class Cam:
def __init__(self):
self.camera = Camera()
def startRecording(self):
self.stream = Stream(self.camera, file_name=self.file_name)
def stopRecording(self):
self.stream.end()
self.camera.end()
def convertToGif(self):
clip = VideoFileClip(f"{self.file_name}_0.avi")
clip.write_gif(f"{self.file_name}.gif")
return f"{self.file_name}.gif"
def __init__(self):
self.start = datetime.now()
self.cap = Camera([0], fps=30, resolution=Camera.RES_LARGE, colour=True, auto_gain=True, auto_exposure=True, auto_whitebalance=True)
# self.cap = cv2.VideoCapture(0)
self.laby = []
self.frame = 0
self.l_bg = None
self.width = 1280
self.height = 720
self.l_average = 0
self.l_frame = None
self.grid = None
self.mask = None
self.f_num = 0
self.fourcc = cv2.VideoWriter_fourcc(*'MJPG')
self.out = cv2.VideoWriter('video_out/cc.avi', self.fourcc, 20.0, (self.width,self.height))
def __init__(self):
self.start = datetime.now()
self.cap = Camera([0],
fps=30,
resolution=Camera.RES_LARGE,
colour=True,
auto_gain=True,
auto_exposure=True,
auto_whitebalance=True)
self.laby = []
self.l_bg = None
self.width = 1280
self.height = 720
self.l_average = 0
self.l_frame = None
self.grid = None
self.mask = None
# expt name
expt_name = input('\nEnter unique experiment name:\n').replace('/', '-')
exp_data_dir = os.path.join(data_dir, expt_name)
if os.path.exists(exp_data_dir):
cont = input(
'\nExperiment folder with this name already exists.\nAre you sure you want to continue? (y/n)\n'
)
if cont != 'y':
quit()
os.makedirs(exp_data_dir, exist_ok=True)
# setup camera
assert cam_count(
) > 0, '\n\nCamera not detected. Is it plugged into the computer? If so, trying unplugging and replugging, then run again.\n\n\n'
cam = Camera(resolution=resolution, fps=fps)
# main loop
ans = ''
dur = 10 # random default
used_ids = []
while True:
ans = input(
"\nMain menu:\n\t'r' to record\n\t'd' to display\n\t'reset' to reset camera\n\t'q' to quit\n"
)
if ans == 'q':
break
elif ans == 'd':
# inspect camera
refresh2d(width, height)
glColor3f(0.2, 0.2, 0.2)
find_mz()
draw_mz(mz)
glutSwapBuffers()
global mz
global start
global width
global height
global processing
global cap
processing = False
window = 0
start = datetime.now()
cap = Camera([0], fps=30, resolution=Camera.RES_LARGE, colour=False)
find_mz()
width = 1400
height = 880
glutInit()
glutInitDisplayMode(GLUT_RGBA | GLUT_DOUBLE | GLUT_ALPHA | GLUT_DEPTH)
glutInitWindowSize(width, height)
glutInitWindowPosition(0, 0)
glutSetCursor(GLUT_CURSOR_NONE)
window = glutCreateWindow("test")
glutDisplayFunc(draw)
glutIdleFunc(draw)
glutMainLoop()
from pseyepy import Camera, Stream, Display
import cv2
import numpy as np
from cv2 import aruco
from cv2 import Rodrigues
from math import sqrt
import matplotlib.pyplot as plt
c = Camera([0, 1], resolution=[Camera.RES_LARGE, Camera.RES_LARGE])
#c = Camera(resolution = [Camera.RES_LARGE])
#c.exposure = 23
#frame, timestamp = c.read(0)
#frame2, t2 = c.read(1)
#matType = cv2.CV_8UC3;
#test = cv2.CreateMat(480, 640, matType, frame)
#test = np.array(frame,copy = True)
#gray = cv2.cvtColor(test, cv2.COLOR_BGR2GRAY)
#test2 = np.array(frame2,copy = True)
#gray2 = cv2.cvtColor(test2, cv2.COLOR_BGR2GRAY)
#cv2.imshow("test",gray)
#cv2.imshow("test2",gray2)
#print(test)
#d = Display(c)
