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include
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linux
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ðŸ“
..
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a.out.h
(6.73 KB)
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acct.h
(3.65 KB)
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adb.h
(1.11 KB)
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adfs_fs.h
(936 B)
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affs_hardblocks.h
(1.51 KB)
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agpgart.h
(3.85 KB)
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aio_abi.h
(3.34 KB)
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am437x-vpfe.h
(3.59 KB)
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android
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apm_bios.h
(3.6 KB)
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arcfb.h
(213 B)
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arm_sdei.h
(2.69 KB)
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aspeed-lpc-ctrl.h
(1.74 KB)
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atalk.h
(1023 B)
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atm.h
(7.7 KB)
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atm_eni.h
(648 B)
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atm_he.h
(406 B)
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atm_idt77105.h
(955 B)
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atm_nicstar.h
(1.25 KB)
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atm_tcp.h
(1.58 KB)
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atm_zatm.h
(1.5 KB)
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atmapi.h
(952 B)
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atmarp.h
(1.27 KB)
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atmbr2684.h
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atmclip.h
(576 B)
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atmdev.h
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atmioc.h
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atmlec.h
(2.33 KB)
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atmmpc.h
(4.13 KB)
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atmppp.h
(639 B)
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atmsap.h
(4.85 KB)
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atmsvc.h
(1.81 KB)
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audit.h
(19.92 KB)
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auto_dev-ioctl.h
(4.87 KB)
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auto_fs.h
(6.28 KB)
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auto_fs4.h
(451 B)
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auxvec.h
(1.56 KB)
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ax25.h
(2.76 KB)
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b1lli.h
(1.68 KB)
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batadv_packet.h
(20.01 KB)
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batman_adv.h
(11.7 KB)
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baycom.h
(883 B)
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bcache.h
(8.17 KB)
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bcm933xx_hcs.h
(419 B)
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bfs_fs.h
(1.85 KB)
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binfmts.h
(628 B)
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blkpg.h
(904 B)
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blktrace_api.h
(4.59 KB)
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blkzoned.h
(6.45 KB)
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bpf.h
(223.3 KB)
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bpf_common.h
(1.33 KB)
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bpf_perf_event.h
(529 B)
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bpfilter.h
(465 B)
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bpqether.h
(981 B)
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bsg.h
(2.44 KB)
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bt-bmc.h
(572 B)
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btf.h
(4.68 KB)
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btrfs.h
(28.24 KB)
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btrfs_tree.h
(24.69 KB)
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byteorder
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caif
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can
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can.h
(7.7 KB)
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capability.h
(13.2 KB)
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capi.h
(3.05 KB)
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cciss_defs.h
(3.2 KB)
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cciss_ioctl.h
(2.7 KB)
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cdrom.h
(28.18 KB)
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cec-funcs.h
(52.64 KB)
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cec.h
(36.81 KB)
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cfm_bridge.h
(1.42 KB)
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cgroupstats.h
(2.17 KB)
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chio.h
(5.22 KB)
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cifs
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close_range.h
(377 B)
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cm4000_cs.h
(1.76 KB)
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cn_proc.h
(3.38 KB)
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coda.h
(17.09 KB)
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coda_psdev.h
(783 B)
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coff.h
(12.18 KB)
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connector.h
(2.2 KB)
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const.h
(788 B)
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coresight-stm.h
(674 B)
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cramfs_fs.h
(3.47 KB)
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cryptouser.h
(3.31 KB)
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cuda.h
(905 B)
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cyclades.h
(16.71 KB)
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cycx_cfm.h
(2.92 KB)
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dcbnl.h
(24.65 KB)
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dccp.h
(6.29 KB)
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devlink.h
(21.05 KB)
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dlm.h
(2.49 KB)
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dlm_device.h
(2.48 KB)
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dlm_netlink.h
(1.13 KB)
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dlm_plock.h
(894 B)
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dlmconstants.h
(4.96 KB)
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dm-ioctl.h
(11.13 KB)
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dm-log-userspace.h
(14.83 KB)
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dma-buf.h
(5.12 KB)
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dn.h
(4.53 KB)
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dqblk_xfs.h
(9.03 KB)
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dvb
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edd.h
(5.47 KB)
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efs_fs_sb.h
(2.17 KB)
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elf-em.h
(2.14 KB)
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elf-fdpic.h
(1.1 KB)
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elf.h
(13.16 KB)
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elfcore.h
(2.92 KB)
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errno.h
(23 B)
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errqueue.h
(1.44 KB)
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erspan.h
(1.03 KB)
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ethtool.h
(81.89 KB)
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ethtool_netlink.h
(22.29 KB)
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eventpoll.h
(2.67 KB)
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fadvise.h
(842 B)
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falloc.h
(3.5 KB)
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fanotify.h
(5.22 KB)
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fb.h
(16.09 KB)
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fcntl.h
(4.08 KB)
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fd.h
(11.4 KB)
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fdreg.h
(5.29 KB)
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fib_rules.h
(1.99 KB)
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fiemap.h
(2.71 KB)
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filter.h
(2.16 KB)
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firewire-cdev.h
(42.86 KB)
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firewire-constants.h
(3.16 KB)
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flat.h
(2.1 KB)
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fou.h
(694 B)
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fpga-dfl.h
(8.52 KB)
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fs.h
(13.11 KB)
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fsl_hypervisor.h
(7.13 KB)
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fsmap.h
(4.29 KB)
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fuse.h
(22.92 KB)
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futex.h
(4.88 KB)
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gameport.h
