#!/usr/bin/python2 # Ion Flux Relabeling # =================== # Oh no! Commander Lambda's latest experiment to improve the efficiency of her # LAMBCHOP doomsday device has backfired spectacularly. She had been improving # the structure of the ion flux converter tree, but something went terribly # wrong and the flux chains exploded. Some of the ion flux converters survived # the explosion intact, but others had their position labels blasted off. She's # having her henchmen rebuild the ion flux converter tree by hand, but you # think you can do it much more quickly - quickly enough, perhaps, to earn a # promotion! # Flux chains require perfect binary trees, so Lambda's design arranged the ion # flux converters to form one. To label them, she performed a post-order # traversal of the tree of converters and labeled each converter with the order # of that converter in the traversal, starting at 1. For example, a tree of 7 # converters would look like the following: # 7 # 3 6 # 1 2 4 5 # Write a function solution(h, q) - where h is the height of the perfect tree # of converters and q is a list of positive integers representing different # flux converters - which returns a list of integers p where each element in p # is the label of the converter that sits on top of the respective converter in # q, or -1 if there is no such converter. For example, solution(3, [1, 4, 7]) # would return the converters above the converters at indexes 1, 4, and 7 in a # perfect binary tree of height 3, which is [3, 6, -1]. # The domain of the integer h is 1 <= h <= 30, where h = 1 represents a perfect # binary tree containing only the root, h = 2 represents a perfect binary tree # with the root and two leaf nodes, h = 3 represents a perfect binary tree with # the root, two internal nodes and four leaf nodes (like the example above), # and so forth. The lists q and p contain at least one but no more than 10000 # distinct integers, all of which will be between 1 and 2^h-1, inclusive. def findParent(h, n): start = 1 end = 2**h - 1 if end == n: return -1 while(True): end = end - 1 mid = start + (end - start)//2 if mid == n or end == n: return end + 1 elif n < mid: end = mid else: start = mid def solution(h, q): p = [] for i in q: p.append(findParent(h, i)) return p print(solution(5, [19, 14, 28])) # 21,15,29 print(solution(3, [7, 3, 5, 1])) # -1,7,6,3