# Tag Info

0

Use round on both the values in the list and the comparison values. They won't be exact but they'll be consistent, so a search will return the expected results.

1

You can subclass list and add in a tolerance to __contains__: class ListOFloats(list): def __contains__(self, f): # If you want a different tolerance, set it like so: # l=ListOFloats([seq]) # l.tol=tolerance_you_want tol=getattr(self, 'tol', 1e-12) return any(abs(e-f) <= 0.5 * tol * (e + f) for e in self) ...

1

Make the comparison something like if(abs(a-b) <= 1e-6 * (a + b)): This is standard practice when using floating point. The real value you use (instead of 1e-6) depends on the magnitude of the numbers you use and your definition of "the same". EDIT I added *(a+b) to give some robustness for values of different magnitudes, and changed the comparison ...

4

The exact value of the float is 1.100000000000000088817841970012523233890533447265625. Python isn't somehow keeping track of the original string. When Python stringifies it with str, it truncates to 12 digits. >>> x = 1.0/9 >>> print decimal.Decimal(x) # prints exact value 0.111111111111111104943205418749130330979824066162109375 ...

2

Agree with ANisus, go is doing the right thing. Concerning C, I'm not convinced by his guess. The C standard does not dictate, but most implementations of libc will convert the decimal representation to nearest float (at least to comply with IEEE-754 2008 or ISO 10967), so I don't think this is the most probable explanation. There are several reasons why ...

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 ...

0

Unspecified by the standard, but testing on some local hardware: #include <stdio.h> int main( int argc, char **argv ) { float a = 0.1; double b = a; printf("%.16f\n", b ); } 0.1000000014901161

4

Using the unsafe package, you can get the see how Go represent the different decimal values as a IEEE 754 binary value: Playground: http://play.golang.org/p/CkbnmsAXC- Result: float32(0.1): 00111101110011001100110011001101 float32(0.2): 00111110010011001100110011001101 float32(0.3): 00111110100110011001100110011010 float64(0.1): ...

1

The standard approach to error analysis of linear systems is to consider that the given system represents any of the systems (A + ΔA) * (x + Δx) = b + Δb where ΔA and Δb have entries of relative size μ = 5 * 10-d, so that ||ΔA|| ∼ μ * ||A|| and ||Δb|| ∼ μ * ||b||. The idea being that the solution found will represent the exact solution of a ...

0

The reason you get different results is because you ask for different things. In the printf, you're asking for a fixed format. With std::cout, you're asking for a variable format, corresponding to "%g" in printf. If you set std::cout to fixed format, with e.g.: std::cout << std::fixed << a; You should see the same thing as with printf( ...

0

default precision for double is 6. You can inspect this using 6. You can inspect this using precision(): std::streamsize ss = std::cout.precision(); std::cout << "Initial precision = " << ss << '\n'; In your example: 110421.100000 // oops, truncated to 6 digits, gives 110421 printed 11043.100000 // oops, truncated to 6 ...

0

The precision of cout is too low by default. You can increase it by using setprecision(). See the following example: #include <iostream> #include <cstdio> #include <iomanip> using namespace std; int main() { //double a = 15670.1; //a += 110420; double a = 1.1; a += 110420; printf("%f\n",a); cout << ...

2

By default, a C++ stream formats floating-point values to 6 significant figures, while printf, with %f, formats them to 6 decimal places. You can use std::setprecision (declared in <iomanip>) to specify a higher precision: cout << setprecision(7) << a << endl; // 110421.1

4

I'm not sure I understand your problem. In CLisp, round rounds to the nearest integer (unless you specify a divisor). The nearest integer to 33.6 is 34 so that bit is right. And since round returns both the quotient and remainder, it gives 34, with a remainder of -0.4. That bit's mostly right so I suspect you're wondering why it's only "mostly". The reason ...

