llvm-project/flang/lib/Evaluate/fold-implementation.h

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//===-- lib/Evaluate/fold-implementation.h --------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
#ifndef FORTRAN_EVALUATE_FOLD_IMPLEMENTATION_H_
#define FORTRAN_EVALUATE_FOLD_IMPLEMENTATION_H_
#include "character.h"
#include "host.h"
#include "int-power.h"
#include "flang/Common/indirection.h"
#include "flang/Common/template.h"
#include "flang/Common/unwrap.h"
#include "flang/Evaluate/characteristics.h"
#include "flang/Evaluate/common.h"
#include "flang/Evaluate/constant.h"
#include "flang/Evaluate/expression.h"
#include "flang/Evaluate/fold.h"
#include "flang/Evaluate/formatting.h"
#include "flang/Evaluate/intrinsics-library.h"
#include "flang/Evaluate/intrinsics.h"
#include "flang/Evaluate/shape.h"
#include "flang/Evaluate/tools.h"
#include "flang/Evaluate/traverse.h"
#include "flang/Evaluate/type.h"
#include "flang/Parser/message.h"
#include "flang/Semantics/scope.h"
#include "flang/Semantics/symbol.h"
#include "flang/Semantics/tools.h"
#include <algorithm>
#include <cmath>
#include <complex>
#include <cstdio>
#include <optional>
#include <type_traits>
#include <variant>
// Some environments, viz. clang on Darwin, allow the macro HUGE
// to leak out of <math.h> even when it is never directly included.
#undef HUGE
namespace Fortran::evaluate {
// Utilities
template <typename T> class Folder {
public:
explicit Folder(FoldingContext &c) : context_{c} {}
[flang] Improve initializer semantics, esp. for component default values This patch plugs many holes in static initializer semantics, improves error messages for default initial values and other component properties in parameterized derived type instantiations, and cleans up several small issues noticed during development. We now do proper scalar expansion, folding, and type, rank, and shape conformance checking for component default initializers in derived types and PDT instantiations. The initial values of named constants are now guaranteed to have been folded when installed in the symbol table, and are no longer folded or scalar-expanded at each use in expression folding. Semantics documentation was extended with information about the various kinds of initializations in Fortran and when each of them are processed in the compiler. Some necessary concomitant changes have bulked this patch out a bit: * contextual messages attachments, which are now produced for parameterized derived type instantiations so that the user can figure out which instance caused a problem with a component, have been added as part of ContextualMessages, and their implementation was debugged * several APIs in evaluate::characteristics was changed so that a FoldingContext is passed as an argument rather than just its intrinsic procedure table; this affected client call sites in many files * new tools in Evaluate/check-expression.cpp to determine when an Expr actually is a single constant value and to validate a non-pointer variable initializer or object component default value * shape conformance checking has additional arguments that control whether scalar expansion is allowed * several now-unused functions and data members noticed and removed * several crashes and bogus errors exposed by testing this new code were fixed * a -fdebug-stack-trace option to enable LLVM's stack tracing on a crash, which might be useful in the future TL;DR: Initialization processing does more and takes place at the right times for all of the various kinds of things that can be initialized. Differential Review: https://reviews.llvm.org/D92783
2020-12-08 04:08:58 +08:00
std::optional<Constant<T>> GetNamedConstant(const Symbol &);
std::optional<Constant<T>> ApplySubscripts(const Constant<T> &array,
const std::vector<Constant<SubscriptInteger>> &subscripts);
std::optional<Constant<T>> ApplyComponent(Constant<SomeDerived> &&,
const Symbol &component,
const std::vector<Constant<SubscriptInteger>> * = nullptr);
std::optional<Constant<T>> GetConstantComponent(
Component &, const std::vector<Constant<SubscriptInteger>> * = nullptr);
std::optional<Constant<T>> Folding(ArrayRef &);
Expr<T> Folding(Designator<T> &&);
Constant<T> *Folding(std::optional<ActualArgument> &);
Expr<T> CSHIFT(FunctionRef<T> &&);
Expr<T> EOSHIFT(FunctionRef<T> &&);
Expr<T> PACK(FunctionRef<T> &&);
Expr<T> RESHAPE(FunctionRef<T> &&);
Expr<T> TRANSPOSE(FunctionRef<T> &&);
Expr<T> UNPACK(FunctionRef<T> &&);
private:
FoldingContext &context_;
};
std::optional<Constant<SubscriptInteger>> GetConstantSubscript(
FoldingContext &, Subscript &, const NamedEntity &, int dim);
// Helper to use host runtime on scalars for folding.
template <typename TR, typename... TA>
std::optional<std::function<Scalar<TR>(FoldingContext &, Scalar<TA>...)>>
GetHostRuntimeWrapper(const std::string &name) {
std::vector<DynamicType> argTypes{TA{}.GetType()...};
if (auto hostWrapper{GetHostRuntimeWrapper(name, TR{}.GetType(), argTypes)}) {
return [hostWrapper](
FoldingContext &context, Scalar<TA>... args) -> Scalar<TR> {
std::vector<Expr<SomeType>> genericArgs{
AsGenericExpr(Constant<TA>{args})...};
return GetScalarConstantValue<TR>(
(*hostWrapper)(context, std::move(genericArgs)))
.value();
};
}
return std::nullopt;
}
// FoldOperation() rewrites expression tree nodes.
// If there is any possibility that the rewritten node will
// not have the same representation type, the result of
// FoldOperation() will be packaged in an Expr<> of the same
// specific type.
// no-op base case
template <typename A>
common::IfNoLvalue<Expr<ResultType<A>>, A> FoldOperation(
FoldingContext &, A &&x) {
static_assert(!std::is_same_v<A, Expr<ResultType<A>>>,
"call Fold() instead for Expr<>");
return Expr<ResultType<A>>{std::move(x)};
}
Component FoldOperation(FoldingContext &, Component &&);
NamedEntity FoldOperation(FoldingContext &, NamedEntity &&);
Triplet FoldOperation(FoldingContext &, Triplet &&);
Subscript FoldOperation(FoldingContext &, Subscript &&);
ArrayRef FoldOperation(FoldingContext &, ArrayRef &&);
CoarrayRef FoldOperation(FoldingContext &, CoarrayRef &&);
DataRef FoldOperation(FoldingContext &, DataRef &&);
Substring FoldOperation(FoldingContext &, Substring &&);
ComplexPart FoldOperation(FoldingContext &, ComplexPart &&);
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, FunctionRef<T> &&);
template <int KIND>
Expr<Type<TypeCategory::Integer, KIND>> FoldIntrinsicFunction(
FoldingContext &context, FunctionRef<Type<TypeCategory::Integer, KIND>> &&);
template <int KIND>
Expr<Type<TypeCategory::Real, KIND>> FoldIntrinsicFunction(
FoldingContext &context, FunctionRef<Type<TypeCategory::Real, KIND>> &&);
template <int KIND>
Expr<Type<TypeCategory::Complex, KIND>> FoldIntrinsicFunction(
FoldingContext &context, FunctionRef<Type<TypeCategory::Complex, KIND>> &&);
template <int KIND>
Expr<Type<TypeCategory::Logical, KIND>> FoldIntrinsicFunction(
FoldingContext &context, FunctionRef<Type<TypeCategory::Logical, KIND>> &&);
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Designator<T> &&designator) {
return Folder<T>{context}.Folding(std::move(designator));
}
Expr<TypeParamInquiry::Result> FoldOperation(
FoldingContext &, TypeParamInquiry &&);
Expr<ImpliedDoIndex::Result> FoldOperation(
FoldingContext &context, ImpliedDoIndex &&);
template <typename T>
Expr<T> FoldOperation(FoldingContext &, ArrayConstructor<T> &&);
Expr<SomeDerived> FoldOperation(FoldingContext &, StructureConstructor &&);
template <typename T>
[flang] Improve initializer semantics, esp. for component default values This patch plugs many holes in static initializer semantics, improves error messages for default initial values and other component properties in parameterized derived type instantiations, and cleans up several small issues noticed during development. We now do proper scalar expansion, folding, and type, rank, and shape conformance checking for component default initializers in derived types and PDT instantiations. The initial values of named constants are now guaranteed to have been folded when installed in the symbol table, and are no longer folded or scalar-expanded at each use in expression folding. Semantics documentation was extended with information about the various kinds of initializations in Fortran and when each of them are processed in the compiler. Some necessary concomitant changes have bulked this patch out a bit: * contextual messages attachments, which are now produced for parameterized derived type instantiations so that the user can figure out which instance caused a problem with a component, have been added as part of ContextualMessages, and their implementation was debugged * several APIs in evaluate::characteristics was changed so that a FoldingContext is passed as an argument rather than just its intrinsic procedure table; this affected client call sites in many files * new tools in Evaluate/check-expression.cpp to determine when an Expr actually is a single constant value and to validate a non-pointer variable initializer or object component default value * shape conformance checking has additional arguments that control whether scalar expansion is allowed * several now-unused functions and data members noticed and removed * several crashes and bogus errors exposed by testing this new code were fixed * a -fdebug-stack-trace option to enable LLVM's stack tracing on a crash, which might be useful in the future TL;DR: Initialization processing does more and takes place at the right times for all of the various kinds of things that can be initialized. Differential Review: https://reviews.llvm.org/D92783
2020-12-08 04:08:58 +08:00
std::optional<Constant<T>> Folder<T>::GetNamedConstant(const Symbol &symbol0) {
const Symbol &symbol{ResolveAssociations(symbol0)};
if (IsNamedConstant(symbol)) {
if (const auto *object{
symbol.detailsIf<semantics::ObjectEntityDetails>()}) {
[flang] Improve initializer semantics, esp. for component default values This patch plugs many holes in static initializer semantics, improves error messages for default initial values and other component properties in parameterized derived type instantiations, and cleans up several small issues noticed during development. We now do proper scalar expansion, folding, and type, rank, and shape conformance checking for component default initializers in derived types and PDT instantiations. The initial values of named constants are now guaranteed to have been folded when installed in the symbol table, and are no longer folded or scalar-expanded at each use in expression folding. Semantics documentation was extended with information about the various kinds of initializations in Fortran and when each of them are processed in the compiler. Some necessary concomitant changes have bulked this patch out a bit: * contextual messages attachments, which are now produced for parameterized derived type instantiations so that the user can figure out which instance caused a problem with a component, have been added as part of ContextualMessages, and their implementation was debugged * several APIs in evaluate::characteristics was changed so that a FoldingContext is passed as an argument rather than just its intrinsic procedure table; this affected client call sites in many files * new tools in Evaluate/check-expression.cpp to determine when an Expr actually is a single constant value and to validate a non-pointer variable initializer or object component default value * shape conformance checking has additional arguments that control whether scalar expansion is allowed * several now-unused functions and data members noticed and removed * several crashes and bogus errors exposed by testing this new code were fixed * a -fdebug-stack-trace option to enable LLVM's stack tracing on a crash, which might be useful in the future TL;DR: Initialization processing does more and takes place at the right times for all of the various kinds of things that can be initialized. Differential Review: https://reviews.llvm.org/D92783
2020-12-08 04:08:58 +08:00
if (const auto *constant{UnwrapConstantValue<T>(object->init())}) {
return *constant;
}
}
}
return std::nullopt;
}
template <typename T>
std::optional<Constant<T>> Folder<T>::Folding(ArrayRef &aRef) {
std::vector<Constant<SubscriptInteger>> subscripts;
int dim{0};
for (Subscript &ss : aRef.subscript()) {
if (auto constant{GetConstantSubscript(context_, ss, aRef.base(), dim++)}) {
