/* $OpenBSD: pack.c,v 1.11 2002/03/14 16:44:24 mpech Exp $ */ /* $NetBSD: pack.c,v 1.5 1996/08/31 21:15:11 mycroft Exp $ */ /* * Copyright (c) 1992, 1993 * The Regents of the University of California. All rights reserved. * * This software was developed by the Computer Systems Engineering group * at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and * contributed to Berkeley. * * All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Lawrence Berkeley Laboratories. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)pack.c 8.1 (Berkeley) 6/6/93 */ #include #include #include #include "config.h" /* * Packing. We have three separate kinds of packing here. * * First, we pack device instances, to collapse things like * * uba0 at sbi0 nexus ? * uba0 at bi0 nexus ? * * into a single instance that is "at sbi0 or bi0". * * Second, we pack locators. Given something like * * hp0 at mba0 drive 0 * hp* at mba* drive ? * ht0 at mba0 drive 0 * tu0 at ht0 slave 0 * ht* at mba* drive ? * tu* at ht* slave ? * * (where the default drive and slave numbers are -1), we have three * locators whose value is 0 and three whose value is -1. Rather than * emitting six integers, we emit just two. * * Finally, we pack parent vectors. This is very much like packing * locators. Unlike locators, however, parent vectors are always * terminated by -1 (rather like the way C strings always end with * a NUL). * * When packing locators, we would like to find sequences such as * {1 2 3} {2 3 4} {3} {4 5} * and turn this into the flat sequence {1 2 3 4 5}, with each subsequence * given by the appropriate offset (here 0, 1, 2, and 3 respectively). * When we pack parent vectors, overlap of this sort is impossible. * Non-overlapping packing is much easier, and so we use that here * and miss out on the chance to squeeze the locator sequence optimally. * (So it goes.) */ typedef int (*vec_cmp_func)(const void *, int, int); #define TAILHSIZE 128 #define PVHASH(i) ((i) & (TAILHSIZE - 1)) #define LOCHASH(l) (((long)(l) >> 2) & (TAILHSIZE - 1)) struct tails { struct tails *t_next; int t_ends_at; }; static struct tails *tails[TAILHSIZE]; static int locspace; static int pvecspace; static int longest_pvec; static void packdevi(void); static void packlocs(void); static void packpvec(void); static void addparents(struct devi *src, struct devi *dst); static int nparents(struct devi **, struct devbase *, int); static int sameas(struct devi *, struct devi *); static int findvec(const void *, int, int, vec_cmp_func, int); static int samelocs(const void *, int, int); static int addlocs(const char **, int); static int loclencmp(const void *, const void *); static int samepv(const void *, int, int); static int addpv(short *, int); static int pvlencmp(const void *, const void *); static void resettails(void); void pack() { struct devi *i; int n; /* Pack instances and make parent vectors. */ packdevi(); /* * Now that we know what we have, find upper limits on space * needed for the loc[] and pv[] tables, and find the longest * single pvec. The loc and pv table sizes are bounded by * what we would get if no packing occurred. */ locspace = pvecspace = 0; for (i = alldevi; i != NULL; i = i->i_next) { if (i->i_collapsed) continue; locspace += i->i_atattr->a_loclen; n = i->i_pvlen + 1; if (n > longest_pvec) longest_pvec = n; pvecspace += n; } /* Allocate and pack loc[]. */ locators.vec = emalloc(locspace * sizeof(*locators.vec)); locators.used = 0; packlocs(); /* Allocate and pack pv[]. */ parents.vec = emalloc(pvecspace * sizeof(*parents.vec)); parents.used = 0; packpvec(); } /* * Pack instances together wherever possible. When