Humanizer meets all your .NET needs for manipulating and displaying strings, enums, dates, times, timespans, numbers and quantities.
You can install Humanizer as a nuget package:
English only: Humanizer.Core
All languages: Humanizer
The following frameworks are supported: net4.8, net6, net7, and net8
Note: The nuget also targets netstandard2. This is to enable scenario where netstandard2 is required. For example Roslyn Analyzers or MSBuil tasks. Other frameworks (other than listed above) that can consume netstandard2 (example net4.6.1 through to net 4.7.2) are not supported. For example net4.6.1 through to net4.7.2 are not supported.
Also Humanizer symbols are source indexed with SourceLink and are included in the package so you can step through Humanizer code while debugging your code.
You choose which packages based on what NuGet package(s) you install. By default, the main Humanizer
2.0 package installs all supported languages exactly like it does in 1.x. If you're not sure, then just use the main Humanizer
package.
Here are the options:
- All languages: use the main
Humanizer
package. This pulls inHumanizer.Core
and all language packages. - English: use the
Humanizer.Core
package. Only the English language resources will be available - Specific languages: Use the language specific packages you'd like. For example for French, use
Humanizer.Core.fr
. You can include multiple languages by installing however many language packages you want.
The detailed explanation for how this works is in the comments here.
Humanize
string extensions allow you turn an otherwise computerized string into a more readable human-friendly one.
The foundation of this was set in the BDDfy framework where class names, method names and properties are turned into human readable sentences.
"PascalCaseInputStringIsTurnedIntoSentence".Humanize() => "Pascal case input string is turned into sentence"
"Underscored_input_string_is_turned_into_sentence".Humanize() => "Underscored input string is turned into sentence"
"Underscored_input_String_is_turned_INTO_sentence".Humanize() => "Underscored input String is turned INTO sentence"
Note that a string that contains only upper case letters, and consists only of one word, is always treated as an acronym (regardless of its length). To guarantee that any arbitrary string will always be humanized you must use a transform (see Transform
method below):
// acronyms are left intact
"HTML".Humanize() => "HTML"
// any unbroken upper case string is treated as an acronym
"HUMANIZER".Humanize() => "HUMANIZER"
"HUMANIZER".Transform(To.LowerCase, To.TitleCase) => "Humanizer"
You may also specify the desired letter casing:
"CanReturnTitleCase".Humanize(LetterCasing.Title) => "Can Return Title Case"
"Can_return_title_Case".Humanize(LetterCasing.Title) => "Can Return Title Case"
"CanReturnLowerCase".Humanize(LetterCasing.LowerCase) => "can return lower case"
"CanHumanizeIntoUpperCase".Humanize(LetterCasing.AllCaps) => "CAN HUMANIZE INTO UPPER CASE"
The
LetterCasing
API and the methods accepting it are legacy from V0.2 era and will be deprecated in the future. Instead of that, you can useTransform
method explained below.
Much like you can humanize a computer friendly into human friendly string you can dehumanize a human friendly string into a computer friendly one:
"Pascal case input string is turned into sentence".Dehumanize() => "PascalCaseInputStringIsTurnedIntoSentence"
There is a Transform
method that supersedes LetterCasing
, ApplyCase
and Humanize
overloads that accept LetterCasing
.
Transform method signature is as follows:
string Transform(this string input, params IStringTransformer[] transformers)
And there are some out of the box implementations of IStringTransformer
for letter casing:
"Sentence casing".Transform(To.LowerCase) => "sentence casing"
"Sentence casing".Transform(To.SentenceCase) => "Sentence casing"
"Sentence casing".Transform(To.TitleCase) => "Sentence Casing"
"Sentence casing".Transform(To.UpperCase) => "SENTENCE CASING"
LowerCase
is a public static property on To
class that returns an instance of private ToLowerCase
class that implements IStringTransformer
and knows how to turn a string into lower case.
The benefit of using Transform
and IStringTransformer
over ApplyCase
and LetterCasing
is that LetterCasing
is an enum and you're limited to use what's in the framework
while IStringTransformer
is an interface you can implement in your codebase once and use it with Transform
method allowing for easy extension.
You can truncate a string
using the Truncate
method:
"Long text to truncate".Truncate(10) => "Long textβ¦"
By default the 'β¦'
character is used to truncate strings. The advantage of using the 'β¦'
character instead of "..."
is that the former only takes a single character and thus allows more text to be shown before truncation. If you want, you can also provide your own truncation string:
"Long text to truncate".Truncate(10, "---") => "Long te---"
The default truncation strategy, Truncator.FixedLength
, is to truncate the input string to a specific length, including the truncation string length.
There are two more truncator strategies available: one for a fixed number of (alpha-numerical) characters and one for a fixed number of words.
To use a specific truncator when truncating, the two Truncate
methods shown in the previous examples all have an overload that allow you to specify the ITruncator
instance to use for the truncation.
Here are examples on how to use the three provided truncators:
"Long text to truncate".Truncate(10, Truncator.FixedLength) => "Long textβ¦"
"Long text to truncate".Truncate(10, "---", Truncator.FixedLength) => "Long te---"
"Long text to truncate".Truncate(6, Truncator.FixedNumberOfCharacters) => "Long tβ¦"
"Long text to truncate".Truncate(6, "---", Truncator.FixedNumberOfCharacters) => "Lon---"
"Long text to truncate".Truncate(2, Truncator.FixedNumberOfWords) => "Long textβ¦"
"Long text to truncate".Truncate(2, "---", Truncator.FixedNumberOfWords) => "Long text---"
Note that you can also use create your own truncator by implementing the ITruncator
interface.
There is also an option to choose whether to truncate the string from the beginning (TruncateFrom.Left
) or the end (TruncateFrom.Right
).
