view doc/v2_planning/requirements.txt @ 1207:53937045f6c7

Pasted content of email sent by Ian about existing python ML libraries
author Olivier Delalleau <delallea@iro>
date Tue, 21 Sep 2010 10:58:14 -0400
parents 5525cf3faaa2
children 31b72defb680
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.. _requirements:

============
Requirements
============


Application Requirements
========================

Terminology and Abbreviations:
------------------------------

MLA - machine learning algorithm

learning problem - a machine learning application typically characterized by a
dataset (possibly dataset folds) one or more functions to be learned from the
data, and one or more metrics to evaluate those functions.  Learning problems
are the benchmarks for empirical model comparison.

n. of - number of

SGD - stochastic gradient descent

Users:
------

- New masters and PhD students in the lab should be able to quickly move into
  'production' mode without having to reinvent the wheel.

- Students in the two ML classes, able to play with the library to explore new
  ML variants. This means some APIs (e.g. Experiment level) must be really well
  documented and conceptually simple.

- Researchers outside the lab (who might study and experiment with our
  algorithms)

- Partners outside the lab (e.g. Bell, Ubisoft) with closed-source commercial
  projects.

Uses:
-----

R1. reproduce previous work (our own and others')

R2. explore MLA variants by swapping components (e.g.  optimization algo, dataset,
  hyper-parameters)

R3. analyze experimental results (e.g. plotting training curves, finding best
  models, marginalizing across hyper-parameter choices)

R4. disseminate (or serve as platform for disseminating) our own published algorithms

R5. provide implementations of common MLA components (e.g. classifiers, datasets,
  optimization algorithms, meta-learning algorithms)

R6. drive large scale parallizable computations (e.g. grid search, bagging,
  random search)

R7. provide implementations of standard pre-processing algorithms (e.g. PCA,
  stemming, Mel-scale spectrograms, GIST features, etc.)

R8. provide high performance suitable for large-scale experiments

R9. be able to use the most efficient algorithms in special case combinations of
  learning algorithm components (e.g. when there is a fast k-fold validation
  algorithm for a particular model family, the library should not require users
  to rewrite their standard k-fold validation script to use it)

R10. support experiments on a variety of datasets (e.g. movies, images, text,
  sound, reinforcement learning?)

R11. support efficient computations on datasets larger than RAM and GPU memory

R12. support infinite datasets (i.e. generated on the fly)

R13. apply trained models "in production".
  - e.g. say you try many combinations of preprocessing, models and associated
    hyper-parameters, and want to easily be able to recover the full "processing
    pipeline" that performs best, and use it on real/test data later.

OD comments: Note that R9 and R13 may conflict with each other. Some
optimizations performed by R9 may modify the input "symbolic graph" in such a
way that extracting the required components for "production purpose" (R13)
could be made more difficult (or even impossible). Imagine for instance that
the graph is modified to take advantage of the fact that k-fold validation can
be performed efficiently internally by some specific algorithm. Then it may
not be obvious anymore how to remove the k-fold split in the saved model you
want to use in production.


Requirements for component architecture
=======================================


R14.  Serializability of experiments. (essentially in pursuit of R6)

Jobs that are running a learning algorithm with our components (datasets,
models, algorithms) must be able to serialize the experiment's state to a string
(typically written to disk) and be able to restart it from such a string.  There
must be a mechanism to tell a job to serialize the experiment as soon as
possible, and a latency of up to 10 seconds should be acceptable.  It must also
be possible to deserialize the experiment for introspection (inspect the state
of individual components), not just for continuing the experiment.  The
experiment can assume that resources on disk that were present when the
experiment started will be present when the experiment resumes.  The experiment
cannot assume that resources written by the experiment will still be there (e.g.
in /tmp or cwd).  Implementations should make an effort to make the serialized
representation compact, when it is possible to recompute or reload from disk
at deserialization time.

This requirement is aimed at enabling process migration and job control as well
as post-hoc analysis of experiment results.

OD asks: When you say "The experiment cannot assume that resources written by
the experiment will still be there", do you mean we should be able to recover
the exact same output after interrupting an experiment, wiping its expdir, and
restarting it? This would mean that any output saved on disk by the experiment
also has to be serialized within the experiment, which may lead to very big
serialization files (and possibly memory issues?)
A less constraining interpretation of your statement (which I like better) is
that we allow "previous" output to be lost: we only ask that the experiment
should be able to produce the "new" outputs after a wipe+restart.