freebsd-nq/sys/net/if.h

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/*-
* SPDX-License-Identifier: BSD-3-Clause
*
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* Copyright (c) 1982, 1986, 1989, 1993
* The Regents of the University of California. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the University nor the names of its contributors
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* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* @(#)if.h 8.1 (Berkeley) 6/10/93
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* $FreeBSD$
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*/
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#ifndef _NET_IF_H_
#define _NET_IF_H_
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#include <sys/cdefs.h>
#if __BSD_VISIBLE
/*
* <net/if.h> does not depend on <sys/time.h> on most other systems. This
* helps userland compatibility. (struct timeval ifi_lastchange)
* The same holds for <sys/socket.h>. (struct sockaddr ifru_addr)
*/
#ifndef _KERNEL
#include <sys/time.h>
#include <sys/socket.h>
#endif
#endif
/*
* Length of interface external name, including terminating '\0'.
* Note: this is the same size as a generic device's external name.
*/
#define IF_NAMESIZE 16
#if __BSD_VISIBLE
#define IFNAMSIZ IF_NAMESIZE
#define IF_MAXUNIT 0x7fff /* historical value */
#endif
#if __BSD_VISIBLE
/*
* Structure used to query names of interface cloners.
*/
struct if_clonereq {
int ifcr_total; /* total cloners (out) */
int ifcr_count; /* room for this many in user buffer */
char *ifcr_buffer; /* buffer for cloner names */
};
/*
* Structure describing information about an interface
* which may be of interest to management entities.
*/
struct if_data {
/* generic interface information */
uint8_t ifi_type; /* ethernet, tokenring, etc */
uint8_t ifi_physical; /* e.g., AUI, Thinnet, 10base-T, etc */
uint8_t ifi_addrlen; /* media address length */
uint8_t ifi_hdrlen; /* media header length */
uint8_t ifi_link_state; /* current link state */
uint8_t ifi_vhid; /* carp vhid */
uint16_t ifi_datalen; /* length of this data struct */
uint32_t ifi_mtu; /* maximum transmission unit */
uint32_t ifi_metric; /* routing metric (external only) */
uint64_t ifi_baudrate; /* linespeed */
/* volatile statistics */
uint64_t ifi_ipackets; /* packets received on interface */
uint64_t ifi_ierrors; /* input errors on interface */
uint64_t ifi_opackets; /* packets sent on interface */
uint64_t ifi_oerrors; /* output errors on interface */
uint64_t ifi_collisions; /* collisions on csma interfaces */
uint64_t ifi_ibytes; /* total number of octets received */
uint64_t ifi_obytes; /* total number of octets sent */
uint64_t ifi_imcasts; /* packets received via multicast */
uint64_t ifi_omcasts; /* packets sent via multicast */
uint64_t ifi_iqdrops; /* dropped on input */
uint64_t ifi_oqdrops; /* dropped on output */
uint64_t ifi_noproto; /* destined for unsupported protocol */
uint64_t ifi_hwassist; /* HW offload capabilities, see IFCAP */
/* Unions are here to make sizes MI. */
union { /* uptime at attach or stat reset */
time_t tt;
uint64_t ph;
} __ifi_epoch;
#define ifi_epoch __ifi_epoch.tt
union { /* time of last administrative change */
struct timeval tv;
struct {
uint64_t ph1;
uint64_t ph2;
} ph;
} __ifi_lastchange;
#define ifi_lastchange __ifi_lastchange.tv
};
/*-
* Interface flags are of two types: network stack owned flags, and driver
* owned flags. Historically, these values were stored in the same ifnet
* flags field, but with the advent of fine-grained locking, they have been
* broken out such that the network stack is responsible for synchronizing
* the stack-owned fields, and the device driver the device-owned fields.
* Both halves can perform lockless reads of the other half's field, subject
* to accepting the involved races.
*
* Both sets of flags come from the same number space, and should not be
* permitted to conflict, as they are exposed to user space via a single
* field.
*
* The following symbols identify read and write requirements for fields:
*
* (i) if_flags field set by device driver before attach, read-only there
* after.
* (n) if_flags field written only by the network stack, read by either the
* stack or driver.
* (d) if_drv_flags field written only by the device driver, read by either
* the stack or driver.
