export_fbx_bin.py

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#
#  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.
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#  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.
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#  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.
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# ##### END GPL LICENSE BLOCK #####

# <pep8 compliant>

# Script copyright (C) Campbell Barton, Bastien Montagne


import array
import datetime
import math
import os
import time

import collections
from collections import namedtuple, OrderedDict
import itertools
from itertools import zip_longest, chain

import bpy
import bpy_extras
from bpy.types import Object, Bone
from mathutils import Vector, Matrix

from . import encode_bin, data_types


# "Constants"
FBX_VERSION = 7400
FBX_HEADER_VERSION = 1003
FBX_SCENEINFO_VERSION = 100
FBX_TEMPLATES_VERSION = 100

FBX_MODELS_VERSION = 232

FBX_GEOMETRY_VERSION = 124
FBX_GEOMETRY_NORMAL_VERSION = 102
FBX_GEOMETRY_BINORMAL_VERSION = 102
FBX_GEOMETRY_TANGENT_VERSION = 102
FBX_GEOMETRY_SMOOTHING_VERSION = 102
FBX_GEOMETRY_VCOLOR_VERSION = 101
FBX_GEOMETRY_UV_VERSION = 101
FBX_GEOMETRY_MATERIAL_VERSION = 101
FBX_GEOMETRY_LAYER_VERSION = 100
FBX_POSE_BIND_VERSION = 100
FBX_DEFORMER_SKIN_VERSION = 101
FBX_DEFORMER_CLUSTER_VERSION = 100
FBX_MATERIAL_VERSION = 102
FBX_TEXTURE_VERSION = 202

FBX_NAME_CLASS_SEP = b"\x00\x01"

FBX_KTIME = 46186158000  # This is the number of "ktimes" in one second (yep, precision over the nanosecond...)


MAT_CONVERT_LAMP = Matrix.Rotation(math.pi / 2.0, 4, 'X')  # Blender is -Z, FBX is -Y.
MAT_CONVERT_CAMERA = Matrix.Rotation(math.pi / 2.0, 4, 'Y')  # Blender is -Z, FBX is +X.
#MAT_CONVERT_BONE = Matrix.Rotation(math.pi / -2.0, 4, 'X')  # Blender is +Y, FBX is +Z.
MAT_CONVERT_BONE = Matrix()


# Lamps.
FBX_LIGHT_TYPES = {
    'POINT': 0,  # Point.
    'SUN': 1,    # Directional.
    'SPOT': 2,   # Spot.
    'HEMI': 1,   # Directional.
    'AREA': 3,   # Area.
}
FBX_LIGHT_DECAY_TYPES = {
    'CONSTANT': 0,                   # None.
    'INVERSE_LINEAR': 1,             # Linear.
    'INVERSE_SQUARE': 2,             # Quadratic.
    'CUSTOM_CURVE': 2,               # Quadratic.
    'LINEAR_QUADRATIC_WEIGHTED': 2,  # Quadratic.
}


##### Misc utilities #####

# Note: this could be in a utility (math.units e.g.)...

UNITS = {
    "meter": 1.0,  # Ref unit!
    "kilometer": 0.001,
    "millimeter": 1000.0,
    "foot": 1.0 / 0.3048,
    "inch": 1.0 / 0.0254,
    "turn": 1.0,  # Ref unit!
    "degree": 360.0,
    "radian": math.pi * 2.0,
    "second": 1.0,  # Ref unit!
    "ktime": FBX_KTIME,
}


def units_convert(val, u_from, u_to):
    """Convert value."""
    conv = UNITS[u_to] / UNITS[u_from]
    return val * conv


def units_convert_iter(it, u_from, u_to):
    """Convert value."""
    conv = UNITS[u_to] / UNITS[u_from]
    return (v * conv for v in it)


def matrix_to_array(mat):
    """Concatenate matrix's columns into a single, flat tuple"""
    # blender matrix is row major, fbx is col major so transpose on write
    return tuple(f for v in mat.transposed() for f in v)


RIGHT_HAND_AXES = {
    # Up, Front -> FBX values (tuples of (axis, sign), Up, Front, Coord).
    # Note: Since we always stay in right-handed system, third coord sign is always positive!
    ('X',  'Y'):  ((0, 1),  (1, 1),  (2, 1)),
    ('X',  '-Y'): ((0, 1),  (1, -1), (2, 1)),
    ('X',  'Z'):  ((0, 1),  (2, 1),  (1, 1)),
    ('X',  '-Z'): ((0, 1),  (2, -1), (1, 1)),
    ('-X', 'Y'):  ((0, -1), (1, 1),  (2, 1)),
    ('-X', '-Y'): ((0, -1), (1, -1), (2, 1)),
    ('-X', 'Z'):  ((0, -1), (2, 1),  (1, 1)),
    ('-X', '-Z'): ((0, -1), (2, -1), (1, 1)),
    ('Y',  'X'):  ((1, 1),  (0, 1),  (2, 1)),
    ('Y',  '-X'): ((1, 1),  (0, -1), (2, 1)),
    ('Y',  'Z'):  ((1, 1),  (2, 1),  (0, 1)),
    ('Y',  '-Z'): ((1, 1),  (2, -1), (0, 1)),
    ('-Y', 'X'):  ((1, -1), (0, 1),  (2, 1)),
    ('-Y', '-X'): ((1, -1), (0, -1), (2, 1)),
    ('-Y', 'Z'):  ((1, -1), (2, 1),  (0, 1)),
    ('-Y', '-Z'): ((1, -1), (2, -1), (0, 1)),
    ('Z',  'X'):  ((2, 1),  (0, 1),  (1, 1)),
    ('Z',  '-X'): ((2, 1),  (0, -1), (1, 1)),
    ('Z',  'Y'):  ((2, 1),  (1, 1),  (0, 1)),  # Blender system!
    ('Z',  '-Y'): ((2, 1),  (1, -1), (0, 1)),
    ('-Z', 'X'):  ((2, -1), (0, 1),  (1, 1)),
    ('-Z', '-X'): ((2, -1), (0, -1), (1, 1)),
    ('-Z', 'Y'):  ((2, -1), (1, 1),  (0, 1)),
    ('-Z', '-Y'): ((2, -1), (1, -1), (0, 1)),
}


##### UIDs code. #####

# ID class (mere int).
class UID(int):
    pass


# UIDs storage.
_keys_to_uids = {}
_uids_to_keys = {}


def _key_to_uid(uids, key):
    # TODO: Check this is robust enough for our needs!
    # Note: We assume we have already checked the related key wasn't yet in _keys_to_uids!
    #       As int64 is signed in FBX, we keep uids below 2**63...
    if isinstance(key, int) and 0 <= key < 2**63:
        # We can use value directly as id!
        uid = key
    else:
        uid = hash(key)
        if uid < 0:
            uid = -uid
        if uid >= 2**63:
            uid //= 2
    # Make sure our uid *is* unique.
    if uid in uids:
        inc = 1 if uid < 2**62 else -1
        while uid in uids:
            uid += inc
            if 0 > uid >= 2**63:
                # Note that this is more that unlikely, but does not harm anyway...
                raise ValueError("Unable to generate an UID for key {}".format(key))
    return UID(uid)


def get_fbxuid_from_key(key):
    """
    Return an UID for given key, which is assumed hasable.
    """
    uid = _keys_to_uids.get(key, None)
    if uid is None:
        uid = _key_to_uid(_uids_to_keys, key)
        _keys_to_uids[key] = uid
        _uids_to_keys[uid] = key
    return uid


# XXX Not sure we'll actually need this one?
def get_key_from_fbxuid(uid):
    """
    Return the key which generated this uid.
    """
    assert(uid.__class__ == UID)
    return _uids_to_keys.get(uid, None)


# Blender-specific key generators
def get_blenderID_key(bid):
    return "B" + bid.rna_type.name + "::" + bid.name


def get_blender_bone_key(armature, bone):
    """Return bone's keys (Model and NodeAttribute)."""
    key = "|".join((get_blenderID_key(armature), get_blenderID_key(bone)))
    return key, key + "_Data"


def get_blender_armature_bindpose_key(armature, mesh):
    """Return armature's bindpose key."""
    return "|".join((get_blenderID_key(armature), get_blenderID_key(mesh), "BindPose"))


def get_blender_armature_skin_key(armature, mesh):
    """Return armature's skin key."""
    return "|".join((get_blenderID_key(armature), get_blenderID_key(mesh), "DeformerSkin"))


def get_blender_bone_cluster_key(armature, mesh, bone):
    """Return bone's cluster key."""
    return "|".join((get_blenderID_key(armature), get_blenderID_key(mesh),
                     get_blenderID_key(bone), "SubDeformerCluster"))


##### Element generators. #####

# Note: elem may be None, in this case the element is not added to any parent.
def elem_empty(elem, name):
    sub_elem = encode_bin.FBXElem(name)
    if elem is not None:
        elem.elems.append(sub_elem)
    return sub_elem


def elem_properties(elem):
    return elem_empty(elem, b"Properties70")


def _elem_data_single(elem, name, value, func_name):
    sub_elem = elem_empty(elem, name)
    getattr(sub_elem, func_name)(value)
    return sub_elem


def _elem_data_vec(elem, name, value, func_name):
    sub_elem = elem_empty(elem, name)
    func = getattr(sub_elem, func_name)
    for v in value:
        func(v)
    return sub_elem


def elem_data_single_bool(elem, name, value):
    return _elem_data_single(elem, name, value, "add_bool")


def elem_data_single_int16(elem, name, value):
    return _elem_data_single(elem, name, value, "add_int16")


def elem_data_single_int32(elem, name, value):
    return _elem_data_single(elem, name, value, "add_int32")


def elem_data_single_int64(elem, name, value):
    return _elem_data_single(elem, name, value, "add_int64")


def elem_data_single_float32(elem, name, value):
    return _elem_data_single(elem, name, value, "add_float32")


def elem_data_single_float64(elem, name, value):
    return _elem_data_single(elem, name, value, "add_float64")


def elem_data_single_bytes(elem, name, value):
    return _elem_data_single(elem, name, value, "add_bytes")


def elem_data_single_string(elem, name, value):
    return _elem_data_single(elem, name, value, "add_string")


def elem_data_single_string_unicode(elem, name, value):
    return _elem_data_single(elem, name, value, "add_string_unicode")


def elem_data_single_bool_array(elem, name, value):
    return _elem_data_single(elem, name, value, "add_bool_array")


def elem_data_single_int32_array(elem, name, value):
    return _elem_data_single(elem, name, value, "add_int32_array")


def elem_data_single_int64_array(elem, name, value):
    return _elem_data_single(elem, name, value, "add_int64_array")


def elem_data_single_float32_array(elem, name, value):
    return _elem_data_single(elem, name, value, "add_float32_array")


def elem_data_single_float64_array(elem, name, value):
    return _elem_data_single(elem, name, value, "add_float64_array")


def elem_data_single_byte_array(elem, name, value):
    return _elem_data_single(elem, name, value, "add_byte_array")


def elem_data_vec_float64(elem, name, value):
    return _elem_data_vec(elem, name, value, "add_float64")

##### Generators for standard FBXProperties70 properties. #####

# Properties definitions, format: (b"type_1", b"label(???)", "name_set_value_1", "name_set_value_2", ...)
# XXX Looks like there can be various variations of formats here... Will have to be checked ultimately!
#     Also, those "custom" types like 'FieldOfView' or 'Lcl Translation' are pure nonsense,
#     these are just Vector3D ultimately... *sigh* (again).
FBX_PROPERTIES_DEFINITIONS = {
    "p_bool": (b"bool", b"", "add_int32"),  # Yes, int32 for a bool (and they do have a core bool type)!!!
    "p_integer": (b"int", b"Integer", "add_int32"),
    "p_enum": (b"enum", b"", "add_int32"),
    "p_number": (b"double", b"Number", "add_float64"),
    "p_visibility": (b"Visibility", b"", "add_float64"),
    "p_fov": (b"FieldOfView", b"", "add_float64"),
    "p_fov_x": (b"FieldOfViewX", b"", "add_float64"),
    "p_fov_y": (b"FieldOfViewY", b"", "add_float64"),
    "p_vector_3d": (b"Vector3D", b"Vector", "add_float64", "add_float64", "add_float64"),
    "p_lcl_translation": (b"Lcl Translation", b"", "add_float64", "add_float64", "add_float64"),
    "p_lcl_rotation": (b"Lcl Rotation", b"", "add_float64", "add_float64", "add_float64"),
    "p_lcl_scaling": (b"Lcl Scaling", b"", "add_float64", "add_float64", "add_float64"),
    "p_color_rgb": (b"ColorRGB", b"Color", "add_float64", "add_float64", "add_float64"),
    "p_string": (b"KString", b"", "add_string_unicode"),
    "p_string_url": (b"KString", b"Url", "add_string_unicode"),
    "p_timestamp": (b"KTime", b"Time", "add_int64"),
    "p_datetime": (b"DateTime", b"", "add_string_unicode"),
    "p_object": (b"object", b""),  # XXX Check this! No value for this prop???
    "p_compound": (b"Compound", b""),
}


