text-1.1.0.1: An efficient packed Unicode text type.

PortabilityGHC
Stabilityexperimental
Maintainerbos@serpentine.com
Safe HaskellTrustworthy

Data.Text

Contents

Description

A time and space-efficient implementation of Unicode text. Suitable for performance critical use, both in terms of large data quantities and high speed.

Note: Read below the synopsis for important notes on the use of this module.

This module is intended to be imported qualified, to avoid name clashes with Prelude functions, e.g.

 import qualified Data.Text as T

To use an extended and very rich family of functions for working with Unicode text (including normalization, regular expressions, non-standard encodings, text breaking, and locales), see the text-icu package: http://hackage.haskell.org/package/text-icu

Synopsis

Strict vs lazy types

This package provides both strict and lazy Text types. The strict type is provided by the Data.Text module, while the lazy type is provided by the Data.Text.Lazy module. Internally, the lazy Text type consists of a list of strict chunks.

The strict Text type requires that an entire string fit into memory at once. The lazy Text type is capable of streaming strings that are larger than memory using a small memory footprint. In many cases, the overhead of chunked streaming makes the lazy Text type slower than its strict counterpart, but this is not always the case. Sometimes, the time complexity of a function in one module may be different from the other, due to their differing internal structures.

Each module provides an almost identical API, with the main difference being that the strict module uses Int values for lengths and counts, while the lazy module uses Int64 lengths.

Acceptable data

A Text value is a sequence of Unicode scalar values, as defined in §3.9, definition D76 of the Unicode 5.2 standard: http://www.unicode.org/versions/Unicode5.2.0/ch03.pdf#page=35. As such, a Text cannot contain values in the range U+D800 to U+DFFF inclusive. Haskell implementations admit all Unicode code points (§3.4, definition D10) as Char values, including code points from this invalid range. This means that there are some Char values that are not valid Unicode scalar values, and the functions in this module must handle those cases.

Within this module, many functions construct a Text from one or more Char values. Those functions will substitute Char values that are not valid Unicode scalar values with the replacement character "�" (U+FFFD). Functions that perform this inspection and replacement are documented with the phrase "Performs replacement on invalid scalar values".

(One reason for this policy of replacement is that internally, a Text value is represented as packed UTF-16 data. Values in the range U+D800 through U+DFFF are used by UTF-16 to denote surrogate code points, and so cannot be represented. The functions replace invalid scalar values, instead of dropping them, as a security measure. For details, see Unicode Technical Report 36, §3.5: http://unicode.org/reports/tr36/#Deletion_of_Noncharacters)

Fusion

Most of the functions in this module are subject to fusion, meaning that a pipeline of such functions will usually allocate at most one Text value.

As an example, consider the following pipeline:

 import Data.Text as T
 import Data.Text.Encoding as E
 import Data.ByteString (ByteString)

 countChars :: ByteString -> Int
 countChars = T.length . T.toUpper . E.decodeUtf8

From the type signatures involved, this looks like it should allocate one ByteString value, and two Text values. However, when a module is compiled with optimisation enabled under GHC, the two intermediate Text values will be optimised away, and the function will be compiled down to a single loop over the source ByteString.

Functions that can be fused by the compiler are documented with the phrase "Subject to fusion".

Types

data Text Source

A space efficient, packed, unboxed Unicode text type.

Instances

Eq Text 
Data Text

This instance preserves data abstraction at the cost of inefficiency. We omit reflection services for the sake of data abstraction.

This instance was created by copying the behavior of Data.Set and Data.Map. If you feel a mistake has been made, please feel free to submit improvements.

Original discussion is archived here:

could we get a Data instance for Data.Text.Text? http:groups.google.comgrouphaskell-cafebrowse_threadthreadb5bbb1b28a7e525d0639d46852575b93

Ord Text 
Read Text 
Show Text 
Typeable Text 
IsString Text 
Monoid Text 
NFData Text 

Creation and elimination

pack :: String -> TextSource

O(n) Convert a String into a Text. Subject to fusion. Performs replacement on invalid scalar values.

unpack :: Text -> StringSource

O(n) Convert a Text into a String. Subject to fusion.

singleton :: Char -> TextSource

O(1) Convert a character into a Text. Subject to fusion. Performs replacement on invalid scalar values.

empty :: TextSource

O(1) The empty Text.

