#!BPY """ Name: 'Motion Capture (.bvh)...' Blender: 242 Group: 'Import' Tip: 'Import a (.bvh) motion capture file' """ __author__ = "Campbell Barton" __url__ = ("blender.org", "blenderartists.org") __version__ = "1.90 06/08/01" __bpydoc__ = """\ This script imports BVH motion capture data to Blender. as empties or armatures. """ # -------------------------------------------------------------------------- # BVH Import v2.0 by Campbell Barton (AKA Ideasman) # -------------------------------------------------------------------------- # ***** BEGIN GPL LICENSE BLOCK ***** # # This program is free software; you can redistribute it and/or # modify it under the terms of the GNU General Public License # as published by the Free Software Foundation; either version 2 # of the License, or (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program; if not, write to the Free Software Foundation, # Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. # # ***** END GPL LICENCE BLOCK ***** # -------------------------------------------------------------------------- import Blender import bpy import BPyMessages Vector= Blender.Mathutils.Vector Euler= Blender.Mathutils.Euler Matrix= Blender.Mathutils.Matrix RotationMatrix = Blender.Mathutils.RotationMatrix TranslationMatrix= Blender.Mathutils.TranslationMatrix DEG2RAD = 0.017453292519943295 class bvh_node_class(object): __slots__=(\ 'name',# bvh joint name 'parent',# bvh_node_class type or None for no parent 'children',# a list of children of this type. 'rest_head_world',# worldspace rest location for the head of this node 'rest_head_local',# localspace rest location for the head of this node 'rest_tail_world',# # worldspace rest location for the tail of this node 'rest_tail_local',# # worldspace rest location for the tail of this node 'channels',# list of 6 ints, -1 for an unused channel, otherwise an index for the BVH motion data lines, lock triple then rot triple 'rot_order',# a triple of indicies as to the order rotation is applied. [0,1,2] is x/y/z - [None, None, None] if no rotation. 'anim_data',# a list one tuple's one for each frame. (locx, locy, locz, rotx, roty, rotz) 'has_loc',# Conveinience function, bool, same as (channels[0]!=-1 or channels[1]!=-1 channels[2]!=-1) 'has_rot',# Conveinience function, bool, same as (channels[3]!=-1 or channels[4]!=-1 channels[5]!=-1) 'temp')# use this for whatever you want def __init__(self, name, rest_head_world, rest_head_local, parent, channels, rot_order): self.name= name self.rest_head_world= rest_head_world self.rest_head_local= rest_head_local self.rest_tail_world= None self.rest_tail_local= None self.parent= parent self.channels= channels self.rot_order= rot_order # convenience functions self.has_loc= channels[0] != -1 or channels[1] != -1 or channels[2] != -1 self.has_rot= channels[3] != -1 or channels[4] != -1 or channels[5] != -1 self.children= [] # list of 6 length tuples: (lx,ly,lz, rx,ry,rz) # even if the channels arnt used they will just be zero # self.anim_data= [(0,0,0,0,0,0)] def __repr__(self): return 'BVH name:"%s", rest_loc:(%.3f,%.3f,%.3f), rest_tail:(%.3f,%.3f,%.3f)' %\ (self.name,\ self.rest_head_world.x, self.rest_head_world.y, self.rest_head_world.z,\ self.rest_head_world.x, self.rest_head_world.y, self.rest_head_world.z) # Change