Welcome to the Rest Services module. This module can be used in Mendix apps as toolkit if you want to achieve one of the following three purposes:
- Consume JSON REST based services
- Publish data or microflows through REST API's
- (Real time) Synchronization of data between Mendix applications
- RestServices on GitHub
- Restservices in the Mendix Appstore
- Blog post: Consuming your first REST service
- Blog post: REST Part II: Publishing Microflows with REST
- Getting Started
- Consuming REST services
- Publishing REST services
- (Real time) data synchronization
- About JSON serialization
- About JSON deserialization
- Working with files / binary data
- Overview of all functions
- Notes for contributers
- Changelog
- The RestServices module can be downloaded from within the Mendix Business Modeler in the Mendix Appstore into any model that is build with Mendix 4.4.4+ or Mendix 5.3.1+.
- The RestServices module depends on the on the Community Commons module, version 5.4 or higher. Download this module as well if it is not already part of your project.
- TODO: connect userroles and layouts (mx 5)
- [Optional] If you want to publish REST services or use the data synchronization features, add
IVK_OpenServiceOverview
to your main navigation if you want to use the administrative features of the RestServices module. Make sure to map your administrative project role to theAdministrator
role in the RestServices module as well. - [Optional] If you want to publish REST services, add
StartPublishServices
to the startup sequence of your application. Also, the 'rest/' request handler needs to be opened if running in the Mendix Standard Cloud (or on premise). - It is strongly recommended to not use the default HSQLDB engine if you want to publish RestServices while running locally.
NOTE: Since Mendix 6.6, you can consume REST services directly with the Call Rest microflow action. You can use Import and Export mappings to create and read messages. See https://world.mendix.com/display/refguide6/Consumed+REST+Services
This readme is the reference guide. For a quick how-to you might take a look at this blog post as well.
This module is able to invoke most, if not any, REST service which is based on JSON, form-data, multipart or binary data. The operations in the 'Consume' folder of the module provide the necessary tools to invoke data. The work horse of all this operations is the java action request
. Most other methods are wrappers around this operation.
Request performs an HTTP request and provides the means to both send data and receive data over HTTP. Its parameters are defined as follow.
method
, the HTTP method to use, which is one ofGET
,POST
,PUT
orDELETE
. Which method to use is usually defined in the documentation of the service to consume. Otherwise see the 'HTTP verbs in REST' section for more information. As a rule of thumb: If you only want to fetch data useGET
, otherwise usePOST
.url
defines the HTTP endpoint to which the request should be send.optRequestData
is an optional Mendix object that provides the parameters which are used in the request (note that it is also possible to pass parameters in theurl
itself). This object will be serialized to JSON (see the corresponding section) and be passed to the endpoint. The format in which the data will be send depends on the actualmethod
andsendWithFormEncoding
parameter.optResponseData
is an optional Mendix object in which the response data will be stored. This object will be filled by any JSON / file data which is in the response body of the request. See the 'JSON deserialization' section for more details how a JSON body is parsed into a Mendix object.
This method returns a RequestResult
object if the service responds with HTTP response 200 OK
or 304 Not Modified
. In all other cases an exception will be thrown.
Most REST operations return a RequestResult
object which contains the meta information of a response. An instance contains the following fields:
ResponseCode
stating whether the server responded with 'OK' or 'Not modified'. A 'Not modified' response might be send by the server if, for example, an 'If-none-modified' header was send, which indicates that you received the proper response to this request in an earlier request. See for example ETags. The value will be 'Error' if an error occured during a REST reques (in which case the current RequestResult object can be retrieved by callinggetRestConsumeError
).RawResponseCode
idem, but as HTTP status code. Note that the status code -1 will be used if there was a connection error.ETag
if the response contained anETag
header, it is picked up and stored in this field. It can be used as optimization for any subsequent requests.ResponseBody
the full and raw response body of the request. This field is only set if the body of the response is not yet parsed (by providing anoptResponseData
parameter for example).
