def test_latent_node_boxes_latent_subgradient():
# same as above, now with elementary subgradients
# learn the "easy" 2x2 boxes dataset.
# a 2x2 box is placed randomly in a 4x4 grid
# we add a latent variable for each 2x2 patch
# that should make the model fairly simple
X, Y = toy.make_simple_2x2(seed=1)
latent_crf = LatentNodeCRF(n_labels=2, inference_method='lp',
n_hidden_states=2, n_features=1)
latent_svm = LatentSubgradientSSVM(model=latent_crf, max_iter=250, C=10,
verbose=10, learning_rate=0.1,
momentum=0)
G = [make_grid_edges(x) for x in X]
# make edges for hidden states:
edges = []
node_indices = np.arange(4 * 4).reshape(4, 4)
for i, (x, y) in enumerate(itertools.product([0, 2], repeat=2)):
for j in xrange(x, x + 2):
for k in xrange(y, y + 2):
edges.append([i + 4 * 4, node_indices[j, k]])
G = [np.vstack([make_grid_edges(x), edges]) for x in X]
# reshape / flatten x and y
X_flat = [x.reshape(-1, 1) for x in X]
Y_flat = [y.ravel() for y in Y]
X_ = zip(X_flat, G, [4 * 4 for x in X_flat])
latent_svm.fit(X_, Y_flat)
assert_equal(latent_svm.score(X_, Y_flat), 1)
def test_latent_node_boxes_edge_features():
# learn the "easy" 2x2 boxes dataset.
# smoketest using a single constant edge feature
X, Y = make_simple_2x2(seed=1, n_samples=40)
latent_crf = EdgeFeatureLatentNodeCRF(n_labels=2, n_hidden_states=2, n_features=1)
base_svm = OneSlackSSVM(latent_crf)
base_svm.C = 10
latent_svm = LatentSSVM(base_svm,
latent_iter=10)
G = [make_grid_edges(x) for x in X]
# make edges for hidden states:
edges = make_edges_2x2()
G = [np.vstack([make_grid_edges(x), edges]) for x in X]
# reshape / flatten x and y
X_flat = [x.reshape(-1, 1) for x in X]
Y_flat = [y.ravel() for y in Y]
#X_ = zip(X_flat, G, [2 * 2 for x in X_flat])
# add edge features
X_ = [(x, g, np.ones((len(g), 1)), 4) for x, g in zip(X_flat, G)]
latent_svm.fit(X_[:20], Y_flat[:20])
assert_array_equal(latent_svm.predict(X_[:20]), Y_flat[:20])
assert_equal(latent_svm.score(X_[:20], Y_flat[:20]), 1)
# test that score is not always 1
assert_true(.98 < latent_svm.score(X_[20:], Y_flat[20:]) < 1)
def test_latent_node_boxes_standard_latent():
# learn the "easy" 2x2 boxes dataset.
# a 2x2 box is placed randomly in a 4x4 grid
# we add a latent variable for each 2x2 patch
# that should make the model fairly simple
X, Y = make_simple_2x2(seed=1, n_samples=40)
latent_crf = LatentNodeCRF(n_labels=2, n_hidden_states=2, n_features=1)
one_slack = OneSlackSSVM(latent_crf)
n_slack = NSlackSSVM(latent_crf)
subgradient = SubgradientSSVM(latent_crf, max_iter=100)
for base_svm in [one_slack, n_slack, subgradient]:
base_svm.C = 10
latent_svm = LatentSSVM(base_svm,
latent_iter=10)
G = [make_grid_edges(x) for x in X]
# make edges for hidden states:
edges = make_edges_2x2()
G = [np.vstack([make_grid_edges(x), edges]) for x in X]
# reshape / flatten x and y
X_flat = [x.reshape(-1, 1) for x in X]
Y_flat = [y.ravel() for y in Y]
X_ = list(zip(X_flat, G, [2 * 2 for x in X_flat]))
latent_svm.fit(X_[:20], Y_flat[:20])
assert_array_equal(latent_svm.predict(X_[:20]), Y_flat[:20])
assert_equal(latent_svm.score(X_[:20], Y_flat[:20]), 1)
# test that score is not always 1
assert_true(.98 < latent_svm.score(X_[20:], Y_flat[20:]) < 1)
def test_k_means_initialization():
n_samples = 10
X, Y = generate_big_checker(n_samples=n_samples)
edges = [make_grid_edges(x, return_lists=True) for x in X]
# flatten the grid
Y = Y.reshape(Y.shape[0], -1)
X = X.reshape(X.shape[0], -1, X.shape[-1])
n_labels = len(np.unique(Y))
X = X.reshape(n_samples, -1, n_labels)
# sanity check for one state
H = kmeans_init(X,
Y,
edges,
n_states_per_label=[1] * n_labels,
n_labels=n_labels)
H = np.vstack(H)
assert_array_equal(Y, H)
# check number of states
H = kmeans_init(X,
Y,
edges,
n_states_per_label=[3] * n_labels,
n_labels=n_labels)
H = np.vstack(H)
assert_array_equal(np.unique(H), np.arange(6))
assert_array_equal(Y, H / 3)
# for dataset with more than two states
X, Y = generate_blocks_multinomial(n_samples=10)
edges = [make_grid_edges(x, return_lists=True) for x in X]
Y = Y.reshape(Y.shape[0], -1)
X = X.reshape(X.shape[0], -1, X.shape[-1])
n_labels = len(np.unique(Y))
# sanity check for one state
H = kmeans_init(X,
Y,
edges,
n_states_per_label=[1] * n_labels,
n_labels=n_labels)
H = np.vstack(H)
assert_array_equal(Y, H)
# check number of states
H = kmeans_init(X,
Y,
edges,
n_states_per_label=[2] * n_labels,
n_labels=n_labels)
H = np.vstack(H)
assert_array_equal(np.unique(H), np.arange(6))
assert_array_equal(Y, H / 2)
def prepare_data_to_graph_crf(self):
from pystruct.utils import make_grid_edges, edge_list_to_features
self.X_flatten = []
self.y_flatten = []
for pic_i, pic_nd_array in enumerate(self.X):
pic_item = list()
cell_index_place = 0
for row_i, row_val in enumerate(pic_nd_array): # pic item
for col_i, cell_features in enumerate(row_val): # pic row iteration cell by cell
pic_item.append(cell_features)
if self.models_parameters['neighborhood'] == 4:
right, down = make_grid_edges(pic_nd_array, neighborhood=4, return_lists=True)
# right, down, upright, downright = make_grid_edges(pic_nd_array, neighborhood=8, return_lists=True)
edges = np.vstack([right, down])
elif self.models_parameters['neighborhood'] == 8:
right, down, upright, downright = make_grid_edges(pic_nd_array, neighborhood=8, return_lists=True)
edges = np.vstack([right, down, upright, downright])
# for val in range
# Guy version - old
# edges_item = list()
# max_cell_index = self.row_threshold * self.row_threshold
# last_row_first_index = max_cell_index - self.row_threshold # e.g. 36-6
# for i in range(0, max_cell_index):
# if i<last_row_first_index: # except last row
# edges_item.append(np.array([i, i + self.row_threshold]))
#
# if (i+1)%self.row_threshold != 0: # except last col
# edges_item.append(np.array([i, i + 1]))
# finish iterate picture
self.X_flatten.append((np.array(pic_item), edges))
for pic_i, pic_nd_array in enumerate(self.y):
pic_item = list()
for row_i, row_val in enumerate(pic_nd_array): # pic item
for col_i, cell_features in enumerate(row_val): # pic row iteration cell by cell
pic_item.append(cell_features)
self.y_flatten.append(pic_item)
self.X = np.array(self.X_flatten)
self.y = np.array(self.y_flatten)
return
def test_energy_continuous():
# make sure that energy as computed by ssvm is the same as by lp
np.random.seed(0)
for inference_method in get_installed(["lp", "ad3"]):
found_fractional = False
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2,
n_features=3)
while not found_fractional:
x = np.random.normal(size=(7, 8, 3))
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
unary_params = np.random.normal(size=(3, 3))
pw1 = np.random.normal(size=(3, 3))
pw2 = np.random.normal(size=(3, 3))
w = np.hstack([unary_params.ravel(), pw1.ravel(), pw2.ravel()])
