Mercurial > hg > CbC > CbC_llvm
view flang/lib/Semantics/pointer-assignment.cpp @ 207:2e18cbf3894f
LLVM12
| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Tue, 08 Jun 2021 06:07:14 +0900 |
| parents | 0572611fdcc8 |
| children | 5f17cb93ff66 |
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//===-- lib/Semantics/pointer-assignment.cpp ------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "pointer-assignment.h" #include "flang/Common/idioms.h" #include "flang/Common/restorer.h" #include "flang/Evaluate/characteristics.h" #include "flang/Evaluate/expression.h" #include "flang/Evaluate/fold.h" #include "flang/Evaluate/tools.h" #include "flang/Parser/message.h" #include "flang/Parser/parse-tree-visitor.h" #include "flang/Parser/parse-tree.h" #include "flang/Semantics/expression.h" #include "flang/Semantics/symbol.h" #include "flang/Semantics/tools.h" #include "llvm/Support/raw_ostream.h" #include <optional> #include <set> #include <string> #include <type_traits> // Semantic checks for pointer assignment. namespace Fortran::semantics { using namespace parser::literals; using evaluate::characteristics::DummyDataObject; using evaluate::characteristics::FunctionResult; using evaluate::characteristics::Procedure; using evaluate::characteristics::TypeAndShape; using parser::MessageFixedText; using parser::MessageFormattedText; class PointerAssignmentChecker { public: PointerAssignmentChecker(evaluate::FoldingContext &context, parser::CharBlock source, const std::string &description) : context_{context}, source_{source}, description_{description} {} PointerAssignmentChecker(evaluate::FoldingContext &context, const Symbol &lhs) : context_{context}, source_{lhs.name()}, description_{"pointer '"s + lhs.name().ToString() + '\''}, lhs_{&lhs}, procedure_{Procedure::Characterize(lhs, context)} { set_lhsType(TypeAndShape::Characterize(lhs, context)); set_isContiguous(lhs.attrs().test(Attr::CONTIGUOUS)); set_isVolatile(lhs.attrs().test(Attr::VOLATILE)); } PointerAssignmentChecker &set_lhsType(std::optional<TypeAndShape> &&); PointerAssignmentChecker &set_isContiguous(bool); PointerAssignmentChecker &set_isVolatile(bool); PointerAssignmentChecker &set_isBoundsRemapping(bool); bool Check(const SomeExpr &); private: template <typename T> bool Check(const T &); template <typename T> bool Check(const evaluate::Expr<T> &); template <typename T> bool Check(const evaluate::FunctionRef<T> &); template <typename T> bool Check(const evaluate::Designator<T> &); bool Check(const evaluate::NullPointer &); bool Check(const evaluate::ProcedureDesignator &); bool Check(const evaluate::ProcedureRef &); // Target is a procedure bool Check( parser::CharBlock rhsName, bool isCall, const Procedure * = nullptr); bool LhsOkForUnlimitedPoly() const; template <typename... A> parser::Message *Say(A &&...); evaluate::FoldingContext &context_; const parser::CharBlock source_; const std::string description_; const Symbol *lhs_{nullptr}; std::optional<TypeAndShape> lhsType_; std::optional<Procedure> procedure_; bool isContiguous_{false}; bool isVolatile_{false}; bool isBoundsRemapping_{false}; }; PointerAssignmentChecker &PointerAssignmentChecker::set_lhsType( std::optional<TypeAndShape> &&lhsType) { lhsType_ = std::move(lhsType); return *this; } PointerAssignmentChecker &PointerAssignmentChecker::set_isContiguous( bool isContiguous) { isContiguous_ = isContiguous; return *this; } PointerAssignmentChecker &PointerAssignmentChecker::set_isVolatile( bool isVolatile) { isVolatile_ = isVolatile; return *this; } PointerAssignmentChecker &PointerAssignmentChecker::set_isBoundsRemapping( bool isBoundsRemapping) { isBoundsRemapping_ = isBoundsRemapping; return *this; } template <typename T> bool PointerAssignmentChecker::Check(const T &) { // Catch-all case for really bad target expression Say("Target associated with %s must be a designator or a call to a" " pointer-valued function"_err_en_US, description_); return false; } template <typename T> bool PointerAssignmentChecker::Check(const evaluate::Expr<T> &x) { return std::visit([&](const auto &x) { return Check(x); }, x.u); } bool PointerAssignmentChecker::Check(const SomeExpr &rhs) { if (HasVectorSubscript(rhs)) { // C1025 Say("An array section with a vector subscript may not be a pointer target"_err_en_US); return false; } else if (ExtractCoarrayRef(rhs)) { // C1026 Say("A coindexed object may not be a pointer target"_err_en_US); return false; } else { return std::visit([&](const auto &x) { return Check(x); }, rhs.u); } } bool PointerAssignmentChecker::Check(const evaluate::NullPointer &) { return true; // P => NULL() without MOLD=; always OK } template <typename T> bool PointerAssignmentChecker::Check(const evaluate::FunctionRef<T> &f) { std::string funcName; const auto *symbol{f.proc().GetSymbol()}; if (symbol) { funcName = symbol->name().ToString(); } else if (const auto *intrinsic{f.proc().GetSpecificIntrinsic()}) { funcName = intrinsic->name; } auto proc{Procedure::Characterize(f.proc(), context_)}; if (!proc) { return false; } std::optional<MessageFixedText> msg; const auto &funcResult{proc->functionResult}; // C1025 if (!funcResult) { msg = "%s is associated with the non-existent result of reference to" " procedure"_err_en_US; } else if (procedure_) { // Shouldn't be here in this function unless lhs is an object pointer. msg = "Procedure %s is associated with the result of a reference to" " function '%s' that does not return a procedure pointer"_err_en_US; } else if (funcResult->IsProcedurePointer()) { msg = "Object %s is associated with the result of a reference to" " function '%s' that is a procedure pointer"_err_en_US; } else if (!funcResult->attrs.test(FunctionResult::Attr::Pointer)) { msg = "%s is associated with the result of a reference to function '%s'" " that is a not a pointer"_err_en_US; } else if (isContiguous_ && !funcResult->attrs.test(FunctionResult::Attr::Contiguous)) { msg = "CONTIGUOUS %s is associated with the result of reference to" " function '%s' that is not contiguous"_err_en_US; } else if (lhsType_) { const auto *frTypeAndShape{funcResult->GetTypeAndShape()}; CHECK(frTypeAndShape); if (!lhsType_->IsCompatibleWith(context_.messages(), *frTypeAndShape, "pointer", "function result", false /*elemental*/, evaluate::CheckConformanceFlags::BothDeferredShape)) { msg = "%s is associated with the result of a reference to function '%s'" " whose pointer result has an incompatible type or shape"_err_en_US; } } if (msg) { auto restorer{common::ScopedSet(lhs_, symbol)}; Say(*msg, description_, funcName); return false; } return true; } template <typename T> bool PointerAssignmentChecker::Check(const evaluate::Designator<T> &d) { const Symbol *last{d.GetLastSymbol()}; const Symbol *base{d.GetBaseObject().symbol()}; if (!last || !base) { // P => "character literal"(1:3) context_.messages().Say("Pointer target is not a named entity"_err_en_US); return false; } std::optional<std::variant<MessageFixedText, MessageFormattedText>> msg; if (procedure_) { // Shouldn't be here in this function unless lhs is an object pointer. msg = "In assignment to procedure %s, the target is not a procedure or" " procedure pointer"_err_en_US; } else if (!evaluate::GetLastTarget(GetSymbolVector(d))) { // C1025 msg = "In assignment to object %s, the target '%s' is not an object with" " POINTER or TARGET attributes"_err_en_US; } else if (auto rhsType{TypeAndShape::Characterize(d, context_)}) { if (!lhsType_) { msg = "%s associated with object '%s' with incompatible type or" " shape"_err_en_US; } else if (rhsType->corank() > 0 && (isVolatile_ != last->attrs().test(Attr::VOLATILE))) { // C1020 // TODO: what if A is VOLATILE in A%B%C? need a better test here if (isVolatile_) { msg = "Pointer may not be VOLATILE when target is a" " non-VOLATILE coarray"_err_en_US; } else { msg = "Pointer must be VOLATILE when target is a" " VOLATILE coarray"_err_en_US; } } else if (rhsType->type().IsUnlimitedPolymorphic()) { if (!LhsOkForUnlimitedPoly()) { msg = "Pointer type must be unlimited polymorphic or non-extensible" " derived type when target is unlimited polymorphic"_err_en_US; } } else { if (!lhsType_->type().IsTkCompatibleWith(rhsType->type())) { msg = MessageFormattedText{ "Target type %s is not compatible with pointer type %s"_err_en_US, rhsType->type().AsFortran(), lhsType_->type().AsFortran()}; } else if (!isBoundsRemapping_) { int lhsRank{evaluate::GetRank(lhsType_->shape())}; int rhsRank{evaluate::GetRank(rhsType->shape())}; if (lhsRank != rhsRank) { msg = MessageFormattedText{ "Pointer has rank %d but target has rank %d"_err_en_US, lhsRank, rhsRank}; } } } } if (msg) { auto restorer{common::ScopedSet(lhs_, last)}; if (auto *m{std::get_if<MessageFixedText>(&*msg)}) { std::string buf; llvm::raw_string_ostream ss{buf}; d.AsFortran(ss); Say(*m, description_, ss.str()); } else { Say(std::get<MessageFormattedText>(*msg)); } return false; } return true; } // Common handling for procedure pointer right-hand sides bool PointerAssignmentChecker::Check( parser::CharBlock rhsName, bool isCall, const Procedure *rhsProcedure) { if (std::optional<MessageFixedText> msg{ evaluate::CheckProcCompatibility(isCall, procedure_, rhsProcedure)}) { Say(std::move(*msg), description_, rhsName); return false; } return true; } bool PointerAssignmentChecker::Check(const evaluate::ProcedureDesignator &d) { if (auto chars{Procedure::Characterize(d, context_)}) { return Check(d.GetName(), false, &*chars); } else { return Check(d.GetName(), false); } } bool PointerAssignmentChecker::Check(const evaluate::ProcedureRef &ref) { const Procedure *procedure{nullptr}; auto chars{Procedure::Characterize(ref, context_)}; if (chars) { procedure = &*chars; if (chars->functionResult) { if (const auto *proc{chars->functionResult->IsProcedurePointer()}) { procedure = proc; } } } return Check(ref.proc().GetName(), true, procedure); } // The target can be unlimited polymorphic if the pointer is, or if it is // a non-extensible derived type. bool PointerAssignmentChecker::LhsOkForUnlimitedPoly() const { const auto &type{lhsType_->type()}; if (type.category() != TypeCategory::Derived || type.IsAssumedType()) { return false; } else if (type.IsUnlimitedPolymorphic()) { return true; } else { return !IsExtensibleType(&type.GetDerivedTypeSpec()); } } template <typename... A> parser::Message *PointerAssignmentChecker::Say(A &&...x) { auto *msg{context_.messages().Say(std::forward<A>(x)...)