Develop Custom Mini-Batch Datastore
A mini-batch datastore is an implementation of a datastore with support for reading data in batches. You can use a mini-batch datastore as a source of training, validation, test, and prediction data sets for deep learning applications that use Deep Learning Toolbox™.
To preprocess sequence, time series, or text data, build your own mini-batch datastore using the framework described here. For an example showing how to use a custom mini-batch datastore, see Train Network Using Custom Mini-Batch Datastore for Sequence Data.
Overview
Build your custom datastore interface using the custom datastore classes and objects. Then, use the custom datastore to bring your data into MATLAB®.
Designing your custom mini-batch datastore involves inheriting from the matlab.io.Datastore and matlab.io.datastore.MiniBatchable classes, and implementing the required
properties and methods. You optionally can add support for shuffling during
training.
Processing Needs | Classes |
|---|---|
Mini-batch datastore for training, validation, test, and prediction data sets in Deep Learning Toolbox | |
Mini-batch datastore with support for shuffling during training |
|
Implement MiniBatchable Datastore
To implement a custom mini-batch datastore named MyDatastore, create
a script MyDatastore.m. The script must be on the MATLAB path and should contain code that inherits from the appropriate class and
defines the required methods. The code for creating a mini-batch datastore for training,
validation, test, and prediction data sets in Deep Learning Toolbox must:
Inherit from the classes
matlab.io.Datastoreandmatlab.io.datastore.MiniBatchable.Define these properties:
MiniBatchSizeandNumObservations.
In addition to these steps, you can define any other properties or methods that you need to process and analyze your data.
Note
If you are training a network and trainingOptions specifies 'Shuffle' as
'once' or 'every-epoch', then you must also
inherit from the matlab.io.datastore.Shuffleable class. For more
information, see Add Support for Shuffling.
The datastore read function must return data in a table. The table elements must be scalars, row vectors, or 1-by-1 cell arrays containing a numeric array.
For networks with a single input layer, the first and second columns specify the predictors and responses, respectively.
Tip
To train a network with multiple input layers or multiple outputs, use the
combine and transform functions to create a
datastore that outputs a cell array with (numInputs +
numOutputs) columns, where numInputs is the number
of network inputs and numOutputs is the number of network outputs. The
first numInputs columns specify the predictors for each input, and the
last numOutputs columns specify the responses. The
InputNames and OutputNames properties of the
neural network determine the order of the inputs and outputs, respectively.
The format of the predictors depend on the type of data.
| Data | Format of Predictors |
|---|---|
| 2-D image | h-by-w-by-c numeric array, where h, w, and c are the height, width, and number of channels of the image, respectively. |
| 3-D image | h-by-w-by-d-by-c numeric array, where h, w, d, and c are the height, width, depth, and number of channels of the image, respectively. |
| Vector sequence | s-by-c matrix, where s is the sequence length and c is the number of features of the sequence. |
| 1-D image sequence | h-by-c-by-s array, where h and c correspond to the height and number of channels of the image, respectively, and s is the sequence length. Each sequence in the mini-batch must have the same sequence length. |
| 2-D image sequence | h-by-w-by-c-by-s array, where h, w, and c correspond to the height, width, and number of channels of the image, respectively, and s is the sequence length. Each sequence in the mini-batch must have the same sequence length. |
| 3-D image sequence | h-by-w-by-d-by-c-by-s array, where h, w, d, and c correspond to the height, width, depth, and number of channels of the image, respectively, and s is the sequence length. Each sequence in the mini-batch must have the same sequence length. |
| Features | c-by-1 column vector, where c is the number of features. |
The table elements must contain a numeric scalar, a numeric row vector, or a 1-by-1 cell array containing a numeric array.
The format of the responses depend on the type of task.
| Task | Format of Responses |
|---|---|
| Classification | Categorical scalar |
| Regression |
|
| Sequence-to-sequence classification | 1-by-s sequence of categorical labels, where s is the sequence length of the corresponding predictor sequence. |
| Sequence-to-sequence regression | R-by-s matrix, where R is the number of responses and s is the sequence length of the corresponding predictor sequence. |
The table elements must contain a categorical scalar, a numeric scalar, a numeric row vector, or a 1-by-1 cell array containing a numeric array.
