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qr1.py
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qr1.py
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import serial
#from picamera.array import PiRGBArray
#from picamera import PiCamera
#import trans
import argparse
import time
import cv2
import math
import numpy as np
import zbar
import imutils
def distance(p,q):
return math.sqrt(math.pow(math.fabs(p[0]-q[0]),2)+math.pow(math.fabs(p[1]-q[1]),2))
def lineEquation(l,m,j):
a = -((m[1] - l[1])/(m[0] - l[0]))
b = 1.0
c = (((m[1] - l[1])/(m[0] - l[0]))*l[0]) - l[1]
try:
pdist = (a*j[0]+(b*j[1])+c)/math.sqrt((a*a)+(b*b))
except:
return 0
else:
return pdist
def lineSlope(l,m):
dx = m[0] - l[0]
dy = m[1] - l[1]
if dy != 0:
align = 1
dxy = dy/dx
return dxy,align
else:
align = 0
dxy = 0.0
return dxy,align
def getSquares(contours,cid):
x,y,w,h= cv2.boundingRect(contours[cid])
return x,y,w,h
def updateCorner(p,ref,baseline,corner):
temp_dist = distance(p,ref)
if temp_dist > baseline:
baseline = temp_dist
corner = p
return baseline,corner
def getVertices(contours,cid,slope,quad):
M0 = (0.0,0.0)
M1 = (0.0,0.0)
M2 = (0.0,0.0)
M3 = (0.0,0.0)
x,y,w,h = cv2.boundingRect(contours[cid])
A = (x,y)
B = (x+w,y)
C = (x+w,h+y)
D = (x,y+h)
W = ((A[0]+B[0])/2,A[1])
X = (B[0],(B[1]+C[1])/2)
Y = ((C[0]+D[0])/2,C[1])
Z = (D[0],(D[1]+A[1])/2)
dmax = []
for i in range(4):
dmax.append(0.0)
pd1 = 0.0
pd2 = 0.0
if(slope > 5 or slope < -5 ):
for i in range(len(contours[cid])):
pd1 = lineEquation(C,A,contours[cid][i])
pd2 = lineEquation(B,D,contours[cid][i])
if(pd1 >= 0.0 and pd2 > 0.0):
dmax[1],M1 = updateCorner(contours[cid][i],W,dmax[1],M1)
elif(pd1 > 0.0 and pd2 <= 0):
dmax[2],M2 = updateCorner(contours[cid][i],X,dmax[2],M2)
elif(pd1 <= 0.0 and pd2 < 0.0):
dmax[3],M3 = updateCorner(contours[cid][i],Y,dmax[3],M3)
elif(pd1 < 0 and pd2 >= 0.0):
dmax[0],M0 = updateCorner(contours[cid][i],Z,dmax[0],M0)
else:
continue
else:
halfx = (A[0]+B[0])/2
halfy = (A[1]+D[1])/2
for i in range(len(contours[cid])):
if(contours[cid][i][0][0]<halfx and contours[cid][i][0][1]<=halfy):
dmax[2],M0 = updateCorner(contours[cid][i][0],C,dmax[2],M0)
elif(contours[cid][i][0][0]>=halfx and contours[cid][i][0][1]<halfy):
dmax[3],M1 = updateCorner(contours[cid][i][0],D,dmax[3],M1)
elif(contours[cid][i][0][0]>halfx and contours[cid][i][0][1]>=halfy):
dmax[0],M2 = updateCorner(contours[cid][i][0],A,dmax[0],M2)
elif(contours[cid][i][0][0]<=halfx and contours[cid][i][0][1]>halfy):
dmax[1],M3 = updateCorner(contours[cid][i][0],B,dmax[1],M3)
quad.append(M0)
quad.append(M1)
quad.append(M2)
quad.append(M3)
return quad
def updateCornerOr(orientation,IN):
if orientation == 0:
M0 = IN[0]
M1 = IN[1]
M2 = IN[2]
M3 = IN[3]
elif orientation == 1:
M0 = IN[1]
M1 = IN[2]
M2 = IN[3]
M3 = IN[0]
elif orientation == 2:
M0 = IN[2]
M1 = IN[3]
M2 = IN[0]
M3 = IN[1]
elif orientation == 3:
M0 = IN[3]
M1 = IN[0]
M2 = IN[1]
M3 = IN[2]
OUT = []
OUT.append(M0)
OUT.append(M1)
OUT.append(M2)
OUT.append(M3)
return OUT
def cross(v1,v2):
cr = v1[0]*v2[1] - v1[1]*v2[0]
return cr
def getIntersection(a1,a2,b1,b2,intersection):
p = a1
q = b1
r = (a2[0]-a1[0],a2[1]-a1[1])
s = (b2[0]-b1[0],b2[1]-b1[1])
if cross(r,s) == 0:
return False, intersection
t = cross((q[0]-p[0],q[1]-p[1]),s)/float(cross(r,s))
intersection = (int(p[0]+(t*r[0])),int(p[1]+(t*r[1])))
return True,intersection
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
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")
dst = np.array([
[0, 0],
[319, 0],
[319, 319],
[0, 319]], dtype = "float32")
# compute the perspective transform matrix and then apply it
M = cv2.getPerspectiveTransform(rect, dst)
warped = cv2.warpPerspective(image, M, (320,320))#maxWidth, maxHeight))
