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state.rb
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#-- # # # # Copyright (c) 1999-2006 Minero Aoki # # This program is free software. # You can distribute/modify this program under the same terms of ruby. # see the file "COPYING". # #++ require 'racc/iset' require 'racc/statetransitiontable' require 'racc/exception' require 'forwardable' module Racc # A table of LALR states. class States include Enumerable def initialize(grammar, debug_flags = DebugFlags.new) @grammar = grammar @symboltable = grammar.symboltable @d_state = debug_flags.state @d_la = debug_flags.la @d_prec = debug_flags.prec @states = [] @statecache = {} @actions = ActionTable.new(@grammar, self) @nfa_computed = false @dfa_computed = false end attr_reader :grammar attr_reader :actions def size @states.size end def inspect '#<state table>' end alias to_s inspect def [](i) @states[i] end def each_state(&block) @states.each(&block) end alias each each_state def each_index(&block) @states.each_index(&block) end extend Forwardable def_delegator "@actions", :shift_n def_delegator "@actions", :reduce_n def_delegator "@actions", :nt_base def should_report_srconflict? srconflict_exist? and (n_srconflicts() != @grammar.n_expected_srconflicts) end def srconflict_exist? n_srconflicts() != 0 end def n_srconflicts @n_srconflicts ||= inject(0) {|sum, st| sum + st.n_srconflicts } end def rrconflict_exist? n_rrconflicts() != 0 end def n_rrconflicts @n_rrconflicts ||= inject(0) {|sum, st| sum + st.n_rrconflicts } end def state_transition_table @state_transition_table ||= StateTransitionTable.generate(self.dfa) end # # NFA (Non-deterministic Finite Automaton) Computation # public def nfa return self if @nfa_computed compute_nfa @nfa_computed = true self end private def compute_nfa @grammar.init # add state 0 core_to_state [ @grammar[0].ptrs[0] ] # generate LALR states cur = 0 @gotos = [] while cur < @states.size generate_states @states[cur] # state is added here cur += 1 end @actions.init end def generate_states(state) puts "dstate: #{state}" if @d_state table = {} state.closure.each do |ptr| if sym = ptr.dereference addsym table, sym, ptr.next end end table.each do |sym, core| puts "dstate: sym=#{sym} ncore=#{core}" if @d_state dest = core_to_state(core.to_a) state.goto_table[sym] = dest id = sym.nonterminal?() ? @gotos.size : nil g = Goto.new(id, sym, state, dest) @gotos.push g if sym.nonterminal? state.gotos[sym] = g puts "dstate: #{state.ident} --#{sym}--> #{dest.ident}" if @d_state # check infinite recursion if state.ident == dest.ident and state.closure.size == 1 raise CompileError, sprintf("Infinite recursion: state %d, with rule %d", state.ident, state.ptrs[0].rule.ident) end end end def addsym(table, sym, ptr) unless s = table[sym] table[sym] = s = ISet.new end s.add ptr end def core_to_state(core) # # convert CORE to a State object. # If matching state does not exist, create it and add to the table. # k = fingerprint(core) unless dest = @statecache[k] # not registered yet dest = State.new(@states.size, core) @states.push dest @statecache[k] = dest puts "core_to_state: create state ID #{dest.ident}" if @d_state else if @d_state puts "core_to_state: dest is cached ID #{dest.ident}" puts "core_to_state: dest core #{dest.core.join(' ')}" end end dest end def fingerprint(arr) arr.map {|i| i.ident }.pack('L*') end # # DFA (Deterministic Finite Automaton) Generation # public def dfa return self if @dfa_computed nfa compute_dfa @dfa_computed = true self end private def compute_dfa la = lookahead() @states.each do |state| state.la = la resolve state end set_accept @states.each do |state| pack state end check_useless end def lookahead # # lookahead algorithm ver.3 -- from bison 1.26 # gotos = @gotos if @d_la puts "\n--- goto ---" gotos.each_with_index {|g, i| print i, ' '; p g } end ### initialize_LA() ### set_goto_map() la_rules = [] @states.each do |state| state.check_la la_rules end ### initialize_F() f = create_tmap(gotos.size) reads = [] edge = [] gotos.each do |goto| goto.to_state.goto_table.each do |t, st| if t.terminal? f[goto.ident] |= (1 << t.ident) elsif t.nullable? edge.push goto.to_state.gotos[t].ident end end if edge.empty? reads.push nil else reads.push edge edge = [] end end digraph f, reads if @d_la puts "\n--- F1 (reads) ---" print_tab gotos, reads, f end ### build_relations() ### compute_FOLLOWS path = nil edge = [] lookback = Array.new(la_rules.size, nil) includes = [] gotos.each do |goto| goto.symbol.heads.each do |ptr| path = record_path(goto.from_state, ptr.rule) lastgoto = path.last st = lastgoto ? lastgoto.to_state : goto.from_state if st.conflict? addrel lookback, st.rruleid(ptr.rule), goto end path.reverse_each do |g| break if g.symbol.terminal? edge.push g.ident break unless g.symbol.nullable? end end if edge.empty? includes.push nil else includes.push edge edge = [] end end includes = transpose(includes) digraph f, includes if @d_la puts "\n--- F2 (includes) ---" print_tab gotos, includes, f end ### compute_lookaheads la = create_tmap(la_rules.size) lookback.each_with_index do |arr, i| if arr arr.each do |g| la[i] |= f[g.ident] end end end if @d_la puts "\n--- LA (lookback) ---" print_tab la_rules, lookback, la end la end def create_tmap(size) Array.new(size, 0) # use Integer as bitmap end def addrel(tbl, i, item) if a = tbl[i] a.push item else tbl[i] = [item] end end def record_path(begst, rule) st = begst path = [] rule.symbols.each do |t| goto = st.gotos[t] path.push goto st = goto.to_state end path end def transpose(rel) new = Array.new(rel.size, nil) rel.each_with_index do |arr, idx| if arr arr.each do |i| addrel new, i, idx end end end new end def digraph(map, relation) n = relation.size index = Array.new(n, nil) vertices = [] @infinity = n + 2 index.each_index do |i| if not index[i] and relation[i] traverse i, index, vertices, map, relation end end end def traverse(i, index, vertices, map, relation) vertices.push i index[i] = height = vertices.size if rp = relation[i] rp.each do |proci| unless index[proci] traverse proci, index, vertices, map, relation end if index[i] > index[proci] # circulative recursion !!! index[i] = index[proci] end map[i] |= map[proci] end end if index[i] == height while true proci = vertices.pop index[proci] = @infinity break if i == proci map[proci] |= map[i] end end end # for debug def print_atab(idx, tab) tab.each_with_index do |i,ii| printf '%-20s', idx[ii].inspect p i end end def print_tab(idx, rel, tab) tab.each_with_index do |bin,i| print i, ' ', idx[i].inspect, ' << '; p rel[i] print ' ' each_t(@symboltable, bin) {|t| print ' ', t } puts end end # for debug def print_tab_i(idx, rel, tab, i) bin = tab[i] print i, ' ', idx[i].inspect, ' << '; p rel[i] print ' ' each_t(@symboltable, bin) {|t| print ' ', t } end # for debug def printb(i) each_t(@symboltable, i) do |t| print t, ' ' end puts end def each_t(tbl, set) 0.upto( set.size ) do |i| (0..7).each do |ii| if set[idx = i * 8 + ii] == 1 yield tbl[idx] end end end end # # resolve # def resolve(state) if state.conflict? resolve_rr state, state.ritems resolve_sr state, state.stokens else if state.rrules.empty? # shift state.stokens.each do |t| state.action[t] = @actions.shift(state.goto_table[t]) end else # reduce state.defact = @actions.reduce(state.rrules[0]) end end end def resolve_rr(state, r) r.each do |item| item.each_la(@symboltable) do |t| act = state.action[t] if act unless act.kind_of?