This commit is contained in:
Alexander Munch-Hansen 2019-05-18 17:12:35 +02:00
parent 12ab541de6
commit e97ec3fea9
18 changed files with 319 additions and 50 deletions

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main.py
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@ -1,5 +1,10 @@
import glob
import random
import re
import sys
import warnings
import time
from typing import List, Tuple
import cv2
import matplotlib.pyplot as plt
@ -7,7 +12,8 @@ import numpy as np
from sklearn.exceptions import DataConversionWarning
import runner
from util import load_classifier, PIECE, COLOR, POSITION, Board, Squares, PieceAndColor, OUR_PIECES
from tensor_classifier import predict_board, predict_piece, predict_empty_nn
from util import load_classifier, PIECE, COLOR, POSITION, Board, Squares, PieceAndColor, OUR_PIECES, FILE, RANK, LESS_PIECE
warnings.filterwarnings(action='ignore', category=DataConversionWarning)
np.set_printoptions(threshold=sys.maxsize)
@ -32,7 +38,7 @@ def identify_piece(image: np.ndarray, position: POSITION, sift: cv2.xfeatures2d_
#prob = classifier.predict_proba(data)
probs[piece.name][color.name] = prob[0, 1]
print(f"{piece}, {color}, {prob[0, 1]}")
#print(f"{piece}, {color}, {prob[0, 1]}")
#if prob[0, 1] > best and color == position.color: # can only be best if correct color. Iterating through both colors for debugging only
if prob[0, 1] > best:
best = prob[0, 1]
@ -92,7 +98,23 @@ def predict_empty(square: np.ndarray, position: POSITION) -> bool:
empty_classifier = load_classifier(f"classifiers/classifier_empty/white_piece_on_{position.color}_square.pkl")
prob = empty_classifier.predict_proba(np.array(y).reshape(1, -1))
#print(f"{position}, {position.color}: {prob[0, 1]}")
return prob[0, 1] > 0.95
y, x = np.histogram(square.ravel(), bins=64, range=[0, 256])
lel = np.array(y).reshape(1, -1)
#print(lel[lel > 5000])
#print(np.array(y).reshape(1, -1))
return prob[0, 1] > 0.75
if position.color == "white":
return prob[0, 1] > 0.75 or len(lel[lel > 5000]) > 5
else:
return prob[0, 1] > 0.65 or len(lel[lel > 5000]) > 5
def remove_most_empties(warped):
@ -133,6 +155,139 @@ def remove_most_empties(warped):
return non_empties
def test_empties():
pred_empty = 0
actual_empty = 0
import random
for filename in glob.glob(f"training_images/*/*_square/*.png"):
square = cv2.imread(filename)
if square.shape != (172, 172, 3):
continue
if 'empty' in filename:
actual_empty += 1
if "black" in filename:
pos = POSITION.A1
else:
pos = POSITION.A2
square = cv2.GaussianBlur(square, (7, 7), 0)
square = cv2.multiply(square, np.array([(random.random() * 0.50) + 0.90]))
pred_empty += predict_empty(square, pos)
#pred_empty += 1 - predict_empty_nn(square)
print(actual_empty)
print(pred_empty)
print(min(actual_empty,pred_empty)/max(actual_empty, pred_empty))
def test_piece_recognition(svms = False):
sift = cv2.xfeatures2d.SIFT_create()
total = 0
correct_guess = 0
for filename in glob.glob(f"training_images/rook/*/*.png"):
img = cv2.imread(filename)
square = cv2.GaussianBlur(img, (9, 9), 0)
square = cv2.multiply(square, np.array([(random.random() * 5) + 0.90]))
#cv2.imwrite("normal_square.png", img)
#cv2.imwrite("modified_square.png", square)
#cv2.imshow("normal", img)
#cv2.imshow("modified", square)
#cv2.waitKey(0)
if "black" in filename:
pos = POSITION.A1
else:
pos = POSITION.A2
if (svms):
res = identify_piece(square, pos, sift)[0]
correct_guess += (res == LESS_PIECE.ROOK)
else:
res = predict_piece(square)
correct_guess += (res == LESS_PIECE.ROOK)
total += 1
for filename in glob.glob(f"training_images/knight/*/*.png"):
img = cv2.imread(filename)
square = cv2.GaussianBlur(img, (7, 7), 0)
square = cv2.multiply(square, np.array([(random.random() * 0.50) + 0.90]))
if "black" in filename:
pos = POSITION.A1
else:
pos = POSITION.A2
if (svms):
res = identify_piece(square, pos, sift)[0]
