Deprecation method to deprecate Rubygems commands
Deprecation method to deprecate Rubygems commands
Verifies each certificate in chain
has signed the following certificate and is valid for the given time
.
Verifies that data
matches the signature
created by public_key
and the digest
algorithm.
Updates the TarHeader’s checksum
Enumerates trusted certificates.
Delegates to the wrapped source’s fetch_spec
method.
Returns the element at Integer offset index
; does not modify self
.
a = [:foo, 'bar', 2] a.at(0) # => :foo a.at(2) # => 2
Adds to array
all elements from each Array in other_arrays
; returns self
:
a = [0, 1] a.concat([2, 3], [4, 5]) # => [0, 1, 2, 3, 4, 5]
Iterates over array elements.
When a block given, passes each successive array element to the block; returns self
:
a = [:foo, 'bar', 2] a.each {|element| puts "#{element.class} #{element}" }
Output:
Symbol foo String bar Integer 2
Allows the array to be modified during iteration:
a = [:foo, 'bar', 2] a.each {|element| puts element; a.clear if element.to_s.start_with?('b') }
Output:
foo bar
When no block given, returns a new Enumerator:
a = [:foo, 'bar', 2] e = a.each e # => #<Enumerator: [:foo, "bar", 2]:each> a1 = e.each {|element| puts "#{element.class} #{element}" }
Output:
Symbol foo String bar Integer 2
Related: each_index
, reverse_each
.
Returns a new Array formed from self
with elements rotated from one end to the other.
When no argument given, returns a new Array that is like self
, except that the first element has been rotated to the last position:
a = [:foo, 'bar', 2, 'bar'] a1 = a.rotate a1 # => ["bar", 2, "bar", :foo]
When given a non-negative Integer count
, returns a new Array with count
elements rotated from the beginning to the end:
a = [:foo, 'bar', 2] a1 = a.rotate(2) a1 # => [2, :foo, "bar"]
If count
is large, uses count % array.size
as the count:
a = [:foo, 'bar', 2] a1 = a.rotate(20) a1 # => [2, :foo, "bar"]
If count
is zero, returns a copy of self
, unmodified:
a = [:foo, 'bar', 2] a1 = a.rotate(0) a1 # => [:foo, "bar", 2]
When given a negative Integer count
, rotates in the opposite direction, from end to beginning:
a = [:foo, 'bar', 2] a1 = a.rotate(-2) a1 # => ["bar", 2, :foo]
If count
is small (far from zero), uses count % array.size
as the count:
a = [:foo, 'bar', 2] a1 = a.rotate(-5) a1 # => ["bar", 2, :foo]
Rotates self
in place by moving elements from one end to the other; returns self
.
When no argument given, rotates the first element to the last position:
a = [:foo, 'bar', 2, 'bar'] a.rotate! # => ["bar", 2, "bar", :foo]
When given a non-negative Integer count
, rotates count
elements from the beginning to the end:
a = [:foo, 'bar', 2] a.rotate!(2) a # => [2, :foo, "bar"]
If count
is large, uses count % array.size
as the count:
a = [:foo, 'bar', 2] a.rotate!(20) a # => [2, :foo, "bar"]
If count
is zero, returns self
unmodified:
a = [:foo, 'bar', 2] a.rotate!(0) a # => [:foo, "bar", 2]
When given a negative Integer
count
, rotates in the opposite direction, from end to beginning:
a = [:foo, 'bar', 2] a.rotate!(-2) a # => ["bar", 2, :foo]
If count
is small (far from zero), uses count % array.size
as the count:
a = [:foo, 'bar', 2] a.rotate!(-5) a # => ["bar", 2, :foo]
Calls the block, if given, with each element of self
; returns a new Array whose elements are the return values from the block:
a = [:foo, 'bar', 2] a1 = a.map {|element| element.class } a1 # => [Symbol, String, Integer]
Returns a new Enumerator if no block given:
a = [:foo, 'bar', 2] a1 = a.map a1 # => #<Enumerator: [:foo, "bar", 2]:map>
Array#collect
is an alias for Array#map
.
Calls the block, if given, with each element; replaces the element with the block’s return value:
a = [:foo, 'bar', 2] a.map! { |element| element.class } # => [Symbol, String, Integer]
Returns a new Enumerator if no block given:
a = [:foo, 'bar', 2] a1 = a.map! a1 # => #<Enumerator: [:foo, "bar", 2]:map!>
Array#collect!
is an alias for Array#map!
.
Returns one of the following:
The maximum-valued element from self
.
A new Array of maximum-valued elements selected from self
.
When no block is given, each element in self
must respond to method <=>
with an Integer.
