# How can I convert an integer into its verbal representation?

Is there a library or a class/function that I can use to convert an integer to it's verbal representation?

Example input: `4,567,788`

Example output: `Four million, Five hundred sixty-seven thousand, seven hundred eighty-eight`

For reference, I am using C# and .NET 3.5.

-
–  bto.rdz Jul 27 at 21:48

if you use the code found in: converting numbers in to words C# and you need it for decimal numbers, here is how to do it:

``````public string DecimalToWords(decimal number)
{
if (number == 0)
return "zero";

if (number < 0)
return "minus " + DecimalToWords(Math.Abs(number));

string words = "";

int intPortion = (int)number;
decimal fraction = (number - intPortion)*100;
int decPortion = (int)fraction;

words = NumericToWords(intPortion);
if (decPortion > 0)
{
words += " and ";
words += NumericToWords(decPortion);
}
return words;
}
``````
-

http://www.exchangecore.com/blog/convert-number-words-c-sharp-console-application/ has some C# script that looks to handle very large numbers and very small decimals.

``````using System;
using System.Collections.Generic;
using System.Text;

namespace NumWords
{
class Program
{
// PROGRAM HANDLES NEGATIVE AND POSITIVE DOUBLES

static String NumWordsWrapper(double n)
{
string words = "";
double intPart;
double decPart = 0;
if (n == 0)
return "zero";
try {
string[] splitter = n.ToString().Split('.');
intPart = double.Parse(splitter[0]);
decPart = double.Parse(splitter[1]);
} catch {
intPart = n;
}

words = NumWords(intPart);

if (decPart > 0) {
if (words != "")
words += " and ";
int counter = decPart.ToString().Length;
switch (counter) {
case 1: words += NumWords(decPart) + " tenths"; break;
case 2: words += NumWords(decPart) + " hundredths"; break;
case 3: words += NumWords(decPart) + " thousandths"; break;
case 4: words += NumWords(decPart) + " ten-thousandths"; break;
case 5: words += NumWords(decPart) + " hundred-thousandths"; break;
case 6: words += NumWords(decPart) + " millionths"; break;
case 7: words += NumWords(decPart) + " ten-millionths"; break;
}
}
return words;
}

static String NumWords(double n) //converts double to words
{
string[] numbersArr = new string[] { "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve", "thirteen", "fourteen", "fifteen", "sixteen", "seventeen", "eighteen", "nineteen" };
string[] tensArr = new string[] { "twenty", "thirty", "fourty", "fifty", "sixty", "seventy", "eighty", "ninty" };
string[] suffixesArr = new string[] { "thousand", "million", "billion", "trillion", "quadrillion", "quintillion", "sextillion", "septillion", "octillion", "nonillion", "decillion", "undecillion", "duodecillion", "tredecillion", "Quattuordecillion", "Quindecillion", "Sexdecillion", "Septdecillion", "Octodecillion", "Novemdecillion", "Vigintillion" };
string words = "";

bool tens = false;

if (n < 0) {
words += "negative ";
n *= -1;
}

int power = (suffixesArr.Length + 1) * 3;

while (power > 3) {
double pow = Math.Pow(10, power);
if (n >= pow) {
if (n % pow > 0) {
words += NumWords(Math.Floor(n / pow)) + " " + suffixesArr[(power / 3) - 1] + ", ";
} else if (n % pow == 0) {
words += NumWords(Math.Floor(n / pow)) + " " + suffixesArr[(power / 3) - 1];
}
n %= pow;
}
power -= 3;
}
if (n >= 1000) {
if (n % 1000 > 0) words += NumWords(Math.Floor(n / 1000)) + " thousand, ";
else words += NumWords(Math.Floor(n / 1000)) + " thousand";
n %= 1000;
}
if (0 <= n && n <= 999) {
if ((int)n / 100 > 0) {
words += NumWords(Math.Floor(n / 100)) + " hundred";
n %= 100;
}
if ((int)n / 10 > 1) {
if (words != "")
words += " ";
words += tensArr[(int)n / 10 - 2];
tens = true;
n %= 10;
}

if (n < 20 && n > 0) {
if (words != "" && tens == false)
words += " ";
words += (tens ? "-" + numbersArr[(int)n - 1] : numbersArr[(int)n - 1]);
n -= Math.Floor(n);
}
}

return words;

}
static void Main(string[] args)
{
Console.Write("Enter a number to convert to words: ");

Console.WriteLine("{0}", NumWordsWrapper(n));
}
}
}
``````