Many REST services require the usage of custom request handlers for authentication, caching etc. In the RestServices module, any call to addHeaderToNextRequest
will add a header to the next (and only the next) request that will be made by the current microflow.
The RestServices module only supports Basic authentication out of the box. But it also possible to authenticate using OAuth or other security protocols by following the specs of the designated service. (There is a working Dropbox integration app based on a combination of the RestServices module and the Deeplink module for requesting tokens).
Basic authentication credentials can be send by using addCredentialsToNextRequest
just before the actual request is made. Too make life easier, it is also possible to use registerCredentials
, which will send credentials with any subsequent request to the same host.
For all standard HTTP verbs there is a method available which wraps the request
operation, but simplifies the arguments one has to provide. See the HTTP Verbs section for best practices about when to use which verb. For a complete list of consume methods see the REST functions overview.
Tries to retrieve an object from the provided resourceURL
. Expects JSON data which will be parsed into the targetObject
object. A targetObject
object should be a just created, empty and transient object. This object will be filled with data as described in the 'JSON Deserialization' section.
Similar to get, but also accepts a requestData
parameter. The primitive members of that object will be appended to the resourceUrl
as HTTP parameters. For example a member 'q' with value 'Rest Services' will be appended to the url as '?q=Rest%20Services'.
Tries to retrieve a list of objects from the provided URL. The expected response body is either an array of JSON objects, or an array of URLs, which will be retrieved automatically to retrieve all the items in the array. getCollection
uses streaming to make the process as memory efficient as possible.
The resultList
parameter should be a completely empty list, but of the same type as firstResult
. The firstResult
object will be used to story the first result in and should be a new, empty, transient object.
Needing to provide both the resultList
and firstResult
parameters might seem a bit awkward, but the firstResult
object is required by the actual implementation to determine the type of the result set, because lists in Mendix are untyped at runtime)
The behavior is similar to getCollection
, but its implementation is very suitable for very large response sets. Instead of building a list, the callbackMicroflow
will be invoked on each individual item in the response array. This way, only one item is in memory of the server at any given time.
Submits an object to the remote server. The requestData
object will be serialized to JSON as described in the 'JSON Serialization' section. If the submitAsFormData
parameter is set, the data will not be encoded as JSON but as form data (which is commonly used for submitting web forms for example). Note that form data only supports flat objects with primitive members only.
Tries to delete a resource at the given URL.
Similar to post
. See the 'HTTP verbs' section or the specs of the service you are consuming to find out whether to use post
or put
.
Can be used in the error handler of a REST request. Returns the RequestResult
object with the response data that would also be returned otherwise if the request was successful. The ResponseCode
field will be set to Error
.
It is possible to use template URLs when consuming REST services. This makes it possible to substitute values directly in an url. For example when using the put
function with the url
http://myservice.com/groups/{groupId}
and the data object { groupId : 123, description : "group"}
, a PUT request will be send to the substituted URL http://myservice.com/groups/123
with payload data { description : "group" }
.
Publishing a REST service is pretty straight forward with this modules. The module provides publishing REST services in two flavors:
- Publishing operations, based on a single microflow.
- Publishing a part of your data model, and providing a typical rest based API to retrieve, update, delete, create and even real-time sync data.
PLEASE NOTE THAT TO BE ABLE TO PUBLISH ANY SERVICE, THE MICROFLOW STARTPUBLISHSERVICES
SHOULD BE CALLED DURING STARTUP OF THE APP!
This readme is the reference guide. For a quick how-to about publishing microflows you might take a look at this blog post
Publishing a microflow is conceptually very similar to publishing a webservice. It publishing a single operation based on a microflow. The difference with a normal Mendix webservice is the transport method; instead of SOAP the RestServices module provides an interface which supports JSON based messages or form / multipart encoded messages (typically used to submit webforms) or raw binary data (for efficient downloads for example).
A published microflow should always have a single transient object as argument. Each field in this transient object is considered a parameter (from HTTP perspective). This means that if you have multiple primitive parameters for your service, for example offset
and limit
, you should create a new transient entity that has two fields with the names offset
and limit
.
