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grid construction and evaluation
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| import sys
sys.path.append("../src")
import os
import random
import itertools
import logging as log
import cv2 as cv
import numpy as np
import scipy.cluster
import scipy.ndimage
import scipy.signal
from geometry import Line
from ransac import DiagonalRansac
from annotations import DataFile,computeBoundingBox
from hough import show,prepareEdgeImg,HoughTransform
from analyzer.epoint import EPoint
from analyzer.corners import Corners
random.seed(361)
log.basicConfig(level=log.DEBUG,format="%(message)s")
def kmeans(img):
arr=np.reshape(img,(-1,3)).astype(np.float)
wood=[193,165,116]
(centers,distortion)=scipy.cluster.vq.kmeans(arr,3)
log.debug("k-means centers: %s",centers)
(black,empty,white)=sorted(centers,key=sum)
if np.linalg.norm(black)>np.linalg.norm(black-wood):
black=None
if np.linalg.norm(white-[255,255,255])>np.linalg.norm(white-wood):
white=None
log.debug("black, white: %s, %s",black,white)
return (black,white,centers)
def quantize(img,centers):
origShape=img.shape
data=np.reshape(img,(-1,3))
(keys,dists)=scipy.cluster.vq.vq(data,centers)
pixels=np.array([centers[k] for k in keys],dtype=np.uint8).reshape(origShape)
return pixels
def filterStones(contours,bwImg,stoneDims):
contourImg=cv.cvtColor(bwImg,cv.COLOR_GRAY2BGR)
res=[]
for (i,c) in enumerate(contours):
keep=True
moments=cv.moments(c)
center=(moments["m10"]/(moments["m00"] or 1), moments["m01"]/(moments["m00"] or 1))
area=cv.contourArea(c)
(x,y,w,h)=cv.boundingRect(c)
if w>stoneDims[0] or h>stoneDims[1]*1.5 or w<2 or h<2:
cv.drawMarker(contourImg,tuple(map(int,center)),(0,0,255),cv.MARKER_TILTED_CROSS,12)
keep=False
coverage1=area/(w*h or 1)
hull=cv.convexHull(c)
coverage2=area/(cv.contourArea(hull) or 1)
# if coverage2<0.8:
# cv.drawMarker(contourImg,tuple(map(int,center)),(0,127,255),cv.MARKER_DIAMOND,12)
# keep=False
if keep:
res.append((EPoint(*center),c))
cv.drawMarker(contourImg,tuple(map(int,center)),(255,0,0),cv.MARKER_CROSS)
log.debug("accepted: %s",len(res))
log.debug("rejected: %s",len(contours)-len(res))
show(contourImg,"accepted and rejected stones")
return res
class BoardDetector:
def __init__(self,annotationsPath):
self._annotations=DataFile(annotationsPath)
self._rectW=0
self._rectH=0
self._rect=None
self._hough=None
self._rectiMatrix=None
self._inverseMatrix=None
def __call__(self,img,filename):
# approximately detect the board
(h,w)=img.shape[:2]
log.debug("image dimensions: %s x %s",w,h)
show(img,filename)
(x1,y1,x2,y2)=self._detectRough(img,filename)
rect=img[y1:y2,x1:x2]
self._rectW=x2-x1
self._rectH=y2-y1
self._rect=rect
# quantize colors
(black,white,colors)=self._sampleColors(rect)
quantized=quantize(rect,colors)
gray=cv.cvtColor(rect,cv.COLOR_BGR2GRAY)
edges=cv.Canny(gray,70,130)
show(edges,"edges")
quantized=quantized & (255-cv.cvtColor(edges,cv.COLOR_GRAY2BGR))
show(quantized,"quantized, edges separated")
# detect black and white stones
stones=self._detectStones(quantized,black,white)
