Standard Library
Ruby comes ``out of the box'' with a large and useful library of
modules and classes. This chapter contains a sampling of the more
useful of these.
Interestingly, and unlike some of the code in later chapters, all of
these libraries are written in Ruby. You'll find the source in the
lib
subdirectory of the standard Ruby distribution.
klassen Complex
|
Forelder:
|
Numeric
|
Versjon:
|
1.6
|
|
Indeks:
new
Arithmetic operations
<=>
==
abs
abs2
arg
conjugate
image
polar
real
to_f
to_i
to_r
to_s
require "complex"
|
|
v1 = Complex(2,3)
|
» |
Complex(2, 3)
|
v2 = 2.im
|
» |
Complex(0, 2)
|
v1 + v2
|
» |
Complex(2, 5)
|
v1 * v2
|
» |
Complex(-6, 4)
|
v2**2
|
» |
Complex(-4, 0)
|
Math.sin(v1)
|
» |
Complex(9.154499147, -4.16890696)
|
v1 < v2
|
» |
false
|
v2**2 == -4
|
» |
true
|
klassemetoder
|
new
|
Complex.new( a, b )
-> aComplex
|
|
Returns a + bi.
|
In addition to the Complex.new
constructor, the Complex
library defines the method
Numeric.im
, such that
aNumeric
.im
returns 0 + aNumeric
i. Complex
numbers are also constructed using the global method
Complex
, which takes one or two arguments. The value it
returns depends on the type of its arguments:
a
|
b
|
Result
|
Number |
Number |
a + bi |
Complex |
0 |
a
|
Complex |
Complex |
Complex( a.real - b.image,
a.image + b.real )
|
Number |
Complex |
Complex( a - b.image,
b.real )
|
|
instansmetoder
|
Arithmetic operations
|
|
|
Performs various arithmetic operations on ref.
ref
|
+ |
aNumeric
-> aComplex
|
Addition |
ref
|
- |
aNumeric
-> aComplex
|
Subtraction |
ref
|
* |
aNumeric
-> aComplex
|
Multiplication |
ref
|
/ |
aNumeric
-> aComplex
|
Division |
ref
|
% |
aNumeric
-> aComplex
|
Remainder |
ref
|
** |
aNumeric
-> aComplex
|
Exponentiation (real and
complex power) |
|
<=>
|
ref <=> other -> -1, 0, +1
|
|
Returns ref.abs <=> other.abs.
|
==
|
ref == anObject -> true or false
|
|
If anObject is a complex number, returns true if
its real and imaginary parts match ref. If anObject is a
simple number, returns true if
ref.real equals anObject and
ref.image is zero. Otherwise, attempts to
coerce anObject to a complex number and compares the result.
|
abs
|
ref.abs -> aFloat
|
|
Absolute value.
|
abs2
|
ref.abs2 -> aFloat
|
|
Square of absolute value.
|
arg
|
ref.arg -> aFloat
|
|
Argument (angle from (1,0)).
|
conjugate
|
ref.conjugate
-> aComplex
|
|
Complex conjugate.
|
image
|
ref.image -> aNumeric
|
|
The imaginary part of ref.
|
polar
|
ref.polar -> anArray
|
|
Returns the two-element array: [c.abs, c.arg].
|
real
|
ref.real -> aNumeric
|
|
The real part of ref.
|
to_f
|
ref.to_f -> aComplex
|
|
Returns Complex(real.to_f, image.to_f) .
|
to_i
|
ref.to_i -> aComplex
|
|
Returns Complex(real.to_i, image.to_i) .
|
to_r
|
ref.to_r -> aComplex
|
|
Returns Complex(real.to_r, image.to_r) , converting both
parts of the complex to a rational number.
|
to_s
|
ref.to_s -> aString
|
|
String representation of ref.
|
In addition, the Math
functions sqrt
, exp
, cos
,
sin
, tan
, log
, log10
, and atan2
are
extended to support a Complex
argument.
klassen Date
|
Forelder:
|
Object
|
Versjon:
|
1.6
|
|
Indeks:
exist2?
exist?
existw?
gregorian_leap?
julian_leap?
leap?
new
new1
new2
new3
neww
today
Accessors
+
--
<<
<=>
===
>>
downto
england
gregorian
italy
jd
julian
leap?
mjd
newsg
next
ns?
os?
sg
step
succ
to_s
upto
require 'date'
|
|
d = Date.new(2000, 3, 31)
|
» |
#<Date: 2451635,2299161>
|
[d.year, d.yday, d.wday]
|
» |
[2000, 91, 5]
|
[d.month, d.mday]
|
» |
[3, 31]
|
[d.cwyear, d.cweek, d.cwday]
|
» |
[2000, 13, 5]
|
[d.jd, d.mjd]
|
» |
[2451635, 51634.5]
|
(d << 1).to_s
|
» |
"2000-02-29"
|
d.succ.to_s
|
» |
"2000-04-01"
|
(d + 100).to_s
|
» |
"2000-07-09"
|
d.leap?
|
» |
true
|
Date.new(2000, 3, -10).to_s
|
» |
"2000-03-22"
|
d1 = Date.neww(2000, 13, 7)
|
» |
#<Date: 2451637,2299161>
|
d1.to_s
|
» |
"2000-04-02"
|
[d1.cwday, d1.wday]
|
» |
[7, 0]
|
The date
library implements class Date
, which provides a
comprehensive set of facilities for storing, manipulating, and
converting dates. To document its options, we need to take a brief
historical detour to establish some vocabulary.
