X-Git-Url: http://git.tdb.fi/?a=blobdiff_plain;f=blender%2Fio_mspgl%2Fexport_texture.py;h=f75d8f93ff3623100642f8d6418ab4c3d44a3e88;hb=cf6eec94b7d02885c00c6b8d79380aae7d7669f5;hp=fea02a7d7e3d885cc606be138bdb01dda93f58f8;hpb=e891021affc89a329d65b526744ebd38589cae32;p=libs%2Fgl.git diff --git a/blender/io_mspgl/export_texture.py b/blender/io_mspgl/export_texture.py index fea02a7d..f75d8f93 100644 --- a/blender/io_mspgl/export_texture.py +++ b/blender/io_mspgl/export_texture.py @@ -1,40 +1,79 @@ +import os + class TextureExporter: def __init__(self): - self.pixels = 'REF' + self.inline_data = True - def export_texture(self, texture): + def export_texture(self, tex_node, usage='RGB'): + image = tex_node.image from .datafile import Resource, Statement, Token - tex_res = Resource(texture.name+".tex2d") + tex_res = Resource(image.name+".tex2d", "texture2d") - if texture.use_interpolation: - if texture.use_mipmap: - tex_res.statements.append(Statement("min_filter", Token('LINEAR_MIPMAP_LINEAR'))) - tex_res.statements.append(Statement("generate_mipmap", True)) - else: - tex_res.statements.append(Statement("min_filter", Token('LINEAR'))) - tex_res.statements.append(Statement("max_anisotropy", texture.filter_eccentricity)) + if tex_node.use_mipmap: + tex_res.statements.append(Statement("generate_mipmap", True)) + + colorspace = image.colorspace_settings.name + if usage=='GRAY' and colorspace=='sRGB': + raise Exception("Grayscale textures with sRGB colorspace are not supported") + + from .util import basename + fn = basename(image.filepath) + if not self.inline_data and fn: + srgb = "_srgb" if colorspace=='sRGB' else "" + tex_res.statements.append(Statement("external_image"+srgb, fn)) else: - if texture.use_mipmap: - tex_res.statements.append(Statement("min_filter", Token('NEAREST_MIPMAP_NEAREST'))) - tex_res.statements.append(Statement("generate_mipmap", True)) + if usage=='RGBA': + fmt = 'SRGB8_ALPHA8' if colorspace=='sRGB' else 'RGBA8' + elif usage=='GRAY': + fmt = 'LUMINANCE8' else: - tex_res.statements.append(Statement("min_filter", Token('NEAREST'))) + fmt = 'SRGB8' if colorspace=='sRGB' else 'RGB8' + + tex_res.statements.append(Statement("storage", Token(fmt), image.size[0], image.size[1])) - if self.pixels=='REF': - from .util import image_name - tex_res.statements.append(Statement("image_data", image_name(texture.image))) - else: texdata = "" - if texture.use_alpha: - fmt = 'RGBA' - for p in texture.image.pixels: + if usage=='RGBA': + for p in image.pixels: texdata += "\\x{:02X}".format(int(p*255)) + elif usage=='GRAY': + for i in range(0, len(image.pixels), 4): + texdata += "\\x{:02X}".format(image.pixels[i]) else: - fmt = 'RGB' - for i in range(0, len(texture.image.pixels), 4): + for i in range(0, len(image.pixels), 4): for j in range(3): - texdata += "\\x{:02X}".format(int(texture.image.pixels[i+j]*255)) - tex_res.statements.append(Statement("storage", Token(fmt), texture.image.size[0], texture.image.size[1])) + texdata += "\\x{:02X}".format(int(image.pixels[i+j]*255)) tex_res.statements.append(Statement("raw_data", texdata)) return tex_res + +class SamplerExporter: + def export_sampler(self, tex_node): + from .datafile import Resource, Statement, Token + samp_res = Resource(self.get_sampler_name(tex_node), "sampler") + + use_interpolation = tex_node.interpolation!='Closest' + if use_interpolation: + if tex_node.use_mipmap: + samp_res.statements.append(Statement("filter", Token('LINEAR_MIPMAP_LINEAR'))) + else: + samp_res.statements.append(Statement("filter", Token('LINEAR'))) + samp_res.statements.append(Statement("max_anisotropy", tex_node.max_anisotropy)) + else: + if tex_node.use_mipmap: + samp_res.statements.append(Statement("filter", Token('NEAREST_MIPMAP_NEAREST'))) + else: + samp_res.statements.append(Statement("filter", Token('NEAREST'))) + + return samp_res + + def get_sampler_name(self, tex_node): + name_parts = [] + + use_interpolation = tex_node.interpolation!='Closest' + name_parts.append("linear" if use_interpolation else "nearest") + if tex_node.use_mipmap: + name_parts.append("mip") + if use_interpolation and tex_node.max_anisotropy>1: + name_parts.append("aniso{:g}x".format(tex_node.max_anisotropy)) + + return "_".join(name_parts)+".samp"