llvm-project/clang/unittests/ASTMatchers/ASTMatchersNodeTest.cpp

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//== unittests/ASTMatchers/ASTMatchersNodeTest.cpp - AST matcher unit tests ==//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "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(isMain(), 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 T> 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<typename T> class X {};", ClassX));
EXPECT_TRUE(matches("class Z { template<class T> class X {}; };", ClassX));
}
TEST(ClassTemplate, DoesNotMatchClassTemplateExplicitSpecialization) {
EXPECT_TRUE(notMatches("template<typename T> class X { };"
"template<> class X<int> { int a; };",
classTemplateDecl(hasName("X"),
hasDescendant(fieldDecl(hasName("a"))))));
}
TEST(ClassTemplate, DoesNotMatchClassTemplatePartialSpecialization) {
EXPECT_TRUE(notMatches("template<typename T, typename U> class X { };"
"template<typename T> class X<T, int> { 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(FriendDecl, Matches) {
EXPECT_TRUE(matches("class Y { friend class X; };",
friendDecl(hasType(asString("class X")))));
EXPECT_TRUE(matches("class Y { friend class X; };",
friendDecl(hasType(recordDecl(hasName("X"))))));
EXPECT_TRUE(matches("class Y { friend void f(); };",
functionDecl(hasName("f"), hasParent(friendDecl()))));
}
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));
}
2020-01-29 20:57:27 +08:00
TEST(TagDecl, MatchesTagDecls) {
EXPECT_TRUE(matches("struct X {};", tagDecl(hasName("X"))));
EXPECT_TRUE(matches("class C {};", tagDecl(hasName("C"))));
EXPECT_TRUE(matches("union U {};", tagDecl(hasName("U"))));
EXPECT_TRUE(matches("enum E {};", tagDecl(hasName("E"))));
}
TEST(Matcher, UnresolvedLookupExpr) {
// FIXME: The test is known to be broken on Windows with delayed template
// parsing.
EXPECT_TRUE(matchesConditionally("template<typename T>"
"T foo() { T a; return a; }"
"template<typename T>"
"void bar() {"
" foo<T>();"
"}",
unresolvedLookupExpr(),
/*ExpectMatch=*/true,
"-fno-delayed-template-parsing"));
}
TEST(Matcher, ADLCall) {
StatementMatcher ADLMatch = callExpr(usesADL());
StatementMatcher ADLMatchOper = cxxOperatorCallExpr(usesADL());
auto NS_Str = R"cpp(
namespace NS {
struct X {};
void f(X);
void operator+(X, X);
}
struct MyX {};
void f(...);
void operator+(MyX, MyX);
)cpp";
auto MkStr = [&](std::string Body) -> std::string {
std::string S = NS_Str;
S += "void test_fn() { " + Body + " }";
return S;
};
EXPECT_TRUE(matches(MkStr("NS::X x; f(x);"), ADLMatch));
EXPECT_TRUE(notMatches(MkStr("NS::X x; NS::f(x);"), ADLMatch));
EXPECT_TRUE(notMatches(MkStr("MyX x; f(x);"), ADLMatch));
EXPECT_TRUE(notMatches(MkStr("NS::X x; using NS::f; f(x);"), ADLMatch));
// Operator call expressions
EXPECT_TRUE(matches(MkStr("NS::X x; x + x;"), ADLMatch));
EXPECT_TRUE(matches(MkStr("NS::X x; x + x;"), ADLMatchOper));
EXPECT_TRUE(notMatches(MkStr("MyX x; x + x;"), ADLMatch));
EXPECT_TRUE(notMatches(MkStr("MyX x; x + x;"), ADLMatchOper));
EXPECT_TRUE(matches(MkStr("NS::X x; operator+(x, x);"), ADLMatch));
EXPECT_TRUE(notMatches(MkStr("NS::X x; NS::operator+(x, x);"), ADLMatch));
}
TEST(Matcher, Call) {
// FIXME: Do we want to overload Call() to directly take
