Datasets:

Fraser
/

dream-coder

	# -- coding: utf-8 --

	from dreamcoder.type import *
	from dreamcoder.utilities import *

	from time import time
	import math


	class InferenceFailure(Exception):
	pass


	class ShiftFailure(Exception):
	pass

	class RunFailure(Exception):
	pass


	class Program(object):
	def __repr__(self): return str(self)

	def __ne__(self, o): return not (self == o)

	def __str__(self): return self.show(False)

	def canHaveType(self, t):
	try:
	context, actualType = self.inferType(Context.EMPTY, [], {})
	context, t = t.instantiate(context)
	context.unify(t, actualType)
	return True
	except UnificationFailure as e:
	return False

	def betaNormalForm(self):
	n = self
	while True:
	np = n.betaReduce()
	if np is None: return n
	n = np

	def infer(self):
	try:
	return self.inferType(Context.EMPTY, [], {})[1].canonical()
	except UnificationFailure as e:
	raise InferenceFailure(self, e)

	def uncurry(self):
	t = self.infer()
	a = len(t.functionArguments())
	e = self
	existingAbstractions = 0
	while e.isAbstraction:
	e = e.body
	existingAbstractions += 1
	newAbstractions = a - existingAbstractions
	assert newAbstractions >= 0

	# e is the body stripped of abstractions. we are going to pile
	# some more lambdas at the front, so free variables in e
	# (which were bound to the stripped abstractions) need to be
	# shifted by the number of abstractions that we will be adding
	e = e.shift(newAbstractions)

	for n in reversed(range(newAbstractions)):
	e = Application(e, Index(n))
	for _ in range(a):
	e = Abstraction(e)

	assert self.infer() == e.infer(), \
	"FATAL: uncurry has a bug. %s : %s, but uncurried to %s : %s" % (self, self.infer(),
	e, e.infer())
	return e

	def wellTyped(self):
	try:
	self.infer()
	return True
	except InferenceFailure:
	return False

	def runWithArguments(self, xs):
	f = self.evaluate([])
	for x in xs:
	f = f(x)
	return f

	def applicationParses(self): yield self, []

	def applicationParse(self): return self, []

	@property
	def closed(self):
	for surroundingAbstractions, child in self.walk():
	if isinstance(child, FragmentVariable):
	return False
	if isinstance(child, Index) and child.free(
	surroundingAbstractions):
	return False
	return True

	@property
	def numberOfFreeVariables(expression):
	n = 0
	for surroundingAbstractions, child in expression.walk():
	# Free variable
	if isinstance(child, Index) and child.free(
	surroundingAbstractions):
	n = max(n, child.i - surroundingAbstractions + 1)
	return n

	def freeVariables(self):
	for surroundingAbstractions, child in self.walk():
	if child.isIndex and child.i >= surroundingAbstractions:
	yield child.i - surroundingAbstractions

	@property
	def isIndex(self): return False

	@property
	def isUnion(self): return False

	@property
	def isApplication(self): return False

	@property
	def isAbstraction(self): return False

	@property
	def isPrimitive(self): return False

	@property
	def isInvented(self): return False

	@property
	def isHole(self): return False

	@staticmethod
	def parse(s):
	s = parseSExpression(s)
	def p(e):
	if isinstance(e,list):
	if e[0] == '#':
	assert len(e) == 2
	return Invented(p(e[1]))
	if e[0] == 'lambda':
	assert len(e) == 2
	return Abstraction(p(e[1]))
	f = p(e[0])
	for x in e[1:]:
	f = Application(f,p(x))
	return f
	assert isinstance(e,str)
	if e[0] == '$': return Index(int(e[1:]))
	if e in Primitive.GLOBALS: return Primitive.GLOBALS[e]
	if e == '??' or e == '?': return FragmentVariable.single
	if e == '<HOLE>': return Hole.single
	raise ParseFailure((s,e))
	return p(s)

	@staticmethod
	def _parse(s,n):
	while n < len(s) and s[n].isspace():
	n += 1
	for p in [
	Application,
	Abstraction,
	Index,
	Invented,
	FragmentVariable,
	Hole,
	Primitive]:
	try:
	return p._parse(s,n)
	except ParseFailure:
	continue
	raise ParseFailure(s)