#s = Stream(c, file_name='example_movie.avi', display=True,codec='png') # begin saving data to files
#s.end()
from pseyepy import Camera, Stream, Display
import cv2
import numpy as np
c = Camera([0, 1], resolution=[Camera.RES_LARGE, Camera.RES_LARGE])
#c = Camera(resolution = [Camera.RES_LARGE])
#c.exposure = 23
frame, timestamp = c.read(0)
frame2, t2 = c.read(1)
#matType = cv2.CV_8UC3;
#test = cv2.CreateMat(480, 640, matType, frame)
test = np.array(frame, copy=True)
gray = cv2.cvtColor(test, cv2.COLOR_BGR2GRAY)
test2 = np.array(frame2, copy=True)
gray2 = cv2.cvtColor(test2, cv2.COLOR_BGR2GRAY)
cv2.imshow("test", gray)
cv2.imshow("test2", gray2)
print(test)
d = Display(c)
#s = Stream(c, file_name='example_movie.avi', display=True,codec='png') # begin saving data to files
#s.end()
#d = Display(c)
#print(frame)
#s = Stream(c, file_name='example_movie.avi', display = True, codec='png') # begin saving data to files
class StillLabyrinthMaker():
"""StillLabyrinthMaker"""
def __init__(self):
self.start = datetime.now()
self.cap = Camera([0],
fps=30,
resolution=Camera.RES_LARGE,
colour=True,
auto_gain=True,
auto_exposure=True,
auto_whitebalance=True)
self.laby = []
self.l_bg = None
self.width = 1280
self.height = 720
self.l_average = 0
self.mask = None
self.grid = None
self.col_frame = None
self.c_size = 4
def process_cam(self, sz, flip):
frame, timestamp = self.cap.read()
self.col_frame = frame.copy()
frame = cv2.cvtColor(frame, cv2.COLOR_BGR2GRAY)
frame = frame[0:360, 0:640]
# frame = cv2.flip(frame, flip)
small = cv2.resize(frame, (0, 0), fx=0.25, fy=0.25)
ret, thr = cv2.threshold(small, 1, 255,
cv2.THRESH_BINARY + cv2.THRESH_OTSU)
kernel = np.ones((1, 1), np.uint8)
opening = cv2.morphologyEx(thr, cv2.MORPH_OPEN, kernel, iterations=1)
bg = cv2.dilate(opening, kernel, iterations=3)
return bg
def add_cam_col(self):
pix = self.laby.load()
for r in range(self.mask.rows):
for c in range(self.mask.columns):
if not self.mask.cell_at(r, c):
red, gre, blu = self.col_frame[r * 4, c * 4]
col = (red, gre, blu)
pix[c * 4, r * 4] = col
red, gre, blu = self.col_frame[r * 4, c * 4 + 1]
col = (red, gre, blu)
pix[c * 4, r * 4 + 1] = col
red, gre, blu = self.col_frame[r * 4, c * 4 + 2]
col = (red, gre, blu)
pix[c * 4, r * 4 + 2] = col
red, gre, blu = self.col_frame[r * 4, c * 4 + 3]
col = (red, gre, blu)
pix[c * 4, r * 4 + 3] = col
red, gre, blu = self.col_frame[r * 4 + 1, c * 4]
col = (red, gre, blu)
pix[c * 4 + 1, r * 4] = col
red, gre, blu = self.col_frame[r * 4 + 2, c * 4]
col = (red, gre, blu)
pix[c * 4 + 2, r * 4] = col
red, gre, blu = self.col_frame[r * 4 + 3, c * 4]
col = (red, gre, blu)
pix[c * 4 + 3, r * 4] = col
red, gre, blu = self.col_frame[r * 4 + 1, c * 4 + 1]
col = (red, gre, blu)
pix[c * 4 + 1, r * 4 + 1] = col
red, gre, blu = self.col_frame[r * 4 + 2, c * 4 + 1]
col = (red, gre, blu)
pix[c * 4 + 2, r * 4 + 1] = col
red, gre, blu = self.col_frame[r * 4 + 3, c * 4 + 1]
col = (red, gre, blu)
pix[c * 4 + 3, r * 4 + 1] = col
red, gre, blu = self.col_frame[r * 4 + 1, c * 4 + 2]
col = (red, gre, blu)
pix[c * 4 + 1, r * 4 + 2] = col
red, gre, blu = self.col_frame[r * 4 + 2, c * 4 + 2]
col = (red, gre, blu)
pix[c * 4 + 2, r * 4 + 2] = col
red, gre, blu = self.col_frame[r * 4 + 3, c * 4 + 2]
col = (red, gre, blu)
pix[c * 4 + 3, r * 4 + 2] = col
red, gre, blu = self.col_frame[r * 4 + 1, c * 4 + 3]
