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jMonkeyEngine is a 3-D game engine for adventurous Java developers
/*
* Copyright (c) 2009-2022 jMonkeyEngine
* All rights reserved.
*
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* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
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* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
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package com.jme3.scene.plugins.gltf;
import com.google.gson.*;
import com.google.gson.stream.JsonReader;
import com.jme3.anim.*;
import com.jme3.asset.*;
import com.jme3.material.Material;
import com.jme3.material.RenderState;
import com.jme3.math.*;
import com.jme3.renderer.Camera;
import com.jme3.renderer.queue.RenderQueue;
import com.jme3.scene.*;
import com.jme3.scene.control.CameraControl;
import com.jme3.scene.mesh.MorphTarget;
import static com.jme3.scene.plugins.gltf.GltfUtils.*;
import com.jme3.texture.Texture;
import com.jme3.texture.Texture2D;
import com.jme3.util.IntMap;
import com.jme3.util.mikktspace.MikktspaceTangentGenerator;
import java.io.*;
import java.net.URLDecoder;
import java.nio.Buffer;
import java.nio.FloatBuffer;
import java.util.*;
import java.util.logging.Level;
import java.util.logging.Logger;
/**
* GLTF 2.0 loader
* Created by Nehon on 07/08/2017.
*/
public class GltfLoader implements AssetLoader {
private static final Logger logger = Logger.getLogger(GltfLoader.class.getName());
// Data cache for already parsed JME objects
private final Map dataCache = new HashMap<>();
private JsonArray scenes;
private JsonArray nodes;
private JsonArray meshes;
private JsonArray accessors;
private JsonArray bufferViews;
private JsonArray buffers;
private JsonArray materials;
private JsonArray textures;
private JsonArray images;
private JsonArray samplers;
private JsonArray animations;
private JsonArray skins;
private JsonArray cameras;
private Material defaultMat;
private AssetInfo info;
private JsonObject docRoot;
private Node rootNode;
private final FloatArrayPopulator floatArrayPopulator = new FloatArrayPopulator();
private final Vector3fArrayPopulator vector3fArrayPopulator = new Vector3fArrayPopulator();
private final QuaternionArrayPopulator quaternionArrayPopulator = new QuaternionArrayPopulator();
private final Matrix4fArrayPopulator matrix4fArrayPopulator = new Matrix4fArrayPopulator();
private final Map defaultMaterialAdapters = new HashMap<>();
private final CustomContentManager customContentManager = new CustomContentManager();
private boolean useNormalsFlag = false;
Map> skinnedSpatials = new HashMap<>();
IntMap skinBuffers = new IntMap<>();
public GltfLoader() {
defaultMaterialAdapters.put("pbrMetallicRoughness", new PBRMetalRoughMaterialAdapter());
}
@Override
public Object load(AssetInfo assetInfo) throws IOException {
return loadFromStream(assetInfo, assetInfo.openStream());
}
protected Object loadFromStream(AssetInfo assetInfo, InputStream stream) throws IOException {
try {
dataCache.clear();
info = assetInfo;
skinnedSpatials.clear();
rootNode = new Node();
if (defaultMat == null) {
defaultMat = new Material(assetInfo.getManager(), "Common/MatDefs/Light/PBRLighting.j3md");
defaultMat.setColor("BaseColor", ColorRGBA.White);
defaultMat.setFloat("Metallic", 0f);
defaultMat.setFloat("Roughness", 1f);
}
docRoot = JsonParser.parseReader(new JsonReader(new InputStreamReader(stream))).getAsJsonObject();
JsonObject asset = docRoot.getAsJsonObject().get("asset").getAsJsonObject();
getAsString(asset, "generator");
String version = getAsString(asset, "version");
String minVersion = getAsString(asset, "minVersion");
if (!isSupported(version, minVersion)) {
logger.log(Level.SEVERE, "Gltf Loader doesn''t support this gltf version: {0}{1}", new Object[]{version, minVersion != null ? ("/" + minVersion) : ""});
}
scenes = docRoot.getAsJsonArray("scenes");
nodes = docRoot.getAsJsonArray("nodes");
meshes = docRoot.getAsJsonArray("meshes");
accessors = docRoot.getAsJsonArray("accessors");
bufferViews = docRoot.getAsJsonArray("bufferViews");
buffers = docRoot.getAsJsonArray("buffers");
materials = docRoot.getAsJsonArray("materials");
textures = docRoot.getAsJsonArray("textures");
images = docRoot.getAsJsonArray("images");
samplers = docRoot.getAsJsonArray("samplers");
animations = docRoot.getAsJsonArray("animations");
skins = docRoot.getAsJsonArray("skins");
cameras = docRoot.getAsJsonArray("cameras");
customContentManager.init(this);
readSkins();
readCameras();
JsonPrimitive defaultScene = docRoot.getAsJsonPrimitive("scene");
readScenes(defaultScene, rootNode);
rootNode = customContentManager.readExtensionAndExtras("root", docRoot, rootNode);
// Loading animations
if (animations != null) {
for (int i = 0; i < animations.size(); i++) {
readAnimation(i);
}
}
setupControls();
// only one scene let's not return the root.
if (rootNode.getChildren().size() == 1) {
Node child = (Node) rootNode.getChild(0);
// Migrate lights that were in the parent to the child.
rootNode.getLocalLightList().forEach(child::addLight);
rootNode = child;
}
// no name for the scene... let's set the file name.
if (rootNode.getName() == null) {
rootNode.setName(assetInfo.getKey().getName());
}
return rootNode;
} catch (Exception e) {
throw new AssetLoadException("An error occurred loading " + assetInfo.getKey().getName(), e);
} finally {
stream.close();
}
}
private void setDefaultParams(Material mat) {
mat.setColor("BaseColor", ColorRGBA.White);
mat.setFloat("Metallic", 0f);
mat.setFloat("Roughness", 1f);
}
private boolean isSupported(String version, String minVersion) {
return "2.0".equals(version);
}
public void readScenes(JsonPrimitive defaultScene, Node rootNode) throws IOException {
if (scenes == null) {
// no scene... lets handle this later...
throw new AssetLoadException("Gltf files with no scene is not yet supported");
}
for (JsonElement scene : scenes) {
Node sceneNode = new Node();
// Specs say that only the default scene should be rendered.