	# parser helpers
	@staticmethod
	def parseConstant(s,n,*constants):
	for constant in constants:
	try:
	for i,c in enumerate(constant):
	if i + n >= len(s) or s[i + n] != c: raise ParseFailure(s)
	return n + len(constant)
	except ParseFailure: continue
	raise ParseFailure(s)

	@staticmethod
	def parseHumanReadable(s):
	s = parseSExpression(s)
	def p(s, environment):
	if isinstance(s, list) and s[0] in ['lambda','\\']:
	assert isinstance(s[1], list) and len(s) == 3
	newEnvironment = list(reversed(s[1])) + environment
	e = p(s[2], newEnvironment)
	for _ in s[1]: e = Abstraction(e)
	return e
	if isinstance(s, list):
	a = p(s[0], environment)
	for x in s[1:]:
	a = Application(a, p(x, environment))
	return a
	for j,v in enumerate(environment):
	if s == v: return Index(j)
	if s in Primitive.GLOBALS: return Primitive.GLOBALS[s]
	assert False, f"could not parse {s}"
	return p(s, [])




	class Application(Program):
	'''Function application'''

	def __init__(self, f, x):
	self.f = f
	self.x = x
	self.hashCode = None
	self.isConditional = (not isinstance(f,int)) and \
	f.isApplication and \
	f.f.isApplication and \
	f.f.f.isPrimitive and \
	f.f.f.name == "if"
	if self.isConditional:
	self.falseBranch = x
	self.trueBranch = f.x
	self.branch = f.f.x
	else:
	self.falseBranch = None
	self.trueBranch = None
	self.branch = None

	def betaReduce(self):
	# See if either the function or the argument can be reduced
	f = self.f.betaReduce()
	if f is not None: return Application(f,self.x)
	x = self.x.betaReduce()
	if x is not None: return Application(self.f,x)

	# Neither of them could be reduced. Is this not a redex?
	if not self.f.isAbstraction: return None

	# Perform substitution
	b = self.f.body
	v = self.x
	return b.substitute(Index(0), v.shift(1)).shift(-1)

	def isBetaLong(self):
	return (not self.f.isAbstraction) and self.f.isBetaLong() and self.x.isBetaLong()

	def freeVariables(self):
	return self.f.freeVariables() \| self.x.freeVariables()

	def clone(self): return Application(self.f.clone(), self.x.clone())

	def annotateTypes(self, context, environment):
	self.f.annotateTypes(context, environment)
	self.x.annotateTypes(context, environment)
	r = context.makeVariable()
	context.unify(arrow(self.x.annotatedType, r), self.f.annotatedType)
	self.annotatedType = r.applyMutable(context)


	@property
	def isApplication(self): return True

	def __eq__(
	self,
	other): return isinstance(
	other,
	Application) and self.f == other.f and self.x == other.x

	def __hash__(self):
	if self.hashCode is None:
	self.hashCode = hash((hash(self.f), hash(self.x)))
	return self.hashCode

	"""Because Python3 randomizes the hash function, we need to never pickle the hash"""
	def __getstate__(self):
	return self.f, self.x, self.isConditional, self.falseBranch, self.trueBranch, self.branch
	def __setstate__(self, state):
	try:
	self.f, self.x, self.isConditional, self.falseBranch, self.trueBranch, self.branch = state
	except ValueError:
	# backward compatibility
	assert 'x' in state
	assert 'f' in state
	f = state['f']
	x = state['x']
	self.f = f
	self.x = x
	self.isConditional = (not isinstance(f,int)) and \
	f.isApplication and \
	f.f.isApplication and \
	f.f.f.isPrimitive and \
	f.f.f.name == "if"
	if self.isConditional:
	self.falseBranch = x
	self.trueBranch = f.x
	self.branch = f.f.x
	else:
	self.falseBranch = None
	self.trueBranch = None
	self.branch = None

	self.hashCode = None

	def visit(self,
	visitor,
	*arguments,
	**keywords): return visitor.application(self,
	*arguments,
	**keywords)

	def show(self, isFunction):
	if isFunction:
	return "%s %s" % (self.f.show(True), self.x.show(False))
	else:
	return "(%s %s)" % (self.f.show(True), self.x.show(False))