subscripts.emplace_back(std::move(*constant));
} else {
return std::nullopt;
}
}
if (Component * component{aRef.base().UnwrapComponent()}) {
return GetConstantComponent(*component, &subscripts);
} else if (std::optional<Constant<T>> array{
[flang] Improve initializer semantics, esp. for component default values This patch plugs many holes in static initializer semantics, improves error messages for default initial values and other component properties in parameterized derived type instantiations, and cleans up several small issues noticed during development. We now do proper scalar expansion, folding, and type, rank, and shape conformance checking for component default initializers in derived types and PDT instantiations. The initial values of named constants are now guaranteed to have been folded when installed in the symbol table, and are no longer folded or scalar-expanded at each use in expression folding. Semantics documentation was extended with information about the various kinds of initializations in Fortran and when each of them are processed in the compiler. Some necessary concomitant changes have bulked this patch out a bit: * contextual messages attachments, which are now produced for parameterized derived type instantiations so that the user can figure out which instance caused a problem with a component, have been added as part of ContextualMessages, and their implementation was debugged * several APIs in evaluate::characteristics was changed so that a FoldingContext is passed as an argument rather than just its intrinsic procedure table; this affected client call sites in many files * new tools in Evaluate/check-expression.cpp to determine when an Expr actually is a single constant value and to validate a non-pointer variable initializer or object component default value * shape conformance checking has additional arguments that control whether scalar expansion is allowed * several now-unused functions and data members noticed and removed * several crashes and bogus errors exposed by testing this new code were fixed * a -fdebug-stack-trace option to enable LLVM's stack tracing on a crash, which might be useful in the future TL;DR: Initialization processing does more and takes place at the right times for all of the various kinds of things that can be initialized. Differential Review: https://reviews.llvm.org/D92783
2020-12-08 04:08:58 +08:00
GetNamedConstant(aRef.base().GetLastSymbol())}) {
return ApplySubscripts(*array, subscripts);
} else {
return std::nullopt;
}
}
template <typename T>
std::optional<Constant<T>> Folder<T>::ApplySubscripts(const Constant<T> &array,
const std::vector<Constant<SubscriptInteger>> &subscripts) {
const auto &shape{array.shape()};
const auto &lbounds{array.lbounds()};
int rank{GetRank(shape)};
CHECK(rank == static_cast<int>(subscripts.size()));
std::size_t elements{1};
ConstantSubscripts resultShape;
ConstantSubscripts ssLB;
for (const auto &ss : subscripts) {
CHECK(ss.Rank() <= 1);
if (ss.Rank() == 1) {
resultShape.push_back(static_cast<ConstantSubscript>(ss.size()));
elements *= ss.size();
ssLB.push_back(ss.lbounds().front());
}
}
ConstantSubscripts ssAt(rank, 0), at(rank, 0), tmp(1, 0);
std::vector<Scalar<T>> values;
while (elements-- > 0) {
bool increment{true};
int k{0};
for (int j{0}; j < rank; ++j) {
if (subscripts[j].Rank() == 0) {
at[j] = subscripts[j].GetScalarValue().value().ToInt64();
} else {
CHECK(k < GetRank(resultShape));
tmp[0] = ssLB.at(k) + ssAt.at(k);
at[j] = subscripts[j].At(tmp).ToInt64();
if (increment) {
if (++ssAt[k] == resultShape[k]) {
ssAt[k] = 0;
} else {
increment = false;
}
}
++k;
}
if (at[j] < lbounds[j] || at[j] >= lbounds[j] + shape[j]) {
context_.messages().Say(
"Subscript value (%jd) is out of range on dimension %d in reference to a constant array value"_err_en_US,
at[j], j + 1);
return std::nullopt;
}
}
values.emplace_back(array.At(at));
CHECK(!increment || elements == 0);
CHECK(k == GetRank(resultShape));
}
if constexpr (T::category == TypeCategory::Character) {
return Constant<T>{array.LEN(), std::move(values), std::move(resultShape)};
} else if constexpr (std::is_same_v<T, SomeDerived>) {
return Constant<T>{array.result().derivedTypeSpec(), std::move(values),
std::move(resultShape)};
} else {
return Constant<T>{std::move(values), std::move(resultShape)};
}
}
template <typename T>
std::optional<Constant<T>> Folder<T>::ApplyComponent(
Constant<SomeDerived> &&structures, const Symbol &component,
const std::vector<Constant<SubscriptInteger>> *subscripts) {
if (auto scalar{structures.GetScalarValue()}) {
2020-09-04 23:44:52 +08:00
if (std::optional<Expr<SomeType>> expr{scalar->Find(component)}) {
if (const Constant<T> *value{UnwrapConstantValue<T>(expr.value())}) {
if (!subscripts) {
return std::move(*value);
} else {
return ApplySubscripts(*value, *subscripts);
}
}
}
} else {
// A(:)%scalar_component & A(:)%array_component(subscripts)
std::unique_ptr<ArrayConstructor<T>> array;
if (structures.empty()) {
return std::nullopt;
}
ConstantSubscripts at{structures.lbounds()};
do {
StructureConstructor scalar{structures.At(at)};
2020-09-04 23:44:52 +08:00
if (std::optional<Expr<SomeType>> expr{scalar.Find(component)}) {
if (const Constant<T> *value{UnwrapConstantValue<T>(expr.value())}) {
if (!array.get()) {
// This technique ensures that character length or derived type
// information is propagated to the array constructor.
2020-09-04 23:44:52 +08:00
auto *typedExpr{UnwrapExpr<Expr<T>>(expr.value())};
CHECK(typedExpr);
array = std::make_unique<ArrayConstructor<T>>(*typedExpr);
}
if (subscripts) {
if (auto element{ApplySubscripts(*value, *subscripts)}) {
CHECK(element->Rank() == 0);
array->Push(Expr<T>{std::move(*element)});
} else {
return std::nullopt;
}
} else {
CHECK(value->Rank() == 0);
array->Push(Expr<T>{*value});
}
} else {
return std::nullopt;
}
}
} while (structures.IncrementSubscripts(at));
// Fold the ArrayConstructor<> into a Constant<>.
CHECK(array);
Expr<T> result{Fold(context_, Expr<T>{std::move(*array)})};
if (auto *constant{UnwrapConstantValue<T>(result)}) {
return constant->Reshape(common::Clone(structures.shape()));
}
}
return std::nullopt;
}
template <typename T>
std::optional<Constant<T>> Folder<T>::GetConstantComponent(Component &component,
const std::vector<Constant<SubscriptInteger>> *subscripts) {
if (std::optional<Constant<SomeDerived>> structures{std::visit(
common::visitors{
[&](const Symbol &symbol) {
[flang] Improve initializer semantics, esp. for component default values This patch plugs many holes in static initializer semantics, improves error messages for default initial values and other component properties in parameterized derived type instantiations, and cleans up several small issues noticed during development. We now do proper scalar expansion, folding, and type, rank, and shape conformance checking for component default initializers in derived types and PDT instantiations. The initial values of named constants are now guaranteed to have been folded when installed in the symbol table, and are no longer folded or scalar-expanded at each use in expression folding. Semantics documentation was extended with information about the various kinds of initializations in Fortran and when each of them are processed in the compiler. Some necessary concomitant changes have bulked this patch out a bit: * contextual messages attachments, which are now produced for parameterized derived type instantiations so that the user can figure out which instance caused a problem with a component, have been added as part of ContextualMessages, and their implementation was debugged * several APIs in evaluate::characteristics was changed so that a FoldingContext is passed as an argument rather than just its intrinsic procedure table; this affected client call sites in many files * new tools in Evaluate/check-expression.cpp to determine when an Expr actually is a single constant value and to validate a non-pointer variable initializer or object component default value * shape conformance checking has additional arguments that control whether scalar expansion is allowed * several now-unused functions and data members noticed and removed * several crashes and bogus errors exposed by testing this new code were fixed * a -fdebug-stack-trace option to enable LLVM's stack tracing on a crash, which might be useful in the future TL;DR: Initialization processing does more and takes place at the right times for all of the various kinds of things that can be initialized. Differential Review: https://reviews.llvm.org/D92783
2020-12-08 04:08:58 +08:00
return Folder<SomeDerived>{context_}.GetNamedConstant(symbol);
},
[&](ArrayRef &aRef) {
return Folder<SomeDerived>{context_}.Folding(aRef);
},
[&](Component &base) {
return Folder<SomeDerived>{context_}.GetConstantComponent(base);
},
[&](CoarrayRef &) {
return std::optional<Constant<SomeDerived>>{};
},
},
component.base().u)}) {
return ApplyComponent(
std::move(*structures), component.GetLastSymbol(), subscripts);
} else {
return std::nullopt;
}
}
template <typename T> Expr<T> Folder<T>::Folding(Designator<T> &&designator) {
if constexpr (T::category == TypeCategory::Character) {
if (auto *substring{common::Unwrap<Substring>(designator.u)}) {
if (std::optional<Expr<SomeCharacter>> folded{
substring->Fold(context_)}) {
if (auto value{GetScalarConstantValue<T>(*folded)}) {
return Expr<T>{*value};
}
}
if (auto length{ToInt64(Fold(context_, substring->LEN()))}) {
if (*length == 0) {
return Expr<T>{Constant<T>{Scalar<T>{}}};
}
}
}
}
return std::visit(
common::visitors{
[&](SymbolRef &&symbol) {
[flang] Improve initializer semantics, esp. for component default values This patch plugs many holes in static initializer semantics, improves error messages for default initial values and other component properties in parameterized derived type instantiations, and cleans up several small issues noticed during development. We now do proper scalar expansion, folding, and type, rank, and shape conformance checking for component default initializers in derived types and PDT instantiations. The initial values of named constants are now guaranteed to have been folded when installed in the symbol table, and are no longer folded or scalar-expanded at each use in expression folding. Semantics documentation was extended with information about the various kinds of initializations in Fortran and when each of them are processed in the compiler. Some necessary concomitant changes have bulked this patch out a bit: * contextual messages attachments, which are now produced for parameterized derived type instantiations so that the user can figure out which instance caused a problem with a component, have been added as part of ContextualMessages, and their implementation was debugged * several APIs in evaluate::characteristics was changed so that a FoldingContext is passed as an argument rather than just its intrinsic procedure table; this affected client call sites in many files * new tools in Evaluate/check-expression.cpp to determine when an Expr actually is a single constant value and to validate a non-pointer variable initializer or object component default value * shape conformance checking has additional arguments that control whether scalar expansion is allowed * several now-unused functions and data members noticed and removed * several crashes and bogus errors exposed by testing this new code were fixed * a -fdebug-stack-trace option to enable LLVM's stack tracing on a crash, which might be useful in the future TL;DR: Initialization processing does more and takes place at the right times for all of the various kinds of things that can be initialized. Differential Review: https://reviews.llvm.org/D92783
2020-12-08 04:08:58 +08:00
if (auto constant{GetNamedConstant(*symbol)}) {
return Expr<T>{std::move(*constant)};
}
return Expr<T>{std::move(designator)};
},
[&](ArrayRef &&aRef) {
aRef = FoldOperation(context_, std::move(aRef));
if (auto c{Folding(aRef)}) {
return Expr<T>{std::move(*c)};
} else {
return Expr<T>{Designator<T>{std::move(aRef)}};
}
},
[&](Component &&component) {
component = FoldOperation(context_, std::move(component));
if (auto c{GetConstantComponent(component)}) {
return Expr<T>{std::move(*c)};
} else {
return Expr<T>{Designator<T>{std::move(component)}};
}
},
[&](auto &&x) {
return Expr<T>{
Designator<T>{FoldOperation(context_, std::move(x))}};
},
},
std::move(designator.u));
}
// Apply type conversion and re-folding if necessary.
