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Achieving typographic effects with the canvas tag

By Michael Deal
Originally published March 1, 2011

Summary

An introduction to typographic effects using the <canvas> element.

My background

The <canvas> element entered my awareness in 2006 when Firefox v2.0 was released. An article on Ajaxian describing the transformation matrix inspired me to create my first <canvas> web-app, Color Sphere (2007). This immersed me into the world of colors and graphic primitives, inspiring the creation of Sketchpad (2007-2008) in an effort to put together an application better than Paint in the browser.

These experiments eventually led to the creation of the startup Mugtug with my long-time friend Charles Pritchard. We are developing Darkroom in HTML5 <canvas>. Darkroom is a non-destructive photo-sharing app, combining the powers of pixel-based filters with vector-based typography and drawing.

Introduction

typ01-canvas.png

The <canvas> element brings Javascript programmers full control of the colors, vectors, and pixels on their screens—the visual makeup of the monitor.

The following examples deal with one area in <canvas> that hasn’t gotten much attention: creating text-effects. The variety of text-effects that can be created in <canvas> is as vast as you can imagine; these demos cover a sub-section of what is possible. Although we’re dealing with text in this article, the methods can be applied to any vector objects, creating exciting visuals in games and other applications, such as:

Text-Shadows in <canvas>
CSS-like text-effects in <canvas> creating clipping masks, finding metrics in <canvas>, and using the shadow property
Zebra-reflection/chaining effects
Photoshop-like text-effects in <canvas> using globalCompositeOperation, createLinearGradient, createPattern
Outer shadows in <canvas>
Revealing a little known feature using clockwise vs. anti-clockwise winding to create the inverse of a drop-shadow (the inner-shadow)
Spaceage-generative effect
Generative based text-effect in <canvas> using hsl() color-cycling and window.requestAnimationFrame to create the feeling of motion

Text-Shadows in Canvas

One of my favorite additions to CSS3 (along with border-radius, web-gradients, and others) is the ability to create shadows. It’s important to realize the differences between CSS and <canvas> shadows, specifically:

CSS uses two methods, box-shadow for box elements such as div, span, and so on, and text-shadow for text content.

<canvas> has one type of shadow, used for all the vector objects: ctx.moveTo, ctx.lineTo, ctx.bezierCurveTo, ctx.quadradicCurveTo, ctx.arc, ctx.rect, ctx.fillText, ctx.strokeText, and so on. To create a shadow in <canvas>, tap into these four properties:

ctx.shadowColor = “red” // string
Color of the shadow; RGB, RGBA, HSL, HEX, and other inputs are valid
ctx.shadowOffsetX = 0; // integer
Horizontal distance of the shadow, in relation to the text
ctx.shadowOffsetY = 0; // integer
Vertical distance of the shadow, in relation to the text
ctx.shadowBlur = 10; // integer
Blurring effect to the shadow; the larger the value, the greater the blur

To get things started, let’s see how <canvas> can emulate CSS effects. Searching through Google images for “css text-shadow” led to a few great demos for us to emulate, Line25, Stereoscopic, and Shadow 3D.

typ02-css3d.png

The stereoscopic 3D effect (see Anaglyph image for more) is an example of a simple line of code put to great use. With the following line of CSS, we can create the illusion of depth when viewed with 3D red/cyan glasses (the kind they give you at 3D movies):

 text-shadow: -0.06em 0 0 red, 0.06em 0 0 cyan;

There are two things to notice when converting this string to <canvas>:

(1) There is no shadow-blur (the third value), so there is no reason to actually run shadow, as fillText would create the same results:

 var text = "Hello world!"
 ctx.fillStyle = "#000";
 ctx.fillText(text, -7, 0);
 ctx.fillStyle = "red";
 ctx.fillText(text, 0, 0);
 ctx.fillStyle = "cyan";
 ctx.fillText(text, 7, 0);

