mariadb/storage/innobase/que/que0que.cc

/*****************************************************************************

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Copyright (c) 2017, 2022, MariaDB Corporation.

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*****************************************************************************/

/**************************************************//**
@file que/que0que.cc
Query graph

Created 5/27/1996 Heikki Tuuri
*******************************************************/

#include "que0que.h"
#include "trx0trx.h"
#include "trx0roll.h"
#include "row0undo.h"
#include "row0ins.h"
#include "row0upd.h"
#include "row0sel.h"
#include "row0purge.h"
#include "dict0crea.h"
#include "log0log.h"
#include "eval0proc.h"

#define QUE_MAX_LOOPS_WITHOUT_CHECK	16

/* Short introduction to query graphs
   ==================================

A query graph consists of nodes linked to each other in various ways. The
execution starts at que_run_threads() which takes a que_thr_t parameter.
que_thr_t contains two fields that control query graph execution: run_node
and prev_node. run_node is the next node to execute and prev_node is the
last node executed.

Each node has a pointer to a 'next' statement, i.e., its brother, and a
pointer to its parent node. The next pointer is NULL in the last statement
of a block.

Loop nodes contain a link to the first statement of the enclosed statement
list. While the loop runs, que_thr_step() checks if execution to the loop
node came from its parent or from one of the statement nodes in the loop. If
it came from the parent of the loop node it starts executing the first
statement node in the loop. If it came from one of the statement nodes in
the loop, then it checks if the statement node has another statement node
following it, and runs it if so.

To signify loop ending, the loop statements (see e.g. while_step()) set
que_thr_t->run_node to the loop node's parent node. This is noticed on the
next call of que_thr_step() and execution proceeds to the node pointed to by
the loop node's 'next' pointer.

For example, the code:

X := 1;
WHILE X < 5 LOOP
 X := X + 1;
 X := X + 1;
X := 5

will result in the following node hierarchy, with the X-axis indicating
'next' links and the Y-axis indicating parent/child links:

A - W - A
    |
    |
    A - A

A = assign_node_t, W = while_node_t. */

/* How a stored procedure containing COMMIT or ROLLBACK commands
is executed?

The commit or rollback can be seen as a subprocedure call.

When the transaction starts to handle a rollback or commit.
It builds a query graph which, when executed, will roll back
or commit the incomplete transaction. The transaction
may be moved to the TRX_QUE_ROLLING_BACK state.
If specified, the SQL cursors opened by the transaction are closed.
When the execution of the graph completes, it is like returning
from a subprocedure: the query thread which requested the operation
starts running again. */

/***********************************************************************//**
Creates a query graph fork node.
@return own: fork node */
que_fork_t*
que_fork_create(mem_heap_t *heap)
{
	que_fork_t*	fork;

	ut_ad(heap);

	fork = static_cast<que_fork_t*>(mem_heap_zalloc(heap, sizeof(*fork)));

	fork->heap = heap;

	fork->common.type = QUE_NODE_FORK;

	fork->state = QUE_FORK_COMMAND_WAIT;

	fork->graph = fork;

	UT_LIST_INIT(fork->thrs, &que_thr_t::thrs);

	return(fork);
}


/** Creates a query graph thread node.
@param[in]	parent		parent node, i.e., a fork node
@param[in]	heap		memory heap where created
@param[in]	prebuilt	row prebuilt structure
@return own: query thread node */
que_thr_t*
que_thr_create(
	que_fork_t*	parent,
	mem_heap_t*	heap,
	row_prebuilt_t*	prebuilt)
{
	que_thr_t*	thr;

	ut_ad(parent != NULL);
	ut_ad(heap != NULL);

	thr = static_cast<que_thr_t*>(mem_heap_zalloc(heap, sizeof(*thr)));

	thr->graph = parent->graph;

	thr->common.parent = parent;

	thr->common.type = QUE_NODE_THR;

	thr->prebuilt = prebuilt;

	UT_LIST_ADD_LAST(parent->thrs, thr);

	return(thr);
}

/**********************************************************************//**
Inits a query thread for a command. */
UNIV_INLINE
void
que_thr_init_command(
/*=================*/
	que_thr_t*	thr)	/*!< in: query thread */
{
	thr->run_node = thr;
	thr->prev_node = thr->common.parent;
	thr->state = QUE_THR_RUNNING;
}