res, energy = crf.inference(x, w, relaxed=True, return_energy=True)
found_fractional = np.any(np.max(res[0], axis=-1) != 1)
psi = crf.psi(x, res)
energy_svm = np.dot(psi, w)
assert_almost_equal(energy, -energy_svm)
def prepare_data(X):
X_directions = []
X_edge_features = []
for x in X:
# get edges in grid
right, down = make_grid_edges(x, return_lists=True)
edges = np.vstack([right, down])
# use 3x3 patch around each point
features = neighborhood_feature(x)
# simple edge feature that encodes just if an edge is horizontal or
# vertical
edge_features_directions = edge_list_to_features([right, down])
# edge feature that contains features from the nodes that the edge connects
edge_features = np.zeros((edges.shape[0], features.shape[1], 4))
edge_features[:len(right), :, 0] = features[right[:, 0]]
edge_features[:len(right), :, 1] = features[right[:, 1]]
#---ORIGINAL CODE
# edge_features[len(right):, :, 0] = features[down[:, 0]]
# edge_features[len(right):, :, 1] = features[down[:, 1]]
edge_features[len(right):, :, 2] = features[down[:, 0]]
edge_features[len(right):, :, 3] = features[down[:, 1]]
#---END OF FIX
edge_features = edge_features.reshape(edges.shape[0], -1)
X_directions.append((features, edges, edge_features_directions))
X_edge_features.append((features, edges, edge_features))
return X_directions, X_edge_features
def test_joint_feature_discrete():
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
y_flat = y.ravel()
for inference_method in get_installed(["lp", "ad3", "qpbo"]):
crf = EdgeFeatureGraphCRF(inference_method=inference_method)
crf.initialize([x], [y_flat])
joint_feature_y = crf.joint_feature(x, y_flat)
assert_equal(joint_feature_y.shape, (crf.size_joint_feature, ))
# first horizontal, then vertical
# we trust the unaries ;)
pw_joint_feature_horz, pw_joint_feature_vert = joint_feature_y[
crf.n_states * crf.n_features:].reshape(2, crf.n_states,
crf.n_states)
xx, yy = np.indices(y.shape)
assert_array_equal(pw_joint_feature_vert,
np.diag([9 * 4, 9 * 4, 9 * 4]))
vert_joint_feature = np.diag([10 * 3, 10 * 3, 10 * 3])
vert_joint_feature[0, 1] = 10
vert_joint_feature[1, 2] = 10
assert_array_equal(pw_joint_feature_horz, vert_joint_feature)
def test_multinomial_blocks_directional_anti_symmetric():
# testing cutting plane ssvm with directional CRF on easy multinomial
# dataset
X_, Y_ = toy.generate_blocks_multinomial(n_samples=10, noise=0.3, seed=0)
G = [make_grid_edges(x, return_lists=True) for x in X_]
edge_features = [edge_list_to_features(edge_list) for edge_list in G]
edges = [np.vstack(g) for g in G]
X = zip([x.reshape(-1, 3) for x in X_], edges, edge_features)
Y = [y.ravel() for y in Y_]
for inference_method in ['lp', 'ad3']:
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2,
symmetric_edge_features=[0],
antisymmetric_edge_features=[1])
clf = StructuredSVM(model=crf, max_iter=20, C=1000, verbose=10,
check_constraints=False, n_jobs=-1)
clf.fit(X, Y)
Y_pred = clf.predict(X)
assert_array_equal(Y, Y_pred)
pairwise_params = clf.w[-9 * 2:].reshape(2, 3, 3)
sym = pairwise_params[0]
antisym = pairwise_params[1]
print(sym)
print(antisym)
assert_array_equal(sym, sym.T)
assert_array_equal(antisym, -antisym.T)
def test_psi_discrete():
X, Y = toy.generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
y_flat = y.ravel()
for inference_method in ["lp", "ad3", "qpbo"]:
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2)
psi_y = crf.psi(x, y_flat)
assert_equal(psi_y.shape, (crf.size_psi,))
# first horizontal, then vertical
# we trust the unaries ;)
pw_psi_horz, pw_psi_vert = psi_y[crf.n_states *
crf.n_features:].reshape(
2, crf.n_states, crf.n_states)
xx, yy = np.indices(y.shape)
assert_array_equal(pw_psi_vert, np.diag([9 * 4, 9 * 4, 9 * 4]))
vert_psi = np.diag([10 * 3, 10 * 3, 10 * 3])
vert_psi[0, 1] = 10
vert_psi[1, 2] = 10
assert_array_equal(pw_psi_horz, vert_psi)
def test_initialization():
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, n_states), edges, edge_features)
y = y.ravel()
crf = EdgeFeatureGraphCRF()
crf.initialize([x], [y])
assert_equal(crf.n_edge_features, 2)
assert_equal(crf.n_features, 3)
assert_equal(crf.n_states, 3)
crf = EdgeFeatureGraphCRF(n_states=3,
n_features=3,
n_edge_features=2)
# no-op
crf.initialize([x], [y])
crf = EdgeFeatureGraphCRF(n_states=4,
n_edge_features=2)
# incompatible
assert_raises(ValueError, crf.initialize, X=[x], Y=[y])
def generate_Potts(shape=(10, 10),
ncolors=2,
beta=1.0,
inference='max-product'):
"""Generate Potts image."""
# Generate initial normal image
x = rnd.normal(size=(*shape, ncolors))
# Unary potentials
unaries = x.reshape(-1, ncolors)
# Pairwise potentials
pairwise = beta*np.eye(ncolors)
# Generate edge matrix
edges = make_grid_edges(x)
# Start clock
start = time()
# Infer image
y = inference_dispatch(unaries, pairwise, edges,
inference_method=inference)
# End clock
took = time() - start
print('Inference took ' + str(took) + ' seconds')
# Compute energy
energy = compute_energy(unaries, pairwise, edges, y)
# Return inferred image and energy
return np.reshape(y, shape), energy
def test_binary_blocks_cutting_plane():
#testing cutting plane ssvm on easy binary dataset
# generate graphs explicitly for each example
for inference_method in get_installed(["lp", "qpbo", "ad3", 'ogm']):
X, Y = generate_blocks(n_samples=3)
crf = GraphCRF(inference_method=inference_method)
clf = NSlackSSVM(model=crf, max_iter=20, C=100, check_constraints=True,
break_on_bad=False, n_jobs=1)
x1, x2, x3 = X
y1, y2, y3 = Y
n_states = len(np.unique(Y))
# delete some rows to make it more fun
x1, y1 = x1[:, :-1], y1[:, :-1]
x2, y2 = x2[:-1], y2[:-1]
# generate graphs
X_ = [x1, x2, x3]
G = [make_grid_edges(x) for x in X_]
# reshape / flatten x and y
X_ = [x.reshape(-1, n_states) for x in X_]
Y = [y.ravel() for y in [y1, y2, y3]]
X = list(zip(X_, G))
clf.fit(X, Y)
Y_pred = clf.predict(X)
for y, y_pred in zip(Y, Y_pred):
assert_array_equal(y, y_pred)
def test_energy_discrete():
for inference_method in get_installed(["qpbo", "ad3"]):
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2, n_features=3)
for i in xrange(10):
x = np.random.normal(size=(7, 8, 3))
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
unary_params = np.random.normal(size=(3, 3))
pw1 = np.random.normal(size=(3, 3))
pw2 = np.random.normal(size=(3, 3))
w = np.hstack([unary_params.ravel(), pw1.ravel(), pw2.ravel()])
y_hat = crf.inference(x, w, relaxed=False)
energy = compute_energy(crf._get_unary_potentials(x, w),
crf._get_pairwise_potentials(x, w), edges,
y_hat)
joint_feature = crf.joint_feature(x, y_hat)
energy_svm = np.dot(joint_feature, w)
assert_almost_equal(energy, energy_svm)
def prepare_data(X):
X_directions = []
X_edge_features = []
for x in X:
# get edges in grid
right, down = make_grid_edges(x, return_lists=True)
edges = np.vstack([right, down])
