PyAssimp initial import.

git-svn-id: https://assimp.svn.sourceforge.net/svnroot/assimp/trunk@147 67173fc5-114c-0410-ac8e-9d2fd5bffc1f
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sebastianhempel 2008-09-17 15:25:20 +00:00
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PyAssimp Readme
---------------
To be filled.

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import structs
import ctypes
import os
from ctypes import POINTER, c_int, c_uint, c_double, c_char, c_float
#get the assimp path
LIBRARY = os.path.join(os.path.dirname(__file__), "assimp.so")
class AssimpError(BaseException):
"""
If ann internal error occures.
"""
pass
class AssimpLib(object):
#open library
_dll = ctypes.cdll.LoadLibrary(LIBRARY)
#get functions
load = _dll.aiImportFile
load.restype = POINTER(structs.SCENE)
release = _dll.aiReleaseImport
class AssimpBase(object):
"""
Base class for all Assimp-classes.
"""
def _load_array(self, data, count, cons):
"""
Loads a whole array out of data, and constructs a new object. If data
is NULL, an empty list will be returned.
data - pointer to array
count - size of the array
cons - constructor
result array data
"""
if data:
return [cons(data[i]) for i in range(count)]
else:
return []
class Scene(AssimpBase):
"""
The root structure of the imported data.
Everything that was imported from the given file can be accessed from here.
"""
#possible flags
FLAGS = {1 : "AI_SCENE_FLAGS_ANIM_SKELETON_ONLY"}
def __init__(self, model):
"""
Converts the model-data to a real scene
model - the raw model-data
"""
#process data
self._load(model)
def _load(self, model):
"""
Converts model from raw-data to fancy data!
model - pointer to data
"""
#store scene flags
self.flags = model.flags
#load mesh-data
self.meshes = self._load_array(model.mMeshes,
model.mNumMeshes,
lambda x: Mesh(x.contents))
def list_flags(self):
"""
Returns a list of all used flags.
result list of flags
"""
return [name for (key, value) in Scene.FLAGS.iteritems()
if (key & self.flags)>0]
class Mesh(AssimpBase):
"""
A mesh represents a geometry or model with a single material.
It usually consists of a number of vertices and a series of primitives/faces
referencing the vertices. In addition there might be a series of bones, each
of them addressing a number of vertices with a certain weight. Vertex data
is presented in channels with each channel containing a single per-vertex
information such as a set of texture coords or a normal vector.
If a data pointer is non-null, the corresponding data stream is present.
A Mesh uses only a single material which is referenced by a material ID.
"""
def __init__(self, mesh):
"""
Loads mesh from raw-data.
"""
#process data
self._load(mesh)
def _load(self, mesh):
"""
Loads mesh-data from raw data
mesh - raw mesh-data
"""
#converts a VECTOR3D-struct to a tuple
vec2tuple = lambda x: (x.x, x.y, x.z)
#load vertices
self.vertices = self._load_array(mesh.mVertices,
mesh.mNumVertices,
vec2tuple)
#load normals
self.normals = self._load_array(mesh.mNormals,
mesh.mNumVertices,
vec2tuple)
#load tangents
self.tangents = self._load_array(mesh.mTangents,
mesh.mNumVertices,
vec2tuple)
#load bitangents
self.bitangents = self._load_array(mesh.mBitangents,
mesh.mNumVertices,
vec2tuple)
#vertex color sets
self.colors = self._load_colors(mesh)
#number of texture coordinates
self.numuv = self._load_uv_component_count(mesh) #FIXME
def _load_uv_component_count(self, mesh):
"""
Loads the number of components for a given UV channel.
mesh - mesh-data
result (count channel 1, count channel 2, ...)
