X-Git-Url: http://git.tdb.fi/?p=libs%2Fgl.git;a=blobdiff_plain;f=blender%2Fio_mspgl%2Fexport_scene.py;h=a42d8180c1d3bc0255285935617787c6a4b74a78;hp=39a7428e146652018c5db011f2e8007e08d0e06c;hb=6c881bc1ee3c0af5c1bb4b3794dcb23ba096ac12;hpb=57232117bfab90f5dd80131daa47d2f184de9ae2

diff --git a/blender/io_mspgl/export_scene.py b/blender/io_mspgl/export_scene.py
index 39a7428e..a42d8180 100644
--- a/blender/io_mspgl/export_scene.py
+++ b/blender/io_mspgl/export_scene.py
@@ -1,31 +1,27 @@
 import math
 import os
+import itertools
+import mathutils
 
 class SceneExporter:
-	def __init__(self):
-		self.selected_only = False
-		self.visible_only = True
-		self.collection = True
-		self.skip_existing = True
-
-	def export_to_file(self, context, out_fn):
-		from .util import Progress
-		progress = Progress(context)
-
+	def export_to_file(self, ctx, out_fn, *, selected_only=False, visible_only=True, collection=True, skip_existing=True):
 		from .scene import create_scene_from_current
-		scene = create_scene_from_current(context, selected_only=self.selected_only, visible_only=self.visible_only)
+		task = ctx.task("Preparing scene", 0.1)
+		scene = create_scene_from_current(task, selected_only=selected_only, visible_only=visible_only)
 
 		resources = {}
-		self.export_scene_resources(context, scene, resources, progress)
+		task = ctx.task("Exporting resources", 0.9)
+		self.export_scene_resources(task, scene, resources)
+		task = ctx.task(scene, 1.0)
 		scene_res = self.export_scene(scene, resources)
-		progress.set_progress(1.0)
 
 		path, base = os.path.split(out_fn)
 		base, ext = os.path.splitext(base)
 
-		if self.collection:
+		task = ctx.task("Writing files", 1.0)
+		if collection:
 			existing = None
-			if self.skip_existing:
+			if skip_existing:
 				existing = lambda r: not os.path.exists(os.path.join(path, r.name))
 			scene_res.write_collection(out_fn, filter=existing)
 		else:
@@ -33,54 +29,75 @@ class SceneExporter:
 			for r in scene_res.collect_references():
 				r.write_to_file(os.path.join(path, r.name))
 
-	def export_scene_resources(self, context, scene, resources, progress):
+	def export_scene_resources(self, ctx, scene, resources):
 		from .export import DataExporter
 		data_exporter = DataExporter()
 
-		data_exporter.export_resources(context, scene.prototypes, resources, None, progress)
+		data_exporter.export_resources(ctx, [p.object for p in scene.prototypes], resources)
 
 	def export_scene(self, scene, resources):
 		from .datafile import Resource, Statement, Token
 		scene_res = Resource(scene.name+".scene", "scene")
 
-		scene_res.statements.append(Statement("type", Token(scene.scene_type.lower())))
+		if scene.background_set or (scene.instances and scene.blended_instances):
+			scene_res.statements.append(Statement("type", Token("ordered")))
+			if scene.background_set:
+				scene_res.statements.append(scene_res.create_reference_statement("scene", resources[scene.background_set.name+".scene"]))
 
-		for i in scene.instances:
-			obj_res = resources[i.prototype+".object"]
-			st = scene_res.create_reference_statement("object", obj_res, i.name)
+			if scene.instances:
+				st = Statement("scene")
+				st.sub.append(Statement("type", Token("simple")))
+				self.add_instances(scene_res, st.sub, scene.instances, resources)
+				scene_res.statements.append(st)
 
-			ss = Statement("transform")
+			if scene.blended_instances:
+				st = Statement("scene")
+				st.sub.append(Statement("type", Token("zsorted")))
+				self.add_instances(scene_res, st.sub, scene.blended_instances, resources)
+				scene_res.statements.append(st)
+		else:
+			scene_type = "zsorted" if scene.blended_instances else "simple"
+			scene_res.statements.append(Statement("type", Token(scene_type)))
 
-			loc = i.matrix_world.to_translation()
-			ss.sub.append(Statement("position", *tuple(loc)))
+			self.add_instances(scene_res, scene_res.statements, scene.instances, resources)
+			self.add_instances(scene_res, scene_res.statements, scene.blended_instances, resources)
 
-			quat = i.matrix_world.to_quaternion()
-			if i.rotation_mode in ('XYZ', 'XZY', 'YXZ', 'YZX', 'ZXY', 'ZYX'):
-				angles = [a*180/math.pi for a in quat.to_euler()]
-				ss.sub.append(Statement("euler", *angles));
-			else:
-				ss.sub.append(Statement("rotation", quat.angle*180/math.pi, *tuple(quat.axis)))
+		return scene_res
 
-			scale = i.matrix_world.to_scale()
-			ss.sub.append(Statement("scale", *tuple(scale)))
+	def add_instances(self, scene_res, statements, instances, resources):
+		from .datafile import Statement
 
