//===-- SemaConcept.cpp - Semantic Analysis for Constraints and Concepts --===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements semantic analysis for C++ constraints and concepts. // //===----------------------------------------------------------------------===// #include "clang/Sema/SemaConcept.h" #include "clang/Sema/Sema.h" #include "clang/Sema/SemaInternal.h" #include "clang/Sema/SemaDiagnostic.h" #include "clang/Sema/TemplateDeduction.h" #include "clang/Sema/Template.h" #include "clang/Sema/Overload.h" #include "clang/Sema/Initialization.h" #include "clang/AST/ExprConcepts.h" #include "clang/AST/RecursiveASTVisitor.h" #include "clang/Basic/OperatorPrecedence.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/PointerUnion.h" #include "llvm/ADT/StringExtras.h" using namespace clang; using namespace sema; namespace { class LogicalBinOp { OverloadedOperatorKind Op = OO_None; const Expr *LHS = nullptr; const Expr *RHS = nullptr; public: LogicalBinOp(const Expr *E) { if (auto *BO = dyn_cast(E)) { Op = BinaryOperator::getOverloadedOperator(BO->getOpcode()); LHS = BO->getLHS(); RHS = BO->getRHS(); } else if (auto *OO = dyn_cast(E)) { // If OO is not || or && it might not have exactly 2 arguments. if (OO->getNumArgs() == 2) { Op = OO->getOperator(); LHS = OO->getArg(0); RHS = OO->getArg(1); } } } bool isAnd() const { return Op == OO_AmpAmp; } bool isOr() const { return Op == OO_PipePipe; } explicit operator bool() const { return isAnd() || isOr(); } const Expr *getLHS() const { return LHS; } const Expr *getRHS() const { return RHS; } }; } bool Sema::CheckConstraintExpression(const Expr *ConstraintExpression, Token NextToken, bool *PossibleNonPrimary, bool IsTrailingRequiresClause) { // C++2a [temp.constr.atomic]p1 // ..E shall be a constant expression of type bool. ConstraintExpression = ConstraintExpression->IgnoreParenImpCasts(); if (LogicalBinOp BO = ConstraintExpression) { return CheckConstraintExpression(BO.getLHS(), NextToken, PossibleNonPrimary) && CheckConstraintExpression(BO.getRHS(), NextToken, PossibleNonPrimary); } else if (auto *C = dyn_cast(ConstraintExpression)) return CheckConstraintExpression(C->getSubExpr(), NextToken, PossibleNonPrimary); QualType Type = ConstraintExpression->getType(); auto CheckForNonPrimary = [&] { if (PossibleNonPrimary) *PossibleNonPrimary = // We have the following case: // template requires func(0) struct S { }; // The user probably isn't aware of the parentheses required around // the function call, and we're only going to parse 'func' as the // primary-expression, and complain that it is of non-bool type. (NextToken.is(tok::l_paren) && (IsTrailingRequiresClause || (Type->isDependentType() && isa(ConstraintExpression)) || Type->isFunctionType() || Type->isSpecificBuiltinType(BuiltinType::Overload))) || // We have the following case: // template requires size_ == 0 struct S { }; // The user probably isn't aware of the parentheses required around // the binary operator, and we're only going to parse 'func' as the // first operand, and complain that it is of non-bool type. getBinOpPrecedence(NextToken.getKind(), /*GreaterThanIsOperator=*/true, getLangOpts().CPlusPlus11) > prec::LogicalAnd; }; // An atomic constraint! if (ConstraintExpression->isTypeDependent()) { CheckForNonPrimary(); return true; } if (!Context.hasSameUnqualifiedType(Type, Context.BoolTy)) { Diag(ConstraintExpression->getExprLoc(), diag::err_non_bool_atomic_constraint) << Type << ConstraintExpression->getSourceRange(); CheckForNonPrimary(); return false; } if (PossibleNonPrimary) *PossibleNonPrimary = false; return true; } template static bool calculateConstraintSatisfaction(Sema &S, const Expr *ConstraintExpr, ConstraintSatisfaction &Satisfaction, AtomicEvaluator &&Evaluator) { ConstraintExpr = ConstraintExpr->IgnoreParenImpCasts(); if (LogicalBinOp BO = ConstraintExpr) { if (calculateConstraintSatisfaction(S, BO.getLHS(), Satisfaction, Evaluator)) return true; bool IsLHSSatisfied = Satisfaction.IsSatisfied; if (BO.isOr() && IsLHSSatisfied) // [temp.constr.op] p3 // A disjunction is a constraint taking two operands. To determine if // a disjunction is satisfied, the satisfaction of the first operand // is checked. If that is satisfied, the disjunction is satisfied. // Otherwise, the disjunction is satisfied if and only if the second // operand is satisfied. return false; if (BO.isAnd() && !IsLHSSatisfied) // [temp.constr.op] p2 // A conjunction is a constraint taking two operands. To determine if // a conjunction is satisfied, the satisfaction of the