fsfw/unittests/datapoollocal/testDataSet.cpp
2024-11-05 17:02:45 +01:00

281 lines
12 KiB
C++

#include <fsfw/datapool/PoolReadGuard.h>
// #include <fsfw/datapoollocal/HasLocalDataPoolIF.h>
#include <fsfw/datapoollocal/SharedLocalDataSet.h>
#include <fsfw/datapoollocal/StaticLocalDataSet.h>
#include <fsfw/globalfunctions/bitutility.h>
#include <fsfw/objectmanager/ObjectManager.h>
#include <catch2/catch_approx.hpp>
#include <catch2/catch_test_macros.hpp>
#include "CatchDefinitions.h"
#include "mocks/LocalPoolOwnerBase.h"
#include "mocks/MessageQueueMock.h"
#include "tests/TestsConfig.h"
using namespace returnvalue;
TEST_CASE("DataSetTest", "[DataSetTest]") {
auto queue = MessageQueueMock(1);
LocalPoolOwnerBase poolOwner(queue, objects::TEST_LOCAL_POOL_OWNER_BASE);
poolOwner.initialize();
LocalPoolStaticTestDataSet localSet;
SECTION("BasicTest") {
/* Test some basic functions */
CHECK(localSet.getReportingEnabled() == false);
CHECK(localSet.getLocalPoolIdsSerializedSize(false) == 3 * sizeof(lp_id_t));
CHECK(localSet.getLocalPoolIdsSerializedSize(true) == 3 * sizeof(lp_id_t) + sizeof(uint8_t));
CHECK(localSet.getSid() == lpool::testSid);
CHECK(localSet.getCreatorObjectId() == objects::TEST_LOCAL_POOL_OWNER_BASE);
size_t maxSize = localSet.getLocalPoolIdsSerializedSize(true);
uint8_t localPoolIdBuff[maxSize];
/* Skip size field */
auto* lpIds = reinterpret_cast<lp_id_t*>(localPoolIdBuff + 1);
size_t serSize = 0;
auto* localPoolIdBuffPtr = reinterpret_cast<uint8_t*>(localPoolIdBuff);
/* Test local pool ID serialization */
CHECK(localSet.serializeLocalPoolIds(&localPoolIdBuffPtr, &serSize, maxSize,
SerializeIF::Endianness::MACHINE) == returnvalue::OK);
CHECK(serSize == maxSize);
CHECK(localPoolIdBuff[0] == 3);
CHECK(lpIds[0] == localSet.localPoolVarUint8.getDataPoolId());
CHECK(lpIds[1] == localSet.localPoolVarFloat.getDataPoolId());
CHECK(lpIds[2] == localSet.localPoolUint16Vec.getDataPoolId());
/* Now serialize without fill count */
lpIds = reinterpret_cast<lp_id_t*>(localPoolIdBuff);
localPoolIdBuffPtr = localPoolIdBuff;
serSize = 0;
CHECK(localSet.serializeLocalPoolIds(&localPoolIdBuffPtr, &serSize, maxSize,
SerializeIF::Endianness::MACHINE, false) == OK);
CHECK(serSize == maxSize - sizeof(uint8_t));
CHECK(lpIds[0] == localSet.localPoolVarUint8.getDataPoolId());
CHECK(lpIds[1] == localSet.localPoolVarFloat.getDataPoolId());
CHECK(lpIds[2] == localSet.localPoolUint16Vec.getDataPoolId());
{
/* Test read operation. Values should be all zeros */
PoolReadGuard readHelper(&localSet);
REQUIRE(readHelper.getReadResult() == returnvalue::OK);
// CHECK(not localSet.isValid());
CHECK(localSet.localPoolVarUint8.value == 0);
// CHECK(not localSet.localPoolVarUint8.isValid());
CHECK(localSet.localPoolVarFloat.value == Catch::Approx(0.0));
// CHECK(not localSet.localPoolVarUint8.isValid());
CHECK(localSet.localPoolUint16Vec.value[0] == 0);
CHECK(localSet.localPoolUint16Vec.value[1] == 0);
CHECK(localSet.localPoolUint16Vec.value[2] == 0);
// CHECK(not localSet.localPoolVarUint8.isValid());
/* Now set new values, commit should be done by read helper automatically */
localSet.localPoolVarUint8 = 232;
localSet.localPoolVarFloat = -2324.322;
localSet.localPoolUint16Vec.value[0] = 232;
localSet.localPoolUint16Vec.value[1] = 23923;
localSet.localPoolUint16Vec.value[2] = 1;
// localSet.setValidity(true, true);
}
/* Zero out some values for next test */
localSet.localPoolVarUint8 = 0;
localSet.localPoolVarFloat = 0;
localSet.setAllVariablesReadOnly();
CHECK(localSet.localPoolUint16Vec.getReadWriteMode() == pool_rwm_t::VAR_READ);
CHECK(localSet.localPoolVarUint8.getReadWriteMode() == pool_rwm_t::VAR_READ);
CHECK(localSet.localPoolVarFloat.getReadWriteMode() == pool_rwm_t::VAR_READ);
{
/* Now we read again and check whether our zeroed values were overwritten with
the values in the pool */
PoolReadGuard readHelper(&localSet);
