forked from OSchip/llvm-project
1061 lines
40 KiB
C++
1061 lines
40 KiB
C++
//===-- lib/Semantics/check-do-forall.cpp ---------------------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "check-do-forall.h"
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#include "flang/Common/template.h"
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#include "flang/Evaluate/call.h"
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#include "flang/Evaluate/expression.h"
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#include "flang/Evaluate/tools.h"
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#include "flang/Parser/message.h"
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#include "flang/Parser/parse-tree-visitor.h"
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#include "flang/Parser/tools.h"
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#include "flang/Semantics/attr.h"
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#include "flang/Semantics/scope.h"
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#include "flang/Semantics/semantics.h"
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#include "flang/Semantics/symbol.h"
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#include "flang/Semantics/tools.h"
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#include "flang/Semantics/type.h"
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namespace Fortran::evaluate {
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using ActualArgumentRef = common::Reference<const ActualArgument>;
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inline bool operator<(ActualArgumentRef x, ActualArgumentRef y) {
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return &*x < &*y;
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}
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} // namespace Fortran::evaluate
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namespace Fortran::semantics {
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using namespace parser::literals;
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using Bounds = parser::LoopControl::Bounds;
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using IndexVarKind = SemanticsContext::IndexVarKind;
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static const parser::ConcurrentHeader &GetConcurrentHeader(
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const parser::LoopControl &loopControl) {
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const auto &concurrent{
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std::get<parser::LoopControl::Concurrent>(loopControl.u)};
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return std::get<parser::ConcurrentHeader>(concurrent.t);
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}
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static const parser::ConcurrentHeader &GetConcurrentHeader(
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const parser::ForallConstruct &construct) {
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const auto &stmt{
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std::get<parser::Statement<parser::ForallConstructStmt>>(construct.t)};
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return std::get<common::Indirection<parser::ConcurrentHeader>>(
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stmt.statement.t)
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.value();
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}
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static const parser::ConcurrentHeader &GetConcurrentHeader(
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const parser::ForallStmt &stmt) {
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return std::get<common::Indirection<parser::ConcurrentHeader>>(stmt.t)
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.value();
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}
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template <typename T>
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static const std::list<parser::ConcurrentControl> &GetControls(const T &x) {
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return std::get<std::list<parser::ConcurrentControl>>(
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GetConcurrentHeader(x).t);
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}
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static const Bounds &GetBounds(const parser::DoConstruct &doConstruct) {
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auto &loopControl{doConstruct.GetLoopControl().value()};
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return std::get<Bounds>(loopControl.u);
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}
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static const parser::Name &GetDoVariable(
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const parser::DoConstruct &doConstruct) {
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const Bounds &bounds{GetBounds(doConstruct)};
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return bounds.name.thing;
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}
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static parser::MessageFixedText GetEnclosingDoMsg() {
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return "Enclosing DO CONCURRENT statement"_en_US;
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}
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static void SayWithDo(SemanticsContext &context, parser::CharBlock stmtLocation,
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parser::MessageFixedText &&message, parser::CharBlock doLocation) {
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context.Say(stmtLocation, message).Attach(doLocation, GetEnclosingDoMsg());
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}
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// 11.1.7.5 - enforce semantics constraints on a DO CONCURRENT loop body
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class DoConcurrentBodyEnforce {
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public:
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DoConcurrentBodyEnforce(
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SemanticsContext &context, parser::CharBlock doConcurrentSourcePosition)
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: context_{context}, doConcurrentSourcePosition_{
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doConcurrentSourcePosition} {}
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std::set<parser::Label> labels() { return labels_; }
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template <typename T> bool Pre(const T &) { return true; }
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template <typename T> void Post(const T &) {}
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template <typename T> bool Pre(const parser::Statement<T> &statement) {
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currentStatementSourcePosition_ = statement.source;
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if (statement.label.has_value()) {
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labels_.insert(*statement.label);
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}
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return true;
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}
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template <typename T> bool Pre(const parser::UnlabeledStatement<T> &stmt) {
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currentStatementSourcePosition_ = stmt.source;
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return true;
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}
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// C1140 -- Can't deallocate a polymorphic entity in a DO CONCURRENT.
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// Deallocation can be caused by exiting a block that declares an allocatable
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// entity, assignment to an allocatable variable, or an actual DEALLOCATE
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// statement
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//
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// Note also that the deallocation of a derived type entity might cause the
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// invocation of an IMPURE final subroutine. (C1139)
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//
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// Only to be called for symbols with ObjectEntityDetails
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static bool HasImpureFinal(const Symbol &original) {
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const Symbol &symbol{ResolveAssociations(original)};
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if (symbol.has<ObjectEntityDetails>()) {
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if (const DeclTypeSpec * symType{symbol.GetType()}) {
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if (const DerivedTypeSpec * derived{symType->AsDerived()}) {
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return semantics::HasImpureFinal(*derived);
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}
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}
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}
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return false;
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}
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// Predicate for deallocations caused by block exit and direct deallocation
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static bool DeallocateAll(const Symbol &) { return true; }
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// Predicate for deallocations caused by intrinsic assignment
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static bool DeallocateNonCoarray(const Symbol &component) {
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return !evaluate::IsCoarray(component);
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}
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static bool WillDeallocatePolymorphic(const Symbol &entity,
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const std::function<bool(const Symbol &)> &WillDeallocate) {
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return WillDeallocate(entity) && IsPolymorphicAllocatable(entity);
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}
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// Is it possible that we will we deallocate a polymorphic entity or one
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// of its components?
