clang-tools-extra/clangd/unittests/SelectionTests.cpp - llvm-project - Git at Google

 //===-- SelectionTests.cpp - ----------------------------------------------===//
 //
 // 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 "Annotations.h"
 #include "Selection.h"
 #include "SourceCode.h"
 #include "TestTU.h"
 #include "support/TestTracer.h"
 #include "clang/AST/Decl.h"
 #include "llvm/Support/Casting.h"
 #include "gmock/gmock.h"
 #include "gtest/gtest.h"

 namespace clang {
 namespace clangd {
 namespace {
 using ::testing::ElementsAreArray;
 using ::testing::UnorderedElementsAreArray;

 // Create a selection tree corresponding to a point or pair of points.
 // This uses the precisely-defined createRight semantics. The fuzzier
 // createEach is tested separately.
 SelectionTree makeSelectionTree(const StringRef MarkedCode, ParsedAST &AST) {
   Annotations Test(MarkedCode);
   switch (Test.points().size()) {
   case 1: { // Point selection.
     unsigned Offset = cantFail(positionToOffset(Test.code(), Test.point()));
     return SelectionTree::createRight(AST.getASTContext(), AST.getTokens(),
                                       Offset, Offset);
   }
   case 2: // Range selection.
     return SelectionTree::createRight(
         AST.getASTContext(), AST.getTokens(),
         cantFail(positionToOffset(Test.code(), Test.points()[0])),
         cantFail(positionToOffset(Test.code(), Test.points()[1])));
   default:
     ADD_FAILURE() << "Expected 1-2 points for selection.\n" << MarkedCode;
     return SelectionTree::createRight(AST.getASTContext(), AST.getTokens(), 0u,
                                       0u);
   }
 }

 Range nodeRange(const SelectionTree::Node *N, ParsedAST &AST) {
   if (!N)
     return Range{};
   const SourceManager &SM = AST.getSourceManager();
   const LangOptions &LangOpts = AST.getLangOpts();
   StringRef Buffer = SM.getBufferData(SM.getMainFileID());
   if (llvm::isa_and_nonnull<TranslationUnitDecl>(N->ASTNode.get<Decl>()))
     return Range{Position{}, offsetToPosition(Buffer, Buffer.size())};
   auto FileRange =
       toHalfOpenFileRange(SM, LangOpts, N->ASTNode.getSourceRange());
   assert(FileRange && "We should be able to get the File Range");
   return Range{
       offsetToPosition(Buffer, SM.getFileOffset(FileRange->getBegin())),
       offsetToPosition(Buffer, SM.getFileOffset(FileRange->getEnd()))};
 }

 std::string nodeKind(const SelectionTree::Node *N) {
   return N ? N->kind() : "<null>";
 }

 std::vector<const SelectionTree::Node *> allNodes(const SelectionTree &T) {
   std::vector<const SelectionTree::Node *> Result = {&T.root()};
   for (unsigned I = 0; I < Result.size(); ++I) {
     const SelectionTree::Node *N = Result[I];
     Result.insert(Result.end(), N->Children.begin(), N->Children.end());
   }
   return Result;
 }

 // Returns true if Common is a descendent of Root.
 // Verifies nothing is selected above Common.
 bool verifyCommonAncestor(const SelectionTree::Node &Root,
                           const SelectionTree::Node *Common,
                           StringRef MarkedCode) {
   if (&Root == Common)
     return true;
   if (Root.Selected)
     ADD_FAILURE() << "Selected nodes outside common ancestor\n" << MarkedCode;
   bool Seen = false;
   for (const SelectionTree::Node *Child : Root.Children)
     if (verifyCommonAncestor(*Child, Common, MarkedCode)) {
       if (Seen)
         ADD_FAILURE() << "Saw common ancestor twice\n" << MarkedCode;
       Seen = true;
     }
   return Seen;
 }

 TEST(SelectionTest, CommonAncestor) {
   struct Case {
     // Selection is between ^marks^.
     // common ancestor marked with a [[range]].
     const char *Code;
     const char *CommonAncestorKind;
   };
   Case Cases[] = {
       {
           R"cpp(
             template <typename T>
             int x = [[T::^U::]]ccc();
           )cpp",
           "NestedNameSpecifierLoc",
       },
       {
           R"cpp(
             struct AAA { struct BBB { static int ccc(); };};
             int x = AAA::[[B^B^B]]::ccc();
           )cpp",
           "RecordTypeLoc",
       },
       {
           R"cpp(
             struct AAA { struct BBB { static int ccc(); };};
             int x = AAA::[[B^BB^]]::ccc();
           )cpp",
           "RecordTypeLoc",
       },
       {
           R"cpp(
             struct AAA { struct BBB { static int ccc(); };};
             int x = [[AAA::BBB::c^c^c]]();
           )cpp",
           "DeclRefExpr",
       },
       {
           R"cpp(
             struct AAA { struct BBB { static int ccc(); };};
             int x = [[AAA::BBB::cc^c(^)]];
           )cpp",
           "CallExpr",
       },

