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#include <stdlib.h>
#include <string.h>
#ifndef BSWABE_DEBUG
#define NDEBUG
#endif
#include <assert.h>

#include <openssl/sha.h>
#include <glib.h>
#include <pbc.h>

#include "bswabe.h"
#include "private.h"

#define TYPE_A_PARAMS \
"type a\n" \
"q 87807107996633125224377819847540498158068831994142082" \
"1102865339926647563088022295707862517942266222142315585" \
"8769582317459277713367317481324925129998224791\n" \
"h 12016012264891146079388821366740534204802954401251311" \
"822919615131047207289359704531102844802183906537786776\n" \
"r 730750818665451621361119245571504901405976559617\n" \
"exp2 159\n" \
"exp1 107\n" \
"sign1 1\n" \
"sign0 1\n"

char last_error[256];

char*
bswabe_error()
{
	return last_error;
}

void
raise_error(char* fmt, ...)
{
	va_list args;

#ifdef BSWABE_DEBUG
	va_start(args, fmt);
	vfprintf(stderr, fmt, args);
	va_end(args);
	exit(1);
#else
	va_start(args, fmt);
	vsnprintf(last_error, 256, fmt, args);
	va_end(args);
#endif
}

void
element_from_string( element_t h, char* s )
{
	unsigned char* r;

	r = malloc(SHA_DIGEST_LENGTH);
	SHA1((unsigned char*) s, strlen(s), r);
	element_from_hash(h, r, SHA_DIGEST_LENGTH);

	free(r);
}

void
bswabe_setup( bswabe_pub_t** pub, bswabe_msk_t** msk )
{
	element_t alpha;

	/* initialize */
 
	*pub = malloc(sizeof(bswabe_pub_t));
	*msk = malloc(sizeof(bswabe_msk_t));

	(*pub)->pairing_desc = strdup(TYPE_A_PARAMS);
	pairing_init_set_buf((*pub)->p, (*pub)->pairing_desc, strlen((*pub)->pairing_desc));

	element_init_G1((*pub)->g,           (*pub)->p);
	element_init_G1((*pub)->h,           (*pub)->p);
	element_init_G2((*pub)->gp,          (*pub)->p);
	element_init_GT((*pub)->g_hat_alpha, (*pub)->p);
	element_init_Zr(alpha,               (*pub)->p);
	element_init_Zr((*msk)->beta,        (*pub)->p);
	element_init_G2((*msk)->g_alpha,     (*pub)->p);

	/* compute */

 	element_random(alpha);
 	element_random((*msk)->beta);
	element_random((*pub)->g);
	element_random((*pub)->gp);

	element_pow_zn((*msk)->g_alpha, (*pub)->gp, alpha); /* g_alpha = gp^a */
	element_pow_zn((*pub)->h, (*pub)->g, (*msk)->beta); /* h = g^b  */
  pairing_apply((*pub)->g_hat_alpha, (*pub)->g, (*msk)->g_alpha, (*pub)->p); /* g_hat_aplha = e(g,g_aplha) = e(g,gp)^a  */
}

bswabe_prv_t* bswabe_keygen( bswabe_pub_t* pub,
														 bswabe_msk_t* msk,
														 char** attributes )
{
	bswabe_prv_t* prv;
	element_t g_r;
	element_t r;
	element_t beta_inv;

	/* initialize */

	prv = malloc(sizeof(bswabe_prv_t));

	element_init_G2(prv->d, pub->p);
	element_init_G2(g_r, pub->p);
	element_init_Zr(r, pub->p);
	element_init_Zr(beta_inv, pub->p);

	prv->comps = g_array_new(0, 1, sizeof(bswabe_prv_comp_t));

	/* compute */

 	element_random(r);
	element_pow_zn(g_r, pub->gp, r); /* g_r = gp^r */

	element_mul(prv->d, msk->g_alpha, g_r); /* gp^r*gp^a = gp^(r+a) */
	element_invert(beta_inv, msk->beta); /* (1/b) */
	element_pow_zn(prv->d, prv->d, beta_inv); /* d = gp^((r+a) * 1/b) */

	while( *attributes )
	{
		bswabe_prv_comp_t c;
		element_t h_rp;
		element_t rp;

		c.attr = *(attributes++);

		element_init_G2(c.d,  pub->p);
		element_init_G1(c.dp, pub->p);
		element_init_G2(h_rp, pub->p);
		element_init_Zr(rp,   pub->p);
		
