doc/connectivity/networking/api/coap.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _coap_sock_interface:

 CoAP
 #####

 .. contents::
     :local:
     :depth: 2

 Overview
 ********

 The Constrained Application Protocol (CoAP) is a specialized web transfer
 protocol for use with constrained nodes and constrained (e.g., low-power,
 lossy) networks. It provides a convenient API for RESTful Web services
 that support CoAP's features. For more information about the protocol
 itself, see `IETF RFC7252 The Constrained Application Protocol <https://tools.ietf.org/html/rfc7252>`_.

 Zephyr provides a CoAP library which supports client and server roles.
 The library is configurable as per user needs. The Zephyr CoAP library
 is implemented using plain buffers. Users of the API create sockets
 for communication and pass the buffer to the library for parsing and other
 purposes. The library itself doesn't create any sockets for users.

 On top of CoAP, Zephyr has support for LWM2M "Lightweight Machine 2 Machine"
 protocol, a simple, low-cost remote management and service enablement mechanism.
 See :ref:`lwm2m_interface` for more information.

 Supported RFCs:

 Supported RFCs:

 - `RFC7252: The Constrained Application Protocol (CoAP) <https://tools.ietf.org/html/rfc7252>`_
 - `RFC6690: Constrained RESTful Environments (CoRE) Link Format <https://tools.ietf.org/html/rfc6690>`_
 - `RFC7959: Block-Wise Transfers in the Constrained Application Protocol (CoAP) <https://tools.ietf.org/html/rfc7959>`_
 - `RFC7641: Observing Resources in the Constrained Application Protocol (CoAP) <https://tools.ietf.org/html/rfc7641>`_

 .. note:: Not all parts of these RFCs are supported. Features are supported based on Zephyr requirements.

 Sample Usage
 ************

 CoAP Server
 ===========

 To create a CoAP server, resources for the server need to be defined.
 The ``.well-known/core`` resource should be added before all other
 resources that should be included in the responses of the ``.well-known/core``
 resource.

 .. code-block:: c

     static struct coap_resource resources[] = {
         { .get = well_known_core_get,
           .path = COAP_WELL_KNOWN_CORE_PATH,
         },
         { .get  = sample_get,
           .post = sample_post,
           .del  = sample_del,
           .put  = sample_put,
           .path = sample_path
         },
         { },
     };

 An application reads data from the socket and passes the buffer to the CoAP library
 to parse the message. If the CoAP message is proper, the library uses the buffer
 along with resources defined above to call the correct callback function
 to handle the CoAP request from the client. It's the callback function's
 responsibility to either reply or act according to CoAP request.

 .. code-block:: c

     coap_packet_parse(&request, data, data_len, options, opt_num);
     ...
     coap_handle_request(&request, resources, options, opt_num,
                         client_addr, client_addr_len);

 If :kconfig:option:`CONFIG_COAP_URI_WILDCARD` enabled, server may accept multiple resources
 using MQTT-like wildcard style:

 - the plus symbol represents a single-level wild card in the path;
 - the hash symbol represents the multi-level wild card in the path.

 .. code-block:: c

     static const char * const led_set[] = { "led","+","set", NULL };
     static const char * const btn_get[] = { "button","#", NULL };
     static const char * const no_wc[] = { "test","+1", NULL };

 It accepts /led/0/set, led/1234/set, led/any/set, /button/door/1, /test/+1,
 but returns -ENOENT for /led/1, /test/21, /test/1.

 This option is enabled by default, disable it to avoid unexpected behaviour
 with resource path like '/some_resource/+/#'.

 CoAP Client
 ===========

 If the CoAP client knows about resources in the CoAP server, the client can start
 prepare CoAP requests and wait for responses. If the client doesn't know
 about resources in the CoAP server, it can request resources through
 the ``.well-known/core`` CoAP message.

 .. code-block:: c

     /* Initialize the CoAP message */
     char *path = "test";
     struct coap_packet request;
     uint8_t data[100];
     uint8_t payload[20];

     coap_packet_init(&request, data, sizeof(data),
                      1, COAP_TYPE_CON, 8, coap_next_token(),
                      COAP_METHOD_GET, coap_next_id());

     /* Append options */
     coap_packet_append_option(&request, COAP_OPTION_URI_PATH,
                               path, strlen(path));

     /* Append Payload marker if you are going to add payload */
     coap_packet_append_payload_marker(&request);

     /* Append payload */
     coap_packet_append_payload(&request, (uint8_t *)payload,
                                sizeof(payload) - 1);

     /* send over sockets */

 Testing
 *******

 There are various ways to test Zephyr CoAP library.

 libcoap
 =======
 libcoap implements a lightweight application-protocol for devices that are
 resource constrained, such as by computing power, RF range, memory, bandwidth,
 or network packet sizes. Sources can be found here `libcoap <https://github.com/obgm/libcoap>`_.
 libcoap has a script (``examples/etsi_coaptest.sh``) to test coap-server functionality
 in Zephyr.

