Newer
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Bastien Montagne
committed
# ***** 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
#
# #**** END GPL LICENSE BLOCK #****
import subprocess
import os
import sys
import time
import re
import platform#
import subprocess#
from bpy.types import(Operator)#all added for render preview
##############################SF###########################
##############find image texture
ext = {
'JPG': "jpeg",
'JPEG': "jpeg",
'GIF': "gif",
'TGA': "tga",
'IFF': "iff",
'PPM': "ppm",
'PNG': "png",
'SYS': "sys",
'TIFF': "tiff",
'TIF': "tiff",
'EXR': "exr",
'HDR': "hdr",
}.get(os.path.splitext(imgF)[-1].upper(), "")
print(" WARNING: texture image format not supported ")
image_map = ""
if ts.mapping == 'FLAT':
image_map = "map_type 0 "
elif ts.mapping == 'SPHERE':
image_map = "map_type 1 "
elif ts.mapping == 'TUBE':
image_map = "map_type 2 "
## map_type 3 and 4 in development (?)
## for POV-Ray, currently they just seem to default back to Flat (type 0)
#elif ts.mapping=="?":
#elif ts.mapping=="?":
if ts.texture.use_interpolation:
image_map += " interpolate 2 "
if ts.texture.extension == 'CLIP':
image_map += " once "
#image_map += "}"
#if ts.mapping=='CUBE':
# image_map+= "warp { cubic } rotate <-90,0,180>"
# no direct cube type mapping. Though this should work in POV 3.7
# it doesn't give that good results(best suited to environment maps?)
# print(" No texture image found ")
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def imgMapTransforms(ts):
# XXX TODO: unchecked textures give error of variable referenced before assignment XXX
# POV-Ray "scale" is not a number of repetitions factor, but ,its
# inverse, a standard scale factor.
# 0.5 Offset is needed relatively to scale because center of the
# scale is 0.5,0.5 in blender and 0,0 in POV
image_map_transforms = ""
image_map_transforms = ("scale <%.4g,%.4g,%.4g> translate <%.4g,%.4g,%.4g>" % \
( 1.0 / ts.scale.x,
1.0 / ts.scale.y,
1.0 / ts.scale.z,
0.5-(0.5/ts.scale.x) - (ts.offset.x),
0.5-(0.5/ts.scale.y) - (ts.offset.y),
ts.offset.z))
# image_map_transforms = (" translate <-0.5,-0.5,0.0> scale <%.4g,%.4g,%.4g> translate <%.4g,%.4g,%.4g>" % \
# ( 1.0 / ts.scale.x,
# 1.0 / ts.scale.y,
# 1.0 / ts.scale.z,
# (0.5 / ts.scale.x) + ts.offset.x,
# (0.5 / ts.scale.y) + ts.offset.y,
# ts.offset.z))
# image_map_transforms = ("translate <-0.5,-0.5,0> scale <-1,-1,1> * <%.4g,%.4g,%.4g> translate <0.5,0.5,0> + <%.4g,%.4g,%.4g>" % \
# (1.0 / ts.scale.x,
# 1.0 / ts.scale.y,
# 1.0 / ts.scale.z,
# ts.offset.x,
# ts.offset.y,
# ts.offset.z))
return image_map_transforms
# texture_coords refers to the mapping of world textures:
if wts.texture_coords == 'VIEW' or wts.texture_coords == 'GLOBAL':
elif wts.texture_coords == 'ANGMAP':
image_mapBG = " map_type 1 "
elif wts.texture_coords == 'TUBE':
image_mapBG = " map_type 2 "
if wts.texture.use_interpolation:
image_mapBG += " interpolate 2 "
if wts.texture.extension == 'CLIP':
image_mapBG += " once "
#image_mapBG += "}"
#if wts.mapping == 'CUBE':
# image_mapBG += "warp { cubic } rotate <-90,0,180>"
# no direct cube type mapping. Though this should work in POV 3.7
# it doesn't give that good results(best suited to environment maps?)
#if image_mapBG == "":
# print(" No background texture image found ")
return bpy.path.abspath(image.filepath, library=image.library)
# end find image texture
# -----------------------------------------------------------------------------
def string_strip_hyphen(name):
return name.replace("-", "")
def safety(name, Level):
# safety string name material
#
# Level=1 is for texture with No specular nor Mirror reflection
# Level=2 is for texture with translation of spec and mir levels
# for when no map influences them
# Level=3 is for texture with Maximum Spec and Mirror
Maurice Raybaud
committed
prefix = ""
return prefix + name + "0" # used for 0 of specular map
return prefix + name + "1" # used for 1 of specular map
Maurice Raybaud
committed
##############end safety string name material
##############################EndSF###########################
def is_renderable(ob):
return (ob.hide_render==False)
def renderable_objects():
return [ob for ob in bpy.data.objects if is_renderable(ob)]
Maurice Raybaud
committed
tabLevel = 0
unpacked_images=[]
workDir=os.path.dirname(__file__)
previewDir=os.path.join(workDir, "preview")
## Make sure Preview directory exists and is empty
if not os.path.isdir(previewDir):
os.mkdir(previewDir)
smokePath = os.path.join(previewDir, "smoke.df3")
def exportPattern(texture):
tex=texture
pat = tex.pov
PATname = "PAT_%s"%string_strip_hyphen(bpy.path.clean_name(tex.name))
mappingDif = ("translate <%.4g,%.4g,%.4g> scale <%.4g,%.4g,%.4g>" % \
(pat.tex_mov_x, pat.tex_mov_y, pat.tex_mov_z,
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1.0 / pat.tex_scale_x, 1.0 / pat.tex_scale_y, 1.0 / pat.tex_scale_z))
texStrg=""
def exportColorRamp(texture):
tex=texture
pat = tex.pov
colRampStrg="color_map {\n"
numColor=0
for el in tex.color_ramp.elements:
numColor+=1
pos = el.position
col=el.color
colR,colG,colB,colA = col[0],col[1],col[2],1-col[3]
if pat.tex_pattern_type not in {'checker', 'hexagon', 'square', 'triangular', 'brick'} :
colRampStrg+="[%.4g color rgbf<%.4g,%.4g,%.4g,%.4g>] \n"%(pos,colR,colG,colB,colA)
if pat.tex_pattern_type in {'brick','checker'} and numColor < 3:
colRampStrg+="color rgbf<%.4g,%.4g,%.4g,%.4g> \n"%(colR,colG,colB,colA)
if pat.tex_pattern_type == 'hexagon' and numColor < 4 :
colRampStrg+="color rgbf<%.4g,%.4g,%.4g,%.4g> \n"%(colR,colG,colB,colA)
if pat.tex_pattern_type == 'square' and numColor < 5 :
colRampStrg+="color rgbf<%.4g,%.4g,%.4g,%.4g> \n"%(colR,colG,colB,colA)
if pat.tex_pattern_type == 'triangular' and numColor < 7 :
colRampStrg+="color rgbf<%.4g,%.4g,%.4g,%.4g> \n"%(colR,colG,colB,colA)
colRampStrg+="} \n"
#end color map
return colRampStrg
#much work to be done here only defaults translated for now:
#pov noise_generator 3 means perlin noise
if pat.tex_pattern_type == 'emulator':
texStrg+="pigment {\n"
####################### EMULATE BLENDER VORONOI TEXTURE ####################
if tex.type == 'VORONOI':
texStrg+="crackle\n"
texStrg+=" offset %.4g\n"%tex.nabla
texStrg+=" form <%.4g,%.4g,%.4g>\n"%(tex.weight_1, tex.weight_2, tex.weight_3)
if tex.distance_metric == 'DISTANCE':
texStrg+=" metric 2.5\n"
if tex.distance_metric == 'DISTANCE_SQUARED':
texStrg+=" metric 2.5\n"
texStrg+=" poly_wave 2\n"
if tex.distance_metric == 'MINKOVSKY':
texStrg+=" metric %s\n"%tex.minkovsky_exponent
if tex.distance_metric == 'MINKOVSKY_FOUR':
texStrg+=" metric 4\n"
if tex.distance_metric == 'MINKOVSKY_HALF':
texStrg+=" metric 0.5\n"
if tex.distance_metric == 'CHEBYCHEV':
texStrg+=" metric 10\n"
if tex.distance_metric == 'MANHATTAN':
texStrg+=" metric 1\n"
if tex.color_mode == 'POSITION':
texStrg+="solid\n"
texStrg+="scale 0.25\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<0,0,0,1>]\n"
texStrg+="[1 color rgbt<1,1,1,0>]\n"
texStrg+="}\n"
####################### EMULATE BLENDER CLOUDS TEXTURE ####################
if tex.type == 'CLOUDS':
if tex.noise_type == 'SOFT_NOISE':
texStrg+="wrinkles\n"
texStrg+="scale 0.25\n"
else:
texStrg+="granite\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<0,0,0,1>]\n"
texStrg+="[1 color rgbt<1,1,1,0>]\n"
texStrg+="}\n"
####################### EMULATE BLENDER WOOD TEXTURE ####################
if tex.type == 'WOOD':
if tex.wood_type == 'RINGS':
texStrg+="wood\n"
texStrg+="scale 0.25\n"
if tex.wood_type == 'RINGNOISE':
texStrg+="wood\n"
texStrg+="scale 0.25\n"
texStrg+="turbulence %.4g\n"%(tex.turbulence/100)
if tex.wood_type == 'BANDS':
texStrg+="marble\n"
texStrg+="scale 0.25\n"
texStrg+="rotate <45,-45,45>\n"
if tex.wood_type == 'BANDNOISE':
texStrg+="marble\n"
texStrg+="scale 0.25\n"
texStrg+="rotate <45,-45,45>\n"
texStrg+="turbulence %.4g\n"%(tex.turbulence/10)
if tex.noise_basis_2 == 'SIN':
texStrg+="sine_wave\n"
if tex.noise_basis_2 == 'TRI':
texStrg+="triangle_wave\n"
if tex.noise_basis_2 == 'SAW':
texStrg+="ramp_wave\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<0,0,0,0>]\n"
texStrg+="[1 color rgbt<1,1,1,0>]\n"
texStrg+="}\n"
####################### EMULATE BLENDER STUCCI TEXTURE ####################
if tex.type == 'STUCCI':
texStrg+="bozo\n"
texStrg+="scale 0.25\n"
if tex.noise_type == 'HARD_NOISE':
texStrg+="triangle_wave\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbf<1,1,1,0>]\n"
texStrg+="[1 color rgbt<0,0,0,1>]\n"
texStrg+="}\n"
else:
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbf<0,0,0,1>]\n"
texStrg+="[1 color rgbt<1,1,1,0>]\n"
texStrg+="}\n"
####################### EMULATE BLENDER MAGIC TEXTURE ####################
if tex.type == 'MAGIC':
