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IP_osr_patches.py
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IP_osr_patches.py
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import os
import argparse
import datetime
import time
import importlib
import scipy.io as sio
import torch
import torch.nn as nn
from torch.optim import lr_scheduler
import torch.backends.cudnn as cudnn
from models import network
from core import train, test
from core.full_test import full_test
from generate_pic import aa_and_each_accuracy, sampling1, sampling2, sampling3, load_dataset, generate_png, generate_iter
from generate_pic import generate_train_iter, generate_valida_iter, generate_test_iter, generate_all_iter, generate_full_iter, generate_iter,generate_train_known_iter,generate_test_known_iter,generate_test_unknown_iter,generate_fulltest_iter
import numpy as np
from sklearn import metrics, preprocessing
from sklearn.metrics import accuracy_score
from sklearn.metrics import cohen_kappa_score
parser = argparse.ArgumentParser("Training")
# Dataset
parser.add_argument('--dataset', choices=['SA', 'PU', 'IP'], default='IP', help='dataset to use')
parser.add_argument('--patches', type=int, default=5, help='number of patches')
parser.add_argument('--num', type=int, default=30, help='number of samples')
# optimization
parser.add_argument('--batch-size', type=int, default=200)
parser.add_argument('--lr', type=float, default=0.001, help="learning rate for model")
parser.add_argument('--experiment_num', type=int, default=10)
parser.add_argument('--max-epoch', type=int, default=100)
parser.add_argument('--stepsize', type=int, default=20)
parser.add_argument('--temp', type=float, default=1.0, help="temp")
parser.add_argument('--num-centers', type=int, default=1)
# model
parser.add_argument('--weight-pl', type=float, default=0.1, help="weight for center loss")
parser.add_argument('--beta', type=float, default=0.1, help="weight for entropy loss")
parser.add_argument('--model', type=str, default='SSMLP-RPL')
parser.add_argument('--layers', type=int, default=4)
parser.add_argument('--embed_dims', type=int, default=64)
parser.add_argument('--segment_dim', type=int, default=8)
# misc
parser.add_argument('--nz', type=int, default=100)
parser.add_argument('--ns', type=int, default=1)
parser.add_argument('--eval-freq', type=int, default=100)
parser.add_argument('--print-freq', type=int, default=100)
parser.add_argument('--gpu', type=str, default='0')
parser.add_argument('--seed', type=int, default=0)
parser.add_argument('--use-cpu', action='store_true')
parser.add_argument('--save-dir', type=str, default='../log')
parser.add_argument('--loss', type=str, default='ARPLoss')
parser.add_argument('--eval', action='store_true', help="Eval", default=False)
parser.add_argument('--cs', action='store_true', help="Confusing Sample", default=False)
def get_accuracy(y_true, y_pred):
num_perclass = np.zeros(int(y_true.max() + 1))
num = np.zeros(int(y_true.max() + 1))
for i in range(len(y_true)):
num_perclass[int(y_true[i])] += 1
for i in range(len(y_pred)):
if y_pred[i] == y_true[i]:
num[int(y_pred[i])] += 1
for i in range(len(num)):
num[i] = num[i] / num_perclass[i]
acc = accuracy_score(y_true, y_pred)
kappa = cohen_kappa_score(y_true, y_pred)
ac = np.zeros(int(y_true.max() + 1 + 2))
ac[:int(y_true.max() + 1)] = num
ac[-1] = acc
ac[-2] = kappa
return ac # acc,num.mean(),kappa
if __name__ == '__main__':
args = parser.parse_args()
options = vars(args)
results = dict()
#path = 'D:/HSI_data/'
#path = '/media/lenovo/0A08DBEC08DBD533/syf/HSI_data/'
path = '/home/lenovo/data/syf/HSI_data/'
#path='/media/liubing/cc5992d7-d217-4ded-97b4-fd47f4fa55f4/syf/HSI_data/'
dataname=args.dataset
model_name='SSMLP-RPL'
data_hsi=sio.loadmat(path+'Indian_pines_corrected.mat')
data_hsi=data_hsi['indian_pines_corrected']
gt=sio.loadmat(path+'Indian_pines_gt.mat')
gt=gt['indian_pines_gt']
# training samples per class
SAMPLES_NUM = args.num
