Google Git
Sign in
llvm / clang / c6761990bda8885d0f421ff03675a3d5f584d483 / . / unittests / Tooling / RangeSelectorTest.cpp
blob: 8a7d555e61ce24a2119e6dcd4dba5fd54d1ea05b [file] [log] [blame]
//===- unittest/Tooling/RangeSelectorTest.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 "clang/Tooling/Transformer/RangeSelector.h"
#include "clang/ASTMatchers/ASTMatchers.h"
#include "clang/Frontend/ASTUnit.h"
#include "clang/Tooling/Tooling.h"
#include "clang/Tooling/Transformer/SourceCode.h"
#include "llvm/Support/Error.h"
#include "llvm/Testing/Support/Error.h"
#include "gmock/gmock.h"
#include "gtest/gtest.h"
using namespace clang;
using namespace transformer;
using namespace ast_matchers;
namespace {
using ::llvm::Expected;
using ::llvm::Failed;
using ::llvm::HasValue;
using ::llvm::StringError;
using ::testing::AllOf;
using ::testing::HasSubstr;
using ::testing::Property;
using MatchResult = MatchFinder::MatchResult;
struct TestMatch {
// The AST unit from which `result` is built. We bundle it because it backs
// the result. Users are not expected to access it.
std::unique_ptr<clang::ASTUnit> ASTUnit;
// The result to use in the test. References `ast_unit`.
MatchResult Result;
};
template <typename M> TestMatch matchCode(StringRef Code, M Matcher) {
auto ASTUnit = tooling::buildASTFromCode(Code);
assert(ASTUnit != nullptr && "AST construction failed");
ASTContext &Context = ASTUnit->getASTContext();
assert(!Context.getDiagnostics().hasErrorOccurred() && "Compilation error");
auto Matches = ast_matchers::match(Matcher, Context);
// We expect a single, exact match.
assert(Matches.size() != 0 && "no matches found");
assert(Matches.size() == 1 && "too many matches");
return TestMatch{std::move(ASTUnit), MatchResult(Matches[0], &Context)};
}
// Applies \p Selector to \p Match and, on success, returns the selected source.
Expected<StringRef> select(RangeSelector Selector, const TestMatch &Match) {
Expected<CharSourceRange> Range = Selector(Match.Result);
if (!Range)
return Range.takeError();
return tooling::getText(*Range, *Match.Result.Context);
}
// Applies \p Selector to a trivial match with only a single bound node with id
// "bound_node_id". For use in testing unbound-node errors.
Expected<CharSourceRange> selectFromTrivial(const RangeSelector &Selector) {
// We need to bind the result to something, or the match will fail. Use a
// binding that is not used in the unbound node tests.
TestMatch Match =
matchCode("static int x = 0;", varDecl().bind("bound_node_id"));
return Selector(Match.Result);
}
// Matches the message expected for unbound-node failures.
testing::Matcher<StringError> withUnboundNodeMessage() {
return testing::Property(
&StringError::getMessage,
AllOf(HasSubstr("unbound_id"), HasSubstr("not bound")));
}
// Applies \p Selector to code containing assorted node types, where the match
// binds each one: a statement ("stmt"), a (non-member) ctor-initializer
// ("init"), an expression ("expr") and a (nameless) declaration ("decl"). Used
// to test failures caused by applying selectors to nodes of the wrong type.
Expected<CharSourceRange> selectFromAssorted(RangeSelector Selector) {
StringRef Code = R"cc(
struct A {};
class F : public A {
public:
F(int) {}
};
void g() { F f(1); }
)cc";
auto Matcher =
compoundStmt(
hasDescendant(
cxxConstructExpr(
hasDeclaration(
decl(hasDescendant(cxxCtorInitializer(isBaseInitializer())
.bind("init")))
.bind("decl")))
.bind("expr")))
.bind("stmt");
return Selector(matchCode(Code, Matcher).Result);
}
// Matches the message expected for type-error failures.
testing::Matcher<StringError> withTypeErrorMessage(StringRef NodeID) {
return testing::Property(
&StringError::getMessage,
AllOf(HasSubstr(NodeID), HasSubstr("mismatched type")));
}
TEST(RangeSelectorTest, UnboundNode) {
EXPECT_THAT_EXPECTED(selectFromTrivial(node("unbound_id")),
Failed<StringError>(withUnboundNodeMessage()));
}
MATCHER_P(EqualsCharSourceRange, Range, "") {
return Range.getAsRange() == arg.getAsRange() &&
Range.isTokenRange() == arg.isTokenRange();
}
// FIXME: here and elsewhere: use llvm::Annotations library to explicitly mark
// points and ranges of interest, enabling more readable tests.
