[deliverable/linux.git] / Documentation / networking / netlink_mmap.txt

This file documents how to use memory mapped I/O with netlink.

Author: Patrick McHardy <kaber@trash.net>

Overview
--------

Memory mapped netlink I/O can be used to increase throughput and decrease
overhead of unicast receive and transmit operations. Some netlink subsystems
require high throughput, these are mainly the netfilter subsystems
nfnetlink_queue and nfnetlink_log, but it can also help speed up large
dump operations of f.i. the routing database.

Memory mapped netlink I/O used two circular ring buffers for RX and TX which
are mapped into the processes address space.

The RX ring is used by the kernel to directly construct netlink messages into
user-space memory without copying them as done with regular socket I/O,
additionally as long as the ring contains messages no recvmsg() or poll()
syscalls have to be issued by user-space to get more message.

The TX ring is used to process messages directly from user-space memory, the
kernel processes all messages contained in the ring using a single sendmsg()
call.

Usage overview
--------------

In order to use memory mapped netlink I/O, user-space needs three main changes:

- ring setup
- conversion of the RX path to get messages from the ring instead of recvmsg()
- conversion of the TX path to construct messages into the ring

Ring setup is done using setsockopt() to provide the ring parameters to the
kernel, then a call to mmap() to map the ring into the processes address space:

- setsockopt(fd, SOL_NETLINK, NETLINK_RX_RING, &params, sizeof(params));
- setsockopt(fd, SOL_NETLINK, NETLINK_TX_RING, &params, sizeof(params));
- ring = mmap(NULL, size, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0)

Usage of either ring is optional, but even if only the RX ring is used the
mapping still needs to be writable in order to update the frame status after
processing.

Conversion of the reception path involves calling poll() on the file
descriptor, once the socket is readable the frames from the ring are
processed in order until no more messages are available, as indicated by
a status word in the frame header.

On kernel side, in order to make use of memory mapped I/O on receive, the
originating netlink subsystem needs to support memory mapped I/O, otherwise
it will use an allocated socket buffer as usual and the contents will be
 copied to the ring on transmission, nullifying most of the performance gains.
Dumps of kernel databases automatically support memory mapped I/O.

Conversion of the transmit path involves changing message construction to
use memory from the TX ring instead of (usually) a buffer declared on the
stack and setting up the frame header appropriately. Optionally poll() can
be used to wait for free frames in the TX ring.

Structured and definitions for using memory mapped I/O are contained in
<linux/netlink.h>.

RX and TX rings
----------------

Each ring contains a number of continuous memory blocks, containing frames of
fixed size dependent on the parameters used for ring setup.

Ring:	[ block 0 ]
		[ frame 0 ]
		[ frame 1 ]
	[ block 1 ]
		[ frame 2 ]
		[ frame 3 ]
	...
	[ block n ]
		[ frame 2 * n ]
		[ frame 2 * n + 1 ]

The blocks are only visible to the kernel, from the point of view of user-space
the ring just contains the frames in a continuous memory zone.

The ring parameters used for setting up the ring are defined as follows:

struct nl_mmap_req {
	unsigned int	nm_block_size;
	unsigned int	nm_block_nr;
	unsigned int	nm_frame_size;
	unsigned int	nm_frame_nr;
};

Frames are grouped into blocks, where each block is a continuous region of memory
and holds nm_block_size / nm_frame_size frames. The total number of frames in
the ring is nm_frame_nr. The following invariants hold:

- frames_per_block = nm_block_size / nm_frame_size

- nm_frame_nr = frames_per_block * nm_block_nr

Some parameters are constrained, specifically:

- nm_block_size must be a multiple of the architectures memory page size.
  The getpagesize() function can be used to get the page size.

- nm_frame_size must be equal or larger to NL_MMAP_HDRLEN, IOW a frame must be
  able to hold at least the frame header

- nm_frame_size must be smaller or equal to nm_block_size

- nm_frame_size must be a multiple of NL_MMAP_MSG_ALIGNMENT

- nm_frame_nr must equal the actual number of frames as specified above.

