# frozen_string_literal: true require "active_support/core_ext/enumerable" module ActiveRecord # = Active Record \Calculations module Calculations class ColumnAliasTracker # :nodoc: def initialize(connection) @connection = connection @aliases = Hash.new(0) end def alias_for(field) aliased_name = column_alias_for(field) if @aliases[aliased_name] == 0 @aliases[aliased_name] = 1 aliased_name else # Update the count count = @aliases[aliased_name] += 1 "#{truncate(aliased_name)}_#{count}" end end private # Converts the given field to the value that the database adapter returns as # a usable column name: # # column_alias_for("users.id") # => "users_id" # column_alias_for("sum(id)") # => "sum_id" # column_alias_for("count(distinct users.id)") # => "count_distinct_users_id" # column_alias_for("count(*)") # => "count_all" def column_alias_for(field) column_alias = +field column_alias.gsub!(/\*/, "all") column_alias.gsub!(/\W+/, " ") column_alias.strip! column_alias.gsub!(/ +/, "_") @connection.table_alias_for(column_alias) end def truncate(name) name.slice(0, @connection.table_alias_length - 2) end end # Count the records. # # Person.count # # => the total count of all people # # Person.count(:age) # # => returns the total count of all people whose age is present in database # # Person.count(:all) # # => performs a COUNT(*) (:all is an alias for '*') # # Person.distinct.count(:age) # # => counts the number of different age values # # If #count is used with {Relation#group}[rdoc-ref:QueryMethods#group], # it returns a Hash whose keys represent the aggregated column, # and the values are the respective amounts: # # Person.group(:city).count # # => { 'Rome' => 5, 'Paris' => 3 } # # If #count is used with {Relation#group}[rdoc-ref:QueryMethods#group] for multiple columns, it returns a Hash whose # keys are an array containing the individual values of each column and the value # of each key would be the #count. # # Article.group(:status, :category).count # # => {["draft", "business"]=>10, ["draft", "technology"]=>4, ["published", "technology"]=>2} # # If #count is used with {Relation#select}[rdoc-ref:QueryMethods#select], it will count the selected columns: # # Person.select(:age).count # # => counts the number of different age values # # Note: not all valid {Relation#select}[rdoc-ref:QueryMethods#select] expressions are valid #count expressions. The specifics differ # between databases. In invalid cases, an error from the database is thrown. # # When given a block, loads all records in the relation, if the relation # hasn't been loaded yet. Calls the block with each record in the relation. # Returns the number of records for which the block returns a truthy value. # # Person.count { |person| person.age > 21 } # # => counts the number of people older that 21 # # Note: If there are a lot of records in the relation, loading all records # could result in performance issues. def count(column_name = nil) if block_given? unless column_name.nil? raise ArgumentError, "Column name argument is not supported when a block is passed." end super() else calculate(:count, column_name) end end # Same as #count, but performs the query asynchronously and returns an # ActiveRecord::Promise. def async_count(column_name = nil) async.count(column_name) end # Calculates the average value on a given column. Returns +nil+ if there's # no row. See #calculate for examples with options. # # Person.average(:age) # => 35.8 def average(column_name) calculate(:average, column_name) end # Same as #average, but performs the query asynchronously and returns an # ActiveRecord::Promise. def async_average(column_name) async.average(column_name) end # Calculates the minimum value on a given column. The value is returned # with the same data type of the column, or +nil+ if there's no row. See # #calculate for examples with options. # # Person.minimum(:age) # => 7 def minimum(column_name) calculate(:minimum, column_name) end # Same as #minimum, but performs the query asynchronously and returns an # ActiveRecord::Promise. def async_minimum(column_name) async.minimum(column_name) end # Calculates the maximum value on a given column. The value is returned # with the same data type of the column, or +nil+ if there's no row. See # #calculate for examples with options. # # Person.maximum(:age) # => 93 def maximum(column_name) calculate(:maximum, column_name) end # Same as #maximum, but performs the query asynchronously and returns an # ActiveRecord::Promise. def async_maximum(column_name) async.maximum(column_name) end # Calculates the sum of values on a given column. The value is returned # with the same data type of the column, +0+ if there's no row. See # #calculate for examples with options. # # Person.sum(:age) # => 4562 # # When given a block, loads all records in the relation, if the relation # hasn't been loaded yet. Calls