Table of Contents
This chapter describes a lot of things that you need to know when
working on the MySQL code. If you plan to contribute to MySQL
development, want to have access to the bleeding-edge versions of
the code, or just want to keep track of development, follow the
instructions in Section 2.9.3, “Installing from the Development Source Tree”. If you
are interested in MySQL internals, you should also subscribe to
our internals
mailing list. This list has
relatively low traffic. For details on how to subscribe, please
see Section 1.6.1, “MySQL Mailing Lists”. All developers at MySQL AB
are on the internals
list and we help other
people who are working on the MySQL code. Feel free to use this
list both to ask questions about the code and to send patches that
you would like to contribute to the MySQL project!
The MySQL server creates the following threads:
Connection manager threads handle client connection requests on the network interfaces that the server listens to. On all platforms, one manager thread handles TCP/IP connection requests. On Unix, this manager thread also handles Unix socket file connection requests. On Windows, a manager thread handles shared-memory connection requests, and another handles named-pipe connection requests. The server does not create threads to handle interfaces that it does not listen to. For example, a Windows server that does not have support for named-pipe connections enabled does not create a thread to handle them.
Connection manager threads associate each client connection with a thread dedicated to it that handles authentication and request processing for that connection. Manager threads create a new thread when necessary but try to avoid doing so by consulting the thread cache first to see whether it contains a thread that can be used for the connection. When a connection ends, its thread is returned to the thread cache if the cache is not full.
For information about tuning the parameters that control thread resources, see Section 7.5.6, “How MySQL Uses Threads for Client Connections”.
On a master replication server, connections from slave servers are handled like client connections: There is one thread per connected slave.
On a slave replication server, an I/O thread is started to connect to the master server and read updates from it. An SQL thread is started to apply updates read from the master. These two threads run independently and can be started and stopped independently.
A signal thread handles all signals. This thread also
normally handles alarms and calls
process_alarm()
to force timeouts on
connections that have been idle too long.
If InnoDB
is used, there will be 4
additional threads by default. Those are file I/O threads,
controlled by the innodb_file_io_threads
parameter. See Section 13.2.5, “InnoDB
Startup Options and System Variables”.
If mysqld is compiled with
-DUSE_ALARM_THREAD
, a dedicated thread that
handles alarms is created. This is only used on some systems
where there are problems with sigwait()
or if you want to use the thr_alarm()
code in your application without a dedicated signal handling
thread.
If the server is started with the
--flush_time=
option, a dedicated thread is created to flush all tables
every val
val
seconds.
Each table for which INSERT DELAYED
statements are issued gets its own thread. See
Section 12.2.4.2, “INSERT DELAYED
Syntax”.
mysqladmin processlist only shows the
connection, INSERT DELAYED
, and replication
threads.
MySQL Enterprise For expert advice on thread management subscribe to the MySQL Enterprise Monitor. For more information, see http://www.mysql.com/products/enterprise/advisors.html.
The test system that is included in Unix source and binary distributions makes it possible for users and developers to perform regression tests on the MySQL code. These tests can be run on Unix.
The current set of test cases doesn't test everything in MySQL, but it should catch most obvious bugs in the SQL processing code, operating system or library issues, and is quite thorough in testing replication. Our goal is to have the tests cover 100% of the code. We welcome contributions to our test suite. You may especially want to contribute tests that examine the functionality critical to your system because this ensures that all future MySQL releases work well with your applications.
The test system consists of a test language interpreter
(mysqltest), a Perl script to run all tests
(mysql-test-run.pl), the actual test cases
written in a special test language, and their expected results.
To run the test suite on your system after a build, type
make test from the source root directory, or
change location to the mysql-test
directory
and type ./mysql-test-run.pl. If you have
installed a binary distribution, change location to the
mysql-test
directory under the installation
root directory (for example,
/usr/local/mysql/mysql-test
), and run
./mysql-test-run.pl. All tests should
succeed. If any do not, feel free to try to find out why and
report the problem if it indicates a bug in MySQL. See
Section 1.7, “How to Report Bugs or Problems”.
If one test fails, you should run
mysql-test-run.pl with the
--force
option to check whether any other tests
fail.
If you have a copy of mysqld running on the
machine where you want to run the test suite, you do not have to
stop it, as long as it is not using ports
9306
or 9307
. If either of
those ports is taken, you should set the
MTR_BUILD_THREAD
environment variable to an
appropriate value, and the test suite will use a different set
of ports for master, slave, NDB, and Instance Manager). For
example:
shell> export MTR_BUILD_THREAD=31 shell> ./mysql-test-run.pl [options
] [test_name
]
In the mysql-test
directory, you can run an
individual test case with ./mysql-test-run.pl
test_name
.
