FiE-Game/Assets/Spine/SpineCSharp/SkeletonBinary.cs

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2023-07-24 21:52:50 +02:00
/******************************************************************************
* Spine Runtimes Software License v2.5
*
* Copyright (c) 2013-2016, Esoteric Software
* All rights reserved.
*
* You are granted a perpetual, non-exclusive, non-sublicensable, and
* non-transferable license to use, install, execute, and perform the Spine
* Runtimes software and derivative works solely for personal or internal
* use. Without the written permission of Esoteric Software (see Section 2 of
* the Spine Software License Agreement), you may not (a) modify, translate,
* adapt, or develop new applications using the Spine Runtimes or otherwise
* create derivative works or improvements of the Spine Runtimes or (b) remove,
* delete, alter, or obscure any trademarks or any copyright, trademark, patent,
* or other intellectual property or proprietary rights notices on or in the
* Software, including any copy thereof. Redistributions in binary or source
* form must include this license and terms.
*
* THIS SOFTWARE IS PROVIDED BY ESOTERIC SOFTWARE "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 ESOTERIC SOFTWARE BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES, BUSINESS INTERRUPTION, OR LOSS OF
* USE, DATA, OR PROFITS) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER
* IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*****************************************************************************/
#if (UNITY_5 || UNITY_5_3_OR_NEWER || UNITY_WSA || UNITY_WP8 || UNITY_WP8_1)
#define IS_UNITY
#endif
using System;
using System.IO;
using System.Collections.Generic;
#if WINDOWS_STOREAPP
using System.Threading.Tasks;
using Windows.Storage;
#endif
namespace Spine {
public class SkeletonBinary {
public const int BONE_ROTATE = 0;
public const int BONE_TRANSLATE = 1;
public const int BONE_SCALE = 2;
public const int BONE_SHEAR = 3;
public const int SLOT_ATTACHMENT = 0;
public const int SLOT_COLOR = 1;
public const int SLOT_TWO_COLOR = 2;
public const int PATH_POSITION = 0;
public const int PATH_SPACING = 1;
public const int PATH_MIX = 2;
public const int CURVE_LINEAR = 0;
public const int CURVE_STEPPED = 1;
public const int CURVE_BEZIER = 2;
public float Scale { get; set; }
private AttachmentLoader attachmentLoader;
private byte[] buffer = new byte[32];
private List<SkeletonJson.LinkedMesh> linkedMeshes = new List<SkeletonJson.LinkedMesh>();
public SkeletonBinary (params Atlas[] atlasArray)
: this(new AtlasAttachmentLoader(atlasArray)) {
}
public SkeletonBinary (AttachmentLoader attachmentLoader) {
if (attachmentLoader == null) throw new ArgumentNullException("attachmentLoader");
this.attachmentLoader = attachmentLoader;
Scale = 1;
}
#if !ISUNITY && WINDOWS_STOREAPP
private async Task<SkeletonData> ReadFile(string path) {
var folder = Windows.ApplicationModel.Package.Current.InstalledLocation;
using (var input = new BufferedStream(await folder.GetFileAsync(path).AsTask().ConfigureAwait(false))) {
SkeletonData skeletonData = ReadSkeletonData(input);
skeletonData.Name = Path.GetFileNameWithoutExtension(path);
return skeletonData;
}
}
public SkeletonData ReadSkeletonData (String path) {
return this.ReadFile(path).Result;
}
#else
public SkeletonData ReadSkeletonData (String path) {
#if WINDOWS_PHONE
using (var input = new BufferedStream(Microsoft.Xna.Framework.TitleContainer.OpenStream(path))) {
#else
using (var input = new FileStream(path, FileMode.Open, FileAccess.Read, FileShare.Read)) {
#endif
SkeletonData skeletonData = ReadSkeletonData(input);
skeletonData.name = Path.GetFileNameWithoutExtension(path);
return skeletonData;
}
}
#endif // WINDOWS_STOREAPP
public static readonly TransformMode[] TransformModeValues = {
TransformMode.Normal,
TransformMode.OnlyTranslation,
TransformMode.NoRotationOrReflection,
TransformMode.NoScale,
TransformMode.NoScaleOrReflection
};
/// <summary>Returns the version string of binary skeleton data.</summary>
public static string GetVersionString (Stream input) {
if (input == null) throw new ArgumentNullException("input");
try {
// Hash.
