source: vis_dev/vis-2.3/src/res/res.c

/**CFile***********************************************************************

  FileName    [res.c]

  PackageName [res]

  Synopsis    [ The main file that incorporates procedures for residue
                verification.]

  Author      [ Kavita Ravi    <ravi@boulder.colorado.edu>,
                Abelardo Pardo <abel@boulder.colorado.edu>]

  Copyright [This file was created at the University of Colorado at Boulder.
  The University of Colorado at Boulder makes no warranty about the suitability
  of this software for any purpose.  It is presented on an AS IS basis.]

******************************************************************************/

#include "resInt.h"

static char rcsid[] UNUSED = "$Id: res.c,v 1.55 2009/04/11 21:31:29 fabio Exp $";

/*---------------------------------------------------------------------------*/
/* Constant declarations                                                     */
/*---------------------------------------------------------------------------*/
#define RES_VERIFY_NOTHING 0
#define RES_VERIFY_DONE 1
#define RES_VERIFY_IGNORE_PREV_RESULTS 2
#define LOG2_FIRST_PRIME 8

/*---------------------------------------------------------------------------*/
/* Structure declarations                                                    */
/*---------------------------------------------------------------------------*/

/*---------------------------------------------------------------------------*/
/* Type declarations                                                         */
/*---------------------------------------------------------------------------*/

/*---------------------------------------------------------------------------*/
/* Variable declarations                                                     */
/*---------------------------------------------------------------------------*/


static int PrimePool [] = { 5,   7,  9, 11, 13, 17,  19,  23,  29,
                            31,  37,  41,  43,  47,  53,  59,  61,  67,  71,
                            73,  79,  83,  89,  97, 101, 103, 107, 109, 113,
                            127, 131, 137, 139, 149, 151, 157, 163, 167, 173,
                            179, 181, 191, 193, 197, 199, 211, 223, 227, 229,
                            233, 239, 241, 251, 257, 263, 269, 271, 277, 281,
                            283, 293, 307, 311, 313, 317, 331, 337, 347, 349,
                            353, 359, 367, 373, 379, 383, 389, 397, 401, 409,
                            419, 421, 431, 433, 439, 443, 449, 457, 461, 463,
                            467, 479, 487, 491, 499, 503, 509, 521, 523, 541,
                            547};
static int PrimePoolSize = 100;    /* Number of elements of the array above */

/*---------------------------------------------------------------------------*/
/* Macro declarations                                                        */
/*---------------------------------------------------------------------------*/

/**AutomaticStart*************************************************************/

/*---------------------------------------------------------------------------*/
/* Static function prototypes                                                */
/*---------------------------------------------------------------------------*/

static int ChoosePrimes(int numOutputs, int **pool, int numDirectVerify);
static int ComputeMaxNumberOfOutputs(void);
static void RestoreOldMddIds(Ntk_Network_t *network, st_table *table);
static st_table * GeneratePointerMatchTableFromNameMatch(Ntk_Network_t *specNetwork, Ntk_Network_t *implNetwork, st_table *nameMatchTable);
static st_table * GenerateDirectVerifyPointerTable(Ntk_Network_t *specNetwork, Ntk_Network_t *implNetwork, st_table *outputMatch, array_t *outputOrderArray, int numDirectVerify);
static st_table * GenerateIdentityMatchTable(Ntk_Network_t *specNetwork, Ntk_Network_t *implNetwork, int inputOrOutput);
static bdd_manager * Initializebdd_manager(Ntk_Network_t *specNetwork, Ntk_Network_t *implNetwork, int *initManagerHere);
static int SetBasicResultInfo(Ntk_Network_t *specNetwork, Ntk_Network_t *implNetwork, int numDirectVerify);
static void Cleanup(int error, Ntk_Network_t *specNetwork, Ntk_Network_t *implNetwork, int initManagerHere, int done, st_table *outputMatch, st_table *inputMatch, st_table *directVerifyMatch, st_table *oldSpecMddIdTable, st_table *oldImplMddIdTable, array_t *specLayerArray, array_t *implLayerArray);
static st_table * SaveOldMddIds(Ntk_Network_t *network);
static int DirectVerification(Ntk_Network_t *specNetwork, Ntk_Network_t *implNetwork, st_table *directVerifyMatch, st_table *inputMatch, st_table *outputMatch, array_t *outputOrderArray);
static bdd_reorder_type_t DecodeDynMethod(char *dynMethodString);
static int ResidueVerification(Ntk_Network_t *specNetwork, Ntk_Network_t *implNetwork, st_table *outputMatch, st_table *inputMatch, int numDirectVerify, array_t *specLayerArray, array_t *implLayerArray, array_t *outputArray);
static void ExtractACubeOfDifference(bdd_manager *mgr, Ntk_Network_t *specNetwork, bdd_node *fn1, bdd_node *fn2);

/**AutomaticEnd***************************************************************/


/*---------------------------------------------------------------------------*/
/* Definition of exported functions                                          */
/*---------------------------------------------------------------------------*/

/**Function********************************************************************

  Synopsis      [Performs direct and residue verification of a given network.]

  Description   [ Performs direct and residue verification of a given network.
  This function is the core routine for residue verification. The network
  parameters are in a specific order: SPECIFICATION first, IMPLEMENTATION
  second. The two networks are differentiated because the specification is the
  only circuit which may store  previously computed results. Also all other
  parameters are with reference to the specification. The next parameter is
  the number  of outputs to directly verify.
  The output order array gives the order of the outputs,
  starting from the MSB. The output and input match table contain name matches
  for the output and input. The key in this table belongs to the specification
  and the value to the implementation. The procedure initializes  the manager,
  computes maximum number of outputs that can be verified, sets basic result
  information. It also sets up the match tables with pointers and saves the
  old MDD Ids in a table. It then calls the direct verification procedure, if
  there are any outputs to be verified. For residue verification, the procedure
  calls the layering procedure on both networks and creates layers. It calls
  the main residue verification procedure and updates the result structures.
  Returns the value 0 on success. The procedure takes in as arguments the
  specification network, the implementation network in that order, the number
  of outputs that need to be directly verified, the order of all the outputs,
  the table with outputs name matches of the spec. and the impl. and a similar
  input name match table.]

  SideEffects        [The residue Info structure gets updated.]

******************************************************************************/
int
Res_NetworkResidueVerify(
         Ntk_Network_t *specNetwork,
         Ntk_Network_t *implNetwork,
         int numDirectVerify,
         array_t *outputOrderArray,
         st_table *outputNameMatch,
         st_table *inputNameMatch)
{
  Ntk_Node_t *nodePtr;           /* To iterate over nodes */
  Ntk_Node_t *implNodePtr;       /* To iterate over nodes */
  Res_ResidueInfo_t *resultSpec; /* Structure holding all the info */
  Res_ResidueInfo_t *resultImpl; /* Structure holding all the info */
  array_t *specLayerArray;       /* array containing the reverse
                                  * topological layers of the spec.
                                  */
  array_t *implLayerArray;       /* array containing the reverse
                                  * topological layers of the impl.
                                  */
  st_table *oldSpecMddIdTable;   /* Tables to store MDD IDs of the spec
                                  * if already assigned
                                  */
  st_table *oldImplMddIdTable;   /* Tables to store MDD IDs of the impl.
                                  * if already assigned
                                  */

  st_table *outputMatch;         /* Output match table with node
                                  * pointers, spec node pointer is
                                  * the key
                                  */
  st_table *inputMatch;          /* Input match table with node
                                  * pointers, spec node pointer is
                                  * the key
                                  */

  bdd_manager *ddManager;          /* Manager read from the network */
  int initManagerHere;           /* Flag to indicate the network Mdd
                                  * managers initialized here
                                  */

  lsGen listGen;                 /* To iterate over outputList */
  long overallLap;               /* To measure overall execution time */
  int maxNumberOfOutputs;        /* max number of outputs that can be
                                  * verified here
                                  * = product(100 primes)
                                  */
  int numOutputs;                /* Store the number of outputs in spec.,
                                  * impl
                                  */
  int done;                      /* flag to determine the status of
                                  * previous verification
                                  */
  int error;                     /* error flag, set for cleanup, 1 failed,
                                  * 0 if successful
                                  */
  int status;                    /* error status of residue verification */
  int directVerifyStatus;        /* direct verification status, 1 if failed,
                                  * 0 if successful
                                  */
  st_table *directVerifyMatch;   /* match table with pointers for the
                                  * directly verified outputs, spec pointer
                                  * is key
                                  */
  char *name;                    /* variable to store name of node */
  array_t *outputArray;          /* array to store output nodes */
  array_t *ignoreOutputArray;    /* array to store outputs nodes to be
                                  * ignored
                                  */
  int verbose;                   /* variable to read residue_verbosity value */
  char *flagValue;               /* string to read flag values */
  int i;                         /* Loop iterators */
  int unassignedValue;           /* NTK_UNASSIGNED_MDD_ID value holder */

  /* Initialize some variables to default values */

  overallLap = 0;
  initManagerHere = 0;
  ddManager = NIL(bdd_manager);
  done = RES_VERIFY_NOTHING;
  error = 0;
  status = 1;
  verbose = 0;

  unassignedValue =  NTK_UNASSIGNED_MDD_ID;
  directVerifyStatus = 1;
  directVerifyMatch = NIL(st_table);
  specLayerArray = NIL(array_t);
  implLayerArray = NIL(array_t);
  outputArray = NIL(array_t);
  ignoreOutputArray = NIL(array_t);
  outputMatch = NIL(st_table);
  inputMatch = NIL(st_table);
  oldSpecMddIdTable = NIL(st_table);
  oldImplMddIdTable = NIL(st_table);
  resultSpec = NIL(Res_ResidueInfo_t);
  resultImpl = NIL(Res_ResidueInfo_t);


  /* Initialize global time values*/
  Res_composeTime = 0;
  Res_smartVarTime = 0;
  Res_shuffleTime = 0;
  Res_orderTime = 0;


  /* Read verbosity value */
  flagValue = Cmd_FlagReadByName("residue_verbosity");
  if (flagValue != NIL(char)) {
    verbose = atoi(flagValue);
  }

  /* Read the mdd Manager (or create it if necessary) */
  ddManager = Initializebdd_manager(specNetwork, implNetwork, &initManagerHere);
  if (ddManager == NIL(bdd_manager)) {
    /* error, but nothing allocated, so no cleanup */
    return 1;
  }

  /* Set up the correct maximum number of outputs */
  maxNumberOfOutputs  = ComputeMaxNumberOfOutputs();
  if (verbose >= 2) {
    fprintf(vis_stdout, "The Maximum Number of outputs that can be");
    fprintf(vis_stdout, " verified are %d.\n", maxNumberOfOutputs);
  }