You can use the mysqltest language to write your own test cases. This is documented in the MySQL Test Framework manual, available at http://dev.mysql.com/doc/.
If you have a question about the test suite, or have a test case
to contribute, send an email message to the MySQL
internals
mailing list. See
Section 1.6.1, “MySQL Mailing Lists”. This list does not accept
attachments, so you should FTP all the relevant files to:
ftp://ftp.mysql.com/pub/mysql/upload/
Before MySQL 4.1, the mysql-test-run shell
script is used instead of the
mysql-test-run.pl Perl script.
mysql-test-run does not try to run its own
server by default but tries to use your currently running
server. To override this and cause
mysql-test-run to start its own server, run
it with the --local
option.
There are two ways to add new functions to MySQL:
You can add functions through the user-defined function (UDF)
interface. User-defined functions are compiled as object files
and then added to and removed from the server dynamically
using the CREATE FUNCTION
and DROP
FUNCTION
statements. See
Section 19.2.2, “CREATE FUNCTION
Syntax”.
You can add functions as native (built-in) MySQL functions. Native functions are compiled into the mysqld server and become available on a permanent basis.
Each method of creating compiled functions has advantages and disadvantages:
If you write user-defined functions, you must install object files in addition to the server itself. If you compile your function into the server, you don't need to do that.
Native functions require you to modify a source distribution. UDFs do not. You can add UDFs to a binary MySQL distribution. No access to MySQL source is necessary.
If you upgrade your MySQL distribution, you can continue to
use your previously installed UDFs, unless you upgrade to a
newer version for which the UDF interface changes. (An
incompatible change occurred in MySQL 4.1.1 for aggregate
functions. A function named xxx_clear()
must be defined rather than xxx_reset()
.)
For native functions, you must repeat your modifications each
time you upgrade.
Whichever method you use to add new functions, they can be invoked
in SQL statements just like native functions such as
ABS()
or
SOUNDEX()
.
See Section 8.2.3, “Function Name Parsing and Resolution”, for the rules describing how the server interprets references to different kinds of functions.
The following sections describe features of the UDF interface, provide instructions for writing UDFs, discuss security precautions that MySQL takes to prevent UDF misuse, and describe how to add native MySQL functions.
For example source code that illustrates how to write UDFs, take a
look at the sql/udf_example.cc
file that is
provided in MySQL source distributions.
The MySQL interface for user-defined functions provides the following features and capabilities:
Functions can return string, integer, or real values and can accept arguments of those same types.
You can define simple functions that operate on a single row at a time, or aggregate functions that operate on groups of rows.
Information is provided to functions that enables them to check the number and types of the arguments passed to them.
You can tell MySQL to coerce arguments to a given type before passing them to a function.
You can indicate that a function returns
NULL
or that an error occurred.
CREATE [AGGREGATE] FUNCTIONfunction_name
RETURNS {STRING|INTEGER|REAL} SONAMEshared_library_name
A user-defined function (UDF) is a way to extend MySQL with a
new function that works like a native (built-in) MySQL function
such as ABS()
or
CONCAT()
.
function_name
is the name that should
be used in SQL statements to invoke the function. The
RETURNS
clause indicates the type of the
function's return value.
shared_library_name
is the basename
of the shared object file that contains the code that implements
the function. The file must be located in a directory that is
searched by your system's dynamic linker.
To create a function, you must have the
INSERT
and privilege for the
mysql
database. This is necessary because
CREATE FUNCTION
adds a row to the
mysql.func
system table that records the
function's name, type, and shared library name. If you do not
have this table, you should run the
mysql_fix_privilege_tables script to create
it. See Section 4.4.5, “mysql_fix_privilege_tables — Upgrade MySQL System Tables”.
An active function is one that has been loaded with
CREATE FUNCTION
and not removed with
DROP FUNCTION
. All active functions are
reloaded each time the server starts, unless you start
mysqld with the
--skip-grant-tables
option. In this case, UDF
initialization is skipped and UDFs are unavailable.
For instructions on writing user-defined functions, see Section 19.2.4, “Adding a New User-Defined Function”. For the UDF mechanism to work, functions must be written in C or C++ (or another language that can use C calling conventions), your operating system must support dynamic loading and you must have compiled mysqld dynamically (not statically).
