On 10-11-2006 07:08, Paul Moore wrote: ... > An Introduction To Using Generic Netlink > =============================================================================== ...
Here is a proposal of small adjustments. Maybe some of them will be useful. Best regards, Jarek P. --- --- netlink.txt- 2006-11-10 10:53:50.000000000 +0100 +++ netlink.txt 2006-11-10 14:08:25.000000000 +0100 @@ -32,7 +32,7 @@ 1.1. Document Overview ------------------------------------------------------------------------------ -This document gives is a brief introduction to Generic Netlink, some simple +This document gives a brief introduction to Generic Netlink, some simple examples on how to use it, and some recommendations on how to make the most of the Generic Netlink communications interface. While this document does not require that the reader have a detailed understanding of what Netlink is @@ -55,21 +55,21 @@ channels are associated with families or "busses", where each bus deals with a specific service; for example, different Netlink busses exist for routing, XFRM, netfilter, and several other kernel subsystems. More information about -Netlink can be found in RFC 3549[1]. +Netlink can be found in RFC 3549[2]. Over the years, Netlink has become very popular which has brought about a very real concern that the number of Netlink family numbers may be exhausted in the near future. In response to this the Generic Netlink family was created which -acts as a Netlink multiplexer, allowing multiple service to use a single +acts as a Netlink multiplexer, allowing multiple services to use a single Netlink bus. -[1] ftp://ftp.rfc-editor.org/in-notes/rfc3549.txt +[2] ftp://ftp.rfc-editor.org/in-notes/rfc3549.txt 2. Architectural Overview ------------------------------------------------------------------------------ -Figure #1 illustrates how the basic Generic Netlink architecture which is -composed of five different types of components. +Figure #1 illustrates the basic Generic Netlink architecture which is +composed of five different types of components: 1) The Netlink subsystem which serves as the underlying transport layer for all of the Generic Netlink communications. @@ -99,7 +99,7 @@ | | +-------+--------------------------------+-------+ | : : | user-space - =====+ : (5) Kernel socket API : +================ + =====+ : (5) kernel socket API : +================ | : : | kernel-space +--------+-------------------------------+-------+ | | @@ -112,7 +112,7 @@ +--+--------------------------+-------+----+ | | | +-------+---------+ | | - | (4) Controller | / \ + | (4) controller | / \ +-----------------+ / \ | | +------------------+--+ +--+------------------+ @@ -149,7 +149,7 @@ 3.1. Family Overview ------------------------------------------------------------------------------ -Generic Netlink family service registrations are defined by two structures, +Generic Netlink family service registrations are defined by two structures: genl_family and genl_ops. The genl_family structure defines the family and it's associated communication channel. The genl_ops structure defines an individual service or operation which the family provides to other Generic @@ -161,7 +161,7 @@ [1] http://people.suug.ch/~tgr/libnl -3.1.2. The genl_family Structure +3.1.1. The genl_family Structure Generic Netlink services are defined by the genl_family structure, which is shown below: @@ -241,7 +241,7 @@ * unsigned int flags This field is used to specify any special attributes of the operation. The - following flags may be used, multiple flags can be OR'd together: + following flags may be used (multiple flags can be OR'd together): - GENL_ADMIN_PERM @@ -251,11 +251,12 @@ This field defines the Netlink attribute policy for the operation request message. If specified, the Generic Netlink mechanism uses this policy to - verify all of the attributes in a operation request message before calling + verify all of the attributes in an operation request message before calling the operation handler. The attribute policy is defined as an array of nla_policy structures indexed - by the attribute number. The nla_policy structure is defined in figure #4. + by the attribute number. The nla_policy structure is defined as shown in + figure #4. struct nla_policy { @@ -269,7 +270,7 @@ - u16 type - This specifies the type of the attribute, presently the following types + This specifies the type of the attribute; presently the following types are defined for general use: o NLA_UNSPEC @@ -278,7 +279,7 @@ o NLA_U8 - A 8 bit unsigned integer + An 8 bit unsigned integer o NLA_U16 @@ -327,11 +328,11 @@ This callback is similar in use to the standard Netlink 'doit' callback, the primary difference being the change in parameters. - The 'doit' handler receives two parameters, the first if the message buffer + The 'doit' handler receives two parameters: the first is the message buffer which triggered the handler and the second is a Generic Netlink genl_info - structure which is defined in figure #5. + structure which is defined as shown in figure #5. - struct genl_ops + struct genl_info { u32 snd_seq; u32 snd_pid; @@ -368,12 +369,12 @@ - struct nlattr **attrs - The parsed Netlink attributes from the request, if the Generic Netlink + The parsed Netlink attributes from the request; if the Generic Netlink family definition specified a Netlink attribute policy then the - attributes will have already been validated. + attributes would have already been validated. The 'doit' handler should do whatever processing is necessary and return - zero on success, or a negative value on failure. Negative return values + zero on success or a negative value on failure. Negative return values will cause a NLMSG_ERROR message to be sent while a zero return value will only cause a NLMSG_ERROR message to be sent if the