path: root/io_export_unreal_psk_psa.py

 #  ***** GPL LICENSE BLOCK *****
 #
 #  This program is free software: you can redistribute it and/or modify
 #  it under the terms of the GNU General Public License as published by
 #  the Free Software Foundation, either version 3 of the License, or
 #  (at your option) any later version.
 #
 #  This program is distributed in the hope that it will be useful,
 #  but WITHOUT ANY WARRANTY; without even the implied warranty of
 #  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 #  GNU General Public License for more details.
 #
 #  You should have received a copy of the GNU General Public License
 #  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 #  All rights reserved.
 #  ***** GPL LICENSE BLOCK *****

"""

-- Unreal Skeletal Mesh and Animation Export (.psk  and .psa) export script v0.0.1 --<br> 

- NOTES:
- This script Exports To Unreal's PSK and PSA file formats for Skeletal Meshes and Animations. <br>
- This script DOES NOT support vertex animation! These require completely different file formats. <br>

- v0.0.1
- Initial version

- v0.0.2
- This version adds support for more than one material index!

[ - Edit by: Darknet
- v0.0.3 - v0.0.12
- This will work on UT3 and it is a stable version that work with vehicle for testing. 
- Main Bone fix no dummy needed to be there.
- Just bone issues position, rotation, and offset for psk.
- The armature bone position, rotation, and the offset of the bone is fix. It was to deal with skeleton mesh export for psk.
- Animation is fix for position, offset, rotation bone support one rotation direction when armature build. 
- It will convert your mesh into triangular when exporting to psk file.
- Did not work with psa export yet.

- v0.0.13
- The animatoin will support different bone rotations when export the animation.

- v0.0.14
- Fixed Action set keys frames when there is no pose keys and it will ignore it.

- v0.0.15
- Fixed multiple objects when exporting to psk. Select one mesh to export to psk.
- ]

- v0.1.1
- Blender 2.50 svn (Support)

Credit to:
- export_cal3d.py (Position of the Bones Format)
- blender2md5.py (Animation Translation Format)
- export_obj.py (Blender 2.5/Pyhton 3.x Format)

- freenode #blendercoder -> user -> ideasman42

- Give Credit to those who work on this script.

- http://sinsoft.com
"""


bl_addon_info = {
    'name': 'Export Skeleletal Mesh/Animation Data',
    'author': 'Darknet/Optimus_P-Fat/Active_Trash/Sinsoft',
    'version': '2.0',
    'blender': (2, 5, 3),
    'location': 'File > Export > Skeletal Mesh/Animation Data (.psk/.psa)',
    'description': 'Export Unreal Engine (.psk)',
    'warning': '', # used for warning icon and text in addons panel
    'wiki_url': 'http://wiki.blender.org/index.php/Extensions:2.5/Py/' \
        'Scripts/File_I-O/Unreal_psk_psa',
    'tracker_url': 'https://projects.blender.org/tracker/index.php?'\
        'func=detail&aid=21366&group_id=153&atid=469',
    'category': 'Import/Export'}


import os
import time
import datetime
import bpy
import mathutils
import operator

from struct import pack, calcsize

MENUPANELBOOL = True

# REFERENCE MATERIAL JUST IN CASE:
# 
# U = x / sqrt(x^2 + y^2 + z^2)
# V = y / sqrt(x^2 + y^2 + z^2)
#
# Triangles specifed counter clockwise for front face
#
#defines for sizeofs
SIZE_FQUAT = 16
SIZE_FVECTOR = 12
SIZE_VJOINTPOS = 44
SIZE_ANIMINFOBINARY = 168
SIZE_VCHUNKHEADER = 32
SIZE_VMATERIAL = 88
SIZE_VBONE = 120
SIZE_FNAMEDBONEBINARY = 120
SIZE_VRAWBONEINFLUENCE = 12
SIZE_VQUATANIMKEY = 32
SIZE_VVERTEX = 16
SIZE_VPOINT = 12
SIZE_VTRIANGLE = 12

########################################################################
# Generic Object->Integer mapping
# the object must be usable as a dictionary key
class ObjMap:
	def __init__(self):
		self.dict = {}
		self.next = 0
	def get(self, obj):
		if obj in self.dict:
			return self.dict[obj]
		else:
			id = self.next
			self.next = self.next + 1
			self.dict[obj] = id
			return id
		
	def items(self):
		getval = operator.itemgetter(0)
		getkey = operator.itemgetter(1)
		return map(getval, sorted(self.dict.items(), key=getkey))

########################################################################
# RG - UNREAL DATA STRUCTS - CONVERTED FROM C STRUCTS GIVEN ON UDN SITE 
# provided here: http://udn.epicgames.com/Two/BinaryFormatSpecifications.html
# updated UDK (Unreal Engine 3): http://udn.epicgames.com/Three/BinaryFormatSpecifications.html
class FQuat:
	def __init__(self): 
		self.X = 0.0
		self.Y = 0.0
		self.Z = 0.0
		self.W = 1.0
		
	def dump(self):
		data = pack('ffff', self.X, self.Y, self.Z, self.W)
		return data
		
	def __cmp__(self, other):
		return cmp(self.X, other.X) \
			or cmp(self.Y, other.Y) \
			or cmp(self.Z, other.Z) \
			or cmp(self.W, other.W)
		
	def __hash__(self):
		return hash(self.X) ^ hash(self.Y) ^ hash(self.Z) ^ hash(self.W)
		
	def __str__(self):
		return "[%f,%f,%f,%f](FQuat)" % (self.X, self.Y, self.Z, self.W)
		
class FVector(object):
	def __init__(self, X=0.0, Y=0.0, Z=0.0):
		self.X = X
		self.Y = Y
		self.Z = Z
		
	def dump(self):
		data = pack('fff', self.X, self.Y, self.Z)
		return data
		
	def __cmp__(self, other):
		return cmp(self.X, other.X) \
			or cmp(self.Y, other.Y) \
			or cmp(self.Z, other.Z)
		
	def _key(self):
		return (type(self).__name__, self.X, self.Y, self.Z)
		
	def __hash__(self):
		return hash(self._key())
		
	def __eq__(self, other):
		if not hasattr(other, '_key'):
			return False
		return self._key() == other._key() 
		
	def dot(self, other):
		return self.X * other.X + self.Y * other.Y + self.Z * other.Z
	
	def cross(self, other):
		return FVector(self.Y * other.Z - self.Z * other.Y,
				self.Z * other.X - self.X * other.Z,
				self.X * other.Y - self.Y * other.X)
				
	def sub(self, other):
		return FVector(self.X - other.X,
			self.Y - other.Y,
			self.Z - other.Z)

class VJointPos:
	def __init__(self):
		self.Orientation = FQuat()
		self.Position = FVector()
		self.Length = 0.0
		self.XSize = 0.0
		self.YSize = 0.0
		self.ZSize = 0.0
		
	def dump(self):
		data = self.Orientation.dump() + self.Position.dump() + pack('4f', self.Length, self.XSize, self.YSize, self.ZSize)
		return data
			
class AnimInfoBinary:
	def __init__(self):
		self.Name = "" # length=64
		self.Group = ""	# length=64
		self.TotalBones = 0
		self.RootInclude = 0
		self.KeyCompressionStyle = 0
		self.KeyQuotum = 0
		self.KeyPrediction = 0.0
		self.TrackTime = 0.0
		self.AnimRate = 0.0
		self.StartBone = 0
		self.FirstRawFrame = 0
		self.NumRawFrames = 0
		
