awk seems to match all the patterns matching an expression and executes the corresponding actions. Is there a precedence that can be associated ?
For eg. In the below, lines starting with # (comments) are matched by both patterns, and both actions are executed. I want commented lines to match only the first action.
/^#.*/ {
// Action for lines starting with '#'
}
{
// Action for other lines
}
If you want to keep the code you already have mostly intact, you could just use the awk next statement. Once you encounter the next statement, awk skips processing the current record and goes to the next line.
So if you put next into the bottom your 1st block the 2nd block wouldn't be executed.
Why not simply if,else :
awk '{ if ($0 ~ /^#/)
// Action for lines starting with '#'
else
// Action for other lines
}'
Your other option is to use the pattern negation operator, '!', for the "everything else" line, if your match options are binary:
/^#.*/ {
// Action for lines starting with '#'
}
!/^#.*/ {
// Action for other lines
}
Of course, your second pattern could also simply match everything that doesn't start with a hash, i.e. /^[^#].*/
But presumably, your example is a simplification. For complex regular expressions, crafting the exact inverse match could be impossible. The negation operator just makes it explicit and foolproof.
And, as you may already know, the ".*" part is unnecessary.
Related
I have a simple grammar, and I am using it to parse some text. The text is user inputted, but my program guarantees that it stars with a match to the grammar. (ie, if my grammar matched only a, the text might be abc or a or a_.) However, when I use the .parse method on my grammar, it fails on any non-exact match. How can I perform a partial match?
In Raku, Grammar.parse has to match the whole string. This is what causes it to fail if your grammar would only match a in the string abc. To allow matching only part of the input string, you can use Grammar.subparse instead.
grammar Foo {
token TOP { 'a' }
}
my $string = 'abc';
say Foo.parse($string); # Nil
say Foo.subparse($string); # 「a」
The input string will need to start with the potential Match. Otherwise, you will get a failed match.
say Foo.subparse('cbacb'); # #<failed match>
You can work around this using a Capture marker.
grammar Bar {
token TOP {
<-[a]>* # Match 0 or more characters that are *not* a
<( 'a' # Start the match, and match a single 'a'
}
}
say Bar.parse('a'); # 「a」
say Bar.subparse('a'); # 「a」
say Bar.parse('abc'); # Nil
say Bar.subparse('abc'); # 「a」
say Bar.parse('cbabc'); # Nil
say Bar.subparse('cbabc'); # 「a」
This works because <-[a]>*, a character class that includes any character except the letter a, will consume all the characters before a potential a. However, the Capture marker will cause these to be dropped from the eventual Match object, leaving you with just the a you wanted to match.
TL;DR
grammar foo { token TOP { a* } }
# Partial match anchored at start of string:
say .subparse: 'abcaa' given foo; # 「a」
# Partial match anchored to end of string:
say 'abcaa' ~~ / <.foo::TOP> $ /; # 「aa」
# Longest partial match, no anchoring:
say ('abcaaabcaabc' ~~ m:g/ <.foo::TOP> /).max(*.chars); # 「aaa」
Vocabulary
There are traditionally two takes on the general notion of text "matching":
"Parsing"
"Regexes"
Raku:
Provides a unified text pattern language and engine that do both jobs.
Makes it easy to stick to one perspective, or other, or blend them, or refactor between them, as suits an individual dev and/or individual use case.
Takes "parsing" to mean more or less a single match starting at the start of the input string whereas "regexes" are much more flexible.
What you've written in your question and your first comment on Tyil's answer reflects the inherent ambiguity of the topic. I'll provide two answers rather than one to try help you and/or other readers to be clearer about Raku's use of vocabulary, and your options functionality wise.
Limited "partial matching" via .parse et al
You began with:
Partial match in a grammar ... I have a simple grammar ... my program guarantees that it starts with a match to the grammar
With that in mind, here's your question:
How can I perform a partial match?
The phrases "guarantees that it starts" and "partial match" are ambiguous.
One take is that you want what I'll call a "prefix" match, matching one or more characters anchored from the start of the string, and not merely any sub-string starting and ending anywhere in the input string.
This nicely fits with "parsing", or at least Raku's use of the word in its grammar methods.
