skia2/modules/canvaskit/interface.js

// Adds JS functions to augment the CanvasKit interface.
// For example, if there is a wrapper around the C++ call or logic to allow
// chaining, it should go here.

// CanvasKit.onRuntimeInitialized is called after the WASM library has loaded.
// Anything that modifies an exposed class (e.g. SkPath) should be set
// after onRuntimeInitialized, otherwise, it can happen outside of that scope.
CanvasKit.onRuntimeInitialized = function() {
  // All calls to 'this' need to go in externs.js so closure doesn't minify them away.

  // Add some helpers for matrices. This is ported from SkMatrix.cpp
  // to save complexity and overhead of going back and forth between
  // C++ and JS layers.
  // I would have liked to use something like DOMMatrix, except it
  // isn't widely supported (would need polyfills) and it doesn't
  // have a mapPoints() function (which could maybe be tacked on here).
  // If DOMMatrix catches on, it would be worth re-considering this usage.
  CanvasKit.SkMatrix = {};
  function sdot(a, b, c, d, e, f) {
    e = e || 0;
    f = f || 0;
    return a * b + c * d + e * f;
  }

  CanvasKit.SkMatrix.identity = function() {
    return [
      1, 0, 0,
      0, 1, 0,
      0, 0, 1,
    ];
  };

  // Return the inverse (if it exists) of this matrix.
  // Otherwise, return the identity.
  CanvasKit.SkMatrix.invert = function(m) {
    var det = m[0]*m[4]*m[8] + m[1]*m[5]*m[6] + m[2]*m[3]*m[7]
            - m[2]*m[4]*m[6] - m[1]*m[3]*m[8] - m[0]*m[5]*m[7];
    if (!det) {
      SkDebug('Warning, uninvertible matrix');
      return CanvasKit.SkMatrix.identity();
    }
    return [
      (m[4]*m[8] - m[5]*m[7])/det, (m[2]*m[7] - m[1]*m[8])/det, (m[1]*m[5] - m[2]*m[4])/det,
      (m[5]*m[6] - m[3]*m[8])/det, (m[0]*m[8] - m[2]*m[6])/det, (m[2]*m[3] - m[0]*m[5])/det,
      (m[3]*m[7] - m[4]*m[6])/det, (m[1]*m[6] - m[0]*m[7])/det, (m[0]*m[4] - m[1]*m[3])/det,
    ];
  };

  // Maps the given points according to the passed in matrix.
  // Results are done in place.
  // See SkMatrix.h::mapPoints for the docs on the math.
  CanvasKit.SkMatrix.mapPoints = function(matrix, ptArr) {
    if (ptArr.length % 2) {
      throw 'mapPoints requires an even length arr';
    }
    for (var i = 0; i < ptArr.length; i+=2) {
      var x = ptArr[i], y = ptArr[i+1];
      // Gx+Hy+I
      var denom  = matrix[6]*x + matrix[7]*y + matrix[8];
      // Ax+By+C
      var xTrans = matrix[0]*x + matrix[1]*y + matrix[2];
      // Dx+Ey+F
      var yTrans = matrix[3]*x + matrix[4]*y + matrix[5];
      ptArr[i]   = xTrans/denom;
      ptArr[i+1] = yTrans/denom;
    }
    return ptArr;
  };

  CanvasKit.SkMatrix.multiply = function(m1, m2) {
    var result = [0,0,0, 0,0,0, 0,0,0];
    for (var r = 0; r < 3; r++) {
      for (var c = 0; c < 3; c++) {
        // m1 and m2 are 1D arrays pretending to be 2D arrays
        result[3*r + c] = sdot(m1[3*r + 0], m2[3*0 + c],
                               m1[3*r + 1], m2[3*1 + c],
                               m1[3*r + 2], m2[3*2 + c]);
      }
    }
    return result;
  }

  // Return a matrix representing a rotation by n radians.
  // px, py optionally say which point the rotation should be around
  // with the default being (0, 0);
  CanvasKit.SkMatrix.rotated = function(radians, px, py) {
    px = px || 0;
    py = py || 0;
    var sinV = Math.sin(radians);
    var cosV = Math.cos(radians);
    return [
      cosV, -sinV, sdot( sinV, py, 1 - cosV, px),
      sinV,  cosV, sdot(-sinV, px, 1 - cosV, py),
      0,        0,                             1,
    ];
  };

  CanvasKit.SkMatrix.scaled = function(sx, sy, px, py) {
    px = px || 0;
    py = py || 0;
    return [
      sx, 0, px - sx * px,
      0, sy, py - sy * py,
      0,  0,            1,
    ];
  };

