Class: Range
| Relationships & Source Files | |
| Super Chains via Extension / Inclusion / Inheritance | |
|
Instance Chain:
self,
::Enumerable
|
|
| Inherits: | Object |
| Defined in: | range.c |
Overview
A Range object represents a collection of values that are between given begin and end values.
You can create an Range object explicitly with:
-
A
range literal:# Ranges that use '..' to include the given end value. (1..4).to_a # => [1, 2, 3, 4] ('a'..'d').to_a # => ["a", "b", "c", "d"] # Ranges that use '...' to exclude the given end value. (1...4).to_a # => [1, 2, 3] ('a'...'d').to_a # => ["a", "b", "c"]
A range may be created using method .new:
# Ranges that by default include the given end value.
Range.new(1, 4).to_a # => [1, 2, 3, 4]
Range.new('a', 'd').to_a # => ["a", "b", "c", "d"]
# Ranges that use third argument {exclude_end} to exclude the given end value.
Range.new(1, 4, true).to_a # => [1, 2, 3]
Range.new('a', 'd', true).to_a # => ["a", "b", "c"]Beginless Ranges
A beginless range has a definite end value, but a nil begin value. Such a range includes all values up to the end value.
r = (..4) # => nil..4
r.begin # => nil
r.include?(-50) # => true
r.include?(4) # => true
r = (...4) # => nil...4
r.include?(4) # => false
Range.new(nil, 4) # => nil..4
Range.new(nil, 4, true) # => nil...4A beginless range may be used to slice an array:
a = [1, 2, 3, 4]
r = (..2) # => nil...2
a[r] # => [1, 2]Method #each for a beginless range raises an exception.
Endless Ranges
An endless range has a definite begin value, but a nil end value. Such a range includes all values from the begin value.
r = (1..) # => 1..
r.end # => nil
r.include?(50) # => true
Range.new(1, nil) # => 1..The literal for an endless range may be written with either two dots or three. The range has the same elements, either way. But note that the two are not equal:
r0 = (1..) # => 1..
r1 = (1...) # => 1...
r0.begin == r1.begin # => true
r0.end == r1.end # => true
r0 == r1 # => falseAn endless range may be used to slice an array:
a = [1, 2, 3, 4]
r = (2..) # => 2..
a[r] # => [3, 4]Method #each for an endless range calls the given block indefinitely:
a = []
r = (1..)
r.each do |i|
a.push(i) if i.even?
break if i > 10
end
a # => [2, 4, 6, 8, 10]A range can be both beginless and endless. For literal beginless, endless ranges, at least the beginning or end of the range must be given as an explicit nil value. It is recommended to use an explicit nil beginning and implicit nil end, since that is what Ruby uses for #inspect:
(nil..) # => (nil..)
(..nil) # => (nil..)
(nil..nil) # => (nil..)Ranges and Other Classes
An object may be put into a range if its class implements instance method <=>. Ruby core classes that do so include ::Array, ::Complex, ::File::Stat, ::Float, ::Integer, ::Kernel, ::Module, ::Numeric, ::Rational, ::String, ::Symbol, and ::Time.
Example:
t0 = Time.now # => 2021-09-19 09:22:48.4854986 -0500
t1 = Time.now # => 2021-09-19 09:22:56.0365079 -0500
t2 = Time.now # => 2021-09-19 09:23:08.5263283 -0500
(t0..t2).include?(t1) # => true
(t0..t1).include?(t2) # => falseA range can be iterated over only if its elements implement instance method succ. Ruby core classes that do so include ::Integer, ::String, and ::Symbol (but not the other classes mentioned above).
Iterator methods include:
-
Included from module Enumerable:
#each_entry,#each_with_index, #each_with_object, #each_slice, #each_cons, and #reverse_each.
Example:
a = []
(1..4).each {|i| a.push(i) }
a # => [1, 2, 3, 4]Ranges and User-Defined Classes
A user-defined class that is to be used in a range must implement instance <=>; see Integer#<=>. To make iteration available, it must also implement instance method succ; see Integer#succ.
The class below implements both <=> and succ, and so can be used both to construct ranges and to iterate over them. Note that the ::Comparable module is included so the #== method is defined in terms of <=>.
# Represent a string of 'X' characters.
class Xs
include Comparable
attr_accessor :length
def initialize(n)
@length = n
end
def succ
Xs.new(@length + 1)
end
def <=>(other)
@length <=> other.length
end
def to_s
sprintf "%2d #{inspect}", @length
end
def inspect
'X' * @length
end
end
r = Xs.new(3)..Xs.new(6) #=> XXX..XXXXXX
r.to_a #=> [XXX, XXXX, XXXXX, XXXXXX]
r.include?(Xs.new(5)) #=> true
r.include?(Xs.new(7)) #=> falseWhat’s Here
First, what’s elsewhere. Class Range:
-
Inherits from
class Object. -
Includes
module Enumerable, which provides dozens of additional methods.
Here, class Range provides methods that are useful for:
-
{Range@Methods+for+Creating+a+Range Creating a }
-
Querying -
Comparing -
Iterating -
Converting -
Methods for Working with JSON
Methods for Creating a Range
-
.new: Returns a new range.
Methods for Querying
-
#begin: Returns the begin value given for
self. -
#bsearch: Returns an element from
selfselected by a binary search. -
#count: Returns a count of elements in
self. -
#end: Returns the end value given for
self. -
#exclude_end?: Returns whether the end object is excluded.
-
#first: Returns the first elements of
self. -
#hash: Returns the integer hash code.
-
#last: Returns the last elements of
self. -
#max: Returns the maximum values in
self. -
#min: Returns the minimum values in
self. -
#minmax: Returns the minimum and maximum values in
self. -
#size: Returns the count of elements in
self.
Methods for Comparing
-
#==: Returns whether a given object is equal to
self(uses #==). -
#===: Returns whether the given object is between the begin and end values.
-
#cover?: Returns whether a given object is within
self. -
#eql?: Returns whether a given object is equal to
self(uses #eql?). -
#include? (aliased as #member?): Returns whether a given object is an element of
self.
Methods for Iterating
-
#%: Requires argument
n; calls the block with eachn-th element ofself. -
#each: Calls the block with each element of
self. -
#step: Takes optional argument
n(defaults to 1); calls the block with eachn-th element ofself.
Methods for Converting
-
#inspect: Returns a string representation of
self(uses #inspect). -
#to_a (aliased as #entries): Returns elements of
selfin an array. -
#to_s: Returns a string representation of
self(uses #to_s).
Methods for Working with JSON
-
.json_create: Returns a new Range object constructed from the given object. -
#as_json: Returns a 2-element hash representingself. -
#to_json: Returns a JSON string representingself.
