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Linux/Documentation/userspace-api/netlink/intro.rst

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Diff markup

Differences between /Documentation/userspace-api/netlink/intro.rst (Version linux-6.12-rc7) and /Documentation/userspace-api/netlink/intro.rst (Version linux-6.4.16)


  1 .. SPDX-License-Identifier: BSD-3-Clause            1 .. SPDX-License-Identifier: BSD-3-Clause
  2                                                     2 
  3 =======================                             3 =======================
  4 Introduction to Netlink                             4 Introduction to Netlink
  5 =======================                             5 =======================
  6                                                     6 
  7 Netlink is often described as an ioctl() repla      7 Netlink is often described as an ioctl() replacement.
  8 It aims to replace fixed-format C structures a      8 It aims to replace fixed-format C structures as supplied
  9 to ioctl() with a format which allows an easy       9 to ioctl() with a format which allows an easy way to add
 10 or extended the arguments.                         10 or extended the arguments.
 11                                                    11 
 12 To achieve this Netlink uses a minimal fixed-f     12 To achieve this Netlink uses a minimal fixed-format metadata header
 13 followed by multiple attributes in the TLV (ty     13 followed by multiple attributes in the TLV (type, length, value) format.
 14                                                    14 
 15 Unfortunately the protocol has evolved over th     15 Unfortunately the protocol has evolved over the years, in an organic
 16 and undocumented fashion, making it hard to co     16 and undocumented fashion, making it hard to coherently explain.
 17 To make the most practical sense this document     17 To make the most practical sense this document starts by describing
 18 netlink as it is used today and dives into mor     18 netlink as it is used today and dives into more "historical" uses
 19 in later sections.                                 19 in later sections.
 20                                                    20 
 21 Opening a socket                                   21 Opening a socket
 22 ================                                   22 ================
 23                                                    23 
 24 Netlink communication happens over sockets, a      24 Netlink communication happens over sockets, a socket needs to be
 25 opened first:                                      25 opened first:
 26                                                    26 
 27 .. code-block:: c                                  27 .. code-block:: c
 28                                                    28 
 29   fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_GE     29   fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_GENERIC);
 30                                                    30 
 31 The use of sockets allows for a natural way of     31 The use of sockets allows for a natural way of exchanging information
 32 in both directions (to and from the kernel). T     32 in both directions (to and from the kernel). The operations are still
 33 performed synchronously when applications send     33 performed synchronously when applications send() the request but
 34 a separate recv() system call is needed to rea     34 a separate recv() system call is needed to read the reply.
 35                                                    35 
 36 A very simplified flow of a Netlink "call" wil     36 A very simplified flow of a Netlink "call" will therefore look
 37 something like:                                    37 something like:
 38                                                    38 
 39 .. code-block:: c                                  39 .. code-block:: c
 40                                                    40 
 41   fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_GE     41   fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_GENERIC);
 42                                                    42 
 43   /* format the request */                         43   /* format the request */
 44   send(fd, &request, sizeof(request));             44   send(fd, &request, sizeof(request));
 45   n = recv(fd, &response, RSP_BUFFER_SIZE);        45   n = recv(fd, &response, RSP_BUFFER_SIZE);
 46   /* interpret the response */                     46   /* interpret the response */
 47                                                    47 
 48 Netlink also provides natural support for "dum     48 Netlink also provides natural support for "dumping", i.e. communicating
 49 to user space all objects of a certain type (e     49 to user space all objects of a certain type (e.g. dumping all network
 50 interfaces).                                       50 interfaces).
 51                                                    51 
 52 .. code-block:: c                                  52 .. code-block:: c
 53                                                    53 
 54   fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_GE     54   fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_GENERIC);
 55                                                    55 
 56   /* format the dump request */                    56   /* format the dump request */
 57   send(fd, &request, sizeof(request));             57   send(fd, &request, sizeof(request));
 58   while (1) {                                      58   while (1) {
 59     n = recv(fd, &buffer, RSP_BUFFER_SIZE);        59     n = recv(fd, &buffer, RSP_BUFFER_SIZE);
 60     /* one recv() call can read multiple messa     60     /* one recv() call can read multiple messages, hence the loop below */
 61     for (nl_msg in buffer) {                       61     for (nl_msg in buffer) {
 62       if (nl_msg.nlmsg_type == NLMSG_DONE)         62       if (nl_msg.nlmsg_type == NLMSG_DONE)
 63         goto dump_finished;                        63         goto dump_finished;
 64       /* process the object */                     64       /* process the object */
 65     }                                              65     }
 66   }                                                66   }
 67   dump_finished:                                   67   dump_finished:
 68                                                    68 
 69 The first two arguments of the socket() call r     69 The first two arguments of the socket() call require little explanation -
 70 it is opening a Netlink socket, with all heade     70 it is opening a Netlink socket, with all headers provided by the user
 71 (hence NETLINK, RAW). The last argument is the     71 (hence NETLINK, RAW). The last argument is the protocol within Netlink.
 72 This field used to identify the subsystem with     72 This field used to identify the subsystem with which the socket will
 73 communicate.                                       73 communicate.
 74                                                    74 
 75 Classic vs Generic Netlink                         75 Classic vs Generic Netlink
 76 --------------------------                         76 --------------------------
 77                                                    77 
 78 Initial implementation of Netlink depended on      78 Initial implementation of Netlink depended on a static allocation
 79 of IDs to subsystems and provided little suppo     79 of IDs to subsystems and provided little supporting infrastructure.
 80 Let us refer to those protocols collectively a     80 Let us refer to those protocols collectively as **Classic Netlink**.
 81 The list of them is defined on top of the ``in     81 The list of them is defined on top of the ``include/uapi/linux/netlink.h``
 82 file, they include among others - general netw     82 file, they include among others - general networking (NETLINK_ROUTE),
 83 iSCSI (NETLINK_ISCSI), and audit (NETLINK_AUDI     83 iSCSI (NETLINK_ISCSI), and audit (NETLINK_AUDIT).
 84                                                    84 
 85 **Generic Netlink** (introduced in 2005) allow     85 **Generic Netlink** (introduced in 2005) allows for dynamic registration of
 86 subsystems (and subsystem ID allocation), intr     86 subsystems (and subsystem ID allocation), introspection and simplifies
 87 implementing the kernel side of the interface.     87 implementing the kernel side of the interface.
 88                                                    88 
 89 The following section describes how to use Gen     89 The following section describes how to use Generic Netlink, as the
 90 number of subsystems using Generic Netlink out     90 number of subsystems using Generic Netlink outnumbers the older
 91 protocols by an order of magnitude. There are      91 protocols by an order of magnitude. There are also no plans for adding
 92 more Classic Netlink protocols to the kernel.      92 more Classic Netlink protocols to the kernel.
