/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (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 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. * * eval.c -- constraint evaluation module * * this module evaluates constraints. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include "alloc.h" #include "out.h" #include "stable.h" #include "literals.h" #include "lut.h" #include "tree.h" #include "ptree.h" #include "itree.h" #include "ipath.h" #include "eval.h" #include "config.h" #include "platform.h" #include "fme.h" #include "stats.h" static struct node *eval_dup(struct node *np, struct lut *ex, struct node *epnames[]); static int check_expr_args(struct evalue *lp, struct evalue *rp, enum datatype dtype, struct node *np); /* * begins_with -- return true if rhs path begins with everything in lhs path */ static int begins_with(struct node *lhs, struct node *rhs) { int lnum; int rnum; if (lhs == NULL) return (1); /* yep -- it all matched */ if (rhs == NULL) return (0); /* nope, ran out of rhs first */ ASSERTeq(lhs->t, T_NAME, ptree_nodetype2str); ASSERTeq(rhs->t, T_NAME, ptree_nodetype2str); if (lhs->u.name.s != rhs->u.name.s) return (0); /* nope, different component names */ if (lhs->u.name.child && lhs->u.name.child->t == T_NUM) lnum = (int)lhs->u.name.child->u.ull; else out(O_DIE, "begins_with: unexpected lhs child"); if (rhs->u.name.child && rhs->u.name.child->t == T_NUM) rnum = (int)rhs->u.name.child->u.ull; else out(O_DIE, "begins_with: unexpected rhs child"); if (lnum != rnum) return (0); /* nope, instance numbers were different */ return (begins_with(lhs->u.name.next, rhs->u.name.next)); } /* * evaluate a variety of functions and place result in valuep. return 1 if * function evaluation was successful; 0 if otherwise (e.g., the case of an * invalid argument to the function) */ /*ARGSUSED*/ static int eval_func(struct node *funcnp, struct lut *ex, struct node *epnames[], struct node *np, struct lut **globals, struct config *croot, struct arrow *arrowp, int try, struct evalue *valuep) { const char *funcname = funcnp->u.func.s; if (funcname == L_within) { /* within()'s are not really constraints -- always true */ valuep->t = UINT64; valuep->v = 1; return (1); } else if (funcname == L_is_under) { struct node *lhs; struct node *rhs; if (np->u.expr.left->t == T_NAME) lhs = np->u.expr.left; else if (np->u.expr.left->u.func.s == L_fru) lhs = eval_fru(np->u.expr.left->u.func.arglist); else if (np->u.expr.left->u.func.s == L_asru) lhs = eval_asru(np->u.expr.left->u.func.arglist); else out(O_DIE, "is_under: unexpected lhs type: %s", ptree_nodetype2str(np->u.expr.left->t)); if (np->u.expr.right->t == T_NAME) rhs = np->u.expr.right; else if (np->u.expr.right->u.func.s == L_fru) rhs = eval_fru(np->u.expr.right->u.func.arglist); else if (np->u.expr.right->u.func.s == L_asru) rhs = eval_asru(np->u.expr.right->u.func.arglist); else out(O_DIE, "is_under: unexpected rhs type: %s", ptree_nodetype2str(np->u.expr.right->t)); /* eval_dup will expand wildcards, iterators, etc... */ lhs = eval_dup(lhs, ex, epnames); rhs = eval_dup(rhs, ex, epnames); valuep->t = UINT64; valuep->v = begins_with(lhs, rhs); out(O_ALTFP|O_VERB2|O_NONL, "eval_func:is_under("); ptree_name_iter(O_ALTFP|O_VERB2|O_NONL, lhs); out(O_ALTFP|O_VERB2|O_NONL, ","); ptree_name_iter(O_ALTFP|O_VERB2|O_NONL, rhs); out(O_ALTFP|O_VERB2, ") returned %d", (int)valuep->v); tree_free(lhs); tree_free(rhs); return (1); } if (try) return (0); if (funcname == L_fru) { valuep->t = NODEPTR; valuep->v = (uintptr_t)eval_fru(np); return (1); } else if (funcname == L_asru) { valuep->t = NODEPTR; valuep->v = (uintptr_t)eval_asru(np); return (1); } else if (funcname == L_defined) { ASSERTeq(np->t, T_GLOBID, ptree_nodetype2str); valuep->t = UINT64; valuep->v = (lut_lookup(*globals, (void *)np->u.globid.s, NULL) != NULL); return (1); } else if (funcname == L_call) { return (! platform_call(np, globals, croot, arrowp, valuep)); } else if (funcname == L_is_connected) { return (! config_is_connected(np, croot, valuep)); } else if (funcname == L_is_on) { return (! config_is_on(np, croot, valuep)); } else if (funcname == L_is_present) { return (! config_is_present(np, croot, valuep)); } else if (funcname == L_is_type) { return (! config_is_type(np, croot, valuep)); } else if (funcname == L_confprop) { return (! config_confprop(np, croot, valuep)); } else if (funcname == L_envprop) { outfl(O_DIE, np->file, np->line, "eval_func: %s not yet supported", funcname); } else if (funcname == L_payloadprop) { outfl(O_ALTFP|O_VERB2|O_NONL, np->file, np->line, "payloadprop(\"%s\") ", np->u.quote.s); if (platform_payloadprop(np, valuep)) { /* platform_payloadprop() returned false */ out(O_ALTFP|O_VERB2, "not found."); return (0); } else { switch (valuep->t) { case UINT64: case NODEPTR: out(O_ALTFP|O_VERB2, "found: %llu", valuep->v); break; case STRING: out(O_ALTFP|O_VERB2, "found: \"%s\"", (char *)(uintptr_t)valuep->v); break; default: out(O_ALTFP|O_VERB2, "found: undefined"); break; } return (1); } } else if (funcname == L_setpayloadprop) { struct evalue *payloadvalp; ASSERTinfo(np->t == T_LIST, ptree_nodetype2str(np->t)); ASSERTinfo(np->u.expr.left->t == T_QUOTE, ptree_nodetype2str(np->u.expr.left->t)); outfl(O_ALTFP|O_VERB2|O_NONL, np->file, np->line, "setpayloadprop: %s: %s=", arrowp->tail->myevent->enode->u.event.ename->u.name.s, np->u.expr.left->u.quote.s); ptree_name_iter(O_ALTFP|O_VERB2|O_NONL, np->u.expr.right); /* * allocate a struct evalue to hold the payload property's * value, unless we've been here already, in which case we * might calculate a different value, but we'll store it * in the already-allocated struct evalue. */ if ((payloadvalp = (struct evalue *)lut_lookup( arrowp->tail->myevent->payloadprops, (void *)np->u.expr.left->u.quote.s, NULL)) == NULL) { payloadvalp = MALLOC(sizeof (*payloadvalp)); } if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, payloadvalp)) { out(O_ALTFP|O_VERB2, " (cannot eval, using zero)"); payloadvalp->t = UINT64; payloadvalp->v = 0; } else { if (payloadvalp->t == UINT64) out(O_ALTFP|O_VERB2, " (%llu)", payloadvalp->v); else out(O_ALTFP|O_VERB2, " (\"%s\")", (char *)(uintptr_t)payloadvalp->v); } /* add to table of payload properties for current problem */ arrowp->tail->myevent->payloadprops = lut_add(arrowp->tail->myevent->payloadprops, (void *)np->u.expr.left->u.quote.s, (void *)payloadvalp, NULL); /* function is always true */ valuep->t = UINT64; valuep->v = 1; return (1); } else if (funcname == L_payloadprop_defined) { outfl(O_ALTFP|O_VERB2|O_NONL, np->file, np->line, "payloadprop_defined(\"%s\") ", np->u.quote.s); if (platform_payloadprop(np, NULL)) { /* platform_payloadprop() returned false */ valuep->v = 0; out(O_ALTFP|O_VERB2, "not found."); } else { valuep->v = 1; out(O_ALTFP|O_VERB2, "found."); } valuep->t = UINT64; return (1); } else if (funcname == L_payloadprop_contains) { int nvals; struct evalue *vals; struct evalue cmpval; ASSERTinfo(np->t == T_LIST, ptree_nodetype2str(np->t)); ASSERTinfo(np->u.expr.left->t == T_QUOTE, ptree_nodetype2str(np->u.expr.left->t)); outfl(O_ALTFP|O_VERB2|O_NONL, np->file, np->line, "payloadprop_contains(\"%s\", ", np->u.expr.left->u.quote.s); ptree_name_iter(O_ALTFP|O_VERB2|O_NONL, np->u.expr.right); outfl(O_ALTFP|O_VERB2|O_NONL, np->file, np->line, ") "); /* evaluate the expression we're comparing against */ if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &cmpval)) { out(O_ALTFP|O_VERB2|O_NONL, "(cannot eval, using zero) "); cmpval.t = UINT64; cmpval.v = 0; } else { if (cmpval.t == UINT64) out(O_ALTFP|O_VERB2, "(%llu) ", cmpval.v); else