texStrg+="leopard\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<1,1,1,0.5>]\n"
texStrg+="[0.25 color rgbf<0,1,0,0.75>]\n"
texStrg+="[0.5 color rgbf<0,0,1,0.75>]\n"
texStrg+="[0.75 color rgbf<1,0,1,0.75>]\n"
texStrg+="[1 color rgbf<0,1,0,0.75>]\n"
texStrg+="}\n"
texStrg+="scale 0.1\n"
####################### EMULATE BLENDER MARBLE TEXTURE ####################
if tex.type == 'MARBLE':
texStrg+="marble\n"
texStrg+="turbulence 0.5\n"
texStrg+="noise_generator 3\n"
texStrg+="scale 0.75\n"
texStrg+="rotate <45,-45,45>\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
if tex.marble_type == 'SOFT':
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<0,0,0,0>]\n"
texStrg+="[0.05 color rgbt<0,0,0,0>]\n"
texStrg+="[1 color rgbt<0.9,0.9,0.9,0>]\n"
texStrg+="}\n"
elif tex.marble_type == 'SHARP':
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<0,0,0,0>]\n"
texStrg+="[0.025 color rgbt<0,0,0,0>]\n"
texStrg+="[1 color rgbt<0.9,0.9,0.9,0>]\n"
texStrg+="}\n"
else:
texStrg+="[0 color rgbt<0,0,0,0>]\n"
texStrg+="[1 color rgbt<1,1,1,0>]\n"
texStrg+="}\n"
if tex.noise_basis_2 == 'SIN':
texStrg+="sine_wave\n"
if tex.noise_basis_2 == 'TRI':
texStrg+="triangle_wave\n"
if tex.noise_basis_2 == 'SAW':
texStrg+="ramp_wave\n"
####################### EMULATE BLENDER BLEND TEXTURE ####################
if tex.type == 'BLEND':
if tex.progression=='RADIAL':
texStrg+="radial\n"
if tex.use_flip_axis=='HORIZONTAL':
texStrg+="rotate x*90\n"
else:
texStrg+="rotate <-90,0,90>\n"
texStrg+="ramp_wave\n"
elif tex.progression=='SPHERICAL':
texStrg+="spherical\n"
texStrg+="scale 3\n"
texStrg+="poly_wave 1\n"
elif tex.progression=='QUADRATIC_SPHERE':
texStrg+="spherical\n"
texStrg+="scale 3\n"
texStrg+=" poly_wave 2\n"
elif tex.progression=='DIAGONAL':
texStrg+="gradient <1,1,0>\n"
texStrg+="scale 3\n"
elif tex.use_flip_axis=='HORIZONTAL':
texStrg+="gradient x\n"
texStrg+="scale 2.01\n"
elif tex.use_flip_axis=='VERTICAL':
texStrg+="gradient y\n"
texStrg+="scale 2.01\n"
#texStrg+="ramp_wave\n"
#texStrg+="frequency 0.5\n"
texStrg+="phase 0.5\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<1,1,1,0>]\n"
texStrg+="[1 color rgbf<0,0,0,1>]\n"
texStrg+="}\n"
if tex.progression == 'LINEAR':
texStrg+=" poly_wave 1\n"
if tex.progression == 'QUADRATIC':
texStrg+=" poly_wave 2\n"
if tex.progression == 'EASING':
texStrg+=" poly_wave 1.5\n"
####################### EMULATE BLENDER MUSGRAVE TEXTURE ####################
# if tex.type == 'MUSGRAVE':
# texStrg+="function{ f_ridged_mf( x, y, 0, 1, 2, 9, -0.5, 3,3 )*0.5}\n"
# texStrg+="color_map {\n"
# texStrg+="[0 color rgbf<0,0,0,1>]\n"
# texStrg+="[1 color rgbf<1,1,1,0>]\n"
# texStrg+="}\n"
# simplified for now:
if tex.type == 'MUSGRAVE':
texStrg+="bozo scale 0.25 \n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {[0.5 color rgbf<0,0,0,1>][1 color rgbt<1,1,1,0>]}ramp_wave \n"
####################### EMULATE BLENDER DISTORTED NOISE TEXTURE ####################
if tex.type == 'DISTORTED_NOISE':
texStrg+="average\n"
texStrg+=" pigment_map {\n"
texStrg+=" [1 bozo scale 0.25 turbulence %.4g\n" %tex.distortion
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<1,1,1,0>]\n"
texStrg+="[1 color rgbf<0,0,0,1>]\n"
texStrg+="}\n"
texStrg+="]\n"
if tex.noise_distortion == 'CELL_NOISE':
texStrg+=" [1 cells scale 0.1\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<1,1,1,0>]\n"
texStrg+="[1 color rgbf<0,0,0,1>]\n"
texStrg+="}\n"
texStrg+="]\n"
if tex.noise_distortion=='VORONOI_CRACKLE':
texStrg+=" [1 crackle scale 0.25\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<1,1,1,0>]\n"
texStrg+="[1 color rgbf<0,0,0,1>]\n"
texStrg+="}\n"
texStrg+="]\n"
if tex.noise_distortion in ['VORONOI_F1','VORONOI_F2','VORONOI_F3','VORONOI_F4','VORONOI_F2_F1']:
texStrg+=" [1 crackle metric 2.5 scale 0.25 turbulence %.4g\n" %(tex.distortion/2)
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<1,1,1,0>]\n"
texStrg+="[1 color rgbf<0,0,0,1>]\n"
texStrg+="}\n"
texStrg+="]\n"
else:
texStrg+=" [1 wrinkles scale 0.25\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0 color rgbt<1,1,1,0>]\n"
texStrg+="[1 color rgbf<0,0,0,1>]\n"
texStrg+="}\n"
texStrg+="]\n"
texStrg+=" }\n"
####################### EMULATE BLENDER NOISE TEXTURE ####################
if tex.type == 'NOISE':
texStrg+="cells\n"
texStrg+="turbulence 3\n"
texStrg+="omega 3\n"
if tex.use_color_ramp == True:
texStrg+=exportColorRamp(tex)
else:
texStrg+="color_map {\n"
texStrg+="[0.75 color rgb<0,0,0,>]\n"
texStrg+="[1 color rgb<1,1,1,>]\n"
texStrg+="}\n"
####################### IGNORE OTHER BLENDER TEXTURE ####################
else: #non translated textures
pass
texStrg+="}\n\n"
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texStrg+="#declare f%s=\n"%PATname
texStrg+="function{pigment{%s}}\n"%PATname
texStrg+="\n"
else:
texStrg+="pigment {\n"
texStrg+="%s\n"%pat.tex_pattern_type
if pat.tex_pattern_type == 'agate':
texStrg+="agate_turb %.4g\n"%pat.modifier_turbulence
if pat.tex_pattern_type in {'spiral1', 'spiral2', 'tiling'}:
texStrg+="%s\n"%pat.modifier_numbers
if pat.tex_pattern_type == 'quilted':
texStrg+="control0 %s control1 %s\n"%(pat.modifier_control0, pat.modifier_control1)
if pat.tex_pattern_type == 'mandel':
texStrg+="%s exponent %s \n"%(pat.f_iter, pat.f_exponent)
if pat.tex_pattern_type == 'julia':
texStrg+="<%.4g, %.4g> %s exponent %s \n"%(pat.julia_complex_1, pat.julia_complex_2, pat.f_iter, pat.f_exponent)
if pat.tex_pattern_type == 'magnet' and pat.magnet_style == 'mandel':
texStrg+="%s mandel %s \n"%(pat.magnet_type, pat.f_iter)
if pat.tex_pattern_type == 'magnet' and pat.magnet_style == 'julia':
texStrg+="%s julia <%.4g, %.4g> %s\n"%(pat.magnet_type, pat.julia_complex_1, pat.julia_complex_2, pat.f_iter)
if pat.tex_pattern_type in {'mandel', 'julia', 'magnet'}:
texStrg+="interior %s, %.4g\n"%(pat.f_ior, pat.f_ior_fac)
texStrg+="exterior %s, %.4g\n"%(pat.f_eor, pat.f_eor_fac)
if pat.tex_pattern_type == 'gradient':
texStrg+="<%s, %s, %s> \n"%(pat.grad_orient_x, pat.grad_orient_y, pat.grad_orient_z)
if pat.tex_pattern_type == 'pavement':
numTiles=pat.pave_tiles
numPattern=1
if pat.pave_sides == '4' and pat.pave_tiles == 3:
numPattern = pat.pave_pat_2
if pat.pave_sides == '6' and pat.pave_tiles == 3:
numPattern = pat.pave_pat_3
if pat.pave_sides == '3' and pat.pave_tiles == 4:
numPattern = pat.pave_pat_3
if pat.pave_sides == '3' and pat.pave_tiles == 5:
numPattern = pat.pave_pat_4
if pat.pave_sides == '4' and pat.pave_tiles == 4:
numPattern = pat.pave_pat_5
if pat.pave_sides == '6' and pat.pave_tiles == 4:
numPattern = pat.pave_pat_7
if pat.pave_sides == '4' and pat.pave_tiles == 5:
numPattern = pat.pave_pat_12
if pat.pave_sides == '3' and pat.pave_tiles == 6:
numPattern = pat.pave_pat_12
if pat.pave_sides == '6' and pat.pave_tiles == 5:
numPattern = pat.pave_pat_22
if pat.pave_sides == '4' and pat.pave_tiles == 6:
numPattern = pat.pave_pat_35
if pat.pave_sides == '6' and pat.pave_tiles == 6:
numTiles = 5
texStrg+="number_of_sides %s number_of_tiles %s pattern %s form %s \n"%(pat.pave_sides, numTiles, numPattern, pat.pave_form)
################ functions #####################################################################################################
if pat.tex_pattern_type == 'function':
texStrg+="{ %s"%pat.func_list
texStrg+="(x"
if pat.func_plus_x != "NONE":
if pat.func_plus_x =='increase':
texStrg+="*"
if pat.func_plus_x =='plus':
texStrg+="+"
texStrg+="%.4g"%pat.func_x
texStrg+=",y"
if pat.func_plus_y != "NONE":
if pat.func_plus_y =='increase':
texStrg+="*"
if pat.func_plus_y =='plus':
texStrg+="+"
texStrg+="%.4g"%pat.func_y
texStrg+=",z"
if pat.func_plus_z != "NONE":
if pat.func_plus_z =='increase':
texStrg+="*"
if pat.func_plus_z =='plus':
texStrg+="+"
texStrg+="%.4g"%pat.func_z
sort = -1
if pat.func_list in {"f_comma","f_crossed_trough","f_cubic_saddle","f_cushion","f_devils_curve",
"f_enneper","f_glob","f_heart","f_hex_x","f_hex_y","f_hunt_surface",
"f_klein_bottle","f_kummer_surface_v1","f_lemniscate_of_gerono","f_mitre",
"f_nodal_cubic","f_noise_generator","f_odd","f_paraboloid","f_pillow",
"f_piriform","f_quantum","f_quartic_paraboloid","f_quartic_saddle",
"f_sphere","f_steiners_roman","f_torus_gumdrop","f_umbrella"}:
sort = 0
if pat.func_list in {"f_bicorn","f_bifolia","f_boy_surface","f_superellipsoid","f_torus"}:
sort = 1
if pat.func_list in {"f_ellipsoid","f_folium_surface","f_hyperbolic_torus",
"f_kampyle_of_eudoxus","f_parabolic_torus","f_quartic_cylinder","f_torus2"}:
sort = 2
if pat.func_list in {"f_blob2","f_cross_ellipsoids","f_flange_cover","f_isect_ellipsoids",
"f_kummer_surface_v2","f_ovals_of_cassini","f_rounded_box","f_spikes_2d","f_strophoid"}:
sort = 3
