minixfs3.c revision 1.1.4.2
1 1.1.4.2 mrg /* $NetBSD: minixfs3.c,v 1.1.4.2 2012/02/18 07:35:35 mrg Exp $ */ 2 1.1.4.2 mrg 3 1.1.4.2 mrg /*- 4 1.1.4.2 mrg * Copyright (c) 2012 5 1.1.4.2 mrg * Vrije Universiteit, Amsterdam, The Netherlands. All rights reserved. 6 1.1.4.2 mrg * 7 1.1.4.2 mrg * Author: Evgeniy Ivanov (based on libsa/ext2fs.c). 8 1.1.4.2 mrg * 9 1.1.4.2 mrg * This code is derived from src/sys/lib/libsa/ext2fs.c contributed to 10 1.1.4.2 mrg * The NetBSD Foundation, see copyrights below. 11 1.1.4.2 mrg * 12 1.1.4.2 mrg * Redistribution and use in source and binary forms, with or without 13 1.1.4.2 mrg * modification, are permitted provided that the following conditions 14 1.1.4.2 mrg * are met: 15 1.1.4.2 mrg * 1. Redistributions of source code must retain the above copyright 16 1.1.4.2 mrg * notice, this list of conditions and the following disclaimer. 17 1.1.4.2 mrg * 2. Redistributions in binary form must reproduce the above copyright 18 1.1.4.2 mrg * notice, this list of conditions and the following disclaimer in the 19 1.1.4.2 mrg * documentation and/or other materials provided with the distribution. 20 1.1.4.2 mrg * 21 1.1.4.2 mrg * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ``AS 22 1.1.4.2 mrg * IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, 23 1.1.4.2 mrg * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 24 1.1.4.2 mrg * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS BE 25 1.1.4.2 mrg * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 26 1.1.4.2 mrg * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 27 1.1.4.2 mrg * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 28 1.1.4.2 mrg * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 29 1.1.4.2 mrg * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 30 1.1.4.2 mrg * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 31 1.1.4.2 mrg * POSSIBILITY OF SUCH DAMAGE. 32 1.1.4.2 mrg */ 33 1.1.4.2 mrg 34 1.1.4.2 mrg /* 35 1.1.4.2 mrg * Copyright (c) 1997 Manuel Bouyer. 36 1.1.4.2 mrg * 37 1.1.4.2 mrg * Redistribution and use in source and binary forms, with or without 38 1.1.4.2 mrg * modification, are permitted provided that the following conditions 39 1.1.4.2 mrg * are met: 40 1.1.4.2 mrg * 1. Redistributions of source code must retain the above copyright 41 1.1.4.2 mrg * notice, this list of conditions and the following disclaimer. 42 1.1.4.2 mrg * 2. Redistributions in binary form must reproduce the above copyright 43 1.1.4.2 mrg * notice, this list of conditions and the following disclaimer in the 44 1.1.4.2 mrg * documentation and/or other materials provided with the distribution. 45 1.1.4.2 mrg * 46 1.1.4.2 mrg * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 47 1.1.4.2 mrg * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 48 1.1.4.2 mrg * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 49 1.1.4.2 mrg * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 50 1.1.4.2 mrg * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 51 1.1.4.2 mrg * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 52 1.1.4.2 mrg * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 53 1.1.4.2 mrg * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 54 1.1.4.2 mrg * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 55 1.1.4.2 mrg * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 56 1.1.4.2 mrg */ 57 1.1.4.2 mrg 58 1.1.4.2 mrg /*- 59 1.1.4.2 mrg * Copyright (c) 1993 60 1.1.4.2 mrg * The Regents of the University of California. All rights reserved. 61 1.1.4.2 mrg * 62 1.1.4.2 mrg * This code is derived from software contributed to Berkeley by 63 1.1.4.2 mrg * The Mach Operating System project at Carnegie-Mellon University. 64 1.1.4.2 mrg * 65 1.1.4.2 mrg * Redistribution and use in source and binary forms, with or without 66 1.1.4.2 mrg * modification, are permitted provided that the following conditions 67 1.1.4.2 mrg * are met: 68 1.1.4.2 mrg * 1. Redistributions of source code must retain the above copyright 69 1.1.4.2 mrg * notice, this list of conditions and the following disclaimer. 70 1.1.4.2 mrg * 2. Redistributions in binary form must reproduce the above copyright 71 1.1.4.2 mrg * notice, this list of conditions and the following disclaimer in the 72 1.1.4.2 mrg * documentation and/or other materials provided with the distribution. 73 1.1.4.2 mrg * 3. Neither the name of the University nor the names of its contributors 74 1.1.4.2 mrg * may be used to endorse or promote products derived from this software 75 1.1.4.2 mrg * without specific prior written permission. 