/*
* Copyright (c) 2006, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*/
/*
* @test
* @bug 6362557
* @summary Some tests of add(BigDecimal, mc)
* @author Joseph D. Darcy
*/
import java.math.*;
import static java.math.BigDecimal.*;
import java.util.Set;
import java.util.EnumSet;
public class AddTests {
private static Set<RoundingMode> nonExactRoundingModes =
EnumSet.complementOf(EnumSet.of(RoundingMode.UNNECESSARY));
/**
* Test for some simple additions, particularly, it will test
* the overflow case.
*/
private static int simpleTests() {
int failures = 0;
BigDecimal[] bd1 = {
new BigDecimal(new BigInteger("7812404666936930160"), 11),
new BigDecimal(new BigInteger("7812404666936930160"), 12),
new BigDecimal(new BigInteger("7812404666936930160"), 13),
};
BigDecimal bd2 = new BigDecimal(new BigInteger("2790000"), 1);
BigDecimal[] expectedResult = {
new BigDecimal("78403046.66936930160"),
new BigDecimal("8091404.666936930160"),
new BigDecimal("1060240.4666936930160"),
};
for (int i = 0; i < bd1.length; i++) {
if (!bd1[i].add(bd2).equals(expectedResult[i]))
failures++;
}
return failures;
}
/**
* Test for extreme value of scale and rounding precision that
* could cause integer overflow in right-shift-into-sticky-bit
* computations.
*/
private static int extremaTests() {
int failures = 0;
failures += addWithoutException(valueOf(1, -Integer.MAX_VALUE),
valueOf(2, Integer.MAX_VALUE), null);
failures += addWithoutException(valueOf(1, -Integer.MAX_VALUE),
valueOf(-2, Integer.MAX_VALUE), null);
return failures;
}
/**
* Print sum of b1 and b2; correct result will not throw an
* exception.
*/
private static int addWithoutException(BigDecimal b1, BigDecimal b2, MathContext mc) {
if (mc == null)
mc = new MathContext(2, RoundingMode.DOWN);
try {
BigDecimal sum = b1.add(b2, mc);
printAddition(b1, b2, sum.toString());
return 0;
} catch(ArithmeticException ae) {
printAddition(b1, b2, "Exception!");
return 1;
}
}
/**
* Test combinations of operands that may meet the condensation
* criteria when rounded to different precisions.
*/
private static int roundingGradationTests() {
int failures = 0;
failures += roundAway(new BigDecimal("1234e100"),
new BigDecimal( "1234e97"));
failures += roundAway(new BigDecimal("1234e100"),
new BigDecimal( "1234e96"));
failures += roundAway(new BigDecimal("1234e100"),
new BigDecimal( "1234e95"));
failures += roundAway(new BigDecimal("1234e100"),
new BigDecimal( "1234e94"));
failures += roundAway(new BigDecimal("1234e100"),
new BigDecimal( "1234e93"));
failures += roundAway(new BigDecimal("1234e100"),
new BigDecimal( "1234e92"));
failures += roundAway(new BigDecimal("1234e100"),
new BigDecimal("1234e50"));
failures += roundAway(new BigDecimal("1000e100"),
new BigDecimal( "1234e97"));
failures += roundAway(new BigDecimal("1000e100"),
new BigDecimal( "1234e96"));
failures += roundAway(new BigDecimal("1000e100"),
new BigDecimal( "1234e95"));
failures += roundAway(new BigDecimal("1000e100"),
new BigDecimal( "1234e94"));
failures += roundAway(new BigDecimal("1000e100"),
new BigDecimal( "1234e93"));
failures += roundAway(new BigDecimal("1000e100"),
new BigDecimal( "1234e92"));
failures += roundAway(new BigDecimal("1000e100"),
new BigDecimal("1234e50"));
failures += roundAway(new BigDecimal("1999e100"),
new BigDecimal( "1234e97"));
failures += roundAway(new BigDecimal("1999e100"),
new BigDecimal( "1234e96"));
failures += roundAway(new BigDecimal("1999e100"),