(897 B)
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gen_stats.h
(1.49 KB)
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genetlink.h
(2.12 KB)
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genwqe
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gfs2_ondisk.h
(14.4 KB)
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gigaset_dev.h
(1.41 KB)
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gpio.h
(6.59 KB)
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gsmmux.h
(1.02 KB)
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gtp.h
(681 B)
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hash_info.h
(921 B)
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hdlc
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hdlc.h
(637 B)
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hdlcdrv.h
(2.84 KB)
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hdreg.h
(22.17 KB)
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hid.h
(1.86 KB)
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hiddev.h
(6.2 KB)
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hidraw.h
(1.95 KB)
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hpet.h
(743 B)
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hsi
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hsr_netlink.h
(1.06 KB)
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hw_breakpoint.h
(742 B)
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hyperv.h
(10.89 KB)
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hysdn_if.h
(1.35 KB)
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i2c-dev.h
(2.55 KB)
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i2c.h
(6.96 KB)
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i2o-dev.h
(11.28 KB)
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i8k.h
(1.49 KB)
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icmp.h
(2.91 KB)
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icmpv6.h
(3.94 KB)
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idxd.h
(8.22 KB)
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if.h
(10.65 KB)
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if_addr.h
(1.84 KB)
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if_addrlabel.h
(721 B)
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if_alg.h
(946 B)
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if_arcnet.h
(3.63 KB)
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if_arp.h
(6.42 KB)
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if_bonding.h
(5.17 KB)
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if_bridge.h
(19.06 KB)
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if_cablemodem.h
(986 B)
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if_eql.h
(1.32 KB)
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if_ether.h
(8.05 KB)
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if_fc.h
(1.7 KB)
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if_fddi.h
(3.66 KB)
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if_frad.h
(2.95 KB)
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if_hippi.h
(4.14 KB)
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if_infiniband.h
(1.22 KB)
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if_link.h
(30.28 KB)
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if_ltalk.h
(210 B)
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if_macsec.h
(5.7 KB)
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if_packet.h
(7.73 KB)
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if_phonet.h
(424 B)
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if_plip.h
(660 B)
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if_ppp.h
(29 B)
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if_pppol2tp.h
(3.21 KB)
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if_pppox.h
(4.76 KB)
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if_slip.h
(872 B)
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if_team.h
(2.54 KB)
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if_tun.h
(4 KB)
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if_tunnel.h
(4.41 KB)
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if_vlan.h
(1.79 KB)
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if_x25.h
(881 B)
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if_xdp.h
(2.94 KB)
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ife.h
(351 B)
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igmp.h
(2.99 KB)
ðŸ“
iio
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ila.h
(1.22 KB)
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in.h
(9.78 KB)
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in6.h
(7.26 KB)
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in_route.h
(936 B)
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inet_diag.h
(4.56 KB)
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inotify.h
(3.21 KB)
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input-event-codes.h
(27.94 KB)
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input.h
(15.61 KB)
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io_uring.h
(6.06 KB)
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ioctl.h
(163 B)
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iommu.h
(4.79 KB)
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ip.h
(4.62 KB)
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ip6_tunnel.h
(1.91 KB)
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ip_vs.h
(13.31 KB)
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ipc.h
(2.05 KB)
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ipmi.h
(15.08 KB)
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ipmi_bmc.h
(464 B)
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ipmi_msgdefs.h
(3.35 KB)
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ipmi_ssif_bmc.h
(441 B)
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ipsec.h
(947 B)
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ipv6.h
(3.87 KB)
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ipv6_route.h
(1.86 KB)
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ipx.h
(2.29 KB)
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irqnr.h
(104 B)
ðŸ“
isdn
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isdn.h
(5.64 KB)
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isdn_divertif.h
(1.17 KB)
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isdn_ppp.h
(1.88 KB)
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isdnif.h
(2.31 KB)
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iso_fs.h
(6.33 KB)
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isst_if.h
(5.26 KB)
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ivtv.h
(2.95 KB)
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ivtvfb.h
(1.18 KB)
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jffs2.h
(6.85 KB)
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joystick.h
(3.35 KB)
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kcm.h
(822 B)
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kcmp.h
(522 B)
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kcov.h
(1.07 KB)
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kd.h
(6.11 KB)
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kdev_t.h
(383 B)
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kernel-page-flags.h
(900 B)
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kernel.h
(438 B)
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kernelcapi.h
(1019 B)
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kexec.h
(1.79 KB)
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keyboard.h
(12.48 KB)
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keyctl.h
(3.42 KB)
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kfd_ioctl.h
(28.14 KB)
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kfd_sysfs.h
(4.25 KB)
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kvm.h
(60.12 KB)
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kvm_para.h
(1001 B)
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l2tp.h
(5.46 KB)
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libc-compat.h
(8.09 KB)
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lightnvm.h
(4.92 KB)
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limits.h
(937 B)
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lirc.h
(7.63 KB)
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llc.h
(3.09 KB)
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loop.h
(3.42 KB)
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lp.h
(4.09 KB)
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lwtunnel.h
(2.13 KB)
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magic.h
(3.45 KB)
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major.h
(4.6 KB)
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map_to_7segment.h
(7.08 KB)
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matroxfb.h
(1.43 KB)
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max2175.h
(1.01 KB)
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mdio.h
(16.87 KB)
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media-bus-format.h
(6.26 KB)
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media.h
(11.12 KB)
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mei.h
(3.39 KB)
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membarrier.h
(7.71 KB)
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memfd.h
(1.29 KB)
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mempolicy.h
(2.18 KB)
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meye.h
(2.47 KB)
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mic_common.h
(6.37 KB)
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mic_ioctl.h
(2.2 KB)
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mii.h
