platform_system_core/base/result_test.cpp
2020-02-07 06:14:16 +00:00

422 lines
13 KiB
C++

/*
* Copyright (C) 2017 The Android Open Source Project
*
* 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
*
* http://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 "android-base/result.h"
#include "errno.h"
#include <istream>
#include <string>
#include <gtest/gtest.h>
using namespace std::string_literals;
namespace android {
namespace base {
TEST(result, result_accessors) {
Result<std::string> result = "success";
ASSERT_RESULT_OK(result);
ASSERT_TRUE(result.has_value());
EXPECT_EQ("success", *result);
EXPECT_EQ("success", result.value());
EXPECT_EQ('s', result->data()[0]);
}
TEST(result, result_accessors_rvalue) {
ASSERT_TRUE(Result<std::string>("success").ok());
ASSERT_TRUE(Result<std::string>("success").has_value());
EXPECT_EQ("success", *Result<std::string>("success"));
EXPECT_EQ("success", Result<std::string>("success").value());
EXPECT_EQ('s', Result<std::string>("success")->data()[0]);
}
TEST(result, result_void) {
Result<void> ok = {};
EXPECT_RESULT_OK(ok);
ok.value(); // should not crash
ASSERT_DEATH(ok.error(), "");
Result<void> fail = Error() << "failure" << 1;
EXPECT_FALSE(fail.ok());
EXPECT_EQ("failure1", fail.error().message());
EXPECT_EQ(0, fail.error().code());
EXPECT_TRUE(ok != fail);
ASSERT_DEATH(fail.value(), "");
auto test = [](bool ok) -> Result<void> {
if (ok) return {};
else return Error() << "failure" << 1;
};
EXPECT_TRUE(test(true).ok());
EXPECT_FALSE(test(false).ok());
test(true).value(); // should not crash
ASSERT_DEATH(test(true).error(), "");
ASSERT_DEATH(test(false).value(), "");
EXPECT_EQ("failure1", test(false).error().message());
}
TEST(result, result_error) {
Result<void> result = Error() << "failure" << 1;
ASSERT_FALSE(result.ok());
ASSERT_FALSE(result.has_value());
EXPECT_EQ(0, result.error().code());
EXPECT_EQ("failure1", result.error().message());
}
TEST(result, result_error_empty) {
Result<void> result = Error();
ASSERT_FALSE(result.ok());
ASSERT_FALSE(result.has_value());
EXPECT_EQ(0, result.error().code());
EXPECT_EQ("", result.error().message());
}
TEST(result, result_error_rvalue) {
// Error() and ErrnoError() aren't actually used to create a Result<T> object.
// Under the hood, they are an intermediate class that can be implicitly constructed into a
// Result<T>. This is needed both to create the ostream and because Error() itself, by
// definition will not know what the type, T, of the underlying Result<T> object that it would
// create is.
auto MakeRvalueErrorResult = []() -> Result<void> { return Error() << "failure" << 1; };
ASSERT_FALSE(MakeRvalueErrorResult().ok());
ASSERT_FALSE(MakeRvalueErrorResult().has_value());
EXPECT_EQ(0, MakeRvalueErrorResult().error().code());
EXPECT_EQ("failure1", MakeRvalueErrorResult().error().message());
}
TEST(result, result_errno_error) {
constexpr int test_errno = 6;
errno = test_errno;
Result<void> result = ErrnoError() << "failure" << 1;
ASSERT_FALSE(result.ok());
ASSERT_FALSE(result.has_value());
EXPECT_EQ(test_errno, result.error().code());
EXPECT_EQ("failure1: "s + strerror(test_errno), result.error().message());
}
TEST(result, result_errno_error_no_text) {
constexpr int test_errno = 6;
errno = test_errno;
Result<void> result = ErrnoError();
ASSERT_FALSE(result.ok());
ASSERT_FALSE(result.has_value());
EXPECT_EQ(test_errno, result.error().code());
EXPECT_EQ(strerror(test_errno), result.error().message());
}
TEST(result, result_error_from_other_result) {
auto error_text = "test error"s;
Result<void> result = Error() << error_text;
ASSERT_FALSE(result.ok());
ASSERT_FALSE(result.has_value());
Result<std::string> result2 = result.error();
ASSERT_FALSE(result2.ok());
ASSERT_FALSE(result2.has_value());
EXPECT_EQ(0, result2.error().code());
EXPECT_EQ(error_text, result2.error().message());
}
TEST(result, result_error_through_ostream) {
auto error_text = "test error"s;
Result<void> result = Error() << error_text;
ASSERT_FALSE(result.ok());
ASSERT_FALSE(result.has_value());
Result<std::string> result2 = Error() << result.error();