if pat.func_list in {"f_algbr_cyl1","f_algbr_cyl2","f_algbr_cyl3","f_algbr_cyl4","f_blob","f_mesh1","f_poly4","f_spikes"}:
sort = 4
if pat.func_list in {"f_devils_curve_2d","f_dupin_cyclid","f_folium_surface_2d","f_hetero_mf","f_kampyle_of_eudoxus_2d",
"f_lemniscate_of_gerono_2d","f_polytubes","f_ridge","f_ridged_mf","f_spiral","f_witch_of_agnesi"}:
sort = 5
if pat.func_list in {"f_helix1","f_helix2","f_piriform_2d","f_strophoid_2d"}:
sort = 6
if pat.func_list == "f_helical_torus":
sort = 7
if sort > -1:
texStrg+=",%.4g"%pat.func_P0
if sort > 0:
texStrg+=",%.4g"%pat.func_P1
if sort > 1:
texStrg+=",%.4g"%pat.func_P2
if sort > 2:
texStrg+=",%.4g"%pat.func_P3
if sort > 3:
texStrg+=",%.4g"%pat.func_P4
if sort > 4:
texStrg+=",%.4g"%pat.func_P5
if sort > 5:
texStrg+=",%.4g"%pat.func_P6
if sort > 6:
texStrg+=",%.4g"%pat.func_P7
texStrg+=",%.4g"%pat.func_P8
texStrg+=",%.4g"%pat.func_P9
texStrg+=")}\n"
############## end functions ###############################################################
if pat.tex_pattern_type not in {'checker', 'hexagon', 'square', 'triangular', 'brick'}:
texStrg+="color_map {\n"
numColor=0
if tex.use_color_ramp == True:
for el in tex.color_ramp.elements:
numColor+=1
pos = el.position
col=el.color
colR,colG,colB,colA = col[0],col[1],col[2],1-col[3]
if pat.tex_pattern_type not in {'checker', 'hexagon', 'square', 'triangular', 'brick'} :
texStrg+="[%.4g color rgbf<%.4g,%.4g,%.4g,%.4g>] \n"%(pos,colR,colG,colB,colA)
if pat.tex_pattern_type in {'brick','checker'} and numColor < 3:
texStrg+="color rgbf<%.4g,%.4g,%.4g,%.4g> \n"%(colR,colG,colB,colA)
if pat.tex_pattern_type == 'hexagon' and numColor < 4 :
texStrg+="color rgbf<%.4g,%.4g,%.4g,%.4g> \n"%(colR,colG,colB,colA)
if pat.tex_pattern_type == 'square' and numColor < 5 :
texStrg+="color rgbf<%.4g,%.4g,%.4g,%.4g> \n"%(colR,colG,colB,colA)
if pat.tex_pattern_type == 'triangular' and numColor < 7 :
texStrg+="color rgbf<%.4g,%.4g,%.4g,%.4g> \n"%(colR,colG,colB,colA)
else:
texStrg+="[0 color rgbf<0,0,0,1>]\n"
texStrg+="[1 color rgbf<1,1,1,0>]\n"
if pat.tex_pattern_type not in {'checker', 'hexagon', 'square', 'triangular', 'brick'} :
texStrg+="} \n"
if pat.tex_pattern_type == 'brick':
texStrg+="brick_size <%.4g, %.4g, %.4g> mortar %.4g \n"%(pat.brick_size_x, pat.brick_size_y, pat.brick_size_z, pat.brick_mortar)
texStrg+="%s \n"%mappingDif
texStrg+="rotate <%.4g,%.4g,%.4g> \n"%(pat.tex_rot_x, pat.tex_rot_y, pat.tex_rot_z)
texStrg+="turbulence <%.4g,%.4g,%.4g> \n"%(pat.warp_turbulence_x, pat.warp_turbulence_y, pat.warp_turbulence_z)
texStrg+="octaves %s \n"%pat.modifier_octaves
texStrg+="lambda %.4g \n"%pat.modifier_lambda
texStrg+="omega %.4g \n"%pat.modifier_omega
texStrg+="frequency %.4g \n"%pat.modifier_frequency
texStrg+="phase %.4g \n"%pat.modifier_phase
texStrg+="}\n\n"
texStrg+="#declare f%s=\n"%PATname
texStrg+="function{pigment{%s}}\n"%PATname
texStrg+="\n"
return(texStrg)
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import mathutils
# Only for testing
if not scene:
scene = bpy.data.scenes[0]
render = scene.render
world = scene.world
global_matrix = mathutils.Matrix.Rotation(-pi / 2.0, 4, 'X')
comments = scene.pov.comments_enable and not scene.pov.tempfiles_enable
linebreaksinlists = scene.pov.list_lf_enable and not scene.pov.tempfiles_enable
feature_set = bpy.context.user_preferences.addons[__package__].preferences.branch_feature_set_povray
using_uberpov = (feature_set=='uberpov')
pov_binary = PovrayRender._locate_binary()
if using_uberpov:
print("Unofficial UberPOV feature set chosen in preferences")
else:
print("Official POV-Ray 3.7 feature set chosen in preferences")
if 'uber' in pov_binary:
print("The name of the binary suggests you are probably rendering with Uber POV engine")
print("The name of the binary suggests you are probably rendering with standard POV engine")
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def setTab(tabtype, spaces):
TabStr = ""
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if tabtype == 'NONE':
TabStr = ""
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elif tabtype == 'TAB':
TabStr = "\t"
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elif tabtype == 'SPACE':
TabStr = spaces * " "
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return TabStr
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tab = setTab(scene.pov.indentation_character, scene.pov.indentation_spaces)
if not scene.pov.tempfiles_enable:
def tabWrite(str_o):
global tabLevel
brackets = str_o.count("{") - str_o.count("}") + str_o.count("[") - str_o.count("]")
if brackets < 0:
tabLevel = tabLevel + brackets
if tabLevel < 0:
print("Indentation Warning: tabLevel = %s" % tabLevel)
tabLevel = 0
if tabLevel >= 1:
file.write("%s" % tab * tabLevel)
file.write(str_o)
if brackets > 0:
tabLevel = tabLevel + brackets
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def uniqueName(name, nameSeq):
if name not in nameSeq:
return name
name_orig = name
i = 1
while name in nameSeq:
name = "%s_%.3d" % (name_orig, i)
tabWrite("matrix <%.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f>\n" %
(matrix[0][0], matrix[1][0], matrix[2][0],
matrix[0][1], matrix[1][1], matrix[2][1],
matrix[0][2], matrix[1][2], matrix[2][2],
matrix[0][3], matrix[1][3], matrix[2][3]))
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def MatrixAsPovString(matrix):
sMatrix = ("matrix <%.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f>\n" %
(matrix[0][0], matrix[1][0], matrix[2][0],
matrix[0][1], matrix[1][1], matrix[2][1],
matrix[0][2], matrix[1][2], matrix[2][2],
matrix[0][3], matrix[1][3], matrix[2][3]))
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return sMatrix
def writeObjectMaterial(material, ob):
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# DH - modified some variables to be function local, avoiding RNA write
# this should be checked to see if it is functionally correct
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# Commented out: always write IOR to be able to use it for SSS, Fresnel reflections...
#if material and material.transparency_method == 'RAYTRACE':
if material:
# But there can be only one!
if material.subsurface_scattering.use: # SSS IOR get highest priority
tabWrite("interior {\n")
tabWrite("ior %.6f\n" % material.subsurface_scattering.ior)
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# Then the raytrace IOR taken from raytrace transparency properties and used for
# reflections if IOR Mirror option is checked.
elif material.pov.mirror_use_IOR:
tabWrite("interior {\n")
tabWrite("ior %.6f\n" % material.raytrace_transparency.ior)
tabWrite("interior {\n")
tabWrite("ior %.6f\n" % material.raytrace_transparency.ior)
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pov_fake_caustics = False
pov_photons_refraction = False
pov_photons_reflection = False
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if material.pov.photons_reflection:
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if material.pov.refraction_type == "0":
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pov_fake_caustics = False
pov_photons_refraction = False
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elif material.pov.refraction_type == "1":
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pov_fake_caustics = True
pov_photons_refraction = False
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elif material.pov.refraction_type == "2":
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pov_fake_caustics = False
pov_photons_refraction = True
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# If only Raytrace transparency is set, its IOR will be used for refraction, but user
# can set up 'un-physical' fresnel reflections in raytrace mirror parameters.
# Last, if none of the above is specified, user can set up 'un-physical' fresnel
# reflections in raytrace mirror parameters. And pov IOR defaults to 1.
if material.pov.caustics_enable:
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if pov_fake_caustics:
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tabWrite("caustics %.3g\n" % material.pov.fake_caustics_power)
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if pov_photons_refraction:
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# Default of 1 means no dispersion
tabWrite("dispersion %.6f\n" % material.pov.photons_dispersion)
Maurice Raybaud
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tabWrite("dispersion_samples %.d\n" % material.pov.photons_dispersion_samples)
if material.use_transparency and material.transparency_method == 'RAYTRACE':
# fade_distance
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# In Blender this value has always been reversed compared to what tooltip says.