// If there are several scenes, they are attached to the rootScene, but they are culled.
sceneNode.setCullHint(Spatial.CullHint.Always);
sceneNode.setName(getAsString(scene.getAsJsonObject(), "name"));
// If the scene is empty, ignore it.
if (!scene.getAsJsonObject().has("nodes")) {
continue;
}
JsonArray sceneNodes = scene.getAsJsonObject().getAsJsonArray("nodes");
sceneNode = customContentManager.readExtensionAndExtras("scene", scene, sceneNode);
rootNode.attachChild(sceneNode);
for (JsonElement node : sceneNodes) {
readChild(sceneNode, node);
}
}
// Setting the default scene cul hint to inherit.
int activeChild = 0;
if (defaultScene != null) {
activeChild = defaultScene.getAsInt();
}
rootNode.getChild(activeChild).setCullHint(Spatial.CullHint.Inherit);
}
public Object readNode(int nodeIndex) throws IOException {
Object obj = fetchFromCache("nodes", nodeIndex, Object.class);
if (obj != null) {
if (obj instanceof JointWrapper) {
// the node can be a previously loaded bone let's return it
return obj;
} else {
// If a spatial is referenced several times, it may be attached to different parents,
// and it's not possible in JME, so we have to clone it.
return ((Spatial) obj).clone();
}
}
Spatial spatial;
JsonObject nodeData = nodes.get(nodeIndex).getAsJsonObject();
JsonArray children = nodeData.getAsJsonArray("children");
Integer meshIndex = getAsInteger(nodeData, "mesh");
if (meshIndex != null) {
assertNotNull(meshes, "Can't find any mesh data, yet a node references a mesh");
// there is a mesh in this node, however gltf
// can split meshes in primitives (some kind of sub meshes),
// We don't have this in JME, so we have to make one Mesh and one Geometry for each primitive.
Geometry[] primitives = readMeshPrimitives(meshIndex);
if (primitives.length == 1 && children == null) {
// only one geometry, let's not wrap it in another node unless the node has children.
spatial = primitives[0];
} else {
// several geometries, let's make a parent Node and attach them to it
Node node = new Node();
for (Geometry primitive : primitives) {
node.attachChild(primitive);
}
spatial = node;
}
spatial.setName(readMeshName(meshIndex));
} else {
// no mesh, we have a node. Can be a camera node or a regular node.
Integer camIndex = getAsInteger(nodeData, "camera");
if (camIndex != null) {
Camera cam = fetchFromCache("cameras", camIndex, Camera.class);
CameraNode node = new CameraNode(null, cam);
node.setControlDir(CameraControl.ControlDirection.SpatialToCamera);
spatial = node;
} else {
Node node = new Node();
spatial = node;
}
}
Integer skinIndex = getAsInteger(nodeData, "skin");
if (skinIndex != null) {
SkinData skinData = fetchFromCache("skins", skinIndex, SkinData.class);
if (skinData != null) {
List spatials = skinnedSpatials.get(skinData);
spatials.add(spatial);
skinData.used = true;
}
}
spatial.setLocalTransform(readTransforms(nodeData));
if (spatial.getName() == null) {
spatial.setName(getAsString(nodeData.getAsJsonObject(), "name"));
}
spatial = customContentManager.readExtensionAndExtras("node", nodeData, spatial);
addToCache("nodes", nodeIndex, spatial, nodes.size());
return spatial;
}
private void readChild(Spatial parent, JsonElement nodeIndex) throws IOException {
Object loaded = readNode(nodeIndex.getAsInt());
if (loaded instanceof Spatial) {
Spatial spatial = ((Spatial) loaded);
((Node) parent).attachChild(spatial);
JsonObject nodeElem = nodes.get(nodeIndex.getAsInt()).getAsJsonObject();
JsonArray children = nodeElem.getAsJsonArray("children");
if (children != null) {
for (JsonElement child : children) {
readChild(spatial, child);
}
}
} else if (loaded instanceof JointWrapper) {
// parent is the Armature Node, we have to apply its transforms to the root bone's animation data
JointWrapper bw = (JointWrapper) loaded;
bw.isRoot = true;
SkinData skinData = fetchFromCache("skins", bw.skinIndex, SkinData.class);
if (skinData == null) {
return;
}
skinData.parent = parent;
}
}
public Transform readTransforms(JsonObject nodeData) {
Transform transform = new Transform();
JsonArray matrix = nodeData.getAsJsonArray("matrix");
if (matrix != null) {
// transforms are given as a mat4
float[] tmpArray = new float[16];
for (int i = 0; i < tmpArray.length; i++) {
tmpArray[i] = matrix.get(i).getAsFloat();
}
// creates a row major matrix from color major data
Matrix4f mat = new Matrix4f(tmpArray);
transform.fromTransformMatrix(mat);
return transform;
}
// no matrix transforms: no transforms or transforms givens as translation/rotation/scale
JsonArray translation = nodeData.getAsJsonArray("translation");
if (translation != null) {
transform.setTranslation(
translation.get(0).getAsFloat(),
translation.get(1).getAsFloat(),
translation.get(2).getAsFloat());
}
JsonArray rotation = nodeData.getAsJsonArray("rotation");
if (rotation != null) {
transform.setRotation(new Quaternion(
rotation.get(0).getAsFloat(),
rotation.get(1).getAsFloat(),
rotation.get(2).getAsFloat(),
rotation.get(3).getAsFloat()));
}
JsonArray scale = nodeData.getAsJsonArray("scale");
if (scale != null) {
transform.setScale(
scale.get(0).getAsFloat(),
scale.get(1).getAsFloat(),
scale.get(2).getAsFloat());
}
return transform;
}
public Geometry[] readMeshPrimitives(int meshIndex) throws IOException {
Geometry[] geomArray = (Geometry[]) fetchFromCache("meshes", meshIndex, Object.class);
if (geomArray != null) {
// cloning the geoms.
Geometry[] geoms = new Geometry[geomArray.length];
for (int i = 0; i < geoms.length; i++) {
geoms[i] = geomArray[i].clone(false);
}
return geoms;
}
JsonObject meshData = meshes.get(meshIndex).getAsJsonObject();
JsonArray primitives = meshData.getAsJsonArray("primitives");
assertNotNull(primitives, "Can't find any primitives in mesh " + meshIndex);
String name = getAsString(meshData, "name");
geomArray = new Geometry[primitives.size()];
int index = 0;
for (JsonElement primitive : primitives) {
JsonObject meshObject = primitive.getAsJsonObject();
Mesh mesh = new Mesh();
addToCache("mesh", 0, mesh, 1);
Integer mode = getAsInteger(meshObject, "mode");
mesh.setMode(getMeshMode(mode));
Integer indices = getAsInteger(meshObject, "indices");
if (indices != null) {
mesh.setBuffer(readAccessorData(indices, new VertexBufferPopulator(VertexBuffer.Type.Index)));
}
JsonObject attributes = meshObject.getAsJsonObject("attributes");
assertNotNull(attributes, "No attributes defined for mesh " + mesh);
skinBuffers.clear();
for (Map.Entry entry : attributes.entrySet()) {
// special case for joints and weights buffer.