out(O_ALTFP|O_VERB2, "(\"%s\") ", (char *)(uintptr_t)cmpval.v); } /* get the payload values and check for a match */ vals = platform_payloadprop_values(np->u.expr.left->u.quote.s, &nvals); valuep->t = UINT64; valuep->v = 0; if (nvals == 0) { out(O_ALTFP|O_VERB2, "not found."); } else { struct evalue preval; int i; out(O_ALTFP|O_VERB2|O_NONL, "found %d values ", nvals); for (i = 0; i < nvals; i++) { preval.t = vals[i].t; preval.v = vals[i].v; if (check_expr_args(&vals[i], &cmpval, UNDEFINED, np)) continue; /* * If we auto-converted the value to a * string, we need to free the * original tree value. */ if (preval.t == NODEPTR && ((struct node *)(uintptr_t)(preval.v))->t == T_NAME) { tree_free((struct node *)(uintptr_t) preval.v); } if (vals[i].v == cmpval.v) { valuep->v = 1; break; } } if (valuep->v) out(O_ALTFP|O_VERB2, "match."); else out(O_ALTFP|O_VERB2, "no match."); for (i = 0; i < nvals; i++) { if (vals[i].t == NODEPTR) { tree_free((struct node *)(uintptr_t) vals[i].v); break; } } FREE(vals); } return (1); } else if (funcname == L_confcall) { return (!platform_confcall(np, globals, croot, arrowp, valuep)); } else if (funcname == L_count) { struct stats *statp; struct istat_entry ent; ASSERTinfo(np->t == T_EVENT, ptree_nodetype2str(np->t)); ent.ename = np->u.event.ename->u.name.s; ent.ipath = ipath(np->u.event.epname); valuep->t = UINT64; if ((statp = (struct stats *) lut_lookup(Istats, &ent, (lut_cmp)istat_cmp)) == NULL) valuep->v = 0; else valuep->v = stats_counter_value(statp); return (1); } else outfl(O_DIE, np->file, np->line, "eval_func: unexpected func: %s", funcname); /*NOTREACHED*/ return (0); } static struct node * eval_wildcardedname(struct node *np, struct lut *ex, struct node *epnames[]) { struct node *npstart, *npend, *npref, *newnp; struct node *np1, *np2, *retp; int i; if (epnames == NULL || epnames[0] == NULL) return (NULL); for (i = 0; epnames[i] != NULL; i++) { if (tree_namecmp(np, epnames[i]) == 0) return (NULL); } /* * get to this point if np does not match any of the entries in * epnames. check if np is a path that must preceded by a wildcard * portion. for this case we must first determine which epnames[] * entry should be used for wildcarding. */ npstart = NULL; for (i = 0; epnames[i] != NULL; i++) { for (npref = epnames[i]; npref; npref = npref->u.name.next) { if (npref->u.name.s == np->u.name.s) { for (np1 = npref, np2 = np; np1 != NULL && np2 != NULL; np1 = np1->u.name.next, np2 = np2->u.name.next) { if (np1->u.name.s != np2->u.name.s) break; } if (np2 == NULL) { npstart = epnames[i]; npend = npref; if (np1 == NULL) break; } } } if (npstart != NULL) break; } if (npstart == NULL) { /* no match; np is not a path to be wildcarded */ return (NULL); } /* * dup (npstart -- npend) which is the wildcarded portion. all * children should be T_NUMs. */ retp = NULL; for (npref = npstart; ! (npref == NULL || npref == npend); npref = npref->u.name.next) { newnp = newnode(T_NAME, np->file, np->line); newnp->u.name.t = npref->u.name.t; newnp->u.name.s = npref->u.name.s; newnp->u.name.last = newnp; newnp->u.name.it = npref->u.name.it; newnp->u.name.cp = npref->u.name.cp; ASSERT(npref->u.name.child != NULL); ASSERT(npref->u.name.child->t == T_NUM); newnp->u.name.child = newnode(T_NUM, np->file, np->line); newnp->u.name.child->u.ull = npref->u.name.child->u.ull; if (retp == NULL) { retp = newnp; } else { retp->u.name.last->u.name.next = newnp; retp->u.name.last = newnp; } } ASSERT(retp != NULL); /* now append the nonwildcarded portion */ retp = tree_name_append(retp, eval_dup(np, ex, NULL)); return (retp); } static struct node * eval_dup(struct node *np, struct lut *ex, struct node *epnames[]) { struct node *newnp; if (np == NULL) return (NULL); switch (np->t) { case T_GLOBID: return (tree_globid(np->u.globid.s, np->file, np->line)); case T_ASSIGN: case T_CONDIF: case T_CONDELSE: case T_NE: case T_EQ: case T_LT: case T_LE: case T_GT: case T_GE: case T_BITAND: case T_BITOR: case T_BITXOR: case T_BITNOT: case T_LSHIFT: case T_RSHIFT: case T_LIST: case T_AND: case T_OR: case T_NOT: case T_ADD: case T_SUB: case T_MUL: case T_DIV: case T_MOD: return (tree_expr(np->t, eval_dup(np->u.expr.left, ex, epnames), eval_dup(np->u.expr.right, ex, epnames))); case T_NAME: { struct iterinfo *iterinfop; struct node *newchild = NULL; iterinfop = lut_lookup(ex, (void *)np->u.name.s, NULL); if (iterinfop != NULL) { /* explicit iterator; not part of pathname */ newnp = newnode(T_NUM, np->file, np->line); newnp->u.ull = iterinfop->num; return (newnp); } /* see if np is a path with wildcard portion */ newnp = eval_wildcardedname(np, ex, epnames); if (newnp != NULL) return (newnp); /* turn off wildcarding for child */ newchild = eval_dup(np->u.name.child, ex, NULL); if (newchild != NULL) { if (newchild->t != T_NUM) { /* * not a number, eh? we must resolve this * to a number. */ struct evalue value; if (eval_expr(newchild, ex, epnames, NULL, NULL, NULL, 1, &value) == 0 || value.t != UINT64) { outfl(O_DIE, np->file, np->line, "eval_dup: could not resolve " "iterator of %s", np->u.name.s); } tree_free(newchild); newchild = newnode(T_NUM, np->file, np->line); newchild->u.ull = value.v; } newnp = newnode(np->t, np->file, np->line); newnp->u.name.s = np->u.name.s; newnp->u.name.it = np->u.name.it; newnp->u.name.cp = np->u.name.cp; newnp->u.name.last = newnp; newnp->u.name.child = newchild; if (np->u.name.next != NULL) { /* turn off wildcarding for next */ return (tree_name_append(newnp, eval_dup(np->u.name.next, ex, NULL))); } else { return (newnp); } } else { outfl(O_DIE, np->file, np->line, "eval_dup: internal error: \"%s\" is neither " "an iterator nor a pathname", np->u.name.s); } /*NOTREACHED*/ break; } case T_EVENT: newnp = newnode(T_NAME, np->file, np->line); newnp->u.name.t = np->u.event.ename->u.name.t; newnp->u.name.s = np->u.event.ename->u.name.s; newnp->u.name.it = np->u.event.ename->u.name.it; newnp->u.name.last = newnp; return (tree_event(newnp, eval_dup(np->u.event.epname, ex, epnames), eval_dup(np->u.event.eexprlist, ex, epnames))); case T_FUNC: return (tree_func(np->u.func.s, eval_dup(np->u.func.arglist, ex, epnames), np->file, np->line)); case T_QUOTE: newnp = newnode(T_QUOTE, np->file, np->line); newnp->u.quote.s = np->u.quote.s; return (newnp); case T_NUM: newnp = newnode(T_NUM, np->file, np->line); newnp->u.ull = np->u.ull; return (newnp); default: outfl(O_DIE, np->file, np->line, "eval_dup: unexpected node type: %s", ptree_nodetype2str(np->t)); } /*NOTREACHED*/ return (0); } /* * eval_potential -- see if constraint is potentially true * * this function is used at instance tree creation time to see if * any constraints are already known to be false. if this function * returns false, then the constraint will always be false and there's * no need to include the propagation arrow in the instance tree. * * if this routine returns true, either the constraint is known to * be always true (so there's no point in attaching the constraint * to the propagation arrow in the instance tree), or the constraint * contains "deferred" expressions like global variables or poller calls * and so it must be evaluated during calls to fme_eval(). in this last * case, where a constraint needs to be attached to the propagation arrow * in the instance tree, this routine returns a newly created constraint * in *newc where all the non-deferred things have been filled in. * * so in summary: * * return of false: constraint can never be true, *newc will be NULL. * * return of true with *newc unchanged: constraint will always be true. * * return of true with *newc changed: use