# 100.001 rather than 100 so that it does not get to 0
# which deactivates the feature in POV
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tabWrite("fade_distance %.3g\n" % \
(100.001 - material.raytrace_transparency.depth_max))
# fade_power
tabWrite("fade_power %.3g\n" % material.raytrace_transparency.falloff)
# fade_color
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tabWrite("fade_color <%.3g, %.3g, %.3g>\n" % material.pov.interior_fade_color[:])
# (variable) dispersion_samples (constant count for now)
tabWrite("}\n")
if material.pov.photons_reflection or material.pov.refraction_type=="2":
tabWrite("photons{")
Maurice Raybaud
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tabWrite("target %.3g\n" % ob.pov.spacing_multiplier)
if not ob.pov.collect_photons:
tabWrite("collect off\n")
if pov_photons_refraction:
tabWrite("refraction on\n")
if pov_photons_reflection:
tabWrite("reflection on\n")
tabWrite("}\n")
DEF_MAT_NAME = "" #or "Default"?
def writeMaterial(material):
# Assumes only called once on each material
if material:
name_orig = material.name
name = materialNames[name_orig] = uniqueName(bpy.path.clean_name(name_orig), materialNames)
name = name_orig = DEF_MAT_NAME
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committed
if material:
# If saturation(.s) is not zero, then color is not grey, and has a tint
colored_specular_found = (material.specular_color.s > 0.0)
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##################
# Several versions of the finish: Level conditions are variations for specular/Mirror
# texture channel map with alternative finish of 0 specular and no mirror reflection.
# Level=1 Means No specular nor Mirror reflection
# Level=2 Means translation of spec and mir levels for when no map influences them
# Level=3 Means Maximum Spec and Mirror
def povHasnoSpecularMaps(Level):
tabWrite("#declare %s = finish {" % safety(name, Level=1))
file.write(" //No specular nor Mirror reflection\n")
tabWrite("\n")
tabWrite("#declare %s = finish {" % safety(name, Level=2))
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file.write(" //translation of spec and mir levels for when no map " \
"influences them\n")
tabWrite("\n")
tabWrite("#declare %s = finish {" % safety(name, Level=3))
file.write(" //Maximum Spec and Mirror\n")
tabWrite("\n")
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# POV-Ray 3.7 now uses two diffuse values respectively for front and back shading
# (the back diffuse is like blender translucency)
frontDiffuse = material.diffuse_intensity
backDiffuse = material.translucency
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if material.pov.conserve_energy:
#Total should not go above one
if (frontDiffuse + backDiffuse) <= 1.0:
pass
elif frontDiffuse == backDiffuse:
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# Try to respect the user's 'intention' by comparing the two values but
# bringing the total back to one.
frontDiffuse = backDiffuse = 0.5
# Let the highest value stay the highest value.
elif frontDiffuse > backDiffuse:
# clamps the sum below 1
backDiffuse = min(backDiffuse, (1.0 - frontDiffuse))
# map hardness between 0.0 and 1.0
roughness = ((1.0 - ((material.specular_hardness - 1.0) / 510.0)))
## scale from 0.0 to 0.1
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# add a small value because 0.0 is invalid.
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################################Diffuse Shader######################################
# Not used for Full spec (Level=3) of the shader.
if material.diffuse_shader == 'OREN_NAYAR' and Level != 3:
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# Blender roughness is what is generally called oren nayar Sigma,
# and brilliance in POV-Ray.
tabWrite("brilliance %.3g\n" % (0.9 + material.roughness))
if material.diffuse_shader == 'TOON' and Level != 3:
tabWrite("brilliance %.3g\n" % (0.01 + material.diffuse_toon_smooth * 0.25))
Bastien Montagne
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# Lower diffuse and increase specular for toon effect seems to look better
# in POV-Ray.
frontDiffuse *= 0.5
if material.diffuse_shader == 'MINNAERT' and Level != 3:
#tabWrite("aoi %.3g\n" % material.darkness)
pass # let's keep things simple for now
if material.diffuse_shader == 'FRESNEL' and Level != 3:
#tabWrite("aoi %.3g\n" % material.diffuse_fresnel_factor)
pass # let's keep things simple for now
if material.diffuse_shader == 'LAMBERT' and Level != 3:
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# trying to best match lambert attenuation by that constant brilliance value
tabWrite("brilliance 1.8\n")
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###########################Specular Shader######################################
# No difference between phong and cook torrence in blender HaHa!
if (material.specular_shader == 'COOKTORR' or
material.specular_shader == 'PHONG'):
tabWrite("phong %.3g\n" % (material.specular_intensity))
tabWrite("phong_size %.3g\n" % (material.specular_hardness / 2 + 0.25))
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# POV-Ray 'specular' keyword corresponds to a Blinn model, without the ior.
elif material.specular_shader == 'BLINN':
# Use blender Blinn's IOR just as some factor for spec intensity
tabWrite("specular %.3g\n" % (material.specular_intensity *
(material.specular_ior / 4.0)))
tabWrite("roughness %.3g\n" % roughness)
#Could use brilliance 2(or varying around 2 depending on ior or factor) too.
elif material.specular_shader == 'TOON':
tabWrite("phong %.3g\n" % (material.specular_intensity * 2.0))
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# use extreme phong_size
tabWrite("phong_size %.3g\n" % (0.1 + material.specular_toon_smooth / 2.0))
elif material.specular_shader == 'WARDISO':
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# find best suited default constant for brilliance Use both phong and
# specular for some values.
tabWrite("specular %.3g\n" % (material.specular_intensity /
(material.specular_slope + 0.0005)))
# find best suited default constant for brilliance Use both phong and
# specular for some values.
tabWrite("roughness %.4g\n" % (0.0005 + material.specular_slope / 10.0))
# find best suited default constant for brilliance Use both phong and
# specular for some values.
tabWrite("brilliance %.4g\n" % (1.8 - material.specular_slope * 1.8))
####################################################################################
tabWrite("specular 0\n")
tabWrite("specular 1\n")
tabWrite("diffuse %.3g %.3g\n" % (frontDiffuse, backDiffuse))
tabWrite("ambient %.3g\n" % material.ambient)
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# POV-Ray blends the global value
#tabWrite("ambient rgb <%.3g, %.3g, %.3g>\n" % \
# tuple([c*material.ambient for c in world.ambient_color]))
tabWrite("emission %.3g\n" % material.emit) # New in POV-Ray 3.7
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#POV-Ray just ignores roughness if there's no specular keyword
#tabWrite("roughness %.3g\n" % roughness)
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if material.pov.conserve_energy:
# added for more realistic shading. Needs some checking to see if it
# really works. --Maurice.
tabWrite("conserve_energy\n")
Maurice Raybaud
committed
if colored_specular_found == True:
tabWrite("metallic\n")
# 'phong 70.0 '
if Level != 1:
if material.raytrace_mirror.use:
raytrace_mirror = material.raytrace_mirror
if raytrace_mirror.reflect_factor:
tabWrite("reflection {\n")
tabWrite("rgb <%.3g, %.3g, %.3g>\n" % material.mirror_color[:])
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if material.pov.mirror_metallic:
tabWrite("metallic %.3g\n" % (raytrace_mirror.reflect_factor))
# Blurry reflections for UberPOV
if using_uberpov and raytrace_mirror.gloss_factor < 1.0:
#tabWrite("#ifdef(unofficial) #if(unofficial = \"patch\") #if(patch(\"upov-reflection-roughness\") > 0)\n")
tabWrite("roughness %.6f\n" % \
(0.000001/raytrace_mirror.gloss_factor))
#tabWrite("#end #end #end\n") # This and previous comment for backward compatibility, messier pov code
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if material.pov.mirror_use_IOR: # WORKING ?
