static void Main(string[] args) { try { // We will write and read an int array of this length. const int DATA_ARRAY_LENGTH = 12; // Rank is the number of dimensions of the data array. const int RANK = 1; // Create an HDF5 file. // The enumeration type H5F.CreateMode provides only the legal // creation modes. Missing H5Fcreate parameters are provided // with default values. H5FileId fileId = H5F.create("myCSharp.h5", H5F.CreateMode.ACC_TRUNC); // Create a HDF5 group. H5GroupId groupId = H5G.create(fileId, "/cSharpGroup"); H5GroupId subGroup = H5G.create(groupId, "mySubGroup"); // Close the subgroup. H5G.close(subGroup); // Prepare to create a data space for writing a 1-dimensional // signed integer array. long[] dims = new long[RANK]; dims[0] = DATA_ARRAY_LENGTH; // Put descending ramp data in an array so that we can // write it to the file. int[] dset_data = new int[DATA_ARRAY_LENGTH]; for (int i = 0; i < DATA_ARRAY_LENGTH; i++) { dset_data[i] = DATA_ARRAY_LENGTH - i; } // Create a data space to accommodate our 1-dimensional array. // The resulting H5DataSpaceId will be used to create the // data set. H5DataSpaceId spaceId = H5S.create_simple(RANK, dims); // Create a copy of a standard data type. We will use the // resulting H5DataTypeId to create the data set. We could // have used the HST.H5Type data directly in the call to // H5D.create, but this demonstrates the use of H5T.copy // and the use of a H5DataTypeId in H5D.create. H5DataTypeId typeId = H5T.copy(H5T.H5Type.NATIVE_INT); // Find the size of the type int typeSize = H5T.getSize(typeId); Console.WriteLine("typeSize is {0}", typeSize); // Set the order to big endian H5T.setOrder(typeId, H5T.Order.BE); // Set the order to little endian H5T.setOrder(typeId, H5T.Order.LE); // Create the data set. H5DataSetId dataSetId = H5D.create(fileId, "/csharpExample", typeId, spaceId); // Write the integer data to the data set. H5D.write(dataSetId, new H5DataTypeId(H5T.H5Type.NATIVE_INT), new H5Array <int>(dset_data)); // If we were writing a single value it might look like this. // int singleValue = 100; // H5D.writeScalar(dataSetId, // new H5DataTypeId(H5T.H5Type.NATIVE_INT), // ref singleValue); // Create an integer array to receive the read data. int[] readDataBack = new int[DATA_ARRAY_LENGTH]; // Read the integer data back from the data set H5D.read(dataSetId, new H5DataTypeId(H5T.H5Type.NATIVE_INT), new H5Array <int>(readDataBack)); // Echo the data for (int i = 0; i < DATA_ARRAY_LENGTH; i++) { Console.WriteLine(readDataBack[i]); } // Close all the open resources. H5D.close(dataSetId); // Reopen and close the data sets to show that we can. dataSetId = H5D.open(fileId, "/csharpExample"); H5D.close(dataSetId); dataSetId = H5D.open(groupId, "/csharpExample"); H5D.close(dataSetId); H5T.close(typeId); H5G.close(groupId); // Get H5O info H5ObjectInfo objectInfo = H5O.getInfoByName(fileId, "/csharpExample"); Console.WriteLine("header.space.message is {0}", objectInfo.header.space.message); Console.WriteLine("fileNumber is {0}", objectInfo.fileNumber); Console.WriteLine("address is {0}", objectInfo.address); Console.WriteLine("type is {0}", objectInfo.objectType.ToString()); Console.WriteLine("reference count is {0}", objectInfo.referenceCount); Console.WriteLine("modification time is {0}", objectInfo.modificationTime); Console.WriteLine("birth time is {0}", objectInfo.birthTime); Console.WriteLine("access time is {0}", objectInfo.accessTime); Console.WriteLine("change time is {0}", objectInfo.changeTime); Console.WriteLine("number of attributes is {0}", objectInfo.nAttributes); Console.WriteLine("header version is {0}", objectInfo.header.version); Console.WriteLine("header nMessages is {0}", objectInfo.header.nMessages); Console.WriteLine("header nChunks is {0}", objectInfo.header.nChunks); Console.WriteLine("header flags is {0}", objectInfo.header.flags); H5LinkInfo