view doc/v2_planning/dataset.txt @ 1396:310e22d7e44b

new file about datalearn in pytables.
author Frederic Bastien <nouiz@nouiz.org>
date Mon, 10 Jan 2011 14:55:39 -0500
parents 04b988fb00b6
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Discussion of Function Specification for Dataset Types
======================================================

Some talking points from the September 2 meeting:

 * Datasets as views/tasks (Pascal Vincent's idea): our dataset specification
   needs to be flexible enough to accommodate different (sub)tasks and views of
   the same underlying data.
 * Datasets as probability distributions from which one can sample.
    * That's not something I would consider to be a dataset-related problem to
        tackle now: a probability distribution in Pylearn would probably be a
        different kind of beast, and it should be easy enough to have a
        DatasetToDistribution class for instance, that would take care of viewing a
        dataset as a probability distribution. -- OD
 * Our specification should allow transparent handling of infinite datasets (or
   simply datasets which cannot fit in memory)
 * GPU/buffering issues.

Commiteee: DE, OB, OD, AB, PV
Leader: DE

Some ideas from existing ML libraries:

- PyML: notion of dataset containers: VectorDataSet, SparseDataSet, KernelData,
  PairDataSet, Aggregate. Ultimately, the learner decides	
- mlpy: very primitive notions of data (simple 2D matrices)
- PyBrain: Datasets are geared towards specific tasks: ClassificationDataSet,
    SequentialDataSet, ReinforcementDataSet, ... Each class is quite
    constrained and may have a different interface.
- MDP: Seems to have restrictions on the type of data being passed around, as
    well as its dimensionality ("Input array data is typically assumed to be
    two-dimensional and ordered such that observations of the same variable are
    stored on rows and different variables are stored on columns.")
- Orange: Data matrices, with names and types associated to each column.
  Basically there seems to be only one base dataset class that contains the
  data. Data points are lists (of values corresponding to each column).
- APGL: Hard to say how they deal with data from the documentation alone.
- Monte: Data is simply numpy arrays.
- scikits.learn: Dataset is a simple container with e.g. dataset.data being
    a 2D numpy array of input features, and dataset.target the target vector.
- Shogun: Vade Retro C++! (may be worth looking into their feature concept
    though).
- Any more worth looking at?

A few things that our dataset containers should support at a minimum:

    - streams, possibly infinite
    - task/views of the data for different problems
    - indexing & slicing 
    - pairs or triples or etc of examples
    - a 'distance/gram matrix' container (imagine that the data is given to you
      as a distance matrix)
    - multi-dimensional time-series (again, maybe with pairs/triples, maybe
      given to you as a distance matrix over time)

Another question to consider is the following: how tight should it integrate
with Theano? Do we want to be able to store data as shared variables or just
have an option for that? Theano + GPU constrains things that we can do (in terms
of sizes, buffering, etc): these are things we need to think about, but it's not
clear whether we should aim for building them into the interface.

Task views of the data for different problems: How can we achieve this? Should
we simply have a set of standard dataset descriptors ('classification',
'regression', 'multi-label', 'density_estimation') and have a set_view method
that changes the current dataset view type?

There is then the question of how to approach the design of a Dataset class from
an OOP perspective. So far, my (Dumi's) idea is to have an almost 'abstract class' 
Dataset that doesn't implement any methods except a few setters/getters. The reason
to have the methods listed that way is to have a common 'specification', but classes
that inherit from Dataset need not implement every single method (only the ones
that are relevant) and can obviously implement other methods as appropriate. The
reason to have a common specification (as abstract as it might be) is to, well,
have a common specification that would make our code clearer and cleaner.

An example of what I (Dumi) am thinking in terms of concrete API:

class Dataset:
    def __init__(self):
        self.type = None
        self.in_memory = None
        self.inputs = None # list of filepaths, or objects in memory, or...
        self.outputs = None

    def get_example(self,example_index):
        raise NotImplementedError()

    def get_next_example(self):
        raise NotImplementedError()

    def get_batch(self,batch_index):
        raise NotImplementedError()

    def get_next_batch(self):
        raise NotImplementedError()

    def get_slice(self,slice_object):
        raise NotImplementedError()

    def set_view(self,view_type):
        self.view_type = view_type
        self.n_classes = None

    def set_n_classes(self,n_classes):
        self.n_classes = n_classes

    def set_batch_size(self,batch_size):
        self.batch_size = batch_size

You will note that there is no notion of train/valid/test in this class: I think we should
just have a train dataset, a valid one and a test one instead or (if it's in one
big file or infinite stream) just handle the split ourselves (via slicing, for
instance). I (Dumi) am of the opinion that it keeps things cleaner, but the
specification does not preclude more fine-grained 'splitting' of the data.

