Standard Types

So far we've been having fun implementing pieces of our jukebox code, but we've been negligent. We've looked at arrays, hashes, and procs, but we haven't really covered the other basic types in Ruby: numbers, strings, ranges, and regular expressions. Let's spend a few pages on these basic building blocks now.


Ruby supports integers and floating point numbers. Integers can be any length (up to a maximum determined by the amount of free memory on your system). Integers within a certain range (normally -230 to 230-1 or -262 to 262-1) are held internally in binary form, and are objects of class Fixnum. Integers outside this range are stored in objects of class Bignum (currently implemented as a variable-length set of short integers). This process is transparent, and Ruby automatically manages the conversion back and forth.

num = 8 7.times do print num.type, " ", num, "\n" num *= num end


Fixnum 8 Fixnum 64 Fixnum 4096 Fixnum 16777216 Bignum 281474976710656 Bignum 79228162514264337593543950336 Bignum 6277101735386680763835789423207666416102355444464034512896

You write integers using an optional leading sign, an optional base indicator (0 for octal, 0x for hex, or 0b for binary), followed by a string of digits in the appropriate base. Underscore characters are ignored in the digit string.

123456 # Fixnum 123_456 # Fixnum (underscore ignored) -543 # Negative Fixnum 123_456_789_123_345_789 # Bignum 0xaabb # Hexadecimal 0377 # Octal -0b101_010 # Binary (negated)

You can also get the integer value corresponding to an ASCII character or escape sequence by preceding it with a question mark. Control and meta combinations can also be generated using ?\C-x, ?\M-x, and ?\M-\C-x. The control version of a value is the same as “value & 0x9f”. The meta version of a value is “value | 0x80”. Finally, the sequence ?\C-? generates an ASCII delete, 0177.

?a # character code ?\n # code for a newline (0x0a) ?\C-a # control a = ?A & 0x9f = 0x01 ?\M-a # meta sets bit 7 ?\M-\C-a # meta and control a ?\C-? # delete character

A numeric literal with a decimal point and/or an exponent is turned into a Float object, corresponding to the native architecture's double data type. You must follow the decimal point with a digit, as 1.e3 tries to invoke the method e3 in class Fixnum.

All numbers are objects, and respond to a variety of messages (listed in full starting on pages 290, 313, 315, 323, and 349). So, unlike (say) C++, you find the absolute value of a number by writing aNumber.abs, not abs(aNumber).

Integers also support several useful iterators. We've seen one already—7.times in the code example at the start of this chapter. Others include upto and downto, for iterating up and down between two integers, and step, which is more like a traditional for loop.

3.times { print "X " } 1.upto(5) { |i| print i, " " } 99.downto(95) { |i| print i, " " } 50.step(80, 5) { |i| print i, " " }


X X X 1 2 3 4 5 99 98 97 96 95 50 55 60 65 70 75 80

Finally, a warning for Perl users. Strings that contain numbers are not automatically converted into numbers when used in expressions. This tends to bite most often when reading numbers from a file. The following code (probably) doesn't do what was intended.

DATA.each do |line| vals = line.split # split line, storing tokens in val print vals[0] + vals[1], " " end

Feed it a file containing

3 4 5 6 7 8

and you'll get the output “34 56 78.” What happened?

The problem is that the input was read as strings, not numbers. The plus operator concatenates strings, so that's what we see in the output. To fix this, use the String#to_i method to convert the string to an integer.

DATA.each do |line| vals = line.split print vals[0].to_i + vals[1].to_i, " " end


7 11 15


Ruby strings are simply sequences of 8-bit bytes. They normally hold printable characters, but that is not a requirement; a string can also hold binary data. Strings are objects of class String.

Strings are often created using string literals—sequences of characters between delimiters. Because binary data is otherwise difficult to represent within program source, you can place various escape sequences in a string literal. Each is replaced with the corresponding binary value as the program is compiled. The type of string delimiter determines the degree of substitution performed. Within single-quoted strings, two consecutive backslashes are replaced by a single backslash, and a backslash followed by a single quote becomes a single quote.