To make these methods available:
require 'json/add/range'Class Method Summary
- .new(begin, end, exclude_end = false) ⇒ Range constructor
Instance Attribute Summary
-
#exclude_end? ⇒ Boolean
readonly
Returns
trueifselfexcludes its end value;falseotherwise:
Instance Method Summary
-
#%(n) {|element| ... } ⇒ self
Iterates over the elements of
self. -
#==(other) ⇒ Boolean
Returns
trueif and only if: -
#===(object) ⇒ Boolean
Returns
trueifobjectis betweenself.beginandself.end. -
#begin ⇒ Object
Returns the object that defines the beginning of
self. -
#bsearch {|obj| ... } ⇒ value
Returns an element from
selfselected by a binary search. -
#count ⇒ Integer
Returns the count of elements, based on an argument or block criterion, if given.
-
#cover?(object) ⇒ Boolean
Returns
trueif the given argument is withinself,falseotherwise. -
#each {|element| ... } ⇒ self
With a block given, passes each element of
selfto the block: -
#end ⇒ Object
Returns the object that defines the end of
self. -
#entries ⇒ Array
Alias for #to_a.
-
#eql?(other) ⇒ Boolean
Returns
trueif and only if: -
#first ⇒ Object
With no argument, returns the first element of
self, if it exists: -
#hash ⇒ Integer
Returns the integer hash value for
self. -
#include?(object) ⇒ Boolean
Alias for #member?.
-
#inspect ⇒ String
Returns a string representation of
self, includingbegin.inspectandend.inspect: -
#last ⇒ Object
With no argument, returns the last element of
self, if it exists: -
#max ⇒ Object
Returns the maximum value in
self, using method<=>or a given block for comparison. -
#include?(object) ⇒ Boolean
(also: #include?)
Returns
trueifobjectis an element ofself,falseotherwise: -
#min ⇒ Object
Returns the minimum value in
self, using method<=>or a given block for comparison. -
#minmax ⇒ Array, Object
Returns a 2-element array containing the minimum and maximum value in
self, either according to comparison method<=>or a given block. -
#overlap?(range) ⇒ Boolean
Returns
trueifrangeoverlaps withself,falseotherwise: -
#reverse_each {|element| ... } ⇒ self
With a block given, passes each element of
selfto the block in reverse order: -
#size ⇒ non_negative_integer, ...
Returns the count of elements in
selfif both begin and end values are numeric; otherwise, returnsnil: -
#step(n = 1) {|element| ... } ⇒ self
Iterates over the elements of
self. -
#to_a ⇒ Array
(also: #entries)
Returns an array containing the elements in
self, if a finite collection; raises an exception otherwise. -
#to_s ⇒ String
Returns a string representation of
self, includingbegin.to_sandend.to_s: - #initialize_copy(orig) Internal use only
::Enumerable - Included
| #all? | Returns whether every element meets a given criterion. |
| #any? | Returns whether any element meets a given criterion. |
| #chain | Returns an enumerator object generated from this enumerator and given enumerables. |
| #chunk | Each element in the returned enumerator is a 2-element array consisting of: |
| #chunk_while | Creates an enumerator for each chunked elements. |
| #collect | Alias for Enumerable#map. |
| #collect_concat | Alias for Enumerable#flat_map. |
| #compact | Returns an array of all non- |
| #count | Returns the count of elements, based on an argument or block criterion, if given. |
| #cycle | When called with positive integer argument |
| #detect | Alias for Enumerable#find. |
| #drop | For positive integer |
| #drop_while | Calls the block with successive elements as long as the block returns a truthy value; returns an array of all elements after that point: |
| #each_cons | Calls the block with each successive overlapped |
| #each_entry | Calls the given block with each element, converting multiple values from yield to an array; returns |
| #each_slice | Calls the block with each successive disjoint |
| #each_with_index | With a block given, calls the block with each element and its index; returns |
| #each_with_object | Calls the block once for each element, passing both the element and the given object: |
| #entries | Alias for Enumerable#to_a. |
| #filter | Returns an array containing elements selected by the block. |
| #filter_map | Returns an array containing truthy elements returned by the block. |
| #find | Returns the first element for which the block returns a truthy value. |
| #find_all | Alias for Enumerable#filter. |
| #find_index | Returns the index of the first element that meets a specified criterion, or |
| #first | Returns the first element or elements. |
| #flat_map | Returns an array of flattened objects returned by the block. |
| #grep | Returns an array of objects based elements of |
| #grep_v | Returns an array of objects based on elements of |
| #group_by | With a block given returns a hash: |
| #include? | Alias for Enumerable#member?. |
| #inject | Returns an object formed from operands via either: |
| #lazy | Returns an |
| #map | Returns an array of objects returned by the block. |
| #max | Returns the element with the maximum element according to a given criterion. |
| #max_by | Returns the elements for which the block returns the maximum values. |
| #member? | Returns whether for any element |
| #min | Returns the element with the minimum element according to a given criterion. |
| #min_by | Returns the elements for which the block returns the minimum values. |
| #minmax | Returns a 2-element array containing the minimum and maximum elements according to a given criterion. |
| #minmax_by | Returns a 2-element array containing the elements for which the block returns minimum and maximum values: |
| #none? | Returns whether no element meets a given criterion. |
| #one? | Returns whether exactly one element meets a given criterion. |
| #partition | With a block given, returns an array of two arrays: |
| #reduce | Alias for Enumerable#inject. |
| #reject | Returns an array of objects rejected by the block. |
| #reverse_each | With a block given, calls the block with each element, but in reverse order; returns |
| #select | Alias for Enumerable#filter. |
| #slice_after | Creates an enumerator for each chunked elements. |
| #slice_before | With argument |
| #slice_when | Creates an enumerator for each chunked elements. |
| #sort | Returns an array containing the sorted elements of |
| #sort_by | With a block given, returns an array of elements of |
| #sum | With no block given, returns the sum of |
| #take | For non-negative integer |
| #take_while | Calls the block with successive elements as long as the block returns a truthy value; returns an array of all elements up to that point: |
| #tally | Returns a hash containing the counts of equal elements: |
| #to_a | Returns an array containing the items in |
| #to_h | When |
| #to_set | Makes a set from the enumerable object with given arguments. |
| #uniq | With no block, returns a new array containing only unique elements; the array has no two elements |
| #zip | With no block given, returns a new array |
Constructor Details
.new(begin, end, exclude_end = false) ⇒ Range
Returns a new range based on the given objects #begin and #end. Optional argument exclude_end determines whether object #end is included as the last object in the range:
Range.new(2, 5).to_a # => [2, 3, 4, 5]
Range.new(2, 5, true).to_a # => [2, 3, 4]
Range.new('a', 'd').to_a # => ["a", "b", "c", "d"]
Range.new('a', 'd', true).to_a # => ["a", "b", "c"]# File 'range.c', line 100
static VALUE
range_initialize(int argc, VALUE *argv, VALUE range)
{
VALUE beg, end, flags;
rb_scan_args(argc, argv, "21", &beg, &end, &flags);
range_modify(range);
range_init(range, beg, end, RBOOL(RTEST(flags)));
return Qnil;
}
Instance Attribute Details
#exclude_end? ⇒ Boolean (readonly)
# File 'range.c', line 132
static VALUE
range_exclude_end_p(VALUE range)
{
return RBOOL(EXCL(range));
}
Instance Method Details
#%(n) {|element| ... } ⇒ self
#%(n) ⇒ Enumerator
self
#%(n) ⇒ Enumerator
Iterates over the elements of self.
