# Tag Info

76

You have to replace BigDecimal bigDecimal = new BigDecimal(d); with BigDecimal bigDecimal = BigDecimal.valueOf(d); and you will get the expected results: 2.66 1.66 Explanation from Java API: BigDecimal.valueOf(double val) - uses the double's canonical string representation provided by the Double.toString() method. This is preferred way to convert a ...

36

Not in general, no. However, you can use strictfp expressions: Within an FP-strict expression, all intermediate values must be elements of the float value set or the double value set, implying that the results of all FP-strict expressions must be those predicted by IEEE 754 arithmetic on operands represented using single and double formats. Within ...

33

Yes, divide by it. 1 / +0.0f is +Infinity, but 1 / -0.0f is -Infinity. It's easy to find out which one it is with a simple comparison, so you get: if (1 / x > 0) // +0 here else // -0 here (this assumes that x can only be one of the two zeroes)

29

All these languages are using the system-provided floating-point format, which represents values in binary rather than in decimal. Values like 0.2 and 0.4 can't be represented exactly in that format, so instead the closest representable value is stored, resulting in a small error. For example, the numeric literal 0.2 results in a floating-point number ...

22

In Python, as with most other programming languages, floating point numbers are represented a lot like scientific notation: with an exponent and a mantissa (significand). A very simple number, say 9.2, is actually this fraction: 5179139571476070 * 2 -49 The limiting factor that makes it impossible to represent small simple decimals is the fact that ...

16

This test case ends up pretty self-explanatory: public static void main (String[] args) throws java.lang.Exception { System.out.println("Rounded: " + round(2.655d,2)); // -> 2.65 System.out.println("Rounded: " + round(1.655d,2)); // -> 1.66 } public static Double round(Double d, int precise) { BigDecimal bigDecimal = new ...

10

Loop over integers, and divide by a floating point number: #include <iostream> #include <iomanip> int main() { std::cout << std::setprecision(1) << std::fixed; for (int d = 10; d <= 20; ++d) { std::cout << d/10. << std::endl; } } Output: 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0

9

One solution would be doing a normal division and then comparing the value to the next integer. If the result is that integer or very near to that integer the result is evenly divisible: \$x = 70; \$y = .1; \$evenlyDivisable = abs((\$x / \$y) - round(\$x / \$y, 0)) < 0.0001; This subtracts both numbers and checks that the absolute difference is smaller than ...

8

There is no difference in the ways compiler treats these 2 cases. The resulting machine code will be the same. However, the first is implicit conversion, and the second is explicit conversion. Depending on compiler flags, you may get a warning when performing implicit conversion that loses precision. On a side note, a literal 3.14 has type double, which ...

8

Where is the error ? That's a rounding error. Neither 1.8 nor 0.2 are exactly representable in a binary floating point format, so the actual values used are slightly different. This means that the final result might not be exactly 2; but streaming it to cout will round it to a few decimal places and print 2. You can see this for yourself by printing it ...

7

C has hexadecimal floating-point constants, with a form starting with “0x”, then hexadecimal digits, optionally including a radix point, then a “p”, then a signed exponent in decimal, which is a power of two. E.g., 0x1.fp-2 is (1 + 15/16)•2-2 = .484375. Hexadecimal floating-point constants make it easy for the compiler to reproduce the exact value. With ...

7

There are two pieces to this puzzle: floating-point numbers and type-insensitive comparison using ==. First, 475957E-8905 evaluates as the floating point number 475957 * 10 ^ -8905, which is incredibly small; in floating-point terms, it's the same as 0 due to the precision limitations of javascript. So, eval("475957E-8905") returns 0. Now, for the second ...

7

This isn't a full answer (mhlester already covered a lot of good ground I won't duplicate), but I would like to stress how much the representation of a number depends on the base you are working in. Consider the fraction 2/3 In good-ol' base 10, we typically write it out as something like 0.666... 0.666 0.667 When we look at those representations, we ...

7

The JVM should implement the IEEE specification consistently and this specification is very technical and precise. The floating point primitives of float and double are the same on all platforms. The difference is only in the treatment of intermediate results, and that the virtual machine may use extended precision (so only more precise, not less) while ...