def _elem_props_set(elem, ptype, name, value, flags):
    p = elem_data_single_string(elem, b"P", name)
    for t in ptype[:2]:
        p.add_string(t)
    p.add_string(flags)
    if len(ptype) == 3:
        getattr(p, ptype[2])(value)
    elif len(ptype) > 3:
        # We assume value is iterable, else it's a bug!
        for callback, val in zip(ptype[2:], value):
            getattr(p, callback)(val)


def _elem_props_flags(animatable, custom):
    if animatable and custom:
        return b"AU"
    elif animatable:
        return b"A"
    elif custom:
        return b"U"
    return b""


def elem_props_set(elem, ptype, name, value=None, animatable=False, custom=False):
    ptype = FBX_PROPERTIES_DEFINITIONS[ptype]
    _elem_props_set(elem, ptype, name, value, _elem_props_flags(animatable, custom))


def elem_props_compound(elem, cmpd_name, custom=False):
    def _setter(ptype, name, value, animatable=False, custom=False):
        name = cmpd_name + b"|" + name
        elem_props_set(elem, ptype, name, value, animatable=animatable, custom=custom)

    elem_props_set(elem, "p_compound", cmpd_name, custom=custom)
    return _setter


def elem_props_template_set(template, elem, ptype_name, name, value, animatable=False):
    """
    Only add a prop if the same value is not already defined in given template.
    Note it is important to not give iterators as value, here!
    """
    ptype = FBX_PROPERTIES_DEFINITIONS[ptype_name]
    tmpl_val, tmpl_ptype, tmpl_animatable = template.properties.get(name, (None, None, False))
    # Note animatable flag from template takes precedence over given one, if applicable.
    if tmpl_ptype is not None:
        if ((len(ptype) == 3 and (tmpl_val, tmpl_ptype) == (value, ptype_name)) or
                (len(ptype) > 3 and (tuple(tmpl_val), tmpl_ptype) == (tuple(value), ptype_name))):
            return  # Already in template and same value.
        _elem_props_set(elem, ptype, name, value, _elem_props_flags(tmpl_animatable, False))
    else:
        _elem_props_set(elem, ptype, name, value, _elem_props_flags(animatable, False))


##### Generators for connection elements. #####

def elem_connection(elem, c_type, uid_src, uid_dst, prop_dst=None):
    e = elem_data_single_string(elem, b"C", c_type)
    e.add_int64(uid_src)
    e.add_int64(uid_dst)
    if prop_dst is not None:
        e.add_string(prop_dst)


##### Templates #####
# TODO: check all those "default" values, they should match Blender's default as much as possible, I guess?

FBXTemplate = namedtuple("FBXTemplate", ("type_name", "prop_type_name", "properties", "nbr_users"))


def fbx_templates_generate(root, fbx_templates):
    # We may have to gather different templates in the same node (e.g. NodeAttribute template gathers properties
    # for Lights, Cameras, LibNodes, etc.).
    templates = OrderedDict()
    for type_name, prop_type_name, properties, nbr_users in fbx_templates.values():
        if type_name not in templates:
            templates[type_name] = [OrderedDict(((prop_type_name, properties),)), nbr_users]
        else:
            templates[type_name][0][prop_type_name] = properties
            templates[type_name][1] += nbr_users

    for type_name, (subprops, nbr_users) in templates.items():
        template = elem_data_single_string(root, b"ObjectType", type_name)
        elem_data_single_int32(template, b"Count", nbr_users)

        for prop_type_name, properties in subprops.items():
            if prop_type_name and properties:
                elem = elem_data_single_string(template, b"PropertyTemplate", prop_type_name)
                props = elem_properties(elem)
                for name, (value, ptype, animatable) in properties.items():
                    elem_props_set(props, ptype, name, value, animatable=animatable)


def fbx_template_def_globalsettings(scene, settings, override_defaults=None, nbr_users=0):
    props = OrderedDict()
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"GlobalSettings", b"", props, nbr_users)


def fbx_template_def_model(scene, settings, override_defaults=None, nbr_users=0):
    gscale = settings.global_scale
    props = OrderedDict((
        # Name,                     Value, Type,     Animatable
        (b"QuaternionInterpolate", (False, "p_bool", False)),
        (b"RotationOffset", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"RotationPivot", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"ScalingOffset", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"ScalingPivot", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"TranslationActive", (False, "p_bool", False)),
        (b"TranslationMin", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"TranslationMax", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"TranslationMinX", (False, "p_bool", False)),
        (b"TranslationMinY", (False, "p_bool", False)),
        (b"TranslationMinZ", (False, "p_bool", False)),
        (b"TranslationMaxX", (False, "p_bool", False)),
        (b"TranslationMaxY", (False, "p_bool", False)),
        (b"TranslationMaxZ", (False, "p_bool", False)),
        (b"RotationOrder", (0, "p_enum", False)),  # we always use 'XYZ' order.
        (b"RotationSpaceForLimitOnly", (False, "p_bool", False)),
        (b"RotationStiffnessX", (0.0, "p_number", False)),
        (b"RotationStiffnessY", (0.0, "p_number", False)),
        (b"RotationStiffnessZ", (0.0, "p_number", False)),
        (b"AxisLen", (10.0, "p_number", False)),
        (b"PreRotation", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"PostRotation", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"RotationActive", (False, "p_bool", False)),
        (b"RotationMin", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"RotationMax", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"RotationMinX", (False, "p_bool", False)),
        (b"RotationMinY", (False, "p_bool", False)),
        (b"RotationMinZ", (False, "p_bool", False)),
        (b"RotationMaxX", (False, "p_bool", False)),
        (b"RotationMaxY", (False, "p_bool", False)),
        (b"RotationMaxZ", (False, "p_bool", False)),
        (b"InheritType", (1, "p_enum", False)),  # RSrs
        (b"ScalingActive", (False, "p_bool", False)),
        (b"ScalingMin", (Vector((1.0, 1.0, 1.0)) * gscale, "p_vector_3d", False)),
        (b"ScalingMax", (Vector((1.0, 1.0, 1.0)) * gscale, "p_vector_3d", False)),
        (b"ScalingMinX", (False, "p_bool", False)),
        (b"ScalingMinY", (False, "p_bool", False)),
        (b"ScalingMinZ", (False, "p_bool", False)),
        (b"ScalingMaxX", (False, "p_bool", False)),
        (b"ScalingMaxY", (False, "p_bool", False)),
        (b"ScalingMaxZ", (False, "p_bool", False)),
        (b"GeometricTranslation", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"GeometricRotation", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"GeometricScaling", (Vector((1.0, 1.0, 1.0)) * gscale, "p_vector_3d", False)),
        (b"MinDampRangeX", (0.0, "p_number", False)),
        (b"MinDampRangeY", (0.0, "p_number", False)),
        (b"MinDampRangeZ", (0.0, "p_number", False)),
        (b"MaxDampRangeX", (0.0, "p_number", False)),
        (b"MaxDampRangeY", (0.0, "p_number", False)),
        (b"MaxDampRangeZ", (0.0, "p_number", False)),
        (b"MinDampStrengthX", (0.0, "p_number", False)),
        (b"MinDampStrengthY", (0.0, "p_number", False)),
        (b"MinDampStrengthZ", (0.0, "p_number", False)),
        (b"MaxDampStrengthX", (0.0, "p_number", False)),
        (b"MaxDampStrengthY", (0.0, "p_number", False)),
        (b"MaxDampStrengthZ", (0.0, "p_number", False)),
        (b"PreferedAngleX", (0.0, "p_number", False)),
        (b"PreferedAngleY", (0.0, "p_number", False)),
        (b"PreferedAngleZ", (0.0, "p_number", False)),
        (b"LookAtProperty", (None, "p_object", False)),
        (b"UpVectorProperty", (None, "p_object", False)),
        (b"Show", (True, "p_bool", False)),
        (b"NegativePercentShapeSupport", (True, "p_bool", False)),
        (b"DefaultAttributeIndex", (0, "p_integer", False)),
        (b"Freeze", (False, "p_bool", False)),
        (b"LODBox", (False, "p_bool", False)),
        (b"Lcl Translation", ((0.0, 0.0, 0.0), "p_lcl_translation", True)),
        (b"Lcl Rotation", ((0.0, 0.0, 0.0), "p_lcl_rotation", True)),
        (b"Lcl Scaling", (Vector((1.0, 1.0, 1.0)) * gscale, "p_lcl_scaling", True)),
        (b"Visibility", (1.0, "p_visibility", True)),
    ))
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"Model", b"FbxNode", props, nbr_users)


def fbx_template_def_light(scene, settings, override_defaults=None, nbr_users=0):
    gscale = settings.global_scale
    props = OrderedDict((
        (b"LightType", (0, "p_enum", False)),  # Point light.
        (b"CastLight", (True, "p_bool", False)),
        (b"Color", ((1.0, 1.0, 1.0), "p_color_rgb", True)),
        (b"Intensity", (100.0, "p_number", True)),  # Times 100 compared to Blender values...
        (b"DecayType", (2, "p_enum", False)),  # Quadratic.
        (b"DecayStart", (30.0 * gscale, "p_number", False)),
        (b"CastShadows", (True, "p_bool", False)),
        (b"ShadowColor", ((0.0, 0.0, 0.0), "p_color_rgb", True)),
        (b"AreaLightShape", (0, "p_enum", False)),  # Rectangle.
    ))
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"NodeAttribute", b"FbxLight", props, nbr_users)


def fbx_template_def_camera(scene, settings, override_defaults=None, nbr_users=0):
    props = OrderedDict()  # TODO!!!
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"NodeAttribute", b"FbxCamera", props, nbr_users)


def fbx_template_def_bone(scene, settings, override_defaults=None, nbr_users=0):
    props = OrderedDict()
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"NodeAttribute", b"LimbNode", props, nbr_users)


def fbx_template_def_geometry(scene, settings, override_defaults=None, nbr_users=0):
    props = OrderedDict((
        (b"Color", ((0.8, 0.8, 0.8), "p_color_rgb", False)),
        (b"BBoxMin", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"BBoxMax", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"Primary Visibility", (True, "p_bool", False)),
        (b"Casts Shadows", (True, "p_bool", False)),
        (b"Receive Shadows", (True, "p_bool", False)),
))
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"Geometry", b"FbxMesh", props, nbr_users)


def fbx_template_def_material(scene, settings, override_defaults=None, nbr_users=0):
    # WIP...
    props = OrderedDict((
        (b"ShadingModel", ("phong", "p_string", False)),
        (b"MultiLayer", (False, "p_bool", False)),
        # Lambert-specific.
        (b"EmissiveColor", ((0.8, 0.8, 0.8), "p_color_rgb", True)),  # Same as diffuse.
        (b"EmissiveFactor", (0.0, "p_number", True)),
        (b"AmbientColor", ((0.0, 0.0, 0.0), "p_color_rgb", True)),
        (b"AmbientFactor", (1.0, "p_number", True)),
        (b"DiffuseColor", ((0.8, 0.8, 0.8), "p_color_rgb", True)),
        (b"DiffuseFactor", (0.8, "p_number", True)),
        (b"TransparentColor", ((0.8, 0.8, 0.8), "p_color_rgb", True)),  # Same as diffuse.
        (b"TransparencyFactor", (0.0, "p_number", True)),
        (b"Opacity", (1.0, "p_number", True)),
        (b"NormalMap", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"Bump", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"BumpFactor", (1.0, "p_number", False)),
        (b"DisplacementColor", ((0.0, 0.0, 0.0), "p_color_rgb", False)),
        (b"DisplacementFactor", (0.0, "p_number", False)),
        # Phong-specific.
        (b"SpecularColor", ((1.0, 1.0, 1.0), "p_color_rgb", True)),
        (b"SpecularFactor", (0.5 / 2.0, "p_number", True)),
        # Not sure about the name, importer uses this (but ShininessExponent for tex prop name!)
        # And in fbx exported by sdk, you have one in template, the other in actual material!!! :/
        # For now, using both.
        (b"Shininess", ((50.0 - 1.0) / 5.10, "p_number", True)),
        (b"ShininessExponent", ((50.0 - 1.0) / 5.10, "p_number", True)),
        (b"ReflectionColor", ((1.0, 1.0, 1.0), "p_color_rgb", True)),
        (b"ReflectionFactor", (0.0, "p_number", True)),
    ))
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"Material", b"FbxSurfacePhong", props, nbr_users)


def fbx_template_def_texture_file(scene, settings, override_defaults=None, nbr_users=0):
    # WIP...
    # XXX Not sure about all names!
    props = OrderedDict((
        (b"TextureTypeUse", (0, "p_enum", False)),  # Standard.
        (b"AlphaSource", (2, "p_enum", False)),  # Black (i.e. texture's alpha), XXX name guessed!.
        (b"Texture alpha", (1.0, "p_number", False)),
        (b"PremultiplyAlpha", (False, "p_bool", False)),
        (b"CurrentTextureBlendMode", (0, "p_enum", False)),  # Translucent, assuming this means "Alpha over"!
        (b"CurrentMappingType", (1, "p_enum", False)),  # Planar.
        (b"WrapModeU", (0, "p_enum", False)),  # Repeat.
        (b"WrapModeV", (0, "p_enum", False)),  # Repeat.
        (b"UVSwap", (False, "p_bool", False)),
        (b"Translation", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"Rotation", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"Scaling", ((1.0, 1.0, 1.0), "p_vector_3d", False)),
        (b"TextureRotationPivot", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        (b"TextureScalingPivot", ((0.0, 0.0, 0.0), "p_vector_3d", False)),
        # Not sure about those two... At least, UseMaterial should always be ON imho.
        (b"UseMaterial", (True, "p_bool", False)),
        (b"UseMipMap", (False, "p_bool", False)),
    ))
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"Texture", b"FbxFileTexture", props, nbr_users)


