From the documentation of EDITWORDBREAKPROCA callback function:
Parameters
code
Type: int
The action to be taken by the callback function. This parameter can be one of the following values.
WB_CLASSIFY
Retrieves the character class and word break flags of the character at the specified position. This value is for use with rich edit controls.
Return Value
Type: int
... If the code parameter specifies WB_CLASSIFY, the return value is the character class and word break flags of the character at the specified position. ...
From the documentation of EM_FINDWORDBREAK message:
Parameters
wParam
Specifies the find operation. This parameter can be one of the following values.
WB_CLASSIFY
Returns the character class and word-break flags of the character at the specified position.
Return value
The message returns a value based on the wParam parameter.
WB_CLASSIFY
Returns the character class and word-break flags of the character at the specified position.
My question is what is a character class in this context and what are valid values? What values are for the flags? I can't find any information on this anywhere.
MSDN says:
Word-break procedures for rich edit controls also group characters into character classes, each identified by a value in the range 0x00 through 0x0F. Breaks occur either after delimiters or between characters of different classes. Thus, a word-break procedure with different classes for alphanumeric and punctuation characters would find two word breaks in the string "Win.doc" (before and after the period).
A character's class can be combined with zero or more word-break flags to form an 8-bit value. When performing word-wrap operations, a rich edit control uses word-break flags to determine where it can break lines. Rich Edit uses the following word-break flags
WBF_BREAKAFTER Lines may be broken after the character.
WBF_BREAKLINE The character is a delimiter. Delimiters mark the ends of words. Lines may be broken after delimiters.
WBF_ISWHITE The character is a white-space character. Trailing white-space characters are not included in the length of a line when wrapping.
The WBF_BREAKAFTER value is used to allow wrapping after a character that does not mark the end of a word, such as a hyphen.
Which is not super helpful. You could perhaps invent your own class enum but I would suggest using GetStringTypeW.
I have seen .NET example code calling Char.GetUnicodeCategory but it seems to me like that will return values outside the documented range.
Apparently, I'm just blind. There's a link that could be found at the bottom of the page:
EM_FINDWORDBREAK message
...
Remarks
If wParam is WB_LEFT and WB_RIGHT, the word-break procedure finds word breaks only after delimiters. This matches the functionality of an edit control. If wParam is WB_MOVEWORDLEFT or WB_MOVEWORDRIGHT, the word-break procedure also compares character classes and word-break flags.
For information about character classes and word-break flags, see Word and Line Breaks.
As you can see, on the last line, there is a link to the information to another page that then goes to another which says:
How to Use Word and Line Break Information
Instructions
Use Word and Line Break Information
...
Word-break procedures for rich edit controls also group characters into character classes, each identified by a value in the range 0x00 through 0x0F. Breaks occur either after delimiters or between characters of different classes. Thus, a word-break procedure with different classes for alphanumeric and punctuation characters would find two word breaks in the string "Win.doc" (before and after the period).
A character's class can be combined with zero or more word-break flags to form an 8-bit value. When performing word-wrap operations, a rich edit control uses word-break flags to determine where it can break lines. Rich Edit uses the following word-break flags.
Flag Description
WBF_BREAKAFTER Lines may be broken after the character.
WBF_BREAKLINE The character is a delimiter. Delimiters mark the ends
of words. Lines may be broken after delimiters.
WBF_ISWHITE The character is a white-space character. Trailing
white-space characters are not included in the length
of a line when wrapping.
The WBF_BREAKAFTER value is used to allow wrapping after a character that does not mark the end of a word, such as a hyphen.
It's because of the second level of indirection that I didn't see it right away.
For some reason I need to fetch emails from /var/mail/username file. It seems like an append only file.
My question is, is it safe to parse the content of the /var/email/username file depending on the first line From username#host Mon Jun 20 16:50:15 2011? What if the similar pattern found inside the email body?
Furthermore, is there any opensource ruby script available for reference?
Yes, that seems like more or less the right way to parse the mbox format - from a quick scan of the RFC specification:
The structure of the separator lines
vary across implementations, but
usually contain the exact character
sequence of "From", followed by a
single Space character (0x20), an
email address of some kind, another
Space character, a timestamp sequence
of some kind, and an end-of- line
marker.
And...
Many implementations are also known
to escape message body lines that
begin with the character sequence of
"From ", so as to prevent confusion
with overly-liberal parsers that do
not search for full separator
lines. In the common case, a leading
Greater-Than symbol (0x3E) is used
for this purpose (with "From "
becoming ">From "). However, other
implementations are known not to
escape such lines unless they are
immediately preceded by a blank line
or if they also appear to contain
an email address and a timestamp.
