src/io/make_nodes.c

/*
 * Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
 *
 * The University of Notre Dame grants you ("Licensee") a
 * non-exclusive, royalty free, license to use, modify and
 * redistribute this software in source and binary code form, provided
 * that the following conditions are met:
 *
 * 1. Acknowledgement of the program authors must be made in any
 *    publication of scientific results based in part on use of the
 *    program.  An acceptable form of acknowledgement is citation of
 *    the article in which the program was described (Matthew
 *    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
 *    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
 *    Parallel Simulation Engine for Molecular Dynamics,"
 *    J. Comput. Chem. 26, pp. 252-271 (2005))
 *
 * 2. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 *
 * 3. 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.
 *
 * This software is provided "AS IS," without a warranty of any
 * kind. All express or implied conditions, representations and
 * warranties, including any implied warranty of merchantability,
 * fitness for a particular purpose or non-infringement, are hereby
 * excluded.  The University of Notre Dame and its licensors shall not
 * be liable for any damages suffered by licensee as a result of
 * using, modifying or distributing the software or its
 * derivatives. In no event will the University of Notre Dame or its
 * licensors be liable for any lost revenue, profit or data, or for
 * direct, indirect, special, consequential, incidental or punitive
 * damages, however caused and regardless of the theory of liability,
 * arising out of the use of or inability to use software, even if the
 * University of Notre Dame has been advised of the possibility of
 * such damages.
 */
 
#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#include "io/node_list.h"
#include "io/make_nodes.h"
#include "utils/simError.h"

/*
  walks to to the top of a stmt_list. Needed when assigning the
  statment list to a block of code.
*/

struct node_tag* walk_to_top( struct node_tag* walk_me ){

  while( walk_me->prev_stmt != NULL ){
    walk_me = walk_me->prev_stmt;
  }
  return walk_me;
}

/*
  the next three functions are for creating and initializing the
  assignment statements.
*/

struct node_tag* assign_i( char* lhs, int rhs ){

  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = ASSIGNMENT_STMT;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = NULL;
  
  the_node->the_data.asmt.type = INT_ASSN;
  the_node->the_data.asmt.identifier = lhs;
  the_node->the_data.asmt.rhs.i_val = rhs;

  return the_node;
}

struct node_tag* assign_d( char* lhs, double rhs ){

  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = ASSIGNMENT_STMT;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = NULL;
  
  the_node->the_data.asmt.type = DOUBLE_ASSN;
  the_node->the_data.asmt.identifier = lhs;
  the_node->the_data.asmt.rhs.d_val = rhs;

  return the_node;
}

struct node_tag* assign_s( char* lhs, char* rhs ){

  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = ASSIGNMENT_STMT;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = NULL;
  
  the_node->the_data.asmt.type = STR_ASSN;
  the_node->the_data.asmt.identifier = lhs;
  the_node->the_data.asmt.rhs.str_ptr = rhs;

  return the_node;
}

/*
  The next function deals with creating and initializing of the
  members statements used by the bonds, bends, torsions, rigid bodies, 
  and cutoff groups.
*/

struct node_tag* members( char* list_str ){

  int nTokens, i;
  char *foo;

  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = MEMBERS_STMT;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = NULL;
  
  nTokens = count_tokens(list_str, " ,;\t");

  if (nTokens < 1) {
    yyerror("can't find any members in this members statement");
  }

  the_node->the_data.mbrs.nMembers = nTokens;

  the_node->the_data.mbrs.memberList = (int *) calloc(nTokens, sizeof(int));

  foo = strtok(list_str, " ,;\t");
  the_node->the_data.mbrs.memberList[0] = atoi( foo );

  for (i = 1; i < nTokens; i++) {
    foo = strtok(NULL, " ,;\t");
    the_node->the_data.mbrs.memberList[i] = atoi( foo );
  }

  free(list_str);
  return the_node;
}

/*
  This function does the C & I of the constraint statements
*/

struct node_tag* constraint( char* list_str ){

  int nTokens;
  char *foo;

  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = CONSTRAINT_STMT;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = NULL;
  
  nTokens = count_tokens(list_str, " ,;\t");
  if (nTokens != 1) {
    yyerror("wrong number of arguments given in constraint statement");
  }
      
  foo = strtok(list_str, " ,;\t");
  the_node->the_data.cnstr.constraint_val = atof( foo );

  free(list_str);
  return the_node;
}

/*
  This function does the C & I for the orientation statements
*/

struct node_tag* orientation( char* list_str ){

  int nTokens;
  char *foo;

