int SharedDataManager::getSegmentInfo(TreeDescriptor treeIdx, int nid, int idx, int **shape, int *shapeSize, int *currDataSize) { Segment *segment; lock.lock(); SharedMemNode *node = sharedTree.find(treeIdx, nid); if(node) { SharedMemNodeData *nodeData = node->getData(); if(!nodeData->isSegmented()) { lock.unlock(); return 0; } int numSegments = nodeData->getNumSegments(); if(idx >= numSegments) idx = numSegments - 1; segment = nodeData->getSegmentAt(idx); segment->getShape(reinterpret_cast<char **>(shape), shapeSize); *currDataSize = segment->getCurrDataSize(); lock.unlock(); return 1; } lock.unlock(); return 0; }
int SharedDataManager::getSegmentData(TreeDescriptor treeId, int nid, int idx, char **dim, int *dimSize, char **data, int *dataSize, char **shape, int *shapeSize, int *currDataSize, bool *timestamped, int *actSamples) { Segment *segment; lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(node) { SharedMemNodeData *nodeData = node->getData(); if(!nodeData->isSegmented()) { lock.unlock(); return 0; } int numSegments = nodeData->getNumSegments(); if(idx >= numSegments || idx < 0) { lock.unlock(); return 0; } segment = nodeData->getSegmentAt(idx); segment->getDim((char **)dim, dimSize); segment->getData((char **)data, dataSize); segment->getShape((char **)shape, shapeSize); *currDataSize = segment->getCurrDataSize(); *timestamped = segment->isTimestamped(); *actSamples = segment->getActSamples(); lock.unlock(); return 1; } lock.unlock(); return 0; }
int SharedDataManager::getNumSegments(TreeDescriptor treeId, int nid, int *numSegments) { lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(node) { SharedMemNodeData *nodeData = node->getData(); *numSegments = nodeData->getNumSegments(); lock.unlock(); return 1; } lock.unlock(); return 0; }
int SharedDataManager::getSegmentLimits(TreeDescriptor treeId, int nid, int idx, char **start, int *startSize, char **end, int *endSize, bool *timestamped) { Segment *segment; lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(node) { SharedMemNodeData *nodeData = node->getData(); if(!nodeData->isSegmented()) { lock.unlock(); return 0; } int numSegments = nodeData->getNumSegments(); if(idx >= numSegments || idx < 0) { lock.unlock(); return 0; } segment = nodeData->getSegmentAt(idx); if(segment->isTimestamped()) { *timestamped = true; segment->getStartTimestamp(start, startSize); segment->getEndTimestamp(end, endSize); } else { segment->getStart((char **)start, startSize); segment->getEnd((char **)end, endSize); *timestamped = false; } lock.unlock(); return 1; } lock.unlock(); return 0; }
int SharedDataManager::findSegment(TreeDescriptor treeId, int nid, int *retIdx) { int numSegments; lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(node) { SharedMemNodeData *nodeData = node->getData(); numSegments = nodeData->getNumSegments(); if(numSegments == 0) { lock.unlock(); return 0; //No segments } *retIdx = numSegments - 1; lock.unlock(); return 1; } return 0; }
int SharedDataManager::getSegmentDataAndShapeCopy(TreeDescriptor treeId, int nid, int idx, char **data, int *dataSize, char **shape, int *shapeSize) { Segment *segment; lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(node) { SharedMemNodeData *nodeData = node->getData(); if(!nodeData->isSegmented()) { lock.unlock(); return 0; } int numSegments = nodeData->getNumSegments(); if(idx >= numSegments || idx < 0) { lock.unlock(); return 0; } segment = nodeData->getSegmentAt(idx); char *currData; segment->getData((char **)&currData, dataSize); *data = new char[*dataSize]; memcpy(*data, currData,*dataSize); char *currShape; segment->getShape((char **)&currShape, shapeSize); *shape = new char[*shapeSize]; memcpy(*shape, currShape, *shapeSize); lock.unlock(); return 1; } lock.unlock(); return 0; }