Internally a date is stored as a Julian day number, the number of
days since midday, January 1st, 4713 BCE.[In
the code, you may find references to the year -4712. As astronomical
dates include a year zero, 4713 BCE is the same year as
-4712.] The rules for converting a Julian day number to a
calendar date are complicated because the Romans estimated the
length of a year incorrectly. In the Julian calendar (often called
Old Style, or O.S.), every year divisible by 4 is a leap year.
The Date
class has options to convert dates using this as an
assumption.
By the sixteenth century, the inaccuracies in this measurement had
become apparent. An edict from Pope Gregory XIII in 1582 created the
New Style (N.S.) or Gregorian calendar, where years divisible by 100 were no
longer leap years unless they were also divisible by 400. This system was
adopted by most Catholic countries immediately, but religious
differences held up a wider adoption. England (and several other
countries) switched in 1752, with some countries following later.
The Date
class allows you to determine whether to implement the
cutover in 1582 (the Date::ITALY
option), 1752
(Date::ENGLAND
), or another date of your choosing.
The Date
class also provides conversions to Modified Julian Day
(MJD) numbers.
MJD values count from midnight, November 17, 1858. Because these
values count from midnight, not midday, there is a half-day added to the
conversion factor.
The descriptions that follow use the abbreviations listed
in Table 24.1 on page 441.
Abbreviations used describing dates
Field
|
Meaning
|
cwday |
An ISO 8601 calendar weekday. 1 is Monday, 7 is Sunday. |
cweek |
An ISO 8601 calendar week. Week 1 is the week containing the
first Thursday (or equivalently the week that contains
January 4th). |
cwyear |
An ISO 8601 calendar-week-based year. May be different from
year, as it rolls forward only on a Monday. |
jd |
The Julian day number---the number of days since January
1st, 4713 BCE. |
mday |
The day of the month (1..31). |
mjd |
A modified Julian day number. |
mon |
The month of the year (1..12). |
sg |
The start of the Gregorian correction: Date::ITALY (the
default) for 1582, Date::ENGLAND for 1752, or
JULIAN , meaning no correction. You may also provide an
arbitrary Julian day number for this parameter, in which case the
correction will start from this date. |
wday |
The day of the week (0 is Sunday). |
week |
The week number into a year (1..53). |
yday |
The day into the year (1..366). |
year |
A year (1966, 2001, and the like). |
|
|
Class Date
exports the constant arrays Date::MONTHNAMES
and Date::DAYNAMES
, which can be indexed by mon and
wday values to return the corresponding English names.
The Date
class also provides low-level date-conversion methods:
* civil_to_jd
|
* jd_to_civil
|
* commercial_to_jd
|
* jd_to_commercial
|
* ordinal_to_jd
|
* jd_to_ordinal
|
* jd_to_mjd
|
* mjd_to_jd
|
These methods perform limited error checking of their parameters, and are not
documented here. The somewhat confusingly named exist..?
routines perform conversions from different formats into a Julian day
number with error checking. These routines also automatically
normalize their parameters.
mixins (innblandede moduler)
|
Comparable:
|
<, <=, ==, >=, >, between? |
klassemetoder
|
exist2?
|
Date.exist2?(
year, yday, sg=Date::ITALY ) -> jd
|
|
Converts a year and yday into a Julian day number,
returning nil on error.
|
exist?
|
Date.exist?( year, mon,
mday, sg=Date::ITALY ) -> jd
|
|
Converts a year, mon, and mday into a Julian day
number, or nil if the parameters are invalid.
|
existw?
|
Date.existw?(
cyear, cweek, cwday, sg=Date::ITALY )
-> jd
|
|
Converts a cyear,
cweek, and cwday into a Julian day number.
|
gregorian_leap?
|
Date.gregorian_leap?( year
) -> true or false
|
|
If year does not end with ``00'', returns true if
year is divisible by 4, otherwise returns true
if year is divisible by 400.
|
julian_leap?
|
Date.julian_leap?( year )
-> true or false
|
|
Returns true if year is divisible by 4.
|
leap?
|
Date.leap?( year ) -> true or false
|
|
Synonym for Date.gregorian_leap? .
|
new
|
Date.new( year=-4712, mon=1, mday=1,
sg=Date::ITALY ) -> aNewDate
|
|
Returns a Date for the given year, mon, and
mday. If mon is negative, it counts back from the end of the
year. If mday is negative, it counts back from the
end of the month.
|
new1
|
Date.new1( jd, sg=Date::ITALY )
-> aNewDate
|
|
Creates a Date corresponding to the given Julian day
number.
|
new2
|
Date.new2( year=-4712, yday=1,
sg=Date::ITALY ) -> aNewDate
|
|
Returns a Date for the given year and
yday. If yday is negative, it counts back from the
end of the year.
|
new3
|
Date.new3( year=-4712, mon=1, mday=1,
sg=Date::ITALY ) -> aNewDate
|
|
Synonym for Date.new .
|
neww
|
Date.neww( cyear=1582, cweek=41,
cwday=5, sg=Date::ITALY ) -> aNewDate
|
|
Returns
a Date for the given cyear, cweek, and
cwday. If cweek is negative, it counts back from the end
of the year. If cwday is negative, it counts back
from the end of the week.
|
today
|
Date.today( sg=Date::ITALY )
-> aNewDate
|
|
Returns a Date for today.
|
instansmetoder
|
Accessors
|
ref.year -> year
ref.yday -> yday
ref.mjd -> mjd
ref.mon -> mon
ref.month -> mon
ref.mday -> mday
ref.day -> mday
ref.cwyear -> cwyear
ref.cweek -> cweek
ref.cwday -> cwday
ref.wday -> wday
|
|
Returns the given component of ref as a number.
|
+
|
ref + anInteger
-> aNewDate
|
|
Returns a new Date anInteger days from ref.
|
--
|
ref - anInteger -> aNewDate
ref - anOtherDate -> anInteger
|
|
The first form returns a new Date anInteger days
before ref.