'escape using "\\"' escape using "\" 'That\'s right' That's right

Double-quoted strings support a boatload more escape sequences. The most common is probably “\n”, the newline character. Table 18.2 gives the complete list. In addition, you can substitute the value of any Ruby expression into a string using the sequence #{ expr }. If the expression is just a global variable, a class variable, or an instance variable, you can omit the braces.

"Seconds/day: #{24*60*60}" Seconds/day: 86400 "#{'Ho! '*3}Merry Christmas" Ho! Ho! Ho! Merry Christmas "This is line #$." This is line 3

There are three more ways to construct string literals: %q, %Q, and “here documents.”

%q and %Q start delimited single- and double-quoted strings.

%q/general single-quoted string/ general single-quoted string %Q!general double-quoted string! general double-quoted string %Q{Seconds/day: #{24*60*60}} Seconds/day: 86400

The character following the “q” or “Q” is the delimiter. If it is an opening bracket, brace, parenthesis, or less-than sign, the string is read until the matching close symbol is found. Otherwise the string is read until the next occurrence of the same delimiter.

Finally, you can construct a string using a here document.

aString = <<END_OF_STRING The body of the string is the input lines up to one ending with the same text that followed the '<<' END_OF_STRING

A here document consists of lines in the source up to, but not including, the terminating string that you specify after the << characters. Normally, this terminator must start in the first column. However, if you put a minus sign after the << characters, you can indent the terminator.

print <<-STRING1, <<-STRING2 Concat STRING1 enate STRING2


Concat enate

Working with Strings

String is probably the largest built-in Ruby class, with over 75 standard methods. We won't go through them all here; the library reference has a complete list. Instead, we'll look at some common string idioms—things that are likely to pop up during day-to-day programming.

Let's get back to our jukebox. Although it's designed to be connected to the Internet, it also holds copies of some popular songs on a local hard drive. That way, if a squirrel chews through our 'net connection we'll still be able to entertain the customers.

For historical reasons (are there any other kind?), the list of songs is stored as rows in a flat file. Each row holds the name of the file containing the song, the song's duration, the artist, and the title, all in vertical-bar-separated fields. A typical file might start:

/jazz/j00132.mp3 | 3:45 | Fats Waller | Ain't Misbehavin' /jazz/j00319.mp3 | 2:58 | Louis Armstrong | Wonderful World /bgrass/bg0732.mp3| 4:09 | Strength in Numbers | Texas Red : : : : /jazz/j00132.mp3 | 3:45 | Fats Waller | Ain't Misbehavin' /jazz/j00319.mp3 | 2:58 | Louis Armstrong | Wonderful World /bgrass/bg0732.mp3| 4:09 | Strength in Numbers | Texas Red : : : :

Looking at the data, it's clear that we'll be using some of class String's many methods to extract and clean up the fields before we create Song objects based on them. At a minimum, we'll need to:

Our first task is to split each line into fields, and String#split will do the job nicely. In this case, we'll pass split a regular expression, /\s*\|\s*/, which splits the line into tokens wherever split finds a vertical bar, optionally surrounded by spaces. And, because the line read from the file has a trailing newline, we'll use String#chomp to strip it off just before we apply the split.

songs = songFile.each do |line| file, length, name, title = line.chomp.split(/\s*\|\s*/) songs.append, name, length) end puts songs[1]


Song: Wonderful World--Louis Armstrong (2:58)

Unfortunately, whoever created the original file entered the artists' names in columns, so some of them contain extra spaces. These will look ugly on our high-tech, super-twist, flat-panel Day-Glo display, so we'd better remove these extra spaces before we go much further. There are many ways of doing this, but probably the simplest is String#squeeze, which trims runs of repeated characters. We'll use the squeeze! form of the method, which alters the string in place.