def fbx_template_def_video(scene, settings, override_defaults=None, nbr_users=0):
    # WIP...
    props = OrderedDict((
        # All pictures.
        (b"Width", (0, "p_integer", False)),
        (b"Height", (0, "p_integer", False)),
        (b"Path", ("", "p_string_url", False)),
        (b"AccessMode", (0, "p_enum", False)),  # Disk (0=Disk, 1=Mem, 2=DiskAsync).
        # All videos.
        (b"StartFrame", (0, "p_integer", False)),
        (b"StopFrame", (0, "p_integer", False)),
        (b"Offset", (0, "p_timestamp", False)),
        (b"PlaySpeed", (1.0, "p_number", False)),
        (b"FreeRunning", (False, "p_bool", False)),
        (b"Loop", (False, "p_bool", False)),
        (b"InterlaceMode", (0, "p_enum", False)),  # None, i.e. progressive.
        # Image sequences.
        (b"ImageSequence", (False, "p_bool", False)),
        (b"ImageSequenceOffset", (0, "p_integer", False)),
        (b"FrameRate", (scene.render.fps / scene.render.fps_base, "p_number", False)),
        (b"LastFrame", (0, "p_integer", False)),
    ))
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"Video", b"FbxVideo", props, nbr_users)


def fbx_template_def_pose(scene, settings, override_defaults=None, nbr_users=0):
    props = OrderedDict()
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"Pose", b"", props, nbr_users)


def fbx_template_def_deformer(scene, settings, override_defaults=None, nbr_users=0):
    props = OrderedDict()
    if override_defaults is not None:
        props.update(override_defaults)
    return FBXTemplate(b"Deformer", b"", props, nbr_users)


##### FBX objects generators. #####
def has_valid_parent(scene_data, obj):
    return obj.parent and obj.parent in scene_data.objects


def use_bake_space_transform(scene_data, obj):
    # NOTE: Only applies to object types supporting this!!! Currently, only meshes...
    #       Also, do not apply it to children objects.
    # TODO: Check whether this can work for bones too...
    return (scene_data.settings.bake_space_transform and not isinstance(obj, Bone) and
            obj.type in {'MESH'} and not has_valid_parent(scene_data, obj))


def object_matrix(scene_data, obj, armature=None, local_space=False, global_space=False):
    """
    Generate object transform matrix (*always* in matching *FBX* space!).
    If local_space is True, returned matrix is *always* in local space.
    Else:
        If global_space is True, returned matrix is always in world space.
        If global_space is False, returned matrix is in parent space if parent is valid, else in world space.
    Note local_space has precedence over global_space.
    If obj is a bone, and global_space is True, armature must be provided (it's the bone's armature object!).
    Applies specific rotation to bones, lamps and cameras (conversion Blender -> FBX).
    """
    is_bone = isinstance(obj, Bone)
    # Objects which are not bones and do not have any parent are *always* in global space (unless local_space is True!).
    is_global = not local_space and (global_space or not (is_bone or has_valid_parent(scene_data, obj)))

    #assert((is_bone and is_global and armature is None) == False,
           #"You must provide an armature object to get bones transform matrix in global space!")

    matrix = obj.matrix_local

    # Lamps, cameras and bones need to be rotated (in local space!).
    if is_bone:
        matrix = matrix * MAT_CONVERT_BONE
    elif obj.type == 'LAMP':
        matrix = matrix * MAT_CONVERT_LAMP
    elif obj.type == 'CAMERA':
        matrix = matrix * MAT_CONVERT_CAMERA

    # Up till here, our matrix is in local space, time to bring it in its final desired space.
    if is_bone:
        # Bones are in armature (object) space currently, either bring them to global space or real
        # local space (relative to parent bone).
        if is_global:
            matrix = armature.matrix_world * matrix
        elif obj.parent:  # Parent bone, get matrix relative to it.
            par_matrix = obj.parent.matrix_local * MAT_CONVERT_BONE
            matrix = par_matrix.inverted() * matrix
    elif obj.parent:
        if is_global:
            # Move matrix to global Blender space.
            matrix = obj.parent.matrix_world * matrix
        elif use_bake_space_transform(scene_data, obj.parent):
            # Blender's and FBX's local space of parent may differ if we use bake_space_transform...
            # Apply parent's *Blender* local space...
            matrix = obj.parent.matrix_local * matrix
            # ...and move it back into parent's *FBX* local space.
            par_mat = object_matrix(scene_data, obj.parent, local_space=True)
            matrix = par_mat.inverted() * matrix

    if use_bake_space_transform(scene_data, obj):
        # If we bake the transforms we need to post-multiply inverse global transform.
        # This means that the global transform will not apply to children of this transform.
        matrix = matrix * scene_data.settings.global_matrix_inv
    if is_global:
        # In any case, pre-multiply the global matrix to get it in FBX global space!
        matrix = scene_data.settings.global_matrix * matrix

    return matrix


def object_tx(scene_data, obj):
    """
    Generate object transform data (always in local space when possible).
    """
    matrix = object_matrix(scene_data, obj)
    loc, rot, scale = matrix.decompose()
    matrix_rot = rot.to_matrix()
    rot = rot.to_euler()  # quat -> euler, we always use 'XYZ' order.

    return loc, rot, scale, matrix, matrix_rot


def fbx_name_class(name, cls):
    return FBX_NAME_CLASS_SEP.join((name, cls))


def fbx_data_element_custom_properties(props, bid):
    """
    Store custom properties of blender ID bid (any mapping-like object, in fact) into FBX properties props.
    """
    for k, v in bid.items():
        if isinstance(v, str):
            elem_props_set(props, "p_string", k.encode(), v, custom=True)
        elif isinstance(v, int):
            elem_props_set(props, "p_integer", k.encode(), v, custom=True)
        if isinstance(v, float):
            elem_props_set(props, "p_number", k.encode(), v, custom=True)


def fbx_data_lamp_elements(root, lamp, scene_data):
    """
    Write the Lamp data block.
    """
    gscale = scene_data.settings.global_scale

    lamp_key = scene_data.data_lamps[lamp]
    do_light = True
    decay_type = FBX_LIGHT_DECAY_TYPES['CONSTANT']
    do_shadow = False
    shadow_color = Vector((0.0, 0.0, 0.0))
    if lamp.type not in {'HEMI'}:
        if lamp.type not in {'SUN'}:
            decay_type = FBX_LIGHT_DECAY_TYPES[lamp.falloff_type]
        do_light = (not lamp.use_only_shadow) and (lamp.use_specular or lamp.use_diffuse)
        do_shadow = lamp.shadow_method not in {'NOSHADOW'}
        shadow_color = lamp.shadow_color

    light = elem_data_single_int64(root, b"NodeAttribute", get_fbxuid_from_key(lamp_key))
    light.add_string(fbx_name_class(lamp.name.encode(), b"NodeAttribute"))
    light.add_string(b"Light")

    elem_data_single_int32(light, b"GeometryVersion", FBX_GEOMETRY_VERSION)  # Sic...

    tmpl = scene_data.templates[b"Light"]
    props = elem_properties(light)
    elem_props_template_set(tmpl, props, "p_enum", b"LightType", FBX_LIGHT_TYPES[lamp.type])
    elem_props_template_set(tmpl, props, "p_bool", b"CastLight", do_light)
    elem_props_template_set(tmpl, props, "p_color_rgb", b"Color", lamp.color)
    elem_props_template_set(tmpl, props, "p_number", b"Intensity", lamp.energy * 100.0)
    elem_props_template_set(tmpl, props, "p_enum", b"DecayType", decay_type)
    elem_props_template_set(tmpl, props, "p_number", b"DecayStart", lamp.distance * gscale)
    elem_props_template_set(tmpl, props, "p_bool", b"CastShadows", do_shadow)
    elem_props_template_set(tmpl, props, "p_color_rgb", b"ShadowColor", shadow_color)
    if lamp.type in {'SPOT'}:
        elem_props_template_set(tmpl, props, "p_number", b"OuterAngle", math.degrees(lamp.spot_size))
        elem_props_template_set(tmpl, props, "p_number", b"InnerAngle",
                                math.degrees(lamp.spot_size * (1.0 - lamp.spot_blend)))

    # Custom properties.
    if scene_data.settings.use_custom_properties:
        fbx_data_element_custom_properties(props, lamp)


def fbx_data_camera_elements(root, cam_obj, scene_data):
    """
    Write the Camera data blocks.
    """
    gscale = scene_data.settings.global_scale

    cam_data = cam_obj.data
    cam_key = scene_data.data_cameras[cam_obj]

    # Real data now, good old camera!
    # Object transform info.
    loc, rot, scale, matrix, matrix_rot = object_tx(scene_data, cam_obj)
    up = matrix_rot * Vector((0.0, 1.0, 0.0))
    to = matrix_rot * Vector((0.0, 0.0, -1.0))
    # Render settings.
    # TODO We could export much more...
    render = scene_data.scene.render
    width = render.resolution_x
    height = render.resolution_y
    aspect = width / height
    # Film width & height from mm to inches
    filmwidth = units_convert(cam_data.sensor_width, "millimeter", "inch")
    filmheight = units_convert(cam_data.sensor_height, "millimeter", "inch")
    filmaspect = filmwidth / filmheight
    # Film offset
    offsetx = filmwidth * cam_data.shift_x
    offsety = filmaspect * filmheight * cam_data.shift_y

    cam = elem_data_single_int64(root, b"NodeAttribute", get_fbxuid_from_key(cam_key))
    cam.add_string(fbx_name_class(cam_data.name.encode(), b"NodeAttribute"))
    cam.add_string(b"Camera")

    tmpl = scene_data.templates[b"Camera"]
    props = elem_properties(cam)
    elem_props_template_set(tmpl, props, "p_vector_3d", b"Position", loc)
    elem_props_template_set(tmpl, props, "p_vector_3d", b"UpVector", up)
    elem_props_template_set(tmpl, props, "p_vector_3d", b"InterestPosition", to)
    # Should we use world value?
    elem_props_template_set(tmpl, props, "p_color_rgb", b"BackgroundColor", (0.0, 0.0, 0.0))
    elem_props_template_set(tmpl, props, "p_bool", b"DisplayTurnTableIcon", True)

    elem_props_template_set(tmpl, props, "p_number", b"FilmWidth", filmwidth)
    elem_props_template_set(tmpl, props, "p_number", b"FilmHeight", filmheight)
    elem_props_template_set(tmpl, props, "p_number", b"FilmAspectRatio", filmaspect)
    elem_props_template_set(tmpl, props, "p_number", b"FilmOffsetX", offsetx)
    elem_props_template_set(tmpl, props, "p_number", b"FilmOffsetY", offsety)

    elem_props_template_set(tmpl, props, "p_enum", b"ApertureMode", 3)  # FocalLength.
    elem_props_template_set(tmpl, props, "p_enum", b"GateFit", 2)  # FitHorizontal.
    elem_props_template_set(tmpl, props, "p_fov", b"FieldOfView", math.degrees(cam_data.angle_x))
    elem_props_template_set(tmpl, props, "p_fov_x", b"FieldOfViewX", math.degrees(cam_data.angle_x))
    elem_props_template_set(tmpl, props, "p_fov_y", b"FieldOfViewY", math.degrees(cam_data.angle_y))
    # No need to convert to inches here...
    elem_props_template_set(tmpl, props, "p_number", b"FocalLength", cam_data.lens)
    elem_props_template_set(tmpl, props, "p_number", b"SafeAreaAspectRatio", aspect)

    elem_props_template_set(tmpl, props, "p_number", b"NearPlane", cam_data.clip_start * gscale)
    elem_props_template_set(tmpl, props, "p_number", b"FarPlane", cam_data.clip_end * gscale)
    elem_props_template_set(tmpl, props, "p_enum", b"BackPlaneDistanceMode", 1)  # RelativeToCamera.
    elem_props_template_set(tmpl, props, "p_number", b"BackPlaneDistance", cam_data.clip_end * gscale)

    # Custom properties.
    if scene_data.settings.use_custom_properties:
        fbx_data_element_custom_properties(props, cam_data)

    elem_data_single_string(cam, b"TypeFlags", b"Camera")
    elem_data_single_int32(cam, b"GeometryVersion", 124)  # Sic...
    elem_data_vec_float64(cam, b"Position", loc)
    elem_data_vec_float64(cam, b"Up", up)
    elem_data_vec_float64(cam, b"LookAt", to)
    elem_data_single_int32(cam, b"ShowInfoOnMoving", 1)
    elem_data_single_int32(cam, b"ShowAudio", 0)
    elem_data_vec_float64(cam, b"AudioColor", (0.0, 1.0, 0.0))
    elem_data_single_float64(cam, b"CameraOrthoZoom", 1.0)


def fbx_data_mesh_elements(root, me, scene_data):
    """
    Write the Mesh (Geometry) data block.
    """
    # Ugly helper... :/
    def _infinite_gen(val):
        while 1:
            yield val

    me_key, me_obj = scene_data.data_meshes[me]

