started branch for analysis v4 dev

deprecated old modules
2024-09-20 00:47:56 +00:00 · 2021-05-26 07:27:09 +00:00 · 2021-05-26 07:27:09 +00:00 · 23329da2b5
commit 23329da2b5
parent 8a365b784e
12 changed files with 21 additions and 1111 deletions
--- a/analysis-master/tra_analysis/Analysis.py
+++ b/analysis-master/tra_analysis/Analysis.py
@ -7,10 +7,12 @@
 #    current benchmark of optimization: 1.33 times faster
 # setup:
-__version__ = "3.0.2"
+__version__ = "3.0.3"
 # changelog should be viewed using print(analysis.__changelog__)
 __changelog__ = """changelog:
 	3.0.3:
 		- fixed spelling of deprecate
 	3.0.2:
 		- fixed __all__
 	3.0.1:
@ -58,7 +60,7 @@ __changelog__ = """changelog:
 			- cycle sort
 			- cocktail sort
 		- tested all sorting algorithms with both lists and numpy arrays
-		- depreciated sort function from Array class
+		- deprecated sort function from Array class
 		- added warnings as an import
 	2.1.4:
 		- added sort and search functions to Array class
@ -136,7 +138,7 @@ __changelog__ = """changelog:
 	1.12.4:
 		- renamed gliko to glicko
 	1.12.3:
-		- removed depreciated code
+		- removed deprecated code
 	1.12.2:
 		- removed team first time trueskill instantiation in favor of integration in superscript.py
 	1.12.1:
@ -248,10 +250,10 @@ __changelog__ = """changelog:
 	1.0.0:
 		- removed c_entities,nc_entities,obstacles,objectives from __all__
 		- applied numba.jit to all functions
-		- depreciated and removed stdev_z_split
+		- deprecated and removed stdev_z_split
 		- cleaned up histo_analysis to include numpy and numba.jit optimizations
-		- depreciated and removed all regression functions in favor of future pytorch optimizer
+		- deprecated and removed all regression functions in favor of future pytorch optimizer
-		- depreciated and removed all nonessential functions (basic_analysis, benchmark, strip_data)
+		- deprecated and removed all nonessential functions (basic_analysis, benchmark, strip_data)
 		- optimized z_normalize using sklearn.preprocessing.normalize
 		- TODO: implement kernel/function based pytorch regression optimizer
 	0.9.0:
@ -270,8 +272,8 @@ __changelog__ = """changelog:
 		- refactors
 		- bugfixes
 	0.8.0:
-		- depreciated histo_analysis_old
+		- deprecated histo_analysis_old
-		- depreciated debug
+		- deprecated debug
 		- altered basic_analysis to take array data instead of filepath
 		- refactor
 		- optimization
@ -319,7 +321,7 @@ __changelog__ = """changelog:
 	0.3.5:
 		- major bug fixes
 		- updated historical analysis
-		- depreciated old historical analysis
+		- deprecated old historical analysis
 	0.3.4:
 		- added __version__, __author__, __all__
 		- added polynomial regression
--- a/analysis-master/tra_analysis/Array.py
+++ b/analysis-master/tra_analysis/Array.py
@ -4,9 +4,11 @@
 #    this should be imported as a python module using 'from tra_analysis import Array'
 # setup:
-__version__ = "1.0.3"
+__version__ = "1.0.4"
 __changelog__ = """changelog:
 	1.0.4:
 		- fixed spelling of deprecate
 	1.0.3:
 		- fixed __all__
 	1.0.2:
@ -135,8 +137,8 @@ class Array(): # tests on nd arrays independent of basic_stats
 		return Array(np.transpose(self.array))
-	def sort(self, array): # depreciated
+	def sort(self, array): # deprecated
-		warnings.warn("Array.sort has been depreciated in favor of Sort")
+		warnings.warn("Array.sort has been deprecated in favor of Sort")
 		array_length = len(array)
 		if array_length <= 1:
 			return array
--- a/analysis-master/tra_analysis/CorrelationTest_obj.py
+++ b/analysis-master/tra_analysis/CorrelationTest_obj.py
@ -1,41 +0,0 @@
 # Only included for backwards compatibility! Do not update, CorrelationTest is preferred and supported.
 import scipy
 from scipy import stats
 class CorrelationTest:
 	def anova_oneway(self, *args): #expects arrays of samples
 		results = scipy.stats.f_oneway(*args)
 		return {"f-value": results[0], "p-value": results[1]}
 	def pearson(self, x, y):
 		results = scipy.stats.pearsonr(x, y)
 		return {"r-value": results[0], "p-value": results[1]}
 	def spearman(self, a, b = None, axis = 0, nan_policy = 'propagate'):
 		results = scipy.stats.spearmanr(a, b = b, axis = axis, nan_policy = nan_policy)
 		return {"r-value": results[0], "p-value": results[1]}
 	def point_biserial(self, x,y):
 		results = scipy.stats.pointbiserialr(x, y)
 		return {"r-value": results[0], "p-value": results[1]}
 	def kendall(self, x, y, initial_lexsort = None, nan_policy = 'propagate', method = 'auto'):
 		results = scipy.stats.kendalltau(x, y, initial_lexsort = initial_lexsort, nan_policy = nan_policy, method = method)
 		return {"tau": results[0], "p-value": results[1]}
 	def kendall_weighted(self, x, y, rank = True, weigher = None, additive = True):
 		results = scipy.stats.weightedtau(x, y, rank = rank, weigher = weigher, additive = additive)
 		return {"tau": results[0], "p-value": results[1]}
 	def mgc(self, x, y, compute_distance = None, reps = 1000, workers = 1, is_twosamp = False, random_state = None):
 		results = scipy.stats.multiscale_graphcorr(x, y, compute_distance = compute_distance, reps = reps, workers = workers, is_twosamp = is_twosamp, random_state = random_state)
 		return {"k-value": results[0], "p-value": results[1], "data": results[2]} # unsure if MGC test returns a k value
