# frozen_string_literal: true
module ActiveRecord
module ConnectionAdapters # :nodoc:
module DatabaseStatements
def initialize
super
reset_transaction
end
# Converts an arel AST to SQL
def to_sql(arel_or_sql_string, binds = [])
sql, _ = to_sql_and_binds(arel_or_sql_string, binds)
sql
end
def to_sql_and_binds(arel_or_sql_string, binds = [], preparable = nil) # :nodoc:
# Arel::TreeManager -> Arel::Node
if arel_or_sql_string.respond_to?(:ast)
arel_or_sql_string = arel_or_sql_string.ast
end
if Arel.arel_node?(arel_or_sql_string) && !(String === arel_or_sql_string)
unless binds.empty?
raise "Passing bind parameters with an arel AST is forbidden. " \
"The values must be stored on the AST directly"
end
collector = collector()
if prepared_statements
collector.preparable = true
sql, binds = visitor.compile(arel_or_sql_string, collector)
if binds.length > bind_params_length
unprepared_statement do
return to_sql_and_binds(arel_or_sql_string)
end
end
preparable = collector.preparable
else
sql = visitor.compile(arel_or_sql_string, collector)
end
[sql.freeze, binds, preparable]
else
arel_or_sql_string = arel_or_sql_string.dup.freeze unless arel_or_sql_string.frozen?
[arel_or_sql_string, binds, preparable]
end
end
private :to_sql_and_binds
# This is used in the StatementCache object. It returns an object that
# can be used to query the database repeatedly.
def cacheable_query(klass, arel) # :nodoc:
if prepared_statements
sql, binds = visitor.compile(arel.ast, collector)
query = klass.query(sql)
else
collector = klass.partial_query_collector
parts, binds = visitor.compile(arel.ast, collector)
query = klass.partial_query(parts)
end
[query, binds]
end
# Returns an ActiveRecord::Result instance.
def select_all(arel, name = nil, binds = [], preparable: nil, async: false)
arel = arel_from_relation(arel)
sql, binds, preparable = to_sql_and_binds(arel, binds, preparable)
select(sql, name, binds, prepare: prepared_statements && preparable, async: async && FutureResult::SelectAll)
rescue ::RangeError
ActiveRecord::Result.empty(async: async)
end
# Returns a record hash with the column names as keys and column values
# as values.
def select_one(arel, name = nil, binds = [], async: false)
select_all(arel, name, binds, async: async).then(&:first)
end
# Returns a single value from a record
def select_value(arel, name = nil, binds = [], async: false)
select_rows(arel, name, binds, async: async).then { |rows| single_value_from_rows(rows) }
end
# Returns an array of the values of the first column in a select:
# select_values("SELECT id FROM companies LIMIT 3") => [1,2,3]
def select_values(arel, name = nil, binds = [])
select_rows(arel, name, binds).map(&:first)
end
# Returns an array of arrays containing the field values.
# Order is the same as that returned by +columns+.
def select_rows(arel, name = nil, binds = [], async: false)
select_all(arel, name, binds, async: async).then(&:rows)
end
def query_value(sql, name = nil) # :nodoc:
single_value_from_rows(query(sql, name))
end
def query_values(sql, name = nil) # :nodoc:
query(sql, name).map(&:first)
end
def query(sql, name = nil) # :nodoc:
internal_exec_query(sql, name).rows
end
# Determines whether the SQL statement is a write query.
def write_query?(sql)
raise NotImplementedError
end
# Executes the SQL statement in the context of this connection and returns
# the raw result from the connection adapter.
#
# Setting +allow_retry+ to true causes the db to reconnect and retry
# executing the SQL statement in case of a connection-related exception.
# This option should only be enabled for known idempotent queries.
#
# Note: the query is assumed to have side effects and the query cache
# will be cleared. If the query is read-only, consider using #select_all
# instead.
#
# Note: depending on your database connector, the result returned by this
# method may be manually memory managed. Consider using #exec_query
# wrapper instead.
def execute(sql, name = nil, allow_retry: false)
internal_execute(sql, name, allow_retry: allow_retry)
