freebsd-nq/sys/modules/Makefile

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Makefile
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1999-08-28 01:08:13 +00:00
# $FreeBSD$
SYSDIR?=${.CURDIR}/..
.include "${SYSDIR}/conf/kern.opts.mk"
SUBDIR_PARALLEL=
# Modules that include binary-only blobs of microcode should be selectable by
# MK_SOURCELESS_UCODE option (see below).
.if defined(MODULES_OVERRIDE) && !defined(ALL_MODULES)
SUBDIR=${MODULES_OVERRIDE}
.else
2012-06-05 17:44:54 +00:00
SUBDIR= \
${_3dfx} \
${_3dfx_linux} \
${_aac} \
${_aacraid} \
accf_data \
accf_dns \
accf_http \
acl_nfs4 \
acl_posix1e \
${_acpi} \
ae \
${_aesni} \
2008-05-19 01:53:47 +00:00
age \
${_agp} \
aha \
${_ahb} \
Separate the parallel scsi knowledge out of the core of the XPT, and modularize it so that new transports can be created. Add a transport for SATA Add a periph+protocol layer for ATA Add a driver for AHCI-compliant hardware. Add a maxio field to CAM so that drivers can advertise their max I/O capability. Modify various drivers so that they are insulated from the value of MAXPHYS. The new ATA/SATA code supports AHCI-compliant hardware, and will override the classic ATA driver if it is loaded as a module at boot time or compiled into the kernel. The stack now support NCQ (tagged queueing) for increased performance on modern SATA drives. It also supports port multipliers. ATA drives are accessed via 'ada' device nodes. ATAPI drives are accessed via 'cd' device nodes. They can all be enumerated and manipulated via camcontrol, just like SCSI drives. SCSI commands are not translated to their ATA equivalents; ATA native commands are used throughout the entire stack, including camcontrol. See the camcontrol manpage for further details. Testing this code may require that you update your fstab, and possibly modify your BIOS to enable AHCI functionality, if available. This code is very experimental at the moment. The userland ABI/API has changed, so applications will need to be recompiled. It may change further in the near future. The 'ada' device name may also change as more infrastructure is completed in this project. The goal is to eventually put all CAM busses and devices until newbus, allowing for interesting topology and management options. Few functional changes will be seen with existing SCSI/SAS/FC drivers, though the userland ABI has still changed. In the future, transports specific modules for SAS and FC may appear in order to better support the topologies and capabilities of these technologies. The modularization of CAM and the addition of the ATA/SATA modules is meant to break CAM out of the mold of being specific to SCSI, letting it grow to be a framework for arbitrary transports and protocols. It also allows drivers to be written to support discrete hardware without jeopardizing the stability of non-related hardware. While only an AHCI driver is provided now, a Silicon Image driver is also in the works. Drivers for ICH1-4, ICH5-6, PIIX, classic IDE, and any other hardware is possible and encouraged. Help with new transports is also encouraged. Submitted by: scottl, mav Approved by: re
2009-07-10 08:18:08 +00:00
ahci \
${_aic} \
aic7xxx \
alc \
Add ale(4), a driver for Atheros AR8121/AR8113/AR8114 PCIe ethernet controller. The controller is also known as L1E(AR8121) and L2E(AR8113/AR8114). Unlike its predecessor Attansic L1, AR8121/AR8113/AR8114 uses completely different Rx logic such that it requires separate driver. Datasheet for AR81xx is not available to open source driver writers but it shares large part of Tx and PHY logic of L1. I still don't understand some part of register meaning and some MAC statistics counters but the driver seems to have no critical issues for performance and stability. The AR81xx requires copy operation to pass received frames to upper stack such that ale(4) consumes a lot of CPU cycles than that of other controller. A couple of silicon bugs also adds more CPU cycles to address the known hardware bug. However, if you have fast CPU you can still saturate the link. Currently ale(4) supports the following hardware features. - MSI. - TCP Segmentation offload. - Hardware VLAN tag insertion/stripping with checksum offload. - Tx TCP/UDP checksum offload and Rx IP/TCP/UDP checksum offload. - Tx/Rx interrupt moderation. - Hardware statistics counters. - Jumbo frame. - WOL. AR81xx PCIe ethernet controllers are mainly found on ASUS EeePC or P5Q series of ASUS motherboards. Special thanks to Jeremy Chadwick who sent the hardware to me. Without his donation writing a driver for AR81xx would never have been possible. Big thanks to all people who reported feedback or tested patches. HW donated by: koitsu Tested by: bsam, Joao Barros <joao.barros <> gmail DOT com > Jan Henrik Sylvester <me <> janh DOT de > Ivan Brawley < ivan <> brawley DOT id DOT au >, CURRENT ML
2008-11-12 09:52:06 +00:00
ale \
alq \
${_amdsbwd} \
${_amdtemp} \
amr \
${_an} \
${_aout} \
${_apm} \
2005-03-31 20:21:43 +00:00
${_arcmsr} \
${_arcnet} \
${_asmc} \