Other implementations are also
known to perform secondary escapes
against these lines if they are
already escaped or quoted, while
others ignore these mechanisms
altogether.
Update:
There's also this: https://github.com/meh/ruby-mbox
Which characters make a URL invalid?
Are these valid URLs?
example.com/file[/].html
http://example.com/file[/].html
In general URIs as defined by RFC 3986 (see Section 2: Characters) may contain any of the following 84 characters:
ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-._~:/?#[]#!$&'()*+,;=
Note that this list doesn't state where in the URI these characters may occur.
Any other character needs to be encoded with the percent-encoding (%hh). Each part of the URI has further restrictions about what characters need to be represented by an percent-encoded word.
The '[' and ']' in this example are "unwise" characters but still legal. If the '/' in the []'s is meant to be part of file name then it is invalid since '/' is reserved and should be properly encoded:
http://example.com/file[/].html
To add some clarification and directly address the question above, there are several classes of characters that cause problems for URLs and URIs.
There are some characters that are disallowed and should never appear in a URL/URI, reserved characters (described below), and other characters that may cause problems in some cases, but are marked as "unwise" or "unsafe". Explanations for why the characters are restricted are clearly spelled out in RFC-1738 (URLs) and RFC-2396 (URIs). Note the newer RFC-3986 (update to RFC-1738) defines the construction of what characters are allowed in a given context but the older spec offers a simpler and more general description of which characters are not allowed with the following rules.
Excluded US-ASCII Characters disallowed within the URI syntax:
control = <US-ASCII coded characters 00-1F and 7F hexadecimal>
space = <US-ASCII coded character 20 hexadecimal>
delims = "<" | ">" | "#" | "%" | <">
The character "#" is excluded because it is used to delimit a URI from a fragment identifier. The percent character "%" is excluded because it is used for the encoding of escaped characters. In other words, the "#" and "%" are reserved characters that must be used in a specific context.
List of unwise characters are allowed but may cause problems:
unwise = "{" | "}" | "|" | "\" | "^" | "[" | "]" | "`"
Characters that are reserved within a query component and/or have special meaning within a URI/URL:
reserved = ";" | "/" | "?" | ":" | "#" | "&" | "=" | "+" | "$" | ","
The "reserved" syntax class above refers to those characters that are allowed within a URI, but which may not be allowed within a particular component of the generic URI syntax. Characters in the "reserved" set are not reserved in all contexts. The hostname, for example, can contain an optional username so it could be something like ftp://user#hostname/ where the '#' character has special meaning.
Here is an example of a URL that has invalid and unwise characters (e.g. '$', '[', ']') and should be properly encoded:
http://mw1.google.com/mw-earth-vectordb/kml-samples/gp/seattle/gigapxl/$[level]/r$[y]_c$[x].jpg
Some of the character restrictions for URIs and URLs are programming language-dependent. For example, the '|' (0x7C) character although only marked as "unwise" in the URI spec will throw a URISyntaxException in the Java java.net.URI constructor so a URL like http://api.google.com/q?exp=a|b is not allowed and must be encoded instead as http://api.google.com/q?exp=a%7Cb if using Java with a URI object instance.
Most of the existing answers here are impractical because they totally ignore the real-world usage of addresses like:
https://en.wikipedia.org/wiki/Möbius_strip or
https://zh.wikipedia.org/wiki/Wikipedia:关于中文维基百科/en.
First, a digression into terminology. What are these addresses? Are they valid URLs?
Historically, the answer was "no". According to RFC 3986, from 2005, such addresses are not URIs (and therefore not URLs, since URLs are a type of URIs). Per the terminology of 2005 IETF standards, we should properly call them IRIs (Internationalized Resource Identifiers), as defined in RFC 3987, which are technically not URIs but can be converted to URIs simply by percent-encoding all non-ASCII characters in the IRI.
Per modern spec, the answer is "yes". The WHATWG Living Standard simply classifies everything that would previously be called "URIs" or "IRIs" as "URLs". This aligns the specced terminology with how normal people who haven't read the spec use the word "URL", which was one of the spec's goals.
What characters are allowed under the WHATWG Living Standard?
Per this newer meaning of "URL", what characters are allowed? In many parts of the URL, such as the query string and path, we're allowed to use arbitrary "URL units", which are
URL code points and percent-encoded bytes.
What are "URL code points"?
