Merge branch 'development' into mueller/possible-ring-buffer-fix

This commit is contained in:
Robin Müller 2022-04-27 08:42:24 +02:00
commit d3e7037759
32 changed files with 437 additions and 117 deletions

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@ -31,6 +31,12 @@ and this project adheres to [Semantic Versioning](http://semver.org/).
creation call. It allows passing context information and an arbitrary user argument into
the message queue. Also streamlined and simplified `MessageQueue` implementation for all OSALs
PR: https://egit.irs.uni-stuttgart.de/fsfw/fsfw/pulls/583
- Clock:
- `timeval` to `TimeOfDay_t`
- Added Mutex for gmtime calls: (compare http://www.opengate.at/blog/2020/01/timeless/)
- Moved the statics used by Clock in ClockCommon.cpp to this file
- Better check for leap seconds
- Added Unittests for Clock (only getter)
## Removed
@ -51,6 +57,9 @@ and this project adheres to [Semantic Versioning](http://semver.org/).
- Small bugfix in STM32 HAL for SPI
PR: https://egit.irs.uni-stuttgart.de/fsfw/fsfw/pulls/599
- HAL GPIO: Improved error checking in `LinuxLibgpioIF::configureGpios(...)`. If a GPIO
configuration fails, the function will exit prematurely with a dedicated error code
PR: https://egit.irs.uni-stuttgart.de/fsfw/fsfw/pulls/602
# [v4.0.0]

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@ -1,9 +1,9 @@
#include "MgmLIS3MDLHandler.h"
#include "fsfw/datapool/PoolReadGuard.h"
#include <cmath>
#include "fsfw/datapool/PoolReadGuard.h"
MgmLIS3MDLHandler::MgmLIS3MDLHandler(object_id_t objectId, object_id_t deviceCommunication,
CookieIF *comCookie, uint32_t transitionDelay)
: DeviceHandlerBase(objectId, deviceCommunication, comCookie),

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@ -44,6 +44,7 @@ ReturnValue_t LinuxLibgpioIF::addGpios(GpioCookie* gpioCookie) {
}
ReturnValue_t LinuxLibgpioIF::configureGpios(GpioMap& mapToAdd) {
ReturnValue_t result = RETURN_OK;
for (auto& gpioConfig : mapToAdd) {
auto& gpioType = gpioConfig.second->gpioType;
switch (gpioType) {
@ -55,7 +56,7 @@ ReturnValue_t LinuxLibgpioIF::configureGpios(GpioMap& mapToAdd) {
if (regularGpio == nullptr) {
return GPIO_INVALID_INSTANCE;
}
configureGpioByChip(gpioConfig.first, *regularGpio);
result = configureGpioByChip(gpioConfig.first, *regularGpio);
break;
}
case (gpio::GpioTypes::GPIO_REGULAR_BY_LABEL): {
@ -63,7 +64,7 @@ ReturnValue_t LinuxLibgpioIF::configureGpios(GpioMap& mapToAdd) {
if (regularGpio == nullptr) {
return GPIO_INVALID_INSTANCE;
}
configureGpioByLabel(gpioConfig.first, *regularGpio);
result = configureGpioByLabel(gpioConfig.first, *regularGpio);
break;
}
case (gpio::GpioTypes::GPIO_REGULAR_BY_LINE_NAME): {
@ -71,7 +72,7 @@ ReturnValue_t LinuxLibgpioIF::configureGpios(GpioMap& mapToAdd) {
if (regularGpio == nullptr) {
return GPIO_INVALID_INSTANCE;
}
configureGpioByLineName(gpioConfig.first, *regularGpio);
result = configureGpioByLineName(gpioConfig.first, *regularGpio);
break;
}
case (gpio::GpioTypes::CALLBACK): {
@ -83,8 +84,11 @@ ReturnValue_t LinuxLibgpioIF::configureGpios(GpioMap& mapToAdd) {
gpioCallback->initValue, gpioCallback->callbackArgs);
}
}
if (result != RETURN_OK) {
return GPIO_INIT_FAILED;
}
return RETURN_OK;
}
return result;
}
ReturnValue_t LinuxLibgpioIF::configureGpioByLabel(gpioId_t gpioId,