experiment_num=args.experiment_num
ROWS, COLUMNS, BAND = data_hsi.shape
data = data_hsi.reshape(np.prod(data_hsi.shape[:2]), np.prod(data_hsi.shape[2:]))
gt2 = gt.reshape(np.prod(gt.shape[:2]), )
CLASSES_NUM = gt.max()
print('The class numbers of the HSI data is:', CLASSES_NUM)
known = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14] # define the known classes
print('The known class of the HSI data is:', known)
unknown = list(set(list(range(0, gt.max()))) - set(known))
print('The unknown class of the HSI data is:', unknown)
print('-----Importing Setting Parameters-----')
patch_list=[7]
for i_patch in range(len(patch_list)):
patches=patch_list[i_patch]
PATCH_LENGTH = int((patches-1)/2)
# number of training samples per class
# lr, num_epochs, batch_size = 0.0001, 200, 32
img_rows = 2 * PATCH_LENGTH + 1
img_cols = 2 * PATCH_LENGTH + 1
INPUT_DIMENSION = data_hsi.shape[2]
FULL_SIZE = data_hsi.shape[0] * data_hsi.shape[1]
ALL_SIZE = data_hsi.shape[0] * data_hsi.shape[1]
data = preprocessing.scale(data)
whole_data = data.reshape(data_hsi.shape[0], data_hsi.shape[1], data_hsi.shape[2])
padded_data = np.lib.pad(whole_data, ((PATCH_LENGTH, PATCH_LENGTH), (PATCH_LENGTH, PATCH_LENGTH), (0, 0)),'symmetric')
Experiment_result = np.zeros([CLASSES_NUM + 7, experiment_num + 2])
for iter_num in range(experiment_num):
np.random.seed(iter_num+123456)
train_indices, test_indices = sampling1(SAMPLES_NUM, gt2, options['dataset'])
full_indices = sampling3(gt2, 1)
TRAIN_SIZE = len(train_indices)
VAL_SIZE = int(TRAIN_SIZE)
TEST_SIZE = len(test_indices)
if unknown == None:
#full_iter = generate_full_iter(whole_data, PATCH_LENGTH, padded_data, INPUT_DIMENSION, args.batch_size, gt2, FULL_SIZE,full_indices)
train_iter = generate_train_iter(TRAIN_SIZE, train_indices, whole_data, PATCH_LENGTH, padded_data, INPUT_DIMENSION,args.batch_size, gt2)
test_iter = generate_test_iter(TEST_SIZE, test_indices, VAL_SIZE, whole_data, PATCH_LENGTH, padded_data,INPUT_DIMENSION, args.batch_size, gt2)
known_test_iter = None
unknown_test_iter = None
else:
full_iter = generate_full_iter(whole_data, PATCH_LENGTH, padded_data, INPUT_DIMENSION, args.batch_size, gt2,FULL_SIZE, full_indices)
test_iter = generate_fulltest_iter(TEST_SIZE, test_indices, VAL_SIZE, whole_data, PATCH_LENGTH, padded_data,INPUT_DIMENSION, args.batch_size, gt2, known, CLASSES_NUM-1)
train_iter = generate_train_known_iter(TRAIN_SIZE, train_indices, whole_data, PATCH_LENGTH, padded_data,INPUT_DIMENSION, args.batch_size, gt2, known, augmentation=True)
known_test_iter = generate_test_known_iter(TEST_SIZE, test_indices, VAL_SIZE, whole_data, PATCH_LENGTH, padded_data,INPUT_DIMENSION, args.batch_size, gt2, known)
unknown_test_iter = generate_test_unknown_iter(TEST_SIZE, test_indices, VAL_SIZE, whole_data, PATCH_LENGTH, padded_data,INPUT_DIMENSION, args.batch_size, gt2, unknown, CLASSES_NUM-1)
options.update(
{
'BAND':BAND,
'known': known,
'unknown': unknown,
'full_iter' : full_iter,
'test_iter' : test_iter,
'train_iter': train_iter,
'known_test_iter' : known_test_iter,
'unknown_test_iter' : unknown_test_iter,
}
)
torch.manual_seed(options['seed'])
os.environ['CUDA_VISIBLE_DEVICES'] = options['gpu']
use_gpu = torch.cuda.is_available()
if options['use_cpu']: use_gpu = False
if use_gpu:
print("Currently using GPU: {}".format(options['gpu']))
cudnn.benchmark = True
torch.cuda.manual_seed_all(options['seed'])
else:
print("Currently using CPU")
# Dataset
print("{} Preparation".format(options['dataset']))
if options['unknown'] == None:
trainloader, testloader, outloader = options['train_iter'], options['test_iter'], None
else:
trainloader, full_testloader, full_loader, testloader, outloader = options['train_iter'], options['test_iter'], \
options['full_iter'], options[
'known_test_iter'], options[
'unknown_test_iter']
# unknow=options['unknown'][0]
# Model
print("Creating model: {}".format(options['model']))
options['num_classes'] = len(options['known'])