*/
#define IFF_UP 0x1 /* (n) interface is up */
#define IFF_BROADCAST 0x2 /* (i) broadcast address valid */
#define IFF_DEBUG 0x4 /* (n) turn on debugging */
#define IFF_LOOPBACK 0x8 /* (i) is a loopback net */
#define IFF_POINTOPOINT 0x10 /* (i) is a point-to-point link */
#define IFF_KNOWSEPOCH 0x20 /* (i) calls if_input in net epoch */
#define IFF_DRV_RUNNING 0x40 /* (d) resources allocated */
#define IFF_NOARP 0x80 /* (n) no address resolution protocol */
#define IFF_PROMISC 0x100 /* (n) receive all packets */
#define IFF_ALLMULTI 0x200 /* (n) receive all multicast packets */
#define IFF_DRV_OACTIVE 0x400 /* (d) tx hardware queue is full */
#define IFF_SIMPLEX 0x800 /* (i) can't hear own transmissions */
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#define IFF_LINK0 0x1000 /* per link layer defined bit */
#define IFF_LINK1 0x2000 /* per link layer defined bit */
#define IFF_LINK2 0x4000 /* per link layer defined bit */
#define IFF_ALTPHYS IFF_LINK2 /* use alternate physical connection */
#define IFF_MULTICAST 0x8000 /* (i) supports multicast */
#define IFF_CANTCONFIG 0x10000 /* (i) unconfigurable using ioctl(2) */
#define IFF_PPROMISC 0x20000 /* (n) user-requested promisc mode */
#define IFF_MONITOR 0x40000 /* (n) user-requested monitor mode */
#define IFF_STATICARP 0x80000 /* (n) static ARP */
#define IFF_DYING 0x200000 /* (n) interface is winding down */
#define IFF_RENAMING 0x400000 /* (n) interface is being renamed */
#define IFF_NOGROUP 0x800000 /* (n) interface is not part of any groups */
/*
* Old names for driver flags so that user space tools can continue to use
* the old (portable) names.
*/
#ifndef _KERNEL
#define IFF_RUNNING IFF_DRV_RUNNING
#define IFF_OACTIVE IFF_DRV_OACTIVE
#endif
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/* flags set internally only: */
#define IFF_CANTCHANGE \
(IFF_BROADCAST|IFF_POINTOPOINT|IFF_DRV_RUNNING|IFF_DRV_OACTIVE|\
IFF_SIMPLEX|IFF_MULTICAST|IFF_ALLMULTI|IFF_PROMISC|\
IFF_DYING|IFF_CANTCONFIG|IFF_KNOWSEPOCH)
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/*
* Values for if_link_state.
*/
#define LINK_STATE_UNKNOWN 0 /* link invalid/unknown */
#define LINK_STATE_DOWN 1 /* link is down */
#define LINK_STATE_UP 2 /* link is up */
/*
* Some convenience macros used for setting ifi_baudrate.
* XXX 1000 vs. 1024? --thorpej@netbsd.org
*/
#define IF_Kbps(x) ((uintmax_t)(x) * 1000) /* kilobits/sec. */
#define IF_Mbps(x) (IF_Kbps((x) * 1000)) /* megabits/sec. */
#define IF_Gbps(x) (IF_Mbps((x) * 1000)) /* gigabits/sec. */
/*
* Capabilities that interfaces can advertise.
*
* struct ifnet.if_capabilities
* contains the optional features & capabilities a particular interface
* supports (not only the driver but also the detected hw revision).
* Capabilities are defined by IFCAP_* below.
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* struct ifnet.if_capenable
* contains the enabled (either by default or through ifconfig) optional
* features & capabilities on this interface.
* Capabilities are defined by IFCAP_* below.
* struct if_data.ifi_hwassist in mbuf CSUM_ flag form, controlled by above
* contains the enabled optional feature & capabilites that can be used
* individually per packet and are specified in the mbuf pkthdr.csum_flags
* field. IFCAP_* and CSUM_* do not match one to one and CSUM_* may be
* more detailed or differentiated than IFCAP_*.
* Hwassist features are defined CSUM_* in sys/mbuf.h
*
* Capabilities that cannot be arbitrarily changed with ifconfig/ioctl
* are listed in IFCAP_CANTCHANGE, similar to IFF_CANTCHANGE.
* This is not strictly necessary because the common code never
* changes capabilities, and it is left to the individual driver
* to do the right thing. However, having the filter here
* avoids replication of the same code in all individual drivers.
