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llvm / llvm-project / clang / b97dcdfcc98b63a8dcd0fbddbc7f3d8978fca47d / . / unittests / AST / StructuralEquivalenceTest.cpp
blob: 9ae0da8b9dd2c6b81141e7f5eb1524e75217aa17 [file] [log] [blame]
#include "clang/AST/ASTContext.h"
#include "clang/AST/ASTStructuralEquivalence.h"
#include "clang/ASTMatchers/ASTMatchers.h"
#include "clang/Frontend/ASTUnit.h"
#include "clang/Testing/CommandLineArgs.h"
#include "clang/Tooling/Tooling.h"
#include "llvm/Support/Host.h"
#include "DeclMatcher.h"
#include "gtest/gtest.h"
namespace clang {
namespace ast_matchers {
using std::get;
struct StructuralEquivalenceTest : ::testing::Test {
std::unique_ptr<ASTUnit> AST0, AST1;
std::string Code0, Code1; // Buffers for SourceManager
// Parses the source code in the specified language and sets the ASTs of
// the current test instance to the parse result.
void makeASTUnits(const std::string &SrcCode0, const std::string &SrcCode1,
TestLanguage Lang) {
this->Code0 = SrcCode0;
this->Code1 = SrcCode1;
std::vector<std::string> Args = getCommandLineArgsForTesting(Lang);
const char *const InputFileName = "input.cc";
AST0 = tooling::buildASTFromCodeWithArgs(Code0, Args, InputFileName);
AST1 = tooling::buildASTFromCodeWithArgs(Code1, Args, InputFileName);
}
// Get a pair of node pointers into the synthesized AST from the given code
// snippets. To determine the returned node, a separate matcher is specified
// for both snippets. The first matching node is returned.
template <typename NodeType, typename MatcherType>
std::tuple<NodeType *, NodeType *>
makeDecls(const std::string &SrcCode0, const std::string &SrcCode1,
TestLanguage Lang, const MatcherType &Matcher0,
const MatcherType &Matcher1) {
makeASTUnits(SrcCode0, SrcCode1, Lang);
NodeType *D0 = FirstDeclMatcher<NodeType>().match(
AST0->getASTContext().getTranslationUnitDecl(), Matcher0);
NodeType *D1 = FirstDeclMatcher<NodeType>().match(
AST1->getASTContext().getTranslationUnitDecl(), Matcher1);
return std::make_tuple(D0, D1);
}
std::tuple<TranslationUnitDecl *, TranslationUnitDecl *>
makeTuDecls(const std::string &SrcCode0, const std::string &SrcCode1,
TestLanguage Lang) {
makeASTUnits(SrcCode0, SrcCode1, Lang);
return std::make_tuple(AST0->getASTContext().getTranslationUnitDecl(),
AST1->getASTContext().getTranslationUnitDecl());
}
// Get a pair of node pointers into the synthesized AST from the given code
// snippets. The same matcher is used for both snippets.
template <typename NodeType, typename MatcherType>
std::tuple<NodeType *, NodeType *>
makeDecls(const std::string &SrcCode0, const std::string &SrcCode1,
TestLanguage Lang, const MatcherType &AMatcher) {
return makeDecls<NodeType, MatcherType>(
SrcCode0, SrcCode1, Lang, AMatcher, AMatcher);
}
// Get a pair of Decl pointers to the synthesized declarations from the given
// code snippets. We search for the first NamedDecl with given name in both
// snippets.
std::tuple<NamedDecl *, NamedDecl *>
makeNamedDecls(const std::string &SrcCode0, const std::string &SrcCode1,
TestLanguage Lang, const char *const Identifier = "foo") {
auto Matcher = namedDecl(hasName(Identifier));
return makeDecls<NamedDecl>(SrcCode0, SrcCode1, Lang, Matcher);
}
// Wraps a Stmt and the ASTContext that contains it.
struct StmtWithASTContext {
Stmt *S;
ASTContext *Context;
explicit StmtWithASTContext(Stmt &S, ASTContext &Context)
: S(&S), Context(&Context) {}
explicit StmtWithASTContext(FunctionDecl *FD)
: S(FD->getBody()), Context(&FD->getASTContext()) {}
};
// Get a pair of node pointers into the synthesized AST from the given code
// snippets. To determine the returned node, a separate matcher is specified
// for both snippets. The first matching node is returned.
template <typename MatcherType>
std::tuple<StmtWithASTContext, StmtWithASTContext>
makeStmts(const std::string &SrcCode0, const std::string &SrcCode1,
TestLanguage Lang, const MatcherType &Matcher0,
const MatcherType &Matcher1) {
makeASTUnits(SrcCode0, SrcCode1, Lang);
Stmt *S0 = FirstDeclMatcher<Stmt>().match(
AST0->getASTContext().getTranslationUnitDecl(), Matcher0);
Stmt *S1 = FirstDeclMatcher<Stmt>().match(
AST1->getASTContext().getTranslationUnitDecl(), Matcher1);
return std::make_tuple(StmtWithASTContext(*S0, AST0->getASTContext()),
StmtWithASTContext(*S1, AST1->getASTContext()));
}
// Get a pair of node pointers into the synthesized AST from the given code
// snippets. The same matcher is used for both snippets.
template <typename MatcherType>
std::tuple<StmtWithASTContext, StmtWithASTContext>
makeStmts(const std::string &SrcCode0, const std::string &SrcCode1,
TestLanguage Lang, const MatcherType &AMatcher) {
return makeStmts(SrcCode0, SrcCode1, Lang, AMatcher, AMatcher);
}
// Convenience function for makeStmts that wraps the code inside a function
// body.
template <typename MatcherType>
std::tuple<StmtWithASTContext, StmtWithASTContext>
makeWrappedStmts(const std::string &SrcCode0, const std::string &SrcCode1,
TestLanguage Lang, const MatcherType &AMatcher) {
auto Wrap = [](const std::string &Src) {
return "void wrapped() {" + Src + ";}";
};
return makeStmts(Wrap(SrcCode0), Wrap(SrcCode1), Lang, AMatcher);
}
bool testStructuralMatch(Decl *D0, Decl *D1) {
llvm::DenseSet<std::pair<Decl *, Decl *>> NonEquivalentDecls01;
llvm::DenseSet<std::pair<Decl *, Decl *>> NonEquivalentDecls10;
StructuralEquivalenceContext Ctx01(
D0->getASTContext(), D1->getASTContext(),
NonEquivalentDecls01, StructuralEquivalenceKind::Default, false, false);
StructuralEquivalenceContext Ctx10(
D1->getASTContext(), D0->getASTContext(),
NonEquivalentDecls10, StructuralEquivalenceKind::Default, false, false);
bool Eq01 = Ctx01.IsEquivalent(D0, D1);
bool Eq10 = Ctx10.IsEquivalent(D1, D0);
EXPECT_EQ(Eq01, Eq10);
return Eq01;
}
bool testStructuralMatch(StmtWithASTContext S0, StmtWithASTContext S1) {
llvm::DenseSet<std::pair<Decl *, Decl *>> NonEquivalentDecls01;
llvm::DenseSet<std::pair<Decl *, Decl *>> NonEquivalentDecls10;
StructuralEquivalenceContext Ctx01(
*S0.Context, *S1.Context, NonEquivalentDecls01,
StructuralEquivalenceKind::Default, false, false);
StructuralEquivalenceContext Ctx10(
*S1.Context, *S0.Context, NonEquivalentDecls10,
StructuralEquivalenceKind::Default, false, false);
bool Eq01 = Ctx01.IsEquivalent(S0.S, S1.S);
bool Eq10 = Ctx10.IsEquivalent(S1.S, S0.S);
EXPECT_EQ(Eq01, Eq10);
return Eq01;
}
bool
testStructuralMatch(std::tuple<StmtWithASTContext, StmtWithASTContext> t) {
return testStructuralMatch(get<0>(t), get<1>(t));
}
bool testStructuralMatch(std::tuple<Decl *, Decl *> t) {
return testStructuralMatch(get<0>(t), get<1>(t));
}
};
TEST_F(StructuralEquivalenceTest, Int) {
auto Decls = makeNamedDecls("int foo;", "int foo;", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(Decls));
}
TEST_F(StructuralEquivalenceTest, IntVsSignedInt) {
auto Decls = makeNamedDecls("int foo;", "signed int foo;", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(Decls));
}
TEST_F(StructuralEquivalenceTest, Char) {
auto Decls = makeNamedDecls("char foo;", "char foo;", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(Decls));
}
// This test is disabled for now.
