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[clangd] Improve heuristic resolution of dependent types in TargetFinder 

* Try to apply heuristic resolution recursively to the base
   expression of a CXXDependentScopeMemberExpr.

 * Try to apply heuristic resolution recursively to the callee
   expression in a call expression.

Fixes https://github.com/clangd/clangd/issues/441

Subscribers: ilya-biryukov, jkorous, arphaman, kadircet, usaxena95, cfe-commits

Tags: #clang

Differential Revision: https://reviews.llvm.org/D82739
This commit is contained in:
Nathan Ridge 2020-07-08 02:51:34 -04:00
parent 8953376478
commit 9946dcd3e9
2 changed files with 370 additions and 252 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

63
clang-tools-extra/clangd/FindTarget.cpp
View File

@ -59,24 +59,32 @@ nodeToString(const ast_type_traits::DynTypedNode &N) {
}
// Helper function for getMembersReferencedViaDependentName()
// which takes a dependent type `T` and heuristically
// which takes a possibly-dependent type `T` and heuristically
// resolves it to a CXXRecordDecl in which we can try name lookup.
CXXRecordDecl *resolveTypeToRecordDecl(const Type *T) {
assert(T);
if (const auto *ICNT = T->getAs<InjectedClassNameType>()) {
if (const auto *RT = T->getAs<RecordType>())
return dyn_cast<CXXRecordDecl>(RT->getDecl());
if (const auto *ICNT = T->getAs<InjectedClassNameType>())
T = ICNT->getInjectedSpecializationType().getTypePtrOrNull();
}
if (!T)
return nullptr;
const auto *TST = T->getAs<TemplateSpecializationType>();
if (!TST)
return nullptr;
const ClassTemplateDecl *TD = dyn_cast_or_null<ClassTemplateDecl>(
TST->getTemplateName().getAsTemplateDecl());
if (!TD)
return nullptr;
return TD->getTemplatedDecl();
}
// Given a dependent type and a member name, heuristically resolve the
// Given a tag-decl type and a member name, heuristically resolve the
// name to one or more declarations.
// The current heuristic is simply to look up the name in the primary
// template. This is a heuristic because the template could potentially
@ -154,6 +162,10 @@ const Type *getPointeeType(const Type *T) {
return FirstArg.getAsType().getTypePtrOrNull();
}
// Forward declaration, needed as this function is mutually recursive
// with resolveDependentExprToDecls.
const Type *resolveDependentExprToType(const Expr *E);
// Try to heuristically resolve a dependent expression `E` to one
// or more declarations that it likely references.
std::vector<const NamedDecl *> resolveDependentExprToDecls(const Expr *E) {
@ -163,6 +175,15 @@ std::vector<const NamedDecl *> resolveDependentExprToDecls(const Expr *E) {
if (ME->isArrow()) {
BaseType = getPointeeType(BaseType);
}
if (const auto *BT = BaseType->getAs<BuiltinType>()) {
// If BaseType is the type of a dependent expression, it's just
// represented as BultinType::Dependent which gives us no information. We
// can get further by analyzing the depedent expression.
Expr *Base = ME->isImplicitAccess() ? nullptr : ME->getBase();
if (Base && BT->getKind() == BuiltinType::Dependent) {
BaseType = resolveDependentExprToType(Base);
}
}
return getMembersReferencedViaDependentName(
BaseType, [ME](ASTContext &) { return ME->getMember(); },
/*IsNonstaticMember=*/true);
@ -173,9 +194,38 @@ std::vector<const NamedDecl *> resolveDependentExprToDecls(const Expr *E) {
[RE](ASTContext &) { return RE->getDeclName(); },
/*IsNonstaticMember=*/false);
}
if (const auto *CE = dyn_cast<CallExpr>(E)) {
const auto *CalleeType = resolveDependentExprToType(CE->getCallee());
if (!CalleeType)
return {};
if (const auto *FnTypePtr = CalleeType->getAs<PointerType>())
CalleeType = FnTypePtr->getPointeeType().getTypePtr();
if (const FunctionType *FnType = CalleeType->getAs<FunctionType>()) {
if (const auto *D =
resolveTypeToRecordDecl(FnType->getReturnType().getTypePtr())) {
return {D};
}
}
}
if (const auto *ME = dyn_cast<MemberExpr>(E)) {
return {ME->getMemberDecl()};
}
return {};
}
// Try to heuristically resolve the type of a dependent expression `E`.