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static bool MightDeallocatePolymorphic(const Symbol &original,
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const std::function<bool(const Symbol &)> &WillDeallocate) {
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const Symbol &symbol{ResolveAssociations(original)};
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// Check the entity itself, no coarray exception here
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if (IsPolymorphicAllocatable(symbol)) {
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return true;
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}
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// Check the components
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if (const auto *details{symbol.detailsIf<ObjectEntityDetails>()}) {
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if (const DeclTypeSpec * entityType{details->type()}) {
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if (const DerivedTypeSpec * derivedType{entityType->AsDerived()}) {
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UltimateComponentIterator ultimates{*derivedType};
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for (const auto &ultimate : ultimates) {
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if (WillDeallocatePolymorphic(ultimate, WillDeallocate)) {
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return true;
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}
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}
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}
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}
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}
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return false;
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}
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void SayDeallocateWithImpureFinal(const Symbol &entity, const char *reason) {
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context_.SayWithDecl(entity, currentStatementSourcePosition_,
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"Deallocation of an entity with an IMPURE FINAL procedure"
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" caused by %s not allowed in DO CONCURRENT"_err_en_US,
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reason);
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}
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void SayDeallocateOfPolymorph(
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parser::CharBlock location, const Symbol &entity, const char *reason) {
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context_.SayWithDecl(entity, location,
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"Deallocation of a polymorphic entity caused by %s"
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" not allowed in DO CONCURRENT"_err_en_US,
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reason);
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}
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// Deallocation caused by block exit
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// Allocatable entities and all of their allocatable subcomponents will be
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// deallocated. This test is different from the other two because it does
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// not deallocate in cases where the entity itself is not allocatable but
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// has allocatable polymorphic components
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void Post(const parser::BlockConstruct &blockConstruct) {
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const auto &endBlockStmt{
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std::get<parser::Statement<parser::EndBlockStmt>>(blockConstruct.t)};
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const Scope &blockScope{context_.FindScope(endBlockStmt.source)};
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const Scope &doScope{context_.FindScope(doConcurrentSourcePosition_)};
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if (DoesScopeContain(&doScope, blockScope)) {
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const char *reason{"block exit"};
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for (auto &pair : blockScope) {
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const Symbol &entity{*pair.second};
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if (IsAllocatable(entity) && !IsSaved(entity) &&
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MightDeallocatePolymorphic(entity, DeallocateAll)) {
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SayDeallocateOfPolymorph(endBlockStmt.source, entity, reason);
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}
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if (HasImpureFinal(entity)) {
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SayDeallocateWithImpureFinal(entity, reason);
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}
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}
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}
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}
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// Deallocation caused by assignment
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// Note that this case does not cause deallocation of coarray components
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void Post(const parser::AssignmentStmt &stmt) {
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const auto &variable{std::get<parser::Variable>(stmt.t)};
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if (const Symbol * entity{GetLastName(variable).symbol}) {
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const char *reason{"assignment"};
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if (MightDeallocatePolymorphic(*entity, DeallocateNonCoarray)) {
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SayDeallocateOfPolymorph(variable.GetSource(), *entity, reason);
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}
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if (HasImpureFinal(*entity)) {
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SayDeallocateWithImpureFinal(*entity, reason);
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}
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}
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}
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// Deallocation from a DEALLOCATE statement
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// This case is different because DEALLOCATE statements deallocate both
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// ALLOCATABLE and POINTER entities
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void Post(const parser::DeallocateStmt &stmt) {
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const auto &allocateObjectList{
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std::get<std::list<parser::AllocateObject>>(stmt.t)};
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for (const auto &allocateObject : allocateObjectList) {
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const parser::Name &name{GetLastName(allocateObject)};
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const char *reason{"a DEALLOCATE statement"};
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if (name.symbol) {
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const Symbol &entity{*name.symbol};
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const DeclTypeSpec *entityType{entity.GetType()};
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if ((entityType && entityType->IsPolymorphic()) || // POINTER case
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MightDeallocatePolymorphic(entity, DeallocateAll)) {
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SayDeallocateOfPolymorph(
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currentStatementSourcePosition_, entity, reason);
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}
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if (HasImpureFinal(entity)) {
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SayDeallocateWithImpureFinal(entity, reason);
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}
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}
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}
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}
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// C1137 -- No image control statements in a DO CONCURRENT
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void Post(const parser::ExecutableConstruct &construct) {
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if (IsImageControlStmt(construct)) {
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const parser::CharBlock statementLocation{
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GetImageControlStmtLocation(construct)};
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auto &msg{context_.Say(statementLocation,
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"An image control statement is not allowed in DO"
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" CONCURRENT"_err_en_US)};
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if (auto coarrayMsg{GetImageControlStmtCoarrayMsg(construct)}) {
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msg.Attach(statementLocation, *coarrayMsg);
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}
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msg.Attach(doConcurrentSourcePosition_, GetEnclosingDoMsg());
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}
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}
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// C1136 -- No RETURN statements in a DO CONCURRENT
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void Post(const parser::ReturnStmt &) {
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context_
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.Say(currentStatementSourcePosition_,
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"RETURN is not allowed in DO CONCURRENT"_err_en_US)
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.Attach(doConcurrentSourcePosition_, GetEnclosingDoMsg());
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}
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// C1139: call to impure procedure and ...