 		element_from_string(h_rp, c.attr); /* h_rp = H(attr)  */
 		element_random(rp);

		element_pow_zn(h_rp, h_rp, rp); /* h_rp = H(attr)^rp  */

		element_mul(c.d, g_r, h_rp); /* d = h_rp * gp^r = H(attr)^rp * gp^r */
		element_pow_zn(c.dp, pub->g, rp); /* dp = g^rp */
		element_clear(h_rp);
		element_clear(rp);

		g_array_append_val(prv->comps, c);
	}

	return prv;
}

/* Generates a node of the policy tree with threshold k */
bswabe_policy_t*
base_node( int k, char* s )
{
	bswabe_policy_t* p;

	p = (bswabe_policy_t*) malloc(sizeof(bswabe_policy_t));
	p->k = k;
	p->attr = s ? strdup(s) : 0; /* s if not empty, null otherwise */
	p->children = g_ptr_array_new();
	p->q = 0;

	return p;
}

/*
	TODO convert this to use a GScanner and handle quotes and / or
	escapes to allow attributes with whitespace or = signs in them
*/

bswabe_policy_t*
parse_policy_postfix( char* s )
{
	char** toks;
	char** cur_toks;
	char*  tok;
	GPtrArray* stack; /* pointers to bswabe_policy_t's */
	bswabe_policy_t* root;

	toks     = g_strsplit(s, " ", 0);
	cur_toks = toks;
	stack    = g_ptr_array_new();

	while( *cur_toks )
	{
		int i, k, n;

		tok = *(cur_toks++);

		if( !*tok )
			continue;

		if( sscanf(tok, "%dof%d", &k, &n) != 2 )
			/* push leaf token */
			g_ptr_array_add(stack, base_node(1, tok));
		else
		{
			bswabe_policy_t* node;

			/* parse "kofn" operator */

			if( k < 1 )
			{
				raise_error("error parsing \"%s\": trivially satisfied operator \"%s\"\n", s, tok);
				return 0;
			}
			else if( k > n )
			{
				raise_error("error parsing \"%s\": unsatisfiable operator \"%s\"\n", s, tok);
				return 0;
			}
			else if( n == 1 )
			{
				raise_error("error parsing \"%s\": identity operator \"%s\"\n", s, tok);
				return 0;
			}
			else if( n > stack->len )
			{
				raise_error("error parsing \"%s\": stack underflow at \"%s\"\n", s, tok);
				return 0;
			}
			
			/* pop n things and fill in children */
			node = base_node(k, 0);
			g_ptr_array_set_size(node->children, n);
			for( i = n - 1; i >= 0; i-- )
				node->children->pdata[i] = g_ptr_array_remove_index(stack, stack->len - 1);
			
			/* push result */
			g_ptr_array_add(stack, node);
		}
	}

	if( stack->len > 1 )
	{
		raise_error("error parsing \"%s\": extra tokens left on stack\n", s);
		return 0;
	}
	else if( stack->len < 1 )
	{
		raise_error("error parsing \"%s\": empty policy\n", s);
		return 0;
	}

	root = g_ptr_array_index(stack, 0);

 	g_strfreev(toks);
 	g_ptr_array_free(stack, 0);

	return root;
}

/* Generates a degree *deg* polynomial with 0 coef equal to zero_val */
bswabe_polynomial_t*
rand_poly( int deg, element_t zero_val )
{
	int i;
	bswabe_polynomial_t* q;

	q = (bswabe_polynomial_t*) malloc(sizeof(bswabe_polynomial_t));
	q->deg = deg;
	q->coef = (element_t*) malloc(sizeof(element_t) * (deg + 1));

	for( i = 0; i < q->deg + 1; i++ )
		element_init_same_as(q->coef[i], zero_val);

	element_set(q->coef[0], zero_val);

	for( i = 1; i < q->deg + 1; i++ )
 		element_random(q->coef[i]);

	return q;
}

void
eval_poly( element_t r, bswabe_polynomial_t* q, element_t x )
{
	int i;
	element_t s, t;

	element_init_same_as(s, r);
	element_init_same_as(t, r);

	element_set0(r);
	element_set1(t);

	for( i = 0; i < q->deg + 1; i++ )
	{
		/* r += q->coef[i] * t */
		element_mul(s, q->coef[i], t);
		element_add(r, r, s);

