Presentation is loading. Please wait.

Presentation is loading. Please wait.

Optimizing Sorting With Genetic Algorithms Xiaoming Li, María Jesús Garzarán, and David Padua University of Illinois at Urbana-Champaign.

Published byAnastasia Skinner Modified over 8 years ago

Similar presentations

Presentation on theme: "Optimizing Sorting With Genetic Algorithms Xiaoming Li, María Jesús Garzarán, and David Padua University of Illinois at Urbana-Champaign."— Presentation transcript:

1 Optimizing Sorting With Genetic Algorithms Xiaoming Li, María Jesús Garzarán, and David Padua University of Illinois at Urbana-Champaign

2 ESSL on Power3

3 ESSL on Power4

4 Outline  Our Solution  Primitives & Selection mechanisms  Genetic Algorithm  Performance results  Classifier System  Conclusion

5 Motivation  No universally best sorting algorithm  Can we automatically GENERATE and tune sorting algorithms for each platform (such as FFTW and Spiral)? –Performance of sorting on the platform and on the input characteristics.  The algorithm selection may not be enough.

6 Algorithm Selection (CGO’04)  Select the best algorithm from Quicksort, Multiway Merge Sort and CC-radix.  Relevant input characteristics: number of keys, entropy vector.

7 Algorithm Selection (CGO’0

8 Proposed Solution  We need different algorithms for different partitions  The best sorting algorithm should be the result of the composition of the these different best algorithms.  Build Composite Sorting algorithms –Identify primitives from the sorting algorithms –Design a general method to select an appropriate sorting primitive at runtime –Design a mechanism to combine the primitives and the selection methods to generate the composite sorting algorithm

9 Outline  Our Solution  Primitives & Selection mechanisms  Genetic Algorithm  Performance results  Classifier System  Conclusion

10 Sorting Primitives  Divide-by-Value –A step in Quicksort –Select one or multiple pivots and sort the input array around these pivots –Parameter: number of pivots  Divide-by-Position (DP) –Divide input into same-size sub-partitions –Use heap to merge the multiple sorted sub-partitions –Parameters: size of sub-partitions, fan-out and size of the heap

11 Sorting Primitives  Divide-by-Radix (DR) –Non-comparison based sorting algorithm –Parameter: radix (r bits) –Step 1: Scan the input to get distribution array, which records how many elements in each of the 2 r sub-partitions. –Step 2: Compute the accumulative distribution array, which is used as the indexes when copying the input to the destination array. –Step 3: Copy the input to the 2 r sub-partitions. 1 1 1 1 01230123 counter 0 1 2 3 01230123 accum.dest. 11 23 30 12 src. 30 11 12 23 1 2 3 4

12 Sorting Primitives  Divide-by-radix-assuming-uniform-distribution (DU) –Step 1 and Step 2 in DR are expensive. –If the input elements are distributed among 2 r sub-partitions near evenly, the input can be copied into the destination array directly assuming every partition have the same number of elements. –Overhead: partition overflow –Parameter: radix (r bits) 0 1 2 3 01230123 accum.dest.src. 1 2 3 4 30 11 12 23 11 23 30 12

13 Selection Primitives Branch-by-Size Branch-by-Entropy –Parameter: number of branches, threshold vector of the branches

14 Leaf Primitives  When the size of a partition is small, we stick to one algorithm to sort the partition fully.  Two methods are used in the cleanup operation –Quicksort –CC-Radix

15 Composite Sorting Algorithms The composite sorting algorithms are built from these primitives. The algorithms have shapes of tree.

