Mercurial > repos > goeckslab > gate_finder
view gate_finder.py @ 2:764f6363e2a9 draft default tip
planemo upload for repository https://github.com/goeckslab/tools-mti/tree/main/tools/vitessce commit a6714d257c45c11d999c7cc2241c89da193cae15
| author | goeckslab |
|---|---|
| date | Fri, 10 May 2024 17:21:02 +0000 |
| parents | 6df8d6e42152 |
| children |
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import argparse import json import warnings from pathlib import Path import numpy as np import pandas as pd from anndata import read_h5ad from sklearn.mixture import GaussianMixture from sklearn.preprocessing import MinMaxScaler from vitessce import ( AnnDataWrapper, Component as cm, MultiImageWrapper, OmeTiffWrapper, VitessceConfig, ) # Generate binarized phenotype for a gate def get_gate_phenotype(g, d): dd = d.copy() dd = np.where(dd < g, 0, dd) np.warnings.filterwarnings('ignore') dd = np.where(dd >= g, 1, dd) return dd def get_gmm_phenotype(data): low = np.percentile(data, 0.01) high = np.percentile(data, 99.99) data = np.clip(data, low, high) sum = np.sum(data) median = np.median(data) data_med = data / sum * median data_log = np.log1p(data_med) data_log = data_log.reshape(-1, 1) scaler = MinMaxScaler(feature_range=(0, 1)) data_norm = scaler.fit_transform(data_log) gmm = GaussianMixture(n_components=2) gmm.fit(data_norm) gate = np.mean(gmm.means_) return get_gate_phenotype(gate, np.ravel(data_norm)) def main(inputs, output, image, anndata, masks=None): """ Parameter --------- inputs : str File path to galaxy tool parameter. output : str Output folder for saving web content. image : str File path to the OME Tiff image. anndata : str File path to anndata containing phenotyping info. masks : str File path to the image masks. """ warnings.simplefilter('ignore') with open(inputs, 'r') as param_handler: params = json.load(param_handler) marker = params['marker'].strip() from_gate = params['from_gate'] to_gate = params['to_gate'] increment = params['increment'] x_coordinate = params['x_coordinate'].strip() or 'X_centroid' y_coordinate = params['y_coordinate'].strip() or 'Y_centroid' adata = read_h5ad(anndata) # If no raw data is available make a copy if adata.raw is None: adata.raw = adata # Copy of the raw data if it exisits if adata.raw is not None: adata.X = adata.raw.X data = pd.DataFrame( adata.X, columns=adata.var.index, index=adata.obs.index ) marker_values = data[[marker]].values marker_values_log = np.log1p(marker_values) # Identify the list of increments gate_names = [] for num in np.arange(from_gate, to_gate, increment): num = round(num, 3) key = marker + '--' + str(num) adata.obs[key] = get_gate_phenotype(num, marker_values_log) gate_names.append(key) adata.obs['GMM_auto'] = get_gmm_phenotype(marker_values) gate_names.append('GMM_auto') adata.obsm['XY_coordinate'] = adata.obs[[x_coordinate, y_coordinate]].values vc = VitessceConfig(name=None, description=None) dataset = vc.add_dataset() image_wrappers = [OmeTiffWrapper(img_path=image, name='OMETIFF')] if masks: image_wrappers.append( OmeTiffWrapper(img_path=masks, name='MASKS', is_bitmask=True) ) dataset.add_object(MultiImageWrapper(image_wrappers)) dataset.add_object( AnnDataWrapper( adata, spatial_centroid_obsm='XY_coordinate', cell_set_obs=gate_names, cell_set_obs_names=[obj[0].upper() + obj[1:] for obj in gate_names], expression_matrix="X" ) ) spatial = vc.add_view(dataset, cm.SPATIAL) cellsets = vc.add_view(dataset, cm.CELL_SETS) status = vc.add_view(dataset, cm.STATUS) lc = vc.add_view(dataset, cm.LAYER_CONTROLLER) genes = vc.add_view(dataset, cm.GENES) cell_set_sizes = vc.add_view(dataset, cm.CELL_SET_SIZES) cell_set_expression = vc.add_view(dataset, cm.CELL_SET_EXPRESSION) vc.layout( (status / genes / cell_set_expression) | (cellsets / cell_set_sizes / lc) | (spatial) ) config_dict = vc.export(to='files', base_url='http://localhost', out_dir=output) with open(Path(output).joinpath('config.json'), 'w') as f: json.dump(config_dict, f, indent=4) if __name__ == '__main__': aparser = argparse.ArgumentParser() aparser.add_argument("-i", "--inputs", dest="inputs", required=True) aparser.add_argument("-e", "--output", dest="output", required=True) aparser.add_argument("-g", "--image", dest="image", required=True) aparser.add_argument("-a", "--anndata", dest="anndata", required=True) aparser.add_argument("-m", "--masks", dest="masks", required=False) args = aparser.parse_args() main(args.inputs, args.output, args.image, args.anndata, args.masks)