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I need an algorithm that given an image's width, height and a target ratio will calculate the number of pixels to be shaved from the image's sides to get to that ratio, that has the smallest change in the image's area.

How might one implement such an algorithm?

Edit

Sorry for the inconsistency in my original question; I have revised my it.

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"calculate the smallest number of pixels to be shaved from the image's sides" is a different goal than "shave_width - shave_height closest to 0". Which one do you want? –  mbeckish Sep 13 '11 at 12:40
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To elaborate on @mbeckish's comment, say the given example values are width = 500 and height = 270 and ratio = 2. Then shave_width = shave_height = 40 makes shave_width - shave_height == 0. Are they the desired values? –  tafa Sep 13 '11 at 12:44
    
(w-sw)/(h-sh) = r, sh = h + sw/r -w/r, differentiate d(sh)/d(sw) = -1/r, diff is 0 at minimum sh. Which isn't any help! Might I suggest an iterative, trial and improvement binomial approach instead? You give a concise mathematical explanation but I struggle to see the application of such an algorithm. –  John Sep 13 '11 at 12:47
    
Continuing @tafa's example - would the answer be shave_width=0, shave_height=20, which satisfies "calculate the smallest number of pixels to be shaved from the image's sides"? –  mbeckish Sep 13 '11 at 12:48
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Maybe you want to minimize the change in area between the original image and final image? Min((x*y)-((x-sx)*(y-sy))? –  mbeckish Sep 13 '11 at 12:53

2 Answers 2

up vote 4 down vote accepted
  1. Bring the ratio into reduced form, so that gcd(ratio_width, ratio_height) = 1.
  2. Calculate floor(width / ratio_width) and floor(height / ratio_height). Your factor is the minimum of these two.
  3. Multiply ratio_width and ratio_height by that factor to obtain the new image dimensions.
  4. Shave the difference.
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To minimize the change in area, you want to find the largest rectangle of the desired aspect ratio that will fit inside the original image bounds.

So, if the original image is too wide, then make the final image's height = original height, and shave off the extra width.

If the original image is too tall, make the final image's width = original width, and shave off the extra height.

Note: This assumes that you are not allowed to increase the width or height beyond the original dimensions. If that is not the case, the algorithm would be:

Constraint 1: x_final * y_final = x_initial * y_initial

Contraint 2: x_final / y_final = r

The solution is:

x_final = sqrt(r*x_initial*y_initial)

y_final = sqrt(x_initial*y_initial/r)

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what if the original is 4x4 and the desired ratio is 3:2? You can't make it 4x2.66666666667 –  harold Sep 13 '11 at 13:30
    
@harold - Round. –  mbeckish Sep 13 '11 at 13:40
    
well then the aspect ratio is wrong –  harold Sep 13 '11 at 13:41
    
@harold - Yes. It depends on the application. For example, what if the given ratio had 8 digits of precision, and required millions of pixels to get the ratio exact? Would you want a giant image, or an aspect ratio that is close enough? –  mbeckish Sep 13 '11 at 13:46
    
well no offense but that makes no sense. Certainly there are aspect ratio's which it is impossible to crop a given image to, for example 4x4 can't be cropped to 1:5. Seeing as it's cropping, the image can never grow. But that wasn't what I was talking about - given a ratio of 3:2 and an image which is 4x4, the result of 4x3 is simply wrong and obviously not what the OP is asking for. –  harold Sep 13 '11 at 13:58

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