yap-6.3/packages/cplint/cplint_Prob.c

/*
	LPAD and CP-Logic interpreter
	
Copyright (c) 2007, Fabrizio Riguzzi

This package uses the library cudd, see http://vlsi.colorado.edu/~fabio/CUDD/
for the relative license.


	This file contains the definition of Prob and ProbBool plus the functions
	for building the BDD
*/


#include "cplint.h"
#include <stdlib.h>

int correctPosition(int index,variable v, DdNode * node,int posBVar);


DdNode * retFunction(DdManager * mgr,array_t *expression, array_t *v)
/* given an expression term1+term2+...+termn, returns the BDD that implements that function */  
{
  array_t * term;
  DdNode * tNode, * tmp, *tmp1;
  int i;
  
  i=0;
  tNode=Cudd_ReadLogicZero(mgr);
  Cudd_Ref(tNode);
  while(i<array_n(expression))
  {
    term=array_fetch(array_t * ,expression,i);
    tmp=retTerm(mgr,term,v);
    Cudd_Ref(tmp);
    tmp1=Cudd_bddOr(mgr,tNode,tmp);
    Cudd_Ref(tmp1);
    Cudd_RecursiveDeref(mgr,tNode);
    tNode=tmp1;
    i++;    
  } 
  return tNode;
}

DdNode * retTerm(DdManager * mgr,array_t *term, array_t * v)
/* given a term V1=v1 and V2=v2 ... Vn=vn, returns the BDD that implements that function */  
{
  factor f;
  DdNode * fNode, * tmp, *tmp1;
  int i;
  
  i=0;
  fNode=Cudd_ReadOne(mgr);
  Cudd_Ref(fNode);
  while (i<array_n(term))
  {
    f=array_fetch(factor, term, i);
    tmp=retFactor(mgr,f,v);
    Cudd_Ref(tmp);
    tmp1= Cudd_bddAnd(mgr,fNode,tmp);
    Cudd_Ref(tmp1);
    Cudd_RecursiveDeref(mgr,fNode);
    fNode=tmp1;
    i++;
  } 
  return fNode;
}

DdNode * retFactor(DdManager * mgr, factor f, array_t * vars)
/* given a factor V=v, returns the BDD that implements that function */  
{
  int varIndex;
  int value;
  int i;
  int bit;
  variable v;
  DdNode * node, *booleanVar, * tmp;
  array_t * booleanVars;
  
  
  varIndex=f.var;
  value=f.value;
  v=array_fetch(variable, vars, varIndex);
  booleanVars=v.booleanVars;
  i=v.nBit-1;
  node=Cudd_ReadOne(mgr);
  Cudd_Ref(node);
  /* booelan var with index 0 in v.booleanVars is the most significant */
  do {
    booleanVar=array_fetch(DdNode *,booleanVars,i);
    bit=value & 01;
    if (bit)
    {
      tmp=Cudd_bddAnd(mgr,node,booleanVar);
      Cudd_Ref(tmp);
    }
    else
      {
      tmp=Cudd_bddAnd(mgr,node,Cudd_Not(booleanVar));
      Cudd_Ref(tmp);
      }
    value=value>>1;
    i--;
    Cudd_RecursiveDeref(mgr,node);
    node=tmp;
  } while (i>=0);
  return node;

}


double Prob(DdNode *node, array_t * vars,array_t * bVar2mVar, GHashTable * nodes)
/* compute the probability of the expression rooted at node
nodes is used to store nodes for which the probability has alread been computed
so that it is not recomputed
 */
{
  int index,mVarIndex,nBit;
  variable v;
  double res;
  double value;
  double * value_p;
  DdNode **key;
  double *rp;

  index=node->index;
  if (Cudd_IsConstant(node))
  {
    value=node->type.value;
    return value;
  }
  else
{
	
	value_p=g_hash_table_lookup(nodes,&node);
	if (value_p!=NULL)
	{
		return *value_p;
	}
	else
  	{
    		mVarIndex=array_fetch(int,bVar2mVar,index);
    		v=array_fetch(variable,vars,mVarIndex);
    		nBit=v.nBit;
    		res=ProbBool(node,0,nBit,0,v,vars,bVar2mVar,nodes);
		key=(DdNode **)malloc(sizeof(DdNode *));
		*key=node;
		rp=(double *)malloc(sizeof(double));
		*rp=res;
		g_hash_table_insert(nodes, key, rp);
    		return res;
  	}
}
}

