axmol/cocos/editor-support/spine/SkeletonRenderer.cpp

437 lines
16 KiB
C++

/******************************************************************************
* Spine Runtimes Software License
* Version 2.3
*
* Copyright (c) 2013-2015, 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 (the "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 otherwise create derivative works, improvements of the
* Software or develop new applications using the Software 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; LOSS OF USE, DATA, OR PROFITS;
* OR BUSINESS INTERRUPTION) 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.
*****************************************************************************/
#include <spine/SkeletonRenderer.h>
#include <spine/spine-cocos2dx.h>
#include <spine/extension.h>
#include <spine/PolygonBatch.h>
#include <algorithm>
USING_NS_CC;
using std::min;
using std::max;
namespace spine {
static const int quadTriangles[6] = {0, 1, 2, 2, 3, 0};
SkeletonRenderer* SkeletonRenderer::createWithData (spSkeletonData* skeletonData, bool ownsSkeletonData) {
SkeletonRenderer* node = new SkeletonRenderer(skeletonData, ownsSkeletonData);
node->autorelease();
return node;
}
SkeletonRenderer* SkeletonRenderer::createWithFile (const std::string& skeletonDataFile, spAtlas* atlas, float scale) {
SkeletonRenderer* node = new SkeletonRenderer(skeletonDataFile, atlas, scale);
node->autorelease();
return node;
}
SkeletonRenderer* SkeletonRenderer::createWithFile (const std::string& skeletonDataFile, const std::string& atlasFile, float scale) {
SkeletonRenderer* node = new SkeletonRenderer(skeletonDataFile, atlasFile, scale);
node->autorelease();
return node;
}
void SkeletonRenderer::initialize () {
_worldVertices = MALLOC(float, 1000); // Max number of vertices per mesh.
_batch = PolygonBatch::createWithCapacity(2000); // Max number of vertices and triangles per batch.
_batch->retain();
_blendFunc = BlendFunc::ALPHA_PREMULTIPLIED;
setOpacityModifyRGB(true);
setGLProgram(GLProgramCache::getInstance()->getGLProgram(GLProgram::SHADER_NAME_POSITION_TEXTURE_COLOR));
}
void SkeletonRenderer::setSkeletonData (spSkeletonData *skeletonData, bool ownsSkeletonData) {
_skeleton = spSkeleton_create(skeletonData);
_ownsSkeletonData = ownsSkeletonData;
}
SkeletonRenderer::SkeletonRenderer ()
: _atlas(0), _debugSlots(false), _debugBones(false), _timeScale(1) {
}
SkeletonRenderer::SkeletonRenderer (spSkeletonData *skeletonData, bool ownsSkeletonData)
: _atlas(0), _debugSlots(false), _debugBones(false), _timeScale(1) {
initWithData(skeletonData, ownsSkeletonData);
}
SkeletonRenderer::SkeletonRenderer (const std::string& skeletonDataFile, spAtlas* atlas, float scale)
: _atlas(0), _debugSlots(false), _debugBones(false), _timeScale(1) {
initWithFile(skeletonDataFile, atlas, scale);
}
SkeletonRenderer::SkeletonRenderer (const std::string& skeletonDataFile, const std::string& atlasFile, float scale)
: _atlas(0), _debugSlots(false), _debugBones(false), _timeScale(1) {
initWithFile(skeletonDataFile, atlasFile, scale);
}
SkeletonRenderer::~SkeletonRenderer () {
if (_ownsSkeletonData) spSkeletonData_dispose(_skeleton->data);
if (_atlas) spAtlas_dispose(_atlas);
spSkeleton_dispose(_skeleton);
_batch->release();
FREE(_worldVertices);
}
void SkeletonRenderer::initWithData (spSkeletonData* skeletonData, bool ownsSkeletonData) {
setSkeletonData(skeletonData, ownsSkeletonData);
initialize();
}
void SkeletonRenderer::initWithFile (const std::string& skeletonDataFile, spAtlas* atlas, float scale) {
spSkeletonJson* json = spSkeletonJson_create(atlas);
json->scale = scale;
spSkeletonData* skeletonData = spSkeletonJson_readSkeletonDataFile(json, skeletonDataFile.c_str());
CCASSERT(skeletonData, json->error ? json->error : "Error reading skeleton data.");
spSkeletonJson_dispose(json);
setSkeletonData(skeletonData, true);
initialize();
}
void SkeletonRenderer::initWithFile (const std::string& skeletonDataFile, const std::string& atlasFile, float scale) {