// FIXME Whether this is equivalent is dependendant on the target.
TEST_F(StructuralEquivalenceTest, DISABLED_CharVsSignedChar) {
auto Decls = makeNamedDecls("char foo;", "signed char foo;", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(Decls));
}
TEST_F(StructuralEquivalenceTest, ForwardRecordDecl) {
auto Decls = makeNamedDecls("struct foo;", "struct foo;", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(Decls));
}
TEST_F(StructuralEquivalenceTest, IntVsSignedIntInStruct) {
auto Decls = makeNamedDecls("struct foo { int x; };",
"struct foo { signed int x; };", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(Decls));
}
TEST_F(StructuralEquivalenceTest, CharVsSignedCharInStruct) {
auto Decls = makeNamedDecls("struct foo { char x; };",
"struct foo { signed char x; };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(Decls));
}
TEST_F(StructuralEquivalenceTest, IntVsSignedIntTemplateSpec) {
auto Decls = makeDecls<ClassTemplateSpecializationDecl>(
R"(template <class T> struct foo; template<> struct foo<int>{};)",
R"(template <class T> struct foo; template<> struct foo<signed int>{};)",
Lang_CXX03, classTemplateSpecializationDecl());
auto Spec0 = get<0>(Decls);
auto Spec1 = get<1>(Decls);
EXPECT_TRUE(testStructuralMatch(Spec0, Spec1));
}
TEST_F(StructuralEquivalenceTest, CharVsSignedCharTemplateSpec) {
auto Decls = makeDecls<ClassTemplateSpecializationDecl>(
R"(template <class T> struct foo; template<> struct foo<char>{};)",
R"(template <class T> struct foo; template<> struct foo<signed char>{};)",
Lang_CXX03, classTemplateSpecializationDecl());
auto Spec0 = get<0>(Decls);
auto Spec1 = get<1>(Decls);
EXPECT_FALSE(testStructuralMatch(Spec0, Spec1));
}
TEST_F(StructuralEquivalenceTest, CharVsSignedCharTemplateSpecWithInheritance) {
auto Decls = makeDecls<ClassTemplateSpecializationDecl>(
R"(
struct true_type{};
template <class T> struct foo;
template<> struct foo<char> : true_type {};
)",
R"(
struct true_type{};
template <class T> struct foo;
template<> struct foo<signed char> : true_type {};
)",
Lang_CXX03, classTemplateSpecializationDecl());
EXPECT_FALSE(testStructuralMatch(Decls));
}
// This test is disabled for now.
// FIXME Enable it, once the check is implemented.
TEST_F(StructuralEquivalenceTest, DISABLED_WrongOrderInNamespace) {
auto Code =
R"(
namespace NS {
template <class T> class Base {
int a;
};
class Derived : Base<Derived> {
};
}
void foo(NS::Derived &);
)";
auto Decls = makeNamedDecls(Code, Code, Lang_CXX03);
NamespaceDecl *NS =
LastDeclMatcher<NamespaceDecl>().match(get<1>(Decls), namespaceDecl());
ClassTemplateDecl *TD = LastDeclMatcher<ClassTemplateDecl>().match(
get<1>(Decls), classTemplateDecl(hasName("Base")));
// Reorder the decls, move the TD to the last place in the DC.
NS->removeDecl(TD);
NS->addDeclInternal(TD);
EXPECT_FALSE(testStructuralMatch(Decls));
}
TEST_F(StructuralEquivalenceTest, WrongOrderOfFieldsInClass) {
auto Code = "class X { int a; int b; };";
auto Decls = makeNamedDecls(Code, Code, Lang_CXX03, "X");
CXXRecordDecl *RD = FirstDeclMatcher<CXXRecordDecl>().match(
get<1>(Decls), cxxRecordDecl(hasName("X")));
FieldDecl *FD =
FirstDeclMatcher<FieldDecl>().match(get<1>(Decls), fieldDecl(hasName("a")));
// Reorder the FieldDecls
RD->removeDecl(FD);
RD->addDeclInternal(FD);
EXPECT_FALSE(testStructuralMatch(Decls));
}
struct StructuralEquivalenceFunctionTest : StructuralEquivalenceTest {
};
TEST_F(StructuralEquivalenceFunctionTest, TemplateVsNonTemplate) {
auto t = makeNamedDecls("void foo();", "template<class T> void foo();",
Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, DifferentOperators) {
auto t = makeDecls<FunctionDecl>(
"struct X{}; bool operator<(X, X);", "struct X{}; bool operator==(X, X);",
Lang_CXX03, functionDecl(hasOverloadedOperatorName("<")),
functionDecl(hasOverloadedOperatorName("==")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, SameOperators) {
auto t = makeDecls<FunctionDecl>(
"struct X{}; bool operator<(X, X);", "struct X{}; bool operator<(X, X);",
Lang_CXX03, functionDecl(hasOverloadedOperatorName("<")),
functionDecl(hasOverloadedOperatorName("<")));
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, CtorVsDtor) {
auto t = makeDecls<FunctionDecl>("struct X{ X(); };", "struct X{ ~X(); };",
Lang_CXX03, cxxConstructorDecl(),
cxxDestructorDecl());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ParamConstWithRef) {
auto t =
makeNamedDecls("void foo(int&);", "void foo(const int&);", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ParamConstSimple) {
auto t = makeNamedDecls("void foo(int);", "void foo(const int);", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(t));
// consider this OK
}
TEST_F(StructuralEquivalenceFunctionTest, Throw) {
auto t = makeNamedDecls("void foo();", "void foo() throw();", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, Noexcept) {
auto t = makeNamedDecls("void foo();",
"void foo() noexcept;", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ThrowVsNoexcept) {
auto t = makeNamedDecls("void foo() throw();",
"void foo() noexcept;", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ThrowVsNoexceptFalse) {
auto t = makeNamedDecls("void foo() throw();",
"void foo() noexcept(false);", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ThrowVsNoexceptTrue) {
auto t = makeNamedDecls("void foo() throw();",
"void foo() noexcept(true);", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, NoexceptNonMatch) {
auto t = makeNamedDecls("void foo() noexcept(false);",
"void foo() noexcept(true);", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, NoexceptMatch) {
auto t = makeNamedDecls("void foo() noexcept(false);",
"void foo() noexcept(false);", Lang_CXX11);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, NoexceptVsNoexceptFalse) {
auto t = makeNamedDecls("void foo() noexcept;",
"void foo() noexcept(false);", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, NoexceptVsNoexceptTrue) {
auto t = makeNamedDecls("void foo() noexcept;",
"void foo() noexcept(true);", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ReturnType) {
auto t = makeNamedDecls("char foo();", "int foo();", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ReturnConst) {
auto t = makeNamedDecls("char foo();", "const char foo();", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ReturnRef) {
auto t = makeNamedDecls("char &foo();",
"char &&foo();", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ParamCount) {
auto t = makeNamedDecls("void foo(int);", "void foo(int, int);", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ParamType) {
auto t = makeNamedDecls("void foo(int);", "void foo(char);", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ParamName) {
auto t = makeNamedDecls("void foo(int a);", "void foo(int b);", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, Variadic) {
auto t =
makeNamedDecls("void foo(int x...);", "void foo(int x);", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, ParamPtr) {
auto t = makeNamedDecls("void foo(int *);", "void foo(int);", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, NameInParen) {
auto t = makeNamedDecls("void ((foo))();", "void foo();", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, NameInParenWithExceptionSpec) {
auto t = makeNamedDecls(
"void (foo)() throw(int);",
"void (foo)() noexcept;",
Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, NameInParenWithConst) {
auto t = makeNamedDecls(
"struct A { void (foo)() const; };",
"struct A { void (foo)(); };",
Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, FunctionsWithDifferentNoreturnAttr) {
auto t = makeNamedDecls("__attribute__((noreturn)) void foo();",
" void foo();", Lang_C99);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest,
FunctionsWithDifferentCallingConventions) {
// These attributes may not be available on certain platforms.
