//===-- lib/Semantics/resolve-names-utils.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 "resolve-names-utils.h"
#include "flang/Common/Fortran-features.h"
#include "flang/Common/Fortran.h"
#include "flang/Common/idioms.h"
#include "flang/Common/indirection.h"
#include "flang/Evaluate/fold.h"
#include "flang/Evaluate/tools.h"
#include "flang/Evaluate/traverse.h"
#include "flang/Evaluate/type.h"
#include "flang/Parser/char-block.h"
#include "flang/Parser/parse-tree.h"
#include "flang/Semantics/expression.h"
#include "flang/Semantics/semantics.h"
#include "flang/Semantics/tools.h"
#include <initializer_list>
#include <variant>
namespace Fortran::semantics {
using common::LanguageFeature;
using common::LogicalOperator;
using common::NumericOperator;
using common::RelationalOperator;
using IntrinsicOperator = parser::DefinedOperator::IntrinsicOperator;
static constexpr const char *operatorPrefix{"operator("};
static GenericKind MapIntrinsicOperator(IntrinsicOperator);
Symbol *Resolve(const parser::Name &name, Symbol *symbol) {
if (symbol && !name.symbol) {
name.symbol = symbol;
}
return symbol;
}
Symbol &Resolve(const parser::Name &name, Symbol &symbol) {
return *Resolve(name, &symbol);
}
parser::MessageFixedText WithSeverity(
const parser::MessageFixedText &msg, parser::Severity severity) {
return parser::MessageFixedText{
msg.text().begin(), msg.text().size(), severity};
}
bool IsIntrinsicOperator(
const SemanticsContext &context, const SourceName &name) {
std::string str{name.ToString()};
for (int i{0}; i != common::LogicalOperator_enumSize; ++i) {
auto names{context.languageFeatures().GetNames(LogicalOperator{i})};
if (llvm::is_contained(names, str)) {
return true;
}
}
for (int i{0}; i != common::RelationalOperator_enumSize; ++i) {
auto names{context.languageFeatures().GetNames(RelationalOperator{i})};
if (llvm::is_contained(names, str)) {
return true;
}
}
return false;
}
template <typename E>
std::forward_list<std::string> GetOperatorNames(
const SemanticsContext &context, E opr) {
std::forward_list<std::string> result;
for (const char *name : context.languageFeatures().GetNames(opr)) {
result.emplace_front(std::string{operatorPrefix} + name + ')');
}
return result;
}
std::forward_list<std::string> GetAllNames(
const SemanticsContext &context, const SourceName &name) {
std::string str{name.ToString()};
if (!name.empty() && name.end()[-1] == ')' &&
name.ToString().rfind(std::string{operatorPrefix}, 0) == 0) {
for (int i{0}; i != common::LogicalOperator_enumSize; ++i) {
auto names{GetOperatorNames(context, LogicalOperator{i})};
if (llvm::is_contained(names, str)) {
return names;
}
}
for (int i{0}; i != common::RelationalOperator_enumSize; ++i) {
auto names{GetOperatorNames(context, RelationalOperator{i})};
if (llvm::is_contained(names, str)) {
return names;
}
}
}
return {str};
}
bool IsLogicalConstant(
const SemanticsContext &context, const SourceName &name) {
std::string str{name.ToString()};
return str == ".true." || str == ".false." ||
(context.IsEnabled(LanguageFeature::LogicalAbbreviations) &&
(str == ".t" || str == ".f."));
}
void GenericSpecInfo::Resolve(Symbol *symbol) const {
if (symbol) {
if (auto *details{symbol->detailsIf<GenericDetails>()}) {
details->set_kind(kind_);
}
if (parseName_) {
semantics::Resolve(*parseName_, symbol);
}
}
}
void GenericSpecInfo::Analyze(const parser::DefinedOpName &name) {
kind_ = GenericKind::OtherKind::DefinedOp;
parseName_ = &name.v;
symbolName_ = name.v.source;
}
void GenericSpecInfo::Analyze(const parser::GenericSpec &x) {
symbolName_ = x.source;
