lfs_accessors.h revision 1.33.2.5
1 1.33.2.5 skrll /* $NetBSD: lfs_accessors.h,v 1.33.2.5 2016/07/09 20:25:25 skrll Exp $ */ 2 1.33.2.2 skrll 3 1.33.2.2 skrll /* from NetBSD: lfs.h,v 1.165 2015/07/24 06:59:32 dholland Exp */ 4 1.33.2.5 skrll /* from NetBSD: dinode.h,v 1.25 2016/01/22 23:06:10 dholland Exp */ 5 1.33.2.5 skrll /* from NetBSD: dir.h,v 1.25 2015/09/01 06:16:03 dholland Exp */ 6 1.33.2.2 skrll 7 1.33.2.2 skrll /*- 8 1.33.2.2 skrll * Copyright (c) 1999, 2000, 2001, 2002, 2003 The NetBSD Foundation, Inc. 9 1.33.2.2 skrll * All rights reserved. 10 1.33.2.2 skrll * 11 1.33.2.2 skrll * This code is derived from software contributed to The NetBSD Foundation 12 1.33.2.2 skrll * by Konrad E. Schroder <perseant (at) hhhh.org>. 13 1.33.2.2 skrll * 14 1.33.2.2 skrll * Redistribution and use in source and binary forms, with or without 15 1.33.2.2 skrll * modification, are permitted provided that the following conditions 16 1.33.2.2 skrll * are met: 17 1.33.2.2 skrll * 1. Redistributions of source code must retain the above copyright 18 1.33.2.2 skrll * notice, this list of conditions and the following disclaimer. 19 1.33.2.2 skrll * 2. Redistributions in binary form must reproduce the above copyright 20 1.33.2.2 skrll * notice, this list of conditions and the following disclaimer in the 21 1.33.2.2 skrll * documentation and/or other materials provided with the distribution. 22 1.33.2.2 skrll * 23 1.33.2.2 skrll * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 24 1.33.2.2 skrll * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 25 1.33.2.2 skrll * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 26 1.33.2.2 skrll * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 27 1.33.2.2 skrll * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 28 1.33.2.2 skrll * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 29 1.33.2.2 skrll * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 30 1.33.2.2 skrll * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 31 1.33.2.2 skrll * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 32 1.33.2.2 skrll * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 33 1.33.2.2 skrll * POSSIBILITY OF SUCH DAMAGE. 34 1.33.2.2 skrll */ 35 1.33.2.2 skrll /*- 36 1.33.2.2 skrll * Copyright (c) 1991, 1993 37 1.33.2.2 skrll * The Regents of the University of California. All rights reserved. 38 1.33.2.2 skrll * 39 1.33.2.2 skrll * Redistribution and use in source and binary forms, with or without 40 1.33.2.2 skrll * modification, are permitted provided that the following conditions 41 1.33.2.2 skrll * are met: 42 1.33.2.2 skrll * 1. Redistributions of source code must retain the above copyright 43 1.33.2.2 skrll * notice, this list of conditions and the following disclaimer. 44 1.33.2.2 skrll * 2. Redistributions in binary form must reproduce the above copyright 45 1.33.2.2 skrll * notice, this list of conditions and the following disclaimer in the 46 1.33.2.2 skrll * documentation and/or other materials provided with the distribution. 47 1.33.2.2 skrll * 3. Neither the name of the University nor the names of its contributors 48 1.33.2.2 skrll * may be used to endorse or promote products derived from this software 49 1.33.2.2 skrll * without specific prior written permission. 50 1.33.2.2 skrll * 51 1.33.2.2 skrll * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 52 1.33.2.2 skrll * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 53 1.33.2.2 skrll * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 54 1.33.2.2 skrll * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 55 1.33.2.2 skrll * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 56 1.33.2.2 skrll * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 57 1.33.2.2 skrll * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 58 1.33.2.2 skrll * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 59 1.33.2.2 skrll * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 60 1.33.2.2 skrll * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 61 1.33.2.2 skrll * SUCH DAMAGE. 62 1.33.2.2 skrll * 63 1.33.2.2 skrll * @(#)lfs.h 8.9 (Berkeley) 5/8/95 64 1.33.2.2 skrll */ 65 1.33.2.2 skrll /* 66 1.33.2.2 skrll * Copyright (c) 2002 Networks Associates Technology, Inc. 67 1.33.2.2 skrll * All rights reserved. 68 1.33.2.2 skrll * 69 1.33.2.2 skrll * This software was developed for the FreeBSD Project by Marshall 70 1.33.2.2 skrll * Kirk McKusick and Network Associates Laboratories, the Security 71 1.33.2.2 skrll * Research Division of Network Associates, Inc. under DARPA/SPAWAR 72 1.33.2.2 skrll * contract N66001-01-C-8035 ("CBOSS"), as part of the DARPA CHATS 73 1.33.2.2 skrll * research program 74 1.33.2.2 skrll * 75 1.33.2.2 skrll * Copyright (c) 1982, 1989, 1993 76 1.33.2.2 skrll * The Regents of the University of California. All rights reserved. 77 1.33.2.2 skrll * (c) UNIX System Laboratories, Inc. 78 1.33.2.2 skrll * All or some portions of this file are derived from material licensed 79 1.33.2.2 skrll * to the University of California by American Telephone and Telegraph 80 1.33.2.2 skrll * Co. or Unix System Laboratories, Inc. and are reproduced herein with 81 1.33.2.2 skrll * the permission of UNIX System Laboratories, Inc. 82 1.33.2.2 skrll * 83 1.33.2.2 skrll * Redistribution and use in source and binary forms, with or without 84 1.33.2.2 skrll * modification, are permitted provided that the following conditions 85 1.33.2.2 skrll * are met: 86 1.33.2.2 skrll * 1. Redistributions of source code must retain the above copyright 87 1.33.2.2 skrll * notice, this list of conditions and the following disclaimer. 88 1.33.2.2 skrll * 2. Redistributions in binary form must reproduce the above copyright 89 1.33.2.2 skrll * notice, this list of conditions and the following disclaimer in the 90 1.33.2.2 skrll * documentation and/or other materials provided with the distribution. 91 1.33.2.2 skrll * 3. Neither the name of the University nor the names of its contributors 92 1.33.2.2 skrll * may be used to endorse or promote products derived from this software 93 1.33.2.2 skrll * without specific prior written permission. 94 1.33.2.2 skrll * 95 1.33.2.2 skrll * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 96 1.33.2.2 skrll * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 97 1.33.2.2 skrll * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 98 1.33.2.2 skrll * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 99 1.33.2.2 skrll * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 100 1.33.2.2 skrll * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 101 1.33.2.2 skrll * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 102 1.33.2.2 skrll * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 103 1.33.2.2 skrll * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 104 1.33.2.2 skrll * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 105 1.33.2.2 skrll * SUCH DAMAGE. 106 1.33.2.2 skrll * 107 1.33.2.2 skrll * @(#)dinode.h 8.9 (Berkeley) 3/29/95 108 1.33.2.2 skrll */ 109 1.33.2.2 skrll /* 110 1.33.2.2 skrll * Copyright (c) 1982, 1986, 1989, 1993 111 1.33.2.2 skrll * The Regents of the University of California. All rights reserved. 112 1.33.2.2 skrll * (c) UNIX System Laboratories, Inc. 113 1.33.2.2 skrll * All or some portions of this file are derived from material licensed 114 1.33.2.2 skrll * to the University of California by American Telephone and Telegraph 115 1.33.2.2 skrll * Co. or Unix System Laboratories, Inc. and are reproduced herein with 116 1.33.2.2 skrll * the permission of UNIX System Laboratories, Inc. 117 1.33.2.2 skrll * 118 1.33.2.2 skrll * Redistribution and use in source and binary forms, with or without 119 1.33.2.2 skrll * modification, are permitted provided that the following conditions 120 1.33.2.2 skrll * are met: 121 1.33.2.2 skrll * 1. Redistributions of source code must retain the above copyright 122 1.33.2.2 skrll * notice, this list of conditions and the following disclaimer. 123 1.33.2.2 skrll * 2. Redistributions in binary form must reproduce the above copyright 124 1.33.2.2 skrll * notice, this list of conditions and the following disclaimer in the 125 1.33.2.2 skrll * documentation and/or other materials provided with the distribution. 126 1.33.2.2 skrll * 3. Neither the name of the University nor the names of its contributors 127 1.33.2.2 skrll * may be used to endorse or promote products derived from this software 128 1.33.2.2 skrll * without specific prior written permission. 129 1.33.2.2 skrll * 130 1.33.2.2 skrll * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 131 1.33.2.2 skrll * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 132 1.33.2.2 skrll * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 133 1.33.2.2 skrll * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 134 1.33.2.2 skrll * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 135 1.33.2.2 skrll * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 136 1.33.2.2 skrll * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 137 1.33.2.2 skrll * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 138 1.33.2.2 skrll * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 139 1.33.2.2 skrll * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 140 1.33.2.2 skrll * SUCH DAMAGE. 