flang/lib/Semantics/check-case.cpp - llvm-project - Git at Google

 //===-- lib/Semantics/check-case.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 "check-case.h"
 #include "flang/Common/idioms.h"
 #include "flang/Common/reference.h"
 #include "flang/Common/template.h"
 #include "flang/Evaluate/fold.h"
 #include "flang/Evaluate/type.h"
 #include "flang/Parser/parse-tree.h"
 #include "flang/Semantics/semantics.h"
 #include "flang/Semantics/tools.h"
 #include <tuple>

 namespace Fortran::semantics {

 template <typename T> class CaseValues {
 public:
   CaseValues(SemanticsContext &c, const evaluate::DynamicType &t)
       : context_{c}, caseExprType_{t} {}

   void Check(const std::list<parser::CaseConstruct::Case> &cases) {
     for (const parser::CaseConstruct::Case &c : cases) {
       AddCase(c);
     }
     if (!hasErrors_) {
       cases_.sort(Comparator{});
       if (!AreCasesDisjoint()) { // C1149
         ReportConflictingCases();
       }
     }
   }

 private:
   using Value = evaluate::Scalar<T>;

   void AddCase(const parser::CaseConstruct::Case &c) {
     const auto &stmt{std::get<parser::Statement<parser::CaseStmt>>(c.t)};
     const parser::CaseStmt &caseStmt{stmt.statement};
     const auto &selector{std::get<parser::CaseSelector>(caseStmt.t)};
     std::visit(
         common::visitors{
             [&](const std::list<parser::CaseValueRange> &ranges) {
               for (const auto &range : ranges) {
                 auto pair{ComputeBounds(range)};
                 if (pair.first && pair.second && *pair.first > *pair.second) {
                   context_.Say(stmt.source,
                       "CASE has lower bound greater than upper bound"_en_US);
                 } else {
                   if constexpr (T::category == TypeCategory::Logical) { // C1148
                     if ((pair.first || pair.second) &&
                         (!pair.first || !pair.second ||
                             *pair.first != *pair.second)) {
                       context_.Say(stmt.source,
                           "CASE range is not allowed for LOGICAL"_err_en_US);
                     }
                   }
                   cases_.emplace_back(stmt);
                   cases_.back().lower = std::move(pair.first);
                   cases_.back().upper = std::move(pair.second);
                 }
               }
             },
             [&](const parser::Default &) { cases_.emplace_front(stmt); },
         },
         selector.u);
   }

   std::optional<Value> GetValue(const parser::CaseValue &caseValue) {
     const parser::Expr &expr{caseValue.thing.thing.value()};
     auto *x{expr.typedExpr.get()};
     if (x && x->v) { // C1147
       auto type{x->v->GetType()};
       if (type && type->category() == caseExprType_.category() &&
           (type->category() != TypeCategory::Character ||
               type->kind() == caseExprType_.kind())) {
         x->v = evaluate::Fold(context_.foldingContext(),
             evaluate::ConvertToType(T::GetType(), std::move(*x->v)));
         if (x->v) {
           if (auto value{evaluate::GetScalarConstantValue<T>(*x->v)}) {
             return *value;
           }
         }
         context_.Say(
             expr.source, "CASE value must be a constant scalar"_err_en_US);
       } else {
         std::string typeStr{type ? type->AsFortran() : "typeless"s};
         context_.Say(expr.source,
             "CASE value has type '%s' which is not compatible with the SELECT CASE expression's type '%s'"_err_en_US,
             typeStr, caseExprType_.AsFortran());
       }
       hasErrors_ = true;
     }
     return std::nullopt;
   }

   using PairOfValues = std::pair<std::optional<Value>, std::optional<Value>>;
   PairOfValues ComputeBounds(const parser::CaseValueRange &range) {
     return std::visit(common::visitors{
                           [&](const parser::CaseValue &x) {
                             auto value{GetValue(x)};
                             return PairOfValues{value, value};
                           },
                           [&](const parser::CaseValueRange::Range &x) {
                             std::optional<Value> lo, hi;
                             if (x.lower) {
                               lo = GetValue(*x.lower);
                             }
                             if (x.upper) {
                               hi = GetValue(*x.upper);
                             }
                             if ((x.lower && !lo) || (x.upper && !hi)) {
                               return PairOfValues{}; // error case
                             }
                             return PairOfValues{std::move(lo), std::move(hi)};
                           },
                       },
         range.u);
   }