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@ -29,6 +29,8 @@ class LinuxLibgpioIF : public GpioIF, public SystemObject {
HasReturnvaluesIF::makeReturnCode(gpioRetvalId, 4);
static constexpr ReturnValue_t GPIO_DUPLICATE_DETECTED =
HasReturnvaluesIF::makeReturnCode(gpioRetvalId, 5);
static constexpr ReturnValue_t GPIO_INIT_FAILED =
HasReturnvaluesIF::makeReturnCode(gpioRetvalId, 6);
LinuxLibgpioIF(object_id_t objectId);
virtual ~LinuxLibgpioIF();

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@ -24,9 +24,7 @@ void UartCookie::setParityEven() { parity = Parity::EVEN; }
Parity UartCookie::getParity() const { return parity; }
void UartCookie::setBitsPerWord(BitsPerWord bitsPerWord_) {
bitsPerWord = bitsPerWord_;
}
void UartCookie::setBitsPerWord(BitsPerWord bitsPerWord_) { bitsPerWord = bitsPerWord_; }
BitsPerWord UartCookie::getBitsPerWord() const { return bitsPerWord; }

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@ -459,8 +459,7 @@ size_t DeviceHandlerBase::getNextReplyLength(DeviceCommandId_t commandId) {
DeviceCommandMap::iterator command = cookieInfo.pendingCommand;
if (command->second.useAlternativeReplyId) {
replyId = command->second.alternativeReplyId;
}
else {
} else {
replyId = commandId;
}
DeviceReplyIter iter = deviceReplyMap.find(replyId);

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@ -1,7 +1,7 @@
#include "MessageQueueBase.h"
MessageQueueBase::MessageQueueBase(MessageQueueId_t id, MessageQueueId_t defaultDest,
MqArgs* args): id(id) {
MessageQueueBase::MessageQueueBase(MessageQueueId_t id, MessageQueueId_t defaultDest, MqArgs* args)
: id(id) {
this->defaultDest = defaultDest;
if (args != nullptr) {
this->args = *args;
@ -29,29 +29,19 @@ ReturnValue_t MessageQueueBase::receiveMessage(MessageQueueMessageIF* message,
return status;
}
MessageQueueId_t MessageQueueBase::getLastPartner() const {
return last;
}
MessageQueueId_t MessageQueueBase::getLastPartner() const { return last; }
MessageQueueId_t MessageQueueBase::getId() const {
return id;
}
MessageQueueId_t MessageQueueBase::getId() const { return id; }
MqArgs& MessageQueueBase::getMqArgs() {
return args;
}
MqArgs& MessageQueueBase::getMqArgs() { return args; }
void MessageQueueBase::setDefaultDestination(MessageQueueId_t defaultDestination) {
this->defaultDest = defaultDestination;
}
MessageQueueId_t MessageQueueBase::getDefaultDestination() const {
return defaultDest;
}
MessageQueueId_t MessageQueueBase::getDefaultDestination() const { return defaultDest; }
bool MessageQueueBase::isDefaultDestinationSet() const {
return (defaultDest != NO_QUEUE);
}
bool MessageQueueBase::isDefaultDestinationSet() const { return (defaultDest != NO_QUEUE); }
ReturnValue_t MessageQueueBase::sendMessage(MessageQueueId_t sendTo, MessageQueueMessageIF* message,
bool ignoreFault) {

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@ -1,8 +1,8 @@
#ifndef FSFW_SRC_FSFW_IPC_MESSAGEQUEUEBASE_H_
#define FSFW_SRC_FSFW_IPC_MESSAGEQUEUEBASE_H_
#include <fsfw/ipc/definitions.h>
#include <fsfw/ipc/MessageQueueIF.h>
#include <fsfw/ipc/definitions.h>
class MessageQueueBase : public MessageQueueIF {
public:
@ -22,13 +22,14 @@ public:
virtual ReturnValue_t reply(MessageQueueMessageIF* message) override;
virtual ReturnValue_t receiveMessage(MessageQueueMessageIF* message,
MessageQueueId_t* receivedFrom) override;
virtual ReturnValue_t sendToDefaultFrom(MessageQueueMessageIF* message,
MessageQueueId_t sentFrom, bool ignoreFault = false) override;
virtual ReturnValue_t sendToDefaultFrom(MessageQueueMessageIF* message, MessageQueueId_t sentFrom,
bool ignoreFault = false) override;
// OSAL specific, forward the abstract function
virtual ReturnValue_t receiveMessage(MessageQueueMessageIF* message) = 0;
virtual ReturnValue_t sendMessageFrom(MessageQueueId_t sendTo, MessageQueueMessageIF* message,
MessageQueueId_t sentFrom, bool ignoreFault = false) = 0;
protected:
MessageQueueId_t id = MessageQueueIF::NO_QUEUE;
MessageQueueId_t last = MessageQueueIF::NO_QUEUE;
@ -36,6 +37,4 @@ protected:
MqArgs args = {};
};
#endif /* FSFW_SRC_FSFW_IPC_MESSAGEQUEUEBASE_H_ */