// Matcher<Decl>, 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<int N>\n"
"struct A { static const int n = 0; };\n"
"struct B : public A<42> {};",
substNonTypeTemplateParmExpr()));
EXPECT_TRUE(matches("template<int N>\n"
"struct A { static const int n = N; };\n"
"struct B : public A<42> {};",
substNonTypeTemplateParmExpr()));
}
TEST(Matcher, NonTypeTemplateParmDecl) {
EXPECT_TRUE(matches("template <int N> void f();",
nonTypeTemplateParmDecl(hasName("N"))));
EXPECT_TRUE(
notMatches("template <typename T> void f();", nonTypeTemplateParmDecl()));
}
TEST(Matcher, templateTypeParmDecl) {
EXPECT_TRUE(matches("template <typename T> void f();",
templateTypeParmDecl(hasName("T"))));
EXPECT_TRUE(
notMatches("template <int N> 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 <stddef.h>\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()));
EXPECT_TRUE(notMatches("class Y { void x() {} };", unresolvedMemberExpr()));
EXPECT_TRUE(
notMatches("class Y { void x() {} };", cxxDependentScopeMemberExpr()));
}
TEST(MemberExpression, MatchesMemberFunctionCall) {
EXPECT_TRUE(matches("class Y { void x() { x(); } };", memberExpr()));
EXPECT_TRUE(matches("class Y { template <class T> void x() { x<T>(); } };",
unresolvedMemberExpr()));
EXPECT_TRUE(matches("template <class T> void x() { T t; t.f(); }",
cxxDependentScopeMemberExpr()));
}
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()));
EXPECT_TRUE(matches("template <class T>"
"class X : T { void f() { this->T::v; } };",
cxxDependentScopeMemberExpr()));
EXPECT_TRUE(matches("template <class T> class X : T { void f() { T::v; } };",
cxxDependentScopeMemberExpr()));
EXPECT_TRUE(matches("template <class T> void x() { T t; t.v; }",
cxxDependentScopeMemberExpr()));
}
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 <int N> void g() { f(); }",
CallFunctionF));
EXPECT_TRUE(
matches("void f(); template <int N> struct S { void g() { f(); } };",
CallFunctionF));
}
// Depedent calls don't match.
EXPECT_TRUE(
notMatches("void f(int); template <typename T> void g(T t) { f(t); }",
CallFunctionF));
EXPECT_TRUE(
notMatches("void f(int);"
"template <typename T> 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 <typename... Ts> 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 <typename T> 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 <typename T> 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<typename T> struct A {};"
"template<> struct A<int> {};",
classTemplateSpecializationDecl()));
EXPECT_TRUE(matches("template<typename T> struct A {}; A<int> a;",
classTemplateSpecializationDecl()));
EXPECT_TRUE(notMatches("template<typename T> 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, NoexceptExpression) {
StatementMatcher NoExcept = cxxNoexceptExpr();
EXPECT_TRUE(matches("void foo(); bool bar = noexcept(foo());", NoExcept));
EXPECT_TRUE(
matches("void foo() noexcept; bool bar = noexcept(foo());", NoExcept));
EXPECT_TRUE(notMatches("void foo() noexcept;", NoExcept));
EXPECT_TRUE(notMatches("void foo() noexcept(1+1);", NoExcept));
EXPECT_TRUE(matches("void foo() noexcept(noexcept(1+1));", NoExcept));
}
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));
// Negative integers.