// If there are more than 4 bones per vertex, there might be several of them
// we need to read them all and to keep only the 4 that have the most weight on the vertex.
String bufferType = entry.getKey();
if (bufferType.startsWith("JOINTS")) {
SkinBuffers buffs = getSkinBuffers(bufferType);
SkinBuffers buffer
= readAccessorData(entry.getValue().getAsInt(), new JointArrayPopulator());
buffs.joints = buffer.joints;
buffs.componentSize = buffer.componentSize;
} else if (bufferType.startsWith("WEIGHTS")) {
SkinBuffers buffs = getSkinBuffers(bufferType);
buffs.weights = readAccessorData(entry.getValue().getAsInt(), new FloatArrayPopulator());
} else {
VertexBuffer vb = readAccessorData(entry.getValue().getAsInt(),
new VertexBufferPopulator(getVertexBufferType(bufferType)));
if (vb != null) {
mesh.setBuffer(vb);
}
}
}
handleSkinningBuffers(mesh, skinBuffers);
if (mesh.getBuffer(VertexBuffer.Type.BoneIndex) != null) {
// the mesh has some skinning let's create needed buffers for HW skinning
// creating empty buffers for HW skinning
// the buffers will be setup if ever used.
VertexBuffer weightsHW = new VertexBuffer(VertexBuffer.Type.HWBoneWeight);
VertexBuffer indicesHW = new VertexBuffer(VertexBuffer.Type.HWBoneIndex);
// setting usage to cpuOnly so that the buffer is not sent empty to the GPU
indicesHW.setUsage(VertexBuffer.Usage.CpuOnly);
weightsHW.setUsage(VertexBuffer.Usage.CpuOnly);
mesh.setBuffer(weightsHW);
mesh.setBuffer(indicesHW);
mesh.generateBindPose();
}
// Read morph target names
LinkedList targetNames = new LinkedList<>();
if (meshData.has("extras") && meshData.getAsJsonObject("extras").has("targetNames")) {
JsonArray targetNamesJson = meshData.getAsJsonObject("extras").getAsJsonArray("targetNames");
for (JsonElement target : targetNamesJson) {
targetNames.add(target.getAsString());
}
}
// Read morph targets
JsonArray targets = meshObject.getAsJsonArray("targets");
if (targets != null) {
for (JsonElement target : targets) {
MorphTarget morphTarget = new MorphTarget();
if (targetNames.size() > 0) {
morphTarget.setName(targetNames.pop());
}
for (Map.Entry entry : target.getAsJsonObject().entrySet()) {
String bufferType = entry.getKey();
VertexBuffer.Type type = getVertexBufferType(bufferType);
VertexBuffer vb = readAccessorData(entry.getValue().getAsInt(),
new VertexBufferPopulator(type));
if (vb != null) {
morphTarget.setBuffer(type, (FloatBuffer) vb.getData());
}
}
mesh.addMorphTarget(morphTarget);
}
}
// Read mesh extras
mesh = customContentManager.readExtensionAndExtras("primitive", meshObject, mesh);
Geometry geom = new Geometry(null, mesh);
Integer materialIndex = getAsInteger(meshObject, "material");
if (materialIndex == null) {
geom.setMaterial(defaultMat);
} else {
useNormalsFlag = false;
geom.setMaterial(readMaterial(materialIndex));
if (geom.getMaterial().getAdditionalRenderState().getBlendMode()
== RenderState.BlendMode.Alpha) {
// Alpha blending is enabled for this material. Let's place the geom in the transparent bucket.
geom.setQueueBucket(RenderQueue.Bucket.Transparent);
}
if (useNormalsFlag && mesh.getBuffer(VertexBuffer.Type.Tangent) == null) {
// No tangent buffer, but there is a normal map, we have to generate them using MiiktSpace
MikktspaceTangentGenerator.generate(geom);
}
}
if (name != null) {
geom.setName(name + (primitives.size() > 1 ? ("_" + index) : ""));
}
geom.updateModelBound();
geomArray[index] = geom;
index++;
}
geomArray = customContentManager.readExtensionAndExtras("mesh", meshData, geomArray);
addToCache("meshes", meshIndex, geomArray, meshes.size());
return geomArray;
}
private SkinBuffers getSkinBuffers(String bufferType) {
int bufIndex = getIndex(bufferType);
SkinBuffers buffs = skinBuffers.get(bufIndex);
if (buffs == null) {
buffs = new SkinBuffers();
skinBuffers.put(bufIndex, buffs);
}
return buffs;
}
private R readAccessorData(int accessorIndex, Populator populator) throws IOException {
assertNotNull(accessors, "No accessor attribute in the gltf file");
JsonObject accessor = accessors.get(accessorIndex).getAsJsonObject();
Integer bufferViewIndex = getAsInteger(accessor, "bufferView");
int byteOffset = getAsInteger(accessor, "byteOffset", 0);
Integer componentType = getAsInteger(accessor, "componentType");
assertNotNull(componentType, "No component type defined for accessor " + accessorIndex);
Integer count = getAsInteger(accessor, "count");
assertNotNull(count, "No count attribute defined for accessor " + accessorIndex);
String type = getAsString(accessor, "type");
assertNotNull(type, "No type attribute defined for accessor " + accessorIndex);
boolean normalized = getAsBoolean(accessor, "normalized", false);
// TODO min / max...don't know what to do about them.
// TODO sparse
R data = populator.populate(bufferViewIndex, componentType, type, count, byteOffset, normalized);
data = customContentManager.readExtensionAndExtras("accessor", accessor, data);
return data;
}
public Object readBuffer(Integer bufferViewIndex, int byteOffset, int count, Object store,
int numComponents, VertexBuffer.Format format) throws IOException {
JsonObject bufferView = bufferViews.get(bufferViewIndex).getAsJsonObject();
Integer bufferIndex = getAsInteger(bufferView, "buffer");
assertNotNull(bufferIndex, "No buffer defined for bufferView " + bufferViewIndex);
int bvByteOffset = getAsInteger(bufferView, "byteOffset", 0);
Integer byteLength = getAsInteger(bufferView, "byteLength");
assertNotNull(byteLength, "No byte length defined for bufferView " + bufferViewIndex);
int byteStride = getAsInteger(bufferView, "byteStride", 0);
// target defines ELEMENT_ARRAY_BUFFER or ARRAY_BUFFER,
// but we already know that since we know we load the index buffer or any other...