Basic interface

cons :: Char -> Text -> TextSource

O(n) Adds a character to the front of a Text. This function is more costly than its List counterpart because it requires copying a new array. Subject to fusion. Performs replacement on invalid scalar values.

snoc :: Text -> Char -> TextSource

O(n) Adds a character to the end of a Text. This copies the entire array in the process, unless fused. Subject to fusion. Performs replacement on invalid scalar values.

append :: Text -> Text -> TextSource

O(n) Appends one Text to the other by copying both of them into a new Text. Subject to fusion.

uncons :: Text -> Maybe (Char, Text)Source

O(1) Returns the first character and rest of a Text, or Nothing if empty. Subject to fusion.

head :: Text -> CharSource

O(1) Returns the first character of a Text, which must be non-empty. Subject to fusion.

last :: Text -> CharSource

O(1) Returns the last character of a Text, which must be non-empty. Subject to fusion.

tail :: Text -> TextSource

O(1) Returns all characters after the head of a Text, which must be non-empty. Subject to fusion.

init :: Text -> TextSource

O(1) Returns all but the last character of a Text, which must be non-empty. Subject to fusion.

null :: Text -> BoolSource

O(1) Tests whether a Text is empty or not. Subject to fusion.

length :: Text -> IntSource

O(n) Returns the number of characters in a Text. Subject to fusion.

compareLength :: Text -> Int -> OrderingSource

O(n) Compare the count of characters in a Text to a number. Subject to fusion.

This function gives the same answer as comparing against the result of length, but can short circuit if the count of characters is greater than the number, and hence be more efficient.

Transformations

map :: (Char -> Char) -> Text -> TextSource

O(n) map f t is the Text obtained by applying f to each element of t. Subject to fusion. Performs replacement on invalid scalar values.

intercalate :: Text -> [Text] -> TextSource

O(n) The intercalate function takes a Text and a list of Texts and concatenates the list after interspersing the first argument between each element of the list.

intersperse :: Char -> Text -> TextSource

O(n) The intersperse function takes a character and places it between the characters of a Text. Subject to fusion. Performs replacement on invalid scalar values.

transpose :: [Text] -> [Text]Source

O(n) The transpose function transposes the rows and columns of its Text argument. Note that this function uses pack, unpack, and the list version of transpose, and is thus not very efficient.

reverse :: Text -> TextSource

O(n) Reverse the characters of a string. Subject to fusion.

replace :: Text -> Text -> Text -> TextSource

O(m+n) Replace every occurrence of one substring with another.

In (unlikely) bad cases, this function's time complexity degrades towards O(n*m).

Case conversion

When case converting Text values, do not use combinators like map toUpper to case convert each character of a string individually, as this gives incorrect results according to the rules of some writing systems. The whole-string case conversion functions from this module, such as toUpper, obey the correct case conversion rules. As a result, these functions may map one input character to two or three output characters. For examples, see the documentation of each function.

Note: In some languages, case conversion is a locale- and context-dependent operation. The case conversion functions in this module are not locale sensitive. Programs that require locale sensitivity should use appropriate versions of the case mapping functions from the text-icu package: http://hackage.haskell.org/package/text-icu

toCaseFold :: Text -> TextSource

O(n) Convert a string to folded case. Subject to fusion.

This function is mainly useful for performing caseless (also known as case insensitive) string comparisons.

A string x is a caseless match for a string y if and only if:

toCaseFold x == toCaseFold y

The result string may be longer than the input string, and may differ from applying toLower to the input string. For instance, the Armenian small ligature "ﬓ" (men now, U+FB13) is case folded to the sequence "մ" (men, U+0574) followed by "ն" (now, U+0576), while the Greek "µ" (micro sign, U+00B5) is case folded to "μ" (small letter mu, U+03BC) instead of itself.

toLower :: Text -> TextSource

O(n) Convert a string to lower case, using simple case conversion. Subject to fusion.

The result string may be longer than the input string. For instance, "İ" (Latin capital letter I with dot above, U+0130) maps to the sequence "i" (Latin small letter i, U+0069) followed by " ̇" (combining dot above, U+0307).

toUpper :: Text -> TextSource

O(n) Convert a string to upper case, using simple case conversion. Subject to fusion.