--- a/analysis-master/tra_analysis/KNN_obj.py
+++ b/analysis-master/tra_analysis/KNN_obj.py
@ -1,25 +0,0 @@
 # Only included for backwards compatibility! Do not update, NaiveBayes is preferred and supported.
 import sklearn
 from sklearn import model_selection, neighbors
 from . import ClassificationMetric, RegressionMetric
 class KNN:
 	def knn_classifier(self, data, labels, n_neighbors, test_size = 0.3, algorithm='auto', leaf_size=30, metric='minkowski', metric_params=None, n_jobs=None, p=2, weights='uniform'): #expects *2d data and 1d labels post-scaling
 		data_train, data_test, labels_train, labels_test = sklearn.model_selection.train_test_split(data, labels, test_size=test_size, random_state=1)
 		model = sklearn.neighbors.KNeighborsClassifier()
 		model.fit(data_train, labels_train)
 		predictions = model.predict(data_test)
 		return model, ClassificationMetric(predictions, labels_test)
 	def knn_regressor(self, data, outputs, n_neighbors, test_size = 0.3, weights = "uniform", algorithm = "auto", leaf_size = 30, p = 2, metric = "minkowski", metric_params = None, n_jobs = None):
 		data_train, data_test, outputs_train, outputs_test = sklearn.model_selection.train_test_split(data, outputs, test_size=test_size, random_state=1)
 		model = sklearn.neighbors.KNeighborsRegressor(n_neighbors = n_neighbors, weights = weights, algorithm = algorithm, leaf_size = leaf_size, p = p, metric = metric, metric_params = metric_params, n_jobs = n_jobs)
 		model.fit(data_train, outputs_train)
 		predictions = model.predict(data_test)
 		return model, RegressionMetric(predictions, outputs_test)
--- a/analysis-master/tra_analysis/NaiveBayes_obj.py
+++ b/analysis-master/tra_analysis/NaiveBayes_obj.py
@ -1,43 +0,0 @@
 # Only included for backwards compatibility! Do not update, NaiveBayes is preferred and supported.
 import sklearn
 from sklearn import model_selection, naive_bayes
 from . import ClassificationMetric, RegressionMetric
 class NaiveBayes:
 	def guassian(self, data, labels, test_size = 0.3, priors = None, var_smoothing = 1e-09):
 		data_train, data_test, labels_train, labels_test = sklearn.model_selection.train_test_split(data, labels, test_size=test_size, random_state=1)
 		model = sklearn.naive_bayes.GaussianNB(priors = priors, var_smoothing = var_smoothing)
 		model.fit(data_train, labels_train)
 		predictions = model.predict(data_test)
 		return model, ClassificationMetric(predictions, labels_test)
 	def multinomial(self, data, labels, test_size = 0.3, alpha=1.0, fit_prior=True, class_prior=None):
 		data_train, data_test, labels_train, labels_test = sklearn.model_selection.train_test_split(data, labels, test_size=test_size, random_state=1)
 		model = sklearn.naive_bayes.MultinomialNB(alpha = alpha, fit_prior = fit_prior, class_prior = class_prior)
 		model.fit(data_train, labels_train)
 		predictions = model.predict(data_test)
 		return model, ClassificationMetric(predictions, labels_test)
 	def bernoulli(self, data, labels, test_size = 0.3, alpha=1.0, binarize=0.0, fit_prior=True, class_prior=None):
 		data_train, data_test, labels_train, labels_test = sklearn.model_selection.train_test_split(data, labels, test_size=test_size, random_state=1)
 		model = sklearn.naive_bayes.BernoulliNB(alpha = alpha, binarize = binarize, fit_prior = fit_prior, class_prior = class_prior)
 		model.fit(data_train, labels_train)
 		predictions = model.predict(data_test)
 		return model, ClassificationMetric(predictions, labels_test)
 	def complement(self, data, labels, test_size = 0.3, alpha=1.0, fit_prior=True, class_prior=None, norm=False):
 		data_train, data_test, labels_train, labels_test = sklearn.model_selection.train_test_split(data, labels, test_size=test_size, random_state=1)
 		model = sklearn.naive_bayes.ComplementNB(alpha = alpha, fit_prior = fit_prior, class_prior = class_prior, norm = norm)
 		model.fit(data_train, labels_train)
 		predictions = model.predict(data_test)
 		return model, ClassificationMetric(predictions, labels_test)
