module Puppet::Pops module Evaluator # AccessOperator handles operator [] # This operator is part of evaluation. # class AccessOperator # Provides access to the Puppet 3.x runtime (scope, etc.) # This separation has been made to make it easier to later migrate the evaluator to an improved runtime. # include Runtime3Support attr_reader :semantic # Initialize with AccessExpression to enable reporting issues # @param access_expression [Model::AccessExpression] the semantic object being evaluated # @return [void] # def initialize(access_expression) @@access_visitor ||= Visitor.new(self, "access", 2, nil) @semantic = access_expression end def access (o, scope, *keys) @@access_visitor.visit_this_2(self, o, scope, keys) end protected def access_Object(o, scope, keys) type = Puppet::Pops::Types::TypeCalculator.infer(o) if type.is_a?(Puppet::Pops::Types::TypeWithMembers) access_func = type['[]'] return access_func.invoke(o, scope, keys) unless access_func.nil? end fail(Issues::OPERATOR_NOT_APPLICABLE, @semantic.left_expr, :operator=>'[]', :left_value => o) end def access_Binary(o, scope, keys) Puppet::Pops::Types::PBinaryType::Binary.from_binary_string(access_String(o.binary_buffer, scope, keys)) end def access_String(o, scope, keys) keys.flatten! result = case keys.size when 0 fail(Issues::BAD_STRING_SLICE_ARITY, @semantic.left_expr, {:actual => keys.size}) when 1 # Note that Ruby 1.8.7 requires a length of 1 to produce a String k1 = Utils.to_n(keys[0]) bad_string_access_key_type(o, 0, k1.nil? ? keys[0] : k1) unless k1.is_a?(Integer) k2 = 1 k1 = k1 < 0 ? o.length + k1 : k1 # abs pos # if k1 is outside, a length of 1 always produces an empty string if k1 < 0 EMPTY_STRING else o[ k1, k2 ] end when 2 k1 = Utils.to_n(keys[0]) k2 = Utils.to_n(keys[1]) [k1, k2].each_with_index { |k,i| bad_string_access_key_type(o, i, k.nil? ? keys[i] : k) unless k.is_a?(Integer) } k1 = k1 < 0 ? o.length + k1 : k1 # abs pos (negative is count from end) k2 = k2 < 0 ? o.length - k1 + k2 + 1 : k2 # abs length (negative k2 is length from pos to end count) # if k1 is outside, adjust to first position, and adjust length if k1 < 0 k2 = k2 + k1 k1 = 0 end o[ k1, k2 ] else fail(Issues::BAD_STRING_SLICE_ARITY, @semantic.left_expr, {:actual => keys.size}) end # Specified as: an index outside of range, or empty result == empty string (result.nil? || result.empty?) ? EMPTY_STRING : result end # Parameterizes a PRegexp Type with a pattern string or r ruby egexp # def access_PRegexpType(o, scope, keys) keys.flatten! unless keys.size == 1 blamed = keys.size == 0 ? @semantic : @semantic.keys[1] fail(Issues::BAD_TYPE_SLICE_ARITY, blamed, :base_type => o, :min=>1, :actual => keys.size) end assert_keys(keys, o, 1, 1, String, Regexp) Types::TypeFactory.regexp(*keys) end # Evaluates [] with 1 or 2 arguments. One argument is an index lookup, two arguments is a slice from/to. # def access_Array(o, scope, keys) keys.flatten! case keys.size when 0 fail(Issues::BAD_ARRAY_SLICE_ARITY, @semantic.left_expr, {:actual => keys.size}) when 1 key = coerce_numeric(keys[0], @semantic.keys[0], scope) unless key.is_a?(Integer) bad_access_key_type(o, 0, key, Integer) end o[key] when 2 # A slice [from, to] with support for -1 to mean start, or end respectively. k1 = coerce_numeric(keys[0], @semantic.keys[0], scope) k2 = coerce_numeric(keys[1], @semantic.keys[1], scope) [k1, k2].each_with_index { |k,i| bad_access_key_type(o, i, k, Integer) unless k.is_a?