All the built in Grammar methods with parse in their name insert an anchor to the start of the string in whatever grammar rule they use to start the parsing process. You cannot remove that anchor. This reflects the choice of vocabulary; "parse" is taken to mean matching from the start no matter what else happens.
The parse method for this "prefix" scenario is .subparse:
grammar foo { token TOP { a* } }
# Partial match anchored at start of string:
say .subparse: 'abcaa' given foo; # 「a」
See also:
Search of SO for "[raku] subparse".
raku doc for .subparse.
But perhaps "guarantees that it starts" and "partial match" did not mean that you wanted anchoring at the start. Your comment on Tyil's answer highlights this ambiguity:
Will .subparse only match at the start, or match anywhere in the string?
Tyil provides a workaround. You can do what Tyil shows, but it'll only match if the very first a encountered in the input string is the one that's at the start of the sub-string you want your "parse" to match.
If instead the first a was a false positive, and there was a second or a subsequent a you wanted the "parse" match to start at, then, at least in the Raku world, it's helpful to call that "regexing" rather than "parsing" and to use "regex" matching via the ~~ smartmatch operator.
Unlimited "partial matching" via ~~
Raku lets you do unlimited partial matching if you use its ~~ construct with a regex.
For example, you could write:
# End of match at end of string:
↓
say 'abcaa' ~~ token { a* $ } # 「aa」
~~ with a regex tells Raku to:
Try match starting at the first character position in the string on the LHS;
If that fails, step forward one character, and try again, with the new position in the input string treated as a fresh starting point;
Repeat that until either matching once, or failing to find any match in the entire string.
Here I've left the start position of the match unspecified (which ~~ takes to mean it can be anywhere in the string) and anchored the end of the pattern to the end of the input string. So it successfully matches the aa at the end of the string.
This anchoring freedom illustrates just one of the many ways that ~~ smart matching provides much greater matching flexibility than using the parse methods.
If you have an existing grammar you can still use that:
grammar foo { token TOP { a* } }
# Anchor matching to end of string:
↓
say 'abcaa' ~~ / <.foo::TOP> $ /; # 「aa」
You have to name both the grammar and the rule within it you wish to invoke and put them inside <...>. And you need to insert a . to avoid a correspondingly named sub-capture, presuming you don't want that.
Here's another example:
# Longest partial match, no anchoring:
say ('abcaaabcaabc' ~~ m:g/ <.foo::TOP> /).max(*.chars); # 「aaa」
"Parsing" in Raku always starts at the beginning of an input string and results in either no match or one match.
In contrast, a "regex" can match arbitrary fragments, and can match any number of fragments. (You can even match overlapping fragments.)
In my last example I used :g, which is short for :global, which is a well known feature among traditional regex engines. :g matches as many times as a match is found in the input string (but not overlapping).
The match operation then returns either Nil (no matches at all) or a list of match objects (one or more). I've applied a .max(*.chars) to yield the longest match (the first if there are multiple longest sub-strings).
I've been trying to learn Perl6 from Perl5, but the issue is that the regex works differently, and it isn't working properly.
I am making a test case to list all files in a directory ending in ".p6$"
This code works with the end character
if 'read.p6' ~~ /read\.p6$/ {
say "'read.p6' contains 'p6'";
}
However, if I try to fit this into a subroutine:
multi list_files_regex (Str $regex) {
my #files = dir;
for #files -> $file {
if $file.path ~~ /$regex/ {
say $file.path;
}
}
}
it no longer works. I don't think the issue with the regex, but with the file name, there may be some attribute I'm not aware of.
How can I get the file name to match the regex in Perl6?
Regexes are a first-class language within Perl 6, rather than simply strings, and what you're seeing here is a result of that.
The form /$foo/ in Perl 6 regex will search for the string value in $foo, so it will be looking, literally, for the characters read\.p6$ (that is, with the dot and dollar sign).
Depending on the situation of the calling code, there are a couple of options:
If you really are receiving regexes as strings, for example read as input or from a file, then use $file.path ~~ /<$regex>/. This means it will treat what's in $regex as regex syntax.
If you will just be passing a range of different regexes in, change the parameter to be of type Regex, and then do $file.path ~~ $regex. In this case, you'd pass them like list_files_regex(/foo/).