Default is the right as shown in the examples above. The examples below show how to truncate from the beginning of the string:
"Long text to truncate".Truncate(10, Truncator.FixedLength, TruncateFrom.Left) => "β¦ truncate"
"Long text to truncate".Truncate(10, "---", Truncator.FixedLength, TruncateFrom.Left) => "---runcate"
"Long text to truncate".Truncate(10, Truncator.FixedNumberOfCharacters, TruncateFrom.Left) => "β¦o truncate"
"Long text to truncate".Truncate(16, "---", Truncator.FixedNumberOfCharacters, TruncateFrom.Left) => "---ext to truncate"
"Long text to truncate".Truncate(2, Truncator.FixedNumberOfWords, TruncateFrom.Left) => "β¦to truncate"
"Long text to truncate".Truncate(2, "---", Truncator.FixedNumberOfWords, TruncateFrom.Left) => "---to truncate"
Calling ToString
directly on enum members usually results in less than ideal output for users. The solution to this is usually to use DescriptionAttribute
data annotation and then read that at runtime to get a more friendly output. That is a great solution; but more often than not we only need to put some space between words of an enum member - which is what String.Humanize()
does well. For an enum like:
public enum EnumUnderTest
{
[Description("Custom description")]
MemberWithDescriptionAttribute,
MemberWithoutDescriptionAttribute,
ALLCAPITALS
}
You will get:
// DescriptionAttribute is honored
EnumUnderTest.MemberWithDescriptionAttribute.Humanize() => "Custom description"
// In the absence of Description attribute string.Humanizer kicks in
EnumUnderTest.MemberWithoutDescriptionAttribute.Humanize() => "Member without description attribute"
// Of course you can still apply letter casing
EnumUnderTest.MemberWithoutDescriptionAttribute.Humanize().Transform(To.TitleCase) => "Member Without Description Attribute"
You are not limited to DescriptionAttribute
for custom description. Any attribute applied on enum members with a string Description
property counts.
This is to help with platforms with missing DescriptionAttribute
and also for allowing subclasses of the DescriptionAttribute
.
You can even configure the name of the property of attibute to use as description.
Configurator.EnumDescriptionPropertyLocator = p => p.Name == "Info"
If you need to provide localised descriptions you can use DisplayAttribute
data annotation instead.
public enum EnumUnderTest
{
[Display(Description = "EnumUnderTest_Member", ResourceType = typeof(Project.Resources))]
Member
}
You will get:
EnumUnderTest.Member.Humanize() => "content" // from Project.Resources found under "EnumUnderTest_Member" resource key
Hopefully this will help avoid littering enums with unnecessary attributes!
Dehumanizes a string into the Enum it was originally Humanized from! The API looks like:
public static TTargetEnum DehumanizeTo<TTargetEnum>(this string input)
And the usage is:
"Member without description attribute".DehumanizeTo<EnumUnderTest>() => EnumUnderTest.MemberWithoutDescriptionAttribute
And just like the Humanize API it honors the Description
attribute. You don't have to provide the casing you provided during humanization: it figures it out.
There is also a non-generic counterpart for when the original Enum is not known at compile time:
public static Enum DehumanizeTo(this string input, Type targetEnum, NoMatch onNoMatch = NoMatch.ThrowsException)
which can be used like:
"Member without description attribute".DehumanizeTo(typeof(EnumUnderTest)) => EnumUnderTest.MemberWithoutDescriptionAttribute
By default both methods throw a NoMatchFoundException
when they cannot match the provided input against the target enum.
In the non-generic method you can also ask the method to return null by setting the second optional parameter to NoMatch.ReturnsNull
.
You can Humanize
an instance of DateTime
or DateTimeOffset
and get back a string telling how far back or forward in time that is:
DateTime.UtcNow.AddHours(-30).Humanize() => "yesterday"
DateTime.UtcNow.AddHours(-2).Humanize() => "2 hours ago"
DateTime.UtcNow.AddHours(30).Humanize() => "tomorrow"
DateTime.UtcNow.AddHours(2).Humanize() => "2 hours from now"
DateTimeOffset.UtcNow.AddHours(1).Humanize() => "an hour from now"
Humanizer supports both local and UTC dates as well as dates with offset (DateTimeOffset
). You could also provide the date you want the input date to be compared against. If null, it will use the current date as comparison base.
Also, culture to use can be specified explicitly. If it is not, current thread's current UI culture is used.
Here is the API signature:
public static string Humanize(this DateTime input, bool utcDate = true, DateTime? dateToCompareAgainst = null, CultureInfo culture = null)
public static string Humanize(this DateTimeOffset input, DateTimeOffset? dateToCompareAgainst = null, CultureInfo culture = null)
Many localizations are available for this method. Here is a few examples:
// In ar culture
DateTime.UtcNow.AddDays(-1).Humanize() => "Ψ£Ω
Ψ³"
DateTime.UtcNow.AddDays(-2).Humanize() => "Ω
ΩΨ° ΩΩΩ
ΩΩ"
DateTime.UtcNow.AddDays(-3).Humanize() => "Ω
ΩΨ° 3 Ψ£ΩΨ§Ω
"
DateTime.UtcNow.AddDays(-11).Humanize() => "Ω
ΩΨ° 11 ΩΩΩ
"
// In ru-RU culture
DateTime.UtcNow.AddMinutes(-1).Humanize() => "ΠΌΠΈΠ½ΡΡΡ Π½Π°Π·Π°Π΄"
DateTime.UtcNow.AddMinutes(-2).Humanize() => "2 ΠΌΠΈΠ½ΡΡΡ Π½Π°Π·Π°Π΄"
DateTime.UtcNow.AddMinutes(-10).Humanize() => "10 ΠΌΠΈΠ½ΡΡ Π½Π°Π·Π°Π΄"
DateTime.UtcNow.AddMinutes(-21).Humanize() => "21 ΠΌΠΈΠ½ΡΡΡ Π½Π°Π·Π°Π΄"
DateTime.UtcNow.AddMinutes(-22).Humanize() => "22 ΠΌΠΈΠ½ΡΡΡ Π½Π°Π·Π°Π΄"
DateTime.UtcNow.AddMinutes(-40).Humanize() => "40 ΠΌΠΈΠ½ΡΡ Π½Π°Π·Π°Π΄"
There are two strategies for DateTime.Humanize
: the default one as seen above and a precision based one.