int byteCount = ReadVarint(input, true);
if (byteCount > 1) input.Position += byteCount - 1;
// Version.
byteCount = ReadVarint(input, true);
if (byteCount > 1) {
byteCount--;
var buffer = new byte[byteCount];
ReadFully(input, buffer, 0, byteCount);
return System.Text.Encoding.UTF8.GetString(buffer, 0, byteCount);
}
throw new ArgumentException("Stream does not contain a valid binary Skeleton Data.", "input");
} catch (Exception e) {
throw new ArgumentException("Stream does not contain a valid binary Skeleton Data.\n" + e, "input");
}
}
public SkeletonData ReadSkeletonData (Stream input) {
if (input == null) throw new ArgumentNullException("input");
float scale = Scale;
var skeletonData = new SkeletonData();
skeletonData.hash = ReadString(input);
if (skeletonData.hash.Length == 0) skeletonData.hash = null;
skeletonData.version = ReadString(input);
if (skeletonData.version.Length == 0) skeletonData.version = null;
skeletonData.width = ReadFloat(input);
skeletonData.height = ReadFloat(input);
bool nonessential = ReadBoolean(input);
if (nonessential) {
skeletonData.fps = ReadFloat(input);
skeletonData.imagesPath = ReadString(input);
if (skeletonData.imagesPath.Length == 0) skeletonData.imagesPath = null;
}
// Bones.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
String name = ReadString(input);
BoneData parent = i == 0 ? null : skeletonData.bones.Items[ReadVarint(input, true)];
BoneData data = new BoneData(i, name, parent);
data.rotation = ReadFloat(input);
data.x = ReadFloat(input) * scale;
data.y = ReadFloat(input) * scale;
data.scaleX = ReadFloat(input);
data.scaleY = ReadFloat(input);
data.shearX = ReadFloat(input);
data.shearY = ReadFloat(input);
data.length = ReadFloat(input) * scale;
data.transformMode = TransformModeValues[ReadVarint(input, true)];
if (nonessential) ReadInt(input); // Skip bone color.
skeletonData.bones.Add(data);
}
// Slots.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
String slotName = ReadString(input);
BoneData boneData = skeletonData.bones.Items[ReadVarint(input, true)];
SlotData slotData = new SlotData(i, slotName, boneData);
int color = ReadInt(input);
slotData.r = ((color & 0xff000000) >> 24) / 255f;
slotData.g = ((color & 0x00ff0000) >> 16) / 255f;
slotData.b = ((color & 0x0000ff00) >> 8) / 255f;
slotData.a = ((color & 0x000000ff)) / 255f;
int darkColor = ReadInt(input); // 0x00rrggbb
if (darkColor != -1) {
slotData.hasSecondColor = true;
slotData.r2 = ((darkColor & 0x00ff0000) >> 16) / 255f;
slotData.g2 = ((darkColor & 0x0000ff00) >> 8) / 255f;
slotData.b2 = ((darkColor & 0x000000ff)) / 255f;
}
slotData.attachmentName = ReadString(input);
slotData.blendMode = (BlendMode)ReadVarint(input, true);
skeletonData.slots.Add(slotData);
}
// IK constraints.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
IkConstraintData data = new IkConstraintData(ReadString(input));
data.order = ReadVarint(input, true);
for (int ii = 0, nn = ReadVarint(input, true); ii < nn; ii++)
data.bones.Add(skeletonData.bones.Items[ReadVarint(input, true)]);
data.target = skeletonData.bones.Items[ReadVarint(input, true)];
data.mix = ReadFloat(input);
data.bendDirection = ReadSByte(input);
skeletonData.ikConstraints.Add(data);
