fsfw/datapool/PoolRawAccess.cpp

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#include <framework/datapool/DataPool.h>
#include <framework/datapool/PoolEntryIF.h>
#include <framework/datapool/PoolRawAccess.h>
#include <framework/serviceinterface/ServiceInterfaceStream.h>
#include <framework/osal/Endiness.h>
PoolRawAccess::PoolRawAccess(uint32_t set_id, uint8_t setArrayEntry,
DataSetIF* data_set, ReadWriteMode_t setReadWriteMode) :
dataPoolId(set_id), arrayEntry(setArrayEntry), valid(false), type(Type::UNKNOWN_TYPE), typeSize(
0), arraySize(0), sizeTillEnd(0), readWriteMode(setReadWriteMode) {
memset(value, 0, sizeof(value));
if (data_set != NULL) {
data_set->registerVariable(this);
}
}
PoolRawAccess::~PoolRawAccess() {
}
ReturnValue_t PoolRawAccess::read() {
PoolEntryIF* read_out = ::dataPool.getRawData(dataPoolId);
if (read_out != NULL) {
valid = read_out->getValid();
if (read_out->getSize() > arrayEntry) {
arraySize = read_out->getSize();
typeSize = read_out->getByteSize() / read_out->getSize();
type = read_out->getType();
if (typeSize <= sizeof(value)) {
uint16_t arrayPosition = arrayEntry * typeSize;
sizeTillEnd = read_out->getByteSize() - arrayPosition;
uint8_t* ptr =
&((uint8_t*) read_out->getRawData())[arrayPosition];
memcpy(value, ptr, typeSize);
return HasReturnvaluesIF::RETURN_OK;
} else {
//Error value type too large.
}
} else {
//Error index requested too large
}
} else {
//Error entry does not exist.
}
error << "PoolRawAccess: read of DP Variable 0x" << std::hex << dataPoolId
<< std::dec << " failed." << std::endl;
valid = INVALID;
typeSize = 0;
sizeTillEnd = 0;
memset(value, 0, sizeof(value));
return HasReturnvaluesIF::RETURN_FAILED;
}
ReturnValue_t PoolRawAccess::commit() {
PoolEntryIF* write_back = ::dataPool.getRawData(dataPoolId);
if ((write_back != NULL) && (readWriteMode != VAR_READ)) {
write_back->setValid(valid);
uint8_t array_position = arrayEntry * typeSize;
uint8_t* ptr = &((uint8_t*) write_back->getRawData())[array_position];
memcpy(ptr, value, typeSize);
return HasReturnvaluesIF::RETURN_OK;
} else {
return HasReturnvaluesIF::RETURN_FAILED;
}
}
uint8_t* PoolRawAccess::getEntry() {
return value;
}
ReturnValue_t PoolRawAccess::getEntryEndianSafe(uint8_t* buffer,
uint32_t* writtenBytes, uint32_t maxSize) {
uint8_t* data_ptr = getEntry();
// debug << "PoolRawAccess::getEntry: Array position: " << index * size_of_type << " Size of T: " << (int)size_of_type << " ByteSize: " << byte_size << " Position: " << *size << std::endl;
if (typeSize == 0)
return DATA_POOL_ACCESS_FAILED;
if (typeSize > maxSize)
return INCORRECT_SIZE;
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#ifndef BYTE_ORDER_SYSTEM
#error BYTE_ORDER_SYSTEM not defined
#elif BYTE_ORDER_SYSTEM == LITTLE_ENDIAN
for (uint8_t count = 0; count < typeSize; count++) {
buffer[count] = data_ptr[typeSize - count - 1];
}
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#elif BYTE_ORDER_SYSTEM == BIG_ENDIAN
memcpy(buffer, data_ptr, typeSize);
#endif
*writtenBytes = typeSize;
return HasReturnvaluesIF::RETURN_OK;
}
Type PoolRawAccess::getType() {
return type;
}
uint8_t PoolRawAccess::getSizeOfType() {
return typeSize;
}
uint8_t PoolRawAccess::getArraySize(){
return arraySize;
}
uint32_t PoolRawAccess::getDataPoolId() const {
return dataPoolId;
}
PoolVariableIF::ReadWriteMode_t PoolRawAccess::getReadWriteMode() const {
return readWriteMode;
}
ReturnValue_t PoolRawAccess::setEntryFromBigEndian(const uint8_t* buffer,
uint32_t setSize) {
if (typeSize == setSize) {
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#ifndef BYTE_ORDER_SYSTEM
#error BYTE_ORDER_SYSTEM not defined
#elif BYTE_ORDER_SYSTEM == LITTLE_ENDIAN
for (uint8_t count = 0; count < typeSize; count++) {
value[count] = buffer[typeSize - count - 1];
}
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#elif BYTE_ORDER_SYSTEM == BIG_ENDIAN
memcpy(value, buffer, typeSize);
#endif
return HasReturnvaluesIF::RETURN_OK;
} else {
error << "PoolRawAccess::setEntryFromBigEndian: Illegal sizes: Internal"
<< (uint32_t) typeSize << ", Requested: " << setSize
<< std::endl;
return INCORRECT_SIZE;
}
}
bool PoolRawAccess::isValid() const {
if (valid != INVALID)
return true;
else
return false;
}
void PoolRawAccess::setValid(uint8_t valid) {
this->valid = valid;
}
uint16_t PoolRawAccess::getSizeTillEnd() const {
return sizeTillEnd;
}
ReturnValue_t PoolRawAccess::serialize(uint8_t** buffer, size_t* size,
size_t maxSize, Endianness streamEndianness) const {
//TODO integer overflow
if (typeSize + *size <= maxSize) {
#warning use endian swapper
if (1) {
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#ifndef BYTE_ORDER_SYSTEM
#error BYTE_ORDER_SYSTEM not defined
#elif BYTE_ORDER_SYSTEM == LITTLE_ENDIAN
for (uint8_t count = 0; count < typeSize; count++) {
(*buffer)[count] = value[typeSize - count - 1];
}
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#elif BYTE_ORDER_SYSTEM == BIG_ENDIAN
memcpy(*buffer, value, typeSize);
#endif
} else {
memcpy(*buffer, value, typeSize);
}
*size += typeSize;
(*buffer) += typeSize;
return HasReturnvaluesIF::RETURN_OK;
} else {
return SerializeIF::BUFFER_TOO_SHORT;
}
}
size_t PoolRawAccess::getSerializedSize() const {
return typeSize;
}
ReturnValue_t PoolRawAccess::deSerialize(const uint8_t** buffer, size_t* size,
Endianness streamEndianness) {
if (*size >= typeSize) {
*size -= typeSize;
if (1) {
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#ifndef BYTE_ORDER_SYSTEM
#error BYTE_ORDER_SYSTEM not defined
#elif BYTE_ORDER_SYSTEM == LITTLE_ENDIAN
for (uint8_t count = 0; count < typeSize; count++) {
value[count] = (*buffer)[typeSize - count - 1];
}
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#elif BYTE_ORDER_SYSTEM == BIG_ENDIAN
memcpy(value, *buffer, typeSize);
#endif
} else {
memcpy(value, *buffer, typeSize);
}
*buffer += typeSize;
return HasReturnvaluesIF::RETURN_OK;
} else {
return SerializeIF::STREAM_TOO_SHORT;
}
}