/**********************************************************************//**
Starts execution of a command in a query fork. Picks a query thread which
is not in the QUE_THR_RUNNING state and moves it to that state. If none
can be chosen, a situation which may arise in parallelized fetches, NULL
is returned.
@return a query thread of the graph moved to QUE_THR_RUNNING state, or
NULL; the query thread should be executed by que_run_threads by the
caller */
que_thr_t*
que_fork_start_command(
/*===================*/
	que_fork_t*	fork)	/*!< in: a query fork */
{
	fork->state = QUE_FORK_ACTIVE;

	fork->last_sel_node = NULL;

	que_thr_t* thr = UT_LIST_GET_FIRST(fork->thrs);

	if (thr) {
		ut_ad(thr->state == QUE_THR_COMPLETED);
		que_thr_init_command(thr);
	}

	return(thr);
}

/**********************************************************************//**
Calls que_graph_free_recursive for statements in a statement list. */
static
void
que_graph_free_stat_list(
/*=====================*/
	que_node_t*	node)	/*!< in: first query graph node in the list */
{
	while (node) {
		que_node_t* next = que_node_get_next(node);
		que_graph_free_recursive(node);
		node = next;
	}
}

/**********************************************************************//**
Frees a query graph, but not the heap where it was created. Does not free
explicit cursor declarations, they are freed in que_graph_free. */
void
que_graph_free_recursive(
/*=====================*/
	que_node_t*	node)	/*!< in: query graph node */
{
	que_fork_t*	fork;
	que_thr_t*	thr;
	undo_node_t*	undo;
	sel_node_t*	sel;
	ins_node_t*	ins;
	upd_node_t*	upd;
	tab_node_t*	cre_tab;
	ind_node_t*	cre_ind;
	purge_node_t*	purge;

	if (node == NULL) {
		return;
	}

	switch (que_node_get_type(node)) {

	case QUE_NODE_FORK:
		fork = static_cast<que_fork_t*>(node);

		thr = UT_LIST_GET_FIRST(fork->thrs);

		while (thr) {
			que_graph_free_recursive(thr);

			thr = UT_LIST_GET_NEXT(thrs, thr);
		}

		break;
	case QUE_NODE_THR:
		thr = static_cast<que_thr_t*>(node);
		que_graph_free_recursive(thr->child);
		break;
	case QUE_NODE_UNDO:

		undo = static_cast<undo_node_t*>(node);

		mem_heap_free(undo->heap);

		break;
	case QUE_NODE_SELECT:

		sel = static_cast<sel_node_t*>(node);

		sel_node_free_private(sel);

		break;
	case QUE_NODE_INSERT:
		ins = static_cast<ins_node_t*>(node);

		que_graph_free_recursive(ins->select);
		ins->~ins_node_t();
		break;
	case QUE_NODE_PURGE:
		purge = static_cast<purge_node_t*>(node);

		mem_heap_free(purge->heap);

		purge->~purge_node_t();
		break;

	case QUE_NODE_UPDATE:
		upd = static_cast<upd_node_t*>(node);

		que_graph_free_recursive(upd->cascade_node);
		ut_free(upd->pcur->old_rec_buf);
		upd->pcur->old_rec_buf = NULL;

		if (upd->cascade_heap) {
			mem_heap_free(upd->cascade_heap);
			upd->cascade_heap = NULL;
		}

		que_graph_free_recursive(upd->select);
		upd->select = NULL;

		if (upd->heap != NULL) {
			mem_heap_free(upd->heap);
			upd->heap = NULL;
		}

		break;
	case QUE_NODE_CREATE_TABLE:
		cre_tab = static_cast<tab_node_t*>(node);

		que_graph_free_recursive(cre_tab->tab_def);
		que_graph_free_recursive(cre_tab->col_def);
		que_graph_free_recursive(cre_tab->v_col_def);

		mem_heap_free(cre_tab->heap);

		break;
	case QUE_NODE_CREATE_INDEX:
		cre_ind = static_cast<ind_node_t*>(node);

		que_graph_free_recursive(cre_ind->ind_def);
		que_graph_free_recursive(cre_ind->field_def);

		mem_heap_free(cre_ind->heap);

		break;
	case QUE_NODE_PROC:
		que_graph_free_stat_list(((proc_node_t*) node)->stat_list);

		break;
	case QUE_NODE_IF:
		que_graph_free_stat_list(((if_node_t*) node)->stat_list);
		que_graph_free_stat_list(((if_node_t*) node)->else_part);
		que_graph_free_stat_list(((if_node_t*) node)->elsif_list);

		break;
	case QUE_NODE_ELSIF:
		que_graph_free_stat_list(((elsif_node_t*) node)->stat_list);

		break;
	case QUE_NODE_WHILE:
		que_graph_free_stat_list(((while_node_t*) node)->stat_list);

		break;
	case QUE_NODE_FOR:
		que_graph_free_stat_list(((for_node_t*) node)->stat_list);

		break;

