Updated, optimizations and cleanup.

* accurate mouse to mapping using ray intersect, * right clicking cancels and returns original coords Doc is here http://mediawiki.blender.org/index.php/Scripts/Manual/UV_Calculate/Click_project_from_face
2006-12-15 04:14:09 +00:00 · 2006-12-15 04:14:09 +00:00 · 0254065f3b
commit 0254065f3b
parent 0fbecfe936
1 changed files with 132 additions and 60 deletions
--- a/release/scripts/uvcalc_quad_clickproj.py
+++ b/release/scripts/uvcalc_quad_clickproj.py
@ -1,13 +1,43 @@
 #!BPY

 """ Registration info for Blender menus: <- these words are ignored
-Name: 'Click Project from face'
+Name: 'Click project from face'
 Blender: 242
 Group: 'UVCalculation'
-Tooltip: 'click'
+Tooltip: '3 Clicks to project uvs onto selected faces.'
 """

+__author__ = ["Campbell Barton"]
+__url__ = ("blender", "elysiun", "http://members.iinet.net.au/~cpbarton/ideasman/")
+__version__ = "0.1"
+__bpydoc__=\
+'''
+http://mediawiki.blender.org/index.php/Scripts/Manual/UV_Calculate/Click_project_from_face
+"

+'''
+
+# -------------------------------------------------------------------------- 
+# Click project v0.1 by Campbell Barton (AKA Ideasman)
+# -------------------------------------------------------------------------- 
+# ***** BEGIN GPL LICENSE BLOCK ***** 
+# 
+# This program is free software; you can redistribute it and/or 
+# modify it under the terms of the GNU General Public License 
+# as published by the Free Software Foundation; either version 2 
+# of the License, or (at your option) any later version. 
+# 
+# This program is distributed in the hope that it will be useful, 
+# but WITHOUT ANY WARRANTY; without even the implied warranty of 
+# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the 
+# GNU General Public License for more details. 
+# 
+# You should have received a copy of the GNU General Public License 
+# along with this program; if not, write to the Free Software Foundation, 
+# Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA. 
+# 
+# ***** END GPL LICENCE BLOCK ***** 
+# -------------------------------------------------------------------------- 

 import Blender
 import BPyMesh
@ -15,8 +45,9 @@ import BPyWindow

 mouseViewRay= BPyWindow.mouseViewRay
 from Blender import Mathutils, Window, Scene, Draw, sys
-from Blender.Mathutils import CrossVecs, Vector, Intersect, LineIntersect, AngleBetweenVecs
+from Blender.Mathutils import CrossVecs, Vector, Matrix, LineIntersect, Intersect #, AngleBetweenVecs, Intersect
 LMB= Window.MButs['L']
+RMB= Window.MButs['R']

 def mouseup():
 	# Loop until click
@ -33,7 +64,7 @@ def mousedown_wait():
 	mouse_buttons = Window.GetMouseButtons()
 	while mouse_buttons & LMB:
 		mouse_buttons = Window.GetMouseButtons()
-		
+		sys.sleep(10)

 def main():
 	
@ -42,13 +73,27 @@ def main():
 	if not ob or ob.type!='Mesh':
 		return
 	
-	mousedown_wait()
+	mousedown_wait() # so the menu items clicking dosnt trigger the mouseclick
 	
 	Window.DrawProgressBar (0.0, '')
 	Window.DrawProgressBar (0.1, '(1 of 3) Click on a face corner')	
 	
 	# wait for a click
-	mouseup()
+	mouse_buttons = Window.GetMouseButtons()
+	while not mouse_buttons & LMB:
+		sys.sleep(10)
+		mouse_buttons = Window.GetMouseButtons()
+		
+		# Allow for RMB cancel
+		if mouse_buttons & RMB:
+			Window.DrawProgressBar (1.0, '')
+			return
+		
+	while mouse_buttons & LMB:
+		sys.sleep(10)
+		mouse_buttons = Window.GetMouseButtons()
+	
+	
 	
 	Window.DrawProgressBar (0.2, '(2 of 3 ) Click confirms the U coords')
 	