The second form
returns the number of days between ref and anOtherDate.
|
<<
|
ref << anInteger -> aNewDate
|
|
Returns a new Date formed by subtracting anInteger months to ref,
adjusting the mday value back to the last day of the month if it
otherwise exceeds it.
|
<=>
|
ref <=> anOther -> -1, 0, +1
|
|
anOther must be a Numeric , in which case it is
treated as
a Julian day number, or a Date .
Returns -1, 0, +1 if ref is
less than, equal to, or greater than anOther. See module
Comparable on page 402.
|
===
|
ref === anOther -> true or false
|
|
anOther must be a Numeric , in which case it is
treated as
a Julian day number, or a Date .
Returns true if the
Julian day number of anOther is the same as ref.
|
>>
|
ref >> anInteger -> aNewDate
|
|
Returns a new Date formed by adding anInteger months to ref,
adjusting the mday value back to the last day of the month if it
otherwise exceeds it.
|
downto
|
ref.downto( aDateMin )
{| date | block }
-> ref
|
|
Invokes block with dates from ref down to aDateMin.
|
england
|
ref.england -> aDate
|
|
Equivalent to ref
.newsg(Date::ENGLAND) .
|
gregorian
|
ref.gregorian
-> aDate
|
|
Equivalent to ref
.newsg(Date::GREGORIAN) .
|
italy
|
ref.italy -> aDate
|
|
Equivalent to ref
.newsg(Date::ITALY) .
|
jd
|
ref.jd -> jd
|
|
Returns the Julian day number for ref.
|
julian
|
ref.julian -> aDate
|
|
Equivalent to ref
.newsg(Date::JULIAN) .
|
leap?
|
ref.leap? -> true or false
|
|
Returns true if ref falls within a leap year.
|
mjd
|
ref.mjd -> mjd
|
|
Returns the Julian day number of ref converted to a modified Julian
day number.
|
newsg
|
ref.newsg( sg=Date::ITALY )
-> aNewDate
|
|
Returns a new Date .
|
next
|
ref.next -> aNewDate
|
|
Synonym for ref.succ.
|
ns?
|
ref.ns? -> true or false
|
|
Returns true if ref falls in the period of New Style dates.
|
os?
|
ref.os? -> true or false
|
|
Returns true if ref falls in the period of Old Style dates.
|
sg
|
ref.sg -> anInteger
|
|
Returns the Julian day number of the start of New Style dates for
ref.
|
step
|
ref.step( aDateLimit, step )
{| date | block }
-> ref
|
|
Invokes block with dates starting at ref,
incrementing by step days, ending at the first date greater than
aDateLimit (less than for a negative step).
|
succ
|
ref.succ -> aNewDate
|
|
Returns the date of ref plus one day.
|
to_s
|
ref.to_s -> aString
|
|
Returns self as ``year-mon-mday.''
|
upto
|
ref.upto( aDateMax )
{| date | block }
-> ref
|
|
Invokes block with dates from ref to aDateMax.
|
require "English"
$OUTPUT_FIELD_SEPARATOR = ' -- '
"waterbuffalo" =~ /buff/
print $LOADED_FEATURES, $POSTMATCH, $PID, "\n"
print $", $', $$, "\n"
|
produces:
English.rb -- alo -- 19685 --
English.rb -- alo -- 19685 --
|
Include the English library file in a Ruby script, and you can
reference the global variables such as $_
using less
cryptic names, listed in the following table.
|
$*
|
$ARGV |
$"
|
$LOADED_FEATURES |
$?
|
$CHILD_STATUS |
$&
|
$MATCH |
$<
|
$DEFAULT_INPUT |
$.
|
$NR |
$>
|
$DEFAULT_OUTPUT |
$,
|
$OFS |
$!
|
$ERROR_INFO |
$\
|
$ORS |
$@
|
$ERROR_POSITION |
$\
|
$OUTPUT_RECORD_SEPARATOR |
$;
|
$FIELD_SEPARATOR |
$,
|
$OUTPUT_FIELD_SEPARATOR |
$;
|
$FS |
$$
|
$PID |
$=
|
$IGNORECASE |
$'
|
$POSTMATCH |
$.
|
$INPUT_LINE_NUMBER |
$`
|
$PREMATCH |
$/
|
$INPUT_RECORD_SEPARATOR |
$$
|
$PROCESS_ID |
$~
|
$LAST_MATCH_INFO |
$0
|
$PROGRAM_NAME |
$+
|
$LAST_PAREN_MATCH |
$/
|
$RS |
$_
|
$LAST_READ_LINE |
|
Indeks:
find
prune
require "find"
Find.find("/etc/passwd", "/var/spool/lp1", ".") do |f|
Find.prune if f == "."
puts f
end
|
produces:
/etc/passwd
/var/spool/lp1
/var/spool/lp1/status
/var/spool/lp1/lock
/var/spool/lp1/.seq
|
The Find
module supports the top-down traversal of a set of
file paths.
klassemetoder
|
find
|
ref.find( [
aName
]*
) {| aFileName | block }
|
|
Calls the associated block with the name of every file and
directory listed as arguments, then recursively on their
subdirectories, and so on.
|
prune
|
ref.prune
|
|
Skips the current file or directory, restarting the
loop with the next entry. If the current file is a directory,
that directory will not be recursively entered.