  /* check number of outputs */
  numOutputs = Ntk_NetworkReadNumCombOutputs(specNetwork);
  /* Check if the circuit has too many outputs */
  if (numOutputs >= maxNumberOfOutputs) {
    error_append("Circuit with too many outputs.\n");
    /* Clean up before you leave */
    error = 1;
    Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
            outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
            oldImplMddIdTable, specLayerArray, implLayerArray);
    return 1;
  } /* End of if */

  /* Create result data structure for both the spec and the implementation */
  done = SetBasicResultInfo(specNetwork, implNetwork, numDirectVerify);
  if (done ==  RES_VERIFY_DONE) {/* same verification as previous time */
    /* Clean up before you leave */
    fprintf(vis_stdout, "Verification has been previously performed\n");
    error = 0;
    Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
            outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
            oldImplMddIdTable, specLayerArray, implLayerArray);
    return 0; /* success */
  } /* end of case RES_VERIFY_DONE */

  /* if output match table does not exist, create one with matching names
   * in the two networks. Insert with spec network node pointer as key
   * in the outputMatch table. If match table does exist, convert name table
   * to pointer table.
   */
  if(outputNameMatch == NIL(st_table)) {
    outputMatch = GenerateIdentityMatchTable(specNetwork, implNetwork, PRIMARY_OUTPUTS);
  } else {
    outputMatch = GeneratePointerMatchTableFromNameMatch(specNetwork,
                                                         implNetwork,outputNameMatch);
    if (outputMatch == NIL(st_table)) {
      error_append("Output pointer table is NULL\n");
      /* Clean up before you leave */
      error = 1;
      Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
              outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
              oldImplMddIdTable, specLayerArray, implLayerArray);
      return 1; /* error return */
    }
  }

  /* if input match table does not exist, create one with matching names
   * in the two networks. Insert with spec network node pointer as key
   * in the inputMatch table. If match table does exist, convert name table
   * to pointer table.
   */
  if(inputNameMatch == NIL(st_table)) {
    inputMatch = GenerateIdentityMatchTable(specNetwork, implNetwork, PRIMARY_INPUTS);
  } else {
    inputMatch = GeneratePointerMatchTableFromNameMatch(specNetwork,
                                                        implNetwork,inputNameMatch);
    if (inputMatch == NIL(st_table)) {
      error_append("Input pointer table is NULL\n");
      /* Clean up before you leave */
      error = 1;
      Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
              outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
              oldImplMddIdTable, specLayerArray, implLayerArray);
      return 1; /* error return */
    }
  }

  /* Save the old MDD IDs in a st_table */
  oldSpecMddIdTable = SaveOldMddIds(specNetwork);
  if (oldSpecMddIdTable == NIL(st_table)) {
    error_append("Unable to save old Mdd Ids for spec\n");
    /* Clean up before you leave */
    error = 1;
    Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
            outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
            oldImplMddIdTable, specLayerArray, implLayerArray);
    return 1;
  }

  /* Save the old MDD IDs in a st_table */
  oldImplMddIdTable = SaveOldMddIds(implNetwork);
  if (oldImplMddIdTable == NIL(st_table)) {
    error_append("Unable to save old Mdd Ids for impl\n");
    /* Clean up before you leave */
    error = 1;
    Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
            outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
            oldImplMddIdTable, specLayerArray, implLayerArray);
    return 1;
  }

  /* Initialize time to measure overall lap time */
  overallLap = util_cpu_time();

  /* Perform direct verification of the given outputs. */
  if (numDirectVerify) {
    /* generate output match table for outputs to be directly verified */
    directVerifyMatch = GenerateDirectVerifyPointerTable(specNetwork,
         implNetwork, outputMatch, outputOrderArray, numDirectVerify);
    if (directVerifyMatch == NIL(st_table)) {
      error_append("Directly verify  pointer table is NULL\n");
      /* Clean up before you leave */
      error = 1;
      Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
              outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
              oldImplMddIdTable, specLayerArray, implLayerArray);
      return 1; /* error return */
    }

    /* perform direct verification of the outputs in the match table */
    directVerifyStatus = DirectVerification(specNetwork, implNetwork,
                    directVerifyMatch, inputMatch, outputMatch, outputOrderArray);
    /* Direct verification error */
    if (directVerifyStatus == 1) {
      error_append("Direct Verification error\n");
      /* Clean up before you leave */
      error = 1;
      Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
      outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
              oldImplMddIdTable, specLayerArray, implLayerArray);
      return 1; /* error return */
    }

    resultSpec = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(specNetwork,
                                            RES_NETWORK_APPL_KEY);
    resultImpl = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(implNetwork,
                                            RES_NETWORK_APPL_KEY);
    /* Direct verification failed */
    if ((ResResidueInfoReadDirectVerificationSuccess(resultSpec) == RES_FAIL) &&
        (ResResidueInfoReadDirectVerificationSuccess(resultImpl) == RES_FAIL)) {
      ResResidueInfoSetSuccess(resultSpec, RES_FAIL);
      ResResidueInfoSetSuccess(resultImpl, RES_FAIL);
      /*  Clean up before you leave */
      error = 0;
      Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
      outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
              oldImplMddIdTable, specLayerArray, implLayerArray);
      return 0;
    } else if (numDirectVerify == numOutputs) {
      if ((ResResidueInfoReadDirectVerificationSuccess(resultSpec) == RES_PASS) &&
          (ResResidueInfoReadDirectVerificationSuccess(resultImpl) == RES_PASS)) {
        /* if all outputs are directly verified */
        ResResidueInfoSetSuccess(resultSpec, RES_PASS);
        ResResidueInfoSetSuccess(resultImpl, RES_PASS);
      }
    } /* end of else */


  } /* Direct Verification, done and successful */

  (void) fprintf(vis_stdout, "Total Direct Verification Time = %.3f (secs).\n",
                 (util_cpu_time() - overallLap)/1000.0);

  if (verbose >= 1) {
    util_print_cpu_stats(vis_stdout);
  }


  /* RESIDUE VERIFICATION starts here */

  if (numOutputs - numDirectVerify) { /* if residue verification required */
    /* reset all Ids after direct verification as residue verification
     * assigns new Ids.
     */
    Ntk_NetworkForEachNode(specNetwork, listGen, nodePtr) {
      Ntk_NodeSetMddId(nodePtr, unassignedValue);
    }
    Ntk_NetworkForEachNode(implNetwork, listGen, nodePtr) {
      Ntk_NodeSetMddId(nodePtr, unassignedValue);
    }

    /* check if directly verified outputs are to be involved in residue
     * verification
     */
    flagValue = Cmd_FlagReadByName("residue_ignore_direct_verified_outputs");
    if (flagValue != NIL(char)) {
      if ((strcmp(flagValue, "1") == 0) && (numDirectVerify)) {
        ignoreOutputArray = array_alloc(Ntk_Node_t *, numDirectVerify);
      }
    }
    if (ignoreOutputArray == NIL(array_t)) {
      /* fill the output array with all output nodes */
      outputArray = array_alloc(Ntk_Node_t *, array_n(outputOrderArray));
      arrayForEachItem(char *, outputOrderArray, i, name) {
        nodePtr = Ntk_NetworkFindNodeByName(specNetwork, name);
        st_lookup(outputMatch, (char *)nodePtr, &implNodePtr);
        array_insert(Ntk_Node_t *, outputArray, i, implNodePtr);
      }
    } else {
      outputArray = array_alloc(Ntk_Node_t *, array_n(outputOrderArray)-numDirectVerify);
      /* fill the output array with nodes not directly verified */
      for (i = 0; i < (array_n(outputOrderArray) - numDirectVerify); i++) {
        name = array_fetch(char *, outputOrderArray, i);
        nodePtr = Ntk_NetworkFindNodeByName(specNetwork, name);
        st_lookup(outputMatch, (char *)nodePtr, &implNodePtr);
        array_insert(Ntk_Node_t *, outputArray, i, implNodePtr);
      }
      /* fill ignore array with outputs directly verified. */
      for (i = (array_n(outputOrderArray) - numDirectVerify); i < array_n(outputOrderArray); i++) {
        name = array_fetch(char *, outputOrderArray, i);
        nodePtr = Ntk_NetworkFindNodeByName(specNetwork, name);
        st_lookup(outputMatch, (char *)nodePtr, &implNodePtr);
        array_insert(Ntk_Node_t *, ignoreOutputArray, (i-array_n(outputOrderArray)+numDirectVerify) , implNodePtr);
      }
    }


    /* Compute the layers to be used for function composition */
    implLayerArray = ResComputeCompositionLayers(implNetwork, outputArray, ignoreOutputArray);

    /* create the output array for the spec. */
    if (ignoreOutputArray == NIL(array_t)) {
      /* fill the output array with all output nodes */
      arrayForEachItem(char *, outputOrderArray, i, name) {
        nodePtr = Ntk_NetworkFindNodeByName(specNetwork, name);
        array_insert(Ntk_Node_t *, outputArray, i, nodePtr);
      }
    } else {
      /* fill the output array with nodes not directly verified */
      for (i = 0; i < (array_n(outputOrderArray) - numDirectVerify); i++) {
        name = array_fetch(char *, outputOrderArray, i);
        nodePtr = Ntk_NetworkFindNodeByName(specNetwork, name);
        array_insert(Ntk_Node_t *, outputArray, i, nodePtr);
      }
      /* fill ignore array with outputs directly verified. */
      for (i = (array_n(outputOrderArray) - numDirectVerify); i < array_n(outputOrderArray); i++) {
        name = array_fetch(char *, outputOrderArray, i);
        nodePtr = Ntk_NetworkFindNodeByName(specNetwork, name);
        array_insert(Ntk_Node_t *, ignoreOutputArray, (i-array_n(outputOrderArray)+numDirectVerify), nodePtr);
      }
    }

    /* Compute the layers to be used for function composition */
    specLayerArray = ResComputeCompositionLayers(specNetwork, outputArray, ignoreOutputArray);

    /* print the array */
    if (verbose >=3) {
      ResLayerPrintInfo(specNetwork, specLayerArray);
      ResLayerPrintInfo(implNetwork, implLayerArray);
    }

    /* free the ignore array */
    if (ignoreOutputArray != NIL(array_t)) {
      array_free(ignoreOutputArray);
    }

    /* Perform residue verification on the spec. and impl. */
    status = ResidueVerification(specNetwork, implNetwork, outputMatch, inputMatch, numDirectVerify, specLayerArray, implLayerArray, outputArray);