the order rotation is applied. MATRIX_IDENTITY_3x3 = Matrix([1,0,0],[0,1,0],[0,0,1]) MATRIX_IDENTITY_4x4 = Matrix([1,0,0,0],[0,1,0,0],[0,0,1,0],[0,0,0,1]) def eulerRotate(x,y,z, rot_order): # Clamp all values between 0 and 360, values outside this raise an error. mats=[RotationMatrix(x%360,3,'x'), RotationMatrix(y%360,3,'y'), RotationMatrix(z%360,3,'z')] # print rot_order # Standard BVH multiplication order, apply the rotation in the order Z,X,Y return (mats[rot_order[2]]*(mats[rot_order[1]]* (mats[rot_order[0]]* MATRIX_IDENTITY_3x3))).toEuler() def read_bvh(file_path, GLOBAL_SCALE=1.0): # File loading stuff # Open the file for importing file = open(file_path, 'rU') # Seperate into a list of lists, each line a list of words. file_lines = file.readlines() # Non standard carrage returns? if len(file_lines) == 1: file_lines = file_lines[0].split('\r') # Split by whitespace. file_lines =[ll for ll in [ l.split() for l in file_lines] if ll] # Create Hirachy as empties if file_lines[0][0].lower() == 'hierarchy': #print 'Importing the BVH Hierarchy for:', file_path pass else: raise 'ERROR: This is not a BVH file' bvh_nodes= {None:None} bvh_nodes_serial = [None] channelIndex = -1 lineIdx = 0 # An index for the file. while lineIdx < len(file_lines) -1: #... if file_lines[lineIdx][0].lower() == 'root' or file_lines[lineIdx][0].lower() == 'joint': # Join spaces into 1 word with underscores joining it. if len(file_lines[lineIdx]) > 2: file_lines[lineIdx][1] = '_'.join(file_lines[lineIdx][1:]) file_lines[lineIdx] = file_lines[lineIdx][:2] # MAY NEED TO SUPPORT MULTIPLE ROOT's HERE!!!, Still unsure weather multiple roots are possible.?? # Make sure the names are unique- Object names will match joint names exactly and both will be unique. name = file_lines[lineIdx][1] #print '%snode: %s, parent: %s' % (len(bvh_nodes_serial) * ' ', name, bvh_nodes_serial[-1]) lineIdx += 2 # Incriment to the next line (Offset) rest_head_local = Vector( GLOBAL_SCALE*float(file_lines[lineIdx][1]), GLOBAL_SCALE*float(file_lines[lineIdx][2]), GLOBAL_SCALE*float(file_lines[lineIdx][3]) ) lineIdx += 1 # Incriment to the next line (Channels) # newChannel[Xposition, Yposition, Zposition, Xrotation, Yrotation, Zrotation] # newChannel references indecies to the motiondata, # if not assigned then -1 refers to the last value that will be added on loading at a value of zero, this is appended # We'll add a zero value onto the end of the MotionDATA so this is always refers to a value. my_channel = [-1, -1, -1, -1, -1, -1] my_rot_order= [None, None, None] rot_count= 0 for channel in file_lines[lineIdx][2:]: channel= channel.lower() channelIndex += 1 # So the index points to the right channel if channel == 'xposition': my_channel[0] = channelIndex elif channel == 'yposition': my_channel[1] = channelIndex elif channel == 'zposition': my_channel[2] = channelIndex elif channel == 'xrotation': my_channel[3] = channelIndex my_rot_order[rot_count]= 0 rot_count+=1 elif channel == 'yrotation': my_channel[4] = channelIndex my_rot_order[rot_count]= 1 rot_count+=1 elif channel == 'zrotation': my_channel[5] = channelIndex my_rot_order[rot_count]= 2 rot_count+=1 channels = file_lines[lineIdx][2:] my_parent= bvh_nodes_serial[-1] # account for none # Apply the parents offset