(Integer) } # Help confused Ruby do the right thing (it truncates to the right, but negative index + length can never overlap # the available range. k1 = k1 < 0 ? o.length + k1 : k1 # abs pos (negative is count from end) k2 = k2 < 0 ? o.length - k1 + k2 + 1 : k2 # abs length (negative k2 is length from pos to end count) # if k1 is outside, adjust to first position, and adjust length if k1 < 0 k2 = k2 + k1 k1 = 0 end # Help ruby always return empty array when asking for a sub array result = o[ k1, k2 ] result.nil? ? [] : result else fail(Issues::BAD_ARRAY_SLICE_ARITY, @semantic.left_expr, {:actual => keys.size}) end end # Evaluates [] with support for one or more arguments. If more than one argument is used, the result # is an array with each lookup. # @note # Does not flatten its keys to enable looking up with a structure # def access_Hash(o, scope, keys) # Look up key in hash, if key is nil, try alternate form (:undef) before giving up. # This is done because the hash may have been produced by 3x logic and may thus contain :undef. result = keys.collect do |k| o.fetch(k) { |key| key.nil? ? o[:undef] : nil } end case result.size when 0 fail(Issues::BAD_HASH_SLICE_ARITY, @semantic.left_expr, {:actual => keys.size}) when 1 result.pop else # remove nil elements and return result.compact! result end end def access_PBooleanType(o, scope, keys) keys.flatten! assert_keys(keys, o, 1, 1, TrueClass, FalseClass) Types::TypeFactory.boolean(keys[0]) end def access_PEnumType(o, scope, keys) keys.flatten! last = keys.last case_insensitive = false if last == true || last == false keys = keys[0...-1] case_insensitive = last end assert_keys(keys, o, 1, Float::INFINITY, String) Types::PEnumType.new(keys, case_insensitive) end def access_PVariantType(o, scope, keys) keys.flatten! assert_keys(keys, o, 1, Float::INFINITY, Types::PAnyType) Types::TypeFactory.variant(*keys) end def access_PSemVerType(o, scope, keys) keys.flatten! assert_keys(keys, o, 1, Float::INFINITY, String, SemanticPuppet::VersionRange) Types::TypeFactory.sem_ver(*keys) end def access_PTimestampType(o, scope, keys) keys.flatten! fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, :base_type => o, :min=>0, :max => 2, :actual => keys.size) if keys.size > 2 Types::TypeFactory.timestamp(*keys) end def access_PTimespanType(o, scope, keys) keys.flatten! fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, :base_type => o, :min=>0, :max => 2, :actual => keys.size) if keys.size > 2 Types::TypeFactory.timespan(*keys) end def access_PTupleType(o, scope, keys) keys.flatten! if Types::TypeFactory.is_range_parameter?(keys[-2]) && Types::TypeFactory.is_range_parameter?(keys[-1]) size_type = Types::TypeFactory.range(keys[-2], keys[-1]) keys = keys[0, keys.size - 2] elsif Types::TypeFactory.is_range_parameter?(keys[-1]) size_type = Types::TypeFactory.range(keys[-1], :default) keys = keys[0, keys.size - 1] end assert_keys(keys, o, 1, Float::INFINITY, Types::PAnyType) Types::TypeFactory.tuple(keys, size_type) end def access_PCallableType(o, scope, keys) if keys.size > 0 && keys[0].is_a?(Array) unless keys.size == 2 fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, :base_type => o, :min=>2, :max => 2, :actual => keys.size) end unless keys[1].is_a?(Types::PAnyType) bad_type_specialization_key_type(o, 1, k, Types::PAnyType) end end Types::TypeFactory.callable(*keys) end def access_PStructType(o, scope, keys) assert_keys(keys, o, 1, 1, Hash) Types::TypeFactory.struct(keys[0]) end def access_PStringType(o, scope, keys) keys.flatten! case keys.size when 1 size_t = collection_size_t(0, keys[0]) when 2 size_t = collection_size_t(0, keys[0], keys[1]) else fail(Issues::BAD_STRING_SLICE_ARITY, @semantic, {:actual => keys.size}) end Types::TypeFactory.string(size_t) end # Asserts type of each key and calls fail with BAD_TYPE_SPECIFICATION # @param keys [Array] the evaluated keys # @param o [Object] evaluated LHS reported as :base_type # @param min [Integer] the minimum number of keys (typically 1) # @param max [Numeric] the maximum number of keys (use same as min, specific number, or Float::INFINITY) # @param allowed_classes [Class] a variable number of classes that each key must be an instance of (any) # @api private # def assert_keys(keys, o, min, max, *allowed_classes) size = keys.size unless size.between?