unittests/Sema/CodeCompleteTest.cpp - clang - Git at Google

 //=== unittests/Sema/CodeCompleteTest.cpp - Code Complete tests ==============//
 //
 // 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 "clang/Frontend/CompilerInstance.h"
 #include "clang/Frontend/FrontendActions.h"
 #include "clang/Lex/Preprocessor.h"
 #include "clang/Parse/ParseAST.h"
 #include "clang/Sema/Sema.h"
 #include "clang/Sema/SemaDiagnostic.h"
 #include "clang/Tooling/Tooling.h"
 #include "llvm/Testing/Support/Annotations.h"
 #include "gmock/gmock.h"
 #include "gtest/gtest.h"
 #include <cstddef>
 #include <string>

 namespace {

 using namespace clang;
 using namespace clang::tooling;
 using ::testing::Each;
 using ::testing::UnorderedElementsAre;

 const char TestCCName[] = "test.cc";

 struct CompletionContext {
   std::vector<std::string> VisitedNamespaces;
   std::string PreferredType;
   // String representation of std::ptrdiff_t on a given platform. This is a hack
   // to properly account for different configurations of clang.
   std::string PtrDiffType;
 };

 class VisitedContextFinder : public CodeCompleteConsumer {
 public:
   VisitedContextFinder(CompletionContext &ResultCtx)
       : CodeCompleteConsumer(/*CodeCompleteOpts=*/{}), ResultCtx(ResultCtx),
         CCTUInfo(std::make_shared<GlobalCodeCompletionAllocator>()) {}

   void ProcessCodeCompleteResults(Sema &S, CodeCompletionContext Context,
                                   CodeCompletionResult *Results,
                                   unsigned NumResults) override {
     ResultCtx.VisitedNamespaces =
         getVisitedNamespace(Context.getVisitedContexts());
     ResultCtx.PreferredType = Context.getPreferredType().getAsString();
     ResultCtx.PtrDiffType =
         S.getASTContext().getPointerDiffType().getAsString();
   }

   CodeCompletionAllocator &getAllocator() override {
     return CCTUInfo.getAllocator();
   }

   CodeCompletionTUInfo &getCodeCompletionTUInfo() override { return CCTUInfo; }

 private:
   std::vector<std::string> getVisitedNamespace(
       CodeCompletionContext::VisitedContextSet VisitedContexts) const {
     std::vector<std::string> NSNames;
     for (const auto *Context : VisitedContexts)
       if (const auto *NS = llvm::dyn_cast<NamespaceDecl>(Context))
         NSNames.push_back(NS->getQualifiedNameAsString());
     return NSNames;
   }

   CompletionContext &ResultCtx;
   CodeCompletionTUInfo CCTUInfo;
 };

 class CodeCompleteAction : public SyntaxOnlyAction {
 public:
   CodeCompleteAction(ParsedSourceLocation P, CompletionContext &ResultCtx)
       : CompletePosition(std::move(P)), ResultCtx(ResultCtx) {}

   bool BeginInvocation(CompilerInstance &CI) override {
     CI.getFrontendOpts().CodeCompletionAt = CompletePosition;
     CI.setCodeCompletionConsumer(new VisitedContextFinder(ResultCtx));
     return true;
   }

 private:
   // 1-based code complete position <Line, Col>;
   ParsedSourceLocation CompletePosition;
   CompletionContext &ResultCtx;
 };

 ParsedSourceLocation offsetToPosition(llvm::StringRef Code, size_t Offset) {
   Offset = std::min(Code.size(), Offset);
   StringRef Before = Code.substr(0, Offset);
   int Lines = Before.count('\n');
   size_t PrevNL = Before.rfind('\n');
   size_t StartOfLine = (PrevNL == StringRef::npos) ? 0 : (PrevNL + 1);
   return {TestCCName, static_cast<unsigned>(Lines + 1),
           static_cast<unsigned>(Offset - StartOfLine + 1)};
 }