// This is where BOZ arguments are converted.
template <typename T>
Constant<T> *Folder<T>::Folding(std::optional<ActualArgument> &arg) {
if (auto *expr{UnwrapExpr<Expr<SomeType>>(arg)}) {
if (!UnwrapExpr<Expr<T>>(*expr)) {
if (auto converted{ConvertToType(T::GetType(), std::move(*expr))}) {
*expr = Fold(context_, std::move(*converted));
}
}
return UnwrapConstantValue<T>(*expr);
}
return nullptr;
}
template <typename... A, std::size_t... I>
std::optional<std::tuple<const Constant<A> *...>> GetConstantArgumentsHelper(
FoldingContext &context, ActualArguments &arguments,
std::index_sequence<I...>) {
static_assert(
(... && IsSpecificIntrinsicType<A>)); // TODO derived types for MERGE?
static_assert(sizeof...(A) > 0);
std::tuple<const Constant<A> *...> args{
Folder<A>{context}.Folding(arguments.at(I))...};
if ((... && (std::get<I>(args)))) {
return args;
} else {
return std::nullopt;
}
}
template <typename... A>
std::optional<std::tuple<const Constant<A> *...>> GetConstantArguments(
FoldingContext &context, ActualArguments &args) {
return GetConstantArgumentsHelper<A...>(
context, args, std::index_sequence_for<A...>{});
}
template <typename... A, std::size_t... I>
std::optional<std::tuple<Scalar<A>...>> GetScalarConstantArgumentsHelper(
FoldingContext &context, ActualArguments &args, std::index_sequence<I...>) {
if (auto constArgs{GetConstantArguments<A...>(context, args)}) {
return std::tuple<Scalar<A>...>{
std::get<I>(*constArgs)->GetScalarValue().value()...};
} else {
return std::nullopt;
}
}
template <typename... A>
std::optional<std::tuple<Scalar<A>...>> GetScalarConstantArguments(
FoldingContext &context, ActualArguments &args) {
return GetScalarConstantArgumentsHelper<A...>(
context, args, std::index_sequence_for<A...>{});
}
// helpers to fold intrinsic function references
// Define callable types used in a common utility that
// takes care of array and cast/conversion aspects for elemental intrinsics
template <typename TR, typename... TArgs>
using ScalarFunc = std::function<Scalar<TR>(const Scalar<TArgs> &...)>;
template <typename TR, typename... TArgs>
using ScalarFuncWithContext =
std::function<Scalar<TR>(FoldingContext &, const Scalar<TArgs> &...)>;
template <template <typename, typename...> typename WrapperType, typename TR,
typename... TA, std::size_t... I>
Expr<TR> FoldElementalIntrinsicHelper(FoldingContext &context,
FunctionRef<TR> &&funcRef, WrapperType<TR, TA...> func,
std::index_sequence<I...>) {
if (std::optional<std::tuple<const Constant<TA> *...>> args{
GetConstantArguments<TA...>(context, funcRef.arguments())}) {
// Compute the shape of the result based on shapes of arguments
ConstantSubscripts shape;
int rank{0};
const ConstantSubscripts *shapes[]{&std::get<I>(*args)->shape()...};
const int ranks[]{std::get<I>(*args)->Rank()...};
for (unsigned int i{0}; i < sizeof...(TA); ++i) {
if (ranks[i] > 0) {
if (rank == 0) {
rank = ranks[i];
shape = *shapes[i];
} else {
if (shape != *shapes[i]) {
// TODO: Rank compatibility was already checked but it seems to be
// the first place where the actual shapes are checked to be the
// same. Shouldn't this be checked elsewhere so that this is also
// checked for non constexpr call to elemental intrinsics function?
context.messages().Say(
"Arguments in elemental intrinsic function are not conformable"_err_en_US);
return Expr<TR>{std::move(funcRef)};
}
}
}
}
CHECK(rank == GetRank(shape));
// Compute all the scalar values of the results
std::vector<Scalar<TR>> results;
if (TotalElementCount(shape) > 0) {
ConstantBounds bounds{shape};
ConstantSubscripts resultIndex(rank, 1);
ConstantSubscripts argIndex[]{std::get<I>(*args)->lbounds()...};
do {
if constexpr (std::is_same_v<WrapperType<TR, TA...>,
ScalarFuncWithContext<TR, TA...>>) {
results.emplace_back(
func(context, std::get<I>(*args)->At(argIndex[I])...));
} else if constexpr (std::is_same_v<WrapperType<TR, TA...>,
ScalarFunc<TR, TA...>>) {
results.emplace_back(func(std::get<I>(*args)->At(argIndex[I])...));
}
(std::get<I>(*args)->IncrementSubscripts(argIndex[I]), ...);
} while (bounds.IncrementSubscripts(resultIndex));
}
// Build and return constant result
if constexpr (TR::category == TypeCategory::Character) {
auto len{static_cast<ConstantSubscript>(
results.empty() ? 0 : results[0].length())};
return Expr<TR>{Constant<TR>{len, std::move(results), std::move(shape)}};
} else {
return Expr<TR>{Constant<TR>{std::move(results), std::move(shape)}};
}
}
return Expr<TR>{std::move(funcRef)};
}
template <typename TR, typename... TA>
Expr<TR> FoldElementalIntrinsic(FoldingContext &context,
FunctionRef<TR> &&funcRef, ScalarFunc<TR, TA...> func) {
return FoldElementalIntrinsicHelper<ScalarFunc, TR, TA...>(
context, std::move(funcRef), func, std::index_sequence_for<TA...>{});
}
template <typename TR, typename... TA>
Expr<TR> FoldElementalIntrinsic(FoldingContext &context,
FunctionRef<TR> &&funcRef, ScalarFuncWithContext<TR, TA...> func) {
return FoldElementalIntrinsicHelper<ScalarFuncWithContext, TR, TA...>(
context, std::move(funcRef), func, std::index_sequence_for<TA...>{});
}
std::optional<std::int64_t> GetInt64Arg(const std::optional<ActualArgument> &);
std::optional<std::int64_t> GetInt64ArgOr(
const std::optional<ActualArgument> &, std::int64_t defaultValue);
template <typename A, typename B>
std::optional<std::vector<A>> GetIntegerVector(const B &x) {
static_assert(std::is_integral_v<A>);
if (const auto *someInteger{UnwrapExpr<Expr<SomeInteger>>(x)}) {
return std::visit(
[](const auto &typedExpr) -> std::optional<std::vector<A>> {
using T = ResultType<decltype(typedExpr)>;
if (const auto *constant{UnwrapConstantValue<T>(typedExpr)}) {
if (constant->Rank() == 1) {
std::vector<A> result;
for (const auto &value : constant->values()) {
result.push_back(static_cast<A>(value.ToInt64()));
}
return result;
}
}
return std::nullopt;
},
someInteger->u);
}
return std::nullopt;
}
// Transform an intrinsic function reference that contains user errors
// into an intrinsic with the same characteristic but the "invalid" name.
// This to prevent generating warnings over and over if the expression
// gets re-folded.
template <typename T> Expr<T> MakeInvalidIntrinsic(FunctionRef<T> &&funcRef) {
SpecificIntrinsic invalid{std::get<SpecificIntrinsic>(funcRef.proc().u)};
invalid.name = IntrinsicProcTable::InvalidName;
return Expr<T>{FunctionRef<T>{ProcedureDesignator{std::move(invalid)},
ActualArguments{std::move(funcRef.arguments())}}};
}
template <typename T> Expr<T> Folder<T>::CSHIFT(FunctionRef<T> &&funcRef) {
auto args{funcRef.arguments()};
CHECK(args.size() == 3);
const auto *array{UnwrapConstantValue<T>(args[0])};
const auto *shiftExpr{UnwrapExpr<Expr<SomeInteger>>(args[1])};
auto dim{GetInt64ArgOr(args[2], 1)};
if (!array || !shiftExpr || !dim) {
return Expr<T>{std::move(funcRef)};
}
auto convertedShift{Fold(context_,
ConvertToType<SubscriptInteger>(Expr<SomeInteger>{*shiftExpr}))};
const auto *shift{UnwrapConstantValue<SubscriptInteger>(convertedShift)};
if (!shift) {
return Expr<T>{std::move(funcRef)};
}
// Arguments are constant
if (*dim < 1 || *dim > array->Rank()) {
context_.messages().Say("Invalid 'dim=' argument (%jd) in CSHIFT"_err_en_US,
static_cast<std::intmax_t>(*dim));
} else if (shift->Rank() > 0 && shift->Rank() != array->Rank() - 1) {
// message already emitted from intrinsic look-up
} else {
int rank{array->Rank()};
int zbDim{static_cast<int>(*dim) - 1};
bool ok{true};
if (shift->Rank() > 0) {
int k{0};
for (int j{0}; j < rank; ++j) {
if (j != zbDim) {
if (array->shape()[j] != shift->shape()[k]) {
context_.messages().Say(
"Invalid 'shift=' argument in CSHIFT: extent on dimension %d is %jd but must be %jd"_err_en_US,
k + 1, static_cast<std::intmax_t>(shift->shape()[k]),
static_cast<std::intmax_t>(array->shape()[j]));
ok = false;
}
++k;
}
}
}
if (ok) {
std::vector<Scalar<T>> resultElements;
ConstantSubscripts arrayAt{array->lbounds()};
ConstantSubscript dimLB{arrayAt[zbDim]};
ConstantSubscript dimExtent{array->shape()[zbDim]};
ConstantSubscripts shiftAt{shift->lbounds()};
for (auto n{GetSize(array->shape())}; n > 0; n -= dimExtent) {
ConstantSubscript shiftCount{shift->At(shiftAt).ToInt64()};
ConstantSubscript zbDimIndex{shiftCount % dimExtent};
if (zbDimIndex < 0) {
zbDimIndex += dimExtent;
}
for (ConstantSubscript j{0}; j < dimExtent; ++j) {
arrayAt[zbDim] = dimLB + zbDimIndex;
resultElements.push_back(array->At(arrayAt));
if (++zbDimIndex == dimExtent) {
zbDimIndex = 0;
}
}
arrayAt[zbDim] = dimLB + dimExtent - 1;
array->IncrementSubscripts(arrayAt);
shift->IncrementSubscripts(shiftAt);
}
return Expr<T>{PackageConstant<T>(
std::move(resultElements), *array, array->shape())};
}
}
// Invalid, prevent re-folding
return MakeInvalidIntrinsic(std::move(funcRef));
}
template <typename T> Expr<T> Folder<T>::EOSHIFT(FunctionRef<T> &&funcRef) {
auto args{funcRef.arguments()};
CHECK(args.size() == 4);
const auto *array{UnwrapConstantValue<T>(args[0])};
const auto *shiftExpr{UnwrapExpr<Expr<SomeInteger>>(args[1])};
auto dim{GetInt64ArgOr(args[3], 1)};
if (!array || !shiftExpr || !dim) {
return Expr<T>{std::move(funcRef)};
}
// Apply type conversions to the shift= and boundary= arguments.