ASSERT_FALSE(result2.ok());
ASSERT_FALSE(result2.has_value());
EXPECT_EQ(0, result2.error().code());
EXPECT_EQ(error_text, result2.error().message());
}
TEST(result, result_errno_error_through_ostream) {
auto error_text = "test error"s;
constexpr int test_errno = 6;
errno = 6;
Result<void> result = ErrnoError() << error_text;
errno = 0;
ASSERT_FALSE(result.ok());
ASSERT_FALSE(result.has_value());
Result<std::string> result2 = Error() << result.error();
ASSERT_FALSE(result2.ok());
ASSERT_FALSE(result2.has_value());
EXPECT_EQ(test_errno, result2.error().code());
EXPECT_EQ(error_text + ": " + strerror(test_errno), result2.error().message());
}
TEST(result, constructor_forwarding) {
auto result = Result<std::string>(std::in_place, 5, 'a');
ASSERT_RESULT_OK(result);
ASSERT_TRUE(result.has_value());
EXPECT_EQ("aaaaa", *result);
}
struct ConstructorTracker {
static size_t constructor_called;
static size_t copy_constructor_called;
static size_t move_constructor_called;
static size_t copy_assignment_called;
static size_t move_assignment_called;
template <typename T>
ConstructorTracker(T&& string) : string(string) {
++constructor_called;
}
ConstructorTracker(const ConstructorTracker& ct) {
++copy_constructor_called;
string = ct.string;
}
ConstructorTracker(ConstructorTracker&& ct) noexcept {
++move_constructor_called;
string = std::move(ct.string);
}
ConstructorTracker& operator=(const ConstructorTracker& ct) {
++copy_assignment_called;
string = ct.string;
return *this;
}
ConstructorTracker& operator=(ConstructorTracker&& ct) noexcept {
++move_assignment_called;
string = std::move(ct.string);
return *this;
}
std::string string;
};
size_t ConstructorTracker::constructor_called = 0;
size_t ConstructorTracker::copy_constructor_called = 0;
size_t ConstructorTracker::move_constructor_called = 0;
size_t ConstructorTracker::copy_assignment_called = 0;
size_t ConstructorTracker::move_assignment_called = 0;
Result<ConstructorTracker> ReturnConstructorTracker(const std::string& in) {
if (in.empty()) {
return "literal string";
}
if (in == "test2") {
return ConstructorTracker(in + in + "2");
}
ConstructorTracker result(in + " " + in);
return result;
};
TEST(result, no_copy_on_return) {
// If returning parameters that may be used to implicitly construct the type T of Result<T>,
// then those parameters are forwarded to the construction of Result<T>.
// If returning an prvalue or xvalue, it will be move constructed during the construction of
// Result<T>.
// This check ensures that that is the case, and particularly that no copy constructors
// are called.
auto result1 = ReturnConstructorTracker("");
ASSERT_RESULT_OK(result1);
EXPECT_EQ("literal string", result1->string);
EXPECT_EQ(1U, ConstructorTracker::constructor_called);
EXPECT_EQ(0U, ConstructorTracker::copy_constructor_called);
EXPECT_EQ(0U, ConstructorTracker::move_constructor_called);
EXPECT_EQ(0U, ConstructorTracker::copy_assignment_called);
EXPECT_EQ(0U, ConstructorTracker::move_assignment_called);
auto result2 = ReturnConstructorTracker("test2");
ASSERT_RESULT_OK(result2);
EXPECT_EQ("test2test22", result2->string);
EXPECT_EQ(2U, ConstructorTracker::constructor_called);
EXPECT_EQ(0U, ConstructorTracker::copy_constructor_called);
EXPECT_EQ(1U, ConstructorTracker::move_constructor_called);
EXPECT_EQ(0U, ConstructorTracker::copy_assignment_called);
EXPECT_EQ(0U, ConstructorTracker::move_assignment_called);
auto result3 = ReturnConstructorTracker("test3");
ASSERT_RESULT_OK(result3);
EXPECT_EQ("test3 test3", result3->string);
EXPECT_EQ(3U, ConstructorTracker::constructor_called);
EXPECT_EQ(0U, ConstructorTracker::copy_constructor_called);
EXPECT_EQ(2U, ConstructorTracker::move_constructor_called);
EXPECT_EQ(0U, ConstructorTracker::copy_assignment_called);
EXPECT_EQ(0U, ConstructorTracker::move_assignment_called);
}
// Below two tests require that we do not hide the move constructor with our forwarding reference
// constructor. This is done with by disabling the forwarding reference constructor if its first
// and only type is Result<T>.
