/**************************************************************************** Copyright (c) 2013 cocos2d-x.org http://www.cocos2d-x.org Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. ****************************************************************************/ #include "cocostudio/CCArmature.h" #include "cocostudio/CCArmatureDataManager.h" #include "cocostudio/CCArmatureDefine.h" #include "cocostudio/CCDataReaderHelper.h" #include "cocostudio/CCDatas.h" #include "cocostudio/CCSkin.h" #if ENABLE_PHYSICS_BOX2D_DETECT #include "Box2D/Box2D.h" #elif ENABLE_PHYSICS_CHIPMUNK_DETECT #include "chipmunk.h" #endif using namespace cocos2d; namespace cocostudio { Armature *Armature::create() { Armature *armature = new Armature(); if (armature && armature->init()) { armature->autorelease(); return armature; } CC_SAFE_DELETE(armature); return nullptr; } Armature *Armature::create(const char *name) { Armature *armature = new Armature(); if (armature && armature->init(name)) { armature->autorelease(); return armature; } CC_SAFE_DELETE(armature); return nullptr; } Armature *Armature::create(const char *name, Bone *parentBone) { Armature *armature = new Armature(); if (armature && armature->init(name, parentBone)) { armature->autorelease(); return armature; } CC_SAFE_DELETE(armature); return nullptr; } Armature::Armature() : _armatureData(nullptr) , _batchNode(nullptr) , _atlas(nullptr) , _parentBone(nullptr) , _armatureTransformDirty(true) , _boneDic(nullptr) , _topBoneList(nullptr) , _animation(nullptr) , _textureAtlasDic(nullptr) { } Armature::~Armature(void) { if(nullptr != _boneDic) { _boneDic->removeAllObjects(); CC_SAFE_DELETE(_boneDic); } if (nullptr != _topBoneList) { _topBoneList->removeAllObjects(); CC_SAFE_DELETE(_topBoneList); } CC_SAFE_DELETE(_animation); CC_SAFE_RELEASE_NULL(_textureAtlasDic); } bool Armature::init() { return init(nullptr); } bool Armature::init(const char *name) { bool bRet = false; do { removeAllChildren(); CC_SAFE_DELETE(_animation); _animation = new ArmatureAnimation(); _animation->init(this); CC_SAFE_DELETE(_boneDic); _boneDic = new Dictionary(); CC_SAFE_DELETE(_topBoneList); _topBoneList = new Array(); _topBoneList->init(); CC_SAFE_DELETE(_textureAtlasDic); _textureAtlasDic = new Dictionary(); _blendFunc.src = CC_BLEND_SRC; _blendFunc.dst = CC_BLEND_DST; _name = name == nullptr ? "" : name; ArmatureDataManager *armatureDataManager = ArmatureDataManager::getInstance(); if(_name.length() != 0) { _name = name; AnimationData *animationData = armatureDataManager->getAnimationData(name); CCASSERT(animationData, "AnimationData not exist! "); _animation->setAnimationData(animationData); ArmatureData *armatureData = armatureDataManager->getArmatureData(name); CCASSERT(armatureData, ""); _armatureData = armatureData; DictElement *_element = nullptr; Dictionary *boneDataDic = &armatureData->boneDataDic; CCDICT_FOREACH(boneDataDic, _element) { Bone *bone = createBone(_element->getStrKey()); //! init bone's Tween to 1st movement's 1st frame do { MovementData *movData = animationData->getMovement(animationData->movementNames.at(0).c_str()); CC_BREAK_IF(!movData); MovementBoneData *movBoneData = movData->getMovementBoneData(bone->getName().c_str()); CC_BREAK_IF(!movBoneData || movBoneData->frameList.count() <= 0); FrameData *frameData = movBoneData->getFrameData(0); CC_BREAK_IF(!frameData); bone->getTweenData()->copy(frameData); bone->changeDisplayByIndex(frameData->displayIndex, false); } while (0); } update(0); updateOffsetPoint(); } else { _name = "new_armature"; _armatureData = ArmatureData::create(); _armatureData->name = _name; AnimationData *animationData = AnimationData::create(); animationData->name = _name; armatureDataManager->addArmatureData(_name.c_str(), _armatureData); armatureDataManager->addAnimationData(_name.c_str(), animationData); _animation->setAnimationData(animationData); } setShaderProgram(ShaderCache::getInstance()->getProgram(GLProgram::SHADER_NAME_POSITION_TEXTURE_COLOR)); unscheduleUpdate(); scheduleUpdate(); setCascadeOpacityEnabled(true); setCascadeColorEnabled(true); bRet = true; } while (0); return bRet; } bool Armature::init(const char *name, Bone *parentBone) { _parentBone = parentBone; return init(name); } Bone *Armature::createBone(const char *boneName) { Bone *existedBone = getBone(boneName); if(existedBone != nullptr) return existedBone; BoneData *boneData = (BoneData *)_armatureData->getBoneData(boneName); std::string parentName = boneData->parentName; Bone *bone = nullptr; if( parentName.length() != 0 ) { createBone(parentName.c_str()); bone = Bone::create(boneName); addBone(bone, parentName.c_str()); } else { bone = Bone::create(boneName); addBone(bone, ""); } bone->setBoneData(boneData); bone->getDisplayManager()->changeDisplayByIndex(-1, false); return bone; } void Armature::addBone(Bone *bone, const char *parentName) { CCASSERT( bone != nullptr, "Argument must be non-nil"); CCASSERT(_boneDic->objectForKey(bone->getName()) == nullptr, "bone already added. It can't be added again"); if (nullptr != parentName) { Bone *boneParent = (Bone *)_boneDic->objectForKey(parentName); if (boneParent) { boneParent->addChildBone(bone); } else { _topBoneList->addObject(bone); } } else { _topBoneList->addObject(bone); } bone->setArmature(this); _boneDic->setObject(bone, bone->getName()); addChild(bone); } void Armature::removeBone(Bone *bone, bool recursion) { CCASSERT(bone != nullptr, "bone must be added to the bone dictionary!"); bone->setArmature(nullptr); bone->removeFromParent(recursion); if (_topBoneList->containsObject(bone)) { _topBoneList->removeObject(bone); } _boneDic->removeObjectForKey(bone->getName()); removeChild(bone, true); } Bone *Armature::getBone(const char *name) const { return (Bone *)_boneDic->objectForKey(name); } void Armature::changeBoneParent(Bone *bone, const char *parentName) { CCASSERT(bone != nullptr, "bone must be added to the bone dictionary!"); if(bone->getParentBone()) { bone->getParentBone()->getChildren()->removeObject(bone); bone->setParentBone(nullptr); } if (parentName != nullptr) { Bone *boneParent = (Bone *)_boneDic->objectForKey(parentName); if (boneParent) { boneParent->addChildBone(bone); if (_topBoneList->containsObject(bone)) { _topBoneList->removeObject(bone); } } else { _topBoneList->addObject(bone); } } } Dictionary *Armature::getBoneDic() const { return _boneDic; } const AffineTransform& Armature::getNodeToParentTransform() const { if (_transformDirty) { _armatureTransformDirty = true; // Translate values float x = _position.x; float y = _position.y; if (_ignoreAnchorPointForPosition) { x += _anchorPointInPoints.x; y += _anchorPointInPoints.y; } // Rotation values // Change rotation code to handle X and Y // If we skew with the exact same value for both x and y then we're simply just rotating float cx = 1, sx = 0, cy = 1, sy = 0; if (_rotationX || _rotationY) { float radiansX = -CC_DEGREES_TO_RADIANS(_rotationX); float radiansY = -CC_DEGREES_TO_RADIANS(_rotationY); cx = cosf(radiansX); sx = sinf(radiansX); cy = cosf(radiansY); sy = sinf(radiansY); } // Add offset point x += cy * _offsetPoint.x * _scaleX + -sx * _offsetPoint.y * _scaleY; y += sy * _offsetPoint.x * _scaleX + cx * _offsetPoint.y * _scaleY; bool needsSkewMatrix = ( _skewX || _skewY ); // optimization: // inline anchor point calculation if skew is not needed // Adjusted transform calculation for rotational skew if (! needsSkewMatrix && !