1# 2# Network device configuration 3# 4 5menuconfig NETDEVICES 6 default y if UML 7 depends on NET 8 bool "Network device support" 9 ---help--- 10 You can say N here if you don't intend to connect your Linux box to 11 any other computer at all. 12 13 You'll have to say Y if your computer contains a network card that 14 you want to use under Linux. If you are going to run SLIP or PPP over 15 telephone line or null modem cable you need say Y here. Connecting 16 two machines with parallel ports using PLIP needs this, as well as 17 AX.25/KISS for sending Internet traffic over amateur radio links. 18 19 See also "The Linux Network Administrator's Guide" by Olaf Kirch and 20 Terry Dawson. Available at <http://www.tldp.org/guides.html>. 21 22 If unsure, say Y. 23 24# All the following symbols are dependent on NETDEVICES - do not repeat 25# that for each of the symbols. 26if NETDEVICES 27 28config MII 29 tristate 30 31config NET_CORE 32 default y 33 bool "Network core driver support" 34 ---help--- 35 You can say N here if you do not intend to use any of the 36 networking core drivers (i.e. VLAN, bridging, bonding, etc.) 37 38if NET_CORE 39 40config BONDING 41 tristate "Bonding driver support" 42 depends on INET 43 depends on IPV6 || IPV6=n 44 ---help--- 45 Say 'Y' or 'M' if you wish to be able to 'bond' multiple Ethernet 46 Channels together. This is called 'Etherchannel' by Cisco, 47 'Trunking' by Sun, 802.3ad by the IEEE, and 'Bonding' in Linux. 48 49 The driver supports multiple bonding modes to allow for both high 50 performance and high availability operation. 51 52 Refer to <file:Documentation/networking/bonding.txt> for more 53 information. 54 55 To compile this driver as a module, choose M here: the module 56 will be called bonding. 57 58config DUMMY 59 tristate "Dummy net driver support" 60 ---help--- 61 This is essentially a bit-bucket device (i.e. traffic you send to 62 this device is consigned into oblivion) with a configurable IP 63 address. It is most commonly used in order to make your currently 64 inactive SLIP address seem like a real address for local programs. 65 If you use SLIP or PPP, you might want to say Y here. It won't 66 enlarge your kernel. What a deal. Read about it in the Network 67 Administrator's Guide, available from 68 <http://www.tldp.org/docs.html#guide>. 69 70 To compile this driver as a module, choose M here: the module 71 will be called dummy. 72 73config EQUALIZER 74 tristate "EQL (serial line load balancing) support" 75 ---help--- 76 If you have two serial connections to some other computer (this 77 usually requires two modems and two telephone lines) and you use 78 SLIP (the protocol for sending Internet traffic over telephone 79 lines) or PPP (a better SLIP) on them, you can make them behave like 80 one double speed connection using this driver. Naturally, this has 81 to be supported at the other end as well, either with a similar EQL 82 Linux driver or with a Livingston Portmaster 2e. 83 84 Say Y if you want this and read 85 <file:Documentation/networking/eql.txt>. You may also want to read 86 section 6.2 of the NET-3-HOWTO, available from 87 <http://www.tldp.org/docs.html#howto>. 88 89 To compile this driver as a module, choose M here: the module 90 will be called eql. If unsure, say N. 91 92config NET_FC 93 bool "Fibre Channel driver support" 94 depends on SCSI && PCI 95 help 96 Fibre Channel is a high speed serial protocol mainly used to connect 97 large storage devices to the computer; it is compatible with and 98 intended to replace SCSI. 99 100 If you intend to use Fibre Channel, you need to have a Fibre channel 101 adaptor card in your computer; say Y here and to the driver for your 102 adaptor below. You also should have said Y to "SCSI support" and 103 "SCSI generic support". 104 105config IFB 106 tristate "Intermediate Functional Block support" 107 depends on NET_CLS_ACT 108 ---help--- 109 This is an intermediate driver that allows sharing of 110 resources. 111 To compile this driver as a module, choose M here: the module 112 will be called ifb. If you want to use more than one ifb 113 device at a time, you need to compile this driver as a module. 114 Instead of 'ifb', the devices will then be called 'ifb0', 115 'ifb1' etc. 116 Look at the iproute2 documentation directory for usage etc 117 118source "drivers/net/team/Kconfig" 119 120config MACVLAN 121 tristate "MAC-VLAN support" 122 ---help--- 123 This allows one to create virtual interfaces that map packets to 124 or from specific MAC addresses to a particular interface. 