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The list of unicode unusual characters

Where can I get the complete list of all unicode characters that doesn't behave as simple characters. Examples: character 0x0363 (won't be printed without another one before), character 0x0084 (does weird things when printed). I need just a raw list of such unusual characters to replace them with something harmless to avoid unwanted output effects. Regular characters (those who not in this list) should use exactly one character place when printed (= cursor moved +1 to the right), should not depend on previous or next characters, and should not affect printing style in any way.
Edit because of multiple comments:
I have some unicode string, usually consists of "usual" characters like 0x20-0x7E or cyrillic letters. Also, there are a lot of other unicode characters that are usual and may be safely assumed as having strlen() = 1. The string is printed on the terminal and I should know the resulting position of the cursor. I don't want to use some complex and non-stable libraries to do that, i want to have simplest possible logic to do that. Every problematic character may be replaced with U+0xFFFD or something like "<U+0363>" (ASCII string with its index instead of character itself). I want to have a list of "possibly-problematic" characters to replace. It is acceptable to have some non-problematic characters in this list too, but not much.

There is no simple algorithm for this. You'll likely need a complex, but extremely stable library: libicu, or something based on it. Basically every other library that does this kind of work is based on libicu, which is maintained by the Unicode organization.
If you don't want to use the official library (or something based on their library), you'll need to parse the Unicode Character Database yourself. In particular, you need to look at Character Properties, and parse the files in the UCD.
I believe you're asking for Bidi_Class (i.e. "direction") to be Left_To_Right, Canonical_Combining_Class to be Not_Reordered, and Joining_Type to be Non_Joining.
You probably also want to check the General_Category and avoid M* (Marks) and C* (Other).
This should work for some Emoji, but this whole approach will break a lot of emoji that look simple and are not. Most famously: ❤️, which is two "characters," not one. You may want to filter out Emoji. As a simple starting point, you may want to restrict yourself to the Basic Multilingual Plane (BMP), which are code points 0000-FFFF. Anything above this range is, almost by definition, rare or unusual. The BMP does include some emoji, but most emoji (and all new emoji) are outside the range.
Remember that the glyphs for single characters can still have radically different widths, even in nominally fixed-width fonts. For example, 𒈙 (U+12219 CUNEIFORM SIGN LUGAL OPPOSING LUGAL) is a completely "normal" character in the way you're describing. It is left-to-right. It doesn't depend on or influence characters around it (it's non-combining and non-joining). Its "length in characters" is 1. Its glyph is also extremely wide in most fonts and breaks a lot of layout. I don't know anything in the Unicode database that would warn you of this, since "glyph width" is entirely a function of fonts, not characters, and Unicode explicitly does not consider fonts. (That said, most of the most problematic characters are outside the BMP. Probably the most common exception is DŽ, but many fixed-width fonts have a narrow glyph for it: DŽ.)
Let's write some cuneiform in a fixed-width font.
Normally, every character should line up with a character above.
Here: 𒈙. See how these characters don't align correctly?
Not only is it a very wide glyph, but its width is not even a multiple.
At least not in my font (Mac Safari 15.0).
But DŽ is ok.
Also remember that there are multiple ways to encode the same "character." For example, é can be a "simple" character (U+00E9), or it can be two characters (U+0065, U+0301). So in some cases é may print in your scheme, and in others it won't. I suspect this is fine for your problem, but if it isn't, you're going to need to apply a normalization form (likely NFC).

Will precluding surrogate code points also impede entering Chinese characters?

I have a name input field in an app and would like to prevent users from entering emojis. My idea is to filter for any characters from the general categories "Cs" and "So" in the Unicode specification, as this would prevent the bulk of inappropriate characters but allow most characters for writing natural language.
But after reading the spec, I'm not sure if this would preclude, for example, a Pinyin keyboard from submitting Chinese characters that need supplemental code points. (My understanding is still rough.)
Would excluding surrogates still leave most Chinese users with the characters they need to enter their names, or is the original Unicode space not big enough for that to be a reasonable expectation?