auto convertedShift{Fold(context_,
ConvertToType<SubscriptInteger>(Expr<SomeInteger>{*shiftExpr}))};
const auto *shift{UnwrapConstantValue<SubscriptInteger>(convertedShift)};
if (!shift) {
return Expr<T>{std::move(funcRef)};
}
const Constant<T> *boundary{nullptr};
std::optional<Expr<SomeType>> convertedBoundary;
if (const auto *boundaryExpr{UnwrapExpr<Expr<SomeType>>(args[2])}) {
convertedBoundary = Fold(context_,
ConvertToType(array->GetType(), Expr<SomeType>{*boundaryExpr}));
boundary = UnwrapExpr<Constant<T>>(convertedBoundary);
if (!boundary) {
return Expr<T>{std::move(funcRef)};
}
}
// Arguments are constant
if (*dim < 1 || *dim > array->Rank()) {
context_.messages().Say(
"Invalid 'dim=' argument (%jd) in EOSHIFT"_err_en_US,
static_cast<std::intmax_t>(*dim));
} else if (shift->Rank() > 0 && shift->Rank() != array->Rank() - 1) {
// message already emitted from intrinsic look-up
} else if (boundary && boundary->Rank() > 0 &&
boundary->Rank() != array->Rank() - 1) {
// ditto
} else {
int rank{array->Rank()};
int zbDim{static_cast<int>(*dim) - 1};
bool ok{true};
if (shift->Rank() > 0) {
int k{0};
for (int j{0}; j < rank; ++j) {
if (j != zbDim) {
if (array->shape()[j] != shift->shape()[k]) {
context_.messages().Say(
"Invalid 'shift=' argument in EOSHIFT: extent on dimension %d is %jd but must be %jd"_err_en_US,
k + 1, static_cast<std::intmax_t>(shift->shape()[k]),
static_cast<std::intmax_t>(array->shape()[j]));
ok = false;
}
++k;
}
}
}
if (boundary && boundary->Rank() > 0) {
int k{0};
for (int j{0}; j < rank; ++j) {
if (j != zbDim) {
if (array->shape()[j] != boundary->shape()[k]) {
context_.messages().Say(
"Invalid 'boundary=' argument in EOSHIFT: extent on dimension %d is %jd but must be %jd"_err_en_US,
k + 1, static_cast<std::intmax_t>(boundary->shape()[k]),
static_cast<std::intmax_t>(array->shape()[j]));
ok = false;
}
++k;
}
}
}
if (ok) {
std::vector<Scalar<T>> resultElements;
ConstantSubscripts arrayAt{array->lbounds()};
ConstantSubscript dimLB{arrayAt[zbDim]};
ConstantSubscript dimExtent{array->shape()[zbDim]};
ConstantSubscripts shiftAt{shift->lbounds()};
ConstantSubscripts boundaryAt;
if (boundary) {
boundaryAt = boundary->lbounds();
}
for (auto n{GetSize(array->shape())}; n > 0; n -= dimExtent) {
ConstantSubscript shiftCount{shift->At(shiftAt).ToInt64()};
for (ConstantSubscript j{0}; j < dimExtent; ++j) {
ConstantSubscript zbAt{shiftCount + j};
if (zbAt >= 0 && zbAt < dimExtent) {
arrayAt[zbDim] = dimLB + zbAt;
resultElements.push_back(array->At(arrayAt));
} else if (boundary) {
resultElements.push_back(boundary->At(boundaryAt));
} else if constexpr (T::category == TypeCategory::Integer ||
T::category == TypeCategory::Real ||
T::category == TypeCategory::Complex ||
T::category == TypeCategory::Logical) {
resultElements.emplace_back();
} else if constexpr (T::category == TypeCategory::Character) {
auto len{static_cast<std::size_t>(array->LEN())};
typename Scalar<T>::value_type space{' '};
resultElements.emplace_back(len, space);
} else {
DIE("no derived type boundary");
}
}
arrayAt[zbDim] = dimLB + dimExtent - 1;
array->IncrementSubscripts(arrayAt);
shift->IncrementSubscripts(shiftAt);
if (boundary) {
boundary->IncrementSubscripts(boundaryAt);
}
}
return Expr<T>{PackageConstant<T>(
std::move(resultElements), *array, array->shape())};
}
}
// Invalid, prevent re-folding
return MakeInvalidIntrinsic(std::move(funcRef));
}
template <typename T> Expr<T> Folder<T>::PACK(FunctionRef<T> &&funcRef) {
auto args{funcRef.arguments()};
CHECK(args.size() == 3);
const auto *array{UnwrapConstantValue<T>(args[0])};
const auto *vector{UnwrapConstantValue<T>(args[2])};
auto convertedMask{Fold(context_,
ConvertToType<LogicalResult>(
Expr<SomeLogical>{DEREF(UnwrapExpr<Expr<SomeLogical>>(args[1]))}))};
const auto *mask{UnwrapConstantValue<LogicalResult>(convertedMask)};
if (!array || !mask || (args[2] && !vector)) {
return Expr<T>{std::move(funcRef)};
}
// Arguments are constant.
ConstantSubscript arrayElements{GetSize(array->shape())};
ConstantSubscript truths{0};
ConstantSubscripts maskAt{mask->lbounds()};
if (mask->Rank() == 0) {
if (mask->At(maskAt).IsTrue()) {
truths = arrayElements;
}
} else if (array->shape() != mask->shape()) {
// Error already emitted from intrinsic processing
return MakeInvalidIntrinsic(std::move(funcRef));
} else {
for (ConstantSubscript j{0}; j < arrayElements;
++j, mask->IncrementSubscripts(maskAt)) {
if (mask->At(maskAt).IsTrue()) {
++truths;
}
}
}
std::vector<Scalar<T>> resultElements;
ConstantSubscripts arrayAt{array->lbounds()};
ConstantSubscript resultSize{truths};
if (vector) {
resultSize = vector->shape().at(0);
if (resultSize < truths) {
context_.messages().Say(
"Invalid 'vector=' argument in PACK: the 'mask=' argument has %jd true elements, but the vector has only %jd elements"_err_en_US,
static_cast<std::intmax_t>(truths),
static_cast<std::intmax_t>(resultSize));
return MakeInvalidIntrinsic(std::move(funcRef));
}
}
for (ConstantSubscript j{0}; j < truths;) {
if (mask->At(maskAt).IsTrue()) {
resultElements.push_back(array->At(arrayAt));
++j;
}
array->IncrementSubscripts(arrayAt);
mask->IncrementSubscripts(maskAt);
}
if (vector) {
ConstantSubscripts vectorAt{vector->lbounds()};
vectorAt.at(0) += truths;
for (ConstantSubscript j{truths}; j < resultSize; ++j) {
resultElements.push_back(vector->At(vectorAt));
++vectorAt[0];
}
}
return Expr<T>{PackageConstant<T>(std::move(resultElements), *array,
ConstantSubscripts{static_cast<ConstantSubscript>(resultSize)})};
}
template <typename T> Expr<T> Folder<T>::RESHAPE(FunctionRef<T> &&funcRef) {
auto args{funcRef.arguments()};
CHECK(args.size() == 4);
const auto *source{UnwrapConstantValue<T>(args[0])};
const auto *pad{UnwrapConstantValue<T>(args[2])};
std::optional<std::vector<ConstantSubscript>> shape{
GetIntegerVector<ConstantSubscript>(args[1])};
std::optional<std::vector<int>> order{GetIntegerVector<int>(args[3])};
if (!source || !shape || (args[2] && !pad) || (args[3] && !order)) {
return Expr<T>{std::move(funcRef)}; // Non-constant arguments
} else if (shape.value().size() > common::maxRank) {
context_.messages().Say(
"Size of 'shape=' argument must not be greater than %d"_err_en_US,
common::maxRank);
} else if (HasNegativeExtent(shape.value())) {
context_.messages().Say(
"'shape=' argument must not have a negative extent"_err_en_US);
} else {
int rank{GetRank(shape.value())};
std::size_t resultElements{TotalElementCount(shape.value())};
std::optional<std::vector<int>> dimOrder;
if (order) {
dimOrder = ValidateDimensionOrder(rank, *order);
}
std::vector<int> *dimOrderPtr{dimOrder ? &dimOrder.value() : nullptr};
if (order && !dimOrder) {
context_.messages().Say("Invalid 'order=' argument in RESHAPE"_err_en_US);
} else if (resultElements > source->size() && (!pad || pad->empty())) {
context_.messages().Say(
"Too few elements in 'source=' argument and 'pad=' "
"argument is not present or has null size"_err_en_US);
} else {
Constant<T> result{!source->empty() || !pad
? source->Reshape(std::move(shape.value()))
: pad->Reshape(std::move(shape.value()))};
ConstantSubscripts subscripts{result.lbounds()};
auto copied{result.CopyFrom(*source,
std::min(source->size(), resultElements), subscripts, dimOrderPtr)};
if (copied < resultElements) {
CHECK(pad);
copied += result.CopyFrom(
*pad, resultElements - copied, subscripts, dimOrderPtr);
}
CHECK(copied == resultElements);
return Expr<T>{std::move(result)};
}
}
// Invalid, prevent re-folding
return MakeInvalidIntrinsic(std::move(funcRef));
}
template <typename T> Expr<T> Folder<T>::TRANSPOSE(FunctionRef<T> &&funcRef) {
auto args{funcRef.arguments()};
CHECK(args.size() == 1);
const auto *matrix{UnwrapConstantValue<T>(args[0])};
if (!matrix) {
return Expr<T>{std::move(funcRef)};
}
// Argument is constant. Traverse its elements in transposed order.
std::vector<Scalar<T>> resultElements;
ConstantSubscripts at(2);
for (ConstantSubscript j{0}; j < matrix->shape()[0]; ++j) {
at[0] = matrix->lbounds()[0] + j;
for (ConstantSubscript k{0}; k < matrix->shape()[1]; ++k) {
at[1] = matrix->lbounds()[1] + k;
resultElements.push_back(matrix->At(at));
}
}
at = matrix->shape();
std::swap(at[0], at[1]);
return Expr<T>{PackageConstant<T>(std::move(resultElements), *matrix, at)};
}
template <typename T> Expr<T> Folder<T>::UNPACK(FunctionRef<T> &&funcRef) {
auto args{funcRef.arguments()};
CHECK(args.size() == 3);
const auto *vector{UnwrapConstantValue<T>(args[0])};
auto convertedMask{Fold(context_,
ConvertToType<LogicalResult>(
Expr<SomeLogical>{DEREF(UnwrapExpr<Expr<SomeLogical>>(args[1]))}))};
const auto *mask{UnwrapConstantValue<LogicalResult>(convertedMask)};
const auto *field{UnwrapConstantValue<T>(args[2])};
if (!vector || !mask || !field) {
return Expr<T>{std::move(funcRef)};
}
// Arguments are constant.
