compiler/util/ir_util.py - third_party/github.com/google/emboss - Git at Google

 # Copyright 2019 Google LLC
 #
 # Licensed under the Apache License, Version 2.0 (the "License");
 # you may not use this file except in compliance with the License.
 # You may obtain a copy of the License at
 #
 #     https://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS,
 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 # See the License for the specific language governing permissions and
 # limitations under the License.

 """Utility functions for reading and manipulating Emboss IR."""

 import operator

 from compiler.util import ir_pb2


 _FIXED_SIZE_ATTRIBUTE = "fixed_size_in_bits"


 def get_attribute(attribute_list, name):
   """Finds name in attribute_list and returns a AttributeValue or None."""
   attribute_value = None
   for attr in attribute_list:
     if attr.name.text == name and not attr.is_default:
       assert attribute_value is None, 'Duplicate attribute "{}".'.format(name)
       attribute_value = attr.value
   return attribute_value


 def get_boolean_attribute(attribute_list, name, default_value=None):
   """Returns the boolean value of an attribute, if any, or default_value.

   Arguments:
       attribute_list: A list of attributes to search.
       name: The name of the desired attribute.
       default_value: A value to return if name is not found in attribute_list,
           or the attribute does not have a boolean value.

   Returns:
       The boolean value of the requested attribute, or default_value if the
       requested attribute is not found or has a non-boolean value.
   """
   attribute_value = get_attribute(attribute_list, name)
   if (not attribute_value or
       not attribute_value.expression.HasField("boolean_constant")):
     return default_value
   return attribute_value.expression.boolean_constant.value


 def get_integer_attribute(attribute_list, name, default_value=None):
   """Returns the integer value of an attribute, if any, or default_value.

   Arguments:
       attribute_list: A list of attributes to search.
       name: The name of the desired attribute.
       default_value: A value to return if name is not found in attribute_list,
           or the attribute does not have an integer value.

   Returns:
       The integer value of the requested attribute, or default_value if the
       requested attribute is not found or has a non-integer value.
   """
   attribute_value = get_attribute(attribute_list, name)
   if (not attribute_value or
       attribute_value.expression.type.WhichOneof("type") != "integer" or
       not is_constant(attribute_value.expression)):
     return default_value
   return constant_value(attribute_value.expression)


 def is_constant(expression, bindings=None):
   return constant_value(expression, bindings) is not None


 def is_constant_type(expression_type):
   """Returns True if expression_type is inhabited by a single value."""
   return (expression_type.integer.modulus == "infinity" or
           expression_type.boolean.HasField("value") or
           expression_type.enumeration.HasField("value"))


 def constant_value(expression, bindings=None):
   """Evaluates expression with the given bindings."""
   if expression.WhichOneof("expression") == "constant":
     return int(expression.constant.value)
   elif expression.WhichOneof("expression") == "constant_reference":
     # We can't look up the constant reference without the IR, but by the time
     # constant_value is called, the actual values should have been propagated to
     # the type information.
     if expression.type.WhichOneof("type") == "integer":
       assert expression.type.integer.modulus == "infinity"
       return int(expression.type.integer.modular_value)
     elif expression.type.WhichOneof("type") == "boolean":
       assert expression.type.boolean.HasField("value")
       return expression.type.boolean.value
     elif expression.type.WhichOneof("type") == "enumeration":
       assert expression.type.enumeration.HasField("value")
       return int(expression.type.enumeration.value)
     else:
       assert False, "Unexpected expression type {}".format(
           expression.type.WhichOneof("type"))
   elif expression.WhichOneof("expression") == "function":
     return _constant_value_of_function(expression.function, bindings)
   elif expression.WhichOneof("expression") == "field_reference":
     return None
   elif expression.WhichOneof("expression") == "boolean_constant":
     return expression.boolean_constant.value
   elif expression.WhichOneof("expression") == "builtin_reference":
     name = expression.builtin_reference.canonical_name.object_path[0]
     if bindings and name in bindings:
       return bindings[name]
     else:
       return None
   elif expression.WhichOneof("expression") is None:
     return None
   else:
     assert False, "Unexpected expression kind {}".format(
         expression.WhichOneof("expression"))