	def dump(self):
		data = pack('64s64siiiifffiii', self.Name, self.Group, self.TotalBones, self.RootInclude, self.KeyCompressionStyle, self.KeyQuotum, self.KeyPrediction, self.TrackTime, self.AnimRate, self.StartBone, self.FirstRawFrame, self.NumRawFrames)
		return data

class VChunkHeader:
	def __init__(self, name, type_size):
		self.ChunkID = name # length=20
		self.TypeFlag = 1999801 # special value
		self.DataSize = type_size
		self.DataCount = 0
		
	def dump(self):
		data = pack('20siii', self.ChunkID, self.TypeFlag, self.DataSize, self.DataCount)
		return data
		
class VMaterial:
	def __init__(self):
		self.MaterialName = "" # length=64
		self.TextureIndex = 0
		self.PolyFlags = 0 # DWORD
		self.AuxMaterial = 0
		self.AuxFlags = 0 # DWORD
		self.LodBias = 0
		self.LodStyle = 0
		
	def dump(self):
		data = pack('64siLiLii', self.MaterialName, self.TextureIndex, self.PolyFlags, self.AuxMaterial, self.AuxFlags, self.LodBias, self.LodStyle)
		return data

class VBone:
	def __init__(self):
		self.Name = "" # length = 64
		self.Flags = 0 # DWORD
		self.NumChildren = 0
		self.ParentIndex = 0
		self.BonePos = VJointPos()
		
	def dump(self):
		data = pack('64sLii', self.Name, self.Flags, self.NumChildren, self.ParentIndex) + self.BonePos.dump()
		return data

#same as above - whatever - this is how Epic does it...		
class FNamedBoneBinary:
	def __init__(self):
		self.Name = "" # length = 64
		self.Flags = 0 # DWORD
		self.NumChildren = 0
		self.ParentIndex = 0
		self.BonePos = VJointPos()
		
		self.IsRealBone = 0  # this is set to 1 when the bone is actually a bone in the mesh and not a dummy
		
	def dump(self):
		data = pack('64sLii', self.Name, self.Flags, self.NumChildren, self.ParentIndex) + self.BonePos.dump()
		return data
	
class VRawBoneInfluence:
	def __init__(self):
		self.Weight = 0.0
		self.PointIndex = 0
		self.BoneIndex = 0
		
	def dump(self):
		data = pack('fii', self.Weight, self.PointIndex, self.BoneIndex)
		return data
		
class VQuatAnimKey:
	def __init__(self):
		self.Position = FVector()
		self.Orientation = FQuat()
		self.Time = 0.0
		
	def dump(self):
		data = self.Position.dump() + self.Orientation.dump() + pack('f', self.Time)
		return data
		
class VVertex(object):
	def __init__(self):
		self.PointIndex = 0 # WORD
		self.U = 0.0
		self.V = 0.0
		self.MatIndex = 0 #BYTE
		self.Reserved = 0 #BYTE
		
	def dump(self):
		data = pack('HHffBBH', self.PointIndex, 0, self.U, self.V, self.MatIndex, self.Reserved, 0)
		return data
		
	def __cmp__(self, other):
		return cmp(self.PointIndex, other.PointIndex) \
			or cmp(self.U, other.U) \
			or cmp(self.V, other.V) \
			or cmp(self.MatIndex, other.MatIndex) \
			or cmp(self.Reserved, other.Reserved)
	
	def _key(self):
		return (type(self).__name__,self.PointIndex, self.U, self.V,self.MatIndex,self.Reserved)
		
	def __hash__(self):
		return hash(self._key())
		
	def __eq__(self, other):
		if not hasattr(other, '_key'):
			return False
		return self._key() == other._key()
		
class VPoint(object):
	def __init__(self):
		self.Point = FVector()
		
	def dump(self):
		return self.Point.dump()
		
	def __cmp__(self, other):
		return cmp(self.Point, other.Point)
	
	def _key(self):
		return (type(self).__name__, self.Point)
	
	def __hash__(self):
		return hash(self._key())
		
	def __eq__(self, other):
		if not hasattr(other, '_key'):
			return False
		return self._key() == other._key() 
		
class VTriangle:
	def __init__(self):
		self.WedgeIndex0 = 0 # WORD
		self.WedgeIndex1 = 0 # WORD
		self.WedgeIndex2 = 0 # WORD
		self.MatIndex = 0 # BYTE
		self.AuxMatIndex = 0 # BYTE
		self.SmoothingGroups = 0 # DWORD
		
	def dump(self):
		data = pack('HHHBBL', self.WedgeIndex0, self.WedgeIndex1, self.WedgeIndex2, self.MatIndex, self.AuxMatIndex, self.SmoothingGroups)
		return data

# END UNREAL DATA STRUCTS
########################################################################

########################################################################
#RG - helper class to handle the normal way the UT files are stored 
#as sections consisting of a header and then a list of data structures
class FileSection:
	def __init__(self, name, type_size):
		self.Header = VChunkHeader(name, type_size)
		self.Data = [] # list of datatypes
		
	def dump(self):
		data = self.Header.dump()
		for i in range(len(self.Data)):
			data = data + self.Data[i].dump()
		return data
		
	def UpdateHeader(self):
		self.Header.DataCount = len(self.Data)
		
class PSKFile:
	def __init__(self):
		self.GeneralHeader = VChunkHeader("ACTRHEAD", 0)
		self.Points = FileSection("PNTS0000", SIZE_VPOINT)		#VPoint
		self.Wedges = FileSection("VTXW0000", SIZE_VVERTEX)		#VVertex
		self.Faces = FileSection("FACE0000", SIZE_VTRIANGLE)		#VTriangle
		self.Materials = FileSection("MATT0000", SIZE_VMATERIAL)	#VMaterial
		self.Bones = FileSection("REFSKELT", SIZE_VBONE)		#VBone
		self.Influences = FileSection("RAWWEIGHTS", SIZE_VRAWBONEINFLUENCE)	#VRawBoneInfluence
		
		#RG - this mapping is not dumped, but is used internally to store the new point indices 
		# for vertex groups calculated during the mesh dump, so they can be used again
		# to dump bone influences during the armature dump
		#
		# the key in this dictionary is the VertexGroup/Bone Name, and the value
		# is a list of tuples containing the new point index and the weight, in that order
		#
		# Layout:
		# { groupname : [ (index, weight), ... ], ... }
		#
		# example: 
		# { 'MyVertexGroup' : [ (0, 1.0), (5, 1.0), (3, 0.5) ] , 'OtherGroup' : [(2, 1.0)] }
		
		self.VertexGroups = {} 
		
	def AddPoint(self, p):
		#print ('AddPoint')
		self.Points.Data.append(p)
		
	def AddWedge(self, w):
		#print ('AddWedge')
		self.Wedges.Data.append(w)
	
	def AddFace(self, f):
		#print ('AddFace')
		self.Faces.Data.append(f)
		
	def AddMaterial(self, m):
		#print ('AddMaterial')
		self.Materials.Data.append(m)
		