This is the much rumoured ATA mkIII update that I've been working on. o ATA is now fully newbus'd and split into modules. This means that on a modern system you just load "atapci and ata" to get the base support, and then one or more of the device subdrivers "atadisk atapicd atapifd atapist ataraid". All can be loaded/unloaded anytime, but for obvious reasons you dont want to unload atadisk when you have mounted filesystems. o The device identify part of the probe has been rewritten to fix the problems with odd devices the old had, and to try to remove so of the long delays some HW could provoke. Also probing is done without the need for interrupts, making earlier probing possible. o SATA devices can be hot inserted/removed and devices will be created/ removed in /dev accordingly. NOTE: only supported on controllers that has this feature: Promise and Silicon Image for now. On other controllers the usual atacontrol detach/attach dance is still needed. o Support for "atomic" composite ATA requests used for RAID. o ATA RAID support has been rewritten and and now supports these metadata formats: "Adaptec HostRAID" "Highpoint V2 RocketRAID" "Highpoint V3 RocketRAID" "Intel MatrixRAID" "Integrated Technology Express" "LSILogic V2 MegaRAID" "LSILogic V3 MegaRAID" "Promise FastTrak" "Silicon Image Medley" "FreeBSD PseudoRAID" o Update the ioctl API to match new RAID levels etc. o Update atacontrol to know about the new RAID levels etc NOTE: you need to recompile atacontrol with the new sys/ata.h, make world will take care of that. NOTE2: that rebuild is done differently from the old system as the rebuild is now done piggybacked on read requests to the array, so atacontrol simply starts a background "dd" to rebuild the array. o The reinit code has been worked over to be much more robust. o The timeout code has been overhauled for races. o Support of new chipsets. o Lots of fixes for bugs found while doing the modulerization and reviewing the old code. Missing or changed features from current ATA: o atapi-cd no longer has support for ATAPI changers. Todays its much cheaper and alot faster to copy those CD images to disk and serve them from there. Besides they dont seem to be made anymore, maybe for that exact reason. o ATA RAID can only read metadata from all the above metadata formats, not write all of them (Promise and Highpoint V2 so far). This means that arrays can be picked up from the BIOS, but they cannot be created from FreeBSD. There is more to it than just the missing write metadata support, those formats are not unique to a given controller like Promise and Highpoint formats, instead they exist for several types, and even worse, some controllers can have different formats and its impossible to tell which one. The outcome is that we cannot reliably create the metadata of those formats and be sure the controller BIOS will understand it. However write support is needed to update/fail/rebuild the arrays properly so it sits fairly high on the TODO list. o So far atapicam is not supported with these changes. When/if this will change is up to the maintainer of atapi-cam so go there for questions. HW donated by: Webveveriet AS HW donated by: Frode Nordahl HW donated by: Yahoo! HW donated by: Sentex Patience by: Vife and my boys (and even the cats)
2005-03-30 12:03:40 +00:00
ata \
ath \
ath_pci \
${_autofs} \
${_auxio} \
${_bce} \
bfe \
bhnd \
bge \
bhnd \
${_bxe} \
${_bios} \
${_bktr} \
${_bm} \
2006-07-26 22:10:10 +00:00
bridgestp \
bwi \
bwn \
bwn_pci \
cam \
${_canbepm} \
${_canbus} \
${_cardbus} \
${_carp} \
cas \
${_cbb} \
cc \
cd9660 \
cd9660_iconv \
${_ce} \
${_cfi} \
${_ciss} \
cloudabi \
${_cloudabi32} \
${_cloudabi64} \
${_cm} \
${_cmx} \
${_coff} \
${_coretemp} \
2004-05-17 14:24:52 +00:00
${_cp} \
${_cpsw} \
${_cpuctl} \
${_cpufreq} \
${_crypto} \
${_cryptodev} \
${_cs} \
${_ct} \
${_ctau} \
ctl \
${_cxgb} \
${_cxgbe} \
dc \
dcons \
dcons_crom \
de \
${_dpms} \
${_dpt} \
${_drm} \
${_drm2} \
dummynet \
${_ed} \
Add kernel interfaces to call EFI Runtime Services. Runtime services require special execution environment for the call. Besides that, OS must inform firmware about runtime virtual memory map which will be active during the calls, with the SetVirtualAddressMap() runtime call, done while the 1:1 mapping is still used. There are two complication: the SetVirtualAddressMap() effectively must be done from loader, which needs to know kernel address map in advance. More, despite not explicitely mentioned in the specification, both 1:1 and the map passed to SetVirtualAddressMap() must be active during the SetVirtualAddressMap() call. Second, there are buggy BIOSes which require both mappings active during runtime calls as well, most likely because they fail to identify all relocations to perform. On amd64, we can get rid of both problems by providing 1:1 mapping for the duration of runtime calls, by temprorary remapping user addresses. As result, we avoid the need for loader to know about future kernel address map, and avoid bugs in BIOSes. Typically BIOS only maps something in low 4G. If not runtime bugs, we would take advantage of the DMAP, as previous versions of this patch did. Similar but more complicated trick can be used even for i386 and 32bit runtime, if and when the EFI boot on i386 is supported. We would need a trampoline page, since potentially whole 4G of VA would be switched on calls, instead of only userspace portion on amd64. Context switches are disabled for the duration of the call, FPU access is granted, and interrupts are not disabled. The later is possible because kernel is mapped during calls. To test, the sysctl mib debug.efi_time is provided, setting it to 1 makes one call to EFI get_time() runtime service, on success the efitm structure is printed to the control terminal. Load efirt.ko, or add EFIRT option to the kernel config, to enable code. Discussed with: emaste, imp Tested by: emaste (mac, qemu) Sponsored by: The FreeBSD Foundation MFC after: 2 weeks
2016-09-21 11:31:58 +00:00
${_efirt} \
${_elink} \
${_em} \
en \
${_ep} \
${_epic} \
esp \
${_et} \
evdev \
${_ex} \
${_exca} \
ext2fs \
${_fatm} \
fdc \
2002-10-21 00:38:18 +00:00
fdescfs \
${_fe} \
filemon \
2002-11-07 16:19:43 +00:00
firewire \
firmware \
fuse \
${_fxp} \