(min, max || Float::INFINITY) fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, :base_type => o, :min=>1, :max => max, :actual => keys.size) end keys.each_with_index do |k, i| unless allowed_classes.any? {|clazz| k.is_a?(clazz) } bad_type_specialization_key_type(o, i, k, *allowed_classes) end end end def bad_access_key_type(lhs, key_index, actual, *expected_classes) fail(Issues::BAD_SLICE_KEY_TYPE, @semantic.keys[key_index], { :left_value => lhs, :actual => bad_key_type_name(actual), :expected_classes => expected_classes }) end def bad_string_access_key_type(lhs, key_index, actual) fail(Issues::BAD_STRING_SLICE_KEY_TYPE, @semantic.keys[key_index], { :left_value => lhs, :actual_type => bad_key_type_name(actual), }) end def bad_key_type_name(actual) case actual when nil 'Undef' when :default 'Default' else Types::TypeCalculator.generalize(Types::TypeCalculator.infer(actual)).to_s end end def bad_type_specialization_key_type(type, key_index, actual, *expected_classes) label_provider = Model::ModelLabelProvider.new() expected = expected_classes.map {|c| label_provider.label(c) }.join(' or ') fail(Issues::BAD_TYPE_SPECIALIZATION, @semantic.keys[key_index], { :type => type, :message => _("Cannot use %{key} where %{expected} is expected") % { key: bad_key_type_name(actual), expected: expected } }) end def access_PPatternType(o, scope, keys) keys.flatten! assert_keys(keys, o, 1, Float::INFINITY, String, Regexp, Types::PPatternType, Types::PRegexpType) Types::TypeFactory.pattern(*keys) end def access_PURIType(o, scope, keys) keys.flatten! if keys.size == 1 param = keys[0] unless Types::PURIType::TYPE_URI_PARAM_TYPE.instance?(param) fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'URI-Type', :actual => param.class}) end Types::PURIType.new(param) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'URI-Type', :min => 1, :actual => keys.size}) end end def access_POptionalType(o, scope, keys) keys.flatten! if keys.size == 1 type = keys[0] unless type.is_a?(Types::PAnyType) if type.is_a?(String) type = Types::TypeFactory.string(type) else fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'Optional-Type', :actual => type.class}) end end Types::POptionalType.new(type) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'Optional-Type', :min => 1, :actual => keys.size}) end end def access_PSensitiveType(o, scope, keys) keys.flatten! if keys.size == 1 type = keys[0] unless type.is_a?(Types::PAnyType) fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'Sensitive-Type', :actual => type.class}) end Types::PSensitiveType.new(type) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'Sensitive-Type', :min => 1, :actual => keys.size}) end end def access_PObjectType(o, scope, keys) keys.flatten! if o.resolved? && !o.name.nil? Types::PObjectTypeExtension.create(o, keys) else if keys.size == 1 Types::TypeFactory.object(keys[0]) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'Object-Type', :min => 1, :actual => keys.size}) end end end def access_PTypeSetType(o, scope, keys) keys.flatten! if keys.size == 1 Types::TypeFactory.type_set(keys[0]) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'TypeSet-Type', :min => 1, :actual => keys.size}) end end def access_PNotUndefType(o, scope, keys) keys.flatten! case keys.size when 0 Types::TypeFactory.not_undef when 1 type = keys[0] case type when String type = Types::TypeFactory.string(type) when Types::PAnyType type = nil if type.class == Types::PAnyType else fail(Issues::BAD_NOT_UNDEF_SLICE_TYPE, @semantic.keys[0], {:base_type => 'NotUndef-Type', :actual => type.class}) end Types::TypeFactory.not_undef(type) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'NotUndef-Type', :min => 0, :max => 1, :actual => keys.size}) end end def access_PTypeType(o, scope, keys) keys.flatten! if keys.size == 1 unless keys[0].is_a?