llvm-project/flang/lib/Evaluate/characteristics.cpp

1028 lines
35 KiB
C++

//===-- lib/Evaluate/characteristics.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/Evaluate/characteristics.h"
#include "flang/Common/indirection.h"
#include "flang/Evaluate/check-expression.h"
#include "flang/Evaluate/fold.h"
#include "flang/Evaluate/intrinsics.h"
#include "flang/Evaluate/tools.h"
#include "flang/Evaluate/type.h"
#include "flang/Parser/message.h"
#include "flang/Semantics/scope.h"
#include "flang/Semantics/symbol.h"
#include "llvm/Support/raw_ostream.h"
#include <initializer_list>
using namespace Fortran::parser::literals;
namespace Fortran::evaluate::characteristics {
// Copy attributes from a symbol to dst based on the mapping in pairs.
template <typename A, typename B>
static void CopyAttrs(const semantics::Symbol &src, A &dst,
const std::initializer_list<std::pair<semantics::Attr, B>> &pairs) {
for (const auto &pair : pairs) {
if (src.attrs().test(pair.first)) {
dst.attrs.set(pair.second);
}
}
}
// Shapes of function results and dummy arguments have to have
// the same rank, the same deferred dimensions, and the same
// values for explicit dimensions when constant.
bool ShapesAreCompatible(const Shape &x, const Shape &y) {
if (x.size() != y.size()) {
return false;
}
auto yIter{y.begin()};
for (const auto &xDim : x) {
const auto &yDim{*yIter++};
if (xDim) {
if (!yDim || ToInt64(*xDim) != ToInt64(*yDim)) {
return false;
}
} else if (yDim) {
return false;
}
}
return true;
}
bool TypeAndShape::operator==(const TypeAndShape &that) const {
return type_ == that.type_ && ShapesAreCompatible(shape_, that.shape_) &&
attrs_ == that.attrs_ && corank_ == that.corank_;
}
std::optional<TypeAndShape> TypeAndShape::Characterize(
const semantics::Symbol &symbol, FoldingContext &context) {
return std::visit(
common::visitors{
[&](const semantics::ObjectEntityDetails &object) {
return Characterize(object);
},
[&](const semantics::ProcEntityDetails &proc) {
const semantics::ProcInterface &interface{proc.interface()};
if (interface.type()) {
return Characterize(*interface.type());
} else if (interface.symbol()) {
return Characterize(*interface.symbol(), context);
} else {
return std::optional<TypeAndShape>{};
}
},
[&](const semantics::UseDetails &use) {
return Characterize(use.symbol(), context);
},
[&](const semantics::HostAssocDetails &assoc) {
return Characterize(assoc.symbol(), context);
},
[&](const semantics::AssocEntityDetails &assoc) {
return Characterize(assoc, context);
},
[](const auto &) { return std::optional<TypeAndShape>{}; },
},
symbol.details());
}
std::optional<TypeAndShape> TypeAndShape::Characterize(
const semantics::ObjectEntityDetails &object) {
if (auto type{DynamicType::From(object.type())}) {
TypeAndShape result{std::move(*type)};
result.AcquireShape(object);
return result;
} else {
return std::nullopt;
}
}
std::optional<TypeAndShape> TypeAndShape::Characterize(
const semantics::AssocEntityDetails &assoc, FoldingContext &context) {
if (auto type{DynamicType::From(assoc.type())}) {
if (auto shape{GetShape(context, assoc.expr())}) {
return TypeAndShape{std::move(*type), std::move(*shape)};
}
}
return std::nullopt;
}
std::optional<TypeAndShape> TypeAndShape::Characterize(
const semantics::DeclTypeSpec &spec) {
if (auto type{DynamicType::From(spec)}) {
return TypeAndShape{std::move(*type)};
} else {
return std::nullopt;
}
}
bool TypeAndShape::IsCompatibleWith(parser::ContextualMessages &messages,
const TypeAndShape &that, const char *thisIs, const char *thatIs,
bool isElemental) const {
const auto &len{that.LEN()};
if (!type_.IsTypeCompatibleWith(that.type_)) {
messages.Say(
"%1$s type '%2$s' is not compatible with %3$s type '%4$s'"_err_en_US,
thatIs, that.type_.AsFortran(len ? len->AsFortran() : ""), thisIs,
type_.AsFortran());
return false;
}
return isElemental ||
CheckConformance(messages, shape_, that.shape_, thisIs, thatIs);
}
void TypeAndShape::AcquireShape(const semantics::ObjectEntityDetails &object) {
CHECK(shape_.empty() && !attrs_.test(Attr::AssumedRank));
corank_ = object.coshape().Rank();
if (object.IsAssumedRank()) {
attrs_.set(Attr::AssumedRank);
return;
}
if (object.IsAssumedShape()) {