       {
           R"cpp(
             void foo() { [[if (1^11) { return; } else {^ }]] }
           )cpp",
           "IfStmt",
       },
       {
           R"cpp(
             int x(int);
             #define M(foo) x(foo)
             int a = 42;
             int b = M([[^a]]);
           )cpp",
           "DeclRefExpr",
       },
       {
           R"cpp(
             void foo();
             #define CALL_FUNCTION(X) X()
             void bar() { CALL_FUNCTION([[f^o^o]]); }
           )cpp",
           "DeclRefExpr",
       },
       {
           R"cpp(
             void foo();
             #define CALL_FUNCTION(X) X()
             void bar() { [[CALL_FUNC^TION(fo^o)]]; }
           )cpp",
           "CallExpr",
       },
       {
           R"cpp(
             void foo();
             #define CALL_FUNCTION(X) X()
             void bar() { [[C^ALL_FUNC^TION(foo)]]; }
           )cpp",
           "CallExpr",
       },
       {
           R"cpp(
             void foo();
             #^define CALL_FUNCTION(X) X(^)
             void bar() { CALL_FUNCTION(foo); }
           )cpp",
           nullptr,
       },
       {
           R"cpp(
             void foo();
             #define CALL_FUNCTION(X) X()
             void bar() { CALL_FUNCTION(foo^)^; }
           )cpp",
           nullptr,
       },
       {
           R"cpp(
             namespace ns {
             #if 0
             void fo^o() {}
             #endif
             }
           )cpp",
           nullptr,
       },
       {
           R"cpp(
             struct S { S(const char*); };
             S [[s ^= "foo"]];
           )cpp",
           "CXXConstructExpr",
       },
       {
           R"cpp(
             struct S { S(const char*); };
             [[S ^s = "foo"]];
           )cpp",
           "VarDecl",
       },
       {
           R"cpp(
             [[^void]] (*S)(int) = nullptr;
           )cpp",
           "BuiltinTypeLoc",
       },
       {
           R"cpp(
             [[void (*S)^(int)]] = nullptr;
           )cpp",
           "FunctionProtoTypeLoc",
       },
       {
           R"cpp(
             [[void (^*S)(int)]] = nullptr;
           )cpp",
           "FunctionProtoTypeLoc",
       },
       {
           R"cpp(
             [[void (*^S)(int) = nullptr]];
           )cpp",
           "VarDecl",
       },
       {
           R"cpp(
             [[void ^(*S)(int)]] = nullptr;
           )cpp",
           "FunctionProtoTypeLoc",
       },
       {
           R"cpp(
             struct S {
               int foo() const;
               int bar() { return [[f^oo]](); }
             };
           )cpp",
           "MemberExpr", // Not implicit CXXThisExpr, or its implicit cast!
       },
       {
           R"cpp(
             auto lambda = [](const char*){ return 0; };
             int x = lambda([["y^"]]);
           )cpp",
           "StringLiteral", // Not DeclRefExpr to operator()!
       },
       {
           R"cpp(
             struct Foo {};
             struct Bar : [[v^ir^tual private Foo]] {};
           )cpp",
           "CXXBaseSpecifier",
       },
       {
           R"cpp(
             struct Foo {};
             struct Bar : private [[Fo^o]] {};
           )cpp",
           "RecordTypeLoc",
       },
       {
           R"cpp(
             struct Foo {};
             struct Bar : [[Fo^o]] {};
           )cpp",
           "RecordTypeLoc",
       },

       // Point selections.
       {"void foo() { [[^foo]](); }", "DeclRefExpr"},
       {"void foo() { [[f^oo]](); }", "DeclRefExpr"},
       {"void foo() { [[fo^o]](); }", "DeclRefExpr"},
       {"void foo() { [[foo^()]]; }", "CallExpr"},
       {"void foo() { [[foo^]] (); }", "DeclRefExpr"},
       {"int bar; void foo() [[{ foo (); }]]^", "CompoundStmt"},
       {"int x = [[42]]^;", "IntegerLiteral"},

       // Ignores whitespace, comments, and semicolons in the selection.
       {"void foo() { [[foo^()]]; /*comment*/^}", "CallExpr"},

       // Tricky case: FunctionTypeLoc in FunctionDecl has a hole in it.
       {"[[^void]] foo();", "BuiltinTypeLoc"},
       {"[[void foo^()]];", "FunctionProtoTypeLoc"},
       {"[[^void foo^()]];", "FunctionDecl"},
       {"[[void ^foo()]];", "FunctionDecl"},
       // Tricky case: two VarDecls share a specifier.
       {"[[int ^a]], b;", "VarDecl"},
       {"[[int a, ^b]];", "VarDecl"},
       // Tricky case: CXXConstructExpr wants to claim the whole init range.
       {
           R"cpp(
             struct X { X(int); };
             class Y {
               X x;
               Y() : [[^x(4)]] {}
             };
           )cpp",
           "CXXCtorInitializer", // Not the CXXConstructExpr!
       },
       // Tricky case: anonymous struct is a sibling of the VarDecl.
       {"[[st^ruct {int x;}]] y;", "CXXRecordDecl"},
       {"[[struct {int x;} ^y]];", "VarDecl"},
       {"struct {[[int ^x]];} y;", "FieldDecl"},
       // FIXME: the AST has no location info for qualifiers.
       {"const [[a^uto]] x = 42;", "AutoTypeLoc"},
       {"[[co^nst auto x = 42]];", "VarDecl"},

       {"^", nullptr},
       {"void foo() { [[foo^^]] (); }", "DeclRefExpr"},

       // FIXME: Ideally we'd get a declstmt or the VarDecl itself here.
       // This doesn't happen now; the RAV doesn't traverse a node containing ;.
       {"int x = 42;^", nullptr},

       // Common ancestor is logically TUDecl, but we never return that.
       {"^int x; int y;^", nullptr},

       // Node types that have caused problems in the past.
       {"template <typename T> void foo() { [[^T]] t; }",
        "TemplateTypeParmTypeLoc"},

       // No crash
       {
           R"cpp(
             template <class T> struct Foo {};
             template <[[template<class> class /*cursor here*/^U]]>
              struct Foo<U<int>*> {};
           )cpp",
           "TemplateTemplateParmDecl"},

       // Foreach has a weird AST, ensure we can select parts of the range init.
       // This used to fail, because the DeclStmt for C claimed the whole range.
       {
           R"cpp(
             struct Str {
               const char *begin();
               const char *end();
             };
             Str makeStr(const char*);
             void loop() {
               for (const char C : [[mak^eStr("foo"^)]])
                 ;
             }
           )cpp",
           "CallExpr"},

       // User-defined literals are tricky: is 12_i one token or two?
       // For now we treat it as one, and the UserDefinedLiteral as a leaf.
       {
           R"cpp(
             struct Foo{};
             Foo operator""_ud(unsigned long long);
             Foo x = [[^12_ud]];
           )cpp",
           "UserDefinedLiteral"},

       {
           R"cpp(
         int a;
         decltype([[^a]] + a) b;
         )cpp",
           "DeclRefExpr"},

       // Objective-C nullability attributes.
       {
           R"cpp(
             @interface I{}
             @property(nullable) [[^I]] *x;
             @end
           )cpp",
           "ObjCInterfaceTypeLoc"},
       {
           R"cpp(
             @interface I{}
             - (void)doSomething:(nonnull [[i^d]])argument;
             @end
           )cpp",
           "TypedefTypeLoc"},