correct_guess += (res == LESS_PIECE.KNIGHT)
else:
res = predict_piece(square)
correct_guess += (res == LESS_PIECE.KNIGHT)
total += 1
for filename in glob.glob(f"training_images/bishop/*/*.png"):
img = cv2.imread(filename)
square = cv2.GaussianBlur(img, (7, 7), 0)
square = cv2.multiply(square, np.array([(random.random() * 0.50) + 0.90]))
if "black" in filename:
pos = POSITION.A1
else:
pos = POSITION.A2
if (svms):
res = identify_piece(square, pos, sift)[0]
correct_guess += (res == LESS_PIECE.BISHOP)
else:
res = predict_piece(square)
correct_guess += (res == LESS_PIECE.BISHOP)
total += 1
for filename in glob.glob(f"training_images/king/*/*.png"):
img = cv2.imread(filename)
square = cv2.GaussianBlur(img, (7, 7), 0)
square = cv2.multiply(square, np.array([(random.random() * 0.50) + 0.90]))
if "black" in filename:
pos = POSITION.A1
else:
pos = POSITION.A2
if (svms):
res = identify_piece(square, pos, sift)[0]
correct_guess += (res == LESS_PIECE.KING)
else:
res = predict_piece(square)
correct_guess += (res == LESS_PIECE.KING)
total += 1
for filename in glob.glob(f"training_images/queen/*/*.png"):
img = cv2.imread(filename)
square = cv2.GaussianBlur(img, (7, 7), 0)
square = cv2.multiply(square, np.array([(random.random() * 0.50) + 0.90]))
if "black" in filename:
pos = POSITION.A1
else:
pos = POSITION.A2
if (svms):
res = identify_piece(square, pos, sift)[0]
correct_guess += (res == LESS_PIECE.QUEEN)
else:
res = predict_piece(square)
correct_guess += (res == LESS_PIECE.QUEEN)
total += 1
print(total)
print(correct_guess)
print(min(total, correct_guess)/max(total, correct_guess))
def find_occupied_squares(warped: np.ndarray) -> Squares:
non_empties = remove_most_empties(warped)
@ -144,18 +299,54 @@ def find_occupied_squares(warped: np.ndarray) -> Squares:
return completely_non_empties
def find_occupied_using_nn(warped: np.ndarray) -> Squares:
non_empties = runner.get_squares(warped)
completely_non_empties = {}
for (position, square) in non_empties.items():
prediction = predict_empty_nn(square)
if prediction:
completely_non_empties[position] = square
return completely_non_empties
if __name__ == '__main__':
test_piece_recognition(svms=True)
exit()
#runner.train_pieces_svm()
board = cv2.imread("whole_boards/boards_for_empty/board_1554288891.129901_rank_8.png")
#board = cv2.imread("whole_boards/boards_for_empty/board_1554286515.323962_rank_3.png")
#board = cv2.imread("quality_check.png")
#board = cv2.imread("whole_boards/boards_for_empty/board_1554286526.199486_rank_3.png")
board = cv2.imread("whole_boards/boards_for_empty/lmao_xd_gg_v2.png")
start = time.time()
warped = runner.warp_board(board)
print(time.time() - start)
#cv2.imshow("warped", warped)
#cv2.waitKey(0)
# squares = runner.get_squares(warped)
#squares = find_occupied_squares(warped)
squares = find_occupied_using_nn(warped)
tmp = find_occupied_squares(warped)
for pos, square in tmp:
for pos, square in squares.items():
piece = predict_piece(square)
cv2.putText(square, f"{pos} {piece}", (0, 50), cv2.FONT_HERSHEY_SIMPLEX, fontScale=1, color=(255,)*3, thickness=3)
cv2.imshow(f"{pos}", square)
cv2.waitKey(0)
exit()
tmp = find_occupied_squares(warped)
#for pos, square in tmp:
# cv2.imshow(f"{pos}", square)
#cv2.waitKey(0)
board = predict_board(tmp)
for pos, piece in board.items():
print(f"{pos}, {piece}")
exit()
"""

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@ -6,15 +6,17 @@ import runner
from util import FILE, RANK, PIECE, COLOR, imwrite, POSITION
cap = cv2.VideoCapture(0)
#cap.set(cv2.CAP_PROP_FRAME_WIDTH, 4096)
#cap.set(cv2.CAP_PROP_FRAME_HEIGHT, 2160)
color = COLOR.BLACK
rank = RANK.EIGHT
cap.set(cv2.CAP_PROP_FRAME_WIDTH, 1920)
cap.set(cv2.CAP_PROP_FRAME_HEIGHT, 1080)
color = COLOR.WHITE
rank = RANK.FIVE
pieces = {
PIECE.rook: [POSITION((FILE.A, rank)), POSITION((FILE.F, rank))],
