/**************************************************************************** Copyright (c) 2010-2011 cocos2d-x.org Copyright (c) 2009 On-Core 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 "ccMacros.h" #include "effects/CCGrid.h" #include "CCDirector.h" #include "effects/CCGrabber.h" #include "support/ccUtils.h" #include "shaders/CCGLProgram.h" #include "shaders/CCShaderCache.h" #include "shaders/ccGLStateCache.h" #include "CCGL.h" #include "support/CCPointExtension.h" #include "support/TransformUtils.h" #include "kazmath/kazmath.h" #include "kazmath/GL/matrix.h" NS_CC_BEGIN // implementation of CCGridBase CCGridBase* CCGridBase::gridWithSize(const ccGridSize& gridSize) { return CCGridBase::create(gridSize); } CCGridBase* CCGridBase::create(const ccGridSize& gridSize) { CCGridBase *pGridBase = new CCGridBase(); if (pGridBase) { if (pGridBase->initWithSize(gridSize)) { pGridBase->autorelease(); } else { CC_SAFE_RELEASE_NULL(pGridBase); } } return pGridBase; } CCGridBase* CCGridBase::gridWithSize(const ccGridSize& gridSize, CCTexture2D *texture, bool flipped) { return CCGridBase::create(gridSize, texture, flipped); } CCGridBase* CCGridBase::create(const ccGridSize& gridSize, CCTexture2D *texture, bool flipped) { CCGridBase *pGridBase = new CCGridBase(); if (pGridBase) { if (pGridBase->initWithSize(gridSize, texture, flipped)) { pGridBase->autorelease(); } else { CC_SAFE_RELEASE_NULL(pGridBase); } } return pGridBase; } bool CCGridBase::initWithSize(const ccGridSize& gridSize, CCTexture2D *pTexture, bool bFlipped) { bool bRet = true; m_bActive = false; m_nReuseGrid = 0; m_sGridSize = gridSize; m_pTexture = pTexture; CC_SAFE_RETAIN(m_pTexture); m_bIsTextureFlipped = bFlipped; const CCSize& texSize = m_pTexture->getContentSize(); m_obStep.x = texSize.width / m_sGridSize.x; m_obStep.y = texSize.height / m_sGridSize.y; m_pGrabber = new CCGrabber(); if (m_pGrabber) { m_pGrabber->grab(m_pTexture); } else { bRet = false; } m_pShaderProgram = CCShaderCache::sharedShaderCache()->programForKey(kCCShader_PositionTexture); calculateVertexPoints(); return bRet; } bool CCGridBase::initWithSize(const ccGridSize& gridSize) { CCDirector *pDirector = CCDirector::sharedDirector(); CCSize s = pDirector->getWinSizeInPixels(); unsigned long POTWide = ccNextPOT((unsigned int)s.width); unsigned long POTHigh = ccNextPOT((unsigned int)s.height); // we only use rgba8888 CCTexture2DPixelFormat format = kCCTexture2DPixelFormat_RGBA8888; void *data = calloc((int)(POTWide * POTHigh * 4), 1); if (! data) { CCLOG("cocos2d: CCGrid: not enough memory."); this->release(); return false; } CCTexture2D *pTexture = new CCTexture2D(); pTexture->initWithData(data, format, POTWide, POTHigh, s); free(data); if (! pTexture) { CCLOG("cocos2d: CCGrid: error creating texture"); delete this; return false; } initWithSize(gridSize, pTexture, false); pTexture->release(); return