The ENUM and SET values read from the binlog contain the indexes of the options that are included in the value, but this doesn't compared with the string values returned by MySQL and JDBC that contain the comma-separated options. With this change, the values read from the binlog will also be comma-separated strings.
Rewrote how the MySQL connector converts temporal values to use schemas with names that identify the semantic
type of temporal value, and customized how the MySQL binlog client library creates Java object values from the
raw binlog events.
Several new "semantic" schema types were defined:
* `io.debezium.time.Year` represents a year number as an INT32 value (e.g., 2016, -345, etc.).
* `io.debezium.time.Date` represents a date by storing the epoch seconds (that is, the number of seconds past the epoch) as an INT64 value.
* `io.debezium.time.Time` represents a time by storing the milliseconds past midnight as an INT32 value.
* `io.debezium.time.MicroTime` represents a time by storing the microsconds past midnight as an INT32 value.
* `io.debezium.time.NanoTime` represents a time by storing the nanoseconds past midnight as an INT32 value.
* `io.debezium.time.Timestamp` represents a date and time (without timezone information) by storing the milliseconds past epoch as an INT64 value.
* `io.debezium.time.MicroTimestamp` represents a date and time (without timezone information) by storing the microseconds past epoch as an INT64 value.
* `io.debezium.time.NanoTimestamp` represents a date and time (without timezone information) by storing the nanoseconds past epoch as an INT64 value.
* `io.debezium.time.ZonedTime` represents a time with timezone and optional fractions of a second (but no date) by storing the ISO8601 form as a STRING value (e.g., `10:15:30+01:00`)
* `io.debezium.time.ZonedTimestamp` represents a date and time with timezone and optional fractions of a second by storing the ISO8601 form as a STRING value (e.g., `2011-12-03T10:15:30.030431+01:00`)
This range of semantic types allows for a far more accurate representation in the events of the temporal values stored within the database. The MySQL connector chooses the semantic type based upon the precision of the MySQL type (e.g., `TIMESTAMP(6)` will be represented with `io.debezium.time.MicroTimestamp`, whereas `TIMESTAMP(3)` will be represented with `io.debezium.time.Timestamp`). This ensures that the events do not lose precision and that the semantics of the database column values are retained in the events even though the values are represented with primitive values.
Obviously these Kafka Connect schema representations are different and more precise than the built-in `org.apache.kafka.connect.data.Date`, `org.apache.kafka.connect.data.Time`, and `org.apache.kafka.connect.data.Timestamp` logical types provided by Kafka Connect and used by the MySQL connector in all 0.2.x and 0.1.x versions. Migration to the new MySQL connector should be possible, although consumers may still need to know about these types to properly handle temporal values and the correct precision (i.e., consumers can just assume all date INT64 values represent milliseconds).
The MySQL binlog client library converted the raw binary event information to JDBC types using a local Calendar instance, which obviously incorporates the local timezone and cannot retain more than millisecond precision. This change extends the library's deserializers to instead use the Java 8 `javax.time` classes and to retain the exact semantics of the database values and to not lose any precisions (since the `javax.time` classes have nanosecond precision).
The same logic is also used to convert the JDBC values obtained during a snapshot from the MySQL Connect/J JDBC driver. The latter has a few quirks, such as not returning any fractional seconds for `TIME` columns, even though `java.sql.Time` can store up to milliseconds.
Most of the logic of the conversions of values and mapping to Kafka Connect schemas is handled in the new `JdbcValueConverters`, which was extracted from the existing `TableSchemaBuilder`. The MySQL connector reuses and actually extends the `JdbcValueConverters` class with its own `MySqlValueConverters` class that also adds support for MySQL-specific types such as `YEAR`. Other connectors whose values are based on JDBC types should be able to reuse and/or extend the `JdbcValueConverters` class.
Integration tests that deal with temporal types were modified to use proper expected values and comparisons.
By default the MySQL JDBC driver will put the entire result set into memory, which obviously doesn't work for tables of even moderate sizes. This change adds support for streaming rows in result sets when the tables have more than a configurable number of rows (defaults to 1,000).
This posed a problem for how we were previously finding the last row in the last table; the MySQL driver does not support `ResultSet.isLast()` on result sets that are streamed. Instead, this commit wraps the consumer to which the snapshot reader writes all source records, with a consumer that buffers the last record. When the snapshot completes, the offset is updated (denoting the end of the snapshot) and set on the last buffered record before that record is flushed to the normal consumer. This should add minimal overhead while simplifying the logic to ensure the last source record has the updated offset.
This also improves the log output of the snapshot process.
The mysql:5.7 docker image changed its output to be more like mysql/mysql-server:5.7, and this broke our build because of what our build is looking for while waiting to for the server to completely intialize. Simply changing the pattern corrects the problem.
* fixes a java.sql.Date conversion test to take into account zone offsets
* makes sure the ZK DB is closed during testing, otherwise file handles may leak and cause test failures