const Type *resolveDependentExprToType(const Expr *E) {
std::vector<const NamedDecl *> Decls = resolveDependentExprToDecls(E);
if (Decls.size() != 1) // Names an overload set -- just bail.
return nullptr;
if (const auto *TD = dyn_cast<TypeDecl>(Decls[0])) {
return TD->getTypeForDecl();
} else if (const auto *VD = dyn_cast<ValueDecl>(Decls[0])) {
return VD->getType().getTypePtrOrNull();
}
return nullptr;
}
const NamedDecl *getTemplatePattern(const NamedDecl *D) {
if (const CXXRecordDecl *CRD = dyn_cast<CXXRecordDecl>(D)) {
if (const auto *Result = CRD->getTemplateInstantiationPattern())
@ -235,9 +285,8 @@ const NamedDecl *getTemplatePattern(const NamedDecl *D) {
// and both are lossy. We must know upfront what the caller ultimately wants.
//
// FIXME: improve common dependent scope using name lookup in primary templates.
// e.g. template<typename T> int foo() { return std::vector<T>().size(); }
// formally size() is unresolved, but the primary template is a good guess.
// This affects:
// We currently handle DependentScopeDeclRefExpr and
// CXXDependentScopeMemberExpr, but some other constructs remain to be handled:
// - DependentTemplateSpecializationType,
// - DependentNameType
// - UnresolvedUsingValueDecl

559
clang-tools-extra/clangd/unittests/FindTargetTests.cpp
View File

@ -561,6 +561,74 @@ TEST_F(TargetDeclTest, OverloadExpr) {
EXPECT_DECLS("UnresolvedMemberExpr", "void func(int *)", "void func(char *)");
}
TEST_F(TargetDeclTest, DependentExprs) {
Flags = {"-fno-delayed-template-parsing"};
// Heuristic resolution of method of dependent field
Code = R"cpp(
struct A { void foo() {} };
template <typename T>
struct B {
A a;
void bar() {
this->a.[[foo]]();
}
};
)cpp";
EXPECT_DECLS("CXXDependentScopeMemberExpr", "void foo()");
// Similar to above but base expression involves a function call.
Code = R"cpp(
struct A {
void foo() {}
};
struct B {
A getA();
};
template <typename T>
struct C {
B c;
void bar() {
this->c.getA().[[foo]]();
}
};
)cpp";
EXPECT_DECLS("CXXDependentScopeMemberExpr", "void foo()");
// Similar to above but uses a function pointer.
Code = R"cpp(
struct A {
void foo() {}
};
struct B {
using FPtr = A(*)();
FPtr fptr;
};
template <typename T>
struct C {
B c;
void bar() {
this->c.fptr().[[foo]]();
}
};
)cpp";
EXPECT_DECLS("CXXDependentScopeMemberExpr", "void foo()");
// Base expression involves a member access into this.
Code = R"cpp(
struct Bar {
int aaaa;
};
template <typename T> struct Foo {
Bar func(int);
void test() {
func(1).[[aaaa]];
}
};
)cpp";
EXPECT_DECLS("CXXDependentScopeMemberExpr", "int aaaa");
}
TEST_F(TargetDeclTest, ObjC) {
Flags = {"-xobjective-c"};
Code = R"cpp(
@ -718,36 +786,37 @@ protected:
TEST_F(FindExplicitReferencesTest, All) {
std::pair</*Code*/ llvm::StringRef, /*References*/ llvm::StringRef> Cases[] =
{// Simple expressions.
{R"cpp(
{
// Simple expressions.