# use 3x3 patch around each point
features = neighborhood_feature(x)
# simple edge feature that encodes just if an edge is horizontal or
# vertical
edge_features_directions = edge_list_to_features([right, down])
# edge feature that contains features from the nodes that the edge connects
edge_features = np.zeros((edges.shape[0], features.shape[1], 4))
edge_features[:len(right), :, 0] = features[right[:, 0]]
edge_features[:len(right), :, 1] = features[right[:, 1]]
#---ORIGINAL CODE
# edge_features[len(right):, :, 0] = features[down[:, 0]]
# edge_features[len(right):, :, 1] = features[down[:, 1]]
edge_features[len(right):, :, 2] = features[down[:, 0]]
edge_features[len(right):, :, 3] = features[down[:, 1]]
#---END OF FIX
edge_features = edge_features.reshape(edges.shape[0], -1)
X_directions.append((features, edges, edge_features_directions))
X_edge_features.append((features, edges, edge_features))
return X_directions, X_edge_features
def test_joint_feature_continuous():
# FIXME
# first make perfect prediction, including pairwise part
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
y = y.ravel()
pw_horz = -1 * np.eye(n_states)
xx, yy = np.indices(pw_horz.shape)
# linear ordering constraint horizontally
pw_horz[xx > yy] = 1
# high cost for unequal labels vertically
pw_vert = -1 * np.eye(n_states)
pw_vert[xx != yy] = 1
pw_vert *= 10
# create crf, assemble weight, make prediction
for inference_method in get_installed(["lp", "ad3"]):
crf = EdgeFeatureGraphCRF(inference_method=inference_method)
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
crf.initialize([x], [y])
y_pred = crf.inference(x, w, relaxed=True)
# compute joint_feature for prediction
joint_feature_y = crf.joint_feature(x, y_pred)
assert_equal(joint_feature_y.shape, (crf.size_joint_feature,))
def test_psi_continuous():
# FIXME
# first make perfect prediction, including pairwise part
X, Y = toy.generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
y = y.ravel()
pw_horz = -1 * np.eye(n_states)
xx, yy = np.indices(pw_horz.shape)
# linear ordering constraint horizontally
pw_horz[xx > yy] = 1
# high cost for unequal labels vertically
pw_vert = -1 * np.eye(n_states)
pw_vert[xx != yy] = 1
pw_vert *= 10
# create crf, assemble weight, make prediction
for inference_method in ["lp", "ad3"]:
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2)
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=True)
# compute psi for prediction
psi_y = crf.psi(x, y_pred)
assert_equal(psi_y.shape, (crf.size_psi,))
def test_energy_continuous():
# make sure that energy as computed by ssvm is the same as by lp
np.random.seed(0)
for inference_method in get_installed(["lp", "ad3"]):
found_fractional = False
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2, n_features=3)
while not found_fractional:
x = np.random.normal(size=(7, 8, 3))
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
unary_params = np.random.normal(size=(3, 3))
pw1 = np.random.normal(size=(3, 3))
pw2 = np.random.normal(size=(3, 3))
w = np.hstack([unary_params.ravel(), pw1.ravel(), pw2.ravel()])
res, energy = crf.inference(x, w, relaxed=True, return_energy=True)
found_fractional = np.any(np.max(res[0], axis=-1) != 1)
joint_feature = crf.joint_feature(x, res)
energy_svm = np.dot(joint_feature, w)
assert_almost_equal(energy, -energy_svm)
def test_energy_continuous():
# make sure that energy as computed by ssvm is the same as by lp
np.random.seed(0)
#for inference_method in get_installed(["lp", "ad3"]):
if True:
found_fractional = False
crf = NodeTypeEdgeFeatureGraphCRF(1, [3], [3], [[2]])
while not found_fractional:
x = np.random.normal(size=(7, 8, 3))
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = ([x.reshape(-1, 3)], [edges], [edge_features])
unary_params = np.random.normal(size=(3, 3))
pw1 = np.random.normal(size=(3, 3))
pw2 = np.random.normal(size=(3, 3))
w = np.hstack([unary_params.ravel(), pw1.ravel(), pw2.ravel()])
crf.initialize(x)
res, energy = crf.inference(x, w, relaxed=True, return_energy=True)
found_fractional = np.any(np.max(res[0], axis=-1) != 1)
joint_feature = crf.joint_feature(x, res)
energy_svm = np.dot(joint_feature, w)
assert_almost_equal(energy, -energy_svm)
def test_energy_discrete():
# for inference_method in get_installed(["qpbo", "ad3"]):
# crf = EdgeFeatureGraphCRF(n_states=3,
# inference_method=inference_method,
# n_edge_features=2, n_features=3)
crf = NodeTypeEdgeFeatureGraphCRF(1, [3], [3], [[2]])
for i in range(10):
x = np.random.normal(size=(7, 8, 3))
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = ([x.reshape(-1, 3)], [edges], [edge_features])
unary_params = np.random.normal(size=(3, 3))
pw1 = np.random.normal(size=(3, 3))
pw2 = np.random.normal(size=(3, 3))
w = np.hstack([unary_params.ravel(), pw1.ravel(), pw2.ravel()])
crf.initialize(x)
y_hat = crf.inference(x, w, relaxed=False)
#flat_edges = crf._index_all_edges(x)
energy = compute_energy(crf._get_unary_potentials(x, w)[0],
crf._get_pairwise_potentials(x, w)[0], edges, #CAUTION: pass the flatened edges!!
y_hat)
joint_feature = crf.joint_feature(x, y_hat)
energy_svm = np.dot(joint_feature, w)
assert_almost_equal(energy, energy_svm)
def test_binary_blocks_one_slack_graph():
#testing cutting plane ssvm on easy binary dataset
# generate graphs explicitly for each example
for inference_method in ["dai", "lp"]:
print("testing %s" % inference_method)
X, Y = toy.generate_blocks(n_samples=3)
crf = GraphCRF(inference_method=inference_method)
clf = OneSlackSSVM(problem=crf, max_iter=100, C=100, verbose=100,
check_constraints=True, break_on_bad=True,
n_jobs=1)
x1, x2, x3 = X
y1, y2, y3 = Y
n_states = len(np.unique(Y))
# delete some rows to make it more fun
x1, y1 = x1[:, :-1], y1[:, :-1]
x2, y2 = x2[:-1], y2[:-1]
# generate graphs
X_ = [x1, x2, x3]
G = [make_grid_edges(x) for x in X_]
# reshape / flatten x and y
X_ = [x.reshape(-1, n_states) for x in X_]
Y = [y.ravel() for y in [y1, y2, y3]]
X = zip(X_, G)
clf.fit(X, Y)
Y_pred = clf.predict(X)
for y, y_pred in zip(Y, Y_pred):
assert_array_equal(y, y_pred)
def test_edge_feature_latent_node_crf_no_latent():
# no latent nodes
# Test inference with different weights in different directions
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1, size_x=10)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
pw_horz = -1 * np.eye(n_states + 5)
xx, yy = np.indices(pw_horz.shape)
# linear ordering constraint horizontally
pw_horz[xx > yy] = 1
# high cost for unequal labels vertically
pw_vert = -1 * np.eye(n_states + 5)
pw_vert[xx != yy] = 1
pw_vert *= 10
# generate edge weights
edge_weights_horizontal = np.repeat(pw_horz[np.newaxis, :, :],
edge_list[0].shape[0], axis=0)
edge_weights_vertical = np.repeat(pw_vert[np.newaxis, :, :],
edge_list[1].shape[0], axis=0)
edge_weights = np.vstack([edge_weights_horizontal, edge_weights_vertical])
