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linedraw.py
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linedraw.py
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from random import *
import math
import argparse
from PIL import Image, ImageDraw, ImageOps
from filters import *
from strokesort import *
import perlin
from util import *
no_cv = False
export_path = "output/out.svg"
draw_contours = True
draw_hatch = True
show_bitmap = False
resolution = 1024
hatch_size = 16
contour_simplify = 2
try:
import numpy as np
import cv2
except:
print("Cannot import numpy/openCV. Switching to NO_CV mode.")
no_cv = True
def find_edges(IM):
print("finding edges...")
if no_cv:
#appmask(IM,[F_Blur])
appmask(IM,[F_SobelX,F_SobelY])
else:
im = np.array(IM)
im = cv2.GaussianBlur(im,(3,3),0)
im = cv2.Canny(im,100,200)
IM = Image.fromarray(im)
return IM.point(lambda p: p > 128 and 255)
def getdots(IM):
print("getting contour points...")
PX = IM.load()
dots = []
w,h = IM.size
for y in range(h-1):
row = []
for x in range(1,w):
if PX[x,y] == 255:
if len(row) > 0:
if x-row[-1][0] == row[-1][-1]+1:
row[-1] = (row[-1][0],row[-1][-1]+1)
else:
row.append((x,0))
else:
row.append((x,0))
dots.append(row)
return dots
def connectdots(dots):
print("connecting contour points...")
contours = []
for y in range(len(dots)):
for x,v in dots[y]:
if v > -1:
if y == 0:
contours.append([(x,y)])
else:
closest = -1
cdist = 100
for x0,v0 in dots[y-1]:
if abs(x0-x) < cdist:
cdist = abs(x0-x)
closest = x0
if cdist > 3:
contours.append([(x,y)])
else:
found = 0
for i in range(len(contours)):
if contours[i][-1] == (closest,y-1):
contours[i].append((x,y,))
found = 1
break
if found == 0:
contours.append([(x,y)])
for c in contours:
if c[-1][1] < y-1 and len(c)<4:
contours.remove(c)
return contours
def getcontours(IM,sc=2):
print("generating contours...")
IM = find_edges(IM)
IM1 = IM.copy()
IM2 = IM.rotate(-90,expand=True).transpose(Image.FLIP_LEFT_RIGHT)
dots1 = getdots(IM1)
contours1 = connectdots(dots1)
dots2 = getdots(IM2)
contours2 = connectdots(dots2)
for i in range(len(contours2)):
contours2[i] = [(c[1],c[0]) for c in contours2[i]]
contours = contours1+contours2
for i in range(len(contours)):
for j in range(len(contours)):
if len(contours[i]) > 0 and len(contours[j])>0:
if distsum(contours[j][0],contours[i][-1]) < 8:
contours[i] = contours[i]+contours[j]
contours[j] = []
for i in range(len(contours)):
contours[i] = [contours[i][j] for j in range(0,len(contours[i]),8)]
contours = [c for c in contours if len(c) > 1]
for i in range(0,len(contours)):
contours[i] = [(v[0]*sc,v[1]*sc) for v in contours[i]]
for i in range(0,len(contours)):
for j in range(0,len(contours[i])):
contours[i][j] = int(contours[i][j][0]+10*perlin.noise(i*0.5,j*0.1,1)),int(contours[i][j][1]+10*perlin.noise(i*0.5,j*0.1,2))
return contours
def hatch(IM,sc=16):
print("hatching...")
