//== unittests/ASTMatchers/ASTMatchersNodeTest.cpp - AST matcher unit tests ==// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "ASTMatchersTest.h" #include "clang/AST/PrettyPrinter.h" #include "clang/ASTMatchers/ASTMatchFinder.h" #include "clang/ASTMatchers/ASTMatchers.h" #include "clang/Tooling/Tooling.h" #include "llvm/ADT/Triple.h" #include "llvm/Support/Host.h" #include "gtest/gtest.h" namespace clang { namespace ast_matchers { TEST(Finder, DynamicOnlyAcceptsSomeMatchers) { MatchFinder Finder; EXPECT_TRUE(Finder.addDynamicMatcher(decl(), nullptr)); EXPECT_TRUE(Finder.addDynamicMatcher(callExpr(), nullptr)); EXPECT_TRUE(Finder.addDynamicMatcher(constantArrayType(hasSize(42)), nullptr)); // Do not accept non-toplevel matchers. EXPECT_FALSE(Finder.addDynamicMatcher(isArrow(), nullptr)); EXPECT_FALSE(Finder.addDynamicMatcher(hasName("x"), nullptr)); } TEST(Decl, MatchesDeclarations) { EXPECT_TRUE(notMatches("", decl(usingDecl()))); EXPECT_TRUE(matches("namespace x { class X {}; } using x::X;", decl(usingDecl()))); } TEST(NameableDeclaration, MatchesVariousDecls) { DeclarationMatcher NamedX = namedDecl(hasName("X")); EXPECT_TRUE(matches("typedef int X;", NamedX)); EXPECT_TRUE(matches("int X;", NamedX)); EXPECT_TRUE(matches("class foo { virtual void X(); };", NamedX)); EXPECT_TRUE(matches("void foo() try { } catch(int X) { }", NamedX)); EXPECT_TRUE(matches("void foo() { int X; }", NamedX)); EXPECT_TRUE(matches("namespace X { }", NamedX)); EXPECT_TRUE(matches("enum X { A, B, C };", NamedX)); EXPECT_TRUE(notMatches("#define X 1", NamedX)); } TEST(NameableDeclaration, REMatchesVariousDecls) { DeclarationMatcher NamedX = namedDecl(matchesName("::X")); EXPECT_TRUE(matches("typedef int Xa;", NamedX)); EXPECT_TRUE(matches("int Xb;", NamedX)); EXPECT_TRUE(matches("class foo { virtual void Xc(); };", NamedX)); EXPECT_TRUE(matches("void foo() try { } catch(int Xdef) { }", NamedX)); EXPECT_TRUE(matches("void foo() { int Xgh; }", NamedX)); EXPECT_TRUE(matches("namespace Xij { }", NamedX)); EXPECT_TRUE(matches("enum X { A, B, C };", NamedX)); EXPECT_TRUE(notMatches("#define Xkl 1", NamedX)); DeclarationMatcher StartsWithNo = namedDecl(matchesName("::no")); EXPECT_TRUE(matches("int no_foo;", StartsWithNo)); EXPECT_TRUE(matches("class foo { virtual void nobody(); };", StartsWithNo)); DeclarationMatcher Abc = namedDecl(matchesName("a.*b.*c")); EXPECT_TRUE(matches("int abc;", Abc)); EXPECT_TRUE(matches("int aFOObBARc;", Abc)); EXPECT_TRUE(notMatches("int cab;", Abc)); EXPECT_TRUE(matches("int cabc;", Abc)); DeclarationMatcher StartsWithK = namedDecl(matchesName(":k[^:]*$")); EXPECT_TRUE(matches("int k;", StartsWithK)); EXPECT_TRUE(matches("int kAbc;", StartsWithK)); EXPECT_TRUE(matches("namespace x { int kTest; }", StartsWithK)); EXPECT_TRUE(matches("class C { int k; };", StartsWithK)); EXPECT_TRUE(notMatches("class C { int ckc; };", StartsWithK)); } TEST(DeclarationMatcher, MatchClass) { DeclarationMatcher ClassMatcher(recordDecl()); // This passes on Windows only because we explicitly pass -target // i386-unknown-unknown. If we were to compile with the default target // triple, we'd want to EXPECT_TRUE if it's Win32 or MSVC. EXPECT_FALSE(matches("", ClassMatcher)); DeclarationMatcher ClassX = recordDecl(recordDecl(hasName("X"))); EXPECT_TRUE(matches("class X;", ClassX)); EXPECT_TRUE(matches("class X {};", ClassX)); EXPECT_TRUE(matches("template class X {};", ClassX)); EXPECT_TRUE(notMatches("", ClassX)); } TEST(DeclarationMatcher, translationUnitDecl) { const std::string Code = "int MyVar1;\n" "namespace NameSpace {\n" "int MyVar2;\n" "} // namespace NameSpace\n"; EXPECT_TRUE(matches( Code, varDecl(hasName("MyVar1"), hasDeclContext(translationUnitDecl())))); EXPECT_FALSE(matches( Code, varDecl(hasName("MyVar2"), hasDeclContext(translationUnitDecl())))); EXPECT_TRUE(matches( Code, varDecl(hasName("MyVar2"), hasDeclContext(decl(hasDeclContext(translationUnitDecl())))))); } TEST(DeclarationMatcher, LinkageSpecification) { EXPECT_TRUE(matches("extern \"C\" { void foo() {}; }", linkageSpecDecl())); EXPECT_TRUE(notMatches("void foo() {};", linkageSpecDecl())); } TEST(ClassTemplate, DoesNotMatchClass) { DeclarationMatcher ClassX = classTemplateDecl(hasName("X")); EXPECT_TRUE(notMatches("class X;", ClassX)); EXPECT_TRUE(notMatches("class X {};", ClassX)); } TEST(ClassTemplate, MatchesClassTemplate) { DeclarationMatcher ClassX = classTemplateDecl(hasName("X")); EXPECT_TRUE(matches("template class X {};", ClassX)); EXPECT_TRUE(matches("class Z { template class X {}; };", ClassX)); } TEST(ClassTemplate, DoesNotMatchClassTemplateExplicitSpecialization) { EXPECT_TRUE(notMatches("template class X { };" "template<> class X { int a; };", classTemplateDecl(hasName("X"), hasDescendant(fieldDecl(hasName("a")))))); } TEST(ClassTemplate, DoesNotMatchClassTemplatePartialSpecialization) { EXPECT_TRUE(notMatches("template class X { };" "template class X { int a; };", classTemplateDecl(hasName("X"), hasDescendant(fieldDecl(hasName("a")))))); } TEST(DeclarationMatcher, MatchCudaDecl) { EXPECT_TRUE(matchesWithCuda("__global__ void f() { }" "void g() { f<<<1, 2>>>(); }", cudaKernelCallExpr())); EXPECT_TRUE(matchesWithCuda("__attribute__((device)) void f() {}", hasAttr(clang::attr::CUDADevice))); EXPECT_TRUE(notMatchesWithCuda("void f() {}", cudaKernelCallExpr())); EXPECT_FALSE(notMatchesWithCuda("__attribute__((global)) void f() {}", hasAttr(clang::attr::CUDAGlobal))); } TEST(ValueDecl, Matches) { EXPECT_TRUE(matches("enum EnumType { EnumValue };", valueDecl(hasType(asString("enum EnumType"))))); EXPECT_TRUE(matches("void FunctionDecl();", valueDecl(hasType(asString("void (void)"))))); } TEST(Enum, DoesNotMatchClasses) { EXPECT_TRUE(notMatches("class X {};", enumDecl(hasName("X")))); } TEST(Enum, MatchesEnums) { EXPECT_TRUE(matches("enum X {};", enumDecl(hasName("X")))); } TEST(EnumConstant, Matches) { DeclarationMatcher Matcher = enumConstantDecl(hasName("A")); EXPECT_TRUE(matches("enum X{ A };", Matcher)); EXPECT_TRUE(notMatches("enum X{ B };", Matcher)); EXPECT_TRUE(notMatches("enum X {};", Matcher)); } TEST(Matcher, UnresolvedLookupExpr) { // FIXME: The test is known to be broken on Windows with delayed template // parsing. EXPECT_TRUE(matchesConditionally("template" "T foo() { T a; return a; }" "template" "void bar() {" " foo();" "}", unresolvedLookupExpr(), /*ExpectMatch=*/true, "-fno-delayed-template-parsing")); } TEST(Matcher, Call) { // FIXME: Do we want to overload Call() to directly take // Matcher, too? StatementMatcher MethodX = callExpr(hasDeclaration(cxxMethodDecl(hasName("x")))); EXPECT_TRUE(matches("class Y { void x() { x(); } };", MethodX)); EXPECT_TRUE(notMatches("class Y { void x() {} };", MethodX)); StatementMatcher MethodOnY = cxxMemberCallExpr(on(hasType(recordDecl(hasName("Y"))))); EXPECT_TRUE( matches("class Y { public: void x(); }; void z() { Y y; y.x(); }", MethodOnY)); EXPECT_TRUE( matches("class Y { public: void x(); }; void z(Y &y) { y.x(); }", MethodOnY)); EXPECT_TRUE( notMatches("class Y { public: void x(); }; void z(Y *&y) { y->x(); }", MethodOnY)); EXPECT_TRUE( notMatches("class Y { public: void x(); }; void z(Y y[]) { y->x(); }", MethodOnY)); EXPECT_TRUE( notMatches("class Y { public: void x(); }; void z() { Y *y; y->x(); }", MethodOnY)); StatementMatcher MethodOnYPointer = cxxMemberCallExpr(on(hasType(pointsTo(recordDecl(hasName("Y")))))); EXPECT_TRUE( matches("class Y { public: void x(); }; void z() { Y *y; y->x(); }", MethodOnYPointer)); EXPECT_TRUE( matches("class Y { public: void x(); }; void z(Y *&y) { y->x(); }", MethodOnYPointer)); EXPECT_TRUE( matches("class Y { public: void x(); }; void z(Y y[]) { y->x(); }", MethodOnYPointer)); EXPECT_TRUE( notMatches("class Y { public: void x(); }; void z() { Y y; y.x(); }", MethodOnYPointer)); EXPECT_TRUE( notMatches("class Y { public: void x(); }; void z(Y &y) { y.x(); }", MethodOnYPointer)); } TEST(Matcher, Lambda) { EXPECT_TRUE(matches("auto f = [] (int i) { return i; };", lambdaExpr())); } TEST(Matcher, ForRange) { EXPECT_TRUE(matches("int as[] = { 1, 2, 3 };" "void f() { for (auto &a : as); }", cxxForRangeStmt())); EXPECT_TRUE(notMatches("void f() { for (int i; i<5; ++i); }", cxxForRangeStmt())); } TEST(Matcher, SubstNonTypeTemplateParm) { EXPECT_FALSE(matches("template\n" "struct A { static const int n = 0; };\n" "struct B : public A<42> {};", substNonTypeTemplateParmExpr())); EXPECT_TRUE(matches("template\n" "struct A { static const int n = N; };\n" "struct B : public A<42> {};", substNonTypeTemplateParmExpr())); } TEST(Matcher, NonTypeTemplateParmDecl) { EXPECT_TRUE(matches("template void f();", nonTypeTemplateParmDecl(hasName("N")))); EXPECT_TRUE( notMatches("template void f();", nonTypeTemplateParmDecl())); } TEST(Matcher, templateTypeParmDecl) { EXPECT_TRUE(matches("template void f();", templateTypeParmDecl(hasName("T")))); EXPECT_TRUE( notMatches("template void f();", templateTypeParmDecl())); } TEST(Matcher, UserDefinedLiteral) { EXPECT_TRUE(matches("constexpr char operator \"\" _inc (const char i) {" " return i + 1;" "}" "char c = 'a'_inc;", userDefinedLiteral())); } TEST(Matcher, FlowControl) { EXPECT_TRUE(matches("void f() { while(true) { break; } }", breakStmt())); EXPECT_TRUE(matches("void f() { while(true) { continue; } }", continueStmt())); EXPECT_TRUE(matches("void f() { goto FOO; FOO: ;}", gotoStmt())); EXPECT_TRUE(matches("void f() { goto FOO; FOO: ;}", labelStmt( hasDeclaration( labelDecl(hasName("FOO")))))); EXPECT_TRUE(matches("void f() { FOO: ; void *ptr = &&FOO; goto *ptr; }", addrLabelExpr())); EXPECT_TRUE(matches("void f() { return; }", returnStmt())); } TEST(Matcher, OverloadedOperatorCall) { StatementMatcher OpCall = cxxOperatorCallExpr(); // Unary operator EXPECT_TRUE(matches("class Y { }; " "bool operator!(Y x) { return false; }; " "Y y; bool c = !y;", OpCall)); // No match -- special operators like "new", "delete" // FIXME: operator new takes size_t, for which we need stddef.h, for which // we need to figure out include paths in the test. // EXPECT_TRUE(NotMatches("#include \n" // "class Y { }; " // "void *operator new(size_t size) { return 0; } " // "Y *y = new Y;", OpCall)); EXPECT_TRUE(notMatches("class Y { }; " "void operator delete(void *p) { } " "void a() {Y *y = new Y; delete y;}", OpCall)); // Binary operator EXPECT_TRUE(matches("class Y { }; " "bool operator&&(Y x, Y y) { return true; }; " "Y a; Y b; bool c = a && b;", OpCall)); // No match -- normal operator, not an overloaded one. EXPECT_TRUE(notMatches("bool x = true, y = true; bool t = x && y;", OpCall)); EXPECT_TRUE(notMatches("int t = 5 << 2;", OpCall)); } TEST(Matcher, ThisPointerType) { StatementMatcher MethodOnY = cxxMemberCallExpr(thisPointerType(recordDecl(hasName("Y")))); EXPECT_TRUE( matches("class Y { public: void x(); }; void z() { Y y; y.x(); }", MethodOnY)); EXPECT_TRUE( matches("class Y { public: void x(); }; void z(Y &y) { y.x(); }", MethodOnY)); EXPECT_TRUE( matches("class Y { public: void x(); }; void z(Y *&y) { y->x(); }", MethodOnY)); EXPECT_TRUE( matches("class Y { public: void x(); }; void z(Y y[]) { y->x(); }", MethodOnY)); EXPECT_TRUE( matches("class Y { public: void x(); }; void z() { Y *y; y->x(); }", MethodOnY)); EXPECT_TRUE(matches( "class Y {" " public: virtual void x();" "};" "class X : public Y {" " public: virtual void x();" "};" "void z() { X *x; x->Y::x(); }", MethodOnY)); } TEST(Matcher, VariableUsage) { StatementMatcher Reference = declRefExpr(to( varDecl(hasInitializer( cxxMemberCallExpr(thisPointerType(recordDecl(hasName("Y")))))))); EXPECT_TRUE(matches( "class Y {" " public:" " bool x() const;" "};" "void z(const Y &y) {" " bool b = y.x();" " if (b) {}" "}", Reference)); EXPECT_TRUE(notMatches( "class Y {" " public:" " bool x() const;" "};" "void z(const Y &y) {" " bool b = y.x();" "}", Reference)); } TEST(Matcher, CalledVariable) { StatementMatcher CallOnVariableY = cxxMemberCallExpr(on(declRefExpr(to(varDecl(hasName("y")))))); EXPECT_TRUE(matches( "class Y { public: void x() { Y y; y.x(); } };", CallOnVariableY)); EXPECT_TRUE(matches( "class Y { public: void x() const { Y y; y.x(); } };", CallOnVariableY)); EXPECT_TRUE(matches( "class Y { public: void x(); };" "class X : public Y { void z() { X y; y.x(); } };", CallOnVariableY)); EXPECT_TRUE(matches( "class Y { public: void x(); };" "class X : public Y { void z() { X *y; y->x(); } };", CallOnVariableY)); EXPECT_TRUE(notMatches( "class Y { public: void x(); };" "class X : public Y { void z() { unsigned long y; ((X*)y)->x(); } };", CallOnVariableY)); } TEST(UnaryExprOrTypeTraitExpr, MatchesSizeOfAndAlignOf) { EXPECT_TRUE(matches("void x() { int a = sizeof(a); }", unaryExprOrTypeTraitExpr())); EXPECT_TRUE(notMatches("void x() { int a = sizeof(a); }", alignOfExpr(anything()))); // FIXME: Uncomment once