  CanvasKit.SkMatrix.skewed = function(kx, ky, px, py) {
    px = px || 0;
    py = py || 0;
    return [
      1, kx, -kx * px,
      ky, 1, -ky * py,
      0,  0,        1,
    ];
  };

  CanvasKit.SkMatrix.translated = function(dx, dy) {
    return [
      1, 0, dx,
      0, 1, dy,
      0, 0,  1,
    ];
  };

  // An SkColorMatrix is a 4x4 color matrix that transforms the 4 color channels
  //  with a 1x4 matrix that post-translates those 4 channels.
  // For example, the following is the layout with the scale (S) and post-transform
  // (PT) items indicated.
  // RS,  0,  0,  0 | RPT
  //  0, GS,  0,  0 | GPT
  //  0,  0, BS,  0 | BPT
  //  0,  0,  0, AS | APT
  //
  // Much of this was hand-transcribed from SkColorMatrix.cpp, because it's easier to
  // deal with a Float32Array of length 20 than to try to expose the SkColorMatrix object.

  var rScale = 0;
  var gScale = 6;
  var bScale = 12;
  var aScale = 18;

  var rPostTrans = 4;
  var gPostTrans = 9;
  var bPostTrans = 14;
  var aPostTrans = 19;

  CanvasKit.SkColorMatrix = {};
  CanvasKit.SkColorMatrix.identity = function() {
    var m = new Float32Array(20);
    m[rScale] = 1;
    m[gScale] = 1;
    m[bScale] = 1;
    m[aScale] = 1;
    return m;
  }

  CanvasKit.SkColorMatrix.scaled = function(rs, gs, bs, as) {
    var m = new Float32Array(20);
    m[rScale] = rs;
    m[gScale] = gs;
    m[bScale] = bs;
    m[aScale] = as;
    return m;
  }

  var rotateIndices = [
    [6, 7, 11, 12],
    [0, 10, 2, 12],
    [0, 1,  5,  6],
  ];
  // axis should be 0, 1, 2 for r, g, b
  CanvasKit.SkColorMatrix.rotated = function(axis, sine, cosine) {
    var m = CanvasKit.SkColorMatrix.identity();
    var indices = rotateIndices[axis];
    m[indices[0]] = cosine;
    m[indices[1]] = sine;
    m[indices[2]] = -sine;
    m[indices[3]] = cosine;
    return m;
  }

  // m is a SkColorMatrix (i.e. a Float32Array), and this sets the 4 "special"
  // params that will translate the colors after they are multiplied by the 4x4 matrix.
  CanvasKit.SkColorMatrix.postTranslate = function(m, dr, dg, db, da) {
    m[rPostTrans] += dr;
    m[gPostTrans] += dg;
    m[bPostTrans] += db;
    m[aPostTrans] += da;
    return m;
  }

  // concat returns a new SkColorMatrix that is the result of multiplying outer*inner;
  CanvasKit.SkColorMatrix.concat = function(outer, inner) {
    var m = new Float32Array(20);
    var index = 0;
    for (var j = 0; j < 20; j += 5) {
        for (var i = 0; i < 4; i++) {
            m[index++] =  outer[j + 0] * inner[i + 0] +
                          outer[j + 1] * inner[i + 5] +
                          outer[j + 2] * inner[i + 10] +
                          outer[j + 3] * inner[i + 15];
        }
        m[index++] =  outer[j + 0] * inner[4] +
                      outer[j + 1] * inner[9] +
                      outer[j + 2] * inner[14] +
                      outer[j + 3] * inner[19] +
                      outer[j + 4];
    }

    return m;
  }

  CanvasKit.SkPath.prototype.addArc = function(oval, startAngle, sweepAngle) {
    // see arc() for the HTMLCanvas version
    // note input angles are degrees.
    this._addArc(oval, startAngle, sweepAngle);
    return this;
  };

  CanvasKit.SkPath.prototype.addOval = function(oval, isCCW, startIndex) {
    if (startIndex === undefined) {
      startIndex = 1;
    }
    this._addOval(oval, !!isCCW, startIndex);
    return this;
  };