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@ -2,6 +2,7 @@
#define FSFW_IPC_MESSAGEQUEUEIF_H_
#include <fsfw/ipc/definitions.h>
#include <cstdint>
#include "../returnvalues/HasReturnvaluesIF.h"
@ -45,7 +46,8 @@ class MessageQueueIF {
virtual ReturnValue_t reply(MessageQueueMessageIF* message) = 0;
/**
* @brief This function reads available messages from the message queue and returns the sender.
* @brief This function reads available messages from the message queue and returns the
* sender.
* @details
* It works identically to the other receiveMessage call, but in addition
* returns the sender's queue id.

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@ -11,9 +11,6 @@
// TODO sanitize input?
// TODO much of this code can be reused for tick-only systems
uint16_t Clock::leapSeconds = 0;
MutexIF* Clock::timeMutex = nullptr;
uint32_t Clock::getTicksPerSecond(void) { return 1000; }
ReturnValue_t Clock::setClock(const TimeOfDay_t* time) {

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@ -2,6 +2,7 @@
#define FSFW_OSAL_FREERTOS_MESSAGEQUEUE_H_
#include <fsfw/ipc/MessageQueueBase.h>
#include "FreeRTOS.h"
#include "TaskManagement.h"
#include "fsfw/internalerror/InternalErrorReporterIF.h"

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@ -2,6 +2,7 @@
#include <chrono>
#include "fsfw/ipc/MutexGuard.h"
#include "fsfw/platform.h"
#include "fsfw/serviceinterface/ServiceInterface.h"
@ -11,9 +12,6 @@
#include <fstream>
#endif
uint16_t Clock::leapSeconds = 0;
MutexIF* Clock::timeMutex = NULL;
using SystemClock = std::chrono::system_clock;
uint32_t Clock::getTicksPerSecond(void) {
@ -127,6 +125,13 @@ ReturnValue_t Clock::getDateAndTime(TimeOfDay_t* time) {
auto seconds = std::chrono::time_point_cast<std::chrono::seconds>(now);
auto fraction = now - seconds;
time_t tt = SystemClock::to_time_t(now);
ReturnValue_t result = checkOrCreateClockMutex();
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
MutexGuard helper(timeMutex);
// gmtime writes its output in a global buffer which is not Thread Safe
// Therefore we have to use a Mutex here
struct tm* timeInfo;
timeInfo = gmtime(&tt);
time->year = timeInfo->tm_year + 1900;

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@ -1,17 +1,17 @@
#ifndef FRAMEWORK_OSAL_HOST_MESSAGEQUEUE_H_
#define FRAMEWORK_OSAL_HOST_MESSAGEQUEUE_H_
#include "fsfw/ipc/MessageQueueBase.h"
#include <memory>
#include <queue>
#include "fsfw/internalerror/InternalErrorReporterIF.h"
#include "fsfw/ipc/MessageQueueBase.h"
#include "fsfw/ipc/MessageQueueIF.h"
#include "fsfw/ipc/MessageQueueMessage.h"
#include "fsfw/ipc/MutexIF.h"
#include "fsfw/ipc/definitions.h"
#include "fsfw/timemanager/Clock.h"
#include <memory>
#include <queue>
/**
* @brief This class manages sending and receiving of
* message queue messages.