# Removed from the line below: gives a more physically correct
# material but needs proper IOR. --Maurice
tabWrite("fresnel 1 ")
tabWrite("falloff %.3g exponent %.3g} " % \
(raytrace_mirror.fresnel, raytrace_mirror.fresnel_factor))
if material.subsurface_scattering.use:
subsurface_scattering = material.subsurface_scattering
Maurice Raybaud
committed
tabWrite("subsurface { translucency <%.3g, %.3g, %.3g> }\n" % (
Maurice Raybaud
committed
(subsurface_scattering.radius[0]),
(subsurface_scattering.radius[1]),
Maurice Raybaud
committed
)
Bastien Montagne
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if material.pov.irid_enable:
tabWrite("irid { %.4g thickness %.4g turbulence %.4g }" % \
(material.pov.irid_amount, material.pov.irid_thickness,
material.pov.irid_turbulence))
tabWrite("diffuse 0.8\n")
tabWrite("phong 70.0\n")
#tabWrite("specular 0.2\n")
# This is written into the object
'''
if material and material.transparency_method=='RAYTRACE':
'interior { ior %.3g} ' % material.raytrace_transparency.ior
'''
#tabWrite("crand 1.0\n") # Sand granyness
#tabWrite("metallic %.6f\n" % material.spec)
#tabWrite("phong %.6f\n" % material.spec)
#tabWrite("phong_size %.6f\n" % material.spec)
#tabWrite("brilliance %.6f " % (material.specular_hardness/256.0) # Like hardness
tabWrite("}\n\n")
# Level=2 Means translation of spec and mir levels for when no map influences them
povHasnoSpecularMaps(Level=2)
special_texture_found = False
for t in material.texture_slots:
if t and t.use:
if (t.texture.type == 'IMAGE' and t.texture.image) or t.texture.type != 'IMAGE':
validPath=True
else:
validPath=False
if(t and t.use and validPath and
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(t.use_map_specular or t.use_map_raymir or t.use_map_normal or t.use_map_alpha)):
continue # Some texture found
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if special_texture_found or colored_specular_found:
# Level=1 Means No specular nor Mirror reflection
povHasnoSpecularMaps(Level=1)
# Level=3 Means Maximum Spec and Mirror
povHasnoSpecularMaps(Level=3)
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# DH disabled for now, this isn't the correct context
active_object = None # bpy.context.active_object # does not always work MR
matrix = global_matrix * camera.matrix_world
focal_point = camera.data.dof_distance
Qsize = render.resolution_x / render.resolution_y
tabWrite("#declare camLocation = <%.6f, %.6f, %.6f>;\n" %
matrix.translation[:])
tabWrite("#declare camLookAt = <%.6f, %.6f, %.6f>;\n" %
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tuple([degrees(e) for e in matrix.to_3x3().to_euler()]))
tabWrite("camera {\n")
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if scene.pov.baking_enable and active_object and active_object.type == 'MESH':
tabWrite("mesh_camera{ 1 3\n") # distribution 3 is what we want here
tabWrite("mesh{%s}\n" % active_object.name)
tabWrite("}\n")
tabWrite("location <0,0,.01>")
tabWrite("direction <0,0,-1>")
tabWrite("location <0, 0, 0>\n")
tabWrite("look_at <0, 0, -1>\n")
tabWrite("right <%s, 0, 0>\n" % - Qsize)
tabWrite("up <0, 1, 0>\n")
tabWrite("angle %f\n" % (360.0 * atan(16.0 / camera.data.lens) / pi))
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tabWrite("rotate <%.6f, %.6f, %.6f>\n" % \
tuple([degrees(e) for e in matrix.to_3x3().to_euler()]))
tabWrite("translate <%.6f, %.6f, %.6f>\n" % matrix.translation[:])
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if camera.data.pov.dof_enable and focal_point != 0:
tabWrite("aperture %.3g\n" % camera.data.pov.dof_aperture)
tabWrite("blur_samples %d %d\n" % \
(camera.data.pov.dof_samples_min, camera.data.pov.dof_samples_max))
tabWrite("variance 1/%d\n" % camera.data.pov.dof_variance)
tabWrite("confidence %.3g\n" % camera.data.pov.dof_confidence)
tabWrite("focal_point <0, 0, %f>\n" % focal_point)
tabWrite("}\n")
# Incremented after each lamp export to declare its target
# currently used for Fresnel diffuse shader as their slope vector:
global lampCount
lampCount = 0
# Get all lamps
for ob in lamps:
lamp = ob.data
matrix = global_matrix * ob.matrix_world
# Color is modified by energy #muiltiplie by 2 for a better match --Maurice
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color = tuple([c * lamp.energy * 2.0 for c in lamp.color])
tabWrite("light_source {\n")
tabWrite("< 0,0,0 >\n")
tabWrite("color rgb<%.3g, %.3g, %.3g>\n" % color)
tabWrite("spotlight\n")
tabWrite("falloff %.2f\n" % (degrees(lamp.spot_size) / 2.0)) # 1 TO 179 FOR BOTH
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tabWrite("radius %.6f\n" % \
((degrees(lamp.spot_size) / 2.0) * (1.0 - lamp.spot_blend)))
# Blender does not have a tightness equivilent, 0 is most like blender default.
tabWrite("tightness 0\n") # 0:10f
tabWrite("point_at <0, 0, -1>\n")
tabWrite("parallel\n")
tabWrite("point_at <0, 0, -1>\n") # *must* be after 'parallel'
tabWrite("area_illumination\n")
tabWrite("fade_distance %.6f\n" % (lamp.distance / 2.0))
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# Area lights have no falloff type, so always use blenders lamp quad equivalent
# for those?
tabWrite("fade_power %d\n" % 2)
size_x = lamp.size
samples_x = lamp.shadow_ray_samples_x
if lamp.shape == 'SQUARE':
size_y = size_x
samples_y = samples_x
else:
size_y = lamp.size_y
samples_y = lamp.shadow_ray_samples_y
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tabWrite("area_light <%.6f,0,0>,<0,%.6f,0> %d, %d\n" % \
(size_x, size_y, samples_x, samples_y))
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if lamp.shadow_ray_sample_method == 'CONSTANT_JITTERED':
if lamp.use_jitter:
tabWrite("jitter\n")
tabWrite("adaptive 1\n")
tabWrite("jitter\n")
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# HEMI never has any shadow_method attribute
if(not scene.render.use_shadows or lamp.type == 'HEMI' or
(lamp.type != 'HEMI' and lamp.shadow_method == 'NOSHADOW')):
tabWrite("shadowless\n")
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# Sun shouldn't be attenuated. Hemi and area lights have no falloff attribute so they
# are put to type 2 attenuation a little higher above.
if lamp.type not in {'SUN', 'AREA', 'HEMI'}:
tabWrite("fade_distance %.6f\n" % (lamp.distance / 2.0))
tabWrite("fade_power %d\n" % 2) # Use blenders lamp quad equivalent
tabWrite("fade_power %d\n" % 1) # Use blenders lamp linear
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# supposing using no fade power keyword would default to constant, no attenuation.
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elif lamp.falloff_type == 'CONSTANT':
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# Using Custom curve for fade power 3 for now.
elif lamp.falloff_type == 'CUSTOM_CURVE':
tabWrite("fade_power %d\n" % 4)
tabWrite("}\n")
lampCount += 1
# v(A,B) rotates vector A about origin by vector B.
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file.write("#declare lampTarget%s= vrotate(<%.4g,%.4g,%.4g>,<%.4g,%.4g,%.4g>);\n" % \
(lampCount, -(ob.location.x), -(ob.location.y), -(ob.location.z),
ob.rotation_euler.x, ob.rotation_euler.y, ob.rotation_euler.z))
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####################################################################################################
def exportMeta(metas):
# TODO - blenders 'motherball' naming is not supported.
if comments and len(metas) >= 1:
file.write("//--Blob objects--\n\n")
# important because no elements will break parsing.
elements = [elem for elem in meta.elements if elem.type in {'BALL', 'ELLIPSOID'}]
tabWrite("blob {\n")
tabWrite("threshold %.4g\n" % meta.threshold)
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importance = ob.pov.importance_value
material = meta.materials[0] # lame! - blender cant do enything else.
except:
material = None
for elem in elements:
loc = elem.co
stiffness = elem.stiffness
if elem.use_negative:
stiffness = - stiffness
if elem.type == 'BALL':
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tabWrite("sphere { <%.6g, %.6g, %.6g>, %.4g, %.4g }\n" % \
(loc.x, loc.y, loc.z, elem.radius, stiffness))
# After this wecould do something simple like...
# "pigment {Blue} }"
# except we'll write the color
elif elem.type == 'ELLIPSOID':
# location is modified by scale
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tabWrite("sphere { <%.6g, %.6g, %.6g>, %.4g, %.4g }\n" % \
(loc.x / elem.size_x, loc.y / elem.size_y, loc.z / elem.size_z,
elem.radius, stiffness))
tabWrite("scale <%.6g, %.6g, %.6g> \n" % \
(elem.size_x, elem.size_y, elem.size_z))
if material:
diffuse_color = material.diffuse_color
trans = 1.0 - material.alpha
if material.use_transparency and material.transparency_method == 'RAYTRACE':
povFilter = material.raytrace_transparency.filter * (1.0 - material.alpha)
trans = (1.0 - material.alpha) - povFilter
material_finish = materialNames[material.name]
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tabWrite("pigment {rgbft<%.3g, %.3g, %.3g, %.3g, %.3g>} \n" % \
(diffuse_color[0], diffuse_color[1], diffuse_color[2],
povFilter, trans))
tabWrite("finish {%s}\n" % safety(material_finish, Level=2))
tabWrite("pigment {rgb<1 1 1>} \n")
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# Write the finish last.
tabWrite("finish {%s}\n" % (safety(DEF_MAT_NAME, Level=2)))
writeObjectMaterial(material, ob)
writeMatrix(global_matrix * ob.matrix_world)
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# Importance for radiosity sampling added here
tabWrite("radiosity { \n")
tabWrite("importance %3g \n" % importance)
tabWrite("}\n")
tabWrite("}\n") # End of Metaball block
if comments and len(metas) >= 1:
file.write("\n")
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# objectNames = {}
DEF_OBJ_NAME = "Default"
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def exportMeshes(scene, sel):
# obmatslist = []
# def hasUniqueMaterial():
# # Grab materials attached to object instances ...
# if hasattr(ob, 'material_slots'):
# for ms in ob.material_slots:
# if ms.material is not None and ms.link == 'OBJECT':
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# if ms.material in obmatslist:
# return False
# else:
# obmatslist.append(ms.material)
# return True
# def hasObjectMaterial(ob):
# # Grab materials attached to object instances ...
# if hasattr(ob, 'material_slots'):
# for ms in ob.material_slots:
# if ms.material is not None and ms.link == 'OBJECT':
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# # If there is at least one material slot linked to the object
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# # and not the data (mesh), always create a new, "private" data instance.
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# return True
# return False
# For objects using local material(s) only!
# This is a mapping between a tuple (dataname, materialnames, ...), and the POV dataname.
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# As only objects using:
# * The same data.
# * EXACTLY the same materials, in EXACTLY the same sockets.
# ... can share a same instance in POV export.
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obmats2data = {}
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def checkObjectMaterials(ob, name, dataname):
if hasattr(ob, 'material_slots'):
has_local_mats = False
key = [dataname]
for ms in ob.material_slots:
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key.append(ms.material.name)
if ms.link == 'OBJECT' and not has_local_mats:
has_local_mats = True
else:
# Even if the slot is empty, it is important to grab it...
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key.append("")
if has_local_mats:
# If this object uses local material(s), lets find if another object
# using the same data and exactly the same list of materials
# (in the same slots) has already been processed...
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# Note that here also, we use object name as new, unique dataname for Pov.
key = tuple(key) # Lists are not hashable...