125 126 Macvlan devices can be added using the "ip" command from the 127 iproute2 package starting with the iproute2-2.6.23 release: 128 129 "ip link add link <real dev> [ address MAC ] [ NAME ] type macvlan" 130 131 To compile this driver as a module, choose M here: the module 132 will be called macvlan. 133 134config MACVTAP 135 tristate "MAC-VLAN based tap driver" 136 depends on MACVLAN 137 depends on INET 138 select TAP 139 help 140 This adds a specialized tap character device driver that is based 141 on the MAC-VLAN network interface, called macvtap. A macvtap device 142 can be added in the same way as a macvlan device, using 'type 143 macvtap', and then be accessed through the tap user space interface. 144 145 To compile this driver as a module, choose M here: the module 146 will be called macvtap. 147 148 149config IPVLAN 150 tristate "IP-VLAN support" 151 depends on INET 152 depends on IPV6 || !IPV6 153 depends on NETFILTER 154 select NET_L3_MASTER_DEV 155 ---help--- 156 This allows one to create virtual devices off of a main interface 157 and packets will be delivered based on the dest L3 (IPv6/IPv4 addr) 158 on packets. All interfaces (including the main interface) share L2 159 making it transparent to the connected L2 switch. 160 161 Ipvlan devices can be added using the "ip" command from the 162 iproute2 package starting with the iproute2-3.19 release: 163 164 "ip link add link <main-dev> [ NAME ] type ipvlan" 165 166 To compile this driver as a module, choose M here: the module 167 will be called ipvlan. 168 169config IPVTAP 170 tristate "IP-VLAN based tap driver" 171 depends on IPVLAN 172 depends on INET 173 select TAP 174 ---help--- 175 This adds a specialized tap character device driver that is based 176 on the IP-VLAN network interface, called ipvtap. An ipvtap device 177 can be added in the same way as a ipvlan device, using 'type 178 ipvtap', and then be accessed through the tap user space interface. 179 180 To compile this driver as a module, choose M here: the module 181 will be called ipvtap. 182 183config VXLAN 184 tristate "Virtual eXtensible Local Area Network (VXLAN)" 185 depends on INET 186 select NET_UDP_TUNNEL 187 select GRO_CELLS 188 ---help--- 189 This allows one to create vxlan virtual interfaces that provide 190 Layer 2 Networks over Layer 3 Networks. VXLAN is often used 191 to tunnel virtual network infrastructure in virtualized environments. 192 For more information see: 193 http://tools.ietf.org/html/draft-mahalingam-dutt-dcops-vxlan-02 194 195 To compile this driver as a module, choose M here: the module 196 will be called vxlan. 197 198config GENEVE 199 tristate "Generic Network Virtualization Encapsulation" 200 depends on INET && NET_UDP_TUNNEL 201 depends on IPV6 || !IPV6 202 select NET_IP_TUNNEL 203 select GRO_CELLS 204 ---help--- 205 This allows one to create geneve virtual interfaces that provide 206 Layer 2 Networks over Layer 3 Networks. GENEVE is often used 207 to tunnel virtual network infrastructure in virtualized environments. 208 For more information see: 209 http://tools.ietf.org/html/draft-gross-geneve-02 210 211 To compile this driver as a module, choose M here: the module 212 will be called geneve. 213 214config GTP 215 tristate "GPRS Tunneling Protocol datapath (GTP-U)" 216 depends on INET && NET_UDP_TUNNEL 217 select NET_IP_TUNNEL 218 ---help--- 219 This allows one to create gtp virtual interfaces that provide 220 the GPRS Tunneling Protocol datapath (GTP-U). This tunneling protocol 221 is used to prevent subscribers from accessing mobile carrier core 222 network infrastructure. This driver requires a userspace software that 223 implements the signaling protocol (GTP-C) to update its PDP context 224 base, such as OpenGGSN <http://git.osmocom.org/openggsn/). This 225 tunneling protocol is implemented according to the GSM TS 09.60 and 226 3GPP TS 29.060 standards. 227 228 To compile this drivers as a module, choose M here: the module 229 wil be called gtp. 230 231config MACSEC 232 tristate "IEEE 802.1AE MAC-level encryption (MACsec)" 233 select CRYPTO 234 select CRYPTO_AES 235 select CRYPTO_GCM 236 select GRO_CELLS 237 ---help--- 238 MACsec is an encryption standard for Ethernet. 239 240config NETCONSOLE 241 tristate "Network console logging support" 242 ---help--- 243 If you want to log kernel messages over the network, enable this. 244 See <file:Documentation/networking/netconsole.txt> for details. 245 246config NETCONSOLE_DYNAMIC 247 bool "Dynamic reconfiguration of logging targets" 248 depends on NETCONSOLE && SYSFS && CONFIGFS_FS && \ 249 !(NETCONSOLE=y && CONFIGFS_FS=m) 250 help 251 This option enables the ability to dynamically reconfigure target 252 parameters (interface, IP addresses, port numbers, MAC addresses) 253 at runtime through a userspace interface exported using configfs. 