EDIT: brought code over from blog post

-
``````Imports System.Text

Public Class NumberWriter

Public Shared Function Parse(ByVal Number As String) As String
If Not AreNumbers(Number) Then Return ""
Dim TempQueue As New Queue(Of String)
For Each ItemA As Char In Number.Replace(",", "").Reverse
TempQueue.Enqueue(ItemA)
Next
Dim Blocks As New List(Of String)
Dim BlockEmpty As New List(Of Boolean)
Do
Dim TempBlock As New StringBuilder(3)
TempBlock.Append(TempQueue.Dequeue)
If TempQueue.Count > 0 Then
TempBlock.Append(TempQueue.Dequeue)
If TempQueue.Count > 0 Then
TempBlock.Append(TempQueue.Dequeue)
End If
End If
If TempQueue.Count < 1 Then Exit Do
Loop
Dim ResultStack As New Stack(Of String)
For int1 As Integer = 0 To Blocks.Count - 1
ResultStack.Push(ReadBlock(Blocks(int1)) & If(Not int1 = 0, If(Not BlockEmpty(int1), " " & CapitalizeWord(GetPlaceValueSet(int1)) & If(BlockEmpty(int1 - 1), "", ", "), ""), ""))
Next
Dim Result1 As String = ""
Do Until ResultStack.Count < 1
Result1 &= ResultStack.Pop
Loop
Return RemoveGrammarErrors(Result1)
End Function

Private Shared Function RemoveGrammarErrors(ByVal Str As String) As String
Dim tstr As String = Str
tstr.Replace("  ", " ")
tstr.Replace(" , ", ", ")
Return tstr
End Function

Private Shared Function AreNumbers(ByVal Str1 As String) As Boolean
Dim Numbers() As String = {"0", "1", "2", "3", "4", "5", "6", "7", "8", "9", ","}
For Each ItemA As Char In Str1
Dim IsN As Boolean = False
For Each ItemB As String In Numbers
If ItemA = ItemB Then IsN = True
Next
If Not IsN Then
Return False
End If
Next
Return True
End Function

Private Shared Function ReadBlock(ByVal Block As String)
Select Case Block.Length
Case 1
Case 2
Case 3
Case Else
Throw New Exception
End Select
End Function

Private Shared Function ReadThreeDigits(ByVal Digits As String)
If Digits.Length > 3 Then Throw New ArgumentException("There are too many digits.")
Dim Result As String = ""
If Not Digits(0) = "0" Then
Result &= ReadSingleDigit(Digits(0)) & " Hundred "
End If
Return Result
End Function

Private Shared Function ReadTwoDigits(ByVal Digits As String)
If Digits.Length > 2 Then Throw New ArgumentException("There are too many digits.")
Select Case Digits(0)
Case "0"
Case "1"
Case Else
End Select
End Function

Private Shared Function ReadSingleDigit(ByVal Digit As String) As String
If Not Digit.Length = 1 Then Throw New ArgumentException("There must be only one digit and it must be more than zero.")
Select Case Digit
Case "0"
Return ""
Case "1"
Return "One"
Case "2"
Return "Two"
Case "3"
Return "Three"
Case "4"
Return "Four"
Case "5"
Return "Five"
Case "6"
Return "Six"
Case "7"
Return "Seven"
Case "8"
Return "Eight"
Case "9"
Return "Nine"
Case Else
Throw New Exception()
End Select
End Function

Private Shared Function ReadTeenNumber(ByVal Num As String) As String
Select Case Num
Case "11"
Return "Eleven"
Case "12"
Return "Twelve"
Case "13"
Return "Thirteen"
Case "14"
Return "Fourteen"
Case "15"
Return "Fifteen"
Case "16"
Return "Sixteen"
Case "17"
Return "Seventeen"
Case "18"
Return "Eighteen"
Case "19"
Return "Nineteen"
Case Else
Throw New Exception()
End Select
End Function

Private Shared Function ReadFirstInNumberPair(ByVal Num As String) As String
If Not (Num > 1 OrElse Num < 10) Then Throw New ArgumentException("Number must be more than 1 and less than 10")
Select Case Num
Case "2"
Return "Twenty"
Case "3"
Return "Thirty"
Case "4"
Return "Fourty"
Case "5"
Return "Fifty"
Case "6"
Return "Sixty"
Case "7"
Return "Seventy"
Case "8"
Return "Eighty"
Case "9"
Return "Ninety"
Case Else
Throw New Exception()
End Select
End Function

Private Shared Function CapitalizeWord(ByVal Word As String) As String
Return Word.Substring(0, 1).ToUpper & Word.Substring(1)
End Function

Private Shared Function GetPlaceValueSet(ByVal Num As Byte) As String
Select Case Num
Case 0
Return "" 'Hundreds
Case 1
Return "Thousand"
Case 2
Return "Million"
Case 3
Return "Billion"
Case 4
Return "Trillion"
Case 5
Case 6
Return "Quintillion"
Case 7
Return "Sextillion"
Case 8
Return "Septillion"
Case 9
Return "Octillion"
Case 10
Return "Nonillion"
Case 11
Return "octillion"
Case 12
Return "nonillion"
Case 13
Return "decillion"
Case 14
Return "undecillion"
Case 15
Return "dodecillion,"
Case 16
Return "tredecillion"
Case 17
Return "quattuordecillion"
Case 18
Return "quindecillion"
Case 19
Return "sexdecillion"
Case 20
Return "septendecillion"
Case 21
Return "octodecillion"
Case 22
Return "novemdecillion"
Case 23
Return "vigintillion"
Case 24
Return "unvigintillion"
Case 25
Return "dovigintillion"
Case 26
Return "trevigintillion"
Case 27
Return "quattuorvigintillion"
Case 28
Return "quinvigintillion"
Case 29
Return "sexvigintillion"
Case 30
Return "septenvigintillion"
Case 31
Return "octovigintillion"
Case 32
Return "novemvigintillion"
Case 33
Return "trigintillion"
Case 34
Return "untrigintillion"
Case 35
Return "dotrigintillion"
Case 36
Return "tretrigintillion"
Case 37
Return "quattuortrigintillion"
Case 38
Return "quintrigintillion"
Case 39
Return "sextrigintillion"
Case 40
Return "septentrigintillion"
Case 41
Return "octotrigintillion"
Case Else
Throw New Exception
End Select
End Function
End Class
``````