attrs_.set(Attr::AssumedShape);
}
if (object.IsAssumedSize()) {
attrs_.set(Attr::AssumedSize);
}
if (object.IsDeferredShape()) {
attrs_.set(Attr::DeferredShape);
}
if (object.IsCoarray()) {
attrs_.set(Attr::Coarray);
}
for (const semantics::ShapeSpec &dim : object.shape()) {
if (dim.ubound().GetExplicit()) {
Expr<SubscriptInteger> extent{*dim.ubound().GetExplicit()};
if (auto lbound{dim.lbound().GetExplicit()}) {
extent =
std::move(extent) + Expr<SubscriptInteger>{1} - std::move(*lbound);
}
shape_.emplace_back(std::move(extent));
} else {
shape_.push_back(std::nullopt);
}
}
}
void TypeAndShape::AcquireLEN() {
if (type_.category() == TypeCategory::Character) {
if (const auto *param{type_.charLength()}) {
if (const auto &intExpr{param->GetExplicit()}) {
LEN_ = *intExpr;
}
}
}
}
llvm::raw_ostream &TypeAndShape::Dump(llvm::raw_ostream &o) const {
o << type_.AsFortran(LEN_ ? LEN_->AsFortran() : "");
attrs_.Dump(o, EnumToString);
if (!shape_.empty()) {
o << " dimension(";
char sep{'('};
for (const auto &expr : shape_) {
o << sep;
sep = ',';
if (expr) {
expr->AsFortran(o);
} else {
o << ':';
}
}
o << ')';
}
return o;
}
bool DummyDataObject::operator==(const DummyDataObject &that) const {
return type == that.type && attrs == that.attrs && intent == that.intent &&
coshape == that.coshape;
}
static common::Intent GetIntent(const semantics::Attrs &attrs) {
if (attrs.test(semantics::Attr::INTENT_IN)) {
return common::Intent::In;
} else if (attrs.test(semantics::Attr::INTENT_OUT)) {
return common::Intent::Out;
} else if (attrs.test(semantics::Attr::INTENT_INOUT)) {
return common::Intent::InOut;
} else {
return common::Intent::Default;
}
}
std::optional<DummyDataObject> DummyDataObject::Characterize(
const semantics::Symbol &symbol) {
if (const auto *obj{symbol.detailsIf<semantics::ObjectEntityDetails>()}) {
if (auto type{TypeAndShape::Characterize(*obj)}) {
std::optional<DummyDataObject> result{std::move(*type)};
using semantics::Attr;
CopyAttrs<DummyDataObject, DummyDataObject::Attr>(symbol, *result,
{
{Attr::OPTIONAL, DummyDataObject::Attr::Optional},
{Attr::ALLOCATABLE, DummyDataObject::Attr::Allocatable},
{Attr::ASYNCHRONOUS, DummyDataObject::Attr::Asynchronous},
{Attr::CONTIGUOUS, DummyDataObject::Attr::Contiguous},
{Attr::VALUE, DummyDataObject::Attr::Value},
{Attr::VOLATILE, DummyDataObject::Attr::Volatile},
{Attr::POINTER, DummyDataObject::Attr::Pointer},
{Attr::TARGET, DummyDataObject::Attr::Target},
});
result->intent = GetIntent(symbol.attrs());
return result;
}
}
return std::nullopt;
}
bool DummyDataObject::CanBePassedViaImplicitInterface() const {
if ((attrs &
Attrs{Attr::Allocatable, Attr::Asynchronous, Attr::Optional,
Attr::Pointer, Attr::Target, Attr::Value, Attr::Volatile})
.any()) {
return false; // 15.4.2.2(3)(a)
} else if ((type.attrs() &
TypeAndShape::Attrs{TypeAndShape::Attr::AssumedShape,
TypeAndShape::Attr::AssumedRank,
TypeAndShape::Attr::Coarray})
.any()) {
return false; // 15.4.2.2(3)(b-d)
} else if (type.type().IsPolymorphic()) {
return false; // 15.4.2.2(3)(f)
} else if (const auto *derived{GetDerivedTypeSpec(type.type())}) {
return derived->parameters().empty(); // 15.4.2.2(3)(e)
} else {
return true;
}
}
llvm::raw_ostream &DummyDataObject::Dump(llvm::raw_ostream &o) const {
attrs.Dump(o, EnumToString);
if (intent != common::Intent::Default) {
o << "INTENT(" << common::EnumToString(intent) << ')';
}
type.Dump(o);
if (!coshape.empty()) {
char sep{'['};
for (const auto &expr : coshape) {
expr.AsFortran(o << sep);
sep = ',';
}
}
return o;
}
DummyProcedure::DummyProcedure(Procedure &&p)
: procedure{new Procedure{std::move(p)}} {}
bool DummyProcedure::operator==(const DummyProcedure &that) const {
return attrs == that.attrs && intent == that.intent &&
procedure.value() == that.procedure.value();
}
std::optional<DummyProcedure> DummyProcedure::Characterize(
const semantics::Symbol &symbol, const IntrinsicProcTable &intrinsics) {
if (auto procedure{Procedure::Characterize(symbol, intrinsics)}) {
// Dummy procedures may not be elemental. Elemental dummy procedure
// interfaces are errors when the interface is not intrinsic, and that
// error is caught elsewhere. Elemental intrinsic interfaces are
// made non-elemental.