With no argument and no block, returns the element in self
having the maximum value per method <=>
:
[0, 1, 2].max # => 2
With an argument Integer n
and no block, returns a new Array with at most n
elements, in descending order per method <=>
:
[0, 1, 2, 3].max(3) # => [3, 2, 1] [0, 1, 2, 3].max(6) # => [3, 2, 1]
When a block is given, the block must return an Integer.
With a block and no argument, calls the block self.size-1
times to compare elements; returns the element having the maximum value per the block:
['0', '00', '000'].max {|a, b| a.size <=> b.size } # => "000"
With an argument n
and a block, returns a new Array with at most n
elements, in descending order per the block:
['0', '00', '000'].max(2) {|a, b| a.size <=> b.size } # => ["000", "00"]
Returns a new Array that is a recursive flattening of self
:
Each non-Array element is unchanged.
Each Array is replaced by its individual elements.
With non-negative Integer argument level
, flattens recursively through level
levels:
a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten(0) # => [0, [1, [2, 3], 4], 5] a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten(1) # => [0, 1, [2, 3], 4, 5] a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten(2) # => [0, 1, 2, 3, 4, 5] a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten(3) # => [0, 1, 2, 3, 4, 5]
With no argument, a nil
argument, or with negative argument level
, flattens all levels:
a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten # => [0, 1, 2, 3, 4, 5] [0, 1, 2].flatten # => [0, 1, 2] a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten(-1) # => [0, 1, 2, 3, 4, 5] a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten(-2) # => [0, 1, 2, 3, 4, 5] [0, 1, 2].flatten(-1) # => [0, 1, 2]
Replaces each nested Array in self
with the elements from that Array; returns self
if any changes, nil
otherwise.
With non-negative Integer argument level
, flattens recursively through level
levels:
a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten!(1) # => [0, 1, [2, 3], 4, 5] a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten!(2) # => [0, 1, 2, 3, 4, 5] a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten!(3) # => [0, 1, 2, 3, 4, 5] [0, 1, 2].flatten!(1) # => nil
With no argument, a nil
argument, or with negative argument level
, flattens all levels:
a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten! # => [0, 1, 2, 3, 4, 5] [0, 1, 2].flatten! # => nil a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten!(-1) # => [0, 1, 2, 3, 4, 5] a = [ 0, [ 1, [2, 3], 4 ], 5 ] a.flatten!(-2) # => [0, 1, 2, 3, 4, 5] [0, 1, 2].flatten!(-1) # => nil
When invoked with a block, yield all permutations of elements of self
; returns self
. The order of permutations is indeterminate.
When a block and an in-range positive Integer argument n
(0 < n <= self.size
) are given, calls the block with all n
-tuple permutations of self
.
Example:
a = [0, 1, 2] a.permutation(2) {|permutation| p permutation }
Output:
[0, 1] [0, 2] [1, 0] [1, 2] [2, 0] [2, 1]
Another example:
a = [0, 1, 2] a.permutation(3) {|permutation| p permutation }
Output:
[0, 1, 2] [0, 2, 1] [1, 0, 2] [1, 2, 0] [2, 0, 1] [2, 1, 0]
When n
is zero, calls the block once with a new empty Array:
a = [0, 1, 2] a.permutation(0) {|permutation| p permutation }
Output:
[]
When n
is out of range (negative or larger than self.size
), does not call the block:
a = [0, 1, 2] a.permutation(-1) {|permutation| fail 'Cannot happen' } a.permutation(4) {|permutation| fail 'Cannot happen' }
When a block given but no argument, behaves the same as a.permutation(a.size)
:
a = [0, 1, 2] a.permutation {|permutation| p permutation }
Output:
[0, 1, 2] [0, 2, 1] [1, 0, 2] [1, 2, 0] [2, 0, 1] [2, 1, 0]
Returns a new Enumerator if no block given:
a = [0, 1, 2] a.permutation # => #<Enumerator: [0, 1, 2]:permutation> a.permutation(2) # => #<Enumerator: [0, 1, 2]:permutation(2)>
Calls the block, if given, with combinations of elements of self
; returns self
. The order of combinations is indeterminate.
When a block and an in-range positive Integer argument n
(0 < n <= self.size
) are given, calls the block with all n
-tuple combinations of self
.
Example:
a = [0, 1, 2] a.combination(2) {|combination| p combination }
Output:
[0, 1] [0, 2] [1, 2]
Another example:
a = [0, 1, 2] a.combination(3) {|combination| p combination }
Output:
[0, 1, 2]
When n
is zero, calls the block once with a new empty Array:
a = [0, 1, 2] a1 = a.combination(0) {|combination| p combination }
Output:
[]
When n
is out of range (negative or larger than self.size
), does not call the block:
a = [0, 1, 2] a.combination(-1) {|combination| fail 'Cannot happen' } a.combination(4) {|combination| fail 'Cannot happen' }
Returns a new Enumerator if no block given:
a = [0, 1, 2] a.combination(2) # => #<Enumerator: [0, 1, 2]:combination(2)>
Returns an element from self
selected by a binary search. self
should be sorted, but this is not checked.