(2) The em unit isn’t supported in <canvas> so it must be converted to px (pixels). We can find the conversion ratio for converting between PT, PC, EM, EX, PX and so forth by creating an element with the same font-properties in the DOM and setting the width to the format to be measured. For instance, to capture the EM-to-PX conversion, we would measure the DOM element with a height of 1em; the resulting offsetHeight would be how many PXs are in each EM.

 var font = "20px sans-serif";
 var d = document.createElement("span");
 d.style.cssText = "font: " + font + " height: 1em; display: block";
 // the value to multiply PXs by to convert to EMs
 var EM2PX = 1 / d.offsetHeight;

Preventing alpha-multiplication

In a more complex example, such as the Neon effect found on Line25, the shadowBlur property must be used to emulate the effect properly. Because the Neon effect relies on multiple shadows, we run into a problem: in <canvas> each vector object can only have one shadow. So, in order to draw multiple shadows, you must draw multiple versions of the text on top of itself. This results in alpha multiplication, and ultimately jagged edges.

typ03-neon.png

I tried running ctx.fillStyle = "rgba(0,0,0,0)" or "transparent" to hide the text, while displaying the shadow. However, this attempt was futile; since the shadow is a multiplication of the fillStyle alpha, the shadow can never be more opaque than the fillStyle.

Luckily, there is a way around this. We can draw the shadow offset from the text, keeping them separated (so they’re not overlapping), and thereby hiding the text off the side of the screen:

 var text = "Hello world!"
 var blur = 10;
 var width = ctx.measureText(text).width + blur * 2;
 ctx.textBaseline = "top";
 ctx.shadowColor = "#000";
 ctx.shadowOffsetX = width;
 ctx.shadowOffsetY = 0;
 ctx.shadowBlur = blur;
 ctx.fillText(text, -width, 0);

Clipping around a text block

To clean this up a bit we can prevent the fillText from being drawn in the first place (while allowing the shadow to be drawn) by adding a clipping path. In order to create a clipping path surrounding the text, we need to know the height of the text (called the "em-height"; historically, the height of the letter M) and the width of the text. We can get the width using ctx.measureText().width, however, ctx.measureText().height doesn’t exist.

Luckily, through CSS hack-ardry (see Typographic Metrics for more ways to fix older implementations of <canvas> using CSS measurements), we can find the height of the text by measuring the offsetHeight of a <span> with the same font-properties:

 var d = document.createElement("span");
 d.font = ;20px arial";
 d.textContent = "Hello world!";
 var emHeight = d.offsetHeight;

From there, we can create a rectangle to use as a clipping path, enclosing the shadow while removing the dummy shape.

 ctx.rect(0, 0, width, emHeight);
 ctx.clip();

Tying it all together, and optimizing as we go: if a shadow has no blur, fillText can be used to the same effect, saving us from setting up the clipping mask:

 var width = ctx.measureText(text).width;
 var style = shadowStyles[text];
 // add a background to the current effect
 ctx.fillStyle = style.background;
 ctx.fillRect(0, offsetY, ctx.canvas.width, textHeight - 1)
 // parse text-shadows from css
 var shadows = parseShadow(style.shadow);
 // loop through the shadow collection
 var n = shadows.length; while(n--) {
     var shadow = shadows[n];
     var totalWidth = width + shadow.blur * 2;
     ctx.save();
     ctx.beginPath();
     ctx.rect(offsetX - shadow.blur, offsetY, offsetX + totalWidth, textHeight);
     ctx.clip();
     if (shadow.blur) { // just run shadow (clip text)
         ctx.shadowColor = shadow.color;
         ctx.shadowOffsetX = shadow.x + totalWidth;
         ctx.shadowOffsetY = shadow.y;
         ctx.shadowBlur = shadow.blur;
         ctx.fillText(text, -totalWidth + offsetX, offsetY + metrics.top);
     } else { // just run pseudo-shadow
         ctx.fillStyle = shadow.color;
         ctx.fillText(text, offsetX + (shadow.x||0), offsetY - (shadow.y||0) + metrics.top);
     }
     ctx.restore();
 }
 // drawing the text in the foreground
 if (style.color) {
     ctx.fillStyle = style.color;
     ctx.fillText(text, offsetX, offsetY + metrics.top);
 }
 // jump to next em-line
 ctx.translate(0, textHeight);