*/
#define IFCAP_RXCSUM 0x00001 /* can offload checksum on RX */
#define IFCAP_TXCSUM 0x00002 /* can offload checksum on TX */
#define IFCAP_NETCONS 0x00004 /* can be a network console */
#define IFCAP_VLAN_MTU 0x00008 /* VLAN-compatible MTU */
#define IFCAP_VLAN_HWTAGGING 0x00010 /* hardware VLAN tag support */
#define IFCAP_JUMBO_MTU 0x00020 /* 9000 byte MTU supported */
#define IFCAP_POLLING 0x00040 /* driver supports polling */
#define IFCAP_VLAN_HWCSUM 0x00080 /* can do IFCAP_HWCSUM on VLANs */
#define IFCAP_TSO4 0x00100 /* can do TCP Segmentation Offload */
#define IFCAP_TSO6 0x00200 /* can do TCP6 Segmentation Offload */
#define IFCAP_LRO 0x00400 /* can do Large Receive Offload */
#define IFCAP_WOL_UCAST 0x00800 /* wake on any unicast frame */
#define IFCAP_WOL_MCAST 0x01000 /* wake on any multicast frame */
#define IFCAP_WOL_MAGIC 0x02000 /* wake on any Magic Packet */
#define IFCAP_TOE4 0x04000 /* interface can offload TCP */
#define IFCAP_TOE6 0x08000 /* interface can offload TCP6 */
#define IFCAP_VLAN_HWFILTER 0x10000 /* interface hw can filter vlan tag */
/* available 0x20000 */
#define IFCAP_VLAN_HWTSO 0x40000 /* can do IFCAP_TSO on VLANs */
#define IFCAP_LINKSTATE 0x80000 /* the runtime link state is dynamic */
#define IFCAP_NETMAP 0x100000 /* netmap mode supported/enabled */
#define IFCAP_RXCSUM_IPV6 0x200000 /* can offload checksum on IPv6 RX */
#define IFCAP_TXCSUM_IPV6 0x400000 /* can offload checksum on IPv6 TX */
#define IFCAP_HWSTATS 0x800000 /* manages counters internally */
Implement kernel support for hardware rate limited sockets. - Add RATELIMIT kernel configuration keyword which must be set to enable the new functionality. - Add support for hardware driven, Receive Side Scaling, RSS aware, rate limited sendqueues and expose the functionality through the already established SO_MAX_PACING_RATE setsockopt(). The API support rates in the range from 1 to 4Gbytes/s which are suitable for regular TCP and UDP streams. The setsockopt(2) manual page has been updated. - Add rate limit function callback API to "struct ifnet" which supports the following operations: if_snd_tag_alloc(), if_snd_tag_modify(), if_snd_tag_query() and if_snd_tag_free(). - Add support to ifconfig to view, set and clear the IFCAP_TXRTLMT flag, which tells if a network driver supports rate limiting or not. - This patch also adds support for rate limiting through VLAN and LAGG intermediate network devices. - How rate limiting works: 1) The userspace application calls setsockopt() after accepting or making a new connection to set the rate which is then stored in the socket structure in the kernel. Later on when packets are transmitted a check is made in the transmit path for rate changes. A rate change implies a non-blocking ifp->if_snd_tag_alloc() call will be made to the destination network interface, which then sets up a custom sendqueue with the given rate limitation parameter. A "struct m_snd_tag" pointer is returned which serves as a "snd_tag" hint in the m_pkthdr for the subsequently transmitted mbufs. 2) When the network driver sees the "m->m_pkthdr.snd_tag" different from NULL, it will move the packets into a designated rate limited sendqueue given by the snd_tag pointer. It is up to the individual drivers how the rate limited traffic will be rate limited. 3) Route changes are detected by the NIC drivers in the ifp->if_transmit() routine when the ifnet pointer in the incoming snd_tag mismatches the one of the network interface. The network adapter frees the mbuf and returns EAGAIN which causes the ip_output() to release and clear the send tag. Upon next ip_output() a new "snd_tag" will be tried allocated. 4) When the PCB is detached the custom sendqueue will be released by a non-blocking ifp->if_snd_tag_free() call to the currently bound network interface. Reviewed by: wblock (manpages), adrian, gallatin, scottl (network) Differential Revision: https://reviews.freebsd.org/D3687 Sponsored by: Mellanox Technologies MFC after: 3 months
2017-01-18 13:31:17 +00:00
#define IFCAP_TXRTLMT 0x1000000 /* hardware supports TX rate limiting */
#define IFCAP_HWRXTSTMP 0x2000000 /* hardware rx timestamping */
#define IFCAP_MEXTPG 0x4000000 /* understands M_EXTPG mbufs */
Add kernel-side support for in-kernel TLS. KTLS adds support for in-kernel framing and encryption of Transport Layer Security (1.0-1.2) data on TCP sockets. KTLS only supports offload of TLS for transmitted data. Key negotation must still be performed in userland. Once completed, transmit session keys for a connection are provided to the kernel via a new TCP_TXTLS_ENABLE socket option. All subsequent data transmitted on the socket is placed into TLS frames and encrypted using the supplied keys. Any data written to a KTLS-enabled socket via write(2), aio_write(2), or sendfile(2) is assumed to be application data and is encoded in TLS frames with an application data type. Individual records can be sent with a custom type (e.g. handshake messages) via sendmsg(2) with a new control message (TLS_SET_RECORD_TYPE) specifying the record type. At present, rekeying is not supported though the in-kernel framework should support rekeying. KTLS makes use of the recently added unmapped mbufs to store TLS frames in the socket buffer. Each TLS frame is described by a single ext_pgs mbuf. The ext_pgs structure contains the header of the TLS record (and trailer for encrypted