When the kernel can't allocate physically continuous memory for a ring block,
it will fall back to use physically discontinuous memory. This might affect
performance negatively, in order to avoid this the nm_frame_size parameter
should be chosen to be as small as possible for the required frame size and
the number of blocks should be increased instead.

Ring frames
------------

Each frames contain a frame header, consisting of a synchronization word and some
meta-data, and the message itself.

Frame:	[ header message ]

The frame header is defined as follows:

struct nl_mmap_hdr {
	unsigned int	nm_status;
	unsigned int	nm_len;
	__u32		nm_group;
	/* credentials */
	__u32		nm_pid;
	__u32		nm_uid;
	__u32		nm_gid;
};

- nm_status is used for synchronizing processing between the kernel and user-
  space and specifies ownership of the frame as well as the operation to perform

- nm_len contains the length of the message contained in the data area

- nm_group specified the destination multicast group of message

- nm_pid, nm_uid and nm_gid contain the netlink pid, UID and GID of the sending
  process. These values correspond to the data available using SOCK_PASSCRED in
  the SCM_CREDENTIALS cmsg.

The possible values in the status word are:

- NL_MMAP_STATUS_UNUSED:
	RX ring:	frame belongs to the kernel and contains no message
			for user-space. Approriate action is to invoke poll()
			to wait for new messages.

	TX ring:	frame belongs to user-space and can be used for
			message construction.

- NL_MMAP_STATUS_RESERVED:
	RX ring only:	frame is currently used by the kernel for message
			construction and contains no valid message yet.
			Appropriate action is to invoke poll() to wait for
			new messages.

- NL_MMAP_STATUS_VALID:
	RX ring:	frame contains a valid message. Approriate action is
			to process the message and release the frame back to
			the kernel by setting the status to
			NL_MMAP_STATUS_UNUSED or queue the frame by setting the
			status to NL_MMAP_STATUS_SKIP.

	TX ring:	the frame contains a valid message from user-space to
			be processed by the kernel. After completing processing
			the kernel will release the frame back to user-space by
			setting the status to NL_MMAP_STATUS_UNUSED.

- NL_MMAP_STATUS_COPY:
	RX ring only:	a message is ready to be processed but could not be
			stored in the ring, either because it exceeded the
			frame size or because the originating subsystem does
			not support memory mapped I/O. Appropriate action is
			to invoke recvmsg() to receive the message and release
			the frame back to the kernel by setting the status to
			NL_MMAP_STATUS_UNUSED.

- NL_MMAP_STATUS_SKIP:
	RX ring only:	user-space queued the message for later processing, but
			processed some messages following it in the ring. The
			kernel should skip this frame when looking for unused
			frames.

The data area of a frame begins at a offset of NL_MMAP_HDRLEN relative to the
frame header.

TX limitations
--------------

As of Jan 2015 the message is always copied from the ring frame to an
allocated buffer due to unresolved security concerns.
See commit 4682a0358639b29cf ("netlink: Always copy on mmap TX.").

Example
-------

Ring setup:

	unsigned int block_size = 16 * getpagesize();
	struct nl_mmap_req req = {
		.nm_block_size		= block_size,
		.nm_block_nr		= 64,
		.nm_frame_size		= 16384,
		.nm_frame_nr		= 64 * block_size / 16384,
	};
	unsigned int ring_size;
	void *rx_ring, *tx_ring;

	/* Configure ring parameters */
	if (setsockopt(fd, SOL_NETLINK, NETLINK_RX_RING, &req, sizeof(req)) < 0)
		exit(1);
	if (setsockopt(fd, SOL_NETLINK, NETLINK_TX_RING, &req, sizeof(req)) < 0)
		exit(1)

	/* Calculate size of each individual ring */
	ring_size = req.nm_block_nr * req.nm_block_size;

	/* Map RX/TX rings. The TX ring is located after the RX ring */
	rx_ring = mmap(NULL, 2 * ring_size, PROT_READ | PROT_WRITE,
		       MAP_SHARED, fd, 0);
	if ((long)rx_ring == -1L)
		exit(1);
	tx_ring = rx_ring + ring_size:

Message reception:

This example assumes some ring parameters of the ring setup are available.