Your service can now be invoked by either providing the values as HTTP parameters (for example: GET http://apphost/rest/yourservice?offset=3&limit=5
) or by sending these fields in the json body of the request. In both cases the fields of your input parameter will be set. For example:
POST http://apphost/rest/yourservice
{ offset : 3, limit : 5 }
Complex objects are supported if JSON is used as transport mechanism. The return type of the microflow should again be a transient object or a String or a filedocument. In the latter case, the string is considered to be the raw response of the operation which is not further processed.
It is possible to build publish services that accept or respond with files as well. See for more details the working with files section.
Publishing a microflow is as simple as calling CreateMicroflowService
with the microflow that provides the implementation. The name of the operation will be derived form the microflow name. The meta data of the operation is published on <app-url>/rest/, including a JSON-schema describing its arguments. The endpoint for the operation itself is <app-url>/rest/<public-name>. For securing your microflow service see Securing published services
It is possible to provide a template path when registering a microflow service. This allows for constructing more complex URLs, from which values are parsed. For example, a microflow could be defined with the template path: groups/{groupId}/users/{userId}
. If that service would be called with http://myapp.com/rest/groups/123/users/John
, the attribute groupId
of the input argument of the microflow would be instantiated with the value 123
. Likewise, the attribute userId
would be instantiated with the value John
.
A Published Service provides a JSON based API to list, retrieve, create, update, delete and track objects in your database. Documentation for these services will be generated automatically by the module and can be read by pointing your browser at <app-url>/rest/. Responses can be rendered JSON, XML or HTML, depending on the Accept
headers of the request. Depending on the selected features, the following endpoints are available for a data service after the base url <app-url>/rest/<service-name>
:
Method | Url | Description |
---|---|---|
GET | /?about | Meta description of this services. Describes the endpoints and datatypes of this service in great detail. |
GET | / | List of all objects published by this service. |
GET | /<key> | Returns a specific instance, identified by the key. |
POST | / | Creates a new object and initializes it based on the JSON body of the request. Returns the key of the newly created object. |
PUT | /<key> | Creates or updates the object with the specified <key>. Returns nothing. |
DELETE | /<key> | Deletes the object with the specified <key>. Returns nothing. |
GET | /changes/list | Returns all objects of this service change by change. Can be used to synchronize data. |
GET | /changes/feed | Similar to changes/list but keeps the HTTP connection open to be able to push any future changes to the consumer. |
The central idea behind a service that there is a persistent entity in your database acting as data source for your service. Furthermore your model should define a transient object that will act as view object of your data, so that your internal data structure is not directly published to the outside. This allows for better maintainability and it guarantees that you can pre- or post-process your data when required.
When publishing data, the Publish Microflow has the responsibility of converting source objects into view objects. When processing incoming data, the Update Microflow is responsible for exactly the reverse process; transforming a view as provided by some consumer into real data in your database.
Each source object should be uniquely identifiable by a single key attribute.
For example: GET <your-app>/rest/<service name>/<identifier> will search for the first source object in your database which key value equals the identifier. If found, this object will be converted by the Publish Microflow into a view object. This view object will be serialized to JSON (or HTML or XML) and returned to the consumer.
Creating a new JSON based data service with full CRUD support is pretty straightforward with the RestServices module. The easiest way to start is to connect the microflow IVK_OpenServiceOverview
to your navigation and create a new Published Service after starting your app.
Once you have figured out the correct configuration for your data service, a best practice is to use the GetOrCreateDataService
microflow in the startup microflow to create your service configuration. Alter and commit the properties of the resulting ServiceDefinition to update the configuration. If the configuration contains consistency errors, those will will be listed in the log of your application.
You can further configure the service from either a microflow or the form in the running app by setting the following properties.