A concrete implementation would look like this (we would have one class per
dataset that we use, and the class declaration contains essentially everything
there is to know about the dataset):

.. code-block:: python

  class MNIST(Dataset):
    def  __init__(self,inputs=['train_x.npy'],outputs=['train_y.npy']):
        self.type='standard_xy'
        self.in_memory = True
        self.inputs = inputs # load them or create 
        self.outputs = outputs
        self.set_view('classification') 
        self.set_n_classes(10)
        self.set_batch_size(20)
        self.n_batches = self._compute_n_batches()

    def get_batch(self,batch_index):
        x,y = self._fetch_batch(batch_index)
        if self.view_type == 'classification':
            return x,numpy.int32(y)
        elif self.view_type == 'density_estimation':
            return x
        else:
            raise NotImplementedError()

    def shared_data(self):
        shared_x = theano.shared(numpy.asarray(self.inputs, dtype=theano.config.floatX))
        shared_y = theano.shared(numpy.asarray(self.outputs, dtype=theano.config.floatX))
        return shared_x, T.cast(shared_y, 'int32')

    def _compute_n_batches(self):
        pass

    def _fetch_batch(self,batch_index):
        pass

But nothing stops you from defining get_train_batch, get_valid_batch and stuff
like that! 

So we'd use it as:

train_mnist = MNIST(inputs = ['train_x.npy'], outputs = ['train_y.npy'])
valid_mnist = MNIST(inputs = ['valid_x.npy'], outputs = ['valid_y.npy'])

x,y = train_mnist.get_batch(0)
train_mnist.set_view('density_estimation')
x = train_mnist.get_batch(0)

or

mnist_data = MNIST(inputs = ['x.npy'], outputs = ['y.npy'])
batches_train = range(int(mnist_data.n_batches*0.8))
batches_valid = range(int(mnist_data.n_batches*0.8),mnist_data.n_batches)

xt,yt = mnist_data.get_batch(batches_train[0])
xv,yv = mnist_data.get_batch(batches_valid[0])




COMMENTS
~~~~~~~~

JB asks:  How about asking datasets to also provide a visualization mechanism
for showing / playing individual examples  from the dataset, but also other
external objects that are similar to dataset examples (e.g. filters from a
weight matrix that filters images).  This doesn't have to be complicated, and it
can be shared between datasets that exist in one modality (e.g. image datasets
can all use an image-rending method)

OD replies: Besides being able to display data without prior knowledge of the
kind of data inside a dataset, is there any reason to put this within the
dataset class? If not, it seems to me it may be more appropriate to have a way
for the dataset to describe the kind of data it holds, and keep the
visualization code separate from the dataset itself. It would make it easier
in particular to try different visualization systems, and description of the
data may turn out to be useful for other reasons (however, it also means we'd
need to come up with a good way to describe data, which could prove
difficult).

JB asks: What may be passed as argument to the functions in Dataset, and what
can be expected in return?  Are there side effects (e.g. on the state of the
Dataset) associated with any of the functions?

JB asks: What properties are part of the Dataset API? What possible types can
they have, are they expected to be read-only or writeable?  What do they mean?


JB asks: What is a view?  Does set_view change the Dataset or return a new
Dataset with a certain view of the original (in which case call it get_view)?
Does the view imply the types of the return-value of functions like
get_batch?  What is the difference between the view and the subclasses of
Dataset in PyML?

JB asks:  Do container formats (I'm thinking of HDF5) offer features for fast
retrieval that we would like to expose via this interface?

JB asks: How would you recommend using this sort of dataset in a boosting
algorithm where points need to be re-weighted.


JB asks: Do we want to provide for the possibility of feedback that modifies the
dataset?  For example, curriculum learning might be adaptive in this sense, or
if we wanted to provide a virtual world for an agent as a dataset then we need
to provide 'actions' to get the next batch.  Could this be done in the current
API?


Field names and attributes
~~~~~~~~~~~~~~~~~~~~~~~~~~