76 1.1.4.2 mrg * 77 1.1.4.2 mrg * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 78 1.1.4.2 mrg * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 79 1.1.4.2 mrg * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 80 1.1.4.2 mrg * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 81 1.1.4.2 mrg * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 82 1.1.4.2 mrg * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 83 1.1.4.2 mrg * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 84 1.1.4.2 mrg * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 85 1.1.4.2 mrg * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 86 1.1.4.2 mrg * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 87 1.1.4.2 mrg * SUCH DAMAGE. 88 1.1.4.2 mrg * 89 1.1.4.2 mrg * 90 1.1.4.2 mrg * Copyright (c) 1990, 1991 Carnegie Mellon University 91 1.1.4.2 mrg * All Rights Reserved. 92 1.1.4.2 mrg * 93 1.1.4.2 mrg * Author: David Golub 94 1.1.4.2 mrg * 95 1.1.4.2 mrg * Permission to use, copy, modify and distribute this software and its 96 1.1.4.2 mrg * documentation is hereby granted, provided that both the copyright 97 1.1.4.2 mrg * notice and this permission notice appear in all copies of the 98 1.1.4.2 mrg * software, derivative works or modified versions, and any portions 99 1.1.4.2 mrg * thereof, and that both notices appear in supporting documentation. 100 1.1.4.2 mrg * 101 1.1.4.2 mrg * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" 102 1.1.4.2 mrg * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR 103 1.1.4.2 mrg * ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. 104 1.1.4.2 mrg * 105 1.1.4.2 mrg * Carnegie Mellon requests users of this software to return to 106 1.1.4.2 mrg * 107 1.1.4.2 mrg * Software Distribution Coordinator or Software.Distribution (at) CS.CMU.EDU 108 1.1.4.2 mrg * School of Computer Science 109 1.1.4.2 mrg * Carnegie Mellon University 110 1.1.4.2 mrg * Pittsburgh PA 15213-3890 111 1.1.4.2 mrg * 112 1.1.4.2 mrg * any improvements or extensions that they make and grant Carnegie the 113 1.1.4.2 mrg * rights to redistribute these changes. 114 1.1.4.2 mrg */ 115 1.1.4.2 mrg 116 1.1.4.2 mrg /* 117 1.1.4.2 mrg * Stand-alone file reading package for MFS file system. 118 1.1.4.2 mrg */ 119 1.1.4.2 mrg 120 1.1.4.2 mrg #include <sys/param.h> 121 1.1.4.2 mrg #include <sys/time.h> 122 1.1.4.2 mrg #ifdef _STANDALONE 123 1.1.4.2 mrg #include <lib/libkern/libkern.h> 124 1.1.4.2 mrg #else 125 1.1.4.2 mrg #include <string.h> 126 1.1.4.2 mrg #endif 127 1.1.4.2 mrg 128 1.1.4.2 mrg #include "stand.h" 129 1.1.4.2 mrg #include "minixfs3.h" 130 1.1.4.2 mrg 131 1.1.4.2 mrg #if defined(LIBSA_FS_SINGLECOMPONENT) && !defined(LIBSA_NO_FS_SYMLINK) 132 1.1.4.2 mrg #define LIBSA_NO_FS_SYMLINK 133 1.1.4.2 mrg #endif 134 1.1.4.2 mrg 135 1.1.4.2 mrg #if defined(LIBSA_NO_TWIDDLE) 136 1.1.4.2 mrg #define twiddle() 137 1.1.4.2 mrg #endif 138 1.1.4.2 mrg 139 1.1.4.2 mrg typedef uint32_t ino32_t; 140 1.1.4.2 mrg #ifndef FSBTODB 141 1.1.4.2 mrg #define FSBTODB(fs, indp) fsbtodb(fs, indp) 142 1.1.4.2 mrg #endif 143 1.1.4.2 mrg 144 1.1.4.2 mrg /* 145 1.1.4.2 mrg * To avoid having a lot of filesystem-block sized buffers lurking (which 146 1.1.4.2 mrg * could be 32k) we only keep a few entries of the indirect block map. 147 1.1.4.2 mrg * With 8k blocks, 2^8 blocks is ~500k so we reread the indirect block 148 1.1.4.2 mrg * ~13 times pulling in a 6M kernel. 149 1.1.4.2 mrg * The cache size must be smaller than the smallest filesystem block, 150 1.1.4.2 mrg * so LN2_IND_CACHE_SZ <= 9 (UFS2 and 4k blocks). 151 1.1.4.2 mrg */ 152 1.1.4.2 mrg #define LN2_IND_CACHE_SZ 6 153 1.1.4.2 mrg #define IND_CACHE_SZ (1 << LN2_IND_CACHE_SZ) 154 1.1.4.2 mrg #define IND_CACHE_MASK (IND_CACHE_SZ - 1) 155 1.1.4.2 mrg 156 1.1.4.2 mrg /* 157 1.1.4.2 mrg * In-core open file. 158 1.1.4.2 mrg */ 159 1.1.4.2 mrg struct file { 160 1.1.4.2 mrg off_t f_seekp; /* seek pointer */ 161 1.1.4.2 mrg struct mfs_sblock *f_fs; /* pointer to super-block */ 162 1.1.4.2 mrg struct mfs_dinode f_di; /* copy of on-disk inode */ 163 1.1.4.2 mrg uint f_nishift; /* for blocks in indirect block */ 164 1.1.4.2 mrg block_t f_ind_cache_block; 165 1.1.4.2 mrg block_t f_ind_cache[IND_CACHE_SZ]; 166 1.1.4.2 mrg 167 1.1.4.2 mrg char *f_buf; /* buffer for data block */ 168 1.1.4.2 mrg size_t f_buf_size; /* size of data block */ 169 1.1.4.2 mrg daddr_t f_buf_blkno; /* block number of data block */ 170 1.1.4.2 mrg }; 171 1.1.4.2 mrg 172 1.1.4.2 mrg #if defined(LIBSA_ENABLE_LS_OP) 173 1.1.4.2 mrg 174 1.1.4.2 mrg #define NELEM(x) (sizeof (x) / sizeof(*x)) 175 1.1.4.2 mrg 176 1.1.4.2 mrg typedef struct entry_t entry_t; 177 1.1.4.2 mrg struct entry_t { 178 1.1.4.2 mrg entry_t *e_next; 179 1.1.4.2 mrg ino32_t e_ino; 180 1.1.4.2 mrg char e_name[1]; 181 1.1.4.2 mrg }; 182 1.1.4.2 mrg 183 1.1.4.2 mrg #endif /* LIBSA_ENABLE_LS_OP */ 184 1.1.4.2 mrg 185 1.1.4.2 mrg 186 1.1.4.2 mrg static int read_inode(ino32_t, struct open_file *); 187 1.1.4.2 mrg static int block_map(struct open_file *, block_t, block_t *); 188 1.1.4.2 mrg static int buf_read_file(struct open_file *, void *, size_t *); 189 1.1.4.2 mrg static int search_directory(const char *, int, struct open_file *, ino32_t *); 190 1.1.4.2 mrg static int read_sblock(struct open_file *, struct mfs_sblock *); 191 1.1.4.2 mrg 192 1.1.4.2 mrg /* 193 1.1.4.2 mrg * Read a new inode into a file structure. 