Transaction
A transaction is an operation that contains one or more SQL statements. The execution of these statements must either be completely successful or completely fail. It is an indivisible work unit.
Introductionβ
Queries and DDL single statements are implicit transactions and are not supported within multi-statement transactions. Each individual write is an implicit transaction by default, and multiple writes can form an explicit transaction. Currently, Doris does not support nested transactions.
Explicit and Implicit Transactionsβ
Explicit Transactionsβ
Explicit transactions require users to actively start, commit, or roll back transactions. Currently, DDL and query statements are not supported.
BEGIN;
[INSERT, UPDATE, DELETE statement]
COMMIT; / ROLLBACK;
Implicit Transactionsβ
Implicit transactions refer to SQL statements that are executed without explicitly adding statements to start and commit transactions before and after the statements.
In Doris, except for Group Commit, each import statement opens a transaction when it starts executing. The transaction is automatically committed after the statement is executed, or automatically rolled back if the statement fails. Each query or DDL statement is also an implicit transaction.
Isolation Levelβ
The only isolation level currently supported by Doris is READ COMMITTED. Under the READ COMMITTED isolation level, a statement sees only data that was committed before the statement began execution. It does not see uncommitted data.
When a single statement is executed, it captures a snapshot of the tables involved at the start of the statement, meaning that a single statement can only see commits from other transactions made before it began execution. Other transactions' commits are not visible during the execution of a single statement.
When a statement is executed inside a multi-statement transaction:
- It sees only data that was committed before the statement began execution. If another transaction commits between the execution of the first and the second statements, two successive statements in the same transaction may see different data.
- Currently, it cannot see changes made by previous statements within the same transaction.
No Duplicates, No Lossβ
Doris supports mechanisms to ensure no duplicates and no loss during data writes. The Label mechanism ensures no duplicates within a single transaction, while two-phase commit coordinates to prevent duplicates across multiple transactions.
Label Mechanismβ
Transactions or writes in Doris can be assigned a Label. This Label is typically a user-defined string with some business logic attributes. If not set, a UUID string will be generated internally. The main purpose of a Label is to uniquely identify a transaction or import task and ensure that a transaction or import with the same Label will only execute successfully once. The Label mechanism ensures that data imports are neither lost nor duplicated. If the upstream data source guarantees at-least-once semantics, combined with Doris's Label mechanism, exactly-once semantics can be achieved. Labels are unique within a database.
Doris will clean up Labels based on time and number. By default, if the number of Labels exceeds 2000, cleanup will be triggered. Labels older than three days will also be cleaned up by default. Once a Label is cleaned up, a Label with the same name can execute successfully again, meaning it no longer has deduplication semantics.
Labels are usually set in the format of business_logic+timestamp
, such as my_business1_20220330_125000
. This Label typically represents a batch of data generated by the business my_business1
at 2022-03-30 12:50:00
. By setting Labels this way, the business can query the import task status using the Label to clearly determine whether the batch of data at that time has been successfully imported. If not, the import can be retried using the same Label.
StreamLoad 2PCβ
StreamLoad 2PC is mainly used to support exactly-once semantics (EOS) when writing to Doris with Flink.
Transaction Operationsβ
Start a Transactionβ
BEGIN;
BEGIN WITH LABEL {user_label};
If this statement is executed while the current session is in the middle of a transaction, Doris will ignore the statement, which can also be understood as transactions cannot be nested.
Commit a Transactionβ
COMMIT;
Used to commit all modifications made in the current transaction.
Rollback a Transactionβ
ROLLBACK;
Used to roll back all modifications made in the current transaction.
Transactions are session-level, so if a session is terminated or closed, the transaction will automatically be rolled back.
Transaction with multiple sql statementsβ
Currently, Doris supports two ways of transaction loading.