@ -65,55 +110,60 @@ def main():
 		
 	me = ob.getData(mesh=1)
 	
-	SELECT_FLAG = Blender.Mesh.FaceFlags['SELECT']
-	me_faces_sel = [ f for f in me.faces if f.flag & SELECT_FLAG ]
-	del SELECT_FLAG
+	# Get the face under the mouse
+	face_click, isect, side = BPyMesh.pickMeshRayFace(me, OriginA, DirectionA)
 	
-	f, isect, side = BPyMesh.pickMeshRayFace(me, OriginA, DirectionA)
-	f_no = f.no
-	if not f:
+	proj_z_component = face_click.no
+	if not face_click:
 		Window.DrawProgressBar (1.0, '')
 		return
 	
-	# find the vertex thats closest
-	
+	# Find the face vertex thats closest to the mouse,
+	# this vert will be used as the corner to map from.
 	best_v= None
 	best_length = 10000000
 	vi1 = None
-	for i, v in enumerate(f.v):
+	for i, v in enumerate(face_click.v):
 		l = (v.co-isect).length
 		if l < best_length:
 			best_v = v
 			best_length = l
 			vi1 = i
 	
-	# now find the 2 edges in the face that connect to v
-	if len(f)==4:
-		if vi1==0: vi2, vi3= 3,1
-		if vi1==1: vi2, vi3= 0,2
-		if vi1==2: vi2, vi3= 1,3
-		if vi1==3: vi2, vi3= 2,0
+	# now get the 2 edges in the face that connect to v
+	# we can work it out fairly easerly
+	if len(face_click)==4:
+		if	 vi1==0: vi2, vi3= 3,1
+		elif vi1==1: vi2, vi3= 0,2
+		elif vi1==2: vi2, vi3= 1,3
+		elif vi1==3: vi2, vi3= 2,0
 	else:
-		if vi1==0: vi2, vi3= 2,1
-		if vi1==1: vi2, vi3= 0,2
-		if vi1==2: vi2, vi3= 1,0
+		if   vi1==0: vi2, vi3= 2,1
+		elif vi1==1: vi2, vi3= 0,2
+		elif vi1==2: vi2, vi3= 1,0
 	
+	face_corner_main =face_click.v[vi1].co
+	face_corner_a =face_click.v[vi2].co
+	face_corner_b =face_click.v[vi3].co
 	
-	loc1 =f.v[vi1].co
-	loc2 =f.v[vi2].co
-	loc3 =f.v[vi3].co
+	line_a_len = (face_corner_a-face_corner_main).length
+	line_b_len = (face_corner_b-face_corner_main).length
 	
-	line1_len = (loc2-loc1).length
-	line2_len = (loc3-loc1).length
-	
-	
-	# tmat = Mathutils.TranslationMatrix(-loc1)
-	
-	Window.SetCursorPos(loc1.x, loc1.y, loc1.z)
+	orig_cursor = Window.GetCursorPos()
+	Window.SetCursorPos(face_corner_main.x, face_corner_main.y, face_corner_main.z)
 	
 	MODE = 0 # firstclick, 1, secondclick
 	mouse_buttons = Window.GetMouseButtons()
-	Window.SetCursorPos(loc1.x, loc1.y, loc1.z)
+	
+	project_mat = Matrix([0,0,0], [0,0,0], [0,0,0])
+	
+	
+	SELECT_FLAG = Blender.Mesh.FaceFlags['SELECT']
+	me_faces_sel = [ ([v.co-face_corner_main for v in f], f.uv) for f in me.faces if f.flag & SELECT_FLAG ]
+	del SELECT_FLAG
+	
+	me_faces_sel_uvs = [uv.copy() for f in me_faces_sel for uv in f[1]]
+	
 	while 1:
 		if mouse_buttons & LMB:
 			if MODE == 0:
@ -122,7 +172,16 @@ def main():
 				MODE = 1 # second click
 			else:
 				break
-		
+		elif mouse_buttons & RMB:
+			
+			# Restore old uvs
+			i= 0
+			for f in me_faces_sel:
+				for uv in f[1]:
+					uv[:] = me_faces_sel_uvs[i]
+					i+=1
+			break
+			
 		mouse_buttons = Window.GetMouseButtons()
 		screen_x, screen_y = Window.GetMouseCoords()
 		mouseInView, OriginA, DirectionA = mouseViewRay(screen_x, screen_y, obmat)
@ -130,42 +189,55 @@ def main():
 		if not mouseInView:
 			continue
 		