6

Since the exponent represent the power of 2, just multiply the number by 2. That should increment the exponent (assuming that the number is normalized both before and after the multiplication). (Normalization usually happens automatically in Java, so this shouldn't be a concern unless you are doing something funny). If you really want to manipulate the bits ...

6

A C implementation is required to implement the types float and double, and arithmetic expressions involving them. So if the compiler knows that the target architecture doesn't have floating-point ops then it must bring in a software library to do it. The compiler is allowed to link against an external library, it's also allowed to implement floating point ...

6

As said in API 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 ...

6

Rounding a double resp Double in itself does not make much sense, as a double datatype cannot be rounded (easily, or at all?). What you are doing is: Take a Double d as input and a int precise number of digits behind the seperator. Create a BigDecimal from that d. Round the BigDecimal correctly. Return the double value of that BigDecimal, which has no ...

6

The simplest possible example: accumulation of a sum. unrolling using multiple accumulators and vectorization allow a speedup of (ADD latency)*(SIMD vector width) on typical pipelined architectures (if the data is in cache; because there's no data reuse, it typically won't help if you're reading from memory), which can easily be an order of magnitude. ...

6

An implementation is allowed to do either (or even be off by one more): For decimal floating constants, and also for hexadecimal floating constants when FLT_RADIX is not a power of 2, the result is either the nearest representable value, or the larger or smaller representable value immediately adjacent to the nearest representable value, chosen in an ...

6

There are times when you cannot define a struct in advance but still require numbers to pass through the marshal-unmarshal process unchanged. In that case you can use the UseNumber method on json.Decoder, which causes all numbers to unmarshal as json.Number (which is just the original string representation of the number). This can also useful for storing ...

5

The reason is because it's being rounded up at the end according to the IEEE Standard for Floating-Point Arithmetic : http://en.wikipedia.org/wiki/IEEE_754 According to the standard: addition, multiplication, and division should be completely correct all the way up to the last bit. This is because a computer has a finite amount of space to represent these ...

5

You should be aware that 0.6 cannot be exactly represented in IEEE floating point, and neither can 0.4, 0.2, and 0.1. This is because the ratio 1/5 is an infinitely repeating fraction in binary, just like ratios such as 1/3 and 1/7 are in decimal. Since none of your initial constants is exact, it is not surprising that your results are not exact, either. ...

5

You can use the BitConverter class: uint value = BitConverter.ToUInt32(BitConverter.GetBytes(44.54321F), 0); Console.WriteLine("{0:x}", value); // 42322c3f You could also do this more directly using an unsafe context: float floatVal = 44.54321F; uint value; unsafe { value = *((uint*)(&floatVal)); } Console.WriteLine("{0:x}", value); // 42322c3f ...

5

.1 doesn't have an exact representation in binary floating point, which is what causes your incorrect result. You could multiply them by a large enough power of 10 so they are integers, then use %, then convert back. This relies on them not being different by a big enough factor that multiplying by the power of 10 causes one of them to overflow/lose ...

5

It's not defined, I found the issue resolved as "working as intended" on the issue tracker: https://code.google.com/p/go/issues/detail?id=966 The suggestion seems to be to use math.Nextafter to derive the value if you need it. Specifically, the formula is math.Nextafter(1.0,2.0)-1.0 (the second argument can be any number greater than 1.0).

5

TL;DR Both decimals precisely represent 0.1. It's just that the decimal format, exactly like IEEE floating point, allows multiple bitwise-different values that represent the exact same number. Explanation It isn't about single not being able to represent 0.1 precisely. As per the documentation of GetBits: The binary representation of a Decimal number ...

5

-ffast-math does a lot more than just break strict IEEE compliance. First of all, of course, it does break strict IEEE compliance, allowing e.g. the reordering of instructions to something which is mathematically the same (ideally) but not exactly the same in floating point. Second, it disables setting errno after single-instruction math functions, which ...

4

Using IEEE 754 rounding, let's see what's going on. In IEEE 754 single-precision floating point, the value of a finite number is dictated by the following: -1sign × 2exponent × (1 + mantissa × 2-23) Where sign is 0 if positive, otherwise 1; exponent is a value between -126 and 127 (-127 and 128 are special); and mantissa is a value between 0 and ...

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