 CompletionContext runCompletion(StringRef Code, size_t Offset) {
   CompletionContext ResultCtx;
   clang::tooling::runToolOnCodeWithArgs(
       std::make_unique<CodeCompleteAction>(offsetToPosition(Code, Offset),
                                            ResultCtx),
       Code, {"-std=c++11"}, TestCCName);
   return ResultCtx;
 }

 CompletionContext runCodeCompleteOnCode(StringRef AnnotatedCode) {
   llvm::Annotations A(AnnotatedCode);
   return runCompletion(A.code(), A.point());
 }

 std::vector<std::string>
 collectPreferredTypes(StringRef AnnotatedCode,
                       std::string *PtrDiffType = nullptr) {
   llvm::Annotations A(AnnotatedCode);
   std::vector<std::string> Types;
   for (size_t Point : A.points()) {
     auto Results = runCompletion(A.code(), Point);
     if (PtrDiffType) {
       assert(PtrDiffType->empty() || *PtrDiffType == Results.PtrDiffType);
       *PtrDiffType = Results.PtrDiffType;
     }
     Types.push_back(Results.PreferredType);
   }
   return Types;
 }

 TEST(SemaCodeCompleteTest, VisitedNSForValidQualifiedId) {
   auto VisitedNS = runCodeCompleteOnCode(R"cpp(
      namespace ns1 {}
      namespace ns2 {}
      namespace ns3 {}
      namespace ns3 { namespace nns3 {} }

      namespace foo {
      using namespace ns1;
      namespace ns4 {} // not visited
      namespace { using namespace ns2; }
      inline namespace bar { using namespace ns3::nns3; }
      } // foo
      namespace ns { foo::^ }
   )cpp")
                        .VisitedNamespaces;
   EXPECT_THAT(VisitedNS, UnorderedElementsAre("foo", "ns1", "ns2", "ns3::nns3",
                                               "foo::(anonymous)"));
 }

 TEST(SemaCodeCompleteTest, VisitedNSForInvalidQualifiedId) {
   auto VisitedNS = runCodeCompleteOnCode(R"cpp(
      namespace na {}
      namespace ns1 {
      using namespace na;
      foo::^
      }
   )cpp")
                        .VisitedNamespaces;
   EXPECT_THAT(VisitedNS, UnorderedElementsAre("ns1", "na"));
 }

 TEST(SemaCodeCompleteTest, VisitedNSWithoutQualifier) {
   auto VisitedNS = runCodeCompleteOnCode(R"cpp(
     namespace n1 {
     namespace n2 {
       void f(^) {}
     }
     }
   )cpp")
                        .VisitedNamespaces;
   EXPECT_THAT(VisitedNS, UnorderedElementsAre("n1", "n1::n2"));
 }

 TEST(PreferredTypeTest, BinaryExpr) {
   // Check various operations for arithmetic types.
   StringRef Code = R"cpp(
     void test(int x) {
       x = ^10;
       x += ^10; x -= ^10; x *= ^10; x /= ^10; x %= ^10;
       x + ^10; x - ^10; x * ^10; x / ^10; x % ^10;
     })cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("int"));

   Code = R"cpp(
     void test(float x) {
       x = ^10;
       x += ^10; x -= ^10; x *= ^10; x /= ^10; x %= ^10;
       x + ^10; x - ^10; x * ^10; x / ^10; x % ^10;
     })cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("float"));

   // Pointer types.
   Code = R"cpp(
     void test(int *ptr) {
       ptr - ^ptr;
       ptr = ^ptr;
     })cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("int *"));

   Code = R"cpp(
     void test(int *ptr) {
       ptr + ^10;
       ptr += ^10;
       ptr -= ^10;
     })cpp";
   {
     std::string PtrDiff;
     auto Types = collectPreferredTypes(Code, &PtrDiff);
     EXPECT_THAT(Types, Each(PtrDiff));
   }

