用于EagleEye3.0 规则集漏报和误报测试的示例项目,项目收集于github和gitee
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/* Copyright (c) 2017, 2019, Oracle and/or its affiliates. All rights reserved.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License, version 2.0,
as published by the Free Software Foundation.
This program is also distributed with certain software (including
but not limited to OpenSSL) that is licensed under separate terms,
as designated in a particular file or component or in included license
documentation. The authors of MySQL hereby grant you an additional
permission to link the program and your derivative works with the
separately licensed software that they have included with MySQL.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License, version 2.0, for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */
#include "sql/table_function.h"
#include <string.h>
#include <algorithm>
#include <memory>
#include <new>
#include "m_string.h"
#include "my_sys.h"
#include "mysql/psi/psi_base.h"
#include "mysql/udf_registration_types.h"
#include "mysql_com.h"
#include "mysql_time.h"
#include "mysqld_error.h"
#include "prealloced_array.h"
#include "sql/field.h"
#include "sql/handler.h"
#include "sql/item.h"
#include "sql/item_json_func.h"
#include "sql/json_dom.h"
#include "sql/json_path.h"
#include "sql/my_decimal.h"
#include "sql/psi_memory_key.h"
#include "sql/rpl_utility.h" // read_field_metadata
#include "sql/sql_class.h" // THD
#include "sql/sql_exception_handler.h"
#include "sql/sql_list.h"
#include "sql/sql_show.h"
#include "sql/sql_table.h" // create_typelib
#include "sql/sql_tmp_table.h" // create_tmp_table_from_fields
#include "sql/system_variables.h"
#include "sql/table.h"
#include "sql_string.h"
#include "template_utils.h"
/******************************************************************************
Implementation of Table_function
******************************************************************************/
bool Table_function::create_result_table(ulonglong options,
const char *table_alias) {
DBUG_ASSERT(table == nullptr);
table = create_tmp_table_from_fields(thd, *get_field_list(), false, options,
table_alias);
return table == nullptr;
}
bool Table_function::write_row() {
int error;
if ((error = table->file->ha_write_row(table->record[0]))) {
if (!table->file->is_ignorable_error(error) &&
create_ondisk_from_heap(thd, table, error, true, nullptr))
return true; // Not a table_is_full error
}
return false;
}
void Table_function::empty_table() {
DBUG_ASSERT(table->is_created());
(void)table->empty_result_table();
}
bool Table_function::init_args() {
if (inited) return false;
if (do_init_args()) return true;
table->pos_in_table_list->dep_tables |= used_tables();
inited = true;
return false;
}
/******************************************************************************
Implementation of JSON_TABLE function
******************************************************************************/
Table_function_json::Table_function_json(THD *thd_arg, const char *alias,
Item *a, List<Json_table_column> *cols)
: Table_function(thd_arg),
m_columns(cols),
m_all_columns(thd->mem_root),
m_table_alias(alias),
is_source_parsed(false),
source(a) {}
bool Table_function_json::walk(Item_processor processor, enum_walk walk,
uchar *arg) {
// Only 'source' may reference columns of other tables; rest is literals.
return source->walk(processor, walk, arg);
}
List<Create_field> *Table_function_json::get_field_list() {
// It's safe as Json_table_column is derived from Create_field
return reinterpret_cast<List<Create_field> *>(&m_vt_list);
}
/**
Check if a JSON value is a JSON OPAQUE, and if it can be printed in the field
as a non base64 value.
This is currently used by JSON_TABLE to see if we can print the JSON value in
a field without having to encode it in base64.
@param field_to_store_in The field we want to store the JSON value in
@param json_data The JSON value we want to store.
@returns
true The JSON value can be stored without encoding it in base64
false The JSON value can not be stored without encoding it, or it is not a
JSON OPAQUE value.
*/
bool can_store_json_value_unencoded(const Field *field_to_store_in,
const Json_wrapper *json_data) {
return (field_to_store_in->type() == MYSQL_TYPE_VARCHAR ||
field_to_store_in->type() == MYSQL_TYPE_BLOB ||
field_to_store_in->type() == MYSQL_TYPE_STRING) &&
json_data->type() == enum_json_type::J_OPAQUE &&
(json_data->field_type() == MYSQL_TYPE_STRING ||
json_data->field_type() == MYSQL_TYPE_VARCHAR);
}
/**
Initialize columns and lists for json table
@details This function does several things:
1) sets up list of fields (vt_list) for result table creation
2) fills array of all columns (m_all_columns) for execution
3) for each column that has default ON EMPTY or ON ERROR clauses, checks
the value to be proper json and initializes column appropriately
4) for each column that involves path, the path is checked to be correct.