{R"cpp(
int global;
int func();
void foo(int param) {
$0^global = $1^param + $2^func();
}
)cpp",
"0: targets = {global}\n"
"1: targets = {param}\n"
"2: targets = {func}\n"},
{R"cpp(
"0: targets = {global}\n"
"1: targets = {param}\n"
"2: targets = {func}\n"},
{R"cpp(
struct X { int a; };
void foo(X x) {
$0^x.$1^a = 10;
}
)cpp",
"0: targets = {x}\n"
"1: targets = {X::a}\n"},
{R"cpp(
"0: targets = {x}\n"
"1: targets = {X::a}\n"},
{R"cpp(
// error-ok: testing with broken code
int bar();
int foo() {
return $0^bar() + $1^bar(42);
}
)cpp",
"0: targets = {bar}\n"
"1: targets = {bar}\n"},
// Namespaces and aliases.
{R"cpp(
"0: targets = {bar}\n"
"1: targets = {bar}\n"},
// Namespaces and aliases.
{R"cpp(
namespace ns {}
namespace alias = ns;
void foo() {
@ -755,19 +824,19 @@ TEST_F(FindExplicitReferencesTest, All) {
using namespace $1^alias;
}
)cpp",
"0: targets = {ns}\n"
"1: targets = {alias}\n"},
// Using declarations.
{R"cpp(
"0: targets = {ns}\n"
"1: targets = {alias}\n"},
// Using declarations.
{R"cpp(
namespace ns { int global; }
void foo() {
using $0^ns::$1^global;
}
)cpp",
"0: targets = {ns}\n"
"1: targets = {ns::global}, qualifier = 'ns::'\n"},
// Simple types.
{R"cpp(
"0: targets = {ns}\n"
"1: targets = {ns::global}, qualifier = 'ns::'\n"},
// Simple types.
{R"cpp(
struct Struct { int a; };
using Typedef = int;
void foo() {
@ -776,13 +845,13 @@ TEST_F(FindExplicitReferencesTest, All) {
static_cast<$4^Struct*>(0);
}
)cpp",
"0: targets = {Struct}\n"
"1: targets = {x}, decl\n"
"2: targets = {Typedef}\n"
"3: targets = {y}, decl\n"
"4: targets = {Struct}\n"},
// Name qualifiers.
{R"cpp(
"0: targets = {Struct}\n"
"1: targets = {x}, decl\n"
"2: targets = {Typedef}\n"
"3: targets = {y}, decl\n"
"4: targets = {Struct}\n"},
// Name qualifiers.
{R"cpp(
namespace a { namespace b { struct S { typedef int type; }; } }
void foo() {
$0^a::$1^b::$2^S $3^x;
@ -790,16 +859,16 @@ TEST_F(FindExplicitReferencesTest, All) {
$6^S::$7^type $8^y;
}
)cpp",
"0: targets = {a}\n"
"1: targets = {a::b}, qualifier = 'a::'\n"
"2: targets = {a::b::S}, qualifier = 'a::b::'\n"
"3: targets = {x}, decl\n"
"4: targets = {a}\n"
"5: targets = {a::b}, qualifier = 'a::'\n"
"6: targets = {a::b::S}\n"
"7: targets = {a::b::S::type}, qualifier = 'struct S::'\n"
"8: targets = {y}, decl\n"},
{R"cpp(
"0: targets = {a}\n"
"1: targets = {a::b}, qualifier = 'a::'\n"
"2: targets = {a::b::S}, qualifier = 'a::b::'\n"
"3: targets = {x}, decl\n"
"4: targets = {a}\n"
"5: targets = {a::b}, qualifier = 'a::'\n"
"6: targets = {a::b::S}\n"
"7: targets = {a::b::S::type}, qualifier = 'struct S::'\n"
"8: targets = {y}, decl\n"},
{R"cpp(
void foo() {
$0^ten: // PRINT "HELLO WORLD!"
goto $1^ten;
@ -816,12 +885,12 @@ TEST_F(FindExplicitReferencesTest, All) {
$2^vector<bool> $3^vb;
}
)cpp",
"0: targets = {vector<int>}\n"
"1: targets = {vi}, decl\n"
"2: targets = {vector<bool>}\n"
"3: targets = {vb}, decl\n"},
// Template type aliases.
