def plot_dead_filter_num_with_different_fdt():
# print()
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
#
# # net=create_net.vgg_cifar10()
checkpoint = torch.load(
'../data/baseline/resnet56_cifar10,accuracy=0.94230.tar')
net = resnet_cifar.resnet56().to(device)
net.load_state_dict(checkpoint['state_dict'])
val_loader = data_loader.create_validation_loader(batch_size=500,
num_workers=6,
dataset_name='cifar10')
relu_list, neural_list = evaluate.check_ReLU_alive(net=net,
neural_dead_times=8000,
data_loader=val_loader)
# net=vgg.vgg16_bn(pretrained=False)
# checkpoint=torch.load('/home/victorfang/Desktop/vgg16_bn_imagenet_deadReLU.tar')
# net=resnet.resnet34(pretrained=True)
# checkpoint=torch.load('/home/victorfang/Desktop/resnet34_imagenet_DeadReLU.tar')
# neural_list=checkpoint['neural_list']
# relu_list=checkpoint['relu_list']
neural_dead_times = 8000
# neural_dead_times=40000
fdt_list = [0.001 * i for i in range(1, 1001)]
dead_filter_num = []
for fdt in fdt_list:
dead_filter_num.append(
dead_filter_statistics(net=net,
neural_list=neural_list,
neural_dead_times=neural_dead_times,
filter_FIRE=fdt,
relu_list=relu_list))
if fdt == 0.8:
print()
plt.figure()
plt.title('df')
plt.plot(fdt_list, dead_filter_num)
plt.xlabel('filter activation ratio')
plt.ylabel('number of filters')
plt.legend()
plt.show()
def dead_neural_rate():
# checkpoint=torch.load('/home/victorfang/Desktop/vgg16_bn_imagenet_deadReLU.tar')
# checkpoint=torch.load('/home/victorfang/Desktop/resnet34_imagenet_DeadReLU.tar')
# neural_list=checkpoint['neural_list']
# relu_list=checkpoint['relu_list']
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
checkpoint = torch.load(
'../data/baseline/resnet56_cifar10,accuracy=0.94230.tar')
net = resnet_cifar.resnet56().to(device)
net.load_state_dict(checkpoint['state_dict'])
# net=create_net.vgg_cifar10()
val_loader = data_loader.create_validation_loader(batch_size=1000,
num_workers=6,
dataset_name='cifar10')
# train_loader=data_loader.create_train_loader(batch_size=1600,num_workers=6,dataset_name='cifar10')
#
relu_list, neural_list = evaluate.check_ReLU_alive(net=net,
neural_dead_times=10000,
data_loader=val_loader)
# ndt_list=[i for i in range(35000,51000,1000)]
ndt_list = [i for i in range(6000, 11000, 1000)]
dead_rate = []
for ndt in ndt_list:
print(ndt)
dead_rate.append(
evaluate.cal_dead_neural_rate(neural_dead_times=ndt,
neural_list_temp=neural_list))
plt.figure()
plt.title('df')
plt.plot(ndt_list, dead_rate)
plt.xlabel('neural dead times')
plt.ylabel('neuron dead rate%')
plt.legend()
plt.show()
def plot_dead_neuron_filter_number(
neural_dead_times=8000,
dataset_name='cifar10',
):
fontsize = 17
label_fontsize = 24
tick_fontsize = 20
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
checkpoint = torch.load(
'../data/baseline/vgg16_bn_cifar10,accuracy=0.941.tar')
vgg16 = storage.restore_net(checkpoint)
vgg16.load_state_dict(checkpoint['state_dict'])
checkpoint = torch.load(
'../data/baseline/resnet56_cifar10,accuracy=0.94230.tar')
resnet56 = resnet_cifar.resnet56().to(device)
resnet56.load_state_dict(checkpoint['state_dict'])
vgg16_imagenet = vgg.vgg16_bn(pretrained=True).to(device)
checkpoint = torch.load(
'/home/victorfang/Desktop/vgg16_bn_imagenet_deadReLU.tar')
relu_list_imagenet = checkpoint['relu_list']
neural_list_imagenet = checkpoint['neural_list']
