Table of Contents
MySQL Connectors provide connectivity to the MySQL server for client programs. APIs provide low-level access to the MySQL protocol and MySQL resources. Both Connectors and the APIs enable you to connect and execute MySQL statements from another language or environment, including ODBC, Java (JDBC), Perl, Python, PHP, Ruby, and native C and embedded MySQL instances.
Connector version numbers do not correlate with MySQL Server version numbers. See Table 23.2, “MySQL Connector Versions and MySQL Server Versions”.
Oracle develops a number of connectors:
Connector/ODBC provides driver support for connecting to MySQL using the Open Database Connectivity (ODBC) API. Support is available for ODBC connectivity from Windows, Unix, and OS X platforms.
Connector/Net enables developers to create .NET applications that connect to MySQL. Connector/Net implements a fully functional ADO.NET interface and provides support for use with ADO.NET aware tools. Applications that use Connector/Net can be written in any supported .NET language.
The MySQL Visual Studio Plugin works with Connector/Net and Visual Studio 2005. The plugin is a MySQL DDEX Provider, which means that you can use the schema and data manipulation tools available in Visual Studio to create and edit objects within a MySQL database.
Connector/J provides driver support for connecting to MySQL from Java applications using the standard Java Database Connectivity (JDBC) API.
Connector/Python provides driver support for connecting to MySQL from Python applications using an API that is compliant with the Python DB API version 2.0. No additional Python modules or MySQL client libraries are required.
Connector/C++ enables C++ applications to connect to MySQL.
Connector/C is a standalone
replacement for the MySQL Client Library
(libmysqlclient
), to be used for C
applications.
For direct access to using MySQL natively within a C application, there are two methods:
The C API provides low-level access
to the MySQL client/server protocol through the
libmysqlclient
client library. This is the
primary method used to connect to an instance of the MySQL
server, and is used both by MySQL command-line clients and many
of the MySQL Connectors and third-party APIs detailed here.
libmysqlclient
is included in MySQL
distributions and in Connector/C distributions.
libmysqld
is an embedded MySQL server library
that enables you to embed an instance of the MySQL server into
your C applications.
libmysqld
is included in MySQL distributions,
but not in Connector/C distributions.
See also Section 23.8.1, “MySQL C API Implementations”.
To access MySQL from a C application, or to build an interface to MySQL for a language not supported by the Connectors or APIs in this chapter, the C API is where to start. A number of programmer's utilities are available to help with the process; see Section 4.7, “MySQL Program Development Utilities”.
The remaining APIs described in this chapter provide an interface to MySQL from specific application languages. These third-party solutions are not developed or supported by Oracle. Basic information on their usage and abilities is provided here for reference purposes only.
All the third-party language APIs are developed using one of two
methods, using libmysqlclient
or by implementing
a native driver. The two
solutions offer different benefits:
Using libmysqlclient
offers complete compatibility with MySQL because it uses the
same libraries as the MySQL client applications. However, the
feature set is limited to the implementation and interfaces
exposed through libmysqlclient
and the
performance may be lower as data is copied between the native
language, and the MySQL API components.
Native drivers are an implementation of the MySQL network protocol entirely within the host language or environment. Native drivers are fast, as there is less copying of data between components, and they can offer advanced functionality not available through the standard MySQL API. Native drivers are also easier for end users to build and deploy because no copy of the MySQL client libraries is needed to build the native driver components.
Table 23.1, “MySQL APIs and Interfaces” lists many of the libraries and interfaces available for MySQL. Table 23.2, “MySQL Connector Versions and MySQL Server Versions” shows which MySQL Server versions each connector supports.
Table 23.1 MySQL APIs and Interfaces
Environment | API | Type | Notes |
---|---|---|---|
Ada | GNU Ada MySQL Bindings | libmysqlclient | See MySQL Bindings for GNU Ada |
C | C API | libmysqlclient | See Section 23.8, “MySQL C API”. |
C | Connector/C | Replacement for libmysqlclient | See MySQL Connector/C Developer Guide. |
C++ | Connector/C++ | libmysqlclient | See MySQL Connector/C++ Developer Guide. |
MySQL++ | libmysqlclient | See MySQL++ Web site. | |
MySQL wrapped | libmysqlclient | See MySQL wrapped. | |
Cocoa | MySQL-Cocoa | libmysqlclient | Compatible with the Objective-C Cocoa environment. See http://mysql-cocoa.sourceforge.net/ |
D | MySQL for D | libmysqlclient | See MySQL for D. |
Eiffel | Eiffel MySQL | libmysqlclient | See Section 23.14, “MySQL Eiffel Wrapper”. |
Erlang | erlang-mysql-driver | libmysqlclient | See
erlang-mysql-driver . |
Haskell | Haskell MySQL Bindings | Native Driver | See Brian O'Sullivan's pure Haskell MySQL bindings. |
hsql-mysql | libmysqlclient | See MySQL driver for Haskell . | |
Java/JDBC | Connector/J | Native Driver | See MySQL Connector/J 5.1 Developer Guide. |
Kaya | MyDB | libmysqlclient | See MyDB. |
Lua | LuaSQL | libmysqlclient | See LuaSQL. |
.NET/Mono | Connector/Net | Native Driver | See MySQL Connector/Net Developer Guide. |
Objective Caml | OBjective Caml MySQL Bindings | libmysqlclient | See MySQL Bindings for Objective Caml. |
Octave | Database bindings for GNU Octave | libmysqlclient | See Database bindings for GNU Octave. |
ODBC | Connector/ODBC | libmysqlclient | See MySQL Connector/ODBC Developer Guide. |
Perl | DBI /DBD::mysql | libmysqlclient | See Section 23.10, “MySQL Perl API”. |
Net::MySQL | Native Driver | See
Net::MySQL
at CPAN | |
PHP | mysql , ext/mysql interface
(deprecated) | libmysqlclient | See Original MySQL API. |
mysqli , ext/mysqli interface | libmysqlclient | See MySQL Improved Extension. | |
PDO_MYSQL | libmysqlclient | See MySQL Functions (PDO_MYSQL). | |
PDO mysqlnd | Native Driver | ||
Python | Connector/Python | Native Driver | See MySQL Connector/Python Developer Guide. |
Python | Connector/Python C Extension | libmysqlclient | See MySQL Connector/Python Developer Guide. |
MySQLdb | libmysqlclient | See Section 23.11, “MySQL Python API”. | |
Ruby | MySQL/Ruby | libmysqlclient | Uses libmysqlclient . See
Section 23.12.1, “The MySQL/Ruby API”. |
Ruby/MySQL | Native Driver | See Section 23.12.2, “The Ruby/MySQL API”. | |
Scheme | Myscsh | libmysqlclient | See
Myscsh . |
SPL | sql_mysql | libmysqlclient | See
sql_mysql
for SPL. |
Tcl | MySQLtcl | libmysqlclient | See Section 23.13, “MySQL Tcl API”. |
Table 23.2 MySQL Connector Versions and MySQL Server Versions
Connector | Connector version | MySQL Server version |
---|---|---|
Connector/C | 6.1.0 GA | 5.6, 5.5, 5.1, 5.0, 4.1 |
Connector/C++ | 1.0.5 GA | 5.6, 5.5, 5.1 |
Connector/J | 5.1.8 | 5.6, 5.5, 5.1, 5.0, 4.1 |
Connector/Net | 6.5 | 5.6, 5.5, 5.1, 5.0 |
Connector/Net | 6.4 | 5.6, 5.5, 5.1, 5.0 |
Connector/Net | 6.3 | 5.6, 5.5, 5.1, 5.0 |
Connector/Net | 6.2 (No longer supported) | 5.6, 5.5, 5.1, 5.0 |
Connector/Net | 6.1 (No longer supported) | 5.6, 5.5, 5.1, 5.0 |
Connector/Net | 6.0 (No longer supported) | 5.6, 5.5, 5.1, 5.0 |
Connector/Net | 5.2 (No longer supported) | 5.6, 5.5, 5.1, 5.0 |
Connector/Net | 1.0 (No longer supported) | 5.0, 4.0 |
Connector/ODBC | 5.1 | 5.6, 5.5, 5.1, 5.0, 4.1.1+ |
Connector/ODBC | 3.51 (Unicode not supported) | 5.6, 5.5, 5.1, 5.0, 4.1 |
Connector/Python | 2.0 | 5.7, 5.6, 5.5 |
Connector/Python | 1.2 | 5.7, 5.6, 5.5 |
The MySQL Connector/ODBC manual is now published in standalone form, not as part of the MySQL Reference Manual. For information, see these documents:
Main manual: MySQL Connector/ODBC Developer Guide
Release notes: MySQL Connector/ODBC Release Notes
The MySQL Connector/Net manual is now published in standalone form, not as part of the MySQL Reference Manual. For information, see these documents:
Main manual: MySQL Connector/Net Developer Guide
Release notes: MySQL Connector/Net Release Notes
The MySQL Connector/J manual is now published in standalone form, not as part of the MySQL Reference Manual. For information, see these documents:
Main manual: MySQL Connector/J 5.1 Developer Guide
Release notes: MySQL Connector/J Release Notes
The MySQL Connector/C++ manual is now published in standalone form, not as part of the MySQL Reference Manual. For information, see these documents:
Main manual: MySQL Connector/C++ Developer Guide
Release notes: MySQL Connector/C++ Release Notes
The MySQL Connector/C manual is now published in standalone form, not as part of the MySQL Reference Manual. For information, see these documents:
Main manual: MySQL Connector/C Developer Guide
Release notes: MySQL Connector/C Release Notes
The MySQL Connector/Python manual is now published in standalone form, not as part of the MySQL Reference Manual. For information, see these documents:
Main manual: MySQL Connector/Python Developer Guide
Release notes: MySQL Connector/Python Release Notes
The embedded MySQL server library makes it possible to run a full-featured MySQL server inside a client application. The main benefits are increased speed and more simple management for embedded applications.
