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calc_statistics.py
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calc_statistics.py
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import os
import numpy as np
import scipy.optimize as op
import matplotlib.pyplot as plt
def compute_1nn(reals, fakes, obsv_len=2):
Real_pos = 0
Real_neg = 0
Fake_pos = 0
Fake_neg = 0
n_reals = reals.shape[0]
n_fakes = fakes.shape[0]
n_mixed = n_reals + n_fakes
nPed = reals.shape[1]
for kk in range(nPed):
mixed_sampels = []
D = np.ones((n_mixed, n_mixed)) * 1000
for ii in range(n_reals):
sample_and_label = [reals[ii, kk], [1]]
mixed_sampels.append(sample_and_label)
for ii in range(n_fakes):
sample_and_label = [fakes[ii, kk], [-1]]
mixed_sampels.append(sample_and_label)
for ii in range(0, n_mixed):
for jj in range(ii+1, n_mixed):
diff = mixed_sampels[ii][0][obsv_len:] - mixed_sampels[jj][0][obsv_len:]
dij = np.mean(np.sqrt(np.sum(np.power(diff, 2), 1)))
D[ii, jj], D[jj, ii] = dij, dij
for ii in range(0, n_mixed):
NN_ind = np.argmin(D[ii])
if mixed_sampels[ii][1][0] == 1 and mixed_sampels[NN_ind][1][0] == 1:
Real_pos += 1
elif mixed_sampels[ii][1][0] == 1 and mixed_sampels[NN_ind][1][0] == -1:
Real_neg += 1
elif mixed_sampels[ii][1][0] == -1 and mixed_sampels[NN_ind][1][0] == -1:
Fake_pos += 1
else: # if all_samples[ii][1][0] == -1 and all_samples[NN_ind][1][0] == 1:
Fake_neg += 1
return np.array([(Real_pos + Fake_pos) / (n_mixed * nPed), Real_pos/(n_reals*nPed), Fake_pos / (n_fakes*nPed)])
def compute_wasserstein(reals, fakes, obsv_len=2):
n_reals = reals.shape[0]
n_fakes = fakes.shape[0]
nPed = reals.shape[1]
cost = 0
for kk in range(nPed):
D = np.ones((n_reals, n_fakes)) * 1000
for ii in range(0, n_reals):
for jj in range(0, n_fakes):
diff = reals[ii, kk][obsv_len:] - fakes[jj, kk][obsv_len:]
dij = np.mean(np.sqrt(np.sum(np.power(diff, 2), 1)))
D[ii, jj], D[jj, ii] = dij, dij
row_ind, col_ind = op.linear_sum_assignment(D)
cost += D[row_ind, col_ind].sum()
# cost += np.sum(D)
return cost/(n_reals*nPed)
def calc_and_store_stats(main_dir):
stats_1nn = dict()
stats_wst = dict()
for dirpath, dirnames, filenames in sorted(os.walk(main_dir)):
cur_dir = dirpath[dirpath.rfind('/')+1:]
if not cur_dir.isdigit():
continue
epoch = int(cur_dir)
stat_1nn_i = 0
stat_wst_i = 0
n_files = 0
for ii, f in enumerate(sorted(filenames)):
if 'npz' not in f: continue
fake_data = np.load(os.path.join(dirpath, f))
fake_obsvs = fake_data['obsvs']
fake_preds = fake_data['preds_our']
nPed = fake_obsvs.shape[0]
if nPed < 6 : # FIXME: number of files
continue
K = real_samples.shape[0]
fake_obsvs = np.concatenate([fake_obsvs.reshape((1, nPed, 2, 2)) for _ in range(K)], axis=0)
fake_samples = np.concatenate((fake_obsvs.reshape(-1, 2, 2), fake_preds[:K].reshape(-1, 2, 2)), axis=1)
# fake_samples = fake_samples[:K]
stat_1nn = compute_1nn(real_samples.reshape(K, nPed, n_past+n_next, 2), fake_samples.reshape(K, nPed, n_past+n_next, 2))
stat_1nn_i += stat_1nn[0]
stat_wst_i += compute_wasserstein(real_samples.reshape(K, nPed, n_past+n_next, 2), fake_samples.reshape(K, nPed, n_past+n_next, 2))
n_files += 1
print(main_dir, 'epoch = %d, EMD = %.5f, 1nn = %.5f'
%(epoch, stat_wst_i/n_files, stat_1nn_i/n_files))
stats_1nn[epoch] = stat_1nn_i / n_files
stats_wst[epoch] = stat_wst_i / n_files
stats_wst_list = []
stats_1nn_list = []
keys_wst = sorted(stats_wst.keys(), reverse=False)
for key in keys_wst:
stats_wst_list.append(stats_wst[key])