alignof is enabled. // EXPECT_TRUE(matches("void x() { int a = alignof(a); }", // unaryExprOrTypeTraitExpr())); // EXPECT_TRUE(notMatches("void x() { int a = alignof(a); }", // sizeOfExpr())); } TEST(MemberExpression, DoesNotMatchClasses) { EXPECT_TRUE(notMatches("class Y { void x() {} };", memberExpr())); } TEST(MemberExpression, MatchesMemberFunctionCall) { EXPECT_TRUE(matches("class Y { void x() { x(); } };", memberExpr())); } TEST(MemberExpression, MatchesVariable) { EXPECT_TRUE( matches("class Y { void x() { this->y; } int y; };", memberExpr())); EXPECT_TRUE( matches("class Y { void x() { y; } int y; };", memberExpr())); EXPECT_TRUE( matches("class Y { void x() { Y y; y.y; } int y; };", memberExpr())); } TEST(MemberExpression, MatchesStaticVariable) { EXPECT_TRUE(matches("class Y { void x() { this->y; } static int y; };", memberExpr())); EXPECT_TRUE(notMatches("class Y { void x() { y; } static int y; };", memberExpr())); EXPECT_TRUE(notMatches("class Y { void x() { Y::y; } static int y; };", memberExpr())); } TEST(Function, MatchesFunctionDeclarations) { StatementMatcher CallFunctionF = callExpr(callee(functionDecl(hasName("f")))); EXPECT_TRUE(matches("void f() { f(); }", CallFunctionF)); EXPECT_TRUE(notMatches("void f() { }", CallFunctionF)); if (llvm::Triple(llvm::sys::getDefaultTargetTriple()).getOS() != llvm::Triple::Win32) { // FIXME: Make this work for MSVC. // Dependent contexts, but a non-dependent call. EXPECT_TRUE(matches("void f(); template void g() { f(); }", CallFunctionF)); EXPECT_TRUE( matches("void f(); template struct S { void g() { f(); } };", CallFunctionF)); } // Depedent calls don't match. EXPECT_TRUE( notMatches("void f(int); template void g(T t) { f(t); }", CallFunctionF)); EXPECT_TRUE( notMatches("void f(int);" "template struct S { void g(T t) { f(t); } };", CallFunctionF)); EXPECT_TRUE(matches("void f(...);", functionDecl(isVariadic()))); EXPECT_TRUE(notMatches("void f(int);", functionDecl(isVariadic()))); EXPECT_TRUE(notMatches("template void f(Ts...);", functionDecl(isVariadic()))); EXPECT_TRUE(notMatches("void f();", functionDecl(isVariadic()))); EXPECT_TRUE(notMatchesC("void f();", functionDecl(isVariadic()))); EXPECT_TRUE(matches("void f(...);", functionDecl(parameterCountIs(0)))); EXPECT_TRUE(matchesC("void f();", functionDecl(parameterCountIs(0)))); EXPECT_TRUE(matches("void f(int, ...);", functionDecl(parameterCountIs(1)))); } TEST(FunctionTemplate, MatchesFunctionTemplateDeclarations) { EXPECT_TRUE( matches("template void f(T t) {}", functionTemplateDecl(hasName("f")))); } TEST(FunctionTemplate, DoesNotMatchFunctionDeclarations) { EXPECT_TRUE( notMatches("void f(double d); void f(int t) {}", functionTemplateDecl(hasName("f")))); } TEST(FunctionTemplate, DoesNotMatchFunctionTemplateSpecializations) { EXPECT_TRUE( notMatches("void g(); template void f(T t) {}" "template <> void f(int t) { g(); }", functionTemplateDecl(hasName("f"), hasDescendant(declRefExpr(to( functionDecl(hasName("g")))))))); } TEST(Matcher, MatchesClassTemplateSpecialization) { EXPECT_TRUE(matches("template struct A {};" "template<> struct A {};", classTemplateSpecializationDecl())); EXPECT_TRUE(matches("template struct A {}; A a;", classTemplateSpecializationDecl())); EXPECT_TRUE(notMatches("template struct A {};", classTemplateSpecializationDecl())); } TEST(DeclaratorDecl, MatchesDeclaratorDecls) { EXPECT_TRUE(matches("int x;", declaratorDecl())); EXPECT_TRUE(notMatches("class A {};", declaratorDecl())); } TEST(ParmVarDecl, MatchesParmVars) { EXPECT_TRUE(matches("void f(int x);", parmVarDecl())); EXPECT_TRUE(notMatches("void f();", parmVarDecl())); } TEST(Matcher, ConstructorCall) { StatementMatcher Constructor = cxxConstructExpr(); EXPECT_TRUE( matches("class X { public: X(); }; void x() { X x; }", Constructor)); EXPECT_TRUE( matches("class X { public: X(); }; void x() { X x = X(); }", Constructor)); EXPECT_TRUE( matches("class X { public: X(int); }; void x() { X x = 0; }", Constructor)); EXPECT_TRUE(matches("class X {}; void x(int) { X x; }", Constructor)); } TEST(Match, ConstructorInitializers) { EXPECT_TRUE(matches("class C { int i; public: C(int ii) : i(ii) {} };", cxxCtorInitializer(forField(hasName("i"))))); } TEST(Matcher, ThisExpr) { EXPECT_TRUE( matches("struct X { int a; int f () { return a; } };", cxxThisExpr())); EXPECT_TRUE( notMatches("struct X { int f () { int a; return a; } };", cxxThisExpr())); } TEST(Matcher, BindTemporaryExpression) { StatementMatcher TempExpression = cxxBindTemporaryExpr(); std::string ClassString = "class string { public: string(); ~string(); }; "; EXPECT_TRUE( matches(ClassString + "string GetStringByValue();" "void FunctionTakesString(string s);" "void run() { FunctionTakesString(GetStringByValue()); }", TempExpression)); EXPECT_TRUE( notMatches(ClassString + "string* GetStringPointer(); " "void FunctionTakesStringPtr(string* s);" "void run() {" " string* s = GetStringPointer();" " FunctionTakesStringPtr(GetStringPointer());" " FunctionTakesStringPtr(s);" "}", TempExpression)); EXPECT_TRUE( notMatches("class no_dtor {};" "no_dtor GetObjByValue();" "void ConsumeObj(no_dtor param);" "void run() { ConsumeObj(GetObjByValue()); }", TempExpression)); } TEST(MaterializeTemporaryExpr, MatchesTemporary) { std::string ClassString = "class string { public: string(); int length(); }; "; EXPECT_TRUE( matches(ClassString + "string GetStringByValue();" "void FunctionTakesString(string s);" "void run() { FunctionTakesString(GetStringByValue()); }", materializeTemporaryExpr())); EXPECT_TRUE( notMatches(ClassString + "string* GetStringPointer(); " "void FunctionTakesStringPtr(string* s);" "void run() {" " string* s = GetStringPointer();" " FunctionTakesStringPtr(GetStringPointer());" " FunctionTakesStringPtr(s);" "}", materializeTemporaryExpr())); EXPECT_TRUE( matches(ClassString + "string GetStringByValue();" "void run() { int k = GetStringByValue().length(); }", materializeTemporaryExpr())); EXPECT_TRUE( notMatches(ClassString + "string GetStringByValue();" "void run() { GetStringByValue(); }", materializeTemporaryExpr())); } TEST(Matcher, NewExpression) { StatementMatcher New = cxxNewExpr(); EXPECT_TRUE(matches("class X { public: X(); }; void x() { new X; }", New)); EXPECT_TRUE( matches("class X { public: X(); }; void x() { new X(); }", New)); EXPECT_TRUE( matches("class X { public: X(int); }; void x() { new X(0); }", New)); EXPECT_TRUE(matches("class