the block with each record in the relation. # Returns the sum of +initial_value_or_column+ and the block return # values: # # Person.sum { |person| person.age } # => 4562 # Person.sum(1000) { |person| person.age } # => 5562 # # Note: If there are a lot of records in the relation, loading all records # could result in performance issues. def sum(initial_value_or_column = 0, &block) if block_given? map(&block).sum(initial_value_or_column) else calculate(:sum, initial_value_or_column) end end # Same as #sum, but performs the query asynchronously and returns an # ActiveRecord::Promise. def async_sum(identity_or_column = nil) async.sum(identity_or_column) end # This calculates aggregate values in the given column. Methods for #count, #sum, #average, # #minimum, and #maximum have been added as shortcuts. # # Person.calculate(:count, :all) # The same as Person.count # Person.average(:age) # SELECT AVG(age) FROM people... # # # Selects the minimum age for any family without any minors # Person.group(:last_name).having("min(age) > 17").minimum(:age) # # Person.sum("2 * age") # # There are two basic forms of output: # # * Single aggregate value: The single value is type cast to Integer for COUNT, Float # for AVG, and the given column's type for everything else. # # * Grouped values: This returns an ordered hash of the values and groups them. It # takes either a column name, or the name of a belongs_to association. # # values = Person.group('last_name').maximum(:age) # puts values["Drake"] # # => 43 # # drake = Family.find_by(last_name: 'Drake') # values = Person.group(:family).maximum(:age) # Person belongs_to :family # puts values[drake] # # => 43 # # values.each do |family, max_age| # ... # end def calculate(operation, column_name) operation = operation.to_s.downcase if @none case operation when "count", "sum" result = group_values.any? ? Hash.new : 0 return @async ? Promise::Complete.new(result) : result when "average", "minimum", "maximum" result = group_values.any? ? Hash.new : nil return @async ? Promise::Complete.new(result) : result end end if has_include?(column_name) relation = apply_join_dependency if operation == "count" unless distinct_value || distinct_select?(column_name || select_for_count) relation.distinct! relation.select_values = Array(klass.primary_key || table[Arel.star]) end # PostgreSQL: ORDER BY expressions must appear in SELECT list when using DISTINCT relation.order_values = [] if group_values.empty? end relation.calculate(operation, column_name) else perform_calculation(operation, column_name) end end # Use #pluck as a shortcut to select one or more attributes without # loading an entire record object per row. # # Person.pluck(:name) # # instead of # # Person.all.map(&:name) # # Pluck returns an Array of attribute values type-casted to match # the plucked column names, if they can be deduced. Plucking an SQL fragment # returns String values by default. # # Person.pluck(:name) # # SELECT people.name FROM people # # => ['David', 'Jeremy', 'Jose'] # # Person.pluck(:id, :name) # # SELECT people.id, people.name FROM people # # => [[1, 'David'], [2, 'Jeremy'], [3, 'Jose']] # # Person.distinct.pluck(:role) # # SELECT DISTINCT role FROM people # # => ['admin', 'member', 'guest'] # # Person.where(age: 21).limit(5).pluck(:id) # # SELECT people.id FROM people WHERE people.age = 21 LIMIT 5 # # => [2, 3] # # Comment.joins(:person).pluck(:id, person: [:id]) # # SELECT comments.id, people.id FROM comments INNER JOIN people on comments.person_id = people.id # # => [[1, 2], [2, 2]] # # Person.pluck(Arel.sql('DATEDIFF(updated_at, created_at)')) # # SELECT DATEDIFF(updated_at, created_at) FROM people # # => ['0', '27761', '173'] # # See also #ids. def pluck(*column_names) if @none if @async return Promise::Complete.new([]) else return [] end end if loaded? && all_attributes?(column_names) result = records.pluck(*column_names) if @async return Promise::Complete.new(result) else return result end end if has_include?(column_names.first) relation = apply_join_dependency relation.pluck(*column_names) else klass.disallow_raw_sql!(flattened_args(column_names)) columns = arel_columns(column_names) relation = spawn relation.select_values = columns result = skip_query_cache_if_necessary do if where_clause.contradiction? ActiveRecord::Result.empty(async: @async) else klass.with_connection do |c| c.select_all(relation.arel, "#{klass.name} Pluck", async: @async) end end end result.then do |result| type_cast_pluck_values(result, columns) end end end # Same as #pluck, but performs the query asynchronously and returns an # ActiveRecord::Promise. def async_pluck(*column_names) async.pluck(*column_names) end # Pick the value(s) from the named column(s) in the current relation. # This is short-hand for relation.limit(1).pluck(*column_names).first, and is primarily useful # when you have a relation that's already narrowed down to a single row. # # Just like #pluck, #pick will only load the actual value, not the entire record object, so it's also # more efficient. The value is, again like with pluck, typecast by the column type. # # Person.where(id: 1).pick(:name) # # SELECT people.name FROM people WHERE id = 1 LIMIT 1 # # => 'David' # # Person.where(id: 1).pick(:name, :email_address) # # SELECT people.name, people.email_address FROM people WHERE id = 1 LIMIT 1 # # => [ 'David', 'david@loudthinking.com' ] def pick(*column_names) if loaded? && all_attributes?