# How to read values from numbers written as words?

As we all know numbers can be written either in numerics, or called by their names. While there are a lot of examples to be found that convert 123 into one hundred twenty three, I could not find good examples of how to convert it the other way around.

Some of the caveats:

1. cardinal/nominal or ordinal: "one" and "first"
2. common spelling mistakes: "forty"/"fourty"
3. hundreds/thousands: 2100 -> "twenty one hundred" and also "two thousand and one hundred"
4. separators: "eleven hundred fifty two", but also "elevenhundred fiftytwo" or "eleven-hundred fifty-two" and whatnot
5. colloquialisms: "thirty-something"
6. fractions: 'one third', 'two fifths'
7. common names: 'a dozen', 'half'

And there are probably more caveats possible that are not yet listed. Suppose the algorithm needs to be very robust, and even understand spelling mistakes.

What fields/papers/studies/algorithms should I read to learn how to write all this? Where is the information?

PS: My final parser should actually understand 3 different languages, English, Russian and Hebrew. And maybe at a later stage more languages will be added. Hebrew also has male/female numbers, like "one man" and "one woman" have a different "one" — "ehad" and "ahat". Russian also has some of its own complexities.

Google does a great job at this. For example:

(the reverse is also possible http://www.google.com/search?q=999999999999+in+english)

• This may not apply to recipes so much, but don't forget about words like score, decade, century etc. Similar to dozen, gross, half as you have already noted. Mar 13, 2009 at 15:42
• "fourty" is not a word in any variant of English! The OED has a couple of mentions of the spelling "fourty", but they are from 1707 or earlier. Mar 17, 2009 at 5:40
• Even though "fourty" is not a word, people commonly mistake is for one. And I need to parse what people write, not "proper" words. Mar 17, 2009 at 13:46
• It would seem that having only one way to say a number (as in "one" in English) is the exception, rather than the rule. French has "un" and "une"; and German has at least 3 different ways to say 1 ("eins", "eine" and "einen" if memory serves me correctly).
– RobH
Mar 18, 2009 at 1:06
• @RobH Pedantry warning!!! "Eine" and "Einen" are indefinite articles (think "a" or "an") and not the integer ("one"). :-) Aug 3, 2011 at 11:47

I was playing around with a PEG parser to do what you wanted (and may post that as a separate answer later) when I noticed that there's a very simple algorithm that does a remarkably good job with common forms of numbers in English, Spanish, and German, at the very least.

Working with English for example, you need a dictionary that maps words to values in the obvious way:

``````"one" -> 1, "two" -> 2, ... "twenty" -> 20,
"dozen" -> 12, "score" -> 20, ...
"hundred" -> 100, "thousand" -> 1000, "million" -> 1000000
``````

...and so forth

The algorithm is just:

``````total = 0
prior = null
for each word w
v <- value(w) or next if no value defined
prior <- case
when prior is null:       v
when prior > v:     prior+v
else                prior*v
else
if w in {thousand,million,billion,trillion...}
total <- total + prior
prior <- null
total = total + prior unless prior is null
``````

For example, this progresses as follows:

``````total    prior      v     unconsumed string
0      _              four score and seven
4     score and seven
0      4
20     and seven
0     80
_     seven
0     80
7
0     87
87

total    prior      v     unconsumed string
0        _            two million four hundred twelve thousand eight hundred seven
2     million four hundred twelve thousand eight hundred seven
0        2
1000000 four hundred twelve thousand eight hundred seven
2000000      _
4     hundred twelve thousand eight hundred seven
2000000      4
100   twelve thousand eight hundred seven
2000000    400
12    thousand eight hundred seven
2000000    412
1000  eight hundred seven
2000000  412000
1000  eight hundred seven
2412000     _
8   hundred seven
2412000     8
100  seven
2412000   800
7
2412000   807
2412807
``````

And so on. I'm not saying it's perfect, but for a quick and dirty it does quite well.