(Types::PAnyType) fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'Type-Type', :actual => keys[0].class}) end Types::PTypeType.new(keys[0]) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'Type-Type', :min => 1, :actual => keys.size}) end end def access_PInitType(o, scope, keys) unless keys[0].is_a?(Types::PAnyType) fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'Init-Type', :actual => keys[0].class}) end Types::TypeFactory.init(*keys) end def access_PIterableType(o, scope, keys) keys.flatten! if keys.size == 1 unless keys[0].is_a?(Types::PAnyType) fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'Iterable-Type', :actual => keys[0].class}) end Types::PIterableType.new(keys[0]) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'Iterable-Type', :min => 1, :actual => keys.size}) end end def access_PIteratorType(o, scope, keys) keys.flatten! if keys.size == 1 unless keys[0].is_a?(Types::PAnyType) fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'Iterator-Type', :actual => keys[0].class}) end Types::PIteratorType.new(keys[0]) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'Iterator-Type', :min => 1, :actual => keys.size}) end end def access_PRuntimeType(o, scope, keys) keys.flatten! assert_keys(keys, o, 2, 2, String, String) # create runtime type based on runtime and name of class, (not inference of key's type) Types::TypeFactory.runtime(*keys) end def access_PIntegerType(o, scope, keys) keys.flatten! unless keys.size.between?(1, 2) fail(Issues::BAD_INTEGER_SLICE_ARITY, @semantic, {:actual => keys.size}) end keys.each_with_index do |x, index| fail(Issues::BAD_INTEGER_SLICE_TYPE, @semantic.keys[index], {:actual => x.class}) unless (x.is_a?(Integer) || x == :default) end Types::PIntegerType.new(*keys) end def access_PFloatType(o, scope, keys) keys.flatten! unless keys.size.between?(1, 2) fail(Issues::BAD_FLOAT_SLICE_ARITY, @semantic, {:actual => keys.size}) end keys.each_with_index do |x, index| fail(Issues::BAD_FLOAT_SLICE_TYPE, @semantic.keys[index], {:actual => x.class}) unless (x.is_a?(Float) || x.is_a?(Integer) || x == :default) end from, to = keys from = from == :default || from.nil? ? nil : Float(from) to = to == :default || to.nil? ? nil : Float(to) Types::PFloatType.new(from, to) end # A Hash can create a new Hash type, one arg sets value type, two args sets key and value type in new type. # With 3 or 4 arguments, these are used to create a size constraint. # It is not possible to create a collection of Hash types directly. # def access_PHashType(o, scope, keys) keys.flatten! if keys.size == 2 && keys[0].is_a?(Integer) && keys[1].is_a?(Integer) return Types::PHashType.new(nil, nil, Types::PIntegerType.new(*keys)) end keys[0,2].each_with_index do |k, index| unless k.is_a?(Types::PAnyType) fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[index], {:base_type => 'Hash-Type', :actual => k.class}) end end case keys.size when 2 size_t = nil when 3 size_t = keys[2] size_t = Types::PIntegerType.new(size_t) unless size_t.is_a?