The result string may be longer than the input string. For instance, the German "ß" (eszett, U+00DF) maps to the two-letter sequence "SS".

toTitle :: Text -> TextSource

O(n) Convert a string to title case, using simple case conversion. Subject to fusion.

The first letter of the input is converted to title case, as is every subsequent letter that immediately follows a non-letter. Every letter that immediately follows another letter is converted to lower case.

The result string may be longer than the input string. For example, the Latin small ligature fl (U+FB02) is converted to the sequence Latin capital letter F (U+0046) followed by Latin small letter l (U+006C).

Note: this function does not take language or culture specific rules into account. For instance, in English, different style guides disagree on whether the book name "The Hill of the Red Fox" is correctly title cased—but this function will capitalize every word.

Justification

justifyLeft :: Int -> Char -> Text -> TextSource

O(n) Left-justify a string to the given length, using the specified fill character on the right. Subject to fusion. Performs replacement on invalid scalar values.

Examples:

 justifyLeft 7 'x' "foo"    == "fooxxxx"
 justifyLeft 3 'x' "foobar" == "foobar"

justifyRight :: Int -> Char -> Text -> TextSource

O(n) Right-justify a string to the given length, using the specified fill character on the left. Performs replacement on invalid scalar values.

Examples:

 justifyRight 7 'x' "bar"    == "xxxxbar"
 justifyRight 3 'x' "foobar" == "foobar"

center :: Int -> Char -> Text -> TextSource

O(n) Center a string to the given length, using the specified fill character on either side. Performs replacement on invalid scalar values.

Examples:

 center 8 'x' "HS" = "xxxHSxxx"

Folds

foldl :: (a -> Char -> a) -> a -> Text -> aSource

O(n) foldl, applied to a binary operator, a starting value (typically the left-identity of the operator), and a Text, reduces the Text using the binary operator, from left to right. Subject to fusion.

foldl' :: (a -> Char -> a) -> a -> Text -> aSource

O(n) A strict version of foldl. Subject to fusion.

foldl1 :: (Char -> Char -> Char) -> Text -> CharSource

O(n) A variant of foldl that has no starting value argument, and thus must be applied to a non-empty Text. Subject to fusion.

foldl1' :: (Char -> Char -> Char) -> Text -> CharSource

O(n) A strict version of foldl1. Subject to fusion.

foldr :: (Char -> a -> a) -> a -> Text -> aSource

O(n) foldr, applied to a binary operator, a starting value (typically the right-identity of the operator), and a Text, reduces the Text using the binary operator, from right to left. Subject to fusion.

foldr1 :: (Char -> Char -> Char) -> Text -> CharSource

O(n) A variant of foldr that has no starting value argument, and thus must be applied to a non-empty Text. Subject to fusion.

Special folds

concat :: [Text] -> TextSource

O(n) Concatenate a list of Texts.

concatMap :: (Char -> Text) -> Text -> TextSource

O(n) Map a function over a Text that results in a Text, and concatenate the results.

any :: (Char -> Bool) -> Text -> BoolSource

O(n) any p t determines whether any character in the Text t satisifes the predicate p. Subject to fusion.

all :: (Char -> Bool) -> Text -> BoolSource

O(n) all p t determines whether all characters in the Text t satisify the predicate p. Subject to fusion.

maximum :: Text -> CharSource

O(n) maximum returns the maximum value from a Text, which must be non-empty. Subject to fusion.

minimum :: Text -> CharSource

O(n) minimum returns the minimum value from a Text, which must be non-empty. Subject to fusion.

Construction

Scans

scanl :: (Char -> Char -> Char) -> Char -> Text -> TextSource

O(n) scanl is similar to foldl, but returns a list of successive reduced values from the left. Subject to fusion. Performs replacement on invalid scalar values.

 scanl f z [x1, x2, ...] == [z, z `f` x1, (z `f` x1) `f` x2, ...]

Note that

 last (scanl f z xs) == foldl f z xs.

scanl1 :: (Char -> Char -> Char) -> Text -> TextSource

O(n) scanl1 is a variant of scanl that has no starting value argument. Subject to fusion. Performs replacement on invalid scalar values.

 scanl1 f [x1, x2, ...] == [x1, x1 `f` x2, ...]

scanr :: (Char -> Char -> Char) -> Char -> Text -> TextSource

O(n) scanr is the right-to-left dual of scanl. Performs replacement on invalid scalar values.

 scanr f v == reverse . scanl (flip f) v . reverse

scanr1 :: (Char -> Char -> Char) -> Text -> TextSource

O(n) scanr1 is a variant of scanr that has no starting value argument. Subject to fusion. Performs replacement on invalid scalar values.