EXPECT_TRUE(
matches("int i = -10;",
unaryOperator(hasOperatorName("-"),
hasUnaryOperand(integerLiteral(equals(10))))));
}
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()));
}
[ASTImporter] Add support for importing ChooseExpr AST nodes. Summary: This allows ASTs to be merged when they contain ChooseExpr (the GNU __builtin_choose_expr construction). This is needed, for example, for cross-CTU analysis of C code that makes use of __builtin_choose_expr. The node is already supported in the AST, but it didn't have a matcher in ASTMatchers. So, this change adds the matcher and adds support to ASTImporter. This was originally reviewed and approved in https://reviews.llvm.org/D58292 and submitted as r354832. It was reverted in r354839 due to failures on the Windows CI builds. This version fixes the test failures on Windows, which were caused by differences in template expansion between versions of clang on different OSes. The version of clang built with MSVC and running on Windows never expands the template in the C++ test in ImportExpr.ImportChooseExpr in clang/unittests/AST/ASTImporter.cpp, but the version on Linux does for the empty arguments and -fms-compatibility. So, this version of the patch drops the C++ test for __builtin_choose_expr, since that version was written to catch regressions of the logic for isConditionTrue() in the AST import code for ChooseExpr, and those regressions are also caught by ASTImporterOptionSpecificTestBase.ImportChooseExpr, which does work on Windows. Reviewers: shafik, a_sidorin, martong, aaron.ballman, rnk, a.sidorin Subscribers: cfe-commits, jdoerfert, rnkovacs, aaron.ballman Tags: #clang Differential Revision: https://reviews.llvm.org/D58663 llvm-svn: 354916
2019-02-27 03:26:41 +08:00
TEST(Matcher, ChooseExpr) {
EXPECT_TRUE(matchesC("void f() { (void)__builtin_choose_expr(1, 2, 3); }",
chooseExpr()));
}
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),
hasDescendant(floatLiteral(
equals(1.0))),
hasDescendant(integerLiteral(
equals(2))))),
has(
designatedInitExpr(
designatorCountIs(2),
hasDescendant(floatLiteral(
equals(2.0))),
hasDescendant(integerLiteral(
equals(2))))),
has(
designatedInitExpr(
designatorCountIs(2),
hasDescendant(floatLiteral(
equals(1.0))),
hasDescendant(integerLiteral(
equals(0)))))
)))));
}
TEST(Matcher, ParenListExpr) {
EXPECT_TRUE(
matches("template<typename T> class foo { void bar() { foo X(*this); } };"
"template class foo<int>;",
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<char *>(&p);",castExpr()));
EXPECT_TRUE(matches("void *p = (void *)(&p);", castExpr()));
EXPECT_TRUE(matches("char q, *p = const_cast<char *>(&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<char*>(&p);",
cxxReinterpretCastExpr()));
}
TEST(ReinterpretCast, DoesNotMatchOtherCasts) {
EXPECT_TRUE(notMatches("char* p = (char*)(&p);", cxxReinterpretCastExpr()));
EXPECT_TRUE(notMatches("char q, *p = const_cast<char*>(&q);",
cxxReinterpretCastExpr()));
EXPECT_TRUE(notMatches("void* p = static_cast<void*>(&p);",
cxxReinterpretCastExpr()));
EXPECT_TRUE(notMatches("struct B { virtual ~B() {} }; struct D : B {};"
"B b;"
"D* p = dynamic_cast<D*>(&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<D*>(&b);",
cxxDynamicCastExpr()));
}
TEST(StaticCast, MatchesSimpleCase) {
EXPECT_TRUE(matches("void* p(static_cast<void*>(&p));",
cxxStaticCastExpr()));
}
TEST(StaticCast, DoesNotMatchOtherCasts) {
EXPECT_TRUE(notMatches("char* p = (char*)(&p);", cxxStaticCastExpr()));
EXPECT_TRUE(notMatches("char q, *p = const_cast<char*>(&q);",
cxxStaticCastExpr()));
EXPECT_TRUE(notMatches("void* p = reinterpret_cast<char*>(&p);",
cxxStaticCastExpr()));
EXPECT_TRUE(notMatches("struct B { virtual ~B() {} }; struct D : B {};"
"B b;"
"D* p = dynamic_cast<D*>(&b);",
cxxStaticCastExpr()));
}
TEST(CStyleCast, MatchesSimpleCase) {
EXPECT_TRUE(matches("int i = (int) 2.2f;", cStyleCastExpr()));