first operand // is checked. If that is not satisfied, the conjunction is not // satisfied. Otherwise, the conjunction is satisfied if and only if // the second operand is satisfied. return false; return calculateConstraintSatisfaction( S, BO.getRHS(), Satisfaction, std::forward(Evaluator)); } else if (auto *C = dyn_cast(ConstraintExpr)) { return calculateConstraintSatisfaction(S, C->getSubExpr(), Satisfaction, std::forward(Evaluator)); } // An atomic constraint expression ExprResult SubstitutedAtomicExpr = Evaluator(ConstraintExpr); if (SubstitutedAtomicExpr.isInvalid()) return true; if (!SubstitutedAtomicExpr.isUsable()) // Evaluator has decided satisfaction without yielding an expression. return false; EnterExpressionEvaluationContext ConstantEvaluated( S, Sema::ExpressionEvaluationContext::ConstantEvaluated); SmallVector EvaluationDiags; Expr::EvalResult EvalResult; EvalResult.Diag = &EvaluationDiags; if (!SubstitutedAtomicExpr.get()->EvaluateAsConstantExpr(EvalResult, S.Context) || !EvaluationDiags.empty()) { // C++2a [temp.constr.atomic]p1 // ...E shall be a constant expression of type bool. S.Diag(SubstitutedAtomicExpr.get()->getBeginLoc(), diag::err_non_constant_constraint_expression) << SubstitutedAtomicExpr.get()->getSourceRange(); for (const PartialDiagnosticAt &PDiag : EvaluationDiags) S.Diag(PDiag.first, PDiag.second); return true; } assert(EvalResult.Val.isInt() && "evaluating bool expression didn't produce int"); Satisfaction.IsSatisfied = EvalResult.Val.getInt().getBoolValue(); if (!Satisfaction.IsSatisfied) Satisfaction.Details.emplace_back(ConstraintExpr, SubstitutedAtomicExpr.get()); return false; } static bool calculateConstraintSatisfaction( Sema &S, const NamedDecl *Template, ArrayRef TemplateArgs, SourceLocation TemplateNameLoc, MultiLevelTemplateArgumentList &MLTAL, const Expr *ConstraintExpr, ConstraintSatisfaction &Satisfaction) { return calculateConstraintSatisfaction( S, ConstraintExpr, Satisfaction, [&](const Expr *AtomicExpr) { EnterExpressionEvaluationContext ConstantEvaluated( S, Sema::ExpressionEvaluationContext::ConstantEvaluated); // Atomic constraint - substitute arguments and check satisfaction. ExprResult SubstitutedExpression; { TemplateDeductionInfo Info(TemplateNameLoc); Sema::InstantiatingTemplate Inst(S, AtomicExpr->getBeginLoc(), Sema::InstantiatingTemplate::ConstraintSubstitution{}, const_cast(Template), Info, AtomicExpr->getSourceRange()); if (Inst.isInvalid()) return ExprError(); // We do not want error diagnostics escaping here. Sema::SFINAETrap Trap(S); SubstitutedExpression = S.SubstExpr(const_cast(AtomicExpr), MLTAL); // Substitution might have stripped off a contextual conversion to // bool if this is the operand of an '&&' or '||'. For example, we // might lose an lvalue-to-rvalue conversion here. If so, put it back // before we try to evaluate. if (!SubstitutedExpression.isInvalid()) SubstitutedExpression = S.PerformContextuallyConvertToBool(SubstitutedExpression.get()); if (SubstitutedExpression.isInvalid() || Trap.hasErrorOccurred()) { // C++2a [temp.constr.atomic]p1 // ...If substitution results in an invalid type or expression, the // constraint is not satisfied. if (!Trap.hasErrorOccurred()) // A non-SFINAE error has occurred as a result of this // substitution. return ExprError(); PartialDiagnosticAt SubstDiag{SourceLocation(), PartialDiagnostic::NullDiagnostic()}; Info.takeSFINAEDiagnostic(SubstDiag); // FIXME: Concepts: This is an unfortunate consequence of there // being no serialization code for PartialDiagnostics and the fact // that serializing them would likely take a lot more storage than // just storing them as strings. We would still like, in the // future, to serialize the proper PartialDiagnostic as serializing // it as a string defeats the purpose of the diagnostic mechanism. SmallString<128> DiagString; DiagString = ": "; SubstDiag.second.EmitToString(S.getDiagnostics(), DiagString); unsigned MessageSize = DiagString.size(); char *Mem = new (S.Context) char[MessageSize]; memcpy(Mem, DiagString.c_str(), MessageSize); Satisfaction.Details.emplace_back( AtomicExpr, new (S.Context) ConstraintSatisfaction::SubstitutionDiagnostic{ SubstDiag.first, StringRef(Mem, MessageSize)}); Satisfaction.IsSatisfied = false; return ExprEmpty(); } } if (!S.CheckConstraintExpression(SubstitutedExpression.get())) return ExprError(); return SubstitutedExpression; }); } static bool CheckConstraintSatisfaction(Sema &S, const NamedDecl *Template, ArrayRef ConstraintExprs, ArrayRef TemplateArgs, SourceRange TemplateIDRange, ConstraintSatisfaction &Satisfaction) { if (ConstraintExprs.empty()) { Satisfaction.IsSatisfied = true; return false; } for (auto& Arg : TemplateArgs) if (Arg.isInstantiationDependent()) { // No need to check satisfaction for dependent constraint expressions. Satisfaction.IsSatisfied = true; return false; } Sema::InstantiatingTemplate Inst(S, TemplateIDRange.getBegin(), Sema::InstantiatingTemplate::ConstraintsCheck{}, const_cast(Template), TemplateArgs, TemplateIDRange); if (Inst.isInvalid()) return true; MultiLevelTemplateArgumentList MLTAL; MLTAL.addOuterTemplateArguments(TemplateArgs); for (const Expr *ConstraintExpr : ConstraintExprs) { if (calculateConstraintSatisfaction(S, Template, TemplateArgs, TemplateIDRange.getBegin(), MLTAL, ConstraintExpr, Satisfaction)) return true; if (!Satisfaction.IsSatisfied) // [temp.constr.op] p2 // [...] To determine if a conjunction is satisfied, the satisfaction // of the first operand is checked. If that is not satisfied, the // conjunction is not satisfied. [...] return false; } return false; } bool Sema::CheckConstraintSatisfaction( const NamedDecl *Template, ArrayRef ConstraintExprs, ArrayRef TemplateArgs, SourceRange TemplateIDRange, ConstraintSatisfaction &OutSatisfaction) { if (ConstraintExprs.empty()) { OutSatisfaction.IsSatisfied = true; return false; } if (!Template) { return ::CheckConstraintSatisfaction(*this, nullptr, ConstraintExprs, TemplateArgs, TemplateIDRange, OutSatisfaction); } llvm::FoldingSetNodeID ID; ConstraintSatisfaction::Profile(ID, Context, Template, TemplateArgs); void *InsertPos; if (auto *Cached = SatisfactionCache.FindNodeOrInsertPos(ID, InsertPos)) { OutSatisfaction = *Cached; return false; } auto Satisfaction = std::make_unique(Template, TemplateArgs); if (::CheckConstraintSatisfaction(*this, Template, ConstraintExprs, TemplateArgs, TemplateIDRange, *Satisfaction)) { return true; } OutSatisfaction = *Satisfaction; // We cannot use InsertPos here because CheckConstraintSatisfaction might have // invalidated it. // Note that entries of SatisfactionCache are deleted in Sema's destructor. SatisfactionCache.InsertNode(Satisfaction.release()); return false; } bool Sema::CheckConstraintSatisfaction(const Expr *ConstraintExpr, ConstraintSatisfaction &Satisfaction) { return calculateConstraintSatisfaction( *this, ConstraintExpr, Satisfaction, [this](const Expr *AtomicExpr) -> ExprResult { // We only do this to immitate lvalue-to-rvalue conversion. return PerformContextuallyConvertToBool(const_cast(AtomicExpr)); }); } bool Sema::CheckFunctionConstraints(const FunctionDecl *FD, ConstraintSatisfaction &Satisfaction, SourceLocation UsageLoc) { const Expr *RC = FD->getTrailingRequiresClause(); if (RC->isInstantiationDependent()) { Satisfaction.IsSatisfied = true; return false; } Qualifiers ThisQuals; CXXRecordDecl *Record = nullptr; if (auto *Method = dyn_cast(FD)) { ThisQuals = Method->getMethodQualifiers(); Record = const_cast(Method->getParent()); } CXXThisScopeRAII ThisScope(*this, Record, ThisQuals, Record != nullptr); // We substitute with empty arguments in order to rebuild the atomic // constraint in a constant-evaluated context. // FIXME: Should this be a dedicated TreeTransform? return CheckConstraintSatisfaction( FD, {RC}, /*TemplateArgs=*/{}, SourceRange(UsageLoc.isValid() ? UsageLoc : FD->getLocation()), Satisfaction); } bool Sema::EnsureTemplateArgumentListConstraints( TemplateDecl *TD, ArrayRef TemplateArgs, SourceRange TemplateIDRange) { ConstraintSatisfaction Satisfaction; llvm::SmallVector AssociatedConstraints; TD->getAssociatedConstraints(AssociatedConstraints); if (CheckConstraintSatisfaction(TD, AssociatedConstraints, TemplateArgs, TemplateIDRange, Satisfaction)) return true; if (!Satisfaction.IsSatisfied) { SmallString<128> TemplateArgString; TemplateArgString = " "; TemplateArgString += getTemplateArgumentBindingsText( TD->getTemplateParameters(), TemplateArgs.data(), TemplateArgs.size()); Diag(TemplateIDRange.getBegin(), diag::err_template_arg_list_constraints_not_satisfied) << (int)getTemplateNameKindForDiagnostics(TemplateName(TD)) << TD << TemplateArgString << TemplateIDRange; DiagnoseUnsatisfiedConstraint(Satisfaction); return true; } return false; } bool Sema::CheckInstantiatedFunctionTemplateConstraints( SourceLocation PointOfInstantiation, FunctionDecl *Decl, ArrayRef TemplateArgs, ConstraintSatisfaction &Satisfaction) { // In most cases we're not going to have constraints, so check for that first. FunctionTemplateDecl *Template = Decl->getPrimaryTemplate(); // Note - code synthesis