}
// Transform constraints.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
TransformConstraintData data = new TransformConstraintData(ReadString(input));
data.order = ReadVarint(input, true);
for (int ii = 0, nn = ReadVarint(input, true); ii < nn; ii++)
data.bones.Add(skeletonData.bones.Items[ReadVarint(input, true)]);
data.target = skeletonData.bones.Items[ReadVarint(input, true)];
data.local = ReadBoolean(input);
data.relative = ReadBoolean(input);
data.offsetRotation = ReadFloat(input);
data.offsetX = ReadFloat(input) * scale;
data.offsetY = ReadFloat(input) * scale;
data.offsetScaleX = ReadFloat(input);
data.offsetScaleY = ReadFloat(input);
data.offsetShearY = ReadFloat(input);
data.rotateMix = ReadFloat(input);
data.translateMix = ReadFloat(input);
data.scaleMix = ReadFloat(input);
data.shearMix = ReadFloat(input);
skeletonData.transformConstraints.Add(data);
}
// Path constraints
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
PathConstraintData data = new PathConstraintData(ReadString(input));
data.order = ReadVarint(input, true);
for (int ii = 0, nn = ReadVarint(input, true); ii < nn; ii++)
data.bones.Add(skeletonData.bones.Items[ReadVarint(input, true)]);
data.target = skeletonData.slots.Items[ReadVarint(input, true)];
data.positionMode = (PositionMode)Enum.GetValues(typeof(PositionMode)).GetValue(ReadVarint(input, true));
data.spacingMode = (SpacingMode)Enum.GetValues(typeof(SpacingMode)).GetValue(ReadVarint(input, true));
data.rotateMode = (RotateMode)Enum.GetValues(typeof(RotateMode)).GetValue(ReadVarint(input, true));
data.offsetRotation = ReadFloat(input);
data.position = ReadFloat(input);
if (data.positionMode == PositionMode.Fixed) data.position *= scale;
data.spacing = ReadFloat(input);
if (data.spacingMode == SpacingMode.Length || data.spacingMode == SpacingMode.Fixed) data.spacing *= scale;
data.rotateMix = ReadFloat(input);
data.translateMix = ReadFloat(input);
skeletonData.pathConstraints.Add(data);
}
// Default skin.
Skin defaultSkin = ReadSkin(input, skeletonData, "default", nonessential);
if (defaultSkin != null) {
skeletonData.defaultSkin = defaultSkin;
skeletonData.skins.Add(defaultSkin);
}
// Skins.
for (int i = 0, n = ReadVarint(input, true); i < n; i++)
skeletonData.skins.Add(ReadSkin(input, skeletonData, ReadString(input), nonessential));
// Linked meshes.
for (int i = 0, n = linkedMeshes.Count; i < n; i++) {
SkeletonJson.LinkedMesh linkedMesh = linkedMeshes[i];
Skin skin = linkedMesh.skin == null ? skeletonData.DefaultSkin : skeletonData.FindSkin(linkedMesh.skin);
if (skin == null) throw new Exception("Skin not found: " + linkedMesh.skin);
Attachment parent = skin.GetAttachment(linkedMesh.slotIndex, linkedMesh.parent);
if (parent == null) throw new Exception("Parent mesh not found: " + linkedMesh.parent);
linkedMesh.mesh.ParentMesh = (MeshAttachment)parent;
linkedMesh.mesh.UpdateUVs();
}
linkedMeshes.Clear();
// Events.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
EventData data = new EventData(ReadString(input));
data.Int = ReadVarint(input, false);
data.Float = ReadFloat(input);
data.String = ReadString(input);
skeletonData.events.Add(data);
}
// Animations.