everything is * packed, go back and set up the parents for each. We must do this * on a second pass because during the first one, we do not know which, * if any, of the parents will collapse during packing. */ void packdevi() { struct devi *i, *l, *p; struct deva *d; int j, m, n; packed = emalloc((ndevi + 1) * sizeof *packed); n = 0; for (d = alldevas; d != NULL; d = d->d_next) { /* * For each instance of each attachment, add or collapse * all its aliases. */ for (i = d->d_ihead; i != NULL; i = i->i_asame) { m = n; for (l = i; l != NULL; l = l->i_alias) { /* Skip if we already handled this one. */ if (l->i_cfindex >= 0) continue; l->i_pvlen = 0; l->i_pvoff = -1; l->i_locoff = -1; /* try to find an equivalent for l */ for (j = m; j < n; j++) { p = packed[j]; if (sameas(l, p)) { l->i_collapsed = 1; l->i_cfindex = p->i_cfindex; goto nextalias; } } /* could not find a suitable alias */ l->i_collapsed = 0; l->i_cfindex = n; l->i_parents = emalloc(sizeof(*l->i_parents)); l->i_parents[0] = NULL; packed[n++] = l; nextalias:; } } } npacked = n; packed[n] = NULL; for (i = alldevi; i != NULL; i = i->i_next) addparents(i, packed[i->i_cfindex]); } /* * Return true if two aliases are "the same". In this case, they need * to attach via the same attribute, have the same config flags, and * have the same locators. */ static int sameas(i1, i2) struct devi *i1, *i2; { const char **p1, **p2; if (i1->i_atattr != i2->i_atattr) return (0); if (i1->i_cfflags != i2->i_cfflags) return (0); for (p1 = i1->i_locs, p2 = i2->i_locs; *p1 == *p2; p2++) if (*p1++ == 0) return (1); return 0; } /* * Add the parents associated with "src" to the (presumably uncollapsed) * instance "dst". */ static void addparents(src, dst) struct devi *src, *dst; { struct nvlist *nv; struct devi *i, **p, **q; int j, n, old, new, ndup; if (dst->i_collapsed) panic("addparents() i_collapsed"); /* Collect up list of parents to add. */ if (src->i_at == NULL) /* none, 'cuz "at root" */ return; if (src->i_atdev != NULL) { n = nparents(NULL, src->i_atdev, src->i_atunit); p = emalloc(n * sizeof *p); if (n == 0) return; (void)nparents(p, src->i_atdev, src->i_atunit); } else { n = 0; for (nv = src->i_atattr->a_refs; nv != NULL; nv = nv->nv_next) n += nparents(NULL, nv->nv_ptr, src->i_atunit); if (n == 0) return; p = emalloc(n * sizeof *p); n = 0; for (nv = src->i_atattr->a_refs; nv != NULL; nv = nv->nv_next) n += nparents(p + n, nv->nv_ptr, src->i_atunit); } /* Now elide duplicates. */ ndup = 0; for (j = 0; j < n; j++) { i = p[j]; for (q = dst->i_parents; *q != NULL; q++) { if (*q == i) { ndup++; p[j] = NULL; break; } } } /* Finally, add all the non-duplicates. */ old = dst->i_pvlen; new = old + (n - ndup); if (old > new) panic("addparents() old > new"); if (old == new) { free(p); return; } dst->i_parents = q = erealloc(dst->i_parents, (new + 1) * sizeof(*q)); dst->i_pvlen = new; q[new] = NULL; q += old; for (j = 0; j < n; j++) if (p[j] != NULL) *q++ = p[j]; free(p); } /* * Count up parents, and optionally store pointers to each. */ static int nparents(p, dev, unit) struct devi **p; struct devbase *dev; int unit; { struct devi *i, *l; int n; n = 0; /* for each instance ... */ for (i = dev->d_ihead; i != NULL; i = i->i_bsame) { /* ... take each un-collapsed alias */ for (l = i; l != NULL; l = l->i_alias) { if (!l->i_collapsed && (unit == WILD || unit == l->i_unit)) { if (p != NULL) *p++ = l; n++; } } } return (n); } static void packlocs() { struct devi **p, *i; int l, o; qsort(packed, npacked, sizeof *packed, loclencmp); for (p = packed; (i = *p) != NULL; p++) { if ((l = i->i_atattr->a_loclen) > 0) { o = findvec(i->i_locs, LOCHASH(i->i_locs[l - 1]), l, samelocs, locators.used); i->i_locoff = o < 0 ? addlocs(i->i_locs, l) : o; } else i->i_locoff = -1; } resettails(); } static void packpvec() { struct devi **p, *i, **par; int l, v, o; short *vec; vec = emalloc(longest_pvec * sizeof(*vec)); qsort(packed, npacked, sizeof *packed, pvlencmp); for (p = packed; (i = *p) != NULL; p++) { l = i->i_pvlen; if (l > longest_pvec) panic("packpvec"); par = i->i_parents; for (v = 0; v < l; v++) vec[v] = par[v]->i_cfindex; if (l == 0 || (o = findvec(vec, PVHASH(vec[l - 1]), l, samepv, parents.used)) < 0) o = addpv(vec, l); i->i_pvoff = o; } free(vec); resettails(); } /* * Return the index at which the given vector already exists, or -1 * if it is not anywhere in the current set. If we return -1, we assume * our caller will add it at the end of the current set, and we make * sure that next time, we will find it there. */ static int findvec(ptr, hash, len, cmp, nextplace) const void *ptr; int hash, len; vec_cmp_func cmp; int nextplace; { struct tails *t, **hp; int off; hp = &tails[hash]; for (t = *hp; t != NULL; t = t->t_next) { off = t->t_ends_at - len; if (off >= 0 && (*cmp)(ptr, off, len)) return (off); } t = emalloc(sizeof(*t)); t->t_next = *hp; *hp = t; t->t_ends_at = nextplace + len; return (-1); } /* * Comparison function for locators. */ static int samelocs(ptr, off, len) const void *ptr; int off; int len; { const char **p, **q; for (p = &locators.vec[off], q = (const char **)ptr; --len >= 0;) if (*p++ != *q++) return (0); /* different */ return (1); /* same */ } /* * Add the given locators at the end of the global loc[] table. */ static int addlocs(locs, len) const char **locs; int len; { const char **p; int ret; ret = locators.used; if ((locators.used = ret + len) > locspace) panic("addlocs: overrun"); for (p = &locators.vec[ret]; --len >= 0;) *p++ = *locs++; return (ret); } /* * Comparison function for qsort-by-locator-length, longest first. * We rashly assume that subtraction of these lengths does not overflow. */ static int loclencmp(a, b) const void *a, *b; { int l1, l2; l1 = (*(struct devi **)a)->i_atattr->a_loclen; l2 = (*(struct devi **)b)->i_atattr->a_loclen; return (l2 - l1); } /* * Comparison function for parent vectors. */ static int samepv(ptr, off, len) const void *ptr; int off; int len; { short *p, *q; for (p = &parents.vec[off], q = (short *)ptr; --len >= 0;) if (*p++ != *q++) return (0); /* different */ return (1); /* same */ } /* * Add the given parent vectors at the end of the global pv[] table. */ static int addpv(pv, len) short *pv; int len; { short *p; int ret; static int firstend = -1; /* * If the vector is empty, reuse the first -1. It will be * there if there are any nonempty vectors at all, since we * do the longest first. If there are no nonempty vectors, * something is probably wrong, but we will ignore that here. */ if (len == 0 && firstend >= 0) return (firstend); len++; /* account for trailing -1 */ ret = parents.used; if ((parents.used = ret + len) > pvecspace) panic("addpv: overrun"); for (p = &parents.vec[ret]; --len > 0;) *p++ = *pv++; *p = -1; if (firstend < 0) firstend = parents.used - 1; return (ret); } /* * Comparison function for qsort-by-parent-vector-length, longest first. * We rashly assume that subtraction of these lengths does not overflow. */ static int pvlencmp(a, b) const void *a, *b; { int l1, l2; l1 = (*(struct devi **)a)->i_pvlen; l2 = (*(struct devi **)b)->i_pvlen; return (l2 - l1); } static void resettails() { struct tails **p, *t, *next; int i; for (p = tails, i = TAILHSIZE; --i >= 0; p++) { for (t = *p; t != NULL; t = next) { next = t->t_next; free(t); } *p = NULL; } }