   struct Case {
     explicit Case(const parser::Statement<parser::CaseStmt> &s) : stmt{s} {}
     bool IsDefault() const { return !lower && !upper; }
     std::string AsFortran() const {
       std::string result;
       {
         llvm::raw_string_ostream bs{result};
         if (lower) {
           evaluate::Constant<T>{*lower}.AsFortran(bs << '(');
           if (!upper) {
             bs << ':';
           } else if (*lower != *upper) {
             evaluate::Constant<T>{*upper}.AsFortran(bs << ':');
           }
           bs << ')';
         } else if (upper) {
           evaluate::Constant<T>{*upper}.AsFortran(bs << "(:") << ')';
         } else {
           bs << "DEFAULT";
         }
       }
       return result;
     }

     const parser::Statement<parser::CaseStmt> &stmt;
     std::optional<Value> lower, upper;
   };

   // Defines a comparator for use with std::list<>::sort().
   // Returns true if and only if the highest value in range x is less
   // than the least value in range y.  The DEFAULT case is arbitrarily
   // defined to be less than all others.  When two ranges overlap,
   // neither is less than the other.
   struct Comparator {
     bool operator()(const Case &x, const Case &y) const {
       if (x.IsDefault()) {
         return !y.IsDefault();
       } else {
         return x.upper && y.lower && *x.upper < *y.lower;
       }
     }
   };

   bool AreCasesDisjoint() const {
     auto endIter{cases_.end()};
     for (auto iter{cases_.begin()}; iter != endIter; ++iter) {
       auto next{iter};
       if (++next != endIter && !Comparator{}(*iter, *next)) {
         return false;
       }
     }
     return true;
   }

   // This has quadratic time, but only runs in error cases
   void ReportConflictingCases() {
     for (auto iter{cases_.begin()}; iter != cases_.end(); ++iter) {
       parser::Message *msg{nullptr};
       for (auto p{cases_.begin()}; p != cases_.end(); ++p) {
         if (p->stmt.source.begin() < iter->stmt.source.begin() &&
             !Comparator{}(*p, *iter) && !Comparator{}(*iter, *p)) {
           if (!msg) {
             msg = &context_.Say(iter->stmt.source,
                 "CASE %s conflicts with previous cases"_err_en_US,
                 iter->AsFortran());
           }
           msg->Attach(
               p->stmt.source, "Conflicting CASE %s"_en_US, p->AsFortran());
         }
       }
     }
   }

   SemanticsContext &context_;
   const evaluate::DynamicType &caseExprType_;
   std::list<Case> cases_;
   bool hasErrors_{false};
 };

 template <TypeCategory CAT> struct TypeVisitor {
   using Result = bool;
   using Types = evaluate::CategoryTypes<CAT>;
   template <typename T> Result Test() {
     if (T::kind == exprType.kind()) {
       CaseValues<T>(context, exprType).Check(caseList);
       return true;
     } else {
       return false;
     }
   }
   SemanticsContext &context;
   const evaluate::DynamicType &exprType;
   const std::list<parser::CaseConstruct::Case> &caseList;
 };

 void CaseChecker::Enter(const parser::CaseConstruct &construct) {
   const auto &selectCaseStmt{
       std::get<parser::Statement<parser::SelectCaseStmt>>(construct.t)};
   const auto &selectCase{selectCaseStmt.statement};
   const auto &selectExpr{
       std::get<parser::Scalar<parser::Expr>>(selectCase.t).thing};
   const auto *x{GetExpr(selectExpr)};
   if (!x) {
     return; // expression semantics failed
   }
   if (auto exprType{x->GetType()}) {
     const auto &caseList{
         std::get<std::list<parser::CaseConstruct::Case>>(construct.t)};
     switch (exprType->category()) {
     case TypeCategory::Integer:
       common::SearchTypes(
           TypeVisitor<TypeCategory::Integer>{context_, *exprType, caseList});
       return;
     case TypeCategory::Logical:
       CaseValues<evaluate::Type<TypeCategory::Logical, 1>>{context_, *exprType}
           .Check(caseList);
       return;
     case TypeCategory::Character:
       common::SearchTypes(
           TypeVisitor<TypeCategory::Character>{context_, *exprType, caseList});
       return;
     default:
       break;
     }
   }
   context_.Say(selectExpr.source,
       "SELECT CASE expression must be integer, logical, or character"_err_en_US);
 }
 } // namespace Fortran::semantics
	//===-- lib/Semantics/check-case.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 "check-case.h"
	#include "flang/Common/idioms.h"
	#include "flang/Common/reference.h"
	#include "flang/Common/template.h"
	#include "flang/Evaluate/fold.h"
	#include "flang/Evaluate/type.h"
	#include "flang/Parser/parse-tree.h"
	#include "flang/Semantics/semantics.h"
	#include "flang/Semantics/tools.h"
	#include <tuple>