The function goes recursively, starting from the top NESTED PATH clause
and going in the depth-first way, traverses the tree of columns.
@param nest_idx index of parent's element in the nesting data array
@param parent Parent of the NESTED PATH clause being initialized
@returns
false ok
true an error occurred
*/
bool Table_function_json::init_json_table_col_lists(uint *nest_idx,
Json_table_column *parent) {
List_iterator<Json_table_column> li(*parent->m_nested_columns);
Json_table_column *col;
const uint current_nest_idx = *nest_idx;
// Used to set fast track between sibling NESTED PATH nodes
Json_table_column *nested = nullptr;
/*
This need to be set up once per statement, as it doesn't change between
EXECUTE calls.
*/
Prepared_stmt_arena_holder ps_arena_holder(thd);
while ((col = li++)) {
String path;
col->is_unsigned = (col->flags & UNSIGNED_FLAG);
col->m_jds_elt = &m_jds[current_nest_idx];
if (col->m_jtc_type != enum_jt_column::JTC_NESTED_PATH) {
col->m_field_idx = m_vt_list.elements;
m_vt_list.push_back(col);
if (check_column_name(col->field_name)) {
my_error(ER_WRONG_COLUMN_NAME, MYF(0), col->field_name);
return true;
}
if ((col->sql_type == MYSQL_TYPE_ENUM ||
col->sql_type == MYSQL_TYPE_SET) &&
!col->interval)
col->interval = create_typelib(thd->mem_root, col);
}
m_all_columns.push_back(col);
switch (col->m_jtc_type) {
case enum_jt_column::JTC_ORDINALITY: {
// No special handling is needed
break;
}
case enum_jt_column::JTC_PATH: {
path.set(col->m_path_str.str, col->m_path_str.length,
thd->variables.character_set_client);
if (parse_path(&path, false, &col->m_path_json)) return true;
if (col->m_on_empty == enum_jtc_on::JTO_DEFAULT) {
String src(col->m_default_empty_str.str,
col->m_default_empty_str.length,
thd->variables.character_set_client);
Json_dom_ptr dom; //@< we'll receive a DOM here
bool parse_error;
if (parse_json(src, 0, "JSON_TABLE", &dom, true, &parse_error) ||
(col->sql_type != MYSQL_TYPE_JSON && !dom->is_scalar())) {
my_error(ER_INVALID_DEFAULT, MYF(0), col->field_name);
return true;
}
col->m_default_empty_json = Json_wrapper(std::move(dom));
}
if (col->m_on_error == enum_jtc_on::JTO_DEFAULT) {
String src(col->m_default_error_str.str,
col->m_default_error_str.length,
thd->variables.character_set_client);
Json_dom_ptr dom; //@< we'll receive a DOM here
bool parse_error;
if (parse_json(src, 0, "JSON_TABLE", &dom, true, &parse_error) ||
(col->sql_type != MYSQL_TYPE_JSON && !dom->is_scalar())) {
my_error(ER_INVALID_DEFAULT, MYF(0), col->field_name);
return true;
}
col->m_default_error_json = Json_wrapper(std::move(dom));
}
break;
}
case enum_jt_column::JTC_EXISTS: {
path.set(col->m_path_str.str, col->m_path_str.length,
thd->variables.character_set_client);
if (parse_path(&path, false, &col->m_path_json)) return true;
break;
}
case enum_jt_column::JTC_NESTED_PATH: {
(*nest_idx)++;
if (*nest_idx >= MAX_NESTED_PATH) {
my_error(ER_JT_MAX_NESTED_PATH, MYF(0), MAX_NESTED_PATH,
m_table_alias);
return true;
}
col->m_child_jds_elt = &m_jds[*nest_idx];
path.set(col->m_path_str.str, col->m_path_str.length,
thd->variables.character_set_client);
if (nested) {
nested->m_next_nested = col;
col->m_prev_nested = nested;
}
nested = col;
if (parse_path(&path, false, &col->m_path_json) ||
init_json_table_col_lists(nest_idx, col))
return true;
break;
}
default:
DBUG_ASSERT(0);
}
}
return false;
}
/**
Check whether given default values can be saved to fields
@returns
true a conversion error occurred
false defaults can be saved or aren't specified
*/
bool Table_function_json::do_init_args() {
Item *dummy = source;
if (source->fix_fields(thd, &dummy)) return true;
DBUG_ASSERT(source->data_type() != MYSQL_TYPE_VAR_STRING);
if (source->has_aggregation() || source->has_subquery() || source != dummy) {
my_error(ER_WRONG_ARGUMENTS, MYF(0), "JSON_TABLE");
return true;
}
try {
/*
Check whether given JSON source is a const and it's valid, see also
Table_function_json::fill_result_table().
