llvm-project/flang/lib/Semantics/semantics.cpp

469 lines
15 KiB
C++

//===-- lib/Semantics/semantics.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 "flang/Semantics/semantics.h"
#include "assignment.h"
#include "canonicalize-acc.h"
#include "canonicalize-do.h"
#include "canonicalize-omp.h"
#include "check-acc-structure.h"
#include "check-allocate.h"
#include "check-arithmeticif.h"
#include "check-case.h"
#include "check-coarray.h"
#include "check-data.h"
#include "check-deallocate.h"
#include "check-declarations.h"
#include "check-do-forall.h"
#include "check-if-stmt.h"
#include "check-io.h"
#include "check-namelist.h"
#include "check-nullify.h"
#include "check-omp-structure.h"
#include "check-purity.h"
#include "check-return.h"
#include "check-select-rank.h"
#include "check-select-type.h"
#include "check-stop.h"
#include "compute-offsets.h"
#include "mod-file.h"
#include "resolve-labels.h"
#include "resolve-names.h"
#include "rewrite-parse-tree.h"
#include "flang/Common/default-kinds.h"
#include "flang/Parser/parse-tree-visitor.h"
#include "flang/Parser/tools.h"
#include "flang/Semantics/expression.h"
#include "flang/Semantics/scope.h"
#include "flang/Semantics/symbol.h"
#include "llvm/Support/raw_ostream.h"
namespace Fortran::semantics {
using NameToSymbolMap = std::multimap<parser::CharBlock, SymbolRef>;
static void DoDumpSymbols(llvm::raw_ostream &, const Scope &, int indent = 0);
static void PutIndent(llvm::raw_ostream &, int indent);
static void GetSymbolNames(const Scope &scope, NameToSymbolMap &symbols) {
// Finds all symbol names in the scope without collecting duplicates.
for (const auto &pair : scope) {
symbols.emplace(pair.second->name(), *pair.second);
}
for (const auto &pair : scope.commonBlocks()) {
symbols.emplace(pair.second->name(), *pair.second);
}
for (const auto &child : scope.children()) {
GetSymbolNames(child, symbols);
}
}
// A parse tree visitor that calls Enter/Leave functions from each checker
// class C supplied as template parameters. Enter is called before the node's
// children are visited, Leave is called after. No two checkers may have the
// same Enter or Leave function. Each checker must be constructible from
// SemanticsContext and have BaseChecker as a virtual base class.
template <typename... C> class SemanticsVisitor : public virtual C... {
public:
using C::Enter...;
using C::Leave...;
using BaseChecker::Enter;
using BaseChecker::Leave;
SemanticsVisitor(SemanticsContext &context)
: C{context}..., context_{context} {}
template <typename N> bool Pre(const N &node) {
if constexpr (common::HasMember<const N *, ConstructNode>) {
context_.PushConstruct(node);
}
Enter(node);
return true;
}
template <typename N> void Post(const N &node) {
Leave(node);
if constexpr (common::HasMember<const N *, ConstructNode>) {
context_.PopConstruct();
}
}
template <typename T> bool Pre(const parser::Statement<T> &node) {
context_.set_location(node.source);
Enter(node);
return true;
}
template <typename T> bool Pre(const parser::UnlabeledStatement<T> &node) {
context_.set_location(node.source);
Enter(node);
return true;
}
template <typename T> void Post(const parser::Statement<T> &node) {
Leave(node);
context_.set_location(std::nullopt);
}
template <typename T> void Post(const parser::UnlabeledStatement<T> &node) {
Leave(node);
context_.set_location(std::nullopt);
}
bool Walk(const parser::Program &program) {
parser::Walk(program, *this);
return !context_.AnyFatalError();
}
private:
SemanticsContext &context_;
};
class MiscChecker : public virtual BaseChecker {
public:
explicit MiscChecker(SemanticsContext &context) : context_{context} {}
void Leave(const parser::EntryStmt &) {