254 See <file:Documentation/networking/netconsole.txt> for details. 255 256config NETPOLL 257 def_bool NETCONSOLE 258 select SRCU 259 260config NET_POLL_CONTROLLER 261 def_bool NETPOLL 262 263config NTB_NETDEV 264 tristate "Virtual Ethernet over NTB Transport" 265 depends on NTB_TRANSPORT 266 267config RIONET 268 tristate "RapidIO Ethernet over messaging driver support" 269 depends on RAPIDIO 270 271config RIONET_TX_SIZE 272 int "Number of outbound queue entries" 273 depends on RIONET 274 default "128" 275 276config RIONET_RX_SIZE 277 int "Number of inbound queue entries" 278 depends on RIONET 279 default "128" 280 281config TUN 282 tristate "Universal TUN/TAP device driver support" 283 depends on INET 284 select CRC32 285 ---help--- 286 TUN/TAP provides packet reception and transmission for user space 287 programs. It can be viewed as a simple Point-to-Point or Ethernet 288 device, which instead of receiving packets from a physical media, 289 receives them from user space program and instead of sending packets 290 via physical media writes them to the user space program. 291 292 When a program opens /dev/net/tun, driver creates and registers 293 corresponding net device tunX or tapX. After a program closed above 294 devices, driver will automatically delete tunXX or tapXX device and 295 all routes corresponding to it. 296 297 Please read <file:Documentation/networking/tuntap.txt> for more 298 information. 299 300 To compile this driver as a module, choose M here: the module 301 will be called tun. 302 303 If you don't know what to use this for, you don't need it. 304 305config TAP 306 tristate 307 ---help--- 308 This option is selected by any driver implementing tap user space 309 interface for a virtual interface to re-use core tap functionality. 310 311config TUN_VNET_CROSS_LE 312 bool "Support for cross-endian vnet headers on little-endian kernels" 313 default n 314 ---help--- 315 This option allows TUN/TAP and MACVTAP device drivers in a 316 little-endian kernel to parse vnet headers that come from a 317 big-endian legacy virtio device. 318 319 Userspace programs can control the feature using the TUNSETVNETBE 320 and TUNGETVNETBE ioctls. 321 322 Unless you have a little-endian system hosting a big-endian virtual 323 machine with a legacy virtio NIC, you should say N. 324 325config VETH 326 tristate "Virtual ethernet pair device" 327 ---help--- 328 This device is a local ethernet tunnel. Devices are created in pairs. 329 When one end receives the packet it appears on its pair and vice 330 versa. 331 332config VIRTIO_NET 333 tristate "Virtio network driver" 334 depends on VIRTIO 335 select NET_FAILOVER 336 ---help--- 337 This is the virtual network driver for virtio. It can be used with 338 QEMU based VMMs (like KVM or Xen). Say Y or M. 339 340config NLMON 341 tristate "Virtual netlink monitoring device" 342 ---help--- 343 This option enables a monitoring net device for netlink skbs. The 344 purpose of this is to analyze netlink messages with packet sockets. 345 Thus applications like tcpdump will be able to see local netlink 346 messages if they tap into the netlink device, record pcaps for further 347 diagnostics, etc. This is mostly intended for developers or support 348 to debug netlink issues. If unsure, say N. 349 350config NET_VRF 351 tristate "Virtual Routing and Forwarding (Lite)" 352 depends on IP_MULTIPLE_TABLES 353 depends on NET_L3_MASTER_DEV 354 depends on IPV6 || IPV6=n 355 depends on IPV6_MULTIPLE_TABLES || IPV6=n 356 ---help--- 357 This option enables the support for mapping interfaces into VRF's. The 358 support enables VRF devices. 359 360config VSOCKMON 361 tristate "Virtual vsock monitoring device" 362 depends on VHOST_VSOCK 363 ---help--- 364 This option enables a monitoring net device for vsock sockets. It is 365 mostly intended for developers or support to debug vsock issues. If 366 unsure, say N. 367 368endif # NET_CORE 369 370config SUNGEM_PHY 371 tristate 372 373source "drivers/net/arcnet/Kconfig" 374 375source "drivers/atm/Kconfig" 376 377source "drivers/net/caif/Kconfig" 378 379source "drivers/net/dsa/Kconfig" 380 381source "drivers/net/ethernet/Kconfig" 382 383source "drivers/net/fddi/Kconfig" 384 385source "drivers/net/hippi/Kconfig" 386 387config NET_SB1000 388 tristate "General Instruments Surfboard 1000" 389 depends on PNP 390 ---help--- 391 This is a driver for the General Instrument (also known as 392 NextLevel) SURFboard 1000 internal 393 cable modem. This is an ISA card which is used by a number of cable 394 TV companies to provide cable modem access. It's a one-way 395 downstream-only cable modem, meaning that your upstream net link is 396 provided by your regular phone modem. 