// Not sure it's useful for us, but I guess it's useful when you map data directly to the GPU.
// int target = getAsInteger(bufferView, "target", 0);
byte[] data = readData(bufferIndex);
data = customContentManager.readExtensionAndExtras("bufferView", bufferView, data);
if (store == null) {
store = new byte[byteLength];
}
if (count == -1) {
count = byteLength;
}
populateBuffer(store, data, count, byteOffset + bvByteOffset, byteStride, numComponents, format);
return store;
}
public byte[] readData(int bufferIndex) throws IOException {
assertNotNull(buffers, "No buffer defined");
JsonObject buffer = buffers.get(bufferIndex).getAsJsonObject();
String uri = getAsString(buffer, "uri");
Integer bufferLength = getAsInteger(buffer, "byteLength");
assertNotNull(bufferLength, "No byteLength defined for buffer " + bufferIndex);
byte[] data = (byte[]) fetchFromCache("buffers", bufferIndex, Object.class);
if (data != null) {
return data;
}
data = getBytes(bufferIndex, uri, bufferLength);
data = customContentManager.readExtensionAndExtras("buffer", buffer, data);
addToCache("buffers", bufferIndex, data, buffers.size());
return data;
}
protected byte[] getBytes(int bufferIndex, String uri, Integer bufferLength) throws IOException {
byte[] data;
if (uri != null) {
if (uri.startsWith("data:")) {
// base 64 embed data
data = Base64.getDecoder().decode(uri.substring(uri.indexOf(",") + 1));
} else {
// external file let's load it
String decoded = decodeUri(uri);
if (!decoded.endsWith(".bin")) {
throw new AssetLoadException(
"Cannot load " + decoded + ", a .bin extension is required.");
}
BinDataKey key = new BinDataKey(info.getKey().getFolder() + decoded);
InputStream input = (InputStream) info.getManager().loadAsset(key);
data = new byte[bufferLength];
DataInputStream dataStream = new DataInputStream(input);
dataStream.readFully(data);
dataStream.close();
}
} else {
// no URI this should not happen in a gltf file, only in glb files.
throw new AssetLoadException("Buffer " + bufferIndex + " has no uri");
}
return data;
}
public Material readMaterial(int materialIndex) throws IOException {
assertNotNull(materials, "There is no material defined yet a mesh references one");
JsonObject matData = materials.get(materialIndex).getAsJsonObject();
JsonObject pbrMat = matData.getAsJsonObject("pbrMetallicRoughness");
MaterialAdapter adapter = null;
if (pbrMat != null) {
adapter = getAdapterForMaterial(info, "pbrMetallicRoughness");
if (adapter == null) {
adapter = defaultMaterialAdapters.get("pbrMetallicRoughness");
}
adapter.init(info.getManager());
}
adapter = customContentManager.readExtensionAndExtras("material", matData, adapter);
if (adapter == null) {
logger.log(Level.WARNING,
"Couldn't find any matching material definition for material " + materialIndex);
adapter = defaultMaterialAdapters.get("pbrMetallicRoughness");
adapter.init(info.getManager());
setDefaultParams(adapter.getMaterial());
}
Integer metallicRoughnessIndex = null;
if (pbrMat != null) {
adapter.setParam("baseColorFactor", getAsColor(pbrMat, "baseColorFactor", ColorRGBA.White));
adapter.setParam("metallicFactor", getAsFloat(pbrMat, "metallicFactor", 1f));
adapter.setParam("roughnessFactor", getAsFloat(pbrMat, "roughnessFactor", 1f));
adapter.setParam("baseColorTexture", readTexture(pbrMat.getAsJsonObject("baseColorTexture")));
adapter.setParam("metallicRoughnessTexture",
readTexture(pbrMat.getAsJsonObject("metallicRoughnessTexture")));
JsonObject metallicRoughnessJson = pbrMat.getAsJsonObject("metallicRoughnessTexture");
metallicRoughnessIndex = metallicRoughnessJson != null ? getAsInteger(metallicRoughnessJson, "index") : null;
}
adapter.getMaterial().setName(getAsString(matData, "name"));
adapter.setParam("emissiveFactor", getAsColor(matData, "emissiveFactor", ColorRGBA.Black));
String alphaMode = getAsString(matData, "alphaMode");
adapter.setParam("alphaMode", alphaMode);
if (alphaMode != null && alphaMode.equals("MASK")) {
adapter.setParam("alphaCutoff", getAsFloat(matData, "alphaCutoff"));
}
adapter.setParam("doubleSided", getAsBoolean(matData, "doubleSided"));
Texture2D normal = readTexture(matData.getAsJsonObject("normalTexture"));
adapter.setParam("normalTexture", normal);
if (normal != null) {
useNormalsFlag = true;
}
JsonObject occlusionJson = matData.getAsJsonObject("occlusionTexture");
Integer occlusionIndex = occlusionJson != null ? getAsInteger(occlusionJson, "index") : null;
if (occlusionIndex != null && occlusionIndex.equals(metallicRoughnessIndex)) {
adapter.getMaterial().setBoolean("AoPackedInMRMap", true);
} else {
adapter.setParam("occlusionTexture", readTexture(matData.getAsJsonObject("occlusionTexture")));
}
adapter.setParam("emissiveTexture", readTexture(matData.getAsJsonObject("emissiveTexture")));
return adapter.getMaterial();
}
public void readCameras() throws IOException {
if (cameras == null) {
return;
}
for (int i = 0; i < cameras.size(); i++) {
// Can't access resolution here... actually it's a shame we can't access settings from anywhere.
// users will have to call resize on the camera.
