Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I wanted to draw a rectangle in android, but not just by specifying the left, top, right and bottom. What I have are 4 vertex coordinates. The rectangle is not horizontal but oblique, so something like the image of the rectangle below:

image of an oblique rectangle

I've been trying to see if I can use a matrix to perform some kind of rotation or use canvas.rotate(), but I'm still not clear how to do it. Can somebody help me with how to draw such a rectangle?

share|improve this question

I'd be interested in seeing somebody else's solution to this problem, but if there isn't an easier way, here's how I implemented it the hard way:

public void drawLineThick(GL10 gl, int thickness, FloatBuffer whichBuffer)
{
    gl.glColor4f(1.0f, 0.0f, 0.0f, 1.0f);
    final float x0 = whichBuffer.get(0);
    final float x1 = whichBuffer.get(2);
    final float y0 = whichBuffer.get(1);
    final float y1 = whichBuffer.get(3);

    boolean slopeZeroCase = false;
    boolean undefinedSlopeCase = false;
    boolean slopeOneCase = false;
    boolean slopeNegOneCase = false;
    boolean slopeSmall = false;
    boolean slopeBig = false;
    float boxThickness = thickness * .001f;

    //Slope (y2-y1)/(x2-x1)
    float m = 0.0f;

    //b parameter of y=mx+b formula, b=y-mx
    float b = 0.0f;

    //Special cases for handling when the slope is zero, undefined
    //both (line of length zero), one, or negative one.
    if (y1 - y0 == 0)
    {
        slopeZeroCase = true;
    }

    if (x1 - x0 == 0)
    {
        undefinedSlopeCase = true;
    }

    //If the slope isn't going to be zero or undefined, it's safe to
    //actually try to calculate it so that we don't have a "divide by zero"
    //by accident
    if (slopeZeroCase == false && undefinedSlopeCase == false)
    {
         m = ((y1 - y0)/(x1 - x0));
         b = (y0 - (m*x0));
    }

    if ( m == 1.0f)
    {
        slopeOneCase = true;
    }

    if (m == -1.0f)
    {
        slopeNegOneCase = true;
    }

    if ((m > 0 && m < 1) || (m < 0 && m > -1))
    {
        slopeSmall = true;
    }
    else
    {
        slopeBig = true;
    }

    //float tempFloat[] = new float[8];

    //Normal line where there is a slope involved
    if (slopeZeroCase == false && undefinedSlopeCase == false && slopeOneCase == false && slopeNegOneCase == false && slopeSmall == true)
    {

        /**
         *          Given a sloped line, in order to make it, "thicker", 
         *          one must offset the original line by + and - the
         *          thickness, in essence creating a box.  The formula
         *          for the points of a given box below (in the direction drawn)
         *          will be:
         * 
         *          p0         p1
         *          *----------*
         *          |          |
         *          |          |
         *          |          |
         *          |          |
         *          *----------*
         *          p3         p2
         *        
         */         

        //p1, x
        tempFloat[0] = x0;

        //p1, y
        tempFloat[1] = y0 + boxThickness;

        //p2, x
        tempFloat[2] = x1;

        //p2, y
        tempFloat[3] = y1 + boxThickness;

        //p3, x
        tempFloat[4] = x1;

        //p3, y
        tempFloat[5] = y1 - boxThickness;

        //p4, x
        tempFloat[6] = x0;

        //p4, y
        tempFloat[7] = y0 - boxThickness;
    }

    else if (slopeZeroCase == false && undefinedSlopeCase == false && slopeOneCase == false && slopeNegOneCase == false && slopeSmall == false)
    {

        /**
         *          Given a sloped line, in order to make it, "thicker", 
         *          one must offset the original line by + and - the
         *          thickness, in essence creating a box.  The formula
         *          for the points of a given box below (in the direction drawn)
         *          will be:
         * 
         * 
         * 
         *          p0         p1
         *          *----------*
         *          |          |
         *          |          |
         *          |          |
         *          |          |
         *          *----------*
         *          p3         p2
         *        
         */         

        //p1, x
        tempFloat[0] = x0 + boxThickness;

        //p1, y
        tempFloat[1] = y0;

        //p2, x
        tempFloat[2] = x1 + boxThickness;

        //p2, y
        tempFloat[3] = y1;

        //p3, x
        tempFloat[4] = x1 - boxThickness;

        //p3, y
        tempFloat[5] = y1;

        //p4, x
        tempFloat[6] = x0 - boxThickness;

        //p4, y
        tempFloat[7] = y0;
    }


    //Horizontal line case, only need to change the y to be +- thickness
    else if (slopeZeroCase == true && undefinedSlopeCase == false && slopeOneCase == false && slopeNegOneCase == false)
    {
        //Log.i("draw", "Horizontal");
        //p1, x
        tempFloat[0] = x0;

        //p1, y
        tempFloat[1] = y0 + boxThickness;

        //p2, x
        tempFloat[2] = x1;