*/
if (source->const_item()) {
String buf;
Item *args[] = {source};
if (get_json_wrapper(args, 0, &buf, func_name(), &m_jds[0].jdata))
return true; // Error is already thrown
is_source_parsed = true;
}
} catch (...) {
/* purecov: begin inspected */
handle_std_exception(func_name());
return true;
/* purecov: end */
}
Json_table_column *col;
for (uint i = 0; i < m_all_columns.size(); i++) {
col = m_all_columns[i];
if (col->m_jtc_type != enum_jt_column::JTC_PATH) continue;
DBUG_ASSERT(col->m_field_idx >= 0);
if (col->m_on_empty == enum_jtc_on::JTO_DEFAULT) {
if (save_json_to_field(thd, get_field(col->m_field_idx), col->m_on_error,
&col->m_default_empty_json, CHECK_FIELD_WARN)) {
my_error(ER_INVALID_DEFAULT, MYF(0), col->field_name);
return true;
}
}
if (col->m_on_error == enum_jtc_on::JTO_DEFAULT) {
if (save_json_to_field(thd, get_field(col->m_field_idx), col->m_on_error,
&col->m_default_error_json, CHECK_FIELD_WARN)) {
my_error(ER_INVALID_DEFAULT, MYF(0), col->field_name);
return true;
}
}
}
return false;
}
bool Table_function_json::init() {
Json_table_column top({nullptr, 0}, m_columns);
if (m_vt_list.elements == 0) {
uint nest_idx = 0;
if (init_json_table_col_lists(&nest_idx, &top)) return true;
List_iterator<Json_table_column> li(m_vt_list);
/*
Check for duplicate names.
Two iterators over vt_list are used. First is used to get a field,
second - to compare the field with fields in the rest of the list.
For each iteration of the first list, we skip fields prior to the
first iterator's field.
*/
Json_table_column *first;
while ((first = li++)) {
Json_table_column *col;
List_iterator<Json_table_column> li2(m_vt_list);
// Compare 'first' with all columns prior to it
while ((col = li2++) && col != first) {
if (!strncmp(first->field_name, col->field_name, NAME_CHAR_LEN)) {
my_error(ER_DUP_FIELDNAME, MYF(0), first->field_name);
return true;
}
}
}
}
return false;
}
/**
A helper function which sets all columns under given NESTED PATH column
to nullptr. Used to evaluate sibling NESTED PATHS.
@param root root NESTED PATH column
@param [out] last last column which belongs to the given NESTED PATH
*/
void Table_function_json::set_subtree_to_null(Json_table_column *root,
Json_table_column **last) {
List_iterator<Json_table_column> li(*root->m_nested_columns);
Json_table_column *col;
while ((col = li++)) {
*last = col;
switch (col->m_jtc_type) {
case enum_jt_column::JTC_NESTED_PATH:
set_subtree_to_null(col, last);
break;
default:
get_field(col->m_field_idx)->set_null();
break;
}
}
}
/**
Fill a json table column
@details Fills a column with data, according to specification in
JSON_TABLE. This function handles all kinds of columns:
Ordinality) just saves the counter into the column's field
Path) extracts value, saves it to the column's field and handles
ON ERROR/ON EMPTY clauses
Exists) checks the path existence and saves either 1 or 0 into result
field
Nested path) matches the path expression against data source. If there're
matches, this function sets NESTED PATH's iterator over those
matches and resets ordinality counter.