procedure->attrs.reset(Procedure::Attr::Elemental);
DummyProcedure result{std::move(procedure.value())};
CopyAttrs<DummyProcedure, DummyProcedure::Attr>(symbol, result,
{
{semantics::Attr::OPTIONAL, DummyProcedure::Attr::Optional},
{semantics::Attr::POINTER, DummyProcedure::Attr::Pointer},
});
result.intent = GetIntent(symbol.attrs());
return result;
} else {
return std::nullopt;
}
}
llvm::raw_ostream &DummyProcedure::Dump(llvm::raw_ostream &o) const {
attrs.Dump(o, EnumToString);
if (intent != common::Intent::Default) {
o << "INTENT(" << common::EnumToString(intent) << ')';
}
procedure.value().Dump(o);
return o;
}
llvm::raw_ostream &AlternateReturn::Dump(llvm::raw_ostream &o) const {
return o << '*';
}
DummyArgument::~DummyArgument() {}
bool DummyArgument::operator==(const DummyArgument &that) const {
return u == that.u; // name and passed-object usage are not characteristics
}
std::optional<DummyArgument> DummyArgument::Characterize(
const semantics::Symbol &symbol, const IntrinsicProcTable &intrinsics) {
auto name{symbol.name().ToString()};
if (symbol.has<semantics::ObjectEntityDetails>()) {
if (auto obj{DummyDataObject::Characterize(symbol)}) {
return DummyArgument{std::move(name), std::move(obj.value())};
}
} else if (auto proc{DummyProcedure::Characterize(symbol, intrinsics)}) {
return DummyArgument{std::move(name), std::move(proc.value())};
}
return std::nullopt;
}
std::optional<DummyArgument> DummyArgument::FromActual(
std::string &&name, const Expr<SomeType> &expr, FoldingContext &context) {
return std::visit(
common::visitors{
[&](const BOZLiteralConstant &) {
return std::make_optional<DummyArgument>(std::move(name),
DummyDataObject{
TypeAndShape{DynamicType::TypelessIntrinsicArgument()}});
},
[](const NullPointer &) { return std::optional<DummyArgument>{}; },
[&](const ProcedureDesignator &designator) {
if (auto proc{Procedure::Characterize(
designator, context.intrinsics())}) {
return std::make_optional<DummyArgument>(
std::move(name), DummyProcedure{std::move(*proc)});
} else {
return std::optional<DummyArgument>{};
}
},
[&](const ProcedureRef &call) {
if (auto proc{
Procedure::Characterize(call, context.intrinsics())}) {
return std::make_optional<DummyArgument>(
std::move(name), DummyProcedure{std::move(*proc)});
} else {
return std::optional<DummyArgument>{};
}
},
[&](const auto &) {
if (auto type{expr.GetType()}) {
if (auto shape{GetShape(context, expr)}) {
return std::make_optional<DummyArgument>(std::move(name),
DummyDataObject{TypeAndShape{*type, std::move(*shape)}});
} else {
return std::make_optional<DummyArgument>(
std::move(name), DummyDataObject{TypeAndShape{*type}});
}
} else {
return std::optional<DummyArgument>{};
}
},
},
expr.u);
}
bool DummyArgument::IsOptional() const {
return std::visit(
common::visitors{
[](const DummyDataObject &data) {
return data.attrs.test(DummyDataObject::Attr::Optional);
},
[](const DummyProcedure &proc) {
return proc.attrs.test(DummyProcedure::Attr::Optional);
},
[](const AlternateReturn &) { return false; },
},
u);
}
void DummyArgument::SetOptional(bool value) {
std::visit(common::visitors{
[value](DummyDataObject &data) {
data.attrs.set(DummyDataObject::Attr::Optional, value);
},
[value](DummyProcedure &proc) {
proc.attrs.set(DummyProcedure::Attr::Optional, value);
