Geometric Shapes is a Unicode block of 96 symbols at codepoint range U+25A0-25FF.
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25A0 | 25B0 | 25C0 | ||||
---|---|---|---|---|---|---|
Symbol | Name | Symbol | Name | Symbol | Name | Last Hex# |
HTML Hex | HTML Hex | HTML Hex | ||||
Dec | Picture | Dec | Picture | Dec | Picture | |
■ | BLACK SQUARE | ▰ | BLACK PARALLELOGRAM | ◀ | BLACK LEFT-POINTING TRIANGLE | 0 |
■ | ▰ | ◀ | ||||
■ | ▰ | ◀ | ||||
□ | WHITE SQUARE | ▱ | WHITE PARALLELOGRAM | ◁ | WHITE LEFT-POINTING TRIANGLE (Z notation domain restriction) | 1 |
□ | ▱ | ◁ | ||||
□ | ▱ | ◁ | ||||
▢ | WHITE SQUARE WITH ROUNDED CORNERS | ▲ | BLACK UP-POINTING TRIANGLE | ◂ | BLACK LEFT-POINTING SMALL TRIANGLE | 2 |
▢ | ▲ | ◂ | ||||
▢ | ▲ | ◂ | ||||
▣ | WHITE SQUARE CONTAINING BLACK SMALL SQUARE | △ | WHITE UP-POINTING TRIANGLE (trine) | ◃ | WHITE LEFT-POINTING SMALL TRIANGLE | 3 |
▣ | △ | ◃ | ||||
▣ | △ | ◃ | ||||
▤ | SQUARE WITH HORIZONTAL FILL | ▴ | BLACK UP-POINTING SMALL TRIANGLE | ◄ | BLACK LEFT-POINTING POINTER | 4 |
▤ | ▴ | ◄ | ||||
▤ | ▴ | ◄ | ||||
▥ | SQUARE WITH VERTICAL FILL | ▵ | WHITE UP-POINTING SMALL TRIANGLE | ◅ | WHITE LEFT-POINTING POINTER | 5 |
▥ | ▵ | ◅ | ||||
▥ | ▵ | ◅ | ||||
▦ | SQUARE WITH ORTHOGONAL CROSSHATCH FILL | ▶ | BLACK RIGHT-POINTING TRIANGLE | ◆ | BLACK DIAMOND | 6 |
▦ | ▶ | ◆ | ||||
▦ | ▶ | ◆ | ||||
▧ | SQUARE WITH UPPER LEFT TO LOWER RIGHT FILL | ▷ | WHITE RIGHT-POINTING TRIANGLE (Z notation range restriction) | ◇ | WHITE DIAMOND | 7 |
▧ | ▷ | ◇ | ||||
▧ | ▷ | ◇ | ||||
▨ | SQUARE WITH UPPER RIGHT TO LOWER LEFT FILL | ▸ | BLACK RIGHT-POINTING SMALL TRIANGLE | ◈ | WHITE DIAMOND CONTAINING BLACK SMALL DIAMOND | 8 |
▨ | ▸ | ◈ | ||||
▨ | ▸ | ◈ | ||||
▩ | SQUARE WITH DIAGONAL CROSSHATCH FILL | ▹ | WHITE RIGHT-POINTING SMALL TRIANGLE | ◉ | FISHEYE (Tainome, a Japanese bullet mark) | 9 |
▩ | ▹ | ◉ | ||||
▩ | ▹ | ◉ | ||||
▪ | BLACK SMALL SQUARE | ► | BLACK RIGHT-POINTING POINTER | ◊ | LOZENGE | A |
▪ | ► | ◊ | ||||
▪ | ► | ◊ | ||||
▫ | WHITE SMALL SQUARE | ▻ | WHITE RIGHT-POINTING POINTER | ○ | WHITE CIRCLE | B |
▫ | ▻ | ○ | ||||
▫ | ▻ | ○ | ||||
▬ | BLACK RECTANGLE | ▼ | BLACK DOWN-POINTING TRIANGLE | ◌ | DOTTED CIRCLE | C |
▬ | ▼ | ◌ | ||||
▬ | ▼ | ◌ | ||||
▭ | WHITE RECTANGLE | ▽ | WHITE DOWN-POINTING TRIANGLE (Hamiltonian operator) | ◍ | CIRCLE WITH VERTICAL FILL | D |
▭ | ▽ | ◍ | ||||
▭ | ▽ | ◍ | ||||
▮ | BLACK VERTICAL RECTANGLE | ▾ | BLACK DOWN-POINTING SMALL TRIANGLE | ◎ | BULLSEYE | E |
▮ | ▾ | ◎ | ||||
▮ | ▾ | ◎ | ||||
▯ | WHITE VERTICAL RECTANGLE | ▿ | WHITE DOWN-POINTING SMALL TRIANGLE | ● | BLACK CIRCLE | F |
▯ | ▿ | ● | ||||
▯ | ▿ | ● | ||||
25A0 | 25B0 | 25C0 |
25D0 | 25E0 | 25F0 | ||||
---|---|---|---|---|---|---|
Symbol | Name | Symbol | Name | Symbol | Name | Last Hex# |
HTML Hex | HTML Hex | HTML Hex | ||||
Dec | Picture | Dec | Picture | Dec | Picture | |
◐ | CIRCLE WITH LEFT HALF BLACK | ◠ | UPPER HALF CIRCLE | ◰ | WHITE SQUARE WITH UPPER LEFT QUADRANT | 0 |
◐ | ◠ | ◰ | ||||
◐ | ◠ | ◰ | ||||
◑ | CIRCLE WITH RIGHT HALF BLACK | ◡ | LOWER HALF CIRCLE | ◱ | WHITE SQUARE WITH LOWER LEFT QUADRANT | 1 |
◑ | ◡ | ◱ | ||||
◑ | ◡ | ◱ | ||||
◒ | CIRCLE WITH LOWER HALF BLACK | ◢ | BLACK LOWER RIGHT TRIANGLE | ◲ | WHITE SQUARE WITH LOWER RIGHT QUADRANT | 2 |
