source: trunk/minix/servers/fs/inode.c@ 21

Last change on this file since 21 was 9, checked in by Mattia Monga, 14 years ago

Minix 3.1.2a

File size: 13.4 KB
RevLine 
[9]1/* This file manages the inode table. There are procedures to allocate and
2 * deallocate inodes, acquire, erase, and release them, and read and write
3 * them from the disk.
4 *
5 * The entry points into this file are
6 * get_inode: search inode table for a given inode; if not there,
7 * read it
8 * put_inode: indicate that an inode is no longer needed in memory
9 * alloc_inode: allocate a new, unused inode
10 * wipe_inode: erase some fields of a newly allocated inode
11 * free_inode: mark an inode as available for a new file
12 * update_times: update atime, ctime, and mtime
13 * rw_inode: read a disk block and extract an inode, or corresp. write
14 * old_icopy: copy to/from in-core inode struct and disk inode (V1.x)
15 * new_icopy: copy to/from in-core inode struct and disk inode (V2.x)
16 * dup_inode: indicate that someone else is using an inode table entry
17 */
18
19#include "fs.h"
20#include "buf.h"
21#include "file.h"
22#include "fproc.h"
23#include "inode.h"
24#include "super.h"
25
26FORWARD _PROTOTYPE( void old_icopy, (struct inode *rip, d1_inode *dip,
27 int direction, int norm));
28FORWARD _PROTOTYPE( void new_icopy, (struct inode *rip, d2_inode *dip,
29 int direction, int norm));
30
31/*===========================================================================*
32 * get_inode *
33 *===========================================================================*/
34PUBLIC struct inode *get_inode(dev, numb)
35dev_t dev; /* device on which inode resides */
36int numb; /* inode number (ANSI: may not be unshort) */
37{
38/* Find a slot in the inode table, load the specified inode into it, and
39 * return a pointer to the slot. If 'dev' == NO_DEV, just return a free slot.
40 */
41
42 register struct inode *rip, *xp;
43
44 /* Search the inode table both for (dev, numb) and a free slot. */
45 xp = NIL_INODE;
46 for (rip = &inode[0]; rip < &inode[NR_INODES]; rip++) {
47 if (rip->i_count > 0) { /* only check used slots for (dev, numb) */
48 if (rip->i_dev == dev && rip->i_num == numb) {
49 /* This is the inode that we are looking for. */
50 rip->i_count++;
51 return(rip); /* (dev, numb) found */
52 }
53 } else {
54 xp = rip; /* remember this free slot for later */
55 }
56 }
57
58 /* Inode we want is not currently in use. Did we find a free slot? */
59 if (xp == NIL_INODE) { /* inode table completely full */
60 err_code = ENFILE;
61 return(NIL_INODE);
62 }
63
64 /* A free inode slot has been located. Load the inode into it. */
65 xp->i_dev = dev;
66 xp->i_num = numb;
67 xp->i_count = 1;
68 if (dev != NO_DEV) rw_inode(xp, READING); /* get inode from disk */
69 xp->i_update = 0; /* all the times are initially up-to-date */
70
71 return(xp);
72}
73
74/*===========================================================================*
75 * put_inode *
76 *===========================================================================*/
77PUBLIC void put_inode(rip)
78register struct inode *rip; /* pointer to inode to be released */
79{
80/* The caller is no longer using this inode. If no one else is using it either
81 * write it back to the disk immediately. If it has no links, truncate it and
82 * return it to the pool of available inodes.
