Increment floating point numbers with the precision of the input with Java - java

I am looking for the most optimized and easy to read version of incrementing a floating point number with its own precision:
increment(1000) should return 1001
increment(100.1) should return 100.2
increment(0.1) should return 0.2
increment(0.01) should return 0.02
increment(0.001) should return 0.002
increment(0.0009) should return 0.0010
increment(0.000123) should return 0.000124
increment(increment(0.0009)) should return 0.002
It could be done by string operation but I don't want to convert this to string and parse it back to double.
I have done the following with String operations:
public static double incrementWithMover(double value){
DecimalFormat df = new DecimalFormat("0", DecimalFormatSymbols.getInstance(Locale.ENGLISH));
df.setMaximumFractionDigits(340); //340 = DecimalFormat.DOUBLE_FRACTION_DIGITS
String valueString = df.format(value);
String[] splitted = valueString.split("\\.");
StringBuilder mover = new StringBuilder();
if(splitted.length == 2){ // Floating Decimals
int precision = splitted[1].length();
df.setMaximumFractionDigits(precision);
mover = new StringBuilder("0.");
for(int i =1; i<precision; i++){
mover.append("0");
}
mover.append("1");
}
else{ // Non Floating Decimals
mover = new StringBuilder("1");
}
double incremented = Double.parseDouble(valueString) + Double.parseDouble(mover.toString());
return Double.parseDouble(df.format(incremented));
}
I am trying to write this method due to I am checking different values and trying to increment all the values in their own precision by one
What could be the best way to write such incrementFloating method?


This may work for you. Changed from doubles to strings.
String[] vals = { "1000","1000.1", ".1", ".01", ".001", ".00123", ".0004" };
for (String v : vals) {
System.out.printf("%s -> %s%n", v, incrementFloating(v));
}
prints
1000 -> 1001
1000.1 -> 1000.2
.1 -> 0.2
.01 -> 0.02
.001 -> 0.002
.00123 -> 0.00124
.0004 -> 0.0005
The method declaration
public static String incrementFloating(String v) {
BigDecimal b = new BigDecimal(v);
BigDecimal increment =
BigDecimal.valueOf(1).scaleByPowerOfTen(-b.scale());
return b.add(increment).stripTrailingZeros().toString();
}


Increment floating point numbers with the precision of the input with Java
This just isn't how it works.
Floats and Doubles aren't stored like you evidently think they are.
Imagine the whole number line. from negative infinity to positive infinity.
This line has an infinite number of integer values on it. Between any 2 integer values, and infinite number of values exist there, too.
Computers aren't magic. Floats are 32-bit, doubles are 64-bit. A 32-bit, by basic math, can only differentiate at most 2^32 numbers, that's about 4 billion.
4 billion is way, way less than 2 orders of infinity.
So how does that work then? Well, there are about 4 billion numbers that are 'blessed'. These numbers are representable by float, and no other numbers are. 0.3, for example, is not blessed. 0.3 is simply not a number in the float numeric system. It doesn't exist.
So, how do I explain that float x = 0.3; works, or what happens when you run float x = 0.1 + 0.2;?
Well, float and double operations convert, silently, to the nearest blessed number.
The distribution of blessed numbers is based on binary (so in decimal they don't make any particular sense), and aren't equally distributed. Near 1.0 there are way more than near 100.0, for example.
That means errors sneak in everywhere. The operation you describe fundamentally doesn't make sense here. You can't do what you want with floats or doubles. Period.
Go with Strings, or go with BigDecimal.
If you're interested, here you go:
BigDecimal bd = new BigDecimal(0.3);
System.out.println(bd);
> 0.299999999999999988897769753748434595763683319091796875
I didn't make that up. Write that code and run it. What is that ungodly number?
That's the nearest blessed number to 0.3.
So, in double number systems, applying your algorithm, increment(0.3) would try to calculate 0.299999999999999988897769753748434595763683319091796876, which isn't blessed, and the nearest blessed number to that is simply 0.299999999999999988897769753748434595763683319091796875 again, and the operation would do nothing.
Makes no sense.
Strings or BigDecimal, it is the only way. Efficiency is in that sense out the window, but unless you intent to run this op a few million times a second, you won't notice.

Related

Observations with Round-ing in Android Studio - java. And some practical explanations expected

In Android Studio I had problems with calculating invoice totals because of the way java rounds. I know there are a lot of explanations, but many recommend methods that don't return reliable results.
For example:
1. Math.round((double)4.715 * (double)100 ) / (double)100 = 4.72 (expected 4.72)
2. Math.round((double)4.725 * (double)100 ) / (double)100 = 4.72 (but expected 4.73)
You can't put this code in an app for a client who calculates invoices. Because , in my case for example, the same invoice is calculated in another system and the result is different, meaning 4.72 respectively 4.73
I know that a double can't be represented exactly and the decimals are different than what we see. But we need a method that returns results as we expect.
Another example would be:
1. java.math.BigDecimal.valueOf(4.715).setScale(2,java.math.BigDecimal.ROUND_HALF_UP).doubleValue() = 4.72
2. new java.math.BigDecimal(4.715).setScale(2,java.math.BigDecimal.ROUND_HALF_UP).doubleValue() = 4.71
3. new java.math.BigDecimal( String.valueOf(4.715) ).setScale(2,java.math.BigDecimal.ROUND_HALF_UP).doubleValue() = 4.72
I think all these aspects could be well explained in Java documentation, but they should indicate a certain method for calculating rounds, a reliable method which returns results as we expected. I only wanted to round to 2 decimales.
In conclusion, which I hope will help some of the beginners, I think that the following method would return stable and good results:
java.math.BigDecimal.valueOf(4.715).setScale(2,java.math.BigDecimal.ROUND_HALF_UP).doubleValue() = 4.72
Or, at least, this is my observation after 3+ years of intensive usage of an app (500+ users every working day).
All practical explanations for these above are very welcome, so we can better understand how to avoid unexpected results.

For the BigDecimal examples the javadoc explains the difference.
BigDecimal(double value) ... is the exact decimal representation of the double's binary floating-point value.
Which we can check, by just printing the value.
System.out.println(new BigDecimal(4.715));
#4.714999999999999857891452847979962825775146484375
Which is barely less than 4.715, but enough such that it gets rounded down.
BigDecimal.valueOf(double value) uses the string representation of the double value from Double.toString(double value) which has quite a few rules.
System.out.println(Double.toString(4.715));
#4.715
The safest best is to just use BigDecimal for your calculations. Especially when dealing with arithmetic operations. It isn't clear when the value will switch to needing more decimal places. For example:
double d = 4.11547;
BigDecimal bd = BigDecimal.valueOf(d);
I this case, the string representation of d is 4.11547, so BigDecimal.valueOf returns the value that is written.
BigDecimal s1 = BigDecimal.valueOf(d-3);
BigDecimal s2 = bd.subtract(new BigDecimal(3));
It might be surprising to find s1 and s2 are different since '3' doesn't get rounded.
System.out.println(s1 + ", " + s2);
#1.1154700000000002, 1.11547
So it is best to use the BigDecimal methods for arithmetic too.

It's in the nature of binary floating point data types, like float and double in Java. double actually states this in his name. It has double precision compared to float - but it is not an exact representation of a decimal number.
Just adding some simplified math detail to the existing answer. This might help understand the seemingly strange behavior of Java floating point numbers.
The root cause of the problem is binary vs. decimal representation of numbers. You use decimal representation when you use a floating point literal in your code, e.g. double d = 1.5; or a String value, e.g. String s = "1.5";.
But the JVM uses a binary representation of the number. The mapping for integer numbers is easy (d for decimal, b for binary): 1 = 1b, 2d = 10b, 3d = 11b .... There is no issue with integer numbers. int and long work just the way you would expect. Except for the overflow...
But for floating point numbers things are different: 0.5d = 0.1b, 0.25d = 0.01b, 0.125d = 0.001b.... You are only able to add values for the series 1/2, 1/4, 1/8, 1/16... Now imagine, you want to show 0.1d in binary representation.
You start with 0.0001b = 0.0625d, which is the first binary value that is still less than 0.1d. 0.0375d remaining. You continue, and the next close value is 0.03125d, and so on. You'll acutally never get to exactly 0.1d. All you get is an approximation. You'll get closer and closer.
Consider the following piece of code. It does the approximation with the help of BigDecimal values:
public void approximate0dot1() {
BigDecimal destVal = new BigDecimal("0.1");
BigDecimal curVal = new BigDecimal("0");
BigDecimal inc = new BigDecimal("1");
BigDecimal div = new BigDecimal("2");
for (int step = 0; step < 20; step++) {
BigDecimal probeVal = curVal.add(inc);
int cmp = probeVal.compareTo(destVal);
if (cmp == 0) {
break;
} else if (cmp < 0) {
curVal = probeVal;
System.out.format("Added: %s, current value: %s, remaining: %s\n", inc, curVal, destVal.subtract(curVal));
}
inc = inc.divide(div);
}
System.out.format("Final value: %s\n", curVal);
}
And the output is:
Added: 0.0625, current value: 0.0625, remaining: 0.0375
Added: 0.03125, current value: 0.09375, remaining: 0.00625
Added: 0.00390625, current value: 0.09765625, remaining: 0.00234375
Added: 0.001953125, current value: 0.099609375, remaining: 0.000390625
Added: 0.000244140625, current value: 0.099853515625, remaining: 0.000146484375
Added: 0.0001220703125, current value: 0.0999755859375, remaining: 0.0000244140625
Added: 0.0000152587890625, current value: 0.0999908447265625, remaining: 0.0000091552734375
Added: 0.00000762939453125, current value: 0.09999847412109375, remaining: 0.00000152587890625
Final value: 0.09999847412109375
This is just a basic example to show the underlying issue. Internally, the JVM obviously does some optimization to get the best possible approximation for the available 64-bit precision, e.g.
System.out.println(new BigDecimal(0.1));
// prints 0.1000000000000000055511151231257827021181583404541015625
But this example shows, that there is already a rounding issue with decimal numbers a simple as a constant with the decimal value 0.1.
Some basic tips:
Do not use BigDecimal(double) constructor if you need exact decimal math, use BigDecimal(String) instead. Bad: new BigDecimal(0.1), Good: new BigDecimal("0.1")
Do not mix BigDecimal and floating point arithmetic, e.g. do not extract double value for further calculations like new BigDecimal("0.1").doubleValue();

Math in Java when precision is lost

The below algorithm works to identify a factor of a small number but fails completely when using a large one such as 7534534523.0
double result = 7; // 7534534523.0;
double divisor = 1;
for (int i = 2; i < result; i++){
double r = result / (double)i;
if (Math.floor(r) == r){
divisor = i;
break;
}
}
System.out.println(result + "/" + divisor + "=" + (result/divisor));
The number 7534534523.0 divided by 2 on a calculator can give a decimal part or round it (losing the 0.5). How can I perform such a check on large numbers? Do I have to use BigDecimal for this? Or is there another way?

If your goal is to represent a number with exactly n significant figures to the right of the decimal, BigDecimal is the class to use.
Immutable, arbitrary-precision signed decimal numbers. A BigDecimal consists of an arbitrary precision integer unscaled value and a 32-bit integer scale. If zero or positive, the scale is the number of digits to the right of the decimal point. If negative, the unscaled value of the number is multiplied by ten to the power of the negation of the scale. The value of the number represented by the BigDecimal is therefore (unscaledValue × 10-scale).
Additionally, you can have a better control over scale manipulation, rounding and format conversion.

I don't see what the problem is in your code. It works exactly like it should.
When I run your code I get this output:
7.534534523E9/77359.0=97397.0
That may have confused you, but its perfectly fine. It's just using scientific notation, but there is nothing wrong with that.
7.534534523E9 = 7.534534523 * 109 = 7,534,534,523
If you want to see it in normal notation, you can use System.out.format to print the result:
System.out.format("%.0f/%.0f=%.0f\n", result, divisor, result / divisor);
Shows:
7534534523/77359=97397
But you don't need double or BigDecimal to check if a number is divisible by another number. You can use the modulo operator on integral types to check if one number is divisible by another. As long as your numbers fit in a long, this works, otherwise you can move on to a BigInteger:
long result = 7534534523L;
long divisor = 1;
for (int i = 2; i < result; i++) {
if (result % i == 0) {
divisor = i;
break;
}
}
System.out.println(result + "/" + divisor + "=" + (result / divisor));

BigDecimal is the way to move ahead for preserving high precision in numbers.
DO NOT do not use constructor BigDecimal(double val) as the rounding is performed and the output is not always same. The same is mentioned in the implementation as well. According to it:
The results of this constructor can be somewhat unpredictable. One might assume that writing new BigDecimal(0.1) in Java creates a BigDecimal which is exactly equal to 0.1 (an unscaled value of 1, with a scale of 1), but it is actually equal to 0.1000000000000000055511151231257827021181583404541015625. This is because 0.1 cannot be represented exactly as a double (or, for that matter, as a binary fraction of any finite length). Thus, the value that is being passed in to the constructor is not exactly equal to 0.1, appearances notwithstanding.
ALWAYS try to use constructor BigDecimal(String val) as it preserves precision and gives same output each time.

double inaccuracy [duplicate]

public class doublePrecision {
public static void main(String[] args) {
double total = 0;
total += 5.6;
total += 5.8;
System.out.println(total);
}
}
The above code prints:
11.399999999999
How would I get this to just print (or be able to use it as) 11.4?

As others have mentioned, you'll probably want to use the BigDecimal class, if you want to have an exact representation of 11.4.
Now, a little explanation into why this is happening:
The float and double primitive types in Java are floating point numbers, where the number is stored as a binary representation of a fraction and a exponent.
More specifically, a double-precision floating point value such as the double type is a 64-bit value, where:
1 bit denotes the sign (positive or negative).
11 bits for the exponent.
52 bits for the significant digits (the fractional part as a binary).
These parts are combined to produce a double representation of a value.
(Source: Wikipedia: Double precision)
For a detailed description of how floating point values are handled in Java, see the Section 4.2.3: Floating-Point Types, Formats, and Values of the Java Language Specification.
The byte, char, int, long types are fixed-point numbers, which are exact representions of numbers. Unlike fixed point numbers, floating point numbers will some times (safe to assume "most of the time") not be able to return an exact representation of a number. This is the reason why you end up with 11.399999999999 as the result of 5.6 + 5.8.
When requiring a value that is exact, such as 1.5 or 150.1005, you'll want to use one of the fixed-point types, which will be able to represent the number exactly.
As has been mentioned several times already, Java has a BigDecimal class which will handle very large numbers and very small numbers.
From the Java API Reference for the BigDecimal class:
Immutable,
arbitrary-precision signed decimal
numbers. A BigDecimal consists of an
arbitrary precision integer unscaled
value and a 32-bit integer scale. If
zero or positive, the scale is the
number of digits to the right of the
decimal point. If negative, the
unscaled value of the number is
multiplied by ten to the power of the
negation of the scale. The value of
the number represented by the
BigDecimal is therefore (unscaledValue
× 10^-scale).
There has been many questions on Stack Overflow relating to the matter of floating point numbers and its precision. Here is a list of related questions that may be of interest:
Why do I see a double variable initialized to some value like 21.4 as 21.399999618530273?
How to print really big numbers in C++
How is floating point stored? When does it matter?
Use Float or Decimal for Accounting Application Dollar Amount?
If you really want to get down to the nitty gritty details of floating point numbers, take a look at What Every Computer Scientist Should Know About Floating-Point Arithmetic.

When you input a double number, for example, 33.33333333333333, the value you get is actually the closest representable double-precision value, which is exactly:
33.3333333333333285963817615993320941925048828125
Dividing that by 100 gives:
0.333333333333333285963817615993320941925048828125
which also isn't representable as a double-precision number, so again it is rounded to the nearest representable value, which is exactly:
0.3333333333333332593184650249895639717578887939453125
When you print this value out, it gets rounded yet again to 17 decimal digits, giving:
0.33333333333333326

If you just want to process values as fractions, you can create a Fraction class which holds a numerator and denominator field.
Write methods for add, subtract, multiply and divide as well as a toDouble method. This way you can avoid floats during calculations.
EDIT: Quick implementation,
public class Fraction {
private int numerator;
private int denominator;
public Fraction(int n, int d){
numerator = n;
denominator = d;
}
public double toDouble(){
return ((double)numerator)/((double)denominator);
}
public static Fraction add(Fraction a, Fraction b){
if(a.denominator != b.denominator){
double aTop = b.denominator * a.numerator;
double bTop = a.denominator * b.numerator;
return new Fraction(aTop + bTop, a.denominator * b.denominator);
}
else{
return new Fraction(a.numerator + b.numerator, a.denominator);
}
}
public static Fraction divide(Fraction a, Fraction b){
return new Fraction(a.numerator * b.denominator, a.denominator * b.numerator);
}
public static Fraction multiply(Fraction a, Fraction b){
return new Fraction(a.numerator * b.numerator, a.denominator * b.denominator);
}
public static Fraction subtract(Fraction a, Fraction b){
if(a.denominator != b.denominator){
double aTop = b.denominator * a.numerator;
double bTop = a.denominator * b.numerator;
return new Fraction(aTop-bTop, a.denominator*b.denominator);
}
else{
return new Fraction(a.numerator - b.numerator, a.denominator);
}
}
}

Observe that you'd have the same problem if you used limited-precision decimal arithmetic, and wanted to deal with 1/3: 0.333333333 * 3 is 0.999999999, not 1.00000000.
Unfortunately, 5.6, 5.8 and 11.4 just aren't round numbers in binary, because they involve fifths. So the float representation of them isn't exact, just as 0.3333 isn't exactly 1/3.
If all the numbers you use are non-recurring decimals, and you want exact results, use BigDecimal. Or as others have said, if your values are like money in the sense that they're all a multiple of 0.01, or 0.001, or something, then multiply everything by a fixed power of 10 and use int or long (addition and subtraction are trivial: watch out for multiplication).
However, if you are happy with binary for the calculation, but you just want to print things out in a slightly friendlier format, try java.util.Formatter or String.format. In the format string specify a precision less than the full precision of a double. To 10 significant figures, say, 11.399999999999 is 11.4, so the result will be almost as accurate and more human-readable in cases where the binary result is very close to a value requiring only a few decimal places.
The precision to specify depends a bit on how much maths you've done with your numbers - in general the more you do, the more error will accumulate, but some algorithms accumulate it much faster than others (they're called "unstable" as opposed to "stable" with respect to rounding errors). If all you're doing is adding a few values, then I'd guess that dropping just one decimal place of precision will sort things out. Experiment.

You may want to look into using java's java.math.BigDecimal class if you really need precision math. Here is a good article from Oracle/Sun on the case for BigDecimal. While you can never represent 1/3 as someone mentioned, you can have the power to decide exactly how precise you want the result to be. setScale() is your friend.. :)
Ok, because I have way too much time on my hands at the moment here is a code example that relates to your question:
import java.math.BigDecimal;
/**
* Created by a wonderful programmer known as:
* Vincent Stoessel
* xaymaca#gmail.com
* on Mar 17, 2010 at 11:05:16 PM
*/
public class BigUp {
public static void main(String[] args) {
BigDecimal first, second, result ;
first = new BigDecimal("33.33333333333333") ;
second = new BigDecimal("100") ;
result = first.divide(second);
System.out.println("result is " + result);
//will print : result is 0.3333333333333333
}
}
and to plug my new favorite language, Groovy, here is a neater example of the same thing:
import java.math.BigDecimal
def first = new BigDecimal("33.33333333333333")
def second = new BigDecimal("100")
println "result is " + first/second // will print: result is 0.33333333333333

Pretty sure you could've made that into a three line example. :)
If you want exact precision, use BigDecimal. Otherwise, you can use ints multiplied by 10 ^ whatever precision you want.

As others have noted, not all decimal values can be represented as binary since decimal is based on powers of 10 and binary is based on powers of two.
If precision matters, use BigDecimal, but if you just want friendly output:
System.out.printf("%.2f\n", total);
Will give you:
11.40

You're running up against the precision limitation of type double.
Java.Math has some arbitrary-precision arithmetic facilities.

You can't, because 7.3 doesn't have a finite representation in binary. The closest you can get is 2054767329987789/2**48 = 7.3+1/1407374883553280.
Take a look at http://docs.python.org/tutorial/floatingpoint.html for a further explanation. (It's on the Python website, but Java and C++ have the same "problem".)
The solution depends on what exactly your problem is:
If it's that you just don't like seeing all those noise digits, then fix your string formatting. Don't display more than 15 significant digits (or 7 for float).
If it's that the inexactness of your numbers is breaking things like "if" statements, then you should write if (abs(x - 7.3) < TOLERANCE) instead of if (x == 7.3).
If you're working with money, then what you probably really want is decimal fixed point. Store an integer number of cents or whatever the smallest unit of your currency is.
(VERY UNLIKELY) If you need more than 53 significant bits (15-16 significant digits) of precision, then use a high-precision floating-point type, like BigDecimal.

private void getRound() {
// this is very simple and interesting
double a = 5, b = 3, c;
c = a / b;
System.out.println(" round val is " + c);
// round val is : 1.6666666666666667
// if you want to only two precision point with double we
// can use formate option in String
// which takes 2 parameters one is formte specifier which
// shows dicimal places another double value
String s = String.format("%.2f", c);
double val = Double.parseDouble(s);
System.out.println(" val is :" + val);
// now out put will be : val is :1.67
}

Use java.math.BigDecimal
Doubles are binary fractions internally, so they sometimes cannot represent decimal fractions to the exact decimal.

/*
0.8 1.2
0.7 1.3
0.7000000000000002 2.3
0.7999999999999998 4.2
*/
double adjust = fToInt + 1.0 - orgV;
// The following two lines works for me.
String s = String.format("%.2f", adjust);
double val = Double.parseDouble(s);
System.out.println(val); // output: 0.8, 0.7, 0.7, 0.8

Doubles are approximations of the decimal numbers in your Java source. You're seeing the consequence of the mismatch between the double (which is a binary-coded value) and your source (which is decimal-coded).
Java's producing the closest binary approximation. You can use the java.text.DecimalFormat to display a better-looking decimal value.

Short answer: Always use BigDecimal and make sure you are using the constructor with String argument, not the double one.
Back to your example, the following code will print 11.4, as you wish.
public class doublePrecision {
public static void main(String[] args) {
BigDecimal total = new BigDecimal("0");
total = total.add(new BigDecimal("5.6"));
total = total.add(new BigDecimal("5.8"));
System.out.println(total);
}
}

Multiply everything by 100 and store it in a long as cents.

Computers store numbers in binary and can't actually represent numbers such as 33.333333333 or 100.0 exactly. This is one of the tricky things about using doubles. You will have to just round the answer before showing it to a user. Luckily in most applications, you don't need that many decimal places anyhow.

Floating point numbers differ from real numbers in that for any given floating point number there is a next higher floating point number. Same as integers. There's no integer between 1 and 2.
There's no way to represent 1/3 as a float. There's a float below it and there's a float above it, and there's a certain distance between them. And 1/3 is in that space.
Apfloat for Java claims to work with arbitrary precision floating point numbers, but I've never used it. Probably worth a look.
http://www.apfloat.org/apfloat_java/
A similar question was asked here before
Java floating point high precision library

Use a BigDecimal. It even lets you specify rounding rules (like ROUND_HALF_EVEN, which will minimize statistical error by rounding to the even neighbor if both are the same distance; i.e. both 1.5 and 2.5 round to 2).

Why not use the round() method from Math class?
// The number of 0s determines how many digits you want after the floating point
// (here one digit)
total = (double)Math.round(total * 10) / 10;
System.out.println(total); // prints 11.4

Check out BigDecimal, it handles problems dealing with floating point arithmetic like that.
The new call would look like this:
term[number].coefficient.add(co);
Use setScale() to set the number of decimal place precision to be used.

If you have no choice other than using double values, can use the below code.
public static double sumDouble(double value1, double value2) {
double sum = 0.0;
String value1Str = Double.toString(value1);
int decimalIndex = value1Str.indexOf(".");
int value1Precision = 0;
if (decimalIndex != -1) {
value1Precision = (value1Str.length() - 1) - decimalIndex;
}
String value2Str = Double.toString(value2);
decimalIndex = value2Str.indexOf(".");
int value2Precision = 0;
if (decimalIndex != -1) {
value2Precision = (value2Str.length() - 1) - decimalIndex;
}
int maxPrecision = value1Precision > value2Precision ? value1Precision : value2Precision;
sum = value1 + value2;
String s = String.format("%." + maxPrecision + "f", sum);
sum = Double.parseDouble(s);
return sum;
}

You can Do the Following!
System.out.println(String.format("%.12f", total));
if you change the decimal value here %.12f

So far I understand it as main goal to get correct double from wrong double.
Look for my solution how to get correct value from "approximate" wrong value - if it is real floating point it rounds last digit - counted from all digits - counting before dot and try to keep max possible digits after dot - hope that it is enough precision for most cases:
public static double roundError(double value) {
BigDecimal valueBigDecimal = new BigDecimal(Double.toString(value));
String valueString = valueBigDecimal.toPlainString();
if (!valueString.contains(".")) return value;
String[] valueArray = valueString.split("[.]");
int places = 16;
places -= valueArray[0].length();
if ("56789".contains("" + valueArray[0].charAt(valueArray[0].length() - 1))) places--;
//System.out.println("Rounding " + value + "(" + valueString + ") to " + places + " places");
return valueBigDecimal.setScale(places, RoundingMode.HALF_UP).doubleValue();
}
I know it is long code, sure not best, maybe someone can fix it to be more elegant. Anyway it is working, see examples:
roundError(5.6+5.8) = 11.399999999999999 = 11.4
roundError(0.4-0.3) = 0.10000000000000003 = 0.1
roundError(37235.137567000005) = 37235.137567
roundError(1/3) 0.3333333333333333 = 0.333333333333333
roundError(3723513756.7000005) = 3.7235137567E9 (3723513756.7)
roundError(3723513756123.7000005) = 3.7235137561237E12 (3723513756123.7)
roundError(372351375612.7000005) = 3.723513756127E11 (372351375612.7)
roundError(1.7976931348623157) = 1.797693134862316

Do not waste your efford using BigDecimal. In 99.99999% cases you don't need it. java double type is of cource approximate but in almost all cases, it is sufficiently precise. Mind that your have an error at 14th significant digit. This is really negligible!
To get nice output use:
System.out.printf("%.2f\n", total);

Java: understanding double (and normalization)

I'm trying to learn a bit on robotics and Java. In my attempt I have written a function that (should) take a uniformed array called q(0.2,0.2,0.2,0.2,0.2), multiply each value in this array by 0.6 or 0.2 based on value Z, compared to another array world (0,1,1,0,0) that represents hit or miss of value Z compared to array world and finally return a new uniformed array.
So:
1.) Loop through (0,1,1,0,0)
2.) if i!=Z than i*0.2, if i=Z than i*0.6
3.) sum all new values in q to a double called normalize
4.) normalize each value in q (value / normalize)
Below is the function:
public static final double pHit = 0.6;
public static final double pMiss = 0.2;
public static int[] world = {0,1,1,0,0};
public static List<Double> q = new ArrayList<Double>();
public static List<Double> sense(int Z){
double normalize = 0;
for(int i=0;i < q.size();i++){
if(Z == world[i]){
q.set(i, (q.get(i) * pHit));
}
else{
q.set(i, (q.get(i) * pMiss));
}
}
//Normalize
for(int i=0;i < q.size();i++){
normalize += q.get(i);
}
for(int i=0;i<q.size();i++){
q.set(i, q.get(i)/normalize);
}
return q;
}
If I set world to (0,1,0,0,0) and Z to 1 I get following results:
0.14285714285714288
0.4285714285714285
0.14285714285714288
0.14285714285714288
0.14285714285714288
This normalizes nicely (sum = 1).
But if I set world to (0,1,1,0,0) and Z to 1 I get a strange result:
0.1111111111111111
0.3333333333333332
0.3333333333333332
0.1111111111111111
0.1111111111111111
This "normalizes" to 0.9999999999999998 ?
Many thanks for any input!

Doubles are not perfect representations of the real number line. They have only about 16 digits of precision. In successive computations, errors can build, sometimes catastrophically. In your case, this has not happened, so be happy.
The value of 0.1 is a nice example. In IEEE floating point, it has only an approximate representation. As a binary fraction, it is 0.0[0011] where the part in square braces repeats forever. This is why floating point numbers (including doubles) may not be the best choice for representing prices.
I highly suggest reading this classic summary:
http://docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html

Floating point numbers are not exactly represented on computers. For that reason you'll get very small fractions off from exact values when multiplying floating values together.
See this answer as it goes into more depth about floating representations and references this Floating-Point Arithmetic article.

Welcome to the world of floating point numbers!
I did not try to understand your code in detail, but the result 0.9999999999999998 is perfectly normal. I recommend you to read a bit about floating point numbers and their precision.

Retain precision with double in Java

public class doublePrecision {
public static void main(String[] args) {
double total = 0;
total += 5.6;
total += 5.8;
System.out.println(total);
}
}
The above code prints:
11.399999999999
How would I get this to just print (or be able to use it as) 11.4?

As others have mentioned, you'll probably want to use the BigDecimal class, if you want to have an exact representation of 11.4.
Now, a little explanation into why this is happening:
The float and double primitive types in Java are floating point numbers, where the number is stored as a binary representation of a fraction and a exponent.
More specifically, a double-precision floating point value such as the double type is a 64-bit value, where:
1 bit denotes the sign (positive or negative).
11 bits for the exponent.
52 bits for the significant digits (the fractional part as a binary).
These parts are combined to produce a double representation of a value.
(Source: Wikipedia: Double precision)
For a detailed description of how floating point values are handled in Java, see the Section 4.2.3: Floating-Point Types, Formats, and Values of the Java Language Specification.
The byte, char, int, long types are fixed-point numbers, which are exact representions of numbers. Unlike fixed point numbers, floating point numbers will some times (safe to assume "most of the time") not be able to return an exact representation of a number. This is the reason why you end up with 11.399999999999 as the result of 5.6 + 5.8.
When requiring a value that is exact, such as 1.5 or 150.1005, you'll want to use one of the fixed-point types, which will be able to represent the number exactly.
As has been mentioned several times already, Java has a BigDecimal class which will handle very large numbers and very small numbers.
From the Java API Reference for the BigDecimal class:
Immutable,
arbitrary-precision signed decimal
numbers. A BigDecimal consists of an
arbitrary precision integer unscaled
value and a 32-bit integer scale. If
zero or positive, the scale is the
number of digits to the right of the
decimal point. If negative, the
unscaled value of the number is
multiplied by ten to the power of the
negation of the scale. The value of
the number represented by the
BigDecimal is therefore (unscaledValue
× 10^-scale).
There has been many questions on Stack Overflow relating to the matter of floating point numbers and its precision. Here is a list of related questions that may be of interest:
Why do I see a double variable initialized to some value like 21.4 as 21.399999618530273?
How to print really big numbers in C++
How is floating point stored? When does it matter?
Use Float or Decimal for Accounting Application Dollar Amount?
If you really want to get down to the nitty gritty details of floating point numbers, take a look at What Every Computer Scientist Should Know About Floating-Point Arithmetic.

When you input a double number, for example, 33.33333333333333, the value you get is actually the closest representable double-precision value, which is exactly:
33.3333333333333285963817615993320941925048828125
Dividing that by 100 gives:
0.333333333333333285963817615993320941925048828125
which also isn't representable as a double-precision number, so again it is rounded to the nearest representable value, which is exactly:
0.3333333333333332593184650249895639717578887939453125
When you print this value out, it gets rounded yet again to 17 decimal digits, giving:
0.33333333333333326

If you just want to process values as fractions, you can create a Fraction class which holds a numerator and denominator field.
Write methods for add, subtract, multiply and divide as well as a toDouble method. This way you can avoid floats during calculations.
EDIT: Quick implementation,
public class Fraction {
private int numerator;
private int denominator;
public Fraction(int n, int d){
numerator = n;
denominator = d;
}
public double toDouble(){
return ((double)numerator)/((double)denominator);
}
public static Fraction add(Fraction a, Fraction b){
if(a.denominator != b.denominator){
double aTop = b.denominator * a.numerator;
double bTop = a.denominator * b.numerator;
return new Fraction(aTop + bTop, a.denominator * b.denominator);
}
else{
return new Fraction(a.numerator + b.numerator, a.denominator);
}
}
public static Fraction divide(Fraction a, Fraction b){
return new Fraction(a.numerator * b.denominator, a.denominator * b.numerator);
}
public static Fraction multiply(Fraction a, Fraction b){
return new Fraction(a.numerator * b.numerator, a.denominator * b.denominator);
}
public static Fraction subtract(Fraction a, Fraction b){
if(a.denominator != b.denominator){
double aTop = b.denominator * a.numerator;
double bTop = a.denominator * b.numerator;
return new Fraction(aTop-bTop, a.denominator*b.denominator);
}
else{
return new Fraction(a.numerator - b.numerator, a.denominator);
}
}
}

Observe that you'd have the same problem if you used limited-precision decimal arithmetic, and wanted to deal with 1/3: 0.333333333 * 3 is 0.999999999, not 1.00000000.
Unfortunately, 5.6, 5.8 and 11.4 just aren't round numbers in binary, because they involve fifths. So the float representation of them isn't exact, just as 0.3333 isn't exactly 1/3.
If all the numbers you use are non-recurring decimals, and you want exact results, use BigDecimal. Or as others have said, if your values are like money in the sense that they're all a multiple of 0.01, or 0.001, or something, then multiply everything by a fixed power of 10 and use int or long (addition and subtraction are trivial: watch out for multiplication).
However, if you are happy with binary for the calculation, but you just want to print things out in a slightly friendlier format, try java.util.Formatter or String.format. In the format string specify a precision less than the full precision of a double. To 10 significant figures, say, 11.399999999999 is 11.4, so the result will be almost as accurate and more human-readable in cases where the binary result is very close to a value requiring only a few decimal places.
The precision to specify depends a bit on how much maths you've done with your numbers - in general the more you do, the more error will accumulate, but some algorithms accumulate it much faster than others (they're called "unstable" as opposed to "stable" with respect to rounding errors). If all you're doing is adding a few values, then I'd guess that dropping just one decimal place of precision will sort things out. Experiment.

You may want to look into using java's java.math.BigDecimal class if you really need precision math. Here is a good article from Oracle/Sun on the case for BigDecimal. While you can never represent 1/3 as someone mentioned, you can have the power to decide exactly how precise you want the result to be. setScale() is your friend.. :)
Ok, because I have way too much time on my hands at the moment here is a code example that relates to your question:
import java.math.BigDecimal;
/**
* Created by a wonderful programmer known as:
* Vincent Stoessel
* xaymaca#gmail.com
* on Mar 17, 2010 at 11:05:16 PM
*/
public class BigUp {
public static void main(String[] args) {
BigDecimal first, second, result ;
first = new BigDecimal("33.33333333333333") ;
second = new BigDecimal("100") ;
result = first.divide(second);
System.out.println("result is " + result);
//will print : result is 0.3333333333333333
}
}
and to plug my new favorite language, Groovy, here is a neater example of the same thing:
import java.math.BigDecimal
def first = new BigDecimal("33.33333333333333")
def second = new BigDecimal("100")
println "result is " + first/second // will print: result is 0.33333333333333

Pretty sure you could've made that into a three line example. :)
If you want exact precision, use BigDecimal. Otherwise, you can use ints multiplied by 10 ^ whatever precision you want.

As others have noted, not all decimal values can be represented as binary since decimal is based on powers of 10 and binary is based on powers of two.
If precision matters, use BigDecimal, but if you just want friendly output:
System.out.printf("%.2f\n", total);
Will give you:
11.40

You're running up against the precision limitation of type double.
Java.Math has some arbitrary-precision arithmetic facilities.

You can't, because 7.3 doesn't have a finite representation in binary. The closest you can get is 2054767329987789/2**48 = 7.3+1/1407374883553280.
Take a look at http://docs.python.org/tutorial/floatingpoint.html for a further explanation. (It's on the Python website, but Java and C++ have the same "problem".)
The solution depends on what exactly your problem is:
If it's that you just don't like seeing all those noise digits, then fix your string formatting. Don't display more than 15 significant digits (or 7 for float).
If it's that the inexactness of your numbers is breaking things like "if" statements, then you should write if (abs(x - 7.3) < TOLERANCE) instead of if (x == 7.3).
If you're working with money, then what you probably really want is decimal fixed point. Store an integer number of cents or whatever the smallest unit of your currency is.
(VERY UNLIKELY) If you need more than 53 significant bits (15-16 significant digits) of precision, then use a high-precision floating-point type, like BigDecimal.

private void getRound() {
// this is very simple and interesting
double a = 5, b = 3, c;
c = a / b;
System.out.println(" round val is " + c);
// round val is : 1.6666666666666667
// if you want to only two precision point with double we
// can use formate option in String
// which takes 2 parameters one is formte specifier which
// shows dicimal places another double value
String s = String.format("%.2f", c);
double val = Double.parseDouble(s);
System.out.println(" val is :" + val);
// now out put will be : val is :1.67
}

Use java.math.BigDecimal
Doubles are binary fractions internally, so they sometimes cannot represent decimal fractions to the exact decimal.