TEST(RangeSelectorTest, BeforeOp) {
StringRef Code = R"cc(
int f(int x, int y, int z) { return 3; }
int g() { return f(/* comment */ 3, 7 /* comment */, 9); }
)cc";
StringRef Call = "call";
TestMatch Match = matchCode(Code, callExpr().bind(Call));
const auto* E = Match.Result.Nodes.getNodeAs<Expr>(Call);
assert(E != nullptr);
auto ExprBegin = E->getSourceRange().getBegin();
EXPECT_THAT_EXPECTED(
before(node(Call))(Match.Result),
HasValue(EqualsCharSourceRange(
CharSourceRange::getCharRange(ExprBegin, ExprBegin))));
}
TEST(RangeSelectorTest, AfterOp) {
StringRef Code = R"cc(
int f(int x, int y, int z) { return 3; }
int g() { return f(/* comment */ 3, 7 /* comment */, 9); }
)cc";
StringRef Call = "call";
TestMatch Match = matchCode(Code, callExpr().bind(Call));
const auto* E = Match.Result.Nodes.getNodeAs<Expr>(Call);
assert(E != nullptr);
const SourceRange Range = E->getSourceRange();
// The end token, a right paren, is one character wide, so advance by one,
// bringing us to the semicolon.
const SourceLocation SemiLoc = Range.getEnd().getLocWithOffset(1);
const auto ExpectedAfter = CharSourceRange::getCharRange(SemiLoc, SemiLoc);
// Test with a char range.
auto CharRange = CharSourceRange::getCharRange(Range.getBegin(), SemiLoc);
EXPECT_THAT_EXPECTED(after(charRange(CharRange))(Match.Result),
HasValue(EqualsCharSourceRange(ExpectedAfter)));
// Test with a token range.
auto TokenRange = CharSourceRange::getTokenRange(Range);
EXPECT_THAT_EXPECTED(after(charRange(TokenRange))(Match.Result),
HasValue(EqualsCharSourceRange(ExpectedAfter)));
}
TEST(RangeSelectorTest, RangeOp) {
StringRef Code = R"cc(
int f(int x, int y, int z) { return 3; }
int g() { return f(/* comment */ 3, 7 /* comment */, 9); }
)cc";
StringRef Arg0 = "a0";
StringRef Arg1 = "a1";
StringRef Call = "call";
auto Matcher = callExpr(hasArgument(0, expr().bind(Arg0)),
hasArgument(1, expr().bind(Arg1)))
.bind(Call);
TestMatch Match = matchCode(Code, Matcher);
// Node-id specific version:
EXPECT_THAT_EXPECTED(select(range(Arg0, Arg1), Match), HasValue("3, 7"));
// General version:
EXPECT_THAT_EXPECTED(select(range(node(Arg0), node(Arg1)), Match),
HasValue("3, 7"));
}
TEST(RangeSelectorTest, NodeOpStatement) {
StringRef Code = "int f() { return 3; }";
StringRef ID = "id";
TestMatch Match = matchCode(Code, returnStmt().bind(ID));
EXPECT_THAT_EXPECTED(select(node(ID), Match), HasValue("return 3;"));
}
TEST(RangeSelectorTest, NodeOpExpression) {
StringRef Code = "int f() { return 3; }";
StringRef ID = "id";
TestMatch Match = matchCode(Code, expr().bind(ID));
EXPECT_THAT_EXPECTED(select(node(ID), Match), HasValue("3"));
}
TEST(RangeSelectorTest, StatementOp) {
StringRef Code = "int f() { return 3; }";
StringRef ID = "id";
TestMatch Match = matchCode(Code, expr().bind(ID));
EXPECT_THAT_EXPECTED(select(statement(ID), Match), HasValue("3;"));
}
TEST(RangeSelectorTest, MemberOp) {
StringRef Code = R"cc(
struct S {
int member;
};
int g() {
S s;
return s.member;
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, memberExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(member(ID), Match), HasValue("member"));
}
// Tests that member does not select any qualifiers on the member name.
