Documentation/isdn/README.concap - android_kernel_oneplus_sm8150 - Gitiles

 Description of the "concap" encapsulation protocol interface
 ============================================================

 The "concap" interface is intended to be used by network device
 drivers that need to process an encapsulation protocol.
 It is assumed that the protocol interacts with a linux network device by
 - data transmission
 - connection control (establish, release)
 Thus, the mnemonic: "CONnection CONtrolling eNCAPsulation Protocol".

 This is currently only used inside the isdn subsystem. But it might
 also be useful to other kinds of network devices. Thus, if you want
 to suggest changes that improve usability or performance of the
 interface, please let me know. I'm willing to include them in future
 releases (even if I needed to adapt the current isdn code to the
 changed interface).


 Why is this useful?
 ===================

 The encapsulation protocol used on top of WAN connections or permanent
 point-to-point links are frequently chosen upon bilateral agreement.
 Thus, a device driver for a certain type of hardware must support
 several different encapsulation protocols at once.

 The isdn device driver did already support several different
 encapsulation protocols. The encapsulation protocol is configured by a
 user space utility (isdnctrl). The isdn network interface code then
 uses several case statements which select appropriate actions
 depending on the currently configured encapsulation protocol.

 In contrast, LAN network interfaces always used a single encapsulation
 protocol which is unique to the hardware type of the interface. The LAN
 encapsulation is usually done by just sticking a header on the data. Thus,
 traditional linux network device drivers used to process the
 encapsulation protocol directly (usually by just providing a hard_header()
 method in the device structure) using some hardware type specific support
 functions. This is simple, direct and efficient. But it doesn't fit all
 the requirements for complex WAN encapsulations.


    The configurability of the encapsulation protocol to be used
    makes isdn network interfaces more flexible, but also much more
    complex than traditional lan network interfaces.


 Many Encapsulation protocols used on top of WAN connections will not just
 stick a header on the data. They also might need to set up or release
 the WAN connection. They also might want to send other data for their
 private purpose over the wire, e.g. ppp does a lot of link level
 negotiation before the first piece of user data can be transmitted.
 Such encapsulation protocols for WAN devices are typically more complex
 than encapsulation protocols for lan devices. Thus, network interface
 code for typical WAN devices also tends to be more complex.


 In order to support Linux' x25 PLP implementation on top of
 isdn network interfaces I could have introduced yet another branch to
 the various case statements inside drivers/isdn/isdn_net.c.
 This eventually made isdn_net.c even more complex. In addition, it made
 isdn_net.c harder to maintain. Thus, by identifying an abstract
 interface between the network interface code and the encapsulation
 protocol, complexity could be reduced and maintainability could be
 increased.


 Likewise, a similar encapsulation protocol will frequently be needed by
 several different interfaces of even different hardware type, e.g. the
 synchronous ppp implementation used by the isdn driver and the
 asynchronous ppp implementation used by the ppp driver have a lot of
 similar code in them. By cleanly separating the encapsulation protocol
 from the hardware specific interface stuff such code could be shared
 better in future.


 When operating over dial-up-connections (e.g. telephone lines via modem,
 non-permanent virtual circuits of wide area networks, ISDN) many
 encapsulation protocols will need to control the connection. Therefore,
 some basic connection control primitives are supported. The type and
 semantics of the connection (i.e the ISO layer where connection service
 is provided) is outside our scope and might be different depending on
 the encapsulation protocol used, e.g. for a ppp module using our service
 on top of a modem connection a connect_request will result in dialing
 a (somewhere else configured) remote phone number. For an X25-interface
 module (LAPB semantics, as defined in Documentation/networking/x25-iface.txt)
 a connect_request will ask for establishing a reliable lapb
 datalink connection.


 The encapsulation protocol currently provides the following
 service primitives to the network device.

 - create a new encapsulation protocol instance
 - delete encapsulation protocol instance and free all its resources
 - initialize (open) the encapsulation protocol instance for use.
 - deactivate (close) an encapsulation protocol instance.
 - process (xmit) data handed down by upper protocol layer
 - receive data from lower (hardware) layer
 - process connect indication from lower (hardware) layer
 - process disconnect indication from lower (hardware) layer


 The network interface driver accesses those primitives via callbacks
 provided by the encapsulation protocol instance within a
 struct concap_proto_ops.

 struct concap_proto_ops{

 	/* create a new encapsulation protocol instance of same type */
 	struct concap_proto *  (*proto_new) (void);

 	/* delete encapsulation protocol instance and free all its resources.
 	   cprot may no longer be referenced after calling this */
 	void (*proto_del)(struct concap_proto *cprot);

