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Memphis-V

Many-core Modeling Platform for Phivers (Processor Hive for RS5)

About

Memphis-V is a full many-core model with:

  • Phivers: hardware modeled in SystemVerilog
  • MAestro: an operating system for many-cores
  • libmemphis and libmutils: standard set of support libraries
  • Standard set of applications
  • Standard Management Application
  • Scenario generation tools
  • Debug tools

The chip area is divided in two regions: GPPC (General Purpose Processing Cores) and Peripherals. For more information, check the platform documentation and all submodules linked above.

Memphis-V is derived from several years of research in many-core platforms. It is also the 5th major version since HeMPS, hence the "V" suffix. The versions that contributed to Memphis-V are:

  • (1) HeMPS: Hermes Multiprocessor System on Chip (Cluster-based-management, MIPS core, SystemC/VHDL)
  • (2) Memphis: HeMPS with peripherals (SystemC/VHDL)
  • (3) HHeMPS: Hybrid HeMPS RISC-V/MIPS (SystemC)
  • (3) MMemphis: Memphis without clustering (SystemC/VHDL)
  • (4) MA-Memphis: Application-Managed MMemphis with RISC-V and broadcast NoC (SystemC)
  • (5) Memphis-V: RTL-modeled MA-Memphis (SystemVerilog)

Installation

Memphis-V runs in a Linux environment. It is possible, although not supported to run under a Mac environment. It is possible to use the WSL to run Memphis-V platform under Windows.

Pre-requisites

Obtaining Memphis-V

Clone this repository with submodules. The master branch contains the latest release without development commits. In this example we chose the home directory to clone Memphis-V.

cd ~
git clone https://github.com/gaph-pucrs/Memphis-5.git --recurse-submodules

Export the environment variable:

  • PATH=~/Memphis-5/bin:$PATH

Here we do it persistently with .bashrc. You can export in .zshrc or other environment file according to your needs.

echo -e "# Memphis-V\nexport PATH=~/Memphis-5/bin:\${PATH}\n" >> ~/.bashrc

Remember to close and reopen the terminal after running or source the environment file (e.g. source ~/.bashrc).

Generating the model

Memphis-V separates testcase, applications and scenario build. A testcase contains a description of the hardware and operating system of the platform. Create a new yaml file in a sandbox folder. Here the example name will be example_testcase.yaml. The file should contain:

simulation:                 # Optional: simulation parameters
  simulator: verilator      # Optional: verilator (default) or vsim
  trace: no                 # Optional: generate wave trace (default is off)
hw:                         # Hardware properties
  page_size_inst_KB: 32     # Size of each instruction memory page (maximum task instruction size)
  page_size_data_KB: 16     # Size of each task memory page (maximum task data size)
  tasks_per_PE: 4           # Maximum number of tasks in the same PE (will define memory size)
  mpsoc_dimension: [3,3]    # Dimension of the many-core [X, Y]
  Peripherals:              # Attached peripherals
    - name: MA_INJ          # Requided: MA Injector peripheral
      pe: 0,0               # is connected at border PE 0x0
      port: S               # Connected at port SOUTH. Note to use a border port.
    - name: APP_INJ         # Required: Application Injector peripheral
      pe: 2,2               # is at border PE 2x2
      port: N               # Connected at port NORTH. Note to use a border port.
  parameters:               # Optional: list of parameters to be passed to hardware build
    - TRAFFIC_DEBUG: yes    # Optional: enable NoC traffic debugging (default is on)
    - UART_DEBUG: yes       # Optional: enable application stdout to log files (default is on)
    - SCHED_DEBUG: yes      # Optional: enable scheduler debugging (default is on)
    - PIPE_DEBUG: yes       # Optional: enable messagin protocol debug (default is on)
    - RAM_DEBUG: no         # Optional: enable RAM access debug (default is off)
    - RS5_DEBUG: no         # Optional: enable core register bank debug (default is off)
    - DMNI_DEBUG: no        # Optional: enable DMNI timing debug (default is off)

The applications description contains a list of possible applications to evaluate in a scenario. You can create multiple different variations of an application by changing its definitions. Create a new yaml file next to the example_testcase.yaml. Here this new file will be called example_applications.yaml. The file should contain:

apps:                             # Application properties
  - name: synthetic               # Add application "synthetic"
  - name: prod_cons               # Add application "prod_cons"
    instance: custom              # Optional: name of the instance (default is "default")
    definitions:                  # Optional: list of definitions to customize your instance
      - PROD_CONS_MSG_SIZE: 64    # Optional: this defines PROD_CONS_MSG_SIZE as 64
      - PROD_CONS_ITERATIONS: 100 # Optional: this defines PROD_CONS_ITERATIONS as 100