end
# Executes +sql+ statement in the context of this connection using
# +binds+ as the bind substitutes. +name+ is logged along with
# the executed +sql+ statement.
#
# Note: the query is assumed to have side effects and the query cache
# will be cleared. If the query is read-only, consider using #select_all
# instead.
def exec_query(sql, name = "SQL", binds = [], prepare: false)
internal_exec_query(sql, name, binds, prepare: prepare)
end
# Executes insert +sql+ statement in the context of this connection using
# +binds+ as the bind substitutes. +name+ is logged along with
# the executed +sql+ statement.
# Some adapters support the `returning` keyword argument which allows to control the result of the query:
# `nil` is the default value and maintains default behavior. If an array of column names is passed -
# the result will contain values of the specified columns from the inserted row.
def exec_insert(sql, name = nil, binds = [], pk = nil, sequence_name = nil, returning: nil)
sql, binds = sql_for_insert(sql, pk, binds, returning)
internal_exec_query(sql, name, binds)
end
# Executes delete +sql+ statement in the context of this connection using
# +binds+ as the bind substitutes. +name+ is logged along with
# the executed +sql+ statement.
def exec_delete(sql, name = nil, binds = [])
internal_exec_query(sql, name, binds)
end
# Executes update +sql+ statement in the context of this connection using
# +binds+ as the bind substitutes. +name+ is logged along with
# the executed +sql+ statement.
def exec_update(sql, name = nil, binds = [])
internal_exec_query(sql, name, binds)
end
def exec_insert_all(sql, name) # :nodoc:
internal_exec_query(sql, name)
end
def explain(arel, binds = [], options = []) # :nodoc:
raise NotImplementedError
end
# Executes an INSERT query and returns the new record's ID
#
# +id_value+ will be returned unless the value is +nil+, in
# which case the database will attempt to calculate the last inserted
# id and return that value.
#
# If the next id was calculated in advance (as in Oracle), it should be
# passed in as +id_value+.
# Some adapters support the `returning` keyword argument which allows defining the return value of the method:
# `nil` is the default value and maintains default behavior. If an array of column names is passed -
# an array of is returned from the method representing values of the specified columns from the inserted row.
def insert(arel, name = nil, pk = nil, id_value = nil, sequence_name = nil, binds = [], returning: nil)
sql, binds = to_sql_and_binds(arel, binds)
value = exec_insert(sql, name, binds, pk, sequence_name, returning: returning)
return returning_column_values(value) unless returning.nil?
id_value || last_inserted_id(value)
end
alias create insert
# Executes the update statement and returns the number of rows affected.
def update(arel, name = nil, binds = [])
sql, binds = to_sql_and_binds(arel, binds)
exec_update(sql, name, binds)
end
# Executes the delete statement and returns the number of rows affected.
def delete(arel, name = nil, binds = [])
sql, binds = to_sql_and_binds(arel, binds)
exec_delete(sql, name, binds)
end
# Executes the truncate statement.
def truncate(table_name, name = nil)
execute(build_truncate_statement(table_name), name)
end
def truncate_tables(*table_names) # :nodoc:
table_names -= [schema_migration.table_name, internal_metadata.table_name]
return if table_names.empty?
with_multi_statements do
disable_referential_integrity do
statements = build_truncate_statements(table_names)
execute_batch(statements, "Truncate Tables")
