TiCDC Open Protocol

TiCDC Open Protocol is a row-level data change notification protocol that provides data sources for monitoring, caching, full-text indexing, analysis engines, and primary-secondary replication between different databases. TiCDC complies with TiCDC Open Protocol and replicates data changes of TiDB to third-party data medium such as MQ (Message Queue).

TiCDC Open Protocol uses Event as the basic unit to replicate data change events to the downstream. The Event is divided into three categories:

Row Changed Event: Represents the data change in a row. When a row is changed, this Event is sent and contains information about the changed row.
DDL Event: Represents the DDL change. This Event is sent after a DDL statement is successfully executed in the upstream. The DDL Event is broadcasted to every MQ Partition.
Resolved Event: Represents a special time point before which the Event received is complete.

Restrictions

In most cases, the Row Changed Event of a version is sent only once, but in special situations such as node failure and network partition, the Row Changed Event of the same version might be sent multiple times.
On the same table, the Row Changed Events of each version which is first sent are incremented in the order of timestamps (TS) in the Event stream.
Resolved Events are periodically broadcasted to each MQ Partition. The Resolved Event means that any Event with a TS earlier than Resolved Event TS has been sent to the downstream.
DDL Events are broadcasted to each MQ Partition.
Multiple Row Changed Events of a row are sent to the same MQ Partition.

Message format

A Message contains one or more Events, arranged in the following format:

Key:

Offset(Byte)	0~7	8~15	16~(15+length1)	...	...
Parameter	Protocol version	Length1	Event Key1	LengthN	Event KeyN

Value:

Offset(Byte)	0~7	8~(7+length1)	...	...
Parameter	Length1	Event Value1	LengthN	Event ValueN

LengthN represents the length of the Nth key/value.
The length and protocol version are the big-endian int64 type.
The version of the current protocol is 1.

Event format

This section introduces the formats of Row Changed Event, DDL Event, and Resolved Event.

Row Changed Event

Key:

{
    "ts":,
    "scm":,
    "tbl":,
    "t":1
}
Parameter Type Description
TS Number The timestamp of the transaction that causes the row change.
Schema Name String The name of the schema where the row is in.
Table Name String The name of the table where the row is in.

Parameter	Type	Description
TS	Number	The timestamp of the transaction that causes the row change.
Schema Name	String	The name of the schema where the row is in.
Table Name	String	The name of the table where the row is in.

Value:

Insert event. The newly added row data is output.

{
    "u":{
        :{
            "t":,
            "h":,
            "f":,
            "v":
        },
        :{
            "t":,
            "h":,
            "f":,
            "v":
        }
    }
}

Update event. The newly added row data ("u") and the row data before the update ("p") are output. The latter ("p") is output only when the old value feature is enabled.

{
    "u":{
        :{
            "t":,
            "h":,
            "f":,
            "v":
        },
        :{
            "t":,
            "h":,
            "f":,
            "v":
        }
    },
    "p":{
        :{
            "t":,
            "h":,
            "f":,
            "v":
        },
        :{
            "t":,
            "h":,
            "f":,
            "v":
        }
    }
}

Delete event. The deleted row data is output. When the old value feature is enabled, the Delete event includes all the columns of the deleted row data; when this feature is disabled, the Delete event only includes the HandleKey column.

{
    "d":{
        :{
            "t":,
            "h":,
            "f":,
            "v":
        },
        :{
            "t":,
            "h":,
            "f":,
            "v":
        }
    }
}

Parameter	Type	Description
Column Name	String	The column name.
Column Type	Number	The column type. For details, see Column Type Code.
Where Handle	Boolean	Determines whether this column can be the filter condition of the `Where` clause. When this column is unique on the table, `Where Handle` is `true`.
Flag	Number	The bit flags of columns. For details, see Bit flags of columns.
Column Value	Any	The Column value.

`DDL Event`

Key:

{
    "ts":,
    "scm":,
    "tbl":,
    "t":2
}
Parameter Type Description
TS Number The timestamp of the transaction that performs the DDL change.
Schema Name String The schema name of the DDL change, which might be an empty string.
Table Name String The table name of the DDL change, which might be am empty string.

Value:
```
{
    "q":,
    "t":
}
```
Parameter Type Description
DDL Query String DDL Query SQL
DDL Type String The DDL type. For details, see DDL Type Code.

Parameter	Type	Description
TS	Number	The timestamp of the transaction that performs the DDL change.
Schema Name	String	The schema name of the DDL change, which might be an empty string.
Table Name	String	The table name of the DDL change, which might be am empty string.

Parameter	Type	Description
DDL Query	String	DDL Query SQL
DDL Type	String	The DDL type. For details, see DDL Type Code.

`Resolved Event`

Key:
```
{
    "ts":,
    "t":3
}
```
Parameter Type Description
TS Number The Resolved timestamp. Any TS earlier than this Event has been sent.
Value: None

Parameter	Type	Description
TS	Number	The Resolved timestamp. Any TS earlier than this Event has been sent.