-		d1_pair = Mathutils.LineIntersect(OriginA, OriginA+DirectionA, loc1, loc2)
-		d2_pair = Mathutils.LineIntersect(OriginA, OriginA+DirectionA, loc1, loc3)
+		
+		# Do a ray tri intersection, not clipped by the tri
+		new_isect = Intersect(face_corner_main, face_corner_a, face_corner_b, DirectionA, OriginA, False)
+		new_isect_alt = new_isect + DirectionA*0.0001
+		
+		
+		# The distance from the mouse cursor ray vector to the edge
+		line_isect_a_pair = LineIntersect(new_isect, new_isect_alt, face_corner_main, face_corner_a)
+		line_isect_b_pair = LineIntersect(new_isect, new_isect_alt, face_corner_main, face_corner_b)
+		
 		if MODE == 0:	
-			d1 = (d1_pair[0]-d1_pair[1]).length
-			d2 = (d2_pair[0]-d2_pair[1]).length
+			line_dist_a = (line_isect_a_pair[0]-line_isect_a_pair[1]).length
+			line_dist_b = (line_isect_b_pair[0]-line_isect_b_pair[1]).length
 			
-			if d1<d2:
-				loc_to_use = loc2
-				y_dist = line2_len
-				x_dist = (d1_pair[1]-loc1).length
+			if line_dist_a < line_dist_b:
+				proj_x_component = face_corner_a - face_corner_main
+				y_axis_length = line_b_len
+				x_axis_length = (line_isect_a_pair[1]-face_corner_main).length
 			else:
-				loc_to_use = loc3
-				y_dist = line1_len
-				x_dist = (d2_pair[1]-loc1).length
+				proj_x_component = face_corner_b - face_corner_main
+				y_axis_length = line_a_len
+				x_axis_length = (line_isect_b_pair[1]-face_corner_main).length
 			
-			line_x = loc_to_use - loc1
-			
-			line_y = Mathutils.CrossVecs(line_x, f_no)
-			line_x.length = 1/x_dist
-			line_y.length = 1/y_dist
+			proj_y_component = CrossVecs(proj_x_component, proj_z_component)
 			
+			proj_y_component.length = 1/y_axis_length
+			proj_x_component.length = 1/x_axis_length
+		
 		else:
-			if d1<d2:	line_y.length = 1/(d2_pair[1]-loc1).length
-			else:		line_y.length = 1/(d1_pair[1]-loc1).length
+			if line_dist_a < line_dist_b:
+				proj_y_component.length = 1/(line_isect_a_pair[1]-new_isect).length
+			else:
+				proj_y_component.length = 1/(line_isect_b_pair[1]-new_isect).length
 		
-		# Make a matrix
-		project_mat = Mathutils.Matrix(line_x, line_y, f_no)
-		project_mat.resize4x4()
+		# Use the existing matrix to make a new 3x3 projecton matrix
+		project_mat[0][:] = proj_x_component
+		project_mat[1][:] = proj_y_component
+		project_mat[2][:] = proj_z_component
 		
-		
-		for f in me_faces_sel:
-			f.uv = [project_mat * (v.co-loc1) for v in f]
+		# Apply the projection matrix
+		for f_proj_co, f_uv in me_faces_sel:
+			for i, uv in enumerate(f_uv):
+				uv[:] = (project_mat * f_proj_co[i])[0:2]
 		
 		Window.Redraw(Window.Types.VIEW3D)
 	
 	Window.DrawProgressBar (1.0, '')
+	Window.SetCursorPos(*orig_cursor)
+	Window.RedrawAll()
 	
 if __name__=='__main__':
 	main()