def main(rs, det):
bda_utils.setup_seed(rs)
# ## 1.b. Load Data
# In[3]:
Xs, Xt = bda_utils.load_data(if_weekday=1, if_interdet=1)
Xs = Xs[:, det:det+1]
Xt = Xt[:, det:det+1]
Xs, Xs_min, Xs_max = bda_utils.normalize2D(Xs)
Xt, Xt_min, Xt_max = bda_utils.normalize2D(Xt)
# In[4]:
# for i in range(Xs.shape[1]):
# plt.figure(figsize=[20,4])
# plt.plot(Xs[:, i])
# plt.plot(Xt[:, i])
# ## 1.d. Hyperparameters
# In[5]:
label_seq_len = 7
# batch_size = full batch
seq_len = 12
reduced_dim = 4
inp_dim = min(Xs.shape[1], Xt.shape[1])
label_dim = min(Xs.shape[1], Xt.shape[1])
hid_dim = 12
layers = 1
lamb = 3
hyper = {
'inp_dim':inp_dim,
'label_dim':label_dim,
'label_seq_len':label_seq_len,
'seq_len':seq_len,
'reduced_dim':reduced_dim,
'hid_dim':hid_dim,
'layers':layers,
'lamb':lamb}
hyper = pd.DataFrame(hyper, index=['Values'])
# In[6]:
hyper
# ## 1.e. Apply BDA and get $Xs_{new}$, $Xt_{new}$
# In[7]:
# [sample size, seq_len, inp_dim (dets)], [sample size, label_seq_len, inp_dim (dets)]
Xs_3d, Ys_3d = bda_utils.sliding_window(Xs, Xs, seq_len, label_seq_len)
Xt_3d, Yt_3d = bda_utils.sliding_window(Xt, Xt, seq_len, label_seq_len)
Ys_3d = Ys_3d[:, label_seq_len-1:, :]
Yt_3d = Yt_3d[:, label_seq_len-1:, :]
# print(Xs_3d.shape)
# print(Ys_3d.shape)
# print(Xt_3d.shape)
# print(Yt_3d.shape)
# In[8]:
t_s = time.time()
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
Xs_train_3d = []
Ys_train_3d = []
Xt_valid_3d = []
Xt_train_3d = []
Yt_valid_3d = []
Yt_train_3d = []
for i in range(Xs_3d.shape[2]):
# print('Starting det %i'%i)
# bda = BDA(kernel_type='linear', dim=seq_len-reduced_dim, lamb=lamb, mu=0.6, gamma=1, T=1) # T is iteration time
# Xs_new, Xt_new, A = bda.fit(
# Xs_3d[:, :, i], bda_utils.get_class(Ys_3d[:, :, i]), Xt_3d[:, :, i], bda_utils.get_class(Yt_3d[:, :, i])
# ) # input shape: ns, n_feature | ns, n_label_feature
Xs_new = Xs_3d[:, :, 0]
Xt_new = Xt_3d[:, :, 0]
# print(Xs_new.shape)
# print(Xt_new.shape)
day_train_t = 1
Xs_train = Xs_new.copy()
Ys_train = Ys_3d[:, :, i]
Xt_valid = Xt_new.copy()[int(84):, :]
Xt_train = Xt_new.copy()[:int(84), :]
Yt_valid = Yt_3d[:, :, i].copy()[int(84):, :]
Yt_train = Yt_3d[:, :, i].copy()[:int(84), :]
Xs_train_3d.append(Xs_train)
Ys_train_3d.append(Ys_train)
Xt_valid_3d.append(Xt_valid)
Xt_train_3d.append(Xt_train)
Yt_valid_3d.append(Yt_valid)
Yt_train_3d.append(Yt_train)
Xs_train_3d = np.array(Xs_train_3d)
Ys_train_3d = np.array(Ys_train_3d)
Xt_valid_3d = np.array(Xt_valid_3d)
Xt_train_3d = np.array(Xt_train_3d)
Yt_valid_3d = np.array(Yt_valid_3d)
Yt_train_3d = np.array(Yt_train_3d)
# bda_utils.save_np(Xs_train_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Ys_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Xt_valid_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Xt_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Yt_valid_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Yt_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# print('Time spent:%.5f'%(time.time()-t_s))
# In[9]:
Xs_train_3d = np.transpose(Xs_train_3d, (1, 2, 0))
Ys_train_3d = np.transpose(Ys_train_3d, (1, 2, 0))
Xt_valid_3d = np.transpose(Xt_valid_3d, (1, 2, 0))
Xt_train_3d = np.transpose(Xt_train_3d, (1, 2, 0))
Yt_valid_3d = np.transpose(Yt_valid_3d, (1, 2, 0))
Yt_train_3d = np.transpose(Yt_train_3d, (1, 2, 0))
# In[10]:
Ys_train_3d.shape
# # 2. Learning Part
# ## 2.a. Build network
# In[11]:
from bda_utils import traff_net_reg
# ## 2.b. Assemble Dataloader
# In[12]:
batch_size = 1960
train_x = Xt_train_3d
train_y = Yt_train_3d
train_x = torch.tensor(train_x, dtype=torch.float32).to(device)
train_y = torch.tensor(train_y, dtype=torch.float32).to(device)
Xt_valid_3d = torch.tensor(Xt_valid_3d, dtype=torch.float32).to(device)
Yt_valid_3d = torch.tensor(Yt_valid_3d, dtype=torch.float32).to(device)
train_dataset = TensorDataset(train_x, train_y)
train_loader = torch.utils.data.DataLoader(train_dataset, batch_size, shuffle=False)
train_iter = iter(train_loader)
# print(train_x.shape)
# print(train_y.shape)
# print('\n')
# print(Xt_valid_3d.shape)
# print(Yt_valid_3d.shape)
# ## 2.c. Learn
# In[16]:
# build model
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
net = traff_net_reg(1, label_dim, seq_len, label_seq_len).to(device)
criterion = nn.MSELoss()
#scheduler = torch.optim.lr_scheduler.StepLR(optimizer, 0.7)
train_loss_set = []
val_loss_set = []
det = 0 # which detector to visualize
# num_fold = len(next(iter(os.walk('./runs_base/')))[1])
# os.mkdir('./runs_base/run%i'%(num_fold+1))
# In[17]:
optimizer = torch.optim.Adam(net.parameters())
# In[18]:
# train
net.train()
epochs = 501
for e in range(epochs):
for i in range(len(train_loader)):
try:
data, label = train_iter.next()
except:
train_iter = iter(train_loader)
data, label = train_iter.next()
# ipdb.set_trace()
out = net(data)
loss = criterion(out, label[:, :, 0]) # label.shape=[batch, 1, num_dets]
optimizer.zero_grad()
loss.backward()
optimizer.step()
val_out = net(Xt_valid_3d)
val_loss = criterion(val_out, Yt_valid_3d[:, :, 0])
val_loss_set.append(val_loss.cpu().detach().numpy())
train_loss_set.append(loss.cpu().detach().numpy())
# if e%50==0:
# # ipdb.set_trace()
# fig = plt.figure(figsize=[16,4])
# ax1 = fig.add_subplot(111)
# ax1.plot(label[:, 0, det].cpu().detach().numpy(), label='ground truth')
# ax1.plot(out[:, det].cpu().detach().numpy(), label='predict')
# ax1.legend()
# plt.show()
# print('Epoch No. %i success, loss: %.5f, val loss: %.5f' %(e, loss.cpu().detach().numpy(), val_loss.cpu().detach().numpy() ))
# In[19]:
# fig = plt.figure(figsize = [16, 4])
# ax1 = fig.add_subplot(121)
# ax1.plot(train_loss_set)
# ax2 = fig.add_subplot(122)
# ax2.plot(val_loss_set)
# # 3. Evaluation
# In[20]:
# val_out = net(Xt_valid_3d)
# plt.figure(figsize=[16,4])
# plt.plot(Yt_valid_3d[:, 0, det].cpu().flatten(), label='label')
# plt.plot(val_out[:, det].cpu().detach().numpy(), label='predict')
# plt.legend()
# In[21]:
# sklearn.metrics.accuracy_score(torch.argmax(val_out, dim=1).cpu(), bda_utils.get_class(Yt_valid_3d[:, 0, det]).cpu().flatten())
g_t = Yt_valid_3d.cpu().flatten().detach().numpy()