Last but not least, dir takes a test parameter, and so you can instead write:
for dir(test => /<$regex>/) -> $file {
say $file.path;
}
I have two questions. Is the behavior I show correct, and if so, is it documented somewhere?
I was playing with the grammar TOP method. Declared as a rule, it implies beginning- and end-of-string anchors along with :sigspace:
grammar Number {
rule TOP { \d+ }
}
my #strings = '137', '137 ', ' 137 ';
for #strings -> $string {
my $result = Number.parse( $string );
given $result {
when Match { put "<$string> worked!" }
when Any { put "<$string> failed!" }
}
}
With no whitespace or trailing whitespace only, the string parses. With leading whitespace, it fails:
<137> worked!
<137 > worked!
< 137 > failed!
I figure this means that rule is applying :sigspace first and the anchors afterward:
grammar Foo {
regex TOP { ^ :sigspace \d+ $ }
}
I expected a rule to allow leading whitespace, which would happen if you switched the order:
grammar Foo {
regex TOP { :sigspace ^ \d+ $ }
}
I could add an explicit token in rule for the beginning of the string:
grammar Number {
rule TOP { ^ \d+ }
}
Now everything works:
<137> worked!
<137 > worked!
< 137 > worked!
I don't have any reason to think it should be one way or the other. The Grammars docs say two things happen, but the docs do not say which order these effects apply:
Note that if you're parsing with .parse method, token TOP is automatically anchored
and
When rule instead of token is used, any whitespace after an atom is turned into a non-capturing call to ws.
I think the answer is that the rule isn't actually anchored in the pattern sense. It's the way .parse works. The cursor has to start at position 0 and end at the last position in the string. That's something outside of the pattern.
The behavior is intended, and is a culmination of these language features:
Sigspace ignores whitespace before the first atom.
From the design docs1 (S05: Regexes and Rules, line 348, emphasis added):
The new :s (:sigspace) modifier causes certain whitespace sequences to be considered "significant"; they are replaced by a whitespace matching rule, . Only whitespace sequences immediately following a matching construct (atom, quantified atom, or assertion) are eligible. Initial whitespace is ignored at the front of any regex, to make it easy to write rules that can participate in longest-token-matching alternations. Trailing space inside the regex delimiters is significant.
This means:
rule TOP { \d+ }
^-------- <.ws> automatically inserted
rule TOP { ^ \d+ $ }
^---^-^---- <.ws> automatically inserted
Regexes are first-class compiled code with lexical scoping.
A regex/rule is not a string that may have characters concatenated to it later to change its behavior. It is a self-contained routine, which is parsed and has its behavior nailed down at compile time.
Regex modifiers like :sigspace, including the one implicitly added by the rule keyword, apply only to their lexical scope - i.e. to the fragment of source code they appear in at compile time. S05, line 6291:
The :i, :m, :r, :s, :dba, :Perl5, and Unicode-level modifiers can be placed inside the regex (and are lexically scoped)
The anchoring of rule TOP is done at run time by .parse.
S05, line 44231:
The .parse and .parsefile methods anchor to the beginning and ending of the text, and fail if the end of text is not reached. (The TOP rule can check against $ itself if it wishes to produce its own error message.)
I.e. the anchoring to the beginning of the string is not intrinsic to the rule TOP, and doesn't affect how the lexical scope of TOP is parsed and compiled. It is done when method .parse is called.
It has to be this way, because because the same grammar can be used with different starting rules instead of TOP, using .parse(..., rule => ...).
So when you write
rule TOP { \d+ }
it is compiled as
regex TOP { :r \d+ <.ws> }
And when you .parse that grammar, it effectively invokes the regex code ^ <TOP> $, with the anchors not being part of TOP's lexical scope but rather of a scope that merely calls the routine TOP. The combined behavior is as if the rule TOP had been written as:
regex TOP { ^ [:r :s \d+] $ }
1) The design docs are in general not to be taken as gospel for what is or isn't part of the Perl 6 language, but S05 is pretty accurate in that regard, except that it mentions some features that haven't been implemented yet but are planned. Anyone who wants to truly grok the intricacies of Perl 6 regexes/grammars, is IMO well served by reading the full S05 from top to bottom at least once.