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@ -8,11 +8,9 @@
#include <fstream>
#include "fsfw/ipc/MutexGuard.h"
#include "fsfw/serviceinterface/ServiceInterface.h"
uint16_t Clock::leapSeconds = 0;
MutexIF* Clock::timeMutex = NULL;
uint32_t Clock::getTicksPerSecond(void) {
uint32_t ticks = sysconf(_SC_CLK_TCK);
return ticks;
@ -117,7 +115,13 @@ ReturnValue_t Clock::getDateAndTime(TimeOfDay_t* time) {
// TODO errno
return HasReturnvaluesIF::RETURN_FAILED;
}
ReturnValue_t result = checkOrCreateClockMutex();
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
MutexGuard helper(timeMutex);
// gmtime writes its output in a global buffer which is not Thread Safe
// Therefore we have to use a Mutex here
struct tm* timeInfo;
timeInfo = gmtime(&timeUnix.tv_sec);
time->year = timeInfo->tm_year + 1900;

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@ -61,8 +61,7 @@ class MessageQueue : public MessageQueueBase {
ReturnValue_t receiveMessage(MessageQueueMessageIF* message) override;
ReturnValue_t flush(uint32_t* count) override;
ReturnValue_t sendMessageFrom(MessageQueueId_t sendTo, MessageQueueMessageIF* message,
MessageQueueId_t sentFrom,
bool ignoreFault = false) override;
MessageQueueId_t sentFrom, bool ignoreFault = false) override;
protected:
/**

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@ -6,9 +6,6 @@
#include "fsfw/ipc/MutexGuard.h"
#include "fsfw/osal/rtems/RtemsBasic.h"
uint16_t Clock::leapSeconds = 0;
MutexIF* Clock::timeMutex = nullptr;
uint32_t Clock::getTicksPerSecond(void) {
rtems_interval ticks_per_second = rtems_clock_get_ticks_per_second();
return static_cast<uint32_t>(ticks_per_second);

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@ -2,6 +2,7 @@
#define FSFW_OSAL_RTEMS_MESSAGEQUEUE_H_
#include <fsfw/ipc/MessageQueueBase.h>
#include "RtemsBasic.h"
#include "fsfw/internalerror/InternalErrorReporterIF.h"
#include "fsfw/ipc/MessageQueueIF.h"

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@ -67,7 +67,6 @@ class PeriodicTask : public RTEMSTaskBase, public PeriodicTaskIF {
*/
ReturnValue_t addComponent(ExecutableObjectIF *object) override;
uint32_t getPeriodMs() const override;
ReturnValue_t sleepFor(uint32_t ms) override;

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@ -91,7 +91,7 @@ ReturnValue_t CCSDSTime::convertFromCDS(Clock::TimeOfDay_t* to, const uint8_t* f
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
return convertTimevalToTimeOfDay(to, &time);
return Clock::convertTimevalToTimeOfDay(&time, to);
}
ReturnValue_t CCSDSTime::convertFromCCS(Clock::TimeOfDay_t* to, const uint8_t* from,
@ -489,11 +489,6 @@ ReturnValue_t CCSDSTime::checkTimeOfDay(const Clock::TimeOfDay_t* time) {
return RETURN_OK;
}
ReturnValue_t CCSDSTime::convertTimevalToTimeOfDay(Clock::TimeOfDay_t* to, timeval* from) {
// This is rather tricky. Implement only if needed. Also, if so, move to OSAL.
return UNSUPPORTED_TIME_FORMAT;
}
ReturnValue_t CCSDSTime::convertFromCDS(timeval* to, const uint8_t* from, size_t* foundLength,
size_t maxLength) {
uint8_t pField = *from;
@ -583,7 +578,7 @@ ReturnValue_t CCSDSTime::convertFromCDS(Clock::TimeOfDay_t* to, const CCSDSTime:
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
return CCSDSTime::convertTimevalToTimeOfDay(to, &tempTimeval);
return Clock::convertTimevalToTimeOfDay(&tempTimeval, to);
}
ReturnValue_t CCSDSTime::convertFromCUC(timeval* to, uint8_t pField, const uint8_t* from,

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@ -223,7 +223,6 @@ class CCSDSTime : public HasReturnvaluesIF {
uint8_t *day);
static bool isLeapYear(uint32_t year);
static ReturnValue_t convertTimevalToTimeOfDay(Clock::TimeOfDay_t *to, timeval *from);
};
#endif /* FSFW_TIMEMANAGER_CCSDSTIME_H_ */

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@ -99,6 +99,13 @@ class Clock {
*/
static ReturnValue_t getDateAndTime(TimeOfDay_t *time);
/**
* Convert to time of day struct given the POSIX timeval struct
* @param from
* @param to
* @return
*/
static ReturnValue_t convertTimevalToTimeOfDay(const timeval *from, TimeOfDay_t *to);
/**
* Converts a time of day struct to POSIX seconds.
* @param time The time of day as input
@ -166,6 +173,7 @@ class Clock {
static MutexIF *timeMutex;
static uint16_t leapSeconds;
static bool leapSecondsSet;
};
#endif /* FSFW_TIMEMANAGER_CLOCK_H_ */