{R"cpp(
"0: targets = {vector<int>}\n"
"1: targets = {vi}, decl\n"
"2: targets = {vector<bool>}\n"
"3: targets = {vb}, decl\n"},
// Template type aliases.
{R"cpp(
template <class T> struct vector { using value_type = T; };
template <> struct vector<bool> { using value_type = bool; };
template <class T> using valias = vector<T>;
@ -830,12 +899,12 @@ TEST_F(FindExplicitReferencesTest, All) {
$2^valias<bool> $3^vb;
}
)cpp",
"0: targets = {valias}\n"
"1: targets = {vi}, decl\n"
"2: targets = {valias}\n"
"3: targets = {vb}, decl\n"},
// Injected class name.
{R"cpp(
"0: targets = {valias}\n"
"1: targets = {vi}, decl\n"
"2: targets = {valias}\n"
"3: targets = {vb}, decl\n"},
// Injected class name.
{R"cpp(
namespace foo {
template <typename $0^T>
class $1^Bar {
@ -844,13 +913,13 @@ TEST_F(FindExplicitReferencesTest, All) {
};
}
)cpp",
"0: targets = {foo::Bar::T}, decl\n"
"1: targets = {foo::Bar}, decl\n"
"2: targets = {foo::Bar}\n"
"3: targets = {foo::Bar::f}, decl\n"
"4: targets = {foo::Bar}\n"},
// MemberExpr should know their using declaration.
{R"cpp(
"0: targets = {foo::Bar::T}, decl\n"
"1: targets = {foo::Bar}, decl\n"
"2: targets = {foo::Bar}\n"
"3: targets = {foo::Bar::f}, decl\n"
"4: targets = {foo::Bar}\n"},
// MemberExpr should know their using declaration.
{R"cpp(
struct X { void func(int); };
struct Y : X {
using X::func;
@ -859,10 +928,10 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^y.$1^func(1);
}
)cpp",
"0: targets = {y}\n"
"1: targets = {Y::func}\n"},
// DeclRefExpr should know their using declaration.
{R"cpp(
"0: targets = {y}\n"
"1: targets = {Y::func}\n"},
// DeclRefExpr should know their using declaration.
{R"cpp(
namespace ns { void bar(int); }
using ns::bar;
@ -870,9 +939,9 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^bar(10);
}
)cpp",
"0: targets = {bar}\n"},
// References from a macro.
{R"cpp(
"0: targets = {bar}\n"},
// References from a macro.
{R"cpp(
#define FOO a
#define BAR b
@ -880,10 +949,10 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^FOO+$1^BAR;
}
)cpp",
"0: targets = {a}\n"
"1: targets = {b}\n"},
// No references from implicit nodes.
{R"cpp(
"0: targets = {a}\n"
"1: targets = {b}\n"},
// No references from implicit nodes.
{R"cpp(
struct vector {
int *begin();
int *end();
@ -895,15 +964,15 @@ TEST_F(FindExplicitReferencesTest, All) {
}
}
)cpp",
"0: targets = {x}, decl\n"
"1: targets = {vector}\n"
"2: targets = {x}\n"},
"0: targets = {x}, decl\n"
"1: targets = {vector}\n"
"2: targets = {x}\n"},
// Handle UnresolvedLookupExpr.
// FIXME
// This case fails when expensive checks are enabled.
// Seems like the order of ns1::func and ns2::func isn't defined.
#ifndef EXPENSIVE_CHECKS
{R"cpp(
{R"cpp(
namespace ns1 { void func(char*); }
namespace ns2 { void func(int*); }
using namespace ns1;
@ -914,11 +983,11 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^func($1^t);
}
)cpp",
"0: targets = {ns1::func, ns2::func}\n"
"1: targets = {t}\n"},
"0: targets = {ns1::func, ns2::func}\n"
"1: targets = {t}\n"},
#endif
// Handle UnresolvedMemberExpr.
{R"cpp(
// Handle UnresolvedMemberExpr.
