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1 //===-- lib/Semantics/tools.cpp -------------------------------------------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 
9 #include "flang/Parser/tools.h"
10 #include "flang/Common/Fortran.h"
11 #include "flang/Common/indirection.h"
12 #include "flang/Parser/dump-parse-tree.h"
13 #include "flang/Parser/message.h"
14 #include "flang/Parser/parse-tree.h"
15 #include "flang/Semantics/scope.h"
16 #include "flang/Semantics/semantics.h"
17 #include "flang/Semantics/symbol.h"
18 #include "flang/Semantics/tools.h"
19 #include "flang/Semantics/type.h"
20 #include "llvm/Support/raw_ostream.h"
21 #include <algorithm>
22 #include <set>
23 #include <variant>
24 
25 namespace Fortran::semantics {
26 
27 // Find this or containing scope that matches predicate
FindScopeContaining(const Scope & start,std::function<bool (const Scope &)> predicate)28 static const Scope *FindScopeContaining(
29     const Scope &start, std::function<bool(const Scope &)> predicate) {
30   for (const Scope *scope{&start};; scope = &scope->parent()) {
31     if (predicate(*scope)) {
32       return scope;
33     }
34     if (scope->IsGlobal()) {
35       return nullptr;
36     }
37   }
38 }
39 
GetTopLevelUnitContaining(const Scope & start)40 const Scope &GetTopLevelUnitContaining(const Scope &start) {
41   CHECK(!start.IsGlobal());
42   return DEREF(FindScopeContaining(
43       start, [](const Scope &scope) { return scope.parent().IsGlobal(); }));
44 }
45 
GetTopLevelUnitContaining(const Symbol & symbol)46 const Scope &GetTopLevelUnitContaining(const Symbol &symbol) {
47   return GetTopLevelUnitContaining(symbol.owner());
48 }
49 
FindModuleContaining(const Scope & start)50 const Scope *FindModuleContaining(const Scope &start) {
51   return FindScopeContaining(
52       start, [](const Scope &scope) { return scope.IsModule(); });
53 }
54 
GetProgramUnitContaining(const Scope & start)55 const Scope &GetProgramUnitContaining(const Scope &start) {
56   CHECK(!start.IsGlobal());
57   return DEREF(FindScopeContaining(start, [](const Scope &scope) {
58     switch (scope.kind()) {
59     case Scope::Kind::Module:
60     case Scope::Kind::MainProgram:
61     case Scope::Kind::Subprogram:
62     case Scope::Kind::BlockData:
63       return true;
64     default:
65       return false;
66     }
67   }));
68 }
69 
GetProgramUnitContaining(const Symbol & symbol)70 const Scope &GetProgramUnitContaining(const Symbol &symbol) {
71   return GetProgramUnitContaining(symbol.owner());
72 }
73 
FindPureProcedureContaining(const Scope & start)74 const Scope *FindPureProcedureContaining(const Scope &start) {
75   // N.B. We only need to examine the innermost containing program unit
76   // because an internal subprogram of a pure subprogram must also
77   // be pure (C1592).
78   const Scope &scope{GetProgramUnitContaining(start)};
79   return IsPureProcedure(scope) ? &scope : nullptr;
80 }
81 
IsDefinedAssignment(const std::optional<evaluate::DynamicType> & lhsType,int lhsRank,const std::optional<evaluate::DynamicType> & rhsType,int rhsRank)82 Tristate IsDefinedAssignment(
83     const std::optional<evaluate::DynamicType> &lhsType, int lhsRank,
84     const std::optional<evaluate::DynamicType> &rhsType, int rhsRank) {
85   if (!lhsType || !rhsType) {
86     return Tristate::No; // error or rhs is untyped
87   }
88   TypeCategory lhsCat{lhsType->category()};
89   TypeCategory rhsCat{rhsType->category()};
90   if (rhsRank > 0 && lhsRank != rhsRank) {
91     return Tristate::Yes;
92   } else if (lhsCat != TypeCategory::Derived) {
93     return ToTristate(lhsCat != rhsCat &&
94         (!IsNumericTypeCategory(lhsCat) || !IsNumericTypeCategory(rhsCat)));
95   } else {
96     const auto *lhsDerived{evaluate::GetDerivedTypeSpec(lhsType)};
97     const auto *rhsDerived{evaluate::GetDerivedTypeSpec(rhsType)};
98     if (lhsDerived && rhsDerived && *lhsDerived == *rhsDerived) {
99       return Tristate::Maybe; // TYPE(t) = TYPE(t) can be defined or
100                               // intrinsic
101     } else {
102       return Tristate::Yes;
103     }
104   }
105 }
106 
IsIntrinsicRelational(common::RelationalOperator opr,const evaluate::DynamicType & type0,int rank0,const evaluate::DynamicType & type1,int rank1)107 bool IsIntrinsicRelational(common::RelationalOperator opr,
108     const evaluate::DynamicType &type0, int rank0,
109     const evaluate::DynamicType &type1, int rank1) {
110   if (!evaluate::AreConformable(rank0, rank1)) {
111     return false;
112   } else {
113     auto cat0{type0.category()};
114     auto cat1{type1.category()};
115     if (IsNumericTypeCategory(cat0) && IsNumericTypeCategory(cat1)) {
116       // numeric types: EQ/NE always ok, others ok for non-complex
117       return opr == common::RelationalOperator::EQ ||
118           opr == common::RelationalOperator::NE ||
119           (cat0 != TypeCategory::Complex && cat1 != TypeCategory::Complex);
120     } else {
121       // not both numeric: only Character is ok
122       return cat0 == TypeCategory::Character && cat1 == TypeCategory::Character;
123     }
124   }
125 }
126 
IsIntrinsicNumeric(const evaluate::DynamicType & type0)127 bool IsIntrinsicNumeric(const evaluate::DynamicType &type0) {
128   return IsNumericTypeCategory(type0.category());
129 }
IsIntrinsicNumeric(const evaluate::DynamicType & type0,int rank0,const evaluate::DynamicType & type1,int rank1)130 bool IsIntrinsicNumeric(const evaluate::DynamicType &type0, int rank0,
131     const evaluate::DynamicType &type1, int rank1) {
132   return evaluate::AreConformable(rank0, rank1) &&
133       IsNumericTypeCategory(type0.category()) &&
134       IsNumericTypeCategory(type1.category());
135 }
136 
IsIntrinsicLogical(const evaluate::DynamicType & type0)137 bool IsIntrinsicLogical(const evaluate::DynamicType &type0) {
138   return type0.category() == TypeCategory::Logical;
139 }
IsIntrinsicLogical(const evaluate::DynamicType & type0,int rank0,const evaluate::DynamicType & type1,int rank1)140 bool IsIntrinsicLogical(const evaluate::DynamicType &type0, int rank0,
141     const evaluate::DynamicType &type1, int rank1) {
142   return evaluate::AreConformable(rank0, rank1) &&
143       type0.category() == TypeCategory::Logical &&
144       type1.category() == TypeCategory::Logical;
145 }
146 
IsIntrinsicConcat(const evaluate::DynamicType & type0,int rank0,const evaluate::DynamicType & type1,int rank1)147 bool IsIntrinsicConcat(const evaluate::DynamicType &type0, int rank0,
148     const evaluate::DynamicType &type1, int rank1) {
149   return evaluate::AreConformable(rank0, rank1) &&
150       type0.category() == TypeCategory::Character &&
151       type1.category() == TypeCategory::Character &&
152       type0.kind() == type1.kind();
153 }
154 
IsGenericDefinedOp(const Symbol & symbol)155 bool IsGenericDefinedOp(const Symbol &symbol) {
156   const Symbol &ultimate{symbol.GetUltimate()};
157   if (const auto *generic{ultimate.detailsIf<GenericDetails>()}) {
158     return generic->kind().IsDefinedOperator();
159   } else if (const auto *misc{ultimate.detailsIf<MiscDetails>()}) {
160     return misc->kind() == MiscDetails::Kind::TypeBoundDefinedOp;
161   } else {
162     return false;
163   }
164 }
165 
IsDefinedOperator(SourceName name)166 bool IsDefinedOperator(SourceName name) {
167   const char *begin{name.begin()};
168   const char *end{name.end()};
169   return begin != end && begin[0] == '.' && end[-1] == '.';
170 }
171 
MakeOpName(SourceName name)172 std::string MakeOpName(SourceName name) {
