Commit 82b968ef authored by unknown's avatar unknown

removed copy paste index code

improved handling of bits in last word


ndb/include/ndbapi/NdbIndexOperation.hpp:
  Removed copy paste index code
ndb/include/ndbapi/NdbOperation.hpp:
  removed bits in last word
ndb/src/kernel/blocks/dbtux/DbtuxDebug.cpp:
  fix debug print
ndb/src/ndbapi/NdbIndexOperation.cpp:
  Removed copy paste index code
ndb/src/ndbapi/NdbOperationSearch.cpp:
  better handling of bits in last word
parent 397a2a17
...@@ -173,29 +173,17 @@ private: ...@@ -173,29 +173,17 @@ private:
NdbIndexOperation(Ndb* aNdb); NdbIndexOperation(Ndb* aNdb);
~NdbIndexOperation(); ~NdbIndexOperation();
void closeScan();
int receiveTCINDXREF(NdbApiSignal* aSignal); int receiveTCINDXREF(NdbApiSignal* aSignal);
// Overloaded method from NdbOperation
void setLastFlag(NdbApiSignal* signal, Uint32 lastFlag);
// Overloaded methods from NdbCursorOperation
int executeCursor(int ProcessorId);
// Overloaded methods from NdbCursorOperation // Overloaded methods from NdbCursorOperation
int indxInit(const class NdbIndexImpl* anIndex, int indxInit(const class NdbIndexImpl* anIndex,
const class NdbTableImpl* aTable, const class NdbTableImpl* aTable,
NdbConnection* myConnection); NdbConnection* myConnection);
int equal_impl(const class NdbColumnImpl*, const char* aValue, Uint32 len);
int prepareSend(Uint32 TC_ConnectPtr, Uint64 TransactionId); int prepareSend(Uint32 TC_ConnectPtr, Uint64 TransactionId);
// Private attributes // Private attributes
const NdbIndexImpl* m_theIndex; const NdbIndexImpl* m_theIndex;
Uint32 m_theIndexDefined[NDB_MAX_ATTRIBUTES_IN_INDEX][3];
Uint32 m_theIndexLen; // Length of the index in words
Uint32 m_theNoOfIndexDefined; // The number of index attributes
}; };
#endif #endif
...@@ -821,8 +821,7 @@ protected: ...@@ -821,8 +821,7 @@ protected:
int insertKEYINFO(const char* aValue, int insertKEYINFO(const char* aValue,
Uint32 aStartPosition, Uint32 aStartPosition,
Uint32 aKeyLenInByte, Uint32 aKeyLenInByte);
Uint32 anAttrBitsInLastWord);
virtual void setErrorCode(int aErrorCode); virtual void setErrorCode(int aErrorCode);
virtual void setErrorCodeAbort(int aErrorCode); virtual void setErrorCodeAbort(int aErrorCode);
......
...@@ -370,7 +370,6 @@ operator<<(NdbOut& out, const Dbtux::Index& index) ...@@ -370,7 +370,6 @@ operator<<(NdbOut& out, const Dbtux::Index& index)
{ {
out << "[Index " << hex << &index; out << "[Index " << hex << &index;
out << " [tableId " << dec << index.m_tableId << "]"; out << " [tableId " << dec << index.m_tableId << "]";
out << " [fragOff " << dec << index.m_fragOff << "]";
out << " [numFrags " << dec << index.m_numFrags << "]"; out << " [numFrags " << dec << index.m_numFrags << "]";
for (unsigned i = 0; i < index.m_numFrags; i++) { for (unsigned i = 0; i < index.m_numFrags; i++) {
out << " [frag " << dec << i << " "; out << " [frag " << dec << i << " ";
...@@ -393,7 +392,6 @@ operator<<(NdbOut& out, const Dbtux::Frag& frag) ...@@ -393,7 +392,6 @@ operator<<(NdbOut& out, const Dbtux::Frag& frag)
out << "[Frag " << hex << &frag; out << "[Frag " << hex << &frag;
out << " [tableId " << dec << frag.m_tableId << "]"; out << " [tableId " << dec << frag.m_tableId << "]";
out << " [indexId " << dec << frag.m_indexId << "]"; out << " [indexId " << dec << frag.m_indexId << "]";
out << " [fragOff " << dec << frag.m_fragOff << "]";
out << " [fragId " << dec << frag.m_fragId << "]"; out << " [fragId " << dec << frag.m_fragId << "]";
out << " [descPage " << hex << frag.m_descPage << "]"; out << " [descPage " << hex << frag.m_descPage << "]";
out << " [descOff " << dec << frag.m_descOff << "]"; out << " [descOff " << dec << frag.m_descOff << "]";
......