	def AddBone(self, b):
		#print ('AddBone [%s]: Position: (x=%f, y=%f, z=%f) Rotation=(%f,%f,%f,%f)'  % (b.Name, b.BonePos.Position.X, b.BonePos.Position.Y, b.BonePos.Position.Z, b.BonePos.Orientation.X,b.BonePos.Orientation.Y,b.BonePos.Orientation.Z,b.BonePos.Orientation.W))
		self.Bones.Data.append(b)
		
	def AddInfluence(self, i):
		#print ('AddInfluence')
		self.Influences.Data.append(i)
		
	def UpdateHeaders(self):
		self.Points.UpdateHeader()
		self.Wedges.UpdateHeader()
		self.Faces.UpdateHeader()
		self.Materials.UpdateHeader()
		self.Bones.UpdateHeader()
		self.Influences.UpdateHeader()
		
	def dump(self):
		self.UpdateHeaders()
		data = self.GeneralHeader.dump() + self.Points.dump() + self.Wedges.dump() + self.Faces.dump() + self.Materials.dump() + self.Bones.dump() + self.Influences.dump()
		return data
		
	def GetMatByIndex(self, mat_index):
		if mat_index >= 0 and len(self.Materials.Data) > mat_index:
			return self.Materials.Data[mat_index]
		else:
			m = VMaterial()
			m.MaterialName = "Mat%i" % mat_index
			self.AddMaterial(m)
			return m
		
	def PrintOut(self):
		print ("--- PSK FILE EXPORTED ---")
		print ('point count: %i' % len(self.Points.Data))
		print ('wedge count: %i' % len(self.Wedges.Data))
		print ('face count: %i' % len(self.Faces.Data))
		print ('material count: %i' % len(self.Materials.Data))
		print ('bone count: %i' % len(self.Bones.Data))
		print ('inlfuence count: %i' % len(self.Influences.Data))
		print ('-------------------------')

# PSA FILE NOTES FROM UDN:
#
#	The raw key array holds all the keys for all the bones in all the specified sequences, 
#	organized as follows:
#	For each AnimInfoBinary's sequence there are [Number of bones] times [Number of frames keys] 
#	in the VQuatAnimKeys, laid out as tracks of [numframes] keys for each bone in the order of 
#	the bones as defined in the array of FnamedBoneBinary in the PSA. 
#
#	Once the data from the PSK (now digested into native skeletal mesh) and PSA (digested into 
#	a native animation object containing one or more sequences) are associated together at runtime, 
#	bones are linked up by name. Any bone in a skeleton (from the PSK) that finds no partner in 
#	the animation sequence (from the PSA) will assume its reference pose stance ( as defined in 
#	the offsets & rotations that are in the VBones making up the reference skeleton from the PSK)

class PSAFile:
	def __init__(self):
		self.GeneralHeader = VChunkHeader("ANIMHEAD", 0)
		self.Bones = FileSection("BONENAMES", SIZE_FNAMEDBONEBINARY)	#FNamedBoneBinary
		self.Animations = FileSection("ANIMINFO", SIZE_ANIMINFOBINARY)	#AnimInfoBinary
		self.RawKeys = FileSection("ANIMKEYS", SIZE_VQUATANIMKEY)	#VQuatAnimKey
		
		# this will take the format of key=Bone Name, value = (BoneIndex, Bone Object)
		# THIS IS NOT DUMPED
		self.BoneLookup = {} 
		
	def dump(self):
		data = self.Generalheader.dump() + self.Bones.dump() + self.Animations.dump() + self.RawKeys.dump()
		return data
	
	def AddBone(self, b):
		#LOUD
		#print "AddBone: " + b.Name
		self.Bones.Data.append(b)
		
	def AddAnimation(self, a):
		#LOUD
		#print "AddAnimation: %s, TotalBones: %i, AnimRate: %f, NumRawFrames: %i, TrackTime: %f" % (a.Name, a.TotalBones, a.AnimRate, a.NumRawFrames, a.TrackTime)
		self.Animations.Data.append(a)
		
	def AddRawKey(self, k):
		#LOUD
		#print "AddRawKey [%i]: Time: %f, Quat: x=%f, y=%f, z=%f, w=%f, Position: x=%f, y=%f, z=%f" % (len(self.RawKeys.Data), k.Time, k.Orientation.X, k.Orientation.Y, k.Orientation.Z, k.Orientation.W, k.Position.X, k.Position.Y, k.Position.Z)
		self.RawKeys.Data.append(k)
		
	def UpdateHeaders(self):
		self.Bones.UpdateHeader()
		self.Animations.UpdateHeader()
		self.RawKeys.UpdateHeader()
		
	def GetBoneByIndex(self, bone_index):
		if bone_index >= 0 and len(self.Bones.Data) > bone_index:
			return self.Bones.Data[bone_index]
	
	def IsEmpty(self):
		return (len(self.Bones.Data) == 0 or len(self.Animations.Data) == 0)
	
	def StoreBone(self, b):
		self.BoneLookup[b.Name] = [-1, b]
					
	def UseBone(self, bone_name):
		if bone_name in self.BoneLookup:
			bone_data = self.BoneLookup[bone_name]
			
			if bone_data[0] == -1:
				bone_data[0] = len(self.Bones.Data)
				self.AddBone(bone_data[1])
				#self.Bones.Data.append(bone_data[1])
			
			return bone_data[0]
			
	def GetBoneByName(self, bone_name):
		if bone_name in self.BoneLookup:
			bone_data = self.BoneLookup[bone_name]
			return bone_data[1]
		
	def GetBoneIndex(self, bone_name):
		if bone_name in self.BoneLookup:
			bone_data = self.BoneLookup[bone_name]
			return bone_data[0]
		
	def dump(self):
		self.UpdateHeaders()
		data = self.GeneralHeader.dump() + self.Bones.dump() + self.Animations.dump() + self.RawKeys.dump()
		return data
		
	def PrintOut(self):
		print ('--- PSA FILE EXPORTED ---')
		print ('bone count: %i' % len(self.Bones.Data))
		print ('animation count: %i' % len(self.Animations.Data))
		print ('rawkey count: %i' % len(self.RawKeys.Data))
		print ('-------------------------')
		
####################################	
# helpers to create bone structs
def make_vbone(name, parent_index, child_count, orientation_quat, position_vect):
	bone = VBone()
	bone.Name = name
	bone.ParentIndex = parent_index
	bone.NumChildren = child_count
	bone.BonePos.Orientation = orientation_quat
	bone.BonePos.Position.X = position_vect.x
	bone.BonePos.Position.Y = position_vect.y
	bone.BonePos.Position.Z = position_vect.z
	
	#these values seem to be ignored?
	#bone.BonePos.Length = tail.length
	#bone.BonePos.XSize = tail.x
	#bone.BonePos.YSize = tail.y
	#bone.BonePos.ZSize = tail.z

	return bone

def make_namedbonebinary(name, parent_index, child_count, orientation_quat, position_vect, is_real):
	bone = FNamedBoneBinary()
	bone.Name = name
	bone.ParentIndex = parent_index
	bone.NumChildren = child_count
	bone.BonePos.Orientation = orientation_quat
	bone.BonePos.Position.X = position_vect.x
	bone.BonePos.Position.Y = position_vect.y
	bone.BonePos.Position.Z = position_vect.z
	bone.IsRealBone = is_real
	return bone	
	