--- a/analysis-master/tra_analysis/RandomForest_obj.py
+++ b/analysis-master/tra_analysis/RandomForest_obj.py
@ -1,25 +0,0 @@
 # Only included for backwards compatibility! Do not update, RandomForest is preferred and supported.
 import sklearn
 from sklearn import ensemble, model_selection
 from . import ClassificationMetric, RegressionMetric
 class RandomForest:
 	def random_forest_classifier(self, data, labels, test_size, n_estimators, criterion="gini", max_depth=None, min_samples_split=2, min_samples_leaf=1, min_weight_fraction_leaf=0.0, max_features="auto", max_leaf_nodes=None, min_impurity_decrease=0.0, min_impurity_split=None, bootstrap=True, oob_score=False, n_jobs=None, random_state=None, verbose=0, warm_start=False, class_weight=None):
 		data_train, data_test, labels_train, labels_test = sklearn.model_selection.train_test_split(data, labels, test_size=test_size, random_state=1)
 		kernel = sklearn.ensemble.RandomForestClassifier(n_estimators = n_estimators, criterion = criterion, max_depth = max_depth, min_samples_split = min_samples_split, min_samples_leaf = min_samples_leaf, min_weight_fraction_leaf = min_weight_fraction_leaf, max_leaf_nodes = max_leaf_nodes, min_impurity_decrease = min_impurity_decrease, bootstrap = bootstrap, oob_score = oob_score, n_jobs = n_jobs, random_state = random_state, verbose = verbose, warm_start = warm_start, class_weight = class_weight)
 		kernel.fit(data_train, labels_train)
 		predictions = kernel.predict(data_test)
 		return kernel, ClassificationMetric(predictions, labels_test)
 	def random_forest_regressor(self, data, outputs, test_size, n_estimators, criterion="mse", max_depth=None, min_samples_split=2, min_samples_leaf=1, min_weight_fraction_leaf=0.0, max_features="auto", max_leaf_nodes=None, min_impurity_decrease=0.0, min_impurity_split=None, bootstrap=True, oob_score=False, n_jobs=None, random_state=None, verbose=0, warm_start=False):
 		data_train, data_test, outputs_train, outputs_test = sklearn.model_selection.train_test_split(data, outputs, test_size=test_size, random_state=1)
 		kernel = sklearn.ensemble.RandomForestRegressor(n_estimators = n_estimators, criterion = criterion, max_depth = max_depth, min_samples_split = min_samples_split, min_weight_fraction_leaf = min_weight_fraction_leaf, max_features = max_features, max_leaf_nodes = max_leaf_nodes, min_impurity_decrease = min_impurity_decrease, min_impurity_split = min_impurity_split, bootstrap = bootstrap, oob_score = oob_score, n_jobs = n_jobs, random_state = random_state, verbose = verbose, warm_start = warm_start)
 		kernel.fit(data_train, outputs_train)
 		predictions = kernel.predict(data_test)
 		return kernel, RegressionMetric(predictions, outputs_test)
--- a/analysis-master/tra_analysis/Sort_obj.py
+++ b/analysis-master/tra_analysis/Sort_obj.py
@ -1,391 +0,0 @@
 # Only included for backwards compatibility! Do not update, Sort is preferred and supported.
 class Sort: # if you haven't used a sort, then you've never lived
 	def quicksort(self, a):
 		def sort(array):
 			less = []
 			equal = []
 			greater = []
 			if len(array) > 1:
 				pivot = array[0]
 				for x in array:
 					if x < pivot:
 						less.append(x)
 					elif x == pivot:
 						equal.append(x)
 					elif x > pivot:
 						greater.append(x)
 				return sort(less)+equal+sort(greater) 
 			else:
 				return array
 		return np.array(sort(a))
 	def mergesort(self, a):
 		def sort(array):
 			array = array
 			if len(array) >1: 
 				middle = len(array) // 2
 				L = array[:middle]
 				R = array[middle:]
 				sort(L)
 				sort(R)
 				i = j = k = 0
 				while i < len(L) and j < len(R): 
 					if L[i] < R[j]: 
 						array[k] = L[i] 
 						i+= 1
 					else: 
 						array[k] = R[j] 
 						j+= 1
 					k+= 1
 				while i < len(L): 
 					array[k] = L[i] 
 					i+= 1
 					k+= 1
 				while j < len(R): 
 					array[k] = R[j] 
 					j+= 1
 					k+= 1
 				return array
 		return sort(a)
 	def introsort(self, a):
 		def sort(array, start, end, maxdepth):
 			array = array
 			if end - start <= 1:
 				return
 			elif maxdepth == 0:
 				heapsort(array, start, end)
 			else:
 				p = partition(array, start, end)
 				sort(array, start, p + 1, maxdepth - 1)
 				sort(array, p + 1, end, maxdepth - 1)
 			return array
 		def partition(array, start, end):
 			pivot = array[start]
 			i = start - 1
 			j = end
 			while True:
 				i = i + 1
 				while array[i] < pivot:
 					i = i + 1
 				j = j - 1
 				while array[j] > pivot:
 					j = j - 1
 				if i >= j:
 					return j
 				swap(array, i, j)
 		def swap(array, i, j):
 			array[i], array[j] = array[j], array[i]
 		def heapsort(array, start, end):
 			build_max_heap(array, start, end)
 			for i in range(end - 1, start, -1):
 				swap(array, start, i)
 				max_heapify(array, index=0, start=start, end=i)
 		def build_max_heap(array, start, end):
 			def parent(i):
 				return (i - 1)//2
 			length = end - start
 			index = parent(length - 1)
 			while index >= 0:
 				max_heapify(array, index, start, end)
 				index = index - 1
 		def max_heapify(array, index, start, end):
 			def left(i):
 				return 2*i + 1
 			def right(i):
 				return 2*i + 2
 			size = end - start
 			l = left(index)
 			r = right(index)
 			if (l < size and array[start + l] > array[start + index]):
 				largest = l
 			else:
 				largest = index
 			if (r < size and array[start + r] > array[start + largest]):
 				largest = r
 			if largest != index:
 				swap(array, start + largest, start + index)
 				max_heapify(array, largest, start, end)
 		maxdepth = (len(a).bit_length() - 1)*2
 		return sort(a, 0, len(a), maxdepth)
 	def heapsort(self, a):
 		def sort(array):
 			array = array
 			n = len(array) 
 			for i in range(n//2 - 1, -1, -1): 
 				heapify(array, n, i) 
 			for i in range(n-1, 0, -1): 
 				array[i], array[0] = array[0], array[i]
 				heapify(array, i, 0) 
 			return array
 		def heapify(array, n, i):
 			array = array
 			largest = i
 			l = 2 * i + 1
 			r = 2 * i + 2
 			if l < n and array[i] < array[l]: 
 				largest = l 
 			if r < n and array[largest] < array[r]: 
 				largest = r 
 			if largest != i: 
 				array[i],array[largest] = array[largest],array[i]
 				heapify(array, n, largest)
 			return array
 		return sort(a)
 	def insertionsort(self, a):
 		def sort(array):
 			array = array
 			for i in range(1, len(array)): 
 				key = array[i] 
 				j = i-1
 				while j >=0 and key < array[j] : 
 						array[j+1] = array[j] 
 						j -= 1
 				array[j+1] = key 
 			return array
 		return sort(a)
 	def timsort(self, a, block = 32):
 		BLOCK = block
 		def sort(array, n):
 			array = array
 			for i in range(0, n, BLOCK):  
 				insertionsort(array, i, min((i+31), (n-1)))
 			size = BLOCK 
 			while size < n:
 				for left in range(0, n, 2*size):  
 					mid = left + size - 1 
 					right = min((left + 2*size - 1), (n-1))  
 					merge(array, left, mid, right)  
 				size = 2*size
 			return array
 		def insertionsort(array, left, right):
 			array = array 
 			for i in range(left + 1, right+1):  
 				temp = array[i]  
 				j = i - 1 
 				while j >= left and array[j] > temp :  
 					array[j+1] = array[j]  
 					j -= 1
 				array[j+1] = temp
 			return array
 		def merge(array, l, m, r): 
 			len1, len2 =  m - l + 1, r - m  
 			left, right = [], []  
 			for i in range(0, len1):  
 				left.append(array[l + i])  
 			for i in range(0, len2):  
 				right.append(array[m + 1 + i])  
 			i, j, k = 0, 0, l 
 			while i < len1 and j < len2:  
 				if left[i] <= right[j]:  
 					array[k] = left[i]  
 					i += 1 
 				else: 
 					array[k] = right[j]  
 					j += 1 
 				k += 1
 			while i < len1:  
 				array[k] = left[i]  
 				k += 1 
 				i += 1
 			while j < len2:  
 				array[k] = right[j]  
 				k += 1
 				j += 1
 		return sort(a, len(a))
 	def selectionsort(self, a):
 		array = a
 		for i in range(len(array)): 
 			min_idx = i
 			for j in range(i+1, len(array)): 
 				if array[min_idx] > array[j]: 
 					min_idx = j         
 			array[i], array[min_idx] = array[min_idx], array[i]
 		return array
 	def shellsort(self, a):
 		array = a
 		n = len(array)
 		gap = n//2
 		while gap > 0: 
 			for i in range(gap,n): 
 				temp = array[i] 
 				j = i 
 				while  j >= gap and array[j-gap] >temp: 
 					array[j] = array[j-gap] 
 					j -= gap 
 				array[j] = temp 
 			gap //= 2
 		return array
 	def bubblesort(self, a):
 		def sort(array):
 			for i, num in enumerate(array):
 				try:
 					if array[i+1] < num:
 						array[i] = array[i+1]
 						array[i+1] = num
 						sort(array)
 				except IndexError:
 					pass
 			return array
 		return sort(a)
 	def cyclesort(self, a):
 		def sort(array):
 			array = array
 			writes = 0
 			for cycleStart in range(0, len(array) - 1): 
 				item = array[cycleStart] 
 				pos = cycleStart 
 				for i in range(cycleStart + 1, len(array)): 
 					if array[i] < item: 
 						pos += 1
 				if pos == cycleStart: 
 					continue
 				while item == array[pos]: 
 					pos += 1
 					array[pos], item = item, array[pos] 
 					writes += 1
 				while pos != cycleStart: 
 					pos = cycleStart 
 					for i in range(cycleStart + 1, len(array)): 
 						if array[i] < item: 
 							pos += 1
 					while item == array[pos]: 
 						pos += 1
 					array[pos], item = item, array[pos] 
 					writes += 1
 			return array
 		return sort(a)
 	def cocktailsort(self, a):
 		def sort(array):
 			array = array
 			n = len(array) 
 			swapped = True
 			start = 0
 			end = n-1
 			while (swapped == True): 
 				swapped = False
 				for i in range (start, end): 
 					if (array[i] > array[i + 1]) : 
 						array[i], array[i + 1]= array[i + 1], array[i] 
 						swapped = True
 				if (swapped == False): 
 					break
 				swapped = False
 				end = end-1
 				for i in range(end-1, start-1, -1): 
 					if (array[i] > array[i + 1]): 
 						array[i], array[i + 1] = array[i + 1], array[i] 
 						swapped = True
 				start = start + 1
 			return array
 		return sort(a)
