#!/usr/bin/env ruby require 'nlp_ruby' require_relative 'grammar' class Chart def initialize n @m = [] (n+1).times { _ = [] (n+1).times { _ << [] } @m << _ } @b = {} end def at i, j @m[i][j] end def add item, i, j at(i,j) << item @b["#{i},#{j},#{item.lhs.symbol}"] = true end def has symbol, i, j return @b["#{i},#{j},#{symbol}"] end end Span = Struct.new(:left, :right) class Item < Grammar::Rule attr_accessor :left, :right, :tail_spans, :dot, :f def initialize rule_or_item, left, right, dot @lhs = Grammar::NT.new(rule_or_item.lhs.symbol, rule_or_item.lhs.index) @left = left @right = right @rhs = [] @tail_spans = {} @f = rule_or_item.f @map = (rule_or_item.map ? rule_or_item.map.dup : []) rule_or_item.rhs.each_with_index { |x,i| if x.class == Grammar::T @rhs << Grammar::T.new(x.word) end if x.class == Grammar::NT @rhs << Grammar::NT.new(x.symbol, x.index) begin @tail_spans[i] = rule_or_item.tail_spans[i].dup rescue @tail_spans[i] = Span.new(-1, -1) end end } @dot = dot @target = rule_or_item.target end def to_s "(#{@left}, #{@right}) [#{tail_spans.map{|k,v| k.to_s+'('+v.left.to_s+','+v.right.to_s+')'}.join ' '}] {#{@map.to_s.delete('[]')}} #{lhs} -> #{rhs.map{|i|i.to_s}.insert(@dot,'*').join ' '} [dot@#{@dot}] ||| #{@target.map{|x|x.to_s}.join ' '}" end end def init input, n, active_chart, passive_chart, grammar grammar.flat.each { |r| input.each_index { |i| if input[i, r.rhs.size] == r.rhs.map { |x| x.word } passive_chart.add Item.new(r, i, i+r.rhs.size, r.rhs.size), i, i+r.rhs.size end } } end def scan item, input, limit, passive_chart while item.rhs[item.dot].class == Grammar::T return false if item.right==limit if item.rhs[item.dot].word == input[item.right] item.dot += 1 item.right += 1 else return false end end return true end def visit i, l, r, x=0 i.upto(r-x) { |span| l.upto(r-span) { |k| yield k, k+span } } end def parse input, n, active_chart, passive_chart, grammar visit(1, 0, n) { |i,j| STDERR.write " span(#{i},#{j})\n" # try to apply rules starting with T grammar.startt.select { |r| r.rhs.first.word == input[i] }.each { |r| new_item = Item.new r, i, i, 0 active_chart.at(i,j) << new_item if scan new_item, input, j, passive_chart } # seed active chart grammar.startn.each { |r| next if r.rhs.size > j-i active_chart.at(i,j) << Item.new(r, i, i, 0) } # parse new_symbols = [] remaining_items = [] while !active_chart.at(i,j).empty? active_item = active_chart.at(i,j).pop advanced = false visit(1, i, j, 1) { |k,l| if passive_chart.has active_item.rhs[active_item.dot].symbol, k, l if k == active_item.right new_item = Item.new active_item, active_item.left, l, active_item.dot+1 new_item.tail_spans[new_item.dot-1] = Span.new(k,l) if scan new_item, input, j, passive_chart if new_item.dot == new_item.rhs.size if new_item.left == i && new_item.right == j new_symbols << new_item.lhs.symbol if !new_symbols.include? new_item.lhs.symbol passive_chart.add new_item, i, j advanced = true end else if new_item.right+(new_item.rhs.size-(new_item.dot)) <= j active_chart.at(i,j) << new_item advanced = true end end end end end } if !advanced remaining_items << active_item end end # 'self-filling' step new_symbols.each { |s| remaining_items.each { |active_item| next if active_item.dot!=0 next if active_item.rhs[active_item.dot].class!=Grammar::NT if active_item.rhs[active_item.dot].symbol == s new_item = Item.new active_item, i, j, active_item.dot+1 new_item.tail_spans[new_item.dot-1] = Span.new(i,j) if new_item.dot==new_item.rhs.size new_symbols << new_item.lhs.symbol if !new_symbols.include? new_item.lhs.symbol passive_chart.add new_item, i, j end end } } } end