Your method would be both ineffective and too excessive.
Not all emoji are outside of the Basic Multilingual Plane (and thus don’t require surrogates in the first place), and not all emoji belong to the general category So. Filtering out only these two groups of characters would leave the following emoji intact:
#️⃣ *️⃣ 0️⃣ 1️⃣ 2️⃣ 3️⃣ 4️⃣ 5️⃣ 6️⃣ 7️⃣ 8️⃣ 9️⃣ ‼️ ⁉️ ℹ️ ↔️ ◼️ ◻️ ◾️ ◽️ ⤴️ ⤵️ 〰️ 〽️
At the same time, this approach would also exclude about 79,000 (and counting) non-emoji characters covering several dozen scripts – many of them historic, but some with active user communities. The majority of all Han (Chinese) characters for instance are encoded outside the BMP. While most of these are of scholarly interest only, you will need to support them regardless especially when you are dealing with personal names. You can never know how uncommon your users’ names might be.
This whole ordeal also hinges on the technical details of your app. Removing surrogates would only work if the framework you are using encodes strings in a format that actually employs surrogates (i.e. UTF-16) and if your framework is simultaneously not aware of how UTF-16 really works (as Java or JavaScript are, for example). Surrogates are never treated as actual characters; they are exceptionally reserved codepoints that exist for the sole purpose of allowing UTF-16 to deal with characters in the higher planes. Other Unicode encodings aren’t even allowed to use them at all.
If your app is written in a language that either uses a different encoding like UTF-8 or is smart enough to process surrogates correctly, then removing Cs characters on input is never going to have any effect because no individual surrogates are ever being exposed to your program. How these characters are entered by the user does not matter because all your app gets to see is the finished product (the actual character codepoints).
If your goal is to remove all emoji and only emoji, then you will have to put a lot of effort into designing your code because the Unicode emoji spec is incredibly convoluted. Most emoji nowadays are constructed out of multiple characters, not all of which are categorised as emoji by themselves. There is no easy way to filter out just emoji from a string other than maintaining an explicit list of every single official emoji which would need to be steadily updated.

Will precluding surrogate code points also impede entering Chinese characters? […] if this would preclude, for example, a Pinyin keyboard from submitting Chinese characters that need supplemental code points.
You cannot intercept how characters are entered, whether via input method editor, copy-paste or dozens of other possibilities. You only get to see a character when it is completed (and an IME's work is done), or depending on the widget toolkit, even only after the text has been submitted. That leaves you with validation. Let's consider a realistic case. From Unihan_Readings.txt 12.0.0 (2018-11-09):
U+20009 ‹𠀉› (the same as U+4E18 丘) a hill; elder; empty; a name
U+22218 ‹𢈘› variant of 鹿 U+9E7F, a deer; surname
U+22489 ‹𢒉› a surname
U+224B9 ‹𢒹› surname
U+25874 ‹𥡴› surname
Assume the user enters 𠀉, then your unnamed – but hopefully Unicode compliant – programming language must consider the text on the grapheme level (1 grapheme cluster) or character level (1 character), not the code unit level (surrogate pair 0xD840 0xDC09). That means that it is okay to exclude characters with the Cs property.

Unicode Character COMBINING LATIN SMALL LETTER C

What is the likelihood that I'll run into COMBINING LATIN SMALL LETTER C (U+0368) in "real life" (besides clever Scottish folk)?
I'm asking since it's in both the Unicode Block Combining Diacritical Marks and the Category Mark, Nonspacing [Mn].
As a result, it seems to gets treated the same as characters such as COMBINING GRAVE ACCENT (U+0300) by Utilities such as the ICU Transliterator (using either the suggested "NFD; [:Nonspacing Mark:] Remove; NFC" or a straight "Latin-ASCII" transliteration).

The likelihood is very close to zero, but not exactly zero. You cannot prevent anyone from using a Unicode character as he likes. There is no specific information about U+0368 in the Unicode Standard, but it has definitely been defined as a combining character that will cause a symbol (c) to be displayed above the preceding character. I would expect to find it mostly in digitized forms of medieval manuscripts, or something like that.
Using it after a space character, as in the “clever” page mentioned, is not the intended use, but not invalid either. Unicode lets you use any combining mark after any character, whether it makes sense or not.
It has no canonical or compatibility decomposition, so there is no clear-cut way to deal with in a context where you cannot, or do not want to, retain the character.