       // Objective-C OpaqueValueExpr/PseudoObjectExpr has weird ASTs.
       // Need to traverse the contents of the OpaqueValueExpr to the POE,
       // and ensure we traverse only the syntactic form of the PseudoObjectExpr.
       {
           R"cpp(
             @interface I{}
             @property(retain) I*x;
             @property(retain) I*y;
             @end
             void test(I *f) { [[^f]].x.y = 0; }
           )cpp",
           "DeclRefExpr"},
       {
           R"cpp(
             @interface I{}
             @property(retain) I*x;
             @property(retain) I*y;
             @end
             void test(I *f) { [[f.^x]].y = 0; }
           )cpp",
           "ObjCPropertyRefExpr"},
       // Examples with implicit properties.
       {
           R"cpp(
             @interface I{}
             -(int)foo;
             @end
             int test(I *f) { return 42 + [[^f]].foo; }
           )cpp",
           "DeclRefExpr"},
       {
           R"cpp(
             @interface I{}
             -(int)foo;
             @end
             int test(I *f) { return 42 + [[f.^foo]]; }
           )cpp",
           "ObjCPropertyRefExpr"},
       {"struct foo { [[int has^h<:32:>]]; };", "FieldDecl"},
       {"struct foo { [[op^erator int()]]; };", "CXXConversionDecl"},
       {"struct foo { [[^~foo()]]; };", "CXXDestructorDecl"},
       // FIXME: The following to should be class itself instead.
       {"struct foo { [[fo^o(){}]] };", "CXXConstructorDecl"},

       {R"cpp(
         struct S1 { void f(); };
         struct S2 { S1 * operator->(); };
         void test(S2 s2) {
           s2[[-^>]]f();
         }
       )cpp",
        "DeclRefExpr"}, // DeclRefExpr to the "operator->" method.

       // Template template argument.
       {R"cpp(
         template <typename> class Vector {};
         template <template <typename> class Container> class A {};
         A<[[V^ector]]> a;
       )cpp",
        "TemplateArgumentLoc"},

       // Attributes
       {R"cpp(
         void f(int * __attribute__(([[no^nnull]])) );
       )cpp",
        "NonNullAttr"},

       {R"cpp(
         // Digraph syntax for attributes to avoid accidental annotations.
         class <:[gsl::Owner([[in^t]])]:> X{};
       )cpp",
        "BuiltinTypeLoc"},

       // This case used to crash - AST has a null Attr
       {R"cpp(
         @interface I
         [[@property(retain, nonnull) <:[My^Object2]:> *x]]; // error-ok
         @end
       )cpp",
        "ObjCPropertyDecl"},

       {R"cpp(
         typedef int Foo;
         enum Bar : [[Fo^o]] {};
       )cpp",
        "TypedefTypeLoc"},
       {R"cpp(
         typedef int Foo;
         enum Bar : [[Fo^o]];
       )cpp",
        "TypedefTypeLoc"},
   };

   for (const Case &C : Cases) {
     trace::TestTracer Tracer;
     Annotations Test(C.Code);

     TestTU TU;
     TU.Code = std::string(Test.code());

     TU.ExtraArgs.push_back("-xobjective-c++");

     auto AST = TU.build();
     auto T = makeSelectionTree(C.Code, AST);
     EXPECT_EQ("TranslationUnitDecl", nodeKind(&T.root())) << C.Code;

     if (Test.ranges().empty()) {
       // If no [[range]] is marked in the example, there should be no selection.
       EXPECT_FALSE(T.commonAncestor()) << C.Code << "\n" << T;
       EXPECT_THAT(Tracer.takeMetric("selection_recovery", "C++"),
                   testing::IsEmpty());
     } else {
       // If there is an expected selection, common ancestor should exist
       // with the appropriate node type.
       EXPECT_EQ(C.CommonAncestorKind, nodeKind(T.commonAncestor()))
           << C.Code << "\n"
           << T;
       // Convert the reported common ancestor to a range and verify it.
       EXPECT_EQ(nodeRange(T.commonAncestor(), AST), Test.range())
           << C.Code << "\n"
           << T;

       // Check that common ancestor is reachable on exactly one path from root,
       // and no nodes outside it are selected.
       EXPECT_TRUE(verifyCommonAncestor(T.root(), T.commonAncestor(), C.Code))
           << C.Code;
       EXPECT_THAT(Tracer.takeMetric("selection_recovery", "C++"),
                   ElementsAreArray({0}));
     }
   }
 }

 // Regression test: this used to match the injected X, not the outer X.
 TEST(SelectionTest, InjectedClassName) {
   const char *Code = "struct ^X { int x; };";
   auto AST = TestTU::withCode(Annotations(Code).code()).build();
   auto T = makeSelectionTree(Code, AST);
   ASSERT_EQ("CXXRecordDecl", nodeKind(T.commonAncestor())) << T;
   auto *D = dyn_cast<CXXRecordDecl>(T.commonAncestor()->ASTNode.get<Decl>());
   EXPECT_FALSE(D->isInjectedClassName());
 }

 TEST(SelectionTree, Metrics) {
   const char *Code = R"cpp(
     // error-ok: testing behavior on recovery expression
     int foo();
     int foo(int, int);
     int x = fo^o(42);
   )cpp";
   auto AST = TestTU::withCode(Annotations(Code).code()).build();
   trace::TestTracer Tracer;
   auto T = makeSelectionTree(Code, AST);
   EXPECT_THAT(Tracer.takeMetric("selection_recovery", "C++"),
               ElementsAreArray({1}));
   EXPECT_THAT(Tracer.takeMetric("selection_recovery_type", "C++"),
               ElementsAreArray({1}));
 }

 // FIXME: Doesn't select the binary operator node in
 //          #define FOO(X) X + 1
 //          int a, b = [[FOO(a)]];
 TEST(SelectionTest, Selected) {
   // Selection with ^marks^.
   // Partially selected nodes marked with a [[range]].
   // Completely selected nodes marked with a $C[[range]].
   const char *Cases[] = {
       R"cpp( int abc, xyz = [[^ab^c]]; )cpp",
       R"cpp( int abc, xyz = [[a^bc^]]; )cpp",
       R"cpp( int abc, xyz = $C[[^abc^]]; )cpp",
       R"cpp(
         void foo() {
           [[if ([[1^11]]) $C[[{
             $C[[return]];
           }]] else [[{^
           }]]]]
           char z;
         }
       )cpp",
       R"cpp(
           template <class T>
           struct unique_ptr {};
           void foo(^$C[[unique_ptr<$C[[unique_ptr<$C[[int]]>]]>]]^ a) {}
       )cpp",
       R"cpp(int a = [[5 >^> 1]];)cpp",
       R"cpp(
         #define ECHO(X) X
         ECHO(EC^HO($C[[int]]) EC^HO(a));
       )cpp",
       R"cpp( $C[[^$C[[int]] a^]]; )cpp",
       R"cpp( $C[[^$C[[int]] a = $C[[5]]^]]; )cpp",
   };
   for (const char *C : Cases) {
     Annotations Test(C);
     auto AST = TestTU::withCode(Test.code()).build();
     auto T = makeSelectionTree(C, AST);

     std::vector<Range> Complete, Partial;
     for (const SelectionTree::Node *N : allNodes(T))
       if (N->Selected == SelectionTree::Complete)
         Complete.push_back(nodeRange(N, AST));
       else if (N->Selected == SelectionTree::Partial)
         Partial.push_back(nodeRange(N, AST));
     EXPECT_THAT(Complete, UnorderedElementsAreArray(Test.ranges("C"))) << C;
     EXPECT_THAT(Partial, UnorderedElementsAreArray(Test.ranges())) << C;
   }
 }

