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unittest now contained directly

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This commit is contained in:
Robin Müller
2020-10-20 17:11:23 +02:00
parent c677358343
commit 865ea3386c
78 changed files with 22684 additions and 4 deletions
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105
unittest/tests/action/TestActionHelper.cpp Normal file
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#include <fsfw/action/ActionHelper.h>
#include <fsfw/ipc/CommandMessage.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
#include <fsfw/unittest/tests/action/TestActionHelper.h>
TEST_CASE( "Action Helper" , "[ActionHelper]") {
ActionHelperOwnerMockBase testDhMock;
MessageQueueMockBase testMqMock;
ActionHelper actionHelper = ActionHelper(
&testDhMock, dynamic_cast<MessageQueueIF*>(&testMqMock));
CommandMessage actionMessage;
ActionId_t testActionId = 777;
std::array <uint8_t, 3> testParams {1, 2, 3};
store_address_t paramAddress;
StorageManagerIF *ipcStore = tglob::getIpcStoreHandle();
ipcStore->addData(&paramAddress, testParams.data(), 3);
REQUIRE(actionHelper.initialize() == retval::CATCH_OK);
SECTION ("Simple tests") {
ActionMessage::setCommand(&actionMessage, testActionId, paramAddress);
CHECK(not testDhMock.executeActionCalled);
REQUIRE(actionHelper.handleActionMessage(&actionMessage) == retval::CATCH_OK);
CHECK(testDhMock.executeActionCalled);
// No message is sent if everything is alright.
CHECK(not testMqMock.wasMessageSent());
store_address_t invalidAddress;
ActionMessage::setCommand(&actionMessage, testActionId, invalidAddress);
actionHelper.handleActionMessage(&actionMessage);
CHECK(testMqMock.wasMessageSent());
const uint8_t* ptr = nullptr;
size_t size = 0;
REQUIRE(ipcStore->getData(paramAddress, &ptr, &size) == static_cast<uint32_t>(StorageManagerIF::DATA_DOES_NOT_EXIST));
REQUIRE(ptr == nullptr);
REQUIRE(size == 0);
testDhMock.getBuffer(&ptr, &size);
REQUIRE(size == 3);
for(uint8_t i = 0; i<3;i++){
REQUIRE(ptr[i] == (i+1));
}
testDhMock.clearBuffer();
}
SECTION("Handle failures"){
actionMessage.setCommand(1234);
REQUIRE(actionHelper.handleActionMessage(&actionMessage) == static_cast<uint32_t>(CommandMessage::UNKNOWN_COMMAND));
CHECK(not testMqMock.wasMessageSent());
uint16_t step = 5;
ReturnValue_t status = 0x1234;
actionHelper.step(step, testMqMock.getId(), testActionId, status);
step += 1;
CHECK(testMqMock.wasMessageSent());
CommandMessage testMessage;
REQUIRE(testMqMock.receiveMessage(&testMessage) == static_cast<uint32_t>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(testMessage.getCommand() == static_cast<uint32_t>(ActionMessage::STEP_FAILED));
REQUIRE(testMessage.getParameter() == static_cast<uint32_t>(testActionId));
uint32_t parameter2 = ((uint32_t)step << 16) | (uint32_t)status;
REQUIRE(testMessage.getParameter2() == parameter2);
REQUIRE(ActionMessage::getStep(&testMessage) == step);
}
SECTION("Handle finish"){
CHECK(not testMqMock.wasMessageSent());
ReturnValue_t status = 0x9876;
actionHelper.finish(testMqMock.getId(), testActionId, status);
CHECK(testMqMock.wasMessageSent());
CommandMessage testMessage;
REQUIRE(testMqMock.receiveMessage(&testMessage) == static_cast<uint32_t>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(testMessage.getCommand() == static_cast<uint32_t>(ActionMessage::COMPLETION_FAILED));
REQUIRE(ActionMessage::getActionId(&testMessage) == testActionId);
REQUIRE(ActionMessage::getReturnCode(&testMessage) == static_cast<uint32_t>(status));
}
SECTION("Handle failed"){
store_address_t toLongParamAddress = StorageManagerIF::INVALID_ADDRESS;
std::array<uint8_t, 5> toLongData = {5, 4, 3, 2, 1};
REQUIRE(ipcStore->addData(&toLongParamAddress, toLongData.data(), 5) == retval::CATCH_OK);
ActionMessage::setCommand(&actionMessage, testActionId, toLongParamAddress);
CHECK(not testDhMock.executeActionCalled);
REQUIRE(actionHelper.handleActionMessage(&actionMessage) == retval::CATCH_OK);
REQUIRE(ipcStore->getData(toLongParamAddress).first == static_cast<uint32_t>(StorageManagerIF::DATA_DOES_NOT_EXIST));
CommandMessage testMessage;
REQUIRE(testMqMock.receiveMessage(&testMessage) == static_cast<uint32_t>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(testMessage.getCommand() == static_cast<uint32_t>(ActionMessage::STEP_FAILED));
REQUIRE(ActionMessage::getReturnCode(&testMessage) == 0xAFFE);
REQUIRE(ActionMessage::getStep(&testMessage) == 0);
REQUIRE(ActionMessage::getActionId(&testMessage) == testActionId);
}
SECTION("Missing IPC Data"){
ActionMessage::setCommand(&actionMessage, testActionId, StorageManagerIF::INVALID_ADDRESS);
CHECK(not testDhMock.executeActionCalled);
REQUIRE(actionHelper.handleActionMessage(&actionMessage) == retval::CATCH_OK);
CommandMessage testMessage;
REQUIRE(testMqMock.receiveMessage(&testMessage) == static_cast<uint32_t>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(testMessage.getCommand() == static_cast<uint32_t>(ActionMessage::STEP_FAILED));
REQUIRE(ActionMessage::getReturnCode(&testMessage) == static_cast<uint32_t>(StorageManagerIF::ILLEGAL_STORAGE_ID));
REQUIRE(ActionMessage::getStep(&testMessage) == 0);
}
SECTION("Data Reply"){
}
}

131
unittest/tests/action/TestActionHelper.h Normal file
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#ifndef UNITTEST_HOSTED_TESTACTIONHELPER_H_
#define UNITTEST_HOSTED_TESTACTIONHELPER_H_
#include <fsfw/action/HasActionsIF.h>
#include <fsfw/ipc/MessageQueueIF.h>
#include <fsfw/unittest/core/CatchDefinitions.h>
#include <cstring>
class ActionHelperOwnerMockBase: public HasActionsIF {
public:
bool getCommandQueueCalled = false;
bool executeActionCalled = false;
static const size_t MAX_SIZE = 3;
uint8_t buffer[MAX_SIZE] = {0, 0, 0};
size_t size = 0;
MessageQueueId_t getCommandQueue() const override {
return tconst::testQueueId;
}
ReturnValue_t executeAction(ActionId_t actionId, MessageQueueId_t commandedBy,
const uint8_t* data, size_t size) override {
executeActionCalled = true;
if(size > MAX_SIZE){
return 0xAFFE;
}
this->size = size;
memcpy(buffer, data, size);
return HasReturnvaluesIF::RETURN_OK;
}
void clearBuffer(){
this->size = 0;
for(size_t i = 0; i<MAX_SIZE; i++){
buffer[i] = 0;
}
}
void getBuffer(const uint8_t** ptr, size_t* size){
if(size != nullptr){
*size = this->size;
}
if(ptr != nullptr){
*ptr = buffer;
}
}
};
class MessageQueueMockBase: public MessageQueueIF {
public:
MessageQueueId_t myQueueId = 0;
bool defaultDestSet = false;
bool messageSent = false;
bool wasMessageSent() {
bool tempMessageSent = messageSent;
messageSent = false;
return tempMessageSent;
}
virtual ReturnValue_t reply( MessageQueueMessage* message ) {
messageSent = true;
lastMessage = (*message);
return HasReturnvaluesIF::RETURN_OK;
};
virtual ReturnValue_t receiveMessage(MessageQueueMessage* message,
MessageQueueId_t *receivedFrom) {
(*message) = lastMessage;
lastMessage.clear();
return HasReturnvaluesIF::RETURN_OK;
}
virtual ReturnValue_t receiveMessage(MessageQueueMessage* message) {
(*message) = lastMessage;
lastMessage.clear();
return HasReturnvaluesIF::RETURN_OK;
}
virtual ReturnValue_t flush(uint32_t* count) {
return HasReturnvaluesIF::RETURN_OK;
}
virtual MessageQueueId_t getLastPartner() const {
return tconst::testQueueId;
}
virtual MessageQueueId_t getId() const {
return tconst::testQueueId;
}
virtual ReturnValue_t sendMessageFrom( MessageQueueId_t sendTo,
MessageQueueMessage* message, MessageQueueId_t sentFrom,
bool ignoreFault = false ) {
messageSent = true;
lastMessage = (*message);
return HasReturnvaluesIF::RETURN_OK;
}
virtual ReturnValue_t sendMessage( MessageQueueId_t sendTo,
MessageQueueMessage* message, bool ignoreFault = false ) override {
messageSent = true;
lastMessage = (*message);
return HasReturnvaluesIF::RETURN_OK;
}
virtual ReturnValue_t sendToDefaultFrom( MessageQueueMessage* message,
MessageQueueId_t sentFrom, bool ignoreFault = false ) {
messageSent = true;
lastMessage = (*message);
return HasReturnvaluesIF::RETURN_OK;
}
virtual ReturnValue_t sendToDefault( MessageQueueMessage* message ) {
messageSent = true;
lastMessage = (*message);
return HasReturnvaluesIF::RETURN_OK;
}
virtual void setDefaultDestination(MessageQueueId_t defaultDestination) {
myQueueId = defaultDestination;
defaultDestSet = true;
}
virtual MessageQueueId_t getDefaultDestination() const {
return myQueueId;
}
virtual bool isDefaultDestinationSet() const {
return defaultDestSet;
}
private:
MessageQueueMessage lastMessage;
};
#endif /* UNITTEST_TESTFW_NEWTESTS_TESTACTIONHELPER_H_ */