AGGREGATE
is a new option for MySQL 3.23. An
AGGREGATE
function works exactly like a
native MySQL aggregate (summary) function such as
SUM
or
COUNT()
. For
AGGREGATE
to work, your
mysql.func
table must contain a
type
column. If your
mysql.func
table does not have this column,
you should run the mysql_fix_privilege_tables
script to create it.
To upgrade the shared library associated with a UDF, issue a
DROP FUNCTION
statement, upgrade the shared
library, and then issue a CREATE FUNCTION
statement. If you upgrade the shared library first and then
use DROP FUNCTION
, the server may crash.
DROP FUNCTION function_name
This statement drops the user-defined function (UDF) named
function_name
.
To drop a function, you must have the DELETE
privilege for the mysql
database. This is
because DROP FUNCTION
removes a row from the
mysql.func
system table that records the
function's name, type, and shared library name.
To upgrade the shared library associated with a UDF, issue a
DROP FUNCTION
statement, upgrade the shared
library, and then issue a CREATE FUNCTION
statement. If you upgrade the shared library first and then
use DROP FUNCTION
, the server may crash.
For the UDF mechanism to work, functions must be written in C or
C++ (or another language that can use C calling conventions),
and your operating system must support dynamic loading. The
MySQL source distribution includes a file
sql/udf_example.cc
that defines 5 new
functions. Consult this file to see how UDF calling conventions
work. UDF-related symbols and data structures are defined in the
include/mysql_com.h
header file. (You need
not include this header file directly because it is included by
mysql.h
.)
A UDF contains code that becomes part of the running server, so
when you write a UDF, you are bound by any and all constraints
that otherwise apply to writing server code. For example, you
may have problems if you attempt to use functions from the
libstdc++
library. Note that these
constraints may change in future versions of the server, so it
is possible that server upgrades will require revisions to UDFs
that were originally written for older servers. For information
about these constraints, see
Section 2.9.2, “Typical configure Options”, and
Section 2.9.4, “Dealing with Problems Compiling MySQL”.
To be able to use UDFs, you need to link
mysqld dynamically. Don't configure MySQL
using --with-mysqld-ldflags=-all-static
. If you
want to use a UDF that needs to access symbols from
mysqld (for example, the
metaphone
function in
sql/udf_example.cc
that uses
default_charset_info
), you must link the
program with -rdynamic
(see man
dlopen
). If you plan to use UDFs, the rule of thumb is
to configure MySQL with
--with-mysqld-ldflags=-rdynamic
unless you have
a very good reason not to.
If you must use a precompiled distribution of MySQL, use MySQL-Max, which contains a dynamically linked server that supports dynamic loading.
For each function that you want to use in SQL statements, you
should define corresponding C (or C++) functions. In the
following discussion, the name “xxx” is used for an
example function name. To distinguish between SQL and C/C++
usage, XXX()
(uppercase) indicates an SQL
function call, and xxx()
(lowercase)
indicates a C/C++ function call.
The C/C++ functions that you write to implement the interface
for XXX()
are:
xxx()
(required)
The main function. This is where the function result is computed. The correspondence between the SQL function data type and the return type of your C/C++ function is shown here:
SQL Type | C/C++ Type |
STRING | char * |
INTEGER | long long |
REAL | double |
xxx_init()
(optional)
The initialization function for xxx()
. It
can be used for the following purposes:
To check the number of arguments to
XXX()
.
To check that the arguments are of a required type or, alternatively, to tell MySQL to coerce arguments to the types you want when the main function is called.
To allocate any memory required by the main function.
To specify the maximum length of the result.
To specify (for REAL
functions) the
maximum number of decimal places in the result.
To specify whether the result can be
NULL
.
xxx_deinit()
(optional)
The deinitialization function for xxx()
.
It should deallocate any memory allocated by the
initialization function.
When an SQL statement invokes XXX()
, MySQL
calls the initialization function xxx_init()
to let it perform any required setup, such as argument checking
or memory allocation. If xxx_init()
returns
an error, MySQL aborts the SQL statement with an error message
and does not call the main or deinitialization functions.
Otherwise, MySQL calls the main function
xxx()
once for each row. After all rows have
been processed, MySQL calls the deinitialization function
xxx_deinit()
so that it can perform any
required cleanup.
For aggregate functions that work like
SUM()
, you must also provide the
following functions:
xxx_reset()
(required before 4.1.1)
Reset the current aggregate value and insert the argument as the initial aggregate value for a new group.
xxx_clear()
(required starting from
4.1.1)
Reset the current aggregate value but do not insert the argument as the initial aggregate value for a new group.
xxx_add()
(required)
Add the argument to the current aggregate value.
