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ruby--ruby/test/ruby/sentence.rb

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# == sentence library
#
# = Features
#
# * syntax based sentences generation
# * sentence operations such as substitution.
#
# = Example
#
# Some arithmetic expressions using "+", "-", "*" and "/" are generated as follows.
#
# require 'sentence'
# Sentence.each({
# :exp => [["num"],
# [:exp, "+", :exp],
# [:exp, "-", :exp],
# [:exp, "*", :exp],
# [:exp, "/", :exp]]
# }, :exp, 2) {|sent| p sent }
# #=>
# #<Sentence: "num">
# #<Sentence: ("num") "+" ("num")>
# #<Sentence: ("num") "+" (("num") "+" ("num"))>
# #<Sentence: ("num") "+" (("num") "-" ("num"))>
# #<Sentence: ("num") "+" (("num") "*" ("num"))>
# #<Sentence: ("num") "+" (("num") "/" ("num"))>
# #<Sentence: (("num") "+" ("num")) "+" ("num")>
# ...
#
# Sentence.each takes 3 arguments.
# The first argument is the syntax for the expressions.
# The second argument, :exp, is a generating nonterminal.
# The third argument, 2, limits derivation to restrict results finitely.
#
# Some arithmetic expressions including parenthesis can be generated as follows.
#
# syntax = {
# :factor => [["n"],
# ["(", :exp, ")"]],
# :term => [[:factor],
# [:term, "*", :factor],
# [:term, "/", :factor]],
# :exp => [[:term],
# [:exp, "+", :term],
# [:exp, "-", :term]]
# }
# Sentence.each(syntax, :exp, 2) {|sent| p sent }
# #=>
# #<Sentence: (("n"))>
# #<Sentence: (("(" ((("n"))) ")"))>
# #<Sentence: (("(" ((("(" ((("n"))) ")"))) ")"))>
# #<Sentence: (("(" (((("n")) "*" ("n"))) ")"))>
# #<Sentence: (("(" (((("n")) "/" ("n"))) ")"))>
# #<Sentence: (("(" (((("n"))) "+" (("n"))) ")"))>
# #<Sentence: (("(" (((("n"))) "-" (("n"))) ")"))>
# #<Sentence: ((("n")) "*" ("n"))>
# #<Sentence: ((("n")) "*" ("(" ((("n"))) ")"))>
# ...
#
# Sentence#to_s can be used to concatenate strings
# in a sentence:
#
# Sentence.each(syntax, :exp, 2) {|sent| p sent.to_s }
# #=>
# "n"
# "(n)"
# "((n))"
# "(n*n)"
# "(n/n)"
# "(n+n)"
# "(n-n)"
# "n*n"
# "n*(n)"
# ...
#
# Sentence() instantiates a sentence object.
#
# Sentence("foo", "bar")
# #=> #<Sentence: "foo" "bar">
#
# Sentence("foo", ["bar", "baz"])
# #=> #<Sentence: "foo" ("bar" "baz")>
#
def Sentence(*ary)
Sentence.new(ary)
end
# Sentence class represents a tree with string leaves.
#
class Sentence
# _ary_ represents a tree.
# It should be a possibly nested array which contains strings.
#
# Note that _ary_ is not copied.
# Don't modify _ary_ after the sentence object is instantiated.
#
# Sentence.new(["a", "pen"])
# #<Sentence: "a" "pen">
#
# Sentence.new(["I", "have", ["a", "pen"]])
# #<Sentence: "I" "have" ("a" "pen")>
#
def initialize(ary)
@sent = ary
end
# returns a string which is concatenation of all strings.
# No separator is used.
#
# Sentence("2", "+", "3").to_s
# "2+3"
#
# Sentence("2", "+", ["3", "*", "5"]).to_s
# "2+3*5"
#
def to_s
@sent.join('')
end
# returns a string which is concatenation of all strings separated by _sep_.
# If _sep_ is not given, single space is used.
#
# Sentence("I", "have", ["a", "pen"]).join
# "I have a pen"
#
# Sentence("I", "have", ["a", "pen"]).join("/")
# "I/have/a/pen"
#
# Sentence("a", [], "b").join("/")
# "a/b"
#
def join(sep=' ')
@sent.flatten.join(sep)