_atlas = spAtlas_createFromFile(atlasFile.c_str(), 0);
CCASSERT(_atlas, "Error reading atlas file.");
spSkeletonJson* json = spSkeletonJson_create(_atlas);
json->scale = scale;
spSkeletonData* skeletonData = spSkeletonJson_readSkeletonDataFile(json, skeletonDataFile.c_str());
CCASSERT(skeletonData, json->error ? json->error : "Error reading skeleton data file.");
spSkeletonJson_dispose(json);
setSkeletonData(skeletonData, true);
initialize();
}
void SkeletonRenderer::update (float deltaTime) {
spSkeleton_update(_skeleton, deltaTime * _timeScale);
}
void SkeletonRenderer::draw (Renderer* renderer, const Mat4& transform, uint32_t transformFlags) {
_drawCommand.init(_globalZOrder);
_drawCommand.func = CC_CALLBACK_0(SkeletonRenderer::drawSkeleton, this, transform, transformFlags);
renderer->addCommand(&_drawCommand);
}
void SkeletonRenderer::drawSkeleton (const Mat4 &transform, uint32_t transformFlags) {
getGLProgramState()->apply(transform);
Color3B nodeColor = getColor();
_skeleton->r = nodeColor.r / (float)255;
_skeleton->g = nodeColor.g / (float)255;
_skeleton->b = nodeColor.b / (float)255;
_skeleton->a = getDisplayedOpacity() / (float)255;
int blendMode = -1;
Color4B color;
const float* uvs = nullptr;
int verticesCount = 0;
const int* triangles = nullptr;
int trianglesCount = 0;
float r = 0, g = 0, b = 0, a = 0;
for (int i = 0, n = _skeleton->slotsCount; i < n; i++) {
spSlot* slot = _skeleton->drawOrder[i];
if (!slot->attachment) continue;
Texture2D *texture = nullptr;
switch (slot->attachment->type) {
case SP_ATTACHMENT_REGION: {
spRegionAttachment* attachment = (spRegionAttachment*)slot->attachment;
spRegionAttachment_computeWorldVertices(attachment, slot->bone, _worldVertices);
texture = getTexture(attachment);
uvs = attachment->uvs;
verticesCount = 8;
triangles = quadTriangles;
trianglesCount = 6;
r = attachment->r;
g = attachment->g;
b = attachment->b;
a = attachment->a;
break;
}
case SP_ATTACHMENT_MESH: {
spMeshAttachment* attachment = (spMeshAttachment*)slot->attachment;
spMeshAttachment_computeWorldVertices(attachment, slot, _worldVertices);
texture = getTexture(attachment);
uvs = attachment->uvs;
verticesCount = attachment->verticesCount;
triangles = attachment->triangles;
trianglesCount = attachment->trianglesCount;
r = attachment->r;
g = attachment->g;
b = attachment->b;
a = attachment->a;
break;
}
case SP_ATTACHMENT_SKINNED_MESH: {
spSkinnedMeshAttachment* attachment = (spSkinnedMeshAttachment*)slot->attachment;
spSkinnedMeshAttachment_computeWorldVertices(attachment, slot, _worldVertices);
texture = getTexture(attachment);
uvs = attachment->uvs;
verticesCount = attachment->uvsCount;
triangles = attachment->triangles;
trianglesCount = attachment->trianglesCount;
r = attachment->r;
g = attachment->g;
b = attachment->b;
a = attachment->a;
break;
}
default: ;
}
if (texture) {
if (slot->data->blendMode != blendMode) {
_batch->flush();
blendMode = slot->data->blendMode;
switch (slot->data->blendMode) {
case SP_BLEND_MODE_ADDITIVE:
GL::blendFunc(_premultipliedAlpha ? GL_ONE : GL_SRC_ALPHA, GL_ONE);
break;
case SP_BLEND_MODE_MULTIPLY:
GL::blendFunc(GL_DST_COLOR, GL_ONE_MINUS_SRC_ALPHA);
break;
case SP_BLEND_MODE_SCREEN:
GL::blendFunc(GL_ONE, GL_ONE_MINUS_SRC_COLOR);
break;
default:
GL::blendFunc(_blendFunc.src, _blendFunc.dst);
}
}
color.a = _skeleton->a * slot->a * a * 255;
float multiplier = _premultipliedAlpha ? color.a : 255;
color.r = _skeleton->r * slot->r * r * multiplier;
color.g = _skeleton->g * slot->g * g * multiplier;
color.b = _skeleton->b * slot->b * b * multiplier;
_batch->add(texture, _worldVertices, uvs, verticesCount, triangles, trianglesCount, &color);
}
}
_batch->flush();
if (_debugSlots || _debugBones) {
Director* director = Director::getInstance();
director->pushMatrix(MATRIX_STACK_TYPE::MATRIX_STACK_MODELVIEW);
director->loadMatrix(MATRIX_STACK_TYPE::MATRIX_STACK_MODELVIEW, transform);
if (_debugSlots) {
// Slots.