PIECE.knight: [POSITION((FILE.E, rank)), POSITION((FILE.H, rank))],
PIECE.bishop: [POSITION((FILE.C, rank)), POSITION((FILE.D, rank))],
PIECE.queen: [POSITION((FILE.B, rank))],
PIECE.king: [POSITION((FILE.G, rank))],
PIECE.PAWN: [POSITION((FILE.A, rank)), POSITION((FILE.B, rank)), POSITION((FILE.C, rank)), POSITION((FILE.D, rank)),
POSITION((FILE.E, rank)), POSITION((FILE.F, rank)), POSITION((FILE.G, rank)), POSITION((FILE.H, rank))]
}
while True:
@ -26,16 +28,18 @@ while True:
if cv2.waitKey(100) & 0xFF == ord("c"):
print(f"capturing frame")
imwrite(f"whole_boards/boards_for_empty/board_{datetime.utcnow().timestamp()}_.png", frame)
#imwrite(f"whole_boards/boards_for_empty/board_{datetime.utcnow().timestamp()}_.png", frame)
imwrite("whole_boards/boards_for_empty/lol_gg_xD.png", frame)
break
warped = runner.warp_board(frame)
runner.save_empty_fields(warped, skip_rank=rank)
#runner.save_empty_fields(warped, skip_rank=rank)
for piece, positions in pieces.items():
for position in positions:
square = runner.get_square(warped, *position)
x, y = position
imwrite(f"training_images/{piece}/{position.color}_square/training_{x}{str(y)}_{datetime.utcnow().timestamp()}.png", square)
square = runner.get_square(warped, position)
imwrite(f"training_images/{piece}/{position.color}_square/training_{position}_{datetime.utcnow().timestamp()}.png", square)
# When everything done, release the capture

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@ -1,9 +1,13 @@
import glob
import os
import time
from datetime import datetime
from pathlib import Path
from typing import Tuple
import copyreg
import cv2
import numpy as np
from sklearn import cluster, metrics, svm, neural_network
@ -14,6 +18,11 @@ from sklearn.preprocessing import StandardScaler
from util import RANK, POSITION, imwrite, PIECE, COLOR, Squares, OUR_PIECES
here: Path = Path(__file__).parent
BASELINE = cv2.imread(str(here.joinpath("new_baseline_board.png")))
BASELINE_GRAY = cv2.cvtColor(BASELINE, cv2.COLOR_BGR2GRAY)
SIFT = cv2.xfeatures2d.SIFT_create()
BASELINE_KEYPOINTS = SIFT.detect(BASELINE_GRAY)
BASELINE_KEYPOINTS, BASELINE_DES = SIFT.compute(BASELINE_GRAY, BASELINE_KEYPOINTS)
def generate_centers(number_of_clusters, sift: cv2.xfeatures2d_SIFT):
@ -112,7 +121,7 @@ def train_pieces_svm() -> None:
current_weight = len(glob.glob(f"training_images/{piece}/{color}_square/*.png"))
print(f"Training for piece: {piece}")
X, Y = load_training_data(piece, color)
classifier = svm.SVC(C=10, gamma=0.01, class_weight={0: 15, 1: 0.8}, probability=True)
classifier = svm.SVC(gamma=0.01, class_weight={0: current_weight, 1: total_weights}, probability=True)
classifier.fit(X, Y)
joblib.dump(classifier, f"classifiers/classifier_{piece}/{color}.pkl")
@ -140,23 +149,30 @@ def find_keypoints(camera_image: np.ndarray, baseline: np.ndarray, debug=False)
:return: (src points, dest points)
"""
cv2.imwrite("camera_image.png", camera_image)
camera_image_gray = cv2.cvtColor(camera_image, cv2.COLOR_BGR2GRAY)
baseline_gray = cv2.cvtColor(baseline, cv2.COLOR_BGR2GRAY)
sift = cv2.xfeatures2d.SIFT_create()
camera_image_keypoints = sift.detect(camera_image_gray, None)
baseline_keypoints = sift.detect(baseline_gray, None)
#sift = cv2.xfeatures2d.SURF_create()
camera_image_keypoints, des = sift.compute(camera_image_gray, camera_image_keypoints)
baseline_keypoints, des2 = sift.compute(baseline_gray, baseline_keypoints)
kp_start = time.time()
camera_image_keypoints = SIFT.detect(camera_image_gray, None)
camera_image_keypoints, des = SIFT.compute(camera_image_gray, camera_image_keypoints)
#print("kp:",time.time() - kp_start)
def_flan = time.time()
# FLANN parameters
FLANN_INDEX_KDTREE = 0
index_params = dict(algorithm=FLANN_INDEX_KDTREE, trees=8)
search_params = dict(checks=100) # or pass empty dictionary
flann_start = time.time()
