Home Programming Making a Clock with the New CSS sin() and cos() Trigonometry Features | CSS-Tips

Making a Clock with the New CSS sin() and cos() Trigonometry Features | CSS-Tips

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Making a Clock with the New CSS sin() and cos() Trigonometry Features | CSS-Tips

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CSS trigonometry capabilities are right here! Nicely, they’re should you’re utilizing the most recent variations of Firefox and Safari, that’s. Having this type of mathematical energy in CSS opens up a complete bunch of potentialities. On this tutorial, I assumed we’d dip our toes within the water to get a really feel for a few the newer capabilities: sin() and cos().

There are different trigonometry capabilities within the pipeline — together with tan() — so why focus simply on sin() and cos()? They occur to be excellent for the thought I take note of, which is to put textual content alongside the sting of a circle. That’s been lined right here on CSS-Tips when Chris shared an method that makes use of a Sass mixin. That was six years in the past, so let’s give it the bleeding edge therapy.

Right here’s what I take note of. Once more, it’s solely supported in Firefox and Safari in the mean time:

So, it’s not precisely like phrases forming a round form, however we’re putting textual content characters alongside the circle to type a clock face. Right here’s some markup we will use to kick issues off:

<div class="clock">
  <div class="clock-face">
    <time datetime="12:00">12</time>
    <time datetime="1:00">1</time>
    <time datetime="2:00">2</time>
    <time datetime="3:00">3</time>
    <time datetime="4:00">4</time>
    <time datetime="5:00">5</time>
    <time datetime="6:00">6</time>
    <time datetime="7:00">7</time>
    <time datetime="8:00">8</time>
    <time datetime="9:00">9</time>
    <time datetime="10:00">10</time>
    <time datetime="11:00">11</time>
  </div>
</div>

Subsequent, listed below are some tremendous primary types for the .clock-face container. I made a decision to make use of the <time> tag with a datetime attribute. 

.clock {
  --_ow: clamp(5rem, 60vw, 40rem);
  --_w: 88cqi;
  aspect-ratio: 1;
  background-color: tomato;
  border-radius: 50%;
  container-type: inline;
  show: grid;
  peak: var(--_ow);
  place-content: middle;
  place: relative;
  width var(--_ow);
}

I adorned issues a bit in there, however solely to get the essential form and background shade to assist us see what we’re doing. Discover how we save the width worth in a CSS variable. We’ll use that later. Not a lot to have a look at to date:

Large tomato colored circle with a vertical list of numbers 1-12 on the left.

It appears like some type of fashionable artwork experiment, proper? Let’s introduce a brand new variable, --_r, to retailer the circle’s radius, which is the same as half of the circle’s width. This fashion, if the width (--_w) modifications, the radius worth (--_r) may also replace — thanks to a different CSS math operate, calc():

.clock {
  --_w: 300px;
  --_r: calc(var(--_w) / 2);
  /* remainder of types */
}

Now, a little bit of math. A circle is 360 levels. We have now 12 labels on our clock, so need to place the numbers each 30 levels (360 / 12). In math-land, a circle begins at 3 o’clock, so midday is definitely minus 90 levels from that, which is 270 levels (360 - 90).

Let’s add one other variable, --_d, that we will use to set a diploma worth for every quantity on the clock face. We’re going to increment the values by 30 levels to finish our circle:

.clock time:nth-child(1) { --_d: 270deg; }
.clock time:nth-child(2) { --_d: 300deg; }
.clock time:nth-child(3) { --_d: 330deg; }
.clock time:nth-child(4) { --_d: 0deg; }
.clock time:nth-child(5) { --_d: 30deg; }
.clock time:nth-child(6) { --_d: 60deg; }
.clock time:nth-child(7) { --_d: 90deg; }
.clock time:nth-child(8) { --_d: 120deg; }
.clock time:nth-child(9) { --_d: 150deg; }
.clock time:nth-child(10) { --_d: 180deg; }
.clock time:nth-child(11) { --_d: 210deg; }
.clock time:nth-child(12) { --_d: 240deg; }

OK, now’s the time to get our arms soiled with the sin() and cos() capabilities! What we need to do is use them to get the X and Y coordinates for every quantity so we will place them correctly across the clock face.