With a block given, calls the block with selected elements of the range; returns self:
a = []
(1..5).%(2) {|element| a.push(element) } # => 1..5
a # => [1, 3, 5]
a = []
('a'..'e').%(2) {|element| a.push(element) } # => "a".."e"
a # => ["a", "c", "e"]With no block given, returns an enumerator, which will be of class ::Enumerator::ArithmeticSequence if self is numeric; otherwise of class ::Enumerator:
e = (1..5) % 2 # => ((1..5).%(2))
e.class # => Enumerator::ArithmeticSequence
('a'..'e') % 2 # => #<Enumerator: ...>Related: #step.
# File 'range.c', line 572
static VALUE
range_percent_step(VALUE range, VALUE step)
{
return range_step(1, &step, range);
}
#==(other) ⇒ Boolean
Returns true if and only if:
-
otheris a range. -
other.begin == self.begin. -
other.end == self.end. -
other.exclude_end? == self.exclude_end?.
Otherwise returns false.
r = (1..5)
r == (1..5) # => true
r = Range.new(1, 5)
r == 'foo' # => false
r == (2..5) # => false
r == (1..4) # => false
r == (1...5) # => false
r == Range.new(1, 5, true) # => falseNote that even with the same argument, the return values of #== and #eql? can differ:
(1..2) == (1..2.0) # => true
(1..2).eql? (1..2.0) # => falseRelated: #eql?.
# File 'range.c', line 182
static VALUE
range_eq(VALUE range, VALUE obj)
{
if (range == obj)
return Qtrue;
if (!rb_obj_is_kind_of(obj, rb_cRange))
return Qfalse;
return rb_exec_recursive_paired(recursive_equal, range, obj, obj);
}
#===(object) ⇒ Boolean
Returns true if object is between self.begin and self.end. false otherwise:
(1..4) === 2 # => true
(1..4) === 5 # => false
(1..4) === 'a' # => false
(1..4) === 4 # => true
(1...4) === 4 # => false
('a'..'d') === 'c' # => true
('a'..'d') === 'e' # => falseA case statement uses method ===, and so:
case 79
when (1..50)
"low"
when (51..75)
"medium"
when (76..100)
"high"
end # => "high"
case "2.6.5"
when ..."2.4"
"EOL"
when "2.4"..."2.5"
"maintenance"
when "2.5"..."3.0"
"stable"
when "3.1"..
"upcoming"
end # => "stable"# File 'range.c', line 1888
static VALUE
range_eqq(VALUE range, VALUE val)
{
return r_cover_p(range, RANGE_BEG(range), RANGE_END(range), val);
}
#begin ⇒ Object
# File 'range.c', line 1177
static VALUE
range_begin(VALUE range)
{
return RANGE_BEG(range);
}
#bsearch {|obj| ... } ⇒ value
Returns an element from self selected by a binary search.
See Binary Searching.
# File 'range.c', line 693
static VALUE
range_bsearch(VALUE range)
{
VALUE beg, end, satisfied = Qnil;
int smaller;
/* Implementation notes:
* Floats are handled by mapping them to 64 bits integers.
* Apart from sign issues, floats and their 64 bits integer have the
* same order, assuming they are represented as exponent followed
* by the mantissa. This is true with or without implicit bit.
*
* Finding the average of two ints needs to be careful about
* potential overflow (since float to long can use 64 bits).
*
* The half-open interval (low, high] indicates where the target is located.
* The loop continues until low and high are adjacent.
*
* -1/2 can be either 0 or -1 in C89. However, when low and high are not adjacent,
* the rounding direction of mid = (low + high) / 2 does not affect the result of
* the binary search.
*
* Note that -0.0 is mapped to the same int as 0.0 as we don't want
* (-1...0.0).bsearch to yield -0.0.
*/
#define BSEARCH(conv, excl) \
do { \
RETURN_ENUMERATOR(range, 0, 0); \
if (!(excl)) high++; \
low--; \
while (low + 1 < high) { \
mid = ((high < 0) == (low < 0)) ? low + ((high - low) / 2) \
: (low + high) / 2; \
BSEARCH_CHECK(conv(mid)); \
if (smaller) { \
high = mid; \
} \
else { \
low = mid; \
} \
} \
return satisfied; \
} while (0)
#define BSEARCH_FIXNUM(beg, end, excl) \
do { \
long low = FIX2LONG(beg); \
long high = FIX2LONG(end); \
long mid; \
BSEARCH(INT2FIX, (excl)); \
} while (0)
beg = RANGE_BEG(range);
end = RANGE_END(range);
if (FIXNUM_P(beg) && FIXNUM_P(end)) {
BSEARCH_FIXNUM(beg, end, EXCL(range));
}
#if SIZEOF_DOUBLE == 8 && defined(HAVE_INT64_T)
else if (RB_FLOAT_TYPE_P(beg) || RB_FLOAT_TYPE_P(end)) {
int64_t low = double_as_int64(NIL_P(beg) ? -HUGE_VAL : RFLOAT_VALUE(rb_Float(beg)));
int64_t high = double_as_int64(NIL_P(end) ? HUGE_VAL : RFLOAT_VALUE(rb_Float(end)));
int64_t mid;
BSEARCH(int64_as_double_to_num, EXCL(range));
}
#endif
else if (is_integer_p(beg) && is_integer_p(end)) {
RETURN_ENUMERATOR(range, 0, 0);
return bsearch_integer_range(beg, end, EXCL(range));
}
else if (is_integer_p(beg) && NIL_P(end)) {
VALUE diff = LONG2FIX(1);
RETURN_ENUMERATOR(range, 0, 0);
while (1) {
VALUE mid = rb_funcall(beg, '+', 1, diff);
BSEARCH_CHECK(mid);
if (smaller) {
if (FIXNUM_P(beg) && FIXNUM_P(mid)) {
BSEARCH_FIXNUM(beg, mid, false);
}
else {
return bsearch_integer_range(beg, mid, false);
}
}
diff = rb_funcall(diff, '*', 1, LONG2FIX(2));
beg = mid;
}
}
else if (NIL_P(beg) && is_integer_p(end)) {
VALUE diff = LONG2FIX(-1);
RETURN_ENUMERATOR(range, 0, 0);
while (1) {
VALUE mid = rb_funcall(end, '+', 1, diff);
BSEARCH_CHECK(mid);
if (!smaller) {
if (FIXNUM_P(mid) && FIXNUM_P(end)) {
BSEARCH_FIXNUM(mid, end, false);
}
else {
return bsearch_integer_range(mid, end, false);
}
}
diff = rb_funcall(diff, '*', 1, LONG2FIX(2));
end = mid;
}
}
else {
rb_raise(rb_eTypeError, "can't do binary search for %s", rb_obj_classname(beg));
}
return range;
}
Returns the count of elements, based on an argument or block criterion, if given.
