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view svm.xml @ 22:cefbe0fe1bbb draft
planemo upload for repository https://github.com/bgruening/galaxytools/tree/master/tools/sklearn commit 8850f42c2c3763e614f7454c9c006f3d2ff572c0
author | bgruening |
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date | Fri, 27 May 2022 11:25:59 +0000 |
parents | aa5170605077 |
children | 0be7886106fb |
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<tool id="sklearn_svm_classifier" name="Support vector machines (SVMs)" version="@VERSION@" profile="20.05"> <description>for classification</description> <macros> <import>main_macros.xml</import> <!-- macro name="class_weight" argument="class_weight"--> </macros> <expand macro="python_requirements" /> <expand macro="macro_stdio" /> <version_command>echo "@VERSION@"</version_command> <command><![CDATA[ python '$svc_script' '$inputs' ]]> </command> <configfiles> <inputs name="inputs" /> <configfile name="svc_script"> <![CDATA[ import sys import json import sklearn.svm import pandas import pickle from galaxy_ml.utils import load_model, get_X_y input_json_path = sys.argv[1] with open(input_json_path, "r") as param_handler: params = json.load(param_handler) #if $selected_tasks.selected_task == "load": header = 'infer' if params["selected_tasks"]["header"] else None data = pandas.read_csv("$selected_tasks.infile_data", sep='\t', header=header, index_col=None, parse_dates=True, encoding=None) with open("$infile_model", 'rb') as model_handler: classifier_object = load_model(model_handler) prediction = classifier_object.predict(data) prediction_df = pandas.DataFrame(prediction) res = pandas.concat([data, prediction_df], axis=1) res.to_csv(path_or_buf = "$outfile_predict", sep="\t", index=False) #else: X, y = get_X_y(params, "$selected_tasks.selected_algorithms.input_options.infile1", "$selected_tasks.selected_algorithms.input_options.infile2") options = params["selected_tasks"]["selected_algorithms"]["options"] selected_algorithm = params["selected_tasks"]["selected_algorithms"]["selected_algorithm"] if not(selected_algorithm=="LinearSVC"): if options["kernel"]: options["kernel"] = str(options["kernel"]) my_class = getattr(sklearn.svm, selected_algorithm) classifier_object = my_class(**options) classifier_object.fit(X, y) with open("$outfile_fit", 'wb') as out_handler: pickle.dump(classifier_object, out_handler) #end if ]]> </configfile> </configfiles> <inputs> <expand macro="sl_Conditional" model="zip"> <param name="selected_algorithm" type="select" label="Classifier type"> <option value="SVC">C-Support Vector Classification</option> <option value="NuSVC">Nu-Support Vector Classification</option> <option value="LinearSVC">Linear Support Vector Classification</option> </param> <when value="SVC"> <expand macro="sl_mixed_input" /> <expand macro="svc_advanced_options"> <expand macro="C" /> </expand> </when> <when value="NuSVC"> <expand macro="sl_mixed_input" /> <expand macro="svc_advanced_options"> <param argument="nu" type="float" optional="true" value="0.5" label="Nu control parameter" help="Controls the number of support vectors. Should be in the interval (0, 1]. " /> </expand> </when> <when value="LinearSVC"> <expand macro="sl_mixed_input" /> <section name="options" title="Advanced Options" expanded="False"> <expand macro="C" /> <expand macro="tol" default_value="0.001" help_text="Tolerance for stopping criterion. " /> <expand macro="random_state" help_text="Integer number. The seed of the pseudo random number generator to use when shuffling the data for probability estimation. A fixed seed allows reproducible results." /> <!--expand macro="class_weight"/--> <param argument="max_iter" type="integer" optional="true" value="1000" label="Maximum number of iterations" help="The maximum number of iterations to be run." /> <param argument="loss" type="select" label="Loss function" help="Specifies the loss function. ''squared_hinge'' is the square of the hinge loss."> <option value="squared_hinge" selected="true">Squared hinge</option> <option value="hinge">Hinge</option> </param> <param argument="penalty" type="select" label="Penalization norm" help=" "> <option value="l1">l1</option> <option value="l2" selected="true">l2</option> </param> <param argument="dual" type="boolean" optional="true" truevalue="booltrue" falsevalue="boolflase" checked="true" label="Use the shrinking heuristic" help="Select the algorithm to either solve the dual or primal optimization problem. Prefer dual=False when n_samples > n_features." /> <param argument="multi_class" type="select" label="Multi-class strategy" help="Determines the multi-class strategy if y contains more than two classes."