(column_names) result = records.pick(*column_names) return @async ? Promise::Complete.new(result) : result end limit(1).pluck(*column_names).then(&:first) end # Same as #pick, but performs the query asynchronously and returns an # ActiveRecord::Promise. def async_pick(*column_names) async.pick(*column_names) end # Returns the base model's ID's for the relation using the table's primary key # # Person.ids # SELECT people.id FROM people # Person.joins(:company).ids # SELECT people.id FROM people INNER JOIN companies ON companies.id = people.company_id def ids primary_key_array = Array(primary_key) if loaded? result = records.map do |record| if primary_key_array.one? record._read_attribute(primary_key_array.first) else primary_key_array.map { |column| record._read_attribute(column) } end end return @async ? Promise::Complete.new(result) : result end if has_include?(primary_key) relation = apply_join_dependency.group(*primary_key_array) return relation.ids end columns = arel_columns(primary_key_array) relation = spawn relation.select_values = columns result = if relation.where_clause.contradiction? ActiveRecord::Result.empty else skip_query_cache_if_necessary do klass.with_connection do |c| c.select_all(relation, "#{klass.name} Ids", async: @async) end end end result.then { |result| type_cast_pluck_values(result, columns) } end # Same as #ids, but performs the query asynchronously and returns an # ActiveRecord::Promise. def async_ids async.ids end private def all_attributes?(column_names) (column_names.map(&:to_s) - @klass.attribute_names - @klass.attribute_aliases.keys).empty? end def has_include?(column_name) eager_loading? || (includes_values.present? && column_name && column_name != :all) end def perform_calculation(operation, column_name) operation = operation.to_s.downcase # If #count is used with #distinct (i.e. `relation.distinct.count`) it is # considered distinct. distinct = distinct_value if operation == "count" column_name ||= select_for_count if column_name == :all if !distinct distinct = distinct_select?(select_for_count) if group_values.empty? elsif group_values.any? || select_values.empty? && order_values.empty? column_name = primary_key end elsif distinct_select?(column_name) distinct = nil end end if group_values.any? execute_grouped_calculation(operation, column_name, distinct) else execute_simple_calculation(operation, column_name, distinct) end end def distinct_select?(column_name) column_name.is_a?(::String) && /\bDISTINCT[\s(]/i.match?(column_name) end def aggregate_column(column_name) return column_name if Arel::Expressions === column_name arel_column(column_name.to_s) do |name| column_name == :all ? Arel.sql("*", retryable: true) : Arel.sql(name) end end def operation_over_aggregate_column(column, operation, distinct) operation == "count" ? column.count(distinct) : column.public_send(operation) end def execute_simple_calculation(operation, column_name, distinct) # :nodoc: if build_count_subquery?(operation, column_name, distinct) # Shortcut when limit is zero. return 0 if limit_value == 0 relation = self query_builder = build_count_subquery(spawn, column_name, distinct) else # PostgreSQL doesn't like ORDER BY when there are no GROUP BY relation = unscope(:order).distinct!(false) column = aggregate_column(column_name) select_value = operation_over_aggregate_column(column, operation, distinct) select_value.distinct = true if operation == "sum" && distinct relation.select_values = [select_value] query_builder = relation.arel end query_result = if relation.where_clause.contradiction? ActiveRecord::Result.empty else skip_query_cache_if_necessary do @klass.with_connection do |c| c.select_all(query_builder, "#{@klass.name} #{operation.capitalize}", async: @async) end end end query_result.then do |result| if operation != "count" type = column.try(:type_caster) || lookup_cast_type_from_join_dependencies(column_name.to_s) || Type.default_value type = type.subtype if Enum::EnumType === type end type_cast_calculated_value(result.cast_values.first, operation, type) end end def execute_grouped_calculation(operation, column_name, distinct) # :nodoc: group_fields = group_values group_fields = group_fields.uniq if group_fields.size > 1 if group_fields.size == 1 && group_fields.first.respond_to?