if (field->Rank() > 0 && field->shape() != mask->shape()) {
// Error already emitted from intrinsic processing
return MakeInvalidIntrinsic(std::move(funcRef));
}
ConstantSubscript maskElements{GetSize(mask->shape())};
ConstantSubscript truths{0};
ConstantSubscripts maskAt{mask->lbounds()};
for (ConstantSubscript j{0}; j < maskElements;
++j, mask->IncrementSubscripts(maskAt)) {
if (mask->At(maskAt).IsTrue()) {
++truths;
}
}
if (truths > GetSize(vector->shape())) {
context_.messages().Say(
"Invalid 'vector=' argument in UNPACK: the 'mask=' argument has %jd true elements, but the vector has only %jd elements"_err_en_US,
static_cast<std::intmax_t>(truths),
static_cast<std::intmax_t>(GetSize(vector->shape())));
return MakeInvalidIntrinsic(std::move(funcRef));
}
std::vector<Scalar<T>> resultElements;
ConstantSubscripts vectorAt{vector->lbounds()};
ConstantSubscripts fieldAt{field->lbounds()};
for (ConstantSubscript j{0}; j < maskElements; ++j) {
if (mask->At(maskAt).IsTrue()) {
resultElements.push_back(vector->At(vectorAt));
vector->IncrementSubscripts(vectorAt);
} else {
resultElements.push_back(field->At(fieldAt));
}
mask->IncrementSubscripts(maskAt);
field->IncrementSubscripts(fieldAt);
}
return Expr<T>{
PackageConstant<T>(std::move(resultElements), *vector, mask->shape())};
}
template <typename T>
Expr<T> FoldMINorMAX(
FoldingContext &context, FunctionRef<T> &&funcRef, Ordering order) {
static_assert(T::category == TypeCategory::Integer ||
T::category == TypeCategory::Real ||
T::category == TypeCategory::Character);
std::vector<Constant<T> *> constantArgs;
// Call Folding on all arguments, even if some are not constant,
// to make operand promotion explicit.
for (auto &arg : funcRef.arguments()) {
if (auto *cst{Folder<T>{context}.Folding(arg)}) {
constantArgs.push_back(cst);
}
}
if (constantArgs.size() != funcRef.arguments().size()) {
return Expr<T>(std::move(funcRef));
}
CHECK(!constantArgs.empty());
Expr<T> result{std::move(*constantArgs[0])};
for (std::size_t i{1}; i < constantArgs.size(); ++i) {
Extremum<T> extremum{order, result, Expr<T>{std::move(*constantArgs[i])}};
result = FoldOperation(context, std::move(extremum));
}
return result;
}
// For AMAX0, AMIN0, AMAX1, AMIN1, DMAX1, DMIN1, MAX0, MIN0, MAX1, and MIN1
// a special care has to be taken to insert the conversion on the result
// of the MIN/MAX. This is made slightly more complex by the extension
// supported by f18 that arguments may have different kinds. This implies
// that the created MIN/MAX result type cannot be deduced from the standard but
// has to be deduced from the arguments.
// e.g. AMAX0(int8, int4) is rewritten to REAL(MAX(int8, INT(int4, 8)))).
template <typename T>
Expr<T> RewriteSpecificMINorMAX(
FoldingContext &context, FunctionRef<T> &&funcRef) {
ActualArguments &args{funcRef.arguments()};
auto &intrinsic{DEREF(std::get_if<SpecificIntrinsic>(&funcRef.proc().u))};
// Rewrite MAX1(args) to INT(MAX(args)) and fold. Same logic for MIN1.
// Find result type for max/min based on the arguments.
DynamicType resultType{args[0].value().GetType().value()};
auto *resultTypeArg{&args[0]};
for (auto j{args.size() - 1}; j > 0; --j) {
DynamicType type{args[j].value().GetType().value()};
if (type.category() == resultType.category()) {
if (type.kind() > resultType.kind()) {
resultTypeArg = &args[j];
resultType = type;
}
} else if (resultType.category() == TypeCategory::Integer) {
// Handle mixed real/integer arguments: all the previous arguments were
// integers and this one is real. The type of the MAX/MIN result will
// be the one of the real argument.
resultTypeArg = &args[j];
resultType = type;
}
}
intrinsic.name =
intrinsic.name.find("max") != std::string::npos ? "max"s : "min"s;
intrinsic.characteristics.value().functionResult.value().SetType(resultType);
auto insertConversion{[&](const auto &x) -> Expr<T> {
using TR = ResultType<decltype(x)>;
FunctionRef<TR> maxRef{std::move(funcRef.proc()), std::move(args)};
return Fold(context, ConvertToType<T>(AsCategoryExpr(std::move(maxRef))));
}};
if (auto *sx{UnwrapExpr<Expr<SomeReal>>(*resultTypeArg)}) {
return std::visit(insertConversion, sx->u);
}
auto &sx{DEREF(UnwrapExpr<Expr<SomeInteger>>(*resultTypeArg))};
return std::visit(insertConversion, sx.u);
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, FunctionRef<T> &&funcRef) {
ActualArguments &args{funcRef.arguments()};
for (std::optional<ActualArgument> &arg : args) {
if (auto *expr{UnwrapExpr<Expr<SomeType>>(arg)}) {
*expr = Fold(context, std::move(*expr));
}
}
if (auto *intrinsic{std::get_if<SpecificIntrinsic>(&funcRef.proc().u)}) {
const std::string name{intrinsic->name};
if (name == "cshift") {
return Folder<T>{context}.CSHIFT(std::move(funcRef));
} else if (name == "eoshift") {
return Folder<T>{context}.EOSHIFT(std::move(funcRef));
} else if (name == "pack") {
return Folder<T>{context}.PACK(std::move(funcRef));
} else if (name == "reshape") {
return Folder<T>{context}.RESHAPE(std::move(funcRef));
} else if (name == "transpose") {
return Folder<T>{context}.TRANSPOSE(std::move(funcRef));
} else if (name == "unpack") {
return Folder<T>{context}.UNPACK(std::move(funcRef));
}
// TODO: spread
// TODO: extends_type_of, same_type_as
if constexpr (!std::is_same_v<T, SomeDerived>) {
return FoldIntrinsicFunction(context, std::move(funcRef));
}
}
return Expr<T>{std::move(funcRef)};
}
template <typename T>
Expr<T> FoldMerge(FoldingContext &context, FunctionRef<T> &&funcRef) {
return FoldElementalIntrinsic<T, T, T, LogicalResult>(context,
std::move(funcRef),
ScalarFunc<T, T, T, LogicalResult>(
[](const Scalar<T> &ifTrue, const Scalar<T> &ifFalse,
const Scalar<LogicalResult> &predicate) -> Scalar<T> {
return predicate.IsTrue() ? ifTrue : ifFalse;
}));
}
Expr<ImpliedDoIndex::Result> FoldOperation(FoldingContext &, ImpliedDoIndex &&);
// Array constructor folding
template <typename T> class ArrayConstructorFolder {
public:
explicit ArrayConstructorFolder(const FoldingContext &c) : context_{c} {}
Expr<T> FoldArray(ArrayConstructor<T> &&array) {
// Calls FoldArray(const ArrayConstructorValues<T> &) below
if (FoldArray(array)) {
auto n{static_cast<ConstantSubscript>(elements_.size())};
if constexpr (std::is_same_v<T, SomeDerived>) {
return Expr<T>{Constant<T>{array.GetType().GetDerivedTypeSpec(),
std::move(elements_), ConstantSubscripts{n}}};
} else if constexpr (T::category == TypeCategory::Character) {
auto length{Fold(context_, common::Clone(array.LEN()))};
if (std::optional<ConstantSubscript> lengthValue{ToInt64(length)}) {
return Expr<T>{Constant<T>{
*lengthValue, std::move(elements_), ConstantSubscripts{n}}};
}
} else {
return Expr<T>{
Constant<T>{std::move(elements_), ConstantSubscripts{n}}};
}
}
return Expr<T>{std::move(array)};
}
private:
bool FoldArray(const common::CopyableIndirection<Expr<T>> &expr) {
Expr<T> folded{Fold(context_, common::Clone(expr.value()))};
if (const auto *c{UnwrapConstantValue<T>(folded)}) {
// Copy elements in Fortran array element order
if (!c->empty()) {
ConstantSubscripts index{c->lbounds()};
do {
elements_.emplace_back(c->At(index));
} while (c->IncrementSubscripts(index));
}
return true;
} else {
return false;
}
}
bool FoldArray(const ImpliedDo<T> &iDo) {
Expr<SubscriptInteger> lower{
Fold(context_, Expr<SubscriptInteger>{iDo.lower()})};
Expr<SubscriptInteger> upper{
Fold(context_, Expr<SubscriptInteger>{iDo.upper()})};
Expr<SubscriptInteger> stride{
Fold(context_, Expr<SubscriptInteger>{iDo.stride()})};
std::optional<ConstantSubscript> start{ToInt64(lower)}, end{ToInt64(upper)},
step{ToInt64(stride)};
if (start && end && step && *step != 0) {
bool result{true};
ConstantSubscript &j{context_.StartImpliedDo(iDo.name(), *start)};
if (*step > 0) {
for (; j <= *end; j += *step) {
result &= FoldArray(iDo.values());
}
} else {
for (; j >= *end; j += *step) {
result &= FoldArray(iDo.values());
}
}
context_.EndImpliedDo(iDo.name());
return result;
} else {
return false;
}
}
bool FoldArray(const ArrayConstructorValue<T> &x) {
return std::visit([&](const auto &y) { return FoldArray(y); }, x.u);
}
bool FoldArray(const ArrayConstructorValues<T> &xs) {
for (const auto &x : xs) {
if (!FoldArray(x)) {
return false;
}
}
return true;
}
FoldingContext context_;
std::vector<Scalar<T>> elements_;
};
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, ArrayConstructor<T> &&array) {
return ArrayConstructorFolder<T>{context}.FoldArray(std::move(array));
}
// Array operation elemental application: When all operands to an operation
// are constant arrays, array constructors without any implied DO loops,
// &/or expanded scalars, pull the operation "into" the array result by
// applying it in an elementwise fashion. For example, [A,1]+[B,2]
// is rewritten into [A+B,1+2] and then partially folded to [A+B,3].