true; } CCGridBase::~CCGridBase(void) { CCLOGINFO("cocos2d: deallocing %p", this); //TODO: ? why 2.0 comments this line setActive(false); CC_SAFE_RELEASE(m_pTexture); CC_SAFE_RELEASE(m_pGrabber); } // properties void CCGridBase::setActive(bool bActive) { m_bActive = bActive; if (! bActive) { CCDirector *pDirector = CCDirector::sharedDirector(); ccDirectorProjection proj = pDirector->getProjection(); pDirector->setProjection(proj); } } void CCGridBase::setTextureFlipped(bool bFlipped) { if (m_bIsTextureFlipped != bFlipped) { m_bIsTextureFlipped = bFlipped; calculateVertexPoints(); } } void CCGridBase::set2DProjection() { CCDirector *director = CCDirector::sharedDirector(); CCSize size = director->getWinSizeInPixels(); glViewport(0, 0, (GLsizei)(size.width * CC_CONTENT_SCALE_FACTOR()), (GLsizei)(size.height * CC_CONTENT_SCALE_FACTOR()) ); kmGLMatrixMode(KM_GL_PROJECTION); kmGLLoadIdentity(); kmMat4 orthoMatrix; kmMat4OrthographicProjection(&orthoMatrix, 0, size.width * CC_CONTENT_SCALE_FACTOR(), 0, size.height * CC_CONTENT_SCALE_FACTOR(), -1, 1); kmGLMultMatrix( &orthoMatrix ); kmGLMatrixMode(KM_GL_MODELVIEW); kmGLLoadIdentity(); ccSetProjectionMatrixDirty(); } void CCGridBase::beforeDraw(void) { // save projection CCDirector *director = CCDirector::sharedDirector(); m_directorProjection = director->getProjection(); // 2d projection // [director setProjection:kCCDirectorProjection2D]; set2DProjection(); m_pGrabber->beforeRender(m_pTexture); } void CCGridBase::afterDraw(cocos2d::CCNode *pTarget) { m_pGrabber->afterRender(m_pTexture); // restore projection CCDirector *director = CCDirector::sharedDirector(); director->setProjection(m_directorProjection); if (pTarget->getCamera()->isDirty()) { const CCPoint& offset = pTarget->getAnchorPointInPoints(); // // XXX: Camera should be applied in the AnchorPoint // kmGLTranslatef(offset.x, offset.y, 0); pTarget->getCamera()->locate(); kmGLTranslatef(-offset.x, -offset.y, 0); } ccGLBindTexture2D(m_pTexture->getName()); // restore projection for default FBO .fixed bug #543 #544 //TODO: CCDirector::sharedDirector()->setProjection(CCDirector::sharedDirector()->getProjection()); //TODO: CCDirector::sharedDirector()->applyOrientation(); blit(); } void CCGridBase::blit(void) { CCAssert(0, ""); } void CCGridBase::reuse(void) { CCAssert(0, ""); } void CCGridBase::calculateVertexPoints(void) { CCAssert(0, ""); } // implementation of CCGrid3D CCGrid3D* CCGrid3D::gridWithSize(const ccGridSize& gridSize, CCTexture2D *pTexture, bool bFlipped) { return CCGrid3D::create(gridSize, pTexture, bFlipped); } CCGrid3D* CCGrid3D::create(const ccGridSize& gridSize, CCTexture2D *pTexture, bool bFlipped) { CCGrid3D *pRet= new CCGrid3D(); if (pRet) { if (pRet->initWithSize(gridSize, pTexture, bFlipped)) { pRet->autorelease(); } else { delete pRet; pRet = NULL; } } return