def compute_iqms(settings, name='ComputeIQMs'): """Workflow that actually computes the IQMs""" workflow = pe.Workflow(name=name) inputnode = pe.Node(niu.IdentityInterface(fields=[ 'subject_id', 'session_id', 'run_id', 'orig', 'brainmask', 'airmask', 'artmask', 'headmask', 'segmentation', 'inu_corrected', 'in_inu', 'pvms', 'metadata', 'reverse_transforms', 'reverse_invert_flags' ]), name='inputnode') outputnode = pe.Node( niu.IdentityInterface(fields=['out_file', 'out_noisefit']), name='outputnode') deriv_dir = check_folder( op.abspath(op.join(settings['output_dir'], 'derivatives'))) # AFNI check smoothing fwhm = pe.Node(afni.FWHMx(combine=True, detrend=True), name='smoothness') # fwhm.inputs.acf = True # add when AFNI >= 16 # Mortamet's QI2 getqi2 = pe.Node(ComputeQI2(erodemsk=settings.get('testing', False)), name='ComputeQI2') # Compute python-coded measures measures = pe.Node(StructuralQC(), 'measures') # Project MNI segmentation to T1 space invt = pe.MapNode(ants.ApplyTransforms(dimension=3, default_value=0, interpolation='NearestNeighbor'), iterfield=['input_image'], name='MNItpms2t1') invt.inputs.input_image = [ op.join(get_mni_icbm152_nlin_asym_09c(), fname + '.nii.gz') for fname in ['1mm_tpm_csf', '1mm_tpm_gm', '1mm_tpm_wm'] ] datasink = pe.Node(IQMFileSink(modality='T1w', out_dir=deriv_dir), name='datasink') workflow.connect([(inputnode, datasink, [('subject_id', 'subject_id'), ('session_id', 'session_id'), ('run_id', 'run_id'), ('metadata', 'metadata')]), (inputnode, getqi2, [('orig', 'in_file'), ('airmask', 'air_msk')]), (inputnode, measures, [('inu_corrected', 'in_noinu'), ('in_inu', 'in_bias'), ('orig', 'in_file'), ('airmask', 'air_msk'), ('headmask', 'head_msk'), ('artmask', 'artifact_msk'), ('segmentation', 'in_segm'), ('pvms', 'in_pvms')]), (inputnode, fwhm, [('orig', 'in_file'), ('brainmask', 'mask')]), (inputnode, invt, [('orig', 'reference_image'), ('reverse_transforms', 'transforms'), ('reverse_invert_flags', 'invert_transform_flags')]), (invt, measures, [('output_image', 'mni_tpms')]), (measures, datasink, [('out_qc', 'root')]), (getqi2, datasink, [('qi2', 'qi_2')]), (fwhm, datasink, [(('fwhm', fwhm_dict), 'root0')]), (getqi2, outputnode, [('out_file', 'out_noisefit')]), (datasink, outputnode, [('out_file', 'out_file')])]) return workflow
def compute_iqms(name="ComputeIQMs"): """ Setup the workflow that actually computes the IQMs. .. workflow:: from mriqc.workflows.anatomical import compute_iqms from mriqc.testing import mock_config with mock_config(): wf = compute_iqms() """ from niworkflows.interfaces.bids import ReadSidecarJSON from ..interfaces.anatomical import Harmonize from .utils import _tofloat workflow = pe.Workflow(name=name) inputnode = pe.Node( niu.IdentityInterface(fields=[ "in_file", "in_ras", "brainmask", "airmask", "artmask", "headmask", "rotmask", "hatmask", "segmentation", "inu_corrected", "in_inu", "pvms", "metadata", "inverse_composite_transform", ]), name="inputnode", ) outputnode = pe.Node( niu.IdentityInterface(fields=["out_file", "noisefit"]), name="outputnode", ) # Extract metadata meta = pe.Node(ReadSidecarJSON(), name="metadata") # Add provenance