/mountainlab-js

MountainLab is data processing, sharing and visualization software for scientists. It is built around MountainSort, spike sorting software, but is designed to be much more generally applicable.

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MountainLab

MountainLab is data processing, sharing and visualization software for scientists. It was built to support MountainSort, spike sorting software, but is designed to be more generally applicable.

Spike Sorting

This page documents MountainLab only. If you would like to use MountainSort spike sorting software, then please follow this link for installation and usage instructions.

Installation

MountainLab and associated plugins and helper code are available for Linux and MacOS. At some point, this may run on Windows.

The easiest way to install MountainLab is using conda:

conda create -n mountainlab
conda activate mountainlab
conda install -c flatiron -c conda-forge mountainlab mountainlab_pytools

You should regularly update the installation via:

conda install -c flatiron -c conda-forge mountainlab mountainlab_pytools

If you are not familiar with conda or do not have it installed, then you should read this conda guide.

Alternative installation

Alternatively you can install MountainLab using npm (you must first install a recent version of NodeJS)

npm install -g mountainlab

and mountainlab_pytools can be installed using pip (use python 3.6 or later)

pip install mountainlab_pytools

Developer installation

Developers should install MountainLab and mountainlab_pytools from source

git clone [this-repo]
cd [this-repo-name]
npm install .

Then add [this-repo-name]/bin to your PATH environment variable.

See the mountainlab_pytools repository for information on installing that package from source.

A note about prior versions of MountainLab

If you have a prior (non-js) version of MountainLab installed, then you may want to uninstall it for sanity's sake (either via apt-get remove or by removing the mountainlab binaries from your path), although it is possible for them to co-exist since the command-line utilities have different names. Note that the processor plugin libraries work equally well and simultaneously with both (we have not changed the .mp spec system). The default package search path has changed, though, so you will need to copy or link your processor packages to the new location (see below).

Test and configure your Installation

Test the installation by running

ml-config

The output of this command will explain how to configure MountainLab on your system (it simply involves setting environment variables by editing a .env file).

Note that, when installed using conda, MountainLab will default to searching a configuration directory within the current conda env. Otherwise, the default location will be be in ~/.mountainlab. You can always determine this location by running ml-config.

Further test the installation by running

ml-list-processors

This should list the names of all the available processors. If you have not yet installed any processor packages, then it will just list a single hello.world processor distributed with MountainLab. To see the specification for this processor in human-readable format, enter

ml-spec hello.world -p

This will show the inputs, outputs, and parameters for this processor. Since it is a minimalist processor, it doesn't have any of these, so the output of this command will be very unexciting.

Processors

MountainLab is not useful if it can't do more than hello.world. The main functionality of MountainLab is to wrap well-defined, deterministic compute operations into processors. Each processor has a specification which defines the inputs, outputs, and parameters that the processor operates on, and can encapsulate programs written in any language.

In order to run a processor it must either be installed or available in a Singularity container.

Installing processors

The easiest way to install a MountainLab processor package is using conda. For example, the ml_ephys package contains processors that are useful for electrophysiology and spike sorting. It can be installed via:

conda install -c flatiron -c conda-forge ml_ephys

Assuming that the conda package is configured properly, this will make a symbolic link in a packages/ directory within the current conda environment. To verify that it was installed properly, try ml-list-processors once again. This time, in addition to hello.world, you should see a collection of processors that start with the ephys. prefix. Now we can get something more useful from ml-spec:

ml-spec ephys.bandpass_filter -p

Alternatively, if you are not using conda, or if a MountainLab package is not available in conda, then you can control which processor packages are registered by manually creating symbolic links to the packages/ directory as follows:

pip install ml_ephys
ml-link-python-module ml_ephys `ml-config package_directory`/ml_ephys

Here, ml-link-python-module is a convenience command distributed with MountainLab that creates symbolic links based on installed python modules. The ml-config package_directory command returns the directory where MountainLab looks for processor packages.

Developers of processor packages should use the following method for installing packages from source

git clone https://github.com/magland/ml_ephys
ln -s ml_ephys `ml-config package_directory`/ml_ephys

Note that in this last case, you should make sure that all python dependencies of ml_ephys are installed.

In general, MountainLab finds registered processors by recursively searching the packages directory for any executable files with a .mp extension. More details on creating plugin processor packages can be found elsewhere in the documentation.

Running processors

Once installed, processors can either be run directly on the command-line (as shown in this section), or by using a Python script (see github.com/mountainsort_examples for an example Python pipelines).

From the command-line (or within a bash script) processors jobs can be executed by issuing the ml-run-process command:

ml-run-process [processor_name] \
    --inputs \
        [ikey1]:[ifile1] \
        [ikey2]:[ifile2] \
        ... 
    --outputs \
        [okey1]:[ofile1] \
        ... 
    --parameters \
        [pkey1]:[pval1] \
        ... 
    [other options]

(Note that -i, -o, and -p can be used in place of --inputs, --outputs, and --parameters)

For example, to run the hello.world processor:

ml-run-process hello.world

MountainLab maintains a database/cache of all of the processor jobs that have executed. If the same processor command is issued at a later time, with the same input files, output files, and parameters, then the system recognizes this and does not actually run the job. To force it to re-execute, use the --force_run flag as follows:

ml-run-process hello.world --force_run

To get help on other options of ml-run-process, use the following or look elsewhere in the documentation

ml-run-process --help

Non-hello-world examples can be found in the MountainSort examples repository

Configuration

As you will learn from running the ml-config command, MountainLab can be configured by setting environment variables. Ideally these should should be specified in the mountainlab.env file (see the output ml-config to determine its location), but those values can also be overridden by setting the variables by command-line in the terminal. You can always check whether these have been successfully set for the current instance of MountainLab by running ml-config after making changes.

