Exemplo n.º 1
0
	def BuildPlane (self, height, faces):
		#-------------------------------------------------------
		# Generate all four vectors
		ver1 = vt(-500, height, -200)
		ver2 = vt(1000, height, -200)
		ver3 = vt(1000, height, 800)
		ver4 = vt(-500, height, 800)


		#-------------------------------------------------------
		# Store corresponding Texel coordinates
		txs = []
		for i in range(4):
			txs.append(faces[0].facePoints[i])
		uvs = []
		for i in range(4):
			uvs.append(tx(txs[i][0], txs[i][1]))



		#-------------------------------------------------------
		poly = Polygon([ver1, ver2, ver3, ver4], uvs)
		polyList = [poly]
		return polyList
Exemplo n.º 2
0
	def BuildPrism (self, center, length, width, height, UVs):
		#-------------------------------------------------------
		# Define all 6 vertices
		cx = center[0]
		cy = center[1]
		cz = center[2]
		ver1 = vt(cx-length/2, cy, cz+width/2)
		ver2 = vt(cx+length/2, cy, cz+width/2)
		ver3 = vt(cx+length/2, cy, cz-width/2)
		ver4 = vt(cx-length/2, cy, cz-width/2)
		ver5 = vt(cx, cy+height, cz+width/2)
		ver6 = vt(cx, cy+height, cz-width/2)


		#-------------------------------------------------------
		# Store corresponding Texel coordinates
		exist_front = False
		exist_left = False
		exist_right = False
		uv_front = []
		uv_back = []
		uv_left = []
		uv_right = []
		#uv_btm = []
		# Assign uvs from input
		for i in UVs:
			# Left surface
			if(i.faceOrientation=="Left"):
				exist_left = True
				for j in i.facePoints:
					uv_left.append(tx(j[0], j[1]))
			# Right surface
			elif(i.faceOrientation=="Right"):
				exist_right = True
				for j in i.facePoints:
					uv_right.append(tx(j[0], j[1]))
			# Front surface
			elif(i.faceOrientation=="Front"):
				exist_front = True
				for j in i.facePoints:
					uv_front.append(tx(j[0], j[1]))
			else:
				print "Face denifition got errors!! Nor left, right, front or Upper."
		# Invent surfaces not provided in inputs
		# Invent front surface if not exist
		if(exist_front == False):
			if(exist_left): # Use left surface as FRONT also
				for i in range(3):
					uv_front.append(uv_left[i])
				exist_front = True
			else:
				if(exist_right): # use right surface as FRONT also
					for i in range(3):
						uv_front.append(uv_right[i])
					exist_front = True
				else:
					print "Front surface wanna copy from left or right, BUT Fail !!!"
		# Invent left surface if not exist. (front surface already exist here)
		if(exist_left == False):
			if(exist_right): # use right surface as LEFT also
				for i in uv_right:
					uv_left.append(i)
				exist_left = True
			else :
				if(exist_front): # use front surface as LEFT also
					for i in range(2):
						uv_left.append(uv_front[i]) # only contains two texels
					uv_left.append(tx(uv_front[2].u, uv_front[2].v)) # add the third texel
					uv_left.append(uv_front[2]) # add the fourth texel
					uv_left[2].u = uv_front[2].u+uv_front[1].u-uv_front[0].u
					uv_left[2].v = uv_front[2].v+uv_front[1].v-uv_front[0].v
					exist_left = True
				else:
					print "Left surface wanna copy from right or front, BUT Fail !!!"
		# Invent right surface is not exist. (front, left already exist here)
		if(exist_right == False):
			if(exist_left): # use right surface as RIGHT also
				for i in uv_left:
					uv_right.append(i)
				exist_right = True
			else :
				if(exist_front): # use front surface as RIGHT also
					for i in range(2):
						uv_left.append(uv_front[i]) # only contains two texels
					uv_left.append(tx(uv_front[2].u, uv_front[2].v)) # add the third texel
					uv_left.append(uv_front[2]) # add the fourth texel
					uv_left[2].u = uv_front[2].u+uv_front[1].u-uv_front[0].u
					uv_left[2].v = uv_front[2].v+uv_front[1].v-uv_front[0].v
					exist_right = True
				else:
					print "Right surface wanna copy from left or front, BUT Fail !!!"
		# # Invent btm surface
		# if(exist_left):
		# 	for i in uv_left:
		# 		uv_btm.append(i)
		# else:
		# 	print "Bottom surface wanna copy from left, BUT Fail !!!"
		# # Invent back surface
		if(exist_front):
			for i in uv_front:
				uv_back.append(i)
		else:
			print "Back surface wanna copy from front, BUT Fail !!!"