if (llvm::Triple(llvm::sys::getDefaultTargetTriple()).getArch() !=
llvm::Triple::x86_64)
return;
auto t = makeNamedDecls("__attribute__((preserve_all)) void foo();",
"__attribute__((ms_abi)) void foo();", Lang_C99);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceFunctionTest, FunctionsWithDifferentSavedRegsAttr) {
if (llvm::Triple(llvm::sys::getDefaultTargetTriple()).getArch() !=
llvm::Triple::x86_64)
return;
auto t = makeNamedDecls(
"__attribute__((no_caller_saved_registers)) void foo();",
" void foo();", Lang_C99);
EXPECT_FALSE(testStructuralMatch(t));
}
struct StructuralEquivalenceCXXMethodTest : StructuralEquivalenceTest {
};
TEST_F(StructuralEquivalenceCXXMethodTest, Virtual) {
auto t = makeDecls<CXXMethodDecl>("struct X { void foo(); };",
"struct X { virtual void foo(); };",
Lang_CXX03, cxxMethodDecl(hasName("foo")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Pure) {
auto t = makeNamedDecls("struct X { virtual void foo(); };",
"struct X { virtual void foo() = 0; };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, DISABLED_Final) {
// The final-ness is not checked yet.
auto t =
makeNamedDecls("struct X { virtual void foo(); };",
"struct X { virtual void foo() final; };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Const) {
auto t = makeNamedDecls("struct X { void foo(); };",
"struct X { void foo() const; };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Static) {
auto t = makeNamedDecls("struct X { void foo(); };",
"struct X { static void foo(); };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Ref1) {
auto t = makeNamedDecls("struct X { void foo(); };",
"struct X { void foo() &&; };", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Ref2) {
auto t = makeNamedDecls("struct X { void foo() &; };",
"struct X { void foo() &&; };", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, AccessSpecifier) {
auto t = makeDecls<CXXMethodDecl>("struct X { public: void foo(); };",
"struct X { private: void foo(); };",
Lang_CXX03, cxxMethodDecl(hasName("foo")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Delete) {
auto t = makeNamedDecls("struct X { void foo(); };",
"struct X { void foo() = delete; };", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Constructor) {
auto t = makeDecls<FunctionDecl>("void foo();", "struct foo { foo(); };",
Lang_CXX03, functionDecl(hasName("foo")),
cxxConstructorDecl(hasName("foo")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, ConstructorParam) {
auto t = makeDecls<CXXConstructorDecl>("struct X { X(); };",
"struct X { X(int); };", Lang_CXX03,
cxxConstructorDecl(hasName("X")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, ConstructorExplicit) {
auto t = makeDecls<CXXConstructorDecl>("struct X { X(int); };",
"struct X { explicit X(int); };",
Lang_CXX11,
cxxConstructorDecl(hasName("X")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, ConstructorDefault) {
auto t = makeDecls<CXXConstructorDecl>("struct X { X(); };",
"struct X { X() = default; };",
Lang_CXX11,
cxxConstructorDecl(hasName("X")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Conversion) {
auto t = makeDecls<CXXConversionDecl>("struct X { operator bool(); };",
"struct X { operator char(); };",
Lang_CXX11,
cxxConversionDecl());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, Operator) {
auto t =
makeDecls<FunctionDecl>("struct X { int operator +(int); };",
"struct X { int operator -(int); };", Lang_CXX03,
functionDecl(hasOverloadedOperatorName("+")),
functionDecl(hasOverloadedOperatorName("-")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, OutOfClass1) {
auto t = makeDecls<FunctionDecl>(
"struct X { virtual void f(); }; void X::f() { }",
"struct X { virtual void f() { }; };", Lang_CXX03,
functionDecl(allOf(hasName("f"), isDefinition())));
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceCXXMethodTest, OutOfClass2) {
auto t = makeDecls<FunctionDecl>(
"struct X { virtual void f(); }; void X::f() { }",
"struct X { void f(); }; void X::f() { }", Lang_CXX03,
functionDecl(allOf(hasName("f"), isDefinition())));
EXPECT_FALSE(testStructuralMatch(t));
}
struct StructuralEquivalenceRecordTest : StructuralEquivalenceTest {
// FIXME Use a common getRecordDecl with ASTImporterTest.cpp!
RecordDecl *getRecordDecl(FieldDecl *FD) {
auto *ET = cast<ElaboratedType>(FD->getType().getTypePtr());
return cast<RecordType>(ET->getNamedType().getTypePtr())->getDecl();
};
};
TEST_F(StructuralEquivalenceRecordTest, Name) {
auto t = makeDecls<CXXRecordDecl>("struct A{ };", "struct B{ };", Lang_CXX03,
cxxRecordDecl(hasName("A")),
cxxRecordDecl(hasName("B")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, Fields) {
auto t = makeNamedDecls("struct foo{ int x; };", "struct foo{ char x; };",
Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, DISABLED_Methods) {
// Currently, methods of a class are not checked at class equivalence.
auto t = makeNamedDecls("struct foo{ int x(); };", "struct foo{ char x(); };",
Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, Bases) {
auto t = makeNamedDecls("struct A{ }; struct foo: A { };",
"struct B{ }; struct foo: B { };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, InheritanceVirtual) {
auto t =
makeNamedDecls("struct A{ }; struct foo: A { };",
"struct A{ }; struct foo: virtual A { };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, DISABLED_InheritanceType) {
// Access specifier in inheritance is not checked yet.
