/ WEB, HTTP, CACHE, PERFORMANCE

Web resource caching: Server-side

The subject of Web resource caching is as old as the World Wide Web itself. However, I’d like to offer an as-exhaustive-as-possible catalog of how one can improve performance by caching. Web resource caching can happen in two different places: client-side - on the browser and server side. In the previous post, I explained the former; this post focuses on the latter.

While client-side caching works well, it has one central issue: to serve the resource locally, it must first have it in the cache. Thus, each client needs its cached resource. If the requested resource is intensive to compute, it doesn’t scale. The idea behind server-side caching is to compute the resource once and serve it from the cache to all clients.

Server-side cache principle

A couple of dedicated server-side resource caching solutions have emerged over the years: Memcached, Varnish, Squid, etc. Other solutions are less focused on web resource caching and more generic, e.g., Redis or Hazelcast.

If you want to dive deeper into generic caching solutions, please check these two posts on the subject.

To continue with the sample from last week, I’ll use Apache APISIX to demo server-side caching. APISIX relies on the proxy-cache plugin for caching. Unfortunately, at the moment, APISIX doesn’t integrate with any third-party caching solution. It offers two options: memory-based and disk-based.

In general, the former is faster, but memory is expensive, while the latter is slower, but disk storage is cheap. Within OpenResty, however, the disk option may be faster because of how LuaJIT handles memory. You should probably start with the disk, and if it’s not fast enough, mount /dev/shm.

Here are my new routes:

apisix.yaml
routes:
  - uri: /cache
    upstream_id: 1
    plugins:
      proxy-rewrite:
        regex_uri: ["/cache(.*)", "/$1"]
      proxy-cache: ~

Note that the default cache key is the host and the request URI, which includes query parameters.

The default proxy-cache configuration uses the default disk-based configuration:

config-default.yaml
  proxy_cache:                      # Proxy Caching configuration
    cache_ttl: 10s                  # The default caching time in disk if the upstream does not specify the cache time
    zones:                          # The parameters of a cache
      - name: disk_cache_one        # The name of the cache, administrator can specify
                                    # which cache to use by name in the admin api (disk|memory)
        memory_size: 50m            # The size of shared memory, it's used to store the cache index for
                                    # disk strategy, store cache content for memory strategy (disk|memory)
        disk_size: 1G               # The size of disk, it's used to store the cache data (disk)
        disk_path: /tmp/disk_cache_one  # The path to store the cache data (disk)
        cache_levels: 1:2           # The hierarchy levels of a cache (disk)
      - name: memory_cache
        memory_size: 50m

We can test the setup with curl:

curl -v localhost:9080/cache

The response is interesting:

< HTTP/1.1 200 OK
< Content-Type: text/html; charset=utf-8
< Content-Length: 147
< Connection: keep-alive
< Date: Tue, 29 Nov 2022 13:17:00 GMT
< Last-Modified: Wed, 23 Nov 2022 13:58:55 GMT
< ETag: "637e271f-93"
< Server: APISIX/3.0.0
< Apisix-Cache-Status: MISS                      (1)
< Accept-Ranges: bytes
1 Because the cache is empty, APISIX has a cache miss. Hence, the response is from the upstream

If we curl again before the default cache expiration period (300 seconds), the response is from the cache:

< HTTP/1.1 200 OK
...
< Apisix-Cache-Status: HIT

After the expiration period, the response is from the upstream, but the header is explicit:

< HTTP/1.1 200 OK
...
< Apisix-Cache-Status: EXPIRED

Note that we can explicitly purge the entire cache by using the custom PURGE HTTP method:

curl localhost:9080/cache -X PURGE

After purging the cache, the above cycle starts anew.

Note that it’s also possible to bypass the cache, e.g., for testing purposes. We can configure the plugin accordingly:

config.yaml
routes:
  - uri: /cache*
    upstream_id: 1
      proxy-cache:
        cache_bypass: ["$arg_bypass"]       (1)
1 Bypass the cache if you send a bypass query parameter with a non-0 value
curl -v localhost:9080/cache?bypass=please

It serves the resource from the upstream regardless of the cache status:

< HTTP/1.1 200 OK
...
< Apisix-Cache-Status: BYPASS

For more details on all available configuration parameters, check the proxy-cache plugin.

Conclusion

This post was relatively straightforward. The most challenging issue with server-side caching is the configuration: what to cache, for how long, etc. Unfortunately, it depends significantly on your context, problems, and available resources. You probably need to apply PDCA: guesstimate a relevant configuration, apply it, measure the performance, and rinse and repeat until you find your sweet spot.

I hope that with an understanding of both client-side and server-side caching, you’ll be able to improve the performance of your applications.

The complete source code for this post can be found on Github.
Nicolas Fränkel

Nicolas Fränkel

Developer Advocate with 15+ years experience consulting for many different customers, in a wide range of contexts (such as telecoms, banking, insurances, large retail and public sector). Usually working on Java/Java EE and Spring technologies, but with focused interests like Rich Internet Applications, Testing, CI/CD and DevOps. Also double as a trainer and triples as a book author.

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