src/third_party/llvm-project/clang-tools-extra/clang-tidy/hicpp/MultiwayPathsCoveredCheck.cpp - cobalt - Git at Google

 //===--- MultiwayPathsCoveredCheck.cpp - clang-tidy------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "MultiwayPathsCoveredCheck.h"
 #include "clang/AST/ASTContext.h"

 #include <limits>

 using namespace clang::ast_matchers;

 namespace clang {
 namespace tidy {
 namespace hicpp {

 void MultiwayPathsCoveredCheck::storeOptions(
     ClangTidyOptions::OptionMap &Opts) {
   Options.store(Opts, "WarnOnMissingElse", WarnOnMissingElse);
 }

 void MultiwayPathsCoveredCheck::registerMatchers(MatchFinder *Finder) {
   Finder->addMatcher(
       switchStmt(
           hasCondition(allOf(
               // Match on switch statements that have either a bit-field or
               // an integer condition. The ordering in 'anyOf()' is
               // important because the last condition is the most general.
               anyOf(ignoringImpCasts(memberExpr(hasDeclaration(
                         fieldDecl(isBitField()).bind("bitfield")))),
                     ignoringImpCasts(declRefExpr().bind("non-enum-condition"))),
               // 'unless()' must be the last match here and must be bound,
               // otherwise the matcher does not work correctly, because it
               // will not explicitly ignore enum conditions.
               unless(ignoringImpCasts(
                   declRefExpr(hasType(enumType())).bind("enum-condition"))))))
           .bind("switch"),
       this);

   // This option is noisy, therefore matching is configurable.
   if (WarnOnMissingElse) {
     Finder->addMatcher(
         ifStmt(allOf(hasParent(ifStmt()), unless(hasElse(anything()))))
             .bind("else-if"),
         this);
   }
 }

 static std::pair<std::size_t, bool> countCaseLabels(const SwitchStmt *Switch) {
   std::size_t CaseCount = 0;
   bool HasDefault = false;

   const SwitchCase *CurrentCase = Switch->getSwitchCaseList();
   while (CurrentCase) {
     ++CaseCount;
     if (isa<DefaultStmt>(CurrentCase))
       HasDefault = true;

     CurrentCase = CurrentCase->getNextSwitchCase();
   }

   return std::make_pair(CaseCount, HasDefault);
 }

 /// This function calculate 2 ** Bits and returns
 /// numeric_limits<std::size_t>::max() if an overflow occured.
 static std::size_t twoPow(std::size_t Bits) {
   return Bits >= std::numeric_limits<std::size_t>::digits
              ? std::numeric_limits<std::size_t>::max()
              : static_cast<size_t>(1) << Bits;
 }

 /// Get the number of possible values that can be switched on for the type T.
 ///
 /// \return - 0 if bitcount could not be determined
 ///         - numeric_limits<std::size_t>::max() when overflow appeared due to
 ///           more than 64 bits type size.
 static std::size_t getNumberOfPossibleValues(QualType T,
                                              const ASTContext &Context) {
   // `isBooleanType` must come first because `bool` is an integral type as well
   // and would not return 2 as result.
   if (T->isBooleanType())
     return 2;
   else if (T->isIntegralType(Context))
     return twoPow(Context.getTypeSize(T));
   else
     return 1;
 }

 void MultiwayPathsCoveredCheck::check(const MatchFinder::MatchResult &Result) {
   if (const auto *ElseIfWithoutElse =
           Result.Nodes.getNodeAs<IfStmt>("else-if")) {
     diag(ElseIfWithoutElse->getLocStart(),
          "potentially uncovered codepath; add an ending else statement");
     return;
   }
   const auto *Switch = Result.Nodes.getNodeAs<SwitchStmt>("switch");
   std::size_t SwitchCaseCount;
   bool SwitchHasDefault;
   std::tie(SwitchCaseCount, SwitchHasDefault) = countCaseLabels(Switch);

   // Checks the sanity of 'switch' statements that actually do define
   // a default branch but might be degenerated by having no or only one case.
   if (SwitchHasDefault) {
     handleSwitchWithDefault(Switch, SwitchCaseCount);
     return;
   }
   // Checks all 'switch' statements that do not define a default label.
   // Here the heavy lifting happens.
   if (!SwitchHasDefault && SwitchCaseCount > 0) {
     handleSwitchWithoutDefault(Switch, SwitchCaseCount, Result);
     return;
   }
   // Warns for degenerated 'switch' statements that neither define a case nor
   // a default label.
   // FIXME: Evaluate, if emitting a fix-it to simplify that statement is
   // reasonable.
   if (!SwitchHasDefault && SwitchCaseCount == 0) {
     diag(Switch->getLocStart(),
          "switch statement without labels has no effect");
     return;
   }
   llvm_unreachable("matched a case, that was not explicitly handled");
 }