141 1.33.2.2 skrll * 142 1.33.2.2 skrll * @(#)dir.h 8.5 (Berkeley) 4/27/95 143 1.33.2.2 skrll */ 144 1.33.2.2 skrll 145 1.33.2.2 skrll #ifndef _UFS_LFS_LFS_ACCESSORS_H_ 146 1.33.2.2 skrll #define _UFS_LFS_LFS_ACCESSORS_H_ 147 1.33.2.2 skrll 148 1.33.2.2 skrll #if defined(_KERNEL_OPT) 149 1.33.2.2 skrll #include "opt_lfs.h" 150 1.33.2.2 skrll #endif 151 1.33.2.2 skrll 152 1.33.2.2 skrll #include <sys/bswap.h> 153 1.33.2.2 skrll 154 1.33.2.4 skrll #include <ufs/lfs/lfs.h> 155 1.33.2.4 skrll 156 1.33.2.2 skrll #if !defined(_KERNEL) && !defined(_STANDALONE) 157 1.33.2.2 skrll #include <assert.h> 158 1.33.2.4 skrll #include <string.h> 159 1.33.2.2 skrll #define KASSERT assert 160 1.33.2.4 skrll #else 161 1.33.2.4 skrll #include <sys/systm.h> 162 1.33.2.2 skrll #endif 163 1.33.2.2 skrll 164 1.33.2.2 skrll /* 165 1.33.2.2 skrll * STRUCT_LFS is used by the libsa code to get accessors that work 166 1.33.2.2 skrll * with struct salfs instead of struct lfs, and by the cleaner to 167 1.33.2.2 skrll * get accessors that work with struct clfs. 168 1.33.2.2 skrll */ 169 1.33.2.2 skrll 170 1.33.2.2 skrll #ifndef STRUCT_LFS 171 1.33.2.2 skrll #define STRUCT_LFS struct lfs 172 1.33.2.2 skrll #endif 173 1.33.2.2 skrll 174 1.33.2.2 skrll /* 175 1.33.2.2 skrll * byte order 176 1.33.2.2 skrll */ 177 1.33.2.2 skrll 178 1.33.2.2 skrll /* 179 1.33.2.2 skrll * For now at least, the bootblocks shall not be endian-independent. 180 1.33.2.2 skrll * We can see later if it fits in the size budget. Also disable the 181 1.33.2.2 skrll * byteswapping if LFS_EI is off. 182 1.33.2.2 skrll * 183 1.33.2.2 skrll * Caution: these functions "know" that bswap16/32/64 are unsigned, 184 1.33.2.2 skrll * and if that changes will likely break silently. 185 1.33.2.2 skrll */ 186 1.33.2.2 skrll 187 1.33.2.2 skrll #if defined(_STANDALONE) || (defined(_KERNEL) && !defined(LFS_EI)) 188 1.33.2.2 skrll #define LFS_SWAP_int16_t(fs, val) (val) 189 1.33.2.2 skrll #define LFS_SWAP_int32_t(fs, val) (val) 190 1.33.2.2 skrll #define LFS_SWAP_int64_t(fs, val) (val) 191 1.33.2.2 skrll #define LFS_SWAP_uint16_t(fs, val) (val) 192 1.33.2.2 skrll #define LFS_SWAP_uint32_t(fs, val) (val) 193 1.33.2.2 skrll #define LFS_SWAP_uint64_t(fs, val) (val) 194 1.33.2.2 skrll #else 195 1.33.2.2 skrll #define LFS_SWAP_int16_t(fs, val) \ 196 1.33.2.2 skrll ((fs)->lfs_dobyteswap ? (int16_t)bswap16(val) : (val)) 197 1.33.2.2 skrll #define LFS_SWAP_int32_t(fs, val) \ 198 1.33.2.2 skrll ((fs)->lfs_dobyteswap ? (int32_t)bswap32(val) : (val)) 199 1.33.2.2 skrll #define LFS_SWAP_int64_t(fs, val) \ 200 1.33.2.2 skrll ((fs)->lfs_dobyteswap ? (int64_t)bswap64(val) : (val)) 201 1.33.2.2 skrll #define LFS_SWAP_uint16_t(fs, val) \ 202 1.33.2.2 skrll ((fs)->lfs_dobyteswap ? bswap16(val) : (val)) 203 1.33.2.2 skrll #define LFS_SWAP_uint32_t(fs, val) \ 204 1.33.2.2 skrll ((fs)->lfs_dobyteswap ? bswap32(val) : (val)) 205 1.33.2.2 skrll #define LFS_SWAP_uint64_t(fs, val) \ 206 1.33.2.2 skrll ((fs)->lfs_dobyteswap ? bswap64(val) : (val)) 207 1.33.2.2 skrll #endif 208 1.33.2.2 skrll 209 1.33.2.2 skrll /* 210 1.33.2.2 skrll * For handling directories we will need to know if the volume is 211 1.33.2.2 skrll * little-endian. 212 1.33.2.2 skrll */ 213 1.33.2.2 skrll #if BYTE_ORDER == LITTLE_ENDIAN 214 1.33.2.2 skrll #define LFS_LITTLE_ENDIAN_ONDISK(fs) (!(fs)->lfs_dobyteswap) 215 1.33.2.2 skrll #else 216 1.33.2.2 skrll #define LFS_LITTLE_ENDIAN_ONDISK(fs) ((fs)->lfs_dobyteswap) 217 1.33.2.2 skrll #endif 218 1.33.2.2 skrll 219 1.33.2.2 skrll 220 1.33.2.2 skrll /* 221 1.33.2.2 skrll * directories 222 1.33.2.2 skrll */ 223 1.33.2.2 skrll 224 1.33.2.2 skrll #define LFS_DIRHEADERSIZE(fs) \ 225 1.33.2.2 skrll ((fs)->lfs_is64 ? sizeof(struct lfs_dirheader64) : sizeof(struct lfs_dirheader32)) 226 1.33.2.2 skrll 227 1.33.2.2 skrll /* 228 1.33.2.2 skrll * The LFS_DIRSIZ macro gives the minimum record length which will hold 229 1.33.2.2 skrll * the directory entry. This requires the amount of space in struct lfs_direct 230 1.33.2.2 skrll * without the d_name field, plus enough space for the name with a terminating 231 1.33.2.2 skrll * null byte (dp->d_namlen+1), rounded up to a 4 byte boundary. 232 1.33.2.2 skrll */ 233 1.33.2.2 skrll #define LFS_DIRECTSIZ(fs, namlen) \ 234 1.33.2.2 skrll (LFS_DIRHEADERSIZE(fs) + (((namlen)+1 + 3) &~ 3)) 235 1.33.2.2 skrll 236 1.33.2.2 skrll /* 237 1.33.2.2 skrll * The size of the largest possible directory entry. This is 238 1.33.2.2 skrll * used by ulfs_dirhash to figure the size of an array, so we 239 1.33.2.2 skrll * need a single constant value true for both lfs32 and lfs64. 240 1.33.2.2 skrll */ 241 1.33.2.2 skrll #define LFS_MAXDIRENTRYSIZE \ 242 1.33.2.2 skrll (sizeof(struct lfs_dirheader64) + (((LFS_MAXNAMLEN+1)+1 + 3) & ~3)) 243 1.33.2.2 skrll 244 1.33.2.2 skrll #if (BYTE_ORDER == LITTLE_ENDIAN) 245 1.33.2.2 skrll #define LFS_OLDDIRSIZ(oldfmt, dp, needswap) \ 246 1.33.2.2 skrll (((oldfmt) && !(needswap)) ? \ 247 1.33.2.2 skrll LFS_DIRECTSIZ((dp)->d_type) : LFS_DIRECTSIZ((dp)->d_namlen)) 248 1.33.2.2 skrll #else 249 1.33.2.2 skrll #define LFS_OLDDIRSIZ(oldfmt, dp, needswap) \ 250 1.33.2.2 skrll (((oldfmt) && (needswap)) ? \ 251 1.33.2.2 skrll LFS_DIRECTSIZ((dp)->d_type) : LFS_DIRECTSIZ((dp)->d_namlen)) 252 1.33.2.2 skrll #endif 253 1.33.2.2 skrll 254 1.33.2.2 skrll #define LFS_DIRSIZ(fs, dp) LFS_DIRECTSIZ(fs, lfs_dir_getnamlen(fs, dp)) 255 1.33.2.2 skrll 256 1.33.2.2 skrll /* Constants for the first argument of LFS_OLDDIRSIZ */ 257 1.33.2.2 skrll #define LFS_OLDDIRFMT 1 258 1.33.2.2 skrll #define LFS_NEWDIRFMT 0 259 1.33.2.2 skrll 260 1.33.2.2 skrll #define LFS_NEXTDIR(fs, dp) \ 261 1.33.2.2 skrll ((LFS_DIRHEADER *)((char *)(dp) + lfs_dir_getreclen(fs, dp))) 262 1.33.2.2 skrll 263 1.33.2.4 skrll static __inline char * 264 1.33.2.2 skrll lfs_dir_nameptr(const STRUCT_LFS *fs, LFS_DIRHEADER *dh) 265 1.33.2.2 skrll { 266 1.33.2.2 skrll if (fs->lfs_is64) { 267 1.33.2.2 skrll return (char *)(&dh->u_64 + 1); 268 1.33.2.2 skrll } else { 269 1.33.2.2 skrll return (char *)(&dh->u_32 + 1); 270 1.33.2.2 skrll } 271 1.33.2.2 skrll } 272 1.33.2.2 skrll 273 1.33.2.4 skrll static __inline uint64_t 274 1.33.2.2 skrll lfs_dir_getino(const STRUCT_LFS *fs, const LFS_DIRHEADER *dh) 275 1.33.2.2 skrll { 276 1.33.2.2 skrll if (fs->lfs_is64) { 277 1.33.2.2 skrll uint64_t ino; 278 1.33.2.2 skrll 279 1.33.2.2 skrll /* 280 1.33.2.2 skrll * XXX we can probably write this in a way that's both 281 1.33.2.2 skrll * still legal and generates better code. 282 1.33.2.2 skrll */ 283 1.33.2.2 skrll memcpy(&ino, &dh->u_64.dh_inoA, sizeof(dh->u_64.dh_inoA)); 284 1.33.2.2 skrll memcpy((char *)&ino + sizeof(dh->u_64.dh_inoA), 285 1.33.2.2 skrll &dh->u_64.dh_inoB, 286 1.33.2.2 skrll sizeof(dh->u_64.dh_inoB)); 287 1.33.2.2 skrll return LFS_SWAP_uint64_t(fs, ino); 288 1.33.2.2 skrll } else { 289 1.33.2.2 skrll return LFS_SWAP_uint32_t(fs, dh->u_32.dh_ino); 290 1.33.2.2 skrll } 291 1.33.2.2 skrll } 292 1.33.2.2 skrll 293 1.33.2.4 skrll static __inline uint16_t 294 1.33.2.2 skrll lfs_dir_getreclen(const STRUCT_LFS *fs, const LFS_DIRHEADER *dh) 295 1.33.2.2 skrll { 296 1.33.2.2 skrll if (fs->lfs_is64) { 297 1.33.2.2 skrll return LFS_SWAP_uint16_t(fs, dh->u_64.dh_reclen); 298 1.33.2.2 skrll } else { 299 1.33.2.2 skrll return LFS_SWAP_uint16_t(fs, dh->u_32.dh_reclen); 300 1.33.2.2 skrll } 301 1.33.2.2 skrll } 302 1.33.2.2 skrll 303 1.33.2.4 skrll static __inline uint8_t 304 1.33.2.2 skrll lfs_dir_gettype(const STRUCT_LFS *fs, const LFS_DIRHEADER *dh) 305 1.33.2.2 skrll { 306 1.33.2.2 skrll if (fs->lfs_is64) { 307 1.33.2.2 skrll KASSERT(fs->lfs_hasolddirfmt == 0); 308 1.33.2.2 skrll return dh->u_64.dh_type; 309 1.33.2.2 skrll } else if (fs->lfs_hasolddirfmt) { 310 1.33.2.2 skrll return LFS_DT_UNKNOWN; 311 1.33.2.2 skrll } else { 312 1.33.2.2 skrll return dh->u_32.dh_type; 313 1.33.2.2 skrll } 314 1.33.2.2 skrll } 315 1.33.2.2 skrll 316 1.33.2.4 skrll static __inline uint8_t 317 1.33.2.2 skrll lfs_dir_getnamlen(const STRUCT_LFS *fs, const LFS_DIRHEADER *dh) 318 1.33.2.2 skrll { 319 1.33.2.2 skrll if (fs->lfs_is64) { 320 1.33.2.2 skrll KASSERT(fs->lfs_hasolddirfmt == 0); 321 1.33.2.3 skrll return dh->u_64.dh_namlen; 322 1.33.2.2 skrll } else if (fs->lfs_hasolddirfmt && LFS_LITTLE_ENDIAN_ONDISK(fs)) { 323 1.33.2.2 skrll /* low-order byte of old 16-bit namlen field */ 324 1.33.2.2 skrll return dh->u_32.dh_type; 325 1.33.2.2 skrll } else { 326 1.33.2.2 skrll return dh->u_32.dh_namlen; 327 1.33.2.2 skrll } 328 1.33.2.2 skrll } 329 1.33.2.2 skrll 330 1.33.2.4 skrll static __inline void 331 1.33.2.2 skrll lfs_dir_setino(STRUCT_LFS *fs, LFS_DIRHEADER *dh, uint64_t ino) 332 1.33.2.2 skrll { 333 1.33.2.2 skrll if (fs->lfs_is64) { 334 1.33.2.2 skrll 335 1.33.2.2 skrll ino = LFS_SWAP_uint64_t(fs, ino); 336 1.33.2.2 skrll /* 337 1.33.2.2 skrll * XXX we can probably write this in a way that's both 338 1.33.2.2 skrll * still legal and generates better code. 339 1.33.2.2 skrll */ 340 1.33.2.2 skrll memcpy(&dh->u_64.dh_inoA, &ino, sizeof(dh->u_64.dh_inoA)); 341 1.33.2.2 skrll memcpy(&dh->u_64.dh_inoB, 342 1.33.2.2 skrll (char *)&ino + sizeof(dh->u_64.dh_inoA), 343 1.33.2.2 skrll sizeof(dh->u_64.dh_inoB)); 344 1.33.2.2 skrll } else { 345 1.33.2.2 skrll dh->u_32.dh_ino = LFS_SWAP_uint32_t(fs, ino); 346 1.33.2.2 skrll } 347 1.33.2.2 skrll } 348 1.33.2.2 skrll 349 1.33.2.4 skrll static __inline void 350 1.33.2.2 skrll lfs_dir_setreclen(STRUCT_LFS *fs, LFS_DIRHEADER *dh, uint16_t reclen) 351 1.33.2.2 skrll { 352 1.33.2.2 skrll if (fs->lfs_is64) { 353 1.33.2.2 skrll dh->u_64.dh_reclen = LFS_SWAP_uint16_t(fs, reclen); 354 1.33.2.2 skrll } else { 355 1.33.2.2 skrll dh->u_32.dh_reclen = LFS_SWAP_uint16_t(fs, reclen); 356 1.33.2.2 skrll } 357 1.33.2.2 skrll } 358 1.33.2.2 skrll 359 1.33.2.4 skrll static __inline void 360 1.33.2.2 skrll lfs_dir_settype(const STRUCT_LFS *fs, LFS_DIRHEADER *dh, uint8_t type) 361 1.33.2.2 skrll { 362 1.33.2.2 skrll if (fs->lfs_is64) { 363 1.33.2.2 skrll KASSERT(fs->lfs_hasolddirfmt == 0); 364 1.33.2.2 skrll dh->u_64.dh_type = type; 365 1.33.2.2 skrll } else if (fs->lfs_hasolddirfmt) { 366 1.33.2.2 skrll /* do nothing */ 367 1.33.2.2 skrll return; 368 1.33.2.2 skrll } else { 369 1.33.2.2 skrll dh->u_32.dh_type = type; 370 1.33.2.2 skrll } 371 1.33.2.2 skrll } 372 1.33.2.2 skrll 373 1.33.2.4 skrll static __inline void 374 1.33.2.2 skrll lfs_dir_setnamlen(const STRUCT_LFS *fs, LFS_DIRHEADER *dh, uint8_t namlen) 375 1.33.2.2 skrll { 376 1.33.2.2 skrll if (fs->lfs_is64) { 377 1.33.2.2 skrll KASSERT(fs->lfs_hasolddirfmt == 0); 378 1.33.2.2 skrll dh->u_64.dh_namlen = namlen; 379 1.33.2.2 skrll } else if (fs->lfs_hasolddirfmt && LFS_LITTLE_ENDIAN_ONDISK(fs)) { 380 1.33.2.2 skrll /* low-order byte of old 16-bit namlen field */ 381 1.33.2.2 skrll dh->u_32.dh_type = namlen; 382 1.33.2.2 skrll } else { 383 1.33.2.2 skrll dh->u_32.dh_namlen = namlen; 384 1.33.2.2 skrll } 385 1.33.2.2 skrll } 386 1.33.2.2 skrll 387 1.33.2.4 skrll static __inline void 388 1.33.2.2 skrll lfs_copydirname(STRUCT_LFS *fs, char *dest, const char *src, 389 1.33.2.2 skrll unsigned namlen, unsigned reclen) 390 1.33.2.2 skrll { 391 1.33.2.2 skrll unsigned spacelen; 392 1.33.2.2 skrll 393 1.33.2.2 skrll KASSERT(reclen > LFS_DIRHEADERSIZE(fs)); 394 1.33.2.2 skrll spacelen = reclen - LFS_DIRHEADERSIZE(fs); 395 1.33.2.2 skrll 396 1.33.2.2 skrll /* must always be at least 1 byte as a null terminator */ 397 1.33.2.2 skrll KASSERT(spacelen > namlen); 398 1.33.2.2 skrll 399 1.33.2.2 skrll memcpy(dest, src, namlen); 400 1.33.2.2 skrll memset(dest + namlen, '\0', spacelen - namlen); 401 1.33.2.2 skrll } 402 1.33.2.2 skrll 403 1.33.2.4 skrll static __inline LFS_DIRHEADER * 404 1.33.2.2 skrll lfs_dirtemplate_dotdot(STRUCT_LFS *fs, union lfs_dirtemplate *dt) 405 1.33.2.2 skrll { 406 1.33.2.2 skrll /* XXX blah, be nice to have a way to do this w/o casts */ 407 1.33.2.2 skrll if (fs->lfs_is64) { 408 1.33.2.2 skrll return (LFS_DIRHEADER *)&dt->u_64.dotdot_header; 409 1.33.2.2 skrll } else { 410 1.33.2.2 skrll return (LFS_DIRHEADER *)&dt->u_32.dotdot_header; 411 1.33.2.2 skrll } 412 1.33.2.2 skrll } 413 1.33.2.2 skrll 414 1.33.2.4 skrll static __inline char * 415 1.33.2.2 skrll lfs_dirtemplate_dotdotname(STRUCT_LFS *fs, union lfs_dirtemplate *dt) 416 1.33.2.2 skrll { 417 1.33.2.2 skrll if (fs->lfs_is64) { 418 1.33.2.2 skrll return dt->u_64.dotdot_name; 419 1.33.2.2 skrll } else { 420 1.33.2.2 skrll return dt->u_32.dotdot_name; 421 1.33.2.2 skrll } 422 1.33.2.2 skrll } 423 1.33.2.2 skrll 424 1.33.2.2 skrll /* 425 1.33.2.2 skrll * dinodes 426 1.33.2.2 skrll */ 427 1.33.2.2 skrll 428 1.33.2.2 skrll /* 429 1.33.2.2 skrll * Maximum length of a symlink that can be stored within the inode. 430 1.33.2.2 skrll */ 431 1.33.2.2 skrll #define LFS32_MAXSYMLINKLEN ((ULFS_NDADDR + ULFS_NIADDR) * sizeof(int32_t)) 432 1.33.2.2 skrll #define LFS64_MAXSYMLINKLEN ((ULFS_NDADDR + ULFS_NIADDR) * sizeof(int64_t)) 433 1.33.2.2 skrll 434 1.33.2.2 skrll #define LFS_MAXSYMLINKLEN(fs) \ 435 1.33.2.2 skrll ((fs)->lfs_is64 ? LFS64_MAXSYMLINKLEN : LFS32_MAXSYMLINKLEN) 436 1.33.2.2 skrll 437 1.33.2.2 skrll #define DINOSIZE(fs) ((fs)->lfs_is64 ? sizeof(struct lfs64_dinode) : sizeof(struct lfs32_dinode)) 438 1.33.2.2 skrll 439 1.33.2.2 skrll #define DINO_IN_BLOCK(fs, base, ix) \ 440 1.33.2.2 skrll ((union lfs_dinode *)((char *)(base) + DINOSIZE(fs) * (ix))) 441 1.33.2.2 skrll 442 1.33.2.4 skrll static __inline void 443 1.33.2.2 skrll lfs_copy_dinode(STRUCT_LFS *fs, 444 1.33.2.2 skrll union lfs_dinode *dst, const union lfs_dinode *src) 445 1.33.2.2 skrll { 446 1.33.2.2 skrll /* 447 1.33.2.2 skrll * We can do structure assignment of the structs, but not of 448 1.33.2.2 skrll * the whole union, as the union is the size of the (larger) 449 1.33.2.2 skrll * 64-bit struct and on a 32-bit fs the upper half of it might 450 1.33.2.2 skrll * be off the end of a buffer or otherwise invalid. 451 1.33.2.2 skrll */ 452 1.33.2.2 skrll if (fs->lfs_is64) { 453 1.33.2.2 skrll dst->u_64 = src->u_64; 454 1.33.2.2 skrll } else { 455 1.33.2.2 skrll dst->u_32 = src->u_32; 456 1.33.2.2 skrll } 457 1.33.2.2 skrll } 458 1.33.2.2 skrll 459 1.33.2.2 skrll #define LFS_DEF_DINO_ACCESSOR(type, type32, field) \ 460 1.33.2.4 skrll static __inline type \ 461 1.33.2.2 skrll lfs_dino_get##field(STRUCT_LFS *fs, union lfs_dinode *dip) \ 462 1.33.2.2 skrll { \ 463 1.33.2.2 skrll if (fs->lfs_is64) { \ 464 1.33.2.2 skrll return LFS_SWAP_##type(fs, dip->u_64.di_##field); \ 465 1.33.2.2 skrll } else { \ 466 1.33.2.2 skrll return LFS_SWAP_##type32(fs, dip->u_32.di_##field); \ 467 1.33.2.2 skrll } \ 468 1.33.2.2 skrll } \ 469 1.33.2.4 skrll static __inline void \ 470 1.33.2.2 skrll lfs_dino_set##field(STRUCT_LFS *fs, union lfs_dinode *dip, type val) \ 471 1.33.2.2 skrll { \ 472 1.33.2.2 skrll if (fs->lfs_is64) { \ 473 1.33.2.2 skrll type *p = &dip->u_64.di_##field; \ 474 1.33.2.2 skrll (void)p; \ 475 1.33.2.2 skrll dip->u_64.di_##field = LFS_SWAP_##type(fs, val); \ 476 1.33.2.2 skrll } else { \ 477 1.33.2.2 skrll type32 *p = &dip->u_32.di_##field; \ 478 1.33.2.2 skrll (void)p; \ 479 1.33.2.2 skrll dip->u_32.di_##field = LFS_SWAP_##type32(fs, val); \ 480 1.33.2.2 skrll } \ 481 1.33.2.2 skrll } \ 482 1.33.2.2 skrll 483 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(uint16_t, uint16_t, mode); 484 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(int16_t, int16_t, nlink); 485 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(uint64_t, uint32_t, inumber); 486 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(uint64_t, uint64_t, size); 487 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(int64_t, int32_t, atime); 488 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(int32_t, int32_t, atimensec); 489 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(int64_t, int32_t, mtime); 490 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(int32_t, int32_t, mtimensec); 491 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(int64_t, int32_t, ctime); 492 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(int32_t, int32_t, ctimensec); 493 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(uint32_t, uint32_t, flags); 494 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(uint64_t, uint32_t, blocks); 495 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(int32_t, int32_t, gen); 496 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(uint32_t, uint32_t, uid); 497 1.33.2.2 skrll LFS_DEF_DINO_ACCESSOR(uint32_t, uint32_t, gid); 498 1.33.2.2 skrll 499 1.33.2.2 skrll /* XXX this should be done differently (it's a fake field) */ 500 1.33.2.4 skrll LFS_DEF_DINO_ACCESSOR(int64_t, int32_t, rdev); 501 1.33.2.2 skrll 502 1.33.2.4 skrll static __inline daddr_t 503 1.33.2.2 skrll lfs_dino_getdb(STRUCT_LFS *fs, union lfs_dinode *dip, unsigned ix) 504 1.33.2.2 skrll { 505 1.33.2.2 skrll KASSERT(ix < ULFS_NDADDR); 506 1.33.2.2 skrll if (fs->lfs_is64) { 507 1.33.2.3 skrll return LFS_SWAP_uint64_t(fs, dip->u_64.di_db[ix]); 508 1.33.2.2 skrll } else { 509 1.33.2.3 skrll /* note: this must sign-extend or UNWRITTEN gets trashed */ 510 1.33.2.3 skrll return (int32_t)LFS_SWAP_uint32_t(fs, dip->u_32.di_db[ix]); 511 1.33.2.2 skrll } 512 1.33.2.2 skrll } 513 1.33.2.2 skrll 514 1.33.2.4 skrll static __inline daddr_t 515 1.33.2.2 skrll lfs_dino_getib(STRUCT_LFS *fs, union lfs_dinode *dip, unsigned ix) 516 1.33.2.2 skrll { 517 1.33.2.2 skrll KASSERT(ix < ULFS_NIADDR); 518 1.33.2.2 skrll if (fs->lfs_is64) { 519 1.33.2.3 skrll return LFS_SWAP_uint64_t(fs, dip->u_64.di_ib[ix]); 520 1.33.2.2 skrll } else { 521 1.33.2.3 skrll /* note: this must sign-extend or UNWRITTEN gets trashed */ 522 1.33.2.3 skrll return (int32_t)LFS_SWAP_uint32_t(fs, dip->u_32.di_ib[ix]); 523 1.33.2.2 skrll } 524 1.33.2.2 skrll } 525 1.33.2.2 skrll 526 1.33.2.4 skrll static __inline void 527 1.33.2.2 skrll lfs_dino_setdb(STRUCT_LFS *fs, union lfs_dinode *dip, unsigned ix, daddr_t val) 528 1.33.2.2 skrll { 529 1.33.2.2 skrll KASSERT(ix < ULFS_NDADDR); 530 1.33.2.2 skrll if (fs->lfs_is64) { 531 1.33.2.3 skrll dip->u_64.di_db[ix] = LFS_SWAP_uint64_t(fs, val); 532 1.33.2.2 skrll } else { 533 1.33.2.3 skrll dip->u_32.di_db[ix] = LFS_SWAP_uint32_t(fs, val); 534 1.33.2.2 skrll } 535 1.33.2.2 skrll } 536 1.33.2.2 skrll 537 1.33.2.4 skrll static __inline void 538 1.33.2.2 skrll lfs_dino_setib(STRUCT_LFS *fs, union lfs_dinode *dip, unsigned ix, daddr_t val) 539 1.33.2.2 skrll { 540 1.33.2.2 skrll KASSERT(ix < ULFS_NIADDR); 541 1.33.2.2 skrll if (fs->lfs_is64) { 542 1.33.2.3 skrll dip->u_64.di_ib[ix] = LFS_SWAP_uint64_t(fs, val); 543 1.33.2.2 skrll } else { 544 1.33.2.3 skrll dip->u_32.di_ib[ix] = LFS_SWAP_uint32_t(fs, val); 545 1.33.2.2 skrll } 546 1.33.2.2 skrll } 547 1.33.2.2 skrll 548 1.33.2.2 skrll /* birthtime is present only in the 64-bit inode */ 549 1.33.2.4 skrll static __inline void 550 1.33.2.2 skrll lfs_dino_setbirthtime(STRUCT_LFS *fs, union lfs_dinode *dip, 551 1.33.2.2 skrll const struct timespec *ts) 552 1.33.2.2 skrll { 553 1.33.2.2 skrll if (fs->lfs_is64) { 554 1.33.2.2 skrll dip->u_64.di_birthtime = ts->tv_sec; 555 1.33.2.2 skrll dip->u_64.di_birthnsec = ts->tv_nsec; 556 1.33.2.2 skrll } else { 557 1.33.2.2 skrll /* drop it on the floor */ 558 1.33.2.2 skrll } 559 1.33.2.2 skrll } 560 1.33.2.2 skrll 561 1.33.2.2 skrll /* 562 1.33.2.2 skrll * indirect blocks 563 1.33.2.2 skrll */ 564 1.33.2.2 skrll 565 1.33.2.4 skrll static __inline daddr_t 566 1.33.2.2 skrll lfs_iblock_get(STRUCT_LFS *fs, void *block, unsigned ix) 567 1.33.2.2 skrll { 568 1.33.2.2 skrll if (fs->lfs_is64) { 569 1.33.2.2 skrll // XXX re-enable these asserts after reorging this file 570 1.33.2.2 skrll //KASSERT(ix < lfs_sb_getbsize(fs) / sizeof(int64_t)); 571 1.33.2.2 skrll return (daddr_t)(((int64_t *)block)[ix]); 572 1.33.2.2 skrll } else { 573 1.33.2.2 skrll //KASSERT(ix < lfs_sb_getbsize(fs) / sizeof(int32_t)); 574 1.33.2.2 skrll /* must sign-extend or UNWRITTEN gets trashed */ 575 1.33.2.2 skrll return (daddr_t)(int64_t)(((int32_t *)block)[ix]); 576 1.33.2.2 skrll } 577 1.33.2.2 skrll } 578 1.33.2.2 skrll 579 1.33.2.4 skrll static __inline void 580 1.33.2.2 skrll lfs_iblock_set(STRUCT_LFS *fs, void *block, unsigned ix, daddr_t val) 581 1.33.2.2 skrll { 582 1.33.2.2 skrll if (fs->lfs_is64) { 583 1.33.2.2 skrll //KASSERT(ix < lfs_sb_getbsize(fs) / sizeof(int64_t)); 584 1.33.2.2 skrll ((int64_t *)block)[ix] = val; 585 1.33.2.2 skrll } else { 586 1.33.2.2 skrll //KASSERT(ix < lfs_sb_getbsize(fs) / sizeof(int32_t)); 587 1.33.2.2 skrll ((int32_t *)block)[ix] = val; 588 1.33.2.2 skrll } 589 1.33.2.2 skrll } 590 1.33.2.2 skrll 591 1.33.2.2 skrll /* 592 1.33.2.2 skrll * "struct buf" associated definitions 593 1.33.2.2 skrll */ 594 1.33.2.2 skrll 595 1.33.2.2 skrll # define LFS_LOCK_BUF(bp) do { \ 596 1.33.2.2 skrll if (((bp)->b_flags & B_LOCKED) == 0 && bp->b_iodone == NULL) { \ 597 1.33.2.2 skrll mutex_enter(&lfs_lock); \ 598 1.33.2.2 skrll ++locked_queue_count; \ 599 1.33.2.2 skrll locked_queue_bytes += bp->b_bufsize; \ 600 1.33.2.2 skrll mutex_exit(&lfs_lock); \ 601 1.33.2.2 skrll } \ 602 1.33.2.2 skrll (bp)->b_flags |= B_LOCKED; \ 603 1.33.2.2 skrll } while (0) 604 1.33.2.2 skrll 605 1.33.2.2 skrll # define LFS_UNLOCK_BUF(bp) do { \ 606 1.33.2.2 skrll if (((bp)->b_flags & B_LOCKED) != 0 && bp->b_iodone == NULL) { \ 607 1.33.2.2 skrll mutex_enter(&lfs_lock); \ 608 1.33.2.2 skrll --locked_queue_count; \ 609 1.33.2.2 skrll locked_queue_bytes -= bp->b_bufsize; \ 610 1.33.2.2 skrll if (locked_queue_count < LFS_WAIT_BUFS && \ 611 1.33.2.2 skrll locked_queue_bytes < LFS_WAIT_BYTES) \ 612 1.33.2.2 skrll cv_broadcast(&locked_queue_cv); \ 613 1.33.2.2 skrll mutex_exit(&lfs_lock); \ 614 1.33.2.2 skrll } \ 615 1.33.2.2 skrll (bp)->b_flags &= ~B_LOCKED; \ 616 1.33.2.2 skrll } while (0) 617 1.33.2.2 skrll 618 1.33.2.2 skrll /* 619 1.33.2.2 skrll * "struct inode" associated definitions 620 1.33.2.2 skrll */ 621 1.33.2.2 skrll 622 1.33.2.2 skrll #define LFS_SET_UINO(ip, flags) do { \ 623 1.33.2.2 skrll if (((flags) & IN_ACCESSED) && !((ip)->i_flag & IN_ACCESSED)) \ 624 1.33.2.2 skrll lfs_sb_adduinodes((ip)->i_lfs, 1); \ 625 1.33.2.2 skrll if (((flags) & IN_CLEANING) && !((ip)->i_flag & IN_CLEANING)) \ 626 1.33.2.2 skrll lfs_sb_adduinodes((ip)->i_lfs, 1); \ 627 1.33.2.2 skrll if (((flags) & IN_MODIFIED) && !((ip)->i_flag & IN_MODIFIED)) \ 628 1.33.2.2 skrll lfs_sb_adduinodes((ip)->i_lfs, 1); \ 629 1.33.2.2 skrll (ip)->i_flag |= (flags); \ 630 1.33.2.2 skrll } while (0) 631 1.33.2.2 skrll 632 1.33.2.2 skrll #define LFS_CLR_UINO(ip, flags) do { \ 633 1.33.2.2 skrll if (((flags) & IN_ACCESSED) && ((ip)->i_flag & IN_ACCESSED)) \ 634 1.33.2.2 skrll lfs_sb_subuinodes((ip)->i_lfs, 1); \ 635 1.33.2.2 skrll if (((flags) & IN_CLEANING) && ((ip)->i_flag & IN_CLEANING)) \ 636 1.33.2.2 skrll lfs_sb_subuinodes((ip)->i_lfs, 1); \ 637 1.33.2.2 skrll if (((flags) & IN_MODIFIED) && ((ip)->i_flag & IN_MODIFIED)) \ 638 1.33.2.2 skrll lfs_sb_subuinodes((ip)->i_lfs, 1); \ 639 1.33.2.2 skrll (ip)->i_flag &= ~(flags); \ 640 1.33.2.2 skrll if (lfs_sb_getuinodes((ip)->i_lfs) < 0) { \ 641 1.33.2.2 skrll panic("lfs_uinodes < 0"); \ 642 1.33.2.2 skrll } \ 643 1.33.2.2 skrll } while (0) 644 1.33.2.2 skrll 645 1.33.2.2 skrll #define LFS_ITIMES(ip, acc, mod, cre) \ 646 1.33.2.2 skrll while ((ip)->i_flag & (IN_ACCESS | IN_CHANGE | IN_UPDATE | IN_MODIFY)) \ 647 1.33.2.2 skrll lfs_itimes(ip, acc, mod, cre) 648 1.33.2.2 skrll 649 1.33.2.2 skrll /* 650 1.33.2.2 skrll * On-disk and in-memory checkpoint segment usage structure. 651 1.33.2.2 skrll */ 652 1.33.2.2 skrll 653 1.33.2.2 skrll #define SEGUPB(fs) (lfs_sb_getsepb(fs)) 654 1.33.2.2 skrll #define SEGTABSIZE_SU(fs) \ 655 1.33.2.2 skrll ((lfs_sb_getnseg(fs) + SEGUPB(fs) - 1) / lfs_sb_getsepb(fs)) 656 1.33.2.2 skrll 657 1.33.2.2 skrll #ifdef _KERNEL 658 1.33.2.2 skrll # define SHARE_IFLOCK(F) \ 659 1.33.2.2 skrll do { \ 660 1.33.2.2 skrll rw_enter(&(F)->lfs_iflock, RW_READER); \ 661 1.33.2.2 skrll } while(0) 662 1.33.2.2 skrll # define UNSHARE_IFLOCK(F) \ 663 1.33.2.2 skrll do { \ 664 1.33.2.2 skrll rw_exit(&(F)->lfs_iflock); \ 665 1.33.2.2 skrll } while(0) 666 1.33.2.2 skrll #else /* ! _KERNEL */ 667 1.33.2.2 skrll # define SHARE_IFLOCK(F) 668 1.33.2.2 skrll # define UNSHARE_IFLOCK(F) 669 1.33.2.2 skrll #endif /* ! _KERNEL */ 670 1.33.2.2 skrll 671 1.33.2.2 skrll /* Read in the block with a specific segment usage entry from the ifile. */ 672 1.33.2.2 skrll #define LFS_SEGENTRY(SP, F, IN, BP) do { \ 673 1.33.2.2 skrll int _e; \ 674 1.33.2.2 skrll SHARE_IFLOCK(F); \ 675 1.33.2.2 skrll VTOI((F)->lfs_ivnode)->i_flag |= IN_ACCESS; \ 676 1.33.2.2 skrll if ((_e = bread((F)->lfs_ivnode, \ 677 1.33.2.2 skrll ((IN) / lfs_sb_getsepb(F)) + lfs_sb_getcleansz(F), \ 678 1.33.2.2 skrll lfs_sb_getbsize(F), 0, &(BP))) != 0) \ 679 1.33.2.3 skrll panic("lfs: ifile read: segentry %llu: error %d\n", \ 680 1.33.2.3 skrll (unsigned long long)(IN), _e); \ 681 1.33.2.2 skrll if (lfs_sb_getversion(F) == 1) \ 682 1.33.2.2 skrll (SP) = (SEGUSE *)((SEGUSE_V1 *)(BP)->b_data + \ 683 1.33.2.2 skrll ((IN) & (lfs_sb_getsepb(F) - 1))); \ 684 1.33.2.2 skrll else \ 685 1.33.2.2 skrll (SP) = (SEGUSE *)(BP)->b_data + ((IN) % lfs_sb_getsepb(F)); \ 686 1.33.2.2 skrll UNSHARE_IFLOCK(F); \ 687 1.33.2.2 skrll } while (0) 688 1.33.2.2 skrll 689 1.33.2.2 skrll #define LFS_WRITESEGENTRY(SP, F, IN, BP) do { \ 690 1.33.2.2 skrll if ((SP)->su_nbytes == 0) \ 691 1.33.2.2 skrll (SP)->su_flags |= SEGUSE_EMPTY; \ 692 1.33.2.2 skrll else \ 693 1.33.2.2 skrll (SP)->su_flags &= ~SEGUSE_EMPTY; \ 694 1.33.2.2 skrll (F)->lfs_suflags[(F)->lfs_activesb][(IN)] = (SP)->su_flags; \ 695 1.33.2.2 skrll LFS_BWRITE_LOG(BP); \ 696 1.33.2.2 skrll } while (0) 697 1.33.2.2 skrll 698 1.33.2.2 skrll /* 699 1.33.2.2 skrll * FINFO (file info) entries. 700 1.33.2.2 skrll */ 701 1.33.2.2 skrll 702 1.33.2.2 skrll /* Size of an on-disk block pointer, e.g. in an indirect block. */ 703 1.33.2.2 skrll /* XXX: move to a more suitable location in this file */ 704 1.33.2.2 skrll #define LFS_BLKPTRSIZE(fs) ((fs)->lfs_is64 ? sizeof(int64_t) : sizeof(int32_t)) 705 1.33.2.2 skrll 706 1.33.2.2 skrll /* Size of an on-disk inode number. */ 707 1.33.2.2 skrll /* XXX: move to a more suitable location in this file */ 708 1.33.2.2 skrll #define LFS_INUMSIZE(fs) ((fs)->lfs_is64 ? sizeof(int64_t) : sizeof(int32_t)) 709 1.33.2.2 skrll 710 1.33.2.2 skrll /* size of a FINFO, without the block pointers */ 711 1.33.2.2 skrll #define FINFOSIZE(fs) ((fs)->lfs_is64 ? sizeof(FINFO64) : sizeof(FINFO32)) 712 1.33.2.2 skrll 713 1.33.2.2 skrll /* Full size of the provided FINFO record, including its block pointers. */ 714 1.33.2.2 skrll #define FINFO_FULLSIZE(fs, fip) \ 715 1.33.2.2 skrll (FINFOSIZE(fs) + lfs_fi_getnblocks(fs, fip) * LFS_BLKPTRSIZE(fs)) 716 1.33.2.2 skrll 717 1.33.2.2 skrll #define NEXT_FINFO(fs, fip) \ 718 1.33.2.2 skrll ((FINFO *)((char *)(fip) + FINFO_FULLSIZE(fs, fip))) 719 1.33.2.2 skrll 720 1.33.2.2 skrll #define LFS_DEF_FI_ACCESSOR(type, type32, field) \ 721 1.33.2.4 skrll static __inline type \ 722 1.33.2.2 skrll lfs_fi_get##field(STRUCT_LFS *fs, FINFO *fip) \ 723 1.33.2.2 skrll { \ 724 1.33.2.2 skrll if (fs->lfs_is64) { \ 725 1.33.2.2 skrll return fip->u_64.fi_##field; \ 726 1.33.2.2 skrll } else { \ 727 1.33.2.2 skrll return fip->u_32.fi_##field; \ 728 1.33.2.2 skrll } \ 729 1.33.2.2 skrll } \ 730 1.33.2.4 skrll static __inline void \ 731 1.33.2.2 skrll lfs_fi_set##field(STRUCT_LFS *fs, FINFO *fip, type val) \ 732 1.33.2.2 skrll { \ 733 1.33.2.2 skrll if (fs->lfs_is64) { \ 734 1.33.2.2 skrll type *p = &fip->u_64.fi_##field; \ 735 1.33.2.2 skrll (void)p; \ 736 1.33.2.2 skrll fip->u_64.fi_##field = val; \ 737 1.33.2.2 skrll } else { \ 738 1.33.2.2 skrll type32 *p = &fip->u_32.fi_##field; \ 739 1.33.2.2 skrll (void)p; \ 740 1.33.2.2 skrll fip->u_32.fi_##field = val; \ 741 1.33.2.2 skrll } \ 742 1.33.2.2 skrll } \ 743 1.33.2.2 skrll 744 1.33.2.2 skrll LFS_DEF_FI_ACCESSOR(uint32_t, uint32_t, nblocks); 745 1.33.2.2 skrll LFS_DEF_FI_ACCESSOR(uint32_t, uint32_t, version); 746 1.33.2.2 skrll LFS_DEF_FI_ACCESSOR(uint64_t, uint32_t, ino); 747 1.33.2.2 skrll LFS_DEF_FI_ACCESSOR(uint32_t, uint32_t, lastlength); 748 1.33.2.2 skrll 749 1.33.2.4 skrll static __inline