// If possible, restructures an array expression into an array constructor
// that comprises a "flat" ArrayConstructorValues with no implied DO loops.
template <typename T>
bool ArrayConstructorIsFlat(const ArrayConstructorValues<T> &values) {
for (const ArrayConstructorValue<T> &x : values) {
if (!std::holds_alternative<Expr<T>>(x.u)) {
return false;
}
}
return true;
}
template <typename T>
std::optional<Expr<T>> AsFlatArrayConstructor(const Expr<T> &expr) {
if (const auto *c{UnwrapConstantValue<T>(expr)}) {
ArrayConstructor<T> result{expr};
if (!c->empty()) {
ConstantSubscripts at{c->lbounds()};
do {
result.Push(Expr<T>{Constant<T>{c->At(at)}});
} while (c->IncrementSubscripts(at));
}
return std::make_optional<Expr<T>>(std::move(result));
} else if (const auto *a{UnwrapExpr<ArrayConstructor<T>>(expr)}) {
if (ArrayConstructorIsFlat(*a)) {
return std::make_optional<Expr<T>>(expr);
}
} else if (const auto *p{UnwrapExpr<Parentheses<T>>(expr)}) {
return AsFlatArrayConstructor(Expr<T>{p->left()});
}
return std::nullopt;
}
template <TypeCategory CAT>
std::enable_if_t<CAT != TypeCategory::Derived,
std::optional<Expr<SomeKind<CAT>>>>
AsFlatArrayConstructor(const Expr<SomeKind<CAT>> &expr) {
return std::visit(
[&](const auto &kindExpr) -> std::optional<Expr<SomeKind<CAT>>> {
if (auto flattened{AsFlatArrayConstructor(kindExpr)}) {
return Expr<SomeKind<CAT>>{std::move(*flattened)};
} else {
return std::nullopt;
}
},
expr.u);
}
// FromArrayConstructor is a subroutine for MapOperation() below.
// Given a flat ArrayConstructor<T> and a shape, it wraps the array
// into an Expr<T>, folds it, and returns the resulting wrapped
// array constructor or constant array value.
template <typename T>
Expr<T> FromArrayConstructor(FoldingContext &context,
ArrayConstructor<T> &&values, std::optional<ConstantSubscripts> &&shape) {
Expr<T> result{Fold(context, Expr<T>{std::move(values)})};
if (shape) {
if (auto *constant{UnwrapConstantValue<T>(result)}) {
return Expr<T>{constant->Reshape(std::move(*shape))};
}
}
return result;
}
// MapOperation is a utility for various specializations of ApplyElementwise()
// that follow. Given one or two flat ArrayConstructor<OPERAND> (wrapped in an
// Expr<OPERAND>) for some specific operand type(s), apply a given function f
// to each of their corresponding elements to produce a flat
// ArrayConstructor<RESULT> (wrapped in an Expr<RESULT>).
// Preserves shape.
// Unary case
template <typename RESULT, typename OPERAND>
Expr<RESULT> MapOperation(FoldingContext &context,
std::function<Expr<RESULT>(Expr<OPERAND> &&)> &&f, const Shape &shape,
Expr<OPERAND> &&values) {
ArrayConstructor<RESULT> result{values};
if constexpr (common::HasMember<OPERAND, AllIntrinsicCategoryTypes>) {
std::visit(
[&](auto &&kindExpr) {
using kindType = ResultType<decltype(kindExpr)>;
auto &aConst{std::get<ArrayConstructor<kindType>>(kindExpr.u)};
for (auto &acValue : aConst) {
auto &scalar{std::get<Expr<kindType>>(acValue.u)};
result.Push(Fold(context, f(Expr<OPERAND>{std::move(scalar)})));
}
},
std::move(values.u));
} else {
auto &aConst{std::get<ArrayConstructor<OPERAND>>(values.u)};
for (auto &acValue : aConst) {
auto &scalar{std::get<Expr<OPERAND>>(acValue.u)};
result.Push(Fold(context, f(std::move(scalar))));
}
}
return FromArrayConstructor(
context, std::move(result), AsConstantExtents(context, shape));
}
template <typename RESULT, typename A>
ArrayConstructor<RESULT> ArrayConstructorFromMold(
const A &prototype, std::optional<Expr<SubscriptInteger>> &&length) {
if constexpr (RESULT::category == TypeCategory::Character) {
return ArrayConstructor<RESULT>{
std::move(length.value()), ArrayConstructorValues<RESULT>{}};
} else {
return ArrayConstructor<RESULT>{prototype};
}
}
// array * array case
template <typename RESULT, typename LEFT, typename RIGHT>
Expr<RESULT> MapOperation(FoldingContext &context,
std::function<Expr<RESULT>(Expr<LEFT> &&, Expr<RIGHT> &&)> &&f,
const Shape &shape, std::optional<Expr<SubscriptInteger>> &&length,
Expr<LEFT> &&leftValues, Expr<RIGHT> &&rightValues) {
auto result{ArrayConstructorFromMold<RESULT>(leftValues, std::move(length))};
auto &leftArrConst{std::get<ArrayConstructor<LEFT>>(leftValues.u)};
if constexpr (common::HasMember<RIGHT, AllIntrinsicCategoryTypes>) {
std::visit(
[&](auto &&kindExpr) {
using kindType = ResultType<decltype(kindExpr)>;
auto &rightArrConst{std::get<ArrayConstructor<kindType>>(kindExpr.u)};
auto rightIter{rightArrConst.begin()};
for (auto &leftValue : leftArrConst) {
CHECK(rightIter != rightArrConst.end());
auto &leftScalar{std::get<Expr<LEFT>>(leftValue.u)};
auto &rightScalar{std::get<Expr<kindType>>(rightIter->u)};
result.Push(Fold(context,
f(std::move(leftScalar), Expr<RIGHT>{std::move(rightScalar)})));
++rightIter;
}
},
std::move(rightValues.u));
} else {
auto &rightArrConst{std::get<ArrayConstructor<RIGHT>>(rightValues.u)};
auto rightIter{rightArrConst.begin()};
for (auto &leftValue : leftArrConst) {
CHECK(rightIter != rightArrConst.end());
auto &leftScalar{std::get<Expr<LEFT>>(leftValue.u)};
auto &rightScalar{std::get<Expr<RIGHT>>(rightIter->u)};
result.Push(
Fold(context, f(std::move(leftScalar), std::move(rightScalar))));
++rightIter;
}
}
return FromArrayConstructor(
context, std::move(result), AsConstantExtents(context, shape));
}
// array * scalar case
template <typename RESULT, typename LEFT, typename RIGHT>
Expr<RESULT> MapOperation(FoldingContext &context,
std::function<Expr<RESULT>(Expr<LEFT> &&, Expr<RIGHT> &&)> &&f,
const Shape &shape, std::optional<Expr<SubscriptInteger>> &&length,
Expr<LEFT> &&leftValues, const Expr<RIGHT> &rightScalar) {
auto result{ArrayConstructorFromMold<RESULT>(leftValues, std::move(length))};
auto &leftArrConst{std::get<ArrayConstructor<LEFT>>(leftValues.u)};
for (auto &leftValue : leftArrConst) {
auto &leftScalar{std::get<Expr<LEFT>>(leftValue.u)};
result.Push(
Fold(context, f(std::move(leftScalar), Expr<RIGHT>{rightScalar})));
}
return FromArrayConstructor(
context, std::move(result), AsConstantExtents(context, shape));
}
// scalar * array case
template <typename RESULT, typename LEFT, typename RIGHT>
Expr<RESULT> MapOperation(FoldingContext &context,
std::function<Expr<RESULT>(Expr<LEFT> &&, Expr<RIGHT> &&)> &&f,
const Shape &shape, std::optional<Expr<SubscriptInteger>> &&length,
const Expr<LEFT> &leftScalar, Expr<RIGHT> &&rightValues) {
auto result{ArrayConstructorFromMold<RESULT>(leftScalar, std::move(length))};
if constexpr (common::HasMember<RIGHT, AllIntrinsicCategoryTypes>) {
std::visit(
[&](auto &&kindExpr) {
using kindType = ResultType<decltype(kindExpr)>;
auto &rightArrConst{std::get<ArrayConstructor<kindType>>(kindExpr.u)};
for (auto &rightValue : rightArrConst) {
auto &rightScalar{std::get<Expr<kindType>>(rightValue.u)};
result.Push(Fold(context,
f(Expr<LEFT>{leftScalar},
Expr<RIGHT>{std::move(rightScalar)})));
}
},
std::move(rightValues.u));
} else {
auto &rightArrConst{std::get<ArrayConstructor<RIGHT>>(rightValues.u)};
for (auto &rightValue : rightArrConst) {
auto &rightScalar{std::get<Expr<RIGHT>>(rightValue.u)};
result.Push(
Fold(context, f(Expr<LEFT>{leftScalar}, std::move(rightScalar))));
}
}
return FromArrayConstructor(
context, std::move(result), AsConstantExtents(context, shape));
}
template <typename DERIVED, typename RESULT, typename LEFT, typename RIGHT>
std::optional<Expr<SubscriptInteger>> ComputeResultLength(
Operation<DERIVED, RESULT, LEFT, RIGHT> &operation) {
if constexpr (RESULT::category == TypeCategory::Character) {
return Expr<RESULT>{operation.derived()}.LEN();
}
return std::nullopt;
}
// ApplyElementwise() recursively folds the operand expression(s) of an
// operation, then attempts to apply the operation to the (corresponding)
// scalar element(s) of those operands. Returns std::nullopt for scalars
// or unlinearizable operands.
template <typename DERIVED, typename RESULT, typename OPERAND>
auto ApplyElementwise(FoldingContext &context,
Operation<DERIVED, RESULT, OPERAND> &operation,
std::function<Expr<RESULT>(Expr<OPERAND> &&)> &&f)
-> std::optional<Expr<RESULT>> {
auto &expr{operation.left()};
expr = Fold(context, std::move(expr));
if (expr.Rank() > 0) {
if (std::optional<Shape> shape{GetShape(context, expr)}) {
if (auto values{AsFlatArrayConstructor(expr)}) {
return MapOperation(context, std::move(f), *shape, std::move(*values));
}
}
}
return std::nullopt;
}
template <typename DERIVED, typename RESULT, typename OPERAND>
auto ApplyElementwise(
FoldingContext &context, Operation<DERIVED, RESULT, OPERAND> &operation)
-> std::optional<Expr<RESULT>> {
return ApplyElementwise(context, operation,
std::function<Expr<RESULT>(Expr<OPERAND> &&)>{
[](Expr<OPERAND> &&operand) {
return Expr<RESULT>{DERIVED{std::move(operand)}};
}});
}
template <typename DERIVED, typename RESULT, typename LEFT, typename RIGHT>
auto ApplyElementwise(FoldingContext &context,
Operation<DERIVED, RESULT, LEFT, RIGHT> &operation,
std::function<Expr<RESULT>(Expr<LEFT> &&, Expr<RIGHT> &&)> &&f)
-> std::optional<Expr<RESULT>> {
auto resultLength{ComputeResultLength(operation)};
auto &leftExpr{operation.left()};
leftExpr = Fold(context, std::move(leftExpr));
auto &rightExpr{operation.right()};
rightExpr = Fold(context, std::move(rightExpr));
if (leftExpr.Rank() > 0) {
if (std::optional<Shape> leftShape{GetShape(context, leftExpr)}) {
if (auto left{AsFlatArrayConstructor(leftExpr)}) {
if (rightExpr.Rank() > 0) {
if (std::optional<Shape> rightShape{GetShape(context, rightExpr)}) {
if (auto right{AsFlatArrayConstructor(rightExpr)}) {
if (CheckConformance(context.messages(), *leftShape, *rightShape,
CheckConformanceFlags::EitherScalarExpandable)
.value_or(false /*fail if not known now to conform*/)) {
return MapOperation(context, std::move(f), *leftShape,
std::move(resultLength), std::move(*left),
std::move(*right));
} else {
return std::nullopt;
}
return MapOperation(context, std::move(f), *leftShape,
std::move(resultLength), std::move(*left), std::move(*right));
}
}
} else if (IsExpandableScalar(rightExpr)) {
return MapOperation(context, std::move(f), *leftShape,
std::move(resultLength), std::move(*left), rightExpr);
}
}
}
} else if (rightExpr.Rank() > 0 && IsExpandableScalar(leftExpr)) {
if (std::optional<Shape> shape{GetShape(context, rightExpr)}) {
if (auto right{AsFlatArrayConstructor(rightExpr)}) {
return MapOperation(context, std::move(f), *shape,
std::move(resultLength), leftExpr, std::move(*right));
}
}
}
return std::nullopt;
}
template <typename DERIVED, typename RESULT, typename LEFT, typename RIGHT>
auto ApplyElementwise(
FoldingContext &context, Operation<DERIVED, RESULT, LEFT, RIGHT> &operation)
-> std::optional<Expr<RESULT>> {
return ApplyElementwise(context, operation,
std::function<Expr<RESULT>(Expr<LEFT> &&, Expr<RIGHT> &&)>{
[](Expr<LEFT> &&left, Expr<RIGHT> &&right) {
return Expr<RESULT>{DERIVED{std::move(left), std::move(right)}};
}});
}
// Unary operations
template <typename TO, typename FROM>
common::IfNoLvalue<std::optional<TO>, FROM> ConvertString(FROM &&s) {
if constexpr (std::is_same_v<TO, FROM>) {
return std::make_optional<TO>(std::move(s));
} else {
// Fortran character conversion is well defined between distinct kinds
// only when the actual characters are valid 7-bit ASCII.
