// Copyright 2019 The Abseil Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // https://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "absl/status/status.h" #include "gmock/gmock.h" #include "gtest/gtest.h" #include "absl/strings/str_cat.h" namespace { using ::testing::Eq; using ::testing::HasSubstr; using ::testing::Optional; using ::testing::UnorderedElementsAreArray; TEST(StatusCode, InsertionOperator) { const absl::StatusCode code = absl::StatusCode::kUnknown; std::ostringstream oss; oss << code; EXPECT_EQ(oss.str(), absl::StatusCodeToString(code)); } // This structure holds the details for testing a single error code, // its creator, and its classifier. struct ErrorTest { absl::StatusCode code; using Creator = absl::Status (*)(absl::string_view); using Classifier = bool (*)(const absl::Status&); Creator creator; Classifier classifier; }; constexpr ErrorTest kErrorTests[]{ {absl::StatusCode::kCancelled, absl::CancelledError, absl::IsCancelled}, {absl::StatusCode::kUnknown, absl::UnknownError, absl::IsUnknown}, {absl::StatusCode::kInvalidArgument, absl::InvalidArgumentError, absl::IsInvalidArgument}, {absl::StatusCode::kDeadlineExceeded, absl::DeadlineExceededError, absl::IsDeadlineExceeded}, {absl::StatusCode::kNotFound, absl::NotFoundError, absl::IsNotFound}, {absl::StatusCode::kAlreadyExists, absl::AlreadyExistsError, absl::IsAlreadyExists}, {absl::StatusCode::kPermissionDenied, absl::PermissionDeniedError, absl::IsPermissionDenied}, {absl::StatusCode::kResourceExhausted, absl::ResourceExhaustedError, absl::IsResourceExhausted}, {absl::StatusCode::kFailedPrecondition, absl::FailedPreconditionError, absl::IsFailedPrecondition}, {absl::StatusCode::kAborted, absl::AbortedError, absl::IsAborted}, {absl::StatusCode::kOutOfRange, absl::OutOfRangeError, absl::IsOutOfRange}, {absl::StatusCode::kUnimplemented, absl::UnimplementedError, absl::IsUnimplemented}, {absl::StatusCode::kInternal, absl::InternalError, absl::IsInternal}, {absl::StatusCode::kUnavailable, absl::UnavailableError, absl::IsUnavailable}, {absl::StatusCode::kDataLoss, absl::DataLossError, absl::IsDataLoss}, {absl::StatusCode::kUnauthenticated, absl::UnauthenticatedError, absl::IsUnauthenticated}, }; TEST(Status, CreateAndClassify) { for (const auto& test : kErrorTests) { SCOPED_TRACE(absl::StatusCodeToString(test.code)); // Ensure that the creator does, in fact, create status objects with the // expected error code and message. std::string message = absl::StrCat("error code ", test.code, " test message"); absl::Status status = test.creator(message); EXPECT_EQ(test.code, status.code()); EXPECT_EQ(message, status.message()); // Ensure that the classifier returns true for a status produced by the // creator. EXPECT_TRUE(test.classifier(status)); // Ensure that the classifier returns false for status with a different // code. for (const auto& other : kErrorTests) { if (other.code != test.code) { EXPECT_FALSE(test.classifier(absl::Status(other.code, ""))) << " other.code = " << other.code; } } } } TEST(Status, DefaultConstructor) { absl::Status status; EXPECT_TRUE(status.ok()); EXPECT_EQ(absl::StatusCode::kOk, status.code()); EXPECT_EQ("", status.message()); } TEST(Status, OkStatus) { absl::Status status = absl::OkStatus(); EXPECT_TRUE(status.ok()); EXPECT_EQ(absl::StatusCode::kOk, status.code()); EXPECT_EQ("", status.message()); } TEST(Status, ConstructorWithCodeMessage) { { absl::Status status(absl::StatusCode::kCancelled, ""); EXPECT_FALSE(status.ok()); EXPECT_EQ(absl::StatusCode::kCancelled, status.code()); EXPECT_EQ("", status.message()); } { absl::Status status(absl::StatusCode::kInternal, "message"); EXPECT_FALSE(status.ok()); EXPECT_EQ(absl::StatusCode::kInternal, status.code()); EXPECT_EQ("message", status.message()); } } TEST(Status, ConstructOutOfRangeCode) { const int kRawCode = 9999; absl::Status