Multiple INSERT INTO VALUES
for one tableβ
Suppose the table schema is:
CREATE TABLE `dt` (
`id` INT(11) NOT NULL,
`name` VARCHAR(50) NULL,
`score` INT(11) NULL
) ENGINE=OLAP
UNIQUE KEY(`id`)
DISTRIBUTED BY HASH(`id`) BUCKETS 1
PROPERTIES (
"replication_num" = "1"
);
Do transaction load:
mysql> BEGIN;
Query OK, 0 rows affected (0.01 sec)
{'label':'txn_insert_b55db21aad7451b-b5b6c339704920c5', 'status':'PREPARE', 'txnId':''}
mysql> INSERT INTO dt (id, name, score) VALUES (1, "Emily", 25), (2, "Benjamin", 35), (3, "Olivia", 28), (4, "Alexander", 60), (5, "Ava", 17);
Query OK, 5 rows affected (0.08 sec)
{'label':'txn_insert_b55db21aad7451b-b5b6c339704920c5', 'status':'PREPARE', 'txnId':'10013'}
mysql> INSERT INTO dt VALUES (6, "William", 69), (7, "Sophia", 32), (8, "James", 64), (9, "Emma", 37), (10, "Liam", 64);
Query OK, 5 rows affected (0.00 sec)
{'label':'txn_insert_b55db21aad7451b-b5b6c339704920c5', 'status':'PREPARE', 'txnId':'10013'}
mysql> COMMIT;
Query OK, 0 rows affected (1.02 sec)
{'label':'txn_insert_b55db21aad7451b-b5b6c339704920c5', 'status':'VISIBLE', 'txnId':'10013'}
This method not only achieves atomicity, but also in Doris, it enhances the writing performance of INSERT INTO VALUES
.
If user enables Group Commit
and transaction insert at the same time, the transaction insert will work.
See Insert Into for more details.
Multiple INSERT INTO SELECT
, UPDATE
, DELETE
for multiple tablesβ
Suppose there are 3 tables: dt1
, dt2
, dt3
, with the same schema as above, and the data in the tables are:
mysql> SELECT * FROM dt1;
+------+-----------+-------+
| id | name | score |
+------+-----------+-------+
| 1 | Emily | 25 |
| 2 | Benjamin | 35 |
| 3 | Olivia | 28 |
| 4 | Alexander | 60 |
| 5 | Ava | 17 |
+------+-----------+-------+
5 rows in set (0.04 sec)
mysql> SELECT * FROM dt2;
+------+---------+-------+
| id | name | score |
+------+---------+-------+
| 6 | William | 69 |
| 7 | Sophia | 32 |
| 8 | James | 64 |
| 9 | Emma | 37 |
| 10 | Liam | 64 |
+------+---------+-------+
5 rows in set (0.03 sec)
mysql> SELECT * FROM dt3;
Empty set (0.03 sec)
Do transaction load, write the data from dt1
and dt2
to dt3
, and update the scores in dt1
and delete the data in dt2
:
mysql> BEGIN;
Query OK, 0 rows affected (0.00 sec)
{'label':'txn_insert_442a6311f6c541ae-b57d7f00fa5db028', 'status':'PREPARE', 'txnId':''}
# ε―Όε
₯δ»»ε‘ηηΆζζ― PREPARE
mysql> INSERT INTO dt3 SELECT * FROM dt1;
Query OK, 5 rows affected (0.07 sec)
{'label':'txn_insert_442a6311f6c541ae-b57d7f00fa5db028', 'status':'PREPARE', 'txnId':'11024'}
mysql> INSERT INTO dt3 SELECT * FROM dt2;
Query OK, 5 rows affected (0.08 sec)
{'label':'txn_insert_442a6311f6c541ae-b57d7f00fa5db028', 'status':'PREPARE', 'txnId':'11025'}
mysql> UPDATE dt1 SET score = score + 10 WHERE id >= 4;
Query OK, 2 rows affected (0.07 sec)
{'label':'txn_insert_442a6311f6c541ae-b57d7f00fa5db028', 'status':'PREPARE', 'txnId':'11026'}
mysql> DELETE FROM dt2 WHERE id >= 9;
Query OK, 0 rows affected (0.01 sec)
{'label':'txn_insert_442a6311f6c541ae-b57d7f00fa5db028', 'status':'PREPARE', 'txnId':'11027'}
mysql> COMMIT;
Query OK, 0 rows affected (0.03 sec)
{'label':'txn_insert_442a6311f6c541ae-b57d7f00fa5db028', 'status':'VISIBLE', 'txnId':'11024'}
Select data:
# the score column of id >= 4 records is updated
mysql> SELECT * FROM dt1;
+------+-----------+-------+
| id | name | score |
+------+-----------+-------+