		#-------------------------------------------------------
		# Generate polygons
		#poly1 = Polygon([ver1, ver2, ver3, ver4], uv_btm)
		poly_back = Polygon([ver1, ver2, ver5], uv_back)
		poly_right = Polygon([ver2, ver3, ver6, ver5], uv_right)
		poly_front = Polygon([ver3, ver4, ver6], uv_front)
		poly_left = Polygon([ver4, ver1, ver5, ver6], uv_left)
		

		#-------------------------------------------------------
		# Return list of polygons
		polyList = [poly_back,poly_left, poly_right, poly_front]
		return polyList
Exemplo n.º 3
0
	def BuildFrustum (self, center, btm_len, btm_wid, top_len, top_wid, height, UVs):
		#-------------------------------------------------------
		# Generate all vertices
		cx = center[0]
		cy = center[1]
		cz = center[2]
		ver1 = vt(cx-btm_len/2, cy, cz+btm_wid/2)
		ver2 = vt(cx+btm_len/2, cy, cz+btm_wid/2)
		ver3 = vt(cx+btm_len/2, cy, cz-btm_wid/2)
		ver4 = vt(cx-btm_len/2, cy, cz-btm_wid/2)
		ver5 = vt(cx-top_len/2, cy+height, cz+top_wid/2)
		ver6 = vt(cx+top_len/2, cy+height, cz+top_wid/2)
		ver7 = vt(cx+top_len/2, cy+height, cz-top_wid/2)
		ver8 = vt(cx-top_len/2, cy+height, cz-top_wid/2)

		
		#-------------------------------------------------------
		# Store corresponding Texel coordinates
		exist_front = False
		exist_left = False
		exist_right = False
		exist_top = False
		uv_front = []
		uv_back = []
		uv_left = []
		uv_right = []
		uv_top = [] 
		#uv_btm = []
		# Assign uvs from input
		for i in UVs:
			# Left surface
			if(i.faceOrientation=="Left"):
				exist_left = True
				for j in i.facePoints:
					uv_left.append(tx(j[0], j[1]))
			# Right surface
			elif(i.faceOrientation=="Right"):
				exist_right = True
				for j in i.facePoints:
					uv_right.append(tx(j[0], j[1]))
			# Front surface
			elif(i.faceOrientation=="Front"):
				exist_front = True
				for j in i.facePoints:
					uv_front.append(tx(j[0], j[1]))
			# Upper surface
			elif(i.faceOrientation=="Upper"):
				exist_top = True
				for j in i.facePoints:
					uv_top.append(tx(j[0], j[1]))
			else:
				print "Face denifition got errors!! Nor left, right, front or Upper."
		# Invent surfaces not provided in inputs
		# Invent front surface if not exist
		if(exist_front == False):
			if(exist_left): # Use left surface as FRONT also
				for i in uv_left:
					uv_front.append(i)
				exist_front = True
			else:
				if(exist_right): # use right surface as FRONT also
					for i in uv_right:
						uv_front.append(i)
					exist_front = True
				else:
					print "Front surface wanna copy from left or right, BUT Fail !!!"
		# Invent left surface if not exist. (front surface already exist here)
		if(exist_left == False):
			if(exist_right): # use right surface as LEFT also
				for i in uv_right:
					uv_left.append(i)
				exist_left = True
			else :
				if(exist_front): # use front surface as LEFT also
					for i in uv_front:
						uv_left.append(i)
					exist_left = True
				else:
					print "Left surface wanna copy from right or front, BUT Fail !!!"
		# Invent right surface is not exist. (front, left already exist here)
		if(exist_right == False):
			if(exist_left): # use right surface as RIGHT also
				for i in uv_left:
					uv_right.append(i)
				exist_right = True
			else :
				if(exist_front): # use front surface as RIGHT also
					for i in uv_front:
						uv_right.append(i)
					exist_right = True
				else:
					print "Right surface wanna copy from left or front, BUT Fail !!!"
		# Invent top surface 
		if(exist_top == False):
			if(exist_front):
				for i in uv_front:
					uv_top.append(i)
				exist_top = True
			else:
				print "Top surface wanna copy from front, BUT Fail !!!"
		# # Invent btm surface
		# if(exist_top):
		# 	for i in uv_top:
		# 		uv_btm.append(i)
		# else:
		# 	print "Bottom surface wanna copy from top, BUT Fail !!!"
		# # Invent back surface
		if(exist_front):
			for i in uv_front:
				uv_back.append(i)
		else:
			print "Back surface wanna copy from front, BUT Fail !!!"