 void MultiwayPathsCoveredCheck::handleSwitchWithDefault(
     const SwitchStmt *Switch, std::size_t CaseCount) {
   assert(CaseCount > 0 && "Switch statement with supposedly one default "
                           "branch did not contain any case labels");
   if (CaseCount == 1 || CaseCount == 2)
     diag(Switch->getLocStart(),
          CaseCount == 1
              ? "degenerated switch with default label only"
              : "switch could be better written as an if/else statement");
 }

 void MultiwayPathsCoveredCheck::handleSwitchWithoutDefault(
     const SwitchStmt *Switch, std::size_t CaseCount,
     const MatchFinder::MatchResult &Result) {
   // The matcher only works because some nodes are explicitly matched and
   // bound but ignored. This is necessary to build the excluding logic for
   // enums and 'switch' statements without a 'default' branch.
   assert(!Result.Nodes.getNodeAs<DeclRefExpr>("enum-condition") &&
          "switch over enum is handled by warnings already, explicitly ignoring "
          "them");
   // Determine the number of case labels. Because 'default' is not present
   // and duplicating case labels is not allowed this number represents
   // the number of codepaths. It can be directly compared to 'MaxPathsPossible'
   // to see if some cases are missing.
   // CaseCount == 0 is caught in DegenerateSwitch. Necessary because the
   // matcher used for here does not match on degenerate 'switch'.
   assert(CaseCount > 0 && "Switch statement without any case found. This case "
                           "should be excluded by the matcher and is handled "
                           "separatly.");
   std::size_t MaxPathsPossible = [&]() {
     if (const auto *GeneralCondition =
             Result.Nodes.getNodeAs<DeclRefExpr>("non-enum-condition")) {
       return getNumberOfPossibleValues(GeneralCondition->getType(),
                                        *Result.Context);
     }
     if (const auto *BitfieldDecl =
             Result.Nodes.getNodeAs<FieldDecl>("bitfield")) {
       return twoPow(BitfieldDecl->getBitWidthValue(*Result.Context));
     }

     return static_cast<std::size_t>(0);
   }();

   // FIXME: Transform the 'switch' into an 'if' for CaseCount == 1.
   if (CaseCount < MaxPathsPossible)
     diag(Switch->getLocStart(),
          CaseCount == 1 ? "switch with only one case; use an if statement"
                         : "potential uncovered code path; add a default label");
 }
 } // namespace hicpp
 } // namespace tidy
 } // namespace clang
	//===--- MultiwayPathsCoveredCheck.cpp - clang-tidy------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "MultiwayPathsCoveredCheck.h"
	#include "clang/AST/ASTContext.h"

	#include <limits>

	using namespace clang::ast_matchers;

	namespace clang {
	namespace tidy {
	namespace hicpp {

	void MultiwayPathsCoveredCheck::storeOptions(
	ClangTidyOptions::OptionMap &Opts) {
	Options.store(Opts, "WarnOnMissingElse", WarnOnMissingElse);
	}

	void MultiwayPathsCoveredCheck::registerMatchers(MatchFinder *Finder) {
	Finder->addMatcher(
	switchStmt(
	hasCondition(allOf(
	// Match on switch statements that have either a bit-field or
	// an integer condition. The ordering in 'anyOf()' is
	// important because the last condition is the most general.
	anyOf(ignoringImpCasts(memberExpr(hasDeclaration(
	fieldDecl(isBitField()).bind("bitfield")))),
	ignoringImpCasts(declRefExpr().bind("non-enum-condition"))),
	// 'unless()' must be the last match here and must be bound,
	// otherwise the matcher does not work correctly, because it
	// will not explicitly ignore enum conditions.
	unless(ignoringImpCasts(
	declRefExpr(hasType(enumType())).bind("enum-condition"))))))
	.bind("switch"),
	this);

	// This option is noisy, therefore matching is configurable.
	if (WarnOnMissingElse) {
	Finder->addMatcher(
	ifStmt(allOf(hasParent(ifStmt()), unless(hasElse(anything()))))
	.bind("else-if"),
	this);
	}
	}

	static std::pair<std::size_t, bool> countCaseLabels(const SwitchStmt *Switch) {
	std::size_t CaseCount = 0;
	bool HasDefault = false;

	const SwitchCase *CurrentCase = Switch->getSwitchCaseList();
	while (CurrentCase) {
	++CaseCount;
	if (isa<DefaultStmt>(CurrentCase))
	HasDefault = true;

	CurrentCase = CurrentCase->getNextSwitchCase();
	}

	return std::make_pair(CaseCount, HasDefault);
	}

	/// This function calculate 2 ** Bits and returns
	/// numeric_limits<std::size_t>::max() if an overflow occured.
	static std::size_t twoPow(std::size_t Bits) {
	return Bits >= std::numeric_limits<std::size_t>::digits
	? std::numeric_limits<std::size_t>::max()
	: static_cast<size_t>(1) << Bits;
	}