 93 Basic information on how communicating with co     93 Basic information on how communicating with core networking parts of
 94 the Linux kernel (or another of the 20 subsyst     94 the Linux kernel (or another of the 20 subsystems using Classic
 95 Netlink) differs from Generic Netlink is provi     95 Netlink) differs from Generic Netlink is provided later in this document.
 96                                                    96 
 97 Generic Netlink                                    97 Generic Netlink
 98 ===============                                    98 ===============
 99                                                    99 
100 In addition to the Netlink fixed metadata head    100 In addition to the Netlink fixed metadata header each Netlink protocol
101 defines its own fixed metadata header. (Simila    101 defines its own fixed metadata header. (Similarly to how network
102 headers stack - Ethernet > IP > TCP we have Ne    102 headers stack - Ethernet > IP > TCP we have Netlink > Generic N. > Family.)
103                                                   103 
104 A Netlink message always starts with struct nl    104 A Netlink message always starts with struct nlmsghdr, which is followed
105 by a protocol-specific header. In case of Gene    105 by a protocol-specific header. In case of Generic Netlink the protocol
106 header is struct genlmsghdr.                      106 header is struct genlmsghdr.
107                                                   107 
108 The practical meaning of the fields in case of    108 The practical meaning of the fields in case of Generic Netlink is as follows:
109                                                   109 
110 .. code-block:: c                                 110 .. code-block:: c
111                                                   111 
112   struct nlmsghdr {                               112   struct nlmsghdr {
113         __u32   nlmsg_len;      /* Length of m    113         __u32   nlmsg_len;      /* Length of message including headers */
114         __u16   nlmsg_type;     /* Generic Net    114         __u16   nlmsg_type;     /* Generic Netlink Family (subsystem) ID */
115         __u16   nlmsg_flags;    /* Flags - req    115         __u16   nlmsg_flags;    /* Flags - request or dump */
116         __u32   nlmsg_seq;      /* Sequence nu    116         __u32   nlmsg_seq;      /* Sequence number */
117         __u32   nlmsg_pid;      /* Port ID, se    117         __u32   nlmsg_pid;      /* Port ID, set to 0 */
118   };                                              118   };
119   struct genlmsghdr {                             119   struct genlmsghdr {
120         __u8    cmd;            /* Command, as    120         __u8    cmd;            /* Command, as defined by the Family */
121         __u8    version;        /* Irrelevant,    121         __u8    version;        /* Irrelevant, set to 1 */
122         __u16   reserved;       /* Reserved, s    122         __u16   reserved;       /* Reserved, set to 0 */
123   };                                              123   };
124   /* TLV attributes follow... */                  124   /* TLV attributes follow... */
125                                                   125 
126 In Classic Netlink :c:member:`nlmsghdr.nlmsg_t    126 In Classic Netlink :c:member:`nlmsghdr.nlmsg_type` used to identify
127 which operation within the subsystem the messa    127 which operation within the subsystem the message was referring to
128 (e.g. get information about a netdev). Generic    128 (e.g. get information about a netdev). Generic Netlink needs to mux
129 multiple subsystems in a single protocol so it    129 multiple subsystems in a single protocol so it uses this field to
130 identify the subsystem, and :c:member:`genlmsg    130 identify the subsystem, and :c:member:`genlmsghdr.cmd` identifies
131 the operation instead. (See :ref:`res_fam` for    131 the operation instead. (See :ref:`res_fam` for
132 information on how to find the Family ID of th    132 information on how to find the Family ID of the subsystem of interest.)
133 Note that the first 16 values (0 - 15) of this    133 Note that the first 16 values (0 - 15) of this field are reserved for
134 control messages both in Classic Netlink and G    134 control messages both in Classic Netlink and Generic Netlink.
135 See :ref:`nl_msg_type` for more details.          135 See :ref:`nl_msg_type` for more details.
136                                                   136 
137 There are 3 usual types of message exchanges o    137 There are 3 usual types of message exchanges on a Netlink socket:
138                                                   138 
139  - performing a single action (``do``);           139  - performing a single action (``do``);
140  - dumping information (``dump``);                140  - dumping information (``dump``);
141  - getting asynchronous notifications (``multi    141  - getting asynchronous notifications (``multicast``).
142                                                   142 
143 Classic Netlink is very flexible and presumabl    143 Classic Netlink is very flexible and presumably allows other types
144 of exchanges to happen, but in practice those     144 of exchanges to happen, but in practice those are the three that get
145 used.                                             145 used.
146                                                   146 
147 Asynchronous notifications are sent by the ker    147 Asynchronous notifications are sent by the kernel and received by
148 the user sockets which subscribed to them. ``d    148 the user sockets which subscribed to them. ``do`` and ``dump`` requests
149 are initiated by the user. :c:member:`nlmsghdr    149 are initiated by the user. :c:member:`nlmsghdr.nlmsg_flags` should
150 be set as follows:                                150 be set as follows:
151                                                   151 
152  - for ``do``: ``NLM_F_REQUEST | NLM_F_ACK``      152  - for ``do``: ``NLM_F_REQUEST | NLM_F_ACK``
153  - for ``dump``: ``NLM_F_REQUEST | NLM_F_ACK |    153  - for ``dump``: ``NLM_F_REQUEST | NLM_F_ACK | NLM_F_DUMP``
154                                                   154 
155 :c:member:`nlmsghdr.nlmsg_seq` should be a set    155 :c:member:`nlmsghdr.nlmsg_seq` should be a set to a monotonically
156 increasing value. The value gets echoed back i    156 increasing value. The value gets echoed back in responses and doesn't
157 matter in practice, but setting it to an incre    157 matter in practice, but setting it to an increasing value for each
158 message sent is considered good hygiene. The p    158 message sent is considered good hygiene. The purpose of the field is
159 matching responses to requests. Asynchronous n    159 matching responses to requests. Asynchronous notifications will have
160 :c:member:`nlmsghdr.nlmsg_seq` of ``0``.          160 :c:member:`nlmsghdr.nlmsg_seq` of ``0``.
161                                                   161 
162 :c:member:`nlmsghdr.nlmsg_pid` is the Netlink     162 :c:member:`nlmsghdr.nlmsg_pid` is the Netlink equivalent of an address.
163 This field can be set to ``0`` when talking to    163 This field can be set to ``0`` when talking to the kernel.
164 See :ref:`nlmsg_pid` for the (uncommon) uses o    164 See :ref:`nlmsg_pid` for the (uncommon) uses of the field.
165                                                   165 
166 The expected use for :c:member:`genlmsghdr.ver    166 The expected use for :c:member:`genlmsghdr.version` was to allow
167 versioning of the APIs provided by the subsyst    167 versioning of the APIs provided by the subsystems. No subsystem to
168 date made significant use of this field, so se    168 date made significant use of this field, so setting it to ``1`` seems
169 like a safe bet.                                  169 like a safe bet.