◒ | ◢ | ◲ | ||||
◒ | ◢ | ◲ | ||||
◓ | CIRCLE WITH UPPER HALF BLACK | ◣ | BLACK LOWER LEFT TRIANGLE | ◳ | WHITE SQUARE WITH UPPER RIGHT QUADRANT | 3 |
◓ | ◣ | ◳ | ||||
◓ | ◣ | ◳ | ||||
◔ | CIRCLE WITH UPPER RIGHT QUADRANT BLACK | ◤ | BLACK UPPER LEFT TRIANGLE | ◴ | WHITE CIRCLE WITH UPPER LEFT QUADRANT | 4 |
◔ | ◤ | ◴ | ||||
◔ | ◤ | ◴ | ||||
◕ | CIRCLE WITH ALL BUT UPPER LEFT QUADRANT BLACK | ◥ | BLACK UPPER RIGHT TRIANGLE | ◵ | WHITE CIRCLE WITH LOWER LEFT QUADRANT | 5 |
◕ | ◥ | ◵ | ||||
◕ | ◥ | ◵ | ||||
◖ | LEFT HALF BLACK CIRCLE | ◦ | WHITE BULLET | ◶ | WHITE CIRCLE WITH LOWER RIGHT QUADRANT | 6 |
◖ | ◦ | ◶ | ||||
◖ | ◦ | ◶ | ||||
◗ | RIGHT HALF BLACK CIRCLE | ◧ | SQUARE WITH LEFT HALF BLACK | ◷ | WHITE CIRCLE WITH UPPER RIGHT QUADRANT | 7 |
◗ | ◧ | ◷ | ||||
◗ | ◧ | ◷ | ||||
◘ | INVERSE BULLET | ◨ | SQUARE WITH RIGHT HALF BLACK | ◸ | UPPER LEFT TRIANGLE | 8 |
◘ | ◨ | ◸ | ||||
◘ | ◨ | ◸ | ||||
◙ | INVERSE WHITE CIRCLE | ◩ | SQUARE WITH UPPER LEFT DIAGONAL HALF BLACK | ◹ | UPPER RIGHT TRIANGLE | 9 |
◙ | ◩ | ◹ | ||||
◙ | ◩ | ◹ | ||||
◚ | UPPER HALF INVERSE WHITE CIRCLE | ◪ | SQUARE WITH LOWER RIGHT DIAGONAL HALF BLACK | ◺ | LOWER LEFT TRIANGLE | A |
◚ | ◪ | ◺ | ||||
◚ | ◪ | ◺ | ||||
◛ | LOWER HALF INVERSE WHITE CIRCLE | ◫ | WHITE SQUARE WITH VERTICAL BISECTING LINE | ◻ | WHITE MEDIUM SQUARE (Modal logic: always, or necessarily) | B |
◛ | ◫ | ◻ | ||||
◛ | ◫ | ◻ | ||||
◜ | UPPER LEFT QUADRANT CIRCULAR ARC | ◬ | WHITE UP-POINTING TRIANGLE WITH DOT | ◼ | BLACK MEDIUM SQUARE | C |
◜ | ◬ | ◼ | ||||
◜ | ◬ | ◼ | ||||
◝ | UPPER RIGHT QUADRANT CIRCULAR ARC | ◭ | UP-POINTING TRIANGLE WITH LEFT HALF BLACK | ◽ | WHITE MEDIUM SMALL SQUARE | D |
◝ | ◭ | ◽ | ||||
◝ | ◭ | ◽ | ||||
◞ | LOWER RIGHT QUADRANT CIRCULAR ARC | ◮ | UP-POINTING TRIANGLE WITH RIGHT HALF BLACK | ◾ | BLACK MEDIUM SMALL SQUARE | E |
◞ | ◮ | ◾ | ||||
◞ | ◮ | ◾ | ||||
◟ | LOWER LEFT QUADRANT CIRCULAR ARC | ◯ | LARGE CIRCLE | ◿ | LOWER RIGHT TRIANGLE | F |
◟ | ◯ | ◿ | ||||
◟ | ◯ | ◿ | ||||
25D0 | 25E0 | 25F0 |
Font sets like Code2000 and the DejaVu family—include coverage for each of the glyphs in the Geometric Shapes range,[1] Unifont also contains all the glyphs.[2] Among the fonts in widespread use,[3][4] significant partial implementation of this range is provided by Arial Unicode MS and Lucida Sans Unicode, which include coverage for 83% (80 out of 96) and 82% (79 out of 96) of the symbols, respectively.[1]
This article contains instructions, advice, or how-to content. The purpose of Wikipedia is to present facts, not to train. Please help improve this article either by rewriting the how-to content or by moving it to Wikiversity or Wikibooks. (July 2011) |
In computing, a newline,[1] also known as a line break or end-of-line (EOL) marker, is a special character or sequence of characters signifying the end of a line of text. The name comes from the fact that the next character after the newline will appear on a new line—that is, on the next line below the text immediately preceding the newline. The actual codes representing a newline vary across operating systems, which can be a problem when exchanging text files between systems with different newline representations.