1. cardinal/nominal or ordinal: "one" and "first" -- just put them in the dictionary
2. english/british: "fourty"/"forty" -- ditto
3. hundreds/thousands: 2100 -> "twenty one hundred" and also "two thousand and one hundred" -- works as is
4. separators: "eleven hundred fifty two", but also "elevenhundred fiftytwo" or "eleven-hundred fifty-two" and whatnot -- just define "next word" to be the longest prefix that matches a defined word, or up to the next non-word if none do, for a start
5. colloqialisms: "thirty-something" -- works
6. fragments: 'one third', 'two fifths' -- uh, not yet...
7. common names: 'a dozen', 'half' -- works; you can even do things like "a half dozen"

Number 6 is the only one I don't have a ready answer for, and that's because of the ambiguity between ordinals and fractions (in English at least) added to the fact that my last cup of coffee was many hours ago.

• If you add code to tell about undefined words, then it can get better over time. But, what about one billion, which I think is defined as a different number in the US and Europe? 1,000,000,000 for US. Mar 20, 2009 at 3:40
• There's no good programmatic way to handle billion from a limited corpus. If you were pulling number out of a larger body of text you might look for correlates (e.g. "colour" or "metres") but in general you're up a bloody stump. Mar 20, 2009 at 4:48
• @MarkusQ: Looking at the larger body of text doesn't always work. For instance, many Canadians use the British spellings, but use the US definitions of million, billion, etc.
– RobH
Aug 3, 2011 at 17:13
• What about forms where numbers are concatenated, like "nineteen ninety" or phone numbers, which are often given as strings of one or two digit numbers? These look like they break the algorithm at `where prior > v:`. Aug 6, 2014 at 15:40
• Then there's phrases like "one ten" to mean 110. Aug 6, 2014 at 15:51

It's not an easy issue, and I know of no library to do it. I might sit down and try to write something like this sometime. I'd do it in either Prolog, Java or Haskell, though. As far as I can see, there are several issues:

• Tokenization: sometimes, numbers are written eleven hundred fifty two, but I've seen elevenhundred fiftytwo or eleven-hundred-fifty-two and whatnot. One would have to conduct a survey on what forms are actually in use. This might be especially tricky for Hebrew.
• Spelling mistakes: that's not so hard. You have a limited amount of words, and a bit of Levenshtein-distance magic should do the trick.
• Alternate forms, like you already mentioned, exist. This includes ordinal/cardinal numbers, as well as forty/fourty and...
• ... common names or commonly used phrases and NEs (named entities). Would you want to extract 30 from the Thirty Years War or 2 from World War II?
• Roman numerals, too?
• Colloqialisms, such as "thirty-something" and "three Euro and shrapnel", which I wouldn't know how to treat.

If you are interested in this, I could give it a shot this weekend. My idea is probably using UIMA and tokenizing with it, then going on to further tokenize/disambiguate and finally translate. There might be more issues, let's see if I can come up with some more interesting things.

Sorry, this is not a real answer yet, just an extension to your question. I'll let you know if I find/write something.

By the way, if you are interested in the semantics of numerals, I just found an interesting paper by Friederike Moltmann, discussing some issues regarding the logic interpretation of numerals.

• thanks! a lot of very useful information. I am using Treetop PEG to start writing a parser, first started with regexps but it was too limiting. This is mostly for parsing cooking recipes, like: "two tablespoons of salt" Sep 18, 2008 at 6:47
• regarding the levenshtein-distance, great idea. i wonder if I should make it aware of the qwerty keyboard for the four different languages ... Sep 18, 2008 at 7:11
• That paper is nonsense, or at least more philosophy than linguistics. He confounds grammar and semantics, begs the question and largely skirts the interesting issues to support his "theory." For example, just replacing "planets" with "chairs" does amazing things to some of his examples. Mar 17, 2009 at 23:23

I have some code I wrote a while ago: text2num. This does some of what you want, except it does not handle ordinal numbers. I haven't actually used this code for anything, so it's largely untested!