auto t =
makeNamedDecls("struct A{ }; struct foo: public A { };",
"struct A{ }; struct foo: private A { };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, Match) {
auto Code = R"(
struct A{ };
struct B{ };
struct foo: A, virtual B {
void x();
int a;
};
)";
auto t = makeNamedDecls(Code, Code, Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, UnnamedRecordsShouldBeInequivalent) {
auto t = makeTuDecls(
R"(
struct A {
struct {
struct A *next;
} entry0;
struct {
struct A *next;
} entry1;
};
)",
"", Lang_C99);
auto *TU = get<0>(t);
auto *Entry0 =
FirstDeclMatcher<FieldDecl>().match(TU, fieldDecl(hasName("entry0")));
auto *Entry1 =
FirstDeclMatcher<FieldDecl>().match(TU, fieldDecl(hasName("entry1")));
auto *R0 = getRecordDecl(Entry0);
auto *R1 = getRecordDecl(Entry1);
ASSERT_NE(R0, R1);
EXPECT_TRUE(testStructuralMatch(R0, R0));
EXPECT_TRUE(testStructuralMatch(R1, R1));
EXPECT_FALSE(testStructuralMatch(R0, R1));
}
TEST_F(StructuralEquivalenceRecordTest, AnonymousRecordsShouldBeInequivalent) {
auto t = makeTuDecls(
R"(
struct X {
struct {
int a;
};
struct {
int b;
};
};
)",
"", Lang_C99);
auto *TU = get<0>(t);
auto *A = FirstDeclMatcher<IndirectFieldDecl>().match(
TU, indirectFieldDecl(hasName("a")));
auto *FA = cast<FieldDecl>(A->chain().front());
RecordDecl *RA = cast<RecordType>(FA->getType().getTypePtr())->getDecl();
auto *B = FirstDeclMatcher<IndirectFieldDecl>().match(
TU, indirectFieldDecl(hasName("b")));
auto *FB = cast<FieldDecl>(B->chain().front());
RecordDecl *RB = cast<RecordType>(FB->getType().getTypePtr())->getDecl();
ASSERT_NE(RA, RB);
EXPECT_TRUE(testStructuralMatch(RA, RA));
EXPECT_TRUE(testStructuralMatch(RB, RB));
EXPECT_FALSE(testStructuralMatch(RA, RB));
}
TEST_F(StructuralEquivalenceRecordTest,
RecordsAreInequivalentIfOrderOfAnonRecordsIsDifferent) {
auto t = makeTuDecls(
R"(
struct X {
struct { int a; };
struct { int b; };
};
)",
R"(
struct X { // The order is reversed.
struct { int b; };
struct { int a; };
};
)",
Lang_C99);
auto *TU = get<0>(t);
auto *A = FirstDeclMatcher<IndirectFieldDecl>().match(
TU, indirectFieldDecl(hasName("a")));
auto *FA = cast<FieldDecl>(A->chain().front());
RecordDecl *RA = cast<RecordType>(FA->getType().getTypePtr())->getDecl();
auto *TU1 = get<1>(t);
auto *A1 = FirstDeclMatcher<IndirectFieldDecl>().match(
TU1, indirectFieldDecl(hasName("a")));
auto *FA1 = cast<FieldDecl>(A1->chain().front());
RecordDecl *RA1 = cast<RecordType>(FA1->getType().getTypePtr())->getDecl();
RecordDecl *X =
FirstDeclMatcher<RecordDecl>().match(TU, recordDecl(hasName("X")));
RecordDecl *X1 =
FirstDeclMatcher<RecordDecl>().match(TU1, recordDecl(hasName("X")));
ASSERT_NE(X, X1);
EXPECT_FALSE(testStructuralMatch(X, X1));
ASSERT_NE(RA, RA1);
EXPECT_TRUE(testStructuralMatch(RA, RA));
EXPECT_TRUE(testStructuralMatch(RA1, RA1));
EXPECT_FALSE(testStructuralMatch(RA1, RA));
}
TEST_F(StructuralEquivalenceRecordTest,
UnnamedRecordsShouldBeInequivalentEvenIfTheSecondIsBeingDefined) {
auto Code =
R"(
struct A {
struct {
struct A *next;
} entry0;
struct {
struct A *next;
} entry1;
};
)";
auto t = makeTuDecls(Code, Code, Lang_C99);
auto *FromTU = get<0>(t);
auto *Entry1 =
FirstDeclMatcher<FieldDecl>().match(FromTU, fieldDecl(hasName("entry1")));
auto *ToTU = get<1>(t);
auto *Entry0 =
FirstDeclMatcher<FieldDecl>().match(ToTU, fieldDecl(hasName("entry0")));
auto *A =
FirstDeclMatcher<RecordDecl>().match(ToTU, recordDecl(hasName("A")));
A->startDefinition(); // Set isBeingDefined, getDefinition() will return a
// nullptr. This may be the case during ASTImport.
auto *R0 = getRecordDecl(Entry0);
auto *R1 = getRecordDecl(Entry1);
ASSERT_NE(R0, R1);
EXPECT_TRUE(testStructuralMatch(R0, R0));
EXPECT_TRUE(testStructuralMatch(R1, R1));
EXPECT_FALSE(testStructuralMatch(R0, R1));
}
TEST_F(StructuralEquivalenceRecordTest, TemplateVsNonTemplate) {
auto t = makeDecls<CXXRecordDecl>("struct A { };",
"template<class T> struct A { };",
Lang_CXX03, cxxRecordDecl(hasName("A")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest,
FwdDeclRecordShouldBeEqualWithFwdDeclRecord) {
auto t = makeNamedDecls("class foo;", "class foo;", Lang_CXX11);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest,
FwdDeclRecordShouldBeEqualWithRecordWhichHasDefinition) {
auto t =
makeNamedDecls("class foo;", "class foo { int A; };", Lang_CXX11);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest,
RecordShouldBeEqualWithRecordWhichHasDefinition) {
auto t = makeNamedDecls("class foo { int A; };", "class foo { int A; };",
Lang_CXX11);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, RecordsWithDifferentBody) {
auto t = makeNamedDecls("class foo { int B; };", "class foo { int A; };",
Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, SameFriendMultipleTimes) {
auto t = makeNamedDecls("struct foo { friend class X; };",
"struct foo { friend class X; friend class X; };",
Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, SameFriendsDifferentOrder) {
auto t = makeNamedDecls("struct foo { friend class X; friend class Y; };",
"struct foo { friend class Y; friend class X; };",
Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceRecordTest, SameFriendsSameOrder) {
auto t = makeNamedDecls("struct foo { friend class X; friend class Y; };",
"struct foo { friend class X; friend class Y; };",
Lang_CXX11);
EXPECT_TRUE(testStructuralMatch(t));
}
struct StructuralEquivalenceLambdaTest : StructuralEquivalenceTest {};
TEST_F(StructuralEquivalenceLambdaTest, LambdaClassesWithDifferentMethods) {
// Get the LambdaExprs, unfortunately we can't match directly the underlying
// implicit CXXRecordDecl of the Lambda classes.