    /* free output array */
    array_free(outputArray);

    if (status) {
      error_append("Residue Verification error\n");
      /* Clean up before you leave */
      error = 1;
      Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
              outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
              oldImplMddIdTable, specLayerArray, implLayerArray);
      return 1; /* error return */
    }


    resultSpec = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(specNetwork,
                                              RES_NETWORK_APPL_KEY);
    resultImpl = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(implNetwork,
                                            RES_NETWORK_APPL_KEY);
    /* Print success message and info */
    if ((ResResidueInfoReadSuccess(resultSpec) == RES_FAIL) &&
        (ResResidueInfoReadSuccess(resultImpl) == RES_FAIL)) {
      /* Clean up before you leave */
      error = 0;
            Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
              outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
              oldImplMddIdTable, specLayerArray, implLayerArray);
      return 0;
    }

    if(verbose >= 2) {
      (void) fprintf(vis_stdout, "Total Compose Time = %3f(secs).\n",
                     Res_composeTime/1000.0);
      (void) fprintf(vis_stdout, "Total Order Time = %3f(secs).\n",
                     Res_orderTime/1000.0);
      (void) fprintf(vis_stdout, "Total Shuffle Time = %3f(secs).\n",
                     Res_shuffleTime/1000.0);

      (void) fprintf(vis_stdout, "Total Smart Var Time = %3f(secs).\n",
                     Res_smartVarTime/1000.0);
    }


  } /* end of residue verification */

  /* Print success message and info */
  if ((ResResidueInfoReadSuccess(resultSpec) == RES_PASS) &&
      (ResResidueInfoReadSuccess(resultImpl) == RES_PASS))
    (void) fprintf(vis_stdout, "Verification of %s and %s successful.\n",
                   Res_ResidueInfoReadName(resultSpec),
                   Res_ResidueInfoReadName(resultImpl));


  if (verbose >= 1) {
    fprintf(vis_stdout, "Specification:\n");
    (void) Res_ResidueInfoPrint(resultSpec);
    fprintf(vis_stdout, "Implementation:\n");
    (void) Res_ResidueInfoPrint(resultImpl);
  }
  if (verbose >= 1) {
    util_print_cpu_stats(vis_stdout);
  }

  (void) fprintf(vis_stdout, "Total Time = %.3f (secs).\n",
                 (util_cpu_time() - overallLap)/1000.0);

  /* no error */
  error = 0;
  Cleanup(error, specNetwork, implNetwork, initManagerHere, done,
          outputMatch, inputMatch, directVerifyMatch, oldSpecMddIdTable,
          oldImplMddIdTable, specLayerArray, implLayerArray);

  /* End of clean up */

  return 0;
} /* End of Res_NetworkResidueVerify */

/*---------------------------------------------------------------------------*/
/* Definition of internal functions                                          */
/*---------------------------------------------------------------------------*/



/*---------------------------------------------------------------------------*/
/* Definition of static functions                                            */
/*---------------------------------------------------------------------------*/

/**Function********************************************************************

  Synopsis [Chooses the primes to process a circuit with those many outputs.]

  Description [Chooses the primes to process a circuit with those many
  outputs. It returns an allocated array of primes selected from PrimePool. The
  number of primes required should exceed the quotient from dividing 2^number
  of outputs by 2^number of directly verified outputs. If there are no directly
  verified outputs, the first prime chosen is 2^LOG2_FIRST_PRIME. The procedure
  is passed the following parameters: number of outputs, the array of primes
  (to be filled) and the number of directly verified outputs.]

  SideEffects [Fills the primes array.]

  See Also    [Res_NetworkResidueVerify]

******************************************************************************/
static int
ChoosePrimes(int numOutputs,
             int **pool,
             int numDirectVerify)
{
  double accumulator = 0.0;
  int i,max, index = 0;
  double factor = log10((double)2.0);

  assert(*pool == NIL(int));

  if (numDirectVerify) {
    accumulator = (double)numDirectVerify;
  } else {
    /* make first prime 2^LOG2_FIRST_PRIME */
    if (numOutputs >= LOG2_FIRST_PRIME) {
      accumulator = (double)LOG2_FIRST_PRIME;
    } else {
      accumulator = (double)numOutputs;
    }
  }

  /* step through primes till their product exceeds the max value of outputs */
  max = 0;
  while (accumulator < ((double)numOutputs)) {
    accumulator += log10((double)PrimePool[max])/factor;
    max++;
  }

  index = 0;
  /* if no direct verification, then set the first prime to be 2^LOG2_FIRST_PRIME */
  if (!numDirectVerify) {
    *pool = ALLOC(int, max+1);
    if (numOutputs >= LOG2_FIRST_PRIME) {
      (*pool)[index++] = (int)pow((double)2.0, (double)LOG2_FIRST_PRIME);
    } else {
      (*pool)[index++] = (int)pow((double)2.0, (double)numOutputs);
    }
  } else {
    *pool = ALLOC(int, max);
  }

  /* fill the array with other primes */
  for(i=0; i < max; i++) {
   (*pool)[index++] = PrimePool[i];
  }

  return index;
} /* End of ChoosePrimes */


/**Function********************************************************************

  Synopsis [Computes the maximum number of outputs a circuit may have in order
  to be processed with the array PrimePool.]

  Description [Computes the maximum number of outputs a circuit may have in
  order to be processed with the array PrimePool. This is the product of all
  the primes in the Prime Pool Table.]

  SideEffects [Updates the static variable maxNumberOfOutputs.]

  SeeAlso     [Res_NetworkResidueVerify]

******************************************************************************/
static int
ComputeMaxNumberOfOutputs(void)
{
  int i;
  double result = 0;
  int maxNumberOfOutputs;

  result = LOG2_FIRST_PRIME;
  for(i = 0; i < PrimePoolSize; i++) {
    result += log10((double)PrimePool[i]);
  } /* End of for */

  maxNumberOfOutputs = (int) (result/log10((double) 2.0)) - 1;

  return (maxNumberOfOutputs);
} /* End of ComputeMaxNumberOfOutputs */


/**Function********************************************************************

  Synopsis    [A procedure restore  MDD Ids from an st table.]

  Description [A procedure restore MDD Ids from an st table. This is to leave
  the network in the state it was in before residue verification was
  called. The procedure's parameters are the network whose IDs need to be
  restored and a table to restore from.]

  SideEffects [The mdd Ids of the network change.]

  SeeAlso     [Res_NetworkResidueVerify SaveOldMddIds]

******************************************************************************/
static void
RestoreOldMddIds(Ntk_Network_t *network,
                 st_table *table)
{
  lsGen listGen;
  Ntk_Node_t *nodePtr;
  int value;
  if (table != NULL) {
    Ntk_NetworkForEachNode(network, listGen, nodePtr) {
      if(st_lookup_int(table, (char *)nodePtr, &value)) {
        Ntk_NodeSetMddId(nodePtr, value);
      } else {
        error_append("Node");
        error_append(Ntk_NetworkReadName(network));
        error_append("should have been in the table.\n");
        (void) lsFinish(listGen);
      }
    }
  }
} /* End of RestoreOldMddIds */


/**Function********************************************************************

  Synopsis [Procedure to generate a match Table with node pointers from a match
  table with names.]

  Description [Procedure to generate a match Table with node pointers from a
  match table with names.The name match table will have pairs of names which
  may be from the spec or the impl. So for each unique pair there are two
  entries in the name match table. The pointer match table is constructed with
  the spec. node pointer as the key. If the node pointer for a name isn't found
  in either network, return NIL (error). The procedure takes in the parameters:
  spec., impl and a name match table and returns a pointer match table
  corresponding to the names.]

  SideEffects   []

  SeeAlso            [Res_NetworkResidueVerify]

******************************************************************************/
static st_table *
GeneratePointerMatchTableFromNameMatch(
                       Ntk_Network_t *specNetwork,
                       Ntk_Network_t *implNetwork,
                       st_table *nameMatchTable)
{
  st_table *pointerMatch;
  Ntk_Node_t *nodePtr, *implNodePtr;
  st_generator *stGen;
  char *key, *value;

  pointerMatch = st_init_table( st_ptrcmp, st_ptrhash);
  st_foreach_item(nameMatchTable, stGen, &key, &value) {
    /* find node in spec */
    nodePtr = Ntk_NetworkFindNodeByName(specNetwork, key);
    if (nodePtr == NIL(Ntk_Node_t)) {
      /* if node not in spec, find in impl */
      implNodePtr = Ntk_NetworkFindNodeByName(implNetwork, key);
      nodePtr = Ntk_NetworkFindNodeByName(specNetwork, value);
    } else {
      implNodePtr = Ntk_NetworkFindNodeByName(implNetwork,value);
    }
    if ((nodePtr == NIL(Ntk_Node_t)) || (implNodePtr == NIL(Ntk_Node_t))) {
      /* error */
      error_append("Nodes not found by the keys in match table.\n");
      st_free_gen(stGen);
      return NIL(st_table);
    }
    st_insert(pointerMatch, (char *)nodePtr, (char *)implNodePtr);
  } /* end of st_foreach_item */

  return(pointerMatch);
} /* End of GeneratePointerMatchTableFromNameMatch */


/**Function********************************************************************

  Synopsis [Generates a pointer match table for the directly verified outputs.]

  Description [Generates a pointer match table for the directly verified
  outputs. Returns NIL if a node isn't found, else returns the table.The
  procedure takes as arguments the spec., the impl., the output match table
  with pointers, the output order array and the number of directly verified
  outputs.]

  SideEffects   []

  SeeAlso            [Res_NetworkResidueVerify]

******************************************************************************/
static st_table *
GenerateDirectVerifyPointerTable(Ntk_Network_t *specNetwork,
                                 Ntk_Network_t *implNetwork,
                                 st_table *outputMatch,
                                 array_t *outputOrderArray,
                                 int numDirectVerify)

{
  char *specName;
  int i;
  Ntk_Node_t *nodePtr, *implNodePtr;
  st_table *directVerifyMatch;

  directVerifyMatch = st_init_table(st_ptrcmp, st_ptrhash);
  for (i = 0; i < numDirectVerify; i++) {
    specName = array_fetch(char *, outputOrderArray, array_n(outputOrderArray) - 1 - i);
    nodePtr = Ntk_NetworkFindNodeByName(specNetwork, specName);
    st_lookup(outputMatch, (char *)nodePtr, &implNodePtr);
    if ((nodePtr == NIL(Ntk_Node_t)) || (implNodePtr == NIL(Ntk_Node_t))) {
      error_append("Couldn't find nodes to directly verify\n");
      st_free_table(directVerifyMatch);
      return NIL(st_table);
    }
    st_insert(directVerifyMatch, (char *)nodePtr, (char *)implNodePtr);
  }
  return (directVerifyMatch);
} /* End of GenerateDirectVerifyPointerTable */


/**Function********************************************************************

  Synopsis [ A procedure to generate a pointer Match table with from
  nodes with identical names.]

  Description [A procedure to generate a pointer Match table with from nodes
  with identical names. This procedure does it for either the inputs or outputs
  depending on the flag. Returns NULL if the impl. does not have a node
  corresponding to the spec. The procedure takes as arguments the spec., the
  impl. and the flag specifying whether the pointer match table is to be built
  for the output or the input.]