DrawPrimitives::setDrawColor4B(0, 0, 255, 255);
glLineWidth(1);
Vec2 points[4];
V3F_C4B_T2F_Quad quad;
for (int i = 0, n = _skeleton->slotsCount; i < n; i++) {
spSlot* slot = _skeleton->drawOrder[i];
if (!slot->attachment || slot->attachment->type != SP_ATTACHMENT_REGION) continue;
spRegionAttachment* attachment = (spRegionAttachment*)slot->attachment;
spRegionAttachment_computeWorldVertices(attachment, slot->bone, _worldVertices);
points[0] = Vec2(_worldVertices[0], _worldVertices[1]);
points[1] = Vec2(_worldVertices[2], _worldVertices[3]);
points[2] = Vec2(_worldVertices[4], _worldVertices[5]);
points[3] = Vec2(_worldVertices[6], _worldVertices[7]);
DrawPrimitives::drawPoly(points, 4, true);
}
}
if (_debugBones) {
// Bone lengths.
glLineWidth(2);
DrawPrimitives::setDrawColor4B(255, 0, 0, 255);
for (int i = 0, n = _skeleton->bonesCount; i < n; i++) {
spBone *bone = _skeleton->bones[i];
float x = bone->data->length * bone->m00 + bone->worldX;
float y = bone->data->length * bone->m10 + bone->worldY;
DrawPrimitives::drawLine(Vec2(bone->worldX, bone->worldY), Vec2(x, y));
}
// Bone origins.
DrawPrimitives::setPointSize(4);
DrawPrimitives::setDrawColor4B(0, 0, 255, 255); // Root bone is blue.
for (int i = 0, n = _skeleton->bonesCount; i < n; i++) {
spBone *bone = _skeleton->bones[i];
DrawPrimitives::drawPoint(Vec2(bone->worldX, bone->worldY));
if (i == 0) DrawPrimitives::setDrawColor4B(0, 255, 0, 255);
}
}
director->popMatrix(MATRIX_STACK_TYPE::MATRIX_STACK_MODELVIEW);
}
}
Texture2D* SkeletonRenderer::getTexture (spRegionAttachment* attachment) const {
return (Texture2D*)((spAtlasRegion*)attachment->rendererObject)->page->rendererObject;
}
Texture2D* SkeletonRenderer::getTexture (spMeshAttachment* attachment) const {
return (Texture2D*)((spAtlasRegion*)attachment->rendererObject)->page->rendererObject;
}
Texture2D* SkeletonRenderer::getTexture (spSkinnedMeshAttachment* attachment) const {
return (Texture2D*)((spAtlasRegion*)attachment->rendererObject)->page->rendererObject;
}
Rect SkeletonRenderer::getBoundingBox () const {
float minX = FLT_MAX, minY = FLT_MAX, maxX = FLT_MIN, maxY = FLT_MIN;
float scaleX = getScaleX(), scaleY = getScaleY();
for (int i = 0; i < _skeleton->slotsCount; ++i) {
spSlot* slot = _skeleton->slots[i];
if (!slot->attachment) continue;
int verticesCount;
if (slot->attachment->type == SP_ATTACHMENT_REGION) {
spRegionAttachment* attachment = (spRegionAttachment*)slot->attachment;
spRegionAttachment_computeWorldVertices(attachment, slot->bone, _worldVertices);
verticesCount = 8;
} else if (slot->attachment->type == SP_ATTACHMENT_MESH) {
spMeshAttachment* mesh = (spMeshAttachment*)slot->attachment;
spMeshAttachment_computeWorldVertices(mesh, slot, _worldVertices);
verticesCount = mesh->verticesCount;
} else if (slot->attachment->type == SP_ATTACHMENT_SKINNED_MESH) {
spSkinnedMeshAttachment* mesh = (spSkinnedMeshAttachment*)slot->attachment;
spSkinnedMeshAttachment_computeWorldVertices(mesh, slot, _worldVertices);
verticesCount = mesh->uvsCount;
} else
continue;
for (int ii = 0; ii < verticesCount; ii += 2) {
float x = _worldVertices[ii] * scaleX, y = _worldVertices[ii + 1] * scaleY;
minX = min(minX, x);
minY = min(minY, y);
maxX = max(maxX, x);
maxY = max(maxY, y);
}
}
Vec2 position = getPosition();
return Rect(position.x + minX, position.y + minY, maxX - minX, maxY - minY);
}
// --- Convenience methods for Skeleton_* functions.