unknow = options['num_classes']
net = network.SSMLP(patches, options['BAND'], options['num_classes'], layers=options['layers'], embed_dims=options['embed_dims'],segment_dim=options['segment_dim'])
feat_dim = options['embed_dims']
# feat_dim = 128
# Loss
options.update(
{
'feat_dim': feat_dim,
'use_gpu': use_gpu
}
)
Loss = importlib.import_module('loss.' + options['loss'])
criterion = getattr(Loss, options['loss'])(**options)
if use_gpu:
net = nn.DataParallel(net).cuda()
criterion = criterion.cuda()
params_list = [{'params': net.parameters()},
{'params': criterion.parameters()}]
# optimizer = torch.optim.SGD(params_list, lr=options['lr'], momentum=0.9, weight_decay=1e-4)
optimizer = torch.optim.Adam(params_list, lr=options['lr'])
if options['stepsize'] > 0:
scheduler = lr_scheduler.MultiStepLR(optimizer, milestones=[30, 60, 90, 120])
start_time = time.time()
for epoch in range(options['max_epoch']):
print("==> Epoch {}/{}".format(epoch + 1, options['max_epoch']))
_, logits_min, dis_min, loss_r = train(net, criterion, optimizer, trainloader, epoch=epoch, **options)
#if options['eval_freq'] > 0 and (epoch + 1) % options['eval_freq'] == 0 or (epoch + 1) == options['max_epoch']:
# print("==> Test", options['loss'])
#results, pred, label = test(net, criterion, full_testloader, testloader, outloader, logits_min, dis_min,
# loss_r, unknow, epoch=epoch, **options)
#print("Acc (%): {:.3f}\t AUROC (%): {:.3f}\t OSCR (%): {:.3f}\t".format(results['ACC'], results['AUROC'],
# results['OSCR']))
# save_networks(net, model_path, file_name, criterion=criterion)
if options['stepsize'] > 0: scheduler.step()
train_time2=time.time()
tes_time1=time.time()
results, pred, label = test(net, criterion, full_testloader, testloader, outloader, logits_min, dis_min,loss_r, unknow, epoch=epoch, **options)
print("Acc (%): {:.3f}\t AUROC (%): {:.3f}\t OSCR (%): {:.3f}\t".format(results['ACC'], results['AUROC'],results['OSCR']))
tes_time2=time.time()
#pred_global = full_test(net, criterion, full_testloader, full_loader, testloader, outloader, logits_min, dis_min,loss_r, unknow, epoch=epoch, **options)
#generate_png(gt, pred_global, dataname, ROWS, COLUMNS, SAMPLES_NUM)
ac = get_accuracy(label, pred)
# ac2 = get_accuracy(_labels, _pred)
elapsed = round(time.time() - start_time)
elapsed = str(datetime.timedelta(seconds=elapsed))
print("Finished. Total elapsed time (h:m:s): {}".format(elapsed))
Experiment_result[0, iter_num] = ac[-1] * 100 # OA
Experiment_result[1, iter_num] = np.mean(ac[:-2]) * 100 # AA
Experiment_result[2, iter_num] = ac[-2] * 100 # Kappa
Experiment_result[3, iter_num] = results['ACC'] #Closed-set OA
Experiment_result[4, iter_num] = results['OSCR'] #OSCR
Experiment_result[5, iter_num] = train_time2 - start_time
Experiment_result[6, iter_num] = tes_time2 - tes_time1
Experiment_result[7:, iter_num] = ac[:-2] * 100
print('########### Experiment {},Model assessment Finished! ###########'.format(iter_num))
########## mean value & standard deviation #############
Experiment_result[:, -2] = np.mean(Experiment_result[:, 0:-2], axis=1) # 计算均值
Experiment_result[:, -1] = np.std(Experiment_result[:, 0:-2], axis=1) # 计算平均差
day = datetime.datetime.now()
day_str = day.strftime('%m_%d_%H_%M')
f = open('./record/' + dataname + '/' + str(day_str) + '_' + dataname + '_' + model_name + '_' +str(SAMPLES_NUM)+ '_num_patch='+str(patches)+'_layers='+str(options['layers'])+'_embed_dims='+str(options['embed_dims'])+'_segment_dim='+str(options['segment_dim'])+'.txt','w')
for i in range(Experiment_result.shape[0]):
f.write(str(i + 1) + ':' + str(round(Experiment_result[i, -2], 2)) + '+/-' + str(
round(Experiment_result[i, -1], 2)) + '\n')
for i in range(Experiment_result.shape[1] - 2):
f.write('Experiment_num' + str(i) + '_open_OA:' + str(Experiment_result[0, i]) + '\n')
for i in range(Experiment_result.shape[1] - 2):
f.write('Experiment_num' + str(i) + '_closed_OA:' + str(Experiment_result[3, i]) + '\n')
f.close()