Mercurial > hg > CbC > CbC_llvm
view flang/lib/Semantics/mod-file.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 | c4bab56944e8 |
line wrap: on
line source
//===-- lib/Semantics/mod-file.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 "mod-file.h" #include "resolve-names.h" #include "flang/Common/restorer.h" #include "flang/Evaluate/tools.h" #include "flang/Parser/message.h" #include "flang/Parser/parsing.h" #include "flang/Semantics/scope.h" #include "flang/Semantics/semantics.h" #include "flang/Semantics/symbol.h" #include "flang/Semantics/tools.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/raw_ostream.h" #include <algorithm> #include <fstream> #include <set> #include <string_view> #include <vector> namespace Fortran::semantics { using namespace parser::literals; // The first line of a file that identifies it as a .mod file. // The first three bytes are a Unicode byte order mark that ensures // that the module file is decoded as UTF-8 even if source files // are using another encoding. struct ModHeader { static constexpr const char bom[3 + 1]{"\xef\xbb\xbf"}; static constexpr int magicLen{13}; static constexpr int sumLen{16}; static constexpr const char magic[magicLen + 1]{"!mod$ v1 sum:"}; static constexpr char terminator{'\n'}; static constexpr int len{magicLen + 1 + sumLen}; }; static std::optional<SourceName> GetSubmoduleParent(const parser::Program &); static void CollectSymbols(const Scope &, SymbolVector &, SymbolVector &); static void PutEntity(llvm::raw_ostream &, const Symbol &); static void PutObjectEntity(llvm::raw_ostream &, const Symbol &); static void PutProcEntity(llvm::raw_ostream &, const Symbol &); static void PutPassName(llvm::raw_ostream &, const std::optional<SourceName> &); static void PutTypeParam(llvm::raw_ostream &, const Symbol &); static void PutEntity( llvm::raw_ostream &, const Symbol &, std::function<void()>, Attrs); static void PutInit(llvm::raw_ostream &, const Symbol &, const MaybeExpr &); static void PutInit(llvm::raw_ostream &, const MaybeIntExpr &); static void PutBound(llvm::raw_ostream &, const Bound &); llvm::raw_ostream &PutAttrs(llvm::raw_ostream &, Attrs, const std::string * = nullptr, std::string before = ","s, std::string after = ""s); static llvm::raw_ostream &PutAttr(llvm::raw_ostream &, Attr); static llvm::raw_ostream &PutType(llvm::raw_ostream &, const DeclTypeSpec &); static llvm::raw_ostream &PutLower(llvm::raw_ostream &, const std::string &); static std::error_code WriteFile( const std::string &, const std::string &, bool = true); static bool FileContentsMatch( const std::string &, const std::string &, const std::string &); static std::string CheckSum(const std::string_view &); // Collect symbols needed for a subprogram interface class SubprogramSymbolCollector { public: SubprogramSymbolCollector(const Symbol &symbol, const Scope &scope) : symbol_{symbol}, scope_{scope} {} const SymbolVector &symbols() const { return need_; } const std::set<SourceName> &imports() const { return imports_; } void Collect(); private: const Symbol &symbol_; const Scope &scope_; bool isInterface_{false}; SymbolVector need_; // symbols that are needed UnorderedSymbolSet needSet_; // symbols already in need_ UnorderedSymbolSet useSet_; // use-associations that might be needed std::set<SourceName> imports_; // imports from host that are needed void DoSymbol(const Symbol &); void DoSymbol(const SourceName &, const Symbol &); void DoType(const DeclTypeSpec *); void DoBound(const Bound &); void DoParamValue(const ParamValue &); bool NeedImport(const SourceName &, const Symbol &); template <typename T> void DoExpr(evaluate::Expr<T> expr) { for (const Symbol &symbol : evaluate::CollectSymbols(expr)) { DoSymbol(symbol); } } }; bool ModFileWriter::WriteAll() { // this