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// C1141: cannot call ieee_get_flag, ieee_[gs]et_halting_mode
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// It's not necessary to check the ieee_get* procedures because they're
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// not pure, and impure procedures are caught by checks for constraint C1139
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void Post(const parser::ProcedureDesignator &procedureDesignator) {
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if (auto *name{std::get_if<parser::Name>(&procedureDesignator.u)}) {
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if (name->symbol && !IsPureProcedure(*name->symbol)) {
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SayWithDo(context_, currentStatementSourcePosition_,
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"Call to an impure procedure is not allowed in DO"
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" CONCURRENT"_err_en_US,
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doConcurrentSourcePosition_);
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}
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if (name->symbol &&
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fromScope(*name->symbol, "__fortran_ieee_exceptions"s)) {
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if (name->source == "ieee_set_halting_mode") {
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SayWithDo(context_, currentStatementSourcePosition_,
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"IEEE_SET_HALTING_MODE is not allowed in DO "
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"CONCURRENT"_err_en_US,
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doConcurrentSourcePosition_);
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}
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}
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} else {
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// C1139: this a procedure component
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auto &component{std::get<parser::ProcComponentRef>(procedureDesignator.u)
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.v.thing.component};
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if (component.symbol && !IsPureProcedure(*component.symbol)) {
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SayWithDo(context_, currentStatementSourcePosition_,
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"Call to an impure procedure component is not allowed"
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" in DO CONCURRENT"_err_en_US,
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doConcurrentSourcePosition_);
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}
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}
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}
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// 11.1.7.5, paragraph 5, no ADVANCE specifier in a DO CONCURRENT
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void Post(const parser::IoControlSpec &ioControlSpec) {
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if (auto *charExpr{
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std::get_if<parser::IoControlSpec::CharExpr>(&ioControlSpec.u)}) {
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if (std::get<parser::IoControlSpec::CharExpr::Kind>(charExpr->t) ==
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parser::IoControlSpec::CharExpr::Kind::Advance) {
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SayWithDo(context_, currentStatementSourcePosition_,
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"ADVANCE specifier is not allowed in DO"
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" CONCURRENT"_err_en_US,
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doConcurrentSourcePosition_);
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}
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}
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}
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private:
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bool fromScope(const Symbol &symbol, const std::string &moduleName) {
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if (symbol.GetUltimate().owner().IsModule() &&
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symbol.GetUltimate().owner().GetName().value().ToString() ==
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moduleName) {
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return true;
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}
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return false;
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}
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std::set<parser::Label> labels_;
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parser::CharBlock currentStatementSourcePosition_;
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SemanticsContext &context_;
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parser::CharBlock doConcurrentSourcePosition_;
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}; // class DoConcurrentBodyEnforce
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// Class for enforcing C1130 -- in a DO CONCURRENT with DEFAULT(NONE),
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// variables from enclosing scopes must have their locality specified
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class DoConcurrentVariableEnforce {
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public:
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DoConcurrentVariableEnforce(
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SemanticsContext &context, parser::CharBlock doConcurrentSourcePosition)
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: context_{context},
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doConcurrentSourcePosition_{doConcurrentSourcePosition},
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blockScope_{context.FindScope(doConcurrentSourcePosition_)} {}
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template <typename T> bool Pre(const T &) { return true; }
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template <typename T> void Post(const T &) {}
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// Check to see if the name is a variable from an enclosing scope
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void Post(const parser::Name &name) {
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if (const Symbol * symbol{name.symbol}) {
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if (IsVariableName(*symbol)) {
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const Scope &variableScope{symbol->owner()};
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if (DoesScopeContain(&variableScope, blockScope_)) {
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context_.SayWithDecl(*symbol, name.source,
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"Variable '%s' from an enclosing scope referenced in DO "
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"CONCURRENT with DEFAULT(NONE) must appear in a "
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"locality-spec"_err_en_US,