request is received with the NLM_F_ACK flag set. @@ -392,7 +393,7 @@ i.e. sk_buff->len, and the message buffer will automatically be sent to the Generic Netlink client that initiated the request. As long as the 'dumpit' handler returns a value greater than zero it will be called again with a - newly allocated message buffer to fill, when the handler has no more data + newly allocated message buffer to fill. When the handler has no more data to send it should return zero; error conditions are indicated by returning a negative value. If necessary, state can be preserved in the netlink_callback parameter which is passed to the 'dumpit' handler; the @@ -412,7 +413,7 @@ and explained in detail. The first step is to define the family itself, which we do by creating an -instance of the genl_family structure which we explained in section 3.1.1.. +instance of the genl_family structure which we explained in section 3.1.1. In our simple example we are going to create a new Generic Netlink family named "DOC_EXMPL". @@ -436,7 +437,6 @@ .name = "DOC_EXMPL", .version = 1, .maxattr = DOC_EXMPL_A_MAX, - }; Figure 6: The DOC_EXMPL family, attributes, and policy @@ -449,7 +449,7 @@ The second step is to define the operations for the family, which we do by creating at least one instance of the genl_ops structure which we explained in -section 3.1.2.. In this example we are only going to define one operation but +section 3.1.2. In this example we are only going to define one operation but you can define up to 255 unique operations for each family. /* handler */ @@ -465,7 +465,7 @@ DOC_EXMPL_C_ECHO, __DOC_EXMPL_C_ECHO, }; - #define DOC_EXMPL_C_MAX (__DOC_EXMPL_C_MAX - 1) + #define DOC_EXMPL_C_MAX (__DOC_EXMPL_C_ECHO - 1) /* operation definition */ struct genl_ops doc_exmpl_gnl_ops_echo = { @@ -492,7 +492,7 @@ This call registers the new family name with the Generic Netlink mechanism and requests a new channel number which is stored in the genl_family struct, replacing the GENL_ID_GENERATE value. It is important to remember to -unregister Generic Netlink families when done as the kernel does allocate +unregister Generic Netlink families when done, as the kernel does allocate resources for each registered family. The fourth and final step is to register the operations for the family. Once @@ -501,7 +501,7 @@ genl_register_ops(&doc_exmpl_gnl_family, &doc_exmpl_gnl_ops_echo); This call registers the DOC_EXMPL_C_ECHO operation in association with the -DOC_EXMPL family. The process is now complete, other Generic Netlink users can +DOC_EXMPL family. The process is now complete. Other Generic Netlink users can now issue DOC_EXMPL_C_ECHO commands and they will be handled as desired. 4. Generic Netlink Communications @@ -515,8 +515,8 @@ Generic Netlink uses the standard Netlink subsystem as a transport layer which means that the foundation of the Generic Netlink message is the standard -Netlink message format, the only difference is the inclusion of a Generic -Netlink message header. The format of the message is defined below: +Netlink message format - the only difference is the inclusion of a Generic +Netlink message header. The format of the message is defined as shown below: 0 1 2 3 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 @@ -540,11 +540,11 @@ 4.2 Kernel Communication ------------------------------------------------------------------------------ -The kernel provides two sets of interfaces for sending, receiving, and +The kernel provides two sets of interfaces for sending, receiving and processing Generic Netlink messages. The majority of the API consists of the general purpose Netlink interfaces, however, there are a small number of -interfaces specific to Generic Netlink. The following two include files -define the Netlink and Generic Netlink API for the kernel. +interfaces specific to Generic Netlink. The following two 'include' files +define the Netlink and Generic Netlink API for the kernel: * include/net/netlink.h * include/net/genetlink.h @@ -556,7 +556,7 @@ demonstrate these steps below is a simple example using the DOC_EXMPL family shown in section 3. -The first step is to allocate a Netlink message buffer, the easiest way to do +The first step is to allocate a Netlink message buffer; the easiest way to do this is with the nlsmsg_new() function. struct sk_buff *skb; @@ -573,7 +573,7 @@ the Netlink and Generic Netlink message headers. The second step is to actually create the message payload. This is obviously -something which is very specific to each use service, but a simple example is +something which is very specific to each used service, but a simple example is shown below. int rc; @@ -643,7 +643,7 @@ as a result there are many different ways it can be used. The following recommendations are based on conventions within the Linux kernel and should be followed whenever possible. While not all existing kernel code follows the -recommendations outlined here all new code should consider these +recommendations outlined here, all new code should consider these recommendations as requirements. 5.1. Attributes And Message Payloads @@ -681,7 +681,7 @@ ------------------------------------------------------------------------------ While it may be tempting to register a single operation for a Generic Netlink -family and multiplex multiple sub-commands on the single operation this +family and multiplex multiple sub-commands on the single operation, this is strongly discouraged for security reasons. Combining multiple behaviors into one operation makes it difficult to restrict the operations using the existing Linux kernel security mechanisms. - To unsubscribe from this list: send the line "unsubscribe netdev" in the body of a message to [EMAIL PROTECTED] More majordomo info at http://vger.kernel.org/majordomo-info.html