The likelihood is utterly indeterminate except to say that if you expect it not to occur, then it will occur.

Subset of Unicode normally used in writing?

What is the subset of Unicode characters that are normally used in writing — such as those that would be typically found in a newspaper article?
For example, in English, the characters in the range [a-zA-Z0-9], plus some punctuation characters, would be sufficient for most writing.
But I want to support languages that use characters that fall outside the ASCII range, while excluding the non-printing or decorative characters.
The objective is to restrict the user input to the application to codepoints that are legitimately used in written language. Because the user input will be saved and displayed, I do not want to allow pranksters to input text consisting entirely of things like diacritics, Unicode combining characters, Unicode flow control characters, etc.
Regrettably, I am not fluent in every single language found in Unicode. Has anyone compiled a list of all of the subset of Unicode characters that are normally used in writing?

The official list of Unicode code points is UnicodeData.txt. This is a plain text file with one line per code point; it's easily machine-readable. For example:
0022;QUOTATION MARK;Po;0;ON;;;;;N;;;;;
The third semicolon-delimited field is the abbreviated name of the "General Category". This is explained further in chapter 4 of the Unicode Standard, specifically in section 4.5; see the table on page 131 (page 12 of the PDF file). For example, "Lu" is uppercase letters, "Ll" is lowercase letters, Pc, Pd, Ps, et al are various kinds of punctuation. (The first letter of the two-letter abbreviation represents a higher-level category such as letter, digit, punctuation, etc.)
Note that some ranges of code points are not listed explicitly. For example, the range of CJK (Chinese, Japanese, Korean) ideographs is represented as:
4E00;<CJK Ideograph, First>;Lo;0;L;;;;;N;;;;;
9FCC;<CJK Ideograph, Last>;Lo;0;L;;;;;N;;;;;
I think there are other files on unicode.org that fill in these gaps.
I'm still not 100% clear on just what subset you're trying to define, but you can probably define it as a particular set of General Category values.

I do not want to allow pranksters to input text consisting entirely of things like diacritics, Unicode combining characters
Diacritics/combining characters will be used in normal written language. So if you want to stop 'pranksters' you're going to need something more sophisticated than just a list of permitted characters. You'll have to do some sort of linguistic analysis for every language you want to permit.
I'd recommend not bothering with this, because it's going to be hard and you won't succeed anyway. Just let people write what they want.

Try WGL4 (652 characters), MES-1 (335 characters) or MES-2 (1062 characters). Find these at Wikipedia.
You may wish to exclude characters IJijĸĿŀʼn˚―⅛⅜⅝⅞♪ from MES-1 if you want to use this set.
Edit: I realize this is a bad answer. Especially the removing characters from MES-1 part was total garbage. I shouldn't have posted this. I'm ashamed of whoever upvoted this.
If anything, use Subset1 (678 characters), Subset2 (1193 characters) and Subset3 (2823 characters). https://unicodesubsets.miraheze.org/wiki/User:PiotrGrochowski

What is the range of Unicode Printable Characters?

Can anybody please tell me what is the range of Unicode printable characters? [e.g. Ascii printable character range is \u0020 - \u007f]

See, http://en.wikipedia.org/wiki/Unicode_control_characters
You might want to look especially at C0 and C1 control character http://en.wikipedia.org/wiki/C0_and_C1_control_codes
The wiki says, the C0 control character is in the range U+0000—U+001F and U+007F (which is the same range as ASCII) and C1 control character is in the range U+0080—U+009F
other than C-control character, Unicode also has hundreds of formatting control characters, e.g. zero-width non-joiner, which makes character spacing closer, or bidirectional text control. This formatting control characters are rather scattered.
More importantly, what are you doing that requires you to know Unicode's non-printable characters? More likely than not, whatever you're trying to do is the wrong approach to solve your problem.