 def _constant_value_of_function(function, bindings):
   """Returns the constant value of evaluating `function`, or None."""
   values = [constant_value(arg, bindings) for arg in function.args]
   # Expressions like `$is_statically_sized && 1 <= $static_size_in_bits <= 64`
   # should return False, not None, if `$is_statically_sized` is false, even
   # though `$static_size_in_bits` is unknown.
   #
   # The easiest way to allow this is to use a three-way logic chart for each;
   # specifically:
   #
   # AND:      True     False    Unknown
   #         +--------------------------
   # True    | True     False    Unknown
   # False   | False    False    False
   # Unknown | Unknown  False    Unknown
   #
   # OR:       True     False    Unknown
   #         +--------------------------
   # True    | True     True     True
   # False   | True     False    Unknown
   # Unknown | True     Unknown  Unknown
   #
   # This raises the question of just how many constant-from-nonconstant
   # expressions Emboss should support.  There are, after all, a vast number of
   # constant expression patterns built from non-constant subexpressions, such as
   # `0 * X` or `X == X` or `3 * X == X + X + X`.  I (bolms@) am not implementing
   # any further special cases because I do not see any practical use for them.
   if function.function == ir_pb2.Function.AND:
     if any(value is False for value in values):
       return False
     elif any(value is None for value in values):
       return None
     else:
       return True
   elif function.function == ir_pb2.Function.OR:
     if any(value is True for value in values):
       return True
     elif any(value is None for value in values):
       return None
     else:
       return False
   elif function.function == ir_pb2.Function.CHOICE:
     if values[0] is None:
       return None
     else:
       return values[1] if values[0] else values[2]
   # Other than the logical operators and choice operator, the result of any
   # function on an unknown value is, itself, considered unknown.
   if any(value is None for value in values):
     return None
   functions = {
       ir_pb2.Function.ADDITION: operator.add,
       ir_pb2.Function.SUBTRACTION: operator.sub,
       ir_pb2.Function.MULTIPLICATION: operator.mul,
       ir_pb2.Function.EQUALITY: operator.eq,
       ir_pb2.Function.INEQUALITY: operator.ne,
       ir_pb2.Function.LESS: operator.lt,
       ir_pb2.Function.LESS_OR_EQUAL: operator.le,
       ir_pb2.Function.GREATER: operator.gt,
       ir_pb2.Function.GREATER_OR_EQUAL: operator.ge,
       # Python's max([1, 2]) == 2; max(1, 2) == 2; max([1]) == 1; but max(1)
       # throws a TypeError ("'int' object is not iterable").
       ir_pb2.Function.MAXIMUM: lambda *x: max(x),
   }
   return functions[function.function](*values)


 def _hashable_form_of_name(name):
   return (name.module_file,) + tuple(name.object_path)


 def hashable_form_of_reference(reference):
   """Returns a representation of reference that can be used as a dict key.

   Arguments:
     reference: An ir_pb2.Reference or ir_pb2.NameDefinition.

   Returns:
     A tuple of the module_file and object_path.
   """
   return _hashable_form_of_name(reference.canonical_name)


 def hashable_form_of_field_reference(field_reference):
   """Returns a representation of field_reference that can be used as a dict key.

   Arguments:
     field_reference: An ir_pb2.FieldReference

   Returns:
     A tuple of tuples of the module_files and object_paths.
   """
   return tuple(_hashable_form_of_name(reference.canonical_name)
                for reference in field_reference.path)


 def is_array(type_ir):
   """Returns true if type_ir is an array type."""
   return type_ir.HasField("array_type")


 def _find_path_in_structure_field(path, field):
   if not path:
     return field
   return None


 def _find_path_in_structure(path, type_definition):
   for field in type_definition.structure.field:
     if field.name.name.text == path[0]:
       return _find_path_in_structure_field(path[1:], field)
   return None


 def _find_path_in_enumeration(path, type_definition):
   if len(path) != 1:
     return None
   for value in type_definition.enumeration.value:
     if value.name.name.text == path[0]:
       return value
   return None


 def _find_path_in_parameters(path, type_definition):
   if len(path) > 1:
     return None
   for parameter in type_definition.runtime_parameter:
     if parameter.name.name.text == path[0]:
       return parameter
   return None