Property | Default value | Description |
---|---|---|
Name | (required) | Public name of this service. The endpoint of the service will be <app-url>/rest/<name>. Example: Tasks |
Description | (optional) | Description of this services. Will be part of the generated meta data |
Source Entity | (required) | The entity in the data model that should be published. Should be persistable. Example: MyModule.Task |
Source Key Attribute | (required) | Attribute that uniquely identifies an object and which will be used as external reference to this object. The attribute should not change over time. Example: TaskID |
Source Constraint | (optional) | XPath constraint that limits which objects are readable / writable through this service. It is possible to use the '[%Current_User%]' token inside this constraint, unless the Enable Change Log flag is set. Example: [Finished = false() and MyModule.Task_Owner = '[%Current_User%]'] |
Authentication Role / Microflow | * |
See Securing published services |
On Publish Microflow | (optional) | Microflow that transforms a source object into some transient object which (the view). This view will be serialized into JSON/HTML/XML when data is requested from the service. The speed of this microflow primarily determines the speed of the service as a whole. |
On Update Microflow | (optional) | Microflow that processes incoming changes. Should have two parameters; one of same type as the source entity, and one which is a transient entity. The transient object will be constructed with JSON data in the incoming request. This transient object should be processed by the microflow and update the source object as desired. Use the ThrowWebserviceException method of Community Commons to signal any exceptions to the consumer. |
On Delete Microflow | (optional) | Similar to the On Update Microflow but takes a String attribute as argument, that represents the key of the object that should be deleted |
Property | Default value | Description |
---|---|---|
Enable GET | true |
Allows requesting individual objects using GET at rest/servicename/objectid |
Enable Listing | true |
Allows listing all available objects using GET at rest/servicename/ |
Enable Update | false |
Allows consumers to update existing objects using PUT or POST at rest/servicename/objectid |
Enable Create | false |
Allows consumers to create new objects using POST at rest/servicename/ |
Enable Delete | false |
Allows consumers to remove existing objects using DELETE at rest/servicename/objectid |
Enable Change Log | false |
See next section |
Use Strict Versioning | false |
If set to true, all requests that modify data are required to provide an if-none-match header, to verify that the request is based on the latest known version. This way conflicting updates are detected and it is not possible to base changes on stale objects |
For a published service, three authentication models can be used:
*
indicates that a service is world accessible. This holds for both reading and writing (if applicable)Rolename
indicates that authentication is required, and that credentials for a user that has a specific role are required. This works similar to webservice authentication, except that the 'WebServiceUser' attribute should not be set. Normal users can perform REST requests as well. The REST module will attempt to pick up any client session that is available (useful when invoking the service from a browser, using Ajax for example). If no such session is found, basic authentication needs to be provided to send credentials to the service.Module.Microflowname
can be used to set up a custom authentication mechanism. This microflow shouldn't require any arguments and return a System.User object or null (if authentication failed). If a user object was returned, the service will be invoked under a fresh session of that user. In the microflow, you can usegetRequestHeader
calls to extract HTTP headers from the request, which can be used to perform authentication. This is very useful if you want to setup authentication using a api key for example.
The Enable Change Log property has significant impact on the behavior and internal working of the service. It introduces a cache in which the JSON representation of each objects are stored and provides the possibility to synchronize with consumers over time. See the Data synchronisation section for more details. Enabling the changelog has the following consequences:
- Two new endpoints are created: rest/service/changes/list and rest/service/changes/feed. Both endpoints provide a list of all changes which where made to the source collection. The endpoints accept an
since
parameter, which can be used to only retrieve changes which were not synced yet. The API and behavior are heavily inspired by the CouchDB changes API. - Requests are served from the cache instead of the database directly. To update an item in the cache, the model needs to call
publishUpdate
orpublishDelete
. This can either be done as after commit / after delete event, or in the logic of your model. Changes are not visible for consumers until one of these methods is called by the model. - It is no longer possible to use the
'[%CurrentUser%]'
token in constraints; the cache is shared with all users connecting to the server so different users can no longer be distinguished. - The performance of retrieving objects is improved, since they are stored in serialized form internally.
- If, for example, the domain model of your source or view object changes, the cache becomes stale. Most model changes are detected by the RestServices module automatically, but you can force rebuilding the complete index by invoking
RebuildServiceIndex
.