daddr_t 750 1.33.2.4 skrll lfs_fi_getblock(STRUCT_LFS *fs, FINFO *fip, unsigned idx) 751 1.33.2.2 skrll { 752 1.33.2.2 skrll void *firstblock; 753 1.33.2.2 skrll 754 1.33.2.2 skrll firstblock = (char *)fip + FINFOSIZE(fs); 755 1.33.2.4 skrll KASSERT(idx < lfs_fi_getnblocks(fs, fip)); 756 1.33.2.2 skrll if (fs->lfs_is64) { 757 1.33.2.4 skrll return ((int64_t *)firstblock)[idx]; 758 1.33.2.2 skrll } else { 759 1.33.2.4 skrll return ((int32_t *)firstblock)[idx]; 760 1.33.2.2 skrll } 761 1.33.2.2 skrll } 762 1.33.2.2 skrll 763 1.33.2.4 skrll static __inline void 764 1.33.2.4 skrll lfs_fi_setblock(STRUCT_LFS *fs, FINFO *fip, unsigned idx, daddr_t blk) 765 1.33.2.2 skrll { 766 1.33.2.2 skrll void *firstblock; 767 1.33.2.2 skrll 768 1.33.2.2 skrll firstblock = (char *)fip + FINFOSIZE(fs); 769 1.33.2.4 skrll KASSERT(idx < lfs_fi_getnblocks(fs, fip)); 770 1.33.2.2 skrll if (fs->lfs_is64) { 771 1.33.2.4 skrll ((int64_t *)firstblock)[idx] = blk; 772 1.33.2.2 skrll } else { 773 1.33.2.4 skrll ((int32_t *)firstblock)[idx] = blk; 774 1.33.2.2 skrll } 775 1.33.2.2 skrll } 776 1.33.2.2 skrll 777 1.33.2.2 skrll /* 778 1.33.2.3 skrll * inode info entries (in the segment summary) 779 1.33.2.3 skrll */ 780 1.33.2.3 skrll 781 1.33.2.3 skrll #define IINFOSIZE(fs) ((fs)->lfs_is64 ? sizeof(IINFO64) : sizeof(IINFO32)) 782 1.33.2.3 skrll 783 1.33.2.3 skrll /* iinfos scroll backward from the end of the segment summary block */ 784 1.33.2.3 skrll #define SEGSUM_IINFOSTART(fs, buf) \ 785 1.33.2.3 skrll ((IINFO *)((char *)buf + lfs_sb_getsumsize(fs) - IINFOSIZE(fs))) 786 1.33.2.3 skrll 787 1.33.2.3 skrll #define NEXTLOWER_IINFO(fs, iip) \ 788 1.33.2.3 skrll ((IINFO *)((char *)(iip) - IINFOSIZE(fs))) 789 1.33.2.3 skrll 790 1.33.2.3 skrll #define NTH_IINFO(fs, buf, n) \ 791 1.33.2.3 skrll ((IINFO *)((char *)SEGSUM_IINFOSTART(fs, buf) - (n)*IINFOSIZE(fs))) 792 1.33.2.3 skrll 793 1.33.2.4 skrll static __inline uint64_t 794 1.33.2.3 skrll lfs_ii_getblock(STRUCT_LFS *fs, IINFO *iip) 795 1.33.2.3 skrll { 796 1.33.2.3 skrll if (fs->lfs_is64) { 797 1.33.2.3 skrll return iip->u_64.ii_block; 798 1.33.2.3 skrll } else { 799 1.33.2.3 skrll return iip->u_32.ii_block; 800 1.33.2.3 skrll } 801 1.33.2.3 skrll } 802 1.33.2.3 skrll 803 1.33.2.4 skrll static __inline void 804 1.33.2.3 skrll lfs_ii_setblock(STRUCT_LFS *fs, IINFO *iip, uint64_t block) 805 1.33.2.3 skrll { 806 1.33.2.3 skrll if (fs->lfs_is64) { 807 1.33.2.3 skrll iip->u_64.ii_block = block; 808 1.33.2.3 skrll } else { 809 1.33.2.3 skrll iip->u_32.ii_block = block; 810 1.33.2.3 skrll } 811 1.33.2.3 skrll } 812 1.33.2.3 skrll 813 1.33.2.3 skrll /* 814 1.33.2.2 skrll * Index file inode entries. 815 1.33.2.2 skrll */ 816 1.33.2.2 skrll 817 1.33.2.2 skrll #define IFILE_ENTRYSIZE(fs) \ 818 1.33.2.2 skrll ((fs)->lfs_is64 ? sizeof(IFILE64) : sizeof(IFILE32)) 819 1.33.2.2 skrll 820 1.33.2.2 skrll /* 821 1.33.2.2 skrll * LFSv1 compatibility code is not allowed to touch if_atime, since it 822 1.33.2.2 skrll * may not be mapped! 823 1.33.2.2 skrll */ 824 1.33.2.2 skrll /* Read in the block with a specific inode from the ifile. */ 825 1.33.2.2 skrll #define LFS_IENTRY(IP, F, IN, BP) do { \ 826 1.33.2.2 skrll int _e; \ 827 1.33.2.2 skrll SHARE_IFLOCK(F); \ 828 1.33.2.2 skrll VTOI((F)->lfs_ivnode)->i_flag |= IN_ACCESS; \ 829 1.33.2.2 skrll if ((_e = bread((F)->lfs_ivnode, \ 830 1.33.2.2 skrll (IN) / lfs_sb_getifpb(F) + lfs_sb_getcleansz(F) + lfs_sb_getsegtabsz(F), \ 831 1.33.2.2 skrll lfs_sb_getbsize(F), 0, &(BP))) != 0) \ 832 1.33.2.2 skrll panic("lfs: ifile ino %d read %d", (int)(IN), _e); \ 833 1.33.2.2 skrll if ((F)->lfs_is64) { \ 834 1.33.2.2 skrll (IP) = (IFILE *)((IFILE64 *)(BP)->b_data + \ 835 1.33.2.2 skrll (IN) % lfs_sb_getifpb(F)); \ 836 1.33.2.2 skrll } else if (lfs_sb_getversion(F) > 1) { \ 837 1.33.2.2 skrll (IP) = (IFILE *)((IFILE32 *)(BP)->b_data + \ 838 1.33.2.2 skrll (IN) % lfs_sb_getifpb(F)); \ 839 1.33.2.2 skrll } else { \ 840 1.33.2.2 skrll (IP) = (IFILE *)((IFILE_V1 *)(BP)->b_data + \ 841 1.33.2.2 skrll (IN) % lfs_sb_getifpb(F)); \ 842 1.33.2.2 skrll } \ 843 1.33.2.2 skrll UNSHARE_IFLOCK(F); \ 844 1.33.2.2 skrll } while (0) 845 1.33.2.2 skrll #define LFS_IENTRY_NEXT(IP, F) do { \ 846 1.33.2.2 skrll if ((F)->lfs_is64) { \ 847 1.33.2.2 skrll (IP) = (IFILE *)((IFILE64 *)(IP) + 1); \ 848 1.33.2.2 skrll } else if (lfs_sb_getversion(F) > 1) { \ 849 1.33.2.2 skrll (IP) = (IFILE *)((IFILE32 *)(IP) + 1); \ 850 1.33.2.2 skrll } else { \ 851 1.33.2.2 skrll (IP) = (IFILE *)((IFILE_V1 *)(IP) + 1); \ 852 1.33.2.2 skrll } \ 853 1.33.2.2 skrll } while (0) 854 1.33.2.2 skrll 855 1.33.2.2 skrll #define LFS_DEF_IF_ACCESSOR(type, type32, field) \ 856 1.33.2.4 skrll static __inline type \ 857 1.33.2.2 skrll lfs_if_get##field(STRUCT_LFS *fs, IFILE *ifp) \ 858 1.33.2.2 skrll { \ 859 1.33.2.2 skrll if (fs->lfs_is64) { \ 860 1.33.2.2 skrll return ifp->u_64.if_##field; \ 861 1.33.2.2 skrll } else { \ 862 1.33.2.2 skrll return ifp->u_32.if_##field; \ 863 1.33.2.2 skrll } \ 864 1.33.2.2 skrll } \ 865 1.33.2.4 skrll static __inline void \ 866 1.33.2.2 skrll lfs_if_set##field(STRUCT_LFS *fs, IFILE *ifp, type val) \ 867 1.33.2.2 skrll { \ 868 1.33.2.2 skrll if (fs->lfs_is64) { \ 869 1.33.2.2 skrll type *p = &ifp->u_64.if_##field; \ 870 1.33.2.2 skrll (void)p; \ 871 1.33.2.2 skrll ifp->u_64.if_##field = val; \ 872 1.33.2.2 skrll } else { \ 873 1.33.2.2 skrll type32 *p = &ifp->u_32.if_##field; \ 874 1.33.2.2 skrll (void)p; \ 875 1.33.2.2 skrll ifp->u_32.if_##field = val; \ 876 1.33.2.2 skrll } \ 877 1.33.2.2 skrll } \ 878 1.33.2.2 skrll 879 1.33.2.5 skrll LFS_DEF_IF_ACCESSOR(uint32_t, uint32_t, version); 880 1.33.2.2 skrll LFS_DEF_IF_ACCESSOR(int64_t, int32_t, daddr); 881 1.33.2.5 skrll LFS_DEF_IF_ACCESSOR(uint64_t, uint32_t, nextfree); 882 1.33.2.5 skrll LFS_DEF_IF_ACCESSOR(uint64_t, uint32_t, atime_sec); 883 1.33.2.5 skrll LFS_DEF_IF_ACCESSOR(uint32_t, uint32_t, atime_nsec); 884 1.33.2.2 skrll 885 1.33.2.2 skrll /* 886 1.33.2.2 skrll * Cleaner information structure. This resides in the ifile and is used 887 1.33.2.2 skrll * to pass information from the kernel to the cleaner. 888 1.33.2.2 skrll */ 889 1.33.2.2 skrll 890 1.33.2.2 skrll #define CLEANSIZE_SU(fs) \ 891 1.33.2.2 skrll ((((fs)->lfs_is64 ? sizeof(CLEANERINFO64) : sizeof(CLEANERINFO32)) + \ 892 1.33.2.2 skrll lfs_sb_getbsize(fs) - 1) >> lfs_sb_getbshift(fs)) 893 1.33.2.2 skrll 894 1.33.2.2 skrll #define LFS_DEF_CI_ACCESSOR(type, type32, field) \ 895 1.33.2.4 skrll static __inline type \ 896 1.33.2.2 skrll lfs_ci_get##field(STRUCT_LFS *fs, CLEANERINFO *cip) \ 897 1.33.2.2 skrll { \ 898 1.33.2.2 skrll if (fs->lfs_is64) { \ 899 1.33.2.2 skrll return cip->u_64.field; \ 900 1.33.2.2 skrll } else { \ 901 1.33.2.2 skrll return cip->u_32.field; \ 902 1.33.2.2 skrll } \ 903 1.33.2.2 skrll } \ 904 1.33.2.4 skrll static __inline void \ 905 1.33.2.2 skrll lfs_ci_set##field(STRUCT_LFS *fs, CLEANERINFO *cip, type val) \ 906 1.33.2.2 skrll { \ 907 1.33.2.2 skrll if (fs->lfs_is64) { \ 908 1.33.2.2 skrll type *p = &cip->u_64.field; \ 909 1.33.2.2 skrll (void)p; \ 910 1.33.2.2 skrll cip->u_64.field = val; \ 911 1.33.2.2 skrll } else { \ 912 1.33.2.2 skrll type32 *p = &cip->u_32.field; \ 913 1.33.2.2 skrll (void)p; \ 914 1.33.2.2 skrll cip->u_32.field = val; \ 915 1.33.2.2 skrll } \ 916 1.33.2.2 skrll } \ 917 1.33.2.2 skrll 918 1.33.2.5 skrll LFS_DEF_CI_ACCESSOR(uint32_t, uint32_t, clean); 919 1.33.2.5 skrll LFS_DEF_CI_ACCESSOR(uint32_t, uint32_t, dirty); 920 1.33.2.2 skrll LFS_DEF_CI_ACCESSOR(int64_t, int32_t, bfree); 921 1.33.2.2 skrll LFS_DEF_CI_ACCESSOR(int64_t, int32_t, avail); 922 1.33.2.5 skrll LFS_DEF_CI_ACCESSOR(uint64_t, uint32_t, free_head); 923 1.33.2.5 skrll LFS_DEF_CI_ACCESSOR(uint64_t, uint32_t, free_tail); 924 1.33.2.5 skrll LFS_DEF_CI_ACCESSOR(uint32_t, uint32_t, flags); 925 1.33.2.2 skrll 926 1.33.2.4 skrll static __inline void 927 1.33.2.2 skrll lfs_ci_shiftcleantodirty(STRUCT_LFS *fs, CLEANERINFO *cip, unsigned num) 928 1.33.2.2 skrll { 929 1.33.2.2 skrll lfs_ci_setclean(fs, cip, lfs_ci_getclean(fs, cip) - num); 930 1.33.2.2 skrll lfs_ci_setdirty(fs, cip, lfs_ci_getdirty(fs, cip) + num); 931 1.33.2.2 skrll } 932 1.33.2.2 skrll 933 1.33.2.4 skrll static __inline void 934 1.33.2.2 skrll lfs_ci_shiftdirtytoclean(STRUCT_LFS *fs, CLEANERINFO *cip, unsigned num) 935 1.33.2.2 skrll { 936 1.33.2.2 skrll lfs_ci_setdirty(fs, cip, lfs_ci_getdirty(fs, cip) - num); 937 1.33.2.2 skrll lfs_ci_setclean(fs, cip, lfs_ci_getclean(fs, cip) + num); 938 1.33.2.2 skrll } 939 1.33.2.2 skrll 940 1.33.2.2 skrll /* Read in the block with the cleaner info from the ifile. */ 941 1.33.2.2 skrll #define LFS_CLEANERINFO(CP, F, BP) do { \ 942 1.33.2.3 skrll int _e; \ 943 1.33.2.2 skrll SHARE_IFLOCK(F); \ 944 1.33.2.2 skrll VTOI((F)->lfs_ivnode)->i_flag |= IN_ACCESS; \ 945 1.33.2.3 skrll _e = bread((F)->lfs_ivnode, \ 946 1.33.2.3 skrll (daddr_t)0, lfs_sb_getbsize(F), 0, &(BP)); \ 947 1.33.2.3 skrll if (_e) \ 948 1.33.2.3 skrll panic("lfs: ifile read: cleanerinfo: error %d\n", _e); \ 949 1.33.2.2 skrll (CP) = (CLEANERINFO *)(BP)->b_data; \ 950 1.33.2.2 skrll UNSHARE_IFLOCK(F); \ 951 1.33.2.2 skrll } while (0) 952 1.33.2.2 skrll 953 1.33.2.2 skrll /* 954 1.33.2.2 skrll * Synchronize the Ifile cleaner info with current avail and bfree. 955 1.33.2.2 skrll */ 956 1.33.2.2 skrll #define LFS_SYNC_CLEANERINFO(cip, fs, bp, w) do { \ 957 1.33.2.2 skrll mutex_enter(&lfs_lock); \ 958 1.33.2.2 skrll if ((w) || lfs_ci_getbfree(fs, cip) != lfs_sb_getbfree(fs) || \ 959 1.33.2.2 skrll lfs_ci_getavail(fs, cip) != lfs_sb_getavail(fs) - fs->lfs_ravail - \ 960 1.33.2.2 skrll fs->lfs_favail) { \ 961 1.33.2.2 skrll lfs_ci_setbfree(fs, cip, lfs_sb_getbfree(fs)); \ 962 1.33.2.2 skrll lfs_ci_setavail(fs, cip, lfs_sb_getavail(fs) - fs->lfs_ravail - \ 963 1.33.2.2 skrll fs->lfs_favail); \ 964 1.33.2.2 skrll if (((bp)->b_flags & B_GATHERED) == 0) { \ 965 1.33.2.2 skrll fs->lfs_flags |= LFS_IFDIRTY; \ 966 1.33.2.2 skrll } \ 967 1.33.2.2 skrll mutex_exit(&lfs_lock); \ 968 1.33.2.2 skrll (void) LFS_BWRITE_LOG(bp); /* Ifile */ \ 969 1.33.2.2 skrll } else { \ 970 1.33.2.2 skrll mutex_exit(&lfs_lock); \ 971 1.33.2.2 skrll brelse(bp, 0); \ 972 1.33.2.2 skrll } \ 973 1.33.2.2 skrll } while (0) 974 1.33.2.2 skrll 975 1.33.2.2 skrll /* 976 1.33.2.2 skrll * Get the head of the inode free list. 977 1.33.2.2 skrll * Always called with the segment lock held. 978 1.33.2.2 skrll */ 979 1.33.2.2 skrll #define LFS_GET_HEADFREE(FS, CIP, BP, FREEP) do { \ 980 1.33.2.2 skrll if (lfs_sb_getversion(FS) > 1) { \ 981 1.33.2.2 skrll LFS_CLEANERINFO((CIP), (FS), (BP)); \ 982 1.33.2.2 skrll lfs_sb_setfreehd(FS, lfs_ci_getfree_head(FS, CIP)); \ 983 1.33.2.2 skrll brelse(BP, 0); \ 984 1.33.2.2 skrll } \ 985 1.33.2.2 skrll *(FREEP) = lfs_sb_getfreehd(FS); \ 986 1.33.2.2 skrll } while (0) 987 1.33.2.2 skrll 988 1.33.2.2 skrll #define LFS_PUT_HEADFREE(FS, CIP, BP, VAL) do { \ 989 1.33.2.2 skrll lfs_sb_setfreehd(FS, VAL); \ 990 1.33.2.2 skrll if (lfs_sb_getversion(FS) > 1) { \ 991 1.33.2.2 skrll LFS_CLEANERINFO((CIP), (FS), (BP)); \ 992 1.33.2.2 skrll lfs_ci_setfree_head(FS, CIP, VAL); \ 993 1.33.2.2 skrll LFS_BWRITE_LOG(BP); \ 994 1.33.2.2 skrll mutex_enter(&lfs_lock); \ 995 1.33.2.2 skrll (FS)->lfs_flags |= LFS_IFDIRTY; \ 996 1.33.2.2 skrll mutex_exit(&lfs_lock); \ 997 1.33.2.2 skrll } \ 998 1.33.2.2 skrll } while (0) 999 1.33.2.2 skrll 1000 1.33.2.2 skrll #define LFS_GET_TAILFREE(FS, CIP, BP, FREEP) do { \ 1001 1.33.2.2 skrll LFS_CLEANERINFO((CIP), (FS), (BP)); \ 1002 1.33.2.2 skrll *(FREEP) = lfs_ci_getfree_tail(FS, CIP); \ 1003 1.33.2.2 skrll brelse(BP, 0); \ 1004 1.33.2.2 skrll } while (0) 1005 1.33.2.2 skrll 1006 1.33.2.2 skrll #define LFS_PUT_TAILFREE(FS, CIP, BP, VAL) do { \ 1007 1.33.2.2 skrll LFS_CLEANERINFO((CIP), (FS), (BP)); \ 1008 1.33.2.2 skrll lfs_ci_setfree_tail(FS, CIP, VAL); \ 1009 1.33.2.2 skrll LFS_BWRITE_LOG(BP); \ 1010 1.33.2.2 skrll mutex_enter(&lfs_lock); \ 1011 1.33.2.2 skrll (FS)->lfs_flags |= LFS_IFDIRTY; \ 1012 1.33.2.2 skrll mutex_exit(&lfs_lock); \ 1013 1.33.2.2 skrll } while (0) 1014 1.33.2.2 skrll 1015 1.33.2.2 skrll /* 1016 1.33.2.2 skrll * On-disk segment summary information 1017 1.33.2.2 skrll */ 1018 1.33.2.2 skrll 1019 1.33.2.2 skrll #define SEGSUM_SIZE(fs) \ 1020 1.33.2.2 skrll (fs->lfs_is64 ? sizeof(SEGSUM64) : \ 1021 1.33.2.2 skrll lfs_sb_getversion(fs) > 1 ? sizeof(SEGSUM32) : sizeof(SEGSUM_V1)) 1022 1.33.2.2 skrll 1023 1.33.2.2 skrll /* 1024 1.33.2.2 skrll * The SEGSUM structure is followed by FINFO structures. Get the pointer 1025 1.33.2.2 skrll * to the first FINFO. 1026 1.33.2.2 skrll * 1027 1.33.2.2 skrll * XXX this can't be a macro yet; this file needs to be resorted. 1028 1.33.2.2 skrll */ 1029 1.33.2.2 skrll #if 0 1030 1.33.2.4 skrll static __inline FINFO * 1031 1.33.2.2 skrll segsum_finfobase(STRUCT_LFS *fs, SEGSUM *ssp) 1032 1.33.2.2 skrll { 1033 1.33.2.2 skrll return (FINFO *)((char *)ssp + SEGSUM_SIZE(fs)); 1034 1.33.2.2 skrll } 1035 1.33.2.2 skrll #else 1036 1.33.2.2 skrll #define SEGSUM_FINFOBASE(fs, ssp) \ 1037 1.33.2.2 skrll ((FINFO *)((char *)(ssp) + SEGSUM_SIZE(fs))); 1038 1.33.2.2 skrll #endif 1039 1.33.2.2 skrll 1040 1.33.2.2 skrll #define LFS_DEF_SS_ACCESSOR(type, type32, field) \ 1041 1.33.2.4 skrll static __inline type \ 1042 1.33.2.2 skrll lfs_ss_get##field(STRUCT_LFS *fs, SEGSUM *ssp) \ 1043 1.33.2.2 skrll { \ 1044 1.33.2.2 skrll if (fs->lfs_is64) { \ 1045 1.33.2.2 skrll return ssp->u_64.ss_##field; \ 1046 1.33.2.2 skrll } else { \ 1047 1.33.2.2 skrll return ssp->u_32.ss_##field; \ 1048 1.33.2.2 skrll } \ 1049 1.33.2.2 skrll } \ 1050 1.33.2.4 skrll static __inline void \ 1051 1.33.2.2 skrll lfs_ss_set##field(STRUCT_LFS *fs, SEGSUM *ssp, type val) \ 1052 1.33.2.2 skrll { \ 1053 1.33.2.2 skrll if (fs->lfs_is64) { \ 1054 1.33.2.2 skrll type *p = &ssp->u_64.ss_##field; \ 1055 1.33.2.2 skrll (void)p; \ 1056 1.33.2.2 skrll ssp->u_64.ss_##field = val; \ 1057 1.33.2.2 skrll } else { \ 1058 1.33.2.2 skrll type32 *p = &ssp->u_32.ss_##field; \ 1059 1.33.2.2 skrll (void)p; \ 1060 1.33.2.2 skrll ssp->u_32.ss_##field = val; \ 1061 1.33.2.2 skrll } \ 1062 1.33.2.2 skrll } \ 1063 1.33.2.2 skrll 1064 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint32_t, uint32_t, sumsum); 1065 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint32_t, uint32_t, datasum); 1066 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint32_t, uint32_t, magic); 1067 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint32_t, uint32_t, ident); 1068 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(int64_t, int32_t, next); 1069 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint16_t, uint16_t, nfinfo); 1070 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint16_t, uint16_t, ninos); 1071 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint16_t, uint16_t, flags); 1072 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint64_t, uint32_t, reclino); 1073 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint64_t, uint64_t, serial); 1074 1.33.2.2 skrll LFS_DEF_SS_ACCESSOR(uint64_t, uint64_t, create); 1075 1.33.2.2 skrll 1076 1.33.2.4 skrll static __inline size_t 1077 1.33.2.2 skrll lfs_ss_getsumstart(STRUCT_LFS *fs) 1078 1.33.2.2 skrll { 1079 1.33.2.2 skrll /* These are actually all the same. */ 1080 1.33.2.2 skrll if (fs->lfs_is64) { 1081 1.33.2.2 skrll return offsetof(SEGSUM64, ss_datasum); 1082 1.33.2.2 skrll } else /* if (lfs_sb_getversion(fs) > 1) */ { 1083 1.33.2.2 skrll return offsetof(SEGSUM32, ss_datasum); 1084 1.33.2.2 skrll } /* else { 1085 1.33.2.2 skrll return offsetof(SEGSUM_V1, ss_datasum); 1086 1.33.2.2 skrll } */ 1087 1.33.2.2 skrll /* 1088 1.33.2.2 skrll * XXX ^^^ until this file is resorted lfs_sb_getversion isn't 1089 1.33.2.2 skrll * defined yet. 1090 1.33.2.2 skrll */ 1091 1.33.2.2 skrll } 1092 1.33.2.2 skrll 1093 1.33.2.4 skrll static __inline uint32_t 1094 1.33.2.2 skrll lfs_ss_getocreate(STRUCT_LFS *fs, SEGSUM *ssp) 1095 1.33.2.2 skrll { 1096 1.33.2.2 skrll KASSERT(fs->lfs_is64 == 0); 1097 1.33.2.2 skrll /* XXX need to resort this file before we can do this */ 1098 1.33.2.2 skrll //KASSERT(lfs_sb_getversion(fs) == 1); 1099 1.33.2.2 skrll 1100 1.33.2.2 skrll return ssp->u_v1.ss_create; 1101 1.33.2.2 skrll } 1102 1.33.2.2 skrll 1103 1.33.2.4 skrll static __inline void 1104 1.33.2.2 skrll lfs_ss_setocreate(STRUCT_LFS *fs, SEGSUM *ssp, uint32_t val) 1105 1.33.2.2 skrll { 1106 1.33.2.2 skrll KASSERT(fs->lfs_is64 == 0); 1107 1.33.2.2 skrll /* XXX need to resort this file before we can do this */ 1108 1.33.2.2 skrll //KASSERT(lfs_sb_getversion(fs) == 1); 1109 1.33.2.2 skrll 1110 1.33.2.2 skrll ssp->u_v1.ss_create = val; 1111 1.33.2.2 skrll } 1112 1.33.2.2 skrll 1113 1.33.2.2 skrll 1114 1.33.2.2 skrll /* 1115 1.33.2.2 skrll * Super block. 1116 1.33.2.2 skrll */ 1117 1.33.2.2 skrll 1118 1.33.2.2 skrll /* 1119 1.33.2.2 skrll * Generate accessors for the on-disk superblock fields with cpp. 1120 1.33.2.2 skrll */ 1121 1.33.2.2 skrll 1122 1.33.2.2 skrll #define LFS_DEF_SB_ACCESSOR_FULL(type, type32, field) \ 1123 1.33.2.4 skrll static __inline type \ 1124 1.33.2.2 skrll lfs_sb_get##field(STRUCT_LFS *fs) \ 1125 1.33.2.2 skrll { \ 1126 1.33.2.2 skrll if (fs->lfs_is64) { \ 1127 1.33.2.2 skrll return fs->lfs_dlfs_u.u_64.dlfs_##field; \ 1128 1.33.2.2 skrll } else { \ 1129 1.33.2.2 skrll return fs->lfs_dlfs_u.u_32.dlfs_##field; \ 1130 1.33.2.2 skrll } \ 1131 1.33.2.2 skrll } \ 1132 1.33.2.4 skrll static __inline void \ 1133 1.33.2.2 skrll lfs_sb_set##field(STRUCT_LFS *fs, type val) \ 1134 1.33.2.2 skrll { \ 1135 1.33.2.2 skrll if (fs->lfs_is64) { \ 1136 1.33.2.2 skrll fs->lfs_dlfs_u.u_64.dlfs_##field = val; \ 1137 1.33.2.2 skrll } else { \ 1138 1.33.2.2 skrll fs->lfs_dlfs_u.u_32.dlfs_##field = val; \ 1139 1.33.2.2 skrll } \ 1140 1.33.2.2 skrll } \ 1141 1.33.2.4 skrll static __inline void \ 1142 1.33.2.2 skrll lfs_sb_add##field(STRUCT_LFS *fs, type val) \ 1143 1.33.2.2 skrll { \ 1144 1.33.2.2 skrll if (fs->lfs_is64) { \ 1145 1.33.2.2 skrll type *p64 = &fs->lfs_dlfs_u.u_64.dlfs_##field; \ 1146 1.33.2.2 skrll *p64 += val; \ 1147 1.33.2.2 skrll } else { \ 1148 1.33.2.2 skrll type32 *p32 = &fs->lfs_dlfs_u.u_32.dlfs_##field; \ 1149 1.33.2.2 skrll *p32 += val; \ 1150 1.33.2.2 skrll } \ 1151 1.33.2.2 skrll } \ 1152 1.33.2.4 skrll static __inline void \ 1153 1.33.2.2 skrll lfs_sb_sub##field(STRUCT_LFS *fs, type val) \ 1154 1.33.2.2 skrll { \ 1155 1.33.2.2 skrll if (fs->lfs_is64) { \ 1156 1.33.2.2 skrll type *p64 = &fs->lfs_dlfs_u.u_64.dlfs_##field; \ 1157 1.33.2.2 skrll *p64 -= val; \ 1158 1.33.2.2 skrll } else { \ 1159 1.33.2.2 skrll type32 *p32 = &fs->lfs_dlfs_u.u_32.dlfs_##field; \ 1160 1.33.2.2 skrll *p32 -= val; \ 1161 1.33.2.2 skrll } \ 1162 1.33.2.2 skrll } 1163 1.33.2.2 skrll 1164 1.33.2.2 skrll #define