MySQL handles aggregate UDFs as follows:
Call xxx_init()
to let the aggregate
function allocate any memory it needs for storing results.
Sort the table according to the GROUP BY
expression.
Call xxx_clear()
for the first row in
each new group.
Call xxx_add()
for each new row that
belongs in the same group.
Call xxx()
to get the result for the
aggregate when the group changes or after the last row has
been processed.
Repeat 3-5 until all rows has been processed
Call xxx_deinit()
to let the UDF free any
memory it has allocated.
All functions must be thread-safe. This includes not just the
main function, but the initialization and deinitialization
functions as well, and also the additional functions required by
aggregate functions. A consequence of this requirement is that
you are not allowed to allocate any global or static variables
that change! If you need memory, you should allocate it in
xxx_init()
and free it in
xxx_deinit()
.
This section describes the different functions that you need to define when you create a simple UDF. Section 19.2.4, “Adding a New User-Defined Function”, describes the order in which MySQL calls these functions.
The main xxx()
function should be declared
as shown in this section. Note that the return type and
parameters differ, depending on whether you declare the SQL
function XXX()
to return
STRING
, INTEGER
, or
REAL
in the CREATE
FUNCTION
statement:
For STRING
functions:
char *xxx(UDF_INIT *initid, UDF_ARGS *args, char *result, unsigned long *length, char *is_null, char *error);
For INTEGER
functions:
long long xxx(UDF_INIT *initid, UDF_ARGS *args, char *is_null, char *error);
For REAL
functions:
double xxx(UDF_INIT *initid, UDF_ARGS *args, char *is_null, char *error);
The initialization and deinitialization functions are declared like this:
my_bool xxx_init(UDF_INIT *initid, UDF_ARGS *args, char *message); void xxx_deinit(UDF_INIT *initid);
The initid
parameter is passed to all three
functions. It points to a UDF_INIT
structure that is used to communicate information between
functions. The UDF_INIT
structure members
follow. The initialization function should fill in any members
that it wishes to change. (To use the default for a member,
leave it unchanged.)
my_bool maybe_null
xxx_init()
should set
maybe_null
to 1
if
xxx()
can return
NULL
. The default value is
1
if any of the arguments are declared
maybe_null
.
unsigned int decimals
The number of decimal digits to the right of the decimal
point. The default value is the maximum number of decimal
digits in the arguments passed to the main function. (For
example, if the function is passed
1.34
, 1.345
, and
1.3
, the default would be 3, because
1.345
has 3 decimal digits.
unsigned int max_length
The maximum length of the result. The default
max_length
value differs depending on
the result type of the function. For string functions, the
default is the length of the longest argument. For integer
functions, the default is 21 digits. For real functions,
the default is 13 plus the number of decimal digits
indicated by initid->decimals
. (For
numeric functions, the length includes any sign or decimal
point characters.)
If you want to return a blob value, you can set
max_length
to 65KB or 16MB. This memory
is not allocated, but the value is used to decide which
data type to use if there is a need to temporarily store
the data.
char *ptr
A pointer that the function can use for its own purposes.
For example, functions can use
initid->ptr
to communicate allocated
memory among themselves. xxx_init()
should allocate the memory and assign it to this pointer:
initid->ptr = allocated_memory;
In xxx()
and
xxx_deinit()
, refer to
initid->ptr
to use or deallocate the
memory.
This section describes the different functions that you need to define when you create an aggregate UDF. Section 19.2.4, “Adding a New User-Defined Function”, describes the order in which MySQL calls these functions.
xxx_reset()
This function is called when MySQL finds the first row in
a new group. It should reset any internal summary
variables and then use the given
UDF_ARGS
argument as the first value in
your internal summary value for the group. Declare
xxx_reset()
as follows:
char *xxx_reset(UDF_INIT *initid, UDF_ARGS *args, char *is_null, char *error);
xxx_reset()
is needed only before MySQL
4.1.1. It is not needed or used as of
MySQL 4.1.1, when the UDF interface changed to use
xxx_clear()
instead. However, you can
define both xxx_reset()
and
xxx_clear()
if you want to have your
UDF work both before and after the interface change. (If
you do include both functions, the
xxx_reset()
function in many cases can
be implemented internally by calling
xxx_clear()
to reset all variables, and
then calling xxx_add()
to add the
UDF_ARGS
argument as the first value in
the group.)
xxx_clear()
This function is called when MySQL needs to reset the
summary results. It is called at the beginning for each
new group but can also be called to reset the values for a
query where there were no matching rows. Declare
xxx_clear()
as follows:
char *xxx_clear(UDF_INIT *initid, char *is_null, char *error);
is_null
is set to point to
CHAR(0)
before calling
xxx_clear()
.