  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = ORIENTATION_STMT;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = NULL;
 
  nTokens = count_tokens(list_str, " ,;\t");
  if (nTokens != 3) {
    yyerror("wrong number of arguments given in orientation");
  }
      
  foo = strtok(list_str, " ,;\t");
  the_node->the_data.ort.phi = atof( foo );

  foo = strtok(NULL, " ,;\t");
  the_node->the_data.ort.theta = atof( foo );

  foo = strtok(NULL, " ,;\t");
  the_node->the_data.ort.psi = atof( foo );

  free(list_str);
  return the_node;
}

/*
  This function does the C & I for the position statements
*/

struct node_tag* position( char* list_str ){

  int nTokens;
  char *foo;

  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = POSITION_STMT;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = NULL;

  nTokens = count_tokens(list_str, " ,;\t");
  if (nTokens != 3) {
    yyerror("wrong number of arguments given in position");
  }
      
  foo = strtok(list_str, " ,;\t");
  the_node->the_data.pos.x = atof( foo );

  foo = strtok(NULL, " ,;\t");
  the_node->the_data.pos.y = atof( foo );

  foo = strtok(NULL, " ,;\t");
  the_node->the_data.pos.z = atof( foo );

  free(list_str);
  return the_node;
}

/*
  The following six functions initialize the statement nodes
  coresponding to the different code block types.
*/

struct node_tag* molecule_blk( struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = MOLECULE_HEAD;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
    
  return the_node;
}

struct node_tag* rigidbody_blk( int index, struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = RIGIDBODY_HEAD;
  the_node->index = index;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
    
  return the_node;
}

struct node_tag* cutoffgroup_blk( int index, struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  // The guillotine statement:
  the_node->type = CUTOFFGROUP_HEAD;
  the_node->index = index;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
    
  return the_node;
}

struct node_tag* atom_blk( int index, struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = ATOM_HEAD;
  the_node->index = index;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
    
  return the_node;
}

struct node_tag* bond_blk( int index, struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = BOND_HEAD;
  the_node->index = index;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
    
  return the_node;
}
 
struct node_tag* bend_blk( int index, struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = BEND_HEAD;
  the_node->index = index;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
    
  return the_node;
}

struct node_tag* torsion_blk( int index, struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = TORSION_HEAD;
  the_node->index = index;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
    
  return the_node;
}

struct node_tag* zconstraint_blk( int index, struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = ZCONSTRAINT_HEAD;
  the_node->index = index;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
    
  return the_node;
} 
 
struct node_tag* component_blk( struct node_tag* stmt_list ){
  
  struct node_tag* the_node;
  the_node = ( struct node_tag* )malloc( sizeof( node ) );
  
  the_node->type = COMPONENT_HEAD;
  the_node->index = 0;
  the_node->next_stmt = NULL;
  the_node->prev_stmt = NULL;
  the_node->stmt_list = walk_to_top( stmt_list );
  
  return the_node;
}


int count_tokens(char *line, char *delimiters) {
  /* PURPOSE: RETURN A COUNT OF THE NUMBER OF TOKENS ON THE LINE. */

  char *working_line;   /* WORKING COPY OF LINE. */
  int ntokens;          /* NUMBER OF TOKENS FOUND IN LINE. */
  char *strtok_ptr;     /* POINTER FOR STRTOK. */
  
  strtok_ptr= working_line= strdup(line);
  
  ntokens=0;
  while (strtok(strtok_ptr,delimiters)!=NULL)
    {
      ntokens++;
      strtok_ptr=NULL;
    }
  