Since you’re not going to want to enter all these <canvas> commands manually, I’ve included a simple text-shadow parser in the demo source; this way you can feed it CSS commands and have it generate <canvas> commands. Now, our <canvas> elements have a whole range of styles they can tie into. These same shadow-effects can be used on any vector object, from WebFonts to complex shapes imported from SVGs, to generative vector shapes, and so on!

typ04-multi.png

View Text-Shadows in <canvas> effects.

Intermission (a tangent on pixel-pushing)

In writing this section of the article, the Stereoscopic example made me curious. How hard it would be to create a 3D-movie-screen effect using <canvas> and two images taken from slightly different perspectives? Apparently, not too hard. The following kernel combines the red channel of the first image (data) with the cyan channel of the second image (data2):

 data[i] = data[i] * 255 / 0xFF;
 data[i+1] = 255 * data2[i+1] / 0xFF;
 data[i+2] = 255 * data2[i+2] / 0xFF;

Visit the Stereoscopic demo to see how to create images to be enhanced with 3D glasses (cyan/magenta). Now, someone just needs to duct-tape two iPhones to their forehead, click “record video” at the same time, and we could make our own 3D movies in HTML5. Any volunteers?

typ05-stereo.png

Neon-rainbow, zebra-reflection — chaining effects

Chaining multiple effects in <canvas> can be simple, but a basic knowledge of the globalCompositeOperation (GCO) is required. To compare the operations to GIMP (or Photoshop): there are 12 GCOs in <canvas>: darker and lighter can be thought of as layer blend-modes; the other 10 operations are applied to the layers as alpha masks (one layer removes the pixels of the other layer). The globalCompositeOperation ties layers (or in our case, strings of code) together, combining them in new and exciting ways:

typ06-global.png

The globalCompositeOperation chart shows GCO modes at work; this chart uses a large portion of the color-spectrum and multiple levels of alpha transparency in order to see in detail what to expect. I would recommend checking out Mozilla’s globalCompositeOperation reference for textual descriptions. For further research, you can learn how the operation works in Porter Duff’s Compositing Digital Images.

My favorite mode is globalCompositeOperation="lighter". Lighter mixes the appended pixels similar to how light mixes; when red, green, and white light are at full intensity, we see white light. It’s an exciting feature to play around with, especially when the <canvas> is set to a low globalAlpha, enabling finer control and smoother edges. Lighter has been put to many uses, my recent favorite being an HTML5 desktop background creator found at WeaveSilk. One of my demos, Breathing Galaxies (JS1k), also uses the lighter mode. Drawing patterns from these two examples, you start to see what effect this mode yields.

NOTE: There is some missing support for some of the GCO modes across the browsers that needs to be sorted out. There are six modes that generally work across browsers: source-over, source-atop, destination-over, destination-out, lighter, and xor. For more information visit globalCompositeOperation browser handling.

Neon-Rainbow Jitter Effect

In the following demo, we’re going to achieve a Photoshop-like neon-rainbow-glow with a jittered outline by chaining effects together using the globalCompositeOperation (source-in, lighter, and darker). This demo is a progression of the “Text-Shadows in <canvas>” demo, using the same strategy in separating the shadow from the text (see previous section):

typ07-jitter.png

View Neon-Rainbow Jitter effect.

