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Background

I'm working on a symmetric rounding class and I find that I'm stuck with regards to how to best find the number at position x that I will be rounding. I'm sure there is an efficient mathematical way to find the single digit and return it without having to resort to string parsing.

Problem

Suppose, I have the following (C#) psuedo-code:

var position = 3;
var value = 102.43587m;
// I want this no ↑ (that is 5)

protected static int FindNDigit(decimal value, int position)
{
    // This snippet is what I am searching for
}

Also, it is worth noting that if my value is a whole number, I will need to return a zero for the result of FindNDigit.

Does anyone have any hints on how I should approach this problem? Is this something that is blaringly obvious that I'm missing?

share|improve this question
4  
You shouldn't be using "var"'s like that. If you know that it is a decimal you should specify it right when you are declaring. –  VoodooChild May 27 '10 at 17:55
7  
@VoodooChild I think thats subjective, i mean they are int and decimals in the final code.. I take it more as style.. and style-wise, well everybody has its own preference. by the way, awesome use of the ↑ up arrow! –  Francisco Noriega May 27 '10 at 17:59
3  
I don't use vars for primitive types because it is a subjective choice, I use vars for all other types though. –  Chris Marisic May 27 '10 at 18:07

6 Answers 6

up vote 5 down vote accepted
using System;

public static class DecimalExtensions
{
    public static int DigitAtPosition(this decimal number, int position)
    {
        if (position <= 0)
        {
            throw new ArgumentException("Position must be positive.");
        }

        if (number < 0)
        {
            number = Math.Abs(number);
        }

        number -= Math.Floor(number);

        if (number == 0)
        {
            return 0;
        }

        if (position == 1)
        {
            return (int)(number * 10);
        }

        return (number * 10).DigitAtPosition(position - 1);
    }
}

Edit: If you wish, you may separate the recursive call from the initial call, to remove the initial conditional checks during recursion:

using System;

public static class DecimalExtensions
{
    public static int DigitAtPosition(this decimal number, int position)
    {
        if (position <= 0)
        {
            throw new ArgumentException("Position must be positive.");
        }

        if (number < 0)
        {
            number = Math.Abs(number);
        }

        return number.digitAtPosition(position);
    }

    static int digitAtPosition(this decimal sanitizedNumber, int validPosition)
    {
        sanitizedNumber -= Math.Floor(sanitizedNumber);

        if (sanitizedNumber == 0)
        {
            return 0;
        }

        if (validPosition == 1)
        {
            return (int)(sanitizedNumber * 10);
        }

        return (sanitizedNumber * 10).digitAtPosition(validPosition - 1);
    }

Here's a few tests:

using System;
using Xunit;

public class DecimalExtensionsTests
{
                         // digit positions
                         // 1234567890123456789012345678
    const decimal number = .3216879846541681986310378765m;

    [Fact]
    public void Throws_ArgumentException_if_position_is_zero()
    {
        Assert.Throws<ArgumentException>(() => number.DigitAtPosition(0));
    }

    [Fact]
    public void Throws_ArgumentException_if_position_is_negative()
    {
        Assert.Throws<ArgumentException>(() => number.DigitAtPosition(-5));
    }

    [Fact]
    public void Works_for_1st_digit()
    {
        Assert.Equal(3, number.DigitAtPosition(1));
    }

    [Fact]
    public void Works_for_28th_digit()
    {
        Assert.Equal(5, number.DigitAtPosition(28));
    }

    [Fact]
    public void Works_for_negative_decimals()
    {
        const decimal negativeNumber = -number;
        Assert.Equal(5, negativeNumber.DigitAtPosition(28));
    }

    [Fact]
    public void Returns_zero_for_whole_numbers()
    {
        const decimal wholeNumber = decimal.MaxValue;
        Assert.Equal(0, wholeNumber.DigitAtPosition(1));
    }

    [Fact]
    public void Returns_zero_if_position_is_greater_than_the_number_of_decimal_digits()
    {
        Assert.Equal(0, number.DigitAtPosition(29));
    }