		#-------------------------------------------------------
		# Generate polygons
		#poly1 = Polygon([ver1, ver2, ver3, ver4], uv_btm)
		poly_top = Polygon([ver5, ver6, ver7, ver8], uv_top)
		poly_back = Polygon([ver1, ver2, ver6, ver5], uv_back)
		poly_right = Polygon([ver2, ver3, ver7, ver6], uv_right)
		poly_front = Polygon([ver3, ver4, ver8, ver7], uv_front)
		poly_left = Polygon([ver4, ver1, ver5, ver8], uv_left)
		

		#-------------------------------------------------------
		# Return list of polygons
		polyList = [poly_back, poly_left, poly_right, poly_top, poly_front]
		return polyList
Exemplo n.º 4
0
	def BuildCylinder (self, center, radius, height, UVs):
		#-------------------------------------------------------
		cx = center[0]
		cy = center[1]
		cz = center[2]
		center = vt(cx, cy, cz)
		# Generate vertices on bottom surface
		btm_v = [None] * 16
		# Compute btm_v0, 4, 8, 12
		btm_v[0] = vt(cx+radius, cy, cz)
		btm_v[8] = vt(cx-radius, cy, cz)
		btm_v[4] = vt(cx, cy, cz+radius)
		btm_v[12] = vt(cx, cy, cz-radius)
		# Compute btm_v2, 6, 10, 14
		for i in [0, 4]:
			btm_v[i+2] = self.ComputeMidVector(btm_v[i], btm_v[i+4], center, radius)
			btm_v[i+2+8] = vt.sum(center, vt.diff(center, btm_v[i+2]))
		# Compute vtm_1,3,5,7 and 9,11,13,15
		for i in [0, 2, 4, 6]:
			btm_v[i+1] = self.ComputeMidVector(btm_v[i], btm_v[i+2], center, radius)
			btm_v[i+1+8] = vt.sum(center, vt.diff(center, btm_v[i+1]))

		# Generate vertices on top surface
		top_v = []
		for i in range(16):
			temp = vt(btm_v[i].x, btm_v[i].y+height, btm_v[i].z)
			top_v.append(temp)