With no argument and no block given, returns the number of elements:
(1..4).count # => 4
(1...4).count # => 3
('a'..'d').count # => 4
('a'...'d').count # => 3
(1..).count # => Infinity
(..4).count # => InfinityWith argument object, returns the number of object found in self, which will usually be zero or one:
(1..4).count(2) # => 1
(1..4).count(5) # => 0
(1..4).count('a') # => 0With a block given, calls the block with each element; returns the number of elements for which the block returns a truthy value:
(1..4).count {|element| element < 3 } # => 2Related: #size.
# File 'range.c', line 2247
static VALUE
range_count(int argc, VALUE *argv, VALUE range)
{
if (argc != 0) {
/* It is odd for instance (1...).count(0) to return Infinity. Just let
* it loop. */
return rb_call_super(argc, argv);
}
else if (rb_block_given_p()) {
/* Likewise it is odd for instance (1...).count {|x| x == 0 } to return
* Infinity. Just let it loop. */
return rb_call_super(argc, argv);
}
VALUE beg = RANGE_BEG(range), end = RANGE_END(range);
if (NIL_P(beg) || NIL_P(end)) {
/* We are confident that the answer is Infinity. */
return DBL2NUM(HUGE_VAL);
}
if (is_integer_p(beg)) {
VALUE size = range_size(range);
if (!NIL_P(size)) {
return size;
}
}
return rb_call_super(argc, argv);
}
#cover?(object) ⇒ Boolean
#cover?(range) ⇒ Boolean
Boolean
#cover?(range) ⇒ Boolean
Returns true if the given argument is within self, false otherwise.
With non-range argument object, evaluates with <= and <.
For range self with included end value (#exclude_end? == false), evaluates thus:
self.begin <= object <= self.endExamples:
r = (1..4)
r.cover?(1) # => true
r.cover?(4) # => true
r.cover?(0) # => false
r.cover?(5) # => false
r.cover?('foo') # => false
r = ('a'..'d')
r.cover?('a') # => true
r.cover?('d') # => true
r.cover?(' ') # => false
r.cover?('e') # => false
r.cover?(0) # => falseFor range r with excluded end value (#exclude_end? == true), evaluates thus:
r.begin <= object < r.endExamples:
r = (1...4)
r.cover?(1) # => true
r.cover?(3) # => true
r.cover?(0) # => false
r.cover?(4) # => false
r.cover?('foo') # => false
r = ('a'...'d')
r.cover?('a') # => true
r.cover?('c') # => true
r.cover?(' ') # => false
r.cover?('d') # => false
r.cover?(0) # => falseWith range argument range, compares the first and last elements of self and range:
r = (1..4)
r.cover?(1..4) # => true
r.cover?(0..4) # => false
r.cover?(1..5) # => false
r.cover?('a'..'d') # => false
r = (1...4)
r.cover?(1..3) # => true
r.cover?(1..4) # => falseIf begin and end are numeric, #cover? behaves like #include?
(1..3).cover?(1.5) # => true
(1..3).include?(1.5) # => trueBut when not numeric, the two methods may differ:
('a'..'d').cover?('cc') # => true
('a'..'d').include?('cc') # => falseReturns false if either:
-
The begin value of
selfis larger than its end value. -
An internal call to
<=>returnsnil; that is, the operands are not comparable.
Beginless ranges cover all values of the same type before the end, excluding the end for exclusive ranges. Beginless ranges cover ranges that end before the end of the beginless range, or at the end of the beginless range for inclusive ranges.
(..2).cover?(1) # => true
(..2).cover?(2) # => true
(..2).cover?(3) # => false
(...2).cover?(2) # => false
(..2).cover?("2") # => false
(..2).cover?(..2) # => true
(..2).cover?(...2) # => true
(..2).cover?(.."2") # => false
(...2).cover?(..2) # => falseEndless ranges cover all values of the same type after the beginning. Endless exclusive ranges do not cover endless inclusive ranges.
(2..).cover?(1) # => false
(2..).cover?(3) # => true
(2...).cover?(3) # => true
(2..).cover?(2) # => true
(2..).cover?("2") # => false
(2..).cover?(2..) # => true
(2..).cover?(2...) # => true
(2..).cover?("2"..) # => false
(2...).cover?(2..) # => false
(2...).cover?(3...) # => true
(2...).cover?(3..) # => false
(3..).cover?(2..) # => falseRanges that are both beginless and endless cover all values and ranges, and return true for all arguments, with the exception that beginless and endless exclusive ranges do not cover endless inclusive ranges.
(nil...).cover?(Object.new) # => true
(nil...).cover?(nil...) # => true
(nil..).cover?(nil...) # => true
(nil...).cover?(nil..) # => false
(nil...).cover?(1..) # => falseRelated: #include?.
# File 'range.c', line 2106
static VALUE
range_cover(VALUE range, VALUE val)
{
VALUE beg, end;
beg = RANGE_BEG(range);
end = RANGE_END(range);
if (rb_obj_is_kind_of(val, rb_cRange)) {
return RBOOL(r_cover_range_p(range, beg, end, val));
}
return r_cover_p(range, beg, end, val);
}
#each {|element| ... } ⇒ self
#each ⇒ Enumerator
self
#each ⇒ Enumerator
With a block given, passes each element of self to the block:
a = []
(1..4).each {|element| a.push(element) } # => 1..4
a # => [1, 2, 3, 4]Raises an exception unless self.first.respond_to?(:succ).
With no block given, returns an enumerator.