# detect lines from edges and stones
edgeImg=prepareEdgeImg(rect)
self._hough=HoughTransform(edgeImg)
stonesImg=np.zeros((self._rectH,self._rectW),np.uint8)
for (point,c) in stones:
cv.circle(stonesImg,(int(point.x),int(point.y)),2,255,-1)
show(stonesImg,"detected stones")
self._hough.update(stonesImg,10)
lines=self._hough.extract()
linesImg=np.copy(rect)
for line in itertools.chain(*lines):
self._drawLine(linesImg,line)
show(linesImg,"detected lines")
# # rectify the image
matrix=self._computeTransformationMatrix(lines[0][0],lines[0][-1],lines[1][0],lines[1][-1])
transformed=cv.warpPerspective(rect,matrix,(self._rectW,self._rectH))
rectiLines=[[line.transform(matrix) for line in pack] for pack in lines]
# determine precise board edges
self._detectBestGrid(rectiLines,linesImg)
def _detectRough(self,img,filename):
corners=self._annotations[filename][0]
(x1,y1,x2,y2)=computeBoundingBox(corners)
log.debug("bounding box: (%s,%s) - (%s,%s)",x1,y1,x2,y2)
return (x1,y1,x2,y2)
def _sampleColors(self,rect):
(h,w)=rect.shape[:2]
minirect=rect[h//4:3*h//4, w//4:3*w//4]
return kmeans(minirect)
def _detectStones(self,quantized,black,white):
(h,w)=quantized.shape[:2]
mask=self._maskStones(quantized,black,white)
stoneDims=(w/19,h/19)
log.debug("stone dims: %s - %s",tuple(x/2 for x in stoneDims),stoneDims)
(contours,hierarchy)=cv.findContours(mask,cv.RETR_LIST,cv.CHAIN_APPROX_SIMPLE)
stoneLocs=filterStones(contours,mask,stoneDims)
return stoneLocs
def _maskStones(self,quantized,black,white):
unit=np.array([1,1,1],dtype=np.uint8)
if black is not None:
maskB=cv.inRange(quantized,black-unit,black+unit)
distTransform=cv.distanceTransform(maskB,cv.DIST_L2,5)
maskB=cv.inRange(distTransform,6,20)
show(maskB,"black areas")
else: maskB=np.zeros(quantized.shape[:2],dtype=np.uint8)
if white is not None:
maskW=cv.inRange(quantized,white-unit,white+unit)
distTransform=cv.distanceTransform(maskW,cv.DIST_L2,5)
maskW=cv.inRange(distTransform,6,20)
show(maskW,"white areas")
else: maskW=np.zeros(quantized.shape[:2],dtype=np.uint8)
stones=cv.bitwise_or(maskB,maskW)
show(stones,"black and white areas")
return stones
def _computeTransformationMatrix(self,p,q,r,s): # p || q, r || s
(a,b,c,d)=Corners([p.intersect(r),p.intersect(s),q.intersect(r),q.intersect(s)]) # canonize the abcd order
pad=20
a_=EPoint(b.x+pad,min(a.y,d.y)+pad)
b_=EPoint(b.x+pad,max(b.y,c.y)-pad)
c_=EPoint(c.x-pad,max(b.y,c.y)-pad)
d_=EPoint(c.x-pad,min(a.y,d.y)+pad)
abcd=[list(point) for point in (a,b,c,d)]
abcd_=[list(point) for point in (a_,b_,c_,d_)]
log.debug("abcd: %s ->",(a,b,c,d))
log.debug("-> abcd_: %s",(a_,b_,c_,d_))
matrix=cv.getPerspectiveTransform(np.float32(abcd),np.float32(abcd_))
log.debug("transformation matrix: %s",matrix)
rect=np.copy(self._rect)
for point in (a,b,c,d):
cv.drawMarker(rect,(int(point.x),int(point.y)),(0,255,255),cv.MARKER_TILTED_CROSS)
show(rect)
transformed=cv.warpPerspective(rect,matrix,(self._rectW,self._rectH))
show(transformed,"rectified image")
self._rectiMatrix=matrix
self._inverseMatrix=np.linalg.inv(matrix)