# do inference
# pad x for hidden states...
x_padded = -100 * np.ones((x.shape[0], x.shape[1], x.shape[2] + 5))
x_padded[:, :, :x.shape[2]] = x
res = lp_general_graph(-x_padded.reshape(-1, n_states + 5), edges,
edge_weights)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, n_states), edges, edge_features, 0)
y = y.ravel()
for inference_method in get_installed(["lp"]):
# same inference through CRF inferface
crf = EdgeFeatureLatentNodeCRF(n_labels=3,
inference_method=inference_method,
n_edge_features=2, n_hidden_states=5)
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=True)
assert_array_almost_equal(res[0], y_pred[0].reshape(-1, n_states + 5),
4)
assert_array_almost_equal(res[1], y_pred[1], 4)
assert_array_equal(y, np.argmax(y_pred[0], axis=-1))
for inference_method in get_installed(["lp", "ad3", "qpbo"]):
# again, this time discrete predictions only
crf = EdgeFeatureLatentNodeCRF(n_labels=3,
inference_method=inference_method,
n_edge_features=2, n_hidden_states=5)
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=False)
assert_array_equal(y, y_pred)
def find_all_edge_connetion(self):
row_dim = self.pixels_frame[1] - self.pixels_frame[0]
col_dim = self.pixels_frame[3] - self.pixels_frame[2]
index_2_dim_array = np.zeros((row_dim, col_dim), dtype='int32')
from pystruct.utils import make_grid_edges, edge_list_to_features
right, down, upright, downright = make_grid_edges(index_2_dim_array,
neighborhood=8,
return_lists=True)
edges = np.vstack([right, down, upright, downright])
total_num_cell = row_dim * col_dim
pixel_dict = dict()
for c_num in range(0, total_num_cell):
pixel_dict[c_num] = list()
list_tuple_indexes = zip(*np.where(
edges == c_num)) # find pixel idx in all edges 2d-array
for i, c_tuple in enumerate(list_tuple_indexes):
c_edge_index = c_tuple[0]
c_edge_place = c_tuple[1]
if c_edge_place == 0: # find surround pixel per edges
pixel_dict[c_num].append(edges[c_edge_index][1])
elif c_edge_place == 1:
pixel_dict[c_num].append(edges[c_edge_index][0])
self.pixel_dict = pixel_dict
return
def test_joint_feature_discrete():
"""
Testing with a single type of nodes. Must de aw well as EdgeFeatureGraphCRF
"""
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = ([x.reshape(-1, 3)], [edges], [edge_features])
y_flat = y.ravel()
#for inference_method in get_installed(["lp", "ad3", "qpbo"]):
if True:
crf = NodeTypeEdgeFeatureGraphCRF(1, [3], [3], [[2]])
joint_feature_y = crf.joint_feature(x, y_flat)
assert_equal(joint_feature_y.shape, (crf.size_joint_feature,))
# first horizontal, then vertical
# we trust the unaries ;)
n_states = crf.l_n_states[0]
n_features = crf.l_n_features[0]
pw_joint_feature_horz, pw_joint_feature_vert = joint_feature_y[n_states *
n_features:].reshape(
2, n_states, n_states)
assert_array_equal(pw_joint_feature_vert, np.diag([9 * 4, 9 * 4, 9 * 4]))
vert_joint_feature = np.diag([10 * 3, 10 * 3, 10 * 3])
vert_joint_feature[0, 1] = 10
vert_joint_feature[1, 2] = 10
assert_array_equal(pw_joint_feature_horz, vert_joint_feature)
def test_binary_blocks_cutting_plane():
#testing cutting plane ssvm on easy binary dataset
# generate graphs explicitly for each example
for inference_method in get_installed(["dai", "lp", "qpbo", "ad3", 'ogm']):
print("testing %s" % inference_method)
X, Y = generate_blocks(n_samples=3)
crf = GraphCRF(inference_method=inference_method)
clf = NSlackSSVM(model=crf,
max_iter=20,
C=100,
check_constraints=True,
break_on_bad=False,
n_jobs=1)
x1, x2, x3 = X
y1, y2, y3 = Y
n_states = len(np.unique(Y))
# delete some rows to make it more fun
x1, y1 = x1[:, :-1], y1[:, :-1]
x2, y2 = x2[:-1], y2[:-1]
# generate graphs
X_ = [x1, x2, x3]
G = [make_grid_edges(x) for x in X_]
# reshape / flatten x and y
X_ = [x.reshape(-1, n_states) for x in X_]
Y = [y.ravel() for y in [y1, y2, y3]]
X = zip(X_, G)
clf.fit(X, Y)
Y_pred = clf.predict(X)
for y, y_pred in zip(Y, Y_pred):
assert_array_equal(y, y_pred)
def test_energy_discrete():
for inference_method in get_installed(["qpbo", "ad3"]):
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2)
for i in xrange(10):
x = np.random.normal(size=(7, 8, 3))
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
unary_params = np.random.normal(size=(3, 3))
pw1 = np.random.normal(size=(3, 3))
pw2 = np.random.normal(size=(3, 3))
w = np.hstack([unary_params.ravel(), pw1.ravel(), pw2.ravel()])
y_hat = crf.inference(x, w, relaxed=False)
energy = compute_energy(crf.get_unary_potentials(x, w),
crf.get_pairwise_potentials(x, w), edges,
y_hat)
psi = crf.psi(x, y_hat)
energy_svm = np.dot(psi, w)
assert_almost_equal(energy, energy_svm)
def test_energy():
# make sure that energy as computed by ssvm is the same as by lp
np.random.seed(0)
for inference_method in ["lp", "ad3"]:
found_fractional = False
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2)
while not found_fractional:
x = np.random.normal(size=(7, 8, 3))
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
unary_params = np.random.normal(size=(3, 3))
pw1 = np.random.normal(size=(3, 3))
pw2 = np.random.normal(size=(3, 3))
w = np.hstack([unary_params.ravel(), pw1.ravel(), pw2.ravel()])
res, energy = crf.inference(x, w, relaxed=True, return_energy=True)
found_fractional = np.any(np.max(res[0], axis=-1) != 1)
psi = crf.psi(x, res)
energy_svm = np.dot(psi, w)
assert_almost_equal(energy, -energy_svm)
if not found_fractional:
# exact discrete labels, test non-relaxed version
res, energy = crf.inference(x, w, relaxed=False,
return_energy=True)
psi = crf.psi(x, res)
energy_svm = np.dot(psi, w)
assert_almost_equal(energy, -energy_svm)
def test_binary_blocks_one_slack_graph():
#testing cutting plane ssvm on easy binary dataset
# generate graphs explicitly for each example
X, Y = generate_blocks(n_samples=3)
crf = GraphCRF(inference_method=inference_method)
clf = OneSlackSSVM(model=crf, max_iter=100, C=1,
check_constraints=True, break_on_bad=True,
n_jobs=1, tol=.1)
x1, x2, x3 = X
y1, y2, y3 = Y
n_states = len(np.unique(Y))
# delete some rows to make it more fun
x1, y1 = x1[:, :-1], y1[:, :-1]
x2, y2 = x2[:-1], y2[:-1]
# generate graphs
X_ = [x1, x2, x3]
G = [make_grid_edges(x) for x in X_]
# reshape / flatten x and y
X_ = [x.reshape(-1, n_states) for x in X_]
Y = [y.ravel() for y in [y1, y2, y3]]
X = list(zip(X_, G))
clf.fit(X, Y)
Y_pred = clf.predict(X)
for y, y_pred in zip(Y, Y_pred):
assert_array_equal(y, y_pred)
def test_initialization():
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, n_states), edges, edge_features)
y = y.ravel()
crf = EdgeFeatureGraphCRF()
crf.initialize([x], [y])
assert_equal(crf.n_edge_features, 2)
assert_equal(crf.n_features, 3)
assert_equal(crf.n_states, 3)
crf = EdgeFeatureGraphCRF(n_states=3,
n_features=3,
n_edge_features=2)
# no-op
crf.initialize([x], [y])