194 1.1.4.2 mrg */ 195 1.1.4.2 mrg static int 196 1.1.4.2 mrg read_inode(ino32_t inumber, struct open_file *f) 197 1.1.4.2 mrg { 198 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 199 1.1.4.2 mrg struct mfs_sblock *fs = fp->f_fs; 200 1.1.4.2 mrg char *buf; 201 1.1.4.2 mrg size_t rsize; 202 1.1.4.2 mrg int rc; 203 1.1.4.2 mrg daddr_t inode_sector; 204 1.1.4.2 mrg struct mfs_dinode *dip; 205 1.1.4.2 mrg 206 1.1.4.2 mrg inode_sector = FSBTODB(fs, ino_to_fsba(fs, inumber)); 207 1.1.4.2 mrg 208 1.1.4.2 mrg /* 209 1.1.4.2 mrg * Read inode and save it. 210 1.1.4.2 mrg */ 211 1.1.4.2 mrg buf = fp->f_buf; 212 1.1.4.2 mrg twiddle(); 213 1.1.4.2 mrg rc = DEV_STRATEGY(f->f_dev)(f->f_devdata, F_READ, 214 1.1.4.2 mrg inode_sector, fs->mfs_block_size, buf, &rsize); 215 1.1.4.2 mrg if (rc) 216 1.1.4.2 mrg return rc; 217 1.1.4.2 mrg if (rsize != fs->mfs_block_size) 218 1.1.4.2 mrg return EIO; 219 1.1.4.2 mrg 220 1.1.4.2 mrg dip = (struct mfs_dinode *)(buf + 221 1.1.4.2 mrg INODE_SIZE * ino_to_fsbo(fs, inumber)); 222 1.1.4.2 mrg mfs_iload(dip, &fp->f_di); 223 1.1.4.2 mrg 224 1.1.4.2 mrg /* 225 1.1.4.2 mrg * Clear out the old buffers 226 1.1.4.2 mrg */ 227 1.1.4.2 mrg fp->f_ind_cache_block = ~0; 228 1.1.4.2 mrg fp->f_buf_blkno = -1; 229 1.1.4.2 mrg return rc; 230 1.1.4.2 mrg } 231 1.1.4.2 mrg 232 1.1.4.2 mrg /* 233 1.1.4.2 mrg * Given an offset in a file, find the disk block number (not zone!) 234 1.1.4.2 mrg * that contains that block. 235 1.1.4.2 mrg */ 236 1.1.4.2 mrg static int 237 1.1.4.2 mrg block_map(struct open_file *f, block_t file_block, block_t *disk_block_p) 238 1.1.4.2 mrg { 239 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 240 1.1.4.2 mrg struct mfs_sblock *fs = fp->f_fs; 241 1.1.4.2 mrg uint level; 242 1.1.4.2 mrg block_t ind_cache; 243 1.1.4.2 mrg block_t ind_block_num; 244 1.1.4.2 mrg zone_t zone; 245 1.1.4.2 mrg size_t rsize; 246 1.1.4.2 mrg int rc; 247 1.1.4.2 mrg int boff; 248 1.1.4.2 mrg int scale = fs->mfs_log_zone_size; /* for block-zone conversion */ 249 1.1.4.2 mrg block_t *buf = (void *)fp->f_buf; 250 1.1.4.2 mrg 251 1.1.4.2 mrg /* 252 1.1.4.2 mrg * Index structure of an inode: 253 1.1.4.2 mrg * 254 1.1.4.2 mrg * mdi_blocks[0..NR_DZONES-1] 255 1.1.4.2 mrg * hold zone numbers for zones 256 1.1.4.2 mrg * 0..NR_DZONES-1 257 1.1.4.2 mrg * 258 1.1.4.2 mrg * mdi_blocks[NR_DZONES+0] 259 1.1.4.2 mrg * block NDADDR+0 is the single indirect block 260 1.1.4.2 mrg * holds zone numbers for zones 261 1.1.4.2 mrg * NR_DZONES .. NR_DZONES + NINDIR(fs)-1 262 1.1.4.2 mrg * 263 1.1.4.2 mrg * mdi_blocks[NR_DZONES+1] 264 1.1.4.2 mrg * block NDADDR+1 is the double indirect block 265 1.1.4.2 mrg * holds zone numbers for INDEX blocks for zones 266 1.1.4.2 mrg * NR_DZONES + NINDIR(fs) .. 267 1.1.4.2 mrg * NR_TZONES + NINDIR(fs) + NINDIR(fs)**2 - 1 268 1.1.4.2 mrg */ 269 1.1.4.2 mrg 270 1.1.4.2 mrg zone = file_block >> scale; 271 1.1.4.2 mrg boff = (int) (file_block - (zone << scale) ); /* relative blk in zone */ 272 1.1.4.2 mrg 273 1.1.4.2 mrg if (zone < NR_DZONES) { 274 1.1.4.2 mrg /* Direct zone */ 275 1.1.4.2 mrg zone_t z = fs2h32(fp->f_di.mdi_zone[zone]); 276 1.1.4.2 mrg if (z == NO_ZONE) { 277 1.1.4.2 mrg *disk_block_p = NO_BLOCK; 278 1.1.4.2 mrg return 0; 279 1.1.4.2 mrg } 280 1.1.4.2 mrg *disk_block_p = (block_t) ((z << scale) + boff); 281 1.1.4.2 mrg return 0; 282 1.1.4.2 mrg } 283 1.1.4.2 mrg 284 1.1.4.2 mrg zone -= NR_DZONES; 285 1.1.4.2 mrg 286 1.1.4.2 mrg ind_cache = zone >> LN2_IND_CACHE_SZ; 287 1.1.4.2 mrg if (ind_cache == fp->f_ind_cache_block) { 288 1.1.4.2 mrg *disk_block_p = 289 1.1.4.2 mrg fs2h32(fp->f_ind_cache[zone & IND_CACHE_MASK]); 290 1.1.4.2 mrg return 0; 291 1.1.4.2 mrg } 292 1.1.4.2 mrg 293 1.1.4.2 mrg for (level = 0;;) { 294 1.1.4.2 mrg level += fp->f_nishift; 295 1.1.4.2 mrg 296 1.1.4.2 mrg if (zone < (block_t)1 << level) 297 1.1.4.2 mrg break; 298 1.1.4.2 mrg if (level > NIADDR * fp->f_nishift) 299 1.1.4.2 mrg /* Zone number too high */ 300 1.1.4.2 mrg return EFBIG; 301 1.1.4.2 mrg zone -= (block_t)1 << level; 302 1.1.4.2 mrg } 303 1.1.4.2 mrg 304 1.1.4.2 mrg ind_block_num = 305 1.1.4.2 mrg fs2h32(fp->f_di.mdi_zone[NR_DZONES + (level / fp->f_nishift - 1)]); 306 1.1.4.2 mrg 307 1.1.4.2 mrg for (;;) { 308 1.1.4.2 mrg level -= fp->f_nishift; 309 1.1.4.2 mrg if (ind_block_num == 0) { 310 1.1.4.2 mrg *disk_block_p = NO_BLOCK; /* missing */ 311 1.1.4.2 mrg return 0; 312 1.1.4.2 mrg } 313 1.1.4.2 mrg 314 1.1.4.2 mrg twiddle(); 315 1.1.4.2 mrg /* 316 1.1.4.2 mrg * If we were feeling brave, we could work out the number 317 1.1.4.2 mrg * of the disk sector and read a single disk sector instead 318 1.1.4.2 mrg * of a filesystem block. 