From dea64611730c84a59c711c61f7f80948f82bcd31 Mon Sep 17 00:00:00 2001
From: Edmond Yoo <hj3yoo@uwaterloo.ca>
Date: Fri, 12 Oct 2018 20:12:47 +0000
Subject: [PATCH] Commit before removing YOLO
---
opencv_dnn.py | 516 +++++++++++++++++++++++++++++++++++++++++++++++++-------
1 files changed, 448 insertions(+), 68 deletions(-)
diff --git a/opencv_dnn.py b/opencv_dnn.py
index 8746c84..03d4cc5 100644
--- a/opencv_dnn.py
+++ b/opencv_dnn.py
@@ -1,11 +1,141 @@
import cv2
import numpy as np
+import pandas as pd
+import imagehash as ih
import os
+import ast
import sys
+import math
+import random
+import collections
+from operator import itemgetter
+import time
+from PIL import Image
+import fetch_data
+import transform_data
+
+card_width = 315
+card_height = 440
-# Disclaimer: majority of the basic framework in this file is modified from the following tutorial:
-# https://www.learnopencv.com/deep-learning-based-object-detection-using-yolov3-with-opencv-python-c/
+def calc_image_hashes(card_pool, save_to=None, hash_size=32, highfreq_factor=4):
+ new_pool = pd.DataFrame(columns=list(card_pool.columns.values))
+ new_pool['card_hash'] = np.NaN
+ new_pool['art_hash'] = np.NaN
+ for ind, card_info in card_pool.iterrows():
+ if ind % 100 == 0:
+ print(ind)
+
+ card_names = []
+ if card_info['layout'] in ['transform', 'double_faced_token']:
+ if isinstance(card_info['card_faces'], str): # For some reason, dict isn't being parsed in the previous step
+ card_faces = ast.literal_eval(card_info['card_faces'])
+ else:
+ card_faces = card_info['card_faces']
+ for i in range(len(card_faces)):
+ card_names.append(card_faces[i]['name'])
+ else: # if card_info['layout'] == 'normal':
+ card_names.append(card_info['name'])
+
+ for card_name in card_names:
+ card_info['name'] = card_name
+ img_name = '%s/card_img/png/%s/%s_%s.png' % (transform_data.data_dir, card_info['set'],
+ card_info['collector_number'],
+ fetch_data.get_valid_filename(card_info['name']))
+ card_img = cv2.imread(img_name)
+ if card_img is None:
+ fetch_data.fetch_card_image(card_info,
+ out_dir='%s/card_img/png/%s' % (transform_data.data_dir, card_info['set']))
+ card_img = cv2.imread(img_name)
+ if card_img is None:
+ print('WARNING: card %s is not found!' % img_name)
+ #img_art = Image.fromarray(card_img[121:580, 63:685]) # For 745*1040 size card image
+ #art_hash = ih.phash(img_art, hash_size=32, highfreq_factor=4)
+ #card_pool.at[ind, 'art_hash'] = art_hash
+ img_card = Image.fromarray(card_img)
+ card_hash = ih.phash(img_card, hash_size=hash_size, highfreq_factor=highfreq_factor)
+ #card_pool.at[ind, 'card_hash'] = card_hash
+ card_info['card_hash'] = card_hash
+ #print(new_pool.index.max())
+ new_pool.loc[0 if new_pool.empty else new_pool.index.max() + 1] = card_info
+
+ new_pool = new_pool[['artist', 'border_color', 'collector_number', 'color_identity', 'colors', 'flavor_text',
+ 'image_uris', 'mana_cost', 'legalities', 'name', 'oracle_text', 'rarity', 'type_line',
+ 'set', 'set_name', 'power', 'toughness', 'art_hash', 'card_hash']]
+ if save_to is not None:
+ new_pool.to_pickle(save_to)
+ return new_pool
+
+
+# www.pyimagesearch.com/2014/08/25/4-point-opencv-getperspective-transform-example/
+def order_points(pts):
+ # initialzie a list of coordinates that will be ordered
+ # such that the first entry in the list is the top-left,
+ # the second entry is the top-right, the third is the
+ # bottom-right, and the fourth is the bottom-left
+ rect = np.zeros((4, 2), dtype="float32")
+
+ # the top-left point will have the smallest sum, whereas
+ # the bottom-right point will have the largest sum
+ s = pts.sum(axis=1)
+ rect[0] = pts[np.argmin(s)]
+ rect[2] = pts[np.argmax(s)]
+
+ # now, compute the difference between the points, the
+ # top-right point will have the smallest difference,
