Should we use http caching only for static stuff?
Or also in API responses could be using caching headers if data from API is not static? it can be changed by application's users.
Caching is needed to gain performance but at the same time it increases the likelihood of the data being outdated. It's true for static resources as well. So if your app is under high load and you want to increase the speed - you may sacrifice up-to-date data for gain in performance.
Note, though, that client side needs to respect caching headers. We often work with browsers - they have it all figured out, but if our client is another service, then you need to ensure that it doesn't ignore the headers. This won't be for free - code will need to be written for this to happen.
Your cache may also be public or private. If it's public (any client is allowed to see the content), you may configure a reverse proxy (like nginx) between your server and the clients. Nginx can be set up to cache results (it also understands cache headers). So it may take off some load from your application by not letting requests through and instead returning cached copies.
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While designing rest API's I time to time have challenge to deal with batch operations (e.g. delete or update many entities at once) to reduce overhead of many tcp client connections. And in particular situation problem usually solves by adding custom api method for specific operation (e.g. POST /files/batchDelete which accepts ids at request body) which doesn't look pretty from point of view of rest api design principles but do the job.
But for me general solution for the problem still desirable. Recently I found Google Cloud Storage JSON API batching documentation which for me looks like pretty general solution. I mean similar format may be used for any http api, not just google cloud storage. So my question is - does anybody know kind of general standard (standard or it's draft, guideline, community effort or so) of making multiple API calls combined into one HTTP request?
I'm aware of capabilities of http/2 which include usage of single tcp connection for http requests but my question is addressed to application level. Which in my opinion still make sense because despite of ability to use http/2 taking that on application level seems like the only way to guarantee that for any client including http/1 which is currently the most used version of http.
TL;DR
REST nor HTTP are ideal for batch operations.
Usually caching, which is one of RESTs constraints, which is not optional but mandatory, prevents batch processing in some form.
It might be beneficial to not expose the data to update or remove in batch as own resources but as data elements within a single resource, like a data table in a HTML page. Here updating or removing all or parts of the entries should be straight forward.
If the system in general is write-intensive it is probably better to think of other solutions such as exposing the DB directly to those clients to spare a further level of indirection and complexity.
Utilization of caching may prevent a lot of workload on the server and even spare unnecessary connecctions
To start with, REST nor HTTP are ideal for batch operations. As Jim Webber pointed out the application domain of HTTP is the transfer of documents over the Web. This is what HTTP does and this is what it is good at. However, any business rules we conclude are just a side effect of the document management and we have to come up with solutions to turn this document management side effects to something useful.
As REST is just a generalization of the concepts used in the browsable Web, it is no miracle that the same concepts that apply to Web development also apply to REST development in some form. Thereby a question like how something should be done in REST usually resolves around answering how something should be done on the Web.
As mentioned before, HTTP isn't ideal in terms of batch processing actions. Sure, a GET request may retrieve multiple results, though in reality you obtain one response containing links to further resources. The creation of resources has, according to the HTTP specification, to be indicated with a Location header that points to the newly created resource. POST is defined as an all purpose method that allows to perform tasks according to server-specific semantics. So you could basically use it to create multiple resources at once. However, the HTTP spec clearly lacks support for indicating the creation of multiple resources at once as the Location header may only appear once per response as well as define only one URI in it. So how can a server indicate the creation of multiple resources to the server?
A further indication that HTTP isn't ideal for batch processing is that a URI must reference a single resource. That resource may change over time, though the URI can't ever point to multiple resources at once. The URI itself is, more or less, used as key by caches which store a cacheable response representation for that URI. As a URI may only ever reference one single resource, a cache will also only ever store the representation of one resource for that URI. A cache will invalidate a stored representation for a URI if an unsafe operation is performed on that URI. In case of a DELETE operation, which is by nature unsafe, the representation for the URI the DELETE is performed on will be removed. If you now "redirect" the DELETE operation to remove multiple backing resources at once, how should a cache take notice of that? It only operates on the URI invoked. Hence even when you delete multiple resources in one go via DELETE a cache might still serve clients with outdated information as it simply didn't take notice of the removal yet and its freshness value would still indicate a fresh-enough state. Unless you disable caching by default, which somehow violates one of REST's constraints, or reduce the time period a representation is considered fresh enough to a very low value, clients will probably get served with outdated information. You could of course perform an unsafe operation on each of these URIs then to "clear" the cache, though in that case you could have invoked the DELETE operation on each resource you wanted to batch delete itself to start with.
It gets a bit easier though if the batch of data you want to remove is not explicitly captured via their own resources but as data of a single resource. Think of a data-table on a Web page where you have certain form-elements, such as a checkbox you can click on to mark an entry as delete candidate and then after invoking the submit button send the respective selected elements to the server which performs the removal of these items. Here only the state of one resource is updated and thus a simple POST, PUT or even PATCH operation can be performed on that resource URI. This also goes well with caching as outlined before as only one resource has to be altered, which through the usage of unsafe operations on that URI will automatically lead to an invalidation of any stored representation for the given URI.
