/* * Copyright (c) 1983 Regents of the University of California. * All rights reserved. The Berkeley software License Agreement * specifies the terms and conditions for redistribution. */ #ifndef lint static char sccsid[] = "@(#)symtab.c 5.1 (Berkeley) 5/28/85"; #endif not lint /* * These routines maintain the symbol table which tracks the state * of the file system being restored. They provide lookup by either * name or inode number. They also provide for creation, deletion, * and renaming of entries. Because of the dynamic nature of pathnames, * names should not be saved, but always constructed just before they * are needed, by calling "myname". */ #include "restore.h" #include /* * The following variables define the inode symbol table. * The primary hash table is dynamically allocated based on * the number of inodes in the file system (maxino), scaled by * HASHFACTOR. The variable "entry" points to the hash table; * the variable "entrytblsize" indicates its size (in entries). */ #define HASHFACTOR 5 static struct entry **entry; static long entrytblsize; /* * Look up an entry by inode number */ struct entry * lookupino(inum) ino_t inum; { register struct entry *ep; if (inum < ROOTINO || inum >= maxino) return (NIL); for (ep = entry[inum % entrytblsize]; ep != NIL; ep = ep->e_next) if (ep->e_ino == inum) return (ep); return (NIL); } /* * Add an entry into the entry table */ addino(inum, np) ino_t inum; struct entry *np; { struct entry **epp; if (inum < ROOTINO || inum >= maxino) panic("addino: out of range %d\n", inum); epp = &entry[inum % entrytblsize]; np->e_ino = inum; np->e_next = *epp; *epp = np; if (dflag) for (np = np->e_next; np != NIL; np = np->e_next) if (np->e_ino == inum) badentry(np, "duplicate inum"); } /* * Delete an entry from the entry table */ deleteino(inum) ino_t inum; { register struct entry *next; struct entry **prev; if (inum < ROOTINO || inum >= maxino) panic("deleteino: out of range %d\n", inum); prev = &entry[inum % entrytblsize]; for (next = *prev; next != NIL; next = next->e_next) { if (next->e_ino == inum) { next->e_ino = 0; *prev = next->e_next; return; } prev = &next->e_next; } panic("deleteino: %d not found\n", inum); } /* * Look up an entry by name */ struct entry * lookupname(name) char *name; { register struct entry *ep; register char *np, *cp; char buf[MAXPATHLEN]; cp = name; for (ep = lookupino(ROOTINO); ep != NIL; ep = ep->e_entries) { for (np = buf; *cp != '/' && *cp != '\0'; ) *np++ = *cp++; *np = '\0'; for ( ; ep != NIL; ep = ep->e_sibling) if (strcmp(ep->e_name, buf) == 0) break; if (ep == NIL) break; if (*cp++ == '\0') return (ep); } return (NIL); } /* * Look up the parent of a pathname */ struct entry * lookupparent(name) char *name; { struct entry *ep; char *tailindex; tailindex = rindex(name, '/'); if (tailindex == 0) return (NIL); *tailindex = '\0'; ep = lookupname(name); *tailindex = '/'; if (ep == NIL) return (NIL); if (ep->e_type != NODE) panic("%s is not a directory\n", name); return (ep); } /* * Determine the current pathname of a node or leaf */ char * myname(ep) register struct entry *ep; { register char *cp; static char namebuf[MAXPATHLEN]; for (cp = &namebuf[MAXPATHLEN - 2]; cp > &namebuf[ep->e_namlen]; ) { cp -= ep->e_namlen; bcopy(ep->e_name, cp, (long)ep->e_namlen); if (ep == lookupino(ROOTINO)) return (cp); *(--cp) = '/'; ep = ep->e_parent; } panic("%s: pathname too long\n", cp); return(cp); } /* * Unused symbol table entries are linked together on a freelist * headed by the following pointer. */ static struct entry *freelist = NIL; /* * add an entry to the symbol table */ struct entry * addentry(name, inum, type) char *name; ino_t inum; int type; { register struct entry *np, *ep; if (freelist != NIL) { np = freelist; freelist = np->e_next; bzero((char *)np, (long)sizeof(struct entry)); } else { np = (struct entry *)calloc(1, sizeof(struct entry)); if (np == NIL) panic("no memory to extend symbol table\n"); } np->e_type = type & ~LINK; ep = lookupparent(name); if (ep == NIL) { if (inum != ROOTINO || lookupino(ROOTINO) != NIL) panic("bad name to addentry %s\n", name); np->e_name = savename(name); np->e_namlen = strlen(name); np->e_parent = np; addino(ROOTINO, np); return (np); } np->e_name = savename(rindex(name, '/') + 1); np->e_namlen = strlen(np->e_name); np->e_parent = ep; np->e_sibling = ep->e_entries; ep->e_entries = np; if (type & LINK) { ep = lookupino(inum); if (ep == NIL) panic("link to non-existant name\n"); np->e_ino = inum; np->e_links = ep->e_links; ep->e_links = np; } else if (inum != 0) { if (lookupino(inum) != NIL) panic("duplicate entry\n"); addino(inum, np); } return (np); } /* * delete an entry from the symbol table */ freeentry(ep) register struct entry *ep; { register struct entry *np; ino_t inum; if (ep->e_flags != REMOVED) badentry(ep, "not marked REMOVED"); if (ep->e_type == NODE) { if (ep->e_links != NIL) badentry(ep, "freeing referenced directory"); if (ep->e_entries != NIL) badentry(ep, "freeing non-empty directory"); } if (ep->e_ino != 0) { np = lookupino(ep->e_ino); if (np == NIL) badentry(ep, "lookupino failed"); if (np == ep) { inum = ep->e_ino; deleteino(inum); if (ep->e_links != NIL) addino(inum, ep->e_links); } else { for (; np != NIL; np = np->e_links) { if (np->e_links == ep) { np->e_links = ep->e_links; break; } } if (np == NIL) badentry(ep, "link not found"); } } removeentry(ep); freename(ep->e_name); ep->e_next = freelist; freelist = ep; } /* * Relocate an entry in the tree structure */ moveentry(ep, newname) register struct entry *ep; char *newname; { struct entry *np; char *cp; np = lookupparent(newname); if (np == NIL) badentry(ep, "cannot move ROOT"); if (np != ep->e_parent) { removeentry(ep); ep->e_parent = np; ep->e_sibling = np->e_entries; np->e_entries = ep; } cp = rindex(newname, '/') + 1; freename(ep->e_name); ep->e_name = savename(cp); ep->e_namlen = strlen(cp); if (strcmp(gentempname(ep), ep->e_name) == 0) ep->e_flags |= TMPNAME; else ep->e_flags &= ~TMPNAME; } /* * Remove an entry in the tree structure */ removeentry(ep) register struct entry *ep; { register struct entry *np; np = ep->e_parent; if (np->e_entries == ep) { np->e_entries = ep->e_sibling; } else { for (np = np->e_entries; np != NIL; np = np->e_sibling) { if (np->e_sibling == ep) { np->e_sibling = ep->e_sibling; break; } } if (np == NIL) badentry(ep, "cannot find entry in parent list"); } } /* * Table of unused string entries, sorted by length. * * Entries are allocated in STRTBLINCR sized pieces so that names * of similar lengths can use the same entry. The value of STRTBLINCR * is chosen so that every entry has at least enough space to hold * a "struct strtbl" header. Thus every entry can be linked onto an * apprpriate free list. * * NB. The macro "allocsize" below assumes that "struct strhdr" * has a size that is a power of two. */ struct strhdr { struct strhdr *next; }; #define STRTBLINCR (sizeof(struct strhdr)) #define allocsize(size) (((size) + 1 + STRTBLINCR - 1) & ~(STRTBLINCR - 1)) static struct strhdr strtblhdr[allocsize(MAXNAMLEN) / STRTBLINCR]; /* * Allocate space for a name. It first looks to see if it already * has an appropriate sized entry, and if not allocates a new one. */ char * savename(name) char *name; { struct strhdr *np; long len; char *cp; if (name == NULL) panic("bad name\n"); len = strlen(name); np = strtblhdr[len / STRTBLINCR].next; if (np != NULL) { strtblhdr[len / STRTBLINCR].next = np->next; cp = (char *)np; } else { cp = malloc((unsigned)allocsize(len)); if (cp == NULL) panic("no space for string table\n"); } (void) strcpy(cp, name); return (cp); } /* * Free space for a name. The resulting entry is linked onto the * appropriate free list. */ freename(name) char *name; { struct strhdr *tp, *np; tp = &strtblhdr[strlen(name) / STRTBLINCR]; np = (struct strhdr *)name; np->next = tp->next; tp->next = np; } /* * Useful quantities placed at the end of a dumped symbol table. */ struct symtableheader { long volno; long stringsize; long entrytblsize; time_t dumptime; time_t dumpdate; ino_t maxino; long ntrec; }; /* * dump a snapshot of the symbol table */ dumpsymtable(filename, checkpt) char *filename; long checkpt; { register struct entry *ep, *tep; register ino_t i; struct entry temp, *tentry; long mynum = 1, stroff = 0; FILE *fd; struct symtableheader hdr; vprintf(stdout, "Check pointing the restore\n"); if ((fd = fopen(filename, "w")) == NULL) { perror("fopen"); panic("cannot create save file %s for symbol table\n", filename); } clearerr(fd); /* * Assign indicies to each entry * Write out the string entries */ for (i = ROOTINO; i < maxino; i++) { for (ep = lookupino(i); ep != NIL; ep = ep->e_links) { ep->e_index = mynum++; (void) fwrite(ep->e_name, sizeof(char), (int)allocsize(ep->e_namlen), fd); } } /* * Convert pointers to indexes, and output */ tep = &temp; stroff = 0; for (i = ROOTINO; i < maxino; i++) { for (ep = lookupino(i); ep != NIL; ep = ep->e_links) { bcopy((char *)ep, (char *)tep, (long)sizeof(struct entry)); tep->e_name = (char *)stroff; stroff += allocsize(ep->e_namlen); tep->e_parent = (struct entry *)ep->e_parent->e_index; if (ep->e_links != NIL) tep->e_links = (struct entry *)ep->e_links->e_index; if (ep->e_sibling != NIL) tep->e_sibling = (struct entry *)ep->e_sibling->e_index; if (ep->e_entries != NIL) tep->e_entries = (struct entry *)ep->e_entries->e_index; if (ep->e_next != NIL) tep->e_next = (struct entry *)ep->e_next->e_index; (void) fwrite((char *)tep, sizeof(struct entry), 1, fd); } } /* * Convert entry pointers to indexes, and output */ for (i = 0; i < entrytblsize; i++) { if (entry[i] == NIL) tentry = NIL; else tentry = (struct entry *)entry[i]->e_index; (void) fwrite((char *)&tentry, sizeof(struct entry *), 1, fd); } hdr.volno = checkpt; hdr.maxino = maxino; hdr.entrytblsize = entrytblsize; hdr.stringsize = stroff; hdr.dumptime = dumptime; hdr.dumpdate = dumpdate; hdr.ntrec = ntrec; (void) fwrite((char *)&hdr, sizeof(struct symtableheader), 1, fd); if (ferror(fd)) { perror("fwrite"); panic("output error to file %s writing symbol table\n", filename); } (void) fclose(fd); } /* * Initialize a symbol table from a file */ initsymtable(filename) char *filename; { char *base; long tblsize; register struct entry *ep; struct entry *baseep, *lep; struct symtableheader hdr; struct stat stbuf; register long i; int fd; vprintf(stdout, "Initialize symbol table.\n"); if (filename == NULL) { entrytblsize = maxino / HASHFACTOR; entry = (struct entry **) calloc((unsigned)entrytblsize, sizeof(struct entry *)); if (entry == (struct entry **)NIL) panic("no memory for entry table\n"); ep = addentry(".", ROOTINO, NODE); ep->e_flags |= NEW; return; } if ((fd = open(filename, 0)) < 0) { perror("open"); panic("cannot open symbol table file %s\n", filename); } if (fstat(fd, &stbuf) < 0) { perror("stat"); panic("cannot stat symbol table file %s\n", filename); } tblsize = stbuf.st_size - sizeof(struct symtableheader); base = calloc(sizeof(char), (unsigned)tblsize); if (base == NULL) panic("cannot allocate space for symbol table\n"); if (read(fd, base, (int)tblsize) < 0 || read(fd, (char *)&hdr, sizeof(struct symtableheader)) < 0) { perror("read"); panic("cannot read symbol table file %s\n", filename); } switch (command) { case 'r': /* * For normal continuation, insure that we are using * the next incremental tape */ if (hdr.dumpdate != dumptime) { if (hdr.dumpdate < dumptime) fprintf(stderr, "Incremental tape too low\n"); else fprintf(stderr, "Incremental tape too high\n"); done(1); } break; case 'R': /* * For restart, insure that we are using the same tape */ curfile.action = SKIP; dumptime = hdr.dumptime; dumpdate = hdr.dumpdate; if (!bflag) newtapebuf(hdr.ntrec); getvol(hdr.volno); break; default: panic("initsymtable called from command %c\n", command); break; } maxino = hdr.maxino; entrytblsize = hdr.entrytblsize; entry = (struct entry **) (base + tblsize - (entrytblsize * sizeof(struct entry *))); baseep = (struct entry *)(base + hdr.stringsize - sizeof(struct entry)); lep = (struct entry *)entry; for (i = 0; i < entrytblsize; i++) { if (entry[i] == NIL) continue; entry[i] = &baseep[(long)entry[i]]; } for (ep = &baseep[1]; ep < lep; ep++) { ep->e_name = base + (long)ep->e_name; ep->e_parent = &baseep[(long)ep->e_parent]; if (ep->e_sibling != NIL) ep->e_sibling = &baseep[(long)ep->e_sibling]; if (ep->e_links != NIL) ep->e_links = &baseep[(long)ep->e_links]; if (ep->e_entries != NIL) ep->e_entries = &baseep[(long)ep->e_entries]; if (ep->e_next != NIL) ep->e_next = &baseep[(long)ep->e_next]; } }