pred = val_out.cpu().detach().numpy().flatten()
g_t = g_t*(Xt_max - Xt_min) + Xt_min
pred = pred*(Xt_max - Xt_min) + Xt_min
pred_ = pred.copy()
pred_[pred_<0] = 0
nrmse = bda_utils.nrmse_loss_func(pred, g_t, 0)
mape = bda_utils.mape_loss_func(pred, g_t, 0)
smape = bda_utils.smape_loss_func(pred, g_t, 0)
mae = bda_utils.mae_loss_func(pred, g_t, 0)
nmae = bda_utils.nmae_loss_func(pred, g_t, 0)
return nrmse, mape, smape, mae, nmae
def main(rs, det):
Xs, Xt = bda_utils.load_data(if_weekday=1, if_interdet=1)
Xs = Xs[:, det:det + 1]
Xt = Xt[:, det:det + 1]
Xs, Xs_min, Xs_max = bda_utils.normalize2D(Xs)
Xt, Xt_min, Xt_max = bda_utils.normalize2D(Xt)
# In[3]:
label_seq_len = 7
# batch_size = full batch
seq_len = 12
reduced_dim = 4
inp_dim = min(Xs.shape[1], Xt.shape[1])
label_dim = min(Xs.shape[1], Xt.shape[1])
hid_dim = 12
layers = 1
lamb = 2
MU = 0.7
bda_dim = label_seq_len - 4
kernel_type = 'linear'
hyper = {
'inp_dim': inp_dim,
'label_dim': label_dim,
'label_seq_len': label_seq_len,
'seq_len': seq_len,
'reduced_dim': reduced_dim,
'hid_dim': hid_dim,
'layers': layers,
'lamb': lamb,
'MU': MU,
'bda_dim': bda_dim,
'kernel_type': kernel_type
}
hyper = pd.DataFrame(hyper, index=['Values'])
hyper
# In[4]:
Xs = Xs[:96, :]
# [sample size, seq_len, inp_dim (dets)], [sample size, label_seq_len, inp_dim (dets)]
Xs_3d, Ys_3d = bda_utils.sliding_window(Xs, Xs, seq_len, label_seq_len)
Xt_3d, Yt_3d = bda_utils.sliding_window(Xt, Xt, seq_len, label_seq_len)
Ys_3d = Ys_3d[:, label_seq_len - 1:, :]
Yt_3d = Yt_3d[:, label_seq_len - 1:, :]
# print(Xs_3d.shape)
# print(Ys_3d.shape)
# print(Xt_3d.shape)
# print(Yt_3d.shape)
# In[5]:
Xs_train_3d = []
Ys_train_3d = []
Xt_valid_3d = []
Xt_train_3d = []
Yt_valid_3d = []
Yt_train_3d = []
for i in range(Xs_3d.shape[2]):
# bda = BDA(kernel_type='linear', dim=seq_len-reduced_dim, lamb=lamb, mu=0.6, gamma=1, T=1) # T is iteration time
# Xs_new, Xt_new, A = bda.fit(
# Xs_3d[:, :, i], bda_utils.get_class(Ys_3d[:, :, i]), Xt_3d[:, :, i], bda_utils.get_class(Yt_3d[:, :, i])
# ) # input shape: ns, n_feature | ns, n_label_feature
Xs_new = Xs_3d[:, :, 0]
Xt_new = Xt_3d[:, :, 0]
day_train_t = 1
Xs_train = Xs_new.copy()
Ys_train = Ys_3d[:, :, i]
Xt_valid = Xt_new.copy()[int(Xs_3d.shape[0]):, :]
Xt_train = Xt_new.copy()[:int(Xs_3d.shape[0]), :]
Yt_valid = Yt_3d[:, :, i].copy()[int(Xs_3d.shape[0]):, :]
Yt_train = Yt_3d[:, :, i].copy()[:int(Xs_3d.shape[0]), :]
Xs_train_3d.append(Xs_train)
Ys_train_3d.append(Ys_train)
Xt_valid_3d.append(Xt_valid)
Xt_train_3d.append(Xt_train)
Yt_valid_3d.append(Yt_valid)
Yt_train_3d.append(Yt_train)
Xs_train_3d = np.array(Xs_train_3d)
Ys_train_3d = np.array(Ys_train_3d)
Xt_valid_3d = np.array(Xt_valid_3d)
Xt_train_3d = np.array(Xt_train_3d)
Yt_valid_3d = np.array(Yt_valid_3d)
Yt_train_3d = np.array(Yt_train_3d)
# bda_utils.save_np(Xs_train_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Ys_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Xt_valid_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Xt_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Yt_valid_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Yt_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# In[6]:
# print(Xs_train.shape)
# print(Ys_train.shape)
# print(Xt_valid.shape)
# print(Xt_train.shape)
# print(Yt_valid.shape)
# print(Yt_train.shape)
# In[7]:
import xgboost as xgb
# In[8]:
regr = xgb.XGBRegressor(base_score=0.5,
booster='gbtree',
colsample_bylevel=1,
colsample_bynode=1,
colsample_bytree=1,
gamma=0,
importance_type='gain',
learning_rate=0.1,
max_delta_step=0,
max_depth=3,
min_child_weight=1,
missing=1,
n_estimators=100,
n_jobs=1,
nthread=None,
objective='reg:squarederror',
random_state=1,
reg_alpha=0,
reg_lambda=1,
scale_pos_weight=1,
seed=None,
silent=None,
subsample=1,
verbosity=1,
tree_method="hist")
# In[9]:
# train_x = np.vstack([Xs_train, Xt_train])
# train_y = np.vstack([Ys_train, Yt_train])
# regr.fit(train_x, train_y.flatten())
regr.fit(Xt_train, Yt_train.flatten())
# In[10]:
g_t = Yt_valid.flatten()
pred = regr.predict(Xt_valid)
# In[17]:
g_t = Yt_valid.flatten()
pred = regr.predict(Xt_valid)
# plt.figure(figsize=[16,4])
# plt.plot(g_t, label='label')
# plt.plot(pred, label='predict')
# plt.legend()
# bda_utils.save_np(g_t, './runs_base/base_data_plot/g_t_base_XGB.csv')
# bda_utils.save_np(pred, './runs_base/base_data_plot/pred_base_XGB.csv')
# In[18]:
nrmse = bda_utils.nrmse_loss_func(pred, g_t, 0)
mape = bda_utils.mape_loss_func(pred, g_t, 0)
smape = bda_utils.smape_loss_func(pred, g_t, 0)
mae = bda_utils.mae_loss_func(pred, g_t, 0)
nmae = bda_utils.nmae_loss_func(pred, g_t, 0)
return nrmse, mape, smape, mae, nmae
def main(rs, det):
Xs, Xt = bda_utils.load_data(if_weekday=1, if_interdet=1)
Xs = Xs[:,det:det+1]
Xt = Xt[:,det:det+1]
Xs, Xs_min, Xs_max = bda_utils.normalize2D(Xs)
Xt, Xt_min, Xt_max = bda_utils.normalize2D(Xt)
# In[4]:
label_seq_len = 7
# batch_size = full batch
seq_len = 12
reduced_dim = 4
inp_dim = min(Xs.shape[1], Xt.shape[1])
label_dim = min(Xs.shape[1], Xt.shape[1])
hid_dim = 12
layers = 1
lamb = 2
MU = 0.7
bda_dim = label_seq_len-4
kernel_type = 'linear'
hyper = {
'inp_dim':inp_dim,
'label_dim':label_dim,
'label_seq_len':label_seq_len,
'seq_len':seq_len,
'reduced_dim':reduced_dim,
'hid_dim':hid_dim,
'layers':layers,
'lamb':lamb,
'MU': MU,
'bda_dim':bda_dim,
'kernel_type':kernel_type}
hyper = pd.DataFrame(hyper, index=['Values'])
hyper
# In[5]:
Xs = Xs[:96, :]
# [sample size, seq_len, inp_dim (dets)], [sample size, label_seq_len, inp_dim (dets)]
Xs_3d, Ys_3d = bda_utils.sliding_window(Xs, Xs, seq_len, label_seq_len)
Xt_3d, Yt_3d = bda_utils.sliding_window(Xt, Xt, seq_len, label_seq_len)
Ys_3d = Ys_3d[:, label_seq_len-1:, :]
Yt_3d = Yt_3d[:, label_seq_len-1:, :]
# print(Xs_3d.shape)
# print(Ys_3d.shape)
# print(Xt_3d.shape)
# print(Yt_3d.shape)
# In[6]:
Xs_train_3d = []
Ys_train_3d = []
Xt_valid_3d = []
Xt_train_3d = []