	unsigned int frame_offset = 0;
	struct nl_mmap_hdr *hdr;
	struct nlmsghdr *nlh;
	unsigned char buf[16384];
	ssize_t len;

	while (1) {
		struct pollfd pfds[1];

		pfds[0].fd	= fd;
		pfds[0].events	= POLLIN | POLLERR;
		pfds[0].revents	= 0;

		if (poll(pfds, 1, -1) < 0 && errno != -EINTR)
			exit(1);

		/* Check for errors. Error handling omitted */
		if (pfds[0].revents & POLLERR)
			<handle error>

		/* If no new messages, poll again */
		if (!(pfds[0].revents & POLLIN))
			continue;

		/* Process all frames */
		while (1) {
			/* Get next frame header */
			hdr = rx_ring + frame_offset;

			if (hdr->nm_status == NL_MMAP_STATUS_VALID) {
				/* Regular memory mapped frame */
				nlh = (void *)hdr + NL_MMAP_HDRLEN;
				len = hdr->nm_len;

				/* Release empty message immediately. May happen
				 * on error during message construction.
				 */
				if (len == 0)
					goto release;
			} else if (hdr->nm_status == NL_MMAP_STATUS_COPY) {
				/* Frame queued to socket receive queue */
				len = recv(fd, buf, sizeof(buf), MSG_DONTWAIT);
				if (len <= 0)
					break;
				nlh = buf;
			} else
				/* No more messages to process, continue polling */
				break;

			process_msg(nlh);
release:
			/* Release frame back to the kernel */
			hdr->nm_status = NL_MMAP_STATUS_UNUSED;

			/* Advance frame offset to next frame */
			frame_offset = (frame_offset + frame_size) % ring_size;
		}
	}

Message transmission:

This example assumes some ring parameters of the ring setup are available.
A single message is constructed and transmitted, to send multiple messages
at once they would be constructed in consecutive frames before a final call
to sendto().

	unsigned int frame_offset = 0;
	struct nl_mmap_hdr *hdr;
	struct nlmsghdr *nlh;
	struct sockaddr_nl addr = {
		.nl_family	= AF_NETLINK,
	};

	hdr = tx_ring + frame_offset;
	if (hdr->nm_status != NL_MMAP_STATUS_UNUSED)
		/* No frame available. Use poll() to avoid. */
		exit(1);

	nlh = (void *)hdr + NL_MMAP_HDRLEN;

	/* Build message */
	build_message(nlh);

	/* Fill frame header: length and status need to be set */
	hdr->nm_len	= nlh->nlmsg_len;
	hdr->nm_status	= NL_MMAP_STATUS_VALID;

	if (sendto(fd, NULL, 0, 0, &addr, sizeof(addr)) < 0)
		exit(1);