Meaningful only within the block associated with
Find::find .
|
klassen File
|
Forelder:
|
IO
|
Versjon:
|
1.6
|
|
Indeks:
cmp
compare
copy
cp
install
makedirs
mkpath
move
mv
rm_f
safe_unlink
syscopy
require 'ftools'
|
|
File.copy 'testfile', 'testfile1'
|
» |
true
|
File.compare 'testfile', 'testfile1'
|
» |
true
|
The FTools
library adds several methods to the built-in
File
class. These methods are particularly useful to programs
that move and copy files, such as installers.
klassemetoder
|
cmp
|
ref.cmp( name1, name2,
verbose=false )
-> true or false
|
|
Synonym for
File.compare
.
|
compare
|
ref.compare( name1, name2,
verbose=false )
-> true or false
|
|
Returns true only if the contents of files name1
and name2 are identical.
|
copy
|
ref.copy( fromName, toName,
verbose=false )
-> true or false
|
|
Equivalent to calling
File.syscopy
, but logs the attempt to
$stderr if verbose is not false .
|
cp
|
ref.cp( fromName, toName,
verbose=false )
-> true or false
|
|
Synonym for
File.copy
.
|
install
|
ref.install( fromName, toName,
aMode=nil , verbose=false )
|
|
Copies file fromName to file toName using
File.syscopy
, unless toName already exists and has the
same content as fromName. Sets the mode of the resulting file
to aMode unless aMode is nil .
|
makedirs
|
ref.makedirs(
[
dirName
]*
[, aBoolean
] )
|
|
Creates the given directories, logging each attempt to
$stderr if the last parameter is
true . Creates any missing parent directories as
required.
|
mkpath
|
ref.mkpath(
[
dirName
]*
[, aBoolean
] )
|
|
Synonym for
File.makedirs
.
|
move
|
ref.move( fromName, toName,
verbose=false )
-> true or false
|
|
Effectively renames fromName to toName, logging to
$stderr if verbose is not false .
|
mv
|
ref.mv( fromName, toName,
verbose=false )
-> true or false
|
|
Synonym for
File.move
.
|
rm_f
|
ref.rm_f(
[
fileName
]*
[, aBoolean
] )
-> anInteger
|
|
Synonym for
File.safe_unlink
(the name refers
to the Unix rm -f command).
|
safe_unlink
|
ref.safe_unlink(
[
fileName
]*
[, aBoolean
] )
-> anInteger or nil
|
|
Unlinks (deletes) the given files, logging to $stderr if
the last parameter is true . The method attempts to make all files
writable before unlinking them, so no errors will occur deleting
read-only files. Returns the number of files deleted, or nil
on error.
|
syscopy
|
ref.syscopy( fromName, toName )
-> true or false
|
|
Efficiently copies the file named fromName to
toName. If toName names a directory, the destination
will be a file in that directory with the same basename as
fromName. After the copy, the file mode of toName
will be the same as that of fromName. Returns true
on success.
|
|
klassen GetoptLong
|
Forelder:
|
Object
|
Versjon:
|
1.6
|
|
Indeks:
new
each
error?
error_message
get
get_option
ordering
ordering=
quiet
quiet=
quiet?
set_options
terminate
terminated?
# Call using "ruby example.rb --size 10k -v -q a.txt b.doc"
require 'getoptlong'
# specify the options we accept and initialize
# the option parser
opts = GetoptLong.new(
[ "--size", "-s", GetoptLong::REQUIRED_ARGUMENT ],
[ "--verbose", "-v", GetoptLong::NO_ARGUMENT ],
[ "--query", "-q", GetoptLong::NO_ARGUMENT ],
[ "--check", "--valid", "-c", GetoptLong::NO_ARGUMENT ]
)
# process the parsed options
opts.each do |opt, arg|
puts "Option: #{opt}, arg #{arg.inspect}"
end
puts "Remaining args: #{ARGV.join(', ')}"
|
produces:
Option: --size, arg "10k"
Option: --verbose, arg ""
Option: --query, arg ""
Remaining args: a.txt, b.doc
|
Class GetoptLong
supports GNU-style command-line option parsing.
Options may be a minus sign (`-') followed by a single character, or
two minus signs (`--') followed by a name (a long option). Long
options may be abbreviated to their shortest unambiguous lengths.
A single internal option may have multiple external representations.
For example, the option to control verbose output could be any of
-v
, --verbose
, or --details
. Some options may
also take an associated value.
Each internal option is passed to GetoptLong
as an array,
containing strings representing the option's external forms and a
flag. The flag (NO_ARGUMENT
, REQUIRED_ARGUMENT
, or
OPTIONAL_ARGUMENT
) specifies how GetoptLong
is to
associate an argument with the option.
If the environment variable
POSIXLY_CORRECT
is set, all options
must precede nonoptions on the command line. Otherwise, the default
behavior of GetoptLong
is to reorganize the command line to put
the options at the front. This behavior may be changed by setting
GetoptLong#ordering=
to one of the constants
PERMUTE
, REQUIRE_ORDER
, or RETURN_IN_ORDER
.
