# C# data structure for multiple unit conversions

I have a C# app and I need to convert between 3 different units (say for example: litres, gallons, and pints).

The app needs to know about certain volumes of liquid, say: 1 pint, 10 pints, 20 pints and 100 pints. I intend to do the calculations and hard code the values (not ideal but necessary),

I'm looking for a data structure that will allow me to easily convert from one unit to another.

Any suggestions?

Please note: I'm not actually using volumes of liquid, its just an example!

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You can store a matrix of conversion factors where

• a: Is litres
• b: Is pints
• c: Are gallons

You'd have (not accurate, but assuming there are two pints to a litre and 4 litres to a gallon)

``````   a     b       c
a  1     2     0.25
b  0.5   1     0.125
c  4     8       1
``````

Alternatively, you can decide that everything is converted to a base value (litres) before being converted to another type, then you just need the first line.

Wrap this in a method that takes a number of units and "from" type and "two" type for the conversion.

Hope this helps

EDIT: some code, as requested

``````    public enum VolumeType
{
Litre = 0,
Pint = 1,
Gallon = 2
}

public static double ConvertUnits(int units, VolumeType from, VolumeType to)
{
double[][] factor =
{
new double[] {1, 2, 0.25},
new double[] {0.5, 1, 0.125},
new double[] {4, 8, 1}
};
return units * factor[(int)from][(int)to];
}

public static void ShowConversion(int oldUnits, VolumeType from, VolumeType to)
{
double newUnits = ConvertUnits(oldUnits, from, to);
Console.WriteLine("{0} {1} = {2} {3}", oldUnits, from.ToString(), newUnits, to.ToString());
}

static void Main(string[] args)
{
ShowConversion(1, VolumeType.Litre, VolumeType.Litre);  // = 1
ShowConversion(1, VolumeType.Litre, VolumeType.Pint);   // = 2
ShowConversion(1, VolumeType.Litre, VolumeType.Gallon); // = 4
ShowConversion(1, VolumeType.Pint, VolumeType.Pint);    // = 1
ShowConversion(1, VolumeType.Pint, VolumeType.Litre);   // = 0.5
ShowConversion(1, VolumeType.Pint, VolumeType.Gallon);  // = 0.125
ShowConversion(1, VolumeType.Gallon, VolumeType.Gallon);// = 1
ShowConversion(1, VolumeType.Gallon, VolumeType.Pint);  // = 8
ShowConversion(1, VolumeType.Gallon, VolumeType.Litre); // = 4
ShowConversion(10, VolumeType.Litre, VolumeType.Pint);  // = 20
ShowConversion(20, VolumeType.Gallon, VolumeType.Pint); // = 160
}
``````
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I like the idea of using a matrix. Could you perhaps elaborate upon how it would be implemented in the current scenario? TIA. –  Cerebrus Jan 30 '09 at 11:13
+1 I like the matrix solution too. –  Nano HE Apr 11 '10 at 13:10

I have done this in an other language by providing the correct access methods (properties):

``````for the class Volume:
AsLitre
AsGallon
AsPint

for the class Distance:
AsInch
AsMeter
AsYard
AsMile
``````

