blender/release/scripts/lightwave_export.py
Willian Padovani Germano ad579abf00 Scripts:
Final (?) updates for 2.40 :) :

- Bob Holcomb sent a better version of his 3ds importer
- Added doc info to bvh2arm: links to doc and mocap tute from author
Jean-Baptiste Perin
- Alessandro Pirovano improved the Lightwave importer.
- Mikael Lagre updated the collada scripts (fixed a bug with camera
lens value)
- Adam Saltsman improved the wings importer (ongoing work with
his pal Toastie).
- Anthony D'Agostino GPL'd his scripts (used Blender's BAL
license previously)

Thanks to all script authors for their work, interest and kindness.
Again, Tom (LetterRip) has played an important part in this, thanks and
welcome :).
2005-12-19 17:21:55 +00:00

644 lines
22 KiB
Python

#!BPY
"""
Name: 'LightWave (.lwo)...'
Blender: 232
Group: 'Export'
Tooltip: 'Export selected meshes to LightWave File Format (.lwo)'
"""
__author__ = "Anthony D'Agostino (Scorpius)"
__url__ = ("blender", "elysiun",
"Author's homepage, http://www.redrival.com/scorpius")
__version__ = "Part of IOSuite 0.5"
__bpydoc__ = """\
This script exports meshes to LightWave file format.
LightWave is a full-featured commercial modeling and rendering
application. The lwo file format is composed of 'chunks,' is well
defined, and easy to read and write. It is similar in structure to the
trueSpace cob format.
Usage:<br>
Select meshes to be exported and run this script from "File->Export" menu.
Supported:<br>
UV Coordinates, Meshes, Materials, Material Indices, Specular
Highlights, and Vertex Colors. For added functionality, each object is
placed on its own layer. Someone added the CLIP chunk and imagename support.
Missing:<br>
Not too much, I hope! :).
Known issues:<br>
Empty objects crash has been fixed.
Notes:<br>
For compatibility reasons, it also reads lwo files in the old LW
v5.5 format.
"""
# $Id$
#
# +---------------------------------------------------------+
# | Copyright (c) 2002 Anthony D'Agostino |
# | http://www.redrival.com/scorpius |
# | scorpius@netzero.com |
# | April 21, 2002 |
# | Read and write LightWave Object File Format (*.lwo) |
# +---------------------------------------------------------+
# ***** 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, meshtools
import struct, chunk, os, cStringIO, time, operator
# ==============================
# === Write LightWave Format ===
# ==============================
def write(filename):
start = time.clock()
file = open(filename, "wb")
objects = Blender.Object.GetSelected()
objects.sort(lambda a,b: cmp(a.name, b.name))
if not objects:
meshtools.print_boxed("No mesh objects are selected.")
return
if len(objects) > 20 and meshtools.show_progress:
meshtools.show_progress = 0
text = generate_text()
desc = generate_desc()
icon = "" #generate_icon()
material_names = get_used_material_names(objects)
tags = generate_tags(material_names)
surfs = generate_surfs(material_names)
chunks = [text, desc, icon, tags]
meshdata = cStringIO.StringIO()
layer_index = 0
for object in objects:
objname = object.name
meshname = object.data.name
mesh = Blender.NMesh.GetRaw(meshname)
#mesh = Blender.NMesh.GetRawFromObject(meshname) # for SubSurf
obj = Blender.Object.Get(objname)
if not mesh: continue
layr = generate_layr(objname, layer_index)
pnts = generate_pnts(mesh, obj.matrix)
bbox = generate_bbox(mesh)
pols = generate_pols(mesh)
ptag = generate_ptag(mesh, material_names)
clip = generate_clip(mesh, material_names)
if mesh.hasFaceUV():
vmad_uv = generate_vmad_uv(mesh) # per face
if meshtools.has_vertex_colors(mesh):
if meshtools.average_vcols:
vmap_vc = generate_vmap_vc(mesh) # per vert
else:
vmad_vc = generate_vmad_vc(mesh) # per face
write_chunk(meshdata, "LAYR", layr); chunks.append(layr)
write_chunk(meshdata, "PNTS", pnts); chunks.append(pnts)
write_chunk(meshdata, "BBOX", bbox); chunks.append(bbox)
write_chunk(meshdata, "POLS", pols); chunks.append(pols)
write_chunk(meshdata, "PTAG", ptag); chunks.append(ptag)
if meshtools.has_vertex_colors(mesh):
if meshtools.average_vcols:
write_chunk(meshdata, "VMAP", vmap_vc)
chunks.append(vmap_vc)
else:
write_chunk(meshdata, "VMAD", vmad_vc)
chunks.append(vmad_vc)
if mesh.hasFaceUV():
write_chunk(meshdata, "VMAD", vmad_uv)
chunks.append(vmad_uv)
write_chunk(meshdata, "CLIP", clip)
chunks.append(clip)
layer_index += 1
for surf in surfs:
chunks.append(surf)
write_header(file, chunks)
write_chunk(file, "ICON", icon)
write_chunk(file, "TEXT", text)
write_chunk(file, "DESC", desc)
write_chunk(file, "TAGS", tags)
file.write(meshdata.getvalue()); meshdata.close()
for surf in surfs:
write_chunk(file, "SURF", surf)
write_chunk(file, "DATE", "August 19, 2005")
Blender.Window.DrawProgressBar(1.0, "") # clear progressbar
file.close()
print '\a\r',
end = time.clock()
seconds = " in %.2f %s" % (end-start, "seconds")
message = "Successfully exported " + os.path.basename(filename) + seconds
meshtools.print_boxed(message)
# =======================================
# === Generate Null-Terminated String ===
# =======================================
def generate_nstring(string):
if len(string)%2 == 0: # even
string += "\0\0"
else: # odd
string += "\0"
return string
# ===============================
# === Get Used Material Names ===
# ===============================
def get_used_material_names(objects):
matnames = {}
for object in objects:
objname = object.name
meshname = object.data.name
mesh = Blender.NMesh.GetRaw(meshname)
if not mesh: continue
if (not mesh.materials) and (meshtools.has_vertex_colors(mesh)):
# vcols only
if meshtools.average_vcols:
matnames["\251 Per-Vert Vertex Colors"] = None
else:
matnames["\251 Per-Face Vertex Colors"] = None
elif (mesh.materials) and (not meshtools.has_vertex_colors(mesh)):
# materials only
for material in mesh.materials:
matnames[material.name] = None
elif (not mesh.materials) and (not meshtools.has_vertex_colors(mesh)):
# neither
matnames["\251 Blender Default"] = None
else:
# both
for material in mesh.materials:
matnames[material.name] = None
return matnames
# =========================================
# === Generate Tag Strings (TAGS Chunk) ===
# =========================================
def generate_tags(material_names):
material_names = map(generate_nstring, material_names.keys())
tags_data = reduce(operator.add, material_names)
return tags_data
# ========================
# === Generate Surface ===
# ========================
def generate_surface(name, mesh):
if name.find("\251 Per-") == 0:
return generate_vcol_surf(mesh)
elif name == "\251 Blender Default":
return generate_default_surf()
else:
return generate_surf(name)
# ======================
# === Generate Surfs ===
# ======================
def generate_surfs(material_names):
keys = material_names.keys()
values = material_names.values()
surfaces = map(generate_surface, keys, values)
return surfaces
# ===================================
# === Generate Layer (LAYR Chunk) ===
# ===================================
def generate_layr(name, idx):
data = cStringIO.StringIO()
data.write(struct.pack(">h", idx)) # layer number
data.write(struct.pack(">h", 0)) # flags
data.write(struct.pack(">fff", 0, 0, 0)) # pivot
