source: vis_dev/vis-2.3/src/part/partInOut.c @ 38

Last change on this file since 38 was 14, checked in by cecile, 13 years ago

vis2.3

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[14]1/**CFile***********************************************************************
2
3  FileName    [partInOut.c]
4
5  PackageName [part]
6
7  Synopsis [Implements the partition of a network considering only the
8  functions at the combinational outputs in terms of the combinational
9  inputs.]
10
11  Description [This module creates a partition where each combinational output
12  is defined in terms of the combinational inputs. More specifically, for each
13  combinational output and for some combinational inputs, there is a vertex in
14  the partition (a combinational input doesn't appear if no combinational
15  output depends on it). There is an edge from combinational input x to
16  combinational output y if the multi-valued function (MVF) for y depends on
17  x. Every vertex in the graph has a vertex name and an MVF (for combinational
18  inputs, the MVF is the trivial variable function). In addition, each
19  combinational input has an MDD id; a combinational output may or may not
20  have an MDD id.]
21
22  SeeAlso     [partPart.c]
23
24  Author      [Abelardo Pardo, Balakrishna Kumthekar]
25
26  Copyright [This file was created at the University of Colorado at Boulder.
27  The University of Colorado at Boulder makes no warranty about the
28  suitability of this software for any purpose.  It is presented on an AS IS
29  basis.]
30
31******************************************************************************/
32
33#include "partInt.h"
34
35static char rcsid[] UNUSED = "$Id: partInOut.c,v 1.15 2005/04/16 14:52:45 fabio Exp $";
36
37/**AutomaticStart*************************************************************/
38
39/*---------------------------------------------------------------------------*/
40/* Static function prototypes                                                */
41/*---------------------------------------------------------------------------*/
42
43
44/**AutomaticEnd***************************************************************/
45
46
47/*---------------------------------------------------------------------------*/
48/* Definition of exported functions                                          */
49/*---------------------------------------------------------------------------*/
50
51/**Function********************************************************************
52
53  Synopsis [Creates the graph representing a set of Mvfs as functions of the
54  variables in the collective support of the specified Mvfs. A copy of the Mvf
55  function is stored in vertex.]
56
57  Description [The input nameToMvf is a table which provides the names and the
58  corresponding Mvfs functions.  The procedure works as follows. For each
59  function, a vertex in the graph is created. For each variable in the support
60  of a given MVF, a vertex is created (if one doesn't already exist), and an
61  edge is added from the that vertex to that MVF. The support of an MVF is
62  taken as the union of the support of its constituent MDDs. The table nameToId
63  is optional and can be NULL. It provides a map from the name of the MVF to
64  its mddId. leafTable provides the pair (mddId, name) for each variable in the
65  support of the MVFs. partName can be NULL in which case the name of the
66  partition would be "dummy".]
67
68  SideEffects []
69
70  SeeAlso     [Part_NetworkCreatePartition Part_NetworkCreatePartitionFromMvfs]
71
72******************************************************************************/
73graph_t *
74Part_CreatePartitionFromMvfs(
75  mdd_manager *manager,                     
76  st_table *nameToMvf,
77  st_table *nameToId,
78  st_table *leafTable,
79  char *partName)
80{
81    graph_t        *partition;
82    Mvf_Function_t *mddFunction;
83    vertex_t       *toVertex;
84    lsList         sinkList;
85    lsGen          gen;
86    st_table       *mddIdToNodeName;
87    st_generator   *stGen;
88    char           *str;
89    long            mddId;
90
91    /* Initialize variables */
92    mddIdToNodeName = leafTable;
93
94    /* Allocate the new partition to be returned */
95    partition = g_alloc();
96    if (partName) {
97        partition->user_data = 
98            (gGeneric)PartPartitionInfoCreate(partName,manager,Part_InOut_c);
99    } /* End of if */
100    else {
101        partition->user_data = 
102            (gGeneric)PartPartitionInfoCreate("dummy",manager,Part_InOut_c);
103    } /* End of if-then-else */