status(static_cast(kRawCode), ""); EXPECT_EQ(absl::StatusCode::kUnknown, status.code()); EXPECT_EQ(kRawCode, status.raw_code()); } constexpr char kUrl1[] = "url.payload.1"; constexpr char kUrl2[] = "url.payload.2"; constexpr char kUrl3[] = "url.payload.3"; constexpr char kUrl4[] = "url.payload.xx"; constexpr char kPayload1[] = "aaaaa"; constexpr char kPayload2[] = "bbbbb"; constexpr char kPayload3[] = "ccccc"; using PayloadsVec = std::vector>; TEST(Status, TestGetSetPayload) { absl::Status ok_status = absl::OkStatus(); ok_status.SetPayload(kUrl1, absl::Cord(kPayload1)); ok_status.SetPayload(kUrl2, absl::Cord(kPayload2)); EXPECT_FALSE(ok_status.GetPayload(kUrl1)); EXPECT_FALSE(ok_status.GetPayload(kUrl2)); absl::Status bad_status(absl::StatusCode::kInternal, "fail"); bad_status.SetPayload(kUrl1, absl::Cord(kPayload1)); bad_status.SetPayload(kUrl2, absl::Cord(kPayload2)); EXPECT_THAT(bad_status.GetPayload(kUrl1), Optional(Eq(kPayload1))); EXPECT_THAT(bad_status.GetPayload(kUrl2), Optional(Eq(kPayload2))); EXPECT_FALSE(bad_status.GetPayload(kUrl3)); bad_status.SetPayload(kUrl1, absl::Cord(kPayload3)); EXPECT_THAT(bad_status.GetPayload(kUrl1), Optional(Eq(kPayload3))); // Testing dynamically generated type_url bad_status.SetPayload(absl::StrCat(kUrl1, ".1"), absl::Cord(kPayload1)); EXPECT_THAT(bad_status.GetPayload(absl::StrCat(kUrl1, ".1")), Optional(Eq(kPayload1))); } TEST(Status, TestErasePayload) { absl::Status bad_status(absl::StatusCode::kInternal, "fail"); bad_status.SetPayload(kUrl1, absl::Cord(kPayload1)); bad_status.SetPayload(kUrl2, absl::Cord(kPayload2)); bad_status.SetPayload(kUrl3, absl::Cord(kPayload3)); EXPECT_FALSE(bad_status.ErasePayload(kUrl4)); EXPECT_TRUE(bad_status.GetPayload(kUrl2)); EXPECT_TRUE(bad_status.ErasePayload(kUrl2)); EXPECT_FALSE(bad_status.GetPayload(kUrl2)); EXPECT_FALSE(bad_status.ErasePayload(kUrl2)); EXPECT_TRUE(bad_status.ErasePayload(kUrl1)); EXPECT_TRUE(bad_status.ErasePayload(kUrl3)); bad_status.SetPayload(kUrl1, absl::Cord(kPayload1)); EXPECT_TRUE(bad_status.ErasePayload(kUrl1)); } TEST(Status, TestComparePayloads) { absl::Status bad_status1(absl::StatusCode::kInternal, "fail"); bad_status1.SetPayload(kUrl1, absl::Cord(kPayload1)); bad_status1.SetPayload(kUrl2, absl::Cord(kPayload2)); bad_status1.SetPayload(kUrl3, absl::Cord(kPayload3)); absl::Status bad_status2(absl::StatusCode::kInternal, "fail"); bad_status2.SetPayload(kUrl2, absl::Cord(kPayload2)); bad_status2.SetPayload(kUrl3, absl::Cord(kPayload3)); bad_status2.SetPayload(kUrl1, absl::Cord(kPayload1)); EXPECT_EQ(bad_status1, bad_status2); } PayloadsVec AllVisitedPayloads(const absl::Status& s) { PayloadsVec result; s.ForEachPayload([&](absl::string_view type_url, const absl::Cord& payload) { result.push_back(std::make_pair(std::string(type_url), payload)); }); return result; } TEST(Status, TestForEachPayload) { absl::Status bad_status(absl::StatusCode::kInternal, "fail"); bad_status.SetPayload(kUrl1, absl::Cord(kPayload1)); bad_status.SetPayload(kUrl2, absl::Cord(kPayload2)); bad_status.SetPayload(kUrl3, absl::Cord(kPayload3)); int count = 0; bad_status.ForEachPayload( [&count](absl::string_view, const absl::Cord&) { ++count; }); EXPECT_EQ(count, 3); PayloadsVec expected_payloads = {{kUrl1, absl::Cord(kPayload1)}, {kUrl2, absl::Cord(kPayload2)}, {kUrl3, absl::Cord(kPayload3)}}; // Test that we visit all the payloads in the status. PayloadsVec visited_payloads = AllVisitedPayloads(bad_status); EXPECT_THAT(visited_payloads, UnorderedElementsAreArray(expected_payloads)); // Test that visitation order is not consistent between run. std::vector scratch; while (true) { scratch.emplace_back(absl::StatusCode::kInternal, "fail"); scratch.back().SetPayload(kUrl1, absl::Cord(kPayload1)); scratch.back().SetPayload(kUrl2, absl::Cord(kPayload2)); scratch.back().SetPayload(kUrl3, absl::Cord(kPayload3)); if (AllVisitedPayloads(scratch.back()) != visited_payloads) { break; } } } TEST(Status, ToString) { absl::Status