X {}; void x(int) { new X; }", New)); } TEST(Matcher, DeleteExpression) { EXPECT_TRUE(matches("struct A {}; void f(A* a) { delete a; }", cxxDeleteExpr())); } TEST(Matcher, DefaultArgument) { StatementMatcher Arg = cxxDefaultArgExpr(); EXPECT_TRUE(matches("void x(int, int = 0) { int y; x(y); }", Arg)); EXPECT_TRUE( matches("class X { void x(int, int = 0) { int y; x(y); } };", Arg)); EXPECT_TRUE(notMatches("void x(int, int = 0) { int y; x(y, 0); }", Arg)); } TEST(Matcher, StringLiterals) { StatementMatcher Literal = stringLiteral(); EXPECT_TRUE(matches("const char *s = \"string\";", Literal)); // wide string EXPECT_TRUE(matches("const wchar_t *s = L\"string\";", Literal)); // with escaped characters EXPECT_TRUE(matches("const char *s = \"\x05five\";", Literal)); // no matching -- though the data type is the same, there is no string literal EXPECT_TRUE(notMatches("const char s[1] = {'a'};", Literal)); } TEST(Matcher, CharacterLiterals) { StatementMatcher CharLiteral = characterLiteral(); EXPECT_TRUE(matches("const char c = 'c';", CharLiteral)); // wide character EXPECT_TRUE(matches("const char c = L'c';", CharLiteral)); // wide character, Hex encoded, NOT MATCHED! EXPECT_TRUE(notMatches("const wchar_t c = 0x2126;", CharLiteral)); EXPECT_TRUE(notMatches("const char c = 0x1;", CharLiteral)); } TEST(Matcher, IntegerLiterals) { StatementMatcher HasIntLiteral = integerLiteral(); EXPECT_TRUE(matches("int i = 10;", HasIntLiteral)); EXPECT_TRUE(matches("int i = 0x1AB;", HasIntLiteral)); EXPECT_TRUE(matches("int i = 10L;", HasIntLiteral)); EXPECT_TRUE(matches("int i = 10U;", HasIntLiteral)); // Non-matching cases (character literals, float and double) EXPECT_TRUE(notMatches("int i = L'a';", HasIntLiteral)); // this is actually a character // literal cast to int EXPECT_TRUE(notMatches("int i = 'a';", HasIntLiteral)); EXPECT_TRUE(notMatches("int i = 1e10;", HasIntLiteral)); EXPECT_TRUE(notMatches("int i = 10.0;", HasIntLiteral)); } TEST(Matcher, FloatLiterals) { StatementMatcher HasFloatLiteral = floatLiteral(); EXPECT_TRUE(matches("float i = 10.0;", HasFloatLiteral)); EXPECT_TRUE(matches("float i = 10.0f;", HasFloatLiteral)); EXPECT_TRUE(matches("double i = 10.0;", HasFloatLiteral)); EXPECT_TRUE(matches("double i = 10.0L;", HasFloatLiteral)); EXPECT_TRUE(matches("double i = 1e10;", HasFloatLiteral)); EXPECT_TRUE(matches("double i = 5.0;", floatLiteral(equals(5.0)))); EXPECT_TRUE(matches("double i = 5.0;", floatLiteral(equals(5.0f)))); EXPECT_TRUE( matches("double i = 5.0;", floatLiteral(equals(llvm::APFloat(5.0))))); EXPECT_TRUE(notMatches("float i = 10;", HasFloatLiteral)); EXPECT_TRUE(notMatches("double i = 5.0;", floatLiteral(equals(6.0)))); EXPECT_TRUE(notMatches("double i = 5.0;", floatLiteral(equals(6.0f)))); EXPECT_TRUE( notMatches("double i = 5.0;", floatLiteral(equals(llvm::APFloat(6.0))))); } TEST(Matcher, NullPtrLiteral) { EXPECT_TRUE(matches("int* i = nullptr;", cxxNullPtrLiteralExpr())); } TEST(Matcher, GNUNullExpr) { EXPECT_TRUE(matches("int* i = __null;", gnuNullExpr())); } TEST(Matcher, AtomicExpr) { EXPECT_TRUE(matches("void foo() { int *ptr; __atomic_load_n(ptr, 1); }", atomicExpr())); } TEST(Matcher, Initializers) { const char *ToMatch = "void foo() { struct point { double x; double y; };" " struct point ptarray[10] = " " { [2].y = 1.0, [2].x = 2.0, [0].x = 1.0 }; }"; EXPECT_TRUE(matchesConditionally( ToMatch, initListExpr( has( cxxConstructExpr( requiresZeroInitialization())), has( initListExpr( hasType(asString("struct point")), has(floatLiteral(equals(1.0))), has(implicitValueInitExpr( hasType(asString("double")))))), has( initListExpr( hasType(asString("struct point")), has(floatLiteral(equals(2.0))), has(floatLiteral(equals(1.0))))) ), true, "-std=gnu++98")); EXPECT_TRUE(matchesC99(ToMatch, initListExpr( hasSyntacticForm( initListExpr( has( designatedInitExpr( designatorCountIs(2), has(floatLiteral( equals(1.0))), has(integerLiteral( equals(2))))), has( designatedInitExpr( designatorCountIs(2), has(floatLiteral( equals(2.0))), has(integerLiteral( equals(2))))), has( designatedInitExpr( designatorCountIs(2), has(floatLiteral( equals(1.0))), has(integerLiteral( equals(0))))) ))))); } TEST(Matcher, ParenListExpr) { EXPECT_TRUE( matches("template class foo { void bar() { foo X(*this); } };" "template class foo;", varDecl(hasInitializer(parenListExpr(has(unaryOperator())))))); } TEST(Matcher, StmtExpr) { EXPECT_TRUE(matches("void declToImport() { int C = ({int X=4; X;}); }", varDecl(hasInitializer(stmtExpr())))); } TEST(Matcher, ImportPredefinedExpr) { // __func__ expands as StringLiteral("foo") EXPECT_TRUE(matches("void foo() { __func__; }", predefinedExpr( hasType(asString("const char [4]")), has(stringLiteral())))); } TEST(Matcher, AsmStatement) { EXPECT_TRUE(matches("void foo() { __asm(\"mov al, 2\"); }", asmStmt())); } TEST(Matcher, Conditions) { StatementMatcher Condition = ifStmt(hasCondition(cxxBoolLiteral(equals(true)))); EXPECT_TRUE(matches("void x() { if (true) {} }", Condition)); EXPECT_TRUE(notMatches("void x() { if (false) {} }", Condition)); EXPECT_TRUE(notMatches("void x() { bool a = true; if (a) {} }", Condition)); EXPECT_TRUE(notMatches("void x() { if (true || false) {} }", Condition)); EXPECT_TRUE(notMatches("void x() { if (1) {} }", Condition)); } TEST(Matcher, ConditionalOperator) { StatementMatcher Conditional = conditionalOperator( hasCondition(cxxBoolLiteral(equals(true))), hasTrueExpression(cxxBoolLiteral(equals(false)))); EXPECT_TRUE(matches("void x() { true ? false : true; }", Conditional)); EXPECT_TRUE(notMatches("void x() { false ? false : true; }", Conditional)); EXPECT_TRUE(notMatches("void x() { true ? true : false; }", Conditional)); StatementMatcher ConditionalFalse = conditionalOperator( hasFalseExpression(cxxBoolLiteral(equals(false)))); EXPECT_TRUE(matches("void x() { true ? true : false; }", ConditionalFalse)); EXPECT_TRUE( notMatches("void x() { true ? false : true; }", ConditionalFalse)); EXPECT_TRUE(matches("void x() { true ? true : false; }", ConditionalFalse)); EXPECT_TRUE( notMatches("void x() { true ? false : true; }", ConditionalFalse)); } TEST(Matcher, BinaryConditionalOperator) { StatementMatcher AlwaysOne = binaryConditionalOperator( hasCondition(implicitCastExpr( has( opaqueValueExpr( hasSourceExpression((integerLiteral(equals(1)))))))), hasFalseExpression(integerLiteral(equals(0)))); EXPECT_TRUE(matches("void