"""
return tuple(mesh.mNumUVComponents[i]
for i in range(structs.MESH.AI_MAX_NUMBER_OF_TEXTURECOORDS))
def _load_colors(self, mesh):
"""
Loads color sets.
mesh - mesh with color sets
result all color sets
"""
result = []
#for all possible sets
for i in range(structs.MESH.AI_MAX_NUMBER_OF_COLOR_SETS):
#try this set
x = mesh.mColors[i]
if x:
channel = []
#read data for al vertices!
for j in range(mesh.mNumVertices):
c = x[j]
channel.append((c.r, c.g, c.b, c.a))
result.append(channel)
return result
#the loader as singleton
_assimp_lib = AssimpLib()
def load(filename, processing=0):
"""
Loads the model with some specific processing parameters.
filename - file to load model from
processing - processing parameters
result Scene-object with model-data
throws AssimpError - could not open file
"""
#read pure data
model = _assimp_lib.load(filename, processing)
if not model:
#Uhhh, something went wrong!
raise AssimpError, ("could not import file: %s" % filename)
try:
#create scene
return Scene(model.contents)
finally:
#forget raw data
_assimp_lib.release(model)

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"""
All ASSIMP C-structures.
"""
from ctypes import POINTER, c_int, c_uint, c_char, c_float, Structure, c_char_p, c_double, c_ubyte
class STRING(Structure):
"""
Represents a String in ASSIMP.
"""
#Maximum length of a string. See "MAXLEN" in "aiTypes.h"
MAXLEN = 1024
_fields_ = [
#length of the string
("length", c_uint),
#string data
("data", c_char*MAXLEN)
]
class MATRIX4X4(Structure):
"""
ASSIMP's 4x4-matrix
"""
_fields_ = [
#all the fields
("a1", c_float), ("a2", c_float), ("a3", c_float), ("a4", c_float),
("b1", c_float), ("b2", c_float), ("b3", c_float), ("b4", c_float),
("c1", c_float), ("c2", c_float), ("c3", c_float), ("c4", c_float),
("d1", c_float), ("d2", c_float), ("d3", c_float), ("d4", c_float),
]
class NODE(Structure):
"""
A node in the imported hierarchy.
Each node has name, a parent node (except for the root node),
a transformation relative to its parent and possibly several child nodes.
Simple file formats don't support hierarchical structures, for these formats
the imported scene does consist of only a single root node with no childs.
"""
pass
NODE._fields_ = [
#The name of the node
("mName", STRING),
#The transformation relative to the node's parent.
("aiMatrix4x4", MATRIX4X4),
#Parent node. NULL if this node is the root node.
("mParent", POINTER(NODE)),
#The number of child nodes of this node.
("mNumChildren", c_uint),
#The child nodes of this node. NULL if mNumChildren is 0.
("mChildren", POINTER(POINTER(NODE))),
#The number of meshes of this node.
("mNumMeshes", c_uint),
#The meshes of this node. Each entry is an index into the mesh.
("mMeshes", POINTER(c_int))
]
class VECTOR3D(Structure):
"""
Represents a three-dimensional vector.
"""
_fields_ = [
("x", c_float),
("y", c_float),
("z", c_float)
]
class COLOR4D(Structure):
"""
Represents a color in Red-Green-Blue space including an alpha component.
"""
_fields_ = [
("r", c_float),
("g", c_float),
("b", c_float),
("a", c_float)
]
class FACE(Structure):
"""
A single face in a mesh, referring to multiple vertices.
If mNumIndices is 3, the face is a triangle,
for mNumIndices > 3 it's a polygon.
Point and line primitives are rarely used and are NOT supported. However,
a load could pass them as degenerated triangles.
"""
_fields_ = [
#Number of indices defining this face. 3 for a triangle, >3 for polygon
("mNumIndices", c_uint),
#Pointer to the indices array. Size of the array is given in numIndices.
("mIndices", POINTER(c_uint))
]
class VERTEXWEIGHT(Structure):
"""
A single influence of a bone on a vertex.
"""
_fields_ = [
#Index of the vertex which is influenced by the bone.
("mVertexId", c_uint),
#The strength of the influence in the range (0...1).
#The influence from all bones at one vertex amounts to 1.