To use the precision based strategy you need to configure it:
Configurator.DateTimeHumanizeStrategy = new PrecisionDateTimeHumanizeStrategy(precision: .75);
Configurator.DateTimeOffsetHumanizeStrategy = new PrecisionDateTimeOffsetHumanizeStrategy(precision: .75); // configure when humanizing DateTimeOffset
The default precision is set to .75 but you can pass your desired precision too. With precision set to 0.75:
44 seconds => 44 seconds ago/from now
45 seconds => one minute ago/from now
104 seconds => one minute ago/from now
105 seconds => two minutes ago/from now
25 days => a month ago/from now
No dehumanization for dates as Humanize
is a lossy transformation and the human friendly date is not reversible
You can call Humanize
on a TimeSpan
to a get human friendly representation for it:
TimeSpan.FromMilliseconds(1).Humanize() => "1 millisecond"
TimeSpan.FromMilliseconds(2).Humanize() => "2 milliseconds"
TimeSpan.FromDays(1).Humanize() => "1 day"
TimeSpan.FromDays(16).Humanize() => "2 weeks"
There is an optional precision
parameter for TimeSpan.Humanize
which allows you to specify the precision of the returned value.
The default value of precision
is 1 which means only the largest time unit is returned like you saw in TimeSpan.FromDays(16).Humanize()
.
Here is a few examples of specifying precision:
TimeSpan.FromDays(1).Humanize(precision:2) => "1 day" // no difference when there is only one unit in the provided TimeSpan
TimeSpan.FromDays(16).Humanize(2) => "2 weeks, 2 days"
// the same TimeSpan value with different precision returns different results
TimeSpan.FromMilliseconds(1299630020).Humanize() => "2 weeks"
TimeSpan.FromMilliseconds(1299630020).Humanize(3) => "2 weeks, 1 day, 1 hour"
TimeSpan.FromMilliseconds(1299630020).Humanize(4) => "2 weeks, 1 day, 1 hour, 30 seconds"
TimeSpan.FromMilliseconds(1299630020).Humanize(5) => "2 weeks, 1 day, 1 hour, 30 seconds, 20 milliseconds"
By default when using precision
parameter empty time units are not counted towards the precision of the returned value.
If this behavior isn't desired for you, you can use the overloaded TimeSpan.Humanize
method with countEmptyUnits
parameter. Leading empty time units never count.
Here is an example showing the difference of counting empty units:
TimeSpan.FromMilliseconds(3603001).Humanize(3) => "1 hour, 3 seconds, 1 millisecond"
TimeSpan.FromMilliseconds(3603001).Humanize(3, countEmptyUnits:true) => "1 hour, 3 seconds"
Many localizations are available for this method:
// in de-DE culture
TimeSpan.FromDays(1).Humanize() => "Ein Tag"
TimeSpan.FromDays(2).Humanize() => "2 Tage"
// in sk-SK culture
TimeSpan.FromMilliseconds(1).Humanize() => "1 milisekunda"
TimeSpan.FromMilliseconds(2).Humanize() => "2 milisekundy"
TimeSpan.FromMilliseconds(5).Humanize() => "5 milisekΓΊnd"
Culture to use can be specified explicitly. If it is not, current thread's current UI culture is used. Example:
TimeSpan.FromDays(1).Humanize(culture: "ru-RU") => "ΠΎΠ΄ΠΈΠ½ Π΄Π΅Π½Ρ"
In addition, a minimum unit of time may be specified to avoid rolling down to a smaller unit. For example:
TimeSpan.FromMilliseconds(122500).Humanize(minUnit: TimeUnit.Second) => "2 minutes, 2 seconds" // instead of 2 minutes, 2 seconds, 500 milliseconds
TimeSpan.FromHours(25).Humanize(minUnit: TimeUnit.Day) => "1 Day" //instead of 1 Day, 1 Hour
In addition, a maximum unit of time may be specified to avoid rolling up to the next largest unit. For example:
TimeSpan.FromDays(7).Humanize(maxUnit: TimeUnit.Day) => "7 days" // instead of 1 week
TimeSpan.FromMilliseconds(2000).Humanize(maxUnit: TimeUnit.Millisecond) => "2000 milliseconds" // instead of 2 seconds
The default maxUnit is TimeUnit.Week
because it gives exact results. You can increase this value to TimeUnit.Month
or TimeUnit.Year
which will give you an approximation based on 365.2425 days a year and 30.436875 days a month. Therefore the months are alternating between 30 and 31 days in length and every fourth year is 366 days long.
TimeSpan.FromDays(486).Humanize(maxUnit: TimeUnit.Year, precision: 7) => "1 year, 3 months, 29 days" // One day further is 1 year, 4 month
TimeSpan.FromDays(517).Humanize(maxUnit: TimeUnit.Year, precision: 7) => "1 year, 4 months, 30 days" // This month has 30 days and one day further is 1 year, 5 months
When there are multiple time units, they are combined using the ", "
string:
TimeSpan.FromMilliseconds(1299630020).Humanize(3) => "2 weeks, 1 day, 1 hour"
When TimeSpan
is zero, the default behavior will return "0" plus whatever the minimum time unit is. However, if you assign true
to toWords
when calling Humanize
, then the method returns "no time". For example:
TimeSpan.Zero.Humanize(1) => "0 milliseconds"
TimeSpan.Zero.Humanize(1, toWords: true) => "no time"
TimeSpan.Zero.Humanize(1, minUnit: Humanizer.Localisation.TimeUnit.Second) => "0 seconds"
Using the collectionSeparator
parameter, you can specify your own separator string:
TimeSpan.FromMilliseconds(1299630020).Humanize(3, collectionSeparator: " - ") => "2 weeks - 1 day - 1 hour"
It is also possible to use the current culture's collection formatter to combine the time units. To do so, specify null
as the collectionSeparator
parameter:
// in en-US culture
TimeSpan.FromMilliseconds(1299630020).Humanize(3, collectionSeparator: null) => "2 weeks, 1 day, and 1 hour"
// in de-DE culture
TimeSpan.FromMilliseconds(1299630020).Humanize(3, collectionSeparator: null) => "2 Wochen, Ein Tag und Eine Stunde"
If words are preferred to numbers, a toWords: true
parameter can be set to convert the numbers in a humanized TimeSpan to words:
TimeSpan.FromMilliseconds(1299630020).Humanize(3, toWords: true) => "two weeks, one day, one hour"
By calling ToAge
, a TimeSpan
can also be expressed as an age.
For cultures that do not define an age expression, the result will be the same as calling Humanize
(but with a default maxUnit
equal to TimeUnit.Year
).