The method for the X coordinate is radius + (radius * cos(diploma)). Let’s plug that into our new --_x variable:

--_x: calc(var(--_r) + (var(--_r) * cos(var(--_d))));

The method for the Y coordinate is radius + (radius * sin(diploma)). We have now what we have to calculate that:

--_y: calc(var(--_r) + (var(--_r) * sin(var(--_d))));

There are a number of housekeeping issues we have to do to arrange the numbers, so let’s put some primary styling on them to ensure they’re completely positioned and positioned with our coordinates:

.clock-face time {
  --_x: calc(var(--_r) + (var(--_r) * cos(var(--_d))));
  --_y: calc(var(--_r) + (var(--_r) * sin(var(--_d))));
  --_sz: 12cqi;
  show: grid;
  peak: var(--_sz);
  left: var(--_x);
  place-content: middle;
  place: absolute;
  prime: var(--_y);
  width: var(--_sz);
}

Discover --_sz, which we’ll use for the width and peak of the numbers in a second. Let’s see what now we have to date.

Large tomato colored circle with off-centered hour number labels along its edge.

This positively appears extra like a clock! See how the top-left nook of every quantity is positioned on the right place across the circle? We have to “shrink” the radius when calculating the positions for every quantity. We are able to deduct the scale of a quantity (--_sz) from the scale of the circle (--_w), earlier than we calculate the radius:

--_r: calc((var(--_w) - var(--_sz)) / 2);
Large tomato colored circle with hour number labels along its rounded edge.

A lot better! Let’s change the colours, so it appears extra elegant:

A white clock face with numbers against a dark gray background. The clock has no arms.

We might cease proper right here! We completed the purpose of putting textual content round a circle, proper? However what’s a clock with out arms to indicate hours, minutes, and seconds?

Let’s use a single CSS animation for that. First, let’s add three extra components to our markup,

<div class="clock">
  <!-- after <time>-tags -->
  <span class="arm seconds"></span>
  <span class="arm minutes"></span>
  <span class="arm hours"></span>
  <span class="arm middle"></span>
</div>

Then some widespread markup for all three arms. Once more, most of that is simply ensure that the arms are completely positioned and positioned accordingly:

.arm {
  background-color: var(--_abg);
  border-radius: calc(var(--_aw) * 2);
  show: block;
  peak: var(--_ah);
  left: calc((var(--_w) - var(--_aw)) / 2);
  place: absolute;
  prime: calc((var(--_w) / 2) - var(--_ah));
  rework: rotate(0deg);
  transform-origin: backside;
  width: var(--_aw);
}

We’ll use the identical animation for all three arms:

@keyframes flip {
  to {
    rework: rotate(1turn);
  }
}

The one distinction is the time the person arms take to make a full flip. For the hours arm, it takes 12 hours to make a full flip. The animation-duration property solely accepts values in milliseconds and seconds. Let’s persist with seconds, which is 43,200 seconds (60 seconds * 60 minutes * 12 hours).

animation: flip 43200s infinite;

It takes 1 hour for the minutes arm to make a full flip. However we wish this to be a multi-step animation so the motion between the arms is staggered slightly than linear. We’ll want 60 steps, one for every minute:

animation: flip 3600s steps(60, finish) infinite;

The seconds arm is virtually the identical because the minutes arm, however the length is 60 seconds as a substitute of 60 minutes:

animation: flip 60s steps(60, finish) infinite;

Let’s replace the properties we created within the widespread types:

.seconds {
  --_abg: hsl(0, 5%, 40%);
  --_ah: 145px;
  --_aw: 2px;
  animation: flip 60s steps(60, finish) infinite;
}
.minutes {
  --_abg: #333;
  --_ah: 145px;
  --_aw: 6px;
  animation: flip 3600s steps(60, finish) infinite;
}
.hours {
  --_abg: #333;
  --_ah: 110px;
  --_aw: 6px;
  animation: flip 43200s linear infinite;
}

What if we need to begin on the present time? We want slightly little bit of JavaScript:

const time = new Date();
const hour = -3600 * (time.getHours() % 12);
const minutes = -60 * time.getMinutes();
app.fashion.setProperty('--_dm', `${minutes}s`);
app.fashion.setProperty('--_dh', `${(hour+minutes)}s`);

I’ve added id="app" to the clockface and set two new customized properties on it that set a unfavorable animation-delay, as Mate Marschalko did when he shared a CSS-only clock. The getHours() technique of JavaScipt’s Date object is utilizing the 24-hour format, so we use the the rest operator to transform it into 12-hour format.