##################################################
#RG - check to make sure face isnt a line
#The face has to be triangle not a line
def is_1d_face(blender_face,mesh):
	#ID Vertex of id point
	v0 = blender_face.verts[0]
	v1 = blender_face.verts[1]
	v2 = blender_face.verts[2]
	
	return (mesh.verts[v0].co == mesh.verts[v1].co or \
	mesh.verts[v1].co == mesh.verts[v2].co or \
	mesh.verts[v2].co == mesh.verts[v0].co)
	return False

##################################################
# http://en.wikibooks.org/wiki/Blender_3D:_Blending_Into_Python/Cookbook#Triangulate_NMesh

#blender 2.50 format using the Operators/command convert the mesh to tri mesh
def triangulateNMesh(object):
	bneedtri = False
	scene = bpy.context.scene
	bpy.ops.object.mode_set(mode='OBJECT')
	for i in scene.objects: i.select = False #deselect all objects
	object.select = True
	scene.objects.active = object #set the mesh object to current
	bpy.ops.object.mode_set(mode='OBJECT')
	print("Checking mesh if needs to convert quad to Tri...")
	for face in object.data.faces:
		if (len(face.verts) > 3):
			bneedtri = True
			break
	
	bpy.ops.object.mode_set(mode='OBJECT')
	if bneedtri == True:
		print("Converting quad to tri mesh...")
		me_da = object.data.copy() #copy data
		me_ob = object.copy() #copy object
		#note two copy two types else it will use the current data or mesh
		me_ob.data = me_da
		bpy.context.scene.objects.link(me_ob)#link the object to the scene #current object location
		for i in scene.objects: i.select = False #deselect all objects
		me_ob.select = True
		scene.objects.active = me_ob #set the mesh object to current
		bpy.ops.object.mode_set(mode='EDIT') #Operators
		bpy.ops.mesh.select_all(action='SELECT')#select all the face/vertex/edge
		bpy.ops.mesh.quads_convert_to_tris() #Operators
		bpy.context.scene.update()
		bpy.ops.object.mode_set(mode='OBJECT') # set it in object
		bpy.context.scene.unrealtriangulatebool = True
		print("Triangulate Mesh Done!")
	else:
		print("No need to convert tri mesh.")
		me_ob = object
	return me_ob

#Blender Bone Index
class BBone:
	def __init__(self):
		self.bone = ""
		self.index = 0
bonedata = []
BBCount = 0	
#deal with mesh bones groups vertex point
def BoneIndex(bone):
	global BBCount, bonedata
	#print("//==============")
	#print(bone.name , "ID:",BBCount)
	BB = BBone()
	BB.bone = bone.name
	BB.index = BBCount
	bonedata.append(BB)
	BBCount += 1
	for current_child_bone in bone.children:
		BoneIndex(current_child_bone)

def BoneIndexArmature(blender_armature):
	global BBCount
	#print("\n Buildng bone before mesh \n")
	#objectbone = blender_armature.pose #Armature bone
	#print(blender_armature)
	objectbone = blender_armature[0].pose 
	#print(dir(ArmatureData))
	
	for bone in objectbone.bones:
		if(bone.parent == None):
			BoneIndex(bone)
			#BBCount += 1
			break
	
# Actual object parsing functions
def parse_meshes(blender_meshes, psk_file):
	#this is use to call the bone name and the index array for group index matches
	global bonedata
	#print("BONE DATA",len(bonedata))
	print ("----- parsing meshes -----")
	print("Number of Object Meshes:",len(blender_meshes))
	for current_obj in blender_meshes: #number of mesh that should be one mesh here
	
		current_obj = triangulateNMesh(current_obj)
		#print(dir(current_obj))
		print("Mesh Name:",current_obj.name)
		current_mesh = current_obj.data
		
		#if len(current_obj.materials) > 0:
		#	object_mat = current_obj.materials[0]
		object_material_index = current_obj.active_material_index
	
		points = ObjMap()
		wedges = ObjMap()
		
		discarded_face_count = 0
		print (" -- Dumping Mesh Faces -- LEN:", len(current_mesh.faces))
		for current_face in current_mesh.faces:
			#print ' -- Dumping UVs -- '
			#print current_face.uv_textures
			
			if len(current_face.verts) != 3:
				raise RuntimeError("Non-triangular face (%i)" % len(current_face.verts))
			
			#No Triangulate Yet
			#			if len(current_face.verts) != 3:
			#				raise RuntimeError("Non-triangular face (%i)" % len(current_face.verts))
			#				#TODO: add two fake faces made of triangles?
			
			#RG - apparently blender sometimes has problems when you do quad to triangle 
			#	conversion, and ends up creating faces that have only TWO points -
			# 	one of the points is simply in the vertex list for the face twice. 
			#	This is bad, since we can't get a real face normal for a LINE, we need 
			#	a plane for this. So, before we add the face to the list of real faces, 
			#	ensure that the face is actually a plane, and not a line. If it is not 
			#	planar, just discard it and notify the user in the console after we're
			#	done dumping the rest of the faces
			
			if not is_1d_face(current_face,current_mesh):
				#print("faces")
				wedge_list = []
				vect_list = []
				
				#get or create the current material
				m = psk_file.GetMatByIndex(object_material_index)

				face_index = current_face.index
				has_UV = False
				faceUV = None
				
				if len(current_mesh.uv_textures) > 0:
					has_UV = True	
					#print("face index: ",face_index)
					#faceUV = current_mesh.active_uv_texture.data[face_index]#UVs for current face
					#faceUV = current_mesh.active_uv_texture.data[0]#UVs for current face
					#print(face_index,"<[FACE NUMBER")
					uv_layer = current_mesh.active_uv_texture
					faceUV = uv_layer.data[face_index]
					#print("============================")
					#size(data) is number of texture faces. Each face has UVs
					#print("DATA face uv: ",len(faceUV.uv), " >> ",(faceUV.uv[0][0]))
				
				for i in range(3):
					vert_index = current_face.verts[i]
					vert = current_mesh.verts[vert_index]
					uv = []
					#assumes 3 UVs Per face (for now).
					if (has_UV):
						if len(faceUV.uv) != 3:
							print ("WARNING: Current face is missing UV coordinates - writing 0,0...")
							print ("WARNING: Face has more than 3 UVs - writing 0,0...")
							uv = [0.0, 0.0]
						else:
							#uv.append(faceUV.uv[i][0])
							#uv.append(faceUV.uv[i][1])
							uv = [faceUV.uv[i][0],faceUV.uv[i][1]] #OR bottom works better # 24 for cube
							#uv = list(faceUV.uv[i]) #30 just cube	
					else:
						print ("No UVs?")
						uv = [0.0, 0.0]
					#print("UV >",uv)
					#uv = [0.0, 0.0] #over ride uv that is not fixed
					#print(uv)
					#flip V coordinate because UEd requires it and DOESN'T flip it on its own like it
					#does with the mesh Y coordinates.
					#this is otherwise known as MAGIC-2
					uv[1] = 1.0 - uv[1]
					
					#deal with the min and max value
					#if value is over the set limit it will null the uv texture
					if (uv[0] > 1):
						uv[0] = 1
					if (uv[0] < 0):
						uv[0] = 0
					if (uv[1] > 1):
						uv[1] = 1
					if (uv[1] < 0):
						uv[1] = 0

					
					# RE - Append untransformed vector (for normal calc below)
					# TODO: convert to Blender.Mathutils
					vect_list.append(FVector(vert.co.x, vert.co.y, vert.co.z))
					