col = (red, gre, blu)
pix[c * 4 + 1, r * 4 + 3] = col
red, gre, blu = self.col_frame[r * 4 + 2, c * 4 + 3]
col = (red, gre, blu)
pix[c * 4 + 2, r * 4 + 3] = col
red, gre, blu = self.col_frame[r * 4 + 3, c * 4 + 3]
col = (red, gre, blu)
pix[c * 4 + 3, r * 4 + 3] = col
def draw(self):
self.add_cam_col()
self.laby.save("{}/{}.png".format("laby", "testtesttest"),
"PNG",
optimize=True)
def main(self):
bg = self.process_cam(0.125, -1)
pil_im = Image.fromarray(bg)
self.mask = Mask.from_img_data(pil_im)
self.grid = MaskedGrid(self.mask)
RecursiveBacktracker.on(self.grid)
self.laby = self.grid.to_png(cell_size=self.c_size, save=False)
self.draw()
print("Completed In: %s" % (datetime.now() - self.start))
def main(cam, show, pseye):
global processing
if pseye == 1:
cap = Camera([0], fps=60, resolution=Camera.RES_LARGE, colour=False)
frame, timestamp = cap.read()
# width, height = frame.shape
else:
cap = cv2.VideoCapture(cam)
sz = 80
run = True
vals = {}
tiles = []
mz = cv2.imread("live_full_mz/live_full_mz.png")
c = 1
last_diff = 0
# cv2.namedWindow("mz", cv2.WND_PROP_FULLSCREEN)
# cv2.setWindowProperty("mz", cv2.WND_PROP_FULLSCREEN, cv2.WINDOW_FULLSCREEN)
if show == 0:
window = False
else:
window = True
while (run):
try:
if pseye == 1:
frame, timestamp = cap.read()
else:
ret, frame = cap.read()
small = cv2.resize(frame, (0, 0), fx=0.18, fy=0.18)
width, height = small.shape
ret, thr = cv2.threshold(small, 1, 255,
cv2.THRESH_BINARY + cv2.THRESH_OTSU)
kernel = np.ones((1, 1), np.uint8)
opening = cv2.morphologyEx(thr,
cv2.MORPH_OPEN,
kernel,
iterations=2)
bg = cv2.dilate(opening, kernel, iterations=3)
if not processing:
processing = True
tiles = processTiles(width, height, sz, bg)
for tile in tiles:
tile = np.array(tile)
if window:
# cv2.imshow('cam', bg)
for i, tile in enumerate(tiles):
cv2.imshow(('%s' % i), tile)
k = cv2.waitKey(1)
if k == ord('q'):
run = False
c += 1
except Exception as e:
print(e)
pass
# program closing, stop camera stream and close windows
if pseye == 1:
cap.end()
else:
cap.release()
cv2.destroyAllWindows()
from pseyepy import Camera, Display
import matplotlib.pyplot as plt
import numpy as np
import cv2
from PIL import Image
import sys, tty, termios
# initialize all connected cameras
c1 = Camera([0, 1], resolution=[Camera.RES_LARGE, Camera.RES_LARGE])
num = 0
while num < 20:
# check for char
fd = sys.stdin.fileno()
old_settings = termios.tcgetattr(fd)
try:
tty.setraw(sys.stdin.fileno())
ch = sys.stdin.read(1)
finally:
termios.tcsetattr(fd, termios.TCSADRAIN, old_settings)
# read from the camera/s
frame, timestamp = c1.read()
#print(frame)
nparr = np.asarray(frame)
print(nparr.shape)
im1 = Image.fromarray(nparr[0])
im2 = Image.fromarray(nparr[1])
im1.save("left/left_{}.jpg".format(num))
import cv2
import numpy as np
from pseyepy import Camera, Display
c = Camera([0], fps=60, resolution=Camera.RES_LARGE, colour=True)
# print("frame: {}, time: {}".format(frame, timestamp))
# d = Display(c)
run = True
frame, timestamp = c.read()
cv2.namedWindow("mz", cv2.WND_PROP_FULLSCREEN)
cv2.setWindowProperty("mz", cv2.WND_PROP_FULLSCREEN, cv2.WINDOW_FULLSCREEN)
cv2.setWindowProperty("mz", cv2.WND_PROP_ASPECT_RATIO, cv2.WINDOW_FREERATIO)
while run:
# im = np.array(frame)
frame, timestamp = c.read()
# width, height = frame.shape
frame = frame[100:320, 100:540]