173   std::string result{name.ToString()};
174   return IsDefinedOperator(name)         ? "OPERATOR(" + result + ")"
175       : result.find("operator(", 0) == 0 ? parser::ToUpperCaseLetters(result)
176                                          : result;
177 }
178 
IsCommonBlockContaining(const Symbol & block,const Symbol & object)179 bool IsCommonBlockContaining(const Symbol &block, const Symbol &object) {
180   const auto &objects{block.get<CommonBlockDetails>().objects()};
181   auto found{std::find(objects.begin(), objects.end(), object)};
182   return found != objects.end();
183 }
184 
IsUseAssociated(const Symbol & symbol,const Scope & scope)185 bool IsUseAssociated(const Symbol &symbol, const Scope &scope) {
186   const Scope &owner{GetProgramUnitContaining(symbol.GetUltimate().owner())};
187   return owner.kind() == Scope::Kind::Module &&
188       owner != GetProgramUnitContaining(scope);
189 }
190 
DoesScopeContain(const Scope * maybeAncestor,const Scope & maybeDescendent)191 bool DoesScopeContain(
192     const Scope *maybeAncestor, const Scope &maybeDescendent) {
193   return maybeAncestor && !maybeDescendent.IsGlobal() &&
194       FindScopeContaining(maybeDescendent.parent(),
195           [&](const Scope &scope) { return &scope == maybeAncestor; });
196 }
197 
DoesScopeContain(const Scope * maybeAncestor,const Symbol & symbol)198 bool DoesScopeContain(const Scope *maybeAncestor, const Symbol &symbol) {
199   return DoesScopeContain(maybeAncestor, symbol.owner());
200 }
201 
FollowHostAssoc(const Symbol & symbol)202 static const Symbol &FollowHostAssoc(const Symbol &symbol) {
203   for (const Symbol *s{&symbol};;) {
204     const auto *details{s->detailsIf<HostAssocDetails>()};
205     if (!details) {
206       return *s;
207     }
208     s = &details->symbol();
209   }
210 }
211 
IsHostAssociated(const Symbol & symbol,const Scope & scope)212 bool IsHostAssociated(const Symbol &symbol, const Scope &scope) {
213   const Scope &subprogram{GetProgramUnitContaining(scope)};
214   return DoesScopeContain(
215       &GetProgramUnitContaining(FollowHostAssoc(symbol)), subprogram);
216 }
217 
IsInStmtFunction(const Symbol & symbol)218 bool IsInStmtFunction(const Symbol &symbol) {
219   if (const Symbol * function{symbol.owner().symbol()}) {
220     return IsStmtFunction(*function);
221   }
222   return false;
223 }
224 
IsStmtFunctionDummy(const Symbol & symbol)225 bool IsStmtFunctionDummy(const Symbol &symbol) {
226   return IsDummy(symbol) && IsInStmtFunction(symbol);
227 }
228 
IsStmtFunctionResult(const Symbol & symbol)229 bool IsStmtFunctionResult(const Symbol &symbol) {
230   return IsFunctionResult(symbol) && IsInStmtFunction(symbol);
231 }
232 
IsPointerDummy(const Symbol & symbol)233 bool IsPointerDummy(const Symbol &symbol) {
234   return IsPointer(symbol) && IsDummy(symbol);
235 }
236 
237 // proc-name
IsProcName(const Symbol & symbol)238 bool IsProcName(const Symbol &symbol) {
239   return symbol.GetUltimate().has<ProcEntityDetails>();
240 }
241 
IsBindCProcedure(const Symbol & symbol)242 bool IsBindCProcedure(const Symbol &symbol) {
243   if (const auto *procDetails{symbol.detailsIf<ProcEntityDetails>()}) {
244     if (const Symbol * procInterface{procDetails->interface().symbol()}) {
245       // procedure component with a BIND(C) interface
246       return IsBindCProcedure(*procInterface);
247     }
248   }
249   return symbol.attrs().test(Attr::BIND_C) && IsProcedure(symbol);
250 }
251 
IsBindCProcedure(const Scope & scope)252 bool IsBindCProcedure(const Scope &scope) {
253   if (const Symbol * symbol{scope.GetSymbol()}) {
254     return IsBindCProcedure(*symbol);
255   } else {
256     return false;
257   }
258 }
259 
FindPointerComponent(const Scope & scope,std::set<const Scope * > & visited)260 static const Symbol *FindPointerComponent(
261     const Scope &scope, std::set<const Scope *> &visited) {
262   if (!scope.IsDerivedType()) {
263     return nullptr;
264   }
265   if (!visited.insert(&scope).second) {
266     return nullptr;
267   }
268   // If there's a top-level pointer component, return it for clearer error
269   // messaging.
270   for (const auto &pair : scope) {
271     const Symbol &symbol{*pair.second};
272     if (IsPointer(symbol)) {
273       return &symbol;
274     }
275   }
276   for (const auto &pair : scope) {
277     const Symbol &symbol{*pair.second};
278     if (const auto *details{symbol.detailsIf<ObjectEntityDetails>()}) {
279       if (const DeclTypeSpec * type{details->type()}) {
280         if (const DerivedTypeSpec * derived{type->AsDerived()}) {
281           if (const Scope * nested{derived->scope()}) {
282             if (const Symbol *
283                 pointer{FindPointerComponent(*nested, visited)}) {
284               return pointer;
285             }
286           }
287         }
288       }
289     }
290   }
291   return nullptr;
292 }
293 
FindPointerComponent(const Scope & scope)294 const Symbol *FindPointerComponent(const Scope &scope) {
295   std::set<const Scope *> visited;
296   return FindPointerComponent(scope, visited);
297 }
298 
FindPointerComponent(const DerivedTypeSpec & derived)299 const Symbol *FindPointerComponent(const DerivedTypeSpec &derived) {
300   if (const Scope * scope{derived.scope()}) {
301     return FindPointerComponent(*scope);
302   } else {
303     return nullptr;
304   }
305 }
306 
FindPointerComponent(const DeclTypeSpec & type)307 const Symbol *FindPointerComponent(const DeclTypeSpec &type) {
308   if (const DerivedTypeSpec * derived{type.AsDerived()}) {
309     return FindPointerComponent(*derived);
310   } else {
311     return nullptr;
312   }
313 }
314 
FindPointerComponent(const DeclTypeSpec * type)315 const Symbol *FindPointerComponent(const DeclTypeSpec *type) {
316   return type ? FindPointerComponent(*type) : nullptr;
317 }
318 
FindPointerComponent(const Symbol & symbol)319 const Symbol *FindPointerComponent(const Symbol &symbol) {
320   return IsPointer(symbol) ? &symbol : FindPointerComponent(symbol.GetType());
321 }
322 
323 // C1594 specifies several ways by which an object might be globally visible.
FindExternallyVisibleObject(const Symbol & object,const Scope & scope)324 const Symbol *FindExternallyVisibleObject(
325     const Symbol &object, const Scope &scope) {
326   // TODO: Storage association with any object for which this predicate holds,
327   // once EQUIVALENCE is supported.
328   if (IsUseAssociated(object, scope) || IsHostAssociated(object, scope) ||
329       (IsPureProcedure(scope) && IsPointerDummy(object)) ||
330       (IsIntentIn(object) && IsDummy(object))) {
331     return &object;
332   } else if (const Symbol * block{FindCommonBlockContaining(object)}) {
333     return block;
334   } else {
335     return nullptr;
336   }
337 }
338 
ExprHasTypeCategory(const SomeExpr & expr,const common::TypeCategory & type)339 bool ExprHasTypeCategory(
340     const SomeExpr &expr, const common::TypeCategory &type) {
341   auto dynamicType{expr.GetType()};
342   return dynamicType && dynamicType->category() == type;
343 }
344 
ExprTypeKindIsDefault(const SomeExpr & expr,const SemanticsContext & context)345 bool ExprTypeKindIsDefault(
346     const SomeExpr &expr, const SemanticsContext &context) {
347   auto dynamicType{expr.GetType()};
348   return dynamicType &&
349       dynamicType->category() != common::TypeCategory::Derived &&
350       dynamicType->kind() == context.GetDefaultKind(dynamicType->category());
351 }
352 
353 // If an analyzed expr or assignment is missing, dump the node and die.