auto t = makeDecls<LambdaExpr>(
"void f() { auto L0 = [](int){}; }",
"void f() { auto L1 = [](){}; }",
Lang_CXX11,
lambdaExpr(),
lambdaExpr());
CXXRecordDecl *L0 = get<0>(t)->getLambdaClass();
CXXRecordDecl *L1 = get<1>(t)->getLambdaClass();
EXPECT_FALSE(testStructuralMatch(L0, L1));
}
TEST_F(StructuralEquivalenceLambdaTest, LambdaClassesWithEqMethods) {
auto t = makeDecls<LambdaExpr>(
"void f() { auto L0 = [](int){}; }",
"void f() { auto L1 = [](int){}; }",
Lang_CXX11,
lambdaExpr(),
lambdaExpr());
CXXRecordDecl *L0 = get<0>(t)->getLambdaClass();
CXXRecordDecl *L1 = get<1>(t)->getLambdaClass();
EXPECT_TRUE(testStructuralMatch(L0, L1));
}
TEST_F(StructuralEquivalenceLambdaTest, LambdaClassesWithDifferentFields) {
auto t = makeDecls<LambdaExpr>(
"void f() { char* X; auto L0 = [X](){}; }",
"void f() { float X; auto L1 = [X](){}; }",
Lang_CXX11,
lambdaExpr(),
lambdaExpr());
CXXRecordDecl *L0 = get<0>(t)->getLambdaClass();
CXXRecordDecl *L1 = get<1>(t)->getLambdaClass();
EXPECT_FALSE(testStructuralMatch(L0, L1));
}
TEST_F(StructuralEquivalenceLambdaTest, LambdaClassesWithEqFields) {
auto t = makeDecls<LambdaExpr>(
"void f() { float X; auto L0 = [X](){}; }",
"void f() { float X; auto L1 = [X](){}; }",
Lang_CXX11,
lambdaExpr(),
lambdaExpr());
CXXRecordDecl *L0 = get<0>(t)->getLambdaClass();
CXXRecordDecl *L1 = get<1>(t)->getLambdaClass();
EXPECT_TRUE(testStructuralMatch(L0, L1));
}
TEST_F(StructuralEquivalenceTest, CompareSameDeclWithMultiple) {
auto t = makeNamedDecls("struct A{ }; struct B{ }; void foo(A a, A b);",
"struct A{ }; struct B{ }; void foo(A a, B b);",
Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTest, ExplicitBoolDifferent) {
auto Decls = makeNamedDecls("struct foo {explicit(false) foo(int);};",
"struct foo {explicit(true) foo(int);};", Lang_CXX20);
CXXConstructorDecl *First = FirstDeclMatcher<CXXConstructorDecl>().match(
get<0>(Decls), cxxConstructorDecl(hasName("foo")));
CXXConstructorDecl *Second = FirstDeclMatcher<CXXConstructorDecl>().match(
get<1>(Decls), cxxConstructorDecl(hasName("foo")));
EXPECT_FALSE(testStructuralMatch(First, Second));
}
TEST_F(StructuralEquivalenceTest, ExplicitBoolSame) {
auto Decls = makeNamedDecls("struct foo {explicit(true) foo(int);};",
"struct foo {explicit(true) foo(int);};", Lang_CXX20);
CXXConstructorDecl *First = FirstDeclMatcher<CXXConstructorDecl>().match(
get<0>(Decls), cxxConstructorDecl(hasName("foo")));
CXXConstructorDecl *Second = FirstDeclMatcher<CXXConstructorDecl>().match(
get<1>(Decls), cxxConstructorDecl(hasName("foo")));
EXPECT_TRUE(testStructuralMatch(First, Second));
}
struct StructuralEquivalenceEnumTest : StructuralEquivalenceTest {};
TEST_F(StructuralEquivalenceEnumTest, FwdDeclEnumShouldBeEqualWithFwdDeclEnum) {
auto t = makeNamedDecls("enum class foo;", "enum class foo;", Lang_CXX11);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceEnumTest,
FwdDeclEnumShouldBeEqualWithEnumWhichHasDefinition) {
auto t =
makeNamedDecls("enum class foo;", "enum class foo { A };", Lang_CXX11);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceEnumTest,
EnumShouldBeEqualWithEnumWhichHasDefinition) {
auto t = makeNamedDecls("enum class foo { A };", "enum class foo { A };",
Lang_CXX11);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceEnumTest, EnumsWithDifferentBody) {
auto t = makeNamedDecls("enum class foo { B };", "enum class foo { A };",
Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
struct StructuralEquivalenceEnumConstantTest : StructuralEquivalenceTest {};
TEST_F(StructuralEquivalenceEnumConstantTest, EnumConstantsWithSameValues) {
auto t = makeNamedDecls("enum foo { foo = 1 };", "enum foo { foo = 1 };",
Lang_C89);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceEnumConstantTest,
EnumConstantsWithDifferentValues) {
auto t =
makeNamedDecls("enum e { foo = 1 };", "enum e { foo = 2 };", Lang_C89);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceEnumConstantTest,
EnumConstantsWithDifferentExprsButSameValues) {
auto t = makeNamedDecls("enum e { foo = 1 + 1 };", "enum e { foo = 2 };",
Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceEnumConstantTest,
EnumConstantsWithDifferentSignedness) {
auto t = makeNamedDecls("enum e : unsigned { foo = 1 };",
"enum e : int { foo = 1 };", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceEnumConstantTest, EnumConstantsWithDifferentWidth) {
auto t = makeNamedDecls("enum e : short { foo = 1 };",
"enum e : int { foo = 1 };", Lang_CXX11);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceEnumConstantTest, EnumConstantsWithDifferentName) {
auto t =
makeDecls<EnumConstantDecl>("enum e { foo = 1 };", "enum e { bar = 1 };",
Lang_CXX11, enumConstantDecl());
EXPECT_FALSE(testStructuralMatch(t));
}
struct StructuralEquivalenceTemplateTest : StructuralEquivalenceTest {};
TEST_F(StructuralEquivalenceTemplateTest, ExactlySameTemplates) {
auto t = makeNamedDecls("template <class T> struct foo;",
"template <class T> struct foo;", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest, DifferentTemplateArgName) {
auto t = makeNamedDecls("template <class T> struct foo;",
"template <class U> struct foo;", Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest, DifferentTemplateArgKind) {
auto t = makeNamedDecls("template <class T> struct foo;",
"template <int T> struct foo;", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest, BitFieldDecl) {
const char *Code = "class foo { int a : 2; };";
auto t = makeNamedDecls(Code, Code, Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest, BitFieldDeclDifferentWidth) {
auto t = makeNamedDecls("class foo { int a : 2; };",
"class foo { int a : 4; };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest, DependentBitFieldDecl) {
const char *Code = "template <class T> class foo { int a : sizeof(T); };";
auto t = makeNamedDecls(Code, Code, Lang_CXX03);
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest, DependentBitFieldDeclDifferentVal) {
auto t = makeNamedDecls(
"template <class A, class B> class foo { int a : sizeof(A); };",
"template <class A, class B> class foo { int a : sizeof(B); };",
Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest, DependentBitFieldDeclDifferentVal2) {
auto t = makeNamedDecls(
"template <class A> class foo { int a : sizeof(A); };",
"template <class A> class foo { int a : sizeof(A) + 1; };", Lang_CXX03);
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest, ExplicitBoolSame) {
auto Decls = makeNamedDecls(
"template <bool b> struct foo {explicit(b) foo(int);};",
"template <bool b> struct foo {explicit(b) foo(int);};", Lang_CXX20);
CXXConstructorDecl *First = FirstDeclMatcher<CXXConstructorDecl>().match(
get<0>(Decls), cxxConstructorDecl(hasName("foo<b>")));
CXXConstructorDecl *Second = FirstDeclMatcher<CXXConstructorDecl>().match(
get<1>(Decls), cxxConstructorDecl(hasName("foo<b>")));
EXPECT_TRUE(testStructuralMatch(First, Second));
}
TEST_F(StructuralEquivalenceTemplateTest, ExplicitBoolDifference) {
auto Decls = makeNamedDecls(
"template <bool b> struct foo {explicit(b) foo(int);};",
"template <bool b> struct foo {explicit(!b) foo(int);};", Lang_CXX20);
CXXConstructorDecl *First = FirstDeclMatcher<CXXConstructorDecl>().match(
get<0>(Decls), cxxConstructorDecl(hasName("foo<b>")));
CXXConstructorDecl *Second = FirstDeclMatcher<CXXConstructorDecl>().match(
get<1>(Decls), cxxConstructorDecl(hasName("foo<b>")));
EXPECT_FALSE(testStructuralMatch(First, Second));
}
TEST_F(StructuralEquivalenceTemplateTest,
TemplateVsSubstTemplateTemplateParmInArgEq) {
auto t = makeDecls<ClassTemplateSpecializationDecl>(
R"(
template <typename P1> class Arg { };
template <template <typename PP1> class P1> class Primary { };
void f() {
// Make specialization with simple template.