+ # whereas the bottom-left will have the largest difference
+ diff = np.diff(pts, axis=1)
+ rect[1] = pts[np.argmin(diff)]
+ rect[3] = pts[np.argmax(diff)]
+
+ # return the ordered coordinates
+ return rect
+
+
+# www.pyimagesearch.com/2014/08/25/4-point-opencv-getperspective-transform-example/
+def four_point_transform(image, pts):
+ # obtain a consistent order of the points and unpack them
+ # individually
+ rect = order_points(pts)
+ (tl, tr, br, bl) = rect
+
+ # compute the width of the new image, which will be the
+ # maximum distance between bottom-right and bottom-left
+ # x-coordiates or the top-right and top-left x-coordinates
+ widthA = np.sqrt(((br[0] - bl[0]) ** 2) + ((br[1] - bl[1]) ** 2))
+ widthB = np.sqrt(((tr[0] - tl[0]) ** 2) + ((tr[1] - tl[1]) ** 2))
+ maxWidth = max(int(widthA), int(widthB))
+
+ # compute the height of the new image, which will be the
+ # maximum distance between the top-right and bottom-right
+ # y-coordinates or the top-left and bottom-left y-coordinates
+ heightA = np.sqrt(((tr[0] - br[0]) ** 2) + ((tr[1] - br[1]) ** 2))
+ heightB = np.sqrt(((tl[0] - bl[0]) ** 2) + ((tl[1] - bl[1]) ** 2))
+ maxHeight = max(int(heightA), int(heightB))
+
+ # now that we have the dimensions of the new image, construct
+ # the set of destination points to obtain a "birds eye view",
+ # (i.e. top-down view) of the image, again specifying points
+ # in the top-left, top-right, bottom-right, and bottom-left
+ # order
+ dst = np.array([
+ [0, 0],
+ [maxWidth - 1, 0],
+ [maxWidth - 1, maxHeight - 1],
+ [0, maxHeight - 1]], dtype="float32")
+
+ # compute the perspective transform matrix and then apply it
+ mat = cv2.getPerspectiveTransform(rect, dst)
+ warped = cv2.warpPerspective(image, mat, (maxWidth, maxHeight))
+
+ # If the image is horizontally long, rotate it by 90
+ if maxWidth > maxHeight:
+ center = (maxHeight / 2, maxHeight / 2)
+ mat_rot = cv2.getRotationMatrix2D(center, 270, 1.0)
+ warped = cv2.warpAffine(warped, mat_rot, (maxHeight, maxWidth))
+
+ # return the warped image
+ return warped
# Get the names of the output layers
@@ -17,7 +147,8 @@
# Remove the bounding boxes with low confidence using non-maxima suppression
-def postprocess(frame, outs, classes, thresh_conf, thresh_nms):
+# https://www.learnopencv.com/deep-learning-based-object-detection-using-yolov3-with-opencv-python-c/
+def post_process(frame, outs, thresh_conf, thresh_nms):
frame_height = frame.shape[0]
frame_width = frame.shape[1]
@@ -42,17 +173,11 @@
confidences.append(float(confidence))
boxes.append([left, top, width, height])
- # Perform non maximum suppression to eliminate redundant overlapping boxes with
- # lower confidences.
- indices = cv2.dnn.NMSBoxes(boxes, confidences, thresh_conf, thresh_nms)
- for i in indices:
- i = i[0]
- box = boxes[i]
- left = box[0]
- top = box[1]
- width = box[2]
- height = box[3]
- draw_pred(frame, class_ids[i], classes, confidences[i], left, top, left + width, top + height)
+ # Perform non maximum suppression to eliminate redundant overlapping boxes with lower confidences.
+ indices = [ind[0] for ind in cv2.dnn.NMSBoxes(boxes, confidences, thresh_conf, thresh_nms)]
+
+ ret = [[class_ids[i], confidences[i], boxes[i]] for i in indices]
+ return ret
# Draw the predicted bounding box
@@ -73,7 +198,114 @@
cv2.putText(frame, label, (left, top), cv2.FONT_HERSHEY_SIMPLEX, 0.5, (255, 255, 255))
-def detect_frame(net, classes, img, thresh_conf=0.5, thresh_nms=0.4, in_dim=(416, 416), out_path=None):
+def remove_glare(img):
+ """
+ Inspired from:
+ http://www.amphident.de/en/blog/preprocessing-for-automatic-pattern-identification-in-wildlife-removing-glare.html
+ The idea is to find area that has low saturation but high value, which is what a glare usually look like.