					# Transform position for export
					#vpos = vert.co * object_material_index
					vpos = vert.co * current_obj.matrix_local
					# Create the point
					p = VPoint()
					p.Point.X = vpos.x
					p.Point.Y = vpos.y
					p.Point.Z = vpos.z
					
					# Create the wedge
					w = VVertex()
					w.MatIndex = object_material_index
					w.PointIndex = points.get(p) # get index from map
					#Set UV TEXTURE
					w.U = uv[0]
					w.V = uv[1]
					index_wedge = wedges.get(w)
					wedge_list.append(index_wedge)
					
					#print results
					#print 'result PointIndex=%i, U=%f, V=%f, wedge_index=%i' % (
					#	w.PointIndex,
					#	w.U,
					#	w.V,
					#	wedge_index)
				
				# Determine face vertex order
				# get normal from blender
				no = current_face.normal
				
				# TODO: convert to Blender.Mathutils
				# convert to FVector
				norm = FVector(no[0], no[1], no[2])
				
				# Calculate the normal of the face in blender order
				tnorm = vect_list[1].sub(vect_list[0]).cross(vect_list[2].sub(vect_list[1]))
				
				# RE - dot the normal from blender order against the blender normal
				# this gives the product of the two vectors' lengths along the blender normal axis
				# all that matters is the sign
				dot = norm.dot(tnorm)

				# print results
				#print 'face norm: (%f,%f,%f), tnorm=(%f,%f,%f), dot=%f' % (
				#	norm.X, norm.Y, norm.Z,
				#	tnorm.X, tnorm.Y, tnorm.Z,
				#	dot)

				tri = VTriangle()
				# RE - magic: if the dot product above > 0, order the vertices 2, 1, 0
				#        if the dot product above < 0, order the vertices 0, 1, 2
				#        if the dot product is 0, then blender's normal is coplanar with the face
				#        and we cannot deduce which side of the face is the outside of the mesh
				if (dot > 0):
					(tri.WedgeIndex2, tri.WedgeIndex1, tri.WedgeIndex0) = wedge_list
				elif (dot < 0):
					(tri.WedgeIndex0, tri.WedgeIndex1, tri.WedgeIndex2) = wedge_list
				else:
					dindex0 = current_face.verts[0];
					dindex1 = current_face.verts[1];
					dindex2 = current_face.verts[2];
					raise RuntimeError("normal vector coplanar with face! points:", current_mesh.verts[dindex0].co, current_mesh.verts[dindex1].co, current_mesh.verts[dindex2].co)
				
				tri.MatIndex = object_material_index
				#print(tri)
				psk_file.AddFace(tri)
				
			else:
				discarded_face_count = discarded_face_count + 1
				
		print (" -- Dumping Mesh Points -- LEN:",len(points.dict))
		for point in points.items():
			psk_file.AddPoint(point)
		print (" -- Dumping Mesh Wedge -- LEN:",len(wedges.dict))
		for wedge in wedges.items():
			psk_file.AddWedge(wedge)
			
		#RG - if we happend upon any non-planar faces above that we've discarded, 
		#	just let the user know we discarded them here in case they want 
		#	to investigate
	
		if discarded_face_count > 0: 
			print ("INFO: Discarded %i non-planar faces." % (discarded_face_count))
		
		#RG - walk through the vertex groups and find the indexes into the PSK points array 
		#for them, then store that index and the weight as a tuple in a new list of 
		#verts for the group that we can look up later by bone name, since Blender matches
		#verts to bones for influences by having the VertexGroup named the same thing as
		#the bone

		#vertex group.
		for bonegroup in bonedata:
			#print("bone gourp build:",bonegroup.bone)
			vert_list = []
			for current_vert in current_mesh.verts:
				#print("INDEX V:",current_vert.index)
				vert_index = current_vert.index
				for vgroup in current_vert.groups:#vertex groupd id
					vert_weight = vgroup.weight
					if(bonegroup.index == vgroup.group):
						p = VPoint()
						vpos = current_vert.co * current_obj.matrix_local
						p.Point.X = vpos.x
						p.Point.Y = vpos.y 
						p.Point.Z = vpos.z
						#print(current_vert.co)
						point_index = points.get(p) #point index
						v_item = (point_index, vert_weight)
						vert_list.append(v_item)
			#bone name, [point id and wieght]
			#print("Add Vertex Group:",bonegroup.bone, " No. Points:",len(vert_list))
			psk_file.VertexGroups[bonegroup.bone] = vert_list
		
		#unrealtriangulatebool #this will remove the mesh from the scene
		if (bpy.context.scene.unrealtriangulatebool == True):
			print("Remove tmp Mesh [ " ,current_obj.name, " ] from scene >"  ,(bpy.context.scene.unrealtriangulatebool ))
			bpy.ops.object.mode_set(mode='OBJECT') # set it in object
			bpy.context.scene.objects.unlink(current_obj)
		
def make_fquat(bquat):
	quat = FQuat()
	
	#flip handedness for UT = set x,y,z to negative (rotate in other direction)
	quat.X = -bquat.x
	quat.Y = -bquat.y
	quat.Z = -bquat.z

	quat.W = bquat.w
	return quat
	
def make_fquat_default(bquat):
	quat = FQuat()
	
	quat.X = bquat.x
	quat.Y = bquat.y
	quat.Z = bquat.z
	
	quat.W = bquat.w
	return quat

# =================================================================================================
# TODO: remove this 1am hack
nbone = 0
def parse_bone(blender_bone, psk_file, psa_file, parent_id, is_root_bone, parent_matrix, parent_root):
	global nbone 	# look it's evil!
	#print '-------------------- Dumping Bone ---------------------- '

	#If bone does not have parent that mean it the root bone
	if blender_bone.parent == None:
		parent_root = blender_bone
	
	
	child_count = len(blender_bone.children)
	#child of parent
	child_parent = blender_bone.parent
	
	if child_parent != None:
		print ("--Bone Name:",blender_bone.name ," parent:" , blender_bone.parent.name, "ID:", nbone)
	else:
		print ("--Bone Name:",blender_bone.name ," parent: None" , "ID:", nbone)
	
	if child_parent != None:
		quat_root = blender_bone.matrix
		quat = make_fquat(quat_root.to_quat())
		
		quat_parent = child_parent.matrix.to_quat().inverse()
		parent_head = child_parent.head * quat_parent
		parent_tail = child_parent.tail * quat_parent
		
		set_position = (parent_tail - parent_head) + blender_bone.head
	else:
		# ROOT BONE
		#This for root 
		set_position = blender_bone.head * parent_matrix #ARMATURE OBJECT Locction
		rot_mat = blender_bone.matrix * parent_matrix.rotation_part() #ARMATURE OBJECT Rotation
		#print(dir(rot_mat))
		
		quat = make_fquat_default(rot_mat.to_quat())
		
	print ("[[======= FINAL POSITION:", set_position)
	final_parent_id = parent_id
	
	#RG/RE -
	#if we are not seperated by a small distance, create a dummy bone for the displacement
	#this is only needed for root bones, since UT assumes a connected skeleton, and from here
	#down the chain we just use "tail" as an endpoint
	#if(head.length > 0.001 and is_root_bone == 1):
	if(0):	
		pb = make_vbone("dummy_" + blender_bone.name, parent_id, 1, FQuat(), tail)
		psk_file.AddBone(pb)
		pbb = make_namedbonebinary("dummy_" + blender_bone.name, parent_id, 1, FQuat(), tail, 0)
		psa_file.StoreBone(pbb)
		final_parent_id = nbone
		nbone = nbone + 1
		#tail = tail-head
		