end
# returns a tree as a nested array.
#
# Note that the result is not copied.
# Don't modify the result.
#
# Sentence(["foo", "bar"], "baz").to_a
# #=> [["foo", "bar"], "baz"]
#
def to_a
@sent
end
# returns <i>i</i>th element as a sentence or string.
#
# s = Sentence(["foo", "bar"], "baz")
# s #=> #<Sentence: ("foo" "bar") "baz">
# s[0] #=> #<Sentence: "foo" "bar">
# s[1] #=> "baz"
#
def [](i)
e = @sent[i]
e.respond_to?(:to_ary) ? Sentence.new(e) : e
end
# returns the number of top level elements.
#
# Sentence.new(%w[foo bar]).length
# #=> 2
#
# Sentence(%w[2 * 7], "+", %w[3 * 5]).length
# #=> 3
#
def length
@sent.length
end
def inspect
"#<#{self.class}: #{inner_inspect(@sent, '')}>"
end
# :stopdoc:
def inner_inspect(ary, r)
first = true
ary.each {|obj|
r << ' ' if !first
first = false
if obj.respond_to? :to_ary
r << '('
inner_inspect(obj, r)
r << ')'
else
r << obj.inspect
end
}
r
end
# :startdoc:
# returns new sentence object which
# _target_ is substituted by the block.
#
# Sentence#subst invokes <tt>_target_ === _string_</tt> for each
# string in the sentence.
# The strings which === returns true are substituted by the block.
# The block is invoked with the substituting string.
#
# Sentence.new(%w[2 + 3]).subst("+") { "*" }
# #<Sentence: "2" "*" "3">
#
# Sentence.new(%w[2 + 3]).subst(/\A\d+\z/) {|s| ((s.to_i)*2).to_s }
# #=> #<Sentence: "4" "+" "6">
#
def subst(target, &b)
Sentence.new(subst_rec(@sent, target, &b))
end
# :stopdoc:
def subst_rec(obj, target, &b)
if obj.respond_to? :to_ary
a = []
obj.each {|e| a << subst_rec(e, target, &b) }
a
elsif target === obj
yield obj
else
obj
end
end
# :startdoc:
# find a subsentence and return it.
# The block is invoked for each subsentence in preorder manner.
# The first subsentence which the block returns true is returned.
#
# Sentence(%w[2 * 7], "+", %w[3 * 5]).find_subtree {|s| s[1] == "*" }
# #=> #<Sentence: "2" "*" "7">
#
def find_subtree(&b)
find_subtree_rec(@sent, &b)
end
# :stopdoc:
def find_subtree_rec(obj, &b)
if obj.respond_to? :to_ary
s = Sentence.new(obj)
if b.call s
return s
else
obj.each {|e|
r = find_subtree_rec(e, &b)
return r if r
}
end
end
nil
end
# :startdoc:
# returns a new sentence object which expands according to the condition
# given by the block.
#
# The block is invoked for each subsentence.
# The subsentences which the block returns true are
# expanded into parent.
#
# s = Sentence(%w[2 * 7], "+", %w[3 * 5])
# #=> #<Sentence: ("2" "*" "7") "+" ("3" "*" "5")>
#
# s.expand { true }
# #=> #<Sentence: "2" "*" "7" "+" "3" "*" "5">
#
# s.expand {|s| s[0] == "3" }
# #=> #<Sentence: (("2" "*" "7") "+" "3" "*" "5")>
#
def expand(&b)
Sentence.new(expand_rec(@sent, &b))
end
# :stopdoc:
def expand_rec(obj, r=[], &b)
if obj.respond_to? :to_ary
s = Sentence.new(obj)
if b.call s
obj.each {|o|
expand_rec(o, r, &b)
}
else
a = []
obj.each {|o|
expand_rec(o, a, &b)