for (int i = 0, n = ReadVarint(input, true); i < n; i++)
ReadAnimation(ReadString(input), input, skeletonData);
skeletonData.bones.TrimExcess();
skeletonData.slots.TrimExcess();
skeletonData.skins.TrimExcess();
skeletonData.events.TrimExcess();
skeletonData.animations.TrimExcess();
skeletonData.ikConstraints.TrimExcess();
skeletonData.pathConstraints.TrimExcess();
return skeletonData;
}
/// <returns>May be null.</returns>
private Skin ReadSkin (Stream input, SkeletonData skeletonData, String skinName, bool nonessential) {
int slotCount = ReadVarint(input, true);
if (slotCount == 0) return null;
Skin skin = new Skin(skinName);
for (int i = 0; i < slotCount; i++) {
int slotIndex = ReadVarint(input, true);
for (int ii = 0, nn = ReadVarint(input, true); ii < nn; ii++) {
String name = ReadString(input);
Attachment attachment = ReadAttachment(input, skeletonData, skin, slotIndex, name, nonessential);
if (attachment != null) skin.AddAttachment(slotIndex, name, attachment);
}
}
return skin;
}
private Attachment ReadAttachment (Stream input, SkeletonData skeletonData, Skin skin, int slotIndex, String attachmentName, bool nonessential) {
float scale = Scale;
String name = ReadString(input);
if (name == null) name = attachmentName;
AttachmentType type = (AttachmentType)input.ReadByte();
switch (type) {
case AttachmentType.Region: {
String path = ReadString(input);
float rotation = ReadFloat(input);
float x = ReadFloat(input);
float y = ReadFloat(input);
float scaleX = ReadFloat(input);
float scaleY = ReadFloat(input);
float width = ReadFloat(input);
float height = ReadFloat(input);
int color = ReadInt(input);
if (path == null) path = name;
RegionAttachment region = attachmentLoader.NewRegionAttachment(skin, name, path);
if (region == null) return null;
region.Path = path;
region.x = x * scale;
region.y = y * scale;
region.scaleX = scaleX;
region.scaleY = scaleY;
region.rotation = rotation;
region.width = width * scale;
region.height = height * scale;
region.r = ((color & 0xff000000) >> 24) / 255f;
region.g = ((color & 0x00ff0000) >> 16) / 255f;
region.b = ((color & 0x0000ff00) >> 8) / 255f;
region.a = ((color & 0x000000ff)) / 255f;
region.UpdateOffset();
return region;
}
case AttachmentType.Boundingbox: {
int vertexCount = ReadVarint(input, true);
Vertices vertices = ReadVertices(input, vertexCount);
if (nonessential) ReadInt(input); //int color = nonessential ? ReadInt(input) : 0; // Avoid unused local warning.
BoundingBoxAttachment box = attachmentLoader.NewBoundingBoxAttachment(skin, name);
if (box == null) return null;
box.worldVerticesLength = vertexCount << 1;
box.vertices = vertices.vertices;
box.bones = vertices.bones;
return box;
}
case AttachmentType.Mesh: {
String path = ReadString(input);
int color = ReadInt(input);
int vertexCount = ReadVarint(input, true);
float[] uvs = ReadFloatArray(input, vertexCount << 1, 1);
int[] triangles = ReadShortArray(input);
Vertices vertices = ReadVertices(input, vertexCount);
int hullLength = ReadVarint(input, true);
int[] edges = null;
float width = 0, height = 0;
if (nonessential) {
edges = ReadShortArray(input);
width = ReadFloat(input);
height = ReadFloat(input);
}
if (path == null) path = name;
MeshAttachment mesh = attachmentLoader.NewMeshAttachment(skin, name, path);
if (mesh == null) return null;
mesh.Path = path;
mesh.r = ((color & 0xff000000) >> 24) / 255f;
mesh.g = ((color & 0x00ff0000) >> 16) / 255f;
mesh.b = ((color & 0x0000ff00) >> 8) / 255f;
mesh.a = ((color & 0x000000ff)) / 255f;
mesh.bones = vertices.bones;
mesh.vertices = vertices.vertices;
mesh.WorldVerticesLength = vertexCount << 1;
mesh.triangles = triangles;
mesh.regionUVs = uvs;
mesh.UpdateUVs();
mesh.HullLength = hullLength << 1;
if (nonessential) {
mesh.Edges = edges;
mesh.Width = width * scale;
mesh.Height = height * scale;
}
return mesh;
}
case AttachmentType.Linkedmesh: {
String path = ReadString(input);
int color = ReadInt(input);