  SideEffects   []

  SeeAlso            [Res_NetworkResidueVerify]

******************************************************************************/
static st_table *
GenerateIdentityMatchTable(Ntk_Network_t *specNetwork,
                           Ntk_Network_t *implNetwork,
                           int inputOrOutput)
{
  Ntk_Node_t *nodePtr, *implNodePtr;
  st_table *matchTable;
  lsGen listGen;
  char *name;

  matchTable = st_init_table(st_ptrcmp, st_ptrhash);
  if (matchTable == NULL) return(NIL(st_table));

  if (inputOrOutput == PRIMARY_INPUTS) {
    Ntk_NetworkForEachCombInput(specNetwork, listGen, nodePtr) {
      name = Ntk_NodeReadName(nodePtr);
      implNodePtr = Ntk_NetworkFindNodeByName(implNetwork, name);
      if (implNodePtr == NIL(Ntk_Node_t)) {
        error_append(name);
        error_append(" node does not have corresponding node in impl.");
        st_free_table(matchTable);
        return (NIL(st_table));
      }
      st_insert(matchTable, (char *)nodePtr, (char *)implNodePtr);
    }
  } else if (inputOrOutput == PRIMARY_OUTPUTS) {
    Ntk_NetworkForEachCombOutput(specNetwork, listGen, nodePtr) {
      name = Ntk_NodeReadName(nodePtr);
      implNodePtr = Ntk_NetworkFindNodeByName(implNetwork,name);
      if (implNodePtr == NIL(Ntk_Node_t)) {
        error_append(name);
        error_append(" node does not have corresponding node in impl.");
        st_free_table(matchTable);
        return (NIL(st_table));
      }
      st_insert(matchTable, (char *)nodePtr, (char *)implNodePtr);
    }
  }
  return (matchTable);
} /* End of GenerateIdentityMatchTable */

/**Function********************************************************************

  Synopsis    [Initialize bdd_managers for the networks.]

  Description [Initialize bdd_managers for the networks. If both managers are
  NIL , initialize a DD Manager here and set it in both networks. If the
  manager is not NIL, then they have to be the same. If different, keep the
  spec network manager. Return a flag if managers are initialized here. The
  procedure takes as arguments the spec., the impl. and the flag specifying
  whether the the manager was initialized here (to be filled).]

  SideEffects [Network manager values might change.]

  SeeAlso     [Res_NetworkResidueVerify]

******************************************************************************/
static bdd_manager *
Initializebdd_manager(Ntk_Network_t *specNetwork,
                    Ntk_Network_t *implNetwork,
                    int *initManagerHere)
{
  bdd_manager *ddManager;

  /* Read the mdd Manager (or create it if necessary) */
  ddManager = (bdd_manager *)Ntk_NetworkReadMddManager(specNetwork);

  /* To set the spec manager the same as the impl. manager, either
   * both are nil, or the impl manager is freed and set to the
   * spec manager
   */
  if(ddManager != (bdd_manager *)Ntk_NetworkReadMddManager(implNetwork)) {
    if ((bdd_manager *)Ntk_NetworkReadMddManager(implNetwork) != NIL(bdd_manager)) {
      /* unacceptable if the impl. manager is different from NIl or
       * from the spec manager
       */
      mdd_quit(Ntk_NetworkReadMddManager(implNetwork));
    }
    Ntk_NetworkSetMddManager(implNetwork, (mdd_manager *)ddManager);
  }

  /* if the spec. manager is NIL, then network initialize manager */
  if (ddManager ==  NIL(bdd_manager)) {
    /* flag to say that manager is verified here */
    *initManagerHere = 1;
    ddManager = (bdd_manager *)Ntk_NetworkInitializeMddManager(specNetwork);
    Ntk_NetworkSetMddManager(implNetwork, (mdd_manager *)ddManager);
  }
  return (ddManager);
} /* End of Initializebdd_manager */

/**Function********************************************************************

  Synopsis [Create the basic result structures for both the specification and
  implementation.]

  Description [Create the basic result structures for both the specification
  and implementation. This procedure returns a flag that specifies if the
  previous verification was a success. If previous information is to be used
  only the condition that either the same spec and impl were verified before,
  is allowed. If the previous verification had the same number of directly
  verified outputs and the verification was a success, a success is returned.
  The impl. result will be overwritten in any case. Returns a flag that
  indicates if verification is to be done. The procedure records the number of
  outputs, inputs, directly verified outputs, spec and impl name. Adds the
  result structure as a hook to the network. The procedure takes as arguments
  the spec., the impl. and the number of directly verified outputs.]

  SideEffects [Changes the result structure in the 2 networks.]

  SeeAlso [Res_NetworkResidueVerify]

******************************************************************************/
static int
SetBasicResultInfo (Ntk_Network_t *specNetwork,
                    Ntk_Network_t *implNetwork,
                    int numDirectVerify)
{
  int numInputs;
  int numOutputs;
  char *specName;
  char *implName;
  Res_ResidueInfo_t *resultSpec;
  Res_ResidueInfo_t *resultImpl;

  /* if previous verification to be considered, make sure the
   *  verification was with the same spec network and the number
   *  of directly verified outputs are the same.
   */
  resultSpec = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(specNetwork,
                                                    RES_NETWORK_APPL_KEY);

  if (resultSpec != NIL(Res_ResidueInfo_t)) {
    if ((strcmp(ResResidueInfoReadNameVerifiedAgainst(resultSpec),
              Ntk_NetworkReadName(implNetwork)) == 0) &&
        (ResResidueInfoReadNumDirectVerifiedOutputs(resultSpec) ==
                                                 numDirectVerify) &&
        (ResResidueInfoReadSuccess(resultSpec) == RES_PASS)) {
      /* if already verified then done, return success (0) */
      return RES_VERIFY_DONE;
    }
    /* if the above conditions are not satisfied, attempt
     * verification again
     */
    Ntk_NetworkFreeApplInfo(specNetwork, RES_NETWORK_APPL_KEY );
  }


  /* create result structure */
  resultSpec = (Res_ResidueInfo_t *)
    ResNetworkResidueInfoReadOrCreate(specNetwork);
  /* add hook to network */
  Ntk_NetworkAddApplInfo(specNetwork, RES_NETWORK_APPL_KEY,
                 (Ntk_ApplInfoFreeFn) Res_ResidueInfoFreeCallback,
                 (void *)resultSpec);

  /* number of outputs */
  numOutputs = Ntk_NetworkReadNumCombOutputs(specNetwork);
  ResResidueInfoSetNumOutputs(resultSpec, numOutputs);
  /* number of Inputs */
  numInputs = Ntk_NetworkReadNumCombInputs(specNetwork);
  ResResidueInfoSetNumInputs(resultSpec, numInputs);
  /* impl name */
  implName = util_strsav(Ntk_NetworkReadName(implNetwork));
  ResResidueInfoSetNameVerifiedAgainst(resultSpec, implName);
  /* number of directly verified outputs */
  ResResidueInfoSetNumDirectVerifiedOutputs(resultSpec, numDirectVerify);

  /*
   * Assumption: The implementation residue information is invalid even
   * if it does exist and will be overwritten
   */
  resultImpl = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(implNetwork,
                                        RES_NETWORK_APPL_KEY);
  /* free existing structure */
  if (resultImpl != NIL(Res_ResidueInfo_t)) {
    Ntk_NetworkFreeApplInfo(implNetwork,RES_NETWORK_APPL_KEY);
  }

  /* create a new structure for the implementation network */
  resultImpl = (Res_ResidueInfo_t *)
    ResNetworkResidueInfoReadOrCreate(implNetwork);
  Ntk_NetworkAddApplInfo(implNetwork, RES_NETWORK_APPL_KEY,
                (Ntk_ApplInfoFreeFn) Res_ResidueInfoFreeCallback,
                (void *)resultImpl);


  /*
   * Get some information about the network  and initialize the residue
   * information for the implementation network.
   */

  /* number of outputs */
  assert (numOutputs == Ntk_NetworkReadNumCombOutputs(implNetwork));
  ResResidueInfoSetNumOutputs(resultImpl, numOutputs);
  /* number of Inputs */
  assert (numInputs == Ntk_NetworkReadNumCombInputs(implNetwork));
  ResResidueInfoSetNumInputs(resultImpl, numInputs);
  /* spec name */
  specName = util_strsav(Ntk_NetworkReadName(specNetwork));
  ResResidueInfoSetNameVerifiedAgainst(resultImpl, specName);
  /* number of directly verified outputs */
  ResResidueInfoSetNumDirectVerifiedOutputs(resultImpl, numDirectVerify);

  return RES_VERIFY_IGNORE_PREV_RESULTS;
} /* End of SetBasicResultInfo */

/**Function********************************************************************

  Synopsis [Cleanup procedure to free all data structures allocated here.]

  Description [Cleanup procedure to free all data structures allocated here.
  Quit manager if created here. Quit result data structures if created here.
  The check against RES_VERIFY_NOTHING is to check if the cleanup is called
  before the result structures were allocated. The arguments to this procedure
  are an error flag staying if this cleanup is under an error condition, the
  spec network, impl. network, a flag that says if the manager was initialized
  here, a flag that indicates if this verification has already been performed,
  an output pointer match table, an input pointer match table, a directly
  verified output pointer match table, a table that contains saved mdds for the
  spec. and the impl., and the layer structures for the spec. and the impl.]

  SideEffects [All data structures allocated in the Res_NetworkResidueVerify
  procedure will be freed here.]

  SeeAlso     [Res_NetworkResidueVerify]

******************************************************************************/
static void
Cleanup(int error,
        Ntk_Network_t *specNetwork,
        Ntk_Network_t *implNetwork,
        int initManagerHere,
        int done,
        st_table *outputMatch,
        st_table *inputMatch,
        st_table *directVerifyMatch,
        st_table *oldSpecMddIdTable,
        st_table *oldImplMddIdTable,
        array_t *specLayerArray,
        array_t *implLayerArray)
{
  bdd_manager *ddManager;

  if (initManagerHere) {
    ddManager = (bdd_manager *)Ntk_NetworkReadMddManager(specNetwork);
    if (ddManager != NIL(bdd_manager)) {
      mdd_quit(ddManager);
      Ntk_NetworkSetMddManager(specNetwork, NIL(mdd_manager));
      Ntk_NetworkSetMddManager(implNetwork, NIL(mdd_manager));
    }
  }

  if (done != RES_VERIFY_NOTHING) {  /* if result structure allocated */
    if (error) { /* on error free results */
      if (done == RES_VERIFY_IGNORE_PREV_RESULTS) {
        /* if spec result was created here */
        Ntk_NetworkFreeApplInfo(specNetwork,RES_NETWORK_APPL_KEY);
      }
      Ntk_NetworkFreeApplInfo(implNetwork,RES_NETWORK_APPL_KEY);
    }
  }
  if (outputMatch != NIL(st_table)) {
    st_free_table(outputMatch);
  }
  if (inputMatch != NIL(st_table)) {
    st_free_table(inputMatch);
  }
  if (directVerifyMatch != NIL(st_table)) {
    st_free_table(directVerifyMatch);
  }

  if (oldSpecMddIdTable != NIL(st_table)) {
    RestoreOldMddIds(specNetwork, oldSpecMddIdTable);
    st_free_table(oldSpecMddIdTable);
  }
  if (oldImplMddIdTable != NIL(st_table)) {
    RestoreOldMddIds(implNetwork, oldImplMddIdTable);
    st_free_table(oldImplMddIdTable);
  }
  if (specLayerArray != NULL) {
    ResLayerArrayFree(specLayerArray);
  }
  if (implLayerArray != NULL) {
    ResLayerArrayFree(implLayerArray);
  }
  return;
} /* End of Cleanup */


/**Function********************************************************************

  Synopsis [Save mdd ids for each node.]