If something went wrong, you can store a value in the
variable to which the error
argument
points. error
points to a single-byte
variable, not to a string buffer.
xxx_clear()
is required only by MySQL
4.1.1 and above. Before MySQL 4.1.1, use
xxx_reset()
instead.
xxx_add()
This function is called for all rows that belong to the
same group, except for the first row. You should use it to
add the value in the UDF_ARGS
argument
to your internal summary variable.
char *xxx_add(UDF_INIT *initid, UDF_ARGS *args, char *is_null, char *error);
The xxx()
function for an aggregate UDF
should be declared the same way as for a non-aggregate UDF.
See Section 19.2.4.1, “UDF Calling Sequences for Simple Functions”.
For an aggregate UDF, MySQL calls the xxx()
function after all rows in the group have been processed. You
should normally never access its UDF_ARGS
argument here but instead return a value based on your
internal summary variables.
Return value handling in xxx()
should be
done the same way as for a non-aggregate UDF. See
Section 19.2.4.4, “UDF Return Values and Error Handling”.
The xxx_reset()
and
xxx_add()
functions handle their
UDF_ARGS
argument the same way as functions
for non-aggregate UDFs. See Section 19.2.4.3, “UDF Argument Processing”.
The pointer arguments to is_null
and
error
are the same for all calls to
xxx_reset()
,
xxx_clear()
, xxx_add()
and xxx()
. You can use this to remember
that you got an error or whether the xxx()
function should return NULL
. You should not
store a string into *error
!
error
points to a single-byte variable, not
to a string buffer.
*is_null
is reset for each group (before
calling xxx_clear()
).
*error
is never reset.
If *is_null
or *error
are set when xxx()
returns, MySQL returns
NULL
as the result for the group function.
The args
parameter points to a
UDF_ARGS
structure that has the members
listed here:
unsigned int arg_count
The number of arguments. Check this value in the initialization function if you require your function to be called with a particular number of arguments. For example:
if (args->arg_count != 2) { strcpy(message,"XXX() requires two arguments"); return 1; }
For other UDF_ARGS
member values that
are arrays, array references are zero-based. That is,
refer to array members using index values from 0 to
args->arg_count
– 1.
enum Item_result *arg_type
A pointer to an array containing the types for each
argument. The possible type values are
STRING_RESULT
,
INT_RESULT
, and
REAL_RESULT
.
To make sure that arguments are of a given type and return
an error if they are not, check the
arg_type
array in the initialization
function. For example:
if (args->arg_type[0] != STRING_RESULT || args->arg_type[1] != INT_RESULT) { strcpy(message,"XXX() requires a string and an integer"); return 1; }
As an alternative to requiring your function's arguments
to be of particular types, you can use the initialization
function to set the arg_type
elements
to the types you want. This causes MySQL to coerce
arguments to those types for each call to
xxx()
. For example, to specify that the
first two arguments should be coerced to string and
integer, respectively, do this in
xxx_init()
:
args->arg_type[0] = STRING_RESULT; args->arg_type[1] = INT_RESULT;
char **args
args->args
communicates information
to the initialization function about the general nature of
the arguments passed to your function. For a constant
argument i
,
args->args[i]
points to the argument
value. (See below for instructions on how to access the
value properly.) For a non-constant argument,
args->args[i]
is
0
. A constant argument is an expression
that uses only constants, such as 3
or
4*7-2
or
SIN(3.14)
. A non-constant
argument is an expression that refers to values that may
change from row to row, such as column names or functions
that are called with non-constant arguments.
For each invocation of the main function,
args->args
contains the actual
arguments that are passed for the row currently being
processed.
If argument i
represents
NULL
,
args->args[i]
is a null pointer (0).
If the argument is not NULL
, functions
can refer to it as follows:
An argument of type STRING_RESULT
is given as a string pointer plus a length, to allow
handling of binary data or data of arbitrary length.
The string contents are available as
args->args[i]
and the string
length is args->lengths[i]
. Do
not assume that the string is null-terminated.
For an argument of type INT_RESULT
,
you must cast args->args[i]
to a
long long
value:
long long int_val; int_val = *((long long*) args->args[i]);
For an argument of type
REAL_RESULT
, you must cast
args->args[i]
to a
double
value:
double real_val; real_val = *((double*) args->args[i]);
unsigned long *lengths
For the initialization function, the
lengths
array indicates the maximum
string length for each argument. You should not change
these. For each invocation of the main function,
lengths
contains the actual lengths of
any string arguments that are passed for the row currently
being processed. For arguments of types
INT_RESULT
or
REAL_RESULT
, lengths
still contains the maximum length of the argument (as for
the initialization function).
char *maybe_null
For the initialization function, the
maybe_null
array indicates for each
argument whether the argument value might be null (0 if
no, 1 if yes).