pRet; } CCGrid3D* CCGrid3D::gridWithSize(const ccGridSize& gridSize) { return CCGrid3D::create(gridSize); } CCGrid3D* CCGrid3D::create(const ccGridSize& gridSize) { CCGrid3D *pRet= new CCGrid3D(); if (pRet) { if (pRet->initWithSize(gridSize)) { pRet->autorelease(); } else { delete pRet; pRet = NULL; } } return pRet; } CCGrid3D::CCGrid3D() : m_pTexCoordinates(NULL) , m_pVertices(NULL) , m_pOriginalVertices(NULL) , m_pIndices(NULL) { } CCGrid3D::~CCGrid3D(void) { CC_SAFE_FREE(m_pTexCoordinates); CC_SAFE_FREE(m_pVertices); CC_SAFE_FREE(m_pIndices); CC_SAFE_FREE(m_pOriginalVertices); } void CCGrid3D::blit(void) { int n = m_sGridSize.x * m_sGridSize.y; ccGLEnableVertexAttribs( kCCVertexAttribFlag_Position | kCCVertexAttribFlag_TexCoords ); m_pShaderProgram->use(); m_pShaderProgram->setUniformForModelViewProjectionMatrix();; // // Attributes // // position glVertexAttribPointer(kCCVertexAttrib_Position, 3, GL_FLOAT, GL_FALSE, 0, m_pVertices); // texCoods glVertexAttribPointer(kCCVertexAttrib_TexCoords, 2, GL_FLOAT, GL_FALSE, 0, m_pTexCoordinates); glDrawElements(GL_TRIANGLES, (GLsizei) n*6, GL_UNSIGNED_SHORT, m_pIndices); CC_INCREMENT_GL_DRAWS(1); } void CCGrid3D::calculateVertexPoints(void) { float width = (float)m_pTexture->getPixelsWide(); float height = (float)m_pTexture->getPixelsHigh(); float imageH = m_pTexture->getContentSizeInPixels().height; int x, y, i; CC_SAFE_FREE(m_pVertices); CC_SAFE_FREE(m_pOriginalVertices); CC_SAFE_FREE(m_pTexCoordinates); CC_SAFE_FREE(m_pIndices); unsigned int numOfPoints = (m_sGridSize.x+1) * (m_sGridSize.y+1); m_pVertices = malloc(numOfPoints * sizeof(ccVertex3F)); m_pOriginalVertices = malloc(numOfPoints * sizeof(ccVertex3F)); m_pTexCoordinates = malloc(numOfPoints * sizeof(ccVertex2F)); m_pIndices = (GLushort*)malloc(m_sGridSize.x * m_sGridSize.y * sizeof(GLushort) * 6); GLfloat *vertArray = (GLfloat*)m_pVertices; GLfloat *texArray = (GLfloat*)m_pTexCoordinates; GLushort *idxArray = m_pIndices; for (x = 0; x < m_sGridSize.x; ++x) { for (y = 0; y < m_sGridSize.y; ++y) { int idx = (y * m_sGridSize.x) + x; GLfloat x1 = x * m_obStep.x; GLfloat x2 = x1 + m_obStep.x; GLfloat y1 = y * m_obStep.y; GLfloat y2= y1 + m_obStep.y; GLushort a = (GLushort)(x * (m_sGridSize.y + 1) + y); GLushort b = (GLushort)((x + 1) * (m_sGridSize.y + 1) + y); GLushort c = (GLushort)((x + 1) * (m_sGridSize.y + 1) + (y + 1)); GLushort d = (GLushort)(x * (m_sGridSize.y + 1) + (y + 1)); GLushort tempidx[6] = {a, b, d, b, c, d}; memcpy(&idxArray[6*idx], tempidx, 6*sizeof(GLushort)); int l1[4] = {a*3, b*3, c*3, d*3}; ccVertex3F e = {x1, y1, 0}; ccVertex3F f = {x2, y1, 0}; ccVertex3F g = {x2, y2, 0}; ccVertex3F h = {x1, y2, 0}; ccVertex3F l2[4] = {e, f, g, h}; int tex1[4] = {a*2, b*2, c*2, d*2}; CCPoint tex2[4] = {ccp(x1, y1), ccp(x2, y1), ccp(x2, y2), ccp(x1, y2)}; for (i = 0; i < 4; ++i) { vertArray[l1[i]] = l2[i].x; vertArray[l1[i] + 