end
end
end
# Runs the given block in a database transaction, and returns the result
# of the block.
#
# == Nested transactions support
#
# #transaction calls can be nested. By default, this makes all database
# statements in the nested transaction block become part of the parent
# transaction. For example, the following behavior may be surprising:
#
# ActiveRecord::Base.transaction do
# Post.create(title: 'first')
# ActiveRecord::Base.transaction do
# Post.create(title: 'second')
# raise ActiveRecord::Rollback
# end
# end
#
# This creates both "first" and "second" posts. Reason is the
# ActiveRecord::Rollback exception in the nested block does not issue a
# ROLLBACK. Since these exceptions are captured in transaction blocks,
# the parent block does not see it and the real transaction is committed.
#
# Most databases don't support true nested transactions. At the time of
# writing, the only database that supports true nested transactions that
# we're aware of, is MS-SQL.
#
# In order to get around this problem, #transaction will emulate the effect
# of nested transactions, by using savepoints:
# https://dev.mysql.com/doc/refman/en/savepoint.html.
#
# It is safe to call this method if a database transaction is already open,
# i.e. if #transaction is called within another #transaction block. In case
# of a nested call, #transaction will behave as follows:
#
# - The block will be run without doing anything. All database statements
# that happen within the block are effectively appended to the already
# open database transaction.
# - However, if +:requires_new+ is set, the block will be wrapped in a
# database savepoint acting as a sub-transaction.
#
# In order to get a ROLLBACK for the nested transaction you may ask for a
# real sub-transaction by passing requires_new: true.
# If anything goes wrong, the database rolls back to the beginning of
# the sub-transaction without rolling back the parent transaction.
# If we add it to the previous example:
#
# ActiveRecord::Base.transaction do
# Post.create(title: 'first')
# ActiveRecord::Base.transaction(requires_new: true) do
# Post.create(title: 'second')
# raise ActiveRecord::Rollback
# end
# end
#
# only post with title "first" is created.
#
# See ActiveRecord::Transactions to learn more.
#
# === Caveats
#
# MySQL doesn't support DDL transactions. If you perform a DDL operation,
# then any created savepoints will be automatically released. For example,
# if you've created a savepoint, then you execute a CREATE TABLE statement,
# then the savepoint that was created will be automatically released.
#
# This means that, on MySQL, you shouldn't execute DDL operations inside
# a #transaction call that you know might create a savepoint. Otherwise,
# #transaction will raise exceptions when it tries to release the
# already-automatically-released savepoints:
#
# Model.connection.transaction do # BEGIN
# Model.connection.transaction(requires_new: true) do # CREATE SAVEPOINT active_record_1
# Model.connection.create_table(...)
# # active_record_1 now automatically released
# end # RELEASE SAVEPOINT active_record_1 <--- BOOM! database error!
# end
#
# == Transaction isolation
#
# If your database supports setting the isolation level for a transaction, you can set
# it like so:
#
# Post.transaction(isolation: :serializable) do
# # ...
# end
#
# Valid isolation levels are:
#
# * :read_uncommitted
# * :read_committed
# * :repeatable_read
# * :serializable
#
# You should consult the documentation for your database to understand the
# semantics of these different levels:
#
# * https://www.postgresql.org/docs/current/static/transaction-iso.html
# * https://dev.mysql.com/doc/refman/en/set-transaction.html
#
# An ActiveRecord::TransactionIsolationError will be raised if:
#
# * The adapter does not support setting the isolation level
# * You are joining an existing open transaction
# * You are creating a nested (savepoint) transaction
#
# The mysql2, trilogy, and postgresql adapters support setting the transaction
# isolation level.
# :args: (requires_new: nil, isolation: nil, &block)
def transaction(requires_new: nil, isolation: nil, joinable: true, &block)
if !requires_new && current_transaction.joinable?
if isolation
raise ActiveRecord::TransactionIsolationError, "cannot set isolation when joining a transaction"
end
yield
else
transaction_manager.within_new_transaction(isolation: isolation, joinable: joinable, &block)
end
rescue ActiveRecord::Rollback
# rollbacks are silently swallowed
end
attr_reader :transaction_manager # :nodoc:
delegate :within_new_transaction, :open_transactions, :current_transaction, :begin_transaction,
:commit_transaction, :rollback_transaction, :materialize_transactions,
:disable_lazy_transactions!, :enable_lazy_transactions!, :dirty_current_transaction,
to: :transaction_manager
def mark_transaction_written_if_write(sql) # :nodoc:
transaction = current_transaction
if transaction.open?
transaction.written ||= write_query?(sql)
end
end
def transaction_open?
current_transaction.open?
end
def reset_transaction(restore: false) # :nodoc:
# Store the existing transaction state to the side
old_state = @transaction_manager if restore && @transaction_manager&.restorable?
@transaction_manager = ConnectionAdapters::TransactionManager.new(self)
if block_given?