// in en-US culture
TimeSpan.FromDays(750).ToAge() => "2 years old"
// in fr culture
TimeSpan.FromDays(750).ToAge() => "2 ans"
You can call Humanize
on any IEnumerable
to get a nicely formatted string representing the objects in the collection. By default ToString()
will be called on each item to get its representation but a formatting function may be passed to Humanize
instead. Additionally, a default separator is provided ("and" in English), but a different separator may be passed into Humanize
.
For instance:
class SomeClass
{
public string SomeString;
public int SomeInt;
public override string ToString()
{
return "Specific String";
}
}
string FormatSomeClass(SomeClass sc)
{
return string.Format("SomeObject #{0} - {1}", sc.SomeInt, sc.SomeString);
}
var collection = new List<SomeClass>
{
new SomeClass { SomeInt = 1, SomeString = "One" },
new SomeClass { SomeInt = 2, SomeString = "Two" },
new SomeClass { SomeInt = 3, SomeString = "Three" }
};
collection.Humanize() // "Specific String, Specific String, and Specific String"
collection.Humanize("or") // "Specific String, Specific String, or Specific String"
collection.Humanize(FormatSomeClass) // "SomeObject #1 - One, SomeObject #2 - Two, and SomeObject #3 - Three"
collection.Humanize(sc => sc.SomeInt.Ordinalize(), "or") // "1st, 2nd, or 3rd"
Items are trimmed and blank (NullOrWhitespace) items are skipped. This results in clean comma punctuation. (If there is a custom formatter function, this applies only to the formatter's output.)
You can provide your own collection formatter by implementing ICollectionFormatter
and registering it with Configurator.CollectionFormatters
.
There are also a few inflector methods:
Pluralize
pluralizes the provided input while taking irregular and uncountable words into consideration:
"Man".Pluralize() => "Men"
"string".Pluralize() => "strings"
Normally you would call Pluralize
on a singular word but if you're unsure about the singularity of the word you can call the method with the optional inputIsKnownToBeSingular
argument:
"Men".Pluralize(inputIsKnownToBeSingular: false) => "Men"
"Man".Pluralize(inputIsKnownToBeSingular: false) => "Men"
"string".Pluralize(inputIsKnownToBeSingular: false) => "strings"
The overload of Pluralize
with plurality
argument is obsolete and was removed in version 2.0.
Singularize
singularizes the provided input while taking irregular and uncountable words into consideration:
"Men".Singularize() => "Man"
"strings".Singularize() => "string"
Normally you would call Singularize
on a plural word but if you're unsure about the plurality of the word you can call the method with the optional inputIsKnownToBePlural
argument:
"Men".Singularize(inputIsKnownToBePlural: false) => "Man"
"Man".Singularize(inputIsKnownToBePlural: false) => "Man"
"strings".Singularize(inputIsKnownToBePlural: false) => "string"
The overload of Singularize
with plurality
argument is obsolete and was removed in version 2.0.
Sometimes, you may need to add a rule from the singularization/pluralization vocabulary (the examples below are already in the DefaultVocabulary
used by Inflector
):
// Adds a word to the vocabulary which cannot easily be pluralized/singularized by RegEx.
// Will match both "salesperson" and "person".
Vocabularies.Default.AddIrregular("person", "people");
// To only match "person" and not "salesperson" you would pass false for the 'matchEnding' parameter.
Vocabularies.Default.AddIrregular("person", "people", matchEnding: false);
// Adds an uncountable word to the vocabulary. Will be ignored when plurality is changed:
Vocabularies.Default.AddUncountable("fish");
// Adds a rule to the vocabulary that does not follow trivial rules for pluralization:
Vocabularies.Default.AddPlural("bus", "buses");
// Adds a rule to the vocabulary that does not follow trivial rules for singularization
// (will match both "vertices" -> "vertex" and "indices" -> "index"):
Vocabularies.Default.AddSingular("(vert|ind)ices$", "$1ex");
Many times you want to call Singularize
and Pluralize
to prefix a word with a number; e.g. "2 requests", "3 men". ToQuantity
prefixes the provided word with the number and accordingly pluralizes or singularizes the word:
"case".ToQuantity(0) => "0 cases"
"case".ToQuantity(1) => "1 case"
"case".ToQuantity(5) => "5 cases"
"man".ToQuantity(0) => "0 men"
"man".ToQuantity(1) => "1 man"
"man".ToQuantity(2) => "2 men"
ToQuantity
can figure out whether the input word is singular or plural and will singularize or pluralize as necessary:
"men".ToQuantity(2) => "2 men"
"process".ToQuantity(2) => "2 processes"
"process".ToQuantity(1) => "1 process"
"processes".ToQuantity(2) => "2 processes"
"processes".ToQuantity(1) => "1 process"
You can also pass a second argument, ShowQuantityAs
, to ToQuantity
to specify how you want the provided quantity to be outputted. The default value is ShowQuantityAs.Numeric
which is what we saw above. The other two values are ShowQuantityAs.Words
and ShowQuantityAs.None
.
"case".ToQuantity(5, ShowQuantityAs.Words) => "five cases"
"case".ToQuantity(5, ShowQuantityAs.None) => "cases"
There is also an overload that allows you to format the number. You can pass in the format and the culture to be used.
"dollar".ToQuantity(2, "C0", new CultureInfo("en-US")) => "$2 dollars"
"dollar".ToQuantity(2, "C2", new CultureInfo("en-US")) => "$2.00 dollars"
"cases".ToQuantity(12000, "N0") => "12,000 cases"
Ordinalize
turns a number into an ordinal string used to denote the position in an ordered sequence such as 1st, 2nd, 3rd, 4th:
1.Ordinalize() => "1st"
5.Ordinalize() => "5th"
You can also call Ordinalize
on a numeric string and achieve the same result: "21".Ordinalize()
=> "21st"
Ordinalize
also supports grammatical gender for both forms.
You can pass an argument to Ordinalize
to specify which gender the number should be outputted in.
The possible values are GrammaticalGender.Masculine
, GrammaticalGender.Feminine
and GrammaticalGender.Neuter
:
// for Brazilian Portuguese locale
1.Ordinalize(GrammaticalGender.Masculine) => "1ΒΊ"
1.Ordinalize(GrammaticalGender.Feminine) => "1Βͺ"
1.Ordinalize(GrammaticalGender.Neuter) => "1ΒΊ"
"2".Ordinalize(GrammaticalGender.Masculine) => "2ΒΊ"
"2".Ordinalize(GrammaticalGender.Feminine) => "2Βͺ"
"2".Ordinalize(GrammaticalGender.Neuter) => "2ΒΊ"
Obviously this only applies to some cultures. For others passing gender in or not passing at all doesn't make any difference in the result.
