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# drawing oblique rectangle in android

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:

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?

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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.

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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.

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