o Revert the part of if_gem.c rev. 1.35 which added a call to gem_stop() to gem_attach() as the former access softc members not yet initialized at that time and gem_reset() actually is enough to stop the chip. [1] o Revise the use of gem_bitwait(); add bus_barrier() calls before calling gem_bitwait() to ensure the respective bit has been written before we starting polling on it and poll for the right bits to change, f.e. even though we only reset RX we have to actually wait for both GEM_RESET_RX and GEM_RESET_TX to clear. Add some additional gem_bitwait() calls in places we've been missing them according to the GEM documentation. Along with this some excessive DELAYs, which probably only were added because of bugs in gem_bitwait() and its use in the first place, as well as as have of an gem_bitwait() reimplementation in gem_reset_tx() were removed. o Add gem_reset_rxdma() and use it to deal with GEM_MAC_RX_OVERFLOW errors more gracefully as unlike gem_init_locked() it resets the RX DMA engine only, causing no link loss and the FIFOs not to be cleared. Also use it deal with GEM_INTR_RX_TAG_ERR errors, with previously were unhandled. This was based on information obtained from the Linux GEM and OpenSolaris ERI drivers. o Turn on workarounds for silicon bugs in the Apple GMAC variants. This was based on information obtained from the Darwin GMAC and Linux GEM drivers. o Turn on "infinite" (i.e. maximum 31 * 64 bytes in length) DMA bursts. This greatly improves especially RX performance. o Optimize the RX path, this consists of: - kicking the receiver as soon as we've a spare descriptor in gem_rint() again instead of just once after all the ready ones have been handled; - kicking the receiver the right way, i.e. as outlined in the GEM documentation in batches of 4 and by pointing it to the descriptor after the last valid one; - calling gem_rint() before gem_tint() in gem_intr() as gem_tint() may take quite a while; - doubling the size of the RX ring to 256 descriptors. Overall the RX performance of a GEM in a 1GHz Sun Fire V210 was improved from ~100Mbit/s to ~850Mbit/s. o In gem_add_rxbuf() don't assign the newly allocated mbuf to rxs_mbuf before calling bus_dmamap_load_mbuf_sg(), if bus_dmamap_load_mbuf_sg() fails we'll free the newly allocated mbuf, unable to recycle the previous one but a NULL pointer dereference instead. o In gem_init_locked() honor the return value of gem_meminit(). o Simplify gem_ringsize() and dont' return garbage in the default case. Based on OpenBSD. o Don't turn on MAC control, MIF and PCS interrupts unless GEM_DEBUG is defined as we don't need/use these interrupts for operation. o In gem_start_locked() sync the DMA maps of the descriptor rings before every kick of the transmitter and not just once after enqueuing all packets as the NIC might instantly start transmitting after we kicked it the first time. o Keep state of the link state and use it to enable or disable the MAC in gem_mii_statchg() accordingly as well as to return early from gem_start_locked() in case the link is down. [3] o Initialize the maximum frame size to a sane value. o In gem_mii_statchg() enable carrier extension if appropriate. o Increment if_ierrors in case of an GEM_MAC_RX_OVERFLOW error and in gem_eint(). [3] o Handle IFF_ALLMULTI correctly; don't set it if we've turned promiscuous group mode on and don't clear the flag if we've disabled promiscuous group mode (these were mostly NOPs though). [2] o Let gem_eint() also report GEM_INTR_PERR errors. o Move setting sc_variant from gem_pci_probe() to gem_pci_attach() as device probe methods are not supposed to touch the softc. o Collapse sc_inited and sc_pci into bits for sc_flags. o Add CTASSERTs ensuring that GEM_NRXDESC and GEM_NTXDESC are set to legal values. o Correctly set up for 802.3x flow control, though #ifdef out the code that actually enables it as this needs more testing and mainly a proper framework to support it. o Correct and add some conversions from hard-coded functions names to __func__ which were borked or forgotten in if_gem.c rev. 1.42. o Use PCIR_BAR instead of a homegrown macro. o Replace sc_enaddr[6] with sc_enaddr[ETHER_ADDR_LEN]. o In gem_pci_attach() in case attaching fails release the resources in the opposite order they were allocated. o Make gem_reset() static to if_gem.c as it's not needed outside that module. o Remove the GEM_GIGABIT flag and the associated code; GEM_GIGABIT was never set and the associated code was in the wrong place. o Remove sc_mif_config; it was only used to cache the contents of the respective register within gem_attach(). o Remove the #ifdef'ed out NetBSD/OpenBSD code for establishing a suspend hook as it will never be used on FreeBSD. o Also probe Apple Intrepid 2 GMAC and Apple Shasta GMAC, add support for Apple K2 GMAC. Based on OpenBSD. o Add support for Sun GBE/P cards, or in other words actually add support for cards based on GEM to gem(4). This mainly consists of adding support for the TBI of these chips. Along with this the PHY selection code was rewritten to hardcode the PHY number for certain configurations as for example the PHY of the on-board ERI of Blade 1000 shows up twice causing no link as the second incarnation is isolated. These changes were ported from OpenBSD with some additional improvements and modulo some bugs. o Add code to if_gem_pci.c allowing to read the MAC-address from the VPD on systems without Open Firmware. This is an improved version of my variant of the respective code in if_hme_pci.c o Now that gem(4) is MI enable it for all archs. Pointed out by: yongari [1] Suggested by: rwatson [2], yongari [3] Tested on: i386 (GEM), powerpc (GMACs by marcel and yongari), sparc64 (ERI and GEM) Reviewed by: yongari Approved by: re (kensmith)
2007-09-26 21:14:18 +00:00
gem \
2003-05-31 18:36:41 +00:00
geom \
${_glxiic} \
${_glxsb} \
gpio \
hatm \
hifn \
hme \
${_hpt27xx} \
${_hptiop} \
2004-10-24 08:53:40 +00:00
${_hptmv} \
${_hptnr} \
