length()
; see the description in the next section.
length("foo") => 3 length("") => 0
strsub("%n is a fink.", "%n", "Fred") => "Fred is a fink." strsub("foobar", "OB", "b") => "fobar" strsub("foobar", "OB", "b", 1) => "foobar"
index()
(rindex()
) returns the index of the first
character of the first (last) occurrence of str2 in str1, or zero
if str2 does not occur in str1 at all. By default the search for
an occurrence of str2 is done while ignoring the upper/lower case
distinction. If case-matters is provided and true, then case is treated
as significant in all comparisons.
index("foobar", "o") => 2 rindex("foobar", "o") => 3 index("foobar", "x") => 0 index("foobar", "oba") => 3 index("Foobar", "foo", 1) => 0
strcmp()
returns a negative integer. If the two strings are
identical, strcmp()
returns zero. Otherwise, strcmp()
returns a positive integer. The ASCII character ordering is used for the
comparison.
E_INVARG
if
bin_string is not a properly-formed binary string. (See the early
section on MOO value types for a full description of binary strings.)
decode_binary("foo") => {"foo"} decode_binary("~~foo") => {"~foo"} decode_binary("foo~0D~0A") => {"foo", 13, 10} decode_binary("foo~0Abar~0Abaz") => {"foo", 10, "bar", 10, "baz"} decode_binary("foo~0D~0A", 1) => {102, 111, 111, 13, 10}
encode_binary("~foo") => "~7Efoo" encode_binary({"foo", 10}, {"bar", 13}) => "foo~0Abar~0D" encode_binary("foo", 10, "bar", 13) => "foo~0Abar~0D"
match()
(rmatch()
) searches for the first (last)
occurrence of the regular expression pattern in the string subject.
If pattern is syntactically malformed, then E_INVARG
is raised.
The process of matching can in some cases consume a great deal of memory in the
server; should this memory consumption become excessive, then the matching
process is aborted and E_QUOTA
is raised.
If no match is found, the empty list is returned; otherwise, these functions return a list containing information about the match (see below). By default, the search ignores upper-/lower-case distinctions. If case-matters is provided and true, then case is treated as significant in all comparisons.
The list that match()
(rmatch()
) returns contains the details
about the match made. The list is in the form:
{start, end, replacements, subject}
where start is the index in subject of the beginning of the match,
end is the index of the end of the match, replacements is a list
described below, and subject is the same string that was given as the
first argument to the match()
or rmatch()
.
The replacements list is always nine items long, each item itself being a list of two integers, the start and end indices in string matched by some parenthesized sub-pattern of pattern. The first item in replacements carries the indices for the first parenthesized sub-pattern, the second item carries those for the second sub-pattern, and so on. If there are fewer than nine parenthesized sub-patterns in pattern, or if some sub-pattern was not used in the match, then the corresponding item in replacements is the list {0, -1}. See the discussion of `%)', below, for more information on parenthesized sub-patterns.
match("foo", "^f*o$") => {} match("foo", "^fo*$") => {1, 3, {{0, -1}, ...}, "foo"} match("foobar", "o*b") => {2, 4, {{0, -1}, ...}, "foobar"} rmatch("foobar", "o*b") => {4, 4, {{0, -1}, ...}, "foobar"} match("foobar", "f%(o*%)b") => {1, 4, {{2, 3}, {0, -1}, ...}, "foobar"}
Regular expression matching allows you to test whether a string fits into a specific syntactic shape. You can also search a string for a substring that fits a pattern.
A regular expression describes a set of strings. The simplest case is one that describes a particular string; for example, the string `foo' when regarded as a regular expression matches `foo' and nothing else. Nontrivial regular expressions use certain special constructs so that they can match more than one string. For example, the regular expression `foo%|bar' matches either the string `foo' or the string `bar'; the regular expression `c[ad]*r' matches any of the strings `cr', `car', `cdr', `caar', `cadddar' and all other such strings with any number of `a''s and `d''s.
Regular expressions have a syntax in which a few characters are special constructs and the rest are ordinary. An ordinary character is a simple regular expression that matches that character and nothing else. The special characters are `$', `^', `.', `*', `+', `?', `[', `]' and `%'. Any other character appearing in a regular expression is ordinary, unless a `%' precedes it.
For example, `f' is not a special character, so it is ordinary, and therefore `f' is a regular expression that matches the string `f' and no other string. (It does not, for example, match the string `ff'.) Likewise, `o' is a regular expression that matches only `o'.
Any two regular expressions a and b can be concatenated. The result is a regular expression which matches a string if a matches some amount of the beginning of that string and b matches the rest of the string.
As a simple example, we can concatenate the regular expressions `f' and `o' to get the regular expression `fo', which matches only the string `fo'. Still trivial.
The following are the characters and character sequences that have special meaning within regular expressions. Any character not mentioned here is not special; it stands for exactly itself for the purposes of searching and matching.
match()
or rmatch()
when the match succeeds; otherwise,
E_INVARG
is raised.
In template, the strings `%1' through `%9' will be replaced by
the text matched by the first through ninth parenthesized sub-patterns when
match()
or rmatch()
was called. The string `%0' in
template will be replaced by the text matched by the pattern as a whole
when match()
or rmatch()
was called. The string `%%' will
be replaced by a single `%' sign. If `%' appears in template
followed by any other character, E_INVARG
will be raised.
subs = match("*** Welcome to LambdaMOO!!!", "%(%w*%) to %(%w*%)"); substitute("I thank you for your %1 here in %2.", subs) => "I thank you for your Welcome here in LambdaMOO."
Aside from the possibly-random selection of the salt, the encryption algorithm
is entirely deterministic. In particular, you can test whether or not a given
string is the same as the one used to produce a given piece of encrypted text;
simply extract the first two characters of the encrypted text and pass the
candidate string and those two characters to crypt()
. If the result is
identical to the given encrypted text, then you've got a match.
crypt("foobar") => "J3fSFQfgkp26w" crypt("foobar", "J3") => "J3fSFQfgkp26w" crypt("mumble", "J3") => "J3D0.dh.jjmWQ" crypt("foobar", "J4") => "J4AcPxOJ4ncq2"
string_hash(x) == string_hash(y)
then, almost certainly,
equal(x, y)
This can be useful, for example, in certain networking applications: after
sending a large piece of text across a connection, also send the result of
applying string_hash()
to the text; if the destination site also
applies string_hash()
to the text and gets the same result, you can be
quite confident that the large text has arrived unchanged.