Sorry it's in VB.NET, but it works completely. It is one way. Number to Verbal. Handles numbers up to 123 characters long I believe.

-

``````namespace ConsoleApplication3
{

class Program
{

static void Main(string[] args)
{

ConvertMyword(int.Parse(s));

}

static void ConvertMyword(int number)
{
int flag = 0;
int lflag = 0;
string words = String.Empty;
string[] places = { "ones", "ten", "hundred", "thousand", "ten thousand", "lacs","tenlacs","crore","tencrore" };
string rawnumber = number.ToString();
char[] a = rawnumber.ToCharArray();
Array.Reverse(a);
for (int i = a.Length - 1; i >= 0; i--)
{
if (i % 2 == 0 && i > 2)
{
if (int.Parse(a[i].ToString()) > 1)
{
if (int.Parse(a[i - 1].ToString()) == 0)
{
words = words + getNumberStringty(int.Parse(a[i].ToString())) + " " + places[i - 1] + " ";
}
else
{
words = words + getNumberStringty(int.Parse(a[i].ToString())) + " ";
}
}
else if (int.Parse(a[i].ToString()) == 1)
{
if (int.Parse(a[i - 1].ToString())== 0)
{
words = words +"Ten" + " ";
}
else
{
words = words + getNumberStringteen(int.Parse(a[i - 1].ToString())) + " ";
}
flag = 1;
}
}
else
{
if (i == 1 || i == 0)
{
if (int.Parse(a[i].ToString()) > 1)
{
words = words + getNumberStringty(int.Parse(a[i].ToString())) + " " + getNumberString(int.Parse(a[0].ToString())) + " ";
break;
}
else if (int.Parse(a[i].ToString()) == 1)
{
if (int.Parse(a[i - 1].ToString()) == 0)
{
words = words + "Ten" + " ";
}
else
{
words = words + getNumberStringteen(int.Parse(a[i - 1].ToString())) + " ";
}

break;
}
else if (int.Parse(a[i - 1].ToString()) != 0)
{
words = words + getNumberString(int.Parse(a[i - 1].ToString())) + " ";
break;
}
else
{
break;
}
}
else
{
if (flag == 0)
{
for(int l=i;l>=0;l--)
{
if (int.Parse(a[l].ToString())!=0)
{
lflag = 1;
}
}
if (lflag == 1 && int.Parse(a[i].ToString())!=0)
{

words = words + getNumberString(int.Parse(a[i].ToString())) + " " + places[i] + " ";
lflag = 0;

}
else if(lflag == 0)
{
// words = words + getNumberString(int.Parse(a[i].ToString())) + " " + places[i] + " ";
lflag = 0;
break;
}

}
else
{
words = words + " " + places[i] + " ";
flag = 0;
}

}
}
}
Console.WriteLine(words);
}
static string getNumberString(int num)
{
string Word = String.Empty;
switch (num)
{
case 1:
Word = "one";
break;
case 2:
Word = "two";
break;

case 3:
Word = "three";
break;

case 4:
Word = "four";
break;

case 5:
Word = "five";
break;

case 6:
Word = "six";
break;
case 7:
Word = "seven";
break;

case 8:
Word = "eight";
break;

case 9:
Word = "nine";
break;

}
return Word;
}
static string getNumberStringty(int num)
{
string Word = String.Empty;
switch (num)
{

case 2:
Word = "twenty";
break;

case 3:
Word = "thirty";
break;

case 4:
Word = "fourty";
break;

case 5:
Word = "fifty";
break;

case 6:
Word = "sixty";
break;
case 7:
Word = "seventy";
break;

case 8:
Word = "eighty";
break;

case 9:
Word = "ninty";
break;

}
return Word;
}
static string getNumberStringteen(int num)
{
string Word = String.Empty;
switch (num)
{
case 1:
Word = "eleven";
break;
case 2:
Word = "tewlve";
break;

case 3:
Word = "thirteen";
break;

case 4:
Word = "fourteen";
break;

case 5:
Word = "fifteen";
break;

case 6:
Word = "sixteen";
break;
case 7:
Word = "seventeen";
break;

case 8:
Word = "eighteen";
break;

case 9:
Word = "ninteen";
break;

}
return Word;
}
}

}
``````
-