	case QUE_NODE_ASSIGNMENT:
	case QUE_NODE_EXIT:
	case QUE_NODE_RETURN:
	case QUE_NODE_COMMIT:
	case QUE_NODE_ROLLBACK:
	case QUE_NODE_LOCK:
	case QUE_NODE_FUNC:
	case QUE_NODE_ORDER:
	case QUE_NODE_ROW_PRINTF:
	case QUE_NODE_OPEN:
	case QUE_NODE_FETCH:
		/* No need to do anything */

		break;
	default:
		ut_error;
	}
}

/**********************************************************************//**
Frees a query graph. */
void
que_graph_free(
/*===========*/
	que_t*	graph)	/*!< in: query graph; we assume that the memory
			heap where this graph was created is private
			to this graph: if not, then use
			que_graph_free_recursive and free the heap
			afterwards! */
{
	ut_ad(graph);

	if (graph->sym_tab) {
		/* The following call frees dynamic memory allocated
		for variables etc. during execution. Frees also explicit
		cursor definitions. */

		sym_tab_free_private(graph->sym_tab);
	}

	if (graph->info) {
		pars_info_free(graph->info);
	}

	que_graph_free_recursive(graph);

	mem_heap_free(graph->heap);
}

/****************************************************************//**
Performs an execution step on a thr node.
@return query thread to run next, or NULL if none */
static
que_thr_t*
que_thr_node_step(
/*==============*/
	que_thr_t*	thr)	/*!< in: query thread where run_node must
				be the thread node itself */
{
	ut_ad(thr->run_node == thr);

	if (thr->prev_node == thr->common.parent) {
		/* If control to the node came from above, it is just passed
		on */

		thr->run_node = thr->child;

		return(thr);
	}

	trx_t *trx= thr->graph->trx;
	trx->mutex_lock();

	if (!trx->lock.wait_thr && thr->graph->state == QUE_FORK_ACTIVE) {
		thr->state = QUE_THR_COMPLETED;
		thr = NULL;
	}

	trx->mutex_unlock();
	return(thr);
}

/****************************************************************//**
Get the first containing loop node (e.g. while_node_t or for_node_t) for the
given node, or NULL if the node is not within a loop.
@return containing loop node, or NULL. */
que_node_t*
que_node_get_containing_loop_node(
/*==============================*/
	que_node_t*	node)	/*!< in: node */
{
	ut_ad(node);

	for (;;) {
		ulint	type;

		node = que_node_get_parent(node);

		if (!node) {
			break;
		}

		type = que_node_get_type(node);

		if ((type == QUE_NODE_FOR) || (type == QUE_NODE_WHILE)) {
			break;
		}
	}

	return(node);
}

/**********************************************************************//**
Performs an execution step of an open or close cursor statement node.
@param thr query thread */
static void open_step(que_thr_t *thr)
{
  open_node_t *node= static_cast<open_node_t*>(thr->run_node);
  ut_ad(que_node_get_type(node) == QUE_NODE_OPEN);
  sel_node_t *sel_node= node->cursor_def;

  if (node->op_type == ROW_SEL_OPEN_CURSOR)
    sel_node->state= SEL_NODE_OPEN;
  else
  {
    ut_ad(sel_node->state != SEL_NODE_CLOSED);
    sel_node->state= SEL_NODE_CLOSED;
  }

  thr->run_node= que_node_get_parent(node);
}

/**********************************************************************//**
Performs an execution step on a query thread.
@return query thread to run next: it may differ from the input
parameter if, e.g., a subprocedure call is made */
UNIV_INLINE
que_thr_t*
que_thr_step(
/*=========*/
	que_thr_t*	thr)	/*!< in: query thread */
{
	que_node_t*	node;
	que_thr_t*	old_thr;
	trx_t*		trx;
	ulint		type;

	trx = thr_get_trx(thr);

	ut_ad(thr->state == QUE_THR_RUNNING);
	ut_a(trx->error_state == DB_SUCCESS);

	thr->resource++;

	node = thr->run_node;
	type = que_node_get_type(node);

	old_thr = thr;

	if (type & QUE_NODE_CONTROL_STAT) {
		if ((thr->prev_node != que_node_get_parent(node))
		    && que_node_get_next(thr->prev_node)) {

			/* The control statements, like WHILE, always pass the
			control to the next child statement if there is any
			child left */

			thr->run_node = que_node_get_next(thr->prev_node);