loader = data_loader.create_validation_loader(batch_size=100,
num_workers=1,
dataset_name=dataset_name)
# loader=data_loader.create_validation_loader(batch_size=1000,num_workers=8,dataset_name='cifar10_trainset')
relu_list_vgg, neural_list_vgg = evaluate.check_ReLU_alive(
net=vgg16,
neural_dead_times=neural_dead_times,
data_loader=loader,
max_data_to_test=10000)
relu_list_resnet, neural_list_resnet = evaluate.check_ReLU_alive(
net=resnet56,
neural_dead_times=neural_dead_times,
data_loader=loader,
max_data_to_test=10000)
def get_statistics(net,
relu_list,
neural_list,
neural_dead_times,
sample_num=10000):
num_conv = 0 # num of conv layers in the net
for mod in net.modules():
if isinstance(mod, torch.nn.modules.conv.Conv2d):
num_conv += 1
neural_dead_list = [] #神经元死亡次数的列表
filter_dead_list = [] #卷积核死亡比率的列表
FIRE = []
for i in range(num_conv):
for relu_key in list(neural_list.keys()):
if relu_list[
i] is relu_key: # find the neural_list_statistics in layer i+1
dead_times = copy.deepcopy(neural_list[relu_key])
neural_dead_list += copy.deepcopy(
dead_times).flatten().tolist()
neural_num = dead_times.shape[1] * dead_times.shape[
2] # neural num for one filter
# compute sum(dead_times)/(batch_size*neural_num) as label for each filter
dead_times = np.sum(dead_times, axis=(1, 2))
FIRE += (dead_times / (neural_num * sample_num)).tolist()
# # judge dead filter by neural_dead_times and dead_filter_ratio
# dead_times[dead_times < neural_dead_times] = 0
# dead_times[dead_times >= neural_dead_times] = 1
# dead_times = np.sum(dead_times, axis=(1, 2)) # count the number of dead neural for one filter
# dead_times = dead_times / neural_num
# filter_dead_list+=dead_times.tolist()
break
active_ratio = 1 - np.array(FIRE)
active_filter_list = 1 - np.array(filter_dead_list)
neural_activated_list = (sample_num -
np.array(neural_dead_list)) / sample_num
return neural_activated_list, active_ratio, #active_filter_list
nal_vgg, afl_vgg = get_statistics(vgg16,
relu_list_vgg,
neural_list_vgg,
neural_dead_times=neural_dead_times)
nal_resnet, afl_resnet = get_statistics(
resnet56,
relu_list_resnet,
neural_list_resnet,
neural_dead_times=neural_dead_times)
nal_imagenet, afl_imagenet = get_statistics(vgg16_imagenet,
relu_list_imagenet,
neural_list_imagenet,
sample_num=50000,
neural_dead_times=40000)
# #cdf_of_dead_neurons
# plt.figure()
# plt.hist([nal_vgg,nal_resnet,nal_imagenet],cumulative=True,histtype='step',bins=1000,density=True,)#linewidth=5.0) #cumulative=False为pdf,true为cdf
# # plt.hist(neural_activated_list,cumulative=True,histtype='bar',bins=20,density=True,rwidth=0.6) #cumulative=False为pdf,true为cdf
# plt.xlabel('Activation Ratio',fontsize = fontsize)
# plt.ylabel('Ratio of Neurons',fontsize = fontsize)
# plt.legend(['VGG-16 on CIFAR-10','ResNet-56 on CIFAR-10','VGG-16 on ImageNet'],loc='upper left',fontsize = fontsize)
# # plt.savefig('0cdf_of_dead_neurons.jpg')
# plt.savefig('cdf_of_dead_neurons.eps',format='eps')
# plt.show()
#
# #cdf_of_inactive_filter
# plt.figure()
# plt.hist([afl_vgg,afl_resnet,afl_imagenet],cumulative=True,histtype='step',bins=1000,density=True,)#linewidth=5.0) #cumulative=False为pdf,true为cdf
# # plt.hist(neural_activated_list,cumulative=True,histtype='bar',bins=20,density=True,rwidth=0.6) #cumulative=False为pdf,true为cdf
# plt.xlabel('Activation Ratio',fontsize = fontsize)
# plt.ylabel('Ratio of Filters',fontsize = fontsize)
# plt.legend(['VGG-16 on CIFAR-10','ResNet-56 on CIFAR-10','VGG-16 on ImageNet'],loc='upper left',fontsize = fontsize)
# # plt.savefig('0cdf_of_inactive_filter.jpg')
# plt.savefig('cdf_of_inactive_filter.eps',format='eps')
# plt.show()
#pdf_of_dead_neurons