Accumulating maps

mapAccumL :: (a -> Char -> (a, Char)) -> a -> Text -> (a, Text)Source

O(n) Like a combination of map and foldl'. Applies a function to each element of a Text, passing an accumulating parameter from left to right, and returns a final Text. Performs replacement on invalid scalar values.

mapAccumR :: (a -> Char -> (a, Char)) -> a -> Text -> (a, Text)Source

The mapAccumR function behaves like a combination of map and a strict foldr; it applies a function to each element of a Text, passing an accumulating parameter from right to left, and returning a final value of this accumulator together with the new Text. Performs replacement on invalid scalar values.

Generation and unfolding

replicate :: Int -> Text -> TextSource

O(n*m) replicate n t is a Text consisting of the input t repeated n times.

unfoldr :: (a -> Maybe (Char, a)) -> a -> TextSource

O(n), where n is the length of the result. The unfoldr function is analogous to the List unfoldr. unfoldr builds a Text from a seed value. The function takes the element and returns Nothing if it is done producing the Text, otherwise Just (a,b). In this case, a is the next Char in the string, and b is the seed value for further production. Subject to fusion. Performs replacement on invalid scalar values.

unfoldrN :: Int -> (a -> Maybe (Char, a)) -> a -> TextSource

O(n) Like unfoldr, unfoldrN builds a Text from a seed value. However, the length of the result should be limited by the first argument to unfoldrN. This function is more efficient than unfoldr when the maximum length of the result is known and correct, otherwise its performance is similar to unfoldr. Subject to fusion. Performs replacement on invalid scalar values.

Substrings

Breaking strings

take :: Int -> Text -> TextSource

O(n) take n, applied to a Text, returns the prefix of the Text of length n, or the Text itself if n is greater than the length of the Text. Subject to fusion.

drop :: Int -> Text -> TextSource

O(n) drop n, applied to a Text, returns the suffix of the Text after the first n characters, or the empty Text if n is greater than the length of the Text. Subject to fusion.

takeWhile :: (Char -> Bool) -> Text -> TextSource

O(n) takeWhile, applied to a predicate p and a Text, returns the longest prefix (possibly empty) of elements that satisfy p. Subject to fusion.

dropWhile :: (Char -> Bool) -> Text -> TextSource

O(n) dropWhile p t returns the suffix remaining after takeWhile p t. Subject to fusion.

dropWhileEnd :: (Char -> Bool) -> Text -> TextSource

O(n) dropWhileEnd p t returns the prefix remaining after dropping characters that fail the predicate p from the end of t. Subject to fusion. Examples:

 dropWhileEnd (=='.') "foo..." == "foo"

dropAround :: (Char -> Bool) -> Text -> TextSource

O(n) dropAround p t returns the substring remaining after dropping characters that fail the predicate p from both the beginning and end of t. Subject to fusion.

strip :: Text -> TextSource

O(n) Remove leading and trailing white space from a string. Equivalent to:

 dropAround isSpace

stripStart :: Text -> TextSource

O(n) Remove leading white space from a string. Equivalent to:

 dropWhile isSpace

stripEnd :: Text -> TextSource

O(n) Remove trailing white space from a string. Equivalent to:

 dropWhileEnd isSpace

splitAt :: Int -> Text -> (Text, Text)Source

O(n) splitAt n t returns a pair whose first element is a prefix of t of length n, and whose second is the remainder of the string. It is equivalent to (take n t, drop n t).

breakOn :: Text -> Text -> (Text, Text)Source

O(n+m) Find the first instance of needle (which must be non-null) in haystack. The first element of the returned tuple is the prefix of haystack before needle is matched. The second is the remainder of haystack, starting with the match.

Examples:

 breakOn "::" "a::b::c" ==> ("a", "::b::c")
 breakOn "/" "foobar"   ==> ("foobar", "")

Laws:

 append prefix match == haystack
   where (prefix, match) = breakOn needle haystack

If you need to break a string by a substring repeatedly (e.g. you want to break on every instance of a substring), use breakOnAll instead, as it has lower startup overhead.