• I ended up using a slight modification of Greg's code with good results, so it's somewhat tested ;-) Mar 17, 2009 at 5:46
• This link is broken. When linking to an external resource, consider including the relevant code in your answer so it will remain available. Jan 29, 2015 at 18:00
• @recursive thanks, I've updated the link to a permanent resource. It's probably a bit too long to include in the answer. Jan 30, 2015 at 0:45
• text2num is a great tool, thanks! I just used it recently and combined it with some simple dictionaries to do substitutions of ordinals for cardinal words and then fed those to the `word_to_num()` function from that module. Thanks! Dec 28, 2018 at 14:09

Use the Python pattern-en library:

``````>>> from pattern.en import number
>>> number('two thousand fifty and a half') => 2050.5
``````
• The question is tagged language agnostic. A python library is not a language-agnostic solution. Dec 23, 2013 at 19:04
• Sadly its not python 3 compatible, nor does it look like it will be. Jan 17, 2017 at 14:26
• @EricJ. A question tagged language-agnostic rather means "any programming language is appropriate in an answer", if it answers the question. It does not mean "no programming language, please". Aug 10, 2021 at 13:57
• @TylerH: That's not how I interpret, "independent of any particular programming language." This answer depends on a specific library for a specific version of Python. Maybe the common usage of that tag has wandered since I wrote the comment in 2013, though. Aug 10, 2021 at 18:32

You should keep in mind that Europe and America count differently.

### European standard:

``````One Thousand
One Million
One Thousand Millions (British also use Milliard)
One Billion
One Thousand Billions
One Trillion
One Thousand Trillions
``````

Here is a small reference on it.

A simple way to see the difference is the following:

``````(American counting Trillion) == (European counting Billion)
``````
• Just thought I'd point out that the British don't use Milliard, it's the French. We (the British) also don't pluralise Million, Billion etc except in the plural. "There were millions of the blighters!" Mar 18, 2009 at 9:37
• All references i found to milliard was for brittain english, sry then
– fmsf
Mar 18, 2009 at 10:10
• milliard is an old word that no one uses in practice. you find it in some old books occassionally.
– Tom
Mar 20, 2009 at 9:20
• In Dutch: duizend, miljoen, miljard, biljoen, biljard, triljoen, triljard, etc. Jun 5, 2009 at 13:59

Ordinal numbers are not applicable because they cant be joined in meaningful ways with other numbers in language (...at least in English)

e.g. one hundred and first, eleven second, etc...

However, there is another English/American caveat with the word 'and'

i.e.

one hundred and one (English) one hundred one (American)

Also, the use of 'a' to mean one in English

a thousand = one thousand

...On a side note Google's calculator does an amazing job of this.

one hundred and three thousand times the speed of light

And even...

two thousand and one hundred plus a dozen

• "One hundred and first" is perfectly valid English. You certainly can say things like "tomorrow will be the two hundred and twelfth day of the year" or "he came in four hundred and thirty first out of four hundred and thirty eight candidates." Mar 17, 2009 at 2:19
• @MarkusQ - ...but not in the context being discussed. Mar 25, 2009 at 23:10

Here is an extremely robust solution in Clojure.

AFAIK it is a unique implementation approach.

``````;----------------------------------------------------------------------
; numbers.clj
; written by: Mike Mattie [email protected]
;----------------------------------------------------------------------
(ns operator.numbers
(:use compojure.core)

(:require
[clojure.string     :as string] ))

(def number-word-table {
"zero"          0
"one"           1
"two"           2
"three"         3
"four"          4
"five"          5
"six"           6
"seven"         7
"eight"         8
"nine"          9
"ten"           10
"eleven"        11
"twelve"        12
"thirteen"      13
"fourteen"      14
"fifteen"       15
"sixteen"       16
"seventeen"     17
"eighteen"      18
"nineteen"      19
"twenty"        20
"thirty"        30
"fourty"        40
"fifty"         50
"sixty"         60
"seventy"       70
"eighty"        80
"ninety"        90
})

(def multiplier-word-table {
"hundred"       100
"thousand"      1000
})

(defn sum-words-to-number [ words ]
(apply + (map (fn [ word ] (number-word-table word)) words)) )

; are you down with the sickness ?
(defn words-to-number [ words ]
(let
[ n           (count words)

multipliers (filter (fn [x] (not (false? x))) (map-indexed
(fn [ i word ]
(if (contains? multiplier-word-table word)
(vector i (multiplier-word-table word))
false))
words) )

x           (ref 0) ]

(loop [ indices (reverse (conj (reverse multipliers) (vector n 1)))
left    0
combine + ]
(let
[ right (first indices) ]

(dosync (alter x combine (* (if (> (- (first right) left) 0)
(sum-words-to-number (subvec words left (first right)))
1)
(second right)) ))

(when (> (count (rest indices)) 0)
(recur (rest indices) (inc (first right))
(if (= (inc (first right)) (first (second indices)))
*
+))) ) )
@x ))
``````