 TEST(SelectionTest, PathologicalPreprocessor) {
   const char *Case = R"cpp(
 #define MACRO while(1)
     void test() {
 #include "Expand.inc"
         br^eak;
     }
   )cpp";
   Annotations Test(Case);
   auto TU = TestTU::withCode(Test.code());
   TU.AdditionalFiles["Expand.inc"] = "MACRO\n";
   auto AST = TU.build();
   EXPECT_THAT(*AST.getDiagnostics(), ::testing::IsEmpty());
   auto T = makeSelectionTree(Case, AST);

   EXPECT_EQ("BreakStmt", T.commonAncestor()->kind());
   EXPECT_EQ("WhileStmt", T.commonAncestor()->Parent->kind());
 }

 TEST(SelectionTest, IncludedFile) {
   const char *Case = R"cpp(
     void test() {
 #include "Exp^and.inc"
         break;
     }
   )cpp";
   Annotations Test(Case);
   auto TU = TestTU::withCode(Test.code());
   TU.AdditionalFiles["Expand.inc"] = "while(1)\n";
   auto AST = TU.build();
   auto T = makeSelectionTree(Case, AST);

   EXPECT_EQ(nullptr, T.commonAncestor());
 }

 TEST(SelectionTest, MacroArgExpansion) {
   // If a macro arg is expanded several times, we only consider the first one
   // selected.
   const char *Case = R"cpp(
     int mul(int, int);
     #define SQUARE(X) mul(X, X);
     int nine = SQUARE(^3);
   )cpp";
   Annotations Test(Case);
   auto AST = TestTU::withCode(Test.code()).build();
   auto T = makeSelectionTree(Case, AST);
   EXPECT_EQ("IntegerLiteral", T.commonAncestor()->kind());
   EXPECT_TRUE(T.commonAncestor()->Selected);

   // Verify that the common assert() macro doesn't suffer from this.
   // (This is because we don't associate the stringified token with the arg).
   Case = R"cpp(
     void die(const char*);
     #define assert(x) (x ? (void)0 : die(#x))
     void foo() { assert(^42); }
   )cpp";
   Test = Annotations(Case);
   AST = TestTU::withCode(Test.code()).build();
   T = makeSelectionTree(Case, AST);

   EXPECT_EQ("IntegerLiteral", T.commonAncestor()->kind());
 }

 TEST(SelectionTest, Implicit) {
   const char *Test = R"cpp(
     struct S { S(const char*); };
     int f(S);
     int x = f("^");
   )cpp";
   auto AST = TestTU::withCode(Annotations(Test).code()).build();
   auto T = makeSelectionTree(Test, AST);

   const SelectionTree::Node *Str = T.commonAncestor();
   EXPECT_EQ("StringLiteral", nodeKind(Str)) << "Implicit selected?";
   EXPECT_EQ("ImplicitCastExpr", nodeKind(Str->Parent));
   EXPECT_EQ("CXXConstructExpr", nodeKind(Str->Parent->Parent));
   EXPECT_EQ(Str, &Str->Parent->Parent->ignoreImplicit())
       << "Didn't unwrap " << nodeKind(&Str->Parent->Parent->ignoreImplicit());

   EXPECT_EQ("CXXConstructExpr", nodeKind(&Str->outerImplicit()));
 }

 TEST(SelectionTest, CreateAll) {
   llvm::Annotations Test("int$unique^ a=1$ambiguous^+1; $empty^");
   auto AST = TestTU::withCode(Test.code()).build();
   unsigned Seen = 0;
   SelectionTree::createEach(
       AST.getASTContext(), AST.getTokens(), Test.point("ambiguous"),
       Test.point("ambiguous"), [&](SelectionTree T) {
         // Expect to see the right-biased tree first.
         if (Seen == 0) {
           EXPECT_EQ("BinaryOperator", nodeKind(T.commonAncestor()));
         } else if (Seen == 1) {
           EXPECT_EQ("IntegerLiteral", nodeKind(T.commonAncestor()));
         }
         ++Seen;
         return false;
       });
   EXPECT_EQ(2u, Seen);

   Seen = 0;
   SelectionTree::createEach(AST.getASTContext(), AST.getTokens(),
                             Test.point("ambiguous"), Test.point("ambiguous"),
                             [&](SelectionTree T) {
                               ++Seen;
                               return true;
                             });
   EXPECT_EQ(1u, Seen) << "Return true --> stop iterating";

   Seen = 0;
   SelectionTree::createEach(AST.getASTContext(), AST.getTokens(),
                             Test.point("unique"), Test.point("unique"),
                             [&](SelectionTree T) {
                               ++Seen;
                               return false;
                             });
   EXPECT_EQ(1u, Seen) << "no ambiguity --> only one tree";

   Seen = 0;
   SelectionTree::createEach(AST.getASTContext(), AST.getTokens(),
                             Test.point("empty"), Test.point("empty"),
                             [&](SelectionTree T) {
                               EXPECT_FALSE(T.commonAncestor());
                               ++Seen;
                               return false;
                             });
   EXPECT_EQ(1u, Seen) << "empty tree still created";

   Seen = 0;
   SelectionTree::createEach(AST.getASTContext(), AST.getTokens(),
                             Test.point("unique"), Test.point("ambiguous"),
                             [&](SelectionTree T) {
                               ++Seen;
                               return false;
                             });
   EXPECT_EQ(1u, Seen) << "one tree for nontrivial selection";
 }

 TEST(SelectionTest, DeclContextIsLexical) {
   llvm::Annotations Test("namespace a { void $1^foo(); } void a::$2^foo();");
   auto AST = TestTU::withCode(Test.code()).build();
   {
     auto ST = SelectionTree::createRight(AST.getASTContext(), AST.getTokens(),
                                          Test.point("1"), Test.point("1"));
     EXPECT_FALSE(ST.commonAncestor()->getDeclContext().isTranslationUnit());
   }
   {
     auto ST = SelectionTree::createRight(AST.getASTContext(), AST.getTokens(),
                                          Test.point("2"), Test.point("2"));
     EXPECT_TRUE(ST.commonAncestor()->getDeclContext().isTranslationUnit());
   }
 }