# File 'range.c', line 933
static VALUE
range_each(VALUE range)
{
VALUE beg, end;
long i;
RETURN_SIZED_ENUMERATOR(range, 0, 0, range_enum_size);
beg = RANGE_BEG(range);
end = RANGE_END(range);
if (FIXNUM_P(beg) && NIL_P(end)) {
range_each_fixnum_endless(beg);
}
else if (FIXNUM_P(beg) && FIXNUM_P(end)) { /* fixnums are special */
return range_each_fixnum_loop(beg, end, range);
}
else if (RB_INTEGER_TYPE_P(beg) && (NIL_P(end) || RB_INTEGER_TYPE_P(end))) {
if (SPECIAL_CONST_P(end) || RBIGNUM_POSITIVE_P(end)) { /* end >= FIXNUM_MIN */
if (!FIXNUM_P(beg)) {
if (RBIGNUM_NEGATIVE_P(beg)) {
do {
rb_yield(beg);
} while (!FIXNUM_P(beg = rb_big_plus(beg, INT2FIX(1))));
if (NIL_P(end)) range_each_fixnum_endless(beg);
if (FIXNUM_P(end)) return range_each_fixnum_loop(beg, end, range);
}
else {
if (NIL_P(end)) range_each_bignum_endless(beg);
if (FIXNUM_P(end)) return range;
}
}
if (FIXNUM_P(beg)) {
i = FIX2LONG(beg);
do {
rb_yield(LONG2FIX(i));
} while (POSFIXABLE(++i));
beg = LONG2NUM(i);
}
ASSUME(!FIXNUM_P(beg));
ASSUME(!SPECIAL_CONST_P(end));
}
if (!FIXNUM_P(beg) && RBIGNUM_SIGN(beg) == RBIGNUM_SIGN(end)) {
if (EXCL(range)) {
while (rb_big_cmp(beg, end) == INT2FIX(-1)) {
rb_yield(beg);
beg = rb_big_plus(beg, INT2FIX(1));
}
}
else {
VALUE c;
while ((c = rb_big_cmp(beg, end)) != INT2FIX(1)) {
rb_yield(beg);
if (c == INT2FIX(0)) break;
beg = rb_big_plus(beg, INT2FIX(1));
}
}
}
}
else if (SYMBOL_P(beg) && (NIL_P(end) || SYMBOL_P(end))) { /* symbols are special */
beg = rb_sym2str(beg);
if (NIL_P(end)) {
rb_str_upto_endless_each(beg, sym_each_i, 0);
}
else {
rb_str_upto_each(beg, rb_sym2str(end), EXCL(range), sym_each_i, 0);
}
}
else {
VALUE tmp = rb_check_string_type(beg);
if (!NIL_P(tmp)) {
if (!NIL_P(end)) {
rb_str_upto_each(tmp, end, EXCL(range), each_i, 0);
}
else {
rb_str_upto_endless_each(tmp, each_i, 0);
}
}
else {
if (!discrete_object_p(beg)) {
rb_raise(rb_eTypeError, "can't iterate from %s",
rb_obj_classname(beg));
}
if (!NIL_P(end))
range_each_func(range, each_i, 0);
else
for (;; beg = rb_funcallv(beg, id_succ, 0, 0))
rb_yield(beg);
}
}
return range;
}
#end ⇒ Object
# File 'range.c', line 1198
static VALUE
range_end(VALUE range)
{
return RANGE_END(range);
}
Alias for #to_a.
#eql?(other) ⇒ Boolean
Returns true if and only if:
-
otheris a range. -
other.begin eql? self.begin. -
other.end eql? self.end. -
other.exclude_end? == self.exclude_end?.
Otherwise returns false.
r = (1..5)
r.eql?(1..5) # => true
r = Range.new(1, 5)
r.eql?('foo') # => false
r.eql?(2..5) # => false
r.eql?(1..4) # => false
r.eql?(1...5) # => false
r.eql?(Range.new(1, 5, true)) # => falseNote that even with the same argument, the return values of #== and #eql? can differ:
(1..2) == (1..2.0) # => true
(1..2).eql? (1..2.0) # => falseRelated: #==.
# File 'range.c', line 250
static VALUE
range_eql(VALUE range, VALUE obj)
{
if (range == obj)
return Qtrue;
if (!rb_obj_is_kind_of(obj, rb_cRange))
return Qfalse;
return rb_exec_recursive_paired(recursive_eql, range, obj, obj);
}
With no argument, returns the first element of self, if it exists:
(1..4).first # => 1
('a'..'d').first # => "a"With non-negative integer argument n given, returns the first n elements in an array:
(1..10).first(3) # => [1, 2, 3]
(1..10).first(0) # => []
(1..4).first(50) # => [1, 2, 3, 4]Raises an exception if there is no first element:
(..4).first # Raises RangeError# File 'range.c', line 1242
static VALUE
range_first(int argc, VALUE *argv, VALUE range)
{
VALUE n, ary[2];
if (NIL_P(RANGE_BEG(range))) {
rb_raise(rb_eRangeError, "cannot get the first element of beginless range");
}
if (argc == 0) return RANGE_BEG(range);
rb_scan_args(argc, argv, "1", &n);
ary[0] = n;
ary[1] = rb_ary_new2(NUM2LONG(n));
rb_block_call(range, idEach, 0, 0, first_i, (VALUE)ary);
return ary[1];
}
#hash ⇒ Integer
Returns the integer hash value for self. Two range objects r0 and r1 have the same hash value if and only if r0.eql?(r1).
Related: #eql?, Object#hash.
# File 'range.c', line 271
static VALUE
range_hash(VALUE range)
{
st_index_t hash = EXCL(range);
VALUE v;
hash = rb_hash_start(hash);
v = rb_hash(RANGE_BEG(range));
hash = rb_hash_uint(hash, NUM2LONG(v));
v = rb_hash(RANGE_END(range));
hash = rb_hash_uint(hash, NUM2LONG(v));
hash = rb_hash_uint(hash, EXCL(range) << 24);
hash = rb_hash_end(hash);
return ST2FIX(hash);
}
#include?(object) ⇒ Boolean
#include?(object) ⇒ Boolean
Boolean
#include?(object) ⇒ Boolean
Alias for #member?.
#initialize_copy(orig)
# File 'range.c', line 112
static VALUE
range_initialize_copy(VALUE range, VALUE orig)
{
range_modify(range);
rb_struct_init_copy(range, orig);
return range;
}
#inspect ⇒ String
Returns a string representation of self, including begin.inspect and end.inspect:
(1..4).inspect # => "1..4"
(1...4).inspect # => "1...4"
(1..).inspect # => "1.."
(..4).inspect # => "..4"Note that returns from #to_s and #inspect may differ:
('a'..'d').to_s # => "a..d"
('a'..'d').inspect # => "\"a\"..\"d\""Related: #to_s.
# File 'range.c', line 1840
static VALUE
range_inspect(VALUE range)
{
return rb_exec_recursive(inspect_range, range, 0);
}
With no argument, returns the last element of self, if it exists:
(1..4).last # => 4
('a'..'d').last # => "d"Note that last with no argument returns the end element of self even if #exclude_end? is true:
(1...4).last # => 4
('a'...'d').last # => "d"With non-negative integer argument n given, returns the last n elements in an array:
(1..10).last(3) # => [8, 9, 10]
(1..10).last(0) # => []
(1..4).last(50) # => [1, 2, 3, 4]Note that last with argument does not return the end element of self if #exclude_end? it true:
(1...4).last(3) # => [1, 2, 3]
('a'...'d').last(3) # => ["a", "b", "c"]Raises an exception if there is no last element:
(1..).last # Raises RangeError# File 'range.c', line 1348
static VALUE
range_last(int argc, VALUE *argv, VALUE range)
{
VALUE b, e;
if (NIL_P(RANGE_END(range))) {
rb_raise(rb_eRangeError, "cannot get the last element of endless range");
}
if (argc == 0) return RANGE_END(range);
b = RANGE_BEG(range);
e = RANGE_END(range);
if (RB_INTEGER_TYPE_P(b) && RB_INTEGER_TYPE_P(e) &&
RB_LIKELY(rb_method_basic_definition_p(rb_cRange, idEach))) {
return rb_int_range_last(argc, argv, range);
}
return rb_ary_last(argc, argv, rb_Array(range));
}
Returns the maximum value in self, using method <=> or a given block for comparison.
