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AI 自动生成测试用例

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lids 2026-05-12 11:31:39 +08:00
parent 3b3119277e
commit ffe2d76bc7
1 changed files with 400 additions and 237 deletions
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tests/test_alert_manager.cpp
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#include "gtest/gtest.h"
#include <gtest/gtest.h>
#include "alert_manager.hpp"
#include <vector>
#include <string>
#include <sstream>
#include <iostream>
// Mock for time to ensure deterministic tests
static uint32_t mock_timestamp = 1640995200; // 2022-01-01 00:00:00 UTC
class MockTime {
// 辅助类:用于捕获标准输出和标准错误输出
class StreamCapture {
public:
static uint32_t getTimestamp() { return mock_timestamp; }
static void setTimestamp(uint32_t t) { mock_timestamp = t; }
};
// Helper function to compare AlertInfo
bool operator==(const AlertInfo& a, const AlertInfo& b) {
return a.type == b.type &&
a.status == b.status &&
a.trigger_time == b.trigger_time &&
a.acknowledge_time == b.acknowledge_time &&
a.resolve_time == b.resolve_time &&
a.description == b.description;
StreamCapture() : old_cout_(std::cout.rdbuf()), old_cerr_(std::cerr.rdbuf()) {
std::cout.rdbuf(ss_cout_.rdbuf());
std::cerr.rdbuf(ss_cerr_.rdbuf());
}
// Test fixture
~StreamCapture() {
std::cout.rdbuf(old_cout_);
std::cerr.rdbuf(old_cerr_);
}
std::string getCout() const { return ss_cout_.str(); }
std::string getCerr() const { return ss_cerr_.str(); }
private:
std::stringstream ss_cout_;
std::stringstream ss_cerr_;
std::streambuf* old_cout_;
std::streambuf* old_cerr_;
};
// 测试夹具:为每个测试用例创建独立的 AlertManager 实例
class AlertManagerTest : public ::testing::Test {
protected:
AlertManager manager;
void SetUp() override {
mock_timestamp = 1640995200;
manager.initialize();
}
void TearDown() override {
manager.clearHistory();
manager.resetAllAlerts();
}
AlertManager manager;
};
TEST_F(AlertManagerTest, testAlertManagerDefaultInitialization) {
EXPECT_FLOAT_EQ(manager.getAltitudeThresholds().first, 100.0f);
EXPECT_FLOAT_EQ(manager.getAltitudeThresholds().second, -50.0f);
EXPECT_TRUE(manager.getActiveAlerts().empty());
EXPECT_TRUE(manager.getAlertHistory(10).empty());
}
// ==================== checkAltitudeAlert 测试 ====================
TEST_F(AlertManagerTest, testInitialize) {
// No direct output assertion, but verify initialization logic
// This is tested implicitly via constructor
EXPECT_NO_FATAL_FAILURE(manager.initialize());
}
// 正常输入测试:高度在阈值范围内,不应触发任何预警
TEST_F(AlertManagerTest, testCheckAltitudeAlertNormalRange) {
StreamCapture capture;
TEST_F(AlertManagerTest, testCheckAltitudeAlertNormal) {
mock_timestamp = 1640995200;
manager.checkAltitudeAlert(105.0f, mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_EQ(alerts.size(), 1);
EXPECT_EQ(alerts[0].type, AlertType::ALTITUDE_UPPER);
EXPECT_EQ(alerts[0].status, AlertStatus::ACTIVE);
EXPECT_EQ(alerts[0].trigger_time, mock_timestamp);
}
// 默认阈值上限100.0,下限-50.0
// 测试正常高度 50.0
manager.checkAltitudeAlert(50.0f, 1000);
TEST_F(AlertManagerTest, testCheckAltitudeAlertBelowLower) {
mock_timestamp = 1640995200;