	/// Get the number of possible values that can be switched on for the type T.
	///
	/// \return - 0 if bitcount could not be determined
	/// - numeric_limits<std::size_t>::max() when overflow appeared due to
	/// more than 64 bits type size.
	static std::size_t getNumberOfPossibleValues(QualType T,
	const ASTContext &Context) {
	// `isBooleanType` must come first because `bool` is an integral type as well
	// and would not return 2 as result.
	if (T->isBooleanType())
	return 2;
	else if (T->isIntegralType(Context))
	return twoPow(Context.getTypeSize(T));
	else
	return 1;
	}

	void MultiwayPathsCoveredCheck::check(const MatchFinder::MatchResult &Result) {
	if (const auto *ElseIfWithoutElse =
	Result.Nodes.getNodeAs<IfStmt>("else-if")) {
	diag(ElseIfWithoutElse->getLocStart(),
	"potentially uncovered codepath; add an ending else statement");
	return;
	}
	const auto *Switch = Result.Nodes.getNodeAs<SwitchStmt>("switch");
	std::size_t SwitchCaseCount;
	bool SwitchHasDefault;
	std::tie(SwitchCaseCount, SwitchHasDefault) = countCaseLabels(Switch);

	// Checks the sanity of 'switch' statements that actually do define
	// a default branch but might be degenerated by having no or only one case.
	if (SwitchHasDefault) {
	handleSwitchWithDefault(Switch, SwitchCaseCount);
	return;
	}
	// Checks all 'switch' statements that do not define a default label.
	// Here the heavy lifting happens.
	if (!SwitchHasDefault && SwitchCaseCount > 0) {
	handleSwitchWithoutDefault(Switch, SwitchCaseCount, Result);
	return;
	}
	// Warns for degenerated 'switch' statements that neither define a case nor
	// a default label.
	// FIXME: Evaluate, if emitting a fix-it to simplify that statement is
	// reasonable.
	if (!SwitchHasDefault && SwitchCaseCount == 0) {
	diag(Switch->getLocStart(),
	"switch statement without labels has no effect");
	return;
	}
	llvm_unreachable("matched a case, that was not explicitly handled");
	}

	void MultiwayPathsCoveredCheck::handleSwitchWithDefault(
	const SwitchStmt *Switch, std::size_t CaseCount) {
	assert(CaseCount > 0 && "Switch statement with supposedly one default "
	"branch did not contain any case labels");
	if (CaseCount == 1 \|\| CaseCount == 2)
	diag(Switch->getLocStart(),
	CaseCount == 1
	? "degenerated switch with default label only"
	: "switch could be better written as an if/else statement");
	}

	void MultiwayPathsCoveredCheck::handleSwitchWithoutDefault(
	const SwitchStmt *Switch, std::size_t CaseCount,
	const MatchFinder::MatchResult &Result) {
	// The matcher only works because some nodes are explicitly matched and
	// bound but ignored. This is necessary to build the excluding logic for
	// enums and 'switch' statements without a 'default' branch.
	assert(!Result.Nodes.getNodeAs<DeclRefExpr>("enum-condition") &&
	"switch over enum is handled by warnings already, explicitly ignoring "
	"them");
	// Determine the number of case labels. Because 'default' is not present
	// and duplicating case labels is not allowed this number represents
	// the number of codepaths. It can be directly compared to 'MaxPathsPossible'
	// to see if some cases are missing.
	// CaseCount == 0 is caught in DegenerateSwitch. Necessary because the
	// matcher used for here does not match on degenerate 'switch'.
	assert(CaseCount > 0 && "Switch statement without any case found. This case "
	"should be excluded by the matcher and is handled "
	"separatly.");
	std::size_t MaxPathsPossible = [&]() {
	if (const auto *GeneralCondition =
	Result.Nodes.getNodeAs<DeclRefExpr>("non-enum-condition")) {
	return getNumberOfPossibleValues(GeneralCondition->getType(),
	*Result.Context);
	}
	if (const auto *BitfieldDecl =
	Result.Nodes.getNodeAs<FieldDecl>("bitfield")) {
	return twoPow(BitfieldDecl->getBitWidthValue(*Result.Context));
	}

	return static_cast<std::size_t>(0);
	}();

	// FIXME: Transform the 'switch' into an 'if' for CaseCount == 1.
	if (CaseCount < MaxPathsPossible)
	diag(Switch->getLocStart(),
	CaseCount == 1 ? "switch with only one case; use an if statement"
	: "potential uncovered code path; add a default label");
	}
	} // namespace hicpp
	} // namespace tidy
	} // namespace clang