Fully recursive version:

``````private static string[] ones = {
"zero", "one", "two", "three", "four", "five", "six", "seven", "eight", "nine",
"ten", "eleven", "twelve", "thirteen", "fourteen", "fifteen", "sixteen", "seventeen", "eighteen", "nineteen",
};

private static string[] tens = { "zero", "ten", "twenty", "thirty", "forty", "fifty", "sixty", "seventy", "eighty", "ninety" };

private static string[] thous = { "hundred", "thousand", "million", "billion", "trillion", "quadrillion" };

public static string ToWords(decimal number)
{
if (number < 0)
return "negative " + ToWords(Math.Abs(number));

int intPortion = (int)number;
int decPortion = (int)((number - intPortion) * (decimal) 100);

return string.Format("{0} dollars and {1} cents", ToWords(intPortion), ToWords(decPortion));
}

private static string ToWords(int number, string appendScale = "")
{
string numString = "";
if (number < 100)
{
if (number < 20)
numString = ones[number];
else
{
numString = tens[number / 10];
if ((number % 10) > 0)
numString += "-" + ones[number % 10];
}
}
else
{
int pow = 0;
string powStr = "";

if (number < 1000) // number is between 100 and 1000
{
pow = 100;
powStr = thous[0];
}
else // find the scale of the number
{
int log = (int)Math.Log(number, 1000);
pow = (int)Math.Pow(1000, log);
powStr = thous[log];
}

numString = string.Format("{0} {1}", ToWords(number / pow, powStr), ToWords(number % pow)).Trim();
}

return string.Format("{0} {1}", numString, appendScale).Trim();
}
``````