manager.checkAltitudeAlert(-55.0f, mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_EQ(alerts.size(), 1);
EXPECT_EQ(alerts[0].type, AlertType::ALTITUDE_LOWER);
EXPECT_EQ(alerts[0].status, AlertStatus::ACTIVE);
}
TEST_F(AlertManagerTest, testCheckAltitudeAlertResetWhenNormal) {
mock_timestamp = 1640995200;
manager.checkAltitudeAlert(105.0f, mock_timestamp); // Trigger upper
mock_timestamp = 1640995201;
manager.checkAltitudeAlert(90.0f, mock_timestamp); // Reset
auto alerts = manager.getActiveAlerts();
EXPECT_TRUE(alerts.empty());
}
TEST_F(AlertManagerTest, testSetAltitudeThresholdsValid) {
manager.setAltitudeThresholds(200.0f, -100.0f);
auto thresholds = manager.getAltitudeThresholds();
EXPECT_FLOAT_EQ(thresholds.first, 200.0f);
EXPECT_FLOAT_EQ(thresholds.second, -100.0f);
}
TEST_F(AlertManagerTest, testSetAltitudeThresholdsInvalid) {
EXPECT_NO_FATAL_FAILURE(manager.setAltitudeThresholds(50.0f, 100.0f));
// Should print error, but no crash
EXPECT_FLOAT_EQ(manager.getAltitudeThresholds().first, 100.0f);
EXPECT_FLOAT_EQ(manager.getAltitudeThresholds().second, -50.0f);
}
TEST_F(AlertManagerTest, testTriggerSensorFailure) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_EQ(alerts.size(), 1);
EXPECT_EQ(alerts[0].type, AlertType::SENSOR_FAILURE);
EXPECT_EQ(alerts[0].status, AlertStatus::ACTIVE);
EXPECT_EQ(alerts[0].trigger_time, mock_timestamp);
}
TEST_F(AlertManagerTest, testTriggerLowBattery) {
mock_timestamp = 1640995200;
manager.triggerLowBattery(mock_timestamp, 15.0f);
auto alerts = manager.getActiveAlerts();
EXPECT_EQ(alerts.size(), 1);
EXPECT_EQ(alerts[0].type, AlertType::LOW_BATTERY);
EXPECT_EQ(alerts[0].status, AlertStatus::ACTIVE);
EXPECT_NE(alerts[0].description.find("15.0%"), std::string::npos);
}
TEST_F(AlertManagerTest, testTriggerCommunicationError) {
mock_timestamp = 1640995200;
manager.triggerCommunicationError(mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_EQ(alerts.size(), 1);
EXPECT_EQ(alerts[0].type, AlertType::COMMUNICATION_ERROR);
EXPECT_EQ(alerts[0].status, AlertStatus::ACTIVE);
}
TEST_F(AlertManagerTest, testAcknowledgeAllAlerts) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
manager.triggerLowBattery(mock_timestamp + 1, 10.0f);
mock_timestamp = 1640995202;
manager.acknowledgeAllAlerts(mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_TRUE(alerts.empty());
EXPECT_EQ(alerts.size(), 0);
}
TEST_F(AlertManagerTest, testAcknowledgeAlert) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
mock_timestamp = 1640995201;
manager.acknowledgeAlert(AlertType::SENSOR_FAILURE, mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_TRUE(alerts.empty());
}
TEST_F(AlertManagerTest, testResetAlert) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
manager.resetAlert(AlertType::SENSOR_FAILURE);
auto alerts = manager.getActiveAlerts();
EXPECT_TRUE(alerts.empty());
}
TEST_F(AlertManagerTest, testResetAllAlerts) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
manager.triggerLowBattery(mock_timestamp + 1, 10.0f);
manager.resetAllAlerts();
auto alerts = manager.getActiveAlerts();
EXPECT_TRUE(alerts.empty());
}
TEST_F(AlertManagerTest, testHasActiveAlerts) {
EXPECT_FALSE(manager.hasActiveAlerts());