1] = l2[i].y; vertArray[l1[i] + 2] = l2[i].z; texArray[tex1[i]] = tex2[i].x / width; if (m_bIsTextureFlipped) { texArray[tex1[i] + 1] = (imageH - tex2[i].y) / height; } else { texArray[tex1[i] + 1] = tex2[i].y / height; } } } } memcpy(m_pOriginalVertices, m_pVertices, (m_sGridSize.x+1) * (m_sGridSize.y+1) * sizeof(ccVertex3F)); } ccVertex3F CCGrid3D::vertex(const ccGridSize& pos) { int index = (pos.x * (m_sGridSize.y+1) + pos.y) * 3; float *vertArray = (float*)m_pVertices; ccVertex3F vert = {vertArray[index], vertArray[index+1], vertArray[index+2]}; return vert; } ccVertex3F CCGrid3D::originalVertex(const ccGridSize& pos) { int index = (pos.x * (m_sGridSize.y+1) + pos.y) * 3; float *vertArray = (float*)m_pOriginalVertices; ccVertex3F vert = {vertArray[index], vertArray[index+1], vertArray[index+2]}; return vert; } void CCGrid3D::setVertex(const ccGridSize& pos, const ccVertex3F& vertex) { int index = (pos.x * (m_sGridSize.y + 1) + pos.y) * 3; float *vertArray = (float*)m_pVertices; vertArray[index] = vertex.x; vertArray[index+1] = vertex.y; vertArray[index+2] = vertex.z; } void CCGrid3D::reuse(void) { if (m_nReuseGrid > 0) { memcpy(m_pOriginalVertices, m_pVertices, (m_sGridSize.x+1) * (m_sGridSize.y+1) * sizeof(ccVertex3F)); --m_nReuseGrid; } } // implementation of CCTiledGrid3D CCTiledGrid3D::CCTiledGrid3D() : m_pTexCoordinates(NULL) , m_pVertices(NULL) , m_pOriginalVertices(NULL) , m_pIndices(NULL) { } CCTiledGrid3D::~CCTiledGrid3D(void) { CC_SAFE_FREE(m_pTexCoordinates); CC_SAFE_FREE(m_pVertices); CC_SAFE_FREE(m_pOriginalVertices); CC_SAFE_FREE(m_pIndices); } CCTiledGrid3D* CCTiledGrid3D::gridWithSize(const ccGridSize& gridSize, CCTexture2D *pTexture, bool bFlipped) { return CCTiledGrid3D::create(gridSize, pTexture, bFlipped); } CCTiledGrid3D* CCTiledGrid3D::create(const ccGridSize& gridSize, CCTexture2D *pTexture, bool bFlipped) { CCTiledGrid3D *pRet= new CCTiledGrid3D(); if (pRet) { if (pRet->initWithSize(gridSize, pTexture, bFlipped)) { pRet->autorelease(); } else { delete pRet; pRet = NULL; } } return pRet; } CCTiledGrid3D* CCTiledGrid3D::gridWithSize(const ccGridSize& gridSize) { return CCTiledGrid3D::create(gridSize); } CCTiledGrid3D* CCTiledGrid3D::create(const ccGridSize& gridSize) { CCTiledGrid3D *pRet= new CCTiledGrid3D(); if (pRet) { if (pRet->initWithSize(gridSize)) { pRet->autorelease(); } else { delete pRet; pRet = NULL; } } return pRet; } void CCTiledGrid3D::blit(void) { int n = m_sGridSize.x * m_sGridSize.y; m_pShaderProgram->use(); m_pShaderProgram->setUniformForModelViewProjectionMatrix(); // // Attributes // ccGLEnableVertexAttribs( kCCVertexAttribFlag_Position | kCCVertexAttribFlag_TexCoords ); // position glVertexAttribPointer(kCCVertexAttrib_Position, 3, GL_FLOAT, GL_FALSE, 0, m_pVertices); // texCoods glVertexAttribPointer(kCCVertexAttrib_TexCoords, 2, GL_FLOAT, GL_FALSE, 