| 1 | Emily | 25 |
| 2 | Benjamin | 35 |
| 3 | Olivia | 28 |
| 4 | Alexander | 70 |
| 5 | Ava | 27 |
+------+-----------+-------+
5 rows in set (0.01 sec)
# the records of id >= 9 are deleted
mysql> SELECT * FROM dt2;
+------+---------+-------+
| id | name | score |
+------+---------+-------+
| 6 | William | 69 |
| 7 | Sophia | 32 |
| 8 | James | 64 |
+------+---------+-------+
3 rows in set (0.02 sec)
# the data of dt1 and dt2 is written to dt3
mysql> SELECT * FROM dt3;
+------+-----------+-------+
| id | name | score |
+------+-----------+-------+
| 1 | Emily | 25 |
| 2 | Benjamin | 35 |
| 3 | Olivia | 28 |
| 4 | Alexander | 60 |
| 5 | Ava | 17 |
| 6 | William | 69 |
| 7 | Sophia | 32 |
| 8 | James | 64 |
| 9 | Emma | 37 |
| 10 | Liam | 64 |
+------+-----------+-------+
10 rows in set (0.01 sec)
Isolation Levelβ
Doris provides the READ COMMITTED
isolation level. Please note the following:
-
In a transaction, each statement reads the data that was committed at the time the statement began executing:
timestamp | ------------ Session 1 ------------ | ------------ Session 2 ------------
t1 | BEGIN; |
t2 | # read n rows from dt1 table |
| INSERT INTO dt3 SELECT * FROM dt1; |
t3 | | # write 2 rows to dt1 table
| | INSERT INTO dt1 VALUES(...), (...);
t4 | # read n + 2 rows FROM dt1 table |
| INSERT INTO dt3 SELECT * FROM dt1; |
t5 | COMMIT; | -
In a transaction, each statement cannot read the modifications made by other statements within the same transactio:
Suppose
dt1
has 5 rows,dt2
has 5 rows,dt3
has 0 rows. And execute the following SQL:BEGIN;
# write 5 rows to dt2,
INSERT INTO dt2 SELECT * FROM dt1;
# write 5 rows to dt3, and cannot read the new data written to dt2 in the previous step
INSERT INTO dt3 SELECT * FROM dt2;
COMMIT;One example:
# create table and insert data
CREATE TABLE `dt1` (
`id` INT(11) NOT NULL,
`name` VARCHAR(50) NULL,
`score` INT(11) NULL
) ENGINE=OLAP
DUPLICATE KEY(`id`)
DISTRIBUTED BY HASH(`id`) BUCKETS 1
PROPERTIES (
"replication_num" = "1"
);
CREATE TABLE dt2 LIKE dt1;
CREATE TABLE dt3 LIKE dt1;
INSERT INTO dt1 VALUES (1, "Emily", 25), (2, "Benjamin", 35), (3, "Olivia", 28), (4, "Alexander", 60), (5, "Ava", 17);
INSERT INTO dt2 VALUES (6, "William", 69), (7, "Sophia", 32), (8, "James", 64), (9, "Emma", 37), (10, "Liam", 64);
# Do transaction write
BEGIN;
INSERT INTO dt2 SELECT * FROM dt1;
INSERT INTO dt3 SELECT * FROM dt2;
COMMIT;
# Select data
mysql> SELECT * FROM dt2;
+------+-----------+-------+
| id | name | score |
+------+-----------+-------+
| 6 | William | 69 |
| 7 | Sophia | 32 |
| 8 | James | 64 |
| 9 | Emma | 37 |
| 10 | Liam | 64 |
| 1 | Emily | 25 |
| 2 | Benjamin | 35 |
| 3 | Olivia | 28 |
| 4 | Alexander | 60 |
| 5 | Ava | 17 |
+------+-----------+-------+
10 rows in set (0.01 sec)
mysql> SELECT * FROM dt3;
+------+---------+-------+
| id | name | score |
+------+---------+-------+
| 6 | William | 69 |
| 7 | Sophia | 32 |
| 8 | James | 64 |
| 9 | Emma | 37 |
| 10 | Liam | 64 |
+------+---------+-------+
5 rows in set (0.01 sec)
Failed Statements Within a Transactionβ
When a statement within a transaction fails, that operation is rolled back. However, other statements within the transaction that have executed successfully are still able to either commit or rollback. Once the transaction is successfully committed, the modifications made by the successfully executed statements within the transaction are applied.