104
105    /* Create vertices for the functions in nameToMvf */
106    st_foreach_item(nameToMvf,stGen,&str,&mddFunction) {
107        toVertex = g_add_vertex(partition);
108
109        /* Update the look-up tables in the graph */
110        st_insert(PartPartitionReadNameToVertex(partition),str,toVertex);
111        if (nameToId) {
112            if (st_lookup(nameToId, str, &mddId)) {
113                st_insert(PartPartitionReadMddIdToVertex(partition),
114                          (char *)mddId, toVertex);
115            } /* End of if */
116        } /* End of if */
117
118        /* Fill in the fields of the data attached to the vertex */
119        toVertex->user_data = 
120            (gGeneric)PartVertexInfoCreateSingle(str, 
121                                            Mvf_FunctionDuplicate(mddFunction),
122                                            mddId);
123    }
124 
125    /* Read the list of vertices on the graph */
126    sinkList = lsCopy(g_get_vertices(partition), (lsGeneric (*)(lsGeneric))0);
127
128    /*
129     * For every function on every combinational output, compute the
130     * support and create vertices in the graph when needed
131     */
132    lsForEachItem(sinkList, gen, toVertex) {
133        st_table *mddSupport; /* Support of the Mvf_Function */
134        st_generator *stGen;  /* To iterate over the MddIds of the support */
135        vertex_t *fromVertex; /* Holds the current vertex in the support */
136
137        /* Obtain an array of mdd_t * */
138        mddFunction = PartVertexReadFunction(toVertex);
139
140        /* Compute the support of the set of mdds*/
141        mddSupport = PartCreateFunctionSupportTable(mddFunction);
142
143        /*
144         * Create one edge (and one vertex if necessary) for every element
145         * in mddSupport
146         */
147        st_foreach_item(mddSupport, stGen, &mddId, NULL) {
148            char *name;
149
150            /* Create vertex with the information if needed */
151            if (st_lookup(PartPartitionReadMddIdToVertex(partition), 
152                          (char *)mddId, &fromVertex) == 0) {
153                fromVertex = g_add_vertex(partition);
154       
155                st_lookup(mddIdToNodeName, (char *)mddId, &name);
156
157                /* Update the look-up tables in the graph */
158                st_insert(PartPartitionReadNameToVertex(partition), 
159                          name, (char *)fromVertex);
160                st_insert(PartPartitionReadMddIdToVertex(partition),
161                          (char *)(long) mddId, (char *)fromVertex);
162       
163                /* Create vertex data */
164                fromVertex->user_data = 
165                    (gGeneric)PartVertexInfoCreateSingle(name,
166                              Mvf_FunctionCreateFromVariable(manager,mddId),
167                                                         mddId);
168            } /* End of if */
169     
170            /*
171             * Add the edge to the graph. Make sure a self loop is not added.
172             * The self loop may be produced by a mdd that has in its support
173             * the same variables that represent the mddId of the node.
174             */
175            if (fromVertex != toVertex) {
176                g_add_edge(fromVertex, toVertex);
177            } /* End of if */
178           
179        } /* End of st_foreach_item */
180   
181        /* Clean the support table */
182        st_free_table(mddSupport);
183    } /* End of lsForEachItem */
184
185    lsDestroy(sinkList, (void (*)(lsGeneric))0);
186
187    return partition;
188} /* End of Part_CreatePartitionFromMvfs */
189
190/**Function********************************************************************
191
192  Synopsis [Creates the graph representing the combinational outputs as
193  functions of the combinational inputs given as input a network and
194  Mvf functions representing the combinational outputs. A copy of the
195  Mvf function is stored in vertex.]
196
197  Description [The input nameToMvf is a table which provides the names
198  of the nodes and their corresponding Mvfs functions.
199  The procedure works as follows. For each combinational output,
200  a vertex in the graph is created. For each combinational input in the
201  support of a given combinational output MVF, a vertex is created
202  (if one doesn't already exist), and an edge is added
203  from the combinational input to the combinational output. The support of
204  an MVF is taken as the union of the support of its constituent MDDs.]