plt.figure()
hist_list = []
for nal in [nal_vgg, nal_resnet, nal_imagenet]:
hist, bins = np.histogram(nal, bins=[0.1 * i for i in range(11)])
hist_list.append(100 * hist / np.sum(hist))
x_tick = np.array([5, 15, 25, 35, 45, 55, 65, 75, 85, 95])
plt.figure()
plt.bar(x_tick - 2,
hist_list[0],
color='coral',
edgecolor='black',
label='VGG-16 on CIFAR-10',
align='center',
width=2)
plt.bar(x_tick,
hist_list[1],
color='cyan',
edgecolor='black',
label='ResNet-56 on CIFAR-10',
align='center',
width=2)
plt.bar(x_tick + 2,
hist_list[2],
color='mediumslateblue',
edgecolor='black',
label='VGG-16 on ImageNet',
align='center',
width=2)
plt.xticks(x_tick, x_tick, size=tick_fontsize)
plt.yticks(size=tick_fontsize)
plt.xlabel('Activation Ratio (%)', fontsize=label_fontsize)
plt.ylabel('% of Neurons', fontsize=label_fontsize)
plt.legend(loc='upper right', fontsize=fontsize)
# plt.savefig('0pdf_of_dead_neurons.jpg')
plt.savefig('pdf_of_dead_neurons.eps', format='eps', bbox_inches='tight')
plt.show()
#pdf_of_inactive_filter
plt.figure()
hist_list = []
for active_ratio in [afl_vgg, afl_resnet, afl_imagenet]:
hist, bins = np.histogram(active_ratio,
bins=[0.1 * i for i in range(11)])
hist_list.append(100 * hist / np.sum(hist))
x_tick = np.array([5, 15, 25, 35, 45, 55, 65, 75, 85, 95])
plt.figure()
plt.bar(x_tick - 2,
hist_list[0],
color='coral',
edgecolor='black',
label='VGG-16 on CIFAR-10',
align='center',
width=2)
plt.bar(x_tick,
hist_list[1],
color='cyan',
edgecolor='black',
label='ResNet-56 on CIFAR-10',
align='center',
width=2)
plt.bar(x_tick + 2,
hist_list[2],
color='mediumslateblue',
edgecolor='black',
label='VGG-16 on ImageNet',
align='center',
width=2)
plt.xticks(x_tick, x_tick, size=tick_fontsize)
plt.yticks(size=tick_fontsize)
plt.xlabel('Activation Ratio (%)', fontsize=label_fontsize)
plt.ylabel('% of Filters', fontsize=label_fontsize)
plt.legend(loc='upper right', fontsize=fontsize)
# plt.savefig('0pdf_of_inactive_filter.jpg')
plt.savefig('pdf_of_inactive_filter.eps',
format='eps',
bbox_inches='tight')
plt.show()
print()
def speed_up_pruned_net():
fontsize = 15
checkpoint = torch.load(
'../data/baseline/vgg16_bn_cifar10,accuracy=0.941.tar')
net_original = storage.restore_net(checkpoint)
checkpoint = torch.load(
'../data/baseline/resnet56_cifar10,accuracy=0.93280.tar')
net_original = resnet_cifar.resnet56()
net_original.load_state_dict(checkpoint['state_dict'])
checkpoint = torch.load(
'../data/model_saved/vgg16bn_cifar10_realdata_regressor6_大幅度/checkpoint/flop=39915982,accuracy=0.93200.tar'
)
checkpoint = torch.load(
'../data/model_saved/resnet56_cifar10_regressor_prunedBaseline2/checkpoint/flop=36145802,accuracy=0.92110.tar'
)
net_pruned = storage.restore_net(checkpoint)
net_pruned.load_state_dict(checkpoint['state_dict'])
# batch_size=[256,512,1024]
num_workers = [i for i in range(4, 5)]
batch_size = [300, 600, 1000, 1600]
device_list = [torch.device('cuda')] #
# device_list=[torch.device('cpu')]
for num_worker in num_workers:
time_original = []
time_pruned = []
for d in device_list:
for bs in batch_size:
net_original.to(d)
net_pruned.to(d)
