Nipype
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Nipype
What is Nipype?
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Nipype (Neuroimaging in Python Pipelines and Interfaces) is a flexible, lightweight and extensible neuroimaging data processing framework in Python. It is a community-developed initiative under the umbrella of Nipy. It addresses the heterogeneous collection of specialized applications in neuroimaging: SPM in MATLAB, FSL in shell, and Nipy in Python. A uniform interface is proposed to facilitate interaction between these different packages within a single workflow. The source code, issues and pull requests can be found here. The fundamental parts of Nipype are Interfaces, the Workflow Engine and the Execution Plugins, as you can see in the figure at the left:
Among the execution plugins, you can find |
Installation
pip
can be used to install the stable release of Nipype:
It is recommended to install python dependencies within a virtual environment. To do so, execute the following commands before running the pip
command:
Basic usage
Let's assume that you have previously installed Nipype's dependencies and you have installed fsl to process the Rhyme judgment dataset available on OpenNeuro.
Here, we present an basic example of performing pre-processing using Nipype:
import nipype.interfaces.fsl as fsl
from nipype import Node, Workflow
preprocessing = Workflow(name='preprocessing')
# using fMRI's linear image registration tool for intra-modal motion correction
mcflirt = Node(fsl.MCFLIRT(), name='mcflirt')
mean = Node(fsl.MeanImage(), name='mean')
# add Nodes to Workflow
preprocessing.connect(mcflirt, 'out_file', mean, 'in_file')
mcflirt.inputs.in_file = '/home/ychi/nipype/ds000003/sub-01/func/sub-01_task-rhymejudgment_bold.nii.gz'
# Workflow execution
preprocessing.run()
Using Nipype Plugins
As shown in the figure above, Nipype's workflow engine supports a plugin architecture for workflow execution. The available plugins, such as SGE, PBS, HTCondor, LSF, Slurm or OAR allow local and distributed execution of workflows and debugging.
All plugins can be executed by calling:
workflow.run(plugin=PLUGIN_NAME, plugin_args=ARGS_DICT)
Using Nipype's OAR plugin
For example, to execute the basic preprocessing example above with OAR resources, you need to call:
workflow.run(plugin='OAR')
Note: you can also provide traditional oarsub arguments by using the oarsub_args
parameter:
workflow.run(plugin='oar', plugin_args=dict(oarsub_args='-q default')
Other parameters supported by OAR plugin are:
template
: custom template file 'hello-world.sh' for batch job submissionmax_jobname_len
: maximum length of the job name. Default 15.
Using Nipype's Slurm plugin
For example, to execute the basic preprocessing example above with Slurm resources, you need to call:
workflow.run(plugin='OAR')
Note: you can also provide traditional oarsub arguments by using the oarsub_args
parameter:
workflow.run(plugin='oar', plugin_args=dict(oarsub_args='-q default')
Other parameters supported by OAR plugin are:
template
: custom template file 'hello-world.sh' for batch job submissionmax_jobname_len
: maximum length of the job name. Default 15.
Pydra
Pydra is a part of the second generation of the Nipype ecosystem, which is meant to provide additional flexibility and reproducibility. Pydra rewrites Nipype engine with mapping and joining as first-class operations. However, Pydra does not have OAR Support. Examples and details of Pydra's OAR extension can be found here.