...@@ -28,9 +28,7 @@ ...@@ -28,9 +28,7 @@
NdbIndexOperation::NdbIndexOperation(Ndb* aNdb) : NdbIndexOperation::NdbIndexOperation(Ndb* aNdb) :
NdbOperation(aNdb), NdbOperation(aNdb),
m_theIndex(NULL), m_theIndex(NULL)
m_theIndexLen(0),
m_theNoOfIndexDefined(0)
{ {
m_tcReqGSN = GSN_TCINDXREQ; m_tcReqGSN = GSN_TCINDXREQ;
m_attrInfoGSN = GSN_INDXATTRINFO; m_attrInfoGSN = GSN_INDXATTRINFO;
...@@ -72,14 +70,7 @@ NdbIndexOperation::indxInit(const NdbIndexImpl * anIndex, ...@@ -72,14 +70,7 @@ NdbIndexOperation::indxInit(const NdbIndexImpl * anIndex,
} }
m_theIndex = anIndex; m_theIndex = anIndex;
m_accessTable = anIndex->m_table; m_accessTable = anIndex->m_table;
m_theIndexLen = 0;
m_theNoOfIndexDefined = 0;
for (Uint32 i=0; i<NDB_MAX_ATTRIBUTES_IN_INDEX; i++)
for (int j=0; j<3; j++)
m_theIndexDefined[i][j] = false;
TcKeyReq * tcKeyReq = CAST_PTR(TcKeyReq, theTCREQ->getDataPtrSend()); TcKeyReq * tcKeyReq = CAST_PTR(TcKeyReq, theTCREQ->getDataPtrSend());
tcKeyReq->scanInfo = 0;
theKEYINFOptr = &tcKeyReq->keyInfo[0]; theKEYINFOptr = &tcKeyReq->keyInfo[0];
theATTRINFOptr = &tcKeyReq->attrInfo[0]; theATTRINFOptr = &tcKeyReq->attrInfo[0];
return 0; return 0;
...@@ -172,284 +163,6 @@ int NdbIndexOperation::interpretedDeleteTuple() ...@@ -172,284 +163,6 @@ int NdbIndexOperation::interpretedDeleteTuple()
return NdbOperation::interpretedDeleteTuple(); return NdbOperation::interpretedDeleteTuple();
} }
int NdbIndexOperation::equal_impl(const NdbColumnImpl* tAttrInfo,
const char* aValuePassed,
Uint32 aVariableKeyLen)
{
register Uint32 tAttrId;
Uint32 tData;
Uint32 tKeyInfoPosition;
const char* aValue = aValuePassed;
Uint32 xfrmData[1024];
Uint32 tempData[1024];
if ((theStatus == OperationDefined) &&
(aValue != NULL) &&
(tAttrInfo != NULL )) {
/************************************************************************
* Start by checking that the attribute is an index key.
* This value is also the word order in the tuple key of this
* tuple key attribute.
* Then check that this tuple key has not already been defined.
* Finally check if all tuple key attributes have been defined. If
* this is true then set Operation state to tuple key defined.
************************************************************************/
tAttrId = tAttrInfo->m_attrId;
tKeyInfoPosition = tAttrInfo->m_keyInfoPos;
Uint32 i = 0;
// Check that the attribute is part if the index attributes
// by checking if it is a primary key attribute of index table
if (tAttrInfo->m_pk) {
Uint32 tKeyDefined = theTupleKeyDefined[0][2];
Uint32 tKeyAttrId = theTupleKeyDefined[0][0];
do {
if (tKeyDefined == false) {
goto keyEntryFound;
} else {
if (tKeyAttrId != tAttrId) {
/******************************************************************
* We read the key defined variable in advance.
* It could potentially read outside its area when
* i = MAXNROFTUPLEKEY - 1,
* it is not a problem as long as the variable
* theTupleKeyDefined is defined
* in the middle of the object.
