function h5ex_d_unlimadd %************************************************************************** % % This example shows how to create and extend an unlimited % dataset. The program first writes integers to a dataset % with dataspace dimensions of DIM0xDIM1, then closes the % file. Next, it reopens the file, reads back the data, % outputs it to the screen, extends the dataset, and writes % new data to the extended portions of the dataset. Finally % it reopens the file again, reads back the data, and % outputs it to the screen. % % This file is intended for use with HDF5 Library version 1.8 %************************************************************************** FILE = 'h5ex_d_unlimadd.h5'; DATASET = 'DS1'; DIM0 = 4; DIM1 = 7; EDIM0 = 6; EDIM1 = 10; CHUNK0 = 4; CHUNK1 = 4; dims = [DIM0, DIM1]; extdims = [EDIM0, EDIM1]; chunk = [CHUNK0, CHUNK1]; % % Initialize data. % wdata = int32(zeros(dims)); for i = 1:DIM0 for j = 1:DIM1 ii=i-1; jj=j-1; wdata(i,j) = ii * jj - jj; end end % %% Create a new file using the default properties. % file = H5F.create(FILE,'H5F_ACC_TRUNC','H5P_DEFAULT','H5P_DEFAULT'); % % Create dataspace with unlimited dimensions. % H5S_UNLIMITED = H5ML.get_constant_value('H5S_UNLIMITED'); maxdims = [H5S_UNLIMITED H5S_UNLIMITED]; space = H5S.create_simple(2, fliplr(dims), fliplr(maxdims)); % % Create the dataset creation property list, and set the chunk % size. % dcpl = H5P.create('H5P_DATASET_CREATE'); H5P.set_chunk (dcpl, fliplr(chunk)); % % Create the unlimited dataset. % dset = H5D.create(file,DATASET,'H5T_STD_I32LE',space,dcpl); % % Write the data to the dataset. % H5D.write(dset,'H5T_NATIVE_INT','H5S_ALL','H5S_ALL','H5P_DEFAULT', wdata); % % Close and release resources. % H5P.close(dcpl); H5D.close(dset); H5S.close(space); H5F.close(file); % %% In this next section we read back the data, extend the dataset, % and write new data to the extended portions. % % % Open file and dataset using the default properties. % file = H5F.open(FILE,'H5F_ACC_RDWR','H5P_DEFAULT'); dset = H5D.open(file,DATASET); % % Read the data using the default properties. % rdata = H5D.read (dset,'H5T_NATIVE_INT','H5S_ALL','H5S_ALL','H5P_DEFAULT'); % % Output the data to the screen. % fprintf ('Dataset before extension:\n'); for i=1:DIM0 fprintf (' ['); for j=1:DIM1 fprintf (' %3d', rdata(i,j)); end fprintf (']\n'); end % % Extend the dataset. % H5D.extend(dset,fliplr(extdims)); % % Retrieve the dataspace for the newly extended dataset. % space = H5D.get_space(dset); % % Initialize data for writing to the extended dataset. % wdata2 = zeros(extdims,'int32'); for i=1:EDIM0 for j=1:EDIM1 wdata2(i,j) = j-1; end end % % Select the entire dataspace. % H5S.select_all(space); % % Subtract a hyperslab reflecting the original dimensions from the % selection. The selection now contains only the newly extended % portions of the dataset. % start = [0 0]; count = dims; H5S.select_hyperslab(space,'H5S_SELECT_NOTB',fliplr(start),[],fliplr(count),[]); % % Write the data to the selected portion of the dataset. % H5D.write(dset,'H5T_NATIVE_INT','H5S_ALL',space,'H5P_DEFAULT',wdata2); % % Close and release resources. % H5D.close(dset); H5S.close(space); H5F.close(file); % %% Now we simply read back the data and output it to the screen. % % % Open file and dataset using the default properties. % file = H5F.open(FILE,'H5F_ACC_RDONLY','H5P_DEFAULT'); dset = H5D.open(file, DATASET); % % Read the data using the default properties. % rdata = H5D.read(dset,'H5T_NATIVE_INT','H5S_ALL','H5S_ALL','H5P_DEFAULT'); % % Output the data to the screen. % fprintf('\nDataset after extension:\n'); fprintf ('Dataset before extension:\n'); for i=1:EDIM0 fprintf (' ['); for j=1:EDIM1 fprintf (' %3d', rdata(i,j)); end fprintf (']\n'); end % % Close and release resources. % H5D.close(dset); H5F.close(file);