songs = songFile.each do |line| file, length, name, title = line.chomp.split(/\s*\|\s*/) name.squeeze!(" ") songs.append, name, length) end puts songs[1]


Song: Wonderful World--Louis Armstrong (2:58)

Finally, there's the minor matter of the time format: the file says 2:58, and we want the number of seconds, 178. We could use split again, this time splitting the time field around the colon character.

mins, secs = length.split(/:/)

Instead, we'll use a related method. String#scan is similar to split in that it breaks a string into chunks based on a pattern. However, unlike split, with scan you specify the pattern that you want the chunks to match. In this case, we want to match one or more digits for both the minutes and seconds component. The pattern for one or more digits is /\d+/.

songs = songFile.each do |line| file, length, name, title = line.chomp.split(/\s*\|\s*/) name.squeeze!(" ") mins, secs = length.scan(/\d+/) songs.append, name, mins.to_i*60+secs.to_i) end puts songs[1]


Song: Wonderful World--Louis Armstrong (178)

Our jukebox has a keyword search capability. Given a word from a song title or an artist's name, it will list all matching tracks. Type in “fats,” and it might come back with songs by Fats Domino, Fats Navarro, and Fats Waller, for example. We'll implement this by creating an indexing class. Feed it an object and some strings, and it will index that object under every word (of two or more characters) that occurs in those strings. This will illustrate a few more of class String's many methods.

class WordIndex def initialize @index = end def index(anObject, *phrases) phrases.each do |aPhrase| aPhrase.scan /\w[-\w']+/ do |aWord| # extract each word aWord.downcase! @index[aWord] = [] if @index[aWord].nil? @index[aWord].push(anObject) end end end def lookup(aWord) @index[aWord.downcase] end end

The String#scan method extracts elements from a string that match a regular expression. In this case, the pattern “\w[-\w']+” matches any character that can appear in a word, followed by one or more of the things specified in the brackets (a hyphen, another word character, or a single quote). We'll talk more about regular expressions in the section “Regular Expressions.” To make our searches case insensitive, we map both the words we extract and the words used as keys during the lookup to lowercase. Note the exclamation mark at the end of the first downcase! method name. As with the squeeze! method we used previously, this is an indication that the method will modify the receiver in place, in this case converting the string to lowercase. There's a minor bug in this code example: the song “Gone, Gone, Gone” would get indexed three times. Can you come up with a fix?

We'll extend our SongList class to index songs as they're added, and add a method to look up a song given a word.

class SongList def initialize @songs = @index = end def append(aSong) @songs.push(aSong) @index.index(aSong,, aSong.artist) self end def lookup(aWord) @index.lookup(aWord) end end

Finally, we'll test it all.

songs = songFile.each do |line| file, length, name, title = line.chomp.split(/\s*\|\s*/) name.squeeze!(" ") mins, secs = length.scan(/\d+/) songs.append, name, mins.to_i*60+secs.to_i) end puts songs.lookup("Fats") puts songs.lookup("ain't") puts songs.lookup("RED") puts songs.lookup("WoRlD")


Song: Ain't Misbehavin'--Fats Waller (225) Song: Ain't Misbehavin'--Fats Waller (225) Song: Texas Red--Strength in Numbers (249) Song: Wonderful World--Louis Armstrong (178)

We could spend the next 50 pages looking at all the methods in class String. However, let's move on instead to look at a simpler datatype: ranges.


Ranges occur everywhere: January to December, 0 to 9, rare to well-done, lines 50 through 67, and so on. If Ruby is to help us model reality, it seems natural for it to support these ranges. In fact, Ruby goes one better: it actually uses ranges to implement three separate features: sequences, conditions, and intervals.

Ranges as Sequences

The first and perhaps most natural use of ranges is to express a sequence. Sequences have a start point, an end point, and a way to produce successive values in the sequence. In Ruby, these sequences are created using the “..” and “...” range operators. The two-dot form creates an inclusive range, while the three-dot form creates a range that excludes the specified high value.

