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import numpy as np | |
import matplotlib.pyplot as plt | |
def get_top_predictions(prediction = None, threshold = 0.7): | |
if prediction is None: | |
return None, None | |
else: | |
sorted_scores_ids = prediction.pred_instances.scores.argsort()[::-1] | |
sorted_scores = prediction.pred_instances.scores[sorted_scores_ids] | |
sorted_predictions = prediction.pred_instances.labels[sorted_scores_ids] | |
return {'pred_above_thresh': sorted_predictions[sorted_scores > threshold], | |
'pred_above_thresh_id': sorted_scores_ids[sorted_scores > threshold], | |
'pred_above_thresh_scores': sorted_scores[sorted_scores > threshold], | |
'pred_above_thresh_bboxes': prediction.pred_instances['bboxes'][sorted_scores_ids][sorted_scores > threshold]} | |
def add_class_labels(top_pred = {}, class_labels = None): | |
if class_labels == None: | |
print('No class labels provided, returning original dictionary') | |
return top_pred | |
else: | |
top_pred['pred_above_thresh_labels'] = [class_labels[x].lower() for x in top_pred['pred_above_thresh']] | |
top_pred['any_detection'] = len(top_pred['pred_above_thresh_labels']) > 0 | |
if top_pred['any_detection']: | |
# Get shark / human / unknown vectors | |
top_pred['is_shark'] = np.array([1 if 'shark' in x else 0 for x in top_pred['pred_above_thresh_labels']]) | |
top_pred['is_human'] = np.array([1 if 'person' in x else 1 if 'surfer' in x else 0 for x in top_pred['pred_above_thresh_labels']]) | |
top_pred['is_unknown'] = np.array([1 if 'unidentifiable' in x else 0 for x in top_pred['pred_above_thresh_labels']]) | |
# Get shark / human / unknown numbers of detections | |
top_pred['shark_n'] = np.sum(top_pred['is_shark']) | |
top_pred['human_n'] = np.sum(top_pred['is_human']) | |
top_pred['unknown_n'] = np.sum(top_pred['is_unknown']) | |
else: | |
# Get shark / human / unknown vectors | |
top_pred['is_shark'] = None | |
top_pred['is_human'] = None | |
top_pred['is_unknown'] = None | |
# Get shark / human / unknown numbers of detections | |
top_pred['shark_n'] = 0 | |
top_pred['human_n'] = 0 | |
top_pred['unknown_n'] = 0 | |
return top_pred | |
def add_class_sizes(top_pred = {}, class_sizes = None): | |
size_list = [] | |
shark_size_list = [] | |
if top_pred['any_detection']: | |
for tmp_pred in top_pred['pred_above_thresh_labels']: | |
tmp_class_sizes = class_sizes[tmp_pred.lower()] | |
if tmp_class_sizes == None: | |
size_list.append(None) | |
else: | |
size_list.append(tmp_class_sizes['feet']) | |
if 'shark' in tmp_pred.lower(): | |
shark_size_list.append(np.mean(tmp_class_sizes['feet'])) | |
top_pred['pred_above_thresh_sizes'] = size_list | |
if top_pred['shark_n'] > 0: | |
top_pred['biggest_shark_size'] = np.max(shark_size_list) | |
else: | |
top_pred['biggest_shark_size'] = None | |
else: | |
top_pred['pred_above_thresh_sizes'] = None | |
top_pred['biggest_shark_size'] = None | |
return top_pred | |
def add_class_weights(top_pred = {}, class_weights = None): | |
weight_list = [] | |
shark_weight_list = [] | |
if top_pred['any_detection']: | |
for tmp_pred in top_pred['pred_above_thresh_labels']: | |
tmp_class_weights = class_weights[tmp_pred.lower()] | |
if tmp_class_weights == None: | |
weight_list.append(None) | |
else: | |
weight_list.append(tmp_class_weights['pounds']) | |
if 'shark' in tmp_pred.lower(): | |
shark_weight_list.append(np.mean(tmp_class_weights['pounds'])) | |
top_pred['pred_above_thresh_weights'] = weight_list | |
if top_pred['shark_n'] > 0: | |
top_pred['biggest_shark_weight'] = np.max(shark_weight_list) | |
else: | |
top_pred['biggest_shark_weight'] = None | |
else: | |
top_pred['pred_above_thresh_weights'] = None | |
top_pred['biggest_shark_weight'] = None | |
return top_pred | |
# Sizes | |
def get_min_distance_shark_person(top_pred, class_sizes = None, dangerous_distance = 100): | |
min_dist = 99999 | |
dist_calculated = False | |
# Calculate distance for every pairing of human and shark | |
# and accumulate the min distance | |
for i, tmp_shark in enumerate(top_pred['is_shark']): | |
for j, tmp_person in enumerate(top_pred['is_human']): | |
if tmp_shark == 1 and tmp_person == 1: | |
dist_calculated = True | |
#print(top_pred['pred_above_thresh_bboxes'][i]) | |
#print(top_pred['pred_above_thresh_bboxes'][j]) | |
tmp_dist_feed = _calculate_dist_estimate(top_pred['pred_above_thresh_bboxes'][i], | |
