This short document aims to give a quick guide to anyone implementing API bindings for IPFS implementations-- in particular go-ipfs.
Sections:
- IPFS Types
- API Transports
- API Commands
- Implementing bindings for the HTTP API
IPFS uses a set of value type that is useful to enumerate up front:
<ipfs-path>is unix-style path, beginning with/ipfs/<cid>/...or/ipns/<hash>/...or/ipns/<domain>/....<hash>is a base58 encoded multihashcidis a multibase encoded CID - a self-describing content-addressing identifier
A note on streams: IPFS is a streaming protocol. Everything about it can be streamed. When importing files, API requests should aim to stream the data in, and handle back-pressure correctly, so that the IPFS node can handle it sequentially without too much memory pressure. (If using HTTP, this is typically handled for you by writes to the request body blocking.)
Like with everything else, IPFS aims to be flexible regarding the API transports. Currently, the go-ipfs implementation supports both an in-process API and an HTTP API. More can be added easily, by mapping the API functions over a transport. (This is similar to how gRPC is also mapped on top of transports, like HTTP).
Mapping to a transport involves leveraging the transport's features to express function calls. For example:
In the commandline, IPFS uses a traditional flag and arg-based mapping, where:
- the first arguments selects the command, as in git - e.g.
ipfs object get - the flags specify options - e.g.
--enc=protobuf -q - the rest are positional arguments - e.g.
ipfs object patch <hash1> add-linkfoo <hash2> - files are specified by filename, or through stdin
(NOTE: When go-ipfs runs the daemon, the CLI API is actually converted to HTTP calls. otherwise, they execute in the same process)
In HTTP, our API layering uses a REST-like mapping, where:
- the URL path selects the command - e.g
/object/get - the URL query string implements option arguments - e.g.
&enc=protobuf&q=true - the URL query also implements positional arguments - e.g.
&arg=<hash1>&arg=add-link&arg=foo&arg=<hash2> - the request body streams file data - reads files or stdin
- multiple streams are muxed with multipart (todo: add tar stream support)
There is a "standard IPFS API" which is currently defined as "all the commands
exposed by the go-ipfs implementation". There are auto-generated API Docs.
You can Also see a listing here, or get a list of
commands by running ipfs commands locally.
As mentioned above, the API commands map to HTTP with:
- the URL path selects the command - e.g
/object/get - the URL query string implements option arguments - e.g.
&enc=protobuf&q=true - the URL query also implements positional arguments - e.g.
&arg=<hash1>&arg=add-link&arg=foo&arg=<hash2> - the request body streams file data - reads files or stdin
- multiple streams are muxed with multipart (todo: add tar stream support)
To date, we have two different HTTP API clients:
- js-ipfs-api - simple javascript wrapper -- best to look at
- go-ipfs/commands/http - generalized transport based on the command definitions
The Go implementation is good to answer harder questions, like how is multipart handled, or what headers should be set in edge conditions. But the javascript implementation is very concise, and easy to follow.
Currently, node-ipfs-api has three main files
- src/index.js defines the functions clients of the API
module will use. uses
RequestAPI, and translates function call parameters to the API almost directly. - src/get-files-stream.js implements the hardest part: file streaming. This one uses multipart.
- src/request-api.js generic function call to perform the actual HTTP requests
Despite all the generalization spoken about above, the IPFS API is actually very
simple. You can inspect all the requests made with nc and the --api option
(as of this PR, or 0.3.8):
> nc -l 5002 &
> ipfs --api /ip4/127.0.0.1/tcp/5002 swarm addrs local --enc=json
POST /api/v0/version?enc=json&stream-channels=true HTTP/1.1
Host: 127.0.0.1:5002
User-Agent: /go-ipfs/0.3.8/
Content-Length: 0
Content-Type: application/octet-stream
Accept-Encoding: gzip
The only hard part is getting the file streaming right. It is (now) fairly easy to stream files to go-ipfs using multipart. Basically, we end up with HTTP requests like this:
> nc -l 5002 &
> ipfs --api /ip4/127.0.0.1/tcp/5002 add -r ~/demo/basic/test
POST /api/v0/add?encoding=json&progress=true&r=true&stream-channels=true HTTP/1.1
Host: 127.0.0.1:5002
User-Agent: /go-ipfs/0.3.8/
Transfer-Encoding: chunked
Content-Disposition: form-data: name="files"
Content-Type: multipart/form-data; boundary=2186ef15d8f2c4f100af72d6d345afe36a4d17ef11264ec5b8ec4436447f
Accept-Encoding: gzip
1
-
e5
-2186ef15d8f2c4f100af72d6d345afe36a4d17ef11264ec5b8ec4436447f
Content-Disposition: form-data; name="file"; filename="test"
Content-Type: multipart/mixed; boundary=acdb172fe12f25e8ffae9981ce6f4580abdefb0cae3ceebe464d802866be
9c
--acdb172fe12f25e8ffae9981ce6f4580abdefb0cae3ceebe464d802866be
Content-Disposition: file; filename="test%2Fbar"
Content-Type: application/octet-stream
4
bar
dc
--acdb172fe12f25e8ffae9981ce6f4580abdefb0cae3ceebe464d802866be
Content-Disposition: file; filename="test%2Fbaz"
Content-Type: multipart/mixed; boundary=2799ac77a72ef7b8a0281945806b9f9a28f7681145aa8e91b052d599b2dd
a0
--2799ac77a72ef7b8a0281945806b9f9a28f7681145aa8e91b052d599b2dd
Content-Type: application/octet-stream
Content-Disposition: file; filename="test%2Fbaz%2Fb"
4
bar
a2
--2799ac77a72ef7b8a0281945806b9f9a28f7681145aa8e91b052d599b2dd
Content-Disposition: file; filename="test%2Fbaz%2Ff"
Content-Type: application/octet-stream
4
foo
44
--2799ac77a72ef7b8a0281945806b9f9a28f7681145aa8e91b052d599b2dd--
9e
--acdb172fe12f25e8ffae9981ce6f4580abdefb0cae3ceebe464d802866be
Content-Disposition: file; filename="test%2Ffoo"
Content-Type: application/octet-stream
4
foo
44
--acdb172fe12f25e8ffae9981ce6f4580abdefb0cae3ceebe464d802866be--
44
--2186ef15d8f2c4f100af72d6d345afe36a4d17ef11264ec5b8ec4436447f--
0
Which produces: http://gateway.ipfs.io/ipfs/QmNtpA5TBNqHrKf3cLQ1AiUKXiE4JmUodbG5gXrajg8wdv