1..10 'a'..'z' 0...anArray.length

In Ruby, unlike in some earlier versions of Perl, ranges are not represented internally as lists: the sequence 1..100000 is held as a Range object containing references to two Fixnum objects. If you need to, you can convert a range to a list using the to_a method.

(1..10).to_a [1, 2, 3, 4, 5, 6, 7, 8, 9, 10] ('bar'..'bat').to_a ["bar", "bas", "bat"]

Ranges implement methods that let you iterate over them and test their contents in a variety of ways.

digits = 0..9 digits.include?(5) true digits.min 0 digits.max 9 digits.reject {|i| i < 5 } [5, 6, 7, 8, 9] digits.each do |digit| dial(digit) end

So far we've shown ranges of numbers and strings. However, as you'd expect from an object-oriented language, Ruby can create ranges based on objects that you define. The only constraints are that the objects must respond to succ by returning the next object in sequence and the objects must be comparable using <=>, the general comparison operator. Sometimes called the spaceship operator, <=> compares two values, returning -1, 0, or +1 depending on whether the first is less than, equal to, or greater than the second.

Here's a simple class that represents rows of “#” signs. We might use it as a text-based stub when testing the jukebox volume control.

class VU include Comparable attr :volume def initialize(volume) # 0..9 @volume = volume end def inspect '#' * @volume end # Support for ranges def <=>(other) self.volume <=> other.volume end def succ raise(IndexError, "Volume too big") if @volume >= 9 end end

We can test it by creating a range of VU objects.

medium = medium.to_a [####, #####, ######, #######] medium.include?( false

Ranges as Conditions

As well as representing sequences, ranges may also be used as conditional expressions. For example, the following code fragment prints sets of lines from standard input, where the first line in each set contains the word “start” and the last line the word “end.”

while gets print if /start/../end/ end

Behind the scenes, the range keeps track of the state of each of the tests. We'll show some examples of this in the section “Loops.”.

Ranges as Intervals

A final use of the versatile range is as an interval test: seeing if some value falls within the interval represented by the range. This is done using ===, the case equality operator.

(1..10) === 5 true (1..10) === 15 false (1..10) === 3.14159 true ('a'..'j') === 'c' true ('a'..'j') === 'z' false

The example of a case expression shows this test in action, determining a jazz style given a year.

Regular Expressions

Back in “Working with Strings” when we were creating a song list from a file, we used a regular expression to match the field delimiter in the input file. We claimed that the expression line.split(/\s*\|\s*/) matched a vertical bar surrounded by optional whitespace. Let's explore regular expressions in more detail to see why this claim is true.

Regular expressions are used to match patterns against strings. Ruby provides built-in support that makes pattern matching and substitution convenient and concise. In this section we'll work through all the main features of regular expressions. There are some details we won't cover: have a look at “Regular Expressions” in Chapter 18 for more information.

Regular expressions are objects of type Regexp. They can be created by calling the constructor explicitly or by using the literal forms /pattern/ and %r\pattern\.

a ='^\s*[a-z]') /^\s*[a-z]/ b = /^\s*[a-z]/ /^\s*[a-z]/ c = %r{^\s*[a-z]} /^\s*[a-z]/

Once you have a regular expression object, you can match it against a string using Regexp#match(aString) or the match operators =~ (positive match) and !~ (negative match). The match operators are defined for both String and Regexp objects. If both operands of the match operator are Strings, the one on the right will be converted to a regular expression.

a = "Fats Waller" a =~ /a/ 1 a =~ /z/ nil a =~ "ll" 7

The match operators return the character position at which the match occurred. They also have the side effect of setting a whole load of Ruby variables. $& receives the part of the string that was matched by the pattern, $` receives the part of the string that preceded the match, and $' receives the string after the match. We can use this to write a method, showRE, which illustrates where a particular pattern matches.

def showRE(a,re) if a =~ re "#{$`}<<#{$&}>>#{$'}" else "no match" end end showRE('very interesting', /t/) very in<<t>>eresting showRE('Fats Waller', /ll/) Fats Wa<<ll>>er

The match also sets the thread-global variables $~ and $1 through $9. The variable $~ is a MatchData object that holds everything you might want to know about the match. $1 and so on hold the values of parts of the match. We'll talk about these later. And for people who cringe when they see these Perl-like variable names, stay tuned. There's good news at the end of the chapter.