},
[](AlternateReturn &) { DIE("cannot set optional"); },
},
u);
}
bool DummyArgument::CanBePassedViaImplicitInterface() const {
if (const auto *object{std::get_if<DummyDataObject>(&u)}) {
return object->CanBePassedViaImplicitInterface();
} else {
return true;
}
}
llvm::raw_ostream &DummyArgument::Dump(llvm::raw_ostream &o) const {
if (!name.empty()) {
o << name << '=';
}
if (pass) {
o << " PASS";
}
std::visit([&](const auto &x) { x.Dump(o); }, u);
return o;
}
FunctionResult::FunctionResult(DynamicType t) : u{TypeAndShape{t}} {}
FunctionResult::FunctionResult(TypeAndShape &&t) : u{std::move(t)} {}
FunctionResult::FunctionResult(Procedure &&p) : u{std::move(p)} {}
FunctionResult::~FunctionResult() {}
bool FunctionResult::operator==(const FunctionResult &that) const {
return attrs == that.attrs && u == that.u;
}
std::optional<FunctionResult> FunctionResult::Characterize(
const Symbol &symbol, const IntrinsicProcTable &intrinsics) {
if (const auto *obj{symbol.detailsIf<semantics::ObjectEntityDetails>()}) {
if (auto type{TypeAndShape::Characterize(*obj)}) {
FunctionResult result{std::move(*type)};
CopyAttrs<FunctionResult, FunctionResult::Attr>(symbol, result,
{
{semantics::Attr::ALLOCATABLE, FunctionResult::Attr::Allocatable},
{semantics::Attr::CONTIGUOUS, FunctionResult::Attr::Contiguous},
{semantics::Attr::POINTER, FunctionResult::Attr::Pointer},
});
return result;
}
} else if (auto maybeProc{Procedure::Characterize(symbol, intrinsics)}) {
FunctionResult result{std::move(*maybeProc)};
result.attrs.set(FunctionResult::Attr::Pointer);
return result;
}
return std::nullopt;
}
bool FunctionResult::IsAssumedLengthCharacter() const {
if (const auto *ts{std::get_if<TypeAndShape>(&u)}) {
return ts->type().IsAssumedLengthCharacter();
} else {
return false;
}
}
bool FunctionResult::CanBeReturnedViaImplicitInterface() const {
if (attrs.test(Attr::Pointer) || attrs.test(Attr::Allocatable)) {
return false; // 15.4.2.2(4)(b)
} else if (const auto *typeAndShape{GetTypeAndShape()}) {
if (typeAndShape->Rank() > 0) {
return false; // 15.4.2.2(4)(a)
} else {
const DynamicType &type{typeAndShape->type()};
switch (type.category()) {
case TypeCategory::Character:
if (const auto *param{type.charLength()}) {
if (const auto &expr{param->GetExplicit()}) {
return IsConstantExpr(*expr); // 15.4.2.2(4)(c)
}
}
return false;
case TypeCategory::Derived:
if (!type.IsPolymorphic()) {
const auto &spec{type.GetDerivedTypeSpec()};
for (const auto &pair : spec.parameters()) {
if (const auto &expr{pair.second.GetExplicit()}) {
if (!IsConstantExpr(*expr)) {
return false; // 15.4.2.2(4)(c)
}
}
}
return true;
}
return false;
default:
return true;
}
}
} else {
return false; // 15.4.2.2(4)(b) - procedure pointer
}
}
llvm::raw_ostream &FunctionResult::Dump(llvm::raw_ostream &o) const {
attrs.Dump(o, EnumToString);
std::visit(common::visitors{
[&](const TypeAndShape &ts) { ts.Dump(o); },
[&](const CopyableIndirection<Procedure> &p) {
p.value().Dump(o << " procedure(") << ')';
},
},
u);
return o;
}
Procedure::Procedure(FunctionResult &&fr, DummyArguments &&args, Attrs a)
: functionResult{std::move(fr)}, dummyArguments{std::move(args)}, attrs{a} {
}
Procedure::Procedure(DummyArguments &&args, Attrs a)
: dummyArguments{std::move(args)}, attrs{a} {}