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@ -1,6 +1,12 @@
#include <ctime>
#include "fsfw/ipc/MutexGuard.h"
#include "fsfw/timemanager/Clock.h"
uint16_t Clock::leapSeconds = 0;
MutexIF* Clock::timeMutex = nullptr;
bool Clock::leapSecondsSet = false;
ReturnValue_t Clock::convertUTCToTT(timeval utc, timeval* tt) {
uint16_t leapSeconds;
ReturnValue_t result = getLeapSeconds(&leapSeconds);
@ -27,12 +33,16 @@ ReturnValue_t Clock::setLeapSeconds(const uint16_t leapSeconds_) {
MutexGuard helper(timeMutex);
leapSeconds = leapSeconds_;
leapSecondsSet = true;
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t Clock::getLeapSeconds(uint16_t* leapSeconds_) {
if (timeMutex == nullptr) {
if (not leapSecondsSet) {
return HasReturnvaluesIF::RETURN_FAILED;
}
if (checkOrCreateClockMutex() != HasReturnvaluesIF::RETURN_OK) {
return HasReturnvaluesIF::RETURN_FAILED;
}
MutexGuard helper(timeMutex);
@ -42,6 +52,29 @@ ReturnValue_t Clock::getLeapSeconds(uint16_t *leapSeconds_) {
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t Clock::convertTimevalToTimeOfDay(const timeval* from, TimeOfDay_t* to) {
struct tm* timeInfo;
// According to https://en.cppreference.com/w/c/chrono/gmtime, the implementation of gmtime_s
// in the Windows CRT is incompatible with the C standard but this should not be an issue for
// this implementation
ReturnValue_t result = checkOrCreateClockMutex();
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
MutexGuard helper(timeMutex);
// gmtime writes its output in a global buffer which is not Thread Safe
// Therefore we have to use a Mutex here
timeInfo = gmtime(&from->tv_sec);
to->year = timeInfo->tm_year + 1900;
to->month = timeInfo->tm_mon + 1;
to->day = timeInfo->tm_mday;
to->hour = timeInfo->tm_hour;
to->minute = timeInfo->tm_min;
to->second = timeInfo->tm_sec;
to->usecond = from->tv_usec;
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t Clock::checkOrCreateClockMutex() {
if (timeMutex == nullptr) {
MutexFactory* mutexFactory = MutexFactory::instance();

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@ -1,8 +1,9 @@
#include "version.h"
#include "fsfw/FSFWVersion.h"
#include <cstdio>
#include "fsfw/FSFWVersion.h"
#ifdef major
#undef major
#endif

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@ -3,4 +3,5 @@ target_sources(${FSFW_TEST_TGT} PRIVATE
testOpDivider.cpp
testBitutil.cpp
testCRC.cpp
testTimevalOperations.cpp
)

