class Numeric # call-seq: # dup -> self # # Returns +self+. # # Related: Numeric#clone. # def dup self end # call-seq: # real? -> true or false # # Returns +true+ if +self+ is a real number (i.e. not Complex). # def real? true end # call-seq: # real -> self # # Returns +self+. # def real self end # call-seq: # integer? -> true or false # # Returns +true+ if +self+ is an Integer. # # 1.0.integer? # => false # 1.integer? # => true # def integer? false end # call-seq: # finite? -> true or false # # Returns +true+ if +self+ is a finite number, +false+ otherwise. # def finite? true end # call-seq: # infinite? -> -1, 1, or nil # # Returns +nil+, -1, or 1 depending on whether +self+ is # finite, -Infinity, or +Infinity. # def infinite? nil end # call-seq: # imag -> 0 # # Returns zero. # def imaginary 0 end alias imag imaginary # call-seq: # conj -> self # # Returns +self+. # def conjugate self end alias conj conjugate # call-seq: # +self -> self # # Returns +self+. # def +@ self end end class Integer # call-seq: # -int -> integer # # Returns +self+, negated. def -@ Primitive.attr! :leaf Primitive.cexpr! 'rb_int_uminus(self)' end # call-seq: # ~int -> integer # # One's complement: # returns the value of +self+ with each bit inverted. # # Because an integer value is conceptually of infinite length, # the result acts as if it had an infinite number of # one bits to the left. # In hex representations, this is displayed # as two periods to the left of the digits: # # sprintf("%X", ~0x1122334455) # => "..FEEDDCCBBAA" # def ~ Primitive.attr! :leaf Primitive.cexpr! 'rb_int_comp(self)' end # call-seq: # abs -> integer # # Returns the absolute value of +self+. # # (-12345).abs # => 12345 # -12345.abs # => 12345 # 12345.abs # => 12345 # def abs Primitive.attr! :leaf Primitive.cexpr! 'rb_int_abs(self)' end # call-seq: # bit_length -> integer # # Returns the number of bits of the value of +self+, # which is the bit position of the highest-order bit # that is different from the sign bit # (where the least significant bit has bit position 1). # If there is no such bit (zero or minus one), returns zero. # # This method returns ceil(log2(self < 0 ? -self : self + 1))>. # # (-2**1000-1).bit_length # => 1001 # (-2**1000).bit_length # => 1000 # (-2**1000+1).bit_length # => 1000 # (-2**12-1).bit_length # => 13 # (-2**12).bit_length # => 12 # (-2**12+1).bit_length # => 12 # -0x101.bit_length # => 9 # -0x100.bit_length # => 8 # -0xff.bit_length # => 8 # -2.bit_length # => 1 # -1.bit_length # => 0 # 0.bit_length # => 0 # 1.bit_length # => 1 # 0xff.bit_length # => 8 # 0x100.bit_length # => 9 # (2**12-1).bit_length # => 12 # (2**12).bit_length # => 13 # (2**12+1).bit_length # => 13 # (2**1000-1).bit_length # => 1000 # (2**1000).bit_length # => 1001 # (2**1000+1).bit_length # => 1001 # # For \Integer _n_, # this method can be used to detect overflow in Array#pack: # # if n.bit_length < 32 # [n].pack('l') # No overflow. # else # raise 'Overflow' # end # def bit_length Primitive.attr! :leaf Primitive.cexpr! 'rb_int_bit_length(self)' end # call-seq: # even? -> true or false # # Returns +true+ if +self+ is an even number, +false+ otherwise. def even? Primitive.attr! :leaf Primitive.cexpr! 'rb_int_even_p(self)' end # call-seq: # integer? -> true # # Since +self+ is already an \Integer, always returns +true+. def integer? true end alias magnitude abs # call-seq: # odd? -> true or false # # Returns +true+ if +self+ is an odd number, +false+ otherwise. def odd? Primitive.attr! :leaf Primitive.cexpr! 