- libCacheSim - building and running cache simulations
- 2023 June: QDLP is available now, see our paper for details.
- 2023 Oct: S3-FIFO and SIEVE are available! These are very simple algorithms that are very effective in reducing cache misses. Try them out in libCacheSim and your production!
- a high-performance cache simulator for running cache simulations.
- a high-performance and versatile trace analyzer for analyzing different cache traces.
- a high-performance library for building cache simulators.
- High performance - over 20M requests/sec for a realistic trace replay.
- High memory efficiency - predictable and small memory footprint.
- State-of-the-art algorithms - eviction algorithms, admission algorithms, sampling techniques, approximate miss ratio computation, see here.
- Parallelism out-of-the-box - uses the many CPU cores to speed up trace analysis and cache simulations.
- The ONLY feature-rich trace analyzer - all types of trace analysis you need, see here.
- Simple API - easy to build cache clusters, multi-layer caching, etc.; see here.
- Extensible - easy to support new trace types or eviction algorithms; see here.
cachesim supports the following algorithms:
- FIFO, LRU, Clock, SLRU
- LFU, LFU with dynamic aging
- ARC, TwoQ
- Belady, BeladySize
- GDSF
- Hyperbolic
- LeCaR
- Cacheus
- LHD
- LRB
- GLCache
- TinyLFU
- QD-LP
- S3-FIFO
- Sieve
We provide some scripts for quick installation of libCacheSim.
cd scripts && bash install_dependency.sh && bash install_libcachesim.sh;
If this does not work, please
- let us know what system you are using and what error you get
- read the following sections for self-installation.
libCacheSim uses cmake build system and has a few dependencies: glib, tcmalloc, zstd. Please see install.md for instructions on how to install the dependencies.
cmake recommends out-of-source build, so we do it in a new directory:
git clone https://github.com/1a1a11a/libCacheSim
pushd libCachesim;
mkdir _build && cd _build;
cmake .. && make -j;
[sudo] make install;
popd;
After building and installing libCacheSim, cachesim
should be in the _build/bin/
directory.
./bin/cachesim trace_path trace_type eviction_algo cache_size [OPTION...]
use ./bin/cachesim --help
to get more information.
Run the example traces with LRU eviction algorithm and 1GB cache size.
# Note that no space between the cache size and the unit, and the unit is not case-sensitive
./bin/cachesim ../data/trace.vscsi vscsi lru 1gb
# Note that there is no space between the cache sizes
./bin/cachesim ../data/trace.vscsi vscsi lru 1mb,16mb,256mb,8gb
# Besides absolute cache size, you can also use a fraction of the working set size
./bin/cachesim ../data/trace.vscsi vscsi lru 0.001,0.01,0.1,0.2
# besides using byte as the unit, you can also treat all objects having the same size, and the size is the number of objects
./bin/cachesim ../data/trace.vscsi vscsi lru 1000,16000 --ignore-obj-size 1
# use a csv trace, note the qutation marks when you have multiple options
./bin/cachesim ../data/trace.csv csv lru 1gb -t "time-col=2, obj-id-col=5, obj-size-col=4"
# use a csv trace with more options
./bin/cachesim ../data/trace.csv csv lru 1gb -t "time-col=2, obj-id-col=5, obj-size-col=4, delimiter=,, has-header=true"
See quick start cachesim for more usages.
You can plot miss ratios of different algorithms and sizes, and plot the miss ratios over time.
# plot miss ratio over size
cd scripts;
python3 plot_mrc_size.py --tracepath ../data/twitter_cluster52.csv --trace-format csv --trace-format-params="time-col=1,obj-id-col=2,obj-size-col=3,delimiter=," --algos=fifo,lru,lecar,s3fifo --sizes=0.001,0.002,0.005,0.01,0.02,0.05,0.1,0.2,0.3,0.4
# plot miss ratio over time
python3 plot_mrc_time.py --tracepath ../data/twitter_cluster52.csv --trace-format csv --trace-format-params="time-col=1, obj-id-col=2, obj-size-col=3, delimiter=,," --algos=fifo,lru,lecar,s3fifo --report-interval=30 --miss-ratio-type="accu"
libCacheSim also has a trace analyzer that provides a lot of useful information about the trace. And it is very fast, designed to work with billions of requests. It also coms with a set of scripts to help you analyze the trace. See trace analysis for more details.
libCacheSim can be used as a library for building cache simulators. For example, you can build a cache cluster with consistent hashing or a multi-layer cache simulator.
Here is a simplified example showing the basic APIs.