TEST(result, result_result_with_success) {
auto return_result_result_with_success = []() -> Result<Result<void>> { return Result<void>(); };
auto result = return_result_result_with_success();
ASSERT_RESULT_OK(result);
ASSERT_RESULT_OK(*result);
auto inner_result = result.value();
ASSERT_RESULT_OK(inner_result);
}
TEST(result, result_result_with_failure) {
auto return_result_result_with_error = []() -> Result<Result<void>> {
return Result<void>(ResultError("failure string", 6));
};
auto result = return_result_result_with_error();
ASSERT_RESULT_OK(result);
ASSERT_FALSE(result->ok());
EXPECT_EQ("failure string", (*result).error().message());
EXPECT_EQ(6, (*result).error().code());
}
// This test requires that we disable the forwarding reference constructor if Result<T> is the
// *only* type that we are forwarding. In otherwords, if we are forwarding Result<T>, int to
// construct a Result<T>, then we still need the constructor.
TEST(result, result_two_parameter_constructor_same_type) {
struct TestStruct {
TestStruct(int value) : value_(value) {}
TestStruct(Result<TestStruct> result, int value) : value_(result->value_ * value) {}
int value_;
};
auto return_test_struct = []() -> Result<TestStruct> {
return Result<TestStruct>(std::in_place, Result<TestStruct>(std::in_place, 6), 6);
};
auto result = return_test_struct();
ASSERT_RESULT_OK(result);
EXPECT_EQ(36, result->value_);
}
TEST(result, die_on_access_failed_result) {
Result<std::string> result = Error();
ASSERT_DEATH(*result, "");
}
TEST(result, die_on_get_error_succesful_result) {
Result<std::string> result = "success";
ASSERT_DEATH(result.error(), "");
}
template <class CharT>
std::basic_ostream<CharT>& SetErrnoToTwo(std::basic_ostream<CharT>& ss) {
errno = 2;
return ss;
}
TEST(result, preserve_errno) {
errno = 1;
int old_errno = errno;
Result<int> result = Error() << "Failed" << SetErrnoToTwo<char>;
ASSERT_FALSE(result.ok());
EXPECT_EQ(old_errno, errno);
errno = 1;
old_errno = errno;
Result<int> result2 = ErrnoError() << "Failed" << SetErrnoToTwo<char>;
ASSERT_FALSE(result2.ok());
EXPECT_EQ(old_errno, errno);
EXPECT_EQ(old_errno, result2.error().code());
}
TEST(result, error_with_fmt) {
Result<int> result = Errorf("{} {}!", "hello", "world");
EXPECT_EQ("hello world!", result.error().message());
result = Errorf("{} {}!", std::string("hello"), std::string("world"));
EXPECT_EQ("hello world!", result.error().message());
result = Errorf("{1} {0}!", "world", "hello");
EXPECT_EQ("hello world!", result.error().message());
result = Errorf("hello world!");
EXPECT_EQ("hello world!", result.error().message());
Result<int> result2 = Errorf("error occurred with {}", result.error());
EXPECT_EQ("error occurred with hello world!", result2.error().message());
constexpr int test_errno = 6;
errno = test_errno;
result = ErrnoErrorf("{} {}!", "hello", "world");
EXPECT_EQ(test_errno, result.error().code());
EXPECT_EQ("hello world!: "s + strerror(test_errno), result.error().message());
}
TEST(result, error_with_fmt_carries_errno) {
constexpr int inner_errno = 6;
errno = inner_errno;
Result<int> inner_result = ErrnoErrorf("inner failure");
errno = 0;
EXPECT_EQ(inner_errno, inner_result.error().code());
// outer_result is created with Errorf, but its error code is got from inner_result.
Result<int> outer_result = Errorf("outer failure caused by {}", inner_result.error());
EXPECT_EQ(inner_errno, outer_result.error().code());
EXPECT_EQ("outer failure caused by inner failure: "s + strerror(inner_errno),
outer_result.error().message());
// now both result objects are created with ErrnoErrorf. errno from the inner_result
// is not passed to outer_result.
constexpr int outer_errno = 10;
errno = outer_errno;
outer_result = ErrnoErrorf("outer failure caused by {}", inner_result.error());
EXPECT_EQ(outer_errno, outer_result.error().code());
EXPECT_EQ("outer failure caused by inner failure: "s + strerror(inner_errno) + ": "s +
strerror(outer_errno),
outer_result.error().message());
}
TEST(result, errno_chaining_multiple) {
constexpr int errno1 = 6;
errno = errno1;
Result<int> inner1 = ErrnoErrorf("error1");
constexpr int errno2 = 10;
errno = errno2;
Result<int> inner2 = ErrnoErrorf("error2");
// takes the error code of inner2 since its the last one.
Result<int> outer = Errorf("two errors: {}, {}", inner1.error(), inner2.error());
EXPECT_EQ(errno2, outer.error().code());
EXPECT_EQ("two errors: error1: "s + strerror(errno1) + ", error2: "s + strerror(errno2),
outer.error().message());
}
} // namespace base
} // namespace android