crf = EdgeFeatureGraphCRF(n_states=4,
n_edge_features=2)
# incompatible
assert_raises(ValueError, crf.initialize, X=[x], Y=[y])
def test_inference():
# Test inference with different weights in different directions
X, Y = toy.generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edges = make_grid_edges(x, neighborhood=4)
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
pw_horz = -1 * np.eye(n_states)
xx, yy = np.indices(pw_horz.shape)
# linear ordering constraint horizontally
pw_horz[xx > yy] = 1
# high cost for unequal labels vertically
pw_vert = -1 * np.eye(n_states)
pw_vert[xx != yy] = 1
pw_vert *= 10
# generate edge weights
edge_weights_horizontal = np.repeat(pw_horz[np.newaxis, :, :],
edge_list[0].shape[0], axis=0)
edge_weights_vertical = np.repeat(pw_vert[np.newaxis, :, :],
edge_list[1].shape[0], axis=0)
edge_weights = np.vstack([edge_weights_horizontal, edge_weights_vertical])
# do inference
res = lp_general_graph(-x.reshape(-1, n_states), edges, edge_weights)
for inference_method in ["lp", "ad3"]:
# same inference through CRF inferface
crf = DirectionalGridCRF(n_states=3, inference_method=inference_method)
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=True)
assert_array_almost_equal(res[0], y_pred[0].reshape(-1, n_states))
assert_array_almost_equal(res[1], y_pred[1])
assert_array_equal(y, np.argmax(y_pred[0], axis=-1))
for inference_method in ["lp", "ad3", "qpbo"]:
# again, this time discrete predictions only
crf = DirectionalGridCRF(n_states=3, inference_method=inference_method)
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=False)
assert_array_equal(y, y_pred)
def test_inference():
# Test inference with different weights in different directions
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
pw_horz = -1 * np.eye(n_states)
xx, yy = np.indices(pw_horz.shape)
# linear ordering constraint horizontally
pw_horz[xx > yy] = 1
# high cost for unequal labels vertically
pw_vert = -1 * np.eye(n_states)
pw_vert[xx != yy] = 1
pw_vert *= 10
# generate edge weights
edge_weights_horizontal = np.repeat(pw_horz[np.newaxis, :, :],
edge_list[0].shape[0],
axis=0)
edge_weights_vertical = np.repeat(pw_vert[np.newaxis, :, :],
edge_list[1].shape[0],
axis=0)
edge_weights = np.vstack([edge_weights_horizontal, edge_weights_vertical])
# do inference
res = lp_general_graph(-x.reshape(-1, n_states), edges, edge_weights)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, n_states), edges, edge_features)
y = y.ravel()
for inference_method in get_installed(["lp", "ad3"]):
# same inference through CRF inferface
crf = EdgeFeatureGraphCRF(inference_method=inference_method)
crf.initialize([x], [y])
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=True)
if isinstance(y_pred, tuple):
# ad3 produces an integer result if it found the exact solution
assert_array_almost_equal(res[1], y_pred[1])
assert_array_almost_equal(res[0], y_pred[0].reshape(-1, n_states))
assert_array_equal(y, np.argmax(y_pred[0], axis=-1))
for inference_method in get_installed(["lp", "ad3", "qpbo"]):
# again, this time discrete predictions only
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2)
crf.initialize([x], [y])
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=False)
assert_array_equal(y, y_pred)
def test_k_means_initialization_graph_crf():
# with only 1 state per label, nothing happends
X, Y = toy.generate_big_checker(n_samples=10)
crf = LatentGraphCRF(n_labels=2, n_states_per_label=1, inference_method="lp")
# convert grid model to graph model
X = [(x.reshape(-1, x.shape[-1]), make_grid_edges(x, return_lists=False)) for x in X]
H = crf.init_latent(X, Y)
assert_array_equal(Y, H)
def test_latent_node_boxes_standard_latent_features():
# learn the "easy" 2x2 boxes dataset.
# we make it even easier now by adding features that encode the correct
# latent state. This basically tests that the features are actually used
X, Y = make_simple_2x2(seed=1, n_samples=20, n_flips=6)
latent_crf = LatentNodeCRF(n_labels=2,
n_hidden_states=2,
n_features=1,
latent_node_features=True)
one_slack = OneSlackSSVM(latent_crf)
n_slack = NSlackSSVM(latent_crf)
subgradient = SubgradientSSVM(latent_crf,
max_iter=100,
learning_rate=0.01,
momentum=0)
for base_svm in [one_slack, n_slack, subgradient]:
base_svm.C = 10
latent_svm = LatentSSVM(base_svm, latent_iter=10)
G = [make_grid_edges(x) for x in X]
# make edges for hidden states:
edges = make_edges_2x2()
G = [np.vstack([make_grid_edges(x), edges]) for x in X]
# reshape / flatten x and y
X_flat = [x.reshape(-1, 1) for x in X]
# augment X with the features for hidden units
X_flat = [
np.vstack([x, y[::2, ::2].reshape(-1, 1)])
for x, y in zip(X_flat, Y)
]
Y_flat = [y.ravel() for y in Y]
X_ = zip(X_flat, G, [2 * 2 for x in X_flat])
latent_svm.fit(X_[:10], Y_flat[:10])
assert_array_equal(latent_svm.predict(X_[:10]), Y_flat[:10])
assert_equal(latent_svm.score(X_[:10], Y_flat[:10]), 1)
# we actually become prefect ^^
assert_true(.98 < latent_svm.score(X_[10:], Y_flat[10:]) <= 1)
def prepare_data_to_edge_feature_graph_crf(self):
from pystruct.utils import make_grid_edges, edge_list_to_features
self.X_flatten = []
self.y_flatten = []
for pic_i, pic_nd_array in enumerate(self.X):
pic_item = list()
for row_i, row_val in enumerate(pic_nd_array): # pic item
for col_i, cell_features in enumerate(row_val): # pic row iteration cell by cell
pic_item.append(cell_features)
if self.models_parameters['neighborhood'] == 4:
# 4 neigh and cross type
if 'type' in self.models_parameters and self.models_parameters['type'] == 'cross_edge':
upright, downright = self.cross_make_grid_edges(pic_nd_array, neighborhood=4, return_lists=True)
edges = np.vstack([upright, downright])
edge_features_directions = self.edge_list_to_features([upright, downright], 4)
else: # regular
right, down = make_grid_edges(pic_nd_array, neighborhood=4, return_lists=True)
edges = np.vstack([right, down])
edge_features_directions = self.edge_list_to_features([right, down], 4)
elif self.models_parameters['neighborhood'] == 8:
right, down, upright, downright = make_grid_edges(pic_nd_array, neighborhood=8, return_lists=True)
edges = np.vstack([right, down, upright, downright])
edge_features_directions = self.edge_list_to_features([right, down, upright, downright], 8)
# finish iterate picture - (pixel feature (list), edge (pixel-pixel) list)
self.X_flatten.append((np.array(pic_item), edges, edge_features_directions))
for pic_i, pic_nd_array in enumerate(self.y):
pic_item = list()
for row_i, row_val in enumerate(pic_nd_array): # pic item
for col_i, cell_features in enumerate(row_val): # pic row iteration cell by cell
pic_item.append(cell_features)
self.y_flatten.append(pic_item)
self.X = np.array(self.X_flatten)