The embedded server library is based on the client/server version of MySQL, which is written in C/C++. Consequently, the embedded server also is written in C/C++. There is no embedded server available in other languages.
The API is identical for the embedded MySQL version and the client/server version. To change an old threaded application to use the embedded library, you normally only have to add calls to the following functions.
Table 23.3 MySQL Embedded Server Library Functions
Function | When to Call |
---|---|
Call it before any other MySQL function is called,
preferably early in the | |
Call it before your program exits. | |
Call it in each thread you create that accesses MySQL. | |
mysql_thread_end() | Call it before calling pthread_exit() . |
Then you must link your code with libmysqld.a
instead of libmysqlclient.a
. To ensure binary
compatibility between your application and the server library, be
sure to compile your application against headers for the same series
of MySQL that was used to compile the server library. For example,
if libmysqld
was compiled against MySQL
5.1 headers, do not compile your application against
MySQL 5.5 headers, or vice versa.
The
mysql_library_
functions are also included in xxx
()libmysqlclient.a
to enable you to change between the embedded and the client/server
version by just linking your application with the right library. See
Section 23.8.7.40, “mysql_library_init()”.
One difference between the embedded server and the standalone server is that for the embedded server, authentication for connections is disabled by default.
In precompiled binary MySQL distributions that include
libmysqld
, the embedded server library, MySQL
builds the library using the appropriate vendor compiler if there
is one.
To get a libmysqld
library if you build MySQL
from source yourself, you should configure MySQL with the
-DWITH_EMBEDDED_SERVER=1
option. See
Section 2.9.4, “MySQL Source-Configuration Options”.
When you link your program with libmysqld
, you
must also include the system-specific pthread
libraries and some libraries that the MySQL server uses. You can
get the full list of libraries by executing mysql_config
--libmysqld-libs.
The correct flags for compiling and linking a threaded program must be used, even if you do not directly call any thread functions in your code.
To compile a C program to include the necessary files to embed the MySQL server library into an executable version of a program, the compiler will need to know where to find various files and need instructions on how to compile the program. The following example shows how a program could be compiled from the command line, assuming that you are using gcc, use the GNU C compiler:
gcc mysql_test.c -o mysql_test \ `/usr/local/mysql/bin/mysql_config --include --libmysqld-libs`
Immediately following the gcc command is the
name of the C program source file. After it, the
-o
option is given to indicate that the file name
that follows is the name that the compiler is to give to the
output file, the compiled program. The next line of code tells the
compiler to obtain the location of the include files and libraries
and other settings for the system on which it is compiled. The
mysql_config command is contained in backticks,
not single quotation marks.
On some non-gcc platforms, the embedded library depends on C++ runtime libraries and linking against the embedded library might result in missing-symbol errors. To solve this, link using a C++ compiler or explicitly list the required libraries on the link command line.
The embedded server has the following limitations:
No user-defined functions (UDFs).
No stack trace on core dump.
You cannot set this up as a master or a slave (no replication).
Very large result sets may be unusable on low memory systems.
You cannot connect to an embedded server from an outside process with sockets or TCP/IP. However, you can connect to an intermediate application, which in turn can connect to an embedded server on the behalf of a remote client or outside process.
InnoDB
is not reentrant in the embedded
server and cannot be used for multiple connections, either
successively or simultaneously.
The Event Scheduler is not available. Because of this, the
event_scheduler
system
variable is disabled.
Some of these limitations can be changed by editing the
mysql_embed.h
include file and recompiling
MySQL.
Any options that may be given with the mysqld
server daemon, may be used with an embedded server library. Server
options may be given in an array as an argument to the
mysql_library_init()
, which
initializes the server. They also may be given in an option file
like my.cnf
. To specify an option file for a
C program, use the --defaults-file
option as one of the elements of the second argument of the
mysql_library_init()
function. See
Section 23.8.7.40, “mysql_library_init()”, for more information on the
mysql_library_init()
function.
Using option files can make it easier to switch between a
client/server application and one where MySQL is embedded. Put
common options under the [server]
group. These
are read by both MySQL versions. Client/server-specific options
should go under the [mysqld]
section. Put
options specific to the embedded MySQL server library in the
[embedded]
section. Options specific to
applications go under section labeled
[ApplicationName_SERVER]
. See
Section 4.2.6, “Using Option Files”.
These two example programs should work without any changes on a Linux or FreeBSD system. For other operating systems, minor changes are needed, mostly with file paths. These examples are designed to give enough details for you to understand the problem, without the clutter that is a necessary part of a real application. The first example is very straightforward. The second example is a little more advanced with some error checking. The first is followed by a command-line entry for compiling the program. The second is followed by a GNUmake file that may be used for compiling instead.
Example 1
test1_libmysqld.c
#include <stdio.h> #include <stdlib.h> #include <stdarg.h> #include "mysql.h" MYSQL *mysql; MYSQL_RES *results; MYSQL_ROW record; static char *server_options[] = \ { "mysql_test", "--defaults-file=my.cnf", NULL }; int num_elements = (sizeof(server_options) / sizeof(char *)) - 1; static char *server_groups[] = { "libmysqld_server", "libmysqld_client", NULL }; int main(void) { mysql_library_init(num_elements, server_options, server_groups); mysql = mysql_init(NULL); mysql_options(mysql, MYSQL_READ_DEFAULT_GROUP, "libmysqld_client"); mysql_options(mysql, MYSQL_OPT_USE_EMBEDDED_CONNECTION, NULL); mysql_real_connect(mysql, NULL,NULL,NULL, "database1", 0,NULL,0); mysql_query(mysql, "SELECT column1, column2 FROM table1"); results = mysql_store_result(mysql); while((record = mysql_fetch_row(results))) { printf("%s - %s \n", record[0], record[1]); } mysql_free_result(results); mysql_close(mysql); mysql_library_end(); return 0; }
Here is the command line for compiling the above program:
gcc test1_libmysqld.c -o test1_libmysqld \ `/usr/local/mysql/bin/mysql_config --include --libmysqld-libs`
Example 2
To try the example, create an test2_libmysqld
directory at the same level as the MySQL source directory. Save
the test2_libmysqld.c
source and the
GNUmakefile
in the directory, and run GNU
make
from inside the
test2_libmysqld
directory.