# Reconfigure the connection without any transaction state in the way
result = yield
# Now the connection's fully established, we can swap back
if old_state
@transaction_manager = old_state
@transaction_manager.restore_transactions
end
result
end
end
# Register a record with the current transaction so that its after_commit and after_rollback callbacks
# can be called.
def add_transaction_record(record, ensure_finalize = true)
current_transaction.add_record(record, ensure_finalize)
end
# Begins the transaction (and turns off auto-committing).
def begin_db_transaction() end
def transaction_isolation_levels
{
read_uncommitted: "READ UNCOMMITTED",
read_committed: "READ COMMITTED",
repeatable_read: "REPEATABLE READ",
serializable: "SERIALIZABLE"
}
end
# Begins the transaction with the isolation level set. Raises an error by
# default; adapters that support setting the isolation level should implement
# this method.
def begin_isolated_db_transaction(isolation)
raise ActiveRecord::TransactionIsolationError, "adapter does not support setting transaction isolation"
end
# Commits the transaction (and turns on auto-committing).
def commit_db_transaction() end
# Rolls back the transaction (and turns on auto-committing). Must be
# done if the transaction block raises an exception or returns false.
def rollback_db_transaction
exec_rollback_db_transaction
rescue ActiveRecord::ConnectionNotEstablished, ActiveRecord::ConnectionFailed
# Connection's gone; that counts as a rollback
end
def exec_rollback_db_transaction() end # :nodoc:
def restart_db_transaction
exec_restart_db_transaction
end
def exec_restart_db_transaction() end # :nodoc:
def rollback_to_savepoint(name = nil)
exec_rollback_to_savepoint(name)
end
def default_sequence_name(table, column)
nil
end
# Set the sequence to the max value of the table's column.
def reset_sequence!(table, column, sequence = nil)
# Do nothing by default. Implement for PostgreSQL, Oracle, ...
end
# Inserts the given fixture into the table. Overridden in adapters that require
# something beyond a simple insert (e.g. Oracle).
# Most of adapters should implement +insert_fixtures_set+ that leverages bulk SQL insert.
# We keep this method to provide fallback
# for databases like SQLite that do not support bulk inserts.
def insert_fixture(fixture, table_name)
execute(build_fixture_sql(Array.wrap(fixture), table_name), "Fixture Insert")
end
def insert_fixtures_set(fixture_set, tables_to_delete = [])
fixture_inserts = build_fixture_statements(fixture_set)
table_deletes = tables_to_delete.map { |table| "DELETE FROM #{quote_table_name(table)}" }
statements = table_deletes + fixture_inserts
with_multi_statements do
disable_referential_integrity do
transaction(requires_new: true) do
execute_batch(statements, "Fixtures Load")
end
end
end
end
def empty_insert_statement_value(primary_key = nil)
"DEFAULT VALUES"
end
# Sanitizes the given LIMIT parameter in order to prevent SQL injection.
#
# The +limit+ may be anything that can evaluate to a string via #to_s. It
# should look like an integer, or an Arel SQL literal.
#
# Returns Integer and Arel::Nodes::SqlLiteral limits as is.
def sanitize_limit(limit)
if limit.is_a?(Integer) || limit.is_a?(Arel::Nodes::SqlLiteral)
limit
else
Integer(limit)
end
end
# Fixture value is quoted by Arel, however scalar values
# are not quotable. In this case we want to convert
# the column value to YAML.
def with_yaml_fallback(value) # :nodoc:
if value.is_a?(Hash) || value.is_a?(Array)
YAML.dump(value)
else
value
end
end
# This is a safe default, even if not high precision on all databases
HIGH_PRECISION_CURRENT_TIMESTAMP = Arel.sql("CURRENT_TIMESTAMP").freeze # :nodoc:
private_constant :HIGH_PRECISION_CURRENT_TIMESTAMP
# Returns an Arel SQL literal for the CURRENT_TIMESTAMP for usage with
# arbitrary precision date/time columns.
#
# Adapters supporting datetime with precision should override this to
# provide as much precision as is available.
def high_precision_current_timestamp
HIGH_PRECISION_CURRENT_TIMESTAMP
end
def internal_exec_query(sql, name = "SQL", binds = [], prepare: false, async: false) # :nodoc:
raise NotImplementedError
end
private
def internal_execute(sql, name = "SCHEMA", allow_retry: false, materialize_transactions: true)
sql = transform_query(sql)
check_if_write_query(sql)
mark_transaction_written_if_write(sql)
raw_execute(sql, name, allow_retry: allow_retry, materialize_transactions: materialize_transactions)
end
def execute_batch(statements, name = nil)
statements.each do |statement|
internal_execute(statement, name)
end
end
def raw_execute(sql, name, async: false, allow_retry: false, materialize_transactions: true)
raise NotImplementedError
end
DEFAULT_INSERT_VALUE = Arel.sql("DEFAULT").freeze
private_constant :DEFAULT_INSERT_VALUE
def default_insert_value(column)
DEFAULT_INSERT_VALUE
end
def build_fixture_sql(fixtures, table_name)
columns = schema_cache.columns_hash(table_name).reject { |_, column| supports_virtual_columns? && column.virtual? }
values_list = fixtures.map do |fixture|
fixture = fixture.stringify_keys
unknown_columns = fixture.keys - columns.keys
if unknown_columns.any?
raise Fixture::FixtureError, %(table "#{table_name}" has no columns named #{unknown_columns.map(&:inspect).join(', ')}.)
end
columns.map do |name, column|
if fixture.key?(name)
type = lookup_cast_type_from_column(column)
with_yaml_fallback(type.serialize(fixture[name]))
else
default_insert_value(column)
end
end
end
table = Arel::Table.new(table_name)
manager = Arel::InsertManager.new(table)
if values_list.size == 1
values = values_list.shift
new_values = []
columns.each_key.with_index { |column, i|
unless values[i].equal?(DEFAULT_INSERT_VALUE)
new_values << values[i]
manager.columns << table[column]
end
}
values_list << new_values
else
columns.each_key { |column| manager.columns << table[column] }
end
manager.values = manager.create_values_list(values_list)
visitor.compile(manager.ast)
end
def build_fixture_statements(fixture_set)
fixture_set.filter_map do |table_name, fixtures|
next if fixtures.empty?
build_fixture_sql(fixtures, table_name)
end
end
def build_truncate_statement(table_name)
"TRUNCATE TABLE #{quote_table_name(table_name)}"
end
def build_truncate_statements(table_names)
table_names.map do |table_name|
build_truncate_statement(table_name)
end
end
def with_multi_statements
yield
end
def combine_multi_statements(total_sql)
total_sql.join(";\n")
end
# Returns an ActiveRecord::Result instance.
def select(sql, name = nil, binds = [], prepare: false, async: false)
if async && async_enabled?
if current_transaction.joinable?
raise AsynchronousQueryInsideTransactionError, "Asynchronous queries are not allowed inside transactions"
end
future_result = async.new(
pool,
sql,
name,
binds,
prepare: prepare,
)
if supports_concurrent_connections? && current_transaction.closed?
future_result.schedule!(ActiveRecord::Base.asynchronous_queries_session)
else
future_result.execute!(self)
end
return future_result
end
result = internal_exec_query(sql, name, binds, prepare: prepare)
if async
FutureResult.wrap(result)
else
result
end
end
def sql_for_insert(sql, pk, binds, returning) # :nodoc:
if supports_insert_returning?
if pk.nil?
# Extract the table from the insert sql. Yuck.
table_ref = extract_table_ref_from_insert_sql(sql)
pk = primary_key(table_ref) if table_ref
end
returning_columns = returning || Array(pk)
returning_columns_statement = returning_columns.map { |c| quote_column_name(c) }.join(", ")
sql = "#{sql} RETURNING #{returning_columns_statement}" if returning_columns.any?
end
[sql, binds]
end
def last_inserted_id(result)
single_value_from_rows(result.rows)
end
def returning_column_values(result)
[last_inserted_id(result)]
end
def single_value_from_rows(rows)
row = rows.first
row && row.first
end
def arel_from_relation(relation)
if relation.is_a?(Relation)
relation.arel
else
relation
end
end
def extract_table_ref_from_insert_sql(sql)
if sql =~ /into\s("[A-Za-z0-9_."\[\]\s]+"|[A-Za-z0-9_."\[\]]+)\s*/im
$1.delete('"').strip
end
end
end
end
end