This is an old question, but it is still valid and I think there is more to usefully, but briefly, say on the subject than is covered by existing answers.
Unicode
Unicode defines properties for characters.
One of these properties is "General Category" which has Major classes and subclasses. The Major classes are Letter, Mark, Punctuation, Symbol, Separator, and Other.
By knowing the properties of your characters, you can decide whether you consider them printable in your particular context.
You must always remember that terms like "character" and "printable" are often difficult and have interesting edge-cases.
Programming Language support
Some programming languages assist with this problem.
For example, the Go language has a "unicode" package which provides many useful Unicode-related functions including these two:
func IsGraphic(r rune) bool
IsGraphic reports whether the rune is defined as a Graphic by Unicode. Such
characters include letters, marks, numbers, punctuation, symbols, and spaces,
from categories L, M, N, P, S, Zs.
func IsPrint(r rune) bool
IsPrint reports whether the rune is defined as printable by Go. Such
characters include letters, marks, numbers, punctuation, symbols, and
the ASCII space character, from categories L, M, N, P, S and the ASCII
space character. This categorization is the same as IsGraphic except
that the only spacing character is ASCII space, U+0020.
Notice that it says "defined as printable by Go" not by "defined as printable by Unicode". It is almost as if there are some depths the wizards at Unicode dare not plumb.
Printable
The more you learn about Unicode, the more you realise how unexpectedly diverse and unfathomably weird human writing systems are.
In particular whether a particular "character" is printable is not always obvious.
Is a zero-width space printable? When is a hyphenation point printable? Are there characters whose printability depends on their position in a word or on what characters are adjacent to them? Is a combining-character always printable?
Footnotes
ASCII printable character range is \u0020 - \u007f
No it isn't. \u007f is DEL which is not normally considered a printable character. It is, for example, associated with the keyboard key labelled "DEL" whose earliest purpose was to command the deletion of a character from some medium (display, file etc).
In fact many 8-bit character sets have many non-consecutive ranges which are non-printable. See for example C0 and C1 controls.

First, you should remove the word 'UTF8' in your question, it's not pertinent (UTF8 is just one of the encodings of Unicode, it's something orthogonal to your question).
Second: the meaning of "printable/non printable" is less clear in Unicode. Perhaps you mean a "graphical character" ; and one can even dispute if a space is printable/graphical. The non-graphical characters would consist, basically, of control characters: the range 0x00-0x0f plus some others that are scattered.
Anyway, the vast majority of Unicode characters (more than 200.000) are "graphical". But this certainly does not imply that they are printable in your environment.
It seems to me a bad idea, if you intend to generate a "random printable" unicode string, to try to include all "printable" characters.

What you should do is pick a font, and then generate a list of which Unicode characters have glyphs defined for your font. You can use a font library like freetype to test glyphs (test for FT_Get_Char_Index(...) != 0).

Taking the opposite approach to #HoldOffHunger, it might be easier to list the ranges of non-printable characters, and use not to test if a character is printable.
In the style of Regex (so if you wanted printable characters, place a ^):
[\u0000-\u0008\u000B-\u001F\u007F-\u009F\u2000-\u200F\u2028-\u202F\u205F-\u206F\u3000\uFEFF]
Which accounts for things like separator spaces and joiners
Note that unlike their answer which is a whitelist that ignores all non-latin languages, this blacklist wont permit non-printable characters just because they're in blocks with printable characters (their answer wholly includes Non-Latin, Language Supplement blocks as 'printable', even though it contains things like 'zero-width non-joiner'..).
Be aware though, that if using this or any other solution, for sanitation for example, you may want to do something more nuanced than a blanket replace.
Arguably in that case, non-breaking spaces should change to space, not be removed, and invisible separator should be replaced with comma conditionally.
Then there's invalid character ranges, either [yet] unused or reserved for encoding purposes, and language-specific variation selectors..
NB when using regular expressions, that you enable unicode awareness if it isn't that way by default (for javascript it's via /.../u).
You can tell if you have it correct by attempting to create the regular expression with some multi-byte character ranges.
For example, the above, plus the invalid character range \u{E0100}-\u{E01EF} in javascript:
/[\u0000-\u0008\u000B-\u001F\u007F-\u009F\u2000-\u200F\u2028-\u202F\u205F-\u206F\u3000\uFEFF\u{E0100}-\u{E01EF}]/u
Without u \u{E0100}-\u{E01EF} equates to \uDB40(\uDD00-\uDB40)\uDDEF, not (\uDB40\uDD00)-(\uDB40\uDDEF), and if replacing you should always enable u even when not including multbyte unicode in the regex itself as you might break surrogate pairs that exist in the text.