test2_libmysqld.c
/* * A simple example client, using the embedded MySQL server library */ #include <mysql.h> #include <stdarg.h> #include <stdio.h> #include <stdlib.h> MYSQL *db_connect(const char *dbname); void db_disconnect(MYSQL *db); void db_do_query(MYSQL *db, const char *query); const char *server_groups[] = { "test2_libmysqld_SERVER", "embedded", "server", NULL }; int main(int argc, char **argv) { MYSQL *one, *two; /* mysql_library_init() must be called before any other mysql * functions. * * You can use mysql_library_init(0, NULL, NULL), and it * initializes the server using groups = { * "server", "embedded", NULL * }. * * In your $HOME/.my.cnf file, you probably want to put: [test2_libmysqld_SERVER] language = /path/to/source/of/mysql/sql/share/english * You could, of course, modify argc and argv before passing * them to this function. Or you could create new ones in any * way you like. But all of the arguments in argv (except for * argv[0], which is the program name) should be valid options * for the MySQL server. * * If you link this client against the normal mysqlclient * library, this function is just a stub that does nothing. */ mysql_library_init(argc, argv, (char **)server_groups); one = db_connect("test"); two = db_connect(NULL); db_do_query(one, "SHOW TABLE STATUS"); db_do_query(two, "SHOW DATABASES"); mysql_close(two); mysql_close(one); /* This must be called after all other mysql functions */ mysql_library_end(); exit(EXIT_SUCCESS); } static void die(MYSQL *db, char *fmt, ...) { va_list ap; va_start(ap, fmt); vfprintf(stderr, fmt, ap); va_end(ap); (void)putc('\n', stderr); if (db) db_disconnect(db); exit(EXIT_FAILURE); } MYSQL * db_connect(const char *dbname) { MYSQL *db = mysql_init(NULL); if (!db) die(db, "mysql_init failed: no memory"); /* * Notice that the client and server use separate group names. * This is critical, because the server does not accept the * client's options, and vice versa. */ mysql_options(db, MYSQL_READ_DEFAULT_GROUP, "test2_libmysqld_CLIENT"); if (!mysql_real_connect(db, NULL, NULL, NULL, dbname, 0, NULL, 0)) die(db, "mysql_real_connect failed: %s", mysql_error(db)); return db; } void db_disconnect(MYSQL *db) { mysql_close(db); } void db_do_query(MYSQL *db, const char *query) { if (mysql_query(db, query) != 0) goto err; if (mysql_field_count(db) > 0) { MYSQL_RES *res; MYSQL_ROW row, end_row; int num_fields; if (!(res = mysql_store_result(db))) goto err; num_fields = mysql_num_fields(res); while ((row = mysql_fetch_row(res))) { (void)fputs(">> ", stdout); for (end_row = row + num_fields; row < end_row; ++row) (void)printf("%s\t", row ? (char*)*row : "NULL"); (void)fputc('\n', stdout); } (void)fputc('\n', stdout); mysql_free_result(res); } else (void)printf("Affected rows: %lld\n", mysql_affected_rows(db)); return; err: die(db, "db_do_query failed: %s [%s]", mysql_error(db), query); }
GNUmakefile
# This assumes the MySQL software is installed in /usr/local/mysql inc := /usr/local/mysql/include/mysql lib := /usr/local/mysql/lib # If you have not installed the MySQL software yet, try this instead #inc := $(HOME)/mysql-5.5/include #lib := $(HOME)/mysql-5.5/libmysqld CC := gcc CPPFLAGS := -I$(inc) -D_THREAD_SAFE -D_REENTRANT CFLAGS := -g -W -Wall LDFLAGS := -static # You can change -lmysqld to -lmysqlclient to use the # client/server library LDLIBS = -L$(lib) -lmysqld -lm -ldl -lcrypt ifneq (,$(shell grep FreeBSD /COPYRIGHT 2>/dev/null)) # FreeBSD LDFLAGS += -pthread else # Assume Linux LDLIBS += -lpthread endif # This works for simple one-file test programs sources := $(wildcard *.c) objects := $(patsubst %c,%o,$(sources)) targets := $(basename $(sources)) all: $(targets) clean: rm -f $(targets) $(objects) *.core
The C API provides low-level access to the MySQL client/server
protocol and enables C programs to access database contents. The C
API code is distributed with MySQL and implemented in the
libmysqlclient
library. See
Section 23.8.1, “MySQL C API Implementations”.
Most other client APIs use the libmysqlclient
library to communicate with the MySQL server. (Exceptions are except
Connector/J and Connector/Net.) This means that, for example, you
can take advantage of many of the same environment variables that
are used by other client programs because they are referenced from
the library. For a list of these variables, see
Section 4.1, “Overview of MySQL Programs”.
For instructions on building client programs using the C API, see Section 23.8.4.1, “Building C API Client Programs”. For programming with threads, see Section 23.8.4.2, “Writing C API Threaded Client Programs”. To create a standalone application which includes the "server" and "client" in the same program (and does not communicate with an external MySQL server), see Section 23.7, “libmysqld, the Embedded MySQL Server Library”.
If, after an upgrade, you experience problems with compiled client
programs, such as Commands out of sync
or
unexpected core dumps, the programs were probably compiled using
old header or library files. In this case, check the date of the
mysql.h
file and
libmysqlclient.a
library used for compilation
to verify that they are from the new MySQL distribution. If not,
recompile the programs with the new headers and libraries.
Recompilation might also be necessary for programs compiled
against the shared client library if the library major version
number has changed (for example, from
libmysqlclient.so.17
to
libmysqlclient.so.18
). For additional
compatibility information, see
Section 23.8.4.3, “Running C API Client Programs”.
Clients have a maximum communication buffer size. The size of the buffer that is allocated initially (16KB) is automatically increased up to the maximum size (16MB by default). Because buffer sizes are increased only as demand warrants, simply increasing the maximum limit does not in itself cause more resources to be used. This size check is mostly a precaution against erroneous statements and communication packets.
The communication buffer must be large enough to contain a single
SQL statement (for client-to-server traffic) and one row of returned
data (for server-to-client traffic). Each session's communication
buffer is dynamically enlarged to handle any query or row up to the
maximum limit. For example, if you have
BLOB
values that contain up to 16MB
of data, you must have a communication buffer limit of at least 16MB
(in both server and client). The default maximum built into the
client library is 1GB, but the default maximum in the server is 1MB.
You can increase this by changing the value of the
max_allowed_packet
parameter at
server startup. See Section 8.12.2, “Tuning Server Parameters”.
The MySQL server shrinks each communication buffer to
net_buffer_length
bytes after each
query. For clients, the size of the buffer associated with a
connection is not decreased until the connection is closed, at which
time client memory is reclaimed.
The MySQL C API is a C-based API that client applications written in C can use to communicate with MySQL Server. Client programs refer to C API header files at compile time and link to a C API library file at link time. The library comes in two versions, depending on how the application is intended to communicate with the server:
libmysqlclient
: The client version of the
library, used for applications that communicate over a network
connection as a client of a standalone server process.
libmysqld
: The embedded server version of
the library, used for applications intended to include an
embedded MySQL server within the application itself. The
application communicates with its own private server instance.
Both libraries have the same interface. In terms of C API calls,
an application communicates with a standalone server the same way
it communicates with an embedded server. A given client can be
built to communicate with a standalone or embedded server,
depending on whether it is linked against
libmysqlclient
or libmysqld
at build time.
There are two ways to obtain the C API header and library files required to build C API client programs:
Install a MySQL Server distribution. Server distributions
include both libmysqlclient
and
libmysqld
.
Install a Connector/C distribution. Connector/C distributions include
only libmysqlclient
. They do not include
libmysqld
.
For both MySQL Server and Connector/C, you can install a binary distribution that contains the C API files pre-built, or you can use a source distribution and build the C API files yourself.
Normally, you install either a MySQL Server distribution or a Connector/C distribution, but not both. For information about issues involved with simultaneous MySQL Server and Connector/C installations, see Section 23.8.2, “Simultaneous MySQL Server and Connector/C Installations”.
The names of the library files to use when linking C API client applications depend on the library type and platform for which a distribution is built:
On Unix (and Unix-like) sytems, the static library is
libmysqlclient.a
. The dynamic library is
libmysqlclient.so
on most Unix systems
and libmysqlclient.dylib
on OS X.
For distributions that include embedded server libraries, the
corresponding library names begin with
libmysqld
rather than
libmysqlclient
.
On Windows, the static library is
mysqlclient.lib
and the dynamic library
is libmysql.dll
. Windows distributions
also include libmysql.lib
, a static
import library needed for using the dynamic library.
For distributions that include embedded server libraries, the
corresponding library names are
mysqlserver.lib
,
libmysqld.dll
, and
libmysqld.lib
.
Windows distributions also include a set of debug libraries.
These have the same names as the nondebug libraries, but are
located in the lib/debug
library. You
must use the debug libraries when compiling clients built
using the debug C runtime.
On Unix, you may also see libraries that include
_r
in the names. Before MySQL 5.5, these were
built as thread-safe (re-entrant) libraries separately from the
non-_r
libraries. As of 5.5, both libraries are
the same and the _r
names are symbolic links to
the corresponding non-_r
names. There is no
need to use the _r
libraries. For example, if
you use mysql_config to obtain linker flags,
you can use mysql_config --libs in all cases,
even for threaded clients. There is no need to use
mysql_config --libs_r.
MySQL Server and Connector/C installation packages both provide the files needed to build and run MySQL C API client programs. This section discusses when it is possible to install both products on the same system. For some packaging formats, this is possible without conflict. For others, both products cannot be installed at the same time.
This discussion assumes the use of similar package types for both products (for example, RPM packages for both products). It does not try to describe coexistence between packaging types (for example, use of RPM packages for one product and a tar file package for the other). Nor does it describe coexistence of packages provided by Oracle and those provided by third-party vendors.
If you install both products, it may be necessary to adjust your development tools or runtime environment to choose one set of header files and libraries over the other. See Section 23.8.4.1, “Building C API Client Programs”, and Section 23.8.4.3, “Running C API Client Programs”.
tar and Zip file packages install under the
directory into which you unpack them. For example, you can unpack
MySQL Server and Connector/C tar packages under
/usr/local
and they will unpack into distinct
directory names without conflict.
Windows MSI installers use their own installation directory, so MySQL Server and Connector/C installers do not conflict.
OS X DMG packages install under the same parent directory but in a different subdirectory, so there is no conflict. For example:
/usr/local/mysql-5.6.11-osx10.7-x86_64/ /usr/local/mysql-connector-c-6.1.0-osx10.7-x86/
Solaris PKG packages install under the same parent directory but in a different subdirectory, so there is no conflict. For example:
/opt/mysql/mysql /opt/mysql/connector-c
The Solaris Connector/C installer does not create any symlinks from
system directories such as /usr/bin
or
/usr/lib
into the installation directory.
That must be done manually if desired after installation.
For RPM installations, there are several types of RPM packages.