OD: One important question is how to handle fields' names and characteristics.
For instance, it can be useful to know that the 3rd input field represents a
number of fingers, and is a non-negative discrete field whose numeric value is
meaningful (compared, to, say, an integer index that would correspond to an
animal's category). We mentioned metadata during the meeting, but we did not
get into its details: that may be a place where to put this kind of things.


Freeing memory
~~~~~~~~~~~~~~

OD: It is sometimes useful to be able to free memory used by previous
computations. A typical example is when you load in memory the original
dataset, then perform various processing steps, ending with a new dataset that
you also store in memory before feeding it to the learner. Unless you very
carefully design your code to avoid it, your original dataset will still
remain in memory (as well as maybe the results of some computations performed
along the way). So there may be a use for a `clear()` method that would be
called by the topmost dataset (the one doing the final memory caching), and
would be forwarded iteratively to previous datasets so as to get back all this
wasted memory space.

What is a mini-batch?
~~~~~~~~~~~~~~~~~~~~~

This is a follow-up to the meeting's discussion about whether a mini-batch
returned by a dataset should be itself a dataset.

OD: During the meeting I was voting in favor of a 'yes', mostly because it
made sense to me (a mini-batch is a subset of a dataset and thus should be a
dataset), but now I tend towards 'no'. The main reason is it is not clear yet
what the dataset interface will be, so that it is hard to judge whether this
is good idea (my main concern is how much additional work would be required by
the writer of a new dataset subclass). Anyway, maybe a first thing we could
think about is what we want a mini-batch to be. I think we can agree that we
would like to be able to do something like:

.. code-block:: python

    for mb in dataset.mini_batches(size=10):
        learner.update(mb.input, mb.target)

so that it should be ok for a mini-batch to be an object whose fields
(that should have the same name as those of the dataset) are numpy arrays.
More generally, we would like to be able to iterate on samples in a
mini-batch, or do random access on them, so a mini-batch should implement
__iter__ and __getitem__.
Besides this, is there any other typical use-case of a mini-batch? In
particular, is there any reason to want an infinite mini-batch, or a very big
mini-batch that may not fit in memory? (in which case we may need to revise
our idea of what 'mini' means) Hopefully the answer to that last question is
no, as I think it would definitely keep things simpler, since we could simply
use numpy arrays (for numeric data) or lists (for anything else) to store
mini-batches' data. So I vote for 'no'.

YB: I agree that a mini-batch should definitely be safely assumed
to fit in memory. That makes it at least in principle semantically
different from a dataset. But barring that restriction, it might
share of the properties of a dataset.

A dataset is a learner
~~~~~~~~~~~~~~~~~~~~~~

OD: (this is hopefully a clearer re-write of the original version from
r7e6e77d50eeb, which I was not happy with).
There are typically three kinds of objects that spit out data:

1. Datasets that are loaded from disk or are able to generate data all by
   themselves (i.e. without any other dataset as input)
2. Datasets that transform their input dataset in a way that only depends on
   the input dataset (e.g. filtering samples or features, normalizing data, etc.)
3. Datasets that transform their input dataset in a way that is learned on a
   potentially different dataset (e.g. PCA when you want to learn the projection
   space on the training set in order to transform both the training and test
   sets).

My impression currently is that we would use dataset subclasses to handle 1
and 2. However, 3 requires a learner framework, so you would need to have
something like a LearnerOutputDataset(trained_learner, dataset).

Note however that 2 is a special case of 3 (where training does nothing), and
1 is a special case of 2 (where we do not care about being given an input
dataset). Thus you could decide to also implement 1 and 2 as learners wrapped
by LearnerOutputDataset.

The main advantages I find in this approach (that I have been using at
Ubisoft) are:

- You only need to learn how to subclass the learner class. The only dataset
  class is LearnerOutputDataset, which you could just name Dataset.
- You do not have different ways to achieve the same result (having to figure
  out which one is most appropriate).
- Upgrading code from 2 to 3 is more straighforward. Such a situation can
  happen e.g. if you write some code that normalizes your input dataset
  (situation 2), then realize later you would like to be able to normalize new
  datasets using the same parameters (e.g. same shift & rescaling), which
  requires situation 3.
- It can make your life easier when thinking about how to plug things together
  (something that has not been discussed yet), because the interfaces of the
  various components are less varied.

I am not saying that we should necessarily do it this way, but I think it is
worth at least keeping in mind this close relationship between simple
processing and learning, and thinking about what are the benefits / drawbacks
in keeping them separate in the class hierarchy.

RP: I actually like this idea of having the dataset implement the same 
interface as the learner ( or actually a subset of the interface .. ).
I hope people decide to do this.

Support for shared variables
~~~~~~~~~~~~~~~~~~~~~~~~~~~~