if (!context_.constructStack().empty()) { // C1571
context_.Say("ENTRY may not appear in an executable construct"_err_en_US);
}
}
void Leave(const parser::AssignStmt &stmt) {
CheckAssignGotoName(std::get<parser::Name>(stmt.t));
}
void Leave(const parser::AssignedGotoStmt &stmt) {
CheckAssignGotoName(std::get<parser::Name>(stmt.t));
}
private:
void CheckAssignGotoName(const parser::Name &name) {
if (context_.HasError(name.symbol)) {
return;
}
const Symbol &symbol{DEREF(name.symbol)};
auto type{evaluate::DynamicType::From(symbol)};
if (!IsVariableName(symbol) || symbol.Rank() != 0 || !type ||
type->category() != TypeCategory::Integer ||
type->kind() !=
context_.defaultKinds().GetDefaultKind(TypeCategory::Integer)) {
context_
.Say(name.source,
"'%s' must be a default integer scalar variable"_err_en_US,
name.source)
.Attach(symbol.name(), "Declaration of '%s'"_en_US, symbol.name());
}
}
SemanticsContext &context_;
};
using StatementSemanticsPass1 = ExprChecker;
using StatementSemanticsPass2 = SemanticsVisitor<AccStructureChecker,
AllocateChecker, ArithmeticIfStmtChecker, AssignmentChecker, CaseChecker,
CoarrayChecker, DataChecker, DeallocateChecker, DoForallChecker,
IfStmtChecker, IoChecker, MiscChecker, NamelistChecker, NullifyChecker,
OmpStructureChecker, PurityChecker, ReturnStmtChecker,
SelectRankConstructChecker, SelectTypeChecker, StopChecker>;
static bool PerformStatementSemantics(
SemanticsContext &context, parser::Program &program) {
ResolveNames(context, program, context.globalScope());
RewriteParseTree(context, program);
ComputeOffsets(context, context.globalScope());
CheckDeclarations(context);
StatementSemanticsPass1{context}.Walk(program);
StatementSemanticsPass2 pass2{context};
pass2.Walk(program);
if (!context.AnyFatalError()) {
pass2.CompileDataInitializationsIntoInitializers();
}
return !context.AnyFatalError();
}
SemanticsContext::SemanticsContext(
const common::IntrinsicTypeDefaultKinds &defaultKinds,
const common::LanguageFeatureControl &languageFeatures,
parser::AllCookedSources &allCookedSources)
: defaultKinds_{defaultKinds}, languageFeatures_{languageFeatures},
allCookedSources_{allCookedSources},
intrinsics_{evaluate::IntrinsicProcTable::Configure(defaultKinds_)},
globalScope_{*this}, intrinsicModulesScope_{globalScope_.MakeScope(
Scope::Kind::IntrinsicModules, nullptr)},
foldingContext_{
parser::ContextualMessages{&messages_}, defaultKinds_, intrinsics_} {}
SemanticsContext::~SemanticsContext() {}
int SemanticsContext::GetDefaultKind(TypeCategory category) const {
return defaultKinds_.GetDefaultKind(category);
}
const DeclTypeSpec &SemanticsContext::MakeNumericType(
TypeCategory category, int kind) {
if (kind == 0) {
kind = GetDefaultKind(category);
}
return globalScope_.MakeNumericType(category, KindExpr{kind});
}
const DeclTypeSpec &SemanticsContext::MakeLogicalType(int kind) {
if (kind == 0) {
kind = GetDefaultKind(TypeCategory::Logical);
}
return globalScope_.MakeLogicalType(KindExpr{kind});
}
bool SemanticsContext::AnyFatalError() const {
return !messages_.empty() &&
(warningsAreErrors_ || messages_.AnyFatalError());
}
bool SemanticsContext::HasError(const Symbol &symbol) {
return errorSymbols_.count(symbol) > 0;
}
bool SemanticsContext::HasError(const Symbol *symbol) {
return !symbol || HasError(*symbol);
}
bool SemanticsContext::HasError(const parser::Name &name) {
return HasError(name.symbol);
}
void SemanticsContext::SetError(const Symbol &symbol, bool value) {
if (value) {
CheckError(symbol);
errorSymbols_.emplace(symbol);
}
}
void SemanticsContext::CheckError(const Symbol &symbol) {
if (!AnyFatalError()) {
std::string buf;
llvm::raw_string_ostream ss{buf};