170                                                   170 
171 .. _nl_msg_type:                                  171 .. _nl_msg_type:
172                                                   172 
173 Netlink message types                             173 Netlink message types
174 ---------------------                             174 ---------------------
175                                                   175 
176 As previously mentioned :c:member:`nlmsghdr.nl    176 As previously mentioned :c:member:`nlmsghdr.nlmsg_type` carries
177 protocol specific values but the first 16 iden    177 protocol specific values but the first 16 identifiers are reserved
178 (first subsystem specific message type should     178 (first subsystem specific message type should be equal to
179 ``NLMSG_MIN_TYPE`` which is ``0x10``).            179 ``NLMSG_MIN_TYPE`` which is ``0x10``).
180                                                   180 
181 There are only 4 Netlink control messages defi    181 There are only 4 Netlink control messages defined:
182                                                   182 
183  - ``NLMSG_NOOP`` - ignore the message, not us    183  - ``NLMSG_NOOP`` - ignore the message, not used in practice;
184  - ``NLMSG_ERROR`` - carries the return code o    184  - ``NLMSG_ERROR`` - carries the return code of an operation;
185  - ``NLMSG_DONE`` - marks the end of a dump;      185  - ``NLMSG_DONE`` - marks the end of a dump;
186  - ``NLMSG_OVERRUN`` - socket buffer has overf    186  - ``NLMSG_OVERRUN`` - socket buffer has overflown, not used to date.
187                                                   187 
188 ``NLMSG_ERROR`` and ``NLMSG_DONE`` are of prac    188 ``NLMSG_ERROR`` and ``NLMSG_DONE`` are of practical importance.
189 They carry return codes for operations. Note t    189 They carry return codes for operations. Note that unless
190 the ``NLM_F_ACK`` flag is set on the request N    190 the ``NLM_F_ACK`` flag is set on the request Netlink will not respond
191 with ``NLMSG_ERROR`` if there is no error. To     191 with ``NLMSG_ERROR`` if there is no error. To avoid having to special-case
192 this quirk it is recommended to always set ``N    192 this quirk it is recommended to always set ``NLM_F_ACK``.
193                                                   193 
194 The format of ``NLMSG_ERROR`` is described by     194 The format of ``NLMSG_ERROR`` is described by struct nlmsgerr::
195                                                   195 
196   --------------------------------------------    196   ----------------------------------------------
197   | struct nlmsghdr - response header             197   | struct nlmsghdr - response header          |
198   --------------------------------------------    198   ----------------------------------------------
199   |    int error                                  199   |    int error                               |
200   --------------------------------------------    200   ----------------------------------------------
201   | struct nlmsghdr - original request header     201   | struct nlmsghdr - original request header |
202   --------------------------------------------    202   ----------------------------------------------
203   | ** optionally (1) payload of the request      203   | ** optionally (1) payload of the request   |
204   --------------------------------------------    204   ----------------------------------------------
205   | ** optionally (2) extended ACK                205   | ** optionally (2) extended ACK             |
206   --------------------------------------------    206   ----------------------------------------------
207                                                   207 
208 There are two instances of struct nlmsghdr her    208 There are two instances of struct nlmsghdr here, first of the response
209 and second of the request. ``NLMSG_ERROR`` car    209 and second of the request. ``NLMSG_ERROR`` carries the information about
210 the request which led to the error. This could    210 the request which led to the error. This could be useful when trying
211 to match requests to responses or re-parse the    211 to match requests to responses or re-parse the request to dump it into
212 logs.                                             212 logs.
213                                                   213 
214 The payload of the request is not echoed in me    214 The payload of the request is not echoed in messages reporting success
215 (``error == 0``) or if ``NETLINK_CAP_ACK`` set    215 (``error == 0``) or if ``NETLINK_CAP_ACK`` setsockopt() was set.
216 The latter is common                              216 The latter is common
217 and perhaps recommended as having to read a co    217 and perhaps recommended as having to read a copy of every request back
218 from the kernel is rather wasteful. The absenc    218 from the kernel is rather wasteful. The absence of request payload
219 is indicated by ``NLM_F_CAPPED`` in :c:member:    219 is indicated by ``NLM_F_CAPPED`` in :c:member:`nlmsghdr.nlmsg_flags`.
220                                                   220 
221 The second optional element of ``NLMSG_ERROR``    221 The second optional element of ``NLMSG_ERROR`` are the extended ACK
222 attributes. See :ref:`ext_ack` for more detail    222 attributes. See :ref:`ext_ack` for more details. The presence
223 of extended ACK is indicated by ``NLM_F_ACK_TL    223 of extended ACK is indicated by ``NLM_F_ACK_TLVS`` in
224 :c:member:`nlmsghdr.nlmsg_flags`.                 224 :c:member:`nlmsghdr.nlmsg_flags`.
225                                                   225 
226 ``NLMSG_DONE`` is simpler, the request is neve    226 ``NLMSG_DONE`` is simpler, the request is never echoed but the extended
227 ACK attributes may be present::                   227 ACK attributes may be present::
228                                                   228 
229   --------------------------------------------    229   ----------------------------------------------
230   | struct nlmsghdr - response header             230   | struct nlmsghdr - response header          |
231   --------------------------------------------    231   ----------------------------------------------
232   |    int error                                  232   |    int error                               |
233   --------------------------------------------    233   ----------------------------------------------
234   | ** optionally extended ACK                    234   | ** optionally extended ACK                 |
235   --------------------------------------------    235   ----------------------------------------------
236                                                   236 
237 Note that some implementations may issue custo << 
238 in reply to ``do`` action requests. In that ca << 
239 implementation-specific and may also be absent << 
240                                                << 
241 .. _res_fam:                                      237 .. _res_fam:
242                                                   238 
243 Resolving the Family ID                           239 Resolving the Family ID
244 -----------------------                           240 -----------------------
245                                                   241 
246 This section explains how to find the Family I    242 This section explains how to find the Family ID of a subsystem.
247 It also serves as an example of Generic Netlin    243 It also serves as an example of Generic Netlink communication.
248                                                   244 
249 Generic Netlink is itself a subsystem exposed     245 Generic Netlink is itself a subsystem exposed via the Generic Netlink API.
250 To avoid a circular dependency Generic Netlink    246 To avoid a circular dependency Generic Netlink has a statically allocated
251 Family ID (``GENL_ID_CTRL`` which is equal to     247 Family ID (``GENL_ID_CTRL`` which is equal to ``NLMSG_MIN_TYPE``).
252 The Generic Netlink family implements a comman    248 The Generic Netlink family implements a command used to find out information
253 about other families (``CTRL_CMD_GETFAMILY``).    249 about other families (``CTRL_CMD_GETFAMILY``).