205
206  SideEffects []
207
208  SeeAlso     [Part_NetworkCreatePartition Part_CreatePartitionFromMvfs]
209
210******************************************************************************/
211graph_t *
212Part_NetworkCreatePartitionFromMvfs(
213  Ntk_Network_t *network,
214  st_table *nameToMvf)
215{
216    graph_t        *partition;
217    Ntk_Node_t     *node;
218    Mvf_Function_t *mddFunction;
219    vertex_t       *toVertex;
220    mdd_manager    *manager;
221    lsList         sinkList;
222    lsGen          gen;
223    st_table       *mddIdToNodeName;
224    st_generator   *stGen;
225    char           *ntkName;
226    char           *str;
227    long           mddId;
228
229    /* Initialize variables */
230    manager = Ntk_NetworkReadMddManager(network);
231    ntkName = Ntk_NetworkReadName(network);
232
233    /* Allocate the new partition to be returned */
234    partition = g_alloc();
235    partition->user_data = 
236        (gGeneric)PartPartitionInfoCreate(ntkName,manager,Part_InOut_c);
237
238    /* Create vertices for the functions in nameToMvf */
239    st_foreach_item(nameToMvf,stGen,&str,&mddFunction) {
240        node = Ntk_NetworkFindNodeByName(network,str);
241        if (node == NIL(Ntk_Node_t)) {
242            fprintf(vis_stderr,"%s has no corresponding node in network \n",
243                    str);
244            Part_PartitionFree(partition);
245            return NIL(graph_t);
246        }
247        mddId = Ntk_NodeReadMddId(node);
248        toVertex = g_add_vertex(partition);
249
250        /* Update the look-up tables in the graph */
251        st_insert(PartPartitionReadNameToVertex(partition),str,
252                  (char *)toVertex);
253
254        if (mddId != NTK_UNASSIGNED_MDD_ID) {
255            st_insert(PartPartitionReadMddIdToVertex(partition),
256                      (char *)(long) mddId, (char *)toVertex);
257        }
258
259        /* Fill in the fields of the data attached to the vertex */
260        toVertex->user_data = 
261            (gGeneric)PartVertexInfoCreateSingle(str, 
262                                            Mvf_FunctionDuplicate(mddFunction),
263                                            mddId);
264    }
265
266    /* Create a table for all the combinational inputs */
267    mddIdToNodeName = st_init_table(st_numcmp, st_numhash);
268    Ntk_NetworkForEachCombInput(network, gen, node) {
269        st_insert(mddIdToNodeName, (char *) (long)Ntk_NodeReadMddId(node), 
270                  Ntk_NodeReadName(node));
271    }
272 
273    /* Read the list of vertices on the graph */
274    sinkList = lsCopy(g_get_vertices(partition), (lsGeneric (*)(lsGeneric))0);
275
276    /*
277     * For every function on every combinational output, compute the
278     * support and create vertices in the graph when needed
279     */
280    lsForEachItem(sinkList, gen, toVertex) {
281        st_table *mddSupport; /* Support of the Mvf_Function */
282        st_generator *stGen;  /* To iterate over the MddIds of the support */
283        vertex_t *fromVertex; /* Holds the current vertex in the support */
284
285        /* Obtain an array of mdd_t * */
286        mddFunction = PartVertexReadFunction(toVertex);
287
288        /* Compute the support of the set of mdds*/
289        mddSupport = PartCreateFunctionSupportTable(mddFunction);
290
291        /*
292         * Create one edge (and one vertex if necessary) for every element
293         * in mddSupport
294         */
295        st_foreach_item(mddSupport, stGen, &mddId, NULL) {
296            char *name;
297
298            /* Create vertex with the information if needed */
299            if (st_lookup(PartPartitionReadMddIdToVertex(partition), 
300                          (char *)mddId, &fromVertex) == 0) {
301                fromVertex = g_add_vertex(partition);
302       
303                st_lookup(mddIdToNodeName, (char *)mddId, &name);
304
305                /* Update the look-up tables in the graph */
306                st_insert(PartPartitionReadNameToVertex(partition), 
307                          name, (char *)fromVertex);
308                st_insert(PartPartitionReadMddIdToVertex(partition),
309                          (char *)(long) mddId, (char *)fromVertex);
310       
311                /* Create vertex data */
312                fromVertex->user_data = 
313                    (gGeneric)PartVertexInfoCreateSingle(name,
314                              Mvf_FunctionCreateFromVariable(manager,mddId),
315                                                         mddId);
316            } /* End of if */
317     
318            /*
319             * Add the edge to the graph. Make sure a self loop is not added.
320             * The self loop may be produced by a mdd that has in its support
321             * the same variables that represent the mddId of the node.
322             */
323            if (fromVertex != toVertex) {
324                g_add_edge(fromVertex, toVertex);
325            } /* End of if */
326           
327        } /* End of st_foreach_item */
328   
329        /* Clean the support table */
330        st_free_table(mddSupport);
331    } /* End of lsForEachItem */
332
333    st_free_table(mddIdToNodeName);
334    lsDestroy(sinkList, (void (*)(lsGeneric))0);
335
336    return partition;
337} /* End of Part_NetworkCreatePartitionFromMvfs */
338
339/*---------------------------------------------------------------------------*/
340/* Definition of internal functions                                          */
341/*---------------------------------------------------------------------------*/
342
343/**Function********************************************************************
344
345  Synopsis [Creates the graph representing the combinational outputs as
346  functions of the combinational inputs.]