x() { 1 ?: 0; }", AlwaysOne)); StatementMatcher FourNotFive = binaryConditionalOperator( hasTrueExpression(opaqueValueExpr( hasSourceExpression((integerLiteral(equals(4)))))), hasFalseExpression(integerLiteral(equals(5)))); EXPECT_TRUE(matches("void x() { 4 ?: 5; }", FourNotFive)); } TEST(ArraySubscriptMatchers, ArraySubscripts) { EXPECT_TRUE(matches("int i[2]; void f() { i[1] = 1; }", arraySubscriptExpr())); EXPECT_TRUE(notMatches("int i; void f() { i = 1; }", arraySubscriptExpr())); } TEST(For, FindsForLoops) { EXPECT_TRUE(matches("void f() { for(;;); }", forStmt())); EXPECT_TRUE(matches("void f() { if(true) for(;;); }", forStmt())); EXPECT_TRUE(notMatches("int as[] = { 1, 2, 3 };" "void f() { for (auto &a : as); }", forStmt())); } TEST(For, ReportsNoFalsePositives) { EXPECT_TRUE(notMatches("void f() { ; }", forStmt())); EXPECT_TRUE(notMatches("void f() { if(true); }", forStmt())); } TEST(CompoundStatement, HandlesSimpleCases) { EXPECT_TRUE(notMatches("void f();", compoundStmt())); EXPECT_TRUE(matches("void f() {}", compoundStmt())); EXPECT_TRUE(matches("void f() {{}}", compoundStmt())); } TEST(CompoundStatement, DoesNotMatchEmptyStruct) { // It's not a compound statement just because there's "{}" in the source // text. This is an AST search, not grep. EXPECT_TRUE(notMatches("namespace n { struct S {}; }", compoundStmt())); EXPECT_TRUE(matches("namespace n { struct S { void f() {{}} }; }", compoundStmt())); } TEST(CastExpression, MatchesExplicitCasts) { EXPECT_TRUE(matches("char *p = reinterpret_cast(&p);",castExpr())); EXPECT_TRUE(matches("void *p = (void *)(&p);", castExpr())); EXPECT_TRUE(matches("char q, *p = const_cast(&q);", castExpr())); EXPECT_TRUE(matches("char c = char(0);", castExpr())); } TEST(CastExpression, MatchesImplicitCasts) { // This test creates an implicit cast from int to char. EXPECT_TRUE(matches("char c = 0;", castExpr())); // This test creates an implicit cast from lvalue to rvalue. EXPECT_TRUE(matches("char c = 0, d = c;", castExpr())); } TEST(CastExpression, DoesNotMatchNonCasts) { EXPECT_TRUE(notMatches("char c = '0';", castExpr())); EXPECT_TRUE(notMatches("char c, &q = c;", castExpr())); EXPECT_TRUE(notMatches("int i = (0);", castExpr())); EXPECT_TRUE(notMatches("int i = 0;", castExpr())); } TEST(ReinterpretCast, MatchesSimpleCase) { EXPECT_TRUE(matches("char* p = reinterpret_cast(&p);", cxxReinterpretCastExpr())); } TEST(ReinterpretCast, DoesNotMatchOtherCasts) { EXPECT_TRUE(notMatches("char* p = (char*)(&p);", cxxReinterpretCastExpr())); EXPECT_TRUE(notMatches("char q, *p = const_cast(&q);", cxxReinterpretCastExpr())); EXPECT_TRUE(notMatches("void* p = static_cast(&p);", cxxReinterpretCastExpr())); EXPECT_TRUE(notMatches("struct B { virtual ~B() {} }; struct D : B {};" "B b;" "D* p = dynamic_cast(&b);", cxxReinterpretCastExpr())); } TEST(FunctionalCast, MatchesSimpleCase) { std::string foo_class = "class Foo { public: Foo(const char*); };"; EXPECT_TRUE(matches(foo_class + "void r() { Foo f = Foo(\"hello world\"); }", cxxFunctionalCastExpr())); } TEST(FunctionalCast, DoesNotMatchOtherCasts) { std::string FooClass = "class Foo { public: Foo(const char*); };"; EXPECT_TRUE( notMatches(FooClass + "void r() { Foo f = (Foo) \"hello world\"; }", cxxFunctionalCastExpr())); EXPECT_TRUE( notMatches(FooClass + "void r() { Foo f = \"hello world\"; }", cxxFunctionalCastExpr())); } TEST(DynamicCast, MatchesSimpleCase) { EXPECT_TRUE(matches("struct B { virtual ~B() {} }; struct D : B {};" "B b;" "D* p = dynamic_cast(&b);", cxxDynamicCastExpr())); } TEST(StaticCast, MatchesSimpleCase) { EXPECT_TRUE(matches("void* p(static_cast(&p));", cxxStaticCastExpr())); } TEST(StaticCast, DoesNotMatchOtherCasts) { EXPECT_TRUE(notMatches("char* p = (char*)(&p);", cxxStaticCastExpr())); EXPECT_TRUE(notMatches("char q, *p = const_cast(&q);", cxxStaticCastExpr())); EXPECT_TRUE(notMatches("void* p = reinterpret_cast(&p);", cxxStaticCastExpr())); EXPECT_TRUE(notMatches("struct B { virtual ~B() {} }; struct D : B {};" "B b;" "D* p = dynamic_cast(&b);", cxxStaticCastExpr())); } TEST(CStyleCast, MatchesSimpleCase) { EXPECT_TRUE(matches("int i = (int) 2.2f;", cStyleCastExpr())); } TEST(CStyleCast, DoesNotMatchOtherCasts) { EXPECT_TRUE(notMatches("char* p = static_cast(0);" "char q, *r = const_cast(&q);" "void* s = reinterpret_cast(&s);" "struct B { virtual ~B() {} }; struct D : B {};" "B b;" "D* t = dynamic_cast(&b);", cStyleCastExpr())); } TEST(ImplicitCast, MatchesSimpleCase) { // This test creates an implicit const cast. EXPECT_TRUE(matches("int x = 0; const int y = x;", varDecl(hasInitializer(implicitCastExpr())))); // This test creates an implicit cast from int to char. EXPECT_TRUE(matches("char c = 0;", varDecl(hasInitializer(implicitCastExpr())))); // This test creates an implicit array-to-pointer cast. EXPECT_TRUE(matches("int arr[6]; int *p = arr;", varDecl(hasInitializer(implicitCastExpr())))); } TEST(ImplicitCast, DoesNotMatchIncorrectly) { // This test verifies that implicitCastExpr() matches exactly when implicit casts // are present, and that it ignores explicit and paren casts. // These two test cases have no casts. EXPECT_TRUE(notMatches("int x = 0;", varDecl(hasInitializer(implicitCastExpr())))); EXPECT_TRUE(notMatches("int x = 0, &y = x;", varDecl(hasInitializer(implicitCastExpr())))); EXPECT_TRUE(notMatches("int x = 0; double d = (double) x;", varDecl(hasInitializer(implicitCastExpr())))); EXPECT_TRUE(notMatches("const int *p; int *q = const_cast(p);", varDecl(hasInitializer(implicitCastExpr())))); EXPECT_TRUE(notMatches("int x = (0);", varDecl(hasInitializer(implicitCastExpr())))); } TEST(Statement, DoesNotMatchDeclarations) { EXPECT_TRUE(notMatches("class X {};", stmt())); } TEST(Statement, MatchesCompoundStatments) { EXPECT_TRUE(matches("void x() {}", stmt())); } TEST(DeclarationStatement, DoesNotMatchCompoundStatements) { EXPECT_TRUE(notMatches("void x() {}", declStmt())); } TEST(DeclarationStatement, MatchesVariableDeclarationStatements) { EXPECT_TRUE(matches("void x() { int a; }", declStmt())); } TEST(ExprWithCleanups, MatchesExprWithCleanups) { EXPECT_TRUE(matches("struct Foo { ~Foo(); };" "const Foo f = Foo();", varDecl(hasInitializer(exprWithCleanups())))); EXPECT_FALSE(matches("struct Foo { }; Foo a;" "const Foo f = a;", varDecl(hasInitializer(exprWithCleanups())))); } TEST(InitListExpression, MatchesInitListExpression) { EXPECT_TRUE(matches("int