_anchorPointInPoints.equals(Point::ZERO)) { x += cy * -_anchorPointInPoints.x * _scaleX + -sx * -_anchorPointInPoints.y * _scaleY; y += sy * -_anchorPointInPoints.x * _scaleX + cx * -_anchorPointInPoints.y * _scaleY; } // Build Transform Matrix // Adjusted transform calculation for rotational skew _transform = AffineTransformMake( cy * _scaleX, sy * _scaleX, -sx * _scaleY, cx * _scaleY, x, y ); // XXX: Try to inline skew // If skew is needed, apply skew and then anchor point if (needsSkewMatrix) { AffineTransform skewMatrix = AffineTransformMake(1.0f, tanf(CC_DEGREES_TO_RADIANS(_skewY)), tanf(CC_DEGREES_TO_RADIANS(_skewX)), 1.0f, 0.0f, 0.0f ); _transform = AffineTransformConcat(skewMatrix, _transform); // adjust anchor point if (!_anchorPointInPoints.equals(Point::ZERO)) { _transform = AffineTransformTranslate(_transform, -_anchorPointInPoints.x, -_anchorPointInPoints.y); } } if (_additionalTransformDirty) { _transform = AffineTransformConcat(_transform, _additionalTransform); _additionalTransformDirty = false; } _transformDirty = false; } return _transform; } void Armature::updateOffsetPoint() { // Set contentsize and Calculate anchor point. Rect rect = getBoundingBox(); setContentSize(rect.size); _offsetPoint = Point(-rect.origin.x, -rect.origin.y); if (rect.size.width != 0 && rect.size.height != 0) { setAnchorPoint(Point(_offsetPoint.x / rect.size.width, _offsetPoint.y / rect.size.height)); } } void Armature::setAnimation(ArmatureAnimation *animation) { _animation = animation; } ArmatureAnimation *Armature::getAnimation() const { return _animation; } bool Armature::getArmatureTransformDirty() const { return _armatureTransformDirty; } void Armature::update(float dt) { _animation->update(dt); for (auto object : *_topBoneList) { static_cast(object)->update(dt); } _armatureTransformDirty = false; } void Armature::draw() { if (_parentBone == nullptr && _batchNode == nullptr) { CC_NODE_DRAW_SETUP(); GL::blendFunc(_blendFunc.src, _blendFunc.dst); } for (auto object : *_children) { if (Bone *bone = dynamic_cast(object)) { Node *node = bone->getDisplayRenderNode(); if (nullptr == node) continue; switch (bone->getDisplayRenderNodeType()) { case CS_DISPLAY_SPRITE: { Skin *skin = static_cast(node); TextureAtlas *textureAtlas = skin->getTextureAtlas(); BlendType blendType = bone->getBlendType(); if(_atlas != textureAtlas || blendType != BLEND_NORMAL) { if (_atlas) { _atlas->drawQuads(); _atlas->removeAllQuads(); } } _atlas = textureAtlas; if (_atlas->getCapacity() == _atlas->getTotalQuads() && !_atlas->resizeCapacity(_atlas->getCapacity() * 2)) return; skin->updateTransform(); if (blendType != BLEND_NORMAL) { updateBlendType(blendType); _atlas->drawQuads(); _atlas->removeAllQuads(); GL::blendFunc(_blendFunc.src, _blendFunc.dst); } } break; case CS_DISPLAY_ARMATURE: { Armature *armature = static_cast(node); TextureAtlas *textureAtlas = armature->getTextureAtlas(); if(_atlas != textureAtlas) { if (_atlas) { _atlas->drawQuads(); _atlas->removeAllQuads(); } } armature->draw(); _atlas = armature->getTextureAtlas(); } break; default: { if (_atlas) { _atlas->drawQuads(); _atlas->removeAllQuads(); } node->visit(); CC_NODE_DRAW_SETUP(); GL::blendFunc(_blendFunc.src, _blendFunc.dst); } break; } } else if(Node *node = dynamic_cast(object)) { if (_atlas) { _atlas->drawQuads(); _atlas->removeAllQuads(); } node->visit(); CC_NODE_DRAW_SETUP(); GL::blendFunc(_blendFunc.src, _blendFunc.dst); } } if(_atlas && !_batchNode && _parentBone == nullptr) { _atlas->drawQuads(); _atlas->removeAllQuads(); } } void Armature::updateBlendType(BlendType blendType) { BlendFunc blendFunc; switch (blendType) { case BLEND_NORMAL: { blendFunc.src = CC_BLEND_SRC; blendFunc.dst = CC_BLEND_DST; } break; case BLEND_ADD: { blendFunc.src = GL_SRC_ALPHA; blendFunc.dst = GL_ONE; } break; case BLEND_MULTIPLY: { blendFunc.src = GL_DST_COLOR; blendFunc.dst = GL_ONE_MINUS_SRC_ALPHA; } break; case BLEND_SCREEN: { blendFunc.src = GL_ONE; blendFunc.dst = GL_ONE_MINUS_SRC_COLOR; } break; default: { blendFunc.src = CC_BLEND_SRC; blendFunc.dst = CC_BLEND_DST; } break; } GL::blendFunc(blendFunc.src, blendFunc.dst); } void Armature::visit() { // quick return if not visible. children won't be drawn. if (!