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if key not in obmats2data:
obmats2data[key] = name
return obmats2data[key]
return None
data_ref = {}
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def store(scene, ob, name, dataname, matrix):
# The Object needs to be written at least once but if its data is
# already in data_ref this has already been done.
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# This func returns the "povray" name of the data, or None
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# if no writing is needed.
if ob.is_modified(scene, 'RENDER'):
# Data modified.
# Create unique entry in data_ref by using object name
# (always unique in Blender) as data name.
data_ref[name] = [(name, MatrixAsPovString(matrix))]
return name
# Here, we replace dataname by the value returned by checkObjectMaterials, only if
# it is not evaluated to False (i.e. only if the object uses some local material(s)).
dataname = checkObjectMaterials(ob, name, dataname) or dataname
if dataname in data_ref:
# Data already known, just add the object instance.
data_ref[dataname].append((name, MatrixAsPovString(matrix)))
# No need to write data
return None
else:
# Data not yet processed, create a new entry in data_ref.
data_ref[dataname] = [(name, MatrixAsPovString(matrix))]
return dataname
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def exportSmoke(smoke_obj_name):
#if LuxManager.CurrentScene.name == 'preview':
#return 1, 1, 1, 1.0
#else:
flowtype = -1
smoke_obj = bpy.data.objects[smoke_obj_name]
domain = None
# Search smoke domain target for smoke modifiers
for mod in smoke_obj.modifiers:
if mod.name == 'Smoke':
if mod.smoke_type == 'FLOW':
if mod.flow_settings.smoke_flow_type == 'BOTH':
flowtype = 2
else:
if mod.flow_settings.smoke_flow_type == 'SMOKE':
flowtype = 0
else:
if mod.flow_settings.smoke_flow_type == 'FIRE':
flowtype = 1
if mod.smoke_type == 'DOMAIN':
domain = smoke_obj
smoke_modifier = mod
eps = 0.000001
if domain is not None:
#if bpy.app.version[0] >= 2 and bpy.app.version[1] >= 71:
# Blender version 2.71 supports direct access to smoke data structure
set = mod.domain_settings
channeldata = []
for v in set.density_grid:
channeldata.append(v.real)
print(v.real)
## Usage en voxel texture:
# channeldata = []
# if channel == 'density':
# for v in set.density_grid:
# channeldata.append(v.real)
# if channel == 'fire':
# for v in set.flame_grid:
# channeldata.append(v.real)
resolution = set.resolution_max
big_res = []
big_res.append(set.domain_resolution[0])
big_res.append(set.domain_resolution[1])
big_res.append(set.domain_resolution[2])
if set.use_high_resolution:
big_res[0] = big_res[0] * (set.amplify + 1)
big_res[1] = big_res[1] * (set.amplify + 1)
big_res[2] = big_res[2] * (set.amplify + 1)
# else:
# p = []
##gather smoke domain settings
# BBox = domain.bound_box
# p.append([BBox[0][0], BBox[0][1], BBox[0][2]])
# p.append([BBox[6][0], BBox[6][1], BBox[6][2]])
# set = mod.domain_settings
# resolution = set.resolution_max
# smokecache = set.point_cache
# ret = read_cache(smokecache, set.use_high_resolution, set.amplify + 1, flowtype)
# res_x = ret[0]
# res_y = ret[1]
# res_z = ret[2]
# density = ret[3]
# fire = ret[4]
# if res_x * res_y * res_z > 0:
##new cache format
# big_res = []
# big_res.append(res_x)
# big_res.append(res_y)
# big_res.append(res_z)
# else:
# max = domain.dimensions[0]
# if (max - domain.dimensions[1]) < -eps:
# max = domain.dimensions[1]
# if (max - domain.dimensions[2]) < -eps:
# max = domain.dimensions[2]
# big_res = [int(round(resolution * domain.dimensions[0] / max, 0)),
# int(round(resolution * domain.dimensions[1] / max, 0)),
# int(round(resolution * domain.dimensions[2] / max, 0))]
# if set.use_high_resolution:
# big_res = [big_res[0] * (set.amplify + 1), big_res[1] * (set.amplify + 1),
# big_res[2] * (set.amplify + 1)]
# if channel == 'density':
# channeldata = density
# if channel == 'fire':
# channeldata = fire
# sc_fr = '%s/%s/%s/%05d' % (efutil.export_path, efutil.scene_filename(), bpy.context.scene.name, bpy.context.scene.frame_current)
# if not os.path.exists( sc_fr ):
# os.makedirs(sc_fr)
#
# smoke_filename = '%s.smoke' % bpy.path.clean_name(domain.name)
# smoke_path = '/'.join([sc_fr, smoke_filename])
#
# with open(smoke_path, 'wb') as smoke_file:
# # Binary densitygrid file format
# #
# # File header
# smoke_file.write(b'SMOKE') #magic number
# smoke_file.write(struct.pack('<I', big_res[0]))
# smoke_file.write(struct.pack('<I', big_res[1]))
# smoke_file.write(struct.pack('<I', big_res[2]))
# Density data
# smoke_file.write(struct.pack('<%df'%len(channeldata), *channeldata))
#
# LuxLog('Binary SMOKE file written: %s' % (smoke_path))
#return big_res[0], big_res[1], big_res[2], channeldata
mydf3 = df3.df3(big_res[0],big_res[1],big_res[2])
for x in range(mydf3.sizeX()):
for y in range(mydf3.sizeY()):
for z in range(mydf3.sizeZ()):
mydf3.set(x, y, z, channeldata[((z*mydf3.sizeY()+y)*mydf3.sizeX()+x)])
mydf3.exportDF3(smokePath)
print('Binary smoke.df3 file written in preview directory')
if comments:
file.write("\n//--Smoke--\n\n")
# media container shape = blender domain
file.write("box{<0,0,0>, <%.4g, %.4g, %.4g>\n"% \
(smoke_obj.dimensions[0], smoke_obj.dimensions[1], smoke_obj.dimensions[2]))
file.write(" translate <%.4g, %.4g, %.4g>\n"% \
(smoke_obj.location[0], smoke_obj.location[1], smoke_obj.location[2]))
file.write(" pigment{ rgbt 1 }\n")
file.write(" hollow\n")
file.write(" interior{ //---------------------\n")
file.write(" media{ method 3\n")
file.write(" emission <1,1,1>*1\n")# 0>1 for dark smoke to white vapour
file.write(" scattering{ 1, // Type\n")
file.write(" <1,1,1>*5.00\n")
file.write(" } // end scattering\n")
file.write(" density{density_file df3 \"%s\"\n" % (smokePath))
file.write(" color_map {\n")
file.write(" [0.00 rgb 0]\n")
file.write(" [0.05 rgb 0]\n")
file.write(" [0.20 rgb 0.2]\n")
file.write(" [0.30 rgb 0.6]\n")
file.write(" [0.40 rgb 1]\n")
file.write(" [1.00 rgb 1]\n")
file.write(" } // end color_map\n")
file.write(" } // end of density\n")
file.write(" samples 20 // higher = more precise\n")
file.write(" } // end of media --------------------------\n")
file.write(" } // end of interior\n")
file.write("}\n")
#file.write(" interpolate 1\n")
#file.write(" frequency 0\n")
#file.write(" }\n")
#file.write("}\n")
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ob_num = 0
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# XXX I moved all those checks here, as there is no need to compute names
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# for object we won't export here!
if ob.type in {'LAMP', 'CAMERA', 'EMPTY', 'META', 'ARMATURE', 'LATTICE'}:
for mod in ob.modifiers:
if mod and hasattr(mod, 'smoke_type'):
exportSmoke(ob.name)
if (mod.smoke_type == 'DOMAIN') or (mod.smoke_type == 'FLOW'):
continue #don't render domain mesh or flow emitter, skip to next object.
for pSys in ob.particle_systems:
if pSys.settings.use_render_emitter:
renderEmitter = True
for mod in [m for m in ob.modifiers if (m is not None) and (m.type == 'PARTICLE_SYSTEM')]:
if (pSys.settings.render_type == 'PATH') and mod.show_render and (pSys.name == mod.particle_system.name):
tstart = time.time()
if ob.active_material is not None:
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pmaterial = ob.material_slots[pSys.settings.material - 1].material
for th in pmaterial.texture_slots:
if th and th.use:
if (th.texture.type == 'IMAGE' and th.texture.image) or th.texture.type != 'IMAGE':
if th.use_map_color_diffuse:
texturedHair=1
if pmaterial.strand.use_blender_units:
strandStart = pmaterial.strand.root_size
strandEnd = pmaterial.strand.tip_size
strandStart = pmaterial.strand.root_size / 200.0
strandEnd = pmaterial.strand.tip_size / 200.0
strandShape = pmaterial.strand.shape
else:
pmaterial = "default" # No material assigned in blender, use default one
strandStart = 0.01
strandEnd = 0.01
strandShape = 0.0
# Set the number of particles to render count rather than 3d view display
pSys.set_resolution(scene, ob, 'RENDER')
steps = pSys.settings.draw_step
steps = 3 ** steps # or (power of 2 rather than 3) + 1 # Formerly : len(particle.hair_keys)
totalNumberOfHairs = ( len(pSys.particles) + len(pSys.child_particles) )
#hairCounter = 0
file.write('#declare HairArray = array[%i] {\n' % totalNumberOfHairs)
for pindex in range(0, totalNumberOfHairs):
#if particle.is_exist and particle.is_visible:
#hairCounter += 1
#controlPointCounter = 0
# Each hair is represented as a separate sphere_sweep in POV-Ray.
file.write('sphere_sweep{')
if pSys.settings.use_hair_bspline:
file.write('b_spline ')
file.write('%i,\n' % (steps + 2)) # +2 because the first point needs tripling to be more than a handle in POV
else:
file.write('linear_spline ')
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#changing world coordinates to object local coordinates by multiplying with inverted matrix
initCo = ob.matrix_world.inverted()*(pSys.co_hair(ob, pindex, 0))
if ob.active_material is not None:
pmaterial = ob.material_slots[pSys.settings.material-1].material
for th in pmaterial.texture_slots:
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if th and th.use and th.use_map_color_diffuse:
#treat POV textures as bitmaps
if (th.texture.type == 'IMAGE' and th.texture.image and th.texture_coords == 'UV' and ob.data.uv_textures != None): # or (th.texture.pov.tex_pattern_type != 'emulator' and th.texture_coords == 'UV' and ob.data.uv_textures != None):
image=th.texture.image
image_width = image.size[0]
image_height = image.size[1]
image_pixels = image.pixels[:]
uv_co = pSys.uv_on_emitter(mod, pSys.particles[pindex], pindex, 0)
x_co = round(uv_co[0] * (image_width - 1))
y_co = round(uv_co[1] * (image_height - 1))
pixelnumber = (image_width * y_co) + x_co
r = image_pixels[pixelnumber*4]
g = image_pixels[pixelnumber*4+1]
b = image_pixels[pixelnumber*4+2]
a = image_pixels[pixelnumber*4+3]
initColor=(r,g,b,a)
else:
#only overwrite variable for each competing texture for now
initColor=th.texture.evaluate((initCo[0],initCo[1],initCo[2]))
if pSys.settings.clump_factor != 0:
hDiameter = pSys.settings.clump_factor / 200.0 * random.uniform(0.5, 1)
hDiameter = strandStart
else:
hDiameter += (strandEnd-strandStart)/(pSys.settings.draw_step+1) #XXX +1 or not?
if step == 0 and pSys.settings.use_hair_bspline:
# Write three times the first point to compensate pov Bezier handling
file.write('<%.6g,%.6g,%.6g>,%.7g,\n' % (co[0], co[1], co[2], abs(hDiameter)))
file.write('<%.6g,%.6g,%.6g>,%.7g,\n' % (co[0], co[1], co[2], abs(hDiameter)))
Campbell Barton
committed
#file.write('<%.6g,%.6g,%.6g>,%.7g' % (particle.location[0], particle.location[1], particle.location[2], abs(hDiameter))) # Useless because particle location is the tip, not the root.