RP asks: What is the status of having the dataset support copying data 
on the GPU ( by storing data in shared variables) ? Have you decided to 
include this feature or not ? I think that the strongest selling point of 
Theano is that it runs on GPU transperently, and I see this as a good 
selling point for the library as well. Plus we intend to move more and 
more towards running things on GPU. If the dataset object does not support
this feature we will need to find hacks around it ..

OD: I have like zero experience with GPU so hopefully someone else can answer
this. But the way I see it, hopefully it could work by having some dataset
object that would take care of storing its input data into a shared variable.
OD (continued): After thinking a bit more about it, I am not sure that would
work. I definitely need to look at some code doing it to get a better
understanding of it, but my feeling is that you need your learner to be
written in a specific way to achieve this, in which case it may be up to the
learner to take its input data and store it into a shared variable.

RP comment: Yes, the dataset object alone can not handle this, the issue is somewhere 
between the dataset and the learner. Or in other words, everytime you change
the data you need to recompile your theano function. So the learner can not
only get data from the dataset, it needs to get a shared variable. The learner
should also be aware when the dataset is changed, to recompile its internal 
functions. I'm not sure which is the best wa to do this. My personal feeling
is that the dataset should be part of the learner. The lerner should provide
a function use_dataset ( or replace_dataset). When this function is called,
all the theano functions in the learner get recompiled based on shared
variables that the dataset object provides. It sort of fits very well in the 
framework that I have in mind, which was spattered around in the learner.txt
and some of my previous emails. I think it shares a lot with James concepts, 
since it follows quite closely the concepts behind Theano.

OD asks: Ok, so why would the dataset have to be responsible for providing a
shared variable? Why wouldn't the learner just create this shared variable
internally and copy into it the data provided by the dataset?

RP replies: Sure, the learner could take care of all this. Note though that the
learner should take care to divide the dataset into chunks that fit in the 
GPU memory ( in case of a large dataset) and then take care of updating the 
shared variables acording to the current chunk. Personally I feel like all
this data division, management and so on should be done by the dataset. 
It feels more natural that way. For example assume you have a dataset that
is composed of a time series and some static data ( carre-tech heart beat
data is a good example). The static data is small enough so that you could 
always store on the GPU, and you would only need to split the time series. 
For the learner to do this ( since it gets the same interface from any 
dataset object) would be like and if <this case> then, while for the 
dataset is just a different class. But I'm happy to have all this GPU stuff
send to the learner as well if everybody else believe that is better. 

FB comment: I don't understand why you would need to recompile the theano function.
Their is 2 cases, the data is in a shared variable. You can directly change the data
in the shared variable without recompiling the theano fct. The second case is when 
the dataset is in an ordinary theano variable. In that case, the first step in the 
theano fct will be to transfer the dataset to the gpu before computation. If the data
change at each call, that will be as efficient as changing the data manually every time
in the shared variable.

AB: I have an idea about this which kind of fits in the "building a
theano op" thing that we talked about at the last meeting.

We can just build a theano Op that wraps dataset objects and takes
care of the details of tranferring data to the GPU or otherwise.

I have a prototype interface/implemantation in the shared_dataset.py
file in this directory.

OD: I like AB's approach.