    # No gscale/gmat here, all data are supposed to be in object space.
    smooth_type = scene_data.settings.mesh_smooth_type

    do_bake_space_transform = use_bake_space_transform(scene_data, me_obj)

    # Vertices are in object space, but we are post-multiplying all transforms with the inverse of the
    # global matrix, so we need to apply the global matrix to the vertices to get the correct result.
    geom_mat_co = scene_data.settings.global_matrix if do_bake_space_transform else None
    # We need to apply the inverse transpose of the global matrix when transforming normals.
    geom_mat_no = Matrix(scene_data.settings.global_matrix_inv_transposed) if do_bake_space_transform else None
    if geom_mat_no is not None:
        # Remove translation & scaling!
        geom_mat_no.translation = Vector()
        geom_mat_no.normalize()

    geom = elem_data_single_int64(root, b"Geometry", get_fbxuid_from_key(me_key))
    geom.add_string(fbx_name_class(me.name.encode(), b"Geometry"))
    geom.add_string(b"Mesh")

    tmpl = scene_data.templates[b"Geometry"]
    props = elem_properties(geom)

    # Custom properties.
    if scene_data.settings.use_custom_properties:
        fbx_data_element_custom_properties(props, me)

    elem_data_single_int32(geom, b"GeometryVersion", FBX_GEOMETRY_VERSION)

    # Vertex cos.
    t_co = array.array(data_types.ARRAY_FLOAT64, (0.0,)) * len(me.vertices) * 3
    me.vertices.foreach_get("co", t_co)
    if geom_mat_co is not None:
        def _vcos_transformed_gen(raw_cos, m=None):
            # Note: we could most likely get much better performances with numpy, but will leave this as TODO for now.
            return chain(*(m * Vector(v) for v in zip(*(iter(raw_cos),) * 3)))
        t_co = _vcos_transformed_gen(t_co, geom_mat_co)
    elem_data_single_float64_array(geom, b"Vertices", t_co)
    del t_co

    # Polygon indices.
    #
    # We do loose edges as two-vertices faces, if enabled...
    #
    # Note we have to process Edges in the same time, as they are based on poly's loops...
    loop_nbr = len(me.loops)
    t_pvi = array.array(data_types.ARRAY_INT32, (0,)) * loop_nbr
    t_ls = [None] * len(me.polygons)

    me.loops.foreach_get("vertex_index", t_pvi)
    me.polygons.foreach_get("loop_start", t_ls)

    # Add "fake" faces for loose edges.
    if scene_data.settings.use_mesh_edges:
        t_le = tuple(e.vertices for e in me.edges if e.is_loose)
        t_pvi.extend(chain(*t_le))
        t_ls.extend(range(loop_nbr, loop_nbr + len(t_le), 2))
        del t_le

    # Edges...
    # Note: Edges are represented as a loop here: each edge uses a single index, which refers to the polygon array.
    #       The edge is made by the vertex indexed py this polygon's point and the next one on the same polygon.
    #       Advantage: Only one index per edge.
    #       Drawback: Only polygon's edges can be represented (that's why we have to add fake two-verts polygons
    #                 for loose edges).
    #       We also have to store a mapping from real edges to their indices in this array, for edge-mapped data
    #       (like e.g. crease).
    t_eli = array.array(data_types.ARRAY_INT32)
    edges_map = {}
    edges_nbr = 0
    if t_ls and t_pvi:
        t_ls = set(t_ls)
        todo_edges = [None] * len(me.edges) * 2
        me.edges.foreach_get("vertices", todo_edges)
        todo_edges = set((v1, v2) if v1 < v2 else (v2, v1) for v1, v2 in zip(*(iter(todo_edges),) * 2))

        li = 0
        vi = vi_start = t_pvi[0]
        for li_next, vi_next in enumerate(t_pvi[1:] + t_pvi[:1], start=1):
            if li_next in t_ls:  # End of a poly's loop.
                vi2 = vi_start
                vi_start = vi_next
            else:
                vi2 = vi_next

            e_key = (vi, vi2) if vi < vi2 else (vi2, vi)
            if e_key in todo_edges:
                t_eli.append(li)
                todo_edges.remove(e_key)
                edges_map[e_key] = edges_nbr
                edges_nbr += 1

            vi = vi_next
            li = li_next
    # End of edges!

    # We have to ^-1 last index of each loop.
    for ls in t_ls:
        t_pvi[ls - 1] ^= -1

    # And finally we can write data!
    elem_data_single_int32_array(geom, b"PolygonVertexIndex", t_pvi)
    elem_data_single_int32_array(geom, b"Edges", t_eli)
    del t_pvi
    del t_ls
    del t_eli

    # And now, layers!

    # Smoothing.
    if smooth_type in {'FACE', 'EDGE'}:
        t_ps = None
        _map = b""
        if smooth_type == 'FACE':
            t_ps = array.array(data_types.ARRAY_INT32, (0,)) * len(me.polygons)
            me.polygons.foreach_get("use_smooth", t_ps)
            _map = b"ByPolygon"
        else:  # EDGE
            # Write Edge Smoothing.
            t_ps = array.array(data_types.ARRAY_INT32, (0,)) * edges_nbr
            for e in me.edges:
                if e.key not in edges_map:
                    continue  # Only loose edges, in theory!
                t_ps[edges_map[e.key]] = not e.use_edge_sharp
            _map = b"ByEdge"
        lay_smooth = elem_data_single_int32(geom, b"LayerElementSmoothing", 0)
        elem_data_single_int32(lay_smooth, b"Version", FBX_GEOMETRY_SMOOTHING_VERSION)
        elem_data_single_string(lay_smooth, b"Name", b"")
        elem_data_single_string(lay_smooth, b"MappingInformationType", _map)
        elem_data_single_string(lay_smooth, b"ReferenceInformationType", b"Direct")
        elem_data_single_int32_array(lay_smooth, b"Smoothing", t_ps)  # Sight, int32 for bool...
        del t_ps

    # TODO: Edge crease (LayerElementCrease).

    # And we are done with edges!
    del edges_map

    # Loop normals.
    # NOTE: this is not supported by importer currently.
    # XXX Official docs says normals should use IndexToDirect,
    #     but this does not seem well supported by apps currently...
    me.calc_normals_split()
    def _nortuples_gen(raw_nors, m):
        # Great, now normals are also expected 4D!
        gen = zip(*(iter(raw_nors),) * 3 + (_infinite_gen(1.0),))
        return gen if m is None else (m * Vector(v) for v in gen)

    t_ln = array.array(data_types.ARRAY_FLOAT64, (0.0,)) * len(me.loops) * 3
    me.loops.foreach_get("normal", t_ln)
    t_ln = _nortuples_gen(t_ln, geom_mat_no)
    if 0:
        t_ln = tuple(t_ln)  # No choice... :/

        lay_nor = elem_data_single_int32(geom, b"LayerElementNormal", 0)
        elem_data_single_int32(lay_nor, b"Version", FBX_GEOMETRY_NORMAL_VERSION)
        elem_data_single_string(lay_nor, b"Name", b"")
        elem_data_single_string(lay_nor, b"MappingInformationType", b"ByPolygonVertex")
        elem_data_single_string(lay_nor, b"ReferenceInformationType", b"IndexToDirect")

        ln2idx = tuple(set(t_ln))
        elem_data_single_float64_array(lay_nor, b"Normals", chain(*ln2idx))
        # Normal weights, no idea what it is.
        t_lnw = array.array(data_types.ARRAY_FLOAT64, (0.0,)) * len(ln2idx)
        elem_data_single_float64_array(lay_nor, b"NormalsW", t_lnw)

        ln2idx = {nor: idx for idx, nor in enumerate(ln2idx)}
        elem_data_single_int32_array(lay_nor, b"NormalsIndex", (ln2idx[n] for n in t_ln))

        del ln2idx
        del t_lnw
    else:
        lay_nor = elem_data_single_int32(geom, b"LayerElementNormal", 0)
        elem_data_single_int32(lay_nor, b"Version", FBX_GEOMETRY_NORMAL_VERSION)
        elem_data_single_string(lay_nor, b"Name", b"")
        elem_data_single_string(lay_nor, b"MappingInformationType", b"ByPolygonVertex")
        elem_data_single_string(lay_nor, b"ReferenceInformationType", b"Direct")
        elem_data_single_float64_array(lay_nor, b"Normals", chain(*t_ln))
        # Normal weights, no idea what it is.
        t_ln = array.array(data_types.ARRAY_FLOAT64, (0.0,)) * len(me.loops)
        elem_data_single_float64_array(lay_nor, b"NormalsW", t_ln)
    del t_ln

    # tspace
    tspacenumber = 0
    if scene_data.settings.use_tspace:
        tspacenumber = len(me.uv_layers)
        if tspacenumber:
            t_ln = array.array(data_types.ARRAY_FLOAT64, (0.0,)) * len(me.loops) * 3
            t_lnw = array.array(data_types.ARRAY_FLOAT64, (0.0,)) * len(me.loops)
            for idx, uvlayer in enumerate(me.uv_layers):
                name = uvlayer.name
                me.calc_tangents(name)
                # Loop bitangents (aka binormals).
                # NOTE: this is not supported by importer currently.
                me.loops.foreach_get("bitangent", t_ln)
                lay_nor = elem_data_single_int32(geom, b"LayerElementBinormal", idx)
                elem_data_single_int32(lay_nor, b"Version", FBX_GEOMETRY_BINORMAL_VERSION)
                elem_data_single_string_unicode(lay_nor, b"Name", name)
                elem_data_single_string(lay_nor, b"MappingInformationType", b"ByPolygonVertex")
                elem_data_single_string(lay_nor, b"ReferenceInformationType", b"Direct")
                elem_data_single_float64_array(lay_nor, b"Binormals", chain(*_nortuples_gen(t_ln, geom_mat_no)))
                # Binormal weights, no idea what it is.
                elem_data_single_float64_array(lay_nor, b"BinormalsW", t_lnw)

                # Loop tangents.
                # NOTE: this is not supported by importer currently.
                me.loops.foreach_get("tangent", t_ln)
                lay_nor = elem_data_single_int32(geom, b"LayerElementTangent", idx)
                elem_data_single_int32(lay_nor, b"Version", FBX_GEOMETRY_TANGENT_VERSION)
                elem_data_single_string_unicode(lay_nor, b"Name", name)
                elem_data_single_string(lay_nor, b"MappingInformationType", b"ByPolygonVertex")
                elem_data_single_string(lay_nor, b"ReferenceInformationType", b"Direct")
                elem_data_single_float64_array(lay_nor, b"Binormals", chain(*_nortuples_gen(t_ln, geom_mat_no)))
                # Tangent weights, no idea what it is.
                elem_data_single_float64_array(lay_nor, b"TangentsW", t_lnw)

            del t_ln
            del t_lnw
            me.free_tangents()

    me.free_normals_split()
    del _nortuples_gen

    # Write VertexColor Layers
    # note, no programs seem to use this info :/
    vcolnumber = len(me.vertex_colors)
    if vcolnumber:
        def _coltuples_gen(raw_cols):
            return zip(*(iter(raw_cols),) * 3 + (_infinite_gen(1.0),))  # We need a fake alpha...

        t_lc = array.array(data_types.ARRAY_FLOAT64, (0.0,)) * len(me.loops) * 3
        for colindex, collayer in enumerate(me.vertex_colors):
            collayer.data.foreach_get("color", t_lc)
            lay_vcol = elem_data_single_int32(geom, b"LayerElementColor", colindex)
            elem_data_single_int32(lay_vcol, b"Version", FBX_GEOMETRY_VCOLOR_VERSION)
            elem_data_single_string_unicode(lay_vcol, b"Name", collayer.name)
            elem_data_single_string(lay_vcol, b"MappingInformationType", b"ByPolygonVertex")
            elem_data_single_string(lay_vcol, b"ReferenceInformationType", b"IndexToDirect")

            col2idx = tuple(set(_coltuples_gen(t_lc)))
            elem_data_single_float64_array(lay_vcol, b"Colors", chain(*col2idx))  # Flatten again...

            col2idx = {col: idx for idx, col in enumerate(col2idx)}
            elem_data_single_int32_array(lay_vcol, b"ColorIndex", (col2idx[c] for c in _coltuples_gen(t_lc)))
            del col2idx
        del t_lc
        del _coltuples_gen

    # Write UV layers.
    # Note: LayerElementTexture is deprecated since FBX 2011 - luckily!
    #       Textures are now only related to materials, in FBX!
    uvnumber = len(me.uv_layers)
    if uvnumber:
        def _uvtuples_gen(raw_uvs):
            return zip(*(iter(raw_uvs),) * 2)

        t_luv = array.array(data_types.ARRAY_FLOAT64, (0.0,)) * len(me.loops) * 2
        for uvindex, uvlayer in enumerate(me.uv_layers):
            uvlayer.data.foreach_get("uv", t_luv)
            lay_uv = elem_data_single_int32(geom, b"LayerElementUV", uvindex)
            elem_data_single_int32(lay_uv, b"Version", FBX_GEOMETRY_UV_VERSION)
            elem_data_single_string_unicode(lay_uv, b"Name", uvlayer.name)
            elem_data_single_string(lay_uv, b"MappingInformationType", b"ByPolygonVertex")
            elem_data_single_string(lay_uv, b"ReferenceInformationType", b"IndexToDirect")

            uv2idx = tuple(set(_uvtuples_gen(t_luv)))
            elem_data_single_float64_array(lay_uv, b"UV", chain(*uv2idx))  # Flatten again...