	def evaluate(self, environment):
	if self.isConditional:
	if self.branch.evaluate(environment):
	return self.trueBranch.evaluate(environment)
	else:
	return self.falseBranch.evaluate(environment)
	else:
	return self.f.evaluate(environment)(self.x.evaluate(environment))

	def inferType(self, context, environment, freeVariables):
	(context, ft) = self.f.inferType(context, environment, freeVariables)
	(context, xt) = self.x.inferType(context, environment, freeVariables)
	(context, returnType) = context.makeVariable()
	context = context.unify(ft, arrow(xt, returnType))
	return (context, returnType.apply(context))

	def applicationParses(self):
	yield self, []
	for f, xs in self.f.applicationParses():
	yield f, xs + [self.x]

	def applicationParse(self):
	f, xs = self.f.applicationParse()
	return f, xs + [self.x]

	def shift(self, offset, depth=0):
	return Application(self.f.shift(offset, depth),
	self.x.shift(offset, depth))

	def substitute(self, old, new):
	if self == old:
	return new
	return Application(
	self.f.substitute(
	old, new), self.x.substitute(
	old, new))

	def walkUncurried(self, d=0):
	yield d, self
	f, xs = self.applicationParse()
	yield from f.walkUncurried(d)
	for x in xs:
	yield from x.walkUncurried(d)

	def walk(self, surroundingAbstractions=0):
	yield surroundingAbstractions, self
	yield from self.f.walk(surroundingAbstractions)
	yield from self.x.walk(surroundingAbstractions)

	def size(self): return self.f.size() + self.x.size()

	@staticmethod
	def _parse(s,n):
	while n < len(s) and s[n].isspace(): n += 1
	if n == len(s) or s[n] != '(': raise ParseFailure(s)
	n += 1

	xs = []
	while True:
	x, n = Program._parse(s, n)
	xs.append(x)
	while n < len(s) and s[n].isspace(): n += 1
	if n == len(s):
	raise ParseFailure(s)
	if s[n] == ")":
	n += 1
	break
	e = xs[0]
	for x in xs[1:]:
	e = Application(e, x)
	return e, n


	class Index(Program):
	'''
	deBruijn index: https://en.wikipedia.org/wiki/De_Bruijn_index
	These indices encode variables.
	'''

	def __init__(self, i):
	self.i = i

	def show(self, isFunction): return "$%d" % self.i

	def __eq__(self, o): return isinstance(o, Index) and o.i == self.i

	def __hash__(self): return self.i

	def visit(self,
	visitor,
	*arguments,
	**keywords): return visitor.index(self,
	*arguments,
	**keywords)

	def evaluate(self, environment):
	return environment[self.i]

	def inferType(self, context, environment, freeVariables):
	if self.bound(len(environment)):
	return (context, environment[self.i].apply(context))
	else:
	i = self.i - len(environment)
	if i in freeVariables:
	return (context, freeVariables[i].apply(context))
	context, variable = context.makeVariable()
	freeVariables[i] = variable
	return (context, variable)

	def clone(self): return Index(self.i)

	def annotateTypes(self, context, environment):
	self.annotatedType = environment[self.i].applyMutable(context)

	def shift(self, offset, depth=0):
	# bound variable
	if self.bound(depth):
	return self
	else: # free variable
	i = self.i + offset
	if i < 0:
	raise ShiftFailure()
	return Index(i)

	def betaReduce(self): return None

	def isBetaLong(self): return True

	def freeVariables(self): return {self.i}

	def substitute(self, old, new):
	if old == self:
	return new
	else:
	return self

	def walk(self, surroundingAbstractions=0): yield surroundingAbstractions, self

	def walkUncurried(self, d=0): yield d, self

	def size(self): return 1

	def free(self, surroundingAbstractions):
	'''Is this index a free variable, given that it has surroundingAbstractions lambda's around it?'''
	return self.i >= surroundingAbstractions

	def bound(self, surroundingAbstractions):
	'''Is this index a bound variable, given that it has surroundingAbstractions lambda's around it?'''
	return self.i < surroundingAbstractions