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symbol->name());
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}
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}
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}
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}
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private:
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SemanticsContext &context_;
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parser::CharBlock doConcurrentSourcePosition_;
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const Scope &blockScope_;
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}; // class DoConcurrentVariableEnforce
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// Find a DO or FORALL and enforce semantics checks on its body
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class DoContext {
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public:
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DoContext(SemanticsContext &context, IndexVarKind kind)
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: context_{context}, kind_{kind} {}
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// Mark this DO construct as a point of definition for the DO variables
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// or index-names it contains. If they're already defined, emit an error
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// message. We need to remember both the variable and the source location of
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// the variable in the DO construct so that we can remove it when we leave
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// the DO construct and use its location in error messages.
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void DefineDoVariables(const parser::DoConstruct &doConstruct) {
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if (doConstruct.IsDoNormal()) {
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context_.ActivateIndexVar(GetDoVariable(doConstruct), IndexVarKind::DO);
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} else if (doConstruct.IsDoConcurrent()) {
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if (const auto &loopControl{doConstruct.GetLoopControl()}) {
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ActivateIndexVars(GetControls(*loopControl));
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}
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}
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}
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// Called at the end of a DO construct to deactivate the DO construct
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void ResetDoVariables(const parser::DoConstruct &doConstruct) {
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if (doConstruct.IsDoNormal()) {
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context_.DeactivateIndexVar(GetDoVariable(doConstruct));
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} else if (doConstruct.IsDoConcurrent()) {
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if (const auto &loopControl{doConstruct.GetLoopControl()}) {
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DeactivateIndexVars(GetControls(*loopControl));
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}
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}
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}
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void ActivateIndexVars(const std::list<parser::ConcurrentControl> &controls) {
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for (const auto &control : controls) {
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context_.ActivateIndexVar(std::get<parser::Name>(control.t), kind_);
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}
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}
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void DeactivateIndexVars(
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const std::list<parser::ConcurrentControl> &controls) {
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for (const auto &control : controls) {
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context_.DeactivateIndexVar(std::get<parser::Name>(control.t));
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}
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}
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void Check(const parser::DoConstruct &doConstruct) {
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if (doConstruct.IsDoConcurrent()) {
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CheckDoConcurrent(doConstruct);
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return;
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}
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if (doConstruct.IsDoNormal()) {
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CheckDoNormal(doConstruct);
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return;
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}
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// TODO: handle the other cases
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}
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void Check(const parser::ForallStmt &stmt) {
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CheckConcurrentHeader(GetConcurrentHeader(stmt));
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}
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void Check(const parser::ForallConstruct &construct) {
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CheckConcurrentHeader(GetConcurrentHeader(construct));
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}
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void Check(const parser::ForallAssignmentStmt &stmt) {
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const evaluate::Assignment *assignment{common::visit(
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common::visitors{[&](const auto &x) { return GetAssignment(x); }},
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stmt.u)};
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if (assignment) {
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CheckForallIndexesUsed(*assignment);
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CheckForImpureCall(assignment->lhs);
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CheckForImpureCall(assignment->rhs);
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if (const auto *proc{
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std::get_if<evaluate::ProcedureRef>(&assignment->u)}) {
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CheckForImpureCall(*proc);
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}
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common::visit(
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common::visitors{
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[](const evaluate::Assignment::Intrinsic &) {},
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[&](const evaluate::ProcedureRef &proc) {
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CheckForImpureCall(proc);
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},