int SharedDataManager::updateSegment(TreeDescriptor treeId, int nid, int idx, char *start, int startSize, char *end, int endSize, char *dim, int dimSize) { Segment *segment; lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(node) { SharedMemNodeData *nodeData = node->getData(); if(!nodeData->isSegmented()) { lock.unlock(); return 0; } int numSegments = nodeData->getNumSegments(); if(idx > numSegments || idx < 0) { lock.unlock(); return 0; } segment = nodeData->getSegmentAt(idx); char *currPtr; int currSize; segment->getStart(&currPtr, &currSize); if(startSize > 0) { if(currSize > 0) allocationManager.deallocateShared((char *)currPtr, currSize); currPtr = allocationManager.allocateShared(startSize); memcpy(currPtr, start, startSize); segment->setStart(currPtr, startSize); } if(endSize > 0) { segment->getEnd(&currPtr, &currSize); if(currSize > 0) allocationManager.deallocateShared((char *)currPtr, currSize); currPtr = allocationManager.allocateShared(endSize); memcpy(currPtr, end, endSize); segment->setEnd(currPtr, endSize); } if(dimSize > 0) { segment->getDim(&currPtr, &currSize); if(currSize > 0) allocationManager.deallocateShared((char *)currPtr, currSize); currPtr = allocationManager.allocateShared(dimSize); memcpy(currPtr, dim, dimSize); segment->setDim(currPtr, dimSize); } CallbackManager *callback = node->getData()->getCallbackManager(); if(callback) callback->callCallback(); lock.unlock(); return 1; } lock.unlock(); return 0; }
/* //Return Shape and type information. The coding is the following: //1) data type //2) item size in bytes //3) number of dimensions //4) total dimension in bytes //The remaining elements are the dimension limits */ int SharedDataManager::appendSegmentData(TreeDescriptor treeId, int nid, int *bounds, int boundsSize, char *data, int dataSize, int idx, int startIdx, bool isTimestamped, _int64 *timestamps, int numTimestamps, int *segmentFilled, int *retIdx) { int numSegments; int *shape; int shapeSize; char *segmentData; int segmentSize; lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(!node) { SharedMemNodeData nodeData; nodeData.setNid(treeId, nid); nodeData.setSegmented(true); sharedTree.insert(&nodeData); node = sharedTree.find(treeId, nid); } if(node) { SharedMemNodeData *nodeData = node->getData(); numSegments = nodeData->getNumSegments(); if(numSegments == 0) //May happen the first time putRow is called { lock.unlock(); // printf("APPENDSEGMENT DATA: NO SEGMENTS"); return TRUNCATED; } if(idx >= numSegments || numSegments == 0) { lock.unlock(); // printf("APPENDSEGMENT DATA: BAD INDEX"); return BAD_INDEX; } Segment *segment = nodeData->getSegmentAt(idx); /* if(!segment->isTimestamped()) { lock.unlock(); return 0; } */ segment->getShape((char **)&shape, &shapeSize); //Check Shape. Meaning of bound array: // 1) data type // 2) item size in bytes // 3) number of dimensions // 4) total dimension in bytes // The remaining elements are the dimension limits if(bounds[0] != shape[0]) { lock.unlock(); // printf("APPENDSEGMENT DATA: BAD TYPE %d %d\n", bounds[0], shape[0]); return BAD_TYPE; } if(bounds[2] < shape[2] - 1 || bounds[2] > shape[2]) { lock.unlock(); // printf("APPENDSEGMENT DATA: BAD TYPE 1"); return BAD_SHAPE; } for(int i = 0; i < shape[2] - 1; i++) { if(bounds[4 + i] != shape[4 + i]) { lock.unlock(); // printf("APPENDSEGMENT DATA: BAD SHAPE"); return BAD_SHAPE; } } int currSegmentSize = segment->getCurrDataSize(); segment->getData((char **)&segmentData, &segmentSize); if(startIdx < 0) { int leftSize = segmentSize - currSegmentSize; if(dataSize > leftSize) { lock.unlock(); // printf("APPENDSEGMENT DATA: DATASIZE > LEFT SIZE"); return TRUNCATED; } if(leftSize == dataSize) *segmentFilled = 1; else *segmentFilled = 0; memcpy(&segmentData[currSegmentSize], data, dataSize); segment->setCurrDataSize(currSegmentSize + dataSize); if(isTimestamped) segment->appendTimestamps(timestamps, numTimestamps); *retIdx = numSegments - 1; CallbackManager *callback = node->getData()->getCallbackManager(); if(callback) callback->callCallback(); lock.unlock(); return 1; } else { int itemSize = bounds[3]; //Total size of a data item (array) int startOfs = startIdx * itemSize; int leftSize = segmentSize - startOfs; if(dataSize > leftSize) { lock.unlock(); // printf("APPENDSEGMENT DATA: DATASIZE > LEFT SIZE"); return TRUNCATED; } if(leftSize == dataSize) *segmentFilled = 1; else *segmentFilled = 0; memcpy(&segmentData[startOfs], data, dataSize); *retIdx = numSegments - 1; //Segment size does not change CallbackManager *callback = node->getData()->getCallbackManager(); if(callback) callback->callCallback(); lock.unlock(); return 1; } } lock.unlock(); return 0; }