	@property
	def isIndex(self): return True

	@staticmethod
	def _parse(s,n):
	while n < len(s) and s[n].isspace(): n += 1
	if n == len(s) or s[n] != '$':
	raise ParseFailure(s)
	n += 1
	j = ""
	while n < len(s) and s[n].isdigit():
	j += s[n]
	n += 1
	if j == "":
	raise ParseFailure(s)
	return Index(int(j)), n


	class Abstraction(Program):
	'''Lambda abstraction. Creates a new function.'''

	def __init__(self, body):
	self.body = body
	self.hashCode = None

	@property
	def isAbstraction(self): return True

	def __eq__(self, o): return isinstance(
	o, Abstraction) and o.body == self.body

	def __hash__(self):
	if self.hashCode is None:
	self.hashCode = hash((hash(self.body),))
	return self.hashCode

	"""Because Python3 randomizes the hash function, we need to never pickle the hash"""
	def __getstate__(self):
	return self.body
	def __setstate__(self, state):
	self.body = state
	self.hashCode = None

	def isBetaLong(self): return self.body.isBetaLong()

	def freeVariables(self):
	return {f - 1 for f in self.body.freeVariables() if f > 0}

	def visit(self,
	visitor,
	*arguments,
	**keywords): return visitor.abstraction(self,
	*arguments,
	**keywords)

	def clone(self): return Abstraction(self.body.clone())

	def annotateTypes(self, context, environment):
	v = context.makeVariable()
	self.body.annotateTypes(context, [v] + environment)
	self.annotatedType = arrow(v.applyMutable(context), self.body.annotatedType)

	def show(self, isFunction):
	return "(lambda %s)" % (self.body.show(False))

	def evaluate(self, environment):
	return lambda x: self.body.evaluate([x] + environment)

	def betaReduce(self):
	b = self.body.betaReduce()
	if b is None: return None
	return Abstraction(b)

	def inferType(self, context, environment, freeVariables):
	(context, argumentType) = context.makeVariable()
	(context, returnType) = self.body.inferType(
	context, [argumentType] + environment, freeVariables)
	return (context, arrow(argumentType, returnType).apply(context))

	def shift(self, offset, depth=0):
	return Abstraction(self.body.shift(offset, depth + 1))

	def substitute(self, old, new):
	if self == old:
	return new
	old = old.shift(1)
	new = new.shift(1)
	return Abstraction(self.body.substitute(old, new))

	def walk(self, surroundingAbstractions=0):
	yield surroundingAbstractions, self
	yield from self.body.walk(surroundingAbstractions + 1)

	def walkUncurried(self, d=0):
	yield d, self
	yield from self.body.walkUncurried(d + 1)

	def size(self): return self.body.size()

	@staticmethod
	def _parse(s,n):
	n = Program.parseConstant(s,n,
	'(\\','(lambda','(\u03bb')

	while n < len(s) and s[n].isspace(): n += 1

	b, n = Program._parse(s,n)
	while n < len(s) and s[n].isspace(): n += 1
	n = Program.parseConstant(s,n,')')
	return Abstraction(b), n


	class Primitive(Program):
	GLOBALS = {}

	def __init__(self, name, ty, value):
	self.tp = ty
	self.name = name
	self.value = value
	if name not in Primitive.GLOBALS:
	Primitive.GLOBALS[name] = self

	@property
	def isPrimitive(self): return True

	def __eq__(self, o): return isinstance(
	o, Primitive) and o.name == self.name

	def __hash__(self): return hash(self.name)

	def visit(self,
	visitor,
	*arguments,
	**keywords): return visitor.primitive(self,
	*arguments,
	**keywords)

	def show(self, isFunction): return self.name

	def clone(self): return Primitive(self.name, self.tp, self.value)

	def annotateTypes(self, context, environment):
	self.annotatedType = self.tp.instantiateMutable(context)

	def evaluate(self, environment): return self.value

	def betaReduce(self): return None

	def isBetaLong(self): return True

	def freeVariables(self): return set()

	def inferType(self, context, environment, freeVariables):
	return self.tp.instantiate(context)

	def shift(self, offset, depth=0): return self

	def substitute(self, old, new):
	if self == old:
	return new
	else:
	return self

	def walk(self, surroundingAbstractions=0): yield surroundingAbstractions, self

	def walkUncurried(self, d=0): yield d, self

	def size(self): return 1

	@staticmethod
	def _parse(s,n):
	while n < len(s) and s[n].isspace(): n += 1
	name = []
	while n < len(s) and not s[n].isspace() and s[n] not in '()':
	name.append(s[n])
	n += 1
	name = "".join(name)
	if name in Primitive.GLOBALS:
	return Primitive.GLOBALS[name], n
	raise ParseFailure(s)