Here are some examples

``````(operator.numbers/words-to-number ["six" "thousand" "five" "hundred" "twenty" "two"])
(operator.numbers/words-to-number ["fifty" "seven" "hundred"])
(operator.numbers/words-to-number ["hundred"])
``````

My LPC implementation of some of your requirements (American English only):

``````internal mapping inordinal = ([]);
internal mapping number = ([]);

#define Numbers ([\
"zero"        : 0, \
"one"         : 1, \
"two"         : 2, \
"three"       : 3, \
"four"        : 4, \
"five"        : 5, \
"six"         : 6, \
"seven"       : 7, \
"eight"       : 8, \
"nine"        : 9, \
"ten"         : 10, \
"eleven"      : 11, \
"twelve"      : 12, \
"thirteen"    : 13, \
"fourteen"    : 14, \
"fifteen"     : 15, \
"sixteen"     : 16, \
"seventeen"   : 17, \
"eighteen"    : 18, \
"nineteen"    : 19, \
"twenty"      : 20, \
"thirty"      : 30, \
"forty"       : 40, \
"fifty"       : 50, \
"sixty"       : 60, \
"seventy"     : 70, \
"eighty"      : 80, \
"ninety"      : 90, \
"hundred"     : 100, \
"thousand"    : 1000, \
"million"     : 1000000, \
"billion"     : 1000000000, \
])

#define Ordinals ([\
"zeroth"        : 0, \
"first"         : 1, \
"second"        : 2, \
"third"         : 3, \
"fourth"        : 4, \
"fifth"         : 5, \
"sixth"         : 6, \
"seventh"       : 7, \
"eighth"        : 8, \
"ninth"         : 9, \
"tenth"         : 10, \
"eleventh"      : 11, \
"twelfth"       : 12, \
"thirteenth"    : 13, \
"fourteenth"    : 14, \
"fifteenth"     : 15, \
"sixteenth"     : 16, \
"seventeenth"   : 17, \
"eighteenth"    : 18, \
"nineteenth"    : 19, \
"twentieth"     : 20, \
"thirtieth"     : 30, \
"fortieth"      : 40, \
"fiftieth"      : 50, \
"sixtieth"      : 60, \
"seventieth"    : 70, \
"eightieth"     : 80, \
"ninetieth"     : 90, \
"hundredth"     : 100, \
"thousandth"    : 1000, \
"millionth"     : 1000000, \
"billionth"     : 1000000000, \
])

varargs int denumerical(string num, status ordinal) {
if(ordinal) {
if(member(inordinal, num))
return inordinal[num];
} else {
if(member(number, num))
return number[num];
}
int sign = 1;
int total = 0;
int sub = 0;
int value;
string array parts = regexplode(num, " |-");
if(sizeof(parts) >= 2 && parts[0] == "" && parts[1] == "-")
sign = -1;
for(int ix = 0, int iix = sizeof(parts); ix < iix; ix++) {
string part = parts[ix];
switch(part) {
case "negative" :
case "minus"    :
sign = -1;
continue;
case ""         :
continue;
}
if(ordinal && ix == iix - 1) {
if(part[0] >= '0' && part[0] <= '9' && ends_with(part, "th"))
value = to_int(part[..<3]);
else if(member(Ordinals, part))
value = Ordinals[part];
else
continue;
} else {
if(part[0] >= '0' && part[0] <= '9')
value = to_int(part);
else if(member(Numbers, part))
value = Numbers[part];
else
continue;
}
if(value < 0) {
sign = -1;
value = - value;
}
if(value < 10) {
if(sub >= 1000) {
total += sub;
sub = value;
} else {
sub += value;
}
} else if(value < 100) {
if(sub < 10) {
sub = 100 * sub + value;
} else if(sub >= 1000) {
total += sub;
sub = value;
} else {
sub *= value;
}
} else if(value < sub) {
total += sub;
sub = value;
} else if(sub == 0) {
sub = value;
} else {
sub *= value;
}
}
total += sub;
return sign * total;
}
``````

