require 'active_support/core_ext/array/wrap' module ActiveRecord module Associations # = Active Record Association Collection # # CollectionAssociation is an abstract class that provides common stuff to # ease the implementation of association proxies that represent # collections. See the class hierarchy in AssociationProxy. # # You need to be careful with assumptions regarding the target: The proxy # does not fetch records from the database until it needs them, but new # ones created with +build+ are added to the target. So, the target may be # non-empty and still lack children waiting to be read from the database. # If you look directly to the database you cannot assume that's the entire # collection because new records may have been added to the target, etc. # # If you need to work on all current children, new and existing records, # +load_target+ and the +loaded+ flag are your friends. class CollectionAssociation < Association #:nodoc: attr_reader :proxy def initialize(owner, reflection) super @proxy = CollectionProxy.new(self) end # Implements the reader method, e.g. foo.items for Foo.has_many :items def reader(force_reload = false) if force_reload klass.uncached { reload } elsif stale_target? reload end proxy end # Implements the writer method, e.g. foo.items= for Foo.has_many :items def writer(records) replace(records) end # Implements the ids reader method, e.g. foo.item_ids for Foo.has_many :items def ids_reader if loaded? || options[:finder_sql] load_target.map do |record| record.send(reflection.association_primary_key) end else column = "#{reflection.quoted_table_name}.#{reflection.association_primary_key}" scoped.select(column).except(:includes).map! do |record| record.send(reflection.association_primary_key) end end end # Implements the ids writer method, e.g. foo.item_ids= for Foo.has_many :items def ids_writer(ids) pk_column = reflection.primary_key_column ids = Array.wrap(ids).reject { |id| id.blank? } ids.map! { |i| pk_column.type_cast(i) } replace(klass.find(ids).index_by { |r| r.id }.values_at(*ids)) end def reset @loaded = false @target = [] end def select(select = nil) if block_given? load_target.select.each { |e| yield e } else scoped.select(select) end end def find(*args) if options[:finder_sql] find_by_scan(*args) else scoped.find(*args) end end def first(*args) first_or_last(:first, *args) end def last(*args) first_or_last(:last, *args) end def build(attributes = {}, options = {}, &block) if attributes.is_a?(Array) attributes.collect { |attr| build(attr, options, &block) } else add_to_target(build_record(attributes, options)) do |record| yield(record) if block_given? end end end def create(attributes = {}, options = {}, &block) create_record(attributes, options, &block) end def create!(attributes = {}, options = {}, &block) create_record(attributes, options, true, &block) end # Add +records+ to this association. Returns +self+ so method calls may be chained. # Since << flattens its argument list and inserts each record, +push+ and +concat+ behave identically. def concat(*records) result = true load_target if owner.new_record? transaction do records.flatten.each do |record| raise_on_type_mismatch(record) add_to_target(record) do |r| result &&= insert_record(record) unless owner.new_record? end end end result && records end # Starts a transaction in the association class's database connection. # # class Author < ActiveRecord::Base # has_many :books # end # # Author.first.books.transaction do # # same effect as calling Book.transaction # end def transaction(*args) reflection.klass.transaction(*args) do yield end end # Remove all records from this association # # See delete for more info. def delete_all delete(load_target).tap do reset loaded! end end # Destroy all the records from this association. # # See destroy for more info. def destroy_all destroy(load_target).tap do reset loaded! end end # Calculate sum using SQL, not Enumerable def sum(*args) if block_given? scoped.sum(*args) { |*block_args| yield(*block_args) } else scoped.sum(*args) end end # Count all records using SQL. If the +:counter_sql+ or +:finder_sql+ option is set for the # association, it will be used for the query. Otherwise, construct options and pass them with # scope to the target class's +count+. def count(column_name = nil, count_options = {}) column_name, count_options = nil, column_name if column_name.is_a?(Hash) if options[:counter_sql] || options[:finder_sql] unless count_options.blank? raise ArgumentError, "If finder_sql/counter_sql is used then options cannot be passed" end reflection.klass.count_by_sql(custom_counter_sql) else if options[:uniq] # This is needed because 'SELECT count(DISTINCT *)..' is not valid SQL. column_name ||= reflection.klass.primary_key count_options.merge!