}
r << a
end
else
r << obj
end
r
end
# :startdoc:
# Sentence.each generates sentences
# by deriving the start symbol _sym_ using _syntax_.
# The derivation is restricted by an positive integer _limit_ to
# avoid infinite generation.
#
# Sentence.each yields the block with a generated sentence.
#
# Sentence.each({
# :exp => [["n"],
# [:exp, "+", :exp],
# [:exp, "*", :exp]]
# }, :exp, 1) {|sent| p sent }
# #=>
# #<Sentence: "n">
# #<Sentence: ("n") "+" ("n")>
# #<Sentence: ("n") "*" ("n")>
#
# Sentence.each({
# :exp => [["n"],
# [:exp, "+", :exp],
# [:exp, "*", :exp]]
# }, :exp, 2) {|sent| p sent }
# #=>
# #<Sentence: "n">
# #<Sentence: ("n") "+" ("n")>
# #<Sentence: ("n") "+" (("n") "+" ("n"))>
# #<Sentence: ("n") "+" (("n") "*" ("n"))>
# #<Sentence: (("n") "+" ("n")) "+" ("n")>
# #<Sentence: (("n") "*" ("n")) "+" ("n")>
# #<Sentence: ("n") "*" ("n")>
# #<Sentence: ("n") "*" (("n") "+" ("n"))>
# #<Sentence: ("n") "*" (("n") "*" ("n"))>
# #<Sentence: (("n") "+" ("n")) "*" ("n")>
# #<Sentence: (("n") "*" ("n")) "*" ("n")>
#
def Sentence.each(syntax, sym, limit)
Gen.new(syntax).each_tree(sym, limit) {|tree|
yield Sentence.new(tree)
}
end
# Sentence.expand_syntax returns an expanded syntax:
# * No rule derives to empty sequence
# * Underivable rule simplified
# * No channel rule
# * Symbols which has zero or one choices are not appered in rhs.
#
# Note that the rules which can derive empty and non-empty
# sequences are modified to derive only non-empty sequences.
#
# Sentence.expand_syntax({
# :underivable1 => [],
# :underivable2 => [[:underivable1]],
# :underivable3 => [[:underivable3]],
# :empty_only1 => [[]],
# :empty_only2 => [[:just_empty1, :just_empty1]],
# :empty_or_not => [[], ["foo"]],
# :empty_or_not_2 => [[:empty_or_not, :empty_or_not]],
# :empty_or_not_3 => [[:empty_or_not, :empty_or_not, :empty_or_not]],
# :empty_or_not_4 => [[:empty_or_not_2, :empty_or_not_2]],
# :channel1 => [[:channeled_data]],
# :channeled_data => [["a", "b"], ["c", "d"]],
# :single_choice => [["single", "choice"]],
# :single_choice_2 => [[:single_choice, :single_choice]],
# })
# #=>
# {
# :underivable1=>[], # underivable rules are simplified to [].
# :underivable2=>[],
# :underivable3=>[],
# :empty_only1=>[], # derivation to empty sequence are removed.
# :empty_only2=>[],
# :empty_or_not=>[["foo"]], # empty sequences are removed too.
# :empty_or_not_2=>[["foo"], ["foo", "foo"]],
# :empty_or_not_3=>[["foo"], ["foo", "foo"], ["foo", "foo", "foo"]],
# :empty_or_not_4=> [["foo"], ["foo", "foo"], [:empty_or_not_2, :empty_or_not_2]],
# :channel1=>[["a", "b"], ["c", "d"]], # channel rules are removed.
# :channeled_data=>[["a", "b"], ["c", "d"]],
# :single_choice=>[["single", "choice"]], # single choice rules are expanded.
# :single_choice_2=>[["single", "choice", "single", "choice"]],
# }
#
# Sentence.expand_syntax({
# :factor => [["n"],
# ["(", :exp, ")"]],
# :term => [[:factor],
# [:term, "*", :factor],
# [:term, "/", :factor]],
# :exp => [[:term],
# [:exp, "+", :term],
# [:exp, "-", :term]]
# })
# #=>
# {:exp=> [["n"],
# ["(", :exp, ")"],
# [:exp, "+", :term],
# [:exp, "-", :term],
# [:term, "*", :factor],
# [:term, "/", :factor]],
# :factor=> [["n"],
# ["(", :exp, ")"]],
# :term=> [["n"],
# ["(", :exp, ")"],
# [:term, "*", :factor],
# [:term, "/", :factor]]
# }
#
def Sentence.expand_syntax(syntax)
Sentence::Gen.expand_syntax(syntax)
end
# :stopdoc:
class Gen
def Gen.each_tree(syntax, sym, limit, &b)
Gen.new(syntax).each_tree(sym, limit, &b)
end
def Gen.each_string(syntax, sym, limit, &b)
Gen.new(syntax).each_string(sym, limit, &b)
end
def initialize(syntax)
@syntax = syntax
end
def self.expand_syntax(syntax)
syntax = simplify_underivable_rules(syntax)
syntax = simplify_emptyonly_rules(syntax)
syntax = make_rules_no_empseq(syntax)
syntax = expand_channel_rules(syntax)
syntax = expand_noalt_rules(syntax)
syntax = reorder_rules(syntax)
end
def self.simplify_underivable_rules(syntax)
deribable_syms = {}
changed = true
while changed
changed = false
syntax.each {|sym, rules|
next if deribable_syms[sym]
rules.each {|rhs|
if rhs.all? {|e| String === e || deribable_syms[e] }
deribable_syms[sym] = true
changed = true
break
end
}
}
end
result = {}
syntax.each {|sym, rules|
if deribable_syms[sym]
rules2 = []
rules.each {|rhs|
rules2 << rhs if rhs.all? {|e| String === e || deribable_syms[e] }
}
result[sym] = rules2.uniq
else
result[sym] = []
end
}
result
end
def self.simplify_emptyonly_rules(syntax)
justempty_syms = {}
changed = true
while changed
changed = false
syntax.each {|sym, rules|
next if justempty_syms[sym]
if !rules.empty? && rules.all? {|rhs| rhs.all? {|e| justempty_syms[e] } }
justempty_syms[sym] = true
changed = true
end
}
end
result = {}
syntax.each {|sym, rules|
result[sym] = rules.map {|rhs| rhs.reject {|e| justempty_syms[e] } }.uniq
}
result
end
def self.expand_emptyable_syms(rhs, emptyable_syms)
if rhs.empty?
