Raised when Ruby can’t yield as requested.
A typical scenario is attempting to yield when no block is given:
def call_block yield 42 end call_block
raises the exception:
LocalJumpError: no block given (yield)
A more subtle example:
def get_me_a_return Proc.new { return 42 } end get_me_a_return.call
raises the exception:
LocalJumpError: unexpected return
Raised in case of a stack overflow.
def me_myself_and_i me_myself_and_i end me_myself_and_i
raises the exception:
SystemStackError: stack level too deep
Random provides an interface to Ruby’s pseudo-random number generator, or PRNG. The PRNG produces a deterministic sequence of bits which approximate true randomness. The sequence may be represented by integers, floats, or binary strings.
The generator may be initialized with either a system-generated or user-supplied seed value by using Random.srand.
The class method Random.rand provides the base functionality of Kernel.rand along with better handling of floating point values. These are both interfaces to Random::DEFAULT, the Ruby system PRNG.
Random.new will create a new PRNG with a state independent of Random::DEFAULT, allowing multiple generators with different seed values or sequence positions to exist simultaneously. Random objects can be marshaled, allowing sequences to be saved and resumed.
PRNGs are currently implemented as a modified Mersenne Twister with a period of 2**19937-1.
Raised when given an invalid regexp expression.
Regexp.new("?")
raises the exception:
RegexpError: target of repeat operator is not specified: /?/
Raised when an invalid operation is attempted on a thread.
For example, when no other thread has been started:
Thread.stop
This will raises the following exception:
ThreadError: stopping only thread note: use sleep to stop forever
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.
Example:
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 } }
Raised when throw is called with a tag which does not have corresponding catch block.
throw "foo", "bar"
raises the exception:
UncaughtThrowError: uncaught throw "foo"
A class that provides the functionality of Kernel#set_trace_func in a nice Object-Oriented API.
We can use TracePoint to gather information specifically for exceptions:
trace = TracePoint.new(:raise) do |tp| p [tp.lineno, tp.event, tp.raised_exception] end #=> #<TracePoint:disabled> trace.enable #=> false 0 / 0 #=> [5, :raise, #<ZeroDivisionError: divided by 0>]
If you don’t specify the type of events you want to listen for, TracePoint will include all available events.
Note do not depend on current event set, as this list is subject to change. Instead, it is recommended you specify the type of events you want to use.
To filter what is traced, you can pass any of the following as events:
:line
execute code on a new line
:class
start a class or module definition
:end
finish a class or module definition
:call
call a Ruby method
:return
return from a Ruby method
:c_call
call a C-language routine
:c_return
return from a C-language routine
:raise
raise an exception
:b_call
event hook at block entry
:b_return
event hook at block ending
:thread_begin
event hook at thread beginning
:thread_end
event hook at thread ending
:fiber_switch
event hook at fiber switch
The Enumerable mixin provides collection classes with several traversal and searching methods, and with the ability to sort. The class must provide a method each, which yields successive members of the collection. If Enumerable#max, #min, or #sort is used, the objects in the collection must also implement a meaningful <=> operator, as these methods rely on an ordering between members of the collection.
Ruby exception objects are subclasses of Exception. However, operating systems typically report errors using plain integers. Module Errno is created dynamically to map these operating system errors to Ruby classes, with each error number generating its own subclass of SystemCallError. As the subclass is created in module Errno, its name will start Errno::.
The names of the Errno:: classes depend on the environment in which Ruby runs. On a typical Unix or Windows platform, there are Errno classes such as Errno::EACCES, Errno::EAGAIN, Errno::EINTR, and so on.
The integer operating system error number corresponding to a particular error is available as the class constant Errno::error::Errno.
Errno::EACCES::Errno #=> 13 Errno::EAGAIN::Errno #=> 11 Errno::EINTR::Errno #=> 4
The full list of operating system errors on your particular platform are available as the constants of Errno.
Errno.constants #=> :E2BIG, :EACCES, :EADDRINUSE, :EADDRNOTAVAIL, ...