#totalNumberOfHairs += len(pSys.particles)# len(particle.hair_keys)
# Each control point is written out, along with the radius of the
# hair at that point.
file.write('<%.6g,%.6g,%.6g>,%.7g' % (co[0], co[1], co[2], abs(hDiameter)))
# All coordinates except the last need a following comma.
Maurice Raybaud
committed
# Write pigment and alpha (between Pov and Blender alpha 0 and 1 are reversed)
file.write('\npigment{ color rgbf < %.3g, %.3g, %.3g, %.3g> }\n' %(initColor[0], initColor[1], initColor[2], 1.0-initColor[3]))
# End the sphere_sweep declaration for this hair
file.write('}\n')
# All but the final sphere_sweep (each array element) needs a terminating comma.
file.write(',\n')
else:
file.write('\n')
# End the array declaration.
file.write('}\n')
file.write('\n')
if not texturedHair:
# Pick up the hair material diffuse color and create a default POV-Ray hair texture.
file.write('#ifndef (HairTexture)\n')
file.write(' #declare HairTexture = texture {\n')
file.write(' pigment {rgbt <%s,%s,%s,%s>}\n' % (pmaterial.diffuse_color[0], pmaterial.diffuse_color[1], pmaterial.diffuse_color[2], (pmaterial.strand.width_fade + 0.05)))
file.write(' }\n')
file.write('#end\n')
file.write('\n')
# Dynamically create a union of the hairstrands (or a subset of them).
# By default use every hairstrand, commented line is for hand tweaking test renders.
file.write('//Increasing HairStep divides the amount of hair for test renders.\n')
file.write('#ifndef(HairStep) #declare HairStep = 1; #end\n')
file.write('union{\n')
file.write(' #local I = 0;\n')
file.write(' #while (I < %i)\n' % totalNumberOfHairs)
file.write(' object {HairArray[I]')
if not texturedHair:
file.write(' texture{HairTexture}\n')
else:
file.write('\n')
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# Translucency of the hair:
file.write(' hollow\n')
file.write(' double_illuminate\n')
file.write(' interior {\n')
file.write(' ior 1.45\n')
file.write(' media {\n')
file.write(' scattering { 1, 10*<0.73, 0.35, 0.15> /*extinction 0*/ }\n')
file.write(' absorption 10/<0.83, 0.75, 0.15>\n')
file.write(' samples 1\n')
file.write(' method 2\n')
file.write(' density {\n')
file.write(' color_map {\n')
file.write(' [0.0 rgb <0.83, 0.45, 0.35>]\n')
file.write(' [0.5 rgb <0.8, 0.8, 0.4>]\n')
file.write(' [1.0 rgb <1,1,1>]\n')
file.write(' }\n')
file.write(' }\n')
file.write(' }\n')
file.write(' }\n')
file.write(' }\n')
file.write(' #local I = I + HairStep;\n')
file.write(' #end\n')
writeMatrix(global_matrix * ob.matrix_world)
file.write('}')
print('Totals hairstrands written: %i' % totalNumberOfHairs)
print('Number of tufts (particle systems)', len(ob.particle_systems))
# Set back the displayed number of particles to preview count
pSys.set_resolution(scene, ob, 'PREVIEW')
if renderEmitter == False:
continue #don't render mesh, skip to next object.
except:
# happens when curves cant be made into meshes because of no-data
continue
Bastien Montagne
committed
importance = ob.pov.importance_value
me_faces = me.tessfaces[:]
Bastien Montagne
committed
#############################################
# Generating a name for object just like materials to be able to use it
# (baking for now or anything else).
Maurice Raybaud
committed
# XXX I don't understand that: if we are here, sel if a non-empty iterable,
Bastien Montagne
committed
# so this condition is always True, IMO -- mont29
if sel:
name_orig = "OB" + ob.name
dataname_orig = "DATA" + ob.data.name
else:
name_orig = DEF_OBJ_NAME
dataname_orig = DEF_OBJ_NAME
name = string_strip_hyphen(bpy.path.clean_name(name_orig))
dataname = string_strip_hyphen(bpy.path.clean_name(dataname_orig))
Bastien Montagne
committed
## for slot in ob.material_slots:
## if slot.material is not None and slot.link == 'OBJECT':
Bastien Montagne
committed
## obmaterial = slot.material
#############################################
info_callback("Object %2.d of %2.d (%s)" % (ob_num, len(sel), ob.name))
#if ob.type != 'MESH':
# continue
matrix = global_matrix * ob.matrix_world
Bastien Montagne
committed
povdataname = store(scene, ob, name, dataname, matrix)
if povdataname is None:
print("This is an instance")
continue
print("Writing Down First Occurence")
uv_textures = me.tessface_uv_textures
if len(uv_textures) > 0:
if me.uv_textures.active and uv_textures.active.data:
uv_layer = uv_textures.active.data
else:
#vcol_layer = me.vertex_colors.active.data
vcol_layer = me.tessface_vertex_colors.active.data
faces_verts = [f.vertices[:] for f in me_faces]
faces_normals = [f.normal[:] for f in me_faces]
verts_normals = [v.normal[:] for v in me.vertices]
quadCount = sum(1 for f in faces_verts if len(f) == 4)
# Use named declaration to allow reference e.g. for baking. MR
file.write("\n")
Bastien Montagne
committed
tabWrite("#declare %s =\n" % povdataname)
tabWrite("mesh2 {\n")
tabWrite("vertex_vectors {\n")
tabWrite("%d" % len(me.vertices)) # vert count
Constantin Rahn
committed
tabStr = tab * tabLevel
file.write(",\n")
file.write(tabStr + "<%.6f, %.6f, %.6f>" % v.co[:]) # vert count
else:
file.write(", ")
file.write("<%.6f, %.6f, %.6f>" % v.co[:]) # vert count
Constantin Rahn
committed
#tabWrite("<%.6f, %.6f, %.6f>" % v.co[:]) # vert count
file.write("\n")
tabWrite("}\n")
for fi, f in enumerate(me_faces):
fv = faces_verts[fi]
# [-1] is a dummy index, use a list so we can modify in place
if f.use_smooth: # Use vertex normals
for v in fv:
key = verts_normals[v]
uniqueNormals[key] = [-1]
key = faces_normals[fi]
uniqueNormals[key] = [-1]
tabWrite("normal_vectors {\n")
tabWrite("%d" % len(uniqueNormals)) # vert count
Constantin Rahn
committed
tabStr = tab * tabLevel
file.write(",\n")
file.write(tabStr + "<%.6f, %.6f, %.6f>" % no) # vert count
else:
file.write(", ")
file.write("<%.6f, %.6f, %.6f>" % no) # vert count
file.write("\n")
tabWrite("}\n")
# Vertex colors
vertCols = {} # Use for material colors also.
if uv_layer:
# Generate unique UV's
uniqueUVs = {}
#n = 0
for fi, uv in enumerate(uv_layer):
if len(faces_verts[fi]) == 4:
uvs = uv_layer[fi].uv[0], uv_layer[fi].uv[1], uv_layer[fi].uv[2], uv_layer[fi].uv[3]
uvs = uv_layer[fi].uv[0], uv_layer[fi].uv[1], uv_layer[fi].uv[2]
tabWrite("uv_vectors {\n")
tabWrite("%d" % len(uniqueUVs)) # vert count
Constantin Rahn
committed
tabStr = tab * tabLevel
file.write(",\n")
file.write(tabStr + "<%.6f, %.6f>" % uv)
else:
file.write(", ")
file.write("<%.6f, %.6f>" % uv)
index[0] = idx
idx += 1
'''
else:
# Just add 1 dummy vector, no real UV's
Constantin Rahn
committed
tabWrite('1') # vert count
file.write("\n")
tabWrite("}\n")
#Write down vertex colors as a texture for each vertex
tabWrite("texture_list {\n")
tabWrite("%d\n" % (((len(me_faces)-quadCount) * 3 )+ quadCount * 4)) # works only with tris and quad mesh for now
VcolIdx=0
if comments:
file.write("\n //Vertex colors: one simple pigment texture per vertex\n")
for fi, f in enumerate(me_faces):
# annoying, index may be invalid
try:
material = me_materials[material_index]
except:
material = None
if material: #and material.use_vertex_color_paint: #Always use vertex color when there is some for now
col = vcol_layer[fi]
if len(faces_verts[fi]) == 4:
cols = col.color1, col.color2, col.color3, col.color4
else:
cols = col.color1, col.color2, col.color3
for col in cols:
key = col[0], col[1], col[2], material_index # Material index!