254                                                   250 
255 To get information about the Generic Netlink f    251 To get information about the Generic Netlink family named for example
256 ``"test1"`` we need to send a message on the p    252 ``"test1"`` we need to send a message on the previously opened Generic Netlink
257 socket. The message should target the Generic     253 socket. The message should target the Generic Netlink Family (1), be a
258 ``do`` (2) call to ``CTRL_CMD_GETFAMILY`` (3).    254 ``do`` (2) call to ``CTRL_CMD_GETFAMILY`` (3). A ``dump`` version of this
259 call would make the kernel respond with inform    255 call would make the kernel respond with information about *all* the families
260 it knows about. Last but not least the name of    256 it knows about. Last but not least the name of the family in question has
261 to be specified (4) as an attribute with the a    257 to be specified (4) as an attribute with the appropriate type::
262                                                   258 
263   struct nlmsghdr:                                259   struct nlmsghdr:
264     __u32 nlmsg_len:    32                        260     __u32 nlmsg_len:    32
265     __u16 nlmsg_type:   GENL_ID_CTRL              261     __u16 nlmsg_type:   GENL_ID_CTRL               // (1)
266     __u16 nlmsg_flags:  NLM_F_REQUEST | NLM_F_    262     __u16 nlmsg_flags:  NLM_F_REQUEST | NLM_F_ACK  // (2)
267     __u32 nlmsg_seq:    1                         263     __u32 nlmsg_seq:    1
268     __u32 nlmsg_pid:    0                         264     __u32 nlmsg_pid:    0
269                                                   265 
270   struct genlmsghdr:                              266   struct genlmsghdr:
271     __u8 cmd:           CTRL_CMD_GETFAMILY        267     __u8 cmd:           CTRL_CMD_GETFAMILY         // (3)
272     __u8 version:       2 /* or 1, doesn't mat    268     __u8 version:       2 /* or 1, doesn't matter */
273     __u16 reserved:     0                         269     __u16 reserved:     0
274                                                   270 
275   struct nlattr:                                  271   struct nlattr:                                   // (4)
276     __u16 nla_len:      10                        272     __u16 nla_len:      10
277     __u16 nla_type:     CTRL_ATTR_FAMILY_NAME     273     __u16 nla_type:     CTRL_ATTR_FAMILY_NAME
278     char data:          test1\0                   274     char data:          test1\0
279                                                   275 
280   (padding:)                                      276   (padding:)
281     char data:          \0\0                      277     char data:          \0\0
282                                                   278 
283 The length fields in Netlink (:c:member:`nlmsg    279 The length fields in Netlink (:c:member:`nlmsghdr.nlmsg_len`
284 and :c:member:`nlattr.nla_len`) always *includ    280 and :c:member:`nlattr.nla_len`) always *include* the header.
285 Attribute headers in netlink must be aligned t    281 Attribute headers in netlink must be aligned to 4 bytes from the start
286 of the message, hence the extra ``\0\0`` after    282 of the message, hence the extra ``\0\0`` after ``CTRL_ATTR_FAMILY_NAME``.
287 The attribute lengths *exclude* the padding.      283 The attribute lengths *exclude* the padding.
288                                                   284 
289 If the family is found kernel will reply with     285 If the family is found kernel will reply with two messages, the response
290 with all the information about the family::       286 with all the information about the family::
291                                                   287 
292   /* Message #1 - reply */                        288   /* Message #1 - reply */
293   struct nlmsghdr:                                289   struct nlmsghdr:
294     __u32 nlmsg_len:    136                       290     __u32 nlmsg_len:    136
295     __u16 nlmsg_type:   GENL_ID_CTRL              291     __u16 nlmsg_type:   GENL_ID_CTRL
296     __u16 nlmsg_flags:  0                         292     __u16 nlmsg_flags:  0
297     __u32 nlmsg_seq:    1    /* echoed from ou    293     __u32 nlmsg_seq:    1    /* echoed from our request */
298     __u32 nlmsg_pid:    5831 /* The PID of our    294     __u32 nlmsg_pid:    5831 /* The PID of our user space process */
299                                                   295 
300   struct genlmsghdr:                              296   struct genlmsghdr:
301     __u8 cmd:           CTRL_CMD_GETFAMILY        297     __u8 cmd:           CTRL_CMD_GETFAMILY
302     __u8 version:       2                         298     __u8 version:       2
303     __u16 reserved:     0                         299     __u16 reserved:     0
304                                                   300 
305   struct nlattr:                                  301   struct nlattr:
306     __u16 nla_len:      10                        302     __u16 nla_len:      10
307     __u16 nla_type:     CTRL_ATTR_FAMILY_NAME     303     __u16 nla_type:     CTRL_ATTR_FAMILY_NAME
308     char data:          test1\0                   304     char data:          test1\0
309                                                   305 
310   (padding:)                                      306   (padding:)
311     data:               \0\0                      307     data:               \0\0
312                                                   308 
313   struct nlattr:                                  309   struct nlattr:
314     __u16 nla_len:      6                         310     __u16 nla_len:      6
315     __u16 nla_type:     CTRL_ATTR_FAMILY_ID       311     __u16 nla_type:     CTRL_ATTR_FAMILY_ID
316     __u16:              123  /* The Family ID     312     __u16:              123  /* The Family ID we are after */
317                                                   313 
318   (padding:)                                      314   (padding:)
319     char data:          \0\0                      315     char data:          \0\0
320                                                   316 
321   struct nlattr:                                  317   struct nlattr:
322     __u16 nla_len:      9                         318     __u16 nla_len:      9
323     __u16 nla_type:     CTRL_ATTR_FAMILY_VERSI    319     __u16 nla_type:     CTRL_ATTR_FAMILY_VERSION
324     __u16:              1                         320     __u16:              1
325                                                   321 
326   /* ... etc, more attributes will follow. */     322   /* ... etc, more attributes will follow. */
327                                                   323 
328 And the error code (success) since ``NLM_F_ACK    324 And the error code (success) since ``NLM_F_ACK`` had been set on the request::
329                                                   325 
330   /* Message #2 - the ACK */                      326   /* Message #2 - the ACK */
331   struct nlmsghdr:                                327   struct nlmsghdr:
332     __u32 nlmsg_len:    36                        328     __u32 nlmsg_len:    36
333     __u16 nlmsg_type:   NLMSG_ERROR               329     __u16 nlmsg_type:   NLMSG_ERROR
334     __u16 nlmsg_flags:  NLM_F_CAPPED /* There     330     __u16 nlmsg_flags:  NLM_F_CAPPED /* There won't be a payload */
335     __u32 nlmsg_seq:    1    /* echoed from ou    331     __u32 nlmsg_seq:    1    /* echoed from our request */
336     __u32 nlmsg_pid:    5831 /* The PID of our    332     __u32 nlmsg_pid:    5831 /* The PID of our user space process */
337                                                   333 
338   int error:            0                         334   int error:            0
339                                                   335 
340   struct nlmsghdr: /* Copy of the request head    336   struct nlmsghdr: /* Copy of the request header as we sent it */
341     __u32 nlmsg_len:    32                        337     __u32 nlmsg_len:    32
342     __u16 nlmsg_type:   GENL_ID_CTRL              338     __u16 nlmsg_type:   GENL_ID_CTRL
343     __u16 nlmsg_flags:  NLM_F_REQUEST | NLM_F_    339     __u16 nlmsg_flags:  NLM_F_REQUEST | NLM_F_ACK
344     __u32 nlmsg_seq:    1                         340     __u32 nlmsg_seq:    1
345     __u32 nlmsg_pid:    0                         341     __u32 nlmsg_pid:    0
346                                                   342 
347 The order of attributes (struct nlattr) is not    343 The order of attributes (struct nlattr) is not guaranteed so the user
348 has to walk the attributes and parse them.        344 has to walk the attributes and parse them.