There is also some confusion whether newlines terminate or separate lines. If a newline is considered a separator, there will be no newline after the last line of a file. The general convention on most systems is to add a newline even after the last line, i.e. to treat newline as a line terminator. Some programs have problems processing the last line of a file if it is not newline terminated. Conversely, programs that expect newline to be used as a separator will interpret a final newline as starting a new (empty) line.
In text intended primarily to be read by humans using software which implements the word wrap feature, a newline character typically only needs to be stored if a line break is required independent of whether the next word would fit on the same line, such as between paragraphs and in vertical lists. See hard return and soft return.
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Software applications and operating systems usually represent a newline with one or two control characters:
Most textual Internet protocols (including HTTP, SMTP, FTP, IRC and many others) mandate the use of ASCII CR+LF (0x0D 0x0A) on the protocol level, but recommend that tolerant applications recognize lone LF as well. In practice, there are many applications that erroneously use the C newline character '\n' instead (see section Newline in programming languages below). This leads to problems when trying to communicate with systems adhering to a stricter interpretation of the standards; one such system is the qmail MTA that actively refuses to accept messages from systems that send bare LF instead of the required CR+LF.[2]
FTP has a feature to transform newlines between CR+LF and LF only when transferring text files. This must not be used on binary files. Usually binary files and text files are recognised by checking their filename extension.
The Unicode standard defines a large number of characters that conforming applications should recognize as line terminators:[3]
LF: Line Feed, U+000A
VT: Vertical Tab, U+000B
FF: Form Feed, U+000C
CR: Carriage Return, U+000D
CR+LF: CR (U+000D) followed by LF (U+000A)
NEL: Next Line, U+0085
LS: Line Separator, U+2028
PS: Paragraph Separator, U+2029
This may seem overly complicated compared to an approach such as converting all line terminators to a single character, for example LF. However, Unicode was designed to preserve all information when converting a text file from any existing encoding to Unicode and back. Therefore, Unicode should contain characters included in existing encodings. NEL is included in ISO-8859-1[citation needed] and EBCDIC (0x15). The approach taken in the Unicode standard allows round-trip transformation to be information-preserving while still enabling applications to recognize all possible types of line terminators.
Recognizing and using the newline codes greater than 0x7F is not often done. They are multiple bytes in UTF-8 and the code for NEL has been used as the ellipsis ('…') character in Windows-1252. For instance:
ASCII was developed simultaneously by the ISO and the ASA, the predecessor organization to ANSI. During the period of 1963–1968, the ISO draft standards supported the use of either CR+LF or LF alone as a newline, while the ASA drafts supported only CR+LF.
