#ifdef HAVE_CONFIG_H # include #endif #include #include #include #include #include #include "panelnode.hxx" SG_USING_STD(vector); // Static (!) handling for all 3D panels in the program. // OSGFIXME: Put the panel as different elements in the scenegraph. // Then just pick in that scenegraph. vector all_3d_panels; bool fgHandle3DPanelMouseEvent( int button, int updown, int x, int y ) { for ( unsigned int i = 0; i < all_3d_panels.size(); i++ ) { if ( all_3d_panels[i]->doMouseAction(button, updown, x, y) ) { return true; } } return false; } void fgUpdate3DPanels() { for ( unsigned int i = 0; i < all_3d_panels.size(); i++ ) { all_3d_panels[i]->getPanel()->updateMouseDelay(); } } FGPanelNode::FGPanelNode(SGPropertyNode* props) { int i; // Make an FGPanel object. But *don't* call init() or bind() on // it -- those methods touch static state. _panel = fgReadPanel(props->getStringValue("path")); // Never mind. We *have* to call init to make sure the static // state is initialized (it's not, if there aren't any 2D // panels). This is a memory leak and should be fixed!` // FIXME _panel->init(); _panel->setDepthTest( props->getBoolValue("depth-test") ); // Read out the pixel-space info _xmax = _panel->getWidth(); _ymax = _panel->getHeight(); // And the corner points SGPropertyNode* pt = props->getChild("bottom-left"); _bottomLeft[0] = pt->getFloatValue("x-m"); _bottomLeft[1] = pt->getFloatValue("y-m"); _bottomLeft[2] = pt->getFloatValue("z-m"); pt = props->getChild("top-left"); _topLeft[0] = pt->getFloatValue("x-m"); _topLeft[1] = pt->getFloatValue("y-m"); _topLeft[2] = pt->getFloatValue("z-m"); pt = props->getChild("bottom-right"); _bottomRight[0] = pt->getFloatValue("x-m"); _bottomRight[1] = pt->getFloatValue("y-m"); _bottomRight[2] = pt->getFloatValue("z-m"); // Now generate our transformation matrix. For shorthand, use // "a", "b", and "c" as our corners and "m" as the matrix. The // vector u goes from a to b, v from a to c, and w is a // perpendicular cross product. osg::Vec3 a = _bottomLeft; osg::Vec3 b = _bottomRight; osg::Vec3 c = _topLeft; osg::Vec3 u = b - a; osg::Vec3 v = c - a; osg::Vec3 w = u^v; osg::Matrix& m = _xform; // Now generate a trivial basis transformation matrix. If we want // to map the three unit vectors to three arbitrary vectors U, V, // and W, then those just become the columns of the 3x3 matrix. m(0,0) = u[0]; m(1,0) = v[0]; m(2,0) = w[0]; m(3,0) = a[0];// |Ux Vx Wx| m(0,1) = u[1]; m(1,1) = v[1]; m(2,1) = w[1]; m(3,1) = a[1];//m = |Uy Vy Wy| m(0,2) = u[2]; m(1,2) = v[2]; m(2,2) = w[2]; m(3,2) = a[2];// |Uz Vz Wz| m(0,3) = 0; m(1,3) = 0; m(2,3) = 0; m(3,3) = 1; // The above matrix maps the unit (!) square to the panel // rectangle. Postmultiply scaling factors that match the // pixel-space size of the panel. for(i=0; i<4; ++i) { m(0,i) *= 1.0/_xmax; m(1,i) *= 1.0/_ymax; } dirtyBound(); // All done. Add us to the list all_3d_panels.push_back(this); setUseDisplayList(false); getOrCreateStateSet()->setRenderingHint(osg::StateSet::TRANSPARENT_BIN); getOrCreateStateSet()->setMode(GL_BLEND, osg::StateAttribute::ON); } FGPanelNode::~FGPanelNode() { delete _panel; } void FGPanelNode::drawImplementation(osg::State& state) const { osg::ref_ptr mv = new osg::RefMatrix; mv->set(_xform*state.getModelViewMatrix()); state.applyModelViewMatrix(mv.get()); // Grab the matrix state, so that we can get back from screen // coordinates to panel coordinates when the user clicks the // mouse. // OSGFIXME: we don't need that when we can really pick const_cast(_lastModelview) = state.getModelViewMatrix(); const_cast(_lastProjection) = state.getProjectionMatrix(); state.getCurrentViewport()->getViewport(const_cast(_lastViewport[0]), const_cast(_lastViewport[1]), const_cast(_lastViewport[2]), const_cast(_lastViewport[3])); _panel->draw(state); } osg::BoundingBox FGPanelNode::computeBound() const { osg::BoundingBox bb; bb.expandBy(_bottomLeft); bb.expandBy(_bottomRight); bb.expandBy(_topLeft); return bb; } bool FGPanelNode::doMouseAction(int button, int updown, int x, int y) { // Covert the screen coordinates to viewport coordinates in the // range [0:1], then transform to OpenGL "post projection" coords // in [-1:1]. Remember the difference in Y direction! float vx = (x + 0.5 - _lastViewport[0]) / _lastViewport[2]; float vy = (y + 0.5 - _lastViewport[1]) / _lastViewport[3]; vx = 2*vx - 1; vy = 1 - 2*vy; // Make two vectors in post-projection coordinates at the given // screen, one in the near field and one in the far field. osg::Vec3 a, b; a[0] = b[0] = vx; a[1] = b[1] = vy; a[2] = 0.75; // "Near" Z value b[2] = -0.75; // "Far" Z value // Run both vectors "backwards" through the OpenGL matrix // transformation. Remember to w-normalize the vectors! osg::Matrix m = _lastModelview*_lastProjection; m = osg::Matrix::inverse(m); a = m.preMult(a); b = m.preMult(b); // And find their intersection on the z=0 plane. The resulting X // and Y coordinates are the hit location in panel coordinates. float dxdz = (b[0] - a[0]) / (b[2] - a[2]); float dydz = (b[1] - a[1]) / (b[2] - a[2]); int panelX = (int)(a[0] - a[2]*dxdz + 0.5); int panelY = (int)(a[1] - a[2]*dydz + 0.5); return _panel->doLocalMouseAction(button, updown, panelX, panelY); }