context for the constraints check is created // inside CheckConstraintsSatisfaction. SmallVector TemplateAC; Template->getAssociatedConstraints(TemplateAC); if (TemplateAC.empty()) { Satisfaction.IsSatisfied = true; return false; } // Enter the scope of this instantiation. We don't use // PushDeclContext because we don't have a scope. Sema::ContextRAII savedContext(*this, Decl); LocalInstantiationScope Scope(*this); // If this is not an explicit specialization - we need to get the instantiated // version of the template arguments and add them to scope for the // substitution. if (Decl->isTemplateInstantiation()) { InstantiatingTemplate Inst(*this, Decl->getPointOfInstantiation(), InstantiatingTemplate::ConstraintsCheck{}, Decl->getPrimaryTemplate(), TemplateArgs, SourceRange()); if (Inst.isInvalid()) return true; MultiLevelTemplateArgumentList MLTAL( *Decl->getTemplateSpecializationArgs()); if (addInstantiatedParametersToScope( Decl, Decl->getPrimaryTemplate()->getTemplatedDecl(), Scope, MLTAL)) return true; } Qualifiers ThisQuals; CXXRecordDecl *Record = nullptr; if (auto *Method = dyn_cast(Decl)) { ThisQuals = Method->getMethodQualifiers(); Record = Method->getParent(); } CXXThisScopeRAII ThisScope(*this, Record, ThisQuals, Record != nullptr); return CheckConstraintSatisfaction(Template, TemplateAC, TemplateArgs, PointOfInstantiation, Satisfaction); } static void diagnoseUnsatisfiedRequirement(Sema &S, concepts::ExprRequirement *Req, bool First) { assert(!Req->isSatisfied() && "Diagnose() can only be used on an unsatisfied requirement"); switch (Req->getSatisfactionStatus()) { case concepts::ExprRequirement::SS_Dependent: llvm_unreachable("Diagnosing a dependent requirement"); break; case concepts::ExprRequirement::SS_ExprSubstitutionFailure: { auto *SubstDiag = Req->getExprSubstitutionDiagnostic(); if (!SubstDiag->DiagMessage.empty()) S.Diag(SubstDiag->DiagLoc, diag::note_expr_requirement_expr_substitution_error) << (int)First << SubstDiag->SubstitutedEntity << SubstDiag->DiagMessage; else S.Diag(SubstDiag->DiagLoc, diag::note_expr_requirement_expr_unknown_substitution_error) << (int)First << SubstDiag->SubstitutedEntity; break; } case concepts::ExprRequirement::SS_NoexceptNotMet: S.Diag(Req->getNoexceptLoc(), diag::note_expr_requirement_noexcept_not_met) << (int)First << Req->getExpr(); break; case concepts::ExprRequirement::SS_TypeRequirementSubstitutionFailure: { auto *SubstDiag = Req->getReturnTypeRequirement().getSubstitutionDiagnostic(); if (!SubstDiag->DiagMessage.empty()) S.Diag(SubstDiag->DiagLoc, diag::note_expr_requirement_type_requirement_substitution_error) << (int)First << SubstDiag->SubstitutedEntity << SubstDiag->DiagMessage; else S.Diag(SubstDiag->DiagLoc, diag::note_expr_requirement_type_requirement_unknown_substitution_error) << (int)First << SubstDiag->SubstitutedEntity; break; } case concepts::ExprRequirement::SS_ConstraintsNotSatisfied: { ConceptSpecializationExpr *ConstraintExpr = Req->getReturnTypeRequirementSubstitutedConstraintExpr(); if (ConstraintExpr->getTemplateArgsAsWritten()->NumTemplateArgs == 1) { // A simple case - expr type is the type being constrained and the concept // was not provided arguments. Expr *e = Req->getExpr(); S.Diag(e->getBeginLoc(), diag::note_expr_requirement_constraints_not_satisfied_simple) << (int)First << S.Context.getReferenceQualifiedType(e) << ConstraintExpr->getNamedConcept(); } else { S.Diag(ConstraintExpr->getBeginLoc(), diag::note_expr_requirement_constraints_not_satisfied) << (int)First << ConstraintExpr; } S.DiagnoseUnsatisfiedConstraint(ConstraintExpr->getSatisfaction()); break; } case concepts::ExprRequirement::SS_Satisfied: llvm_unreachable("We checked this above"); } } static void diagnoseUnsatisfiedRequirement(Sema &S, concepts::TypeRequirement *Req, bool First) { assert(!Req->isSatisfied() && "Diagnose() can only be used on an unsatisfied requirement"); switch (Req->getSatisfactionStatus()) { case concepts::TypeRequirement::SS_Dependent: llvm_unreachable("Diagnosing a dependent requirement"); return; case concepts::TypeRequirement::SS_SubstitutionFailure: { auto *SubstDiag = Req->getSubstitutionDiagnostic(); if (!SubstDiag->DiagMessage.empty()) S.Diag(SubstDiag->DiagLoc, diag::note_type_requirement_substitution_error) << (int)First << SubstDiag->SubstitutedEntity << SubstDiag->DiagMessage; else S.Diag(SubstDiag->DiagLoc, diag::note_type_requirement_unknown_substitution_error) << (int)First << SubstDiag->SubstitutedEntity; return; } default: llvm_unreachable("Unknown satisfaction status"); return; } } static