'rb_int_odd_p(self)' end # call-seq: # ord -> self # # Returns +self+; # intended for compatibility to character literals in Ruby 1.9. def ord self end # call-seq: # size -> integer # # Returns the number of bytes in the machine representation of +self+; # the value is system-dependent: # # 1.size # => 8 # -1.size # => 8 # 2147483647.size # => 8 # (256**10 - 1).size # => 10 # (256**20 - 1).size # => 20 # (256**40 - 1).size # => 40 # def size Primitive.attr! :leaf Primitive.cexpr! 'rb_int_size(self)' end # call-seq: # times {|i| ... } -> self # times -> enumerator # # Calls the given block +self+ times with each integer in (0..self-1): # # a = [] # 5.times {|i| a.push(i) } # => 5 # a # => [0, 1, 2, 3, 4] # # With no block given, returns an Enumerator. def times Primitive.attr! :inline_block unless defined?(yield) return Primitive.cexpr! 'SIZED_ENUMERATOR(self, 0, 0, int_dotimes_size)' end i = 0 while i < self yield i i = i.succ end self end # call-seq: # to_i -> self # # Returns +self+ (which is already an \Integer). def to_i self end # call-seq: # to_int -> self # # Returns +self+ (which is already an \Integer). def to_int self end # call-seq: # zero? -> true or false # # Returns +true+ if +self+ has a zero value, +false+ otherwise. def zero? Primitive.attr! :leaf Primitive.cexpr! 'rb_int_zero_p(self)' end # call-seq: # ceildiv(numeric) -> integer # # Returns the result of division +self+ by +numeric+. # rounded up to the nearest integer. # # 3.ceildiv(3) # => 1 # 4.ceildiv(3) # => 2 # # 4.ceildiv(-3) # => -1 # -4.ceildiv(3) # => -1 # -4.ceildiv(-3) # => 2 # # 3.ceildiv(1.2) # => 3 # def ceildiv(other) -div(0 - other) end # # call-seq: # numerator -> self # # Returns +self+. # def numerator self end # call-seq: # denominator -> 1 # # Returns +1+. def denominator 1 end with_yjit do if Primitive.rb_builtin_basic_definition_p(:downto) undef :downto def downto(to) # :nodoc: Primitive.attr! :inline_block, :c_trace # When no block is given, return an Enumerator that enumerates from `self` to `to`. # Not using `block_defined?` and `to_enum` to keep them unaffected by redefinitions. unless defined?(yield) return Primitive.cexpr! 'SIZED_ENUMERATOR(self, 1, &to, int_downto_size)' end from = self while from >= to yield from from = from.pred end self end end end end class Float # call-seq: # to_f -> self # # Returns +self+ (which is already a \Float). def to_f self end # call-seq: # float.abs -> float # # Returns the absolute value of +self+: # # (-34.56).abs # => 34.56 # -34.56.abs # => 34.56 # 34.56.abs # => 34.56 # def abs Primitive.attr! :leaf Primitive.cexpr! 'rb_float_abs(self)' end alias magnitude abs # call-seq: # -float -> float # # Returns +self+, negated. # def -@ Primitive.attr! :leaf Primitive.cexpr! 'rb_float_uminus(self)' end # call-seq: # zero? -> true or false # # Returns +true+ if +self+ is 0.0, +false+ otherwise. def zero? Primitive.attr! :leaf Primitive.cexpr! 'RBOOL(FLOAT_ZERO_P(self))' end # call-seq: # positive? -> true or false # # Returns +true+ if +self+ is greater than 0, +false+ otherwise. def positive? Primitive.attr! :leaf Primitive.cexpr! 'RBOOL(RFLOAT_VALUE(self) > 0.0)' end # call-seq: # negative? -> true or false # # Returns +true+ if +self+ is less than 0, +false+ otherwise. def negative? Primitive.attr! :leaf Primitive.cexpr! 'RBOOL(RFLOAT_VALUE(self) < 0.0)' end end