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
EXPECT_FALSE(manager.hasUnacknowledgedAlerts());
// 测试接近上限但未超过
manager.checkAltitudeAlert(99.9f, 1001);
EXPECT_FALSE(manager.hasActiveAlerts());
// 测试接近下限但未低于
manager.checkAltitudeAlert(-49.9f, 1002);
EXPECT_FALSE(manager.hasActiveAlerts());
}
// 边界值测试:高度刚好等于阈值,不应触发预警
TEST_F(AlertManagerTest, testCheckAltitudeAlertAtThreshold) {
StreamCapture capture;
// 测试高度等于上限
manager.checkAltitudeAlert(100.0f, 2000);
EXPECT_FALSE(manager.hasActiveAlerts());
// 测试高度等于下限
manager.checkAltitudeAlert(-50.0f, 2001);
EXPECT_FALSE(manager.hasActiveAlerts());
}
// 边界值测试:高度超过上限,应触发 ALTITUDE_UPPER 预警
TEST_F(AlertManagerTest, testCheckAltitudeAlertExceedsUpper) {
StreamCapture capture;
// 高度超过上限
manager.checkAltitudeAlert(150.0f, 3000);
EXPECT_TRUE(manager.hasActiveAlerts());
EXPECT_TRUE(manager.hasUnacknowledgedAlerts());
auto activeAlerts = manager.getActiveAlerts();
ASSERT_EQ(1, activeAlerts.size());
EXPECT_EQ(AlertType::ALTITUDE_UPPER, activeAlerts[0].type);
EXPECT_EQ(AlertStatus::ACTIVE, activeAlerts[0].status);
EXPECT_EQ(3000, activeAlerts[0].trigger_time);
// 验证输出包含预警信息
std::string coutOutput = capture.getCout();
EXPECT_NE(std::string::npos, coutOutput.find("高度上限预警"));
EXPECT_NE(std::string::npos, coutOutput.find("150"));
}
// 边界值测试:高度低于下限,应触发 ALTITUDE_LOWER 预警
TEST_F(AlertManagerTest, testCheckAltitudeAlertBelowLower) {
StreamCapture capture;
// 高度低于下限
manager.checkAltitudeAlert(-100.0f, 4000);
EXPECT_TRUE(manager.hasActiveAlerts());
EXPECT_TRUE(manager.hasUnacknowledgedAlerts());
auto activeAlerts = manager.getActiveAlerts();
ASSERT_EQ(1, activeAlerts.size());
EXPECT_EQ(AlertType::ALTITUDE_LOWER, activeAlerts[0].type);
EXPECT_EQ(AlertStatus::ACTIVE, activeAlerts[0].status);
EXPECT_EQ(4000, activeAlerts[0].trigger_time);
// 验证输出包含预警信息
std::string coutOutput = capture.getCout();
EXPECT_NE(std::string::npos, coutOutput.find("高度下限预警"));
EXPECT_NE(std::string::npos, coutOutput.find("-100"));
}
// 特殊场景测试:高度超过上限后恢复正常,预警应解除
TEST_F(AlertManagerTest, testCheckAltitudeAlertUpperResolved) {
StreamCapture capture;
// 先触发上限预警
manager.checkAltitudeAlert(150.0f, 5000);
EXPECT_TRUE(manager.hasActiveAlerts());
// 高度恢复正常
manager.checkAltitudeAlert(80.0f, 5001);
// 预警应被解决
EXPECT_FALSE(manager.hasActiveAlerts());
EXPECT_FALSE(manager.hasUnacknowledgedAlerts());
// 验证历史记录中存在已解决的预警
auto history = manager.getAlertHistory(10);
bool foundResolved = false;
for (const auto& alert : history) {
if (alert.type == AlertType::ALTITUDE_UPPER &&
alert.status == AlertStatus::RESOLVED) {
foundResolved = true;
break;
}
}
EXPECT_TRUE(foundResolved);
}
// 特殊场景测试:高度低于下限后恢复正常,预警应解除
TEST_F(AlertManagerTest, testCheckAltitudeAlertLowerResolved) {
StreamCapture capture;
// 先触发下限预警
manager.checkAltitudeAlert(-100.0f, 6000);
EXPECT_TRUE(manager.hasActiveAlerts());
// 高度恢复正常
manager.checkAltitudeAlert(0.0f, 6001);
// 预警应被解决
EXPECT_FALSE(manager.hasActiveAlerts());
EXPECT_FALSE(manager.hasUnacknowledgedAlerts());
// 验证历史记录
auto history = manager.getAlertHistory(10);
bool foundResolved = false;
for (const auto& alert : history) {
if (alert.type == AlertType::ALTITUDE_LOWER &&