{R"cpp(
struct X {
void func(char*);
void func(int*);
@ -929,11 +998,11 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^x.$1^func($2^t);
}
)cpp",
"0: targets = {x}\n"
"1: targets = {X::func, X::func}\n"
"2: targets = {t}\n"},
// Handle DependentScopeDeclRefExpr.
{R"cpp(
"0: targets = {x}\n"
"1: targets = {X::func, X::func}\n"
"2: targets = {t}\n"},
// Handle DependentScopeDeclRefExpr.
{R"cpp(
template <class T>
struct S {
static int value;
@ -944,11 +1013,11 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^S<$1^T>::$2^value;
}
)cpp",
"0: targets = {S}\n"
"1: targets = {T}\n"
"2: targets = {S::value}, qualifier = 'S<T>::'\n"},
// Handle CXXDependentScopeMemberExpr.
{R"cpp(
"0: targets = {S}\n"
"1: targets = {T}\n"
"2: targets = {S::value}, qualifier = 'S<T>::'\n"},
// Handle CXXDependentScopeMemberExpr.
{R"cpp(
template <class T>
struct S {
int value;
@ -959,10 +1028,10 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^t.$1^value;
}
)cpp",
"0: targets = {t}\n"
"1: targets = {S::value}\n"},
// Type template parameters.
{R"cpp(
"0: targets = {t}\n"
"1: targets = {S::value}\n"},
// Type template parameters.
{R"cpp(
template <class T>
void foo() {
static_cast<$0^T>(0);
@ -970,21 +1039,21 @@ TEST_F(FindExplicitReferencesTest, All) {
$2^T $3^t;
}
)cpp",
"0: targets = {T}\n"
"1: targets = {T}\n"
"2: targets = {T}\n"
"3: targets = {t}, decl\n"},
// Non-type template parameters.
{R"cpp(
"0: targets = {T}\n"
"1: targets = {T}\n"
"2: targets = {T}\n"
"3: targets = {t}, decl\n"},
// Non-type template parameters.
{R"cpp(
template <int I>
void foo() {
int $0^x = $1^I;
}
)cpp",
"0: targets = {x}, decl\n"
"1: targets = {I}\n"},
// Template template parameters.
{R"cpp(
"0: targets = {x}, decl\n"
"1: targets = {I}\n"},
// Template template parameters.
{R"cpp(
template <class T> struct vector {};
template <template<class> class TT, template<class> class ...TP>
@ -995,16 +1064,16 @@ TEST_F(FindExplicitReferencesTest, All) {
$6^foo<$7^TP...>();
}
)cpp",
"0: targets = {TT}\n"
"1: targets = {x}, decl\n"
"2: targets = {foo}\n"
"3: targets = {TT}\n"
"4: targets = {foo}\n"
"5: targets = {vector}\n"
"6: targets = {foo}\n"
"7: targets = {TP}\n"},
// Non-type template parameters with declarations.
{R"cpp(
"0: targets = {TT}\n"
"1: targets = {x}, decl\n"
"2: targets = {foo}\n"
"3: targets = {TT}\n"
"4: targets = {foo}\n"
"5: targets = {vector}\n"
"6: targets = {foo}\n"
"7: targets = {TP}\n"},
// Non-type template parameters with declarations.
{R"cpp(
int func();
template <int(*)()> struct wrapper {};
@ -1014,12 +1083,12 @@ TEST_F(FindExplicitReferencesTest, All) {
$3^FuncParam();
}
)cpp",
"0: targets = {wrapper<&func>}\n"
"1: targets = {func}\n"
"2: targets = {w}, decl\n"
"3: targets = {FuncParam}\n"},
// declaration references.
{R"cpp(
"0: targets = {wrapper<&func>}\n"
"1: targets = {func}\n"
"2: targets = {w}, decl\n"
"3: targets = {FuncParam}\n"},
// declaration references.
