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| author | jpayne |
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| date | Tue, 18 Mar 2025 17:55:14 -0400 |
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# Copyright 2001 by Jeffrey Chang. All rights reserved. # # This file is part of the Biopython distribution and governed by your # choice of the "Biopython License Agreement" or the "BSD 3-Clause License". # Please see the LICENSE file that should have been included as part of this # package. """Maximum Entropy code. Uses Improved Iterative Scaling. """ # TODO Define terminology from functools import reduce import warnings try: import numpy as np except ImportError: from Bio import MissingPythonDependencyError raise MissingPythonDependencyError( "Please install NumPy if you want to use Bio.MaxEntropy. " "See http://www.numpy.org/" ) from None from Bio import BiopythonDeprecationWarning warnings.warn( "The 'Bio.MaxEntropy' module is deprecated and will be removed in a future " "release of Biopython. Consider using scikit-learn instead.", BiopythonDeprecationWarning, ) class MaxEntropy: """Hold information for a Maximum Entropy classifier. Members: classes List of the possible classes of data. alphas List of the weights for each feature. feature_fns List of the feature functions. Car data from example Naive Bayes Classifier example by Eric Meisner November 22, 2003 http://www.inf.u-szeged.hu/~ormandi/teaching >>> from Bio.MaxEntropy import train, classify >>> xcar = [ ... ['Red', 'Sports', 'Domestic'], ... ['Red', 'Sports', 'Domestic'], ... ['Red', 'Sports', 'Domestic'], ... ['Yellow', 'Sports', 'Domestic'], ... ['Yellow', 'Sports', 'Imported'], ... ['Yellow', 'SUV', 'Imported'], ... ['Yellow', 'SUV', 'Imported'], ... ['Yellow', 'SUV', 'Domestic'], ... ['Red', 'SUV', 'Imported'], ... ['Red', 'Sports', 'Imported']] >>> ycar = ['Yes','No','Yes','No','Yes','No','Yes','No','No','Yes'] Requires some rules or features >>> def udf1(ts, cl): ... return ts[0] != 'Red' ... >>> def udf2(ts, cl): ... return ts[1] != 'Sports' ... >>> def udf3(ts, cl): ... return ts[2] != 'Domestic' ... >>> user_functions = [udf1, udf2, udf3] # must be an iterable type >>> xe = train(xcar, ycar, user_functions) >>> for xv, yv in zip(xcar, ycar): ... xc = classify(xe, xv) ... print('Pred: %s gives %s y is %s' % (xv, xc, yv)) ... Pred: ['Red', 'Sports', 'Domestic'] gives No y is Yes Pred: ['Red', 'Sports', 'Domestic'] gives No y is No Pred: ['Red', 'Sports', 'Domestic'] gives No y is Yes Pred: ['Yellow', 'Sports', 'Domestic'] gives No y is No Pred: ['Yellow', 'Sports', 'Imported'] gives No y is Yes Pred: ['Yellow', 'SUV', 'Imported'] gives No y is No Pred: ['Yellow', 'SUV', 'Imported'] gives No y is Yes Pred: ['Yellow', 'SUV', 'Domestic'] gives No y is No Pred: ['Red', 'SUV', 'Imported'] gives No y is No Pred: ['Red', 'Sports', 'Imported'] gives No y is Yes """ def __init__(self): """Initialize the class.""" self.classes = [] self.alphas = [] self.feature_fns = [] def calculate(me, observation): """Calculate the log of the probability for each class. me is a MaxEntropy object that has been trained. observation is a vector representing the observed data. The return value is a list of unnormalized log probabilities for each class. """ scores = [] assert len(me.feature_fns) == len(me.alphas) for klass in me.classes: lprob = 0.0 for fn, alpha in zip(me.feature_fns, me.alphas): lprob += fn(observation, klass) * alpha scores.append(lprob) return scores def classify(me, observation): """Classify an observation into a class.""" scores = calculate(me, observation) max_score, klass = scores[0], me.classes[0] for i in range(1, len(scores)): if scores[i] > max_score: max_score, klass = scores[i], me.classes[i] return klass def _eval_feature_fn(fn, xs, classes): """Evaluate a feature function on every instance of the training set and class (PRIVATE). fn is a callback function that takes two parameters: a training instance and a class. Return a dictionary of (training set index, class index) -> non-zero value. Values of 0 are not stored in the dictionary. """ values = {} for i in range(len(xs)): for j in range(len(classes)): f = fn(xs[i], classes[j]) if f != 0: values[(i, j)] = f return values def _calc_empirical_expects(xs, ys, classes, features): """Calculate the expectation of each function from the data (PRIVATE). This is the constraint for the maximum entropy distribution. Return a list of expectations, parallel to the list of features. """ # E[f_i] = SUM_x,y P(x, y) f(x, y) # = 1/N f(x, y) class2index = {} for index, key in enumerate(classes): class2index[key] = index ys_i = [class2index[y] for y in ys] expect = [] N = len(xs) for feature in features: s = 0 for i in range(N): s += feature.get((i, ys_i[i]), 0) expect.append(s / N) return expect def _calc_model_expects(xs, classes, features, alphas): """Calculate the expectation