* Reading wrong data and not using it causes no problems.
*****************************************************************/
i++;
tKeyAttrId = theTupleKeyDefined[i][0];
tKeyDefined = theTupleKeyDefined[i][2];
continue;
} else {
goto equal_error2;
}//if
}//if
} while (i < NDB_MAX_ATTRIBUTES_IN_INDEX);
goto equal_error2;
} else {
goto equal_error1;
}
/**************************************************************************
* Now it is time to retrieve the tuple key data from the pointer supplied
* by the application.
* We have to retrieve the size of the attribute in words and bits.
*************************************************************************/
keyEntryFound:
m_theIndexDefined[i][0] = tAttrId;
m_theIndexDefined[i][1] = tKeyInfoPosition;
m_theIndexDefined[i][2] = true;
Uint32 sizeInBytes = tAttrInfo->m_attrSize * tAttrInfo->m_arraySize;
{
/*************************************************************************
* Check if the pointer of the value passed is aligned on a 4 byte
* boundary. If so only assign the pointer to the internal variable
* aValue. If it is not aligned then we start by copying the value to
* tempData and use this as aValue instead.
*************************************************************************/
const int attributeSize = sizeInBytes;
const int slack = sizeInBytes & 3;
if ((((UintPtr)aValue & 3) != 0) || (slack != 0)){
memcpy(&tempData[0], aValue, attributeSize);
aValue = (char*)&tempData[0];
if(slack != 0) {
char * tmp = (char*)&tempData[0];
memset(&tmp[attributeSize], 0, (4 - slack));
}//if
}//if
}
const char* aValueToWrite = aValue;
CHARSET_INFO* cs = tAttrInfo->m_cs;
if (cs != 0) {
// current limitation: strxfrm does not increase length
assert(cs->strxfrm_multiply == 1);
unsigned n =
(*cs->coll->strnxfrm)(cs,
(uchar*)xfrmData, sizeof(xfrmData),
(const uchar*)aValue, sizeInBytes);
while (n < sizeInBytes)
((uchar*)xfrmData)[n++] = 0x20;
aValue = (char*)xfrmData;
}
Uint32 bitsInLastWord = 8 * (sizeInBytes & 3) ;
Uint32 totalSizeInWords = (sizeInBytes + 3)/4;// Inc. bits in last word
Uint32 sizeInWords = sizeInBytes / 4; // Exc. bits in last word
if (true){ //tArraySize != 0) {
Uint32 tIndexLen = m_theIndexLen;
m_theIndexLen = tIndexLen + totalSizeInWords;
if ((aVariableKeyLen == sizeInBytes) ||
(aVariableKeyLen == 0)) {
;
} else {
goto equal_error3;
}
}
#if 0
else {
/************************************************************************
* The attribute is a variable array. We need to use the length parameter
* to know the size of this attribute in the key information and
* variable area. A key is however not allowed to be larger than 4
* kBytes and this is checked for variable array attributes
* used as keys.
***********************************************************************/
Uint32 tMaxVariableKeyLenInWord = (MAXTUPLEKEYLENOFATTERIBUTEINWORD -
tKeyInfoPosition);
tAttrSizeInBits = aVariableKeyLen << 3;
tAttrSizeInWords = tAttrSizeInBits >> 5;
tAttrBitsInLastWord = tAttrSizeInBits - (tAttrSizeInWords << 5);
tAttrLenInWords = ((tAttrSizeInBits + 31) >> 5);
if (tAttrLenInWords > tMaxVariableKeyLenInWord) {
setErrorCodeAbort(4207);
return -1;
}//if
m_theIndexLen = m_theIndexLen + tAttrLenInWords;
}//if
#endif
int tDistrKey = tAttrInfo->m_distributionKey;
OperationType tOpType = theOperationType;
if ((tDistrKey != 1)) {
;
} else {
/** TODO DISTKEY */
theDistrKeyIndicator = 1;
}
/**************************************************************************
* If the operation is an insert request and the attribute is stored then
* we also set the value in the stored part through putting the
* information in the INDXATTRINFO signals.