 See the `net-tools <https://github.com/zephyrproject-rtos/net-tools>`_ project for more details

 The :ref:`coap-server-sample` sample can be built and executed on QEMU as described
 in :ref:`networking_with_qemu`.

 Use this command on the host to run the libcoap implementation of
 the ETSI test cases:

 .. code-block:: console

    sudo ./libcoap/examples/etsi_coaptest.sh -i tap0 2001:db8::1

 TTCN3
 =====
 Eclipse has TTCN3 based tests to run against CoAP implementations.

 Install eclipse-titan and set symbolic links for titan tools

 .. code-block:: console

     sudo apt-get install eclipse-titan

     cd /usr/share/titan

     sudo ln -s /usr/bin bin
     sudo ln /usr/bin/titanver bin
     sudo ln -s /usr/bin/mctr_cli bin
     sudo ln -s /usr/include/titan include
     sudo ln -s /usr/lib/titan lib

     export TTCN3_DIR=/usr/share/titan

     git clone https://github.com/eclipse/titan.misc.git

     cd titan.misc

 Follow the instruction to setup CoAP test suite from here:

 - https://github.com/eclipse/titan.misc
 - https://github.com/eclipse/titan.misc/tree/master/CoAP_Conf

 After the build is complete, the :ref:`coap-server-sample` sample can be built
 and executed on QEMU as described in :ref:`networking_with_qemu`.

 Change the client (test suite) and server (Zephyr coap-server sample) addresses
 in coap.cfg file as per your setup.

 Execute the test cases with following command.

 .. code-block:: console

    ttcn3_start coaptests coap.cfg

 Sample output of ttcn3 tests looks like this.

 .. code-block:: console

    Verdict statistics: 0 none (0.00 %), 10 pass (100.00 %), 0 inconc (0.00 %), 0 fail (0.00 %), 0 error (0.00 %).
    Test execution summary: 10 test cases were executed. Overall verdict: pass

 API Reference
 *************

 .. doxygengroup:: coap
	.. _coap_sock_interface:

	CoAP
	#####

	.. contents::
	:local:
	:depth: 2

	Overview
	********

	The Constrained Application Protocol (CoAP) is a specialized web transfer
	protocol for use with constrained nodes and constrained (e.g., low-power,
	lossy) networks. It provides a convenient API for RESTful Web services
	that support CoAP's features. For more information about the protocol
	itself, see `IETF RFC7252 The Constrained Application Protocol <https://tools.ietf.org/html/rfc7252>`_.

	Zephyr provides a CoAP library which supports client and server roles.
	The library is configurable as per user needs. The Zephyr CoAP library
	is implemented using plain buffers. Users of the API create sockets
	for communication and pass the buffer to the library for parsing and other
	purposes. The library itself doesn't create any sockets for users.

	On top of CoAP, Zephyr has support for LWM2M "Lightweight Machine 2 Machine"
	protocol, a simple, low-cost remote management and service enablement mechanism.
	See :ref:`lwm2m_interface` for more information.

	Supported RFCs:

	Supported RFCs:

	- `RFC7252: The Constrained Application Protocol (CoAP) <https://tools.ietf.org/html/rfc7252>`_
	- `RFC6690: Constrained RESTful Environments (CoRE) Link Format <https://tools.ietf.org/html/rfc6690>`_
	- `RFC7959: Block-Wise Transfers in the Constrained Application Protocol (CoAP) <https://tools.ietf.org/html/rfc7959>`_
	- `RFC7641: Observing Resources in the Constrained Application Protocol (CoAP) <https://tools.ietf.org/html/rfc7641>`_

	.. note:: Not all parts of these RFCs are supported. Features are supported based on Zephyr requirements.

	Sample Usage
	************

	CoAP Server
	===========

	To create a CoAP server, resources for the server need to be defined.
	The ``.well-known/core`` resource should be added before all other
	resources that should be included in the responses of the ``.well-known/core``
	resource.

	.. code-block:: c

	static struct coap_resource resources[] = {
	{ .get = well_known_core_get,
	.path = COAP_WELL_KNOWN_CORE_PATH,
	},
	{ .get = sample_get,
	.post = sample_post,
	.del = sample_del,
	.put = sample_put,
	.path = sample_path
	},
	{ },
	};

	An application reads data from the socket and passes the buffer to the CoAP library
	to parse the message. If the CoAP message is proper, the library uses the buffer
	along with resources defined above to call the correct callback function
	to handle the CoAP request from the client. It's the callback function's
	responsibility to either reply or act according to CoAP request.