String skinName = ReadString(input);
String parent = ReadString(input);
bool inheritDeform = ReadBoolean(input);
float width = 0, height = 0;
if (nonessential) {
width = ReadFloat(input);
height = ReadFloat(input);
}
if (path == null) path = name;
MeshAttachment mesh = attachmentLoader.NewMeshAttachment(skin, name, path);
if (mesh == null) return null;
mesh.Path = path;
mesh.r = ((color & 0xff000000) >> 24) / 255f;
mesh.g = ((color & 0x00ff0000) >> 16) / 255f;
mesh.b = ((color & 0x0000ff00) >> 8) / 255f;
mesh.a = ((color & 0x000000ff)) / 255f;
mesh.inheritDeform = inheritDeform;
if (nonessential) {
mesh.Width = width * scale;
mesh.Height = height * scale;
}
linkedMeshes.Add(new SkeletonJson.LinkedMesh(mesh, skinName, slotIndex, parent));
return mesh;
}
case AttachmentType.Path: {
bool closed = ReadBoolean(input);
bool constantSpeed = ReadBoolean(input);
int vertexCount = ReadVarint(input, true);
Vertices vertices = ReadVertices(input, vertexCount);
float[] lengths = new float[vertexCount / 3];
for (int i = 0, n = lengths.Length; i < n; i++)
lengths[i] = ReadFloat(input) * scale;
if (nonessential) ReadInt(input); //int color = nonessential ? ReadInt(input) : 0;
PathAttachment path = attachmentLoader.NewPathAttachment(skin, name);
if (path == null) return null;
path.closed = closed;
path.constantSpeed = constantSpeed;
path.worldVerticesLength = vertexCount << 1;
path.vertices = vertices.vertices;
path.bones = vertices.bones;
path.lengths = lengths;
return path;
}
case AttachmentType.Point: {
float rotation = ReadFloat(input);
float x = ReadFloat(input);
float y = ReadFloat(input);
if (nonessential) ReadInt(input); //int color = nonessential ? ReadInt(input) : 0;
PointAttachment point = attachmentLoader.NewPointAttachment(skin, name);
if (point == null) return null;
point.x = x * scale;
point.y = y * scale;
point.rotation = rotation;
//if (nonessential) point.color = color;
return point;
}
case AttachmentType.Clipping: {
int endSlotIndex = ReadVarint(input, true);
int vertexCount = ReadVarint(input, true);
Vertices vertices = ReadVertices(input, vertexCount);
if (nonessential) ReadInt(input);
ClippingAttachment clip = attachmentLoader.NewClippingAttachment(skin, name);
if (clip == null) return null;
clip.EndSlot = skeletonData.slots.Items[endSlotIndex];
clip.worldVerticesLength = vertexCount << 1;
clip.vertices = vertices.vertices;
clip.bones = vertices.bones;
return clip;
}
}
return null;
}
private Vertices ReadVertices (Stream input, int vertexCount) {
float scale = Scale;
int verticesLength = vertexCount << 1;
Vertices vertices = new Vertices();
if(!ReadBoolean(input)) {
vertices.vertices = ReadFloatArray(input, verticesLength, scale);
return vertices;
}
var weights = new ExposedList<float>(verticesLength * 3 * 3);
var bonesArray = new ExposedList<int>(verticesLength * 3);
for (int i = 0; i < vertexCount; i++) {
int boneCount = ReadVarint(input, true);
bonesArray.Add(boneCount);
for (int ii = 0; ii < boneCount; ii++) {
bonesArray.Add(ReadVarint(input, true));
weights.Add(ReadFloat(input) * scale);
weights.Add(ReadFloat(input) * scale);
weights.Add(ReadFloat(input));
}
}
vertices.vertices = weights.ToArray();
vertices.bones = bonesArray.ToArray();
return vertices;
}
private float[] ReadFloatArray (Stream input, int n, float scale) {
float[] array = new float[n];
if (scale == 1) {
for (int i = 0; i < n; i++)
array[i] = ReadFloat(input);
} else {
for (int i = 0; i < n; i++)
array[i] = ReadFloat(input) * scale;
}
return array;
}
private int[] ReadShortArray (Stream input) {
int n = ReadVarint(input, true);
int[] array = new int[n];
for (int i = 0; i < n; i++)
array[i] = (input.ReadByte() << 8) | input.ReadByte();
return array;
}
private void ReadAnimation (String name, Stream input, SkeletonData skeletonData) {
var timelines = new ExposedList<Timeline>();
float scale = Scale;
float duration = 0;
// Slot timelines.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