("mWeight", c_float)
]
class BONE(Structure):
"""
A single bone of a mesh. A bone has a name by which it can be found
in the frame hierarchy and by which it can be addressed by animations.
In addition it has a number of influences on vertices.
"""
_fields_ = [
#The name of the bone.
("mName", STRING),
#The number of vertices affected by this bone
("mNumWeights", c_uint),
#The vertices affected by this bone
("mWeights", POINTER(VERTEXWEIGHT)),
#Matrix that transforms from mesh space to bone space in bind pose
("mOffsetMatrix", MATRIX4X4)
]
class MESH(Structure):
"""
A mesh represents a geometry or model with a single material.
It usually consists of a number of vertices and a series of primitives/faces
referencing the vertices. In addition there might be a series of bones, each
of them addressing a number of vertices with a certain weight. Vertex data
is presented in channels with each channel containing a single per-vertex
information such as a set of texture coords or a normal vector.
If a data pointer is non-null, the corresponding data stream is present.
A Mesh uses only a single material which is referenced by a material ID.
"""
#Maximum number of texture coord sets (UV(W) channels) per mesh.
#See "AI_MAX_NUMBER_OF_TEXTURECOORDS" in "aiMesh.h" for further
#information.
AI_MAX_NUMBER_OF_TEXTURECOORDS = 4
#Maximum number of vertex color sets per mesh.
#Normally: Diffuse, specular, ambient and emissive
#However one could use the vertex color sets for any other purpose, too.
AI_MAX_NUMBER_OF_COLOR_SETS = 4
_fields_ = [
#The number of vertices in this mesh.
#This is also the size of all of the per-vertex data arrays
("mNumVertices", c_uint), #OK
#The number of primitives (triangles, polygones, lines) in this mesh.
#This is also the size of the mFaces array
("mNumFaces", c_uint),
#Vertex positions.
#This array is always present in a mesh. The array is
#mNumVertices in size.
("mVertices", POINTER(VECTOR3D)), #OK
#Vertex normals.
#The array contains normalized vectors, NULL if not present.
#The array is mNumVertices in size.
("mNormals", POINTER(VECTOR3D)), #OK
#Vertex tangents.
#The tangent of a vertex points in the direction of the positive
#X texture axis. The array contains normalized vectors, NULL if
#not present. The array is mNumVertices in size.
#@note If the mesh contains tangents, it automatically also
#contains bitangents.
("mTangents", POINTER(VECTOR3D)), #OK
#Vertex bitangents.
#The bitangent of a vertex points in the direction of the positive
#Y texture axis. The array contains normalized vectors, NULL if not
#present. The array is mNumVertices in size.
#@note If the mesh contains tangents, it automatically also contains
#bitangents.
("mBitangents", POINTER(VECTOR3D)), #OK
#Vertex color sets.
#A mesh may contain 0 to #AI_MAX_NUMBER_OF_COLOR_SETS vertex
#colors per vertex. NULL if not present. Each array is
#mNumVertices in size if present.
("mColors", POINTER(COLOR4D)*AI_MAX_NUMBER_OF_COLOR_SETS), #OK
#Vertex texture coords, also known as UV channels.
#A mesh may contain 0 to AI_MAX_NUMBER_OF_TEXTURECOORDS per
#vertex. NULL if not present. The array is mNumVertices in size.
("mTextureCoords", POINTER(VECTOR3D)*AI_MAX_NUMBER_OF_TEXTURECOORDS),
#Specifies the number of components for a given UV channel.
#Up to three channels are supported (UVW, for accessing volume
#or cube maps). If the value is 2 for a given channel n, the
#component p.z of mTextureCoords[n][p] is set to 0.0f.
#If the value is 1 for a given channel, p.y is set to 0.0f, too.
#@note 4D coords are not supported
("mNumUVComponents", c_uint*AI_MAX_NUMBER_OF_TEXTURECOORDS),
#The faces the mesh is contstructed from.
#Each face referres to a number of vertices by their indices.