Camera cam = new Camera(1, 1);
JsonObject camObj = cameras.get(i).getAsJsonObject();
String type = getAsString(camObj, "type");
assertNotNull(type, "No type defined for camera");
JsonObject camData = camObj.getAsJsonObject(type);
if (type.equals("perspective")) {
float aspectRatio = getAsFloat(camData, "aspectRation", 1f);
Float yfov = getAsFloat(camData, "yfov");
assertNotNull(yfov, "No yfov for perspective camera");
Float zNear = getAsFloat(camData, "znear");
assertNotNull(zNear, "No znear for perspective camera");
Float zFar = getAsFloat(camData, "zfar", zNear * 1000f);
cam.setFrustumPerspective(yfov * FastMath.RAD_TO_DEG, aspectRatio, zNear, zFar);
cam = customContentManager.readExtensionAndExtras("camera.perspective", camData, cam);
} else {
Float xmag = getAsFloat(camData, "xmag");
assertNotNull(xmag, "No xmag for orthographic camera");
Float ymag = getAsFloat(camData, "ymag");
assertNotNull(ymag, "No ymag for orthographic camera");
Float zNear = getAsFloat(camData, "znear");
assertNotNull(zNear, "No znear for orthographic camera");
Float zFar = getAsFloat(camData, "zfar", zNear * 1000f);
assertNotNull(zFar, "No zfar for orthographic camera");
cam.setParallelProjection(true);
cam.setFrustum(zNear, zFar, -xmag, xmag, ymag, -ymag);
cam = customContentManager.readExtensionAndExtras("camera.orthographic", camData, cam);
}
cam = customContentManager.readExtensionAndExtras("camera", camObj, cam);
addToCache("cameras", i, cam, cameras.size());
}
}
public Texture2D readTexture(JsonObject texture) throws IOException {
return readTexture(texture, false);
}
public Texture2D readTexture(JsonObject texture, boolean flip) throws IOException {
if (texture == null) {
return null;
}
Integer textureIndex = getAsInteger(texture, "index");
assertNotNull(textureIndex, "Texture has no index");
assertNotNull(textures, "There are no textures, yet one is referenced by a material");
JsonObject textureData = textures.get(textureIndex).getAsJsonObject();
Integer sourceIndex = getAsInteger(textureData, "source");
Integer samplerIndex = getAsInteger(textureData, "sampler");
Texture2D texture2d = readImage(sourceIndex, flip);
if (samplerIndex != null) {
texture2d = readSampler(samplerIndex, texture2d);
} else {
texture2d.setWrap(Texture.WrapMode.Repeat);
}
texture2d = customContentManager.readExtensionAndExtras("texture", texture, texture2d);
return texture2d;
}
public Texture2D readImage(int sourceIndex, boolean flip) throws IOException {
if (images == null) {
throw new AssetLoadException("No image defined");
}
JsonObject image = images.get(sourceIndex).getAsJsonObject();
String uri = getAsString(image, "uri");
Integer bufferView = getAsInteger(image, "bufferView");
String mimeType = getAsString(image, "mimeType");
Texture2D result;
if (uri == null) {
assertNotNull(bufferView, "Image " + sourceIndex + " should either have an uri or a bufferView");
assertNotNull(mimeType, "Image " + sourceIndex + " should have a mimeType");
byte[] data = (byte[]) readBuffer(bufferView, 0, -1, null, 1, VertexBuffer.Format.Byte);
String extension = mimeType.split("/")[1];
TextureKey key = new TextureKey("image" + sourceIndex + "." + extension, flip);
result = (Texture2D) info.getManager().loadAssetFromStream(key, new ByteArrayInputStream(data));
} else if (uri.startsWith("data:")) {
// base64 encoded image
String[] uriInfo = uri.split(",");
byte[] data = Base64.getDecoder().decode(uriInfo[1]);
String headerInfo = uriInfo[0].split(";")[0];
String extension = headerInfo.split("/")[1];
TextureKey key = new TextureKey("image" + sourceIndex + "." + extension, flip);
result = (Texture2D) info.getManager().loadAssetFromStream(key, new ByteArrayInputStream(data));
} else {
// external file image
String decoded = decodeUri(uri);
TextureKey key = new TextureKey(info.getKey().getFolder() + decoded, flip);
Texture tex = info.getManager().loadTexture(key);
result = (Texture2D) tex;
}
return result;
}
public void readAnimation(int animationIndex) throws IOException {
JsonObject animation = animations.get(animationIndex).getAsJsonObject();
JsonArray channels = animation.getAsJsonArray("channels");
JsonArray samplers = animation.getAsJsonArray("samplers");
String name = getAsString(animation, "name");
assertNotNull(channels, "No channels for animation " + name);
assertNotNull(samplers, "No samplers for animation " + name);
// temp data storage of track data
TrackData[] tracks = new TrackData[nodes.size()];
boolean hasMorphTrack = false;
for (JsonElement channel : channels) {
JsonObject target = channel.getAsJsonObject().getAsJsonObject("target");
Integer targetNode = getAsInteger(target, "node");
String targetPath = getAsString(target, "path");
if (targetNode == null) {
// no target node for the channel, specs say to ignore the channel.
continue;
}
assertNotNull(targetPath, "No target path for channel");
//
// if (targetPath.equals("weights")) {
// // Morph animation, not implemented in JME, let's warn the user and skip the channel
// logger.log(Level.WARNING,
// "Morph animation is not supported by JME yet, skipping animation track");
// continue;
// }
TrackData trackData = tracks[targetNode];
if (trackData == null) {
trackData = new TrackData();
tracks[targetNode] = trackData;
}
Integer samplerIndex = getAsInteger(channel.getAsJsonObject(), "sampler");
assertNotNull(samplerIndex, "No animation sampler provided for channel");
JsonObject sampler = samplers.get(samplerIndex).getAsJsonObject();
Integer timeIndex = getAsInteger(sampler, "input");
assertNotNull(timeIndex, "No input accessor Provided for animation sampler");
Integer dataIndex = getAsInteger(sampler, "output");
assertNotNull(dataIndex, "No output accessor Provided for animation sampler");
String interpolation = getAsString(sampler, "interpolation");
if (interpolation == null || !interpolation.equals("LINEAR")) {
// JME anim system only supports Linear interpolation (will be possible with monkanim though)
// TODO rework this once monkanim is core,
// or allow a hook for animation loading to fit custom animation systems
logger.log(Level.WARNING, "JME only supports linear interpolation for animations");
}
trackData = customContentManager.readExtensionAndExtras("animation.sampler", sampler, trackData);
float[] times = fetchFromCache("accessors", timeIndex, float[].class);
if (times == null) {
times = readAccessorData(timeIndex, floatArrayPopulator);