`Examples of the Event stream output`

This section shows and displays the output logs of the Event stream.

Suppose that you execute the following SQL statement in the upstream and the MQ Partition number is 2:

CREATE TABLE test.t1(id int primary key, val varchar(16));

From the following Log 1 and Log 3, you can see that the DDL Event is broadcasted to all MQ Partitions, and that the Resolved Event is periodically broadcasted to each MQ Partition.

1. [partition=0] [key="{\"ts\":415508856908021766,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":2}"] [value="{\"q\":\"CREATE TABLE test.t1(id int primary key, val varchar(16))\",\"t\":3}"]
2. [partition=0] [key="{\"ts\":415508856908021766,\"t\":3}"] [value=]
3. [partition=1] [key="{\"ts\":415508856908021766,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":2}"] [value="{\"q\":\"CREATE TABLE test.t1(id int primary key, val varchar(16))\",\"t\":3}"]
4. [partition=1] [key="{\"ts\":415508856908021766,\"t\":3}"] [value=]

Execute the following SQL statements in the upstream:

BEGIN;
INSERT INTO test.t1(id, val) VALUES (1, 'aa');
INSERT INTO test.t1(id, val) VALUES (2, 'aa');
UPDATE test.t1 SET val = 'bb' WHERE id = 2;
INSERT INTO test.t1(id, val) VALUES (3, 'cc');
COMMIT;

From the following Log 5 and Log 6, you can see that Row Changed Events on the same table might be sent to different partitions based on the primary key, but changes to the same row are sent to the same partition so that the downstream can easily process the Event concurrently.
From Log 6, multiple changes to the same row in a transaction are only sent in one Row Changed Event.
Log 8 is a repeated event of Log 7. Row Changed Event might be repeated, but the first Event of each version is sent orderly.

5. [partition=0] [key="{\"ts\":415508878783938562,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":1}"] [value="{\"u\":{\"id\":{\"t\":3,\"h\":true,\"v\":1},\"val\":{\"t\":15,\"v\":\"YWE=\"}}}"]
6. [partition=1] [key="{\"ts\":415508878783938562,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":1}"] [value="{\"u\":{\"id\":{\"t\":3,\"h\":true,\"v\":2},\"val\":{\"t\":15,\"v\":\"YmI=\"}}}"]
7. [partition=0] [key="{\"ts\":415508878783938562,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":1}"] [value="{\"u\":{\"id\":{\"t\":3,\"h\":true,\"v\":3},\"val\":{\"t\":15,\"v\":\"Y2M=\"}}}"]
8. [partition=0] [key="{\"ts\":415508878783938562,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":1}"] [value="{\"u\":{\"id\":{\"t\":3,\"h\":true,\"v\":3},\"val\":{\"t\":15,\"v\":\"Y2M=\"}}}"]

Execute the following SQL statements in the upstream:

BEGIN;
DELETE FROM test.t1 WHERE id = 1;
UPDATE test.t1 SET val = 'dd' WHERE id = 3;
UPDATE test.t1 SET id = 4, val = 'ee' WHERE id = 2;
COMMIT;

Log 9 is the Row Changed Event of the Delete type. This type of Event only contains primary key columns or unique index columns.
Log 13 and Log 14 are Resolved Events. The Resolved Event means that in this Partition, any events smaller than the Resolved TS (including Row Changed Event and DDL Event) have been sent.

9. [partition=0] [key="{\"ts\":415508881418485761,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":1}"] [value="{\"d\":{\"id\":{\"t\":3,\"h\":true,\"v\":1}}}"]
10. [partition=1] [key="{\"ts\":415508881418485761,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":1}"] [value="{\"d\":{\"id\":{\"t\":3,\"h\":true,\"v\":2}}}"]
11. [partition=0] [key="{\"ts\":415508881418485761,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":1}"] [value="{\"u\":{\"id\":{\"t\":3,\"h\":true,\"v\":3},\"val\":{\"t\":15,\"v\":\"ZGQ=\"}}}"]
12. [partition=0] [key="{\"ts\":415508881418485761,\"scm\":\"test\",\"tbl\":\"t1\",\"t\":1}"] [value="{\"u\":{\"id\":{\"t\":3,\"h\":true,\"v\":4},\"val\":{\"t\":15,\"v\":\"ZWU=\"}}}"]
13. [partition=0] [key="{\"ts\":415508881038376963,\"t\":3}"] [value=]
14. [partition=1] [key="{\"ts\":415508881038376963,\"t\":3}"] [value=]

`Protocol parsing for consumers`

Currently, TiCDC does not provide the standard parsing library for TiCDC Open Protocol, but the Golang version and Java version of parsing examples are provided. You can refer to the data format provided in this document and the following examples to implement the protocol parsing for consumers.