_visible) { return; } kmGLPushMatrix(); if (_grid && _grid->isActive()) { _grid->beforeDraw(); } transform(); sortAllChildren(); draw(); // reset for next frame _orderOfArrival = 0; if (_grid && _grid->isActive()) { _grid->afterDraw(this); } kmGLPopMatrix(); } Rect Armature::getBoundingBox() const { float minx, miny, maxx, maxy = 0; bool first = true; Rect boundingBox = Rect(0, 0, 0, 0); for(auto object : *_children) { if (Bone *bone = dynamic_cast(object)) { Rect r = bone->getDisplayManager()->getBoundingBox(); if(first) { minx = r.getMinX(); miny = r.getMinY(); maxx = r.getMaxX(); maxy = r.getMaxY(); first = false; } else { minx = r.getMinX() < boundingBox.getMinX() ? r.getMinX() : boundingBox.getMinX(); miny = r.getMinY() < boundingBox.getMinY() ? r.getMinY() : boundingBox.getMinY(); maxx = r.getMaxX() > boundingBox.getMaxX() ? r.getMaxX() : boundingBox.getMaxX(); maxy = r.getMaxY() > boundingBox.getMaxY() ? r.getMaxY() : boundingBox.getMaxY(); } boundingBox.setRect(minx, miny, maxx - minx, maxy - miny); } } return RectApplyAffineTransform(boundingBox, getNodeToParentTransform()); } Bone *Armature::getBoneAtPoint(float x, float y) const { int length = _children->count(); Bone *bs; for(int i = length - 1; i >= 0; i--) { bs = static_cast( _children->getObjectAtIndex(i) ); if(bs->getDisplayManager()->containPoint(x, y)) { return bs; } } return nullptr; } TextureAtlas *Armature::getTexureAtlasWithTexture(Texture2D *texture) const { int key = texture->getName(); if (_parentBone && _parentBone->getArmature()) { return _parentBone->getArmature()->getTexureAtlasWithTexture(texture); } else if (_batchNode) { _batchNode->getTexureAtlasWithTexture(texture); } TextureAtlas *atlas = static_cast(_textureAtlasDic->objectForKey(key)); if (atlas == nullptr) { atlas = TextureAtlas::createWithTexture(texture, 4); _textureAtlasDic->setObject(atlas, key); } return atlas; } void Armature::setParentBone(Bone *parentBone) { _parentBone = parentBone; DictElement *element = nullptr; CCDICT_FOREACH(_boneDic, element) { Bone *bone = static_cast(element->getObject()); bone->setArmature(this); } } Bone *Armature::getParentBone() const { return _parentBone; } void CCArmature::setColliderFilter(ColliderFilter *filter) { DictElement *element = nullptr; CCDICT_FOREACH(_boneDic, element) { Bone *bone = static_cast(element->getObject()); bone->setColliderFilter(filter); } } #if ENABLE_PHYSICS_BOX2D_DETECT b2Body *Armature::getBody() const { return _body; } void Armature::setBody(b2Body *body) { if (_body == body) { return; } _body = body; _body->SetUserData(this); for(auto object : *_children) { if (Bone *bone = dynamic_cast(object)) { Array *displayList = bone->getDisplayManager()->getDecorativeDisplayList(); for(auto displayObject : displayList) { ColliderDetector *detector = static_cast(displayObject)->getColliderDetector(); if (detector != nullptr) { detector->setBody(_body); } } } } } b2Fixture *Armature::getShapeList() { if (_body) { return _body->GetFixtureList(); } else { return nullptr; } } #elif ENABLE_PHYSICS_CHIPMUNK_DETECT cpBody *Armature::getBody() const { return _body; } void Armature::setBody(cpBody *body) { if (_body == body) { return; } _body = body; _body->data = this; for(auto object: *_children) { if (Bone *bone = dynamic_cast(object)) { Array *displayList = bone->getDisplayManager()->getDecorativeDisplayList(); for(auto displayObject: *displayList) { ColliderDetector *detector = static_cast(displayObject)->getColliderDetector(); if (detector != nullptr) { detector->setBody(_body); } } } } } cpShape *Armature::getShapeList() { if (_body) { return _body->shapeList_private; } else { return nullptr; } } #endif }