data.write(generate_nstring(name)) # name
return data.getvalue()
# ===================================
# === Generate Verts (PNTS Chunk) ===
# ===================================
def generate_pnts(mesh, matrix):
data = cStringIO.StringIO()
for i in range(len(mesh.verts)):
if not i%100 and meshtools.show_progress:
Blender.Window.DrawProgressBar(float(i)/len(mesh.verts), "Writing Verts")
x, y, z = meshtools.apply_transform(mesh.verts[i].co, matrix)
data.write(struct.pack(">fff", x, z, y))
return data.getvalue()
# ==========================================
# === Generate Bounding Box (BBOX Chunk) ===
# ==========================================
def generate_bbox(mesh):
data = cStringIO.StringIO()
# need to transform verts here
nv = map(getattr, mesh.verts, ["co"]*len(mesh.verts))
xx = map(operator.getitem, nv, [0]*len(nv))
yy = map(operator.getitem, nv, [1]*len(nv))
zz = map(operator.getitem, nv, [2]*len(nv))
data.write(struct.pack(">6f", min(xx), min(zz), min(yy), max(xx), max(zz), max(yy)))
return data.getvalue()
# ========================================
# === Average All Vertex Colors (Fast) ===
# ========================================
def average_vertexcolors(mesh):
vertexcolors = {}
vcolor_add = lambda u, v: [u[0]+v[0], u[1]+v[1], u[2]+v[2], u[3]+v[3]]
vcolor_div = lambda u, s: [u[0]/s, u[1]/s, u[2]/s, u[3]/s]
for i in range(len(mesh.faces)): # get all vcolors that share this vertex
if not i%100 and meshtools.show_progress:
Blender.Window.DrawProgressBar(float(i)/len(mesh.verts), "Finding Shared VColors")
for j in range(len(mesh.faces[i].v)):
index = mesh.faces[i].v[j].index
color = mesh.faces[i].col[j]
r,g,b,a = color.r, color.g, color.b, color.a
vertexcolors.setdefault(index, []).append([r,g,b,a])
for i in range(len(vertexcolors)): # average them
if not i%100 and meshtools.show_progress:
Blender.Window.DrawProgressBar(float(i)/len(mesh.verts), "Averaging Vertex Colors")
vcolor = [0,0,0,0] # rgba
for j in range(len(vertexcolors[i])):
vcolor = vcolor_add(vcolor, vertexcolors[i][j])
shared = len(vertexcolors[i])
vertexcolors[i] = vcolor_div(vcolor, shared)
return vertexcolors
# ====================================================
# === Generate Per-Vert Vertex Colors (VMAP Chunk) ===
# ====================================================
def generate_vmap_vc(mesh):
data = cStringIO.StringIO()
data.write("RGB ") # type
data.write(struct.pack(">H", 3)) # dimension
data.write(generate_nstring("Blender's Vertex Colors")) # name
vertexcolors = average_vertexcolors(mesh)
for i in range(len(vertexcolors)):
r, g, b, a = vertexcolors[i]
data.write(struct.pack(">H", i)) # vertex index
data.write(struct.pack(">fff", r/255.0, g/255.0, b/255.0))
return data.getvalue()
# ====================================================
# === Generate Per-Face Vertex Colors (VMAD Chunk) ===
# ====================================================
def generate_vmad_vc(mesh):
data = cStringIO.StringIO()
data.write("RGB ") # type
data.write(struct.pack(">H", 3)) # dimension
data.write(generate_nstring("Blender's Vertex Colors")) # name
for i in range(len(mesh.faces)):
if not i%100 and meshtools.show_progress:
Blender.Window.DrawProgressBar(float(i)/len(mesh.faces), "Writing Vertex Colors")
numfaceverts = len(mesh.faces[i].v)
for j in range(numfaceverts-1, -1, -1): # Reverse order
r = mesh.faces[i].col[j].r
g = mesh.faces[i].col[j].g
b = mesh.faces[i].col[j].b
v = mesh.faces[i].v[j].index
data.write(struct.pack(">H", v)) # vertex index
data.write(struct.pack(">H", i)) # face index
data.write(struct.pack(">fff", r/255.0, g/255.0, b/255.0))
return data.getvalue()