MySQL Server shared
and
devel
RPM packages are similar to the
corresponding Connector/C RPM packages. These RPM package types cannot
coexist because the MySQL Server and Connector/C RPM packages use the
same installation locations for the client library-related files.
This means the following conditions hold:
If MySQL Server shared
and
devel
RPM packages are installed, they
provide the C API headers and libraries, and there is no need
to install the Connector/C RPM packages. To install the Connector/C packages
anyway, you must first remove the corresponding MySQL Server
packages.
To install MySQL Server RPM packages if you already have Connector/C RPM packages installed, you must first remove the Connector/C RPM packages.
MySQL Server RPM packages other than shared
and
devel
do not conflict with Connector/C packages and
can be installed if Connector/C is installed. This includes the main
server RPM that includes the mysqld server
itself.
Many of the clients in MySQL source distributions are written in
C, such as mysql,
mysqladmin, and mysqlshow.
If you are looking for examples that demonstrate how to use the C
API, take a look at these clients: Obtain a source distribution
and look in its client
directory. See
Section 2.1.2, “How to Get MySQL”.
The following sections provide information on building client programs that use the C API. Topics include compiling and linking clients, writing threaded clients, and troubleshooting runtime problems.
This section provides guidelines for compiling C programs that use the MySQL C API.
The examples here use gcc as the compiler. A different compiler might be appropriate on some systems (for example, clang on OS X or FreeBSD, or Sun Studio on Solaris). Adjust the examples as necessary.
You may need to specify an -I
option when you
compile client programs that use MySQL header files, so that the
compiler can find them. For example, if the header files are
installed in /usr/local/mysql/include
, use
this option in the compile command:
-I/usr/local/mysql/include
MySQL clients must be linked using the
-lmysqlclient
option in the link command. You
may also need to specify a -L
option to tell
the linker where to find the library. For example, if the
library is installed in
/usr/local/mysql/lib
, use these options in
the link command:
-L/usr/local/mysql/lib -lmysqlclient
The path names may differ on your system. Adjust the
-I
and -L
options as
necessary.
To make it simpler to compile MySQL programs on Unix, use the mysql_config script. See Section 4.7.2, “mysql_config — Display Options for Compiling Clients”.
mysql_config displays the options needed for compiling or linking:
shell>mysql_config --cflags
shell>mysql_config --libs
You can run those commands to get the proper options and add them manually to compilation or link commands. Alternatively, include the output from mysql_config directly within command lines using backticks:
shell>gcc -c `mysql_config --cflags` progname.c
shell>gcc -o progname progname.o `mysql_config --libs`
On Unix, linking uses dynamic libraries by default. To link to
the static client library instead, add its path name to the link
command. For example, if the library is located in
/usr/local/mysql/lib
, link like this:
shell> gcc -o progname progname.o /usr/local/mysql/lib/libmysqlclient.a
Or use mysql_config to provide the library name:
shell> gcc -o progname progname.o `mysql_config --variable=pkglibdir`/libmysqlclient.a
mysql_config does not currently provide a way
to list all libraries needed for static linking, so it might be
necessary to name additional libraries on the link command (for
example, -lnsl -lsocket
on Solaris). To get
an idea which libraries to add, use mysql_config
--libs and ldd libmysqlclient.so
(or otool -L libmysqlclient.dylib on OS X).
To specify header and library file locations, use the facilities provided by your development environment.
To build C API clients on Windows, you must link in the C client library, as well as the Windows ws2_32 sockets library and Secur32 security library.
On Windows, you can link your code with either the dynamic or
static C client library. The static library is named
mysqlclient.lib
and the dynamic library is
named libmysql.dll
. In addition, the
libmysql.lib
static import library is
needed for using the dynamic library.
If you link with the static library, failure can occur unless these conditions are satisfied:
The client application must be compiled with the same version of Visual Studio used to compile the library.
The client application should link the C runtime statically
by using the /MT
compiler option.
If the client application is built in debug mode and uses the
static debug C runtime (/MTd
compiler
option), it can link to the mysqlclient.lib
static library if that library was built using the same option.
If the client application uses the dynamic C runtime
(/MD
option, or /MDd
option in debug mode), it must be linked to the
libmysql.dll
dynamic library. It cannot
link to the static client library.
The MSDN page describing the link options can be found here: http://msdn.microsoft.com/en-us/library/2kzt1wy3.aspx
If the linker cannot find the MySQL client library, you might
get undefined-reference errors for symbols that start with
mysql_
, such as those shown here:
/tmp/ccFKsdPa.o: In function `main': /tmp/ccFKsdPa.o(.text+0xb): undefined reference to `mysql_init' /tmp/ccFKsdPa.o(.text+0x31): undefined reference to `mysql_real_connect' /tmp/ccFKsdPa.o(.text+0x69): undefined reference to `mysql_error' /tmp/ccFKsdPa.o(.text+0x9a): undefined reference to `mysql_close'
You should be able to solve this problem by adding
-L
at the end of your link command, where
dir_path
-lmysqlclientdir_path
represents the path name of
the directory where the client library is located. To determine
the correct directory, try this command:
shell> mysql_config --libs
The output from mysql_config might indicate other libraries that should be specified on the link command as well. You can include mysql_config output directly in your compile or link command using backticks. For example:
shell> gcc -o progname progname.o `mysql_config --libs`
If an error occurs at link time that the
floor
symbol is undefined, link to the math
library by adding -lm
to the end of the
compile/link line. Similarly, if you get undefined-reference
errors for other functions that should exist on your system,
such as connect()
, check the manual page for
the function in question to determine which libraries you should
add to the link command.
If you get undefined-reference errors such as the following for functions that do not exist on your system, it usually means that your MySQL client library was compiled on a system that is not 100% compatible with yours:
mf_format.o(.text+0x201): undefined reference to `__lxstat'
In this case, you should download the latest MySQL or Connector/C source distribution and compile the MySQL client library yourself. See Section 2.9, “Installing MySQL from Source”, and MySQL Connector/C Developer Guide.
The client library is almost thread-safe. The biggest problem is
that the subroutines in sql/net_serv.cc
that read from sockets are not interrupt-safe. This was done
with the thought that you might want to have your own alarm that
can break a long read to a server. If you install interrupt
handlers for the SIGPIPE
interrupt, socket
handling should be thread-safe.
To avoid aborting the program when a connection terminates,
MySQL blocks SIGPIPE
on the first call to
mysql_library_init()
,
mysql_init()
, or
mysql_connect()
. To use your own
SIGPIPE
handler, first call
mysql_library_init()
, then
install your handler.
If “undefined symbol” errors occur when linking
against the libmysqlclient
client library, in
most cases this is because you have not included the thread
libraries on the link/compile command.
The client library is thread-safe per connection. You can let two threads share the same connection with the following caveats:
Multiple threads cannot send a query to the MySQL server at
the same time on the same connection. In particular, you
must ensure that between calls to
mysql_query()
and
mysql_store_result()
in one
thread, no other thread uses the same connection. You must
have a mutex lock around your pair of
mysql_query()
and
mysql_store_result()
calls.
After mysql_store_result()
returns, the lock can be released and other threads may
query the same connection.
If you use POSIX threads, you can use
pthread_mutex_lock()
and
pthread_mutex_unlock()
to establish and
release a mutex lock.
Many threads can access different result sets that are
retrieved with
mysql_store_result()
.
To use mysql_use_result()
,
you must ensure that no other thread is using the same
connection until the result set is closed. However, it
really is best for threaded clients that share the same
connection to use
mysql_store_result()
.
You need to know the following if you have a thread that did not create the connection to the MySQL database but is calling MySQL functions:
When you call mysql_init()
,
MySQL creates a thread-specific variable for the thread that is
used by the debug library (among other things). If you call a
MySQL function before the thread has called
mysql_init()
, the thread does
not have the necessary thread-specific variables in place and
you are likely to end up with a core dump sooner or later. To
avoid problems, you must do the following:
Call mysql_library_init()
before any other MySQL functions. It is not thread-safe, so
call it before threads are created, or protect the call with
a mutex.
Arrange for
mysql_thread_init()
to be
called early in the thread handler before calling any MySQL
function. If you call
mysql_init()
, it will call
mysql_thread_init()
for you.
In the thread, call
mysql_thread_end()
before
calling pthread_exit()
. This frees the
memory used by MySQL thread-specific variables.
The preceding notes regarding
mysql_init()
also apply to
mysql_connect()
, which calls
mysql_init()
.
If, after an upgrade, you experience problems with compiled
client programs, such as Commands out of sync
or unexpected core dumps, the programs were probably compiled
using old header or library files. In this case, check the date
of the mysql.h
file and
libmysqlclient.a
library used for
compilation to verify that they are from the new MySQL
distribution. If not, recompile the programs with the new
headers and libraries. Recompilation might also be necessary for
programs compiled against the shared client library if the
library major version number has changed (for example, from
libmysqlclient.so.17
to
libmysqlclient.so.18
).