In addition, Ordinalize
supports variations some cultures apply depending on the position of the ordinalized number in a sentence.
Use the argument wordForm
to get one result or another. Possible values are WordForm.Abbreviation
and WordForm.Normal
.
You can combine wordForm
argument with gender but passing this argument in when it is not applicable will not make any difference in the result.
// Spanish locale
1.Ordinalize(WordForm.Abbreviation) => "1.er" // As in "Vivo en el 1.er piso"
1.Ordinalize(WordForm.Normal) => "1.ΒΊ" // As in "He llegado el 1ΒΊ"
"3".Ordinalize(GrammaticalGender.Feminine, WordForm.Abbreviation) => "3.Βͺ"
"3".Ordinalize(GrammaticalGender.Feminine, WordForm.Normal) => "3.Βͺ"
"3".Ordinalize(GrammaticalGender.Masculine, WordForm.Abbreviation) => "3.er"
"3".Ordinalize(GrammaticalGender.Masculine, WordForm.Normal) => "3.ΒΊ"
Titleize
converts the input words to Title casing; equivalent to "some title".Humanize(LetterCasing.Title)
Pascalize
converts the input words to UpperCamelCase, also removing underscores and spaces:
"some_title for something".Pascalize() => "SomeTitleForSomething"
Camelize
behaves identically to Pascalize
, except that the first character is lower case:
"some_title for something".Camelize() => "someTitleForSomething"
Underscore
separates the input words with underscore:
"SomeTitle".Underscore() => "some_title"
Dasherize
and Hyphenate
replace underscores with dashes in the string:
"some_title".Dasherize() => "some-title"
"some_title".Hyphenate() => "some-title"
Kebaberize
separates the input words with hyphens and all words are converted to lowercase
"SomeText".Kebaberize() => "some-text"
Humanizer provides a fluent API to deal with DateTime
and TimeSpan
as follows:
TimeSpan
methods:
2.Milliseconds() => TimeSpan.FromMilliseconds(2)
2.Seconds() => TimeSpan.FromSeconds(2)
2.Minutes() => TimeSpan.FromMinutes(2)
2.Hours() => TimeSpan.FromHours(2)
2.Days() => TimeSpan.FromDays(2)
2.Weeks() => TimeSpan.FromDays(14)
There are no fluent APIs for month or year as a month could have between 28 to 31 days and a year could be 365 or 366 days.
You could use these methods to, for example, replace
DateTime.Now.AddDays(2).AddHours(3).AddMinutes(-5)
with
DateTime.Now + 2.Days() + 3.Hours() - 5.Minutes()
There are also three categories of fluent methods to deal with DateTime
:
In.TheYear(2010) // Returns the first of January of 2010
In.January // Returns 1st of January of the current year
In.FebruaryOf(2009) // Returns 1st of February of 2009
In.One.Second // DateTime.UtcNow.AddSeconds(1);
In.Two.SecondsFrom(DateTime dateTime)
In.Three.Minutes // With corresponding From method
In.Three.Hours // With corresponding From method
In.Three.Days // With corresponding From method
In.Three.Weeks // With corresponding From method
In.Three.Months // With corresponding From method
In.Three.Years // With corresponding From method
On.January.The4th // Returns 4th of January of the current year
On.February.The(12) // Returns 12th of Feb of the current year
and some extension methods:
var someDateTime = new DateTime(2011, 2, 10, 5, 25, 45, 125);
// Returns new DateTime(2008, 2, 10, 5, 25, 45, 125) changing the year to 2008
someDateTime.In(2008)
// Returns new DateTime(2011, 2, 10, 2, 25, 45, 125) changing the hour to 2:25:45.125
someDateTime.At(2)
// Returns new DateTime(2011, 2, 10, 2, 20, 15, 125) changing the time to 2:20:15.125
someDateTime.At(2, 20, 15)
// Returns new DateTime(2011, 2, 10, 12, 0, 0) changing the time to 12:00:00.000
someDateTime.AtNoon()
// Returns new DateTime(2011, 2, 10, 0, 0, 0) changing the time to 00:00:00.000
someDateTime.AtMidnight()
Obviously you could chain the methods too; e.g. On.November.The13th.In(2010).AtNoon + 5.Minutes()
Humanizer provides a fluent API that produces (usually big) numbers in a clearer fashion:
1.25.Billions() => 1250000000
3.Hundreds().Thousands() => 300000
Humanizer can change numbers to words using the ToWords
extension:
1.ToWords() => "one"
10.ToWords() => "ten"
11.ToWords() => "eleven"
122.ToWords() => "one hundred and twenty-two"
3501.ToWords() => "three thousand five hundred and one"
You can also pass a second argument, GrammaticalGender
, to ToWords
to specify which gender the number should be outputted in.
The possible values are GrammaticalGender.Masculine
, GrammaticalGender.Feminine
and GrammaticalGender.Neuter
:
// for Russian locale
1.ToWords(GrammaticalGender.Masculine) => "ΠΎΠ΄ΠΈΠ½"
1.ToWords(GrammaticalGender.Feminine) => "ΠΎΠ΄Π½Π°"
1.ToWords(GrammaticalGender.Neuter) => "ΠΎΠ΄Π½ΠΎ"
// for Arabic locale
1.ToWords(GrammaticalGender.Masculine) => "ΩΨ§ΨΨ―"
1.ToWords(GrammaticalGender.Feminine) => "ΩΨ§ΨΨ―Ψ©"
1.ToWords(GrammaticalGender.Neuter) => "ΩΨ§ΨΨ―"
(-1).ToWords() => "ΩΨ§ΩΨ΅ ΩΨ§ΨΨ―"
Obviously this only applies to some cultures. For others passing gender in doesn't make any difference in the result.