--- a/analysis-master/tra_analysis/StatisticalTest_obj.py
+++ b/analysis-master/tra_analysis/StatisticalTest_obj.py
@ -1,170 +0,0 @@
 # Only included for backwards compatibility! Do not update, StatisticalTest is preferred and supported.
 import scipy
 from scipy import stats
 class StatisticalTest:
 	def ttest_onesample(self, a, popmean, axis = 0, nan_policy = 'propagate'):
 		results = scipy.stats.ttest_1samp(a, popmean, axis = axis, nan_policy = nan_policy)
 		return {"t-value": results[0], "p-value": results[1]}
 	def ttest_independent(self, a, b, equal = True, nan_policy = 'propagate'):
 		results = scipy.stats.ttest_ind(a, b, equal_var = equal, nan_policy = nan_policy)
 		return {"t-value": results[0], "p-value": results[1]}
 	def ttest_statistic(self, o1, o2, equal = True):
 		results = scipy.stats.ttest_ind_from_stats(o1["mean"], o1["std"], o1["nobs"], o2["mean"], o2["std"], o2["nobs"], equal_var = equal)
 		return {"t-value": results[0], "p-value": results[1]}
 	def ttest_related(self, a, b, axis = 0, nan_policy='propagate'):
 		results = scipy.stats.ttest_rel(a, b, axis = axis, nan_policy = nan_policy)
 		return {"t-value": results[0], "p-value": results[1]}
 	def ks_fitness(self, rvs, cdf, args = (), N = 20, alternative = 'two-sided', mode = 'approx'):
 		results = scipy.stats.kstest(rvs, cdf, args = args, N = N, alternative = alternative, mode = mode)
 		return {"ks-value": results[0], "p-value": results[1]}
 	def chisquare(self, f_obs, f_exp = None, ddof = None, axis = 0):
 		results = scipy.stats.chisquare(f_obs, f_exp = f_exp, ddof = ddof, axis = axis)
 		return {"chisquared-value": results[0], "p-value": results[1]}
 	def powerdivergence(self, f_obs, f_exp = None, ddof = None, axis = 0, lambda_ = None):
 		results = scipy.stats.power_divergence(f_obs, f_exp = f_exp, ddof = ddof, axis = axis, lambda_ = lambda_)
 		return {"powerdivergence-value": results[0], "p-value": results[1]}
 	def ks_twosample(self, x, y, alternative = 'two_sided', mode = 'auto'):
 		results = scipy.stats.ks_2samp(x, y, alternative = alternative, mode = mode)
 		return {"ks-value": results[0], "p-value": results[1]}
 	def es_twosample(self, x, y, t = (0.4, 0.8)):
 		results = scipy.stats.epps_singleton_2samp(x, y, t = t)
 		return {"es-value": results[0], "p-value": results[1]}
 	def mw_rank(self, x, y, use_continuity = True, alternative = None):
 		results = scipy.stats.mannwhitneyu(x, y, use_continuity = use_continuity, alternative = alternative)
 		return {"u-value": results[0], "p-value": results[1]}
 	def mw_tiecorrection(self, rank_values):
 		results = scipy.stats.tiecorrect(rank_values)
 		return {"correction-factor": results}
 	def rankdata(self, a, method = 'average'):
 		results = scipy.stats.rankdata(a, method = method)
 		return results
 	def wilcoxon_ranksum(self, a, b): # this seems to be superceded by Mann Whitney Wilcoxon U Test
 		results = scipy.stats.ranksums(a, b)
 		return {"u-value": results[0], "p-value": results[1]}
 	def wilcoxon_signedrank(self, x, y = None, zero_method = 'wilcox', correction = False, alternative = 'two-sided'):
 		results = scipy.stats.wilcoxon(x, y = y, zero_method = zero_method, correction = correction, alternative = alternative)
 		return {"t-value": results[0], "p-value": results[1]}
 	def kw_htest(self, *args, nan_policy = 'propagate'):
 		results = scipy.stats.kruskal(*args, nan_policy = nan_policy)
 		return {"h-value": results[0], "p-value": results[1]}
 	def friedman_chisquare(self, *args):
 		results = scipy.stats.friedmanchisquare(*args)
 		return {"chisquared-value": results[0], "p-value": results[1]}
 	def bm_wtest(self, x, y, alternative = 'two-sided', distribution = 't', nan_policy = 'propagate'):
 		results = scipy.stats.brunnermunzel(x, y, alternative = alternative, distribution = distribution, nan_policy = nan_policy)
 		return {"w-value": results[0], "p-value": results[1]}
 	def combine_pvalues(self, pvalues, method = 'fisher', weights = None):
 		results = scipy.stats.combine_pvalues(pvalues, method = method, weights = weights)
 		return {"combined-statistic": results[0], "p-value": results[1]}
 	def jb_fitness(self, x):
 		results = scipy.stats.jarque_bera(x)
 		return {"jb-value": results[0], "p-value": results[1]}
 	def ab_equality(self, x, y):
 		results = scipy.stats.ansari(x, y)
 		return {"ab-value": results[0], "p-value": results[1]}
 	def bartlett_variance(self, *args):
 		results = scipy.stats.bartlett(*args)
 		return {"t-value": results[0], "p-value": results[1]}
 	def levene_variance(self, *args, center = 'median', proportiontocut = 0.05):
 		results = scipy.stats.levene(*args, center = center, proportiontocut = proportiontocut)
 		return {"w-value": results[0], "p-value": results[1]}
 	def sw_normality(self, x):
 		results = scipy.stats.shapiro(x)
 		return {"w-value": results[0], "p-value": results[1]}
 	def shapiro(self, x):
 		return "destroyed by facts and logic"