# b,g,r = cv2.split(im)
cv2.imshow("mz", frame)
# cv2.imshow("R", r)
# cv2.imshow("G", g)
# cv2.imshow("B", b)
def __init__(self):
self.camera = Camera()
## import os from pseyepy import Camera, Stream, Display path = '/Users/ben/Desktop' file_name = '20180107_crayfish0' file_name += os.path.join(path, file_name + '.avi') ## c = Camera([0, 1], resolution=Camera.RES_LARGE, fps=15) d = Display(c) ## s = Stream(c, file_name=file_name, codec='png') ## s.end() c.end() ##
class LabyrinthMaker():
"""LabyrinthMaker"""
def __init__(self):
self.start = datetime.now()
self.cap = Camera([0],
fps=30,
resolution=Camera.RES_LARGE,
colour=True,
auto_gain=True,
auto_exposure=True,
auto_whitebalance=True)
self.laby = []
self.l_bg = None
self.width = 1280
self.height = 720
self.l_average = 0
self.l_frame = None
self.grid = None
self.mask = None
def process_cam(self, sz, flip, bw=True):
# get the frame
frame, timestamp = self.cap.read()
# crop to correct ratio
# frame = frame[100:460, 0:640]
frame = frame[0:360, 0:640]
# -1 flip hori+vert / 1 flip vert / 0 flip hori
frame = cv2.flip(frame, flip)
# resize smaller for faster processing
# small = cv2.resize(frame, (0, 0), fx=0.15, fy=0.15)
small = cv2.resize(frame, (0, 0), fx=sz, fy=sz)
small = cv2.cvtColor(small, cv2.COLOR_RGB2BGR)
self.l_frame = small
if not bw:
return small
gray = cv2.cvtColor(small, cv2.COLOR_BGR2GRAY)
# threshold the image
# otsu threshold is adaptive
# so will adjust to the range present in the image
ret, thr = cv2.threshold(gray, 1, 255,
cv2.THRESH_BINARY + cv2.THRESH_OTSU)
# opening and dilating to remove noise
# kernel size is size of operation
kernel = np.ones((1, 1), np.uint8)
opening = cv2.morphologyEx(thr, cv2.MORPH_OPEN, kernel, iterations=1)
bg = cv2.dilate(opening, kernel, iterations=3)
return bg
def draw_cam(self):
# draws the camera to a second window
bg = self.process_cam(0.5, 1, bw=False)
cv2.namedWindow("camera")
cv2.moveWindow("camera", 0, 0)
cv2.imshow("camera", bg)
def draw_mask(self):
if self.mask is not None:
# Blur the camera image
self.l_frame = cv2.blur(self.l_frame, (10, 10))
glPointSize(13.333)
glBegin(GL_POINTS)
for r in range(self.mask.rows):
for c in range(self.mask.columns):
if not self.mask.cell_at(r, c):
bb, gg, rr = self.l_frame[r, c]
glColor3f(rr / 255, gg / 255, bb / 255)
glVertex2f((c + 0.5) * 13.333, (r + 0.5) * 13.333)
# bb, gg, rr = self.l_frame[r+1, c+1]
# glColor3f(rr/255, gg/255, bb/255)
# glVertex2f(c*13.333+12, r*13.333+12)
glEnd()
def draw_laby(self):
# Draws the labyrinth to gl
# set the line width for drawing
glLineWidth(1)
# set the color of the line
glColor3f(0.1, 0.1, 0.1)
# begin shape with pairs of lines
glBegin(GL_LINES)
# the list of points is backwards so reverse it
# self.mz.reverse()
# loop over coordinates adding all the vertices
for loc in self.laby:
x1, y1, x2, y2 = loc
# @ 0.1 = *5
# @ 0.25 = *2
# @ 0.15 = *3.333
glVertex2f(x1 * 3.333, y1 * 3.333)
glVertex2f(x2 * 3.333, y2 * 3.333)
# glVertex2f(x1*4, y1*4)
# glVertex2f(x2*4, y2*4)
# complete the shape and draw everything
glEnd()
def refresh_scene(self):
# refresh the gl scene
glViewport(0, 0, self.width, self.height)
glMatrixMode(GL_PROJECTION)
glLoadIdentity()
glOrtho(0.0, self.width, 0.0, self.height, 0.0, 1.0)
glMatrixMode(GL_MODELVIEW)
glLoadIdentity()
def update(self):