kind_ = common::visit(
common::visitors{
[&](const parser::Name &y) -> GenericKind {
parseName_ = &y;
symbolName_ = y.source;
return GenericKind::OtherKind::Name;
},
[&](const parser::DefinedOperator &y) {
return common::visit(
common::visitors{
[&](const parser::DefinedOpName &z) -> GenericKind {
Analyze(z);
return GenericKind::OtherKind::DefinedOp;
},
[&](const IntrinsicOperator &z) {
return MapIntrinsicOperator(z);
},
},
y.u);
},
[&](const parser::GenericSpec::Assignment &) -> GenericKind {
return GenericKind::OtherKind::Assignment;
},
[&](const parser::GenericSpec::ReadFormatted &) -> GenericKind {
return common::DefinedIo::ReadFormatted;
},
[&](const parser::GenericSpec::ReadUnformatted &) -> GenericKind {
return common::DefinedIo::ReadUnformatted;
},
[&](const parser::GenericSpec::WriteFormatted &) -> GenericKind {
return common::DefinedIo::WriteFormatted;
},
[&](const parser::GenericSpec::WriteUnformatted &) -> GenericKind {
return common::DefinedIo::WriteUnformatted;
},
},
x.u);
}
llvm::raw_ostream &operator<<(
llvm::raw_ostream &os, const GenericSpecInfo &info) {
os << "GenericSpecInfo: kind=" << info.kind_.ToString();
os << " parseName="
<< (info.parseName_ ? info.parseName_->ToString() : "null");
os << " symbolName="
<< (info.symbolName_ ? info.symbolName_->ToString() : "null");
return os;
}
// parser::DefinedOperator::IntrinsicOperator -> GenericKind
static GenericKind MapIntrinsicOperator(IntrinsicOperator op) {
switch (op) {
SWITCH_COVERS_ALL_CASES
case IntrinsicOperator::Concat:
return GenericKind::OtherKind::Concat;
case IntrinsicOperator::Power:
return NumericOperator::Power;
case IntrinsicOperator::Multiply:
return NumericOperator::Multiply;
case IntrinsicOperator::Divide:
return NumericOperator::Divide;
case IntrinsicOperator::Add:
return NumericOperator::Add;
case IntrinsicOperator::Subtract:
return NumericOperator::Subtract;
case IntrinsicOperator::AND:
return LogicalOperator::And;
case IntrinsicOperator::OR:
return LogicalOperator::Or;
case IntrinsicOperator::EQV:
return LogicalOperator::Eqv;
case IntrinsicOperator::NEQV:
return LogicalOperator::Neqv;
case IntrinsicOperator::NOT:
return LogicalOperator::Not;
case IntrinsicOperator::LT:
return RelationalOperator::LT;
case IntrinsicOperator::LE:
return RelationalOperator::LE;
case IntrinsicOperator::EQ:
return RelationalOperator::EQ;
case IntrinsicOperator::NE:
return RelationalOperator::NE;
case IntrinsicOperator::GE:
return RelationalOperator::GE;
case IntrinsicOperator::GT:
return RelationalOperator::GT;
}
}
class ArraySpecAnalyzer {
public:
ArraySpecAnalyzer(SemanticsContext &context) : context_{context} {}
ArraySpec Analyze(const parser::ArraySpec &);
ArraySpec AnalyzeDeferredShapeSpecList(const parser::DeferredShapeSpecList &);
ArraySpec Analyze(const parser::ComponentArraySpec &);
ArraySpec Analyze(const parser::CoarraySpec &);
private:
SemanticsContext &context_;
ArraySpec arraySpec_;
template <typename T> void Analyze(const std::list<T> &list) {
for (const auto &elem : list) {
Analyze(elem);
}
}
void Analyze(const parser::AssumedShapeSpec &);
void Analyze(const parser::ExplicitShapeSpec &);
void Analyze(const parser::AssumedImpliedSpec &);
void Analyze(const parser::DeferredShapeSpecList &);
void Analyze(const parser::AssumedRankSpec &);
void MakeExplicit(const std::optional<parser::SpecificationExpr> &,
const parser::SpecificationExpr &);
void MakeImplied(const std::optional<parser::SpecificationExpr> &);
void MakeDeferred(int);
Bound GetBound(const std::optional<parser::SpecificationExpr> &);
Bound GetBound(const parser::SpecificationExpr &);
