/** * @file szd_float.c * @author Sheng Di, Dingwen Tao, Xin Liang, Xiangyu Zou, Tao Lu, Wen Xia, Xuan Wang, Weizhe Zhang * @date Aug, 2018 * @brief * (C) 2016 by Mathematics and Computer Science (MCS), Argonne National Laboratory. * See COPYRIGHT in top-level directory. */ #include #include #include #include "szd_float.h" #include "TightDataPointStorageF.h" #include "sz.h" #include "utility.h" #include "Huffman.h" /** * * int compressionType: 1 (time-based compression) ; 0 (space-based compression) * hist_data: only valid when compressionType==1, hist_data is the historical dataset such as the data in previous time step * * @return status SUCCESSFUL (SZ_SUCCESS) or not (other error codes) f * */ int SZ_decompress_args_float(float* newData, size_t r1, unsigned char* cmpBytes, size_t cmpSize, int compressionType, float* hist_data, sz_exedata* pde_exe, sz_params* pde_params) { int status = SZ_SUCCESS; size_t dataLength = r1; //unsigned char* tmpBytes; size_t targetUncompressSize = dataLength <<2; //i.e., *4 //tmpSize must be "much" smaller than dataLength size_t i, tmpSize = 8+MetaDataByteLength+pde_exe->SZ_SIZE_TYPE; unsigned char* szTmpBytes; if(cmpSize!=8+4+MetaDataByteLength && cmpSize!=8+8+MetaDataByteLength) //4,8 means two posibilities of SZ_SIZE_TYPE { pde_params->losslessCompressor = is_lossless_compressed_data(cmpBytes, cmpSize); if(pde_params->szMode!=SZ_TEMPORAL_COMPRESSION) { if(pde_params->losslessCompressor!=-1) pde_params->szMode = SZ_BEST_COMPRESSION; else pde_params->szMode = SZ_BEST_SPEED; } if(pde_params->szMode==SZ_BEST_SPEED) { tmpSize = cmpSize; szTmpBytes = cmpBytes; } else if(pde_params->szMode==SZ_BEST_COMPRESSION || pde_params->szMode==SZ_DEFAULT_COMPRESSION || pde_params->szMode==SZ_TEMPORAL_COMPRESSION) { if(targetUncompressSizelosslessCompressor, cmpBytes, (unsigned long)cmpSize, &szTmpBytes, (unsigned long)targetUncompressSize+4+MetaDataByteLength+exe_params->SZ_SIZE_TYPE);// (unsigned long)targetUncompressSize+8: consider the total length under lossless compression mode is actually 3+4+1+targetUncompressSize } else { printf("Wrong value of pde_params->szMode in the double compressed bytes.\n"); status = SZ_MERR; return status; } } else szTmpBytes = cmpBytes; // calc sol_ID //pde_params->sol_ID = szTmpBytes[1+3-2+14-4]; //szTmpBytes: version(1bytes), samebyte(1byte), [14-4]:sol_ID=SZ or SZ_Transpose //TODO: convert szTmpBytes to data array. TightDataPointStorageF* tdps = NULL; int errBoundMode = new_TightDataPointStorageF_fromFlatBytes(&tdps, szTmpBytes, tmpSize, pde_exe, pde_params); if(tdps == NULL) { return SZ_FORMAT_ERR; } int floatSize = sizeof(float); if(tdps->isLossless) { //*newData = (float*)malloc(floatSize*dataLength); comment by tickduan if(sysEndianType==BIG_ENDIAN_SYSTEM) { memcpy(newData, szTmpBytes+4+MetaDataByteLength+exe_params->SZ_SIZE_TYPE, dataLength*floatSize); } else { unsigned char* p = szTmpBytes+4+MetaDataByteLength+exe_params->SZ_SIZE_TYPE; for(i=0;isol_ID==SZ { if(tdps->raBytes_size > 0) //v2.0 { getSnapshotData_float_1D(newData,r1,tdps, errBoundMode, 0, hist_data, pde_params); } else //1.4.13 or time-based compression { getSnapshotData_float_1D(newData,r1,tdps, errBoundMode, compressionType, hist_data, pde_params); } } //cost_start_(); //cost_end_(); //printf("totalCost_=%f\n", totalCost_); free_TightDataPointStorageF2(tdps); if(pde_params->szMode!