 function neonLightEffect() {
   var text = "alert('"+String.fromCharCode(0x2665)+"')";
   var font = "120px Futura, Helvetica, sans-serif";
   var jitter = 25; // the distance of the maximum jitter
   var offsetX = 30;
   var offsetY = 70;
   var blur = getBlurValue(100);
   // save state
   ctx.save();
   ctx.font = font;
   // calculate width + height of text-block
   var metrics = getMetrics(text, font);
   // create clipping mask around text-effect
   ctx.rect(offsetX - blur/2, offsetY - blur/2,
            offsetX + metrics.width + blur, metrics.height + blur);
   ctx.clip();
   // create shadow-blur to mask rainbow onto (since shadowColor doesn't accept gradients)
   ctx.save();
   ctx.fillStyle = "#fff";
   ctx.shadowColor = "rgba(0,0,0,1)";
   ctx.shadowOffsetX = metrics.width + blur;
   ctx.shadowOffsetY = 0;
   ctx.shadowBlur = blur;
   ctx.fillText(text, -metrics.width + offsetX - blur, offsetY + metrics.top);
   ctx.restore();
   // create the rainbow linear-gradient
   var gradient = ctx.createLinearGradient(0, 0, metrics.width, 0);
   gradient.addColorStop(0, "rgba(255, 0, 0, 1)");
   gradient.addColorStop(0.15, "rgba(255, 255, 0, 1)");
   gradient.addColorStop(0.3, "rgba(0, 255, 0, 1)");
   gradient.addColorStop(0.5, "rgba(0, 255, 255, 1)");
   gradient.addColorStop(0.65, "rgba(0, 0, 255, 1)");
   gradient.addColorStop(0.8, "rgba(255, 0, 255, 1)");
   gradient.addColorStop(1, "rgba(255, 0, 0, 1)");
   // change composite so source is applied within the shadow-blur
   ctx.globalCompositeOperation = "source-atop";
   // apply gradient to shadow-blur
   ctx.fillStyle = gradient;
   ctx.fillRect(offsetX - jitter/2, offsetY,
                metrics.width + offsetX, metrics.height + offsetY);
   // change composite to mix as light
   ctx.globalCompositeOperation = "lighter";
   // multiply the layer
   ctx.globalAlpha = 0.7
   ctx.drawImage(ctx.canvas, 0, 0);
   ctx.drawImage(ctx.canvas, 0, 0);
   ctx.globalAlpha = 1
   // draw white-text ontop of glow
   ctx.fillStyle = "rgba(255,255,255,0.95)";
   ctx.fillText(text, offsetX, offsetY + metrics.top);
   // created jittered stroke
   ctx.lineWidth = 0.80;
   ctx.strokeStyle = "rgba(255,255,255,0.25)";
   var i = 10; while(i--) {
       var left = jitter / 2 - Math.random() * jitter;
       var top = jitter / 2 - Math.random() * jitter;
       ctx.strokeText(text, left + offsetX, top + offsetY + metrics.top);
   }
   ctx.strokeStyle = "rgba(0,0,0,0.20)";
   ctx.strokeText(text, offsetX, offsetY + metrics.top);
   ctx.restore();
 };

Zebra reflection effect

The zebra reflection effect was inspired by WebDesignerWall's excellent resource on how to spice up your page with CSS. This takes the idea a little bit further, creating a “reflection” for the text such as you might see in iTunes. The effect combines fillColor (white), createPattern (zebra.png), and linearGradient (shine); this illustrates the ability to apply multiple fill types to each vector object:

typ08-zebra.png

View zebra reflection effect.

 function sleekZebraEffect() {
   // inspired by - http://www.webdesignerwall.com/demo/css-gradient-text/
   var text = "Sleek Zebra...";
   var font = "100px Futura, Helvetica, sans-serif";

   // save state
   ctx.save();
   ctx.font = font;

   // getMetrics calculates:
   // width + height of text-block
   // top + middle + bottom baseline
   var metrics = getMetrics(text, font);
   var offsetRefectionY = -20;
   var offsetY = 70;
   var offsetX = 60;