};
ArraySpec AnalyzeArraySpec(
SemanticsContext &context, const parser::ArraySpec &arraySpec) {
return ArraySpecAnalyzer{context}.Analyze(arraySpec);
}
ArraySpec AnalyzeArraySpec(
SemanticsContext &context, const parser::ComponentArraySpec &arraySpec) {
return ArraySpecAnalyzer{context}.Analyze(arraySpec);
}
ArraySpec AnalyzeDeferredShapeSpecList(SemanticsContext &context,
const parser::DeferredShapeSpecList &deferredShapeSpecs) {
return ArraySpecAnalyzer{context}.AnalyzeDeferredShapeSpecList(
deferredShapeSpecs);
}
ArraySpec AnalyzeCoarraySpec(
SemanticsContext &context, const parser::CoarraySpec &coarraySpec) {
return ArraySpecAnalyzer{context}.Analyze(coarraySpec);
}
ArraySpec ArraySpecAnalyzer::Analyze(const parser::ComponentArraySpec &x) {
common::visit([this](const auto &y) { Analyze(y); }, x.u);
CHECK(!arraySpec_.empty());
return arraySpec_;
}
ArraySpec ArraySpecAnalyzer::Analyze(const parser::ArraySpec &x) {
common::visit(common::visitors{
[&](const parser::AssumedSizeSpec &y) {
Analyze(
std::get<std::list<parser::ExplicitShapeSpec>>(y.t));
Analyze(std::get<parser::AssumedImpliedSpec>(y.t));
},
[&](const parser::ImpliedShapeSpec &y) { Analyze(y.v); },
[&](const auto &y) { Analyze(y); },
},
x.u);
CHECK(!arraySpec_.empty());
return arraySpec_;
}
ArraySpec ArraySpecAnalyzer::AnalyzeDeferredShapeSpecList(
const parser::DeferredShapeSpecList &x) {
Analyze(x);
CHECK(!arraySpec_.empty());
return arraySpec_;
}
ArraySpec ArraySpecAnalyzer::Analyze(const parser::CoarraySpec &x) {
common::visit(
common::visitors{
[&](const parser::DeferredCoshapeSpecList &y) { MakeDeferred(y.v); },
[&](const parser::ExplicitCoshapeSpec &y) {
Analyze(std::get<std::list<parser::ExplicitShapeSpec>>(y.t));
MakeImplied(
std::get<std::optional<parser::SpecificationExpr>>(y.t));
},
},
x.u);
CHECK(!arraySpec_.empty());
return arraySpec_;
}
void ArraySpecAnalyzer::Analyze(const parser::AssumedShapeSpec &x) {
arraySpec_.push_back(ShapeSpec::MakeAssumedShape(GetBound(x.v)));
}
void ArraySpecAnalyzer::Analyze(const parser::ExplicitShapeSpec &x) {
MakeExplicit(std::get<std::optional<parser::SpecificationExpr>>(x.t),
std::get<parser::SpecificationExpr>(x.t));
}
void ArraySpecAnalyzer::Analyze(const parser::AssumedImpliedSpec &x) {
MakeImplied(x.v);
}
void ArraySpecAnalyzer::Analyze(const parser::DeferredShapeSpecList &x) {
MakeDeferred(x.v);
}
void ArraySpecAnalyzer::Analyze(const parser::AssumedRankSpec &) {
arraySpec_.push_back(ShapeSpec::MakeAssumedRank());
}
void ArraySpecAnalyzer::MakeExplicit(
const std::optional<parser::SpecificationExpr> &lb,
const parser::SpecificationExpr &ub) {
arraySpec_.push_back(ShapeSpec::MakeExplicit(GetBound(lb), GetBound(ub)));
}
void ArraySpecAnalyzer::MakeImplied(
const std::optional<parser::SpecificationExpr> &lb) {
arraySpec_.push_back(ShapeSpec::MakeImplied(GetBound(lb)));
}
void ArraySpecAnalyzer::MakeDeferred(int n) {
for (int i = 0; i < n; ++i) {
arraySpec_.push_back(ShapeSpec::MakeDeferred());
}
}
Bound ArraySpecAnalyzer::GetBound(
const std::optional<parser::SpecificationExpr> &x) {
return x ? GetBound(*x) : Bound{1};
}
Bound ArraySpecAnalyzer::GetBound(const parser::SpecificationExpr &x) {
MaybeSubscriptIntExpr expr;
if (MaybeExpr maybeExpr{AnalyzeExpr(context_, x.v)}) {
if (auto *intExpr{evaluate::UnwrapExpr<SomeIntExpr>(*maybeExpr)}) {
expr = evaluate::Fold(context_.foldingContext(),
evaluate::ConvertToType<evaluate::SubscriptInteger>(
std::move(*intExpr)));
}
}
return Bound{std::move(expr)};
}
// If src is SAVE (explicitly or implicitly),
// set SAVE attribute on all members of dst.
