Calculate the sine, cosine, tangent, and more in CSS.
Trigonometric functions
In CSS it's possible to write mathematical expressions. At the base sits the calc()
function to do calculations, but most likely you've also heard of min()
, max()
, and clamp()
as well.
Joining these functions are the trigonometric functions sin()
, cos()
, tan()
, asin()
, acos()
, atan()
, and atan2()
. These functions are defined in the CSS Values and Units Module Level 4 and are available in all browsers.
sin()
, cos()
, and tan()
cos()
,tan()
The core three trig functions are:
cos()
: Returns the cosine of an angle, which is a value between-1
and1
.sin()
: Returns the sine of an angle, which is a value between-1
and1
.tan()
: Returns the tangent of an angle, which is a value between−∞
and+∞
.
Unlike their JavaScript counterparts, these functions accept both angles and radians as their argument.
In the following demo, these functions are used to draw the lines that make up the triangle surrounding the set --angle
:
- The "hypotenuse" (yellow line) is a line from the center of the circle to the position of the dot. Its length is equal to the
--radius
of the circle. - The "adjacent" (red line) is a line from the center of the circle along the X-axis. Its length is equal to the
--radius
multiplied by the cosine of the--angle
. - The "opposite" (blue line) is a line from the center of the dot along the Y-axis. Its length is equal to the
--radius
multiplied by the sine of the--angle
. - The
tan()
function of the--angle
is used to draw the green line from the dot towards the X-axis.
asin()
, acos()
, atan()
, and atan2()
The arc or inverse counterparts to sin()
, cos()
, and tan()
are asin()
, acos()
, and atan()
respectively. These functions do the calculation in the opposite direction: they take a numeric value as their argument and return the corresponding angle for it.
Finally there's atan2()
which accepts two arguments A
and B
. The function returns the angle between the positive X-axis and the point (B,A)
.
Examples
There are various use-cases for these functions. What follows is a small selection.
Move items on a circular path around a central point
In the following demo, the dots revolve around a central point. Instead of rotating each dot around its own center and then moving it outwards, each dot is translated on the X and Y axes. The distances on the X and Y axes are determined by taking the cos()
and, respectively, the sin()
of the --angle
into account.
:root {
--radius: 20vmin;
}
.dot {
--angle: 30deg;
translate: /* Translation on X-axis */
calc(cos(var(--angle)) * var(--radius))
/* Translation on Y-axis */
calc(sin(var(--angle)) * var(--radius) * -1)
;
}
To distribute the dots evenly around the central point, each dot is given an additional offset based on its nth-child
index. For example, if there are three dots, there's a distance of 120deg
(= 360deg / 3
) between each dot.
- The first child element out of three gets offset by
0 x 120deg
=0deg
. - The second child element out of three gets offset by
1 x 120deg
=120deg
. - The third child element out of three gets offset by
2 x 120deg
=240deg
.
Rotate an element to face its origin
The atan2()
function calculates the relative angle from one point to another. The function accepts two comma-separated values as its parameters: the y
and x
position of the other point, relative to the originating point which sits at origin 0,0
.
With the calculated value it's possible to rotate elements so that they face each other, by using the Individual Transform Properties.
In the following example, the boxes are rotated so that they face the location of the mouse. The mouse position is synced to a custom property through JavaScript.
div.box {
--my-x: 200;
--my-y: 300;
/* Position the box inside its parent */
position: absolute;
width: 50px;
aspect-ratio: 1;
translate: calc((var(--my-x) * 1px)) calc(var(--my-y) * 1px);
/* Rotate so that the box faces the mouse position */
/* For this, take the box its own position and size (25 = half the width) into account */
rotate: atan2(
calc((var(--mouse-x) - var(--my-x) - 25) * 1),
calc((var(--mouse-y) - var(--my-y) - 25) * -1)
);
}
Community highlight
As demonstrated in this Animated Möbius strip by Ana Tudor, cos()
and sin()
can be used for more than just translations. Here their outcome is used to manipulate the the s
and l
components of the hsl()
color function.