addprov = pe.Node(AddProvenance(), name="provenance", run_without_submitting=True) # AFNI check smoothing fwhm_interface = get_fwhmx() fwhm = pe.Node(fwhm_interface, name="smoothness") # Harmonize homog = pe.Node(Harmonize(), name="harmonize") if config.workflow.species.lower() != "human": homog.inputs.erodemsk = False homog.inputs.thresh = 0.8 # Mortamet's QI2 getqi2 = pe.Node(ComputeQI2(), name="ComputeQI2") # Compute python-coded measures measures = pe.Node( StructuralQC(human=config.workflow.species.lower() == "human"), "measures") # Project MNI segmentation to T1 space invt = pe.MapNode( ants.ApplyTransforms(dimension=3, default_value=0, interpolation="Linear", float=True), iterfield=["input_image"], name="MNItpms2t1", ) if config.workflow.species.lower() == "human": invt.inputs.input_image = [ str(p) for p in get_template( config.workflow.template_id, suffix="probseg", resolution=1, label=["CSF", "GM", "WM"], ) ] else: invt.inputs.input_image = [ str(p) for p in get_template( config.workflow.template_id, suffix="probseg", label=["CSF", "GM", "WM"], ) ] datasink = pe.Node( IQMFileSink( out_dir=config.execution.output_dir, dataset=config.execution.dsname, ), name="datasink", run_without_submitting=True, ) def _getwm(inlist): return inlist[-1] # fmt: off workflow.connect([ (inputnode, meta, [("in_file", "in_file")]), (inputnode, datasink, [("in_file", "in_file"), (("in_file", _get_mod), "modality")]), (inputnode, addprov, [(("in_file", _get_mod), "modality")]), (meta, datasink, [("subject", "subject_id"), ("session", "session_id"), ("task", "task_id"), ("acquisition", "acq_id"), ("reconstruction", "rec_id"), ("run", "run_id"), ("out_dict", "metadata")]), (inputnode, addprov, [("in_file", "in_file"), ("airmask", "air_msk"), ("rotmask", "rot_msk")]), (inputnode, getqi2, [("in_ras", "in_file"), ("hatmask", "air_msk")]), (inputnode, homog, [("inu_corrected", "in_file"), (("pvms", _getwm), "wm_mask")]), (inputnode, measures, [("in_inu", "in_bias"), ("in_ras", "in_file"), ("airmask", "air_msk"), ("headmask", "head_msk"), ("artmask", "artifact_msk"), ("rotmask", "rot_msk"), ("segmentation", "in_segm"), ("pvms", "in_pvms")]), (inputnode, fwhm, [("in_ras", "in_file"), ("brainmask", "mask")]), (inputnode, invt, [("in_ras", "reference_image"), ("inverse_composite_transform", "transforms")]), (homog, measures, [("out_file", "in_noinu")]), (invt, measures, [("output_image", "mni_tpms")]), (fwhm, measures, [(("fwhm", _tofloat), "in_fwhm")]), (measures, datasink, [("out_qc", "root")]), (addprov, datasink, [("out_prov", "provenance")]), (getqi2, datasink, [("qi2", "qi_2")]), (getqi2, outputnode, [("out_file", "noisefit")]), (datasink, outputnode, [("out_file", "out_file")]), ]) # fmt: on return workflow