Data API proposal by Olivier D
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

A single sample containing multiple fields (e.g. an input and a target part)
is an object s that you can manipulate as follows:

.. code-block:: python

    # Obtain actual data stored within `s` (e.g. a numpy vector). There is no
    # guarantee that modifying the resulting data object will actually update
    # the data stored in `s`.
    data = s()
    # Create a sample that sees a field of `s`.
    input_part = s.input
    # Obtain actual input data (e.g. as a numpy vector).
    input_data = input_part()
    # Create a sample that sees the i-th element of the data stored in `s`.
    ith = s[i]
    # This should not fail.
    assert ith() == s()[i]
    # You could also select a range.
    i_to_j = s[i:j]
    assert i_to_j() == s()[i:j]
    # And actually do pretty much anything you want with __getitem__, as long
    # as the underlying data stored in the sample supports it (for instance,
    # here it should be at least a 3D tensor).
    fancy_selection = s[i, :, j:k]
    assert fancy_selection() == s()[i, :, j:k]
    # Write some value (e.g. a numpy vector) into the sample. May raise an
    # exception if the sample is in read-only mode.
    s._write(val)
    # Shortcut to write data into a field (same as `s.input._write(val)`).
    s.input = val
    # Basic mathematical operators.
    s *= val
    s += val
    s -= val
    s /= val
    # Replace a field. Note that this is different from `s.input = val`
    # because here `new_input` is a sample, not a numeric value: the current
    # `s.input` will not be written to, instead it makes `s.input` point
    # towards a different sample. This may lead to confusion, so a different
    # syntax may be better (e.g. s._set_field('input', new_input)).
    s.input = new_input
    # The equality of two samples is defined by the equality of their
    # underlying data.
    def __eq__(self, other):
        return self() == other()
    # Iterate on fields (open question: should they be ordered?).
    fields = dict([(name, sample) for name, sample in s._iter_fields()])
    assert fields['input'] == s.input
    # Iterating on a sample yields samples that see consecutive elements.
    for sample, value in izip(s, s()):
        assert sample() == value
    # The length of a sample is the same as that of its underlying data.
    assert len(s) == len(s())
    # The shape of a sample is the same as that of its underlying data.
    # Note that it only makes sense for tensor-like data.
    assert s._shape() == s().shape
    # The size of a sample is the product of its shape elements.
    assert s._size() == reduce(operator.__mul__, s._shape())
    
All sample methods should start with '_', to differentiate them from the
sample's fields. This is a bit awkward, but I like the `sample.field` syntax
compared to something like "sample.get_field('field')", which makes code less
readable, especially when combining with sub_fields, e.g. `sample.input.x1`
vs. sample.get_field('input').get_field('x1').

The extension from sample to dataset is actually to use the same class, but
with the convention that the first "dimension" in the data seen by the dataset
corresponds to the samples' indices in the dataset.

.. code-block:: python

    # Return data stored in dataset `d` (e.g. a numpy matrix).
    data = d()
    # Return the i-th sample in the dataset.
    s = d[i]
    # Data should match!
    assert data[i] == s()
    # Return a subset of the dataset.
    sub_data = d[i:j]
    # Advanced indexing.
    sub_data = d[some_list_of_indices]
    # Dataset that sees the input part only.
    input_part = d.input
    # Dataset such that its i-th element is data[i][something] (see the sample
    # examples for what `something` may be).
    some_sub_data = d[:, something]
    # The following should not fail.
    assert d[i, something] == d[i][something] # == some_sub_data[i]
    # You can also write into a dataset.
    d._write(val)
    d.input = val
    # Center dataset in-place (requires `d` not to be read-only).
    d -= numpy.mean(d())
    # The length of a dataset is its number of samples.
    n_samples = len(d)
    # The width of a dataset (if it exists) is the length of its samples.
    assert d._shape()[1] == len(d[0])   # == d._width()  (shortcut)
    # Iterating on a dataset yields individual samples.
    for i, sample in enumerate(d):
        assert d[i] == sample
    # It is allowed for a dataset to hold heterogeneous data. For instance
    # you could have
    len(d.data1) != len(d.data2)
    # A sample in the dataset is not required to inherit all the dataset's
    # fields, for instance in the case above you could decide that the dataset
    # sees the same data as its first sub-dataset, i.e.
    d[i] == d.data1[i]
    
There remain some fuzzy points. For instance, are fields allowed to overlap?
(e.g. so that one could write both s.pos_3d to get the 3d vector coordinate of
sample s, and s.x to get the x coordinate without being forced to go through
s.pos_3d.x). What are the fields of s[i:j] if the (i, j) range does not
exactly match a subset of fields? How do we handle metadata? (e.g. if we want
to describe the dataset to say it contains 28x28 image data, so that an
algorithm for filter visualization can automatically deal with it)

Now, on to some use cases.