354 template <typename T>
CheckMissingAnalysis(bool absent,const T & x)355 static void CheckMissingAnalysis(bool absent, const T &x) {
356   if (absent) {
357     std::string buf;
358     llvm::raw_string_ostream ss{buf};
359     ss << "node has not been analyzed:\n";
360     parser::DumpTree(ss, x);
361     common::die(ss.str().c_str());
362   }
363 }
364 
Get(const parser::Expr & x)365 const SomeExpr *GetExprHelper::Get(const parser::Expr &x) {
366   CheckMissingAnalysis(!x.typedExpr, x);
367   return common::GetPtrFromOptional(x.typedExpr->v);
368 }
Get(const parser::Variable & x)369 const SomeExpr *GetExprHelper::Get(const parser::Variable &x) {
370   CheckMissingAnalysis(!x.typedExpr, x);
371   return common::GetPtrFromOptional(x.typedExpr->v);
372 }
Get(const parser::DataStmtConstant & x)373 const SomeExpr *GetExprHelper::Get(const parser::DataStmtConstant &x) {
374   CheckMissingAnalysis(!x.typedExpr, x);
375   return common::GetPtrFromOptional(x.typedExpr->v);
376 }
377 
GetAssignment(const parser::AssignmentStmt & x)378 const evaluate::Assignment *GetAssignment(const parser::AssignmentStmt &x) {
379   CheckMissingAnalysis(!x.typedAssignment, x);
380   return common::GetPtrFromOptional(x.typedAssignment->v);
381 }
GetAssignment(const parser::PointerAssignmentStmt & x)382 const evaluate::Assignment *GetAssignment(
383     const parser::PointerAssignmentStmt &x) {
384   CheckMissingAnalysis(!x.typedAssignment, x);
385   return common::GetPtrFromOptional(x.typedAssignment->v);
386 }
387 
FindInterface(const Symbol & symbol)388 const Symbol *FindInterface(const Symbol &symbol) {
389   return std::visit(
390       common::visitors{
391           [](const ProcEntityDetails &details) {
392             return details.interface().symbol();
393           },
394           [](const ProcBindingDetails &details) { return &details.symbol(); },
395           [](const auto &) -> const Symbol * { return nullptr; },
396       },
397       symbol.details());
398 }
399 
FindSubprogram(const Symbol & symbol)400 const Symbol *FindSubprogram(const Symbol &symbol) {
401   return std::visit(
402       common::visitors{
403           [&](const ProcEntityDetails &details) -> const Symbol * {
404             if (const Symbol * interface{details.interface().symbol()}) {
405               return FindSubprogram(*interface);
406             } else {
407               return &symbol;
408             }
409           },
410           [](const ProcBindingDetails &details) {
411             return FindSubprogram(details.symbol());
412           },
413           [&](const SubprogramDetails &) { return &symbol; },
414           [](const UseDetails &details) {
415             return FindSubprogram(details.symbol());
416           },
417           [](const HostAssocDetails &details) {
418             return FindSubprogram(details.symbol());
419           },
420           [](const auto &) -> const Symbol * { return nullptr; },
421       },
422       symbol.details());
423 }
424 
FindFunctionResult(const Symbol & symbol)425 const Symbol *FindFunctionResult(const Symbol &symbol) {
426   if (const Symbol * subp{FindSubprogram(symbol)}) {
427     if (const auto &subpDetails{subp->detailsIf<SubprogramDetails>()}) {
428       if (subpDetails->isFunction()) {
429         return &subpDetails->result();
430       }
431     }
432   }
433   return nullptr;
434 }
435 
FindOverriddenBinding(const Symbol & symbol)436 const Symbol *FindOverriddenBinding(const Symbol &symbol) {
437   if (symbol.has<ProcBindingDetails>()) {
438     if (const DeclTypeSpec * parentType{FindParentTypeSpec(symbol.owner())}) {
439       if (const DerivedTypeSpec * parentDerived{parentType->AsDerived()}) {
440         if (const Scope * parentScope{parentDerived->typeSymbol().scope()}) {
441           return parentScope->FindComponent(symbol.name());
442         }
443       }
444     }
445   }
446   return nullptr;
447 }
448 
FindParentTypeSpec(const DerivedTypeSpec & derived)449 const DeclTypeSpec *FindParentTypeSpec(const DerivedTypeSpec &derived) {
450   return FindParentTypeSpec(derived.typeSymbol());
451 }
452 
FindParentTypeSpec(const DeclTypeSpec & decl)453 const DeclTypeSpec *FindParentTypeSpec(const DeclTypeSpec &decl) {
454   if (const DerivedTypeSpec * derived{decl.AsDerived()}) {
455     return FindParentTypeSpec(*derived);
456   } else {
457     return nullptr;
458   }
459 }
460 
FindParentTypeSpec(const Scope & scope)461 const DeclTypeSpec *FindParentTypeSpec(const Scope &scope) {
462   if (scope.kind() == Scope::Kind::DerivedType) {
463     if (const auto *symbol{scope.symbol()}) {
464       return FindParentTypeSpec(*symbol);
465     }
466   }
467   return nullptr;
468 }
469 
FindParentTypeSpec(const Symbol & symbol)470 const DeclTypeSpec *FindParentTypeSpec(const Symbol &symbol) {
471   if (const Scope * scope{symbol.scope()}) {
472     if (const auto *details{symbol.detailsIf<DerivedTypeDetails>()}) {
473       if (const Symbol * parent{details->GetParentComponent(*scope)}) {
474         return parent->GetType();
475       }
476     }
477   }
478   return nullptr;
479 }
480 
IsExtensibleType(const DerivedTypeSpec * derived)481 bool IsExtensibleType(const DerivedTypeSpec *derived) {
482   return derived && !IsIsoCType(derived) &&
483       !derived->typeSymbol().attrs().test(Attr::BIND_C) &&
484       !derived->typeSymbol().get<DerivedTypeDetails>().sequence();
485 }
486 
IsBuiltinDerivedType(const DerivedTypeSpec * derived,const char * name)487 bool IsBuiltinDerivedType(const DerivedTypeSpec *derived, const char *name) {
488   if (!derived) {
489     return false;
490   } else {
491     const auto &symbol{derived->typeSymbol()};
492     return symbol.owner().IsModule() &&
493         (symbol.owner().GetName().value() == "__fortran_builtins" ||
494             symbol.owner().GetName().value() == "__fortran_type_info") &&
495         symbol.name() == "__builtin_"s + name;
496   }
497 }
498 
IsIsoCType(const DerivedTypeSpec * derived)499 bool IsIsoCType(const DerivedTypeSpec *derived) {
500   return IsBuiltinDerivedType(derived, "c_ptr") ||
501       IsBuiltinDerivedType(derived, "c_funptr");
502 }
503 
IsTeamType(const DerivedTypeSpec * derived)504 bool IsTeamType(const DerivedTypeSpec *derived) {
505   return IsBuiltinDerivedType(derived, "team_type");
506 }
507 
IsEventTypeOrLockType(const DerivedTypeSpec * derivedTypeSpec)508 bool IsEventTypeOrLockType(const DerivedTypeSpec *derivedTypeSpec) {
509   return IsBuiltinDerivedType(derivedTypeSpec, "event_type") ||
510       IsBuiltinDerivedType(derivedTypeSpec, "lock_type");
511 }
512 
IsOrContainsEventOrLockComponent(const Symbol & symbol)513 bool IsOrContainsEventOrLockComponent(const Symbol &symbol) {
514   if (const Symbol * root{GetAssociationRoot(symbol)}) {
515     if (const auto *details{root->detailsIf<ObjectEntityDetails>()}) {
516       if (const DeclTypeSpec * type{details->type()}) {
517         if (const DerivedTypeSpec * derived{type->AsDerived()}) {
518           return IsEventTypeOrLockType(derived) ||
519               FindEventOrLockPotentialComponent(*derived);
520         }
521       }
522     }
523   }
524   return false;
525 }
526 
527 // Check this symbol suitable as a type-bound procedure - C769
CanBeTypeBoundProc(const Symbol * symbol)528 bool CanBeTypeBoundProc(const Symbol *symbol) {
529   if (!symbol || IsDummy(*symbol) || IsProcedurePointer(*symbol)) {
530     return false;
531   } else if (symbol->has<SubprogramNameDetails>()) {
532     return symbol->owner().kind() == Scope::Kind::Module;
533   } else if (auto *details{symbol->detailsIf<SubprogramDetails>()}) {
534     return symbol->owner().kind() == Scope::Kind::Module ||
535         details->isInterface();
536   } else if (const auto *proc{symbol->detailsIf<ProcEntityDetails>()}) {
537     return !symbol->attrs().test(Attr::INTRINSIC) &&
538         proc->HasExplicitInterface();
539   } else {
540     return false;
541   }
542 }
543 
IsInitialized(const Symbol & symbol,bool ignoreDATAstatements,const Symbol * derivedTypeSymbol)544 bool IsInitialized(const Symbol &symbol, bool ignoreDATAstatements,