   // Comparison operators.
   Code = R"cpp(
     void test(int i) {
       i <= ^1; i < ^1; i >= ^1; i > ^1; i == ^1; i != ^1;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("int"));

   Code = R"cpp(
     void test(int *ptr) {
       ptr <= ^ptr; ptr < ^ptr; ptr >= ^ptr; ptr > ^ptr;
       ptr == ^ptr; ptr != ^ptr;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("int *"));

   // Relational operations.
   Code = R"cpp(
     void test(int i, int *ptr) {
       i && ^1; i || ^1;
       ptr && ^1; ptr || ^1;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("_Bool"));

   // Bitwise operations.
   Code = R"cpp(
     void test(long long ll) {
       ll | ^1; ll & ^1;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("long long"));

   Code = R"cpp(
     enum A {};
     void test(A a) {
       a | ^1; a & ^1;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("enum A"));

   Code = R"cpp(
     enum class A {};
     void test(A a) {
       // This is technically illegal with the 'enum class' without overloaded
       // operators, but we pretend it's fine.
       a | ^a; a & ^a;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("enum A"));

   // Binary shifts.
   Code = R"cpp(
     void test(int i, long long ll) {
       i << ^1; ll << ^1;
       i <<= ^1; i <<= ^1;
       i >> ^1; ll >> ^1;
       i >>= ^1; i >>= ^1;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("int"));

   // Comma does not provide any useful information.
   Code = R"cpp(
     class Cls {};
     void test(int i, int* ptr, Cls x) {
       (i, ^i);
       (ptr, ^ptr);
       (x, ^x);
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("NULL TYPE"));

   // User-defined types do not take operator overloading into account.
   // However, they provide heuristics for some common cases.
   Code = R"cpp(
     class Cls {};
     void test(Cls c) {
       // we assume arithmetic and comparions ops take the same type.
       c + ^c; c - ^c; c * ^c; c / ^c; c % ^c;
       c == ^c; c != ^c; c < ^c; c <= ^c; c > ^c; c >= ^c;
       // same for the assignments.
       c = ^c; c += ^c; c -= ^c; c *= ^c; c /= ^c; c %= ^c;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("class Cls"));

   Code = R"cpp(
     class Cls {};
     void test(Cls c) {
       // we assume relational ops operate on bools.
       c && ^c; c || ^c;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("_Bool"));

   Code = R"cpp(
     class Cls {};
     void test(Cls c) {
       // we make no assumptions about the following operators, since they are
       // often overloaded with a non-standard meaning.
       c << ^c; c >> ^c; c | ^c; c & ^c;
       c <<= ^c; c >>= ^c; c |= ^c; c &= ^c;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("NULL TYPE"));
 }

 TEST(PreferredTypeTest, Members) {
   StringRef Code = R"cpp(
     struct vector {
       int *begin();
       vector clone();
     };

     void test(int *a) {
       a = ^vector().^clone().^begin();
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("int *"));
 }

 TEST(PreferredTypeTest, Conditions) {
   StringRef Code = R"cpp(
     struct vector {
       bool empty();
     };

     void test() {
       if (^vector().^empty()) {}
       while (^vector().^empty()) {}
       for (; ^vector().^empty();) {}
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("_Bool"));
 }

 TEST(PreferredTypeTest, InitAndAssignment) {
   StringRef Code = R"cpp(
     struct vector {
       int* begin();
     };

     void test() {
       const int* x = ^vector().^begin();
       x = ^vector().^begin();

       if (const int* y = ^vector().^begin()) {}
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("const int *"));
 }

 TEST(PreferredTypeTest, UnaryExprs) {
   StringRef Code = R"cpp(
     void test(long long a) {
       a = +^a;
       a = -^a
       a = ++^a;
       a = --^a;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("long long"));

   Code = R"cpp(
     void test(int a, int *ptr) {
       !^a;
       !^ptr;
       !!!^a;

       a = !^a;
       a = !^ptr;
       a = !!!^a;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("_Bool"));