	# TODO(@mtensor): needs to be fixed to handle both pickling lambda functions and unpickling in general.
	# def __getstate__(self):
	# return self.name

	# def __setstate__(self, state):
	# #for backwards compatibility:
	# if type(state) == dict:
	# self.__dict__ = state
	# else:
	# p = Primitive.GLOBALS[state]
	# self.__init__(p.name, p.tp, p.value)

	class Invented(Program):
	'''New invented primitives'''

	def __init__(self, body):
	self.body = body
	self.tp = self.body.infer()
	self.hashCode = None

	@property
	def isInvented(self): return True

	def show(self, isFunction): return "#%s" % (self.body.show(False))

	def visit(self,
	visitor,
	*arguments,
	**keywords): return visitor.invented(self,
	*arguments,
	**keywords)

	def __eq__(self, o): return isinstance(o, Invented) and o.body == self.body

	def __hash__(self):
	if self.hashCode is None:
	self.hashCode = hash((0, hash(self.body)))
	return self.hashCode

	"""Because Python3 randomizes the hash function, we need to never pickle the hash"""
	def __getstate__(self):
	return self.body, self.tp
	def __setstate__(self, state):
	self.body, self.tp = state
	self.hashCode = None

	def clone(self): return Invented(self.body)

	def annotateTypes(self, context, environment):
	self.annotatedType = self.tp.instantiateMutable(context)

	def evaluate(self, e): return self.body.evaluate([])

	def betaReduce(self): return self.body

	def isBetaLong(self): return True

	def freeVariables(self): return set()

	def inferType(self, context, environment, freeVariables):
	return self.tp.instantiate(context)

	def shift(self, offset, depth=0): return self

	def substitute(self, old, new):
	if self == old:
	return new
	else:
	return self

	def walk(self, surroundingAbstractions=0): yield surroundingAbstractions, self

	def walkUncurried(self, d=0): yield d, self

	def size(self): return 1

	@staticmethod
	def _parse(s,n):
	while n < len(s) and s[n].isspace(): n += 1
	if n < len(s) and s[n] == '#':
	n += 1
	b,n = Program._parse(s,n)
	return Invented(b),n

	raise ParseFailure(s)


	class FragmentVariable(Program):
	def __init__(self): pass

	def show(self, isFunction): return "??"

	def __eq__(self, o): return isinstance(o, FragmentVariable)

	def __hash__(self): return 42

	def visit(self, visitor, arguments, *keywords):
	return visitor.fragmentVariable(self, arguments, *keywords)

	def evaluate(self, e):
	raise Exception('Attempt to evaluate fragment variable')

	def betaReduce(self):
	raise Exception('Attempt to beta reduce fragment variable')

	def inferType(self, context, environment, freeVariables):
	return context.makeVariable()

	def shift(self, offset, depth=0):
	raise Exception('Attempt to shift fragment variable')

	def substitute(self, old, new):
	if self == old:
	return new
	else:
	return self

	def match(
	self,
	context,
	expression,
	holes,
	variableBindings,
	environment=[]):
	surroundingAbstractions = len(environment)
	try:
	context, variable = context.makeVariable()
	holes.append(
	(variable, expression.shift(-surroundingAbstractions)))
	return context, variable
	except ShiftFailure:
	raise MatchFailure()

	def walk(self, surroundingAbstractions=0): yield surroundingAbstractions, self

	def walkUncurried(self, d=0): yield d, self

	def size(self): return 1

	@staticmethod
	def _parse(s,n):
	while n < len(s) and s[n].isspace(): n += 1
	n = Program.parseConstant(s,n,'??','?')
	return FragmentVariable.single, n

	FragmentVariable.single = FragmentVariable()


	class Hole(Program):
	def __init__(self): pass

	def show(self, isFunction): return "<HOLE>"