}
TEST(CStyleCast, DoesNotMatchOtherCasts) {
EXPECT_TRUE(notMatches("char* p = static_cast<char*>(0);"
"char q, *r = const_cast<char*>(&q);"
"void* s = reinterpret_cast<char*>(&s);"
"struct B { virtual ~B() {} }; struct D : B {};"
"B b;"
"D* t = dynamic_cast<D*>(&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<int *>(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(CXXStdInitializerListExpression, MatchesCXXStdInitializerListExpression) {
const std::string code = "namespace std {"
"template <typename> class initializer_list {"
" public: initializer_list() noexcept {}"
"};"
"}"
"struct A {"
" A(std::initializer_list<int>) {}"
"};";
EXPECT_TRUE(matches(code + "A a{0};",
cxxConstructExpr(has(cxxStdInitializerListExpr()),
hasDeclaration(cxxConstructorDecl(
ofClass(hasName("A")))))));
EXPECT_TRUE(matches(code + "A a = {0};",
cxxConstructExpr(has(cxxStdInitializerListExpr()),
hasDeclaration(cxxConstructorDecl(
ofClass(hasName("A")))))));
EXPECT_TRUE(notMatches("int a[] = { 1, 2 };", cxxStdInitializerListExpr()));
EXPECT_TRUE(notMatches("struct B { int x, y; }; B b = { 5, 6 };",
cxxStdInitializerListExpr()));
}
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(ParenExpression, IgnoringParens) {
EXPECT_FALSE(matches("const char* str = (\"my-string\");",
implicitCastExpr(hasSourceExpression(stringLiteral()))));
EXPECT_TRUE(matches(
"const char* str = (\"my-string\");",
implicitCastExpr(hasSourceExpression(ignoringParens(stringLiteral())))));
}
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 <typename T, int Size> 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()));
EXPECT_TRUE(matches("auto i = 2;", varDecl(hasType(isInteger()))));
EXPECT_TRUE(matches("struct X{}; auto x = X{};",
varDecl(hasType(recordDecl(hasName("X"))))));
// 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, MatchesDeclTypes) {
EXPECT_TRUE(matches("decltype(1 + 1) sum = 1 + 1;", decltypeType()));
EXPECT_TRUE(matches("decltype(1 + 1) sum = 1 + 1;",
decltypeType(hasUnderlyingType(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"))),
// std::make_unique<VerifyIdIsBoundTo<TypeLoc>>("loc", 1)));
//EXPECT_TRUE(matchAndVerifyResultTrue(
// "int* a;",
// pointerTypeLoc().bind("loc"),
// std::make_unique<VerifyIdIsBoundTo<TypeLoc>>("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 <typename T> class A{}; A<int> a;",
templateSpecializationType()));
}
TEST(TypeMatching, MatchesDeucedTemplateSpecializationType) {
EXPECT_TRUE(matches("template <typename T> class A{ public: A(T) {} }; A a(1);",
deducedTemplateSpecializationType(),
LanguageMode::Cxx17OrLater));
}
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 <typename T>"
"int F() {"
" return 1 + T();"
"}"
"int i = F<int>();";
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 <typename T> 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"))))))));
EXPECT_TRUE(matches(
"namespace N { struct A { struct B { struct C {}; }; }; } N::A::B::C c;",
nestedNameSpecifierLoc(hasPrefix(
specifiesTypeLoc(loc(qualType(asString("struct N::A"))))))));
}
template <typename T>
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<T>("");
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<T>(Node);
return selectFirst<T>(
"", 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<T>(Node);
return selectFirst<T>(
"", 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<T>(Node);
const auto *Dec = Nodes.getNodeAs<FieldDecl>("decl");
return selectFirst<T>(
"", 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(""),
std::make_unique<VerifyAncestorHasChildIsEqual<CXXRecordDecl>>()));
EXPECT_TRUE(matchAndVerifyResultTrue(
"void f() { if (true) if(true) {} }", ifStmt().bind(""),
std::make_unique<VerifyAncestorHasChildIsEqual<IfStmt>>()));
EXPECT_TRUE(matchAndVerifyResultTrue(
"class X { class Y {} y; };",
fieldDecl(hasName("y"), hasType(type().bind(""))).bind("decl"),