   Code = R"cpp(
     void test(int a) {
       const int* x = &^a;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("const int"));

   Code = R"cpp(
     void test(int *a) {
       int x = *^a;
       int &r = *^a;
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("int *"));

   Code = R"cpp(
     void test(int a) {
       *^a;
       &^a;
     }

   )cpp";
 }

 TEST(PreferredTypeTest, ParenExpr) {
   StringRef Code = R"cpp(
     const int *i = ^(^(^(^10)));
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("const int *"));
 }

 TEST(PreferredTypeTest, FunctionArguments) {
   StringRef Code = R"cpp(
     void foo(const int*);

     void bar(const int*);
     void bar(const int*, int b);

     struct vector {
       const int *data();
     };
     void test() {
       foo(^(^(^(^vec^tor^().^da^ta^()))));
       bar(^(^(^(^vec^tor^().^da^ta^()))));
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("const int *"));

   Code = R"cpp(
     void bar(int, volatile double *);
     void bar(int, volatile double *, int, int);

     struct vector {
       double *data();
     };

     struct class_members {
       void bar(int, volatile double *);
       void bar(int, volatile double *, int, int);
     };
     void test() {
       bar(10, ^(^(^(^vec^tor^().^da^ta^()))));
       class_members().bar(10, ^(^(^(^vec^tor^().^da^ta^()))));
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("volatile double *"));

   Code = R"cpp(
     namespace ns {
       struct vector {
       };
     }
     void accepts_vector(ns::vector);

     void test() {
       accepts_vector(^::^ns::^vector());
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("ns::vector"));

   Code = R"cpp(
     template <class T>
     struct vector { using self = vector; };

     void accepts_vector(vector<int>);
     int foo(int);

     void test() {
       accepts_vector(^::^vector<decltype(foo(1))>::^self);
     }
   )cpp";
   EXPECT_THAT(collectPreferredTypes(Code), Each("vector<int>"));
 }
 } // namespace
	//=== unittests/Sema/CodeCompleteTest.cpp - Code Complete tests ==============//
	//
	// 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 "clang/Frontend/CompilerInstance.h"
	#include "clang/Frontend/FrontendActions.h"
	#include "clang/Lex/Preprocessor.h"
	#include "clang/Parse/ParseAST.h"
	#include "clang/Sema/Sema.h"
	#include "clang/Sema/SemaDiagnostic.h"
	#include "clang/Tooling/Tooling.h"
	#include "llvm/Testing/Support/Annotations.h"
	#include "gmock/gmock.h"
	#include "gtest/gtest.h"
	#include <cstddef>
	#include <string>

	namespace {

	using namespace clang;
	using namespace clang::tooling;
	using ::testing::Each;
	using ::testing::UnorderedElementsAre;

	const char TestCCName[] = "test.cc";

	struct CompletionContext {
	std::vector<std::string> VisitedNamespaces;
	std::string PreferredType;
	// String representation of std::ptrdiff_t on a given platform. This is a hack
	// to properly account for different configurations of clang.
	std::string PtrDiffType;
	};

	class VisitedContextFinder : public CodeCompleteConsumer {
	public:
	VisitedContextFinder(CompletionContext &ResultCtx)
	: CodeCompleteConsumer(/CodeCompleteOpts=/{}), ResultCtx(ResultCtx),
	CCTUInfo(std::make_shared<GlobalCodeCompletionAllocator>()) {}

	void ProcessCodeCompleteResults(Sema &S, CodeCompletionContext Context,
	CodeCompletionResult *Results,
	unsigned NumResults) override {
	ResultCtx.VisitedNamespaces =
	getVisitedNamespace(Context.getVisitedContexts());
	ResultCtx.PreferredType = Context.getPreferredType().getAsString();
	ResultCtx.PtrDiffType =
	S.getASTContext().getPointerDiffType().getAsString();
	}