accumletivly if my_parent==None: rest_head_world= Vector(rest_head_local) else: rest_head_world= my_parent.rest_head_world + rest_head_local bvh_node= bvh_nodes[name]= bvh_node_class(name, rest_head_world, rest_head_local, my_parent, my_channel, my_rot_order) # If we have another child then we can call ourselves a parent, else bvh_nodes_serial.append(bvh_node) # Account for an end node if file_lines[lineIdx][0].lower() == 'end' and file_lines[lineIdx][1].lower() == 'site': # There is somtimes a name after 'End Site' but we will ignore it. lineIdx += 2 # Incriment to the next line (Offset) rest_tail = Vector( GLOBAL_SCALE*float(file_lines[lineIdx][1]), GLOBAL_SCALE*float(file_lines[lineIdx][2]), GLOBAL_SCALE*float(file_lines[lineIdx][3]) ) bvh_nodes_serial[-1].rest_tail_world= bvh_nodes_serial[-1].rest_head_world + rest_tail bvh_nodes_serial[-1].rest_tail_local= rest_tail # Just so we can remove the Parents in a uniform way- End end never has kids # so this is a placeholder bvh_nodes_serial.append(None) if len(file_lines[lineIdx]) == 1 and file_lines[lineIdx][0] == '}': # == ['}'] bvh_nodes_serial.pop() # Remove the last item if len(file_lines[lineIdx]) == 1 and file_lines[lineIdx][0].lower() == 'motion': #print '\nImporting motion data' lineIdx += 3 # Set the cursor to the first frame break lineIdx += 1 # Remove the None value used for easy parent reference del bvh_nodes[None] # Dont use anymore del bvh_nodes_serial bvh_nodes_list= bvh_nodes.values() while lineIdx < len(file_lines): line= file_lines[lineIdx] for bvh_node in bvh_nodes_list: #for bvh_node in bvh_nodes_serial: lx= ly= lz= rx= ry= rz= 0.0 channels= bvh_node.channels anim_data= bvh_node.anim_data if channels[0] != -1: lx= GLOBAL_SCALE * float( line[channels[0]] ) if channels[1] != -1: ly= GLOBAL_SCALE * float( line[channels[1]] ) if channels[2] != -1: lz= GLOBAL_SCALE * float( line[channels[2]] ) if channels[3] != -1 or channels[4] != -1 or channels[5] != -1: rx, ry, rz = eulerRotate(float( line[channels[3]] ), float( line[channels[4]] ), float( line[channels[5]] ), bvh_node.rot_order) #x,y,z = x/10.0, y/10.0, z/10.0 # For IPO's 36 is 360d # Make interpolation not cross between 180d, thjis fixes sub frame interpolation and time scaling. # Will go from (355d to 365d) rather then to (355d to 5d) - inbetween these 2 there will now be a correct interpolation. while anim_data[-1][3] - rx > 180: rx+=360 while anim_data[-1][3] - rx < -180: rx-=360 while anim_data[-1][4] - ry > 180: ry+=360 while anim_data[-1][4] - ry < -180: ry-=360 while anim_data[-1][5] - rz > 180: rz+=360 while anim_data[-1][5] - rz < -180: rz-=360 # Done importing motion data # anim_data.append( (lx, ly, lz, rx, ry, rz) ) lineIdx += 1 # Assign children for bvh_node in bvh_nodes.itervalues(): bvh_node_parent= bvh_node.parent if bvh_node_parent: bvh_node_parent.children.append(bvh_node) # Now set the tip of each bvh_node for bvh_node in bvh_nodes.itervalues(): if not bvh_node.rest_tail_world: if len(bvh_node.children)==1: bvh_node.rest_tail_world= Vector(bvh_node.children[0].rest_head_world) bvh_node.rest_tail_local= Vector(bvh_node.children[0].rest_head_local) else: if not bvh_node.children: raise 'error, bvh node has no end and no children. bad file' # Removed temp for now