/*
0.8 1.2
0.7 1.3
0.7000000000000002 2.3
0.7999999999999998 4.2
*/
double adjust = fToInt + 1.0 - orgV;
// The following two lines works for me.
String s = String.format("%.2f", adjust);
double val = Double.parseDouble(s);
System.out.println(val); // output: 0.8, 0.7, 0.7, 0.8

Doubles are approximations of the decimal numbers in your Java source. You're seeing the consequence of the mismatch between the double (which is a binary-coded value) and your source (which is decimal-coded).
Java's producing the closest binary approximation. You can use the java.text.DecimalFormat to display a better-looking decimal value.

Short answer: Always use BigDecimal and make sure you are using the constructor with String argument, not the double one.
Back to your example, the following code will print 11.4, as you wish.
public class doublePrecision {
public static void main(String[] args) {
BigDecimal total = new BigDecimal("0");
total = total.add(new BigDecimal("5.6"));
total = total.add(new BigDecimal("5.8"));
System.out.println(total);
}
}

Multiply everything by 100 and store it in a long as cents.

Computers store numbers in binary and can't actually represent numbers such as 33.333333333 or 100.0 exactly. This is one of the tricky things about using doubles. You will have to just round the answer before showing it to a user. Luckily in most applications, you don't need that many decimal places anyhow.

Floating point numbers differ from real numbers in that for any given floating point number there is a next higher floating point number. Same as integers. There's no integer between 1 and 2.
There's no way to represent 1/3 as a float. There's a float below it and there's a float above it, and there's a certain distance between them. And 1/3 is in that space.
Apfloat for Java claims to work with arbitrary precision floating point numbers, but I've never used it. Probably worth a look.
http://www.apfloat.org/apfloat_java/
A similar question was asked here before
Java floating point high precision library

Use a BigDecimal. It even lets you specify rounding rules (like ROUND_HALF_EVEN, which will minimize statistical error by rounding to the even neighbor if both are the same distance; i.e. both 1.5 and 2.5 round to 2).

Why not use the round() method from Math class?
// The number of 0s determines how many digits you want after the floating point
// (here one digit)
total = (double)Math.round(total * 10) / 10;
System.out.println(total); // prints 11.4

Check out BigDecimal, it handles problems dealing with floating point arithmetic like that.
The new call would look like this:
term[number].coefficient.add(co);
Use setScale() to set the number of decimal place precision to be used.

If you have no choice other than using double values, can use the below code.
public static double sumDouble(double value1, double value2) {
double sum = 0.0;
String value1Str = Double.toString(value1);
int decimalIndex = value1Str.indexOf(".");
int value1Precision = 0;
if (decimalIndex != -1) {
value1Precision = (value1Str.length() - 1) - decimalIndex;
}
String value2Str = Double.toString(value2);
decimalIndex = value2Str.indexOf(".");
int value2Precision = 0;
if (decimalIndex != -1) {
value2Precision = (value2Str.length() - 1) - decimalIndex;
}
int maxPrecision = value1Precision > value2Precision ? value1Precision : value2Precision;
sum = value1 + value2;
String s = String.format("%." + maxPrecision + "f", sum);
sum = Double.parseDouble(s);
return sum;
}

You can Do the Following!
System.out.println(String.format("%.12f", total));
if you change the decimal value here %.12f

So far I understand it as main goal to get correct double from wrong double.
Look for my solution how to get correct value from "approximate" wrong value - if it is real floating point it rounds last digit - counted from all digits - counting before dot and try to keep max possible digits after dot - hope that it is enough precision for most cases:
public static double roundError(double value) {
BigDecimal valueBigDecimal = new BigDecimal(Double.toString(value));
String valueString = valueBigDecimal.toPlainString();
if (!valueString.contains(".")) return value;
String[] valueArray = valueString.split("[.]");
int places = 16;
places -= valueArray[0].length();
if ("56789".contains("" + valueArray[0].charAt(valueArray[0].length() - 1))) places--;
//System.out.println("Rounding " + value + "(" + valueString + ") to " + places + " places");
return valueBigDecimal.setScale(places, RoundingMode.HALF_UP).doubleValue();
}
I know it is long code, sure not best, maybe someone can fix it to be more elegant. Anyway it is working, see examples:
roundError(5.6+5.8) = 11.399999999999999 = 11.4
roundError(0.4-0.3) = 0.10000000000000003 = 0.1
roundError(37235.137567000005) = 37235.137567
roundError(1/3) 0.3333333333333333 = 0.333333333333333
roundError(3723513756.7000005) = 3.7235137567E9 (3723513756.7)
roundError(3723513756123.7000005) = 3.7235137561237E12 (3723513756123.7)
roundError(372351375612.7000005) = 3.723513756127E11 (372351375612.7)
roundError(1.7976931348623157) = 1.797693134862316

Do not waste your efford using BigDecimal. In 99.99999% cases you don't need it. java double type is of cource approximate but in almost all cases, it is sufficiently precise. Mind that your have an error at 14th significant digit. This is really negligible!
To get nice output use:
System.out.printf("%.2f\n", total);

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