349                                                   345 
350 Note that Generic Netlink sockets are not asso    346 Note that Generic Netlink sockets are not associated or bound to a single
351 family. A socket can be used to exchange messa    347 family. A socket can be used to exchange messages with many different
352 families, selecting the recipient family on me    348 families, selecting the recipient family on message-by-message basis using
353 the :c:member:`nlmsghdr.nlmsg_type` field.        349 the :c:member:`nlmsghdr.nlmsg_type` field.
354                                                   350 
355 .. _ext_ack:                                      351 .. _ext_ack:
356                                                   352 
357 Extended ACK                                      353 Extended ACK
358 ------------                                      354 ------------
359                                                   355 
360 Extended ACK controls reporting of additional     356 Extended ACK controls reporting of additional error/warning TLVs
361 in ``NLMSG_ERROR`` and ``NLMSG_DONE`` messages    357 in ``NLMSG_ERROR`` and ``NLMSG_DONE`` messages. To maintain backward
362 compatibility this feature has to be explicitl    358 compatibility this feature has to be explicitly enabled by setting
363 the ``NETLINK_EXT_ACK`` setsockopt() to ``1``.    359 the ``NETLINK_EXT_ACK`` setsockopt() to ``1``.
364                                                   360 
365 Types of extended ack attributes are defined i    361 Types of extended ack attributes are defined in enum nlmsgerr_attrs.
366 The most commonly used attributes are ``NLMSGE    362 The most commonly used attributes are ``NLMSGERR_ATTR_MSG``,
367 ``NLMSGERR_ATTR_OFFS`` and ``NLMSGERR_ATTR_MIS    363 ``NLMSGERR_ATTR_OFFS`` and ``NLMSGERR_ATTR_MISS_*``.
368                                                   364 
369 ``NLMSGERR_ATTR_MSG`` carries a message in Eng    365 ``NLMSGERR_ATTR_MSG`` carries a message in English describing
370 the encountered problem. These messages are fa    366 the encountered problem. These messages are far more detailed
371 than what can be expressed thru standard UNIX     367 than what can be expressed thru standard UNIX error codes.
372                                                   368 
373 ``NLMSGERR_ATTR_OFFS`` points to the attribute    369 ``NLMSGERR_ATTR_OFFS`` points to the attribute which caused the problem.
374                                                   370 
375 ``NLMSGERR_ATTR_MISS_TYPE`` and ``NLMSGERR_ATT    371 ``NLMSGERR_ATTR_MISS_TYPE`` and ``NLMSGERR_ATTR_MISS_NEST``
376 inform about a missing attribute.                 372 inform about a missing attribute.
377                                                   373 
378 Extended ACKs can be reported on errors as wel    374 Extended ACKs can be reported on errors as well as in case of success.
379 The latter should be treated as a warning.        375 The latter should be treated as a warning.
380                                                   376 
381 Extended ACKs greatly improve the usability of    377 Extended ACKs greatly improve the usability of Netlink and should
382 always be enabled, appropriately parsed and re    378 always be enabled, appropriately parsed and reported to the user.
383                                                   379 
384 Advanced topics                                   380 Advanced topics
385 ===============                                   381 ===============
386                                                   382 
387 Dump consistency                                  383 Dump consistency
388 ----------------                                  384 ----------------
389                                                   385 
390 Some of the data structures kernel uses for st    386 Some of the data structures kernel uses for storing objects make
391 it hard to provide an atomic snapshot of all t    387 it hard to provide an atomic snapshot of all the objects in a dump
392 (without impacting the fast-paths updating the    388 (without impacting the fast-paths updating them).
393                                                   389 
394 Kernel may set the ``NLM_F_DUMP_INTR`` flag on    390 Kernel may set the ``NLM_F_DUMP_INTR`` flag on any message in a dump
395 (including the ``NLMSG_DONE`` message) if the     391 (including the ``NLMSG_DONE`` message) if the dump was interrupted and
396 may be inconsistent (e.g. missing objects). Us    392 may be inconsistent (e.g. missing objects). User space should retry
397 the dump if it sees the flag set.                 393 the dump if it sees the flag set.
398                                                   394 
399 Introspection                                     395 Introspection
400 -------------                                     396 -------------
401                                                   397 
402 The basic introspection abilities are enabled     398 The basic introspection abilities are enabled by access to the Family
403 object as reported in :ref:`res_fam`. User can    399 object as reported in :ref:`res_fam`. User can query information about
404 the Generic Netlink family, including which op    400 the Generic Netlink family, including which operations are supported
405 by the kernel and what attributes the kernel u    401 by the kernel and what attributes the kernel understands.
406 Family information includes the highest ID of     402 Family information includes the highest ID of an attribute kernel can parse,
407 a separate command (``CTRL_CMD_GETPOLICY``) pr    403 a separate command (``CTRL_CMD_GETPOLICY``) provides detailed information
408 about supported attributes, including ranges o    404 about supported attributes, including ranges of values the kernel accepts.
409                                                   405 
410 Querying family information is useful in cases    406 Querying family information is useful in cases when user space needs
411 to make sure that the kernel has support for a    407 to make sure that the kernel has support for a feature before issuing
412 a request.                                        408 a request.
413                                                   409 
414 .. _nlmsg_pid:                                    410 .. _nlmsg_pid:
415                                                   411 
416 nlmsg_pid                                         412 nlmsg_pid
417 ---------                                         413 ---------
418                                                   414 
419 :c:member:`nlmsghdr.nlmsg_pid` is the Netlink     415 :c:member:`nlmsghdr.nlmsg_pid` is the Netlink equivalent of an address.
420 It is referred to as Port ID, sometimes Proces    416 It is referred to as Port ID, sometimes Process ID because for historical
421 reasons if the application does not select (bi    417 reasons if the application does not select (bind() to) an explicit Port ID
422 kernel will automatically assign it the ID equ    418 kernel will automatically assign it the ID equal to its Process ID
423 (as reported by the getpid() system call).        419 (as reported by the getpid() system call).