REQUIRE(readHelper.getReadResult() == returnvalue::OK);
// CHECK(localSet.isValid());
CHECK(localSet.localPoolVarUint8.value == 232);
// CHECK(localSet.localPoolVarUint8.isValid());
CHECK(localSet.localPoolVarFloat.value == Catch::Approx(-2324.322));
// CHECK(localSet.localPoolVarFloat.isValid());
CHECK(localSet.localPoolUint16Vec.value[0] == 232);
CHECK(localSet.localPoolUint16Vec.value[1] == 23923);
CHECK(localSet.localPoolUint16Vec.value[2] == 1);
// CHECK(localSet.localPoolUint16Vec.isValid());
// Now we serialize these values into a buffer without the validity buffer
maxSize = localSet.getSerializedSize();
CHECK(maxSize == sizeof(uint8_t) + sizeof(uint16_t) * 3 + sizeof(float));
serSize = 0;
/* Already reserve additional space for validity buffer, will be needed later */
uint8_t buffer[maxSize + 1];
uint8_t* buffPtr = buffer;
CHECK(localSet.serialize(&buffPtr, &serSize, maxSize, SerializeIF::Endianness::MACHINE) ==
returnvalue::OK);
uint8_t rawUint8 = buffer[0];
CHECK(rawUint8 == 232);
float rawFloat = 0.0;
std::memcpy(&rawFloat, buffer + sizeof(uint8_t), sizeof(float));
CHECK(rawFloat == Catch::Approx(-2324.322));
uint16_t rawUint16Vec[3];
std::memcpy(&rawUint16Vec, buffer + sizeof(uint8_t) + sizeof(float), 3 * sizeof(uint16_t));
CHECK(rawUint16Vec[0] == 232);
CHECK(rawUint16Vec[1] == 23923);
CHECK(rawUint16Vec[2] == 1);
size_t sizeToDeserialize = maxSize;
/* Now we zeros out the raw entries and deserialize back into the dataset */
std::memset(buffer, 0, sizeof(buffer));
const uint8_t* constBuffPtr = buffer;
CHECK(localSet.deSerialize(&constBuffPtr, &sizeToDeserialize,
SerializeIF::Endianness::MACHINE) == returnvalue::OK);
/* Check whether deserialization was successfull */
CHECK(localSet.localPoolVarUint8.value == 0);
CHECK(localSet.localPoolVarFloat.value == Catch::Approx(0.0));
CHECK(localSet.localPoolVarUint8.value == 0);
CHECK(localSet.localPoolUint16Vec.value[0] == 0);
CHECK(localSet.localPoolUint16Vec.value[1] == 0);
CHECK(localSet.localPoolUint16Vec.value[2] == 0);
/* Validity should be unchanged */
// CHECK(localSet.localPoolVarUint8.isValid());
// CHECK(localSet.localPoolVarFloat.isValid());
// CHECK(localSet.localPoolUint16Vec.isValid());
/* Now we do the same process but with the validity buffer */
localSet.localPoolVarUint8 = 232;
localSet.localPoolVarFloat = -2324.322;
localSet.localPoolUint16Vec.value[0] = 232;
localSet.localPoolUint16Vec.value[1] = 23923;
localSet.localPoolUint16Vec.value[2] = 1;
// localSet.localPoolVarUint8.setValid(true);
// localSet.localPoolVarFloat.setValid(false);
// localSet.localPoolUint16Vec.setValid(true);
// localSet.setValidityBufferGeneration(true);
maxSize = localSet.getSerializedSize();
CHECK(maxSize == sizeof(uint8_t) + sizeof(uint16_t) * 3 + sizeof(float) + 1);
serSize = 0;
buffPtr = buffer;
CHECK(localSet.serialize(&buffPtr, &serSize, maxSize, SerializeIF::Endianness::MACHINE) ==
returnvalue::OK);
CHECK(rawUint8 == 232);
std::memcpy(&rawFloat, buffer + sizeof(uint8_t), sizeof(float));
CHECK(rawFloat == Catch::Approx(-2324.322));
std::memcpy(&rawUint16Vec, buffer + sizeof(uint8_t) + sizeof(float), 3 * sizeof(uint16_t));
CHECK(rawUint16Vec[0] == 232);
CHECK(rawUint16Vec[1] == 23923);
CHECK(rawUint16Vec[2] == 1);
/* We can do it like this because the buffer only has one byte for
less than 8 variables */
uint8_t* validityByte = buffer + sizeof(buffer) - 1;
bool bitSet = false;
bitutil::get(validityByte, 0, bitSet);
CHECK(bitSet == true);
bitutil::get(validityByte, 1, bitSet);
CHECK(bitSet == false);
bitutil::get(validityByte, 2, bitSet);
CHECK(bitSet == true);
/* Now we manipulate the validity buffer for the deserialization */
bitutil::clear(validityByte, 0);
bitutil::set(validityByte, 1);
bitutil::clear(validityByte, 2);
/* Zero out everything except validity buffer */
std::memset(buffer, 0, sizeof(buffer) - 1);