POSIXLY_CORRECT
may not be overridden.
Per-option constants
|
NO_ARGUMENT
|
|
Flags an option that takes no argument. |
OPTIONAL_ARGUMENT
|
|
A nonoption following this option
will be used as this option's argument. |
REQUIRED_ARGUMENT
|
|
This option must be followed by an
argument. |
|
Overall constants
|
PERMUTE
|
|
Options and their arguments will be shuffled
to the front of the command line. |
REQUIRE_ORDER
|
|
Options and their arguments must
appear at the start of the command line. The first nonoption
terminates option processing. |
RETURN_IN_ORDER
|
|
Return options in the order in
which they occur on the command line. |
|
klassemetoder
|
new
|
GetoptLong.new( [
options
]*
) -> ref
|
|
Returns a new option parser. Any options are passed to
ref.set_options .
|
instansmetoder
|
each
|
ref.each {| anOption, anArgument | block }
|
|
Loops calling GetoptLong#get , passing the returned option
and argument to the associated block. The loop ends when get
returns nil for anOption.
|
error?
|
ref.error?
-> anException
|
|
Returns an Exception object documenting any error that has
occurred, or nil if there has not been an error.
|
error_message
|
ref.error_message
-> aString
|
|
Returns the text of the last error message.
|
get
|
ref.get -> [ anOption,
anArgument ]
|
|
Returns the next option, along with any associated argument. If
there is no argument, nil is returned for
anArgument. If there are no remaining unprocessed options,
or if there is an error in option processing and quiet
has been set, nil is returned for
anOption. Otherwise,
if there is an error, a message is written to $stderr and
an exception (a subclass of StandardError ) is raised.
The option string returned is the first option that was given in
the corresponding array passed to set_options .
|
get_option
|
ref.get_option -> [ anOption,
anArgument ]
|
|
Synonym for GetoptLong#get .
|
ordering
|
ref.ordering -> aFixnum
|
|
Returns the current ordering.
|
ordering=
|
ref.ordering = aFixnum
|
|
Sets the ordering to one of PERMUTE , REQUIRE_ORDER ,
or RETURN_IN_ORDER . Quietly ignored if the environment
variable POSIXLY_CORRECT is set. Ordering may not be
changed once option processing has been started.
|
quiet
|
ref.quiet -> true or false
|
|
Returns the current value of the quiet attribute.
|
quiet=
|
ref.quiet = true or false
|
|
Sets the current value of the quiet attribute. If
false , any errors encountered are reported to
$stderr .
|
quiet?
|
ref.quiet? -> true or false
|
|
Synonym for GetoptLong#quiet .
|
set_options
|
ref.set_options(
[
anOptArray
]*
) -> ref
|
|
Each parameter is an array specifying a single internal option.
The array contains one or more strings specifying the external
form(s) of the option, and one of the flags NO_ARGUMENT ,
OPTIONAL_ARGUMENT , or REQUIRED_ARGUMENT . See the
sample code on page 448 for examples of use.
|
terminate
|
ref.terminate -> ref
|
|
Terminates option processing. Any remaining arguments are
written back to ARGV . This may be called from within a
GetoptLong#each or on its own. For example, calling the
following program using ``ruby example.rb --size 10k -v
-term -q a.txt b.doc '' will leave the -q and filenames
in ARGV .
require 'getoptlong'
opts = GetoptLong.new(
[ "--size", "-s", GetoptLong::REQUIRED_ARGUMENT ],
[ "--verbose", "-v", GetoptLong::NO_ARGUMENT ],
[ "--term", "-t", GetoptLong::NO_ARGUMENT ],
[ "--query", "-q", GetoptLong::NO_ARGUMENT ],
[ "--check", "--valid", "-c", GetoptLong::NO_ARGUMENT ]
)
opts.each do |opt, arg|
puts "Option: #{opt}, arg #{arg.inspect}"
opts.terminate if (opt == '--term')
end
puts "Remaining args: #{ARGV.join(', ')}"
|
produces:
Option: --size, arg "10k"
Option: --verbose, arg ""
Option: --term, arg ""
Remaining args: -q, a.txt, b.doc
|
|
terminated?
|
ref.terminated?
-> true or false
|
|
Returns true if option processing has been terminated.
|
|
Indeks:
create_makefile
dir_config
find_library
have_func
have_header
have_library
The mkmf
library is used by Ruby extension modules to help
create Makefiles
. When writing an extension, you create a
program named ``extconf.rb
'', which may be as simple as:
require 'mkmf'
create_makefile("Test")
|
When run, this script will produce a Makefile
suited to the
target platform. mkmf
contains several methods you can use
to find libraries and include files and to set compiler flags.
For more information on creating extension modules, see Chapter
17, which begins on page 169.
|
PLATFORM
|
varies |
A constant string that describes the
platform on which Ruby is running, such as ``mswin32'' or
``i686-linux.'' |
$CFLAGS
|
|
Global variable for compiler flags. |
$LDFLAGS
|
|
Global variable for linker flags. |
instansmetoder
|
create_makefile
|
create_makefile( target )
|
|
Creates a Makefile for an extension named target.
If this method is not called, no Makefile is created.
|
dir_config
|
dir_config( name )
|
|
Looks for directory configuration options for name given
as arguments to this program or to the original build of Ruby.