There aren't two regex effects going on. The rule applies :sigspace. After that, the grammar is defined. When you call .parse, it starts at the beginning of the string and goes to the end (or fails). That anchoring isn't part of the grammar. It's part of how .parse applies the grammar.
My main issue was the odd way some of the things are worded in the docs. They aren't technically wrong, but they also tend to assume knowledge about things the reader might not know. In this case, the casual comment about anchoring TOP isn't as special as it seems. Any rule passed to .parse is anchored in the same way. There's no special behavior for that rule name other than it's the default value for :rule in a call to .parse.
I do not know how to pass an regular expression as an argument to a function.
If I pass a string, it is OK,
I have the following awk file,
#!/usr/bin/awk -f
function find(name){
for(i=0;i<NF;i++)if($(i+1)~name)print $(i+1)
}
{
find("mysql")
}
I do something like
$ ./fct.awk <(echo "$str")
This works OK.
But when I call in the awk file,
{
find(/mysql/)
}
This does not work.
What am I doing wrong?
Thanks,
Eric J.
you cannot (should not) pass regex constant to a user-defined function. you have to use dynamic regex in this case. like find("mysql")
if you do find(/mysql/), what does awk do is : find($0~/mysql/) so it pass a 0 or 1 to your find(..) function.
see this question for detail.
awk variable assignment statement explanation needed
also
http://www.gnu.org/software/gawk/manual/gawk.html#Using-Constant-Regexps
section: 6.1.2 Using Regular Expression Constants
warning: regexp constant for parameter #1 yields boolean value
The regex gets evaluated (matching against $0) before it's passed to the function. You have to use strings.
Note: make sure you do proper escaping: http://www.gnu.org/software/gawk/manual/gawk.html#Computed-Regexps
If you use GNU awk, you can use regular expression as user defined function parameter.
You have to define your regex as #/.../.
In your example, you would use it like this:
function find(regex){
for(i=1;i<=NF;i++)
if($i ~ regex)
print $i
}
{
find(#/mysql/)
}
It's called strongly type regexp constant and it's available since GNU awk version 4.2 (Oct 2017).
Example here.
use quotations, treat them as a string. this way it works for mawk, mawk2, and gnu-gawk. but you'll also need to double the backslashes since making them strings will eat away one of them right off the bat.
in your examplem just find("mysql") will suffice.
you can actually get it to pass arbitrary regex as you wish, and not be confined to just gnu-gawk, as long as you're willing to make them strings not the #/../ syntax others have mentioned. This is where the # of backslashes make a difference.
You can even make regex out of arbitrary bytes too, preferably via octal codes. if you do "\342\234\234" as a regex, the system will convert that into actual bytes in the regex before matching.
While there's nothing with that approach, if you wanna be 100% safe and prefer not having arbitrary bytes flying around , write it as
"[\\342][\\234][\\234]" ----> ✜
Once initially read by awk to create an internal representation, it'll look like this :
[\342][\234][\234]
which will still match the identical objects you desire (in this case, some sort of cross-looking dingbat). This will spit out annoying warnings in unicode-aware mode of gawk due to attempting to enclose non-ASCII bytes directly into square brackets. For that use case,
"\\342\\234\\234" ------(eqv to )---> /\342\234\234/
will keep gawk happy and quiet. Lately I've been filling the gaps in my own codes and write regex that can mimic all the Unicode-script classes that perl enjoys.
gawk '/<Lexer>/,/<\/Lexer>/' file
this works but it prints the first and last records, which I'd like to omit. How to do so?
It says: "The record that turns on the range pattern and the one that turns it off both match the range pattern. If you don't want to operate on these records, you can write if statements in the rule's action to distinguish them from the records you are interested in." but no example.
I tried something like
gawk '/<Lexer>/,/<\/Lexer>/' {1,FNR-1} file
but it doesn't work.
If you have a better way to do this, without using awk, say so.
You can do it with 2 separate match statements and a variable
gawk '/<Lexer>/{p=1; next} /<\/Lexer>/ {p=0} p==1 {print}' file
This matches <Lexer> and sets p to 1 and then skips to the next line. While p is 1 it prints the current line. When it matches </Lexer> it sets p to 0 and skips. As p is 0 printing is suppressed.