	namespace Fortran::semantics {

	template <typename T> class CaseValues {
	public:
	CaseValues(SemanticsContext &c, const evaluate::DynamicType &t)
	: context_{c}, caseExprType_{t} {}

	void Check(const std::list<parser::CaseConstruct::Case> &cases) {
	for (const parser::CaseConstruct::Case &c : cases) {
	AddCase(c);
	}
	if (!hasErrors_) {
	cases_.sort(Comparator{});
	if (!AreCasesDisjoint()) { // C1149
	ReportConflictingCases();
	}
	}
	}

	private:
	using Value = evaluate::Scalar<T>;

	void AddCase(const parser::CaseConstruct::Case &c) {
	const auto &stmt{std::get<parser::Statement<parser::CaseStmt>>(c.t)};
	const parser::CaseStmt &caseStmt{stmt.statement};
	const auto &selector{std::get<parser::CaseSelector>(caseStmt.t)};
	std::visit(
	common::visitors{
	[&](const std::list<parser::CaseValueRange> &ranges) {
	for (const auto &range : ranges) {
	auto pair{ComputeBounds(range)};
	if (pair.first && pair.second && pair.first > pair.second) {
	context_.Say(stmt.source,
	"CASE has lower bound greater than upper bound"_en_US);
	} else {
	if constexpr (T::category == TypeCategory::Logical) { // C1148
	if ((pair.first \|\| pair.second) &&
	(!pair.first \|\| !pair.second \|\|
	pair.first != pair.second)) {
	context_.Say(stmt.source,
	"CASE range is not allowed for LOGICAL"_err_en_US);
	}
	}
	cases_.emplace_back(stmt);
	cases_.back().lower = std::move(pair.first);
	cases_.back().upper = std::move(pair.second);
	}
	}
	},
	[&](const parser::Default &) { cases_.emplace_front(stmt); },
	},
	selector.u);
	}

	std::optional<Value> GetValue(const parser::CaseValue &caseValue) {
	const parser::Expr &expr{caseValue.thing.thing.value()};
	auto *x{expr.typedExpr.get()};
	if (x && x->v) { // C1147
	auto type{x->v->GetType()};
	if (type && type->category() == caseExprType_.category() &&
	(type->category() != TypeCategory::Character \|\|
	type->kind() == caseExprType_.kind())) {
	x->v = evaluate::Fold(context_.foldingContext(),
	evaluate::ConvertToType(T::GetType(), std::move(*x->v)));
	if (x->v) {
	if (auto value{evaluate::GetScalarConstantValue<T>(*x->v)}) {
	return *value;
	}
	}
	context_.Say(
	expr.source, "CASE value must be a constant scalar"_err_en_US);
	} else {
	std::string typeStr{type ? type->AsFortran() : "typeless"s};
	context_.Say(expr.source,
	"CASE value has type '%s' which is not compatible with the SELECT CASE expression's type '%s'"_err_en_US,
	typeStr, caseExprType_.AsFortran());
	}
	hasErrors_ = true;
	}
	return std::nullopt;
	}

	using PairOfValues = std::pair<std::optional<Value>, std::optional<Value>>;
	PairOfValues ComputeBounds(const parser::CaseValueRange &range) {
	return std::visit(common::visitors{
	[&](const parser::CaseValue &x) {
	auto value{GetValue(x)};
	return PairOfValues{value, value};
	},
	[&](const parser::CaseValueRange::Range &x) {
	std::optional<Value> lo, hi;
	if (x.lower) {
	lo = GetValue(*x.lower);
	}
	if (x.upper) {
	hi = GetValue(*x.upper);
	}
	if ((x.lower && !lo) \|\| (x.upper && !hi)) {
	return PairOfValues{}; // error case
	}
	return PairOfValues{std::move(lo), std::move(hi)};
	},
	},
	range.u);
	}