 } // namespace
 } // namespace clangd
 } // namespace clang
	//===-- SelectionTests.cpp - ----------------------------------------------===//
	//
	// 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 "Annotations.h"
	#include "Selection.h"
	#include "SourceCode.h"
	#include "TestTU.h"
	#include "support/TestTracer.h"
	#include "clang/AST/Decl.h"
	#include "llvm/Support/Casting.h"
	#include "gmock/gmock.h"
	#include "gtest/gtest.h"

	namespace clang {
	namespace clangd {
	namespace {
	using ::testing::ElementsAreArray;
	using ::testing::UnorderedElementsAreArray;

	// Create a selection tree corresponding to a point or pair of points.
	// This uses the precisely-defined createRight semantics. The fuzzier
	// createEach is tested separately.
	SelectionTree makeSelectionTree(const StringRef MarkedCode, ParsedAST &AST) {
	Annotations Test(MarkedCode);
	switch (Test.points().size()) {
	case 1: { // Point selection.
	unsigned Offset = cantFail(positionToOffset(Test.code(), Test.point()));
	return SelectionTree::createRight(AST.getASTContext(), AST.getTokens(),
	Offset, Offset);
	}
	case 2: // Range selection.
	return SelectionTree::createRight(
	AST.getASTContext(), AST.getTokens(),
	cantFail(positionToOffset(Test.code(), Test.points()[0])),
	cantFail(positionToOffset(Test.code(), Test.points()[1])));
	default:
	ADD_FAILURE() << "Expected 1-2 points for selection.\n" << MarkedCode;
	return SelectionTree::createRight(AST.getASTContext(), AST.getTokens(), 0u,
	0u);
	}
	}

	Range nodeRange(const SelectionTree::Node *N, ParsedAST &AST) {
	if (!N)
	return Range{};
	const SourceManager &SM = AST.getSourceManager();
	const LangOptions &LangOpts = AST.getLangOpts();
	StringRef Buffer = SM.getBufferData(SM.getMainFileID());
	if (llvm::isa_and_nonnull<TranslationUnitDecl>(N->ASTNode.get<Decl>()))
	return Range{Position{}, offsetToPosition(Buffer, Buffer.size())};
	auto FileRange =
	toHalfOpenFileRange(SM, LangOpts, N->ASTNode.getSourceRange());
	assert(FileRange && "We should be able to get the File Range");
	return Range{
	offsetToPosition(Buffer, SM.getFileOffset(FileRange->getBegin())),
	offsetToPosition(Buffer, SM.getFileOffset(FileRange->getEnd()))};
	}

	std::string nodeKind(const SelectionTree::Node *N) {
	return N ? N->kind() : "<null>";
	}

	std::vector<const SelectionTree::Node *> allNodes(const SelectionTree &T) {
	std::vector<const SelectionTree::Node *> Result = {&T.root()};
	for (unsigned I = 0; I < Result.size(); ++I) {
	const SelectionTree::Node *N = Result[I];
	Result.insert(Result.end(), N->Children.begin(), N->Children.end());
	}
	return Result;
	}

	// Returns true if Common is a descendent of Root.
	// Verifies nothing is selected above Common.
	bool verifyCommonAncestor(const SelectionTree::Node &Root,
	const SelectionTree::Node *Common,
	StringRef MarkedCode) {
	if (&Root == Common)
	return true;
	if (Root.Selected)
	ADD_FAILURE() << "Selected nodes outside common ancestor\n" << MarkedCode;
	bool Seen = false;
	for (const SelectionTree::Node *Child : Root.Children)
	if (verifyCommonAncestor(*Child, Common, MarkedCode)) {
	if (Seen)
	ADD_FAILURE() << "Saw common ancestor twice\n" << MarkedCode;
	Seen = true;
	}
	return Seen;
	}

	TEST(SelectionTest, CommonAncestor) {
	struct Case {
	// Selection is between ^marks^.
	// common ancestor marked with a [[range]].
	const char *Code;
	const char *CommonAncestorKind;
	};
	Case Cases[] = {
	{
	R"cpp(
	template <typename T>
	int x = [[T::^U::]]ccc();
	)cpp",
	"NestedNameSpecifierLoc",
	},
	{
	R"cpp(
	struct AAA { struct BBB { static int ccc(); };};
	int x = AAA::[[B^B^B]]::ccc();
	)cpp",
	"RecordTypeLoc",
	},
	{
	R"cpp(
	struct AAA { struct BBB { static int ccc(); };};
	int x = AAA::[[B^BB^]]::ccc();
	)cpp",
	"RecordTypeLoc",
	},
	{
	R"cpp(
	struct AAA { struct BBB { static int ccc(); };};
	int x = [[AAA::BBB::c^c^c]]();
	)cpp",
	"DeclRefExpr",
	},
	{
	R"cpp(
	struct AAA { struct BBB { static int ccc(); };};
	int x = [[AAA::BBB::cc^c(^)]];
	)cpp",
	"CallExpr",
	},