 	def ad_onesample(self, x, dist = 'norm'):
 		results = scipy.stats.anderson(x, dist = dist)
 		return {"d-value": results[0], "critical-values": results[1], "significance-value": results[2]}
 	def ad_ksample(self, samples, midrank = True):
 		results = scipy.stats.anderson_ksamp(samples, midrank = midrank)
 		return {"d-value": results[0], "critical-values": results[1], "significance-value": results[2]}
 	def binomial(self, x, n = None, p = 0.5, alternative = 'two-sided'):
 		results = scipy.stats.binom_test(x, n = n, p = p, alternative = alternative)
 		return {"p-value": results}
 	def fk_variance(self, *args, center = 'median', proportiontocut = 0.05):
 		results = scipy.stats.fligner(*args, center = center, proportiontocut = proportiontocut)
 		return {"h-value": results[0], "p-value": results[1]} # unknown if the statistic is an h value
 	def mood_mediantest(self, *args, ties = 'below', correction = True, lambda_ = 1, nan_policy = 'propagate'):
 		results = scipy.stats.median_test(*args, ties = ties, correction = correction, lambda_ = lambda_, nan_policy = nan_policy)
 		return {"chisquared-value": results[0], "p-value": results[1], "m-value": results[2], "table": results[3]}
 	def mood_equalscale(self, x, y, axis = 0):
 		results = scipy.stats.mood(x, y, axis = axis)
 		return {"z-score": results[0], "p-value": results[1]}
 	def skewtest(self, a, axis = 0, nan_policy = 'propogate'):
 		results = scipy.stats.skewtest(a, axis = axis, nan_policy = nan_policy)
 		return {"z-score": results[0], "p-value": results[1]}
 	def kurtosistest(self, a, axis = 0, nan_policy = 'propogate'):
 		results = scipy.stats.kurtosistest(a, axis = axis, nan_policy = nan_policy)
 		return {"z-score": results[0], "p-value": results[1]}
 	def normaltest(self, a, axis = 0, nan_policy = 'propogate'):
 		results = scipy.stats.normaltest(a, axis = axis, nan_policy = nan_policy)
 		return {"z-score": results[0], "p-value": results[1]}
--- a/analysis-master/tra_analysis/init.py
+++ b/analysis-master/tra_analysis/init.py
@ -7,10 +7,14 @@
 #    current benchmark of optimization: 1.33 times faster
 # setup:
-__version__ = "3.0.0"
+__version__ = "4.0.0-dev"
 # changelog should be viewed using print(analysis.__changelog__)
 __changelog__ = """changelog:
 	4.0.0:
 		- deprecated all *_obj.py compatibility modules
 		- deprecated titanlearn.py
 		- deprecated visualization.py
 	3.0.0:
 		- incremented version to release 3.0.0
 	3.0.0-rc2:
@ -53,7 +57,6 @@ __all__ = [
 ]
 from . import Analysis as Analysis
 from . import Analysis as analysis
 from .Array import Array
 from .ClassificationMetric import ClassificationMetric
 from . import CorrelationTest
--- a/analysis-master/tra_analysis/regression_old.py
+++ b/analysis-master/tra_analysis/regression_old.py
@ -1,222 +0,0 @@
 # Titan Robotics Team 2022: CUDA-based Regressions Module
 # Not actively maintained, may be removed in future release
 # Written by Arthur Lu & Jacob Levine
 # Notes:
 #   this module has been automatically inegrated into analysis.py, and should be callable as a class from the package
 #   this module is cuda-optimized (as appropriate) and vectorized (except for one small part)
 # setup:
 __version__ = "0.0.4"
 # changelog should be viewed using print(analysis.regression.__changelog__)
 __changelog__ = """
 	0.0.4:
 		- bug fixes
 		- fixed changelog
 	0.0.3:
 		- bug fixes
 	0.0.2:
 		-Added more parameters to log, exponential, polynomial
 		-Added SigmoidalRegKernelArthur, because Arthur apparently needs
 		to train the scaling and shifting of sigmoids
 	0.0.1:
 		-initial release, with linear, log, exponential, polynomial, and sigmoid kernels
 		-already vectorized (except for polynomial generation) and CUDA-optimized
 """
 __author__ = (
 	"Jacob Levine <jlevine@imsa.edu>",
 	"Arthur Lu <learthurgo@gmail.com>",
 )
 __all__ = [
 	'factorial',
 	'take_all_pwrs',
 	'num_poly_terms',
 	'set_device',
 	'LinearRegKernel',
 	'SigmoidalRegKernel',
 	'LogRegKernel',
 	'PolyRegKernel',
 	'ExpRegKernel',
 	'SigmoidalRegKernelArthur',
 	'SGDTrain',
 	'CustomTrain',
 	'CircleFit'
 ]
 import torch
 global device
 device = "cuda:0" if torch.cuda.is_available() else "cpu"
 #todo: document completely
 def set_device(self, new_device):
 	device=new_device
 class LinearRegKernel():
 	parameters= []
 	weights=None
 	bias=None
 	def __init__(self, num_vars):
 		self.weights=torch.rand(num_vars, requires_grad=True, device=device)
 		self.bias=torch.rand(1, requires_grad=True, device=device)
 		self.parameters=[self.weights,self.bias]
 	def forward(self,mtx):
 		long_bias=self.bias.repeat([1,mtx.size()[1]])
 		return torch.matmul(self.weights,mtx)+long_bias
 class SigmoidalRegKernel():
 	parameters= []
 	weights=None
 	bias=None
 	sigmoid=torch.nn.Sigmoid()
 	def __init__(self, num_vars):
 		self.weights=torch.rand(num_vars, requires_grad=True, device=device)
