--- title: Plugin Develop --- ## table of contents - [table of contents](#table-of-contents) - [where to put your plugins](#where-to-put-your-plugins) - [check dependencies](#check-dependencies) - [name and config](#name-and-config) - [schema and check](#schema-and-check) - [choose phase to run](#choose-phase-to-run) - [implement the logic](#implement-the-logic) - [conf parameter](#conf-parameter) - [ctx parameter](#ctx-parameter) - [write test case](#write-test-case) - [Attach the test-nginx execution process:](#attach-the-test-nginx-execution-process) - [Register public API](#register-public-api) - [Register control API](#register-control-api) This documentation is about developing plugin in Lua. For other languages, see [external plugin](./external-plugin.md). ## where to put your plugins There are two ways to add new features based on APISIX. 1. modify the source of APISIX and redistribute it (not so recommended) 1. setup the `extra_lua_path` and `extra_lua_cpath` in `conf/config.yaml` to load your own code. Your own code will be loaded instead of the builtin one with the same name, so you can use this way to override the builtin behavior if needed. For example, you can create a directory structure like this: ``` ├── example │   └── apisix │   ├── plugins │   │   └── 3rd-party.lua │   └── stream │   └── plugins │   └── 3rd-party.lua ``` Then add this configuration into your `conf/config.yaml`: ```yaml apisix: ... extra_lua_path: "/path/to/example/?.lua" ``` Now using `require "apisix.plugins.3rd-party"` will load your plugin, just like `require "apisix.plugins.jwt-auth"` will load the `jwt-auth` plugin. ## check dependencies if you have dependencies on external libraries, check the dependent items. if your plugin needs to use shared memory, it needs to declare via [customizing Nginx configuration](./customize-nginx-configuration.md), for example : ```yaml # put this in config.yaml: nginx_config: http_configuration_snippet: | # for openid-connect plugin lua_shared_dict discovery 1m; # cache for discovery metadata documents lua_shared_dict jwks 1m; # cache for JWKs lua_shared_dict introspection 10m; # cache for JWT verification results ``` The plugin itself provides the init method. It is convenient for plugins to perform some initialization after the plugin is loaded. Note : if the dependency of some plugin needs to be initialized when Nginx start, you may need to add logic to the initialization method "http_init" in the file __apisix/init.lua__, and you may need to add some processing on generated part of Nginx configuration file in __apisix/cli/ngx_tpl.lua__ file. But it is easy to have an impact on the overall situation according to the existing plugin mechanism, **we do not recommend this unless you have a complete grasp of the code**. ## name, priority and the others Determine the name and priority of the plugin, and add to conf/config.yaml. For example, for the example-plugin plugin, you need to specify the plugin name in the code (the name is the unique identifier of the plugin and cannot be duplicate), you can see the code in file "__apisix/plugins/example-plugin.lua__" : ```lua local plugin_name = "example-plugin" local _M = { version = 0.1, priority = 0, name = plugin_name, schema = schema, metadata_schema = metadata_schema, } ``` Note: The priority of the new plugin cannot be same to any existing ones, you can use the `/v1/schema` method of [control API](./control-api.md#get-v1schema) to view the priority of all plugins. In addition, plugins with higher priority value will be executed first in a given phase (see the definition of `phase` in [choose-phase-to-run](#choose-phase-to-run)). For example, the priority of example-plugin is 0 and the priority of ip-restriction is 3000. Therefore, the ip-restriction plugin will be executed first, then the example-plugin plugin. It's recommended to use priority 1 ~ 99 for your plugin unless you want it to run before some builtin plugins. In the "__conf/config-default.yaml__" configuration file, the enabled plugins (all specified by plugin name) are listed. ```yaml plugins: # plugin list - limit-req - limit-count - limit-conn - key-auth - prometheus - node-status - jwt-auth - zipkin - ip-restriction - grpc-transcode - serverless-pre-function - serverless-post-function - openid-connect - proxy-rewrite - redirect ... ``` Note: the order of the plugins is not related to the order of execution. To enable your plugin, copy this plugin list into `conf/config.yaml`, and add your plugin name. For instance: ```yaml apisix: admin_key: - name: "admin" key: edd1c9f034335f136f87ad84b625c8f1 # using fixed API token has security risk, please update it when you deploy to production environment role: admin plugins: # copied from config-default.yaml ... - your-plugin ``` If your plugin has a new code directory of its own, and you need to redistribute it with the APISIX source code, you will need to modify the `Makefile` to create directory, such as: ``` $(INSTALL) -d $(INST_LUADIR)/apisix/plugins/skywalking $(INSTALL) apisix/plugins/skywalking/*.lua $(INST_LUADIR)/apisix/plugins/skywalking/ ``` There are other fields in the `_M` which affect the plugin's behavior. ```lua local _M = { ... type = 'auth', run_policy = 'prefer_route', } ``` `run_policy` field can be used to control the behavior of the plugin execution. When this field set to `prefer_route`, and the plugin has been configured both in the global and at the route level, only the route level one will take effect. `type` field is required to be set to `auth` if your plugin needs to work with consumer. See the section below. ## schema and check Write [JSON Schema](https://json-schema.org) descriptions and check functions. Similarly, take the example-plugin plugin as an example to see its configuration data: ```json { "example-plugin": { "i": 1, "s": "s", "t": [1] } } ``` Let's look at its schema description : ```lua local schema = { type = "object", properties = { i = {type = "number", minimum = 0}, s = {type = "string"}, t = {type = "array", minItems = 1}, ip = {type = "string"}, port = {type = "integer"}, }, required = {"i"}, } ``` The schema defines a non-negative number `i`, a string `s`, a non-empty array of `t`, and `ip` / `port`. Only `i` is required. At the same time, we need to implement the __check_schema(conf)__ method to complete the specification verification. ```lua function _M.check_schema(conf, schema_type) return core.schema.check(schema, conf) end ``` Note: the project has provided the public method "__core.schema.check__", which can be used directly to complete JSON verification. In addition, if the plugin needs to use some metadata, we can define the plugin `metadata_schema`, and then we can dynamically manage these metadata through the `admin api`. Example: ```lua local metadata_schema = { type = "object", properties = { ikey = {type = "number", minimum = 0}, skey = {type = "string"}, }, required = {"ikey", "skey"}, additionalProperties = false, } local plugin_name = "example-plugin" local _M = { version = 0.1, priority = 0, -- TODO: add a type field, may be a good idea name = plugin_name, schema = schema, metadata_schema = metadata_schema, } ``` You might have noticed the key-auth plugin has `type = 'auth'` in its definition. When we set the type of plugin to `auth`, it means that this plugin is an authentication plugin. An authentication plugin needs to choose a consumer after execution. For example, in key-auth plugin, it calls the `consumer.attach_consumer` to attach a consumer, which is chosen via the `apikey` header. To interact with the `consumer` resource, this type of plugin needs to provide a `consumer_schema` to check the `plugins` configuration in the `consumer`. Here is the consumer configuration for key-auth plugin: ```json { "username": "Joe", "plugins": { "key-auth": { "key": "Joe's key" } } } ``` It will be used when you try to create a [Consumer](https://github.com/apache/apisix/blob/master/docs/en/latest/admin-api.md#consumer) To validate the configuration, the plugin uses a schema like this: ```lua local consumer_schema = { type = "object", additionalProperties = false, properties = { key = {type = "string"}, }, required = {"key"}, } ``` Note the difference between key-auth's __check_schema(conf)__ method to example-plugin's: ```lua -- key-auth function _M.check_schema(conf, schema_type) if schema_type == core.schema.TYPE_CONSUMER then return core.schema.check(consumer_schema, conf) else return core.schema.check(schema, conf) end end ``` ```lua -- example-plugin function _M.check_schema(conf, schema_type) return core.schema.check(schema, conf) end ``` ## choose phase to run Determine which phase to run, generally access or rewrite. If you don't know the [Openresty life cycle](https://openresty-reference.readthedocs.io/en/latest/Directives/), it's recommended to know it in advance. For example key-auth is an authentication plugin, thus the authentication should be completed before forwarding the request to any upstream service. Therefore, the plugin must be executed in the rewrite phases. In APISIX, only the authentication logic can be run in the rewrite phase. Other logic needs to run before proxy should be in access phase. The following code snippet shows how to implement any logic relevant to the plugin in the OpenResty log phase. ```lua function _M.log(conf) -- Implement logic here end ``` **Note : we can't invoke `ngx.exit` or `core.respond.exit` in rewrite phase and access phase. if need to exit, just return the status and body, the plugin engine will make the exit happen with the returned status and body. [example](https://github.com/apache/apisix/blob/35269581e21473e1a27b11cceca6f773cad0192a/apisix/plugins/limit-count.lua#L177)** ## implement the logic Write the logic of the plugin in the corresponding phase. There are two parameters `conf` and `ctx` in the phase method, take the `limit-conn` plugin configuration as an example. ```shell curl http://127.0.0.1:9080/apisix/admin/routes/1 -H 'X-API-KEY: edd1c9f034335f136f87ad84b625c8f1' -X PUT -d ' { "methods": ["GET"], "uri": "/index.html", "id": 1, "plugins": { "limit-conn": { "conn": 1, "burst": 0, "default_conn_delay": 0.1, "rejected_code": 503, "key": "remote_addr" } }, "upstream": { "type": "roundrobin", "nodes": { "39.97.63.215:80": 1 } } }' ``` ### conf parameter The `conf` parameter is the relevant configuration information of the plugin, you can use `core.log.warn(core.json.encode(conf))` to output it to `error.log` for viewing, as shown below: ```lua function _M.access(conf, ctx) core.log.warn(core.json.encode(conf)) ...... end ``` conf: ```json { "rejected_code": 503, "burst": 0, "default_conn_delay": 0.1, "conn": 1, "key": "remote_addr" } ``` ### ctx parameter The `ctx` parameter caches data information related to the request. You can use `core.log.warn(core.json.encode(ctx, true))` to output it to `error.log` for viewing, as shown below : ```lua function _M.access(conf, ctx) core.log.warn(core.json.encode(ctx, true)) ...... end ``` ## write test case For functions, write and improve the test cases of various dimensions, do a comprehensive test for your plugin! The test cases of plugins are all in the "__t/plugin__" directory. You can go ahead to find out. APISIX uses [****test-nginx****](https://github.com/openresty/test-nginx) as the test framework. A test case (.t file) is usually divided into prologue and data parts by \__data\__. Here we will briefly introduce the data part, that is, the part of the real test case. For example, the key-auth plugin: ```perl === TEST 1: sanity --- config location /t { content_by_lua_block { local plugin = require("apisix.plugins.key-auth") local ok, err = plugin.check_schema({key = 'test-key'}, core.schema.TYPE_CONSUMER) if not ok then ngx.say(err) end ngx.say("done") } } --- request GET /t --- response_body done --- no_error_log [error] ``` A test case consists of three parts : - __Program code__ : configuration content of Nginx location - __Input__ : http request information - __Output check__ : status, header, body, error log check When we request __/t__, which config in the configuration file, the Nginx will call "__content_by_lua_block__" instruction to complete the Lua script, and finally return. The assertion of the use case is response_body return "done", "__no_error_log__" means to check the "__error.log__" of Nginx. There must be no ERROR level record. The log files for the unit test are located in the following folder: 't/servroot/logs'. The above test case represents a simple scenario. Most scenarios will require multiple steps to validate. To do this, create multiple tests `=== TEST 1`, `=== TEST 2`, and so on. These tests will be executed sequentially, allowing you to break down scenarios into a sequence of atomic steps. Additionally, there are some convenience testing endpoints which can be found [here](https://github.com/apache/apisix/blob/master/t/lib/server.lua#L36). For example, see [proxy-rewrite](https://github.com/apache/apisix/blob/master/t/plugin/proxy-rewrite.lua). In test 42, the upstream `uri` is made to redirect `/test?new_uri=hello` to `/hello` (which always returns `hello world`). In test 43, the response body is confirmed to equal `hello world`, meaning the proxy-rewrite configuration added with test 42 worked correctly. Refer the following [document](how-to-build.md#4-test) to setup the testing framework. ### Attach the test-nginx execution process: According to the path we configured in the makefile and some configuration items at the front of each __.t__ file, the framework will assemble into a complete nginx.conf file. "__t/servroot__" is the working directory of Nginx and start the Nginx instance. according to the information provided by the test case, initiate the http request and check that the return items of HTTP include HTTP status, HTTP response header, HTTP response body and so on. ### Register public API A plugin can register API which exposes to the public. Take jwt-auth plugin as an example, this plugin registers `GET /apisix/plugin/jwt/sign` to allow client to sign its key: ```lua local function gen_token() --... end function _M.api() return { { methods = {"GET"}, uri = "/apisix/plugin/jwt/sign", handler = gen_token, } } end ``` Note that the public API is exposed to the public. You may need to use [interceptors](plugin-interceptors.md) to protect it. ### Register control API If you only want to expose the API to the localhost or intranet, you can expose it via [Control API](./control-api.md). Take a look at example-plugin plugin: ```lua local function hello() local args = ngx.req.get_uri_args() if args["json"] then return 200, {msg = "world"} else return 200, "world\n" end end function _M.control_api() return { { methods = {"GET"}, uris = {"/v1/plugin/example-plugin/hello"}, handler = hello, } } end ``` If you don't change the default control API configuration, the plugin will be expose `GET /v1/plugin/example-plugin/hello` which can only be accessed via `127.0.0.1`.