ss << symbol;
common::die(
"No error was reported but setting error on: %s", ss.str().c_str());
}
}
const Scope &SemanticsContext::FindScope(parser::CharBlock source) const {
return const_cast<SemanticsContext *>(this)->FindScope(source);
}
Scope &SemanticsContext::FindScope(parser::CharBlock source) {
if (auto *scope{globalScope_.FindScope(source)}) {
return *scope;
} else {
common::die(
"SemanticsContext::FindScope(): invalid source location for '%s'",
source.ToString().c_str());
}
}
void SemanticsContext::PopConstruct() {
CHECK(!constructStack_.empty());
constructStack_.pop_back();
}
void SemanticsContext::CheckIndexVarRedefine(const parser::CharBlock &location,
const Symbol &variable, parser::MessageFixedText &&message) {
const Symbol &symbol{ResolveAssociations(variable)};
auto it{activeIndexVars_.find(symbol)};
if (it != activeIndexVars_.end()) {
std::string kind{EnumToString(it->second.kind)};
Say(location, std::move(message), kind, symbol.name())
.Attach(it->second.location, "Enclosing %s construct"_en_US, kind);
}
}
void SemanticsContext::WarnIndexVarRedefine(
const parser::CharBlock &location, const Symbol &variable) {
CheckIndexVarRedefine(location, variable,
"Possible redefinition of %s variable '%s'"_warn_en_US);
}
void SemanticsContext::CheckIndexVarRedefine(
const parser::CharBlock &location, const Symbol &variable) {
CheckIndexVarRedefine(
location, variable, "Cannot redefine %s variable '%s'"_err_en_US);
}
void SemanticsContext::CheckIndexVarRedefine(const parser::Variable &variable) {
if (const Symbol * entity{GetLastName(variable).symbol}) {
CheckIndexVarRedefine(variable.GetSource(), *entity);
}
}
void SemanticsContext::CheckIndexVarRedefine(const parser::Name &name) {
if (const Symbol * entity{name.symbol}) {
CheckIndexVarRedefine(name.source, *entity);
}
}
void SemanticsContext::ActivateIndexVar(
const parser::Name &name, IndexVarKind kind) {
CheckIndexVarRedefine(name);
if (const Symbol * indexVar{name.symbol}) {
activeIndexVars_.emplace(
ResolveAssociations(*indexVar), IndexVarInfo{name.source, kind});
}
}
void SemanticsContext::DeactivateIndexVar(const parser::Name &name) {
if (Symbol * indexVar{name.symbol}) {
auto it{activeIndexVars_.find(ResolveAssociations(*indexVar))};
if (it != activeIndexVars_.end() && it->second.location == name.source) {
activeIndexVars_.erase(it);
}
}
}
SymbolVector SemanticsContext::GetIndexVars(IndexVarKind kind) {
SymbolVector result;
for (const auto &[symbol, info] : activeIndexVars_) {
if (info.kind == kind) {
result.push_back(symbol);
}
}
return result;
}
SourceName SemanticsContext::SaveTempName(std::string &&name) {
return {*tempNames_.emplace(std::move(name)).first};
}
SourceName SemanticsContext::GetTempName(const Scope &scope) {
for (const auto &str : tempNames_) {
if (IsTempName(str)) {
SourceName name{str};
if (scope.find(name) == scope.end()) {
return name;
}
}
}
return SaveTempName(".F18."s + std::to_string(tempNames_.size()));
}
bool SemanticsContext::IsTempName(const std::string &name) {
return name.size() > 5 && name.substr(0, 5) == ".F18.";
}
Scope *SemanticsContext::GetBuiltinModule(const char *name) {
return ModFileReader{*this}.Read(SourceName{name, std::strlen(name)},
true /*intrinsic*/, nullptr, true /*silence errors*/);
}
void SemanticsContext::UseFortranBuiltinsModule() {
if (builtinsScope_ == nullptr) {
builtinsScope_ = GetBuiltinModule("__fortran_builtins");
if (builtinsScope_) {
intrinsics_.SupplyBuiltins(*builtinsScope_);
}
}
}
bool Semantics::Perform() {
// Implicitly USE the __Fortran_builtins module so that special types
// (e.g., __builtin_team_type) are available to semantics, esp. for
// intrinsic checking.