By using binary search, finds a value from this array which meets the given condition in O(log n)
where n
is the size of the array.
There are two search modes:
Find-minimum mode: the block should return true
or false
.
Find-any mode: the block should return a numeric value.
The block should not mix the modes by and sometimes returning true
or false
and sometimes returning a numeric value, but this is not checked.
Find-Minimum Mode
In find-minimum mode, the block always returns true
or false
. The further requirement (though not checked) is that there are no indexes i
and j
such that:
0 <= i < j <= self.size
.
The block returns true
for self[i]
and false
for self[j]
.
In find-minimum mode, method bsearch returns the first element for which the block returns true.
Examples:
a = [0, 4, 7, 10, 12] a.bsearch {|x| x >= 4 } # => 4 a.bsearch {|x| x >= 6 } # => 7 a.bsearch {|x| x >= -1 } # => 0 a.bsearch {|x| x >= 100 } # => nil
Less formally: the block is such that all false
-evaluating elements precede all true
-evaluating elements.
These make sense as blocks in find-minimum mode:
a = [0, 4, 7, 10, 12] a.map {|x| x >= 4 } # => [false, true, true, true, true] a.map {|x| x >= 6 } # => [false, false, true, true, true] a.map {|x| x >= -1 } # => [true, true, true, true, true] a.map {|x| x >= 100 } # => [false, false, false, false, false]
This would not make sense:
a = [0, 4, 7, 10, 12] a.map {|x| x == 7 } # => [false, false, true, false, false]
Find-Any Mode
In find-any mode, the block always returns a numeric value. The further requirement (though not checked) is that there are no indexes i
and j
such that:
0 <= i < j <= self.size
.
The block returns a negative value for self[i]
and a positive value for self[j]
.
The block returns a negative value for self[i]
and zero self[j]
.
The block returns zero for self[i]
and a positive value for self[j]
.
In find-any mode, method bsearch returns some element for which the block returns zero, or nil
if no such element is found.
Examples:
a = [0, 4, 7, 10, 12] a.bsearch {|element| 7 <=> element } # => 7 a.bsearch {|element| -1 <=> element } # => nil a.bsearch {|element| 5 <=> element } # => nil a.bsearch {|element| 15 <=> element } # => nil
Less formally: the block is such that:
All positive-evaluating elements precede all zero-evaluating elements.
All positive-evaluating elements precede all negative-evaluating elements.
All zero-evaluating elements precede all negative-evaluating elements.
These make sense as blocks in find-any mode:
a = [0, 4, 7, 10, 12] a.map {|element| 7 <=> element } # => [1, 1, 0, -1, -1] a.map {|element| -1 <=> element } # => [-1, -1, -1, -1, -1] a.map {|element| 5 <=> element } # => [1, 1, -1, -1, -1] a.map {|element| 15 <=> element } # => [1, 1, 1, 1, 1]
This would not make sense:
a = [0, 4, 7, 10, 12] a.map {|element| element <=> 7 } # => [-1, -1, 0, 1, 1]
Returns an enumerator if no block given:
a = [0, 4, 7, 10, 12] a.bsearch # => #<Enumerator: [0, 4, 7, 10, 12]:bsearch>
Returns a Hash
containing implementation-dependent counters inside the VM.
This hash includes information about method/constant cache serials:
{ :global_constant_state=>481, :class_serial=>9029 }
The contents of the hash are implementation specific and may be changed in the future.
This method is only expected to work on C Ruby.
The primary interface to this library. Use to setup delegation when defining your class.
class MyClass < DelegateClass(ClassToDelegateTo) # Step 1 def initialize super(obj_of_ClassToDelegateTo) # Step 2 end end
or:
MyClass = DelegateClass(ClassToDelegateTo) do # Step 1 def initialize super(obj_of_ClassToDelegateTo) # Step 2 end end
Here’s a sample of use from Tempfile
which is really a File
object with a few special rules about storage location and when the File
should be deleted. That makes for an almost textbook perfect example of how to use delegation.
class Tempfile < DelegateClass(File) # constant and class member data initialization... def initialize(basename, tmpdir=Dir::tmpdir) # build up file path/name in var tmpname... @tmpfile = File.open(tmpname, File::RDWR|File::CREAT|File::EXCL, 0600) # ... super(@tmpfile) # below this point, all methods of File are supported... end # ... end