One example:
mysql> BEGIN;
Query OK, 0 rows affected (0.00 sec)
{'label':'txn_insert_c5940d31bf364f57-a48b628886415442', 'status':'PREPARE', 'txnId':''}
mysql> INSERT INTO dt3 SELECT * FROM dt1;
Query OK, 5 rows affected (0.07 sec)
{'label':'txn_insert_c5940d31bf364f57-a48b628886415442', 'status':'PREPARE', 'txnId':'11058'}
# The failed insert is rolled back
mysql> INSERT INTO dt3 SELECT * FROM dt2;
ERROR 5025 (HY000): Insert has filtered data in strict mode, tracking_url=http://172.21.16.12:9082/api/_load_error_log?file=__shard_3/error_log_insert_stmt_3d1fed266ce443f2-b54d2609c2ea6b11_3d1fed266ce443f2_b54d2609c2ea6b11
mysql> INSERT INTO dt3 SELECT * FROM dt2 WHERE id = 7;
Query OK, 0 rows affected (0.07 sec)
mysql> COMMIT;
Query OK, 0 rows affected (0.02 sec)
{'label':'txn_insert_c5940d31bf364f57-a48b628886415442', 'status':'VISIBLE', 'txnId':'11058'}
Select data:
# The data in dt1 is written to dt3, the data with id = 7 in dt2 is written successfully, and the other data is written failed
mysql> SELECT * FROM dt3;
+------+----------+-------+
| id | name | score |
+------+----------+-------+
| 1 | Emily | 25 |
| 2 | Benjamin | 35 |
| 3 | Olivia | 28 |
| 4 | Alexande | 60 |
| 5 | Ava | 17 |
| 7 | Sophia | 32 |
+------+----------+-------+
6 rows in set (0.01 sec)
QAβ
-
Writing to multiple tables must belong to the same Database; otherwise, you will encounter the error
Transaction insert must be in the same database
-
Mixing the two transaction load of
INSERT INTO SELECT
,UPDATE
,DELETE
andINSERT INTO VALUES
is not allowed; otherwise, you will encounter the errorTransaction insert can not insert into values and insert into select at the same time
. -
Delete Command supports delete by specifying a filter predicate or using clause, to guarantee the isolation, currently only support that, the delete operations must before the insert operations for one table in one transaction, otherwise, you will encounter the error
Can not delete because there is a insert operation for the same table
. -
If the time-consuming from
BEGIN
statement exceeds the timeout configured in Doris, the transaction will be rolled back. Currently, the timeout uses the maximum value of session variablesinsert_timeout
andquery_timeout
. -
When using JDBC to connect to Doris for transaction operations, please add
useLocalSessionState=true
in the JDBC URL; otherwise, you may encounter the errorThis is in a transaction, only insert, update, delete, commit, rollback is acceptable
. -
In cloud mode, transaction load does not support
merge on write
unique tables, otherwise, you will encounter the errorTransaction load is not supported for merge on write unique keys table in cloud mode
.