(9.27 KB)
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minix_fs.h
(2.07 KB)
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mman.h
(1.35 KB)
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mmc
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mmtimer.h
(2.07 KB)
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module.h
(255 B)
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mount.h
(4.44 KB)
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mpls.h
(2.25 KB)
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mpls_iptunnel.h
(761 B)
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mptcp.h
(5.48 KB)
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mqueue.h
(2.15 KB)
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mroute.h
(5.3 KB)
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mroute6.h
(4.47 KB)
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mrp_bridge.h
(1.67 KB)
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msdos_fs.h
(6.8 KB)
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msg.h
(3.29 KB)
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mtio.h
(7.98 KB)
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n_r3964.h
(2.35 KB)
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nbd-netlink.h
(2.35 KB)
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nbd.h
(2.95 KB)
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ncsi.h
(3.79 KB)
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ndctl.h
(6.71 KB)
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neighbour.h
(5.02 KB)
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net.h
(2.04 KB)
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net_dropmon.h
(2.85 KB)
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net_namespace.h
(715 B)
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net_tstamp.h
(5.67 KB)
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netconf.h
(614 B)
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netdevice.h
(2.2 KB)
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netfilter
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netfilter.h
(1.78 KB)
ðŸ“
netfilter_arp
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netfilter_arp.h
(445 B)
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netfilter_bridge
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netfilter_bridge.h
(1.14 KB)
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netfilter_decnet.h
(1.93 KB)
ðŸ“
netfilter_ipv4
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netfilter_ipv4.h
(2.12 KB)
ðŸ“
netfilter_ipv6
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netfilter_ipv6.h
(2.14 KB)
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netlink.h
(11.23 KB)
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netlink_diag.h
(1.49 KB)
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netrom.h
(807 B)
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nexthop.h
(1.5 KB)
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nfc.h
(10.95 KB)
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nfs.h
(4.39 KB)
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nfs2.h
(1.43 KB)
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nfs3.h
(2.4 KB)
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nfs4.h
(6.44 KB)
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nfs4_mount.h
(1.89 KB)
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nfs_fs.h
(1.6 KB)
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nfs_idmap.h
(2.19 KB)
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nfs_mount.h
(2.09 KB)
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nfsacl.h
(718 B)
ðŸ“
nfsd
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nilfs2_api.h
(7.41 KB)
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nilfs2_ondisk.h
(17.61 KB)
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nitro_enclaves.h
(12.84 KB)
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nl80211.h
(327.41 KB)
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nsfs.h
(639 B)
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nubus.h
(8 KB)
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nvme_ioctl.h
(2.06 KB)
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nvram.h
(532 B)
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omap3isp.h
(20.36 KB)
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omapfb.h
(5.78 KB)
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oom.h
(511 B)
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openat2.h
(1.26 KB)
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openvswitch.h
(39.24 KB)
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packet_diag.h
(1.63 KB)
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param.h
(141 B)
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parport.h
(3.56 KB)
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patchkey.h
(892 B)
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pci.h
(1.35 KB)
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pci_regs.h
(56.47 KB)
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pcitest.h
(711 B)
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perf_event.h
(39.63 KB)
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personality.h
(2.05 KB)
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pfkeyv2.h
(10.32 KB)
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pfrut.h
(7.8 KB)
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pg.h
(2.34 KB)
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phantom.h
(1.62 KB)
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phonet.h
(4.57 KB)
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pkt_cls.h
(18.08 KB)
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pkt_sched.h
(29.59 KB)
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pktcdvd.h
(2.62 KB)
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pmu.h
(5.19 KB)
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poll.h
(22 B)
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posix_acl.h
(1.22 KB)
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posix_acl_xattr.h
(1.09 KB)
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posix_types.h
(1.07 KB)
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ppdev.h
(3.14 KB)
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ppp-comp.h
(2.47 KB)
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ppp-ioctl.h
(5.35 KB)
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ppp_defs.h
(4.99 KB)
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pps.h
(4.62 KB)
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pr.h
(1.05 KB)
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prctl.h
(7.83 KB)
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psample.h
(2.22 KB)
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psci.h
(4.23 KB)
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psp-sev.h
(4.48 KB)
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ptp_clock.h
(7.28 KB)
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ptrace.h
(3.59 KB)
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qemu_fw_cfg.h
(2.41 KB)
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qnx4_fs.h
(2.27 KB)
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qnxtypes.h
(624 B)
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qrtr.h
(893 B)
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quota.h
(6.14 KB)
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radeonfb.h
(360 B)
ðŸ“
raid
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random.h
(1.34 KB)
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raw.h
(365 B)
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rds.h
(9.08 KB)
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reboot.h
(1.31 KB)
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reiserfs_fs.h
(775 B)
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reiserfs_xattr.h
(533 B)
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resource.h
(2.29 KB)
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rfkill.h
(6.45 KB)
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rio_cm_cdev.h
(3.17 KB)
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rio_mport_cdev.h
(9.11 KB)
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romfs_fs.h
(1.21 KB)
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rose.h
(2.18 KB)
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route.h
(2.28 KB)
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rpmsg.h
(544 B)
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rseq.h
(4.79 KB)
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rtc.h
(3.92 KB)
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rtnetlink.h
(19.73 KB)
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rxrpc.h
(4.96 KB)
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scc.h
(4.49 KB)
ðŸ“
sched
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sched.h
(2.73 KB)
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scif_ioctl.h
(6.23 KB)
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screen_info.h
(2.42 KB)
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sctp.h
(35.15 KB)
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sdla.h
(2.77 KB)
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seccomp.h
(2.2 KB)
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securebits.h
(2.64 KB)
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sed-opal.h
(3.2 KB)
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seg6.h
(1.14 KB)
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seg6_genl.h
(589 B)
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seg6_hmac.h
(423 B)
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seg6_iptunnel.h
(927 B)
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seg6_local.h