These arguments may be one of:
--with-
name
-dir =directory
|
--with-
name
-include =directory
|
--with-
name
-lib =directory
|
The given directories will be added to the appropriate search
paths (include or link) in the Makefile .
|
find_library
|
find_library( name,
function, [
path
]+
)
-> true or false
|
|
Same as have_library , but will also search in the given
directory paths.
|
have_func
|
have_func( function )
-> true or false
|
|
If the named
function exists in the standard compile environment,
adds the directive -DHAVE_FUNCTION
to the compile command in the Makefile and returns true .
|
have_header
|
have_header( header )
-> true or false
|
|
If the given header file can be found in the
standard search path, adds the directive -DHAVE_HEADER
to the compile command in the Makefile and returns true .
|
have_library
|
have_library( library,
function ) -> true or false
|
|
If the given function exists in the named library, which must exist in
the standard search path or in a directory added with
dir_config , adds the library to the link command
in the Makefile and returns true .
|
|
Indeks:
parsedate
The ParseDate
module defines a single method,
ParseDate::parsedate
, which converts a date and/or time string
into its constituents. It uses heuristics that handle a wide
variety of date and time formats, including a subset of ISO 8601,
Unix ctime
, and most common written variants. The following table shows
some examples.
StringGuess?
|
yy
|
mm
|
dd
|
hh
|
min
|
sec
|
zone
|
wd
|
1999-09-05 23:55:21+0900 |
F |
1999 |
9 |
5 |
23 |
55 |
21 |
+0900 |
-- |
1983-12-25 |
F |
1983 |
12 |
25 |
-- |
-- |
-- |
-- |
-- |
1965-11-10 T13:45 |
F |
1965 |
11 |
10 |
13 |
45 |
-- |
-- |
-- |
10/9/75 1:30pm |
F |
75 |
10 |
9 |
13 |
30 |
-- |
-- |
-- |
10/9/75 1:30pm |
T |
1975 |
10 |
9 |
13 |
30 |
-- |
-- |
-- |
Mon Feb 28 17:15:49 CST 2000 |
F |
2000 |
2 |
28 |
17 |
15 |
49 |
CST |
1 |
Tue, 02-Mar-99 11:20:32 GMT |
F |
99 |
3 |
2 |
11 |
20 |
32 |
GMT |
2 |
Tue, 02-Mar-99 11:20:32 GMT |
T |
1999 |
3 |
2 |
11 |
20 |
32 |
GMT |
2 |
12-January-1990, 04:00 WET |
F |
1990 |
1 |
12 |
4 |
0 |
-- |
WET |
-- |
4/3/99 |
F |
99 |
4 |
3 |
-- |
-- |
-- |
-- |
-- |
4/3/99 |
T |
1999 |
4 |
3 |
-- |
-- |
-- |
-- |
-- |
10th February, 1976 |
F |
1976 |
2 |
10 |
-- |
-- |
-- |
-- |
-- |
March 1st, 84 |
T |
1984 |
3 |
1 |
-- |
-- |
-- |
-- |
-- |
Friday |
F |
-- |
-- |
-- |
-- |
-- |
-- |
-- |
5 |
|
klassemetoder
|
parsedate
|
ref.parsedate( aString, guessYear=false ) -> [ year, mon, mday,
hour, min, sec, zone, wday
]
|
|
Parses a string containing a date and/or a time, returning an
array of Fixnum objects containing the various components.
nil is returned for fields that cannot be parsed from
aString. If the result contains a year that is less than
100 and guessYear is true, parsedate will return
a year value equal to year plus 2000 if year is less
than 69, year plus 1900 otherwise.
|
The profile
library prints to $stderr
a summary
of the number of calls to, and the time spent in, each method in a
Ruby program. The output is sorted by the total time spent in each
method. Profiling can be enabled from the command line using the
-r
profile
option, or from within a source program by
requiring the profile
module.
require 'profile'
def ackerman(m, n)
if m == 0 then n+1
elsif n == 0 and m > 0 then ackerman(m-1, 1)
else ackerman(m-1, ackerman(m, n-1))
end
end
ackerman(3,3)
|
produces:
time seconds seconds calls ms/call ms/call name
74.04 2.51 2.51 2432 1.03 42.68 Object#ackerman
14.16 2.99 0.48 3676 0.13 0.13 Fixnum#==
9.14 3.30 0.31 2431 0.13 0.13 Fixnum#-
2.36 3.38 0.08 1188 0.07 0.07 Fixnum#+
0.29 3.39 0.01 57 0.18 0.18 Fixnum#>
0.00 3.39 0.00 1 0.00 0.00 Module#method_added
0.00 3.39 0.00 1 0.00 3390.00 #toplevel
|
klassen PStore
|
Forelder:
|
Object
|
Versjon:
|
1.6
|
|
Indeks:
new
[ ]
[ ]=
abort
commit
path
root?
roots
transaction
The PStore
class provides transactional, file-based
persistent storage of Ruby objects. The following example stores two
hierarchies in a PStore. The first, identified by the key
``names
'', is an array of Strings. The second, identified by
``tree
'', is a simple binary tree.
require "pstore"
class T
def initialize(val, left=nil, right=nil)
@val, @left, @right = val, left, right
end
def to_a
[ @val, @left.to_a, @right.to_a ]
end
end
store = PStore.new("/tmp/store")
store.transaction do
store['names'] = [ 'Douglas', 'Barenberg', 'Meyer' ]
store['tree'] = T.new('top',
T.new('A', T.new('B')),
T.new('C', T.new('D', nil, T.new('E'))))
end
# now read it back in
store.transaction do
puts "Roots: #{store.roots.join(', ')}"
puts store['names'].join(', ')
puts store['tree'].to_a.inspect
end
|
produces:
Roots: names, tree
Douglas, Barenberg, Meyer
["top", ["A", ["B", [], []], []], ["C", ["D", [], ["E", [], []]], []]]
|
Each PStore
can store several
object hierarchies. Each hierarchy has a root, identified by a key
(often a string). At the start of a PStore
transaction, these
hierarchies are read from a disk file and made available to the Ruby
program. At the end of the transaction, the hierarchies are written
back to the file. Any changes made to objects in these hierarchies
are therefore saved on disk, to be read at the start of the next
transaction that uses that file.