319 1.1.4.2 mrg * However we don't do this very often anyway... 320 1.1.4.2 mrg */ 321 1.1.4.2 mrg rc = DEV_STRATEGY(f->f_dev)(f->f_devdata, F_READ, 322 1.1.4.2 mrg FSBTODB(fs, ind_block_num), fs->mfs_block_size, 323 1.1.4.2 mrg buf, &rsize); 324 1.1.4.2 mrg if (rc) 325 1.1.4.2 mrg return rc; 326 1.1.4.2 mrg if (rsize != fs->mfs_block_size) 327 1.1.4.2 mrg return EIO; 328 1.1.4.2 mrg 329 1.1.4.2 mrg ind_block_num = fs2h32(buf[zone >> level]); 330 1.1.4.2 mrg if (level == 0) 331 1.1.4.2 mrg break; 332 1.1.4.2 mrg zone &= (1 << level) - 1; 333 1.1.4.2 mrg } 334 1.1.4.2 mrg 335 1.1.4.2 mrg /* Save the part of the block that contains this sector */ 336 1.1.4.2 mrg memcpy(fp->f_ind_cache, &buf[zone & ~IND_CACHE_MASK], 337 1.1.4.2 mrg IND_CACHE_SZ * sizeof fp->f_ind_cache[0]); 338 1.1.4.2 mrg fp->f_ind_cache_block = ind_cache; 339 1.1.4.2 mrg 340 1.1.4.2 mrg zone = (zone_t)ind_block_num; 341 1.1.4.2 mrg *disk_block_p = (block_t)((zone << scale) + boff); 342 1.1.4.2 mrg return 0; 343 1.1.4.2 mrg } 344 1.1.4.2 mrg 345 1.1.4.2 mrg /* 346 1.1.4.2 mrg * Read a portion of a file into an internal buffer. 347 1.1.4.2 mrg * Return the location in the buffer and the amount in the buffer. 348 1.1.4.2 mrg */ 349 1.1.4.2 mrg static int 350 1.1.4.2 mrg buf_read_file(struct open_file *f, void *v, size_t *size_p) 351 1.1.4.2 mrg { 352 1.1.4.2 mrg char **buf_p = v; 353 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 354 1.1.4.2 mrg struct mfs_sblock *fs = fp->f_fs; 355 1.1.4.2 mrg long off; 356 1.1.4.2 mrg block_t file_block; 357 1.1.4.2 mrg block_t disk_block; 358 1.1.4.2 mrg size_t block_size; 359 1.1.4.2 mrg int rc; 360 1.1.4.2 mrg 361 1.1.4.2 mrg off = blkoff(fs, fp->f_seekp); 362 1.1.4.2 mrg file_block = lblkno(fs, fp->f_seekp); 363 1.1.4.2 mrg block_size = fs->mfs_block_size; 364 1.1.4.2 mrg 365 1.1.4.2 mrg if (file_block != fp->f_buf_blkno) { 366 1.1.4.2 mrg rc = block_map(f, file_block, &disk_block); 367 1.1.4.2 mrg if (rc) 368 1.1.4.2 mrg return rc; 369 1.1.4.2 mrg 370 1.1.4.2 mrg if (disk_block == 0) { 371 1.1.4.2 mrg memset(fp->f_buf, 0, block_size); 372 1.1.4.2 mrg fp->f_buf_size = block_size; 373 1.1.4.2 mrg } else { 374 1.1.4.2 mrg twiddle(); 375 1.1.4.2 mrg rc = DEV_STRATEGY(f->f_dev)(f->f_devdata, F_READ, 376 1.1.4.2 mrg FSBTODB(fs, disk_block), 377 1.1.4.2 mrg block_size, fp->f_buf, &fp->f_buf_size); 378 1.1.4.2 mrg if (rc) 379 1.1.4.2 mrg return rc; 380 1.1.4.2 mrg } 381 1.1.4.2 mrg 382 1.1.4.2 mrg fp->f_buf_blkno = file_block; 383 1.1.4.2 mrg } 384 1.1.4.2 mrg 385 1.1.4.2 mrg /* 386 1.1.4.2 mrg * Return address of byte in buffer corresponding to 387 1.1.4.2 mrg * offset, and size of remainder of buffer after that 388 1.1.4.2 mrg * byte. 389 1.1.4.2 mrg */ 390 1.1.4.2 mrg *buf_p = fp->f_buf + off; 391 1.1.4.2 mrg *size_p = block_size - off; 392 1.1.4.2 mrg 393 1.1.4.2 mrg /* 394 1.1.4.2 mrg * But truncate buffer at end of file. 395 1.1.4.2 mrg */ 396 1.1.4.2 mrg if (*size_p > fp->f_di.mdi_size - fp->f_seekp) 397 1.1.4.2 mrg *size_p = fp->f_di.mdi_size - fp->f_seekp; 398 1.1.4.2 mrg 399 1.1.4.2 mrg return 0; 400 1.1.4.2 mrg } 401 1.1.4.2 mrg 402 1.1.4.2 mrg /* 403 1.1.4.2 mrg * Search a directory for a name and return its 404 1.1.4.2 mrg * inode number. 405 1.1.4.2 mrg */ 406 1.1.4.2 mrg static int 407 1.1.4.2 mrg search_directory(const char *name, int length, struct open_file *f, 408 1.1.4.2 mrg ino32_t *inumber_p) 409 1.1.4.2 mrg { 410 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 411 1.1.4.2 mrg struct mfs_sblock *fs = fp->f_fs; 412 1.1.4.2 mrg struct mfs_direct *dp; 413 1.1.4.2 mrg struct mfs_direct *dbuf; 414 1.1.4.2 mrg size_t buf_size; 415 1.1.4.2 mrg int namlen; 416 1.1.4.2 mrg int rc; 417 1.1.4.2 mrg 418 1.1.4.2 mrg fp->f_seekp = 0; 419 1.1.4.2 mrg 420 1.1.4.2 mrg while (fp->f_seekp < (off_t)fp->f_di.mdi_size) { 421 1.1.4.2 mrg rc = buf_read_file(f, (void *)&dbuf, &buf_size); 422 1.1.4.2 mrg if (rc) 423 1.1.4.2 mrg return rc; 424 1.1.4.2 mrg if (buf_size == 0) 425 1.1.4.2 mrg return EIO; 426 1.1.4.2 mrg 427 1.1.4.2 mrg /* XXX we assume, that buf_read_file reads an fs block and 428 1.1.4.2 mrg * doesn't truncate buffer. Currently i_size in MFS doesn't 429 1.1.4.2 mrg * the same as size of allocated blocks, it makes buf_read_file 430 1.1.4.2 mrg * to truncate buf_size. 431 1.1.4.2 mrg */ 432 1.1.4.2 mrg if (buf_size < fs->mfs_block_size) 433 1.1.4.2 mrg buf_size = fs->mfs_block_size; 434 1.1.4.2 mrg 435 1.1.4.2 mrg for (dp = dbuf; dp < &dbuf[NR_DIR_ENTRIES(fs)]; dp++) { 