  CanvasKit.SkPath.prototype.addPath = function() {
    // Takes 1, 2, 7, or 10 required args, where the first arg is always the path.
    // The last arg is optional and chooses between add or extend mode.
    // The options for the remaining args are:
    //   - an array of 6 or 9 parameters (perspective is optional)
    //   - the 9 parameters of a full matrix or
    //     the 6 non-perspective params of a matrix.
    var args = Array.prototype.slice.call(arguments);
    var path = args[0];
    var extend = false;
    if (typeof args[args.length-1] === "boolean") {
      extend = args.pop();
    }
    if (args.length === 1) {
      // Add path, unchanged.  Use identity matrix
      this._addPath(path, 1, 0, 0,
                          0, 1, 0,
                          0, 0, 1,
                          extend);
    } else if (args.length === 2) {
      // User provided the 9 params of a full matrix as an array.
      var a = args[1];
      this._addPath(path, a[0],      a[1],      a[2],
                          a[3],      a[4],      a[5],
                          a[6] || 0, a[7] || 0, a[8] || 1,
                          extend);
    } else if (args.length === 7 || args.length === 10) {
      // User provided the 9 params of a (full) matrix directly.
      // (or just the 6 non perspective ones)
      // These are in the same order as what Skia expects.
      var a = args;
      this._addPath(path, a[1],      a[2],      a[3],
                          a[4],      a[5],      a[6],
                          a[7] || 0, a[8] || 0, a[9] || 1,
                          extend);
    } else {
      SkDebug('addPath expected to take 1, 2, 7, or 10 required args. Got ' + args.length);
      return null;
    }
    return this;
  };

  // points is either an array of [x, y] where x and y are numbers or
  // a typed array from Malloc where the even indices will be treated
  // as x coordinates and the odd indices will be treated as y coordinates.
  CanvasKit.SkPath.prototype.addPoly = function(points, close) {
    var ptr;
    var n;
    // This was created with CanvasKit.Malloc, so assume the user has
    // already been filled with data.
    if (points['_ck']) {
      ptr = points.byteOffset;
      n = points.length/2;
    } else {
      ptr = copy2dArray(points, CanvasKit.HEAPF32);
      n = points.length;
    }
    this._addPoly(ptr, n, close);
    CanvasKit._free(ptr);
    return this;
  };

  CanvasKit.SkPath.prototype.addRect = function() {
    // Takes 1, 2, 4 or 5 args
    //  - SkRect
    //  - SkRect, isCCW
    //  - left, top, right, bottom
    //  - left, top, right, bottom, isCCW
    if (arguments.length === 1 || arguments.length === 2) {
      var r = arguments[0];
      var ccw = arguments[1] || false;
      this._addRect(r.fLeft, r.fTop, r.fRight, r.fBottom, ccw);
    } else if (arguments.length === 4 || arguments.length === 5) {
      var a = arguments;
      this._addRect(a[0], a[1], a[2], a[3], a[4] || false);
    } else {
      SkDebug('addRect expected to take 1, 2, 4, or 5 args. Got ' + arguments.length);
      return null;
    }
    return this;
  };

  CanvasKit.SkPath.prototype.addRoundRect = function() {
    // Takes 3, 4, 6 or 7 args
    //  - SkRect, radii, ccw
    //  - SkRect, rx, ry, ccw
    //  - left, top, right, bottom, radii, ccw
    //  - left, top, right, bottom, rx, ry, ccw
    var args = arguments;
    if (args.length === 3 || args.length === 6) {
      var radii = args[args.length-2];
    } else if (args.length === 6 || args.length === 7){
      // duplicate the given (rx, ry) pairs for each corner.
      var rx = args[args.length-3];
      var ry = args[args.length-2];
      var radii = [rx, ry, rx, ry, rx, ry, rx, ry];
    } else {
      SkDebug('addRoundRect expected to take 3, 4, 6, or 7 args. Got ' + args.length);
      return null;
    }
    if (radii.length !== 8) {
      SkDebug('addRoundRect needs 8 radii provided. Got ' + radii.length);
      return null;
    }
    var rptr = copy1dArray(radii, CanvasKit.HEAPF32);
    if (args.length === 3 || args.length === 4) {
      var r = args[0];
      var ccw = args[args.length - 1];
      this._addRoundRect(r.fLeft, r.fTop, r.fRight, r.fBottom, rptr, ccw);
    } else if (args.length === 6 || args.length === 7) {
      var a = args;
      this._addRoundRect(a[0], a[1], a[2], a[3], rptr, ccw);
    }
    CanvasKit._free(rptr);
    return this;
  };

  CanvasKit.SkPath.prototype.arc = function(x, y, radius, startAngle, endAngle, ccw) {
    // emulates the HTMLCanvas behavior.  See addArc() for the SkPath version.
    // Note input angles are radians.
    var bounds = CanvasKit.LTRBRect(x-radius, y-radius, x+radius, y+radius);
    var sweep = radiansToDegrees(endAngle - startAngle) - (360 * !!ccw);
    var temp = new CanvasKit.SkPath();
    temp.addArc(bounds, radiansToDegrees(startAngle), sweep);
    this.addPath(temp, true);
    temp.delete();
    return this;
  };