		# Generate all vertices from given
		# Vertex on one circle surface
		'''ver1 = vt.equal(center)
		ver2 = vt.equal(v2)
		ver3 = vt.sum(v1, vt.diff(v1, v2))
		# Generate third&fourth vertices on verticle line
		temp = vt.cross(vt.diff(v2, v1), vt.diff(v3, v1))
		temp = vt.normalize(temp)
		temp = vt.scale(temp, radius)
		ver4 = vt.sum(v1, temp)
		ver5 = vt.sum(v1, vt.diff(ver1, ver4))
		ver6 = self.ComputeMidVector(ver2, ver5, ver1, radius)
		ver7 = vt.sum(v1, vt.diff(ver1, ver6))
		ver8 = self.ComputeMidVector(ver2, ver4, ver1, radius)
		ver9 = vt.sum(v1, vt.diff(ver1, ver6))'''


		#-------------------------------------------------------
		# Store corresponding Texel coordinates
		print "----------------------------"
		tx1 = UVs[0].facePoints[0]
		#print tx1
		tx2 = UVs[0].facePoints[1]
		#print tx2
		tx3 = UVs[0].facePoints[2]
		#print tx3
		tx4 = UVs[0].facePoints[3]
		#print tx4
		dis_btm = [tx2[0]-tx1[0], tx2[1]-tx1[1]]
		dis_top = [tx3[0]-tx4[0], tx3[1]-tx4[1]]
		dis_left = [tx4[0]-tx1[0], tx4[1]-tx1[1]]
		dis_right = [tx3[0]-tx2[0], tx3[1]-tx2[1]]
		#print dis_btm
		#print dis_top
		tx_btm = [] # store all nice texels on bottom edge 
		tx_top = [] # store all nice texels on top edge 
		tx_left = [] # store all five texels on left edge
		tx_right = [] # store all five texels on right edge
		uv_front = []
		uv_back = []
		uv_top = []
		uv_btm = []
		# Divide two texels into 9 texels on top and btm edge
		for i in range(9):
			tx_btm.append(tx(tx1[0]+i*dis_btm[0]/8.0, tx1[1]+i*dis_btm[1]/8.0))
			tx_top.append(tx(tx4[0]+i*dis_top[0]/8.0, tx4[1]+i*dis_top[1]/8.0))
		# Divde two texels into 5 texels on left and right edge
		for i in range(4):
			tx_right.append(tx(tx2[0]+i*dis_right[0]/4.0, tx2[1]+i*dis_right[1]/4.0))
			tx_left.append(tx(tx4[0]-i*dis_left[0]/4.0, tx4[1]-i*dis_left[1]/4.0))

		# Generate the 16 side surfaces based on 18 texels
		for i in range(8):
			uv_front.append([tx_btm[i], tx_btm[i+1], tx_top[i+1], tx_top[i]])
			uv_back.append([tx_btm[i], tx_btm[i+1], tx_top[i+1], tx_top[i]])
		# Generate the top and btm surface's texels
		for i in range(4):
			uv_btm.append(tx_btm[2*i])
			uv_top.append(tx_btm[2*i])
		for i in range(4):
			uv_btm.append(tx_right[i])
			uv_top.append(tx_right[i])
		for i in range(4):
			uv_btm.append(tx_top[2*i])
			uv_top.append(tx_top[8 - 2*i])
		for i in range(4):
			uv_btm.append(tx_left[i])
			uv_top.append(tx_left[i])


		
		#-------------------------------------------------------
		# Generate polygons
		polyList = []
		temp_top = []
		temp_btm = []
		# The two circle polygon on top and bot
		for i in range(16):
			temp_top.append(top_v[i])
			temp_btm.append(btm_v[i])
		#polyList.append(Polygon(temp_btm, uv_btm))
		polyList.append(Polygon(temp_top, uv_top))
		# The 16 polygons on side
		for i in range(16):
			if(i < 8):
				tempPolygon = Polygon([btm_v[i], btm_v[(i+1)%16], top_v[(i+1)%16], top_v[i]], uv_front[i])
			else:
				tempPolygon = Polygon([btm_v[i], btm_v[(i+1)%16], top_v[(i+1)%16], top_v[i]], uv_back[i-8])
			polyList.append(tempPolygon)
		

		#-------------------------------------------------------
		# Return list of polygons
		return polyList