blog-static/code/cs325-langs/hws/hw4.txt

115 lines
4.0 KiB
Plaintext
Raw Permalink Normal View History

2019-12-27 23:18:00 -08:00
CS 325-001, Algorithms, Fall 2019
HW4 - Priority Queue and Heaps
Due via the submit program on Monday Oct 21, 11:59pm.
No late submission will be accepted.
Need to submit: report.txt, nbest.py, kmergesort.py, datastream.py.
datastream.py will be graded for correctness (1%).
To submit:
flip $ /nfs/farm/classes/eecs/fall2019/cs325-001/submit hw4 report.txt {nbest,kmergesort,datastream}.py
(You can submit each file separately, or submit them together.)
To see your best results so far:
flip $ /nfs/farm/classes/eecs/fall2019/cs325-001/query hw4
Textbooks for References:
[1] CLRS Ch. 6
[2] KT slides for binary heaps (only read the first 20 pages!):
https://www.cs.princeton.edu/~wayne/kleinberg-tardos/pdf/BinomialHeaps.pdf
[3] Python heapq module
0. There are two methods for building a heap from an unsorted array:
(1) insert each element into the heap --- O(nlogn) -- heapq.heappush()
(2) heapify (top-down) --- O(n) -- heapq.heapify()
(a) Derive these time complexities.
(b) Use a long list of random numbers to show the difference in time. (Hint: random.shuffle or random.sample)
(c) What about sorted or reversely-sorted numbers?
1. Given two lists A and B, each with n integers, return
a sorted list C that contains the smallest n elements from AxB:
AxB = { (x, y) | x in A, y in B }
i.e., AxB is the Cartesian Product of A and B.
ordering: (x,y) < (x',y') iff. x+y < x'+y' or (x+y==x'+y' and y<y')
You need to implement three algorithms and compare:
(a) enumerate all n^2 pairs, sort, and take top n.
(b) enumerate all n^2 pairs, but use qselect from hw1.
(c) Dijkstra-style best-first, only enumerate O(n) (at most 2n) pairs.
Hint: you can use Python's heapq module for priority queue.
Q: What are the time complexities of these algorithms?
>>> a, b = [4, 1, 5, 3], [2, 6, 3, 4]
>>> nbesta(a, b) # algorithm (a), slowest
[(1, 2), (1, 3), (3, 2), (1, 4)]
>>> nbestb(a, b) # algorithm (b), slow
[(1, 2), (1, 3), (3, 2), (1, 4)]
>>> nbestc(a, b) # algorithm (c), fast
[(1, 2), (1, 3), (3, 2), (1, 4)]
Filename: nbest.py
2. k-way mergesort (the classical mergesort is a special case where k=2).
>>> kmergesort([4,1,5,2,6,3,7,0], 3) # k=3
[0,1,2,3,4,5,6,7]
Q: What is the complexity? Write down the detailed analysis in report.txt.
Filename: kmergesort.py
3. [WILL BE GRADED]
Find the k smallest numbers in a data stream of length n (k<<n),
using only O(k) space (the stream itself might be too big to fit in memory).
>>> ksmallest(4, [10, 2, 9, 3, 7, 8, 11, 5, 7])
[2, 3, 5, 7]
>>> ksmallest(3, range(1000000, 0, -1))
[1, 2, 3]
Note:
a) it should work with both lists and lazy lists
b) the output list should be sorted
Q: What is your complexity? Write down the detailed analysis in report.txt.
Filename: datastream.py
[UPDATE] The built-in function heapq.nsmallest() is _not_ allowed for this problem.
The whole point is to implement it yourself. :)
4. (optional) Summarize the time complexities of the basic operations (push, pop-min, peak, heapify) for these implementations of priority queue:
(a) unsorted array
(b) sorted array (highest priority first)
(c) reversly sorted array (lowest priority first)
(d) linked list
(e) binary heap
Debriefing (required!): --------------------------
0. What's your name?
1. Approximately how many hours did you spend on this assignment?
2. Would you rate it as easy, moderate, or difficult?
3. Did you work on it mostly alone, or mostly with other people?
Note you are encouraged to discuss with your classmates,
but each students should submit his/her own code.
4. How deeply do you feel you understand the material it covers (0%-100%)?
5. Which part(s) of the course you like the most so far?
6. Which part(s) of the course you dislike the most so far?
This section is intended to help us calibrate the homework assignments.
Your answers to this section will *not* affect your grade; however, skipping it
will certainly do.