static void PropagateSaveAttr(
const EquivalenceObject &src, EquivalenceSet &dst) {
if (IsSaved(src.symbol)) {
for (auto &obj : dst) {
if (!obj.symbol.attrs().test(Attr::SAVE)) {
obj.symbol.attrs().set(Attr::SAVE);
// If the other equivalenced symbol itself is not SAVE,
// then adding SAVE here implies that it has to be implicit.
obj.symbol.implicitAttrs().set(Attr::SAVE);
}
}
}
}
static void PropagateSaveAttr(const EquivalenceSet &src, EquivalenceSet &dst) {
if (!src.empty()) {
PropagateSaveAttr(src.front(), dst);
}
}
void EquivalenceSets::AddToSet(const parser::Designator &designator) {
if (CheckDesignator(designator)) {
if (Symbol * symbol{currObject_.symbol}) {
if (!currSet_.empty()) {
// check this symbol against first of set for compatibility
Symbol &first{currSet_.front().symbol};
CheckCanEquivalence(designator.source, first, *symbol) &&
CheckCanEquivalence(designator.source, *symbol, first);
}
auto subscripts{currObject_.subscripts};
if (subscripts.empty()) {
if (const ArraySpec * shape{symbol->GetShape()};
shape && shape->IsExplicitShape()) {
// record a whole array as its first element
for (const ShapeSpec &spec : *shape) {
if (auto lbound{spec.lbound().GetExplicit()}) {
if (auto lbValue{evaluate::ToInt64(*lbound)}) {
subscripts.push_back(*lbValue);
continue;
}
}
subscripts.clear(); // error recovery
break;
}
}
}
auto substringStart{currObject_.substringStart};
currSet_.emplace_back(
*symbol, subscripts, substringStart, designator.source);
PropagateSaveAttr(currSet_.back(), currSet_);
}
}
currObject_ = {};
}
void EquivalenceSets::FinishSet(const parser::CharBlock &source) {
std::set<std::size_t> existing; // indices of sets intersecting this one
for (auto &obj : currSet_) {
auto it{objectToSet_.find(obj)};
if (it != objectToSet_.end()) {
existing.insert(it->second); // symbol already in this set
}
}
if (existing.empty()) {
sets_.push_back({}); // create a new equivalence set
MergeInto(source, currSet_, sets_.size() - 1);
} else {
auto it{existing.begin()};
std::size_t dstIndex{*it};
MergeInto(source, currSet_, dstIndex);
while (++it != existing.end()) {
MergeInto(source, sets_[*it], dstIndex);
}
}
currSet_.clear();
}
// Report an error or warning if sym1 and sym2 cannot be in the same equivalence
// set.