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EDIT: sample copied from MSDN

``````interface IEnglishDimensions
{
float Length();
float Width();
}
// Declare the metric units interface:
interface IMetricDimensions
{
float Length();
float Width();
}
// Declare the "Box" class that implements the two interfaces:
// IEnglishDimensions and IMetricDimensions:
class Box : IEnglishDimensions, IMetricDimensions
{
float lengthInches;
float widthInches;
public Box(float length, float width)
{
lengthInches = length;
widthInches = width;
}
// Explicitly implement the members of IEnglishDimensions:
float IEnglishDimensions.Length()
{
return lengthInches;
}
float IEnglishDimensions.Width()
{
return widthInches;
}
// Explicitly implement the members of IMetricDimensions:
float IMetricDimensions.Length()
{
return lengthInches * 2.54f;
}
float IMetricDimensions.Width()
{
return widthInches * 2.54f;
}
public static void Main()
{
// Declare a class instance "myBox":
Box myBox = new Box(30.0f, 20.0f);
// Declare an instance of the English units interface:
IEnglishDimensions eDimensions = (IEnglishDimensions) myBox;
// Declare an instance of the metric units interface:
IMetricDimensions mDimensions = (IMetricDimensions) myBox;
// Print dimensions in English units:
System.Console.WriteLine("Length(in): {0}", eDimensions.Length());
System.Console.WriteLine("Width (in): {0}", eDimensions.Width());
// Print dimensions in metric units:
System.Console.WriteLine("Length(cm): {0}", mDimensions.Length());
System.Console.WriteLine("Width (cm): {0}", mDimensions.Width());
}
}
``````
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Here's the source code in its full entirety:

``````using System;
using System.Collections.Generic;
using System.Globalization;
using System.IO;

namespace UnitConversion
{
internal delegate double Converter(double value);

class UnitConverter
{
private readonly IDictionary<string, IDictionary<string, Converter>> converters =
new Dictionary<string, IDictionary<string, Converter>>();

public UnitConverter()
{
numberFormatInfo = (NumberFormatInfo)NumberFormatInfo.InvariantInfo.Clone();
numberFormatInfo.NumberDecimalSeparator = ".";
numberFormatInfo.NumberGroupSeparator = String.Empty;
}

public void ParseConverterDefinition(string converterDefinition)
{
string[] parts = converterDefinition.Split(' ');
double sourceUnitsValue = double.Parse(parts[0], NumberFormatInfo.InvariantInfo);
double targetUnitsValue = double.Parse(parts[3], NumberFormatInfo.InvariantInfo);

}

private void AddConverters(string sourceUnits, double sourceUnitsValue, string targetUnits, double targetUnitsValue)
{
if (!converters.ContainsKey(sourceUnits))

converters[sourceUnits][targetUnits] =
delegate(double value)
{ return value * targetUnitsValue / sourceUnitsValue; };
}

public double? Convert(double value, string sourceUnits, string targetUnits, params string[] skipUnits)
{
if (!converters.ContainsKey(sourceUnits))
return null;

if (converters[sourceUnits].ContainsKey(targetUnits))
return converters[sourceUnits][targetUnits](value);

foreach (KeyValuePair<string, Converter> pair in converters[sourceUnits])
{
if (Array.IndexOf(skipUnits, pair.Key) != -1)
continue;

List<string> skip = new List<string>(skipUnits);

double? result = Convert(converters[sourceUnits][pair.Key](value), pair.Key, targetUnits, skip.ToArray());
if (result != null)
return result;
} // foreach

return null;
}

public string Convert(string conversionRequest)
{
string[] parts = conversionRequest.Split(' ');
return ConvertFormatted(double.Parse(parts[0], NumberFormatInfo.InvariantInfo), parts[1], parts[4]);
}

public string ConvertFormatted(double value, string sourceUnits, string targetUnits)
{
double? convertedValue = Convert(value, sourceUnits, targetUnits);
if (convertedValue == null)
return "No conversion is possible.";

return string.Format("{0} {1} = {2} {3}", value.ToString("N6", numberFormatInfo), sourceUnits,
convertedValue < 0.01 || convertedValue > 1000000 ?
convertedValue.Value.ToString("#.######e+00", numberFormatInfo) :
convertedValue.Value.ToString("N6", numberFormatInfo),
targetUnits);
}
}

class Program
{
static void Main(string[] args)
{

UnitConverter unitConverter = new UnitConverter();

{
if (s.IndexOf("?") == -1)
unitConverter.ParseConverterDefinition(s);
else
Console.WriteLine(unitConverter.Convert(s));
} // foreach
}
}
}
``````

It processes the file in the following format

``````7200.0 second = 2 hour
10.0 glob = 1 decaglob
1 day = 24.0 hour
1 minute = 60 second
1 glob = 10 centiglob
1 day = 24 hour
1 year = 365.25 day
50 centiglob = ? decaglob
5.6 second = ? hour
3 millisecond = ? hour
5.6 second = ? day
1 day = ? glob
1 hour = ? second
1 year = ? second
``````

and calculates, for instance, 50 centiglobs in decaglobs.

This code is capable of doing chained conversions (e.g. year -> day -> hour -> second).

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