In normal use, a PStore
object is created and then is used one or
more times to control a transaction. Within the body of the
transaction, any object hierarchies that had previously been saved
are made available, and any changes to object hierarchies, and any
new hierarchies, are written back to the file at the end.
klassemetoder
|
new
|
PStore.new( aFilename )
-> aPStore
|
|
Returns a new PStore object associated with the given
file. If the file exists, its contents must have been previously
written by PStore .
|
instansmetoder
|
[ ]
|
ref[ anObject ] -> anOtherObject
|
|
Root Access---Returns the root of an object hierarchy identified
by anObject. An exception is raised if anObject does
not identify a root.
|
[ ]=
|
ref[ anObject ] =
anOtherObject
-> anOtherObject
|
|
Root Creation---Sets anOtherObject as the base of the object
hierarchy to be identified using anObject.
|
abort
|
ref.abort
|
|
Terminates this transaction, losing any changes made to the
object hierarchies.
|
commit
|
ref.commit
|
|
Terminates the current transaction, saving the object hierarchies
into the store's file.
|
path
|
ref.path -> aString
|
|
Returns the name of the file associated with this store.
|
root?
|
ref.root?( anObject )
-> true or false
|
|
Returns true if anObject is the key of a root in
this store.
|
roots
|
ref.roots -> anArray
|
|
Returns an array containing the keys of the root objects
available in this store.
|
transaction
|
ref.transaction {| ref | block }
-> anObject
|
|
If the file associated with ref exists, reads in the object
hierarchies from it. It then executes the associated block, passing
in ref. The block may use this parameter to access the roots
of the hierarchies and hence access the persistent objects. If
the block calls PStore#abort , or if it raises an exception,
no data is saved back to the associated file. Otherwise, if it
invokes PStore#commit , or if it terminates normally, the
object hierarchies are written back to the file. The value
returned is the value returned by the block.
|
|
klassen Tempfile
|
Forelder:
|
[IO]
|
Versjon:
|
1.6
|
|
Indeks:
new
close
open
path
require "tempfile"
|
|
tf = Tempfile.new("afile")
|
tf.path
|
» |
"/tmp/afile19701.0"
|
tf.puts("Cosi Fan Tutte")
|
» |
nil
|
tf.close
|
» |
nil
|
tf.open
|
» |
#<File:0x40195040>
|
tf.gets
|
» |
"Cosi Fan Tutte\n"
|
tf.close(true)
|
» |
#<File:0x40195040>
|
Class Tempfile
creates managed temporary files. Although they
behave the same as any other IO
objects, temporary files are
automatically deleted when the Ruby program terminates. Once a
Tempfile
object has been created, the underlying file may be
opened and closed a number of times in succession.
Tempfile
does not directly inherit from IO
. Instead, it
delegates calls to a File
object. From the programmer's
perspective, apart from the unusual new
, open,
and
close
semantics, a Tempfile
object behaves as if it
were an IO
object.
klassemetoder
|
new
|
Tempfile.new( basename,
tmpdir=<see below> )
-> ref
|
|
Constructs a temporary file in the given directory. The file
name is built by concatenating basename, the current
process id and (as an extension) a unique sequence number. If
the tmpdir parameter is not supplied, it defaults to the
value of one of the environment variables TMPDIR , TMP ,
or TEMP , or to the directory /tmp .
The file is then opened using mode ``w+'', which allows reading
and writing and deletes any existing content (see Table
22.5 on page 326).
|
open
|
Tempfile.open( basename,
tmpdir )
-> ref
|
|
Synonym for Tempfile.new .
|
instansmetoder
|
close
|
ref.close( final=false )
|
|
Closes ref. If final is true , deletes the underlying
real file. If final is false , ref may be
subsequently reopened. In all cases, the underlying file is
deleted when the program terminates.
|
open
|
ref.open
|
|
Reopens ref using mode ``r+'', which allows reading and
writing but does not delete existing content.
|
path
|
ref.path -> aString
|
|
Returns the full path of the underlying file.
|
klassen Mutex
|
Forelder:
|
Object
|
Versjon:
|
1.6
|
|
Indeks:
lock
locked?
synchronize
try_lock
unlock
require 'thread'
sema4 = Mutex.new
a = Thread.new {
sema4.synchronize {
# access shared resource
}
}
b = Thread.new {
sema4.synchronize {
# access shared resource
}
}
|
Mutex
implements a simple semaphore that can be used to
coordinate access to shared data from multiple concurrent threads.
instansmetoder
|
lock
|
ref.lock
-> ref
|
|
Attempts to grab the lock and waits if it isn't available.
|
locked?
|
ref.locked?