+ """
+ img_hsv = cv2.cvtColor(img, cv2.COLOR_BGR2HSV)
+ _, s, v = cv2.split(img_hsv)
+ non_sat = (s < 32) * 255 # Find all pixels that are not very saturated
+
+ # Slightly decrease the area of the non-satuared pixels by a erosion operation.
+ disk = cv2.getStructuringElement(cv2.MORPH_ELLIPSE, (3, 3))
+ non_sat = cv2.erode(non_sat.astype(np.uint8), disk)
+
+ # Set all brightness values, where the pixels are still saturated to 0.
+ v[non_sat == 0] = 0
+ # filter out very bright pixels.
+ glare = (v > 200) * 255
+
+ # Slightly increase the area for each pixel
+ glare = cv2.dilate(glare.astype(np.uint8), disk)
+ glare_reduced = np.ones((img.shape[0], img.shape[1], 3), dtype=np.uint8) * 200
+ glare = cv2.cvtColor(glare, cv2.COLOR_GRAY2BGR)
+ corrected = np.where(glare, glare_reduced, img)
+ return corrected
+
+
+def find_card(img, thresh_c=5, kernel_size=(3, 3), size_ratio=0.2):
+ # Typical pre-processing - grayscale, blurring, thresholding
+ img_gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
+ img_blur = cv2.medianBlur(img_gray, 5)
+ img_thresh = cv2.adaptiveThreshold(img_blur, 255, cv2.ADAPTIVE_THRESH_MEAN_C, cv2.THRESH_BINARY_INV, 5, thresh_c)
+
+ # Dilute the image, then erode them to remove minor noises
+ kernel = np.ones(kernel_size, np.uint8)
+ img_dilate = cv2.dilate(img_thresh, kernel, iterations=1)
+ img_erode = cv2.erode(img_dilate, kernel, iterations=1)
+
+ # Find the contour
+ #img_contour = img_erode.copy()
+ _, cnts, hier = cv2.findContours(img_erode, cv2.RETR_TREE, cv2.CHAIN_APPROX_SIMPLE)
+ if len(cnts) == 0:
+ print('no contours')
+ return []
+ #img_contour = cv2.cvtColor(img_contour, cv2.COLOR_GRAY2BGR)
+ #img_contour = cv2.drawContours(img_contour, cnts, -1, (0, 255, 0), 1)
+ #cv2.imshow('test', img_contour)
+
+ # For each contours detected, check if they are large enough and are rectangle
+ cnts_rect = []
+ ind_sort = sorted(range(len(cnts)), key=lambda i: cv2.contourArea(cnts[i]), reverse=True)
+ for i in range(min(len(cnts), 5)): # The card should be within top 5 largest contour
+ size = cv2.contourArea(cnts[ind_sort[i]])
+ peri = cv2.arcLength(cnts[ind_sort[i]], True)
+ approx = cv2.approxPolyDP(cnts[ind_sort[i]], 0.04 * peri, True)
+ if size > img.shape[0] * img.shape[1] * size_ratio and len(approx) == 4:
+ cnts_rect.append(approx)
+
+ return cnts_rect
+
+
+def draw_card_graph(exist_cards, card_pool, f_len):
+ w_card = 63
+ h_card = 88
+ gap = 25
+ gap_sm = 10
+ w_bar = 300
+ h_bar = 12
+ txt_scale = 0.8
+ n_cards_p_col = 4
+ w_img = gap + (w_card + gap + w_bar + gap) * 2
+ #h_img = gap + (h_card + gap) * n_cards_p_col
+ h_img = 480
+ img_graph = np.zeros((h_img, w_img, 3), dtype=np.uint8)
+ x_anchor = gap
+ y_anchor = gap
+
+ i = 0
+ for key, val in sorted(exist_cards.items(), key=itemgetter(1), reverse=True)[:n_cards_p_col * 2]:
+ card_name = key[:key.find('(') - 1]
+ card_set = key[key.find('(') + 1:key.find(')')]