Yt_valid_3d = []
Yt_train_3d = []
for i in range(Xs_3d.shape[2]):
# bda = BDA(kernel_type='linear', dim=seq_len-reduced_dim, lamb=lamb, mu=0.6, gamma=1, T=1) # T is iteration time
# Xs_new, Xt_new, A = bda.fit(
# Xs_3d[:, :, i], bda_utils.get_class(Ys_3d[:, :, i]), Xt_3d[:, :, i], bda_utils.get_class(Yt_3d[:, :, i])
# ) # input shape: ns, n_feature | ns, n_label_feature
Xs_new = Xs_3d[:, :, 0]
Xt_new = Xt_3d[:, :, 0]
day_train_t = 1
Xs_train = Xs_new.copy()
Ys_train = Ys_3d[:, :, i]
Xt_valid = Xt_new.copy()[int(Xs_3d.shape[0]):, :]
Xt_train = Xt_new.copy()[:int(Xs_3d.shape[0]), :]
Yt_valid = Yt_3d[:, :, i].copy()[int(Xs_3d.shape[0]):, :]
Yt_train = Yt_3d[:, :, i].copy()[:int(Xs_3d.shape[0]), :]
Xs_train_3d.append(Xs_train)
Ys_train_3d.append(Ys_train)
Xt_valid_3d.append(Xt_valid)
Xt_train_3d.append(Xt_train)
Yt_valid_3d.append(Yt_valid)
Yt_train_3d.append(Yt_train)
Xs_train_3d = np.array(Xs_train_3d)
Ys_train_3d = np.array(Ys_train_3d)
Xt_valid_3d = np.array(Xt_valid_3d)
Xt_train_3d = np.array(Xt_train_3d)
Yt_valid_3d = np.array(Yt_valid_3d)
Yt_train_3d = np.array(Yt_train_3d)
# bda_utils.save_np(Xs_train_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Ys_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Xt_valid_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Xt_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Yt_valid_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Yt_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# In[7]:
# print(Xs_train.shape)
# print(Ys_train.shape)
# print(Xt_valid.shape)
# print(Xt_train.shape)
# print(Yt_valid.shape)
# print(Yt_train.shape)
# In[8]:
from sklearn.ensemble import RandomForestRegressor
# In[27]:
regr = RandomForestRegressor(max_depth=3, random_state=rs)
# In[28]:
# train_x = np.vstack([Xs_train, Xt_train])
# train_y = np.vstack([Ys_train, Yt_train])
# regr.fit(train_x, train_y.flatten())
regr.fit(Xt_train, Yt_train.flatten())
# In[29]:
g_t = Yt_valid.flatten()
pred = regr.predict(Xt_valid)
# In[33]:
g_t = Yt_valid.flatten()
pred = regr.predict(Xt_valid)
# plt.figure(figsize=[16,4])
# plt.plot(g_t, label='label')
# plt.plot(pred, label='predict')
# plt.legend()
# bda_utils.save_np(g_t, './runs_base/base_data_plot/g_t_base_RF.csv')
# bda_utils.save_np(pred, './runs_base/base_data_plot/pred_base_RF.csv')
# In[34]:
nrmse = bda_utils.nrmse_loss_func(pred, g_t, 0)
mape = bda_utils.mape_loss_func(pred, g_t, 0)
smape = bda_utils.smape_loss_func(pred, g_t, 0)
mae = bda_utils.mae_loss_func(pred, g_t, 0)
nmae = bda_utils.nmae_loss_func(pred, g_t, 0)
return nrmse, mape, smape, mae, nmae
def main(seq_len, reduced_dim):
def kernel(ker, X1, X2, gamma):
K = None
if not ker or ker == 'primal':
K = X1
elif ker == 'linear':
if X2 is not None:
K = sklearn.metrics.pairwise.linear_kernel(
np.asarray(X1).T,
np.asarray(X2).T)
else:
K = sklearn.metrics.pairwise.linear_kernel(np.asarray(X1).T)
elif ker == 'rbf':
if X2 is not None:
K = sklearn.metrics.pairwise.rbf_kernel(
np.asarray(X1).T,
np.asarray(X2).T, gamma)
else:
K = sklearn.metrics.pairwise.rbf_kernel(
np.asarray(X1).T, None, gamma)
return K
def proxy_a_distance(source_X, target_X):
"""
Compute the Proxy-A-Distance of a source/target representation
"""
nb_source = np.shape(source_X)[0]
nb_target = np.shape(target_X)[0]
train_X = np.vstack((source_X, target_X))
train_Y = np.hstack(
(np.zeros(nb_source, dtype=int), np.ones(nb_target, dtype=int)))
clf = svm.LinearSVC(random_state=0)
clf.fit(train_X, train_Y)
y_pred = clf.predict(train_X)
error = metrics.mean_absolute_error(train_Y, y_pred)
dist = 2 * (1 - 2 * error)
return dist
def estimate_mu(_X1, _Y1, _X2, _Y2):
adist_m = proxy_a_distance(_X1, _X2)
C = len(np.unique(_Y1))
epsilon = 1e-3
list_adist_c = []
for i in range(1, C + 1):
ind_i, ind_j = np.where(_Y1 == i), np.where(_Y2 == i)
Xsi = _X1[ind_i[0], :]
Xtj = _X2[ind_j[0], :]
adist_i = proxy_a_distance(Xsi, Xtj)
list_adist_c.append(adist_i)
adist_c = sum(list_adist_c) / C
mu = adist_c / (adist_c + adist_m)
if mu > 1:
mu = 1
if mu < epsilon:
mu = 0
return mu
# In[4]:
class BDA:
def __init__(self,
kernel_type='primal',
dim=30,
lamb=1,
mu=0.5,
gamma=1,
T=10,
mode='BDA',
estimate_mu=False):
'''
Init func
:param kernel_type: kernel, values: 'primal' | 'linear' | 'rbf'
:param dim: dimension after transfer
:param lamb: lambda value in equation
:param mu: mu. Default is -1, if not specificied, it calculates using A-distance
:param gamma: kernel bandwidth for rbf kernel
:param T: iteration number
:param mode: 'BDA' | 'WBDA'
:param estimate_mu: True | False, if you want to automatically estimate mu instead of manally set it
'''
self.kernel_type = kernel_type
self.dim = dim
self.lamb = lamb
self.mu = mu
self.gamma = gamma
self.T = T
self.mode = mode
self.estimate_mu = estimate_mu
def fit(self, Xs, Ys, Xt, Yt):
'''
Transform and Predict using 1NN as JDA paper did
:param Xs: ns * n_feature, source feature
:param Ys: ns * 1, source label
:param Xt: nt * n_feature, target feature
:param Yt: nt * 1, target label
:return: acc, y_pred, list_acc
'''
# ipdb.set_trace()
list_acc = []
X = np.hstack((Xs.T, Xt.T)) # X.shape: [n_feature, ns+nt]
X_mean = np.linalg.norm(
X, axis=0) # why it's axis=0? the average of features
X_mean[X_mean == 0] = 1
X /= X_mean
m, n = X.shape
ns, nt = len(Xs), len(Xt)
e = np.vstack((1 / ns * np.ones((ns, 1)), -1 / nt * np.ones(
(nt, 1))))
C = np.unique(Ys)
H = np.eye(n) - 1 / n * np.ones((n, n))
mu = self.mu
M = 0
Y_tar_pseudo = None
Xs_new = None
for t in range(self.T):
print('\tStarting iter %i' % t)
N = 0
M0 = e * e.T * len(C)
# ipdb.set_trace()
if Y_tar_pseudo is not None:
for i in range(len(C)):
e = np.zeros((n, 1))
Ns = len(Ys[np.where(Ys == C[i])])
Nt = len(Y_tar_pseudo[np.where(Y_tar_pseudo == C[i])])
# Ns = 1
# Nt = 1
alpha = 1 # bda
tt = Ys == C[i]
e[np.where(tt == True)] = 1 / Ns
# ipdb.set_trace()
yy = Y_tar_pseudo == C[i]
ind = np.where(yy == True)
inds = [item + ns for item in ind]
try:
e[tuple(inds)] = -alpha / Nt
e[np.isinf(e)] = 0
except:
e[tuple(inds)] = 0 # ?