397 398 At present this driver only compiles as a module, so say M here if 399 you have this card. The module will be called sb1000. Then read 400 <file:Documentation/networking/device_drivers/sb1000.txt> for 401 information on how to use this module, as it needs special ppp 402 scripts for establishing a connection. Further documentation 403 and the necessary scripts can be found at: 404 405 <http://www.jacksonville.net/~fventuri/> 406 <http://home.adelphia.net/~siglercm/sb1000.html> 407 <http://linuxpower.cx/~cable/> 408 409 If you don't have this card, of course say N. 410 411source "drivers/net/phy/Kconfig" 412 413source "drivers/net/plip/Kconfig" 414 415source "drivers/net/ppp/Kconfig" 416 417source "drivers/net/slip/Kconfig" 418 419source "drivers/s390/net/Kconfig" 420 421source "drivers/net/usb/Kconfig" 422 423source "drivers/net/wireless/Kconfig" 424 425source "drivers/net/wimax/Kconfig" 426 427source "drivers/net/wan/Kconfig" 428 429source "drivers/net/ieee802154/Kconfig" 430 431config XEN_NETDEV_FRONTEND 432 tristate "Xen network device frontend driver" 433 depends on XEN 434 select XEN_XENBUS_FRONTEND 435 default y 436 help 437 This driver provides support for Xen paravirtual network 438 devices exported by a Xen network driver domain (often 439 domain 0). 440 441 The corresponding Linux backend driver is enabled by the 442 CONFIG_XEN_NETDEV_BACKEND option. 443 444 If you are compiling a kernel for use as Xen guest, you 445 should say Y here. To compile this driver as a module, chose 446 M here: the module will be called xen-netfront. 447 448config XEN_NETDEV_BACKEND 449 tristate "Xen backend network device" 450 depends on XEN_BACKEND 451 help 452 This driver allows the kernel to act as a Xen network driver 453 domain which exports paravirtual network devices to other 454 Xen domains. These devices can be accessed by any operating 455 system that implements a compatible front end. 456 457 The corresponding Linux frontend driver is enabled by the 458 CONFIG_XEN_NETDEV_FRONTEND configuration option. 459 460 The backend driver presents a standard network device 461 endpoint for each paravirtual network device to the driver 462 domain network stack. These can then be bridged or routed 463 etc in order to provide full network connectivity. 464 465 If you are compiling a kernel to run in a Xen network driver 466 domain (often this is domain 0) you should say Y here. To 467 compile this driver as a module, chose M here: the module 468 will be called xen-netback. 469 470config VMXNET3 471 tristate "VMware VMXNET3 ethernet driver" 472 depends on PCI && INET 473 depends on !(PAGE_SIZE_64KB || ARM64_64K_PAGES || \ 474 IA64_PAGE_SIZE_64KB || MICROBLAZE_64K_PAGES || \ 475 PARISC_PAGE_SIZE_64KB || PPC_64K_PAGES) 476 help 477 This driver supports VMware's vmxnet3 virtual ethernet NIC. 478 To compile this driver as a module, choose M here: the 479 module will be called vmxnet3. 480 481config FUJITSU_ES 482 tristate "FUJITSU Extended Socket Network Device driver" 483 depends on ACPI 484 help 485 This driver provides support for Extended Socket network device 486 on Extended Partitioning of FUJITSU PRIMEQUEST 2000 E2 series. 487 488config THUNDERBOLT_NET 489 tristate "Networking over Thunderbolt cable" 490 depends on THUNDERBOLT && INET 491 help 492 Select this if you want to create network between two 493 computers over a Thunderbolt cable. The driver supports Apple 494 ThunderboltIP protocol and allows communication with any host 495 supporting the same protocol including Windows and macOS. 496 497 To compile this driver a module, choose M here. The module will be 498 called thunderbolt-net. 499 500source "drivers/net/hyperv/Kconfig" 501 502config NETDEVSIM 503 tristate "Simulated networking device" 504 depends on DEBUG_FS 505 depends on MAY_USE_DEVLINK 506 help 507 This driver is a developer testing tool and software model that can 508 be used to test various control path networking APIs, especially 509 HW-offload related. 510 511 To compile this driver as a module, choose M here: the module 512 will be called netdevsim. 513 514config NET_FAILOVER 515 tristate "Failover driver" 516 select FAILOVER 517 help 518 This provides an automated failover mechanism via APIs to create 519 and destroy a failover master netdev and manages a primary and 520 standby slave netdevs that get registered via the generic failover 521 infrastructure. This can be used by paravirtual drivers to enable 522 an alternate low latency datapath. It alsoenables live migration of 523 a VM with direct attached VF by failing over to the paravirtual 524 datapath when the VF is unplugged. 525 526endif # NETDEVICES 527