+ confidence = sum(val) / f_len
+ card_info = card_pool[(card_pool['name'] == card_name) & (card_pool['set'] == card_set)].iloc[0]
+ img_name = '%s/card_img/tiny/%s/%s_%s.png' % (transform_data.data_dir, card_info['set'],
+ card_info['collector_number'],
+ fetch_data.get_valid_filename(card_info['name']))
+ card_img = cv2.imread(img_name)
+ img_graph[y_anchor:y_anchor + h_card, x_anchor:x_anchor + w_card] = card_img
+ cv2.putText(img_graph, '%s (%s)' % (card_name, card_set),
+ (x_anchor + w_card + gap, y_anchor + gap_sm + int(txt_scale * 25)), cv2.FONT_HERSHEY_SIMPLEX,
+ txt_scale, (255, 255, 255), 1)
+ cv2.rectangle(img_graph, (x_anchor + w_card + gap, y_anchor + h_card - (gap_sm + h_bar)),
+ (x_anchor + w_card + gap + int(w_bar * confidence), y_anchor + h_card - gap_sm), (0, 255, 0),
+ thickness=cv2.FILLED)
+ y_anchor += h_card + gap
+ i += 1
+ if i % n_cards_p_col == 0:
+ x_anchor += w_card + gap + w_bar + gap
+ y_anchor = gap
+ pass
+ return img_graph
+
+
+def detect_frame(net, classes, img, card_pool, thresh_conf=0.5, thresh_nms=0.4, in_dim=(416, 416), out_path=None, display=True,
+ debug=False):
+ start_1 = time.time()
+ elapsed = []
+ '''
# Create a 4D blob from a frame.
blob = cv2.dnn.blobFromImage(img, 1 / 255, in_dim, [0, 0, 0], 1, crop=False)
@@ -82,79 +314,224 @@
# Runs the forward pass to get output of the output layers
outs = net.forward(get_outputs_names(net))
+ elapsed.append((time.time() - start_1) * 1000)
+
+ start_2 = time.time()
+ img_result = img.copy()
# Remove the bounding boxes with low confidence
- postprocess(img, outs, classes, thresh_conf, thresh_nms)
-
+ obj_list = post_process(img, outs, thresh_conf, thresh_nms)
+ for obj in obj_list:
+ class_id, confidence, box = obj
+ left, top, width, height = box
+ draw_pred(img_result, class_id, classes, confidence, left, top, left + width, top + height)
+ elapsed.append((time.time() - start_2) * 1000)
+ '''
+ img_result = img.copy()
+ obj_list = []
# Put efficiency information. The function getPerfProfile returns the
# overall time for inference(t) and the timings for each of the layers(in layersTimes)
- t, _ = net.getPerfProfile()
- label = 'Inference time: %.2f ms' % (t * 1000.0 / cv2.getTickFrequency())
- cv2.putText(img, label, (0, 15), cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 0, 255))
+ #if display:
+ # t, _ = net.getPerfProfile()
+ # label = 'Inference time: %.2f ms' % (t * 1000.0 / cv2.getTickFrequency())
+ # cv2.putText(img_result, label, (0, 15), cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 0, 255))
+
+ '''
+ Assuming that the model has properly identified all cards, there should be 1 card that can be classified per
+ bounding box. Find the largest rectangular contour from the region of interest, and identify the card by
+ comparing the perceptual hashing of the image with the other cards' image from the database.