N = N + np.dot(e, e.T)
# ipdb.set_trace()
# In BDA, mu can be set or automatically estimated using A-distance
# In WBDA, we find that setting mu=1 is enough
if self.estimate_mu and self.mode == 'BDA':
if Xs_new is not None:
mu = estimate_mu(Xs_new, Ys, Xt_new, Y_tar_pseudo)
else:
mu = 0
# ipdb.set_trace()
M = (1 - mu) * M0 + mu * N
M /= np.linalg.norm(M, 'fro')
# ipdb.set_trace()
K = kernel(self.kernel_type, X, None, gamma=self.gamma)
n_eye = m if self.kernel_type == 'primal' else n
a, b = np.linalg.multi_dot([
K, M, K.T
]) + self.lamb * np.eye(n_eye), np.linalg.multi_dot(
[K, H, K.T])
w, V = scipy.linalg.eig(a, b)
ind = np.argsort(w)
A = V[:, ind[:self.dim]]
Z = np.dot(A.T, K)
Z_mean = np.linalg.norm(Z, axis=0) # why it's axis=0?
Z_mean[Z_mean == 0] = 1
Z /= Z_mean
Xs_new, Xt_new = Z[:, :ns].T, Z[:, ns:].T
global device
model = sklearn.neighbors.KNeighborsClassifier().fit(
Xs_new, Ys.ravel())
Y_tar_pseudo = model.predict(Xt_new)
# ipdb.set_trace()
acc = sklearn.metrics.accuracy_score(
Y_tar_pseudo, Yt) # Yt is already in classes
# print(acc)
return Xs_new, Xt_new, A #, acc, Y_tar_pseudo, list_acc
# ## 1.b. Load Data
# In[46]:
Xs, Xt = bda_utils.load_data(if_weekday=1, if_interdet=1)
Xs = Xs[:, :1]
Xt = Xt[:, :1]
Xs, Xs_min, Xs_max = bda_utils.normalize2D(Xs)
Xt, Xt_min, Xt_max = bda_utils.normalize2D(Xt)
# ## 1.d. Hyperparameters
# In[86]:
label_seq_len = 3
# batch_size = full batch
seq_len = 48
reduced_dim = 15
inp_dim = min(Xs.shape[1], Xt.shape[1])
label_dim = min(Xs.shape[1], Xt.shape[1])
hid_dim = 12
layers = 1
lamb = 3
hyper = {
'inp_dim': inp_dim,
'label_dim': label_dim,
'label_seq_len': label_seq_len,
'seq_len': seq_len,
'reduced_dim': reduced_dim,
'hid_dim': hid_dim,
'layers': layers,
'lamb': lamb
}
hyper = pd.DataFrame(hyper, index=['Values'])
# In[87]:
hyper
# ## 1.e. Apply BDA and get $Xs_{new}$, $Xt_{new}$
# In[88]:
# [sample size, seq_len, inp_dim (dets)], [sample size, label_seq_len, inp_dim (dets)]
Xs_3d, Ys_3d = bda_utils.sliding_window(Xs, Xs, seq_len, 1)
Xt_3d, Yt_3d = bda_utils.sliding_window(Xt, Xt, seq_len, 1)
# In[89]:
t_s = time.time()
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
Xs_train_3d = []
Ys_train_3d = []
Xt_valid_3d = []
Xt_train_3d = []
Yt_valid_3d = []
Yt_train_3d = []
for i in range(Xs_3d.shape[2]):
bda = BDA(kernel_type='linear',
dim=seq_len - reduced_dim,
lamb=lamb,
mu=0.6,
gamma=1,
T=1) # T is iteration time
Xs_new, Xt_new, A = bda.fit(
Xs_3d[:, :, i], bda_utils.get_class(Ys_3d[:, :, i]), Xt_3d[:, :,
i],
bda_utils.get_class(
Yt_3d[:, :,
i])) # input shape: ns, n_feature | ns, n_label_feature
day_train_t = 1
Xs_train = Xs_new.copy()
Ys_train = Ys_3d[:, :, i]
Xt_valid = Xt_new.copy()[int(96 * day_train_t):, :]
Xt_train = Xt_new.copy()[:int(96 * day_train_t), :]
Yt_valid = Yt_3d[:, :, i].copy()[int(96 * day_train_t):, :]
Yt_train = Yt_3d[:, :, i].copy()[:int(96 * day_train_t), :]
Xs_train_3d.append(Xs_train)
Ys_train_3d.append(Ys_train)
Xt_valid_3d.append(Xt_valid)
Xt_train_3d.append(Xt_train)
Yt_valid_3d.append(Yt_valid)
Yt_train_3d.append(Yt_train)
Xs_train_3d = np.array(Xs_train_3d)
Ys_train_3d = np.array(Ys_train_3d)
Xt_valid_3d = np.array(Xt_valid_3d)
Xt_train_3d = np.array(Xt_train_3d)
Yt_valid_3d = np.array(Yt_valid_3d)
Yt_train_3d = np.array(Yt_train_3d)
# In[90]:
Xs_train_3d = np.transpose(Xs_train_3d, (1, 2, 0))
Ys_train_3d = np.transpose(Ys_train_3d, (1, 2, 0))
Xt_valid_3d = np.transpose(Xt_valid_3d, (1, 2, 0))
Xt_train_3d = np.transpose(Xt_train_3d, (1, 2, 0))
Yt_valid_3d = np.transpose(Yt_valid_3d, (1, 2, 0))
Yt_train_3d = np.transpose(Yt_train_3d, (1, 2, 0))
Xs_train_3d.shape
class traff_net(nn.Module):
def __init__(self, seq_len, hid_dim=12, layers=3):
super(traff_net, self).__init__()
self.seq_len = seq_len
self.fc = nn.Sequential(
nn.Linear(seq_len, seq_len * 8),
nn.ReLU(),
nn.Linear(seq_len * 8, seq_len * 32),
nn.ReLU(),
nn.Linear(seq_len * 32, seq_len * 64),
nn.ReLU(),
nn.Linear(seq_len * 64, 100 + 1), # 101 classes (0-101)
nn.ReLU(),
) # regression
def forward(self, x):
y = nn.Flatten()(x)
y = self.fc(y) # fully connected layer
return y
batch_size = 1960
train_x = np.vstack([Xs_train_3d, Xt_train_3d])
train_y = np.vstack([Ys_train_3d, Yt_train_3d])
train_x = torch.tensor(train_x, dtype=torch.float32).to(device)
train_y = torch.tensor(train_y, dtype=torch.float32).to(device)
Xt_valid_3d = torch.tensor(Xt_valid_3d, dtype=torch.float32).to(device)
Yt_valid_3d = torch.tensor(Yt_valid_3d, dtype=torch.float32).to(device)
train_dataset = TensorDataset(train_x, train_y)
train_loader = torch.utils.data.DataLoader(train_dataset,
batch_size,
shuffle=False)
train_iter = iter(train_loader)
# build model
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
net = traff_net(seq_len - reduced_dim).to(device)
criterion = nn.CrossEntropyLoss()
optimizer = torch.optim.Adam(net.parameters(), lr=0.01)
#scheduler = torch.optim.lr_scheduler.StepLR(optimizer, 0.7)
train_loss_set = []
val_loss_set = []
det = 0 # which detector to visualize
# In[96]:
# train
net.train()
epochs = 201
for e in range(epochs):
for i in range(len(train_loader)):
try:
data, label = train_iter.next()
except:
train_iter = iter(train_loader)
data, label = train_iter.next()
out = net(data)
loss = criterion(out,
bda_utils.get_class(label[:, 0, 0]).flatten().