rest_tail_world= Vector(0,0,0) rest_tail_local= Vector(0,0,0) for bvh_node_child in bvh_node.children: rest_tail_world += bvh_node_child.rest_head_world rest_tail_local += bvh_node_child.rest_head_local bvh_node.rest_tail_world= rest_tail_world * (1.0/len(bvh_node.children)) bvh_node.rest_tail_local= rest_tail_local * (1.0/len(bvh_node.children)) # Make sure tail isnt the same location as the head. if (bvh_node.rest_tail_local-bvh_node.rest_head_local).length <= 0.001*GLOBAL_SCALE: bvh_node.rest_tail_local.y= bvh_node.rest_tail_local.y + GLOBAL_SCALE/10 bvh_node.rest_tail_world.y= bvh_node.rest_tail_world.y + GLOBAL_SCALE/10 return bvh_nodes def bvh_node_dict2objects(bvh_nodes, IMPORT_START_FRAME= 1, IMPORT_LOOP= False): if IMPORT_START_FRAME<1: IMPORT_START_FRAME= 1 scn= bpy.data.scenes.active scn.objects.selected = [] objects= [] def add_ob(name): ob = scn.objects.new('Empty') objects.append(ob) return ob # Add objects for name, bvh_node in bvh_nodes.iteritems(): bvh_node.temp= add_ob(name) # Parent the objects for bvh_node in bvh_nodes.itervalues(): bvh_node.temp.makeParent([ bvh_node_child.temp for bvh_node_child in bvh_node.children ], 1, 0) # ojbs, noninverse, 1 = not fast. # Offset for bvh_node in bvh_nodes.itervalues(): # Make relative to parents offset bvh_node.temp.loc= bvh_node.rest_head_local # Add tail objects for name, bvh_node in bvh_nodes.iteritems(): if not bvh_node.children: ob_end= add_ob(name + '_end') bvh_node.temp.makeParent([ob_end], 1, 0) # ojbs, noninverse, 1 = not fast. ob_end.loc= bvh_node.rest_tail_local # Animate the data, the last used bvh_node will do since they all have the same number of frames for current_frame in xrange(len(bvh_node.anim_data)): Blender.Set('curframe', current_frame+IMPORT_START_FRAME) for bvh_node in bvh_nodes.itervalues(): lx,ly,lz,rx,ry,rz= bvh_node.anim_data[current_frame] rest_head_local= bvh_node.rest_head_local bvh_node.temp.loc= rest_head_local.x+lx, rest_head_local.y+ly, rest_head_local.z+lz bvh_node.temp.rot= rx*DEG2RAD,ry*DEG2RAD,rz*DEG2RAD bvh_node.temp.insertIpoKey(Blender.Object.IpoKeyTypes.LOCROT) scn.update(1) return objects def bvh_node_dict2armature(bvh_nodes, IMPORT_START_FRAME= 1, IMPORT_LOOP= False): if IMPORT_START_FRAME<1: IMPORT_START_FRAME= 1 # Add the new armature, scn = bpy.data.scenes.active scn.objects.selected = [] arm_data= bpy.data.armatures.new() arm_ob = scn.objects.new(arm_data) scn.objects.context = [arm_ob] scn.objects.active = arm_ob # Put us into editmode arm_data.makeEditable() # Get the average bone length for zero length bones, we may not use this. average_bone_length= 0.0 nonzero_count= 0 for bvh_node in bvh_nodes.itervalues(): l= (bvh_node.rest_head_local-bvh_node.rest_tail_local).length if l: average_bone_length+= l nonzero_count+=1 # Very rare cases all bones couldbe zero length??? if not average_bone_length: average_bone_length = 0.1 else: # Normal operation average_bone_length = average_bone_length/nonzero_count ZERO_AREA_BONES= [] for name, bvh_node in bvh_nodes.iteritems(): # New editbone bone= bvh_node.temp= Blender.Armature.Editbone() bone.name= name arm_data.bones[name]= bone bone.head= bvh_node.rest_head_world bone.tail= bvh_node.rest_tail_world # ZERO AREA BONES. if (bone.head-bone.tail).length < 0.001: if bvh_node.parent: ofs= bvh_node.parent.rest_head_local- bvh_node.parent.rest_tail_local if ofs.length: # is our parent zero length also?? unlikely bone.tail= bone.tail+ofs else: bone.tail.y= bone.tail.y+average_bone_length else: bone.tail.y= bone.tail.y+average_bone_length ZERO_AREA_BONES.append(bone.name) for bvh_node in bvh_nodes.itervalues(): if bvh_node.parent: # bvh_node.temp is the Editbone # Set the bone parent bvh_node.temp.parent= bvh_node.parent.temp # Set the connection state if not bvh_node.has_loc and\ bvh_node.parent and\ bvh_node.parent.temp.name not in ZERO_AREA_BONES and\ bvh_node.parent.rest_tail_local == bvh_node.rest_head_local: bvh_node.temp.options= [Blender.Armature.CONNECTED] # Replace the editbone with the editbone name, # to avoid memory errors accessing the editbone outside editmode for bvh_node in bvh_nodes.itervalues(): bvh_node.temp= bvh_node.temp.name arm_data.update() # Now Apply the animation to the armature # Get armature animation data pose= arm_ob.getPose() pose_bones= pose.bones action = Blender.Armature.NLA.NewAction("Action") action.setActive(arm_ob) #xformConstants= [ Blender.Object.Pose.LOC, Blender.Object.Pose.ROT ] # Replace the bvh_node.temp (currently an editbone) # With a tuple (pose_bone, armature_bone, bone_rest_matrix, bone_rest_matrix_inv) for bvh_node in bvh_nodes.itervalues(): bone_name= bvh_node.temp # may not be the same name as the bvh_node, could have been shortened. pose_bone= pose_bones[bone_name] rest_bone= arm_data.bones[bone_name] bone_rest_matrix = rest_bone.matrix['ARMATURESPACE'].rotationPart() bone_rest_matrix_inv= Matrix(bone_rest_matrix) bone_rest_matrix_inv.invert() bone_rest_matrix_inv.resize4x4() bone_rest_matrix.resize4x4() bvh_node.temp= (pose_bone, bone, bone_rest_matrix, bone_rest_matrix_inv) # Make a dict for fast access without rebuilding a list all the time. xformConstants_dict={ (True,True): [Blender.Object.Pose.LOC, Blender.Object.Pose.ROT],\ (False,True): [Blender.Object.Pose.ROT],\ (True,False): [Blender.Object.Pose.LOC],\ (False,False): [],\ } # KEYFRAME METHOD, SLOW, USE IPOS DIRECT # Animate the data, the last used bvh_node will do since they all have the same number of frames for current_frame in xrange(len(bvh_node.anim_data)-1): # skip the first frame (rest frame) # print current_frame #if current_frame==40: # debugging # break # Dont neet to set the current frame for bvh_node in bvh_nodes.itervalues(): pose_bone, bone, bone_rest_matrix, bone_rest_matrix_inv= bvh_node.temp lx,ly,lz,rx,ry,rz= bvh_node.anim_data[current_frame+1] if bvh_node.has_rot: # Set the rotation, not so simple bone_rotation_matrix= Euler(rx,ry,rz).toMatrix() bone_rotation_matrix.resize4x4() pose_bone.quat= (bone_rest_matrix * bone_rotation_matrix * bone_rest_matrix_inv).toQuat() if bvh_node.has_loc: # Set the Location, simple too pose_bone.loc= (\ TranslationMatrix(Vector(lx, ly, lz) - bvh_node.rest_head_local ) *\ bone_rest_matrix_inv).translationPart() # WHY * 10? - just how pose works # Get the transform xformConstants= xformConstants_dict[bvh_node.has_loc, bvh_node.has_rot] if xformConstants: # Insert the keyframe from the loc/quat pose_bone.insertKey(arm_ob, current_frame+IMPORT_START_FRAME, xformConstants, True ) # First time, set the IPO's to linear if current_frame==0: for ipo in