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@ -0,0 +1,124 @@
#include <fsfw/globalfunctions/timevalOperations.h>
#include <catch2/catch_approx.hpp>
#include <catch2/catch_test_macros.hpp>
#include "fsfw_tests/unit/CatchDefinitions.h"
TEST_CASE("TimevalTest", "[timevalOperations]") {
SECTION("Comparison") {
timeval t1;
t1.tv_sec = 1648227422;
t1.tv_usec = 123456;
timeval t2;
t2.tv_sec = 1648227422;
t2.tv_usec = 123456;
REQUIRE(t1 == t2);
REQUIRE(t2 == t1);
REQUIRE_FALSE(t1 != t2);
REQUIRE_FALSE(t2 != t1);
REQUIRE(t1 <= t2);
REQUIRE(t2 <= t1);
REQUIRE(t1 >= t2);
REQUIRE(t2 >= t1);
REQUIRE_FALSE(t1 < t2);
REQUIRE_FALSE(t2 < t1);
REQUIRE_FALSE(t1 > t2);
REQUIRE_FALSE(t2 > t1);
timeval t3;
t3.tv_sec = 1648227422;
t3.tv_usec = 123457;
REQUIRE_FALSE(t1 == t3);
REQUIRE(t1 != t3);
REQUIRE(t1 <= t3);
REQUIRE_FALSE(t3 <= t1);
REQUIRE_FALSE(t1 >= t3);
REQUIRE(t3 >= t1);
REQUIRE(t1 < t3);
REQUIRE_FALSE(t3 < t1);
REQUIRE_FALSE(t1 > t3);
REQUIRE(t3 > t1);
timeval t4;
t4.tv_sec = 1648227423;
t4.tv_usec = 123456;
REQUIRE_FALSE(t1 == t4);
REQUIRE(t1 != t4);
REQUIRE(t1 <= t4);
REQUIRE_FALSE(t4 <= t1);
REQUIRE_FALSE(t1 >= t4);
REQUIRE(t4 >= t1);
REQUIRE(t1 < t4);
REQUIRE_FALSE(t4 < t1);
REQUIRE_FALSE(t1 > t4);
REQUIRE(t4 > t1);
}
SECTION("Operators") {
timeval t1;
t1.tv_sec = 1648227422;
t1.tv_usec = 123456;
timeval t2;
t2.tv_sec = 1648227422;
t2.tv_usec = 123456;
timeval t3 = t1 - t2;
REQUIRE(t3.tv_sec == 0);
REQUIRE(t3.tv_usec == 0);
timeval t4 = t1 - t3;
REQUIRE(t4.tv_sec == 1648227422);
REQUIRE(t4.tv_usec == 123456);
timeval t5 = t3 - t1;
REQUIRE(t5.tv_sec == -1648227422);
REQUIRE(t5.tv_usec == -123456);
timeval t6;
t6.tv_sec = 1648227400;
t6.tv_usec = 999999;
timeval t7 = t6 + t1;
REQUIRE(t7.tv_sec == (1648227422ull + 1648227400ull + 1ull));
REQUIRE(t7.tv_usec == 123455);
timeval t8 = t1 - t6;
REQUIRE(t8.tv_sec == 1648227422 - 1648227400 - 1);
REQUIRE(t8.tv_usec == 123457);
double scalar = 2;
timeval t9 = t1 * scalar;
REQUIRE(t9.tv_sec == 3296454844);
REQUIRE(t9.tv_usec == 246912);
timeval t10 = scalar * t1;
REQUIRE(t10.tv_sec == 3296454844);
REQUIRE(t10.tv_usec == 246912);
timeval t11 = t6 * scalar;
REQUIRE(t11.tv_sec == (3296454800 + 1));
REQUIRE(t11.tv_usec == 999998);
timeval t12 = t1 / scalar;
REQUIRE(t12.tv_sec == 824113711);
REQUIRE(t12.tv_usec == 61728);
timeval t13 = t6 / scalar;
REQUIRE(t13.tv_sec == 824113700);
// Rounding issue
REQUIRE(t13.tv_usec == 499999);
double scalar2 = t9 / t1;
REQUIRE(scalar2 == Catch::Approx(2.0));
double scalar3 = t1 / t6;
REQUIRE(scalar3 == Catch::Approx(1.000000013));
double scalar4 = t3 / t1;
REQUIRE(scalar4 == Catch::Approx(0));
double scalar5 = t12 / t1;
REQUIRE(scalar5 == Catch::Approx(0.5));
}
SECTION("timevalOperations::toTimeval") {
double seconds = 1648227422.123456;
timeval t1 = timevalOperations::toTimeval(seconds);
REQUIRE(t1.tv_sec == 1648227422);
// Allow 1 usec rounding tolerance
REQUIRE(t1.tv_usec >= 123455);
REQUIRE(t1.tv_usec <= 123457);
}
}

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@ -4,8 +4,8 @@
#include <cstring>
#include <queue>
#include "fsfw/ipc/MessageQueueBase.h"
#include "fsfw/ipc/CommandMessage.h"
#include "fsfw/ipc/MessageQueueBase.h"
#include "fsfw/ipc/MessageQueueIF.h"
#include "fsfw/ipc/MessageQueueMessage.h"
#include "fsfw_tests/unit/CatchDefinitions.h"

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@ -1,4 +1,5 @@
target_sources(${FSFW_TEST_TGT} PRIVATE
TestMessageQueue.cpp
TestSemaphore.cpp
TestClock.cpp
)