The above mentioned usage of form-elements to mark certain elements for removal depends however on the media-type issued. In the case of HTML its forms section specifies the available components and their affordances. An affordance is the knowledge what you can and should do with certain objects. I.e. a button or link may want to be pushed, a text field may expect numeric or alphanumeric input which further may be length limited and so on. Other media types, such as hal-forms, halform or ion, attempt to provide form representations and components for a JSON based notation, however, support for such media-types is still quite limited.
As one of your concerns are the number of client connections to your service, I assume you have a write-intensive scenario as in read-intensive cases caching would probably take away a good chunk of load from your server. I.e. BBC once reported that they could reduce the load on their servers drastically just by introducing a one minute caching interval for recently requested resources. This mainly affected their start page and the linked articles as people clicked on the latest news more often than on old news. On receiving a couple of thousands, if not hundred thousands, request per minute they could, as mentioned before, reduce the number of requests actually reaching the server significantly and therefore take away a huge load on their servers.
Write intensive use-cases however can't take benefit of caching as much as read-intensive cases as the cache would get invalidated quite often and the actual request being forward to the server for processing. If the API is more or less used to perform CRUD operations, as so many "REST" APIs do in reality, it is questionable if it wouldn't be preferable to expose the database directly to the clients. Almost all modern database vendors ship with sophisticated user-right management options and allow to create views that can be exposed to certain users. The "REST API" on top of it basically just adds a further level of indirection and complexity in such a case. By exposing the DB directly, performing batch updates or deletions shouldn't be an issue at all as through the respective query languages support for such operations should already be build into the DB layer.
In regards to the number of connections clients create: HTTP from 1.0 on allows the reusage of connections via the Connection: keep-alive header directive. In HTTP/1.1 persistent connections are used by default if not explicitly requested to close via the respective Connection: close header directive. HTTP/2 introduced full-duplex connections that allow many channels and therefore requests to reuse the same connections at the same time. This is more or less a fix for the connection limitation suggested in RFC 2626 which plenty of Web developers avoided by using CDN and similar stuff. Currently most implementations use a maximum limit of 100 channels and therefore simultaneous downloads via a single connections AFAIK.
Usually opening and closing a connection takes a bit of time and server resources and the more open connections a server has to deal with the more a system may suffer. Though open connections with hardly any traffic aren't a big issue for most servers. While the connection creation was usually considered to be the costly part, through the usage of persistent connections that factor moved now towards the number of requests issued, hence the request for sending out batch-requests, which HTTP is not really made for. Again, as mentioned throughout the post, through the smart utilization of caching plenty of requests may never reach the server at all, if possible. This is probably one of the best optimization strategies to reduce the number of simultaneous requests, as probably plenty of requests might never reach the server at all. Probably the best advice to give is in such a case to have a look at what kind of resources are requested frequently, which requests take up a lot of processing capacity and which ones can easily get responded with by utilizing caching options.
reduce overhead of many tcp client connections
If this is the crux of the issue, the easiest way to solve this is to switch to HTTP/2
In a way, HTTP/2 does exactly what you want. You open 1 connection, and using that collection you can send many HTTP requests in parallel. Unlike batching in a single HTTP request, it's mostly transparent for clients and response and requests can be processed out of order.
Ultimately batching multiple operations in a single HTTP request is always a network hack.
HTTP/2 is widely available. If HTTP/1.1 is still the most used version (this might be true, but gap is closing), this has more to do with servers not yet being set up for it, not clients.
Let's say you've got a fully hypermedia driven API. Consumers have to navigate three reources, via following hypermedia, until they can get to the resource they want. Is there any reason a client could not cache these steps temporarily and go directly to the resource they want?
I know the goal of REST is to decouple clients and servers, but if you've got 5 web requests going on behind the scenes the user experience could be poor waiting for all this to happen.
The worst case I can think of is that a cached URL gets changed. And so the client will just start from the entrypoint again and cache the steps.
Caching on the client side is going to be very important for a lot of well performing Hypermedia clients. Here is some more specific guidance straight from Fielding's dissertation:
The advantage of adding cache constraints is that they have the potential to partially or completely eliminate some interactions, improving efficiency, scalability, and user-perceived performance by reducing the average latency of a series of interactions. The trade-off, however, is that a cache can decrease reliability if stale data within the cache differs significantly from the data that would have been obtained had the request been sent directly to the server.
The are trade offs but event a short time frame for caching will greatly improve performance. Ideally the Hypermedia API will provide caching guidance. This could be done in the same manner that HTML caching works with the browser and Expires and Cache-Control headers.
Also if the resource has moved then the API should inform you with the proper 301 Moved Permanently response.