	CodeCompletionAllocator &getAllocator() override {
	return CCTUInfo.getAllocator();
	}

	CodeCompletionTUInfo &getCodeCompletionTUInfo() override { return CCTUInfo; }

	private:
	std::vector<std::string> getVisitedNamespace(
	CodeCompletionContext::VisitedContextSet VisitedContexts) const {
	std::vector<std::string> NSNames;
	for (const auto *Context : VisitedContexts)
	if (const auto *NS = llvm::dyn_cast<NamespaceDecl>(Context))
	NSNames.push_back(NS->getQualifiedNameAsString());
	return NSNames;
	}

	CompletionContext &ResultCtx;
	CodeCompletionTUInfo CCTUInfo;
	};

	class CodeCompleteAction : public SyntaxOnlyAction {
	public:
	CodeCompleteAction(ParsedSourceLocation P, CompletionContext &ResultCtx)
	: CompletePosition(std::move(P)), ResultCtx(ResultCtx) {}

	bool BeginInvocation(CompilerInstance &CI) override {
	CI.getFrontendOpts().CodeCompletionAt = CompletePosition;
	CI.setCodeCompletionConsumer(new VisitedContextFinder(ResultCtx));
	return true;
	}

	private:
	// 1-based code complete position <Line, Col>;
	ParsedSourceLocation CompletePosition;
	CompletionContext &ResultCtx;
	};

	ParsedSourceLocation offsetToPosition(llvm::StringRef Code, size_t Offset) {
	Offset = std::min(Code.size(), Offset);
	StringRef Before = Code.substr(0, Offset);
	int Lines = Before.count('\n');
	size_t PrevNL = Before.rfind('\n');
	size_t StartOfLine = (PrevNL == StringRef::npos) ? 0 : (PrevNL + 1);
	return {TestCCName, static_cast<unsigned>(Lines + 1),
	static_cast<unsigned>(Offset - StartOfLine + 1)};
	}

	CompletionContext runCompletion(StringRef Code, size_t Offset) {
	CompletionContext ResultCtx;
	clang::tooling::runToolOnCodeWithArgs(
	std::make_unique<CodeCompleteAction>(offsetToPosition(Code, Offset),
	ResultCtx),
	Code, {"-std=c++11"}, TestCCName);
	return ResultCtx;
	}

	CompletionContext runCodeCompleteOnCode(StringRef AnnotatedCode) {
	llvm::Annotations A(AnnotatedCode);
	return runCompletion(A.code(), A.point());
	}

	std::vector<std::string>
	collectPreferredTypes(StringRef AnnotatedCode,
	std::string *PtrDiffType = nullptr) {
	llvm::Annotations A(AnnotatedCode);
	std::vector<std::string> Types;
	for (size_t Point : A.points()) {
	auto Results = runCompletion(A.code(), Point);
	if (PtrDiffType) {
	assert(PtrDiffType->empty() \|\| *PtrDiffType == Results.PtrDiffType);
	*PtrDiffType = Results.PtrDiffType;
	}
	Types.push_back(Results.PreferredType);
	}
	return Types;
	}

	TEST(SemaCodeCompleteTest, VisitedNSForValidQualifiedId) {
	auto VisitedNS = runCodeCompleteOnCode(R"cpp(
	namespace ns1 {}
	namespace ns2 {}
	namespace ns3 {}
	namespace ns3 { namespace nns3 {} }

	namespace foo {
	using namespace ns1;
	namespace ns4 {} // not visited
	namespace { using namespace ns2; }
	inline namespace bar { using namespace ns3::nns3; }
	} // foo
	namespace ns { foo::^ }
	)cpp")
	.VisitedNamespaces;
	EXPECT_THAT(VisitedNS, UnorderedElementsAre("foo", "ns1", "ns2", "ns3::nns3",
	"foo::(anonymous)"));
	}