std::make_unique<VerifyAncestorHasChildIsEqual<Type>>()));
}
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 <typename T>
class X { T t; };
template <typename T>
using typeAliasTemplateDecl = X<T>;
using typeAliasDecl = X<int>;
)";
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(hasAnySelector({
"contents", "meth:"}))
));
EXPECT_TRUE(matchesObjC(
Objc1String,
objcMessageExpr(hasSelector("contents"))));
EXPECT_TRUE(matchesObjC(
Objc1String,
objcMessageExpr(hasAnySelector("contents", "contentsA"))));
EXPECT_FALSE(matchesObjC(
Objc1String,
objcMessageExpr(hasAnySelector("contentsB", "contentsC"))));
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(ObjCDeclMatcher, 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 "
"@implementation Thing (ABC) "
"- (void)abc_doThing {} "
"@end "
;
EXPECT_TRUE(matchesObjC(
ObjCString,
objcProtocolDecl(hasName("Proto"))));
EXPECT_TRUE(matchesObjC(
ObjCString,
objcImplementationDecl(hasName("Thing"))));
EXPECT_TRUE(matchesObjC(
ObjCString,
objcCategoryDecl(hasName("ABC"))));
EXPECT_TRUE(matchesObjC(
ObjCString,
objcCategoryImplDecl(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"))));
}
TEST(ObjCStmtMatcher, ExceptionStmts) {
std::string ObjCString =
"void f(id obj) {"
" @try {"
" @throw obj;"
" } @catch (...) {"
" } @finally {}"
"}";
EXPECT_TRUE(matchesObjC(
ObjCString,
objcTryStmt()));
EXPECT_TRUE(matchesObjC(
ObjCString,
objcThrowStmt()));
EXPECT_TRUE(matchesObjC(
ObjCString,
objcCatchStmt()));
EXPECT_TRUE(matchesObjC(
ObjCString,
objcFinallyStmt()));
}
TEST(ObjCAutoreleaseMatcher, AutoreleasePool) {
std::string ObjCString =
"void f() {"
"@autoreleasepool {"
" int x = 1;"
"}"
"}";
EXPECT_TRUE(matchesObjC(ObjCString, autoreleasePoolStmt()));
std::string ObjCStringNoPool = "void f() { int x = 1; }";
EXPECT_FALSE(matchesObjC(ObjCStringNoPool, autoreleasePoolStmt()));
}
TEST(OMPExecutableDirective, Matches) {
auto Matcher = stmt(ompExecutableDirective());
const std::string Source0 = R"(
void x() {
#pragma omp parallel
;
})";
EXPECT_TRUE(matchesWithOpenMP(Source0, Matcher));
const std::string Source1 = R"(
void x() {
#pragma omp taskyield
;
})";
EXPECT_TRUE(matchesWithOpenMP(Source1, Matcher));
const std::string Source2 = R"(
void x() {
;
})";
EXPECT_TRUE(notMatchesWithOpenMP(Source2, Matcher));
}
TEST(OMPDefaultClause, Matches) {
auto Matcher = ompExecutableDirective(hasAnyClause(ompDefaultClause()));
const std::string Source0 = R"(
void x() {
;
})";
EXPECT_TRUE(notMatchesWithOpenMP(Source0, Matcher));
const std::string Source1 = R"(
void x() {
#pragma omp parallel
;
})";
EXPECT_TRUE(notMatchesWithOpenMP(Source1, Matcher));
const std::string Source2 = R"(
void x() {
#pragma omp parallel default(none)
;
})";
EXPECT_TRUE(matchesWithOpenMP(Source2, Matcher));
const std::string Source3 = R"(
void x() {
#pragma omp parallel default(shared)
;
})";
EXPECT_TRUE(matchesWithOpenMP(Source3, Matcher));
const std::string Source4 = R"(
void x(int x) {
#pragma omp parallel num_threads(x)
;
})";
EXPECT_TRUE(notMatchesWithOpenMP(Source4, Matcher));
}
TEST(MatchFinderAPI, matchesDynamic) {
std::string SourceCode = "struct A { void f() {} };";
auto Matcher = functionDecl(isDefinition()).bind("method");
auto astUnit = tooling::buildASTFromCode(SourceCode);
auto GlobalBoundNodes = matchDynamic(Matcher, astUnit->getASTContext());
EXPECT_EQ(GlobalBoundNodes.size(), 1u);
EXPECT_EQ(GlobalBoundNodes[0].getMap().size(), 1u);
auto GlobalMethodNode = GlobalBoundNodes[0].getNodeAs<FunctionDecl>("method");
EXPECT_TRUE(GlobalMethodNode != nullptr);
auto MethodBoundNodes =
matchDynamic(Matcher, *GlobalMethodNode, astUnit->getASTContext());
EXPECT_EQ(MethodBoundNodes.size(), 1u);
EXPECT_EQ(MethodBoundNodes[0].getMap().size(), 1u);
auto MethodNode = MethodBoundNodes[0].getNodeAs<FunctionDecl>("method");
EXPECT_EQ(MethodNode, GlobalMethodNode);
}
} // namespace ast_matchers
} // namespace clang