	{
	R"cpp(
	void foo() { [[if (1^11) { return; } else {^ }]] }
	)cpp",
	"IfStmt",
	},
	{
	R"cpp(
	int x(int);
	#define M(foo) x(foo)
	int a = 42;
	int b = M([[^a]]);
	)cpp",
	"DeclRefExpr",
	},
	{
	R"cpp(
	void foo();
	#define CALL_FUNCTION(X) X()
	void bar() { CALL_FUNCTION([[f^o^o]]); }
	)cpp",
	"DeclRefExpr",
	},
	{
	R"cpp(
	void foo();
	#define CALL_FUNCTION(X) X()
	void bar() { [[CALL_FUNC^TION(fo^o)]]; }
	)cpp",
	"CallExpr",
	},
	{
	R"cpp(
	void foo();
	#define CALL_FUNCTION(X) X()
	void bar() { [[C^ALL_FUNC^TION(foo)]]; }
	)cpp",
	"CallExpr",
	},
	{
	R"cpp(
	void foo();
	#^define CALL_FUNCTION(X) X(^)
	void bar() { CALL_FUNCTION(foo); }
	)cpp",
	nullptr,
	},
	{
	R"cpp(
	void foo();
	#define CALL_FUNCTION(X) X()
	void bar() { CALL_FUNCTION(foo^)^; }
	)cpp",
	nullptr,
	},
	{
	R"cpp(
	namespace ns {
	#if 0
	void fo^o() {}
	#endif
	}
	)cpp",
	nullptr,
	},
	{
	R"cpp(
	struct S { S(const char*); };
	S [[s ^= "foo"]];
	)cpp",
	"CXXConstructExpr",
	},
	{
	R"cpp(
	struct S { S(const char*); };
	[[S ^s = "foo"]];
	)cpp",
	"VarDecl",
	},
	{
	R"cpp(
	[[^void]] (*S)(int) = nullptr;
	)cpp",
	"BuiltinTypeLoc",
	},
	{
	R"cpp(
	[[void (*S)^(int)]] = nullptr;
	)cpp",
	"FunctionProtoTypeLoc",
	},
	{
	R"cpp(
	[[void (^*S)(int)]] = nullptr;
	)cpp",
	"FunctionProtoTypeLoc",
	},
	{
	R"cpp(
	[[void (*^S)(int) = nullptr]];
	)cpp",
	"VarDecl",
	},
	{
	R"cpp(
	[[void ^(*S)(int)]] = nullptr;
	)cpp",
	"FunctionProtoTypeLoc",
	},
	{
	R"cpp(
	struct S {
	int foo() const;
	int bar() { return [[f^oo]](); }
	};
	)cpp",
	"MemberExpr", // Not implicit CXXThisExpr, or its implicit cast!
	},
	{
	R"cpp(
	auto lambda = [](const char*){ return 0; };
	int x = lambda([["y^"]]);
	)cpp",
	"StringLiteral", // Not DeclRefExpr to operator()!
	},
	{
	R"cpp(
	struct Foo {};
	struct Bar : [[v^ir^tual private Foo]] {};
	)cpp",
	"CXXBaseSpecifier",
	},
	{
	R"cpp(
	struct Foo {};
	struct Bar : private [[Fo^o]] {};
	)cpp",
	"RecordTypeLoc",
	},
	{
	R"cpp(
	struct Foo {};
	struct Bar : [[Fo^o]] {};
	)cpp",
	"RecordTypeLoc",
	},

	// Point selections.
	{"void foo() { [[^foo]](); }", "DeclRefExpr"},
	{"void foo() { [[f^oo]](); }", "DeclRefExpr"},
	{"void foo() { [[fo^o]](); }", "DeclRefExpr"},
	{"void foo() { [[foo^()]]; }", "CallExpr"},
	{"void foo() { [[foo^]] (); }", "DeclRefExpr"},
	{"int bar; void foo() [[{ foo (); }]]^", "CompoundStmt"},
	{"int x = [[42]]^;", "IntegerLiteral"},

	// Ignores whitespace, comments, and semicolons in the selection.
	{"void foo() { [[foo^()]]; /comment/^}", "CallExpr"},

	// Tricky case: FunctionTypeLoc in FunctionDecl has a hole in it.
	{"[[^void]] foo();", "BuiltinTypeLoc"},
	{"[[void foo^()]];", "FunctionProtoTypeLoc"},
	{"[[^void foo^()]];", "FunctionDecl"},
	{"[[void ^foo()]];", "FunctionDecl"},
	// Tricky case: two VarDecls share a specifier.
	{"[[int ^a]], b;", "VarDecl"},
	{"[[int a, ^b]];", "VarDecl"},
	// Tricky case: CXXConstructExpr wants to claim the whole init range.
	{
	R"cpp(
	struct X { X(int); };
	class Y {
	X x;
	Y() : [[^x(4)]] {}
	};
	)cpp",
	"CXXCtorInitializer", // Not the CXXConstructExpr!
	},
	// Tricky case: anonymous struct is a sibling of the VarDecl.
	{"[[st^ruct {int x;}]] y;", "CXXRecordDecl"},
	{"[[struct {int x;} ^y]];", "VarDecl"},
	{"struct {[[int ^x]];} y;", "FieldDecl"},
	// FIXME: the AST has no location info for qualifiers.
	{"const [[a^uto]] x = 42;", "AutoTypeLoc"},
	{"[[co^nst auto x = 42]];", "VarDecl"},

	{"^", nullptr},
	{"void foo() { [[foo^^]] (); }", "DeclRefExpr"},

	// FIXME: Ideally we'd get a declstmt or the VarDecl itself here.
	// This doesn't happen now; the RAV doesn't traverse a node containing ;.
	{"int x = 42;^", nullptr},

	// Common ancestor is logically TUDecl, but we never return that.
	{"^int x; int y;^", nullptr},

	// Node types that have caused problems in the past.
	{"template <typename T> void foo() { [[^T]] t; }",
	"TemplateTypeParmTypeLoc"},

	// No crash
	{
	R"cpp(
	template <class T> struct Foo {};
	template <[[template<class> class /cursor here/^U]]>
	struct Foo<U<int>*> {};
	)cpp",
	"TemplateTemplateParmDecl"},

	// Foreach has a weird AST, ensure we can select parts of the range init.
	// This used to fail, because the DeclStmt for C claimed the whole range.
	{
	R"cpp(
	struct Str {
	const char *begin();
	const char *end();
	};
	Str makeStr(const char*);
	void loop() {
	for (const char C : [[mak^eStr("foo"^)]])
	;
	}
	)cpp",
	"CallExpr"},

	// User-defined literals are tricky: is 12_i one token or two?
	// For now we treat it as one, and the UserDefinedLiteral as a leaf.
	{
	R"cpp(
	struct Foo{};
	Foo operator""_ud(unsigned long long);
	Foo x = [[^12_ud]];
	)cpp",
	"UserDefinedLiteral"},

	{
	R"cpp(
	int a;
	decltype([[^a]] + a) b;
	)cpp",
	"DeclRefExpr"},

	// Objective-C nullability attributes.
	{
	R"cpp(
	@interface I{}
	@property(nullable) [[^I]] *x;
	@end
	)cpp",
	"ObjCInterfaceTypeLoc"},
	{
	R"cpp(
	@interface I{}
	- (void)doSomething:(nonnull [[i^d]])argument;
	@end
	)cpp",
	"TypedefTypeLoc"},

