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

413 lines
13 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-do.h"
#include "canonicalize-omp.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-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::map<const char *, 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().begin(), *pair.second);
}
for (const auto &pair : scope.commonBlocks()) {
symbols.emplace(pair.second->name().begin(), *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<AllocateChecker,
ArithmeticIfStmtChecker, AssignmentChecker, CaseChecker, CoarrayChecker,
DataChecker, DeallocateChecker, DoForallChecker, IfStmtChecker, IoChecker,
MiscChecker, NamelistChecker, NullifyChecker, OmpStructureChecker,
PurityChecker, ReturnStmtChecker, StopChecker>;
static bool PerformStatementSemantics(
SemanticsContext &context, parser::Program &program) {
ResolveNames(context, program);
RewriteParseTree(context, program);
ComputeOffsets(context);
CheckDeclarations(context);
StatementSemanticsPass1{context}.Walk(program);
StatementSemanticsPass2{context}.Walk(program);
return !context.AnyFatalError();
}
SemanticsContext::SemanticsContext(
const common::IntrinsicTypeDefaultKinds &defaultKinds,
const common::LanguageFeatureControl &languageFeatures,
parser::AllSources &allSources)
: defaultKinds_{defaultKinds}, languageFeatures_{languageFeatures},
allSources_{allSources},
intrinsics_{evaluate::IntrinsicProcTable::Configure(defaultKinds_)},
foldingContext_{
parser::ContextualMessages{&messages_}, defaultKinds_, intrinsics_} {}
SemanticsContext::~SemanticsContext() {}
int SemanticsContext::GetDefaultKind(TypeCategory category) const {
return defaultKinds_.GetDefaultKind(category);
}
bool SemanticsContext::IsEnabled(common::LanguageFeature feature) const {
return languageFeatures_.IsEnabled(feature);
}
bool SemanticsContext::ShouldWarn(common::LanguageFeature feature) const {
return languageFeatures_.ShouldWarn(feature);
}
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 CheckError(symbol.test(Symbol::Flag::Error));
}
bool SemanticsContext::HasError(const Symbol *symbol) {
return CheckError(!symbol || HasError(*symbol));
}
bool SemanticsContext::HasError(const parser::Name &name) {
return HasError(name.symbol);
}
void SemanticsContext::SetError(Symbol &symbol, bool value) {
if (value) {
CHECK(AnyFatalError());
symbol.set(Symbol::Flag::Error);
}
}
bool SemanticsContext::CheckError(bool error) {
CHECK(!error || AnyFatalError());
return error;
}
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");
}
}
void SemanticsContext::PopConstruct() {
CHECK(!constructStack_.empty());
constructStack_.pop_back();
}
void SemanticsContext::CheckIndexVarRedefine(const parser::CharBlock &location,
const Symbol &variable, parser::MessageFixedText &&message) {
if (const Symbol * root{GetAssociationRoot(variable)}) {
auto it{activeIndexVars_.find(*root)};
if (it != activeIndexVars_.end()) {
std::string kind{EnumToString(it->second.kind)};
Say(location, std::move(message), kind, root->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'"_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}) {
if (const Symbol * root{GetAssociationRoot(*indexVar)}) {
activeIndexVars_.emplace(*root, IndexVarInfo{name.source, kind});
}
}
}
void SemanticsContext::DeactivateIndexVar(const parser::Name &name) {
if (Symbol * indexVar{name.symbol}) {
if (const Symbol * root{GetAssociationRoot(*indexVar)}) {
auto it{activeIndexVars_.find(*root)};
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;
}
bool Semantics::Perform() {
return ValidateLabels(context_, program_) &&
parser::CanonicalizeDo(program_) && // force line break
CanonicalizeOmp(context_.messages(), program_) &&
PerformStatementSemantics(context_, program_) &&
ModFileWriter{context_}.WriteAll();
}
void Semantics::EmitMessages(llvm::raw_ostream &os) const {
context_.messages().Emit(os, cooked_);
}
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);
for (const auto &pair : symbols) {
const Symbol &symbol{pair.second};
if (auto sourceInfo{cooked_.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.size()) {
os << " size=" << scope.size() << " align=" << scope.align();
}
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