int SharedDataManager::beginTimestampedSegment(TreeDescriptor treeId, int nid, int idx, int numItems, char *shape, int shapeSize, char *data, int dataSize, _int64 start, _int64 end, char *dim, int dimSize, int *retIdx) { Segment *segment; //printf("BEGIN TIMESTAMPED SEGMENT SHARE: %d\n", *(int *)shape); lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(!node) { SharedMemNodeData nodeData; nodeData.setNid(treeId, nid); nodeData.setSegmented(true); sharedTree.insert(&nodeData); node = sharedTree.find(treeId, nid); } if(node) { SharedMemNodeData *nodeData = node->getData(); if(!nodeData->isSegmented()) { nodeData->free(&allocationManager); nodeData->setSegmented(true); } int numSegments = nodeData->getNumSegments(); if(idx > numSegments) { lock.unlock(); return 0; } if(idx == numSegments || idx < 0) { segment = (Segment *)allocationManager.allocateShared(sizeof(Segment)); // printf("ALLOCATED SEGMENT: %x\n", segment); segment->initialize(); nodeData->appendSegment(segment); *retIdx = numSegments; } else { segment = nodeData->getSegmentAt(idx); *retIdx = idx; } char *currPtr; segment->free(&allocationManager); if(dimSize == 0) { currPtr = allocationManager.allocateShared(8 * numItems); // printf("ALLOCATED SEGMENT DIM: %x\n", currPtr); segment->setDim(currPtr, 8 * numItems); } currPtr = allocationManager.allocateShared(shapeSize); // printf("ALLOCATED SEGMENT SHAPE: %x %d\n", currPtr, *(int *)shape); memcpy(currPtr, shape, shapeSize); segment->setShape(currPtr, shapeSize); currPtr = allocationManager.allocateShared(dataSize); // printf("ALLOCATED SEGMENTDATA: %x\n", currPtr); memcpy(currPtr, data, dataSize); segment->setData(currPtr, dataSize); //The following parameters are meaningful only when copying a segment from the tree into cache segment->setStartTimestamp(start); segment->setEndTimestamp(end); if(dimSize > 0) { currPtr = allocationManager.allocateShared(dimSize); // printf("ALLOCATED SEGMENT DIM : %x\n", currPtr); memcpy(currPtr, dim, dimSize); segment->setDim(currPtr, dimSize); segment->setStartTimestamp(*(_int64 *)dim); if(end == 0) segment->setEndTimestamp(*(_int64 *)dim); } segment->setTimestamped(true); lock.unlock(); //printf("END BEGIN TIMESTAMPED SEGMENT LAST SEGMENT: %x\n", nodeData->getLastSegment()); return 1; } lock.unlock(); return 0; }
int SharedDataManager::beginSegment(TreeDescriptor treeId, int nid, int idx, char *start, int startSize, char *end, int endSize, char *dim, int dimSize, char *shape, int shapeSize, char *data, int dataSize, int *retIdx) { Segment *segment; lock.lock(); SharedMemNode *node = sharedTree.find(treeId, nid); if(!node) { SharedMemNodeData nodeData; nodeData.setNid(treeId, nid); nodeData.setSegmented(true); sharedTree.insert(&nodeData); node = sharedTree.find(treeId, nid); } if(node) { SharedMemNodeData *nodeData = node->getData(); if(!nodeData->isSegmented()) { nodeData->free(&allocationManager); nodeData->setSegmented(true); } int numSegments = nodeData->getNumSegments(); if(idx > numSegments) { lock.unlock(); return 0; } if(idx == numSegments || idx < 0) { segment = (Segment *)allocationManager.allocateShared(sizeof(Segment)); segment->initialize(); nodeData->appendSegment(segment); *retIdx = numSegments; } else { segment = nodeData->getSegmentAt(idx); *retIdx = idx; } char *currPtr; segment->free(&allocationManager); currPtr = allocationManager.allocateShared(startSize); memcpy(currPtr, start, startSize); segment->setStart(currPtr, startSize); currPtr = allocationManager.allocateShared(endSize); memcpy(currPtr, end, endSize); segment->setEnd(currPtr, endSize); currPtr = allocationManager.allocateShared(dimSize); memcpy(currPtr, dim, dimSize); segment->setDim(currPtr, dimSize); currPtr = allocationManager.allocateShared(shapeSize); memcpy(currPtr, shape, shapeSize); segment->setShape(currPtr, shapeSize); currPtr = allocationManager.allocateShared(dataSize); memcpy(currPtr, data, dataSize); segment->setData(currPtr, dataSize); segment->setTimestamped(false); lock.unlock(); return 1; } lock.unlock(); return 0; }