making it pretty

draw.py

@@ -5,8 +5,8 @@ machine chooch.
 """
 import os
 
-import linedraw
 import stream
+import linedraw
 
 def draw(rec_filename):
 	"""

linedraw.py

@@ -1,11 +1,15 @@
+#!/usr/bin/env python3
+"""
+Takes a raster image file and vectorizes it to create line art usable by
+a pen plotter.
+"""
 import os
-from random import *
 import math
+from random import *
 
 from PIL import Image, ImageDraw, ImageOps
 
 no_cv = True
-export_path = "output/out.svg"
 draw_contours = True
 draw_hatch = False
 
@@ -24,6 +28,7 @@ F_Blur = {
 	(-2,1):4,(-1,1):9,(0,1):12,(1,1):9,(2,1):4,
 	(-2,2):2,(-1,2):4,(0,2):5,(1,2):4,(2,2):2,
 }
+
 F_SobelX = {
 	(-1,-1): 1,
 	(0,-1):  0,
@@ -33,7 +38,8 @@ F_SobelX = {
 	(1,0):  -2,
 	(-1,1):  1,
 	(0,1):   0,
-	(1,1):   -1}
+	(1,1)   -1}
+
 F_SobelY = {
 	(-1,-1): 1,
 	(0,-1):  2,
@@ -45,9 +51,9 @@ F_SobelY = {
 	(0,1):  -2,
 	(1,1):  -1}
 
-def appmask(IM,masks):
-	PX = IM.load()
-	w,h = IM.size
+def appmask(image, masks):
+	PX = image.load()
+	w, h = image.size
 	NPX = {}
 	for x in range(0, w):
 		for y in range(0, h):
@@ -99,38 +105,37 @@ def sortlines(lines):
 	return slines
 
 
-
-def auto_canny(img, sigma=0.33):
+def auto_canny(image, sigma=0.33):
 	"""
 	Automatically determines appropriate upper and lower boundries for the Canny function.
 	"""
-	med = np.median(img)
+	med = np.median(image)
 	lower = int(max(0, (1.0 - sigma) * med))
 	upper = int(min(255, (1.0 + sigma) * med))
-	edges = cv2.Canny(img, lower, upper)
+	edges = cv2.Canny(image, lower, upper)
 	return edges
 
 
-def find_edges(IM):
+def find_edges(image):
 	print("finding edges...")
 	no_cv = True
 	if no_cv:
-		#appmask(IM,[F_Blur])
-		appmask(IM,[F_SobelX,F_SobelY])
+		#appmask(image, [F_Blur])
+		appmask(image, [F_SobelX, F_SobelY])
 	else:
-		im = np.array(IM) 
-		im = cv2.GaussianBlur(im,(3,3),0)
-		#im = cv2.Canny(im,100,200)
-		im = auto_canny(im)
-		IM = Image.fromarray(im)
-	return IM.point(lambda p: p > 128 and 255)  
+		image = np.array(image) 
+		image = cv2.GaussianBlur(image, (3, 3), 0)
+		#image = cv2.Canny(image,100,200)
+		image = auto_canny(image)
+		image = Image.fromarray(image)
+	return image.point(lambda p: p > 128 and 255)  
 
 
-def getdots(IM):
+def getdots(image):
 	print("getting contour points...")
-	PX = IM.load()
+	PX = image.load()
 	dots = []
-	w,h = IM.size
+	w, h = image.size
 	for y in range(h-1):
 		row = []
 		for x in range(1, w):
@@ -179,14 +184,14 @@ def connectdots(dots):
 	return contours
 
 
-def getcontours(IM,sc=2):
+def getcontours(image, 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)
+	image = find_edges(image)
+	image1 = IM.copy()
+	image2 = image.rotate(-90, expand=True).transpose(Image.FLIP_LEFT_RIGHT)
+	dots1 = getdots(image1)
 	contours1 = connectdots(dots1)
-	dots2 = getdots(IM2)
+	dots2 = getdots(image2)
 	contours2 = connectdots(dots2)
 
 	for i in range(len(contours2)):
@@ -216,10 +221,10 @@ def getcontours(IM,sc=2):
 	return contours
 
 
-def hatch(IM,sc=16):
+def hatch(image, sc=16):
 	print("hatching...")
-	PX = IM.load()
-	w,h = IM.size
+	PX = image.load()
+	w,h = image.size
 	lg1 = []
 	lg2 = []
 	for x0 in range(w):
@@ -268,6 +273,7 @@ def sketch(path, export_path=None, resolution=1024, hatch_size=16, contour_simpl
 		width = int(resolution/contour_simplify)
 		height = int(resolution/contour_simplify*image.size[0]/image.size[1])
 		lines += getcontours(image.resize((width, height)), contour_simplify)
+
 	if draw_hatch:
 		width = int(resolution/hatch_size)
 		height = int(resolution/hatch_size*image.size[0]/image.size[1])