/** * Element wise divide the value by value from a given array. * * @param array IArray object * @return new array * @throws ShapeNotMatchException mismatching shape */ public IArrayMath toEltDivide(IArray newArray) throws ShapeNotMatchException { getArray().getArrayUtils().checkShape(newArray); IArray result = getFactory().createArray(Double.TYPE, getArray().getShape()); if (getArray().getRank() == newArray.getRank()) { eltDivideWithEqualSize(newArray, result); } else { ISliceIterator sourceSliceIterator = null; ISliceIterator resultSliceIterator = null; try { sourceSliceIterator = getArray().getSliceIterator(newArray.getRank()); resultSliceIterator = result.getSliceIterator(newArray.getRank()); while (sourceSliceIterator.hasNext() && resultSliceIterator.hasNext()) { IArray sourceSlice = sourceSliceIterator.getArrayNext(); IArray resultSlice = resultSliceIterator.getArrayNext(); sourceSlice.getArrayMath().eltDivideWithEqualSize(newArray, resultSlice); } } catch (InvalidRangeException e) { throw new ShapeNotMatchException("shape is invalid"); } } return result.getArrayMath(); }
/** * Element wise divide the array1 value by value from given array2. * * @param array IArray object * @return this array1 after modification * @throws ShapeNotMatchException mismatching shape */ public IArrayMath eltDivide(IArray newArray) throws ShapeNotMatchException { getArray().getArrayUtils().checkShape(newArray); if (getArray().getRank() == newArray.getRank()) { eltDivideWithEqualSize(newArray, getArray()); } else { ISliceIterator sourceSliceIterator = null; try { sourceSliceIterator = getArray().getSliceIterator(newArray.getRank()); while (sourceSliceIterator.hasNext()) { IArray sourceSlice = sourceSliceIterator.getArrayNext(); sourceSlice.getArrayMath().eltDivideWithEqualSize(newArray, sourceSlice); } } catch (InvalidRangeException e) { throw new ShapeNotMatchException("shape is invalid"); } } getArray().setDirty(true); return this; }
public Boolean process() throws Exception { if (skip_norm) { normalised_data = normalise_groupdata; return false; } // Read in needed data and prepare output arrays IArray dataArray = ((Plot) normalise_groupdata).findSignalArray(); IArray variance_array = ((Plot) normalise_groupdata).getVariance().getData(); /* If we have a 3D array, this means a series of monitor counts is available to * allow normalisation at each scan step. If the array is 2D, then no such * normalisation is necessary. */ double monmax = 1.0; // Value to which we normalise; usually maximum monitor counts if (dataArray.getRank() > 2) { int[] data_dims = dataArray.getShape(); int dlength = dataArray.getRank(); IArray monitor_array = normalise_groupdata.getRootGroup().getDataItem("monitor_data").getData(); // We should have a monitor array rather than a single value monmax = monitor_array.getArrayMath().getMaximum(); System.out.printf("Normalising to %f monitor counts\n", monmax); IArray outarray = Factory.createArray(double.class, data_dims); IArray out_variance = Factory.createArray(double.class, data_dims); int[] origin_list = new int[dlength]; int[] range_list = new int[dlength]; int[] target_shape = new int[dlength]; // shape to make a 2D array from multi-dim array for (int i = 0; i < dlength; i++) origin_list[i] = 0; // take in all elements for (int i = 0; i < dlength - 2; i++) { range_list[i] = data_dims[i]; // last two are rank reduced target_shape[i] = 1; } range_list[dlength - 2] = 1; range_list[dlength - 1] = 1; target_shape[dlength - 2] = data_dims[dlength - 2]; target_shape[dlength - 1] = data_dims[dlength - 1]; // Create an iterator over the higher dimensions. We leave in the final two dimensions so // that we can // use the getCurrentCounter method to create an origin. // Iterate over two-dimensional slices // Array loop_array = dataArray.sectionNoReduce(origin_list, range_list, null); ISliceIterator higher_dim_iter = dataArray.getSliceIterator(2); IArrayIterator mon_iter = monitor_array.getIterator(); ISliceIterator high_dim_out_it = outarray.getSliceIterator(2); ISliceIterator var_out_it = out_variance.getSliceIterator(2); ISliceIterator invar_iter = variance_array.getSliceIterator(2); // Now loop over higher dimensional frames while (higher_dim_iter.hasNext()) { double monval = mon_iter.getDoubleNext(); if (monval == 0) { String errorstring = "Normalisation error: zero monitor counts found"; throw new Exception(errorstring); } double monerr = monmax * monmax / (monval * monval * monval); monval = monmax / monval; // Actual value to multiply by IArray[] out_with_var = {high_dim_out_it.getArrayNext(), var_out_it.getArrayNext()}; IArray[] in_with_var = {higher_dim_iter.getArrayNext(), invar_iter.getArrayNext()}; // First create a scalar for normalisation of each frame double[] norm_with_err = {monval, monerr}; ArrayOperations.multiplyByScalar(in_with_var, norm_with_err, out_with_var); } // Now build the output databag String resultName = "normalisation_result"; normalised_data = PlotFactory.createPlot(normalise_groupdata, resultName, dataDimensionType); ((NcGroup) normalised_data).addLog("Apply normalisation to get " + resultName); PlotFactory.addDataToPlot( normalised_data, resultName, outarray, "Normalised data", "Normalised counts", out_variance); // Copy axes across from previous data List<Axis> data_axes = ((Plot) normalise_groupdata).getAxisList(); for (Axis oneaxis : data_axes) { PlotFactory.addAxisToPlot(normalised_data, oneaxis, oneaxis.getDimensionName()); } // We need the value to which everything has been normalised to be available to // subsequent processing steps IAttribute norm_val = Factory.createAttribute("normalised_to_val", monmax); // normalised_data.buildResultGroup(signal, stthVector, channelVector, twoThetaVector); normalised_data.addOneAttribute(norm_val); } else { normalised_data = normalise_groupdata; } return false; }