use crate::{ schema::Table, vdbe::{builder::ProgramBuilder, insn::Insn}, Result, }; use super::{ emitter::{emit_query, Resolver, TranslateCtx}, main_loop::LoopLabels, plan::{QueryDestination, SelectPlan, TableReferences}, }; /// Emit the subqueries contained in the FROM clause. /// This is done first so the results can be read in the main query loop. pub fn emit_subqueries( program: &mut ProgramBuilder, t_ctx: &mut TranslateCtx, tables: &mut TableReferences, ) -> Result<()> { for table_reference in tables.joined_tables_mut() { if let Table::FromClauseSubquery(from_clause_subquery) = &mut table_reference.table { // Emit the subquery and get the start register of the result columns. let result_columns_start = emit_subquery(program, &mut from_clause_subquery.plan, t_ctx)?; // Set the start register of the subquery's result columns. // This is done so that translate_expr() can read the result columns of the subquery, // as if it were reading from a regular table. from_clause_subquery.result_columns_start_reg = Some(result_columns_start); } } Ok(()) } /// Emit a subquery and return the start register of the result columns. /// This is done by emitting a coroutine that stores the result columns in sequential registers. /// Each subquery in a FROM clause has its own separate SelectPlan which is wrapped in a coroutine. /// /// The resulting bytecode from a subquery is mostly exactly the same as a regular query, except: /// - it ends in an EndCoroutine instead of a Halt. /// - instead of emitting ResultRows, the coroutine yields to the main query loop. /// - the first register of the result columns is returned to the parent query, /// so that translate_expr() can read the result columns of the subquery, /// as if it were reading from a regular table. /// /// Since a subquery has its own SelectPlan, it can contain nested subqueries, /// which can contain even more nested subqueries, etc. pub fn emit_subquery( program: &mut ProgramBuilder, plan: &mut SelectPlan, t_ctx: &mut TranslateCtx, ) -> Result { let yield_reg = program.alloc_register(); let coroutine_implementation_start_offset = program.allocate_label(); match &mut plan.query_destination { QueryDestination::CoroutineYield { yield_reg: y, coroutine_implementation_start, } => { // The parent query will use this register to jump to/from the subquery. *y = yield_reg; // The parent query will use this register to reinitialize the coroutine when it needs to run multiple times. *coroutine_implementation_start = coroutine_implementation_start_offset; } _ => unreachable!("emit_subquery called on non-subquery"), } let end_coroutine_label = program.allocate_label(); let mut metadata = TranslateCtx { labels_main_loop: (0..plan.joined_tables().len()) .map(|_| LoopLabels::new(program)) .collect(), label_main_loop_end: None, meta_group_by: None, meta_left_joins: (0..plan.joined_tables().len()).map(|_| None).collect(), meta_sort: None, reg_agg_start: None, reg_nonagg_emit_once_flag: None, reg_result_cols_start: None, limit_ctx: None, reg_offset: None, reg_limit_offset_sum: None, resolver: Resolver::new(t_ctx.resolver.schema, t_ctx.resolver.symbol_table), non_aggregate_expressions: Vec::new(), cdc_cursor_id: None, }; let subquery_body_end_label = program.allocate_label(); program.emit_insn(Insn::InitCoroutine { yield_reg, jump_on_definition: subquery_body_end_label, start_offset: coroutine_implementation_start_offset, }); program.preassign_label_to_next_insn(coroutine_implementation_start_offset); let result_column_start_reg = emit_query(program, plan, &mut metadata)?; program.resolve_label(end_coroutine_label, program.offset()); program.emit_insn(Insn::EndCoroutine { yield_reg }); program.preassign_label_to_next_insn(subquery_body_end_label); Ok(result_column_start_reg) }