self.y = np.array(self.y_flatten)
return
def test_k_means_initialization_graph_crf():
# with only 1 state per label, nothing happends
X, Y = generate_big_checker(n_samples=10)
crf = LatentGraphCRF(n_states_per_label=1, n_features=2, n_labels=2)
# convert grid model to graph model
X = [(x.reshape(-1, x.shape[-1]), make_grid_edges(x, return_lists=False))
for x in X]
H = crf.init_latent(X, Y)
assert_array_equal(Y, H)
def test_inference():
# Test inference with different weights in different directions
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
pw_horz = -1 * np.eye(n_states)
xx, yy = np.indices(pw_horz.shape)
# linear ordering constraint horizontally
pw_horz[xx > yy] = 1
# high cost for unequal labels vertically
pw_vert = -1 * np.eye(n_states)
pw_vert[xx != yy] = 1
pw_vert *= 10
# generate edge weights
edge_weights_horizontal = np.repeat(pw_horz[np.newaxis, :, :],
edge_list[0].shape[0], axis=0)
edge_weights_vertical = np.repeat(pw_vert[np.newaxis, :, :],
edge_list[1].shape[0], axis=0)
edge_weights = np.vstack([edge_weights_horizontal, edge_weights_vertical])
# do inference
res = lp_general_graph(-x.reshape(-1, n_states), edges, edge_weights)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, n_states), edges, edge_features)
y = y.ravel()
for inference_method in get_installed(["lp", "ad3"]):
# same inference through CRF inferface
crf = EdgeFeatureGraphCRF(inference_method=inference_method)
crf.initialize([x], [y])
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=True)
if isinstance(y_pred, tuple):
# ad3 produces an integer result if it found the exact solution
assert_array_almost_equal(res[1], y_pred[1])
assert_array_almost_equal(res[0], y_pred[0].reshape(-1, n_states))
assert_array_equal(y, np.argmax(y_pred[0], axis=-1))
for inference_method in get_installed(["lp", "ad3", "qpbo"]):
# again, this time discrete predictions only
crf = EdgeFeatureGraphCRF(n_states=3,
inference_method=inference_method,
n_edge_features=2)
crf.initialize([x], [y])
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
y_pred = crf.inference(x, w, relaxed=False)
assert_array_equal(y, y_pred)
def test_k_means_initialization():
n_samples = 10
X, Y = generate_big_checker(n_samples=n_samples)
edges = [make_grid_edges(x, return_lists=True) for x in X]
# flatten the grid
Y = Y.reshape(Y.shape[0], -1)
X = X.reshape(X.shape[0], -1, X.shape[-1])
n_labels = len(np.unique(Y))
X = X.reshape(n_samples, -1, n_labels)
# sanity check for one state
H = kmeans_init(X, Y, edges, n_states_per_label=[1] * n_labels,
n_labels=n_labels)
H = np.vstack(H)
assert_array_equal(Y, H)
# check number of states
H = kmeans_init(X, Y, edges, n_states_per_label=[3] * n_labels,
n_labels=n_labels)
H = np.vstack(H)
assert_array_equal(np.unique(H), np.arange(6))
assert_array_equal(Y, H // 3)
# for dataset with more than two states
X, Y = generate_blocks_multinomial(n_samples=10)
edges = [make_grid_edges(x, return_lists=True) for x in X]
Y = Y.reshape(Y.shape[0], -1)
X = X.reshape(X.shape[0], -1, X.shape[-1])
n_labels = len(np.unique(Y))
# sanity check for one state
H = kmeans_init(X, Y, edges, n_states_per_label=[1] * n_labels,
n_labels=n_labels)
H = np.vstack(H)
assert_array_equal(Y, H)
# check number of states
H = kmeans_init(X, Y, edges, n_states_per_label=[2] * n_labels,
n_labels=n_labels)
H = np.vstack(H)
assert_array_equal(np.unique(H), np.arange(6))
assert_array_equal(Y, H // 2)
def test_latent_node_boxes_latent_subgradient():
# same as above, now with elementary subgradients
X, Y = make_simple_2x2(seed=1)
latent_crf = LatentNodeCRF(n_labels=2, n_hidden_states=2, n_features=1)
latent_svm = SubgradientLatentSSVM(model=latent_crf, max_iter=50, C=10)
G = [make_grid_edges(x) for x in X]
edges = make_edges_2x2()
G = [np.vstack([make_grid_edges(x), edges]) for x in X]
# reshape / flatten x and y
X_flat = [x.reshape(-1, 1) for x in X]
Y_flat = [y.ravel() for y in Y]
X_ = list(zip(X_flat, G, [4 * 4 for x in X_flat]))
latent_svm.fit(X_, Y_flat)
assert_equal(latent_svm.score(X_, Y_flat), 1)
def test_latent_node_boxes_latent_subgradient():
# same as above, now with elementary subgradients
X, Y = make_simple_2x2(seed=1)
latent_crf = LatentNodeCRF(n_labels=2, n_hidden_states=2, n_features=1)
latent_svm = SubgradientLatentSSVM(model=latent_crf, max_iter=50, C=10)
G = [make_grid_edges(x) for x in X]
edges = make_edges_2x2()
G = [np.vstack([make_grid_edges(x), edges]) for x in X]
# reshape / flatten x and y
X_flat = [x.reshape(-1, 1) for x in X]
Y_flat = [y.ravel() for y in Y]
X_ = zip(X_flat, G, [4 * 4 for x in X_flat])
latent_svm.fit(X_, Y_flat)
assert_equal(latent_svm.score(X_, Y_flat), 1)
def test_latent_node_boxes_standard_latent_features():
# learn the "easy" 2x2 boxes dataset.
# we make it even easier now by adding features that encode the correct
# latent state. This basically tests that the features are actually used
X, Y = make_simple_2x2(seed=1, n_samples=20, n_flips=6)
latent_crf = LatentNodeCRF(n_labels=2, n_hidden_states=2, n_features=1,
latent_node_features=True)
one_slack = OneSlackSSVM(latent_crf)
n_slack = NSlackSSVM(latent_crf)
subgradient = SubgradientSSVM(latent_crf, max_iter=100, learning_rate=0.01,
momentum=0)
for base_svm in [one_slack, n_slack, subgradient]:
base_svm.C = 10
latent_svm = LatentSSVM(base_svm,
latent_iter=10)
G = [make_grid_edges(x) for x in X]
# make edges for hidden states:
edges = make_edges_2x2()
G = [np.vstack([make_grid_edges(x), edges]) for x in X]
# reshape / flatten x and y
X_flat = [x.reshape(-1, 1) for x in X]
# augment X with the features for hidden units
X_flat = [np.vstack([x, y[::2, ::2].reshape(-1, 1)])
for x, y in zip(X_flat, Y)]
Y_flat = [y.ravel() for y in Y]
X_ = zip(X_flat, G, [2 * 2 for x in X_flat])
latent_svm.fit(X_[:10], Y_flat[:10])
assert_array_equal(latent_svm.predict(X_[:10]), Y_flat[:10])
assert_equal(latent_svm.score(X_[:10], Y_flat[:10]), 1)
# we actually become prefect ^^
assert_true(.98 < latent_svm.score(X_[10:], Y_flat[10:]) <= 1)
def decoding(self, W, A, b, x, k):
n, dim = x.shape[0], x.shape[1]
S = np.dot(x, W) + b
edges = make_grid_edges(S.reshape(1, n, k))
pairwise = A
unaries = S
y = inference_max_product(unaries, pairwise, edges)
return y
def prepare_data(X):
X_directions = []
X_edge_features = []
for x in X:
# get edges in grid
right, down = make_grid_edges(x, return_lists=True)
edges = np.vstack([right, down])
# use 3x3 patch around each point
features = x.reshape(x.shape[0] * x.shape[1], -1)
# simple edge feature that encodes just if an edge is horizontal or
# vertical
edge_features_directions = edge_list_to_features([right, down])
X_directions.append((features, edges, edge_features_directions))
return X_directions
def test_latent_node_boxes_standard_latent():