addToCache("accessors", timeIndex, times, accessors.size());
}
if (targetPath.equals("translation")) {
trackData.timeArrays.add(new TrackData.TimeData(times, TrackData.Type.Translation));
Vector3f[] translations = readAccessorData(dataIndex, vector3fArrayPopulator);
trackData.translations = translations;
} else if (targetPath.equals("scale")) {
trackData.timeArrays.add(new TrackData.TimeData(times, TrackData.Type.Scale));
Vector3f[] scales = readAccessorData(dataIndex, vector3fArrayPopulator);
trackData.scales = scales;
} else if (targetPath.equals("rotation")) {
trackData.timeArrays.add(new TrackData.TimeData(times, TrackData.Type.Rotation));
Quaternion[] rotations = readAccessorData(dataIndex, quaternionArrayPopulator);
trackData.rotations = rotations;
} else {
trackData.timeArrays.add(new TrackData.TimeData(times, TrackData.Type.Morph));
float[] weights = readAccessorData(dataIndex, floatArrayPopulator);
trackData.weights = weights;
hasMorphTrack = true;
}
tracks[targetNode] = customContentManager.readExtensionAndExtras("channel", channel, trackData);
}
if (name == null) {
name = "anim_" + animationIndex;
}
List spatials = new ArrayList<>();
AnimClip anim = new AnimClip(name);
List aTracks = new ArrayList<>();
int skinIndex = -1;
List usedJoints = new ArrayList<>();
for (int i = 0; i < tracks.length; i++) {
TrackData trackData = tracks[i];
if (trackData == null || trackData.timeArrays.isEmpty()) {
continue;
}
trackData.update();
Object node = fetchFromCache("nodes", i, Object.class);
if (node instanceof Spatial) {
Spatial s = (Spatial) node;
spatials.add(s);
if (trackData.rotations != null || trackData.translations != null
|| trackData.scales != null) {
TransformTrack track = new TransformTrack(s, trackData.times,
trackData.translations, trackData.rotations, trackData.scales);
aTracks.add(track);
}
if (trackData.weights != null && s instanceof Geometry) {
Geometry g = (Geometry) s;
int nbMorph = g.getMesh().getMorphTargets().length;
// for (int k = 0; k < trackData.weights.length; k++) {
// System.err.print(trackData.weights[k] + ",");
// if(k % nbMorph == 0 && k!=0){
// System.err.println(" ");
// }
// }
MorphTrack track = new MorphTrack(g, trackData.times, trackData.weights, nbMorph);
aTracks.add(track);
}
} else if (node instanceof JointWrapper) {
JointWrapper jw = (JointWrapper) node;
usedJoints.add(jw.joint);
if (skinIndex == -1) {
skinIndex = jw.skinIndex;
} else {
// Check if all joints affected by this animation are from the same skin,
// the track will be skipped.
if (skinIndex != jw.skinIndex) {
logger.log(Level.WARNING, "Animation " + animationIndex + " (" + name
+ ") applies to joints that are not from the same skin: skin "
+ skinIndex + ", joint " + jw.joint.getName()
+ " from skin " + jw.skinIndex);
continue;
}
}
TransformTrack track = new TransformTrack(jw.joint, trackData.times,
trackData.translations, trackData.rotations, trackData.scales);
aTracks.add(track);
}
}
// Check each bone to see if their local pose is different from their bind pose.
// If it is, we ensure that the bone has an animation track,
// else JME way of applying anim transforms will apply the bind pose to those bones,
// instead of the local pose that is supposed to be the default
if (skinIndex != -1) {
SkinData skin = fetchFromCache("skins", skinIndex, SkinData.class);
for (Joint joint : skin.joints) {
if (!usedJoints.contains(joint)) {
// create a track
float[] times = new float[]{0};
Vector3f[] translations = new Vector3f[]{joint.getLocalTranslation()};
Quaternion[] rotations = new Quaternion[]{joint.getLocalRotation()};
Vector3f[] scales = new Vector3f[]{joint.getLocalScale()};
TransformTrack track = new TransformTrack(joint, times, translations, rotations, scales);
aTracks.add(track);
}
}
}
anim.setTracks(aTracks.toArray(new AnimTrack[aTracks.size()]));
anim = customContentManager.readExtensionAndExtras("animations", animation, anim);
if (skinIndex != -1) {
// we have an armature animation.
SkinData skin = fetchFromCache("skins", skinIndex, SkinData.class);
skin.animComposer.addAnimClip(anim);
}
if (!spatials.isEmpty()) {
if (skinIndex != -1) {
// there are some spatial or morph tracks in this bone animation... or the other way around.
// Let's add the spatials in the skinnedSpatials.
SkinData skin = fetchFromCache("skins", skinIndex, SkinData.class);
List spat = skinnedSpatials.get(skin);
spat.addAll(spatials);
// the animControl will be added in the setupControls();
if (hasMorphTrack && skin.morphControl == null) {
skin.morphControl = new MorphControl();
}
} else {
// Spatial animation
Spatial spatial = null;
if (spatials.size() == 1) {
spatial = spatials.get(0);
} else {
spatial = findCommonAncestor(spatials);
}
AnimComposer composer = spatial.getControl(AnimComposer.class);
if (composer == null) {
composer = new AnimComposer();
spatial.addControl(composer);
}
composer.addAnimClip(anim);
if (hasMorphTrack && spatial.getControl(MorphControl.class) == null) {
spatial.addControl(new MorphControl());
}
}
}
}
public Texture2D readSampler(int samplerIndex, Texture2D texture) throws IOException {
if (samplers == null) {
throw new AssetLoadException("No samplers defined");
}
JsonObject sampler = samplers.get(samplerIndex).getAsJsonObject();
Texture.MagFilter magFilter = getMagFilter(getAsInteger(sampler, "magFilter"));
Texture.MinFilter minFilter = getMinFilter(getAsInteger(sampler, "minFilter"));
Texture.WrapMode wrapS = getWrapMode(getAsInteger(sampler, "wrapS"));
Texture.WrapMode wrapT = getWrapMode(getAsInteger(sampler, "wrapT"));
if (magFilter != null) {
texture.setMagFilter(magFilter);
}
if (minFilter != null) {
texture.setMinFilter(minFilter);
}
texture.setWrap(Texture.WrapAxis.S, wrapS);
texture.setWrap(Texture.WrapAxis.T, wrapT);
texture = customContentManager.readExtensionAndExtras("texture.sampler", sampler, texture);
return texture;
}
public void readSkins() throws IOException {
if (skins == null) {
// no skins, no bone animation.
return;
}
List allJoints = new ArrayList<>();
for (int index = 0; index < skins.size(); index++) {
JsonObject skin = skins.get(index).getAsJsonObject();
// Note that the "skeleton" index is intentionally ignored.
// It's not mandatory and exporters tends to mix up how it should be used
// because the specs are not clear.
// Anyway we have other means to detect both armature structures and root bones.