@param[in] fld Column's field to save data to
@param[out] skip true <=> it's a NESTED PATH node and its path
expression didn't return any matches or a
previous sibling NESTED PATH clause still producing
records, thus all columns of this NESTED PATH node
should be skipped
@returns
false column is filled
true an error occurred, execution should be stopped
*/
bool Json_table_column::fill_column(Field *fld, jt_skip_reason *skip) {
*skip = JTS_NONE;
if (m_jtc_type != enum_jt_column::JTC_NESTED_PATH) {
fld->set_notnull();
DBUG_ASSERT(m_field_idx == fld->field_index);
}
switch (m_jtc_type) {
case enum_jt_column::JTC_ORDINALITY: {
if (fld->store(m_jds_elt->m_rowid, true)) return true;
break;
}
case enum_jt_column::JTC_PATH: {
THD *thd = fld->table->in_use;
// Vector of matches
Json_wrapper_vector data_v(key_memory_JSON);
m_jds_elt->jdata.seek(m_path_json, m_path_json.leg_count(), &data_v, true,
false);
if (data_v.size() > 0) {
Json_wrapper buf;
bool is_error = false;
enum_check_fields warn;
// Always issue at least a warning on truncation
if (m_on_error == enum_jtc_on::JTO_ERROR) {
// Issue an error when data is truncated on saving into field
warn = CHECK_FIELD_ERROR_FOR_NULL;
} else
warn = CHECK_FIELD_WARN;
if (data_v.size() > 1) {
// Make result array
if (fld->type() == MYSQL_TYPE_JSON) {
Json_array *a = new (std::nothrow) Json_array();
if (!a) return true;
for (Json_wrapper &w : data_v) {
if (a->append_alias(w.clone_dom(thd))) {
delete a; /* purecov: inspected */
return true;
}
}
buf = Json_wrapper(a);
} else {
is_error = true;
// Thrown an error when save_json_to_field() isn't called
if (m_on_error == enum_jtc_on::JTO_ERROR)
my_error(ER_WRONG_JSON_TABLE_VALUE, MYF(0), field_name);
}
} else
buf = std::move(data_v[0]);
is_error =
is_error || save_json_to_field(thd, fld, m_on_error, &buf, warn);
if (is_error) switch (m_on_error) {
case enum_jtc_on::JTO_ERROR: {
return true;
break;
}
case enum_jtc_on::JTO_DEFAULT: {
save_json_to_field(thd, fld, m_on_error, &m_default_error_json,
CHECK_FIELD_IGNORE);
break;
}
case enum_jtc_on::JTO_NULL:
default: {
fld->set_null();
break;
}
}
} else {
switch (m_on_empty) {
case enum_jtc_on::JTO_ERROR: {
my_error(ER_MISSING_JSON_TABLE_VALUE, MYF(0), field_name);
return true;
}
case enum_jtc_on::JTO_DEFAULT: {
save_json_to_field(thd, fld, m_on_error, &m_default_empty_json,
CHECK_FIELD_IGNORE);
break;
}
case enum_jtc_on::JTO_NULL:
default: {
fld->set_null();
break;
}
}
}
break;
}
case enum_jt_column::JTC_EXISTS: {
// Vector of matches
Json_wrapper_vector data_v(key_memory_JSON);
m_jds_elt->jdata.seek(m_path_json, m_path_json.leg_count(), &data_v, true,
true);
if (data_v.size() >= 1)
fld->store(1, true);
else
fld->store(0, true);
break;
}
case enum_jt_column::JTC_NESTED_PATH: {
// If this node sends data, advance ts iterator
if (m_child_jds_elt->producing_records) {
++m_child_jds_elt->it;
m_child_jds_elt->m_rowid++;
if ((m_child_jds_elt->it != m_child_jds_elt->v.end()))
m_child_jds_elt->jdata = std::move(*m_child_jds_elt->it);
else {
m_child_jds_elt->producing_records = false;
*skip = JTS_EOD;
}
return false;
}
// Run only one sibling nested path at a time
for (Json_table_column *tc = m_prev_nested; tc; tc = tc->m_prev_nested) {
DBUG_ASSERT(tc->m_jtc_type == enum_jt_column::JTC_NESTED_PATH);
if (tc->m_child_jds_elt->producing_records) {
*skip = JTS_SIBLING;
return false;
}
}
m_child_jds_elt->v.clear();
if (m_jds_elt->jdata.seek(m_path_json, m_path_json.leg_count(),
&m_child_jds_elt->v, true, false))
return true;
if (m_child_jds_elt->v.size() == 0) {
*skip = JTS_EOD;
return false;
}
m_child_jds_elt->it = m_child_jds_elt->v.begin();
m_child_jds_elt->producing_records = true;
m_child_jds_elt->m_rowid = 1;
m_child_jds_elt->jdata = std::move(*m_child_jds_elt->it);
break;
}
default: {
DBUG_ASSERT(0);
break;
}
}
return false;
}
void Json_table_column::cleanup() {
// Reset paths and wrappers to free allocated memory.