Also, culture to use can be specified explicitly. If it is not, current thread's current UI culture is used. Here's an example:
11.ToWords(new CultureInfo("en")) => "eleven"
1.ToWords(GrammaticalGender.Masculine, new CultureInfo("ru")) => "ΠΎΠ΄ΠΈΠ½"
Another overload of the method allow you to pass a bool to remove the "And" that can be added before the last number:
3501.ToWords(false) => "three thousand five hundred one"
102.ToWords(false) => "one hundred two"
This method can be useful for writing checks for example.
Furthermore, ToWords
supports variations some cultures apply depending on the position of the number in a sentence.
Use the argument wordForm
to get one result or another. Possible values are WordForm.Abbreviation
and WordForm.Normal
.
This argument can be combined with the rest of the arguments presented above.
Passing wordForm
argument in when it is not applicable will not make any difference in the result.
// Spanish locale
21501.ToWords(WordForm.Abbreviation, GrammaticalGender.Masculine) => "veintiΓΊn mil quinientos un"
21501.ToWords(WordForm.Normal, GrammaticalGender.Masculine) => "veintiΓΊn mil quinientos uno"
21501.ToWords(WordForm.Abbreviation, GrammaticalGender.Feminine) => "veintiuna mil quinientas una"
// English US locale
21501.ToWords(WordForm.Abbreviation, GrammaticalGender.Masculine, new CultureInfo("en-US")) => "twenty-one thousand five hundred and one"
This is kind of mixing ToWords
with Ordinalize
. You can call ToOrdinalWords
on a number to get an ordinal representation of the number in words! For example:
0.ToOrdinalWords() => "zeroth"
1.ToOrdinalWords() => "first"
2.ToOrdinalWords() => "second"
8.ToOrdinalWords() => "eighth"
10.ToOrdinalWords() => "tenth"
11.ToOrdinalWords() => "eleventh"
12.ToOrdinalWords() => "twelfth"
20.ToOrdinalWords() => "twentieth"
21.ToOrdinalWords() => "twenty first"
121.ToOrdinalWords() => "hundred and twenty first"
ToOrdinalWords
also supports grammatical gender.
You can pass a second argument to ToOrdinalWords
to specify the gender of the output.
The possible values are GrammaticalGender.Masculine
, GrammaticalGender.Feminine
and GrammaticalGender.Neuter
:
// for Brazilian Portuguese locale
1.ToOrdinalWords(GrammaticalGender.Masculine) => "primeiro"
1.ToOrdinalWords(GrammaticalGender.Feminine) => "primeira"
1.ToOrdinalWords(GrammaticalGender.Neuter) => "primeiro"
2.ToOrdinalWords(GrammaticalGender.Masculine) => "segundo"
2.ToOrdinalWords(GrammaticalGender.Feminine) => "segunda"
2.ToOrdinalWords(GrammaticalGender.Neuter) => "segundo"
// for Arabic locale
1.ToOrdinalWords(GrammaticalGender.Masculine) => "Ψ§ΩΨ£ΩΩ"
1.ToOrdinalWords(GrammaticalGender.Feminine) => "Ψ§ΩΨ£ΩΩΩ"
1.ToOrdinalWords(GrammaticalGender.Neuter) => "Ψ§ΩΨ£ΩΩ"
2.ToOrdinalWords(GrammaticalGender.Masculine) => "Ψ§ΩΨ«Ψ§ΩΩ"
2.ToOrdinalWords(GrammaticalGender.Feminine) => "Ψ§ΩΨ«Ψ§ΩΩΨ©"
2.ToOrdinalWords(GrammaticalGender.Neuter) => "Ψ§ΩΨ«Ψ§ΩΩ"
Obviously this only applies to some cultures. For others passing gender in doesn't make any difference in the result.
Also, culture to use can be specified explicitly. If it is not, current thread's current UI culture is used. Here's an example:
10.ToOrdinalWords(new CultureInfo("en-US")) => "tenth"
1.ToOrdinalWords(GrammaticalGender.Masculine, new CulureInfo("pt-BR")) => "primeiro"
ToOrdinalWords
also supports variations some cultures apply depending on the position of the ordinalized number in a sentence.
Use the argument wordForm
to get one result or another. Possible values are WordForm.Abbreviation
and WordForm.Normal
.
Combine this argument with the rest of the arguments presented above.
Passing wordForm
argument in when it is not applicable will not make any difference in the result.
// Spanish locale
43.ToOrdinalWords(WordForm.Normal, GrammaticalGender.Masculine) => "cuadragΓ©simo tercero"
43.ToOrdinalWords(WordForm.Abbreviation, GrammaticalGender.Masculine) => "cuadragΓ©simo tercer"
43.ToOrdinalWords(WordForm.Abbreviation, GrammaticalGender.Feminine) => "cuadragΓ©sima tercera"
// English locale
43.ToOrdinalWords(GrammaticalGender.Masculine, WordForm.Abbreviation, new CultureInfo("en")) => "forty-third"
This is kind of an extension of Ordinalize
// for English UK locale
new DateTime(2015, 1, 1).ToOrdinalWords() => "1st January 2015"
new DateTime(2015, 2, 12).ToOrdinalWords() => "12th February 2015"
new DateTime(2015, 3, 22).ToOrdinalWords() => "22nd March 2015"
// for English US locale
new DateTime(2015, 1, 1).ToOrdinalWords() => "January 1st, 2015"
new DateTime(2015, 2, 12).ToOrdinalWords() => "February 12th, 2015"
new DateTime(2015, 3, 22).ToOrdinalWords() => "March 22nd, 2015"
ToOrdinalWords
also supports grammatical case.
You can pass a second argument to ToOrdinalWords
to specify the case of the output.
The possible values are GrammaticalCase.Nominative
, GrammaticalCase.Genitive
, GrammaticalCase.Dative
, GrammaticalCase.Accusative
, GrammaticalCase.Instrumental
and GrammaticalGender.Prepositional
:
Obviously this only applies to some cultures. For others passing case in doesn't make any difference in the result.
