/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Routines for manipulating tdesc and tdata structures */ #include #include #include #include #include "ctftools.h" #include "memory.h" #include "traverse.h" /* * The layout hash is used during the equivalency checking. We have a node in * the child graph that may be equivalent to a node in the parent graph. To * find the corresponding node (if any) in the parent, we need a quick way to * get to all nodes in the parent that look like the node in the child. Since a * large number of nodes don't have names, we need to incorporate the layout of * the node into the hash. If we don't, we'll end up with the vast majority of * nodes in bucket zero, with one or two nodes in each of the remaining buckets. * * There are a couple of constraints, both of which concern forward * declarations. Recall that a forward declaration tdesc is equivalent to a * tdesc that actually defines the structure or union. As such, we cannot * incorporate anything into the hash for a named struct or union node that * couldn't be found by looking at the forward, and vice versa. */ int tdesc_layouthash(int nbuckets, void *node) { tdesc_t *tdp = node; char *name = NULL; ulong_t h = 0; if (tdp->t_name) name = tdp->t_name; else { switch (tdp->t_type) { case POINTER: case TYPEDEF: case VOLATILE: case CONST: case RESTRICT: name = tdp->t_tdesc->t_name; break; case FUNCTION: h = tdp->t_fndef->fn_nargs + tdp->t_fndef->fn_vargs; name = tdp->t_fndef->fn_ret->t_name; break; case ARRAY: h = tdp->t_ardef->ad_nelems; name = tdp->t_ardef->ad_contents->t_name; break; case STRUCT: case UNION: /* * Unnamed structures, which cannot have forward * declarations pointing to them. We can therefore * incorporate the name of the first member into * the hash value. */ name = tdp->t_members->ml_name; break; case ENUM: /* Use the first element in the hash value */ name = tdp->t_emem->el_name; break; default: /* * Intrinsics, forwards, and typedefs all have * names. */ warning("Unexpected unnamed %d tdesc (ID %d)\n", tdp->t_type, tdp->t_id); } } if (name) return (hash_name(nbuckets, name)); return (h % nbuckets); } int tdesc_layoutcmp(void *arg1, void *arg2) { tdesc_t *tdp1 = arg1, *tdp2 = arg2; if (tdp1->t_name == NULL) { if (tdp2->t_name == NULL) return (0); else return (-1); } else if (tdp2->t_name == NULL) return (1); else return (strcmp(tdp1->t_name, tdp2->t_name)); } int tdesc_idhash(int nbuckets, void *data) { tdesc_t *tdp = data; return (tdp->t_id % nbuckets); } int tdesc_idcmp(void *arg1, void *arg2) { tdesc_t *tdp1 = arg1, *tdp2 = arg2; if (tdp1->t_id == tdp2->t_id) return (0); else return (tdp1->t_id > tdp2->t_id ? 1 : -1); } int tdesc_namehash(int nbuckets, void *data) { tdesc_t *tdp = data; ulong_t h, g; char *c; if (tdp->t_name == NULL) return (0); for (h = 0, c = tdp->t_name; *c; c++) { h = (h << 4) + *c; if ((g = (h & 0xf0000000)) != 0) { h ^= (g >> 24); h ^= g; } } return (h % nbuckets); } int tdesc_namecmp(void *arg1, void *arg2) { tdesc_t *tdp1 = arg1, *tdp2 = arg2; return (!streq(tdp1->t_name, tdp2->t_name)); } /*ARGSUSED1*/ int tdesc_print(void *data, void *private) { tdesc_t *tdp = data; printf("%7d %s\n", tdp->t_id, (tdp->t_name ? tdp->t_name : "(anon)")); return (1); } static void free_intr(tdesc_t *tdp) { free(tdp->t_intr); } static void free_ardef(tdesc_t *tdp) { free(tdp->t_ardef); } static void free_mlist(tdesc_t *tdp) { mlist_t *ml = tdp->t_members; mlist_t *oml; while (ml) { oml = ml; ml = ml->ml_next; if (oml->ml_name) free(oml->ml_name); free(oml); } } static void free_elist(tdesc_t *tdp) { elist_t *el = tdp->t_emem; elist_t *oel; while (el) { oel = el; el = el->el_next; if (oel->el_name) free(oel->el_name); free(oel); } } static void (*free_cbs[])(tdesc_t *) = { NULL, free_intr, NULL, free_ardef, NULL, free_mlist, free_mlist, free_elist, NULL, NULL, NULL, NULL, NULL, NULL }; /*ARGSUSED1*/ static int tdesc_free_cb(tdesc_t *tdp, void *private) { if (tdp->t_name) free(tdp->t_name); if (free_cbs[tdp->t_type]) free_cbs[tdp->t_type](tdp); free(tdp); return (1); } void tdesc_free(tdesc_t *tdp) { (void) tdesc_free_cb(tdp, NULL); } static int