m_path_json = Json_path();
if (m_on_empty == enum_jtc_on::JTO_DEFAULT)
m_default_empty_json = Json_wrapper();
if (m_on_error == enum_jtc_on::JTO_DEFAULT)
m_default_error_json = Json_wrapper();
}
/**
Fill json table
@details This function goes along the flattened list of columns and
updates them by calling fill_column(). As it goes, it pushes all nested
path nodes to 'nested' list, using it as a stack. After writing a row, it
checks whether there's more data in the right-most nested path (top in the
stack). If there is, it advances path's iterator, if no - pops the path
from stack and goes to the next nested path (i.e more to left). When stack
is empty, then the loop is over and all data (if any) was stored in the table,
and function exits. Otherwise, the list of columns is positioned to the top
nested path in the stack and incremented to the column after the nested
path, then the loop of updating columns is executed again. So, whole
execution could look as follows:
columns ( <-- npr
cr1,
cr2,
nested path .. columns ( <-- np1
c11,
nested path .. columns ( <-- np2
c21
)
)
)
iteration | columns updated in the loop
1 npr cr1 cr2 np1 c11 np2 c21
2 c21
3 c21
4 c11 np2 c21
5 c21
6 c11 np2 c21
7 c21
8 npr cr1 cr2 np1 c11 np2 c21
9 c21
10 c11 np2 c21
Note that result table's row isn't automatically reset and if a column
isn't updated, its data is written multiple times. E.g. cr1 in the
example above is updated 2 times, but is written 10 times. This allows to
save cycles on updating fields that for sure haven't been changed.
When there's sibling nested paths, i.e two or more nested paths in the
same columns clause, then they're processed one at a time. Started with
first, and the rest are set to null with help f set_subtree_to_null().
When the first sibling nested path runs out of rows, it's set to null and
processing moves on to the next one.
@returns
false table filled
true error occurred
*/
bool Table_function_json::fill_json_table() {
// 'Stack' of nested NESTED PATH clauses
Prealloced_array<uint, MAX_NESTED_PATH> nested(PSI_NOT_INSTRUMENTED);
// The column being processed
uint col_idx = 0;
jt_skip_reason skip_subtree;
const enum_check_fields check_save = thd->check_for_truncated_fields;
do {
skip_subtree = JTS_NONE;
/*
When a NESTED PATH runs out of matches, we set it to null, and
continue filling the row, so next sibling NESTED PATH could start
sending rows. But if there's no such NESTED PATH, then this row must be
skipped as it's not a result of a match.
*/
bool skip_row = true;
for (; col_idx < m_all_columns.size(); col_idx++) {
/*
When NESTED PATH doesn't have a match for any reason, set its
columns to nullptr.
*/
Json_table_column *col = m_all_columns[col_idx];
if (col->fill_column(
(col->m_field_idx >= 0 ? get_field(col->m_field_idx) : nullptr),
&skip_subtree))
return true;
if (skip_subtree) {
set_subtree_to_null(col, &col);
// Position iterator to the last element of subtree
while (m_all_columns[col_idx] != col) col_idx++;
} else if (col->m_jtc_type == enum_jt_column::JTC_NESTED_PATH) {
nested.push_back(col_idx);
// Found a NESTED PATH which produced a record
skip_row = false;
}
}
if (!skip_row) write_row();
// Find next nested path and advance its iterator.
if (nested.size() > 0) {
uint j = nested.back();
nested.pop_back();
Json_table_column *col = m_all_columns[j];
/*
When there're sibling NESTED PATHs and the first one is producing
records, second one will skip_subtree and we need to reset it here,
as it's not relevant.