  CanvasKit.SkPath.prototype.arcTo = function() {
    // takes 4, 5 or 7 args
    // - 5 x1, y1, x2, y2, radius
    // - 4 oval (as Rect), startAngle, sweepAngle, forceMoveTo
    // - 7 rx, ry, xAxisRotate, useSmallArc, isCCW, x, y
    var args = arguments;
    if (args.length === 5) {
      this._arcTo(args[0], args[1], args[2], args[3], args[4]);
    } else if (args.length === 4) {
      this._arcTo(args[0], args[1], args[2], args[3]);
    } else if (args.length === 7) {
      this._arcTo(args[0], args[1], args[2], !!args[3], !!args[4], args[5], args[6]);
    } else {
      throw 'Invalid args for arcTo. Expected 4, 5, or 7, got '+ args.length;
    }

    return this;
  };

  CanvasKit.SkPath.prototype.close = function() {
    this._close();
    return this;
  };

  CanvasKit.SkPath.prototype.conicTo = function(x1, y1, x2, y2, w) {
    this._conicTo(x1, y1, x2, y2, w);
    return this;
  };

  CanvasKit.SkPath.prototype.cubicTo = function(cp1x, cp1y, cp2x, cp2y, x, y) {
    this._cubicTo(cp1x, cp1y, cp2x, cp2y, x, y);
    return this;
  };

  CanvasKit.SkPath.prototype.dash = function(on, off, phase) {
    if (this._dash(on, off, phase)) {
      return this;
    }
    return null;
  };

  CanvasKit.SkPath.prototype.lineTo = function(x, y) {
    this._lineTo(x, y);
    return this;
  };

  CanvasKit.SkPath.prototype.moveTo = function(x, y) {
    this._moveTo(x, y);
    return this;
  };

  CanvasKit.SkPath.prototype.offset = function(dx, dy) {
    this._transform(1, 0, dx,
                    0, 1, dy,
                    0, 0, 1);
    return this;
  };

  CanvasKit.SkPath.prototype.quadTo = function(cpx, cpy, x, y) {
    this._quadTo(cpx, cpy, x, y);
    return this;
  };

 CanvasKit.SkPath.prototype.rArcTo = function(rx, ry, xAxisRotate, useSmallArc, isCCW, dx, dy) {
    this._rArcTo(rx, ry, xAxisRotate, useSmallArc, isCCW, dx, dy);
    return this;
  };

  CanvasKit.SkPath.prototype.rConicTo = function(dx1, dy1, dx2, dy2, w) {
    this._rConicTo(dx1, dy1, dx2, dy2, w);
    return this;
  };

  // These params are all relative
  CanvasKit.SkPath.prototype.rCubicTo = function(cp1x, cp1y, cp2x, cp2y, x, y) {
    this._rCubicTo(cp1x, cp1y, cp2x, cp2y, x, y);
    return this;
  };

  CanvasKit.SkPath.prototype.rLineTo = function(dx, dy) {
    this._rLineTo(dx, dy);
    return this;
  };

  CanvasKit.SkPath.prototype.rMoveTo = function(dx, dy) {
    this._rMoveTo(dx, dy);
    return this;
  };

  // These params are all relative
  CanvasKit.SkPath.prototype.rQuadTo = function(cpx, cpy, x, y) {
    this._rQuadTo(cpx, cpy, x, y);
    return this;
  };

  CanvasKit.SkPath.prototype.stroke = function(opts) {
    // Fill out any missing values with the default values.
    /**
     * See externs.js for this definition
     * @type {StrokeOpts}
     */
    opts = opts || {};
    opts.width = opts.width || 1;
    opts.miter_limit = opts.miter_limit || 4;
    opts.cap = opts.cap || CanvasKit.StrokeCap.Butt;
    opts.join = opts.join || CanvasKit.StrokeJoin.Miter;
    opts.precision = opts.precision || 1;
    if (this._stroke(opts)) {
      return this;
    }
    return null;
  };

  CanvasKit.SkPath.prototype.transform = function() {
    // Takes 1 or 9 args
    if (arguments.length === 1) {
      // argument 1 should be a 6 or 9 element array.
      var a = arguments[0];
      this._transform(a[0], a[1], a[2],
                      a[3], a[4], a[5],
                      a[6] || 0, a[7] || 0, a[8] || 1);
    } else if (arguments.length === 6 || arguments.length === 9) {
      // these arguments are the 6 or 9 members of the matrix
      var a = arguments;
      this._transform(a[0], a[1], a[2],
                      a[3], a[4], a[5],
                      a[6] || 0, a[7] || 0, a[8] || 1);
    } else {
      throw 'transform expected to take 1 or 9 arguments. Got ' + arguments.length;
    }
    return this;
  };
  // isComplement is optional, defaults to false
  CanvasKit.SkPath.prototype.trim = function(startT, stopT, isComplement) {
    if (this._trim(startT, stopT, !!isComplement)) {
      return this;
    }
    return null;
  };