int slotIndex = ReadVarint(input, true);
for (int ii = 0, nn = ReadVarint(input, true); ii < nn; ii++) {
int timelineType = input.ReadByte();
int frameCount = ReadVarint(input, true);
switch (timelineType) {
case SLOT_ATTACHMENT: {
AttachmentTimeline timeline = new AttachmentTimeline(frameCount);
timeline.slotIndex = slotIndex;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++)
timeline.SetFrame(frameIndex, ReadFloat(input), ReadString(input));
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[frameCount - 1]);
break;
}
case SLOT_COLOR: {
ColorTimeline timeline = new ColorTimeline(frameCount);
timeline.slotIndex = slotIndex;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
float time = ReadFloat(input);
int color = ReadInt(input);
float r = ((color & 0xff000000) >> 24) / 255f;
float g = ((color & 0x00ff0000) >> 16) / 255f;
float b = ((color & 0x0000ff00) >> 8) / 255f;
float a = ((color & 0x000000ff)) / 255f;
timeline.SetFrame(frameIndex, time, r, g, b, a);
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[(timeline.FrameCount - 1) * ColorTimeline.ENTRIES]);
break;
}
case SLOT_TWO_COLOR: {
TwoColorTimeline timeline = new TwoColorTimeline(frameCount);
timeline.slotIndex = slotIndex;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
float time = ReadFloat(input);
int color = ReadInt(input);
float r = ((color & 0xff000000) >> 24) / 255f;
float g = ((color & 0x00ff0000) >> 16) / 255f;
float b = ((color & 0x0000ff00) >> 8) / 255f;
float a = ((color & 0x000000ff)) / 255f;
int color2 = ReadInt(input); // 0x00rrggbb
float r2 = ((color2 & 0x00ff0000) >> 16) / 255f;
float g2 = ((color2 & 0x0000ff00) >> 8) / 255f;
float b2 = ((color2 & 0x000000ff)) / 255f;
timeline.SetFrame(frameIndex, time, r, g, b, a, r2, g2, b2);
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[(timeline.FrameCount - 1) * TwoColorTimeline.ENTRIES]);
break;
}
}
}
}
// Bone timelines.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
int boneIndex = ReadVarint(input, true);
for (int ii = 0, nn = ReadVarint(input, true); ii < nn; ii++) {
int timelineType = input.ReadByte();
int frameCount = ReadVarint(input, true);
switch (timelineType) {
case BONE_ROTATE: {
RotateTimeline timeline = new RotateTimeline(frameCount);
timeline.boneIndex = boneIndex;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
timeline.SetFrame(frameIndex, ReadFloat(input), ReadFloat(input));
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[(frameCount - 1) * RotateTimeline.ENTRIES]);
break;
}
case BONE_TRANSLATE:
case BONE_SCALE:
case BONE_SHEAR: {
TranslateTimeline timeline;
float timelineScale = 1;
if (timelineType == BONE_SCALE)
timeline = new ScaleTimeline(frameCount);
else if (timelineType == BONE_SHEAR)
timeline = new ShearTimeline(frameCount);
else {
timeline = new TranslateTimeline(frameCount);
timelineScale = scale;
}
timeline.boneIndex = boneIndex;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
timeline.SetFrame(frameIndex, ReadFloat(input), ReadFloat(input) * timelineScale, ReadFloat(input)
* timelineScale);
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[(frameCount - 1) * TranslateTimeline.ENTRIES]);
break;
}
}
}
}
// IK timelines.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
int index = ReadVarint(input, true);
int frameCount = ReadVarint(input, true);
IkConstraintTimeline timeline = new IkConstraintTimeline(frameCount);
timeline.ikConstraintIndex = index;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
timeline.SetFrame(frameIndex, ReadFloat(input), ReadFloat(input), ReadSByte(input));
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[(frameCount - 1) * IkConstraintTimeline.ENTRIES]);
}
// Transform constraint timelines.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
int index = ReadVarint(input, true);
int frameCount = ReadVarint(input, true);
TransformConstraintTimeline timeline = new TransformConstraintTimeline(frameCount);