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[&](const evaluate::Assignment::BoundsSpec &bounds) {
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for (const auto &bound : bounds) {
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CheckForImpureCall(SomeExpr{bound});
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}
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},
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[&](const evaluate::Assignment::BoundsRemapping &bounds) {
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for (const auto &bound : bounds) {
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CheckForImpureCall(SomeExpr{bound.first});
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CheckForImpureCall(SomeExpr{bound.second});
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}
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},
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},
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assignment->u);
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}
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}
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private:
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void SayBadDoControl(parser::CharBlock sourceLocation) {
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context_.Say(sourceLocation, "DO controls should be INTEGER"_err_en_US);
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}
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void CheckDoControl(const parser::CharBlock &sourceLocation, bool isReal) {
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const bool warn{context_.warnOnNonstandardUsage() ||
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context_.ShouldWarn(common::LanguageFeature::RealDoControls)};
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if (isReal && !warn) {
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// No messages for the default case
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} else if (isReal && warn) {
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context_.Say(sourceLocation, "DO controls should be INTEGER"_port_en_US);
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} else {
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SayBadDoControl(sourceLocation);
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}
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}
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void CheckDoVariable(const parser::ScalarName &scalarName) {
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const parser::CharBlock &sourceLocation{scalarName.thing.source};
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if (const Symbol * symbol{scalarName.thing.symbol}) {
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if (!IsVariableName(*symbol)) {
|
|
context_.Say(
|
|
sourceLocation, "DO control must be an INTEGER variable"_err_en_US);
|
|
} else {
|
|
const DeclTypeSpec *symType{symbol->GetType()};
|
|
if (!symType) {
|
|
SayBadDoControl(sourceLocation);
|
|
} else {
|
|
if (!symType->IsNumeric(TypeCategory::Integer)) {
|
|
CheckDoControl(
|
|
sourceLocation, symType->IsNumeric(TypeCategory::Real));
|
|
}
|
|
}
|
|
} // No messages for INTEGER
|
|
}
|
|
}
|
|
|
|
// Semantic checks for the limit and step expressions
|
|
void CheckDoExpression(const parser::ScalarExpr &scalarExpression) {
|
|
if (const SomeExpr * expr{GetExpr(context_, scalarExpression)}) {
|
|
if (!ExprHasTypeCategory(*expr, TypeCategory::Integer)) {
|
|
// No warnings or errors for type INTEGER
|
|
const parser::CharBlock &loc{scalarExpression.thing.value().source};
|
|
CheckDoControl(loc, ExprHasTypeCategory(*expr, TypeCategory::Real));
|
|
}
|
|
}
|
|
}
|
|
|
|
void CheckDoNormal(const parser::DoConstruct &doConstruct) {
|
|
// C1120 -- types of DO variables must be INTEGER, extended by allowing
|
|
// REAL and DOUBLE PRECISION
|
|
const Bounds &bounds{GetBounds(doConstruct)};
|
|
CheckDoVariable(bounds.name);
|
|
CheckDoExpression(bounds.lower);
|
|
CheckDoExpression(bounds.upper);
|
|
if (bounds.step) {
|
|
CheckDoExpression(*bounds.step);
|
|
if (IsZero(*bounds.step)) {
|
|
context_.Say(bounds.step->thing.value().source,
|
|
"DO step expression should not be zero"_warn_en_US);
|
|
}
|
|
}
|
|
}
|
|
|
|
void CheckDoConcurrent(const parser::DoConstruct &doConstruct) {
|
|
auto &doStmt{
|
|
std::get<parser::Statement<parser::NonLabelDoStmt>>(doConstruct.t)};
|
|
currentStatementSourcePosition_ = doStmt.source;
|
|
|
|
const parser::Block &block{std::get<parser::Block>(doConstruct.t)};
|
|
DoConcurrentBodyEnforce doConcurrentBodyEnforce{context_, doStmt.source};
|
|
parser::Walk(block, doConcurrentBodyEnforce);
|
|
|
|
LabelEnforce doConcurrentLabelEnforce{context_,
|
|
doConcurrentBodyEnforce.labels(), currentStatementSourcePosition_,
|
|
"DO CONCURRENT"};
|
|
parser::Walk(block, doConcurrentLabelEnforce);
|
|
|
|
const auto &loopControl{doConstruct.GetLoopControl()};
|
|
CheckConcurrentLoopControl(*loopControl);
|
|
CheckLocalitySpecs(*loopControl, block);
|
|
}
|
|
|
|
// Return a set of symbols whose names are in a Local locality-spec. Look
|
|
// the names up in the scope that encloses the DO construct to avoid getting
|
|
// the local versions of them. Then follow the host-, use-, and
|
|
// construct-associations to get the root symbols
|
|
UnorderedSymbolSet GatherLocals(
|
|
const std::list<parser::LocalitySpec> &localitySpecs) const {
|
|
UnorderedSymbolSet symbols;
|
|
const Scope &parentScope{
|
|
context_.FindScope(currentStatementSourcePosition_).parent()};
|
|
// Loop through the LocalitySpec::Local locality-specs
|
|
for (const auto &ls : localitySpecs) {
|
|
if (const auto *names{std::get_if<parser::LocalitySpec::Local>(&ls.u)}) {
|
|
// Loop through the names in the Local locality-spec getting their
|
|
// symbols
|
|
for (const parser::Name &name : names->v) {
|
|
if (const Symbol * symbol{parentScope.FindSymbol(name.source)}) {
|
|
symbols.insert(ResolveAssociations(*symbol));
|
|
}
|
|
}
|
|
}
|
|
}
|
|
return symbols;
|
|
}
|
|
|
|
UnorderedSymbolSet GatherSymbolsFromExpression(
|
|
const parser::Expr &expression) const {
|
|
UnorderedSymbolSet result;
|
|
if (const auto *expr{GetExpr(context_, expression)}) {
|
|
for (const Symbol &symbol : evaluate::CollectSymbols(*expr)) {
|
|
result.insert(ResolveAssociations(symbol));
|
|
}
|
|
}
|
|
return result;
|
|
}
|
|
|
|
// C1121 - procedures in mask must be pure
|
|
void CheckMaskIsPure(const parser::ScalarLogicalExpr &mask) const {
|
|
UnorderedSymbolSet references{
|
|
GatherSymbolsFromExpression(mask.thing.thing.value())};
|
|
for (const Symbol &ref : OrderBySourcePosition(references)) {
|
|
if (IsProcedure(ref) && !IsPureProcedure(ref)) {
|
|
context_.SayWithDecl(ref, parser::Unwrap<parser::Expr>(mask)->source,
|
|
"%s mask expression may not reference impure procedure '%s'"_err_en_US,
|
|
LoopKindName(), ref.name());
|
|
return;
|
|
}
|
|
}
|
|
}
|
|
|
|
void CheckNoCollisions(const UnorderedSymbolSet &refs,
|
|
const UnorderedSymbolSet &uses, parser::MessageFixedText &&errorMessage,
|
|
const parser::CharBlock &refPosition) const {
|
|
for (const Symbol &ref : OrderBySourcePosition(refs)) {
|
|
if (uses.find(ref) != uses.end()) {