*************************************************************************/
if ((tOpType == InsertRequest) ||
(tOpType == WriteRequest)) {
// invalid data can crash kernel
if (cs != NULL &&
(*cs->cset->well_formed_len)(cs,
aValueToWrite,
aValueToWrite + sizeInBytes,
sizeInBytes) != sizeInBytes)
goto equal_error4;
Uint32 ahValue;
Uint32 sz = totalSizeInWords;
AttributeHeader::init(&ahValue, tAttrId, sz);
insertATTRINFO( ahValue );
insertATTRINFOloop((Uint32*)aValueToWrite, sizeInWords);
if (bitsInLastWord != 0) {
tData = *(Uint32*)(aValueToWrite + (sizeInWords << 2));
tData = convertEndian(tData);
tData = tData & ((1 << bitsInLastWord) - 1);
tData = convertEndian(tData);
insertATTRINFO( tData );
}//if
}//if
/**************************************************************************
* Store the Key information in the TCINDXREQ and INDXKEYINFO signals.
*************************************************************************/
if (insertKEYINFO(aValue, tKeyInfoPosition,
totalSizeInWords, bitsInLastWord) != -1) {
/************************************************************************
* Add one to number of tuple key attributes defined.
* If all have been defined then set the operation state to indicate
* that tuple key is defined.
* Thereby no more search conditions are allowed in this version.
***********************************************************************/
Uint32 tNoIndexDef = m_theNoOfIndexDefined;
Uint32 tErrorLine = theErrorLine;
int tNoIndexAttrs = m_theIndex->m_columns.size();
unsigned char tInterpretInd = theInterpretIndicator;
tNoIndexDef++;
m_theNoOfIndexDefined = tNoIndexDef;
tErrorLine++;
theErrorLine = tErrorLine;
if (int(tNoIndexDef) == tNoIndexAttrs) {
if (tOpType == UpdateRequest) {
if (tInterpretInd == 1) {
theStatus = GetValue;
} else {
theStatus = SetValue;
}//if
return 0;
} else if ((tOpType == ReadRequest) || (tOpType == DeleteRequest) ||
(tOpType == ReadExclusive)) {
theStatus = GetValue;
// create blob handles automatically
if (tOpType == DeleteRequest && m_currentTable->m_noOfBlobs != 0) {
for (unsigned i = 0; i < m_currentTable->m_columns.size(); i++) {
NdbColumnImpl* c = m_currentTable->m_columns[i];
assert(c != 0);
if (c->getBlobType()) {
if (getBlobHandle(theNdbCon, c) == NULL)
return -1;
}
}
}
return 0;
} else if ((tOpType == InsertRequest) || (tOpType == WriteRequest)) {
theStatus = SetValue;
return 0;
} else {
setErrorCodeAbort(4005);
return -1;
}//if
}//if
return 0;
} else {
return -1;
}//if
} else {
if (theStatus != OperationDefined) {
return -1;
}//if
if (aValue == NULL) {
setErrorCodeAbort(4505);
return -1;
}//if
if ( tAttrInfo == NULL ) {
setErrorCodeAbort(4004);
return -1;
}//if
}//if
return -1;
equal_error1:
setErrorCodeAbort(4205);
return -1;
equal_error2:
setErrorCodeAbort(4206);
return -1;
equal_error3:
setErrorCodeAbort(4209);
return -1;
equal_error4:
setErrorCodeAbort(744);
return -1;
}
int NdbIndexOperation::executeCursor(int aProcessorId)
{
printf("NdbIndexOperation::executeCursor NYI\n");
// NYI
return -1;
}
void
NdbIndexOperation::setLastFlag(NdbApiSignal* signal, Uint32 lastFlag)
{
TcKeyReq * const req = CAST_PTR(TcKeyReq, signal->getDataPtrSend());
TcKeyReq::setExecuteFlag(req->requestInfo, lastFlag);
}
int int
NdbIndexOperation::prepareSend(Uint32 aTC_ConnectPtr, Uint64 aTransactionId) NdbIndexOperation::prepareSend(Uint32 aTC_ConnectPtr, Uint64 aTransactionId)
{ {
...@@ -548,7 +261,7 @@ NdbIndexOperation::prepareSend(Uint32 aTC_ConnectPtr, Uint64 aTransactionId) ...@@ -548,7 +261,7 @@ NdbIndexOperation::prepareSend(Uint32 aTC_ConnectPtr, Uint64 aTransactionId)
Uint8 tDirtyIndicator = theDirtyIndicator; Uint8 tDirtyIndicator = theDirtyIndicator;
OperationType tOperationType = theOperationType; OperationType tOperationType = theOperationType;