# update the labyrinth from camera image
bg = self.process_cam(0.15, -1)
# if not first frame
if self.l_bg is not None:
# calculate the average of the current bg
average = np.average(bg)
# compare to the last stored average
diff = average - self.l_average
# if there is a big enough difference +/-
if diff > 1.5 or diff < -1.5:
# translate numpy array to PIL image
pil_im = Image.fromarray(bg)
# make a mask from the image
self.mask = Mask.from_img_data(pil_im)
# build a grid from the unmasked areas
self.grid = MaskedGrid(self.mask)
# build walls in the grid
RecursiveBacktracker.on(self.grid)
# get walls as list of coordinate pairs for drawing
self.laby = self.grid.to_point_pairs(cell_size=4)
# save the new average
self.l_average = average
# save the background
self.l_bg = bg
def draw(self):
glClearColor(1, 1, 1, 1)
glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT)
glLoadIdentity()
self.refresh_scene()
self.update()
self.draw_mask()
self.draw_laby()
self.draw_cam()
glutSwapBuffers()
def main(self):
glutInit()
glutInitDisplayMode(GLUT_RGBA | GLUT_DOUBLE | GLUT_ALPHA | GLUT_DEPTH)
glutInitWindowSize(self.width, self.height)
glutInitWindowPosition(1280, 0)
glutSetCursor(GLUT_CURSOR_NONE)
window = glutCreateWindow("LabyrinthMaker")
glutDisplayFunc(self.draw)
glutIdleFunc(self.draw)
glutMainLoop()
class LabyrinthMaker():
"""LabyrinthMaker"""
def __init__(self):
self.start = datetime.now()
self.cap = Camera([0], fps=30, resolution=Camera.RES_LARGE, colour=True, auto_gain=True, auto_exposure=True, auto_whitebalance=True)
# self.cap = cv2.VideoCapture(0)
self.laby = []
self.frame = 0
self.l_bg = None
self.width = 1280
self.height = 720
self.l_average = 0
self.l_frame = None
self.grid = None
self.mask = None
self.f_num = 0
self.fourcc = cv2.VideoWriter_fourcc(*'MJPG')
self.out = cv2.VideoWriter('video_out/cc.avi', self.fourcc, 20.0, (self.width,self.height))
def process_cam(self, sz, flip, bw=True):
# get the frame
frame, timestamp = self.cap.read()
# ret, frame = self.cap.read()
# crop to correct ratio
# frame = frame[100:460, 0:640]
frame = frame[0:360, 0:640]
# -1 flip hori+vert / 1 flip vert / 0 flip hori
frame = cv2.flip(frame, flip)
# resize smaller for faster processing
# small = cv2.resize(frame, (0, 0), fx=0.15, fy=0.15)
small = cv2.resize(frame, (0, 0), fx=sz, fy=sz)
small = cv2.cvtColor(small, cv2.COLOR_RGB2BGR)
self.l_frame = small
if not bw:
return small
gray = cv2.cvtColor(small, cv2.COLOR_BGR2GRAY)
# threshold the image
# otsu threshold is adaptive
# so will adjust to the range present in the image
ret, thr = cv2.threshold(gray, 1, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU)
# opening and dilating to remove noise
# kernel size is size of operation
kernel = np.ones((1, 1), np.uint8)
opening = cv2.morphologyEx(thr, cv2.MORPH_OPEN, kernel, iterations=1)
bg = cv2.dilate(opening, kernel, iterations=3)
return bg
def draw_cam(self):
# draws the camera to a second window
bg = self.process_cam(0.5, 1, bw=False)
cv2.namedWindow("camera")
cv2.moveWindow("camera", 0, 0)
cv2.imshow("camera", bg)
def draw_mask(self):
if self.mask is not None:
# saturate
l_frame_hsv = cv2.cvtColor(self.l_frame, cv2.COLOR_BGR2HSV).astype("float32")
h, s, v = cv2.split(l_frame_hsv)
s = s * 5
s = np.clip(s, 0, 255)
l_frame_hsv = cv2.merge([h, s, v])