${_hptrr} \
hwpmc \
${_hyperv} \
i2c \
${_ibcore} \
${_ibcs2} \
${_ichwd} \
${_ida} \
if_bridge \
if_disc \
if_edsc \
${_if_enc} \
if_epair \
${_if_gif} \
${_if_gre} \
${_if_me} \
if_lagg \
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
${_if_ndis} \
${_if_stf} \
if_tap \
if_tun \
2001-09-05 23:47:46 +00:00
if_vlan \
if_vxlan \
2008-02-29 22:42:29 +00:00
${_igb} \
${_iir} \
imgact_binmisc \
${_io} \
${_ioat} \
${_ipoib} \
${_ipdivert} \
${_ipfilter} \
${_ipfw} \
2008-02-29 22:28:18 +00:00
ipfw_nat \
Add ipfw_nat64 module that implements stateless and stateful NAT64. The module works together with ipfw(4) and implemented as its external action module. Stateless NAT64 registers external action with name nat64stl. This keyword should be used to create NAT64 instance and to address this instance in rules. Stateless NAT64 uses two lookup tables with mapped IPv4->IPv6 and IPv6->IPv4 addresses to perform translation. A configuration of instance should looks like this: 1. Create lookup tables: # ipfw table T46 create type addr valtype ipv6 # ipfw table T64 create type addr valtype ipv4 2. Fill T46 and T64 tables. 3. Add rule to allow neighbor solicitation and advertisement: # ipfw add allow icmp6 from any to any icmp6types 135,136 4. Create NAT64 instance: # ipfw nat64stl NAT create table4 T46 table6 T64 5. Add rules that matches the traffic: # ipfw add nat64stl NAT ip from any to table(T46) # ipfw add nat64stl NAT ip from table(T64) to 64:ff9b::/96 6. Configure DNS64 for IPv6 clients and add route to 64:ff9b::/96 via NAT64 host. Stateful NAT64 registers external action with name nat64lsn. The only one option required to create nat64lsn instance - prefix4. It defines the pool of IPv4 addresses used for translation. A configuration of instance should looks like this: 1. Add rule to allow neighbor solicitation and advertisement: # ipfw add allow icmp6 from any to any icmp6types 135,136 2. Create NAT64 instance: # ipfw nat64lsn NAT create prefix4 A.B.C.D/28 3. Add rules that matches the traffic: # ipfw add nat64lsn NAT ip from any to A.B.C.D/28 # ipfw add nat64lsn NAT ip6 from any to 64:ff9b::/96 4. Configure DNS64 for IPv6 clients and add route to 64:ff9b::/96 via NAT64 host. Obtained from: Yandex LLC Relnotes: yes Sponsored by: Yandex LLC Differential Revision: https://reviews.freebsd.org/D6434
2016-08-13 16:09:49 +00:00
${_ipfw_nat64} \
${_ipfw_nptv6} \
${_ipmi} \
ip6_mroute_mod \
2007-10-15 08:26:12 +00:00
ip_mroute_mod \
${_ips} \
${_ipw} \
${_ipwfw} \
${_isci} \
${_iser} \
isp \
${_ispfw} \
${_iwi} \
${_iwifw} \
${_iwm} \
${_iwmfw} \
${_iwn} \
${_iwnfw} \
${_ix} \
${_ixv} \
${_ixgb} \
${_ixl} \
${_ixlv} \
2008-05-27 01:54:45 +00:00
jme \
joy \
kbdmux \
kgssapi \
kgssapi_krb5 \
khelp \
krpc \
ksyms \
le \
lge \
2005-05-06 14:47:54 +00:00
libalias \
libiconv \
libmbpool \
libmchain \
${_linprocfs} \
${_linsysfs} \
${_linux} \
${_linux_common} \
${_linux64} \
linuxkpi \
lmc \
lpt \
mac_biba \
mac_bsdextended \
mac_ifoff \
mac_lomac \
mac_mls \
mac_none \
mac_partition \
mac_portacl \
mac_seeotheruids \
mac_stub \
mac_test \
malo \
md \
mdio \
2004-08-02 19:21:51 +00:00
mem \
mfi \
mii \
mlx \
${_mlx4} \
${_mlx4ib} \
${_mlx4en} \
${_mlx5} \
${_mlx5en} \
${_mly} \
mmc \
mmcsd \
mpr \
mps \
mpt \
2005-11-26 12:46:01 +00:00
mqueue \
mrsas \
msdosfs \
msdosfs_iconv \
${_mse} \
2006-12-13 02:37:48 +00:00
msk \
${_mthca} \
mvs \
mwl \
${_mwlfw} \
mxge \
2003-02-27 14:49:56 +00:00
my \
${_nandfs} \
${_nandsim} \
2014-09-23 05:37:17 +00:00
${_ncr} \
${_nctgpio} \
${_ncv} \
${_ndis} \
netfpga10g \
${_netgraph} \
${_nfe} \
nfscl \
nfscommon \
nfsd \
nfslock \
nfslockd \
nfssvc \
nge \
nmdm \
${_nsp} \
nullfs \
${_ntb} \
${_nvd} \
${_nvme} \
${_nvram} \
2007-10-15 08:26:12 +00:00
${_nxge} \
oce \
otus \
${_otusfw} \
ow \
${_padlock} \
This is the much-discussed major upgrade to the random(4) device, known to you all as /dev/random. This code has had an extensive rewrite and a good series of reviews, both by the author and other parties. This means a lot of code has been simplified. Pluggable structures for high-rate entropy generators are available, and it is most definitely not the case that /dev/random can be driven by only a hardware souce any more. This has been designed out of the device. Hardware sources are stirred into the CSPRNG (Yarrow, Fortuna) like any other entropy source. Pluggable modules may be written by third parties for additional sources. The harvesting structures and consequently the locking have been simplified. Entropy harvesting is done in a more general way (the documentation for this will follow). There is some GREAT entropy to be had in the UMA allocator, but it is disabled for now as messing with that is likely to annoy many people. The venerable (but effective) Yarrow algorithm, which is no longer supported by its authors now has an alternative, Fortuna. For now, Yarrow is retained as the default algorithm, but this may be changed using a kernel option. It is intended to make Fortuna the default algorithm for 11.0. Interested parties are encouraged to read ISBN 978-0-470-47424-2 "Cryptography Engineering" By Ferguson, Schneier and Kohno for Fortuna's gory details. Heck, read it anyway. Many thanks to Arthur Mesh who did early grunt work, and who got caught in the crossfire rather more than he deserved to. My thanks also to folks who helped me thresh this out on whiteboards and in the odd "Hallway track", or otherwise. My Nomex pants are on. Let the feedback commence! Reviewed by: trasz,des(partial),imp(partial?),rwatson(partial?) Approved by: so(des)
2014-10-30 21:21:53 +00:00
${_padlock_rng} \
patm \
${_pccard} \
${_pcfclock} \
pcn \
${_pf} \
${_pflog} \
${_pfsync} \
plip \
${_pmc} \
2015-07-17 20:30:30 +00:00
${_pms} \
ppbus \
