YUVCanvas draws YUV video frames to an HTML 5 canvas element.
It is used in the ogv.js media player and is suitable for high-frequency frame updates using WebGL for drawing and colorspace conversion.
Copyright 2014-2019 by Brion Vibber firstname.lastname@example.org MIT license, see the source files:
1.2.6 - 2019-05-27
- added an extra WebGL option to preserve back buffer, fixes canvas video capture in Firefox
1.2.5 - 2019-05-27
- remove some extra WebGL options that just slowed things down and could cause flicker in Safari during canvas video capture
1.2.4 - 2019-02-06
- fix software rendering path for crop offsets (Theora)
1.2.3 - 2019-02-04
- optimize software rendering path by a few percent
1.2.2 - 2019-02-04
- don't use WebGL when software rendering is in use (failIfMajorPerformanceCaveat)
- fix use of preferLowPowerToHighPerformance for preferring integrated GPU
1.2.1 - 2018-01-18
- fix regression breaking iOS 9
1.2.0 - 2017-10-27
- optimized Windows rendering (restored "stripe" more cleanly)
- retooled rendering order to minimize CPU/GPU sync points
1.1.0 - 2017-10-27
- improved scaling/filtering on Windows (dropped "stripe" optimization)
1.0.1 - 2017-02-17
- fix flickering in Safari with software rendering
1.0.0 - 2016-09-11
- Initial break-out release from ogv.js
Planar YUV frames are packed into objects per the yuv-buffer format. Frame buffer objects can be safely copied or transferred between worker threads, and can be either garbage collected or reused for another frame after output.
Each frame buffer includes the frame's size, a crop rectangle, a display aspect ratio, and chroma subsampling format as well as the raw bytes.
WebGL drawing acceleration
Accelerated YCbCr->RGB conversion and drawing is done using WebGL on supporting browsers (Firefox, Chrome, IE 11, Edge, and Safari for iOS 8 & OS X 10.9), and is enabled by default if available.
Caller can pass the 'webGL: false' key to options to force use of the software conversion and 2d canvas, or 'webGL: true' to force a failure if WebGL initialization fails.
Windows vs luminance textures
The Y, U and V planes are uploaded as luminance textures, then combined into RGB output by a shader.
Early versions of IE 11 do not support luminance or alpha textures at all, and in IE 11 update 1 and Edge uploading is unexpectedly slow. In fact, luminance and alpha textures seem consistently slow on Windows even in Chrome and Firefox, possibly due to a mismatch in interfaces between WebGL and Direct3D.
On Windows, the textures are uploaded as packed RGBA textures, then unpacked to luminance textures on the GPU. This has a small runtime cost, but seems less than the cost of letting the ANGLE layer in the browser swizzle.
var YUVCanvas = require('yuv-canvas'); // Get your canvas var canvas = document.querySelector('canvas#myvid'); // Attach it to a YUVCanvas.FrameSink instance! // // This will take over the canvas drawing context, which may include switching // it into WebGL mode or resizing it to fit the output frames. From now on you // can manipulate the canvas element itself such as attaching it in the DOM or // changing its CSS styles, but should not attempt to touch its size or drawing // context directly. var yuv = YUVCanvas.attach(canvas); // Now... given a YUV frame buffer object, draw it! var buffer = decodeVideoFrame(); yuv.drawFrame(buffer); // Or clear the canvas. yuv.clear();
The included demo combines Y, U, and V planes from grayscale JPEGs into a color photograph on a canvas. Check it out!
npm install (or
grunt to rebuild if necessary) to build derived files in a local source checkout.
Derived files are the array of WebGL shaders (
build/shaders.js) and the bundled JS for the demo (