Procedure::~Procedure() {}
bool Procedure::operator==(const Procedure &that) const {
return attrs == that.attrs && functionResult == that.functionResult &&
dummyArguments == that.dummyArguments;
}
int Procedure::FindPassIndex(std::optional<parser::CharBlock> name) const {
int argCount{static_cast<int>(dummyArguments.size())};
int index{0};
if (name) {
while (index < argCount && *name != dummyArguments[index].name.c_str()) {
++index;
}
}
CHECK(index < argCount);
return index;
}
bool Procedure::CanOverride(
const Procedure &that, std::optional<int> passIndex) const {
// A pure procedure may override an impure one (7.5.7.3(2))
if ((that.attrs.test(Attr::Pure) && !attrs.test(Attr::Pure)) ||
that.attrs.test(Attr::Elemental) != attrs.test(Attr::Elemental) ||
functionResult != that.functionResult) {
return false;
}
int argCount{static_cast<int>(dummyArguments.size())};
if (argCount != static_cast<int>(that.dummyArguments.size())) {
return false;
}
for (int j{0}; j < argCount; ++j) {
if ((!passIndex || j != *passIndex) &&
dummyArguments[j] != that.dummyArguments[j]) {
return false;
}
}
return true;
}
std::optional<Procedure> Procedure::Characterize(
const semantics::Symbol &original, const IntrinsicProcTable &intrinsics) {
Procedure result;
const auto &symbol{ResolveAssociations(original)};
CopyAttrs<Procedure, Procedure::Attr>(symbol, result,
{
{semantics::Attr::PURE, Procedure::Attr::Pure},
{semantics::Attr::ELEMENTAL, Procedure::Attr::Elemental},
{semantics::Attr::BIND_C, Procedure::Attr::BindC},
});
if (result.attrs.test(Attr::Elemental) &&
!symbol.attrs().test(semantics::Attr::IMPURE)) {
result.attrs.set(Attr::Pure); // explicitly flag pure procedures
}
return std::visit(
common::visitors{
[&](const semantics::SubprogramDetails &subp)
-> std::optional<Procedure> {
if (subp.isFunction()) {
if (auto fr{FunctionResult::Characterize(
subp.result(), intrinsics)}) {
result.functionResult = std::move(fr);
} else {
return std::nullopt;
}
} else {
result.attrs.set(Attr::Subroutine);
}
for (const semantics::Symbol *arg : subp.dummyArgs()) {
if (!arg) {
result.dummyArguments.emplace_back(AlternateReturn{});
} else if (auto argCharacteristics{
DummyArgument::Characterize(*arg, intrinsics)}) {
result.dummyArguments.emplace_back(
std::move(argCharacteristics.value()));
} else {
return std::nullopt;
}
}
return result;
},
[&](const semantics::ProcEntityDetails &proc)
-> std::optional<Procedure> {
if (symbol.attrs().test(semantics::Attr::INTRINSIC)) {
return intrinsics.IsSpecificIntrinsicFunction(
symbol.name().ToString());
}
const semantics::ProcInterface &interface{proc.interface()};
if (const semantics::Symbol * interfaceSymbol{interface.symbol()}) {
return Characterize(*interfaceSymbol, intrinsics);
} else {
result.attrs.set(Attr::ImplicitInterface);
const semantics::DeclTypeSpec *type{interface.type()};
if (symbol.test(semantics::Symbol::Flag::Subroutine)) {
// ignore any implicit typing
result.attrs.set(Attr::Subroutine);
} else if (type) {
if (auto resultType{DynamicType::From(*type)}) {
result.functionResult = FunctionResult{*resultType};
} else {
return std::nullopt;
}
} else if (symbol.test(semantics::Symbol::Flag::Function)) {
return std::nullopt;
}
// The PASS name, if any, is not a characteristic.