  Description [Save old mdd ids for each node and returns a table with the
  nodes and the Ids.]

  SideEffects   []

  SeeAlso [Res_NetworkResidueVerify RestoreOldMddIds]

******************************************************************************/
static st_table *
SaveOldMddIds(Ntk_Network_t *network)
{
  st_table *oldMddIdTable;
  Ntk_Node_t *nodePtr;
  lsGen listGen;             /* To iterate over outputList */

  oldMddIdTable = st_init_table(st_ptrcmp, st_ptrhash);
  if (oldMddIdTable == NULL) return NIL(st_table);

  Ntk_NetworkForEachNode(network, listGen, nodePtr) {
    st_insert(oldMddIdTable, (char *)nodePtr,
              (char *)(long)Ntk_NodeReadMddId(nodePtr));
  }
  return(oldMddIdTable);
}

/**Function********************************************************************

  Synopsis [Perform direct verification of the given outputs.]

  Description [Perform direct verification of the given outputs. If error,
  returns 1, if successful returns 0. The directVerifyMatch table contains the
  node pointer matches for the outputs to be directly verified. The procedure
  first checks if the input variables are ordered.  If not ordered, it orders
  the variables. builds two array with corresponding nodes to be directly
  verified and a permutation array for the correspondence of the inputs.  The
  outputs arrays are ordered starting with the LSB. For each of these nodes in
  the array, the bdd is built and compared. Since the primary input variables
  in the spec and the impl may have different mdd ids, a step of bdd permute is
  performed on the impl bdd to represent it in terms of the spec PI
  variables. The resultant Bdds are checked to see if they are identical.  The
  result structure is updated. The parameters to this procedure are the spec.
  and the impl. network, the match table of the pointers of the directly
  verified outputs, the tables with the input and output pointer matches and
  the order array of the outputs.]

  SideEffects   [Result Structure is updated.]

  SeeAlso     [Res_NetworkResidueVerify]

******************************************************************************/
static int
DirectVerification(Ntk_Network_t *specNetwork,
                   Ntk_Network_t *implNetwork,
                   st_table *directVerifyMatch,
                   st_table *inputMatch,
                   st_table *outputMatch,
                   array_t *outputOrderArray)
{

    Ntk_Node_t *nodePtr, *implNodePtr;         /* node variables */
    long startTime, endTime, directVerifyTime; /* to measure elapsed time */
    long lapTimeSpec, lapTimeImpl;             /* to measure elapsed time */
    bdd_node *specBDD, *implBDD, *permutedBDD;   /* bdds of direct verified outputs */
    lsGen listGen;                             /* To iterate over outputList */
    int *permut;                              /* permutation array to store
                                               * correspondence of inputs
                                               */
    int specMddId, implMddId;
    Ntk_Node_t **specArray, **implArray;      /* arrays to store the
                                               * corresponding nodes of the
                                               * spec. and the impl.
                                               */
    st_generator *stGen;
    lsList dummy;                               /* dummy list fed to the ord
                                                 * package.
                                                 */
    char *key, *value;                          /* variables to read values
                                                 * from the st_table
                                                 */
    int index, i;                               /* iterators */
    char *name;                                 /* variable to read node name */
    int numOutputs;                             /* total number of outputs of
                                                 * the spec.(impl).
                                                 */
    bdd_manager *ddManager;                     /* the bdd manager */
    bdd_reorder_type_t oldDynMethod, dynMethod = BDD_REORDER_SAME;
                                                /* dynamic reordering methods */
    int dynStatus = 0;                          /* original status of the manager
                                                 * w. r. t. dynamic reordering
                                                 */
    boolean dyn;                                /* current dynamic reordering
                                                 * status
                                                 */
    int verbose;                                /* verbosity level */
    char  *flagValue;                           /* string to hold "Set" variable
                                                 * value
                                                 */
    Res_ResidueInfo_t *resultSpec;              /* result structure for the
                                                 * spec.
                                                 */
    Res_ResidueInfo_t *resultImpl;              /* result structure for the
                                                 * impl.
                                                 */
    int specSize, implSize;                     /* sizes of bdds */
    mdd_t *fnMddT;                              /* mdd_t structure to calculate sizes */


    /* Initializations */
    dummy = (lsList)0;
    lapTimeSpec = 0;
    lapTimeImpl = 0;
    dyn = FALSE;
    verbose = 0;

    /* read verbosity value */
    flagValue = Cmd_FlagReadByName("residue_verbosity");
    if (flagValue != NIL(char)) {
      verbose = atoi(flagValue);
    }

    /* read if dynamic ordering is required */
    flagValue = Cmd_FlagReadByName("residue_autodyn_direct_verif");
    if (flagValue != NIL(char)) {
      dyn = (strcmp(flagValue, "1") == 0) ? TRUE : FALSE;
    }
    /* read method for dynamic reordering */
    if (dyn == TRUE) {
      flagValue = Cmd_FlagReadByName("residue_direct_dyn_method");
      if (flagValue != NULL) {
        dynMethod = DecodeDynMethod(flagValue);
      } else {
        dynMethod = BDD_REORDER_SAME;
      }
    }

    /* read manager from network */
    ddManager = (bdd_manager *)Ntk_NetworkReadMddManager(specNetwork);
    /* save old values for dynamic reordering */
    if (dyn == TRUE) {
      dynStatus = bdd_reordering_status(ddManager, &oldDynMethod);
      bdd_dynamic_reordering(ddManager, dynMethod, BDD_REORDER_VERBOSITY_DEFAULT);
    }

    /* find total time elapsed */
    directVerifyTime = util_cpu_time();

    /* find number of outputs to be directly verified */
    numOutputs = st_count(directVerifyMatch);

    /*
     * Order primary input variables in the network to build the BDDs for
     * outputs to be directly verified.
     */
    if (Ord_NetworkTestAreVariablesOrdered(specNetwork,
                                           Ord_InputAndLatch_c) == FALSE) {
      /* order the variables in the network since not done */
      startTime = util_cpu_time();
      Ord_NetworkOrderVariables(specNetwork, Ord_RootsByDefault_c,
                      Ord_NodesByDefault_c, FALSE, Ord_InputAndLatch_c,
                      Ord_Unassigned_c, dummy, 0);

      endTime = util_cpu_time();
      lapTimeSpec += endTime - startTime;

      startTime = endTime;
      Ord_NetworkOrderVariables(implNetwork, Ord_RootsByDefault_c,
                      Ord_NodesByDefault_c, FALSE, Ord_InputAndLatch_c,
                      Ord_Unassigned_c, dummy, 0);
      lapTimeImpl += endTime - startTime;

    } else {
      /* if order is not specified, assume the same order for spec.
       * and implementation
       */
      Ntk_NetworkForEachCombInput(specNetwork, listGen, nodePtr) {
        assert(Ntk_NodeReadMddId(nodePtr) != NTK_UNASSIGNED_MDD_ID);
        st_lookup(inputMatch, (char *)nodePtr, &implNodePtr);
        Ntk_NodeSetMddId(implNodePtr, Ntk_NodeReadMddId(nodePtr));
      }
    }

    if (verbose >= 5) {
      Ntk_NetworkForEachCombInput(specNetwork, listGen, nodePtr) {
        specMddId = Ntk_NodeReadMddId(nodePtr);
        if (specMddId != NTK_UNASSIGNED_MDD_ID) {
          fprintf(vis_stdout, "%s ", Ntk_NodeReadName(nodePtr));
        }
      }
      fprintf(vis_stdout, "\n");
      Ntk_NetworkForEachCombInput(specNetwork, listGen, nodePtr) {
        specMddId = Ntk_NodeReadMddId(nodePtr);
        if (specMddId != NTK_UNASSIGNED_MDD_ID) {
          fprintf(vis_stdout, "%d ", specMddId);
        }
      }
      fprintf(vis_stdout, "\n");
    }

    /* build arrays of corresponding nodes to be directly verified */
    specArray = ALLOC(Ntk_Node_t *, numOutputs);
    implArray = ALLOC(Ntk_Node_t *, numOutputs);
    index = 0;
    /* Order array starting from the LSB, so direct verification is performed
     * starting from the inputs.
     */
    for (i = 0; i < array_n(outputOrderArray); i++) {
      name = array_fetch(char *, outputOrderArray, array_n(outputOrderArray)-1-i);
      nodePtr = Ntk_NetworkFindNodeByName(specNetwork, name);
      /* find node in direct verify match table */
      if (st_lookup(directVerifyMatch, (char *)nodePtr, (char **)&value)) {
        specArray[index] = (Ntk_Node_t *)nodePtr;
        implArray[index] = (Ntk_Node_t *)value;
        index++;
      }
    }
    /* number of outputs in the arrays should be as many entries as the match
     * table.
     */
    assert(numOutputs == index);

    /* Create a permutation array for the specMddId and implMddId input nodes */
    permut = ALLOC(int, bdd_num_vars(ddManager));
    for (i= 0; (unsigned) i < bdd_num_vars(ddManager); i++) {
      permut[i] = i;
    }
    st_foreach_item(inputMatch, stGen, &key, &value) {
      nodePtr = (Ntk_Node_t *)key;
      implNodePtr = (Ntk_Node_t *)value;
      if ((nodePtr == NIL(Ntk_Node_t)) || (implNodePtr == NIL(Ntk_Node_t))){
        error_append("Input match values do not return");
        error_append("valid node pointers.\n");
        /* Clean up */
        FREE(permut);
        FREE(specArray);
        FREE(implArray);
        st_free_gen(stGen);
        return 1;
      }
      /* create the array with the impl. vars to be composed with spec. vars. */
      specMddId = Ntk_NodeReadMddId(nodePtr);
      implMddId = Ntk_NodeReadMddId(implNodePtr);
      /* there should be no node with NTK_UNASSIGNED_MDD_ID due to the
       * ordering above
       */
      assert(specMddId != NTK_UNASSIGNED_MDD_ID);
      assert(implMddId != NTK_UNASSIGNED_MDD_ID);
      permut[implMddId] = specMddId;