|
|
context_.SayWithDecl(ref, refPosition, std::move(errorMessage),
|
|
LoopKindName(), ref.name());
|
|
return;
|
|
}
|
|
}
|
|
}
|
|
|
|
void HasNoReferences(const UnorderedSymbolSet &indexNames,
|
|
const parser::ScalarIntExpr &expr) const {
|
|
CheckNoCollisions(GatherSymbolsFromExpression(expr.thing.thing.value()),
|
|
indexNames,
|
|
"%s limit expression may not reference index variable '%s'"_err_en_US,
|
|
expr.thing.thing.value().source);
|
|
}
|
|
|
|
// C1129, names in local locality-specs can't be in mask expressions
|
|
void CheckMaskDoesNotReferenceLocal(const parser::ScalarLogicalExpr &mask,
|
|
const UnorderedSymbolSet &localVars) const {
|
|
CheckNoCollisions(GatherSymbolsFromExpression(mask.thing.thing.value()),
|
|
localVars,
|
|
"%s mask expression references variable '%s'"
|
|
" in LOCAL locality-spec"_err_en_US,
|
|
mask.thing.thing.value().source);
|
|
}
|
|
|
|
// C1129, names in local locality-specs can't be in limit or step
|
|
// expressions
|
|
void CheckExprDoesNotReferenceLocal(const parser::ScalarIntExpr &expr,
|
|
const UnorderedSymbolSet &localVars) const {
|
|
CheckNoCollisions(GatherSymbolsFromExpression(expr.thing.thing.value()),
|
|
localVars,
|
|
"%s expression references variable '%s'"
|
|
" in LOCAL locality-spec"_err_en_US,
|
|
expr.thing.thing.value().source);
|
|
}
|
|
|
|
// C1130, DEFAULT(NONE) locality requires names to be in locality-specs to
|
|
// be used in the body of the DO loop
|
|
void CheckDefaultNoneImpliesExplicitLocality(
|
|
const std::list<parser::LocalitySpec> &localitySpecs,
|
|
const parser::Block &block) const {
|
|
bool hasDefaultNone{false};
|
|
for (auto &ls : localitySpecs) {
|
|
if (std::holds_alternative<parser::LocalitySpec::DefaultNone>(ls.u)) {
|
|
if (hasDefaultNone) {
|
|
// C1127, you can only have one DEFAULT(NONE)
|
|
context_.Say(currentStatementSourcePosition_,
|
|
"Only one DEFAULT(NONE) may appear"_port_en_US);
|
|
break;
|
|
}
|
|
hasDefaultNone = true;
|
|
}
|
|
}
|
|
if (hasDefaultNone) {
|
|
DoConcurrentVariableEnforce doConcurrentVariableEnforce{
|
|
context_, currentStatementSourcePosition_};
|
|
parser::Walk(block, doConcurrentVariableEnforce);
|
|
}
|
|
}
|
|
|
|
// C1123, concurrent limit or step expressions can't reference index-names
|
|
void CheckConcurrentHeader(const parser::ConcurrentHeader &header) const {
|
|
if (const auto &mask{
|
|
std::get<std::optional<parser::ScalarLogicalExpr>>(header.t)}) {
|
|
CheckMaskIsPure(*mask);
|
|
}
|
|
auto &controls{std::get<std::list<parser::ConcurrentControl>>(header.t)};
|
|
UnorderedSymbolSet indexNames;
|
|
for (const parser::ConcurrentControl &control : controls) {
|
|
const auto &indexName{std::get<parser::Name>(control.t)};
|
|
if (indexName.symbol) {
|
|
indexNames.insert(*indexName.symbol);
|
|
}
|
|
}
|
|
if (!indexNames.empty()) {
|
|
for (const parser::ConcurrentControl &control : controls) {
|
|
HasNoReferences(indexNames, std::get<1>(control.t));
|
|
HasNoReferences(indexNames, std::get<2>(control.t));
|
|
if (const auto &intExpr{
|
|
std::get<std::optional<parser::ScalarIntExpr>>(control.t)}) {
|
|
const parser::Expr &expr{intExpr->thing.thing.value()};
|
|
CheckNoCollisions(GatherSymbolsFromExpression(expr), indexNames,
|
|
"%s step expression may not reference index variable '%s'"_err_en_US,
|
|
expr.source);
|
|
if (IsZero(expr)) {
|
|
context_.Say(expr.source,
|
|
"%s step expression may not be zero"_err_en_US, LoopKindName());
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
void CheckLocalitySpecs(
|
|
const parser::LoopControl &control, const parser::Block &block) const {
|
|
const auto &concurrent{
|
|
std::get<parser::LoopControl::Concurrent>(control.u)};
|
|
const auto &header{std::get<parser::ConcurrentHeader>(concurrent.t)};
|
|
const auto &localitySpecs{
|
|
std::get<std::list<parser::LocalitySpec>>(concurrent.t)};
|
|
if (!localitySpecs.empty()) {
|
|
const UnorderedSymbolSet &localVars{GatherLocals(localitySpecs)};
|
|
for (const auto &c : GetControls(control)) {
|
|
CheckExprDoesNotReferenceLocal(std::get<1>(c.t), localVars);
|
|
CheckExprDoesNotReferenceLocal(std::get<2>(c.t), localVars);
|
|
if (const auto &expr{
|
|
std::get<std::optional<parser::ScalarIntExpr>>(c.t)}) {
|
|
CheckExprDoesNotReferenceLocal(*expr, localVars);
|
|
}
|
|
}
|
|
if (const auto &mask{
|
|
std::get<std::optional<parser::ScalarLogicalExpr>>(header.t)}) {
|
|
CheckMaskDoesNotReferenceLocal(*mask, localVars);
|
|
}
|
|
CheckDefaultNoneImpliesExplicitLocality(localitySpecs, block);
|
|
}
|
|
}
|
|
|
|
// check constraints [C1121 .. C1130]
|
|
void CheckConcurrentLoopControl(const parser::LoopControl &control) const {
|
|
const auto &concurrent{
|
|
std::get<parser::LoopControl::Concurrent>(control.u)};
|
|
CheckConcurrentHeader(std::get<parser::ConcurrentHeader>(concurrent.t));
|
|
}
|
|
|
|
template <typename T> void CheckForImpureCall(const T &x) {
|
|
if (auto bad{FindImpureCall(context_.foldingContext(), x)}) {
|
|
context_.Say(
|
|
"Impure procedure '%s' may not be referenced in a %s"_err_en_US, *bad,
|
|
LoopKindName());
|
|
}
|
|
}
|
|
|
|
// Each index should be used on the LHS of each assignment in a FORALL
|
|
void CheckForallIndexesUsed(const evaluate::Assignment &assignment) {
|
|
SymbolVector indexVars{context_.GetIndexVars(IndexVarKind::FORALL)};
|
|
if (!indexVars.empty()) {
|
|
UnorderedSymbolSet symbols{evaluate::CollectSymbols(assignment.lhs)};
|
|
common::visit(
|
|
common::visitors{
|
|
[&](const evaluate::Assignment::BoundsSpec &spec) {
|
|
for (const auto &bound : spec) {
|
|
// TODO: this is working around missing std::set::merge in some versions of
|
|
// clang that we are building with
|
|
#ifdef __clang__
|
|
auto boundSymbols{evaluate::CollectSymbols(bound)};
|
|
symbols.insert(boundSymbols.begin(), boundSymbols.end());
|
|
#else
|
|
symbols.merge(evaluate::CollectSymbols(bound));
|
|
#endif
|
|
}
|
|
},
|
|
[&](const evaluate::Assignment::BoundsRemapping &remapping) {
|
|
for (const auto &bounds : remapping) {
|
|
#ifdef __clang__
|
|
auto lbSymbols{evaluate::CollectSymbols(bounds.first)};
|
|
symbols.insert(lbSymbols.begin(), lbSymbols.end());
|
|
auto ubSymbols{evaluate::CollectSymbols(bounds.second)};
|
|
symbols.insert(ubSymbols.begin(), ubSymbols.end());
|
|
#else
|
|
symbols.merge(evaluate::CollectSymbols(bounds.first));
|
|
symbols.merge(evaluate::CollectSymbols(bounds.second));
|
|
#endif
|
|
}
|
|
},
|
|
[](const auto &) {},
|
|
},
|
|
assignment.u);
|
|
for (const Symbol &index : indexVars) {
|
|
if (symbols.count(index) == 0) {
|
|
context_.Say("FORALL index variable '%s' not used on left-hand side"
|
|
" of assignment"_warn_en_US,
|
|
index.name());
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
// For messages where the DO loop must be DO CONCURRENT, make that explicit.
|
|
const char *LoopKindName() const {
|
|
return kind_ == IndexVarKind::DO ? "DO CONCURRENT" : "FORALL";
|
|
}
|
|
|
|
SemanticsContext &context_;
|
|
const IndexVarKind kind_;
|
|
parser::CharBlock currentStatementSourcePosition_;
|
|
}; // class DoContext
|
|
|
|
void DoForallChecker::Enter(const parser::DoConstruct &doConstruct) {
|
|
DoContext doContext{context_, IndexVarKind::DO};
|
|
doContext.DefineDoVariables(doConstruct);
|
|
}
|
|
|
|
void DoForallChecker::Leave(const parser::DoConstruct &doConstruct) {
|
|