545     const Symbol *derivedTypeSymbol) {
546   if (!ignoreDATAstatements && symbol.test(Symbol::Flag::InDataStmt)) {
547     return true;
548   } else if (IsNamedConstant(symbol)) {
549     return false;
550   } else if (const auto *object{symbol.detailsIf<ObjectEntityDetails>()}) {
551     if (object->init()) {
552       return true;
553     } else if (object->isDummy() || IsFunctionResult(symbol)) {
554       return false;
555     } else if (IsAllocatable(symbol)) {
556       return true;
557     } else if (!IsPointer(symbol) && object->type()) {
558       if (const auto *derived{object->type()->AsDerived()}) {
559         if (&derived->typeSymbol() == derivedTypeSymbol) {
560           // error recovery: avoid infinite recursion on invalid
561           // recursive usage of a derived type
562         } else if (derived->HasDefaultInitialization()) {
563           return true;
564         }
565       }
566     }
567   } else if (const auto *proc{symbol.detailsIf<ProcEntityDetails>()}) {
568     return proc->init().has_value();
569   }
570   return false;
571 }
572 
HasIntrinsicTypeName(const Symbol & symbol)573 bool HasIntrinsicTypeName(const Symbol &symbol) {
574   std::string name{symbol.name().ToString()};
575   if (name == "doubleprecision") {
576     return true;
577   } else if (name == "derived") {
578     return false;
579   } else {
580     for (int i{0}; i != common::TypeCategory_enumSize; ++i) {
581       if (name == parser::ToLowerCaseLetters(EnumToString(TypeCategory{i}))) {
582         return true;
583       }
584     }
585     return false;
586   }
587 }
588 
IsSeparateModuleProcedureInterface(const Symbol * symbol)589 bool IsSeparateModuleProcedureInterface(const Symbol *symbol) {
590   if (symbol && symbol->attrs().test(Attr::MODULE)) {
591     if (auto *details{symbol->detailsIf<SubprogramDetails>()}) {
592       return details->isInterface();
593     }
594   }
595   return false;
596 }
597 
598 // 3.11 automatic data object
IsAutomatic(const Symbol & symbol)599 bool IsAutomatic(const Symbol &symbol) {
600   if (const auto *object{symbol.detailsIf<ObjectEntityDetails>()}) {
601     if (!object->isDummy() && !IsAllocatable(symbol) && !IsPointer(symbol)) {
602       if (const DeclTypeSpec * type{symbol.GetType()}) {
603         // If a type parameter value is not a constant expression, the
604         // object is automatic.
605         if (type->category() == DeclTypeSpec::Character) {
606           if (const auto &length{
607                   type->characterTypeSpec().length().GetExplicit()}) {
608             if (!evaluate::IsConstantExpr(*length)) {
609               return true;
610             }
611           }
612         } else if (const DerivedTypeSpec * derived{type->AsDerived()}) {
613           for (const auto &pair : derived->parameters()) {
614             if (const auto &value{pair.second.GetExplicit()}) {
615               if (!evaluate::IsConstantExpr(*value)) {
616                 return true;
617               }
618             }
619           }
620         }
621       }
622       // If an array bound is not a constant expression, the object is
623       // automatic.
624       for (const ShapeSpec &dim : object->shape()) {
625         if (const auto &lb{dim.lbound().GetExplicit()}) {
626           if (!evaluate::IsConstantExpr(*lb)) {
627             return true;
628           }
629         }
630         if (const auto &ub{dim.ubound().GetExplicit()}) {
631           if (!evaluate::IsConstantExpr(*ub)) {
632             return true;
633           }
634         }
635       }
636     }
637   }
638   return false;
639 }
640 
IsFinalizable(const Symbol & symbol)641 bool IsFinalizable(const Symbol &symbol) {
642   if (IsPointer(symbol)) {
643     return false;
644   }
645   if (const auto *object{symbol.detailsIf<ObjectEntityDetails>()}) {
646     if (object->isDummy() && !IsIntentOut(symbol)) {
647       return false;
648     }
649     const DeclTypeSpec *type{object->type()};
650     const DerivedTypeSpec *derived{type ? type->AsDerived() : nullptr};
651     return derived && IsFinalizable(*derived);
652   }
653   return false;
654 }
655 
IsFinalizable(const DerivedTypeSpec & derived)656 bool IsFinalizable(const DerivedTypeSpec &derived) {
657   if (!derived.typeSymbol().get<DerivedTypeDetails>().finals().empty()) {
658     return true;
659   }
660   DirectComponentIterator components{derived};
661   return bool{std::find_if(components.begin(), components.end(),
662       [](const Symbol &component) { return IsFinalizable(component); })};
663 }
664 
HasImpureFinal(const DerivedTypeSpec & derived)665 bool HasImpureFinal(const DerivedTypeSpec &derived) {
666   if (const auto *details{
667           derived.typeSymbol().detailsIf<DerivedTypeDetails>()}) {
668     const auto &finals{details->finals()};
669     return std::any_of(finals.begin(), finals.end(),
670         [](const auto &x) { return !x.second->attrs().test(Attr::PURE); });
671   } else {
672     return false;
673   }
674 }
675 
IsCoarray(const Symbol & symbol)676 bool IsCoarray(const Symbol &symbol) { return symbol.Corank() > 0; }
677 
IsAutomaticObject(const Symbol & symbol)678 bool IsAutomaticObject(const Symbol &symbol) {
679   if (IsDummy(symbol) || IsPointer(symbol) || IsAllocatable(symbol)) {
680     return false;
681   }
682   if (const DeclTypeSpec * type{symbol.GetType()}) {
683     if (type->category() == DeclTypeSpec::Character) {
684       ParamValue length{type->characterTypeSpec().length()};
685       if (length.isExplicit()) {
686         if (MaybeIntExpr lengthExpr{length.GetExplicit()}) {
687           if (!ToInt64(lengthExpr)) {
688             return true;
689           }
690         }
691       }
692     }
693   }
694   if (symbol.IsObjectArray()) {
695     for (const ShapeSpec &spec : symbol.get<ObjectEntityDetails>().shape()) {
696       auto &lbound{spec.lbound().GetExplicit()};
697       auto &ubound{spec.ubound().GetExplicit()};
698       if ((lbound && !evaluate::ToInt64(*lbound)) ||
699           (ubound && !evaluate::ToInt64(*ubound))) {
700         return true;
701       }
702     }
703   }
704   return false;
705 }
706 
IsAssumedLengthCharacter(const Symbol & symbol)707 bool IsAssumedLengthCharacter(const Symbol &symbol) {
708   if (const DeclTypeSpec * type{symbol.GetType()}) {
709     return type->category() == DeclTypeSpec::Character &&
710         type->characterTypeSpec().length().isAssumed();
711   } else {
712     return false;
713   }
714 }
715 
IsInBlankCommon(const Symbol & symbol)716 bool IsInBlankCommon(const Symbol &symbol) {
717   const Symbol *block{FindCommonBlockContaining(symbol)};
718   return block && block->name().empty();
719 }
720 
721 // C722 and C723:  For a function to be assumed length, it must be external and
722 // of CHARACTER type
IsExternal(const Symbol & symbol)723 bool IsExternal(const Symbol &symbol) {
724   return ClassifyProcedure(symbol) == ProcedureDefinitionClass::External;
725 }
726 
IsModuleProcedure(const Symbol & symbol)727 bool IsModuleProcedure(const Symbol &symbol) {
728   return ClassifyProcedure(symbol) == ProcedureDefinitionClass::Module;
729 }
IsExternalInPureContext(const Symbol & symbol,const Scope & scope)730 const Symbol *IsExternalInPureContext(
731     const Symbol &symbol, const Scope &scope) {
732   if (const auto *pureProc{FindPureProcedureContaining(scope)}) {
733     if (const Symbol * root{GetAssociationRoot(symbol)}) {
734       if (const Symbol *
735           visible{FindExternallyVisibleObject(*root, *pureProc)}) {
736         return visible;
737       }
738     }
739   }
740   return nullptr;
741 }
742 
FindPolymorphicPotentialComponent(const DerivedTypeSpec & derived)743 PotentialComponentIterator::const_iterator FindPolymorphicPotentialComponent(
744     const DerivedTypeSpec &derived) {
745   PotentialComponentIterator potentials{derived};
746   return std::find_if(
747       potentials.begin(), potentials.end(), [](const Symbol &component) {
748         if (const auto *details{component.detailsIf<ObjectEntityDetails>()}) {