(:distinct => true) end value = scoped.count(column_name, count_options) limit = options[:limit] offset = options[:offset] if limit || offset [ [value - offset.to_i, 0].max, limit.to_i ].min else value end end end # Removes +records+ from this association calling +before_remove+ and # +after_remove+ callbacks. # # This method is abstract in the sense that +delete_records+ has to be # provided by descendants. Note this method does not imply the records # are actually removed from the database, that depends precisely on # +delete_records+. They are in any case removed from the collection. def delete(*records) delete_or_destroy(records, options[:dependent]) end # Destroy +records+ and remove them from this association calling # +before_remove+ and +after_remove+ callbacks. # # Note that this method will _always_ remove records from the database # ignoring the +:dependent+ option. def destroy(*records) records = find(records) if records.any? { |record| record.kind_of?(Fixnum) || record.kind_of?(String) } delete_or_destroy(records, :destroy) end # Returns the size of the collection by executing a SELECT COUNT(*) # query if the collection hasn't been loaded, and calling # collection.size if it has. # # If the collection has been already loaded +size+ and +length+ are # equivalent. If not and you are going to need the records anyway # +length+ will take one less query. Otherwise +size+ is more efficient. # # This method is abstract in the sense that it relies on # +count_records+, which is a method descendants have to provide. def size if owner.new_record? || (loaded? && !options[:uniq]) target.size elsif !loaded? && options[:group] load_target.size elsif !loaded? && !options[:uniq] && target.is_a?(Array) unsaved_records = target.select { |r| r.new_record? } unsaved_records.size + count_records else count_records end end # Returns the size of the collection calling +size+ on the target. # # If the collection has been already loaded +length+ and +size+ are # equivalent. If not and you are going to need the records anyway this # method will take one less query. Otherwise +size+ is more efficient. def length load_target.size end # Equivalent to collection.size.zero?. If the collection has # not been already loaded and you are going to fetch the records anyway # it is better to check collection.length.zero?. def empty? size.zero? end def any? if block_given? load_target.any? { |*block_args| yield(*block_args) } else !empty? end end # Returns true if the collection has more than 1 record. Equivalent to collection.size > 1. def many? if block_given? load_target.many? { |*block_args| yield(*block_args) } else size > 1 end end def uniq(collection = load_target) seen = {} collection.find_all do |record| seen[record.id] = true unless seen.key?(record.id) end end # Replace this collection with +other_array+ # This will perform a diff and delete/add only records that have changed. def replace(other_array) other_array.each { |val| raise_on_type_mismatch(val) } original_target = load_target.dup transaction do delete(target - other_array) unless concat(other_array - target) @target = original_target raise RecordNotSaved, "Failed to replace #{reflection.name} because one or more of the " \ "new records could not be saved." end end end def include?(record) if record.is_a?(reflection.klass) if record.new_record? include_in_memory?(record) else load_target if options[:finder_sql] loaded? ? target.include?(record) : scoped.exists?(record) end else false end end def load_target if find_target? @target = merge_target_lists(find_target, target) end loaded! target end def add_to_target(record) callback(:before_add, record) yield(record) if block_given? if options[:uniq] && index = @target.index(record) @target[index] = record else @target << record end callback(:after_add, record) set_inverse_instance(record) record end private def custom_counter_sql if options[:counter_sql] interpolate(options[:counter_sql]) else # replace the SELECT clause with COUNT(*), preserving any hints within /* ... */ interpolate(options[:finder_sql]).sub(/SELECT\b(\/\*.*?\*\/ )?(.