records) as well as references to the associated TLS session. KTLS supports two primary methods of encrypting TLS frames: software TLS and ifnet TLS. Software TLS marks mbufs holding socket data as not ready via M_NOTREADY similar to sendfile(2) when TLS framing information is added to an unmapped mbuf in ktls_frame(). ktls_enqueue() is then called to schedule TLS frames for encryption. In the case of sendfile_iodone() calls ktls_enqueue() instead of pru_ready() leaving the mbufs marked M_NOTREADY until encryption is completed. For other writes (vn_sendfile when pages are available, write(2), etc.), the PRUS_NOTREADY is set when invoking pru_send() along with invoking ktls_enqueue(). A pool of worker threads (the "KTLS" kernel process) encrypts TLS frames queued via ktls_enqueue(). Each TLS frame is temporarily mapped using the direct map and passed to a software encryption backend to perform the actual encryption. (Note: The use of PHYS_TO_DMAP could be replaced with sf_bufs if someone wished to make this work on architectures without a direct map.) KTLS supports pluggable software encryption backends. Internally, Netflix uses proprietary pure-software backends. This commit includes a simple backend in a new ktls_ocf.ko module that uses the kernel's OpenCrypto framework to provide AES-GCM encryption of TLS frames. As a result, software TLS is now a bit of a misnomer as it can make use of hardware crypto accelerators. Once software encryption has finished, the TLS frame mbufs are marked ready via pru_ready(). At this point, the encrypted data appears as regular payload to the TCP stack stored in unmapped mbufs. ifnet TLS permits a NIC to offload the TLS encryption and TCP segmentation. In this mode, a new send tag type (IF_SND_TAG_TYPE_TLS) is allocated on the interface a socket is routed over and associated with a TLS session. TLS records for a TLS session using ifnet TLS are not marked M_NOTREADY but are passed down the stack unencrypted. The ip_output_send() and ip6_output_send() helper functions that apply send tags to outbound IP packets verify that the send tag of the TLS record matches the outbound interface. If so, the packet is tagged with the TLS send tag and sent to the interface. The NIC device driver must recognize packets with the TLS send tag and schedule them for TLS encryption and TCP segmentation. If the the outbound interface does not match the interface in the TLS send tag, the packet is dropped. In addition, a task is scheduled to refresh the TLS send tag for the TLS session. If a new TLS send tag cannot be allocated, the connection is dropped. If a new TLS send tag is allocated, however, subsequent packets will be tagged with the correct TLS send tag. (This latter case has been tested by configuring both ports of a Chelsio T6 in a lagg and failing over from one port to another. As the connections migrated to the new port, new TLS send tags were allocated for the new port and connections resumed without being dropped.) ifnet TLS can be enabled and disabled on supported network interfaces via new '[-]txtls[46]' options to ifconfig(8). ifnet TLS is supported across both vlan devices and lagg interfaces using failover, lacp with flowid enabled, or lacp with flowid enabled. Applications may request the current KTLS mode of a connection via a new TCP_TXTLS_MODE socket option. They can also use this socket option to toggle between software and ifnet TLS modes. In addition, a testing tool is available in tools/tools/switch_tls. This is modeled on tcpdrop and uses similar syntax. However, instead of dropping connections, -s is used to force KTLS connections to switch to software TLS and -i is used to switch to ifnet TLS. Various sysctls and counters are available under the kern.ipc.tls sysctl node. The kern.ipc.tls.enable node must be set to true to enable KTLS (it is off by default). The use of unmapped mbufs must also be enabled via kern.ipc.mb_use_ext_pgs to enable KTLS. KTLS is enabled via the KERN_TLS kernel option. This patch is the culmination of years of work by several folks including Scott Long and Randall Stewart for the original design and implementation; Drew Gallatin for several optimizations including the use of ext_pgs mbufs, the M_NOTREADY mechanism for TLS records awaiting software encryption, and pluggable software crypto backends; and John Baldwin for modifications to support hardware TLS offload. Reviewed by: gallatin, hselasky, rrs Obtained from: Netflix Sponsored by: Netflix, Chelsio Communications Differential Revision: https://reviews.freebsd.org/D21277
2019-08-27 00:01:56 +00:00
#define IFCAP_TXTLS4 0x8000000 /* can do TLS encryption and segmentation for TCP */
#define IFCAP_TXTLS6 0x10000000 /* can do TLS encryption and segmentation for TCP6 */
#define IFCAP_VXLAN_HWCSUM 0x20000000 /* can do IFCAN_HWCSUM on VXLANs */
#define IFCAP_VXLAN_HWTSO 0x40000000 /* can do IFCAP_TSO on VXLANs */