  // bones should be a 3d array.
  // Each bone is a 3x2 transformation matrix in column major order:
  // | scaleX   skewX transX |
  // |  skewY  scaleY transY |
  // and bones is an array of those matrices.
  // Returns a copy of this (SkVertices) with the bones applied.
  CanvasKit.SkVertices.prototype.applyBones = function(bones) {
    var bPtr = copy3dArray(bones, CanvasKit.HEAPF32);
    var vert = this._applyBones(bPtr, bones.length);
    CanvasKit._free(bPtr);
    return vert;
  }

  CanvasKit.SkImage.prototype.encodeToData = function() {
    if (!arguments.length) {
      return this._encodeToData();
    }

    if (arguments.length === 2) {
      var a = arguments;
      return this._encodeToDataWithFormat(a[0], a[1]);
    }

    throw 'encodeToData expected to take 0 or 2 arguments. Got ' + arguments.length;
  }

  CanvasKit.SkImage.prototype.makeShader = function(xTileMode, yTileMode, localMatrix) {
    if (localMatrix) {
      // Add perspective args if not provided.
      if (localMatrix.length === 6) {
        localMatrix.push(0, 0, 1);
      }
      return this._makeShader(xTileMode, yTileMode, localMatrix);
    } else {
      return this._makeShader(xTileMode, yTileMode);
    }
  }

  CanvasKit.SkImage.prototype.readPixels = function(imageInfo, srcX, srcY) {
    var rowBytes;
    // Important to use ["string"] notation here, otherwise the closure compiler will
    // minify away the colorType.
    switch (imageInfo["colorType"]) {
      case CanvasKit.ColorType.RGBA_8888:
        rowBytes = imageInfo.width * 4; // 1 byte per channel == 4 bytes per pixel in 8888
        break;
      case CanvasKit.ColorType.RGBA_F32:
        rowBytes = imageInfo.width * 16; // 4 bytes per channel == 16 bytes per pixel in F32
        break;
      default:
        SkDebug("Colortype not yet supported");
        return;
    }
    var pBytes = rowBytes * imageInfo.height;
    var pPtr = CanvasKit._malloc(pBytes);

    if (!this._readPixels(imageInfo, pPtr, rowBytes, srcX, srcY)) {
      SkDebug("Could not read pixels with the given inputs");
      return null;
    }

    // Put those pixels into a typed array of the right format and then
    // make a copy with slice() that we can return.
    var retVal = null;
    switch (imageInfo["colorType"]) {
      case CanvasKit.ColorType.RGBA_8888:
        retVal = new Uint8Array(CanvasKit.HEAPU8.buffer, pPtr, pBytes).slice();
        break;
      case CanvasKit.ColorType.RGBA_F32:
        retVal = new Float32Array(CanvasKit.HEAPU8.buffer, pPtr, pBytes).slice();
        break;
    }

    // Free the allocated pixels in the WASM memory
    CanvasKit._free(pPtr);
    return retVal;

  }

  // atlas is an SkImage, e.g. from CanvasKit.MakeImageFromEncoded
  // srcRects and dstXforms should be CanvasKit.SkRectBuilder and CanvasKit.RSXFormBuilder
  // or just arrays of floats in groups of 4.
  // colors, if provided, should be a CanvasKit.SkColorBuilder or array of SkColor
  // (from CanvasKit.Color)
  CanvasKit.SkCanvas.prototype.drawAtlas = function(atlas, srcRects, dstXforms, paint,
                                       /*optional*/ blendMode, colors) {
    if (!atlas || !paint || !srcRects || !dstXforms) {
      SkDebug('Doing nothing since missing a required input');
      return;
    }
    if (srcRects.length !== dstXforms.length || (colors && colors.length !== dstXforms.length)) {
      SkDebug('Doing nothing since input arrays length mismatches');
    }
    if (!blendMode) {
      blendMode = CanvasKit.BlendMode.SrcOver;
    }

    var srcRectPtr;
    if (srcRects.build) {
      srcRectPtr = srcRects.build();
    } else {
      srcRectPtr = copy1dArray(srcRects, CanvasKit.HEAPF32);
    }

    var dstXformPtr;
    if (dstXforms.build) {
      dstXformPtr = dstXforms.build();
    } else {
      dstXformPtr = copy1dArray(dstXforms, CanvasKit.HEAPF32);
    }

    var colorPtr = 0; // enscriptem doesn't like undefined for nullptr
    if (colors) {
      if (colors.build) {
        colorPtr = colors.build();
      } else {
        colorPtr = copy1dArray(colors, CanvasKit.HEAPU32);
      }
    }

    this._drawAtlas(atlas, dstXformPtr, srcRectPtr, colorPtr, dstXforms.length,
                    blendMode, paint);

    if (srcRectPtr && !srcRects.build) {
      CanvasKit._free(srcRectPtr);
    }
    if (dstXformPtr && !dstXforms.build) {
      CanvasKit._free(dstXformPtr);
    }
    if (colorPtr && !colors.build) {
      CanvasKit._free(colorPtr);
    }