sizeToDeserialize = maxSize;
constBuffPtr = buffer;
CHECK(localSet.deSerialize(&constBuffPtr, &sizeToDeserialize,
SerializeIF::Endianness::MACHINE) == returnvalue::OK);
/* Check whether deserialization was successfull */
CHECK(localSet.localPoolVarUint8.value == 0);
CHECK(localSet.localPoolVarFloat.value == Catch::Approx(0.0));
CHECK(localSet.localPoolVarUint8.value == 0);
CHECK(localSet.localPoolUint16Vec.value[0] == 0);
CHECK(localSet.localPoolUint16Vec.value[1] == 0);
CHECK(localSet.localPoolUint16Vec.value[2] == 0);
// CHECK(not localSet.localPoolVarUint8.isValid());
// CHECK(localSet.localPoolVarFloat.isValid());
// CHECK(not localSet.localPoolUint16Vec.isValid());
}
/* Common fault test cases */
LocalPoolObjectBase* variableHandle = poolOwner.getPoolObjectHandle(lpool::uint32VarId);
CHECK(variableHandle != nullptr);
CHECK(localSet.registerVariable(variableHandle) == static_cast<int>(DataSetIF::DATA_SET_FULL));
variableHandle = nullptr;
REQUIRE(localSet.registerVariable(variableHandle) ==
static_cast<int>(DataSetIF::POOL_VAR_NULL));
}
SECTION("MorePoolVariables") {
LocalDataSet set(poolOwner.sharedPool, 2, 10);
/* Register same variables again to get more than 8 registered variables */
for (uint8_t idx = 0; idx < 8; idx++) {
REQUIRE(set.registerVariable(&localSet.localPoolVarUint8) == returnvalue::OK);
}
REQUIRE(set.registerVariable(&localSet.localPoolVarUint8) == returnvalue::OK);
REQUIRE(set.registerVariable(&localSet.localPoolUint16Vec) == returnvalue::OK);
// set.setValidityBufferGeneration(true);
{
PoolReadGuard readHelper(&localSet);
localSet.localPoolVarUint8.value = 42;
// localSet.localPoolVarUint8.setValid(true);
// localSet.localPoolUint16Vec.setValid(false);
}
size_t maxSize = set.getSerializedSize();
CHECK(maxSize == 9 + sizeof(uint16_t) * 3 + 2);
size_t serSize = 0;
/* Already reserve additional space for validity buffer, will be needed later */
uint8_t buffer[maxSize + 1];
uint8_t* buffPtr = buffer;
CHECK(set.serialize(&buffPtr, &serSize, maxSize, SerializeIF::Endianness::MACHINE) == OK);
std::array<uint8_t, 2> validityBuffer{};
std::memcpy(validityBuffer.data(), buffer + 9 + sizeof(uint16_t) * 3, 2);
/* The first 9 variables should be valid */
CHECK(validityBuffer[0] == 0xff);
bool bitSet = false;
bitutil::get(validityBuffer.data() + 1, 0, bitSet);
CHECK(bitSet == true);
bitutil::get(validityBuffer.data() + 1, 1, bitSet);
CHECK(bitSet == false);
/* Now we invert the validity */
validityBuffer[0] = 0;
validityBuffer[1] = 0b0100'0000;
std::memcpy(buffer + 9 + sizeof(uint16_t) * 3, validityBuffer.data(), 2);
const uint8_t* constBuffPtr = buffer;
size_t sizeToDeSerialize = serSize;
CHECK(set.deSerialize(&constBuffPtr, &sizeToDeSerialize, SerializeIF::Endianness::MACHINE) ==
returnvalue::OK);
// CHECK(localSet.localPoolVarUint8.isValid() == false);
// CHECK(localSet.localPoolUint16Vec.isValid() == true);
}
SECTION("SharedDataSet") {
object_id_t sharedSetId = objects::SHARED_SET_ID;
SharedLocalDataSet sharedSet(sharedSetId, poolOwner.sharedPool, lpool::testSetId, 5);
localSet.localPoolVarUint8.setReadWriteMode(pool_rwm_t::VAR_WRITE);
localSet.localPoolUint16Vec.setReadWriteMode(pool_rwm_t::VAR_WRITE);
CHECK(sharedSet.registerVariable(&localSet.localPoolVarUint8) == returnvalue::OK);
CHECK(sharedSet.registerVariable(&localSet.localPoolUint16Vec) == returnvalue::OK);
CHECK(sharedSet.initialize() == returnvalue::OK);
CHECK(sharedSet.lockDataset() == returnvalue::OK);
CHECK(sharedSet.unlockDataset() == returnvalue::OK);
{
// PoolReadGuard rg(&sharedSet);
// CHECK(rg.getReadResult() == returnvalue::OK);
localSet.localPoolVarUint8.value = 5;
localSet.localPoolUint16Vec.value[0] = 1;
localSet.localPoolUint16Vec.value[1] = 2;
localSet.localPoolUint16Vec.value[2] = 3;
CHECK(sharedSet.commit() == returnvalue::OK);
}
// sharedSet.setReadCommitProtectionBehaviour(true);
}
}