Within the CSS, we have to add the animation-delay as properly:

.minutes {
  animation-delay: var(--_dm, 0s);
  /* different types */
}

.hours {
  animation-delay: var(--_dh, 0s);
  /* different types */
}

Only one thing more. Utilizing CSS @helps and the properties we’ve already created, we will present a fallback to browsers that don’t supprt sin() and cos(). (Thanks, Temani Afif!):

@helps not (left: calc(1px * cos(45deg))) {
  time {
    left: 50% !essential;
    prime: 50% !essential;
    rework: translate(-50%,-50%) rotate(var(--_d)) translate(var(--_r)) rotate(calc(-1*var(--_d)))
  }
}

And, voilà! Our clock is finished! Right here’s the ultimate demo yet another time. Once more, it’s solely supported in Firefox and Safari in the mean time.

What else can we do?

Simply messing round right here, however we will shortly flip our clock right into a round picture gallery by changing the <time> tags with <img> then updating the width (--_w) and radius (--_r) values:

Let’s strive yet another. I discussed earlier how the clock seemed type of like a contemporary artwork experiment. We are able to lean into that and re-create a sample I noticed on a poster (that I sadly didn’t purchase) in an artwork gallery the opposite day. As I recall, it was known as “Moon” and consisted of a bunch of dots forming a circle.

A large circle formed out of a bunch of smaller filled circles of various earthtone colors.

We’ll use an unordered checklist this time because the circles don’t observe a specific order. We’re not even going to place all of the checklist objects within the markup. As a substitute, let’s inject them with JavaScript and add a number of controls we will use to govern the ultimate outcome.

The controls are vary inputs (<enter kind="vary">) which we’ll wrap in a <type> and pay attention for the enter occasion.

<type id="controls">
  <fieldset>
    <label>Variety of rings
      <enter kind="vary" min="2" max="12" worth="10" id="rings" />
    </label>
    <label>Dots per ring
      <enter kind="vary" min="5" max="12" worth="7" id="dots" />
    </label>
    <label>Unfold
      <enter kind="vary" min="10" max="40" worth="40" id="unfold" />
    </label>
  </fieldset>
</type>

We’ll run this technique on “enter”, which is able to create a bunch of <li> components with the diploma (--_d) variable we used earlier utilized to every one. We are able to additionally repurpose our radius variable (--_r) .

I additionally need the dots to be completely different colours. So, let’s randomize (properly, not utterly randomized) the HSL shade worth for every checklist merchandise and retailer it as a brand new CSS variable, --_bgc:

const replace = () => {
  let s = "";
  for (let i = 1; i <= rings.valueAsNumber; i++) {
    const r = unfold.valueAsNumber * i;
    const theta = coords(dots.valueAsNumber * i);
    for (let j = 0; j < theta.size; j++) {
      s += `<li fashion="--_d:${theta[j]};--_r:${r}px;--_bgc:hsl(${random(
        50,
        25
      )},${random(90, 50)}%,${random(90, 60)}%)"></li>`;
    }
  }
  app.innerHTML = s;
}

The random() technique picks a worth inside an outlined vary of numbers:

const random = (max, min = 0, f = true) => f ? Math.flooring(Math.random() * (max - min) + min) : Math.random() * max;

And that’s it. We use JavaScript to render the markup, however as quickly because it’s rendered, we don’t actually need it. The sin() and cos() capabilities assist us place all of the dots in the appropriate spots.

Closing ideas

Inserting issues round a circle is a reasonably primary instance to display the powers of trigonometry capabilities like sin() and cos(). But it surely’s actually cool that we’re getting fashionable CSS options that present new options for previous workarounds I’m positive we’ll see far more attention-grabbing, complicated, and inventive use circumstances, particularly as browser help involves Chrome and Edge.

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