linkInfo = H5L.getInfo(fileId, "/cSharpGroup"); Console.WriteLine( "address: {0:x}, charSet: {1}, creationOrder: {2}", linkInfo.address, linkInfo.charSet, linkInfo.creationOrder); Console.WriteLine("linkType: {0}, softLinkSizeOrUD: {1}", linkInfo.linkType, linkInfo.softLinkSizeOrUD); // Reopen the group id to show that we can. groupId = H5G.open(fileId, "/cSharpGroup"); // Use H5L.iterate to visit links H5LIterateCallback myDelegate; myDelegate = MyH5LFunction; ulong linkNumber = 0; H5IterationResult result = H5L.iterate(groupId, H5IndexType.NAME, H5IterationOrder.INCREASING, ref linkNumber, myDelegate, 0); // Create some attributes H5DataTypeId attributeType = H5T.copy(H5T.H5Type.NATIVE_INT); long[] attributeDims = new long[1]; const int RAMP_LENGTH = 5; attributeDims[0] = RAMP_LENGTH; int[] ascendingRamp = new int[RAMP_LENGTH] { 1, 2, 3, 4, 5 }; int[] descendingRamp = new int[RAMP_LENGTH] { 5, 4, 3, 2, 1 }; int[] randomData = new int[RAMP_LENGTH] { 3, 123, 27, 6, 1 }; int[] readBackRamp = new int[RAMP_LENGTH]; // Call set buffer using H5Memory // Allocate memory from "C" runtime heap (not garbage collected) H5Memory typeConversionBuffer = new H5Memory(new IntPtr(DATA_ARRAY_LENGTH)); H5Memory backgroundBuffer = new H5Memory(new IntPtr(DATA_ARRAY_LENGTH)); // Set the property list type conversion and background buffers. H5PropertyListId myPropertyListId = H5P.create(H5P.PropertyListClass.DATASET_XFER); H5P.setBuffer(myPropertyListId, typeConversionBuffer, backgroundBuffer); // Test use of vlen // Create a vlen data type H5DataTypeId tid1 = H5T.vlenCreate(H5T.H5Type.NATIVE_UINT); H5DataSetId vDataSetId = H5D.create(fileId, "/vlenTest", tid1, spaceId); // Create a jagged array of integers. hvl_t[] vlArray = new hvl_t[DATA_ARRAY_LENGTH]; // HDF5 variable length data types require the use of void // pointers. C# requires that sections of code that deal // directly with pointer be marked // as unsafe. unsafe { for (int i = 0; i < DATA_ARRAY_LENGTH; i++) { IntPtr ptr = new IntPtr((i + 1) * sizeof(int)); // Allocate memory that is not garbage collected. vlArray[i].p = H5CrtHeap.Allocate( new IntPtr((i + 1) * sizeof(int)) ).ToPointer(); // Fill the array with integers = the row number int *intPointer = (int *)vlArray[i].p; for (int j = 0; j < i + 1; j++) { intPointer[j] = (int)i; } if (IntPtr.Size == 8) { vlArray[i].len = (ulong)i + 1; } else { vlArray[i].len = (uint)i + 1; } } // Write the variable length data H5D.write(vDataSetId, tid1, new H5Array <hvl_t>(vlArray)); // Create an array to read back the array. hvl_t[] vlReadBackArray = new hvl_t[DATA_ARRAY_LENGTH]; // Read the array back H5D.read(vDataSetId, tid1, new H5Array <hvl_t>(vlReadBackArray)); // Write the data to the console for (int i = 0; i < DATA_ARRAY_LENGTH; i++) { int *iPointer = (int *)vlReadBackArray[i].p; for (int j = 0; j < i + 1; j++) { Console.WriteLine(iPointer[j]); } } // Reclaim the memory that read allocated H5D.vlenReclaim(tid1, spaceId, new H5PropertyListId(H5P.Template.DEFAULT), new H5Array <hvl_t>(vlReadBackArray)); // Now read it back again using our own memory manager //H5AllocateCallback allocDelegate = new H5AllocCallback(userAlloc); H5FreeCallback freeDelegate = new H5FreeCallback(userFree); H5PropertyListId memManagerPlist = H5P.create(H5P.PropertyListClass.DATASET_XFER); unsafe { H5P.setVlenMemManager(memManagerPlist, userAlloc, IntPtr.Zero, freeDelegate, IntPtr.Zero); } // Read the array back H5D.read(vDataSetId, tid1, new H5DataSpaceId(H5S.H5SType.ALL), new H5DataSpaceId(H5S.H5SType.ALL), memManagerPlist, new H5Array <hvl_t>(vlReadBackArray)); // Write the data to the console for (int i = 0; i < DATA_ARRAY_LENGTH; i++) { int *iPointer = (int *)vlReadBackArray[i].p; for (int j = 0; j < i + 1; j++) { Console.WriteLine(iPointer[j]); } } // Reclaim the memory that read allocated using our free