#This array is always present in a mesh, its size is given
#in mNumFaces.
("mFaces", POINTER(FACE)),
#The number of bones this mesh contains.
#Can be 0, in which case the mBones array is NULL.
("mNumBones", c_uint),
#The bones of this mesh.
#A bone consists of a name by which it can be found in the
#frame hierarchy and a set of vertex weights.
("mBones", POINTER(POINTER(BONE))),
#The material used by this mesh.
#A mesh does use only a single material. If an imported model uses
#multiple materials, the import splits up the mesh. Use this value
#as index into the scene's material list.
("mMaterialIndex", c_uint)
]
class MATERIALPROPERTY(Structure):
"""
Data structure for a single property inside a material.
"""
_fields_ = [
#Specifies the name of the property (key)
#Keys are case insensitive.
("mKey", STRING),
#Size of the buffer mData is pointing to, in bytes
#This value may not be 0.
("mDataLength", c_uint),
#Type information for the property.
#Defines the data layout inside the
#data buffer. This is used by the library
#internally to perform debug checks.
#THIS IS AN ENUM!
("mType", c_int),
#Binary buffer to hold the property's value
#The buffer has no terminal character. However,
#if a string is stored inside it may use 0 as terminal,
#but it would be contained in mDataLength. This member
#is never 0
("mData", c_char_p)
]
class MATERIAL(Structure):
"""
Data structure for a material.
Material data is stored using a key-value structure, called property
(to guarant that the system is maximally flexible).
The library defines a set of standard keys (AI_MATKEY) which should be
enough for nearly all purposes.
"""
_fields_ = [
#List of all material properties loaded.
("mProperties", POINTER(POINTER(MATERIALPROPERTY))),
#Number of properties loaded
("mNumProperties", c_uint),
("mNumAllocated", c_uint)
]
class VECTORKEY(Structure):
"""
A time-value pair specifying a certain 3D vector for the given time.
"""
_fields_ = [
#The time of this key
("mTime", c_double),
#The value of this key
("mValue", VECTOR3D)
]
class QUATERNION(Structure):
"""
Represents a quaternion in a 4D vector.
"""
_fields = [
#the components
("w", c_float),
("x", c_float),
("y", c_float),
("z", c_float)
]
class QUATKEY(Structure):
"""
A time-value pair specifying a rotation for the given time. For joint
animations the rotation is usually expressed using a quaternion.
"""
_fields_ = [
#The time of this key
("mTime", c_double),
#The value of this key
("mValue", QUATERNION)
]
class BONEANIM(Structure):
"""
Describes the animation of a single node. The name specifies the bone/node
which is affected by this animation channel. The keyframes are given in
three separate series of values, one each for position, rotation and
scaling.
NOTE: The name "BoneAnim" is misleading. This structure is also used to
describe the animation of regular nodes on the node graph. They needn't be
nodes.
"""
_fields_ = [
#The name of the bone affected by this animation.
("mBoneName", STRING),
#The number of position keys
("mNumPositionKeys", c_uint),
#The position keys of this animation channel. Positions are
#specified as 3D vector. The array is mNumPositionKeys in size.
("mPositionKeys", POINTER(VECTORKEY)),
#The number of rotation keys
("mNumRotationKeys", c_uint),
#The rotation keys of this animation channel. Rotations are given as
#quaternions, which are 4D vectors. The array is mNumRotationKeys in
#size.
("mRotationKeys", POINTER(QUATKEY)),
#The number of scaling keys
("mNumScalingKeys", c_uint),
#The scaling keys of this animation channel. Scalings are specified
#as 3D vector. The array is mNumScalingKeys in size.
("mScalingKeys", POINTER(VECTORKEY))
]
class ANIMATION(Structure):
"""
An animation consists of keyframe data for a number of bones.
For each bone affected by the animation a separate series of data is given.
"""
_fields_ = [
#The name of the animation. If the modelling package this data was
#exported from does support only a single animation channel, this
#name is usually empty (length is zero).