		/* t *= x */
		element_mul(t, t, x);
	}

	element_clear(s);
	element_clear(t);
}

/* Recursive algorithm to fill the policy. Works on each node starting from the root:
	- Fills the polynomial q of each node
	- c & cp for leaves (i.e. children->len == 0)
	- Recursively fills the children 
*/

void
fill_policy( bswabe_policy_t* p, bswabe_pub_t* pub, element_t e )
{
	int i;
	element_t r;
	element_t t;
	element_t h;

	element_init_Zr(r, pub->p);
	element_init_Zr(t, pub->p);
	element_init_G2(h, pub->p);

	p->q = rand_poly(p->k - 1, e);

	if( p->children->len == 0 )
	{
		element_init_G1(p->c,  pub->p);
		element_init_G2(p->cp, pub->p);

		element_from_string(h, p->attr);
		element_pow_zn(p->c,  pub->g, p->q->coef[0]); /* c = g^q(0)  */
		element_pow_zn(p->cp, h,      p->q->coef[0]); /* cp = H(attr)^q(0)  */
	}
	else
		for( i = 0; i < p->children->len; i++ )
		{
			element_set_si(r, i + 1);
			eval_poly(t, p->q, r);
			fill_policy(g_ptr_array_index(p->children, i), pub, t);
		}

	element_clear(r);
	element_clear(t);
	element_clear(h);
}

bswabe_cph_t*
bswabe_enc( bswabe_pub_t* pub, element_t m, char* policy )
{
	bswabe_cph_t* cph;
 	element_t s;

	/* initialize */

	cph = malloc(sizeof(bswabe_cph_t));

	element_init_Zr(s, pub->p);
	element_init_GT(m, pub->p);
	element_init_GT(cph->cs, pub->p);
	element_init_G1(cph->c,  pub->p);
	cph->policy = policy;
	cph->p = parse_policy_postfix(policy); /* Assign the policy */
	/* compute */

 	element_random(m);
 	element_random(s);
	element_pow_zn(cph->cs, pub->g_hat_alpha, s); /* g_hat_aplha = e(g,g_aplha) = e(g,gp)^a  */
						      /* cs = e(g,gp)^(as)  */	
	element_mul(cph->cs, cph->cs, m); /* cs = me(g,gp)^(as) */

	element_pow_zn(cph->c, pub->h, s); /* c = h^s  */

	fill_policy(cph->p, pub, s); /* The zero_val of the root polynomial is s (qr(0) = s) */
	return cph;
}

/* Recursively verify if the ciphertext policy is satisfied by the private key  */

void
check_sat( bswabe_policy_t* p, bswabe_prv_t* prv )
{
	int i, l;

	p->satisfiable = 0;
	if( p->children->len == 0 ) /* If leave  */
	{
		for( i = 0; i < prv->comps->len; i++ )
			if( !strcmp(g_array_index(prv->comps, bswabe_prv_comp_t, i).attr,
									p->attr) )
			{
				p->satisfiable = 1;
				p->attri = i;
				break;
			}
	}
	else
	{
		for( i = 0; i < p->children->len; i++ ) /* Recursively applies to the children  */
			check_sat(g_ptr_array_index(p->children, i), prv);

		l = 0;
		for( i = 0; i < p->children->len; i++ ) /* Checks how many children nodes are satisfied  */
			if( ((bswabe_policy_t*) g_ptr_array_index(p->children, i))->satisfiable )
				l++;

		if( l >= p->k ) /* k is the threshold value  */
			p->satisfiable = 1;
	}
}

/* Picks a set of k children that satisfy the policy */
void
pick_sat_naive( bswabe_policy_t* p, bswabe_prv_t* prv )
{
	int i, k, l;

	assert(p->satisfiable == 1);

	if( p->children->len == 0 )
		return;

	p->satl = g_array_new(0, 0, sizeof(int));

	l = 0;
	for( i = 0; i < p->children->len && l < p->k; i++ )
		if( ((bswabe_policy_t*) g_ptr_array_index(p->children, i))->satisfiable )
		{
			pick_sat_naive(g_ptr_array_index(p->children, i), prv);
			l++;
			k = i + 1;
			g_array_append_val(p->satl, k);
		}
}