routines H5D.vlenReclaim(tid1, spaceId, memManagerPlist, new H5Array <hvl_t>(vlReadBackArray)); } H5S.close(spaceId); H5DataSpaceId attributeSpace = H5S.create_simple(1, attributeDims); H5AttributeId attributeId = H5A.create(groupId, "ascendingRamp", attributeType, attributeSpace); int offset = H5T.getOffset(attributeType); Console.WriteLine("Offset is {0}", offset); H5DataTypeId float32BE = H5T.copy(H5T.H5Type.IEEE_F32BE); H5T.Norm norm = H5T.getNorm(float32BE); Console.WriteLine("Norm is {0}", norm); int precision = H5T.getPrecision(float32BE); Console.WriteLine("Precision is {0}", precision); H5FloatingBitFields bitFields = H5T.getFields(float32BE); Console.WriteLine("getFields: sign bit position: {0}", bitFields.signBitPosition); Console.WriteLine("getFields: exponent bit position: {0}", bitFields.exponentBitPosition); Console.WriteLine("getFields: number of exponent bits: {0}", bitFields.nExponentBits); Console.WriteLine("getFields: mantissa bit position: {0} ", bitFields.mantissaBitPosition); Console.WriteLine("getFields: number of mantissa bits: {0}", bitFields.nMantissaBits); Console.Write("{0}", bitFields); // Write to an attribute H5A.write <int>(attributeId, attributeType, new H5Array <int>(ascendingRamp)); // Read from an attribute H5A.read <int>(attributeId, attributeType, new H5Array <int>(readBackRamp)); // Echo results Console.WriteLine("ramp elements are: "); foreach (int rampElement in readBackRamp) { Console.WriteLine(" {0}", rampElement); } H5A.close(attributeId); // Create and write two more attributes. attributeId = H5A.createByName(groupId, ".", "descendingRamp", attributeType, attributeSpace); H5A.write <int>(attributeId, attributeType, new H5Array <int>(descendingRamp)); H5A.close(attributeId); attributeId = H5A.createByName(groupId, ".", "randomData", attributeType, attributeSpace); H5A.write <int>(attributeId, attributeType, new H5Array <int>(randomData)); // Read back the attribute data H5A.read <int>(attributeId, attributeType, new H5Array <int>(readBackRamp)); Console.WriteLine("ramp elements are: "); foreach (int rampElement in readBackRamp) { Console.WriteLine(" {0}", rampElement); } H5A.close(attributeId); // Iterate through the attributes. long position = 0; H5AIterateCallback attributeDelegate; attributeDelegate = MyH5AFunction; H5ObjectInfo groupInfo = H5O.getInfo(groupId); Console.WriteLine( "fileNumber: {0}, total space: {1}, referceCount: {2}, modification time: {3}", groupInfo.fileNumber, groupInfo.header.space.total, groupInfo.referenceCount, groupInfo.modificationTime); // While iterating, collect the names of all the attributes. ArrayList attributeNames = new ArrayList(); H5A.iterate(groupId, H5IndexType.CRT_ORDER, H5IterationOrder.INCREASING, ref position, attributeDelegate, (object)attributeNames); // Write out the names of the attributes foreach (string attributeName in attributeNames) { Console.WriteLine("attribute name is {0}", attributeName); } // Demonstrate H5A.openName attributeId = H5A.openName(groupId, "descendingRamp"); Console.WriteLine("got {0} by name", H5A.getName(attributeId)); H5A.close(attributeId); // Demonstrate H5A.getNameByIndex string secondAttribute = H5A.getNameByIndex(groupId, ".", H5IndexType.CRT_ORDER, H5IterationOrder.INCREASING, 1); Console.WriteLine("second attribute is named {0}", secondAttribute); // Demonstrate H5G.getInfo H5GInfo gInfo = H5G.getInfo(groupId); Console.WriteLine( "link storage: {0}, max creation order: {1}, nLinks: {2}", gInfo.linkStorageType, gInfo.maxCreationOrder, gInfo.nLinks); // Demonstrate H5A.getSpace //attributeId = H5A.openByName(groupId, ".", "descendingRamp"); attributeId = H5A.open(groupId, "descendingRamp"); H5DataSpaceId rampSpaceId = H5A.getSpace(attributeId); H5S.close(rampSpaceId); // Demonstrate H5A.getType H5DataTypeId rampTypeId = H5A.getType(attributeId); Console.WriteLine("size of