16 Outline  Our Solution  Primitives & Selection mechanisms  Genetic Algorithm  Performance results  Classifier System  Conclusion

17 Search Strategy  Search the best tree  Search the best parameter values of the primitives –Good solutions for small size problem should be retained to use in the solution for larger problem.  Genetic algorithms are a natural solution that satisfy the requirements: –Preserve good sub-trees –Give good sub-trees more chances to propagate

18 Composite Sorting Algorithms Search the best parameter values to adapt –To the architectural features –To the input characteristics

19 Search Strategy  Search for the best tree  Search for the best parameter values of the primitives –Good solutions for small size problem should be retained to use in the solution for larger problem.  Genetic algorithms are a natural solution that satisfy the requirements: –Preserve good sub-trees –Give good sub-trees more chances to propagate

20 Genetic Algorithm Mutation –Mutate the structure of the algorithm. –Change the parameter values of primitives.

21 Crossover Propagate good sub-trees

22 Fitness Function  A fitness function measures the relative performance of the genomes in a population.  The average performance of a genome on the training inputs is the base for the fitness of the genome.  A genome which performs well across inputs is preferred –fitness is penalized when performance varies across the test inputs

23 Library Generation  Installation phase: Use genetic algorithm to search for the sorting genome. –Set of genomes in initial population –Test the genomes in a set of inputs with different characteristics

24 Outline  Our Solution  Primitives & Selection mechanisms  Genetic Algorithm  Performance results  Classifier System  Conclusion

25 Platforms  AMD Athlon MP  Sun UltraSparcIII  SGI R12000  IBM Power3  IBM Power4  Intel Itanium2  Intel Xeon

26 AMD Athlon MP

27 Power3

28 Multiple-peak Performance

29 Outline  Our Solution  Primitives & Selection mechanisms  Genetic Algorithm  Performance results  Classifier System  Conclusion

30 The best genomes in different regions

31 Problems of Genetic Adaptation  Fitness function is the average performance of the genome on the test inputs.  Fitness function in our genetic algorithm prefers genomes with stable performance  The genetic algorithm is not powerful enough to evolve into the complex genome which chooses the best genome in each small region

32 Using Classifier System  Search the best genomes for different regions of the input characteristics. –Selects the regions –Selects the best algorithm for each region  Nice feature: The fitness of a genomes in a region will not be affected by its fitness in other regions

33 Map sorting composition into a classifier system  The input characteristics (number of keys and entropy vector) are encoded into bit strings.  A rule in the classifier system has two parts –Condition: A string consisting of ‘0’, ‘1’, and ‘*’. Condition string will be used to match the encoded input characteristics. –Action: Sorting genomes without branch primitives

34 Example for Classifier Sorting Example: –For inputs of up-to 16M keys –Encode number of keys with 4 bits. 0000: 0~1M, 0001: 1~2M… Number of keys = 10.5M. Encoded into “1100” ConditionActionFitnessAccuracy (dr 5 (lq 1 16)) …… (dp 4 2 ( lr 5 16)) …… …… 1100 01** 1010 110*(dv 2 ( lr 6 16))

35 Performance of Classifier Sorting Power3

36 Power4

37 Conclusions  Replace the complexity of finding an efficient algorithm with the task of defining a set of generic primitives.  Design methods to search in the space of the composition of the primitives. Genetic algorithms Classifier system

Download ppt "Optimizing Sorting With Genetic Algorithms Xiaoming Li, María Jesús Garzarán, and David Padua University of Illinois at Urbana-Champaign."

Similar presentations

Algorithm Design Techniques

Algorithm Design Techniques
Optimizing Matrix Multiplication with a Classifier Learning System Xiaoming Li (presenter) María Jesús Garzarán University of Illinois at Urbana-Champaign.

Optimizing Matrix Multiplication with a Classifier Learning System Xiaoming Li (presenter) María Jesús Garzarán University of Illinois at Urbana-Champaign.
Representing Hypothesis Operators Fitness Function Genetic Programming

Representing Hypothesis Operators Fitness Function Genetic Programming
The Study of Cache Oblivious Algorithms Prepared by Jia Guo.

The Study of Cache Oblivious Algorithms Prepared by Jia Guo.
Analysis of Algorithms

Analysis of Algorithms
Using Parallel Genetic Algorithm in a Predictive Job Scheduling

Using Parallel Genetic Algorithm in a Predictive Job Scheduling
Parallel Sorting Sathish Vadhiyar. Sorting  Sorting n keys over p processors  Sort and move the keys to the appropriate processor so that every key.