	@property
	def isHole(self): return True

	def __eq__(self, o): return isinstance(o, Hole)

	def __hash__(self): return 42

	def evaluate(self, e):
	raise Exception('Attempt to evaluate hole')

	def betaReduce(self):
	raise Exception('Attempt to beta reduce hole')

	def inferType(self, context, environment, freeVariables):
	return context.makeVariable()

	def shift(self, offset, depth=0):
	raise Exception('Attempt to shift fragment variable')

	def walk(self, surroundingAbstractions=0): yield surroundingAbstractions, self

	def walkUncurried(self, d=0): yield d, self

	def size(self): return 1

	@staticmethod
	def _parse(s,n):
	while n < len(s) and s[n].isspace(): n += 1
	n = Program.parseConstant(s,n,
	'<HOLE>')
	return Hole.single, n


	Hole.single = Hole()


	class ShareVisitor(object):
	def __init__(self):
	self.primitiveTable = {}
	self.inventedTable = {}
	self.indexTable = {}
	self.applicationTable = {}
	self.abstractionTable = {}

	def invented(self, e):
	body = e.body.visit(self)
	i = id(body)
	if i in self.inventedTable:
	return self.inventedTable[i]
	new = Invented(body)
	self.inventedTable[i] = new
	return new

	def primitive(self, e):
	if e.name in self.primitiveTable:
	return self.primitiveTable[e.name]
	self.primitiveTable[e.name] = e
	return e

	def index(self, e):
	if e.i in self.indexTable:
	return self.indexTable[e.i]
	self.indexTable[e.i] = e
	return e

	def application(self, e):
	f = e.f.visit(self)
	x = e.x.visit(self)
	fi = id(f)
	xi = id(x)
	i = (fi, xi)
	if i in self.applicationTable:
	return self.applicationTable[i]
	new = Application(f, x)
	self.applicationTable[i] = new
	return new

	def abstraction(self, e):
	body = e.body.visit(self)
	i = id(body)
	if i in self.abstractionTable:
	return self.abstractionTable[i]
	new = Abstraction(body)
	self.abstractionTable[i] = new
	return new

	def execute(self, e):
	return e.visit(self)


	class Mutator:
	"""Perform local mutations to an expr, yielding the expr and the
	description length distance from the original program"""

	def __init__(self, grammar, fn):
	"""Fn yields (expression, loglikelihood) from a type and loss.
	Therefore, loss+loglikelihood is the distance from the original program."""
	self.fn = fn
	self.grammar = grammar
	self.history = []

	def enclose(self, expr):
	for h in self.history[::-1]:
	expr = h(expr)
	return expr

	def invented(self, e, tp, env, is_lhs=False):
	deleted_ll = self.logLikelihood(tp, e, env)
	for expr, replaced_ll in self.fn(tp, deleted, is_left_application=is_lhs):
	yield self.enclose(expr), deleted_ll + replaced_ll

	def primitive(self, e, tp, env, is_lhs=False):
	deleted_ll = self.logLikelihood(tp, e, env)
	for expr, replaced_ll in self.fn(tp, deleted_ll, is_left_application=is_lhs):
	yield self.enclose(expr), deleted_ll + replaced_ll

	def index(self, e, tp, env, is_lhs=False):
	#yield from ()
	deleted_ll = self.logLikelihood(tp, e, env) #self.grammar.logVariable
	for expr, replaced_ll in self.fn(tp, deleted_ll, is_left_application=is_lhs):
	yield self.enclose(expr), deleted_ll + replaced_ll

	def application(self, e, tp, env, is_lhs=False):
	self.history.append(lambda expr: Application(expr, e.x))
	f_tp = arrow(e.x.infer(), tp)
	yield from e.f.visit(self, f_tp, env, is_lhs=True)
	self.history[-1] = lambda expr: Application(e.f, expr)
	x_tp = inferArg(tp, e.f.infer())
	yield from e.x.visit(self, x_tp, env)
	self.history.pop()
	deleted_ll = self.logLikelihood(tp, e, env)
	for expr, replaced_ll in self.fn(tp, deleted_ll, is_left_application=is_lhs):
	yield self.enclose(expr), deleted_ll + replaced_ll