# learn the "easy" 2x2 boxes dataset.
# a 2x2 box is placed randomly in a 4x4 grid
# we add a latent variable for each 2x2 patch
# that should make the model fairly simple
X, Y = make_simple_2x2(seed=1, n_samples=40)
latent_crf = LatentNodeCRF(n_labels=2, n_hidden_states=2, n_features=1)
one_slack = OneSlackSSVM(latent_crf)
n_slack = NSlackSSVM(latent_crf)
subgradient = SubgradientSSVM(latent_crf,
max_iter=100,
learning_rate=0.01,
momentum=0)
for base_svm in [one_slack, n_slack, subgradient]:
base_svm.C = 10
latent_svm = LatentSSVM(base_svm, latent_iter=10)
G = [make_grid_edges(x) for x in X]
# make edges for hidden states:
edges = make_edges_2x2()
G = [np.vstack([make_grid_edges(x), edges]) for x in X]
# reshape / flatten x and y
X_flat = [x.reshape(-1, 1) for x in X]
Y_flat = [y.ravel() for y in Y]
X_ = zip(X_flat, G, [2 * 2 for x in X_flat])
latent_svm.fit(X_[:20], Y_flat[:20])
assert_array_equal(latent_svm.predict(X_[:20]), Y_flat[:20])
assert_equal(latent_svm.score(X_[:20], Y_flat[:20]), 1)
# test that score is not always 1
assert_true(.98 < latent_svm.score(X_[20:], Y_flat[20:]) < 1)
def region_graph(regions):
edges = make_grid_edges(regions)
n_vertices = np.max(regions) + 1
crossings = edges[regions.ravel()[edges[:, 0]]
!= regions.ravel()[edges[:, 1]]]
edges = regions.ravel()[crossings]
edges = np.sort(edges, axis=1)
crossing_hash = (edges[:, 0] + n_vertices * edges[:, 1])
# find unique connections
unique_hash = np.unique(crossing_hash)
# undo hashing
unique_crossings = np.c_[unique_hash % n_vertices,
unique_hash // n_vertices]
return unique_crossings
def test_multinomial_blocks_directional_simple():
# testing cutting plane ssvm with directional CRF on easy multinomial
# dataset
X_, Y_ = generate_blocks_multinomial(n_samples=10, noise=0.3, seed=0)
G = [make_grid_edges(x, return_lists=True) for x in X_]
edge_features = [edge_list_to_features(edge_list) for edge_list in G]
edges = [np.vstack(g) for g in G]
X = list(zip([x.reshape(-1, 3) for x in X_], edges, edge_features))
Y = [y.ravel() for y in Y_]
crf = EdgeFeatureGraphCRF(n_states=3, n_edge_features=2)
clf = NSlackSSVM(model=crf, max_iter=10, C=1, check_constraints=False)
clf.fit(X, Y)
Y_pred = clf.predict(X)
assert_array_equal(Y, Y_pred)
def test_multinomial_blocks_directional_simple():
# testing cutting plane ssvm with directional CRF on easy multinomial
# dataset
X_, Y_ = generate_blocks_multinomial(n_samples=10, noise=0.3, seed=0)
G = [make_grid_edges(x, return_lists=True) for x in X_]
edge_features = [edge_list_to_features(edge_list) for edge_list in G]
edges = [np.vstack(g) for g in G]
X = zip([x.reshape(-1, 3) for x in X_], edges, edge_features)
Y = [y.ravel() for y in Y_]
crf = EdgeFeatureGraphCRF(n_states=3, n_edge_features=2)
clf = NSlackSSVM(model=crf, max_iter=10, C=1, check_constraints=False)
clf.fit(X, Y)
Y_pred = clf.predict(X)
assert_array_equal(Y, Y_pred)
def loss_augmented_decoding(self, W, A, b, x, y, k):
n, dim = x.shape[0], x.shape[1]
S = np.dot(x, W) + b
S_ = S
S_[range(n), y] -= 1
edges = make_grid_edges(S.reshape(1, n, k))
pairwise = A
unaries = S_
# decoding
ans = inference_max_product(unaries, pairwise, edges)
return ans
def test_binary_blocks_cutting_plane_latent_node():
#testing cutting plane ssvm on easy binary dataset
# we use the LatentNodeCRF without latent nodes and check that it does the
# same as GraphCRF
X, Y = generate_blocks(n_samples=3)
crf = GraphCRF()
clf = NSlackSSVM(model=crf,
max_iter=20,
C=100,
check_constraints=True,
break_on_bad=False,
n_jobs=1)
x1, x2, x3 = X
y1, y2, y3 = Y
n_states = len(np.unique(Y))
# delete some rows to make it more fun
x1, y1 = x1[:, :-1], y1[:, :-1]
x2, y2 = x2[:-1], y2[:-1]
# generate graphs
X_ = [x1, x2, x3]
G = [make_grid_edges(x) for x in X_]
# reshape / flatten x and y
X_ = [x.reshape(-1, n_states) for x in X_]
Y = [y.ravel() for y in [y1, y2, y3]]
X = zip(X_, G)
clf.fit(X, Y)
Y_pred = clf.predict(X)
for y, y_pred in zip(Y, Y_pred):
assert_array_equal(y, y_pred)
latent_crf = LatentNodeCRF(n_labels=2, n_hidden_states=0)
latent_svm = LatentSSVM(NSlackSSVM(model=latent_crf,
max_iter=20,
C=100,
check_constraints=True,
break_on_bad=False,
n_jobs=1),
latent_iter=3)
X_latent = zip(X_, G, np.zeros(len(X_)))
latent_svm.fit(X_latent, Y, H_init=Y)
Y_pred = latent_svm.predict(X_latent)
for y, y_pred in zip(Y, Y_pred):
assert_array_equal(y, y_pred)
assert_array_almost_equal(latent_svm.w, clf.w)
def region_graph(regions):
edges = make_grid_edges(regions)
n_vertices = np.max(regions) + 1
crossings = edges[regions.ravel()[edges[:,
0]] != regions.ravel()[edges[:,
1]]]
edges = regions.ravel()[crossings]
edges = np.sort(edges, axis=1)
crossing_hash = (edges[:, 0] + n_vertices * edges[:, 1])
# find unique connections
unique_hash = np.unique(crossing_hash)
# undo hashing
unique_crossings = np.c_[unique_hash % n_vertices,
unique_hash // n_vertices]
return unique_crossings
def test_binary_blocks_cutting_plane_latent_node():
#testing cutting plane ssvm on easy binary dataset
# we use the LatentNodeCRF without latent nodes and check that it does the
# same as GraphCRF
X, Y = toy.generate_blocks(n_samples=3)
crf = GraphCRF(inference_method='lp')
clf = StructuredSVM(model=crf, max_iter=20, C=100, verbose=0,
check_constraints=True, break_on_bad=False,
n_jobs=1)
x1, x2, x3 = X
y1, y2, y3 = Y
n_states = len(np.unique(Y))
# delete some rows to make it more fun
x1, y1 = x1[:, :-1], y1[:, :-1]
x2, y2 = x2[:-1], y2[:-1]
# generate graphs
X_ = [x1, x2, x3]
G = [make_grid_edges(x) for x in X_]
# reshape / flatten x and y
X_ = [x.reshape(-1, n_states) for x in X_]
Y = [y.ravel() for y in [y1, y2, y3]]
X = zip(X_, G)
clf.fit(X, Y)
Y_pred = clf.predict(X)
for y, y_pred in zip(Y, Y_pred):
assert_array_equal(y, y_pred)
latent_crf = LatentNodeCRF(n_labels=2, inference_method='lp',
n_hidden_states=0)
latent_svm = LatentSSVM(StructuredSVM(model=latent_crf, max_iter=20,
C=100, verbose=0,
check_constraints=True,
break_on_bad=False, n_jobs=1),
latent_iter=3)
X_latent = zip(X_, G, np.zeros(len(X_)))
latent_svm.fit(X_latent, Y, H_init=Y)
Y_pred = latent_svm.predict(X_latent)
for y, y_pred in zip(Y, Y_pred):
assert_array_equal(y, y_pred)
assert_array_almost_equal(latent_svm.w, clf.w)
def generate_edges(sps):
"""
generate edges from superpixels
"""
edges = psutil.make_grid_edges(sps)
vertices = np.unique(sps)
n_vertices = vertices.shape[0]
# filter out edges that connect to themselves
crossings = edges[sps.ravel()[edges[:, 0]] != sps.ravel()[edges[:, 1]]]
edges = sps.ravel()[crossings]
edges = np.sort(edges, axis=1)
# find unique crossing
crossing_hash = (edges[:, 0] + n_vertices * edges[:, 1])
unique_hash = np.unique(crossing_hash)