return result;
}
},
[&](const semantics::ProcBindingDetails &binding) {
if (auto result{Characterize(binding.symbol(), intrinsics)}) {
if (!symbol.attrs().test(semantics::Attr::NOPASS)) {
auto passName{binding.passName()};
for (auto &dummy : result->dummyArguments) {
if (!passName || dummy.name.c_str() == *passName) {
dummy.pass = true;
return result;
}
}
DIE("PASS argument missing");
}
return result;
} else {
return std::optional<Procedure>{};
}
},
[&](const semantics::UseDetails &use) {
return Characterize(use.symbol(), intrinsics);
},
[&](const semantics::HostAssocDetails &assoc) {
return Characterize(assoc.symbol(), intrinsics);
},
[](const auto &) { return std::optional<Procedure>{}; },
},
symbol.details());
}
std::optional<Procedure> Procedure::Characterize(
const ProcedureDesignator &proc, const IntrinsicProcTable &intrinsics) {
if (const auto *symbol{proc.GetSymbol()}) {
if (auto result{characteristics::Procedure::Characterize(
ResolveAssociations(*symbol), intrinsics)}) {
return result;
}
} else if (const auto *intrinsic{proc.GetSpecificIntrinsic()}) {
return intrinsic->characteristics.value();
}
return std::nullopt;
}
std::optional<Procedure> Procedure::Characterize(
const ProcedureRef &ref, const IntrinsicProcTable &intrinsics) {
if (auto callee{Characterize(ref.proc(), intrinsics)}) {
if (callee->functionResult) {
if (const Procedure *
proc{callee->functionResult->IsProcedurePointer()}) {
return {*proc};
}
}
}
return std::nullopt;
}
bool Procedure::CanBeCalledViaImplicitInterface() const {
if (attrs.test(Attr::Elemental) || attrs.test(Attr::BindC)) {
return false; // 15.4.2.2(5,6)
} else if (IsFunction() &&
!functionResult->CanBeReturnedViaImplicitInterface()) {
return false;
} else {
for (const DummyArgument &arg : dummyArguments) {
if (!arg.CanBePassedViaImplicitInterface()) {
return false;
}
}
return true;
}
}
llvm::raw_ostream &Procedure::Dump(llvm::raw_ostream &o) const {
attrs.Dump(o, EnumToString);
if (functionResult) {
functionResult->Dump(o << "TYPE(") << ") FUNCTION";
} else {
o << "SUBROUTINE";
}
char sep{'('};
for (const auto &dummy : dummyArguments) {
dummy.Dump(o << sep);
sep = ',';
}
return o << (sep == '(' ? "()" : ")");
}
// Utility class to determine if Procedures, etc. are distinguishable
class DistinguishUtils {
public:
// Are these procedures distinguishable for a generic name?
static bool Distinguishable(const Procedure &, const Procedure &);
// Are these procedures distinguishable for a generic operator or assignment?
static bool DistinguishableOpOrAssign(const Procedure &, const Procedure &);
private:
struct CountDummyProcedures {
CountDummyProcedures(const DummyArguments &args) {
for (const DummyArgument &arg : args) {
if (std::holds_alternative<DummyProcedure>(arg.u)) {
total += 1;
notOptional += !arg.IsOptional();
}
}
}
int total{0};
int notOptional{0};
};
static bool Rule3Distinguishable(const Procedure &, const Procedure &);
static const DummyArgument *Rule1DistinguishingArg(
const DummyArguments &, const DummyArguments &);
static int FindFirstToDistinguishByPosition(
const DummyArguments &, const DummyArguments &);
static int FindLastToDistinguishByName(
const DummyArguments &, const DummyArguments &);
static int CountCompatibleWith(const DummyArgument &, const DummyArguments &);
static int CountNotDistinguishableFrom(
const DummyArgument &, const DummyArguments &);
static bool Distinguishable(const DummyArgument &, const DummyArgument &);
static bool Distinguishable(const DummyDataObject &, const DummyDataObject &);
static bool Distinguishable(const DummyProcedure &, const DummyProcedure &);
static bool Distinguishable(const FunctionResult &, const FunctionResult &);
static bool Distinguishable(const TypeAndShape &, const TypeAndShape &);
static bool IsTkrCompatible(const DummyArgument &, const DummyArgument &);
static bool IsTkrCompatible(const TypeAndShape &, const TypeAndShape &);
static const DummyArgument *GetAtEffectivePosition(
const DummyArguments &, int);
static const DummyArgument *GetPassArg(const Procedure &);
};
// Simpler distinguishability rules for operators and assignment
bool DistinguishUtils::DistinguishableOpOrAssign(
const Procedure &proc1, const Procedure &proc2) {
auto &args1{proc1.dummyArguments};
auto &args2{proc2.dummyArguments};
if (args1.size() != args2.size()) {
return true; // C1511: distinguishable based on number of arguments
}
for (std::size_t i{0}; i < args1.size(); ++i) {
if (Distinguishable(args1[i], args2[i])) {
return true; // C1511, C1512: distinguishable based on this arg
}
}
return false;
}
bool DistinguishUtils::Distinguishable(
const Procedure &proc1, const Procedure &proc2) {
auto &args1{proc1.dummyArguments};
auto &args2{proc2.dummyArguments};
auto count1{CountDummyProcedures(args1)};
auto count2{CountDummyProcedures(args2)};
if (count1.notOptional > count2.total || count2.notOptional > count1.total) {
return true; // distinguishable based on C1514 rule 2
}
if (Rule3Distinguishable(proc1, proc2)) {
return true; // distinguishable based on C1514 rule 3
}
if (Rule1DistinguishingArg(args1, args2)) {
return true; // distinguishable based on C1514 rule 1
}
int pos1{FindFirstToDistinguishByPosition(args1, args2)};
int name1{FindLastToDistinguishByName(args1, args2)};
if (pos1 >= 0 && pos1 <= name1) {
return true; // distinguishable based on C1514 rule 4
}
int pos2{FindFirstToDistinguishByPosition(args2, args1)};
int name2{FindLastToDistinguishByName(args2, args1)};
if (pos2 >= 0 && pos2 <= name2) {
return true; // distinguishable based on C1514 rule 4
}
return false;
}
// C1514 rule 3: Procedures are distinguishable if both have a passed-object
// dummy argument and those are distinguishable.