DoContext doContext{context_, IndexVarKind::DO};
|
|
doContext.Check(doConstruct);
|
|
doContext.ResetDoVariables(doConstruct);
|
|
}
|
|
|
|
void DoForallChecker::Enter(const parser::ForallConstruct &construct) {
|
|
DoContext doContext{context_, IndexVarKind::FORALL};
|
|
doContext.ActivateIndexVars(GetControls(construct));
|
|
}
|
|
void DoForallChecker::Leave(const parser::ForallConstruct &construct) {
|
|
DoContext doContext{context_, IndexVarKind::FORALL};
|
|
doContext.Check(construct);
|
|
doContext.DeactivateIndexVars(GetControls(construct));
|
|
}
|
|
|
|
void DoForallChecker::Enter(const parser::ForallStmt &stmt) {
|
|
DoContext doContext{context_, IndexVarKind::FORALL};
|
|
doContext.ActivateIndexVars(GetControls(stmt));
|
|
}
|
|
void DoForallChecker::Leave(const parser::ForallStmt &stmt) {
|
|
DoContext doContext{context_, IndexVarKind::FORALL};
|
|
doContext.Check(stmt);
|
|
doContext.DeactivateIndexVars(GetControls(stmt));
|
|
}
|
|
void DoForallChecker::Leave(const parser::ForallAssignmentStmt &stmt) {
|
|
DoContext doContext{context_, IndexVarKind::FORALL};
|
|
doContext.Check(stmt);
|
|
}
|
|
|
|
template <typename A>
|
|
static parser::CharBlock GetConstructPosition(const A &a) {
|
|
return std::get<0>(a.t).source;
|
|
}
|
|
|
|
static parser::CharBlock GetNodePosition(const ConstructNode &construct) {
|
|
return common::visit(
|
|
[&](const auto &x) { return GetConstructPosition(*x); }, construct);
|
|
}
|
|
|
|
void DoForallChecker::SayBadLeave(StmtType stmtType,
|
|
const char *enclosingStmtName, const ConstructNode &construct) const {
|
|
context_
|
|
.Say("%s must not leave a %s statement"_err_en_US, EnumToString(stmtType),
|
|
enclosingStmtName)
|
|
.Attach(GetNodePosition(construct), "The construct that was left"_en_US);
|
|
}
|
|
|
|
static const parser::DoConstruct *MaybeGetDoConstruct(
|
|
const ConstructNode &construct) {
|
|
if (const auto *doNode{
|
|
std::get_if<const parser::DoConstruct *>(&construct)}) {
|
|
return *doNode;
|
|
} else {
|
|
return nullptr;
|
|
}
|
|
}
|
|
|
|
static bool ConstructIsDoConcurrent(const ConstructNode &construct) {
|
|
const parser::DoConstruct *doConstruct{MaybeGetDoConstruct(construct)};
|
|
return doConstruct && doConstruct->IsDoConcurrent();
|
|
}
|
|
|
|
// Check that CYCLE and EXIT statements do not cause flow of control to
|
|
// leave DO CONCURRENT, CRITICAL, or CHANGE TEAM constructs.
|
|
void DoForallChecker::CheckForBadLeave(
|
|
StmtType stmtType, const ConstructNode &construct) const {
|
|
common::visit(common::visitors{
|
|
[&](const parser::DoConstruct *doConstructPtr) {
|
|
if (doConstructPtr->IsDoConcurrent()) {
|
|
// C1135 and C1167 -- CYCLE and EXIT statements can't
|
|
// leave a DO CONCURRENT
|
|
SayBadLeave(stmtType, "DO CONCURRENT", construct);
|
|
}
|
|
},
|
|
[&](const parser::CriticalConstruct *) {
|
|
// C1135 and C1168 -- similarly, for CRITICAL
|
|
SayBadLeave(stmtType, "CRITICAL", construct);
|
|
},
|
|
[&](const parser::ChangeTeamConstruct *) {
|
|
// C1135 and C1168 -- similarly, for CHANGE TEAM
|
|
SayBadLeave(stmtType, "CHANGE TEAM", construct);
|
|
},
|
|
[](const auto *) {},
|
|
},
|
|
construct);
|
|
}
|
|
|
|
static bool StmtMatchesConstruct(const parser::Name *stmtName,
|
|
StmtType stmtType, const std::optional<parser::Name> &constructName,
|
|
const ConstructNode &construct) {
|
|
bool inDoConstruct{MaybeGetDoConstruct(construct) != nullptr};
|
|
if (!stmtName) {
|
|
return inDoConstruct; // Unlabeled statements match all DO constructs
|
|
} else if (constructName && constructName->source == stmtName->source) {
|
|
return stmtType == StmtType::EXIT || inDoConstruct;
|
|
} else {
|
|
return false;
|
|
}
|
|
}
|
|
|
|
// C1167 Can't EXIT from a DO CONCURRENT
|
|
void DoForallChecker::CheckDoConcurrentExit(
|
|
StmtType stmtType, const ConstructNode &construct) const {
|
|
if (stmtType == StmtType::EXIT && ConstructIsDoConcurrent(construct)) {
|
|
SayBadLeave(StmtType::EXIT, "DO CONCURRENT", construct);
|
|
}
|
|
}
|
|
|
|
// Check nesting violations for a CYCLE or EXIT statement. Loop up the
|
|
// nesting levels looking for a construct that matches the CYCLE or EXIT
|
|
// statment. At every construct, check for a violation. If we find a match
|
|
// without finding a violation, the check is complete.
|
|
void DoForallChecker::CheckNesting(
|
|
StmtType stmtType, const parser::Name *stmtName) const {
|
|
const ConstructStack &stack{context_.constructStack()};
|
|
for (auto iter{stack.cend()}; iter-- != stack.cbegin();) {
|
|
const ConstructNode &construct{*iter};
|
|
const std::optional<parser::Name> &constructName{
|
|
MaybeGetNodeName(construct)};
|
|
if (StmtMatchesConstruct(stmtName, stmtType, constructName, construct)) {
|
|
CheckDoConcurrentExit(stmtType, construct);
|
|
return; // We got a match, so we're finished checking
|
|
}
|
|
CheckForBadLeave(stmtType, construct);
|
|
}
|
|
|
|
// We haven't found a match in the enclosing constructs
|
|
if (stmtType == StmtType::EXIT) {
|
|
context_.Say("No matching construct for EXIT statement"_err_en_US);
|
|
} else {
|
|
context_.Say("No matching DO construct for CYCLE statement"_err_en_US);
|
|
}
|
|
}
|
|
|
|
// C1135 -- Nesting for CYCLE statements
|
|
void DoForallChecker::Enter(const parser::CycleStmt &cycleStmt) {
|
|
CheckNesting(StmtType::CYCLE, common::GetPtrFromOptional(cycleStmt.v));
|
|
}
|
|
|
|
// C1167 and C1168 -- Nesting for EXIT statements
|
|
void DoForallChecker::Enter(const parser::ExitStmt &exitStmt) {
|
|
CheckNesting(StmtType::EXIT, common::GetPtrFromOptional(exitStmt.v));
|
|
}
|
|
|
|
void DoForallChecker::Leave(const parser::AssignmentStmt &stmt) {
|
|
const auto &variable{std::get<parser::Variable>(stmt.t)};
|
|
context_.CheckIndexVarRedefine(variable);
|
|
}
|
|
|
|
static void CheckIfArgIsDoVar(const evaluate::ActualArgument &arg,
|
|
const parser::CharBlock location, SemanticsContext &context) {
|
|
common::Intent intent{arg.dummyIntent()};
|
|
if (intent == common::Intent::Out || intent == common::Intent::InOut) {
|
|
if (const SomeExpr * argExpr{arg.UnwrapExpr()}) {
|
|
if (const Symbol * var{evaluate::UnwrapWholeSymbolDataRef(*argExpr)}) {
|
|
if (intent == common::Intent::Out) {
|
|
context.CheckIndexVarRedefine(location, *var);
|
|
} else {
|
|
context.WarnIndexVarRedefine(location, *var); // INTENT(INOUT)
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
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// Check to see if a DO variable is being passed as an actual argument to a
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// dummy argument whose intent is OUT or INOUT. To do this, we need to find
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// the expressions for actual arguments which contain DO variables. We get the
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// intents of the dummy arguments from the ProcedureRef in the "typedCall"
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// field of the CallStmt which was filled in during expression checking. At
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// the same time, we need to iterate over the parser::Expr versions of the
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// actual arguments to get their source locations of the arguments for the
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// messages.