flag affects character literals: force it to be consistent auto restorer{ common::ScopedSet(parser::useHexadecimalEscapeSequences, false)}; WriteAll(context_.globalScope()); return !context_.AnyFatalError(); } void ModFileWriter::WriteAll(const Scope &scope) { for (const auto &child : scope.children()) { WriteOne(child); } } void ModFileWriter::WriteOne(const Scope &scope) { if (scope.kind() == Scope::Kind::Module) { auto *symbol{scope.symbol()}; if (!symbol->test(Symbol::Flag::ModFile)) { Write(*symbol); } WriteAll(scope); // write out submodules } } // Construct the name of a module file. Non-empty ancestorName means submodule. static std::string ModFileName(const SourceName &name, const std::string &ancestorName, const std::string &suffix) { std::string result{name.ToString() + suffix}; return ancestorName.empty() ? result : ancestorName + '-' + result; } // Write the module file for symbol, which must be a module or submodule. void ModFileWriter::Write(const Symbol &symbol) { auto *ancestor{symbol.get<ModuleDetails>().ancestor()}; auto ancestorName{ancestor ? ancestor->GetName().value().ToString() : ""s}; auto path{context_.moduleDirectory() + '/' + ModFileName(symbol.name(), ancestorName, context_.moduleFileSuffix())}; PutSymbols(DEREF(symbol.scope())); if (std::error_code error{ WriteFile(path, GetAsString(symbol), context_.debugModuleWriter())}) { context_.Say( symbol.name(), "Error writing %s: %s"_err_en_US, path, error.message()); } } // Return the entire body of the module file // and clear saved uses, decls, and contains. std::string ModFileWriter::GetAsString(const Symbol &symbol) { std::string buf; llvm::raw_string_ostream all{buf}; auto &details{symbol.get<ModuleDetails>()}; if (!details.isSubmodule()) { all << "module " << symbol.name(); } else { auto *parent{details.parent()->symbol()}; auto *ancestor{details.ancestor()->symbol()}; all << "submodule(" << ancestor->name(); if (parent != ancestor) { all << ':' << parent->name(); } all << ") " << symbol.name(); } all << '\n' << uses_.str(); uses_.str().clear(); all << useExtraAttrs_.str(); useExtraAttrs_.str().clear(); all << decls_.str(); decls_.str().clear(); auto str{contains_.str()}; contains_.str().clear(); if (!str.empty()) { all << "contains\n" << str; } all << "end\n"; return all.str(); } // Put out the visible symbols from scope. bool ModFileWriter::PutSymbols(const Scope &scope) { SymbolVector sorted; SymbolVector uses; CollectSymbols(scope, sorted, uses); std::string buf; // stuff after CONTAINS in derived type llvm::raw_string_ostream typeBindings{buf}; for (const Symbol &symbol : sorted) { PutSymbol(typeBindings, symbol); } for (const Symbol &symbol : uses) { PutUse(symbol); } if (auto str{typeBindings.str()}; !str.empty()) { CHECK(scope.IsDerivedType()); decls_ << "contains\n" << str; return true; } else { return false; } } static llvm::raw_ostream &PutGenericName( llvm::raw_ostream &os, const Symbol &symbol) { if (IsGenericDefinedOp(symbol)) { return os << "operator(" << symbol.name() << ')'; } else { return os << symbol.name(); } } // Emit a symbol to decls_, except for bindings in a derived type (type-bound // procedures, type-bound generics, final procedures) which go to typeBindings. void ModFileWriter::PutSymbol( llvm::raw_ostream &typeBindings, const Symbol &symbol) { std::visit(common::visitors{ [&](const ModuleDetails &) { /* should be current module */ }, [&](const DerivedTypeDetails &) { PutDerivedType(symbol); }, [&](const SubprogramDetails &) { PutSubprogram(symbol); }, [&](const GenericDetails &x) { if (symbol.owner().IsDerivedType()) { // generic binding for (const Symbol &proc : x.specificProcs()) { PutGenericName(typeBindings << "generic::", symbol) << "=>" << proc.name() << '\n'; } } else { PutGeneric(symbol); if (x.specific()) { PutSymbol(typeBindings, *x.specific()); } if (x.derivedType()) { PutSymbol(typeBindings, *x.derivedType()); } } }, [&](const UseDetails &) { PutUse(symbol); }, [](const UseErrorDetails &) {}, [&](const ProcBindingDetails &x) { bool deferred{symbol.attrs().test(Attr::DEFERRED)}; typeBindings << "procedure"; if (deferred) { typeBindings << '(' << x.symbol().name() << ')'; } PutPassName(typeBindings, x.passName()); auto attrs{symbol.attrs()}; if (x.passName()) { attrs.reset(Attr::PASS); } PutAttrs(typeBindings, attrs); typeBindings << "::" << symbol.name(); if (!deferred && x.symbol().name() != symbol.name()) { typeBindings << "=>" << x.symbol().name(); } typeBindings << '\n'; }, [&](const NamelistDetails &x) { decls_ << "namelist/" << symbol.name(); char sep{'/'}; for (const Symbol &object : x.objects()) { decls_ << sep << object.name(); sep = ','; } decls_ << '\n'; }, [&](const CommonBlockDetails &x) { decls_ << "common/" << symbol.name(); char sep = '/'; for (const auto &object : x.objects()) { decls_ << sep << object->name(); sep = ','; } decls_ << '\n'; if (symbol.attrs().test(Attr::BIND_C)) { PutAttrs(decls_, symbol.attrs(), x.bindName(), ""s); decls_ << "::/" << symbol.name() << "/\n"; } }, [](const HostAssocDetails &) {}, [](const MiscDetails &) {}, [&](const auto &) { PutEntity(decls_, symbol); }, }, symbol.details()); } void ModFileWriter::PutDerivedType(const Symbol &typeSymbol) { auto &details{typeSymbol.get<DerivedTypeDetails>()}; PutAttrs(decls_ << "type", typeSymbol.attrs()); if (const DerivedTypeSpec * extends{typeSymbol.GetParentTypeSpec()}) { decls_ << ",extends(" << extends->name() << ')'; } decls_ << "::" << typeSymbol.name(); auto &typeScope{*typeSymbol.scope()}; if (!details.paramNames().empty()) { char sep{'('}; for (const auto &name : details.paramNames()) { decls_ << sep << name; sep = ','; } decls_ << ')'; } decls_ << '\n'; if (details.sequence()) { decls_ << "sequence\n"; } bool contains{PutSymbols(typeScope)}; if (!details.finals().empty()) { const char *sep{contains ? "final::" : "contains\nfinal::"}; for (const auto &pair : details.finals()) { decls_ << sep << pair.second->name(); sep = ","; } if (*sep == ',') { decls_ << '\n'; } } decls_ << "end type\n"; } // Attributes that may be in a subprogram prefix static const Attrs subprogramPrefixAttrs{Attr::ELEMENTAL, Attr::IMPURE, Attr::MODULE, Attr::NON_RECURSIVE, Attr::PURE, Attr::RECURSIVE}; void ModFileWriter::PutSubprogram(const Symbol &symbol) { auto attrs{symbol.attrs()}; auto &details{symbol.get<SubprogramDetails>()}; Attrs bindAttrs{}; if (attrs.test(Attr::BIND_C)) { // bind(c) is a suffix, not prefix bindAttrs.set(Attr::BIND_C, true); attrs.set(Attr::BIND_C, false); } bool isAbstract{attrs.test(Attr::ABSTRACT)}; if (isAbstract) { attrs.set(Attr::ABSTRACT, false); } Attrs prefixAttrs{subprogramPrefixAttrs & attrs}; // emit any non-prefix attributes in an attribute statement attrs &= ~subprogramPrefixAttrs; std::string ssBuf; llvm::raw_string_ostream ss{ssBuf}; PutAttrs(ss, attrs); if (!ss.str().empty()) { decls_ << ss.str().substr(1) << "::" << symbol.name() << '\n'; } bool isInterface{details.isInterface()}; llvm::raw_ostream &os{isInterface ? decls_ : contains_}; if (isInterface) { os << (isAbstract ? "abstract " : "") << "interface\n"; } PutAttrs(os, prefixAttrs, nullptr, ""s, " "s); os << (details.isFunction() ? "function " : "subroutine "); os << symbol.name() << '('; int n = 0; for (const auto &dummy : details.dummyArgs()) { if (n++ > 0) { os << ','; } if (dummy) { os << dummy->name(); } else { os << "*"; } } os << ')'; PutAttrs(os, bindAttrs, details.bindName(), " "s, ""s); if (details.isFunction()) { const Symbol &result{details.result()}; if (result.name() != symbol.name()) { os << " result(" << result.name() << ')'; } } os << '\n'; // walk symbols, collect ones needed for interface const Scope &scope{ details.entryScope() ? *details.entryScope() : DEREF(symbol.scope())}; SubprogramSymbolCollector collector{symbol, scope}; collector.Collect(); std::string typeBindingsBuf; llvm::raw_string_ostream typeBindings{typeBindingsBuf}; ModFileWriter writer{context_}; for (const Symbol &need : collector.symbols()) { writer.PutSymbol(typeBindings, need); } CHECK(typeBindings.str().empty()); os << writer.uses_.str(); for (const SourceName &import : collector.imports()) { decls_ << "import::" << import << "\n"; } os << writer.decls_.str(); os << "end\n"; if (isInterface) { os << "end interface\n"; } } static bool IsIntrinsicOp(const Symbol &symbol) { if (const auto *details{symbol.GetUltimate().detailsIf<GenericDetails>()}) { return details->kind().IsIntrinsicOperator(); } else { return false; } } void ModFileWriter::PutGeneric(const Symbol &symbol) { const auto &genericOwner{symbol.owner()}; auto &details{symbol.get<GenericDetails>()}; PutGenericName(decls_ << "interface ", symbol) << '\n'; for (const Symbol &specific : details.specificProcs()) { if (specific.owner() == genericOwner) { decls_ << "procedure::" << specific.name() << '\n'; } } decls_ << "end interface\n"; if (symbol.attrs().test(Attr::PRIVATE)) { PutGenericName(decls_ << "private::", symbol) << '\n'; } } void ModFileWriter::PutUse(const Symbol &symbol) { auto &details{symbol.get<UseDetails>()}; auto &use{details.symbol()}; uses_ << "use " << GetUsedModule(details).name(); PutGenericName(uses_ << ",only:", symbol); // Can have intrinsic op with different local-name and use-name // (e.g. `operator(<)` and `operator(.lt.)`) but rename is not allowed if (!IsIntrinsicOp(symbol) && use.name() != symbol.name()) { PutGenericName(uses_ << "=>", use); } uses_ << '\n'; PutUseExtraAttr(Attr::VOLATILE, symbol, use); PutUseExtraAttr(Attr::ASYNCHRONOUS, symbol, use); if (symbol.attrs().test(Attr::PRIVATE)) { PutGenericName(useExtraAttrs_ << "private::", symbol) << '\n'; } } // We have "USE local => use" in this module. If attr was added locally // (i.e. on local but not on use), also write it out in the mod file. void ModFileWriter::PutUseExtraAttr( Attr attr, const Symbol &local, const Symbol &use) { if (local.attrs().test(attr) && !use.attrs().test(attr)) { PutAttr(useExtraAttrs_, attr) << "::"; useExtraAttrs_ << local.name() << '\n'; } } // When a generic interface has the same name as a derived type // in the same scope, the generic shadows the derived type. // If the derived type were declared first, emit the generic // interface at the position of derived type's declaration. // (ReplaceName() is not used for this purpose because doing so // would confusingly position error messages pertaining to the generic // interface upon the derived type's declaration.) static inline SourceName NameInModuleFile(const Symbol &symbol) { if (const auto *generic{symbol.detailsIf<GenericDetails>()}) { if (const auto *derivedTypeOverload{generic->derivedType()}) { if (derivedTypeOverload->name().begin() < symbol.name().begin()) { return derivedTypeOverload->name(); } } } else if (const auto *use{symbol.detailsIf<UseDetails>()}) { if (use->symbol().attrs().test(Attr::PRIVATE)) { // Avoid the use in sorting of names created to access private // specific procedures as a result of generic resolution; // they're not in the cooked source. return use->symbol().name(); } } return symbol.name(); } // Collect the symbols of this scope sorted by their original order, not name. // Namelists are an exception: they are sorted after other symbols. void CollectSymbols( const Scope &scope, SymbolVector &sorted, SymbolVector &uses) { SymbolVector