("mName", STRING),
#Duration of the animation in ticks.
("mDuration", c_double),
#Ticks per second. 0 if not specified in the imported file
("mTicksPerSecond", c_double),
#The number of bone animation channels. Each channel affects a
#single bone.
("mNumBones", c_uint),
#The bone animation channels. Each channel affects a single bone.
#The array is mNumBones in size.
("mBones", POINTER(POINTER(BONEANIM)))
]
class TEXEL(Structure):
"""
Helper structure to represent a texel in ARGB8888 format
"""
_fields_ = [
("b", c_ubyte),
("g", c_ubyte),
("r", c_ubyte),
("a", c_ubyte)
]
class TEXTURE(Structure):
"""
Helper structure to describe an embedded texture
Normally textures are contained in external files but some file formats
do embedd them.
"""
_fields_ = [
#Width of the texture, in pixels
#If mHeight is zero the texture is compressed in a format
#like JPEG. In this case mWidth specifies the size of the
#memory area pcData is pointing to, in bytes.
("mWidth", c_uint),
#Height of the texture, in pixels
#If this value is zero, pcData points to an compressed texture
#in an unknown format (e.g. JPEG).
("mHeight", c_uint),
#A hint from the loader to make it easier for applications
#to determine the type of embedded compressed textures.
#If mHeight != 0 this member is undefined. Otherwise it
#will be set to '\0\0\0\0' if the loader has no additional
#information about the texture file format used OR the
#file extension of the format without a leading dot.
#E.g. 'dds\0', 'pcx\0'. All characters are lower-case.
("achFormatHint", c_char*4),
#Data of the texture.
#Points to an array of mWidth * mHeight aiTexel's.
#The format of the texture data is always ARGB8888 to
#make the implementation for user of the library as easy
#as possible. If mHeight = 0 this is a pointer to a memory
#buffer of size mWidth containing the compressed texture
#data. Good luck, have fun!
("pcData", POINTER(TEXEL))
]
class SCENE(Structure):
"""
The root structure of the imported data.
Everything that was imported from the given file can be accessed from here.
"""
_fields_ = [
#Any combination of the AI_SCENE_FLAGS_XXX flags
("flags", c_uint), #OK
#The root node of the hierarchy.
#There will always be at least the root node if the import
#was successful. Presence of further nodes depends on the
#format and content of the imported file.
("mRootNode", POINTER(NODE)),
#The number of meshes in the scene.
("mNumMeshes", c_uint), #OK
#The array of meshes.
#Use the indices given in the aiNode structure to access
#this array. The array is mNumMeshes in size.
("mMeshes", POINTER(POINTER(MESH))), #OK
#The number of materials in the scene.
("mNumMaterials", c_uint),
#The array of materials.
#Use the index given in each aiMesh structure to access this
#array. The array is mNumMaterials in size.
("mMaterials", POINTER(POINTER(MATERIAL))),
#The number of animations in the scene.
("mNumAnimations", c_uint),
#The array of animations.
#All animations imported from the given file are listed here.
#The array is mNumAnimations in size.
("mAnimations", POINTER(POINTER(ANIMATION))),
#The number of textures embedded into the file
("mNumTextures", c_uint),
#The array of embedded textures.
#Not many file formats embedd their textures into the file.
#An example is Quake's MDL format (which is also used by
#some GameStudio(TM) versions)
("mTextures", POINTER(POINTER(TEXTURE)))
]

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from pyassimp import pyassimp
MODEL = r"../test.ase"
def main():
scene = pyassimp.load(MODEL)
#write some statistics
print "SCENE:"
print " flags:", ", ".join(scene.list_flags())
print " meshes:", len(scene.meshes)
print ""
print "MESHES:"
for index, mesh in enumerate(scene.meshes):
print " MESH", index+1
print " vertices:", len(mesh.vertices)
print " first:", mesh.vertices[:3]
print " colors:", len(mesh.colors)
print " uv-counts:", mesh.numuv
print ""
if __name__ == "__main__":
main()