The initialization function should return 0
if no error occurred and 1
otherwise. If an
error occurs, xxx_init()
should store a
null-terminated error message in the
message
parameter. The message is returned
to the client. The message buffer is
MYSQL_ERRMSG_SIZE
characters long, but you
should try to keep the message to less than 80 characters so
that it fits the width of a standard terminal screen.
The return value of the main function xxx()
is the function value, for long long
and
double
functions. A string function should
return a pointer to the result and set
*result
and *length
to
the contents and length of the return value. For example:
memcpy(result, "result string", 13); *length = 13;
The result
buffer that is passed to the
xxx()
function is 255 bytes long. If your
result fits in this, you don't have to worry about memory
allocation for results.
If your string function needs to return a string longer than
255 bytes, you must allocate the space for it with
malloc()
in your
xxx_init()
function or your
xxx()
function and free it in your
xxx_deinit()
function. You can store the
allocated memory in the ptr
slot in the
UDF_INIT
structure for reuse by future
xxx()
calls. See
Section 19.2.4.1, “UDF Calling Sequences for Simple Functions”.
To indicate a return value of NULL
in the
main function, set *is_null
to
1
:
*is_null = 1;
To indicate an error return in the main function, set
*error
to 1
:
*error = 1;
If xxx()
sets *error
to
1
for any row, the function value is
NULL
for the current row and for any
subsequent rows processed by the statement in which
XXX()
was invoked.
(xxx()
is not even called for subsequent
rows.)
Before MySQL 3.22.10, you should set both
*error
and *is_null
:
*error = 1; *is_null = 1;
Files implementing UDFs must be compiled and installed on the
host where the server runs. This process is described below
for the example UDF file
sql/udf_example.cc
that is included in
the MySQL source distribution.
The immediately following instructions are for Unix. Instructions for Windows are given later in this section.
The udf_example.cc
file contains the
following functions:
metaphon()
returns a metaphon string of
the string argument. This is something like a soundex
string, but it's more tuned for English.
myfunc_double()
returns the sum of the
ASCII values of the characters in its arguments, divided
by the sum of the length of its arguments.
myfunc_int()
returns the sum of the
length of its arguments.
sequence([const int])
returns a
sequence starting from the given number or 1 if no number
has been given.
lookup()
returns the IP number for a
hostname.
reverse_lookup()
returns the hostname
for an IP number. The function may be called either with a
single string argument of the form
'xxx.xxx.xxx.xxx'
or with four numbers.
A dynamically loadable file should be compiled as a sharable object file, using a command something like this:
shell> gcc -shared -o udf_example.so udf_example.cc
If you are using gcc, you should be able to
create udf_example.so
with a simpler
command:
shell> make udf_example.so
You can easily determine the correct compiler options for your
system by running this command in the sql
directory of your MySQL source tree:
shell> make udf_example.o
You should run a compile command similar to the one that
make displays, except that you should
remove the -c
option near the end of the line
and add -o udf_example.so
to the end of the
line. (On some systems, you may need to leave the
-c
on the command.)
After you compile a shared object containing UDFs, you must
install it and tell MySQL about it. Compiling a shared object
from udf_example.cc
produces a file named
something like udf_example.so
(the exact
name may vary from platform to platform). Copy this file to
some directory such as /usr/lib
that
searched by your system's dynamic (runtime) linker, or add the
directory in which you placed the shared object to the linker
configuration file (for example,
/etc/ld.so.conf
).
The dynamic linker name is system-specific (for example, ld-elf.so.1 on FreeBSD, ld.so on Linux, or dyld on Mac OS X). Consult your system documentation for information about the linker name and how to configure it.
On many systems, you can also set the
LD_LIBRARY
or
LD_LIBRARY_PATH
environment variable to
point at the directory where you have the files for your UDF.
The dlopen
manual page tells you which
variable you should use on your system. You should set this in
mysql.server or
mysqld_safe startup scripts and restart
mysqld.
On some systems, the ldconfig program that
configures the dynamic linker does not recognize a shared
object unless its name begins with lib
. In
this case you should rename a file such as
udf_example.so
to
libudf_example.so
.