+ '''
+ det_cards = []
+ for i in range(len(obj_list)):
+ start_3 = time.time()
+ _, _, box = obj_list[i]
+ left, top, width, height = box
+ # Just in case the bounding box trimmed the edge of the cards, give it a bit of offset around the edge
+ offset_ratio = 0.1
+ x1 = max(0, int(left - offset_ratio * width))
+ x2 = min(img.shape[1], int(left + (1 + offset_ratio) * width))
+ y1 = max(0, int(top - offset_ratio * height))
+ y2 = min(img.shape[0], int(top + (1 + offset_ratio) * height))
+ img_snip = img[y1:y2, x1:x2]
+ cnts = find_card(img_snip)
+ elapsed.append((time.time() - start_3) * 1000)
+ if len(cnts) > 0:
+ start_4 = time.time()
+ cnt = cnts[0] # The largest (rectangular) contour
+ pts = np.float32([p[0] for p in cnt])
+ img_warp = four_point_transform(img_snip, pts)
+ img_warp = cv2.resize(img_warp, (card_width, card_height))
+ elapsed.append((time.time() - start_4) * 1000)
+ '''
+ img_art = img_warp[47:249, 22:294]
+ img_art = Image.fromarray(img_art.astype('uint8'), 'RGB')
+ art_hash = ih.phash(img_art, hash_size=32, highfreq_factor=4)
+ card_pool['hash_diff'] = card_pool['art_hash'] - art_hash
+ min_cards = card_pool[card_pool['hash_diff'] == min(card_pool['hash_diff'])]
+ card_name = min_cards.iloc[0]['name']
+ '''
+ start_5 = time.time()
+ img_card = Image.fromarray(img_warp.astype('uint8'), 'RGB')
+ card_hash = ih.phash(img_card, hash_size=32, highfreq_factor=4).hash.flatten()
+ card_pool['hash_diff'] = card_pool['card_hash'].apply(lambda x: np.count_nonzero(x != card_hash))
+ min_cards = card_pool[card_pool['hash_diff'] == min(card_pool['hash_diff'])]
+ card_name = min_cards.iloc[0]['name']
+ card_set = min_cards.iloc[0]['set']
+ det_cards.append((card_name, card_set))
+ hash_diff = min_cards.iloc[0]['hash_diff']
+ elapsed.append((time.time() - start_5) * 1000)
+
+ # Display the result
+ if debug:
+ # cv2.rectangle(img_warp, (22, 47), (294, 249), (0, 255, 0), 2)
+ cv2.putText(img_warp, card_name + ', ' + str(hash_diff), (0, 50),
+ cv2.FONT_HERSHEY_SIMPLEX, 1, (255, 255, 255), 2)
+ cv2.putText(img_result, card_name, (x1, y1), cv2.FONT_HERSHEY_SIMPLEX, 0.5, (255, 255, 255), 2)
+ if debug:
+ cv2.imshow('card#%d' % i, img_warp)
+ elif debug:
+ cv2.imshow('card#%d' % i, np.zeros((1, 1), dtype=np.uint8))
if out_path is not None:
- cv2.imwrite(out_path, img.astype(np.uint8))
+ cv2.imwrite(out_path, img_result.astype(np.uint8))
+ elapsed = [(time.time() - start_1) * 1000] + elapsed
+ #print(', '.join(['%.2f' % t for t in elapsed]))
+ return obj_list, det_cards, img_result
-def detect_video(net, classes, capture, thresh_conf=0.5, thresh_nms=0.4, in_dim=(416, 416), out_path=None):
+def detect_video(net, classes, capture, card_pool, thresh_conf=0.5, thresh_nms=0.4, in_dim=(416, 416), out_path=None,
+ display=True, debug=False):
if out_path is not None:
- vid_writer = cv2.VideoWriter(out_path, cv2.VideoWriter_fourcc('M', 'J', 'P', 'G'), 30,
- (round(capture.get(cv2.CAP_PROP_FRAME_WIDTH)),
- round(capture.get(cv2.CAP_PROP_FRAME_HEIGHT))))
- while True:
- ret, frame = capture.read()
- if not ret:
- # End of video
- print("End of video. Press any key to exit")
- cv2.waitKey(0)
- break
- '''
- # Create a 4D blob from a frame.