The major client library version determines compatibility. (For
example, for libmysqlclient.so.18.1.0
, the
major version is 18.) For this reason, the libraries shipped
with newer versions of MySQL are drop-in replacements for older
versions that have the same major number. As long as the major
library version is the same, you can upgrade the library and old
applications should continue to work with it.
Undefined-reference errors might occur at runtime when you try
to execute a MySQL program. If these errors specify symbols that
start with mysql_
or indicate that the
libmysqlclient
library cannot be found, it
means that your system cannot find the shared
libmysqlclient.so
library. The solution to
this problem is to tell your system to search for shared
libraries in the directory where that library is located. Use
whichever of the following methods is appropriate for your
system:
Add the path of the directory where
libmysqlclient.so
is located to the
LD_LIBRARY_PATH
or
LD_LIBRARY
environment variable.
On OS X, add the path of the directory where
libmysqlclient.dylib
is located to the
DYLD_LIBRARY_PATH
environment variable.
Copy the shared-library files (such as
libmysqlclient.so
) to some directory
that is searched by your system, such as
/lib
, and update the shared library
information by executing ldconfig
. Be
sure to copy all related files. A shared library might exist
under several names, using symlinks to provide the alternate
names.
If the application is linked to the embedded server library,
runtime error messages will indicate the
libmysqld
rather than
libmysqlclient
library, but the solution to
the problem is the same as just described.
The string and numeric forms of the MySQL server version are
available at compile time as the values of the
MYSQL_SERVER_VERSION
and
MYSQL_VERSION_ID
macros, and at runtime as
the values of the
mysql_get_server_info()
and
mysql_get_server_version()
functions.
The client library version is the MySQL version. For
Connector/C, this is the MySQL version on which the Connector/C
distribution is based. The string and numeric forms of this
version are available at compile time as the values of the
MYSQL_SERVER_VERSION
and
MYSQL_VERSION_ID
macros, and at runtime as
the values of the
mysql_get_client_info()
and
mysql_get_client_version()
functions.
This section describes C API data structures other than those used for prepared statements. For information about the latter, see Section 23.8.9, “C API Prepared Statement Data Structures”.
This structure represents a handle to one database connection.
It is used for almost all MySQL functions. Do not try to make
a copy of a MYSQL
structure. There is no
guarantee that such a copy will be usable.
This structure represents the result of a query that returns
rows (SELECT
,
SHOW
,
DESCRIBE
,
EXPLAIN
). The information
returned from a query is called the result
set in the remainder of this section.
This is a type-safe representation of one row of data. It is
currently implemented as an array of counted byte strings.
(You cannot treat these as null-terminated strings if field
values may contain binary data, because such values may
contain null bytes internally.) Rows are obtained by calling
mysql_fetch_row()
.
This structure contains metadata: information about a field,
such as the field's name, type, and size. Its members are
described in more detail later in this section. You may obtain
the MYSQL_FIELD
structures for each field
by calling mysql_fetch_field()
repeatedly. Field values are not part of this structure; they
are contained in a MYSQL_ROW
structure.
This is a type-safe representation of an offset into a MySQL
field list. (Used by
mysql_field_seek()
.) Offsets
are field numbers within a row, beginning at zero.
The type used for the number of rows and for
mysql_affected_rows()
,
mysql_num_rows()
, and
mysql_insert_id()
. This type
provides a range of 0
to
1.84e19
.
Some functions that return a row count using this type return
-1 as an unsigned value to indicate an error or exceptional
condition. You can check for -1 by comparing the return value
to (my_ulonglong)-1
(or to
(my_ulonglong)~0
, which is equivalent).
On some systems, attempting to print a value of type
my_ulonglong
does not work. To print such a
value, convert it to unsigned long
and use
a %lu
print format. Example:
printf ("Number of rows: %lu\n", (unsigned long) mysql_num_rows(result));
A boolean type, for values that are true (nonzero) or false (zero).
The MYSQL_FIELD
structure contains the members
described in the following list. The definitions apply primarily
for columns of result sets such as those produced by
SELECT
statements. As of MySQL
5.5.3, MYSQL_FIELD
structures are also used to
provide metadata for OUT
and
INOUT
parameters returned from stored
procedures executed using prepared
CALL
statements. For such
parameters, some of the structure members have a meaning different
from the meaning for column values.
char * name
The name of the field, as a null-terminated string. If the
field was given an alias with an AS
clause,
the value of name
is the alias. For a
procedure parameter, the parameter name.
char * org_name
The name of the field, as a null-terminated string. Aliases are ignored. For expressions, the value is an empty string. For a procedure parameter, the parameter name.
char * table
The name of the table containing this field, if it is not a
calculated field. For calculated fields, the
table
value is an empty string. If the
column is selected from a view, table
names
the view. If the table or view was given an alias with an
AS
clause, the value of
table
is the alias. For a
UNION
, the value is the empty
string. For a procedure parameter, the procedure name.
char * org_table
The name of the table, as a null-terminated string. Aliases
are ignored. If the column is selected from a view,
org_table
names the view. For a
UNION
, the value is the empty
string. For a procedure parameter, the procedure name.
char * db
The name of the database that the field comes from, as a
null-terminated string. If the field is a calculated field,
db
is an empty string. For a
UNION
, the value is the empty
string. For a procedure parameter, the name of the database
containing the procedure.
char * catalog
The catalog name. This value is always
"def"
.
char * def
The default value of this field, as a null-terminated string.
This is set only if you use
mysql_list_fields()
.
unsigned long length
The width of the field. This corresponds to the display length, in bytes.
The server determines the length
value
before it generates the result set, so this is the minimum
length required for a data type capable of holding the largest
possible value from the result column, without knowing in
advance the actual values that will be produced by the query
for the result set.
unsigned long max_length
The maximum width of the field for the result set (the length
in bytes of the longest field value for the rows actually in
the result set). If you use
mysql_store_result()
or
mysql_list_fields()
, this
contains the maximum length for the field. If you use
mysql_use_result()
, the value
of this variable is zero.
The value of max_length
is the length of
the string representation of the values in the result set. For
example, if you retrieve a
FLOAT
column and the
“widest” value is -12.345
,
max_length
is 7 (the length of
'-12.345'
).
If you are using prepared statements,
max_length
is not set by default because
for the binary protocol the lengths of the values depend on
the types of the values in the result set. (See
Section 23.8.9, “C API Prepared Statement Data Structures”.)
If you want the max_length
values anyway,
enable the STMT_ATTR_UPDATE_MAX_LENGTH
option with
mysql_stmt_attr_set()
and the
lengths will be set when you call
mysql_stmt_store_result()
.
(See Section 23.8.11.3, “mysql_stmt_attr_set()”, and
Section 23.8.11.28, “mysql_stmt_store_result()”.)
unsigned int name_length
The length of name
.
unsigned int org_name_length
The length of org_name
.
unsigned int table_length
The length of table
.
unsigned int org_table_length
The length of org_table
.
unsigned int db_length
The length of db
.
unsigned int catalog_length
The length of catalog
.
unsigned int def_length
The length of def
.
unsigned int flags
Bit-flags that describe the field. The
flags
value may have zero or more of the
bits set that are shown in the following table.
Flag Value | Flag Description |
---|---|
NOT_NULL_FLAG | Field cannot be NULL |
PRI_KEY_FLAG | Field is part of a primary key |
UNIQUE_KEY_FLAG | Field is part of a unique key |
MULTIPLE_KEY_FLAG | Field is part of a nonunique key |
UNSIGNED_FLAG | Field has the UNSIGNED attribute |
ZEROFILL_FLAG | Field has the ZEROFILL attribute |
BINARY_FLAG | Field has the BINARY attribute |
AUTO_INCREMENT_FLAG | Field has the AUTO_INCREMENT attribute |
ENUM_FLAG | Field is an ENUM |
SET_FLAG | Field is a SET |
BLOB_FLAG | Field is a BLOB or
TEXT (deprecated) |
TIMESTAMP_FLAG | Field is a TIMESTAMP (deprecated) |
NUM_FLAG | Field is numeric; see additional notes following table |
NO_DEFAULT_VALUE_FLAG | Field has no default value; see additional notes following table |
Some of these flags indicate data type information and are
superseded by or used in conjunction with the
MYSQL_TYPE_
value in the xxx
field->type
member
described later:
To check for BLOB
or
TIMESTAMP
values, check
whether type
is
MYSQL_TYPE_BLOB
or
MYSQL_TYPE_TIMESTAMP
. (The
BLOB_FLAG
and
TIMESTAMP_FLAG
flags are unneeded.)
ENUM
and
SET
values are returned as
strings. For these, check that the type
value is MYSQL_TYPE_STRING
and that the
ENUM_FLAG
or
SET_FLAG
flag is set in the
flags
value.
NUM_FLAG
indicates that a column is
numeric. This includes columns with a type of
MYSQL_TYPE_DECIMAL
,
MYSQL_TYPE_NEWDECIMAL
,
MYSQL_TYPE_TINY
,
MYSQL_TYPE_SHORT
,
MYSQL_TYPE_LONG
,
MYSQL_TYPE_FLOAT
,
MYSQL_TYPE_DOUBLE
,
MYSQL_TYPE_NULL
,
MYSQL_TYPE_LONGLONG
,
MYSQL_TYPE_INT24
, and
MYSQL_TYPE_YEAR
.