(Types::PIntegerType) when 4 size_t = collection_size_t(2, keys[2], keys[3]) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, { :base_type => 'Hash-Type', :min => 2, :max => 4, :actual => keys.size }) end Types::PHashType.new(keys[0], keys[1], size_t) end # CollectionType is parameterized with a range def access_PCollectionType(o, scope, keys) keys.flatten! case keys.size when 1 size_t = collection_size_t(0, keys[0]) when 2 size_t = collection_size_t(0, keys[0], keys[1]) else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'Collection-Type', :min => 1, :max => 2, :actual => keys.size}) end Types::PCollectionType.new(size_t) end # An Array can create a new Array type. It is not possible to create a collection of Array types. # def access_PArrayType(o, scope, keys) keys.flatten! case keys.size when 1 unless keys[0].is_a?(Types::PAnyType) fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'Array-Type', :actual => keys[0].class}) end type = keys[0] size_t = nil when 2 if keys[0].is_a?(Types::PAnyType) size_t = collection_size_t(1, keys[1]) type = keys[0] else size_t = collection_size_t(0, keys[0], keys[1]) type = nil end when 3 if keys[0].is_a?(Types::PAnyType) size_t = collection_size_t(1, keys[1], keys[2]) type = keys[0] else fail(Issues::BAD_TYPE_SLICE_TYPE, @semantic.keys[0], {:base_type => 'Array-Type', :actual => keys[0].class}) end else fail(Issues::BAD_TYPE_SLICE_ARITY, @semantic, {:base_type => 'Array-Type', :min => 1, :max => 3, :actual => keys.size}) end Types::PArrayType.new(type, size_t) end # Produces an PIntegerType (range) given one or two keys. def collection_size_t(start_index, *keys) if keys.size == 1 && keys[0].is_a?(Types::PIntegerType) keys[0] else keys.each_with_index do |x, index| fail(Issues::BAD_COLLECTION_SLICE_TYPE, @semantic.keys[start_index + index], {:actual => x.class}) unless (x.is_a?(Integer) || x == :default) end Types::PIntegerType.new(*keys) end end # A Puppet::Resource represents either just a type (no title), or is a fully qualified type/title. # def access_Resource(o, scope, keys) # To access a Puppet::Resource as if it was a PResourceType, simply infer it, and take the type of # the parameterized meta type (i.e. Type[Resource[the_resource_type, the_resource_title]]) t = Types::TypeCalculator.infer(o).type # must map "undefined title" from resource to nil t.title = nil if t.title == EMPTY_STRING access(t, scope, *keys) end # If a type reference is encountered here, it's an error def access_PTypeReferenceType(o, scope, keys) fail(Issues::UNKNOWN_RESOURCE_TYPE, @semantic, {:type_name => o.type_string }) end # A Resource can create a new more specific Resource type, and/or an array of resource types # If the given type has title set, it can not be specified further. # @example # Resource[File] # => File # Resource[File, 'foo'] # => File[foo] # Resource[File. 'foo', 'bar'] # => [File[foo], File[bar]] # File['foo', 'bar'] # => [File[foo], File[bar]] # File['foo']['bar'] # => Value of the 'bar' parameter in the File['foo'] resource # Resource[File]['foo', 'bar'] # => [File[Foo], File[bar]] # Resource[File, 'foo', 'bar'] # => [File[foo], File[bar]] # Resource[File, 'foo']['bar'] # => Value of the 'bar' parameter in the File['foo'] resource # def access_PResourceType(o, scope, keys) blamed = keys.size == 0 ? @semantic : @semantic.keys[0] if keys.size == 0 fail(Issues::BAD_TYPE_SLICE_ARITY, blamed, :base_type => o.to_s, :min => 1, :max => -1, :actual => 0) end # Must know which concrete resource type to operate on in all cases. # It is not allowed to specify the type in an array arg - e.g. Resource[[File, 'foo']] # type_name is LHS type_name if set, else the first given arg type_name = o.type_name || Types::TypeFormatter.singleton.capitalize_segments(keys.shift) type_name = case type_name when Types::PResourceType type_name.type_name when String type_name else # blame given left expression if it defined the type, else the first given key expression blame = o.type_name.nil? ? @semantic.keys[0] : @semantic.left_expr fail(Issues::ILLEGAL_RESOURCE_SPECIALIZATION, blame, {:actual => bad_key_type_name(type_name)}) end # type name must conform if type_name !