Support hardware rate limiting (pacing) with TLS offload. - Add a new send tag type for a send tag that supports both rate limiting (packet pacing) and TLS offload (mostly similar to D22669 but adds a separate structure when allocating the new tag type). - When allocating a send tag for TLS offload, check to see if the connection already has a pacing rate. If so, allocate a tag that supports both rate limiting and TLS offload rather than a plain TLS offload tag. - When setting an initial rate on an existing ifnet KTLS connection, set the rate in the TCP control block inp and then reset the TLS send tag (via ktls_output_eagain) to reallocate a TLS + ratelimit send tag. This allocates the TLS send tag asynchronously from a task queue, so the TLS rate limit tag alloc is always sleepable. - When modifying a rate on a connection using KTLS, look for a TLS send tag. If the send tag is only a plain TLS send tag, assume we failed to allocate a TLS ratelimit tag (either during the TCP_TXTLS_ENABLE socket option, or during the send tag reset triggered by ktls_output_eagain) and ignore the new rate. If the send tag is a ratelimit TLS send tag, change the rate on the TLS tag and leave the inp tag alone. - Lock the inp lock when setting sb_tls_info for a socket send buffer so that the routines in tcp_ratelimit can safely dereference the pointer without needing to grab the socket buffer lock. - Add an IFCAP_TXTLS_RTLMT capability flag and associated administrative controls in ifconfig(8). TLS rate limit tags are only allocated if this capability is enabled. Note that TLS offload (whether unlimited or rate limited) always requires IFCAP_TXTLS[46]. Reviewed by: gallatin, hselasky Relnotes: yes Sponsored by: Netflix Differential Revision: https://reviews.freebsd.org/D26691
2020-10-29 00:23:16 +00:00
#define IFCAP_TXTLS_RTLMT 0x80000000 /* can do TLS with rate limiting */
#define IFCAP_HWCSUM_IPV6 (IFCAP_RXCSUM_IPV6 | IFCAP_TXCSUM_IPV6)
#define IFCAP_HWCSUM (IFCAP_RXCSUM | IFCAP_TXCSUM)
#define IFCAP_TSO (IFCAP_TSO4 | IFCAP_TSO6)
#define IFCAP_WOL (IFCAP_WOL_UCAST | IFCAP_WOL_MCAST | IFCAP_WOL_MAGIC)
#define IFCAP_TOE (IFCAP_TOE4 | IFCAP_TOE6)
Add kernel-side support for in-kernel TLS. KTLS adds support for in-kernel framing and encryption of Transport Layer Security (1.0-1.2) data on TCP sockets. KTLS only supports offload of TLS for transmitted data. Key negotation must still be performed in userland. Once completed, transmit session keys for a connection are provided to the kernel via a new TCP_TXTLS_ENABLE socket option. All subsequent data transmitted on the socket is placed into TLS frames and encrypted using the supplied keys. Any data written to a KTLS-enabled socket via write(2), aio_write(2), or sendfile(2) is assumed to be application data and is encoded in TLS frames with an application data type. Individual records can be sent with a custom type (e.g. handshake messages) via sendmsg(2) with a new control message (TLS_SET_RECORD_TYPE) specifying the record type. At present, rekeying is not supported though the in-kernel framework should support rekeying. KTLS makes use of the recently added unmapped mbufs to store TLS frames in the socket buffer. Each TLS frame is described by a single ext_pgs mbuf. The ext_pgs structure contains the header of the TLS record (and trailer for encrypted records) as well as references to the associated TLS session. KTLS supports two primary methods of encrypting TLS frames: software TLS and ifnet TLS. Software TLS marks mbufs holding socket data as not ready via M_NOTREADY similar to sendfile(2) when TLS framing information is added to an unmapped mbuf in ktls_frame(). ktls_enqueue() is then called to schedule TLS frames for encryption. In the case of sendfile_iodone() calls ktls_enqueue() instead of pru_ready() leaving the mbufs marked M_NOTREADY until encryption is completed. For other writes (vn_sendfile when pages are available, write(2), etc.), the PRUS_NOTREADY is set when invoking pru_send() along with invoking ktls_enqueue(). A pool of worker threads (the "KTLS" kernel process) encrypts TLS frames queued via ktls_enqueue(). Each TLS frame is temporarily mapped using the direct map and passed to a software encryption backend to perform the actual encryption. (Note: The use of PHYS_TO_DMAP could be replaced with sf_bufs if someone wished to make this work on architectures without a direct map.) KTLS supports pluggable software encryption backends. Internally, Netflix uses proprietary pure-software backends. This commit includes a simple backend in a new ktls_ocf.ko module that uses the kernel's OpenCrypto framework to provide AES-GCM encryption of TLS frames. As a result, software TLS is now a bit of a misnomer as it can make use of hardware crypto accelerators. Once software encryption has finished, the TLS frame mbufs are marked ready via pru_ready(). At this point, the encrypted data appears as regular payload to the TCP stack stored in unmapped mbufs. ifnet TLS permits a NIC to offload the TLS encryption and TCP segmentation. In this mode, a new send tag type (IF_SND_TAG_TYPE_TLS) is allocated on the interface a socket is routed over and associated with a TLS session. TLS records for a TLS session using ifnet TLS are not marked M_NOTREADY but are passed down the stack unencrypted. The ip_output_send() and ip6_output_send() helper functions that apply send tags to outbound IP packets verify that the send tag of the TLS record matches the outbound interface. If so, the packet is tagged with the TLS send tag and sent to the interface. The NIC device driver must recognize packets with the TLS send tag and schedule them for TLS encryption and TCP segmentation. If the the outbound interface does not match the interface in the TLS send tag, the packet is dropped. In addition, a task is scheduled to refresh the TLS send tag for the TLS session. If a