# How to calculate rotation angle from retangle points?

I have 4 points `1`,`2`,`3`,`4` that closes a rectangle.

The points are in a array in this following way: `x1` `y1` `x2` `y2` `x3` `y3` `x4` `y4`

The problem I have is that the rectangle can be rotated in a angle.

How can I calculate the original points (gray outline), and the angle?

I'm trying to reproduce this effect in javascript+css3-transform, so I need to first know the straight dimensions and then rotate with the css.

I just know if the retangle is straight by comparing points e.g. `y1==y2`

``````if(x1==x4 && x2==x3 && y1==y2 && y4==y3){

retangle.style.top = y1;
retangle.style.left = x1;
retangle.style.width = x2-x1;
retangle.style.height = y4-y1;
retangle.style.transform = "rotate(?deg)";

}
``````
-

You can use any coordinate pair on the same side to calculate the rotation angle. Note that mathematic angles normally assume 0 as long the +ve X axis and increase by rotating anti–clockwise (so along the +ve Y axis is 90°, -ve X axis is 180° and so on).

Also, javascript trigonometry functions return values in radians that must be converted to degrees before being used in a CSS transform.

If the shape is not rotated more than 90°, then life is fairly simple and you can use the tanget ratio of a right angle triangle:

``````tan(angle) = length of opposite side / length of adjacent side
``````

For the OP, the best corners to use are 1 and 4 so that rotation is kept in the first quadrant and clockwise (per the draft CSS3 spec). In javascript terms:

``````var rotationRadians = Math.atan((x1 - x4) / (y1 - y4));
``````

To convert to degrees:

``````var RAD2DEG = 180 / Math.PI;
``````

If the rotation is more than 90°, you will need to adjust the angle. e.g. where the angle is greater than 90° but less than 180°, you'll get a -ve result from the above and need to add 180°:

``````  rotationDegrees += 180;
``````

Also, if you are using page dimentions, y coordinates increase going down the page, which is the opposite of the normal mathetmatic sense so you need to reverse the sense of `y1 - y4` in the above.

### Edit

Based on the orientation of points in the OP, the following is a general function to return the center and clockwise rotation of the rectangle in degrees. That's all you should need, though you can rotate the corners to be "level" yourself if you wish. You can apply trigonometric functions to calculate new corners or just do some averages (similar to Ian's answer).

``````/*  General case solution for a rectangle
*
*  Given coordinages of [x1, y1, x2, y2, x3, y3, x4, y4]
*  where the corners are:
*            top left    : x1, y1
*            top right   : x2, y2
*            bottom right: x3, y3
*            bottom left : x4, y4
*
*  The centre is the average top left and bottom right coords:
*  center: (x1 + x3) / 2 and (y1 + y3) / 2
*
*  Clockwise rotation: Math.atan((x1 - x4)/(y1 - y4)) with
*
*  Note that if using page coordinates, y is +ve down the page which
*  is the reverse of the mathematic sense so y page coordinages
*  should be multiplied by -1 before being given to the function.
*  (e.g. a page y of 400 should be -400).
*/
function getRotation(coords) {
// Get center as average of top left and bottom right
var center = [(coords[0] + coords[4]) / 2,
(coords[1] + coords[5]) / 2];

// Get differences top left minus bottom left
var diffs = [coords[0] - coords[6], coords[1] - coords[7]];

// Get rotation in degrees
var rotation = Math.atan(diffs[0]/diffs[1]) * 180 / Math.PI;

// Adjust for 2nd & 3rd quadrants, i.e. diff y is -ve.
if (diffs[1] < 0) {
rotation += 180;

// i.e. diff x is -ve, diff y is +ve
} else if (diffs[0] < 0) {
rotation += 360;
}
// return array of [[centerX, centerY], rotation];
return [center, rotation];
}
``````
-
thanks a lot, I did not get the <90 angles, can you explain me? seem to be working fine, with some glitches, jsfiddle.net/Victornpb/nBKAP I also confused the matriz order, but I made the changes. acctually I'm tring to convert Collada to js+css, but seems a long road, I have no idea how to deal with Z coordinates. –  Vitim.us Oct 22 '12 at 4:17
The point order and orientation in the fiddle is different to your post. It seems you are using cartesian coordinates, so where in the above I have `coords[0] - coords[6]` you need `x3 - x4` and where I have `coords[1] - coords[7]` you need `y3 - y4`. –  RobG Oct 22 '12 at 4:38
yeah Google sketchup uses cartesian. So instead of inverting axes I just swapped the top property to bottom to match things. And the rect points is actually in another order, is actually bottom-right-counter-cw [3,2][4,1] not top-left-cw [1,2][4,3] –  Vitim.us Oct 22 '12 at 4:54

The center of the rectangle is right between two opposite corners:

``````cx = (x1 + x3) / 2
cy = (y1 + y3) / 2
``````

The size of the rectangle is the distance between two points:

``````w = sqrt(pow(x2-x1, 2) + pow(y2-y1, 2))
h = sqrt(pow(x3-x2, 2) + pow(y3-y2, 2))
``````

The corners of the gray rectangle can be calculated from the center and the size, for example the top left corner:

``````x = cx - w / 2
y = cy - h / 2
``````

The angle is the arctangent of a side of the square:

``````a = arctan2(y4 - y1, x4 - x1)
``````

(I'm not sure exactly which angle it returns, or what angle you expect for that matter, so you get to test a bit.)

-
The required angle is the clockwise rotation. If the OP is using page coordinates, the Y coordinate has the wrong sense (+ve down the page whereas Math trig functions epxect -ve in that direction), so your expression should be `Math.arctan2(-(y1 - y4), x1 - x4)`. But that will only work in the first quadrant and needs adjustment if the angle is greater than 90° (e.g. in the second quadrant it will give -45° instead of 135°, in the 3rd it will give -135° instead of 225°). –  RobG Oct 22 '12 at 3:22
@RobG: Judging from the blue coordinate system indicator in the picture, the OP is using a Y coordinate that is positive upwards, not downwards. I don't know if the op wants degrees or radians, or if he is limited to positive angles. –  Guffa Oct 22 '12 at 7:42

Um, middle school math?

``````var deg = 90 - Math.arctan((x2-x1) / (y2-y1));
``````

This is how you get the angle between the vertical pink line and the black line starting at the pink line intersection.

The dimensions can be calculated with the help of the Pythagoras theorem:

``````var width = Math.sqrt((x2-x1)^2 / (y2-y1)^2));
var height = Math.sqrt((x1-x4)^2) / (y4-y1)^2));
``````

The positional coordinates (left and top) are the averages of x1 and x3 and y1 and y3 respectively.

``````var left = Math.floor((x1 + x3) / 2);
var top = Math.floor((y1 + y3) / 2);
``````

You want to use the negative-margin trick.

``````var marginLeft = -Math.ceil(width / 2);
var marginTop = -Math.ceil(height / 2);
``````
-
Javascript trigonometry functions (such as `Math.atan`) return values in radians. There are `Math.PI` radians in 180°. Anyway, you're making life harder than it needs to be, the rotation of any side can be used, so the clockwise rotation angle (in radians) can be calulated from any coordinate pair on the same side, e.g.: `Math.asin((x4-y1)/(y1-y4))`. Note that where rotation exceeds 90°, further processing is required. –  RobG Oct 22 '12 at 0:33