flann = cv2.FlannBasedMatcher(index_params, search_params)
matches = flann.knnMatch(des, des2, k=2)
#print("end_def:", time.time() - def_flan)
matches = flann.knnMatch(des, BASELINE_DES, k=2)
#print("flann:",time.time() - flann_start)
# Need to draw only good matches, so create a mask
matchesMask = [[0, 0] for _ in range(len(matches))]
@ -168,6 +184,8 @@ def find_keypoints(camera_image: np.ndarray, baseline: np.ndarray, debug=False)
matchesMask[i] = [1, 0]
good_matches.append([m, n])
#good_matches = list(filter(lambda x: x[0].distance < 0.55 * x[1].distance, matches))
if debug:
# Save keypoints
keypoints_image = camera_image.copy()
@ -178,7 +196,7 @@ def find_keypoints(camera_image: np.ndarray, baseline: np.ndarray, debug=False)
camera_image,
camera_image_keypoints,
baseline,
baseline_keypoints,
BASELINE_KEYPOINTS,
matches,
None,
matchColor=(0, 255, 0),
@ -192,15 +210,16 @@ def find_keypoints(camera_image: np.ndarray, baseline: np.ndarray, debug=False)
src_points = np.zeros((len(good_matches), 2), dtype=np.float32)
dst_points = np.zeros((len(good_matches), 2), dtype=np.float32)
for i, (m, n) in enumerate(good_matches):
src_points[i, :] = camera_image_keypoints[m.queryIdx].pt
dst_points[i, :] = baseline_keypoints[m.trainIdx].pt
dst_points[i, :] = BASELINE_KEYPOINTS[m.trainIdx].pt
return src_points, dst_points
def find_homography(camera_image: np.ndarray,
baseline: np.ndarray = cv2.imread(str(here.joinpath("new_baseline_board.png"))),
baseline: np.ndarray = BASELINE,
debug=False) -> np.ndarray:
src_points, dst_points = find_keypoints(camera_image, baseline, debug=debug)
h, mask = cv2.findHomography(src_points, dst_points, cv2.RANSAC)
@ -209,11 +228,10 @@ def find_homography(camera_image: np.ndarray,
def warp_board(camera_image: np.ndarray, homography: np.ndarray = None, debug=False) -> np.ndarray:
baseline = cv2.imread(str(here.joinpath("new_baseline_board.png")))
if homography is None:
homography = find_homography(camera_image, baseline, debug=debug)
homography = find_homography(camera_image, BASELINE, debug=debug)
height, width, channels = baseline.shape
height, width, channels = BASELINE.shape
return cv2.warpPerspective(camera_image, homography, (width, height))
@ -240,12 +258,15 @@ def get_squares(warped_board: np.ndarray) -> Squares:
for position in POSITION}
def save_empty_fields(warped_board: np.ndarray, skip_rank: RANK = None) -> None:
def save_empty_fields(warped_board: np.ndarray, skip_rank: RANK = None, fourk=False) -> None:
for position in POSITION:
if position.rank == skip_rank:
continue
square = get_square(warped_board, position)
imwrite(f"training_images/empty/{position.color}_square/training_{position}_{datetime.utcnow().timestamp()}.png", square)
if fourk:
imwrite(f"training_images/4k/empty/{position.color}_square/training_{position}_{datetime.utcnow().timestamp()}.png", square)
else:
imwrite(f"training_images/empty/{position.color}_square/training_{position}_{datetime.utcnow().timestamp()}.png", square)
def load_data_nn(spec_piece, color):
@ -292,4 +313,5 @@ def train_nn():
if __name__ == '__main__':
#train_nn()
train_empty_or_piece_hist()
do_pre_processing()
train_pieces_svm()

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@ -1,27 +1,55 @@
from pathlib import Path
import cv2
import numpy as np
from tensorflow.python.keras import models
from util import PIECE, Squares, Board
from util import PIECE, Squares, Board, OUR_PIECES, LESS_PIECE
here: Path = Path(__file__).parent
#new_model = models.load_model(str(here.joinpath('pls_model_new_fuck_lel.h5')))
new_model = models.load_model(str(here.joinpath('5_piece_new_fuck_lel.h5')))
empty_class = models.load_model(str(here.joinpath('2_piece_new_fuck_lel.h5')))
#all_piece_model = models.load_model(str(here.joinpath('6_piece_new_fuck_lel.h5')))
new_model = models.load_model('chess_model_3_pieces.h5')