alert.status == AlertStatus::RESOLVED) {
foundResolved = true;
break;
}
}
EXPECT_TRUE(foundResolved);
}
// 特殊场景测试:同时超过上下限(理论上不可能,但测试逻辑完整性)
TEST_F(AlertManagerTest, testCheckAltitudeAlertBothThresholds) {
StreamCapture capture;
// 修改阈值使上下限重叠(通过 setAltitudeThresholds 会校验,这里直接测试逻辑)
// 注意:此测试仅验证 checkAltitudeAlert 的逻辑,不依赖阈值设置
// 先触发上限预警
manager.checkAltitudeAlert(150.0f, 7000);
EXPECT_TRUE(manager.hasActiveAlerts());
// 再触发下限预警(此时高度低于下限)
manager.checkAltitudeAlert(-100.0f, 7001);
// 应有 2 个活动预警
auto activeAlerts = manager.getActiveAlerts();
EXPECT_EQ(2, activeAlerts.size());
}
// 异常输入测试:高度为 NaN如果支持
TEST_F(AlertManagerTest, testCheckAltitudeAlertNaN) {
StreamCapture capture;
// 使用 NaN 值(如果编译器支持)
float nanValue = std::numeric_limits<float>::quiet_NaN();
// NaN 与任何值的比较结果都是 false因此不会触发预警
manager.checkAltitudeAlert(nanValue, 8000);
// 不应触发任何预警
EXPECT_FALSE(manager.hasActiveAlerts());
}
// 异常输入测试:高度为无穷大
TEST_F(AlertManagerTest, testCheckAltitudeAlertInfinity) {
StreamCapture capture;
float infValue = std::numeric_limits<float>::infinity();
// 正无穷应触发上限预警
manager.checkAltitudeAlert(infValue, 9000);
EXPECT_TRUE(manager.hasActiveAlerts());
auto activeAlerts = manager.getActiveAlerts();
ASSERT_EQ(1, activeAlerts.size());
EXPECT_EQ(AlertType::ALTITUDE_UPPER, activeAlerts[0].type);
}
// 异常输入测试:高度为负无穷
TEST_F(AlertManagerTest, testCheckAltitudeAlertNegativeInfinity) {
StreamCapture capture;
float negInfValue = -std::numeric_limits<float>::infinity();
// 负无穷应触下限预警
manager.checkAltitudeAlert(negInfValue, 10000);
EXPECT_TRUE(manager.hasActiveAlerts());
auto activeAlerts = manager.getActiveAlerts();
ASSERT_EQ(1, activeAlerts.size());
EXPECT_EQ(AlertType::ALTITUDE_LOWER, activeAlerts[0].type);
}
// 特殊场景测试:时间戳为 0
TEST_F(AlertManagerTest, testCheckAltitudeAlertTimestampZero) {
StreamCapture capture;
// 时间戳为 0 不应影响预警逻辑
manager.checkAltitudeAlert(150.0f, 0);
EXPECT_TRUE(manager.hasActiveAlerts());
auto activeAlerts = manager.getActiveAlerts();
ASSERT_EQ(1, activeAlerts.size());
EXPECT_EQ(0, activeAlerts[0].trigger_time);
}
// 特殊场景测试:连续多次触发同一预警,不应重复触发
TEST_F(AlertManagerTest, testCheckAltitudeAlertDuplicateTrigger) {
StreamCapture capture;
// 第一次触发
manager.checkAltitudeAlert(150.0f, 11000);
EXPECT_TRUE(manager.hasActiveAlerts());
// 第二次触发(高度仍然超过上限)
manager.checkAltitudeAlert(200.0f, 11001);
// 应仍只有 1 个活动预警
auto activeAlerts = manager.getActiveAlerts();
ASSERT_EQ(1, activeAlerts.size());
// 验证历史记录中只有 1 次触发
auto history = manager.getAlertHistory(10);
int triggerCount = 0;
for (const auto& alert : history) {
if (alert.type == AlertType::ALTITUDE_UPPER &&
alert.status == AlertStatus::ACTIVE) {
triggerCount++;
}
}
EXPECT_EQ(1, triggerCount);
}
// ==================== setAltitudeThresholds 测试 ====================
// 正常输入测试:设置有效的上下限阈值
TEST_F(AlertManagerTest, testSetAltitudeThresholdsValid) {
StreamCapture capture;
manager.setAltitudeThresholds(200.0f, -100.0f);
// 验证输出
std::string coutOutput = capture.getCout();
EXPECT_NE(std::string::npos, coutOutput.find("预警阈值已更新"));
EXPECT_NE(std::string::npos, coutOutput.find("200"));
EXPECT_NE(std::string::npos, coutOutput.find("-100"));
// 验证新阈值生效
manager.checkAltitudeAlert(150.0f, 12000);