{R"cpp(
namespace ns {}
class S {};
void foo() {
@ -1031,19 +1100,19 @@ TEST_F(FindExplicitReferencesTest, All) {
namespace $9^NS = $10^ns;
}
)cpp",
"0: targets = {Foo}, decl\n"
"1: targets = {foo()::Foo::Foo}, decl\n"
"2: targets = {Foo}\n"
"3: targets = {foo()::Foo::field}, decl\n"
"4: targets = {Var}, decl\n"
"5: targets = {E}, decl\n"
"6: targets = {foo()::ABC}, decl\n"
"7: targets = {INT}, decl\n"
"8: targets = {INT2}, decl\n"
"9: targets = {NS}, decl\n"
"10: targets = {ns}\n"},
// User-defined conversion operator.
{R"cpp(
"0: targets = {Foo}, decl\n"
"1: targets = {foo()::Foo::Foo}, decl\n"
"2: targets = {Foo}\n"
"3: targets = {foo()::Foo::field}, decl\n"
"4: targets = {Var}, decl\n"
"5: targets = {E}, decl\n"
"6: targets = {foo()::ABC}, decl\n"
"7: targets = {INT}, decl\n"
"8: targets = {INT2}, decl\n"
"9: targets = {NS}, decl\n"
"10: targets = {ns}\n"},
// User-defined conversion operator.
{R"cpp(
void foo() {
class $0^Bar {};
class $1^Foo {
@ -1056,18 +1125,18 @@ TEST_F(FindExplicitReferencesTest, All) {
$7^f.$8^operator $9^Bar();
}
)cpp",
"0: targets = {Bar}, decl\n"
"1: targets = {Foo}, decl\n"
"2: targets = {foo()::Foo::operator Bar}, decl\n"
"3: targets = {Bar}\n"
"4: targets = {Bar}\n"
"5: targets = {Foo}\n"
"6: targets = {f}, decl\n"
"7: targets = {f}\n"
"8: targets = {foo()::Foo::operator Bar}\n"
"9: targets = {Bar}\n"},
// Destructor.
{R"cpp(
"0: targets = {Bar}, decl\n"
"1: targets = {Foo}, decl\n"
"2: targets = {foo()::Foo::operator Bar}, decl\n"
"3: targets = {Bar}\n"
"4: targets = {Bar}\n"
"5: targets = {Foo}\n"
"6: targets = {f}, decl\n"
"7: targets = {f}\n"
"8: targets = {foo()::Foo::operator Bar}\n"
"9: targets = {Bar}\n"},
// Destructor.
{R"cpp(
void foo() {
class $0^Foo {
public:
@ -1082,18 +1151,18 @@ TEST_F(FindExplicitReferencesTest, All) {
$6^f.~ /*...*/ $7^Foo();
}
)cpp",
"0: targets = {Foo}, decl\n"
// FIXME: It's better to target destructor's FunctionDecl instead of
// the type itself (similar to constructor).
"1: targets = {Foo}\n"
"2: targets = {foo()::Foo::destructMe}, decl\n"
"3: targets = {Foo}\n"
"4: targets = {Foo}\n"
"5: targets = {f}, decl\n"
"6: targets = {f}\n"
"7: targets = {Foo}\n"},
// cxx constructor initializer.
{R"cpp(
"0: targets = {Foo}, decl\n"
// FIXME: It's better to target destructor's FunctionDecl instead of
// the type itself (similar to constructor).
"1: targets = {Foo}\n"
"2: targets = {foo()::Foo::destructMe}, decl\n"
"3: targets = {Foo}\n"
"4: targets = {Foo}\n"
"5: targets = {f}, decl\n"
"6: targets = {f}\n"
"7: targets = {Foo}\n"},
// cxx constructor initializer.
{R"cpp(
class Base {};
void foo() {
// member initializer
@ -1113,34 +1182,34 @@ TEST_F(FindExplicitReferencesTest, All) {
};
}
)cpp",
"0: targets = {X}, decl\n"
"1: targets = {foo()::X::abc}, decl\n"
"2: targets = {foo()::X::X}, decl\n"
"3: targets = {foo()::X::abc}\n"
"4: targets = {Derived}, decl\n"
"5: targets = {Base}\n"
"6: targets = {Base}\n"
"7: targets = {foo()::Derived::B}, decl\n"
"8: targets = {foo()::Derived::Derived}, decl\n"
"9: targets = {Base}\n"
"10: targets = {Foo}, decl\n"
"11: targets = {foo()::Foo::Foo}, decl\n"
"12: targets = {foo()::Foo::Foo}, decl\n"
"13: targets = {Foo}\n"},
// Anonymous entities should not be reported.
