//===-- lib/Semantics/rewrite-parse-tree.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 "rewrite-parse-tree.h" #include "rewrite-directives.h" #include "flang/Common/indirection.h" #include "flang/Parser/parse-tree-visitor.h" #include "flang/Parser/parse-tree.h" #include "flang/Parser/tools.h" #include "flang/Semantics/scope.h" #include "flang/Semantics/semantics.h" #include "flang/Semantics/symbol.h" #include "flang/Semantics/tools.h" #include namespace Fortran::semantics { using namespace parser::literals; /// Convert misidentified statement functions to array element assignments /// or pointer-valued function result assignments. /// Convert misidentified format expressions to namelist group names. /// Convert misidentified character variables in I/O units to integer /// unit number expressions. /// Convert misidentified named constants in data statement values to /// initial data targets class RewriteMutator { public: RewriteMutator(SemanticsContext &context) : errorOnUnresolvedName_{!context.AnyFatalError()}, messages_{context.messages()} {} // Default action for a parse tree node is to visit children. template bool Pre(T &) { return true; } template void Post(T &) {} void Post(parser::Name &); void Post(parser::SpecificationPart &); bool Pre(parser::ExecutionPart &); void Post(parser::ReadStmt &); void Post(parser::WriteStmt &); // Name resolution yet implemented: // TODO: Can some/all of these now be enabled? bool Pre(parser::EquivalenceStmt &) { return false; } bool Pre(parser::Keyword &) { return false; } bool Pre(parser::EntryStmt &) { return false; } bool Pre(parser::CompilerDirective &) { return false; } // Don't bother resolving names in end statements. bool Pre(parser::EndBlockDataStmt &) { return false; } bool Pre(parser::EndFunctionStmt &) { return false; } bool Pre(parser::EndInterfaceStmt &) { return false; } bool Pre(parser::EndModuleStmt &) { return false; } bool Pre(parser::EndMpSubprogramStmt &) { return false; } bool Pre(parser::EndProgramStmt &) { return false; } bool Pre(parser::EndSubmoduleStmt &) { return false; } bool Pre(parser::EndSubroutineStmt &) { return false; } bool Pre(parser::EndTypeStmt &) { return false; } private: using stmtFuncType = parser::Statement>; bool errorOnUnresolvedName_{true}; parser::Messages &messages_; std::list stmtFuncsToConvert_; }; // Check that name has been resolved to a symbol void RewriteMutator::Post(parser::Name &name) { if (!name.symbol && errorOnUnresolvedName_) { messages_.Say(name.source, "Internal: no symbol found for '%s'"_err_en_US, name.source); } } static bool ReturnsDataPointer(const Symbol &symbol) { if (const Symbol * funcRes{FindFunctionResult(symbol)}) { return IsPointer(*funcRes) && !IsProcedure(*funcRes); } else if (const auto *generic{symbol.detailsIf()}) { for (auto ref : generic->specificProcs()) { if (ReturnsDataPointer(*ref)) { return true; } } } return false; } // Find mis-parsed statement functions and move to stmtFuncsToConvert_ list. void RewriteMutator::Post(parser::SpecificationPart &x) { auto &list{std::get>(x.t)}; for (auto it{list.begin()}; it != list.end();) { bool isAssignment{false}; if (auto *stmt{std::get_if(&it->u)}) { if (const Symbol * symbol{std::get(stmt->statement.value().t).symbol}) { const Symbol &ultimate{symbol->GetUltimate()}; isAssignment = ultimate.has() || ReturnsDataPointer(ultimate); if (isAssignment) { stmtFuncsToConvert_.emplace_back(std::move(*stmt)); } } } if (isAssignment) { it = list.erase(it); } else { ++it; } } } // Insert converted assignments at start of ExecutionPart. bool RewriteMutator::Pre(parser::ExecutionPart &x) { auto origFirst{x.v.begin()}; // insert each elem before origFirst for (stmtFuncType &sf : stmtFuncsToConvert_) { auto stmt{sf.statement.value().ConvertToAssignment()}; stmt.source = sf.source; x.v.insert(origFirst, parser::ExecutionPartConstruct{ parser::ExecutableConstruct{std::move(stmt)}}); } stmtFuncsToConvert_.clear(); return true; } // When a namelist group name appears (without NML=) in a READ or WRITE // statement in such a way that it can be misparsed as a format expression, // rewrite the I/O statement's parse tree node as if the namelist group // name had appeared with NML=. template void FixMisparsedUntaggedNamelistName(READ_OR_WRITE &x) { if (x.iounit && x.format && std::holds_alternative(x.format->u)) { if (const parser::Name * name{parser::Unwrap(x.format)}) { if (name->symbol && name->symbol->GetUltimate().has()) { x.controls.emplace_front(parser::IoControlSpec{std::move(*name)}); x.format.reset(); } } } } // READ(CVAR) [, ...] will be misparsed as UNIT=CVAR; correct // it to READ CVAR [,...] with CVAR as a format rather than as // an internal I/O unit for unformatted I/O, which Fortran does // not support. void RewriteMutator::Post(parser::ReadStmt &x) { if (x.iounit && !x.format && x.controls.empty()) { if (auto *var{std::get_if(&x.iounit->u)}) { const parser::Name &last{parser::GetLastName(*var)}; DeclTypeSpec *type{last.symbol ? last.symbol->GetType() : nullptr}; if (type && type->category() == DeclTypeSpec::Character) { x.format = common::visit( [](auto &&indirection) { return parser::Expr{std::move(indirection)}; }, std::move(var->u)); x.iounit.reset(); } } } FixMisparsedUntaggedNamelistName(x); } void RewriteMutator::Post(parser::WriteStmt &x) { FixMisparsedUntaggedNamelistName(x); } bool RewriteParseTree(SemanticsContext &context, parser::Program &program) { RewriteMutator mutator{context}; parser::Walk(program, mutator); return !context.AnyFatalError() && RewriteOmpParts(context, program); } } // namespace Fortran::semantics