749           const DeclTypeSpec *type{details->type()};
750           return type && type->IsPolymorphic();
751         }
752         return false;
753       });
754 }
755 
IsOrContainsPolymorphicComponent(const Symbol & symbol)756 bool IsOrContainsPolymorphicComponent(const Symbol &symbol) {
757   if (const Symbol * root{GetAssociationRoot(symbol)}) {
758     if (const auto *details{root->detailsIf<ObjectEntityDetails>()}) {
759       if (const DeclTypeSpec * type{details->type()}) {
760         if (type->IsPolymorphic()) {
761           return true;
762         }
763         if (const DerivedTypeSpec * derived{type->AsDerived()}) {
764           return (bool)FindPolymorphicPotentialComponent(*derived);
765         }
766       }
767     }
768   }
769   return false;
770 }
771 
InProtectedContext(const Symbol & symbol,const Scope & currentScope)772 bool InProtectedContext(const Symbol &symbol, const Scope &currentScope) {
773   return IsProtected(symbol) && !IsHostAssociated(symbol, currentScope);
774 }
775 
776 // C1101 and C1158
WhyNotModifiable(const Symbol & symbol,const Scope & scope)777 std::optional<parser::MessageFixedText> WhyNotModifiable(
778     const Symbol &symbol, const Scope &scope) {
779   const Symbol *root{GetAssociationRoot(symbol)};
780   if (!root) {
781     return "'%s' is construct associated with an expression"_en_US;
782   } else if (InProtectedContext(*root, scope)) {
783     return "'%s' is protected in this scope"_en_US;
784   } else if (IsExternalInPureContext(*root, scope)) {
785     return "'%s' is externally visible and referenced in a pure"
786            " procedure"_en_US;
787   } else if (IsOrContainsEventOrLockComponent(*root)) {
788     return "'%s' is an entity with either an EVENT_TYPE or LOCK_TYPE"_en_US;
789   } else if (IsIntentIn(*root)) {
790     return "'%s' is an INTENT(IN) dummy argument"_en_US;
791   } else if (!IsVariableName(*root)) {
792     return "'%s' is not a variable"_en_US;
793   } else {
794     return std::nullopt;
795   }
796 }
797 
WhyNotModifiable(parser::CharBlock at,const SomeExpr & expr,const Scope & scope,bool vectorSubscriptIsOk)798 std::optional<parser::Message> WhyNotModifiable(parser::CharBlock at,
799     const SomeExpr &expr, const Scope &scope, bool vectorSubscriptIsOk) {
800   if (!evaluate::IsVariable(expr)) {
801     return parser::Message{at, "Expression is not a variable"_en_US};
802   } else if (auto dataRef{evaluate::ExtractDataRef(expr, true)}) {
803     if (!vectorSubscriptIsOk && evaluate::HasVectorSubscript(expr)) {
804       return parser::Message{at, "Variable has a vector subscript"_en_US};
805     }
806     const Symbol &symbol{dataRef->GetFirstSymbol()};
807     if (auto maybeWhy{WhyNotModifiable(symbol, scope)}) {
808       return parser::Message{symbol.name(),
809           parser::MessageFormattedText{std::move(*maybeWhy), symbol.name()}};
810     }
811   } else {
812     // reference to function returning POINTER
813   }
814   return std::nullopt;
815 }
816 
817 class ImageControlStmtHelper {
818   using ImageControlStmts = std::variant<parser::ChangeTeamConstruct,
819       parser::CriticalConstruct, parser::EventPostStmt, parser::EventWaitStmt,
820       parser::FormTeamStmt, parser::LockStmt, parser::StopStmt,
821       parser::SyncAllStmt, parser::SyncImagesStmt, parser::SyncMemoryStmt,
822       parser::SyncTeamStmt, parser::UnlockStmt>;
823 
824 public:
operator ()(const T &)825   template <typename T> bool operator()(const T &) {
826     return common::HasMember<T, ImageControlStmts>;
827   }
operator ()(const common::Indirection<T> & x)828   template <typename T> bool operator()(const common::Indirection<T> &x) {
829     return (*this)(x.value());
830   }
operator ()(const parser::AllocateStmt & stmt)831   bool operator()(const parser::AllocateStmt &stmt) {
832     const auto &allocationList{std::get<std::list<parser::Allocation>>(stmt.t)};
833     for (const auto &allocation : allocationList) {
834       const auto &allocateObject{
835           std::get<parser::AllocateObject>(allocation.t)};
836       if (IsCoarrayObject(allocateObject)) {
837         return true;
838       }
839     }
840     return false;
841   }
operator ()(const parser::DeallocateStmt & stmt)842   bool operator()(const parser::DeallocateStmt &stmt) {
843     const auto &allocateObjectList{
844         std::get<std::list<parser::AllocateObject>>(stmt.t)};
845     for (const auto &allocateObject : allocateObjectList) {
846       if (IsCoarrayObject(allocateObject)) {
847         return true;
848       }
849     }
850     return false;
851   }
operator ()(const parser::CallStmt & stmt)852   bool operator()(const parser::CallStmt &stmt) {
853     const auto &procedureDesignator{
854         std::get<parser::ProcedureDesignator>(stmt.v.t)};
855     if (auto *name{std::get_if<parser::Name>(&procedureDesignator.u)}) {
856       // TODO: also ensure that the procedure is, in fact, an intrinsic
857       if (name->source == "move_alloc") {
858         const auto &args{std::get<std::list<parser::ActualArgSpec>>(stmt.v.t)};
859         if (!args.empty()) {
860           const parser::ActualArg &actualArg{
861               std::get<parser::ActualArg>(args.front().t)};
862           if (const auto *argExpr{
863                   std::get_if<common::Indirection<parser::Expr>>(
864                       &actualArg.u)}) {
865             return HasCoarray(argExpr->value());
866           }
867         }
868       }
869     }
870     return false;
871   }
operator ()(const parser::Statement<parser::ActionStmt> & stmt)872   bool operator()(const parser::Statement<parser::ActionStmt> &stmt) {
873     return std::visit(*this, stmt.statement.u);
874   }
875 
876 private:
IsCoarrayObject(const parser::AllocateObject & allocateObject)877   bool IsCoarrayObject(const parser::AllocateObject &allocateObject) {
878     const parser::Name &name{GetLastName(allocateObject)};
879     return name.symbol && IsCoarray(*name.symbol);
880   }
881 };
882 
IsImageControlStmt(const parser::ExecutableConstruct & construct)883 bool IsImageControlStmt(const parser::ExecutableConstruct &construct) {
884   return std::visit(ImageControlStmtHelper{}, construct.u);
885 }
886 
GetImageControlStmtCoarrayMsg(const parser::ExecutableConstruct & construct)887 std::optional<parser::MessageFixedText> GetImageControlStmtCoarrayMsg(
888     const parser::ExecutableConstruct &construct) {
889   if (const auto *actionStmt{
890           std::get_if<parser::Statement<parser::ActionStmt>>(&construct.u)}) {
891     return std::visit(
892         common::visitors{
893             [](const common::Indirection<parser::AllocateStmt> &)
894                 -> std::optional<parser::MessageFixedText> {
895               return "ALLOCATE of a coarray is an image control"
896                      " statement"_en_US;
897             },
898             [](const common::Indirection<parser::DeallocateStmt> &)
899                 -> std::optional<parser::MessageFixedText> {
900               return "DEALLOCATE of a coarray is an image control"
901                      " statement"_en_US;
902             },
903             [](const common::Indirection<parser::CallStmt> &)
904                 -> std::optional<parser::MessageFixedText> {
905               return "MOVE_ALLOC of a coarray is an image control"
906                      " statement "_en_US;
907             },
908             [](const auto &) -> std::optional<parser::MessageFixedText> {
909               return std::nullopt;
910             },
911         },
912         actionStmt->statement.u);
913   }
914   return std::nullopt;
915 }
916 
GetImageControlStmtLocation(const parser::ExecutableConstruct & executableConstruct)917 parser::CharBlock GetImageControlStmtLocation(
918     const parser::ExecutableConstruct &executableConstruct) {
919   return std::visit(
920       common::visitors{
921           [](const common::Indirection<parser::ChangeTeamConstruct>
922                   &construct) {