TO str;
for (auto iter{s.cbegin()}; iter != s.cend(); ++iter) {
if (static_cast<std::uint64_t>(*iter) > 127) {
return std::nullopt;
}
str.push_back(*iter);
}
return std::make_optional<TO>(std::move(str));
}
}
template <typename TO, TypeCategory FROMCAT>
Expr<TO> FoldOperation(
FoldingContext &context, Convert<TO, FROMCAT> &&convert) {
if (auto array{ApplyElementwise(context, convert)}) {
return *array;
}
struct {
FoldingContext &context;
Convert<TO, FROMCAT> &convert;
} msvcWorkaround{context, convert};
return std::visit(
[&msvcWorkaround](auto &kindExpr) -> Expr<TO> {
using Operand = ResultType<decltype(kindExpr)>;
// This variable is a workaround for msvc which emits an error when
// using the FROMCAT template parameter below.
TypeCategory constexpr FromCat{FROMCAT};
static_assert(FromCat == Operand::category);
auto &convert{msvcWorkaround.convert};
char buffer[64];
if (auto value{GetScalarConstantValue<Operand>(kindExpr)}) {
FoldingContext &ctx{msvcWorkaround.context};
if constexpr (TO::category == TypeCategory::Integer) {
if constexpr (FromCat == TypeCategory::Integer) {
auto converted{Scalar<TO>::ConvertSigned(*value)};
if (converted.overflow) {
ctx.messages().Say(
"INTEGER(%d) to INTEGER(%d) conversion overflowed"_en_US,
Operand::kind, TO::kind);
}
return ScalarConstantToExpr(std::move(converted.value));
} else if constexpr (FromCat == TypeCategory::Real) {
auto converted{value->template ToInteger<Scalar<TO>>()};
if (converted.flags.test(RealFlag::InvalidArgument)) {
ctx.messages().Say(
"REAL(%d) to INTEGER(%d) conversion: invalid argument"_en_US,
Operand::kind, TO::kind);
} else if (converted.flags.test(RealFlag::Overflow)) {
ctx.messages().Say(
"REAL(%d) to INTEGER(%d) conversion overflowed"_en_US,
Operand::kind, TO::kind);
}
return ScalarConstantToExpr(std::move(converted.value));
}
} else if constexpr (TO::category == TypeCategory::Real) {
if constexpr (FromCat == TypeCategory::Integer) {
auto converted{Scalar<TO>::FromInteger(*value)};
if (!converted.flags.empty()) {
std::snprintf(buffer, sizeof buffer,
"INTEGER(%d) to REAL(%d) conversion", Operand::kind,
TO::kind);
RealFlagWarnings(ctx, converted.flags, buffer);
}
return ScalarConstantToExpr(std::move(converted.value));
} else if constexpr (FromCat == TypeCategory::Real) {
auto converted{Scalar<TO>::Convert(*value)};
if (!converted.flags.empty()) {
std::snprintf(buffer, sizeof buffer,
"REAL(%d) to REAL(%d) conversion", Operand::kind, TO::kind);
RealFlagWarnings(ctx, converted.flags, buffer);
}
if (ctx.flushSubnormalsToZero()) {
converted.value = converted.value.FlushSubnormalToZero();
}
return ScalarConstantToExpr(std::move(converted.value));
}
} else if constexpr (TO::category == TypeCategory::Complex) {
if constexpr (FromCat == TypeCategory::Complex) {
return FoldOperation(ctx,
ComplexConstructor<TO::kind>{
AsExpr(Convert<typename TO::Part>{AsCategoryExpr(
Constant<typename Operand::Part>{value->REAL()})}),
AsExpr(Convert<typename TO::Part>{AsCategoryExpr(
Constant<typename Operand::Part>{value->AIMAG()})})});
}
} else if constexpr (TO::category == TypeCategory::Character &&
FromCat == TypeCategory::Character) {
if (auto converted{ConvertString<Scalar<TO>>(std::move(*value))}) {
return ScalarConstantToExpr(std::move(*converted));
}
} else if constexpr (TO::category == TypeCategory::Logical &&
FromCat == TypeCategory::Logical) {
return Expr<TO>{value->IsTrue()};
}
} else if constexpr (TO::category == FromCat &&
FromCat != TypeCategory::Character) {
// Conversion of non-constant in same type category
if constexpr (std::is_same_v<Operand, TO>) {
return std::move(kindExpr); // remove needless conversion
[flang] Fix spurious errors from runtime derived type table construction Andrezj W. @ Arm discovered that the runtime derived type table building code in semantics was detecting fatal errors in the tests that the f18 driver wasn't printing. This patch fixes f18 so that these messages are printed; however, the messages were not valid user errors, and the rest of this patch fixes them up. There were two sources of the bogus errors. One was that the runtime derived type information table builder was calculating the shapes of allocatable and pointer array components in derived types, and then complaining that they weren't constant or LEN parameter values, which of course they couldn't be since they have to have deferred shapes and those bounds were expressions like LBOUND(component,dim=1). The second was that f18 was forwarding the actual LEN type parameter expressions of a type instantiation too far into the uses of those parameters in various expressions in the declarations of components; when an actual LEN type parameter is not a constant value, it needs to remain a "bare" type parameter inquiry so that it will be lowered to a descriptor inquiry and acquire a captured expression value. Fixing this up properly involved: moving some code into new utility function templates in Evaluate/tools.h, tweaking the rewriting of conversions in expression folding to elide needless integer kind conversions of type parameter inquiries, making type parameter inquiry folding *not* replace bare LEN type parameters with non-constant actual parameter values, and cleaning up some altered test results. Differential Revision: https://reviews.llvm.org/D101001
2021-04-22 06:12:07 +08:00
} else if constexpr (TO::category == TypeCategory::Logical ||
TO::category == TypeCategory::Integer) {
if (auto *innerConv{
[flang] Fix spurious errors from runtime derived type table construction Andrezj W. @ Arm discovered that the runtime derived type table building code in semantics was detecting fatal errors in the tests that the f18 driver wasn't printing. This patch fixes f18 so that these messages are printed; however, the messages were not valid user errors, and the rest of this patch fixes them up. There were two sources of the bogus errors. One was that the runtime derived type information table builder was calculating the shapes of allocatable and pointer array components in derived types, and then complaining that they weren't constant or LEN parameter values, which of course they couldn't be since they have to have deferred shapes and those bounds were expressions like LBOUND(component,dim=1). The second was that f18 was forwarding the actual LEN type parameter expressions of a type instantiation too far into the uses of those parameters in various expressions in the declarations of components; when an actual LEN type parameter is not a constant value, it needs to remain a "bare" type parameter inquiry so that it will be lowered to a descriptor inquiry and acquire a captured expression value. Fixing this up properly involved: moving some code into new utility function templates in Evaluate/tools.h, tweaking the rewriting of conversions in expression folding to elide needless integer kind conversions of type parameter inquiries, making type parameter inquiry folding *not* replace bare LEN type parameters with non-constant actual parameter values, and cleaning up some altered test results. Differential Revision: https://reviews.llvm.org/D101001
2021-04-22 06:12:07 +08:00
std::get_if<Convert<Operand, TO::category>>(&kindExpr.u)}) {
// Conversion of conversion of same category & kind
if (auto *x{std::get_if<Expr<TO>>(&innerConv->left().u)}) {
[flang] Fix spurious errors from runtime derived type table construction Andrezj W. @ Arm discovered that the runtime derived type table building code in semantics was detecting fatal errors in the tests that the f18 driver wasn't printing. This patch fixes f18 so that these messages are printed; however, the messages were not valid user errors, and the rest of this patch fixes them up. There were two sources of the bogus errors. One was that the runtime derived type information table builder was calculating the shapes of allocatable and pointer array components in derived types, and then complaining that they weren't constant or LEN parameter values, which of course they couldn't be since they have to have deferred shapes and those bounds were expressions like LBOUND(component,dim=1). The second was that f18 was forwarding the actual LEN type parameter expressions of a type instantiation too far into the uses of those parameters in various expressions in the declarations of components; when an actual LEN type parameter is not a constant value, it needs to remain a "bare" type parameter inquiry so that it will be lowered to a descriptor inquiry and acquire a captured expression value. Fixing this up properly involved: moving some code into new utility function templates in Evaluate/tools.h, tweaking the rewriting of conversions in expression folding to elide needless integer kind conversions of type parameter inquiries, making type parameter inquiry folding *not* replace bare LEN type parameters with non-constant actual parameter values, and cleaning up some altered test results. Differential Revision: https://reviews.llvm.org/D101001
2021-04-22 06:12:07 +08:00
if constexpr (TO::category == TypeCategory::Logical ||
TO::kind <= Operand::kind) {
return std::move(*x); // no-op Logical or Integer
// widening/narrowing conversion pair
} else if constexpr (std::is_same_v<TO,
DescriptorInquiry::Result>) {
if (std::holds_alternative<DescriptorInquiry>(x->u) ||
std::holds_alternative<TypeParamInquiry>(x->u)) {
// int(int(size(...),kind=k),kind=8) -> size(...)
return std::move(*x);
}
}
}
}
}
}
return Expr<TO>{std::move(convert)};
},
convert.left().u);
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Parentheses<T> &&x) {
auto &operand{x.left()};
operand = Fold(context, std::move(operand));
if (auto value{GetScalarConstantValue<T>(operand)}) {
// Preserve parentheses, even around constants.