if (!program_.v.empty()) {
const auto *frontModule{std::get_if<common::Indirection<parser::Module>>(
&program_.v.front().u)};
if (frontModule &&
std::get<parser::Statement<parser::ModuleStmt>>(frontModule->value().t)
.statement.v.source == "__fortran_builtins") {
// Don't try to read the builtins module when we're actually building it.
} else {
context_.UseFortranBuiltinsModule();
}
}
return ValidateLabels(context_, program_) &&
parser::CanonicalizeDo(program_) && // force line break
CanonicalizeAcc(context_.messages(), program_) &&
CanonicalizeOmp(context_.messages(), program_) &&
PerformStatementSemantics(context_, program_) &&
ModFileWriter{context_}.WriteAll();
}
void Semantics::EmitMessages(llvm::raw_ostream &os) const {
context_.messages().Emit(os, context_.allCookedSources());
}
void Semantics::DumpSymbols(llvm::raw_ostream &os) {
DoDumpSymbols(os, context_.globalScope());
}
void Semantics::DumpSymbolsSources(llvm::raw_ostream &os) const {
NameToSymbolMap symbols;
GetSymbolNames(context_.globalScope(), symbols);
const parser::AllCookedSources &allCooked{context_.allCookedSources()};
for (const auto &pair : symbols) {
const Symbol &symbol{pair.second};
if (auto sourceInfo{allCooked.GetSourcePositionRange(symbol.name())}) {
os << symbol.name().ToString() << ": " << sourceInfo->first.file.path()
<< ", " << sourceInfo->first.line << ", " << sourceInfo->first.column
<< "-" << sourceInfo->second.column << "\n";
} else if (symbol.has<semantics::UseDetails>()) {
os << symbol.name().ToString() << ": "
<< symbol.GetUltimate().owner().symbol()->name().ToString() << "\n";
}
}
}
void DoDumpSymbols(llvm::raw_ostream &os, const Scope &scope, int indent) {
PutIndent(os, indent);
os << Scope::EnumToString(scope.kind()) << " scope:";
if (const auto *symbol{scope.symbol()}) {
os << ' ' << symbol->name();
}
if (scope.alignment().has_value()) {
os << " size=" << scope.size() << " alignment=" << *scope.alignment();
}
if (scope.derivedTypeSpec()) {
os << " instantiation of " << *scope.derivedTypeSpec();
}
os << '\n';
++indent;
for (const auto &pair : scope) {
const auto &symbol{*pair.second};
PutIndent(os, indent);
os << symbol << '\n';
if (const auto *details{symbol.detailsIf<GenericDetails>()}) {
if (const auto &type{details->derivedType()}) {
PutIndent(os, indent);
os << *type << '\n';
}
}
}
if (!scope.equivalenceSets().empty()) {
PutIndent(os, indent);
os << "Equivalence Sets:";
for (const auto &set : scope.equivalenceSets()) {
os << ' ';
char sep = '(';
for (const auto &object : set) {
os << sep << object.AsFortran();
sep = ',';
}
os << ')';
}
os << '\n';
}
if (!scope.crayPointers().empty()) {
PutIndent(os, indent);
os << "Cray Pointers:";
for (const auto &[pointee, pointer] : scope.crayPointers()) {
os << " (" << pointer->name() << ',' << pointee << ')';
}
}
for (const auto &pair : scope.commonBlocks()) {
const auto &symbol{*pair.second};
PutIndent(os, indent);
os << symbol << '\n';
}
for (const auto &child : scope.children()) {
DoDumpSymbols(os, child, indent);
}
--indent;
}
static void PutIndent(llvm::raw_ostream &os, int indent) {
for (int i = 0; i < indent; ++i) {
os << " ";
}
}
} // namespace Fortran::semantics