-> true or false
|
|
Returns true if this lock is currently held by some
thread.
|
synchronize
|
ref.synchronize { block }
-> ref
|
|
Obtains a lock (using Mutex#lock ), runs the block,
and releases the lock when the block completes.
|
try_lock
|
ref.try_lock -> true or false
|
|
Attempts to obtain the lock and returns
immediately. Returns true if the lock was granted.
|
unlock
|
ref.unlock
-> ref or nil
|
|
Releases the lock. Returns nil if ref wasn't locked.
|
klassen ConditionVariable
|
Forelder:
|
Object
|
Versjon:
|
1.6
|
|
Indeks:
broadcast
signal
wait
require 'thread'
mutex = Mutex.new
resource = ConditionVariable.new
a = Thread.new {
mutex.synchronize {
# Thread 'a' now needs the resource
resource.wait(mutex)
# 'a' can now have the resource
}
}
b = Thread.new {
mutex.synchronize {
# Thread 'b' has finished using the resource
resource.signal
}
}
|
ConditionVariable
objects augment class Mutex
. Using
condition variables, it is possible to suspend while in the middle
of a critical section until a resource becomes available (see the discussion
on page 117).
instansmetoder
|
broadcast
|
ref.broadcast
|
|
Wakes up all threads waiting for this lock.
|
signal
|
ref.signal
|
|
Wakes up the first thread in line waiting for this lock.
|
wait
|
ref.wait( aMutex )
-> aMutex
|
|
Releases the lock held in aMutex and waits; reacquires
the lock on wakeup.
|
require "timeout"
for snooze in 1..2
puts "About to sleep for #{snooze}"
timeout(1.5) do
sleep(snooze)
end
puts "That was refreshing"
end
|
produces:
About to sleep for 1
That was refreshing
About to sleep for 2
/tc/usr/lib/ruby/1.6/timeout.rb:37: execution expired (TimeoutError)
from prog.rb:5:in `timeout'
from prog.rb:5
from prog.rb:3:in `each'
from prog.rb:3
|
The timeout
method takes a single parameter, representing
a timeout period in seconds, and a block. The block is executed, and
a timer is run concurrently. If the block terminates before the
timeout, timeout
returns true
. Otherwise, a
TimeoutError
exception is raised.
klassen WeakRef
|
Forelder:
|
Delegator
|
Versjon:
|
1.6
|
|
Indeks:
new
weakref_alive?
require "weakref"
ref = "fol de rol"
puts "Initial object is #{ref}"
ref = WeakRef.new(ref)
puts "Weak reference is #{ref}"
ObjectSpace.garbage_collect
puts "But then it is #{ref}"
|
produces:
Initial object is fol de rol
Weak reference is fol de rol
prog.rb:8: Illegal Reference - probably recycled (WeakRef::RefError)
|
In Ruby, objects are not eligible for garbage collection if there
are still references to them. Normally, this is a Good Thing---it
would be disconcerting to have an object simply evaporate while you
were using it. However, sometimes you may need more flexibility. For
example, you might want to implement an in-memory cache of commonly
used file contents. As you read more files, the cache grows. At some
point, you may run low on memory. The garbage collector will be
invoked, but the objects in the cache are all referenced by the
cache data structures, and so will not be deleted.
A weak reference behaves
exactly as any normal object reference with one important
exception---the referenced object may be garbage collected, even
while references to it exist. In the cache example, if the cached
files were accessed using weak references, once memory runs low they
will be garbage collected, freeing memory for the rest of the
application.
Weak references introduce a slight complexity. As the object
referenced can be deleted by garbage collection at any time, code
that accesses these objects must take care to ensure that the
references are valid. Two techniques can be used. First, the code
can reference the objects normally. Any attempt to reference an
object that has been garbage collected will raise a
WeakRef::RefError
exception.
An alternative approach is to use the WeakRef#weakref_alive?
method to check that a reference is valid before using it. Garbage
collection must be disabled during the test and subsequent reference
to the object. In a single-threaded program, you could use something
like:
ref = WeakRef.new(someObject)
#
# .. some time later
#
gcWasDisabled = GC.disable
if ref.weakref_alive?
# do stuff with 'ref'
end
GC.enable unless gcWasDisabled
|
klassemetoder
|
new
|
WeakRef.new( anObject )
-> ref
|
|
Creates and returns a weak reference to anObject. All
future references to anObject should be made using ref.
|
instansmetoder
|
weakref_alive?
|
ref.weakref_alive?
-> true or false
|
|
Returns false if the object referenced by ref has
been garbage collected.
|
Extracted from the book "Programming Ruby -
The Pragmatic Programmer's Guide".
Translation to norwegian by Norway Ruby User Group.
Copyright for the english original authored by David Thomas and Andrew Hunt:
Copyright
©
2001 Addison Wesley Longman, Inc.
This material may
be distributed only subject to the terms and conditions set forth in
the Open Publication License, v1.0 or later (the latest version is
presently available at
http://www.opencontent.org/openpub/).
(Please note that the license for the original has changed from the above. The above is the license of the original version that was used as a foundation for the translation efforts.)
Copyright for the norwegian translation:
Copyright ©
2002 Norway Ruby User Group.
This material may be distributed only subject to the terms and conditions set forth in the Open Publication License, v1.0 or later (the latest version is presently available at
http://www.opencontent.org/openpub/).
Distribution of substantively modified versions of this document is prohibited without the explicit permission of the copyright holder.
Distribution of the work or derivative of the work in any standard (paper) book form is prohibited unless prior permission is obtained from the copyright holder.