a[] = { 1, 2 };", initListExpr(hasType(asString("int [2]"))))); EXPECT_TRUE(matches("struct B { int x, y; }; B b = { 5, 6 };", initListExpr(hasType(recordDecl(hasName("B")))))); EXPECT_TRUE(matches("struct S { S(void (*a)()); };" "void f();" "S s[1] = { &f };", declRefExpr(to(functionDecl(hasName("f")))))); EXPECT_TRUE( matches("int i[1] = {42, [0] = 43};", integerLiteral(equals(42)))); } TEST(UsingDeclaration, MatchesUsingDeclarations) { EXPECT_TRUE(matches("namespace X { int x; } using X::x;", usingDecl())); } TEST(UsingDeclaration, MatchesShadowUsingDelcarations) { EXPECT_TRUE(matches("namespace f { int a; } using f::a;", usingDecl(hasAnyUsingShadowDecl(hasName("a"))))); } TEST(UsingDirectiveDeclaration, MatchesUsingNamespace) { EXPECT_TRUE(matches("namespace X { int x; } using namespace X;", usingDirectiveDecl())); EXPECT_FALSE( matches("namespace X { int x; } using X::x;", usingDirectiveDecl())); } TEST(While, MatchesWhileLoops) { EXPECT_TRUE(notMatches("void x() {}", whileStmt())); EXPECT_TRUE(matches("void x() { while(true); }", whileStmt())); EXPECT_TRUE(notMatches("void x() { do {} while(true); }", whileStmt())); } TEST(Do, MatchesDoLoops) { EXPECT_TRUE(matches("void x() { do {} while(true); }", doStmt())); EXPECT_TRUE(matches("void x() { do ; while(false); }", doStmt())); } TEST(Do, DoesNotMatchWhileLoops) { EXPECT_TRUE(notMatches("void x() { while(true) {} }", doStmt())); } TEST(SwitchCase, MatchesCase) { EXPECT_TRUE(matches("void x() { switch(42) { case 42:; } }", switchCase())); EXPECT_TRUE(matches("void x() { switch(42) { default:; } }", switchCase())); EXPECT_TRUE(matches("void x() { switch(42) default:; }", switchCase())); EXPECT_TRUE(notMatches("void x() { switch(42) {} }", switchCase())); } TEST(SwitchCase, MatchesSwitch) { EXPECT_TRUE(matches("void x() { switch(42) { case 42:; } }", switchStmt())); EXPECT_TRUE(matches("void x() { switch(42) { default:; } }", switchStmt())); EXPECT_TRUE(matches("void x() { switch(42) default:; }", switchStmt())); EXPECT_TRUE(notMatches("void x() {}", switchStmt())); } TEST(ExceptionHandling, SimpleCases) { EXPECT_TRUE(matches("void foo() try { } catch(int X) { }", cxxCatchStmt())); EXPECT_TRUE(matches("void foo() try { } catch(int X) { }", cxxTryStmt())); EXPECT_TRUE( notMatches("void foo() try { } catch(int X) { }", cxxThrowExpr())); EXPECT_TRUE(matches("void foo() try { throw; } catch(int X) { }", cxxThrowExpr())); EXPECT_TRUE(matches("void foo() try { throw 5;} catch(int X) { }", cxxThrowExpr())); EXPECT_TRUE(matches("void foo() try { throw; } catch(...) { }", cxxCatchStmt(isCatchAll()))); EXPECT_TRUE(notMatches("void foo() try { throw; } catch(int) { }", cxxCatchStmt(isCatchAll()))); EXPECT_TRUE(matches("void foo() try {} catch(int X) { }", varDecl(isExceptionVariable()))); EXPECT_TRUE(notMatches("void foo() try { int X; } catch (...) { }", varDecl(isExceptionVariable()))); } TEST(ParenExpression, SimpleCases) { EXPECT_TRUE(matches("int i = (3);", parenExpr())); EXPECT_TRUE(matches("int i = (3 + 7);", parenExpr())); EXPECT_TRUE(notMatches("int i = 3;", parenExpr())); EXPECT_TRUE(notMatches("int foo() { return 1; }; int a = foo();", parenExpr())); } TEST(TypeMatching, MatchesTypes) { EXPECT_TRUE(matches("struct S {};", qualType().bind("loc"))); } TEST(TypeMatching, MatchesConstantArrayTypes) { EXPECT_TRUE(matches("int a[2];", constantArrayType())); EXPECT_TRUE(notMatches( "void f() { int a[] = { 2, 3 }; int b[a[0]]; }", constantArrayType(hasElementType(builtinType())))); EXPECT_TRUE(matches("int a[42];", constantArrayType(hasSize(42)))); EXPECT_TRUE(matches("int b[2*21];", constantArrayType(hasSize(42)))); EXPECT_TRUE(notMatches("int c[41], d[43];", constantArrayType(hasSize(42)))); } TEST(TypeMatching, MatchesDependentSizedArrayTypes) { EXPECT_TRUE(matches( "template class array { T data[Size]; };", dependentSizedArrayType())); EXPECT_TRUE(notMatches( "int a[42]; int b[] = { 2, 3 }; void f() { int c[b[0]]; }", dependentSizedArrayType())); } TEST(TypeMatching, MatchesIncompleteArrayType) { EXPECT_TRUE(matches("int a[] = { 2, 3 };", incompleteArrayType())); EXPECT_TRUE(matches("void f(int a[]) {}", incompleteArrayType())); EXPECT_TRUE(notMatches("int a[42]; void f() { int b[a[0]]; }", incompleteArrayType())); } TEST(TypeMatching, MatchesVariableArrayType) { EXPECT_TRUE(matches("void f(int b) { int a[b]; }", variableArrayType())); EXPECT_TRUE(notMatches("int a[] = {2, 3}; int b[42];", variableArrayType())); EXPECT_TRUE(matches( "void f(int b) { int a[b]; }", variableArrayType(hasSizeExpr(ignoringImpCasts(declRefExpr(to( varDecl(hasName("b"))))))))); } TEST(TypeMatching, MatchesAtomicTypes) { if (llvm::Triple(llvm::sys::getDefaultTargetTriple()).getOS() != llvm::Triple::Win32) { // FIXME: Make this work for MSVC. EXPECT_TRUE(matches("_Atomic(int) i;", atomicType())); EXPECT_TRUE(matches("_Atomic(int) i;", atomicType(hasValueType(isInteger())))); EXPECT_TRUE(notMatches("_Atomic(float) f;", atomicType(hasValueType(isInteger())))); } } TEST(TypeMatching, MatchesAutoTypes) { EXPECT_TRUE(matches("auto i = 2;", autoType())); EXPECT_TRUE(matches("int v[] = { 2, 3 }; void f() { for (int i : v) {} }", autoType())); // FIXME: Matching against the type-as-written can't work here, because the // type as written was not deduced. //EXPECT_TRUE(matches("auto a = 1;", // autoType(hasDeducedType(isInteger())))); //EXPECT_TRUE(notMatches("auto b = 2.0;", // autoType(hasDeducedType(isInteger())))); } TEST(TypeMatching, MatchesFunctionTypes) { EXPECT_TRUE(matches("int (*f)(int);", functionType())); EXPECT_TRUE(matches("void f(int i) {}", functionType())); } TEST(TypeMatching, IgnoringParens) { EXPECT_TRUE( notMatches("void (*fp)(void);", pointerType(pointee(functionType())))); EXPECT_TRUE(matches("void (*fp)(void);", pointerType(pointee(ignoringParens(functionType()))))); } TEST(TypeMatching, MatchesFunctionProtoTypes) { EXPECT_TRUE(matches("int (*f)(int);", functionProtoType())); EXPECT_TRUE(matches("void f(int i);", functionProtoType())); EXPECT_TRUE(matches("void f();", functionProtoType(parameterCountIs(0)))); EXPECT_TRUE(notMatchesC("void f();", functionProtoType())); EXPECT_TRUE( matchesC("void f(void);", functionProtoType(parameterCountIs(0)))); } TEST(TypeMatching, MatchesParenType) { EXPECT_TRUE( matches("int (*array)[4];", varDecl(hasType(pointsTo(parenType()))))); EXPECT_TRUE(notMatches("int *array[4];", varDecl(hasType(parenType())))); EXPECT_TRUE(matches( "int (*ptr_to_func)(int);", varDecl(hasType(pointsTo(parenType(innerType(functionType()))))))); EXPECT_TRUE(notMatches( "int (*ptr_to_array)[4];", varDecl(hasType(pointsTo(parenType(innerType(functionType()))))))); } TEST(TypeMatching, PointerTypes) { // FIXME: Reactive when these tests can be more specific (not matching // implicit code on certain platforms), likely when we have hasDescendant for // Types/TypeLocs. //EXPECT_TRUE(matchAndVerifyResultTrue( // "int* a;", // pointerTypeLoc(pointeeLoc(typeLoc().bind("loc"))), // llvm::make_unique>("loc", 1))); //EXPECT_TRUE(matchAndVerifyResultTrue( // "int* a;", // pointerTypeLoc().bind("loc"), // llvm::make_unique>("loc", 1))); EXPECT_TRUE(matches( "int** a;", loc(pointerType(pointee(qualType()))))); EXPECT_TRUE(matches( "int** a;", loc(pointerType(pointee(pointerType()))))); EXPECT_TRUE(matches( "int* b; int* * const a = &b;", loc(qualType(isConstQualified(), pointerType())))); std::string Fragment = "struct A { int i; }; int A::* ptr = &A::i;"; EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ptr"), hasType(blockPointerType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("ptr"), hasType(memberPointerType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ptr"), hasType(pointerType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ptr"), hasType(referenceType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ptr"), hasType(lValueReferenceType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ptr"), hasType(rValueReferenceType())))); Fragment = "int *ptr;"; EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ptr"), hasType(blockPointerType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ptr"), hasType(memberPointerType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("ptr"), hasType(pointerType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ptr"), hasType(referenceType())))); Fragment = "int a; int &ref = a;"; EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ref"), hasType(blockPointerType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ref"), hasType(memberPointerType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ref"), hasType(pointerType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("ref"), hasType(referenceType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("ref"), hasType(lValueReferenceType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ref"), hasType(rValueReferenceType())))); Fragment = "int &&ref = 2;"; EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ref"), hasType(blockPointerType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ref"), hasType(memberPointerType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ref"), hasType(pointerType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("ref"), hasType(referenceType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("ref"), hasType(lValueReferenceType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("ref"), hasType(rValueReferenceType())))); } TEST(TypeMatching, AutoRefTypes) { std::string Fragment = "auto a = 1;" "auto b = a;" "auto &c = a;" "auto &&d = c;" "auto &&e = 2;"; EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("a"), hasType(referenceType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("b"), hasType(referenceType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("c"), hasType(referenceType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("c"), hasType(lValueReferenceType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("c"), hasType(rValueReferenceType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("d"), hasType(referenceType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("d"), hasType(lValueReferenceType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("d"), hasType(rValueReferenceType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("e"), hasType(referenceType())))); EXPECT_TRUE(notMatches(Fragment, varDecl(hasName("e"), hasType(lValueReferenceType())))); EXPECT_TRUE(matches(Fragment, varDecl(hasName("e"), hasType(rValueReferenceType())))); } TEST(TypeMatching, MatchesEnumTypes) { EXPECT_TRUE(matches("enum Color { Green }; Color color;", loc(enumType()))); EXPECT_TRUE(matches("enum class Color { Green }; Color color;", loc(enumType()))); } TEST(TypeMatching, MatchesPointersToConstTypes) { EXPECT_TRUE(matches("int b; int * const a = &b;", loc(pointerType()))); EXPECT_TRUE(matches("int b; int * const a = &b;", loc(pointerType()))); EXPECT_TRUE(matches( "int b; const int * a = &b;", loc(pointerType(pointee(builtinType()))))); EXPECT_TRUE(matches( "int b; const int * a = &b;", pointerType(pointee(builtinType())))); } TEST(TypeMatching, MatchesTypedefTypes) { EXPECT_TRUE(matches("typedef int X; X a;", varDecl(hasName("a"), hasType(typedefType())))); } TEST(TypeMatching, MatchesTemplateSpecializationType) { EXPECT_TRUE(matches("template class A{}; A a;", templateSpecializationType())); } TEST(TypeMatching, MatchesRecordType) { EXPECT_TRUE(matches("class C{}; C c;", recordType())); EXPECT_TRUE(matches("struct S{}; S s;", recordType(hasDeclaration(recordDecl(hasName("S")))))); EXPECT_TRUE(notMatches("int i;", recordType(hasDeclaration(recordDecl(hasName("S")))))); } TEST(TypeMatching, MatchesElaboratedType) { EXPECT_TRUE(matches( "namespace N {" " namespace M {" " class D {};" " }" "}" "N::M::D d;", elaboratedType())); EXPECT_TRUE(matches("class C {} c;", elaboratedType())); EXPECT_TRUE(notMatches("class C {}; C c;", elaboratedType())); } TEST(TypeMatching, MatchesSubstTemplateTypeParmType) { const std::string code = "template " "int F() {" " return 1 + T();" "}" "int i = F();"; EXPECT_FALSE(matches(code, binaryOperator(hasLHS( expr(hasType(substTemplateTypeParmType())))))); EXPECT_TRUE(matches(code, binaryOperator(hasRHS( expr(hasType(substTemplateTypeParmType())))))); } TEST(NNS, MatchesNestedNameSpecifiers) { EXPECT_TRUE(matches("namespace ns { struct A {}; } ns::A a;", nestedNameSpecifier())); EXPECT_TRUE(matches("template class A { typename T::B b; };", nestedNameSpecifier())); EXPECT_TRUE(matches("struct A { void f(); }; void A::f() {}", nestedNameSpecifier())); EXPECT_TRUE(matches("namespace a { namespace b {} } namespace ab = a::b;", nestedNameSpecifier())); EXPECT_TRUE(matches( "struct A { static void f() {} }; void g() { A::f(); }", nestedNameSpecifier())); EXPECT_TRUE(notMatches( "struct