424                                                   420 
425 Similarly to the bind() semantics of the TCP/I    421 Similarly to the bind() semantics of the TCP/IP network protocols the value
426 of zero means "assign automatically", hence it    422 of zero means "assign automatically", hence it is common for applications
427 to leave the :c:member:`nlmsghdr.nlmsg_pid` fi    423 to leave the :c:member:`nlmsghdr.nlmsg_pid` field initialized to ``0``.
428                                                   424 
429 The field is still used today in rare cases wh    425 The field is still used today in rare cases when kernel needs to send
430 a unicast notification. User space application    426 a unicast notification. User space application can use bind() to associate
431 its socket with a specific PID, it then commun    427 its socket with a specific PID, it then communicates its PID to the kernel.
432 This way the kernel can reach the specific use    428 This way the kernel can reach the specific user space process.
433                                                   429 
434 This sort of communication is utilized in UMH     430 This sort of communication is utilized in UMH (User Mode Helper)-like
435 scenarios when kernel needs to trigger user sp    431 scenarios when kernel needs to trigger user space processing or ask user
436 space for a policy decision.                      432 space for a policy decision.
437                                                   433 
438 Multicast notifications                           434 Multicast notifications
439 -----------------------                           435 -----------------------
440                                                   436 
441 One of the strengths of Netlink is the ability    437 One of the strengths of Netlink is the ability to send event notifications
442 to user space. This is a unidirectional form o    438 to user space. This is a unidirectional form of communication (kernel ->
443 user) and does not involve any control message    439 user) and does not involve any control messages like ``NLMSG_ERROR`` or
444 ``NLMSG_DONE``.                                   440 ``NLMSG_DONE``.
445                                                   441 
446 For example the Generic Netlink family itself     442 For example the Generic Netlink family itself defines a set of multicast
447 notifications about registered families. When     443 notifications about registered families. When a new family is added the
448 sockets subscribed to the notifications will g    444 sockets subscribed to the notifications will get the following message::
449                                                   445 
450   struct nlmsghdr:                                446   struct nlmsghdr:
451     __u32 nlmsg_len:    136                       447     __u32 nlmsg_len:    136
452     __u16 nlmsg_type:   GENL_ID_CTRL              448     __u16 nlmsg_type:   GENL_ID_CTRL
453     __u16 nlmsg_flags:  0                         449     __u16 nlmsg_flags:  0
454     __u32 nlmsg_seq:    0                         450     __u32 nlmsg_seq:    0
455     __u32 nlmsg_pid:    0                         451     __u32 nlmsg_pid:    0
456                                                   452 
457   struct genlmsghdr:                              453   struct genlmsghdr:
458     __u8 cmd:           CTRL_CMD_NEWFAMILY        454     __u8 cmd:           CTRL_CMD_NEWFAMILY
459     __u8 version:       2                         455     __u8 version:       2
460     __u16 reserved:     0                         456     __u16 reserved:     0
461                                                   457 
462   struct nlattr:                                  458   struct nlattr:
463     __u16 nla_len:      10                        459     __u16 nla_len:      10
464     __u16 nla_type:     CTRL_ATTR_FAMILY_NAME     460     __u16 nla_type:     CTRL_ATTR_FAMILY_NAME
465     char data:          test1\0                   461     char data:          test1\0
466                                                   462 
467   (padding:)                                      463   (padding:)
468     data:               \0\0                      464     data:               \0\0
469                                                   465 
470   struct nlattr:                                  466   struct nlattr:
471     __u16 nla_len:      6                         467     __u16 nla_len:      6
472     __u16 nla_type:     CTRL_ATTR_FAMILY_ID       468     __u16 nla_type:     CTRL_ATTR_FAMILY_ID
473     __u16:              123  /* The Family ID     469     __u16:              123  /* The Family ID we are after */
474                                                   470 
475   (padding:)                                      471   (padding:)
476     char data:          \0\0                      472     char data:          \0\0
477                                                   473 
478   struct nlattr:                                  474   struct nlattr:
479     __u16 nla_len:      9                         475     __u16 nla_len:      9
480     __u16 nla_type:     CTRL_ATTR_FAMILY_VERSI    476     __u16 nla_type:     CTRL_ATTR_FAMILY_VERSION
481     __u16:              1                         477     __u16:              1
482                                                   478 
483   /* ... etc, more attributes will follow. */     479   /* ... etc, more attributes will follow. */
484                                                   480 
485 The notification contains the same information    481 The notification contains the same information as the response
486 to the ``CTRL_CMD_GETFAMILY`` request.            482 to the ``CTRL_CMD_GETFAMILY`` request.
487                                                   483 
488 The Netlink headers of the notification are mo    484 The Netlink headers of the notification are mostly 0 and irrelevant.
489 The :c:member:`nlmsghdr.nlmsg_seq` may be eith    485 The :c:member:`nlmsghdr.nlmsg_seq` may be either zero or a monotonically
490 increasing notification sequence number mainta    486 increasing notification sequence number maintained by the family.
491                                                   487 
492 To receive notifications the user socket must     488 To receive notifications the user socket must subscribe to the relevant
493 notification group. Much like the Family ID, t    489 notification group. Much like the Family ID, the Group ID for a given
494 multicast group is dynamic and can be found in    490 multicast group is dynamic and can be found inside the Family information.
495 The ``CTRL_ATTR_MCAST_GROUPS`` attribute conta    491 The ``CTRL_ATTR_MCAST_GROUPS`` attribute contains nests with names
496 (``CTRL_ATTR_MCAST_GRP_NAME``) and IDs (``CTRL    492 (``CTRL_ATTR_MCAST_GRP_NAME``) and IDs (``CTRL_ATTR_MCAST_GRP_ID``) of
497 the groups family.                                493 the groups family.
498                                                   494 
499 Once the Group ID is known a setsockopt() call    495 Once the Group ID is known a setsockopt() call adds the socket to the group:
500                                                   496 
501 .. code-block:: c                                 497 .. code-block:: c
502                                                   498 
503   unsigned int group_id;                          499   unsigned int group_id;
504                                                   500 
505   /* .. find the group ID... */                   501   /* .. find the group ID... */
506                                                   502 
507   setsockopt(fd, SOL_NETLINK, NETLINK_ADD_MEMB    503   setsockopt(fd, SOL_NETLINK, NETLINK_ADD_MEMBERSHIP,
508              &group_id, sizeof(group_id));        504              &group_id, sizeof(group_id));
509                                                   505 
510 The socket will now receive notifications.        506 The socket will now receive notifications.
511                                                   507 
512 It is recommended to use separate sockets for     508 It is recommended to use separate sockets for receiving notifications
513 and sending requests to the kernel. The asynch    509 and sending requests to the kernel. The asynchronous nature of notifications
514 means that they may get mixed in with the resp    510 means that they may get mixed in with the responses making the message
515 handling much harder.                             511 handling much harder.