dl = data_loader.create_validation_loader(
batch_size=bs,
num_workers=num_worker,
dataset_name='cifar10')
start_time = time.time()
evaluate.evaluate_net(net=net_original,
data_loader=dl,
save_net=False,
device=d)
end_time = time.time()
time_original.append(end_time - start_time)
del dl
dl = data_loader.create_validation_loader(
batch_size=bs,
num_workers=num_worker,
dataset_name='cifar10')
start_time = time.time()
evaluate.evaluate_net(net=net_pruned,
data_loader=dl,
save_net=False,
device=d)
end_time = time.time()
time_pruned.append(end_time - start_time)
del dl
print('time before pruned:', time_original)
print('time after pruned:', time_pruned)
acceleration = np.array(time_original) / np.array(time_pruned)
baseline = np.ones(shape=len(batch_size))
x_tick = range(len(baseline))
plt.figure()
plt.bar(x_tick, acceleration, color='blue', hatch='//') #,label='GPU')
# plt.bar(x_tick[len(batch_size):], acceleration[len(batch_size):], color='grey', hatch='\\', label='CPU')
# plt.bar(x_tick,baseline,color='red',hatch='*',label='Baseline')
plt.xticks(x_tick, batch_size, fontsize=fontsize)
plt.yticks(fontsize=fontsize)
for x, y in enumerate(list(acceleration)):
plt.text(x, y + 0.1, '%.2f x' % y, ha='center', fontsize=fontsize)
plt.ylim([0, np.max(acceleration) + 0.5])
plt.xlabel('Batch-Size', fontsize=fontsize)
plt.ylabel('Speed-Up', fontsize=fontsize)
# plt.legend(loc='upper left')
plt.savefig('resnet_gpu_speed_up.eps', format='eps')
# plt.savefig(str(num_worker)+'speed_up.jpg')
plt.show()
print()
projection_matrix = v[:, :dim]
return torch.matmul(tensor_2d, projection_matrix)
def normalize(tensor):
mean = tensor.mean(dim=0)
std = tensor.std(dim=0)
tensor = (tensor - mean) / std
return tensor
if __name__ == "__main__":
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
# net= vgg.vgg16_bn(pretrained=True).to(device)
net1 = resnet_cifar.resnet56().to(device)
i = 0
for mod in net1.modules():
if isinstance(mod, torch.nn.Conv2d):
i += 1
net2 = resnet.resnet50().to(device)
net3 = vgg.vgg16_bn().to(device)
test = gcn(in_features=10, out_features=10).to(device)
test.forward(net=net1,
net_name='resnet56',
dataset_name='cifar10',
rounds=2)
# def conversion(dataset_name,net_name,checkpoint_path='',checkpoint=None):
#转化之前的cifar上的resnet
# checkpoint=torch.load(checkpoint_path)
# # net=checkpoint.pop('net')
# net=resnet_cifar.resnet32()
# checkpoint['state_dict']['fc.weight']=checkpoint['state_dict'].pop('linear.weight')
# checkpoint['state_dict']['fc.bias']=checkpoint['state_dict'].pop('linear.bias')
#
# net.load_state_dict(checkpoint['state_dict'])
# checkpoint.update(get_net_information(net,dataset_name,net_name))
# torch.save(checkpoint,checkpoint_path)
if __name__ == "__main__":
# conversion(checkpoint_path='../data/baseline/resnet32_cifar10,accuracy=0.92380.tar',net_name='resnet56',dataset_name='cifar10')
checkpoint = torch.load(
'/home/victorfang/model_pytorch/data/baseline/resnet56_cifar10,accuracy=0.94230.tar'
)
net = resnet_cifar.resnet56()
# net.load_state_dict(checkpoint['state_dict'])
c = get_net_information(net=net,
dataset_name='cifar10',
net_name='resnet56')
net = restore_net(checkpoint, True)
from framework import evaluate, data_loader
evaluate.evaluate_net(
net, data_loader.create_validation_loader(512, 4, 'cifar10'), False)
# c=get_net_information(net=net,dataset_name=dataset_name,net_name='resnet50')