  free(working_line);
  return(ntokens);
}
Revision:	507
Committed:	Fri Apr 15 22:04:00 2005 UTC (20 years ago) by gezelter
Content type:	text/plain
File size:	11064 byte(s)
Log Message:	xemacs has been drafted to perform our indentation services
#	User	Rev	Content
1	gezelter	507	/*
2	gezelter	246	* Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3			*
4			* The University of Notre Dame grants you ("Licensee") a
5			* non-exclusive, royalty free, license to use, modify and
6			* redistribute this software in source and binary code form, provided
7			* that the following conditions are met:
8			*
9			* 1. Acknowledgement of the program authors must be made in any
10			* publication of scientific results based in part on use of the
11			* program. An acceptable form of acknowledgement is citation of
12			* the article in which the program was described (Matthew
13			* A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
14			* J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
15			* Parallel Simulation Engine for Molecular Dynamics,"
16			* J. Comput. Chem. 26, pp. 252-271 (2005))
17			*
18			* 2. Redistributions of source code must retain the above copyright
19			* notice, this list of conditions and the following disclaimer.
20			*
21			* 3. Redistributions in binary form must reproduce the above copyright
22			* notice, this list of conditions and the following disclaimer in the
23			* documentation and/or other materials provided with the
24			* distribution.
25			*
26			* This software is provided "AS IS," without a warranty of any
27			* kind. All express or implied conditions, representations and
28			* warranties, including any implied warranty of merchantability,
29			* fitness for a particular purpose or non-infringement, are hereby
30			* excluded. The University of Notre Dame and its licensors shall not
31			* be liable for any damages suffered by licensee as a result of
32			* using, modifying or distributing the software or its
33			* derivatives. In no event will the University of Notre Dame or its
34			* licensors be liable for any lost revenue, profit or data, or for
35			* direct, indirect, special, consequential, incidental or punitive
36			* damages, however caused and regardless of the theory of liability,
37			* arising out of the use of or inability to use software, even if the
38			* University of Notre Dame has been advised of the possibility of
39			* such damages.
40			*/
41
42	gezelter	2	#include <stdio.h>
43			#include <stdlib.h>
44			#include <string.h>
45
46	tim	3	#include "io/node_list.h"
47			#include "io/make_nodes.h"
48			#include "utils/simError.h"
49	gezelter	2
50			/*
51			walks to to the top of a stmt_list. Needed when assigning the
52			statment list to a block of code.
53			*/
54
55			struct node_tag* walk_to_top( struct node_tag* walk_me ){
56
57			while( walk_me->prev_stmt != NULL ){
58			walk_me = walk_me->prev_stmt;
59			}
60			return walk_me;
61			}
62
63			/*
64			the next three functions are for creating and initializing the
65			assignment statements.
66			*/
67
68			struct node_tag* assign_i( char* lhs, int rhs ){
69
70			struct node_tag* the_node;
71			the_node = ( struct node_tag* )malloc( sizeof( node ) );
72
73			the_node->type = ASSIGNMENT_STMT;
74			the_node->index = 0;
75			the_node->next_stmt = NULL;
76			the_node->prev_stmt = NULL;
77			the_node->stmt_list = NULL;
78
79			the_node->the_data.asmt.type = INT_ASSN;
80			the_node->the_data.asmt.identifier = lhs;
81			the_node->the_data.asmt.rhs.i_val = rhs;
82
83			return the_node;
84			}
85
86			struct node_tag* assign_d( char* lhs, double rhs ){
87
88			struct node_tag* the_node;
89			the_node = ( struct node_tag* )malloc( sizeof( node ) );
90
91			the_node->type = ASSIGNMENT_STMT;
92			the_node->index = 0;
93			the_node->next_stmt = NULL;
94			the_node->prev_stmt = NULL;
95			the_node->stmt_list = NULL;
96
97			the_node->the_data.asmt.type = DOUBLE_ASSN;
98			the_node->the_data.asmt.identifier = lhs;
99			the_node->the_data.asmt.rhs.d_val = rhs;
100
101			return the_node;
102			}
103
104			struct node_tag* assign_s( char* lhs, char* rhs ){
105
106			struct node_tag* the_node;
107			the_node = ( struct node_tag* )malloc( sizeof( node ) );
108
109			the_node->type = ASSIGNMENT_STMT;