516                                                   512 
517 Buffer sizing                                     513 Buffer sizing
518 -------------                                     514 -------------
519                                                   515 
520 Netlink sockets are datagram sockets rather th    516 Netlink sockets are datagram sockets rather than stream sockets,
521 meaning that each message must be received in     517 meaning that each message must be received in its entirety by a single
522 recv()/recvmsg() system call. If the buffer pr    518 recv()/recvmsg() system call. If the buffer provided by the user is too
523 short, the message will be truncated and the `    519 short, the message will be truncated and the ``MSG_TRUNC`` flag set
524 in struct msghdr (struct msghdr is the second     520 in struct msghdr (struct msghdr is the second argument
525 of the recvmsg() system call, *not* a Netlink     521 of the recvmsg() system call, *not* a Netlink header).
526                                                   522 
527 Upon truncation the remaining part of the mess    523 Upon truncation the remaining part of the message is discarded.
528                                                   524 
529 Netlink expects that the user buffer will be a    525 Netlink expects that the user buffer will be at least 8kB or a page
530 size of the CPU architecture, whichever is big    526 size of the CPU architecture, whichever is bigger. Particular Netlink
531 families may, however, require a larger buffer    527 families may, however, require a larger buffer. 32kB buffer is recommended
532 for most efficient handling of dumps (larger b    528 for most efficient handling of dumps (larger buffer fits more dumped
533 objects and therefore fewer recvmsg() calls ar    529 objects and therefore fewer recvmsg() calls are needed).
534                                                   530 
535 .. _classic_netlink:                           << 
536                                                << 
537 Classic Netlink                                   531 Classic Netlink
538 ===============                                   532 ===============
539                                                   533 
540 The main differences between Classic and Gener    534 The main differences between Classic and Generic Netlink are the dynamic
541 allocation of subsystem identifiers and availa    535 allocation of subsystem identifiers and availability of introspection.
542 In theory the protocol does not differ signifi    536 In theory the protocol does not differ significantly, however, in practice
543 Classic Netlink experimented with concepts whi    537 Classic Netlink experimented with concepts which were abandoned in Generic
544 Netlink (really, they usually only found use i    538 Netlink (really, they usually only found use in a small corner of a single
545 subsystem). This section is meant as an explai    539 subsystem). This section is meant as an explainer of a few of such concepts,
546 with the explicit goal of giving the Generic N    540 with the explicit goal of giving the Generic Netlink
547 users the confidence to ignore them when readi    541 users the confidence to ignore them when reading the uAPI headers.
548                                                   542 
549 Most of the concepts and examples here refer t    543 Most of the concepts and examples here refer to the ``NETLINK_ROUTE`` family,
550 which covers much of the configuration of the     544 which covers much of the configuration of the Linux networking stack.
551 Real documentation of that family, deserves a     545 Real documentation of that family, deserves a chapter (or a book) of its own.
552                                                   546 
553 Families                                          547 Families
554 --------                                          548 --------
555                                                   549 
556 Netlink refers to subsystems as families. This    550 Netlink refers to subsystems as families. This is a remnant of using
557 sockets and the concept of protocol families,     551 sockets and the concept of protocol families, which are part of message
558 demultiplexing in ``NETLINK_ROUTE``.              552 demultiplexing in ``NETLINK_ROUTE``.
559                                                   553 
560 Sadly every layer of encapsulation likes to re    554 Sadly every layer of encapsulation likes to refer to whatever it's carrying
561 as "families" making the term very confusing:     555 as "families" making the term very confusing:
562                                                   556 
563  1. AF_NETLINK is a bona fide socket protocol     557  1. AF_NETLINK is a bona fide socket protocol family
564  2. AF_NETLINK's documentation refers to what     558  2. AF_NETLINK's documentation refers to what comes after its own
565     header (struct nlmsghdr) in a message as a    559     header (struct nlmsghdr) in a message as a "Family Header"
566  3. Generic Netlink is a family for AF_NETLINK    560  3. Generic Netlink is a family for AF_NETLINK (struct genlmsghdr follows
567     struct nlmsghdr), yet it also calls its us    561     struct nlmsghdr), yet it also calls its users "Families".
568                                                   562 
569 Note that the Generic Netlink Family IDs are i    563 Note that the Generic Netlink Family IDs are in a different "ID space"
570 and overlap with Classic Netlink protocol numb    564 and overlap with Classic Netlink protocol numbers (e.g. ``NETLINK_CRYPTO``
571 has the Classic Netlink protocol ID of 21 whic    565 has the Classic Netlink protocol ID of 21 which Generic Netlink will
572 happily allocate to one of its families as wel    566 happily allocate to one of its families as well).
573                                                   567 
574 Strict checking                                   568 Strict checking
575 ---------------                                   569 ---------------
576                                                   570 
577 The ``NETLINK_GET_STRICT_CHK`` socket option e    571 The ``NETLINK_GET_STRICT_CHK`` socket option enables strict input checking
578 in ``NETLINK_ROUTE``. It was needed because hi    572 in ``NETLINK_ROUTE``. It was needed because historically kernel did not
579 validate the fields of structures it didn't pr    573 validate the fields of structures it didn't process. This made it impossible
580 to start using those fields later without risk    574 to start using those fields later without risking regressions in applications
581 which initialized them incorrectly or not at a    575 which initialized them incorrectly or not at all.
582                                                   576 
583 ``NETLINK_GET_STRICT_CHK`` declares that the a    577 ``NETLINK_GET_STRICT_CHK`` declares that the application is initializing
584 all fields correctly. It also opts into valida    578 all fields correctly. It also opts into validating that message does not
585 contain trailing data and requests that kernel    579 contain trailing data and requests that kernel rejects attributes with
586 type higher than largest attribute type known     580 type higher than largest attribute type known to the kernel.
587                                                   581 
588 ``NETLINK_GET_STRICT_CHK`` is not used outside    582 ``NETLINK_GET_STRICT_CHK`` is not used outside of ``NETLINK_ROUTE``.
589                                                   583 
590 Unknown attributes                                584 Unknown attributes
591 ------------------                                585 ------------------
592                                                   586 
593 Historically Netlink ignored all unknown attri    587 Historically Netlink ignored all unknown attributes. The thinking was that
594 it would free the application from having to p    588 it would free the application from having to probe what kernel supports.
595 The application could make a request to change    589 The application could make a request to change the state and check which
596 parts of the request "stuck".                     590 parts of the request "stuck".
597                                                   591 
598 This is no longer the case for new Generic Net    592 This is no longer the case for new Generic Netlink families and those opting
599 in to strict checking. See enum netlink_valida    593 in to strict checking. See enum netlink_validation for validation types
600 performed.                                        594 performed.