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void DoForallChecker::Leave(const parser::CallStmt &callStmt) {
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if (const auto &typedCall{callStmt.typedCall}) {
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const auto &parsedArgs{
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std::get<std::list<parser::ActualArgSpec>>(callStmt.v.t)};
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auto parsedArgIter{parsedArgs.begin()};
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const evaluate::ActualArguments &checkedArgs{typedCall->arguments()};
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for (const auto &checkedOptionalArg : checkedArgs) {
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|
if (parsedArgIter == parsedArgs.end()) {
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break; // No more parsed arguments, we're done.
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|
}
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const auto &parsedArg{std::get<parser::ActualArg>(parsedArgIter->t)};
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|
++parsedArgIter;
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|
if (checkedOptionalArg) {
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|
const evaluate::ActualArgument &checkedArg{*checkedOptionalArg};
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|
if (const auto *parsedExpr{
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|
std::get_if<common::Indirection<parser::Expr>>(&parsedArg.u)}) {
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|
CheckIfArgIsDoVar(checkedArg, parsedExpr->value().source, context_);
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|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
void DoForallChecker::Leave(const parser::ConnectSpec &connectSpec) {
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|
const auto *newunit{
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|
std::get_if<parser::ConnectSpec::Newunit>(&connectSpec.u)};
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|
if (newunit) {
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|
context_.CheckIndexVarRedefine(newunit->v.thing.thing);
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|
}
|
|
}
|
|
|
|
using ActualArgumentSet = std::set<evaluate::ActualArgumentRef>;
|
|
|
|
struct CollectActualArgumentsHelper
|
|
: public evaluate::SetTraverse<CollectActualArgumentsHelper,
|
|
ActualArgumentSet> {
|
|
using Base = SetTraverse<CollectActualArgumentsHelper, ActualArgumentSet>;
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|
CollectActualArgumentsHelper() : Base{*this} {}
|
|
using Base::operator();
|
|
ActualArgumentSet operator()(const evaluate::ActualArgument &arg) const {
|
|
return Combine(ActualArgumentSet{arg},
|
|
CollectActualArgumentsHelper{}(arg.UnwrapExpr()));
|
|
}
|
|
};
|
|
|
|
template <typename A> ActualArgumentSet CollectActualArguments(const A &x) {
|
|
return CollectActualArgumentsHelper{}(x);
|
|
}
|
|
|
|
template ActualArgumentSet CollectActualArguments(const SomeExpr &);
|
|
|
|
void DoForallChecker::Enter(const parser::Expr &parsedExpr) { ++exprDepth_; }
|
|
|
|
void DoForallChecker::Leave(const parser::Expr &parsedExpr) {
|
|
CHECK(exprDepth_ > 0);
|
|
if (--exprDepth_ == 0) { // Only check top level expressions
|
|
if (const SomeExpr * expr{GetExpr(context_, parsedExpr)}) {
|
|
ActualArgumentSet argSet{CollectActualArguments(*expr)};
|
|
for (const evaluate::ActualArgumentRef &argRef : argSet) {
|
|
CheckIfArgIsDoVar(*argRef, parsedExpr.source, context_);
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
void DoForallChecker::Leave(const parser::InquireSpec &inquireSpec) {
|
|
const auto *intVar{std::get_if<parser::InquireSpec::IntVar>(&inquireSpec.u)};
|
|
if (intVar) {
|
|
const auto &scalar{std::get<parser::ScalarIntVariable>(intVar->t)};
|
|
context_.CheckIndexVarRedefine(scalar.thing.thing);
|
|
}
|
|
}
|
|
|
|
void DoForallChecker::Leave(const parser::IoControlSpec &ioControlSpec) {
|
|
const auto *size{std::get_if<parser::IoControlSpec::Size>(&ioControlSpec.u)};
|
|
if (size) {
|
|
context_.CheckIndexVarRedefine(size->v.thing.thing);
|
|
}
|
|
}
|
|
|
|
void DoForallChecker::Leave(const parser::OutputImpliedDo &outputImpliedDo) {
|
|
const auto &control{std::get<parser::IoImpliedDoControl>(outputImpliedDo.t)};
|
|
const parser::Name &name{control.name.thing.thing};
|
|
context_.CheckIndexVarRedefine(name.source, *name.symbol);
|
|
}
|
|
|
|
void DoForallChecker::Leave(const parser::StatVariable &statVariable) {
|
|
context_.CheckIndexVarRedefine(statVariable.v.thing.thing);
|
|
}
|
|
|
|
} // namespace Fortran::semantics
|