	struct Case {
	explicit Case(const parser::Statement<parser::CaseStmt> &s) : stmt{s} {}
	bool IsDefault() const { return !lower && !upper; }
	std::string AsFortran() const {
	std::string result;
	{
	llvm::raw_string_ostream bs{result};
	if (lower) {
	evaluate::Constant<T>{*lower}.AsFortran(bs << '(');
	if (!upper) {
	bs << ':';
	} else if (lower != upper) {
	evaluate::Constant<T>{*upper}.AsFortran(bs << ':');
	}
	bs << ')';
	} else if (upper) {
	evaluate::Constant<T>{*upper}.AsFortran(bs << "(:") << ')';
	} else {
	bs << "DEFAULT";
	}
	}
	return result;
	}

	const parser::Statement<parser::CaseStmt> &stmt;
	std::optional<Value> lower, upper;
	};

	// Defines a comparator for use with std::list<>::sort().
	// Returns true if and only if the highest value in range x is less
	// than the least value in range y. The DEFAULT case is arbitrarily
	// defined to be less than all others. When two ranges overlap,
	// neither is less than the other.
	struct Comparator {
	bool operator()(const Case &x, const Case &y) const {
	if (x.IsDefault()) {
	return !y.IsDefault();
	} else {
	return x.upper && y.lower && x.upper < y.lower;
	}
	}
	};

	bool AreCasesDisjoint() const {
	auto endIter{cases_.end()};
	for (auto iter{cases_.begin()}; iter != endIter; ++iter) {
	auto next{iter};
	if (++next != endIter && !Comparator{}(iter, next)) {
	return false;
	}
	}
	return true;
	}

	// This has quadratic time, but only runs in error cases
	void ReportConflictingCases() {
	for (auto iter{cases_.begin()}; iter != cases_.end(); ++iter) {
	parser::Message *msg{nullptr};
	for (auto p{cases_.begin()}; p != cases_.end(); ++p) {
	if (p->stmt.source.begin() < iter->stmt.source.begin() &&
	!Comparator{}(p, iter) && !Comparator{}(iter, p)) {
	if (!msg) {
	msg = &context_.Say(iter->stmt.source,
	"CASE %s conflicts with previous cases"_err_en_US,
	iter->AsFortran());
	}
	msg->Attach(
	p->stmt.source, "Conflicting CASE %s"_en_US, p->AsFortran());
	}
	}
	}
	}

	SemanticsContext &context_;
	const evaluate::DynamicType &caseExprType_;
	std::list<Case> cases_;
	bool hasErrors_{false};
	};

	template <TypeCategory CAT> struct TypeVisitor {
	using Result = bool;
	using Types = evaluate::CategoryTypes<CAT>;
	template <typename T> Result Test() {
	if (T::kind == exprType.kind()) {
	CaseValues<T>(context, exprType).Check(caseList);
	return true;
	} else {
	return false;
	}
	}
	SemanticsContext &context;
	const evaluate::DynamicType &exprType;
	const std::list<parser::CaseConstruct::Case> &caseList;
	};

	void CaseChecker::Enter(const parser::CaseConstruct &construct) {
	const auto &selectCaseStmt{
	std::get<parser::Statement<parser::SelectCaseStmt>>(construct.t)};
	const auto &selectCase{selectCaseStmt.statement};
	const auto &selectExpr{
	std::get<parser::Scalar<parser::Expr>>(selectCase.t).thing};
	const auto *x{GetExpr(selectExpr)};
	if (!x) {
	return; // expression semantics failed
	}
	if (auto exprType{x->GetType()}) {
	const auto &caseList{
	std::get<std::list<parser::CaseConstruct::Case>>(construct.t)};
	switch (exprType->category()) {
	case TypeCategory::Integer:
	common::SearchTypes(
	TypeVisitor<TypeCategory::Integer>{context_, *exprType, caseList});
	return;
	case TypeCategory::Logical:
	CaseValues<evaluate::Type<TypeCategory::Logical, 1>>{context_, *exprType}
	.Check(caseList);
	return;
	case TypeCategory::Character:
	common::SearchTypes(
	TypeVisitor<TypeCategory::Character>{context_, *exprType, caseList});
	return;
	default:
	break;
	}
	}
	context_.Say(selectExpr.source,
	"SELECT CASE expression must be integer, logical, or character"_err_en_US);
	}
	} // namespace Fortran::semantics