If the change log is enabled for a service the RestServices module will preserve a change log with which consumers can synchronize. A typical change item like this:
{
"seq": 2,
"deleted": false,
"key": "2"
"url": "http://localhost:8080/rest/customers/2",
"etag": "6a068f795f26d65c5aa8ef335c6e9ac1",
"data": {
"Name": "bla",
"Nr": 2,
"Orders": []
},
}
The seq
attribute indicates the revision this service is currently at. For each changes that happens with the entity that is published by this service, this sequence number is increased by one. Consumers should keep track of this sequence number, as they are only required to fetch all the changes with a higher number using the since
parameter.
Revisions are not kept forever, they are removed as soon as they are shadowed by a newer revision for the same key
. The key
attribute describes which object this change is about. This means that a consumer actually might miss some changes, but that the end result after synchronization will always be consistent with the publisher.
The url
is the fully qualified url at which this object could be fetched using a GET operation. The etag
value indicates the current version of the object altered by the change. If the deleted
attribute is false, the object has been created or changed, and its actual contents can be found under the data
attribute.
To set up a changelog in your data service, please read the Enabling the change log section.
Retrieving the changes published by a services is as simple as sending a GET request to rest/service-name/changes/list:
+----------+ +-----------+
| | ------ GET /rest/service/changes/list?since=<seq>-----> | |
| consumer | | publisher |
| | <------------- returns list of changes ---------------- | |
+----------+ +-----------+
The since
parameter specifies the last change the consumer already knows. If no changes has been received before, use '0'. Further parameters are described in greater detail in the generated service description.
A second endpoint available for retrieving changes is rest/service-name/changes/feed. This service yields the same results as the list service, except that the HTTP request does not end after all known changes are send. Rather, the connection is kept open so that new changes can be pushed back to the consumer in real time. If the connection is closed for any reason the consumer should try to reconnect automatically.
The RestServices module provides several methods to consume a changelog published by another app. Those can be found in the CONSUME/Change Tracking
folder. Note that for all these functions only the collection URL needs to be specified (for example: http://app/rest/tasks). Furthermore the module automatically tracks which changes have been received already, so there is no need to specify the since
parameter.
fetchChanges
: Requests recent changes for a certain collection using the list API. The updateMicroflow should have one parameter of some transient object type. The microflow will be called for each change and the parameter will be initialized by deserializing thedata
field of the change. The deleteMicroflow should have a string parameter, which will be initialized to the key of the object to be deleted.followChanges
: Similar tofetchChanges
. Requests recent changes and start listening for new incoming changes using the feed API.unfollowChanges
: Stop listing to changesresetChangeTracking
: Resets the last know sequence number to zero. This means that upon the next synchronization, all data will be retrieved again.
The state of the change log can be viewed in the RestServices overview form, both as consumer and as publisher.
The JSON serialization process starts with a (preferably) transient object and converts it into a JSON structure as follows:
- Given a transient object, a new JSON object is created (
{}
) - Each of its primitives members is added as key value pair to the JSON object. The 'nearest' json type is used, for example integers and longs are turned into numbers, booleans in to booleans and the others into strings (or
null
values). For example:{ "task" : 17, "description" : "Buy milk" }
. Decimals are serialized as string to preserve precision. For a numeric presentation please use the Mendix float attribute type. - For each owned reference that points to a transient object, another key/value pair is added to the object. As key the name of the reference is used, but excluding the module name. As value either
null
is used if the reference is not set, or the child object is serialized into a JSON object as well, using this very same procedure. - For each owned referenceset that points to a transient object, the same approach is taken, except that the value is an array (
[]
) to which each serialized child object is added. - If an owned reference(set) points to a a persistent object the reference is not serialized, unless a data services is defined for the specified entity. In such a case, the url of the referred object is determined and added to the result.