Every regular expression contains a pattern, which is used to match the regular expression against a string.

Within a pattern, all characters except ., |, (, ), [, {, +, \, ^, $, *, and ? match themselves.

showRE('kangaroo', /angar/) k<<angar>>oo showRE('!@%&-_=+', /%&/) !@<<%&>>-_=+

If you want to match one of these special characters literally, precede it with a backslash. This explains part of the pattern we used to split the song line, /\s*\|\s*/. The \| means “match a vertical bar.” Without the backslash, the “|” would have meant alternation (which we'll describe later).

showRE('yes | no', /\|/) yes <<|>> no showRE('yes (no)', /\(no\)/) yes <<(no)>> showRE('are you sure?', /e\?/) are you sur<<e?>>

A backslash followed by an alphanumeric character is used to introduce a special match construct, which we'll cover later. In addition, a regular expression may contain #{...} expression substitutions.


By default, a regular expression will try to find the first match for the pattern in a string. Match /iss/ against the string “Mississippi,” and it will find the substring “iss” starting at position one. But what if you want to force a pattern to match only at the start or end of a string?

The patterns ^ and $ match the beginning and end of a line, respectively. These are often used to anchor a pattern match: for example, /^option/ matches the word “option” only if it appears at the start of a line. The sequence \A matches the beginning of a string, and \z and \Z match the end of a string. (Actually, \Z matches the end of a string unless the string ends with a “\n”, it which case it matches just before the “\n”.)

showRE("this is\nthe time", /^the/) this is\n<<the>> time showRE("this is\nthe time", /is$/) this <<is>>\nthe time showRE("this is\nthe time", /\Athis/) <<this>> is\nthe time showRE("this is\nthe time", /\Athe/) no match

Similarly, the patterns \b and \B match word boundaries and nonword boundaries, respectively. Word characters are letters, numbers, and underscore.

showRE("this is\nthe time", /\bis/) this <<is>>\nthe time showRE("this is\nthe time", /\Bis/) th<<is>> is\nthe time

Character Classes

A character class is a set of characters between brackets: [characters] matches any single character between the brackets. [aeiou] will match a vowel, [,.:;!?] matches punctuation, and so on. The significance of the special regular expression characters—.|()[{+^$*?—is turned off inside the brackets. However, normal string substitution still occurs, so (for example) \b represents a backspace character and \n a newline (see Table 18.2). In addition, you can use the abbreviations shown in Table 5.1, so that (for example) \s matches any whitespace character, not just a literal space.

showRE('It costs $12.', /[aeiou]/) It c<<o>>sts $12. showRE('It costs $12.', /[\s]/) It<< >>costs $12.

Within the brackets, the sequence c1-c2 represents all the characters between c1 and c2, inclusive.

If you want to include the literal characters ] and - within a character class, they must appear at the start.

a = 'Gamma [Design Patterns-page 123]' showRE(a, /[]]/) Gamma [Design Patterns-page 123<<]>> showRE(a, /[B-F]/) Gamma [<<D>>esign Patterns-page 123] showRE(a, /[-]/) Gamma [Design Patterns<<->>page 123] showRE(a, /[0-9]/) Gamma [Design Patterns-page <<1>>23]

Put a ^ immediately after the opening bracket to negate a character class: [^a-z] matches any character that isn't a lowercase alphabetic.