Stream Load 2PCβ
1. Enable two-phase commit by setting two_phase_commit:true
in the HTTP Header.
curl --location-trusted -u user:passwd -H "two_phase_commit:true" -T test.txt http://fe_host:http_port/api/{db}/{table}/_stream_load
{
"TxnId": 18036,
"Label": "55c8ffc9-1c40-4d51-b75e-f2265b3602ef",
"TwoPhaseCommit": "true",
"Status": "Success",
"Message": "OK",
"NumberTotalRows": 100,
"NumberLoadedRows": 100,
"NumberFilteredRows": 0,
"NumberUnselectedRows": 0,
"LoadBytes": 1031,
"LoadTimeMs": 77,
"BeginTxnTimeMs": 1,
"StreamLoadPutTimeMs": 1,
"ReadDataTimeMs": 0,
"WriteDataTimeMs": 58,
"CommitAndPublishTimeMs": 0
}
2. Trigger the commit operation for a transaction (can be sent to FE or BE).
-
Specify the transaction using the Transaction ID:
curl -X PUT --location-trusted -u user:passwd -H "txn_id:18036" -H "txn_operation:commit" http://fe_host:http_port/api/{db}/{table}/_stream_load_2pc
{
"status": "Success",
"msg": "transaction [18036] commit successfully."
} -
Specify the transaction using the label:
curl -X PUT --location-trusted -u user:passwd -H "label:55c8ffc9-1c40-4d51-b75e-f2265b3602ef" -H "txn_operation:commit" http://fe_host:http_port/api/{db}/{table}/_stream_load_2pc
{
"status": "Success",
"msg": "label [55c8ffc9-1c40-4d51-b75e-f2265b3602ef] commit successfully."
}
3. Trigger the abort operation for a transaction (can be sent to FE or BE).
-
Specify the transaction using the Transaction ID:
curl -X PUT --location-trusted -u user:passwd -H "txn_id:18037" -H "txn_operation:abort" http://fe_host:http_port/api/{db}/{table}/_stream_load_2pc
{
"status": "Success",
"msg": "transaction [18037] abort successfully."
} -
Specify the transaction using the label:
curl -X PUT --location-trusted -u user:passwd -H "label:55c8ffc9-1c40-4d51-b75e-f2265b3602ef" -H "txn_operation:abort" http://fe_host:http_port/api/{db}/{table}/_stream_load_2pc
{
"status": "Success",
"msg": "label [55c8ffc9-1c40-4d51-b75e-f2265b3602ef] abort successfully."
}
Broker Load into muti tables with a transactionβ
All Broker Load tasks are atomic and ensure atomicity even when loading multiple tables within the same task. The Label mechanism can be used to ensure data load without loss or duplication.
The following example demonstrates loading data from HDFS by using wildcard patterns to match two sets of files and load them into two different tables.
LOAD LABEL example_db.label2
(
DATA INFILE("hdfs://hdfs_host:hdfs_port/input/file-10*")
INTO TABLE `my_table1`
PARTITION (p1)
COLUMNS TERMINATED BY ","
(k1, tmp_k2, tmp_k3)
SET (
k2 = tmp_k2 + 1,
k3 = tmp_k3 + 1
)
DATA INFILE("hdfs://hdfs_host:hdfs_port/input/file-20*")
INTO TABLE `my_table2`
COLUMNS TERMINATED BY ","
(k1, k2, k3)
)
WITH BROKER hdfs
(
"username"="hdfs_user",
"password"="hdfs_password"
);
The wildcard pattern is used to match and load two sets of files, file-10*
and file-20*
, into my_table1
and my_table2
respectively. In the case of my_table1
, the load is specified to the p1
partition, and the values of thesecond and third columns in the source file are incremented by 1 before being loaded.