-1

You could try using # placeholders if you want to suppress trailing zeroes, and avoid scientific notation. Though you'll need a lot of them for very small numbers, e.g.: Console.WriteLine(double.Epsilon.ToString("0.########....###"));

-3

I believe you can do this, based on what you want to accomplish with the display: Consider this: Double myDouble = 10/3; myDouble.ToString("G17"); Your output will be: 3.3333333333333335 See this link for why: http://msdn.microsoft.com/en-us/library/kfsatb94(v=vs.110).aspx By default, the return value only contains 15 digits of precision ...

1

Use Double to calculate and Long to store.

0

It depends in part on your definition of equality. If you require exact string match, the answer is no. For example: System.out.println(0.1e-1); prints 0.01 Now assume that "equal" means decimal value equality, so that 0.1e-1 and 0.01 are equal. If you limit your doubles to normal numbers (not subnormal, overflow, or underflow) with less than 16 ...

0

The first conversion, from decimal to binary, may yield another mathematical value, because not every decimal can be represented exactly as a binary number. This is true independent of the accuracy of the binary, take 0.1 as an example. The second conversion, from binary to decimal, is always possible in a loss-less fashion, i.e. yielding the same ...

3

BigDecimal could help, but I would suggest reading the whole answer. Floating point errors are 'normal' in a sense, that you cannot store every floating point number exact within a variable. There are many resources out there how to deal with this problem, a few links here: If you do not know what the actual problem is check this out. What Every Computer ...

2

The floor function from cmath is an heritage from C, it was here before C++ proposed a long double version of floor... Now we can't remove it as it's used, so the new one was created in std. floor(ans+0.5) will cast (ans + 0.5) to a 'normal' double, hence the loss of precision.

1

floats are not capable to write 57.6 precisely. 0.6=1/5, and it is the infinite binary fractional. If you put the result of rounding back into double, you will have absolutely the same problem. So, you have to round and transfer into string, cutting off the excessive digits. As shows your example, the PHP prepares the float just to this operation.

0

I tried this, to see what is going on ... @z doesn't change ... DECLARE @num FLOAT = 1.0005 DECLARE @exponent AS INT = 0 declare @x float declare @z float WHILE @num - FLOOR(@num) > 0.000001 BEGIN SET @exponent += 1 SET @num *= 10 set @x = FLOOR(@num) set @z = @num - FLOOR(@num) END

0

There is no general rule that ensures that adding n copies of 1.0/n will result in exactly 1.0. This can be explored by changing n in the following program: import java.math.BigDecimal; public class Test { public static void main(String[] args) { int n = 3; double[] counts = new double[n+1]; for(int i=1; i<counts.length; ...

0

I agree with anders abel. There won't be a way to do this using a float number representation. In direct result of IEE 1985-754 only the numbers that can be represented by can be stored and calculated with precisly (as long as the chosen bit number allows this). For Example : 1024 * 1.75 * 183.375 / 1040.0675 <-- will be stored precisly 10 / ...

0

You may format the printing of a floating point number, but not its actual size. You may read this on formatting floating point number. To save your time, you may use the %f format specifier, as printf("%.PRECISIONf", fvar); where PRECISION is the number of digits you want after decimal, for e.g. int print_float(float fvar, unsigned int precision) { ...

0

Do int dec; float no; printf("\nEnter no of decimal places and the number "); scanf("%d%f",&dec,&no); printf("%.*f",dec,no);

2

There is a difference when compiling for x86 vs x64 Windows targets. For x86 platform the 'Extended' type has a different 'size' then on the x64 platform. See the Delphi help (XE2): System.Extended offers greater precision than other real types, but is less portable. Be careful using System.Extended if you are creating data files to share across ...

4

This is in fact an issue of representability. Here's the SSCCE: {\$APPTYPE CONSOLE} uses SysUtils, Windows; function ExFloatToStr(Value: Extended): string; var Buffer: array[0..63] of Char; FormatSettings: TFormatSettings; begin GetLocaleFormatSettings(GetUserDefaultLCID, FormatSettings); SetString(Result, Buffer, FloatToText(Buffer, Value, ...