Some character classes are used so frequently that Ruby provides abbreviations for them. These abbreviations are listed in Table 5.1—they may be used both within brackets and in the body of a pattern.

showRE('It costs $12.', /\s/) It<< >>costs $12. showRE('It costs $12.', /\d/) It costs $<<1>>2.
Table 5.1 : Character class abbreviations
Sequence As [ ... ] Meaning
\d [0-9] Digit character
\D [^0-9] Nondigit
\s [\s\t\r\n\f] Whitespace character
\S [^\s\t\r\n\f] Nonwhitespace character
\w [A-Za-z0-9_] Word character
\W [^A-Za-z0-9_] Nonword character

Finally, a period (“.”) appearing outside brackets represents any character except a newline (and in multiline mode it matches a newline, too).

a = 'It costs $12.' showRE(a, /c.s/) It <<cos>>ts $12. showRE(a, /./) <<I>>t costs $12. showRE(a, /\./) It costs $12<<.>>


When we specified the pattern that split the song list line, /\s*\|\s*/, we said we wanted to match a vertical bar surrounded by an arbitrary amount of whitespace. We now know that the \s sequences match a single whitespace character, so it seems likely that the asterisks somehow mean “an arbitrary amount.” In fact, the asterisk is one of a number of modifiers that allow you to match multiple occurrences of a pattern.

If r stands for the immediately preceding regular expression within a pattern, then:

r* matches zero or more occurrences of r.
r+ matches one or more occurrences of r.
r? matches zero or one occurrence of r.
r{m,n} matches at least “m” and at most “n” occurrences of r.
r{m,} matches at least “m” occurrences of r.

These repetition constructs have a high precedence—they bind only to the immediately preceding regular expression in the pattern. /ab+/ matches an “a” followed by one or more “b”s, not a sequence of “ab”s. You have to be careful with the * construct too—the pattern /a*/ will match any string; every string has zero or more “a”s.

These patterns are called greedy, because by default they will match as much of the string as they can. You can alter this behavior, and have them match the minimum, by adding a question mark suffix.

a = "The moon is made of cheese" showRE(a, /\w+/) <<The>> moon is made of cheese showRE(a, /\s.*\s/) The<< moon is made of >>cheese showRE(a, /\s.*?\s/) The<< moon >>is made of cheese showRE(a, /[aeiou]{2,99}/) The m<<oo>>n is made of cheese showRE(a, /mo?o/) The <<moo>>n is made of cheese


We know that the vertical bar is special, because our line splitting pattern had to escape it with a backslash. That's because an unescaped vertical bar “|” matches either the regular expression that precedes it or the regular expression that follows it.

a = "red ball blue sky" showRE(a, /d|e/) r<<e>>d ball blue sky showRE(a, /al|lu/) red b<<al>>l blue sky showRE(a, /red ball|angry sky/) <<red ball>> blue sky

There's a trap for the unwary here, as “|” has a very low precedence. The last example above matches “red ball” or “angry sky”, not “red ball sky” or “red angry sky”. To match “red ball sky” or “red angry sky”, you'd need to override the default precedence using grouping.


You can use parentheses to group terms within a regular expression. Everything within the group is treated as a single regular expression.

showRE('banana', /an*/) b<<an>>ana showRE('banana', /(an)*/) <<>>banana showRE('banana', /(an)+/) b<<anan>>a
a = 'red ball blue sky' showRE(a, /blue|red/) <<red>> ball blue sky showRE(a, /(blue|red) \w+/) <<red ball>> blue sky showRE(a, /(red|blue) \w+/) <<red ball>> blue sky showRE(a, /red|blue \w+/) <<red>> ball blue sky
showRE(a, /red (ball|angry) sky/) no match a = 'the red angry sky' showRE(a, /red (ball|angry) sky/) the <<red angry sky>>

Parentheses are also used to collect the results of pattern matching. Ruby counts opening parentheses, and for each stores the result of the partial match between it and the corresponding closing parenthesis. You can use this partial match both within the remainder of the pattern and in your Ruby program. Within the pattern, the sequence \1 refers to the match of the first group, \2 the second group, and so on. Outside the pattern, the special variables $1, $2, and so on, serve the same purpose.