0, m_pTexCoordinates); glDrawElements(GL_TRIANGLES, (GLsizei)n*6, GL_UNSIGNED_SHORT, m_pIndices); CC_INCREMENT_GL_DRAWS(1); } void CCTiledGrid3D::calculateVertexPoints(void) { float width = (float)m_pTexture->getPixelsWide(); float height = (float)m_pTexture->getPixelsHigh(); float imageH = m_pTexture->getContentSizeInPixels().height; int numQuads = m_sGridSize.x * m_sGridSize.y; CC_SAFE_FREE(m_pVertices); CC_SAFE_FREE(m_pOriginalVertices); CC_SAFE_FREE(m_pTexCoordinates); CC_SAFE_FREE(m_pIndices); m_pVertices = malloc(numQuads*4*sizeof(ccVertex3F)); m_pOriginalVertices = malloc(numQuads*4*sizeof(ccVertex3F)); m_pTexCoordinates = malloc(numQuads*4*sizeof(ccVertex2F)); m_pIndices = (GLushort*)malloc(numQuads*6*sizeof(GLushort)); GLfloat *vertArray = (GLfloat*)m_pVertices; GLfloat *texArray = (GLfloat*)m_pTexCoordinates; GLushort *idxArray = m_pIndices; int x, y; for( x = 0; x < m_sGridSize.x; x++ ) { for( y = 0; y < m_sGridSize.y; y++ ) { float x1 = x * m_obStep.x; float x2 = x1 + m_obStep.x; float y1 = y * m_obStep.y; float y2 = y1 + m_obStep.y; *vertArray++ = x1; *vertArray++ = y1; *vertArray++ = 0; *vertArray++ = x2; *vertArray++ = y1; *vertArray++ = 0; *vertArray++ = x1; *vertArray++ = y2; *vertArray++ = 0; *vertArray++ = x2; *vertArray++ = y2; *vertArray++ = 0; float newY1 = y1; float newY2 = y2; if (m_bIsTextureFlipped) { newY1 = imageH - y1; newY2 = imageH - y2; } *texArray++ = x1 / width; *texArray++ = newY1 / height; *texArray++ = x2 / width; *texArray++ = newY1 / height; *texArray++ = x1 / width; *texArray++ = newY2 / height; *texArray++ = x2 / width; *texArray++ = newY2 / height; } } for (x = 0; x < numQuads; x++) { idxArray[x*6+0] = (GLushort)(x * 4 + 0); idxArray[x*6+1] = (GLushort)(x * 4 + 1); idxArray[x*6+2] = (GLushort)(x * 4 + 2); idxArray[x*6+3] = (GLushort)(x * 4 + 1); idxArray[x*6+4] = (GLushort)(x * 4 + 2); idxArray[x*6+5] = (GLushort)(x * 4 + 3); } memcpy(m_pOriginalVertices, m_pVertices, numQuads * 12 * sizeof(GLfloat)); } void CCTiledGrid3D::setTile(const ccGridSize& pos, const ccQuad3& coords) { int idx = (m_sGridSize.y * pos.x + pos.y) * 4 * 3; float *vertArray = (float*)m_pVertices; memcpy(&vertArray[idx], &coords, sizeof(ccQuad3)); } ccQuad3 CCTiledGrid3D::originalTile(const ccGridSize& pos) { int idx = (m_sGridSize.y * pos.x + pos.y) * 4 * 3; float *vertArray = (float*)m_pOriginalVertices; ccQuad3 ret; memcpy(&ret, &vertArray[idx], sizeof(ccQuad3)); return ret; } ccQuad3 CCTiledGrid3D::tile(const ccGridSize& pos) { int idx = (m_sGridSize.y * pos.x + pos.y) * 4 * 3; float *vertArray = (float*)m_pVertices; ccQuad3 ret; memcpy(&ret, &vertArray[idx], sizeof(ccQuad3)); return ret; } void CCTiledGrid3D::reuse(void) { if (m_nReuseGrid > 0) { int numQuads = m_sGridSize.x * m_sGridSize.y; memcpy(m_pOriginalVertices, m_pVertices, numQuads * 12 * sizeof(GLfloat)); --m_nReuseGrid; } } NS_CC_END