        //p2, y
        tempFloat[3] = y1 + boxThickness;

        //p3, x
        tempFloat[4] = x1;

        //p3, y
        tempFloat[5] = y1 - boxThickness;

        //p4, x
        tempFloat[6] = x0;

        //p4, y
        tempFloat[7] = y0 - boxThickness;
    }

    //Vertical line case, only need to change the x to be +- thickness
    else if (slopeZeroCase == false && undefinedSlopeCase == true && slopeOneCase == false && slopeNegOneCase == false)
    {
        //Log.i("draw", "Vertical");
        //p1, x
        tempFloat[0] = x0 + boxThickness;

        //p1, y
        tempFloat[1] = y0;

        //p2, x
        tempFloat[2] = x1 + boxThickness;

        //p2, y
        tempFloat[3] = y1;

        //p3, x
        tempFloat[4] = x1 - boxThickness;

        //p3, y
        tempFloat[5] = y1;

        //p4, x
        tempFloat[6] = x0 - boxThickness;

        //p4, y
        tempFloat[7] = y0;
    }

    //Case where slope = 1
    else if (slopeZeroCase == false && undefinedSlopeCase == false && slopeOneCase == true && slopeNegOneCase == false)
    {
        //Log.i("draw", "OneSlope");
        //p1, x
        tempFloat[0] = y0 - boxThickness;

        //p1, y
        tempFloat[1] = x0 + boxThickness;

        //p2, x
        tempFloat[2] = y1 - boxThickness;

        //p2, y
        tempFloat[3] = x1 + boxThickness;

        //p3, x
        tempFloat[4] = y1 + boxThickness;

        //p3, y
        tempFloat[5] = x1 - boxThickness;

        //p4, x
        tempFloat[6] = y0 + boxThickness;

        //p4, y
        tempFloat[7] = x0 - boxThickness;

    }

    //Case where slope = -1
    else if (slopeZeroCase == false && undefinedSlopeCase == false && slopeOneCase == false && slopeNegOneCase == true)
    {
        Log.i("draw", "OneSlope");
        //p1, x
        tempFloat[0] = -y0 + boxThickness;

        //p1, y
        tempFloat[1] = -x0 + boxThickness;

        //p2, x
        tempFloat[2] = -y1 + boxThickness;

        //p2, y
        tempFloat[3] = -x1 + boxThickness;

        //p3, x
        tempFloat[4] = -y1 - boxThickness;

        //p3, y
        tempFloat[5] = -x1 - boxThickness;

        //p4, x
        tempFloat[6] = -y0 - boxThickness;

        //p4, y
        tempFloat[7] = -x0 - boxThickness;

    }

    //Allocate the wrapped buffers that OpenGL ES uses for drawing, buffers changed to
    //be allocated at class scope so that they're not re-allocated every time this
    //algorithm is run
    //ByteBuffer tempBoxByteBuffer = ByteBuffer.allocateDirect(tempFloat.length * 4);
    //tempBoxByteBuffer.order(ByteOrder.nativeOrder());
    //FloatBuffer boxFloatBuffer = tempBoxByteBuffer.asFloatBuffer();
    boxFloatBuffer.put(tempFloat);
    boxFloatBuffer.position(0);

    //Draw triangles using points p0, p1, and p2 for the first, and
    //p0, p3, and p2 for the second, filling in between.  See box
    //above for diagram of points.  Indices also changed to be allocated at class scope
    //short indices[] = {0, 1, 2, 0, 3, 2};
    //ByteBuffer tempIndiceBuffer = ByteBuffer.allocateDirect(indices.length * 2);
    //tempIndiceBuffer.order(ByteOrder.nativeOrder());
    //ShortBuffer indiceBuffer = tempIndiceBuffer.asShortBuffer();
    //indiceBuffer.put(indices);
    //indiceBuffer.position(0);

    gl.glVertexPointer(2, GL10.GL_FLOAT, 0, boxFloatBuffer);
    //gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 2);

    gl.glDrawElements(GL10.GL_TRIANGLES, indices.length, GL10.GL_UNSIGNED_SHORT, indiceBuffer);

}

This particular implementation was done so that I could have a filled-in box, which is not a default OpenGL ES capability. What I did, instead, was draw two triangles. The math includes several special cases, a zero slope, a one slope, an undefined slope, a slope is greater than 0 but less than one or less than zero but greater than negative one case, or a slope is greater than one or less than negative one case. All you have to do is draw a line loop instead of a triangle between each set of points, and you'll have a non-filled box.

share|improve this answer
    
I haven't looked at this code in a while, but it could use some improvement. It works, but there are cases that could be eliminated to save some code space. – moscro Dec 29 '10 at 0:03
    
if any answer helps you out do accept it by checking the arrow on the left side of answer. – Javanator Feb 7 '11 at 11:31

workaround : instead of drawing rectangle draw a line but set stroke width for paint.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.