# return the warped image
return warped
cv2.namedWindow('rect')
cap = cv2.VideoCapture(-1)
# Reduce the size of video to 320x240 so rpi can process faster
#cap.set(3,640)
#cap.set(4,480)
# camera = PiCamera()
# camera.resolution = (640,480)
# camera.framerate = 32
# rawCapture = PiRGBArray(camera,size=(640,480))
# time.sleep(0.1)
# for frame in camera.capture_continuous(rawCapture,format="bgr",use_video_port=True):
# image = frame.array
# img = image
#show the image
#wait until some key is pressed to procced
while True:
_, image = cap.read()
img = image
edges = cv2.Canny(image,100,200)
cv2.imshow("Canny",edges)
#contours,hierarchy = cv2.findContours(edges,cv2.RETR_TREE,cv2.CHAIN_APPROX_SIMPLE)
im2,contours,hierarchy = cv2.findContours(edges,cv2.RETR_TREE,cv2.CHAIN_APPROX_SIMPLE)
cv2.imshow("contours",im2)
mu = []
mc = []
mark = 0
for x in range(0,len(contours)):
mu.append(cv2.moments(contours[x]))
for m in mu:
if m['m00'] != 0:
mc.append((m['m10']/m['m00'],m['m01']/m['m00']))
else:
mc.append((0,0))
for x in range(0,len(contours)):
k = x
c = 0
while(hierarchy[0][k][2] != -1):
k = hierarchy[0][k][2]
c = c + 1
if hierarchy[0][k][2] != -1:
c = c + 1
if c >= 5:
if mark == 0:
A = x
elif mark == 1:
B = x
elif mark == 2:
C = x
mark = mark+1
if mark >2 :
AB = distance(mc[A],mc[B])
BC = distance(mc[B],mc[C])
AC = distance(mc[A],mc[C])
if(AB>BC and AB>AC):
outlier = C
median1 = A
median2 = B
elif(AC>AB and AC>BC):
outlier = B
median1 = A
median2 = C
elif(BC>AB and BC>AC):
outlier = A
median1 = B
median2 = C
top = outlier
dist = lineEquation(mc[median1],mc[median2],mc[outlier])
slope,align = lineSlope(mc[median1],mc[median2])
if align == 0:
bottom = median1
right = median2
elif(slope < 0 and dist < 0):
bottom = median1
right = median2
orientation = 0
elif(slope > 0 and dist < 0):
right = median1
bottom = median2
orientation = 1
elif(slope < 0 and dist > 0):
right = median1
bottom = median2
orientation = 2
elif(slope > 0 and dist > 0):
bottom = median1
right = median2
orientation = 3
areatop = 0.0
arearight = 0.0
areabottom = 0.0
if(top < len(contours) and right < len(contours) and bottom < len(contours) and cv2.contourArea(contours[top]) > 10 and cv2.contourArea(contours[right]) > 10 and cv2.contourArea(contours[bottom]) > 10):
tempL = []
tempM = []
tempO = []
src = []
N = (0,0)
tempL = getVertices(contours,top,slope,tempL)
tempM = getVertices(contours,right,slope,tempM)
tempO = getVertices(contours,bottom,slope,tempO)
L = updateCornerOr(orientation,tempL)
M = updateCornerOr(orientation,tempM)
O = updateCornerOr(orientation,tempO)
iflag,N = getIntersection(M[1],M[2],O[3],O[2],N)
src.append(L[0])
src.append(M[1])
src.append(N)
src.append(O[3])
src = np.asarray(src,np.float32)
warped1 = four_point_transform(img,src)
warped = warped1
#sw added to rotate image to correct orientation for visual purposes only - not needed for zbar
rowsrot,colsrot,dummy = warped1.shape
#print rowsrot,colsrot,dummy
if orientation > 0:
Mrot = cv2.getRotationMatrix2D((colsrot/2,rowsrot/2),(90 * orientation),1)
warped = cv2.warpAffine(warped1,Mrot,(colsrot,rowsrot))
cv2.imshow("warped",warped)
cv2.circle(img,N,1,(0,0,255),2)
cv2.drawContours(img,contours,top,(255,0,0),2)
cv2.drawContours(img,contours,right,(0,255,0),2)
cv2.drawContours(img,contours,bottom,(0,0,255),2)
warped = cv2.cvtColor(warped,cv2.COLOR_BGR2GRAY)
scanner = zbar.ImageScanner()
scanner.parse_config('enable')
imagez = zbar.Image(warped.shape[0],warped.shape[1],'Y800',warped.tostring())
scanner.scan(imagez)
for symbol in imagez:
x = symbol.data
print x
print int(180.0 * slope / 3.1415926)
cv2.imshow("rect",img)
key = cv2.waitKey(1) & 0xFF
if key == ord("q"):
break
cap.release()
cv2.destroyAllWindows()