    [Fact]
    public void Does_not_throw_if_number_is_max_decimal_value()
    {
        Assert.DoesNotThrow(() => decimal.MaxValue.DigitAtPosition(1));
    }

    [Fact]
    public void Does_not_throw_if_number_is_min_decimal_value()
    {
        Assert.DoesNotThrow(() => decimal.MinValue.DigitAtPosition(1));
    }

    [Fact]
    public void Does_not_throw_if_position_is_max_integer_value()
    {
        Assert.DoesNotThrow(() => number.DigitAtPosition(int.MaxValue));
    }
}
share|improve this answer
    
What does this solution cover that the others do not? Does it deal with edge cases? –  Elijah May 27 '10 at 20:26
    
Yes, it should deal with all edge cases. The most upvoted answer deals with too few values before overflowing, IMO. –  Sam Pearson May 27 '10 at 20:49
    
(not to mention it doesn't compile) –  Sam Pearson May 27 '10 at 22:15
    
Accepted because this solution deals with real-world edge cases. –  Elijah May 28 '10 at 16:57
(int)(value * Math.Pow(10, position)) % 10
share|improve this answer
    
+1, beat me by seconds :) –  Justin Ethier May 27 '10 at 17:56
2  
You should strip off the digits to the left of "position" first to avoid unnecessary overflows. –  mbeckish May 27 '10 at 17:57
    
@mbeckish it is enough for simple cases. for complex you have to do it in loop, multiply and strip –  Andrey May 27 '10 at 17:59
    
Math.Pow() returns the type double and that upsets the compiler a bit. Besides, casting decimal to an int is really bad idea. Aren't You missing a pair of parenthesis? –  Maciej Hehl May 27 '10 at 18:49
    
@mbeckish, Andrey: Would it not also be possible to just ignore overflow in this case? As long as you aren't modifying value itself, there's no reason you'd need to worry about the lost data there. @Maciej Hehl: How does this look? decimal.Floor(value * Math.Pow(10, position)) % 10 –  JAB May 27 '10 at 19:28

How about:

(int)(double(value) * Math.Pow(10, position)) % 10

Basically you multiply by 10 ^ pos in order to move that digit to the one's place, and then you use the modulus operator % to divide out the rest of the number.

share|improve this answer
6  
+1 for including an explanation :). I'm sure the code would include this as a comment. –  Daniel May 27 '10 at 18:37
    
I like how both simple answers are EXACTLY the same. Creepy. –  Rubys May 27 '10 at 19:32
    
With value = 10 and position = 1, this returns 0 :( –  JoanComasFdz Dec 17 '12 at 13:22
    
To get the last digit: value % 10 –  zzg Mar 19 at 0:24

Edited: Totally had the wrong and opposite answer here. I was calculating the position to the left of the decimal instead of the right. See the upvoted answers for the correct code.

share|improve this answer
    
yeah, did you try to run it? remainder (%) doesn't work with double. –  Andrey May 27 '10 at 18:15
    
My mistake. I quickly ran it in VS2010 interactive and used integer instead of decimal. I'll see if Math.DivRem() will work. –  JasDev May 27 '10 at 18:19

How about this:

protected static int FindNDigit(decimal value, int position)
{
    var index = value.ToString().IndexOf(".");
    position = position + index;
    return (int)Char.GetNumericValue(value.ToString(), position);
}
share|improve this answer
    
Good effort, but he said that he did not want to resort to string parsing... –  Justin Ethier May 27 '10 at 18:14
    
Yep. Missed that constraint. :( –  Paul Kearney - pk May 27 '10 at 18:19

I found this one here working:

public int ValueAtPosition(int value, int position)
{
    var result = value / (int)Math.Pow(10, position);
    result = result % 10;
    return result;
}

And also this one to know the full value (i.e.: 111, position 3 = 100 , sorry I don't know the proper name):

public int FullValueAtPosition(int value, int position)
{
    return this.ValueAtPosition(value, position) * (int)Math.Pow(10, position);
}
share|improve this answer

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