void SkeletonRenderer::updateWorldTransform () {
spSkeleton_updateWorldTransform(_skeleton);
}
void SkeletonRenderer::setToSetupPose () {
spSkeleton_setToSetupPose(_skeleton);
}
void SkeletonRenderer::setBonesToSetupPose () {
spSkeleton_setBonesToSetupPose(_skeleton);
}
void SkeletonRenderer::setSlotsToSetupPose () {
spSkeleton_setSlotsToSetupPose(_skeleton);
}
spBone* SkeletonRenderer::findBone (const std::string& boneName) const {
return spSkeleton_findBone(_skeleton, boneName.c_str());
}
spSlot* SkeletonRenderer::findSlot (const std::string& slotName) const {
return spSkeleton_findSlot(_skeleton, slotName.c_str());
}
bool SkeletonRenderer::setSkin (const std::string& skinName) {
return spSkeleton_setSkinByName(_skeleton, skinName.empty() ? 0 : skinName.c_str()) ? true : false;
}
bool SkeletonRenderer::setSkin (const char* skinName) {
return spSkeleton_setSkinByName(_skeleton, skinName) ? true : false;
}
spAttachment* SkeletonRenderer::getAttachment (const std::string& slotName, const std::string& attachmentName) const {
return spSkeleton_getAttachmentForSlotName(_skeleton, slotName.c_str(), attachmentName.c_str());
}
bool SkeletonRenderer::setAttachment (const std::string& slotName, const std::string& attachmentName) {
return spSkeleton_setAttachment(_skeleton, slotName.c_str(), attachmentName.empty() ? 0 : attachmentName.c_str()) ? true : false;
}
bool SkeletonRenderer::setAttachment (const std::string& slotName, const char* attachmentName) {
return spSkeleton_setAttachment(_skeleton, slotName.c_str(), attachmentName) ? true : false;
}
spSkeleton* SkeletonRenderer::getSkeleton () {
return _skeleton;
}
void SkeletonRenderer::setTimeScale (float scale) {
_timeScale = scale;
}
float SkeletonRenderer::getTimeScale () const {
return _timeScale;
}
void SkeletonRenderer::setDebugSlotsEnabled (bool enabled) {
_debugSlots = enabled;
}
bool SkeletonRenderer::getDebugSlotsEnabled () const {
return _debugSlots;
}
void SkeletonRenderer::setDebugBonesEnabled (bool enabled) {
_debugBones = enabled;
}
bool SkeletonRenderer::getDebugBonesEnabled () const {
return _debugBones;
}
void SkeletonRenderer::onEnter () {
#if CC_ENABLE_SCRIPT_BINDING
if (_scriptType == kScriptTypeJavascript && ScriptEngineManager::sendNodeEventToJSExtended(this, kNodeOnEnter)) return;
#endif
Node::onEnter();
scheduleUpdate();
}
void SkeletonRenderer::onExit () {
#if CC_ENABLE_SCRIPT_BINDING
if (_scriptType == kScriptTypeJavascript && ScriptEngineManager::sendNodeEventToJSExtended(this, kNodeOnExit)) return;
#endif
Node::onExit();
unscheduleUpdate();
}
// --- CCBlendProtocol
const BlendFunc& SkeletonRenderer::getBlendFunc () const {
return _blendFunc;
}
void SkeletonRenderer::setBlendFunc (const BlendFunc &blendFunc) {
_blendFunc = blendFunc;
}
void SkeletonRenderer::setOpacityModifyRGB (bool value) {
_premultipliedAlpha = value;
}
bool SkeletonRenderer::isOpacityModifyRGB () const {
return _premultipliedAlpha;
}
}