 	/* initialize the protocol's data. To be called at interface startup
 	   or when the device driver resets the interface. All services of the
 	   encapsulation protocol may be used after this*/
 	int (*restart)(struct concap_proto *cprot,
 		       struct net_device *ndev,
 		       struct concap_device_ops *dops);

 	/* deactivate an encapsulation protocol instance. The encapsulation
 	   protocol may not call any *dops methods after this. */
 	int (*close)(struct concap_proto *cprot);

 	/* process a frame handed down to us by upper layer */
 	int (*encap_and_xmit)(struct concap_proto *cprot, struct sk_buff *skb);

 	/* to be called for each data entity received from lower layer*/
 	int (*data_ind)(struct concap_proto *cprot, struct sk_buff *skb);

 	/* to be called when a connection was set up/down.
 	   Protocols that don't process these primitives might fill in
 	   dummy methods here */
 	int (*connect_ind)(struct concap_proto *cprot);
 	int (*disconn_ind)(struct concap_proto *cprot);
 };


 The data structures are defined in the header file include/linux/concap.h.


 A Network interface using encapsulation protocols must also provide
 some service primitives to the encapsulation protocol:

 - request data being submitted by lower layer (device hardware)
 - request a connection being set up by lower layer
 - request a connection being released by lower layer

 The encapsulation protocol accesses those primitives via callbacks
 provided by the network interface within a struct concap_device_ops.

 struct concap_device_ops{

 	/* to request data be submitted by device */
 	int (*data_req)(struct concap_proto *, struct sk_buff *);

 	/* Control methods must be set to NULL by devices which do not
 	   support connection control. */
 	/* to request a connection be set up */
 	int (*connect_req)(struct concap_proto *);

 	/* to request a connection be released */
 	int (*disconn_req)(struct concap_proto *);
 };

 The network interface does not explicitly provide a receive service
 because the encapsulation protocol directly calls netif_rx().


 An encapsulation protocol itself is actually the
 struct concap_proto{
 	struct net_device *net_dev;		/* net device using our service  */
 	struct concap_device_ops *dops; /* callbacks provided by device */
  	struct concap_proto_ops  *pops; /* callbacks provided by us */
 	int flags;
 	void *proto_data;               /* protocol specific private data, to
 					   be accessed via *pops methods only*/
 	/*
 	  :
 	  whatever
 	  :
 	  */
 };

 Most of this is filled in when the device requests the protocol to
 be reset (opend). The network interface must provide the net_dev and
 dops pointers. Other concap_proto members should be considered private
 data that are only accessed by the pops callback functions. Likewise,
 a concap proto should access the network device's private data
 only by means of the callbacks referred to by the dops pointer.


 A possible extended device structure which uses the connection controlling
 encapsulation services could look like this:

 struct concap_device{
 	struct net_device net_dev;
 	struct my_priv  /* device->local stuff */
 			/* the my_priv struct might contain a
 			   struct concap_device_ops *dops;
 	                   to provide the device specific callbacks
 			*/
 	struct concap_proto *cprot;        /* callbacks provided by protocol */
 };


 Misc Thoughts
 =============

 The concept of the concap proto might help to reuse protocol code and
 reduce the complexity of certain network interface implementations.
 The trade off is that it introduces yet another procedure call layer
 when processing the protocol. This has of course some impact on
 performance. However, typically the concap interface will be used by
 devices attached to slow lines (like telephone, isdn, leased synchronous
 lines). For such slow lines, the overhead is probably negligible.
 This might no longer hold for certain high speed WAN links (like
 ATM).


 If general linux network interfaces explicitly supported concap
 protocols (e.g. by a member struct concap_proto* in struct net_device)
 then the interface of the service function could be changed
 by passing a pointer of type (struct net_device*) instead of
 type (struct concap_proto*). Doing so would make many of the service
 functions compatible to network device support functions.

 e.g. instead of the concap protocol's service function

   int (*encap_and_xmit)(struct concap_proto *cprot, struct sk_buff *skb);

 we could have

   int (*encap_and_xmit)(struct net_device *ndev, struct sk_buff *skb);

 As this is compatible to the dev->hard_start_xmit() method, the device
 driver could directly register the concap protocol's encap_and_xmit()
 function as its hard_start_xmit() method. This would eliminate one
 procedure call layer.