NO_DEFAULT_VALUE_FLAG
indicates that a
column has no DEFAULT
clause in its
definition. This does not apply to NULL
columns (because such columns have a default of
NULL
), or to
AUTO_INCREMENT
columns (which have an
implied default value).
The following example illustrates a typical use of the
flags
value:
if (field->flags & NOT_NULL_FLAG) printf("Field cannot be null\n");
You may use the convenience macros shown in the following
table to determine the boolean status of the
flags
value.
unsigned int decimals
The number of decimals for numeric fields.
unsigned int charsetnr
An ID number that indicates the character set/collation pair for the field.
Normally, character values in result sets are converted to the
character set indicated by the
character_set_results
system
variable. In this case, charsetnr
corresponds to the character set indicated by that variable.
Character set conversion can be suppressed by setting
character_set_results
to
NULL
. In this case,
charsetnr
corresponds to the character set
of the original table column or expression. See also
Section 10.1.4, “Connection Character Sets and Collations”.
To distinguish between binary and nonbinary data for string
data types, check whether the charsetnr
value is 63. If so, the character set is
binary
, which indicates binary rather than
nonbinary data. This enables you to distinguish
BINARY
from
CHAR
,
VARBINARY
from
VARCHAR
, and the
BLOB
types from the
TEXT
types.
charsetnr
values are the same as those
displayed in the Id
column of the
SHOW COLLATION
statement or the
ID
column of the
INFORMATION_SCHEMA
COLLATIONS
table. You can use
those information sources to see which character set and
collation specific charsetnr
values
indicate:
mysql>SHOW COLLATION WHERE Id = 63;
+-----------+---------+----+---------+----------+---------+ | Collation | Charset | Id | Default | Compiled | Sortlen | +-----------+---------+----+---------+----------+---------+ | binary | binary | 63 | Yes | Yes | 1 | +-----------+---------+----+---------+----------+---------+ mysql>SELECT COLLATION_NAME, CHARACTER_SET_NAME
->FROM INFORMATION_SCHEMA.COLLATIONS WHERE ID = 33;
+-----------------+--------------------+ | COLLATION_NAME | CHARACTER_SET_NAME | +-----------------+--------------------+ | utf8_general_ci | utf8 | +-----------------+--------------------+
enum enum_field_types type
The type of the field. The type
value may
be one of the MYSQL_TYPE_
symbols shown in
the following table.
Type Value | Type Description |
---|---|
MYSQL_TYPE_TINY | TINYINT field |
MYSQL_TYPE_SHORT | SMALLINT field |
MYSQL_TYPE_LONG | INTEGER field |
MYSQL_TYPE_INT24 | MEDIUMINT field |
MYSQL_TYPE_LONGLONG | BIGINT field |
MYSQL_TYPE_DECIMAL | DECIMAL or
NUMERIC field |
MYSQL_TYPE_NEWDECIMAL | Precision math DECIMAL or
NUMERIC |
MYSQL_TYPE_FLOAT | FLOAT field |
MYSQL_TYPE_DOUBLE | DOUBLE or
REAL field |
MYSQL_TYPE_BIT | BIT field |
MYSQL_TYPE_TIMESTAMP | TIMESTAMP field |
MYSQL_TYPE_DATE | DATE field |
MYSQL_TYPE_TIME | TIME field |
MYSQL_TYPE_DATETIME | DATETIME field |
MYSQL_TYPE_YEAR | YEAR field |
MYSQL_TYPE_STRING | CHAR or
BINARY field |
MYSQL_TYPE_VAR_STRING | VARCHAR or
VARBINARY field |
MYSQL_TYPE_BLOB | BLOB or
TEXT field (use
max_length to determine the maximum
length) |
MYSQL_TYPE_SET | SET field |
MYSQL_TYPE_ENUM | ENUM field |
MYSQL_TYPE_GEOMETRY | Spatial field |
MYSQL_TYPE_NULL | NULL -type field |
You can use the IS_NUM()
macro to test
whether a field has a numeric type. Pass the
type
value to IS_NUM()
and it evaluates to TRUE if the field is numeric:
if (IS_NUM(field->type)) printf("Field is numeric\n");
ENUM
and
SET
values are returned as
strings. For these, check that the type
value is MYSQL_TYPE_STRING
and that the
ENUM_FLAG
or SET_FLAG
flag is set in the flags
value.
The functions available in the C API are summarized here and described in greater detail in a later section. See Section 23.8.7, “C API Function Descriptions”.
Table 23.4 C API Function Names and Descriptions
Function | Description |
---|---|
my_init() | Initialize global variables, and thread handler in thread-safe programs |
mysql_affected_rows() | Returns the number of rows changed/deleted/inserted by the last
UPDATE ,
DELETE , or
INSERT query |
mysql_autocommit() | Toggles autocommit mode on/off |
mysql_change_user() | Changes user and database on an open connection |
mysql_character_set_name() | Return default character set name for current connection |
mysql_client_find_plugin() | Return pointer to plugin |
mysql_client_register_plugin() | Register a plugin |
mysql_close() | Closes a server connection |
mysql_commit() | Commits the transaction |
mysql_connect() | Connects to a MySQL server (this function is deprecated; use
mysql_real_connect()
instead) |
mysql_create_db() | Creates a database (this function is deprecated; use the SQL statement
CREATE DATABASE instead) |
mysql_data_seek() | Seeks to an arbitrary row number in a query result set |
mysql_debug() | Does a DBUG_PUSH with the given string |
mysql_drop_db() | Drops a database (this function is deprecated; use the SQL statement
DROP DATABASE instead) |
mysql_dump_debug_info() | Makes the server write debug information to the log |
mysql_eof() | Determines whether the last row of a result set has been read (this
function is deprecated;
mysql_errno() or
mysql_error() may be used
instead) |
mysql_errno() | Returns the error number for the most recently invoked MySQL function |
mysql_error() | Returns the error message for the most recently invoked MySQL function |
mysql_escape_string() | Escapes special characters in a string for use in an SQL statement |
mysql_fetch_field() | Returns the type of the next table field |
mysql_fetch_field_direct() | Returns the type of a table field, given a field number |
mysql_fetch_fields() | Returns an array of all field structures |
mysql_fetch_lengths() | Returns the lengths of all columns in the current row |
mysql_fetch_row() | Fetches the next row from the result set |
mysql_field_count() | Returns the number of result columns for the most recent statement |
mysql_field_seek() | Puts the column cursor on a specified column |
mysql_field_tell() | Returns the position of the field cursor used for the last
mysql_fetch_field() |
mysql_free_result() | Frees memory used by a result set |
mysql_get_character_set_info() | Return information about default character set |
mysql_get_client_info() | Returns client version information as a string |
mysql_get_client_version() | Returns client version information as an integer |
mysql_get_host_info() | Returns a string describing the connection |
mysql_get_proto_info() | Returns the protocol version used by the connection |
mysql_get_server_info() | Returns the server version number |
mysql_get_server_version() | Returns version number of server as an integer |
mysql_get_ssl_cipher() | Return current SSL cipher |
mysql_hex_string() | Encode string in hexadecimal format |
mysql_info() | Returns information about the most recently executed query |
mysql_init() | Gets or initializes a MYSQL structure |
mysql_insert_id() | Returns the ID generated for an AUTO_INCREMENT column
by the previous query |
mysql_kill() | Kills a given thread |
mysql_library_end() | Finalize the MySQL C API library |
mysql_library_init() | Initialize the MySQL C API library |
mysql_list_dbs() | Returns database names matching a simple regular expression |
mysql_list_fields() | Returns field names matching a simple regular expression |
mysql_list_processes() | Returns a list of the current server threads |
mysql_list_tables() | Returns table names matching a simple regular expression |
mysql_load_plugin() | Load a plugin |
mysql_load_plugin_v() | Load a plugin |
mysql_more_results() | Checks whether any more results exist |
mysql_next_result() | Returns/initiates the next result in multiple-result executions |
mysql_num_fields() | Returns the number of columns in a result set |
mysql_num_rows() | Returns the number of rows in a result set |
mysql_options() | Sets connect options for
mysql_real_connect() |
mysql_ping() | Checks whether the connection to the server is working, reconnecting as necessary |
mysql_plugin_options() | Set a plugin option |
mysql_query() | Executes an SQL query specified as a null-terminated string |
mysql_real_connect() | Connects to a MySQL server |
mysql_real_escape_string() | Escapes special characters in a string for use in an SQL statement, taking into account the current character set of the connection |
mysql_real_query() | Executes an SQL query specified as a counted string |
mysql_refresh() | Flush or reset tables and caches |
mysql_reload() | Tells the server to reload the grant tables |
mysql_rollback() | Rolls back the transaction |
mysql_row_seek() | Seeks to a row offset in a result set, using value returned from
mysql_row_tell() |
mysql_row_tell() | Returns the row cursor position |
mysql_select_db() | Selects a database |
mysql_server_end() | Finalize the MySQL C API library |
mysql_server_init() | Initialize the MySQL C API library |
mysql_set_character_set() | Set default character set for current connection |
mysql_set_local_infile_default() | Set the LOAD DATA LOCAL
INFILE handler callbacks to their default values |
mysql_set_local_infile_handler() | Install application-specific
LOAD DATA LOCAL
INFILE handler callbacks |
mysql_set_server_option() | Sets an option for the connection (like
multi-statements ) |
mysql_sqlstate() | Returns the SQLSTATE error code for the last error |
mysql_shutdown() | Shuts down the database server |
mysql_ssl_set() | Prepare to establish SSL connection to server |
mysql_stat() | Returns the server status as a string |
mysql_store_result() | Retrieves a complete result set to the client |
mysql_thread_end() | Finalize thread handler |
mysql_thread_id() | Returns the current thread ID |
mysql_thread_init() | Initialize thread handler |
mysql_thread_safe() | Returns 1 if the clients are compiled as thread-safe |
mysql_use_result() | Initiates a row-by-row result set retrieval |
mysql_warning_count() | Returns the warning count for the previous SQL statement |
Application programs should use this general outline for interacting with MySQL:
Initialize the MySQL library by calling
mysql_library_init()
. This
function exists in both the libmysqlclient
C client library and the libmysqld
embedded
server library, so it is used whether you build a regular
client program by linking with the
-libmysqlclient
flag, or an embedded server
application by linking with the -libmysqld
flag.