- For file documents special serialization rules apply. See the working with files section for details
For example the following domain model results in the JSON object listed below, assuming that the serialization process is started with an OrderView instance:
{
"Nr": 1,
"Total": 9.4,
"OrderCustomer": "http://localhost:8080/rest/customers/3",
"OrderLines": [
{
"Description": "Coffee Biscuits 36pcs",
"Amount": 2,
"Price": 0.89
},
{
"Description": "Dark Coffee 36pads Limited Edition",
"Amount": 3,
"Price": 2.54
}
]
}
It is possible to manually trigger the serialization process by using the serializeObjectToJson
java action.
Some API's that are consumed might require attribute names that would not be valid in Mendix. For example an API might require an attibute that is called id
or my-profile-url
. To override the default name under which a member is serialized, add an additional member to the Mendix object that has the exact same name as the member you want to serialize, but appended with _jsonkey
. The value of this attribute should be a string and contain the name under which you want to serialize. This works for assocations as well (but note that the module name of the association should be skipped).
For example an object with the following attibutes and values:
- attribute
_id
with value "3" - attribute `_id_jsonkey with value "id"
- attribute
profileUrl
with value "https://github.com/mweststrate" - attribute
profileUrl_jsonkey
with value "my-profile-url"
Will result in the following JSON:
{ id : 3, my-profile-url : "https://github.com/mweststrate" }
The JSON deserialization process is the inverse of the serialization process and can be triggered manually by calling deserializeJsonToObject
. The process always starts with a freshly created transient object (the target) and the JSON structure as string. The root of the JSON structure should always be an JSON object (for arrays, see the getCollection
method). The parse process then starts as follows:
- For each primitive key/value pair in the JSON object, a matching (see below) primitive attribute is searched in the transient object. If found, the value is parsed and set.
- If the primitive is of type string, but the member with the same name in the transient object is a reference, the process assumes that the string value represents an url. The url is then fetched using a GET request and its result is also interpreted as JSON and deserialized. The resulting object is assigned to the reference.
- If the member in the target object is a reference, and the value is a JSON object, a new object of the child type of the reference is instantiated, and the JSON value is parsed into that object; which then is stored in the references.
- If the member in the target object is a referenceset, and the value is a JSON array of JSON objects, well, that works the same as a mentioned in 3. but then a complete referenceset is filled.
- If you need to parse a JSON array of primitive values, use a referenceset that has as child
RestServices.Primitive
. These objects can hold a JSON primitive and allows to create primitive lists which don't exist natively in Mendix.
A member name matches if the names are the same in a case insensitive way. The module will also look for attributes that have an additional underscore (_
) as prefix. This is to be able to prevent name collisions with references and to be able to use attributes with a name that are reserved within Mendix. Furthermore, if the characters -
or $
are used in json (or any other strange characters that are not allowed in Mendix field names), this maps to the _
underscore character in the Mendix attribute name. For associations, the module name is never considered. Pro tip: fill these properties with the proper default value.
Some examples:
- The json key
count
maps to the Mendix attributescount
and_count
- The json key
id
maps to the Mendix attribute_id
(sinceid
is reserved in Mendix) - The json key
my super dooper complex @#-$#$% key
maps to the Mendix attributemy_super_dooper_complex_________key
For example https://www.rijksmuseum.nl/api/en/collection/?key=XXXXX&format=json&q=geertgen
generates the following JSON (shortened a bit for readability) which can be parsed into the domain model as shown below, assuming that parsing starts with an instance of the Query
entity. Note that only some specific attributes of interest are made part of the domain model.