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unittest/tests/container/RingBufferTest.cpp Normal file
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#include <fsfw/container/SimpleRingBuffer.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
#include <cstring>
TEST_CASE("Ring Buffer Test" , "[RingBufferTest]") {
uint8_t testData[13]= {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12};
uint8_t readBuffer[10] = {13, 13, 13, 13, 13, 13, 13, 13, 13, 13};
SimpleRingBuffer ringBuffer(10, false, 5);
SECTION("Simple Test") {
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 9) == retval::CATCH_OK);
REQUIRE(ringBuffer.writeData(testData, 3) == retval::CATCH_FAILED);
REQUIRE(ringBuffer.readData(readBuffer, 5, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 5; i++) {
CHECK(readBuffer[i] == i);
}
REQUIRE(ringBuffer.availableWriteSpace() == 5);
ringBuffer.clear();
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 4) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 4, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 4; i++) {
CHECK(readBuffer[i] == i);
}
REQUIRE(ringBuffer.writeData(testData, 9) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 9, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 9; i++) {
CHECK(readBuffer[i] == i);
}
}
SECTION("Get Free Element Test") {
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 8) == retval::CATCH_OK);
REQUIRE(ringBuffer.availableWriteSpace() == 1);
REQUIRE(ringBuffer.readData(readBuffer, 8, true) == retval::CATCH_OK);
REQUIRE(ringBuffer.availableWriteSpace() == 9);
uint8_t *testPtr = nullptr;
REQUIRE(ringBuffer.getFreeElement(&testPtr, 10) == retval::CATCH_FAILED);
REQUIRE(ringBuffer.writeTillWrap() == 2);
// too many excess bytes.
REQUIRE(ringBuffer.getFreeElement(&testPtr, 8) == retval::CATCH_FAILED);
REQUIRE(ringBuffer.getFreeElement(&testPtr, 5) == retval::CATCH_OK);
REQUIRE(ringBuffer.getExcessBytes() == 3);
std::memcpy(testPtr, testData, 5);
ringBuffer.confirmBytesWritten(5);
REQUIRE(ringBuffer.getAvailableReadData() == 5);
ringBuffer.readData(readBuffer, 5, true);
for(uint8_t i = 0; i< 5; i++) {
CHECK(readBuffer[i] == i);
}
}
SECTION("Read Remaining Test") {
REQUIRE(ringBuffer.writeData(testData, 3) == retval::CATCH_OK);
REQUIRE(ringBuffer.getAvailableReadData() == 3);
REQUIRE(ringBuffer.readData(readBuffer, 5, false, false, nullptr) == retval::CATCH_FAILED);
size_t trueSize = 0;
REQUIRE(ringBuffer.readData(readBuffer, 5, false, true, &trueSize) == retval::CATCH_OK);
REQUIRE(trueSize == 3);
for(uint8_t i = 0; i< 3; i++) {
CHECK(readBuffer[i] == i);
}
trueSize = 0;
REQUIRE(ringBuffer.deleteData(5, false, &trueSize) == retval::CATCH_FAILED);
REQUIRE(trueSize == 0);
REQUIRE(ringBuffer.deleteData(5, true, &trueSize) == retval::CATCH_OK);
REQUIRE(trueSize == 3);
}
}
TEST_CASE("Ring Buffer Test2" , "[RingBufferTest2]") {
uint8_t testData[13]= {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12};
uint8_t readBuffer[10] = {13, 13, 13, 13, 13, 13, 13, 13, 13, 13};
uint8_t* newBuffer = new uint8_t[10];
SimpleRingBuffer ringBuffer(newBuffer, 10, true, 5);
SECTION("Simple Test") {
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 9) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 5, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 5; i++) {
CHECK(readBuffer[i] == i);
}
REQUIRE(ringBuffer.availableWriteSpace() == 5);
ringBuffer.clear();
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 4) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 4, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 4; i++) {
CHECK(readBuffer[i] == i);
}
REQUIRE(ringBuffer.writeData(testData, 9) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 9, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 9; i++) {
CHECK(readBuffer[i] == i);
}
}
SECTION("Get Free Element Test") {
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 8) == retval::CATCH_OK);
REQUIRE(ringBuffer.availableWriteSpace() == 1);
REQUIRE(ringBuffer.readData(readBuffer, 8, true) == retval::CATCH_OK);
REQUIRE(ringBuffer.availableWriteSpace() == 9);
uint8_t *testPtr = nullptr;
REQUIRE(ringBuffer.getFreeElement(&testPtr, 10) == retval::CATCH_FAILED);
REQUIRE(ringBuffer.writeTillWrap() == 2);
// too many excess bytes.
REQUIRE(ringBuffer.getFreeElement(&testPtr, 8) == retval::CATCH_FAILED);
REQUIRE(ringBuffer.getFreeElement(&testPtr, 5) == retval::CATCH_OK);
REQUIRE(ringBuffer.getExcessBytes() == 3);
std::memcpy(testPtr, testData, 5);
ringBuffer.confirmBytesWritten(5);
REQUIRE(ringBuffer.getAvailableReadData() == 5);
ringBuffer.readData(readBuffer, 5, true);
for(uint8_t i = 0; i< 5; i++) {
CHECK(readBuffer[i] == i);
}
}
SECTION("Read Remaining Test") {
REQUIRE(ringBuffer.writeData(testData, 3) == retval::CATCH_OK);
REQUIRE(ringBuffer.getAvailableReadData() == 3);
REQUIRE(ringBuffer.readData(readBuffer, 5, false, false, nullptr) == retval::CATCH_FAILED);
size_t trueSize = 0;
REQUIRE(ringBuffer.readData(readBuffer, 5, false, true, &trueSize) == retval::CATCH_OK);
REQUIRE(trueSize == 3);
for(uint8_t i = 0; i< 3; i++) {
CHECK(readBuffer[i] == i);
}
trueSize = 0;
REQUIRE(ringBuffer.deleteData(5, false, &trueSize) == retval::CATCH_FAILED);
REQUIRE(trueSize == 0);
REQUIRE(ringBuffer.deleteData(5, true, &trueSize) == retval::CATCH_OK);
REQUIRE(trueSize == 3);
}
SECTION("Overflow"){
REQUIRE(ringBuffer.availableWriteSpace()==9);
//Writing more than the buffer is large, technically thats allowed
//But it is senseless and has undesired impact on read call
REQUIRE(ringBuffer.writeData(testData, 13) == retval::CATCH_OK);
REQUIRE(ringBuffer.getAvailableReadData()==3);
ringBuffer.clear();
uint8_t * ptr = nullptr;
REQUIRE(ringBuffer.getFreeElement(&ptr, 13) == retval::CATCH_OK);
REQUIRE(ptr != nullptr);
memcpy(ptr, testData, 13);
ringBuffer.confirmBytesWritten(13);
REQUIRE(ringBuffer.getAvailableReadData()==3);
REQUIRE(ringBuffer.readData(readBuffer, 3, true)== retval::CATCH_OK);
for(auto i =0;i<3;i++){
REQUIRE(readBuffer[i] == testData[i+10]);
}
}
}
TEST_CASE("Ring Buffer Test3" , "[RingBufferTest3]") {
uint8_t testData[13]= {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12};
uint8_t readBuffer[10] = {13, 13, 13, 13, 13, 13, 13, 13, 13, 13};
uint8_t* newBuffer = new uint8_t[10];
SimpleRingBuffer ringBuffer(newBuffer, 10, true, 15);
SECTION("Simple Test") {
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 9) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 5, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 5; i++) {
CHECK(readBuffer[i] == i);
}
REQUIRE(ringBuffer.availableWriteSpace() == 5);
ringBuffer.clear();
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 4) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 4, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 4; i++) {
CHECK(readBuffer[i] == i);
}
REQUIRE(ringBuffer.writeData(testData, 9) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 9, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 9; i++) {
CHECK(readBuffer[i] == i);
}
}
SECTION("Get Free Element Test") {
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 8) == retval::CATCH_OK);
REQUIRE(ringBuffer.availableWriteSpace() == 1);
REQUIRE(ringBuffer.readData(readBuffer, 8, true) == retval::CATCH_OK);
REQUIRE(ringBuffer.availableWriteSpace() == 9);
uint8_t *testPtr = nullptr;
REQUIRE(ringBuffer.getFreeElement(&testPtr, 10) == retval::CATCH_OK);
REQUIRE(ringBuffer.getExcessBytes() == 8);
REQUIRE(ringBuffer.writeTillWrap() == 2);
// too many excess bytes.
REQUIRE(ringBuffer.getFreeElement(&testPtr, 8) == retval::CATCH_FAILED);
// Less Execss bytes overwrites before
REQUIRE(ringBuffer.getFreeElement(&testPtr, 3) == retval::CATCH_OK);
REQUIRE(ringBuffer.getExcessBytes() == 1);
std::memcpy(testPtr, testData, 3);
ringBuffer.confirmBytesWritten(3);
REQUIRE(ringBuffer.getAvailableReadData() == 3);
ringBuffer.readData(readBuffer, 3, true);
for(uint8_t i = 0; i< 3; i++) {
CHECK(readBuffer[i] == i);
}
}
SECTION("Read Remaining Test") {
REQUIRE(ringBuffer.writeData(testData, 3) == retval::CATCH_OK);
REQUIRE(ringBuffer.getAvailableReadData() == 3);
REQUIRE(ringBuffer.readData(readBuffer, 5, false, false, nullptr) == retval::CATCH_FAILED);
size_t trueSize = 0;
REQUIRE(ringBuffer.readData(readBuffer, 5, false, true, &trueSize) == retval::CATCH_OK);
REQUIRE(trueSize == 3);
for(uint8_t i = 0; i< 3; i++) {
CHECK(readBuffer[i] == i);
}
trueSize = 0;
REQUIRE(ringBuffer.deleteData(5, false, &trueSize) == retval::CATCH_FAILED);
REQUIRE(trueSize == 0);
REQUIRE(ringBuffer.deleteData(5, true, &trueSize) == retval::CATCH_OK);
REQUIRE(trueSize == 3);
}
SECTION("Overflow"){
REQUIRE(ringBuffer.availableWriteSpace()==9);
//Writing more than the buffer is large, technically thats allowed
//But it is senseless and has undesired impact on read call
REQUIRE(ringBuffer.writeData(testData, 13) == retval::CATCH_OK);
REQUIRE(ringBuffer.getAvailableReadData()==3);
ringBuffer.clear();
uint8_t * ptr = nullptr;
REQUIRE(ringBuffer.getFreeElement(&ptr, 13) == retval::CATCH_OK);
REQUIRE(ptr != nullptr);
memcpy(ptr, testData, 13);
ringBuffer.confirmBytesWritten(13);
REQUIRE(ringBuffer.getAvailableReadData()==3);
REQUIRE(ringBuffer.readData(readBuffer, 3, true)== retval::CATCH_OK);
for(auto i =0;i<3;i++){
REQUIRE(readBuffer[i] == testData[i+10]);
}
}
}
TEST_CASE("Ring Buffer Test4" , "[RingBufferTest4]") {
uint8_t testData[13]= {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12};
uint8_t readBuffer[10] = {13, 13, 13, 13, 13, 13, 13, 13, 13, 13};
SimpleRingBuffer ringBuffer(10, false, 15);
SECTION("Simple Test") {
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 9) == retval::CATCH_OK);
REQUIRE(ringBuffer.writeData(testData, 3) == retval::CATCH_FAILED);
REQUIRE(ringBuffer.readData(readBuffer, 5, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 5; i++) {
CHECK(readBuffer[i] == i);
}
REQUIRE(ringBuffer.availableWriteSpace() == 5);
ringBuffer.clear();
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 4) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 4, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 4; i++) {
CHECK(readBuffer[i] == i);
}
REQUIRE(ringBuffer.writeData(testData, 9) == retval::CATCH_OK);
REQUIRE(ringBuffer.readData(readBuffer, 9, true) == retval::CATCH_OK);
for(uint8_t i = 0; i< 9; i++) {
CHECK(readBuffer[i] == i);
}
}
SECTION("Get Free Element Test") {
REQUIRE(ringBuffer.availableWriteSpace() == 9);
REQUIRE(ringBuffer.writeData(testData, 8) == retval::CATCH_OK);
REQUIRE(ringBuffer.availableWriteSpace() == 1);
REQUIRE(ringBuffer.readData(readBuffer, 8, true) == retval::CATCH_OK);
REQUIRE(ringBuffer.availableWriteSpace() == 9);
uint8_t *testPtr = nullptr;
REQUIRE(ringBuffer.getFreeElement(&testPtr, 10) == retval::CATCH_FAILED);
REQUIRE(ringBuffer.writeTillWrap() == 2);
REQUIRE(ringBuffer.getFreeElement(&testPtr, 8) == retval::CATCH_OK);
REQUIRE(ringBuffer.getFreeElement(&testPtr, 5) == retval::CATCH_OK);
REQUIRE(ringBuffer.getExcessBytes() == 3);
std::memcpy(testPtr, testData, 5);
ringBuffer.confirmBytesWritten(5);
REQUIRE(ringBuffer.getAvailableReadData() == 5);
ringBuffer.readData(readBuffer, 5, true);
for(uint8_t i = 0; i< 5; i++) {
CHECK(readBuffer[i] == i);
}
}
SECTION("Read Remaining Test") {
REQUIRE(ringBuffer.writeData(testData, 3) == retval::CATCH_OK);
REQUIRE(ringBuffer.getAvailableReadData() == 3);
REQUIRE(ringBuffer.readData(readBuffer, 5, false, false, nullptr) == retval::CATCH_FAILED);
size_t trueSize = 0;
REQUIRE(ringBuffer.readData(readBuffer, 5, false, true, &trueSize) == retval::CATCH_OK);
REQUIRE(trueSize == 3);
for(uint8_t i = 0; i< 3; i++) {
CHECK(readBuffer[i] == i);
}
trueSize = 0;
REQUIRE(ringBuffer.deleteData(5, false, &trueSize) == retval::CATCH_FAILED);
REQUIRE(trueSize == 0);
REQUIRE(ringBuffer.deleteData(5, true, &trueSize) == retval::CATCH_OK);
REQUIRE(trueSize == 3);
}
}