Extends TimeOnly to allow humanizing it to a clock notation
// for English US locale
new TimeOnly(3, 0).ToClockNotation() => "three o'clock"
new TimeOnly(12, 0).ToClockNotation() => "noon"
new TimeOnly(14, 30).ToClockNotation() => "half past two"
// for Brazilian Portuguese locale
new TimeOnly(3, 0).ToClockNotation() => "trΓͺs em ponto"
new TimeOnly(12, 0).ToClockNotation() => "meio-dia"
new TimeOnly(14, 30).ToClockNotation() => "duas e meia"
Humanizer can change numbers to Roman numerals using the ToRoman
extension. The numbers 1 to 10 can be expressed in Roman numerals as follows:
1.ToRoman() => "I"
2.ToRoman() => "II"
3.ToRoman() => "III"
4.ToRoman() => "IV"
5.ToRoman() => "V"
6.ToRoman() => "VI"
7.ToRoman() => "VII"
8.ToRoman() => "VIII"
9.ToRoman() => "IX"
10.ToRoman() => "X"
Also the reverse operation using the FromRoman
extension.
"I".FromRoman() => 1
"II".FromRoman() => 2
"III".FromRoman() => 3
"IV".FromRoman() => 4
"V".FromRoman() => 5
Note that only integers smaller than 4000 can be converted to Roman numerals.
Humanizer can change numbers to Metric numerals using the ToMetric
extension. The numbers 1, 1230 and 0.1 can be expressed in Metric numerals as follows:
1d.ToMetric() => "1"
1230d.ToMetric() => "1.23k"
0.1d.ToMetric() => "100m"
Also the reverse operation using the FromMetric
extension.
"1".FromMetric() => 1
"1.23k".FromMetric() => 1230
"100m".FromMetric() => 0.1
Humanizer includes a port of the brilliant ByteSize library.
Quite a few changes and additions are made on ByteSize
to make the interaction with ByteSize
easier and more consistent with the Humanizer API.
Here is a few examples of how you can convert from numbers to byte sizes and between size magnitudes:
var fileSize = (10).Kilobytes();
fileSize.Bits => 81920
fileSize.Bytes => 10240
fileSize.Kilobytes => 10
fileSize.Megabytes => 0.009765625
fileSize.Gigabytes => 9.53674316e-6
fileSize.Terabytes => 9.31322575e-9
There are a few extension methods that allow you to turn a number into a ByteSize instance:
3.Bits();
5.Bytes();
(10.5).Kilobytes();
(2.5).Megabytes();
(10.2).Gigabytes();
(4.7).Terabytes();
You can also add/subtract the values using +/- operators and Add/Subtract methods:
var total = (10).Gigabytes() + (512).Megabytes() - (2.5).Gigabytes();
total.Subtract((2500).Kilobytes()).Add((25).Megabytes());
A ByteSize
object contains two properties that represent the largest metric prefix symbol and value:
var maxFileSize = (10).Kilobytes();
maxFileSize.LargestWholeNumberSymbol; // "KB"
maxFileSize.LargestWholeNumberValue; // 10
If you want a string representation you can call ToString
or Humanize
interchangeably on the ByteSize
instance:
7.Bits().ToString(); // 7 b
8.Bits().ToString(); // 1 B
(.5).Kilobytes().Humanize(); // 512 B
(1000).Kilobytes().ToString(); // 1000 KB
(1024).Kilobytes().Humanize(); // 1 MB
(.5).Gigabytes().Humanize(); // 512 MB
(1024).Gigabytes().ToString(); // 1 TB
You can also optionally provide a format for the expected string representation.
The formatter can contain the symbol of the value to display: b
, B
, KB
, MB
, GB
, TB
.
The formatter uses the built in double.ToString
method with #.##
as the default format which rounds the number to two decimal places:
var b = (10.505).Kilobytes();
// Default number format is #.##
b.ToString("KB"); // 10.52 KB
b.Humanize("MB"); // .01 MB
b.Humanize("b"); // 86057 b
// Default symbol is the largest metric prefix value >= 1
b.ToString("#.#"); // 10.5 KB
// All valid values of double.ToString(string format) are acceptable
b.ToString("0.0000"); // 10.5050 KB
b.Humanize("000.00"); // 010.51 KB
// You can include number format and symbols
b.ToString("#.#### MB"); // .0103 MB
b.Humanize("0.00 GB"); // 0 GB
b.Humanize("#.## B"); // 10757.12 B
If you want a string representation with full words you can call ToFullWords
on the ByteSize
instance:
7.Bits().ToFullWords(); // 7 bits
8.Bits().ToFullWords(); // 1 byte
(.5).Kilobytes().ToFullWords(); // 512 bytes
(1000).Kilobytes().ToFullWords(); // 1000 kilobytes
(1024).Kilobytes().ToFullWords(); // 1 megabyte
(.5).Gigabytes().ToFullWords(); // 512 megabytes
(1024).Gigabytes().ToFullWords(); // 1 terabyte
There isn't a Dehumanize
method to turn a string representation back into a ByteSize
instance; but you can use Parse
and TryParse
on ByteSize
to do that.
Like other TryParse
methods, ByteSize.TryParse
returns boolean
value indicating whether or not the parsing was successful.
If the value is parsed it is output to the out
parameter supplied:
ByteSize output;
ByteSize.TryParse("1.5mb", out output);
// Invalid
ByteSize.Parse("1.5 b"); // Can't have partial bits
// Valid
ByteSize.Parse("5b");
ByteSize.Parse("1.55B");
ByteSize.Parse("1.55KB");
ByteSize.Parse("1.55 kB "); // Spaces are trimmed
ByteSize.Parse("1.55 kb");
ByteSize.Parse("1.55 MB");
ByteSize.Parse("1.55 mB");
ByteSize.Parse("1.55 mb");
ByteSize.Parse("1.55 GB");
ByteSize.Parse("1.55 gB");
ByteSize.Parse("1.55 gb");
ByteSize.Parse("1.55 TB");
ByteSize.Parse("1.55 tB");
ByteSize.Parse("1.55 tb");
Finally, if you need to calculate the rate at which a quantity of bytes has been transferred, you can use the Per
method of ByteSize
. The Per
method accepts one argument - the measurement interval for the bytes; this is the amount of time it took to transfer the bytes.