The URL code points are ASCII alphanumeric, U+0021 (!), U+0024 ($), U+0026 (&), U+0027 ('), U+0028 LEFT PARENTHESIS, U+0029 RIGHT PARENTHESIS, U+002A (*), U+002B (+), U+002C (,), U+002D (-), U+002E (.), U+002F (/), U+003A (:), U+003B (;), U+003D (=), U+003F (?), U+0040 (#), U+005F (_), U+007E (~), and code points in the range U+00A0 to U+10FFFD, inclusive, excluding surrogates and noncharacters.
(Note that the list of "URL code points" doesn't include %, but that %s are allowed in "URL code units" if they're part of a percent-encoding sequence.)
The only place I can spot where the spec permits the use of any character that's not in this set is in the host, where IPv6 addresses are enclosed in [ and ] characters. Everywhere else in the URL, either URL units are allowed or some even more restrictive set of characters.
What characters were allowed under the old RFCs?
For the sake of history, and since it's not explored fully elsewhere in the answers here, let's examine was allowed under the older pair of specs.
First of all, we have two types of RFC 3986 reserved characters:
:/?#[]#, which are part of the generic syntax for a URI defined in RFC 3986
!$&'()*+,;=, which aren't part of the RFC's generic syntax, but are reserved for use as syntactic components of particular URI schemes. For instance, semicolons and commas are used as part of the syntax of data URIs, and & and = are used as part of the ubiquitous ?foo=bar&qux=baz format in query strings (which isn't specified by RFC 3986).
Any of the reserved characters above can be legally used in a URI without encoding, either to serve their syntactic purpose or just as literal characters in data in some places where such use could not be misinterpreted as the character serving its syntactic purpose. (For example, although / has syntactic meaning in a URL, you can use it unencoded in a query string, because it doesn't have meaning in a query string.)
RFC 3986 also specifies some unreserved characters, which can always be used simply to represent data without any encoding:
abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789-._~
Finally, the % character itself is allowed for percent-encodings.
That leaves only the following ASCII characters that are forbidden from appearing in a URL:
The control characters (chars 0-1F and 7F), including new line, tab, and carriage return.
"<>^`{|}
Every other character from ASCII can legally feature in a URL.
Then RFC 3987 extends that set of unreserved characters with the following unicode character ranges:
%xA0-D7FF / %xF900-FDCF / %xFDF0-FFEF
/ %x10000-1FFFD / %x20000-2FFFD / %x30000-3FFFD
/ %x40000-4FFFD / %x50000-5FFFD / %x60000-6FFFD
/ %x70000-7FFFD / %x80000-8FFFD / %x90000-9FFFD
/ %xA0000-AFFFD / %xB0000-BFFFD / %xC0000-CFFFD
/ %xD0000-DFFFD / %xE1000-EFFFD
These block choices from the old spec seem bizarre and arbitrary given the latest Unicode block definitions; this is probably because the blocks have been added to in the decade since RFC 3987 was written.
Finally, it's perhaps worth noting that simply knowing which characters can legally appear in a URL isn't sufficient to recognise whether some given string is a legal URL or not, since some characters are only legal in particular parts of the URL. For example, the reserved characters [ and ] are legal as part of an IPv6 literal host in a URL like http://[1080::8:800:200C:417A]/foo but aren't legal in any other context, so the OP's example of http://example.com/file[/].html is illegal.
In your supplementary question you asked if www.example.com/file[/].html is a valid URL.
That URL isn't valid because a URL is a type of URI and a valid URI must have a scheme like http: (see RFC 3986).
If you meant to ask if http://www.example.com/file[/].html is a valid URL then the answer is still no because the square bracket characters aren't valid there.
The square bracket characters are reserved for URLs in this format: http://[2001:db8:85a3::8a2e:370:7334]/foo/bar (i.e. an IPv6 literal instead of a host name)
It's worth reading RFC 3986 carefully if you want to understand the issue fully.
All valid characters that can be used in a URI (a URL is a type of URI) are defined in RFC 3986.
All other characters can be used in a URL provided that they are "URL Encoded" first. This involves changing the invalid character for specific "codes" (usually in the form of the percent symbol (%) followed by a hexadecimal number).
This link, HTML URL Encoding Reference, contains a list of the encodings for invalid characters.
Several of Unicode character ranges are valid HTML5, although it might still not be a good idea to use them.
E.g., href docs say http://www.w3.org/TR/html5/links.html#attr-hyperlink-href:
The href attribute on a and area elements must have a value that is a valid URL potentially surrounded by spaces.
Then the definition of "valid URL" points to http://url.spec.whatwg.org/, which says it aims to:
Align RFC 3986 and RFC 3987 with contemporary implementations and obsolete them in the process.