unique_crossings = np.c_[unique_hash % n_vertices, unique_hash // n_vertices]
return vertices, unique_crossings
def test_joint_feature_continuous():
"""
Testing with a single type of nodes. Must de aw well as EdgeFeatureGraphCRF
"""
# FIXME
# first make perfect prediction, including pairwise part
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
#x = (x.reshape(-1, 3), edges, edge_features)
x = ([x.reshape(-1, 3)], [edges], [edge_features])
y = y.ravel()
pw_horz = -1 * np.eye(n_states)
xx, yy = np.indices(pw_horz.shape)
# linear ordering constraint horizontally
pw_horz[xx > yy] = 1
# high cost for unequal labels vertically
pw_vert = -1 * np.eye(n_states)
pw_vert[xx != yy] = 1
pw_vert *= 10
# create crf, assemble weight, make prediction
# for inference_method in get_installed(["lp", "ad3"]):
# crf = EdgeFeatureGraphCRF(inference_method=inference_method)
if True:
crf = NodeTypeEdgeFeatureGraphCRF(1, [3], [3], [[2]])
w = np.hstack([np.eye(3).ravel(), -pw_horz.ravel(), -pw_vert.ravel()])
#crf.initialize([x], [y])
#report_model_config(crf)
crf.initialize(x, y)
y_pred = crf.inference(x, w, relaxed=True)
# compute joint_feature for prediction
joint_feature_y = crf.joint_feature(x, y_pred)
assert_equal(joint_feature_y.shape, (crf.size_joint_feature,))
def test_multinomial_blocks_directional_anti_symmetric():
# testing cutting plane ssvm with directional CRF on easy multinomial
# dataset
X_, Y_ = generate_blocks_multinomial(n_samples=10, noise=0.3, seed=0)
G = [make_grid_edges(x, return_lists=True) for x in X_]
edge_features = [edge_list_to_features(edge_list) for edge_list in G]
edges = [np.vstack(g) for g in G]
X = list(zip([x.reshape(-1, 3) for x in X_], edges, edge_features))
Y = [y.ravel() for y in Y_]
crf = EdgeFeatureGraphCRF(symmetric_edge_features=[0], antisymmetric_edge_features=[1])
clf = NSlackSSVM(model=crf, C=100)
clf.fit(X, Y)
Y_pred = clf.predict(X)
assert_array_equal(Y, Y_pred)
pairwise_params = clf.w[-9 * 2 :].reshape(2, 3, 3)
sym = pairwise_params[0]
antisym = pairwise_params[1]
assert_array_equal(sym, sym.T)
assert_array_equal(antisym, -antisym.T)
def test_multinomial_blocks_directional_anti_symmetric():
# testing cutting plane ssvm with directional CRF on easy multinomial
# dataset
X_, Y_ = generate_blocks_multinomial(n_samples=10, noise=0.3, seed=0)
G = [make_grid_edges(x, return_lists=True) for x in X_]
edge_features = [edge_list_to_features(edge_list) for edge_list in G]
edges = [np.vstack(g) for g in G]
X = zip([x.reshape(-1, 3) for x in X_], edges, edge_features)
Y = [y.ravel() for y in Y_]
crf = EdgeFeatureGraphCRF(symmetric_edge_features=[0],
antisymmetric_edge_features=[1])
clf = NSlackSSVM(model=crf, C=100)
clf.fit(X, Y)
Y_pred = clf.predict(X)
assert_array_equal(Y, Y_pred)
pairwise_params = clf.w[-9 * 2:].reshape(2, 3, 3)
sym = pairwise_params[0]
antisym = pairwise_params[1]
assert_array_equal(sym, sym.T)
assert_array_equal(antisym, -antisym.T)
def risk(self, flatten_w, x, y_true, y_true_labels, dim=0, k=0):
n, _ = x.shape[0], x.shape[1]
if dim == 0 and k == 0:
dim = self.dim
k = self.k
W = flatten_w[:dim * k].reshape(k, dim).T
A = flatten_w[dim * k:dim * k + k * k].reshape(k, k).T
b = flatten_w[dim * k + k * k:]
y_pred = self.loss_augmented_decoding(W, A, b, x, y_true_labels, k)
S = np.dot(x, W) + b
edges = make_grid_edges(S.reshape(1, n, k))
pairwise = A
unaries = S
loss = self.hamming_loss_base(y_true_labels, y_pred)
score_y = compute_energy(unaries, pairwise, edges, y_true_labels)
score_y_pred = compute_energy(unaries, pairwise, edges, y_pred)
return loss - score_y + score_y_pred
def inference_data():
"""
Testing with a single type of nodes. Must do as well as EdgeFeatureGraphCRF
"""
# Test inference with different weights in different directions
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
n_states = x.shape[-1]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
pw_horz = -1 * np.eye(n_states)
xx, yy = np.indices(pw_horz.shape)
# linear ordering constraint horizontally
pw_horz[xx > yy] = 1
# high cost for unequal labels vertically
pw_vert = -1 * np.eye(n_states)
pw_vert[xx != yy] = 1
pw_vert *= 10
# generate edge weights
edge_weights_horizontal = np.repeat(pw_horz[np.newaxis, :, :],
edge_list[0].shape[0], axis=0)
edge_weights_vertical = np.repeat(pw_vert[np.newaxis, :, :],
edge_list[1].shape[0], axis=0)
edge_weights = np.vstack([edge_weights_horizontal, edge_weights_vertical])
# do inference
res = lp_general_graph(-x.reshape(-1, n_states), edges, edge_weights)
edge_features = edge_list_to_features(edge_list)
x = ([x.reshape(-1, n_states)], [edges], [edge_features])
y = y.ravel()
return x, y, pw_horz, pw_vert, res, n_states
def test_joint_feature_discrete():
X, Y = generate_blocks_multinomial(noise=2, n_samples=1, seed=1)
x, y = X[0], Y[0]
edge_list = make_grid_edges(x, 4, return_lists=True)
edges = np.vstack(edge_list)
edge_features = edge_list_to_features(edge_list)
x = (x.reshape(-1, 3), edges, edge_features)
y_flat = y.ravel()
for inference_method in get_installed(["lp", "ad3", "qpbo"]):
crf = EdgeFeatureGraphCRF(inference_method=inference_method)
crf.initialize([x], [y_flat])
joint_feature_y = crf.joint_feature(x, y_flat)
assert_equal(joint_feature_y.shape, (crf.size_joint_feature,))
# first horizontal, then vertical
# we trust the unaries ;)
pw_joint_feature_horz, pw_joint_feature_vert = joint_feature_y[crf.n_states *
crf.n_features:].reshape(
2, crf.n_states, crf.n_states)
xx, yy = np.indices(y.shape)
assert_array_equal(pw_joint_feature_vert, np.diag([9 * 4, 9 * 4, 9 * 4]))
vert_joint_feature = np.diag([10 * 3, 10 * 3, 10 * 3])
vert_joint_feature[0, 1] = 10
vert_joint_feature[1, 2] = 10
assert_array_equal(pw_joint_feature_horz, vert_joint_feature)
# a 2x2 box is placed randomly in a 4x4 grid
# we add a latent variable for each 2x2 patch
# that should make the model fairly simple
X, Y = make_simple_2x2(seed=1)
# flatten X and Y
X_flat = [x.reshape(-1, 1).astype(np.float) for x in X]
Y_flat = [y.ravel() for y in Y]
# first, use standard graph CRF. Can't do much, high loss.
crf = GraphCRF()
svm = NSlackSSVM(model=crf, max_iter=200, C=1, n_jobs=1)
G = [make_grid_edges(x) for x in X]
X_grid_edges = list(zip(X_flat, G))
svm.fit(X_grid_edges, Y_flat)
plot_boxes(svm.predict(X_grid_edges), title="Non-latent SSVM predictions")
print("Training score binary grid CRF: %f" % svm.score(X_grid_edges, Y_flat))
# using one latent variable for each 2x2 rectangle
latent_crf = LatentNodeCRF(n_labels=2, n_features=1, n_hidden_states=2,
inference_method='lp')
ssvm = OneSlackSSVM(model=latent_crf, max_iter=200, C=100,
n_jobs=-1, show_loss_every=10, inference_cache=50)
latent_svm = LatentSSVM(ssvm)
# make edges for hidden states:
