/*
* Portions Copyright (c) 2009 Nokia Corporation and/or its subsidiary(-ies).
* All rights reserved.
* This component and the accompanying materials are made available
* under the terms of "Eclipse Public License v1.0"
* which accompanies this distribution, and is available
* at the URL "http://www.eclipse.org/legal/epl-v10.html".
*
* Initial Contributors:
* Nokia Corporation - initial contribution.
*
* Contributors:
*
* Description:
* The original NIST Statistical Test Suite code is placed in public domain.
* (http://csrc.nist.gov/groups/ST/toolkit/rng/documentation_software.html)
*
* This software was developed at the National Institute of Standards and Technology by
* employees of the Federal Government in the course of their official duties. Pursuant
* to title 17 Section 105 of the United States Code this software is not subject to
* copyright protection and is in the public domain. The NIST Statistical Test Suite is
* an experimental system. NIST assumes no responsibility whatsoever for its use by other
* parties, and makes no guarantees, expressed or implied, about its quality, reliability,
* or any other characteristic. We would appreciate acknowledgment if the software is used.
*/
#include "openc.h"
#include "../include/externs.h"
#include "../include/cephes.h"
double psi2(int m, int n);
void
Serial(int m, int n)
{
double p_value1, p_value2, psim0, psim1, psim2, del1, del2;
psim0 = psi2(m, n);
psim1 = psi2(m-1, n);
psim2 = psi2(m-2, n);
del1 = psim0 - psim1;
del2 = psim0 - 2.0*psim1 + psim2;
p_value1 = cephes_igamc(pow(2, m-1)/2, del1/2.0);
p_value2 = cephes_igamc(pow(2, m-2)/2, del2/2.0);
fprintf(stats[TEST_SERIAL], "\t\t\t SERIAL TEST\n");
fprintf(stats[TEST_SERIAL], "\t\t---------------------------------------------\n");
fprintf(stats[TEST_SERIAL], "\t\t COMPUTATIONAL INFORMATION: \n");
fprintf(stats[TEST_SERIAL], "\t\t---------------------------------------------\n");
fprintf(stats[TEST_SERIAL], "\t\t(a) Block length (m) = %d\n", m);
fprintf(stats[TEST_SERIAL], "\t\t(b) Sequence length (n) = %d\n", n);
fprintf(stats[TEST_SERIAL], "\t\t(c) Psi_m = %f\n", psim0);
fprintf(stats[TEST_SERIAL], "\t\t(d) Psi_m-1 = %f\n", psim1);
fprintf(stats[TEST_SERIAL], "\t\t(e) Psi_m-2 = %f\n", psim2);
fprintf(stats[TEST_SERIAL], "\t\t(f) Del_1 = %f\n", del1);
fprintf(stats[TEST_SERIAL], "\t\t(g) Del_2 = %f\n", del2);
fprintf(stats[TEST_SERIAL], "\t\t---------------------------------------------\n");
fprintf(stats[TEST_SERIAL], "%s\t\tp_value1 = %f\n", p_value1 < ALPHA ? "FAILURE" : "SUCCESS", p_value1);
fprintf(results[TEST_SERIAL], "%f\n", p_value1);
fprintf(stats[TEST_SERIAL], "%s\t\tp_value2 = %f\n\n", p_value2 < ALPHA ? "FAILURE" : "SUCCESS", p_value2);
fprintf(results[TEST_SERIAL], "%f\n", p_value2);
}
double
psi2(int m, int n)
{
int i, j, k, powLen;
double sum, numOfBlocks;
unsigned int *P;
if ( (m == 0) || (m == -1) )
return 0.0;
numOfBlocks = n;
powLen = (int)pow(2, m+1)-1;
if ( (P = (unsigned int*)calloc(powLen,sizeof(unsigned int)))== NULL ) {
fprintf(stats[TEST_SERIAL], "Serial Test: Insufficient memory available.\n");
fflush(stats[TEST_SERIAL]);
return 0.0;
}
for ( i=1; i<powLen-1; i++ )
P[i] = 0; /* INITIALIZE NODES */
for ( i=0; i<numOfBlocks; i++ ) { /* COMPUTE FREQUENCY */
k = 1;
for ( j=0; j<m; j++ ) {
if ( epsilon[(i+j)%n] == 0 )
k *= 2;
else if ( epsilon[(i+j)%n] == 1 )
k = 2*k+1;
}
P[k-1]++;
}
sum = 0.0;
for ( i=(int)pow(2, m)-1; i<(int)pow(2, m+1)-1; i++ )
sum += pow(P[i], 2);
sum = (sum * pow(2, m)/(double)n) - (double)n;
free(P);
return sum;
}