bool EquivalenceSets::CheckCanEquivalence(
const parser::CharBlock &source, const Symbol &sym1, const Symbol &sym2) {
std::optional<parser::MessageFixedText> msg;
const DeclTypeSpec *type1{sym1.GetType()};
const DeclTypeSpec *type2{sym2.GetType()};
bool isDefaultNum1{IsDefaultNumericSequenceType(type1)};
bool isAnyNum1{IsAnyNumericSequenceType(type1)};
bool isDefaultNum2{IsDefaultNumericSequenceType(type2)};
bool isAnyNum2{IsAnyNumericSequenceType(type2)};
bool isChar1{IsCharacterSequenceType(type1)};
bool isChar2{IsCharacterSequenceType(type2)};
if (sym1.attrs().test(Attr::PROTECTED) &&
!sym2.attrs().test(Attr::PROTECTED)) { // C8114
msg = "Equivalence set cannot contain '%s'"
" with PROTECTED attribute and '%s' without"_err_en_US;
} else if ((isDefaultNum1 && isDefaultNum2) || (isChar1 && isChar2)) {
// ok & standard conforming
} else if (!(isAnyNum1 || isChar1) &&
!(isAnyNum2 || isChar2)) { // C8110 - C8113
if (AreTkCompatibleTypes(type1, type2)) {
if (context_.ShouldWarn(LanguageFeature::EquivalenceSameNonSequence)) {
msg =
"nonstandard: Equivalence set contains '%s' and '%s' with same "
"type that is neither numeric nor character sequence type"_port_en_US;
}
} else {
msg = "Equivalence set cannot contain '%s' and '%s' with distinct types "
"that are not both numeric or character sequence types"_err_en_US;
}
} else if (isAnyNum1) {
if (isChar2) {
if (context_.ShouldWarn(
LanguageFeature::EquivalenceNumericWithCharacter)) {
msg = "nonstandard: Equivalence set contains '%s' that is numeric "
"sequence type and '%s' that is character"_port_en_US;
}
} else if (isAnyNum2 &&
context_.ShouldWarn(LanguageFeature::EquivalenceNonDefaultNumeric)) {
if (isDefaultNum1) {
msg =
"nonstandard: Equivalence set contains '%s' that is a default "
"numeric sequence type and '%s' that is numeric with non-default kind"_port_en_US;
} else if (!isDefaultNum2) {
msg = "nonstandard: Equivalence set contains '%s' and '%s' that are "
"numeric sequence types with non-default kinds"_port_en_US;
}
}
}
if (msg &&
(!context_.IsInModuleFile(source) ||
msg->severity() == parser::Severity::Error)) {
context_.Say(source, std::move(*msg), sym1.name(), sym2.name());
return false;
}
return true;
}
// Move objects from src to sets_[dstIndex]
void EquivalenceSets::MergeInto(const parser::CharBlock &source,
EquivalenceSet &src, std::size_t dstIndex) {
EquivalenceSet &dst{sets_[dstIndex]};
PropagateSaveAttr(dst, src);
for (const auto &obj : src) {
dst.push_back(obj);
objectToSet_[obj] = dstIndex;
}
PropagateSaveAttr(src, dst);
src.clear();
}
// If set has an object with this symbol, return it.
const EquivalenceObject *EquivalenceSets::Find(
const EquivalenceSet &set, const Symbol &symbol) {
for (const auto &obj : set) {
if (obj.symbol == symbol) {
return &obj;
}
}
return nullptr;
}
bool EquivalenceSets::CheckDesignator(const parser::Designator &designator) {
return common::visit(
common::visitors{
[&](const parser::DataRef &x) {
return CheckDataRef(designator.source, x);
},
[&](const parser::Substring &x) {
const auto &dataRef{std::get<parser::DataRef>(x.t)};
const auto &range{std::get<parser::SubstringRange>(x.t)};
bool ok{CheckDataRef(designator.source, dataRef)};
if (const auto &lb{std::get<0>(range.t)}) {
ok &= CheckSubstringBound(lb->thing.thing.value(), true);
} else {
currObject_.substringStart = 1;
}
if (const auto &ub{std::get<1>(range.t)}) {
ok &= CheckSubstringBound(ub->thing.thing.value(), false);
}
return ok;
},
},
designator.u);
}
bool EquivalenceSets::CheckDataRef(
const parser::CharBlock &source, const parser::DataRef &x) {
return common::visit(
common::visitors{
[&](const parser::Name &name) { return CheckObject(name); },
[&](const common::Indirection<parser::StructureComponent> &) {