  }

  // points is either an array of [x, y] where x and y are numbers or
  // a typed array from Malloc where the even indices will be treated
  // as x coordinates and the odd indices will be treated as y coordinates.
  CanvasKit.SkCanvas.prototype.drawPoints = function(mode, points, paint) {
    var ptr;
    var n;
    // This was created with CanvasKit.Malloc, so assume the user has
    // already been filled with data.
    if (points['_ck']) {
      ptr = points.byteOffset;
      n = points.length/2;
    } else {
      ptr = copy2dArray(points, CanvasKit.HEAPF32);
      n = points.length;
    }
    this._drawPoints(mode, ptr, n, paint);
    CanvasKit._free(ptr);
  }

  // returns Uint8Array
  CanvasKit.SkCanvas.prototype.readPixels = function(x, y, w, h, alphaType,
                                                     colorType, dstRowBytes) {
    // supply defaults (which are compatible with HTMLCanvas's getImageData)
    alphaType = alphaType || CanvasKit.AlphaType.Unpremul;
    colorType = colorType || CanvasKit.ColorType.RGBA_8888;
    dstRowBytes = dstRowBytes || (4 * w);

    var len = h * dstRowBytes
    var pptr = CanvasKit._malloc(len);
    var ok = this._readPixels({
      'width': w,
      'height': h,
      'colorType': colorType,
      'alphaType': alphaType,
    }, pptr, dstRowBytes, x, y);
    if (!ok) {
      CanvasKit._free(pptr);
      return null;
    }

    // The first typed array is just a view into memory. Because we will
    // be free-ing that, we call slice to make a persistent copy.
    var pixels = new Uint8Array(CanvasKit.HEAPU8.buffer, pptr, len).slice();
    CanvasKit._free(pptr);
    return pixels;
  }

  // pixels is a TypedArray. No matter the input size, it will be treated as
  // a Uint8Array (essentially, a byte array).
  CanvasKit.SkCanvas.prototype.writePixels = function(pixels, srcWidth, srcHeight,
                                                      destX, destY, alphaType, colorType) {
    if (pixels.byteLength % (srcWidth * srcHeight)) {
      throw 'pixels length must be a multiple of the srcWidth * srcHeight';
    }
    var bytesPerPixel = pixels.byteLength / (srcWidth * srcHeight);
    // supply defaults (which are compatible with HTMLCanvas's putImageData)
    alphaType = alphaType || CanvasKit.AlphaType.Unpremul;
    colorType = colorType || CanvasKit.ColorType.RGBA_8888;
    var srcRowBytes = bytesPerPixel * srcWidth;

    var pptr = CanvasKit._malloc(pixels.byteLength);
    CanvasKit.HEAPU8.set(pixels, pptr);

    var ok = this._writePixels({
      'width': srcWidth,
      'height': srcHeight,
      'colorType': colorType,
      'alphaType': alphaType,
    }, pptr, srcRowBytes, destX, destY);

    CanvasKit._free(pptr);
    return ok;
  }

  // colorMatrix is an SkColorMatrix (e.g. Float32Array of length 20)
  CanvasKit.SkColorFilter.MakeMatrix = function(colorMatrix) {
    if (!colorMatrix || colorMatrix.length !== 20) {
      SkDebug('ignoring invalid color matrix');
      return;
    }
    var fptr = copy1dArray(colorMatrix, CanvasKit.HEAPF32);
    // We know skia memcopies the floats, so we can free our memory after the call returns.
    var m = CanvasKit.SkColorFilter._makeMatrix(fptr);
    CanvasKit._free(fptr);
    return m;
  }

  CanvasKit.SkShader.Blend = function(mode, dst, src, localMatrix) {
    if (!localMatrix) {
      return this._Blend(mode, dst, src);
    }
    return this._Blend(mode, dst, src, localMatrix);
  }

  CanvasKit.SkShader.Lerp = function(t, dst, src, localMatrix) {
    if (!localMatrix) {
      return this._Lerp(t, dst, src);
    }
    return this._Lerp(t, dst, src, localMatrix);
  }