On Windows, you can compile user-defined functions by using the following procedure:
You need to obtain the Bazaar source repository for MySQL 4.0 or higher. See Section 2.9.3, “Installing from the Development Source Tree”.
In the source repository, look in the
VC++Files/examples/udf_example
directory. There are files named
udf_example.def
,
udf_example.dsp
, and
udf_example.dsw
there.
In the source repository, look in the
sql
directory. Copy the
udf_example.cc
from this directory to
the VC++Files/examples/udf_example
directory and rename the file to
udf_example.cpp
.
Open the udf_example.dsw
file with
Visual Studio VC++ and use it to compile the UDFs as a
normal project.
After the shared object file has been installed, notify mysqld about the new functions with these statements:
mysql>CREATE FUNCTION metaphon RETURNS STRING SONAME 'udf_example.so';
mysql>CREATE FUNCTION myfunc_double RETURNS REAL SONAME 'udf_example.so';
mysql>CREATE FUNCTION myfunc_int RETURNS INTEGER SONAME 'udf_example.so';
mysql>CREATE FUNCTION lookup RETURNS STRING SONAME 'udf_example.so';
mysql>CREATE FUNCTION reverse_lookup
->RETURNS STRING SONAME 'udf_example.so';
mysql>CREATE AGGREGATE FUNCTION avgcost
->RETURNS REAL SONAME 'udf_example.so';
Functions can be deleted using DROP
FUNCTION
:
mysql>DROP FUNCTION metaphon;
mysql>DROP FUNCTION myfunc_double;
mysql>DROP FUNCTION myfunc_int;
mysql>DROP FUNCTION lookup;
mysql>DROP FUNCTION reverse_lookup;
mysql>DROP FUNCTION avgcost;
The CREATE FUNCTION
and DROP
FUNCTION
statements update the
func
system table in the
mysql
database. The function's name, type
and shared library name are saved in the table. You must have
the INSERT
and DELETE
privileges for the mysql
database to create
and drop functions.
You should not use CREATE FUNCTION
to add a
function that has previously been created. If you need to
reinstall a function, you should remove it with DROP
FUNCTION
and then reinstall it with CREATE
FUNCTION
. You would need to do this, for example, if
you recompile a new version of your function, so that
mysqld gets the new version. Otherwise, the
server continues to use the old version.
An active function is one that has been loaded with
CREATE FUNCTION
and not removed with
DROP FUNCTION
. All active functions are
reloaded each time the server starts, unless you start
mysqld with the
--skip-grant-tables
option. In this case, UDF
initialization is skipped and UDFs are unavailable.
If the new function will be referred to in statements that will be replicated to slave servers, you must ensure that every slave server also has the function available. Otherwise, replication will fail on the slaves when they attempt to invoke the function.
MySQL takes the following measures to prevent misuse of user-defined functions.
You must have the INSERT
privilege to be
able to use CREATE FUNCTION
and the
DELETE
privilege to be able to use
DROP FUNCTION
. This is necessary because
these statements add and delete rows from the
mysql.func
table.
UDFs should have at least one symbol defined in addition to
the xxx
symbol that corresponds to the main
xxx()
function. These auxiliary symbols
correspond to the xxx_init()
,
xxx_deinit()
,
xxx_reset()
,
xxx_clear()
, and
xxx_add()
functions. As of MySQL 4.0.24 and
4.1.10a, mysqld supports an
--allow-suspicious-udfs
option that controls
whether UDFs that have only an xxx
symbol
can be loaded. By default, the option is off, to prevent
attempts at loading functions from shared object files other
than those containing legitimate UDFs. If you have older UDFs
that contain only the xxx
symbol and that
cannot be recompiled to include an auxiliary symbol, it may be
necessary to specify the
--allow-suspicious-udfs
option. Otherwise,
you should avoid enabling this capability.
UDF object files cannot be placed in arbitrary directories.
They must be located in some system directory that the dynamic
linker is configured to search. To enforce this restriction
and prevent attempts at specifying pathnames outside of
directories searched by the dynamic linker, MySQL checks the
shared object file name specified in CREATE
FUNCTION
statements for pathname delimiter
characters. As of MySQL 4.0.24 and 4.1.10a, MySQL also checks
for pathname delimiters in filenames stored in the
mysql.func
table when it loads functions.
This prevents attempts at specifying illegitimate pathnames
through direct manipulation of the
mysql.func
table. For information about
UDFs and the runtime linker, see
Section 19.2.4.5, “Compiling and Installing User-Defined Functions”.