Well, I was too late on the answer for this question, but I was working a little test scenario that seems to have worked very well for me. I used a (simple, but ugly, and large) regular expression to locate all the words for me. The expression is as follows:

``````(?<Value>(?:zero)|(?:one|first)|(?:two|second)|(?:three|third)|(?:four|fourth)|
(?:five|fifth)|(?:six|sixth)|(?:seven|seventh)|(?:eight|eighth)|(?:nine|ninth)|
(?:ten|tenth)|(?:eleven|eleventh)|(?:twelve|twelfth)|(?:thirteen|thirteenth)|
(?:fourteen|fourteenth)|(?:fifteen|fifteenth)|(?:sixteen|sixteenth)|
(?:seventeen|seventeenth)|(?:eighteen|eighteenth)|(?:nineteen|nineteenth)|
(?:twenty|twentieth)|(?:thirty|thirtieth)|(?:forty|fortieth)|(?:fifty|fiftieth)|
(?:sixty|sixtieth)|(?:seventy|seventieth)|(?:eighty|eightieth)|(?:ninety|ninetieth)|
(?<Magnitude>(?:hundred|hundredth)|(?:thousand|thousandth)|(?:million|millionth)|
(?:billion|billionth)))
``````

Shown here with line breaks for formatting purposes..

Anyways, my method was to execute this RegEx with a library like PCRE, and then read back the named matches. And it worked on all of the different examples listed in this question, minus the "One Half", types, as I didn't add them in, but as you can see, it wouldn't be hard to do so. This addresses a lot of issues. For example, it addresses the following items in the original question and other answers:

1. cardinal/nominal or ordinal: "one" and "first"
2. common spelling mistakes: "forty"/"fourty" (Note that it does not EXPLICITLY address this, that would be something you'd want to do before you passed the string to this parser. This parser sees this example as "FOUR"...)
3. hundreds/thousands: 2100 -> "twenty one hundred" and also "two thousand and one hundred"
4. separators: "eleven hundred fifty two", but also "elevenhundred fiftytwo" or "eleven-hundred fifty-two" and whatnot
5. colloqialisms: "thirty-something" (This also is not TOTALLY addressed, as what IS "something"? Well, this code finds this number as simply "30").**

Now, rather than store this monster of a regular expression in your source, I was considering building this RegEx at runtime, using something like the following:

``````char *ones[] = {"zero", "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve",
"thirteen", "fourteen", "fifteen", "sixteen", "seventeen", "eighteen", "nineteen"};
char *tens[] = {"", "", "twenty", "thirty", "forty", "fifty", "sixty", "seventy", "eighty", "ninety"};
char *ordinalones[] = { "", "first", "second", "third", "fourth", "fifth", "", "", "", "", "", "", "twelfth" };
char *ordinaltens[] = { "", "", "twentieth", "thirtieth", "fortieth", "fiftieth", "sixtieth", "seventieth", "eightieth", "ninetieth" };
and so on...
``````

The easy part here is we are only storing the words that matter. In the case of SIXTH, you'll notice that there isn't an entry for it, because it's just it's normal number with TH tacked on... But ones like TWELVE need different attention.

Ok, so now we have the code to build our (ugly) RegEx, now we just execute it on our number strings.

One thing I would recommend, is to filter, or eat the word "AND". It's not necessary, and only leads to other issues.

So, what you are going to want to do is setup a function that passes the named matches for "Magnitude" into a function that looks at all the possible magnitude values, and multiplies your current result by that value of magnitude. Then, you create a function that looks at the "Value" named matches, and returns an int (or whatever you are using), based on the value discovered there.

All VALUE matches are ADDED to your result, while magnitutde matches multiply the result by the mag value. So, Two Hundred Fifty Thousand becomes "2", then "2 * 100", then "200 + 50", then "250 * 1000", ending up with 250000...

