Introduction
This article shows how we can perform rubber-banding in an OpenGL application.
Background
Rubber-banding is frequently used by drawing programs. The objective is to draw something such as a rectangle, then erase it without disturbing what has already been rendered. The rubber-banding rectangle can then be used for selecting objects. For an OpenGL application, rubber-banding can be achieved by rendering with the logic op enabled and set to XOR mode.
The source code here includes a simple C++ class called jxglTracker. The two main member functions in the class are DrawTrackRect() and Track(). In the DrawTrackRect() function, the logic op is enabled by calling glEnable(GL_COLOR_LOGIC_OP) and the XOR mode is set by calling glLogicOp(GL_XOR). The rubber-banding rectangle is drawn using glRecti().
void jxglTracker::DrawTrackRect(int x1, int y1, int x2, int y2)
{
CRect rectClient;
m_pWnd->GetClientRect(&rectClient);
glEnable(GL_COLOR_LOGIC_OP);
glLogicOp(GL_XOR);
if(x1 < x2)
{
glColor4f(0.0, 0.0, 1.0, 0.5);
}
else
{
glColor4f(1.0, 0.0, 0.0, 0.5);
}
glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
glRecti(x1, rectClient.Height() - y1, x2,
rectClient.Height() - y2);
glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
glFlush(); glDisable(GL_COLOR_LOGIC_OP);
}
In the Track() function, we first set the drawing buffer to the front-buffer instead of the default back-buffer. This is needed because we do not want to disturb what has already been drawn (which could be expensive to redraw) while the rubber-banding rectangle is constantly being drawn and erased. Here, we also set up a convenient projection matrix so the pixels on the window client rectangle corresponds to the OpenGL model coordinate system. The DrawTrackRect() is called in an infinite for loop until WM_LBUTTONUP, WM_RBUTTONDOWN or the ESC WM_KEYDOWN message is received. The Track() function takes CWnd* pWnd and CPoint point as parameters, and is generally called from the WM_LBUTTONDOWN message handler of the client window pWnd.
BOOL jxglTracker::Track(CWnd* pWnd, CPoint point)
{
m_pWnd = pWnd;
ASSERT(m_pWnd != 0);
CRect rectClient;
m_pWnd->GetClientRect(&rectClient);
glDrawBuffer(GL_FRONT);
glMatrixMode(GL_PROJECTION);
glPushMatrix();
glLoadIdentity();
glOrtho(0, rectClient.Width(), 0,
rectClient.Height(), -1, 1);
glViewport(-1, -1, rectClient.Width() + 2,
rectClient.Height() + 2);
if (::GetCapture() != NULL)
{
return FALSE;
}
pWnd->SetCapture();
ASSERT(pWnd == CWnd::GetCapture());
pWnd->UpdateWindow();
BOOL bMoved = FALSE;
CPoint ptOld = point;
CRect rectOld = CRect(ptOld, ptOld);
CPoint ptNew;
BOOL bStop = FALSE;
for (;;)
{
MSG msg;
VERIFY(::GetMessage(&msg, NULL, 0, 0));
if (CWnd::GetCapture() != pWnd)
{
break;
}
if(msg.message == WM_LBUTTONUP || msg.message == WM_MOUSEMOVE)
{
ptNew.x = (int)(short)LOWORD(msg.lParam);
ptNew.y = (int)(short)HIWORD(msg.lParam);
m_rect = CRect(ptOld, ptNew);
if (bMoved)
{
m_bErased = TRUE;
DrawTrackRect(&rectOld);
}
rectOld = m_rect;
if (msg.message != WM_LBUTTONUP)
{
bMoved = TRUE;
}
if (msg.message == WM_MOUSEMOVE)
{
m_bErased = FALSE;
DrawTrackRect(&m_rect);
}
else
{
bStop = TRUE;
ASSERT(msg.message == WM_LBUTTONUP);
}
}
else if(msg.message == WM_KEYDOWN)
{
if (msg.wParam == VK_ESCAPE)
{
bStop = TRUE;
}
}
else if(msg.message == WM_RBUTTONDOWN)
{
bStop = TRUE;
}
else
{
DispatchMessage(&msg);
}
if(bStop)
{
break;
}
}
ReleaseCapture();
if(!m_bErased)
{
DrawTrackRect(m_rect);
}
glPopMatrix();
glDrawBuffer(GL_BACK);
return TRUE;
}
Using the Code
The jxglTracker class can be simply used inside the WM_LBUTTONDOWN message handler like shown below:
void COglRubberBandView::OnLButtonDown(UINT nFlags, CPoint point)
{
CPaintDC dc(this); wglMakeCurrent(dc.m_hDC, m_hRC);
jxglTracker tracker;
tracker.Track(this, point);
CView::OnLButtonDown(nFlags, point);
}
Points of Interest
An MDI MFC-OpenGL application (oglRubberBand) is used to test the jxglTracker rubber-banding class. This application is generated by the MFC AppWizard (accepting default settings) using VC++ 6.0. It is beyond the scope of this article to explain the details of setting up OpenGL. The main logic is contained in the view class (COglRubberBandView) and should be pretty easy to follow. Of course, the jxglTracker.h and jxglTracker.cpp files are added to the project. OpenGL libraries are linked through #pragma comment(lib,"opengl32.lib") etc. in the stdafx.h file.
Depending on the graphics card speed of your system, you can change the number of geometry entities to draw, as shown below. Notice that the drawing speed of the rubber-banding should not be affected by the number of entities already drawn.
void COglRubberBandView::OnPaint()
{
const int nLines = 10000; }
Happy coding!
History
- 8th February, 2006: Initial post
- 16th November, 2009: Article updated - code change that fixed a display bug in Windows 7 environment
- 6th January, 2012: Article updated - code change that fixed a bug on Vista and Windows 7
Junlin Xu is the founder of Computations & Graphics, Inc. (www.cg-inc.com) and author of OpenGraph Library and Real3D-Analysis. He has seventeen years of software development experience. His expertise includes C++, C#, C++/CLI, ObjectiveC, MFC, OpenGL, DirectX, WIN32 API, COM/COM++, WinForms, MS SQL, MySql, ASP.NET, WCF, WPF, Mirth Connect. He is also an expert in Finite Element Method procedure. He is currently a software engineer at a company in Colorado. He can be reached at junlin.xu@gmail.com.
Submit an article or tip
Post your Blog
News 
Suggestion 
Question 
Bug 
Answer 
Joke 
Rant 
Admin 