new BigDecimal( "1234e95"));
failures += roundAway(new BigDecimal("1999e100"),
new BigDecimal( "1234e94"));
failures += roundAway(new BigDecimal("1999e100"),
new BigDecimal( "1234e93"));
failures += roundAway(new BigDecimal("1999e100"),
new BigDecimal( "1234e92"));
failures += roundAway(new BigDecimal("1999e100"),
new BigDecimal("1234e50"));
failures += roundAway(new BigDecimal("9999e100"),
new BigDecimal( "1234e97"));
failures += roundAway(new BigDecimal("9999e100"),
new BigDecimal( "1234e96"));
failures += roundAway(new BigDecimal("9999e100"),
new BigDecimal( "1234e95"));
failures += roundAway(new BigDecimal("9999e100"),
new BigDecimal( "1234e94"));
failures += roundAway(new BigDecimal("9999e100"),
new BigDecimal( "1234e93"));
failures += roundAway(new BigDecimal("9999e100"),
new BigDecimal( "1234e92"));
failures += roundAway(new BigDecimal("9999e100"),
new BigDecimal("1234e50"));
return failures;
}
private static void printAddition(BigDecimal b1, BigDecimal b2, String s) {
System.out.println("" + b1+ "\t+\t" + b2 + "\t=\t" + s);
}
private static int roundAway(BigDecimal b1, BigDecimal b2) {
int failures = 0;
b1.precision();
b2.precision();
BigDecimal b1_negate = b1.negate();
BigDecimal b2_negate = b2.negate();
b1_negate.precision();
b2_negate.precision();
failures += roundAway1(b1, b2);
failures += roundAway1(b1, b2_negate);
failures += roundAway1(b1_negate, b2);
failures += roundAway1(b1_negate, b2_negate);
return failures;
}
private static int roundAway1(BigDecimal b1, BigDecimal b2) {
int failures = 0;
failures += roundAway0(b1, b2);
failures += roundAway0(b2, b1);
return failures;
}
/**
* Compare b1.add(b2, mc) with b1.add(b2).round(mc) for a variety
* of MathContexts.
*/
private static int roundAway0(BigDecimal b1, BigDecimal b2) {
int failures = 0;
BigDecimal exactSum = b1.add(b2);
for(int precision = 1 ; precision < exactSum.precision()+2; precision++) {
for(RoundingMode rm : nonExactRoundingModes) {
MathContext mc = new MathContext(precision, rm);
BigDecimal roundedExactSum = exactSum.round(mc);
try {
BigDecimal sum = b1.add(b2, mc);
if (!roundedExactSum.equals(sum) ) {
failures++;
System.out.println("Exact sum " + exactSum +
"\trounded by " + mc +
"\texpected: " + roundedExactSum + " got: ");
printAddition(b1, b2, sum.toString());
}
// else {
// System.out.print(mc + "\t");
// printAddition(b1, b2, sum.toString());
// }
} catch (ArithmeticException ae) {
printAddition(b1, b2, "Exception!");
failures++;
}
}
}
return failures;
}
/**
* Verify calling the precision method should not change the
* computed result.
*/
private static int precisionConsistencyTest() {
int failures = 0;
MathContext mc = new MathContext(1,RoundingMode.DOWN);
BigDecimal a = BigDecimal.valueOf(1999, -1); //value is equivalent to 19990
BigDecimal sum1 = a.add(BigDecimal.ONE, mc);
a.precision();
BigDecimal sum2 = a.add(BigDecimal.ONE, mc);
if (!sum1.equals(sum2)) {
failures ++;
System.out.println("Unequal sums after calling precision!");
System.out.print("Before:\t");
printAddition(a, BigDecimal.ONE, sum1.toString());
System.out.print("After:\t");
printAddition(a, BigDecimal.ONE, sum2.toString());
}
return failures;
}
public static void main(String argv[]) {
int failures = 0;
failures += extremaTests();
failures += roundingGradationTests();
failures += precisionConsistencyTest();
if (failures > 0) {
throw new RuntimeException("Incurred " + failures +
" failures while testing rounding add.");
}
}
}