Introduction to High Performance Computing

15 Aug 2016, 08:00 → 26 Aug 2016, 15:00 Europe/Stockholm

KTH Lecture Hall E3

Erwin Laure (PDC - Center for High-Performance Computing), Michael Hanke (CSC - KTH School of Computer Science and Communication), Stefano Markidis (PDC - KTH)

The PDC Center for High Performance Computing and the KTH School of Computer Science and Communication (CSC) welcome you to our summer school introductory course on high-performance computing. This course is part of the Swedish e-Science Education.

Interested students and researchers (with academic or industrial backgrounds) from all over the world are invited to apply to attend the course, which will be held at the KTH main campus in Stockholm during late August. (Please note that for KTH Masters students, the summer school is available as course number DD2358.)

This course provides the skills needed to utilize high-performance computing (HPC) resources, and includes an introduction to a range of important topics, such as:

• HPC programming languages, libraries and tools,
• modern computer architectures,
• parallel algorithms, and
• optimizing serial and parallel programs.

Case studies in various scientific disciplines will be used to help illustrate these topics. The course consists of both lectures and guided hands-on lab sessions. Participants who successfully complete the course (including the associated programming project) will be awarded 7.5 ECTS (European Credit Transfer and Accumulation System) points.

The course is suitable for scientists and graduate students who are interested in high-performance computing. Applicants must be able to communicate in English, and have previous programming experience.

The PDC Summer School receives considerable funding from SeSE, the Swedish e-Science Education. The two leading e-Science centres in Sweden, SeRC (www.e-science.se) and eSSENCE (http://essenceofescience.se) have taken the initiative to establish a graduate school, SeSE, to fund, develop and offer basic training in fields where the use of e-Science is emerging and where education can have an immense impact on the research, but also to provide advanced training for students in fields that are already computer-intensive. The school is open to all graduate students in Sweden, and is built upon the previous successful schools NGSSC and KCSE. SeSE will be a meeting place for graduate students using e-Science tools and techniques.

2016 will be the 21st year that the course has been held – participants will become part of the long tradition of the PDC Summer School, which you can read about in the course pages for all the previous years.

Please note that there are a limited number of places available in the summer school, so be sure to register early! Course registration opens on March 14, and closes on May 31, 2016.

Monday, 15 August

1 Registration - room E3 at KTH Main campus

2 Welcome to PDC and the Summer School

Speaker: Erwin Laure (PDC-HPC)

Slides Intro2016-all.pdf

10:15 Coffee Break

3 High-Performance Computer Architecture

Speaker: Erik Hagersten

Slides 1._Intro_and_pipelines.pdf 2._Caches_and_memory_systems.pdf

12:15 Picnic - KTH garden

4 High-Performance Computer Architecture

Speaker: Erik Hagersten

Slides 3._Multiprocessors.pdf 4._HW_optimizations.pdf

15:00 Coffee Break

5 High-Performance Computer Architecture

Speaker: Erik Hagersten

Slides 5._Multicores.pdf 6._SW_optimizing.pdf

Tuesday, 16 August

6 Concepts and Algorithms for Scientific Computing

In this talk we will present of what Scientific Computing is and what the challenges are. In particular, we will discuss the "simulation pipeline". The present and future of Scientific Computing is massively parallel. Consequences for modelling and examples for algorithm contruction for scalable computing are given.

Speaker: Michael Hanke

Slides SciComp2016.pdf

10:00 Coffee Break

7 Concepts and Algorithms for Scientific Computing

Speaker: Michael Hanke

12:15 Individual Lunch

8 Introduction to PDC's Environment

Slides pdc_intro_slides.pdf

14:30 Coffee Break

9 Lab: Introduction to PDC's Environment

10 PDC Machine Room Tour

Wednesday, 17 August

11 Shared memory programming, OpenMP

Two common ways of speeding up programs are to use processes or threads executing in parallel. The second week of the Summer School presents process-based parallel computing using MPI. In this lecture parallelization using threads will be discussed. Threads can be managed in different ways, e.g. using a low level library, like the POSIX threads library. The lecture deals with OpenMP, which is a more convenient way to use threads. OpenMP is a specification for a set of compiler directives, library routines, and environment variables that can be used to specify shared memory parallelism in Fortran and C/C++ programs. The threaded program can be executed on a shared memory computer (e.g. a multi- core processor). Typically, the iterations of a time consuming loop are shared among a team of threads, each thread working on part of the iterations. The loop is parallelized by writing a directive in the code and a compiler or a pre- processor will generate parallel code. Using short code examples, the lecture covers the most important OpenMP-constructs, how to use them and how not to use them. A few more realistic examples are presented as well.