1

Without the f suffix all floating-point constants are double in C. If written with lf suffix then it'll be a long double. C literal constant generally aren't depend on the precision. An integer literal 1 or 2 are of type int although their values lies completely in char's range

1

While all of the other answers are good there is still one thing missing: It is impossible to represent irrational numbers (e.g. π, sqrt(2), log(3), etc.) precisely! And that actually is why they are called irrational. No amount of bit storage in the world would be enough to hold even one of them. Only symbolic arithmetic is able to preserve their ...

0

Try this: Math.round(17.99*100) As the previous answer explained, multiplying a float number is not exact science; what you can do is to expect a result in a certain precision range. Take a look at Number.prototype.toPrecision(). (17.99*100).toPrecision(4)

0

Floating point arithmetic isn't an exact science. The reason is that in memory, your precision is stored in binary (all powers of two). If it can't be represented by an exact power of two you can get some lost precision. Your number, 1798.9999999999998 had enough lost precision that it didn't round up in the multiplication. ...

3

f means float which means single-precision IEEE-754 floating-point number. They aren't very precise, they only have roughly seven significant digits. You can double that (!) by using d for double, which is a double-precision floating-point number, giving roughly 15 digits of precision. Provided, of course, that whatever you're passing this into accepts ...

0

Unfortunately, it's computationally impossible to prevent rounding of a number with potentially infinite decimal places. There are some hacks one could suggest, though, like having a class HugeNumber whose objects are lists or arrays of algarisms, or even strings that contain only numbers, and having arithmetic operations implemented in it (by yourself, of ...

1

If you are trying to work with numbers requiring precision beyond the JavaScript float (only 64 bits of precision) you could consider using a library like one of those mentioned in this question: Is there a decimal math library for JavaScript? In particular the bignumber library looks promising for your purposes. Here is a quick demonstration jsfiddle: ...

3

Such geometric predicates suffer in a lot of ways from floating point errors. The only industrial strength solution is to use adaptable arithmetic filtering (provided that a robust implementation of the coplanar test is not covering you). Luckily such implementations (that would take quite some time to write) are already available. In the previous link the ...

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 ...

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 ...

2

Stitch the vertices together and use UV mapping to compose your puzzle mesh. That way you will not have this visual artifact. It's a rendering artifact not a floating point error. You often see this sort of thing when say two wall pieces that are, seemingly, perfectly aligned still show a tiny (pixel wide) gap. Another way to solve this would be to overlap ...

4

The golang specification says, "float64 is the set of all IEEE-754 64-bit floating-point numbers." which is commonly known as double precision numbers, http://en.wikipedia.org/wiki/Double-precision_floating-point_format You can read all of its glory details if interested, but to answer your question, quote, "...next range, from 253 to 254, everything is ...

2

Yes, float64 has 52 bits to store your counter. You should be accurate until 253. (Side note: the entire JavaScript language uses only Floating Point.)

2

The basic problem is: Given two calculated values, a and b, that would be a and b if calculated exactly but that differ because of floating-point rounding, what can we determine about a and b regarding less than, equal to, and greater than? Suppose we know the maximum possible total error in a and b is e. Then we can determine one of: If a – b < –e, ...

1

it's because square of 3389774.583 is not 11490571723552.8. If you will try windows calculator you will get value around 11490571723552.823889. So there is no chance to get result 0 for (11490571723552.8 - x * x) where x is 3389774.583 Try double x = 3389774.583; double xx = x*x; Console.WriteLine(xx); string ss = "x is " + x + " x square is " + x * x ...

0

Try rounding the output to a number of decimals with a format string: Console.WriteLine(ss.ToString("F2"));

2

Depending on your platform you may have support for complex192 &/or complex256 these are generally not available on Intel platforms under Windows but are on some others - if your code is running on Solaris or on a supercomputer cluster it may support one of these types. On Linux you may even find them available or you could create your array using ...

Top 50 recent answers are included