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unittest/tests/container/TestArrayList.cpp Normal file
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#include <fsfw/container/ArrayList.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
/**
* @brief Array List test
*/
TEST_CASE("Array List" , "[ArrayListTest]") {
//perform set-up here
ArrayList<uint16_t> list(20);
struct TestClass{
public:
TestClass(){};
TestClass(uint32_t number1, uint64_t number2):
number1(number1), number2(number2){};
uint32_t number1 = -1;
uint64_t number2 = -1;
bool operator==(const TestClass& other){
return ((this->number1 == other.number1) and (this->number2 == other.number2));
};
};
ArrayList<TestClass> complexList(20);
SECTION("SimpleTest") {
REQUIRE(list.maxSize()==20);
REQUIRE(list.size == 0);
REQUIRE(list.insert(10) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(list[0] == 10);
REQUIRE(list.front() != nullptr);
REQUIRE((*list.front()) == 10);
REQUIRE(list.back() != nullptr);
REQUIRE((*list.back()) == 10);
// Need to test the const version of back as well
const uint16_t* number = const_cast<const ArrayList<uint16_t>*>(&list)->back();
REQUIRE(*number == 10);
list.clear();
REQUIRE(list.size == 0);
}
SECTION("Fill and check"){
//This is an invalid element but its not a nullptr
REQUIRE(list.back() != nullptr);
for (auto i =0; i < 20; i++){
REQUIRE(list.insert(i) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
}
REQUIRE(list.insert(20) == static_cast<int>(ArrayList<uint16_t>::FULL));
ArrayList<uint16_t>::Iterator it = list.begin();
REQUIRE((*it) == 0);
it++;
REQUIRE((*it) == 1);
it--;
REQUIRE((*it) == 0);
it++;
for(auto it2 = list.begin(); it2!=list.end(); it2++){
if (it == it2){
REQUIRE((*it) == (*it2));
break;
}else{
REQUIRE((*it2) == 0);
REQUIRE(it2 != it);
}
}
}
SECTION("Const Iterator"){
ArrayList<uint16_t>::Iterator it = list.begin();
for (auto i =0; i < 10; i++){
REQUIRE(list.insert(i) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
}
it++;
const uint16_t* number = it.value;
REQUIRE(*number == 1);
}
SECTION("Const Iterator"){
ArrayList<TestClass>::Iterator it = complexList.begin();
for (auto i =0; i < 10; i++){
REQUIRE(complexList.insert(TestClass(i, i+1)) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
}
it++;
const TestClass* secondTest = it.value;
bool compare = TestClass(1, 2) == *secondTest;
REQUIRE(compare);
it++;
REQUIRE(it->number1 == 2);
REQUIRE(it->number2 == 3);
const ArrayList<TestClass>::Iterator it4(&(complexList[2]));
REQUIRE(it4->number1 == 2);
REQUIRE((*it4).number2 == 3);
REQUIRE(complexList.remaining()==10);
}
}

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#include <fsfw/container/DynamicFIFO.h>
#include <fsfw/container/FIFO.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
#include <catch.hpp>
#include <CatchDefinitions.h>
TEST_CASE( "Dynamic Fifo Tests", "[TestDynamicFifo]") {
INFO("Dynamic Fifo Tests");
struct Test{
uint64_t number1;
uint32_t number2;
uint8_t number3;
bool operator==(struct Test& other){
if ((other.number1 == this->number1) and
(other.number1 == this->number1) and
(other.number1 == this->number1)){
return true;
}
return false;
}
};
DynamicFIFO<Test> fifo(3);
std::vector<Test> list;
struct Test structOne({UINT64_MAX, UINT32_MAX, UINT8_MAX});
struct Test structTwo({0, 1, 2});
struct Test structThree({42, 43, 44});
list.push_back(structThree);
list.push_back(structTwo);
list.push_back(structOne);
SECTION("Insert, retrieval test"){
REQUIRE(fifo.getMaxCapacity()==3);
REQUIRE(fifo.size()==0);
REQUIRE(fifo.empty());
REQUIRE(not fifo.full());
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structThree)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(FIFOBase<Test>::FULL));
struct Test testptr;
REQUIRE(fifo.peek(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
bool equal = testptr == structOne;
REQUIRE(equal);
REQUIRE(fifo.size()==3);
REQUIRE(fifo.full());
REQUIRE(not fifo.empty());
for(size_t i=2;i<3;i--){
testptr.number1 = 0;
testptr.number2 = 0;
testptr.number3 = 0;
REQUIRE(fifo.retrieve(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
equal = testptr == list[i];
REQUIRE(equal);
REQUIRE(fifo.size()==i);
}
testptr.number1 = 0;
testptr.number2 = 0;
testptr.number3 = 0;
REQUIRE(fifo.retrieve(&testptr)==static_cast<int>(FIFOBase<Test>::EMPTY));
REQUIRE(fifo.peek(&testptr)==static_cast<int>(FIFOBase<Test>::EMPTY));
REQUIRE(not fifo.full());
REQUIRE(fifo.empty());
REQUIRE(fifo.pop()==static_cast<int>(FIFOBase<Test>::EMPTY));
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==1);
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==2);
REQUIRE(fifo.pop()==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==1);
testptr.number1 = 0;
testptr.number2 = 0;
testptr.number3 = 0;
REQUIRE(fifo.peek(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
equal = testptr == structTwo;
REQUIRE(equal);
REQUIRE(fifo.pop()==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==0);
REQUIRE(fifo.empty());
//struct Test* ptr = nullptr;
//REQUIRE(fifo.retrieve(ptr) == static_cast<int>(HasReturnvaluesIF::RETURN_FAILED));
//REQUIRE(fifo.peek(ptr) == static_cast<int>(HasReturnvaluesIF::RETURN_FAILED));
};
SECTION("Copy Test"){
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structThree)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==3);
REQUIRE(fifo.full());
REQUIRE(not fifo.empty());
DynamicFIFO<Test> fifo2(fifo);
REQUIRE(fifo2.size()==3);
REQUIRE(fifo2.full());
REQUIRE(not fifo2.empty());
};
SECTION("Assignment Test"){
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structThree)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==3);
REQUIRE(fifo.full());
REQUIRE(not fifo.empty());
DynamicFIFO<Test> fifo2(6);
fifo2 = fifo;
REQUIRE(fifo2.size()==3);
REQUIRE(fifo2.full());
REQUIRE(not fifo2.empty());
for(size_t i=2;i<3;i--){
struct Test testptr = {0, 0, 0};
REQUIRE(fifo2.retrieve(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
bool equal = testptr == list[i];
REQUIRE(equal);
REQUIRE(fifo2.size()==i);
}
};
SECTION("Assignment Test Smaller"){
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structThree)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==3);
REQUIRE(fifo.full());
REQUIRE(not fifo.empty());
DynamicFIFO<Test> fifo2(2);
fifo2 = fifo;
REQUIRE(fifo2.size()==3);
REQUIRE(fifo2.full());
REQUIRE(not fifo2.empty());
for(size_t i=2;i<3;i--){
struct Test testptr = {0, 0, 0};
REQUIRE(fifo2.retrieve(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
bool equal = testptr == list[i];
REQUIRE(equal);
REQUIRE(fifo2.size()==i);
}
};
};