The following are some of the configuration variables (they each have a default value if left empty):

  • ML_TEMPORARY_DIRECTORY -- the location where temporary data files are stored (default: /tmp/mountainlab-tmp)
  • ML_PACKAGE_SEARCH_DIRECTORY -- the primary location for ML processing packages
  • ML_ADDITIONAL_PACKAGE_SEARCH_DIRECTORIES -- optional additional directories to search for packages (colon separated list)
  • ML_ADDITIONAL_PRV_SEARCH_DIRECTORIES -- optional additional directories to search for files pointed to by .prv objects

Command reference

The following commands are available from any terminal. Use the --help flag on any of these to get more detailed information.

  • mda-info Get information about a .mda file
  • ml-config Show the current configuration (i.e., environment variables)
  • ml-exec-process Run a processor job without involving the process cache for completed processes
  • ml-link-python-module Register a processor package from an installed python module, as described above
  • ml-list-processors List all registered processors on the local machine
  • ml-prv-create Create a new .prv file based on an existing data file (computes the sha1sum, etc)
  • ml-prv-download Download a file corresponding to a .prv file or object
  • ml-prv-locate Locate a file on the local machine (or remotely) based on a .prv file
  • ml-prv-sha1sum Compute the sha1sum of a data file (uses a cache for efficiency)
  • ml-prv-stat Compute the prv object for a data file (uses a cache for efficiency)
  • ml-read-dir Read a directory, which could be a kbucket path, returning a JSON object
  • ml-run-process Run a processor job
  • ml-spec Retrieve the spec object for a particular registered processor

PRV files

This section needs to be expanded and corrected. Right now it does not explain what a PRV file is.

Note that .prv files can be substituted for both inputs or outputs. In such a case, where an input file has a .prv extension, MountainLab will search the local machine for the corresponding data file and substitute that in before running the processor (see the ml-prv-locate command). In the case that one of the output files has a .prv extension, MountainLab will store the output in a temporary file (in ML_TEMPORARY_DIRECTORY) and then create a corresponding .prv file in the output location specified in the command (see the ml-prv-create command).

Thus one can do command-line processing purely using .prv files, as in the following example of creating a synthetic electrophysiology dataset (which requires the ml_ephys processor library to be installed):

ml-run-process ephys.synthesize_random_waveforms --outputs waveforms_out:data/waveforms_true.mda.prv geometry_out:data/geom.csv --parameters upsamplefac:13 M:4
ml-run-process ephys.synthesize_random_firings --outputs firings_out:data/firings_true.mda.prv --parameters duration:600
ml-run-process ephys.synthesize_timeseries --inputs firings:data/firings_true.mda.prv waveforms:data/waveforms_true.mda.prv --outputs timeseries_out:data/raw.mda.prv --parameters duration:600 waveform_upsamplefac:13

All files will be stored in temporary locations, which can be retrieved using the ml-prv-locate command as follows:

ml-prv-locate raw_synth.mda.prv 
/tmp/mountainlab-tmp/output_184a04c2877517f8996fd992b6f923bee8c6bbd2_timeseries_out

Creating custom python processors

While MountainLab processor packages can be created in any language, the easiest way to contribute to code is to use our mlprocessors framework. There you will find a step-by-step guide and links to several examples.

Custom processor libraries

Here is a list of user-contributed processor packages that we know of. You may git clone each of these into a working directory, then link them to your MountainLab packages directory as above.

  • Identity processors A set of "hello world" processors, to show how to make a simple processor and do file I/O.

  • ddms: Tools for converting to/from neurosuite format, by Alex Morley.

  • ironclust: CPU-only octave implementation of JRCLUST algorithm, wrapped as a processor, by James Jun.

  • Loren Frank's lab processors:

    • franklab_msdrift: Modified drift processors that compare both neighbor and non-neighbor epochs for drift tracking, by Mari Sosa.

    • franklab_mstaggedcuration: Tagged curation processors that preserve "rejected" clusters for accurate metrics recalculation, by Anna Gillespie.

You can also create your own MountainLab processor libraries using any language (python, C/C++, matlab, etc). Processor libraries are simply represented by executable .mp files that provide the specifications (spec) for a collection of processors together with command strings telling MountainLab how to execute those processors using system calls. For details, see the above ml_identity processors, and creating custom processor libraries

Credits and acknowledgements

The framework was conceived by and primarily implemented by Jeremy Magland at the Flatiron Institute and is released under the Apache license v2.

The project is currently being developed and maintained by:

  • Jeremy Magland
  • Tom Davidson
  • Alex Morley
  • Witold Wysota

Other key collaborators include folks at Flatiron Institute, including Alex Barnett, Dylan Simon, Leslie Greengard, Joakim Anden, and James Jun.

Jason Chung, Loren Frank, Leslie Greengard and Alex Barnett are direct collaborators in our spike sorting efforts and have therefore contributed to MountainLab, which has a broader scope. Other MountainSort users have contributed invaluable feedback, particularly investigators at UCSF (Mari Sosa has contributed code to the project).

MountainLab will also play a central role in the implementation of a website for comparing spike sorting algorithms on a standard set of ground-truth datasets. Alex Barnett, Jeremy Magland, and James Jun are leading this effort, but it is a community project, and we hope to have a lot of involvement from other players in the field of electrophysiology and spike sorting.

Alex Morley has a project and vision for applying continuous integration principles to research which will most likely use MountainLab as a core part of its implementation.

(If I have neglected to acknowledge your contribution, please remind me.)

Related Projects / Components

KBucket & kbclient - Distributed Data Access
MountainView & EPhys-Viz (WIP) - Visualisation
MountainLab PyTools - Python Tools