	TEST(SemaCodeCompleteTest, VisitedNSForInvalidQualifiedId) {
	auto VisitedNS = runCodeCompleteOnCode(R"cpp(
	namespace na {}
	namespace ns1 {
	using namespace na;
	foo::^
	}
	)cpp")
	.VisitedNamespaces;
	EXPECT_THAT(VisitedNS, UnorderedElementsAre("ns1", "na"));
	}

	TEST(SemaCodeCompleteTest, VisitedNSWithoutQualifier) {
	auto VisitedNS = runCodeCompleteOnCode(R"cpp(
	namespace n1 {
	namespace n2 {
	void f(^) {}
	}
	}
	)cpp")
	.VisitedNamespaces;
	EXPECT_THAT(VisitedNS, UnorderedElementsAre("n1", "n1::n2"));
	}

	TEST(PreferredTypeTest, BinaryExpr) {
	// Check various operations for arithmetic types.
	StringRef Code = R"cpp(
	void test(int x) {
	x = ^10;
	x += ^10; x -= ^10; x *= ^10; x /= ^10; x %= ^10;
	x + ^10; x - ^10; x * ^10; x / ^10; x % ^10;
	})cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("int"));

	Code = R"cpp(
	void test(float x) {
	x = ^10;
	x += ^10; x -= ^10; x *= ^10; x /= ^10; x %= ^10;
	x + ^10; x - ^10; x * ^10; x / ^10; x % ^10;
	})cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("float"));

	// Pointer types.
	Code = R"cpp(
	void test(int *ptr) {
	ptr - ^ptr;
	ptr = ^ptr;
	})cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("int *"));

	Code = R"cpp(
	void test(int *ptr) {
	ptr + ^10;
	ptr += ^10;
	ptr -= ^10;
	})cpp";
	{
	std::string PtrDiff;
	auto Types = collectPreferredTypes(Code, &PtrDiff);
	EXPECT_THAT(Types, Each(PtrDiff));
	}

	// Comparison operators.
	Code = R"cpp(
	void test(int i) {
	i <= ^1; i < ^1; i >= ^1; i > ^1; i == ^1; i != ^1;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("int"));

	Code = R"cpp(
	void test(int *ptr) {
	ptr <= ^ptr; ptr < ^ptr; ptr >= ^ptr; ptr > ^ptr;
	ptr == ^ptr; ptr != ^ptr;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("int *"));

	// Relational operations.
	Code = R"cpp(
	void test(int i, int *ptr) {
	i && ^1; i \|\| ^1;
	ptr && ^1; ptr \|\| ^1;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("_Bool"));

	// Bitwise operations.
	Code = R"cpp(
	void test(long long ll) {
	ll \| ^1; ll & ^1;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("long long"));

	Code = R"cpp(
	enum A {};
	void test(A a) {
	a \| ^1; a & ^1;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("enum A"));

	Code = R"cpp(
	enum class A {};
	void test(A a) {
	// This is technically illegal with the 'enum class' without overloaded
	// operators, but we pretend it's fine.
	a \| ^a; a & ^a;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("enum A"));

	// Binary shifts.
	Code = R"cpp(
	void test(int i, long long ll) {
	i << ^1; ll << ^1;
	i <<= ^1; i <<= ^1;
	i >> ^1; ll >> ^1;
	i >>= ^1; i >>= ^1;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("int"));

	// Comma does not provide any useful information.
	Code = R"cpp(
	class Cls {};
	void test(int i, int* ptr, Cls x) {
	(i, ^i);
	(ptr, ^ptr);
	(x, ^x);
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("NULL TYPE"));

	// User-defined types do not take operator overloading into account.
	// However, they provide heuristics for some common cases.
	Code = R"cpp(
	class Cls {};
	void test(Cls c) {
	// we assume arithmetic and comparions ops take the same type.
	c + ^c; c - ^c; c * ^c; c / ^c; c % ^c;
	c == ^c; c != ^c; c < ^c; c <= ^c; c > ^c; c >= ^c;
	// same for the assignments.
	c = ^c; c += ^c; c -= ^c; c *= ^c; c /= ^c; c %= ^c;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("class Cls"));