EXPECT_FALSE(manager.hasActiveAlerts());
manager.checkAltitudeAlert(250.0f, 12001);
EXPECT_TRUE(manager.hasActiveAlerts());
}
TEST_F(AlertManagerTest, testHasUnacknowledgedAlerts) {
EXPECT_FALSE(manager.hasUnacknowledgedAlerts());
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
EXPECT_TRUE(manager.hasUnacknowledgedAlerts());
manager.acknowledgeAllAlerts(mock_timestamp + 1);
EXPECT_FALSE(manager.hasUnacknowledgedAlerts());
// 边界值测试:设置上限等于下限(非法)
TEST_F(AlertManagerTest, testSetAltitudeThresholdsEqual) {
StreamCapture capture;
manager.setAltitudeThresholds(100.0f, 100.0f);
// 验证错误输出
std::string cerrOutput = capture.getCerr();
EXPECT_NE(std::string::npos, cerrOutput.find("上限阈值必须大于下限阈值"));
// 验证阈值未改变
manager.checkAltitudeAlert(150.0f, 13000);
EXPECT_TRUE(manager.hasActiveAlerts());
}
TEST_F(AlertManagerTest, testGetActiveAlerts) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_EQ(alerts.size(), 1);
EXPECT_EQ(alerts[0].type, AlertType::SENSOR_FAILURE);
// 异常输入测试:设置上限小于下限(非法)
TEST_F(AlertManagerTest, testSetAltitudeThresholdsUpperLessThanLower) {
StreamCapture capture;
manager.setAltitudeThresholds(-50.0f, 100.0f);
// 验证错误输出
std::string cerrOutput = capture.getCerr();
EXPECT_NE(std::string::npos, cerrOutput.find("上限阈值必须大于下限阈值"));
// 验证阈值未改变
manager.checkAltitudeAlert(150.0f, 14000);
EXPECT_TRUE(manager.hasActiveAlerts());
}
TEST_F(AlertManagerTest, testGetAlertHistoryMaxCount) {
mock_timestamp = 1640995200;
for (int i = 0; i < 15; ++i) {
manager.triggerSensorFailure(mock_timestamp + i);
// 边界值测试:设置非常大的阈值范围
TEST_F(AlertManagerTest, testSetAltitudeThresholdsLargeRange) {
StreamCapture capture;
float largeUpper = 1000000.0f;
float largeLower = -1000000.0f;
manager.setAltitudeThresholds(largeUpper, largeLower);
// 验证阈值设置成功
manager.checkAltitudeAlert(500000.0f, 15000);
EXPECT_FALSE(manager.hasActiveAlerts());
manager.checkAltitudeAlert(2000000.0f, 15001);
EXPECT_TRUE(manager.hasActiveAlerts());
}
// 边界值测试:设置非常小的阈值范围
TEST_F(AlertManagerTest, testSetAltitudeThresholdsSmallRange) {
StreamCapture capture;
float smallUpper = 0.001f;
float smallLower = -0.001f;
manager.setAltitudeThresholds(smallUpper, smallLower);
// 验证阈值设置成功
manager.checkAltitudeAlert(0.0005f, 16000);
EXPECT_FALSE(manager.hasActiveAlerts());
manager.checkAltitudeAlert(0.002f, 16001);
EXPECT_TRUE(manager.hasActiveAlerts());
}
// 特殊场景测试:设置阈值后,原有的活动预警应被重置
TEST_F(AlertManagerTest, testSetAltitudeThresholdsResetsAlerts) {
StreamCapture capture;
// 先触发一个预警
manager.checkAltitudeAlert(150.0f, 17000);
EXPECT_TRUE(manager.hasActiveAlerts());
// 修改阈值
manager.setAltitudeThresholds(200.0f, -100.0f);
// 原有的预警应被重置(解决)
EXPECT_FALSE(manager.hasActiveAlerts());
// 验证历史记录中存在已解决的预警
auto history = manager.getAlertHistory(10);
EXPECT_EQ(history.size(), 10);
bool foundResolved = false;
for (const auto& alert : history) {
if (alert.type == AlertType::ALTITUDE_UPPER &&
alert.status == AlertStatus::RESOLVED) {
foundResolved = true;
break;
}
}
EXPECT_TRUE(foundResolved);
}
TEST_F(AlertManagerTest, testGetStatusDescriptionNoAlerts) {
std::string desc = manager.getStatusDescription();
EXPECT_EQ(desc, "系统状态:正常");
// 特殊场景测试:连续设置阈值,验证状态一致性