 The device's data request function could also be defined as

   int (*data_req)(struct net_device *ndev, struct sk_buff *skb);

 This might even allow for some protocol stacking. And the network
 interface might even register the same data_req() function directly
 as its hard_start_xmit() method when a zero layer encapsulation
 protocol is configured. Thus, eliminating the performance penalty
 of the concap interface when a trivial concap protocol is used.
 Nevertheless, the device remains able to support encapsulation
 protocol configuration.
	Description of the "concap" encapsulation protocol interface
	============================================================

	The "concap" interface is intended to be used by network device
	drivers that need to process an encapsulation protocol.
	It is assumed that the protocol interacts with a linux network device by
	- data transmission
	- connection control (establish, release)
	Thus, the mnemonic: "CONnection CONtrolling eNCAPsulation Protocol".

	This is currently only used inside the isdn subsystem. But it might
	also be useful to other kinds of network devices. Thus, if you want
	to suggest changes that improve usability or performance of the
	interface, please let me know. I'm willing to include them in future
	releases (even if I needed to adapt the current isdn code to the
	changed interface).


	Why is this useful?
	===================

	The encapsulation protocol used on top of WAN connections or permanent
	point-to-point links are frequently chosen upon bilateral agreement.
	Thus, a device driver for a certain type of hardware must support
	several different encapsulation protocols at once.

	The isdn device driver did already support several different
	encapsulation protocols. The encapsulation protocol is configured by a
	user space utility (isdnctrl). The isdn network interface code then
	uses several case statements which select appropriate actions
	depending on the currently configured encapsulation protocol.

	In contrast, LAN network interfaces always used a single encapsulation
	protocol which is unique to the hardware type of the interface. The LAN
	encapsulation is usually done by just sticking a header on the data. Thus,
	traditional linux network device drivers used to process the
	encapsulation protocol directly (usually by just providing a hard_header()
	method in the device structure) using some hardware type specific support
	functions. This is simple, direct and efficient. But it doesn't fit all
	the requirements for complex WAN encapsulations.


	The configurability of the encapsulation protocol to be used
	makes isdn network interfaces more flexible, but also much more
	complex than traditional lan network interfaces.


	Many Encapsulation protocols used on top of WAN connections will not just
	stick a header on the data. They also might need to set up or release
	the WAN connection. They also might want to send other data for their
	private purpose over the wire, e.g. ppp does a lot of link level
	negotiation before the first piece of user data can be transmitted.
	Such encapsulation protocols for WAN devices are typically more complex
	than encapsulation protocols for lan devices. Thus, network interface
	code for typical WAN devices also tends to be more complex.


	In order to support Linux' x25 PLP implementation on top of
	isdn network interfaces I could have introduced yet another branch to
	the various case statements inside drivers/isdn/isdn_net.c.
	This eventually made isdn_net.c even more complex. In addition, it made
	isdn_net.c harder to maintain. Thus, by identifying an abstract
	interface between the network interface code and the encapsulation
	protocol, complexity could be reduced and maintainability could be
	increased.


	Likewise, a similar encapsulation protocol will frequently be needed by
	several different interfaces of even different hardware type, e.g. the
	synchronous ppp implementation used by the isdn driver and the
	asynchronous ppp implementation used by the ppp driver have a lot of
	similar code in them. By cleanly separating the encapsulation protocol
	from the hardware specific interface stuff such code could be shared
	better in future.


	When operating over dial-up-connections (e.g. telephone lines via modem,
	non-permanent virtual circuits of wide area networks, ISDN) many
	encapsulation protocols will need to control the connection. Therefore,
	some basic connection control primitives are supported. The type and
	semantics of the connection (i.e the ISO layer where connection service
	is provided) is outside our scope and might be different depending on
	the encapsulation protocol used, e.g. for a ppp module using our service
	on top of a modem connection a connect_request will result in dialing
	a (somewhere else configured) remote phone number. For an X25-interface
	module (LAPB semantics, as defined in Documentation/networking/x25-iface.txt)
	a connect_request will ask for establishing a reliable lapb
	datalink connection.


	The encapsulation protocol currently provides the following
	service primitives to the network device.

	- create a new encapsulation protocol instance
	- delete encapsulation protocol instance and free all its resources
	- initialize (open) the encapsulation protocol instance for use.
	- deactivate (close) an encapsulation protocol instance.
	- process (xmit) data handed down by upper protocol layer
	- receive data from lower (hardware) layer
	- process connect indication from lower (hardware) layer
	- process disconnect indication from lower (hardware) layer


	The network interface driver accesses those primitives via callbacks
	provided by the encapsulation protocol instance within a
	struct concap_proto_ops.

	struct concap_proto_ops{

	/* create a new encapsulation protocol instance of same type */
	struct concap_proto * (*proto_new) (void);