            uv2idx = {uv: idx for idx, uv in enumerate(uv2idx)}
            elem_data_single_int32_array(lay_uv, b"UVIndex", (uv2idx[uv] for uv in _uvtuples_gen(t_luv)))
            del uv2idx
        del t_luv
        del _uvtuples_gen

    # Face's materials.
    me_fbxmats_idx = None
    if me in scene_data.mesh_mat_indices:
        me_fbxmats_idx = scene_data.mesh_mat_indices[me]
        me_blmats = me.materials
        if me_fbxmats_idx and me_blmats:
            lay_mat = elem_data_single_int32(geom, b"LayerElementMaterial", 0)
            elem_data_single_int32(lay_mat, b"Version", FBX_GEOMETRY_MATERIAL_VERSION)
            elem_data_single_string(lay_mat, b"Name", b"")
            nbr_mats = len(me_fbxmats_idx)
            if nbr_mats > 1:
                t_pm = array.array(data_types.ARRAY_INT32, (0,)) * len(me.polygons)
                me.polygons.foreach_get("material_index", t_pm)

                # We have to validate mat indices, and map them to FBX indices.
                blmats_to_fbxmats_idxs = [me_fbxmats_idx[m] for m in me_blmats]
                mat_idx_limit = len(blmats_to_fbxmats_idxs)
                def_mat = blmats_to_fbxmats_idxs[0]
                _gen = (blmats_to_fbxmats_idxs[m] if m < mat_idx_limit else def_mat for m in t_pm)
                t_pm = array.array(data_types.ARRAY_INT32, _gen)

                elem_data_single_string(lay_mat, b"MappingInformationType", b"ByPolygon")
                # XXX Logically, should be "Direct" reference type, since we do not have any index array, and have one
                #     value per polygon...
                #     But looks like FBX expects it to be IndexToDirect here (maybe because materials are already
                #     indices??? *sigh*).
                elem_data_single_string(lay_mat, b"ReferenceInformationType", b"IndexToDirect")
                elem_data_single_int32_array(lay_mat, b"Materials", t_pm)
                del t_pm
            else:
                elem_data_single_string(lay_mat, b"MappingInformationType", b"AllSame")
                elem_data_single_string(lay_mat, b"ReferenceInformationType", b"IndexToDirect")
                elem_data_single_int32_array(lay_mat, b"Materials", [0])

    # And the "layer TOC"...

    layer = elem_data_single_int32(geom, b"Layer", 0)
    elem_data_single_int32(layer, b"Version", FBX_GEOMETRY_LAYER_VERSION)
    lay_nor = elem_empty(layer, b"LayerElement")
    elem_data_single_string(lay_nor, b"Type", b"LayerElementNormal")
    elem_data_single_int32(lay_nor, b"TypedIndex", 0)
    if smooth_type in {'FACE', 'EDGE'}:
        lay_smooth = elem_empty(layer, b"LayerElement")
        elem_data_single_string(lay_smooth, b"Type", b"LayerElementSmoothing")
        elem_data_single_int32(lay_smooth, b"TypedIndex", 0)
    if vcolnumber:
        lay_vcol = elem_empty(layer, b"LayerElement")
        elem_data_single_string(lay_vcol, b"Type", b"LayerElementColor")
        elem_data_single_int32(lay_vcol, b"TypedIndex", 0)
    if uvnumber:
        lay_uv = elem_empty(layer, b"LayerElement")
        elem_data_single_string(lay_uv, b"Type", b"LayerElementUV")
        elem_data_single_int32(lay_uv, b"TypedIndex", 0)
    if me_fbxmats_idx is not None:
        lay_mat = elem_empty(layer, b"LayerElement")
        elem_data_single_string(lay_mat, b"Type", b"LayerElementMaterial")
        elem_data_single_int32(lay_mat, b"TypedIndex", 0)

    # Add other uv and/or vcol layers...
    for vcolidx, uvidx, tspaceidx in zip_longest(range(1, vcolnumber), range(1, uvnumber), range(1, tspacenumber),
                                                 fillvalue=0):
        layer = elem_data_single_int32(geom, b"Layer", max(vcolidx, uvidx))
        elem_data_single_int32(layer, b"Version", FBX_GEOMETRY_LAYER_VERSION)
        if vcolidx:
            lay_vcol = elem_empty(layer, b"LayerElement")
            elem_data_single_string(lay_vcol, b"Type", b"LayerElementColor")
            elem_data_single_int32(lay_vcol, b"TypedIndex", vcolidx)
        if uvidx:
            lay_uv = elem_empty(layer, b"LayerElement")
            elem_data_single_string(lay_uv, b"Type", b"LayerElementUV")
            elem_data_single_int32(lay_uv, b"TypedIndex", uvidx)
        if tspaceidx:
            lay_binor = elem_empty(layer, b"LayerElement")
            elem_data_single_string(lay_binor, b"Type", b"LayerElementBinormal")
            elem_data_single_int32(lay_binor, b"TypedIndex", tspaceidx)
            lay_tan = elem_empty(layer, b"LayerElement")
            elem_data_single_string(lay_tan, b"Type", b"LayerElementTangent")
            elem_data_single_int32(lay_tan, b"TypedIndex", tspaceidx)


def fbx_data_material_elements(root, mat, scene_data):
    """
    Write the Material data block.
    """
    ambient_color = (0.0, 0.0, 0.0)
    if scene_data.data_world:
        ambient_color = next(iter(scene_data.data_world.keys())).ambient_color

    mat_key, _objs = scene_data.data_materials[mat]
    # Approximation...
    mat_type = b"phong" if mat.specular_shader in {'COOKTORR', 'PHONG', 'BLINN'} else b"lambert"

    fbx_mat = elem_data_single_int64(root, b"Material", get_fbxuid_from_key(mat_key))
    fbx_mat.add_string(fbx_name_class(mat.name.encode(), b"Material"))
    fbx_mat.add_string(b"")

    elem_data_single_int32(fbx_mat, b"Version", FBX_MATERIAL_VERSION)
    # those are not yet properties, it seems...
    elem_data_single_string(fbx_mat, b"ShadingModel", mat_type)
    elem_data_single_int32(fbx_mat, b"MultiLayer", 0)  # Should be bool...

    tmpl = scene_data.templates[b"Material"]
    props = elem_properties(fbx_mat)
    elem_props_template_set(tmpl, props, "p_string", b"ShadingModel", mat_type.decode())
    elem_props_template_set(tmpl, props, "p_color_rgb", b"EmissiveColor", mat.diffuse_color)
    elem_props_template_set(tmpl, props, "p_number", b"EmissiveFactor", mat.emit)
    elem_props_template_set(tmpl, props, "p_color_rgb", b"AmbientColor", ambient_color)
    elem_props_template_set(tmpl, props, "p_number", b"AmbientFactor", mat.ambient)
    elem_props_template_set(tmpl, props, "p_color_rgb", b"DiffuseColor", mat.diffuse_color)
    elem_props_template_set(tmpl, props, "p_number", b"DiffuseFactor", mat.diffuse_intensity)
    elem_props_template_set(tmpl, props, "p_color_rgb", b"TransparentColor",
                            mat.diffuse_color if mat.use_transparency else (1.0, 1.0, 1.0))
    elem_props_template_set(tmpl, props, "p_number", b"TransparencyFactor",
                            1.0 - mat.alpha if mat.use_transparency else 0.0)
    elem_props_template_set(tmpl, props, "p_number", b"Opacity", mat.alpha if mat.use_transparency else 1.0)
    elem_props_template_set(tmpl, props, "p_vector_3d", b"NormalMap", (0.0, 0.0, 0.0))
    # Not sure about those...
    """
    b"Bump": ((0.0, 0.0, 0.0), "p_vector_3d"),
    b"BumpFactor": (1.0, "p_number"),
    b"DisplacementColor": ((0.0, 0.0, 0.0), "p_color_rgb"),
    b"DisplacementFactor": (0.0, "p_number"),
    """
    if mat_type == b"phong":
        elem_props_template_set(tmpl, props, "p_color_rgb", b"SpecularColor", mat.specular_color)
        elem_props_template_set(tmpl, props, "p_number", b"SpecularFactor", mat.specular_intensity / 2.0)
        # See Material template about those two!
        elem_props_template_set(tmpl, props, "p_number", b"Shininess", (mat.specular_hardness - 1.0) / 5.10)
        elem_props_template_set(tmpl, props, "p_number", b"ShininessExponent", (mat.specular_hardness - 1.0) / 5.10)
        elem_props_template_set(tmpl, props, "p_color_rgb", b"ReflectionColor", mat.mirror_color)
        elem_props_template_set(tmpl, props, "p_number", b"ReflectionFactor",
                                mat.raytrace_mirror.reflect_factor if mat.raytrace_mirror.use else 0.0)

    # Custom properties.
    if scene_data.settings.use_custom_properties:
        fbx_data_element_custom_properties(props, mat)


def _gen_vid_path(img, scene_data):
    msetts = scene_data.settings.media_settings
    fname_rel = bpy_extras.io_utils.path_reference(img.filepath, msetts.base_src, msetts.base_dst, msetts.path_mode,
                                                   msetts.subdir, msetts.copy_set, img.library)
    fname_abs = os.path.normpath(os.path.abspath(os.path.join(msetts.base_dst, fname_rel)))
    return fname_abs, fname_rel


def fbx_data_texture_file_elements(root, tex, scene_data):
    """
    Write the (file) Texture data block.
    """
    # XXX All this is very fuzzy to me currently...
    #     Textures do not seem to use properties as much as they could.
    #     For now assuming most logical and simple stuff.

    tex_key, _mats = scene_data.data_textures[tex]
    img = tex.texture.image
    fname_abs, fname_rel = _gen_vid_path(img, scene_data)

    fbx_tex = elem_data_single_int64(root, b"Texture", get_fbxuid_from_key(tex_key))
    fbx_tex.add_string(fbx_name_class(tex.name.encode(), b"Texture"))
    fbx_tex.add_string(b"")

    elem_data_single_string(fbx_tex, b"Type", b"TextureVideoClip")
    elem_data_single_int32(fbx_tex, b"Version", FBX_TEXTURE_VERSION)
    elem_data_single_string(fbx_tex, b"TextureName", fbx_name_class(tex.name.encode(), b"Texture"))
    elem_data_single_string(fbx_tex, b"Media", fbx_name_class(img.name.encode(), b"Video"))
    elem_data_single_string_unicode(fbx_tex, b"FileName", fname_abs)
    elem_data_single_string_unicode(fbx_tex, b"RelativeFilename", fname_rel)

    alpha_source = 0  # None
    if img.use_alpha:
        if tex.texture.use_calculate_alpha:
            alpha_source = 1  # RGBIntensity as alpha.
        else:
            alpha_source = 2  # Black, i.e. alpha channel.
    # BlendMode not useful for now, only affects layered textures afaics.
    mapping = 0  # None.
    if tex.texture_coords in {'ORCO'}:  # XXX Others?
        if tex.mapping in {'FLAT'}:
            mapping = 1  # Planar
        elif tex.mapping in {'CUBE'}:
            mapping = 4  # Box
        elif tex.mapping in {'TUBE'}:
            mapping = 3  # Cylindrical
        elif tex.mapping in {'SPHERE'}:
            mapping = 2  # Spherical
    elif tex.texture_coords in {'UV'}:
        # XXX *HOW* do we link to correct UVLayer???
        mapping = 6  # UV
    wrap_mode = 1  # Clamp
    if tex.texture.extension in {'REPEAT'}:
        wrap_mode = 0  # Repeat

    tmpl = scene_data.templates[b"TextureFile"]
    props = elem_properties(fbx_tex)
    elem_props_template_set(tmpl, props, "p_enum", b"AlphaSource", alpha_source)
    elem_props_template_set(tmpl, props, "p_bool", b"PremultiplyAlpha",
                            img.alpha_mode in {'STRAIGHT'})  # Or is it PREMUL?
    elem_props_template_set(tmpl, props, "p_enum", b"CurrentMappingType", mapping)
    elem_props_template_set(tmpl, props, "p_enum", b"WrapModeU", wrap_mode)
    elem_props_template_set(tmpl, props, "p_enum", b"WrapModeV", wrap_mode)
    elem_props_template_set(tmpl, props, "p_vector_3d", b"Translation", tex.offset)
    elem_props_template_set(tmpl, props, "p_vector_3d", b"Scaling", tex.scale)
    elem_props_template_set(tmpl, props, "p_bool", b"UseMipMap", tex.texture.use_mipmap)