(:to_sym) association = klass._reflect_on_association(group_fields.first) associated = association && association.belongs_to? # only count belongs_to associations group_fields = Array(association.foreign_key) if associated end group_fields = arel_columns(group_fields) @klass.with_connection do |connection| column_alias_tracker = ColumnAliasTracker.new(connection) group_aliases = group_fields.map { |field| field = connection.visitor.compile(field) if Arel.arel_node?(field) column_alias_tracker.alias_for(field.to_s.downcase) } group_columns = group_aliases.zip(group_fields) column = aggregate_column(column_name) column_alias = column_alias_tracker.alias_for("#{operation} #{column_name.to_s.downcase}") select_value = operation_over_aggregate_column(column, operation, distinct) select_value.as(adapter_class.quote_column_name(column_alias)) select_values = [select_value] select_values += self.select_values unless having_clause.empty? select_values.concat group_columns.map { |aliaz, field| aliaz = adapter_class.quote_column_name(aliaz) if field.respond_to?(:as) field.as(aliaz) else "#{field} AS #{aliaz}" end } relation = except(:group).distinct!(false) relation.group_values = group_fields relation.select_values = select_values result = skip_query_cache_if_necessary do connection.select_all(relation.arel, "#{@klass.name} #{operation.capitalize}", async: @async) end result.then do |calculated_data| if association key_ids = calculated_data.collect { |row| row[group_aliases.first] } key_records = association.klass.base_class.where(association.klass.base_class.primary_key => key_ids) key_records = key_records.index_by(&:id) end key_types = group_columns.each_with_object({}) do |(aliaz, col_name), types| types[aliaz] = col_name.try(:type_caster) || type_for(col_name) do calculated_data.column_types.fetch(aliaz, Type.default_value) end end hash_rows = calculated_data.cast_values(key_types).map! do |row| calculated_data.columns.each_with_object({}).with_index do |(col_name, hash), i| hash[col_name] = row[i] end end if operation != "count" type = column.try(:type_caster) || lookup_cast_type_from_join_dependencies(column_name.to_s) || Type.default_value type = type.subtype if Enum::EnumType === type end hash_rows.each_with_object({}) do |row, result| key = group_aliases.map { |aliaz| row[aliaz] } key = key.first if key.size == 1 key = key_records[key] if associated result[key] = type_cast_calculated_value(row[column_alias], operation, type) end end end end def type_for(field, &block) field_name = field.respond_to?(:name) ? field.name.to_s : field.to_s.split(".").last @klass.type_for_attribute(field_name, &block) end def lookup_cast_type_from_join_dependencies(name, join_dependencies = build_join_dependencies) each_join_dependencies(join_dependencies) do |join| type = join.base_klass.attribute_types.fetch(name, nil) return type if type end nil end def type_cast_pluck_values(result, columns) cast_types = if result.columns.size != columns.size klass.attribute_types else join_dependencies = nil columns.map.with_index do |column, i| column.try(:type_caster) || klass.attribute_types.fetch(name = result.columns[i]) do join_dependencies ||= build_join_dependencies lookup_cast_type_from_join_dependencies(name, join_dependencies) || result.column_types[name] || Type.default_value end end end result.cast_values(cast_types) end def type_cast_calculated_value(value, operation, type) case operation when "count" value.to_i when "sum" type.deserialize(value || 0) when "average" case type.type when :integer, :decimal value&.to_d else type.deserialize(value) end else # "minimum", "maximum" type.deserialize(value) end end def select_for_count if select_values.present? return select_values.first if select_values.one? select_values.map do |field| column = arel_column(field.to_s) do |attr_name| Arel.sql(attr_name) end if column.is_a?(Arel::Nodes::SqlLiteral) column else "#{adapter_class.quote_table_name(column.relation.name)}.#{adapter_class.quote_column_name(column.name)}" end end.join(", ") else :all end end def build_count_subquery?(operation, column_name, distinct) # SQLite and older MySQL does not support `COUNT DISTINCT` with `*` or # multiple columns, so we need to use subquery for this. operation == "count" && (((column_name == :all || select_values.many?) && distinct) || has_limit_or_offset?) end def build_count_subquery(relation, column_name, distinct) if column_name == :all column_alias = Arel.star relation.select_values = [ Arel.sql(FinderMethods::ONE_AS_ONE) ] unless distinct else column_alias = Arel.sql("count_column") relation.select_values = [ aggregate_column(column_name).as(column_alias) ] end subquery_alias = Arel.sql("subquery_for_count", retryable: true) select_value = operation_over_aggregate_column(column_alias, "count", false) relation.build_subquery(subquery_alias, select_value) end end end