 def _find_path_in_type_definition(path, type_definition):
   """Finds the object with the given path in the given type_definition."""
   if not path:
     return type_definition
   obj = _find_path_in_parameters(path, type_definition)
   if obj:
     return obj
   if type_definition.HasField("structure"):
     obj = _find_path_in_structure(path, type_definition)
   elif type_definition.HasField("enumeration"):
     obj = _find_path_in_enumeration(path, type_definition)
   if obj:
     return obj
   else:
     return _find_path_in_type_list(path, type_definition.subtype)


 def _find_path_in_type_list(path, type_list):
   for type_definition in type_list:
     if type_definition.name.name.text == path[0]:
       return _find_path_in_type_definition(path[1:], type_definition)
   return None


 def _find_path_in_module(path, module_ir):
   if not path:
     return module_ir
   return _find_path_in_type_list(path, module_ir.type)


 def find_object_or_none(name, ir):
   """Finds the object with the given canonical name, if it exists.."""
   if (isinstance(name, ir_pb2.Reference) or
       isinstance(name, ir_pb2.NameDefinition)):
     path = _hashable_form_of_name(name.canonical_name)
   elif isinstance(name, ir_pb2.CanonicalName):
     path = _hashable_form_of_name(name)
   else:
     path = name

   for module in ir.module:
     if module.source_file_name == path[0]:
       return _find_path_in_module(path[1:], module)

   return None


 def find_object(name, ir):
   """Finds the IR of the type, field, or value with the given canonical name."""
   result = find_object_or_none(name, ir)
   assert result is not None, "Bad reference {}".format(name)
   return result


 def find_parent_object(name, ir):
   """Finds the parent object of the object with the given canonical name."""
   if (isinstance(name, ir_pb2.Reference) or
       isinstance(name, ir_pb2.NameDefinition)):
     path = _hashable_form_of_name(name.canonical_name)
   elif isinstance(name, ir_pb2.CanonicalName):
     path = _hashable_form_of_name(name)
   else:
     path = name
   return find_object(path[:-1], ir)


 def get_base_type(type_ir):
   """Returns the base type of the given type.

   Arguments:
     type_ir: IR of a type reference.

   Returns:
     If type_ir corresponds to an atomic type (like "UInt"), returns type_ir.  If
     type_ir corresponds to an array type (like "UInt:8[12]" or "Square[8][8]"),
     returns the type after stripping off the array types ("UInt" or "Square").
   """
   while type_ir.HasField("array_type"):
     type_ir = type_ir.array_type.base_type
   assert type_ir.HasField("atomic_type"), (
       "Unknown kind of type {}".format(type_ir))
   return type_ir


 def fixed_size_of_type_in_bits(type_ir, ir):
   """Returns the fixed, known size for the given type, in bits, or None.

   Arguments:
     type_ir: The IR of a type.
     ir: A complete IR, used to resolve references to types.

   Returns:
     size if the size of the type can be determined, otherwise None.
   """
   array_multiplier = 1
   while type_ir.HasField("array_type"):
     if type_ir.array_type.WhichOneof("size") == "automatic":
       return None
     else:
       assert type_ir.array_type.WhichOneof("size") == "element_count", (
           'Expected array size to be "automatic" or "element_count".')
     element_count = type_ir.array_type.element_count
     if not is_constant(element_count):
       return None
     else:
       array_multiplier *= constant_value(element_count)
     assert not type_ir.HasField("size_in_bits"), (
         "TODO(bolms): implement explicitly-sized arrays")
     type_ir = type_ir.array_type.base_type
   assert type_ir.HasField("atomic_type"), "Unexpected type!"
   if type_ir.HasField("size_in_bits"):
     size = constant_value(type_ir.size_in_bits)
   else:
     type_definition = find_object(type_ir.atomic_type.reference, ir)
     size_attr = get_attribute(type_definition.attribute, _FIXED_SIZE_ATTRIBUTE)
     if not size_attr:
       return None
     size = constant_value(size_attr.expression)
   return size * array_multiplier


 def field_is_virtual(field_ir):
   """Returns true if the field is virtual."""
   # TODO(bolms): Should there be a more explicit indicator that a field is
   # virtual?
   return not field_ir.HasField("location")


 def field_is_read_only(field_ir):
   """Returns true if the field is read-only."""
   # For now, all virtual fields are read-only, and no non-virtual fields are
   # read-only.
   return field_ir.write_method.read_only
	# Copyright 2019 Google LLC
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# https://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.

