# Tag Info

160

I'd say the answer depends on the rounding mode when converting the double to float. float has 24 binary bits of precision, and double has 53. In binary, 0.1 is: 0.1₁₀ = 0.0001100110011001100110011001100110011001100110011…₂ ^ ^ ^ ^ 1 10 20 24 So if we round up at the 24th digit, we'll get 0.1₁₀ ~ ...

53

The number 0.1 will be rounded to the closest floating-point representation with the given precision. This approximation might be either greater than or less than 0.1, so without looking at the actual values, you can't predict whether the single precision or double precision approximation is greater. Here's what the double precision value gets rounded to ...

51

If the idea is to print integers stored as doubles as if they are integers, and otherwise print the doubles with the minimum necessary precision: public static String fmt(double d) { if(d == (int) d) return String.format("%d",(int)d); else return String.format("%s",d); } Produces: 232 0.18 1237875192 4.58 0 1.2345 And does not ...

29

doubles and floats are binary floating point types. This means they cannot precisely represent many decimal numbers (like 1.09). This leads to some subtle round off errors. In your case 100 * 1.09 actually results in a number very slightly larger than 109, so the Ceiling function correctly rounds it up to the nearest integer, 110. Change it to a decimal and ...

28

The reason for the difference is simple, if not obvious. If you use the equality operator ==, then you're using the IEEE test for equality. If you're using the Equals(object) method, then you have to maintain the contract of object.Equals(object). When you implement this method (and the corresponding GetHashCode method), you have to maintain that contract, ...

28

You don't even need to assume IEEE. C89 says in 3.1.2.5: The set of values of the type float is a subset of the set of values of the type double And every other C and C++ standard says equivalent things. As far as I know, NaNs and infinities are "values of the type float", albeit values with some special-case rules when used as operands. The fact ...

20

I suspect you're using a culture where the decimal separator is "," and the grouping separator is ".". You can specify the culture to use when parsing: double d = double.Parse(s, CultureInfo.InvariantCulture); Whether this is appropriate or not depends on the context, very often - where is the string coming from? If it's a user, do you know what their ...

19

If you convert .1 to binary you get: 0.000110011001100110011001100110011001100110011001100... repeating forever Mapping to data types, you get: float(.1) = %.00011001100110011001101 ^--- note rounding double(.1) = %.0001100110011001100110011001100110011001100110011010 Convert that to base 10: float(.1) = ...

17

It is all explained in the javadoc: Note that in most cases, for two instances of class Double, d1 and d2, the value of d1.equals(d2) is true if and only if d1.doubleValue() == d2.doubleValue() also has the value true. However, there are two exceptions: If d1 and d2 both represent Double.NaN, then the equals method returns true, even ...

16

Unlike operations with integral types, which throw exceptions in cases of overflow or illegal operations such as division by zero, operations with floating-point values do not throw exceptions. Instead, in exceptional situations, the result of a floating-point operation is zero, positive infinity, negative infinity, or not a number (NaN): From ...

15

From C99: 6.3.1.5 Real floating types 1 When a float is promoted to double or long double, or a double is promoted to long double, its value is unchanged. 2 When a double is demoted to float, a long double is demoted to double or float, or a value being represented in greater precision and range than required by its semantic type (see 6.3.1.8) is ...

14

double cannot represent every value. It guarantees to represent integers, but that is about it. If you need something more like "human" approximation of numbers, use decimal: decimal val = decimal.Parse("0.3"); Note: decimal also doesn't represent every value - but the way it does the approximation tends to be more like how people expect numbers to work. ...

14

When you put a 0 in front of an integer-type literal, it will interpret it as representing an octal number. Since "9" isn't a valid digit for octal numbers, that might be what's going on. Try printing out the (decimal) value of "010L" and see whether is says "8" to confirm. Note: not sure if Java does this, or if this is purely an artifact of Eclipse. If ...

14

This is the declaration for PositiveInfinity in Double. No, it is not. This is a portion of the decompilation of the Double struct provided by Resharper. That's better. This looks like a cycle that wouldn't pass the compiler. That's because it is a cycle that would not pass the compiler. Why does Resharper's decompiler produce code ...

13

If it's a financial value, you should pretty much always use BigDecimal - or use an integer with an implicit scaling value (e.g. store cents instead of dollars). Floating binary point (float, double) is almost never appropriate for financial applications, as the values usually have precise decimal values which aren't exactly representable in floating binary ...