Initialize a connection handler by calling
mysql_init()
and connect to
the server by calling
mysql_real_connect()
.
Issue SQL statements and process their results. (The following discussion provides more information about how to do this.)
Close the connection to the MySQL server by calling
mysql_close()
.
End use of the MySQL library by calling
mysql_library_end()
.
The purpose of calling
mysql_library_init()
and
mysql_library_end()
is to provide
proper initialization and finalization of the MySQL library. For
applications that are linked with the client library, they provide
improved memory management. If you do not call
mysql_library_end()
, a block of
memory remains allocated. (This does not increase the amount of
memory used by the application, but some memory leak detectors
will complain about it.) For applications that are linked with the
embedded server, these calls start and stop the server.
In a nonmulti-threaded environment, the call to
mysql_library_init()
may be
omitted, because mysql_init()
will
invoke it automatically as necessary. However,
mysql_library_init()
is not
thread-safe in a multi-threaded environment, and thus neither is
mysql_init()
, which calls
mysql_library_init()
. You must
either call mysql_library_init()
prior to spawning any threads, or else use a mutex to protect the
call, whether you invoke
mysql_library_init()
or indirectly
through mysql_init()
. This should
be done prior to any other client library call.
To connect to the server, call
mysql_init()
to initialize a
connection handler, then call
mysql_real_connect()
with that
handler (along with other information such as the host name, user
name, and password). Upon connection,
mysql_real_connect()
sets the
reconnect
flag (part of the
MYSQL
structure) to a value of
1
in versions of the API older than 5.0.3, or
0
in newer versions. A value of
1
for this flag indicates that if a statement
cannot be performed because of a lost connection, to try
reconnecting to the server before giving up. You can use the
MYSQL_OPT_RECONNECT
option to
mysql_options()
to control
reconnection behavior. When you are done with the connection, call
mysql_close()
to terminate it.
While a connection is active, the client may send SQL statements
to the server using mysql_query()
or mysql_real_query()
. The
difference between the two is that
mysql_query()
expects the query to
be specified as a null-terminated string whereas
mysql_real_query()
expects a
counted string. If the string contains binary data (which may
include null bytes), you must use
mysql_real_query()
.
For each non-SELECT
query (for
example, INSERT
,
UPDATE
,
DELETE
), you can find out how many
rows were changed (affected) by calling
mysql_affected_rows()
.
For SELECT
queries, you retrieve
the selected rows as a result set. (Note that some statements are
SELECT
-like in that they return
rows. These include SHOW
,
DESCRIBE
, and
EXPLAIN
. Treat these statements the
same way as SELECT
statements.)
There are two ways for a client to process result sets. One way is
to retrieve the entire result set all at once by calling
mysql_store_result()
. This
function acquires from the server all the rows returned by the
query and stores them in the client. The second way is for the
client to initiate a row-by-row result set retrieval by calling
mysql_use_result()
. This function
initializes the retrieval, but does not actually get any rows from
the server.
In both cases, you access rows by calling
mysql_fetch_row()
. With
mysql_store_result()
,
mysql_fetch_row()
accesses rows
that have previously been fetched from the server. With
mysql_use_result()
,
mysql_fetch_row()
actually
retrieves the row from the server. Information about the size of
the data in each row is available by calling
mysql_fetch_lengths()
.
After you are done with a result set, call
mysql_free_result()
to free the
memory used for it.
The two retrieval mechanisms are complementary. Choose the
approach that is most appropriate for each client application. In
practice, clients tend to use
mysql_store_result()
more
commonly.
An advantage of
mysql_store_result()
is that
because the rows have all been fetched to the client, you not only
can access rows sequentially, you can move back and forth in the
result set using mysql_data_seek()
or mysql_row_seek()
to change the
current row position within the result set. You can also find out
how many rows there are by calling
mysql_num_rows()
. On the other
hand, the memory requirements for
mysql_store_result()
may be very
high for large result sets and you are more likely to encounter
out-of-memory conditions.
An advantage of mysql_use_result()
is that the client requires less memory for the result set because
it maintains only one row at a time (and because there is less
allocation overhead,
mysql_use_result()
can be faster).
Disadvantages are that you must process each row quickly to avoid
tying up the server, you do not have random access to rows within
the result set (you can only access rows sequentially), and the
number of rows in the result set is unknown until you have
retrieved them all. Furthermore, you must
retrieve all the rows even if you determine in mid-retrieval that
you've found the information you were looking for.
The API makes it possible for clients to respond appropriately to
statements (retrieving rows only as necessary) without knowing
whether the statement is a SELECT
.
You can do this by calling
mysql_store_result()
after each
mysql_query()
(or
mysql_real_query()
). If the result
set call succeeds, the statement was a
SELECT
and you can read the rows.
If the result set call fails, call
mysql_field_count()
to determine
whether a result was actually to be expected. If
mysql_field_count()
returns zero,
the statement returned no data (indicating that it was an
INSERT
,
UPDATE
,
DELETE
, and so forth), and was not
expected to return rows. If
mysql_field_count()
is nonzero,
the statement should have returned rows, but did not. This
indicates that the statement was a
SELECT
that failed. See the
description for
mysql_field_count()
for an example
of how this can be done.
Both mysql_store_result()
and
mysql_use_result()
enable you to
obtain information about the fields that make up the result set
(the number of fields, their names and types, and so forth). You
can access field information sequentially within the row by
calling mysql_fetch_field()
repeatedly, or by field number within the row by calling
mysql_fetch_field_direct()
. The
current field cursor position may be changed by calling
mysql_field_seek()
. Setting the
field cursor affects subsequent calls to
mysql_fetch_field()
. You can also
get information for fields all at once by calling
mysql_fetch_fields()
.
For detecting and reporting errors, MySQL provides access to error
information by means of the
mysql_errno()
and
mysql_error()
functions. These
return the error code or error message for the most recently
invoked function that can succeed or fail, enabling you to
determine when an error occurred and what it was.
In the descriptions here, a parameter or return value of
NULL
means NULL
in the sense
of the C programming language, not a MySQL NULL
value.
Functions that return a value generally return a pointer or an
integer. Unless specified otherwise, functions returning a pointer
return a non-NULL
value to indicate success or
a NULL
value to indicate an error, and
functions returning an integer return zero to indicate success or
nonzero to indicate an error. Note that “nonzero”
means just that. Unless the function description says otherwise,
do not test against a value other than zero:
if (result) /* correct */ ... error ... if (result < 0) /* incorrect */ ... error ... if (result == -1) /* incorrect */ ... error ...
When a function returns an error, the
Errors subsection of the function
description lists the possible types of errors. You can find out
which of these occurred by calling
mysql_errno()
. A string
representation of the error may be obtained by calling
mysql_error()
.
my_ulonglong mysql_affected_rows(MYSQL
*mysql)
mysql_affected_rows()
may be
called immediately after executing a statement with
mysql_query()
or
mysql_real_query()
. It returns
the number of rows changed, deleted, or inserted by the last
statement if it was an UPDATE
,
DELETE
, or
INSERT
. For
SELECT
statements,
mysql_affected_rows()
works like
mysql_num_rows()
.
For UPDATE
statements, the
affected-rows value by default is the number of rows actually
changed. If you specify the CLIENT_FOUND_ROWS
flag to mysql_real_connect()
when connecting to mysqld, the affected-rows
value is the number of rows “found”; that is,
matched by the WHERE
clause.
For REPLACE
statements, the
affected-rows value is 2 if the new row replaced an old row,
because in this case, one row was inserted after the duplicate
was deleted.