The sequence CR+LF was in common use on many early computer systems that had adopted Teletype machines, typically a Teletype Model 33 ASR, as a console device, because this sequence was required to position those printers at the start of a new line. On these systems, text was often routinely composed to be compatible with these printers, since the concept of device drivers hiding such hardware details from the application was not yet well developed; applications had to talk directly to the Teletype machine and follow its conventions.
Most minicomputer systems from DEC used this convention. CP/M used it as well, to print on the same terminals that minicomputers used. From there MS-DOS (1981) adopted CP/M's CR+LF in order to be compatible, and this convention was inherited by Microsoft's later Windows operating system.
The separation of the two functions concealed the fact that the print head could not return from the far right to the beginning of the next line in one-character time. That is why the sequence was always sent with the CR first. In fact, it was often necessary to send extra characters (extraneous CRs or NULs, which are ignored) to give the print head time to move to the left margin. Even many early video displays required multiple character times to scroll the display.
The Multics operating system began development in 1964 and used LF alone as its newline. Multics used a device driver to translate this character to whatever sequence a printer needed (including extra padding characters), and the single byte was much more convenient for programming. The seemingly more obvious choice of CR was not used, as a plain CR provided the useful function of overprinting one line with another, and thus it was useful to not translate it. Unix followed the Multics practice, and later systems followed Unix.
To facilitate the creation of portable programs, programming languages provide some abstractions to deal with the different types of newline sequences used in different environments.
The C programming language provides the escape sequences '\n' (newline) and '\r' (carriage return). However, these are not required to be equivalent to the ASCII LF and CR control characters. The C standard only guarantees two things:
On Unix platforms, where C originated, the native newline sequence is ASCII LF (0x0A), so '\n' was simply defined to be that value. With the internal and external representation being identical, the translation performed in text mode is a no-op, and text mode and binary mode behave the same. This has caused many programmers who developed their software on Unix systems simply to ignore the distinction completely, resulting in code that is not portable to different platforms.
The C library function fgets() is best avoided in binary mode because any file not written with the UNIX newline convention will be misread. Also, in text mode, any file not written with the system's native newline sequence (such as a file created on a UNIX system, then copied to a Windows system) will be misread as well.
Another common problem is the use of '\n' when communicating using an Internet protocol that mandates the use of ASCII CR+LF for ending lines. Writing '\n' to a text mode stream works correctly on Windows systems, but produces only LF on Unix, and something completely different on more exotic systems. Using "\r\n" in binary mode is slightly better.
Many languages, such as C++, Perl,[6] and Haskell provide the same interpretation of '\n' as C.
Java, PHP,[7] and Python[8] provide the '\r\n' sequence (for ASCII CR+LF). In contrast to C, these are guaranteed to represent the values U+000A and U+000D, respectively.
The Java I/O libraries do not transparently translate these into platform-dependent newline sequences on input or output. Instead, they provide functions for writing a full line that automatically add the native newline sequence, and functions for reading lines that accept any of CR, LF, or CR+LF as a line terminator (see BufferedReader.readLine()). The System.getProperty() method can be used to retrieve the underlying line separator.
Example:
String eol = System.getProperty( "line.separator" ); String lineColor = "Color: Red" + eol;
Python permits "Universal Newline Support" when opening a file for reading, when importing modules, and when executing a file.[9]
Some languages have created special variables, constants, and subroutines to facilitate newlines during program execution.
The different newline conventions often cause text files that have been transferred between systems of different types to be displayed incorrectly. For example, files originating on Unix or Apple Macintosh systems may appear as a single long line on some Windows programs. Conversely, when viewing a file originating from a Windows computer on a Unix system, the extra CR may be displayed as ^M at the end of each line or as a second line break.
The problem can be hard to spot if some programs handle the foreign newlines properly while others do not. For example, a compiler may fail with obscure syntax errors even though the source file looks correct when displayed on the console or in an editor. On a Unix system, the command cat -v myfile.txt will send the file to stdout (normally the terminal) and make the ^M visible, which can be useful for debugging. Modern text editors generally recognize all flavours of CR / LF newlines and allow the user to convert between the different standards. Web browsers are usually also capable of displaying text files and websites which use different types of newlines.