timeline.transformConstraintIndex = index;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
timeline.SetFrame(frameIndex, ReadFloat(input), ReadFloat(input), ReadFloat(input), ReadFloat(input), ReadFloat(input));
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[(frameCount - 1) * TransformConstraintTimeline.ENTRIES]);
}
// Path constraint timelines.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
int index = ReadVarint(input, true);
PathConstraintData data = skeletonData.pathConstraints.Items[index];
for (int ii = 0, nn = ReadVarint(input, true); ii < nn; ii++) {
int timelineType = ReadSByte(input);
int frameCount = ReadVarint(input, true);
switch(timelineType) {
case PATH_POSITION:
case PATH_SPACING: {
PathConstraintPositionTimeline timeline;
float timelineScale = 1;
if (timelineType == PATH_SPACING) {
timeline = new PathConstraintSpacingTimeline(frameCount);
if (data.spacingMode == SpacingMode.Length || data.spacingMode == SpacingMode.Fixed) timelineScale = scale;
} else {
timeline = new PathConstraintPositionTimeline(frameCount);
if (data.positionMode == PositionMode.Fixed) timelineScale = scale;
}
timeline.pathConstraintIndex = index;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
timeline.SetFrame(frameIndex, ReadFloat(input), ReadFloat(input) * timelineScale);
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[(frameCount - 1) * PathConstraintPositionTimeline.ENTRIES]);
break;
}
case PATH_MIX: {
PathConstraintMixTimeline timeline = new PathConstraintMixTimeline(frameCount);
timeline.pathConstraintIndex = index;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
timeline.SetFrame(frameIndex, ReadFloat(input), ReadFloat(input), ReadFloat(input));
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[(frameCount - 1) * PathConstraintMixTimeline.ENTRIES]);
break;
}
}
}
}
// Deform timelines.
for (int i = 0, n = ReadVarint(input, true); i < n; i++) {
Skin skin = skeletonData.skins.Items[ReadVarint(input, true)];
for (int ii = 0, nn = ReadVarint(input, true); ii < nn; ii++) {
int slotIndex = ReadVarint(input, true);
for (int iii = 0, nnn = ReadVarint(input, true); iii < nnn; iii++) {
VertexAttachment attachment = (VertexAttachment)skin.GetAttachment(slotIndex, ReadString(input));
bool weighted = attachment.bones != null;
float[] vertices = attachment.vertices;
int deformLength = weighted ? vertices.Length / 3 * 2 : vertices.Length;
int frameCount = ReadVarint(input, true);
DeformTimeline timeline = new DeformTimeline(frameCount);
timeline.slotIndex = slotIndex;
timeline.attachment = attachment;
for (int frameIndex = 0; frameIndex < frameCount; frameIndex++) {
float time = ReadFloat(input);
float[] deform;
int end = ReadVarint(input, true);
if (end == 0)
deform = weighted ? new float[deformLength] : vertices;
else {
deform = new float[deformLength];
int start = ReadVarint(input, true);
end += start;
if (scale == 1) {
for (int v = start; v < end; v++)
deform[v] = ReadFloat(input);
} else {
for (int v = start; v < end; v++)
deform[v] = ReadFloat(input) * scale;
}
if (!weighted) {
for (int v = 0, vn = deform.Length; v < vn; v++)
deform[v] += vertices[v];
}
}
timeline.SetFrame(frameIndex, time, deform);
if (frameIndex < frameCount - 1) ReadCurve(input, frameIndex, timeline);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[frameCount - 1]);
}
}
}
// Draw order timeline.
int drawOrderCount = ReadVarint(input, true);
if (drawOrderCount > 0) {
DrawOrderTimeline timeline = new DrawOrderTimeline(drawOrderCount);
int slotCount = skeletonData.slots.Count;
for (int i = 0; i < drawOrderCount; i++) {
float time = ReadFloat(input);
int offsetCount = ReadVarint(input, true);
int[] drawOrder = new int[slotCount];
for (int ii = slotCount - 1; ii >= 0; ii--)
drawOrder[ii] = -1;
int[] unchanged = new int[slotCount - offsetCount];
int originalIndex = 0, unchangedIndex = 0;
for (int ii = 0; ii < offsetCount; ii++) {
int slotIndex = ReadVarint(input, true);
// Collect unchanged items.