elsif rhs.length == 1
if emptyable_syms[rhs[0]]
yield rhs
yield []
else
yield rhs
end
else
rest = rhs.dup
first = rest.shift
if emptyable_syms[first]
expand_emptyable_syms(rest, emptyable_syms) {|rhs2|
yield [first] + rhs2
yield rhs2
}
else
expand_emptyable_syms(rest, emptyable_syms) {|rhs2|
yield [first] + rhs2
}
end
end
end
def self.make_rules_no_empseq(syntax)
emptyable_syms = {}
changed = true
while changed
changed = false
syntax.each {|sym, rules|
next if emptyable_syms[sym]
rules.each {|rhs|
if rhs.all? {|e| emptyable_syms[e] }
emptyable_syms[sym] = true
changed = true
break
end
}
}
end
result = {}
syntax.each {|sym, rules|
rules2 = []
rules.each {|rhs|
expand_emptyable_syms(rhs, emptyable_syms) {|rhs2|
next if rhs2.empty?
rules2 << rhs2
}
}
result[sym] = rules2.uniq
}
result
end
def self.expand_channel_rules(syntax)
channel_rules = {}
syntax.each {|sym, rules|
channel_rules[sym] = {sym=>true}
rules.each {|rhs|
if rhs.length == 1 && Symbol === rhs[0]
channel_rules[sym][rhs[0]] = true
end
}
}
changed = true
while changed
changed = false
channel_rules.each {|sym, set|
n1 = set.size
set.keys.each {|s|
set.update(channel_rules[s])
}
n2 = set.size
changed = true if n1 < n2
}
end
result = {}
syntax.each {|sym, rules|
rules2 = []
channel_rules[sym].each_key {|s|
syntax[s].each {|rhs|
unless rhs.length == 1 && Symbol === rhs[0]
rules2 << rhs
end
}
}
result[sym] = rules2.uniq
}
result
end
def self.expand_noalt_rules(syntax)
noalt_syms = {}
syntax.each {|sym, rules|
if rules.length == 1
noalt_syms[sym] = true
end
}
result = {}
syntax.each {|sym, rules|
rules2 = []
rules.each {|rhs|
rhs2 = []
rhs.each {|e|
if noalt_syms[e]
rhs2.concat syntax[e][0]
else
rhs2 << e
end
}
rules2 << rhs2
}
result[sym] = rules2.uniq
}
result
end
def self.reorder_rules(syntax)
result = {}
syntax.each {|sym, rules|
result[sym] = rules.sort_by {|rhs|
[rhs.find_all {|e| Symbol === e }.length, rhs.length]
}
}
result
end
def each_tree(sym, limit)
generate_from_sym(sym, limit) {|_, tree|
yield tree
}
nil
end
def each_string(sym, limit)
generate_from_sym(sym, limit) {|_, tree|
yield [tree].join('')
}
nil
end
def generate_from_sym(sym, limit, &b)
return if limit < 0
if String === sym
yield limit, sym
else
rules = @syntax[sym]
raise "undefined rule: #{sym}" if !rules
rules.each {|rhs|
if rhs.length == 1 || rules.length == 1
limit1 = limit
else
limit1 = limit-1
end
generate_from_rhs(rhs, limit1, &b)
}
end
nil
end
def generate_from_rhs(rhs, limit)
return if limit < 0
if rhs.empty?
yield limit, []
else
generate_from_sym(rhs[0], limit) {|limit1, child|
generate_from_rhs(rhs[1..-1], limit1) {|limit2, arr|
yield limit2, [child, *arr]
}
}
end
nil
end
end
# :startdoc:
end