Difference between revisions of "MergeSort"
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==SequentialMergeSorter== | ==SequentialMergeSorter== | ||
+ | {{CodeToImplement|SequentialMergeSorter|sortRange|sort.merge.studio}} | ||
− | {{ | + | Implement the classic divide and conquer sequential algorithm here. |
+ | |||
+ | {{Warning|Be use to leverage the provided <nowiki>private final Combiner<T> combiner;</nowiki> field to perform the combine step.}} | ||
==ParallelMergeSorter== | ==ParallelMergeSorter== |
Revision as of 16:31, 10 November 2021
Contents
Motivation
Sorting is a problem that is well solved by divide and conquer algorithms. Merge sort is a elegant example which can be parallelized in a straight-forward manner.
Finally, parallelization of the combine step, while not trivial, is possible (and left as an optional fun exercise for those so inclined).
Background
In computer science, merge sort refers to a sorting algorithm which splits an array of data into continuously smaller halves until the arrays reach a size of 1, after which the elements are continuously compared and merged into a sorted array.
For more information on how this process works, visit the wikipedia page on merge sort.
Visualization
If you are unclear on how merge sort works, take a look at the visualgo explanation and visualization of merge sort.
The Core Questions
- What are the tasks?
- What is the data?
- Is the data mutable?
- If so, how is it shared?
Mistakes To Avoid
Warning: Be sure to calculate the midpoint correctly. |
Warning: When checking the base case, remember to account for [minInclusive, maxExclusive). It is all too easy to get an off by 1 error and stack overflow. |
Warning: When transitioning to sequential, make sure to NOT sort the entire array when you are only responsible for a range [min,max). |
Code to Use
Both the sequential and parallel merge sorts will be passed a Combiner. When you are done with the divide and conquer phases, invoke combiner.combineRange(data, min, mid, maxExclusive) to merge the two sorted sub-problem results.
Code to Implement
You will need to implement merge sort sequentially and in parallel, but you will need to do both implementations recursively. The kernel method should call itself using recursion, but each public mergesort method should only call its kernel once to do the work.
Sorter
class: | Sorter.java | |
methods: | sort | |
package: | sort.core | |
source folder: | student/src/main/java |
Here you will provide the default implementation of the sort method.
default void sort(T[] data, Comparator<T> comparator)
You should simply invoke the sortRange method with the correct arguments.
SequentialCombiner
class: | SequentialCombiner.java | |
methods: | combineRangeIntoBuffer | |
package: | sort.merge.studio | |
source folder: | student/src/main/java |
Merge sort's combine step leverages the fact that it can rely on the two sub-ranges are provided in sorted order. Use this fact to fill the provided temporary buffer with the sorted contents of the entire range [min, maxExclusive).
Performance note: in an effort to make this part of the assignment more appropriately approachable, a temporary buffer will be created, combined into, and copied back from. Merge sort can be built such that depths of the recursion alternate which buffer is read from and written to. The added complexity this performance improvement would incur is not deemed valuable from a pedagogical stand point, but it is worth noting.
The public method combineRange(data, comparator, min, mid, maxExclusive) is provided:
@Override public void combineRange(T[] data, Comparator<T> comparator, int min, int mid, int maxExclusive) { int rangeLength = maxExclusive - min; T[] buffer = ArrayUtils.createArray(componentType, rangeLength); combineRangeIntoBuffer(buffer, data, comparator, min, mid, maxExclusive); System.arraycopy(buffer, 0, data, min, maxExclusive - min); }
It creates a temporary buffer and passes it to combineRangeIntoBuffer(buffer, data, comparator, min, mid, maxExclusive) which you will implement to fill the temporary buffer with the combined sorted contents. The contents of the temporary buffer is then copied back to the data array.
SequentialMergeSorter
class: | SequentialMergeSorter.java | |
methods: | sortRange | |
package: | sort.merge.studio | |
source folder: | student/src/main/java |
Implement the classic divide and conquer sequential algorithm here.
Warning:Be use to leverage the provided private final Combiner<T> combiner; field to perform the combine step. |
ParallelMergeSorter
class: | ParallelMergeSorter.java | |
methods: | sortRange | |
package: | sort.merge.studio | |
source folder: | student/src/main/java |
(Optional) Challenge Parallel Combiner
You can divide and conquer the combine step in merge sort. The work should remain while the critical path length can be cleanly improved from down to .
For details on how to complete this challenge, check out: MergeSort_Parallel_Combiner
Testing Your Solution
Correctness
class: | MergeSortTestSuite.java | |
package: | sort.merge.studio | |
source folder: | testing/src/test/java |
Performance
class: | SortTiming.java | |
package: | sort | |
source folder: | src/main/java |
Note: do not be concerned if your implementations run slower than Java's highly optimized Dual Pivot Quicksort.
Pledge, Acknowledgments, Citations
file: | studio-merge-sort-pledge-acknowledgments-citations.txt |
More info about the Honor Pledge