 		self.bias=torch.rand(1, requires_grad=True, device=device)
 		self.parameters=[self.weights,self.bias]
 	def forward(self,mtx):
 		long_bias=self.bias.repeat([1,mtx.size()[1]])
 		return self.sigmoid(torch.matmul(self.weights,mtx)+long_bias)
 class SigmoidalRegKernelArthur():
 	parameters= []
 	weights=None
 	in_bias=None
 	scal_mult=None
 	out_bias=None
 	sigmoid=torch.nn.Sigmoid()
 	def __init__(self, num_vars):
 		self.weights=torch.rand(num_vars, requires_grad=True, device=device)
 		self.in_bias=torch.rand(1, requires_grad=True, device=device)
 		self.scal_mult=torch.rand(1, requires_grad=True, device=device)
 		self.out_bias=torch.rand(1, requires_grad=True, device=device)
 		self.parameters=[self.weights,self.in_bias, self.scal_mult, self.out_bias]
 	def forward(self,mtx):
 		long_in_bias=self.in_bias.repeat([1,mtx.size()[1]])
 		long_out_bias=self.out_bias.repeat([1,mtx.size()[1]])
 		return (self.scal_mult*self.sigmoid(torch.matmul(self.weights,mtx)+long_in_bias))+long_out_bias
 class LogRegKernel():
 	parameters= []
 	weights=None
 	in_bias=None
 	scal_mult=None
 	out_bias=None
 	def __init__(self, num_vars):
 		self.weights=torch.rand(num_vars, requires_grad=True, device=device)
 		self.in_bias=torch.rand(1, requires_grad=True, device=device)
 		self.scal_mult=torch.rand(1, requires_grad=True, device=device)
 		self.out_bias=torch.rand(1, requires_grad=True, device=device)
 		self.parameters=[self.weights,self.in_bias, self.scal_mult, self.out_bias]
 	def forward(self,mtx):
 		long_in_bias=self.in_bias.repeat([1,mtx.size()[1]])
 		long_out_bias=self.out_bias.repeat([1,mtx.size()[1]])
 		return (self.scal_mult*torch.log(torch.matmul(self.weights,mtx)+long_in_bias))+long_out_bias
 class ExpRegKernel():
 	parameters= []
 	weights=None
 	in_bias=None
 	scal_mult=None
 	out_bias=None
 	def __init__(self, num_vars):
 		self.weights=torch.rand(num_vars, requires_grad=True, device=device)
 		self.in_bias=torch.rand(1, requires_grad=True, device=device)
 		self.scal_mult=torch.rand(1, requires_grad=True, device=device)
 		self.out_bias=torch.rand(1, requires_grad=True, device=device)
 		self.parameters=[self.weights,self.in_bias, self.scal_mult, self.out_bias]
 	def forward(self,mtx):
 		long_in_bias=self.in_bias.repeat([1,mtx.size()[1]])
 		long_out_bias=self.out_bias.repeat([1,mtx.size()[1]])
 		return (self.scal_mult*torch.exp(torch.matmul(self.weights,mtx)+long_in_bias))+long_out_bias
 class PolyRegKernel():
 	parameters= []
 	weights=None
 	bias=None
 	power=None
 	def __init__(self, num_vars, power):
 		self.power=power
 		num_terms=self.num_poly_terms(num_vars, power)
 		self.weights=torch.rand(num_terms, requires_grad=True, device=device)
 		self.bias=torch.rand(1, requires_grad=True, device=device)
 		self.parameters=[self.weights,self.bias]
 	def num_poly_terms(self,num_vars, power):
 		if power == 0:
 			return 0
 		return int(self.factorial(num_vars+power-1) / self.factorial(power) / self.factorial(num_vars-1)) + self.num_poly_terms(num_vars, power-1)
 	def factorial(self,n):
 		if n==0:
 			return 1
 		else:
 			return n*self.factorial(n-1)
 	def take_all_pwrs(self, vec, pwr):
 		#todo: vectorize (kinda)
 		combins=torch.combinations(vec, r=pwr, with_replacement=True)
 		out=torch.ones(combins.size()[0]).to(device).to(torch.float)
 		for i in torch.t(combins).to(device).to(torch.float):
 			out *= i
 		if pwr == 1:
 			return out
 		else:
 			return torch.cat((out,self.take_all_pwrs(vec, pwr-1)))
 	def forward(self,mtx):
 		#TODO: Vectorize the last part
 		cols=[]
 		for i in torch.t(mtx):
 			cols.append(self.take_all_pwrs(i,self.power))
 		new_mtx=torch.t(torch.stack(cols))
 		long_bias=self.bias.repeat([1,mtx.size()[1]])
 		return torch.matmul(self.weights,new_mtx)+long_bias
 def SGDTrain(self, kernel, data, ground, loss=torch.nn.MSELoss(), iterations=1000, learning_rate=.1, return_losses=False):
 	optim=torch.optim.SGD(kernel.parameters, lr=learning_rate)
 	data_cuda=data.to(device)
 	ground_cuda=ground.to(device)
 	if (return_losses):
 		losses=[]
 		for i in range(iterations):
 			with torch.set_grad_enabled(True):
 				optim.zero_grad()
 				pred=kernel.forward(data_cuda)
 				ls=loss(pred,ground_cuda)
 				losses.append(ls.item())
 				ls.backward()
 				optim.step()
 		return [kernel,losses]
 	else:
 		for i in range(iterations):
 			with torch.set_grad_enabled(True):
 				optim.zero_grad()
 				pred=kernel.forward(data_cuda)
 				ls=loss(pred,ground_cuda)
 				ls.backward()
 				optim.step()
 		return kernel
 def CustomTrain(self, kernel, optim, data, ground, loss=torch.nn.MSELoss(), iterations=1000, return_losses=False):
 	data_cuda=data.to(device)
 	ground_cuda=ground.to(device)
 	if (return_losses):
 		losses=[]
 		for i in range(iterations):
 			with torch.set_grad_enabled(True):
 				optim.zero_grad()
 				pred=kernel.forward(data)
 				ls=loss(pred,ground)
 				losses.append(ls.item())