923             return std::get<parser::Statement<parser::ChangeTeamStmt>>(
924                 construct.value().t)
925                 .source;
926           },
927           [](const common::Indirection<parser::CriticalConstruct> &construct) {
928             return std::get<parser::Statement<parser::CriticalStmt>>(
929                 construct.value().t)
930                 .source;
931           },
932           [](const parser::Statement<parser::ActionStmt> &actionStmt) {
933             return actionStmt.source;
934           },
935           [](const auto &) { return parser::CharBlock{}; },
936       },
937       executableConstruct.u);
938 }
939 
HasCoarray(const parser::Expr & expression)940 bool HasCoarray(const parser::Expr &expression) {
941   if (const auto *expr{GetExpr(expression)}) {
942     for (const Symbol &symbol : evaluate::CollectSymbols(*expr)) {
943       if (const Symbol * root{GetAssociationRoot(symbol)}) {
944         if (IsCoarray(*root)) {
945           return true;
946         }
947       }
948     }
949   }
950   return false;
951 }
952 
IsPolymorphic(const Symbol & symbol)953 bool IsPolymorphic(const Symbol &symbol) {
954   if (const DeclTypeSpec * type{symbol.GetType()}) {
955     return type->IsPolymorphic();
956   }
957   return false;
958 }
959 
IsPolymorphicAllocatable(const Symbol & symbol)960 bool IsPolymorphicAllocatable(const Symbol &symbol) {
961   return IsAllocatable(symbol) && IsPolymorphic(symbol);
962 }
963 
CheckAccessibleComponent(const Scope & scope,const Symbol & symbol)964 std::optional<parser::MessageFormattedText> CheckAccessibleComponent(
965     const Scope &scope, const Symbol &symbol) {
966   CHECK(symbol.owner().IsDerivedType()); // symbol must be a component
967   if (symbol.attrs().test(Attr::PRIVATE)) {
968     if (const Scope * moduleScope{FindModuleContaining(symbol.owner())}) {
969       if (!moduleScope->Contains(scope)) {
970         return parser::MessageFormattedText{
971             "PRIVATE component '%s' is only accessible within module '%s'"_err_en_US,
972             symbol.name(), moduleScope->GetName().value()};
973       }
974     }
975   }
976   return std::nullopt;
977 }
978 
OrderParameterNames(const Symbol & typeSymbol)979 std::list<SourceName> OrderParameterNames(const Symbol &typeSymbol) {
980   std::list<SourceName> result;
981   if (const DerivedTypeSpec * spec{typeSymbol.GetParentTypeSpec()}) {
982     result = OrderParameterNames(spec->typeSymbol());
983   }
984   const auto &paramNames{typeSymbol.get<DerivedTypeDetails>().paramNames()};
985   result.insert(result.end(), paramNames.begin(), paramNames.end());
986   return result;
987 }
988 
OrderParameterDeclarations(const Symbol & typeSymbol)989 SymbolVector OrderParameterDeclarations(const Symbol &typeSymbol) {
990   SymbolVector result;
991   if (const DerivedTypeSpec * spec{typeSymbol.GetParentTypeSpec()}) {
992     result = OrderParameterDeclarations(spec->typeSymbol());
993   }
994   const auto &paramDecls{typeSymbol.get<DerivedTypeDetails>().paramDecls()};
995   result.insert(result.end(), paramDecls.begin(), paramDecls.end());
996   return result;
997 }
998 
FindOrInstantiateDerivedType(Scope & scope,DerivedTypeSpec && spec,SemanticsContext & semanticsContext,DeclTypeSpec::Category category)999 const DeclTypeSpec &FindOrInstantiateDerivedType(Scope &scope,
1000     DerivedTypeSpec &&spec, SemanticsContext &semanticsContext,
1001     DeclTypeSpec::Category category) {
1002   spec.EvaluateParameters(semanticsContext);
1003   if (const DeclTypeSpec *
1004       type{scope.FindInstantiatedDerivedType(spec, category)}) {
1005     return *type;
1006   }
1007   // Create a new instantiation of this parameterized derived type
1008   // for this particular distinct set of actual parameter values.
1009   DeclTypeSpec &type{scope.MakeDerivedType(category, std::move(spec))};
1010   type.derivedTypeSpec().Instantiate(scope, semanticsContext);
1011   return type;
1012 }
1013 
FindSeparateModuleSubprogramInterface(const Symbol * proc)1014 const Symbol *FindSeparateModuleSubprogramInterface(const Symbol *proc) {
1015   if (proc) {
1016     if (const Symbol * submodule{proc->owner().symbol()}) {
1017       if (const auto *details{submodule->detailsIf<ModuleDetails>()}) {
1018         if (const Scope * ancestor{details->ancestor()}) {
1019           const Symbol *iface{ancestor->FindSymbol(proc->name())};
1020           if (IsSeparateModuleProcedureInterface(iface)) {
1021             return iface;
1022           }
1023         }
1024       }
1025     }
1026   }
1027   return nullptr;
1028 }
1029 
ClassifyProcedure(const Symbol & symbol)1030 ProcedureDefinitionClass ClassifyProcedure(const Symbol &symbol) { // 15.2.2
1031   const Symbol &ultimate{symbol.GetUltimate()};
1032   if (ultimate.attrs().test(Attr::INTRINSIC)) {
1033     return ProcedureDefinitionClass::Intrinsic;
1034   } else if (ultimate.attrs().test(Attr::EXTERNAL)) {
1035     return ProcedureDefinitionClass::External;
1036   } else if (const auto *procDetails{ultimate.detailsIf<ProcEntityDetails>()}) {
1037     if (procDetails->isDummy()) {
1038       return ProcedureDefinitionClass::Dummy;
1039     } else if (IsPointer(ultimate)) {
1040       return ProcedureDefinitionClass::Pointer;
1041     }
1042   } else if (const Symbol * subp{FindSubprogram(symbol)}) {
1043     if (const auto *subpDetails{subp->detailsIf<SubprogramDetails>()}) {
1044       if (subpDetails->stmtFunction()) {
1045         return ProcedureDefinitionClass::StatementFunction;
1046       }
1047     }
1048     switch (ultimate.owner().kind()) {
1049     case Scope::Kind::Global:
1050       return ProcedureDefinitionClass::External;
1051     case Scope::Kind::Module:
1052       return ProcedureDefinitionClass::Module;
1053     case Scope::Kind::MainProgram:
1054     case Scope::Kind::Subprogram:
1055       return ProcedureDefinitionClass::Internal;
1056     default:
1057       break;
1058     }
1059   }
1060   return ProcedureDefinitionClass::None;
1061 }
1062 
1063 // ComponentIterator implementation
1064 
1065 template <ComponentKind componentKind>
1066 typename ComponentIterator<componentKind>::const_iterator
Create(const DerivedTypeSpec & derived)1067 ComponentIterator<componentKind>::const_iterator::Create(
1068     const DerivedTypeSpec &derived) {
1069   const_iterator it{};
1070   it.componentPath_.emplace_back(derived);
1071   it.Increment(); // cue up first relevant component, if any
1072   return it;
1073 }
1074 
1075 template <ComponentKind componentKind>
1076 const DerivedTypeSpec *
PlanComponentTraversal(const Symbol & component) const1077 ComponentIterator<componentKind>::const_iterator::PlanComponentTraversal(
1078     const Symbol &component) const {
1079   if (const auto *details{component.detailsIf<ObjectEntityDetails>()}) {
1080     if (const DeclTypeSpec * type{details->type()}) {
1081       if (const auto *derived{type->AsDerived()}) {
1082         bool traverse{false};
1083         if constexpr (componentKind == ComponentKind::Ordered) {
1084           // Order Component (only visit parents)
1085           traverse = component.test(Symbol::Flag::ParentComp);
1086         } else if constexpr (componentKind == ComponentKind::Direct) {
1087           traverse = !IsAllocatableOrPointer(component);
1088         } else if constexpr (componentKind == ComponentKind::Ultimate) {
1089           traverse = !IsAllocatableOrPointer(component);
1090         } else if constexpr (componentKind == ComponentKind::Potential) {
1091           traverse = !IsPointer(component);
1092         } else if constexpr (componentKind == ComponentKind::Scope) {
1093           traverse = !IsAllocatableOrPointer(component);
1094         }
1095         if (traverse) {
1096           const Symbol &newTypeSymbol{derived->typeSymbol()};
1097           // Avoid infinite loop if the type is already part of the types
1098           // being visited. It is possible to have "loops in type" because
1099           // C744 does not forbid to use not yet declared type for
1100           // ALLOCATABLE or POINTER components.