436 1.1.4.2 mrg char *cp; 437 1.1.4.2 mrg if (fs2h32(dp->mfsd_ino) == (ino32_t) 0) 438 1.1.4.2 mrg continue; 439 1.1.4.2 mrg /* Compute the length of the name */ 440 1.1.4.2 mrg cp = memchr(dp->mfsd_name, '\0', sizeof(dp->mfsd_name)); 441 1.1.4.2 mrg if (cp == NULL) 442 1.1.4.2 mrg namlen = sizeof(dp->mfsd_name); 443 1.1.4.2 mrg else 444 1.1.4.2 mrg namlen = cp - (dp->mfsd_name); 445 1.1.4.2 mrg 446 1.1.4.2 mrg if (namlen == length && 447 1.1.4.2 mrg !memcmp(name, dp->mfsd_name, length)) { 448 1.1.4.2 mrg /* found entry */ 449 1.1.4.2 mrg *inumber_p = fs2h32(dp->mfsd_ino); 450 1.1.4.2 mrg return 0; 451 1.1.4.2 mrg } 452 1.1.4.2 mrg } 453 1.1.4.2 mrg fp->f_seekp += buf_size; 454 1.1.4.2 mrg } 455 1.1.4.2 mrg return ENOENT; 456 1.1.4.2 mrg } 457 1.1.4.2 mrg 458 1.1.4.2 mrg int 459 1.1.4.2 mrg read_sblock(struct open_file *f, struct mfs_sblock *fs) 460 1.1.4.2 mrg { 461 1.1.4.2 mrg static uint8_t sbbuf[MINBSIZE]; 462 1.1.4.2 mrg size_t buf_size; 463 1.1.4.2 mrg int rc; 464 1.1.4.2 mrg 465 1.1.4.2 mrg /* We must read amount multiple of sector size, hence we can't 466 1.1.4.2 mrg * read SBSIZE and read MINBSIZE. 467 1.1.4.2 mrg */ 468 1.1.4.2 mrg if (SBSIZE > MINBSIZE) 469 1.1.4.2 mrg return EINVAL; 470 1.1.4.2 mrg 471 1.1.4.2 mrg rc = DEV_STRATEGY(f->f_dev)(f->f_devdata, F_READ, 472 1.1.4.2 mrg SUPER_BLOCK_OFF / DEV_BSIZE, MINBSIZE, sbbuf, &buf_size); 473 1.1.4.2 mrg if (rc) 474 1.1.4.2 mrg return rc; 475 1.1.4.2 mrg 476 1.1.4.2 mrg if (buf_size != MINBSIZE) 477 1.1.4.2 mrg return EIO; 478 1.1.4.2 mrg 479 1.1.4.2 mrg mfs_sbload((void *)sbbuf, fs); 480 1.1.4.2 mrg 481 1.1.4.2 mrg if (fs->mfs_magic != SUPER_MAGIC) 482 1.1.4.2 mrg return EINVAL; 483 1.1.4.2 mrg if (fs->mfs_block_size < MINBSIZE) 484 1.1.4.2 mrg return EINVAL; 485 1.1.4.2 mrg if ((fs->mfs_block_size % 512) != 0) 486 1.1.4.2 mrg return EINVAL; 487 1.1.4.2 mrg if (SBSIZE > fs->mfs_block_size) 488 1.1.4.2 mrg return EINVAL; 489 1.1.4.2 mrg if ((fs->mfs_block_size % INODE_SIZE) != 0) 490 1.1.4.2 mrg return EINVAL; 491 1.1.4.2 mrg 492 1.1.4.2 mrg /* For even larger disks, a similar problem occurs with s_firstdatazone. 493 1.1.4.2 mrg * If the on-disk field contains zero, we assume that the value was too 494 1.1.4.2 mrg * large to fit, and compute it on the fly. 495 1.1.4.2 mrg */ 496 1.1.4.2 mrg if (fs->mfs_firstdatazone_old == 0) { 497 1.1.4.2 mrg block_t offset; 498 1.1.4.2 mrg offset = START_BLOCK + fs->mfs_imap_blocks + fs->mfs_zmap_blocks; 499 1.1.4.2 mrg offset += (fs->mfs_ninodes + fs->mfs_inodes_per_block - 1) / 500 1.1.4.2 mrg fs->mfs_inodes_per_block; 501 1.1.4.2 mrg 502 1.1.4.2 mrg fs->mfs_firstdatazone = 503 1.1.4.2 mrg (offset + (1 << fs->mfs_log_zone_size) - 1) >> 504 1.1.4.2 mrg fs->mfs_log_zone_size; 505 1.1.4.2 mrg } else { 506 1.1.4.2 mrg fs->mfs_firstdatazone = (zone_t) fs->mfs_firstdatazone_old; 507 1.1.4.2 mrg } 508 1.1.4.2 mrg 509 1.1.4.2 mrg if (fs->mfs_imap_blocks < 1 || fs->mfs_zmap_blocks < 1 510 1.1.4.2 mrg || fs->mfs_ninodes < 1 || fs->mfs_zones < 1 511 1.1.4.2 mrg || fs->mfs_firstdatazone <= 4 512 1.1.4.2 mrg || fs->mfs_firstdatazone >= fs->mfs_zones 513 1.1.4.2 mrg || (unsigned) fs->mfs_log_zone_size > 4) 514 1.1.4.2 mrg return EINVAL; 515 1.1.4.2 mrg 516 1.1.4.2 mrg /* compute in-memory mfs_sblock values */ 517 1.1.4.2 mrg fs->mfs_inodes_per_block = fs->mfs_block_size / INODE_SIZE; 518 1.1.4.2 mrg 519 1.1.4.2 mrg 520 1.1.4.2 mrg { 521 1.1.4.2 mrg int32_t mult = fs->mfs_block_size >> LOG_MINBSIZE; 522 1.1.4.2 mrg int ln2 = LOG_MINBSIZE; 523 1.1.4.2 mrg 524 1.1.4.2 mrg for (; mult != 1; ln2++) 525 1.1.4.2 mrg mult >>= 1; 526 1.1.4.2 mrg 527 1.1.4.2 mrg fs->mfs_bshift = ln2; 528 1.1.4.2 mrg /* XXX assume hw bsize = 512 */ 529 1.1.4.2 mrg fs->mfs_fsbtodb = ln2 - LOG_MINBSIZE + 1; 530 1.1.4.2 mrg } 531 1.1.4.2 mrg 532 1.1.4.2 mrg fs->mfs_qbmask = fs->mfs_block_size - 1; 533 1.1.4.2 mrg fs->mfs_bmask = ~fs->mfs_qbmask; 534 1.1.4.2 mrg 535 1.1.4.2 mrg return 0; 536 1.1.4.2 mrg } 537 1.1.4.2 mrg 538 1.1.4.2 mrg /* 539 1.1.4.2 mrg * Open a file. 540 1.1.4.2 mrg */ 541 1.1.4.2 mrg __compactcall int 542 1.1.4.2 mrg minixfs3_open(const char *path, struct open_file *f) 543 1.1.4.2 mrg { 544 1.1.4.2 mrg #ifndef LIBSA_FS_SINGLECOMPONENT 545 1.1.4.2 mrg const char *cp, *ncp; 546 1.1.4.2 mrg int c; 547 1.1.4.2 mrg #endif 548 1.1.4.2 mrg ino32_t inumber; 549 1.1.4.2 mrg struct file *fp; 550 1.1.4.2 mrg struct mfs_sblock *fs; 551 1.1.4.2 mrg int rc; 552 1.1.4.2 mrg #ifndef LIBSA_NO_FS_SYMLINK 553 1.1.4.2 mrg ino32_t parent_inumber; 554 1.1.4.2 mrg int nlinks = 0; 555 1.1.4.2 mrg char namebuf[MAXPATHLEN+1]; 556 1.1.4.2 mrg char *buf; 557 1.1.4.2 mrg #endif 558 1.1.4.2 mrg 559 1.1.4.2 mrg /* allocate file system specific data structure */ 560 1.1.4.2 mrg fp = alloc(sizeof(struct file)); 561 1.1.4.2 mrg memset(fp, 0, sizeof(struct file)); 562 1.1.4.2 mrg f->f_fsdata = (void *)fp; 563 1.1.4.2 mrg 564 1.1.4.2 mrg /* allocate space and read super block */ 565 1.1.4.2 mrg fs = alloc(sizeof(*fs)); 566 1.1.4.2 mrg memset(fs, 0, sizeof(*fs)); 567 1.1.4.2 mrg fp->f_fs = fs; 568 1.1.4.2 mrg twiddle(); 569 1.1.4.2 mrg 570 1.1.4.2 mrg rc = read_sblock(f, fs); 571 1.1.4.2 mrg if (rc) 572 1.1.4.2 mrg goto out; 573 1.1.4.2 mrg 574 1.1.4.2 mrg /* alloc a block sized buffer used for all fs transfers */ 575 1.1.4.2 mrg fp->f_buf = alloc(fs->mfs_block_size); 576 1.1.4.2 mrg 577 1.1.4.2 mrg /* 578 1.1.4.2 mrg * Calculate indirect block levels. 