JsonArray jsonJoints = skin.getAsJsonArray("joints");
assertNotNull(jsonJoints, "No joints defined for skin");
int idx = allJoints.indexOf(jsonJoints);
if (idx >= 0) {
// skin already exists let's just set it in the cache
SkinData sd = fetchFromCache("skins", idx, SkinData.class);
addToCache("skins", index, sd, nodes.size());
continue;
} else {
allJoints.add(jsonJoints);
}
// These inverse bind matrices, once inverted again,
// will give us the real bind pose of the bones (in model space),
// since the skeleton in not guaranteed to be exported in bind pose.
Integer matricesIndex = getAsInteger(skin, "inverseBindMatrices");
Matrix4f[] inverseBindMatrices = null;
if (matricesIndex != null) {
inverseBindMatrices = readAccessorData(matricesIndex, matrix4fArrayPopulator);
} else {
inverseBindMatrices = new Matrix4f[jsonJoints.size()];
for (int i = 0; i < inverseBindMatrices.length; i++) {
inverseBindMatrices[i] = new Matrix4f();
}
}
Joint[] joints = new Joint[jsonJoints.size()];
for (int i = 0; i < jsonJoints.size(); i++) {
int boneIndex = jsonJoints.get(i).getAsInt();
Matrix4f inverseModelBindMatrix = inverseBindMatrices[i];
joints[i] = readNodeAsBone(boneIndex, i, index, inverseModelBindMatrix);
}
for (int i = 0; i < jsonJoints.size(); i++) {
findChildren(jsonJoints.get(i).getAsInt());
}
Armature armature = new Armature(joints);
armature = customContentManager.readExtensionAndExtras("skin", skin, armature);
SkinData skinData = new SkinData();
skinData.joints = joints;
skinData.skinningControl = new SkinningControl(armature);
skinData.animComposer = new AnimComposer();
addToCache("skins", index, skinData, nodes.size());
skinnedSpatials.put(skinData, new ArrayList());
armature.update();
armature.saveInitialPose();
}
}
public Joint readNodeAsBone(int nodeIndex, int jointIndex, int skinIndex, Matrix4f inverseModelBindMatrix)
throws IOException {
JointWrapper jointWrapper = fetchFromCache("nodes", nodeIndex, JointWrapper.class);
if (jointWrapper != null) {
return jointWrapper.joint;
}
JsonObject nodeData = nodes.get(nodeIndex).getAsJsonObject();
String name = getAsString(nodeData, "name");
if (name == null) {
name = "Joint_" + nodeIndex;
}
Joint joint = new Joint(name);
Transform boneTransforms = null;
boneTransforms = readTransforms(nodeData);
joint.setLocalTransform(boneTransforms);
joint.setInverseModelBindMatrix(inverseModelBindMatrix);
addToCache("nodes", nodeIndex, new JointWrapper(joint, jointIndex, skinIndex), nodes.size());
return joint;
}
private void findChildren(int nodeIndex) throws IOException {
JointWrapper jw = fetchFromCache("nodes", nodeIndex, JointWrapper.class);
if (jw == null) {
logger.log(Level.WARNING,
"No JointWrapper found for nodeIndex={0}.", nodeIndex);
return;
}
JsonObject nodeData = nodes.get(nodeIndex).getAsJsonObject();
JsonArray children = nodeData.getAsJsonArray("children");
if (children != null) {
for (JsonElement child : children) {
int childIndex = child.getAsInt();
if (jw.children.contains(childIndex)) {
// bone already has the child in its children
continue;
}
JointWrapper cjw = fetchFromCache("nodes", childIndex, JointWrapper.class);
if (cjw != null) {
jw.joint.addChild(cjw.joint);
jw.children.add(childIndex);
} else {
// The child might be a Node
// Creating a dummy node to read the subgraph
Node n = new Node();
readChild(n, child);
Spatial s = n.getChild(0);
// removing the spatial from the dummy node,
// it will be attached to the attachment node of the bone
s.removeFromParent();
jw.attachedSpatial = s;
}
}
}
}
private void setupControls() {
for (SkinData skinData : skinnedSpatials.keySet()) {
List spatials = skinnedSpatials.get(skinData);
if (spatials.isEmpty()) {
continue;
}
Spatial spatial = skinData.parent;
if (spatials.size() >= 1) {
spatial = findCommonAncestor(spatials);
}
// if (spatial != skinData.parent) {
// skinData.rootBoneTransformOffset = spatial.getWorldTransform().invert();
// if (skinData.parent != null) {
// skinData.rootBoneTransformOffset.combineWithParent(skinData.parent.getWorldTransform());
// }
// }
if (skinData.animComposer != null && skinData.animComposer.getSpatial() == null) {
spatial.addControl(skinData.animComposer);
}
spatial.addControl(skinData.skinningControl);
if (skinData.morphControl != null) {
spatial.addControl(skinData.morphControl);
}
}
for (int i = 0; i < nodes.size(); i++) {
JointWrapper bw = fetchFromCache("nodes", i, JointWrapper.class);
if (bw == null || bw.attachedSpatial == null) {
continue;
}
String jointName = bw.joint.getName();
SkinData skinData = fetchFromCache("skins", bw.skinIndex, SkinData.class);
SkinningControl skinControl = skinData.skinningControl;
if (skinControl.getSpatial() == null) {
logger.log(Level.WARNING,
"No skinned Spatial for joint \"{0}\" -- will skin the model's root node!",
jointName);
rootNode.addControl(skinControl);
}
skinControl.getAttachmentsNode(jointName).attachChild(bw.attachedSpatial);
}
}
private String readMeshName(int meshIndex) {
JsonObject meshData = meshes.get(meshIndex).getAsJsonObject();
return getAsString(meshData, "name");
}
public T fetchFromCache(String name, int index, Class type) {
Object[] data = dataCache.get(name);
if (data == null) {
return null;
}
try {
T ret = type.cast(data[index]);
return ret;
} catch (ClassCastException e) {
return null;
}
}
public void addToCache(String name, int index, Object object, int maxLength) {
Object[] data = dataCache.get(name);
if (data == null) {
data = new Object[maxLength];
dataCache.put(name, data);
}
data[index] = object;
}
public AssetInfo getInfo() {
return info;
}
public JsonObject getDocRoot() {
return docRoot;
}
public Node getRootNode() {
return rootNode;
}
private String decodeUri(String uri) {
try {
return URLDecoder.decode(uri, "UTF-8");
} catch (UnsupportedEncodingException e) {
return uri; // This would mean that UTF-8 is unsupported on the platform.