}; if (msg) { if (lhs_) { return evaluate::AttachDeclaration(msg, *lhs_); } if (!source_.empty()) { msg->Attach(source_, "Declaration of %s"_en_US, description_); } } return msg; } // Verify that any bounds on the LHS of a pointer assignment are valid. // Return true if it is a bound-remapping so we can perform further checks. static bool CheckPointerBounds( evaluate::FoldingContext &context, const evaluate::Assignment &assignment) { auto &messages{context.messages()}; const SomeExpr &lhs{assignment.lhs}; const SomeExpr &rhs{assignment.rhs}; bool isBoundsRemapping{false}; std::size_t numBounds{std::visit( common::visitors{ [&](const evaluate::Assignment::BoundsSpec &bounds) { return bounds.size(); }, [&](const evaluate::Assignment::BoundsRemapping &bounds) { isBoundsRemapping = true; evaluate::ExtentExpr lhsSizeExpr{1}; for (const auto &bound : bounds) { lhsSizeExpr = std::move(lhsSizeExpr) * (common::Clone(bound.second) - common::Clone(bound.first) + evaluate::ExtentExpr{1}); } if (std::optional<std::int64_t> lhsSize{evaluate::ToInt64( evaluate::Fold(context, std::move(lhsSizeExpr)))}) { if (auto shape{evaluate::GetShape(context, rhs)}) { if (std::optional<std::int64_t> rhsSize{ evaluate::ToInt64(evaluate::Fold( context, evaluate::GetSize(std::move(*shape))))}) { if (*lhsSize > *rhsSize) { messages.Say( "Pointer bounds require %d elements but target has" " only %d"_err_en_US, *lhsSize, *rhsSize); // 10.2.2.3(9) } } } } return bounds.size(); }, [](const auto &) -> std::size_t { DIE("not valid for pointer assignment"); }, }, assignment.u)}; if (numBounds > 0) { if (lhs.Rank() != static_cast<int>(numBounds)) { messages.Say("Pointer '%s' has rank %d but the number of bounds specified" " is %d"_err_en_US, lhs.AsFortran(), lhs.Rank(), numBounds); // C1018 } } if (isBoundsRemapping && rhs.Rank() != 1 && !evaluate::IsSimplyContiguous(rhs, context)) { messages.Say("Pointer bounds remapping target must have rank 1 or be" " simply contiguous"_err_en_US); // 10.2.2.3(9) } return isBoundsRemapping; } bool CheckPointerAssignment( evaluate::FoldingContext &context, const evaluate::Assignment &assignment) { return CheckPointerAssignment(context, assignment.lhs, assignment.rhs, CheckPointerBounds(context, assignment)); } bool CheckPointerAssignment(evaluate::FoldingContext &context, const SomeExpr &lhs, const SomeExpr &rhs, bool isBoundsRemapping) { const Symbol *pointer{GetLastSymbol(lhs)}; if (!pointer) { return false; // error was reported } if (!IsPointer(*pointer)) { evaluate::SayWithDeclaration(context.messages(), *pointer, "'%s' is not a pointer"_err_en_US, pointer->name()); return false; } if (pointer->has<ProcEntityDetails>() && evaluate::ExtractCoarrayRef(lhs)) { context.messages().Say( // C1027 "Procedure pointer may not be a coindexed object"_err_en_US); return false; } return PointerAssignmentChecker{context, *pointer} .set_isBoundsRemapping(isBoundsRemapping) .Check(rhs); } bool CheckPointerAssignment( evaluate::FoldingContext &context, const Symbol &lhs, const SomeExpr &rhs) { CHECK(IsPointer(lhs)); return PointerAssignmentChecker{context, lhs}.Check(rhs); } bool CheckPointerAssignment(evaluate::FoldingContext &context, parser::CharBlock source, const std::string &description, const DummyDataObject &lhs, const SomeExpr &rhs) { return PointerAssignmentChecker{context, source, description} .set_lhsType(common::Clone(lhs.type)) .set_isContiguous(lhs.attrs.test(DummyDataObject::Attr::Contiguous)) .set_isVolatile(lhs.attrs.test(DummyDataObject::Attr::Volatile)) .Check(rhs); } bool CheckInitialTarget(evaluate::FoldingContext &context, const SomeExpr &pointer, const SomeExpr &init) { return evaluate::IsInitialDataTarget(init, &context.messages()) && CheckPointerAssignment(context, pointer, init); } } // namespace Fortran::semantics