This manual page explains how stringi deals with character strings in various encodings.
In particular you should note that:
R lets strings in ASCII, UTF-8, and your platform's
native encoding coexist. A character vector printed on the console
by calling print
or cat
is
silently re-encoded to the native encoding.
Functions in stringi process each string internally in Unicode, the most universal character encoding ever. Even if a string is given in the native encoding, i.e., your platform's default one, it will be converted to Unicode (precisely: UTF-8 or UTF-16).
Most stringi functions always return UTF-8 encoded strings, regardless of the input encoding. What is more, the functions have been optimized for UTF-8/ASCII input (they have competitive, if not better performance, especially when performing more complex operations like string comparison, sorting, and even concatenation). Thus, it is best to rely on cascading calls to stringi operations solely.
For portability reasons, the UTF-8 encoding is the most natural choice
for representing Unicode character strings in R. UTF-8 has ASCII as its
subset (code points 1--127 represent the same characters in both of them).
Code points larger than 127 are represented by multi-byte sequences
(from 2 to 4 bytes: Please note that not all sequences of bytes
are valid UTF-8, compare stri_enc_isutf8
).
Most of the computations in stringi are performed internally using either UTF-8 or UTF-16 encodings (this depends on type of service you request: some ICU services are designed only to work with UTF-16). Due to such a choice, with stringi you get the same result on each platform, which is -- unfortunately -- not the case of base R's functions (for instance, it is known that performing a regular expression search under Linux on some texts may give you a different result to those obtained under Windows). We really had portability in our minds while developing our package!
We have observed that R correctly handles UTF-8 strings regardless of your platform's native encoding (see below). Therefore, we decided that most functions in stringi will output its results in UTF-8 -- this speeds ups computations on cascading calls to our functions: the strings does not have to be re-encoded each time.
Note that some Unicode characters may have an ambiguous representation.
For example, ``a with ogonek'' (one character) and ``a''+``ogonek''
(two graphemes) are semantically the same. stringi provides functions
to normalize character sequences, see stri_trans_nfc
for discussion. However, it is observed that denormalized strings
do appear very rarely in typical string processing activities.
Additionally, do note that stringi silently removes byte order marks
(BOMs - they may incidentally appear in a string read from a text file)
from UTF8-encoded strings, see stri_enc_toutf8
.
Data in memory are just bytes (small integer values) -- an encoding is a way to represent characters with such numbers, it is a semantic "key" to understand a given byte sequence. For example, in ISO-8859-2 (Central European), the value 177 represents Polish ``a with ogonek'', and in ISO-8859-1 (Western European), the same value denotes the ``plus-minus'' sign. Thus, a character encoding is a translation scheme: we need to communicate with R somehow, relying on how it represents strings.
Basically, R has a very simple encoding marking mechanism,
see stri_enc_mark
. There is an implicit assumption
that your platform's default (native) encoding always extends
ASCII -- stringi checks that whenever your native encoding
is being detected automatically on ICU's initialization and each time
when you change it manually by calling stri_enc_set
.
Character strings in R (internally) can be declared to be in:
UTF-8
;
latin1
, i.e., either ISO-8859-1 (Western European on
Linux, macOS, and other Unixes) or WINDOWS-1252 (Windows);
bytes
-- for strings that
should be manipulated as sequences of bytes.
Moreover, there are two other cases:
ASCII -- for strings consisting only of byte codes not greater than 127;-
native
(a.k.a. unknown
in Encoding
;
quite a misleading name: no explicit encoding mark) -- for
strings that are assumed to be in your platform's native (default) encoding.
This can represent UTF-8 if you are an macOS user,
or some 8-bit Windows code page, for example.
The native encoding used by R may be determined by examining
the LC_CTYPE category, see Sys.getlocale
.
Intuitively, ``native'' strings result from reading a string from stdin (e.g., keyboard input). This makes sense: your operating system works in some encoding and provides R with some data.
Each time when a stringi function encounters a string declared
in native encoding, it assumes that the input data should be translated
from the default encoding, i.e., the one returned by stri_enc_get
(unless you know what you are doing, the default encoding should only be
changed if the automatic encoding detection process fails on stringi
load).
