Covering the Corral (corral.X) The cows are so modest they want Farmer John to install covers around the circular corral where they occasionally gather. The corral has circumference C (1 <= C <= 1,000,000,000), and FJ can choose from a set of M (1 <= M <= 100,000) covers that have fixed starting points and sizes. At least one set of covers can surround the entire corral. Cover i can be installed at integer location x_i (distance from starting point around corral) (0 <= x_i < C) and has integer length l_i (1 <= l_i <= C). FJ wants to minimize the number of segments he must install. What is the minimum number of segments required to cover the entire circumference of the corral? Consider a corral of circumference 5, shown below as a pair of connected line segments where both '0's are the same point on the corral (as are both 1's, 2's, and 3's). Three potential covering segments are available for installation: Start Length i x_i l_i 1 0 1 2 1 2 3 3 3 0 1 2 3 4 0 1 2 3 ... corral: +---+---+---+---+--:+---+---+---+- ... 11111 1111 22222222 22222222 333333333333 |..................| As shown, installing segments 2 and 3 cover an extent of (at least) five units around the circumference. FJ has no trouble with the overlap, so don't worry about that. PROBLEM NAME: corral INPUT FORMAT: * Line 1: Two space-separated integers: C and M * Lines 2..M+1: Line i+1 contains two space-separated integers: x_i and l_i SAMPLE INPUT: 5 3 0 1 1 2 3 3 OUTPUT FORMAT: * Line 1: A single integer that is the minimum number of segments required to cover all segments of the circumference of the corral SAMPLE OUTPUT: 2