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#include <fsfw/container/DynamicFIFO.h>
#include <fsfw/container/FIFO.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
TEST_CASE( "Static Fifo Tests", "[TestFifo]") {
INFO("Fifo Tests");
struct Test{
uint64_t number1;
uint32_t number2;
uint8_t number3;
bool operator==(struct Test& other){
if ((other.number1 == this->number1) and
(other.number1 == this->number1) and
(other.number1 == this->number1)){
return true;
}
return false;
}
};
FIFO<Test, 3> fifo;
std::vector<Test> list;
struct Test structOne({UINT64_MAX, UINT32_MAX, UINT8_MAX});
struct Test structTwo({0, 1, 2});
struct Test structThree({42, 43, 44});
list.push_back(structThree);
list.push_back(structTwo);
list.push_back(structOne);
SECTION("Insert, retrieval test"){
REQUIRE(fifo.getMaxCapacity()==3);
REQUIRE(fifo.size()==0);
REQUIRE(fifo.empty());
REQUIRE(not fifo.full());
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structThree)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(FIFOBase<Test>::FULL));
struct Test testptr;
REQUIRE(fifo.peek(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
bool equal = testptr == structOne;
REQUIRE(equal);
REQUIRE(fifo.size()==3);
REQUIRE(fifo.full());
REQUIRE(not fifo.empty());
for(size_t i=2;i<3;i--){
testptr.number1 = 0;
testptr.number2 = 0;
testptr.number3 = 0;
REQUIRE(fifo.retrieve(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
equal = testptr == list[i];
REQUIRE(equal);
REQUIRE(fifo.size()==i);
}
testptr.number1 = 0;
testptr.number2 = 0;
testptr.number3 = 0;
REQUIRE(fifo.retrieve(&testptr)==static_cast<int>(FIFOBase<Test>::EMPTY));
REQUIRE(fifo.peek(&testptr)==static_cast<int>(FIFOBase<Test>::EMPTY));
REQUIRE(not fifo.full());
REQUIRE(fifo.empty());
REQUIRE(fifo.pop()==static_cast<int>(FIFOBase<Test>::EMPTY));
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==1);
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==2);
REQUIRE(fifo.pop()==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==1);
testptr.number1 = 0;
testptr.number2 = 0;
testptr.number3 = 0;
// Test that retrieve and peek will not cause a nullptr dereference
struct Test* ptr = nullptr;
REQUIRE(fifo.retrieve(ptr) == static_cast<int>(HasReturnvaluesIF::RETURN_FAILED));
REQUIRE(fifo.peek(ptr) == static_cast<int>(HasReturnvaluesIF::RETURN_FAILED));
REQUIRE(fifo.peek(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
equal = testptr == structTwo;
REQUIRE(equal);
REQUIRE(fifo.pop()==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==0);
REQUIRE(fifo.empty());
};
SECTION("Copy Test"){
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structThree)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==3);
REQUIRE(fifo.full());
REQUIRE(not fifo.empty());
FIFO<Test, 3> fifo2(fifo);
REQUIRE(fifo2.size()==3);
REQUIRE(fifo2.full());
REQUIRE(not fifo2.empty());
for(size_t i=2;i<3;i--){
struct Test testptr = {0, 0, 0};
REQUIRE(fifo2.retrieve(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
bool equal = testptr == list[i];
REQUIRE(equal);
REQUIRE(fifo2.size()==i);
}
};
SECTION("Assignment Test"){
REQUIRE(fifo.insert(structOne)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structTwo)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.insert(structThree)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(fifo.size()==3);
REQUIRE(fifo.full());
REQUIRE(not fifo.empty());
FIFO<Test, 3> fifo2;
fifo2 = fifo;
REQUIRE(fifo2.size()==3);
REQUIRE(fifo2.full());
REQUIRE(not fifo2.empty());
for(size_t i=2;i<3;i--){
struct Test testptr = {0, 0, 0};
REQUIRE(fifo2.retrieve(&testptr)==static_cast<int>(HasReturnvaluesIF::RETURN_OK));
bool equal = testptr == list[i];
REQUIRE(equal);
REQUIRE(fifo2.size()==i);
}
};
};

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#include <fsfw/container/FixedArrayList.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
TEST_CASE( "FixedArrayList Tests", "[TestFixedArrayList]") {
INFO("FixedArrayList Tests");
using testList = FixedArrayList<uint32_t, 260, uint16_t>;
testList list;
REQUIRE(list.size==0);
REQUIRE(list.insert(10) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(list.size==1);
REQUIRE(list.maxSize()==260);
SECTION("Copy Constructor"){
testList list2(list);
REQUIRE(list2.size==1);
REQUIRE(list2[0] == 10);
REQUIRE(list.maxSize()==260);
};
SECTION("Assignment copy"){
testList list2;
REQUIRE(list2.size==0);
list2 = list;
REQUIRE(list2.size==1);
REQUIRE(list2[0] == 10);
REQUIRE(list.maxSize()==260);
};
SECTION("Fill"){
for(auto i=1;i<260;i++){
REQUIRE(list.insert(i) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
}
REQUIRE(list.insert(260) == static_cast<int>(ArrayList<uint32_t, uint16_t>::FULL));
list.clear();
REQUIRE(list.size == 0);
}
}