579 1.1.4.2 mrg */ 580 1.1.4.2 mrg { 581 1.1.4.2 mrg int32_t mult; 582 1.1.4.2 mrg int ln2; 583 1.1.4.2 mrg 584 1.1.4.2 mrg /* 585 1.1.4.2 mrg * We note that the number of indirect blocks is always 586 1.1.4.2 mrg * a power of 2. This lets us use shifts and masks instead 587 1.1.4.2 mrg * of divide and remainder and avoinds pulling in the 588 1.1.4.2 mrg * 64bit division routine into the boot code. 589 1.1.4.2 mrg */ 590 1.1.4.2 mrg mult = NINDIR(fs); 591 1.1.4.2 mrg #ifdef DEBUG 592 1.1.4.2 mrg if (!powerof2(mult)) { 593 1.1.4.2 mrg /* Hummm was't a power of 2 */ 594 1.1.4.2 mrg rc = EINVAL; 595 1.1.4.2 mrg goto out; 596 1.1.4.2 mrg } 597 1.1.4.2 mrg #endif 598 1.1.4.2 mrg for (ln2 = 0; mult != 1; ln2++) 599 1.1.4.2 mrg mult >>= 1; 600 1.1.4.2 mrg 601 1.1.4.2 mrg fp->f_nishift = ln2; 602 1.1.4.2 mrg } 603 1.1.4.2 mrg 604 1.1.4.2 mrg inumber = ROOT_INODE; 605 1.1.4.2 mrg if ((rc = read_inode(inumber, f)) != 0) 606 1.1.4.2 mrg goto out; 607 1.1.4.2 mrg 608 1.1.4.2 mrg #ifndef LIBSA_FS_SINGLECOMPONENT 609 1.1.4.2 mrg cp = path; 610 1.1.4.2 mrg while (*cp) { 611 1.1.4.2 mrg 612 1.1.4.2 mrg /* 613 1.1.4.2 mrg * Remove extra separators 614 1.1.4.2 mrg */ 615 1.1.4.2 mrg while (*cp == '/') 616 1.1.4.2 mrg cp++; 617 1.1.4.2 mrg if (*cp == '\0') 618 1.1.4.2 mrg break; 619 1.1.4.2 mrg 620 1.1.4.2 mrg /* 621 1.1.4.2 mrg * Check that current node is a directory. 622 1.1.4.2 mrg */ 623 1.1.4.2 mrg if ((fp->f_di.mdi_mode & I_TYPE) != I_DIRECTORY) { 624 1.1.4.2 mrg rc = ENOTDIR; 625 1.1.4.2 mrg goto out; 626 1.1.4.2 mrg } 627 1.1.4.2 mrg 628 1.1.4.2 mrg /* 629 1.1.4.2 mrg * Get next component of path name. 630 1.1.4.2 mrg */ 631 1.1.4.2 mrg ncp = cp; 632 1.1.4.2 mrg while ((c = *cp) != '\0' && c != '/') 633 1.1.4.2 mrg cp++; 634 1.1.4.2 mrg 635 1.1.4.2 mrg /* 636 1.1.4.2 mrg * Look up component in current directory. 637 1.1.4.2 mrg * Save directory inumber in case we find a 638 1.1.4.2 mrg * symbolic link. 639 1.1.4.2 mrg */ 640 1.1.4.2 mrg #ifndef LIBSA_NO_FS_SYMLINK 641 1.1.4.2 mrg parent_inumber = inumber; 642 1.1.4.2 mrg #endif 643 1.1.4.2 mrg rc = search_directory(ncp, cp - ncp, f, &inumber); 644 1.1.4.2 mrg if (rc) 645 1.1.4.2 mrg goto out; 646 1.1.4.2 mrg 647 1.1.4.2 mrg /* 648 1.1.4.2 mrg * Open next component. 649 1.1.4.2 mrg */ 650 1.1.4.2 mrg if ((rc = read_inode(inumber, f)) != 0) 651 1.1.4.2 mrg goto out; 652 1.1.4.2 mrg 653 1.1.4.2 mrg #ifndef LIBSA_NO_FS_SYMLINK 654 1.1.4.2 mrg /* 655 1.1.4.2 mrg * Check for symbolic link. 656 1.1.4.2 mrg */ 657 1.1.4.2 mrg if ((fp->f_di.mdi_mode & I_TYPE) == I_SYMBOLIC_LINK) { 658 1.1.4.2 mrg int link_len = fp->f_di.mdi_size; 659 1.1.4.2 mrg int len; 660 1.1.4.2 mrg size_t buf_size; 661 1.1.4.2 mrg block_t disk_block; 662 1.1.4.2 mrg 663 1.1.4.2 mrg len = strlen(cp); 664 1.1.4.2 mrg 665 1.1.4.2 mrg if (link_len + len > MAXPATHLEN || 666 1.1.4.2 mrg ++nlinks > MAXSYMLINKS) { 667 1.1.4.2 mrg rc = ENOENT; 668 1.1.4.2 mrg goto out; 669 1.1.4.2 mrg } 670 1.1.4.2 mrg 671 1.1.4.2 mrg memmove(&namebuf[link_len], cp, len + 1); 672 1.1.4.2 mrg 673 1.1.4.2 mrg /* 674 1.1.4.2 mrg * Read file for symbolic link 675 1.1.4.2 mrg */ 676 1.1.4.2 mrg buf = fp->f_buf; 677 1.1.4.2 mrg rc = block_map(f, (block_t)0, &disk_block); 678 1.1.4.2 mrg if (rc) 679 1.1.4.2 mrg goto out; 680 1.1.4.2 mrg 681 1.1.4.2 mrg twiddle(); 682 1.1.4.2 mrg rc = DEV_STRATEGY(f->f_dev)(f->f_devdata, 683 1.1.4.2 mrg F_READ, FSBTODB(fs, disk_block), 684 1.1.4.2 mrg fs->mfs_block_size, buf, &buf_size); 685 1.1.4.2 mrg if (rc) 686 1.1.4.2 mrg goto out; 687 1.1.4.2 mrg 688 1.1.4.2 mrg memcpy(namebuf, buf, link_len); 689 1.1.4.2 mrg 690 1.1.4.2 mrg /* 691 1.1.4.2 mrg * If relative pathname, restart at parent directory. 692 1.1.4.2 mrg * If absolute pathname, restart at root. 693 1.1.4.2 mrg */ 694 1.1.4.2 mrg cp = namebuf; 695 1.1.4.2 mrg if (*cp != '/') 696 1.1.4.2 mrg inumber = parent_inumber; 697 1.1.4.2 mrg else 698 1.1.4.2 mrg inumber = (ino32_t) ROOT_INODE; 699 1.1.4.2 mrg 700 1.1.4.2 mrg if ((rc = read_inode(inumber, f)) != 0) 701 1.1.4.2 mrg goto out; 702 1.1.4.2 mrg } 703 1.1.4.2 mrg #endif /* !LIBSA_NO_FS_SYMLINK */ 704 1.1.4.2 mrg } 705 1.1.4.2 mrg 706 1.1.4.2 mrg /* 707 1.1.4.2 mrg * Found terminal component. 