  CanvasKit.SkSurface.prototype.captureFrameAsSkPicture = function(drawFrame) {
    // Set up SkPictureRecorder
    var spr = new CanvasKit.SkPictureRecorder();
    var canvas = spr.beginRecording(
                    CanvasKit.LTRBRect(0, 0, this.width(), this.height()));
    drawFrame(canvas);
    var pic = spr.finishRecordingAsPicture();
    spr.delete();
    // TODO: do we need to clean up the memory for canvas?
    // If we delete it here, saveAsFile doesn't work correctly.
    return pic;
  }

  CanvasKit.SkSurface.prototype.requestAnimationFrame = function(callback, dirtyRect) {
    if (!this._cached_canvas) {
      this._cached_canvas = this.getCanvas();
    }
    window.requestAnimationFrame(function() {
      if (this._context !== undefined) {
        CanvasKit.setCurrentContext(this._context);
      }

      callback(this._cached_canvas);

      // We do not dispose() of the SkSurface here, as the client will typically
      // call requestAnimationFrame again from within the supplied callback.
      // For drawing a single frame, prefer drawOnce().
      this.flush();
    }.bind(this));
  }

  // drawOnce will dispose of the surface after drawing the frame using the provided
  // callback.
  CanvasKit.SkSurface.prototype.drawOnce = function(callback, dirtyRect) {
    if (!this._cached_canvas) {
      this._cached_canvas = this.getCanvas();
    }
    window.requestAnimationFrame(function() {
      if (this._context !== undefined) {
        CanvasKit.setCurrentContext(this._context);
      }
      callback(this._cached_canvas);

      this.flush();
      this.dispose();
    }.bind(this));
  }

  // Run through the JS files that are added at compile time.
  if (CanvasKit._extraInitializations) {
    CanvasKit._extraInitializations.forEach(function(init) {
      init();
    });
  }
}; // end CanvasKit.onRuntimeInitialized, that is, anything changing prototypes or dynamic.

CanvasKit.LTRBRect = function(l, t, r, b) {
  return {
    fLeft: l,
    fTop: t,
    fRight: r,
    fBottom: b,
  };
}

CanvasKit.XYWHRect = function(x, y, w, h) {
  return {
    fLeft: x,
    fTop: y,
    fRight: x+w,
    fBottom: y+h,
  };
}

// RRectXY returns an RRect with the given rect and a radiusX and radiusY for
// all 4 corners.
CanvasKit.RRectXY = function(rect, rx, ry) {
  return {
    rect: rect,
    rx1: rx,
    ry1: ry,
    rx2: rx,
    ry2: ry,
    rx3: rx,
    ry3: ry,
    rx4: rx,
    ry4: ry,
  };
}

CanvasKit.MakePathFromCmds = function(cmds) {
  var ptrLen = loadCmdsTypedArray(cmds);
  var path = CanvasKit._MakePathFromCmds(ptrLen[0], ptrLen[1]);
  CanvasKit._free(ptrLen[0]);
  return path;
}

CanvasKit.MakeSkDashPathEffect = function(intervals, phase) {
  if (!phase) {
    phase = 0;
  }
  if (!intervals.length || intervals.length % 2 === 1) {
    throw 'Intervals array must have even length';
  }
  var ptr = copy1dArray(intervals, CanvasKit.HEAPF32);
  var dpe = CanvasKit._MakeSkDashPathEffect(ptr, intervals.length, phase);
  CanvasKit._free(ptr);
  return dpe;
}

// data is a TypedArray or ArrayBuffer e.g. from fetch().then(resp.arrayBuffer())
CanvasKit.MakeAnimatedImageFromEncoded = function(data) {
  data = new Uint8Array(data);

  var iptr = CanvasKit._malloc(data.byteLength);
  CanvasKit.HEAPU8.set(data, iptr);
  var img = CanvasKit._decodeAnimatedImage(iptr, data.byteLength);
  if (!img) {
    SkDebug('Could not decode animated image');
    return null;
  }
  return img;
}

// data is a TypedArray or ArrayBuffer e.g. from fetch().then(resp.arrayBuffer())
CanvasKit.MakeImageFromEncoded = function(data) {
  data = new Uint8Array(data);

  var iptr = CanvasKit._malloc(data.byteLength);
  CanvasKit.HEAPU8.set(data, iptr);
  var img = CanvasKit._decodeImage(iptr, data.byteLength);
  if (!img) {
    SkDebug('Could not decode image');
    return null;
  }
  return img;
}