ppc \
ppi \
pps \
procfs \
proto \
pseudofs \
${_pst} \
pty \
puc \
${_qlxge} \
${_qlxgb} \
${_qlxgbe} \
ral \
${_ralfw} \
${_random_fortuna} \
${_random_yarrow} \
${_random_other} \
rc4 \
2008-05-05 20:41:54 +00:00
${_rdma} \
This is the much-discussed major upgrade to the random(4) device, known to you all as /dev/random. This code has had an extensive rewrite and a good series of reviews, both by the author and other parties. This means a lot of code has been simplified. Pluggable structures for high-rate entropy generators are available, and it is most definitely not the case that /dev/random can be driven by only a hardware souce any more. This has been designed out of the device. Hardware sources are stirred into the CSPRNG (Yarrow, Fortuna) like any other entropy source. Pluggable modules may be written by third parties for additional sources. The harvesting structures and consequently the locking have been simplified. Entropy harvesting is done in a more general way (the documentation for this will follow). There is some GREAT entropy to be had in the UMA allocator, but it is disabled for now as messing with that is likely to annoy many people. The venerable (but effective) Yarrow algorithm, which is no longer supported by its authors now has an alternative, Fortuna. For now, Yarrow is retained as the default algorithm, but this may be changed using a kernel option. It is intended to make Fortuna the default algorithm for 11.0. Interested parties are encouraged to read ISBN 978-0-470-47424-2 "Cryptography Engineering" By Ferguson, Schneier and Kohno for Fortuna's gory details. Heck, read it anyway. Many thanks to Arthur Mesh who did early grunt work, and who got caught in the crossfire rather more than he deserved to. My thanks also to folks who helped me thresh this out on whiteboards and in the odd "Hallway track", or otherwise. My Nomex pants are on. Let the feedback commence! Reviewed by: trasz,des(partial),imp(partial?),rwatson(partial?) Approved by: so(des)
2014-10-30 21:21:53 +00:00
${_rdrand_rng} \
Take the support for the 8139C+/8169/8169S/8110S chips out of the rl(4) driver and put it in a new re(4) driver. The re(4) driver shares the if_rlreg.h file with rl(4) but is a separate module. (Ultimately I may change this. For now, it's convenient.) rl(4) has been modified so that it will never attach to an 8139C+ chip, leaving it to re(4) instead. Only re(4) has the PCI IDs to match the 8169/8169S/8110S gigE chips. if_re.c contains the same basic code that was originally bolted onto if_rl.c, with the following updates: - Added support for jumbo frames. Currently, there seems to be a limit of approximately 6200 bytes for jumbo frames on transmit. (This was determined via experimentation.) The 8169S/8110S chips apparently are limited to 7.5K frames on transmit. This may require some more work, though the framework to handle jumbo frames on RX is in place: the re_rxeof() routine will gather up frames than span multiple 2K clusters into a single mbuf list. - Fixed bug in re_txeof(): if we reap some of the TX buffers, but there are still some pending, re-arm the timer before exiting re_txeof() so that another timeout interrupt will be generated, just in case re_start() doesn't do it for us. - Handle the 'link state changed' interrupt - Fix a detach bug. If re(4) is loaded as a module, and you do tcpdump -i re0, then you do 'kldunload if_re,' the system will panic after a few seconds. This happens because ether_ifdetach() ends up calling the BPF detach code, which notices the interface is in promiscuous mode and tries to switch promisc mode off while detaching the BPF listner. This ultimately results in a call to re_ioctl() (due to SIOCSIFFLAGS), which in turn calls re_init() to handle the IFF_PROMISC flag change. Unfortunately, calling re_init() here turns the chip back on and restarts the 1-second timeout loop that drives re_tick(). By the time the timeout fires, if_re.ko has been unloaded, which results in a call to invalid code and blows up the system. To fix this, I cleared the IFF_UP flag before calling ether_ifdetach(), which stops the ioctl routine from trying to reset the chip. - Modified comments in re_rxeof() relating to the difference in RX descriptor status bit layout between the 8139C+ and the gigE chips. The layout is different because the frame length field was expanded from 12 bits to 13, and they got rid of one of the status bits to make room. - Add diagnostic code (re_diag()) to test for the case where a user has installed a broken 32-bit 8169 PCI NIC in a 64-bit slot. Some NICs have the REQ64# and ACK64# lines connected even though the board is 32-bit only (in this case, they should be pulled high). This fools the chip into doing 64-bit DMA transfers even though there is no 64-bit data path. To detect this, re_diag() puts the chip into digital loopback mode and sets the receiver to promiscuous mode, then initiates a single 64-byte packet transmission. The frame is echoed back to the host, and if the frame contents are intact, we know DMA is working correctly, otherwise we complain loudly on the console and abort the device attach. (At the moment, I don't know of any way to work around the problem other than physically modifying the board, so until/unless I can think of a software workaround, this will have do to.) - Created re(4) man page - Modified rlphy.c to allow re(4) to attach as well as rl(4). Note that this code works for the sample 8169/Marvell 88E1000 NIC that I have, but probably won't work for the 8169S/8110S chips. RealTek has sent me some sample NICs, but they haven't arrived yet. I will probably need to add an rlgphy driver to handle the on-board PHY in the 8169S/8110S (it needs special DSP initialization).