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#include <fsfw/container/FixedMap.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
template class FixedMap<unsigned int, unsigned short>;
TEST_CASE( "FixedMap Tests", "[TestFixedMap]") {
INFO("FixedMap Tests");
FixedMap<unsigned int, unsigned short> map(30);
REQUIRE(map.size() == 0);
REQUIRE(map.maxSize() == 30);
REQUIRE(map.getSerializedSize() == sizeof(uint32_t));
REQUIRE(map.empty());
REQUIRE(not map.full());
SECTION("Fill and erase"){
for (uint16_t i=0;i<30;i++){
REQUIRE(map.insert(std::make_pair(i, i+1))== static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.exists(i) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.find(i)->second==i+1);
REQUIRE(not map.empty());
}
REQUIRE(map.insert(0, 0) == static_cast<int>(FixedMap<uint32_t, uint16_t>::KEY_ALREADY_EXISTS));
REQUIRE(map.insert(31, 0) == static_cast<int>(FixedMap<uint32_t, uint16_t>::MAP_FULL));
REQUIRE(map.exists(31) == static_cast<int>(FixedMap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.size() == 30);
REQUIRE(map.full());
{
uint16_t* ptr;
REQUIRE(map.find(5,&ptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(*ptr == 6);
REQUIRE(*(map.findValue(6)) == 7);
REQUIRE(map.find(31,&ptr) == static_cast<int>(FixedMap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
}
REQUIRE(map.getSerializedSize() == (sizeof(uint32_t)+ 30*(sizeof(uint32_t) + sizeof(uint16_t))));
REQUIRE(map.erase(2) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.erase(31) == static_cast<int>(FixedMap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.exists(2) == static_cast<int>(FixedMap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.size() == 29);
for (auto element: map){
if (element.first == 5){
REQUIRE(element.second == 6);
}
}
for (FixedMap<uint32_t, uint16_t>::Iterator it = map.begin(); it != map.end(); it++){
REQUIRE(it->second == it->first + 1);
REQUIRE((*it).second == (*it).first + 1);
it->second = it->second + 1;
REQUIRE(it->second == it->first + 2);
}
for (FixedMap<uint32_t, uint16_t>::Iterator it = map.begin(); it != map.end(); it++){
REQUIRE(map.erase(&it) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
}
REQUIRE(map.size() == 0);
for (FixedMap<uint32_t, uint16_t>::Iterator it = map.begin(); it != map.end(); it++){
// This line should never executed if begin and end is correct
FAIL("Should never be reached, Iterators invalid");
}
};
SECTION("Insert variants"){
FixedMap<uint32_t, uint16_t>::Iterator it = map.end();
REQUIRE(map.insert(36, 37, &it) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(it->first == 36);
REQUIRE(it->second == 37);
REQUIRE(map.size() == 1);
REQUIRE(map.insert(37, 38, nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.find(37)->second == 38);
REQUIRE(map.size() == 2);
REQUIRE(map.insert(37, 24, nullptr) == static_cast<int>(FixedMap<uint32_t, uint16_t>::KEY_ALREADY_EXISTS));
REQUIRE(map.find(37)->second != 24);
REQUIRE(map.size() == 2);
};
SECTION("Serialize and DeSerialize") {
REQUIRE(map.insert(36, 37, nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.insert(37, 38, nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
uint8_t buffer[sizeof(uint32_t)
+ 2 * (sizeof(uint32_t) + sizeof(uint16_t))];
REQUIRE(
map.getSerializedSize()
== (sizeof(uint32_t)
+ 2 * (sizeof(uint32_t) + sizeof(uint16_t))));
uint8_t *loc_ptr = buffer;
size_t size = 0;
REQUIRE(
map.serialize(&loc_ptr, &size, 10, SerializeIF::Endianness::BIG)
== static_cast<int>(SerializeIF::BUFFER_TOO_SHORT));
loc_ptr = buffer;
size = 0;
REQUIRE(
map.serialize(&loc_ptr, &size,
sizeof(uint32_t)
+ 2 * (sizeof(uint32_t) + sizeof(uint16_t)),
SerializeIF::Endianness::BIG)
== static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(size == 16);
uint32_t internal_size = 0;
const uint8_t *ptr2 = buffer;
REQUIRE(
SerializeAdapter::deSerialize(&internal_size, &ptr2, &size,
SerializeIF::Endianness::BIG)
== static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(internal_size == 2);
for (uint8_t i = 36; i < 38; i++) {
uint32_t first_element = 0;
REQUIRE(
SerializeAdapter::deSerialize(&first_element, &ptr2, &size,
SerializeIF::Endianness::BIG)
== static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(first_element == i);
uint16_t second_element = 0;
REQUIRE(
SerializeAdapter::deSerialize(&second_element, &ptr2, &size,
SerializeIF::Endianness::BIG)
== static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(second_element == i + 1);
}
REQUIRE(size == 0);
map.clear();
const uint8_t* constPtr = buffer;
size = 16;
REQUIRE(map.size() == 0);
REQUIRE(map.deSerialize(&constPtr, &size,
SerializeIF::Endianness::BIG) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.size() == 2);
REQUIRE(map.find(36)->second == 37);
for(auto& element: map){
REQUIRE((element.first+1) == element.second);
}
};
SECTION("Failed erase and deSerialize"){
FixedMap<uint32_t, uint16_t>::Iterator it;
std::pair<uint32_t, uint16_t> pair = std::make_pair(44, 43);
it = FixedMap<uint32_t, uint16_t>::Iterator(&pair);
REQUIRE(map.erase(&it) == static_cast<int>(FixedMap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.find(45) == map.end());
size_t toLargeMap = 100;
const uint8_t* ptr = reinterpret_cast<uint8_t*>(&toLargeMap);
size_t size = sizeof(size_t);
REQUIRE(map.deSerialize(&ptr, &size, SerializeIF::Endianness::BIG) ==
static_cast<int>(SerializeIF::TOO_MANY_ELEMENTS));
};
SECTION("Little Endianess"){
map.clear();
map.insert(10,20, nullptr);
uint8_t newBuffer[sizeof(uint32_t)+ 1*(sizeof(uint32_t) + sizeof(uint16_t))];
uint8_t* ptr = newBuffer;
size_t size = 0;
size_t max_size = sizeof(uint32_t)+ 1*(sizeof(uint32_t) + sizeof(uint16_t));
REQUIRE(map.serialize(&ptr, &size, max_size,
SerializeIF::Endianness::LITTLE) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
map.clear();
REQUIRE(map.size()==0);
const uint8_t* ptr2 = newBuffer;
REQUIRE(map.deSerialize(&ptr2, &size,
SerializeIF::Endianness::LITTLE) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.size()==1);
REQUIRE(map.find(10)->second == 20);
};
}

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unittest/tests/container/TestFixedOrderedMultimap.cpp Normal file
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#include <fsfw/container/FixedOrderedMultimap.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
TEST_CASE( "FixedOrderedMultimap Tests", "[TestFixedOrderedMultimap]") {
INFO("FixedOrderedMultimap Tests");
FixedOrderedMultimap<unsigned int, unsigned short> map(30);
REQUIRE(map.size() == 0);
REQUIRE(map.maxSize() == 30);
SECTION("Test insert, find, exists"){
for (uint16_t i=0;i<30;i++){
REQUIRE(map.insert(std::make_pair(i, i+1))== static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.exists(i) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.find(i)->second==i+1);
}
REQUIRE(map.insert(0, 0) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::MAP_FULL));
REQUIRE(map.exists(31) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.size() == 30);
{
uint16_t* ptr;
REQUIRE(map.find(5,&ptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(*ptr == 6);
REQUIRE(map.find(31,&ptr) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
}
REQUIRE(map.erase(2) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.erase(31) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.exists(2) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.size() == 29);
for (auto element: map){
if (element.first == 5){
REQUIRE(element.second == 6);
}
}
for (FixedOrderedMultimap<uint32_t, uint16_t>::Iterator it = map.begin(); it != map.end(); it++){
REQUIRE(it->second == it->first + 1);
REQUIRE((*it).second == (*it).first + 1);
it->second = it->second + 1;
REQUIRE(it->second == it->first + 2);
}
{
FixedOrderedMultimap<uint32_t, uint16_t>::Iterator it = map.begin();
while(it != map.end()){
REQUIRE(map.erase(&it) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
}
REQUIRE(map.size() == 0);
}
for (FixedOrderedMultimap<uint32_t, uint16_t>::Iterator it = map.begin(); it != map.end(); it++){
// This line should never executed if begin and end is correct
FAIL("Should never be reached, Iterators invalid");
}
};
SECTION("Test different insert variants")
{
FixedOrderedMultimap<uint32_t, uint16_t>::Iterator it = map.end();
REQUIRE(map.insert(36, 37, &it) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(it->first == 36);
REQUIRE(it->second == 37);
REQUIRE(map.size() == 1);
REQUIRE(map.insert(37, 38, nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.find(37)->second == 38);
REQUIRE(map.size() == 2);
REQUIRE(map.insert(37, 24, nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.find(37)->second == 38);
REQUIRE(map.insert(0, 1, nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.find(0)->second == 1);
REQUIRE(map.size() == 4);
map.clear();
REQUIRE(map.size() == 0);
}
SECTION("Test different erase and find with no entries"){
FixedOrderedMultimap<uint32_t, uint16_t>::Iterator it;
it = map.end();
REQUIRE(map.erase(&it) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.find(1)== map.end());
}
}
TEST_CASE( "FixedOrderedMultimap Non Trivial Type", "[TestFixedOrderedMultimapNonTrivial]") {
INFO("FixedOrderedMultimap Non Trivial Type");
class TestClass{
public:
TestClass(){};
TestClass(uint32_t number1, uint64_t number2):
number1(number1),number2(number2){};
~TestClass(){};
bool operator==(const TestClass& lhs){
return ((this->number1 == lhs.number1) and (this->number2 == lhs.number2));
}
bool operator!=(const TestClass& lhs){
return not(this->operator ==(lhs));
}
TestClass(const TestClass& other){
this->number1 = other.number1;
this->number2 = other.number2;
};
TestClass& operator=(const TestClass& other){
this->number1 = other.number1;
this->number2 = other.number2;
return *this;
};
private:
uint32_t number1 = 0;
uint64_t number2 = 5;
};
FixedOrderedMultimap<unsigned int, TestClass> map(30);
REQUIRE(map.size() == 0);
REQUIRE(map.maxSize() == 30);
SECTION("Test insert, find, exists"){
for (uint16_t i=0;i<30;i++){
REQUIRE(map.insert(std::make_pair(i, TestClass(i+1,i)))== static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.exists(i) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
bool compare = map.find(i)->second == TestClass(i+1,i);
REQUIRE(compare);
}
REQUIRE(map.insert(0, TestClass()) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::MAP_FULL));
REQUIRE(map.exists(31) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.size() == 30);
{
TestClass* ptr = nullptr;
REQUIRE(map.find(5,&ptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
bool compare = *ptr == TestClass(6, 5);
REQUIRE(compare);
REQUIRE(map.find(31,&ptr) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
}
REQUIRE(map.erase(2) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(map.erase(31) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.exists(2) == static_cast<int>(FixedOrderedMultimap<uint32_t, uint16_t>::KEY_DOES_NOT_EXIST));
REQUIRE(map.size() == 29);
for (auto element: map){
if (element.first == 5){
bool compare = element.second == TestClass(6, 5);
REQUIRE(compare);
}
}
for (FixedOrderedMultimap<uint32_t, TestClass>::Iterator it = map.begin(); it != map.end(); it++){
bool compare = it->second == TestClass(it->first + 1, it->first);
REQUIRE(compare);
compare = (*it).second == TestClass((*it).first + 1, (*it).first);
REQUIRE(compare);
it->second = TestClass(it->first + 2, it->first);
compare = it->second == TestClass(it->first + 2, it->first);
REQUIRE(compare);
}
{
FixedOrderedMultimap<uint32_t, TestClass>::Iterator it = map.begin();
while(it != map.end()){
REQUIRE(map.erase(&it) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
}
REQUIRE(map.size() == 0);
}
for (FixedOrderedMultimap<uint32_t, TestClass>::Iterator it = map.begin(); it != map.end(); it++){
// This line should never executed if begin and end is correct
FAIL("Should never be reached, Iterators invalid");
}
};
SECTION("Test different insert variants")
{
FixedOrderedMultimap<uint32_t, TestClass>::Iterator it = map.end();
REQUIRE(map.insert(36, TestClass(37, 36), &it) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(it->first == 36);
bool compare = it->second == TestClass(37, 36);
REQUIRE(compare);
REQUIRE(map.size() == 1);
REQUIRE(map.insert(37, TestClass(38, 37), nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
compare = map.find(37)->second == TestClass(38, 37);
REQUIRE(compare);
REQUIRE(map.size() == 2);
REQUIRE(map.insert(37, TestClass(24, 37), nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
compare = map.find(37)->second == TestClass(38, 37);
REQUIRE(compare);
REQUIRE(map.insert(0, TestClass(1, 0), nullptr) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
compare = map.find(0)->second == TestClass(1, 0);
REQUIRE(compare);
REQUIRE(map.size() == 4);
map.clear();
REQUIRE(map.size() == 0);
}
SECTION("Test different erase and find with no entries"){
FixedOrderedMultimap<uint32_t, TestClass>::Iterator it;
it = map.end();
REQUIRE(map.erase(&it) == static_cast<int>(FixedOrderedMultimap<uint32_t, TestClass>::KEY_DOES_NOT_EXIST));
REQUIRE(map.find(1)== map.end());
}
}