With no argument and no block given, returns the maximum-valued element of self.
(1..4).max # => 4
('a'..'d').max # => "d"
(-4..-1).max # => -1With non-negative integer argument n given, and no block given, returns the n maximum-valued elements of self in an array:
(1..4).max(2) # => [4, 3]
('a'..'d').max(2) # => ["d", "c"]
(-4..-1).max(2) # => [-1, -2]
(1..4).max(50) # => [4, 3, 2, 1]If a block is given, it is called:
-
First, with the first two element of
self. -
Then, sequentially, with the so-far maximum value and the next element of
self.
To illustrate:
(1..4).max {|a, b| p [a, b]; a <=> b } # => 4Output:
[2, 1]
[3, 2]
[4, 3]With no argument and a block given, returns the return value of the last call to the block:
(1..4).max {|a, b| -(a <=> b) } # => 1With non-negative integer argument n given, and a block given, returns the return values of the last n calls to the block in an array:
(1..4).max(2) {|a, b| -(a <=> b) } # => [1, 2]
(1..4).max(50) {|a, b| -(a <=> b) } # => [1, 2, 3, 4]Returns an empty array if n is zero:
(1..4).max(0) # => []
(1..4).max(0) {|a, b| -(a <=> b) } # => []Returns nil or an empty array if:
-
The begin value of the range is larger than the end value:
(4..1).max # => nil (4..1).max(2) # => [] (4..1).max {|a, b| -(a <=> b) } # => nil (4..1).max(2) {|a, b| -(a <=> b) } # => [] -
The begin value of an exclusive range is equal to the end value:
(1...1).max # => nil (1...1).max(2) # => [] (1...1).max {|a, b| -(a <=> b) } # => nil (1...1).max(2) {|a, b| -(a <=> b) } # => []
Raises an exception if either:
-
selfis a endless range:(1..). -
A block is given and
selfis a beginless range.
# File 'range.c', line 1557
static VALUE
range_max(int argc, VALUE *argv, VALUE range)
{
VALUE e = RANGE_END(range);
int nm = FIXNUM_P(e) || rb_obj_is_kind_of(e, rb_cNumeric);
if (NIL_P(RANGE_END(range))) {
rb_raise(rb_eRangeError, "cannot get the maximum of endless range");
}
VALUE b = RANGE_BEG(range);
if (rb_block_given_p() || (EXCL(range) && !nm) || argc) {
if (NIL_P(b)) {
rb_raise(rb_eRangeError, "cannot get the maximum of beginless range with custom comparison method");
}
return rb_call_super(argc, argv);
}
else {
int c = NIL_P(b) ? -1 : OPTIMIZED_CMP(b, e);
if (c > 0)
return Qnil;
if (EXCL(range)) {
if (!RB_INTEGER_TYPE_P(e)) {
rb_raise(rb_eTypeError, "cannot exclude non Integer end value");
}
if (c == 0) return Qnil;
if (!RB_INTEGER_TYPE_P(b)) {
rb_raise(rb_eTypeError, "cannot exclude end value with non Integer begin value");
}
if (FIXNUM_P(e)) {
return LONG2NUM(FIX2LONG(e) - 1);
}
return rb_funcall(e, '-', 1, INT2FIX(1));
}
return e;
}
}
#include?(object) ⇒ Boolean Also known as: #include?
Returns true if object is an element of self, false otherwise:
(1..4).include?(2) # => true
(1..4).include?(5) # => false
(1..4).include?(4) # => true
(1...4).include?(4) # => false
('a'..'d').include?('b') # => true
('a'..'d').include?('e') # => false
('a'..'d').include?('B') # => false
('a'..'d').include?('d') # => true
('a'...'d').include?('d') # => falseIf begin and end are numeric, #include? behaves like #cover?
(1..3).include?(1.5) # => true
(1..3).cover?(1.5) # => trueBut when not numeric, the two methods may differ:
('a'..'d').include?('cc') # => false
('a'..'d').cover?('cc') # => trueRelated: #cover?.
# File 'range.c', line 1924
static VALUE
range_include(VALUE range, VALUE val)
{
VALUE ret = range_include_internal(range, val);
if (!UNDEF_P(ret)) return ret;
return rb_call_super(1, &val);
}
Returns the minimum value in self, using method <=> or a given block for comparison.
With no argument and no block given, returns the minimum-valued element of self.
(1..4).min # => 1
('a'..'d').min # => "a"
(-4..-1).min # => -4With non-negative integer argument n given, and no block given, returns the n minimum-valued elements of self in an array:
(1..4).min(2) # => [1, 2]
('a'..'d').min(2) # => ["a", "b"]
(-4..-1).min(2) # => [-4, -3]
(1..4).min(50) # => [1, 2, 3, 4]If a block is given, it is called:
-
First, with the first two element of
self. -
Then, sequentially, with the so-far minimum value and the next element of
self.
To illustrate:
(1..4).min {|a, b| p [a, b]; a <=> b } # => 1Output:
[2, 1]
[3, 1]
[4, 1]With no argument and a block given, returns the return value of the last call to the block:
(1..4).min {|a, b| -(a <=> b) } # => 4With non-negative integer argument n given, and a block given, returns the return values of the last n calls to the block in an array:
(1..4).min(2) {|a, b| -(a <=> b) } # => [4, 3]
(1..4).min(50) {|a, b| -(a <=> b) } # => [4, 3, 2, 1]Returns an empty array if n is zero:
(1..4).min(0) # => []
(1..4).min(0) {|a, b| -(a <=> b) } # => []Returns nil or an empty array if:
-
The begin value of the range is larger than the end value:
(4..1).min # => nil (4..1).min(2) # => [] (4..1).min {|a, b| -(a <=> b) } # => nil (4..1).min(2) {|a, b| -(a <=> b) } # => [] -
The begin value of an exclusive range is equal to the end value:
(1...1).min # => nil (1...1).min(2) # => [] (1...1).min {|a, b| -(a <=> b) } # => nil (1...1).min(2) {|a, b| -(a <=> b) } # => []
Raises an exception if either:
-
selfis a beginless range:(..4). -
A block is given and
selfis an endless range.
# File 'range.c', line 1449
static VALUE
range_min(int argc, VALUE *argv, VALUE range)
{
if (NIL_P(RANGE_BEG(range))) {
rb_raise(rb_eRangeError, "cannot get the minimum of beginless range");
}
if (rb_block_given_p()) {
if (NIL_P(RANGE_END(range))) {
rb_raise(rb_eRangeError, "cannot get the minimum of endless range with custom comparison method");
}
return rb_call_super(argc, argv);
}
else if (argc != 0) {
return range_first(argc, argv, range);
}
else {
VALUE b = RANGE_BEG(range);
VALUE e = RANGE_END(range);
int c = NIL_P(e) ? -1 : OPTIMIZED_CMP(b, e);
if (c > 0 || (c == 0 && EXCL(range)))
return Qnil;
return b;
}
}
Returns a 2-element array containing the minimum and maximum value in self, either according to comparison method <=> or a given block.