2003-09-08 02:11:25 +00:00
re \
rl \
rtwn \
rtwn_pci \
rtwn_usb \
${_rtwnfw} \
${_s3} \
${_safe} \
${_sbni} \
scc \
${_scsi_low} \
sdhci \
sdhci_pci \
sem \
send \
${_sf} \
${_sfxge} \
sge \
siba_bwn \
siftr \
siis \
sis \
sk \
smbfs \
sn \
${_snc} \
snp \
sound \
${_speaker} \
${_splash} \
${_sppp} \
ste \
${_stg} \
2006-07-25 00:45:55 +00:00
stge \
${_streams} \
${_svr4} \
${_sym} \
${_syscons} \
sysvipc \
${_ti} \
${_tcp_fastpath} \
tests/framework \
tests/callout_test \
tl \
tmpfs \
${_toecore} \
${_tpm} \
trm \
2004-04-27 17:57:45 +00:00
${_twa} \
2002-10-21 00:38:18 +00:00
twe \
tws \
tx \
${_txp} \
uart \
ubsec \
udf \
udf_iconv \
ufs \
uinput \
unionfs \
2009-02-23 18:32:59 +00:00
usb \
utopia \
${_vesa} \
${_virtio} \
vge \
${_viawd} \
videomode \
vkbd \
${_vmm} \
${_vmware} \
${_vpo} \
vr \
vte \
vx \
${_vxge} \
wb \
${_wbwd} \
${_wi} \
wlan \
wlan_acl \
wlan_amrr \
wlan_ccmp \
wlan_rssadapt \
wlan_tkip \
wlan_wep \
wlan_xauth \
${_wpi} \
${_wpifw} \
${_x86bios} \
${_xe} \
xl \
zlib
.if ${MK_AUTOFS} != "no" || defined(ALL_MODULES)
_autofs= autofs
.endif
.if ${MK_CDDL} != "no" || defined(ALL_MODULES)
.if (${MACHINE_CPUARCH} != "arm" || ${MACHINE_ARCH:Marmv6*} != "") && \
${MACHINE_CPUARCH} != "mips" && \
${MACHINE_CPUARCH} != "sparc64"
SUBDIR+= dtrace
.endif
SUBDIR+= opensolaris
.endif
.if ${MK_CRYPT} != "no" || defined(ALL_MODULES)
.if exists(${.CURDIR}/../opencrypto)
_crypto= crypto
_cryptodev= cryptodev
_random_fortuna=random_fortuna
_random_yarrow= random_yarrow
_random_other= random_other
.endif
.endif
.if ${MK_CUSE} != "no" || defined(ALL_MODULES)
SUBDIR+= cuse
.endif
.if ${MK_EXTRA_TCP_STACKS} != "no" || defined(ALL_MODULES)
_tcp_fastpath= tcp/fastpath
.endif
.if (${MK_INET_SUPPORT} != "no" || ${MK_INET6_SUPPORT} != "no") || \
defined(ALL_MODULES)
_carp= carp
_toecore= toecore
_if_enc= if_enc
_if_gif= if_gif
_if_gre= if_gre
.endif
.if (${MK_INET_SUPPORT} != "no" && ${MK_INET6_SUPPORT} != "no") || \
defined(ALL_MODULES)
_if_stf= if_stf
.endif
.if ${MK_INET_SUPPORT} != "no" || defined(ALL_MODULES)
_if_me= if_me
_ipdivert= ipdivert
_ipfw= ipfw
Add ipfw_nat64 module that implements stateless and stateful NAT64. The module works together with ipfw(4) and implemented as its external action module. Stateless NAT64 registers external action with name nat64stl. This keyword should be used to create NAT64 instance and to address this instance in rules. Stateless NAT64 uses two lookup tables with mapped IPv4->IPv6 and IPv6->IPv4 addresses to perform translation. A configuration of instance should looks like this: 1. Create lookup tables: # ipfw table T46 create type addr valtype ipv6 # ipfw table T64 create type addr valtype ipv4 2. Fill T46 and T64 tables. 3. Add rule to allow neighbor solicitation and advertisement: # ipfw add allow icmp6 from any to any icmp6types 135,136 4. Create NAT64 instance: # ipfw nat64stl NAT create table4 T46 table6 T64 5. Add rules that matches the traffic: # ipfw add nat64stl NAT ip from any to table(T46) # ipfw add nat64stl NAT ip from table(T64) to 64:ff9b::/96 6. Configure DNS64 for IPv6 clients and add route to 64:ff9b::/96 via NAT64 host. Stateful NAT64 registers external action with name nat64lsn. The only one option required to create nat64lsn instance - prefix4. It defines the pool of IPv4 addresses used for translation. A configuration of instance should looks like this: 1. Add rule to allow neighbor solicitation and advertisement: # ipfw add allow icmp6 from any to any icmp6types 135,136 2. Create NAT64 instance: # ipfw nat64lsn NAT create prefix4 A.B.C.D/28 3. Add rules that matches the traffic: # ipfw add nat64lsn NAT ip from any to A.B.C.D/28 # ipfw add nat64lsn NAT ip6 from any to 64:ff9b::/96 4. Configure DNS64 for IPv6 clients and add route to 64:ff9b::/96 via NAT64 host. Obtained from: Yandex LLC Relnotes: yes Sponsored by: Yandex LLC Differential Revision: https://reviews.freebsd.org/D6434
2016-08-13 16:09:49 +00:00
.if ${MK_INET6_SUPPORT} != "no" || defined(ALL_MODULES)
_ipfw_nat64= ipfw_nat64
.endif
.endif
.if ${MK_INET6_SUPPORT} != "no" || defined(ALL_MODULES)
_ipfw_nptv6= ipfw_nptv6
.endif
.if ${MK_IPFILTER} != "no" || defined(ALL_MODULES)
_ipfilter= ipfilter
2002-10-21 00:38:18 +00:00
.endif
.if ${MK_ISCSI} != "no" || defined(ALL_MODULES)
SUBDIR+= iscsi
SUBDIR+= iscsi_initiator
.endif
.if ${MK_NAND} != "no" || defined(ALL_MODULES)
_nandfs= nandfs
_nandsim= nandsim
.endif
.if ${MK_NETGRAPH} != "no" || defined(ALL_MODULES)
_netgraph= netgraph
.endif
.if (${MK_PF} != "no" && (${MK_INET_SUPPORT} != "no" || \
${MK_INET6_SUPPORT} != "no")) || defined(ALL_MODULES)
_pf= pf
_pflog= pflog
.if ${MK_INET_SUPPORT} != "no"
_pfsync= pfsync
.endif