TEST_F(AlertManagerTest, testSetAltitudeThresholdsMultipleTimes) {
StreamCapture capture;
// 第一次设置
manager.setAltitudeThresholds(200.0f, -100.0f);
// 触发预警
manager.checkAltitudeAlert(250.0f, 18000);
EXPECT_TRUE(manager.hasActiveAlerts());
// 第二次设置
manager.setAltitudeThresholds(300.0f, -200.0f);
// 原有预警被重置
EXPECT_FALSE(manager.hasActiveAlerts());
// 新阈值下,原来的高度不再触发预警
manager.checkAltitudeAlert(250.0f, 18001);
EXPECT_FALSE(manager.hasActiveAlerts());
}
TEST_F(AlertManagerTest, testGetStatusDescriptionWithAlerts) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
std::string desc = manager.getStatusDescription();
EXPECT_NE(desc.find("有1个活动预警"), std::string::npos);
EXPECT_NE(desc.find("传感器故障"), std::string::npos);
}
// 特殊场景测试:设置阈值后立即检查高度
TEST_F(AlertManagerTest, testSetAltitudeThresholdsImmediateCheck) {
StreamCapture capture;
TEST_F(AlertManagerTest, testClearHistory) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
manager.clearHistory();
EXPECT_TRUE(manager.getAlertHistory(10).empty());
}
// 设置新阈值
manager.setAltitudeThresholds(50.0f, -10.0f);
TEST_F(AlertManagerTest, testAddToHistoryLimit) {
mock_timestamp = 1640995200;
for (int i = 0; i < 100; ++i) {
manager.triggerSensorFailure(mock_timestamp + i);
}
auto history = manager.getAlertHistory(10);
EXPECT_EQ(history.size(), 10);
}
// 立即检查高度,应触发预警
manager.checkAltitudeAlert(60.0f, 19000);
EXPECT_TRUE(manager.hasActiveAlerts());
TEST_F(AlertManagerTest, testTriggerAlert) {
mock_timestamp = 1640995200;
manager.triggerAlert(AlertType::SENSOR_FAILURE, mock_timestamp, "Test alert");
auto alerts = manager.getActiveAlerts();
EXPECT_EQ(alerts.size(), 1);
EXPECT_EQ(alerts[0].description, "Test alert");
}
TEST_F(AlertManagerTest, testUpdateAlertStatusAcknowledged) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
mock_timestamp = 1640995201;
manager.updateAlertStatus(AlertType::SENSOR_FAILURE, AlertStatus::ACKNOWLEDGED, mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_TRUE(alerts.empty());
}
TEST_F(AlertManagerTest, testUpdateAlertStatusResolved) {
mock_timestamp = 1640995200;
manager.triggerSensorFailure(mock_timestamp);
mock_timestamp = 1640995201;
manager.updateAlertStatus(AlertType::SENSOR_FAILURE, AlertStatus::RESOLVED, mock_timestamp);
auto alerts = manager.getActiveAlerts();
EXPECT_TRUE(alerts.empty());
}
TEST_F(AlertManagerTest, testGetAlertTypeName) {
EXPECT_EQ(manager.getAlertTypeName(AlertType::ALTITUDE_UPPER), "高度上限预警");
EXPECT_EQ(manager.getAlertTypeName(AlertType::NONE), "");
EXPECT_EQ(manager.getAlertTypeName(static_cast<AlertType>(99)), "未知预警");
}
TEST_F(AlertManagerTest, testGetAlertStatusName) {
EXPECT_EQ(manager.getAlertStatusName(AlertStatus::ACTIVE), "预警中");
EXPECT_EQ(manager.getAlertStatusName(AlertStatus::INACTIVE), "未激活");
EXPECT_EQ(manager.getAlertStatusName(static_cast<AlertStatus>(99)), "未知状态");
}
TEST_F(AlertManagerTest, testDestructorDoesNotCrash) {
// Verify destructor doesn't throw or crash
EXPECT_NO_FATAL_FAILURE({
AlertManager* mgr = new AlertManager();
delete mgr;
});
auto activeAlerts = manager.getActiveAlerts();
ASSERT_EQ(1, activeAlerts.size());
EXPECT_EQ(AlertType::ALTITUDE_UPPER, activeAlerts[0].type);
}