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GitHub - markfarnan/go-canvas: Library to use HTML5 Canvas from Go-WASM, with all drawing within go code

Library to use HTML5 Canvas from Go-WASM, with all drawing within go code - markfarnan/go-canvas

Visit SiteGitHub - markfarnan/go-canvas: Library to use HTML5 Canvas  from Go-WASM, with all drawing within go code

GitHub - markfarnan/go-canvas: Library to use HTML5 Canvas from Go-WASM, with all drawing within go code

Library to use HTML5 Canvas from Go-WASM, with all drawing within go code - markfarnan/go-canvas

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go-canvas

go-canvas is a pure go+webassembly Library for efficiently drawing on a html5 canvas element within the browser from go without requiring calls back to JS to utilise canvas drawing functions.

The library provides the following features:

  • Abstracts away the initial DOM interactions to setup the canvas.
  • Creates the shadow image frame, and graphical Context to draw on it.
  • Initializes basic font cache for text using truetype font.
  • Sets up and handles requestAnimationFrame callback from the browser.

Concept

go-canvas takes an alternate approach to the current common methods for using canvas, allowing all drawing primitives to be done totally with go code, without calling JS.

standard syscall way

In a standard WASM application for canvas, the go code must create a function that responds to requestAnimationFrame callbacks and renders the frame within that call. It interacts with the canvas drawing primitives via the syscall/js functions and context switches. i.e.

laserCtx.Call("beginPath")
laserCtx.Call("arc", gs.laserX, gs.laserY, gs.laserSize, 0, math.Pi*2, false)
laserCtx.Call("fill")
laserCtx.Call("closePath")

Downsides of this approach (for me at least), are messy JS calls which can't easily be checked at compile time, forcing a full redraw every frame, even if nothing changed on that canvas, or changes being much slower than the requested frame rate.

go native way

go-canvas allows all drawing to be done natively using Go by creating an entirely separate image buffer which is drawn to using a 2D drawing library. I'm currently using one from https://github.com/llgcode/draw2d which provides most of the standard canvas primitives and more. This shadow Image buffer can be updated at whatever rate the developer deems appropriate, which may very well be slower than the browsers animation rate.

This shadow Image buffer is then copied over to the browser canvas buffer during each requestAnimationFrame callback, at whatever rate the browser requests. The handling of the callback and copy is done automatically within the library.

Secondly, this also allows the option of drawing to the image buffer, outside of the requestAnimationFrame callback if required. After some testing it appears that it is still best to do the drawing within the requestAnimationFrame callback.

go-canvas provides several options to control all this, and take care of the browser/dom interactions

  • User specifies the go render/draw callback method when calling the START function. This callback passes the graphical context to the render routine.
  • Render routine can choose to return whether any drawing took place. If it returns false, then the requestAnimationFrame callback does nothing, just returns immediately, saving CPU cycles. (No point to copy buffers and redraw if nothing has changed) This allows the drawing to be adaptive to the rate of data changes.
  • The 'start' function accepts a maxFPS parameter. The library will automatically throttle the requestAnimationFrame callback to only do redraws or image buffer copies to this max rate. Note it MAY be slower depending on the Render time, and the requirements of the browser doing other work. When a tab is hidden, the browser regularly reduces and may even stop call to the animation callback. No critical timing should be done in the render/draw routings.
  • You may pass 'nil' for the render function. In this case all drawing happens totally under the users control, outside of the library. This may be more useful in future when WASM supports proper threading. Right now however, testing shows it is slower as all work is in the one thread, and you lose the scheduling benefits of the requestAnimationFrame call.

Drawing therefore, is pure go. i.e.

func Render(gc *draw2dimg.GraphicContext) bool {
    // {some movement code removed for clarity, see the demo code for full function}
    // draws red 🔴 laser
    gc.SetFillColor(color.RGBA{0xff, 0x00, 0x00, 0xff})
    gc.SetStrokeColor(color.RGBA{0xff, 0x00, 0x00, 0xff})

    gc.BeginPath()
    gc.ArcTo(gs.laserX, gs.laserY, gs.laserSize, gs.laserSize, 0, math.Pi*2)
    gc.FillStroke()
    gc.Close()
return true  // Yes, we drew something, copy it over to the browser

If you do want to render outside the animation loop, a simple way to cause the code to draw the frame on schedule, independent from the browsers callbacks, is to use time.Tick. An example is in the demo app below.

If however your image is only updated from user input or some network activity, then it would be straightforward to fire the redraw only when required from these inputs. This can be controlled within the Render function, by just returning FALSE at the start. Nothing is draw, nor copied (saving CPU time) and the previous frames data remains.

Known issues !

There is currently a likely race condition for long draw functions, where the requestAnimationFrame may get a partially completed image buffer. This is more likely the longer the user render operation takes. Currently think how best to handle this, ideally without locks. Turns out this is not an issue, due to the single threaded nature. Eventually if drawing is in a separate thread, this will have to be handled.

Demo

A simple demo can be found in: ./demo directory. This is a shameless rewrite of the 'Moving red Laser' demo by Martin Olsansky https://medium.freecodecamp.org/webassembly-with-golang-is-fun-b243c0e34f02

Compile with GOOS=js GOARCH=wasm go build -o main.wasm

Includes a Caddy configuration file to support WASM, so will serve by just running 'caddy' in the demo directory and opening browser to http://localhost:8080

Live

Live Demo available at: https://markfarnan.github.io/go-canvas

Future

This library was written after a weekend of investigation and posted on request for the folks on #webassembly on Gophers Slack.

I intend to extend it further, time permitting, into fully fledged support package for all things go-canvas-wasm related, using this image frame method.

Several of the ideas I'm considering are:

  • Support for layered canvas, at least 3 for 'background', 'action' and 'user interaction'
  • Traps & helper functions for mouse interactions over the canvas
  • Unit tests - soon as I figure out how to do tests for WASM work.
  • Performance improvements in the image buffer copy - https://github.com/agnivade/shimmer/blob/c073303a81ab9a90b6fc14eb6d90c3a1b930025e/load_image_cb.go#L40 has been suggested as a place to start.
  • Detect if nothing has changed for the frame, and if so, don't even recopy the buffer, saving yet more time. May be useful for layers that change less frequently.
  • Multiple draw / render frames to fix the 'incomplete image' problem. -- Not actually a problem
  • Tidy up the close/end frame functionality to properly release resources on page unload and prevent 'browser reload errors' due to missing animation callback function.
  • Update for Go 1.13 and Go Modules
  • Add FPS Calculator metric

Others ? Feedback, suggestions etc. welcome. I can be found on Gophers Slack, #Webassembly channel.

Mark Farnan, February 2020

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