> <option value="ovr" selected="true">ovr</option> <option value="crammer_singer">crammer_singer</option> </param> <param argument="fit_intercept" type="boolean" optional="true" truevalue="booltrue" falsevalue="boolflase" checked="true" label="Calculate the intercept for this model" help="If set to false, data is expected to be already centered." /> <param argument="intercept_scaling" type="float" optional="true" value="1" label="Add synthetic feature to the instance vector" help=" " /> </section> </when> </expand> </inputs> <expand macro="output" /> <tests> <test> <param name="infile1" value="train_set.tabular" ftype="tabular" /> <param name="infile2" value="train_set.tabular" ftype="tabular" /> <param name="header1" value="True" /> <param name="header2" value="True" /> <param name="col1" value="1,2,3,4" /> <param name="col2" value="5" /> <param name="selected_task" value="train" /> <param name="selected_algorithm" value="SVC" /> <param name="random_state" value="5" /> <output name="outfile_fit" file="svc_model01" compare="sim_size" /> </test> <test> <param name="infile1" value="train_set.tabular" ftype="tabular" /> <param name="infile2" value="train_set.tabular" ftype="tabular" /> <param name="header1" value="True" /> <param name="header2" value="True" /> <param name="col1" value="1,2,3,4" /> <param name="col2" value="5" /> <param name="selected_task" value="train" /> <param name="selected_algorithm" value="NuSVC" /> <param name="random_state" value="5" /> <output name="outfile_fit" file="svc_model02" compare="sim_size" /> </test> <test> <param name="infile1" value="train_set.tabular" ftype="tabular" /> <param name="infile2" value="train_set.tabular" ftype="tabular" /> <param name="header1" value="True" /> <param name="header2" value="True" /> <param name="col1" value="1,2,3,4" /> <param name="col2" value="5" /> <param name="selected_task" value="train" /> <param name="selected_algorithm" value="LinearSVC" /> <param name="random_state" value="5" /> <output name="outfile_fit" file="svc_model03" compare="sim_size" /> </test> <test> <param name="infile_model" value="svc_model01" ftype="zip" /> <param name="infile_data" value="test_set.tabular" ftype="tabular" /> <param name="header" value="True" /> <param name="selected_task" value="load" /> <output name="outfile_predict" file="svc_prediction_result01.tabular" /> </test> <test> <param name="infile_model" value="svc_model02" ftype="zip" /> <param name="infile_data" value="test_set.tabular" ftype="tabular" /> <param name="header" value="True" /> <param name="selected_task" value="load" /> <output name="outfile_predict" file="svc_prediction_result02.tabular" /> </test> <test> <param name="infile_model" value="svc_model03" ftype="zip" /> <param name="infile_data" value="test_set.tabular" ftype="tabular" /> <param name="header" value="True" /> <param name="selected_task" value="load" /> <output name="outfile_predict" file="svc_prediction_result03.tabular" /> </test> <!-- The following test is expected to fail, it is testing the whitelist/blacklist filtering. It loads a pickle with malicious content that we do not accept. --> <test expect_failure="true"> <param name="infile_model" value="pickle_blacklist" ftype="zip" /> <param name="infile_data" value="test_set.tabular" ftype="tabular" /> <param name="header" value="True" /> <param name="selected_task" value="load" /> </test> </tests> <help><![CDATA[ **What it does** This module implements the Support Vector Machine (SVM) classification algorithms. Support vector machines (SVMs) are a set of supervised learning methods used for classification, regression and outliers detection. **The advantages of support vector machines are:** 1- Effective in high dimensional spaces. 2- Still effective in cases where number of dimensions is greater than the number of samples. 3- Uses a subset of training points in the decision function (called support vectors), so it is also memory efficient. 4- Versatile: different Kernel functions can be specified for the decision function. Common kernels are provided, but it is also possible to specify custom kernels. **The disadvantages of support vector machines include:** 1- If the number of features is much greater than the number of samples, the method is likely to give poor performances. 2- SVMs do not directly provide probability estimates, these are calculated using an expensive five-fold cross-validation For more information check http://scikit-learn.org/stable/modules/neighbors.html ]]> </help> <expand macro="sklearn_citation" /> </tool>