   // throwing a linear-gradient in to shine up the text
   var gradient = ctx.createLinearGradient(0, offsetY, 0, metrics.height + offsetY);
   gradient.addColorStop(0.1, '#000');
   gradient.addColorStop(0.35, '#fff');
   gradient.addColorStop(0.65, '#fff');
   gradient.addColorStop(1.0, '#000');
   ctx.fillStyle = gradient
   ctx.fillText(text, offsetX, offsetY + metrics.top);

   // draw reflected text
   ctx.save();
   ctx.globalCompositeOperation = "source-over";
   ctx.translate(0, metrics.height + offsetRefectionY)
   ctx.scale(1, -1);
   ctx.font = font;
   ctx.fillStyle = "#fff";
   ctx.fillText(text, offsetX, -metrics.height - offsetY + metrics.top);
   ctx.scale(1, -1);

   // cut the gradient out of the reflected text
   ctx.globalCompositeOperation = "destination-out";
   var gradient = ctx.createLinearGradient(0, offsetY, 0, metrics.height + offsetY);
   gradient.addColorStop(0.0, 'rgba(0,0,0,0.65)');
   gradient.addColorStop(1.0, '#000');
   ctx.fillStyle = gradient;
   ctx.fillRect(offsetX, offsetY, metrics.width, metrics.height);

   // restore back to original transform state
   ctx.restore();

   // using source-atop to allow the transparent .png to show through to the gradient
   ctx.globalCompositeOperation = "source-atop";

   // creating pattern from <image> sourced.
   ctx.fillStyle = ctx.createPattern(image, 'repeat');

   // fill the height of two em-boxes, to encompass both normal and reflected state
   ctx.fillRect(offsetX, offsetY, metrics.width, metrics.height * 2);
   ctx.restore();
 };

Inner/outer shadows in canvas

The <canvas> spec doesn’t touch on the subject of inner vs. outer shadows. In fact, at first appearance, you may expect that inner shadow isn’t supported. This is not the case, it’s just a bit tricker to enable. As proposed in a recent post from F1LT3R, you can create inner-shadows using the unique properties of clockwise vs. anti-clockwise winding rules. To do this, you create an inner-shadow by drawing a container rectangle and then, using opposite winding rules, draw a cutout shape, creating the inverse of the shape.

The following example allows for the inner-shadow and fillStyle to be stylized with color+gradient+pattern simultaneously. You can specify pattern rotation individually; notice the zebra stripes are now perpendicular to each other. A clipping mask the size of the bounding-box is used, removing the need for a super-large container to enclose the cutout shape, and improving the speed by preventing the unnecessary parts of the shadow from being processed.

typ09-inner.png

View inner-shadow effect.

 function innerShadow() {

   function drawShape() { // draw anti-clockwise
     ctx.arc(0, 0, 100, 0, Math.PI * 2, true); // Outer circle
     ctx.moveTo(70, 0);
     ctx.arc(0, 0, 70, 0, Math.PI, false); // Mouth
     ctx.moveTo(-20, -20);
     ctx.arc(30, -30, 10, 0, Math.PI * 2, false); // Left eye
     ctx.moveTo(140, 70);
     ctx.arc(-20, -30, 10, 0, Math.PI * 2, false); // Right eye
   };

   var width = 200;
   var offset = width + 50;
   var innerColor = "rgba(0,0,0,1)";
   var outerColor = "rgba(0,0,0,1)";

   ctx.translate(150, 170);

   // apply inner-shadow
   ctx.save();
   ctx.fillStyle = "#000";
   ctx.shadowColor = innerColor;
   ctx.shadowBlur = getBlurValue(120);
   ctx.shadowOffsetX = -15;
   ctx.shadowOffsetY = 15;

   // create clipping path (around blur + shape, preventing outer-rect blurring)
   ctx.beginPath();
   ctx.rect(-offset/2, -offset/2, offset, offset);
   ctx.clip();