}
}
public static class WeightData {
float value;
short index;
int componentSize;
public WeightData(float value, short index, int componentSize) {
this.value = value;
this.index = index;
this.componentSize = componentSize;
}
}
private class JointWrapper {
Joint joint;
int jointIndex;
int skinIndex;
boolean isRoot = false;
Spatial attachedSpatial;
List children = new ArrayList<>();
public JointWrapper(Joint joint, int jointIndex, int skinIndex) {
this.joint = joint;
this.jointIndex = jointIndex;
this.skinIndex = skinIndex;
}
}
private class SkinData {
SkinningControl skinningControl;
MorphControl morphControl;
AnimComposer animComposer;
Spatial spatial;
Spatial parent;
Transform rootBoneTransformOffset;
Joint[] joints;
boolean used = false;
}
public static class SkinBuffers {
short[] joints;
float[] weights;
int componentSize;
public SkinBuffers(short[] joints, int componentSize) {
this.joints = joints;
this.componentSize = componentSize;
}
public SkinBuffers() {}
}
private interface Populator {
T populate(Integer bufferViewIndex, int componentType, String type, int count, int byteOffset,
boolean normalized) throws IOException;
}
private class VertexBufferPopulator implements Populator {
VertexBuffer.Type bufferType;
public VertexBufferPopulator(VertexBuffer.Type bufferType) {
this.bufferType = bufferType;
}
@Override
public VertexBuffer populate(Integer bufferViewIndex, int componentType, String type, int count,
int byteOffset, boolean normalized) throws IOException {
if (bufferType == null) {
logger.log(Level.WARNING, "could not assign data to any VertexBuffer type for buffer view {0}", bufferViewIndex);
return null;
}
VertexBuffer vb = new VertexBuffer(bufferType);
VertexBuffer.Format format = getVertexBufferFormat(componentType);
VertexBuffer.Format originalFormat = format;
if (normalized) {
// Some float data can be packed into short buffers,
// "normalized" means they have to be unpacked.
// In that case the buffer is a FloatBuffer
format = VertexBuffer.Format.Float;
}
int numComponents = getNumberOfComponents(type);
Buffer buff = VertexBuffer.createBuffer(format, numComponents, count);
int bufferSize = numComponents * count;
if (bufferViewIndex == null) {
// no referenced buffer, specs says to pad the buffer with zeros.
padBuffer(buff, bufferSize);
} else {
readBuffer(bufferViewIndex, byteOffset, count, buff, numComponents, originalFormat);
}
if (bufferType == VertexBuffer.Type.Index) {
numComponents = 3;
}
vb.setupData(VertexBuffer.Usage.Dynamic, numComponents, format, buff);
return vb;
}
}
private class FloatArrayPopulator implements Populator {
@Override
public float[] populate(Integer bufferViewIndex, int componentType, String type, int count,
int byteOffset, boolean normalized) throws IOException {
int numComponents = getNumberOfComponents(type);
int dataSize = numComponents * count;
float[] data = new float[dataSize];
if (bufferViewIndex == null) {
// no referenced buffer, specs says to pad the data with zeros.
padBuffer(data, dataSize);
} else {
readBuffer(bufferViewIndex, byteOffset, count, data, numComponents,
getVertexBufferFormat(componentType));
}
return data;
}
}
//
// private class FloatGridPopulator implements Populator {
//
// @Override
// public float[][] populate(Integer bufferViewIndex, int componentType, String type, int count,
// int byteOffset, boolean normalized) throws IOException {
//
// int numComponents = getNumberOfComponents(type);
// int dataSize = numComponents * count;
// float[] data = new float[dataSize];
//
// if (bufferViewIndex == null) {
// // no referenced buffer, specs says to pad the data with zeros.
// padBuffer(data, dataSize);
// } else {
// readBuffer(bufferViewIndex, byteOffset, count, data, numComponents,
// getVertexBufferFormat(componentType));
// }
//
// return data;
// }
//
// }
private class Vector3fArrayPopulator implements Populator {
@Override
public Vector3f[] populate(Integer bufferViewIndex, int componentType, String type, int count,
int byteOffset, boolean normalized) throws IOException {
int numComponents = getNumberOfComponents(type);
int dataSize = numComponents * count;
Vector3f[] data = new Vector3f[count];
if (bufferViewIndex == null) {
// no referenced buffer, specs says to pad the data with zeros.
padBuffer(data, dataSize);
} else {
readBuffer(bufferViewIndex, byteOffset, count, data, numComponents,
getVertexBufferFormat(componentType));
}
return data;
}
}
private class QuaternionArrayPopulator implements Populator {
@Override
public Quaternion[] populate(Integer bufferViewIndex, int componentType, String type, int count,
int byteOffset, boolean normalized) throws IOException {
int numComponents = getNumberOfComponents(type);
int dataSize = numComponents * count;
Quaternion[] data = new Quaternion[count];
if (bufferViewIndex == null) {
// no referenced buffer, specs says to pad the data with zeros.
padBuffer(data, dataSize);
} else {
readBuffer(bufferViewIndex, byteOffset, count, data, numComponents,
getVertexBufferFormat(componentType));
}
return data;
}
}
private class Matrix4fArrayPopulator implements Populator {
@Override
public Matrix4f[] populate(Integer bufferViewIndex, int componentType, String type, int count,
int byteOffset, boolean normalized) throws IOException {
int numComponents = getNumberOfComponents(type);
int dataSize = numComponents * count;
Matrix4f[] data = new Matrix4f[count];
if (bufferViewIndex == null) {
// no referenced buffer, specs says to pad the data with zeros.
padBuffer(data, dataSize);
} else {
readBuffer(bufferViewIndex, byteOffset, count, data, numComponents,
getVertexBufferFormat(componentType));
}
return data;
}
}
private class JointArrayPopulator implements Populator {
@Override
public SkinBuffers populate(Integer bufferViewIndex, int componentType, String type, int count,
int byteOffset, boolean normalized) throws IOException {
int numComponents = getNumberOfComponents(type);
// can be bytes or shorts.
VertexBuffer.Format format = VertexBuffer.Format.Byte;
if (componentType == 5123) {
format = VertexBuffer.Format.Short;
}
int dataSize = numComponents * count;
short[] data = new short[dataSize];
if (bufferViewIndex == null) {
// no referenced buffer, specs says to pad the data with zeros.
padBuffer(data, dataSize);
} else {
readBuffer(bufferViewIndex, byteOffset, count, data, numComponents, format);
}
return new SkinBuffers(data, format.getComponentSize());
}
}
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