To add a new native MySQL function, use the procedure described here, which requires that you use a source distribution. You cannot add native functions to a binary distribution because it is necessary to modify MySQL source code and compile MySQL from the modified source. If you migrate to another version of MySQL (for example, when a new version is released), you must repeat the procedure with the new version.
If the new native function will be referred to in statements that will be replicated to slave servers, you must ensure that every slave server also has the function available. Otherwise, replication will fail on the slaves when they attempt to invoke the function.
To add a new native function, follow these steps to modify
source files in the sql
directory:
Add one line to lex.h
that defines the
function name in the sql_functions[]
array.
If the function prototype is simple (just takes zero, one,
two, or three arguments), add a line to the
sql_functions[]
array in
lex.h
that specifies
SYM(FUNC_ARG
as the second argument (where N
)N
is the number of arguments the function takes). Also, add a
function in item_create.cc
that creates
a function object. Look at "ABS"
and
create_funcs_abs()
for an example of
this.
If the function prototype is not simple (for example, if it
takes a variable number of arguments), you should make two
changes to sql_yacc.yy
. One is a line
that indicates the preprocessor symbol that
yacc should define; this should be added
at the beginning of the file. The other is an
“item” to be added to the
simple_expr
parsing rule that defines the
function parameters. You will need an item for each syntax
with which the function can be called. For an example that
shows how this this is done, check all occurrences of
ATAN
in sql_yacc.yy
.
In item_func.h
, declare a class
inheriting from Item_num_func
or
Item_str_func
, depending on whether your
function returns a number or a string.
In item_func.cc
, add one of the
following declarations, depending on whether you are
defining a numeric or string function:
double Item_func_newname::val() longlong Item_func_newname::val_int() String *Item_func_newname::Str(String *str)
If you inherit your object from any of the standard items
(like Item_num_func
), you probably only
have to define one of these functions and let the parent
object take care of the other functions. For example, the
Item_str_func
class defines a
val()
function that executes
atof()
on the value returned by
::str()
.
If the function is non-deterministic, include the following statement in the item constructor to indicate that function results should not be cached:
current_thd->lex->safe_to_cache_query=0;
A function is non-deterministic if, given fixed values for its arguments, it can return different results for different invocations.
You should probably also define the following object function:
void Item_func_newname::fix_length_and_dec()
This function should at least calculate
max_length
based on the given arguments.
max_length
is the maximum number of
characters the function may return. This function should
also set maybe_null = 0
if the main
function can't return a NULL
value. The
function can check whether any of the function arguments can
return NULL
by checking the arguments'
maybe_null
variable. Look at
Item_func_mod::fix_length_and_dec
for a
typical example of how to do this.
All functions must be thread-safe. In other words, do not use any global or static variables in the functions without protecting them with mutexes.
If you want to return NULL
from
::val()
, ::val_int()
, or
::str()
, you should set
null_value
to 1 and return 0.
For ::str()
object functions, there are
additional considerations to be aware of:
The String *str
argument provides a
string buffer that may be used to hold the result. (For more
information about the String
type, take a
look at the sql_string.h
file.)
The ::str()
function should return the
string that holds the result, or (char*)
0
if the result is NULL
.
All current string functions try to avoid allocating any memory unless absolutely necessary!
In MySQL, you can define a procedure in C++ that can access and
modify the data in a query before it is sent to the client. The
modification can be done on a row-by-row or GROUP
BY
level.
We have created an example procedure in MySQL 3.23 to show you what can be done.
Additionally, we recommend that you take a look at
mylua
. With this you can use the LUA language
to load a procedure at runtime into mysqld.
analyse([
max_elements
[,max_memory
]])
This procedure is defined in the
sql/sql_analyse.cc
file. It examines the
result from a query and returns an analysis of the results that
suggests optimal data types for each column. To obtain this
analysis, append PROCEDURE ANALYSE
to the end
of a SELECT
statement:
SELECT ... FROM ... WHERE ... PROCEDURE ANALYSE([max_elements
,[max_memory
]])
For example:
SELECT col1, col2 FROM table1 PROCEDURE ANALYSE(10, 2000);
The results show some statistics for the values returned by the
query, and propose an optimal data type for the columns. This
can be helpful for checking your existing tables, or after
importing new data. You may need to try different settings for
the arguments so that PROCEDURE ANALYSE()
does not suggest the ENUM
data type when it
is not appropriate.
The arguments are optional and are used as follows:
max_elements
(default 256) is the
maximum number of distinct values that
analyse
notices per column. This is used
by analyse
to check whether the optimal
data type should be of type ENUM
.
max_memory
(default 8192) is the
maximum amount of memory that analyse
should allocate per column while trying to find all distinct
values.