new constraint in *newc. * * the lookup table for all explicit iterators, ex, is passed in. * * *newc can either be NULL on entry, or if can contain constraints from * previous calls to eval_potential() (i.e. for building up an instance * tree constraint from several potential constraints). if *newc already * contains constraints, anything added to it will be joined by adding * a T_AND node at the top of *newc. */ int eval_potential(struct node *np, struct lut *ex, struct node *epnames[], struct node **newc) { struct node *newnp; struct evalue value; if (eval_expr(np, ex, epnames, NULL, NULL, NULL, 1, &value) == 0) { /* * couldn't eval expression because * it contains deferred items. make * a duplicate expression with all the * non-deferred items expanded. */ newnp = eval_dup(np, ex, epnames); if (*newc == NULL) { /* * constraint is potentially true if deferred * expression in newnp is true. *newc was NULL * so new constraint is just the one in newnp. */ *newc = newnp; return (1); } else { /* * constraint is potentially true if deferred * expression in newnp is true. *newc already * contained a constraint so add an AND with the * constraint in newnp. */ *newc = tree_expr(T_AND, *newc, newnp); return (1); } } else if (value.t == UNDEFINED) { /* constraint can never be true */ return (0); } else if (value.t == UINT64 && value.v == 0) { /* constraint can never be true */ return (0); } else { /* constraint is always true (nothing deferred to eval) */ return (1); } } static int check_expr_args(struct evalue *lp, struct evalue *rp, enum datatype dtype, struct node *np) { /* auto-convert T_NAMES to strings */ if (lp->t == NODEPTR && ((struct node *)(uintptr_t)(lp->v))->t == T_NAME) { char *s = ipath2str(NULL, ipath((struct node *)(uintptr_t)lp->v)); lp->t = STRING; lp->v = (uintptr_t)stable(s); FREE(s); out(O_ALTFP|O_VERB2, "convert lhs path to \"%s\"", (char *)(uintptr_t)lp->v); } if (rp != NULL && rp->t == NODEPTR && ((struct node *)(uintptr_t)(rp->v))->t == T_NAME) { char *s = ipath2str(NULL, ipath((struct node *)(uintptr_t)rp->v)); rp->t = STRING; rp->v = (uintptr_t)stable(s); FREE(s); out(O_ALTFP|O_VERB2, "convert rhs path to \"%s\"", (char *)(uintptr_t)rp->v); } /* auto-convert strings to numbers */ if (dtype == UINT64) { if (lp->t == STRING) { lp->t = UINT64; lp->v = strtoull((char *)(uintptr_t)lp->v, NULL, 0); } if (rp != NULL && rp->t == STRING) { rp->t = UINT64; rp->v = strtoull((char *)(uintptr_t)rp->v, NULL, 0); } } if (dtype != UNDEFINED && lp->t != dtype) { outfl(O_OK, np->file, np->line, "invalid datatype of argument for operation %s", ptree_nodetype2str(np->t)); return (1); } if (rp != NULL && lp->t != rp->t) { outfl(O_OK, np->file, np->line, "mismatch in datatype of arguments for operation %s", ptree_nodetype2str(np->t)); return (1); } return (0); } /* * eval_expr -- evaluate expression into *valuep * * the meaning of the return value depends on the input value of try. * * for try == 1: if any deferred items are encounted, bail out and return * false. returns true if we made it through entire expression without * hitting any deferred items. * * for try == 0: return true if all operations were performed successfully. * return false if otherwise. for example, any of the following conditions * will result in a false return value: * - attempted use of an uninitialized global variable * - failure in function evaluation * - illegal arithmetic operation (argument out of range) */ int eval_expr(struct node *np, struct lut *ex, struct node *epnames[], struct lut **globals, struct config *croot, struct arrow *arrowp, int try, struct evalue *valuep) { struct evalue *gval; struct evalue lval; struct evalue rval; if (np == NULL) { valuep->t = UINT64; valuep->v = 1; /* no constraint means "true" */ return (1); } valuep->t = UNDEFINED; switch (np->t) { case T_GLOBID: if (try) return (0); /* * only handle case of getting (and not setting) the value * of a global variable */ gval = lut_lookup(*globals, (void *)np->u.globid.s, NULL); if (gval == NULL) { valuep->t = UNDEFINED; return (0); } else { valuep->t = gval->t; valuep->v = gval->v; return (1); } case T_ASSIGN: if (try) return (0); /* * first evaluate rhs, then try to store value in lhs which * should be a global variable */ if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); ASSERT(np->u.expr.left->t == T_GLOBID); gval = lut_lookup(*globals, (void *)np->u.expr.left->u.globid.s, NULL); if (gval == NULL) { gval = MALLOC(sizeof (*gval)); *globals = lut_add(*globals, (void *) np->u.expr.left->u.globid.s, gval, NULL); } gval->t = rval.t; gval->v = rval.v; if (gval->t == UINT64) { out(O_ALTFP|O_VERB2, "assign $%s=%llu", np->u.expr.left->u.globid.s, gval->v); } else { out(O_ALTFP|O_VERB2, "assign $%s=\"%s\"", np->u.expr.left->u.globid.s, (char *)(uintptr_t)gval->v); } /* * but always return true -- an assignment should not * cause a constraint to be false. */ valuep->t = UINT64; valuep->v = 1; return (1); case T_EQ: #define IMPLICIT_ASSIGN_IN_EQ #ifdef IMPLICIT_ASSIGN_IN_EQ /* * if lhs is an uninitialized global variable, perform * an assignment. * * one insidious side effect of implicit assignment is * that the "==" operator does not return a Boolean if * implicit assignment was performed. */ if (try == 0 && np->u.expr.left->t == T_GLOBID && (gval = lut_lookup(*globals, (void *)np->u.expr.left->u.globid.s, NULL)) == NULL) { if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); gval = MALLOC(sizeof (*gval)); *globals = lut_add(*globals, (void *) np->u.expr.left->u.globid.s, gval, NULL); gval->t = rval.t; gval->v = rval.v; valuep->t = rval.t; valuep->v = rval.v; return (1); } #endif /* IMPLICIT_ASSIGN_IN_EQ */ if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UNDEFINED, np)) return (0); valuep->t = UINT64; valuep->v = (lval.v == rval.v); return (1); case T_LT: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = UINT64; valuep->v = (lval.v < rval.v); return (1); case T_LE: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = UINT64; valuep->v = (lval.v <= rval.v); return (1); case T_GT: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = UINT64; valuep->v = (lval.v > rval.v); return (1); case T_GE: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = UINT64; valuep->v = (lval.v >= rval.v); return (1); case T_BITAND: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = lval.t; valuep->v = (lval.v & rval.v); return (1); case T_BITOR: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = lval.t; valuep->v = (lval.v | rval.v); return (1); case T_BITXOR: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = lval.t; valuep->v = (lval.v ^ rval.v); return (1); case T_BITNOT: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); ASSERT(np->u.expr.right == NULL); if (check_expr_args(&lval, NULL, UINT64, np)) return (0); valuep->t = UINT64; valuep->v = ~ lval.v; return (1); case T_LSHIFT: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = UINT64; valuep->v = (lval.v << rval.v); return (1); case T_RSHIFT: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = UINT64; valuep->v = (lval.v >> rval.v); return (1); case T_CONDIF: { struct node *retnp; int dotrue = 0; /* * evaluate * expression ? stmtA [ : stmtB ] * * first see if expression is true or false, then determine * if stmtA (or stmtB, if it exists) should be evaluated. * * "dotrue = 1" means stmtA should be evaluated. */ if (eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval) && lval.t != UNDEFINED && lval.v != 0) dotrue = 1; ASSERT(np->u.expr.right != NULL); if (np->u.expr.right->t == T_CONDELSE) { if (dotrue) retnp = np->u.expr.right->u.expr.left; else