The Per
method returns a ByteRate
class which has a Humanize
method. By default, rates are given in seconds (eg, MB/s). However, if desired, a TimeUnit may be passed to Humanize
for an alternate interval. Valid intervals are TimeUnit.Second
, TimeUnit.Minute
, and TimeUnit.Hour
. Examples of each interval and example byte rate usage is below.
var size = ByteSize.FromMegabytes(10);
var measurementInterval = TimeSpan.FromSeconds(1);
var text = size.Per(measurementInterval).Humanize();
// 10 MB/s
text = size.Per(measurementInterval).Humanize(TimeUnit.Minute);
// 600 MB/min
text = size.Per(measurementInterval).Humanize(TimeUnit.Hour);
// 35.15625 GB/hour
You can specify a format for the bytes part of the humanized output:
19854651984.Bytes().Per(1.Seconds()).Humanize("#.##");
// 18.49 GB/s
Humanizer includes methods to change a numeric heading to words. The heading can be a double
whereas the result will be a string. You can choose whether to return a full representation of the heading (e.g. north, east, south or west), a short representation (e.g. N, E, S, W) or a unicode arrow character (e.g. β, β, β, β).
360.ToHeading();
// N
720.ToHeading();
// N
In order to retrieve a full version of the heading, use the following call:
180.ToHeading(HeadingStyle.Full);
// south
360.ToHeading(HeadingStyle.Full);
// north
Please note that a textual representation has a maximum deviation of 11.25Β°.
The methods above all have an overload with which you can provide a CultureInfo
object in order to determine the localized result to return.
To retrieve an arrow representing the heading use the following method:
90.ToHeadingArrow();
// β
225.ToHeadingArrow();
// β
The arrow representation of the heading has a maximum deviation of 22.5Β°.
In order to retrieve a heading based on the short text representation (e.g. N, E, S, W), the following method can be used:
"S".FromShortHeading();
// 180
"SW".FromShortHeading();
// 225
Humanizer can change whole numbers into their 'tuple' using Tupleize
. For example:
1.Tupleize();
// single
3.Tupleize();
// triple
100.Tupleize();
// centuple
The numbers 1-10, 100 and 1000 will be converted into a 'named' tuple (i.e. "single", "double" etc.). Any other number "n" will be converted to "n-tuple".
Humanizer can translate time units to their symbols:
TimeUnit.Day.ToSymbol();
// d
TimeUnit.Week.ToSymbol();
// week
TimeUnit.Year.ToSymbol();
// y
This is just a baseline and you can use this to simplify your day to day job. For example, in Asp.Net MVC we keep chucking Display
attribute on ViewModel properties so HtmlHelper
can generate correct labels for us; but, just like enums, in vast majority of cases we just need a space between the words in property name - so why not use "string".Humanize
for that?!
You may find an Asp.Net MVC sample in the code that does that (although the project is excluded from the solution file to make the nuget package available for .Net 3.5 too).
This is achieved using a custom DataAnnotationsModelMetadataProvider
I called HumanizerMetadataProvider. It is small enough to repeat here; so here we go:
using System;
using System.Collections.Generic;
using System.ComponentModel;
using System.ComponentModel.DataAnnotations;
using System.Linq;
using System.Web.Mvc;
using Humanizer;
public class HumanizerMetadataProvider : DataAnnotationsModelMetadataProvider
{
protected override ModelMetadata CreateMetadata(
IEnumerable<Attribute> attributes,
Type containerType,
Func<object> modelAccessor,
Type modelType,
string propertyName)
{
var propertyAttributes = attributes.ToList();
var modelMetadata = base.CreateMetadata(propertyAttributes, containerType, modelAccessor, modelType, propertyName);
if (IsTransformRequired(modelMetadata, propertyAttributes))
modelMetadata.DisplayName = modelMetadata.PropertyName.Humanize();
return modelMetadata;
}
private static bool IsTransformRequired(ModelMetadata modelMetadata, IList<Attribute> propertyAttributes)
{
if (string.IsNullOrEmpty(modelMetadata.PropertyName))
return false;
if (propertyAttributes.OfType<DisplayNameAttribute>().Any())
return false;
if (propertyAttributes.OfType<DisplayAttribute>().Any())
return false;
return true;
}
}
This class calls the base class to extract the metadata and then, if required, humanizes the property name.
It is checking if the property already has a DisplayName
or Display
attribute on it in which case the metadata provider will just honor the attribute and leave the property alone.
For other properties it will Humanize the property name. That is all.
Now you need to register this metadata provider with Asp.Net MVC.
Make sure you use System.Web.Mvc.ModelMetadataProviders
, and not System.Web.ModelBinding.ModelMetadataProviders
:
ModelMetadataProviders.Current = new HumanizerMetadataProvider();
... and now you can replace:
public class RegisterModel
{
[Display(Name = "User name")]
public string UserName { get; set; }
[Display(Name = "Email address")]
public string EmailAddress { get; set; }
[Display(Name = "Confirm password")]
public string ConfirmPassword { get; set; }
}
with:
public class RegisterModel
{
public string UserName { get; set; }
public string EmailAddress { get; set; }
public string ConfirmPassword { get; set; }
}
... and the "metadata humanizer" will take care of the rest.
No need to mention that if you want title casing for your labels you can chain the method with Transform
:
modelMetadata.DisplayName = modelMetadata.PropertyName.Humanize().Transform(To.TitleCase);
Humanizer is a Portable Class Library. There is currently an issue if you try to use PCL's in an MVC view since the MVC views do not share the same build system as the regular project. You must specify all references in the web.config
file, including ones the project system normally automatically adds.
If you encounter errors saying that you must add a reference to either System.Runtime
or System.Globalization
, this applies to you. The solution is to add the contract references to your web.config
as listed here. Note that this applies to any PCL you use in an MVC view, not just Humanizer.
Humanizer project is built & tested continuously by Azure DevOps (more details here). That applies to pull requests too. Shortly after you submit a PR you can check the build and test status notification on your PR.
The current build status on the CI server is
Below is a list of related open source projects:
If using ReSharper, annotations for Humanizer are available in the Humanizer.Annotations package, which you can obtain via the ReSharper Extension Manager. These annotations do not yet cover the entire library, but pull requests are always welcome!.
PowerShell Humanizer is a PowerShell module that wraps Humanizer.
Humanizer.jvm is an adaptation of the Humanizer framework for .Net which is made for the jvm and is written in Kotlin. Humanizer.jvm meets all your jvm needs for manipulating and displaying strings, enums, dates, times, timespans, numbers and quantities.
Humanizer.node is a TypeScript port of the Humanizer framework.
Icon created by Tyrone Rieschiek