347
348  Description [The procedure works as follows. It calls the function
349  Ntm_NetworkBuildMvfs with the combinational outputs as roots and the
350  combinational inputs as leaves to obtain the multi-valued functions for
351  every combinational output.  For each combinational output, a vertex in the
352  graph is created. For each combinational input in the support of a given
353  combinational output MVF, a vertex is created for the combinational input
354  (if one doesn't already exist), and an edge is added from the combinational
355  input to the combinational output. The support of an MVF is taken as the
356  union of the support of its constituent MDDs.]
357
358  SideEffects []
359
360  SeeAlso     [Part_NetworkCreatePartition]
361
362******************************************************************************/
363void
364PartPartitionInputsOutputs(
365  Ntk_Network_t *network,
366  graph_t *partition,
367  lsList  rootList,
368  lsList  leaveList,
369  mdd_t   *careSet)
370{
371  Ntk_Node_t     *node;            /* Pointer to iterate over nodes */
372  Mvf_Function_t *mddFunction;     /* Pointer to a MDD */
373  mdd_manager    *manager;         /* Mdd manager in the partition */
374  st_table       *tableOfLeaves;   /* To store the leaves of the graph */
375  st_table       *mddIdToNodeName; /* For quick lookup of node's name */
376  array_t        *arrayOfMvf;      /* To store the next state functions */
377  array_t        *arrayOfRoots;    /* To store the roots of the graph */
378  lsList         sinkList;         /* Vertices representing comb. outputs */
379  lsGen          gen;              /* To iterate over lists */
380  vertex_t       *toVertex;        /* Will hold the current function vertex */
381  int            i;                /* Index for loops */
382  long            mddId;            /* Will hold the mddId being processed */
383
384
385  manager = PartPartitionReadMddManager(partition);
386
387  /* Take the nodes in leaveList as the leaves */
388  tableOfLeaves = st_init_table(st_ptrcmp, st_ptrhash);
389  mddIdToNodeName = st_init_table(st_numcmp, st_numhash);
390  if (leaveList == (lsList)0) {
391    Ntk_NetworkForEachCombInput(network, gen, node) {
392      st_insert(tableOfLeaves, (char *)node, (char *) (long) (-1) );
393      st_insert(mddIdToNodeName, (char *) (long)Ntk_NodeReadMddId(node), 
394                Ntk_NodeReadName(node));
395    }
396  } /* End of then */ 
397  else {
398    lsForEachItem(leaveList, gen, node) {
399      st_insert(tableOfLeaves, (char *)node, (char *) (long) (-1) );
400      st_insert(mddIdToNodeName, (char *) (long)Ntk_NodeReadMddId(node), 
401                Ntk_NodeReadName(node));
402    }
403  } /* End of if-then-else */
404
405  /* Take the nodes in rootList as the roots */
406  if (rootList == (lsList)0) {
407    arrayOfRoots = array_alloc(Ntk_Node_t *, 
408                               Ntk_NetworkReadNumCombOutputs(network));
409    i = 0;
410    Ntk_NetworkForEachCombOutput(network, gen, node) {
411      array_insert(Ntk_Node_t *, arrayOfRoots, i++, node);
412    }
413  } /* End of then */ 
414  else {
415    arrayOfRoots = array_alloc(Ntk_Node_t *, lsLength(rootList));
416    i = 0;
417    lsForEachItem(rootList, gen, node) {
418      array_insert(Ntk_Node_t *, arrayOfRoots, i++, node);
419    }
420  } /* End of if-then-else */
421
422  /* Build the next state functions as a function of the inputs */
423  arrayOfMvf = Ntm_NetworkBuildMvfs(network, arrayOfRoots, tableOfLeaves, 
424                                    careSet);
425
426  /* Create one vertex for every component of arrayOfMvf */
427  for (i=0; i < array_n(arrayOfRoots); i++) {
428    node = array_fetch(Ntk_Node_t *, arrayOfRoots, i);
429   
430    mddId = Ntk_NodeReadMddId(node);
431
432    /* obtain the function attached to the node */
433    mddFunction = array_fetch(Mvf_Function_t *, arrayOfMvf, i);
434    toVertex = g_add_vertex(partition);
435   
436    /* Update the look-up tables in the graph */
437    st_insert(PartPartitionReadNameToVertex(partition),
438              Ntk_NodeReadName(node), (char *)toVertex);
439    if (mddId != NTK_UNASSIGNED_MDD_ID) {