Uint32 tIndexLen = m_theIndexLen; Uint32 tIndexLen = theTupKeyLen;
Uint8 abortOption = theNdbCon->m_abortOption; Uint8 abortOption = theNdbCon->m_abortOption;
tcKeyReq->setDirtyFlag(tReqInfo, tDirtyIndicator); tcKeyReq->setDirtyFlag(tReqInfo, tDirtyIndicator);
...@@ -683,11 +396,6 @@ NdbIndexOperation::prepareSend(Uint32 aTC_ConnectPtr, Uint64 aTransactionId) ...@@ -683,11 +396,6 @@ NdbIndexOperation::prepareSend(Uint32 aTC_ConnectPtr, Uint64 aTransactionId)
return 0; return 0;
} }
void NdbIndexOperation::closeScan()
{
printf("NdbIndexOperation::closeScan NYI\n");
}
/*************************************************************************** /***************************************************************************
int receiveTCINDXREF( NdbApiSignal* aSignal) int receiveTCINDXREF( NdbApiSignal* aSignal)
......
...@@ -129,12 +129,9 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo, ...@@ -129,12 +129,9 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo,
const int slack = sizeInBytes & 3; const int slack = sizeInBytes & 3;
if ((((UintPtr)aValue & 3) != 0) || (slack != 0)){ if ((((UintPtr)aValue & 3) != 0) || (slack != 0)){
tempData[attributeSize >> 2] = 0;
memcpy(&tempData[0], aValue, attributeSize); memcpy(&tempData[0], aValue, attributeSize);
aValue = (char*)&tempData[0]; aValue = (char*)&tempData[0];
if(slack != 0) {
char * tmp = (char*)&tempData[0];
memset(&tmp[attributeSize], 0, (4 - slack));
}//if
}//if }//if
} }
const char* aValueToWrite = aValue; const char* aValueToWrite = aValue;
...@@ -152,9 +149,7 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo, ...@@ -152,9 +149,7 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo,
aValue = (char*)xfrmData; aValue = (char*)xfrmData;
} }
Uint32 bitsInLastWord = 8 * (sizeInBytes & 3) ;
Uint32 totalSizeInWords = (sizeInBytes + 3)/4; // Inc. bits in last word Uint32 totalSizeInWords = (sizeInBytes + 3)/4; // Inc. bits in last word
Uint32 sizeInWords = sizeInBytes / 4; // Exc. bits in last word
if (true){ //tArraySize != 0) { if (true){ //tArraySize != 0) {
Uint32 tTupKeyLen = theTupKeyLen; Uint32 tTupKeyLen = theTupKeyLen;
...@@ -195,8 +190,7 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo, ...@@ -195,8 +190,7 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo,
if ((tDistrKey != 1)) { if ((tDistrKey != 1)) {
; ;
} else { } else {
/** TODO DISTKEY */ //set_distribution_key(aValue, totalSizeInWords);
theDistrKeyIndicator = 1;
} }
/****************************************************************************** /******************************************************************************
* If the operation is an insert request and the attribute is stored then * If the operation is an insert request and the attribute is stored then
...@@ -216,21 +210,13 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo, ...@@ -216,21 +210,13 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo,
const Uint32 sz = totalSizeInWords; const Uint32 sz = totalSizeInWords;
AttributeHeader::init(&ahValue, tAttrId, sz); AttributeHeader::init(&ahValue, tAttrId, sz);
insertATTRINFO( ahValue ); insertATTRINFO( ahValue );
insertATTRINFOloop((Uint32*)aValueToWrite, sizeInWords); insertATTRINFOloop((Uint32*)aValueToWrite, sz);
if (bitsInLastWord != 0) {
tData = *(Uint32*)(aValueToWrite + (sizeInWords << 2));
tData = convertEndian(tData);
tData = tData & ((1 << bitsInLastWord) - 1);
tData = convertEndian(tData);
insertATTRINFO( tData );
}//if
}//if }//if
/*************************************************************************** /***************************************************************************
* Store the Key information in the TCKEYREQ and KEYINFO signals. * Store the Key information in the TCKEYREQ and KEYINFO signals.