{
R"cpp(
"0: targets = {X}, decl\n"
"1: targets = {foo()::X::abc}, decl\n"
"2: targets = {foo()::X::X}, decl\n"
"3: targets = {foo()::X::abc}\n"
"4: targets = {Derived}, decl\n"
"5: targets = {Base}\n"
"6: targets = {Base}\n"
"7: targets = {foo()::Derived::B}, decl\n"
"8: targets = {foo()::Derived::Derived}, decl\n"
"9: targets = {Base}\n"
"10: targets = {Foo}, decl\n"
"11: targets = {foo()::Foo::Foo}, decl\n"
"12: targets = {foo()::Foo::Foo}, decl\n"
"13: targets = {Foo}\n"},
// Anonymous entities should not be reported.
{
R"cpp(
void foo() {
class {} $0^x;
int (*$1^fptr)(int $2^a, int) = nullptr;
}
)cpp",
"0: targets = {x}, decl\n"
"1: targets = {fptr}, decl\n"
"2: targets = {a}, decl\n"},
// Namespace aliases should be handled properly.
{
R"cpp(
"0: targets = {x}, decl\n"
"1: targets = {fptr}, decl\n"
"2: targets = {a}, decl\n"},
// Namespace aliases should be handled properly.
{
R"cpp(
namespace ns { struct Type {}; }
namespace alias = ns;
namespace rec_alias = alias;
@ -1151,28 +1220,28 @@ TEST_F(FindExplicitReferencesTest, All) {
$6^rec_alias::$7^Type $8^c;
}
)cpp",
"0: targets = {ns}\n"
"1: targets = {ns::Type}, qualifier = 'ns::'\n"
"2: targets = {a}, decl\n"
"3: targets = {alias}\n"
"4: targets = {ns::Type}, qualifier = 'alias::'\n"
"5: targets = {b}, decl\n"
"6: targets = {rec_alias}\n"
"7: targets = {ns::Type}, qualifier = 'rec_alias::'\n"
"8: targets = {c}, decl\n"},
// Handle SizeOfPackExpr.
{
R"cpp(
"0: targets = {ns}\n"
"1: targets = {ns::Type}, qualifier = 'ns::'\n"
"2: targets = {a}, decl\n"
"3: targets = {alias}\n"
"4: targets = {ns::Type}, qualifier = 'alias::'\n"
"5: targets = {b}, decl\n"
"6: targets = {rec_alias}\n"
"7: targets = {ns::Type}, qualifier = 'rec_alias::'\n"
"8: targets = {c}, decl\n"},
// Handle SizeOfPackExpr.
