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the-skyline-problem.py
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the-skyline-problem.py
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# Time: O(nlogn)
# Space: O(n)
#
# A city's skyline is the outer contour of the silhouette formed
# by all the buildings in that city when viewed from a distance.
# Now suppose you are given the locations and height of all the
# buildings as shown on a cityscape photo (Figure A), write a
# program to output the skyline formed by these buildings
# collectively (Figure B).
#
# The geometric information of each building is represented by a
# triplet of integers [Li, Ri, Hi], where Li and Ri are the x
# coordinates of the left and right edge of the ith building,
# respectively, and Hi is its height. It is guaranteed that 0 <= Li,
# Ri <= INT_MAX, 0 < Hi <= INT_MAX, and Ri - Li > 0. You may assume
# all buildings are perfect rectangles grounded on an absolutely
# flat surface at height 0.
#
# Notes:
#
# The number of buildings in any input list is guaranteed to be
# in the range [0, 10000].
# The input list is already sorted in ascending order by the
# left x position Li.
# The output list must be sorted by the x position.
# There must be no consecutive horizontal lines of equal height
# in the output skyline.
# For instance, [...[2 3], [4 5], [7 5], [11 5], [12 7]...] is
# not acceptable;
# the three lines of height 5 should be merged into one
# in the final output as such: [...[2 3], [4 5], [12 7], ...]
#
# Divide and conquer solution.
start, end, height = 0, 1, 2
class Solution:
# @param {integer[][]} buildings
# @return {integer[][]}
def getSkyline(self, buildings):
intervals = self.ComputeSkylineInInterval(buildings, 0, len(buildings))
res = []
last_end = -1
for interval in intervals:
if last_end != -1 and last_end < interval[start]:
res.append([last_end, 0])
res.append([interval[start], interval[height]])
last_end = interval[end]
if last_end != -1:
res.append([last_end, 0])
return res
# Divide and Conquer.
def ComputeSkylineInInterval(self, buildings, left_endpoint, right_endpoint):
if right_endpoint - left_endpoint <= 1:
return buildings[left_endpoint:right_endpoint]
mid = left_endpoint + ((right_endpoint - left_endpoint) / 2)
left_skyline = self.ComputeSkylineInInterval(buildings, left_endpoint, mid)
right_skyline = self.ComputeSkylineInInterval(buildings, mid, right_endpoint)
return self.MergeSkylines(left_skyline, right_skyline)
# Merge Sort.
def MergeSkylines(self, left_skyline, right_skyline):
i, j = 0, 0
merged = []
while i < len(left_skyline) and j < len(right_skyline):
if left_skyline[i][end] < right_skyline[j][start]:
merged.append(left_skyline[i])
i += 1
elif right_skyline[j][end] < left_skyline[i][start]:
merged.append(right_skyline[j])
j += 1
elif left_skyline[i][start] <= right_skyline[j][start]:
i, j = self.MergeIntersectSkylines(merged, left_skyline[i], i,\
right_skyline[j], j)
else: # left_skyline[i][start] > right_skyline[j][start].
j, i = self.MergeIntersectSkylines(merged, right_skyline[j], j, \
left_skyline[i], i)
# Insert the remaining skylines.
merged += left_skyline[i:]
merged += right_skyline[j:]
return merged
# a[start] <= b[start]
def MergeIntersectSkylines(self, merged, a, a_idx, b, b_idx):
if a[end] <= b[end]:
if a[height] > b[height]: # |aaa|
if b[end] != a[end]: # |abb|b
b[start] = a[end]
merged.append(a)
a_idx += 1
else: # aaa
b_idx += 1 # abb
elif a[height] == b[height]: # abb
b[start] = a[start] # abb
a_idx += 1
else: # a[height] < b[height].
if a[start] != b[start]: # bb
merged.append([a[start], b[start], a[height]]) # |a|bb
a_idx += 1
else: # a[end] > b[end].
if a[height] >= b[height]: # aaaa
b_idx += 1 # abba
else:
# |bb|
# |a||bb|a
if a[start] != b[start]:
merged.append([a[start], b[start], a[height]])
a[start] = b[end]
merged.append(b)
b_idx += 1
return a_idx, b_idx