double ProbBool(DdNode *node, int bits, int nBit,int posBVar,variable v,
array_t * vars,array_t * bVar2mVar, GHashTable * nodes)
/* explores a group of binary variables making up the multivalued variable v */
{
  DdNode *T,*F;
  double p,res;
  array_t * probs;
  
  probs=v.probabilities;
  if (nBit==0)
  {
    if (bits>=array_n(probs))
      return 0;
    else
    {
      p=array_fetch(double,probs,bits);
      res=p*Prob(node,vars,bVar2mVar,nodes);
      return res;
    }
  }
  else
  {
    if (correctPosition(node->index,v,node,posBVar))
    {
      T = node->type.kids.T;
      F = node->type.kids.E;
      bits=bits<<1;
      
      res=ProbBool(T,bits+1,nBit-1,posBVar+1,v,vars,bVar2mVar,nodes)+ 
        ProbBool(F,bits,nBit-1,posBVar+1,v,vars,bVar2mVar,nodes);
      return res;
    }
    else
    {
      
      bits=bits<<1;
      res=ProbBool(node,bits+1,nBit-1,posBVar+1,v,vars,bVar2mVar,nodes)+ 
        ProbBool(node,bits,nBit-1,posBVar+1,v,vars,bVar2mVar,nodes);
      return res;
    }
  }
}

int correctPosition(int index,variable v, DdNode * node,int posBVar)
/* returns 1 is the boolean variable with index posBVar is in the correct position 
currently explored by ProbBool */
{
  DdNode * bvar;
  
  bvar=array_fetch(DdNode *,v.booleanVars,posBVar);
  return bvar->index==index;
}
update package locations to a subdir packages 2009-02-16 12:23:29 +00:00			`/*`
			`LPAD and CP-Logic interpreter`

			`Copyright (c) 2007, Fabrizio Riguzzi`

			`This package uses the library cudd, see http://vlsi.colorado.edu/~fabio/CUDD/`
			`for the relative license.`


			`This file contains the definition of Prob and ProbBool plus the functions`
			`for building the BDD`
			`*/`


			`#include "cplint.h"`
			`#include <stdlib.h>`

			`int correctPosition(int index,variable v, DdNode * node,int posBVar);`



			`DdNode * retFunction(DdManager * mgr,array_t expression, array_t v)`
			`/* given an expression term1+term2+...+termn, returns the BDD that implements that function */`
			`{`
			`array_t * term;`
			`DdNode * tNode, * tmp, *tmp1;`
			`int i;`

			`i=0;`
			`tNode=Cudd_ReadLogicZero(mgr);`
			`Cudd_Ref(tNode);`
			`while(i<array_n(expression))`
			`{`
			`term=array_fetch(array_t * ,expression,i);`
			`tmp=retTerm(mgr,term,v);`
			`Cudd_Ref(tmp);`
			`tmp1=Cudd_bddOr(mgr,tNode,tmp);`
			`Cudd_Ref(tmp1);`
			`Cudd_RecursiveDeref(mgr,tNode);`
			`tNode=tmp1;`
			`i++;`
			`}`
			`return tNode;`
			`}`

			`DdNode * retTerm(DdManager * mgr,array_t term, array_t v)`
			`/* given a term V1=v1 and V2=v2 ... Vn=vn, returns the BDD that implements that function */`
			`{`
			`factor f;`
			`DdNode * fNode, * tmp, *tmp1;`
			`int i;`

			`i=0;`
			`fNode=Cudd_ReadOne(mgr);`
			`Cudd_Ref(fNode);`
			`while (i<array_n(term))`
			`{`
			`f=array_fetch(factor, term, i);`
			`tmp=retFactor(mgr,f,v);`
			`Cudd_Ref(tmp);`
			`tmp1= Cudd_bddAnd(mgr,fNode,tmp);`
			`Cudd_Ref(tmp1);`
			`Cudd_RecursiveDeref(mgr,fNode);`
			`fNode=tmp1;`
			`i++;`
			`}`
			`return fNode;`
			`}`

			`DdNode * retFactor(DdManager * mgr, factor f, array_t * vars)`
			`/* given a factor V=v, returns the BDD that implements that function */`
			`{`
			`int varIndex;`
			`int value;`
			`int i;`
			`int bit;`
			`variable v;`
			`DdNode * node, booleanVar, tmp;`
			`array_t * booleanVars;`