self.l_frame = cv2.cvtColor(l_frame_hsv.astype("uint8"), cv2.COLOR_HSV2BGR)
# Blur the camera image
self.l_frame = cv2.blur(self.l_frame, (13, 13))
# glPointSize(13.333*2)
glPointSize(13.333)
glBegin(GL_POINTS)
for r in range(self.mask.rows):
for c in range(self.mask.columns):
if not self.mask.cell_at(r, c):
bb, gg, rr = self.l_frame[r, c]
glColor3f(rr/255, gg/255, bb/255)
glVertex2f((c+0.5)*13.333, (r+0.5)*13.333)
# glVertex2f((c+0.5)*(13.333*2), (r+0.5)*(13.333*2))
# bb, gg, rr = self.l_frame[r+1, c+1]
# glColor3f(rr/255, gg/255, bb/255)
# glVertex2f(c*13.333+12, r*13.333+12)
glEnd()
def draw_laby(self):
# Draws the labyrinth to gl
# set the line width for drawing
glLineWidth(1)
# set the color of the line
glColor3f(0.1, 0.1, 0.2)
# begin shape with pairs of lines
glBegin(GL_LINES)
# the list of points is backwards so reverse it
# self.mz.reverse()
# loop over coordinates adding all the vertices
for loc in self.laby:
x1, y1, x2, y2 = loc
# @ 0.1 = *5
# @ 0.25 = *2
# @ 0.15 = *3.333
glVertex2f(x1*3.333, y1*3.333)
glVertex2f(x2*3.333, y2*3.333)
# glVertex2f(x1*6.666, y1*6.666)
# glVertex2f(x2*6.666, y2*6.666)
# glVertex2f(x1*4, y1*4)
# glVertex2f(x2*4, y2*4)
# complete the shape and draw everything
glEnd()
def refresh_scene(self):
# refresh the gl scene
# NOTE: DOUBLE HEIGHT AND WIDTH FOR HIGHDPI, REDUCE FOR STANDARD
# glViewport(0, 0, self.width*2, self.height*2)
glViewport(0, 0, self.width, self.height)
glMatrixMode(GL_PROJECTION)
glLoadIdentity()
glOrtho(0.0, self.width, 0.0, self.height, 0.0, 1.0)
# glOrtho(0.0, self.width*2, 0.0, self.height*2, 0.0, 1.0)
glMatrixMode (GL_MODELVIEW)
glLoadIdentity()
def update(self):
# update the labyrinth from camera image
bg = self.process_cam(0.15, 1)
# if not first frame
if self.l_bg is not None:
# calculate the average of the current bg
average = np.average(bg)
# compare to the last stored average
diff = average - self.l_average
# if there is a big enough difference +/-
if diff > 1.65 or diff < -1.65:
# translate numpy array to PIL image
pil_im = Image.fromarray(bg)
# PERHAPS CULD PUT SOME KIND OF BACKGROUND
# SUBTRACTION HERE
# make a mask from the image
self.mask = Mask.from_img_data(pil_im)
# build a grid from the unmasked areas
self.grid = MaskedGrid(self.mask)
# build walls in the grid
RecursiveBacktracker.on(self.grid)
# get walls as list of coordinate pairs for drawing
self.laby = self.grid.to_point_pairs(cell_size=4)
# save the new average
self.l_average = average
# save the background
self.l_bg = bg
def save_frame(self):
glReadBuffer(GL_BACK)
fbuffer = glReadPixels(0, 0, self.width, self.height, GL_RGB, GL_UNSIGNED_BYTE)
imagebuffer = np.fromstring(fbuffer, np.uint8)
fimage = imagebuffer.reshape(self.height, self.width, 3)
image = Image.fromarray(fimage)
image.save("video_out/frames/live/%s.png" % self.f_num, 'png')
outim = cv2.cvtColor(fimage, cv2.COLOR_RGB2BGR)
self.out.write(outim)
def draw(self):
glClearColor(1, 1, 1, 1)
glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT)
glLoadIdentity()
self.refresh_scene()
self.update()
self.draw_mask()
self.draw_laby()
# self.save_frame()
self.draw_cam()
self.f_num = self.f_num + 1
def main(self):
if not glfw.init():
return
# http://www.glfw.org/docs/latest/monitor_guide.html#monitor_monitors
# monitor = glfw.get_primary_monitor()
# mode = monitor.video_mode
window = glfw.create_window(self.width, self.height, "LabyrinthMaker_GLFW", None, None)