#include <libCacheSim.h>
/* open trace, see quickstart_lib.md for opening csv and binary trace */
reader_t *reader = open_trace("../data/trace.vscsi", VSCSI_TRACE, NULL);
/* create a container for reading from trace */
request_t *req = new_request();
/* create a LRU cache */
common_cache_params_t cc_params = {.cache_size=1024*1024U};
cache_t *cache = LRU_init(cc_params, NULL);
/* counters */
uint64_t n_req = 0, n_miss = 0;
/* loop through the trace */
while (read_one_req(reader, req) == 0) {
if (!cache->get(cache, req)) {
n_miss++;
}
n_req++;
}
printf("miss ratio: %.4lf\n", (double)n_miss / n_req);
/* cleaning */
close_trace(reader);
free_request(req);
cache->cache_free(cache);
save this to test.c
and compile it with
gcc test.c $(pkg-config --cflags --libs libCacheSim glib-2.0) -o test.out
See here for more details, and see example folder for examples on how to use libCacheSim, such as building a cache cluster with consistent hashing, multi-layer cache simulators.
libCacheSim supports txt, csv, and binary traces. We prefer binary traces because it allows libCacheSim to run faster, and the traces are more compact.
We also support zstd compressed binary traces without decompression. This allows you to store the traces with less space.
If you need to add a new trace type or a new algorithm, please see here for details.
In the repo, there are sample (one from cloudphysics and one from twitter) traces in different formats (csv, txt, vscsi, and oracleGeneral). Note that the provided traces are very small samples and should not be used for evaluating different algorithms' miss ratios. The full traces can be found either with the original release or the processed oracleGeneral format.
Note that the oracleGeneral traces are compressed with zstd and have the following format:
struct {
uint32_t timestamp;
uint64_t obj_id;
uint32_t obj_size;
int64_t next_access_vtime; // -1 if no next access
}
The compressed traces can be used with libCacheSim without decompression. And libCacheSim provides a tracePrint
tool to print the trace in human-readable format.
Dataset | Year | Type | Original release | OracleGeneral format |
---|---|---|---|---|
Tencent Photo | 2018 | object | link | link |
WikiCDN | 2019 | object | link | link |
Tencent CBS | 2020 | block | link | link |
Alibaba Block | 2020 | block | link | link |
2020 | key-value | link | link | |
MetaKV | 2022 | key-value | link | link |
MetaCDN | 2023 | object | link | link |
Among the large number of traces, I recommend using the newer traces from Twitter (cluster52), Wiki, and Meta.
Please join the Google group https://groups.google.com/g/libcachesim and ask questions.
We gladly welcome pull requests.
Before making any large changes, we recommend opening an issue and discussing your proposed changes.
If the changes are minor, then feel free to make them without discussion.
This project adheres to Google's coding style. By participating, you are expected to uphold this code.
@inproceedings{yang2020-workload,
author = {Juncheng Yang and Yao Yue and K. V. Rashmi},
title = {A large scale analysis of hundreds of in-memory cache clusters at Twitter},
booktitle = {14th USENIX Symposium on Operating Systems Design and Implementation (OSDI 20)},
year = {2020},
isbn = {978-1-939133-19-9},
pages = {191--208},
url = {https://www.usenix.org/conference/osdi20/presentation/yang},
publisher = {USENIX Association},
}
@inproceedings{yang2023-s3fifo,
title = {FIFO Queues Are All You Need for Cache Eviction},
author = {Juncheng Yang and Yazhuo Zhang and Ziyue Qiu and Yao Yue and K.V. Rashmi},
isbn = {9798400702297},
publisher = {Association for Computing Machinery},
booktitle = {Symposium on Operating Systems Principles (SOSP'23)},
pages = {130–149},
numpages = {20},
year={2023}
}
@inproceedings{yang2023-qdlp,
author = {Juncheng Yang and Ziyue Qiu and Yazhuo Zhang and Yao Yue and K.V. Rashmi},
title = {FIFO Can Be Better than LRU: The Power of Lazy Promotion and Quick Demotion},
year = {2023},
isbn = {9798400701955},
publisher = {Association for Computing Machinery},
doi = {10.1145/3593856.3595887},
booktitle = {Proceedings of the 19th Workshop on Hot Topics in Operating Systems (HotOS23)},
pages = {70–79},
numpages = {10},
}
If you used libCacheSim in your research, please cite the above papers. And we welcome you to send us a link to your paper and add a reference to references.md.
See LICENSE for details.
- PyMimircache: a python based cache trace analysis platform, now deprecated