new TLS send tag cannot be allocated, the connection is dropped. If a new TLS send tag is allocated, however, subsequent packets will be tagged with the correct TLS send tag. (This latter case has been tested by configuring both ports of a Chelsio T6 in a lagg and failing over from one port to another. As the connections migrated to the new port, new TLS send tags were allocated for the new port and connections resumed without being dropped.) ifnet TLS can be enabled and disabled on supported network interfaces via new '[-]txtls[46]' options to ifconfig(8). ifnet TLS is supported across both vlan devices and lagg interfaces using failover, lacp with flowid enabled, or lacp with flowid enabled. Applications may request the current KTLS mode of a connection via a new TCP_TXTLS_MODE socket option. They can also use this socket option to toggle between software and ifnet TLS modes. In addition, a testing tool is available in tools/tools/switch_tls. This is modeled on tcpdrop and uses similar syntax. However, instead of dropping connections, -s is used to force KTLS connections to switch to software TLS and -i is used to switch to ifnet TLS. Various sysctls and counters are available under the kern.ipc.tls sysctl node. The kern.ipc.tls.enable node must be set to true to enable KTLS (it is off by default). The use of unmapped mbufs must also be enabled via kern.ipc.mb_use_ext_pgs to enable KTLS. KTLS is enabled via the KERN_TLS kernel option. This patch is the culmination of years of work by several folks including Scott Long and Randall Stewart for the original design and implementation; Drew Gallatin for several optimizations including the use of ext_pgs mbufs, the M_NOTREADY mechanism for TLS records awaiting software encryption, and pluggable software crypto backends; and John Baldwin for modifications to support hardware TLS offload. Reviewed by: gallatin, hselasky, rrs Obtained from: Netflix Sponsored by: Netflix, Chelsio Communications Differential Revision: https://reviews.freebsd.org/D21277
2019-08-27 00:01:56 +00:00
#define IFCAP_TXTLS (IFCAP_TXTLS4 | IFCAP_TXTLS6)
#define IFCAP_CANTCHANGE (IFCAP_NETMAP)
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#define IFQ_MAXLEN 50
#define IFNET_SLOWHZ 1 /* granularity is 1 second */
/*
* Message format for use in obtaining information about interfaces
* from getkerninfo and the routing socket
* For the new, extensible interface see struct if_msghdrl below.
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*/
struct if_msghdr {
u_short ifm_msglen; /* to skip over non-understood messages */
u_char ifm_version; /* future binary compatibility */
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u_char ifm_type; /* message type */
int ifm_addrs; /* like rtm_addrs */
int ifm_flags; /* value of if_flags */
u_short ifm_index; /* index for associated ifp */
u_short _ifm_spare1;
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struct if_data ifm_data;/* statistics and other data about if */
};
/*
* The 'l' version shall be used by new interfaces, like NET_RT_IFLISTL. It is
* extensible after ifm_data_off or within ifm_data. Both the if_msghdr and
* if_data now have a member field detailing the struct length in addition to
* the routing message length. Macros are provided to find the start of
* ifm_data and the start of the socket address strucutres immediately following
* struct if_msghdrl given a pointer to struct if_msghdrl.
*/
#define IF_MSGHDRL_IFM_DATA(_l) \
(struct if_data *)((char *)(_l) + (_l)->ifm_data_off)
#define IF_MSGHDRL_RTA(_l) \
(void *)((uintptr_t)(_l) + (_l)->ifm_len)
struct if_msghdrl {
u_short ifm_msglen; /* to skip over non-understood messages */
u_char ifm_version; /* future binary compatibility */
u_char ifm_type; /* message type */
int ifm_addrs; /* like rtm_addrs */
int ifm_flags; /* value of if_flags */
u_short ifm_index; /* index for associated ifp */
u_short _ifm_spare1; /* spare space to grow if_index, see if_var.h */
u_short ifm_len; /* length of if_msghdrl incl. if_data */
u_short ifm_data_off; /* offset of if_data from beginning */
int _ifm_spare2;
struct if_data ifm_data;/* statistics and other data about if */
};
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/*
* Message format for use in obtaining information about interface addresses
* from getkerninfo and the routing socket
* For the new, extensible interface see struct ifa_msghdrl below.
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*/
struct ifa_msghdr {
u_short ifam_msglen; /* to skip over non-understood messages */
u_char ifam_version; /* future binary compatibility */
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u_char ifam_type; /* message type */
int ifam_addrs; /* like rtm_addrs */
int ifam_flags; /* value of ifa_flags */
u_short ifam_index; /* index for associated ifp */
u_short _ifam_spare1;
int ifam_metric; /* value of ifa_ifp->if_metric */
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};
/*
* The 'l' version shall be used by new interfaces, like NET_RT_IFLISTL. It is
* extensible after ifam_metric or within ifam_data. Both the ifa_msghdrl and
* if_data now have a member field detailing the struct length in addition to
* the routing message length. Macros are provided to find the start of
* ifm_data and the start of the socket address strucutres immediately following
* struct ifa_msghdrl given a pointer to struct ifa_msghdrl.