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@ -0,0 +1,86 @@
#include <fsfw/globalfunctions/timevalOperations.h>
#include <fsfw/timemanager/Clock.h>
#include <array>
#include <catch2/catch_approx.hpp>
#include <catch2/catch_test_macros.hpp>
#include "fsfw_tests/unit/CatchDefinitions.h"
TEST_CASE("OSAL::Clock Test", "[OSAL::Clock Test]") {
SECTION("Test getClock") {
timeval time;
ReturnValue_t result = Clock::getClock_timeval(&time);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
Clock::TimeOfDay_t timeOfDay;
result = Clock::getDateAndTime(&timeOfDay);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
timeval timeOfDayAsTimeval;
result = Clock::convertTimeOfDayToTimeval(&timeOfDay, &timeOfDayAsTimeval);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
// We require timeOfDayAsTimeval to be larger than time as it
// was request a few ns later
double difference = timevalOperations::toDouble(timeOfDayAsTimeval - time);
CHECK(difference >= 0.0);
CHECK(difference <= 0.005);
// Conversion in the other direction
Clock::TimeOfDay_t timevalAsTimeOfDay;
result = Clock::convertTimevalToTimeOfDay(&time, &timevalAsTimeOfDay);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
CHECK(timevalAsTimeOfDay.year <= timeOfDay.year);
// TODO We should write TimeOfDay operators!
}
SECTION("Leap seconds") {
uint16_t leapSeconds = 0;
ReturnValue_t result = Clock::getLeapSeconds(&leapSeconds);
REQUIRE(result == HasReturnvaluesIF::RETURN_FAILED);
REQUIRE(leapSeconds == 0);
result = Clock::setLeapSeconds(18);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
result = Clock::getLeapSeconds(&leapSeconds);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
REQUIRE(leapSeconds == 18);
}
SECTION("usec Test") {
timeval timeAsTimeval;
ReturnValue_t result = Clock::getClock_timeval(&timeAsTimeval);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
uint64_t timeAsUsec = 0;
result = Clock::getClock_usecs(&timeAsUsec);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
double timeAsUsecDouble = static_cast<double>(timeAsUsec) / 1000000.0;
timeval timeAsUsecTimeval = timevalOperations::toTimeval(timeAsUsecDouble);
double difference = timevalOperations::toDouble(timeAsUsecTimeval - timeAsTimeval);
// We accept 5 ms difference
CHECK(difference >= 0.0);
CHECK(difference <= 0.005);
uint64_t timevalAsUint64 = static_cast<uint64_t>(timeAsTimeval.tv_sec) * 1000000ull +
static_cast<uint64_t>(timeAsTimeval.tv_usec);
CHECK((timeAsUsec - timevalAsUint64) >= 0);
CHECK((timeAsUsec - timevalAsUint64) <= (5 * 1000));
}
SECTION("Test j2000") {
double j2000;
timeval time;
time.tv_sec = 1648208539;
time.tv_usec = 0;
ReturnValue_t result = Clock::convertTimevalToJD2000(time, &j2000);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
double correctJ2000 = 2459663.98772 - 2451545.0;
CHECK(j2000 == Catch::Approx(correctJ2000).margin(1.2 * 1e-8));
}
SECTION("Convert to TT") {
timeval utcTime;
utcTime.tv_sec = 1648208539;
utcTime.tv_usec = 999000;
timeval tt;
ReturnValue_t result = Clock::setLeapSeconds(27);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
result = Clock::convertUTCToTT(utcTime, &tt);
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
CHECK(tt.tv_usec == 183000);
// The plus 1 is a own forced overflow of usecs
CHECK(tt.tv_sec == (1648208539 + 27 + 10 + 32 + 1));
}
}