(2.01 KB)
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selinux_netlink.h
(1.17 KB)
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sem.h
(2.97 KB)
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serial.h
(3.78 KB)
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serial_core.h
(6.1 KB)
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serial_reg.h
(15.13 KB)
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serio.h
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xilinx-v4l2-controls.h
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zorro_ids.h
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Editing: cec-funcs.h
/* SPDX-License-Identifier: ((GPL-2.0 WITH Linux-syscall-note) OR BSD-3-Clause) */ /* * cec - HDMI Consumer Electronics Control message functions * * Copyright 2016 Cisco Systems, Inc. and/or its affiliates. All rights reserved. */ #ifndef _CEC_UAPI_FUNCS_H #define _CEC_UAPI_FUNCS_H #include <linux/cec.h> /* One Touch Play Feature */ static __inline__ void cec_msg_active_source(struct cec_msg *msg, __u16 phys_addr) { msg->len = 4; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_ACTIVE_SOURCE; msg->msg[2] = phys_addr >> 8; msg->msg[3] = phys_addr & 0xff; } static __inline__ void cec_ops_active_source(const struct cec_msg *msg, __u16 *phys_addr) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; } static __inline__ void cec_msg_image_view_on(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_IMAGE_VIEW_ON; } static __inline__ void cec_msg_text_view_on(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_TEXT_VIEW_ON; } /* Routing Control Feature */ static __inline__ void cec_msg_inactive_source(struct cec_msg *msg, __u16 phys_addr) { msg->len = 4; msg->msg[1] = CEC_MSG_INACTIVE_SOURCE; msg->msg[2] = phys_addr >> 8; msg->msg[3] = phys_addr & 0xff; } static __inline__ void cec_ops_inactive_source(const struct cec_msg *msg, __u16 *phys_addr) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; } static __inline__ void cec_msg_request_active_source(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_REQUEST_ACTIVE_SOURCE; msg->reply = reply ? CEC_MSG_ACTIVE_SOURCE : 0; } static __inline__ void cec_msg_routing_information(struct cec_msg *msg, __u16 phys_addr) { msg->len = 4; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_ROUTING_INFORMATION; msg->msg[2] = phys_addr >> 8; msg->msg[3] = phys_addr & 0xff; } static __inline__ void cec_ops_routing_information(const struct cec_msg *msg, __u16 *phys_addr) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; } static __inline__ void cec_msg_routing_change(struct cec_msg *msg, int reply, __u16 orig_phys_addr, __u16 new_phys_addr) { msg->len = 6; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_ROUTING_CHANGE; msg->msg[2] = orig_phys_addr >> 8; msg->msg[3] = orig_phys_addr & 0xff; msg->msg[4] = new_phys_addr >> 8; msg->msg[5] = new_phys_addr & 0xff; msg->reply = reply ? CEC_MSG_ROUTING_INFORMATION : 0; } static __inline__ void cec_ops_routing_change(const struct cec_msg *msg, __u16 *orig_phys_addr, __u16 *new_phys_addr) { *orig_phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *new_phys_addr = (msg->msg[4] << 8) | msg->msg[5]; } static __inline__ void cec_msg_set_stream_path(struct cec_msg *msg, __u16 phys_addr) { msg->len = 4; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_SET_STREAM_PATH; msg->msg[2] = phys_addr >> 8; msg->msg[3] = phys_addr & 0xff; } static __inline__ void cec_ops_set_stream_path(const struct cec_msg *msg, __u16 *phys_addr) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; } /* Standby Feature */ static __inline__ void cec_msg_standby(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_STANDBY; } /* One Touch Record Feature */ static __inline__ void cec_msg_record_off(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_RECORD_OFF; msg->reply = reply ? CEC_MSG_RECORD_STATUS : 0; } struct cec_op_arib_data { __u16 transport_id; __u16 service_id; __u16 orig_network_id; }; struct cec_op_atsc_data { __u16 transport_id; __u16 program_number; }; struct cec_op_dvb_data { __u16 transport_id; __u16 service_id; __u16 orig_network_id; }; struct cec_op_channel_data { __u8 channel_number_fmt; __u16 major; __u16 minor; }; struct cec_op_digital_service_id { __u8 service_id_method; __u8 dig_bcast_system; union { struct cec_op_arib_data arib; struct cec_op_atsc_data atsc; struct cec_op_dvb_data dvb; struct cec_op_channel_data channel; }; }; struct cec_op_record_src { __u8 type; union { struct cec_op_digital_service_id digital; struct { __u8 ana_bcast_type; __u16 ana_freq; __u8 bcast_system; } analog; struct { __u8 plug; } ext_plug; struct { __u16 phys_addr; } ext_phys_addr; }; }; static __inline__ void cec_set_digital_service_id(__u8 *msg, const struct cec_op_digital_service_id *digital) { *msg++ = (digital->service_id_method << 7) | digital->dig_bcast_system; if (digital->service_id_method == CEC_OP_SERVICE_ID_METHOD_BY_CHANNEL) { *msg++ = (digital->channel.channel_number_fmt << 2) | (digital->channel.major >> 8); *msg++ = digital->channel.major & 0xff; *msg++ = digital->channel.minor >> 8; *msg++ = digital->channel.minor & 0xff; *msg++ = 0; *msg++ = 0; return; } switch (digital->dig_bcast_system) { case CEC_OP_DIG_SERVICE_BCAST_SYSTEM_ATSC_GEN: case CEC_OP_DIG_SERVICE_BCAST_SYSTEM_ATSC_CABLE: case CEC_OP_DIG_SERVICE_BCAST_SYSTEM_ATSC_SAT: case CEC_OP_DIG_SERVICE_BCAST_SYSTEM_ATSC_T: *msg++ = digital->atsc.transport_id >> 8; *msg++ = digital->atsc.transport_id & 0xff; *msg++ = digital->atsc.program_number >> 8; *msg++ = digital->atsc.program_number & 0xff; *msg++ = 0; *msg++ = 0; break; default: *msg++ = digital->dvb.transport_id >> 8; *msg++ = digital->dvb.transport_id & 0xff; *msg++ = digital->dvb.service_id >> 8; *msg++ = digital->dvb.service_id & 0xff; *msg++ = digital->dvb.orig_network_id >> 8; *msg++ = digital->dvb.orig_network_id & 0xff; break; } } static __inline__ void cec_get_digital_service_id(const __u8 *msg, struct cec_op_digital_service_id *digital) { digital->service_id_method = msg[0] >> 7; digital->dig_bcast_system = msg[0] & 0x7f; if (digital->service_id_method == CEC_OP_SERVICE_ID_METHOD_BY_CHANNEL) { digital->channel.channel_number_fmt = msg[1] >> 2; digital->channel.major = ((msg[1] & 3) << 6) | msg[2]; digital->channel.minor = (msg[3] << 8) | msg[4]; return; } digital->dvb.transport_id = (msg[1] << 8) | msg[2]; digital->dvb.service_id = (msg[3] << 8) | msg[4]; digital->dvb.orig_network_id = (msg[5] << 8) | msg[6]; } static __inline__ void cec_msg_record_on_own(struct cec_msg *msg) { msg->len = 3; msg->msg[1] = CEC_MSG_RECORD_ON; msg->msg[2] = CEC_OP_RECORD_SRC_OWN; } static __inline__ void cec_msg_record_on_digital(struct cec_msg *msg, const struct cec_op_digital_service_id *digital) { msg->len = 10; msg->msg[1] = CEC_MSG_RECORD_ON; msg->msg[2] = CEC_OP_RECORD_SRC_DIGITAL; cec_set_digital_service_id(msg->msg + 3, digital); } static __inline__ void cec_msg_record_on_analog(struct cec_msg *msg, __u8 ana_bcast_type, __u16 ana_freq, __u8 bcast_system) { msg->len = 7; msg->msg[1] = CEC_MSG_RECORD_ON; msg->msg[2] = CEC_OP_RECORD_SRC_ANALOG; msg->msg[3] = ana_bcast_type; msg->msg[4] = ana_freq >> 8; msg->msg[5] = ana_freq & 0xff; msg->msg[6] = bcast_system; } static __inline__ void cec_msg_record_on_plug(struct cec_msg *msg, __u8 plug) { msg->len = 4; msg->msg[1] = CEC_MSG_RECORD_ON; msg->msg[2] = CEC_OP_RECORD_SRC_EXT_PLUG; msg->msg[3] = plug; } static __inline__ void cec_msg_record_on_phys_addr(struct cec_msg *msg, __u16 phys_addr) { msg->len = 5; msg->msg[1] = CEC_MSG_RECORD_ON; msg->msg[2] = CEC_OP_RECORD_SRC_EXT_PHYS_ADDR; msg->msg[3] = phys_addr >> 8; msg->msg[4] = phys_addr & 0xff; } static __inline__ void cec_msg_record_on(struct cec_msg *msg, int reply, const struct cec_op_record_src *rec_src) { switch (rec_src->type) { case CEC_OP_RECORD_SRC_OWN: cec_msg_record_on_own(msg); break; case CEC_OP_RECORD_SRC_DIGITAL: cec_msg_record_on_digital(msg, &rec_src->digital); break; case CEC_OP_RECORD_SRC_ANALOG: cec_msg_record_on_analog(msg, rec_src->analog.ana_bcast_type, rec_src->analog.ana_freq, rec_src->analog.bcast_system); break; case CEC_OP_RECORD_SRC_EXT_PLUG: cec_msg_record_on_plug(msg, rec_src->ext_plug.plug); break; case CEC_OP_RECORD_SRC_EXT_PHYS_ADDR: cec_msg_record_on_phys_addr(msg, rec_src->ext_phys_addr.phys_addr); break; } msg->reply = reply ? CEC_MSG_RECORD_STATUS : 0; } static __inline__ void cec_ops_record_on(const struct cec_msg *msg, struct cec_op_record_src *rec_src) { rec_src->type = msg->msg[2]; switch (rec_src->type) { case CEC_OP_RECORD_SRC_OWN: break; case CEC_OP_RECORD_SRC_DIGITAL: cec_get_digital_service_id(msg->msg + 3, &rec_src->digital); break; case CEC_OP_RECORD_SRC_ANALOG: rec_src->analog.ana_bcast_type = msg->msg[3]; rec_src->analog.ana_freq = (msg->msg[4] << 8) | msg->msg[5]; rec_src->analog.bcast_system = msg->msg[6]; break; case CEC_OP_RECORD_SRC_EXT_PLUG: rec_src->ext_plug.plug = msg->msg[3]; break; case CEC_OP_RECORD_SRC_EXT_PHYS_ADDR: rec_src->ext_phys_addr.phys_addr = (msg->msg[3] << 8) | msg->msg[4]; break; } } static __inline__ void cec_msg_record_status(struct cec_msg *msg, __u8 rec_status) { msg->len = 3; msg->msg[1] = CEC_MSG_RECORD_STATUS; msg->msg[2] = rec_status; } static __inline__ void cec_ops_record_status(const struct cec_msg *msg, __u8 *rec_status) { *rec_status = msg->msg[2]; } static __inline__ void cec_msg_record_tv_screen(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_RECORD_TV_SCREEN; msg->reply = reply ? CEC_MSG_RECORD_ON : 0; } /* Timer Programming Feature */ static __inline__ void cec_msg_timer_status(struct cec_msg *msg, __u8 timer_overlap_warning, __u8 media_info, __u8 prog_info, __u8 prog_error, __u8 duration_hr, __u8 duration_min) { msg->len = 3; msg->msg[1] = CEC_MSG_TIMER_STATUS; msg->msg[2] = (timer_overlap_warning << 7) | (media_info << 5) | (prog_info ? 