/* TODO there should be a better way of doing this */
bswabe_policy_t* cur_comp_pol;
int
cmp_int( const void* a, const void* b )
{
	int k, l;
	
	k = ((bswabe_policy_t*) g_ptr_array_index(cur_comp_pol->children, *((int*)a)))->min_leaves;
	l = ((bswabe_policy_t*) g_ptr_array_index(cur_comp_pol->children, *((int*)b)))->min_leaves;

	return
		k <  l ? -1 :
		k == l ?  0 : 1;
}

void
pick_sat_min_leaves( bswabe_policy_t* p, bswabe_prv_t* prv )
{
	int i, k, l;
	int* c;

	assert(p->satisfiable == 1);

	if( p->children->len == 0 )
		p->min_leaves = 1;
	else
	{
		for( i = 0; i < p->children->len; i++ )
			if( ((bswabe_policy_t*) g_ptr_array_index(p->children, i))->satisfiable )
				pick_sat_min_leaves(g_ptr_array_index(p->children, i), prv);

		c = alloca(sizeof(int) * p->children->len);
		for( i = 0; i < p->children->len; i++ )
			c[i] = i;

		cur_comp_pol = p;
		qsort(c, p->children->len, sizeof(int), cmp_int);

		p->satl = g_array_new(0, 0, sizeof(int));
		p->min_leaves = 0;
		l = 0;

		for( i = 0; i < p->children->len && l < p->k; i++ )
			if( ((bswabe_policy_t*) g_ptr_array_index(p->children, c[i]))->satisfiable )
			{
				l++;
				p->min_leaves += ((bswabe_policy_t*) g_ptr_array_index(p->children, c[i]))->min_leaves;
				k = c[i] + 1;
				g_array_append_val(p->satl, k);
			}
		assert(l == p->k);
	}
}

void
lagrange_coef( element_t r, GArray* s, int i )
{
	int j, k;
	element_t t;

	element_init_same_as(t, r);

	element_set1(r);
	for( k = 0; k < s->len; k++ )
	{
		j = g_array_index(s, int, k);
		if( j == i )
			continue;
		element_set_si(t, - j);
		element_mul(r, r, t); /* num_muls++; */
		element_set_si(t, i - j);
		element_invert(t, t);
		element_mul(r, r, t); /* num_muls++; */
	}

	element_clear(t);
}

void
dec_leaf_naive( element_t r, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	bswabe_prv_comp_t* c;
	element_t s;

	c = &(g_array_index(prv->comps, bswabe_prv_comp_t, p->attri));

	element_init_GT(s, pub->p);

	pairing_apply(r, p->c,  c->d,  pub->p); /* num_pairings++; */
	pairing_apply(s, p->cp, c->dp, pub->p); /* num_pairings++; */
	element_invert(s, s);
	element_mul(r, r, s); /* num_muls++; */

	element_clear(s);
}

void dec_node_naive( element_t r, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub );

void
dec_internal_naive( element_t r, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	int i;
	element_t s;
	element_t t;

	element_init_GT(s, pub->p);
	element_init_Zr(t, pub->p);

	element_set1(r);
	for( i = 0; i < p->satl->len; i++ )
	{
		dec_node_naive
			(s, g_ptr_array_index
			 (p->children, g_array_index(p->satl, int, i) - 1), prv, pub);
 		lagrange_coef(t, p->satl, g_array_index(p->satl, int, i));
		element_pow_zn(s, s, t); /* num_exps++; */
		element_mul(r, r, s); /* num_muls++; */
	}

	element_clear(s);
	element_clear(t);
}

void
dec_node_naive( element_t r, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	assert(p->satisfiable);
	if( p->children->len == 0 )
		dec_leaf_naive(r, p, prv, pub);
	else
		dec_internal_naive(r, p, prv, pub);
}

void
dec_naive( element_t r, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	dec_node_naive(r, p, prv, pub);
}

void
dec_leaf_merge( element_t exp, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	bswabe_prv_comp_t* c;
	element_t s;

	c = &(g_array_index(prv->comps, bswabe_prv_comp_t, p->attri));

	if( !c->used )
	{
		c->used = 1;
		element_init_G1(c->z,  pub->p);
		element_init_G1(c->zp, pub->p);
		element_set1(c->z);
		element_set1(c->zp);
	}

	element_init_G1(s, pub->p);

	element_pow_zn(s, p->c, exp); /* num_exps++; */
	element_mul(c->z, c->z, s); /* num_muls++; */

	element_pow_zn(s, p->cp, exp); /* num_exps++; */
	element_mul(c->zp, c->zp, s); /* num_muls++; */

	element_clear(s);
}

void dec_node_merge( element_t exp, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub );

void
dec_internal_merge( element_t exp, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	int i;
	element_t t;
	element_t expnew;