View File

@ -81,7 +81,8 @@ TEST_CASE("CCSDSTime Tests", "[TestCCSDSTime]") {
std::string timeAscii = "2022-12-31T23:59:59.123Z";
Clock::TimeOfDay_t timeTo;
const uint8_t* timeChar = reinterpret_cast<const uint8_t*>(timeAscii.c_str());
CCSDSTime::convertFromASCII(&timeTo, timeChar, timeAscii.length());
auto result = CCSDSTime::convertFromASCII(&timeTo, timeChar, timeAscii.length());
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
REQUIRE(timeTo.year == 2022);
REQUIRE(timeTo.month == 12);
REQUIRE(timeTo.day == 31);
@ -89,6 +90,19 @@ TEST_CASE("CCSDSTime Tests", "[TestCCSDSTime]") {
REQUIRE(timeTo.minute == 59);
REQUIRE(timeTo.second == 59);
REQUIRE(timeTo.usecond == Catch::Approx(123000));
std::string timeAscii2 = "2022-365T23:59:59.123Z";
const uint8_t* timeChar2 = reinterpret_cast<const uint8_t*>(timeAscii2.c_str());
Clock::TimeOfDay_t timeTo2;
result = CCSDSTime::convertFromCcsds(&timeTo2, timeChar2, timeAscii2.length());
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
REQUIRE(timeTo2.year == 2022);
REQUIRE(timeTo2.month == 12);
REQUIRE(timeTo2.day == 31);
REQUIRE(timeTo2.hour == 23);
REQUIRE(timeTo2.minute == 59);
REQUIRE(timeTo2.second == 59);
REQUIRE(timeTo2.usecond == Catch::Approx(123000));
}
SECTION("CDS Conversions") {
@ -119,6 +133,7 @@ TEST_CASE("CCSDSTime Tests", "[TestCCSDSTime]") {
CHECK(cdsTime.msDay_h == 0xE0);
CHECK(cdsTime.msDay_l == 0xC5);
CHECK(cdsTime.msDay_ll == 0xC3);
CHECK(cdsTime.pField == CCSDSTime::P_FIELD_CDS_SHORT);
// Conversion back to timeval
timeval timeReturnAsTimeval;
@ -128,5 +143,56 @@ TEST_CASE("CCSDSTime Tests", "[TestCCSDSTime]") {
timeval difference = timeAsTimeval - timeReturnAsTimeval;
CHECK(difference.tv_usec == 456);
CHECK(difference.tv_sec == 0);
Clock::TimeOfDay_t timeReturnAsTimeOfDay;
result = CCSDSTime::convertFromCDS(&timeReturnAsTimeOfDay, &cdsTime);
CHECK(result == HasReturnvaluesIF::RETURN_OK);
CHECK(timeReturnAsTimeOfDay.year == 2020);
CHECK(timeReturnAsTimeOfDay.month == 2);
CHECK(timeReturnAsTimeOfDay.day == 29);
CHECK(timeReturnAsTimeOfDay.hour == 13);
CHECK(timeReturnAsTimeOfDay.minute == 24);
CHECK(timeReturnAsTimeOfDay.second == 45);
// micro seconds precision is lost
CHECK(timeReturnAsTimeOfDay.usecond == 123000);
Clock::TimeOfDay_t timeReturnAsTodFromBuffer;
const uint8_t* buffer = reinterpret_cast<const uint8_t*>(&cdsTime);
result = CCSDSTime::convertFromCDS(&timeReturnAsTodFromBuffer, buffer, sizeof(cdsTime));
REQUIRE(result == HasReturnvaluesIF::RETURN_OK);
CHECK(timeReturnAsTodFromBuffer.year == time.year);
CHECK(timeReturnAsTodFromBuffer.month == time.month);
CHECK(timeReturnAsTodFromBuffer.day == time.day);
CHECK(timeReturnAsTodFromBuffer.hour == time.hour);
CHECK(timeReturnAsTodFromBuffer.minute == time.minute);
CHECK(timeReturnAsTodFromBuffer.second == time.second);
CHECK(timeReturnAsTodFromBuffer.usecond == 123000);
Clock::TimeOfDay_t todFromCCSDS;
result = CCSDSTime::convertFromCcsds(&todFromCCSDS, buffer, sizeof(cdsTime));
CHECK(result == HasReturnvaluesIF::RETURN_OK);
CHECK(todFromCCSDS.year == time.year);
CHECK(todFromCCSDS.month == time.month);
CHECK(todFromCCSDS.day == time.day);
CHECK(todFromCCSDS.hour == time.hour);
CHECK(todFromCCSDS.minute == time.minute);
CHECK(todFromCCSDS.second == time.second);
CHECK(todFromCCSDS.usecond == 123000);
}
SECTION("CCSDS Failures") {
Clock::TimeOfDay_t time;
time.year = 2020;
time.month = 12;
time.day = 32;
time.hour = 13;
time.minute = 24;
time.second = 45;
time.usecond = 123456;
CCSDSTime::Ccs_mseconds to;
auto result = CCSDSTime::convertToCcsds(&to, &time);
REQUIRE(result == CCSDSTime::INVALID_TIME_FORMAT);
CCSDSTime::Ccs_seconds to2;
result = CCSDSTime::convertToCcsds(&to2, &time);
REQUIRE(result == CCSDSTime::INVALID_TIME_FORMAT);
}
}