namelist; std::size_t commonSize{scope.commonBlocks().size()}; auto symbols{scope.GetSymbols()}; sorted.reserve(symbols.size() + commonSize); for (SymbolRef symbol : symbols) { if (!symbol->test(Symbol::Flag::ParentComp)) { if (symbol->has<NamelistDetails>()) { namelist.push_back(symbol); } else { sorted.push_back(symbol); } if (const auto *details{symbol->detailsIf<GenericDetails>()}) { uses.insert(uses.end(), details->uses().begin(), details->uses().end()); } } } // Sort most symbols by name: use of Symbol::ReplaceName ensures the source // location of a symbol's name is the first "real" use. std::sort(sorted.begin(), sorted.end(), [](SymbolRef x, SymbolRef y) { return NameInModuleFile(x).begin() < NameInModuleFile(y).begin(); }); sorted.insert(sorted.end(), namelist.begin(), namelist.end()); for (const auto &pair : scope.commonBlocks()) { sorted.push_back(*pair.second); } std::sort( sorted.end() - commonSize, sorted.end(), SymbolSourcePositionCompare{}); } void PutEntity(llvm::raw_ostream &os, const Symbol &symbol) { std::visit( common::visitors{ [&](const ObjectEntityDetails &) { PutObjectEntity(os, symbol); }, [&](const ProcEntityDetails &) { PutProcEntity(os, symbol); }, [&](const TypeParamDetails &) { PutTypeParam(os, symbol); }, [&](const auto &) { common::die("PutEntity: unexpected details: %s", DetailsToString(symbol.details()).c_str()); }, }, symbol.details()); } void PutShapeSpec(llvm::raw_ostream &os, const ShapeSpec &x) { if (x.lbound().isAssumed()) { CHECK(x.ubound().isAssumed()); os << ".."; } else { if (!x.lbound().isDeferred()) { PutBound(os, x.lbound()); } os << ':'; if (!x.ubound().isDeferred()) { PutBound(os, x.ubound()); } } } void PutShape( llvm::raw_ostream &os, const ArraySpec &shape, char open, char close) { if (!shape.empty()) { os << open; bool first{true}; for (const auto &shapeSpec : shape) { if (first) { first = false; } else { os << ','; } PutShapeSpec(os, shapeSpec); } os << close; } } void PutObjectEntity(llvm::raw_ostream &os, const Symbol &symbol) { auto &details{symbol.get<ObjectEntityDetails>()}; PutEntity( os, symbol, [&]() { PutType(os, DEREF(symbol.GetType())); }, symbol.attrs()); PutShape(os, details.shape(), '(', ')'); PutShape(os, details.coshape(), '[', ']'); PutInit(os, symbol, details.init()); os << '\n'; } void PutProcEntity(llvm::raw_ostream &os, const Symbol &symbol) { if (symbol.attrs().test(Attr::INTRINSIC)) { os << "intrinsic::" << symbol.name() << '\n'; if (symbol.attrs().test(Attr::PRIVATE)) { os << "private::" << symbol.name() << '\n'; } return; } const auto &details{symbol.get<ProcEntityDetails>()}; const ProcInterface &interface{details.interface()}; Attrs attrs{symbol.attrs()}; if (details.passName()) { attrs.reset(Attr::PASS); } PutEntity( os, symbol, [&]() { os << "procedure("; if (interface.symbol()) { os << interface.symbol()->name(); } else if (interface.type()) { PutType(os, *interface.type()); } os << ')'; PutPassName(os, details.passName()); }, attrs); os << '\n'; } void PutPassName( llvm::raw_ostream &os, const std::optional<SourceName> &passName) { if (passName) { os << ",pass(" << *passName << ')'; } } void PutTypeParam(llvm::raw_ostream &os, const Symbol &symbol) { auto &details{symbol.get<TypeParamDetails>()}; PutEntity( os, symbol, [&]() { PutType(os, DEREF(symbol.GetType())); PutLower(os << ',', common::EnumToString(details.attr())); }, symbol.attrs()); PutInit(os, details.init()); os << '\n'; } void PutInit( llvm::raw_ostream &os, const Symbol &symbol, const MaybeExpr &init) { if (init) { if (symbol.attrs().test(Attr::PARAMETER) || symbol.owner().IsDerivedType()) { os << (symbol.attrs().test(Attr::POINTER) ? "=>" : "="); init->AsFortran(os); } } } void PutInit(llvm::raw_ostream &os, const MaybeIntExpr &init) { if (init) { init->AsFortran(os << '='); } } void PutBound(llvm::raw_ostream &os, const Bound &x) { if (x.isAssumed()) { os << '*'; } else if (x.isDeferred()) { os << ':'; } else { x.GetExplicit()->AsFortran(os); } } // Write an entity (object or procedure) declaration. // writeType is called to write out the type. void PutEntity(llvm::raw_ostream &os, const Symbol &symbol, std::function<void()> writeType, Attrs attrs) { writeType(); PutAttrs(os, attrs, symbol.GetBindName()); os << "::" << symbol.name(); } // Put out each attribute to os, surrounded by `before` and `after` and // mapped to lower case. llvm::raw_ostream &PutAttrs(llvm::raw_ostream &os, Attrs attrs, const std::string *bindName, std::string before, std::string after) { attrs.set(Attr::PUBLIC, false); // no need to write PUBLIC attrs.set(Attr::EXTERNAL, false); // no need to write EXTERNAL if (bindName) { os << before << "bind(c, name=\"" << *bindName << "\")" << after; attrs.set(Attr::BIND_C, false); } for (std::size_t i{0}; i < Attr_enumSize; ++i) { Attr attr{static_cast<Attr>(i)}; if (attrs.test(attr)) { PutAttr(os << before, attr) << after; } } return os; } llvm::raw_ostream &PutAttr(llvm::raw_ostream &os, Attr attr) { return PutLower(os, AttrToString(attr)); } llvm::raw_ostream &PutType(llvm::raw_ostream &os, const DeclTypeSpec &type) { return PutLower(os, type.AsFortran()); } llvm::raw_ostream &PutLower(llvm::raw_ostream &os, const std::string &str) { for (char c : str) { os << parser::ToLowerCaseLetter(c); } return os; } struct Temp { Temp(int fd, std::string path) : fd{fd}, path{path} {} Temp(Temp &&t) : fd{std::exchange(t.fd, -1)}, path{std::move(t.path)} {} ~Temp() { if (fd >= 0) { llvm::sys::fs::file_t native{llvm::sys::fs::convertFDToNativeFile(fd)}; llvm::sys::fs::closeFile(native); llvm::sys::fs::remove(path.c_str()); } } int fd; std::string path; }; // Create a temp file in the same directory and with the same suffix as path. // Return an open file descriptor and its path. static llvm::ErrorOr<Temp> MkTemp(const std::string &path) { auto length{path.length()}; auto dot{path.find_last_of("./")}; std::string suffix{ dot < length && path[dot] == '.' ? path.substr(dot + 1) : ""}; CHECK(length > suffix.length() && path.substr(length - suffix.length()) == suffix); auto prefix{path.substr(0, length - suffix.length())}; int fd; llvm::SmallString<16> tempPath; if (std::error_code err{llvm::sys::fs::createUniqueFile( prefix + "%%%%%%" + suffix, fd, tempPath)}) { return err; } return Temp{fd, tempPath.c_str()}; } // Write the module file at path, prepending header. If an error occurs, // return errno, otherwise 0. static std::error_code WriteFile( const std::string &path, const std::string &contents, bool debug) { auto header{std::string{ModHeader::bom} + ModHeader::magic + CheckSum(contents) + ModHeader::terminator}; if (debug) { llvm::dbgs() << "Processing module " << path << ": "; } if (FileContentsMatch(path, header, contents)) { if (debug) { llvm::dbgs() << "module unchanged, not writing\n"; } return {}; } llvm::ErrorOr<Temp> temp{MkTemp(path)}; if (!temp) { return temp.getError(); } llvm::raw_fd_ostream writer(temp->fd, /*shouldClose=*/false); writer << header; writer << contents; writer.flush(); if (writer.has_error()) { return writer.error(); } if (debug) { llvm::dbgs() << "module written\n"; } return llvm::sys::fs::rename(temp->path, path); } // Return true if the stream matches what we would write for the mod file. static bool FileContentsMatch(const std::string &path, const std::string &header, const std::string &contents) { std::size_t hsize{header.size()}; std::size_t csize{contents.size()}; auto buf_or{llvm::MemoryBuffer::getFile(path)}; if (!buf_or) { return false; } auto buf = std::move(buf_or.get()); if (buf->getBufferSize() != hsize + csize) { return false; } if (!std::equal(header.begin(), header.end(), buf->getBufferStart(), buf->getBufferStart() + hsize)) { return false; } return std::equal(contents.begin(), contents.end(), buf->getBufferStart() + hsize, buf->getBufferEnd()); } // Compute a simple hash of the contents of a module file and // return it as a string of hex digits. // This uses the Fowler-Noll-Vo hash function. static std::string CheckSum(const std::string_view &contents) { std::uint64_t hash{0xcbf29ce484222325ull}; for (char c : contents) { hash ^= c & 0xff; hash *= 0x100000001b3; } static const char *digits = "0123456789abcdef"; std::string result(ModHeader::sumLen, '0'); for (size_t i{ModHeader::sumLen}; hash != 0; hash >>= 4) { result[--i] = digits[hash & 0xf]; } return result; } static bool VerifyHeader(llvm::ArrayRef<char> content) { std::string_view sv{content.data(), content.size()}; if (sv.substr(0, ModHeader::magicLen) != ModHeader::magic) { return false; } std::string_view expectSum{sv.substr(ModHeader::magicLen, ModHeader::sumLen)}; std::string actualSum{CheckSum(sv.substr(ModHeader::len))}; return expectSum == actualSum; } Scope *ModFileReader::Read(const SourceName &name, Scope *ancestor) { std::string ancestorName; // empty for module if (ancestor) { if (auto *scope{ancestor->FindSubmodule(name)}) { return scope; } ancestorName = ancestor->GetName().value().ToString(); } else { auto it{context_.globalScope().find(name)}; if (it != context_.globalScope().end()) { return it->second->scope(); } } parser::Parsing parsing{context_.allCookedSources()}; parser::Options options; options.isModuleFile = true; options.features.Enable(common::LanguageFeature::BackslashEscapes); options.searchDirectories = context_.searchDirectories(); auto path{ModFileName(name, ancestorName, context_.moduleFileSuffix())}; const auto *sourceFile{parsing.Prescan(path, options)}; if (parsing.messages().AnyFatalError()) { for (auto &msg : parsing.messages().messages()) { std::string str{msg.ToString()}; Say(name, ancestorName, parser::MessageFixedText{str.c_str(), str.size()}, path); } return nullptr; } CHECK(sourceFile); if (!VerifyHeader(sourceFile->content())) { Say(name, ancestorName, "File has invalid checksum: %s"_en_US, sourceFile->path()); return nullptr; } llvm::raw_null_ostream NullStream; parsing.Parse(NullStream); auto &parseTree{parsing.parseTree()}; if (!parsing.messages().empty() || !parsing.consumedWholeFile() || !parseTree) { Say(name, ancestorName, "Module file is corrupt: %s"_err_en_US, sourceFile->path()); return nullptr; } Scope *parentScope; // the scope this module/submodule goes into if (!ancestor) { parentScope = &context_.globalScope(); } else if (std::optional<SourceName> parent{GetSubmoduleParent(*parseTree)}) { parentScope = Read(*parent, ancestor); } else { parentScope = ancestor; } auto pair{parentScope->try_emplace(name, UnknownDetails{})}; if (!pair.second) { return nullptr; } Symbol &modSymbol{*pair.first->second}; modSymbol.set(Symbol::Flag::ModFile); ResolveNames(context_, *parseTree); CHECK(modSymbol.has<ModuleDetails>()); CHECK(modSymbol.test(Symbol::Flag::ModFile)); return modSymbol.scope(); } parser::Message &ModFileReader::Say(const SourceName &name, const std::string &ancestor, parser::MessageFixedText &&msg, const std::string &arg) { return context_.Say(name, "Cannot read module file for %s: %s"_err_en_US, parser::MessageFormattedText{ancestor.empty() ? "module '%s'"_en_US : "submodule '%s' of module '%s'"_en_US, name, ancestor} .MoveString(), parser::MessageFormattedText{std::move(msg), arg}.MoveString()); } // program was read from a .mod file for a submodule; return the name of the // submodule's parent submodule, nullptr if none. static std::optional<SourceName> GetSubmoduleParent( const