110			the_node->index = 0;
111			the_node->next_stmt = NULL;
112			the_node->prev_stmt = NULL;
113			the_node->stmt_list = NULL;
114
115			the_node->the_data.asmt.type = STR_ASSN;
116			the_node->the_data.asmt.identifier = lhs;
117			the_node->the_data.asmt.rhs.str_ptr = rhs;
118
119			return the_node;
120			}
121
122			/*
123			The next function deals with creating and initializing of the
124			members statements used by the bonds, bends, torsions, rigid bodies,
125			and cutoff groups.
126			*/
127
128			struct node_tag* members( char* list_str ){
129
130			int nTokens, i;
131			char *foo;
132
133			struct node_tag* the_node;
134			the_node = ( struct node_tag* )malloc( sizeof( node ) );
135
136			the_node->type = MEMBERS_STMT;
137			the_node->index = 0;
138			the_node->next_stmt = NULL;
139			the_node->prev_stmt = NULL;
140			the_node->stmt_list = NULL;
141
142			nTokens = count_tokens(list_str, " ,;\t");
143
144			if (nTokens < 1) {
145			yyerror("can't find any members in this members statement");
146			}
147
148			the_node->the_data.mbrs.nMembers = nTokens;
149
150			the_node->the_data.mbrs.memberList = (int *) calloc(nTokens, sizeof(int));
151
152			foo = strtok(list_str, " ,;\t");
153			the_node->the_data.mbrs.memberList[0] = atoi( foo );
154
155			for (i = 1; i < nTokens; i++) {
156			foo = strtok(NULL, " ,;\t");
157			the_node->the_data.mbrs.memberList[i] = atoi( foo );
158			}
159
160	tim	490	free(list_str);
161	gezelter	2	return the_node;
162			}
163
164			/*
165			This function does the C & I of the constraint statements
166			*/
167
168			struct node_tag* constraint( char* list_str ){
169
170			int nTokens;
171			char *foo;
172
173			struct node_tag* the_node;
174			the_node = ( struct node_tag* )malloc( sizeof( node ) );
175
176			the_node->type = CONSTRAINT_STMT;
177			the_node->index = 0;
178			the_node->next_stmt = NULL;
179			the_node->prev_stmt = NULL;
180			the_node->stmt_list = NULL;
181
182			nTokens = count_tokens(list_str, " ,;\t");
183			if (nTokens != 1) {
184			yyerror("wrong number of arguments given in constraint statement");
185			}
186
187			foo = strtok(list_str, " ,;\t");
188			the_node->the_data.cnstr.constraint_val = atof( foo );
189
190	tim	490	free(list_str);
191	gezelter	2	return the_node;
192			}
193
194			/*
195			This function does the C & I for the orientation statements
196			*/
197
198			struct node_tag* orientation( char* list_str ){
199
200			int nTokens;
201			char *foo;
202
203			struct node_tag* the_node;
204			the_node = ( struct node_tag* )malloc( sizeof( node ) );
205
206			the_node->type = ORIENTATION_STMT;
207			the_node->index = 0;
208			the_node->next_stmt = NULL;
209			the_node->prev_stmt = NULL;
210			the_node->stmt_list = NULL;
211
212			nTokens = count_tokens(list_str, " ,;\t");
213			if (nTokens != 3) {
214			yyerror("wrong number of arguments given in orientation");
215			}
216
217			foo = strtok(list_str, " ,;\t");
218			the_node->the_data.ort.phi = atof( foo );
219
220			foo = strtok(NULL, " ,;\t");
221			the_node->the_data.ort.theta = atof( foo );
222
223			foo = strtok(NULL, " ,;\t");
224			the_node->the_data.ort.psi = atof( foo );
225
226	tim	490	free(list_str);
227	gezelter	2	return the_node;
228			}
229
230			/*
231			This function does the C & I for the position statements
232			*/
233
234			struct node_tag* position( char* list_str ){
235
236			int nTokens;
237			char *foo;
238
239			struct node_tag* the_node;
240			the_node = ( struct node_tag* )malloc( sizeof( node ) );
241
242			the_node->type = POSITION_STMT;
243			the_node->index = 0;
244			the_node->next_stmt = NULL;
245			the_node->prev_stmt = NULL;
246			the_node->stmt_list = NULL;
247
248			nTokens = count_tokens(list_str, " ,;\t");
249			if (nTokens != 3) {
250			yyerror("wrong number of arguments given in position");
251			}
252
253			foo = strtok(list_str, " ,;\t");
254			the_node->the_data.pos.x = atof( foo );
255
256			foo = strtok(NULL, " ,;\t");
257			the_node->the_data.pos.y = atof( foo );
258
259			foo = strtok(NULL, " ,;\t");
260			the_node->the_data.pos.z = atof( foo );
261
262	tim	490	free(list_str);
263	gezelter	2	return the_node;
264			}
265
266			/*
267			The following six functions initialize the statement nodes
268			coresponding to the different code block types.