.endif
.if ${MK_SOURCELESS_UCODE} != "no"
_bce= bce
_fatm= fatm
_fxp= fxp
_ispfw= ispfw
_mwlfw= mwlfw
_otusfw= otusfw
_ralfw= ralfw
_rtwnfw= rtwnfw
_sf= sf
_ti= ti
_txp= txp
.endif
.if ${MK_SOURCELESS_UCODE} != "no" && ${MACHINE_CPUARCH} != "arm" && \
${MACHINE_CPUARCH} != "mips" && \
${MACHINE_ARCH} != "powerpc" && ${MACHINE_CPUARCH} != "riscv"
_cxgbe= cxgbe
.endif
.if ${MK_ZFS} != "no" || defined(ALL_MODULES)
SUBDIR+= zfs
.endif
.if ${MACHINE_CPUARCH} != "aarch64" && ${MACHINE_CPUARCH} != "arm" && \
${MACHINE_CPUARCH} != "mips" && ${MACHINE_CPUARCH} != "powerpc" && \
${MACHINE_CPUARCH} != "riscv"
_syscons= syscons
_vpo= vpo
.endif
.if ${MACHINE_CPUARCH} != "mips"
# no BUS_SPACE_UNSPECIFIED
# No barrier instruction support (specific to this driver)
_sym= sym
# intr_disable() is a macro, causes problems
.if ${MK_SOURCELESS_UCODE} != "no"
_cxgb= cxgb
.endif
.endif
.if ${MACHINE_CPUARCH} == "aarch64"
_em= em
_igb= igb
.endif
.if ${MACHINE_CPUARCH} == "i386" || ${MACHINE_CPUARCH} == "amd64"
_agp= agp
_an= an
_aout= aout
_bktr= bktr
_bxe= bxe
_cardbus= cardbus
_cbb= cbb
_cpuctl= cpuctl
_cpufreq= cpufreq
_cs= cs
_dpms= dpms
_drm= drm
_drm2= drm2
_ed= ed
_em= em
_ep= ep
_et= et
_exca= exca
_fe= fe
.if ${MK_OFED} != "no" || defined(ALL_MODULES)
_ibcore= ibcore
.endif
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
_if_ndis= if_ndis
_igb= igb
_io= io
.if ${MK_OFED} != "no" || defined(ALL_MODULES)
_ipoib= ipoib
_iser= iser
.endif
_ix= ix
_ixv= ixv
_linprocfs= linprocfs
_linsysfs= linsysfs
_linux= linux
_nctgpio= nctgpio
_ndis= ndis
_pccard= pccard
.if ${MK_OFED} != "no" || defined(ALL_MODULES)
2008-05-05 20:41:54 +00:00
_rdma= rdma
.endif
_safe= safe
_scsi_low= scsi_low
_speaker= speaker
_splash= splash
_sppp= sppp
_vmware= vmware
_vxge= vxge
_wbwd= wbwd
_wi= wi
_xe= xe
.if ${MACHINE} != "pc98"
_aac= aac
_aacraid= aacraid
_acpi= acpi
.if ${MK_CRYPT} != "no" || defined(ALL_MODULES)
_aesni= aesni
.endif
_amdsbwd= amdsbwd
_amdtemp= amdtemp
_arcmsr= arcmsr
_asmc= asmc
_ciss= ciss
_cmx= cmx
_coretemp= coretemp
.if ${MK_SOURCELESS_HOST} != "no"
_hpt27xx= hpt27xx
.endif
_hptiop= hptiop
.if ${MK_SOURCELESS_HOST} != "no"
2004-10-24 08:53:40 +00:00
_hptmv= hptmv
_hptnr= hptnr
_hptrr= hptrr
.endif
_hyperv= hyperv
2004-05-13 11:13:55 +00:00
_ichwd= ichwd
_ida= ida
_iir= iir
2006-02-14 12:55:07 +00:00
_ipmi= ipmi
_ips= ips
_isci= isci
_ipw= ipw
2006-03-17 13:06:19 +00:00
_iwi= iwi
_iwm= iwm
_iwn= iwn
_ixgb= ixgb
.if ${MK_SOURCELESS_UCODE} != "no"
_ipwfw= ipwfw
_iwifw= iwifw
_iwmfw= iwmfw
_iwnfw= iwnfw
.endif
_mlx4= mlx4
_mlx5= mlx5
.if (${MK_INET_SUPPORT} != "no" && ${MK_INET6_SUPPORT} != "no") || \
defined(ALL_MODULES)
_mlx4en= mlx4en
_mlx5en= mlx5en
.endif
.if ${MK_OFED} != "no" || defined(ALL_MODULES)
_mlx4ib= mlx4ib
.endif
_mly= mly
.if ${MK_OFED} != "no" || defined(ALL_MODULES)
_mthca= mthca
.endif
_nfe= nfe
_nvd= nvd
_nvme= nvme
_nvram= nvram
_nxge= nxge
.if ${MK_CRYPT} != "no" || defined(ALL_MODULES)
_padlock= padlock
This is the much-discussed major upgrade to the random(4) device, known to you all as /dev/random. This code has had an extensive rewrite and a good series of reviews, both by the author and other parties. This means a lot of code has been simplified. Pluggable structures for high-rate entropy generators are available, and it is most definitely not the case that /dev/random can be driven by only a hardware souce any more. This has been designed out of the device. Hardware sources are stirred into the CSPRNG (Yarrow, Fortuna) like any other entropy source. Pluggable modules may be written by third parties for additional sources. The harvesting structures and consequently the locking have been simplified. Entropy harvesting is done in a more general way (the documentation for this will follow). There is some GREAT entropy to be had in the UMA allocator, but it is disabled for now as messing with that is likely to annoy many people. The venerable (but effective) Yarrow algorithm, which is no longer supported by its authors now has an alternative, Fortuna. For now, Yarrow is retained as the default algorithm, but this may be changed using a kernel option. It is intended to make Fortuna the default algorithm for 11.0. Interested parties are encouraged to read ISBN 978-0-470-47424-2 "Cryptography Engineering" By Ferguson, Schneier and Kohno for Fortuna's gory details. Heck, read it anyway. Many thanks to Arthur Mesh who did early grunt work, and who got caught in the crossfire rather more than he deserved to. My thanks also to folks who helped me thresh this out on whiteboards and in the odd "Hallway track", or otherwise. My Nomex pants are on. Let the feedback commence! Reviewed by: trasz,des(partial),imp(partial?),rwatson(partial?) Approved by: so(des)