	/* delete encapsulation protocol instance and free all its resources.
	cprot may no longer be referenced after calling this */
	void (proto_del)(struct concap_proto cprot);

	/* initialize the protocol's data. To be called at interface startup
	or when the device driver resets the interface. All services of the
	encapsulation protocol may be used after this*/
	int (restart)(struct concap_proto cprot,
	struct net_device *ndev,
	struct concap_device_ops *dops);

	/* deactivate an encapsulation protocol instance. The encapsulation
	protocol may not call any dops methods after this. /
	int (close)(struct concap_proto cprot);

	/* process a frame handed down to us by upper layer */
	int (encap_and_xmit)(struct concap_proto cprot, struct sk_buff *skb);

	/* to be called for each data entity received from lower layer*/
	int (data_ind)(struct concap_proto cprot, struct sk_buff *skb);

	/* to be called when a connection was set up/down.
	Protocols that don't process these primitives might fill in
	dummy methods here */
	int (connect_ind)(struct concap_proto cprot);
	int (disconn_ind)(struct concap_proto cprot);
	};


	The data structures are defined in the header file include/linux/concap.h.


	A Network interface using encapsulation protocols must also provide
	some service primitives to the encapsulation protocol:

	- request data being submitted by lower layer (device hardware)
	- request a connection being set up by lower layer
	- request a connection being released by lower layer

	The encapsulation protocol accesses those primitives via callbacks
	provided by the network interface within a struct concap_device_ops.

	struct concap_device_ops{

	/* to request data be submitted by device */
	int (data_req)(struct concap_proto , struct sk_buff *);

	/* Control methods must be set to NULL by devices which do not
	support connection control. */
	/* to request a connection be set up */
	int (connect_req)(struct concap_proto );

	/* to request a connection be released */
	int (disconn_req)(struct concap_proto );
	};

	The network interface does not explicitly provide a receive service
	because the encapsulation protocol directly calls netif_rx().




	An encapsulation protocol itself is actually the
	struct concap_proto{
	struct net_device net_dev; / net device using our service */
	struct concap_device_ops dops; / callbacks provided by device */
	struct concap_proto_ops pops; / callbacks provided by us */
	int flags;
	void proto_data; / protocol specific private data, to
	be accessed via pops methods only/
	/*
	:
	whatever
	:
	*/
	};

	Most of this is filled in when the device requests the protocol to
	be reset (opend). The network interface must provide the net_dev and
	dops pointers. Other concap_proto members should be considered private
	data that are only accessed by the pops callback functions. Likewise,
	a concap proto should access the network device's private data
	only by means of the callbacks referred to by the dops pointer.


	A possible extended device structure which uses the connection controlling
	encapsulation services could look like this:

	struct concap_device{
	struct net_device net_dev;
	struct my_priv /* device->local stuff */
	/* the my_priv struct might contain a
	struct concap_device_ops *dops;
	to provide the device specific callbacks
	*/
	struct concap_proto cprot; / callbacks provided by protocol */
	};



	Misc Thoughts
	=============

	The concept of the concap proto might help to reuse protocol code and
	reduce the complexity of certain network interface implementations.
	The trade off is that it introduces yet another procedure call layer
	when processing the protocol. This has of course some impact on
	performance. However, typically the concap interface will be used by
	devices attached to slow lines (like telephone, isdn, leased synchronous
	lines). For such slow lines, the overhead is probably negligible.
	This might no longer hold for certain high speed WAN links (like
	ATM).


	If general linux network interfaces explicitly supported concap
	protocols (e.g. by a member struct concap_proto* in struct net_device)
	then the interface of the service function could be changed
	by passing a pointer of type (struct net_device*) instead of
	type (struct concap_proto*). Doing so would make many of the service
	functions compatible to network device support functions.

	e.g. instead of the concap protocol's service function

	int (encap_and_xmit)(struct concap_proto cprot, struct sk_buff *skb);

	we could have

	int (encap_and_xmit)(struct net_device ndev, struct sk_buff *skb);

	As this is compatible to the dev->hard_start_xmit() method, the device
	driver could directly register the concap protocol's encap_and_xmit()
	function as its hard_start_xmit() method. This would eliminate one
	procedure call layer.


	The device's data request function could also be defined as

	int (data_req)(struct net_device ndev, struct sk_buff *skb);

	This might even allow for some protocol stacking. And the network
	interface might even register the same data_req() function directly
	as its hard_start_xmit() method when a zero layer encapsulation
	protocol is configured. Thus, eliminating the performance penalty
	of the concap interface when a trivial concap protocol is used.
	Nevertheless, the device remains able to support encapsulation
	protocol configuration.