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llvm-project/flang/lib/Semantics/scope.cpp
Tim Keith c353ebbfa4 [flang] Compute sizes and offsets for symbols 
Summary:
Add size and offset properties to symbols, representing their byte size
and offset within their enclosing scope.

Add size and align properties to scopes so that they are available for
scopes representing derived types.

Add ComputeOffsets pass over the symbol table to fill in those fields.

Compute descriptor size based on rank and length parameters. Extract
DerivedTypeSpec::NumLengthParameters from DynamicType::RequiresDescriptor
to share the code.

Add Scope::GetSymbols to get symbols in canonical order.
compute-offsets.cpp and mod-file.cpp both need to process symbols in the
order in which they are declared. Move the collecting of those symbols
into Scope so that it can be shared.

Add symbol size and offset to output of `-fdebug-dump-symbols` and use
that in some tests.

Still to do:
- make size and alignment rules configurable based on target
- use offsets to check EQUIVALENCE statements

Differential Revision: https://reviews.llvm.org/D78680
2020-04-23 14:54:34 -07:00

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//===-- lib/Semantics/scope.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/scope.h"
#include "flang/Parser/characters.h"
#include "flang/Semantics/symbol.h"
#include "flang/Semantics/type.h"
#include "llvm/Support/raw_ostream.h"
#include <algorithm>
#include <memory>
namespace Fortran::semantics {
Symbols<1024> Scope::allSymbols;
bool EquivalenceObject::operator==(const EquivalenceObject &that) const {
return symbol == that.symbol && subscripts == that.subscripts &&
substringStart == that.substringStart;
}
bool EquivalenceObject::operator<(const EquivalenceObject &that) const {
return &symbol < &that.symbol ||
(&symbol == &that.symbol &&
(subscripts < that.subscripts ||
(subscripts == that.subscripts &&
substringStart < that.substringStart)));
}
std::string EquivalenceObject::AsFortran() const {
std::string buf;
llvm::raw_string_ostream ss{buf};
ss << symbol.name().ToString();
if (!subscripts.empty()) {
char sep{'('};
for (auto subscript : subscripts) {
ss << sep << subscript;
sep = ',';
}
ss << ')';
}
if (substringStart) {
ss << '(' << *substringStart << ":)";
}
return ss.str();
}
bool Scope::IsModule() const {
return kind_ == Kind::Module && !symbol_->get<ModuleDetails>().isSubmodule();
}
bool Scope::IsSubmodule() const {
return kind_ == Kind::Module && symbol_->get<ModuleDetails>().isSubmodule();
}
Scope &Scope::MakeScope(Kind kind, Symbol *symbol) {
return children_.emplace_back(*this, kind, symbol);
}
template <typename T>
static std::vector<common::Reference<T>> GetSortedSymbols(
std::map<SourceName, common::Reference<Symbol>> symbols) {
std::vector<common::Reference<T>> result;
result.reserve(symbols.size());
for (auto &pair : symbols) {
result.push_back(*pair.second);
}
std::sort(result.begin(), result.end());
return result;
}
std::vector<common::Reference<Symbol>> Scope::GetSymbols() {
return GetSortedSymbols<Symbol>(symbols_);
}
SymbolVector Scope::GetSymbols() const {
return GetSortedSymbols<const Symbol>(symbols_);
}
Scope::iterator Scope::find(const SourceName &name) {
return symbols_.find(name);
}
Scope::size_type Scope::erase(const SourceName &name) {
auto it{symbols_.find(name)};
if (it != end()) {
symbols_.erase(it);
return 1;
} else {
return 0;
}
}
Symbol *Scope::FindSymbol(const SourceName &name) const {
auto it{find(name)};
if (it != end()) {
return &*it->second;
} else if (CanImport(name)) {
return parent_.FindSymbol(name);
} else {
return nullptr;
}
}
Symbol *Scope::FindComponent(SourceName name) const {
CHECK(IsDerivedType());
auto found{find(name)};
if (found != end()) {
return &*found->second;
} else if (const Scope * parent{GetDerivedTypeParent()}) {
return parent->FindComponent(name);
} else {
return nullptr;
}
}
std::optional<SourceName> Scope::GetName() const {
