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TimeSpan.FromSeconds takes a double, and can represent values down to 100 nanoseconds, however this method inexplicably rounds the time to whole milliseconds.

Given that I've just spent half an hour to pinpoint this (documented!) behaviour, knowing why this might be the case would make it easier to put up with the wasted time.

Can anyone suggest why this seemingly counter-productive behaviour is implemented?

TimeSpan.FromSeconds(0.12345678).TotalSeconds
    // 0.123
TimeSpan.FromTicks((long)(TimeSpan.TicksPerSecond * 0.12345678)).TotalSeconds
    // 0.1234567
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I'm sorry to see the old answer go away. I doubt I could come up with anything better (and I wanted to +1 it...) – Peter Jan 20 '11 at 19:34
    
"[K]nowing why this might be the case would make it easier to put up with the wasted time." Consider it a sunk cost. – jason Jan 21 '11 at 5:29
1  
Got bitten by that too. My theory is that it was a bug in .net 1 and hasn't been changed because it'd break existing programs. IMO MS should at least update the intellisense description to indicate that these function have only millisecond precision. – CodesInChaos Jan 21 '11 at 15:30
1  
up vote 10 down vote accepted
+25

As you've found out yourself, it's a documented feature. It's described in the documentation of TimeSpan:

Parameters

value Type: System.Double

A number of seconds, accurate to the nearest millisecond.

The reason for this is probably because a double is not that accurate at all. It is always a good idea to do some rounding when comparing doubles, because it might just be a very tiny bit larger or smaller than you'd expect. That behaviour could actually provide you with some unexpected nanoseconds when you try to put in whole milliseconds. I think that is the reason they chose to round the value to whole milliseconds and discard the smaller digits.

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"Unexpected nanoseconds" sounds like a plausible theory. Still doesn't justify it in my book, but that's beside the point. +1. – romkyns Jan 21 '11 at 21:42
    
Yes, but milliseconds will probably be enough for most people. People who are smart enough to work with nanoseconds can use TimeSpan.FromTicks(TimeSpan.TicksPerSecond * YourSecondsDouble). ;) – GolezTrol Jan 21 '11 at 21:49

On the rights of a speculation..

  1. TimeSpan.MaxValue.TotalMilliseconds is equat to 922337203685477. The number that has 15 digits.
  2. double is precise to 15 digits.
  3. TimeSpan.FromSeconds, TimeSpan.FromMinutes etc. all go through conversion to milliseconds expressed in double (then to ticks then to TimeSpan which is not interesting now)

So, when you are creating TimeSpan that will be close to TimeSpan.MaxValue (or MinValue) the conversion will be precise to milliseconds only.
So the probable answer to the question "why" is: to have the same precision all the times.
Further thing to think about is whether the job could have been done better if conversions were done through firstly converting value to ticks expressed in long.

share|improve this answer
    
According to the docs, the value is converted to ticks first. – GolezTrol Jan 21 '11 at 20:44
    
    
I'm sorry, I misread. – GolezTrol Jan 21 '11 at 21:27
    
@Golez: that's OK. We are all mistaken occasionally. – alpha-mouse Jan 21 '11 at 21:30

Imagine you're the developer responsible for designing the TimeSpan type. You've got all the basic functionality in place; it all seems to be working great. Then one day some beta tester comes along and shows you this code:

double x = 100000000000000;
double y = 0.5;
TimeSpan t1 = TimeSpan.FromMilliseconds(x + y);
TimeSpan t2 = TimeSpan.FromMilliseconds(x) + TimeSpan.FromMilliseconds(y);
Console.WriteLine(t1 == t2);

Why does that output False? the tester asks you. Even though you understand why this happened (the loss of precision in adding together x and y), you have to admit it does seem a bit strange from a client perspective. Then he throws this one at you:

x = 10.0;
y = 0.5;
t1 = TimeSpan.FromMilliseconds(x + y);
t2 = TimeSpan.FromMilliseconds(x) + TimeSpan.FromMilliseconds(y);
Console.WriteLine(t1 == t2);

That one outputs True! The tester is understandably skeptical.

At this point you have a decision to make. Either you can allow an arithmetic operation between TimeSpan values that have been constructed from double values to yield a result whose precision exceeds the accuracy of the double type itself—e.g., 100000000000000.5 (16 significant figures)—or you can, you know, not allow that.

So you decide, you know what, I'll just make it so that any method that uses a double to construct a TimeSpan will be rounded to the nearest millisecond. That way, it is explicitly documented that converting from a double to a TimeSpan is a lossy operation, absolving me in cases where a client sees weird behavior like this after converting from double to TimeSpan and hoping for an accurate result.

I'm not necessarily arguing that this is the "right" decision here; clearly, this approach causes some confusion on its own. I'm just saying that a decision needed to be made one way or the other, and this is what was apparently decided.

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You could use this very argument to outlaw doubles altogether... But then, I can imagine the designers paying undue attention to absolute beginners while testing this specific class... Wish we could know for sure how this came into existence :) – romkyns Jan 22 '11 at 11:50

I think the explanation is there: TimeSpan structure incorrectly handles values close to min and max value

And it looks like it's not going to change any time soon :-)

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FromSeconds uses private method Interval

public static TimeSpan FromSeconds(double value)
{
    return Interval(value, 0x3e8);
}

0x3e8 == 1000

Interval method multiplay value on that const and then cast to long (see last row):

private static TimeSpan Interval(double value, int scale)
{
    if (double.IsNaN(value))
    {
        throw new ArgumentException(Environment.GetResourceString("Arg_CannotBeNaN"));
    }
    double num = value * scale; // Multiply!!!!
    double num2 = num + ((value >= 0.0) ? 0.5 : -0.5);
    if ((num2 > 922337203685477) || (num2 < -922337203685477))
    {
        throw new OverflowException(Environment.GetResourceString("Overflow_TimeSpanTooLong"));
    }
    return new TimeSpan(((long) num2) * 0x2710L); // Cast to long!!!
}

As result we have precision with 3 (x1000) signs. Use reflector to investigate

share|improve this answer
    
I did of course look. Reflector can always answer the how, but not the why. Did this help you find out why the cast to long occurs before the multiplication? I would consider that a bug had it not been documented. Perhaps it was still a bug that was easier to document than to fix. Bottom line is, this code doesn't answer the "why" question. – romkyns Jan 21 '11 at 10:52
1  
@romkyns "A bug is easier to document than to fix!" I think you just found Microsoft new slogan! ;-) – Nicolas Buduroi Jan 21 '11 at 20:10
    
@Nicolas: As a separate phrase this sounds amusing. But I don't think that we are having an unexpected bug here. This design might be intentional. – alpha-mouse Jan 21 '11 at 21:29
2  
This answer doesn’t address the question at all. – Timwi Jan 21 '11 at 21:54

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