	def abstraction(self, e, tp, env, is_lhs=False):
	self.history.append(lambda expr: Abstraction(expr))
	yield from e.body.visit(self, tp.arguments[1], [tp.arguments[0]]+env)
	self.history.pop()
	deleted_ll = self.logLikelihood(tp, e, env)
	for expr, replaced_ll in self.fn(tp, deleted_ll, is_left_application=is_lhs):
	yield self.enclose(expr), deleted_ll + replaced_ll

	def execute(self, e, tp):
	yield from e.visit(self, tp, [])

	def logLikelihood(self, tp, e, env):
	summary = None
	try:
	_, summary = self.grammar.likelihoodSummary(Context.EMPTY, env,
	tp, e, silent=True)
	except AssertionError as err:
	#print(f"closedLikelihoodSummary failed on tp={tp}, e={e}, error={err}")
	pass
	if summary is not None:
	return summary.logLikelihood(self.grammar)
	else:
	tmpE, depth = e, 0
	while isinstance(tmpE, Abstraction):
	depth += 1
	tmpE = tmpE.body
	to_introduce = len(tp.functionArguments()) - depth
	if to_introduce == 0:
	#print(f"HIT NEGATIVEINFINITY, tp={tp}, e={e}")
	return NEGATIVEINFINITY
	for i in reversed(range(to_introduce)):
	e = Application(e, Index(i))
	for _ in range(to_introduce):
	e = Abstraction(e)
	return self.logLikelihood(tp, e, env)


	class RegisterPrimitives(object):
	def invented(self, e): e.body.visit(self)

	def primitive(self, e):
	if e.name not in Primitive.GLOBALS:
	Primitive(e.name, e.tp, e.value)

	def index(self, e): pass

	def application(self, e):
	e.f.visit(self)
	e.x.visit(self)

	def abstraction(self, e): e.body.visit(self)

	@staticmethod
	def register(e): e.visit(RegisterPrimitives())


	class PrettyVisitor(object):
	def __init__(self, Lisp=False):
	self.Lisp = Lisp
	self.numberOfVariables = 0
	self.freeVariables = {}

	self.variableNames = ["x", "y", "z", "u", "v", "w"]
	self.variableNames += [chr(ord('a') + j)
	for j in range(20)]
	self.toplevel = True

	def makeVariable(self):
	v = self.variableNames[self.numberOfVariables]
	self.numberOfVariables += 1
	return v

	def invented(self, e, environment, isFunction, isAbstraction):
	s = e.body.visit(self, [], isFunction, isAbstraction)
	return s

	def primitive(self, e, environment, isVariable, isAbstraction): return e.name

	def index(self, e, environment, isVariable, isAbstraction):
	if e.i < len(environment):
	return environment[e.i]
	else:
	i = e.i - len(environment)
	if i in self.freeVariables:
	return self.freeVariables[i]
	else:
	v = self.makeVariable()
	self.freeVariables[i] = v
	return v

	def application(self, e, environment, isFunction, isAbstraction):
	self.toplevel = False
	s = "%s %s" % (e.f.visit(self, environment, True, False),
	e.x.visit(self, environment, False, False))
	if isFunction:
	return s
	else:
	return "(" + s + ")"

	def abstraction(self, e, environment, isFunction, isAbstraction):
	toplevel = self.toplevel
	self.toplevel = False
	if not self.Lisp:
	# Invent a new variable
	v = self.makeVariable()
	body = e.body.visit(self,
	[v] + environment,
	False,
	True)
	if not e.body.isAbstraction:
	body = "." + body
	body = v + body
	if not isAbstraction:
	body = "λ" + body
	if not toplevel:
	body = "(%s)" % body
	return body
	else:
	child = e
	newVariables = []
	while child.isAbstraction:
	newVariables = [self.makeVariable()] + newVariables
	child = child.body
	body = child.visit(self, newVariables + environment,
	False, True)
	body = "(λ (%s) %s)"%(" ".join(reversed(newVariables)), body)
	return body



	def prettyProgram(e, Lisp=False):
	return e.visit(PrettyVisitor(Lisp=Lisp), [], False, False)

	class EtaExpandFailure(Exception): pass
	class EtaLongVisitor(object):
	"""Converts an expression into eta-longform"""
	def __init__(self, request=None):
	self.request = request
	self.context = None