*/
if (col->m_child_jds_elt->producing_records) skip_subtree = JTS_NONE;
col_idx = j;
}
} while (nested.size() != 0 || skip_subtree != JTS_EOD);
thd->check_for_truncated_fields = check_save;
return false;
}
bool Table_function_json::fill_result_table() {
String buf;
DBUG_ASSERT(!table->materialized);
// reset table
empty_table();
try {
Item *args[] = {source};
/*
There are 3 possible cases of data source expression const-ness:
1. Always const, e.g. a plain string, source will be parsed once at
Table_function_json::init()
2. Non-const during init(), but become const after it, e.g a field from a
const table: source will be parsed here ONCE
3. Non-const, e.g. a table field: source will be parsed here EVERY TIME
fill_result_table() is called
*/
if (((!source->const_item() || !is_source_parsed) &&
get_json_wrapper(args, 0, &buf, func_name(), &m_jds[0].jdata)) ||
args[0]->null_value)
// No need to set null_value as it's not used by table functions
return 0;
is_source_parsed = true;
return fill_json_table();
} catch (...) {
/* purecov: begin inspected */
handle_std_exception(func_name());
return true;
/* purecov: end */
}
return 0;
}
static bool print_on_empty_error(String *str, enum_jtc_on jto,
LEX_STRING *default_str) {
switch (jto) {
case enum_jtc_on::JTO_ERROR:
return str->append(STRING_WITH_LEN(" error on "));
case enum_jtc_on::JTO_NULL:
return str->append(STRING_WITH_LEN(" null on "));
case enum_jtc_on::JTO_DEFAULT: {
return (str->append(STRING_WITH_LEN(" default '")) ||
str->append(default_str) || str->append(STRING_WITH_LEN("' on")));
break;
}
default:
DBUG_ASSERT(0);
};
return false;
}
bool Table_function_json::print_nested_path(Json_table_column *col, String *str,
enum_query_type query_type) {
if (str->append('\'') || str->append(col->m_path_str) ||
str->append(STRING_WITH_LEN("' columns (")))
return true;
Json_table_column *jtc;
List_iterator<Json_table_column> li(*col->m_nested_columns);
bool first = true;
while ((jtc = li++)) {
if (!first) {
if (str->append(STRING_WITH_LEN(", "))) return true;
} else
first = false;
switch (jtc->m_jtc_type) {
case enum_jt_column::JTC_ORDINALITY: {
if (str->append(jtc->field_name, strlen(jtc->field_name)) ||
str->append(STRING_WITH_LEN(" for ordinality")))
return true;
break;
}
case enum_jt_column::JTC_EXISTS:
case enum_jt_column::JTC_PATH: {
String type(15);
if (str->append(jtc->field_name, strlen(jtc->field_name)) ||
str->append(' '))
return true;
uint data = 0;
Field *fld = get_field(jtc->m_field_idx);
fld->save_field_metadata((uchar *)&data);
std::pair<my_off_t, std::pair<uint, bool>> pack = read_field_metadata(
reinterpret_cast<const uchar *>(&data), fld->binlog_type());
data = pack.second.first;
DBUG_ASSERT(fld->binlog_type() != MYSQL_TYPE_TYPED_ARRAY);
show_sql_type(jtc->sql_type, false, data, &type, fld->charset());
str->append(type);
if (jtc->m_jtc_type == enum_jt_column::JTC_EXISTS) {
if (str->append(STRING_WITH_LEN(" exists"))) return true;
}
if (str->append(STRING_WITH_LEN(" path '")) ||
str->append(jtc->m_path_str) || str->append('\''))
return true;
if (jtc->m_jtc_type == enum_jt_column::JTC_EXISTS) break;
if (jtc->m_on_empty != enum_jtc_on::JTO_IMPLICIT) {
print_on_empty_error(str, jtc->m_on_empty, &jtc->m_default_empty_str);
if (str->append(STRING_WITH_LEN(" empty"))) return true;
}
if (jtc->m_on_error != enum_jtc_on::JTO_IMPLICIT) {
if (print_on_empty_error(str, jtc->m_on_error,
&jtc->m_default_error_str) ||
str->append(STRING_WITH_LEN(" error")))
return true;
}
break;
}
case enum_jt_column::JTC_NESTED_PATH: {
if (str->append(STRING_WITH_LEN("nested path ")) ||
print_nested_path(jtc, str, query_type))
return true;
break;
}
};
}
return str->append(')');
}
bool Table_function_json::print(String *str, enum_query_type query_type) {
if (str->append(STRING_WITH_LEN("json_table("))) return true;
source->print(thd, str, query_type);
return (thd->is_error() || str->append(STRING_WITH_LEN(", ")) ||
print_nested_path(m_columns->head(), str, query_type) ||
str->append(')'));
}
table_map Table_function_json::used_tables() { return source->used_tables(); }
void Table_function_json::do_cleanup() {
source->cleanup();
for (uint i = 0; i < MAX_NESTED_PATH; i++) m_jds[i].cleanup();
for (uint i = 0; i < m_all_columns.size(); i++) m_all_columns[i]->cleanup();
m_all_columns.clear();
m_vt_list.empty();
}
void JT_data_source::cleanup() {
jdata = Json_wrapper();
v.clear();
v.shrink_to_fit();
producing_records = false;
}