{
R"cpp(
template <typename... E>
void foo() {
constexpr int $0^size = sizeof...($1^E);
};
)cpp",
"0: targets = {size}, decl\n"
"1: targets = {E}\n"},
// Class template argument deduction
{
R"cpp(
"0: targets = {size}, decl\n"
"1: targets = {E}\n"},
// Class template argument deduction
{
R"cpp(
template <typename T>
struct Test {
Test(T);
@ -1181,51 +1250,51 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^Test $1^a(5);
}
)cpp",
"0: targets = {Test}\n"
"1: targets = {a}, decl\n"},
// Templates
{R"cpp(
"0: targets = {Test}\n"
"1: targets = {a}, decl\n"},
// Templates
{R"cpp(
namespace foo {
template <typename $0^T>
class $1^Bar {};
}
)cpp",
"0: targets = {foo::Bar::T}, decl\n"
"1: targets = {foo::Bar}, decl\n"},
// Templates
{R"cpp(
"0: targets = {foo::Bar::T}, decl\n"
"1: targets = {foo::Bar}, decl\n"},
// Templates
{R"cpp(
namespace foo {
template <typename $0^T>
void $1^func();
}
)cpp",
"0: targets = {T}, decl\n"
"1: targets = {foo::func}, decl\n"},
// Templates
{R"cpp(
"0: targets = {T}, decl\n"
"1: targets = {foo::func}, decl\n"},
// Templates
{R"cpp(
namespace foo {
template <typename $0^T>
$1^T $2^x;
}
)cpp",
"0: targets = {foo::T}, decl\n"
"1: targets = {foo::T}\n"
"2: targets = {foo::x}, decl\n"},
// Templates
{R"cpp(
"0: targets = {foo::T}, decl\n"
"1: targets = {foo::T}\n"
"2: targets = {foo::x}, decl\n"},
// Templates
{R"cpp(
template<typename T> class vector {};
namespace foo {
template <typename $0^T>
using $1^V = $2^vector<$3^T>;
}
)cpp",
"0: targets = {foo::T}, decl\n"
"1: targets = {foo::V}, decl\n"
"2: targets = {vector}\n"
"3: targets = {foo::T}\n"},
// Concept
{
R"cpp(
"0: targets = {foo::T}, decl\n"
"1: targets = {foo::V}, decl\n"
"2: targets = {vector}\n"
"3: targets = {foo::T}\n"},
// Concept
{
R"cpp(
template <typename T>
concept Drawable = requires (T t) { t.draw(); };
@ -1236,17 +1305,17 @@ TEST_F(FindExplicitReferencesTest, All) {
}
}
)cpp",
"0: targets = {T}, decl\n"
"1: targets = {Drawable}\n"
"2: targets = {T}\n"
"3: targets = {foo::bar}, decl\n"
"4: targets = {T}\n"
"5: targets = {t}, decl\n"
"6: targets = {t}\n"
"7: targets = {}\n"},
// Objective-C: properties
{
R"cpp(
"0: targets = {T}, decl\n"
"1: targets = {Drawable}\n"
"2: targets = {T}\n"
"3: targets = {foo::bar}, decl\n"
"4: targets = {T}\n"
"5: targets = {t}, decl\n"
"6: targets = {t}\n"
"7: targets = {}\n"},
// Objective-C: properties
{
R"cpp(
@interface I {}
@property(retain) I* x;
@property(retain) I* y;
@ -1256,12 +1325,12 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^f.$1^x.$2^y = 0;
}
)cpp",
"0: targets = {f}\n"
"1: targets = {I::x}\n"
"2: targets = {I::y}\n"},
// Objective-C: implicit properties
{
R"cpp(
"0: targets = {f}\n"
"1: targets = {I::x}\n"
"2: targets = {I::y}\n"},
// Objective-C: implicit properties
{
R"cpp(
@interface I {}
-(I*)x;
-(void)setY:(I*)y;
@ -1271,11 +1340,11 @@ TEST_F(FindExplicitReferencesTest, All) {
$0^f.$1^x.$2^y = 0;
}
)cpp",
"0: targets = {f}\n"
"1: targets = {I::x}\n"
"2: targets = {I::setY:}\n"},
// Designated initializers.
{R"cpp(
"0: targets = {f}\n"
"1: targets = {I::x}\n"
"2: targets = {I::setY:}\n"},
// Designated initializers.
{R"cpp(
void foo() {
struct $0^Foo {
int $1^Bar;
@ -1283,12 +1352,12 @@ TEST_F(FindExplicitReferencesTest, All) {
$2^Foo $3^f { .$4^Bar = 42 };
}
)cpp",
"0: targets = {Foo}, decl\n"
"1: targets = {foo()::Foo::Bar}, decl\n"
"2: targets = {Foo}\n"
"3: targets = {f}, decl\n"
"4: targets = {foo()::Foo::Bar}\n"},
{R"cpp(
"0: targets = {Foo}, decl\n"
"1: targets = {foo()::Foo::Bar}, decl\n"
"2: targets = {Foo}\n"
"3: targets = {f}, decl\n"
"4: targets = {foo()::Foo::Bar}\n"},
{R"cpp(
void foo() {
struct $0^Baz {
int $1^Field;