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#include <fsfw/container/PlacementFactory.h>
#include <fsfw/storagemanager/LocalPool.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
#include <fsfw/container/ArrayList.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
TEST_CASE( "PlacementFactory Tests", "[TestPlacementFactory]") {
INFO("PlacementFactory Tests");
const uint16_t element_sizes[3] = {sizeof(uint16_t), sizeof(uint32_t), sizeof(uint64_t)};
const uint16_t n_elements[3] = {1, 1, 1};
LocalPool<3> storagePool(0x1, element_sizes, n_elements, false, true);
PlacementFactory factory(&storagePool);
SECTION("Pool overload"){
store_address_t address;
uint8_t* ptr = nullptr;
REQUIRE(storagePool.getFreeElement(&address, sizeof(ArrayList<uint32_t, uint16_t>), &ptr)
== static_cast<int>(StorageManagerIF::DATA_TOO_LARGE));
ArrayList<uint32_t, uint16_t>* list2 = factory.generate<ArrayList<uint32_t, uint16_t> >(80);
REQUIRE(list2 == nullptr);
}
SECTION("Test generate and destroy"){
uint64_t* number = factory.generate<uint64_t>(32000);
REQUIRE(number != nullptr);
REQUIRE(*number == 32000);
store_address_t address;
uint8_t* ptr = nullptr;
REQUIRE(storagePool.getFreeElement(&address, sizeof(uint64_t), &ptr)
== static_cast<int>(StorageManagerIF::DATA_TOO_LARGE));
uint64_t* number2 = factory.generate<uint64_t>(12345);
REQUIRE(number2 == nullptr);
REQUIRE(factory.destroy(number) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(storagePool.getFreeElement(&address, sizeof(uint64_t), &ptr)
== static_cast<int>(HasReturnvaluesIF::RETURN_OK));
REQUIRE(storagePool.deleteData(address) == static_cast<int>(HasReturnvaluesIF::RETURN_OK));
//Check that PlacementFactory checks for nullptr
ptr = nullptr;
REQUIRE(factory.destroy(ptr) == static_cast<int>(HasReturnvaluesIF::RETURN_FAILED));
}
}

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#include <fsfw/ipc/MessageQueueIF.h>
#include <fsfw/ipc/QueueFactory.h>
#include "catch.hpp"
#include <array>
#include "core/CatchDefinitions.h"
TEST_CASE("MessageQueue Basic Test","[TestMq]") {
MessageQueueIF* testSenderMq =
QueueFactory::instance()->createMessageQueue(1);
MessageQueueId_t testSenderMqId = testSenderMq->getId();
MessageQueueIF* testReceiverMq =
QueueFactory::instance()->createMessageQueue(1);
MessageQueueId_t testReceiverMqId = testReceiverMq->getId();
std::array<uint8_t, 20> testData { 0 };
testData[0] = 42;
MessageQueueMessage testMessage(testData.data(), 1);
testSenderMq->setDefaultDestination(testReceiverMqId);
SECTION("Simple Tests") {
auto result = testSenderMq->sendMessage(testReceiverMqId, &testMessage);
REQUIRE(result == retval::CATCH_OK);
MessageQueueMessage recvMessage;
result = testReceiverMq->receiveMessage(&recvMessage);
REQUIRE(result == retval::CATCH_OK);
CHECK(recvMessage.getData()[0] == 42);
result = testSenderMq->sendMessage(testReceiverMqId, &testMessage);
REQUIRE(result == retval::CATCH_OK);
MessageQueueId_t senderId = 0;
result = testReceiverMq->receiveMessage(&recvMessage,&senderId);
REQUIRE(result == retval::CATCH_OK);
CHECK(recvMessage.getData()[0] == 42);
CHECK(senderId == testSenderMqId);
senderId = testReceiverMq->getLastPartner();
CHECK(senderId == testSenderMqId);
}
}

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unittest/tests/osal/TestSemaphore.cpp Normal file
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#ifdef LINUX
/*
#include "core/CatchDefinitions.h"
#include "catch.hpp"
#include <fsfw/tasks/SemaphoreFactory.h>
#include <fsfw/timemanager/Stopwatch.h>
TEST_CASE("Binary Semaphore Test" , "[BinSemaphore]") {
//perform set-up here
SemaphoreIF* binSemaph = SemaphoreFactory::instance()->
createBinarySemaphore();
REQUIRE(binSemaph != nullptr);
SECTION("Simple Test") {
// set-up is run for each section
REQUIRE(binSemaph->getSemaphoreCounter() == 1);
REQUIRE(binSemaph->release() ==
static_cast<int>(SemaphoreIF::SEMAPHORE_NOT_OWNED));
REQUIRE(binSemaph->acquire(SemaphoreIF::POLLING) ==
retval::CATCH_OK);
{
// not precise enough on linux.. should use clock instead..
//Stopwatch stopwatch(false);
//REQUIRE(binSemaph->acquire(SemaphoreIF::TimeoutType::WAITING, 5) ==
// SemaphoreIF::SEMAPHORE_TIMEOUT);
//dur_millis_t time = stopwatch.stop();
//CHECK(time == 5);
}
REQUIRE(binSemaph->getSemaphoreCounter() == 0);
REQUIRE(binSemaph->release() == retval::CATCH_OK);
}
SemaphoreFactory::instance()->deleteSemaphore(binSemaph);
// perform tear-down here
}
TEST_CASE("Counting Semaphore Test" , "[CountingSemaph]") {
SECTION("Simple Test") {
}
}
*/
#endif

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unittest/tests/serialize/TestSerialBufferAdapter.cpp Normal file
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#include <fsfw/serialize/SerialBufferAdapter.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
static bool test_value_bool = true;
static uint16_t tv_uint16 {283};
static std::array<uint8_t, 512> testArray;
TEST_CASE("Serial Buffer Adapter", "[single-file]") {
size_t serialized_size = 0;
test_value_bool = true;
uint8_t * arrayPtr = testArray.data();
std::array<uint8_t, 5> test_serial_buffer {5, 4, 3, 2, 1};
SerialBufferAdapter<uint8_t> tv_serial_buffer_adapter =
SerialBufferAdapter<uint8_t>(test_serial_buffer.data(),
test_serial_buffer.size(), false);
tv_uint16 = 16;
SECTION("Serialize without size field") {
SerializeAdapter::serialize(&test_value_bool, &arrayPtr,
&serialized_size, testArray.size(),
SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_serial_buffer_adapter, &arrayPtr,
&serialized_size, testArray.size(),
SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_uint16, &arrayPtr, &serialized_size,
testArray.size(), SerializeIF::Endianness::MACHINE);
REQUIRE(serialized_size == 8);
REQUIRE(testArray[0] == true);
REQUIRE(testArray[1] == 5);
REQUIRE(testArray[2] == 4);
REQUIRE(testArray[3] == 3);
REQUIRE(testArray[4] == 2);
REQUIRE(testArray[5] == 1);
memcpy(&tv_uint16, testArray.data() + 6, sizeof(tv_uint16));
REQUIRE(tv_uint16 == 16);
}
SECTION("Serialize with size field") {
SerialBufferAdapter<uint8_t> tv_serial_buffer_adapter_loc =
SerialBufferAdapter<uint8_t>(test_serial_buffer.data(),
test_serial_buffer.size(), true);
serialized_size = 0;
arrayPtr = testArray.data();
SerializeAdapter::serialize(&test_value_bool, &arrayPtr,&serialized_size,
testArray.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_serial_buffer_adapter_loc, &arrayPtr,
&serialized_size, testArray.size(),
SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_uint16, &arrayPtr, &serialized_size,
testArray.size(), SerializeIF::Endianness::MACHINE);
REQUIRE(serialized_size == 9);
REQUIRE(testArray[0] == true);
REQUIRE(testArray[1] == 5);
REQUIRE(testArray[2] == 5);
REQUIRE(testArray[3] == 4);
REQUIRE(testArray[4] == 3);
REQUIRE(testArray[5] == 2);
REQUIRE(testArray[6] == 1);
memcpy(&tv_uint16, testArray.data() + 7, sizeof(tv_uint16));
REQUIRE(tv_uint16 == 16);
}
SECTION("Test set buffer function") {
SerialBufferAdapter<uint8_t> tv_serial_buffer_adapter_loc =
SerialBufferAdapter<uint8_t>((uint8_t*)nullptr,
0, true);
tv_serial_buffer_adapter_loc.setBuffer(test_serial_buffer.data(),
test_serial_buffer.size());
serialized_size = 0;
arrayPtr = testArray.data();
SerializeAdapter::serialize(&test_value_bool, &arrayPtr,&serialized_size,
testArray.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_serial_buffer_adapter_loc, &arrayPtr,
&serialized_size, testArray.size(),
SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_uint16, &arrayPtr, &serialized_size,
testArray.size(), SerializeIF::Endianness::MACHINE);
REQUIRE(serialized_size == 9);
REQUIRE(testArray[0] == true);
REQUIRE(testArray[1] == 5);
REQUIRE(testArray[2] == 5);
REQUIRE(testArray[3] == 4);
REQUIRE(testArray[4] == 3);
REQUIRE(testArray[5] == 2);
REQUIRE(testArray[6] == 1);
memcpy(&tv_uint16, testArray.data() + 7, sizeof(tv_uint16));
REQUIRE(tv_uint16 == 16);
}
SECTION("Deserialization with size field") {
size_t buffer_size = 4;
memcpy(testArray.data(), &buffer_size, sizeof(uint16_t));
testArray[2] = 1;
testArray[3] = 1;
testArray[4] = 1;
testArray[5] = 0;
std::array<uint8_t, 4> test_recv_array;
arrayPtr = testArray.data();
// copy testArray[1] to testArray[4] into receive buffer, skip
// size field (testArray[0]) for deSerialization.
SerialBufferAdapter<uint16_t> tv_serial_buffer_adapter3 =
SerialBufferAdapter<uint16_t>(test_recv_array.data(), 4, true);
// Deserialization
size_t size = 6;
auto result = tv_serial_buffer_adapter3.deSerialize(
const_cast<const uint8_t**>(&arrayPtr), &size,
SerializeIF::Endianness::MACHINE);
REQUIRE(result == retval::CATCH_OK);
CHECK(test_recv_array[0] == 1);
CHECK(test_recv_array[1] == 1);
CHECK(test_recv_array[2] == 1);
CHECK(test_recv_array[3] == 0);
}
SECTION("Deserialization without size field") {
size_t buffer_size = 4;
memcpy(testArray.data(), &buffer_size, sizeof(uint16_t));
testArray[2] = 1;
testArray[3] = 1;
testArray[4] = 1;
testArray[5] = 0;
std::array<uint8_t, 4> test_recv_array;
arrayPtr = testArray.data() + 2;
// copy testArray[1] to testArray[4] into receive buffer, skip
// size field (testArray[0])
SerialBufferAdapter<uint16_t> tv_serial_buffer_adapter3 =
SerialBufferAdapter<uint16_t>(test_recv_array.data(), 4, false);
// Deserialization
size_t size = 4;
tv_serial_buffer_adapter3.deSerialize(
const_cast<const uint8_t**>(&arrayPtr), &size,
SerializeIF::Endianness::MACHINE);
CHECK(test_recv_array[0] == 1);
CHECK(test_recv_array[1] == 1);
CHECK(test_recv_array[2] == 1);
CHECK(test_recv_array[3] == 0);
}
}