Functions which allow "bytes"
encoding markings are very rare in
stringi, and were carefully selected. These are:
stri_enc_toutf8
(with argument is_unknown_8bit=TRUE
),
stri_enc_toascii
, and stri_encode
.
Finally, note that R lets strings in ASCII, UTF-8, and your platform's
native encoding coexist. A character vector printed with
print
, cat
, etc., is silently re-encoded
so that it can be properly shown, e.g., on the console.
Apart from automatic conversion from the native encoding,
you may re-encode a string manually, for example
when you read it from a file created on a different platform.
Call stri_enc_list
for the list of
encodings supported by ICU.
Note that converter names are case-insensitive
and ICU tries to normalize the encoding specifiers.
Leading zeroes are ignored in sequences of digits (if further digits follow),
and all non-alphanumeric characters are ignored. Thus the strings
"UTF-8", "utf_8", "u*Tf08" and "Utf 8" are equivalent.
The stri_encode
function
allows you to convert between any given encodings
(in some cases you will obtain bytes
-marked
strings, or even lists of raw vectors (i.e., for UTF-16).
There are also some useful more specialized functions,
like stri_enc_toutf32
(converts a character vector to a list
of integers, where one code point is exactly one numeric value)
or stri_enc_toascii
(substitutes all non-ASCII
bytes with the SUBSTITUTE CHARACTER,
which plays a similar role as R's NA
value).
There are also some routines for automated encoding detection,
see, e.g., stri_enc_detect
.
Given a text file, one has to know how to interpret (encode) raw data in order to obtain meaningful information.
Encoding detection is always an imprecise operation and needs a considerable amount of data. However, in case of some encodings (like UTF-8, ASCII, or UTF-32) a ``false positive'' byte sequence is quite rare (statistically speaking).
Check out stri_enc_detect
(among others) for a useful
function in this category.
"Hundreds of encodings have been developed over the years, each for small groups of languages and for special purposes. As a result, the interpretation of text, input, sorting, display, and storage depends on the knowledge of all the different types of character sets and their encodings. Programs have been written to handle either one single encoding at a time and switch between them, or to convert between external and internal encodings."
"Unicode provides a single character set that covers the major languages of the world, and a small number of machine-friendly encoding forms and schemes to fit the needs of existing applications and protocols. It is designed for best interoperability with both ASCII and ISO-8859-1 (the most widely used character sets) to make it easier for Unicode to be used in almost all applications and protocols" (see the ICU User Guide).
The Unicode Standard determines the way to map any possible character to a numeric value -- a so-called code point. Such code points, however, have to be stored somehow in computer's memory. The Unicode Standard encodes characters in the range U+0000..U+10FFFF, which amounts to a 21-bit code space. Depending on the encoding form (UTF-8, UTF-16, or UTF-32), each character will then be represented either as a sequence of one to four 8-bit bytes, one or two 16-bit code units, or a single 32-bit integer (compare the ICU FAQ).
Unicode can be thought of as a superset of the spectrum of characters supported by any given code page.
Unicode Basics -- ICU User Guide, http://userguide.icu-project.org/unicode
Conversion -- ICU User Guide, http://userguide.icu-project.org/conversion
Converters -- ICU User Guide, http://userguide.icu-project.org/conversion/converters (technical details)
UTF-8, UTF-16, UTF-32 & BOM -- ICU FAQ, http://www.unicode.org/faq/utf_bom.html
Other stringi_general_topics: stringi-arguments
,
stringi-locale
,
stringi-package
,
stringi-search-boundaries
,
stringi-search-charclass
,
stringi-search-coll
,
stringi-search-fixed
,
stringi-search-regex
,
stringi-search
Other encoding_management: stri_enc_info
,
stri_enc_list
, stri_enc_mark
,
stri_enc_set
Other encoding_detection: stri_enc_detect2
,
stri_enc_detect
,
stri_enc_isascii
,
stri_enc_isutf16be
,
stri_enc_isutf8
Other encoding_conversion: stri_enc_fromutf32
,
stri_enc_toascii
,
stri_enc_tonative
,
stri_enc_toutf32
,
stri_enc_toutf8
, stri_encode