83 */
84
85 if (rip == NIL_INODE) return; /* checking here is easier than in caller */
86 if (--rip->i_count == 0) { /* i_count == 0 means no one is using it now */
87 if (rip->i_nlinks == 0) {
88 /* i_nlinks == 0 means free the inode. */
89 truncate_inode(rip, 0); /* return all the disk blocks */
90 rip->i_mode = I_NOT_ALLOC; /* clear I_TYPE field */
91 rip->i_dirt = DIRTY;
92 free_inode(rip->i_dev, rip->i_num);
93 } else {
94 if (rip->i_pipe == I_PIPE) truncate_inode(rip, 0);
95 }
96 rip->i_pipe = NO_PIPE; /* should always be cleared */
97 if (rip->i_dirt == DIRTY) rw_inode(rip, WRITING);
98 }
99}
100
101/*===========================================================================*
102 * alloc_inode *
103 *===========================================================================*/
104PUBLIC struct inode *alloc_inode(dev_t dev, mode_t bits)
105{
106/* Allocate a free inode on 'dev', and return a pointer to it. */
107
108 register struct inode *rip;
109 register struct super_block *sp;
110 int major, minor, inumb;
111 bit_t b;
112
113 sp = get_super(dev); /* get pointer to super_block */
114 if (sp->s_rd_only) { /* can't allocate an inode on a read only device. */
115 err_code = EROFS;
116 return(NIL_INODE);
117 }
118
119 /* Acquire an inode from the bit map. */
120 b = alloc_bit(sp, IMAP, sp->s_isearch);
121 if (b == NO_BIT) {
122 err_code = ENFILE;
123 major = (int) (sp->s_dev >> MAJOR) & BYTE;
124 minor = (int) (sp->s_dev >> MINOR) & BYTE;
125 printf("Out of i-nodes on %sdevice %d/%d\n",
126 sp->s_dev == root_dev ? "root " : "", major, minor);
127 return(NIL_INODE);
128 }
129 sp->s_isearch = b; /* next time start here */
130 inumb = (int) b; /* be careful not to pass unshort as param */
131
132 /* Try to acquire a slot in the inode table. */
133 if ((rip = get_inode(NO_DEV, inumb)) == NIL_INODE) {
134 /* No inode table slots available. Free the inode just allocated. */
135 free_bit(sp, IMAP, b);
136 } else {
137 /* An inode slot is available. Put the inode just allocated into it. */
138 rip->i_mode = bits; /* set up RWX bits */
139 rip->i_nlinks = 0; /* initial no links */
140 rip->i_uid = fp->fp_effuid; /* file's uid is owner's */
141 rip->i_gid = fp->fp_effgid; /* ditto group id */
142 rip->i_dev = dev; /* mark which device it is on */
143 rip->i_ndzones = sp->s_ndzones; /* number of direct zones */
144 rip->i_nindirs = sp->s_nindirs; /* number of indirect zones per blk*/
145 rip->i_sp = sp; /* pointer to super block */
146
147 /* Fields not cleared already are cleared in wipe_inode(). They have
148 * been put there because truncate() needs to clear the same fields if
149 * the file happens to be open while being truncated. It saves space
150 * not to repeat the code twice.
151 */
152 wipe_inode(rip);
153 }
154
155 return(rip);
156}
157
158/*===========================================================================*
159 * wipe_inode *
160 *===========================================================================*/
161PUBLIC void wipe_inode(rip)
162register struct inode *rip; /* the inode to be erased */
163{
164/* Erase some fields in the inode. This function is called from alloc_inode()
165 * when a new inode is to be allocated, and from truncate(), when an existing
166 * inode is to be truncated.
167 */
168
169 register int i;
170
171 rip->i_size = 0;
172 rip->i_update = ATIME | CTIME | MTIME; /* update all times later */
173 rip->i_dirt = DIRTY;
174 for (i = 0; i < V2_NR_TZONES; i++) rip->i_zone[i] = NO_ZONE;
175}
176
177/*===========================================================================*
178 * free_inode *
179 *===========================================================================*/
180PUBLIC void free_inode(dev, inumb)
181dev_t dev; /* on which device is the inode */
182ino_t inumb; /* number of inode to be freed */
183{
184/* Return an inode to the pool of unallocated inodes. */
185
186 register struct super_block *sp;
187 bit_t b;
188
189 /* Locate the appropriate super_block. */
190 sp = get_super(dev);
191 if (inumb <= 0 || inumb > sp->s_ninodes) return;
192 b = inumb;
193 free_bit(sp, IMAP, b);
194 if (b < sp->s_isearch) sp->s_isearch = b;
195}
196
197/*===========================================================================*
198 * update_times *
199 *===========================================================================*/
200PUBLIC void update_times(rip)
201register struct inode *rip; /* pointer to inode to be read/written */
202{
203/* Various system calls are required by the standard to update atime, ctime,
204 * or mtime. Since updating a time requires sending a message to the clock
205 * task--an expensive business--the times are marked for update by setting
206 * bits in i_update. When a stat, fstat, or sync is done, or an inode is
207 * released, update_times() may be called to actually fill in the times.