    } /* end of input match */

    /*
     * Build BDDs for each output to be directly verified and check
     * for identical BDDs in spec. and impl.
     */
    for (i = 0; i < numOutputs; i++) {
      /* build the spec BDD */
      startTime = util_cpu_time();
      specBDD = BuildBDDforNode(specNetwork, specArray[i], PRIMARY_INPUTS);
      if (specBDD == NIL(bdd_node)) {
        error_append("Unable to build spec. BDD for the direct verification output");
        error_append(Ntk_NodeReadName(specArray[i]));
        error_append(".\n");
        /* Clean up */
        FREE(permut);
        FREE(specArray);
        FREE(implArray);
        return 1; /* error status */
      } /* end of if spec BDD is NIL */
      endTime = util_cpu_time();
      lapTimeSpec += endTime - startTime;

      /* build the impl BDD */
      startTime = endTime;
      implBDD = BuildBDDforNode(implNetwork, implArray[i], PRIMARY_INPUTS);
      if (implBDD == NIL(bdd_node)) {
        error_append("Unable to build spec. BDD for the direct verification output");
        error_append(Ntk_NodeReadName(implArray[i]));
        error_append(".\n");
        /* Clean up */
        bdd_recursive_deref(ddManager, specBDD);
        FREE(permut);
        FREE(specArray);
        FREE(implArray);
        return 1; /* error status */
      } /* end of if spec BDD is NIL */
      endTime = util_cpu_time();
      lapTimeImpl += endTime - startTime;

      /* call bdd permute to compose the impl variables with the spec
       * variables.
       */
      startTime = endTime;
      bdd_ref(permutedBDD = bdd_bdd_permute(ddManager, implBDD, permut));
      bdd_recursive_deref(ddManager, implBDD);
      endTime = util_cpu_time();
      lapTimeSpec += (endTime - startTime)/2;
      lapTimeImpl += (endTime - startTime)/2;
      implBDD = permutedBDD;
      if (implBDD == NIL(bdd_node)) {
        error_append("Permuting the impl bdd in terms of spec bdd vars failed\n");
        /* Clean up */
        bdd_recursive_deref(ddManager, specBDD);
        FREE(permut);
        FREE(specArray);
        FREE(implArray);
        return 1; /* error status */
      }

      /* compare the bdds */
      if(specBDD != implBDD)  {
        /* error since spec and impl are not the same */
        /* update result structure */
        if (verbose >= 2) {
          (void)fprintf(vis_stdout, "Vector where the two networks differ :\n");
          (void)fprintf(vis_stdout, "Specification Input Names :\n");
          ExtractACubeOfDifference(ddManager, specNetwork, specBDD, implBDD);
        }
        resultSpec = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(specNetwork,
                                          RES_NETWORK_APPL_KEY);
        resultImpl = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(implNetwork,
                                          RES_NETWORK_APPL_KEY);
        ResResidueInfoSetDirectVerificationSuccess(resultSpec, RES_FAIL);
        ResResidueInfoSetDirectVerificationSuccess(resultImpl, RES_FAIL);
        (void) fprintf(vis_stdout, "%.2f (secs) spent in failed direct verification.\n",
                       (util_cpu_time() - directVerifyTime)/1000.0);
        fprintf(vis_stdout, "Residue Direct Verification failed at output node ");
        fprintf(vis_stdout, "%s", Ntk_NodeReadName(specArray[i]));
        fprintf(vis_stdout, " of the spec.\n");
        fprintf(vis_stdout, "Spec. did not match Impl.\n");
        /* Clean up */
        /* free the bdds just created */
        bdd_recursive_deref(ddManager, specBDD);
        bdd_recursive_deref(ddManager, implBDD);
        FREE(permut);
        FREE(specArray);
        FREE(implArray);
        return 0;
      } /* end if spec BDD != impl BDD */

      /* if the bdds are equal, print some information */
      if (verbose >= 2) {
        fprintf(vis_stdout, "%d out of %d ", i + 1 ,numOutputs);
        fprintf(vis_stdout, "direct verification outputs done.\n");
      }
      if (verbose >= 3) {
        fprintf(vis_stdout, "%s(spec)/%s(impl) output verified. \n",
                Ntk_NodeReadName(specArray[i]), Ntk_NodeReadName(implArray[i]));
        bdd_ref(specBDD);
        fnMddT = bdd_construct_bdd_t(ddManager, specBDD);
        specSize = bdd_size(fnMddT);
        bdd_free(fnMddT);
        bdd_ref(implBDD);
        fnMddT = bdd_construct_bdd_t(ddManager, implBDD);
        implSize = bdd_size(fnMddT);
        bdd_free(fnMddT);
        fprintf(vis_stdout, "Size of %s(spec) = %d, Size of %s(impl) = %d\n",
         Ntk_NodeReadName(specArray[i]) ,specSize, Ntk_NodeReadName(implArray[i]), implSize);
        fprintf(vis_stdout, "%.3f spec time elapsed, %.3f impl. time elapsed.\n", lapTimeSpec/1000.0,
                lapTimeImpl/1000.0);
      }
      /* free the bdds just created */
      bdd_recursive_deref(ddManager, specBDD);
      bdd_recursive_deref(ddManager, implBDD);

    } /* end of for-loop that iterates through the nodes to be directly
       * verified.
       */

    FREE(permut);
    FREE(specArray);
    FREE(implArray);

    /* set direct verification success info */
    /* update result structure */
    resultSpec = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(specNetwork,
                                                        RES_NETWORK_APPL_KEY);
    resultImpl = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(implNetwork,
                                                        RES_NETWORK_APPL_KEY);
    ResResidueInfoSetDirectVerificationSuccess(resultSpec, RES_PASS);
    ResResidueInfoSetCpuDirectVerif(resultSpec, (float) lapTimeSpec);
    ResResidueInfoSetDirectVerificationSuccess(resultImpl, RES_PASS);
    ResResidueInfoSetCpuDirectVerif(resultImpl, (float) lapTimeImpl);

    /* Print success message */
    fprintf(vis_stdout, "Residue Direct Verification successful.\n");

    /* Print Time taken for direct verification */
    if (verbose >= 1) {
      (void) fprintf(vis_stdout, "%.2f (secs) spent in Direct verification.\n",
                       (util_cpu_time() - directVerifyTime)/1000.0);
    }

    /* Print which outputs were directly verified and time spent for
     * the spec and the impl
     */
    if (verbose >= 2) {
      fprintf(vis_stdout, "Time taken to build spec. BDD = %.3f\n",
              ResResidueInfoReadCpuDirectVerif(resultSpec)/1000.0);
      fprintf(vis_stdout, "Time taken to build impl. BDD = %.3f\n",
              ResResidueInfoReadCpuDirectVerif(resultImpl)/1000.0);
      st_foreach_item(directVerifyMatch, stGen, &key, &value) {
        fprintf(vis_stdout, "%s ", Ntk_NodeReadName((Ntk_Node_t *)key));
      }
      fprintf(vis_stdout, "verified successfully.\n");
    }

    /* Print order of variables of this verification */
    if (verbose >= 3) {
      Ord_NetworkPrintVariableOrder(vis_stdout, specNetwork,
      Ord_InputAndLatch_c);
      Ord_NetworkPrintVariableOrder(vis_stdout, implNetwork,
      Ord_InputAndLatch_c);
    }

    /* restore the old values for dynamic reordering */
    if(dyn == TRUE) {
      bdd_dynamic_reordering(ddManager, oldDynMethod, BDD_REORDER_VERBOSITY_DEFAULT);
      if (!dynStatus) {
        bdd_dynamic_reordering_disable(ddManager);
      }
    }

    return 0; /* direct verification success */
} /* End of Direct Verification */


/**Function********************************************************************

  Synopsis [Decode the option of reordering.]

  Description [Decode the option of reordering. Returns the dynMethod value.]

  SideEffects   []

******************************************************************************/
static bdd_reorder_type_t
DecodeDynMethod(char *dynMethodString)
{
  bdd_reorder_type_t dynMethod;

  /* Translate reordering string to specifying method */
  if (dynMethodString == NIL(char)) {
    dynMethod = BDD_REORDER_SIFT;
  } else if (strcmp(dynMethodString, "same") == 0) {
    dynMethod = BDD_REORDER_SAME;
  } else if (strcmp(dynMethodString, "none") == 0) {
    dynMethod = BDD_REORDER_NONE;
  } else if (strcmp(dynMethodString, "random") == 0) {
    dynMethod = BDD_REORDER_RANDOM;
  } else if (strcmp(dynMethodString, "randompivot") == 0) {
    dynMethod = BDD_REORDER_RANDOM_PIVOT;
  } else if (strcmp(dynMethodString, "sift") == 0) {
    dynMethod = BDD_REORDER_SIFT;
  } else if (strcmp(dynMethodString, "siftconverge") == 0) {
    dynMethod = BDD_REORDER_SIFT_CONVERGE;
  } else if (strcmp(dynMethodString, "symmsift") == 0) {
    dynMethod = BDD_REORDER_SYMM_SIFT;
  } else if (strcmp(dynMethodString, "symmsiftconverge") == 0) {
    dynMethod = BDD_REORDER_SYMM_SIFT_CONV;
  } else if (strcmp(dynMethodString, "window2") == 0) {
    dynMethod = BDD_REORDER_WINDOW2;
  } else if (strcmp(dynMethodString, "window3") == 0) {
    dynMethod = BDD_REORDER_WINDOW3;
  } else if (strcmp(dynMethodString, "window4") == 0) {
    dynMethod = BDD_REORDER_WINDOW4;
  } else if (strcmp(dynMethodString, "window2converge") == 0) {
    dynMethod = BDD_REORDER_WINDOW2_CONV;
  } else if (strcmp(dynMethodString, "window3converge") == 0) {
    dynMethod = BDD_REORDER_WINDOW3_CONV;
  } else if (strcmp(dynMethodString, "window4converge") == 0) {
    dynMethod = BDD_REORDER_WINDOW4_CONV;
  } else if (strcmp(dynMethodString, "groupsift") == 0) {
    dynMethod = BDD_REORDER_GROUP_SIFT;
  } else if (strcmp(dynMethodString, "groupsiftconverge") == 0) {
    dynMethod = BDD_REORDER_GROUP_SIFT_CONV;
  } else if (strcmp(dynMethodString, "anneal") == 0) {
    dynMethod = BDD_REORDER_ANNEALING;
  } else if (strcmp(dynMethodString, "genetic") == 0) {
    dynMethod = BDD_REORDER_GENETIC;
  } else if (strcmp(dynMethodString, "linear") == 0) {
    dynMethod = BDD_REORDER_LINEAR;
  } else if (strcmp(dynMethodString, "linearconverge") == 0) {
    dynMethod = BDD_REORDER_LINEAR_CONVERGE;
  } else if (strcmp(dynMethodString, "exact") == 0) {
    dynMethod = BDD_REORDER_EXACT;
  } else {
    dynMethod = BDD_REORDER_SIFT;
  }
  return dynMethod;
} /* End of DecodeDynMethod */



/**Function********************************************************************

  Synopsis  [Main Function to perform residue verification.]