	/* Advance frame offset to next frame */
	frame_offset = (frame_offset + frame_size) % ring_size;
Commit	Line	Data
5683264c PM	1	This file documents how to use memory mapped I/O with netlink.
	2
	3	Author: Patrick McHardy <kaber@trash.net>
	4
	5	Overview
	6	--------
	7
	8	Memory mapped netlink I/O can be used to increase throughput and decrease
	9	overhead of unicast receive and transmit operations. Some netlink subsystems
	10	require high throughput, these are mainly the netfilter subsystems
	11	nfnetlink_queue and nfnetlink_log, but it can also help speed up large
	12	dump operations of f.i. the routing database.
	13
	14	Memory mapped netlink I/O used two circular ring buffers for RX and TX which
	15	are mapped into the processes address space.
	16
	17	The RX ring is used by the kernel to directly construct netlink messages into
	18	user-space memory without copying them as done with regular socket I/O,
	19	additionally as long as the ring contains messages no recvmsg() or poll()
	20	syscalls have to be issued by user-space to get more message.
	21
	22	The TX ring is used to process messages directly from user-space memory, the
	23	kernel processes all messages contained in the ring using a single sendmsg()
	24	call.
	25
	26	Usage overview
	27	--------------
	28
	29	In order to use memory mapped netlink I/O, user-space needs three main changes:
	30
	31	- ring setup
	32	- conversion of the RX path to get messages from the ring instead of recvmsg()
	33	- conversion of the TX path to construct messages into the ring
	34
	35	Ring setup is done using setsockopt() to provide the ring parameters to the
	36	kernel, then a call to mmap() to map the ring into the processes address space:
	37
	38	- setsockopt(fd, SOL_NETLINK, NETLINK_RX_RING, &params, sizeof(params));
	39	- setsockopt(fd, SOL_NETLINK, NETLINK_TX_RING, &params, sizeof(params));
	40	- ring = mmap(NULL, size, PROT_READ \| PROT_WRITE, MAP_SHARED, fd, 0)
	41
	42	Usage of either ring is optional, but even if only the RX ring is used the
	43	mapping still needs to be writable in order to update the frame status after
	44	processing.
	45
	46	Conversion of the reception path involves calling poll() on the file
	47	descriptor, once the socket is readable the frames from the ring are
c17cb8b5	48	processed in order until no more messages are available, as indicated by
5683264c PM	49	a status word in the frame header.
	50
	51	On kernel side, in order to make use of memory mapped I/O on receive, the
	52	originating netlink subsystem needs to support memory mapped I/O, otherwise
	53	it will use an allocated socket buffer as usual and the contents will be
	54	copied to the ring on transmission, nullifying most of the performance gains.
	55	Dumps of kernel databases automatically support memory mapped I/O.
	56
f884ab15	57	Conversion of the transmit path involves changing message construction to
5683264c	58	use memory from the TX ring instead of (usually) a buffer declared on the
c17cb8b5	59	stack and setting up the frame header appropriately. Optionally poll() can
5683264c PM	60	be used to wait for free frames in the TX ring.
	61
	62	Structured and definitions for using memory mapped I/O are contained in
	63	<linux/netlink.h>.
	64
	65	RX and TX rings
	66	----------------
	67
f884ab15 AP	68	Each ring contains a number of continuous memory blocks, containing frames of
f884ab15 AP	69	fixed size dependent on the parameters used for ring setup.
5683264c PM	70
	71	Ring: [ block 0 ]
	72	[ frame 0 ]
	73	[ frame 1 ]
	74	[ block 1 ]
	75	[ frame 2 ]
	76	[ frame 3 ]
	77	...
	78	[ block n ]
	79	[ frame 2 * n ]
	80	[ frame 2 * n + 1 ]
	81
	82	The blocks are only visible to the kernel, from the point of view of user-space
f884ab15	83	the ring just contains the frames in a continuous memory zone.
5683264c PM	84
	85	The ring parameters used for setting up the ring are defined as follows:
	86
	87	struct nl_mmap_req {
	88	unsigned int nm_block_size;
	89	unsigned int nm_block_nr;
	90	unsigned int nm_frame_size;
	91	unsigned int nm_frame_nr;
	92	};
	93