top_pred['pred_above_thresh_bboxes'][j], | |
[top_pred['pred_above_thresh_labels'][i], top_pred['pred_above_thresh_labels'][j]], | |
class_sizes, | |
measurement = 'feet') | |
#print(tmp_dist_feed) | |
min_dist = min(min_dist, tmp_dist_feed) | |
else: | |
pass | |
return {'min_dist': str(round(min_dist,1)) + ' feet' if dist_calculated else '', | |
'any_dist_calculated': dist_calculated, | |
'dangerous_dist': min_dist < dangerous_distance} | |
def _calculate_dist_estimate(bbox1, bbox2, labels, class_sizes = None, measurement = 'feet'): | |
class_feet_size_mean = np.array([class_sizes[labels[0]][measurement][0], | |
class_sizes[labels[1]][measurement][0]]).mean() | |
box_pixel_size_mean = np.array([np.linalg.norm(bbox1[[0, 1]] - bbox1[[2, 3]]), | |
np.linalg.norm(bbox2[[0, 1]] - bbox2[[2, 3]])]).mean() | |
# Calculate the max size of the two boxes | |
box_center_1 = np.array([(bbox1[2] - bbox1[0])/2 + bbox1[0], | |
(bbox1[3] - bbox1[1])/2 + bbox1[1]]) | |
box_center_2 = np.array([(bbox2[2] - bbox2[0])/2 + bbox2[0], | |
(bbox2[3] - bbox2[1])/2 + bbox2[1]]) | |
# Return ratio distance | |
return np.linalg.norm(box_center_1 - box_center_2) / box_pixel_size_mean * class_feet_size_mean | |
# bboxes info! | |
# 1 x1 (left, lower pixel number) | |
# 2 y1 (top , lower pixel number) | |
# 3 x2 (right, higher pixel number) | |
# 4 y2 (bottom, higher pixel number) | |
def process_results_for_plot(predictions = None, threshold = 0.5, classes = None, | |
class_sizes = None, dangerous_distance = 100): | |
top_pred = get_top_predictions(predictions, threshold = threshold) | |
top_pred = add_class_labels(top_pred, class_labels = classes) | |
top_pred = add_class_sizes(top_pred, class_sizes = class_sizes) | |
top_pred = add_class_weights(top_pred, class_weights = class_sizes) | |
if len(top_pred['pred_above_thresh']) > 0: | |
min_dist = get_min_distance_shark_person(top_pred, class_sizes = class_sizes) | |
else: | |
min_dist = {'any_dist_calculated': False, | |
'min_dist': '', | |
'dangerous_dist': False} | |
return {'min_dist_str': min_dist['min_dist'], | |
'shark_sighted': top_pred['shark_n'] > 0, | |
'human_sighted': top_pred['human_n'] > 0, | |
'shark_n': top_pred['shark_n'], | |
'human_n': top_pred['human_n'], | |
'human_and_shark': (top_pred['shark_n'] > 0) and (top_pred['human_n'] > 0), | |
'dangerous_dist': min_dist['dangerous_dist'], | |
'dist_calculated': min_dist['any_dist_calculated'], | |
'biggest_shark_size': '' if top_pred['biggest_shark_size'] == None else str(round(top_pred['biggest_shark_size'],1)) + ' feet', | |
'biggest_shark_weight': '' if top_pred['biggest_shark_weight'] == None else str(round(top_pred['biggest_shark_weight'],1)) + ' pounds', | |
} | |
def prediction_dashboard(top_pred = None): | |
# Bullet points: | |
shark_sighted = 'Shark Detected: ' + str(top_pred['shark_sighted']) | |
human_sighted = 'Number of Humans: ' + str(top_pred['human_n']) | |
shark_size_estimate = 'Biggest shark size: ' + str(top_pred['biggest_shark_size']) | |
shark_weight_estimate = 'Biggest shark weight: ' + str(top_pred['biggest_shark_weight']) | |
danger_level = 'Danger Level: ' | |
danger_level += 'High' if top_pred['dangerous_dist'] else 'Low' | |
danger_color = 'orangered' if top_pred['dangerous_dist'] else 'yellowgreen' | |
# Create a list of strings to plot | |
strings = [shark_sighted, human_sighted, shark_size_estimate, shark_weight_estimate, danger_level] | |
# Create a figure and axis | |
fig, ax = plt.subplots() | |
fig.set_facecolor((35/255,40/255,54/255)) | |
# Hide axes | |
ax.axis('off') | |
# Position for starting to place text, starting from top | |
y_pos = 0.7 | |
# Iterate through list and place each item as text on the plot | |
for s in strings: | |
if 'danger' in s.lower(): | |
ax.text(0.05, y_pos, s, transform=ax.transAxes, fontsize=16, color=danger_color) | |
else: | |
ax.text(0.05, y_pos, s, transform=ax.transAxes, fontsize=16, color=(0, 204/255, 153/255)) | |
y_pos -= 0.1 # move down for next item | |
# plt.tight_layout() | |
# If we haven't already shown or saved the plot, then we need to | |
# draw the figure first... | |
fig.canvas.draw(); | |
# Now we can save it to a numpy array. | |
data = np.frombuffer(fig.canvas.tostring_rgb(), dtype=np.uint8) | |
data = data.reshape(fig.canvas.get_width_height()[::-1] + (3,)) | |
plt.close() | |
#plt.savefig('tmp.png', format='png') | |
return data #plt.show() |