708 1.1.4.2 mrg */ 709 1.1.4.2 mrg rc = 0; 710 1.1.4.2 mrg 711 1.1.4.2 mrg #else /* !LIBSA_FS_SINGLECOMPONENT */ 712 1.1.4.2 mrg 713 1.1.4.2 mrg /* look up component in the current (root) directory */ 714 1.1.4.2 mrg rc = search_directory(path, strlen(path), f, &inumber); 715 1.1.4.2 mrg if (rc) 716 1.1.4.2 mrg goto out; 717 1.1.4.2 mrg 718 1.1.4.2 mrg /* open it */ 719 1.1.4.2 mrg rc = read_inode(inumber, f); 720 1.1.4.2 mrg 721 1.1.4.2 mrg #endif /* !LIBSA_FS_SINGLECOMPONENT */ 722 1.1.4.2 mrg 723 1.1.4.2 mrg fp->f_seekp = 0; /* reset seek pointer */ 724 1.1.4.2 mrg 725 1.1.4.2 mrg out: 726 1.1.4.2 mrg if (rc) 727 1.1.4.2 mrg minixfs3_close(f); 728 1.1.4.2 mrg 729 1.1.4.2 mrg return rc; 730 1.1.4.2 mrg } 731 1.1.4.2 mrg 732 1.1.4.2 mrg __compactcall int 733 1.1.4.2 mrg minixfs3_close(struct open_file *f) 734 1.1.4.2 mrg { 735 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 736 1.1.4.2 mrg 737 1.1.4.2 mrg f->f_fsdata = NULL; 738 1.1.4.2 mrg if (fp == NULL) 739 1.1.4.2 mrg return 0; 740 1.1.4.2 mrg 741 1.1.4.2 mrg if (fp->f_buf) 742 1.1.4.2 mrg dealloc(fp->f_buf, fp->f_fs->mfs_block_size); 743 1.1.4.2 mrg dealloc(fp->f_fs, sizeof(*fp->f_fs)); 744 1.1.4.2 mrg dealloc(fp, sizeof(struct file)); 745 1.1.4.2 mrg return 0; 746 1.1.4.2 mrg } 747 1.1.4.2 mrg 748 1.1.4.2 mrg /* 749 1.1.4.2 mrg * Copy a portion of a file into kernel memory. 750 1.1.4.2 mrg * Cross block boundaries when necessary. 751 1.1.4.2 mrg */ 752 1.1.4.2 mrg __compactcall int 753 1.1.4.2 mrg minixfs3_read(struct open_file *f, void *start, size_t size, size_t *resid) 754 1.1.4.2 mrg { 755 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 756 1.1.4.2 mrg size_t csize; 757 1.1.4.2 mrg char *buf; 758 1.1.4.2 mrg size_t buf_size; 759 1.1.4.2 mrg int rc = 0; 760 1.1.4.2 mrg char *addr = start; 761 1.1.4.2 mrg 762 1.1.4.2 mrg while (size != 0) { 763 1.1.4.2 mrg if (fp->f_seekp >= (off_t)fp->f_di.mdi_size) 764 1.1.4.2 mrg break; 765 1.1.4.2 mrg 766 1.1.4.2 mrg rc = buf_read_file(f, &buf, &buf_size); 767 1.1.4.2 mrg if (rc) 768 1.1.4.2 mrg break; 769 1.1.4.2 mrg 770 1.1.4.2 mrg csize = size; 771 1.1.4.2 mrg if (csize > buf_size) 772 1.1.4.2 mrg csize = buf_size; 773 1.1.4.2 mrg 774 1.1.4.2 mrg memcpy(addr, buf, csize); 775 1.1.4.2 mrg 776 1.1.4.2 mrg fp->f_seekp += csize; 777 1.1.4.2 mrg addr += csize; 778 1.1.4.2 mrg size -= csize; 779 1.1.4.2 mrg } 780 1.1.4.2 mrg 781 1.1.4.2 mrg if (resid) 782 1.1.4.2 mrg *resid = size; 783 1.1.4.2 mrg return rc; 784 1.1.4.2 mrg } 785 1.1.4.2 mrg 786 1.1.4.2 mrg /* 787 1.1.4.2 mrg * Not implemented. 788 1.1.4.2 mrg */ 789 1.1.4.2 mrg #ifndef LIBSA_NO_FS_WRITE 790 1.1.4.2 mrg __compactcall int 791 1.1.4.2 mrg minixfs3_write(struct open_file *f, void *start, size_t size, size_t *resid) 792 1.1.4.2 mrg { 793 1.1.4.2 mrg 794 1.1.4.2 mrg return EROFS; 795 1.1.4.2 mrg } 796 1.1.4.2 mrg #endif /* !LIBSA_NO_FS_WRITE */ 797 1.1.4.2 mrg 798 1.1.4.2 mrg #ifndef LIBSA_NO_FS_SEEK 799 1.1.4.2 mrg __compactcall off_t 800 1.1.4.2 mrg minixfs3_seek(struct open_file *f, off_t offset, int where) 801 1.1.4.2 mrg { 802 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 803 1.1.4.2 mrg 804 1.1.4.2 mrg switch (where) { 805 1.1.4.2 mrg case SEEK_SET: 806 1.1.4.2 mrg fp->f_seekp = offset; 807 1.1.4.2 mrg break; 808 1.1.4.2 mrg case SEEK_CUR: 809 1.1.4.2 mrg fp->f_seekp += offset; 810 1.1.4.2 mrg break; 811 1.1.4.2 mrg case SEEK_END: 812 1.1.4.2 mrg fp->f_seekp = fp->f_di.mdi_size - offset; 813 1.1.4.2 mrg break; 814 1.1.4.2 mrg default: 815 1.1.4.2 mrg return -1; 816 1.1.4.2 mrg } 817 1.1.4.2 mrg return fp->f_seekp; 818 1.1.4.2 mrg } 819 1.1.4.2 mrg #endif /* !LIBSA_NO_FS_SEEK */ 820 1.1.4.2 mrg 821 1.1.4.2 mrg __compactcall int 822 1.1.4.2 mrg minixfs3_stat(struct open_file *f, struct stat *sb) 823 1.1.4.2 mrg { 824 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 825 1.1.4.2 mrg 826 1.1.4.2 mrg /* only important stuff */ 827 1.1.4.2 mrg memset(sb, 0, sizeof *sb); 828 1.1.4.2 mrg sb->st_mode = fp->f_di.mdi_mode; 829 1.1.4.2 mrg sb->st_uid = fp->f_di.mdi_uid; 830 1.1.4.2 mrg sb->st_gid = fp->f_di.mdi_gid; 831 1.1.4.2 mrg sb->st_size = fp->f_di.mdi_size; 832 1.1.4.2 mrg return 0; 833 1.1.4.2 mrg } 834 1.1.4.2 mrg 835 1.1.4.2 mrg #if defined(LIBSA_ENABLE_LS_OP) 836 1.1.4.2 mrg __compactcall void 837 1.1.4.2 mrg minixfs3_ls(struct open_file *f, const char *pattern) 838 1.1.4.2 mrg { 839 1.1.4.2 mrg struct file *fp = (struct file *)f->f_fsdata; 840 1.1.4.2 mrg struct mfs_sblock *fs = fp->f_fs; 841 1.1.4.2 mrg struct mfs_direct *dp; 842 1.1.4.2 mrg struct mfs_direct *dbuf; 843 1.1.4.2 mrg size_t buf_size; 844 1.1.4.2 mrg entry_t *names = 0, *n, **np; 845 1.1.4.2 mrg 846 1.1.4.2 mrg fp->f_seekp = 0; 847 1.1.4.2 mrg while (fp->f_seekp < (off_t)fp->f_di.mdi_size) { 848 1.1.4.2 mrg int rc = buf_read_file(f, &dbuf, &buf_size); 849 1.1.4.2 mrg if (rc) 850 1.1.4.2 mrg goto out; 851 1.1.4.2 mrg 852 1.1.4.2 mrg /* XXX we assume, that buf_read_file reads an fs block and 853 1.1.4.2 mrg * doesn't truncate buffer. Currently i_size in MFS doesn't 854 1.1.4.2 mrg * the same as size of allocated blocks, it makes buf_read_file 855 1.1.4.2 mrg * to truncate buf_size. 856 1.1.4.2 mrg */ 857 1.1.4.2 mrg if (buf_size < fs->mfs_block_size) 858 1.1.4.2 mrg buf_size = fs->mfs_block_size; 859 1.1.4.2 mrg 860 1.1.4.2 mrg for (dp = dbuf; dp < &dbuf[NR_DIR_ENTRIES(fs)]; dp++) { 861 1.1.4.2 mrg char *cp; 862 1.1.4.2 mrg int namlen; 863 1.1.4.2 mrg 864 1.1.4.2 mrg if (fs2h32(dp->mfsd_ino) == 0) 865 1.1.4.2 mrg continue; 866 1.1.4.2 mrg 867 1.1.4.2 mrg if (pattern && !fnmatch(dp->mfsd_name, pattern)) 868 1.1.4.2 mrg continue; 869 1.1.4.2 mrg 870 1.1.4.2 mrg /* Compute the length of the name, 871 1.1.4.2 mrg * We don't use strlen and strcpy, because original MFS 872 1.1.4.2 mrg * code doesn't. 873 1.1.4.2 mrg */ 874 1.1.4.2 mrg cp = memchr(dp->mfsd_name, '\0', sizeof(dp->mfsd_name)); 875 1.1.4.2 mrg if (cp == NULL) 876 1.1.4.2 mrg namlen = sizeof(dp->mfsd_name); 877 1.1.4.2 mrg else 878 1.1.4.2 mrg namlen = cp - (dp->mfsd_name); 879 1.1.4.2 mrg 880 1.1.4.2 mrg n = alloc(sizeof *n + namlen); 881 1.1.4.2 mrg if (!n) { 882 1.1.4.2 mrg printf("%d: %s\n", 883 1.1.4.2 mrg fs2h32(dp->mfsd_ino), dp->mfsd_name); 884 1.1.4.2 mrg continue; 885 1.1.4.2 mrg } 886 1.1.4.2 mrg n->e_ino = fs2h32(dp->mfsd_ino); 887 1.1.4.2 mrg strncpy(n->e_name, dp->mfsd_name, namlen); 888 1.1.4.2 mrg n->e_name[namlen] = '\0'; 889 1.1.4.2 mrg for (np = &names; *np; np = &(*np)->e_next) { 890 1.1.4.2 mrg if (strcmp(n->e_name, (*np)->e_name) < 0) 891 1.1.4.2 mrg break; 892 1.1.4.2 mrg } 893 1.1.4.2 mrg n->e_next = *np; 894 1.1.4.2 mrg *np = n; 895 1.1.4.2 mrg } 896 1.1.4.2 mrg fp->f_seekp += buf_size; 897 1.1.4.2 mrg } 898 1.1.4.2 mrg 899 1.1.4.2 mrg if (names) { 900 1.1.4.2 mrg entry_t *p_names = names; 901 1.1.4.2 mrg do { 902 1.1.4.2 mrg n = p_names; 903 1.1.4.2 mrg printf("%d: %s\n", 904 1.1.4.2 mrg n->e_ino, n->e_name); 905 1.1.4.2 mrg p_names = n->e_next; 906 1.1.4.2 mrg } while (p_names); 907 1.1.4.2 mrg } else { 908 1.1.4.2 mrg printf("not found\n"); 909 1.1.4.2 mrg } 910 1.1.4.2 mrg out: 911 1.1.4.2 mrg if (names) { 912 1.1.4.2 mrg do { 913 1.1.4.2 mrg n = names; 914 1.1.4.2 mrg names = n->e_next; 915 1.1.4.2 mrg dealloc(n, 0); 916 1.1.4.2 mrg } while (names); 917 1.1.4.2 mrg } 918 1.1.4.2 mrg return; 919 1.1.4.2 mrg } 920 1.1.4.2 mrg #endif 921 1.1.4.2 mrg 922 1.1.4.2 mrg /* 923 1.1.4.2 mrg * byte swap functions for big endian machines 924 1.1.4.2 mrg * (mfs is always little endian) 925 1.1.4.2 mrg */ 926 1.1.4.2 mrg 927 1.1.4.2 mrg /* These functions are only needed if native byte order is not big endian */ 928 1.1.4.2 mrg #if BYTE_ORDER == BIG_ENDIAN 929 1.1.4.2 mrg void 930 1.1.4.2 mrg minixfs3_sb_bswap(struct mfs_sblock *old, struct mfs_sblock *new) 931 1.1.4.2 mrg { 932 1.1.4.2 mrg new->mfs_ninodes = bswap32(old->mfs_ninodes); 933 1.1.4.2 mrg new->mfs_nzones = bswap16(old->mfs_nzones); 934 1.1.4.2 mrg new->mfs_imap_blocks = bswap16(old->mfs_imap_blocks); 935 1.1.4.2 mrg new->mfs_zmap_blocks = bswap16(old->mfs_zmap_blocks); 936 1.1.4.2 mrg new->mfs_firstdatazone_old = bswap16(old->mfs_firstdatazone_old); 937 1.1.4.2 mrg new->mfs_log_zone_size = bswap16(old->mfs_log_zone_size); 938 1.1.4.2 mrg new->mfs_max_size = bswap32(old->mfs_max_size); 939 1.1.4.2 mrg new->mfs_zones = bswap32(old->mfs_zones); 940 1.1.4.2 mrg new->mfs_magic = bswap16(old->mfs_magic); 941 1.1.4.2 mrg new->mfs_block_size = bswap16(old->mfs_block_size); 942 1.1.4.2 mrg new->mfs_disk_version = old->mfs_disk_version; 943 1.1.4.2 mrg } 944 1.1.4.2 mrg 945 1.1.4.2 mrg void minixfs3_i_bswap(struct mfs_dinode *old, struct mfs_dinode *new) 946 1.1.4.2 mrg { 947 1.1.4.2 mrg int i; 948 1.1.4.2 mrg 949 1.1.4.2 mrg new->mdi_mode = bswap16(old->mdi_mode); 950 1.1.4.2 mrg new->mdi_nlinks = bswap16(old->mdi_nlinks); 951 1.1.4.2 mrg new->mdi_uid = bswap16(old->mdi_uid); 952 1.1.4.2 mrg new->mdi_gid = bswap16(old->mdi_gid); 953 1.1.4.2 mrg new->mdi_size = bswap32(old->mdi_size); 954 1.1.4.2 mrg new->mdi_atime = bswap32(old->mdi_atime); 955 1.1.4.2 mrg new->mdi_mtime = bswap32(old->mdi_mtime); 956 1.1.4.2 mrg new->mdi_ctime = bswap32(old->mdi_ctime); 957 1.1.4.2 mrg 958 1.1.4.2 mrg /* We don't swap here, because indirects must be swapped later 959 1.1.4.2 mrg * anyway, hence everything is done by block_map(). 960 1.1.4.2 mrg */ 961 1.1.4.2 mrg for (i = 0; i < NR_TZONES; i++) 962 1.1.4.2 mrg new->mdi_zone[i] = old->mdi_zone[i]; 963 1.1.4.2 mrg } 964 1.1.4.2 mrg #endif 965
Indexes created Sat Oct 11 19:10:01 GMT 2025