-			st.sub.append(ss)
-			scene_res.statements.append(st)
+		for i in instances:
+			obj_res = resources[i.prototype.name+".object"]
+			st = scene_res.create_reference_statement("object", obj_res)
+			if i.name:
+				st.append(i.name)
 
-		return scene_res
+			st.sub.append(self.create_transform_statement(i))
+			statements.append(st)
 
-	def export_sequence_resources(self, scene, resources):
-		from .datafile import Resource, Statement, Token
+	def create_transform_statement(self, instance):
+		from .datafile import Statement
 
-		if scene.background_set:
-			wrapper_name = scene.name+".wrapper.scene"
-			if wrapper_name not in resources:
-				wrapper_res = Resource(wrapper_name, "scene")
-				wrapper_res.statements.append(Statement("type", Token("ordered")))
-				for s in scene.get_chain():
-					wrapper_res.statements.append(wrapper_res.create_reference_statement("scene", resources[s.name+".scene"]))
+		st = Statement("transform")
 
-				resources[wrapper_name] = wrapper_res
+		loc = instance.matrix_world.to_translation()
+		st.sub.append(Statement("position", *tuple(loc)))
+
+		quat = instance.matrix_world.to_quaternion()
+		if instance.rotation_mode in ('XYZ', 'XZY', 'YXZ', 'YZX', 'ZXY', 'ZYX'):
+			angles = [a*180/math.pi for a in quat.to_euler()]
+			st.sub.append(Statement("euler", *angles));
+		else:
+			st.sub.append(Statement("rotation", quat.angle*180/math.pi, *tuple(quat.axis)))
+
+		scale = instance.matrix_world.to_scale()
+		st.sub.append(Statement("scale", *tuple(scale)))
+
+		return st
+
+	def export_sequence_resources(self, scene, resources):
+		from .datafile import Resource, Statement, Token
 
 		lights = []
 		s = scene
@@ -101,39 +118,184 @@ class SceneExporter:
 		lighting_name = scene.name+".lightn"
 		if lighting_name not in resources:
 			lighting_res = Resource(lighting_name, "lighting")
+			lighting_res.statements.append(Statement("ambient", *tuple(scene.ambient_light)))
 			for l in lights:
 				lighting_res.statements.append(lighting_res.create_reference_statement("light", resources[l.name+".light"]))
 
 			resources[lighting_name] = lighting_res
 
 	def export_sequence(self, scene, resources):
-		from .datafile import Resource, Statement
+		from .datafile import Resource, Statement, Token
 		seq_res = Resource(scene.name+".seq", "sequence")
 
 		if scene.use_hdr:
 			seq_res.statements.append(Statement("hdr", True))
 
-		content = scene
-		if scene.background_set:
-			content = resources[scene.name+".wrapper.scene"]
+		self.add_clear(seq_res.statements, (0.0, 0.0, 0.0, 0.0), 1.0)
+
+		scene_res = resources[scene.name+".scene"]
+		seq_res.statements.append(seq_res.create_reference_statement("renderable", "content", scene_res))
+
+		lighting_res = resources[scene.name+".lightn"]
+
+		any_opaque = False
+		any_blended = False
+		use_ibl = False
+		use_shadow = False
+		shadowed_lights = []
+		shadow_casters = []
+		s = scene
+		while s:
+			if s.instances:
+				any_opaque = True
+			if s.blended_instances:
+				any_blended = True
+			if s.use_ibl:
+				use_ibl = True
+			if s.use_shadow:
+				use_shadow = True
+			shadowed_lights += [l.data for l in s.lights if l.data.use_shadow]
+			for i in itertools.chain(s.instances, s.blended_instances):
+				o = i.prototype.object
+				if o.material_slots and o.material_slots[0].material and o.material_slots[0].material.shadow_method!='NONE':
+					shadow_casters.append(i)
+			s = s.background_set
+
+		shadowed_lights.sort(key=lambda l:l.shadow_map_size, reverse=True)
+
+		main_tags = []
+		if any_opaque:
+			main_tags.append("")
+		if any_blended:
+			main_tags.append("blended")
+
+		content = "content"
+		if use_ibl and scene.use_sky:
+			self.add_auxiliary_sequence(seq_res, "environment", "sky", ((0.0, 0.0, 0.0, 0.0), 1.0), main_tags, lighting_res)
 