What characters are valid?
At present, Unicode is defined as starting from U+0000 and ending at U+10FFFF. The first block, Basic Latin, spans U+0000 to U+007F and the last block, Supplementary Private Use Area-B, spans U+100000 to 10FFFF. If you want to see all of these blocks, see here: Wikipedia.org: Unicode Block; List of Blocks.
Let's break down what's valid/invalid in the Latin Block1.
The Latin Block: TLDR
If you're interested in filtering out either invisible characters, you'll want to filter out:
U+0000 to U+0008: Control
U+000E to U+001F: Device (i.e., Control)
U+007F: Delete (Control)
U+008D to U+009F: Device (i.e., Control)
The Latin Block: Full Ranges
Here's the Latin block, broken up into smaller sections...
U+0000 to U+0008: Control
U+0009 to U+000C: Space
U+000E to U+001F: Device (i.e., Control)
U+0020: Space
U+0021 to U+002F: Symbols
U+0030 to U+0039: Numbers
U+003A to U+0040: Symbols
U+0041 to U+005A: Uppercase Letters
U+005B to U+0060: Symbols
U+0061 to U+007A: Lowercase Letters
U+007B to U+007E: Symbols
U+007F: Delete (Control)
U+0080 to U+008C: Latin1-Supplement symbols.
U+008D to U+009F: Device (i.e., Control)
U+00A0: Non-breaking space. (i.e., )
U+00A1 to U+00BF: Symbols.
U+00C0 to U+00FF: Accented characters.
The Other Blocks
Unicode is famous for supporting non-Latin character sets, so what are these other blocks? This is just a broad overview, see the wikipedia.org page for the full, complete list.
Latin1 & Latin1-Related Blocks
U+0000 to U+007F : Basic Latin
U+0080 to U+00FF : Latin-1 Supplement
U+0100 to U+017F : Latin Extended-A
U+0180 to U+024F : Latin Extended-B
Combinable blocks
U+0250 to U+036F: 3 Blocks.
Non-Latin, Language blocks
U+0370 to U+1C7F: 55 Blocks.
Non-Latin, Language Supplement blocks
U+1C80 to U+209F: 11 Blocks.
Symbol blocks
U+20A0 to U+2BFF: 22 Blocks.
Ancient Language blocks
U+2C00 to U+2C5F: 1 Block (Glagolitic).
Language Extensions blocks
U+2C60 to U+FFEF: 66 Blocks.
Special blocks
U+FFF0 to U+FFFF: 1 Block (Specials).

One approach is to render each character to a texture and manually check if it is visible. This solution excludes spaces.
I've written such a program and used it to determine there are roughly 467241 printable characters within the first 471859 code points. I've selected this number because it covers all of the first 4 Planes of Unicode, which seem to contain all printable characters. See https://en.wikipedia.org/wiki/Plane_(Unicode)
I would much like to refine my program to produce the list of ranges, but for now here's what I am working with for anyone who needs immediate answers:
https://editor.p5js.org/SamyBencherif/sketches/_OE8Y3kS9
I am posting this tool because I think this question attracts a lot of people who are looking for slightly different applications of knowing printable ranges. Hopefully this is useful, even though it does not fully answer the question.

The printable Unicode character range, excluding the hex, is 32 to 126 in the int datatype.

Unicode, stict term, has no range. Numbers can go infinite.
What you gave is not UTF8 which has 1 byte for ASCII characters.
As for the range, I believe there is no range of printable characters. It always evolves. Check the page I gave above.