~ Patterns::CLASSREF_EXT fail(Issues::ILLEGAL_CLASSREF, blamed, {:name=>type_name}) end # The result is an array if multiple titles are given, or if titles are specified with an array # (possibly multiple arrays, and nested arrays). result_type_array = keys.size > 1 || keys[0].is_a?(Array) keys_orig_size = keys.size keys.flatten! keys.compact! # If given keys that were just a mix of empty/nil with empty array as a result. # As opposed to calling the function the wrong way (without any arguments), (configurable issue), # Return an empty array # if keys.empty? && keys_orig_size > 0 optionally_fail(Issues::EMPTY_RESOURCE_SPECIALIZATION, blamed) return result_type_array ? [] : nil end if !o.title.nil? # lookup resource and return one or more parameter values resource = find_resource(scope, o.type_name, o.title) unless resource fail(Issues::UNKNOWN_RESOURCE, @semantic, {:type_name => o.type_name, :title => o.title}) end result = keys.map do |k| unless is_parameter_of_resource?(scope, resource, k) fail(Issues::UNKNOWN_RESOURCE_PARAMETER, @semantic, {:type_name => o.type_name, :title => o.title, :param_name=>k}) end get_resource_parameter_value(scope, resource, k) end return result_type_array ? result : result.pop end keys = [:no_title] if keys.size < 1 # if there was only a type_name and it was consumed result = keys.each_with_index.map do |t, i| unless t.is_a?(String) || t == :no_title index = keys_orig_size != keys.size ? i+1 : i fail(Issues::BAD_TYPE_SPECIALIZATION, @semantic.keys[index], { :type => o, :message => "Cannot use #{bad_key_type_name(t)} where a resource title String is expected" }) end Types::PResourceType.new(type_name, t == :no_title ? nil : t) end # returns single type if request was for a single entity, else an array of types (possibly empty) return result_type_array ? result : result.pop end NS = '::'.freeze def access_PClassType(o, scope, keys) blamed = keys.size == 0 ? @semantic : @semantic.keys[0] keys_orig_size = keys.size if keys_orig_size == 0 fail(Issues::BAD_TYPE_SLICE_ARITY, blamed, :base_type => o.to_s, :min => 1, :max => -1, :actual => 0) end # The result is an array if multiple classnames are given, or if classnames are specified with an array # (possibly multiple arrays, and nested arrays). result_type_array = keys.size > 1 || keys[0].is_a?(Array) keys.flatten! keys.compact! # If given keys that were just a mix of empty/nil with empty array as a result. # As opposed to calling the function the wrong way (without any arguments), (configurable issue), # Return an empty array # if keys.empty? && keys_orig_size > 0 optionally_fail(Issues::EMPTY_RESOURCE_SPECIALIZATION, blamed) return result_type_array ? [] : nil end if o.class_name.nil? result = keys.each_with_index.map do |c, i| fail(Issues::ILLEGAL_HOSTCLASS_NAME, @semantic.keys[i], {:name => c}) unless c.is_a?(String) name = c.downcase # Remove leading '::' since all references are global, and 3x runtime does the wrong thing name = name[2..-1] if name[0,2] == NS fail(Issues::ILLEGAL_NAME, @semantic.keys[i], {:name=>c}) unless name =~ Patterns::NAME Types::PClassType.new(name) end else # lookup class resource and return one or more parameter values resource = find_resource(scope, 'class', o.class_name) if resource result = keys.map do |k| if is_parameter_of_resource?(scope, resource, k) get_resource_parameter_value(scope, resource, k) else fail(Issues::UNKNOWN_RESOURCE_PARAMETER, @semantic, {:type_name => 'Class', :title => o.class_name, :param_name=>k}) end end else fail(Issues::UNKNOWN_RESOURCE, @semantic, {:type_name => 'Class', :title => o.class_name}) end end # returns single type as type, else an array of types return result_type_array ? result : result.pop end end end end