retnp = np->u.expr.right->u.expr.right; } else { /* no ELSE clause */ if (dotrue) retnp = np->u.expr.right; else { valuep->t = UINT64; valuep->v = 0; return (0); } } if (!eval_expr(retnp, ex, epnames, globals, croot, arrowp, try, valuep)) return (0); return (1); } case T_CONDELSE: /* * shouldn't get here, since T_CONDELSE is supposed to be * evaluated as part of T_CONDIF */ out(O_ALTFP|O_DIE, "eval_expr: wrong context for operation %s", ptree_nodetype2str(np->t)); return (0); case T_NE: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UNDEFINED, np)) return (0); valuep->t = UINT64; valuep->v = (lval.v != rval.v); return (1); case T_LIST: case T_AND: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, valuep)) return (0); if (valuep->v == 0) { valuep->t = UINT64; return (1); } if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, valuep)) return (0); valuep->t = UINT64; valuep->v = valuep->v == 0 ? 0 : 1; return (1); case T_OR: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, valuep)) return (0); if (valuep->v != 0) { valuep->t = UINT64; valuep->v = 1; return (1); } if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, valuep)) return (0); valuep->t = UINT64; valuep->v = valuep->v == 0 ? 0 : 1; return (1); case T_NOT: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, valuep)) return (0); valuep->t = UINT64; valuep->v = ! valuep->v; return (1); case T_ADD: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = lval.t; valuep->v = lval.v + rval.v; return (1); case T_SUB: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); /* since valuep is unsigned, return false if lval.v < rval.v */ if (lval.v < rval.v) { out(O_ERR, "eval_expr: T_SUB result is out of range"); valuep->t = UNDEFINED; return (0); } valuep->t = lval.t; valuep->v = lval.v - rval.v; return (1); case T_MUL: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); valuep->t = lval.t; valuep->v = lval.v * rval.v; return (1); case T_DIV: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); /* return false if dividing by zero */ if (rval.v == 0) { out(O_ERR, "eval_expr: T_DIV division by zero"); valuep->t = UNDEFINED; return (0); } valuep->t = lval.t; valuep->v = lval.v / rval.v; return (1); case T_MOD: if (!eval_expr(np->u.expr.left, ex, epnames, globals, croot, arrowp, try, &lval)) return (0); if (!eval_expr(np->u.expr.right, ex, epnames, globals, croot, arrowp, try, &rval)) return (0); if (check_expr_args(&lval, &rval, UINT64, np)) return (0); /* return false if dividing by zero */ if (rval.v == 0) { out(O_ERR, "eval_expr: T_MOD division by zero"); valuep->t = UNDEFINED; return (0); } valuep->t = lval.t; valuep->v = lval.v % rval.v; return (1); case T_NAME: if (try) { struct iterinfo *iterinfop; /* * at itree_create() time, we can expand simple * iterators. anything else we'll punt on. */ iterinfop = lut_lookup(ex, (void *)np->u.name.s, NULL); if (iterinfop != NULL) { /* explicit iterator; not part of pathname */ valuep->t = UINT64; valuep->v = (unsigned long long)iterinfop->num; return (1); } return (0); } /* return address of struct node */ valuep->t = NODEPTR; valuep->v = (uintptr_t)np; return (1); case T_QUOTE: valuep->t = STRING; valuep->v = (uintptr_t)np->u.quote.s; return (1); case T_FUNC: return (eval_func(np, ex, epnames, np->u.func.arglist, globals, croot, arrowp, try, valuep)); case T_NUM: valuep->t = UINT64; valuep->v = np->u.ull; return (1); default: outfl(O_DIE, np->file, np->line, "eval_expr: unexpected node type: %s", ptree_nodetype2str(np->t)); } /*NOTREACHED*/ return (0); } /* * eval_fru() and eval_asru() don't do much, but are called from a number * of places. */ struct node * eval_fru(struct node *np) { ASSERT(np->t == T_NAME); return (np); } struct node * eval_asru(struct node *np) { ASSERT(np->t == T_NAME); return (np); }