	"""Utility functions for reading and manipulating Emboss IR."""

	import operator

	from compiler.util import ir_pb2


	_FIXED_SIZE_ATTRIBUTE = "fixed_size_in_bits"


	def get_attribute(attribute_list, name):
	"""Finds name in attribute_list and returns a AttributeValue or None."""
	attribute_value = None
	for attr in attribute_list:
	if attr.name.text == name and not attr.is_default:
	assert attribute_value is None, 'Duplicate attribute "{}".'.format(name)
	attribute_value = attr.value
	return attribute_value


	def get_boolean_attribute(attribute_list, name, default_value=None):
	"""Returns the boolean value of an attribute, if any, or default_value.

	Arguments:
	attribute_list: A list of attributes to search.
	name: The name of the desired attribute.
	default_value: A value to return if name is not found in attribute_list,
	or the attribute does not have a boolean value.

	Returns:
	The boolean value of the requested attribute, or default_value if the
	requested attribute is not found or has a non-boolean value.
	"""
	attribute_value = get_attribute(attribute_list, name)
	if (not attribute_value or
	not attribute_value.expression.HasField("boolean_constant")):
	return default_value
	return attribute_value.expression.boolean_constant.value


	def get_integer_attribute(attribute_list, name, default_value=None):
	"""Returns the integer value of an attribute, if any, or default_value.

	Arguments:
	attribute_list: A list of attributes to search.
	name: The name of the desired attribute.
	default_value: A value to return if name is not found in attribute_list,
	or the attribute does not have an integer value.

	Returns:
	The integer value of the requested attribute, or default_value if the
	requested attribute is not found or has a non-integer value.
	"""
	attribute_value = get_attribute(attribute_list, name)
	if (not attribute_value or
	attribute_value.expression.type.WhichOneof("type") != "integer" or
	not is_constant(attribute_value.expression)):
	return default_value
	return constant_value(attribute_value.expression)


	def is_constant(expression, bindings=None):
	return constant_value(expression, bindings) is not None


	def is_constant_type(expression_type):
	"""Returns True if expression_type is inhabited by a single value."""
	return (expression_type.integer.modulus == "infinity" or
	expression_type.boolean.HasField("value") or
	expression_type.enumeration.HasField("value"))


	def constant_value(expression, bindings=None):
	"""Evaluates expression with the given bindings."""
	if expression.WhichOneof("expression") == "constant":
	return int(expression.constant.value)
	elif expression.WhichOneof("expression") == "constant_reference":
	# We can't look up the constant reference without the IR, but by the time
	# constant_value is called, the actual values should have been propagated to
	# the type information.
	if expression.type.WhichOneof("type") == "integer":
	assert expression.type.integer.modulus == "infinity"
	return int(expression.type.integer.modular_value)
	elif expression.type.WhichOneof("type") == "boolean":
	assert expression.type.boolean.HasField("value")
	return expression.type.boolean.value
	elif expression.type.WhichOneof("type") == "enumeration":
	assert expression.type.enumeration.HasField("value")
	return int(expression.type.enumeration.value)
	else:
	assert False, "Unexpected expression type {}".format(
	expression.type.WhichOneof("type"))
	elif expression.WhichOneof("expression") == "function":
	return _constant_value_of_function(expression.function, bindings)
	elif expression.WhichOneof("expression") == "field_reference":
	return None
	elif expression.WhichOneof("expression") == "boolean_constant":
	return expression.boolean_constant.value
	elif expression.WhichOneof("expression") == "builtin_reference":
	name = expression.builtin_reference.canonical_name.object_path[0]
	if bindings and name in bindings:
	return bindings[name]
	else:
	return None
	elif expression.WhichOneof("expression") is None:
	return None
	else:
	assert False, "Unexpected expression kind {}".format(
	expression.WhichOneof("expression"))