With no block given, returns the minimum and maximum values, using <=> for comparison:
(1..4).minmax # => [1, 4]
(1...4).minmax # => [1, 3]
('a'..'d').minmax # => ["a", "d"]
(-4..-1).minmax # => [-4, -1]With a block given, the block must return an integer:
-
Negative if
ais smaller thanb. -
Zero if
aandbare equal. -
Positive if
ais larger thanb.
The block is called self.size times to compare elements; returns a 2-element ::Array containing the minimum and maximum values from self, per the block:
(1..4).minmax {|a, b| -(a <=> b) } # => [4, 1]Returns [nil, nil] if:
-
The begin value of the range is larger than the end value:
(4..1).minmax # => [nil, nil] (4..1).minmax {|a, b| -(a <=> b) } # => [nil, nil] -
The begin value of an exclusive range is equal to the end value:
(1...1).minmax # => [nil, nil] (1...1).minmax {|a, b| -(a <=> b) } # => [nil, nil]
Raises an exception if self is a beginless or an endless range.
# File 'range.c', line 1643
static VALUE
range_minmax(VALUE range)
{
if (rb_block_given_p()) {
return rb_call_super(0, NULL);
}
return rb_assoc_new(
rb_funcall(range, id_min, 0),
rb_funcall(range, id_max, 0)
);
}
#overlap?(range) ⇒ Boolean
Returns true if range overlaps with self, false otherwise:
(0..2).overlap?(1..3) #=> true
(0..2).overlap?(3..4) #=> false
(0..).overlap?(..0) #=> trueWith non-range argument, raises ::TypeError.
(1..3).overlap?(1) # TypeErrorReturns false if an internal call to <=> returns nil; that is, the operands are not comparable.
(1..3).overlap?('a'..'d') # => falseReturns false if self or range is empty. “Empty range” means that its begin value is larger than, or equal for an exclusive range, its end value.
(4..1).overlap?(2..3) # => false
(4..1).overlap?(..3) # => false
(4..1).overlap?(2..) # => false
(2...2).overlap?(1..2) # => false
(1..4).overlap?(3..2) # => false
(..4).overlap?(3..2) # => false
(1..).overlap?(3..2) # => false
(1..2).overlap?(2...2) # => falseReturns false if the begin value one of self and range is larger than, or equal if the other is an exclusive range, the end value of the other:
(4..5).overlap?(2..3) # => false
(4..5).overlap?(2...4) # => false
(1..2).overlap?(3..4) # => false
(1...3).overlap?(3..4) # => falseReturns false if the end value one of self and range is larger than, or equal for an exclusive range, the end value of the other:
(4..5).overlap?(2..3) # => false
(4..5).overlap?(2...4) # => false
(1..2).overlap?(3..4) # => false
(1...3).overlap?(3..4) # => falseNote that the method wouldn’t make any assumptions about the beginless range being actually empty, even if its upper bound is the minimum possible value of its type, so all this would return true:
(...-Float::INFINITY).overlap?(...-Float::INFINITY) # => true
(..."").overlap?(..."") # => true
(...[]).overlap?(...[]) # => trueEven if those ranges are effectively empty (no number can be smaller than -Float::INFINITY), they are still considered overlapping with themselves.
Related: #cover?.
# File 'range.c', line 2358
static VALUE
range_overlap(VALUE range, VALUE other)
{
if (!rb_obj_is_kind_of(other, rb_cRange)) {
rb_raise(rb_eTypeError, "wrong argument type %"PRIsVALUE" (expected Range)",
rb_class_name(rb_obj_class(other)));
}
VALUE self_beg = RANGE_BEG(range);
VALUE self_end = RANGE_END(range);
int self_excl = EXCL(range);
VALUE other_beg = RANGE_BEG(other);
VALUE other_end = RANGE_END(other);
int other_excl = EXCL(other);
if (empty_region_p(self_beg, other_end, other_excl)) return Qfalse;
if (empty_region_p(other_beg, self_end, self_excl)) return Qfalse;
if (!NIL_P(self_beg) && !NIL_P(other_beg)) {
VALUE cmp = rb_funcall(self_beg, id_cmp, 1, other_beg);
if (NIL_P(cmp)) return Qfalse;
/* if both begin values are equal, no more comparisons needed */
if (rb_cmpint(cmp, self_beg, other_beg) == 0) return Qtrue;
}
else if (NIL_P(self_beg) && NIL_P(other_beg)) {
VALUE cmp = rb_funcall(self_end, id_cmp, 1, other_end);
return RBOOL(!NIL_P(cmp));
}
if (empty_region_p(self_beg, self_end, self_excl)) return Qfalse;
if (empty_region_p(other_beg, other_end, other_excl)) return Qfalse;
return Qtrue;
}
#reverse_each {|element| ... } ⇒ self
#reverse_each ⇒ Enumerator
self
#reverse_each ⇒ Enumerator
With a block given, passes each element of self to the block in reverse order:
a = []
(1..4).reverse_each {|element| a.push(element) } # => 1..4
a # => [4, 3, 2, 1]
a = []
(1...4).reverse_each {|element| a.push(element) } # => 1...4
a # => [3, 2, 1]With no block given, returns an enumerator.
# File 'range.c', line 1127
static VALUE
range_reverse_each(VALUE range)
{
RETURN_SIZED_ENUMERATOR(range, 0, 0, range_enum_size);
VALUE beg = RANGE_BEG(range);
VALUE end = RANGE_END(range);
int excl = EXCL(range);
if (NIL_P(end)) {
rb_raise(rb_eTypeError, "can't iterate from %s",
rb_obj_classname(end));
}
if (FIXNUM_P(beg) && FIXNUM_P(end)) {
if (excl) {
if (end == LONG2FIX(FIXNUM_MIN)) return range;
end = rb_int_minus(end, INT2FIX(1));
}
range_reverse_each_fixnum_section(beg, end);
}
else if ((NIL_P(beg) || RB_INTEGER_TYPE_P(beg)) && RB_INTEGER_TYPE_P(end)) {
if (excl) {
end = rb_int_minus(end, INT2FIX(1));
}
range_reverse_each_positive_bignum_section(beg, end);
range_reverse_each_fixnum_section(beg, end);
range_reverse_each_negative_bignum_section(beg, end);
}
else {
return rb_call_super(0, NULL);
}
return range;
}
#size ⇒ non_negative_integer, ...
Returns the count of elements in self if both begin and end values are numeric; otherwise, returns nil:
(1..4).size # => 4
(1...4).size # => 3
(1..).size # => Infinity
('a'..'z').size #=> nilRelated: #count.