if (const auto *sym{GetSymbol()}) {
return sym->name();
} else {
return std::nullopt;
}
}
bool Scope::Contains(const Scope &that) const {
for (const Scope *scope{&that};; scope = &scope->parent()) {
if (*scope == *this) {
return true;
}
if (scope->IsGlobal()) {
return false;
}
}
}
Symbol *Scope::CopySymbol(const Symbol &symbol) {
auto pair{try_emplace(symbol.name(), symbol.attrs())};
if (!pair.second) {
return nullptr; // already exists
} else {
Symbol &result{*pair.first->second};
result.flags() = symbol.flags();
result.set_details(common::Clone(symbol.details()));
return &result;
}
}
const std::list<EquivalenceSet> &Scope::equivalenceSets() const {
return equivalenceSets_;
}
void Scope::add_equivalenceSet(EquivalenceSet &&set) {
equivalenceSets_.emplace_back(std::move(set));
}
void Scope::add_crayPointer(const SourceName &name, Symbol &pointer) {
CHECK(pointer.test(Symbol::Flag::CrayPointer));
crayPointers_.emplace(name, pointer);
}
Symbol &Scope::MakeCommonBlock(const SourceName &name) {
const auto it{commonBlocks_.find(name)};
if (it != commonBlocks_.end()) {
return *it->second;
} else {
Symbol &symbol{MakeSymbol(name, Attrs{}, CommonBlockDetails{})};
commonBlocks_.emplace(name, symbol);
return symbol;
}
}
Symbol *Scope::FindCommonBlock(const SourceName &name) {
const auto it{commonBlocks_.find(name)};
return it != commonBlocks_.end() ? &*it->second : nullptr;
}
Scope *Scope::FindSubmodule(const SourceName &name) const {
auto it{submodules_.find(name)};
if (it == submodules_.end()) {
return nullptr;
} else {
return &*it->second;
}
}
bool Scope::AddSubmodule(const SourceName &name, Scope &submodule) {
return submodules_.emplace(name, submodule).second;
}
const DeclTypeSpec *Scope::FindType(const DeclTypeSpec &type) const {
auto it{std::find(declTypeSpecs_.begin(), declTypeSpecs_.end(), type)};
return it != declTypeSpecs_.end() ? &*it : nullptr;
}
const DeclTypeSpec &Scope::MakeNumericType(
TypeCategory category, KindExpr &&kind) {
return MakeLengthlessType(NumericTypeSpec{category, std::move(kind)});
}
const DeclTypeSpec &Scope::MakeLogicalType(KindExpr &&kind) {
return MakeLengthlessType(LogicalTypeSpec{std::move(kind)});
}
const DeclTypeSpec &Scope::MakeTypeStarType() {
return MakeLengthlessType(DeclTypeSpec{DeclTypeSpec::TypeStar});
}
const DeclTypeSpec &Scope::MakeClassStarType() {
return MakeLengthlessType(DeclTypeSpec{DeclTypeSpec::ClassStar});
}
// Types that can't have length parameters can be reused without having to
// compare length expressions. They are stored in the global scope.
const DeclTypeSpec &Scope::MakeLengthlessType(DeclTypeSpec &&type) {
const auto *found{FindType(type)};
return found ? *found : declTypeSpecs_.emplace_back(std::move(type));
}
const DeclTypeSpec &Scope::MakeCharacterType(
ParamValue &&length, KindExpr &&kind) {
return declTypeSpecs_.emplace_back(
CharacterTypeSpec{std::move(length), std::move(kind)});
}
DeclTypeSpec &Scope::MakeDerivedType(
DeclTypeSpec::Category category, DerivedTypeSpec &&spec) {
return declTypeSpecs_.emplace_back(category, std::move(spec));
}
void Scope::set_chars(parser::CookedSource &cooked) {
CHECK(kind_ == Kind::Module);
CHECK(parent_.IsGlobal() || parent_.IsModuleFile());
CHECK(DEREF(symbol_).test(Symbol::Flag::ModFile));
// TODO: Preserve the CookedSource rather than acquiring its string.
chars_ = cooked.AcquireData();
}
Scope::ImportKind Scope::GetImportKind() const {
if (importKind_) {
return *importKind_;
}
if (symbol_ && !symbol_->attrs().test(Attr::MODULE)) {
if (auto *details{symbol_->detailsIf<SubprogramDetails>()}) {
if (details->isInterface()) {
return ImportKind::None; // default for non-mod-proc interface body
}
}
}
return ImportKind::Default;
}
std::optional<parser::MessageFixedText> Scope::SetImportKind(ImportKind kind) {
if (!importKind_) {
importKind_ = kind;
return std::nullopt;
}
bool hasNone{kind == ImportKind::None || *importKind_ == ImportKind::None};