Current works up to the (short scale) quadrillions. Additional support (for larger numbers, or for the long scale) can be added simply by changing the `thous` variable.

Perhaps, needlessly complex (the special case for hundreds bugs me a little), given that modifying the non-recursive version is also fairly simple.

-

Currently the best, most robust, library for this is definitely Humanizer. It's open sourced and available as a nuget:

``````Console.WriteLine(4567788.ToWords()); // => four million five hundred and sixty-seven thousand seven hundred and eighty-eight
``````

It also has a wide range of tools solving the small problems every application has with `string`s, `enum`s, `DateTime`s, `TimeSpan`s and so forth, and supports many different languages.

``````Console.WriteLine(4567788.ToOrdinalWords().Underscore().Hyphenate().ApplyCase(LetterCasing.AllCaps)); // => FOUR-MILLION-FIVE-HUNDRED-AND-SIXTY-SEVEN-THOUSAND-SEVEN-HUNDRED-AND-EIGHTY-EIGHTH
``````
-

In case anyone wants a JavaScript version

``````Number.prototype.numberToWords = function () {
var unitsMap = ["zero", "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve", "thirteen", "fourteen", "fifteen", "sixteen", "seventeen", "eighteen", "nineteen"];
var tensMap = ["zero", "ten", "twenty", "thirty", "forty", "fifty", "sixty", "seventy", "eighty", "ninety"];

var num = this.valueOf();
if (Math.round(num == 0)) {
return "zero";
}
if (num < 0) {
var positivenum = Math.abs(num);
return "minus " + Number(positivenum).numberToWords();
}
var words = "";
if (Math.floor(num / 1000000) > 0) {
words += Math.floor(num / 1000000).numberToWords() + " million ";
num = Math.floor(num % 1000000);
}
if (Math.floor(num / 1000) > 0) {
words += Math.floor(num / 1000).numberToWords() + " thousand ";
num = Math.floor(num % 1000);
}
if (Math.floor(num / 100) > 0) {
words += Math.floor(num / 100).numberToWords() + " hundred ";
num = Math.floor(num % 100);
}
if (Math.floor(num > 0)) {
if (words != "") {
words += "and ";
}
if (num < 20) {
words += unitsMap[num];
}
else {
words += tensMap[Math.floor(num / 10)];
if ((num % 10) > 0) {
words += "-" + unitsMap[Math.round(num % 10)];
}
}
}
return words.trim();
}
``````
-