System call error module used by webrick for cross platform compatibility.
EPROTO
protocol error
ECONNRESET
remote host reset the connection request
ECONNABORTED
Client sent TCP reset (RST) before server has accepted the connection requested by client.
The Warning module contains a single method named warn, and the module extends itself, making Warning.warn available. Warning.warn is called for all warnings issued by Ruby. By default, warnings are printed to $stderr.
By overriding Warning.warn, you can change how warnings are handled by Ruby, either filtering some warnings, and/or outputting warnings somewhere other than $stderr. When Warning.warn is overridden, super can be called to get the default behavior of printing the warning to $stderr.
Coverage provides coverage measurement feature for Ruby. This feature is experimental, so these APIs may be changed in future.
require “coverage”
require or load Ruby source file
Coverage.result will return a hash that contains filename as key and coverage array as value. A coverage array gives, for each line, the number of line execution by the interpreter. A nil value means coverage is disabled for this line (lines like else and end).
[foo.rb] s = 0 10.times do |x| s += x end if s == 45 p :ok else p :ng end [EOF] require "coverage" Coverage.start require "foo.rb" p Coverage.result #=> {"foo.rb"=>[1, 1, 10, nil, nil, 1, 1, nil, 0, nil]}
Racc is a LALR(1) parser generator. It is written in Ruby itself, and generates Ruby programs.
racc [-o<var>filename</var>] [--output-file=<var>filename</var>]
[-e<var>rubypath</var>] [--embedded=<var>rubypath</var>]
[-v] [--verbose]
[-O<var>filename</var>] [--log-file=<var>filename</var>]
[-g] [--debug]
[-E] [--embedded]
[-l] [--no-line-convert]
[-c] [--line-convert-all]
[-a] [--no-omit-actions]
[-C] [--check-only]
[-S] [--output-status]
[--version] [--copyright] [--help] <var>grammarfile</var>
filename
Racc grammar file. Any extension is permitted.
outfile
A filename for output. default is <filename>.tab.rb
filename
Place logging output in file filename. Default log file name is <filename>.output.
rubypath
output executable file(mode 755). where path is the Ruby interpreter.
verbose mode. create filename.output file, like yacc’s y.output file.
add debug code to parser class. To display debugging information, use this ‘-g’ option and set @yydebug true in parser class.
Output parser which doesn’t need runtime files (racc/parser.rb).
Check syntax of racc grammar file and quit.
Print messages time to time while compiling.
turns off line number converting.
Convert line number of actions, inner, header and footer.
Call all actions, even if an action is empty.
print Racc version and quit.
Print copyright and quit.
Print usage and quit.
Parser Using Racc To compile Racc grammar file, simply type:
$ racc parse.y
This creates Ruby script file “parse.tab.y”. The -o option can change the output filename.
Racc Grammar File If you want your own parser, you have to write a grammar file. A grammar file contains the name of your parser class, grammar for the parser, user code, and anything else. When writing a grammar file, yacc’s knowledge is helpful. If you have not used yacc before, Racc is not too difficult.
Here’s an example Racc grammar file.
class Calcparser
rule
target: exp { print val[0] }
exp: exp '+' exp
| exp '*' exp
| '(' exp ')'
| NUMBER
end
Racc grammar files resemble yacc files. But (of course), this is Ruby code. yacc’s $$ is the ‘result’, $0, $1… is an array called ‘val’, and $-1, $-2… is an array called ‘_values’.
See the Grammar File Reference for more information on grammar files.
Parser Then you must prepare the parse entry method. There are two types of parse methods in Racc, Racc::Parser#do_parse and Racc::Parser#yyparse
Racc::Parser#do_parse is simple.
It’s yyparse() of yacc, and Racc::Parser#next_token is yylex(). This method must returns an array like [TOKENSYMBOL, ITS_VALUE]. EOF is [false, false]. (TOKENSYMBOL is a Ruby symbol (taken from String#intern) by default. If you want to change this, see the grammar reference.