208 */
209
210 time_t cur_time;
211 struct super_block *sp;
212
213 sp = rip->i_sp; /* get pointer to super block. */
214 if (sp->s_rd_only) return; /* no updates for read-only file systems */
215
216 cur_time = clock_time();
217 if (rip->i_update & ATIME) rip->i_atime = cur_time;
218 if (rip->i_update & CTIME) rip->i_ctime = cur_time;
219 if (rip->i_update & MTIME) rip->i_mtime = cur_time;
220 rip->i_update = 0; /* they are all up-to-date now */
221}
222
223/*===========================================================================*
224 * rw_inode *
225 *===========================================================================*/
226PUBLIC void rw_inode(rip, rw_flag)
227register struct inode *rip; /* pointer to inode to be read/written */
228int rw_flag; /* READING or WRITING */
229{
230/* An entry in the inode table is to be copied to or from the disk. */
231
232 register struct buf *bp;
233 register struct super_block *sp;
234 d1_inode *dip;
235 d2_inode *dip2;
236 block_t b, offset;
237
238 /* Get the block where the inode resides. */
239 sp = get_super(rip->i_dev); /* get pointer to super block */
240 rip->i_sp = sp; /* inode must contain super block pointer */
241 offset = sp->s_imap_blocks + sp->s_zmap_blocks + 2;
242 b = (block_t) (rip->i_num - 1)/sp->s_inodes_per_block + offset;
243 bp = get_block(rip->i_dev, b, NORMAL);
244 dip = bp->b_v1_ino + (rip->i_num - 1) % V1_INODES_PER_BLOCK;
245 dip2 = bp->b_v2_ino + (rip->i_num - 1) %
246 V2_INODES_PER_BLOCK(sp->s_block_size);
247
248 /* Do the read or write. */
249 if (rw_flag == WRITING) {
250 if (rip->i_update) update_times(rip); /* times need updating */
251 if (sp->s_rd_only == FALSE) bp->b_dirt = DIRTY;
252 }
253
254 /* Copy the inode from the disk block to the in-core table or vice versa.
255 * If the fourth parameter below is FALSE, the bytes are swapped.
256 */
257 if (sp->s_version == V1)
258 old_icopy(rip, dip, rw_flag, sp->s_native);
259 else
260 new_icopy(rip, dip2, rw_flag, sp->s_native);
261
262 put_block(bp, INODE_BLOCK);
263 rip->i_dirt = CLEAN;
264}
265
266/*===========================================================================*
267 * old_icopy *
268 *===========================================================================*/
269PRIVATE void old_icopy(rip, dip, direction, norm)
270register struct inode *rip; /* pointer to the in-core inode struct */
271register d1_inode *dip; /* pointer to the d1_inode inode struct */
272int direction; /* READING (from disk) or WRITING (to disk) */
273int norm; /* TRUE = do not swap bytes; FALSE = swap */
274
275{
276/* The V1.x IBM disk, the V1.x 68000 disk, and the V2 disk (same for IBM and
277 * 68000) all have different inode layouts. When an inode is read or written
278 * this routine handles the conversions so that the information in the inode
279 * table is independent of the disk structure from which the inode came.
280 * The old_icopy routine copies to and from V1 disks.
