Current Path : /sys/dev/firewire/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/dev/firewire/firewire.h |
/*- * Copyright (c) 2003 Hidetoshi Shimokawa * Copyright (c) 1998-2002 Katsushi Kobayashi and Hidetoshi Shimokawa * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the acknowledgement as bellow: * * This product includes software developed by K. Kobayashi and H. Shimokawa * * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * * $FreeBSD: release/9.1.0/sys/dev/firewire/firewire.h 188726 2009-02-17 19:37:04Z sbruno $ * */ #ifndef _FIREWIRE_H #define _FIREWIRE_H 1 #define DEV_DEF 0 #define DEV_DV 2 struct fw_isochreq { unsigned char ch:6, tag:2; }; struct fw_isobufreq { struct fw_bufspec { unsigned int nchunk; unsigned int npacket; unsigned int psize; } tx, rx; }; struct fw_addr { uint32_t hi; uint32_t lo; }; struct fw_asybindreq { struct fw_addr start; unsigned long len; }; struct fw_reg_req_t { uint32_t addr; uint32_t data; }; #define MAXREC(x) (2 << (x)) #define FWPMAX_S400 (2048 + 20) /* MAXREC plus space for control data */ #define FWMAXQUEUE 128 #define FWLOCALBUS 0xffc0 #define FWTCODE_WREQQ 0 #define FWTCODE_WREQB 1 #define FWTCODE_WRES 2 #define FWTCODE_RREQQ 4 #define FWTCODE_RREQB 5 #define FWTCODE_RRESQ 6 #define FWTCODE_RRESB 7 #define FWTCODE_CYCS 8 #define FWTCODE_LREQ 9 #define FWTCODE_STREAM 0xa #define FWTCODE_LRES 0xb #define FWTCODE_PHY 0xe #define FWRETRY_1 0 #define FWRETRY_X 1 #define FWRETRY_A 2 #define FWRETRY_B 3 #define FWRCODE_COMPLETE 0 #define FWRCODE_ER_CONFL 4 #define FWRCODE_ER_DATA 5 #define FWRCODE_ER_TYPE 6 #define FWRCODE_ER_ADDR 7 /* * Defined 1394a-2000 * Table 5B-1 */ #define FWSPD_S100 0 #define FWSPD_S200 1 #define FWSPD_S400 2 #define FWSPD_S800 3 #define FWSPD_S1600 4 #define FWSPD_S3200 5 #define FWP_TL_VALID (1 << 7) struct fw_isohdr { uint32_t hdr[1]; }; struct fw_asyhdr { uint32_t hdr[4]; }; #if BYTE_ORDER == BIG_ENDIAN #define BIT4x2(x,y) uint8_t x:4, y:4 #define BIT16x2(x,y) uint32_t x:16, y:16 #else #define BIT4x2(x,y) uint8_t y:4, x:4 #define BIT16x2(x,y) uint32_t y:16, x:16 #endif #if BYTE_ORDER == BIG_ENDIAN #define COMMON_HDR(a,b,c,d) uint32_t a:16,b:8,c:4,d:4 #define COMMON_RES(a,b,c,d) uint32_t a:16,b:4,c:4,d:8 #else #define COMMON_HDR(a,b,c,d) uint32_t d:4,c:4,b:8,a:16 #define COMMON_RES(a,b,c,d) uint32_t d:8,c:4,b:4,a:16 #endif struct fw_pkt { union { uint32_t ld[0]; struct { COMMON_HDR(, , tcode, ); } common; struct { COMMON_HDR(len, chtag, tcode, sy); uint32_t payload[0]; } stream; struct { COMMON_HDR(dst, tlrt, tcode, pri); BIT16x2(src, ); } hdr; struct { COMMON_HDR(dst, tlrt, tcode, pri); BIT16x2(src, dest_hi); uint32_t dest_lo; } rreqq; struct { COMMON_HDR(dst, tlrt, tcode, pri); COMMON_RES(src, rtcode, , ); uint32_t :32; } wres; struct { COMMON_HDR(dst, tlrt, tcode, pri); BIT16x2(src, dest_hi); uint32_t dest_lo; BIT16x2(len, extcode); } rreqb; struct { COMMON_HDR(dst, tlrt, tcode, pri); BIT16x2(src, dest_hi); uint32_t dest_lo; uint32_t data; } wreqq; struct { COMMON_HDR(dst, tlrt, tcode, pri); BIT16x2(src, dest_hi); uint32_t dest_lo; uint32_t data; } cyc; struct { COMMON_HDR(dst, tlrt, tcode, pri); COMMON_RES(src, rtcode, , ); uint32_t :32; uint32_t data; } rresq; struct { COMMON_HDR(dst, tlrt, tcode, pri); BIT16x2(src, dest_hi); uint32_t dest_lo; BIT16x2(len, extcode); uint32_t payload[0]; } wreqb; struct { COMMON_HDR(dst, tlrt, tcode, pri); BIT16x2(src, dest_hi); uint32_t dest_lo; BIT16x2(len, extcode); uint32_t payload[0]; } lreq; struct { COMMON_HDR(dst, tlrt, tcode, pri); COMMON_RES(src, rtcode, , ); uint32_t :32; BIT16x2(len, extcode); uint32_t payload[0]; } rresb; struct { COMMON_HDR(dst, tlrt, tcode, pri); COMMON_RES(src, rtcode, , ); uint32_t :32; BIT16x2(len, extcode); uint32_t payload[0]; } lres; } mode; }; /* * Response code (rtcode) */ /* The node has successfully completed the command. */ #define RESP_CMP 0 /* A resource conflict was detected. The request may be retried. */ #define RESP_CONFLICT_ERROR 4 /* Hardware error, data is unavailable. */ #define RESP_DATA_ERROR 5 /* A field in the request packet header was set to an unsupported or incorrect * value, or an invalid transaction was attempted (e.g., a write to a read-only * address). */ #define RESP_TYPE_ERROR 6 /* The destination offset field in the request was set to an address not * accessible in the destination node. */ #define RESP_ADDRESS_ERROR 7 /* * Extended transaction code (extcode) */ #define EXTCODE_MASK_SWAP 1 #define EXTCODE_CMP_SWAP 2 #define EXTCODE_FETCH_ADD 3 #define EXTCODE_LITTLE_ADD 4 #define EXTCODE_BOUNDED_ADD 5 #define EXTCODE_WRAP_ADD 6 struct fw_eui64 { uint32_t hi, lo; }; #define FW_EUI64_BYTE(eui, x) \ ((((x)<4)? \ ((eui)->hi >> (8*(3-(x)))): \ ((eui)->lo >> (8*(7-(x)))) \ ) & 0xff) #define FW_EUI64_EQUAL(x, y) \ ((x).hi == (y).hi && (x).lo == (y).lo) struct fw_asyreq { struct fw_asyreq_t{ unsigned char sped; unsigned int type; #define FWASREQNODE 0 #define FWASREQEUI 1 #define FWASRESTL 2 #define FWASREQSTREAM 3 unsigned short len; union { struct fw_eui64 eui; }dst; }req; struct fw_pkt pkt; uint32_t data[512]; }; struct fw_devinfo { struct fw_eui64 eui; uint16_t dst; uint16_t status; }; #define FW_MAX_DEVLST 70 struct fw_devlstreq { uint16_t n; uint16_t info_len; struct fw_devinfo dev[FW_MAX_DEVLST]; }; /* * Defined in IEEE 1394a-2000 * 4.3.4.1 */ #define FW_SELF_ID_PORT_CONNECTED_TO_CHILD 3 #define FW_SELF_ID_PORT_CONNECTED_TO_PARENT 2 #define FW_SELF_ID_PORT_NOT_CONNECTED 1 #define FW_SELF_ID_PORT_NOT_EXISTS 0 #define FW_SELF_ID_PAGE0 0 #define FW_SELF_ID_PAGE1 1 #if BYTE_ORDER == BIG_ENDIAN union fw_self_id { struct { uint32_t id:2, phy_id:6, sequel:1, link_active:1, gap_count:6, phy_speed:2, reserved:2, contender:1, power_class:3, port0:2, port1:2, port2:2, initiated_reset:1, more_packets:1; } p0; struct { uint32_t id:2, phy_id:6, sequel:1, sequence_num:3, reserved2:2, port3:2, port4:2, port5:2, port6:2, port7:2, port8:2, port9:2, port10:2, reserved1:1, more_packets:1; } p1; struct { uint32_t id:2, phy_id:6, sequel:1, sequence_num:3, :2, port11:2, port12:2, port13:2, port14:2, port15:2, :8; } p2; }; #else union fw_self_id { struct { uint32_t more_packets:1, initiated_reset:1, port2:2, port1:2, port0:2, power_class:3, contender:1, reserved:2, phy_speed:2, gap_count:6, link_active:1, sequel:1, phy_id:6, id:2; } p0; struct { uint32_t more_packets:1, reserved1:1, port10:2, port9:2, port8:2, port7:2, port6:2, port5:2, port4:2, port3:2, reserved2:2, sequence_num:3, sequel:1, phy_id:6, id:2; } p1; struct { uint32_t reserved3:8, port15:2, port14:2, port13:2, port12:2, port11:2, reserved4:2, sequence_num:3, sequel:1, phy_id:6, id:2; } p2; }; #endif struct fw_topology_map { uint32_t crc:16, crc_len:16; uint32_t generation; uint32_t self_id_count:16, node_count:16; union fw_self_id self_id[4*64]; }; struct fw_speed_map { uint32_t crc:16, crc_len:16; uint32_t generation; uint8_t speed[64][64]; }; struct fw_crom_buf { struct fw_eui64 eui; uint32_t len; void *ptr; }; /* * FireWire specific system requests. */ #define FW_SSTBUF _IOWR('S', 86, struct fw_isobufreq) #define FW_GSTBUF _IOWR('S', 87, struct fw_isobufreq) #define FW_SRSTREAM _IOWR('S', 88, struct fw_isochreq) #define FW_GRSTREAM _IOWR('S', 89, struct fw_isochreq) #define FW_STSTREAM _IOWR('S', 90, struct fw_isochreq) #define FW_GTSTREAM _IOWR('S', 91, struct fw_isochreq) #define FW_ASYREQ _IOWR('S', 92, struct fw_asyreq) #define FW_IBUSRST _IOR('S', 1, unsigned int) #define FW_GDEVLST _IOWR('S', 2, struct fw_devlstreq) #define FW_SBINDADDR _IOWR('S', 3, struct fw_asybindreq) #define FW_CBINDADDR _IOWR('S', 4, struct fw_asybindreq) #define FW_GTPMAP _IOR('S', 5, struct fw_topology_map) #define FW_GCROM _IOWR('S', 7, struct fw_crom_buf) #define FW_SDEUI64 _IOW('S', 20, struct fw_eui64) #define FW_GDEUI64 _IOR('S', 21, struct fw_eui64) #define FWOHCI_RDREG _IOWR('S', 80, struct fw_reg_req_t) #define FWOHCI_WRREG _IOWR('S', 81, struct fw_reg_req_t) #define FWOHCI_RDPHYREG _IOWR('S', 82, struct fw_reg_req_t) #define FWOHCI_WRPHYREG _IOWR('S', 83, struct fw_reg_req_t) #define DUMPDMA _IOWR('S', 82, uint32_t) #ifdef _KERNEL #define FWMAXNDMA 0x100 /* 8 bits DMA channel id. in device No. */ #if defined(__DragonFly__) || __FreeBSD_version < 500000 #define dev2unit(x) ((minor(x) & 0xff) | (minor(x) >> 8)) #define unit2minor(x) (((x) & 0xff) | (((x) << 8) & ~0xffff)) #endif #define MAKEMINOR(f, u, s) \ ((f) | (((u) & 0xff) << 8) | (s & 0xff)) #define DEV2UNIT(x) ((dev2unit(x) & 0xff00) >> 8) #define DEV2SUB(x) (dev2unit(x) & 0xff) #define FWMEM_FLAG 0x10000 #define DEV_FWMEM(x) (dev2unit(x) & FWMEM_FLAG) #endif #endif