Just for fun, I wrote a vbScript version of this and it worked great with all the examples provided. Now, it doesn't support named matches, so I had to work a little harder getting the correct result, but I got it. Bottom line is, if it's a "VALUE" match, add it your accumulator. If it's a magnitude match, multiply your accumulator by 100, 1000, 1000000, 1000000000, etc... This will provide you with some pretty amazing results, and all you have to do to adjust for things like "one half" is add them to your RegEx, put in a code marker for them, and handle them.

Well, I hope this post helps SOMEONE out there. If anyone want, I can post by vbScript pseudo code that I used to test this with, however, it's not pretty code, and NOT production code.

If I may.. What is the final language this will be written in? C++, or something like a scripted language? Greg Hewgill's source will go a long way in helping understand how all of this comes together.

Let me know if I can be of any other help. Sorry, I only know English/American, so I can't help you with the other languages.

I was converting ordinal edition statements from early modern books (e.g. "2nd edition", "Editio quarta") to integers and needed support for ordinals 1-100 in English and ordinals 1-10 in a few Romance languages. Here's what I came up with in Python:

``````def get_data_mapping():
data_mapping = {
"1st": 1,
"2nd": 2,
"3rd": 3,

"tenth": 10,
"eleventh": 11,
"twelfth": 12,
"thirteenth": 13,
"fourteenth": 14,
"fifteenth": 15,
"sixteenth": 16,
"seventeenth": 17,
"eighteenth": 18,
"nineteenth": 19,
"twentieth": 20,

"new": 2,
"newly": 2,
"nova": 2,
"nouvelle": 2,
"altera": 2,
"andere": 2,

# latin
"primus": 1,
"secunda": 2,
"tertia": 3,
"quarta": 4,
"quinta": 5,
"sexta": 6,
"septima": 7,
"octava": 8,
"nona": 9,
"decima": 10,

# italian
"primo": 1,
"secondo": 2,
"terzo": 3,
"quarto": 4,
"quinto": 5,
"sesto": 6,
"settimo": 7,
"ottavo": 8,
"nono": 9,
"decimo": 10,

# french
"premier": 1,
"deuxième": 2,
"troisième": 3,
"quatrième": 4,
"cinquième": 5,
"sixième": 6,
"septième": 7,
"huitième": 8,
"neuvième": 9,
"dixième": 10,

# spanish
"primero": 1,
"segundo": 2,
"tercero": 3,
"cuarto": 4,
"quinto": 5,
"sexto": 6,
"septimo": 7,
"octavo": 8,
"noveno": 9,
"decimo": 10
}

# create 4th, 5th, ... 20th
for i in xrange(16):
data_mapping[str(4+i) + "th"] = 4+i

# create 21st, 22nd, ... 99th
for i in xrange(79):
last_char = str(i)[-1]

if last_char == "0":
data_mapping[str(20+i) + "th"] = 20+i

elif last_char == "1":
data_mapping[str(20+i) + "st"] = 20+i

elif last_char == "2":
data_mapping[str(20+i) + "nd"] = 20+i

elif last_char == "3":
data_mapping[str(20+i) + "rd"] = 20+i

else:
data_mapping[str(20+i) + "th"] = 20+i

ordinals = [
"first", "second", "third",
"fourth", "fifth", "sixth",
"seventh", "eighth", "ninth"
]

# create first, second ... ninth
for c, i in enumerate(ordinals):
data_mapping[i] = c+1

# create twenty-first, twenty-second ... ninty-ninth
for ci, i in enumerate([
"twenty", "thirty", "forty",
"fifty", "sixty", "seventy",
"eighty", "ninety"
]):
for cj, j in enumerate(ordinals):
data_mapping[i + "-" + j] = 20 + (ci*10) + (cj+1)
data_mapping[i.replace("y", "ieth")] = 20 + (ci*10)

return data_mapping
``````

One place to start looking is the gnu get_date lib, which can parse just about any English textual date into a timestamp. While not exactly what you're looking for, their solution to a similar problem could provide a lot of useful clues.

Try

1. Open an HTTP Request to "http://www.google.com/search?q=" + number + "+in+decimal".

2. Parse the result for your number.

3. Cache the number / result pairs to lesson the requests over time.