For example I have a pie chart drawn where I have n number of components and I have their percentage values in an array. And now I get the array of percentage updated and I want to repaint the pie chart. Is there any algorithm to draw it with minimum change of coloring required? I was thinking that A* can be the optimum solution but finding the heuristic for this problem is hard.

Personally I wouldn't bother I'd just repaint the pie chart. I expect the time saved by not repainting unchanged parts of the chart will be overwhelmed by the time spent figuring out what to change. Nevertheless, here's an idea: Draw your pie charts as a set of 100 triangles arranged in a circle. If 100 isn't enough to make the chart look pretty, choose some integer multiple of 100. Suppose that segment A is 20% of the original chart and is the first (counting clockwise from 12 o'clock) segment in the chart. On painting simply colour triangles 120 as you wish. If segment A expands to 25%, repaint triangles 2125. And so on. I don't think I've ever seen a pie chart where fractions of percentages were visually meaningful so I wouldn't sweat over dealing with values such as 23.8%, I'd just round them. 


This is not a solution. I simply tried to formalize the problem and see if I can come up with something. I'm afraid the the problem has no solution with low computational cost. Let's start by formalizing the problem: Input: Two ordered sets of n points on the circumference of a circle: A(1)..A(n) and B(1)..B(n), each defines a set of arcs such that
Basic Math: The arclength of the arc between angle x and y is mod(yx,360) (arcs are notated clockwise). where mod(a,b) = ab*floor(a/b)* We'll mark O(a1,a2,b1,b2) as the intersection between arc [a1,a2) and arc [b1,b2). Note the two arcs can have between 0 and 2 intersections. e.g O(270,100,90,280)= {[270,280),[90,100)}, while O(10,20,30,40)= {} We'll mark L(a1,a2,b1,b2) as the arclength of the larger intersection between arc [a1,a2) and arc [b1,b2) . I won't describe the calculation of L(a1,a2,b1,b2) here. Special case: Keeping the same order of arcs: Find a drawing offset w that maximizes L(A(1),A(2),mod(B(1)+w,360),mod(B(2)+w,360)) + L(A(2),A(3),mod(B(2)+w,360),mod(B(3)+w,360)) + ... + L(A(n),A(1),mod(B(n)+w,360),B(1),mod(B(1)+w,360) General case: Without keeping the same order of arcs: Find both
That maximizes the same expression as in the special case. My thoughts I'm afraid that due to the noncontinuity of the modulo function, there is no easy way to find an optimal solution. For the special case, you may simply search for an optimal w starting with a given resolution (e.g. 0.1 degrees), and increase the resolution near the best w's (You don't need a subpixel resolution anyway). As for the general case, I believe that you'll have to find a good heuristic for limiting the permutations set  maybe by leaving large arcs at about the same places. 


Guessing its not just repainting work your after but.. make dubbelbuffer, compare, paint difference. 