ramp data type is {0} bytes.", H5T.getSize(rampTypeId)); H5T.close(rampTypeId); // Demonstrate H5A.getInfo H5AttributeInfo rampInfo = H5A.getInfo(attributeId); Console.WriteLine( "characterset: {0}, creationOrder: {1}, creationOrderValid: {2}, dataSize: {3}", rampInfo.characterSet, rampInfo.creationOrder, rampInfo.creationOrderValid, rampInfo.dataSize); // Demonstrate H5A.Delete H5A.Delete(groupId, "descendingRamp"); //H5A.DeleteByName(groupId, ".", "descendingRamp"); // Iterate through the attributes to show that the deletion // was successful. position = 0; ArrayList namesAfterDeletion = new ArrayList(); H5A.iterate(groupId, H5IndexType.CRT_ORDER, H5IterationOrder.DECREASING, ref position, attributeDelegate, (object)namesAfterDeletion); H5G.close(groupId); H5F.close(fileId); // Reopen and reclose the file. H5FileId openId = H5F.open("myCSharp.h5", H5F.OpenMode.ACC_RDONLY); H5F.close(openId); // Set the function to be called on error. unsafe { H5AutoCallback myErrorDelegate = new H5AutoCallback(myErrorFunction); H5E.setAuto(0, myErrorDelegate, IntPtr.Zero); } // Uncomment the next line if you want to generate an error to // test H5E.setAuto // H5G.open(openId, "noGroup"); } // This catches all the HDF exception classes. Because each call // generates a unique exception, different exception can be handled // separately. For example, to catch open errors we could have used // catch (H5FopenException openException). catch (HDFException e) { Console.WriteLine(e.Message); } Console.WriteLine("Processing complete!"); Console.ReadLine(); }
} // test_integer_dtype static void test_float_dtype() { try { Console.Write("Testing getting some floating-point information"); const string GEN_FILE_NAME = "gen_types.h5"; const string FLOAT_TYPE_NAME = "new float type 1"; // Open file pre-generated by a C program. H5FileId genfileId = H5F.open(GEN_FILE_NAME, H5F.OpenMode.ACC_RDONLY); // Open the datatype to check. H5DataTypeId dtypeId = H5T.open(genfileId, FLOAT_TYPE_NAME); // Get and check fields. H5FloatingBitFields fields = H5T.getFields(dtypeId); if (fields.signBitPosition != 44) { Console.WriteLine("Incorrect sign bit position: {0}, should be {1}", fields.signBitPosition, 44); nerrors++; } if (fields.exponentBitPosition != 34) { Console.WriteLine("Incorrect exponential bit position: {0}, should be {1}", fields.exponentBitPosition, 34); nerrors++; } if (fields.nExponentBits != 10) { Console.WriteLine("Incorrect size of exponent: {0}, should be {1}", fields.nExponentBits, 10); nerrors++; } if (fields.mantissaBitPosition != 3) { Console.WriteLine("Incorrect mantissa bit-position: {0}, should be {1}", fields.mantissaBitPosition, 3); nerrors++; } if (fields.nMantissaBits != 31) { Console.WriteLine("Incorrect size of mantissa: {0}, should be {1}", fields.nMantissaBits, 44); nerrors++; } // Check precision. int precision = H5T.getPrecision(dtypeId); if (precision != 42) { Console.WriteLine("Incorrect precision: {0}, should be {1}", precision, 42); nerrors++; } // Check offset. int offset = H5T.getOffset(dtypeId); if (offset != 3) { Console.WriteLine("Incorrect offset: {0}, should be {1}", offset, 3); nerrors++; } // Check norm. H5T.Norm norm = H5T.getNorm(dtypeId); if (norm != H5T.Norm.IMPLIED) // need to be determined, not really 3 { Console.WriteLine("Incorrect norm: {0}, should be {1}", norm, H5T.Norm.IMPLIED); nerrors++; } // Check size. int size = H5T.getSize(dtypeId); if (size != 7) { Console.WriteLine("Incorrect size: {0}, should be {1}", size, 7); nerrors++; } // Close datatype and file. H5T.close(dtypeId); H5F.close(genfileId); Console.WriteLine("\t\tPASSED"); } // end of try block catch (HDFException anyHDF5E) { Console.WriteLine(anyHDF5E.Message); nerrors++; } catch (System.Exception sysE) { Console.WriteLine(sysE.TargetSite); Console.WriteLine(sysE.Message); nerrors++; } } // end of test_float_dtype