.. code-block:: python

    # Mini-batches.
    mb_dataset = d._minibatches(batch_size=5)
    # The mini-batch dataset views samples that are mini-batches.
    assert mb_dataset[0]() == d[0:5]() # As long as len(d) >= 5.

    # Shuffling samples.
    random_indices = range(len(d))
    random_indices = numpy.random.shuffle(random_indices)
    shuffled_dataset = d[random_indices]

    # Typical linear regression with stochastic gradient descent.
    n_inputs = d.input._width()
    n_targets = d.target._width()
    weights = numpy.zeros((n_inputs, n_targets))
    bias = numpy.zeros(n_targets)
    mb_dataset = d._minibatches(batch_size=10)
    # Note: it is important to get the number of inputs / targets
    # before converting to minibatches, because
    #   mb_dataset.input._width() == 10
    # since this is the length of a minibatch matrix. However you
    # could still do the following, which is less readable:
    #   n_inputs = mb_dataset.input._shape()[2]
    # You could also wait until you see the first sample to create
    # the parameters (this would actually be a better way to do it, since
    # it avoids calling the _width method).
    for input, target in izip(mb_dataset.input, mb_dataset.target):
        cost = (numpy.dot(input(), weights) + b - target())**2
        # Update weights and bias depending on cost....

A few more points:
    - Infinite datasets could be used (would just need to define a convention
      on what __len__ should do).
    - It is also ok to have datasets that do not support random access (so the
      only way to access samples is through iteration).
    - Ideally, data should be deterministic (i.e. __call__() should always
      return the same thing). It would probably be up to the user to be super
      careful if he decides to use a non-deterministic dataset.
    - About the "task vs. dataset" distinction. This could be achieved by
      associating to a task the names of the fields it requires (e.g. "input"
      and "target" for the regression task), and if the dataset does not
      already defines these fields, using a dataset wrapper than does it
      (saying for instance that "input" is the concatenation of "x1" and "x2",
      and "target" is "y", for a dataset whose fields are x1, x2 and y).


RP comments:
 - I like this approach. I think having overlapping fields might be useful.
 I would add that I was thinking of a way to look at one's results. Is
 something I've been faced with, say you run 500 jobs and then you want to
 understand those jobs' results. Looking just at the best performing seems a waste, and
 there is a lot more information you can extract from your results if you are
 able to generate certain plots or statistics. To do this you would need to
 get the data in ipython (or something quite similar) where you have available
 the needed functions to plot different things, generate different tables. The
 point that I was trying to make is that you can get those results in
 something that has this very API that Olivier described. This way both both
 your input data and your results will be in the same form and whatever
 visualization functions you have for your results you can use on your data as
 well. For this you would need a bit more flexibility, in the sense that if
 you have some data d, you should be able to put constraints on it, like 
 d.some_field == 5 means all entries in d that has some_field == 5, or 
 d.some_field > 5. You would also not use psql anymore but this console, 
 which would collect the results for you from sql, and give them to you as 
 data object.

OD replies: Actually this should be doable with (almost) what I wrote above,
due to the way numpy redefines ==, >, etc. (which btw should break some of my
assertions above, since I had forgotten about this). If you replace e.g. my
implementation of __eq__ above by the following:

.. code-block:: python

    def __eq__(self, other):
        return other == self()

Here, `self` is a dataset that represents some numpy vector data. Then whether
`other` is another dataset or a numpy vector or some scalar, this will return
a numpy boolean vector (the result of the comparison made by numpy). We may
support boolean vectors in advanced indexing, so you could do
    d[d.some_field == 5]
and obtain the subset of `d` whose samples have `some_field` set to 5.
Same could be done with __lt__, __le__, etc.