You can do everything you need to with SQL triggers. The following SQL adds a trigger on
tablename.table_id to automatically create the primary key UUID when inserting, then stores the newly created ID into an SQL variable for retrieval later:
CREATE TRIGGER `tablename_newid`
AFTER INSERT ON `tablename`
FOR EACH ROW
IF ASCII(NEW.table_id) = 0 THEN
SET NEW.table_id = UNHEX(REPLACE(UUID(),'-',''));
SET @last_uuid = NEW.table_id;
As a bonus, it inserts the UUID in binary form to a binary(16) field to save storage space and greatly increase query speed.
edit: the trigger should check for an existing column value before inserting its own UUID in order to mimic the ability to provide values for table primary keys in MySQL - without this, any values passed in will always be overridden by the trigger. The example has been updated to use
ASCII() = 0 to check for the existence of the primary key value in the INSERT, which will detect empty string values for a binary field.
edit 2: after a comment here it has since been pointed out to me that using
BEFORE INSERT has the effect of setting the
@last_uuid variable even if the row insert fails. I have updated my answer to use
AFTER INSERT - whilst I feel this is a totally fine approach under general circumstances it may have issues with row replication under clustered or replicated databases. If anyone knows, I would love to as well!
To read the new row's insert ID back out, just run
When querying and reading such binary values, the MySQL functions
UNHEX() will be very helpful, as will writing your query values in hex notation (preceded by
0x). The php-side code for your original answer, given this type of trigger applied to table1, would be:
// insert row
$sql = "INSERT INTO table1(text) VALUES ('some text')";
// get last inserted UUID
$sql = "SELECT HEX(@last_uuid)";
$result = mysql_query($sql);
$row = mysql_fetch_row($result);
$id = $row;
// perform a query using said ID
mysql_query("SELECT FROM table1 WHERE id = 0x" . $id);
Following up in response to @ina's comment:
A UUID is not a string, even if MySQL chooses to represent it as such. It's binary data in its raw form, and those dashes are just MySQL's friendly way of representing it to you.
The most efficient storage for a UUID is to create it as
UNHEX(REPLACE(UUID(),'-','')) - this will remove that formatting and convert it back to binary data. Those functions will make the original insertion slower, but all following comparisons you do on that key or column will be much faster on a 16-byte binary field than a 36-character string.
For one, character data requires parsing and localisation. Any strings coming in to the query engine are generally being collated automatically against the character set of the database, and some APIs (wordpress comes to mind) even run
CONVERT() on all string data before querying. Binary data doesn't have this overhead. For the other, your
char(36) is actually allocating 36 characters, which means (if your database is UTF-8) each character could be as long as 3 or 4 bytes depending on the version of MySQL you are using. So a
char(36) can range anywhere from 36 bytes (if it consists entirely of low-ASCII characters) to 144 if consisting entirely of high-order UTF8 characters. This is much larger than the 16 bytes we have allocated for our binary field.
Any logic performed on this data can be done with
UNHEX(), but is better accomplished by simply escaping data in queries as hex, prefixed with
0x. This is just as fast as reading a string, gets converted to binary on the fly and directly assigned to the query or cell in question. Very fast.
Reading data out is slightly slower - you have to call
HEX() on all binary data read out of a query to get it in a useful format if your client API doesn't deal well with binary data (PHP in paricular will usually determine that binary strings
=== null and will break them if manipulated without first calling
base64_encode() or similar) - but this overhead is about as minimal as character collation and more importantly is only being called on the actual cells
SELECTed, not all cells involved in the internal computations of a query result.
So of course, all these small speed increases are very minimal and other areas result in small decreases - but when you add them all up
binary still comes out on top, and when you consider use cases and the general 'reads > writes' principle it really shines.
... and that's why
binary(16) is better than