long()) # label.shape=[batch, 1, num_dets]
optimizer.zero_grad()
loss.backward()
optimizer.step()
val_out = net(Xt_valid_3d)
val_loss = criterion(
val_out,
bda_utils.get_class(Yt_valid_3d[:, 0, 0]).flatten().long())
val_loss_set.append(val_loss.cpu().detach().numpy())
train_loss_set.append(loss.cpu().detach().numpy())
return loss.cpu().detach().numpy(), val_loss.cpu().detach().numpy()
def main(rs, det):
bda_utils.setup_seed(rs)
# # 1. BDA Part
# ## 1.a. Define BDA methodology
# In[53]:
def kernel(ker, X1, X2, gamma):
K = None
if not ker or ker == 'primal':
K = X1
elif ker == 'linear':
if X2 is not None:
K = sklearn.metrics.pairwise.linear_kernel(
np.asarray(X1).T,
np.asarray(X2).T)
else:
K = sklearn.metrics.pairwise.linear_kernel(np.asarray(X1).T)
elif ker == 'rbf':
if X2 is not None:
K = sklearn.metrics.pairwise.rbf_kernel(
np.asarray(X1).T,
np.asarray(X2).T, gamma)
else:
K = sklearn.metrics.pairwise.rbf_kernel(
np.asarray(X1).T, None, gamma)
return K
def proxy_a_distance(source_X, target_X):
"""
Compute the Proxy-A-Distance of a source/target representation
"""
nb_source = np.shape(source_X)[0]
nb_target = np.shape(target_X)[0]
train_X = np.vstack((source_X, target_X))
train_Y = np.hstack(
(np.zeros(nb_source, dtype=int), np.ones(nb_target, dtype=int)))
clf = svm.LinearSVC(random_state=0)
clf.fit(train_X, train_Y)
y_pred = clf.predict(train_X)
error = metrics.mean_absolute_error(train_Y, y_pred)
dist = 2 * (1 - 2 * error)
return dist
def estimate_mu(_X1, _Y1, _X2, _Y2):
adist_m = proxy_a_distance(_X1, _X2)
C = len(np.unique(_Y1))
epsilon = 1e-3
list_adist_c = []
for i in range(1, C + 1):
ind_i, ind_j = np.where(_Y1 == i), np.where(_Y2 == i)
Xsi = _X1[ind_i[0], :]
Xtj = _X2[ind_j[0], :]
adist_i = proxy_a_distance(Xsi, Xtj)
list_adist_c.append(adist_i)
adist_c = sum(list_adist_c) / C
mu = adist_c / (adist_c + adist_m)
if mu > 1:
mu = 1
if mu < epsilon:
mu = 0
return mu
# In[54]:
class BDA:
def __init__(self,
kernel_type='primal',
dim=30,
lamb=1,
mu=0.5,
gamma=1,
T=10,
mode='BDA',
estimate_mu=False):
'''
Init func
:param kernel_type: kernel, values: 'primal' | 'linear' | 'rbf'
:param dim: dimension after transfer
:param lamb: lambda value in equation
:param mu: mu. Default is -1, if not specificied, it calculates using A-distance
:param gamma: kernel bandwidth for rbf kernel
:param T: iteration number
:param mode: 'BDA' | 'WBDA'
:param estimate_mu: True | False, if you want to automatically estimate mu instead of manally set it
'''
self.kernel_type = kernel_type
self.dim = dim
self.lamb = lamb
self.mu = mu
self.gamma = gamma
self.T = T
self.mode = mode
self.estimate_mu = estimate_mu
def fit(self, Xs, Ys, Xt, Yt):
'''
Transform and Predict using 1NN as JDA paper did
:param Xs: ns * n_feature, source feature
:param Ys: ns * 1, source label
:param Xt: nt * n_feature, target feature
:param Yt: nt * 1, target label
:return: acc, y_pred, list_acc
'''
# ipdb.set_trace()
list_acc = []
X = np.hstack((Xs.T, Xt.T)) # X.shape: [n_feature, ns+nt]
X_mean = np.linalg.norm(
X, axis=0) # why it's axis=0? the average of features
X_mean[X_mean == 0] = 1
X /= X_mean
m, n = X.shape
ns, nt = len(Xs), len(Xt)
e = np.vstack((1 / ns * np.ones((ns, 1)), -1 / nt * np.ones(
(nt, 1))))
C = np.unique(Ys)
H = np.eye(n) - 1 / n * np.ones((n, n))
mu = self.mu
M = 0
Y_tar_pseudo = None
Xs_new = None
for t in range(self.T):
# print('\tStarting iter %i'%t)
N = 0
M0 = e * e.T * len(C)
# ipdb.set_trace()
if Y_tar_pseudo is not None:
for i in range(len(C)):
e = np.zeros((n, 1))
Ns = len(Ys[np.where(Ys == C[i])])
Nt = len(Y_tar_pseudo[np.where(Y_tar_pseudo == C[i])])
if self.mode == 'WBDA':
Ps = Ns / len(Ys)
Pt = Nt / len(Y_tar_pseudo)
alpha = Pt / Ps
# mu = 1
else:
alpha = 1
tt = Ys == C[i]
e[np.where(tt == True)] = 1 / Ns
# ipdb.set_trace()
yy = Y_tar_pseudo == C[i]
ind = np.where(yy == True)
inds = [item + ns for item in ind]
try:
e[tuple(inds)] = -alpha / Nt
e[np.isinf(e)] = 0
except:
e[tuple(inds)] = 0 # ?
N = N + np.dot(e, e.T)
# ipdb.set_trace()
# In BDA, mu can be set or automatically estimated using A-distance
# In WBDA, we find that setting mu=1 is enough
if self.estimate_mu and self.mode == 'BDA':
if Xs_new is not None:
mu = estimate_mu(Xs_new, Ys, Xt_new, Y_tar_pseudo)
else:
mu = 0
# ipdb.set_trace()
M = (1 - mu) * M0 + mu * N
M /= np.linalg.norm(M, 'fro')
# ipdb.set_trace()
K = kernel(self.kernel_type, X, None, gamma=self.gamma)
n_eye = m if self.kernel_type == 'primal' else n
a, b = np.linalg.multi_dot([
K, M, K.T
]) + self.lamb * np.eye(n_eye), np.linalg.multi_dot(
[K, H, K.T])
w, V = scipy.linalg.eig(a, b)
ind = np.argsort(w)
A = V[:, ind[:self.dim]]
Z = np.dot(A.T, K)
Z_mean = np.linalg.norm(Z, axis=0) # why it's axis=0?