			`varIndex=f.var;`
			`value=f.value;`
			`v=array_fetch(variable, vars, varIndex);`
			`booleanVars=v.booleanVars;`
			`i=v.nBit-1;`
			`node=Cudd_ReadOne(mgr);`
			`Cudd_Ref(node);`
			`/* booelan var with index 0 in v.booleanVars is the most significant */`
			`do {`
			`booleanVar=array_fetch(DdNode *,booleanVars,i);`
			`bit=value & 01;`
			`if (bit)`
			`{`
			`tmp=Cudd_bddAnd(mgr,node,booleanVar);`
			`Cudd_Ref(tmp);`
			`}`
			`else`
			`{`
			`tmp=Cudd_bddAnd(mgr,node,Cudd_Not(booleanVar));`
			`Cudd_Ref(tmp);`
			`}`
			`value=value>>1;`
			`i--;`
			`Cudd_RecursiveDeref(mgr,node);`
			`node=tmp;`
			`} while (i>=0);`
			`return node;`

			`}`



			`double Prob(DdNode node, array_t vars,array_t * bVar2mVar, GHashTable * nodes)`
			`/* compute the probability of the expression rooted at node`
			`nodes is used to store nodes for which the probability has alread been computed`
			`so that it is not recomputed`
			`*/`
			`{`
			`int index,mVarIndex,nBit;`
			`variable v;`
			`double res;`
			`double value;`
			`double * value_p;`
			`DdNode **key;`
			`double *rp;`

			`index=node->index;`
			`if (Cudd_IsConstant(node))`
			`{`
			`value=node->type.value;`
			`return value;`
			`}`
			`else`
			`{`

			`value_p=g_hash_table_lookup(nodes,&node);`
			`if (value_p!=NULL)`
			`{`
			`return *value_p;`
			`}`
			`else`
			`{`
			`mVarIndex=array_fetch(int,bVar2mVar,index);`
			`v=array_fetch(variable,vars,mVarIndex);`
			`nBit=v.nBit;`
			`res=ProbBool(node,0,nBit,0,v,vars,bVar2mVar,nodes);`
			`key=(DdNode *)malloc(sizeof(DdNode ));`
			`*key=node;`
			`rp=(double *)malloc(sizeof(double));`
			`*rp=res;`
			`g_hash_table_insert(nodes, key, rp);`
			`return res;`
			`}`
			`}`
			`}`

			`double ProbBool(DdNode *node, int bits, int nBit,int posBVar,variable v,`
			`array_t * vars,array_t * bVar2mVar, GHashTable * nodes)`
			`/* explores a group of binary variables making up the multivalued variable v */`
			`{`
			`DdNode T,F;`
			`double p,res;`
			`array_t * probs;`

			`probs=v.probabilities;`
			`if (nBit==0)`
			`{`
			`if (bits>=array_n(probs))`
			`return 0;`
			`else`
			`{`
			`p=array_fetch(double,probs,bits);`
			`res=p*Prob(node,vars,bVar2mVar,nodes);`
			`return res;`
			`}`
			`}`
			`else`
			`{`
			`if (correctPosition(node->index,v,node,posBVar))`
			`{`
			`T = node->type.kids.T;`
			`F = node->type.kids.E;`
			`bits=bits<<1;`

			`res=ProbBool(T,bits+1,nBit-1,posBVar+1,v,vars,bVar2mVar,nodes)+`
			`ProbBool(F,bits,nBit-1,posBVar+1,v,vars,bVar2mVar,nodes);`
			`return res;`
			`}`
			`else`
			`{`

			`bits=bits<<1;`
			`res=ProbBool(node,bits+1,nBit-1,posBVar+1,v,vars,bVar2mVar,nodes)+`
			`ProbBool(node,bits,nBit-1,posBVar+1,v,vars,bVar2mVar,nodes);`
			`return res;`
			`}`
			`}`
			`}`

			`int correctPosition(int index,variable v, DdNode * node,int posBVar)`
			`/* returns 1 is the boolean variable with index posBVar is in the correct position`
			`currently explored by ProbBool */`
			`{`
			`DdNode * bvar;`

			`bvar=array_fetch(DdNode *,v.booleanVars,posBVar);`
			`return bvar->index==index;`
			`}`