The scenario contains the list of applications instances that will be evaluated in the platform. Create a new yaml file next to the example_applications.yaml and example_testcase.yaml. Here this new file will be called example_scenario.yaml. This file should contain:

management:                 # Management application properties
  - task: mapper_task       # Required: the first management task should be mapper_task
    static_mapping: [0,0]   # Required: map mapper_task to 0x0
  - task: migration_task    # Optional: migration_task is a QoS decider for real-time applications
    static_mapping: [0,1]   # Required: all management tasks should be statically mapped
  - task: rt_monitor        # Optional: rt_monitor is a QoS observer for real-time applications
    static_mapping: [0,2]   # Required: all management tasks should be statically mapped
apps:                       # Application properties
  - name: synthetic         # Optional: add instance of application "synthetic"
  - name: prod_cons
    instance: custom        # Optional: define the instance we want to add (from applications yaml)
  - name: prod_cons
    instance: custom        # We can add multiple runs of the same application instance (e.g. prod_cons custom)
    start_time_ms: 5        # Optional: application start time (default is 0)
    static_mapping:         # Optional: static mapping (default is dynamic)
      prod: [1,1]           # Optional: task "prod" is mapped to 1x1

After creating the description of the testcase and the scenario, the testcase should be generated. This step builds the support libraries, the kernel, and all management tasks:

memphi5 testcase example_testcase.yaml

Then, generate the application instances inside the testcase folder with the yaml description:

memphi5 applications example_testcase example_applications.yaml

Then, the scenario should be generated for the testcase folder previously created:

memphi5 scenario example_testcase example_scenario.yaml 

Simulating

To simulate the generated model, run the simulation for the generated scenario folder:

memphi5 simulate example_testcase/example_scenario

If the graphical debugger is properly installed, it should open automatically. Otherwise, run the simulation without the graphical debugger:

memphi5 simulate example_testcase/example_scenario --nogui

The simulation will automatically stop once all applications in the scenario are evaluated. You can also set a timeout for the simulation (in milliseconds):

memphi5 simulate example_testcase/example_scenario --timeout 50

Evaluating and Debugging

To open the debugger manually after a simulation is already done, run:

memphi5 debug example_testcase/example_scenario

Main window

The main window contains the informations described in the image below. Additional functionalities are:

MainWindow

Communication Overview

Shows the NoC traffic distributed among PEs.

Task Mapping Overview

Shows tasks running in each mapped PE or tasks that already terminated.

Debug Log Reader for MPSoCs (Deloream)

Shows by application and task the debug messages produced.

PE Log

Shows all messages produced by the PE (including the kernel).

Scheduling

Shows a scheduling graph of the selected PE.

Further reading

Check the GraphicalDebugger repository for more information. A video in portuguese is available showing all features of the Debugger.

Acknowledgements

  • Migration heuristic
Dalzotto, A. E., Borges, C. S., Ruaro, M., and Moraes, F. G. (2022). Leveraging NoC-based Many-core Performance Through Runtime Mapping Defragmentation. In Proceedings of the International Conference on Electronics, Circuits, and Systems (ICECS), pages 1-6.
  • Mapping heuristic
Dalzotto, A. E., Ruaro, M., Erthal, L. V., and Moraes, F. G. (2021). Dynamic Mapping for Many-cores using Management Application Organization. In Proceedings of the International Conference on Electronics, Circuits, and Systems (ICECS), pages 1-6.
  • MA-Memphis
Dalzotto, A. E., Ruaro, M., Erthal, L. V., and Moraes, F. G. (2021). Management Application - a New Approach to Control Many-Core Systems. In Proceedings of the Symposium on Integrated Circuits and Systems Design (SBCCI), pages 1-6.
  • MA Paradigm
Ruaro, M., Santana, A., Jantsch, A., and Moraes, F. G. (2021). Modular and Distributed Management of Manycore SoCs. ACM Transactions on Computer Systems (TOCS), 38(1-2):1-16.
  • Memphis
Ruaro, M., Caimi, L. L., Fochi, V., and Moraes, F. G. (2019). Memphis: a framework for heterogeneous many-core SoCs generation and validation. Design Automation for Embedded Systems, 23(3-4):103-122.
  • Graphical debugger
Ruaro, M., Carara, E. A., and Moraes, F. G. (2014). Tool-set for NoC-based MPSoC debugging—A protocol view perspective. In Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS), pages 2531-2534.
  • Generation framework
Castilhos, G., Wachter, E., Madalozzo, G., Erichsen, A., Monteiro, T., and Moraes, F. (2014). A framework for mpsoc generation and distributed applications evaluation. In Proceedings of the International Symposium on Quality Electronic Design (ISQED), pages 408-411.
  • HeMPS
Carara, E. A., De Oliveira, R. P., Calazans, N. L., and Moraes, F. G. (2009). HeMPS-a framework for NoC-based MPSoC generation. In Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS), pages 1345-1348.

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