Z_mean[Z_mean == 0] = 1
Z /= Z_mean
Xs_new, Xt_new = Z[:, :ns].T, Z[:, ns:].T
global device
model = sklearn.svm.SVC(kernel='linear').fit(
Xs_new, Ys.ravel())
Y_tar_pseudo = model.predict(Xt_new)
# ipdb.set_trace()
acc = sklearn.metrics.mean_squared_error(
Y_tar_pseudo, Yt) # Yt is already in classes
# print(acc)
return Xs_new, Xt_new, A #, acc, Y_tar_pseudo, list_acc
# ## 1.b. Load Data
# In[55]:
Xs, Xt = bda_utils.load_data(if_weekday=1, if_interdet=1)
Xs = Xs[:, det:det + 1]
Xt = Xt[:, det:det + 1]
Xs, Xs_min, Xs_max = bda_utils.normalize2D(Xs)
Xt, Xt_min, Xt_max = bda_utils.normalize2D(Xt)
# In[56]:
# for i in range(Xs.shape[1]):
# plt.figure(figsize=[20,4])
# plt.plot(Xs[:, i])
# plt.plot(Xt[:, i])
# ## 1.d. Hyperparameters
# In[57]:
label_seq_len = 7
# batch_size = full batch
seq_len = 12
reduced_dim = 4
inp_dim = min(Xs.shape[1], Xt.shape[1])
label_dim = min(Xs.shape[1], Xt.shape[1])
hid_dim = 12
layers = 1
lamb = 2
MU = 0.7
bda_dim = label_seq_len - 4
kernel_type = 'linear'
hyper = {
'inp_dim': inp_dim,
'label_dim': label_dim,
'label_seq_len': label_seq_len,
'seq_len': seq_len,
'reduced_dim': reduced_dim,
'hid_dim': hid_dim,
'layers': layers,
'lamb': lamb,
'MU': MU,
'bda_dim': bda_dim,
'kernel_type': kernel_type
}
hyper = pd.DataFrame(hyper, index=['Values'])
# In[58]:
hyper
# ## 1.e. Apply BDA and get $Xs_{new}$, $Xt_{new}$
# In[59]:
Xs = Xs[:96, :]
# In[60]:
# [sample size, seq_len, inp_dim (dets)], [sample size, label_seq_len, inp_dim (dets)]
Xs_3d, Ys_3d = bda_utils.sliding_window(Xs, Xs, seq_len, label_seq_len)
Xt_3d, Yt_3d = bda_utils.sliding_window(Xt, Xt, seq_len, label_seq_len)
Ys_3d = Ys_3d[:, label_seq_len - 1:, :]
Yt_3d = Yt_3d[:, label_seq_len - 1:, :]
# print(Xs_3d.shape)
# print(Ys_3d.shape)
# print(Xt_3d.shape)
# print(Yt_3d.shape)
# In[64]:
t_s = time.time()
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
Xs_train_3d = []
Ys_train_3d = []
Xt_valid_3d = []
Xt_train_3d = []
Yt_valid_3d = []
Yt_train_3d = []
for i in range(Xs_3d.shape[2]):
# print('Starting det %i'%i)
bda = BDA(kernel_type='linear',
dim=seq_len - reduced_dim,
lamb=lamb,
mu=MU,
gamma=1,
T=2) # T is iteration time
Xs_new, Xt_new, A = bda.fit(
Xs_3d[:, :, i], bda_utils.get_class(Ys_3d[:, :, i]), Xt_3d[:, :,
i],
bda_utils.get_class(
Yt_3d[:, :,
i])) # input shape: ns, n_feature | ns, n_label_feature
# normalize
Xs_new, Xs_new_min, Xs_new_max = bda_utils.normalize2D(Xs_new)
Xt_new, Xt_new_min, Xt_new_max = bda_utils.normalize2D(Xt_new)
# print(Xs_new.shape)
# print(Xt_new.shape)
day_train_t = 1
Xs_train = Xs_new.copy()
Ys_train = Ys_3d[:, :, i]
Xt_valid = Xt_new.copy()[int(96 * day_train_t):, :]
Xt_train = Xt_new.copy()[:int(96 * day_train_t), :]
Yt_valid = Yt_3d[:, :, i].copy()[int(96 * day_train_t):, :]
Yt_train = Yt_3d[:, :, i].copy()[:int(96 * day_train_t), :]
Xs_train_3d.append(Xs_train)
Ys_train_3d.append(Ys_train)
Xt_valid_3d.append(Xt_valid)
Xt_train_3d.append(Xt_train)
Yt_valid_3d.append(Yt_valid)
Yt_train_3d.append(Yt_train)
Xs_train_3d = np.array(Xs_train_3d)
Ys_train_3d = np.array(Ys_train_3d)
Xt_valid_3d = np.array(Xt_valid_3d)
Xt_train_3d = np.array(Xt_train_3d)
Yt_valid_3d = np.array(Yt_valid_3d)
Yt_train_3d = np.array(Yt_train_3d)
# bda_utils.save_np(Xs_train_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Ys_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Xt_valid_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Xt_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Yt_valid_3d, './outputs/BDA/Xs_new_%i.csv'%(bda_utils.get_num()-14/6))
# bda_utils.save_np(Yt_train_3d, './outputs/BDA/Xt_new_%i.csv'%(bda_utils.get_num()-14/6))
# print('Time spent:%.5f'%(time.time()-t_s))
# In[65]:
Xs_train_3d = np.transpose(Xs_train_3d, (1, 2, 0))
Ys_train_3d = np.transpose(Ys_train_3d, (1, 2, 0))
Xt_valid_3d = np.transpose(Xt_valid_3d, (1, 2, 0))
Xt_train_3d = np.transpose(Xt_train_3d, (1, 2, 0))
Yt_valid_3d = np.transpose(Yt_valid_3d, (1, 2, 0))
Yt_train_3d = np.transpose(Yt_train_3d, (1, 2, 0))
# In[66]:
Ys_train_3d.shape
# # 2. Learning Part
# ## 2.a. Build network
# In[67]:
from bda_utils import traff_net_reg
# ## 2.b. Assemble Dataloader
# In[68]:
batch_size = 1960
train_x = np.vstack([Xs_train_3d, Xt_train_3d])
train_y = np.vstack([Ys_train_3d, Yt_train_3d])
train_x = torch.tensor(train_x, dtype=torch.float32).to(device)
train_y = torch.tensor(train_y, dtype=torch.float32).to(device)
Xt_valid_3d = torch.tensor(Xt_valid_3d, dtype=torch.float32).to(device)
Yt_valid_3d = torch.tensor(Yt_valid_3d, dtype=torch.float32).to(device)
train_dataset = TensorDataset(train_x, train_y)
train_loader = torch.utils.data.DataLoader(train_dataset,
batch_size,
shuffle=False)
train_iter = iter(train_loader)
# print(train_x.shape)
# print(train_y.shape)
# print('\n')
# print(Xt_valid_3d.shape)
# print(Yt_valid_3d.shape)
# ## 2.c. Learn
# In[69]:
# build model
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
net = traff_net_reg(inp_dim, label_dim, seq_len - reduced_dim,
label_seq_len).to(device)
criterion = nn.MSELoss()
#scheduler = torch.optim.lr_scheduler.StepLR(optimizer, 0.7)
train_loss_set = []
val_loss_set = []
det = 0 # which detector to visualize
num_fold = len(next(iter(os.walk('./runs/')))[1])
os.mkdir('./runs/run%i' % (num_fold + 1))
# In[70]:
optimizer = torch.optim.Adam(net.parameters())
# In[71]:
# train
net.train()
epochs = 1001
for e in range(epochs):
for i in range(len(train_loader)):
try:
data, label = train_iter.next()
except:
train_iter = iter(train_loader)
data, label = train_iter.next()
# ipdb.set_trace()
out = net(data)
loss = criterion(out, label[:, 0, 0].reshape(
-1, 1)) # label.shape=[batch, 1, num_dets]
optimizer.zero_grad()
loss.backward()
optimizer.step()
val_out = net(Xt_valid_3d)
val_loss = criterion(val_out, Yt_valid_3d[:, 0, 0].reshape(-1, 1))
val_loss_set.append(val_loss.cpu().detach().numpy())
train_loss_set.append(loss.cpu().detach().numpy())
if e % 50 == 0:
# # ipdb.set_trace()
# fig = plt.figure(figsize=[16,4])
# ax1 = fig.add_subplot(111)
# ax1.plot(bda_utils.get_class(label)[:, 0, det].cpu().detach().numpy(), label='ground truth')
# ax1.plot(100*out.cpu().detach().numpy(), label='predict')
# ax1.legend()
# plt.show()
# print('Epoch No. %i success, loss: %.5f, val loss: %.5f' %(e, loss.cpu().detach().numpy(), val_loss.cpu().detach().numpy() ))
## SAVE BEST MODEL
# initialize model
best_net = traff_net_reg(inp_dim, label_dim, seq_len - reduced_dim,
label_seq_len).to(device)
# load existing parameters, or create one
try:
best_net.load_state_dict(
torch.load('./runs/run%i/best.pth' % (num_fold + 1)))
except:
print('Saved initial model parameters')
bda_utils.save_model(net, 'best')
best_net = net
# try to calculate nrmse, or skip this loop
try:
nrmse_best = bda_utils.nrmse_loss_func(
best_net(Xt_valid_3d).cpu().detach().numpy().flatten(), \
Yt_valid_3d[:, 0, det].cpu().flatten().detach().numpy(), 0
)
nrmse = bda_utils.nrmse_loss_func(
val_out.cpu().detach().numpy().flatten(), \
Yt_valid_3d[:, 0, det].cpu().flatten().detach().numpy(), 0
)
except:
print('No feasible prediction, new model parameters saved')
bda_utils.save_model(net, 'best')
continue
if nrmse < nrmse_best:
print('Updated model parameters')
bda_utils.save_model(net, 'best')
bda_utils.save_model(net, 'last')
# In[43]:
# bda_utils.save_np(Xs_new, 'Xs_new.csv')
# In[72]:
# fig = plt.figure(figsize = [16, 4])
# ax1 = fig.add_subplot(121)
# ax1.plot(train_loss_set)
# ax1.set_xlabel('Epochs')
# ax1.set_ylabel('MSELoss')
# ax1.set_title('Train')
# ax2 = fig.add_subplot(122)
# ax2.plot(val_loss_set)
# ax2.set_xlabel('Epochs')
# ax2.set_ylabel('MSELoss')
# ax1.set_title('Validation')
# # 3. Evaluation
# In[73]:
best_net = traff_net_reg(inp_dim, label_dim, seq_len - reduced_dim,
label_seq_len).to(device)
best_net.load_state_dict(
torch.load('./runs/run%i/best.pth' % (num_fold + 1)))
val_out = best_net(Xt_valid_3d)
g_t = Yt_valid_3d[:, 0, det].cpu().flatten().detach().numpy()
pred = val_out.cpu().detach().numpy().flatten()
g_t = g_t * (Xt_max - Xt_min) + Xt_min
pred = pred * (Xt_max - Xt_min) + Xt_min
pred_ = pred.copy()
pred_[pred_ < 0] = 0
# plt.figure(figsize=[16,4])
# plt.plot(g_t, label='label')
# plt.plot(pred_, label='predict')
# plt.legend()
# In[74]:
# sklearn.metrics.accuracy_score(torch.argmax(val_out, dim=1).cpu(), bda_utils.get_class(Yt_valid_3d[:, 0, det]).cpu().flatten())
nrmse = bda_utils.nrmse_loss_func(pred_, g_t, 0)
mape = bda_utils.mape_loss_func(pred_, g_t, 0)
smape = bda_utils.smape_loss_func(pred_, g_t, 0)
mae = bda_utils.mae_loss_func(pred_, g_t, 0)
nmae = bda_utils.nmae_loss_func(pred, g_t, 0)
return nrmse, mape, smape, mae, nmae
def main(rs, det):
bda_utils.setup_seed(10)
# # 1. BDA Part
# ## 1.a. Define BDA methodology
# In[3]:
def kernel(ker, X1, X2, gamma):
K = None
if not ker or ker == 'primal':
K = X1
elif ker == 'linear':
if X2 is not None:
K = sklearn.metrics.pairwise.linear_kernel(
np.asarray(X1).T,
np.asarray(X2).T)
else:
K = sklearn.metrics.pairwise.linear_kernel(np.asarray(X1).T)
elif ker == 'rbf':
if X2 is not None:
K = sklearn.metrics.pairwise.rbf_kernel(
np.asarray(X1).T,
np.asarray(X2).T, gamma)
else:
K = sklearn.metrics.pairwise.rbf_kernel(
np.asarray(X1).T, None, gamma)
return K
def proxy_a_distance(source_X, target_X):
"""
Compute the Proxy-A-Distance of a source/target representation
"""
nb_source = np.shape(source_X)[0]
nb_target = np.shape(target_X)[0]
train_X = np.vstack((source_X, target_X))
train_Y = np.hstack(
(np.zeros(nb_source, dtype=int), np.ones(nb_target, dtype=int)))
clf = svm.LinearSVC(random_state=0)
clf.fit(train_X, train_Y)
y_pred = clf.predict(train_X)
error = metrics.mean_absolute_error(train_Y, y_pred)
dist = 2 * (1 - 2 * error)
return dist
def estimate_mu(_X1, _Y1, _X2, _Y2):
adist_m = proxy_a_distance(_X1, _X2)
C = len(np.unique(_Y1))
epsilon = 1e-3
list_adist_c = []
for i in range(1, C + 1):
ind_i, ind_j = np.where(_Y1 == i), np.where(_Y2 == i)
Xsi = _X1[ind_i[0], :]
Xtj = _X2[ind_j[0], :]
adist_i = proxy_a_distance(Xsi, Xtj)
list_adist_c.append(adist_i)
adist_c = sum(list_adist_c) / C
mu = adist_c / (adist_c + adist_m)
if mu > 1:
mu = 1
if mu < epsilon:
mu = 0
return mu
# In[4]:
class BDA:
def __init__(self,
kernel_type='primal',
dim=30,
lamb=1,
mu=0.5,
gamma=1,
T=10,
mode='BDA',
estimate_mu=False):
'''
Init func
:param kernel_type: kernel, values: 'primal' | 'linear' | 'rbf'
:param dim: dimension after transfer
:param lamb: lambda value in equation
:param mu: mu. Default is -1, if not specificied, it calculates using A-distance
:param gamma: kernel bandwidth for rbf kernel
:param T: iteration number
:param mode: 'BDA' | 'WBDA'
:param estimate_mu: True | False, if you want to automatically estimate mu instead of manally set it
'''
self.kernel_type = kernel_type
self.dim = dim
self.lamb = lamb
self.mu = mu
self.gamma = gamma
self.T = T
self.mode = mode
self.estimate_mu = estimate_mu
def fit(self, Xs, Ys, Xt, Yt):
'''
Transform and Predict using 1NN as JDA paper did
:param Xs: ns * n_feature, source feature
:param Ys: ns * 1, source label
:param Xt: nt * n_feature, target feature
:param Yt: nt * 1, target label
:return: acc, y_pred, list_acc
'''
# ipdb.set_trace()
list_acc = []
X = np.hstack((Xs.T, Xt.T)) # X.shape: [n_feature, ns+nt]
X_mean = np.linalg.norm(
X, axis=0) # why it's axis=0? the average of features
X_mean[X_mean == 0] = 1
X /= X_mean
m, n = X.shape
ns, nt = len(Xs), len(Xt)
e = np.vstack((1 / ns * np.ones((ns, 1)), -1 / nt * np.ones(
(nt, 1))))
C = np.unique(Ys)
H = np.eye(n) - 1 / n * np.ones((n, n))
mu = self.mu
M = 0
Y_tar_pseudo = None
Xs_new = None
for t in range(self.T):
# print('\tStarting iter %i'%t)
N = 0
M0 = e * e.T * len(C)
# ipdb.set_trace()
if Y_tar_pseudo is not None:
for i in range(len(C)):
e = np.zeros((n, 1))
Ns = len(Ys[np.where(Ys == C[i])])
Nt = len(Y_tar_pseudo[np.where(Y_tar_pseudo == C[i])])
if self.mode == 'WBDA':
Ps = Ns / len(Ys)
Pt = Nt / len(Y_tar_pseudo)
alpha = Pt / Ps
# mu = 1
else:
alpha = 1
tt = Ys == C[i]
e[np.where(tt == True)] = 1 / Ns
# ipdb.set_trace()
yy = Y_tar_pseudo == C[i]
ind = np.where(yy == True)
inds = [item + ns for item in ind]
try:
e[tuple(inds)] = -alpha / Nt
e[np.isinf(e)] = 0
except:
e[tuple(inds)] = 0 # ?