	element_init_Zr(t, pub->p);
	element_init_Zr(expnew, pub->p);

	for( i = 0; i < p->satl->len; i++ )
	{
 		lagrange_coef(t, p->satl, g_array_index(p->satl, int, i));
		element_mul(expnew, exp, t); /* num_muls++; */
		dec_node_merge(expnew, g_ptr_array_index
									 (p->children, g_array_index(p->satl, int, i) - 1), prv, pub);
	}

	element_clear(t);
	element_clear(expnew);
}

void
dec_node_merge( element_t exp, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	assert(p->satisfiable);
	if( p->children->len == 0 )
		dec_leaf_merge(exp, p, prv, pub);
	else
		dec_internal_merge(exp, p, prv, pub);
}

void
dec_merge( element_t r, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	int i;
	element_t one;
	element_t s;

	/* first mark all attributes as unused */
	for( i = 0; i < prv->comps->len; i++ )
		g_array_index(prv->comps, bswabe_prv_comp_t, i).used = 0;

	/* now fill in the z's and zp's */
	element_init_Zr(one, pub->p);
	element_set1(one);
	dec_node_merge(one, p, prv, pub);
	element_clear(one);

	/* now do all the pairings and multiply everything together */
	element_set1(r);
	element_init_GT(s, pub->p);
	for( i = 0; i < prv->comps->len; i++ )
		if( g_array_index(prv->comps, bswabe_prv_comp_t, i).used )
		{
			bswabe_prv_comp_t* c = &(g_array_index(prv->comps, bswabe_prv_comp_t, i));

			pairing_apply(s, c->z, c->d, pub->p); /* num_pairings++; */
			element_mul(r, r, s); /* num_muls++; */

			pairing_apply(s, c->zp, c->dp, pub->p); /* num_pairings++; */
			element_invert(s, s);
			element_mul(r, r, s); /* num_muls++; */
		}
	element_clear(s);
}

void
dec_leaf_flatten( element_t r, element_t exp,
									bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	bswabe_prv_comp_t* c;
	element_t s;
	element_t t;

	c = &(g_array_index(prv->comps, bswabe_prv_comp_t, p->attri));

	element_init_GT(s, pub->p);
	element_init_GT(t, pub->p);

	pairing_apply(s, p->c,  c->d,  pub->p); /* num_pairings++; */
	pairing_apply(t, p->cp, c->dp, pub->p); /* num_pairings++; */
	element_invert(t, t);
	element_mul(s, s, t); /* num_muls++; */
	element_pow_zn(s, s, exp); /* num_exps++; */

	element_mul(r, r, s); /* num_muls++; */

	element_clear(s);
	element_clear(t);
}

void dec_node_flatten( element_t r, element_t exp,
											 bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub );

void
dec_internal_flatten( element_t r, element_t exp,
											bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	int i;
	element_t t;
	element_t expnew;

	element_init_Zr(t, pub->p);
	element_init_Zr(expnew, pub->p);

	for( i = 0; i < p->satl->len; i++ )
	{
 		lagrange_coef(t, p->satl, g_array_index(p->satl, int, i));
		element_mul(expnew, exp, t); /* num_muls++; */
		dec_node_flatten(r, expnew, g_ptr_array_index
										 (p->children, g_array_index(p->satl, int, i) - 1), prv, pub);
	}

	element_clear(t);
	element_clear(expnew);
}

void
dec_node_flatten( element_t r, element_t exp,
									bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	assert(p->satisfiable);
	if( p->children->len == 0 )
		dec_leaf_flatten(r, exp, p, prv, pub);
	else
		dec_internal_flatten(r, exp, p, prv, pub);
}

void
dec_flatten( element_t r, bswabe_policy_t* p, bswabe_prv_t* prv, bswabe_pub_t* pub )
{
	element_t one;

	element_init_Zr(one, pub->p);

	element_set1(one);
	element_set1(r);

	dec_node_flatten(r, one, p, prv, pub);

	element_clear(one);
}

int
bswabe_dec( bswabe_pub_t* pub, bswabe_prv_t* prv, bswabe_cph_t* cph, element_t m )
{
	element_t t;

	element_init_GT(m, pub->p);
	element_init_GT(t, pub->p);

	check_sat(cph->p, prv);
	if( !cph->p->satisfiable )
	{
		raise_error("cannot decrypt, attributes in key do not satisfy policy\n");
		return 0;
	}