13

An IEEE-754 double precision value has about 15 decimal digits of precision so it will be limited to five decimal places only if your values are up around the tens of billions. What you're most likely seeing is simply the default output format for doubles which, like C, will tend to give you a limited number of fractional digits. You can see this in the ...

12

The classes from the Decimal TR are not implemented for all compilers. Some compilers, e.g., gcc, implement the C Decimal TR and provide the corresponding extensions in C++, too. In the past there was an open source implementation for the C++ Decimal TR available but I failed to locate it. If your compiler doesn't support the decimal types, your best option ...

12

The difference is that 6.5 can be represented exactly in both float and double - whereas 3.2 can't be represented exactly in either type... and the two closest approximations are different. An equality comparison between float and double first converts the float to a double and then compares the two. So the data loss. You shouldn't ever compare floats or ...

12

Because you are doing integer division. Try 5.0/10.0 instead. (Or 5.0/10 or 5/10.0 - at least one of the operands being a double.) The compiler doesn't use the stuff to the left of the = sign to determine the value of the constant expression on the right. It interpets the 5 as an integer and the 10 as an integer and thus the / as integer division. When you ...

11

Try to wrap your numbers with f, as normally 2.0 would represent a double number. You can read more about float here. float top = shape.Y + (shape.Height / 2.0f) - 4.5f;

11

strlen works by iterating through the array that it assumes the passed const char* points at until it finds a char with value 0. This is the null-terminating character that is automatically added to the end of string literals. The bytes that make up the value representation of your double do not end with a null character. The strlen will just keep going past ...

11

The portable way to do this is with memcpy (you may also be able to conditionally do it with reinterpret_cast or a union, but those aren't certain to be portable because they violate the letter of the strict-alias rules): // First, static assert that the sizes are the same memcpy(&result, &bits, sizeof(bits)); But before you do make sure you know ...

11

Yes. Use BigInteger. It's designed for this purpose. The numbers you are using won't fit in the primitive integral and can't even be represented precisely in the floating-point types1. BigInteger m = BigInteger.Parse("374711027510012111075768211110475111691021051041057653548210911210211112250867 66690120741165250567278571217510410482757487"); BigInteger n = ...

11

The Math#round method is not broken. 138.515 can't be exactly represented as a double. To see the exact value, you can use: System.out.println(new BigDecimal(138.515d)); which prints: 138.5149999999999863575794734060764312744140625 It is therefore accurate for round to return 138.51. If you need more precision than double can give, you can use ...

11

Use %f to print a double, not %d. The latter causes undefined behavior. Also the expression 1/2 uses integer division which yields 0, so to get .5, use 1/2. (note trailing period). Finally, to actually get .5 instead of something like 0.500000, specify the precision: printf("%.1f\n", sum);

10

By default, Double (an imprecise but efficient data type) will be chosen for fractional data. If you annotate it to use Rational instead, then you can get precise answers. ghci> map (\x -> x - 0.1) [0.2,0.3..0.9] :: [Rational] [1 % 10,1 % 5,3 % 10,2 % 5,1 % 2,3 % 5,7 % 10,4 % 5] The percent sign is used to indicate precise fractions, so 1 % 10 means ...

10

Your constructor has a typo: Employee (String firstname, String lastname, double Salary){ double salary should be lowercase. As it is this line: this.salary = salary; Does nothing as it is equivalent to this.salary = this.salary. As soon as you change the parameter to be lowercase salary, it will assign the value you pass into the constructor to the ...

10

i1/i2 will be 0. Since i1 and i2 are both integers. If you have int1/int2, if the answer is not a perfect integer, the digits after the decimal point will be removed. In your case, 2/5 is 0.4, so you'll get 0. You can cast i1 or i2 to double (the other will be implicitly converted) double d = 3 + (double)i1/i2 +2;

10

Well... Is the following line needed here? double kk = Math.pow(1 + k, k); It completely messed up change computation, since you powered what the user inputs (k) + 1 to the kth power. If you want to change it to a double, (double)k will do. Of course, for monetary computation, you'd better be using: BigDecimal cent based Integer / Long computation

10

They're both implementations of different parts of the IEEE floating point standard. A float is 4 bytes wide, whereas a double is 8 bytes wide. As a rule of thumb, you should probably prefer to use double in most cases, and only use float when you have a good reason to. (An example of a good reason to use float as opposed to a double is "I know I don't need ...

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