{
"elapsedMilliseconds": 51,
"count": 9,
"artObjects": [
{
"links": {
"self": "https://www.rijksmuseum.nl/api/en/collection/SK-A-2150",
"web": "https://www.rijksmuseum.nl/en/collection/SK-A-2150"
},
"id": "en-SK-A-2150",
"title": "The Adoration of the Magi",
"hasImage": true,
"principalOrFirstMaker": "Geertgen tot Sint Jans",
"longTitle": "The Adoration of the Magi, Geertgen tot Sint Jans, c. 1480 - c. 1485",
"webImage": {
"guid": "9b0a55b9-5bf9-4670-9a24-929d076b5bd1",
"width": 1929,
"height": 2500,
"url": "http://lh6.ggpht.com/JE0o7Cgs3kKT5wDAR0Ks32zuTZUulpAcJFwTFNNJMJ6ENOVL3PE1MaKUEmFP-kdTqxXlDGtlNIZrryxe10G8g3mm_Q=s0"
},
"headerImage": {
"guid": "93364abc-e6a2-476b-aa07-197cd90b0dda",
"offsetPercentageX": 50,
"offsetPercentageY": 50,
"width": 1920,
"height": 460,
"url": "http://lh5.ggpht.com/4go9ib-06Mq5jHS2RltLrwhsE1-0TKBx2PnfDjzPIyCL7kcbMc_8aNpng7lHipgPBwBJNbL95WohglA-KkK2avtGczsY=s0"
},
"productionPlaces": [
"Haarlem"
]
}
]
}
When it comes to deserializing attributes for incoming objects (in, for example, a microflow service), attributes will keep their default values from the domain model if they are lacking in the input. For some primitive types this can be confusing, especially for booleans. For booleans, you can use the RestServices.BooleanValue
enumeration to be able to distinguish the absence of a value in your transient object, by putting the default value to empty.
It is possible to send or receive files using the RestServices module. To publish an operation that supports binary data you can define a microflow service which input or output argument (or both) inherits from a System.FileDocument
. If the input parameter is a filedocument, it interprets requests with Content-Type: multipart/form-data
correctly if there is one part that contains binary data. The other form data parameters can be picked up if a similarly named attribute is present in the type of the input argument. If the return type of a microflow service is a filedocument, the binary contents is streamed in raw format to the consumer, using Content-Type: application/octet-stream
.
It is possible to send binary data using the post
java action. If the submitAsFormData
parameter is set, the file is send using Content-Type: multipart/form-data
, and other attributes of the filedocument are included as well as form parts. If the root object has references to other filedocuments, each of the referred file documents will be added as part to the multipart request. The part name will equal the reference name. This way it is possible to send multiple files with a single request.
If submitAsFormData
is set to false, the contents of the filedocument is streamed raw in the request body to the publisher. Any other attributes in the filedocument are added as request parameters to the target url.
If the consumed service responds with binary data, this is picked up properly by the generic request
java action if the optResponseData
parameter inherits from System.FileDocument.
Sends a cookie along with the next request that will be made
Sends a username / password combination along with the next request, using Basic authentication.
Sends a header along with the next request.
Sends an If-None-Match header along with the next request, to compare an ETag from a cache with the latest version on the server. Data services published with the Rest Services module support the ETag mechanism out of the box.
Delete an object on a remote service by permorming a HTTP DELETE request
Fetches any missing changes from a remote collection (published by a change-tracking enabled data service) that is being tracked by this app.
Fetches any missing changes from a remote collection (published by a change-tracking enabled data service) that is being tracked by this app and keeps the connection open to listen to any new incoming changes.
Fetches a (JSON) resource from a remote server by performing a HTTP GET request.
See get
, but automatically converts request data into URL parameters.
Fetches a collection from a remote server by performing a HTTP GET request. In contrast to get
, getCollection excpects an JSON array instead of a JSON object as response.
See getCollection
. The Async
variation is suitable for very large collections which might not fit in memory otherwise. Each item of the collection will be streamed, parsed and processed by a callback to minimize memory consumption.
Returns a list of cookies that where set by the remote server as part of the response to the latest request.
Returns a specific header that was set by the remote server as part of the response to the latest request.
Returns the meta data and response body of the latest (failed) request.
Adds an object to a remote collection or performs a form post, using HTTP POST.
Adds an object to a remote collection, using HTTP POST, parses the response data into a Mendix object.
Adds/ updates an object in a remote collection using HTTP PUT.
Similar to addCredentialsToNextRequest
, but the credentials will be reused automatically by any subsequent request to the same domain.
Generic method to make a HTTP request. post
, put
, get
, delete
are wrapper methods around this function. Request allows for less common combinations of parameters.