*/
#define IFA_MSGHDRL_IFAM_DATA(_l) \
(struct if_data *)((char *)(_l) + (_l)->ifam_data_off)
#define IFA_MSGHDRL_RTA(_l) \
(void *)((uintptr_t)(_l) + (_l)->ifam_len)
struct ifa_msghdrl {
u_short ifam_msglen; /* to skip over non-understood messages */
u_char ifam_version; /* future binary compatibility */
u_char ifam_type; /* message type */
int ifam_addrs; /* like rtm_addrs */
int ifam_flags; /* value of ifa_flags */
u_short ifam_index; /* index for associated ifp */
u_short _ifam_spare1; /* spare space to grow if_index, see if_var.h */
u_short ifam_len; /* length of ifa_msghdrl incl. if_data */
u_short ifam_data_off; /* offset of if_data from beginning */
int ifam_metric; /* value of ifa_ifp->if_metric */
struct if_data ifam_data;/* statistics and other data about if or
* address */
};
/*
* Message format for use in obtaining information about multicast addresses
* from the routing socket
*/
struct ifma_msghdr {
u_short ifmam_msglen; /* to skip over non-understood messages */
u_char ifmam_version; /* future binary compatibility */
u_char ifmam_type; /* message type */
int ifmam_addrs; /* like rtm_addrs */
int ifmam_flags; /* value of ifa_flags */
u_short ifmam_index; /* index for associated ifp */
u_short _ifmam_spare1;
};
/*
* Message format announcing the arrival or departure of a network interface.
*/
struct if_announcemsghdr {
u_short ifan_msglen; /* to skip over non-understood messages */
u_char ifan_version; /* future binary compatibility */
u_char ifan_type; /* message type */
u_short ifan_index; /* index for associated ifp */
char ifan_name[IFNAMSIZ]; /* if name, e.g. "en0" */
u_short ifan_what; /* what type of announcement */
};
#define IFAN_ARRIVAL 0 /* interface arrival */
#define IFAN_DEPARTURE 1 /* interface departure */
/*
* Buffer with length to be used in SIOCGIFDESCR/SIOCSIFDESCR requests
*/
struct ifreq_buffer {
size_t length;
void *buffer;
};
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/*
* Interface request structure used for socket
* ioctl's. All interface ioctl's must have parameter
* definitions which begin with ifr_name. The
* remainder may be interface specific.
*/
struct ifreq {
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char ifr_name[IFNAMSIZ]; /* if name, e.g. "en0" */
union {
struct sockaddr ifru_addr;
struct sockaddr ifru_dstaddr;
struct sockaddr ifru_broadaddr;
struct ifreq_buffer ifru_buffer;
short ifru_flags[2];
short ifru_index;
int ifru_jid;
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int ifru_metric;
int ifru_mtu;
int ifru_phys;
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int ifru_media;
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caddr_t ifru_data;
int ifru_cap[2];
u_int ifru_fib;
u_char ifru_vlan_pcp;
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} ifr_ifru;
#define ifr_addr ifr_ifru.ifru_addr /* address */
#define ifr_dstaddr ifr_ifru.ifru_dstaddr /* other end of p-to-p link */
#define ifr_broadaddr ifr_ifru.ifru_broadaddr /* broadcast address */
#ifndef _KERNEL
#define ifr_buffer ifr_ifru.ifru_buffer /* user supplied buffer with its length */
#endif
#define ifr_flags ifr_ifru.ifru_flags[0] /* flags (low 16 bits) */
#define ifr_flagshigh ifr_ifru.ifru_flags[1] /* flags (high 16 bits) */
#define ifr_jid ifr_ifru.ifru_jid /* jail/vnet */
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#define ifr_metric ifr_ifru.ifru_metric /* metric */
#define ifr_mtu ifr_ifru.ifru_mtu /* mtu */
#define ifr_phys ifr_ifru.ifru_phys /* physical wire */
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#define ifr_media ifr_ifru.ifru_media /* physical media */
#ifndef _KERNEL
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#define ifr_data ifr_ifru.ifru_data /* for use by interface */
#endif
#define ifr_reqcap ifr_ifru.ifru_cap[0] /* requested capabilities */
#define ifr_curcap ifr_ifru.ifru_cap[1] /* current capabilities */
#define ifr_index ifr_ifru.ifru_index /* interface index */
#define ifr_fib ifr_ifru.ifru_fib /* interface fib */
#define ifr_vlan_pcp ifr_ifru.ifru_vlan_pcp /* VLAN priority */
#define ifr_lan_pcp ifr_ifru.ifru_vlan_pcp /* VLAN priority */
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};
#define _SIZEOF_ADDR_IFREQ(ifr) \
((ifr).ifr_addr.sa_len > sizeof(struct sockaddr) ? \
(sizeof(struct ifreq) - sizeof(struct sockaddr) + \
(ifr).ifr_addr.sa_len) : sizeof(struct ifreq))
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struct ifaliasreq {
char ifra_name[IFNAMSIZ]; /* if name, e.g. "en0" */
struct sockaddr ifra_addr;
struct sockaddr ifra_broadaddr;
struct sockaddr ifra_mask;
int ifra_vhid;
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};
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/* 9.x compat */
struct oifaliasreq {
char ifra_name[IFNAMSIZ];
struct sockaddr ifra_addr;
struct sockaddr ifra_broadaddr;
struct sockaddr ifra_mask;
};
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struct ifmediareq {
char ifm_name[IFNAMSIZ]; /* if name, e.g. "en0" */
int ifm_current; /* current media options */
int ifm_mask; /* don't care mask */
int ifm_status; /* media status */
int ifm_active; /* active options */
int ifm_count; /* # entries in ifm_ulist array */
int *ifm_ulist; /* media words */
};
struct ifdrv {
char ifd_name[IFNAMSIZ]; /* if name, e.g. "en0" */
unsigned long ifd_cmd;
size_t ifd_len;
void *ifd_data;
};
/*
* Structure used to retrieve aux status data from interfaces.
