Skip to content

Scheduling on Asymmetric Multicore Processors based on high-frequency core switching

Notifications You must be signed in to change notification settings

lluchs/amp-scheduling

Repository files navigation

amp-scheduling

Code I created for my Master's thesis. Abstract:

Asymmetric multicore processors (AMP) integrate multiple core types with different power and performance characteristics in a single package. Using optimized scheduling, these processors can deliver higher performance per watt than a symmetric multicore processor. An application executes most efficiently on a certain core depending on how it uses resources like CPU and memory. Previous approaches analyze applications at coarse granularities, classifying each process or thread. In systems such as servers that have homogeneous processes with similar behavior in all threads, these approaches cannot distribute applications to core types effectively.

However, applications generally go through different execution phases over time. These phases often differ in their resource usage and exist at both large and small scales. Whereas some systems already incorporate changing application behavior over large time intervals, it should also be possible to utilize shorter phases to save energy by migrating between cores at high frequency.

In this work, we design and implement such a system that characterizes the small-scale phase behavior of applications between developer-defined points by monitoring memory accesses with performance counters. At runtime, it migrates the application thread to the optimal core for each execution phase.

We evaluate our system on an AMD Ryzen processor. These processors allow asymmetric core configurations using frequency scaling. We fail to see reductions in power consumption with our system on these processors. We show that, contrary to available documentation, Ryzen does not have per-core voltage domains and conclude that these processors are not suitable as asymmetric platform.

Building

Most code is written in C and builds on Linux with the Meson Build system. Some parts require likwid for performance counter monitoring.

meson build
cd build
ninja

Adapting an Application

  1. Install the libraries globally with ninja install. This step isn't strictly necessary, but makes including and linking the libraries easier.

  2. Insert measurement points. Include swp.h and add SWP_MARK; to functions. Call swp_init() during application initialization and swp_deinit() before shutdown.

  3. Run in measurement mode. Modify the build system to link with libswp (i.e., add -lswp to the linker commands). Build and run the application. It will print results when swp_deinit() is called. Save the results in a file in plot/out/swp.

  4. Create control flow graph. Run make -C plot/out/swp. It will create a graph in the same directory.

  5. Create application profile. Run plot/swpcfg.awk your-swp-output.txt. It will print an application profile. Passing more than one file is also possible. Look at the profile and decide on a threshold value.

  6. Run in migration mode. Run:

     LD_PRELOAD=libswp_migrate.so SWP_CFG=your-swp-profile.txt SWP_THRESHOLD=0.42 FAST_CPU=0 SLOW_CPU=2 your-application
    

Benchmarks

The repository includes three benchmark folders (benchmark, ryzenpower, and ultoverhead) that work similarly. You need ZSH, GNU Awk, GNU Make, and R. To run the benchmarks and analyze the results, do the following:

  1. Build everything (see above). Enable user space mwait on Ryzen with bin/enable-mwait. In R, run install.packages("tidyverse") for the analysis and plotting scripts.
  2. Modify the benchmark run script configuration at the top.
  3. Run the benchmark: ./run <name of benchmark run>
  4. Wait for the benchmark to finish. Results are written to results/<name>.
  5. Create TSV files by running make tsv b=<name> and plots by running make plot b=<name>.

The repository includes the benchmark runs I used for the thesis:

  • Figure 5.4 and 5.5: benchmark/results/2018-02-22_01
  • Figure 5.6 and 5.8: ultoverhead/results/2018-02-21_02
  • Figure 5.7: ryzenpower/results/2018-02-25_01
  • Figure 5.9a and A.1: benchmark/results/2018-02-24_01
  • Figure 5.9b and A.2: benchmark/results/2018-02-21_01

Repository Organization

libultmigration

  • ultmigration.[hsc]: Implementation of user space core migration. Set the FAST_CPU and SLOW_CPU environment variables to the CPU ids you want to migrate to.

  • ultmigration_dummy.c: Dummy implementation for benchmarks or for systems that do not support user space mwait.

  • ultmigration_pstate.c: Implementation for Ryzen that changes the P-state of one core instead of migrating. Does not produce any useful results compared to migration and did not make it into the thesis.

libswp

See “Adapting an Application” above for usage.

  • swp/swp.h: Common API for all swp libraries.

  • swp/swp.cpp: Application analysis library that monitors performance counters between developer-defined points.

  • swp/swp_migrate.cpp: Library for migrating based on a profile and a threshold.

  • swp/swp_dummy.cpp: Dummy library for benchmarks.

pmc

  • pmc/pmc.c: Small library for reading Ryzen L3 cache counters via MSRs.

test

  • test/simple.c: Simple test for libultmigration that just migrates a few times.

  • test/micro.c: Microbenchmark modelling the optimal migration scenario.

  • test/micro_pmc.c: micro with manual Ryzen L3 cache miss counter monitoring.

  • test/micro_swp.c: micro with libswp instrumentation.

  • test/ult_idle.c: Initializes libultmigration, the does nothing. Used to test mwait overhead.

  • test/ultoverhead.c: Benchmark for measuring performance overhead from libultmigration.

tools

  • tools/amdccx.c: Reads Ryzen CCX id from cpuid data.

  • tools/amdpstate.c: Reads and writes Ryzen P-state configuration. Additional commands for reading effective frequency and RAPL counters.

  • tools/l3topology.c: Figures out core ids at the L3 cache on Ryzen processors with disabled cores. For example, on our Ryzen 1600X test system with six cores, the first L3 cache has cores 0, 2, 3 active and the second L3 cache cores 0, 1, 2. This information is important for filtering the L3 cache counters by core.

About

Scheduling on Asymmetric Multicore Processors based on high-frequency core switching

Topics

Resources

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published