    # Custom properties.
    if scene_data.settings.use_custom_properties:
        fbx_data_element_custom_properties(props, tex.texture)


def fbx_data_video_elements(root, vid, scene_data):
    """
    Write the actual image data block.
    """
    vid_key, _texs = scene_data.data_videos[vid]
    fname_abs, fname_rel = _gen_vid_path(vid, scene_data)

    fbx_vid = elem_data_single_int64(root, b"Video", get_fbxuid_from_key(vid_key))
    fbx_vid.add_string(fbx_name_class(vid.name.encode(), b"Video"))
    fbx_vid.add_string(b"Clip")

    elem_data_single_string(fbx_vid, b"Type", b"Clip")
    # XXX No Version???
    elem_data_single_string_unicode(fbx_vid, b"FileName", fname_abs)
    elem_data_single_string_unicode(fbx_vid, b"RelativeFilename", fname_rel)

    if scene_data.settings.media_settings.embed_textures:
        try:
            with open(vid.filepath, 'br') as f:
                elem_data_single_byte_array(fbx_vid, b"Content", f.read())
        except Exception as e:
            print("WARNING: embeding file {} failed ({})".format(vid.filepath, e))
            elem_data_single_byte_array(fbx_vid, b"Content", b"")
    else:
        elem_data_single_byte_array(fbx_vid, b"Content", b"")


def fbx_data_armature_elements(root, armature, scene_data):
    """
    Write:
        * Bones "data" (NodeAttribute::LimbNode, contains pretty much nothing!).
        * Deformers (i.e. Skin), bind between an armature and a mesh.
        ** SubDeformers (i.e. Cluster), one per bone/vgroup pair.
        * BindPose.
    Note armature itself has no data, it is a mere "Null" Model...
    """

    # Bones "data".
    tmpl = scene_data.templates[b"Bone"]
    for bo in armature.data.bones:
        _bo_key, bo_data_key, _arm = scene_data.data_bones[bo]
        fbx_bo = elem_data_single_int64(root, b"NodeAttribute", get_fbxuid_from_key(bo_data_key))
        fbx_bo.add_string(fbx_name_class(bo.name.encode(), b"NodeAttribute"))
        fbx_bo.add_string(b"LimbNode")
        elem_data_single_string(fbx_bo, b"TypeFlags", b"Skeleton")

        props = elem_properties(fbx_bo)
        elem_props_template_set(tmpl, props, "p_number", b"Size", (bo.tail_local - bo.head_local).length)

        # Custom properties.
        if scene_data.settings.use_custom_properties:
            fbx_data_element_custom_properties(props, bo)

    # Deformers and BindPoses.
    # Note: we might also use Deformers for our "parent to vertex" stuff???
    deformer = scene_data.data_deformers.get(armature, None)
    if deformer is not None:
        for me, (skin_key, obj, clusters) in deformer.items():
            # BindPose.
            # We assume bind pose for our bones are their "Editmode" pose...
            # All matrices are expected in global (world) space.
            bindpose_key = get_blender_armature_bindpose_key(armature, me)
            fbx_pose = elem_data_single_int64(root, b"Pose", get_fbxuid_from_key(bindpose_key))
            fbx_pose.add_string(fbx_name_class(me.name.encode(), b"Pose"))
            fbx_pose.add_string(b"BindPose")

            elem_data_single_string(fbx_pose, b"Type", b"BindPose")
            elem_data_single_int32(fbx_pose, b"Version", FBX_POSE_BIND_VERSION)
            elem_data_single_int32(fbx_pose, b"NbPoseNodes", 1 + len(armature.data.bones))

            # First node is mesh/object.
            mat_world_obj = object_matrix(scene_data, obj, global_space=True)
            fbx_posenode = elem_empty(fbx_pose, b"PoseNode")
            elem_data_single_int64(fbx_posenode, b"Node", get_fbxuid_from_key(scene_data.objects[obj]))
            elem_data_single_float64_array(fbx_posenode, b"Matrix", matrix_to_array(mat_world_obj))
            # And all bones of armature!
            mat_world_bones = {}
            for bo in armature.data.bones:
                bomat = object_matrix(scene_data, bo, armature, global_space=True)
                mat_world_bones[bo] = bomat
                fbx_posenode = elem_empty(fbx_pose, b"PoseNode")
                elem_data_single_int64(fbx_posenode, b"Node", get_fbxuid_from_key(scene_data.objects[bo]))
                elem_data_single_float64_array(fbx_posenode, b"Matrix", matrix_to_array(bomat))

            # Deformer.
            fbx_skin = elem_data_single_int64(root, b"Deformer", get_fbxuid_from_key(skin_key))
            fbx_skin.add_string(fbx_name_class(armature.name.encode(), b"Deformer"))
            fbx_skin.add_string(b"Skin")

            elem_data_single_int32(fbx_skin, b"Version", FBX_DEFORMER_SKIN_VERSION)
            elem_data_single_float64(fbx_skin, b"Link_DeformAcuracy", 50.0)  # Only vague idea what it is...

            for bo, clstr_key in clusters.items():
                # Find which vertices are affected by this bone/vgroup pair, and matching weights.
                indices = []
                weights = []
                vg_idx = obj.vertex_groups[bo.name].index
                for idx, v in enumerate(me.vertices):
                    vert_vg = [vg for vg in v.groups if vg.group == vg_idx]
                    if not vert_vg:
                        continue
                    indices.append(idx)
                    weights.append(vert_vg[0].weight)

                # Create the cluster.
                fbx_clstr = elem_data_single_int64(root, b"Deformer", get_fbxuid_from_key(clstr_key))
                fbx_clstr.add_string(fbx_name_class(bo.name.encode(), b"SubDeformer"))
                fbx_clstr.add_string(b"Cluster")

                elem_data_single_int32(fbx_clstr, b"Version", FBX_DEFORMER_CLUSTER_VERSION)
                # No idea what that user data might be...
                fbx_userdata = elem_data_single_string(fbx_clstr, b"UserData", b"")
                fbx_userdata.add_string(b"")
                if indices:
                    elem_data_single_int32_array(fbx_clstr, b"Indexes", indices)
                    elem_data_single_float64_array(fbx_clstr, b"Weights", weights)
                # Transform and TransformLink matrices...
                # They seem to be mostly the same as BindPose ones???
                # WARNING! Even though official FBX API presents Transform in global space,
                #          **it is stored in bone space in FBX data!** See:
                #          http://area.autodesk.com/forum/autodesk-fbx/fbx-sdk/why-the-values-return-
                #                 by-fbxcluster-gettransformmatrix-x-not-same-with-the-value-in-ascii-fbx-file/
                elem_data_single_float64_array(fbx_clstr, b"Transform",
                                               matrix_to_array(mat_world_bones[bo].inverted() * mat_world_obj))
                elem_data_single_float64_array(fbx_clstr, b"TransformLink", matrix_to_array(mat_world_bones[bo]))


def fbx_data_object_elements(root, obj, scene_data):
    """
    Write the Object (Model) data blocks.
    Note we handle "Model" part of bones as well here!
    """
    obj_type = b"Null"  # default, sort of empty...
    if isinstance(obj, Bone):
        obj_type = b"LimbNode"
    elif (obj.type == 'MESH'):
        obj_type = b"Mesh"
    elif (obj.type == 'LAMP'):
        obj_type = b"Light"
    elif (obj.type == 'CAMERA'):
        obj_type = b"Camera"
    obj_key = scene_data.objects[obj]
    model = elem_data_single_int64(root, b"Model", get_fbxuid_from_key(obj_key))
    model.add_string(fbx_name_class(obj.name.encode(), b"Model"))
    model.add_string(obj_type)

    elem_data_single_int32(model, b"Version", FBX_MODELS_VERSION)

    # Object transform info.
    loc, rot, scale, matrix, matrix_rot = object_tx(scene_data, obj)
    rot = tuple(units_convert_iter(rot, "radian", "degree"))

    tmpl = scene_data.templates[b"Model"]
    # For now add only loc/rot/scale...
    props = elem_properties(model)
    elem_props_template_set(tmpl, props, "p_lcl_translation", b"Lcl Translation", loc)
    elem_props_template_set(tmpl, props, "p_lcl_rotation", b"Lcl Rotation", rot)
    elem_props_template_set(tmpl, props, "p_lcl_scaling", b"Lcl Scaling", scale)

    # TODO: "constraints" (limit loc/rot/scale, and target-to-object).

    # Custom properties.
    if scene_data.settings.use_custom_properties:
        fbx_data_element_custom_properties(props, obj)

    # Those settings would obviously need to be edited in a complete version of the exporter, may depends on
    # object type, etc.
    elem_data_single_int32(model, b"MultiLayer", 0)
    elem_data_single_int32(model, b"MultiTake", 0)
    elem_data_single_bool(model, b"Shading", True)
    elem_data_single_string(model, b"Culling", b"CullingOff")

    if isinstance(obj, Object) and obj.type == 'CAMERA':
        # Why, oh why are FBX cameras such a mess???
        # And WHY add camera data HERE??? Not even sure this is needed...
        render = scene_data.scene.render
        width = render.resolution_x * 1.0
        height = render.resolution_y * 1.0
        elem_props_template_set(tmpl, props, "p_enum", b"ResolutionMode", 0)  # Don't know what it means
        elem_props_template_set(tmpl, props, "p_number", b"AspectW", width)
        elem_props_template_set(tmpl, props, "p_number", b"AspectH", height)
        elem_props_template_set(tmpl, props, "p_bool", b"ViewFrustum", True)
        elem_props_template_set(tmpl, props, "p_enum", b"BackgroundMode", 0)  # Don't know what it means
        elem_props_template_set(tmpl, props, "p_bool", b"ForegroundTransparent", True)


##### Top-level FBX data container. #####

# Helper container gathering some data we need multiple times:
#     * templates.
#     * objects.
#     * connections.
#     * takes.
FBXData = namedtuple("FBXData", (
    "templates", "templates_users", "connections",
    "settings", "scene", "objects",
    "data_lamps", "data_cameras", "data_meshes", "mesh_mat_indices",
    "data_bones", "data_deformers",
    "data_world", "data_materials", "data_textures", "data_videos",
))


def fbx_mat_properties_from_texture(tex):
    """
    Returns a set of FBX metarial properties that are affected by the given texture.
    Quite obviously, this is a fuzzy and far-from-perfect mapping! Amounts of influence are completely lost, e.g.
    Note tex is actually expected to be a texture slot.
    """
    # Tex influence does not exists in FBX, so assume influence < 0.5 = no influence... :/
    INFLUENCE_THRESHOLD = 0.5

    # Mapping Blender -> FBX (blend_use_name, blend_fact_name, fbx_name).
    blend_to_fbx = (
        # Lambert & Phong...
        ("diffuse", "diffuse", b"DiffuseFactor"),
        ("color_diffuse", "diffuse_color", b"DiffuseColor"),
        ("alpha", "alpha", b"TransparencyFactor"),
        ("diffuse", "diffuse", b"TransparentColor"),  # Uses diffuse color in Blender!
        ("emit", "emit", b"EmissiveFactor"),
        ("diffuse", "diffuse", b"EmissiveColor"),  # Uses diffuse color in Blender!
        ("ambient", "ambient", b"AmbientFactor"),
        #("", "", b"AmbientColor"),  # World stuff in Blender, for now ignore...
        ("normal", "normal", b"NormalMap"),
        # Note: unsure about those... :/
        #("", "", b"Bump"),
        #("", "", b"BumpFactor"),
        #("", "", b"DisplacementColor"),
        #("", "", b"DisplacementFactor"),
        # Phong only.
        ("specular", "specular", b"SpecularFactor"),
        ("color_spec", "specular_color", b"SpecularColor"),
        # See Material template about those two!
        ("hardness", "hardness", b"Shininess"),
        ("hardness", "hardness", b"ShininessExponent"),
        ("mirror", "mirror", b"ReflectionColor"),
        ("raymir", "raymir", b"ReflectionFactor"),
    )

    tex_fbx_props = set()
    for use_map_name, name_factor, fbx_prop_name in blend_to_fbx:
        if getattr(tex, "use_map_" + use_map_name) and getattr(tex, name_factor + "_factor") >= INFLUENCE_THRESHOLD:
            tex_fbx_props.add(fbx_prop_name)

    return tex_fbx_props


def fbx_skeleton_from_armature(scene, settings, armature, objects, data_bones, data_deformers, arm_parents):
    """
    Create skeleton from armature/bones (NodeAttribute/LimbNode and Model/LimbNode), and for each deformed mesh,
    create Pose/BindPose(with sub PoseNode) and Deformer/Skin(with Deformer/SubDeformer/Cluster).
    Also supports "parent to bone" (simple parent to Model/LimbNode).
    arm_parents is a set of tuples (armature, object) for all successful armature bindings.
    """
    arm = armature.data
    bones = {}
    for bo in arm.bones:
        key, data_key = get_blender_bone_key(armature, bo)
        objects[bo] = key
        data_bones[bo] = (key, data_key, armature)
        bones[bo.name] = bo

    for obj in objects.keys():
        if not isinstance(obj, Object):
            continue
        if obj.type not in {'MESH'}:
            continue
        if obj.parent != armature:
            continue