The File Transfer Protocol can automatically convert newlines in files being transferred between systems with different newline representations when the transfer is done in "ASCII mode". However, transferring binary files in this mode usually has disastrous results: Any occurrence of the newline byte sequence—which does not have line terminator semantics in this context, but is just part of a normal sequence of bytes—will be translated to whatever newline representation the other system uses, effectively corrupting the file. FTP clients often employ some heuristics (for example, inspection of filename extensions) to automatically select either binary or ASCII mode, but in the end it is up to the user to make sure his or her files are transferred in the correct mode. If there is any doubt as to the correct mode, binary mode should be used, as then no files will be altered by FTP, though they may display incorrectly.
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Text editors are often used for converting a text file between different newline formats; most modern editors can read and write files using at least the different ASCII CR/LF conventions. The standard Windows editor Notepad is not one of them (although Wordpad and the MS-DOS Editor are).
Editors are often unsuitable for converting larger files. For larger files (on Windows NT/2000/XP) the following command is often used:
TYPE unix_file | FIND "" /V > dos_file
On many Unix systems, the dos2unix (sometimes named fromdos or d2u) and unix2dos (sometimes named todos or u2d) utilities are used to translate between ASCII CR+LF (DOS/Windows) and LF (Unix) newlines. Different versions of these commands vary slightly in their syntax. However, the tr command is available on virtually every Unix-like system and is used to perform arbitrary replacement operations on single characters. A DOS/Windows text file can be converted to Unix format by simply removing all ASCII CR characters with
tr -d '\r' < inputfile > outputfile
or, if the text has only CR newlines, by converting all CR newlines to LF with
tr '\r' '\n' < inputfile > outputfile
The same tasks are sometimes performed with awk, sed, Tr_(Unix) or in Perl if the platform has a Perl interpreter:
awk '{sub("$","\r\n"); printf("%s",$0);}' inputfile > outputfile # UNIX to DOS (adding CRs on Linux and BSD based OS that haven't GNU extensions) awk '{gsub("\r",""); print;}' inputfile > outputfile # DOS to UNIX (removing CRs on Linux and BSD based OS that haven't GNU extensions) sed -e 's/$/\r/' inputfile > outputfile # UNIX to DOS (adding CRs on Linux based OS that use GNU extensions) sed -e 's/\r$//' inputfile > outputfile # DOS to UNIX (removing CRs on Linux based OS that use GNU extensions) cat inputfile | tr -d "\r" > outputfile # DOS to UNIX (removing CRs using tr(1). Not Unicode compliant.) perl -pe 's/\r?\n|\r/\r\n/g' inputfile > outputfile # Convert to DOS perl -pe 's/\r?\n|\r/\n/g' inputfile > outputfile # Convert to UNIX perl -pe 's/\r?\n|\r/\r/g' inputfile > outputfile # Convert to old Mac
To identify what type of line breaks a text file contains, the file command can be used. Moreover, the editor Vim can be convenient to make a file compatible with the Windows notepad text editor. For example:
[prompt] > file myfile.txt myfile.txt: ASCII English text [prompt] > vim myfile.txt within vim :set fileformat=dos :wq [prompt] > file myfile.txt myfile.txt: ASCII English text, with CRLF line terminators
The following grep commands echo the filename (in this case myfile.txt) to the command line if the file is of the specified style:
grep -PL $'\r\n' myfile.txt # show UNIX style file (LF terminated) grep -Pl $'\r\n' myfile.txt # show DOS style file (CRLF terminated)
For Debian-based systems, these commands are used:
egrep -L $'\r\n' myfile.txt # show UNIX style file (LF terminated) egrep -l $'\r\n' myfile.txt # show DOS style file (CRLF terminated)
The above grep commands work under Unix systems or in Cygwin under Windows. Note that these commands make some assumptions about the kinds of files that exist on the system (specifically it's assuming only UNIX and DOS-style files—no Mac OS 9-style files).
This technique is often combined with find to list files recursively. For instance, the following command checks all "regular files" (e.g. it will exclude directories, symbolic links, etc.) to find all UNIX-style files in a directory tree, starting from the current directory (.), and saves the results in file unix_files.txt, overwriting it if the file already exists:
find . -type f -exec grep -PL '\r\n' {} \; > unix_files.txt
This example will find C files and convert them to LF style line endings:
find -name '*.[ch]' -exec fromdos {} \;
The file command also detects the type of EOL used:
file myfile.txt > myfile.txt: ASCII text, with CRLF line terminators
Other tools permit the user to visualise the EOL characters:
od -a myfile.txt cat -e myfile.txt hexdump -c myfile.txt
dos2unix, unix2dos, mac2unix, unix2mac, mac2dos, dos2mac can perform conversions. The flip[10] command is often used.