  Description [Main Function to perform residue verification.  The network
  parameters are in a specific order: SPECIFICATION first, IMPLEMENTATION
  second.  All other parameters store values of the specification. The
  procedure first turns off dynamic reordering unless specified otherwise. The
  array of required primes are computed and the cudd manager is
  initialized. The main loop iterates over the primes. The residue ADD is
  constructed for as many variables as POs with respect to each prime.  Then
  calls a procedure which composes the networks (in layers) into the residue
  ADD. The final ADD is compared for both the spec and the impl.  A sub-routine
  composes the network into the residue ADD depending on the composition
  method.  The final ADDs for the specification and the implementation are
  checked against each other. The procedure returns 0 if it were unable to
  complete for some reason, like memory failure, incomplete networks, etc.  The
  procedure returns 0 if successful in building the BDDs of the two
  circuits. The parameters to this procedure are spec. network, impl. network,
  output pointer match table, input pointer match table, number of directly
  verified outputs, layer structure of the spec. and the impl. and an array of
  nodes with outputs for residue verification.]

  SideEffects   []

******************************************************************************/
static int
ResidueVerification(Ntk_Network_t *specNetwork,
                    Ntk_Network_t *implNetwork,
                    st_table *outputMatch,
                    st_table *inputMatch,
                    int numDirectVerify,
                    array_t *specLayerArray,
                    array_t *implLayerArray,
                    array_t *outputArray)
{
  int numOutputs;                 /* number of outputs in the networks */
  int actualOutputs;                 /* number of outputs in the networks */
  int msbId;                      /* stores the top Id available */
  int msbLsb;                     /* 1 means Msb on top */

  Ntk_Node_t *nodePtr, *implNodePtr; /* variables to store nodes in networks */

  Res_ResidueInfo_t *resultSpec;   /* spec. result structure */
  Res_ResidueInfo_t *resultImpl;   /* impl. result structure */

  int verbose;                     /* verbosity value */
  char *flagValue;                 /* string to store flag values */
  int i;                           /* iterating index */

  lsGen listGen;                   /* list generator for looping over nodes
                                    * in a network.
                                    */
  st_generator *stGen;     /* generator to step through st_table */
  char *key, *value;               /* variables to read in st-table values */
  long overallLap;      /* to measure elapsed time */
  long lap;     /* to measure elapsed time */
  int primeIndex;       /* index to iterate over prime array */
  bdd_manager *ddManager;      /* Manager read from the network */
  bdd_node *implADD, *specADD, *tmpDd; /* final ADDs after composition */
  int specSize, implSize;               /* sizes of bdds */
  int specMddId, implMddId;  /* id variables for nodes */
  bdd_node *residueDd;  /* residue ADD (n x m) */
  int *permut;  /* array to permute impl ADD variables to spec.
                                 * ADD variables.
                                 */
  int numOfPrimes;      /* Number of primes needed for verification */
  int *primeTable;      /* array to store primes needed for current
                                 * verification
                                 */
  bdd_reorder_type_t oldDynMethod, dynMethod; /* dynamic reordering
                                               * methods
                                               */
  int dynStatus;                /* Status of manager w.r.t. original
                                 * reordering
                                 */
  boolean dyn;          /* flag to indicate dynamic reordering
                                 * is turned on.
                                 */
  mdd_t *fnMddT;                /* mdd_t structure to calculate sizes */
  int unassignedValue;          /* NTK_UNASSIGNED_MDD_ID value holder */
  array_t *implOutputArray;     /* array of output nodes of the impl.in consideration
                                 * for composition
                                 */

  /* Initialization */
  verbose = 0;
  unassignedValue =  NTK_UNASSIGNED_MDD_ID;
  numOfPrimes = 0;
  msbLsb = 1; /* default value msb is on top */
  primeTable = NULL;
  overallLap = util_cpu_time();
  dyn = FALSE; /* default dynamic reordering disabled */
  permut = NULL;

  /* specify if the top var of the residue ADD is the MSB/LSB */
  flagValue = Cmd_FlagReadByName("residue_top_var");
  if (flagValue != NIL(char) && strcmp(flagValue,"lsb") == 0) {
    msbLsb = 0;
  } else {
    msbLsb = 1;
  }

  /* initialize number of outputs */
  actualOutputs = Ntk_NetworkReadNumCombOutputs(specNetwork);

  /* Read the mdd Manager (or create it if necessary) */
  ddManager = (bdd_manager *)Ntk_NetworkReadMddManager(specNetwork);
    /* save old dynamic reordering values */
  dynStatus = bdd_reordering_status(ddManager, &oldDynMethod);

  /* read verbosity value */
  flagValue = Cmd_FlagReadByName("residue_verbosity");
  if (flagValue != NIL(char)) {
    verbose = atoi(flagValue);
  }

  /* read if dynamic ordering is required */
  flagValue = Cmd_FlagReadByName("residue_autodyn_residue_verif");
  if (flagValue != NIL(char)) {
    dyn = (strcmp(flagValue,"1")==0) ? TRUE : FALSE;
  }
  /* read method of dynamic reordering */
  if (dyn == TRUE) {
    flagValue = Cmd_FlagReadByName("residue_residue_dyn_method");
    if ( flagValue != NULL) {
      dynMethod = DecodeDynMethod(flagValue);
    } else {
      dynMethod = BDD_REORDER_SAME;
    }
    /* update manager with dynamic reordering and the method */
    bdd_dynamic_reordering(ddManager, dynMethod, BDD_REORDER_VERBOSITY_DEFAULT);
  } else {
    /* unless specified, TURN REORDERING OFF for residue verification */
    bdd_dynamic_reordering_disable(ddManager);
  }

  /*
   * Choose the set of primes that will be used, primeTable is allocated
   * here.
   */
  numOfPrimes = ChoosePrimes(actualOutputs,  &primeTable, numDirectVerify);

  /* get result structures */
  resultSpec = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(specNetwork,
                                                    RES_NETWORK_APPL_KEY);
  resultImpl = (Res_ResidueInfo_t *)Ntk_NetworkReadApplInfo(implNetwork,
                                                    RES_NETWORK_APPL_KEY);

  /* update result with primes info */
  if ((resultSpec  != NIL(Res_ResidueInfo_t)) && (resultImpl != NIL(Res_ResidueInfo_t))) {
    ResResidueInfoAllocatePrimeInfoArray(resultSpec, numOfPrimes, primeTable);
    ResResidueInfoAllocatePrimeInfoArray(resultImpl, numOfPrimes, primeTable);
    ResResidueInfoSetNumOfPrimes(resultSpec, numOfPrimes);
    ResResidueInfoSetNumOfPrimes(resultImpl, numOfPrimes);
  } else {
    /* error - the result structure should be there */
    error_append("Result structures are missing\n");
    FREE(primeTable);
    return 1;
  }

  /* Print the list of primes depending on the verbosity level*/
  if (verbose >= 0) {
    (void) fprintf(vis_stdout, "List of Primes used: ");
    for(i=0; i<numOfPrimes; i++) {
      (void) fprintf(vis_stdout, "%d ", primeTable[i]);
    }
    (void) fprintf(vis_stdout, "\n");
  } /* End of if */

  /* form impl Output Array */
  implOutputArray = array_alloc(Ntk_Node_t *, array_n(outputArray));
  arrayForEachItem(Ntk_Node_t *, outputArray, i, nodePtr) {
    st_lookup(outputMatch, (char *)nodePtr, &implNodePtr);
    array_insert(Ntk_Node_t *, implOutputArray, i, implNodePtr);
  }

  /* number of outputs in consideration */
  numOutputs = array_n(outputArray);


  /* Main Loop in which the verification is done for each prime. */
  for(primeIndex = 0; primeIndex < numOfPrimes; primeIndex++) {
    int currentPrime;

    /* Read current prime from table */
    currentPrime = primeTable[primeIndex];
    if (verbose >=2)
      (void) fprintf(vis_stdout, "Processing prime %d:\n", currentPrime);

    /* update the mdd manager with the first set of output variables */
    MddCreateVariables((mdd_manager *)ddManager, numOutputs-bdd_num_vars(ddManager));


    /* Obtain the residue bdd for the given prime, assume top id is
     * always 0i.e. msbId = 0;
     */
    msbId = 0;
    bdd_ref(residueDd = bdd_add_residue(ddManager, numOutputs, currentPrime,
                                         msbLsb, msbId));

    /*  Set the output Id. Needs to be set each time because it gets
     * cleared each time.
     */
    arrayForEachItem(Ntk_Node_t *, outputArray, i , nodePtr) {
      st_lookup(outputMatch, (char *)nodePtr, &implNodePtr);
      if (msbLsb == 1) {
        Ntk_NodeSetMddId(nodePtr, i);
        Ntk_NodeSetMddId(implNodePtr, i);
      } else {
        Ntk_NodeSetMddId(nodePtr, numOutputs - i);
        Ntk_NodeSetMddId(implNodePtr, numOutputs - i);
      }
    }


    /* Set the cpu usage lap */
    lap = util_cpu_time();

    if (verbose >= 1) {
      fprintf(vis_stdout, "Specification being built\n");
    }
    /* the actual composition of the spec. network into the residue ADD
     * is done here. The composed ADD return is referenced
     */
    specADD = ComposeLayersIntoResidue(specNetwork, specLayerArray, residueDd, outputArray);
    if (specADD == NIL(bdd_node)) {
      error_append("Composition of spec. failed.\n");
      /* Clean up before you leave */
      array_free(implOutputArray);
      FREE(primeTable);
      bdd_recursive_deref(ddManager, residueDd);
      return 1; /* error return */
    }

    /* Store the information in the result structure of the spec.*/
    bdd_ref(specADD);
    fnMddT = bdd_construct_bdd_t(ddManager, specADD);
    specSize = bdd_size(fnMddT);
    bdd_free(fnMddT);
    ResResidueInfoSetPerPrimeInfo(resultSpec, primeIndex, currentPrime,
                                  (util_cpu_time() - lap)/1000.0, specSize, specADD);
    /* Print info regarding this prime if pertinent */
    if (verbose >=3) {
      (void) fprintf(vis_stdout, "%.2f (secs) spent in composing prime\n",
                     ResResidueInfoReadPerPrimeInfo(resultSpec, primeIndex)->cpuTime);
      (void) fprintf(vis_stdout, "Composed Dd with %d nodes\n", specSize);
    }