Primary <Arg> A;
}
)",
R"(
template <typename P1> class Arg { };
template <template <typename PP1> class P1> class Primary { };
template <template <typename PP1> class P1> class Templ {
void f() {
// Make specialization with substituted template template param.
Primary <P1> A;
};
};
// Instantiate with substitution Arg into P1.
template class Templ <Arg>;
)",
Lang_CXX03, classTemplateSpecializationDecl(hasName("Primary")));
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceTemplateTest,
TemplateVsSubstTemplateTemplateParmInArgNotEq) {
auto t = makeDecls<ClassTemplateSpecializationDecl>(
R"(
template <typename P1> class Arg { };
template <template <typename PP1> class P1> class Primary { };
void f() {
// Make specialization with simple template.
Primary <Arg> A;
}
)",
R"(
// Arg is different from the other, this should cause non-equivalence.
template <typename P1> class Arg { int X; };
template <template <typename PP1> class P1> class Primary { };
template <template <typename PP1> class P1> class Templ {
void f() {
// Make specialization with substituted template template param.
Primary <P1> A;
};
};
// Instantiate with substitution Arg into P1.
template class Templ <Arg>;
)",
Lang_CXX03, classTemplateSpecializationDecl(hasName("Primary")));
EXPECT_FALSE(testStructuralMatch(t));
}
struct StructuralEquivalenceDependentTemplateArgsTest
: StructuralEquivalenceTemplateTest {};
TEST_F(StructuralEquivalenceDependentTemplateArgsTest,
SameStructsInDependentArgs) {
std::string Code =
R"(
template <typename>
struct S1;
template <typename>
struct enable_if;
struct S
{
template <typename T, typename enable_if<S1<T>>::type>
void f();
};
)";
auto t = makeDecls<FunctionTemplateDecl>(Code, Code, Lang_CXX11,
functionTemplateDecl(hasName("f")));
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceDependentTemplateArgsTest,
DifferentStructsInDependentArgs) {
std::string Code =
R"(
template <typename>
struct S1;
template <typename>
struct S2;
template <typename>
struct enable_if;
)";
auto t = makeDecls<FunctionTemplateDecl>(Code + R"(
struct S
{
template <typename T, typename enable_if<S1<T>>::type>
void f();
};
)",
Code + R"(
struct S
{
template <typename T, typename enable_if<S2<T>>::type>
void f();
};
)",
Lang_CXX11,
functionTemplateDecl(hasName("f")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceDependentTemplateArgsTest,
SameStructsInDependentScopeDeclRefExpr) {
std::string Code =
R"(
template <typename>
struct S1;
template <bool>
struct enable_if;
struct S
{
template <typename T, typename enable_if<S1<T>::value>::type>
void f(); // DependentScopeDeclRefExpr:^^^^^^^^^^^^
};
)";
auto t = makeDecls<FunctionTemplateDecl>(Code, Code, Lang_CXX11,
functionTemplateDecl(hasName("f")));
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceDependentTemplateArgsTest,
DifferentStructsInDependentScopeDeclRefExpr) {
std::string Code =
R"(
template <typename>
struct S1;
template <typename>
struct S2;
template <bool>
struct enable_if;
)";
auto t = makeDecls<FunctionTemplateDecl>(Code + R"(
struct S
{
template <typename T, typename enable_if<S1<T>::value>::type>
void f(); // DependentScopeDeclRefExpr:^^^^^^^^^^^^
};
)",
Code + R"(
struct S
{
template <typename T, typename enable_if<S2<T>::value>::type>
void f();
};
)",
Lang_CXX03,
functionTemplateDecl(hasName("f")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceDependentTemplateArgsTest,
DifferentValueInDependentScopeDeclRefExpr) {
std::string Code =
R"(
template <typename>
struct S1;
template <bool>
struct enable_if;
)";
auto t = makeDecls<FunctionTemplateDecl>(Code + R"(
struct S
{
template <typename T, typename enable_if<S1<T>::value1>::type>
void f(); // DependentScopeDeclRefExpr:^^^^^^^^^^^^
};
)",
Code + R"(
struct S
{
template <typename T, typename enable_if<S1<T>::value2>::type>
void f();
};
)",
Lang_CXX03,
functionTemplateDecl(hasName("f")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(
StructuralEquivalenceTemplateTest,
ClassTemplSpecWithQualifiedAndNonQualifiedTypeArgsShouldBeEqual) {
auto t = makeDecls<ClassTemplateSpecializationDecl>(
R"(
template <class T> struct Primary {};
namespace N {
struct Arg;
}
// Explicit instantiation with qualified name.
template struct Primary<N::Arg>;
)",
R"(
template <class T> struct Primary {};
namespace N {
struct Arg;
}
using namespace N;
// Explicit instantiation with UNqualified name.
template struct Primary<Arg>;
)",
Lang_CXX03, classTemplateSpecializationDecl(hasName("Primary")));
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(
StructuralEquivalenceTemplateTest,
ClassTemplSpecWithInequivalentQualifiedAndNonQualifiedTypeArgs) {
auto t = makeDecls<ClassTemplateSpecializationDecl>(
R"(
template <class T> struct Primary {};
namespace N {
struct Arg { int a; };
}
// Explicit instantiation with qualified name.
template struct Primary<N::Arg>;
)",
R"(
template <class T> struct Primary {};
namespace N {
// This struct is not equivalent with the other in the prev TU.
struct Arg { double b; }; // -- Field mismatch.
}
using namespace N;
// Explicit instantiation with UNqualified name.
template struct Primary<Arg>;
)",
Lang_CXX03, classTemplateSpecializationDecl(hasName("Primary")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(
StructuralEquivalenceTemplateTest,
ClassTemplSpecWithQualifiedAndNonQualifiedTemplArgsShouldBeEqual) {
auto t = makeDecls<ClassTemplateSpecializationDecl>(
R"(
template <template <class> class T> struct Primary {};
namespace N {
template <class T> struct Arg;
}
// Explicit instantiation with qualified name.
template struct Primary<N::Arg>;
)",
R"(
template <template <class> class T> struct Primary {};
namespace N {
template <class T> struct Arg;
}
using namespace N;
// Explicit instantiation with UNqualified name.
template struct Primary<Arg>;
)",
Lang_CXX03, classTemplateSpecializationDecl(hasName("Primary")));
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(
StructuralEquivalenceTemplateTest,
ClassTemplSpecWithInequivalentQualifiedAndNonQualifiedTemplArgs) {
auto t = makeDecls<ClassTemplateSpecializationDecl>(
R"(
template <template <class> class T> struct Primary {};
namespace N {
template <class T> struct Arg { int a; };
}
// Explicit instantiation with qualified name.
template struct Primary<N::Arg>;
)",
R"(
template <template <class> class T> struct Primary {};
namespace N {
// This template is not equivalent with the other in the prev TU.
template <class T> struct Arg { double b; }; // -- Field mismatch.