void diagnoseUnsatisfiedRequirement(Sema &S, concepts::NestedRequirement *Req, bool First) { if (Req->isSubstitutionFailure()) { concepts::Requirement::SubstitutionDiagnostic *SubstDiag = Req->getSubstitutionDiagnostic(); if (!SubstDiag->DiagMessage.empty()) S.Diag(SubstDiag->DiagLoc, diag::note_nested_requirement_substitution_error) << (int)First << SubstDiag->SubstitutedEntity << SubstDiag->DiagMessage; else S.Diag(SubstDiag->DiagLoc, diag::note_nested_requirement_unknown_substitution_error) << (int)First << SubstDiag->SubstitutedEntity; return; } S.DiagnoseUnsatisfiedConstraint(Req->getConstraintSatisfaction(), First); } static void diagnoseWellFormedUnsatisfiedConstraintExpr(Sema &S, Expr *SubstExpr, bool First = true) { SubstExpr = SubstExpr->IgnoreParenImpCasts(); if (BinaryOperator *BO = dyn_cast(SubstExpr)) { switch (BO->getOpcode()) { // These two cases will in practice only be reached when using fold // expressions with || and &&, since otherwise the || and && will have been // broken down into atomic constraints during satisfaction checking. case BO_LOr: // Or evaluated to false - meaning both RHS and LHS evaluated to false. diagnoseWellFormedUnsatisfiedConstraintExpr(S, BO->getLHS(), First); diagnoseWellFormedUnsatisfiedConstraintExpr(S, BO->getRHS(), /*First=*/false); return; case BO_LAnd: { bool LHSSatisfied = BO->getLHS()->EvaluateKnownConstInt(S.Context).getBoolValue(); if (LHSSatisfied) { // LHS is true, so RHS must be false. diagnoseWellFormedUnsatisfiedConstraintExpr(S, BO->getRHS(), First); return; } // LHS is false diagnoseWellFormedUnsatisfiedConstraintExpr(S, BO->getLHS(), First); // RHS might also be false bool RHSSatisfied = BO->getRHS()->EvaluateKnownConstInt(S.Context).getBoolValue(); if (!RHSSatisfied) diagnoseWellFormedUnsatisfiedConstraintExpr(S, BO->getRHS(), /*First=*/false); return; } case BO_GE: case BO_LE: case BO_GT: case BO_LT: case BO_EQ: case BO_NE: if (BO->getLHS()->getType()->isIntegerType() && BO->getRHS()->getType()->isIntegerType()) { Expr::EvalResult SimplifiedLHS; Expr::EvalResult SimplifiedRHS; BO->getLHS()->EvaluateAsInt(SimplifiedLHS, S.Context, Expr::SE_NoSideEffects, /*InConstantContext=*/true); BO->getRHS()->EvaluateAsInt(SimplifiedRHS, S.Context, Expr::SE_NoSideEffects, /*InConstantContext=*/true); if (!SimplifiedLHS.Diag && ! SimplifiedRHS.Diag) { S.Diag(SubstExpr->getBeginLoc(), diag::note_atomic_constraint_evaluated_to_false_elaborated) << (int)First << SubstExpr << toString(SimplifiedLHS.Val.getInt(), 10) << BinaryOperator::getOpcodeStr(BO->getOpcode()) << toString(SimplifiedRHS.Val.getInt(), 10); return; } } break; default: break; } } else if (auto *CSE = dyn_cast(SubstExpr)) { if (CSE->getTemplateArgsAsWritten()->NumTemplateArgs == 1) { S.Diag( CSE->getSourceRange().getBegin(), diag:: note_single_arg_concept_specialization_constraint_evaluated_to_false) << (int)First << CSE->getTemplateArgsAsWritten()->arguments()[0].getArgument() << CSE->getNamedConcept(); } else { S.Diag(SubstExpr->getSourceRange().getBegin(), diag::note_concept_specialization_constraint_evaluated_to_false) << (int)First << CSE; } S.DiagnoseUnsatisfiedConstraint(CSE->getSatisfaction()); return; } else if (auto *RE = dyn_cast(SubstExpr)) { for (concepts::Requirement *Req : RE->getRequirements()) if (!Req->isDependent() && !Req->isSatisfied()) { if (auto *E = dyn_cast(Req)) diagnoseUnsatisfiedRequirement(S, E, First); else if (auto *T = dyn_cast(Req)) diagnoseUnsatisfiedRequirement(S, T, First); else diagnoseUnsatisfiedRequirement( S, cast(Req), First); break; } return; } S.Diag(SubstExpr->getSourceRange().getBegin(), diag::note_atomic_constraint_evaluated_to_false) << (int)First << SubstExpr; } template static void diagnoseUnsatisfiedConstraintExpr( Sema &S, const Expr *E, const llvm::PointerUnion &Record, bool First = true) { if (auto *Diag = Record.template dyn_cast()){ S.Diag(Diag->first, diag::note_substituted_constraint_expr_is_ill_formed) << Diag->second; return; } diagnoseWellFormedUnsatisfiedConstraintExpr(S, Record.template get(), First); } void Sema::DiagnoseUnsatisfiedConstraint(const ConstraintSatisfaction& Satisfaction, bool First) { assert(!Satisfaction.IsSatisfied && "Attempted to diagnose a satisfied constraint"); for (auto &Pair : Satisfaction.Details) { diagnoseUnsatisfiedConstraintExpr(*this, Pair.first, Pair.second, First); First = false; } } void Sema::DiagnoseUnsatisfiedConstraint( const ASTConstraintSatisfaction &Satisfaction, bool First) { assert(!Satisfaction.IsSatisfied && "Attempted to diagnose a satisfied