	// Objective-C OpaqueValueExpr/PseudoObjectExpr has weird ASTs.
	// Need to traverse the contents of the OpaqueValueExpr to the POE,
	// and ensure we traverse only the syntactic form of the PseudoObjectExpr.
	{
	R"cpp(
	@interface I{}
	@property(retain) I*x;
	@property(retain) I*y;
	@end
	void test(I *f) { [[^f]].x.y = 0; }
	)cpp",
	"DeclRefExpr"},
	{
	R"cpp(
	@interface I{}
	@property(retain) I*x;
	@property(retain) I*y;
	@end
	void test(I *f) { [[f.^x]].y = 0; }
	)cpp",
	"ObjCPropertyRefExpr"},
	// Examples with implicit properties.
	{
	R"cpp(
	@interface I{}
	-(int)foo;
	@end
	int test(I *f) { return 42 + [[^f]].foo; }
	)cpp",
	"DeclRefExpr"},
	{
	R"cpp(
	@interface I{}
	-(int)foo;
	@end
	int test(I *f) { return 42 + [[f.^foo]]; }
	)cpp",
	"ObjCPropertyRefExpr"},
	{"struct foo { [[int has^h<:32:>]]; };", "FieldDecl"},
	{"struct foo { [[op^erator int()]]; };", "CXXConversionDecl"},
	{"struct foo { [[^~foo()]]; };", "CXXDestructorDecl"},
	// FIXME: The following to should be class itself instead.
	{"struct foo { [[fo^o(){}]] };", "CXXConstructorDecl"},

	{R"cpp(
	struct S1 { void f(); };
	struct S2 { S1 * operator->(); };
	void test(S2 s2) {
	s2[[-^>]]f();
	}
	)cpp",
	"DeclRefExpr"}, // DeclRefExpr to the "operator->" method.

	// Template template argument.
	{R"cpp(
	template <typename> class Vector {};
	template <template <typename> class Container> class A {};
	A<[[V^ector]]> a;
	)cpp",
	"TemplateArgumentLoc"},

	// Attributes
	{R"cpp(
	void f(int * __attribute__(([[no^nnull]])) );
	)cpp",
	"NonNullAttr"},

	{R"cpp(
	// Digraph syntax for attributes to avoid accidental annotations.
	class <:[gsl::Owner([[in^t]])]:> X{};
	)cpp",
	"BuiltinTypeLoc"},

	// This case used to crash - AST has a null Attr
	{R"cpp(
	@interface I
	[[@property(retain, nonnull) <:[My^Object2]:> *x]]; // error-ok
	@end
	)cpp",
	"ObjCPropertyDecl"},

	{R"cpp(
	typedef int Foo;
	enum Bar : [[Fo^o]] {};
	)cpp",
	"TypedefTypeLoc"},
	{R"cpp(
	typedef int Foo;
	enum Bar : [[Fo^o]];
	)cpp",
	"TypedefTypeLoc"},
	};

	for (const Case &C : Cases) {
	trace::TestTracer Tracer;
	Annotations Test(C.Code);

	TestTU TU;
	TU.Code = std::string(Test.code());

	TU.ExtraArgs.push_back("-xobjective-c++");

	auto AST = TU.build();
	auto T = makeSelectionTree(C.Code, AST);
	EXPECT_EQ("TranslationUnitDecl", nodeKind(&T.root())) << C.Code;

	if (Test.ranges().empty()) {
	// If no [[range]] is marked in the example, there should be no selection.
	EXPECT_FALSE(T.commonAncestor()) << C.Code << "\n" << T;
	EXPECT_THAT(Tracer.takeMetric("selection_recovery", "C++"),
	testing::IsEmpty());
	} else {
	// If there is an expected selection, common ancestor should exist
	// with the appropriate node type.
	EXPECT_EQ(C.CommonAncestorKind, nodeKind(T.commonAncestor()))
	<< C.Code << "\n"
	<< T;
	// Convert the reported common ancestor to a range and verify it.
	EXPECT_EQ(nodeRange(T.commonAncestor(), AST), Test.range())
	<< C.Code << "\n"
	<< T;

	// Check that common ancestor is reachable on exactly one path from root,
	// and no nodes outside it are selected.
	EXPECT_TRUE(verifyCommonAncestor(T.root(), T.commonAncestor(), C.Code))
	<< C.Code;
	EXPECT_THAT(Tracer.takeMetric("selection_recovery", "C++"),
	ElementsAreArray({0}));
	}
	}
	}

	// Regression test: this used to match the injected X, not the outer X.
	TEST(SelectionTest, InjectedClassName) {
	const char *Code = "struct ^X { int x; };";
	auto AST = TestTU::withCode(Annotations(Code).code()).build();
	auto T = makeSelectionTree(Code, AST);
	ASSERT_EQ("CXXRecordDecl", nodeKind(T.commonAncestor())) << T;
	auto *D = dyn_cast<CXXRecordDecl>(T.commonAncestor()->ASTNode.get<Decl>());
	EXPECT_FALSE(D->isInjectedClassName());
	}

	TEST(SelectionTree, Metrics) {
	const char *Code = R"cpp(
	// error-ok: testing behavior on recovery expression
	int foo();
	int foo(int, int);
	int x = fo^o(42);
	)cpp";
	auto AST = TestTU::withCode(Annotations(Code).code()).build();
	trace::TestTracer Tracer;
	auto T = makeSelectionTree(Code, AST);
	EXPECT_THAT(Tracer.takeMetric("selection_recovery", "C++"),
	ElementsAreArray({1}));
	EXPECT_THAT(Tracer.takeMetric("selection_recovery_type", "C++"),
	ElementsAreArray({1}));
	}

	// FIXME: Doesn't select the binary operator node in
	// #define FOO(X) X + 1
	// int a, b = [[FOO(a)]];
	TEST(SelectionTest, Selected) {
	// Selection with ^marks^.
	// Partially selected nodes marked with a [[range]].
	// Completely selected nodes marked with a $C[[range]].
	const char *Cases[] = {
	R"cpp( int abc, xyz = [[^ab^c]]; )cpp",
	R"cpp( int abc, xyz = [[a^bc^]]; )cpp",
	R"cpp( int abc, xyz = $C[[^abc^]]; )cpp",
	R"cpp(
	void foo() {
	[[if ([[1^11]]) $C[[{
	$C[[return]];
	}]] else [[{^
	}]]]]
	char z;
	}
	)cpp",
	R"cpp(
	template <class T>
	struct unique_ptr {};
	void foo(^$C[[unique_ptr<$C[[unique_ptr<$C[[int]]>]]>]]^ a) {}
	)cpp",
	R"cpp(int a = [[5 >^> 1]];)cpp",
	R"cpp(
	#define ECHO(X) X
	ECHO(EC^HO($C[[int]]) EC^HO(a));
	)cpp",
	R"cpp( $C[[^$C[[int]] a^]]; )cpp",
	R"cpp( $C[[^$C[[int]] a = $C[[5]]^]]; )cpp",
	};
	for (const char *C : Cases) {
	Annotations Test(C);
	auto AST = TestTU::withCode(Test.code()).build();
	auto T = makeSelectionTree(C, AST);

	std::vector<Range> Complete, Partial;
	for (const SelectionTree::Node *N : allNodes(T))
	if (N->Selected == SelectionTree::Complete)
	Complete.push_back(nodeRange(N, AST));
	else if (N->Selected == SelectionTree::Partial)
	Partial.push_back(nodeRange(N, AST));
	EXPECT_THAT(Complete, UnorderedElementsAreArray(Test.ranges("C"))) << C;
	EXPECT_THAT(Partial, UnorderedElementsAreArray(Test.ranges())) << C;
	}
	}