}
using namespace N;
// Explicit instantiation with UNqualified name.
template struct Primary<Arg>;
)",
Lang_CXX03, classTemplateSpecializationDecl(hasName("Primary")));
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(
StructuralEquivalenceTemplateTest,
ClassTemplSpecWithInequivalentShadowedTemplArg) {
auto t = makeDecls<ClassTemplateSpecializationDecl>(
R"(
template <template <class> class T> struct Primary {};
template <class T> struct Arg { int a; };
// Explicit instantiation with ::Arg
template struct Primary<Arg>;
)",
R"(
template <template <class> class T> struct Primary {};
template <class T> struct Arg { int a; };
namespace N {
// This template is not equivalent with the other in the global scope.
template <class T> struct Arg { double b; }; // -- Field mismatch.
// Explicit instantiation with N::Arg which shadows ::Arg
template struct Primary<Arg>;
}
)",
Lang_CXX03, classTemplateSpecializationDecl(hasName("Primary")));
EXPECT_FALSE(testStructuralMatch(t));
}
struct StructuralEquivalenceCacheTest : public StructuralEquivalenceTest {
llvm::DenseSet<std::pair<Decl *, Decl *>> NonEquivalentDecls;
template <typename NodeType, typename MatcherType>
std::pair<NodeType *, NodeType *>
findDeclPair(std::tuple<TranslationUnitDecl *, TranslationUnitDecl *> TU,
MatcherType M) {
NodeType *D0 = FirstDeclMatcher<NodeType>().match(get<0>(TU), M);
NodeType *D1 = FirstDeclMatcher<NodeType>().match(get<1>(TU), M);
return {D0, D1};
}
template <typename NodeType>
bool isInNonEqCache(std::pair<NodeType *, NodeType *> D) {
return NonEquivalentDecls.count(D) > 0;
}
};
TEST_F(StructuralEquivalenceCacheTest, SimpleNonEq) {
auto TU = makeTuDecls(
R"(
class A {};
class B {};
void x(A, A);
)",
R"(
class A {};
class B {};
void x(A, B);
)",
Lang_CXX03);
StructuralEquivalenceContext Ctx(
get<0>(TU)->getASTContext(), get<1>(TU)->getASTContext(),
NonEquivalentDecls, StructuralEquivalenceKind::Default, false, false);
auto X = findDeclPair<FunctionDecl>(TU, functionDecl(hasName("x")));
EXPECT_FALSE(Ctx.IsEquivalent(X.first, X.second));
EXPECT_FALSE(isInNonEqCache(findDeclPair<CXXRecordDecl>(
TU, cxxRecordDecl(hasName("A"), unless(isImplicit())))));
EXPECT_FALSE(isInNonEqCache(findDeclPair<CXXRecordDecl>(
TU, cxxRecordDecl(hasName("B"), unless(isImplicit())))));
}
TEST_F(StructuralEquivalenceCacheTest, SpecialNonEq) {
auto TU = makeTuDecls(
R"(
class A {};
class B { int i; };
void x(A *);
void y(A *);
class C {
friend void x(A *);
friend void y(A *);
};
)",
R"(
class A {};
class B { int i; };
void x(A *);
void y(B *);
class C {
friend void x(A *);
friend void y(B *);
};
)",
Lang_CXX03);
StructuralEquivalenceContext Ctx(
get<0>(TU)->getASTContext(), get<1>(TU)->getASTContext(),
NonEquivalentDecls, StructuralEquivalenceKind::Default, false, false);
auto C = findDeclPair<CXXRecordDecl>(
TU, cxxRecordDecl(hasName("C"), unless(isImplicit())));
EXPECT_FALSE(Ctx.IsEquivalent(C.first, C.second));
EXPECT_FALSE(isInNonEqCache(C));
EXPECT_FALSE(isInNonEqCache(findDeclPair<CXXRecordDecl>(
TU, cxxRecordDecl(hasName("A"), unless(isImplicit())))));
EXPECT_FALSE(isInNonEqCache(findDeclPair<CXXRecordDecl>(
TU, cxxRecordDecl(hasName("B"), unless(isImplicit())))));
EXPECT_FALSE(isInNonEqCache(
findDeclPair<FunctionDecl>(TU, functionDecl(hasName("x")))));
EXPECT_FALSE(isInNonEqCache(
findDeclPair<FunctionDecl>(TU, functionDecl(hasName("y")))));
}
TEST_F(StructuralEquivalenceCacheTest, Cycle) {
auto TU = makeTuDecls(
R"(
class C;
class A { C *c; };
void x(A *);
class C {
friend void x(A *);
};
)",
R"(
class C;
class A { C *c; };
void x(A *);
class C {
friend void x(A *);
};
)",
Lang_CXX03);
StructuralEquivalenceContext Ctx(
get<0>(TU)->getASTContext(), get<1>(TU)->getASTContext(),
NonEquivalentDecls, StructuralEquivalenceKind::Default, false, false);
auto C = findDeclPair<CXXRecordDecl>(
TU, cxxRecordDecl(hasName("C"), unless(isImplicit())));
EXPECT_TRUE(Ctx.IsEquivalent(C.first, C.second));
EXPECT_FALSE(isInNonEqCache(C));
EXPECT_FALSE(isInNonEqCache(findDeclPair<CXXRecordDecl>(
TU, cxxRecordDecl(hasName("A"), unless(isImplicit())))));
EXPECT_FALSE(isInNonEqCache(
findDeclPair<FunctionDecl>(TU, functionDecl(hasName("x")))));
}
struct StructuralEquivalenceStmtTest : StructuralEquivalenceTest {};
/// Fallback matcher to be used only when there is no specific matcher for a
/// Expr subclass. Remove this once all Expr subclasses have their own matcher.
static auto &fallbackExprMatcher = expr;
TEST_F(StructuralEquivalenceStmtTest, AddrLabelExpr) {
auto t = makeWrappedStmts("lbl: &&lbl;", "lbl: &&lbl;", Lang_CXX03,
addrLabelExpr());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, AddrLabelExprDifferentLabel) {
auto t = makeWrappedStmts("lbl1: lbl2: &&lbl1;", "lbl1: lbl2: &&lbl2;",
Lang_CXX03, addrLabelExpr());
// FIXME: Should be false. LabelDecl are incorrectly matched.