- blob = cv2.dnn.blobFromImage(frame, 1 / 255, in_dim, [0, 0, 0], 1, crop=False)
+ img_graph = draw_card_graph({}, None, -1) # Black image of the graph just to get the dimension
+ width = round(capture.get(cv2.CAP_PROP_FRAME_WIDTH)) + img_graph.shape[1]
+ height = max(round(capture.get(cv2.CAP_PROP_FRAME_HEIGHT)), img_graph.shape[0])
+ vid_writer = cv2.VideoWriter(out_path, cv2.VideoWriter_fourcc(*'MJPG'), 10.0, (width, height))
+ max_num_obj = 0
+ f_len = 10 # number of frames to consider to check for existing cards
+ exist_cards = {}
+ try:
+ while True:
+ ret, frame = capture.read()
+ start_time = time.time()
+ if not ret:
+ # End of video
+ print("End of video. Press any key to exit")
+ cv2.waitKey(0)
+ break
+ # Use the YOLO model to identify each cards annonymously
+ start_yolo = time.time()
+ obj_list, det_cards, img_result = detect_frame(net, classes, frame, card_pool, thresh_conf=thresh_conf,
+ thresh_nms=thresh_nms, in_dim=in_dim, out_path=None,
+ display=display, debug=debug)
+ elapsed_yolo = (time.time() - start_yolo) * 1000
+ # If the card was already detected in the previous frame, append 1 to the list
+ # If the card previously detected was not found in this trame, append 0 to the list
+ # If the card wasn't previously detected, make a new list and add 1 to it
+ # If the same card is detected multiple times in the same frame, keep track of the duplicates
+ # The confidence will be calculated based on the number of frames the card was detected for
+ det_cards_count = collections.Counter(det_cards).items()
+ det_cards_list = []
+ for card, count in det_cards_count:
+ card_name, card_set = card
+ for i in range(count): 1
+ key = '%s (%s) #%d' % (card_name, card_set, i + 1)
+ det_cards_list.append(key)
+ gone = []
+ for key, val in exist_cards.items():
+ if key in det_cards_list:
+ exist_cards[key] = exist_cards[key][1 - f_len:] + [1]
+ else:
+ exist_cards[key] = exist_cards[key][1 - f_len:] + [0]
+ if len(val) == f_len and sum(val) == 0:
+ gone.append(key)
+ for key in det_cards_list:
+ if key not in exist_cards.keys():
+ exist_cards[key] = [1]
+ for key in gone:
+ exist_cards.pop(key)
+ start_graph = time.time()
+ img_graph = draw_card_graph(exist_cards, card_pool, f_len)
+ elapsed_graph = (time.time() - start_graph) * 1000
+ if debug:
+ max_num_obj = max(max_num_obj, len(obj_list))
+ for i in range(len(obj_list), max_num_obj):
+ cv2.imshow('card#%d' % i, np.zeros((1, 1), dtype=np.uint8))
- # Sets the input to the network
- net.setInput(blob)
+ start_display = time.time()
+ img_save = np.zeros((height, width, 3), dtype=np.uint8)
+ img_save[0:img_result.shape[0], 0:img_result.shape[1]] = img_result
+ img_save[0:img_graph.shape[0], img_result.shape[1]:img_result.shape[1] + img_graph.shape[1]] = img_graph
+ if display:
+ cv2.imshow('result', img_save)
+ elapsed_display = (time.time() - start_display) * 1000
- # Runs the forward pass to get output of the output layers
- outs = net.forward(get_outputs_names(net))
-
- # Remove the bounding boxes with low confidence
- postprocess(frame, outs, classes, thresh_conf, thresh_nms)
-
- # Put efficiency information. The function getPerfProfile returns the
- # overall time for inference(t) and the timings for each of the layers(in layersTimes)
- t, _ = net.getPerfProfile()
- label = 'Inference time: %.2f ms' % (t * 1000.0 / cv2.getTickFrequency())
- cv2.putText(frame, label, (0, 15), cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 0, 255))
- '''
- detect_frame(net, classes, frame,
- thresh_conf=thresh_conf, thresh_nms=thresh_nms, in_dim=in_dim, out_path=None)
- cv2.imshow('result', frame)
+ elapsed_ms = (time.time() - start_time) * 1000
+ #print('Elapsed time: %.2f ms, %.2f, %.2f, %.2f' % (elapsed_ms, elapsed_yolo, elapsed_graph, elapsed_display))
+ if out_path is not None:
+ vid_writer.write(img_save.astype(np.uint8))
+ cv2.waitKey(1)
+ except KeyboardInterrupt:
+ capture.release()
if out_path is not None:
- vid_writer.write(frame.astype(np.uint8))
- cv2.waitKey(1)
-
- if out_path is not None:
- vid_writer.release()
- cv2.destroyAllWindows()
- pass
+ vid_writer.release()
+ cv2.destroyAllWindows()
def main():
# Specify paths for all necessary files
- test_path = '../data/test1.mp4'
+ test_path = os.path.abspath('test_file/test4.mp4')
+ #weight_path = 'backup/tiny_yolo_10_39500.weights'
+ #cfg_path = 'cfg/tiny_yolo_10.cfg'
+ #class_path = "data/obj_10.names"
weight_path = 'weights/second_general/tiny_yolo_final.weights'
- cfg_path = 'cfg/tiny_yolo.cfg'
- class_path = "data/obj.names"
+ cfg_path = 'cfg/tiny_yolo_old.cfg'
+ class_path = 'data/obj.names'
out_dir = 'out'
if not os.path.isfile(test_path):
print('The test file %s doesn\'t exist!' % os.path.abspath(test_path))
+ return
if not os.path.isfile(weight_path):
print('The weight file %s doesn\'t exist!' % os.path.abspath(test_path))
+ return
if not os.path.isfile(cfg_path):
print('The config file %s doesn\'t exist!' % os.path.abspath(test_path))
+ return
if not os.path.isfile(class_path):
print('The class file %s doesn\'t exist!' % os.path.abspath(test_path))
+ return
+
+
+ '''
+ df_list = []
+ for set_name in fetch_data.all_set_list:
+ csv_name = '%s/csv/%s.csv' % (transform_data.data_dir, set_name)
+ df = fetch_data.load_all_cards_text(csv_name)
+ df_list.append(df)
+ #print(df)
+ card_pool = pd.concat(df_list, sort=True)
+ card_pool.reset_index(drop=True, inplace=True)
+ card_pool.drop('Unnamed: 0', axis=1, inplace=True, errors='ignore')
+ for hash_size in [8, 16, 32, 64]:
+ for highfreq_factor in [4, 8, 16, 32]:
+ pck_name = 'card_pool_%d_%d.pck' % (hash_size, highfreq_factor)
+ if not os.path.exists(pck_name):
+ print(pck_name)
+ calc_image_hashes(card_pool, save_to=pck_name, hash_size=hash_size, highfreq_factor=highfreq_factor)
+ '''
+ #csv_name = '%s/csv/%s.csv' % (transform_data.data_dir, 'rtr')
+ #card_pool = fetch_data.load_all_cards_text(csv_name)
+ #card_pool = calc_image_hashes(card_pool, save_to='card_pool.pck')
+ #return
+ card_pool = pd.read_pickle('card_pool_32_4.pck')
+ #card_pool = card_pool[(card_pool['set'] == 'rtr') | (card_pool['set'] == 'isd')]
+ card_pool = card_pool[['name', 'set', 'collector_number', 'card_hash']]
+
+ # ImageHash is basically just one numpy.ndarray with (hash_size)^2 number of bits. pre-emptively flattening it
+ # significantly increases speed for subtracting hashes in the future.
+ card_pool['card_hash'] = card_pool['card_hash'].apply(lambda x: x.hash.flatten())
+
+ thresh_conf = 0.01
+ thresh_nms = 0.8
# Setup
# Read class names from text file
@@ -162,22 +539,25 @@
classes = [line.strip() for line in f.readlines()]
# Load up the neural net using the config and weights
net = cv2.dnn.readNetFromDarknet(cfg_path, weight_path)
- #net.setPreferableBackend(cv2.dnn.DNN_BACKEND_OPENCV)
- #net.setPreferableTarget(cv2.dnn.DNN_TARGET_CPU)
+ net.setPreferableBackend(cv2.dnn.DNN_BACKEND_OPENCV)
+ net.setPreferableTarget(cv2.dnn.DNN_TARGET_CPU)
# Save the detection result if out_dir is provided
if out_dir is None or out_dir == '':
out_path = None
else:
- out_path = out_dir + '/' + os.path.split(test_path)[1]
+ f_name = os.path.split(test_path)[1]
+ out_path = out_dir + '/' + f_name[:f_name.find('.')] + '.avi'
# Check if test file is image or video
test_ext = test_path[test_path.find('.') + 1:]
+
if test_ext in ['jpg', 'jpeg', 'bmp', 'png', 'tiff']:
img = cv2.imread(test_path)
- detect_frame(net, classes, img, out_path=out_path)
+ detect_frame(net, classes, img, card_pool, out_path=out_path, thresh_conf=thresh_conf, thresh_nms=thresh_nms)
else:
- capture = cv2.VideoCapture(test_path)
- detect_video(net, classes, capture, out_path=out_path)
+ capture = cv2.VideoCapture(0)
+ detect_video(net, classes, capture, card_pool, out_path=out_path, thresh_conf=thresh_conf, thresh_nms=thresh_nms,
+ display=True, debug=False)
capture.release()
pass
--
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