# File 'range.c', line 835
static VALUE
range_size(VALUE range)
{
VALUE b = RANGE_BEG(range), e = RANGE_END(range);
if (rb_obj_is_kind_of(b, rb_cNumeric)) {
if (rb_obj_is_kind_of(e, rb_cNumeric)) {
return ruby_num_interval_step_size(b, e, INT2FIX(1), EXCL(range));
}
if (NIL_P(e)) {
return DBL2NUM(HUGE_VAL);
}
}
else if (NIL_P(b)) {
if (rb_obj_is_kind_of(e, rb_cNumeric)) {
return DBL2NUM(HUGE_VAL);
}
}
return Qnil;
}
#step(n = 1) {|element| ... } ⇒ self
#step(n = 1) ⇒ Enumerator
self
#step(n = 1) ⇒ Enumerator
Iterates over the elements of self.
With a block given and no argument, calls the block each element of the range; returns self:
a = []
(1..5).step {|element| a.push(element) } # => 1..5
a # => [1, 2, 3, 4, 5]
a = []
('a'..'e').step {|element| a.push(element) } # => "a".."e"
a # => ["a", "b", "c", "d", "e"]With a block given and a positive integer argument n given, calls the block with element 0, element n, element 2n, and so on:
a = []
(1..5).step(2) {|element| a.push(element) } # => 1..5
a # => [1, 3, 5]
a = []
('a'..'e').step(2) {|element| a.push(element) } # => "a".."e"
a # => ["a", "c", "e"]With no block given, returns an enumerator, which will be of class ::Enumerator::ArithmeticSequence if self is numeric; otherwise of class ::Enumerator:
e = (1..5).step(2) # => ((1..5).step(2))
e.class # => Enumerator::ArithmeticSequence
('a'..'e').step # => #<Enumerator: ...>Related: #%.
# File 'range.c', line 438
static VALUE
range_step(int argc, VALUE *argv, VALUE range)
{
VALUE b, e, step, tmp;
b = RANGE_BEG(range);
e = RANGE_END(range);
step = (!rb_check_arity(argc, 0, 1) ? INT2FIX(1) : argv[0]);
if (!rb_block_given_p()) {
if (!rb_obj_is_kind_of(step, rb_cNumeric)) {
step = rb_to_int(step);
}
if (rb_equal(step, INT2FIX(0))) {
rb_raise(rb_eArgError, "step can't be 0");
}
const VALUE b_num_p = rb_obj_is_kind_of(b, rb_cNumeric);
const VALUE e_num_p = rb_obj_is_kind_of(e, rb_cNumeric);
if ((b_num_p && (NIL_P(e) || e_num_p)) || (NIL_P(b) && e_num_p)) {
return rb_arith_seq_new(range, ID2SYM(rb_frame_this_func()), argc, argv,
range_step_size, b, e, step, EXCL(range));
}
RETURN_SIZED_ENUMERATOR(range, argc, argv, range_step_size);
}
step = check_step_domain(step);
VALUE iter[2] = {INT2FIX(1), step};
if (FIXNUM_P(b) && NIL_P(e) && FIXNUM_P(step)) {
long i = FIX2LONG(b), unit = FIX2LONG(step);
do {
rb_yield(LONG2FIX(i));
i += unit; /* FIXABLE+FIXABLE never overflow */
} while (FIXABLE(i));
b = LONG2NUM(i);
for (;; b = rb_big_plus(b, step))
rb_yield(b);
}
else if (FIXNUM_P(b) && FIXNUM_P(e) && FIXNUM_P(step)) { /* fixnums are special */
long end = FIX2LONG(e);
long i, unit = FIX2LONG(step);
if (!EXCL(range))
end += 1;
i = FIX2LONG(b);
while (i < end) {
rb_yield(LONG2NUM(i));
if (i + unit < i) break;
i += unit;
}
}
else if (SYMBOL_P(b) && (NIL_P(e) || SYMBOL_P(e))) { /* symbols are special */
b = rb_sym2str(b);
if (NIL_P(e)) {
rb_str_upto_endless_each(b, sym_step_i, (VALUE)iter);
}
else {
rb_str_upto_each(b, rb_sym2str(e), EXCL(range), sym_step_i, (VALUE)iter);
}
}
else if (ruby_float_step(b, e, step, EXCL(range), TRUE)) {
/* done */
}
else if (rb_obj_is_kind_of(b, rb_cNumeric) ||
!NIL_P(rb_check_to_integer(b, "to_int")) ||
!NIL_P(rb_check_to_integer(e, "to_int"))) {
ID op = EXCL(range) ? '<' : idLE;
VALUE v = b;
int i = 0;
while (NIL_P(e) || RTEST(rb_funcall(v, op, 1, e))) {
rb_yield(v);
i++;
v = rb_funcall(b, '+', 1, rb_funcall(INT2NUM(i), '*', 1, step));
}
}
else {
tmp = rb_check_string_type(b);
if (!NIL_P(tmp)) {
b = tmp;
if (NIL_P(e)) {
rb_str_upto_endless_each(b, step_i, (VALUE)iter);
}
else {
rb_str_upto_each(b, e, EXCL(range), step_i, (VALUE)iter);
}
}
else {
if (!discrete_object_p(b)) {
rb_raise(rb_eTypeError, "can't iterate from %s",
rb_obj_classname(b));
}
if (!NIL_P(e))
range_each_func(range, step_i, (VALUE)iter);
else
for (;; b = rb_funcallv(b, id_succ, 0, 0))
step_i(b, (VALUE)iter);
}
}
return range;
}
#to_a ⇒ Array Also known as: #entries
Returns an array containing the elements in self, if a finite collection; raises an exception otherwise.
(1..4).to_a # => [1, 2, 3, 4]
(1...4).to_a # => [1, 2, 3]
('a'..'d').to_a # => ["a", "b", "c", "d"]# File 'range.c', line 869
static VALUE
range_to_a(VALUE range)
{
if (NIL_P(RANGE_END(range))) {
rb_raise(rb_eRangeError, "cannot convert endless range to an array");
}
return rb_call_super(0, 0);
}
#to_s ⇒ String
Returns a string representation of self, including begin.to_s and end.to_s:
(1..4).to_s # => "1..4"
(1...4).to_s # => "1...4"
(1..).to_s # => "1.."
(..4).to_s # => "..4"Note that returns from #to_s and #inspect may differ:
('a'..'d').to_s # => "a..d"
('a'..'d').inspect # => "\"a\"..\"d\""Related: #inspect.
# File 'range.c', line 1781
static VALUE
range_to_s(VALUE range)
{
VALUE str, str2;
str = rb_obj_as_string(RANGE_BEG(range));
str2 = rb_obj_as_string(RANGE_END(range));
str = rb_str_dup(str);
rb_str_cat(str, "...", EXCL(range) ? 3 : 2);
rb_str_append(str, str2);
return str;
}