void RasterNode::blt(const glm::mat4& transform, const glm::vec2& destSize)
{
GLContext* pContext = GLContext::getCurrent();
FRect destRect;
StandardShaderPtr pShader = pContext->getStandardShader();
float opacity = getEffectiveOpacity();
pContext->setBlendColor(glm::vec4(1.0f, 1.0f, 1.0f, opacity));
pShader->setAlpha(opacity);
if (m_pFXNode) {
pContext->setBlendMode(m_BlendMode, true);
m_pFXNode->getTex()->activate(GL_TEXTURE0);
pShader->setColorModel(0);
pShader->disableColorspaceMatrix();
pShader->setGamma(glm::vec4(1.0f, 1.0f, 1.0f, 1.0f));
pShader->setPremultipliedAlpha(true);
pShader->setMask(false);
FRect relDestRect = m_pFXNode->getRelDestRect();
destRect = FRect(relDestRect.tl.x*destSize.x, relDestRect.tl.y*destSize.y,
relDestRect.br.x*destSize.x, relDestRect.br.y*destSize.y);
} else {
m_pSurface->activate(getMediaSize());
pContext->setBlendMode(m_BlendMode, m_pSurface->isPremultipliedAlpha());
destRect = FRect(glm::vec2(0,0), destSize);
}
glm::vec3 pos(destRect.tl.x, destRect.tl.y, 0);
glm::vec3 scaleVec(destRect.size().x, destRect.size().y, 1);
glm::mat4 localTransform = glm::translate(transform, pos);
localTransform = glm::scale(localTransform, scaleVec);
pShader->setTransform(localTransform);
pShader->activate();
m_pSubVA->draw();
}
void OGLSurface::activate(const IntPoint& logicalSize, bool bPremultipliedAlpha) const
{
StandardShaderPtr pShader = StandardShader::get();
GLContext::checkError("OGLSurface::activate()");
switch (m_pf) {
case YCbCr420p:
case YCbCrJ420p:
pShader->setColorModel(1);
break;
case YCbCrA420p:
pShader->setColorModel(3);
break;
case A8:
pShader->setColorModel(2);
break;
default:
pShader->setColorModel(0);
}
m_pTextures[0]->activate(GL_TEXTURE0);
if (pixelFormatIsPlanar(m_pf)) {
m_pTextures[1]->activate(GL_TEXTURE1);
m_pTextures[2]->activate(GL_TEXTURE2);
if (m_pf == YCbCrA420p) {
m_pTextures[3]->activate(GL_TEXTURE3);
}
}
if (pixelFormatIsPlanar(m_pf) || colorIsModified()) {
glm::mat4 mat = calcColorspaceMatrix();
pShader->setColorspaceMatrix(mat);
} else {
pShader->disableColorspaceMatrix();
}
pShader->setGamma(glm::vec4(1/m_Gamma.x, 1/m_Gamma.y, 1/m_Gamma.z,
1./m_AlphaGamma));
pShader->setPremultipliedAlpha(bPremultipliedAlpha);
if (m_pMaskTexture) {
m_pMaskTexture->activate(GL_TEXTURE4);
// Special case for pot textures:
// The tex coords in the vertex array are scaled to fit the image texture. We
// need to undo this and fit to the mask texture. In the npot case, everything
// evaluates to (1,1);
glm::vec2 texSize = glm::vec2(m_pTextures[0]->getGLSize());
glm::vec2 imgSize = glm::vec2(m_pTextures[0]->getSize());
glm::vec2 maskTexSize = glm::vec2(m_pMaskTexture->getGLSize());
glm::vec2 maskImgSize = glm::vec2(m_pMaskTexture->getSize());
glm::vec2 maskScale = glm::vec2(maskTexSize.x/maskImgSize.x,
maskTexSize.y/maskImgSize.y);
glm::vec2 imgScale = glm::vec2(texSize.x/imgSize.x, texSize.y/imgSize.y);
glm::vec2 maskPos = m_MaskPos/maskScale;
// Special case for words nodes.
if (logicalSize != IntPoint(0,0)) {
maskScale *= glm::vec2((float)logicalSize.x/m_Size.x,
(float)logicalSize.y/m_Size.y);
}
pShader->setMask(true, maskPos, m_MaskSize*maskScale/imgScale);
} else {
pShader->setMask(false);
}
pShader->activate();
GLContext::checkError("OGLSurface::activate");
}