context_.Say(source, // C8107
"Derived type component '%s' is not allowed in an equivalence set"_err_en_US,
source);
return false;
},
[&](const common::Indirection<parser::ArrayElement> &elem) {
bool ok{CheckDataRef(source, elem.value().base)};
for (const auto &subscript : elem.value().subscripts) {
ok &= common::visit(
common::visitors{
[&](const parser::SubscriptTriplet &) {
context_.Say(source, // C924, R872
"Array section '%s' is not allowed in an equivalence set"_err_en_US,
source);
return false;
},
[&](const parser::IntExpr &y) {
return CheckArrayBound(y.thing.value());
},
},
subscript.u);
}
return ok;
},
[&](const common::Indirection<parser::CoindexedNamedObject> &) {
context_.Say(source, // C924 (R872)
"Coindexed object '%s' is not allowed in an equivalence set"_err_en_US,
source);
return false;
},
},
x.u);
}
bool EquivalenceSets::CheckObject(const parser::Name &name) {
currObject_.symbol = name.symbol;
return currObject_.symbol != nullptr;
}
bool EquivalenceSets::CheckArrayBound(const parser::Expr &bound) {
MaybeExpr expr{
evaluate::Fold(context_.foldingContext(), AnalyzeExpr(context_, bound))};
if (!expr) {
return false;
}
if (expr->Rank() > 0) {
context_.Say(bound.source, // C924, R872
"Array with vector subscript '%s' is not allowed in an equivalence set"_err_en_US,
bound.source);
return false;
}
auto subscript{evaluate::ToInt64(*expr)};
if (!subscript) {
context_.Say(bound.source, // C8109
"Array with nonconstant subscript '%s' is not allowed in an equivalence set"_err_en_US,
bound.source);
return false;
}
currObject_.subscripts.push_back(*subscript);
return true;
}
bool EquivalenceSets::CheckSubstringBound(
const parser::Expr &bound, bool isStart) {
MaybeExpr expr{
evaluate::Fold(context_.foldingContext(), AnalyzeExpr(context_, bound))};
if (!expr) {
return false;
}
auto subscript{evaluate::ToInt64(*expr)};
if (!subscript) {
context_.Say(bound.source, // C8109
"Substring with nonconstant bound '%s' is not allowed in an equivalence set"_err_en_US,
bound.source);
return false;
}
if (!isStart) {
auto start{currObject_.substringStart};
if (*subscript < (start ? *start : 1)) {
context_.Say(bound.source, // C8116
"Substring with zero length is not allowed in an equivalence set"_err_en_US);
return false;
}
} else if (*subscript != 1) {
currObject_.substringStart = *subscript;
}
return true;
}
bool EquivalenceSets::IsCharacterSequenceType(const DeclTypeSpec *type) {
return IsSequenceType(type, [&](const IntrinsicTypeSpec &type) {
auto kind{evaluate::ToInt64(type.kind())};
return type.category() == TypeCategory::Character && kind &&
kind.value() == context_.GetDefaultKind(TypeCategory::Character);
});
}
// Numeric or logical type of default kind or DOUBLE PRECISION or DOUBLE COMPLEX
bool EquivalenceSets::IsDefaultKindNumericType(const IntrinsicTypeSpec &type) {
if (auto kind{evaluate::ToInt64(type.kind())}) {
switch (type.category()) {
case TypeCategory::Integer:
case TypeCategory::Logical:
return *kind == context_.GetDefaultKind(TypeCategory::Integer);
case TypeCategory::Real:
case TypeCategory::Complex:
return *kind == context_.GetDefaultKind(TypeCategory::Real) ||
*kind == context_.doublePrecisionKind();
default:
return false;
}
}
return false;
}
bool EquivalenceSets::IsDefaultNumericSequenceType(const DeclTypeSpec *type) {
return IsSequenceType(type, [&](const IntrinsicTypeSpec &type) {
return IsDefaultKindNumericType(type);
});
}
bool EquivalenceSets::IsAnyNumericSequenceType(const DeclTypeSpec *type) {
return IsSequenceType(type, [&](const IntrinsicTypeSpec &type) {
return type.category() == TypeCategory::Logical ||
common::IsNumericTypeCategory(type.category());
});
}
// Is type an intrinsic type that satisfies predicate or a sequence type
// whose components do.