TEST(RangeSelectorTest, MemberOpQualified) {
StringRef Code = R"cc(
struct S {
int member;
};
struct T : public S {
int field;
};
int g() {
T t;
return t.S::member;
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, memberExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(member(ID), Match), HasValue("member"));
}
TEST(RangeSelectorTest, MemberOpTemplate) {
StringRef Code = R"cc(
struct S {
template <typename T> T foo(T t);
};
int f(int x) {
S s;
return s.template foo<int>(3);
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, memberExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(member(ID), Match), HasValue("foo"));
}
TEST(RangeSelectorTest, MemberOpOperator) {
StringRef Code = R"cc(
struct S {
int operator*();
};
int f(int x) {
S s;
return s.operator *();
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, memberExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(member(ID), Match), HasValue("operator *"));
}
TEST(RangeSelectorTest, NameOpNamedDecl) {
StringRef Code = R"cc(
int myfun() {
return 3;
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, functionDecl().bind(ID));
EXPECT_THAT_EXPECTED(select(name(ID), Match), HasValue("myfun"));
}
TEST(RangeSelectorTest, NameOpDeclRef) {
StringRef Code = R"cc(
int foo(int x) {
return x;
}
int g(int x) { return foo(x) * x; }
)cc";
StringRef Ref = "ref";
TestMatch Match = matchCode(Code, declRefExpr(to(functionDecl())).bind(Ref));
EXPECT_THAT_EXPECTED(select(name(Ref), Match), HasValue("foo"));
}
TEST(RangeSelectorTest, NameOpCtorInitializer) {
StringRef Code = R"cc(
class C {
public:
C() : field(3) {}
int field;
};
)cc";
StringRef Init = "init";
TestMatch Match = matchCode(Code, cxxCtorInitializer().bind(Init));
EXPECT_THAT_EXPECTED(select(name(Init), Match), HasValue("field"));
}
TEST(RangeSelectorTest, NameOpErrors) {
EXPECT_THAT_EXPECTED(selectFromTrivial(name("unbound_id")),
Failed<StringError>(withUnboundNodeMessage()));
EXPECT_THAT_EXPECTED(selectFromAssorted(name("stmt")),
Failed<StringError>(withTypeErrorMessage("stmt")));
}
TEST(RangeSelectorTest, NameOpDeclRefError) {
StringRef Code = R"cc(
struct S {
int operator*();
};
int f(int x) {
S s;
return *s + x;
}
)cc";
StringRef Ref = "ref";
TestMatch Match = matchCode(Code, declRefExpr(to(functionDecl())).bind(Ref));
EXPECT_THAT_EXPECTED(
name(Ref)(Match.Result),
Failed<StringError>(testing::Property(
&StringError::getMessage,
AllOf(HasSubstr(Ref), HasSubstr("requires property 'identifier'")))));
}
TEST(RangeSelectorTest, CallArgsOp) {
const StringRef Code = R"cc(
struct C {
int bar(int, int);
};
int f() {
C x;
return x.bar(3, 4);
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, callExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(callArgs(ID), Match), HasValue("3, 4"));
}
TEST(RangeSelectorTest, CallArgsOpNoArgs) {
const StringRef Code = R"cc(
struct C {
int bar();
};
int f() {
C x;
return x.bar();
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, callExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(callArgs(ID), Match), HasValue(""));
}
TEST(RangeSelectorTest, CallArgsOpNoArgsWithComments) {
const StringRef Code = R"cc(
struct C {
int bar();
};
int f() {
C x;
return x.bar(/*empty*/);
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, callExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(callArgs(ID), Match), HasValue("/*empty*/"));
}
// Tests that arguments are extracted correctly when a temporary (with parens)
// is used.
TEST(RangeSelectorTest, CallArgsOpWithParens) {
const StringRef Code = R"cc(
struct C {
int bar(int, int) { return 3; }
};
int f() {
C x;
return C().bar(3, 4);
}
)cc";
StringRef ID = "id";
TestMatch Match =
matchCode(Code, callExpr(callee(functionDecl(hasName("bar")))).bind(ID));
EXPECT_THAT_EXPECTED(select(callArgs(ID), Match), HasValue("3, 4"));
}
TEST(RangeSelectorTest, CallArgsOpLeadingComments) {
const StringRef Code = R"cc(
struct C {
int bar(int, int) { return 3; }
};
int f() {
C x;
return x.bar(/*leading*/ 3, 4);
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, callExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(callArgs(ID), Match),
HasValue("/*leading*/ 3, 4"));
}
TEST(RangeSelectorTest, CallArgsOpTrailingComments) {
const StringRef Code = R"cc(
struct C {
int bar(int, int) { return 3; }
};
int f() {
C x;
return x.bar(3 /*trailing*/, 4);
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, callExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(callArgs(ID), Match),
