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  • calculate.coffee

  • ¶

    Various math-heavy helpers that are used throughout CamanJS.

    class Caman.Calculate
  • ¶

    Calculates the distance between two points.

    @param [Number] x1 1st point x-coordinate. @param [Number] y1 1st point y-coordinate. @param [Number] x2 2nd point x-coordinate. @param [Number] y2 2nd point y-coordinate. @return [Number] The distance between the two points.

      @distance: (x1, y1, x2, y2) ->
    Math.sqrt Math.pow(x2 - x1, 2) + Math.pow(y2 - y1, 2)
  • ¶

    Generates a pseudorandom number that lies within the max - mix range. The number can be either an integer or a float depending on what the user specifies.

    @param [Number] min The lower bound (inclusive). @param [Number] max The upper bound (inclusive). @param [Boolean] getFloat Return a Float or a rounded Integer? @return [Number] The pseudorandom number, either as a float or integer.

      @randomRange: (min, max, getFloat = false) ->
    rand = min + (Math.random() * (max - min))
    return if getFloat then rand.toFixed(getFloat) else Math.round(rand)
  • ¶

    Calculates the luminance of a single pixel using a special weighted sum. @param [Object] rgba RGBA object describing a single pixel. @return [Number] The luminance value of the pixel.

      @luminance: (rgba) -> (0.299 * rgba.r) + (0.587 * rgba.g) + (0.114 * rgba.b)
  • ¶

    Generates a bezier curve given a start and end point, with two control points in between. Can also optionally bound the y values between a low and high bound.

    This is different than most bezier curve functions because it attempts to construct it in such a way that we can use it more like a simple input -> output system, or a one-to-one function. In other words we can provide an input color value, and immediately receive an output modified color value.

    Note that, by design, this does not force X values to be in the range [0..255]. This is to generalize the function a bit more. If you give it a starting X value that isn't 0, and/or a ending X value that isn't 255, you may run into problems with your filter!

    @param [Array] start 2-item array describing the x, y coordinate of the start point. @param [Array] ctrl1 2-item array describing the x, y coordinate of the first control point. @param [Array] ctrl2 2-item array decribing the x, y coordinate of the second control point. @param [Array] end 2-item array describing the x, y coordinate of the end point. @param [Number] lowBound (optional) Minimum possible value for any y-value in the curve. @param [Number] highBound (optional) Maximum posisble value for any y-value in the curve. @return [Array] Array whose index represents every x-value between start and end, and value represents the corresponding y-value.

      @bezier: (start, ctrl1, ctrl2, end, lowBound, highBound) ->
    x0 = start[0]
    y0 = start[1]
    x1 = ctrl1[0]
    y1 = ctrl1[1]
    x2 = ctrl2[0]
    y2 = ctrl2[1]
    x3 = end[0]
    y3 = end[1]
    bezier = {}
  • ¶

    Calculate our X/Y coefficients

        Cx = parseInt(3 * (x1 - x0), 10)
    Bx = 3 * (x2 - x1) - Cx
    Ax = x3 - x0 - Cx - Bx

    Cy = 3 * (y1 - y0)
    By = 3 * (y2 - y1) - Cy
    Ay = y3 - y0 - Cy - By
  • ¶

    1000 is actually arbitrary. We need to make sure we do enough calculations between 0 and 255 that, in even the more extreme circumstances, we calculate as many values as possible. In the event that an X value is skipped, it will be found later on using linear interpolation.

        for i in [0...1000]
      t = i / 1000

      curveX = Math.round (Ax * Math.pow(t, 3)) + (Bx * Math.pow(t, 2)) + (Cx * t) + x0
      curveY = Math.round (Ay * Math.pow(t, 3)) + (By * Math.pow(t, 2)) + (Cy * t) + y0

      if lowBound and curveY < lowBound
        curveY = lowBound
      else if highBound and curveY > highBound
        curveY = highBound

      bezier[curveX] = curveY
  • ¶

    Do a search for missing values in the bezier array and use linear interpolation to approximate their values

        if bezier.length < end[0] + 1
      for i in [0..end[0]]
        if not bezier[i]?
          leftCoord = [i-1, bezier[i-1]]
  • ¶

    Find the first value to the right. Ideally this loop will break very quickly.

              for j in [i..end[0]]
            if bezier[j]?
              rightCoord = [j, bezier[j]]
              break

          bezier[i] = leftCoord[1] + 
            ((rightCoord[1] - leftCoord[1]) / (rightCoord[0] - leftCoord[0])) * 
            (i - leftCoord[0])
  • ¶

    Edge case

        bezier[end[0]] = bezier[end[0] - 1] if not bezier[end[0]]?
    
    return bezier
      
Calculate = Caman.Calculate