# ================================================
# === Generate Per-Face UV Coords (VMAD Chunk) ===
# ================================================
def generate_vmad_uv(mesh):
data = cStringIO.StringIO()
data.write("TXUV") # type
data.write(struct.pack(">H", 2)) # dimension
data.write(generate_nstring("Blender's UV Coordinates")) # name
for i in range(len(mesh.faces)):
if not i%100 and meshtools.show_progress:
Blender.Window.DrawProgressBar(float(i)/len(mesh.faces), "Writing UV Coordinates")
numfaceverts = len(mesh.faces[i].v)
for j in range(numfaceverts-1, -1, -1): # Reverse order
U,V = mesh.faces[i].uv[j]
v = mesh.faces[i].v[j].index
data.write(struct.pack(">H", v)) # vertex index
data.write(struct.pack(">H", i)) # face index
data.write(struct.pack(">ff", U, V))
return data.getvalue()
# ======================================
# === Generate Variable-Length Index ===
# ======================================
def generate_vx(index):
if index < 0xFF00:
value = struct.pack(">H", index) # 2-byte index
else:
value = struct.pack(">L", index | 0xFF000000) # 4-byte index
return value
# ===================================
# === Generate Faces (POLS Chunk) ===
# ===================================
def generate_pols(mesh):
data = cStringIO.StringIO()
data.write("FACE") # polygon type
for i in range(len(mesh.faces)):
if not i%100 and meshtools.show_progress:
Blender.Window.DrawProgressBar(float(i)/len(mesh.faces), "Writing Faces")
data.write(struct.pack(">H", len(mesh.faces[i].v))) # numfaceverts
numfaceverts = len(mesh.faces[i].v)
for j in range(numfaceverts-1, -1, -1): # Reverse order
index = mesh.faces[i].v[j].index
data.write(generate_vx(index))
return data.getvalue()
# =================================================
# === Generate Polygon Tag Mapping (PTAG Chunk) ===
# =================================================
def generate_ptag(mesh, material_names):
data = cStringIO.StringIO()
data.write("SURF") # polygon tag type
for i in range(len(mesh.faces)): # numfaces
if not i%100 and meshtools.show_progress:
Blender.Window.DrawProgressBar(float(i)/len(mesh.faces), "Writing Surface Indices")
data.write(generate_vx(i))
if (not mesh.materials) and (meshtools.has_vertex_colors(mesh)): # vcols only
if meshtools.average_vcols:
name = "\251 Per-Vert Vertex Colors"
else:
name = "\251 Per-Face Vertex Colors"
elif (mesh.materials) and (not meshtools.has_vertex_colors(mesh)): # materials only
idx = mesh.faces[i].mat #erialIndex
name = mesh.materials[idx].name
elif (not mesh.materials) and (not meshtools.has_vertex_colors(mesh)): # neither
name = "\251 Blender Default"
else: # both
idx = mesh.faces[i].mat
name = mesh.materials[idx].name
names = material_names.keys()
surfidx = names.index(name)
data.write(struct.pack(">H", surfidx)) # surface index
return data.getvalue()
# ===================================================
# === Generate VC Surface Definition (SURF Chunk) ===
# ===================================================
def generate_vcol_surf(mesh):
data = cStringIO.StringIO()
if meshtools.average_vcols and meshtools.has_vertex_colors(mesh):
surface_name = generate_nstring("\251 Per-Vert Vertex Colors")
else:
surface_name = generate_nstring("\251 Per-Face Vertex Colors")
data.write(surface_name)
data.write("\0\0")
data.write("COLR")
data.write(struct.pack(">H", 14))
data.write(struct.pack(">fffH", 1, 1, 1, 0))
data.write("DIFF")
data.write(struct.pack(">H", 6))
data.write(struct.pack(">fH", 0.0, 0))
data.write("LUMI")
data.write(struct.pack(">H", 6))
data.write(struct.pack(">fH", 1.0, 0))
data.write("VCOL")