Racc::Parser#yyparse is little complicated, but useful. It does not use Racc::Parser#next_token, instead it gets tokens from any iterator.
For example, yyparse(obj, :scan) causes calling +obj#scan+, and you can return tokens by yielding them from +obj#scan+.
When debugging, “-v” or/and the “-g” option is helpful.
“-v” creates verbose log file (.output). “-g” creates a “Verbose Parser”. Verbose Parser prints the internal status when parsing. But it’s not automatic. You must use -g option and set +@yydebug+ to true in order to get output. -g option only creates the verbose parser.
Racc reported syntax error. Isn’t there too many “end”? grammar of racc file is changed in v0.10.
Racc does not use ‘%’ mark, while yacc uses huge number of ‘%’ marks..
Racc reported “XXXX conflicts”. Try “racc -v xxxx.y”. It causes producing racc’s internal log file, xxxx.output.
Try “racc -g xxxx.y”. This command let racc generate “debugging parser”. Then set @yydebug=true in your parser. It produces a working log of your parser.
Racc runtime A parser, which is created by Racc, requires the Racc runtime module; racc/parser.rb.
Ruby 1.8.x comes with Racc runtime module, you need NOT distribute Racc runtime files.
If you want to include the Racc runtime module with your parser. This can be done by using ‘-E’ option:
$ racc -E -omyparser.rb myparser.y
This command creates myparser.rb which ‘includes’ Racc runtime. Only you must do is to distribute your parser file (myparser.rb).
Note: parser.rb is LGPL, but your parser is not. Your own parser is completely yours.
The Benchmark module provides methods to measure and report the time used to execute Ruby code.
Measure the time to construct the string given by the expression "a"*1_000_000_000:
require 'benchmark' puts Benchmark.measure { "a"*1_000_000_000 }
On my machine (OSX 10.8.3 on i5 1.7 GHz) this generates:
0.350000 0.400000 0.750000 ( 0.835234)
This report shows the user CPU time, system CPU time, the sum of the user and system CPU times, and the elapsed real time. The unit of time is seconds.
Do some experiments sequentially using the bm method:
require 'benchmark' n = 5000000 Benchmark.bm do |x| x.report { for i in 1..n; a = "1"; end } x.report { n.times do ; a = "1"; end } x.report { 1.upto(n) do ; a = "1"; end } end
The result:
user system total real 1.010000 0.000000 1.010000 ( 1.014479) 1.000000 0.000000 1.000000 ( 0.998261) 0.980000 0.000000 0.980000 ( 0.981335)
Continuing the previous example, put a label in each report:
require 'benchmark' n = 5000000 Benchmark.bm(7) do |x| x.report("for:") { for i in 1..n; a = "1"; end } x.report("times:") { n.times do ; a = "1"; end } x.report("upto:") { 1.upto(n) do ; a = "1"; end } end
The result:
user system total real for: 1.010000 0.000000 1.010000 ( 1.015688) times: 1.000000 0.000000 1.000000 ( 1.003611) upto: 1.030000 0.000000 1.030000 ( 1.028098)
The times for some benchmarks depend on the order in which items are run. These differences are due to the cost of memory allocation and garbage collection. To avoid these discrepancies, the bmbm method is provided. For example, to compare ways to sort an array of floats:
require 'benchmark' array = (1..1000000).map { rand } Benchmark.bmbm do |x| x.report("sort!") { array.dup.sort! } x.report("sort") { array.dup.sort } end
The result:
Rehearsal -----------------------------------------
sort! 1.490000 0.010000 1.500000 ( 1.490520)
sort 1.460000 0.000000 1.460000 ( 1.463025)
-------------------------------- total: 2.960000sec
user system total real
sort! 1.460000 0.000000 1.460000 ( 1.460465)
sort 1.450000 0.010000 1.460000 ( 1.448327)
Report statistics of sequential experiments with unique labels, using the benchmark method:
require 'benchmark' include Benchmark # we need the CAPTION and FORMAT constants n = 5000000 Benchmark.benchmark(CAPTION, 7, FORMAT, ">total:", ">avg:") do |x| tf = x.report("for:") { for i in 1..n; a = "1"; end } tt = x.report("times:") { n.times do ; a = "1"; end } tu = x.report("upto:") { 1.upto(n) do ; a = "1"; end } [tf+tt+tu, (tf+tt+tu)/3] end
The result:
user system total real for: 0.950000 0.000000 0.950000 ( 0.952039) times: 0.980000 0.000000 0.980000 ( 0.984938) upto: 0.950000 0.000000 0.950000 ( 0.946787) >total: 2.880000 0.000000 2.880000 ( 2.883764) >avg: 0.960000 0.000000 0.960000 ( 0.961255)
The Forwardable module provides delegation of specified methods to a designated object, using the methods def_delegator and def_delegators.