269			*/
270
271			struct node_tag* molecule_blk( struct node_tag* stmt_list ){
272
273			struct node_tag* the_node;
274			the_node = ( struct node_tag* )malloc( sizeof( node ) );
275
276			the_node->type = MOLECULE_HEAD;
277			the_node->index = 0;
278			the_node->next_stmt = NULL;
279			the_node->prev_stmt = NULL;
280			the_node->stmt_list = walk_to_top( stmt_list );
281
282			return the_node;
283			}
284
285			struct node_tag* rigidbody_blk( int index, struct node_tag* stmt_list ){
286
287			struct node_tag* the_node;
288			the_node = ( struct node_tag* )malloc( sizeof( node ) );
289
290			the_node->type = RIGIDBODY_HEAD;
291			the_node->index = index;
292			the_node->next_stmt = NULL;
293			the_node->prev_stmt = NULL;
294			the_node->stmt_list = walk_to_top( stmt_list );
295
296			return the_node;
297			}
298
299			struct node_tag* cutoffgroup_blk( int index, struct node_tag* stmt_list ){
300
301			struct node_tag* the_node;
302			the_node = ( struct node_tag* )malloc( sizeof( node ) );
303
304			// The guillotine statement:
305			the_node->type = CUTOFFGROUP_HEAD;
306			the_node->index = index;
307			the_node->next_stmt = NULL;
308			the_node->prev_stmt = NULL;
309			the_node->stmt_list = walk_to_top( stmt_list );
310
311			return the_node;
312			}
313
314			struct node_tag* atom_blk( int index, struct node_tag* stmt_list ){
315
316			struct node_tag* the_node;
317			the_node = ( struct node_tag* )malloc( sizeof( node ) );
318
319			the_node->type = ATOM_HEAD;
320			the_node->index = index;
321			the_node->next_stmt = NULL;
322			the_node->prev_stmt = NULL;
323			the_node->stmt_list = walk_to_top( stmt_list );
324
325			return the_node;
326			}
327
328			struct node_tag* bond_blk( int index, struct node_tag* stmt_list ){
329
330			struct node_tag* the_node;
331			the_node = ( struct node_tag* )malloc( sizeof( node ) );
332
333			the_node->type = BOND_HEAD;
334			the_node->index = index;
335			the_node->next_stmt = NULL;
336			the_node->prev_stmt = NULL;
337			the_node->stmt_list = walk_to_top( stmt_list );
338
339			return the_node;
340			}
341
342			struct node_tag* bend_blk( int index, struct node_tag* stmt_list ){
343
344			struct node_tag* the_node;
345			the_node = ( struct node_tag* )malloc( sizeof( node ) );
346
347			the_node->type = BEND_HEAD;
348			the_node->index = index;
349			the_node->next_stmt = NULL;
350			the_node->prev_stmt = NULL;
351			the_node->stmt_list = walk_to_top( stmt_list );
352
353			return the_node;
354			}
355
356			struct node_tag* torsion_blk( int index, struct node_tag* stmt_list ){
357
358			struct node_tag* the_node;
359			the_node = ( struct node_tag* )malloc( sizeof( node ) );
360
361			the_node->type = TORSION_HEAD;
362			the_node->index = index;
363			the_node->next_stmt = NULL;
364			the_node->prev_stmt = NULL;
365			the_node->stmt_list = walk_to_top( stmt_list );
366
367			return the_node;
368			}
369
370			struct node_tag* zconstraint_blk( int index, struct node_tag* stmt_list ){
371
372			struct node_tag* the_node;
373			the_node = ( struct node_tag* )malloc( sizeof( node ) );
374
375			the_node->type = ZCONSTRAINT_HEAD;
376			the_node->index = index;
377			the_node->next_stmt = NULL;
378			the_node->prev_stmt = NULL;
379			the_node->stmt_list = walk_to_top( stmt_list );
380
381			return the_node;
382			}
383
384			struct node_tag* component_blk( struct node_tag* stmt_list ){
385
386			struct node_tag* the_node;
387			the_node = ( struct node_tag* )malloc( sizeof( node ) );
388
389			the_node->type = COMPONENT_HEAD;
390			the_node->index = 0;
391			the_node->next_stmt = NULL;
392			the_node->prev_stmt = NULL;
393			the_node->stmt_list = walk_to_top( stmt_list );
394
395			return the_node;
396			}
397
398
399			int count_tokens(char line, char delimiters) {
400	gezelter	507	/* PURPOSE: RETURN A COUNT OF THE NUMBER OF TOKENS ON THE LINE. */
401	gezelter	2
402			char working_line; / WORKING COPY OF LINE. */
403			int ntokens; /* NUMBER OF TOKENS FOUND IN LINE. */
404			char strtok_ptr; / POINTER FOR STRTOK. */
405
406			strtok_ptr= working_line= strdup(line);
407
408			ntokens=0;
409			while (strtok(strtok_ptr,delimiters)!=NULL)
410			{
411			ntokens++;
412			strtok_ptr=NULL;
413			}
414
415			free(working_line);
416			return(ntokens);
417			}