        # Always handled by an Armature modifier...
        found = False
        for mod in obj.modifiers:
            if mod.type not in {'ARMATURE'}:
                continue
            # We only support vertex groups binding method, not bone envelopes one!
            if mod.object == armature and mod.use_vertex_groups:
                found = True
                break

        if not found:
            continue

        # Now we have a mesh using this armature. First, find out which bones are concerned!
        # XXX Assuming here non-used bones can have no cluster, this has to be checked!
        used_bones = tuple(bones[vg.name] for vg in obj.vertex_groups if vg.name in bones)
        if not used_bones:
            continue

        # Note: bindpose have no relations at all (no connections), so no need for any preprocess for them.

        # Create skin & clusters relations (note skins are connected to geometry, *not* model!).
        me = obj.data
        clusters = {bo: get_blender_bone_cluster_key(armature, me, bo) for bo in used_bones}
        data_deformers.setdefault(armature, {})[me] = (get_blender_armature_skin_key(armature, me), obj, clusters)

        # We don't want a regular parent relationship for those in FBX...
        arm_parents.add((armature, obj))


def fbx_data_from_scene(scene, settings):
    """
    Do some pre-processing over scene's data...
    """
    objtypes = settings.object_types

    ##### Gathering data...

    # This is rather simple for now, maybe we could end generating templates with most-used values
    # instead of default ones?
    objects = {obj: get_blenderID_key(obj) for obj in scene.objects if obj.type in objtypes}
    data_lamps = {obj.data: get_blenderID_key(obj.data) for obj in objects if obj.type == 'LAMP'}
    # Unfortunately, FBX camera data contains object-level data (like position, orientation, etc.)...
    data_cameras = {obj: get_blenderID_key(obj.data) for obj in objects if obj.type == 'CAMERA'}
    data_meshes = {obj.data: (get_blenderID_key(obj.data), obj) for obj in objects if obj.type == 'MESH'}

    # Armatures!
    data_bones = {}
    data_deformers = {}
    arm_parents = set()
    for obj in tuple(objects.keys()):
        if obj.type not in {'ARMATURE'}:
            continue
        fbx_skeleton_from_armature(scene, settings, obj, objects, data_bones, data_deformers, arm_parents)

    # Some world settings are embedded in FBX materials...
    if scene.world:
        data_world = {scene.world: get_blenderID_key(scene.world)}
    else:
        data_world = {}

    # TODO: Check all the mat stuff works even when mats are linked to Objects
    #       (we can then have the same mesh used with different materials...).
    #       *Should* work, as FBX always links its materials to Models (i.e. objects).
    #       XXX However, material indices would probably break...
    data_materials = {}
    for obj in objects:
        # Only meshes for now!
        if not isinstance(obj, Object) or obj.type not in {'MESH'}:
            continue
        for mat_s in obj.material_slots:
            mat = mat_s.material
            # Note theoretically, FBX supports any kind of materials, even GLSL shaders etc.
            # However, I doubt anything else than Lambert/Phong is really portable!
            # We support any kind of 'surface' shader though, better to have some kind of default Lambert than nothing.
            # TODO: Support nodes (*BIG* todo!).
            if mat.type in {'SURFACE'} and not mat.use_nodes:
                if mat in data_materials:
                    data_materials[mat][1].append(obj)
                else:
                    data_materials[mat] = (get_blenderID_key(mat), [obj])

    # Note FBX textures also hold their mapping info.
    # TODO: Support layers?
    data_textures = {}
    # FbxVideo also used to store static images...
    data_videos = {}
    # For now, do not use world textures, don't think they can be linked to anything FBX wise...
    for mat in data_materials.keys():
        for tex in mat.texture_slots:
            if tex is None:
                continue
            # For now, only consider image textures.
            # Note FBX does has support for procedural, but this is not portable at all (opaque blob),
            # so not useful for us.
            # TODO I think ENVIRONMENT_MAP should be usable in FBX as well, but for now let it aside.
            #if tex.texture.type not in {'IMAGE', 'ENVIRONMENT_MAP'}:
            if tex.texture.type not in {'IMAGE'}:
                continue
            img = tex.texture.image
            if img is None:
                continue
            # Find out whether we can actually use this texture for this material, in FBX context.
            tex_fbx_props = fbx_mat_properties_from_texture(tex)
            if not tex_fbx_props:
                continue
            if tex in data_textures:
                data_textures[tex][1][mat] = tex_fbx_props
            else:
                data_textures[tex] = (get_blenderID_key(tex), {mat: tex_fbx_props})
            if img in data_videos:
                data_videos[img][1].append(tex)
            else:
                data_videos[img] = (get_blenderID_key(img), [tex])

    ##### Creation of templates...

    templates = OrderedDict()
    templates[b"GlobalSettings"] = fbx_template_def_globalsettings(scene, settings, nbr_users=1)

    if data_lamps:
        templates[b"Light"] = fbx_template_def_light(scene, settings, nbr_users=len(data_lamps))

    if data_cameras:
        templates[b"Camera"] = fbx_template_def_camera(scene, settings, nbr_users=len(data_cameras))

    if data_bones:
        templates[b"Bone"] = fbx_template_def_bone(scene, settings, nbr_users=len(data_bones))

    if data_meshes:
        templates[b"Geometry"] = fbx_template_def_geometry(scene, settings, nbr_users=len(data_meshes))

    if objects:
        templates[b"Model"] = fbx_template_def_model(scene, settings, nbr_users=len(objects))

    if arm_parents:
        # Number of Pose|BindPose elements should be the same as number of meshes-parented-to-armatures
        templates[b"BindPose"] = fbx_template_def_pose(scene, settings, nbr_users=len(arm_parents))

    if data_deformers:
        nbr = len(data_deformers)
        nbr += sum(len(clusters) for def_me in data_deformers.values() for a, b, clusters in def_me.values())
        templates[b"Deformers"] = fbx_template_def_deformer(scene, settings, nbr_users=nbr)

    # No world support in FBX...
    """
    if data_world:
        templates[b"World"] = fbx_template_def_world(scene, settings, nbr_users=len(data_world))
    """

    if data_materials:
        templates[b"Material"] = fbx_template_def_material(scene, settings, nbr_users=len(data_materials))

    if data_textures:
        templates[b"TextureFile"] = fbx_template_def_texture_file(scene, settings, nbr_users=len(data_textures))

    if data_videos:
        templates[b"Video"] = fbx_template_def_video(scene, settings, nbr_users=len(data_videos))

    templates_users = sum(tmpl.nbr_users for tmpl in templates.values())

    ##### Creation of connections...

    connections = []

    # Objects (with classical parenting).
    for obj, obj_key in objects.items():
        # Bones are handled later.
        if isinstance(obj, Object):
            par = obj.parent
            par_key = 0  # Convention, "root" node (never explicitly written).
            if par and par in objects:
                par_type = obj.parent_type
                if par_type in {'OBJECT', 'BONE'}:
                    # Meshes parented to armature also have 'OBJECT' par_type, in FBX this is handled separately,
                    # we do not want an extra object parenting!
                    if (par, obj) not in arm_parents:
                        par_key = objects[par]
                else:
                    print("Sorry, “{}” parenting type is not supported".format(par_type))
            connections.append((b"OO", get_fbxuid_from_key(obj_key), get_fbxuid_from_key(par_key), None))

    # Armature & Bone chains.
    for bo, (bo_key, _bo_data_key, arm) in data_bones.items():
        par = bo.parent
        if not par:  # Root bone.
            par = arm
        if par not in objects:
            continue
        connections.append((b"OO", get_fbxuid_from_key(bo_key), get_fbxuid_from_key(objects[par]), None))

    # Cameras
    for obj_cam, cam_key in data_cameras.items():
        cam_obj_key = objects[obj_cam]
        connections.append((b"OO", get_fbxuid_from_key(cam_key), get_fbxuid_from_key(cam_obj_key), None))

    # Object data.
    for obj, obj_key in objects.items():
        if isinstance(obj, Bone):
            _bo_key, bo_data_key, _arm = data_bones[obj]
            assert(_bo_key == obj_key)
            connections.append((b"OO", get_fbxuid_from_key(bo_data_key), get_fbxuid_from_key(obj_key), None))
        elif obj.type == 'LAMP':
            lamp_key = data_lamps[obj.data]
            connections.append((b"OO", get_fbxuid_from_key(lamp_key), get_fbxuid_from_key(obj_key), None))
        elif obj.type == 'MESH':
            mesh_key, _obj = data_meshes[obj.data]
            connections.append((b"OO", get_fbxuid_from_key(mesh_key), get_fbxuid_from_key(obj_key), None))

    # Deformers (armature-to-geometry, only for meshes currently)...
    for arm, deformed_meshes in data_deformers.items():
        for me, (skin_key, _obj, clusters) in deformed_meshes.items():
            # skin -> geometry
            mesh_key, _obj = data_meshes[me]
            connections.append((b"OO", get_fbxuid_from_key(skin_key), get_fbxuid_from_key(mesh_key), None))
            for bo, clstr_key in clusters.items():
                # cluster -> skin
                connections.append((b"OO", get_fbxuid_from_key(clstr_key), get_fbxuid_from_key(skin_key), None))
                # bone -> cluster
                connections.append((b"OO", get_fbxuid_from_key(objects[bo]), get_fbxuid_from_key(clstr_key), None))

    # Materials
    mesh_mat_indices = {}
    _objs_indices = {}
    for mat, (mat_key, objs) in data_materials.items():
        for obj in objs:
            obj_key = objects[obj]
            connections.append((b"OO", get_fbxuid_from_key(mat_key), get_fbxuid_from_key(obj_key), None))
            # Get index of this mat for this object.
            # Mat indices for mesh faces are determined by their order in 'mat to ob' connections.
            # Only mats for meshes currently...
            me = obj.data
            idx = _objs_indices[obj] = _objs_indices.get(obj, -1) + 1
            mesh_mat_indices.setdefault(me, {})[mat] = idx
    del _objs_indices

    # Textures
    for tex, (tex_key, mats) in data_textures.items():
        for mat, fbx_mat_props in mats.items():
            mat_key, _objs = data_materials[mat]
            for fbx_prop in fbx_mat_props:
                # texture -> material properties
                connections.append((b"OP", get_fbxuid_from_key(tex_key), get_fbxuid_from_key(mat_key), fbx_prop))

    # Images
    for vid, (vid_key, texs) in data_videos.items():
        for tex in texs:
            tex_key, _texs = data_textures[tex]
            connections.append((b"OO", get_fbxuid_from_key(vid_key), get_fbxuid_from_key(tex_key), None))

    ##### And pack all this!

    return FBXData(
        templates, templates_users, connections,
        settings, scene, objects,
        data_lamps, data_cameras, data_meshes, mesh_mat_indices,
        data_bones, data_deformers,
        data_world, data_materials, data_textures, data_videos,
    )


##### Top-level FBX elements generators. #####

def fbx_header_elements(root, scene_data, time=None):
    """
    Write boiling code of FBX root.
    time is expected to be a datetime.datetime object, or None (using now() in this case).
    """
    ##### Start of FBXHeaderExtension element.
    header_ext = elem_empty(root, b"FBXHeaderExtension")

    elem_data_single_int32(header_ext, b"FBXHeaderVersion", FBX_HEADER_VERSION)

    elem_data_single_int32(header_ext, b"FBXVersion", FBX_VERSION)

    # No encryption!
    elem_data_single_int32(header_ext, b"EncryptionType", 0)

    if time is None:
        time = datetime.datetime.now()
    elem = elem_empty(header_ext, b"CreationTimeStamp")
    elem_data_single_int32(elem, b"Version", 1000)
    elem_data_single_int32(elem, b"Year", time.year)
    elem_data_single_int32(elem, b"Month", time.month)
    elem_data_single_int32(elem, b"Day", time.day)
    elem_data_single_int32(elem, b"Hour", time.hour)
    elem_data_single_int32(elem, b"Minute", time.minute)
    elem_data_single_int32(elem, b"Second", time.second)
    elem_data_single_int32(elem, b"Millisecond", time.microsecond // 1000)

    elem_data_single_string_unicode(header_ext, b"Creator", "Blender version %s" % bpy.app.version_string)

    # 'SceneInfo' seems mandatory to get a valid FBX file...
    # TODO use real values!
    # XXX Should we use scene.name.encode() here?
    scene_info = elem_data_single_string(header_ext, b"SceneInfo", fbx_name_class(b"GlobalInfo", b"SceneInfo"))
    scene_info.add_string(b"UserData")
    elem_data_single_string(scene_info, b"Type", b"UserData")
    elem_data_single_int32(scene_info, b"Version", FBX_SCENEINFO_VERSION)
    meta_data = elem_empty(scene_info, b"MetaData")
    elem_data_single_int32(meta_data, b"Version", FBX_SCENEINFO_VERSION)
    elem_data_single_string(meta_data, b"Title", b"")
    elem_data_single_string(meta_data, b"Subject", b"")
    elem_data_single_string(meta_data, b"Author", b"")
    elem_data_single_string(meta_data, b"Keywords", b"")
    elem_data_single_string(meta_data, b"Revision", b"")
    elem_data_single_string(meta_data, b"Comment", b"")

    props = elem_properties(scene_info)
    elem_props_set(props, "p_string_url", b"DocumentUrl", "/foobar.fbx")
    elem_props_set(props, "p_string_url", b"SrcDocumentUrl", "/foobar.fbx")
    original = elem_props_compound(props, b"Original")
    original("p_string", b"ApplicationVendor", "Blender Foundation")
    original("p_string", b"ApplicationName", "Blender")
    original("p_string", b"ApplicationVersion", "2.70")
    original("p_datetime", b"DateTime_GMT", "01/01/1970 00:00:00.000")
    original("p_string", b"FileName", "/foobar.fbx")
    lastsaved = elem_props_compound(props, b"LastSaved")
    lastsaved("p_string", b"ApplicationVendor", "Blender Foundation")
    lastsaved("p_string", b"ApplicationName", "Blender")
    lastsaved("p_string", b"ApplicationVersion", "2.70")
    lastsaved("p_datetime", b"DateTime_GMT", "01/01/1970 00:00:00.000")