bool EquivalenceSets::IsSequenceType(const DeclTypeSpec *type,
std::function<bool(const IntrinsicTypeSpec &)> predicate) {
if (!type) {
return false;
} else if (const IntrinsicTypeSpec * intrinsic{type->AsIntrinsic()}) {
return predicate(*intrinsic);
} else if (const DerivedTypeSpec * derived{type->AsDerived()}) {
for (const auto &pair : *derived->typeSymbol().scope()) {
const Symbol &component{*pair.second};
if (IsAllocatableOrPointer(component) ||
!IsSequenceType(component.GetType(), predicate)) {
return false;
}
}
return true;
} else {
return false;
}
}
// MapSubprogramToNewSymbols() relies on the following recursive symbol/scope
// copying infrastructure to duplicate an interface's symbols and map all
// of the symbol references in their contained expressions and interfaces
// to the new symbols.
struct SymbolAndTypeMappings {
std::map<const Symbol *, const Symbol *> symbolMap;
std::map<const DeclTypeSpec *, const DeclTypeSpec *> typeMap;
};
class SymbolMapper : public evaluate::AnyTraverse<SymbolMapper, bool> {
public:
using Base = evaluate::AnyTraverse<SymbolMapper, bool>;
SymbolMapper(Scope &scope, SymbolAndTypeMappings &map)
: Base{*this}, scope_{scope}, map_{map} {}
using Base::operator();
bool operator()(const SymbolRef &ref) {
if (const Symbol *mapped{MapSymbol(*ref)}) {
const_cast<SymbolRef &>(ref) = *mapped;
} else if (ref->has<UseDetails>()) {
CopySymbol(&*ref);
}
return false;
}
bool operator()(const Symbol &x) {
if (MapSymbol(x)) {
DIE("SymbolMapper hit symbol outside SymbolRef");
}
return false;
}
void MapSymbolExprs(Symbol &);
Symbol *CopySymbol(const Symbol *);
private:
void MapParamValue(ParamValue ¶m) { (*this)(param.GetExplicit()); }
void MapBound(Bound &bound) { (*this)(bound.GetExplicit()); }
void MapShapeSpec(ShapeSpec &spec) {
MapBound(spec.lbound());
MapBound(spec.ubound());
}
const Symbol *MapSymbol(const Symbol &) const;
const Symbol *MapSymbol(const Symbol *) const;
const DeclTypeSpec *MapType(const DeclTypeSpec &);
const DeclTypeSpec *MapType(const DeclTypeSpec *);
const Symbol *MapInterface(const Symbol *);
Scope &scope_;
SymbolAndTypeMappings &map_;
};
Symbol *SymbolMapper::CopySymbol(const Symbol *symbol) {
if (symbol) {
if (auto *subp{symbol->detailsIf<SubprogramDetails>()}) {
if (subp->isInterface()) {
if (auto pair{scope_.try_emplace(symbol->name(), symbol->attrs())};
pair.second) {
Symbol ©{*pair.first->second};
map_.symbolMap[symbol] = ©
copy.set(symbol->test(Symbol::Flag::Subroutine)
? Symbol::Flag::Subroutine
: Symbol::Flag::Function);
Scope &newScope{scope_.MakeScope(Scope::Kind::Subprogram, ©)};
copy.set_scope(&newScope);
copy.set_details(SubprogramDetails{});
auto &newSubp{copy.get<SubprogramDetails>()};
newSubp.set_isInterface(true);
newSubp.set_isDummy(subp->isDummy());
newSubp.set_defaultIgnoreTKR(subp->defaultIgnoreTKR());
MapSubprogramToNewSymbols(*symbol, copy, newScope, &map_);
return ©
}
}
} else if (Symbol * copy{scope_.CopySymbol(*symbol)}) {
map_.symbolMap[symbol] = copy;
return copy;
}
}
return nullptr;
}
void SymbolMapper::MapSymbolExprs(Symbol &symbol) {
common::visit(
common::visitors{[&](ObjectEntityDetails &object) {
if (const DeclTypeSpec * type{object.type()}) {
if (const DeclTypeSpec * newType{MapType(*type)}) {
object.ReplaceType(*newType);
}
}
for (ShapeSpec &spec : object.shape()) {
MapShapeSpec(spec);
}
for (ShapeSpec &spec : object.coshape()) {
MapShapeSpec(spec);
}
},
[&](ProcEntityDetails &proc) {
if (const Symbol *
mappedSymbol{MapInterface(proc.rawProcInterface())}) {