return matrix
def _detectBestGrid(self,lines,img):
intersections=[]
for p in lines[0]:
for q in lines[1]:
intersections.append(p.intersect(q))
sack=DiagonalRansac(intersections,19)
diagonals=sack.extract(10,3000)
log.debug("diagonals candidates: %s",diagonals)
for line in diagonals:
self._drawLine(img,line.transform(self._inverseMatrix),[0,255,255])
show(img,"diagonals candidates")
best=(0,None)
transformedImg=cv.warpPerspective(img,self._rectiMatrix,(self._rectW,self._rectH))
for e in diagonals:
for f in diagonals:
center=e.intersect(f)
if not center: continue
if center.x<0 or center.x>self._rectW or center.y<0 or center.y>self._rectH: continue
for line in itertools.chain(*lines):
for i in range(1,10): # 10th is useless, 11-19 are symmetrical to 1-9
grid=self._constructGrid(e,f,line,i)
if not grid: continue
score=self._scoreGrid(grid)
if score>best[0]:
best=(score,grid)
log.debug("new best grid: %s",score)
self._showGrid(transformedImg,grid)
return best[1]
def _constructGrid(self,e,f,line,i):
"""Contruct a grid.
:param e: (Line) one diagonal
:param f: (Line) other diagonal
:param line: (Line) one of the grid lines
:param i: (int) line's index among the grid's lines, 1<=i<=9"""
center=e.intersect(f)
p1=line.intersect(e)
p2=line.intersect(f)
a=center+9*(p1-center)/(10-i)
b=center+9*(p2-center)/(10-i)
c=2*center-a
d=2*center-b
# abort unfitting sizes
if not all(0<=point.x<self._rectW and 0<=point.y<self._rectH for point in (a,b,c,d)):
return None
if any(g.dist(h)<19*10 for (g,h) in [(a,b),(a,c),(a,d),(b,c),(b,d),(c,d)]):
return None
(a,b,c,d)=Corners([a,b,c,d])
rows=[]
cols=[]
for j in range(19):
rows.append(Line.fromPoints((a*(18-j)+b*j)/18,(d*(18-j)+c*j)/18))
cols.append(Line.fromPoints((a*(18-j)+d*j)/18,(b*(18-j)+c*j)/18))
return (rows,cols)
def _scoreGrid(self,lines):
return sum(self._hough.scoreLine(p.transform(self._inverseMatrix)) for p in itertools.chain(*lines))
def _drawLine(self,img,line,color=None):
if not color: color=[0,255,0]
(h,w)=img.shape[:2]
corners=[EPoint(0,0),EPoint(w,0),EPoint(0,h),EPoint(w,h)] # NW NE SW SE
borders=[
[Line.fromPoints(corners[0],corners[1]), Line.fromPoints(corners[2],corners[3])], # N S
[Line.fromPoints(corners[0],corners[2]), Line.fromPoints(corners[1],corners[3])] # W E
]
(a,b)=(line.intersect(borders[0][0]), line.intersect(borders[0][1]))
log.debug("%s %s",line,(a,b))
if not a or not b:
(a,b)=(line.intersect(borders[1][0]), line.intersect(borders[1][1]))
log.debug("* %s %s",line,(a,b))
if any(abs(x)>10**5 for x in [*a,*b]):
log.debug("ignored")
return
cv.line(img,(int(a.x),int(a.y)),(int(b.x),int(b.y)),color)
def _showGrid(self,img,lines):
img=np.copy(img)
(rows,cols)=lines
for row in rows:
for col in cols:
point=row.intersect(col)
xy=(int(point.x),int(point.y))
cv.circle(img,xy,4,[0,0,255],-1)
show(img,"grid candidate")
if __name__=="__main__":
detector=BoardDetector(sys.argv[2])
filepath=sys.argv[1]
filename=os.path.basename(filepath)
img=cv.imread(filepath)
detector(img,filename)
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