    ##### End of FBXHeaderExtension element.

    # FileID is replaced by dummy value currently...
    elem_data_single_bytes(root, b"FileId", b"FooBar")

    # CreationTime is replaced by dummy value currently, but anyway...
    elem_data_single_string_unicode(root, b"CreationTime",
                                    "{:04}-{:02}-{:02} {:02}:{:02}:{:02}:{:03}"
                                    "".format(time.year, time.month, time.day, time.hour, time.minute, time.second,
                                              time.microsecond * 1000))

    elem_data_single_string_unicode(root, b"Creator", "Blender version %s" % bpy.app.version_string)

    ##### Start of GlobalSettings element.
    global_settings = elem_empty(root, b"GlobalSettings")

    elem_data_single_int32(global_settings, b"Version", 1000)

    props = elem_properties(global_settings)
    up_axis, front_axis, coord_axis = RIGHT_HAND_AXES[scene_data.settings.to_axes]
    elem_props_set(props, "p_integer", b"UpAxis", up_axis[0])
    elem_props_set(props, "p_integer", b"UpAxisSign", up_axis[1])
    elem_props_set(props, "p_integer", b"FrontAxis", front_axis[0])
    elem_props_set(props, "p_integer", b"FrontAxisSign", front_axis[1])
    elem_props_set(props, "p_integer", b"CoordAxis", coord_axis[0])
    elem_props_set(props, "p_integer", b"CoordAxisSign", coord_axis[1])
    elem_props_set(props, "p_number", b"UnitScaleFactor", 1.0)
    elem_props_set(props, "p_color_rgb", b"AmbientColor", (0.0, 0.0, 0.0))
    elem_props_set(props, "p_string", b"DefaultCamera", "Producer Perspective")
    # XXX Those time stuff is taken from a file, have no (complete) idea what it means!
    elem_props_set(props, "p_enum", b"TimeMode", 11)
    elem_props_set(props, "p_timestamp", b"TimeSpanStart", 0)
    elem_props_set(props, "p_timestamp", b"TimeSpanStop", 46186158000)  # XXX One second!

    ##### End of GlobalSettings element.


def fbx_documents_elements(root, scene_data):
    """
    Write 'Document' part of FBX root.
    Seems like FBX support multiple documents, but until I find examples of such, we'll stick to single doc!
    time is expected to be a datetime.datetime object, or None (using now() in this case).
    """
    name = scene_data.scene.name

    ##### Start of Documents element.
    docs = elem_empty(root, b"Documents")

    elem_data_single_int32(docs, b"Count", 1)

    doc_uid = get_fbxuid_from_key("__FBX_Document__" + name)
    doc = elem_data_single_int64(docs, b"Document", doc_uid)
    doc.add_string(b"")
    doc.add_string_unicode(name)

    props = elem_properties(doc)
    elem_props_set(props, "p_object", b"SourceObject")
    elem_props_set(props, "p_string", b"ActiveAnimStackName", "")

    # XXX Some kind of ID? Offset?
    #     Anyway, as long as we have only one doc, probably not an issue.
    elem_data_single_int64(doc, b"RootNode", 0)


def fbx_references_elements(root, scene_data):
    """
    Have no idea what references are in FBX currently... Just writing empty element.
    """
    docs = elem_empty(root, b"References")


def fbx_definitions_elements(root, scene_data):
    """
    Templates definitions. Only used by Objects data afaik (apart from dummy GlobalSettings one).
    """
    definitions = elem_empty(root, b"Definitions")

    elem_data_single_int32(definitions, b"Version", FBX_TEMPLATES_VERSION)
    elem_data_single_int32(definitions, b"Count", scene_data.templates_users)

    fbx_templates_generate(definitions, scene_data.templates)


def fbx_objects_elements(root, scene_data):
    """
    Data (objects, geometry, material, textures, armatures, etc.
    """
    objects = elem_empty(root, b"Objects")

    for lamp in scene_data.data_lamps.keys():
        fbx_data_lamp_elements(objects, lamp, scene_data)

    for cam in scene_data.data_cameras.keys():
        fbx_data_camera_elements(objects, cam, scene_data)

    for mesh in scene_data.data_meshes.keys():
        fbx_data_mesh_elements(objects, mesh, scene_data)

    for obj in scene_data.objects.keys():
        fbx_data_object_elements(objects, obj, scene_data)

    for obj in scene_data.objects.keys():
        if not isinstance(obj, Object) or obj.type not in {'ARMATURE'}:
            continue
        fbx_data_armature_elements(objects, obj, scene_data)

    for mat in scene_data.data_materials.keys():
        fbx_data_material_elements(objects, mat, scene_data)

    for tex in scene_data.data_textures.keys():
        fbx_data_texture_file_elements(objects, tex, scene_data)

    for vid in scene_data.data_videos.keys():
        fbx_data_video_elements(objects, vid, scene_data)


def fbx_connections_elements(root, scene_data):
    """
    Relations between Objects (which material uses which texture, and so on).
    """
    connections = elem_empty(root, b"Connections")

    for c in scene_data.connections:
        elem_connection(connections, *c)


def fbx_takes_elements(root, scene_data):
    """
    Animations. Have yet to check how this work...
    """
    takes = elem_empty(root, b"Takes")
    elem_data_single_string(takes, b"Current", b"")


##### "Main" functions. #####
FBXSettingsMedia = namedtuple("FBXSettingsMedia", (
    "path_mode", "base_src", "base_dst", "subdir",
    "embed_textures", "copy_set",
))
FBXSettings = namedtuple("FBXSettings", (
    "to_axes", "global_matrix", "global_scale",
    "bake_space_transform", "global_matrix_inv", "global_matrix_inv_transposed",
    "context_objects", "object_types", "use_mesh_modifiers",
    "mesh_smooth_type", "use_mesh_edges", "use_tspace", "use_armature_deform_only",
    "use_anim", "use_anim_optimize", "anim_optimize_precision", "use_anim_action_all", "use_default_take",
    "use_metadata", "media_settings", "use_custom_properties",
))


# This func can be called with just the filepath
def save_single(operator, scene, filepath="",
                global_matrix=Matrix(),
                axis_up="Z",
                axis_forward="Y",
                context_objects=None,
                object_types=None,
                use_mesh_modifiers=True,
                mesh_smooth_type='FACE',
                use_armature_deform_only=False,
                use_anim=True,
                use_anim_optimize=True,
                anim_optimize_precision=6,
                use_anim_action_all=False,
                use_metadata=True,
                path_mode='AUTO',
                use_mesh_edges=True,
                use_tspace=True,
                use_default_take=True,
                embed_textures=False,
                use_custom_properties=False,
                bake_space_transform=False,
                **kwargs
                ):

    if object_types is None:
        object_types = {'EMPTY', 'CAMERA', 'LAMP', 'ARMATURE', 'MESH'}

    global_scale = global_matrix.median_scale
    global_matrix_inv = global_matrix.inverted()
    # For transforming mesh normals.
    global_matrix_inv_transposed = global_matrix_inv.transposed()

    # Only embed textures in COPY mode!
    if embed_textures and path_mode != 'COPY':
        embed_textures = False

    media_settings = FBXSettingsMedia(
        path_mode,
        os.path.dirname(bpy.data.filepath),  # base_src
        os.path.dirname(filepath),  # base_dst
        # Local dir where to put images (medias), using FBX conventions.
        os.path.splitext(os.path.basename(filepath))[0] + ".fbm",  # subdir
        embed_textures,
        set(),  # copy_set
    )

    settings = FBXSettings(
        (axis_up, axis_forward), global_matrix, global_scale,
        bake_space_transform, global_matrix_inv, global_matrix_inv_transposed,
        context_objects, object_types, use_mesh_modifiers,
        mesh_smooth_type, use_mesh_edges, use_tspace, use_armature_deform_only,
        use_anim, use_anim_optimize, anim_optimize_precision, use_anim_action_all, use_default_take,
        use_metadata, media_settings, use_custom_properties,
    )

    import bpy_extras.io_utils

    print('\nFBX export starting... %r' % filepath)
    start_time = time.process_time()

    # Generate some data about exported scene...
    scene_data = fbx_data_from_scene(scene, settings)

    root = elem_empty(None, b"")  # Root element has no id, as it is not saved per se!

    # Mostly FBXHeaderExtension and GlobalSettings.
    fbx_header_elements(root, scene_data)

    # Documents and References are pretty much void currently.
    fbx_documents_elements(root, scene_data)
    fbx_references_elements(root, scene_data)

    # Templates definitions.
    fbx_definitions_elements(root, scene_data)

    # Actual data.
    fbx_objects_elements(root, scene_data)

    # How data are inter-connected.
    fbx_connections_elements(root, scene_data)

    # Animation.
    fbx_takes_elements(root, scene_data)

    # And we are down, we can write the whole thing!
    encode_bin.write(filepath, root, FBX_VERSION)

    # copy all collected files, if we did not embed them.
    if not media_settings.embed_textures:
        bpy_extras.io_utils.path_reference_copy(media_settings.copy_set)

    print('export finished in %.4f sec.' % (time.process_time() - start_time))
    return {'FINISHED'}


# defaults for applications, currently only unity but could add others.
def defaults_unity3d():
    return {
        "global_matrix": Matrix.Rotation(-math.pi / 2.0, 4, 'X'),
        "use_selection": False,
        "object_types": {'ARMATURE', 'EMPTY', 'MESH'},
        "use_mesh_modifiers": True,
        "use_armature_deform_only": True,
        "use_anim": True,
        "use_anim_optimize": False,
        "use_anim_action_all": True,
        "batch_mode": 'OFF',
        "use_default_take": True,
        # Should really be True, but it can cause problems if a model is already in a scene or prefab
        # with the old transforms.
        "bake_space_transform": False,
    }


def save(operator, context,
         filepath="",
         use_selection=False,
         batch_mode='OFF',
         use_batch_own_dir=False,
         **kwargs
         ):
    """
    This is a wrapper around save_single, which handles multi-scenes (or groups) cases, when batch-exporting a whole
    .blend file.
    """

    ret = None

    org_mode = None
    if context.active_object and context.active_object.mode != 'OBJECT' and bpy.ops.object.mode_set.poll():
        org_mode = context.active_object.mode
        bpy.ops.object.mode_set(mode='OBJECT')

    if batch_mode == 'OFF':
        kwargs_mod = kwargs.copy()
        if use_selection:
            kwargs_mod["context_objects"] = context.selected_objects
        else:
            kwargs_mod["context_objects"] = context.scene.objects

        ret = save_single(operator, context.scene, filepath, **kwargs_mod)
    else:
        fbxpath = filepath

        prefix = os.path.basename(fbxpath)
        if prefix:
            fbxpath = os.path.dirname(fbxpath)

        if batch_mode == 'GROUP':
            data_seq = bpy.data.groups
        else:
            data_seq = bpy.data.scenes

        # call this function within a loop with BATCH_ENABLE == False
        # no scene switching done at the moment.
        # orig_sce = context.scene

        new_fbxpath = fbxpath  # own dir option modifies, we need to keep an original
        for data in data_seq:  # scene or group
            newname = "_".join((prefix, bpy.path.clean_name(data.name)))

            if use_batch_own_dir:
                new_fbxpath = os.path.join(fbxpath, newname)
                # path may already exist
                # TODO - might exist but be a file. unlikely but should probably account for it.

                if not os.path.exists(new_fbxpath):
                    os.makedirs(new_fbxpath)

            filepath = os.path.join(new_fbxpath, newname + '.fbx')

            print('\nBatch exporting %s as...\n\t%r' % (data, filepath))

            if batch_mode == 'GROUP':  # group
                # group, so objects update properly, add a dummy scene.
                scene = bpy.data.scenes.new(name="FBX_Temp")
                scene.layers = [True] * 20
                # bpy.data.scenes.active = scene # XXX, cant switch
                for ob_base in data.objects:
                    scene.objects.link(ob_base)

                scene.update()
                # TODO - BUMMER! Armatures not in the group wont animate the mesh
            else:
                scene = data

            kwargs_batch = kwargs.copy()
            kwargs_batch["context_objects"] = data.objects

            save_single(operator, scene, filepath, **kwargs_batch)

            if batch_mode == 'GROUP':
                # remove temp group scene
                bpy.data.scenes.remove(scene)

        # no active scene changing!
        # bpy.data.scenes.active = orig_sce

        ret = {'FINISHED'}  # so the script wont run after we have batch exported.

    if context.active_object and org_mode and bpy.ops.object.mode_set.poll():
        bpy.ops.object.mode_set(mode=org_mode)

    return ret