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unittest/tests/serialize/TestSerialLinkedPacket.cpp Normal file
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#include <fsfw/globalfunctions/arrayprinter.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
#include <fsfw/unittest/tests/serialize/TestSerialLinkedPacket.h>
TEST_CASE("Serial Linked Packet" , "[SerLinkPacket]") {
// perform set-up here
uint32_t header = 42;
std::array<uint8_t, 3> testArray {1,2,3};
uint32_t tail = 96;
size_t packetMaxSize = 256;
uint8_t packet [packetMaxSize] = {};
size_t packetLen = 0;
SECTION("Test Deserialization with Serial Buffer Adapter.") {
// This is a serialization of a packet, made "manually".
// We generate a packet which store data big-endian by swapping some
// values. (like coming from ground).
header = EndianConverter::convertBigEndian(header);
std::memcpy(packet, &header, sizeof(header));
packetLen += sizeof(header);
std::copy(testArray.data(), testArray.data() + testArray.size(),
packet + packetLen);
packetLen += testArray.size();
tail = EndianConverter::convertBigEndian(tail);
std::memcpy(packet + packetLen, &tail, sizeof(tail));
packetLen += sizeof(tail);
//arrayprinter::print(packet, packetLen, OutputType::DEC);
// This is the buffer which will be filled when testClass.deSerialize
// is called.
std::array<uint8_t, 3> bufferAdaptee = {};
TestPacket testClass(packet, packetLen, bufferAdaptee.data(),
bufferAdaptee.size());
const uint8_t* readOnlyPointer = packet;
// Deserialize big endian packet by setting bigEndian to true.
ReturnValue_t result = testClass.deSerialize(&readOnlyPointer,
&packetLen, SerializeIF::Endianness::BIG);
REQUIRE(result == retval::CATCH_OK);
CHECK(testClass.getHeader() == 42);
// Equivalent check.
// CHECK(testClass.getBuffer()[0] == 1);
CHECK(bufferAdaptee[0] == 1);
CHECK(bufferAdaptee[1] == 2);
CHECK(bufferAdaptee[2] == 3);
CHECK(testClass.getTail() == 96);
}
SECTION("Test Serialization") {
// Same process as performed in setup, this time using the class
// instead of doing it manually.
TestPacket testClass(header, tail, testArray.data(), testArray.size());
size_t serializedSize = 0;
uint8_t* packetPointer = packet;
// serialize for ground: bigEndian = true.
ReturnValue_t result = testClass.serialize(&packetPointer,
&serializedSize, packetMaxSize, SerializeIF::Endianness::BIG);
REQUIRE(result == retval::CATCH_OK);
// Result should be big endian now.
CHECK(packet[3] == 42);
CHECK(packet[4] == 1);
CHECK(packet[5] == 2);
CHECK(packet[6] == 3);
CHECK(packet[10] == 96);
}
// perform tear-down here
}

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#ifndef UNITTEST_HOSTED_TESTSERIALLINKEDPACKET_H_
#define UNITTEST_HOSTED_TESTSERIALLINKEDPACKET_H_
#include <fsfw/objectmanager/SystemObjectIF.h>
#include <fsfw/parameters/HasParametersIF.h>
#include <fsfw/serialize/SerialBufferAdapter.h>
#include <fsfw/serialize/SerialLinkedListAdapter.h>
#include <cstdint>
class TestPacket: public SerialLinkedListAdapter<SerializeIF> {
public:
/**
* For Deserialization
*/
TestPacket(const uint8_t *somePacket, size_t size, uint8_t * storePointer,
size_t storeSize):
buffer(storePointer, storeSize)
{
setLinks();
}
/**
* For Serialization
*/
TestPacket(uint32_t header, uint32_t tail,
const uint8_t* parameters, size_t paramSize):
header(header), buffer(parameters, paramSize),
tail(tail) {
setLinks();
}
uint32_t getHeader() const {
return header.entry;
}
const uint8_t * getBuffer() {
return buffer.entry.getConstBuffer();
}
const size_t getBufferLength() {
return buffer.getSerializedSize();
}
uint16_t getTail() const {
return tail.entry;
}
private:
void setLinks() {
setStart(&header);
header.setNext(&buffer);
buffer.setNext(&tail);
tail.setEnd();
}
SerializeElement<uint32_t> header = 0;
SerializeElement<SerialBufferAdapter<uint8_t>> buffer;
SerializeElement<uint32_t> tail = 0;
};
#endif /* UNITTEST_TESTFW_NEWTESTS_TESTTEMPLATE_H_ */

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#include <fsfw/serialize/SerializeAdapter.h>
#include "catch.hpp"
#include <array>
#include "core/CatchDefinitions.h"
static bool test_value_bool = true;
static uint8_t tv_uint8 {5};
static uint16_t tv_uint16 {283};
static uint32_t tv_uint32 {929221};
static uint64_t tv_uint64 {2929329429};
static int8_t tv_int8 {-16};
static int16_t tv_int16 {-829};
static int32_t tv_int32 {-2312};
static float tv_float {8.2149214};
static float tv_sfloat = {-922.2321321};
static double tv_double {9.2132142141e8};
static double tv_sdouble {-2.2421e19};
static std::array<uint8_t, 512> test_array;
TEST_CASE( "Serialization size tests", "[TestSerialization]") {
//REQUIRE(unitTestClass.test_autoserialization() == 0);
REQUIRE(SerializeAdapter::getSerializedSize(&test_value_bool) ==
sizeof(test_value_bool));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_uint8) ==
sizeof(tv_uint8));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_uint16) ==
sizeof(tv_uint16));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_uint32 ) ==
sizeof(tv_uint32));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_uint64) ==
sizeof(tv_uint64));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_int8) ==
sizeof(tv_int8));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_int16) ==
sizeof(tv_int16));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_int32) ==
sizeof(tv_int32));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_float) ==
sizeof(tv_float));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_sfloat) ==
sizeof(tv_sfloat ));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_double) ==
sizeof(tv_double));
REQUIRE(SerializeAdapter::getSerializedSize(&tv_sdouble) ==
sizeof(tv_sdouble));
}
TEST_CASE("Auto Serialize Adapter testing", "[single-file]") {
size_t serialized_size = 0;
uint8_t * p_array = test_array.data();
SECTION("Serializing...") {
SerializeAdapter::serialize(&test_value_bool, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_uint8, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_uint16, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_uint32, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_int8, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_int16, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_int32, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_uint64, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_float, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_double, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_sfloat, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
SerializeAdapter::serialize(&tv_sdouble, &p_array,
&serialized_size, test_array.size(), SerializeIF::Endianness::MACHINE);
REQUIRE (serialized_size == 47);
}
SECTION("Deserializing") {
p_array = test_array.data();
size_t remaining_size = serialized_size;
SerializeAdapter::deSerialize(&test_value_bool,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_uint8,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_uint16,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_uint32,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_int8,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_int16,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_int32,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_uint64,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_float,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_double,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_sfloat,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
SerializeAdapter::deSerialize(&tv_sdouble,
const_cast<const uint8_t**>(&p_array), &remaining_size, SerializeIF::Endianness::MACHINE);
REQUIRE(test_value_bool == true);
REQUIRE(tv_uint8 == 5);
REQUIRE(tv_uint16 == 283);
REQUIRE(tv_uint32 == 929221);
REQUIRE(tv_uint64 == 2929329429);
REQUIRE(tv_int8 == -16);
REQUIRE(tv_int16 == -829);
REQUIRE(tv_int32 == -2312);
REQUIRE(tv_float == Approx(8.214921));
REQUIRE(tv_double == Approx(9.2132142141e8));
REQUIRE(tv_sfloat == Approx(-922.2321321));
REQUIRE(tv_sdouble == Approx(-2.2421e19));
}
}