281 */
282
283 int i;
284
285 if (direction == READING) {
286 /* Copy V1.x inode to the in-core table, swapping bytes if need be. */
287 rip->i_mode = conv2(norm, (int) dip->d1_mode);
288 rip->i_uid = conv2(norm, (int) dip->d1_uid );
289 rip->i_size = conv4(norm, dip->d1_size);
290 rip->i_mtime = conv4(norm, dip->d1_mtime);
291 rip->i_atime = rip->i_mtime;
292 rip->i_ctime = rip->i_mtime;
293 rip->i_nlinks = dip->d1_nlinks; /* 1 char */
294 rip->i_gid = dip->d1_gid; /* 1 char */
295 rip->i_ndzones = V1_NR_DZONES;
296 rip->i_nindirs = V1_INDIRECTS;
297 for (i = 0; i < V1_NR_TZONES; i++)
298 rip->i_zone[i] = conv2(norm, (int) dip->d1_zone[i]);
299 } else {
300 /* Copying V1.x inode to disk from the in-core table. */
301 dip->d1_mode = conv2(norm, (int) rip->i_mode);
302 dip->d1_uid = conv2(norm, (int) rip->i_uid );
303 dip->d1_size = conv4(norm, rip->i_size);
304 dip->d1_mtime = conv4(norm, rip->i_mtime);
305 dip->d1_nlinks = rip->i_nlinks; /* 1 char */
306 dip->d1_gid = rip->i_gid; /* 1 char */
307 for (i = 0; i < V1_NR_TZONES; i++)
308 dip->d1_zone[i] = conv2(norm, (int) rip->i_zone[i]);
309 }
310}
311
312/*===========================================================================*
313 * new_icopy *
314 *===========================================================================*/
315PRIVATE void new_icopy(rip, dip, direction, norm)
316register struct inode *rip; /* pointer to the in-core inode struct */
317register d2_inode *dip; /* pointer to the d2_inode struct */
318int direction; /* READING (from disk) or WRITING (to disk) */
319int norm; /* TRUE = do not swap bytes; FALSE = swap */
320
321{
322/* Same as old_icopy, but to/from V2 disk layout. */
323
324 int i;
325
326 if (direction == READING) {
327 /* Copy V2.x inode to the in-core table, swapping bytes if need be. */
328 rip->i_mode = conv2(norm,dip->d2_mode);
329 rip->i_uid = conv2(norm,dip->d2_uid);
330 rip->i_nlinks = conv2(norm,dip->d2_nlinks);
331 rip->i_gid = conv2(norm,dip->d2_gid);
332 rip->i_size = conv4(norm,dip->d2_size);
333 rip->i_atime = conv4(norm,dip->d2_atime);
334 rip->i_ctime = conv4(norm,dip->d2_ctime);
335 rip->i_mtime = conv4(norm,dip->d2_mtime);
336 rip->i_ndzones = V2_NR_DZONES;
337 rip->i_nindirs = V2_INDIRECTS(rip->i_sp->s_block_size);
338 for (i = 0; i < V2_NR_TZONES; i++)
339 rip->i_zone[i] = conv4(norm, (long) dip->d2_zone[i]);
340 } else {
341 /* Copying V2.x inode to disk from the in-core table. */
342 dip->d2_mode = conv2(norm,rip->i_mode);
343 dip->d2_uid = conv2(norm,rip->i_uid);
344 dip->d2_nlinks = conv2(norm,rip->i_nlinks);
345 dip->d2_gid = conv2(norm,rip->i_gid);
346 dip->d2_size = conv4(norm,rip->i_size);
347 dip->d2_atime = conv4(norm,rip->i_atime);
348 dip->d2_ctime = conv4(norm,rip->i_ctime);
349 dip->d2_mtime = conv4(norm,rip->i_mtime);
350 for (i = 0; i < V2_NR_TZONES; i++)
351 dip->d2_zone[i] = conv4(norm, (long) rip->i_zone[i]);
352 }
353}
354
355/*===========================================================================*
356 * dup_inode *
357 *===========================================================================*/
358PUBLIC void dup_inode(ip)
359struct inode *ip; /* The inode to be duplicated. */
360{
361/* This routine is a simplified form of get_inode() for the case where
362 * the inode pointer is already known.
363 */
364
365 ip->i_count++;
366}
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