		} else if (type == QUE_NODE_IF) {
			if_step(thr);
		} else if (type == QUE_NODE_FOR) {
			for_step(thr);
		} else if (type == QUE_NODE_PROC) {
			if (thr->prev_node == que_node_get_parent(node)) {
				trx->last_sql_stat_start.least_undo_no
					= trx->undo_no;
			}

			proc_step(thr);
		} else if (type == QUE_NODE_WHILE) {
			while_step(thr);
		} else {
			ut_error;
		}
	} else if (type == QUE_NODE_ASSIGNMENT) {
		assign_step(thr);
	} else if (type == QUE_NODE_SELECT) {
		thr = row_sel_step(thr);
	} else if (type == QUE_NODE_INSERT) {
		trx_start_if_not_started_xa(thr_get_trx(thr), true);
		thr = row_ins_step(thr);
	} else if (type == QUE_NODE_UPDATE) {
		trx_start_if_not_started_xa(thr_get_trx(thr), true);
		thr = row_upd_step(thr);
	} else if (type == QUE_NODE_FETCH) {
		thr = fetch_step(thr);
	} else if (type == QUE_NODE_OPEN) {
		open_step(thr);
	} else if (type == QUE_NODE_FUNC) {
		proc_eval_step(thr);

	} else if (type == QUE_NODE_LOCK) {

		ut_error;
	} else if (type == QUE_NODE_THR) {
		thr = que_thr_node_step(thr);
	} else if (type == QUE_NODE_COMMIT) {
		thr = trx_commit_step(thr);
	} else if (type == QUE_NODE_UNDO) {
		thr = row_undo_step(thr);
	} else if (type == QUE_NODE_PURGE) {
		thr = row_purge_step(thr);
	} else if (type == QUE_NODE_RETURN) {
		thr = return_step(thr);
	} else if (type == QUE_NODE_EXIT) {
		thr = exit_step(thr);
	} else if (type == QUE_NODE_ROLLBACK) {
		thr = trx_rollback_step(thr);
	} else if (type == QUE_NODE_CREATE_TABLE) {
		thr = dict_create_table_step(thr);
	} else if (type == QUE_NODE_CREATE_INDEX) {
		thr = dict_create_index_step(thr);
	} else if (type == QUE_NODE_ROW_PRINTF) {
		thr = row_printf_step(thr);
	} else {
		ut_error;
	}

	if (type == QUE_NODE_EXIT) {
		old_thr->prev_node = que_node_get_containing_loop_node(node);
	} else {
		old_thr->prev_node = node;
	}

	if (thr) {
		ut_a(thr_get_trx(thr)->error_state == DB_SUCCESS);
	}

	return(thr);
}

/**********************************************************************//**
Run a query thread until it finishes or encounters e.g. a lock wait. */
static
void
que_run_threads_low(
/*================*/
	que_thr_t*	thr)	/*!< in: query thread */
{
	ut_ad(thr->state == QUE_THR_RUNNING);

	/* cumul_resource counts how much resources the OS thread (NOT the
	query thread) has spent in this function */

	for (trx_t* trx = thr_get_trx(thr);;) {
		ut_ad(!trx->mutex_is_owner());
		ut_a(trx->error_state == DB_SUCCESS);
		/* Check that there is enough space in the log to accommodate
		possible log entries by this query step; if the operation can
		touch more than about 4 pages, checks must be made also within
		the query step! */

		log_free_check();

		/* Perform the actual query step: note that the query thread
		may change if, e.g., a subprocedure call is made */

		que_thr_t* next_thr = que_thr_step(thr);
		ut_ad(trx == thr_get_trx(thr));
		if (!next_thr) {
			return;
		}

		ut_a(next_thr == thr);
	}
}

/**********************************************************************//**
Run a query thread. Handles lock waits. */
void
que_run_threads(
/*============*/
	que_thr_t*	thr)	/*!< in: query thread */
{
	trx_t* trx = thr->graph->trx;
loop:
	ut_a(trx->error_state == DB_SUCCESS);
	que_run_threads_low(thr);

	if (thr->state != QUE_THR_COMPLETED) {
		if (trx->lock.wait_thr) {
			ut_ad(trx->id);
			if (lock_wait(thr) == DB_SUCCESS) {
				goto loop;
			}
		} else if (trx->error_state == DB_SUCCESS) {
			goto loop;
		}
	}
}

/*********************************************************************//**
Evaluate the given SQL.
@return error code or DB_SUCCESS */
dberr_t
que_eval_sql(
/*=========*/
	pars_info_t*	info,	/*!< in: info struct, or NULL */
	const char*	sql,	/*!< in: SQL string */
	trx_t*		trx)	/*!< in: trx */
{
	que_thr_t*	thr;
	que_t*		graph;

	DBUG_ENTER("que_eval_sql");
	DBUG_PRINT("que_eval_sql", ("query: %s", sql));

	ut_a(trx->error_state == DB_SUCCESS);

	graph = pars_sql(info, sql);

	graph->trx = trx;
	trx->graph = NULL;

	ut_a(thr = que_fork_start_command(graph));

	que_run_threads(thr);

	que_graph_free(graph);

	DBUG_RETURN(trx->error_state);
}