**************************************************************************/ **************************************************************************/
if (insertKEYINFO(aValue, tKeyInfoPosition, if (insertKEYINFO(aValue, tKeyInfoPosition, totalSizeInWords) != -1) {
totalSizeInWords, bitsInLastWord) != -1) {
/************************************************************************* /*************************************************************************
* Add one to number of tuple key attributes defined. * Add one to number of tuple key attributes defined.
* If all have been defined then set the operation state to indicate * If all have been defined then set the operation state to indicate
...@@ -239,7 +225,7 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo, ...@@ -239,7 +225,7 @@ NdbOperation::equal_impl(const NdbColumnImpl* tAttrInfo,
************************************************************************/ ************************************************************************/
Uint32 tNoKeysDef = theNoOfTupKeyDefined; Uint32 tNoKeysDef = theNoOfTupKeyDefined;
Uint32 tErrorLine = theErrorLine; Uint32 tErrorLine = theErrorLine;
int tNoTableKeys = m_currentTable->m_noOfKeys; int tNoTableKeys = m_accessTable->m_noOfKeys;
unsigned char tInterpretInd = theInterpretIndicator; unsigned char tInterpretInd = theInterpretIndicator;
tNoKeysDef++; tNoKeysDef++;
theNoOfTupKeyDefined = tNoKeysDef; theNoOfTupKeyDefined = tNoKeysDef;
...@@ -365,8 +351,7 @@ NdbOperation::setTupleId() ...@@ -365,8 +351,7 @@ NdbOperation::setTupleId()
int int
NdbOperation::insertKEYINFO(const char* aValue, NdbOperation::insertKEYINFO(const char* aValue,
register Uint32 aStartPosition, register Uint32 aStartPosition,
register Uint32 anAttrSizeInWords, register Uint32 anAttrSizeInWords)
register Uint32 anAttrBitsInLastWord)
{ {
NdbApiSignal* tSignal; NdbApiSignal* tSignal;
NdbApiSignal* tCurrentKEYINFO; NdbApiSignal* tCurrentKEYINFO;
...@@ -386,7 +371,7 @@ NdbOperation::insertKEYINFO(const char* aValue, ...@@ -386,7 +371,7 @@ NdbOperation::insertKEYINFO(const char* aValue,
*****************************************************************************/ *****************************************************************************/
tEndPos = aStartPosition + anAttrSizeInWords - 1; tEndPos = aStartPosition + anAttrSizeInWords - 1;
if ((tEndPos < 9) && (anAttrBitsInLastWord == 0)) { if ((tEndPos < 9)) {
register Uint32 tkeyData = *(Uint32*)aValue; register Uint32 tkeyData = *(Uint32*)aValue;
//TcKeyReq* tcKeyReq = CAST_PTR(TcKeyReq, tTCREQ->getDataPtrSend()); //TcKeyReq* tcKeyReq = CAST_PTR(TcKeyReq, tTCREQ->getDataPtrSend());
register Uint32* tDataPtr = (Uint32*)aValue; register Uint32* tDataPtr = (Uint32*)aValue;
...@@ -496,25 +481,6 @@ NdbOperation::insertKEYINFO(const char* aValue, ...@@ -496,25 +481,6 @@ NdbOperation::insertKEYINFO(const char* aValue,
} while (1); } while (1);
LastWordLabel: LastWordLabel:
/*****************************************************************************
* There could be a last word that only contains partial data. This word*
* will contain zeroes in the rest of the bits since the index expects *
* a certain number of words and do not care for parts of words. *
*****************************************************************************/
if (anAttrBitsInLastWord != 0) {
tData = *(Uint32*)(aValue + (anAttrSizeInWords - 1) * 4);
tData = convertEndian(tData);
tData = tData & ((1 << anAttrBitsInLastWord) - 1);
tData = convertEndian(tData);
if (tPosition > 8) {
tCurrentKEYINFO->setData(tData, signalCounter);
signalCounter++;
} else {
theTCREQ->setData(tData, (12 + tPosition));
}//if
}//if
return 0; return 0;
} }
......
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