440      st_insert(PartPartitionReadMddIdToVertex(partition),
441                (char *)(long) mddId, (char *)toVertex);
442    } /* End of if */
443    toVertex->user_data = 
444      (gGeneric)PartVertexInfoCreateSingle(Ntk_NodeReadName(node), 
445                                           mddFunction, 
446                                           mddId);
447  } /* End of for */
448 
449  /* Read the list of vertices on the graph */
450  sinkList = lsCopy(g_get_vertices(partition), (lsGeneric (*)(lsGeneric))0);
451
452  /*
453   * For every function on every combinational output, compute the
454   * support and create vertices in the graph when needed
455   */
456  lsForEachItem(sinkList, gen, toVertex) {
457    st_table     *mddSupport; /* To store the support of the Mvf_Function */
458    st_generator *stGen;      /* To iterate over the MddIds of the support */
459    vertex_t     *fromVertex; /* Will hold the current vertex in the support */
460
461    /* Obtain an array of mdd_t * */
462    mddFunction = PartVertexReadFunction(toVertex);
463
464    /* Compute the support of the set of mdds*/
465    mddSupport = PartCreateFunctionSupportTable(mddFunction);
466
467    /*
468     * Create one edge (and one vertex if necessary) for every element
469     * in mddSupport
470     */
471    st_foreach_item(mddSupport, stGen, &mddId, NULL) {
472      char *name;
473
474      /* Create vertex with the information if needed */
475      if (st_lookup(PartPartitionReadMddIdToVertex(partition), 
476                    (char *)mddId, &fromVertex) == 0) {
477        fromVertex = g_add_vertex(partition);
478       
479        st_lookup(mddIdToNodeName, (char *)mddId, &name);
480
481        /* Update the look-up tables in the graph */
482        st_insert(PartPartitionReadNameToVertex(partition), 
483                  name, (char *)fromVertex);
484        st_insert(PartPartitionReadMddIdToVertex(partition),
485                  (char *)(long) mddId, (char *)fromVertex);
486       
487        /* Create vertex data */
488        fromVertex->user_data = 
489          (gGeneric)PartVertexInfoCreateSingle(name,
490                                               Mvf_FunctionCreateFromVariable(manager,mddId),
491                                               mddId);
492      } /* End of if */
493     
494      /*
495       * Add the edge to the graph. Make sure a self loop is not added. The
496       * self loop may be produced by a mdd that has in its support the same
497       * variables that represent the mddId of the node.
498       */
499      if (fromVertex != toVertex) {
500        g_add_edge(fromVertex, toVertex);
501      } /* End of if */
502     
503    } /* End of st_foreach_item */
504   
505    /* Clean the support table */
506    st_free_table(mddSupport);
507  } /* End of lsForEachItem */
508 
509  /* Clean up */
510  st_free_table(mddIdToNodeName);
511  st_free_table(tableOfLeaves);
512  array_free(arrayOfRoots);
513  lsDestroy(sinkList, (void (*)(lsGeneric))0);
514  /*
515   * The contents of this array (array of mdds) is not deallocated because the
516   * information has been transferred to the partition structure. All the
517   * functions are stored now as part of the vertex information.
518   */
519  array_free(arrayOfMvf);
520 
521} /* End of PartPartitionInputsOutputs */
522
523
524/**Function********************************************************************
525
526  Synopsis [Creates the graph representing the combinational outputs as
527  functions of the combinational inputs.]
528
529  Description [The procedure works as follows. It calls the function
530  Ntm_NetworkBuildMvfs with the combinational outputs as roots and the
531  combinational inputs as leaves to obtain the multi-valued functions for
532  every combinational output.  For each combinational output, a vertex in the
533  graph is created. For each combinational input in the support of a given
534  combinational output MVF, a vertex is created for the combinational input
535  (if one doesn't already exist), and an edge is added from the combinational
536  input to the combinational output. The support of an MVF is taken as the
537  union of the support of its constituent MDDs.]
