High Performance Data Visualizaitons in JavaScript [Topconf 2013]

Transcript

1. Vladimir Agafonkin High Performance Data Visualizations in JavaScript November 2013

2. /mourner

3. data visualization

4. None
5. None
6. None
7. None
8. None
9. None

10. not static anymore

11. responding to user actions clicking, hovering, scrolling, touch gestures, etc.

12. None
13. None
14. None

15. navigating through data

16. filtering

17. demand for real-time interactivity is increasing

18. responsibility for processing data is shifting from the server
    

    to the browser

19. lots of data
    +
    lots of rendering
    =
    big performance

    problem

20. pure JS
    fast rendering, DOM
    slow

21. rule #1
    the less stuff we render
    the better

22. data processing rendering

23. data processing rendering

24. None

25. data reduction

26. search

27. loading data
    once
    ! searching data
    lots of

    times

28. search index

29. grid

30. tree data structures •binary heap •binary search tree •range tree

    •k-d tree •quadtree •R-tree

31. points – quadtree

32. rectangles – R-tree

33. var tree = rbush();
    ! tree.insert([5, 10, 15, 25, obj]);
    

    ! ...
    ! tree.search([7, 7, 12, 12]); github.com/mourner/rbush

34. greedy rendering

35. •avoids rendering many objects in the same spot •free index

    for instant mouse/touch interaction greedy rendering

36. kothic.org/js

37. collision detection

38. Crossfilter (many dimensions)

39. geometric clipping

40. polyline clipping Cohen-Sutherland algorithm

41. polygon clipping Sutherland-Hodgeman algorithm

42. polyline simplification

43. distance-based simplification

44. Douglas-Peucker simplification

45. mourner.github.com/simplify-js

46. clustering
    grouping objects which are
    close to each other

47. None
48. None

49. hierarchical clustering once for all zoom levels

50. data loading and processing

51. UI JS browser freezes
    on heavy calculations UI

52. Web Workers

53. pure JS
    fast
    ! rendering, DOM
    slow

54. Worker •isolated DOM-less environment, freaking fast •runs in its own

    thread, doesn’t lock the UI •sends and receives messages

55. Web Workers
    you’ve been using it all wrong

56. <script src='data.js'></script>
    ! <script>
    ...
    worker.postMessage(HUGE_DATA_ARRAY);
    ...
    </script> loading and

    sending to Worker

57. UI Worker JS browser freezes on data loading and sending
    

    data loading UI

58. importScripts('data.js');
    ! ...
    ! onmessage = function (e) {
    var

    result =
    searchData(e.data.query);
    ! postMessage(result);
    } Loading in Worker

59. UI Worker JS browser freezes when receiving data from Worker
    

    data loading UI UI

60. var array = new Float16Array(len);
    ...
    ! var buffer =

    array.buffer;
    ! postMessage(buffer, [buffer]);
    ! // buffer stops being available transferable objects (all browsers except IE)

61. UI Worker JS browser doesn't freeze,
    data is sent

    as ArrayBuffer
    data loading UI UI

62. function addNumbers(a, b) {
    'use asm';
    ! a = a

    | 0; // int
    b = +b; // double
    ! return +(a + b); // double
    } asm.js

63. asm.js •useful for computational bottlenecks •supported in FF only •backwards

    compatibility! •V8 optimizes without annotations

64. V8: lets make it as fast as asm.js but without

    the need for special syntax

65. rendering backends
    SVG, Canvas, WebGL

66. SVG •fast native events for interactivity •easy to update separate

    objects •easy to animate •slows down the browser (with a large number of objects)

67. Canvas •doesn't affect browser performance after rendering •you can draw

    something once and copy •pixel data can be manipulated or generated in a Worker

68. Canvas •expensive to redraw with each update •hard to implement

    interactivity

69. WebGL •main way to visualize in 3D •very fast in

    2D if you need to draw lots of sprites •performance gain vs Canvas-2D is questionable in other cases •much more difficult to use; limitations •no support in iOS and IE9-10, difficult in IE11

70. low number of objects:
    use SVG
    ! lots of

    stuff to draw:
    use Canvas

71. Canvas Performance

72. redraw partially

73. use several Canvas layers

74. draw once to an offscreen canvas and copy

75. function drawStar(ctx, x, y) {
    ...
    }
    ! drawStar(ctx, 10,

    20);
    drawStar(ctx, 50, 70);
    ...

76. function drawStar() {
    ...
    return canvas;
    }
    ! var star

    = drawStar();
    ! ctx.drawImage(star, 10, 20);
    ctx.drawImage(star, 50, 70);
    ...

77. minimize stroke/fill

78. function drawLine(x1, x2, y1, y2) {
    ! ctx.strokeStyle = 'red';
    

    ! ctx.beginPath();
    ctx.moveTo(x1, y1);
    ctx.lineTo(x2, y2);
    ! ctx.stroke();
    }
    ! drawLine(10, 20, 30, 40);
    drawLine(200, 10, 0, 50);
    drawLine(30, 40, 70, 0);

79. function drawLine(x1, x2, y1, y2) {
    ! ctx.beginPath();
    ctx.moveTo(x1, y1);
    

    ctx.lineTo(x2, y2);
    }
    ! ctx.strokeStyle = 'red';
    ! drawLine(10, 20, 30, 40);
    drawLine(200, 10, 0, 50);
    drawLine(30, 40, 70, 0);
    ! ctx.stroke();

80. generate or manipulate
    raw pixel data in a Worker

81. var data =
    ctx.getImageData(0, 0, width, height).data;
    ! worker.postMessage(data.buffer,

    [data.buffer]);
    ! ...
    ! worker.onmessage = function (e) {
    var imageData =
    ctx.createImageData(width, height);
    ! imageData.data.set(e.data);
    ! ctx.putImageData(imageData, 0, 0);
    } Canvas + Worker

82. var pixels = new Uint8ClampedArray(
    width * height);
    ! function

    drawPixel(x, y, r, g, b, a) {
    var i = 4 * (256 * y + x);
    ! pixels[i] = r;
    pixels[i + 1] = g;
    pixels[i + 2] = b;
    pixels[i + 3] = a;
    }
    ! ...
    ! postMessage(pixels.buffer, [pixels.buffer]); drawing pixels in a Worker

83. var pixels = new Uint8ClampedArray(data);
    ! for (var x =

    0; x < width; x++) {
    for (var y = 0; y < height; y++) {
    var i = 4 * (256 * y + x);
    ! pixels[i] = 2 * pixels[i];
    pixels[i + 1] = 2 * pixels[i + 1];
    pixels[i + 2] = 2 * pixels[i + 2];
    }
    }
    ! ...
    ! postMessage(pixels.buffer, [pixels.buffer]); processing pixels in a Worker

84. dynamic hill shading

85. still too much for the browsers? resorting to the server

86. Cavnas lookup table

87. UTFGrid •65535 symbols •each symbol is 4х4 pixels •1-3 KB

    per 256х256 tile in average

88. Thanks!
    Questions? Vladimir Agafonkin [email protected]