while (originalIndex != slotIndex)
unchanged[unchangedIndex++] = originalIndex++;
// Set changed items.
drawOrder[originalIndex + ReadVarint(input, true)] = originalIndex++;
}
// Collect remaining unchanged items.
while (originalIndex < slotCount)
unchanged[unchangedIndex++] = originalIndex++;
// Fill in unchanged items.
for (int ii = slotCount - 1; ii >= 0; ii--)
if (drawOrder[ii] == -1) drawOrder[ii] = unchanged[--unchangedIndex];
timeline.SetFrame(i, time, drawOrder);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[drawOrderCount - 1]);
}
// Event timeline.
int eventCount = ReadVarint(input, true);
if (eventCount > 0) {
EventTimeline timeline = new EventTimeline(eventCount);
for (int i = 0; i < eventCount; i++) {
float time = ReadFloat(input);
EventData eventData = skeletonData.events.Items[ReadVarint(input, true)];
Event e = new Event(time, eventData);
e.Int = ReadVarint(input, false);
e.Float = ReadFloat(input);
e.String = ReadBoolean(input) ? ReadString(input) : eventData.String;
timeline.SetFrame(i, e);
}
timelines.Add(timeline);
duration = Math.Max(duration, timeline.frames[eventCount - 1]);
}
timelines.TrimExcess();
skeletonData.animations.Add(new Animation(name, timelines, duration));
}
private void ReadCurve (Stream input, int frameIndex, CurveTimeline timeline) {
switch (input.ReadByte()) {
case CURVE_STEPPED:
timeline.SetStepped(frameIndex);
break;
case CURVE_BEZIER:
timeline.SetCurve(frameIndex, ReadFloat(input), ReadFloat(input), ReadFloat(input), ReadFloat(input));
break;
}
}
private static sbyte ReadSByte (Stream input) {
int value = input.ReadByte();
if (value == -1) throw new EndOfStreamException();
return (sbyte)value;
}
private static bool ReadBoolean (Stream input) {
return input.ReadByte() != 0;
}
private float ReadFloat (Stream input) {
buffer[3] = (byte)input.ReadByte();
buffer[2] = (byte)input.ReadByte();
buffer[1] = (byte)input.ReadByte();
buffer[0] = (byte)input.ReadByte();
return BitConverter.ToSingle(buffer, 0);
}
private static int ReadInt (Stream input) {
return (input.ReadByte() << 24) + (input.ReadByte() << 16) + (input.ReadByte() << 8) + input.ReadByte();
}
private static int ReadVarint (Stream input, bool optimizePositive) {
int b = input.ReadByte();
int result = b & 0x7F;
if ((b & 0x80) != 0) {
b = input.ReadByte();
result |= (b & 0x7F) << 7;
if ((b & 0x80) != 0) {
b = input.ReadByte();
result |= (b & 0x7F) << 14;
if ((b & 0x80) != 0) {
b = input.ReadByte();
result |= (b & 0x7F) << 21;
if ((b & 0x80) != 0) result |= (input.ReadByte() & 0x7F) << 28;
}
}
}
return optimizePositive ? result : ((result >> 1) ^ -(result & 1));
}
private string ReadString (Stream input) {
int byteCount = ReadVarint(input, true);
switch (byteCount) {
case 0:
return null;
case 1:
return "";
}
byteCount--;
byte[] buffer = this.buffer;
if (buffer.Length < byteCount) buffer = new byte[byteCount];
ReadFully(input, buffer, 0, byteCount);
return System.Text.Encoding.UTF8.GetString(buffer, 0, byteCount);
}
private static void ReadFully (Stream input, byte[] buffer, int offset, int length) {
while (length > 0) {
int count = input.Read(buffer, offset, length);
if (count <= 0) throw new EndOfStreamException();
offset += count;
length -= count;
}
}
internal class Vertices {
public int[] bones;
public float[] vertices;
}
}
}