bool DistinguishUtils::Rule3Distinguishable(
const Procedure &proc1, const Procedure &proc2) {
const DummyArgument *pass1{GetPassArg(proc1)};
const DummyArgument *pass2{GetPassArg(proc2)};
return pass1 && pass2 && Distinguishable(*pass1, *pass2);
}
// Find a non-passed-object dummy data object in one of the argument lists
// that satisfies C1514 rule 1. I.e. x such that:
// - m is the number of dummy data objects in one that are nonoptional,
// are not passed-object, that x is TKR compatible with
// - n is the number of non-passed-object dummy data objects, in the other
// that are not distinguishable from x
// - m is greater than n
const DummyArgument *DistinguishUtils::Rule1DistinguishingArg(
const DummyArguments &args1, const DummyArguments &args2) {
auto size1{args1.size()};
auto size2{args2.size()};
for (std::size_t i{0}; i < size1 + size2; ++i) {
const DummyArgument &x{i < size1 ? args1[i] : args2[i - size1]};
if (!x.pass && std::holds_alternative<DummyDataObject>(x.u)) {
if (CountCompatibleWith(x, args1) >
CountNotDistinguishableFrom(x, args2) ||
CountCompatibleWith(x, args2) >
CountNotDistinguishableFrom(x, args1)) {
return &x;
}
}
}
return nullptr;
}
// Find the index of the first nonoptional non-passed-object dummy argument
// in args1 at an effective position such that either:
// - args2 has no dummy argument at that effective position
// - the dummy argument at that position is distinguishable from it
int DistinguishUtils::FindFirstToDistinguishByPosition(
const DummyArguments &args1, const DummyArguments &args2) {
int effective{0}; // position of arg1 in list, ignoring passed arg
for (std::size_t i{0}; i < args1.size(); ++i) {
const DummyArgument &arg1{args1.at(i)};
if (!arg1.pass && !arg1.IsOptional()) {
const DummyArgument *arg2{GetAtEffectivePosition(args2, effective)};
if (!arg2 || Distinguishable(arg1, *arg2)) {
return i;
}
}
effective += !arg1.pass;
}
return -1;
}
// Find the index of the last nonoptional non-passed-object dummy argument
// in args1 whose name is such that either:
// - args2 has no dummy argument with that name
// - the dummy argument with that name is distinguishable from it
int DistinguishUtils::FindLastToDistinguishByName(
const DummyArguments &args1, const DummyArguments &args2) {
std::map<std::string, const DummyArgument *> nameToArg;
for (const auto &arg2 : args2) {
nameToArg.emplace(arg2.name, &arg2);
}
for (int i = args1.size() - 1; i >= 0; --i) {
const DummyArgument &arg1{args1.at(i)};
if (!arg1.pass && !arg1.IsOptional()) {
auto it{nameToArg.find(arg1.name)};
if (it == nameToArg.end() || Distinguishable(arg1, *it->second)) {
return i;
}
}
}
return -1;
}
// Count the dummy data objects in args that are nonoptional, are not
// passed-object, and that x is TKR compatible with
int DistinguishUtils::CountCompatibleWith(
const DummyArgument &x, const DummyArguments &args) {
return std::count_if(args.begin(), args.end(), [&](const DummyArgument &y) {
return !y.pass && !y.IsOptional() && IsTkrCompatible(x, y);
});
}
// Return the number of dummy data objects in args that are not
// distinguishable from x and not passed-object.