bool hasAll{kind == ImportKind::All || *importKind_ == ImportKind::All};
// Check C8100 and C898: constraints on multiple IMPORT statements
if (hasNone || hasAll) {
return hasNone
? "IMPORT,NONE must be the only IMPORT statement in a scope"_err_en_US
: "IMPORT,ALL must be the only IMPORT statement in a scope"_err_en_US;
} else if (kind != *importKind_ &&
(kind != ImportKind::Only || kind != ImportKind::Only)) {
return "Every IMPORT must have ONLY specifier if one of them does"_err_en_US;
} else {
return std::nullopt;
}
}
void Scope::add_importName(const SourceName &name) {
importNames_.insert(name);
}
// true if name can be imported or host-associated from parent scope.
bool Scope::CanImport(const SourceName &name) const {
if (IsGlobal() || parent_.IsGlobal()) {
return false;
}
switch (GetImportKind()) {
SWITCH_COVERS_ALL_CASES
case ImportKind::None:
return false;
case ImportKind::All:
case ImportKind::Default:
return true;
case ImportKind::Only:
return importNames_.count(name) > 0;
}
}
const Scope *Scope::FindScope(parser::CharBlock source) const {
return const_cast<Scope *>(this)->FindScope(source);
}
Scope *Scope::FindScope(parser::CharBlock source) {
bool isContained{sourceRange_.Contains(source)};
if (!isContained && !IsGlobal() && !IsModuleFile()) {
return nullptr;
}
for (auto &child : children_) {
if (auto *scope{child.FindScope(source)}) {
return scope;
}
}
return isContained ? this : nullptr;
}
void Scope::AddSourceRange(const parser::CharBlock &source) {
for (auto *scope = this; !scope->IsGlobal(); scope = &scope->parent()) {
scope->sourceRange_.ExtendToCover(source);
}
}
llvm::raw_ostream &operator<<(llvm::raw_ostream &os, const Scope &scope) {
os << Scope::EnumToString(scope.kind()) << " scope: ";
if (auto *symbol{scope.symbol()}) {
os << *symbol << ' ';
}
if (scope.derivedTypeSpec_) {
os << "instantiation of " << *scope.derivedTypeSpec_ << ' ';
}
os << scope.children_.size() << " children\n";
for (const auto &pair : scope.symbols_) {
const Symbol &symbol{*pair.second};
os << " " << symbol << '\n';
}
if (!scope.equivalenceSets_.empty()) {
os << " Equivalence Sets:\n";
for (const auto &set : scope.equivalenceSets_) {
os << " ";
for (const auto &object : set) {
os << ' ' << object.AsFortran();
}
os << '\n';
}
}
for (const auto &pair : scope.commonBlocks_) {
const Symbol &symbol{*pair.second};
os << " " << symbol << '\n';
}
return os;
}
bool Scope::IsParameterizedDerivedType() const {
if (!IsDerivedType()) {
return false;
}
if (const Scope * parent{GetDerivedTypeParent()}) {
if (parent->IsParameterizedDerivedType()) {
return true;
}
}
for (const auto &pair : symbols_) {
if (pair.second->has<TypeParamDetails>()) {
return true;
}
}
return false;
}
const DeclTypeSpec *Scope::FindInstantiatedDerivedType(
const DerivedTypeSpec &spec, DeclTypeSpec::Category category) const {
DeclTypeSpec type{category, spec};
if (const auto *result{FindType(type)}) {
return result;
} else if (IsGlobal()) {
return nullptr;
} else {
return parent().FindInstantiatedDerivedType(spec, category);
}
}
const Symbol *Scope::GetSymbol() const {
if (symbol_) {
return symbol_;
}
if (derivedTypeSpec_) {
return &derivedTypeSpec_->typeSymbol();
}
return nullptr;
}
const Scope *Scope::GetDerivedTypeParent() const {
if (const Symbol * symbol{GetSymbol()}) {
if (const DerivedTypeSpec * parent{symbol->GetParentTypeSpec(this)}) {
return parent->scope();
}
}
return nullptr;
}
const Scope &Scope::GetDerivedTypeBase() const {
const Scope *child{this};
for (const Scope *parent{GetDerivedTypeParent()}; parent != nullptr;
parent = child->GetDerivedTypeParent()) {
child = parent;
}
return *child;
}
void Scope::InstantiateDerivedTypes(SemanticsContext &context) {
for (DeclTypeSpec &type : declTypeSpecs_) {
if (type.category() == DeclTypeSpec::TypeDerived ||
type.category() == DeclTypeSpec::ClassDerived) {
type.derivedTypeSpec().Instantiate(*this, context);
}
}
}
} // namespace Fortran::semantics
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