of each feature from the model (PRIVATE). This is not used in maximum entropy training, but provides a good function for debugging. """ # SUM_X P(x) SUM_Y P(Y|X) F(X, Y) # = 1/N SUM_X SUM_Y P(Y|X) F(X, Y) p_yx = _calc_p_class_given_x(xs, classes, features, alphas) expects = [] for feature in features: sum = 0.0 for (i, j), f in feature.items(): sum += p_yx[i][j] * f expects.append(sum / len(xs)) return expects def _calc_p_class_given_x(xs, classes, features, alphas): """Calculate conditional probability P(y|x) (PRIVATE). y is the class and x is an instance from the training set. Return a XSxCLASSES matrix of probabilities. """ prob_yx = np.zeros((len(xs), len(classes))) # Calculate log P(y, x). assert len(features) == len(alphas) for feature, alpha in zip(features, alphas): for (x, y), f in feature.items(): prob_yx[x][y] += alpha * f # Take an exponent to get P(y, x) prob_yx = np.exp(prob_yx) # Divide out the probability over each class, so we get P(y|x). for i in range(len(xs)): z = sum(prob_yx[i]) prob_yx[i] = prob_yx[i] / z return prob_yx def _calc_f_sharp(N, nclasses, features): """Calculate a matrix of f sharp values (PRIVATE).""" # f#(x, y) = SUM_i feature(x, y) f_sharp = np.zeros((N, nclasses)) for feature in features: for (i, j), f in feature.items(): f_sharp[i][j] += f return f_sharp def _iis_solve_delta( N, feature, f_sharp, empirical, prob_yx, max_newton_iterations, newton_converge ): """Solve delta using Newton's method (PRIVATE).""" # SUM_x P(x) * SUM_c P(c|x) f_i(x, c) e^[delta_i * f#(x, c)] = 0 delta = 0.0 iters = 0 while iters < max_newton_iterations: # iterate for Newton's method f_newton = df_newton = 0.0 # evaluate the function and derivative for (i, j), f in feature.items(): prod = prob_yx[i][j] * f * np.exp(delta * f_sharp[i][j]) f_newton += prod df_newton += prod * f_sharp[i][j] f_newton, df_newton = empirical - f_newton / N, -df_newton / N ratio = f_newton / df_newton delta -= ratio if np.fabs(ratio) < newton_converge: # converged break iters = iters + 1 else: raise RuntimeError("Newton's method did not converge") return delta def _train_iis( xs, classes, features, f_sharp, alphas, e_empirical, max_newton_iterations, newton_converge, ): """Do one iteration of hill climbing to find better alphas (PRIVATE).""" # This is a good function to parallelize. # Pre-calculate P(y|x) p_yx = _calc_p_class_given_x(xs, classes, features, alphas) N = len(xs) newalphas = alphas[:] for i in range(len(alphas)): delta = _iis_solve_delta( N, features[i], f_sharp, e_empirical[i], p_yx, max_newton_iterations, newton_converge, ) newalphas[i] += delta return newalphas def train( training_set, results, feature_fns, update_fn=None, max_iis_iterations=10000, iis_converge=1.0e-5, max_newton_iterations=100, newton_converge=1.0e-10, ): """Train a maximum entropy classifier, returns MaxEntropy object. Train a maximum entropy classifier on a training set. training_set is a list of observations. results is a list of the class assignments for each observation. feature_fns is a list of the features. These are callback functions that take an observation and class and return a 1 or 0. update_fn is a callback function that is called at each training iteration. It is passed a MaxEntropy object that encapsulates the current state of the training. The maximum number of iterations and the convergence criterion for IIS are given by max_iis_iterations and iis_converge, respectively, while max_newton_iterations and newton_converge are the maximum number of iterations and the convergence criterion for Newton's method. """ if not training_set: raise ValueError("No data in the training set.") if len(training_set) != len(results): raise ValueError("training_set and results should be parallel lists.") # Rename variables for convenience. xs, ys = training_set, results # Get a list of all the classes that need to be trained. classes = sorted(set(results)) # Cache values for all features. features = [_eval_feature_fn(fn, training_set, classes) for fn in feature_fns] # Cache values for f#. f_sharp = _calc_f_sharp(len(training_set), len(classes), features) # Pre-calculate the empirical expectations of the features. e_empirical = _calc_empirical_expects(xs, ys, classes, features) # Now train the alpha parameters to weigh each feature. alphas = [0.0] * len(features) iters = 0 while iters < max_iis_iterations: nalphas = _train_iis( xs, classes, features, f_sharp, alphas, e_empirical, max_newton_iterations, newton_converge, ) diff = [np.fabs(x - y) for x, y in zip(alphas, nalphas)] diff = reduce(np.add, diff, 0) alphas = nalphas me = MaxEntropy() me.alphas, me.classes, me.feature_fns = alphas, classes, feature_fns if update_fn is not None: update_fn(me) if diff < iis_converge: # converged break else: raise RuntimeError("IIS did not converge") return me if __name__ == "__main__": from Bio._utils import run_doctest run_doctest(verbose=0)