This course describes the system design flow and interfaces that can be used for data movement in the Versal™ AI Engine. It demonstrates how to utilize AI Engine APIs and the AI Engine DSP library for faster development.
In addition, advanced features in adaptive data flow (ADF) graph implementation, such as using streams, cascade streams, buffer location constraints, runtime parameterization, and APIs to update and read runtime parameters, are covered. The course also highlights how to utilize the Vitis™ Model Composer tool for AI Engine designs.
The emphasis of this course is on:
Implementing a system-level design flow (PS + PL + AIE) and the supported simulation
Using an interface for data movement between the PL and AI Engine
Utilizing AI Engine APIs for arithmetic operations and advanced MAC intrinsics to implement filters
Utilizing the AI Engine DSP library for faster development
Applying advanced features for optimizing a system-level design
Utilizing the Vitis Model Composer tool for AI Engine designs
What's New for 2024.1
Versal Adaptive SoC - Application Mapping and Partitioning module: Updated with the system design planning flow
All labs have been updated to the latest software versions
Level
ACAP 3
Course Duration
2 days
Audience
Software and hardware developers, system architects, and anyone who needs to accelerate their software applications using our devices
Prerequisites
Comfort with the C/C++ programming language
Software development flow
Vitis software for application acceleration development flow
Software Tools
Vitis Unified IDE 2024.1
Vitis Model Composer 2024.1
Hardware
Architecture: Versal adaptive SoCs
Skills Gained
After completing this comprehensive training, you will have the necessary skills to:
Describe system-level application partitioning for AMD Versal devices
Describe the data movement between the PS, PL, and AI Engines as well as the clocking specifications
Describe and implement a system-level design integrating PS + PL + AI Engines for Versal adaptive SoCs using supported emulation and the Vitis tool flow
Describe the Vitis export to Vivado™ flow as well as the AI Engine reset and reload methodology
Utilize the AI Engine DSP library for faster development
Apply location constraints on kernels and buffers in the AI Engine array
Apply runtime parameters in a graph to modify application behavior
Debug and analyze a system-level design using Vitis debug and trace
Utilize the AI Engine library in Vitis Model Composer for AI Engine development
Course Outline
Day 1
Design Analysis
Versal Adaptive SoC: Application Partitioning (Review) - Covers what application partitioning is and how an application can be accelerated by using various compute engines in the Versal device. Also describes how different models of computation (sequential, concurrent, and functional) can be mapped to the Versal adaptive SoC. {Lecture}
Versal Adaptive SoC: Application Partitioning - Explains how image and video processing can be targeted for the Versal device by utilizing the different engines (Scalar Engine, Adaptable Engine, and Intelligent Engine). Also describes the AI engine development flow. {Lecture
Versal AI Engine Data Movement
Versal Adaptive SoC: Data Communications 1 - Describes the implementation of AI Engine and programmable logic (PL) kernels and how to implement the functions in the AI Engine that take advantage of low power. {Lecture}
Versal Adaptive SoC: Data Communications 2 - Describes the programming model for the implementation of stream interfaces for the AI Engine kernels and PL kernels. Lists the stream data types that are supported by AI Engine and PL kernels. {Lecture, Lab}
Vitis Tool Flow
System Design Flow - Demonstrates the Vitis compiler flow to integrate a compiled AI Engine design graph (libadf.a) with additional kernels implemented in the PL region of the device (including HLS and RTL kernels) and link them for use on a target platform. These compiled hardware functions can then be called from a host program running in the Arm® processor in the Versal device or on an external x86 processor. {Lecture, Lab}
System Design Flow: Models and Methodology - Reviews the system simulation models and illustrates the Vitis export to Vivado flow. Also describes the AI Engine reset and reload methodology. {Lecture, Lab}
The Programming Model
Introduction to AI Engine APIs for Arithmetic Operations - Describes the Versal AI Engine APIs for arithmetic, comparison, and reduction operations. Also describes the matrix multiplication, FFT, and special multiplication operations. For advanced users, covers how to implement filters using advanced intrinsics functions for various filters, such as non-symmetric FIRs, symmetric FIRs, or half-band decimators. {Lecture}
Day 2
Libraries
Introduction to the AI Engine DSP Library - Provides an overview of the available DSP library, which enables faster development and comes with ready-to-use example designs that help with using the library and tools. {Lecture, Labs}
The Programming Model
Advanced Graph Input Specifications - Learn advanced features such as using initialization functions, writing directly using streams from the AI Engine, cascade stream, core location constraints, and buffer location constraints. {Lecture}
Advanced Graph Input and Runtime Parameters - Describes how to implement runtime parameterization, which can be used as adaptive feedback and to switch functionality dynamically. {Lecture, Lab}
Debugging
Versal AI Engine Application Debug and Trace - Shows how to debug the AI Engine application running on the Linux® OS and how to debug via hardware emulation that allows simulation of the application. {Lecture}
Vitis Model Composer
Vitis Model Composer for AI Engine Design - Describes the Vitis Model Composer tool and how to use the libraries available with the tool for AI Engine design development. {Lecture, Lab}
Request
Reservations can no longer be made for this event.