   // apply inner-shadow (w/ clockwise vs. anti-clockwise cutout)
   ctx.beginPath();
   ctx.rect(-offset/2, -offset/2, offset, offset);
   drawShape();
   ctx.fill();
   ctx.restore();

   // cutout temporary rectangle used to create inner-shadow
   ctx.globalCompositeOperation = "destination-out";
   ctx.fill();

   // prepare vector paths
   ctx.beginPath();
   drawShape();

   // apply fill-gradient to inner-shadow
   ctx.save();
   ctx.globalCompositeOperation = "source-in";
   var gradient = ctx.createLinearGradient(-offset/2, 0, offset/2, 0);
   gradient.addColorStop(0.3, '#ff0');
   gradient.addColorStop(0.7, '#f00');
   ctx.fillStyle = gradient;
   ctx.fill();

   // apply fill-pattern to inner-shadow
   ctx.globalCompositeOperation = "source-atop";
   ctx.globalAlpha = 1;
   ctx.rotate(0.9);
   ctx.fillStyle = ctx.createPattern(image, 'repeat');
   ctx.fill();
   ctx.restore();

   // apply fill-gradient
   ctx.save();
   ctx.globalCompositeOperation = "destination-over";
   var gradient = ctx.createLinearGradient(-offset/2, -offset/2, offset/2, offset/2);
   gradient.addColorStop(0.1, '#f00');
   gradient.addColorStop(0.5, 'rgba(255,255,0,1)');
   gradient.addColorStop(1.0, '#00f');
   ctx.fillStyle = gradient
   ctx.fill();

   // apply fill-pattern
   ctx.globalCompositeOperation = "source-atop";
   ctx.globalAlpha = 0.2;
   ctx.rotate(-0.4);
   ctx.fillStyle = ctx.createPattern(image, 'repeat');
   ctx.fill();
   ctx.restore();

   // apply outer-shadow (color-only without temporary layer)
   ctx.globalCompositeOperation = "destination-over";
   ctx.shadowColor = outerColor;
   ctx.shadowBlur = 40;
   ctx.shadowOffsetX = 15;
   ctx.shadowOffsetY = 10;
   ctx.fillStyle = "#fff";
   ctx.fill();
 };

From these examples you can see that, using globalCompositeOperation, we can chain effects together, producing more elaborate effects (utilizing masking and blending). The screen is your oyster! ;-)

Spaceage—generative effects.

In <canvas>, going from the unicode character 0x2708…

typ10-unicode.png

…to this shaded example

typ11-shaded.png

can be achieved by multiple calls to ctx.strokeText() with a thin lineWidth (0.25), while slowly decreasing the x-offset and alpha, giving our vector elements the feeling of motion.

By mapping the element’s XY position to a sine/cosine wave and cycling through colors using the HSL property, we can create more interesting effects, such as this “biohazard” example:

typ12-biohazard.png

HSL: Hue, Saturation, Lightness (1978)

HSL is a newly supported format in the CSS3 specs. Where HEX was designed for computers, HSL is designed to be human readable.

Illustrating the ease of HSL, to cycle through the color spectrum, we’d simply increment the “hue” from 360; the hue is mapped to the spectrum in cylindric fashion. Lightness controls how dark/light the color is; 0% indicates a black pixel, whereas 100% indicates a white pixel. Saturation controls how bright or vivid a color is; greys are created with a saturation of 0%, and vivid colors are created using a value of 100%.

typ13-hsl.png

Because HSL is a recent standard, you may wish to continue supporting older browsers, which is possible via color-space conversion. The following code accepts an HSL object {H: 360, S: 100, L: 100} and outputs an RGB object {R: 255, G: 255, B: 255}. From there, you can use those values to create your rgb or rgba string. For more in-depth information see Wikipedia’s insightful article on HSL.

