ACDC_KNOSYS-2021/MSC/kmm.py

import math, numpy, sklearn.metrics.pairwise as sk, sys
from sklearn import linear_model
from cvxopt import matrix, solvers

#DENSITY ESTIMATION
#KMM solving the quadratic programming problem to get betas (weights) for each training instance
def kmm(Xtrain, Xtest, sigma):
	n_tr = len(Xtrain)
	n_te = len(Xtest)
	
	#calculate Kernel
	print 'Computing kernel for training data ...'
	K_ns = sk.rbf_kernel(Xtrain, Xtrain, sigma)
	#make it symmetric
	K = 0.5*(K_ns + K_ns.transpose())
	
	#calculate kappa
	print 'Computing kernel for kappa ...'
	kappa_r = sk.rbf_kernel(Xtrain, Xtest, sigma)
	ones = numpy.ones(shape=(n_te, 1))
	kappa = numpy.dot(kappa_r, ones)
	kappa = -(float(n_tr)/float(n_te)) * kappa
	
	#calculate eps
	eps = (math.sqrt(n_tr) - 1)/math.sqrt(n_tr)
	
	#constraints
	A0 = numpy.ones(shape=(1,n_tr))
	A1 = -numpy.ones(shape=(1,n_tr))
	A = numpy.vstack([A0, A1, -numpy.eye(n_tr), numpy.eye(n_tr)])
	b = numpy.array([[n_tr*(eps+1), n_tr*(eps-1)]])
	b = numpy.vstack([b.T, -numpy.zeros(shape=(n_tr,1)), numpy.ones(shape=(n_tr,1))*1000])
	
	print 'Solving quadratic program for beta ...'
	P = matrix(K, tc='d')
	q = matrix(kappa, tc='d')
	G = matrix(A, tc='d')
	h = matrix(b, tc='d')
	beta = solvers.qp(P,q,G,h)
	return [i for i in beta['x']]


#KMM PARAMETER TUNING
#Train a linear regression model with Lasso (L1 regularization).
#Model parameter selection via cross validation
#Predict the target (Beta) for a given test dataset
def regression(XTrain, betaTrain, XTest):
	model = linear_model.LassoCV(cv=10, alphas=[0.001,0.005,0.01,0.05,0.1,0.5,1,5,10])
	model.fit(XTrain, betaTrain)
	Beta = model.predict(XTest)
	return [i for i in Beta]


#KMM PARAMETER TUNING
#Compute J score for parameter tuning of KMM
def computeJ(betaTrain, betaTest):
	tr = sum([i ** 2 for i in betaTrain])
	te = sum(betaTest)
	return ((1/float(len(betaTrain)))*tr) - ((2/float(len(betaTest)))*te)


#I/O OPERATIONS
#Read input csv file
def getData(filename):
	data = []
	with open(filename) as f:
		content = f.readlines()
	
	for line in content:
		line = line.strip()
		data.append(map(float,line.split(",")))
	return data


#I/O OPERATIONS
#Write Output to file
def writeFile(filename, data):
	if len(data) == 0:
		return
	
	with open(filename, 'w') as f:
		for i in data:
			f.write(str(i) + '\n')


#MAIN ALGORITHM
#compute beta
def getBeta(traindata, testdata, gammab):
	
	Jmin = 0
	beta = []
	
	for g in gammab:
		betaTrain = kmm(traindata, testdata, g)
		betaTest = regression(traindata, betaTrain, testdata)
		J = computeJ(betaTrain,betaTest)
		
		#print betaTrain
		#print betaTest
		#print J
		
		if len(beta) == 0:
			Jmin = J
			beta = list(betaTrain)
		elif Jmin > J:
			Jmin = J
			beta = list(betaTrain)
	
	return beta
    

#MAIN METHOD
def main():
    #traindata = [[1,2,3],[4,7,4],[3,3,3],[4,4,4],[5,5,5],[3,4,5],[1,2,3],[4,7,4],[3,3,3],[4,4,4],[5,5,5],[3,4,5],[1,2,3],[4,7,4],[3,3,3],[4,4,4],[5,5,5],[3,4,5],[1,2,3],[4,7,4],[3,3,3],[4,4,4],[5,5,5],[3,4,5]]
    #testdata = [[5,9,10],[4,5,6],[10,20,30],[1,2,3],[3,4,5],[5,6,7],[7,8,9],[100,100,100],[11,22,33],[12,11,5],[5,9,10],[4,5,6],[10,20,30],[1,2,3],[3,4,5],[5,6,7],[7,8,9],[100,100,100],[11,22,33],[12,11,5]]
    #gammab = [0.001]
	
	if len(sys.argv) != 4:
		print 'Incorrect number of arguments.'
		print 'Arg: training_file, test_file, output_file.'
		return
    
	traindata = getData(sys.argv[1])
	testdata = getData(sys.argv[2])
	gammab = [1/float(len(traindata)),0.0001,0.0005,0.001,0.005,0.01,0.05,0.1,0.5,1,5,10]
	print 'Got training and test data.'
	
	beta = getBeta(traindata, testdata, gammab)
	
	writeFile(sys.argv[3], beta)

if __name__ == '__main__':
	main()
Add files via upload 2021-10-04 18:29:54 +08:00			`import math, numpy, sklearn.metrics.pairwise as sk, sys`
			`from sklearn import linear_model`
			`from cvxopt import matrix, solvers`

