{GetInt64ArgOr(args[2], 2)}) { |
| return Expr<T>{SelectedRealKind(*p, *r, *radix)}; |
| } |
| } |
| } |
| } else if (name == "shape") { |
| if (auto shape{GetShape(context, args[0])}) { |
| if (auto shapeExpr{AsExtentArrayExpr(*shape)}) { |
| return Fold(context, ConvertToType<T>(std::move(*shapeExpr))); |
| } |
| } |
| } else if (name == "sign") { |
| return FoldElementalIntrinsic<T, T, T>(context, std::move(funcRef), |
| ScalarFunc<T, T, T>( |
| [&context](const Scalar<T> &j, const Scalar<T> &k) -> Scalar<T> { |
| typename Scalar<T>::ValueWithOverflow result{j.SIGN(k)}; |
| if (result.overflow) { |
| context.messages().Say( |
| "sign(integer(kind=%d)) folding overflowed"_en_US, KIND); |
| } |
| return result.value; |
| })); |
| } else if (name == "size") { |
| if (auto shape{GetShape(context, args[0])}) { |
| if (auto &dimArg{args[1]}) { // DIM= is present, get one extent |
| if (auto dim{GetInt64Arg(args[1])}) { |
| int rank{GetRank(*shape)}; |
| if (*dim >= 1 && *dim <= rank) { |
| if (auto &extent{shape->at(*dim - 1)}) { |
| return Fold(context, ConvertToType<T>(std::move(*extent))); |
| } |
| } else { |
| context.messages().Say( |
| "size(array,dim=%jd) dimension is out of range for rank-%d array"_en_US, |
| *dim, rank); |
| } |
| } |
| } else if (auto extents{common::AllElementsPresent(std::move(*shape))}) { |
| // DIM= is absent; compute PRODUCT(SHAPE()) |
| ExtentExpr product{1}; |
| for (auto &&extent : std::move(*extents)) { |
| product = std::move(product) * std::move(extent); |
| } |
| return Expr<T>{ConvertToType<T>(Fold(context, std::move(product)))}; |
| } |
| } |
| } else if (name == "sizeof") { // in bytes; extension |
| if (auto info{ |
| characteristics::TypeAndShape::Characterize(args[0], context)}) { |
| if (auto bytes{info->MeasureSizeInBytes(context)}) { |
| return Expr<T>{Fold(context, ConvertToType<T>(std::move(*bytes)))}; |
| } |
| } |
| } else if (name == "storage_size") { // in bits |
| if (auto info{ |
| characteristics::TypeAndShape::Characterize(args[0], context)}) { |
| if (auto bytes{info->MeasureElementSizeInBytes(context, true)}) { |
| return Expr<T>{ |
| Fold(context, Expr<T>{8} * ConvertToType<T>(std::move(*bytes)))}; |
| } |
| } |
| } else if (name == "sum") { |
| return FoldSum<T>(context, std::move(funcRef)); |
| } else if (name == "ubound") { |
| return UBOUND(context, std::move(funcRef)); |
| } |
| // TODO: count(w/ dim), dot_product, findloc, ibits, image_status, ishftc, |
| // matmul, maxloc, minloc, sign, transfer |
| return Expr<T>{std::move(funcRef)}; |
| } |
| |
| // Substitutes a bare type parameter reference with its value if it has one now |
| // in an instantiation. Bare LEN type parameters are substituted only when |
| // the known value is constant. |
| Expr<TypeParamInquiry::Result> FoldOperation( |
| FoldingContext &context, TypeParamInquiry &&inquiry) { |
| std::optional<NamedEntity> base{inquiry.base()}; |
| parser::CharBlock parameterName{inquiry.parameter().name()}; |
| if (base) { |
| // Handling "designator%typeParam". Get the value of the type parameter |
| // from the instantiation of the base |
| if (const semantics::DeclTypeSpec * |
| declType{base->GetLastSymbol().GetType()}) { |
| if (const semantics::ParamValue * |
| paramValue{ |
| declType->derivedTypeSpec().FindParameter(parameterName)}) { |
| const semantics::MaybeIntExpr ¶mExpr{paramValue->GetExplicit()}; |
| if (paramExpr && IsConstantExpr(*paramExpr)) { |
| Expr<SomeInteger> intExpr{*paramExpr}; |
| return Fold(context, |
| ConvertToType<TypeParamInquiry::Result>(std::move(intExpr))); |
| } |
| } |
| } |
| } else { |
| // A "bare" type parameter: replace with its value, if that's now known |
| // in a current derived type instantiation, for KIND type parameters. |
| if (const auto *pdt{context.pdtInstance()}) { |
| bool isLen{false}; |
| if (const semantics::Scope * scope{context.pdtInstance()->scope()}) { |
| auto iter{scope->find(parameterName)}; |
| if (iter != scope->end()) { |
| const Symbol &symbol{*iter->second}; |
| const auto *details{symbol.detailsIf<semantics::TypeParamDetails>()}; |
| if (details) { |
| isLen = details->attr() == common::TypeParamAttr::Len; |
| const semantics::MaybeIntExpr &initExpr{details->init()}; |
| if (initExpr && IsConstantExpr(*initExpr) && |
| (!isLen || ToInt64(*initExpr))) { |
| Expr<SomeInteger> expr{*initExpr}; |
| return Fold(context, |
| ConvertToType<TypeParamInquiry::Result>(std::move(expr))); |
| } |
| } |
| } |
| } |
| if (const auto *value{pdt->FindParameter(parameterName)}) { |
| if (value->isExplicit()) { |
| auto folded{Fold(context, |
| AsExpr(ConvertToType<TypeParamInquiry::Result>( |
| Expr<SomeInteger>{value->GetExplicit().value()})))}; |
| if (!isLen || ToInt64(folded)) { |
| return folded; |
| } |
| } |
| } |
| } |
| } |
| return AsExpr(std::move(inquiry)); |
| } |
| |
| std::optional<std::int64_t> ToInt64(const Expr<SomeInteger> &expr) { |
| return std::visit( |
| [](const auto &kindExpr) { return ToInt64(kindExpr); }, expr.u); |
| } |
| |
| std::optional<std::int64_t> ToInt64(const Expr<SomeType> &expr) { |
| if (const auto *intExpr{UnwrapExpr<Expr<SomeInteger>>(expr)}) { |
| return ToInt64(*intExpr); |
| } else { |
| return std::nullopt; |
| } |
| } |
| |
| FOR_EACH_INTEGER_KIND(template class ExpressionBase, ) |
| template class ExpressionBase<SomeInteger>; |
| } // namespace Fortran::evaluate |