Parallel Sorting Sathish Vadhiyar. Sorting  Sorting n keys over p processors  Sort and move the keys to the appropriate processor so that every key.
Offline Adaptation Using Automatically Generated Heuristics Frédéric de Mesmay, Yevgen Voronenko, and Markus Püschel Department of Electrical and Computer.

Offline Adaptation Using Automatically Generated Heuristics Frédéric de Mesmay, Yevgen Voronenko, and Markus Püschel Department of Electrical and Computer.
Types of Algorithms.

Types of Algorithms.
Parameter control Chapter 8. A.E. Eiben and J.E. Smith, Introduction to Evolutionary Computing Parameter Control in EAs 2 Motivation 1 An EA has many.

Parameter control Chapter 8. A.E. Eiben and J.E. Smith, Introduction to Evolutionary Computing Parameter Control in EAs 2 Motivation 1 An EA has many.
Parameter Control A.E. Eiben and J.E. Smith, Introduction to Evolutionary Computing Chapter 8.

Parameter Control A.E. Eiben and J.E. Smith, Introduction to Evolutionary Computing Chapter 8.
Chapter 4: Divide and Conquer Master Theorem, Mergesort, Quicksort, Binary Search, Binary Trees The Design and Analysis of Algorithms.

Chapter 4: Divide and Conquer Master Theorem, Mergesort, Quicksort, Binary Search, Binary Trees The Design and Analysis of Algorithms.
SLIQ: A Fast Scalable Classifier for Data Mining Manish Mehta, Rakesh Agrawal, Jorma Rissanen 1996. Presentation by: Vladan Radosavljevic.

SLIQ: A Fast Scalable Classifier for Data Mining Manish Mehta, Rakesh Agrawal, Jorma Rissanen Presentation by: Vladan Radosavljevic.
Sorting Chapter 11. 2 Sorting Consider list x 1, x 2, x 3, … x n We seek to arrange the elements of the list in order –Ascending or descending Some O(n.

Sorting Chapter Sorting Consider list x 1, x 2, x 3, … x n We seek to arrange the elements of the list in order –Ascending or descending Some O(n.
Content Based Image Clustering and Image Retrieval Using Multiple Instance Learning Using Multiple Instance Learning Xin Chen Advisor: Chengcui Zhang Department.

Content Based Image Clustering and Image Retrieval Using Multiple Instance Learning Using Multiple Instance Learning Xin Chen Advisor: Chengcui Zhang Department.
Bitmap Index Buddhika Madduma 22/03/2010 Web and Document Databases - ACS-7102.

Bitmap Index Buddhika Madduma 22/03/2010 Web and Document Databases - ACS-7102.
Faster Sorting Methods Chapter 9. 2 Chapter Contents Merge Sort Merging Arrays Recursive Merge Sort The Efficiency of Merge Sort Merge Sort in the Java.

Faster Sorting Methods Chapter 9. 2 Chapter Contents Merge Sort Merging Arrays Recursive Merge Sort The Efficiency of Merge Sort Merge Sort in the Java.
Object Recognition Using Genetic Algorithms CS773C Advanced Machine Intelligence Applications Spring 2008: Object Recognition.

Object Recognition Using Genetic Algorithms CS773C Advanced Machine Intelligence Applications Spring 2008: Object Recognition.
Cache effective mergesort and quicksort Nir Zepkowitz Based on: “Improving Memory Performance of Sorting Algorithms” by Li Xiao, Xiaodong Zhang, Stefan.

Cache effective mergesort and quicksort Nir Zepkowitz Based on: “Improving Memory Performance of Sorting Algorithms” by Li Xiao, Xiaodong Zhang, Stefan.
Intro to AI Genetic Algorithm Ruth Bergman Fall 2002.

Intro to AI Genetic Algorithm Ruth Bergman Fall 2002.

Similar presentations

Ads by Google