 				ls.backward()
 				optim.step()
 		return [kernel,losses]
 	else:
 		for i in range(iterations):
 			with torch.set_grad_enabled(True):
 				optim.zero_grad()
 				pred=kernel.forward(data_cuda)
 				ls=loss(pred,ground_cuda)
 				ls.backward()
 				optim.step()
 		return kernel
--- a/analysis-master/tra_analysis/titanlearn.py
+++ b/analysis-master/tra_analysis/titanlearn.py
@ -1,122 +0,0 @@
 # Titan Robotics Team 2022: ML Module
 # Written by Arthur Lu & Jacob Levine
 # Notes:
 #    this should be imported as a python module using 'import titanlearn'
 #    this should be included in the local directory or environment variable
 #    this module is optimized for multhreaded computing
 #    this module learns from its mistakes far faster than 2022's captains
 # setup:
 __version__ = "1.1.1"
 #changelog should be viewed using print(analysis.__changelog__)
 __changelog__ = """changelog:
 	1.1.1:
 		- removed matplotlib import
 		- removed graphloss()
 	1.1.0:
 		- added net, dataset, dataloader, and stdtrain template definitions
 		- added graphloss function
 	1.0.1:
 		- added clear functions
 	1.0.0:
 		- complete rewrite planned
 		- depreciated 1.0.0.xxx versions
 		- added simple training loop
 	0.0.x:
 		-added generation of ANNS, basic SGD training
 """
 __author__ = (
 	"Arthur Lu <arthurlu@ttic.edu>,"
 	"Jacob Levine <jlevine@ttic.edu>,"
 	)
 __all__ = [
 	'clear',
 	'net',
 	'dataset',
 	'dataloader',
 	'train',
 	'stdtrainer',
 	]
 import torch
 from os import system, name
 import numpy as np
 def clear(): 
 	if name == 'nt': 
 		_ = system('cls') 
 	else: 
 		_ = system('clear') 
 class net(torch.nn.Module): #template for standard neural net
 	def __init__(self):
 		super(Net, self).__init__()
 	def forward(self, input):
 		pass
 class dataset(torch.utils.data.Dataset): #template for standard dataset
 	def __init__(self):
 		super(torch.utils.data.Dataset).__init__()
 	def __getitem__(self, index):
 		pass
 	def __len__(self):
 		pass
 def dataloader(dataset, batch_size, num_workers, shuffle = True):
 	return torch.utils.data.DataLoader(dataset, batch_size=batch_size, shuffle=shuffle, num_workers=num_workers)
 def train(device, net, epochs, trainloader, optimizer, criterion): #expects standard dataloader, whch returns (inputs, labels)
 	dataset_len = trainloader.dataset.__len__()
 	iter_count = 0
 	running_loss = 0
 	running_loss_list = []
 	for epoch in range(epochs):  # loop over the dataset multiple times
 		for i, data in enumerate(trainloader, 0):
 			inputs = data[0].to(device)
 			labels = data[1].to(device)
 			optimizer.zero_grad()
 			outputs = net(inputs)
 			loss = criterion(outputs, labels.to(torch.float))
 			loss.backward()
 			optimizer.step()
 			# monitoring steps below
 			iter_count += 1
 			running_loss += loss.item()
 			running_loss_list.append(running_loss)
 			clear()
 			print("training on: " + device)
 			print("iteration: " + str(i) + "/" + str(int(dataset_len / trainloader.batch_size)) + " | " + "epoch: " + str(epoch) + "/" + str(epochs))
 			print("current batch loss: " + str(loss.item))
 			print("running loss: " + str(running_loss / iter_count))
 	return net, running_loss_list
 	print("finished training")
 def stdtrainer(net, criterion, optimizer, dataloader, epochs, batch_size):
 	device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
 	net = net.to(device)
 	criterion = criterion.to(device)
 	optimizer = optimizer.to(device)
 	trainloader = dataloader
 	return train(device, net, epochs, trainloader, optimizer, criterion)
--- a/analysis-master/tra_analysis/visualization.py
+++ b/analysis-master/tra_analysis/visualization.py
@ -1,58 +0,0 @@
 # Titan Robotics Team 2022: Visualization Module
 # Written by Arthur Lu & Jacob Levine
 # Notes:
 #    this should be imported as a python module using 'import visualization'
 #    this should be included in the local directory or environment variable
 #    fancy
 # setup:
 __version__ = "0.0.1"
 #changelog should be viewed using print(analysis.__changelog__)
 __changelog__ = """changelog:
 	0.0.1:
 		- added graphhistogram function as a fragment of visualize_pit.py
 	0.0.0:
 		- created visualization.py
 		- added graphloss()
 		- added imports
 """
 __author__ = (
 	"Arthur Lu <arthurlu@ttic.edu>,"
 	"Jacob Levine <jlevine@ttic.edu>,"
 	)
 __all__ = [
 	'graphloss',
 	]
 import matplotlib.pyplot as plt
 import numpy as np
 def graphloss(losses):
 	x = range(0, len(losses))
 	plt.plot(x, losses)
 	plt.show()
 def graphhistogram(data, figsize, sharey = True): # expects library with key as variable and contents as occurances
 	fig, ax = plt.subplots(1, len(data), sharey=sharey, figsize=figsize)
 	i = 0
 	for variable in data:
 		ax[i].hist(data[variable])
 		ax[i].invert_xaxis()
 		ax[i].set_xlabel('Variable')
 		ax[i].set_ylabel('Frequency')
 		ax[i].set_title(variable)
 		plt.yticks(np.arange(len(data[variable])))
 		i+=1
 	plt.show()