That document defines URL code points as:
ASCII alphanumeric, "!", "$", "&", "'", "(", ")", "*", "+", ",", "-", ".", "/", ":", ";", "=", "?", "#", "_", "~", and code points in the ranges U+00A0 to U+D7FF, U+E000 to U+FDCF, U+FDF0 to U+FFFD, U+10000 to U+1FFFD, U+20000 to U+2FFFD, U+30000 to U+3FFFD, U+40000 to U+4FFFD, U+50000 to U+5FFFD, U+60000 to U+6FFFD, U+70000 to U+7FFFD, U+80000 to U+8FFFD, U+90000 to U+9FFFD, U+A0000 to U+AFFFD, U+B0000 to U+BFFFD, U+C0000 to U+CFFFD, U+D0000 to U+DFFFD, U+E1000 to U+EFFFD, U+F0000 to U+FFFFD, U+100000 to U+10FFFD.
The term "URL code points" is then used in the statement:
If c is not a URL code point and not "%", parse error.
in a several parts of the parsing algorithm, including the schema, authority, relative path, query and fragment states: so basically the entire URL.
Also, the validator http://validator.w3.org/ passes for URLs like "你好", and does not pass for URLs with characters like spaces "a b"
Of course, as mentioned by Stephen C, it is not just about characters but also about context: you have to understand the entire algorithm. But since class "URL code points" is used on key points of the algorithm, it that gives a good idea of what you can use or not.
See also: Unicode characters in URLs
I needed to select characters to split URLs in a string, so I decided to create a list of characters which could not be found in the URL by myself:
>>> allowed = "-_.~!*'();:#&=+$,/?%#[]?#ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789"
>>> from string import printable
>>> ''.join(set(printable).difference(set(allowed)))
'`" <\x0b\n\r\x0c\\\t{^}|>'
So, the possible choices are the newline, tab, space, backslash and "<>{}^|. I guess I'll go with the space or newline. :)
I am implementing an old HTTP (0.9, 1.0, 1.1) request and response reader/writer. The request URI is the most problematic place.
You can't just use RFC 1738, 2396 or 3986 as it is. There are many old HTTP clients and servers that allow more characters. So I've made research based on accidentally published web server access logs: "GET URI HTTP/1.0" 200.
I've found that the following non-standard characters are often used in URIs:
\ { } < > | ` ^ "
These characters were described in RFC 1738 as unsafe.
If you want to be compatible with all old HTTP clients and servers - you have to allow these characters in the request URI.
Please read more information about this research in oghttp-request-collector.
This is not really an answer to your question, but validating URLs is really a serious p.i.t.a. You're probably just better off validating the domain name and leave query part of the URL be. That is my experience.
You could also resort to pinging the URL and seeing if it results in a valid response, but that might be too much for such a simple task.
Regular expressions to detect URLs are abundant, google it :)
I can't comment on the above answers, but wanted to emphasize the point (in another answer) that allowed characters aren't allowed everywhere. For example, domain names can't have underscores, so http://test_url.com is invalid.
From the source (emphasis added when needed):
Unsafe:
Characters can be unsafe for a number of reasons. The space character is unsafe because significant spaces may disappear and insignificant spaces may be introduced when URLs are transcribed or typeset or subjected to the treatment of word-processing programs.
The characters "<" and ">" are unsafe because they are used as the
delimiters around URLs in free text; the quote mark (""") is used to
delimit URLs in some systems. The character "#" is unsafe and should
always be encoded because it is used in World Wide Web and in other
systems to delimit a URL from a fragment/anchor identifier that might
follow it. The character "%" is unsafe because it is used for
encodings of other characters. Other characters are unsafe because
gateways and other transport agents are known to sometimes modify such
characters. These characters are "{", "}", "|", "", "^", "~", "[",
"]", and "`".
All unsafe characters must always be encoded within a URL. For
example, the character "#" must be encoded within URLs even in systems
that do not normally deal with fragment or anchor identifiers, so that
if the URL is copied into another system that does use them, it will
not be necessary to change the URL encoding.
Source
I came up with a couple of regular expressions for PHP that will convert URLs in text to anchor tags. (First it converts all www. URLs to http://, and then converts all URLs with https?:// to a href=... HTML links
$string = preg_replace('/(https?:\/\/)([!#$&-;=?\-\[\]_a-z~%]+)/sim', '$2', preg_replace('/(\s)((www\.)([!#$&-;=?\-\[\]_a-z~%]+))/sim', '$1http://$2', $string) );