constraint"); for (auto &Pair : Satisfaction) { diagnoseUnsatisfiedConstraintExpr(*this, Pair.first, Pair.second, First); First = false; } } const NormalizedConstraint * Sema::getNormalizedAssociatedConstraints( NamedDecl *ConstrainedDecl, ArrayRef AssociatedConstraints) { auto CacheEntry = NormalizationCache.find(ConstrainedDecl); if (CacheEntry == NormalizationCache.end()) { auto Normalized = NormalizedConstraint::fromConstraintExprs(*this, ConstrainedDecl, AssociatedConstraints); CacheEntry = NormalizationCache .try_emplace(ConstrainedDecl, Normalized ? new (Context) NormalizedConstraint( std::move(*Normalized)) : nullptr) .first; } return CacheEntry->second; } static bool substituteParameterMappings(Sema &S, NormalizedConstraint &N, ConceptDecl *Concept, ArrayRef TemplateArgs, const ASTTemplateArgumentListInfo *ArgsAsWritten) { if (!N.isAtomic()) { if (substituteParameterMappings(S, N.getLHS(), Concept, TemplateArgs, ArgsAsWritten)) return true; return substituteParameterMappings(S, N.getRHS(), Concept, TemplateArgs, ArgsAsWritten); } TemplateParameterList *TemplateParams = Concept->getTemplateParameters(); AtomicConstraint &Atomic = *N.getAtomicConstraint(); TemplateArgumentListInfo SubstArgs; MultiLevelTemplateArgumentList MLTAL; MLTAL.addOuterTemplateArguments(TemplateArgs); if (!Atomic.ParameterMapping) { llvm::SmallBitVector OccurringIndices(TemplateParams->size()); S.MarkUsedTemplateParameters(Atomic.ConstraintExpr, /*OnlyDeduced=*/false, /*Depth=*/0, OccurringIndices); Atomic.ParameterMapping.emplace( MutableArrayRef( new (S.Context) TemplateArgumentLoc[OccurringIndices.count()], OccurringIndices.count())); for (unsigned I = 0, J = 0, C = TemplateParams->size(); I != C; ++I) if (OccurringIndices[I]) new (&(*Atomic.ParameterMapping)[J++]) TemplateArgumentLoc( S.getIdentityTemplateArgumentLoc(TemplateParams->begin()[I], // Here we assume we do not support things like // template // concept C = ...; // // template requires C // struct S { }; // The above currently yields a diagnostic. // We still might have default arguments for concept parameters. ArgsAsWritten->NumTemplateArgs > I ? ArgsAsWritten->arguments()[I].getLocation() : SourceLocation())); } Sema::InstantiatingTemplate Inst( S, ArgsAsWritten->arguments().front().getSourceRange().getBegin(), Sema::InstantiatingTemplate::ParameterMappingSubstitution{}, Concept, SourceRange(ArgsAsWritten->arguments()[0].getSourceRange().getBegin(), ArgsAsWritten->arguments().back().getSourceRange().getEnd())); if (S.SubstTemplateArguments(*Atomic.ParameterMapping, MLTAL, SubstArgs)) return true; Atomic.ParameterMapping.emplace( MutableArrayRef( new (S.Context) TemplateArgumentLoc[SubstArgs.size()], SubstArgs.size())); std::copy(SubstArgs.arguments().begin(), SubstArgs.arguments().end(), N.getAtomicConstraint()->ParameterMapping->begin()); return false; } Optional NormalizedConstraint::fromConstraintExprs(Sema &S, NamedDecl *D, ArrayRef E) { assert(E.size() != 0); auto Conjunction = fromConstraintExpr(S, D, E[0]); if (!Conjunction) return None; for (unsigned I = 1; I < E.size(); ++I) { auto Next = fromConstraintExpr(S, D, E[I]); if (!Next) return None; *Conjunction = NormalizedConstraint(S.Context, std::move(*Conjunction), std::move(*Next), CCK_Conjunction); } return Conjunction; } llvm::Optional NormalizedConstraint::fromConstraintExpr(Sema &S, NamedDecl *D, const Expr *E) { assert(E != nullptr); // C++ [temp.constr.normal]p1.1 // [...] // - The normal form of an expression (E) is the normal form of E. // [...] E = E->IgnoreParenImpCasts(); if (LogicalBinOp BO = E) { auto LHS = fromConstraintExpr(S, D, BO.getLHS()); if (!LHS) return None; auto RHS = fromConstraintExpr(S, D, BO.getRHS()); if (!RHS) return None; return NormalizedConstraint(S.Context, std::move(*LHS), std::move(*RHS), BO.isAnd() ? CCK_Conjunction : CCK_Disjunction); } else if (auto *CSE = dyn_cast(E)) { const NormalizedConstraint *SubNF; { Sema::InstantiatingTemplate Inst( S, CSE->getExprLoc(), Sema::InstantiatingTemplate::ConstraintNormalization{}, D, CSE->getSourceRange()); // C++ [temp.constr.normal]p1.1 // [...] // The normal form of an id-expression of the form C, // where C names a concept, is the normal form of the // constraint-expression of C, after substituting A1, A2, ..., AN for C’s // respective template parameters in the parameter mappings in each atomic // constraint. If any such substitution results in an invalid type or // expression, the program is ill-formed; no diagnostic is required. // [...] ConceptDecl *CD = CSE->getNamedConcept(); SubNF = S.getNormalizedAssociatedConstraints(CD, {CD->getConstraintExpr()}); if (!SubNF) return None; } Optional New; New.emplace(S.Context, *SubNF); if (substituteParameterMappings( S, *New, CSE->getNamedConcept(), CSE->getTemplateArguments(), CSE->getTemplateArgsAsWritten())) return None; return New; } return NormalizedConstraint{new (S.Context) AtomicConstraint(S, E)}; } using NormalForm = llvm::SmallVector, 4>; static NormalForm makeCNF(const NormalizedConstraint &Normalized) { if (Normalized.isAtomic()) return {{Normalized.getAtomicConstraint()}}; NormalForm LCNF = makeCNF(Normalized.getLHS()); NormalForm RCNF = makeCNF(Normalized.getRHS()); if (Normalized.getCompoundKind() == NormalizedConstraint::CCK_Conjunction) { LCNF.reserve(LCNF.size() + RCNF.size()); while (!RCNF.empty()) LCNF.push_back(RCNF.pop_back_val()); return LCNF; } // Disjunction NormalForm Res; Res.reserve(LCNF.size() * RCNF.size()); for (auto &LDisjunction : LCNF) for (auto &RDisjunction : RCNF) { NormalForm::value_type Combined; Combined.reserve(LDisjunction.size() + RDisjunction.size()); std::copy(LDisjunction.begin(), LDisjunction.end(), std::back_inserter(Combined)); std::copy(RDisjunction.begin(), RDisjunction.end(), std::back_inserter(Combined)); Res.emplace_back(Combined); } return Res; } static NormalForm makeDNF(const NormalizedConstraint &Normalized) { if (Normalized.isAtomic()) return {{Normalized.getAtomicConstraint()}}; NormalForm LDNF = makeDNF(Normalized.getLHS()); NormalForm RDNF = makeDNF(Normalized.getRHS()); if (Normalized.getCompoundKind() == NormalizedConstraint::CCK_Disjunction) { LDNF.reserve(LDNF.size() + RDNF.size()); while (!RDNF.empty()) LDNF.push_back(RDNF.pop_back_val()); return LDNF; } // Conjunction NormalForm Res; Res.reserve(LDNF.size() * RDNF.size()); for (auto &LConjunction : LDNF) { for (auto &RConjunction : RDNF) { NormalForm::value_type Combined; Combined.reserve(LConjunction.size() + RConjunction.size()); std::copy(LConjunction.begin(), LConjunction.end(), std::back_inserter(Combined)); std::copy(RConjunction.begin(), RConjunction.end(), std::back_inserter(Combined)); Res.emplace_back(Combined); } } return Res; } template static bool subsumes(NormalForm PDNF, NormalForm QCNF, AtomicSubsumptionEvaluator E) { // C++ [temp.constr.order] p2 // Then, P subsumes Q if and only if, for every disjunctive clause Pi in the // disjunctive normal form of P, Pi subsumes every conjunctive clause Qj in // the conjuctive normal form of Q, where [...] for (const auto &Pi : PDNF) { for (const auto &Qj : QCNF) { // C++ [temp.constr.order] p2 // - [...] a disjunctive clause Pi subsumes a conjunctive clause Qj if // and only if there exists an atomic constraint Pia in Pi for which // there exists an atomic constraint, Qjb, in Qj such that Pia // subsumes Qjb. bool Found = false; for (const AtomicConstraint *Pia : Pi) { for (const AtomicConstraint *Qjb : Qj) { if (E(*Pia, *Qjb)) { Found = true; break; } } if (Found) break; } if (!Found) return false; } } return true; } template static bool subsumes(Sema &S, NamedDecl *DP, ArrayRef P, NamedDecl *DQ, ArrayRef Q, bool &Subsumes, AtomicSubsumptionEvaluator E) { // C++ [temp.constr.order] p2 // In order to determine if a constraint P subsumes a constraint Q, P is // transformed into disjunctive normal form, and Q is transformed into // conjunctive normal form. [...] auto *PNormalized = S.getNormalizedAssociatedConstraints(DP, P); if (!PNormalized) return true; const NormalForm PDNF = makeDNF(*PNormalized); auto *QNormalized = S.getNormalizedAssociatedConstraints(DQ, Q); if (!QNormalized) return true; const NormalForm QCNF = makeCNF(*QNormalized); Subsumes = subsumes(PDNF, QCNF, E); return false; } bool Sema::IsAtLeastAsConstrained(NamedDecl *D1, ArrayRef AC1, NamedDecl *D2, ArrayRef AC2, bool &Result) { if (AC1.empty()) { Result = AC2.empty(); return false; } if (AC2.empty()) { // TD1 has associated constraints and TD2 does not. Result = true; return false; } std::pair Key{D1, D2}; auto CacheEntry = SubsumptionCache.find(Key); if (CacheEntry != SubsumptionCache.end()) { Result = CacheEntry->second; return false; } if (subsumes(*this, D1, AC1, D2, AC2, Result, [this] (const AtomicConstraint &A, const AtomicConstraint &B) { return A.subsumes(Context, B); })) return true; SubsumptionCache.try_emplace(Key, Result); return false; } bool Sema::MaybeEmitAmbiguousAtomicConstraintsDiagnostic(NamedDecl *D1, ArrayRef AC1, NamedDecl *D2, ArrayRef AC2) { if (isSFINAEContext()) // No need to work here because our notes would be discarded. return false; if (AC1.empty() || AC2.empty()) return false; auto NormalExprEvaluator = [this] (const AtomicConstraint &A, const AtomicConstraint &B) { return A.subsumes(Context, B); }; const Expr *AmbiguousAtomic1 = nullptr, *AmbiguousAtomic2 = nullptr; auto IdenticalExprEvaluator = [&] (const AtomicConstraint &A, const AtomicConstraint &B) { if (!A.hasMatchingParameterMapping(Context, B)) return false; const Expr *EA = A.ConstraintExpr, *EB = B.ConstraintExpr; if (EA == EB) return true; // Not the same source level expression - are the expressions // identical? llvm::FoldingSetNodeID IDA, IDB; EA->Profile(IDA, Context, /*Canonical=*/true); EB->Profile(IDB, Context, /*Canonical=*/true); if (IDA != IDB) return false; AmbiguousAtomic1 = EA; AmbiguousAtomic2 = EB; return true; }; { // The subsumption checks might cause diagnostics SFINAETrap Trap(*this); auto *Normalized1 = getNormalizedAssociatedConstraints(D1, AC1); if (!Normalized1) return false; const NormalForm DNF1 = makeDNF(*Normalized1); const NormalForm CNF1 = makeCNF(*Normalized1); auto *Normalized2 = getNormalizedAssociatedConstraints(D2, AC2); if (!Normalized2) return false; const NormalForm DNF2 = makeDNF(*Normalized2); const NormalForm CNF2 = makeCNF(*Normalized2); bool Is1AtLeastAs2Normally = subsumes(DNF1, CNF2, NormalExprEvaluator); bool Is2AtLeastAs1Normally = subsumes(DNF2, CNF1, NormalExprEvaluator); bool Is1AtLeastAs2 = subsumes(DNF1, CNF2, IdenticalExprEvaluator); bool Is2AtLeastAs1 = subsumes(DNF2, CNF1, IdenticalExprEvaluator); if (Is1AtLeastAs2 == Is1AtLeastAs2Normally && Is2AtLeastAs1 == Is2AtLeastAs1Normally) // Same result - no ambiguity was caused by identical atomic expressions. return false; } // A different result! Some ambiguous atomic constraint(s) caused a difference assert(AmbiguousAtomic1 && AmbiguousAtomic2); Diag(AmbiguousAtomic1->getBeginLoc(), diag::note_ambiguous_atomic_constraints) << AmbiguousAtomic1->getSourceRange(); Diag(AmbiguousAtomic2->getBeginLoc(), diag::note_ambiguous_atomic_constraints_similar_expression) << AmbiguousAtomic2->getSourceRange(); return true; } concepts::ExprRequirement::ExprRequirement( Expr *E, bool IsSimple, SourceLocation NoexceptLoc, ReturnTypeRequirement Req, SatisfactionStatus Status, ConceptSpecializationExpr *SubstitutedConstraintExpr) : Requirement(IsSimple ? RK_Simple : RK_Compound, Status == SS_Dependent, Status == SS_Dependent && (E->containsUnexpandedParameterPack() || Req.containsUnexpandedParameterPack()), Status == SS_Satisfied), Value(E), NoexceptLoc(NoexceptLoc), TypeReq(Req), SubstitutedConstraintExpr(SubstitutedConstraintExpr), Status(Status) { assert((!IsSimple || (Req.isEmpty() && NoexceptLoc.isInvalid())) && "Simple requirement must not have a return type requirement or a " "noexcept specification"); assert((Status > SS_TypeRequirementSubstitutionFailure && Req.isTypeConstraint()) == (SubstitutedConstraintExpr != nullptr)); } concepts::ExprRequirement::ExprRequirement( SubstitutionDiagnostic *ExprSubstDiag, bool IsSimple, SourceLocation NoexceptLoc, ReturnTypeRequirement Req) : Requirement(IsSimple ? RK_Simple : RK_Compound, Req.isDependent(), Req.containsUnexpandedParameterPack(), /*IsSatisfied=*/false), Value(ExprSubstDiag), NoexceptLoc(NoexceptLoc), TypeReq(Req), Status(SS_ExprSubstitutionFailure) { assert((!IsSimple || (Req.isEmpty() && NoexceptLoc.isInvalid())) && "Simple requirement must not have a return type requirement or a " "noexcept specification"); } concepts::ExprRequirement::ReturnTypeRequirement:: ReturnTypeRequirement(TemplateParameterList *TPL) : TypeConstraintInfo(TPL, false) { assert(TPL->size() == 1); const TypeConstraint *TC = cast(TPL->getParam(0))->getTypeConstraint(); assert(TC && "TPL must have a template type parameter with a type constraint"); auto *Constraint = cast(TC->getImmediatelyDeclaredConstraint()); bool Dependent = Constraint->getTemplateArgsAsWritten() && TemplateSpecializationType::anyInstantiationDependentTemplateArguments( Constraint->getTemplateArgsAsWritten()->arguments().drop_front(1)); TypeConstraintInfo.setInt(Dependent ? true : false); } concepts::TypeRequirement::TypeRequirement(TypeSourceInfo *T) : Requirement(RK_Type, T->getType()->isInstantiationDependentType(), T->getType()->containsUnexpandedParameterPack(), // We reach this ctor with either dependent types (in which // IsSatisfied doesn't matter) or with non-dependent type in // which the existence of the type indicates satisfaction. /*IsSatisfied=*/true), Value(T), Status(T->getType()->isInstantiationDependentType() ? SS_Dependent : SS_Satisfied) {}