Course details
Applications of Parallel Computers
PDD Acad. year 2023/2024 Winter semester
The course gives an overview of usable parallel platforms and models of programming, mainly shared-memory programming (OpenMP), message passing (MPI) and data-parallel programming (CUDA, OpenCL). A parallelization methodology is completed by performance studies and applied to a particular problem. The emphasis is put on practical aspects and implementation.
Guarantor
Course coordinator
Language of instruction
Completion
Time span
- 39 hrs lectures
Assessment points
- 100 pts final exam
Department
Lecturer
Instructor
Learning objectives
To clarify possibilities of parallel programming on multi-core processors, on clusters and on GP GPUs. View over synchronization and communication techniques. Get to know a method of parallelization and performance prediction of selected real-world applications, the design of correct programs and the use parallel computing in practice.
Topics for the state doctoral exam (SDZ):
- Indicators and laws of parallel processing, function of constant efficiency, scalability.
- Parallel processing in OpenMP, SPMD, loops, sections, tasks and synchronization primitives.
- Architectures with shared memory, UMA, NUMA, cache coherence protocols.
- Blocking and non-blocking pair-wise communications in MPI.
- Collective communications in MPI, parallel input-output.
- Architecture of superscalar processors, algorithms for out-of-order instruction execution.
- Data parallelism SIMD and SIMT, HW implementation and SW support.
- Architecture of graphics processing units, differences from superscalar CPUs.
- Programming language CUDA, thread and memory models..
To learn how to parallelize various classes of problems and predict their performance. To be able to utilize parallelism and communication at thread- and process level. To get acquainted with state-of-the-art standard interfaces, language extensions and other tools for parallel programming (MPI, OpenMP). Write and debug a parallel program for a selected task.
Parallel architectures with distributed and shared memory, programming in C/C++ with MPI and OpenMP, GPGPU, parallelization of basic numerical methods.
Recommended prerequisites
Prerequisite knowledge and skills
Types of parallel computers, programming in C/C++, basic numerical methods
Study literature
- http://www.cs.berkeley.edu/~demmel/cs267_Spr13/
- David Patterson John Hennessy: Computer Organization and Design MIPS Edition, Morgan Kaufmann, 2013, s. 800, ISBN: 978-0-12-407726-3
- Kirk, D., and Hwu, W.: Programming Massively Parallel Processors: A Hands-on Approach, Elsevier, 2017, s. 540, ISBN: 978-0-12-811986-0
Syllabus of lectures
- Parallel computer architectures, performance measures and their prediction
- Patterns for parallel programming
- Synchronization and communication techniques.
- Shared variable programming with OpenMP
- Message-passing programming with MPI
- Data parallel programming with CUDA/OpenCL
- Examples of task parallelization and parallel applications
Progress assessment
Defence of a software project based on a variant of parallel programming.
Course inclusion in study plans
- Programme DIT, any year of study, Compulsory-Elective group O
- Programme DIT, any year of study, Compulsory-Elective group O
- Programme DIT-EN (in English), any year of study, Compulsory-Elective group O
- Programme DIT-EN (in English), any year of study, Compulsory-Elective group O
- Programme VTI-DR-4, field DVI4, any year of study, Elective
- Programme VTI-DR-4, field DVI4, any year of study, Elective
- Programme VTI-DR-4 (in English), field DVI4, any year of study, Elective
- Programme VTI-DR-4 (in English), field DVI4, any year of study, Elective