 // HSL (1978) = H: Hue / S: Saturation / L: Lightness
 HSL_RGB = function (o) { // { H: 0-360, S: 0-100, L: 0-100 }
   var H = o.H / 360,
       S = o.S / 100,
       L = o.L / 100,
       R, G, B, _1, _2;

   function Hue_2_RGB(v1, v2, vH) {
     if (vH < 0) vH += 1;
     if (vH > 1) vH -= 1;
     if ((6 * vH) < 1) return v1 + (v2 - v1) * 6 * vH;
     if ((2 * vH) < 1) return v2;
     if ((3 * vH) < 2) return v1 + (v2 - v1) * ((2 / 3) - vH) * 6;
     return v1;
   }

   if (S == 0) { // HSL from 0 to 1
     R = L * 255;
     G = L * 255;
     B = L * 255;
   } else {
     if (L < 0.5) {
       _2 = L * (1 + S);
     } else {
       _2 = (L + S) - (S * L);
     }
     _1 = 2 * L - _2;

     R = 255 * Hue_2_RGB(_1, _2, H + (1 / 3));
     G = 255 * Hue_2_RGB(_1, _2, H);
     B = 255 * Hue_2_RGB(_1, _2, H - (1 / 3));
   }

   return {
     R: R,
     G: G,
     B: B
   };
 };

Creating animations with requestAnimationFrame

In the past, to create animations in Javascript there were two choices, setTimeout and setInterval.

window.requestAnimationFrame is the new standard here to replace both; saving the world electricity (and your computer a few heartbeats) by allowing the browser to regulate animations based on available resources. Some important features include:

  • When a user exists the frame, the animation can slow down or stop completely, to prevent the unnecessary use of resources.
  • There is a limit cap to the frame-rate at 60FPS. The reason for this is that it is well above the level humans can notice (most humans by 30FPS see animation being “fluid”).

At the time of this writing, vendor-specific prefixes are required to use requestAnimationFrame. Paul Irish created a shim layer that has cross-vendor support, in requestAnimationFrame for smart animating:

 // shim layer with setTimeout fallback
 window.requestAnimFrame = (function(){
   return  window.requestAnimationFrame       ||
           window.webkitRequestAnimationFrame ||
           window.mozRequestAnimationFrame    ||
           window.oRequestAnimationFrame      ||
           window.msRequestAnimationFrame     ||
           function(/* function */ callback, /* DOMElement */ element){
             window.setTimeout(callback, 1000 / 60);
           };
 })();

Taking that a bit further, the more ambitious might tie this together with a poly-fill such as requestAnimationFrame.js (there are a few features to be worked out) that would support older browsers to a further extent, while switching to this new standard.

The following example shows how to create an animation, sending thousands of calls to strokeText through a low alpha without stalling the browser. The controls are a bit strange, but it produces some cool results:

View Spaceage effect.

 (function animate() {
   var i = 50;
   while(i--) {
       if (n > endpos) return;

       n += definition;
       ctx.globalAlpha = (0.5 - (n + startpos) / endpos) * alpha;
       if (doColorCycle) {
           hue = n + color;
           ctx.strokeStyle = "hsl(" + (hue % 360) + ",99%,50%)"; // iterate hue
       }
       var x = cos(n / cosdiv) * n * cosmult; // cosine
       var y = sin(n / sindiv) * n * sinmult; // sin
       ctx.strokeText(text, x + xoffset, y + yoffset); // draw rainbow text
   }
   timeout = window.requestAnimationFrame(animate, 0);
 })();

typ14-spaceage1.png

typ15-spaceage2.png

typ16-spaceage3.png

Source code

With support from across the browser vendor-sphere, there is no question about the future of <canvas>. It can be ported to the iPhone/Android/Desktop executables using PhoneGap or Titanium.

Source code can be found in CanvasTextEffects.zip.

See also

Related articles

Canvas

Text

Attributions

  • Portions of this content come from HTML5Rocks! article