# Tag Info

5

Without using fixed point (integer) arithmetic you can NOT be sure that your calculations are ALWAYS correct. This is because of the way IEEE 754 floating point representation works, some decimal numbers cannot be represented as finite-length binary fractions. However, ALL fixed point numbers can be expressed as a finite length integer; therefore, they can ...

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You have to set a context with 1000 decimal digits: context = decimal.Context(prec=1000) decimal.setcontext(context) From now on computations will use 1000 digits precision. Example: >>> decimal.setcontext(decimal.Context(prec=1000)) >>> pi = ...

3

contains() will work as you want it to if you switch your HashSet to a TreeSet. It is different from most sets as it will decide equality based on the compareTo() method as opposed to equals() and hashCode(): a TreeSet instance performs all element comparisons using its compareTo (or compare) method And since BigDecimal.compareTo() compares without ...

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The problem is that you're using doubles during the calculation itself, thus inevitably losing accuracy. Yes, you're using BigDecimal at the end, but only after already destroying data by putting it in doubles. The solution is to not use doubles at ANY point in the calculation. Use BigDecimal for every step of the way. To use a metaphor: What you're doing ...

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Usually, pow(a,b) is computed as exp(b * ln(a)). Both exp() and ln() are calculated up to a certain precision from their series (e.g. this). All you need are addition, subtraction, multiplication, and division operations which you already have. Since your numbers are always real rationals, as you mentioned all you need are integer exponentiation algorithm, ...

1

If the quotient has a nonterminating decimal expansion and the operation is specified to return an exact result, an ArithmeticException is thrown. Otherwise, the exact result of the division is returned, as done for other operations. Use divide method like that a.divide(b, 2, RoundingMode.HALF_UP) where 2 is precision and RoundingMode.HALF_UP is rounding ...

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It crashes on an ArithmeticException because the result is a number with infinite decimals. From http://docs.oracle.com/javase/1.5.0/docs/api/java/math/BigDecimal.html "In the case of divide, the exact quotient could have an infinitely long decimal expansion; for example, 1 divided by 3. If the quotient has a nonterminating decimal expansion and the ...

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If you need the precision of BigDecimal, you need to use it for all calculations. It is not sufficient to convert the result from double to BigDecimal at the end, because the precision is gone by then. You need to convert all your aX variables to BigDecimal, and replace operators with calls to the corresponding methods of BigDecimal class: BigDecimal pi = ...

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If you want to sort them easily, you could do the following: BigDecimal x1 = new BigDecimal("1235.2345"); BigDecimal x2 = new BigDecimal("235.2345"); BigDecimal[] nums = {x1,x2}; List<BigDecimal> lnums = Arrays.asList(nums); Collections.sort(lnums); Arrays.asList() merely passes the value of the reference of your array. ...

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You made the mistake of initialising the Decimal object with a double which can't represent your big number. So instead of saying: ...

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Historically, it was often reasonable to use floating-point types for precise calculations on whole numbers which could get bigger than 2^32, but not bigger than 2^52 [or, on machines with a proper "long double" type, 2^64]. Dividing a 52-bit number by a 32-bit number to yield a 20-bit quotient would require a rather lengthy drawn-out process on the 8088, ...

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If the size of BigDecimal is too large for your cache, than you should convert amounts to long values when they are written to the cache and convert them back to BigDecimal when they are read. This will give you a smaller memory footprint for your cache and will have accurate calculations in your application. Even if you are able to represent your inputs to ...

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