			`#DENSITY ESTIMATION`
			`#KMM solving the quadratic programming problem to get betas (weights) for each training instance`
			`def kmm(Xtrain, Xtest, sigma):`
			`n_tr = len(Xtrain)`
			`n_te = len(Xtest)`

			`#calculate Kernel`
			`print 'Computing kernel for training data ...'`
			`K_ns = sk.rbf_kernel(Xtrain, Xtrain, sigma)`
			`#make it symmetric`
			`K = 0.5*(K_ns + K_ns.transpose())`

			`#calculate kappa`
			`print 'Computing kernel for kappa ...'`
			`kappa_r = sk.rbf_kernel(Xtrain, Xtest, sigma)`
			`ones = numpy.ones(shape=(n_te, 1))`
			`kappa = numpy.dot(kappa_r, ones)`
			`kappa = -(float(n_tr)/float(n_te)) * kappa`

			`#calculate eps`
			`eps = (math.sqrt(n_tr) - 1)/math.sqrt(n_tr)`

			`#constraints`
			`A0 = numpy.ones(shape=(1,n_tr))`
			`A1 = -numpy.ones(shape=(1,n_tr))`
			`A = numpy.vstack([A0, A1, -numpy.eye(n_tr), numpy.eye(n_tr)])`
			`b = numpy.array([[n_tr(eps+1), n_tr(eps-1)]])`
			`b = numpy.vstack([b.T, -numpy.zeros(shape=(n_tr,1)), numpy.ones(shape=(n_tr,1))*1000])`

			`print 'Solving quadratic program for beta ...'`
			`P = matrix(K, tc='d')`
			`q = matrix(kappa, tc='d')`
			`G = matrix(A, tc='d')`
			`h = matrix(b, tc='d')`
			`beta = solvers.qp(P,q,G,h)`
			`return [i for i in beta['x']]`


			`#KMM PARAMETER TUNING`
			`#Train a linear regression model with Lasso (L1 regularization).`
			`#Model parameter selection via cross validation`
			`#Predict the target (Beta) for a given test dataset`
			`def regression(XTrain, betaTrain, XTest):`
			`model = linear_model.LassoCV(cv=10, alphas=[0.001,0.005,0.01,0.05,0.1,0.5,1,5,10])`
			`model.fit(XTrain, betaTrain)`
			`Beta = model.predict(XTest)`
			`return [i for i in Beta]`


			`#KMM PARAMETER TUNING`
			`#Compute J score for parameter tuning of KMM`
			`def computeJ(betaTrain, betaTest):`
			`tr = sum([i ** 2 for i in betaTrain])`
			`te = sum(betaTest)`
			`return ((1/float(len(betaTrain)))tr) - ((2/float(len(betaTest)))te)`


			`#I/O OPERATIONS`
			`#Read input csv file`
			`def getData(filename):`
			`data = []`
			`with open(filename) as f:`
			`content = f.readlines()`

			`for line in content:`
			`line = line.strip()`
			`data.append(map(float,line.split(",")))`
			`return data`


			`#I/O OPERATIONS`
			`#Write Output to file`
			`def writeFile(filename, data):`
			`if len(data) == 0:`
			`return`

			`with open(filename, 'w') as f:`
			`for i in data:`
			`f.write(str(i) + '\n')`


			`#MAIN ALGORITHM`
			`#compute beta`
			`def getBeta(traindata, testdata, gammab):`

			`Jmin = 0`
			`beta = []`

			`for g in gammab:`
			`betaTrain = kmm(traindata, testdata, g)`
			`betaTest = regression(traindata, betaTrain, testdata)`
			`J = computeJ(betaTrain,betaTest)`

			`#print betaTrain`
			`#print betaTest`
			`#print J`

			`if len(beta) == 0:`
			`Jmin = J`
			`beta = list(betaTrain)`
			`elif Jmin > J:`
			`Jmin = J`
			`beta = list(betaTrain)`

			`return beta`


			`#MAIN METHOD`
			`def main():`
			`#traindata = [[1,2,3],[4,7,4],[3,3,3],[4,4,4],[5,5,5],[3,4,5],[1,2,3],[4,7,4],[3,3,3],[4,4,4],[5,5,5],[3,4,5],[1,2,3],[4,7,4],[3,3,3],[4,4,4],[5,5,5],[3,4,5],[1,2,3],[4,7,4],[3,3,3],[4,4,4],[5,5,5],[3,4,5]]`
			`#testdata = [[5,9,10],[4,5,6],[10,20,30],[1,2,3],[3,4,5],[5,6,7],[7,8,9],[100,100,100],[11,22,33],[12,11,5],[5,9,10],[4,5,6],[10,20,30],[1,2,3],[3,4,5],[5,6,7],[7,8,9],[100,100,100],[11,22,33],[12,11,5]]`
			`#gammab = [0.001]`

			`if len(sys.argv) != 4:`
			`print 'Incorrect number of arguments.'`
			`print 'Arg: training_file, test_file, output_file.'`
			`return`

			`traindata = getData(sys.argv[1])`
			`testdata = getData(sys.argv[2])`
			`gammab = [1/float(len(traindata)),0.0001,0.0005,0.001,0.005,0.01,0.05,0.1,0.5,1,5,10]`
			`print 'Got training and test data.'`

			`beta = getBeta(traindata, testdata, gammab)`

			`writeFile(sys.argv[3], beta)`

			`if __name__ == '__main__':`
			`main()`