	.. code-block:: c

	coap_packet_parse(&request, data, data_len, options, opt_num);
	...
	coap_handle_request(&request, resources, options, opt_num,
	client_addr, client_addr_len);

	If :kconfig:option:`CONFIG_COAP_URI_WILDCARD` enabled, server may accept multiple resources
	using MQTT-like wildcard style:

	- the plus symbol represents a single-level wild card in the path;
	- the hash symbol represents the multi-level wild card in the path.

	.. code-block:: c

	static const char * const led_set[] = { "led","+","set", NULL };
	static const char * const btn_get[] = { "button","#", NULL };
	static const char * const no_wc[] = { "test","+1", NULL };

	It accepts /led/0/set, led/1234/set, led/any/set, /button/door/1, /test/+1,
	but returns -ENOENT for /led/1, /test/21, /test/1.

	This option is enabled by default, disable it to avoid unexpected behaviour
	with resource path like '/some_resource/+/#'.

	CoAP Client
	===========

	If the CoAP client knows about resources in the CoAP server, the client can start
	prepare CoAP requests and wait for responses. If the client doesn't know
	about resources in the CoAP server, it can request resources through
	the ``.well-known/core`` CoAP message.

	.. code-block:: c

	/* Initialize the CoAP message */
	char *path = "test";
	struct coap_packet request;
	uint8_t data[100];
	uint8_t payload[20];

	coap_packet_init(&request, data, sizeof(data),
	1, COAP_TYPE_CON, 8, coap_next_token(),
	COAP_METHOD_GET, coap_next_id());

	/* Append options */
	coap_packet_append_option(&request, COAP_OPTION_URI_PATH,
	path, strlen(path));

	/* Append Payload marker if you are going to add payload */
	coap_packet_append_payload_marker(&request);

	/* Append payload */
	coap_packet_append_payload(&request, (uint8_t *)payload,
	sizeof(payload) - 1);

	/* send over sockets */

	Testing
	*******

	There are various ways to test Zephyr CoAP library.

	libcoap
	=======
	libcoap implements a lightweight application-protocol for devices that are
	resource constrained, such as by computing power, RF range, memory, bandwidth,
	or network packet sizes. Sources can be found here `libcoap <https://github.com/obgm/libcoap>`_.
	libcoap has a script (``examples/etsi_coaptest.sh``) to test coap-server functionality
	in Zephyr.

	See the `net-tools <https://github.com/zephyrproject-rtos/net-tools>`_ project for more details

	The :ref:`coap-server-sample` sample can be built and executed on QEMU as described
	in :ref:`networking_with_qemu`.

	Use this command on the host to run the libcoap implementation of
	the ETSI test cases:

	.. code-block:: console

	sudo ./libcoap/examples/etsi_coaptest.sh -i tap0 2001:db8::1

	TTCN3
	=====
	Eclipse has TTCN3 based tests to run against CoAP implementations.

	Install eclipse-titan and set symbolic links for titan tools

	.. code-block:: console

	sudo apt-get install eclipse-titan

	cd /usr/share/titan

	sudo ln -s /usr/bin bin
	sudo ln /usr/bin/titanver bin
	sudo ln -s /usr/bin/mctr_cli bin
	sudo ln -s /usr/include/titan include
	sudo ln -s /usr/lib/titan lib

	export TTCN3_DIR=/usr/share/titan

	git clone https://github.com/eclipse/titan.misc.git

	cd titan.misc

	Follow the instruction to setup CoAP test suite from here:

	- https://github.com/eclipse/titan.misc
	- https://github.com/eclipse/titan.misc/tree/master/CoAP_Conf

	After the build is complete, the :ref:`coap-server-sample` sample can be built
	and executed on QEMU as described in :ref:`networking_with_qemu`.

	Change the client (test suite) and server (Zephyr coap-server sample) addresses
	in coap.cfg file as per your setup.

	Execute the test cases with following command.

	.. code-block:: console

	ttcn3_start coaptests coap.cfg

	Sample output of ttcn3 tests looks like this.

	.. code-block:: console

	Verdict statistics: 0 none (0.00 %), 10 pass (100.00 %), 0 inconc (0.00 %), 0 fail (0.00 %), 0 error (0.00 %).
	Test execution summary: 10 test cases were executed. Overall verdict: pass

	API Reference
	*************

	.. doxygengroup:: coap