VcolIdx+=1
vertCols[key] = [VcolIdx]
if linebreaksinlists:
tabWrite("texture {pigment{ color rgb <%6f,%6f,%6f> }}\n" % (col[0], col[1], col[2]))
else:
tabWrite("texture {pigment{ color rgb <%6f,%6f,%6f> }}" % (col[0], col[1], col[2]))
tabStr = tab * tabLevel
Maurice Raybaud
committed
# Multiply diffuse with SSS Color
if material.subsurface_scattering.use:
diffuse_color = [i * j for i, j in zip(material.subsurface_scattering.color[:], material.diffuse_color[:])]
Maurice Raybaud
committed
key = diffuse_color[0], diffuse_color[1], diffuse_color[2], \
material_index
vertCols[key] = [-1]
else:
diffuse_color = material.diffuse_color[:]
key = diffuse_color[0], diffuse_color[1], diffuse_color[2], \
material_index
vertCols[key] = [-1]
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tabWrite("\n}\n")
# Face indices
tabWrite("\nface_indices {\n")
tabWrite("%d" % (len(me_faces) + quadCount)) # faces count
tabStr = tab * tabLevel
for fi, f in enumerate(me_faces):
fv = faces_verts[fi]
material_index = f.material_index
if len(fv) == 4:
indices = (0, 1, 2), (0, 2, 3)
else:
indices = ((0, 1, 2),)
if vcol_layer:
col = vcol_layer[fi]
if len(fv) == 4:
cols = col.color1, col.color2, col.color3, col.color4
else:
cols = col.color1, col.color2, col.color3
if not me_materials or me_materials[material_index] is None: # No materials
for i1, i2, i3 in indices:
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file.write(",\n")
# vert count
file.write(tabStr + "<%d,%d,%d>" % (fv[i1], fv[i2], fv[i3]))
else:
file.write(", ")
file.write("<%d,%d,%d>" % (fv[i1], fv[i2], fv[i3])) # vert count
else:
material = me_materials[material_index]
for i1, i2, i3 in indices:
if me.vertex_colors: #and material.use_vertex_color_paint:
# Color per vertex - vertex color
col1 = cols[i1]
col2 = cols[i2]
col3 = cols[i3]
ci1 = vertCols[col1[0], col1[1], col1[2], material_index][0]
ci2 = vertCols[col2[0], col2[1], col2[2], material_index][0]
ci3 = vertCols[col3[0], col3[1], col3[2], material_index][0]
else:
# Color per material - flat material color
if material.subsurface_scattering.use:
diffuse_color = [i * j for i, j in zip(material.subsurface_scattering.color[:], material.diffuse_color[:])]
else:
diffuse_color = material.diffuse_color[:]
ci1 = ci2 = ci3 = vertCols[diffuse_color[0], diffuse_color[1], \
diffuse_color[2], f.material_index][0]
# ci are zero based index so we'll subtract 1 from them
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file.write(",\n")
file.write(tabStr + "<%d,%d,%d>, %d,%d,%d" % \
(fv[i1], fv[i2], fv[i3], ci1-1, ci2-1, ci3-1)) # vert count
else:
file.write(", ")
file.write("<%d,%d,%d>, %d,%d,%d" % \
(fv[i1], fv[i2], fv[i3], ci1-1, ci2-1, ci3-1)) # vert count
file.write("\n")
tabWrite("}\n")
# normal_indices indices
tabWrite("normal_indices {\n")
tabWrite("%d" % (len(me_faces) + quadCount)) # faces count
tabStr = tab * tabLevel
for fi, fv in enumerate(faces_verts):
if len(fv) == 4:
indices = (0, 1, 2), (0, 2, 3)
else:
indices = ((0, 1, 2),)
for i1, i2, i3 in indices:
if me_faces[fi].use_smooth:
file.write(",\n")
file.write(tabStr + "<%d,%d,%d>" %\
(uniqueNormals[verts_normals[fv[i1]]][0],\
uniqueNormals[verts_normals[fv[i2]]][0],\
uniqueNormals[verts_normals[fv[i3]]][0])) # vert count
else:
file.write(", ")
file.write("<%d,%d,%d>" %\
(uniqueNormals[verts_normals[fv[i1]]][0],\
uniqueNormals[verts_normals[fv[i2]]][0],\
uniqueNormals[verts_normals[fv[i3]]][0])) # vert count
else:
idx = uniqueNormals[faces_normals[fi]][0]
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file.write(",\n")
file.write(tabStr + "<%d,%d,%d>" % (idx, idx, idx)) # vert count
else:
file.write(", ")
file.write("<%d,%d,%d>" % (idx, idx, idx)) # vert count
file.write("\n")
tabWrite("}\n")
if uv_layer:
tabWrite("uv_indices {\n")
tabWrite("%d" % (len(me_faces) + quadCount)) # faces count
tabStr = tab * tabLevel
for fi, fv in enumerate(faces_verts):
if len(fv) == 4:
indices = (0, 1, 2), (0, 2, 3)
else:
indices = ((0, 1, 2),)
uv = uv_layer[fi]
if len(faces_verts[fi]) == 4:
uvs = uv.uv[0][:], uv.uv[1][:], uv.uv[2][:], uv.uv[3][:]
else:
uvs = uv.uv[0][:], uv.uv[1][:], uv.uv[2][:]
for i1, i2, i3 in indices:
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file.write(",\n")
file.write(tabStr + "<%d,%d,%d>" % (
uniqueUVs[uvs[i1]][0],\
uniqueUVs[uvs[i2]][0],\
uniqueUVs[uvs[i3]][0]))
else:
file.write(", ")
file.write("<%d,%d,%d>" % (
uniqueUVs[uvs[i1]][0],\
uniqueUVs[uvs[i2]][0],\
uniqueUVs[uvs[i3]][0]))
file.write("\n")
tabWrite("}\n")
if me.materials:
try:
material = me.materials[0] # dodgy
writeObjectMaterial(material, ob)
except IndexError:
print(me)
#Importance for radiosity sampling added here:
tabWrite("radiosity { \n")
tabWrite("importance %3g \n" % importance)
tabWrite("}\n")
tabWrite("}\n") # End of mesh block
# No vertex colors, so write material colors as vertex colors
for i, material in enumerate(me_materials):
if material:
Maurice Raybaud
committed
# Multiply diffuse with SSS Color
if material.subsurface_scattering.use:
diffuse_color = [i * j for i, j in zip(material.subsurface_scattering.color[:], material.diffuse_color[:])]
Maurice Raybaud
committed
key = diffuse_color[0], diffuse_color[1], diffuse_color[2], i # i == f.mat
vertCols[key] = [-1]
else:
diffuse_color = material.diffuse_color[:]
key = diffuse_color[0], diffuse_color[1], diffuse_color[2], i # i == f.mat
vertCols[key] = [-1]
Maurice Raybaud
committed
idx = 0
LocalMaterialNames = []
Maurice Raybaud
committed
for col, index in vertCols.items():
#if me_materials:
mater = me_materials[col[3]]
Maurice Raybaud
committed
material_finish = DEF_MAT_NAME # not working properly,
trans = 0.0
Maurice Raybaud
committed
else:
material_finish = materialNames[mater.name]
if mater.use_transparency:
trans = 1.0 - mater.alpha
Maurice Raybaud
committed
else:
trans = 0.0
if (mater.specular_color.s == 0.0):
Maurice Raybaud
committed
colored_specular_found = False
else:
colored_specular_found = True
if mater.use_transparency and mater.transparency_method == 'RAYTRACE':
povFilter = mater.raytrace_transparency.filter * (1.0 - mater.alpha)
trans = (1.0 - mater.alpha) - povFilter
Maurice Raybaud
committed
else:
povFilter = 0.0
##############SF
texturesDif = ""
texturesSpec = ""
texturesNorm = ""
texturesAlpha = ""
#proceduralFlag=False
for t in mater.texture_slots:
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if t and t.use and t.texture.type != 'IMAGE' and t.texture.type != 'NONE':
proceduralFlag=True
image_filename = "PAT_%s"%string_strip_hyphen(bpy.path.clean_name(t.texture.name))
if image_filename:
if t.use_map_color_diffuse:
texturesDif = image_filename
# colvalue = t.default_value # UNUSED
t_dif = t
if t_dif.texture.pov.tex_gamma_enable:
imgGamma = (" gamma %.3g " % t_dif.texture.pov.tex_gamma_value)
if t.use_map_specular or t.use_map_raymir:
texturesSpec = image_filename
# colvalue = t.default_value # UNUSED
t_spec = t
if t.use_map_normal:
texturesNorm = image_filename
# colvalue = t.normal_factor * 10.0 # UNUSED
#textNormName=t.texture.image.name + ".normal"
#was the above used? --MR
t_nor = t
if t.use_map_alpha:
texturesAlpha = image_filename
# colvalue = t.alpha_factor * 10.0 # UNUSED
#textDispName=t.texture.image.name + ".displ"
#was the above used? --MR
t_alpha = t
if t and t.texture.type == 'IMAGE' and t.use and t.texture.image and t.texture.pov.tex_pattern_type == 'emulator':
proceduralFlag=False
if t.texture.image.packed_file:
orig_image_filename=t.texture.image.filepath_raw
workDir=os.path.dirname(__file__)
previewDir=os.path.join(workDir, "preview")
unpackedfilename= os.path.join(previewDir,("unpacked_img_"+(string_strip_hyphen(bpy.path.clean_name(t.texture.name)))))
if not os.path.exists(unpackedfilename):
# record which images that were newly copied and can be safely
# cleaned up
unpacked_images.append(unpackedfilename)
t.texture.image.filepath_raw=unpackedfilename
t.texture.image.save()
image_filename = unpackedfilename
t.texture.image.filepath_raw=orig_image_filename
else:
image_filename = path_image(t.texture.image)
Maurice Raybaud
committed
# IMAGE SEQUENCE BEGINS
if image_filename:
if bpy.data.images[t.texture.image.name].source == 'SEQUENCE':
korvaa = "." + str(bpy.data.textures[t.texture.name].image_user.frame_offset + 1).zfill(3) + "."
image_filename = image_filename.replace(".001.", korvaa)
print(" seq debug ")
print(image_filename)
# IMAGE SEQUENCE ENDS
Maurice Raybaud
committed
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imgGamma = ""
if image_filename:
if t.use_map_color_diffuse:
texturesDif = image_filename
# colvalue = t.default_value # UNUSED
t_dif = t
if t_dif.texture.pov.tex_gamma_enable:
imgGamma = (" gamma %.3g " % t_dif.texture.pov.tex_gamma_value)
if t.use_map_specular or t.use_map_raymir:
texturesSpec = image_filename
# colvalue = t.default_value # UNUSED
t_spec = t
if t.use_map_normal:
texturesNorm = image_filename
# colvalue = t.normal_factor * 10.0 # UNUSED
#textNormName=t.texture.image.name + ".normal"
#was the above used? --MR
t_nor = t
if t.use_map_alpha:
texturesAlpha = image_filename
# colvalue = t.alpha_factor * 10.0 # UNUSED
#textDispName=t.texture.image.name + ".displ"
#was the above used? --MR
t_alpha = t
####################################################################################
file.write("\n")
# THIS AREA NEEDS TO LEAVE THE TEXTURE OPEN UNTIL ALL MAPS ARE WRITTEN DOWN.
# --MR
currentMatName = string_strip_hyphen(materialNames[mater.name])
Maurice Raybaud
committed
LocalMaterialNames.append(currentMatName)
file.write("\n #declare MAT_%s = \ntexture{\n" % currentMatName)
################################################################################
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