Golang examples
Java examples

`Column type code`

Column Type Code represents the column data type of the Row Changed Event.

Type	Code	Output Example	Description
TINYINT/BOOLEAN	1	{"t":1,"v":1}
SMALLINT	2	{"t":2,"v":1}
INT	3	{"t":3,"v":123}
FLOAT	4	{"t":4,"v":153.123}
DOUBLE	5	{"t":5,"v":153.123}
NULL	6	{"t":6,"v":null}
TIMESTAMP	7	{"t":7,"v":"1973-12-30 15:30:00"}
BIGINT	8	{"t":8,"v":123}
MEDIUMINT	9	{"t":9,"v":123}
DATE	10/14	{"t":10,"v":"2000-01-01"}
TIME	11	{"t":11,"v":"23:59:59"}
DATETIME	12	{"t":12,"v":"2015-12-20 23:58:58"}
YEAR	13	{"t":13,"v":1970}
VARCHAR/VARBINARY	15/253	{"t":15,"v":"test"} / {"t":15,"v":"\\x89PNG\\r\\n\\x1a\\n"}	The value is encoded in UTF-8. When the upstream type is VARBINARY, invisible characters are escaped.
BIT	16	{"t":16,"v":81}
JSON	245	{"t":245,"v":"{\"key1\": \"value1\"}"}
DECIMAL	246	{"t":246,"v":"129012.1230000"}
ENUM	247	{"t":247,"v":1}
SET	248	{"t":248,"v":3}
TINYTEXT/TINYBLOB	249	{"t":249,"v":"5rWL6K+VdGV4dA=="}	The value is encoded in Base64.
MEDIUMTEXT/MEDIUMBLOB	250	{"t":250,"v":"5rWL6K+VdGV4dA=="}	The value is encoded in Base64.
LONGTEXT/LONGBLOB	251	{"t":251,"v":"5rWL6K+VdGV4dA=="}	The value is encoded in Base64.
TEXT/BLOB	252	{"t":252,"v":"5rWL6K+VdGV4dA=="}	The value is encoded in Base64.
CHAR/BINARY	254	{"t":254,"v":"test"} / {"t":254,"v":"\\x89PNG\\r\\n\\x1a\\n"}	The value is encoded in UTF-8. When the upstream type is BINARY, invisible characters are escaped.
GEOMETRY	255		Unsupported

`DDL Type Code`

DDL Type Code represents the DDL statement type of the DDL Event.

Type	Code
Create Schema	1
Drop Schema	2
Create Table	3
Drop Table	4
Add Column	5
Drop Column	6
Add Index	7
Drop Index	8
Add Foreign Key	9
Drop Foreign Key	10
Truncate Table	11
Modify Column	12
Rebase Auto ID	13
Rename Table	14
Set Default Value	15
Shard RowID	16
Modify Table Comment	17
Rename Index	18
Add Table Partition	19
Drop Table Partition	20
Create View	21
Modify Table Charset And Collate	22
Truncate Table Partition	23
Drop View	24
Recover Table	25
Modify Schema Charset And Collate	26
Lock Table	27
Unlock Table	28
Repair Table	29
Set TiFlash Replica	30
Update TiFlash Replica Status	31
Add Primary Key	32
Drop Primary Key	33
Create Sequence	34
Alter Sequence	35
Drop Sequence	36

`Bit flags of columns`

The bit flags represent specific attributes of columns.

Bit	Value	Name	Description
1	0x01	BinaryFlag	Whether the column is a binary-encoded column.
2	0x02	HandleKeyFlag	Whether the column is a Handle index column.
3	0x04	GeneratedColumnFlag	Whether the column is a generated column.
4	0x08	PrimaryKeyFlag	Whether the column is a primary key column.
5	0x10	UniqueKeyFlag	Whether the column is a unique index column.
6	0x20	MultipleKeyFlag	Whether the column is a composite index column.
7	0x40	NullableFlag	Whether the column is a nullable column.
8	0x80	UnsignedFlag	Whether the column is an unsigned column.

Example:

If the value of a column flag is 85, the column is a nullable column, a unique index column, a generated column, and a binary-encoded column.

85 == 0b_101_0101
   == NullableFlag | UniqueKeyFlag | GeneratedColumnFlag | BinaryFlag

If the value of a column is 46, the column is a composite index column, a primary key column, a generated column, and a Handle key column.

46 == 0b_010_1110
   == MultipleKeyFlag | PrimaryKeyFlag | GeneratedColumnFlag | HandleKeyFlag

Note

BinaryFlag is meaningful only when the column type is BLOB/TEXT (including TINYBLOB/TINYTEXT and BINARY/CHAR). When the upstream column is the BLOB type, the BinaryFlag value is set to 1. When the upstream column is the TEXT type, the BinaryFlag value is set to 0.
To replicate a table from the upstream, TiCDC selects a valid index as the Handle index. The HandleKeyFlag value of the Handle index column is set to 1.

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