0x10 : 0) | (prog_info ? prog_info : prog_error); if (prog_info == CEC_OP_PROG_INFO_NOT_ENOUGH_SPACE || prog_info == CEC_OP_PROG_INFO_MIGHT_NOT_BE_ENOUGH_SPACE || prog_error == CEC_OP_PROG_ERROR_DUPLICATE) { msg->len += 2; msg->msg[3] = ((duration_hr / 10) << 4) | (duration_hr % 10); msg->msg[4] = ((duration_min / 10) << 4) | (duration_min % 10); } } static __inline__ void cec_ops_timer_status(const struct cec_msg *msg, __u8 *timer_overlap_warning, __u8 *media_info, __u8 *prog_info, __u8 *prog_error, __u8 *duration_hr, __u8 *duration_min) { *timer_overlap_warning = msg->msg[2] >> 7; *media_info = (msg->msg[2] >> 5) & 3; if (msg->msg[2] & 0x10) { *prog_info = msg->msg[2] & 0xf; *prog_error = 0; } else { *prog_info = 0; *prog_error = msg->msg[2] & 0xf; } if (*prog_info == CEC_OP_PROG_INFO_NOT_ENOUGH_SPACE || *prog_info == CEC_OP_PROG_INFO_MIGHT_NOT_BE_ENOUGH_SPACE || *prog_error == CEC_OP_PROG_ERROR_DUPLICATE) { *duration_hr = (msg->msg[3] >> 4) * 10 + (msg->msg[3] & 0xf); *duration_min = (msg->msg[4] >> 4) * 10 + (msg->msg[4] & 0xf); } else { *duration_hr = *duration_min = 0; } } static __inline__ void cec_msg_timer_cleared_status(struct cec_msg *msg, __u8 timer_cleared_status) { msg->len = 3; msg->msg[1] = CEC_MSG_TIMER_CLEARED_STATUS; msg->msg[2] = timer_cleared_status; } static __inline__ void cec_ops_timer_cleared_status(const struct cec_msg *msg, __u8 *timer_cleared_status) { *timer_cleared_status = msg->msg[2]; } static __inline__ void cec_msg_clear_analogue_timer(struct cec_msg *msg, int reply, __u8 day, __u8 month, __u8 start_hr, __u8 start_min, __u8 duration_hr, __u8 duration_min, __u8 recording_seq, __u8 ana_bcast_type, __u16 ana_freq, __u8 bcast_system) { msg->len = 13; msg->msg[1] = CEC_MSG_CLEAR_ANALOGUE_TIMER; msg->msg[2] = day; msg->msg[3] = month; /* Hours and minutes are in BCD format */ msg->msg[4] = ((start_hr / 10) << 4) | (start_hr % 10); msg->msg[5] = ((start_min / 10) << 4) | (start_min % 10); msg->msg[6] = ((duration_hr / 10) << 4) | (duration_hr % 10); msg->msg[7] = ((duration_min / 10) << 4) | (duration_min % 10); msg->msg[8] = recording_seq; msg->msg[9] = ana_bcast_type; msg->msg[10] = ana_freq >> 8; msg->msg[11] = ana_freq & 0xff; msg->msg[12] = bcast_system; msg->reply = reply ? CEC_MSG_TIMER_CLEARED_STATUS : 0; } static __inline__ void cec_ops_clear_analogue_timer(const struct cec_msg *msg, __u8 *day, __u8 *month, __u8 *start_hr, __u8 *start_min, __u8 *duration_hr, __u8 *duration_min, __u8 *recording_seq, __u8 *ana_bcast_type, __u16 *ana_freq, __u8 *bcast_system) { *day = msg->msg[2]; *month = msg->msg[3]; /* Hours and minutes are in BCD format */ *start_hr = (msg->msg[4] >> 4) * 10 + (msg->msg[4] & 0xf); *start_min = (msg->msg[5] >> 4) * 10 + (msg->msg[5] & 0xf); *duration_hr = (msg->msg[6] >> 4) * 10 + (msg->msg[6] & 0xf); *duration_min = (msg->msg[7] >> 4) * 10 + (msg->msg[7] & 0xf); *recording_seq = msg->msg[8]; *ana_bcast_type = msg->msg[9]; *ana_freq = (msg->msg[10] << 8) | msg->msg[11]; *bcast_system = msg->msg[12]; } static __inline__ void cec_msg_clear_digital_timer(struct cec_msg *msg, int reply, __u8 day, __u8 month, __u8 start_hr, __u8 start_min, __u8 duration_hr, __u8 duration_min, __u8 recording_seq, const struct cec_op_digital_service_id *digital) { msg->len = 16; msg->reply = reply ? CEC_MSG_TIMER_CLEARED_STATUS : 0; msg->msg[1] = CEC_MSG_CLEAR_DIGITAL_TIMER; msg->msg[2] = day; msg->msg[3] = month; /* Hours and minutes are in BCD format */ msg->msg[4] = ((start_hr / 10) << 4) | (start_hr % 10); msg->msg[5] = ((start_min / 10) << 4) | (start_min % 10); msg->msg[6] = ((duration_hr / 10) << 4) | (duration_hr % 10); msg->msg[7] = ((duration_min / 10) << 4) | (duration_min % 10); msg->msg[8] = recording_seq; cec_set_digital_service_id(msg->msg + 9, digital); } static __inline__ void cec_ops_clear_digital_timer(const struct cec_msg *msg, __u8 *day, __u8 *month, __u8 *start_hr, __u8 *start_min, __u8 *duration_hr, __u8 *duration_min, __u8 *recording_seq, struct cec_op_digital_service_id *digital) { *day = msg->msg[2]; *month = msg->msg[3]; /* Hours and minutes are in BCD format */ *start_hr = (msg->msg[4] >> 4) * 10 + (msg->msg[4] & 0xf); *start_min = (msg->msg[5] >> 4) * 10 + (msg->msg[5] & 0xf); *duration_hr = (msg->msg[6] >> 4) * 10 + (msg->msg[6] & 0xf); *duration_min = (msg->msg[7] >> 4) * 10 + (msg->msg[7] & 0xf); *recording_seq = msg->msg[8]; cec_get_digital_service_id(msg->msg + 9, digital); } static __inline__ void cec_msg_clear_ext_timer(struct cec_msg *msg, int reply, __u8 day, __u8 month, __u8 start_hr, __u8 start_min, __u8 duration_hr, __u8 duration_min, __u8 recording_seq, __u8 ext_src_spec, __u8 plug, __u16 phys_addr) { msg->len = 13; msg->msg[1] = CEC_MSG_CLEAR_EXT_TIMER; msg->msg[2] = day; msg->msg[3] = month; /* Hours and minutes are in BCD format */ msg->msg[4] = ((start_hr / 10) << 4) | (start_hr % 10); msg->msg[5] = ((start_min / 10) << 4) | (start_min % 10); msg->msg[6] = ((duration_hr / 10) << 4) | (duration_hr % 10); msg->msg[7] = ((duration_min / 10) << 4) | (duration_min % 10); msg->msg[8] = recording_seq; msg->msg[9] = ext_src_spec; msg->msg[10] = plug; msg->msg[11] = phys_addr >> 8; msg->msg[12] = phys_addr & 0xff; msg->reply = reply ? CEC_MSG_TIMER_CLEARED_STATUS : 0; } static __inline__ void cec_ops_clear_ext_timer(const struct cec_msg *msg, __u8 *day, __u8 *month, __u8 *start_hr, __u8 *start_min, __u8 *duration_hr, __u8 *duration_min, __u8 *recording_seq, __u8 *ext_src_spec, __u8 *plug, __u16 *phys_addr) { *day = msg->msg[2]; *month = msg->msg[3]; /* Hours and minutes are in BCD format */ *start_hr = (msg->msg[4] >> 4) * 10 + (msg->msg[4] & 0xf); *start_min = (msg->msg[5] >> 4) * 10 + (msg->msg[5] & 0xf); *duration_hr = (msg->msg[6] >> 4) * 10 + (msg->msg[6] & 0xf); *duration_min = (msg->msg[7] >> 4) * 10 + (msg->msg[7] & 0xf); *recording_seq = msg->msg[8]; *ext_src_spec = msg->msg[9]; *plug = msg->msg[10]; *phys_addr = (msg->msg[11] << 8) | msg->msg[12]; } static __inline__ void cec_msg_set_analogue_timer(struct cec_msg *msg, int reply, __u8 day, __u8 month, __u8 start_hr, __u8 start_min, __u8 duration_hr, __u8 duration_min, __u8 recording_seq, __u8 ana_bcast_type, __u16 ana_freq, __u8 bcast_system) { msg->len = 13; msg->msg[1] = CEC_MSG_SET_ANALOGUE_TIMER; msg->msg[2] = day; msg->msg[3] = month; /* Hours and minutes are in BCD format */ msg->msg[4] = ((start_hr / 10) << 4) | (start_hr % 10); msg->msg[5] = ((start_min / 10) << 4) | (start_min % 10); msg->msg[6] = ((duration_hr / 10) << 4) | (duration_hr % 10); msg->msg[7] = ((duration_min / 10) << 4) | (duration_min % 10); msg->msg[8] = recording_seq; msg->msg[9] = ana_bcast_type; msg->msg[10] = ana_freq >> 8; msg->msg[11] = ana_freq & 0xff; msg->msg[12] = bcast_system; msg->reply = reply ? CEC_MSG_TIMER_STATUS : 0; } static __inline__ void cec_ops_set_analogue_timer(const struct cec_msg *msg, __u8 *day, __u8 *month, __u8 *start_hr, __u8 *start_min, __u8 *duration_hr, __u8 *duration_min, __u8 *recording_seq, __u8 *ana_bcast_type, __u16 *ana_freq, __u8 *bcast_system) { *day = msg->msg[2]; *month = msg->msg[3]; /* Hours and minutes are in BCD format */ *start_hr = (msg->msg[4] >> 4) * 10 + (msg->msg[4] & 0xf); *start_min = (msg->msg[5] >> 4) * 10 + (msg->msg[5] & 0xf); *duration_hr = (msg->msg[6] >> 4) * 10 + (msg->msg[6] & 0xf); *duration_min = (msg->msg[7] >> 4) * 10 + (msg->msg[7] & 0xf); *recording_seq = msg->msg[8]; *ana_bcast_type = msg->msg[9]; *ana_freq = (msg->msg[10] << 8) | msg->msg[11]; *bcast_system = msg->msg[12]; } static __inline__ void cec_msg_set_digital_timer(struct cec_msg *msg, int reply, __u8 day, __u8 month, __u8 start_hr, __u8 start_min, __u8 duration_hr, __u8 duration_min, __u8 recording_seq, const struct cec_op_digital_service_id *digital) { msg->len = 16; msg->reply = reply ? CEC_MSG_TIMER_STATUS : 0; msg->msg[1] = CEC_MSG_SET_DIGITAL_TIMER; msg->msg[2] = day; msg->msg[3] = month; /* Hours and minutes are in BCD format */ msg->msg[4] = ((start_hr / 10) << 4) | (start_hr % 10); msg->msg[5] = ((start_min / 10) << 4) | (start_min % 10); msg->msg[6] = ((duration_hr / 10) << 4) | (duration_hr % 10); msg->msg[7] = ((duration_min / 10) << 4) | (duration_min % 10); msg->msg[8] = recording_seq; cec_set_digital_service_id(msg->msg + 9, digital); } static __inline__ void cec_ops_set_digital_timer(const struct cec_msg *msg, __u8 *day, __u8 *month, __u8 *start_hr, __u8 *start_min, __u8 *duration_hr, __u8 *duration_min, __u8 *recording_seq, struct cec_op_digital_service_id *digital) { *day = msg->msg[2]; *month = msg->msg[3]; /* Hours and minutes are in BCD format */ *start_hr = (msg->msg[4] >> 4) * 10 + (msg->msg[4] & 0xf); *start_min = (msg->msg[5] >> 4) * 10 + (msg->msg[5] & 0xf); *duration_hr = (msg->msg[6] >> 4) * 10 + (msg->msg[6] & 0xf); *duration_min = (msg->msg[7] >> 4) * 10 + (msg->msg[7] & 0xf); *recording_seq = msg->msg[8]; cec_get_digital_service_id(msg->msg + 9, digital); } static __inline__ void cec_msg_set_ext_timer(struct cec_msg *msg, int reply, __u8 day, __u8 month, __u8 start_hr, __u8 start_min, __u8 duration_hr, __u8 duration_min, __u8 recording_seq, __u8 ext_src_spec, __u8 plug, __u16 phys_addr) { msg->len = 13; msg->msg[1] = CEC_MSG_SET_EXT_TIMER; msg->msg[2] = day; msg->msg[3] = month; /* Hours and minutes are in BCD format */ msg->msg[4] = ((start_hr / 10) << 4) | (start_hr % 10); msg->msg[5] = ((start_min / 10) << 4) | (start_min % 10); msg->msg[6] = ((duration_hr / 10) << 4) | (duration_hr % 10); msg->msg[7] = ((duration_min / 10) << 4) | (duration_min % 10); msg->msg[8] = recording_seq; msg->msg[9] = ext_src_spec; msg->msg[10] = plug; msg->msg[11] = phys_addr >> 8; msg->msg[12] = phys_addr & 0xff; msg->reply = reply ? CEC_MSG_TIMER_STATUS : 0; } static __inline__ void cec_ops_set_ext_timer(const struct cec_msg *msg, __u8 *day, __u8 *month, __u8 *start_hr, __u8 *start_min, __u8 *duration_hr, __u8 *duration_min, __u8 *recording_seq, __u8 *ext_src_spec, __u8 *plug, __u16 *phys_addr) { *day = msg->msg[2]; *month = msg->msg[3]; /* Hours and minutes are in BCD format */ *start_hr = (msg->msg[4] >> 4) * 10 + (msg->msg[4] & 0xf); *start_min = (msg->msg[5] >> 4) * 10 + (msg->msg[5] & 0xf); *duration_hr = (msg->msg[6] >> 4) * 10 + (msg->msg[6] & 0xf); *duration_min = (msg->msg[7] >> 4) * 10 + (msg->msg[7] & 0xf); *recording_seq = msg->msg[8]; *ext_src_spec = msg->msg[9]; *plug = msg->msg[10]; *phys_addr = (msg->msg[11] << 8) | msg->msg[12]; } static __inline__ void cec_msg_set_timer_program_title(struct cec_msg *msg, const char *prog_title) { unsigned int len = strlen(prog_title); if (len > 14) len = 14; msg->len = 2 + len; msg->msg[1] = CEC_MSG_SET_TIMER_PROGRAM_TITLE; memcpy(msg->msg + 2, prog_title, len); } static __inline__ void cec_ops_set_timer_program_title(const struct cec_msg *msg, char *prog_title) { unsigned int len = msg->len > 2 ? msg->len - 2 : 0; if (len > 14) len = 14; memcpy(prog_title, msg->msg + 2, len); prog_title[len] = '\0'; } /* System Information Feature */ static __inline__ void cec_msg_cec_version(struct cec_msg *msg, __u8 cec_version) { msg->len = 3; msg->msg[1] = CEC_MSG_CEC_VERSION; msg->msg[2] = cec_version; } static __inline__ void cec_ops_cec_version(const struct cec_msg *msg, __u8 *cec_version) { *cec_version = msg->msg[2]; } static __inline__ void cec_msg_get_cec_version(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GET_CEC_VERSION; msg->reply = reply ? CEC_MSG_CEC_VERSION : 0; } static __inline__ void cec_msg_report_physical_addr(struct cec_msg *msg, __u16 phys_addr, __u8 prim_devtype) { msg->len = 5; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_REPORT_PHYSICAL_ADDR; msg->msg[2] = phys_addr >> 8; msg->msg[3] = phys_addr & 0xff; msg->msg[4] = prim_devtype; } static __inline__ void cec_ops_report_physical_addr(const struct cec_msg *msg, __u16 *phys_addr, __u8 *prim_devtype) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *prim_devtype = msg->msg[4]; } static __inline__ void cec_msg_give_physical_addr(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GIVE_PHYSICAL_ADDR; msg->reply = reply ? CEC_MSG_REPORT_PHYSICAL_ADDR : 0; } static __inline__ void cec_msg_set_menu_language(struct cec_msg *msg, const char *language) { msg->len = 5; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_SET_MENU_LANGUAGE; memcpy(msg->msg + 2, language, 3); } static __inline__ void cec_ops_set_menu_language(const struct cec_msg *msg, char *language) { memcpy(language, msg->msg + 2, 3); language[3] = '\0'; } static __inline__ void cec_msg_get_menu_language(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GET_MENU_LANGUAGE; msg->reply = reply ? CEC_MSG_SET_MENU_LANGUAGE : 0; } /* * Assumes a single RC Profile byte and a single Device Features byte, * i.e. no extended features are supported by this helper function. * * As of CEC 2.0 no extended features are defined, should those be added * in the future, then this function needs to be adapted or a new function * should be added. */ static __inline__ void cec_msg_report_features(struct cec_msg *msg, __u8 cec_version, __u8 all_device_types, __u8 rc_profile, __u8 dev_features) { msg->len = 6; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_REPORT_FEATURES; msg->msg[2] = cec_version; msg->msg[3] = all_device_types; msg->msg[4] = rc_profile; msg->msg[5] = dev_features; } static __inline__ void cec_ops_report_features(const struct cec_msg *msg, __u8 *cec_version, __u8 *all_device_types, const __u8 **rc_profile, const __u8 **dev_features) { const __u8 *p = &msg->msg[4]; *cec_version = msg->msg[2]; *all_device_types = msg->msg[3]; *rc_profile = p; *dev_features = NULL; while (p < &msg->msg[14] && (*p & CEC_OP_FEAT_EXT)) p++; if (!(*p & CEC_OP_FEAT_EXT)) { *dev_features = p + 1; while (p < &msg->msg[15] && (*p & CEC_OP_FEAT_EXT)) p++; } if (*p & CEC_OP_FEAT_EXT) *rc_profile = *dev_features = NULL; } static __inline__ void cec_msg_give_features(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GIVE_FEATURES; msg->reply = reply ? CEC_MSG_REPORT_FEATURES : 0; } /* Deck Control Feature */ static __inline__ void cec_msg_deck_control(struct cec_msg *msg, __u8 deck_control_mode) { msg->len = 3; msg->msg[1] = CEC_MSG_DECK_CONTROL; msg->msg[2] = deck_control_mode; } static __inline__ void cec_ops_deck_control(const struct cec_msg *msg, __u8 *deck_control_mode) { *deck_control_mode = msg->msg[2]; } static __inline__ void cec_msg_deck_status(struct cec_msg *msg, __u8 deck_info) { msg->len = 3; msg->msg[1] = CEC_MSG_DECK_STATUS; msg->msg[2] = deck_info; } static __inline__ void cec_ops_deck_status(const struct cec_msg *msg, __u8 *deck_info) { *deck_info = msg->msg[2]; } static __inline__ void cec_msg_give_deck_status(struct cec_msg *msg, int reply, __u8 status_req) { msg->len = 3; msg->msg[1] = CEC_MSG_GIVE_DECK_STATUS; msg->msg[2] = status_req; msg->reply = reply ? CEC_MSG_DECK_STATUS : 0; } static __inline__ void cec_ops_give_deck_status(const struct cec_msg *msg, __u8 *status_req) { *status_req = msg->msg[2]; } static __inline__ void cec_msg_play(struct cec_msg *msg, __u8 play_mode) { msg->len = 3; msg->msg[1] = CEC_MSG_PLAY; msg->msg[2] = play_mode; } static __inline__ void cec_ops_play(const struct cec_msg *msg, __u8 *play_mode) { *play_mode = msg->msg[2]; } /* Tuner Control Feature */ struct cec_op_tuner_device_info { __u8 rec_flag; __u8 tuner_display_info; __u8 is_analog; union { struct cec_op_digital_service_id digital; struct { __u8 ana_bcast_type; __u16 ana_freq; __u8 bcast_system; } analog; }; }; static __inline__ void cec_msg_tuner_device_status_analog(struct cec_msg *msg, __u8 rec_flag, __u8 tuner_display_info, __u8 ana_bcast_type, __u16 ana_freq, __u8 bcast_system) { msg->len = 7; msg->msg[1] = CEC_MSG_TUNER_DEVICE_STATUS; msg->msg[2] = (rec_flag << 7) | tuner_display_info; msg->msg[3] = ana_bcast_type; msg->msg[4] = ana_freq >> 8; msg->msg[5] = ana_freq & 0xff; msg->msg[6] = bcast_system; } static __inline__ void cec_msg_tuner_device_status_digital(struct cec_msg *msg, __u8 rec_flag, __u8 tuner_display_info, const struct cec_op_digital_service_id *digital) { msg->len = 10; msg->msg[1] = CEC_MSG_TUNER_DEVICE_STATUS; msg->msg[2] = (rec_flag << 7) | tuner_display_info; cec_set_digital_service_id(msg->msg + 3, digital); } static __inline__ void cec_msg_tuner_device_status(struct cec_msg *msg, const struct cec_op_tuner_device_info *tuner_dev_info) { if (tuner_dev_info->is_analog) cec_msg_tuner_device_status_analog(msg, tuner_dev_info->rec_flag, tuner_dev_info->tuner_display_info, tuner_dev_info->analog.ana_bcast_type, tuner_dev_info->analog.ana_freq, tuner_dev_info->analog.bcast_system); else cec_msg_tuner_device_status_digital(msg, tuner_dev_info->rec_flag, tuner_dev_info->tuner_display_info, &tuner_dev_info->digital); } static __inline__ void cec_ops_tuner_device_status(const struct cec_msg *msg, struct cec_op_tuner_device_info *tuner_dev_info) { tuner_dev_info->is_analog = msg->len < 10; tuner_dev_info->rec_flag = msg->msg[2] >> 7; tuner_dev_info->tuner_display_info = msg->msg[2] & 0x7f; if (tuner_dev_info->is_analog) { tuner_dev_info->analog.ana_bcast_type = msg->msg[3]; tuner_dev_info->analog.ana_freq = (msg->msg[4] << 8) | msg->msg[5]; tuner_dev_info->analog.bcast_system = msg->msg[6]; return; } cec_get_digital_service_id(msg->msg + 3, &tuner_dev_info->digital); } static __inline__ void cec_msg_give_tuner_device_status(struct cec_msg *msg, int reply, __u8 status_req) { msg->len = 3; msg->msg[1] = CEC_MSG_GIVE_TUNER_DEVICE_STATUS; msg->msg[2] = status_req; msg->reply = reply ? CEC_MSG_TUNER_DEVICE_STATUS : 0; } static __inline__ void cec_ops_give_tuner_device_status(const struct cec_msg *msg, __u8 *status_req) { *status_req = msg->msg[2]; } static __inline__ void cec_msg_select_analogue_service(struct cec_msg *msg, __u8 ana_bcast_type, __u16 ana_freq, __u8 bcast_system) { msg->len = 6; msg->msg[1] = CEC_MSG_SELECT_ANALOGUE_SERVICE; msg->msg[2] = ana_bcast_type; msg->msg[3] = ana_freq >> 8; msg->msg[4] = ana_freq & 0xff; msg->msg[5] = bcast_system; } static __inline__ void cec_ops_select_analogue_service(const struct cec_msg *msg, __u8 *ana_bcast_type, __u16 *ana_freq, __u8 *bcast_system) { *ana_bcast_type = msg->msg[2]; *ana_freq = (msg->msg[3] << 8) | msg->msg[4]; *bcast_system = msg->msg[5]; } static __inline__ void cec_msg_select_digital_service(struct cec_msg *msg, const struct cec_op_digital_service_id *digital) { msg->len = 9; msg->msg[1] = CEC_MSG_SELECT_DIGITAL_SERVICE; cec_set_digital_service_id(msg->msg + 2, digital); } static __inline__ void cec_ops_select_digital_service(const struct cec_msg *msg, struct cec_op_digital_service_id *digital) { cec_get_digital_service_id(msg->msg + 2, digital); } static __inline__ void cec_msg_tuner_step_decrement(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_TUNER_STEP_DECREMENT; } static __inline__ void cec_msg_tuner_step_increment(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_TUNER_STEP_INCREMENT; } /* Vendor Specific Commands Feature */ static __inline__ void cec_msg_device_vendor_id(struct cec_msg *msg, __u32 vendor_id) { msg->len = 5; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_DEVICE_VENDOR_ID; msg->msg[2] = vendor_id >> 16; msg->msg[3] = (vendor_id >> 8) & 0xff; msg->msg[4] = vendor_id & 0xff; } static __inline__ void cec_ops_device_vendor_id(const struct cec_msg *msg, __u32 *vendor_id) { *vendor_id = (msg->msg[2] << 16) | (msg->msg[3] << 8) | msg->msg[4]; } static __inline__ void cec_msg_give_device_vendor_id(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GIVE_DEVICE_VENDOR_ID; msg->reply = reply ? CEC_MSG_DEVICE_VENDOR_ID : 0; } static __inline__ void cec_msg_vendor_command(struct cec_msg *msg, __u8 size, const __u8 *vendor_cmd) { if (size > 14) size = 14; msg->len = 2 + size; msg->msg[1] = CEC_MSG_VENDOR_COMMAND; memcpy(msg->msg + 2, vendor_cmd, size); } static __inline__ void cec_ops_vendor_command(const struct cec_msg *msg, __u8 *size, const __u8 **vendor_cmd) { *size = msg->len - 2; if (*size > 14) *size = 14; *vendor_cmd = msg->msg + 2; } static __inline__ void cec_msg_vendor_command_with_id(struct cec_msg *msg, __u32 vendor_id, __u8 size, const __u8 *vendor_cmd) { if (size > 11) size = 11; msg->len = 5 + size; msg->msg[1] = CEC_MSG_VENDOR_COMMAND_WITH_ID; msg->msg[2] = vendor_id >> 16; msg->msg[3] = (vendor_id >> 8) & 0xff; msg->msg[4] = vendor_id & 0xff; memcpy(msg->msg + 5, vendor_cmd, size); } static __inline__ void cec_ops_vendor_command_with_id(const struct cec_msg *msg, __u32 *vendor_id, __u8 *size, const __u8 **vendor_cmd) { *size = msg->len - 5; if (*size > 11) *size = 11; *vendor_id = (msg->msg[2] << 16) | (msg->msg[3] << 8) | msg->msg[4]; *vendor_cmd = msg->msg + 5; } static __inline__ void cec_msg_vendor_remote_button_down(struct cec_msg *msg, __u8 size, const __u8 *rc_code) { if (size > 14) size = 14; msg->len = 2 + size; msg->msg[1] = CEC_MSG_VENDOR_REMOTE_BUTTON_DOWN; memcpy(msg->msg + 2, rc_code, size); } static __inline__ void cec_ops_vendor_remote_button_down(const struct cec_msg *msg, __u8 *size, const __u8 **rc_code) { *size = msg->len - 2; if (*size > 14) *size = 14; *rc_code = msg->msg + 2; } static __inline__ void cec_msg_vendor_remote_button_up(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_VENDOR_REMOTE_BUTTON_UP; } /* OSD Display Feature */ static __inline__ void cec_msg_set_osd_string(struct cec_msg *msg, __u8 disp_ctl, const char *osd) { unsigned int len = strlen(osd); if (len > 13) len = 13; msg->len = 3 + len; msg->msg[1] = CEC_MSG_SET_OSD_STRING; msg->msg[2] = disp_ctl; memcpy(msg->msg + 3, osd, len); } static __inline__ void cec_ops_set_osd_string(const struct cec_msg *msg, __u8 *disp_ctl, char *osd) { unsigned int len = msg->len > 3 ? msg->len - 3 : 0; *disp_ctl = msg->msg[2]; if (len > 13) len = 13; memcpy(osd, msg->msg + 3, len); osd[len] = '\0'; } /* Device OSD Transfer Feature */ static __inline__ void cec_msg_set_osd_name(struct cec_msg *msg, const char *name) { unsigned int len = strlen(name); if (len > 14) len = 14; msg->len = 2 + len; msg->msg[1] = CEC_MSG_SET_OSD_NAME; memcpy(msg->msg + 2, name, len); } static __inline__ void cec_ops_set_osd_name(const struct cec_msg *msg, char *name) { unsigned int len = msg->len > 2 ? msg->len - 2 : 0; if (len > 14) len = 14; memcpy(name, msg->msg + 2, len); name[len] = '\0'; } static __inline__ void cec_msg_give_osd_name(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GIVE_OSD_NAME; msg->reply = reply ? CEC_MSG_SET_OSD_NAME : 0; } /* Device Menu Control Feature */ static __inline__ void cec_msg_menu_status(struct cec_msg *msg, __u8 menu_state) { msg->len = 3; msg->msg[1] = CEC_MSG_MENU_STATUS; msg->msg[2] = menu_state; } static __inline__ void cec_ops_menu_status(const struct cec_msg *msg, __u8 *menu_state) { *menu_state = msg->msg[2]; } static __inline__ void cec_msg_menu_request(struct cec_msg *msg, int reply, __u8 menu_req) { msg->len = 3; msg->msg[1] = CEC_MSG_MENU_REQUEST; msg->msg[2] = menu_req; msg->reply = reply ? CEC_MSG_MENU_STATUS : 0; } static __inline__ void cec_ops_menu_request(const struct cec_msg *msg, __u8 *menu_req) { *menu_req = msg->msg[2]; } struct cec_op_ui_command { __u8 ui_cmd; __u8 has_opt_arg; union { struct cec_op_channel_data channel_identifier; __u8 ui_broadcast_type; __u8 ui_sound_presentation_control; __u8 play_mode; __u8 ui_function_media; __u8 ui_function_select_av_input; __u8 ui_function_select_audio_input; }; }; static __inline__ void cec_msg_user_control_pressed(struct cec_msg *msg, const struct cec_op_ui_command *ui_cmd) { msg->len = 3; msg->msg[1] = CEC_MSG_USER_CONTROL_PRESSED; msg->msg[2] = ui_cmd->ui_cmd; if (!ui_cmd->has_opt_arg) return; switch (ui_cmd->ui_cmd) { case 0x56: case 0x57: case 0x60: case 0x68: case 0x69: case 0x6a: /* The optional operand is one byte for all these ui commands */ msg->len++; msg->msg[3] = ui_cmd->play_mode; break; case 0x67: msg->len += 4; msg->msg[3] = (ui_cmd->channel_identifier.channel_number_fmt << 2) | (ui_cmd->channel_identifier.major >> 8); msg->msg[4] = ui_cmd->channel_identifier.major & 0xff; msg->msg[5] = ui_cmd->channel_identifier.minor >> 8; msg->msg[6] = ui_cmd->channel_identifier.minor & 0xff; break; } } static __inline__ void cec_ops_user_control_pressed(const struct cec_msg *msg, struct cec_op_ui_command *ui_cmd) { ui_cmd->ui_cmd = msg->msg[2]; ui_cmd->has_opt_arg = 0; if (msg->len == 3) return; switch (ui_cmd->ui_cmd) { case 0x56: case 0x57: case 0x60: case 0x68: case 0x69: case 0x6a: /* The optional operand is one byte for all these ui commands */ ui_cmd->play_mode = msg->msg[3]; ui_cmd->has_opt_arg = 1; break; case 0x67: if (msg->len < 7) break; ui_cmd->has_opt_arg = 1; ui_cmd->channel_identifier.channel_number_fmt = msg->msg[3] >> 2; ui_cmd->channel_identifier.major = ((msg->msg[3] & 3) << 6) | msg->msg[4]; ui_cmd->channel_identifier.minor = (msg->msg[5] << 8) | msg->msg[6]; break; } } static __inline__ void cec_msg_user_control_released(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_USER_CONTROL_RELEASED; } /* Remote Control Passthrough Feature */ /* Power Status Feature */ static __inline__ void cec_msg_report_power_status(struct cec_msg *msg, __u8 pwr_state) { msg->len = 3; msg->msg[1] = CEC_MSG_REPORT_POWER_STATUS; msg->msg[2] = pwr_state; } static __inline__ void cec_ops_report_power_status(const struct cec_msg *msg, __u8 *pwr_state) { *pwr_state = msg->msg[2]; } static __inline__ void cec_msg_give_device_power_status(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GIVE_DEVICE_POWER_STATUS; msg->reply = reply ? CEC_MSG_REPORT_POWER_STATUS : 0; } /* General Protocol Messages */ static __inline__ void cec_msg_feature_abort(struct cec_msg *msg, __u8 abort_msg, __u8 reason) { msg->len = 4; msg->msg[1] = CEC_MSG_FEATURE_ABORT; msg->msg[2] = abort_msg; msg->msg[3] = reason; } static __inline__ void cec_ops_feature_abort(const struct cec_msg *msg, __u8 *abort_msg, __u8 *reason) { *abort_msg = msg->msg[2]; *reason = msg->msg[3]; } /* This changes the current message into a feature abort message */ static __inline__ void cec_msg_reply_feature_abort(struct cec_msg *msg, __u8 reason) { cec_msg_set_reply_to(msg, msg); msg->len = 4; msg->msg[2] = msg->msg[1]; msg->msg[3] = reason; msg->msg[1] = CEC_MSG_FEATURE_ABORT; } static __inline__ void cec_msg_abort(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_ABORT; } /* System Audio Control Feature */ static __inline__ void cec_msg_report_audio_status(struct cec_msg *msg, __u8 aud_mute_status, __u8 aud_vol_status) { msg->len = 3; msg->msg[1] = CEC_MSG_REPORT_AUDIO_STATUS; msg->msg[2] = (aud_mute_status << 7) | (aud_vol_status & 0x7f); } static __inline__ void cec_ops_report_audio_status(const struct cec_msg *msg, __u8 *aud_mute_status, __u8 *aud_vol_status) { *aud_mute_status = msg->msg[2] >> 7; *aud_vol_status = msg->msg[2] & 0x7f; } static __inline__ void cec_msg_give_audio_status(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GIVE_AUDIO_STATUS; msg->reply = reply ? CEC_MSG_REPORT_AUDIO_STATUS : 0; } static __inline__ void cec_msg_set_system_audio_mode(struct cec_msg *msg, __u8 sys_aud_status) { msg->len = 3; msg->msg[1] = CEC_MSG_SET_SYSTEM_AUDIO_MODE; msg->msg[2] = sys_aud_status; } static __inline__ void cec_ops_set_system_audio_mode(const struct cec_msg *msg, __u8 *sys_aud_status) { *sys_aud_status = msg->msg[2]; } static __inline__ void cec_msg_system_audio_mode_request(struct cec_msg *msg, int reply, __u16 phys_addr) { msg->len = phys_addr == 0xffff ? 2 : 4; msg->msg[1] = CEC_MSG_SYSTEM_AUDIO_MODE_REQUEST; msg->msg[2] = phys_addr >> 8; msg->msg[3] = phys_addr & 0xff; msg->reply = reply ? CEC_MSG_SET_SYSTEM_AUDIO_MODE : 0; } static __inline__ void cec_ops_system_audio_mode_request(const struct cec_msg *msg, __u16 *phys_addr) { if (msg->len < 4) *phys_addr = 0xffff; else *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; } static __inline__ void cec_msg_system_audio_mode_status(struct cec_msg *msg, __u8 sys_aud_status) { msg->len = 3; msg->msg[1] = CEC_MSG_SYSTEM_AUDIO_MODE_STATUS; msg->msg[2] = sys_aud_status; } static __inline__ void cec_ops_system_audio_mode_status(const struct cec_msg *msg, __u8 *sys_aud_status) { *sys_aud_status = msg->msg[2]; } static __inline__ void cec_msg_give_system_audio_mode_status(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_GIVE_SYSTEM_AUDIO_MODE_STATUS; msg->reply = reply ? CEC_MSG_SYSTEM_AUDIO_MODE_STATUS : 0; } static __inline__ void cec_msg_report_short_audio_descriptor(struct cec_msg *msg, __u8 num_descriptors, const __u32 *descriptors) { unsigned int i; if (num_descriptors > 4) num_descriptors = 4; msg->len = 2 + num_descriptors * 3; msg->msg[1] = CEC_MSG_REPORT_SHORT_AUDIO_DESCRIPTOR; for (i = 0; i < num_descriptors; i++) { msg->msg[2 + i * 3] = (descriptors[i] >> 16) & 0xff; msg->msg[3 + i * 3] = (descriptors[i] >> 8) & 0xff; msg->msg[4 + i * 3] = descriptors[i] & 0xff; } } static __inline__ void cec_ops_report_short_audio_descriptor(const struct cec_msg *msg, __u8 *num_descriptors, __u32 *descriptors) { unsigned int i; *num_descriptors = (msg->len - 2) / 3; if (*num_descriptors > 4) *num_descriptors = 4; for (i = 0; i < *num_descriptors; i++) descriptors[i] = (msg->msg[2 + i * 3] << 16) | (msg->msg[3 + i * 3] << 8) | msg->msg[4 + i * 3]; } static __inline__ void cec_msg_request_short_audio_descriptor(struct cec_msg *msg, int reply, __u8 num_descriptors, const __u8 *audio_format_id, const __u8 *audio_format_code) { unsigned int i; if (num_descriptors > 4) num_descriptors = 4; msg->len = 2 + num_descriptors; msg->msg[1] = CEC_MSG_REQUEST_SHORT_AUDIO_DESCRIPTOR; msg->reply = reply ? CEC_MSG_REPORT_SHORT_AUDIO_DESCRIPTOR : 0; for (i = 0; i < num_descriptors; i++) msg->msg[2 + i] = (audio_format_id[i] << 6) | (audio_format_code[i] & 0x3f); } static __inline__ void cec_ops_request_short_audio_descriptor(const struct cec_msg *msg, __u8 *num_descriptors, __u8 *audio_format_id, __u8 *audio_format_code) { unsigned int i; *num_descriptors = msg->len - 2; if (*num_descriptors > 4) *num_descriptors = 4; for (i = 0; i < *num_descriptors; i++) { audio_format_id[i] = msg->msg[2 + i] >> 6; audio_format_code[i] = msg->msg[2 + i] & 0x3f; } } static __inline__ void cec_msg_set_audio_volume_level(struct cec_msg *msg, __u8 audio_volume_level) { msg->len = 3; msg->msg[1] = CEC_MSG_SET_AUDIO_VOLUME_LEVEL; msg->msg[2] = audio_volume_level; } static __inline__ void cec_ops_set_audio_volume_level(const struct cec_msg *msg, __u8 *audio_volume_level) { *audio_volume_level = msg->msg[2]; } /* Audio Rate Control Feature */ static __inline__ void cec_msg_set_audio_rate(struct cec_msg *msg, __u8 audio_rate) { msg->len = 3; msg->msg[1] = CEC_MSG_SET_AUDIO_RATE; msg->msg[2] = audio_rate; } static __inline__ void cec_ops_set_audio_rate(const struct cec_msg *msg, __u8 *audio_rate) { *audio_rate = msg->msg[2]; } /* Audio Return Channel Control Feature */ static __inline__ void cec_msg_report_arc_initiated(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_REPORT_ARC_INITIATED; } static __inline__ void cec_msg_initiate_arc(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_INITIATE_ARC; msg->reply = reply ? CEC_MSG_REPORT_ARC_INITIATED : 0; } static __inline__ void cec_msg_request_arc_initiation(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_REQUEST_ARC_INITIATION; msg->reply = reply ? CEC_MSG_INITIATE_ARC : 0; } static __inline__ void cec_msg_report_arc_terminated(struct cec_msg *msg) { msg->len = 2; msg->msg[1] = CEC_MSG_REPORT_ARC_TERMINATED; } static __inline__ void cec_msg_terminate_arc(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_TERMINATE_ARC; msg->reply = reply ? CEC_MSG_REPORT_ARC_TERMINATED : 0; } static __inline__ void cec_msg_request_arc_termination(struct cec_msg *msg, int reply) { msg->len = 2; msg->msg[1] = CEC_MSG_REQUEST_ARC_TERMINATION; msg->reply = reply ? CEC_MSG_TERMINATE_ARC : 0; } /* Dynamic Audio Lipsync Feature */ /* Only for CEC 2.0 and up */ static __inline__ void cec_msg_report_current_latency(struct cec_msg *msg, __u16 phys_addr, __u8 video_latency, __u8 low_latency_mode, __u8 audio_out_compensated, __u8 audio_out_delay) { msg->len = 6; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_REPORT_CURRENT_LATENCY; msg->msg[2] = phys_addr >> 8; msg->msg[3] = phys_addr & 0xff; msg->msg[4] = video_latency; msg->msg[5] = (low_latency_mode << 2) | audio_out_compensated; if (audio_out_compensated == 3) msg->msg[msg->len++] = audio_out_delay; } static __inline__ void cec_ops_report_current_latency(const struct cec_msg *msg, __u16 *phys_addr, __u8 *video_latency, __u8 *low_latency_mode, __u8 *audio_out_compensated, __u8 *audio_out_delay) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *video_latency = msg->msg[4]; *low_latency_mode = (msg->msg[5] >> 2) & 1; *audio_out_compensated = msg->msg[5] & 3; if (*audio_out_compensated == 3 && msg->len >= 7) *audio_out_delay = msg->msg[6]; else *audio_out_delay = 0; } static __inline__ void cec_msg_request_current_latency(struct cec_msg *msg, int reply, __u16 phys_addr) { msg->len = 4; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_REQUEST_CURRENT_LATENCY; msg->msg[2] = phys_addr >> 8; msg->msg[3] = phys_addr & 0xff; msg->reply = reply ? CEC_MSG_REPORT_CURRENT_LATENCY : 0; } static __inline__ void cec_ops_request_current_latency(const struct cec_msg *msg, __u16 *phys_addr) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; } /* Capability Discovery and Control Feature */ static __inline__ void cec_msg_cdc_hec_inquire_state(struct cec_msg *msg, __u16 phys_addr1, __u16 phys_addr2) { msg->len = 9; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HEC_INQUIRE_STATE; msg->msg[5] = phys_addr1 >> 8; msg->msg[6] = phys_addr1 & 0xff; msg->msg[7] = phys_addr2 >> 8; msg->msg[8] = phys_addr2 & 0xff; } static __inline__ void cec_ops_cdc_hec_inquire_state(const struct cec_msg *msg, __u16 *phys_addr, __u16 *phys_addr1, __u16 *phys_addr2) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *phys_addr1 = (msg->msg[5] << 8) | msg->msg[6]; *phys_addr2 = (msg->msg[7] << 8) | msg->msg[8]; } static __inline__ void cec_msg_cdc_hec_report_state(struct cec_msg *msg, __u16 target_phys_addr, __u8 hec_func_state, __u8 host_func_state, __u8 enc_func_state, __u8 cdc_errcode, __u8 has_field, __u16 hec_field) { msg->len = has_field ? 10 : 8; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HEC_REPORT_STATE; msg->msg[5] = target_phys_addr >> 8; msg->msg[6] = target_phys_addr & 0xff; msg->msg[7] = (hec_func_state << 6) | (host_func_state << 4) | (enc_func_state << 2) | cdc_errcode; if (has_field) { msg->msg[8] = hec_field >> 8; msg->msg[9] = hec_field & 0xff; } } static __inline__ void cec_ops_cdc_hec_report_state(const struct cec_msg *msg, __u16 *phys_addr, __u16 *target_phys_addr, __u8 *hec_func_state, __u8 *host_func_state, __u8 *enc_func_state, __u8 *cdc_errcode, __u8 *has_field, __u16 *hec_field) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *target_phys_addr = (msg->msg[5] << 8) | msg->msg[6]; *hec_func_state = msg->msg[7] >> 6; *host_func_state = (msg->msg[7] >> 4) & 3; *enc_func_state = (msg->msg[7] >> 4) & 3; *cdc_errcode = msg->msg[7] & 3; *has_field = msg->len >= 10; *hec_field = *has_field ? ((msg->msg[8] << 8) | msg->msg[9]) : 0; } static __inline__ void cec_msg_cdc_hec_set_state(struct cec_msg *msg, __u16 phys_addr1, __u16 phys_addr2, __u8 hec_set_state, __u16 phys_addr3, __u16 phys_addr4, __u16 phys_addr5) { msg->len = 10; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HEC_INQUIRE_STATE; msg->msg[5] = phys_addr1 >> 8; msg->msg[6] = phys_addr1 & 0xff; msg->msg[7] = phys_addr2 >> 8; msg->msg[8] = phys_addr2 & 0xff; msg->msg[9] = hec_set_state; if (phys_addr3 != CEC_PHYS_ADDR_INVALID) { msg->msg[msg->len++] = phys_addr3 >> 8; msg->msg[msg->len++] = phys_addr3 & 0xff; if (phys_addr4 != CEC_PHYS_ADDR_INVALID) { msg->msg[msg->len++] = phys_addr4 >> 8; msg->msg[msg->len++] = phys_addr4 & 0xff; if (phys_addr5 != CEC_PHYS_ADDR_INVALID) { msg->msg[msg->len++] = phys_addr5 >> 8; msg->msg[msg->len++] = phys_addr5 & 0xff; } } } } static __inline__ void cec_ops_cdc_hec_set_state(const struct cec_msg *msg, __u16 *phys_addr, __u16 *phys_addr1, __u16 *phys_addr2, __u8 *hec_set_state, __u16 *phys_addr3, __u16 *phys_addr4, __u16 *phys_addr5) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *phys_addr1 = (msg->msg[5] << 8) | msg->msg[6]; *phys_addr2 = (msg->msg[7] << 8) | msg->msg[8]; *hec_set_state = msg->msg[9]; *phys_addr3 = *phys_addr4 = *phys_addr5 = CEC_PHYS_ADDR_INVALID; if (msg->len >= 12) *phys_addr3 = (msg->msg[10] << 8) | msg->msg[11]; if (msg->len >= 14) *phys_addr4 = (msg->msg[12] << 8) | msg->msg[13]; if (msg->len >= 16) *phys_addr5 = (msg->msg[14] << 8) | msg->msg[15]; } static __inline__ void cec_msg_cdc_hec_set_state_adjacent(struct cec_msg *msg, __u16 phys_addr1, __u8 hec_set_state) { msg->len = 8; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HEC_SET_STATE_ADJACENT; msg->msg[5] = phys_addr1 >> 8; msg->msg[6] = phys_addr1 & 0xff; msg->msg[7] = hec_set_state; } static __inline__ void cec_ops_cdc_hec_set_state_adjacent(const struct cec_msg *msg, __u16 *phys_addr, __u16 *phys_addr1, __u8 *hec_set_state) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *phys_addr1 = (msg->msg[5] << 8) | msg->msg[6]; *hec_set_state = msg->msg[7]; } static __inline__ void cec_msg_cdc_hec_request_deactivation(struct cec_msg *msg, __u16 phys_addr1, __u16 phys_addr2, __u16 phys_addr3) { msg->len = 11; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HEC_REQUEST_DEACTIVATION; msg->msg[5] = phys_addr1 >> 8; msg->msg[6] = phys_addr1 & 0xff; msg->msg[7] = phys_addr2 >> 8; msg->msg[8] = phys_addr2 & 0xff; msg->msg[9] = phys_addr3 >> 8; msg->msg[10] = phys_addr3 & 0xff; } static __inline__ void cec_ops_cdc_hec_request_deactivation(const struct cec_msg *msg, __u16 *phys_addr, __u16 *phys_addr1, __u16 *phys_addr2, __u16 *phys_addr3) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *phys_addr1 = (msg->msg[5] << 8) | msg->msg[6]; *phys_addr2 = (msg->msg[7] << 8) | msg->msg[8]; *phys_addr3 = (msg->msg[9] << 8) | msg->msg[10]; } static __inline__ void cec_msg_cdc_hec_notify_alive(struct cec_msg *msg) { msg->len = 5; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HEC_NOTIFY_ALIVE; } static __inline__ void cec_ops_cdc_hec_notify_alive(const struct cec_msg *msg, __u16 *phys_addr) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; } static __inline__ void cec_msg_cdc_hec_discover(struct cec_msg *msg) { msg->len = 5; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HEC_DISCOVER; } static __inline__ void cec_ops_cdc_hec_discover(const struct cec_msg *msg, __u16 *phys_addr) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; } static __inline__ void cec_msg_cdc_hpd_set_state(struct cec_msg *msg, __u8 input_port, __u8 hpd_state) { msg->len = 6; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HPD_SET_STATE; msg->msg[5] = (input_port << 4) | hpd_state; } static __inline__ void cec_ops_cdc_hpd_set_state(const struct cec_msg *msg, __u16 *phys_addr, __u8 *input_port, __u8 *hpd_state) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *input_port = msg->msg[5] >> 4; *hpd_state = msg->msg[5] & 0xf; } static __inline__ void cec_msg_cdc_hpd_report_state(struct cec_msg *msg, __u8 hpd_state, __u8 hpd_error) { msg->len = 6; msg->msg[0] |= 0xf; /* broadcast */ msg->msg[1] = CEC_MSG_CDC_MESSAGE; /* msg[2] and msg[3] (phys_addr) are filled in by the CEC framework */ msg->msg[4] = CEC_MSG_CDC_HPD_REPORT_STATE; msg->msg[5] = (hpd_state << 4) | hpd_error; } static __inline__ void cec_ops_cdc_hpd_report_state(const struct cec_msg *msg, __u16 *phys_addr, __u8 *hpd_state, __u8 *hpd_error) { *phys_addr = (msg->msg[2] << 8) | msg->msg[3]; *hpd_state = msg->msg[5] >> 4; *hpd_error = msg->msg[5] & 0xf; } #endif
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