PX = IM.load()
w,h = IM.size
lg1 = []
lg2 = []
for x0 in range(w):
for y0 in range(h):
x = x0*sc
y = y0*sc
if PX[x0,y0] > 144:
pass
elif PX[x0,y0] > 64:
lg1.append([(x,y+sc/4),(x+sc,y+sc/4)])
elif PX[x0,y0] > 16:
lg1.append([(x,y+sc/4),(x+sc,y+sc/4)])
lg2.append([(x+sc,y),(x,y+sc)])
else:
lg1.append([(x,y+sc/4),(x+sc,y+sc/4)])
lg1.append([(x,y+sc/2+sc/4),(x+sc,y+sc/2+sc/4)])
lg2.append([(x+sc,y),(x,y+sc)])
lines = [lg1,lg2]
for k in range(0,len(lines)):
for i in range(0,len(lines[k])):
for j in range(0,len(lines[k])):
if lines[k][i] != [] and lines[k][j] != []:
if lines[k][i][-1] == lines[k][j][0]:
lines[k][i] = lines[k][i]+lines[k][j][1:]
lines[k][j] = []
lines[k] = [l for l in lines[k] if len(l) > 0]
lines = lines[0]+lines[1]
for i in range(0,len(lines)):
for j in range(0,len(lines[i])):
lines[i][j] = int(lines[i][j][0]+sc*perlin.noise(i*0.5,j*0.1,1)),int(lines[i][j][1]+sc*perlin.noise(i*0.5,j*0.1,2))-j
return lines
def sketch(path):
IM = None
possible = [path,"images/"+path,"images/"+path+".jpg","images/"+path+".png","images/"+path+".tif"]
for p in possible:
try:
IM = Image.open(p)
break
except FileNotFoundError:
print("The Input File wasn't found. Check Path")
exit(0)
pass
w,h = IM.size
IM = IM.convert("L")
IM=ImageOps.autocontrast(IM,10)
lines = []
if draw_contours:
lines += getcontours(IM.resize((resolution//contour_simplify,resolution//contour_simplify*h//w)),contour_simplify)
if draw_hatch:
lines += hatch(IM.resize((resolution//hatch_size,resolution//hatch_size*h//w)),hatch_size)
lines = sortlines(lines)
if show_bitmap:
disp = Image.new("RGB",(resolution,resolution*h//w),(255,255,255))
draw = ImageDraw.Draw(disp)
for l in lines:
draw.line(l,(0,0,0),5)
disp.show()
f = open(export_path,'w')
f.write(makesvg(lines))
f.close()
print(len(lines),"strokes.")
print("done.")
return lines
def makesvg(lines):
print("generating svg file...")
out = '<svg xmlns="http://www.w3.org/2000/svg" version="1.1">'
for l in lines:
l = ",".join([str(p[0]*0.5)+","+str(p[1]*0.5) for p in l])
out += '<polyline points="'+l+'" stroke="black" stroke-width="2" fill="none" />\n'
out += '</svg>'
return out
if __name__ == "__main__":
parser = argparse.ArgumentParser(description='Convert image to vectorized line drawing for plotters.')
parser.add_argument('-i','--input',dest='input_path',
default='lenna',action='store',nargs='?',type=str,
help='Input path')
parser.add_argument('-o','--output',dest='output_path',
default=export_path,action='store',nargs='?',type=str,
help='Output path.')
parser.add_argument('-b','--show_bitmap',dest='show_bitmap',
const = not show_bitmap,default= show_bitmap,action='store_const',
help="Display bitmap preview.")
parser.add_argument('-nc','--no_contour',dest='no_contour',
const = draw_contours,default= not draw_contours,action='store_const',
help="Don't draw contours.")
parser.add_argument('-nh','--no_hatch',dest='no_hatch',
const = draw_hatch,default= not draw_hatch,action='store_const',
help='Disable hatching.')
parser.add_argument('--no_cv',dest='no_cv',
const = not no_cv,default= no_cv,action='store_const',
help="Don't use openCV.")
parser.add_argument('--hatch_size',dest='hatch_size',
default=hatch_size,action='store',nargs='?',type=int,
help='Patch size of hatches. eg. 8, 16, 32')
parser.add_argument('--contour_simplify',dest='contour_simplify',
default=contour_simplify,action='store',nargs='?',type=int,
help='Level of contour simplification. eg. 1, 2, 3')
args = parser.parse_args()
export_path = args.output_path
draw_hatch = not args.no_hatch
draw_contours = not args.no_contour
hatch_size = args.hatch_size
contour_simplify = args.contour_simplify
show_bitmap = args.show_bitmap
no_cv = args.no_cv
sketch(args.input_path)