#new_model.summary()
#board = cv2.imread("whole_boards/boards_for_empty/board_1554286488.605142_rank_3.png")
#board = cv2.imread("whole_boards/boards_for_empty/board_1554285167.655788_rank_5.png")
board = cv2.imread("whole_boards/boards_for_empty/board_1554288891.129901_rank_8.png")
#board = cv2.imread("whole_boards/boards_for_empty/board_1554288891.129901_rank_8.png")
def predict_empty_nn(square):
square = square[6:-6, 6:-6]
width, height, channels = square.shape
square = square / 255.0
test = empty_class.predict(np.array(square).reshape((-1, width, height, 3)))
print([round(x, 2) for x in test[0]])
return int(np.argmax(test))
def predict_piece(square):
square = square[6:-6, 6:-6]
width, height, channels = square.shape
square = square / 255.0
test = new_model.predict(np.array(square).reshape((-1, width, height, 3)))
print([round(x, 2) for x in test[0]])
return LESS_PIECE(int(np.argmax(test)))
def predict_board(occupied_squares: Squares) -> Board:
board = Board()
for pos, square in occupied_squares.items():
square = cv2.cvtColor(square, cv2.COLOR_BGR2GRAY)
width, height = square.shape
#square = cv2.cvtColor(square, cv2.COLOR_BGR2GRAY)
square = square[6:-6, 6:-6]
width, height, channels = square.shape
square = square / 255.0
test = new_model.predict(np.array(square).reshape((-1, width, height, 1)))
#test = new_model.predict(np.array(square).reshape((-1, width, height, 3)))
test = new_model.predict(np.array(square).reshape((-1, width, height, 3)))
#cv2.putText(square, f"{pos} {PIECE(int(np.argmax(test)))}", (0, 50), cv2.FONT_HERSHEY_SIMPLEX, fontScale=1, color=(255,) * 3, thickness=3)
#cv2.imwrite("lel", square)
board[pos] = PIECE(int(np.argmax(test)))
#print(f"{pos}, {test}")
board[pos] = LESS_PIECE(int(np.argmax(test)))
return board

22
util.py
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@ -9,6 +9,8 @@ import cv2
import numpy as np
from sklearn.externals import joblib
here: Path = Path(__file__).parent
class COLOR(Enum):
WHITE = "white"
@ -30,13 +32,25 @@ class PIECE(Enum):
def __str__(self) -> str:
return self.name.lower()
class LESS_PIECE(Enum):
ROOK = 0
KNIGHT = 1
BISHOP = 2
KING = 3
QUEEN = 4
def __str__(self) -> str:
return self.name.lower()
PieceAndColor = Tuple[PIECE, COLOR]
OUR_PIECES = (
PIECE.KNIGHT,
PIECE.ROOK,
PIECE.BISHOP,
LESS_PIECE.ROOK,
LESS_PIECE.KNIGHT,
LESS_PIECE.BISHOP,
LESS_PIECE.KING,
LESS_PIECE.QUEEN
)
@ -100,4 +114,4 @@ def imwrite(*args, **kwargs):
@lru_cache()
def load_classifier(filename):
# print(f"Loading classifier {filename}")
return joblib.load(filename)
return joblib.load(str(here.joinpath(filename)))

16
web.py
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@ -7,12 +7,14 @@ from flask import Flask, jsonify, request
from main import find_occupied_squares
from runner import find_homography, warp_board
from tensor_classifier import predict_board
from time import time
app = Flask(__name__)
@app.route("/", methods=["POST"])
def process():
print("Received request")
data = request.get_json(force=True)
decoded = base64.b64decode(data["img"])
@ -21,16 +23,24 @@ def process():
camera_img = cv2.cvtColor(camera_img, cv2.COLOR_BGR2RGB)
# def do_everything:
homography = find_homography(camera_img)
start = time()
print("Finding keypoints")
homography = find_homography(camera_img, debug=True)
print("Computing homography")
warped_board = warp_board(camera_img, homography)
print("Warping board")
cv2.imwrite("warped.png", warped_board)
print("Removing empty squares")
occupied_squares = find_occupied_squares(warped_board)
print("Predicting board state")
board = predict_board(occupied_squares)
print(f"The request took {round(time() - start, 3)} seconds")
print("Returning board state")
# Finally, output for unity to read
return jsonify({
"homography": homography.tolist(),
"board": board.to_array,
})
})
def main():