2014-10-30 21:21:53 +00:00
_padlock_rng= padlock_rng
_rdrand_rng= rdrand_rng
.endif
_s3= s3
_tpm= tpm
2004-04-27 17:57:45 +00:00
_twa= twa
_vesa= vesa
_viawd= viawd
_virtio= virtio
_wpi= wpi
.if ${MK_SOURCELESS_UCODE} != "no"
_wpifw= wpifw
.endif
_x86bios= x86bios
.endif
2002-09-16 08:32:48 +00:00
.endif
.if ${MACHINE_CPUARCH} == "amd64"
Add kernel interfaces to call EFI Runtime Services. Runtime services require special execution environment for the call. Besides that, OS must inform firmware about runtime virtual memory map which will be active during the calls, with the SetVirtualAddressMap() runtime call, done while the 1:1 mapping is still used. There are two complication: the SetVirtualAddressMap() effectively must be done from loader, which needs to know kernel address map in advance. More, despite not explicitely mentioned in the specification, both 1:1 and the map passed to SetVirtualAddressMap() must be active during the SetVirtualAddressMap() call. Second, there are buggy BIOSes which require both mappings active during runtime calls as well, most likely because they fail to identify all relocations to perform. On amd64, we can get rid of both problems by providing 1:1 mapping for the duration of runtime calls, by temprorary remapping user addresses. As result, we avoid the need for loader to know about future kernel address map, and avoid bugs in BIOSes. Typically BIOS only maps something in low 4G. If not runtime bugs, we would take advantage of the DMAP, as previous versions of this patch did. Similar but more complicated trick can be used even for i386 and 32bit runtime, if and when the EFI boot on i386 is supported. We would need a trampoline page, since potentially whole 4G of VA would be switched on calls, instead of only userspace portion on amd64. Context switches are disabled for the duration of the call, FPU access is granted, and interrupts are not disabled. The later is possible because kernel is mapped during calls. To test, the sysctl mib debug.efi_time is provided, setting it to 1 makes one call to EFI get_time() runtime service, on success the efitm structure is printed to the control terminal. Load efirt.ko, or add EFIRT option to the kernel config, to enable code. Discussed with: emaste, imp Tested by: emaste (mac, qemu) Sponsored by: The FreeBSD Foundation MFC after: 2 weeks
2016-09-21 11:31:58 +00:00
_efirt= efirt
_ioat= ioat
_ixl= ixl
_ixlv= ixlv
_linux64= linux64
_linux_common= linux_common
_ntb= ntb
2015-07-17 20:30:30 +00:00
_pms= pms
_qlxge= qlxge
_qlxgb= qlxgb
_qlxgbe= qlxgbe
_sfxge= sfxge
.if ${MK_BHYVE} != "no" || defined(ALL_MODULES)
_vmm= vmm
.endif
.endif
.if ${MACHINE_CPUARCH} == "i386"
# XXX some of these can move to the general case when de-i386'ed
# XXX some of these can move now, but are untested on other architectures.
_3dfx= 3dfx
_3dfx_linux= 3dfx_linux
_aic= aic
_apm= apm
_arcnet= arcnet
.if ${MK_SOURCELESS_UCODE} != "no"
_ce= ce
.endif
_coff= coff
.if ${MK_SOURCELESS_UCODE} != "no"
_cp= cp
.endif
_elink= elink
_glxiic= glxiic
_glxsb= glxsb
#_ibcs2= ibcs2
_mse= mse
_ncr= ncr
_ncv= ncv
_nsp= nsp
_pcfclock= pcfclock
_pst= pst
_sbni= sbni
_streams= streams
_stg= stg
_svr4= svr4
.if ${MACHINE} == "i386"
.if ${MK_EISA} != "no"
_ahb= ahb
.endif
_bios= bios
_cm= cm
.if ${MK_SOURCELESS_UCODE} != "no"
_ctau= ctau
.endif
_dpt= dpt
_ex= ex
.elif ${MACHINE} == "pc98"
_canbepm= canbepm
_canbus= canbus
_ct= ct
_pmc= pmc
_snc= snc
.endif
.endif
.if ${MACHINE_CPUARCH} == "arm"
_cfi= cfi
_cpsw= cpsw
.endif
.if ${MACHINE_CPUARCH} == "powerpc"
_agp= agp
_an= an
_bm= bm
_cardbus= cardbus
_cbb= cbb
_cfi= cfi
_cpufreq= cpufreq
_drm= drm
_exca= exca
_nvram= powermac_nvram
_pccard= pccard
_wi= wi
.endif
2003-01-09 16:37:37 +00:00
.if ${MACHINE_ARCH} == "powerpc64"
_drm2= drm2
.endif
.if ${MACHINE_CPUARCH} == "sparc64"
_auxio= auxio
2005-11-09 08:46:02 +00:00
_em= em
_epic= epic
_igb= igb
.endif
.if (${MACHINE_CPUARCH} == "amd64" || ${MACHINE_ARCH} == "armv6" || \
${MACHINE_CPUARCH} == "i386")
_cloudabi32= cloudabi32
.endif
.if ${MACHINE_CPUARCH} == "aarch64" || ${MACHINE_CPUARCH} == "amd64"
_cloudabi64= cloudabi64
.endif
.endif
SUBDIR+=${MODULES_EXTRA}
.for reject in ${WITHOUT_MODULES}
SUBDIR:= ${SUBDIR:N${reject}}
.endfor
# Calling kldxref(8) for each module is expensive.
2003-01-21 05:52:48 +00:00
.if !defined(NO_XREF)
2003-03-12 14:32:46 +00:00
.MAKEFLAGS+= -DNO_XREF
afterinstall: .PHONY
@if type kldxref >/dev/null 2>&1; then \
${ECHO} kldxref ${DESTDIR}${KMODDIR}; \
kldxref ${DESTDIR}${KMODDIR}; \
fi
.endif
.include "${SYSDIR}/conf/config.mk"
SUBDIR:= ${SUBDIR:u:O}
.include <bsd.subdir.mk>