LFS_DEF_SB_ACCESSOR(t, f) LFS_DEF_SB_ACCESSOR_FULL(t, t, f) 1165 1.33.2.2 skrll 1166 1.33.2.2 skrll #define LFS_DEF_SB_ACCESSOR_32ONLY(type, field, val64) \ 1167 1.33.2.4 skrll static __inline type \ 1168 1.33.2.2 skrll lfs_sb_get##field(STRUCT_LFS *fs) \ 1169 1.33.2.2 skrll { \ 1170 1.33.2.2 skrll if (fs->lfs_is64) { \ 1171 1.33.2.2 skrll return val64; \ 1172 1.33.2.2 skrll } else { \ 1173 1.33.2.2 skrll return fs->lfs_dlfs_u.u_32.dlfs_##field; \ 1174 1.33.2.2 skrll } \ 1175 1.33.2.2 skrll } 1176 1.33.2.2 skrll 1177 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, version); 1178 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR_FULL(uint64_t, uint32_t, size); 1179 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, ssize); 1180 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR_FULL(uint64_t, uint32_t, dsize); 1181 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, bsize); 1182 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, fsize); 1183 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, frag); 1184 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(uint64_t, uint32_t, freehd); 1185 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, bfree); 1186 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(uint64_t, uint32_t, nfiles); 1187 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, avail); 1188 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR(int32_t, uinodes); 1189 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, idaddr); 1190 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR_32ONLY(uint32_t, ifile, LFS_IFILE_INUM); 1191 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, lastseg); 1192 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, nextseg); 1193 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, curseg); 1194 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, offset); 1195 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, lastpseg); 1196 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, inopf); 1197 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, minfree); 1198 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR(uint64_t, maxfilesize); 1199 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, fsbpseg); 1200 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, inopb); 1201 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, ifpb); 1202 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, sepb); 1203 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, nindir); 1204 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, nseg); 1205 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, nspf); 1206 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, cleansz); 1207 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, segtabsz); 1208 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR_32ONLY(uint32_t, segmask, 0); 1209 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR_32ONLY(uint32_t, segshift, 0); 1210 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint64_t, bmask); 1211 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, bshift); 1212 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint64_t, ffmask); 1213 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, ffshift); 1214 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint64_t, fbmask); 1215 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, fbshift); 1216 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, blktodb); 1217 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, fsbtodb); 1218 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, sushift); 1219 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR(int32_t, maxsymlinklen); 1220 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, cksum); 1221 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint16_t, pflags); 1222 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, nclean); 1223 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR(int32_t, dmeta); 1224 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, minfreeseg); 1225 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, sumsize); 1226 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint64_t, serial); 1227 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, ibsize); 1228 1.33.2.2 skrll LFS_DEF_SB_ACCESSOR_FULL(int64_t, int32_t, s0addr); 1229 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint64_t, tstamp); 1230 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, inodefmt); 1231 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, interleave); 1232 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, ident); 1233 1.33.2.5 skrll LFS_DEF_SB_ACCESSOR(uint32_t, resvseg); 1234 1.33.2.2 skrll 1235 1.33.2.2 skrll /* special-case accessors */ 1236 1.33.2.2 skrll 1237 1.33.2.2 skrll /* 1238 1.33.2.2 skrll * the v1 otstamp field lives in what's now dlfs_inopf 1239 1.33.2.2 skrll */ 1240 1.33.2.2 skrll #define lfs_sb_getotstamp(fs) lfs_sb_getinopf(fs) 1241 1.33.2.2 skrll #define lfs_sb_setotstamp(fs, val) lfs_sb_setinopf(fs, val) 1242 1.33.2.2 skrll 1243 1.33.2.2 skrll /* 1244 1.33.2.2 skrll * lfs_sboffs is an array 1245 1.33.2.2 skrll */ 1246 1.33.2.4 skrll static __inline int32_t 1247 1.33.2.2 skrll lfs_sb_getsboff(STRUCT_LFS *fs, unsigned n) 1248 1.33.2.2 skrll { 1249 1.33.2.2 skrll #ifdef KASSERT /* ugh */ 1250 1.33.2.2 skrll KASSERT(n < LFS_MAXNUMSB); 1251 1.33.2.2 skrll #endif 1252 1.33.2.2 skrll if (fs->lfs_is64) { 1253 1.33.2.2 skrll return fs->lfs_dlfs_u.u_64.dlfs_sboffs[n]; 1254 1.33.2.2 skrll } else { 1255 1.33.2.2 skrll return fs->lfs_dlfs_u.u_32.dlfs_sboffs[n]; 1256 1.33.2.2 skrll } 1257 1.33.2.2 skrll } 1258 1.33.2.4 skrll static __inline void 1259 1.33.2.2 skrll lfs_sb_setsboff(STRUCT_LFS *fs, unsigned n, int32_t val) 1260 1.33.2.2 skrll { 1261 1.33.2.2 skrll #ifdef KASSERT /* ugh */ 1262 1.33.2.2 skrll KASSERT(n < LFS_MAXNUMSB); 1263 1.33.2.2 skrll #endif 1264 1.33.2.2 skrll if (fs->lfs_is64) { 1265 1.33.2.2 skrll fs->lfs_dlfs_u.u_64.dlfs_sboffs[n] = val; 1266 1.33.2.2 skrll } else { 1267 1.33.2.2 skrll fs->lfs_dlfs_u.u_32.dlfs_sboffs[n] = val; 1268 1.33.2.2 skrll } 1269 1.33.2.2 skrll } 1270 1.33.2.2 skrll 1271 1.33.2.2 skrll /* 1272 1.33.2.2 skrll * lfs_fsmnt is a string 1273 1.33.2.2 skrll */ 1274 1.33.2.4 skrll static __inline const char * 1275 1.33.2.2 skrll lfs_sb_getfsmnt(STRUCT_LFS *fs) 1276 1.33.2.2 skrll { 1277 1.33.2.2 skrll if (fs->lfs_is64) { 1278 1.33.2.4 skrll return (const char *)fs->lfs_dlfs_u.u_64.dlfs_fsmnt; 1279 1.33.2.2 skrll } else { 1280 1.33.2.4 skrll return (const char *)fs->lfs_dlfs_u.u_32.dlfs_fsmnt; 1281 1.33.2.2 skrll } 1282 1.33.2.2 skrll } 1283 1.33.2.2 skrll 1284 1.33.2.4 skrll static __inline void 1285 1.33.2.2 skrll lfs_sb_setfsmnt(STRUCT_LFS *fs, const char *str) 1286 1.33.2.2 skrll { 1287 1.33.2.2 skrll if (fs->lfs_is64) { 1288 1.33.2.4 skrll (void)strncpy((char *)fs->lfs_dlfs_u.u_64.dlfs_fsmnt, str, 1289 1.33.2.2 skrll sizeof(fs->lfs_dlfs_u.u_64.dlfs_fsmnt)); 1290 1.33.2.2 skrll } else { 1291 1.33.2.4 skrll (void)strncpy((char *)fs->lfs_dlfs_u.u_32.dlfs_fsmnt, str, 1292 1.33.2.2 skrll sizeof(fs->lfs_dlfs_u.u_32.dlfs_fsmnt)); 1293 1.33.2.2 skrll } 1294 1.33.2.2 skrll } 1295 1.33.2.2 skrll 1296 1.33.2.2 skrll /* Highest addressable fsb */ 1297 1.33.2.2 skrll #define LFS_MAX_DADDR(fs) \ 1298 1.33.2.2 skrll ((fs)->lfs_is64 ? 0x7fffffffffffffff : 0x7fffffff) 1299 1.33.2.2 skrll 1300 1.33.2.2 skrll /* LFS_NINDIR is the number of indirects in a file system block. */ 1301 1.33.2.2 skrll #define LFS_NINDIR(fs) (lfs_sb_getnindir(fs)) 1302 1.33.2.2 skrll 1303 1.33.2.2 skrll /* LFS_INOPB is the number of inodes in a secondary storage block. */ 1304 1.33.2.2 skrll #define LFS_INOPB(fs) (lfs_sb_getinopb(fs)) 1305 1.33.2.2 skrll /* LFS_INOPF is the number of inodes in a fragment. */ 1306 1.33.2.2 skrll #define LFS_INOPF(fs) (lfs_sb_getinopf(fs)) 1307 1.33.2.2 skrll 1308 1.33.2.2 skrll #define lfs_blkoff(fs, loc) ((int)((loc) & lfs_sb_getbmask(fs))) 1309 1.33.2.2 skrll #define lfs_fragoff(fs, loc) /* calculates (loc % fs->lfs_fsize) */ \ 1310 1.33.2.2 skrll ((int)((loc) & lfs_sb_getffmask(fs))) 1311 1.33.2.2 skrll 1312 1.33.2.2 skrll /* XXX: lowercase these as they're no longer macros */ 1313 1.33.2.2 skrll /* Frags to diskblocks */ 1314 1.33.2.4 skrll static __inline uint64_t 1315 1.33.2.2 skrll LFS_FSBTODB(STRUCT_LFS *fs, uint64_t b) 1316 1.33.2.2 skrll { 1317 1.33.2.2 skrll #if defined(_KERNEL) 1318 1.33.2.2 skrll return b << (lfs_sb_getffshift(fs) - DEV_BSHIFT); 1319 1.33.2.2 skrll #else 1320 1.33.2.2 skrll return b << lfs_sb_getfsbtodb(fs); 1321 1.33.2.2 skrll #endif 1322 1.33.2.2 skrll } 1323 1.33.2.2 skrll /* Diskblocks to frags */ 1324 1.33.2.4 skrll static __inline uint64_t 1325 1.33.2.2 skrll LFS_DBTOFSB(STRUCT_LFS *fs, uint64_t b) 1326 1.33.2.2 skrll { 1327 1.33.2.2 skrll #if defined(_KERNEL) 1328 1.33.2.2 skrll return b >> (lfs_sb_getffshift(fs) - DEV_BSHIFT); 1329 1.33.2.2 skrll #else 1330 1.33.2.2 skrll return b >> lfs_sb_getfsbtodb(fs); 1331 1.33.2.2 skrll #endif 1332 1.33.2.2 skrll } 1333 1.33.2.2 skrll 1334 1.33.2.2 skrll #define lfs_lblkno(fs, loc) ((loc) >> lfs_sb_getbshift(fs)) 1335 1.33.2.2 skrll #define lfs_lblktosize(fs, blk) ((blk) << lfs_sb_getbshift(fs)) 1336 1.33.2.2 skrll 1337 1.33.2.2 skrll /* Frags to bytes */ 1338 1.33.2.4 skrll static __inline uint64_t 1339 1.33.2.2 skrll lfs_fsbtob(STRUCT_LFS *fs, uint64_t b) 1340 1.33.2.2 skrll { 1341 1.33.2.2 skrll return b << lfs_sb_getffshift(fs); 1342 1.33.2.2 skrll } 1343 1.33.2.2 skrll /* Bytes to frags */ 1344 1.33.2.4 skrll static __inline uint64_t 1345 1.33.2.2 skrll lfs_btofsb(STRUCT_LFS *fs, uint64_t b) 1346 1.33.2.2 skrll { 1347 1.33.2.2 skrll return b >> lfs_sb_getffshift(fs); 1348 1.33.2.2 skrll } 1349 1.33.2.2 skrll 1350 1.33.2.2 skrll #define lfs_numfrags(fs, loc) /* calculates (loc / fs->lfs_fsize) */ \ 1351 1.33.2.2 skrll ((loc) >> lfs_sb_getffshift(fs)) 1352 1.33.2.2 skrll #define lfs_blkroundup(fs, size)/* calculates roundup(size, lfs_sb_getbsize(fs)) */ \ 1353 1.33.2.2 skrll ((off_t)(((size) + lfs_sb_getbmask(fs)) & (~lfs_sb_getbmask(fs)))) 1354 1.33.2.2 skrll #define lfs_fragroundup(fs, size)/* calculates roundup(size, fs->lfs_fsize) */ \ 1355 1.33.2.2 skrll ((off_t)(((size) + lfs_sb_getffmask(fs)) & (~lfs_sb_getffmask(fs)))) 1356 1.33.2.2 skrll #define lfs_fragstoblks(fs, frags)/* calculates (frags / fs->fs_frag) */ \ 1357 1.33.2.2 skrll ((frags) >> lfs_sb_getfbshift(fs)) 1358 1.33.2.2 skrll #define lfs_blkstofrags(fs, blks)/* calculates (blks * fs->fs_frag) */ \ 1359 1.33.2.2 skrll ((blks) << lfs_sb_getfbshift(fs)) 1360 1.33.2.2 skrll #define lfs_fragnum(fs, fsb) /* calculates (fsb % fs->lfs_frag) */ \ 1361 1.33.2.2 skrll ((fsb) & ((fs)->lfs_frag - 1)) 1362 1.33.2.2 skrll #define lfs_blknum(fs, fsb) /* calculates rounddown(fsb, fs->lfs_frag) */ \ 1363 1.33.2.2 skrll ((fsb) &~ ((fs)->lfs_frag - 1)) 1364 1.33.2.2 skrll #define lfs_dblksize(fs, dp, lbn) \ 1365 1.33.2.2 skrll (((lbn) >= ULFS_NDADDR || lfs_dino_getsize(fs, dp) >= ((lbn) + 1) << lfs_sb_getbshift(fs)) \ 1366 1.33.2.2 skrll ? lfs_sb_getbsize(fs) \ 1367 1.33.2.2 skrll : (lfs_fragroundup(fs, lfs_blkoff(fs, lfs_dino_getsize(fs, dp))))) 1368 1.33.2.2 skrll 1369 1.33.2.2 skrll #define lfs_segsize(fs) (lfs_sb_getversion(fs) == 1 ? \ 1370 1.33.2.2 skrll lfs_lblktosize((fs), lfs_sb_getssize(fs)) : \ 1371 1.33.2.2 skrll lfs_sb_getssize(fs)) 1372 1.33.2.2 skrll /* XXX segtod produces a result in frags despite the 'd' */ 1373 1.33.2.2 skrll #define lfs_segtod(fs, seg) (lfs_btofsb(fs, lfs_segsize(fs)) * (seg)) 1374 1.33.2.2 skrll #define lfs_dtosn(fs, daddr) /* block address to segment number */ \ 1375 1.33.2.2 skrll ((uint32_t)(((daddr) - lfs_sb_gets0addr(fs)) / lfs_segtod((fs), 1))) 1376 1.33.2.2 skrll #define lfs_sntod(fs, sn) /* segment number to disk address */ \ 1377 1.33.2.2 skrll ((daddr_t)(lfs_segtod((fs), (sn)) + lfs_sb_gets0addr(fs))) 1378 1.33.2.2 skrll 1379 1.33.2.2 skrll /* XXX, blah. make this appear only if struct inode is defined */ 1380 1.33.2.2 skrll #ifdef _UFS_LFS_LFS_INODE_H_ 1381 1.33.2.4 skrll static __inline uint32_t 1382 1.33.2.2 skrll lfs_blksize(STRUCT_LFS *fs, struct inode *ip, uint64_t lbn) 1383 1.33.2.2 skrll { 1384 1.33.2.2 skrll if (lbn >= ULFS_NDADDR || lfs_dino_getsize(fs, ip->i_din) >= (lbn + 1) << lfs_sb_getbshift(fs)) { 1385 1.33.2.2 skrll return lfs_sb_getbsize(fs); 1386 1.33.2.2 skrll } else { 1387 1.33.2.2 skrll return lfs_fragroundup(fs, lfs_blkoff(fs, lfs_dino_getsize(fs, ip->i_din))); 1388 1.33.2.2 skrll } 1389 1.33.2.2 skrll } 1390 1.33.2.2 skrll #endif 1391 1.33.2.2 skrll 1392 1.33.2.2 skrll /* 1393 1.33.2.2 skrll * union lfs_blocks 1394 1.33.2.2 skrll */ 1395 1.33.2.2 skrll 1396 1.33.2.4 skrll static __inline void 1397 1.33.2.2 skrll lfs_blocks_fromvoid(STRUCT_LFS *fs, union lfs_blocks *bp, void *p) 1398 1.33.2.2 skrll { 1399 1.33.2.2 skrll if (fs->lfs_is64) { 1400 1.33.2.2 skrll bp->b64 = p; 1401 1.33.2.2 skrll } else { 1402 1.33.2.2 skrll bp->b32 = p; 1403 1.33.2.2 skrll } 1404 1.33.2.2 skrll } 1405 1.33.2.2 skrll 1406 1.33.2.4 skrll static __inline void 1407 1.33.2.2 skrll lfs_blocks_fromfinfo(STRUCT_LFS *fs, union lfs_blocks *bp, FINFO *fip) 1408 1.33.2.2 skrll { 1409 1.33.2.2 skrll void *firstblock; 1410 1.33.2.2 skrll 1411 1.33.2.2 skrll firstblock = (char *)fip + FINFOSIZE(fs); 1412 1.33.2.2 skrll if (fs->lfs_is64) { 1413 1.33.2.2 skrll bp->b64 = (int64_t *)firstblock; 1414 1.33.2.2 skrll } else { 1415 1.33.2.2 skrll bp->b32 = (int32_t *)firstblock; 1416 1.33.2.2 skrll } 1417 1.33.2.2 skrll } 1418 1.33.2.2 skrll 1419 1.33.2.4 skrll static __inline daddr_t 1420 1.33.2.4 skrll lfs_blocks_get(STRUCT_LFS *fs, union lfs_blocks *bp, unsigned idx) 1421 1.33.2.2 skrll { 1422 1.33.2.2 skrll if (fs->lfs_is64) { 1423 1.33.2.4 skrll return bp->b64[idx]; 1424 1.33.2.2 skrll } else { 1425 1.33.2.4 skrll return bp->b32[idx]; 1426 1.33.2.2 skrll } 1427 1.33.2.2 skrll } 1428 1.33.2.2 skrll 1429 1.33.2.4 skrll static __inline void 1430 1.33.2.4 skrll lfs_blocks_set(STRUCT_LFS *fs, union lfs_blocks *bp, unsigned idx, daddr_t val) 1431 1.33.2.2 skrll { 1432 1.33.2.2 skrll if (fs->lfs_is64) { 1433 1.33.2.4 skrll bp->b64[idx] = val; 1434 1.33.2.2 skrll } else { 1435 1.33.2.4 skrll bp->b32[idx] = val; 1436 1.33.2.2 skrll } 1437 1.33.2.2 skrll } 1438 1.33.2.2 skrll 1439 1.33.2.4 skrll static __inline void 1440 1.33.2.2 skrll lfs_blocks_inc(STRUCT_LFS *fs, union lfs_blocks *bp) 1441 1.33.2.2 skrll { 1442 1.33.2.2 skrll if (fs->lfs_is64) { 1443 1.33.2.2 skrll bp->b64++; 1444 1.33.2.2 skrll } else { 1445 1.33.2.2 skrll bp->b32++; 1446 1.33.2.2 skrll } 1447 1.33.2.2 skrll } 1448 1.33.2.2 skrll 1449 1.33.2.4 skrll static __inline int 1450 1.33.2.2 skrll lfs_blocks_eq(STRUCT_LFS *fs, union lfs_blocks *bp1, union lfs_blocks *bp2) 1451 1.33.2.2 skrll { 1452 1.33.2.2 skrll if (fs->lfs_is64) { 1453 1.33.2.2 skrll return bp1->b64 == bp2->b64; 1454 1.33.2.2 skrll } else { 1455 1.33.2.2 skrll return bp1->b32 == bp2->b32; 1456 1.33.2.2 skrll } 1457 1.33.2.2 skrll } 1458 1.33.2.2 skrll 1459 1.33.2.4 skrll static __inline int 1460 1.33.2.2 skrll lfs_blocks_sub(STRUCT_LFS *fs, union lfs_blocks *bp1, union lfs_blocks *bp2) 1461 1.33.2.2 skrll { 1462 1.33.2.2 skrll /* (remember that the pointers are typed) */ 1463 1.33.2.2 skrll if (fs->lfs_is64) { 1464 1.33.2.2 skrll return bp1->b64 - bp2->b64; 1465 1.33.2.2 skrll } else { 1466 1.33.2.2 skrll return bp1->b32 - bp2->b32; 1467 1.33.2.2 skrll } 1468 1.33.2.2 skrll } 1469 1.33.2.2 skrll 1470 1.33.2.2 skrll /* 1471 1.33.2.2 skrll * struct segment 1472 1.33.2.2 skrll */ 1473 1.33.2.2 skrll 1474 1.33.2.2 skrll 1475 1.33.2.2 skrll /* 1476 1.33.2.2 skrll * Macros for determining free space on the disk, with the variable metadata 1477 1.33.2.2 skrll * of segment summaries and inode blocks taken into account. 1478 1.33.2.2 skrll */ 1479 1.33.2.2 skrll /* 1480 1.33.2.2 skrll * Estimate number of clean blocks not available for writing because 1481 1.33.2.2 skrll * they will contain metadata or overhead. This is calculated as 1482 1.33.2.2 skrll * 1483 1.33.2.2 skrll * E = ((C * M / D) * D + (0) * (T - D)) / T 1484 1.33.2.2 skrll * or more simply 1485 1.33.2.2 skrll * E = (C * M) / T 1486 1.33.2.2 skrll * 1487 1.33.2.2 skrll * where 1488 1.33.2.2 skrll * C is the clean space, 1489 1.33.2.2 skrll * D is the dirty space, 1490 1.33.2.2 skrll * M is the dirty metadata, and 1491 1.33.2.2 skrll * T = C + D is the total space on disk. 1492 1.33.2.2 skrll * 1493 1.33.2.2 skrll * This approximates the old formula of E = C * M / D when D is close to T, 1494 1.33.2.2 skrll * but avoids falsely reporting "disk full" when the sample size (D) is small. 1495 1.33.2.2 skrll */ 1496 1.33.2.2 skrll #define LFS_EST_CMETA(F) (( \ 1497 1.33.2.2 skrll (lfs_sb_getdmeta(F) * (int64_t)lfs_sb_getnclean(F)) / \ 1498 1.33.2.2 skrll (lfs_sb_getnseg(F)))) 1499 1.33.2.2 skrll 1500 1.33.2.2 skrll /* Estimate total size of the disk not including metadata */ 1501 1.33.2.2 skrll #define LFS_EST_NONMETA(F) (lfs_sb_getdsize(F) - lfs_sb_getdmeta(F) - LFS_EST_CMETA(F)) 1502 1.33.2.2 skrll 1503 1.33.2.2 skrll /* Estimate number of blocks actually available for writing */ 1504 1.33.2.2 skrll #define LFS_EST_BFREE(F) (lfs_sb_getbfree(F) > LFS_EST_CMETA(F) ? \ 1505 1.33.2.2 skrll lfs_sb_getbfree(F) - LFS_EST_CMETA(F) : 0) 1506 1.33.2.2 skrll 1507 1.33.2.2 skrll /* Amount of non-meta space not available to mortal man */ 1508 1.33.2.2 skrll #define LFS_EST_RSVD(F) ((LFS_EST_NONMETA(F) * \ 1509 1.33.2.5 skrll (uint64_t)lfs_sb_getminfree(F)) / \ 1510 1.33.2.2 skrll 100) 1511 1.33.2.2 skrll 1512 1.33.2.2 skrll /* Can credential C write BB blocks? XXX: kauth_cred_geteuid is abusive */ 1513 1.33.2.2 skrll #define ISSPACE(F, BB, C) \ 1514 1.33.2.2 skrll ((((C) == NOCRED || kauth_cred_geteuid(C) == 0) && \ 1515 1.33.2.2 skrll LFS_EST_BFREE(F) >= (BB)) || \ 1516 1.33.2.2 skrll (kauth_cred_geteuid(C) != 0 && IS_FREESPACE(F, BB))) 1517 1.33.2.2 skrll 1518 1.33.2.2 skrll /* Can an ordinary user write BB blocks */ 1519 1.33.2.2 skrll #define IS_FREESPACE(F, BB) \ 1520 1.33.2.2 skrll (LFS_EST_BFREE(F) >= (BB) + LFS_EST_RSVD(F)) 1521 1.33.2.2 skrll 1522 1.33.2.2 skrll /* 1523 1.33.2.2 skrll * The minimum number of blocks to create a new inode. This is: 1524 1.33.2.2 skrll * directory direct block (1) + ULFS_NIADDR indirect blocks + inode block (1) + 1525 1.33.2.2 skrll * ifile direct block (1) + ULFS_NIADDR indirect blocks = 3 + 2 * ULFS_NIADDR blocks. 1526 1.33.2.2 skrll */ 1527 1.33.2.2 skrll #define LFS_NRESERVE(F) (lfs_btofsb((F), (2 * ULFS_NIADDR + 3) << lfs_sb_getbshift(F))) 1528 1.33.2.2 skrll 1529 1.33.2.2 skrll 1530 1.33.2.2 skrll 1531 1.33.2.2 skrll #endif /* _UFS_LFS_LFS_ACCESSORS_H_ */ 1532
Indexes created Mon Oct 27 08:10:08 GMT 2025