    /* Set the cpu usage lap */
    lap = util_cpu_time();

    /*
     * the actual composition of the impl. network into the residue ADD
     * is done here. The composed ADD return is referenced
     */
    if (verbose >= 1) {
      fprintf(vis_stdout, "Implementation being built\n");
    }
    implADD = ComposeLayersIntoResidue(implNetwork, implLayerArray, residueDd, implOutputArray);

    bdd_recursive_deref(ddManager, residueDd);
    if (implADD == NIL(bdd_node)) {
      error_append("Composition of spec. failed.\n");
      /* Clean up before you leave */
      bdd_recursive_deref(ddManager, specADD);
      array_free(implOutputArray);
      FREE(primeTable);
      return 1; /* error return */
    }

    /* Create a permutation array for the specMddId and implMddId input nodes */
    permut = ALLOC(int, bdd_num_vars(ddManager));
    for (i= 0; (unsigned) i < bdd_num_vars(ddManager); i++) {
      permut[i] = i;
    }
    st_foreach_item(inputMatch, stGen, &key, &value) {
      nodePtr = (Ntk_Node_t *)key;
      implNodePtr = (Ntk_Node_t *)value;
      if ((nodePtr == NIL(Ntk_Node_t)) || (implNodePtr == NIL(Ntk_Node_t))){
        error_append("Input match values do not return");
        error_append("valid node pointers.\n");
        /* Clean up */
        FREE(permut);
        FREE(primeTable);
        array_free(implOutputArray);
        bdd_recursive_deref(ddManager, specADD);
        bdd_recursive_deref(ddManager, implADD);
        st_free_gen(stGen);
        return 1;
      }
      /* create the array with the impl. vars to be composed with spec. vars. */
      specMddId = Ntk_NodeReadMddId(nodePtr);
      implMddId = Ntk_NodeReadMddId(implNodePtr);

      /* there should be no node with NTK_UNASSIGNED_MDD_ID due to the
       * ordering above
       */

#if 0
      if (Ntk_NodeReadNumFanouts(nodePtr) != 0) {
        assert(specMddId != NTK_UNASSIGNED_MDD_ID);
      }
      if (Ntk_NodeReadNumFanouts(implNodePtr) != 0) {
        assert(implMddId != NTK_UNASSIGNED_MDD_ID);
      }
#endif

      if ((specMddId != NTK_UNASSIGNED_MDD_ID) &&
          (implMddId != NTK_UNASSIGNED_MDD_ID)) {
        permut[implMddId] = specMddId;
      } else {
        assert(specMddId == implMddId);
      }

    } /* end of st_foreach_item */

    /* permute the variables so that the impl variables are replaced by
     * spec. variables
     */
    bdd_ref(tmpDd = bdd_add_permute(ddManager, implADD, permut));
    bdd_recursive_deref(ddManager, implADD);
    FREE(permut);
    implADD = tmpDd;
    if(implADD == NIL(bdd_node)) { /* error */
      error_append("Last composition failed,");
      error_append("Cannot compose spec. ADD PI vars into Impl. ADD.\n");
      FREE(primeTable);
      array_free(implOutputArray);
      return 1; /* error return */
    }

    if (verbose > 0) {
      (void) fprintf(vis_stdout, "%.2f (secs) spent in residue verification.\n",
                     (util_cpu_time() - overallLap)/1000.0);
    }

    /* Store the information in the result structure of the impl.*/
    bdd_ref(implADD);
    fnMddT = bdd_construct_bdd_t(ddManager, implADD);
    implSize = bdd_size(fnMddT);
    bdd_free(fnMddT);
    ResResidueInfoSetPerPrimeInfo(resultImpl, primeIndex, currentPrime,
         (util_cpu_time() - lap)/1000.0, implSize, implADD);
    /* Print info regarding this prime if pertinent */
    if (verbose >=3) {
      (void) fprintf(vis_stdout, "%.2f (secs) spent in composing prime\n",
                     ResResidueInfoReadPerPrimeInfo(resultImpl, primeIndex)->cpuTime);
      (void) fprintf(vis_stdout, "Composed Dd with %d nodes\n", implSize);
    }


    /* Compare the Spec and the Impl composed Dds */
    if (ResResidueInfoReadPerPrimeInfo(resultSpec, primeIndex)->residueDd !=
        ResResidueInfoReadPerPrimeInfo(resultImpl, primeIndex)->residueDd) {
      ResResidueInfoSetSuccess(resultSpec, RES_FAIL);
      ResResidueInfoSetSuccess(resultImpl, RES_FAIL);
      (void) fprintf(vis_stdout, "Verification of %s and %s failed.\n",
                     Res_ResidueInfoReadName(resultSpec),
                     Res_ResidueInfoReadName(resultImpl));
      (void)fprintf(vis_stdout,"The composed ADDs with residue are not the same.\n");
      (void)fprintf(vis_stdout,"Verification failed at prime %d.\n", currentPrime);
      if (verbose >= 2) {
        (void)fprintf(vis_stdout, "Vector where the two networks differ :\n");
        (void)fprintf(vis_stdout, "Specification Input Names :\n");
        ExtractACubeOfDifference(ddManager, specNetwork, specADD, implADD);
      }

      /* Clean up before you leave */
      bdd_recursive_deref(ddManager, ResResidueInfoReadPerPrimeInfo(resultSpec, primeIndex)->residueDd);
      ResResidueInfoSetPerPrimeDd(resultSpec, primeIndex, NIL(bdd_node));

      bdd_recursive_deref(ddManager, ResResidueInfoReadPerPrimeInfo(resultImpl, primeIndex)->residueDd);
      ResResidueInfoSetPerPrimeDd(resultImpl, primeIndex, NIL(bdd_node));
      array_free(implOutputArray);
      FREE(primeTable);
      return 0;
    } else {

      /* free the result Dd*/
      bdd_recursive_deref(ddManager, ResResidueInfoReadPerPrimeInfo(resultSpec, primeIndex)->residueDd);
      ResResidueInfoSetPerPrimeDd(resultSpec, primeIndex, NIL(bdd_node));

      bdd_recursive_deref(ddManager, ResResidueInfoReadPerPrimeInfo(resultImpl, primeIndex)->residueDd);
      ResResidueInfoSetPerPrimeDd(resultImpl, primeIndex, NIL(bdd_node));
    }


    /* reset node Ids of primary inputs */
    Ntk_NetworkForEachCombInput(specNetwork, listGen, nodePtr) {
      Ntk_NodeSetMddId(nodePtr, unassignedValue);
    }
    Ntk_NetworkForEachCombInput(implNetwork, listGen, nodePtr) {
      Ntk_NodeSetMddId(nodePtr, unassignedValue);
    }


  } /* End of the main for-loop */
  FREE(primeTable);
  array_free(implOutputArray);

  /* restore old dynamic reordering values */
  bdd_dynamic_reordering(ddManager, oldDynMethod, BDD_REORDER_VERBOSITY_DEFAULT);
  if (!dynStatus) {
    bdd_dynamic_reordering_disable(ddManager);
  }

  /* set pass flag if residue verification success and direct verification
   * success.
   */
  if (((numDirectVerify) &&
       (ResResidueInfoReadDirectVerificationSuccess(resultSpec) == RES_PASS)) ||
       (ResResidueInfoReadDirectVerificationSuccess(resultSpec) != RES_FAIL)) {
    ResResidueInfoSetSuccess(resultSpec, RES_PASS);
  }
  if (((numDirectVerify) &&
       (ResResidueInfoReadDirectVerificationSuccess(resultImpl) == RES_PASS)) ||
      (ResResidueInfoReadDirectVerificationSuccess(resultImpl) != RES_FAIL)) {
    ResResidueInfoSetSuccess(resultImpl, RES_PASS);
  }
  return 0;
} /* End of ResidueVerification */

/**Function********************************************************************

  Synopsis [ Prints out a cube in the XOR of the 2 Bdds]

  Description [ ]
  value]

  SideEffects   [.]

  SeeAlso            []

******************************************************************************/
static void
ExtractACubeOfDifference(bdd_manager *mgr,
                         Ntk_Network_t *specNetwork,
                         bdd_node *fn1,
                         bdd_node *fn2)
{
  bdd_t *fnMddT, *fnMddT1;      /* mdd_t structure to calculate sizes */
  bdd_t *fnMddT2, *fnMddT3;     /* mdd_t structure to calculate sizes */
  bdd_gen *gen;
  array_t *cube, *namesArray;
  lsGen listGen;
  int i, literal;
  Ntk_Node_t *nodePtr;

  /* make bdd_ts of the two functions */
  bdd_ref(fn2);
  fnMddT = bdd_construct_bdd_t(mgr, fn2);
  bdd_ref(fn1);
  fnMddT1 = bdd_construct_bdd_t(mgr, fn1);
  fnMddT2 = bdd_not(fnMddT1);
  /* extracts some cubes in the intersection of fn1' and fn2 */
  fnMddT3 = bdd_intersects(fnMddT, fnMddT2);
  /* check not zero */
  if (bdd_is_tautology(fnMddT3, 0)) {
    bdd_free(fnMddT3);
    bdd_free(fnMddT2);
    /* extracts some cubes in the intersection of fn2' and fn1 */
    fnMddT2 = bdd_not(fnMddT);
    fnMddT3 = bdd_intersects(fnMddT1, fnMddT2);
  }
  assert(!bdd_is_tautology(fnMddT3, 0));
  bdd_free(fnMddT);
  bdd_free(fnMddT1);
  bdd_free(fnMddT2);

  /* pick a cube from the xor of fn1 and fn2 */
  gen = bdd_first_cube(fnMddT3, &cube);
  bdd_free(fnMddT3);

  /* store the names to be printed out later */
  namesArray = array_alloc(char *, array_n(cube));
  Ntk_NetworkForEachCombInput(specNetwork, listGen, nodePtr) {
    array_insert(char *, namesArray , Ntk_NodeReadMddId(nodePtr),  Ntk_NodeReadName(nodePtr));
  }

  /* print out the cube */
  arrayForEachItem(int, cube, i, literal) {
    if (literal != 2) {
      (void) fprintf(vis_stdout, "%s ", array_fetch(char *, namesArray, i));
    }
  }
  fprintf(vis_stdout, "\n");
  arrayForEachItem(int, cube, i, literal) {
    if (literal != 2) {
      (void) fprintf(vis_stdout, "%1d", literal);
    }
  }
  fprintf(vis_stdout, "\n");
  array_free(namesArray);
  bdd_gen_free(gen);
  return;
}