This example shows how to create a custom mini-batch datastore for processing sequence
data. Save the script in a file called MySequenceDatastore.m.
| Steps | Implementation |
|---|---|
| classdef MySequenceDatastore < matlab.io.Datastore & ... matlab.io.datastore.MiniBatchable properties Datastore Labels NumClasses SequenceDimension MiniBatchSize end properties(SetAccess = protected) NumObservations end properties(Access = private) % This property is inherited from Datastore CurrentFileIndex end methods function ds = MySequenceDatastore(folder) % Construct a MySequenceDatastore object % Create a file datastore. The readSequence function is % defined following the class definition. fds = fileDatastore(folder, ... 'ReadFcn',@readSequence, ... 'IncludeSubfolders',true); ds.Datastore = fds; % Read labels from folder names numObservations = numel(fds.Files); for i = 1:numObservations file = fds.Files{i}; filepath = fileparts(file); [~,label] = fileparts(filepath); labels{i,1} = label; end ds.Labels = categorical(labels); ds.NumClasses = numel(unique(labels)); % Determine sequence dimension. When you define the LSTM % network architecture, you can use this property to % specify the input size of the sequenceInputLayer. X = preview(fds); ds.SequenceDimension = size(X,1); % Initialize datastore properties. ds.MiniBatchSize = 128; ds.NumObservations = numObservations; ds.CurrentFileIndex = 1; end function tf = hasdata(ds) % Return true if more data is available tf = ds.CurrentFileIndex + ds.MiniBatchSize - 1 ... <= ds.NumObservations; end function [data,info] = read(ds) % Read one mini-batch batch of data miniBatchSize = ds.MiniBatchSize; info = struct; for i = 1:miniBatchSize predictors{i,1} = read(ds.Datastore); responses(i,1) = ds.Labels(ds.CurrentFileIndex); ds.CurrentFileIndex = ds.CurrentFileIndex + 1; end data = preprocessData(ds,predictors,responses); end function data = preprocessData(ds,predictors,responses) % data = preprocessData(ds,predictors,responses) preprocesses % the data in predictors and responses and returns the table % data miniBatchSize = ds.MiniBatchSize; % Pad data to length of longest sequence. sequenceLengths = cellfun(@(X) size(X,2),predictors); maxSequenceLength = max(sequenceLengths); for i = 1:miniBatchSize X = predictors{i}; % Pad sequence with zeros. if size(X,2) < maxSequenceLength X(:,maxSequenceLength) = 0; end predictors{i} = X; end % Return data as a table. data = table(predictors,responses); end function reset(ds) % Reset to the start of the data reset(ds.Datastore); ds.CurrentFileIndex = 1; end end methods (Hidden = true) function frac = progress(ds) % Determine percentage of data read from datastore frac = (ds.CurrentFileIndex - 1) / ds.NumObservations; end end end % end class definition readSequence. You must create this
function to read sequence data from a
MAT-file.function data = readSequence(filename) % data = readSequence(filename) reads the sequence X from the MAT-file % filename S = load(filename); data = S.X; end |
Add Support for Shuffling
To add support for shuffling, first follow the instructions in Implement MiniBatchable Datastore and then update your
implementation code in MySequenceDatastore.m to:
Inherit from an additional class
matlab.io.datastore.Shuffleable.Define the additional method
shuffle.
This example code adds shuffling support to the MySequenceDatastore class. Vertical ellipses indicate where you should
copy code from the MySequenceDatastore implementation.
| Steps | Implementation |
|---|---|
|
classdef MySequenceDatastore < matlab.io.Datastore & ... matlab.io.datastore.MiniBatchable & ... matlab.io.datastore.Shuffleable % previously defined properties . . . methods % previously defined methods . . . function dsNew = shuffle(ds) % dsNew = shuffle(ds) shuffles the files and the % corresponding labels in the datastore. % Create a copy of datastore dsNew = copy(ds); dsNew.Datastore = copy(ds.Datastore); fds = dsNew.Datastore; % Shuffle files and corresponding labels numObservations = dsNew.NumObservations; idx = randperm(numObservations); fds.Files = fds.Files(idx); dsNew.Labels = dsNew.Labels(idx); end end end |
Validate Custom Mini-Batch Datastore
If you have followed all the instructions presented here, then the implementation of your custom mini-batch datastore is complete. Before using this datastore, qualify it using the guidelines presented in Testing Guidelines for Custom Datastores.
See Also
trainnet | trainingOptions | dlnetwork
Related Examples
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