	my_id = nbone
	
	pb = make_vbone(blender_bone.name, final_parent_id, child_count, quat, set_position)
	psk_file.AddBone(pb)
	pbb = make_namedbonebinary(blender_bone.name, final_parent_id, child_count, quat, set_position, 1)
	psa_file.StoreBone(pbb)

	nbone = nbone + 1
	
	#RG - dump influences for this bone - use the data we collected in the mesh dump phase
	# to map our bones to vertex groups
	#print("///////////////////////")
	#print("set influence")
	if blender_bone.name in psk_file.VertexGroups:
		vertex_list = psk_file.VertexGroups[blender_bone.name]
		#print("vertex list:", len(vertex_list), " of >" ,blender_bone.name )
		for vertex_data in vertex_list:
			#print("set influence vettex")
			point_index = vertex_data[0]
			vertex_weight = vertex_data[1]
			influence = VRawBoneInfluence()
			influence.Weight = vertex_weight
			#influence.BoneIndex = my_id
			influence.BoneIndex = my_id
			influence.PointIndex = point_index
			#print(influence)
			#print ('Adding Bone Influence for [%s] = Point Index=%i, Weight=%f' % (blender_bone.name, point_index, vertex_weight))
			#print("adding influence")
			psk_file.AddInfluence(influence)
	
	#blender_bone.matrix_local
	#recursively dump child bones
	mainparent = parent_matrix
	#if len(blender_bone.children) > 0:
	for current_child_bone in blender_bone.children:
		parse_bone(current_child_bone, psk_file, psa_file, my_id, 0, mainparent, parent_root)

def parse_armature(blender_armature, psk_file, psa_file):
	print ("----- parsing armature -----")
	print ('blender_armature length: %i' % (len(blender_armature)))
	
	#magic 0 sized root bone for UT - this is where all armature dummy bones will attach
	#dont increment nbone here because we initialize it to 1 (hackity hackity hack)

	#count top level bones first. NOT EFFICIENT.
	child_count = 0
	for current_obj in blender_armature: 
		current_armature = current_obj.data
		bones = [x for x in current_armature.bones if not x.parent == None]
		child_count += len(bones)

	for current_obj in blender_armature:
		print ("Current Armature Name: " + current_obj.name)
		current_armature = current_obj.data
		#armature_id = make_armature_bone(current_obj, psk_file, psa_file)
		
		#we dont want children here - only the top level bones of the armature itself
		#we will recursively dump the child bones as we dump these bones
		"""
		bones = [x for x in current_armature.bones if not x.parent == None]
		#will ingore this part of the ocde
		"""
		for current_bone in current_armature.bones: #list the bone. #note this will list all the bones.
			if(current_bone.parent == None):
				parse_bone(current_bone, psk_file, psa_file, 0, 0, current_obj.matrix_local, None)
				break

# get blender objects by type		
def get_blender_objects(objects, intype):
	return [x for x in objects if x.type == intype]
			
#strips current extension (if any) from filename and replaces it with extension passed in
def make_filename_ext(filename, extension):
	new_filename = ''
	extension_index = filename.find('.')
	
	if extension_index == -1:
		new_filename = filename + extension
	else:
		new_filename = filename[0:extension_index] + extension
		
	return new_filename

# returns the quaternion Grassman product a*b
# this is the same as the rotation a(b(x)) 
# (ie. the same as B*A if A and B are matrices representing 
# the rotations described by quaternions a and b)
def grassman(a, b):	
	return mathutils.Quaternion(
		a.w*b.w - a.x*b.x - a.y*b.y - a.z*b.z,
		a.w*b.x + a.x*b.w + a.y*b.z - a.z*b.y,
		a.w*b.y - a.x*b.z + a.y*b.w + a.z*b.x,
		a.w*b.z + a.x*b.y - a.y*b.x + a.z*b.w)
		
def parse_animation(blender_scene, blender_armatures, psa_file):
	#to do list:
	#need to list the action sets
	#need to check if there animation
	#need to check if animation is has one frame then exit it
	print ('\n----- parsing animation -----')
	##print(dir(blender_scene))
	
	#print(dir(blender_armatures))
	
	render_data = blender_scene.render
	bHaveAction = True
	
	anim_rate = render_data.fps
	
	#print("dir:",dir(blender_scene))
	#print(dir(bpy.data.actions))
	#print("dir:",dir(bpy.data.actions[0]))
	
	
	print("==== Blender Settings ====")
	print ('Scene: %s Start Frame: %i, End Frame: %i' % (blender_scene.name, blender_scene.frame_start, blender_scene.frame_end))
	print ('Frames Per Sec: %i' % anim_rate)
	print ("Default FPS: 24" )
	
	cur_frame_index = 0
	
	#print(dir(bpy.data.actions))
	#print(dir(bpy.context.scene.set))
	
	#list of armature objects
	for arm in blender_armatures:
		#check if there animation data from armature or something
		#print(dir(arm.animation_data))
		#print("[["+dir(arm.animation_data.action))
		if not arm.animation_data:
			print("======================================")
			print("Check Animation Data: None")
			print("Armature has no animation, skipping...")
			print("======================================")
			break
			
		if not arm.animation_data.action:
			print("======================================")
			print("Check Action: None")
			print("Armature has no animation, skipping...")
			print("======================================")
			break
		act = arm.animation_data.action
		#print(dir(act))
		action_name = act.name
		
		if not len(act.fcurves):
			print("//===========================================================")
			print("// None bone pose set keys for this action set... skipping...")
			print("//===========================================================")
			bHaveAction = False
			
		#this deal with action export control
		if bHaveAction == True:
			print("")
			print("==== Action Set ====")
			print("Action Name:",action_name)
			#look for min and max frame that current set keys
			framemin, framemax = act.get_frame_range()
			#print("max frame:",framemax)
			start_frame = framemin
			end_frame = framemax
			scene_frames = range(start_frame, end_frame+1)
			frame_count = len(scene_frames)
			#===================================================
			anim = AnimInfoBinary()
			anim.Name = action_name
			anim.Group = "" #what is group?
			anim.NumRawFrames = frame_count
			anim.AnimRate = anim_rate
			anim.FirstRawFrame = cur_frame_index
			#===================================================
			count_previous_keys = len(psa_file.RawKeys.Data)
			print("Frame Key Set Count:",frame_count, "Total Frame:",frame_count)
			#print("init action bones...")
			unique_bone_indexes = {}
			# bone lookup table
			bones_lookup =  {}
		
			#build bone node for animation keys needed to be set
			for bone in arm.data.bones:
				bones_lookup[bone.name] = bone
			#print("bone name:",bone.name)
			frame_count = len(scene_frames)
			#print ('Frame Count: %i' % frame_count)
			pose_data = arm.pose
		
			#these must be ordered in the order the bones will show up in the PSA file!
			ordered_bones = {}
			ordered_bones = sorted([(psa_file.UseBone(x.name), x) for x in pose_data.bones], key=operator.itemgetter(0))
			