proc.set_procInterfaces(
*mappedSymbol, BypassGeneric(mappedSymbol->GetUltimate()));
} else if (const DeclTypeSpec * mappedType{MapType(proc.type())}) {
proc.set_type(*mappedType);
}
if (proc.init()) {
if (const Symbol * mapped{MapSymbol(*proc.init())}) {
proc.set_init(*mapped);
}
}
},
[&](const HostAssocDetails &hostAssoc) {
if (const Symbol * mapped{MapSymbol(hostAssoc.symbol())}) {
symbol.set_details(HostAssocDetails{*mapped});
}
},
[](const auto &) {}},
symbol.details());
}
const Symbol *SymbolMapper::MapSymbol(const Symbol &symbol) const {
if (auto iter{map_.symbolMap.find(&symbol)}; iter != map_.symbolMap.end()) {
return iter->second;
}
return nullptr;
}
const Symbol *SymbolMapper::MapSymbol(const Symbol *symbol) const {
return symbol ? MapSymbol(*symbol) : nullptr;
}
const DeclTypeSpec *SymbolMapper::MapType(const DeclTypeSpec &type) {
if (auto iter{map_.typeMap.find(&type)}; iter != map_.typeMap.end()) {
return iter->second;
}
const DeclTypeSpec *newType{nullptr};
if (type.category() == DeclTypeSpec::Category::Character) {
const CharacterTypeSpec &charType{type.characterTypeSpec()};
if (charType.length().GetExplicit()) {
ParamValue newLen{charType.length()};
(*this)(newLen.GetExplicit());
newType = &scope_.MakeCharacterType(
std::move(newLen), KindExpr{charType.kind()});
}
} else if (const DerivedTypeSpec *derived{type.AsDerived()}) {
if (!derived->parameters().empty()) {
DerivedTypeSpec newDerived{derived->name(), derived->typeSymbol()};
newDerived.CookParameters(scope_.context().foldingContext());
for (const auto &[paramName, paramValue] : derived->parameters()) {
ParamValue newParamValue{paramValue};
MapParamValue(newParamValue);
newDerived.AddParamValue(paramName, std::move(newParamValue));
}
// Scope::InstantiateDerivedTypes() instantiates it later.
newType = &scope_.MakeDerivedType(type.category(), std::move(newDerived));
}
}
if (newType) {
map_.typeMap[&type] = newType;
}
return newType;
}
const DeclTypeSpec *SymbolMapper::MapType(const DeclTypeSpec *type) {
return type ? MapType(*type) : nullptr;
}
const Symbol *SymbolMapper::MapInterface(const Symbol *interface) {
if (const Symbol *mapped{MapSymbol(interface)}) {
return mapped;
}
if (interface) {
if (&interface->owner() != &scope_) {
return interface;
} else if (const auto *subp{interface->detailsIf<SubprogramDetails>()};
subp && subp->isInterface()) {
return CopySymbol(interface);
}
}
return nullptr;
}
void MapSubprogramToNewSymbols(const Symbol &oldSymbol, Symbol &newSymbol,
Scope &newScope, SymbolAndTypeMappings *mappings) {
SymbolAndTypeMappings newMappings;
if (!mappings) {
mappings = &newMappings;
}
mappings->symbolMap[&oldSymbol] = &newSymbol;
const auto &oldDetails{oldSymbol.get<SubprogramDetails>()};
auto &newDetails{newSymbol.get<SubprogramDetails>()};
SymbolMapper mapper{newScope, *mappings};
for (const Symbol *dummyArg : oldDetails.dummyArgs()) {
if (!dummyArg) {
newDetails.add_alternateReturn();
} else if (Symbol * copy{mapper.CopySymbol(dummyArg)}) {
copy->set(Symbol::Flag::Implicit, false);
newDetails.add_dummyArg(*copy);
mappings->symbolMap[dummyArg] = copy;
}
}
if (oldDetails.isFunction()) {
newScope.erase(newSymbol.name());
const Symbol &result{oldDetails.result()};
if (Symbol * copy{mapper.CopySymbol(&result)}) {
newDetails.set_result(*copy);
mappings->symbolMap[&result] = copy;
}
}
for (auto &[_, ref] : newScope) {
mapper.MapSymbolExprs(*ref);
}
newScope.InstantiateDerivedTypes();
}
} // namespace Fortran::semantics
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