	TEST(SelectionTest, PathologicalPreprocessor) {
	const char *Case = R"cpp(
	#define MACRO while(1)
	void test() {
	#include "Expand.inc"
	br^eak;
	}
	)cpp";
	Annotations Test(Case);
	auto TU = TestTU::withCode(Test.code());
	TU.AdditionalFiles["Expand.inc"] = "MACRO\n";
	auto AST = TU.build();
	EXPECT_THAT(*AST.getDiagnostics(), ::testing::IsEmpty());
	auto T = makeSelectionTree(Case, AST);

	EXPECT_EQ("BreakStmt", T.commonAncestor()->kind());
	EXPECT_EQ("WhileStmt", T.commonAncestor()->Parent->kind());
	}

	TEST(SelectionTest, IncludedFile) {
	const char *Case = R"cpp(
	void test() {
	#include "Exp^and.inc"
	break;
	}
	)cpp";
	Annotations Test(Case);
	auto TU = TestTU::withCode(Test.code());
	TU.AdditionalFiles["Expand.inc"] = "while(1)\n";
	auto AST = TU.build();
	auto T = makeSelectionTree(Case, AST);

	EXPECT_EQ(nullptr, T.commonAncestor());
	}

	TEST(SelectionTest, MacroArgExpansion) {
	// If a macro arg is expanded several times, we only consider the first one
	// selected.
	const char *Case = R"cpp(
	int mul(int, int);
	#define SQUARE(X) mul(X, X);
	int nine = SQUARE(^3);
	)cpp";
	Annotations Test(Case);
	auto AST = TestTU::withCode(Test.code()).build();
	auto T = makeSelectionTree(Case, AST);
	EXPECT_EQ("IntegerLiteral", T.commonAncestor()->kind());
	EXPECT_TRUE(T.commonAncestor()->Selected);

	// Verify that the common assert() macro doesn't suffer from this.
	// (This is because we don't associate the stringified token with the arg).
	Case = R"cpp(
	void die(const char*);
	#define assert(x) (x ? (void)0 : die(#x))
	void foo() { assert(^42); }
	)cpp";
	Test = Annotations(Case);
	AST = TestTU::withCode(Test.code()).build();
	T = makeSelectionTree(Case, AST);

	EXPECT_EQ("IntegerLiteral", T.commonAncestor()->kind());
	}

	TEST(SelectionTest, Implicit) {
	const char *Test = R"cpp(
	struct S { S(const char*); };
	int f(S);
	int x = f("^");
	)cpp";
	auto AST = TestTU::withCode(Annotations(Test).code()).build();
	auto T = makeSelectionTree(Test, AST);

	const SelectionTree::Node *Str = T.commonAncestor();
	EXPECT_EQ("StringLiteral", nodeKind(Str)) << "Implicit selected?";
	EXPECT_EQ("ImplicitCastExpr", nodeKind(Str->Parent));
	EXPECT_EQ("CXXConstructExpr", nodeKind(Str->Parent->Parent));
	EXPECT_EQ(Str, &Str->Parent->Parent->ignoreImplicit())
	<< "Didn't unwrap " << nodeKind(&Str->Parent->Parent->ignoreImplicit());

	EXPECT_EQ("CXXConstructExpr", nodeKind(&Str->outerImplicit()));
	}

	TEST(SelectionTest, CreateAll) {
	llvm::Annotations Test("int$unique^ a=1$ambiguous^+1; $empty^");
	auto AST = TestTU::withCode(Test.code()).build();
	unsigned Seen = 0;
	SelectionTree::createEach(
	AST.getASTContext(), AST.getTokens(), Test.point("ambiguous"),
	Test.point("ambiguous"), [&](SelectionTree T) {
	// Expect to see the right-biased tree first.
	if (Seen == 0) {
	EXPECT_EQ("BinaryOperator", nodeKind(T.commonAncestor()));
	} else if (Seen == 1) {
	EXPECT_EQ("IntegerLiteral", nodeKind(T.commonAncestor()));
	}
	++Seen;
	return false;
	});
	EXPECT_EQ(2u, Seen);

	Seen = 0;
	SelectionTree::createEach(AST.getASTContext(), AST.getTokens(),
	Test.point("ambiguous"), Test.point("ambiguous"),
	[&](SelectionTree T) {
	++Seen;
	return true;
	});
	EXPECT_EQ(1u, Seen) << "Return true --> stop iterating";

	Seen = 0;
	SelectionTree::createEach(AST.getASTContext(), AST.getTokens(),
	Test.point("unique"), Test.point("unique"),
	[&](SelectionTree T) {
	++Seen;
	return false;
	});
	EXPECT_EQ(1u, Seen) << "no ambiguity --> only one tree";

	Seen = 0;
	SelectionTree::createEach(AST.getASTContext(), AST.getTokens(),
	Test.point("empty"), Test.point("empty"),
	[&](SelectionTree T) {
	EXPECT_FALSE(T.commonAncestor());
	++Seen;
	return false;
	});
	EXPECT_EQ(1u, Seen) << "empty tree still created";

	Seen = 0;
	SelectionTree::createEach(AST.getASTContext(), AST.getTokens(),
	Test.point("unique"), Test.point("ambiguous"),
	[&](SelectionTree T) {
	++Seen;
	return false;
	});
	EXPECT_EQ(1u, Seen) << "one tree for nontrivial selection";
	}

	TEST(SelectionTest, DeclContextIsLexical) {
	llvm::Annotations Test("namespace a { void $1^foo(); } void a::$2^foo();");
	auto AST = TestTU::withCode(Test.code()).build();
	{
	auto ST = SelectionTree::createRight(AST.getASTContext(), AST.getTokens(),
	Test.point("1"), Test.point("1"));
	EXPECT_FALSE(ST.commonAncestor()->getDeclContext().isTranslationUnit());
	}
	{
	auto ST = SelectionTree::createRight(AST.getASTContext(), AST.getTokens(),
	Test.point("2"), Test.point("2"));
	EXPECT_TRUE(ST.commonAncestor()->getDeclContext().isTranslationUnit());
	}
	}

	} // namespace
	} // namespace clangd
	} // namespace clang