f884ab15	94	Frames are grouped into blocks, where each block is a continuous region of memory
5683264c PM	95	and holds nm_block_size / nm_frame_size frames. The total number of frames in
	96	the ring is nm_frame_nr. The following invariants hold:
	97
	98	- frames_per_block = nm_block_size / nm_frame_size
	99
	100	- nm_frame_nr = frames_per_block * nm_block_nr
	101
	102	Some parameters are constrained, specifically:
	103
	104	- nm_block_size must be a multiple of the architectures memory page size.
	105	The getpagesize() function can be used to get the page size.
	106
	107	- nm_frame_size must be equal or larger to NL_MMAP_HDRLEN, IOW a frame must be
	108	able to hold at least the frame header
	109
	110	- nm_frame_size must be smaller or equal to nm_block_size
	111
	112	- nm_frame_size must be a multiple of NL_MMAP_MSG_ALIGNMENT
	113
	114	- nm_frame_nr must equal the actual number of frames as specified above.
	115
f884ab15	116	When the kernel can't allocate physically continuous memory for a ring block,
3dd17ede	117	it will fall back to use physically discontinuous memory. This might affect
5683264c PM	118	performance negatively, in order to avoid this the nm_frame_size parameter
	119	should be chosen to be as small as possible for the required frame size and
	120	the number of blocks should be increased instead.
	121
	122	Ring frames
	123	------------
	124
	125	Each frames contain a frame header, consisting of a synchronization word and some
	126	meta-data, and the message itself.
	127
	128	Frame: [ header message ]
	129
	130	The frame header is defined as follows:
	131
	132	struct nl_mmap_hdr {
	133	unsigned int nm_status;
	134	unsigned int nm_len;
	135	__u32 nm_group;
	136	/* credentials */
	137	__u32 nm_pid;
	138	__u32 nm_uid;
	139	__u32 nm_gid;
	140	};
	141
	142	- nm_status is used for synchronizing processing between the kernel and user-
	143	space and specifies ownership of the frame as well as the operation to perform
	144
	145	- nm_len contains the length of the message contained in the data area
	146
	147	- nm_group specified the destination multicast group of message
	148
	149	- nm_pid, nm_uid and nm_gid contain the netlink pid, UID and GID of the sending
	150	process. These values correspond to the data available using SOCK_PASSCRED in
	151	the SCM_CREDENTIALS cmsg.
	152
	153	The possible values in the status word are:
	154
	155	- NL_MMAP_STATUS_UNUSED:
	156	RX ring: frame belongs to the kernel and contains no message
	157	for user-space. Approriate action is to invoke poll()
	158	to wait for new messages.
	159
	160	TX ring: frame belongs to user-space and can be used for
	161	message construction.
	162
	163	- NL_MMAP_STATUS_RESERVED:
	164	RX ring only: frame is currently used by the kernel for message
	165	construction and contains no valid message yet.
	166	Appropriate action is to invoke poll() to wait for
	167	new messages.
	168
	169	- NL_MMAP_STATUS_VALID:
	170	RX ring: frame contains a valid message. Approriate action is
	171	to process the message and release the frame back to
	172	the kernel by setting the status to
	173	NL_MMAP_STATUS_UNUSED or queue the frame by setting the
	174	status to NL_MMAP_STATUS_SKIP.
	175
	176	TX ring: the frame contains a valid message from user-space to
	177	be processed by the kernel. After completing processing
	178	the kernel will release the frame back to user-space by
	179	setting the status to NL_MMAP_STATUS_UNUSED.
	180
	181	- NL_MMAP_STATUS_COPY:
182	RX ring only: a message is ready to be processed but could not be
183	stored in the ring, either because it exceeded the
184	frame size or because the originating subsystem does
185	not support memory mapped I/O. Appropriate action is
186	to invoke recvmsg() to receive the message and release
187	the frame back to the kernel by setting the status to
188	NL_MMAP_STATUS_UNUSED.
189
190	- NL_MMAP_STATUS_SKIP:
191	RX ring only: user-space queued the message for later processing, but
192	processed some messages following it in the ring. The
193	kernel should skip this frame when looking for unused
194	frames.
195