In (unlikely) bad cases, this function's time complexity degrades towards O(n*m).

breakOnEnd :: Text -> Text -> (Text, Text)Source

O(n+m) Similar to breakOn, but searches from the end of the string.

The first element of the returned tuple is the prefix of haystack up to and including the last match of needle. The second is the remainder of haystack, following the match.

 breakOnEnd "::" "a::b::c" ==> ("a::b::", "c")

break :: (Char -> Bool) -> Text -> (Text, Text)Source

O(n) break is like span, but the prefix returned is over elements that fail the predicate p.

span :: (Char -> Bool) -> Text -> (Text, Text)Source

O(n) span, applied to a predicate p and text t, returns a pair whose first element is the longest prefix (possibly empty) of t of elements that satisfy p, and whose second is the remainder of the list.

group :: Text -> [Text]Source

O(n) Group characters in a string by equality.

groupBy :: (Char -> Char -> Bool) -> Text -> [Text]Source

O(n) Group characters in a string according to a predicate.

inits :: Text -> [Text]Source

O(n) Return all initial segments of the given Text, shortest first.

tails :: Text -> [Text]Source

O(n) Return all final segments of the given Text, longest first.

Breaking into many substrings

Splitting functions in this library do not perform character-wise copies to create substrings; they just construct new Texts that are slices of the original.

splitOn :: Text -> Text -> [Text]Source

O(m+n) Break a Text into pieces separated by the first Text argument, consuming the delimiter. An empty delimiter is invalid, and will cause an error to be raised.

Examples:

 splitOn "\r\n" "a\r\nb\r\nd\r\ne" == ["a","b","d","e"]
 splitOn "aaa"  "aaaXaaaXaaaXaaa"  == ["","X","X","X",""]
 splitOn "x"    "x"                == ["",""]

and

 intercalate s . splitOn s         == id
 splitOn (singleton c)             == split (==c)

In (unlikely) bad cases, this function's time complexity degrades towards O(n*m).

split :: (Char -> Bool) -> Text -> [Text]Source

O(n) Splits a Text into components delimited by separators, where the predicate returns True for a separator element. The resulting components do not contain the separators. Two adjacent separators result in an empty component in the output. eg.

 split (=='a') "aabbaca" == ["","","bb","c",""]
 split (=='a') ""        == [""]

chunksOf :: Int -> Text -> [Text]Source

O(n) Splits a Text into components of length k. The last element may be shorter than the other chunks, depending on the length of the input. Examples:

 chunksOf 3 "foobarbaz"   == ["foo","bar","baz"]
 chunksOf 4 "haskell.org" == ["hask","ell.","org"]

Breaking into lines and words

lines :: Text -> [Text]Source

O(n) Breaks a Text up into a list of Texts at newline Chars. The resulting strings do not contain newlines.

words :: Text -> [Text]Source

O(n) Breaks a Text up into a list of words, delimited by Chars representing white space.

unlines :: [Text] -> TextSource

O(n) Joins lines, after appending a terminating newline to each.

unwords :: [Text] -> TextSource

O(n) Joins words using single space characters.

Predicates

isPrefixOf :: Text -> Text -> BoolSource

O(n) The isPrefixOf function takes two Texts and returns True iff the first is a prefix of the second. Subject to fusion.

isSuffixOf :: Text -> Text -> BoolSource

O(n) The isSuffixOf function takes two Texts and returns True iff the first is a suffix of the second.

isInfixOf :: Text -> Text -> BoolSource

O(n+m) The isInfixOf function takes two Texts and returns True iff the first is contained, wholly and intact, anywhere within the second.

In (unlikely) bad cases, this function's time complexity degrades towards O(n*m).

View patterns

stripPrefix :: Text -> Text -> Maybe TextSource

O(n) Return the suffix of the second string if its prefix matches the entire first string.

Examples:

 stripPrefix "foo" "foobar" == Just "bar"
 stripPrefix ""    "baz"    == Just "baz"
 stripPrefix "foo" "quux"   == Nothing

This is particularly useful with the ViewPatterns extension to GHC, as follows:

 {-# LANGUAGE ViewPatterns #-}
 import Data.Text as T

 fnordLength :: Text -> Int
 fnordLength (stripPrefix "fnord" -> Just suf) = T.length suf
 fnordLength _                                 = -1

stripSuffix :: Text -> Text -> Maybe TextSource

O(n) Return the prefix of the second string if its suffix matches the entire first string.