N = N + np.dot(e, e.T)
# ipdb.set_trace()
# In BDA, mu can be set or automatically estimated using A-distance
# In WBDA, we find that setting mu=1 is enough
if self.estimate_mu and self.mode == 'BDA':
if Xs_new is not None:
mu = estimate_mu(Xs_new, Ys, Xt_new, Y_tar_pseudo)
else:
mu = 0
# ipdb.set_trace()
M = (1 - mu) * M0 + mu * N
M /= np.linalg.norm(M, 'fro')
# ipdb.set_trace()
K = kernel(self.kernel_type, X, None, gamma=self.gamma)
n_eye = m if self.kernel_type == 'primal' else n
a, b = np.linalg.multi_dot([
K, M, K.T
]) + self.lamb * np.eye(n_eye), np.linalg.multi_dot(
[K, H, K.T])
w, V = scipy.linalg.eig(a, b)
ind = np.argsort(w)
A = V[:, ind[:self.dim]]
Z = np.dot(A.T, K)
Z_mean = np.linalg.norm(Z, axis=0) # why it's axis=0?
Z_mean[Z_mean == 0] = 1
Z /= Z_mean
Xs_new, Xt_new = Z[:, :ns].T, Z[:, ns:].T
global device
model = sklearn.svm.SVC(kernel='linear').fit(
Xs_new, Ys.ravel())
Y_tar_pseudo = model.predict(Xt_new)
# ipdb.set_trace()
acc = sklearn.metrics.mean_squared_error(
Y_tar_pseudo, Yt) # Yt is already in classes
# print(acc)
return Xs_new, Xt_new, A #, acc, Y_tar_pseudo, list_acc
# ## 1.b. Load Data
# In[5]:
Xs, Xt = bda_utils.load_data(if_weekday=1, if_interdet=1)
Xs = Xs[:, det:det + 1]
Xt = Xt[:, det:det + 1]
Xs, Xs_min, Xs_max = bda_utils.normalize2D(Xs)
Xt, Xt_min, Xt_max = bda_utils.normalize2D(Xt)
# In[6]:
# for i in range(Xs.shape[1]):
# plt.figure(figsize=[20,4])
# plt.plot(Xs[:, i])
# plt.plot(Xt[:, i])
# ## 1.d. Hyperparameters
# In[7]:
label_seq_len = 7
# batch_size = full batch
seq_len = 12
reduced_dim = 4
inp_dim = min(Xs.shape[1], Xt.shape[1])
label_dim = min(Xs.shape[1], Xt.shape[1])
hid_dim = 12
layers = 1
lamb = 2
MU = 0.7
bda_dim = label_seq_len - 4
kernel_type = 'linear'
hyper = {
'inp_dim': inp_dim,
'label_dim': label_dim,
'label_seq_len': label_seq_len,
'seq_len': seq_len,
'reduced_dim': reduced_dim,
'hid_dim': hid_dim,
'layers': layers,
'lamb': lamb,
'MU': MU,
'bda_dim': bda_dim,
'kernel_type': kernel_type
}
hyper = pd.DataFrame(hyper, index=['Values'])
# In[8]:
hyper
# ## 1.e. Apply BDA and get $Xs_{new}$, $Xt_{new}$
# In[9]:
Xs = Xs[:96, :]
# In[10]:
# [sample size, seq_len, inp_dim (dets)], [sample size, label_seq_len, inp_dim (dets)]
Xs_3d, Ys_3d = bda_utils.sliding_window(Xs, Xs, seq_len, label_seq_len)
Xt_3d, Yt_3d = bda_utils.sliding_window(Xt, Xt, seq_len, label_seq_len)
Ys_3d = Ys_3d[:, label_seq_len - 1:, :]
Yt_3d = Yt_3d[:, label_seq_len - 1:, :]
# print(Xs_3d.shape)
# print(Ys_3d.shape)
# print(Xt_3d.shape)
# print(Yt_3d.shape)
# In[11]:
t_s = time.time()
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
Xs_train_3d = []
Ys_train_3d = []
Xt_valid_3d = []
Xt_train_3d = []
Yt_valid_3d = []
Yt_train_3d = []
for i in range(Xs_3d.shape[2]):
# print('Starting det %i'%i)
bda = BDA(kernel_type='linear',
dim=seq_len - reduced_dim,
lamb=lamb,
mu=MU,
gamma=1,
T=2) # T is iteration time
Xs_new, Xt_new, A = bda.fit(
Xs_3d[:, :, i], bda_utils.get_class(Ys_3d[:, :, i]), Xt_3d[:, :,
i],
bda_utils.get_class(
Yt_3d[:, :,
i])) # input shape: ns, n_feature | ns, n_label_feature
# normalize
Xs_new, Xs_new_min, Xs_new_max = bda_utils.normalize2D(Xs_new)
Xt_new, Xt_new_min, Xt_new_max = bda_utils.normalize2D(Xt_new)
# print(Xs_new.shape)
# print(Xt_new.shape)
day_train_t = 1
Xs_train = Xs_new.copy()
Ys_train = Ys_3d[:, :, i]
Xt_valid = Xt_new.copy()[int(96 * day_train_t):, :]
Xt_train = Xt_new.copy()[:int(96 * day_train_t), :]
Yt_valid = Yt_3d[:, :, i].copy()[int(96 * day_train_t):, :]
Yt_train = Yt_3d[:, :, i].copy()[:int(96 * day_train_t), :]
# print('Time spent:%.5f'%(time.time()-t_s))
# In[12]:
# print(Xs_train.shape)
# print(Ys_train.shape)
# print(Xt_valid.shape)
# print(Xt_train.shape)
# print(Yt_valid.shape)
# print(Yt_train.shape)
# In[13]:
train_x = np.vstack([Xs_train, Xt_train])
train_y = np.vstack([Ys_train, Yt_train])
# # 2. Regression Part
# In[14]:
import xgboost as xgb
# In[15]:
regr = xgb.XGBRegressor(base_score=0.5,
booster='gbtree',
colsample_bylevel=1,
colsample_bynode=1,
colsample_bytree=1,
gamma=0,
importance_type='gain',
learning_rate=0.1,
max_delta_step=0,
max_depth=3,
min_child_weight=1,
missing=1,
n_estimators=100,
n_jobs=1,
nthread=None,
objective='reg:squarederror',
random_state=1,
reg_alpha=0,
reg_lambda=1,
scale_pos_weight=1,
seed=None,
silent=None,
subsample=1,
verbosity=1,
tree_method="hist")
regr.fit(train_x, train_y.flatten())
# # 3. Evaluation
# In[16]:
g_t = Yt_valid.flatten()
pred = regr.predict(Xt_valid)
# plt.figure(figsize=[16,4])
# plt.plot(g_t, label='label')
# plt.plot(pred, label='predict')
# plt.legend()
# In[17]:
nrmse = bda_utils.nrmse_loss_func(pred, g_t, 0)
mape = bda_utils.mape_loss_func(pred, g_t, 0)
smape = bda_utils.smape_loss_func(pred, g_t, 0)
mae = bda_utils.mae_loss_func(pred, g_t, 0)
nmae = bda_utils.nmae_loss_func(pred, g_t, 0)
return nrmse, mape, smape, mae, nmae