def compute_iqms(settings, name='ComputeIQMs'): """ Workflow that actually computes the IQMs .. workflow:: from mriqc.workflows.functional import compute_iqms wf = compute_iqms(settings={'output_dir': 'out'}) """ from mriqc.workflows.utils import _tofloat biggest_file_gb = settings.get("biggest_file_size_gb", 1) workflow = pe.Workflow(name=name) inputnode = pe.Node(niu.IdentityInterface(fields=[ 'subject_id', 'session_id', 'task_id', 'acq_id', 'rec_id', 'run_id', 'orig', 'epi_mean', 'brainmask', 'hmc_epi', 'hmc_fd', 'fd_thres', 'in_tsnr', 'metadata' ]), name='inputnode') outputnode = pe.Node(niu.IdentityInterface( fields=['out_file', 'out_dvars', 'outliers', 'out_spikes', 'out_fft']), name='outputnode') #Set FD threshold inputnode.inputs.fd_thres = settings.get('fd_thres', 0.2) deriv_dir = check_folder( op.abspath(op.join(settings['output_dir'], 'derivatives'))) # Compute DVARS dvnode = pe.Node(nac.ComputeDVARS(save_plot=False, save_all=True), name='ComputeDVARS') dvnode.interface.estimated_memory_gb = biggest_file_gb * 3 # AFNI quality measures fwhm = pe.Node(afni.FWHMx(combine=True, detrend=True), name='smoothness') # fwhm.inputs.acf = True # add when AFNI >= 16 outliers = pe.Node(afni.OutlierCount(fraction=True, out_file='ouliers.out'), name='outliers') outliers.interface.estimated_memory_gb = biggest_file_gb * 2.5 quality = pe.Node(afni.QualityIndex(automask=True), out_file='quality.out', name='quality') quality.interface.estimated_memory_gb = biggest_file_gb * 3 measures = pe.Node(FunctionalQC(), name='measures') measures.interface.estimated_memory_gb = biggest_file_gb * 3 workflow.connect([(inputnode, dvnode, [('hmc_epi', 'in_file'), ('brainmask', 'in_mask')]), (inputnode, measures, [('epi_mean', 'in_epi'), ('brainmask', 'in_mask'), ('hmc_epi', 'in_hmc'), ('hmc_fd', 'in_fd'), ('fd_thres', 'fd_thres'), ('in_tsnr', 'in_tsnr')]), (inputnode, fwhm, [('epi_mean', 'in_file'), ('brainmask', 'mask')]), (inputnode, quality, [('hmc_epi', 'in_file')]), (inputnode, outliers, [('hmc_epi', 'in_file'), ('brainmask', 'mask')]), (dvnode, measures, [('out_all', 'in_dvars')]), (fwhm, measures, [(('fwhm', _tofloat), 'in_fwhm')]), (dvnode, outputnode, [('out_all', 'out_dvars')]), (outliers, outputnode, [('out_file', 'outliers')])]) # Save to JSON file datasink = pe.Node(IQMFileSink(modality='bold', out_dir=deriv_dir), name='datasink') workflow.connect([ (inputnode, datasink, [('subject_id', 'subject_id'), ('session_id', 'session_id'), ('task_id', 'task_id'), ('acq_id', 'acq_id'), ('rec_id', 'rec_id'), ('run_id', 'run_id'), ('metadata', 'metadata')]), (outliers, datasink, [(('out_file', _parse_tout), 'aor')]), (quality, datasink, [(('out_file', _parse_tqual), 'aqi')]), (measures, datasink, [('out_qc', 'root')]), (datasink, outputnode, [('out_file', 'out_file')]) ]) if settings.get('fft_spikes_detector', False): # FFT spikes finder spikes_fft = pe.Node(niu.Function( input_names=['in_file'], output_names=['n_spikes', 'out_spikes', 'out_fft'], function=slice_wise_fft), name='SpikesFinderFFT') workflow.connect([ (inputnode, spikes_fft, [('orig', 'in_file')]), (spikes_fft, outputnode, [('out_spikes', 'out_spikes'), ('out_fft', 'out_fft')]), (spikes_fft, datasink, [('n_spikes', 'spikes_num')]) ]) return workflow