/* 	if( no_opt_sat ) */
/* 		pick_sat_naive(cph->p, prv); */
/* 	else */
	pick_sat_min_leaves(cph->p, prv);

/* 	if( dec_strategy == DEC_NAIVE ) */
/* 		dec_naive(t, cph->p, prv, pub); */
/* 	else if( dec_strategy == DEC_FLATTEN ) */
	dec_flatten(t, cph->p, prv, pub);
/* 	else */
/* 		dec_merge(t, cph->p, prv, pub); */

	element_mul(m, cph->cs, t); /* num_muls++; */

	pairing_apply(t, cph->c, prv->d, pub->p); /* num_pairings++; */
	element_invert(t, t);
	element_mul(m, m, t); /* num_muls++; */

	return 1;
}

// Returns the policy of a ciphertext
char* bswabe_policyList( bswabe_cph_t* cph)
	{
	return cph->policy;
	}

char** bswabe_attrList( bswabe_prv_t* prv)
	{
	int i;
	char** attrList;
	attrList = malloc(sizeof(char*)*(prv->comps->len+1));

	for( i = 0; i < prv->comps->len; i++ )
		attrList[i]= g_array_index(prv->comps, bswabe_prv_comp_t, i).attr;

	attrList[prv->comps->len] = 0;
	return attrList;
	}

/* Generate an encrypted keyword using the public key and a clear keyword  */
peks_sew_t peks_enc( bswabe_pub_t* pub, char* w )
{
	peks_sew_t sew;
	element_t hr; /* h^r  */
	element_t hw; /* H_1(W)  */
 	element_t r; 

	/* initialize */

	element_init_Zr(r, pub->p);
	element_init_G1(hr,  pub->p);
	element_init_G1(hw,  pub->p);
	element_init_GT(sew.B, pub->p);
	element_init_G1(sew.A,  pub->p);

	/* compute */

 	element_random(r);
	element_pow_zn(hr, pub->h, r); /* h^r */
	element_pow_zn(sew.A, pub->g, r); /* A = g^r */
 	element_from_string(hw, w); /* H_1(W) */

  	pairing_apply(sew.B, hw, hr, pub->p); /* B = e( H_1(W), h^r ) */
	
//	element_clear(r);
//	element_clear(hr);
//	element_clear(hw);
	return sew;
}

/* Generates an encrypted index using the public key and a clear index.
   Each keyword of the clear index should be on a different line  */
peks_ind_t* peks_enc_ind( bswabe_pub_t* pub, char* ind_file )
{
	peks_ind_t* ind;

	FILE* f;
	
	/* initialize */

	ind = malloc(sizeof(peks_ind_t));

	ind->comps = g_array_new(0, 1, sizeof(peks_sew_t));

	f = fopen(ind_file, "r");

	char line[256];

	/* compute */
	while (fgets(line, sizeof(line), f)) 
	{	
		peks_sew_t sew;
		sew = peks_enc(pub, line);
		g_array_append_val(ind->comps, sew);
    	}
	
	return ind;
}

/* Generates a trapdoor using private key and a word */
peks_trap_t* peks_trap( bswabe_pub_t* pub, bswabe_msk_t* msk, char* w )
{
	peks_trap_t* trap;
	element_t hw; /* H_1(W)  */

	/* initialize */
	
	trap = malloc(sizeof(peks_trap_t));
	element_init_G1(hw,  pub->p);
	element_init_G1(trap->T,  pub->p);

	/* compute */

 	element_from_string(hw, w); /* H_1(W) */
	element_pow_zn(trap->T, hw, msk->beta);

	return trap; 
}

/* Tests if the encrypted word match with the trapdoor  */
int peks_test( bswabe_pub_t* pub, peks_sew_t sew, peks_trap_t* trap )
{
	element_t test;

	/* initialize */
	
	element_init_GT(test, pub->p);

	/* compute */
	
	pairing_apply(test, trap->T, sew.A, pub->p); /* test = e( T_W, A ) */

	return element_cmp(test, sew.B);
}

/* Tests if the encrypted index match with the trapdoor  */
int peks_test_ind( bswabe_pub_t* pub, peks_ind_t* ind, peks_trap_t* trap )
{
	int i;
	/* compute */
	for( i = 0; i < ind->comps->len; i++ )
	{
		if( !peks_test(pub, g_array_index(ind->comps, peks_sew_t, i), trap))
			return 0;	
	}

	return 1;
}