data.write(struct.pack(">H", 34))
data.write(struct.pack(">fH4s", 1.0, 0, "RGB ")) # intensity, envelope, type
data.write(generate_nstring("Blender's Vertex Colors")) # name
data.write("CMNT") # material comment
comment = "Vertex Colors: Exported from Blender\256 " + meshtools.blender_version_str
comment = generate_nstring(comment)
data.write(struct.pack(">H", len(comment)))
data.write(comment)
return data.getvalue()
# ================================================
# === Generate Surface Definition (SURF Chunk) ===
# ================================================
def generate_surf(material_name):
data = cStringIO.StringIO()
data.write(generate_nstring(material_name))
data.write("\0\0")
material = Blender.Material.Get(material_name)
R,G,B = material.R, material.G, material.B
data.write("COLR")
data.write(struct.pack(">H", 14))
data.write(struct.pack(">fffH", R, G, B, 0))
data.write("DIFF")
data.write(struct.pack(">H", 6))
data.write(struct.pack(">fH", material.ref, 0))
data.write("LUMI")
data.write(struct.pack(">H", 6))
data.write(struct.pack(">fH", material.emit, 0))
data.write("SPEC")
data.write(struct.pack(">H", 6))
data.write(struct.pack(">fH", material.spec, 0))
data.write("GLOS")
data.write(struct.pack(">H", 6))
gloss = material.hard / (255/2.0)
gloss = round(gloss, 1)
data.write(struct.pack(">fH", gloss, 0))
data.write("CMNT") # material comment
comment = material_name + ": Exported from Blender\256 " + meshtools.blender_version_str
comment = generate_nstring(comment)
data.write(struct.pack(">H", len(comment)))
data.write(comment)
# Check if the material contains any image maps
mtextures = material.getTextures() # Get a list of textures linked to the material
for mtex in mtextures:
if (mtex) and (mtex.tex.type == Blender.Texture.Types.IMAGE): # Check if the texture is of type "IMAGE"
data.write("BLOK") # Surface BLOK header
data.write(struct.pack(">H", 104)) # Hardcoded and ugly! Will only handle 1 image per material
# IMAP subchunk (image map sub header)
data.write("IMAP")
data_tmp = cStringIO.StringIO()
data_tmp.write(struct.pack(">H", 0)) # Hardcoded - not sure what it represents
data_tmp.write("CHAN")
data_tmp.write(struct.pack(">H", 4))
data_tmp.write("COLR")
data_tmp.write("OPAC") # Hardcoded texture layer opacity
data_tmp.write(struct.pack(">H", 8))
data_tmp.write(struct.pack(">H", 0))
data_tmp.write(struct.pack(">f", 1.0))
data_tmp.write(struct.pack(">H", 0))
data_tmp.write("ENAB")
data_tmp.write(struct.pack(">HH", 2, 1)) # 1 = texture layer enabled
data_tmp.write("NEGA")
data_tmp.write(struct.pack(">HH", 2, 0)) # Disable negative image (1 = invert RGB values)
data_tmp.write("AXIS")
data_tmp.write(struct.pack(">HH", 2, 1))
data.write(struct.pack(">H", len(data_tmp.getvalue())))
data.write(data_tmp.getvalue())
# IMAG subchunk
data.write("IMAG")
data.write(struct.pack(">HH", 2, 1))
data.write("PROJ")
data.write(struct.pack(">HH", 2, 5)) # UV projection
data.write("VMAP")
uvname = generate_nstring("Blender's UV Coordinates")
data.write(struct.pack(">H", len(uvname)))
data.write(uvname)
return data.getvalue()
# =============================================
# === Generate Default Surface (SURF Chunk) ===
# =============================================
def generate_default_surf():
data = cStringIO.StringIO()
material_name = "\251 Blender Default"
data.write(generate_nstring(material_name))
data.write("\0\0")
data.write("COLR")
data.write(struct.pack(">H", 14))
data.write(struct.pack(">fffH", 1, 1, 1, 0))
data.write("DIFF")
data.write(struct.pack(">H", 6))
data.write(struct.pack(">fH", 0.8, 0))
data.write("LUMI")