"12:50am" =~ /(\d\d):(\d\d)(..)/ 0 "Hour is #$1, minute #$2" "Hour is 12, minute 50" "12:50am" =~ /((\d\d):(\d\d))(..)/ 0 "Time is #$1" "Time is 12:50" "Hour is #$2, minute #$3" "Hour is 12, minute 50" "AM/PM is #$4" "AM/PM is am"

The ability to use part of the current match later in that match allows you to look for various forms of repetition.

# match duplicated letter showRE('He said "Hello"', /(\w)\1/) He said "He<<ll>>o" # match duplicated substrings showRE('Mississippi', /(\w+)\1/) M<<ississ>>ippi

You can also use back references to match delimiters.

showRE('He said "Hello"', /(["']).*?\1/) He said <<"Hello">> showRE("He said 'Hello'", /(["']).*?\1/) He said <<'Hello'>>

Pattern-Based Substitution

Sometimes finding a pattern in a string is good enough. If a friend challenges you to find a word that contains the letters a, b, c, d, and e in order, you could search a word list with the pattern /a.*b.*c.*d.*e/ and find “absconded” and “ambuscade.” That has to be worth something.

However, there are times when you need to change things based on a pattern match. Let's go back to our song list file. Whoever created it entered all the artists' names in lowercase. When we display them on our jukebox's screen, they'd look better in mixed case. How can we change the first character of each word to uppercase?

The methods String#sub and String#gsub look for a portion of a string matching their first argument and replace it with their second argument. String#sub performs one replacement, while String#gsub replaces every occurrence of the match. Both routines return a new copy of the String containing the substitutions. Mutator versions String#sub! and String#gsub! modify the original string.

a = "the quick brown fox" a.sub(/[aeiou]/, '*') "th* quick brown fox" a.gsub(/[aeiou]/, '*') "th* q**ck br*wn f*x" a.sub(/\s\S+/, ”) "the brown fox" a.gsub(/\s\S+/, ”) "the"

The second argument to both functions can be either a String or a block. If a block is used, the block's value is substituted into the String.

a = "the quick brown fox" a.sub(/^./) { $&.upcase } "The quick brown fox" a.gsub(/[aeiou]/) { $&.upcase } "thE qUIck brOwn fOx"

So, this looks like the answer to converting our artists' names. The pattern that matches the first character of a word is \b\w—look for a word boundary followed by a word character. Combine this with gsub and we can hack the artists' names.

def mixedCase(aName) aName.gsub(/\b\w/) { $&.upcase } end mixedCase("fats waller") "Fats Waller" mixedCase("louis armstrong") "Louis Armstrong" mixedCase("strength in numbers") "Strength In Numbers"

Backslash Sequences in the Substitution

Earlier we noted that the sequences \1, \2, and so on are available in the pattern, standing for the nth group matched so far. The same sequences are available in the second argument of sub and gsub.

"fred:smith".sub(/(\w+):(\w+)/, '\2, \1') "smith, fred" "nercpyitno".gsub(/(.)(.)/, '\2\1') "encryption"

There are additional backslash sequences that work in substitution strings: \& (last match), \+ (last matched group), \` (string prior to match), \' (string after match), and \\ (a literal backslash). It gets confusing if you want to include a literal backslash in a substitution. The obvious thing is to write

str.gsub(/\\/, '\\\\')

Clearly, this code is trying to replace each backslash in str with two. The programmer doubled up the backslashes in the replacement text, knowing that they'd be converted to “\\” in syntax analysis. However, when the substitution occurs, the regular expression engine performs another pass through the string, converting “\\” to “\”, so the net effect is to replace each single backslash with another single backslash. You need to write gsub(/\\/, '\\\\\\\\')!