def compute_iqms(settings, name='ComputeIQMs'): """Workflow that actually computes the IQMs""" workflow = pe.Workflow(name=name) inputnode = pe.Node(niu.IdentityInterface(fields=[ 'subject_id', 'session_id', 'task_id', 'run_id', 'orig', 'epi_mean', 'brainmask', 'hmc_epi', 'hmc_fd', 'in_tsnr', 'metadata']), name='inputnode') outputnode = pe.Node(niu.IdentityInterface( fields=['out_file', 'out_dvars', 'outliers', 'out_spikes', 'out_fft']), name='outputnode') deriv_dir = check_folder(op.abspath(op.join(settings['output_dir'], 'derivatives'))) # Compute DVARS dvnode = pe.Node(nac.ComputeDVARS(save_plot=False, save_all=True), name='ComputeDVARS') # AFNI quality measures fwhm = pe.Node(afni.FWHMx(combine=True, detrend=True), name='smoothness') # fwhm.inputs.acf = True # add when AFNI >= 16 outliers = pe.Node(afni.OutlierCount(fraction=True, out_file='ouliers.out'), name='outliers') quality = pe.Node(afni.QualityIndex(automask=True), out_file='quality.out', name='quality') # FFT spikes finder spikes_fft = pe.Node(niu.Function( input_names=['in_file'], output_names=['n_spikes', 'out_spikes', 'out_fft'], function=slice_wise_fft), name='SpikesFinderFFT') measures = pe.Node(FunctionalQC(), name='measures') workflow.connect([ (inputnode, dvnode, [('orig', 'in_file'), ('brainmask', 'in_mask')]), (inputnode, measures, [('epi_mean', 'in_epi'), ('brainmask', 'in_mask'), ('hmc_epi', 'in_hmc'), ('hmc_fd', 'in_fd'), ('in_tsnr', 'in_tsnr')]), (inputnode, fwhm, [('epi_mean', 'in_file'), ('brainmask', 'mask')]), (inputnode, spikes_fft, [('orig', 'in_file')]), (inputnode, quality, [('hmc_epi', 'in_file')]), (inputnode, outliers, [('hmc_epi', 'in_file'), ('brainmask', 'mask')]), (dvnode, measures, [('out_all', 'in_dvars')]), (dvnode, outputnode, [('out_all', 'out_dvars')]), (outliers, outputnode, [('out_file', 'outliers')]), (spikes_fft, outputnode, [('out_spikes', 'out_spikes'), ('out_fft', 'out_fft')]) ]) # Save to JSON file datasink = pe.Node(IQMFileSink( modality='bold', out_dir=deriv_dir), name='datasink') workflow.connect([ (inputnode, datasink, [('subject_id', 'subject_id'), ('session_id', 'session_id'), ('task_id', 'task_id'), ('run_id', 'run_id'), ('metadata', 'metadata')]), (outliers, datasink, [(('out_file', _parse_tout), 'aor')]), (quality, datasink, [(('out_file', _parse_tqual), 'aqi')]), (measures, datasink, [('out_qc', 'root')]), (spikes_fft, datasink, [('n_spikes', 'spikes_num')]), (fwhm, datasink, [(('fwhm', fwhm_dict), 'root0')]), (datasink, outputnode, [('out_file', 'out_file')]) ]) return workflow
def compute_iqms(name="ComputeIQMs"): """ Initialize the workflow that actually computes the IQMs. .. workflow:: from mriqc.workflows.functional import compute_iqms from mriqc.testing import mock_config with mock_config(): wf = compute_iqms() """ from nipype.algorithms.confounds import ComputeDVARS from nipype.interfaces.afni import OutlierCount, QualityIndex from niworkflows.interfaces.bids import ReadSidecarJSON from mriqc.interfaces import FunctionalQC, IQMFileSink from mriqc.interfaces.reports import AddProvenance from mriqc.interfaces.transitional import GCOR from mriqc.workflows.utils import _tofloat, get_fwhmx mem_gb = config.workflow.biggest_file_gb workflow = pe.Workflow(name=name) inputnode = pe.Node( niu.IdentityInterface(fields=[ "in_file", "in_ras", "epi_mean", "brainmask", "hmc_epi", "hmc_fd", "fd_thres", "in_tsnr", "metadata", "exclude_index", ]), name="inputnode", ) outputnode = pe.Node( niu.IdentityInterface(fields=[ "out_file", "out_dvars", "outliers", "out_spikes", "out_fft", ]), name="outputnode", ) # Set FD threshold inputnode.inputs.fd_thres = config.workflow.fd_thres # Compute DVARS dvnode = pe.Node( ComputeDVARS(save_plot=False, save_all=True), name="ComputeDVARS", mem_gb=mem_gb * 3, ) # AFNI quality measures fwhm_interface = get_fwhmx() fwhm = pe.Node(fwhm_interface, name="smoothness") # fwhm.inputs.acf = True # add when AFNI >= 16 outliers = pe.Node( OutlierCount(fraction=True, out_file="outliers.out"), name="outliers", mem_gb=mem_gb * 2.5, ) quality = pe.Node( QualityIndex(automask=True), out_file="quality.out", name="quality", mem_gb=mem_gb * 3, ) gcor = pe.Node(GCOR(), name="gcor", mem_gb=mem_gb * 2) measures = pe.Node(FunctionalQC(), name="measures", mem_gb=mem_gb * 3) # fmt: off workflow.connect([(inputnode, dvnode, [("hmc_epi", "in_file"), ("brainmask", "in_mask")]), (inputnode, measures, [("epi_mean", "in_epi"), ("brainmask", "in_mask"), ("hmc_epi", "in_hmc"), ("hmc_fd", "in_fd"), ("fd_thres", "fd_thres"), ("in_tsnr", "in_tsnr")]), (inputnode, fwhm, [("epi_mean", "in_file"), ("brainmask", "mask")]), (inputnode, quality, [("hmc_epi", "in_file")]), (inputnode, outliers, [("hmc_epi", "in_file"), ("brainmask", "mask")]), (inputnode, gcor, [("hmc_epi", "in_file"), ("brainmask", "mask")]), (dvnode, measures, [("out_all", "in_dvars")]), (fwhm, measures, [(("fwhm", _tofloat), "in_fwhm")]), (dvnode, outputnode, [("out_all", "out_dvars")]), (outliers, outputnode, [("out_file", "outliers")])]) # fmt: on # Add metadata meta = pe.Node(ReadSidecarJSON(), name="metadata", run_without_submitting=True) addprov = pe.Node( AddProvenance(modality="bold"), name="provenance", run_without_submitting=True, ) # Save to JSON file datasink = pe.Node( IQMFileSink( modality="bold", out_dir=str(config.execution.output_dir), dataset=config.execution.dsname, ), name="datasink", run_without_submitting=True, ) # fmt: off workflow.connect([ (inputnode, datasink, [("in_file", "in_file"), ("exclude_index", "dummy_trs")]), (inputnode, meta, [("in_file", "in_file")]), (inputnode, addprov, [("in_file", "in_file")]), (meta, datasink, [("subject", "subject_id"), ("session", "session_id"), ("task", "task_id"), ("acquisition", "acq_id"), ("reconstruction", "rec_id"), ("run", "run_id"), ("out_dict", "metadata")]), (addprov, datasink, [("out_prov", "provenance")]), (outliers, datasink, [(("out_file", _parse_tout), "aor")]), (gcor, datasink, [(("out", _tofloat), "gcor")]), (quality, datasink, [(("out_file", _parse_tqual), "aqi")]), (measures, datasink, [("out_qc", "root")]), (datasink, outputnode, [("out_file", "out_file")]) ]) # fmt: on # FFT spikes finder if config.workflow.fft_spikes_detector: from .utils import slice_wise_fft spikes_fft = pe.Node( niu.Function( input_names=["in_file"], output_names=["n_spikes", "out_spikes", "out_fft"], function=slice_wise_fft, ), name="SpikesFinderFFT", ) # fmt: off workflow.connect([ (inputnode, spikes_fft, [("in_ras", "in_file")]), (spikes_fft, outputnode, [("out_spikes", "out_spikes"), ("out_fft", "out_fft")]), (spikes_fft, datasink, [("n_spikes", "spikes_num")]) ]) # fmt: on return workflow