	def _constant_value_of_function(function, bindings):
	"""Returns the constant value of evaluating `function`, or None."""
	values = [constant_value(arg, bindings) for arg in function.args]
	# Expressions like `$is_statically_sized && 1 <= $static_size_in_bits <= 64`
	# should return False, not None, if `$is_statically_sized` is false, even
	# though `$static_size_in_bits` is unknown.
	#
	# The easiest way to allow this is to use a three-way logic chart for each;
	# specifically:
	#
	# AND: True False Unknown
	# +--------------------------
	# True \| True False Unknown
	# False \| False False False
	# Unknown \| Unknown False Unknown
	#
	# OR: True False Unknown
	# +--------------------------
	# True \| True True True
	# False \| True False Unknown
	# Unknown \| True Unknown Unknown
	#
	# This raises the question of just how many constant-from-nonconstant
	# expressions Emboss should support. There are, after all, a vast number of
	# constant expression patterns built from non-constant subexpressions, such as
	# `0 * X` or `X == X` or `3 * X == X + X + X`. I (bolms@) am not implementing
	# any further special cases because I do not see any practical use for them.
	if function.function == ir_pb2.Function.AND:
	if any(value is False for value in values):
	return False
	elif any(value is None for value in values):
	return None
	else:
	return True
	elif function.function == ir_pb2.Function.OR:
	if any(value is True for value in values):
	return True
	elif any(value is None for value in values):
	return None
	else:
	return False
	elif function.function == ir_pb2.Function.CHOICE:
	if values[0] is None:
	return None
	else:
	return values[1] if values[0] else values[2]
	# Other than the logical operators and choice operator, the result of any
	# function on an unknown value is, itself, considered unknown.
	if any(value is None for value in values):
	return None
	functions = {
	ir_pb2.Function.ADDITION: operator.add,
	ir_pb2.Function.SUBTRACTION: operator.sub,
	ir_pb2.Function.MULTIPLICATION: operator.mul,
	ir_pb2.Function.EQUALITY: operator.eq,
	ir_pb2.Function.INEQUALITY: operator.ne,
	ir_pb2.Function.LESS: operator.lt,
	ir_pb2.Function.LESS_OR_EQUAL: operator.le,
	ir_pb2.Function.GREATER: operator.gt,
	ir_pb2.Function.GREATER_OR_EQUAL: operator.ge,
	# Python's max([1, 2]) == 2; max(1, 2) == 2; max([1]) == 1; but max(1)
	# throws a TypeError ("'int' object is not iterable").
	ir_pb2.Function.MAXIMUM: lambda *x: max(x),
	}
	return functions[function.function](*values)


	def _hashable_form_of_name(name):
	return (name.module_file,) + tuple(name.object_path)


	def hashable_form_of_reference(reference):
	"""Returns a representation of reference that can be used as a dict key.

	Arguments:
	reference: An ir_pb2.Reference or ir_pb2.NameDefinition.

	Returns:
	A tuple of the module_file and object_path.
	"""
	return _hashable_form_of_name(reference.canonical_name)


	def hashable_form_of_field_reference(field_reference):
	"""Returns a representation of field_reference that can be used as a dict key.

	Arguments:
	field_reference: An ir_pb2.FieldReference

	Returns:
	A tuple of tuples of the module_files and object_paths.
	"""
	return tuple(_hashable_form_of_name(reference.canonical_name)
	for reference in field_reference.path)


	def is_array(type_ir):
	"""Returns true if type_ir is an array type."""
	return type_ir.HasField("array_type")


	def _find_path_in_structure_field(path, field):
	if not path:
	return field
	return None


	def _find_path_in_structure(path, type_definition):
	for field in type_definition.structure.field:
	if field.name.name.text == path[0]:
	return _find_path_in_structure_field(path[1:], field)
	return None


	def _find_path_in_enumeration(path, type_definition):
	if len(path) != 1:
	return None
	for value in type_definition.enumeration.value:
	if value.name.name.text == path[0]:
	return value
	return None


	def _find_path_in_parameters(path, type_definition):
	if len(path) > 1:
	return None
	for parameter in type_definition.runtime_parameter:
	if parameter.name.name.text == path[0]:
	return parameter
	return None