	Code = R"cpp(
	class Cls {};
	void test(Cls c) {
	// we assume relational ops operate on bools.
	c && ^c; c \|\| ^c;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("_Bool"));

	Code = R"cpp(
	class Cls {};
	void test(Cls c) {
	// we make no assumptions about the following operators, since they are
	// often overloaded with a non-standard meaning.
	c << ^c; c >> ^c; c \| ^c; c & ^c;
	c <<= ^c; c >>= ^c; c \|= ^c; c &= ^c;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("NULL TYPE"));
	}

	TEST(PreferredTypeTest, Members) {
	StringRef Code = R"cpp(
	struct vector {
	int *begin();
	vector clone();
	};

	void test(int *a) {
	a = ^vector().^clone().^begin();
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("int *"));
	}

	TEST(PreferredTypeTest, Conditions) {
	StringRef Code = R"cpp(
	struct vector {
	bool empty();
	};

	void test() {
	if (^vector().^empty()) {}
	while (^vector().^empty()) {}
	for (; ^vector().^empty();) {}
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("_Bool"));
	}

	TEST(PreferredTypeTest, InitAndAssignment) {
	StringRef Code = R"cpp(
	struct vector {
	int* begin();
	};

	void test() {
	const int* x = ^vector().^begin();
	x = ^vector().^begin();

	if (const int* y = ^vector().^begin()) {}
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("const int *"));
	}

	TEST(PreferredTypeTest, UnaryExprs) {
	StringRef Code = R"cpp(
	void test(long long a) {
	a = +^a;
	a = -^a
	a = ++^a;
	a = --^a;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("long long"));

	Code = R"cpp(
	void test(int a, int *ptr) {
	!^a;
	!^ptr;
	!!!^a;

	a = !^a;
	a = !^ptr;
	a = !!!^a;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("_Bool"));

	Code = R"cpp(
	void test(int a) {
	const int* x = &^a;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("const int"));

	Code = R"cpp(
	void test(int *a) {
	int x = *^a;
	int &r = *^a;
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("int *"));

	Code = R"cpp(
	void test(int a) {
	*^a;
	&^a;
	}

	)cpp";
	}

	TEST(PreferredTypeTest, ParenExpr) {
	StringRef Code = R"cpp(
	const int *i = ^(^(^(^10)));
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("const int *"));
	}

	TEST(PreferredTypeTest, FunctionArguments) {
	StringRef Code = R"cpp(
	void foo(const int*);

	void bar(const int*);
	void bar(const int*, int b);

	struct vector {
	const int *data();
	};
	void test() {
	foo(^(^(^(^vec^tor^().^da^ta^()))));
	bar(^(^(^(^vec^tor^().^da^ta^()))));
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("const int *"));

	Code = R"cpp(
	void bar(int, volatile double *);
	void bar(int, volatile double *, int, int);

	struct vector {
	double *data();
	};

	struct class_members {
	void bar(int, volatile double *);
	void bar(int, volatile double *, int, int);
	};
	void test() {
	bar(10, ^(^(^(^vec^tor^().^da^ta^()))));
	class_members().bar(10, ^(^(^(^vec^tor^().^da^ta^()))));
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("volatile double *"));

	Code = R"cpp(
	namespace ns {
	struct vector {
	};
	}
	void accepts_vector(ns::vector);

	void test() {
	accepts_vector(^::^ns::^vector());
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("ns::vector"));

	Code = R"cpp(
	template <class T>
	struct vector { using self = vector; };

	void accepts_vector(vector<int>);
	int foo(int);

	void test() {
	accepts_vector(^::^vector<decltype(foo(1))>::^self);
	}
	)cpp";
	EXPECT_THAT(collectPreferredTypes(Code), Each("vector<int>"));
	}
	} // namespace