			#############################
			# ORDERED FRAME, BONE
			#for frame in scene_frames:
			
			for i in range(frame_count):
				frame = scene_frames[i]
				#LOUD
				#print ("==== outputting frame %i ===" % frame)
				
				if frame_count > i+1:
					next_frame = scene_frames[i+1]
					#print "This Frame: %i, Next Frame: %i" % (frame, next_frame)
				else:
					next_frame = -1
					#print "This Frame: %i, Next Frame: NONE" % frame
				
				#frame start from 1 as number one from blender
				blender_scene.set_frame(frame)
				
				cur_frame_index = cur_frame_index + 1
				for bone_data in ordered_bones:
					bone_index = bone_data[0]
					pose_bone = bone_data[1]
					#print("[=====POSE NAME:",pose_bone.name)
					
					#print("LENG >>.",len(bones_lookup))
					blender_bone = bones_lookup[pose_bone.name]
					
					#just need the total unique bones used, later for this AnimInfoBinary
					unique_bone_indexes[bone_index] = bone_index
					#LOUD
					#print ("-------------------", pose_bone.name)
					head = pose_bone.head
					
					posebonemat = mathutils.Matrix(pose_bone.matrix)
					parent_pose = pose_bone.parent
					if parent_pose != None:
						parentposemat = mathutils.Matrix(parent_pose.matrix)
						#blender 2.4X it been flip around with new 2.50 (mat1 * mat2) should now be (mat2 * mat1)
						posebonemat = parentposemat.invert() * posebonemat
					head = posebonemat.translation_part()
					quat = posebonemat.to_quat().normalize()
					vkey = VQuatAnimKey()
					vkey.Position.X = head.x
					vkey.Position.Y = head.y
					vkey.Position.Z = head.z
					
					if parent_pose != None:
						quat = make_fquat(quat)
					else:
						quat = make_fquat_default(quat)
					
					vkey.Orientation = quat
					#print("Head:",head)
					#print("Orientation",quat)
					
					#time from now till next frame = diff / framesPerSec
					if next_frame >= 0:
						diff = next_frame - frame
					else:
						diff = 1.0
					
					#print ("Diff = ", diff)
					vkey.Time = float(diff)/float(anim_rate)
					
					psa_file.AddRawKey(vkey)
					
			#done looping frames
			#done looping armatures
			#continue adding animInfoBinary counts here
		
			anim.TotalBones = len(unique_bone_indexes)
			print("Bones Count:",anim.TotalBones)
			anim.TrackTime = float(frame_count) / anim.AnimRate
			print("Time Track Frame:",anim.TrackTime)
			psa_file.AddAnimation(anim)
			print("==== Finish Action Build(s) ====")
		
exportmessage = "Export Finish"		
		
def fs_callback(filename, context, user_setting):
	#this deal with repeat export and the reset settings
	global bonedata, BBCount, nbone, exportmessage
	bonedata = []#clear array
	BBCount = 0
	nbone = 0
	
	start_time = time.clock()
	
	print ("========EXPORTING TO UNREAL SKELETAL MESH FORMATS========\r\n")
	print("Blender Version:", bpy.app.version_string)
	
	psk = PSKFile()
	psa = PSAFile()
	
	#sanity check - this should already have the extension, but just in case, we'll give it one if it doesn't
	psk_filename = make_filename_ext(filename, '.psk')
	
	#make the psa filename
	psa_filename = make_filename_ext(filename, '.psa')
	
	print ('PSK File: ' +  psk_filename)
	print ('PSA File: ' +  psa_filename)
	
	barmature = True
	bmesh = True
	blender_meshes = []
	blender_armature = []
	selectmesh = []
	selectarmature = []
	
	current_scene = context.scene
	cur_frame = current_scene.frame_current #store current frame before we start walking them during animation parse
	objects = current_scene.objects
	
	print("Checking object count...")
	for next_obj in objects:
		if next_obj.type == 'MESH':
			blender_meshes.append(next_obj)
			if (next_obj.select):
				#print("mesh object select")
				selectmesh.append(next_obj)
		if next_obj.type == 'ARMATURE':
			blender_armature.append(next_obj)
			if (next_obj.select):
				#print("armature object select")
				selectarmature.append(next_obj)
	
	print("Mesh Count:",len(blender_meshes)," Armature Count:",len(blender_armature))
	print("====================================")
	print("Checking Mesh Condtion(s):")
	if len(blender_meshes) == 1:
		print(" - One Mesh Scene")
	elif (len(blender_meshes) > 1) and (len(selectmesh) == 1):
		print(" - One Mesh [Select]")
	else:
		print(" - Too Many Meshes!")
		print(" - Select One Mesh Object!")
		bmesh = False
	print("====================================")
	print("Checking Armature Condtion(s):")
	if len(blender_armature) == 1:
		print(" - One Armature Scene")
	elif (len(blender_armature) > 1) and (len(selectarmature) == 1):
		print(" - One Armature [Select]")
	else:
		print(" - Too Armature Meshes!")
		print(" - Select One Armature Object Only!")
		barmature = False
	
	if 	(bmesh == False) or (barmature == False):
		exportmessage = "Export Fail! Check Log."
		print("=================================")
		print("= Export Fail!                  =")
		print("=================================")
	else:
		exportmessage = "Export Finish!"
		#need to build a temp bone index for mesh group vertex
		BoneIndexArmature(blender_armature)

		try:
			#######################
			# STEP 1: MESH DUMP
			# we build the vertexes, wedges, and faces in here, as well as a vertexgroup lookup table
			# for the armature parse
			print("//===============================")
			print("// STEP 1")
			print("//===============================")
			parse_meshes(blender_meshes, psk)
		except:
			context.scene.set_frame(cur_frame) #set frame back to original frame
			print ("Exception during Mesh Parse")
			raise
		
		try:
			#######################
			# STEP 2: ARMATURE DUMP
			# IMPORTANT: do this AFTER parsing meshes - we need to use the vertex group data from 
			# the mesh parse in here to generate bone influences
			print("//===============================")
			print("// STEP 2")
			print("//===============================")
			parse_armature(blender_armature, psk, psa) 
			
		except:
			context.scene.set_frame(cur_frame) #set frame back to original frame
			print ("Exception during Armature Parse")
			raise

		try:
			#######################
			# STEP 3: ANIMATION DUMP
			# IMPORTANT: do AFTER parsing bones - we need to do bone lookups in here during animation frames
			print("//===============================")
			print("// STEP 3")
			print("//===============================")
			parse_animation(current_scene, blender_armature, psa) 
			
		except:
			context.scene.set_frame(cur_frame) #set frame back to original frame
			print ("Exception during Animation Parse")
			raise

		# reset current frame
		
		context.scene.set_frame(cur_frame) #set frame back to original frame
		
		##########################
		# FILE WRITE
		print("//===========================================")
		print("// bExportPsk:",bpy.context.scene.unrealexportpsk," bExportPsa:",bpy.context.scene.unrealexportpsa)
		print("//===========================================")
		if bpy.context.scene.unrealexportpsk == True:
			print("Writing Skeleton Mesh Data...")
			#RG - dump psk file
			psk.PrintOut()
			file = open(psk_filename, "wb") 
			file.write(psk.dump())
			file.close() 
			print ("Successfully Exported File: " + psk_filename)
		if bpy.context.scene.unrealexportpsa == True:
			print("Writing Animaiton Data...")
			#RG - dump psa file
			if not psa.IsEmpty():
				psa.PrintOut()
				file = open(psa_filename, "wb") 
				file.write(psa.dump())
				file.close() 
				print ("Successfully Exported File: " + psa_filename)
			else:
				print ("No Animations (.psa file) to Export")

		print ('PSK/PSA Export Script finished in %.2f seconds' % (time.clock() - start_time))
		
		#MSG BOX EXPORT COMPLETE
		#...