A { static void f() {} }; void g(A* a) { a->f(); }", nestedNameSpecifier())); } TEST(NullStatement, SimpleCases) { EXPECT_TRUE(matches("void f() {int i;;}", nullStmt())); EXPECT_TRUE(notMatches("void f() {int i;}", nullStmt())); } TEST(NS, Alias) { EXPECT_TRUE(matches("namespace test {} namespace alias = ::test;", namespaceAliasDecl(hasName("alias")))); } TEST(NNS, MatchesTypes) { NestedNameSpecifierMatcher Matcher = nestedNameSpecifier( specifiesType(hasDeclaration(recordDecl(hasName("A"))))); EXPECT_TRUE(matches("struct A { struct B {}; }; A::B b;", Matcher)); EXPECT_TRUE(matches("struct A { struct B { struct C {}; }; }; A::B::C c;", Matcher)); EXPECT_TRUE(notMatches("namespace A { struct B {}; } A::B b;", Matcher)); } TEST(NNS, MatchesNamespaceDecls) { NestedNameSpecifierMatcher Matcher = nestedNameSpecifier( specifiesNamespace(hasName("ns"))); EXPECT_TRUE(matches("namespace ns { struct A {}; } ns::A a;", Matcher)); EXPECT_TRUE(notMatches("namespace xx { struct A {}; } xx::A a;", Matcher)); EXPECT_TRUE(notMatches("struct ns { struct A {}; }; ns::A a;", Matcher)); } TEST(NNS, MatchesNestedNameSpecifierPrefixes) { EXPECT_TRUE(matches( "struct A { struct B { struct C {}; }; }; A::B::C c;", nestedNameSpecifier(hasPrefix(specifiesType(asString("struct A")))))); EXPECT_TRUE(matches( "struct A { struct B { struct C {}; }; }; A::B::C c;", nestedNameSpecifierLoc(hasPrefix( specifiesTypeLoc(loc(qualType(asString("struct A")))))))); } template class VerifyAncestorHasChildIsEqual : public BoundNodesCallback { public: bool run(const BoundNodes *Nodes) override { return false; } bool run(const BoundNodes *Nodes, ASTContext *Context) override { const T *Node = Nodes->getNodeAs(""); return verify(*Nodes, *Context, Node); } bool verify(const BoundNodes &Nodes, ASTContext &Context, const Stmt *Node) { // Use the original typed pointer to verify we can pass pointers to subtypes // to equalsNode. const T *TypedNode = cast(Node); return selectFirst( "", match(stmt(hasParent( stmt(has(stmt(equalsNode(TypedNode)))).bind(""))), *Node, Context)) != nullptr; } bool verify(const BoundNodes &Nodes, ASTContext &Context, const Decl *Node) { // Use the original typed pointer to verify we can pass pointers to subtypes // to equalsNode. const T *TypedNode = cast(Node); return selectFirst( "", match(decl(hasParent( decl(has(decl(equalsNode(TypedNode)))).bind(""))), *Node, Context)) != nullptr; } bool verify(const BoundNodes &Nodes, ASTContext &Context, const Type *Node) { // Use the original typed pointer to verify we can pass pointers to subtypes // to equalsNode. const T *TypedNode = cast(Node); const auto *Dec = Nodes.getNodeAs("decl"); return selectFirst( "", match(fieldDecl(hasParent(decl(has(fieldDecl( hasType(type(equalsNode(TypedNode)).bind(""))))))), *Dec, Context)) != nullptr; } }; TEST(IsEqualTo, MatchesNodesByIdentity) { EXPECT_TRUE(matchAndVerifyResultTrue( "class X { class Y {}; };", recordDecl(hasName("::X::Y")).bind(""), llvm::make_unique>())); EXPECT_TRUE(matchAndVerifyResultTrue( "void f() { if (true) if(true) {} }", ifStmt().bind(""), llvm::make_unique>())); EXPECT_TRUE(matchAndVerifyResultTrue( "class X { class Y {} y; };", fieldDecl(hasName("y"), hasType(type().bind(""))).bind("decl"), llvm::make_unique>())); } TEST(TypedefDeclMatcher, Match) { EXPECT_TRUE(matches("typedef int typedefDeclTest;", typedefDecl(hasName("typedefDeclTest")))); EXPECT_TRUE(notMatches("using typedefDeclTest2 = int;", typedefDecl(hasName("typedefDeclTest2")))); } TEST(TypeAliasDeclMatcher, Match) { EXPECT_TRUE(matches("using typeAliasTest2 = int;", typeAliasDecl(hasName("typeAliasTest2")))); EXPECT_TRUE(notMatches("typedef int typeAliasTest;", typeAliasDecl(hasName("typeAliasTest")))); } TEST(TypedefNameDeclMatcher, Match) { EXPECT_TRUE(matches("typedef int typedefNameDeclTest1;", typedefNameDecl(hasName("typedefNameDeclTest1")))); EXPECT_TRUE(matches("using typedefNameDeclTest2 = int;", typedefNameDecl(hasName("typedefNameDeclTest2")))); } TEST(TypeAliasTemplateDeclMatcher, Match) { std::string Code = R"( template class X { T t; }; template using typeAliasTemplateDecl = X; using typeAliasDecl = X; )"; EXPECT_TRUE( matches(Code, typeAliasTemplateDecl(hasName("typeAliasTemplateDecl")))); EXPECT_TRUE( notMatches(Code, typeAliasTemplateDecl(hasName("typeAliasDecl")))); } TEST(ObjCMessageExprMatcher, SimpleExprs) { // don't find ObjCMessageExpr where none are present EXPECT_TRUE(notMatchesObjC("", objcMessageExpr(anything()))); std::string Objc1String = "@interface Str " " - (Str *)uppercaseString;" "@end " "@interface foo " "- (void)contents;" "- (void)meth:(Str *)text;" "@end " " " "@implementation foo " "- (void) meth:(Str *)text { " " [self contents];" " Str *up = [text uppercaseString];" "} " "@end "; EXPECT_TRUE(matchesObjC( Objc1String, objcMessageExpr(anything()))); EXPECT_TRUE(matchesObjC( Objc1String, objcMessageExpr(hasSelector("contents")))); EXPECT_TRUE(matchesObjC( Objc1String, objcMessageExpr(matchesSelector("cont*")))); EXPECT_FALSE(matchesObjC( Objc1String, objcMessageExpr(matchesSelector("?cont*")))); EXPECT_TRUE(notMatchesObjC( Objc1String, objcMessageExpr(hasSelector("contents"), hasNullSelector()))); EXPECT_TRUE(matchesObjC( Objc1String, objcMessageExpr(hasSelector("contents"), hasUnarySelector()))); EXPECT_TRUE(matchesObjC( Objc1String, objcMessageExpr(hasSelector("contents"), numSelectorArgs(0)))); EXPECT_TRUE(matchesObjC( Objc1String, objcMessageExpr(matchesSelector("uppercase*"), argumentCountIs(0) ))); } TEST(ObjCDeclMacher, CoreDecls) { std::string ObjCString = "@protocol Proto " "- (void)protoDidThing; " "@end " "@interface Thing " "@property int enabled; " "@end " "@interface Thing (ABC) " "- (void)abc_doThing; " "@end " "@implementation Thing " "{ id _ivar; } " "- (void)anything {} " "@end " ; EXPECT_TRUE(matchesObjC( ObjCString, objcProtocolDecl(hasName("Proto")))); EXPECT_TRUE(matchesObjC( ObjCString, objcCategoryDecl(hasName("ABC")))); EXPECT_TRUE(matchesObjC( ObjCString, objcMethodDecl(hasName("protoDidThing")))); EXPECT_TRUE(matchesObjC( ObjCString, objcMethodDecl(hasName("abc_doThing")))); EXPECT_TRUE(matchesObjC( ObjCString, objcMethodDecl(hasName("anything")))); EXPECT_TRUE(matchesObjC( ObjCString, objcIvarDecl(hasName("_ivar")))); EXPECT_TRUE(matchesObjC( ObjCString, objcPropertyDecl(hasName("enabled")))); } } // namespace ast_matchers } // namespace clang