=SZ_BEST_SPEED && cmpSize!=8+MetaDataByteLength+exe_params->SZ_SIZE_TYPE) free(szTmpBytes); return status; } void decompressDataSeries_float_1D(float* data, size_t dataSeriesLength, float* hist_data, TightDataPointStorageF* tdps) { //updateQuantizationInfo(tdps->intervals); int intvRadius = tdps->intervals/2; size_t i, j, k = 0, p = 0, l = 0; // k is to track the location of residual_bit // in resiMidBits, p is to track the // byte_index of resiMidBits, l is for // leadNum unsigned char* leadNum; float interval = tdps->realPrecision*2; convertByteArray2IntArray_fast_2b(tdps->exactDataNum, tdps->leadNumArray, tdps->leadNumArray_size, &leadNum); //data = (float*)malloc(sizeof(float)*dataSeriesLength); // comment by tickduan // type tree int* types = (int*)malloc(dataSeriesLength*sizeof(int)); HuffmanTree* huffmanTree = createHuffmanTree(tdps->stateNum); decode_withTree(huffmanTree, tdps->typeArray, dataSeriesLength, types); SZ_ReleaseHuffman(huffmanTree); unsigned char preBytes[4]; unsigned char curBytes[4]; memset(preBytes, 0, 4); size_t curByteIndex = 0; int reqBytesLength, resiBitsLength, resiBits; unsigned char leadingNum; float medianValue, exactData, predValue; reqBytesLength = tdps->reqLength/8; resiBitsLength = tdps->reqLength%8; medianValue = tdps->medianValue; // decompress core int type; for (i = 0; i < dataSeriesLength; i++) { type = types[i]; switch (type) { case 0: // compute resiBits resiBits = 0; if (resiBitsLength != 0) { int kMod8 = k % 8; int rightMovSteps = getRightMovingSteps(kMod8, resiBitsLength); if (rightMovSteps > 0) { int code = getRightMovingCode(kMod8, resiBitsLength); resiBits = (tdps->residualMidBits[p] & code) >> rightMovSteps; } else if (rightMovSteps < 0) { int code1 = getLeftMovingCode(kMod8); int code2 = getRightMovingCode(kMod8, resiBitsLength); int leftMovSteps = -rightMovSteps; rightMovSteps = 8 - leftMovSteps; resiBits = (tdps->residualMidBits[p] & code1) << leftMovSteps; p++; resiBits = resiBits | ((tdps->residualMidBits[p] & code2) >> rightMovSteps); } else // rightMovSteps == 0 { int code = getRightMovingCode(kMod8, resiBitsLength); resiBits = (tdps->residualMidBits[p] & code); p++; } k += resiBitsLength; } // recover the exact data memset(curBytes, 0, 4); leadingNum = leadNum[l++]; memcpy(curBytes, preBytes, leadingNum); for (j = leadingNum; j < reqBytesLength; j++) curBytes[j] = tdps->exactMidBytes[curByteIndex++]; if (resiBitsLength != 0) { unsigned char resiByte = (unsigned char) (resiBits << (8 - resiBitsLength)); curBytes[reqBytesLength] = resiByte; } exactData = bytesToFloat(curBytes); data[i] = exactData + medianValue; memcpy(preBytes,curBytes,4); break; default: //predValue = 2 * data[i-1] - data[i-2]; predValue = data[i-1]; data[i] = predValue + (float)(type - intvRadius) * interval; break; } //printf("%.30G\n",data[i]); } free(leadNum); free(types); return; } void getSnapshotData_float_1D(float* data, size_t dataSeriesLength, TightDataPointStorageF* tdps, int errBoundMode, int compressionType, float* hist_data, sz_params* pde_params) { size_t i; if (tdps->allSameData) { float value = bytesToFloat(tdps->exactMidBytes); //*data = (float*)malloc(sizeof(float)*dataSeriesLength); commnet by tickduan for (i = 0; i < dataSeriesLength; i++) data[i] = value; } else { decompressDataSeries_float_1D(data, dataSeriesLength, hist_data, tdps); } }