return Expr<T>{Parentheses<T>{Expr<T>{Constant<T>{*value}}}};
} else if (std::holds_alternative<Parentheses<T>>(operand.u)) {
// ((x)) -> (x)
return std::move(operand);
} else {
return Expr<T>{Parentheses<T>{std::move(operand)}};
}
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Negate<T> &&x) {
if (auto array{ApplyElementwise(context, x)}) {
return *array;
}
auto &operand{x.left()};
if (auto *nn{std::get_if<Negate<T>>(&x.left().u)}) {
return std::move(nn->left()); // -(-x) -> x
} else if (auto value{GetScalarConstantValue<T>(operand)}) {
if constexpr (T::category == TypeCategory::Integer) {
auto negated{value->Negate()};
if (negated.overflow) {
context.messages().Say(
"INTEGER(%d) negation overflowed"_en_US, T::kind);
}
return Expr<T>{Constant<T>{std::move(negated.value)}};
} else {
// REAL & COMPLEX negation: no exceptions possible
return Expr<T>{Constant<T>{value->Negate()}};
}
}
return Expr<T>{std::move(x)};
}
// Binary (dyadic) operations
template <typename LEFT, typename RIGHT>
std::optional<std::pair<Scalar<LEFT>, Scalar<RIGHT>>> OperandsAreConstants(
const Expr<LEFT> &x, const Expr<RIGHT> &y) {
if (auto xvalue{GetScalarConstantValue<LEFT>(x)}) {
if (auto yvalue{GetScalarConstantValue<RIGHT>(y)}) {
return {std::make_pair(*xvalue, *yvalue)};
}
}
return std::nullopt;
}
template <typename DERIVED, typename RESULT, typename LEFT, typename RIGHT>
std::optional<std::pair<Scalar<LEFT>, Scalar<RIGHT>>> OperandsAreConstants(
const Operation<DERIVED, RESULT, LEFT, RIGHT> &operation) {
return OperandsAreConstants(operation.left(), operation.right());
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Add<T> &&x) {
if (auto array{ApplyElementwise(context, x)}) {
return *array;
}
if (auto folded{OperandsAreConstants(x)}) {
if constexpr (T::category == TypeCategory::Integer) {
auto sum{folded->first.AddSigned(folded->second)};
if (sum.overflow) {
context.messages().Say(
"INTEGER(%d) addition overflowed"_en_US, T::kind);
}
return Expr<T>{Constant<T>{sum.value}};
} else {
auto sum{folded->first.Add(folded->second, context.rounding())};
RealFlagWarnings(context, sum.flags, "addition");
if (context.flushSubnormalsToZero()) {
sum.value = sum.value.FlushSubnormalToZero();
}
return Expr<T>{Constant<T>{sum.value}};
}
}
return Expr<T>{std::move(x)};
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Subtract<T> &&x) {
if (auto array{ApplyElementwise(context, x)}) {
return *array;
}
if (auto folded{OperandsAreConstants(x)}) {
if constexpr (T::category == TypeCategory::Integer) {
auto difference{folded->first.SubtractSigned(folded->second)};
if (difference.overflow) {
context.messages().Say(
"INTEGER(%d) subtraction overflowed"_en_US, T::kind);
}
return Expr<T>{Constant<T>{difference.value}};
} else {
auto difference{
folded->first.Subtract(folded->second, context.rounding())};
RealFlagWarnings(context, difference.flags, "subtraction");
if (context.flushSubnormalsToZero()) {
difference.value = difference.value.FlushSubnormalToZero();
}
return Expr<T>{Constant<T>{difference.value}};
}
}
return Expr<T>{std::move(x)};
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Multiply<T> &&x) {
if (auto array{ApplyElementwise(context, x)}) {
return *array;
}
if (auto folded{OperandsAreConstants(x)}) {
if constexpr (T::category == TypeCategory::Integer) {
auto product{folded->first.MultiplySigned(folded->second)};
if (product.SignedMultiplicationOverflowed()) {
context.messages().Say(
"INTEGER(%d) multiplication overflowed"_en_US, T::kind);
}
return Expr<T>{Constant<T>{product.lower}};
} else {
auto product{folded->first.Multiply(folded->second, context.rounding())};
RealFlagWarnings(context, product.flags, "multiplication");
if (context.flushSubnormalsToZero()) {
product.value = product.value.FlushSubnormalToZero();
}
return Expr<T>{Constant<T>{product.value}};
}
} else if constexpr (T::category == TypeCategory::Integer) {
if (auto c{GetScalarConstantValue<T>(x.right())}) {
x.right() = std::move(x.left());
x.left() = Expr<T>{std::move(*c)};
}
if (auto c{GetScalarConstantValue<T>(x.left())}) {
if (c->IsZero()) {
return std::move(x.left());
} else if (c->CompareSigned(Scalar<T>{1}) == Ordering::Equal) {
return std::move(x.right());
} else if (c->CompareSigned(Scalar<T>{-1}) == Ordering::Equal) {
return Expr<T>{Negate<T>{std::move(x.right())}};
}
}
}
return Expr<T>{std::move(x)};
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Divide<T> &&x) {
if (auto array{ApplyElementwise(context, x)}) {
return *array;
}
if (auto folded{OperandsAreConstants(x)}) {
if constexpr (T::category == TypeCategory::Integer) {
auto quotAndRem{folded->first.DivideSigned(folded->second)};
if (quotAndRem.divisionByZero) {
context.messages().Say("INTEGER(%d) division by zero"_en_US, T::kind);
return Expr<T>{std::move(x)};
}
if (quotAndRem.overflow) {
context.messages().Say(
"INTEGER(%d) division overflowed"_en_US, T::kind);
}
return Expr<T>{Constant<T>{quotAndRem.quotient}};
} else {
auto quotient{folded->first.Divide(folded->second, context.rounding())};
RealFlagWarnings(context, quotient.flags, "division");
if (context.flushSubnormalsToZero()) {
quotient.value = quotient.value.FlushSubnormalToZero();
}
return Expr<T>{Constant<T>{quotient.value}};
}
}
return Expr<T>{std::move(x)};
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Power<T> &&x) {
if (auto array{ApplyElementwise(context, x)}) {
return *array;
}
if (auto folded{OperandsAreConstants(x)}) {
if constexpr (T::category == TypeCategory::Integer) {
auto power{folded->first.Power(folded->second)};
if (power.divisionByZero) {
context.messages().Say(
"INTEGER(%d) zero to negative power"_en_US, T::kind);
} else if (power.overflow) {
context.messages().Say("INTEGER(%d) power overflowed"_en_US, T::kind);
} else if (power.zeroToZero) {
context.messages().Say(
"INTEGER(%d) 0**0 is not defined"_en_US, T::kind);
}
return Expr<T>{Constant<T>{power.power}};
} else {
if (auto callable{GetHostRuntimeWrapper<T, T, T>("pow")}) {
return Expr<T>{
Constant<T>{(*callable)(context, folded->first, folded->second)}};
} else {
context.messages().Say(
"Power for %s cannot be folded on host"_en_US, T{}.AsFortran());
}
}
}
return Expr<T>{std::move(x)};
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, RealToIntPower<T> &&x) {
if (auto array{ApplyElementwise(context, x)}) {
return *array;
}
return std::visit(
[&](auto &y) -> Expr<T> {
if (auto folded{OperandsAreConstants(x.left(), y)}) {
auto power{evaluate::IntPower(folded->first, folded->second)};
RealFlagWarnings(context, power.flags, "power with INTEGER exponent");
if (context.flushSubnormalsToZero()) {
power.value = power.value.FlushSubnormalToZero();
}
return Expr<T>{Constant<T>{power.value}};
} else {
return Expr<T>{std::move(x)};
}
},
x.right().u);
}
template <typename T>
Expr<T> FoldOperation(FoldingContext &context, Extremum<T> &&x) {
if (auto array{ApplyElementwise(context, x,
std::function<Expr<T>(Expr<T> &&, Expr<T> &&)>{[=](Expr<T> &&l,
Expr<T> &&r) {
return Expr<T>{Extremum<T>{x.ordering, std::move(l), std::move(r)}};
}})}) {
return *array;
}
if (auto folded{OperandsAreConstants(x)}) {
if constexpr (T::category == TypeCategory::Integer) {
if (folded->first.CompareSigned(folded->second) == x.ordering) {
return Expr<T>{Constant<T>{folded->first}};
}
} else if constexpr (T::category == TypeCategory::Real) {
if (folded->first.IsNotANumber() ||
(folded->first.Compare(folded->second) == Relation::Less) ==
(x.ordering == Ordering::Less)) {
return Expr<T>{Constant<T>{folded->first}};
}
} else {
static_assert(T::category == TypeCategory::Character);
// Result of MIN and MAX on character has the length of
// the longest argument.
auto maxLen{std::max(folded->first.length(), folded->second.length())};
bool isFirst{x.ordering == Compare(folded->first, folded->second)};
auto res{isFirst ? std::move(folded->first) : std::move(folded->second)};
res = res.length() == maxLen
? std::move(res)
: CharacterUtils<T::kind>::Resize(res, maxLen);
return Expr<T>{Constant<T>{std::move(res)}};
}
return Expr<T>{Constant<T>{folded->second}};
}
return Expr<T>{std::move(x)};
}
template <int KIND>
Expr<Type<TypeCategory::Real, KIND>> ToReal(
FoldingContext &context, Expr<SomeType> &&expr) {
using Result = Type<TypeCategory::Real, KIND>;
std::optional<Expr<Result>> result;
std::visit(
[&](auto &&x) {
using From = std::decay_t<decltype(x)>;
if constexpr (std::is_same_v<From, BOZLiteralConstant>) {
// Move the bits without any integer->real conversion
From original{x};
result = ConvertToType<Result>(std::move(x));
const auto *constant{UnwrapExpr<Constant<Result>>(*result)};
CHECK(constant);
Scalar<Result> real{constant->GetScalarValue().value()};
From converted{From::ConvertUnsigned(real.RawBits()).value};
if (original != converted) { // C1601
context.messages().Say(
"Nonzero bits truncated from BOZ literal constant in REAL intrinsic"_en_US);
}
} else if constexpr (IsNumericCategoryExpr<From>()) {
result = Fold(context, ConvertToType<Result>(std::move(x)));
} else {
common::die("ToReal: bad argument expression");
}
},
std::move(expr.u));
return result.value();
}
template <typename T>
Expr<T> ExpressionBase<T>::Rewrite(FoldingContext &context, Expr<T> &&expr) {
return std::visit(
[&](auto &&x) -> Expr<T> {
if constexpr (IsSpecificIntrinsicType<T>) {
return FoldOperation(context, std::move(x));
} else if constexpr (std::is_same_v<T, SomeDerived>) {
return FoldOperation(context, std::move(x));
} else if constexpr (common::HasMember<decltype(x),
TypelessExpression>) {
return std::move(expr);
} else {
return Expr<T>{Fold(context, std::move(x))};
}
},
std::move(expr.u));
}
FOR_EACH_TYPE_AND_KIND(extern template class ExpressionBase, )
} // namespace Fortran::evaluate
#endif // FORTRAN_EVALUATE_FOLD_IMPLEMENTATION_H_