int DistinguishUtils::CountNotDistinguishableFrom(
const DummyArgument &x, const DummyArguments &args) {
return std::count_if(args.begin(), args.end(), [&](const DummyArgument &y) {
return !y.pass && std::holds_alternative<DummyDataObject>(y.u) &&
!Distinguishable(y, x);
});
}
bool DistinguishUtils::Distinguishable(
const DummyArgument &x, const DummyArgument &y) {
if (x.u.index() != y.u.index()) {
return true; // different kind: data/proc/alt-return
}
return std::visit(
common::visitors{
[&](const DummyDataObject &z) {
return Distinguishable(z, std::get<DummyDataObject>(y.u));
},
[&](const DummyProcedure &z) {
return Distinguishable(z, std::get<DummyProcedure>(y.u));
},
[&](const AlternateReturn &) { return false; },
},
x.u);
}
bool DistinguishUtils::Distinguishable(
const DummyDataObject &x, const DummyDataObject &y) {
using Attr = DummyDataObject::Attr;
if (Distinguishable(x.type, y.type)) {
return true;
} else if (x.attrs.test(Attr::Allocatable) && y.attrs.test(Attr::Pointer) &&
y.intent != common::Intent::In) {
return true;
} else if (y.attrs.test(Attr::Allocatable) && x.attrs.test(Attr::Pointer) &&
x.intent != common::Intent::In) {
return true;
} else {
return false;
}
}
bool DistinguishUtils::Distinguishable(
const DummyProcedure &x, const DummyProcedure &y) {
const Procedure &xProc{x.procedure.value()};
const Procedure &yProc{y.procedure.value()};
if (Distinguishable(xProc, yProc)) {
return true;
} else {
const std::optional<FunctionResult> &xResult{xProc.functionResult};
const std::optional<FunctionResult> &yResult{yProc.functionResult};
return xResult ? !yResult || Distinguishable(*xResult, *yResult)
: yResult.has_value();
}
}
bool DistinguishUtils::Distinguishable(
const FunctionResult &x, const FunctionResult &y) {
if (x.u.index() != y.u.index()) {
return true; // one is data object, one is procedure
}
return std::visit(
common::visitors{
[&](const TypeAndShape &z) {
return Distinguishable(z, std::get<TypeAndShape>(y.u));
},
[&](const CopyableIndirection<Procedure> &z) {
return Distinguishable(z.value(),
std::get<CopyableIndirection<Procedure>>(y.u).value());
},
},
x.u);
}
bool DistinguishUtils::Distinguishable(
const TypeAndShape &x, const TypeAndShape &y) {
return !IsTkrCompatible(x, y) && !IsTkrCompatible(y, x);
}
// Compatibility based on type, kind, and rank
bool DistinguishUtils::IsTkrCompatible(
const DummyArgument &x, const DummyArgument &y) {
const auto *obj1{std::get_if<DummyDataObject>(&x.u)};
const auto *obj2{std::get_if<DummyDataObject>(&y.u)};
return obj1 && obj2 && IsTkrCompatible(obj1->type, obj2->type);
}
bool DistinguishUtils::IsTkrCompatible(
const TypeAndShape &x, const TypeAndShape &y) {
return x.type().IsTkCompatibleWith(y.type()) &&
(x.attrs().test(TypeAndShape::Attr::AssumedRank) ||
y.attrs().test(TypeAndShape::Attr::AssumedRank) ||
x.Rank() == y.Rank());
}
// Return the argument at the given index, ignoring the passed arg
const DummyArgument *DistinguishUtils::GetAtEffectivePosition(
const DummyArguments &args, int index) {
for (const DummyArgument &arg : args) {
if (!arg.pass) {
if (index == 0) {
return &arg;
}
--index;
}
}
return nullptr;
}
// Return the passed-object dummy argument of this procedure, if any
const DummyArgument *DistinguishUtils::GetPassArg(const Procedure &proc) {
for (const auto &arg : proc.dummyArguments) {
if (arg.pass) {
return &arg;
}
}
return nullptr;
}
bool Distinguishable(const Procedure &x, const Procedure &y) {
return DistinguishUtils::Distinguishable(x, y);
}
bool DistinguishableOpOrAssign(const Procedure &x, const Procedure &y) {
return DistinguishUtils::DistinguishableOpOrAssign(x, y);
}
DEFINE_DEFAULT_CONSTRUCTORS_AND_ASSIGNMENTS(DummyArgument)
DEFINE_DEFAULT_CONSTRUCTORS_AND_ASSIGNMENTS(DummyProcedure)
DEFINE_DEFAULT_CONSTRUCTORS_AND_ASSIGNMENTS(FunctionResult)
DEFINE_DEFAULT_CONSTRUCTORS_AND_ASSIGNMENTS(Procedure)
} // namespace Fortran::evaluate::characteristics
template class Fortran::common::Indirection<
Fortran::evaluate::characteristics::Procedure, true>;