(Reduce) raise "racc: fatal: #{act.class} in action table" end # Cannot resolve R/R conflict (on t). # Reduce with upper rule as default. state.rr_conflict act.rule, item.rule, t else # No conflict. state.action[t] = @actions.reduce(item.rule) end end end end def resolve_sr(state, s) s.each do |stok| goto = state.goto_table[stok] act = state.action[stok] unless act # no conflict state.action[stok] = @actions.shift(goto) else unless act.kind_of?(Reduce) puts 'DEBUG -------------------------------' p stok p act state.action.each do |k,v| print k.inspect, ' ', v.inspect, "\n" end raise "racc: fatal: #{act.class} in action table" end # conflict on stok rtok = act.rule.precedence case do_resolve_sr(stok, rtok) when :Reduce # action is already set when :Shift # overwrite act.decref state.action[stok] = @actions.shift(goto) when :Error act.decref state.action[stok] = @actions.error when :CantResolve # shift as default act.decref state.action[stok] = @actions.shift(goto) state.sr_conflict stok, act.rule end end end end ASSOC = { :Left => :Reduce, :Right => :Shift, :Nonassoc => :Error } def do_resolve_sr(stok, rtok) puts "resolve_sr: s/r conflict: rtok=#{rtok}, stok=#{stok}" if @d_prec unless rtok and rtok.precedence puts "resolve_sr: no prec for #{rtok}(R)" if @d_prec return :CantResolve end rprec = rtok.precedence unless stok and stok.precedence puts "resolve_sr: no prec for #{stok}(S)" if @d_prec return :CantResolve end sprec = stok.precedence ret = if rprec == sprec ASSOC[rtok.assoc] or raise "racc: fatal: #{rtok}.assoc is not Left/Right/Nonassoc" else (rprec > sprec) ? (:Reduce) : (:Shift) end puts "resolve_sr: resolved as #{ret.id2name}" if @d_prec ret end # # complete # def set_accept anch = @symboltable.anchor init_state = @states[0].goto_table[@grammar.start] targ_state = init_state.action[anch].goto_state acc_state = targ_state.action[anch].goto_state acc_state.action.clear acc_state.goto_table.clear acc_state.defact = @actions.accept end def pack(state) ### find most frequently used reduce rule act = state.action arr = Array.new(@grammar.size, 0) act.each do |t, a| arr[a.ruleid] += 1 if a.kind_of?(Reduce) end i = arr.max s = (i > 0) ? arr.index(i) : nil ### set & delete default action if s r = @actions.reduce(s) if not state.defact or state.defact == r act.delete_if {|t, a| a == r } state.defact = r end else state.defact ||= @actions.error end end def check_useless used = [] @actions.each_reduce do |act| if not act or act.refn == 0 act.rule.useless = true else t = act.rule.target used[t.ident] = t end end @symboltable.nt_base.upto(@symboltable.nt_max - 1) do |n| unless used[n] @symboltable[n].useless = true end end end end # class StateTable # A LALR state. class State def initialize(ident, core) @ident = ident @core = core @goto_table = {} @gotos = {} @stokens = nil @ritems = nil @action = {} @defact = nil @rrconf = nil @srconf = nil @closure = make_closure(@core) end attr_reader :ident alias stateid ident alias hash ident attr_reader :core attr_reader :closure attr_reader :goto_table attr_reader :gotos attr_reader :stokens attr_reader :ritems attr_reader :rrules attr_reader :action attr_accessor :defact # default action attr_reader :rrconf attr_reader :srconf def inspect "<state #{@ident}>" end alias to_s inspect def ==(oth) @ident == oth.ident end alias eql? == def make_closure(core) set = ISet.new core.each do |ptr| set.add ptr if t = ptr.dereference and t.nonterminal? set.update_a t.expand end end set.to_a end def check_la(la_rules) @conflict = false s = [] r = [] @closure.each do |ptr| if t = ptr.dereference if t.terminal? s[t.ident] = t if t.ident == 1 # $error @conflict = true end end else r.push ptr.rule end end unless r.empty? if not s.empty? or r.size > 1 @conflict = true end end s.compact! @stokens = s @rrules = r if @conflict @la_rules_i = la_rules.size @la_rules = r.map {|i| i.ident } la_rules.concat r else @la_rules_i = @la_rules = nil end end def conflict? @conflict end def rruleid(rule) if i = @la_rules.index(rule.ident) @la_rules_i + i else puts '/// rruleid' p self p rule p @rrules p @la_rules_i raise 'racc: fatal: cannot get reduce rule id' end end def la=(la) return unless @conflict i = @la_rules_i @ritems = r = [] @rrules.each do |rule| r.push Item.new(rule, la[i]) i += 1 end end def rr_conflict(high, low, ctok) c = RRconflict.new(@ident, high, low, ctok) @rrconf ||= {} if a = @rrconf[ctok] a.push c else @rrconf[ctok] = [c] end end def sr_conflict(shift, reduce) c = SRconflict.new(@ident, shift, reduce) @srconf ||= {} if a = @srconf[shift] a.push c else @srconf[shift] = [c] end end def n_srconflicts @srconf ? @srconf.size : 0 end def n_rrconflicts @rrconf ? @rrconf.size : 0 end end # class State # # Represents a transition on the grammar. # "Real goto" means a transition by nonterminal, # but this class treats also terminal's. # If one is a terminal transition, .ident returns nil. # class Goto def initialize(ident, sym, from, to) @ident = ident @symbol = sym @from_state = from @to_state = to end attr_reader :ident attr_reader :symbol attr_reader :from_state attr_reader :to_state def inspect "(#{@from_state.ident}-#{@symbol}->#{@to_state.ident})" end end # LALR item. A set of rule and its lookahead tokens. class Item def initialize(rule, la) @rule = rule @la = la end attr_reader :rule attr_reader :la def each_la(tbl) la = @la 0.upto(la.size - 1) do |i| (0..7).each do |ii| if la[idx = i * 8 + ii] == 1 yield tbl[idx] end end end end end # The table of LALR actions. Actions are either of # Shift, Reduce, Accept and Error. class ActionTable def initialize(rt, st) @grammar = rt @statetable = st @reduce = [] @shift = [] @accept = nil @error = nil end def init @grammar.each do |rule| @reduce.push Reduce.new(rule) end @statetable.each do |state| @shift.push Shift.new(state) end @accept = Accept.new @error = Error.new end def reduce_n @reduce.size end def reduce(i) case i when Rule then i = i.ident when Integer then ; else raise "racc: fatal: wrong class #{i.class} for reduce" end r = @reduce[i] or raise "racc: fatal: reduce action #{i.inspect} not exist" r.incref r end def each_reduce(&block) @reduce.each(&block) end def shift_n @shift.size end def shift(i) case i when State then i = i.ident when Integer then ; else raise "racc: fatal: wrong class #{i.class} for shift" end @shift[i] or raise "racc: fatal: shift action #{i} does not exist" end def each_shift(&block) @shift.each(&block) end attr_reader :accept attr_reader :error end class Shift def initialize(goto) @goto_state = goto end attr_reader :goto_state def goto_id @goto_state.ident end def inspect "<shift #{@goto_state.ident}>" end end class Reduce def initialize(rule) @rule = rule @refn = 0 end attr_reader :rule attr_reader :refn def ruleid @rule.ident end def inspect "<reduce #{@rule.ident}>" end def incref @refn += 1 end def decref @refn -= 1 raise 'racc: fatal: act.refn < 0' if @refn < 0 end end class Accept def inspect "<accept>" end end class Error def inspect "<error>" end end class SRconflict def initialize(sid, shift, reduce) @stateid = sid @shift = shift @reduce = reduce end attr_reader :stateid attr_reader :shift attr_reader :reduce def to_s sprintf('state %d: S/R conflict rule %d reduce and shift %s', @stateid, @reduce.ruleid, @shift.to_s) end end class RRconflict def initialize(sid, high, low, tok) @stateid = sid @high_prec = high @low_prec = low @token = tok end attr_reader :stateid attr_reader :high_prec attr_reader :low_prec attr_reader :token def to_s sprintf('state %d: R/R conflict with rule %d and %d on %s', @stateid, @high_prec.ident, @low_prec.ident, @token.to_s) end end end