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kittydar.js
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kittydar.js
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var hog = require("hog-descriptor"),
nms = require("./nms"),
nnOptions = require("./classifiers/nn-options"),
svmOptions = require("./classifiers/svm-options");
if (process.arch) { // in node
// make sure browserify doesn't pick this require up
var require_ = require;
var Canvas = require_('canvas');
}
exports.Kittydar = Kittydar;
exports.detectCats = function(canvas, options) {
var kittydar = new Kittydar(options);
return kittydar.detectCats(canvas);
}
var defaultParams = {
patchSize: 48, // size of training images in px
minSize: 48, // starting window size
resize: 360, // initial image resize size in px
scaleStep: 6, // scaling step size in px
shiftBy: 6, // px to slide window by
overlapThresh: 0.5, // min overlap ratio to classify as an overlap
minOverlaps: 2, // minumum overlapping rects to classify as a head
HOGparams: { // parameters for HOG descriptor
cellSize: 6, // must divide evenly into shiftBy
blockSize: 2,
blockStride: 1,
bins: 6,
norm: "L2"
},
extractFeatures: function(imagedata, histograms) {
// override if using another set of features
var descriptor = hog.extractHOGFromHistograms(histograms, this.HOGparams);
return descriptor;
},
classify: function(features) {
// override if using another classifier
var output = net.runInput(features)[0];
return {
isCat: output > 0.999,
value: output
};
}
}
function Kittydar(options) {
this.params = {};
extend(this.params, defaultParams);
extend(this.params, options);
if (this.params.classifier == "svm") {
// use the support vector machine as the classifier
extend(this.params, svmOptions);
}
else {
// use the neural network as the classifier
extend(this.params, nnOptions);
}
}
Kittydar.prototype = {
detectCats: function(canvas) {
// get canvases of the image at different scales
var resizes = this.getAllSizes(canvas, this.params.minSize);
var cats = [];
resizes.forEach(function(resize) {
var kitties = this.detectAtScale(resize.imagedata, resize.scale);
cats = cats.concat(kitties);
}.bind(this));
cats = this.combineOverlaps(cats, this.params.overlapThresh, this.params.minOverlaps);
return cats;
},
getAllSizes: function(canvas, minSize) {
// For use with Worker threads, return canvas ImageDatas
// resized to accomodate various window sizes
minSize = minSize || this.params.minSize;
// resize canvas to cut down on number of windows to check
var max = Math.max(canvas.width, canvas.height)
var scale = Math.min(max, this.params.resize) / max;
var resizes = [];
for (var size = minSize; size < max; size += this.params.scaleStep) {
var winScale = (minSize / size) * scale;
var imagedata = this.scaleCanvas(canvas, winScale);
resizes.push({
imagedata: imagedata,
scale: winScale,
size: size
})
}
return resizes;
},
scaleCanvas: function(canvas, scale) {
var width = Math.floor(canvas.width * scale);
var height = Math.floor(canvas.height * scale);
canvas = resizeCanvas(canvas, width, height);
var ctx = canvas.getContext("2d");
var imagedata = ctx.getImageData(0, 0, width, height);
return imagedata;
},
detectAtScale: function(imagedata, scale) {
// Detect using a sliding window of a fixed size.
var histograms = hog.extractHistograms(imagedata, this.params.HOGparams);
var cats = [];
var width = imagedata.width,
height = imagedata.height;
var size = this.params.patchSize;
var shift = this.params.shiftBy;
for (var y = 0; y + size < height; y += shift) {
for (var x = 0; x + size < width; x += shift) {
var histRect = getRect(histograms, x / shift, y / shift, size / shift, size / shift);
var features = this.params.extractFeatures(imagedata, histRect);
var result = this.params.classify(features);
if (result.isCat) {
cats.push({
x: Math.floor(x / scale),
y: Math.floor(y / scale),
width: Math.floor(size / scale),
height: Math.floor(size / scale),
value: result.value
});
}
}
}
return cats;
},
combineOverlaps: function(rects, overlapThresh, minOverlaps) {
cats = nms.combineOverlaps(rects, overlapThresh, minOverlaps);
return cats;
}
}
function getRect(matrix, x, y, width, height) {
var square = new Array(height);
for (var i = 0; i < height; i++) {
square[i] = new Array(width);
for (var j = 0; j < width; j++) {
square[i][j] = matrix[y + i][x + j];
}
}
return square;
}
function resizeCanvas(canvas, width, height) {
var resizeCanvas = createCanvas(width, height);
var ctx = resizeCanvas.getContext('2d');
ctx.patternQuality = "best";
ctx.drawImage(canvas, 0, 0, canvas.width, canvas.height,
0, 0, width, height);
return resizeCanvas;
}
function createCanvas(width, height) {
if (typeof Canvas !== 'undefined') {
// have node-canvas
return new Canvas(width, height);
}
else {
// in browser
var canvas = document.createElement('canvas');
canvas.setAttribute('width', width);
canvas.setAttribute('height', height);
return canvas;
}
}
function extend(object, extensions) {
for (ext in extensions) {
object[ext] = extensions[ext];
}
}