tdata_label_cmp(labelent_t *le1, labelent_t *le2) { return (le1->le_idx - le2->le_idx); } void tdata_label_add(tdata_t *td, char *label, int idx) { labelent_t *le = xmalloc(sizeof (*le)); le->le_name = xstrdup(label); le->le_idx = (idx == -1 ? td->td_nextid - 1 : idx); slist_add(&td->td_labels, le, (int (*)())tdata_label_cmp); } static int tdata_label_top_cb(void *data, void *arg) { labelent_t *le = data; labelent_t **topp = arg; *topp = le; return (1); } labelent_t * tdata_label_top(tdata_t *td) { labelent_t *top = NULL; (void) list_iter(td->td_labels, tdata_label_top_cb, &top); return (top); } static int tdata_label_find_cb(labelent_t *le, labelent_t *tmpl) { return (streq(le->le_name, tmpl->le_name)); } int tdata_label_find(tdata_t *td, char *label) { labelent_t let; labelent_t *ret; if (streq(label, "BASE")) { ret = (labelent_t *)list_first(td->td_labels); return (ret ? ret->le_idx : -1); } let.le_name = label; if (!(ret = (labelent_t *)list_find(td->td_labels, &let, (int (*)())tdata_label_find_cb))) return (-1); return (ret->le_idx); } static int tdata_label_newmax_cb(void *data, void *arg) { labelent_t *le = data; int *newmaxp = arg; if (le->le_idx > *newmaxp) { le->le_idx = *newmaxp; return (1); } return (0); } void tdata_label_newmax(tdata_t *td, int newmax) { (void) list_iter(td->td_labels, tdata_label_newmax_cb, &newmax); } /*ARGSUSED1*/ static void tdata_label_free_cb(labelent_t *le, void *private) { if (le->le_name) free(le->le_name); free(le); } void tdata_label_free(tdata_t *td) { list_free(td->td_labels, (void (*)())tdata_label_free_cb, NULL); td->td_labels = NULL; } tdata_t * tdata_new(void) { tdata_t *new = xcalloc(sizeof (tdata_t)); new->td_layouthash = hash_new(TDATA_LAYOUT_HASH_SIZE, tdesc_layouthash, tdesc_layoutcmp); new->td_idhash = hash_new(TDATA_ID_HASH_SIZE, tdesc_idhash, tdesc_idcmp); /* * This is also traversed as a list, but amortized O(1) * lookup massively impacts part of the merge phase, so * we store the iidescs as a hash. */ new->td_iihash = hash_new(IIDESC_HASH_SIZE, iidesc_hash, NULL); new->td_nextid = 1; new->td_curvgen = 1; pthread_mutex_init(&new->td_mergelock, NULL); return (new); } void tdata_free(tdata_t *td) { hash_free(td->td_iihash, (void (*)())iidesc_free, NULL); hash_free(td->td_layouthash, (void (*)())tdesc_free_cb, NULL); hash_free(td->td_idhash, NULL, NULL); list_free(td->td_fwdlist, NULL, NULL); tdata_label_free(td); free(td->td_parlabel); free(td->td_parname); pthread_mutex_destroy(&td->td_mergelock); free(td); } /*ARGSUSED1*/ static int build_hashes(tdesc_t *ctdp, tdesc_t **ctdpp, void *private) { tdata_t *td = private; hash_add(td->td_idhash, ctdp); hash_add(td->td_layouthash, ctdp); return (1); } static tdtrav_cb_f build_hashes_cbs[] = { NULL, build_hashes, /* intrinsic */ build_hashes, /* pointer */ build_hashes, /* array */ build_hashes, /* function */ build_hashes, /* struct */ build_hashes, /* union */ build_hashes, /* enum */ build_hashes, /* forward */ build_hashes, /* typedef */ tdtrav_assert, /* typedef_unres */ build_hashes, /* volatile */ build_hashes, /* const */ build_hashes /* restrict */ }; static void tdata_build_hashes_common(tdata_t *td, hash_t *hash) { (void) iitraverse_hash(hash, &td->td_curvgen, NULL, NULL, build_hashes_cbs, td); } void tdata_build_hashes(tdata_t *td) { tdata_build_hashes_common(td, td->td_iihash); } /* Merge td2 into td1. td2 is destroyed by the merge */ void tdata_merge(tdata_t *td1, tdata_t *td2) { td1->td_curemark = MAX(td1->td_curemark, td2->td_curemark); td1->td_curvgen = MAX(td1->td_curvgen, td2->td_curvgen); td1->td_nextid = MAX(td1->td_nextid, td2->td_nextid); hash_merge(td1->td_iihash, td2->td_iihash); /* Add td2's type tree to the hashes */ tdata_build_hashes_common(td1, td2->td_iihash); list_concat(&td1->td_fwdlist, td2->td_fwdlist); td2->td_fwdlist = NULL; slist_merge(&td1->td_labels, td2->td_labels, (int (*)())tdata_label_cmp); td2->td_labels = NULL; /* free the td2 hashes (data is now part of td1) */ hash_free(td2->td_layouthash, NULL, NULL); td2->td_layouthash = NULL; hash_free(td2->td_iihash, NULL, NULL); td2->td_iihash = NULL; tdata_free(td2); }