221 lines
7.6 KiB
C
221 lines
7.6 KiB
C
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/* lil-gp Genetic Programming System, version 1.0, 11 July 1995
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* Copyright (C) 1995 Michigan State University
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of version 2 of the GNU General Public License as
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* published by the Free Software Foundation.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
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*
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* Douglas Zongker (zongker@isl.cps.msu.edu)
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* Dr. Bill Punch (punch@isl.cps.msu.edu)
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*
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* Computer Science Department
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* A-714 Wells Hall
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* Michigan State University
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* East Lansing, Michigan 48824
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* USA
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*
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*/
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#include <lilgp.h>
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/* set_current_individual()
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*
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* the current_individual variable is used so that evaluation tokens know
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* where to find their target trees. set_current_individual() is used to
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* set this value from the application code.
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*/
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#if !defined(POSIX_MT) && !defined(SOLARIS_MT)
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static individual * current_individual;
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#define CURRENT_INDIVIDUAL current_individual
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#else
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#define CURRENT_INDIVIDUAL (get_globaldata())->current_individual
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#endif
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void set_current_individual ( individual *ind )
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{
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CURRENT_INDIVIDUAL = ind;
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}
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/* evaluate_tree()
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*
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* this is the wrapper which sets up a traversal pointer for doing the
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* evaluation. the whichtree argument is needed so that ARG terminals
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* know where to find their values.
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*/
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DATATYPE evaluate_tree ( lnode *tree, int whichtree )
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{
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lnode *l = tree;
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#ifdef DEBUG_EVAL
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printf ( "call to evaluate_tree in context %d\n", whichtree );
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#endif
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return evaluate_tree_recurse ( &l, whichtree );
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}
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/* evaluate_tree_recurse()
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*
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* the recursive part of the tree evaluator. returns the value of the
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* evaluated tree.
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*/
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DATATYPE evaluate_tree_recurse ( lnode **l, int whichtree )
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{
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farg arg[MAXARGS];
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int i;
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function *f = (**l).f;
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treeinfo savearg;
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/* step the traversal pointer forward, now that we've saved which
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function we're at. */
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++*l;
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switch ( f->type )
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{
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case FUNC_DATA:
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/* function (DATA type): recursively evaluate each subtree,
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saving the values. pass these values to the user code. */
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for ( i = 0; i < f->arity; ++i )
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arg[i].d = evaluate_tree_recurse ( l, whichtree );
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return (f->code)(whichtree, arg);
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break;
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case EVAL_DATA:
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/* evaluation token (DATA type): first evaluate each child,
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saving the returned values. these values will be returned
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by the appropriate ARG tokens in the called tree. */
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for ( i = 0; i < f->arity; ++i )
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arg[i].d = evaluate_tree_recurse ( l, whichtree );
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/* the arguments are stored using three fields in the global
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tree_map. we save whatever was in these three fields in
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local variables. */
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savearg.arguments = tree_map[f->evaltree].arguments;
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savearg.argtype = tree_map[f->evaltree].argtype;
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savearg.evaluatedfrom = tree_map[f->evaltree].evaluatedfrom;
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/** now we store the new values in the global structure. **/
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/* first, the argument list. */
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tree_map[f->evaltree].arguments = arg;
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/* next, the type of this eval token. */
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tree_map[f->evaltree].argtype = EVAL_DATA;
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/* now the tree number which we are currently evaluating. this
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is necessary so that nested ADFs evaluate correctly -- we must
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remember where we are so that ARG tokens know which tree's
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arguments to look at. */
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tree_map[f->evaltree].evaluatedfrom = whichtree;
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/* finally call evaluate_tree to evaluate the target tree. */
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arg->d = evaluate_tree ( CURRENT_INDIVIDUAL->tr[f->evaltree].data,
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f->evaltree );
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/* restore the old values in the global structure. */
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tree_map[f->evaltree].arguments = savearg.arguments;
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tree_map[f->evaltree].argtype = savearg.argtype;
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tree_map[f->evaltree].evaluatedfrom = savearg.evaluatedfrom;
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/* return the final value. */
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return arg->d;
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break;
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case FUNC_EXPR:
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/* function (EXPR type): save the address of each child tree,
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using the skip nodes to quickly move the traversal pointer
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past the child. */
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for ( i = 0; i < f->arity; ++i )
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{
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arg[i].t = (*l+1);
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*l += (**l).s;
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++*l;
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}
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/* now pass this array of saved trees to the user code. */
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return (f->code)(whichtree, arg);
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break;
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case EVAL_EXPR:
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/* evaluation token (EXPR type): works just like the DATA
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type, only the saved arguments are tree address instead
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of values. */
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for ( i = 0; i < f->arity; ++i )
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{
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arg[i].t = (*l+1);
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*l += (**l).s;
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++*l;
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}
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savearg.arguments = tree_map[f->evaltree].arguments;
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savearg.argtype = tree_map[f->evaltree].argtype;
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savearg.evaluatedfrom = tree_map[f->evaltree].evaluatedfrom;
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tree_map[f->evaltree].arguments = arg;
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tree_map[f->evaltree].argtype = EVAL_EXPR;
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tree_map[f->evaltree].evaluatedfrom = whichtree;
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arg->d = evaluate_tree ( CURRENT_INDIVIDUAL->tr[f->evaltree].data,
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f->evaltree );
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tree_map[f->evaltree].arguments = savearg.arguments;
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tree_map[f->evaltree].argtype = savearg.argtype;
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tree_map[f->evaltree].evaluatedfrom = savearg.evaluatedfrom;
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return arg->d;
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break;
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case EVAL_TERM:
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/* evaluation token (TERM type): works just like the DATA
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type, only we pass NULL as an argument list. */
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savearg.arguments = tree_map[f->evaltree].arguments;
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savearg.argtype = tree_map[f->evaltree].argtype;
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savearg.evaluatedfrom = tree_map[f->evaltree].evaluatedfrom;
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tree_map[f->evaltree].arguments = NULL;
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tree_map[f->evaltree].argtype = EVAL_TERM;
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tree_map[f->evaltree].evaluatedfrom = whichtree;
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arg->d = evaluate_tree ( CURRENT_INDIVIDUAL->tr[f->evaltree].data,
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f->evaltree );
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tree_map[f->evaltree].arguments = savearg.arguments;
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tree_map[f->evaltree].argtype = savearg.argtype;
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tree_map[f->evaltree].evaluatedfrom = savearg.evaluatedfrom;
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return arg->d;
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break;
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case TERM_ARG:
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/* an ARG terminal. */
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if ( tree_map[whichtree].argtype == EVAL_DATA )
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/* if the EVAL token calling this tree is of type DATA, then
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just pull the value out of the argument list and return it. */
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return tree_map[whichtree].arguments[f->evaltree].d;
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else
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/* if the EVAL token calling this tree is of type EXPR, then
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evaluate the tree pointer in the argument list and return
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the value. */
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return evaluate_tree ( tree_map[whichtree].arguments[f->evaltree].t, tree_map[whichtree].evaluatedfrom );
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break;
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case TERM_ERC:
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/* ERC terminal: traversal pointer points to ERC structure.
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pull the value out, and step the pointer forward. */
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return (*((*l)++)).d->d;
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break;
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default: /* TERM_NORM */
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/* normal terminal: just call the user code. */
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return (f->code)(whichtree, NULL);
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break;
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}
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}
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