parser::Program &program) { CHECK(program.v.size() == 1); auto &unit{program.v.front()}; auto &submod{std::get<common::Indirection<parser::Submodule>>(unit.u)}; auto &stmt{ std::get<parser::Statement<parser::SubmoduleStmt>>(submod.value().t)}; auto &parentId{std::get<parser::ParentIdentifier>(stmt.statement.t)}; if (auto &parent{std::get<std::optional<parser::Name>>(parentId.t)}) { return parent->source; } else { return std::nullopt; } } void SubprogramSymbolCollector::Collect() { const auto &details{symbol_.get<SubprogramDetails>()}; isInterface_ = details.isInterface(); for (const Symbol *dummyArg : details.dummyArgs()) { if (dummyArg) { DoSymbol(*dummyArg); } } if (details.isFunction()) { DoSymbol(details.result()); } for (const auto &pair : scope_) { const Symbol &symbol{*pair.second}; if (const auto *useDetails{symbol.detailsIf<UseDetails>()}) { if (useSet_.count(useDetails->symbol().GetUltimate()) > 0) { need_.push_back(symbol); } } } } void SubprogramSymbolCollector::DoSymbol(const Symbol &symbol) { DoSymbol(symbol.name(), symbol); } // Do symbols this one depends on; then add to need_ void SubprogramSymbolCollector::DoSymbol( const SourceName &name, const Symbol &symbol) { const auto &scope{symbol.owner()}; if (scope != scope_ && !scope.IsDerivedType()) { if (scope != scope_.parent()) { useSet_.insert(symbol); } if (NeedImport(name, symbol)) { imports_.insert(name); } return; } if (!needSet_.insert(symbol).second) { return; // already done } std::visit(common::visitors{ [this](const ObjectEntityDetails &details) { for (const ShapeSpec &spec : details.shape()) { DoBound(spec.lbound()); DoBound(spec.ubound()); } for (const ShapeSpec &spec : details.coshape()) { DoBound(spec.lbound()); DoBound(spec.ubound()); } if (const Symbol * commonBlock{details.commonBlock()}) { DoSymbol(*commonBlock); } }, [this](const CommonBlockDetails &details) { for (const auto &object : details.objects()) { DoSymbol(*object); } }, [](const auto &) {}, }, symbol.details()); if (!symbol.has<UseDetails>()) { DoType(symbol.GetType()); } if (!scope.IsDerivedType()) { need_.push_back(symbol); } } void SubprogramSymbolCollector::DoType(const DeclTypeSpec *type) { if (!type) { return; } switch (type->category()) { case DeclTypeSpec::Numeric: case DeclTypeSpec::Logical: break; // nothing to do case DeclTypeSpec::Character: DoParamValue(type->characterTypeSpec().length()); break; default: if (const DerivedTypeSpec * derived{type->AsDerived()}) { const auto &typeSymbol{derived->typeSymbol()}; if (const DerivedTypeSpec * extends{typeSymbol.GetParentTypeSpec()}) { DoSymbol(extends->name(), extends->typeSymbol()); } for (const auto &pair : derived->parameters()) { DoParamValue(pair.second); } for (const auto &pair : *typeSymbol.scope()) { const Symbol &comp{*pair.second}; DoSymbol(comp); } DoSymbol(derived->name(), derived->typeSymbol()); } } } void SubprogramSymbolCollector::DoBound(const Bound &bound) { if (const MaybeSubscriptIntExpr & expr{bound.GetExplicit()}) { DoExpr(*expr); } } void SubprogramSymbolCollector::DoParamValue(const ParamValue ¶mValue) { if (const auto &expr{paramValue.GetExplicit()}) { DoExpr(*expr); } } // Do we need a IMPORT of this symbol into an interface block? bool SubprogramSymbolCollector::NeedImport( const SourceName &name, const Symbol &symbol) { if (!isInterface_) { return false; } else if (symbol.owner().Contains(scope_)) { return true; } else if (const Symbol * found{scope_.FindSymbol(name)}) { // detect import from ancestor of use-associated symbol return found->has<UseDetails>() && found->owner() != scope_; } else { // "found" can be null in the case of a use-associated derived type's parent // type CHECK(symbol.has<DerivedTypeDetails>()); return false; } } } // namespace Fortran::semantics