* Kernel suppliers to this interface should respect the formatting
* needed by ifconfig(8): each line starts with a TAB and ends with
* a newline. The canonical example to copy and paste is in if_tun.c.
*/
#define IFSTATMAX 800 /* 10 lines of text */
struct ifstat {
char ifs_name[IFNAMSIZ]; /* if name, e.g. "en0" */
char ascii[IFSTATMAX + 1];
};
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/*
* Structure used in SIOCGIFCONF request.
* Used to retrieve interface configuration
* for machine (useful for programs which
* must know all networks accessible).
*/
struct ifconf {
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int ifc_len; /* size of associated buffer */
union {
caddr_t ifcu_buf;
struct ifreq *ifcu_req;
} ifc_ifcu;
#define ifc_buf ifc_ifcu.ifcu_buf /* buffer address */
#define ifc_req ifc_ifcu.ifcu_req /* array of structures returned */
};
/*
* interface groups
*/
#define IFG_ALL "all" /* group contains all interfaces */
/* XXX: will we implement this? */
#define IFG_EGRESS "egress" /* if(s) default route(s) point to */
struct ifg_req {
union {
char ifgrqu_group[IFNAMSIZ];
char ifgrqu_member[IFNAMSIZ];
} ifgrq_ifgrqu;
#define ifgrq_group ifgrq_ifgrqu.ifgrqu_group
#define ifgrq_member ifgrq_ifgrqu.ifgrqu_member
};
/*
* Used to lookup groups for an interface
*/
struct ifgroupreq {
char ifgr_name[IFNAMSIZ];
u_int ifgr_len;
union {
char ifgru_group[IFNAMSIZ];
struct ifg_req *ifgru_groups;
} ifgr_ifgru;
#define ifgr_group ifgr_ifgru.ifgru_group
#define ifgr_groups ifgr_ifgru.ifgru_groups
};
/*
* Structure used to request i2c data
* from interface transceivers.
*/
struct ifi2creq {
uint8_t dev_addr; /* i2c address (0xA0, 0xA2) */
uint8_t offset; /* read offset */
uint8_t len; /* read length */
uint8_t spare0;
uint32_t spare1;
uint8_t data[8]; /* read buffer */
};
/*
* RSS hash.
*/
#define RSS_FUNC_NONE 0 /* RSS disabled */
#define RSS_FUNC_PRIVATE 1 /* non-standard */
#define RSS_FUNC_TOEPLITZ 2
#define RSS_TYPE_IPV4 0x00000001
#define RSS_TYPE_TCP_IPV4 0x00000002
#define RSS_TYPE_IPV6 0x00000004
#define RSS_TYPE_IPV6_EX 0x00000008
#define RSS_TYPE_TCP_IPV6 0x00000010
#define RSS_TYPE_TCP_IPV6_EX 0x00000020
#define RSS_TYPE_UDP_IPV4 0x00000040
#define RSS_TYPE_UDP_IPV6 0x00000080
#define RSS_TYPE_UDP_IPV6_EX 0x00000100
#define RSS_KEYLEN 128
struct ifrsskey {
char ifrk_name[IFNAMSIZ]; /* if name, e.g. "en0" */
uint8_t ifrk_func; /* RSS_FUNC_ */
uint8_t ifrk_spare0;
uint16_t ifrk_keylen;
uint8_t ifrk_key[RSS_KEYLEN];
};
struct ifrsshash {
char ifrh_name[IFNAMSIZ]; /* if name, e.g. "en0" */
uint8_t ifrh_func; /* RSS_FUNC_ */
uint8_t ifrh_spare0;
uint16_t ifrh_spare1;
uint32_t ifrh_types; /* RSS_TYPE_ */
};
#define IFNET_PCP_NONE 0xff /* PCP disabled */
#define IFDR_MSG_SIZE 64
#define IFDR_REASON_MSG 1
#define IFDR_REASON_VENDOR 2
struct ifdownreason {
char ifdr_name[IFNAMSIZ];
uint32_t ifdr_reason;
uint32_t ifdr_vendor;
char ifdr_msg[IFDR_MSG_SIZE];
};
#endif /* __BSD_VISIBLE */
#ifdef _KERNEL
#ifdef MALLOC_DECLARE
MALLOC_DECLARE(M_IFADDR);
MALLOC_DECLARE(M_IFMADDR);
#endif
extern struct sx ifnet_detach_sxlock;
#endif
#ifndef _KERNEL
struct if_nameindex {
unsigned int if_index; /* 1, 2, ... */
char *if_name; /* null terminated name: "le0", ... */
};
__BEGIN_DECLS
void if_freenameindex(struct if_nameindex *);
char *if_indextoname(unsigned int, char *);
struct if_nameindex *if_nameindex(void);
unsigned int if_nametoindex(const char *);
__END_DECLS
#endif
#endif /* !_NET_IF_H_ */