s(absl::StatusCode::kInternal, "fail"); EXPECT_EQ("INTERNAL: fail", s.ToString()); s.SetPayload("foo", absl::Cord("bar")); EXPECT_EQ("INTERNAL: fail [foo='bar']", s.ToString()); s.SetPayload("bar", absl::Cord("\377")); EXPECT_THAT(s.ToString(), AllOf(HasSubstr("INTERNAL: fail"), HasSubstr("[foo='bar']"), HasSubstr("[bar='\\xff']"))); } TEST(Status, CopyConstructor) { { absl::Status status; absl::Status copy(status); EXPECT_EQ(copy, status); } { absl::Status status(absl::StatusCode::kInvalidArgument, "message"); absl::Status copy(status); EXPECT_EQ(copy, status); } { absl::Status status(absl::StatusCode::kInvalidArgument, "message"); status.SetPayload(kUrl1, absl::Cord(kPayload1)); absl::Status copy(status); EXPECT_EQ(copy, status); } } TEST(Status, CopyAssignment) { absl::Status assignee; { absl::Status status; assignee = status; EXPECT_EQ(assignee, status); } { absl::Status status(absl::StatusCode::kInvalidArgument, "message"); assignee = status; EXPECT_EQ(assignee, status); } { absl::Status status(absl::StatusCode::kInvalidArgument, "message"); status.SetPayload(kUrl1, absl::Cord(kPayload1)); assignee = status; EXPECT_EQ(assignee, status); } } TEST(Status, MoveConstructor) { { absl::Status status; absl::Status copy(absl::Status{}); EXPECT_EQ(copy, status); } { absl::Status status(absl::StatusCode::kInvalidArgument, "message"); absl::Status copy( absl::Status(absl::StatusCode::kInvalidArgument, "message")); EXPECT_EQ(copy, status); } { absl::Status status(absl::StatusCode::kInvalidArgument, "message"); status.SetPayload(kUrl1, absl::Cord(kPayload1)); absl::Status copy1(status); absl::Status copy2(std::move(status)); EXPECT_EQ(copy1, copy2); } } TEST(Status, MoveAssignment) { absl::Status assignee; { absl::Status status; assignee = absl::Status(); EXPECT_EQ(assignee, status); } { absl::Status status(absl::StatusCode::kInvalidArgument, "message"); assignee = absl::Status(absl::StatusCode::kInvalidArgument, "message"); EXPECT_EQ(assignee, status); } { absl::Status status(absl::StatusCode::kInvalidArgument, "message"); status.SetPayload(kUrl1, absl::Cord(kPayload1)); absl::Status copy(status); assignee = std::move(status); EXPECT_EQ(assignee, copy); } } TEST(Status, Update) { absl::Status s; s.Update(absl::OkStatus()); EXPECT_TRUE(s.ok()); const absl::Status a(absl::StatusCode::kCancelled, "message"); s.Update(a); EXPECT_EQ(s, a); const absl::Status b(absl::StatusCode::kInternal, "other message"); s.Update(b); EXPECT_EQ(s, a); s.Update(absl::OkStatus()); EXPECT_EQ(s, a); EXPECT_FALSE(s.ok()); } TEST(Status, Equality) { absl::Status ok; absl::Status no_payload = absl::CancelledError("no payload"); absl::Status one_payload = absl::InvalidArgumentError("one payload"); one_payload.SetPayload(kUrl1, absl::Cord(kPayload1)); absl::Status two_payloads = one_payload; two_payloads.SetPayload(kUrl2, absl::Cord(kPayload2)); const std::array status_arr = {ok, no_payload, one_payload, two_payloads}; for (int i = 0; i < status_arr.size(); i++) { for (int j = 0; j < status_arr.size(); j++) { if (i == j) { EXPECT_TRUE(status_arr[i] == status_arr[j]); EXPECT_FALSE(status_arr[i] != status_arr[j]); } else { EXPECT_TRUE(status_arr[i] != status_arr[j]); EXPECT_FALSE(status_arr[i] == status_arr[j]); } } } } TEST(Status, Swap) { auto test_swap = [](const absl::Status& s1, const absl::Status& s2) { absl::Status copy1 = s1, copy2 = s2; swap(copy1, copy2); EXPECT_EQ(copy1, s2); EXPECT_EQ(copy2, s1); }; const absl::Status ok; const absl::Status no_payload(absl::StatusCode::kAlreadyExists, "no payload"); absl::Status with_payload(absl::StatusCode::kInternal, "with payload"); with_payload.SetPayload(kUrl1, absl::Cord(kPayload1)); test_swap(ok, no_payload); test_swap(no_payload, ok); test_swap(ok, with_payload); test_swap(with_payload, ok); test_swap(no_payload, with_payload); test_swap(with_payload, no_payload); } } // namespace