action.getAllChannelIpos().itervalues(): if ipo: for cur in ipo: cur.interpolation = Blender.IpoCurve.InterpTypes.LINEAR if IMPORT_LOOP: cur.extend = Blender.IpoCurve.ExtendTypes.CYCLIC # END KEYFRAME METHOD """ # IPO KEYFRAME SETTING # Add in the IPOs by adding keyframes, AFAIK theres no way to add IPOs to an action so I do this :/ for bvh_node in bvh_nodes.itervalues(): pose_bone, bone, bone_rest_matrix, bone_rest_matrix_inv= bvh_node.temp # Get the transform xformConstants= xformConstants_dict[bvh_node.has_loc, bvh_node.has_rot] if xformConstants: pose_bone.loc[:]= 0,0,0 pose_bone.quat[:]= 0,0,1,0 # Insert the keyframe from the loc/quat pose_bone.insertKey(arm_ob, IMPORT_START_FRAME, xformConstants) action_ipos= action.getAllChannelIpos() for bvh_node in bvh_nodes.itervalues(): has_loc= bvh_node.has_loc has_rot= bvh_node.has_rot if not has_rot and not has_loc: # No animation data continue ipo= action_ipos[bvh_node.temp[0].name] # posebones name as key if has_loc: curve_xloc= ipo[Blender.Ipo.PO_LOCX] curve_yloc= ipo[Blender.Ipo.PO_LOCY] curve_zloc= ipo[Blender.Ipo.PO_LOCZ] curve_xloc.interpolation= \ curve_yloc.interpolation= \ curve_zloc.interpolation= \ Blender.IpoCurve.InterpTypes.LINEAR if has_rot: curve_wquat= ipo[Blender.Ipo.PO_QUATW] curve_xquat= ipo[Blender.Ipo.PO_QUATX] curve_yquat= ipo[Blender.Ipo.PO_QUATY] curve_zquat= ipo[Blender.Ipo.PO_QUATZ] curve_wquat.interpolation= \ curve_xquat.interpolation= \ curve_yquat.interpolation= \ curve_zquat.interpolation= \ Blender.IpoCurve.InterpTypes.LINEAR # Get the bone pose_bone, bone, bone_rest_matrix, bone_rest_matrix_inv= bvh_node.temp def pose_rot(anim_data): bone_rotation_matrix= Euler(anim_data[3], anim_data[4], anim_data[5]).toMatrix() bone_rotation_matrix.resize4x4() return tuple((bone_rest_matrix * bone_rotation_matrix * bone_rest_matrix_inv).toQuat()) # qw,qx,qy,qz def pose_loc(anim_data): return tuple((TranslationMatrix(Vector(anim_data[0], anim_data[1], anim_data[2])) * bone_rest_matrix_inv).translationPart()) last_frame= len(bvh_node.anim_data)+IMPORT_START_FRAME-1 if has_loc: pose_locations= [pose_loc(anim_key) for anim_key in bvh_node.anim_data] # Add the start at the end, we know the start is just 0,0,0 anyway curve_xloc.append((last_frame, pose_locations[-1][0])) curve_yloc.append((last_frame, pose_locations[-1][1])) curve_zloc.append((last_frame, pose_locations[-1][2])) if len(pose_locations) > 1: ox,oy,oz= pose_locations[0] x,y,z= pose_locations[1] for i in xrange(1, len(pose_locations)-1): # from second frame to second last frame nx,ny,nz= pose_locations[i+1] xset= yset= zset= True # we set all these by default if abs((ox+nx)/2 - x) < 0.00001: xset= False if abs((oy+ny)/2 - y) < 0.00001: yset= False if abs((oz+nz)/2 - z) < 0.00001: zset= False if xset: curve_xloc.append((i+IMPORT_START_FRAME, x)) if yset: curve_yloc.append((i+IMPORT_START_FRAME, y)) if zset: curve_zloc.append((i+IMPORT_START_FRAME, z)) # Set the old and use the new ox,oy,oz= x,y,z x,y,z= nx,ny,nz if has_rot: pose_rotations= [pose_rot(anim_key) for anim_key in bvh_node.anim_data] # Add the start at the end, we know the start is just 0,0,0 anyway curve_wquat.append((last_frame, pose_rotations[-1][0])) curve_xquat.append((last_frame, pose_rotations[-1][1])) curve_yquat.append((last_frame, pose_rotations[-1][2])) curve_zquat.append((last_frame, pose_rotations[-1][3])) if