		#DONE
		print ("PSK/PSA Export Complete")

def write_data(path, context, user_setting):
	print("//============================")
	print("// running psk/psa export...")
	print("//============================")
	fs_callback(path, context, user_setting)
	pass

from bpy.props import *

exporttypedata = []

# [index,text field,0] #or something like that
exporttypedata.append(("0","PSK","Export PSK"))
exporttypedata.append(("1","PSA","Export PSA"))
exporttypedata.append(("2","ALL","Export ALL"))

IntProperty= bpy.types.Scene.IntProperty

IntProperty(attr="unrealfpsrate", name="fps rate",
    description="Set the frame per second (fps) for unreal.",
    default=24,min=1,max=100)
	
bpy.types.Scene.EnumProperty( attr="unrealexport_settings",
    name="Export:",
    description="Select a export settings (psk/psa/all)...",
    items = exporttypedata, default = '0')
		
bpy.types.Scene.BoolProperty( attr="unrealtriangulatebool",
    name="Triangulate Mesh",
    description="Convert Quad to Tri Mesh Boolean...",
    default=False)
	
bpy.types.Scene.BoolProperty( attr="unrealactionexportall",
    name="All Actions",
    description="This let you export all actions from current armature.[Not Build Yet]",
    default=False)	
	
bpy.types.Scene.BoolProperty( attr="unrealexportpsk",
    name="bool export psa",
    description="bool for exporting this psk format",
    default=False)
	
bpy.types.Scene.BoolProperty( attr="unrealexportpsa",
    name="bool export psa",
    description="bool for exporting this psa format",
    default=False)

class ExportUDKAnimData(bpy.types.Operator):
	global exportmessage
	'''Export Skeleton Mesh / Animation Data file(s)'''
	bl_idname = "export.udk_anim_data" # this is important since its how bpy.ops.export.udk_anim_data is constructed
	bl_label = "Export PSK/PSA"
	__doc__ = "One mesh and one armature else select one mesh or armature to be exported."

	# List of operator properties, the attributes will be assigned
	# to the class instance from the operator settings before calling.

	filepath = StringProperty(name="File Path", description="Filepath used for exporting the PSA file", maxlen= 1024, default= "")
	use_setting = BoolProperty(name="No Options Yet", description="No Options Yet", default= True)
	pskexportbool = BoolProperty(name="Export PSK", description="Export Skeletal Mesh", default= True)
	psaexportbool = BoolProperty(name="Export PSA", description="Export Action Set (Animation Data)", default= True)
	actionexportall = BoolProperty(name="All Actions", description="This will export all the actions that matches the current armature.", default=False)

	def poll(self, context):
		return context.active_object != None

	def execute(self, context):
		#check if  skeleton mesh is needed to be exported
		if (self.properties.pskexportbool):
			bpy.context.scene.unrealexportpsk = True
		else:
			bpy.context.scene.unrealexportpsk = False
		#check if  animation data is needed to be exported
		if (self.properties.psaexportbool):
			bpy.context.scene.unrealexportpsa = True
		else:
			bpy.context.scene.unrealexportpsa = False
			
		write_data(self.properties.filepath, context, self.properties.use_setting)
		
		self.report({'WARNING', 'INFO'}, exportmessage)
		return {'FINISHED'}
		
	def invoke(self, context, event):
		wm = context.manager
		wm.add_fileselect(self)
		return {'RUNNING_MODAL'}
		
def menu_func(self, context):
	bpy.context.scene.unrealexportpsk = True
	bpy.context.scene.unrealexportpsa = True
	default_path = os.path.splitext(bpy.data.filepath)[0] + ".psk"
	self.layout.operator("export.udk_anim_data", text="Skeleton Mesh / Animation Data (.psk/.psa)").filepath = default_path
	

class VIEW3D_PT_unrealtools_objectmode(bpy.types.Panel):
	bl_space_type = "VIEW_3D"
	bl_region_type = "TOOLS"
	bl_label = "Unreal Tools"
	
	def poll(self, context):
		return context.active_object

	def draw(self, context):
		layout = self.layout
		#layout.label(text="Unreal Tools")
		rd = context.scene
		#drop box
		layout.prop(rd, "unrealexport_settings",expand=True)
		#layout.prop(rd, "unrealexport_settings")
		#button
		layout.operator("object.UnrealExport")
		#FPS #it use the real data from your scene
		layout.prop(rd.render, "fps")
		
		layout.prop(rd, "unrealactionexportall")
		#row = layout.row()
		#row.label(text="Action Set(s)(not build)")
		#for action in  bpy.data.actions:
			#print(dir( action))
			#print(action.get_frame_range())
			#row = layout.row()
			#row.prop(action, "name")
			
			#print(dir(action.groups[0]))
			#for g in action.groups:#those are bones
				#print("group...")
				#print(dir(g))
				#print("////////////")
				#print((g.name))
				#print("////////////")
			
			#row.label(text="Active:" + action.select)
		btrimesh = False
		
class OBJECT_OT_UnrealExport(bpy.types.Operator):
	global exportmessage
	bl_idname = "OBJECT_OT_UnrealExport"
	bl_label = "Unreal Export"
	__doc__ = "Select export setting for .psk/.psa or both."
	
	def invoke(self, context, event):
		#path = StringProperty(name="File Path", description="File path used for exporting the PSA file", maxlen= 1024, default= "")
		print("Init Export Script:")
		if(int(bpy.context.scene.unrealexport_settings) == 0):
			bpy.context.scene.unrealexportpsk = True
			bpy.context.scene.unrealexportpsa = False
			print("Exporting PSK...")
		if(int(bpy.context.scene.unrealexport_settings) == 1):
			bpy.context.scene.unrealexportpsk = False
			bpy.context.scene.unrealexportpsa = True
			print("Exporting PSA...")
		if(int(bpy.context.scene.unrealexport_settings) == 2):
			bpy.context.scene.unrealexportpsk = True
			bpy.context.scene.unrealexportpsa = True
			print("Exporting ALL...")

		default_path = os.path.splitext(bpy.data.filepath)[0] + ".psk"
		fs_callback(default_path, bpy.context, False)
		
		#self.report({'WARNING', 'INFO'}, exportmessage)
		self.report({'INFO'}, exportmessage)
		return{'FINISHED'}	
	
def register():
	global MENUPANELBOOL
	if MENUPANELBOOL:
		bpy.types.register(OBJECT_OT_UnrealExport)
		bpy.types.register(VIEW3D_PT_unrealtools_objectmode)
	bpy.types.register(ExportUDKAnimData)
	bpy.types.INFO_MT_file_export.append(menu_func)

def unregister():
	global MENUPANELBOOL
	if MENUPANELBOOL:
		bpy.types.unregister(OBJECT_OT_UnrealExport)
		bpy.types.unregister(VIEW3D_PT_unrealtools_objectmode)
	bpy.types.unregister(ExportUDKAnimData)
	bpy.types.INFO_MT_file_export.remove(menu_func)

if __name__ == "__main__":
    register()