This commit is contained in:
monoid 2021-02-20 15:25:54 +09:00
parent 769ac11912
commit f802d99a0c

167
p4.py
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@ -6,8 +6,9 @@ import pickle
import matplotlib import matplotlib
import matplotlib.pyplot as plt import matplotlib.pyplot as plt
import random import random
import itertools
matplotlib.use("TkAgg") import math
#matplotlib.use("TkAgg")
PICKLE_DATA_FILENAME = "mnist.pickle" PICKLE_DATA_FILENAME = "mnist.pickle"
if not os.path.exists(PICKLE_DATA_FILENAME): if not os.path.exists(PICKLE_DATA_FILENAME):
@ -30,39 +31,153 @@ X = X / 255
y = np.array([int(i) for i in y]) y = np.array([int(i) for i in y])
Y = np.eye(10)[y] Y = np.eye(10)[y]
train_x,train_y = X[0:3500*17], Y[0:3500*17]
dev_x,dev_y = X[3500*17:3500*18], Y[3500*17:3500*18]
test_x,test_y = X[3500*18:3500*20], Y[3500*18:3500*20]
gen:np.random.Generator = np.random.default_rng() gen:np.random.Generator = np.random.default_rng()
eta = 0.01 eta = 0.0001
MiniBatchN = 100 MiniBatchN = 32
weight1 = Variable(gen.normal(0,1,size=(784,10))) class CheckPoint:
bias1 = Variable(gen.normal(0,1,size=(10))) def __init__(self,param,accuracy,loss,iteration):
super().__init__()
self.param = param
self.accuracy = accuracy
self.loss = loss
self.iteration = iteration
class Model:
def __init__(self, layerDim:[int]):
super().__init__()
gen:np.random.Generator = np.random.default_rng()
self.layerDim = layerDim
self.param = []
self.checkpoints = []
self.iteration = 0
front = 784
for sd in layerDim:
back = sd
weight = Variable(gen.normal(0,1,size=(front,back)))
bias = Variable(gen.normal(0,1,size=(back)))
self.param.append((weight,bias))
front = back
def caculate(self,input_x,y):
input_var = Variable(input_x)
Z = input_var
for i,(w,b) in enumerate(self.param):
U = Z @ w + b
if i < len(self.param) - 1:
Z = relu(U)
else:
Z = U
J = SoftmaxWithNegativeLogLikelihood(Z,y)
return J
def train_one_iterate(self,input_x,y,eta):
#forward pass
J = self.caculate(input_x,y)
#backpropagation
J.backprop(np.ones(()))
for i,(w,b) in enumerate(self.param):
w = Variable(w.numpy() - (w.grad) * eta)
b = Variable(b.numpy() - (b.grad) * eta)
self.param[i] = (w,b)
self.iteration += 1
return J
def get_loss_and_confusion(self,input_x,y):
J = self.caculate(input_x,y)
s = J.softmax_numpy()
s = np.round(s)
confusion = (np.transpose(y)@s)
return J.numpy(), confusion
def set_checkpoint(self,dev_x,dev_y):
J = self.caculate(dev_x,dev_y)
loss = np.average(J.numpy())
print(f"check point #{len(self.checkpoints)}")
print(self.iteration,'iteration : avg loss : ',loss)
confusion = get_confusion(J)
accuracy = get_accuracy_from_confusion(confusion)
print('accuracy : {:.2f}%'.format(accuracy * 100))
self.checkpoints.append(CheckPoint(
self.param,
accuracy*100,
loss,
self.iteration
))
def get_confusion(J:SoftmaxWithNegativeLogLikelihood):
s = J.softmax_numpy()
s = np.eye(10)[np.argmax(s,axis=len(s.shape)-1)]
confusion = (np.transpose(J.y)@s)
return confusion
def get_accuracy_from_confusion(confusion):
return np.trace(confusion).sum() / np.sum(confusion)
def model_filename(layerDim:[int]):
return f"model{layerDim}.pickle"
def save_model(model:Model):
with open(model_filename(model.layerDim),"wb") as model_file:
pickle.dump(model,model_file)
def load_or_create_model(layerDim:list):
model_name = model_filename(layerDim)
if os.path.exists(model_name):
with open(model_name,"rb") as model_file:
return pickle.load(model_file)
else:
return Model(layerDim)
model = load_or_create_model([300,300,100,10])
accuracy_list = [] accuracy_list = []
loss_list = []
iteration_list = []
end_n = math.floor(3500*17 /MiniBatchN)
for iteration in range(0,100): for epoch in range(1):
choiced_index = gen.choice(range(0,60000),MiniBatchN) #one epoch
input_var = Variable(X[choiced_index]) for iteration in range(0,end_n):
U1 = (input_var @ weight1 + bias1) choiced_index = gen.choice(range(0,len(train_x)),MiniBatchN)
J = SoftmaxWithNegativeLogLikelihood(U1,Y[choiced_index]) batch_x = train_x[choiced_index]
batch_y = train_y[choiced_index]
#batch_x = train_x[MiniBatchN*iteration:MiniBatchN*(iteration+1)]
#batch_y = train_y[MiniBatchN*iteration:MiniBatchN*(iteration+1)]
model.train_one_iterate(batch_x,batch_y,eta)
if (model.iteration-1) % 200 == 0:
model.set_checkpoint(dev_x,dev_y)
if (model.iteration) % 10 == 0:
print(f"iteration {model.iteration+1}")
J.backprop(np.ones(())) J = model.caculate(test_x,test_y)
#update variable loss = np.average(J.numpy())
weight1 = Variable(weight1.numpy() - (weight1.grad) * eta) print('testset : avg loss : ',loss)
bias1 = Variable(bias1.numpy() - (bias1.grad) * eta)
if iteration % 5 == 0:
print(iteration,'iteration : avg(J) == ',np.average(J.numpy()))
s = J.softmax_numpy()
#print(Y[0:1000].shape)
s = np.round(s)
confusion = (np.transpose(Y[choiced_index])@s)
accuracy = np.trace(confusion).sum() / MiniBatchN
print('accuracy : ',accuracy * 100,'%')
accuracy_list.append(accuracy)
confusion = get_confusion(J)
accuracy = get_accuracy_from_confusion(confusion)
print('accuracy : {:.2f}%'.format(accuracy * 100))
if True:
save_model(model)
plt.subplot(1,2,1)
plt.title("accuracy") plt.title("accuracy")
plt.plot(np.linspace(0,len(accuracy_list),len(accuracy_list)),accuracy_list) plt.plot([*map(lambda x: x.iteration,model.checkpoints)],
[*map(lambda x: x.accuracy,model.checkpoints)]
)
plt.subplot(1,2,2)
plt.title("loss")
plt.plot([*map(lambda x: x.iteration,model.checkpoints)],
[*map(lambda x: x.loss,model.checkpoints)])
plt.show() plt.show()
plt.title("confusion matrix") plt.title("confusion matrix")
plt.imshow(confusion,cmap='gray') plt.imshow(confusion,cmap='Blues')
plt.colorbar()
for i,j in itertools.product(range(confusion.shape[0]),range(confusion.shape[1])):
plt.text(j,i,"{:}".format(confusion[i,j]),horizontalalignment="center",color="white" if i == j else "black")
plt.show() plt.show()