1101           for (const auto &node : componentPath_) {
1102             if (&newTypeSymbol == &node.GetTypeSymbol()) {
1103               return nullptr;
1104             }
1105           }
1106           return derived;
1107         }
1108       }
1109     } // intrinsic & unlimited polymorphic not traversable
1110   }
1111   return nullptr;
1112 }
1113 
1114 template <ComponentKind componentKind>
StopAtComponentPre(const Symbol & component)1115 static bool StopAtComponentPre(const Symbol &component) {
1116   if constexpr (componentKind == ComponentKind::Ordered) {
1117     // Parent components need to be iterated upon after their
1118     // sub-components in structure constructor analysis.
1119     return !component.test(Symbol::Flag::ParentComp);
1120   } else if constexpr (componentKind == ComponentKind::Direct) {
1121     return true;
1122   } else if constexpr (componentKind == ComponentKind::Ultimate) {
1123     return component.has<ProcEntityDetails>() ||
1124         IsAllocatableOrPointer(component) ||
1125         (component.get<ObjectEntityDetails>().type() &&
1126             component.get<ObjectEntityDetails>().type()->AsIntrinsic());
1127   } else if constexpr (componentKind == ComponentKind::Potential) {
1128     return !IsPointer(component);
1129   }
1130 }
1131 
1132 template <ComponentKind componentKind>
StopAtComponentPost(const Symbol & component)1133 static bool StopAtComponentPost(const Symbol &component) {
1134   return componentKind == ComponentKind::Ordered &&
1135       component.test(Symbol::Flag::ParentComp);
1136 }
1137 
1138 template <ComponentKind componentKind>
Increment()1139 void ComponentIterator<componentKind>::const_iterator::Increment() {
1140   while (!componentPath_.empty()) {
1141     ComponentPathNode &deepest{componentPath_.back()};
1142     if (deepest.component()) {
1143       if (!deepest.descended()) {
1144         deepest.set_descended(true);
1145         if (const DerivedTypeSpec *
1146             derived{PlanComponentTraversal(*deepest.component())}) {
1147           componentPath_.emplace_back(*derived);
1148           continue;
1149         }
1150       } else if (!deepest.visited()) {
1151         deepest.set_visited(true);
1152         return; // this is the next component to visit, after descending
1153       }
1154     }
1155     auto &nameIterator{deepest.nameIterator()};
1156     if (nameIterator == deepest.nameEnd()) {
1157       componentPath_.pop_back();
1158     } else if constexpr (componentKind == ComponentKind::Scope) {
1159       deepest.set_component(*nameIterator++->second);
1160       deepest.set_descended(false);
1161       deepest.set_visited(true);
1162       return; // this is the next component to visit, before descending
1163     } else {
1164       const Scope &scope{deepest.GetScope()};
1165       auto scopeIter{scope.find(*nameIterator++)};
1166       if (scopeIter != scope.cend()) {
1167         const Symbol &component{*scopeIter->second};
1168         deepest.set_component(component);
1169         deepest.set_descended(false);
1170         if (StopAtComponentPre<componentKind>(component)) {
1171           deepest.set_visited(true);
1172           return; // this is the next component to visit, before descending
1173         } else {
1174           deepest.set_visited(!StopAtComponentPost<componentKind>(component));
1175         }
1176       }
1177     }
1178   }
1179 }
1180 
1181 template <ComponentKind componentKind>
1182 std::string
BuildResultDesignatorName() const1183 ComponentIterator<componentKind>::const_iterator::BuildResultDesignatorName()
1184     const {
1185   std::string designator{""};
1186   for (const auto &node : componentPath_) {
1187     designator += "%" + DEREF(node.component()).name().ToString();
1188   }
1189   return designator;
1190 }
1191 
1192 template class ComponentIterator<ComponentKind::Ordered>;
1193 template class ComponentIterator<ComponentKind::Direct>;
1194 template class ComponentIterator<ComponentKind::Ultimate>;
1195 template class ComponentIterator<ComponentKind::Potential>;
1196 template class ComponentIterator<ComponentKind::Scope>;
1197 
FindCoarrayUltimateComponent(const DerivedTypeSpec & derived)1198 UltimateComponentIterator::const_iterator FindCoarrayUltimateComponent(
1199     const DerivedTypeSpec &derived) {
1200   UltimateComponentIterator ultimates{derived};
1201   return std::find_if(ultimates.begin(), ultimates.end(), IsCoarray);
1202 }
1203 
FindPointerUltimateComponent(const DerivedTypeSpec & derived)1204 UltimateComponentIterator::const_iterator FindPointerUltimateComponent(
1205     const DerivedTypeSpec &derived) {
1206   UltimateComponentIterator ultimates{derived};
1207   return std::find_if(ultimates.begin(), ultimates.end(), IsPointer);
1208 }
1209 
FindEventOrLockPotentialComponent(const DerivedTypeSpec & derived)1210 PotentialComponentIterator::const_iterator FindEventOrLockPotentialComponent(
1211     const DerivedTypeSpec &derived) {
1212   PotentialComponentIterator potentials{derived};
1213   return std::find_if(
1214       potentials.begin(), potentials.end(), [](const Symbol &component) {
1215         if (const auto *details{component.detailsIf<ObjectEntityDetails>()}) {
1216           const DeclTypeSpec *type{details->type()};
1217           return type && IsEventTypeOrLockType(type->AsDerived());
1218         }
1219         return false;
1220       });
1221 }
1222 
FindAllocatableUltimateComponent(const DerivedTypeSpec & derived)1223 UltimateComponentIterator::const_iterator FindAllocatableUltimateComponent(
1224     const DerivedTypeSpec &derived) {
1225   UltimateComponentIterator ultimates{derived};
1226   return std::find_if(ultimates.begin(), ultimates.end(), IsAllocatable);
1227 }
1228 
1229 UltimateComponentIterator::const_iterator
FindPolymorphicAllocatableUltimateComponent(const DerivedTypeSpec & derived)1230 FindPolymorphicAllocatableUltimateComponent(const DerivedTypeSpec &derived) {
1231   UltimateComponentIterator ultimates{derived};
1232   return std::find_if(
1233       ultimates.begin(), ultimates.end(), IsPolymorphicAllocatable);
1234 }
1235 
1236 UltimateComponentIterator::const_iterator
FindPolymorphicAllocatableNonCoarrayUltimateComponent(const DerivedTypeSpec & derived)1237 FindPolymorphicAllocatableNonCoarrayUltimateComponent(
1238     const DerivedTypeSpec &derived) {
1239   UltimateComponentIterator ultimates{derived};
1240   return std::find_if(ultimates.begin(), ultimates.end(), [](const Symbol &x) {
1241     return IsPolymorphicAllocatable(x) && !IsCoarray(x);