data.write(struct.pack(">H", 6))
data.write(struct.pack(">fH", 0, 0))
data.write("SPEC")
data.write(struct.pack(">H", 6))
data.write(struct.pack(">fH", 0.5, 0))
data.write("GLOS")
data.write(struct.pack(">H", 6))
gloss = 50 / (255/2.0)
gloss = round(gloss, 1)
data.write(struct.pack(">fH", gloss, 0))
data.write("CMNT") # material comment
comment = material_name + ": Exported from Blender\256 " + meshtools.blender_version_str
# vals = map(chr, range(164,255,1))
# keys = range(164,255,1)
# keys = map(lambda x: `x`, keys)
# comment = map(None, keys, vals)
# comment = reduce(operator.add, comment)
# comment = reduce(operator.add, comment)
comment = generate_nstring(comment)
data.write(struct.pack(">H", len(comment)))
data.write(comment)
return data.getvalue()
# ============================================
# === Generate Object Comment (TEXT Chunk) ===
# ============================================
def generate_text():
comment = "Lightwave Export Script for Blender "
comment += meshtools.blender_version_str + "\n"
comment += "by Anthony D'Agostino\n"
comment += "scorpius@netzero.com\n"
comment += "http://ourworld.compuserve.com/homepages/scorpius\n"
return generate_nstring(comment)
# ==============================================
# === Generate Description Line (DESC Chunk) ===
# ==============================================
def generate_desc():
comment = "Copyright 2002 Scorpius Entertainment"
return generate_nstring(comment)
# ==================================================
# === Generate Thumbnail Icon Image (ICON Chunk) ===
# ==================================================
def generate_icon():
data = cStringIO.StringIO()
file = open("f:/obj/radiosity/lwo2_icon.tga", "rb") # 60x60 uncompressed TGA
file.read(18)
icon_data = file.read(3600) # ?
file.close()
data.write(struct.pack(">HH", 0, 60))
data.write(icon_data)
#print len(icon_data)
return data.getvalue()
# ===============================================
# === Generate CLIP chunk with STIL subchunks ===
# ===============================================
def generate_clip(mesh, material_names):
data = cStringIO.StringIO()
clipid = 1
for i in range(len(mesh.materials)): # Run through list of materials used by mesh
material = Blender.Material.Get(mesh.materials[i].name)
mtextures = material.getTextures() # Get a list of textures linked to the material
for mtex in mtextures:
if (mtex) and (mtex.tex.type == Blender.Texture.Types.IMAGE): # Check if the texture is of type "IMAGE"
pathname = mtex.tex.image.filename # If full path is needed use filename in place of name
pathname = pathname[0:2] + pathname.replace("\\", "/")[3:] # Convert to Modo standard path
imagename = generate_nstring(pathname)
data.write(struct.pack(">L", clipid)) # CLIP sequence/id
data.write("STIL") # STIL image
data.write(struct.pack(">H", len(imagename))) # Size of image name
data.write(imagename)
clipid += 1
return data.getvalue()
# ===================
# === Write Chunk ===
# ===================
def write_chunk(file, name, data):
file.write(name)
file.write(struct.pack(">L", len(data)))
file.write(data)
# =============================
# === Write LWO File Header ===
# =============================
def write_header(file, chunks):
chunk_sizes = map(len, chunks)
chunk_sizes = reduce(operator.add, chunk_sizes)
form_size = chunk_sizes + len(chunks)*8 + len("FORM")
file.write("FORM")
file.write(struct.pack(">L", form_size))
file.write("LWO2")
def fs_callback(filename):
if filename.find('.lwo', -4) <= 0: filename += '.lwo'
write(filename)
Blender.Window.FileSelector(fs_callback, "Export LWO")