HasValue("3 /*trailing*/, 4"));
}
TEST(RangeSelectorTest, CallArgsOpEolComments) {
const StringRef Code = R"cc(
struct C {
int bar(int, int) { return 3; }
};
int f() {
C x;
return x.bar( // Header
1, // foo
2 // bar
);
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, callExpr().bind(ID));
std::string ExpectedString = R"( // Header
1, // foo
2 // bar
)";
EXPECT_THAT_EXPECTED(select(callArgs(ID), Match), HasValue(ExpectedString));
}
TEST(RangeSelectorTest, CallArgsErrors) {
EXPECT_THAT_EXPECTED(selectFromTrivial(callArgs("unbound_id")),
Failed<StringError>(withUnboundNodeMessage()));
EXPECT_THAT_EXPECTED(selectFromAssorted(callArgs("stmt")),
Failed<StringError>(withTypeErrorMessage("stmt")));
}
TEST(RangeSelectorTest, StatementsOp) {
StringRef Code = R"cc(
void g();
void f() { /* comment */ g(); /* comment */ g(); /* comment */ }
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, compoundStmt().bind(ID));
EXPECT_THAT_EXPECTED(
select(statements(ID), Match),
HasValue(" /* comment */ g(); /* comment */ g(); /* comment */ "));
}
TEST(RangeSelectorTest, StatementsOpEmptyList) {
StringRef Code = "void f() {}";
StringRef ID = "id";
TestMatch Match = matchCode(Code, compoundStmt().bind(ID));
EXPECT_THAT_EXPECTED(select(statements(ID), Match), HasValue(""));
}
TEST(RangeSelectorTest, StatementsOpErrors) {
EXPECT_THAT_EXPECTED(selectFromTrivial(statements("unbound_id")),
Failed<StringError>(withUnboundNodeMessage()));
EXPECT_THAT_EXPECTED(selectFromAssorted(statements("decl")),
Failed<StringError>(withTypeErrorMessage("decl")));
}
TEST(RangeSelectorTest, ElementsOp) {
StringRef Code = R"cc(
void f() {
int v[] = {/* comment */ 3, /* comment*/ 4 /* comment */};
(void)v;
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, initListExpr().bind(ID));
EXPECT_THAT_EXPECTED(
select(initListElements(ID), Match),
HasValue("/* comment */ 3, /* comment*/ 4 /* comment */"));
}
TEST(RangeSelectorTest, ElementsOpEmptyList) {
StringRef Code = R"cc(
void f() {
int v[] = {};
(void)v;
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, initListExpr().bind(ID));
EXPECT_THAT_EXPECTED(select(initListElements(ID), Match), HasValue(""));
}
TEST(RangeSelectorTest, ElementsOpErrors) {
EXPECT_THAT_EXPECTED(selectFromTrivial(initListElements("unbound_id")),
Failed<StringError>(withUnboundNodeMessage()));
EXPECT_THAT_EXPECTED(selectFromAssorted(initListElements("stmt")),
Failed<StringError>(withTypeErrorMessage("stmt")));
}
TEST(RangeSelectorTest, ElseBranchOpSingleStatement) {
StringRef Code = R"cc(
int f() {
int x = 0;
if (true) x = 3;
else x = 4;
return x + 5;
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, ifStmt().bind(ID));
EXPECT_THAT_EXPECTED(select(elseBranch(ID), Match), HasValue("else x = 4;"));
}
TEST(RangeSelectorTest, ElseBranchOpCompoundStatement) {
StringRef Code = R"cc(
int f() {
int x = 0;
if (true) x = 3;
else { x = 4; }
return x + 5;
}
)cc";
StringRef ID = "id";
TestMatch Match = matchCode(Code, ifStmt().bind(ID));
EXPECT_THAT_EXPECTED(select(elseBranch(ID), Match),
HasValue("else { x = 4; }"));
}
// Tests case where the matched node is the complete expanded text.
TEST(RangeSelectorTest, ExpansionOp) {
StringRef Code = R"cc(
#define BADDECL(E) int bad(int x) { return E; }
BADDECL(x * x)
)cc";
StringRef Fun = "Fun";
TestMatch Match = matchCode(Code, functionDecl(hasName("bad")).bind(Fun));
EXPECT_THAT_EXPECTED(select(expansion(node(Fun)), Match),
HasValue("BADDECL(x * x)"));
}
// Tests case where the matched node is (only) part of the expanded text.
TEST(RangeSelectorTest, ExpansionOpPartial) {
StringRef Code = R"cc(
#define BADDECL(E) int bad(int x) { return E; }
BADDECL(x * x)
)cc";
StringRef Ret = "Ret";
TestMatch Match = matchCode(Code, returnStmt().bind(Ret));
EXPECT_THAT_EXPECTED(select(expansion(node(Ret)), Match),
HasValue("BADDECL(x * x)"));
}
TEST(RangeSelectorTest, IfBoundOpBound) {
StringRef Code = R"cc(
int f() {
return 3 + 5;
}
)cc";
StringRef ID = "id", Op = "op";
TestMatch Match =
matchCode(Code, binaryOperator(hasLHS(expr().bind(ID))).bind(Op));
EXPECT_THAT_EXPECTED(select(ifBound(ID, node(ID), node(Op)), Match),
HasValue("3"));
}
TEST(RangeSelectorTest, IfBoundOpUnbound) {
StringRef Code = R"cc(
int f() {
return 3 + 5;
}
)cc";
StringRef ID = "id", Op = "op";
TestMatch Match = matchCode(Code, binaryOperator().bind(Op));
EXPECT_THAT_EXPECTED(select(ifBound(ID, node(ID), node(Op)), Match),
HasValue("3 + 5"));
}
} // namespace