1242   });
1243 }
1244 
FindUltimateComponent(const DerivedTypeSpec & derived,const std::function<bool (const Symbol &)> & predicate)1245 const Symbol *FindUltimateComponent(const DerivedTypeSpec &derived,
1246     const std::function<bool(const Symbol &)> &predicate) {
1247   UltimateComponentIterator ultimates{derived};
1248   if (auto it{std::find_if(ultimates.begin(), ultimates.end(),
1249           [&predicate](const Symbol &component) -> bool {
1250             return predicate(component);
1251           })}) {
1252     return &*it;
1253   }
1254   return nullptr;
1255 }
1256 
FindUltimateComponent(const Symbol & symbol,const std::function<bool (const Symbol &)> & predicate)1257 const Symbol *FindUltimateComponent(const Symbol &symbol,
1258     const std::function<bool(const Symbol &)> &predicate) {
1259   if (predicate(symbol)) {
1260     return &symbol;
1261   } else if (const auto *object{symbol.detailsIf<ObjectEntityDetails>()}) {
1262     if (const auto *type{object->type()}) {
1263       if (const auto *derived{type->AsDerived()}) {
1264         return FindUltimateComponent(*derived, predicate);
1265       }
1266     }
1267   }
1268   return nullptr;
1269 }
1270 
FindImmediateComponent(const DerivedTypeSpec & type,const std::function<bool (const Symbol &)> & predicate)1271 const Symbol *FindImmediateComponent(const DerivedTypeSpec &type,
1272     const std::function<bool(const Symbol &)> &predicate) {
1273   if (const Scope * scope{type.scope()}) {
1274     const Symbol *parent{nullptr};
1275     for (const auto &pair : *scope) {
1276       const Symbol *symbol{&*pair.second};
1277       if (predicate(*symbol)) {
1278         return symbol;
1279       }
1280       if (symbol->test(Symbol::Flag::ParentComp)) {
1281         parent = symbol;
1282       }
1283     }
1284     if (parent) {
1285       if (const auto *object{parent->detailsIf<ObjectEntityDetails>()}) {
1286         if (const auto *type{object->type()}) {
1287           if (const auto *derived{type->AsDerived()}) {
1288             return FindImmediateComponent(*derived, predicate);
1289           }
1290         }
1291       }
1292     }
1293   }
1294   return nullptr;
1295 }
1296 
IsFunctionResultWithSameNameAsFunction(const Symbol & symbol)1297 bool IsFunctionResultWithSameNameAsFunction(const Symbol &symbol) {
1298   if (IsFunctionResult(symbol)) {
1299     if (const Symbol * function{symbol.owner().symbol()}) {
1300       return symbol.name() == function->name();
1301     }
1302   }
1303   return false;
1304 }
1305 
Post(const parser::GotoStmt & gotoStmt)1306 void LabelEnforce::Post(const parser::GotoStmt &gotoStmt) {
1307   checkLabelUse(gotoStmt.v);
1308 }
Post(const parser::ComputedGotoStmt & computedGotoStmt)1309 void LabelEnforce::Post(const parser::ComputedGotoStmt &computedGotoStmt) {
1310   for (auto &i : std::get<std::list<parser::Label>>(computedGotoStmt.t)) {
1311     checkLabelUse(i);
1312   }
1313 }
1314 
Post(const parser::ArithmeticIfStmt & arithmeticIfStmt)1315 void LabelEnforce::Post(const parser::ArithmeticIfStmt &arithmeticIfStmt) {
1316   checkLabelUse(std::get<1>(arithmeticIfStmt.t));
1317   checkLabelUse(std::get<2>(arithmeticIfStmt.t));
1318   checkLabelUse(std::get<3>(arithmeticIfStmt.t));
1319 }
1320 
Post(const parser::AssignStmt & assignStmt)1321 void LabelEnforce::Post(const parser::AssignStmt &assignStmt) {
1322   checkLabelUse(std::get<parser::Label>(assignStmt.t));
1323 }
1324 
Post(const parser::AssignedGotoStmt & assignedGotoStmt)1325 void LabelEnforce::Post(const parser::AssignedGotoStmt &assignedGotoStmt) {
1326   for (auto &i : std::get<std::list<parser::Label>>(assignedGotoStmt.t)) {
1327     checkLabelUse(i);
1328   }
1329 }
1330 
Post(const parser::AltReturnSpec & altReturnSpec)1331 void LabelEnforce::Post(const parser::AltReturnSpec &altReturnSpec) {
1332   checkLabelUse(altReturnSpec.v);
1333 }
1334 
Post(const parser::ErrLabel & errLabel)1335 void LabelEnforce::Post(const parser::ErrLabel &errLabel) {
1336   checkLabelUse(errLabel.v);
1337 }
Post(const parser::EndLabel & endLabel)1338 void LabelEnforce::Post(const parser::EndLabel &endLabel) {
1339   checkLabelUse(endLabel.v);
1340 }
Post(const parser::EorLabel & eorLabel)1341 void LabelEnforce::Post(const parser::EorLabel &eorLabel) {
1342   checkLabelUse(eorLabel.v);
1343 }
1344 
checkLabelUse(const parser::Label & labelUsed)1345 void LabelEnforce::checkLabelUse(const parser::Label &labelUsed) {
1346   if (labels_.find(labelUsed) == labels_.end()) {
1347     SayWithConstruct(context_, currentStatementSourcePosition_,
1348         parser::MessageFormattedText{
1349             "Control flow escapes from %s"_err_en_US, construct_},
1350         constructSourcePosition_);
1351   }
1352 }
1353 
GetEnclosingConstructMsg()1354 parser::MessageFormattedText LabelEnforce::GetEnclosingConstructMsg() {
1355   return {"Enclosing %s statement"_en_US, construct_};
1356 }
1357 
SayWithConstruct(SemanticsContext & context,parser::CharBlock stmtLocation,parser::MessageFormattedText && message,parser::CharBlock constructLocation)1358 void LabelEnforce::SayWithConstruct(SemanticsContext &context,
1359     parser::CharBlock stmtLocation, parser::MessageFormattedText &&message,
1360     parser::CharBlock constructLocation) {
1361   context.Say(stmtLocation, message)
1362       .Attach(constructLocation, GetEnclosingConstructMsg());
1363 }
1364 
HasAlternateReturns(const Symbol & subprogram)1365 bool HasAlternateReturns(const Symbol &subprogram) {
1366   for (const auto *dummyArg : subprogram.get<SubprogramDetails>().dummyArgs()) {
1367     if (!dummyArg) {
1368       return true;
1369     }
1370   }
1371   return false;
1372 }
1373 
InCommonBlock(const Symbol & symbol)1374 bool InCommonBlock(const Symbol &symbol) {
1375   const auto *details{symbol.detailsIf<ObjectEntityDetails>()};
1376   return details && details->commonBlock();
1377 }
1378 
MaybeGetNodeName(const ConstructNode & construct)1379 const std::optional<parser::Name> &MaybeGetNodeName(
1380     const ConstructNode &construct) {
1381   return std::visit(
1382       common::visitors{
1383           [&](const parser::BlockConstruct *blockConstruct)
1384               -> const std::optional<parser::Name> & {
1385             return std::get<0>(blockConstruct->t).statement.v;
1386           },
1387           [&](const auto *a) -> const std::optional<parser::Name> & {
1388             return std::get<0>(std::get<0>(a->t).statement.t);
1389           },
1390       },
1391       construct);
1392 }
1393 
1394 } // namespace Fortran::semantics
1395