196	The data area of a frame begins at a offset of NL_MMAP_HDRLEN relative to the
197	frame header.
198
199	TX limitations
200	--------------
201
e6b02be8 RW	202	As of Jan 2015 the message is always copied from the ring frame to an
	203	allocated buffer due to unresolved security concerns.
	204	See commit 4682a0358639b29cf ("netlink: Always copy on mmap TX.").
5683264c PM	205
	206	Example
	207	-------
	208
	209	Ring setup:
	210
	211	unsigned int block_size = 16 * getpagesize();
	212	struct nl_mmap_req req = {
	213	.nm_block_size = block_size,
	214	.nm_block_nr = 64,
	215	.nm_frame_size = 16384,
	216	.nm_frame_nr = 64 * block_size / 16384,
	217	};
	218	unsigned int ring_size;
	219	void rx_ring, tx_ring;
	220
	221	/* Configure ring parameters */
88050049	222	if (setsockopt(fd, SOL_NETLINK, NETLINK_RX_RING, &req, sizeof(req)) < 0)
5683264c	223	exit(1);
88050049	224	if (setsockopt(fd, SOL_NETLINK, NETLINK_TX_RING, &req, sizeof(req)) < 0)
5683264c PM	225	exit(1)
5683264c PM	226
c17cb8b5	227	/* Calculate size of each individual ring */
5683264c PM	228	ring_size = req.nm_block_nr * req.nm_block_size;
	229
	230	/* Map RX/TX rings. The TX ring is located after the RX ring */
	231	rx_ring = mmap(NULL, 2 * ring_size, PROT_READ \| PROT_WRITE,
	232	MAP_SHARED, fd, 0);
	233	if ((long)rx_ring == -1L)
	234	exit(1);
	235	tx_ring = rx_ring + ring_size:
	236
	237	Message reception:
	238
	239	This example assumes some ring parameters of the ring setup are available.
	240
	241	unsigned int frame_offset = 0;
	242	struct nl_mmap_hdr *hdr;
	243	struct nlmsghdr *nlh;
	244	unsigned char buf[16384];
	245	ssize_t len;
	246
	247	while (1) {
	248	struct pollfd pfds[1];
	249
	250	pfds[0].fd = fd;
	251	pfds[0].events = POLLIN \| POLLERR;
	252	pfds[0].revents = 0;
	253
	254	if (poll(pfds, 1, -1) < 0 && errno != -EINTR)
	255	exit(1);
	256
	257	/* Check for errors. Error handling omitted */
	258	if (pfds[0].revents & POLLERR)
	259	<handle error>
	260
	261	/* If no new messages, poll again */
	262	if (!(pfds[0].revents & POLLIN))
	263	continue;
	264
	265	/* Process all frames */
	266	while (1) {
	267	/* Get next frame header */
	268	hdr = rx_ring + frame_offset;
	269
76237576	270	if (hdr->nm_status == NL_MMAP_STATUS_VALID) {
5683264c	271	/* Regular memory mapped frame */
76237576	272	nlh = (void *)hdr + NL_MMAP_HDRLEN;
5683264c PM	273	len = hdr->nm_len;
	274
	275	/* Release empty message immediately. May happen
	276	* on error during message construction.
	277	*/
	278	if (len == 0)
	279	goto release;
	280	} else if (hdr->nm_status == NL_MMAP_STATUS_COPY) {
	281	/* Frame queued to socket receive queue */
	282	len = recv(fd, buf, sizeof(buf), MSG_DONTWAIT);
	283	if (len <= 0)
	284	break;
	285	nlh = buf;
	286	} else
	287	/* No more messages to process, continue polling */
	288	break;
	289
	290	process_msg(nlh);
	291	release:
	292	/* Release frame back to the kernel */
	293	hdr->nm_status = NL_MMAP_STATUS_UNUSED;
	294
	295	/* Advance frame offset to next frame */
	296	frame_offset = (frame_offset + frame_size) % ring_size;
	297	}
	298	}
	299
	300	Message transmission:
	301
	302	This example assumes some ring parameters of the ring setup are available.
	303	A single message is constructed and transmitted, to send multiple messages
	304	at once they would be constructed in consecutive frames before a final call
	305	to sendto().
	306
	307	unsigned int frame_offset = 0;
	308	struct nl_mmap_hdr *hdr;
	309	struct nlmsghdr *nlh;
	310	struct sockaddr_nl addr = {
	311	.nl_family = AF_NETLINK,
	312	};
	313
	314	hdr = tx_ring + frame_offset;
	315	if (hdr->nm_status != NL_MMAP_STATUS_UNUSED)
	316	/* No frame available. Use poll() to avoid. */
	317	exit(1);
	318
	319	nlh = (void *)hdr + NL_MMAP_HDRLEN;
	320
	321	/* Build message */
	322	build_message(nlh);
	323
	324	/* Fill frame header: length and status need to be set */
	325	hdr->nm_len = nlh->nlmsg_len;
	326	hdr->nm_status = NL_MMAP_STATUS_VALID;
	327
	328	if (sendto(fd, NULL, 0, 0, &addr, sizeof(addr)) < 0)
	329	exit(1);
	330
	331	/* Advance frame offset to next frame */
	332	frame_offset = (frame_offset + frame_size) % ring_size;