len(pose_rotations) > 1: ow,ox,oy,oz= pose_rotations[0] w,x,y,z= pose_rotations[1] for i in xrange(1, len(pose_rotations)-1): # from second frame to second last frame nw, nx,ny,nz= pose_rotations[i+1] wset= xset= yset= zset= True # we set all these by default if abs((ow+nw)/2 - w) < 0.00001: wset= False if abs((ox+nx)/2 - x) < 0.00001: xset= False if abs((oy+ny)/2 - y) < 0.00001: yset= False if abs((oz+nz)/2 - z) < 0.00001: zset= False if wset: curve_wquat.append((i+IMPORT_START_FRAME, w)) if xset: curve_xquat.append((i+IMPORT_START_FRAME, x)) if yset: curve_yquat.append((i+IMPORT_START_FRAME, y)) if zset: curve_zquat.append((i+IMPORT_START_FRAME, z)) # Set the old and use the new ow,ox,oy,oz= w,x,y,z w,x,y,z= nw,nx,ny,nz # IPO KEYFRAME SETTING """ pose.update() return arm_ob #=============# # TESTING # #=============# #('/metavr/mocap/bvh/boxer.bvh') #('/d/staggered_walk.bvh') #('/metavr/mocap/bvh/dg-306-g.bvh') # Incompleate EOF #('/metavr/mocap/bvh/wa8lk.bvh') # duplicate joint names, \r line endings. #('/metavr/mocap/bvh/walk4.bvh') # 0 channels ''' import os DIR = '/metavr/mocap/bvh/' for f in ('/d/staggered_walk.bvh',): #for f in os.listdir(DIR)[5:6]: #for f in os.listdir(DIR): if f.endswith('.bvh'): s = Blender.Scene.New(f) s.makeCurrent() #file= DIR + f file= f print f bvh_nodes= read_bvh(file, 1.0) bvh_node_dict2armature(bvh_nodes, 1) ''' def load_bvh_ui(file, PREF_UI= True): if BPyMessages.Error_NoFile(file): return Draw= Blender.Draw IMPORT_SCALE = Draw.Create(0.1) IMPORT_START_FRAME = Draw.Create(1) IMPORT_AS_ARMATURE = Draw.Create(1) IMPORT_AS_EMPTIES = Draw.Create(0) IMPORT_LOOP = Draw.Create(0) # Get USER Options if PREF_UI: pup_block = [\ ('As Armature', IMPORT_AS_ARMATURE, 'Imports the BVH as an armature'),\ ('As Empties', IMPORT_AS_EMPTIES, 'Imports the BVH as empties'),\ ('Scale: ', IMPORT_SCALE, 0.001, 100.0, 'Scale the BVH, Use 0.01 when 1.0 is 1 metre'),\ ('Start Frame: ', IMPORT_START_FRAME, 1, 30000, 'Frame to start BVH motion'),\ ('Loop Animation', IMPORT_LOOP, 'Enable cyclic IPOs'),\ ] if not Draw.PupBlock('BVH Import...', pup_block): return print 'Attempting import BVH', file IMPORT_SCALE = IMPORT_SCALE.val IMPORT_START_FRAME = IMPORT_START_FRAME.val IMPORT_AS_ARMATURE = IMPORT_AS_ARMATURE.val IMPORT_AS_EMPTIES = IMPORT_AS_EMPTIES.val IMPORT_LOOP = IMPORT_LOOP.val if not IMPORT_AS_ARMATURE and not IMPORT_AS_EMPTIES: Blender.Draw.PupMenu('No import option selected') return Blender.Window.WaitCursor(1) # Get the BVH data and act on it. t1= Blender.sys.time() print '\tparsing bvh...', bvh_nodes= read_bvh(file, IMPORT_SCALE) print '%.4f' % (Blender.sys.time()-t1) t1= Blender.sys.time() print '\timporting to blender...', if IMPORT_AS_ARMATURE: bvh_node_dict2armature(bvh_nodes, IMPORT_START_FRAME, IMPORT_LOOP) if IMPORT_AS_EMPTIES: bvh_node_dict2objects(bvh_nodes, IMPORT_START_FRAME, IMPORT_LOOP) print 'Done in %.4f\n' % (Blender.sys.time()-t1) Blender.Window.WaitCursor(0) def main(): Blender.Window.FileSelector(load_bvh_ui, 'Import BVH', '*.bvh') if __name__ == '__main__': #def foo(): main() ''' scn = bpy.data.scenes.active for ob in list(scn.objects): if ob.name!='arm__': scn.objects.unlink(ob) load_bvh_ui('/test.bvh', False) '''