Examples:

 stripSuffix "bar" "foobar" == Just "foo"
 stripSuffix ""    "baz"    == Just "baz"
 stripSuffix "foo" "quux"   == Nothing

This is particularly useful with the ViewPatterns extension to GHC, as follows:

 {-# LANGUAGE ViewPatterns #-}
 import Data.Text as T

 quuxLength :: Text -> Int
 quuxLength (stripSuffix "quux" -> Just pre) = T.length pre
 quuxLength _                                = -1

commonPrefixes :: Text -> Text -> Maybe (Text, Text, Text)Source

O(n) Find the longest non-empty common prefix of two strings and return it, along with the suffixes of each string at which they no longer match.

If the strings do not have a common prefix or either one is empty, this function returns Nothing.

Examples:

 commonPrefixes "foobar" "fooquux" == Just ("foo","bar","quux")
 commonPrefixes "veeble" "fetzer"  == Nothing
 commonPrefixes "" "baz"           == Nothing

Searching

filter :: (Char -> Bool) -> Text -> TextSource

O(n) filter, applied to a predicate and a Text, returns a Text containing those characters that satisfy the predicate.

breakOnAllSource

Arguments

:: Text

needle to search for

-> Text

haystack in which to search

-> [(Text, Text)] 

O(n+m) Find all non-overlapping instances of needle in haystack. Each element of the returned list consists of a pair:

  • The entire string prior to the kth match (i.e. the prefix)
  • The kth match, followed by the remainder of the string

Examples:

 breakOnAll "::" ""
 ==> []
 breakOnAll "/" "a/b/c/"
 ==> [("a", "/b/c/"), ("a/b", "/c/"), ("a/b/c", "/")]

In (unlikely) bad cases, this function's time complexity degrades towards O(n*m).

The needle parameter may not be empty.

find :: (Char -> Bool) -> Text -> Maybe CharSource

O(n) The find function takes a predicate and a Text, and returns the first element matching the predicate, or Nothing if there is no such element.

partition :: (Char -> Bool) -> Text -> (Text, Text)Source

O(n) The partition function takes a predicate and a Text, and returns the pair of Texts with elements which do and do not satisfy the predicate, respectively; i.e.

 partition p t == (filter p t, filter (not . p) t)

Indexing

If you think of a Text value as an array of Char values (which it is not), you run the risk of writing inefficient code.

An idiom that is common in some languages is to find the numeric offset of a character or substring, then use that number to split or trim the searched string. With a Text value, this approach would require two O(n) operations: one to perform the search, and one to operate from wherever the search ended.

For example, suppose you have a string that you want to split on the substring "::", such as "foo::bar::quux". Instead of searching for the index of "::" and taking the substrings before and after that index, you would instead use breakOnAll "::".

index :: Text -> Int -> CharSource

O(n) Text index (subscript) operator, starting from 0.

findIndex :: (Char -> Bool) -> Text -> Maybe IntSource

O(n) The findIndex function takes a predicate and a Text and returns the index of the first element in the Text satisfying the predicate. Subject to fusion.

count :: Text -> Text -> IntSource

O(n+m) The count function returns the number of times the query string appears in the given Text. An empty query string is invalid, and will cause an error to be raised.

In (unlikely) bad cases, this function's time complexity degrades towards O(n*m).

Zipping

zip :: Text -> Text -> [(Char, Char)]Source

O(n) zip takes two Texts and returns a list of corresponding pairs of bytes. If one input Text is short, excess elements of the longer Text are discarded. This is equivalent to a pair of unpack operations.

zipWith :: (Char -> Char -> Char) -> Text -> Text -> TextSource

O(n) zipWith generalises zip by zipping with the function given as the first argument, instead of a tupling function. Performs replacement on invalid scalar values.

Low level operations

copy :: Text -> TextSource

O(n) Make a distinct copy of the given string, sharing no storage with the original string.

As an example, suppose you read a large string, of which you need only a small portion. If you do not use copy, the entire original array will be kept alive in memory by the smaller string. Making a copy "breaks the link" to the original array, allowing it to be garbage collected if there are no other live references to it.