import numpy as np

a = np.array([[1,1,1],[2,2,2],[3,3,3]])

b = np.array([[4,4,4],[5,5,5],[6,6,6],[7,7,7]])

dists = np.zeros((3,4))

for i in range(3):

    for j in range(4):

        dists[i][j] = np.sqrt(np.sum(np.square(a[i] - b[j])))

print(dists)

dists=np.zeros((3,4))

for i in range(3):

    dists[i] = np.sqrt(np.sum(np.square(a[i] - b),axis=1))

print(dists)

r1=(np.sum(np.square(a),axis=1)*(np.ones((b.shape[0],1)))).T

r2=np.sum(np.square(b),axis=1)*(np.ones((a.shape[0],1)))

r3=-2*np.dot(a,b.T)

print(np.sqrt(r1+r2+r3))

import numpy as np

class KNearsNeighbor():

    def _init_(self):

        pass

    def train(self, x, y):

        self.X_train = x

        self.y_train = y

　　

    # 选择使用几个循环体的方式来计算距离

    def predict(self, X, k=1, num_loops=0):

        if num_loops == 0:

            dist = self.compute_distances_no_loops(X)

        elif num_loops == 1:

            dist = self.compute_distances_one_loops(X)

        elif num_loops == 2:

            dist = self.compute_distances_two_loops(X)

        else:

            raise ValueError('Invalid value %d' % num_loops)

        return dist

    def compute_distances_two_loops(self, X):

        num_test = X.shape[0]

        num_train = self.X_train.shape[0]

        dists = np.zeros((num_test, num_train))

        for i in range(num_test):

            for j in range(num_train):

                dists[i][j] = np.sqrt(np.sum(np.square(X[i] - self.X_train[j])))

        return dists

    def compute_distances_one_loops(self, X):

        num_test = X.shape[0]

        num_train = self.X_train.shape[0]

        dists = np.zeros((num_test,num_train))

        for i in range(num_test):

                dists[i] = np.sqrt(np.sum(np.square(X[i] - self.X_train), axis=1))

        return dists

    def compute_distances_no_loops(self, X):

        # num_test = X.shape[0]

        # num_train = self.X_train.shape[0]

        # dists = np.zeros((num_test,num_train))

        dists = np.sqrt(-2*np.dot(X, self.X_train.T) +

                        np.sum(np.square(self.X_train), axis=1)*(np.ones((X.shape[0],1))) +

                               np.sum(np.square(X), axis=1)*(np.ones(X_train.shape[0],1)).T)

        return dists

　　 # 预测标签

    def predict_labels(self, dists, k=1):

        num_test = dists.shape[0]

        y_pred = np.zeros(num_test)

        for i in range(num_test):

            closest_y = self.y_train[np.argsort(dists[i])[:k]]  # 【【【按照距离给索引排序】取最近的k个索引】按照索引取训练标签】

            y_pred[i] = np.argmax(np.bincount(closest_y))       #  投票，注意np.bincount()和np.argmax()在投票上的妙用

        return y_pred

import numpy as np

num_folds = 5

k_choices = [1, 3, 5, 8, 10, 12, 15, 20, 50, 100]

X_train_folds = []

y_train_folds = []

################################################################################

# TODO:                                                                        #

# Split up the training data into folds. After splitting, X_train_folds and    #

# y_train_folds should each be lists of length num_folds, where                #

# y_train_folds[i] is the label vector for the points in X_train_folds[i].     #

# Hint: Look up the numpy array_split function.                                #

################################################################################

X_train_folds = np.split(X_train, num_folds)

y_train_folds = np.split(y_train, num_folds)

################################################################################

#                                 END OF YOUR CODE                             #

################################################################################

# A dictionary holding the accuracies for different values of k that we find

# when running cross-validation. After running cross-validation,

# k_to_accuracies[k] should be a list of length num_folds giving the different

# accuracy values that we found when using that value of k.

k_to_accuracies = {}

################################################################################

# TODO:                                                                        #

# Perform k-fold cross validation to find the best value of k. For each        #

# possible value of k, run the k-nearest-neighbor algorithm num_folds times,   #

# where in each case you use all but one of the folds as training data and the #

# last fold as a validation set. Store the accuracies for all fold and all     #

# values of k in the k_to_accuracies dictionary.                               #

################################################################################

for k in k_choices:

    k_to_accuracies[k]=np.zeros(num_folds)

    for i in range(num_folds):

        Xtr = np.concatenate(

            (np.array(X_train_folds)[:i],np.array(X_train_folds)[(i+1):]),axis=0)

        ytr = np.concatenate(

            (np.array(y_train_folds)[:i],np.array(y_train_folds)[(i+1):]),axis=0)

        Xte = np.array(X_train_folds)[i]

        yte = np.array(y_train_folds)[i]

        # [num_of_folds, num_in_flods, feature_of_x] -> [num_of_pictures, feature_of_x]

        Xtr = np.reshape(Xtr, (X_train.shape[0] * 4 / 5, -1))

        ytr = np.reshape(ytr, (y_train.shape[0] * 4 / 5, -1))

        Xte = np.reshape(Xte, (X_train.shape[0] / 5, -1))

        yte = np.reshape(yte, (y_train.shape[0] / 5, -1))

        classifier.train(Xtr, ytr)

        yte_pred = classifier.predict(Xte, k)

        yte_pred = np.reshape(yte_pred, (yte_pred.shape[0], -1))

        accuracy = np.sum(yte_pred == yte, dtype=float)/len(yte)   # bool to int,我们需要显示指定为float

        k_to_accuracies[k][i] = accuracy

################################################################################

#                                 END OF YOUR CODE                             #

################################################################################

# Print out the computed accuracies

for k in sorted(k_to_accuracies):

    for accuracy in k_to_accuracies[k]:

        print 'k = %d, accuracy = %f' % (k, accuracy)

def svm_loss_vectorized(W, X, y, reg):

  """

  Structured SVM loss function, vectorized implementation.

  Inputs and outputs are the same as svm_loss_naive.

  """

  loss = 0.0

  dW = np.zeros(W.shape) # initialize the gradient as zero

  # 向前传播

  scores = X.dot(W)

  scores_correct = scores[np.arange(y.shape[0]),y].reshape(y.shape[0],1)

  margins = np.maximum(0., scores - scores_correct + 1)      # 错误类加上阈值减去正确类得分，满足的置零，不满足的计算loss

  margins[np.arange(y.shape[0]),y] = 0                       # 把上一步正确类参与计算的部分置零

  loss = np.sum(margins)/y.shape[0] + 0.5*reg*np.sum(W*W)

  # 反向传播

  margins[margins>0] = 1                         # 类relu反向传播

  row_grad = np.sum(margins, axis=1)

  margins[np.arange(y.shape[0]),y] - row_grad    # 分类器反向都是这样，错误类不动，正确类减去上层梯度

  dW = np.dot(X.T,margins)/y.shape[0] + reg*W

  return loss, dW