For example, say you have a class RecordCollection which contains an array @records. You could provide the lookup method record_number(), which simply calls [] on the @records array, like this:
require 'forwardable' class RecordCollection attr_accessor :records extend Forwardable def_delegator :@records, :[], :record_number end
We can use the lookup method like so:
r = RecordCollection.new r.records = [4,5,6] r.record_number(0) # => 4
Further, if you wish to provide the methods size, <<, and map, all of which delegate to @records, this is how you can do it:
class RecordCollection # re-open RecordCollection class def_delegators :@records, :size, :<<, :map end r = RecordCollection.new r.records = [1,2,3] r.record_number(0) # => 1 r.size # => 3 r << 4 # => [1, 2, 3, 4] r.map { |x| x * 2 } # => [2, 4, 6, 8]
You can even extend regular objects with Forwardable.
my_hash = Hash.new my_hash.extend Forwardable # prepare object for delegation my_hash.def_delegator "STDOUT", "puts" # add delegation for STDOUT.puts() my_hash.puts "Howdy!"
We want to rely on what has come before obviously, but with delegation we can take just the methods we need and even rename them as appropriate. In many cases this is preferable to inheritance, which gives us the entire old interface, even if much of it isn’t needed.
class Queue extend Forwardable def initialize @q = [ ] # prepare delegate object end # setup preferred interface, enq() and deq()... def_delegator :@q, :push, :enq def_delegator :@q, :shift, :deq # support some general Array methods that fit Queues well def_delegators :@q, :clear, :first, :push, :shift, :size end q = Queue.new q.enq 1, 2, 3, 4, 5 q.push 6 q.shift # => 1 while q.size > 0 puts q.deq end q.enq "Ruby", "Perl", "Python" puts q.first q.clear puts q.first
This should output:
2 3 4 5 6 Ruby nil
Be advised, RDoc will not detect delegated methods.
forwardable.rb provides single-method delegation via the def_delegator and def_delegators methods. For full-class delegation via DelegateClass, see delegate.rb.
SingleForwardable can be used to setup delegation at the object level as well.
printer = String.new printer.extend SingleForwardable # prepare object for delegation printer.def_delegator "STDOUT", "puts" # add delegation for STDOUT.puts() printer.puts "Howdy!"
Also, SingleForwardable can be used to set up delegation for a Class or Module.
class Implementation def self.service puts "serviced!" end end module Facade extend SingleForwardable def_delegator :Implementation, :service end Facade.service #=> serviced!
If you want to use both Forwardable and SingleForwardable, you can use methods def_instance_delegator and def_single_delegator, etc.
This library is an interface to secure random number generators which are suitable for generating session keys in HTTP cookies, etc.