Resets any state information this app has about a remote collection that is being tracked.
Sets settings for all requests that are executed by RestServices module.
maxConcurrentRequest
- number of maximum concurrent requests executed. This will set concurrency level per host. Total concurrency level is double this setting.timeout
- timeout specified in milliseconds. This will set timeout for both establishing connection and waiting between data chunks arrived from server.
Stops tracking a remote collection, which was being followed as result of a followChanges
call.
Registers a new microflow service. The microflow will be available for consumption through the REST module.
Registers a data service. This can be used to open a REST based data service on a part of your domain model.
Returns a list of cookies that was send to this service by the client. Can be used in the context of a microflow or data service.
Returns a header that was send to this service by the client. Can be used in the context of a microflow or data service.
Distributes (possibly real-time using server push) the deletion of an object to all consumers of a data service. Can only be used in combination with data services that has change tracking enabled.
Distributes (possibly real-time using server push) the creation or update of an object to all consumers of a data service. Can only be used in combination with data services that has change tracking enabled.
Sends a cookie to the client using the Set-Cookie
header.
Sets a specific header on the response.
Sets the HTTP response status of a request.
Throws a RestService exception, accepts the following attributes:
- httpStatus: The HTTP status of the request. Has to be between 400 and 599
- errorMessage: The error message
- errorCode: Custom error code for this exception, to make the error easier recognizable and referable.
RestServiceExceptions are compatible with Webservice exceptions, so they can be used safely in microflows that are published through webservices as well.
Appends an url parameter to an url. The method takes care of properly appending the parameter and URL encoding the value.
Appends a forward slash /
to an url, if its not there yet.
Copies similarly named primitive attributes from one object to another.
Returns the base url on which the rest services are published for this app. For example: http://localhost:8080/rest/
Checks whether a string is a valid URL.
Checks whether a value can be used as object key in a data service
Shows an overviw of all data service definitions.
Sets an alternative base path for the RestServices modules. (Default: rest/
). Note that in sandbox deployments, ws-doc/
will be used automatically.
Should be called from the apps startup microflow. Without, no microflow or data service will be served.
Escapes a string in such a way that it can be used as part of an URL.
We know that the RestSevices module has already been used successfully to integrate with the following services:
- Dropbox.com
- Paydro.net
- Postcodeapi.nu
- Rijksmuseum.nl
- Feel free to fork and send pull requests!
- Use the mxgit tool to track and merge changes in the mpr file.
- Note that this is a GitHub repository which is based on git, in contrast to the Mendix TeamServer, which is based on SVN. So the build-in Teamserver support of the Mendix Modeler will not work for this repository!
- If you want to receive access to the Mendix Project in which this module is managed, feel to request me an invite! The backlog of the project is also managed there.
- Unit tests are defined in the Tests module. Those can be run in the usual way using the already included UnitTesting module
How does REST Services relate to Mendix Webservices and Mendix AppServices? Mendix Webservices are the de-facto integration method. Webservices are well supported in the Mendix Modeler and allow you to publish and consume operations. Webservices rely on the WSDL / SOAP standards for definition and transport.
Mendix Appservices are build on top of webservices and make integration between Mendix Apps easier. They allow you to skip object mappings and provide an API versioning system.
RestServices allows you to consume and publish operations as well, but based on the JSON standard and REST principles. Besides JSON, the module also provides full support for form-encoded, multipart and binary data transfer, allowing the module the integrate with almost any REST service.
It is also possible do share data using RestServices as the module generates REST based crud operations for your data and (real-time) synchronization strategies.
See the table at http://en.wikipedia.org/wiki/Representational_state_transfer#Applied_to_web_services to get an idea how the get
, put
, post
and delete
verbs should be used in combination with rest. The RestServices module respects these best practices as well.
See the table at [http://en.wikipedia.org/wiki/Representational_state_transfer#Applied_to_web_services](http://en.wikipedia.org/wiki/Representational_state_transfer#Applied_to_web_services