	def makeLong(self, e, request):
	if request.isArrow():
	# eta expansion
	return Abstraction(Application(e.shift(1),
	Index(0)))
	return None


	def abstraction(self, e, request, environment):
	if not request.isArrow(): raise EtaExpandFailure()

	return Abstraction(e.body.visit(self,
	request.arguments[1],
	[request.arguments[0]] + environment))

	def _application(self, e, request, environment):
	l = self.makeLong(e, request)
	if l is not None: return l.visit(self, request, environment)

	f, xs = e.applicationParse()

	if f.isIndex:
	ft = environment[f.i].applyMutable(self.context)
	elif f.isInvented or f.isPrimitive:
	ft = f.tp.instantiateMutable(self.context)
	else: assert False, "Not in beta long form: %s"%e

	self.context.unify(request, ft.returns())
	ft = ft.applyMutable(self.context)

	xt = ft.functionArguments()
	if len(xs) != len(xt): raise EtaExpandFailure()

	returnValue = f
	for x,t in zip(xs,xt):
	t = t.applyMutable(self.context)
	returnValue = Application(returnValue,
	x.visit(self, t, environment))
	return returnValue

	# This procedure works by recapitulating the generative process
	# applications indices and primitives are all generated identically

	def application(self, e, request, environment): return self._application(e, request, environment)

	def index(self, e, request, environment): return self._application(e, request, environment)

	def primitive(self, e, request, environment): return self._application(e, request, environment)

	def invented(self, e, request, environment): return self._application(e, request, environment)

	def execute(self, e):
	assert len(e.freeVariables()) == 0

	if self.request is None:
	eprint("WARNING: request not specified for etaexpansion")
	self.request = e.infer()
	self.context = MutableContext()
	el = e.visit(self, self.request, [])
	self.context = None
	# assert el.infer().canonical() == e.infer().canonical(), \
	# f"Types are not preserved by ETA expansion: {e} : {e.infer().canonical()} vs {el} : {el.infer().canonical()}"
	return el



	class StripPrimitiveVisitor():
	"""Replaces all primitives .value's w/ None. Does not destructively modify anything"""
	def invented(self,e):
	return Invented(e.body.visit(self))
	def primitive(self,e):
	return Primitive(e.name,e.tp,None)
	def application(self,e):
	return Application(e.f.visit(self),
	e.x.visit(self))
	def abstraction(self,e):
	return Abstraction(e.body.visit(self))
	def index(self,e): return e

	class ReplacePrimitiveValueVisitor():
	"""Intended to be used after StripPrimitiveVisitor.
	Replaces all primitive.value's with their corresponding entry in Primitive.GLOBALS"""
	def invented(self,e):
	return Invented(e.body.visit(self))
	def primitive(self,e):
	return Primitive(e.name,e.tp,Primitive.GLOBALS[e.name].value)
	def application(self,e):
	return Application(e.f.visit(self),
	e.x.visit(self))
	def abstraction(self,e):
	return Abstraction(e.body.visit(self))
	def index(self,e): return e

	def strip_primitive_values(e):
	return e.visit(StripPrimitiveVisitor())
	def unstrip_primitive_values(e):
	return e.visit(ReplacePrimitiveValueVisitor())


	# from luke
	class TokeniseVisitor(object):
	def invented(self, e):
	return [e.body]

	def primitive(self, e): return [e.name]

	def index(self, e):
	return ["$" + str(e.i)]

	def application(self, e):
	return ["("] + e.f.visit(self) + e.x.visit(self) + [")"]

	def abstraction(self, e):
	return ["(_lambda"] + e.body.visit(self) + [")_lambda"]


	def tokeniseProgram(e):
	return e.visit(TokeniseVisitor())


	def untokeniseProgram(l):
	lookup = {
	"(_lambda": "(lambda",
	")_lambda": ")"
	}
	s = " ".join(lookup.get(x, x) for x in l)
	return Program.parse(s)

	if __name__ == "__main__":
	from dreamcoder.domains.arithmetic.arithmeticPrimitives import *
	e = Program.parse("(#(lambda (?? (+ 1 $0))) (lambda (?? (+ 1 $0))) (lambda (?? (+ 1 $0))) - * (+ +))")
	eprint(e)