// pixels must be a Uint8Array with bytes representing the pixel values
// (e.g. each set of 4 bytes could represent RGBA values for a single pixel).
CanvasKit.MakeImage = function(pixels, width, height, alphaType, colorType) {
  var bytesPerPixel = pixels.length / (width * height);
  var info = {
    'width': width,
    'height': height,
    'alphaType': alphaType,
    'colorType': colorType,
  };
  var pptr = copy1dArray(pixels, CanvasKit.HEAPU8);
  // No need to _free pptr, Image takes it with SkData::MakeFromMalloc

  return CanvasKit._MakeImage(info, pptr, pixels.length, width * bytesPerPixel);
}

CanvasKit.MakeLinearGradientShader = function(start, end, colors, pos, mode, localMatrix, flags) {
  var colorPtr = copy1dArray(colors, CanvasKit.HEAPU32);
  var posPtr =   copy1dArray(pos,    CanvasKit.HEAPF32);
  flags = flags || 0;

  if (localMatrix) {
    // Add perspective args if not provided.
    if (localMatrix.length === 6) {
      localMatrix.push(0, 0, 1);
    }
    var lgs = CanvasKit._MakeLinearGradientShader(start, end, colorPtr, posPtr,
                                                  colors.length, mode, flags, localMatrix);
  } else {
    var lgs = CanvasKit._MakeLinearGradientShader(start, end, colorPtr, posPtr,
                                                  colors.length, mode, flags);
  }

  CanvasKit._free(colorPtr);
  CanvasKit._free(posPtr);
  return lgs;
}

CanvasKit.MakeRadialGradientShader = function(center, radius, colors, pos, mode, localMatrix, flags) {
  var colorPtr = copy1dArray(colors, CanvasKit.HEAPU32);
  var posPtr =   copy1dArray(pos,    CanvasKit.HEAPF32);
  flags = flags || 0;

  if (localMatrix) {
    // Add perspective args if not provided.
    if (localMatrix.length === 6) {
      localMatrix.push(0, 0, 1);
    }
    var rgs = CanvasKit._MakeRadialGradientShader(center, radius, colorPtr, posPtr,
                                                  colors.length, mode, flags, localMatrix);
  } else {
    var rgs = CanvasKit._MakeRadialGradientShader(center, radius, colorPtr, posPtr,
                                                  colors.length, mode, flags);
  }

  CanvasKit._free(colorPtr);
  CanvasKit._free(posPtr);
  return rgs;
}

CanvasKit.MakeTwoPointConicalGradientShader = function(start, startRadius, end, endRadius,
                                                       colors, pos, mode, localMatrix, flags) {
  var colorPtr = copy1dArray(colors, CanvasKit.HEAPU32);
  var posPtr =   copy1dArray(pos,    CanvasKit.HEAPF32);
  flags = flags || 0;

  if (localMatrix) {
    // Add perspective args if not provided.
    if (localMatrix.length === 6) {
      localMatrix.push(0, 0, 1);
    }
    var rgs = CanvasKit._MakeTwoPointConicalGradientShader(
                        start, startRadius, end, endRadius,
                        colorPtr, posPtr, colors.length, mode, flags, localMatrix);
  } else {
    var rgs = CanvasKit._MakeTwoPointConicalGradientShader(
                        start, startRadius, end, endRadius,
                        colorPtr, posPtr, colors.length, mode, flags);
  }

  CanvasKit._free(colorPtr);
  CanvasKit._free(posPtr);
  return rgs;
}

CanvasKit.MakeSkVertices = function(mode, positions, textureCoordinates, colors,
                                    boneIndices, boneWeights, indices, isVolatile) {
  // Default isVolitile to true if not set
  isVolatile = isVolatile === undefined ? true : isVolatile;
  var idxCount = (indices && indices.length) || 0;

  var flags = 0;
  // These flags are from SkVertices.h and should be kept in sync with those.
  if (textureCoordinates && textureCoordinates.length) {
    flags |= (1 << 0);
  }
  if (colors && colors.length) {
    flags |= (1 << 1);
  }
  if (boneIndices && boneIndices.length) {
    flags |= (1 << 2);
  }
  if (!isVolatile) {
    flags |= (1 << 3);
  }

  var builder = new CanvasKit._SkVerticesBuilder(mode,  positions.length, idxCount, flags);

  copy2dArray(positions,            CanvasKit.HEAPF32, builder.positions());
  if (builder.texCoords()) {
    copy2dArray(textureCoordinates, CanvasKit.HEAPF32, builder.texCoords());
  }
  if (builder.colors()) {
    copy1dArray(colors,             CanvasKit.HEAPU32, builder.colors());
  }
  if (builder.boneIndices()) {
    copy2dArray(boneIndices,        CanvasKit.HEAP32, builder.boneIndices());
  }
  if (builder.boneWeights()) {
    copy2dArray(boneWeights,        CanvasKit.HEAPF32, builder.boneWeights());
  }
  if (builder.indices()) {
    copy1dArray(indices,            CanvasKit.HEAPU16, builder.indices());
  }

  var idxCount = (indices && indices.length) || 0;
  // Create the vertices, which owns the memory that the builder had allocated.
  return builder.detach();
};