	def _find_path_in_type_definition(path, type_definition):
	"""Finds the object with the given path in the given type_definition."""
	if not path:
	return type_definition
	obj = _find_path_in_parameters(path, type_definition)
	if obj:
	return obj
	if type_definition.HasField("structure"):
	obj = _find_path_in_structure(path, type_definition)
	elif type_definition.HasField("enumeration"):
	obj = _find_path_in_enumeration(path, type_definition)
	if obj:
	return obj
	else:
	return _find_path_in_type_list(path, type_definition.subtype)


	def _find_path_in_type_list(path, type_list):
	for type_definition in type_list:
	if type_definition.name.name.text == path[0]:
	return _find_path_in_type_definition(path[1:], type_definition)
	return None


	def _find_path_in_module(path, module_ir):
	if not path:
	return module_ir
	return _find_path_in_type_list(path, module_ir.type)


	def find_object_or_none(name, ir):
	"""Finds the object with the given canonical name, if it exists.."""
	if (isinstance(name, ir_pb2.Reference) or
	isinstance(name, ir_pb2.NameDefinition)):
	path = _hashable_form_of_name(name.canonical_name)
	elif isinstance(name, ir_pb2.CanonicalName):
	path = _hashable_form_of_name(name)
	else:
	path = name

	for module in ir.module:
	if module.source_file_name == path[0]:
	return _find_path_in_module(path[1:], module)

	return None


	def find_object(name, ir):
	"""Finds the IR of the type, field, or value with the given canonical name."""
	result = find_object_or_none(name, ir)
	assert result is not None, "Bad reference {}".format(name)
	return result


	def find_parent_object(name, ir):
	"""Finds the parent object of the object with the given canonical name."""
	if (isinstance(name, ir_pb2.Reference) or
	isinstance(name, ir_pb2.NameDefinition)):
	path = _hashable_form_of_name(name.canonical_name)
	elif isinstance(name, ir_pb2.CanonicalName):
	path = _hashable_form_of_name(name)
	else:
	path = name
	return find_object(path[:-1], ir)


	def get_base_type(type_ir):
	"""Returns the base type of the given type.

	Arguments:
	type_ir: IR of a type reference.

	Returns:
	If type_ir corresponds to an atomic type (like "UInt"), returns type_ir. If
	type_ir corresponds to an array type (like "UInt:8[12]" or "Square[8][8]"),
	returns the type after stripping off the array types ("UInt" or "Square").
	"""
	while type_ir.HasField("array_type"):
	type_ir = type_ir.array_type.base_type
	assert type_ir.HasField("atomic_type"), (
	"Unknown kind of type {}".format(type_ir))
	return type_ir


	def fixed_size_of_type_in_bits(type_ir, ir):
	"""Returns the fixed, known size for the given type, in bits, or None.

	Arguments:
	type_ir: The IR of a type.
	ir: A complete IR, used to resolve references to types.

	Returns:
	size if the size of the type can be determined, otherwise None.
	"""
	array_multiplier = 1
	while type_ir.HasField("array_type"):
	if type_ir.array_type.WhichOneof("size") == "automatic":
	return None
	else:
	assert type_ir.array_type.WhichOneof("size") == "element_count", (
	'Expected array size to be "automatic" or "element_count".')
	element_count = type_ir.array_type.element_count
	if not is_constant(element_count):
	return None
	else:
	array_multiplier *= constant_value(element_count)
	assert not type_ir.HasField("size_in_bits"), (
	"TODO(bolms): implement explicitly-sized arrays")
	type_ir = type_ir.array_type.base_type
	assert type_ir.HasField("atomic_type"), "Unexpected type!"
	if type_ir.HasField("size_in_bits"):
	size = constant_value(type_ir.size_in_bits)
	else:
	type_definition = find_object(type_ir.atomic_type.reference, ir)
	size_attr = get_attribute(type_definition.attribute, _FIXED_SIZE_ATTRIBUTE)
	if not size_attr:
	return None
	size = constant_value(size_attr.expression)
	return size * array_multiplier


	def field_is_virtual(field_ir):
	"""Returns true if the field is virtual."""
	# TODO(bolms): Should there be a more explicit indicator that a field is
	# virtual?
	return not field_ir.HasField("location")


	def field_is_read_only(field_ir):
	"""Returns true if the field is read-only."""
	# For now, all virtual fields are read-only, and no non-virtual fields are
	# read-only.
	return field_ir.write_method.read_only