I have a setup where I would like to have extremely aggressive HTTP caching on my internal proxy. Basically, what I want to achieve is a simplistic caching strategy like this:
any GET request that does not 500x or 400x gets cached indefinitely
any PUT or POST or DELETE or PATCH that does not 500x or 400x invalidates the resource and it's subpaths (since I only use nested resources and I use them a lot).
I don't plan to have a ridiculous number of subpaths either (around 1000 per root-level resource, and less and less drilling down obviously).
So basically I want to avoid the absolute most of the requests even touching my core app.
I plan to run the caching backend on a separate machine with lots of RAM and evil storage, and there is going to be one such machine (so I don't have to expire across a cluster or anything like that).
Which proxy cache would be better for this task? Varnish or HAProxy? What are the settings that I should look for to achieve this kind of expiry? Is this a common pattern to make REST servers caching-friendly?
HAproxy is only a load balancer. It will not do any caching for you.
Varnish is a good choice for your described case. As for the configuration, you are best off to send the caching details (ttl/expiry time and cachability) from your backend that will instruct varnish on cache handling of the document.
Assume the following scenario A web application serves up resources through a RESTful API. A number of clients consume this API. The goal is to keep the data on the clients synchronized with the web application (in both directions).
The easiest way to do this is to ask the API if any of the resources have changed since the client last synchronized with the API. This means that the client needs to ask the API for the appropriate resources accompanied by timestamp (to see if the data needs to be updated). This seems to me like the approach with the least overhead in terms of needless consumption of bandwidth.
However, I have the feeling that this approach has a few downsides in terms of design and responsibilities. For example, the API shouldn't have to deal with checking whether the resources are out of date. It seems that the only responsibility of the API should be to serve up the resources when asked without having to deal with the updating aspect. By following this second approach, the client would ask for a lot of data every time it wants to update its data to keep it synchronized with the web application. In other words, the client would check whether the data it got back is newer than the locally stored data. If this process takes place every few minutes, this might become a significant burden for the system.
Am I seeing this correctly or is there a middle road that I am overlooking?
This is a pretty common problem, and a RESTful approach can help you solve it. HTTP (the application protocol typically used to build RESTful services) supports a variety of techniques that can be used to keep API clients in sync with the data on the server side.
If the client receives a Last-Modified or E-Tag header in a HTTP response, it may use that information to make conditional GET calls in the future. This allows the server to quickly indicate with a 304 – Not Modified response that the client’s previously stored representation of the resource is still valid and accurate. This will allow the server (or even better, an intermediate proxy or cache server) to be as efficient as possible in how it responds to the client’s requests, potentially reducing costly round-trips to a back-end data store.
If a response contains a Last-Modified header and the client wishes to take advantage of the performance optimization available with it, they must include an If-Modified-Since directive in a subsequent GET call to the same URI, passing in the same timestamp value it received. This instructs the server to only GET the information from the authoritative back-end source if it knows it has changed since that time. Your server will have to be built to support this technique, of course.
A similar principle applies to E-Tag headers. An E-Tag is a simple hash code representing a specific state of the resource at a particular point in time. If the resource changes in any way, so does its E-Tag value. If the client sees an E-Tag in a response it should pass it in subsequent GET requests to the same URI, thereby allowing the server to quickly determine if the client has an up-to-date representation of the resource.
Finally, you should probably look at the long polling technique to reduce the number of repeated GET requests issued by your clients to the server. In essence, the trick is to issue very long GET requests to the server to watch for server data changes. The GET will not return a response until either the data has changed or the very long timeout fires. If the latter, the client just re-issues the same long-lived request to watch for changes again. See also topics like Comet and Web Sockets which are similar in approach.
I have a REST API where I would like to cache the JSON response of the index (GET /foo) and the read actions (GET /foo/1) to significantly increase the performance. When there is a POST or a PUT on a resource the cache entries for the index and read results need to be expired, so no old content is served.
Is this a scenario that's best done with a Reverse proxy like Squid / Varnish or would you choose memcache(d)?
Using a reverse proxy that sits on the HTTP layer is more transparent. That means that it's possible to see what's going on over the wire. The bad thing is that few of these support caching authenticated responses, so their efficiency may drop to 0 if your resources require authentication. Reverse proxies also don't usually automatically expire resource A (/foo) when this completely unrelated resource B (/foo/1) is modified. That's correct behaviour that you'd have to add to your solution somehow.
Both of these problems can be solved if you use memcached, since it doesn't have the transparency requirement.
I would go for a reverse proxy like varnish because you can implement (and test) your service without involving cache logic, and add caching as a separate layer. You can upgrade/restart your service while varnish serves old results for GET request (great for availability), and it's easy to setup rules in varnish to invalide (purge) existing cache results based on specific GET/POST actions.
If you want to employ distributed memory memcached is a good solution. https://github.com/cpatni/middleman is a reverse proxy which uses memcached for caching.