EXPECT_TRUE(testStructuralMatch(t));
}
static const std::string MemoryOrderSrc = R"(
enum memory_order {
memory_order_relaxed,
memory_order_consume,
memory_order_acquire,
memory_order_release,
memory_order_acq_rel,
memory_order_seq_cst
};
)";
TEST_F(StructuralEquivalenceStmtTest, AtomicExpr) {
std::string Prefix = "char a, b; " + MemoryOrderSrc;
auto t = makeStmts(
Prefix +
"void wrapped() { __atomic_load(&a, &b, memory_order_seq_cst); }",
Prefix +
"void wrapped() { __atomic_load(&a, &b, memory_order_seq_cst); }",
Lang_CXX03, atomicExpr());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, AtomicExprDifferentOp) {
std::string Prefix = "char a, b; " + MemoryOrderSrc;
auto t = makeStmts(
Prefix +
"void wrapped() { __atomic_load(&a, &b, memory_order_seq_cst); }",
Prefix +
"void wrapped() { __atomic_store(&a, &b, memory_order_seq_cst); }",
Lang_CXX03, atomicExpr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, BinaryOperator) {
auto t = makeWrappedStmts("1 + 1", "1 + 1", Lang_CXX03, binaryOperator());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, BinaryOperatorDifferentOps) {
auto t = makeWrappedStmts("1 + 1", "1 - 1", Lang_CXX03, binaryOperator());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, CallExpr) {
std::string Src = "int call(); int wrapped() { call(); }";
auto t = makeStmts(Src, Src, Lang_CXX03, callExpr());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, CallExprDifferentCallee) {
std::string FunctionSrc = "int func1(); int func2();\n";
auto t = makeStmts(FunctionSrc + "void wrapper() { func1(); }",
FunctionSrc + "void wrapper() { func2(); }", Lang_CXX03,
callExpr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, CharacterLiteral) {
auto t = makeWrappedStmts("'a'", "'a'", Lang_CXX03, characterLiteral());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, CharacterLiteralDifferentValues) {
auto t = makeWrappedStmts("'a'", "'b'", Lang_CXX03, characterLiteral());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, ExpressionTraitExpr) {
auto t = makeWrappedStmts("__is_lvalue_expr(1)", "__is_lvalue_expr(1)",
Lang_CXX03, fallbackExprMatcher());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, ExpressionTraitExprDifferentKind) {
auto t = makeWrappedStmts("__is_lvalue_expr(1)", "__is_rvalue_expr(1)",
Lang_CXX03, fallbackExprMatcher());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, FloatingLiteral) {
auto t = makeWrappedStmts("1.0", "1.0", Lang_CXX03, fallbackExprMatcher());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, FloatingLiteralDifferentSpelling) {
auto t = makeWrappedStmts("0x10.1p0", "16.0625", Lang_CXX17,
fallbackExprMatcher());
// Same value but with different spelling is equivalent.
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, FloatingLiteralDifferentType) {
auto t = makeWrappedStmts("1.0", "1.0f", Lang_CXX03, fallbackExprMatcher());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, FloatingLiteralDifferentValue) {
auto t = makeWrappedStmts("1.01", "1.0", Lang_CXX03, fallbackExprMatcher());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, GenericSelectionExprSame) {
auto t = makeWrappedStmts("_Generic(0u, unsigned int: 0, float: 1)",
"_Generic(0u, unsigned int: 0, float: 1)", Lang_C99,
genericSelectionExpr());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, GenericSelectionExprSignsDiffer) {
auto t = makeWrappedStmts("_Generic(0u, unsigned int: 0, float: 1)",
"_Generic(0, int: 0, float: 1)", Lang_C99,
genericSelectionExpr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, GenericSelectionExprOrderDiffers) {
auto t = makeWrappedStmts("_Generic(0u, unsigned int: 0, float: 1)",
"_Generic(0u, float: 1, unsigned int: 0)", Lang_C99,
genericSelectionExpr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, GenericSelectionExprDependentResultSame) {
auto t = makeStmts(
R"(
template <typename T>
void f() {
T x;
(void)_Generic(x, int: 0, float: 1);
}
void g() { f<int>(); }
)",
R"(
template <typename T>
void f() {
T x;
(void)_Generic(x, int: 0, float: 1);
}
void g() { f<int>(); }
)",
Lang_CXX03, genericSelectionExpr());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest,
GenericSelectionExprDependentResultOrderDiffers) {
auto t = makeStmts(
R"(
template <typename T>
void f() {
T x;
(void)_Generic(x, float: 1, int: 0);
}
void g() { f<int>(); }
)",
R"(
template <typename T>
void f() {
T x;
(void)_Generic(x, int: 0, float: 1);
}
void g() { f<int>(); }
)",
Lang_CXX03, genericSelectionExpr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, IntegerLiteral) {
auto t = makeWrappedStmts("1", "1", Lang_CXX03, integerLiteral());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, IntegerLiteralDifferentSpelling) {
auto t = makeWrappedStmts("1", "0x1", Lang_CXX03, integerLiteral());
// Same value but with different spelling is equivalent.
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, IntegerLiteralDifferentValue) {
auto t = makeWrappedStmts("1", "2", Lang_CXX03, integerLiteral());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, IntegerLiteralDifferentTypes) {
auto t = makeWrappedStmts("1", "1L", Lang_CXX03, integerLiteral());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, MemberExpr) {
std::string ClassSrc = "struct C { int a; int b; };";
auto t = makeStmts(ClassSrc + "int wrapper() { C c; return c.a; }",
ClassSrc + "int wrapper() { C c; return c.a; }",
Lang_CXX03, memberExpr());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, MemberExprDifferentMember) {
std::string ClassSrc = "struct C { int a; int b; };";
auto t = makeStmts(ClassSrc + "int wrapper() { C c; return c.a; }",
ClassSrc + "int wrapper() { C c; return c.b; }",
Lang_CXX03, memberExpr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, ObjCStringLiteral) {
auto t =
makeWrappedStmts("@\"a\"", "@\"a\"", Lang_OBJCXX, fallbackExprMatcher());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, ObjCStringLiteralDifferentContent) {
auto t =
makeWrappedStmts("@\"a\"", "@\"b\"", Lang_OBJCXX, fallbackExprMatcher());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, StringLiteral) {
auto t = makeWrappedStmts("\"a\"", "\"a\"", Lang_CXX03, stringLiteral());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, StringLiteralDifferentContent) {
auto t = makeWrappedStmts("\"a\"", "\"b\"", Lang_CXX03, stringLiteral());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, StringLiteralDifferentLength) {
auto t = makeWrappedStmts("\"a\"", "\"aa\"", Lang_CXX03, stringLiteral());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, TypeTraitExpr) {
auto t = makeWrappedStmts("__is_pod(int)", "__is_pod(int)", Lang_CXX03,
fallbackExprMatcher());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, TypeTraitExprDifferentType) {
auto t = makeWrappedStmts("__is_pod(int)", "__is_pod(long)", Lang_CXX03,
fallbackExprMatcher());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, TypeTraitExprDifferentTrait) {
auto t = makeWrappedStmts(
"__is_pod(int)", "__is_trivially_constructible(int)", Lang_CXX03, expr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, TypeTraitExprDifferentTraits) {
auto t = makeWrappedStmts("__is_constructible(int)",
"__is_constructible(int, int)", Lang_CXX03, expr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, UnaryExprOrTypeTraitExpr) {
auto t = makeWrappedStmts("sizeof(int)", "sizeof(int)", Lang_CXX03,
unaryExprOrTypeTraitExpr());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, UnaryExprOrTypeTraitExprDifferentKind) {
auto t = makeWrappedStmts("sizeof(int)", "alignof(long)", Lang_CXX11,
unaryExprOrTypeTraitExpr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, UnaryExprOrTypeTraitExprDifferentType) {
auto t = makeWrappedStmts("sizeof(int)", "sizeof(long)", Lang_CXX03,
unaryExprOrTypeTraitExpr());
EXPECT_FALSE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, UnaryOperator) {
auto t = makeWrappedStmts("+1", "+1", Lang_CXX03, unaryOperator());
EXPECT_TRUE(testStructuralMatch(t));
}
TEST_F(StructuralEquivalenceStmtTest, UnaryOperatorDifferentOps) {
auto t = makeWrappedStmts("+1", "-1", Lang_CXX03, unaryOperator());
EXPECT_FALSE(testStructuralMatch(t));
}
} // end namespace ast_matchers
} // end namespace clang