538
539  SideEffects []
540
541  SeeAlso     [Part_NetworkCreatePartition]
542
543******************************************************************************/
544int
545PartPartitionInOutChangeRoots(
546  Ntk_Network_t *network,
547  graph_t *partition,
548  lsList  rootList,
549  int verbosity)
550{
551  Ntk_Node_t     *node;            /* Pointer to iterate over nodes */
552  mdd_manager    *manager;         /* Mdd manager in the partition */
553  lsList         newRootList;
554  lsList         vertexList;
555  lsGen          gen;              /* To iterate over lists */
556  vertex_t       *vertex;
557  char           *vertexName;
558  long           initialTime, finalTime;
559  st_table       *rootNodesTable = st_init_table(st_ptrcmp, st_ptrhash);
560  mdd_t          *careSet;
561
562  int prevNumOfLatchDataInput = 0;
563  int prevNumOfPrimaryOutput = 0;
564  int newNumOfLatchDataInput = 0;
565  int newNumOfPrimaryOutput = 0;
566  int overlapNumOfLatchDataInput = 0;
567  int overlapNumOfPrimaryOutPut = 0;
568
569  initialTime = util_cpu_time();
570
571  manager = PartPartitionReadMddManager(partition);
572  vertexList = g_get_vertices(partition);
573
574  lsForEachItem(vertexList, gen, vertex){
575    vertexName = PartVertexReadName(vertex);
576    node = Ntk_NetworkFindNodeByName(network, vertexName);
577    if (Ntk_NodeTestIsCombOutput(node)){
578      st_insert(rootNodesTable, (char *)node, (char *)(long)(-1));
579      if (Ntk_NodeTestIsLatchDataInput(node)){
580        prevNumOfLatchDataInput++;
581      }else if (Ntk_NodeTestIsPrimaryOutput(node)){
582        prevNumOfPrimaryOutput++;
583      }
584    }
585  }
586
587  newRootList = lsCreate();
588  lsForEachItem(rootList, gen, node){
589    if (!(st_is_member(rootNodesTable, (char *)node))){
590      lsNewEnd(newRootList, (lsGeneric)node, LS_NH);
591      if (Ntk_NodeTestIsLatchDataInput(node)){
592        newNumOfLatchDataInput++;
593      }else if (Ntk_NodeTestIsPrimaryOutput(node)){
594        newNumOfPrimaryOutput++;
595      }
596    }else{
597      if (Ntk_NodeTestIsLatchDataInput(node)){
598        overlapNumOfLatchDataInput++;
599      }else if (Ntk_NodeTestIsPrimaryOutput(node)){
600        overlapNumOfPrimaryOutPut++;
601      }
602    }
603  }
604
605  st_free_table(rootNodesTable);
606
607  if (lsLength(newRootList) > 0){
608    careSet = mdd_one(manager);
609    PartPartitionInputsOutputs(network, partition, newRootList, 
610                               (lsList)0, careSet);
611    mdd_free(careSet);
612  }
613
614  lsDestroy(newRootList, (void (*)(lsGeneric))0);
615
616  finalTime = util_cpu_time();
617
618  if (verbosity >= 2){
619    fprintf(vis_stdout, "PART: Partition is changed.\n");
620    fprintf(vis_stdout, "PART: Old - %d next state functions\n",
621            prevNumOfLatchDataInput);
622    fprintf(vis_stdout, "PART: Old - %d primary outputs\n",
623            prevNumOfPrimaryOutput);
624    fprintf(vis_stdout, "PART: New - %d next state functions\n",
625            prevNumOfLatchDataInput + newNumOfLatchDataInput);
626    fprintf(vis_stdout, "PART: New - %d primary outputs\n",
627            prevNumOfPrimaryOutput + newNumOfPrimaryOutput);
628    fprintf(vis_stdout, "PART: Partitioning time = %10ld\n",
629                    (finalTime - initialTime) / 1000);
630    Part_PartitionPrintStats(vis_stdout, partition, FALSE);
631  }
632
633  /*
634   * Is partition increased?
635   */
636  if (newNumOfLatchDataInput + newNumOfPrimaryOutput > 0){
637    return 1;
638  }else{
639    return 0;
640  } 
641} /* End of PartPartitionInOutChangeRoots */
642
643/*---------------------------------------------------------------------------*/
644/* Definition of static functions                                            */
645/*---------------------------------------------------------------------------*/
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