Speaker: Christoph Kessler

Slides pdc16_OpenMP_intro_2x1.pdf

10:00 Coffee Break

12 Shared memory programming, OpenMP

Speaker: Christoph Kessler

12:00 Individual Lunch

13 Shared memory programming, OpenMP

Speaker: Christoph Kessler

14 Lab: Programming Exercises on OpenMP

Speakers: Mr Niclas Jansson (CSC/NA), Stefano Markidis

15:00 Coffee Break

15 Lab: Programming Exercises on OpenMP

Speakers: Mr Niclas Jansson (CSC/NA), Stefano Markidis

Thursday, 18 August

16 Shared memory programming, OpenMP

Speaker: Christoph Kessler

10:00 Coffee Break

17 Shared memory programming, OpenMP

Speaker: Christoph Kessler

12:00 Individual Lunch

18 Lab: OpenMP Advanced Project

Speakers: Mr Niclas Jansson (CSC/NA), Stefano Markidis

15:00 Coffee Break

19 Lab: OpenMP Advanced Project

Speakers: Mr Niclas Jansson (CSC/NA), Stefano Markidis

Friday, 19 August

20 GPU Architectures

Speaker: Szilard Pall

Slides 01_PDCSummer16_gpu-intro.pdf

10:00 Coffee Break

21 Introduction to CUDA

Slides

• 02_PDCSummer16_cuda_1.pdf
• 03_PDCSummer16_cuda_2.pdf
• 04_PDCSummer16_cuda_libs.pdf
• 05_PDCSummer16_devtools.pdf

12:00 Individual Lunch

22 Lab: CUDA

Speaker: Szilard Pall

15:00 Coffee Break

23 Lab: CUDA

Speaker: Szilard Pall

Monday, 22 August

24 Wrap up: GPU Programming

Speaker: Szilard Pall

10:00 Coffee Break

25 MPI: Introduction, Basic Concepts, Point-to-Point Communication

Speaker: Erwin Laure (PDC-HPC)

Slides

• MPI-1.pdf
• MPI-2.pdf
• MPI-3.pdf

12:00 Individual Lunch

26 MPI - Point-to-Point Communication

Speaker: Erwin Laure (PDC-HPC)

27 Lab: MPI Part 1

15:00 Coffee Break

28 Lab: MPI Part 1

Tuesday, 23 August

29 MPI - Collective Communication

Speaker: Erwin Laure (PDC-HPC)

Slides MPI-4.pdf

10:00 Coffee Break

30 MPI - Intermediate MPI

Speaker: Erwin Laure (PDC-HPC)

Slides MPI-5.pdf

12:00 Individual Lunch

31 Lab: MPI Part 2

15:00 Coffee Break

32 Lab: MPI Part 2

33 Project Work

Wednesday, 24 August

34 Performance Engineering

Speaker: Pekka Manninen

Slides Performance-engineering.pdf

10:00 Coffee Break

35 Performance Engineering

Speaker: Pekka Manninen

12:00 Individual Lunch

36 Lab: Performance Engineering

15:00 Coffee Break

37 Lab: Performance Engineering

Thursday, 25 August

38 Wrap up: Performance Engineering

Speaker: Pekka Manninen

39 MPI: Advanced Concepts

Speaker: Erwin Laure (PDC-HPC)

Slides MPI-6.pdf MPI-6.pdf

10:00 Coffee Break

40 MPI: Advanced Concepts

Speaker: Erwin Laure (PDC-HPC)

41 Case Study: Energy Efficiency in Scientific Computing

Energy consumption is a crucial challenge that the high performance computing community will have to face to efficiently leverage the Exascale systems that will be available at the end of this decade. In this talk we will motivate the roots of the power wall, and introduce a "recipe" of measures that are being implemented in hardware as well as scientific applications in order to reduce energy consumption: 1) Selection of energy efficient hardware 2) Dynamic voltage-frequency scaling 3) Dynamic concurrency throttling 4) Suppression of polling 5) Approximate computing 6) Near threshold voltage computing 7) Use of energy proportional hardware 8) Virtualization of computational resources

Speaker: Prof. Enrique Quintana Ortí

Slides KTH_summerschool2016.pdf

12:00 Individual Lunch

42 Lab: MPI Part 3

15:00 Coffee Break

43 Lab: MPI Part 3

44 Project Work

18:00 Social Dinner at Cypern Restaurant

Friday, 26 August

45 The Future of Computing - Towards the Post Moore’s Law Era

This lecture presents the Moore's law and discusses its future focusing on future emerging technologies in computing.

Speaker: Stefano Markidis

Slides PDCsummerSchool2016-Markidis.pdf

10:00 Coffee Break

46 The Future of Computing - Towards the Post Moore’s Law Era

Speaker: Stefano Markidis

47 Case Study: State of the Art Parallel Computing enables new Science breakthroughs

NVIDIAs Alison Lowndes will provide an overview of NVIDIA's latest hardware and software offering and how this enables discovery and insight via parallel scientific visual computing. She will also cover recent progress in algorithms and papers that should be of great interest Alison Lowndes Deep Learning Solutions Architect & Community Manager EMEA| NVIDIA (UK) Recent mature graduate in Artificial Intelligence (University of Leeds), combining technical and theoretical computer science with a physics background. Completed a thorough empirical study of deep learning, specifically with GPU technology, covering the entire history and technical aspects of GPGPU with underlying mathematics. After 25+ years in international project management and entrepreneurship, Alison now manages the Deep Learning and AI developer community across EMEAI and advises on a wide range of applications of deep learning.

Speaker: Alison Lowndes (Nvidia)

Slides NVIDIA_KTH_PDC_.pdf

48 Course Evaluation

In class course evaluation

12:10 Individual Lunch

49 Open Lab and Project Work