if not window:
glfw.terminate()
return
glfw.make_context_current(window)
while not glfw.window_should_close(window):
# render
self.draw()
glfw.swap_buffers(window)
glfw.poll_events()
glfw.terminate()
import cv2 from pseyepy import Camera, Stream, Display import string import glob criteria = (cv2.TERM_CRITERIA_EPS + cv2.TERM_CRITERIA_MAX_ITER, 30, 0.001) objp = np.zeros((6*7,3), np.float32) objp[:,:2] = np.mgrid[0:7,0:6].T.reshape(-1,2) # Arrays to store object points and image points from all the images. objpoints1 = [] # 3d point in real world space imgpoints1 = [] # 2d points in image plane. objpoints2 = [] # 3d point in real world space imgpoints2 = [] # 2d points in image plane. c = Camera([0,1],resolution = [Camera.RES_LARGE,Camera.RES_LARGE]) # frame, timestamp = c.read(0) # #frame2, t2 = c.read(1) # i = 0 ###################################################################### #COMMENT ME OUT WHEN YOU ARE DONE TAKING PHOTOS # while (i < 10): # frame, timestamp = c.read(0) # frame2, t2 = c.read(1) # img = np.array(frame,copy = True) # img2 = np.array(frame2,copy = True)
def main(cam, show, pseye):
if pseye == 1:
cap = Camera([0], fps=60, resolution=Camera.RES_LARGE, colour=False)
# frame, timestamp = cap.read()
# width, height = frame.shape
else:
cap = cv2.VideoCapture(cam)
# width = floor(cap.get(3)) // 2
# height = floor(cap.get(4)) // 2
# sz = 100
run = True
# vals = {}
mz = cv2.imread("live_full_mz/live_full_mz.png")
# mz_sm = cv2.resize(mz, (0,0), fx=0.3, fy=0.3)
global processing
c = 1
# last_diff = 0
cv2.namedWindow("mz", cv2.WND_PROP_FULLSCREEN)
cv2.setWindowProperty("mz", cv2.WND_PROP_FULLSCREEN, cv2.WINDOW_FULLSCREEN)
cv2.setWindowProperty("mz", cv2.WND_PROP_ASPECT_RATIO,
cv2.WINDOW_FREERATIO)
if show == 0:
window = False
else:
window = True
while (run):
try:
if pseye == 1:
frame, timestamp = cap.read()
# width, height = frame.shape
else:
ret, frame = cap.read()
frame = frame[100:320, 100:540]
small = cv2.resize(frame, (0, 0), fx=0.25, fy=0.25)
# gray = cv2.cvtColor(small,cv2.COLOR_BGR2GRAY)
ret, thr = cv2.threshold(small, 1, 255,
cv2.THRESH_BINARY + cv2.THRESH_OTSU)
kernel = np.ones((1, 1), np.uint8)
opening = cv2.morphologyEx(thr,
cv2.MORPH_OPEN,
kernel,
iterations=1)
bg = cv2.dilate(opening, kernel, iterations=2)
# if c < 50:
if not processing:
# diff = detect_diffs_two(vals, c, width, height, sz, bg)
# print(diff - last_diff)
# d_sum = diff - last_diff
# if d_sum > 0.005 or d_sum < -0.005:
processing = True
mz = processFrame(bg)
try:
mz = np.array(mz)
# mz = cv2.resize(mz, (0, 0), fx=4, fy=4)
except Exception as e:
print(e)
pass
# mz = cv2.imread("live_full_mz/live_full_mz.png")
# last_diff = diff
# mz_sm = cv2.resize(mz, (0,0), fx=0.3, fy=0.3)
# mz - cv2.imread("live_full/", 1)
# detect_diffs(vals, c, width, height, sz, bg)
# print("----")
if window:
try:
# cv2.imshow('cam', bg)
cv2.imshow('mz', mz)
except Exception as e:
print(e)
pass
k = cv2.waitKey(1)
# if k == ord('+'):
# mz = cv2.resize(mz, (0,0), fx=1.1, fy=1.1)
# if k == ord('-'):
# mz = cv2.resize(mz, (0,0), fx=0.9, fy=0.9)
if k == ord('q'):
run = False
c += 1
except Exception as e:
print(e)
pass
if pseye == 1:
cap.end()
else:
cap.release()
cv2.destroyAllWindows()