*)\bFROM\b/im) { "SELECT #{$1}COUNT(*) FROM" } end end def custom_finder_sql interpolate(options[:finder_sql]) end def find_target records = if options[:finder_sql] reflection.klass.find_by_sql(custom_finder_sql) else scoped.all end records = options[:uniq] ? uniq(records) : records records.each { |record| set_inverse_instance(record) } records end # We have some records loaded from the database (persisted) and some that are # in-memory (memory). The same record may be represented in the persisted array # and in the memory array. # # So the task of this method is to merge them according to the following rules: # # * The final array must not have duplicates # * The order of the persisted array is to be preserved # * Any changes made to attributes on objects in the memory array are to be preserved # * Otherwise, attributes should have the value found in the database def merge_target_lists(persisted, memory) return persisted if memory.empty? return memory if persisted.empty? persisted.map! do |record| # Unfortunately we cannot simply do memory.delete(record) since on 1.8 this returns # record rather than memory.at(memory.index(record)). The behavior is fixed in 1.9. mem_index = memory.index(record) if mem_index mem_record = memory.delete_at(mem_index) (record.attribute_names - mem_record.changes.keys).each do |name| mem_record[name] = record[name] end mem_record else record end end persisted + memory end def create_record(attributes, options, raise = false, &block) unless owner.persisted? raise ActiveRecord::RecordNotSaved, "You cannot call create unless the parent is saved" end if attributes.is_a?(Array) attributes.collect { |attr| create_record(attr, options, raise, &block) } else transaction do add_to_target(build_record(attributes, options)) do |record| yield(record) if block_given? insert_record(record, true, raise) end end end end # Do the relevant stuff to insert the given record into the association collection. def insert_record(record, validate = true, raise = false) raise NotImplementedError end def create_scope scoped.scope_for_create.stringify_keys end def delete_or_destroy(records, method) records = records.flatten records.each { |record| raise_on_type_mismatch(record) } existing_records = records.reject { |r| r.new_record? } transaction do records.each { |record| callback(:before_remove, record) } delete_records(existing_records, method) if existing_records.any? records.each { |record| target.delete(record) } records.each { |record| callback(:after_remove, record) } end end # Delete the given records from the association, using one of the methods :destroy, # :delete_all or :nullify (or nil, in which case a default is used). def delete_records(records, method) raise NotImplementedError end def callback(method, record) callbacks_for(method).each do |callback| case callback when Symbol owner.send(callback, record) when Proc callback.call(owner, record) else callback.send(method, owner, record) end end end def callbacks_for(callback_name) full_callback_name = "#{callback_name}_for_#{reflection.name}" owner.class.send(full_callback_name.to_sym) || [] end # Should we deal with assoc.first or assoc.last by issuing an independent query to # the database, or by getting the target, and then taking the first/last item from that? # # If the args is just a non-empty options hash, go to the database. # # Otherwise, go to the database only if none of the following are true: # * target already loaded # * owner is new record # * custom :finder_sql exists # * target contains new or changed record(s) # * the first arg is an integer (which indicates the number of records to be returned) def fetch_first_or_last_using_find?(args) if args.first.is_a?(Hash) true else !(loaded? || owner.new_record? || options[:finder_sql] || target.any? { |record| record.new_record? || record.changed? } || args.first.kind_of?(Integer)) end end def include_in_memory?(record) if reflection.is_a?(ActiveRecord::Reflection::ThroughReflection) owner.send(reflection.through_reflection.name).any? { |source| target = source.send(reflection.source_reflection.name) target.respond_to?(:include?) ? target.include?(record) : target == record } || target.include?(record) else target.include?(record) end end # If using a custom finder_sql, #find scans the entire collection. def find_by_scan(*args) expects_array = args.first.kind_of?(Array) ids = args.flatten.compact.uniq.map { |arg| arg.to_i } if ids.size == 1 id = ids.first record = load_target.detect { |r| id == r.id } expects_array ? [ record ] : record else load_target.select { |r| ids.include?(r.id) } end end # Fetches the first/last using SQL if possible, otherwise from the target array. def first_or_last(type, *args) args.shift if args.first.is_a?(Hash) && args.first.empty? collection = fetch_first_or_last_using_find?(args) ? scoped : load_target collection.send(type, *args) end end end end