-		ss = Statement("pass", "", "content")
-		ss.sub.append(Statement("depth_test", "lequal"))
-		ss.sub.append(seq_res.create_reference_statement("lighting", resources[scene.name+".lightn"]))
-		ss.sub.append(seq_res.create_reference_statement("scene", content))
-		seq_res.statements.append(ss)
+			st = Statement("effect", "environment")
+			st.sub.append(Statement("type", Token("environment_map")))
+			st.sub.append(Statement("size", 32))
+			st.sub.append(Statement("roughness_levels", 2))
+			st.sub.append(Statement("fixed_position", 0.0, 0.0, 0.0))
+			st.sub.append(Statement("content", content))
+			st.sub.append(Statement("environment", "environment_sequence"))
+
+			seq_res.statements.append(st)
+			content = "environment"
+
+		if scene.use_sky:
+			st = Statement("effect", "sky")
+			st.sub.append(Statement("type", Token("sky")))
+			st.sub.append(seq_res.create_reference_statement("sun", resources[scene.sun_light.name+".light"]))
+			st.sub.append(Statement("content", content))
+
+			seq_res.statements.append(st)
+			content = "sky"
+
+		if use_shadow:
+			self.add_auxiliary_sequence(seq_res, "shadow", "content", (None, 1.0), ["shadow"], None)
+			self.add_auxiliary_sequence(seq_res, "thsm", "content", (None, 1.0), ["shadow_thsm"], None)
+
+			st = Statement("effect", "shadow_map")
+			st.sub.append(Statement("type", Token("shadow_map")))
+			st.sub.append(Statement("enable_for_method", "blended"))
+			st.sub.append(Statement("size", *self.compute_shadowmap_size(shadowed_lights)))
+			target, radius = self.compute_bounding_sphere(shadow_casters)
+			st.sub.append(Statement("target", *target))
+			st.sub.append(Statement("radius", radius))
+			st.sub.append(Statement("content", content))
+			st.sub.append(seq_res.create_reference_statement("lighting", lighting_res))
+			for l in shadowed_lights:
+				ss = seq_res.create_reference_statement("light", resources[l.name+".light"])
+				ss.sub.append(Statement("size", int(l.shadow_map_size)))
+				shadow_caster = "thsm_sequence" if l.type=='POINT' else "shadow_sequence"
+				ss.sub.append(Statement("shadow_caster", shadow_caster))
+				st.sub.append(ss)
+
+			seq_res.statements.append(st)
+			content = "shadow_map"
+
+		self.add_content_steps(seq_res, content, lighting_res, main_tags)
+
+		if scene.use_ao:
+			ss = Statement("postprocessor")
+			ss.sub.append(Statement("type", Token("ambient_occlusion")))
+			ss.sub.append(Statement("occlusion_radius", scene.ao_distance))
+			ss.sub.append(Statement("samples", scene.ao_samples))
+			seq_res.statements.append(ss)
 
 		if scene.use_hdr:
-			seq_res.statements.append(Statement("bloom"))
-			ss = Statement("colorcurve")
+			ss = Statement("postprocessor")
+			ss.sub.append(Statement("type", Token("bloom")))
+			seq_res.statements.append(ss)
+
+			ss = Statement("postprocessor")
+			ss.sub.append(Statement("type", Token("colorcurve")))
 			ss.sub.append(Statement("exposure_adjust", scene.exposure))
 			ss.sub.append(Statement("srgb"))
 			seq_res.statements.append(ss)
 		else:
 			# Add a colorcurve with linear response to convert into sRGB color space
-			ss = Statement("colorcurve")
+			ss = Statement("postprocessor")
+			ss.sub.append(Statement("type", Token("colorcurve")))
 			ss.sub.append(Statement("brightness_response", 1.0))
 			ss.sub.append(Statement("srgb"))
 			seq_res.statements.append(ss)
 
 		return seq_res
+
+	def add_clear(self, statements, color, depth):
+		from .datafile import Statement
+
+		st = Statement("clear")
+		if color is not None:
+			st.sub.append(Statement("color", *color))
+		if depth is not None:
+			st.sub.append(Statement("depth", depth))
+		statements.append(st)
+
+	def add_content_steps(self, seq_res, renderable, lighting, tags):
+		from .datafile import Statement, Token
+
+		for t in tags:
+			st = Statement("step", t, renderable)
+			st.sub.append(Statement("depth_test", Token("LEQUAL")))
+			if lighting:
+				st.sub.append(seq_res.create_reference_statement("lighting", lighting))
+			seq_res.statements.append(st)
+
+	def add_auxiliary_sequence(self, seq_res, aux_name, content, clear_values, step_tags, lighting):
+		seq_name = os.path.splitext(seq_res.name)[0]
+
+		from .datafile import Resource, Statement
+		aux_seq_res = Resource("{}_{}.seq".format(seq_name, aux_name), "sequence")
+		self.add_clear(aux_seq_res.statements, *clear_values)
+		aux_seq_res.statements.append(Statement("renderable", "content"))
+		self.add_content_steps(aux_seq_res, "content", lighting, step_tags)
+
+		st = seq_res.create_reference_statement("sequence", aux_name+"_sequence", aux_seq_res)
+		st.sub.append(Statement("renderable", "content", content))
+		seq_res.statements.append(st)
+
+	def compute_shadowmap_size(self, lights):
+		total_area = 0
+		for l in lights:
+			s = int(l.shadow_map_size)
+			total_area += s*s
+
+		size = 1
+		while size*size<total_area:
+			size *= 2
+		if size*size>total_area*2:
+			return (size, size//2)
+		else:
+			return (size, size)
+
+	def compute_bounding_sphere(self, instances):
+		points = []
+		for i in instances:
+			points += [i.matrix_world@mathutils.Vector(c) for c in i.prototype.object.bound_box]
+
+		from .util import compute_bounding_sphere
+		return compute_bounding_sphere(points)