str = 'a\b\c' "a\b\c" str.gsub(/\\/, '\\\\\\\\') "a\\b\\c"

However, using the fact that \& is replaced by the matched string, you could also write

str = 'a\b\c' "a\b\c" str.gsub(/\\/, '\&\&') "a\\b\\c"

If you use the block form of gsub, the string for substitution is analyzed only once (during the syntax pass) and the result is what you intended.

str = 'a\b\c' "a\b\c" str.gsub(/\\/) { '\\\\' } "a\\b\\c"

Finally, as an example of the wonderful expressiveness of combining regular expressions with code blocks, consider the following code fragment from the CGI library module, written by Wakou Aoyama. The code takes a string containing HTML escape sequences and converts it into normal ASCII. Because it was written for a Japanese audience, it uses the “n” modifier on the regular expressions, which turns off wide-character processing. It also illustrates Ruby's case expression, which we discuss in “Case Expressions.”

def unescapeHTML(string) str = string.dup str.gsub!(/&(.*?);/n) { match = $1.dup case match when /\Aamp\z/ni then '&' when /\Aquot\z/ni then '"' when /\Agt\z/ni then '>' when /\Alt\z/ni then '<' when /\A#(\d+)\z/n then Integer($1).chr when /\A#x([0-9a-f]+)\z/ni then $1.hex.chr end } str end puts unescapeHTML("1&lt;2 &amp;&amp; 4&gt;3") puts unescapeHTML("&quot;A&quot; = &#65; = &#x41;")


1<2 && 4>3 "A" = A = A

Object-Oriented Regular Expressions

We have to admit that while all these weird variables are very convenient to use, they aren't very object oriented, and they're certainly cryptic. And didn't we say that everything in Ruby was an object? What's gone wrong here?

Nothing, really. It's just that when Matz designed Ruby, he produced a fully object-oriented regular expression handling system. He then made it look familiar to Perl programmers by wrapping all these $-variables on top of it all. The objects and classes are still there, underneath the surface. So let's spend a while digging them out.

We've already come across one class: regular expression literals create instances of class Regexp.

re = /cat/ re.type Regexp

The method Regexp#match matches a regular expression against a string. If unsuccessful, the method returns nil. On success, it returns an instance of class MatchData. And that MatchData object gives you access to all available information about the match. All that good stuff that you can get from the $-variables is bundled in a handy little object.

re = /(\d+):(\d+)/ # match a time hh:mm md = re.match("Time: 12:34am") md.type MatchData md[0] # == $& "12:34" md[1] # == $1 "12" md[2] # == $2 "34" md.pre_match # == $` "Time: " md.post_match # == $' "am"

Because the match data is stored in its own object, you can keep the results of two or more pattern matches available at the same time, something you can't do using the $-variables. In the next example, we're matching the same Regexp object against two strings. Each match returns a unique MatchData object, which we verify by examining the two subpattern fields.

re = /(\d+):(\d+)/ # match a time hh:mm md1 = re.match("Time: 12:34am") md2 = re.match("Time: 10:30pm") md1[1, 2] ["12", "34"] md2[1, 2] ["10", "30"]

So how do the $-variables fit in? Well, after every pattern match, Ruby stores a reference to the result (nil or a MatchData object) in a thread-local variable (accessible using $~). All the other regular expression variables are then derived from this object. Although we can't really think of a use for the following code, it demonstrates that all the other MatchData-related $-variables are indeed slaved off the value in $~.

re = /(\d+):(\d+)/ md1 = re.match("Time: 12:34am") md2 = re.match("Time: 10:30pm") [ $1, $2 ] # last successful match ["10", "30"] $~ = md1 [ $1, $2 ] # previous successful match ["12", "34"]

Having said all this, we have to 'fess up. Andy and Dave normally use the $-variables rather than worrying about MatchData objects. For everyday use, they just end up being more convenient. Sometimes we just can't help being pragmatic.

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