This class perfectly converts your float or double (till 2 precision). Just copy and paste in your IDE and see the result.

``````class ConversionClass
{
private static Dictionary<int, string> InitialNumbers = new Dictionary<int, string>();
private static Dictionary<int, string> MultipleOfTen = new Dictionary<int, string>();
private static Dictionary<int, string> MultipleOfHundered = new Dictionary<int, string>();

private static void InitializeStatic()
{

MultipleOfHundered.Add(6, "million");                      //          1 000 000
MultipleOfHundered.Add(7, "million");                      //        100 000 000
MultipleOfHundered.Add(8, "million");                      //      1 000 000 000
MultipleOfHundered.Add(9, "billion");                      //  1 000 000 000 000
}

public static void Main()
{
InitializeStatic();
Console.WriteLine("Enter number :");
double userValue ;
if (double.TryParse(userInput, out userValue))  // userValue = 193524019.50
{
int decimalPortion = (int)userValue;
//var fractionPortion = Math.Ceiling(((userValue < 1.0) ? userValue : (userValue % Math.Floor(userValue))) * 100);
int fractionPortion = (int)(userValue * 100) - ((int)userValue * 100);

int digit; int power;
StringBuilder numberInText = new StringBuilder();

while (decimalPortion > 0)
{
GetDigitAndPower(decimalPortion, out digit, out power);
numberInText.Append(ConvertToText(ref decimalPortion, ref digit, ref power));
if (decimalPortion > 0)
{
decimalPortion = GetReminder(decimalPortion, digit, power);
}
}
numberInText.Append(" point ");
while (fractionPortion > 0)
{
GetDigitAndPower(fractionPortion, out digit, out power);
numberInText.Append(ConvertToText(ref fractionPortion, ref digit, ref power));
if (fractionPortion > 0)
{
fractionPortion = GetReminder(fractionPortion, digit, power);
}
}

Console.WriteLine(numberInText.ToString());
}
}

private static int GetReminder(int orgValue, int digit, int power)
{
int returningValue = orgValue - (digit * (int)Math.Pow(10, power));
return returningValue;
}

private static void GetDigitAndPower(int originalValue, out int digit, out int power)
{
for (power = 0, digit = 0; power < 10; power++)
{
var divisionFactor = (int)Math.Pow(10, power);
int operationalValue = (originalValue / divisionFactor);
if (operationalValue <= 0)
{
power = power - 1;
digit = (int)(originalValue / Math.Pow(10, power));
break;
}
}
}

private static string ConvertToText(ref int orgValue, ref int digit, ref int power)
{
string numberToText = string.Empty;

if (power < 2)
{
if (InitialNumbers.ContainsKey(orgValue))
{
//This is for number 1 to 19
numberToText = InitialNumbers[orgValue];
orgValue = 0;
}
else if (MultipleOfTen.ContainsKey(digit))
{
//This is for multiple of 10 (20,30,..90)
numberToText = MultipleOfTen[digit];
}
}
else
{
if (power < 4)
{
numberToText = string.Format("{0} {1}", InitialNumbers[digit], MultipleOfHundered[power]);
}
else
{
StringBuilder sb = new StringBuilder();
int multiplicationFactor = power / 3;
int innerOrgValue = (int) (orgValue / Math.Pow(10, (multiplicationFactor * 3)));
digit = innerOrgValue;
var multiple = MultipleOfHundered[power];
power = power - ((int)Math.Ceiling(Math.Log10(innerOrgValue)) - 1);

int innerPower = 0;
int innerDigit = 0;
while (innerOrgValue > 0)
{
GetDigitAndPower(innerOrgValue, out innerDigit, out innerPower);
var text = ConvertToText(ref innerOrgValue, ref innerDigit, ref innerPower);
sb.Append(text);
sb.Append(" ");
if (innerOrgValue > 0)
{
innerOrgValue = GetReminder(innerOrgValue, innerDigit, innerPower);
}
}
sb.Append(multiple);
numberToText = sb.ToString();

}
}

return numberToText + " ";
}

}
``````
-
@Hannele 's solution is also good but it fails for value : 10 000, 100 000 –  Aamol Jun 25 at 2:58

## protected by i3arnonDec 2 '14 at 21:42

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