601                                                   595 
602 Fixed metadata and structures                     596 Fixed metadata and structures
603 -----------------------------                     597 -----------------------------
604                                                   598 
605 Classic Netlink made liberal use of fixed-form    599 Classic Netlink made liberal use of fixed-format structures within
606 the messages. Messages would commonly have a s    600 the messages. Messages would commonly have a structure with
607 a considerable number of fields after struct n    601 a considerable number of fields after struct nlmsghdr. It was also
608 common to put structures with multiple members    602 common to put structures with multiple members inside attributes,
609 without breaking each member into an attribute    603 without breaking each member into an attribute of its own.
610                                                   604 
611 This has caused problems with validation and e    605 This has caused problems with validation and extensibility and
612 therefore using binary structures is actively     606 therefore using binary structures is actively discouraged for new
613 attributes.                                       607 attributes.
614                                                   608 
615 Request types                                     609 Request types
616 -------------                                     610 -------------
617                                                   611 
618 ``NETLINK_ROUTE`` categorized requests into 4     612 ``NETLINK_ROUTE`` categorized requests into 4 types ``NEW``, ``DEL``, ``GET``,
619 and ``SET``. Each object can handle all or som    613 and ``SET``. Each object can handle all or some of those requests
620 (objects being netdevs, routes, addresses, qdi    614 (objects being netdevs, routes, addresses, qdiscs etc.) Request type
621 is defined by the 2 lowest bits of the message    615 is defined by the 2 lowest bits of the message type, so commands for
622 new objects would always be allocated with a s    616 new objects would always be allocated with a stride of 4.
623                                                   617 
624 Each object would also have its own fixed meta !! 618 Each object would also have it's own fixed metadata shared by all request
625 types (e.g. struct ifinfomsg for netdev reques    619 types (e.g. struct ifinfomsg for netdev requests, struct ifaddrmsg for address
626 requests, struct tcmsg for qdisc requests).       620 requests, struct tcmsg for qdisc requests).
627                                                   621 
628 Even though other protocols and Generic Netlin    622 Even though other protocols and Generic Netlink commands often use
629 the same verbs in their message names (``GET``    623 the same verbs in their message names (``GET``, ``SET``) the concept
630 of request types did not find wider adoption.     624 of request types did not find wider adoption.
631                                                   625 
632 Notification echo                                 626 Notification echo
633 -----------------                                 627 -----------------
634                                                   628 
635 ``NLM_F_ECHO`` requests for notifications resu    629 ``NLM_F_ECHO`` requests for notifications resulting from the request
636 to be queued onto the requesting socket. This     630 to be queued onto the requesting socket. This is useful to discover
637 the impact of the request.                        631 the impact of the request.
638                                                   632 
639 Note that this feature is not universally impl    633 Note that this feature is not universally implemented.
640                                                   634 
641 Other request-type-specific flags                 635 Other request-type-specific flags
642 ---------------------------------                 636 ---------------------------------
643                                                   637 
644 Classic Netlink defined various flags for its     638 Classic Netlink defined various flags for its ``GET``, ``NEW``
645 and ``DEL`` requests in the upper byte of nlms    639 and ``DEL`` requests in the upper byte of nlmsg_flags in struct nlmsghdr.
646 Since request types have not been generalized     640 Since request types have not been generalized the request type specific
647 flags are rarely used (and considered deprecat    641 flags are rarely used (and considered deprecated for new families).
648                                                   642 
649 For ``GET`` - ``NLM_F_ROOT`` and ``NLM_F_MATCH    643 For ``GET`` - ``NLM_F_ROOT`` and ``NLM_F_MATCH`` are combined into
650 ``NLM_F_DUMP``, and not used separately. ``NLM    644 ``NLM_F_DUMP``, and not used separately. ``NLM_F_ATOMIC`` is never used.
651                                                   645 
652 For ``DEL`` - ``NLM_F_NONREC`` is only used by    646 For ``DEL`` - ``NLM_F_NONREC`` is only used by nftables and ``NLM_F_BULK``
653 only by FDB some operations.                      647 only by FDB some operations.
654                                                   648 
655 The flags for ``NEW`` are used most commonly i    649 The flags for ``NEW`` are used most commonly in classic Netlink. Unfortunately,
656 the meaning is not crystal clear. The followin    650 the meaning is not crystal clear. The following description is based on the
657 best guess of the intention of the authors, an    651 best guess of the intention of the authors, and in practice all families
658 stray from it in one way or another. ``NLM_F_R    652 stray from it in one way or another. ``NLM_F_REPLACE`` asks to replace
659 an existing object, if no matching object exis    653 an existing object, if no matching object exists the operation should fail.
660 ``NLM_F_EXCL`` has the opposite semantics and     654 ``NLM_F_EXCL`` has the opposite semantics and only succeeds if object already
661 existed.                                          655 existed.
662 ``NLM_F_CREATE`` asks for the object to be cre    656 ``NLM_F_CREATE`` asks for the object to be created if it does not
663 exist, it can be combined with ``NLM_F_REPLACE    657 exist, it can be combined with ``NLM_F_REPLACE`` and ``NLM_F_EXCL``.
664                                                   658 
665 A comment in the main Netlink uAPI header stat    659 A comment in the main Netlink uAPI header states::
666                                                   660 
667    4.4BSD ADD           NLM_F_CREATE|NLM_F_EXC    661    4.4BSD ADD           NLM_F_CREATE|NLM_F_EXCL
668    4.4BSD CHANGE        NLM_F_REPLACE             662    4.4BSD CHANGE        NLM_F_REPLACE
669                                                   663 
670    True CHANGE          NLM_F_CREATE|NLM_F_REP    664    True CHANGE          NLM_F_CREATE|NLM_F_REPLACE
671    Append               NLM_F_CREATE              665    Append               NLM_F_CREATE
672    Check                NLM_F_EXCL                666    Check                NLM_F_EXCL
673                                                   667 
674 which seems to indicate that those flags preda    668 which seems to indicate that those flags predate request types.
675 ``NLM_F_REPLACE`` without ``NLM_F_CREATE`` was    669 ``NLM_F_REPLACE`` without ``NLM_F_CREATE`` was initially used instead
676 of ``SET`` commands.                              670 of ``SET`` commands.
677 ``NLM_F_EXCL`` without ``NLM_F_CREATE`` was us    671 ``NLM_F_EXCL`` without ``NLM_F_CREATE`` was used to check if object exists
678 without creating it, presumably predating ``GE    672 without creating it, presumably predating ``GET`` commands.
679                                                   673 
680 ``NLM_F_APPEND`` indicates that if one key can    674 ``NLM_F_APPEND`` indicates that if one key can have multiple objects associated
681 with it (e.g. multiple next-hop objects for a     675 with it (e.g. multiple next-hop objects for a route) the new object should be
682 added to the list rather than replacing the en    676 added to the list rather than replacing the entire list.
683                                                   677 
684 uAPI reference                                    678 uAPI reference
685 ==============                                    679 ==============
686                                                   680 
687 .. kernel-doc:: include/uapi/linux/netlink.h      681 .. kernel-doc:: include/uapi/linux/netlink.h
                                                      

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