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unittest/tests/storagemanager/TestNewAccessor.cpp Normal file
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#include <fsfw/storagemanager/LocalPool.h>
#include <fsfw/unittest/catch2/catch.hpp>
#include <fsfw/unittest/core/CatchDefinitions.h>
#include <array>
TEST_CASE( "New Accessor" , "[NewAccessor]") {
uint16_t numberOfElements[1] = {1};
uint16_t sizeofElements[1] = {10};
LocalPool<1> SimplePool = LocalPool<1>(0, sizeofElements, numberOfElements);
std::array<uint8_t, 20> testDataArray;
std::array<uint8_t, 20> receptionArray;
store_address_t testStoreId;
ReturnValue_t result = retval::CATCH_FAILED;
for(size_t i = 0; i < testDataArray.size(); i++) {
testDataArray[i] = i;
}
size_t size = 10;
SECTION ("Simple tests getter functions") {
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
auto resultPair = SimplePool.getData(testStoreId);
REQUIRE(resultPair.first == retval::CATCH_OK);
resultPair.second.getDataCopy(receptionArray.data(), 20);
CHECK(resultPair.second.getId() == testStoreId);
CHECK(resultPair.second.size() == 10);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
std::copy(resultPair.second.data(), resultPair.second.data() +
resultPair.second.size(), receptionArray.data());
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
{
auto resultPairLoc = SimplePool.getData(testStoreId);
REQUIRE(resultPairLoc.first == retval::CATCH_OK);
// data should be deleted when accessor goes out of scope.
}
resultPair = SimplePool.getData(testStoreId);
REQUIRE(resultPair.first == (int) StorageManagerIF::DATA_DOES_NOT_EXIST);
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
{
ConstStorageAccessor constAccessor(testStoreId);
result = SimplePool.getData(testStoreId, constAccessor);
REQUIRE(result == retval::CATCH_OK);
constAccessor.getDataCopy(receptionArray.data(), 20);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
// likewise, data should be deleted when accessor gets out of scope.
}
resultPair = SimplePool.getData(testStoreId);
REQUIRE(resultPair.first == (int) StorageManagerIF::DATA_DOES_NOT_EXIST);
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
{
resultPair = SimplePool.getData(testStoreId);
REQUIRE(resultPair.first == retval::CATCH_OK);
resultPair.second.release();
// now data should not be deleted anymore
}
resultPair = SimplePool.getData(testStoreId);
REQUIRE(resultPair.first == retval::CATCH_OK);
resultPair.second.getDataCopy(receptionArray.data(), 20);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
}
SECTION("Simple tests modify functions") {
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
{
StorageAccessor accessor(testStoreId);
result = SimplePool.modifyData(testStoreId, accessor);
REQUIRE(result == retval::CATCH_OK);
CHECK(accessor.getId() == testStoreId);
CHECK(accessor.size() == 10);
accessor.getDataCopy(receptionArray.data(), 20);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
std::copy(accessor.data(), accessor.data() +
accessor.size(), receptionArray.data());
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
// data should be deleted when accessor goes out of scope
}
auto resultPair = SimplePool.getData(testStoreId);
REQUIRE(resultPair.first == (int) StorageManagerIF::DATA_DOES_NOT_EXIST);
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
{
auto resultPairLoc = SimplePool.modifyData(testStoreId);
REQUIRE(resultPairLoc.first == retval::CATCH_OK);
CHECK(resultPairLoc.second.getId() == testStoreId);
CHECK(resultPairLoc.second.size() == 10);
resultPairLoc.second.getDataCopy(receptionArray.data(), 20);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
std::copy(resultPairLoc.second.data(), resultPairLoc.second.data() +
resultPairLoc.second.size(), receptionArray.data());
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
resultPairLoc.second.release();
// data should not be deleted when accessor goes out of scope
}
resultPair = SimplePool.getData(testStoreId);
REQUIRE(resultPair.first == retval::CATCH_OK);
}
SECTION("Write tests") {
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
{
auto resultPair = SimplePool.modifyData(testStoreId);
REQUIRE(resultPair.first == retval::CATCH_OK);
testDataArray[9] = 42;
resultPair.second.write(testDataArray.data(), 10, 0);
// now data should not be deleted
resultPair.second.release();
}
auto resultConstPair = SimplePool.getData(testStoreId);
REQUIRE(resultConstPair.first == retval::CATCH_OK);
resultConstPair.second.getDataCopy(receptionArray.data(), 10);
for(size_t i = 0; i < size-1; i++) {
CHECK(receptionArray[i] == i );
}
CHECK(receptionArray[9] == 42 );
auto resultPair = SimplePool.modifyData(testStoreId);
REQUIRE(resultPair.first == retval::CATCH_OK);
result = resultPair.second.write(testDataArray.data(), 20, 0);
REQUIRE(result == retval::CATCH_FAILED);
result = resultPair.second.write(testDataArray.data(), 10, 5);
REQUIRE(result == retval::CATCH_FAILED);
memset(testDataArray.data(), 42, 5);
result = resultPair.second.write(testDataArray.data(), 5, 5);
REQUIRE(result == retval::CATCH_OK);
resultConstPair = SimplePool.getData(testStoreId);
resultPair.second.getDataCopy(receptionArray.data(), 20);
for(size_t i = 5; i < 10; i++) {
CHECK(receptionArray[i] == 42 );
}
}
}

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unittest/tests/storagemanager/TestPool.cpp Normal file
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#include <config/objects/Factory.h>
#include <fsfw/objectmanager/ObjectManager.h>
#include <fsfw/storagemanager/LocalPool.h>
#include <catch2/catch.hpp>
#include "core/CatchDefinitions.h"
TEST_CASE( "Local Pool Simple Tests [1 Pool]" , "[TestPool]") {
uint16_t numberOfElements[1] = {1};
uint16_t sizeofElements[1] = {10};
LocalPool<1> SimplePool = LocalPool<1>(0, sizeofElements, numberOfElements);
std::array<uint8_t, 20> testDataArray;
std::array<uint8_t, 20> receptionArray;
store_address_t testStoreId;
ReturnValue_t result = retval::CATCH_FAILED;
uint8_t *pointer = nullptr;
const uint8_t * constPointer = nullptr;
uint8_t test = 0;
for(size_t i = 0; i < testDataArray.size(); i++) {
testDataArray[i] = i;
}
size_t size = 10;
SECTION ( "Basic tests") {
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
result = SimplePool.getData(testStoreId, &constPointer, &size);
REQUIRE(result == retval::CATCH_OK);
memcpy(receptionArray.data(), constPointer, size);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
memset(receptionArray.data(), 0, size);
result = SimplePool.modifyData(testStoreId, &pointer, &size);
memcpy(receptionArray.data(), pointer, size);
REQUIRE(result == retval::CATCH_OK);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
result = SimplePool.deleteData(testStoreId);
REQUIRE(result == retval::CATCH_OK);
result = SimplePool.addData(&testStoreId, testDataArray.data(), 15);
CHECK (result == (int) StorageManagerIF::DATA_TOO_LARGE);
}
SECTION ( "Reservation Tests ") {
pointer = nullptr;
result = SimplePool.getFreeElement(&testStoreId, size, &pointer);
REQUIRE (result == retval::CATCH_OK);
memcpy(pointer, testDataArray.data(), size);
constPointer = nullptr;
result = SimplePool.getData(testStoreId, &constPointer, &size);
REQUIRE (result == retval::CATCH_OK);
memcpy(receptionArray.data(), constPointer, size);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
}
SECTION ( "Add, delete, add, add when full") {
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
result = SimplePool.getData(testStoreId, &constPointer, &size);
REQUIRE( result == retval::CATCH_OK);
memcpy(receptionArray.data(), constPointer, size);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
result = SimplePool.deleteData(testStoreId);
REQUIRE(result == retval::CATCH_OK);
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
result = SimplePool.getData(testStoreId, &constPointer, &size);
REQUIRE( result == retval::CATCH_OK);
memcpy(receptionArray.data(), constPointer, size);
for(size_t i = 0; i < size; i++) {
CHECK(receptionArray[i] == i );
}
store_address_t newAddress;
result = SimplePool.addData(&newAddress, testDataArray.data(), size);
REQUIRE(result == (int) StorageManagerIF::DATA_STORAGE_FULL);
}
SECTION ( "Initialize and clear store, delete with pointer") {
result = SimplePool.initialize();
REQUIRE(result == retval::CATCH_OK);
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
SimplePool.clearStore();
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
result = SimplePool.modifyData(testStoreId, &pointer, &size);
REQUIRE(result == retval::CATCH_OK);
store_address_t newId;
result = SimplePool.deleteData(pointer, size, &testStoreId);
REQUIRE(result == retval::CATCH_OK);
REQUIRE(testStoreId.raw != (uint32_t) StorageManagerIF::INVALID_ADDRESS);
result = SimplePool.addData(&testStoreId, testDataArray.data(), size);
REQUIRE(result == retval::CATCH_OK);
}
}

8
unittest/tests/tests.mk Normal file
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CXXSRC += $(wildcard $(CURRENTPATH)/container/*.cpp)
CXXSRC += $(wildcard $(CURRENTPATH)/action/*.cpp)
CXXSRC += $(wildcard $(CURRENTPATH)/serialize/*.cpp)
CXXSRC += $(wildcard $(CURRENTPATH)/storagemanager/*.cpp)
# OSAL not included for now.
INCLUDES += $(CURRENTPATH)