You can use this library in your application by requiring it:
require 'securerandom'
It supports the following secure random number generators:
openssl
/dev/urandom
Win32
Generate random hexadecimal strings:
require 'securerandom' p SecureRandom.hex(10) #=> "52750b30ffbc7de3b362" p SecureRandom.hex(10) #=> "92b15d6c8dc4beb5f559" p SecureRandom.hex(13) #=> "39b290146bea6ce975c37cfc23"
Generate random base64 strings:
p SecureRandom.base64(10) #=> "EcmTPZwWRAozdA==" p SecureRandom.base64(10) #=> "KO1nIU+p9DKxGg==" p SecureRandom.base64(12) #=> "7kJSM/MzBJI+75j8"
Generate random binary strings:
p SecureRandom.random_bytes(10) #=> "\016\t{\370g\310pbr\301" p SecureRandom.random_bytes(10) #=> "\323U\030TO\234\357\020\a\337"
Generate UUIDs:
p SecureRandom.uuid #=> "2d931510-d99f-494a-8c67-87feb05e1594" p SecureRandom.uuid #=> "bad85eb9-0713-4da7-8d36-07a8e4b00eab"
The marshaling library converts collections of Ruby objects into a byte stream, allowing them to be stored outside the currently active script. This data may subsequently be read and the original objects reconstituted.
Marshaled data has major and minor version numbers stored along with the object information. In normal use, marshaling can only load data written with the same major version number and an equal or lower minor version number. If Ruby’s “verbose” flag is set (normally using -d, -v, -w, or –verbose) the major and minor numbers must match exactly. Marshal versioning is independent of Ruby’s version numbers. You can extract the version by reading the first two bytes of marshaled data.
str = Marshal.dump("thing") RUBY_VERSION #=> "1.9.0" str[0].ord #=> 4 str[1].ord #=> 8
Some objects cannot be dumped: if the objects to be dumped include bindings, procedure or method objects, instances of class IO, or singleton objects, a TypeError will be raised.
If your class has special serialization needs (for example, if you want to serialize in some specific format), or if it contains objects that would otherwise not be serializable, you can implement your own serialization strategy.
There are two methods of doing this, your object can define either marshal_dump and marshal_load or _dump and _load. marshal_dump will take precedence over _dump if both are defined. marshal_dump may result in smaller Marshal strings.
By design, Marshal.load can deserialize almost any class loaded into the Ruby process. In many cases this can lead to remote code execution if the Marshal data is loaded from an untrusted source.
As a result, Marshal.load is not suitable as a general purpose serialization format and you should never unmarshal user supplied input or other untrusted data.
If you need to deserialize untrusted data, use JSON or another serialization format that is only able to load simple, ‘primitive’ types such as String, Array, Hash, etc. Never allow user input to specify arbitrary types to deserialize into.
When dumping an object the method marshal_dump will be called. marshal_dump must return a result containing the information necessary for marshal_load to reconstitute the object. The result can be any object.
When loading an object dumped using marshal_dump the object is first allocated then marshal_load is called with the result from marshal_dump. marshal_load must recreate the object from the information in the result.
Example:
class MyObj def initialize name, version, data @name = name @version = version @data = data end def marshal_dump [@name, @version] end def marshal_load array @name, @version = array end end
Use _dump and _load when you need to allocate the object you’re restoring yourself.
When dumping an object the instance method _dump is called with an Integer which indicates the maximum depth of objects to dump (a value of -1 implies that you should disable depth checking). _dump must return a String containing the information necessary to reconstitute the object.
The class method _load should take a String and use it to return an object of the same class.
Example:
class MyObj def initialize name, version, data @name = name @version = version @data = data end def _dump level [@name, @version].join ':' end def self._load args new(*args.split(':')) end end
Since Marshal.dump outputs a string you can have _dump return a Marshal string which is Marshal.loaded in _load for complex objects.
WIN32OLE_VARIABLE objects represent OLE variable information.
WIN32OLE_VARIANT objects represents OLE variant.
Win32OLE converts Ruby object into OLE variant automatically when invoking OLE methods. If OLE method requires the argument which is different from the variant by automatic conversion of Win32OLE, you can convert the specfied variant type by using WIN32OLE_VARIANT class.
param = WIN32OLE_VARIANT.new(10, WIN32OLE::VARIANT::VT_R4) oleobj.method(param)
WIN32OLE_VARIANT does not support VT_RECORD variant. Use WIN32OLE_RECORD class instead of WIN32OLE_VARIANT if the VT_RECORD variant is needed.
Error raised when a response from the server is non-parseable.