keys_1nn = sorted(stats_1nn.keys(), reverse=False)
for key in keys_1nn:
stats_1nn_list.append(stats_1nn[key])
np.savez(stats_file, stats_1nn=stats_1nn_list, stats_wst=stats_wst_list)
def plot_stats_1nn(K_data=-1, interval=1, ind=-1):
stats_data = np.load(stats_file)
stats_1nn = stats_data['stats_1nn']
if K_data == -1: K_data = len(stats_1nn)
epc = [50 * nItr * (i+1) for i in range(0, K_data, interval)]
stats_1nn = [stats_1nn[i] * 100 for i in range(0, K_data, interval)]
label, = plt.plot(epc, stats_1nn, args[ind], LineWidth=1)
plt.fill_between(epc, stats_1nn, np.ones_like(stats_1nn) * 50, color=colors[ind], alpha=0.2)
print(epc)
print(stats_1nn)
return label
def plot_stats_wst(K_data=-1, interval=1, ind=-1):
stats_data = np.load(stats_file)
stats_wst = stats_data['stats_wst']
if K_data == -1: K_data = len(stats_wst)
epc = [50 * nItr * (i+1) for i in range(len(stats_wst))]
stats_wst = [stats_wst[i] * 1 for i in range(0, K_data, interval)]
label, = plt.plot(epc[:K_data], stats_wst[:K_data], args[ind], LineWidth=1)
plt.fill_between(epc[:K_data], stats_wst[:K_data], np.zeros_like(stats_wst)[:K_data] , color=colors[ind], alpha=0.2)
return label
def plot_dataset():
fig, ax = plt.subplots()
for ii in range(len(real_samples)):
# plt.plot(real_samples[ii, :2, 0], real_samples[ii, :2, 1], 'b')
plt.plot(real_samples[ii, 1:, 0], real_samples[ii, 1:, 1], 'r')
plt.plot(real_samples[ii, 0, 0], real_samples[ii, 0, 1], 'bo')
plt.plot(real_samples[ii, -1, 0], real_samples[ii, -1, 1], 'g.')
ax.arrow(real_samples[ii, 0, 0], real_samples[ii, 0, 1],
(real_samples[ii, 1, 0] -real_samples[ii, 0, 0]) * 0.85,
(real_samples[ii, 1, 1] -real_samples[ii, 0, 1]) * 0.85, head_width=0.03, head_length=0.04, fc='k', ec='b')
plt.xlim([-1.1, 1.1])
plt.ylim([-1, 1])
plt.show()
exit(1)
dataset_file = '../data/toy/toy-768.npz'
real = np.load(dataset_file)
real_obsv, real_pred, = real['obsvs'], real['preds']
real_samples = np.concatenate((real_obsv, real_pred), axis=1)
# plot_dataset()
#FIXME
num_samples = 20 # FIXME
real_samples = real_samples.reshape((-1, 6, 4, 2))[:num_samples]
n_samples = real_obsv.shape[0]
n_past = real_obsv.shape[1]
n_next = real_pred.shape[1]
# FIXME
main_dirs = (
'../preds-iccv/toy/VanillaGAN',
'../preds-iccv/toy/L2-GAN',
'../preds-iccv/toy/SGAN-V20',
'../preds-iccv/toy/Unrolled10+L2',
'../preds-iccv/toy/Info+Unrolled5',
'../preds-iccv/toy/Unrolled10',
'../preds-iccv/toy/InfoGAN',
)
colors = ['red', 'green', 'blue', 'cyan', 'yellow', 'magenta', 'black', 'orange', 'brown']
args = ['r--x', 'g--o', 'b--*', 'c--^', 'y--v', 'm--+', 'k--*', 'r--s', 'r-->']
fig = plt.figure(figsize=(12, 2.5), dpi=100, facecolor='w', edgecolor='k')
labels = []
legends = []
nItr = 63
for i, main_dir in enumerate(main_dirs):
stats_file = os.path.join(main_dir, 'stats' + str(num_samples) + '.npz')
if not os.path.exists(stats_file):
calc_and_store_stats(main_dir)
# labels.append(plot_stats_1nn(30, 1, i))
# plt.ylabel('1NN Accuracy %')
# plt.ylim([73, 104])
labels.append(plot_stats_wst(30, 1, i))
plt.ylabel('Earth Mover\'s Distance')
plt.ylim([-0.005, .12])
legends.append(main_dir[main_dir.rfind('/')+1:])
# plt.xlabel('Iteration')
plt.xlim([2000, 117000])
plt.legend(labels, legends, loc='lower right')
plt.grid(color='gray', linestyle='--', linewidth=1, alpha=0.2, axis='y')
fig.patch.set_visible(False)
ax = plt.gca()
ax.spines['top'].set_visible(False)
ax.spines['right'].set_visible(False)
plt.show()