For INSERT
... ON DUPLICATE KEY UPDATE
statements, the
affected-rows value per row is 1 if the row is inserted as a new
row, 2 if an existing row is updated, and 0 if an existing row
is set to its current values. If you specify the
CLIENT_FOUND_ROWS
flag, the affected-rows
value is 1 (not 0) if an existing row is set to its current
values.
Following a CALL
statement for a
stored procedure,
mysql_affected_rows()
returns
the value that it would return for the last statement executed
within the procedure, or 0
if that statement
would return -1
. Within the procedure, you
can use ROW_COUNT()
at the SQL
level to obtain the affected-rows value for individual
statements.
As of MySQL 5.5.5,
mysql_affected_rows()
returns a
meaningful value for a wider range of statements. For details,
see the description for
ROW_COUNT()
in
Section 12.14, “Information Functions”.
An integer greater than zero indicates the number of rows
affected or retrieved. Zero indicates that no records were
updated for an UPDATE
statement,
no rows matched the WHERE
clause in the query
or that no query has yet been executed. -1 indicates that the
query returned an error or that, for a
SELECT
query,
mysql_affected_rows()
was called
prior to calling
mysql_store_result()
.
Because mysql_affected_rows()
returns an unsigned value, you can check for -1 by comparing the
return value to (my_ulonglong)-1
(or to
(my_ulonglong)~0
, which is equivalent).
None.
char *stmt = "UPDATE products SET cost=cost*1.25 WHERE group=10"; mysql_query(&mysql,stmt); printf("%ld products updated", (long) mysql_affected_rows(&mysql));
my_bool mysql_autocommit(MYSQL *mysql, my_bool
mode)
Sets autocommit mode on if mode
is 1, off if
mode
is 0.
Zero for success. Nonzero if an error occurred.
None.
my_bool mysql_change_user(MYSQL *mysql, const char
*user, const char *password, const char *db)
Changes the user and causes the database specified by
db
to become the default (current) database
on the connection specified by mysql
. In
subsequent queries, this database is the default for table
references that include no explicit database specifier.
mysql_change_user()
fails if the
connected user cannot be authenticated or does not have
permission to use the database. In this case, the user and
database are not changed.
Pass a db
parameter of
NULL
if you do not want to have a default
database.
This function resets the session state as if one had done a new
connect and reauthenticated. (See
Section 23.8.16, “Controlling Automatic Reconnection Behavior”.) It always performs a
ROLLBACK
of
any active transactions, closes and drops all temporary tables,
and unlocks all locked tables. Session system variables are
reset to the values of the corresponding global system
variables. Prepared statements are released and
HANDLER
variables are closed.
Locks acquired with GET_LOCK()
are released. These effects occur even if the user did not
change.
Zero for success. Nonzero if an error occurred.
The same that you can get from
mysql_real_connect()
, plus:
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
The MySQL server does not implement this command (probably an old server).
The user or password was wrong.
The database did not exist.
The user did not have access rights to the database.
The database name was too long.
if (mysql_change_user(&mysql, "user", "password", "new_database")) { fprintf(stderr, "Failed to change user. Error: %s\n", mysql_error(&mysql)); }
const char *mysql_character_set_name(MYSQL
*mysql)
Returns the default character set name for the current connection.
The default character set name
None.
void mysql_close(MYSQL *mysql)
Closes a previously opened connection.
mysql_close()
also deallocates
the connection handle pointed to by mysql
if
the handle was allocated automatically by
mysql_init()
or
mysql_connect()
.
None.
None.
my_bool mysql_commit(MYSQL *mysql)
Commits the current transaction.
The action of this function is subject to the value of the
completion_type
system
variable. In particular, if the value of
completion_type
is
RELEASE
(or 2), the server performs a release
after terminating a transaction and closes the client
connection. Call mysql_close()
from the client program to close the connection from the client
side.
Zero for success. Nonzero if an error occurred.
None.
MYSQL *mysql_connect(MYSQL *mysql, const char *host,
const char *user, const char *passwd)
This function is deprecated. Use
mysql_real_connect()
instead.
mysql_connect()
attempts to
establish a connection to a MySQL database engine running on
host
.
mysql_connect()
must complete
successfully before you can execute any of the other API
functions, with the exception of
mysql_get_client_info()
.
The meanings of the parameters are the same as for the
corresponding parameters for
mysql_real_connect()
with the
difference that the connection parameter may be
NULL
. In this case, the C API allocates
memory for the connection structure automatically and frees it
when you call mysql_close()
. The
disadvantage of this approach is that you cannot retrieve an
error message if the connection fails. (To get error information
from mysql_errno()
or
mysql_error()
, you must provide
a valid MYSQL
pointer.)
Same as for
mysql_real_connect()
.
Same as for
mysql_real_connect()
.
int mysql_create_db(MYSQL *mysql, const char
*db)
Creates the database named by the db
parameter.
This function is deprecated. It is preferable to use
mysql_query()
to issue an SQL
CREATE DATABASE
statement
instead.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
if(mysql_create_db(&mysql, "my_database")) { fprintf(stderr, "Failed to create new database. Error: %s\n", mysql_error(&mysql)); }
void mysql_data_seek(MYSQL_RES *result, my_ulonglong
offset)
Seeks to an arbitrary row in a query result set. The
offset
value is a row number. Specify a value
in the range from 0
to
mysql_num_rows(result)-1
.
This function requires that the result set structure contains
the entire result of the query, so
mysql_data_seek()
may be used
only in conjunction with
mysql_store_result()
, not with
mysql_use_result()
.
None.
None.
void mysql_debug(const char *debug)
Does a DBUG_PUSH
with the given string.
mysql_debug()
uses the Fred Fish
debug library. To use this function, you must compile the client
library to support debugging. See
Section 24.5.3, “The DBUG Package”.
None.
None.
The call shown here causes the client library to generate a
trace file in /tmp/client.trace
on the
client machine:
mysql_debug("d:t:O,/tmp/client.trace");
int mysql_drop_db(MYSQL *mysql, const char
*db)
Drops the database named by the db
parameter.
This function is deprecated. It is preferable to use
mysql_query()
to issue an SQL
DROP DATABASE
statement instead.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
if(mysql_drop_db(&mysql, "my_database")) fprintf(stderr, "Failed to drop the database: Error: %s\n", mysql_error(&mysql));
int mysql_dump_debug_info(MYSQL *mysql)
Instructs the server to write debugging information to the error
log. The connected user must have the
SUPER
privilege.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
my_bool mysql_eof(MYSQL_RES *result)
This function is deprecated.
mysql_errno()
or
mysql_error()
may be used
instead.
mysql_eof()
determines whether
the last row of a result set has been read.
If you acquire a result set from a successful call to
mysql_store_result()
, the client
receives the entire set in one operation. In this case, a
NULL
return from
mysql_fetch_row()
always means
the end of the result set has been reached and it is unnecessary
to call mysql_eof()
. When used
with mysql_store_result()
,
mysql_eof()
always returns true.
On the other hand, if you use
mysql_use_result()
to initiate a
result set retrieval, the rows of the set are obtained from the
server one by one as you call
mysql_fetch_row()
repeatedly.
Because an error may occur on the connection during this
process, a NULL
return value from
mysql_fetch_row()
does not
necessarily mean the end of the result set was reached normally.
In this case, you can use
mysql_eof()
to determine what
happened. mysql_eof()
returns a
nonzero value if the end of the result set was reached and zero
if an error occurred.
Historically, mysql_eof()
predates the standard MySQL error functions
mysql_errno()
and
mysql_error()
. Because those
error functions provide the same information, their use is
preferred over mysql_eof()
,
which is deprecated. (In fact, they provide more information,
because mysql_eof()
returns only
a boolean value whereas the error functions indicate a reason
for the error when one occurs.)
Zero for success. Nonzero if the end of the result set has been reached.
None.
The following example shows how you might use
mysql_eof()
:
mysql_query(&mysql,"SELECT * FROM some_table"); result = mysql_use_result(&mysql); while((row = mysql_fetch_row(result))) { // do something with data } if(!mysql_eof(result)) // mysql_fetch_row() failed due to an error { fprintf(stderr, "Error: %s\n", mysql_error(&mysql)); }
However, you can achieve the same effect with the standard MySQL error functions:
mysql_query(&mysql,"SELECT * FROM some_table"); result = mysql_use_result(&mysql); while((row = mysql_fetch_row(result))) { // do something with data } if(mysql_errno(&mysql)) // mysql_fetch_row() failed due to an error { fprintf(stderr, "Error: %s\n", mysql_error(&mysql)); }
unsigned int mysql_errno(MYSQL *mysql)
For the connection specified by mysql
,
mysql_errno()
returns the error
code for the most recently invoked API function that can succeed
or fail. A return value of zero means that no error occurred.
Client error message numbers are listed in the MySQL
errmsg.h
header file. Server error message
numbers are listed in mysqld_error.h
.
Errors also are listed at Appendix B, Errors, Error Codes, and Common Problems.
Some functions such as
mysql_fetch_row()
do not set
mysql_errno()
if they succeed.
A rule of thumb is that all functions that have to ask the
server for information reset
mysql_errno()
if they succeed.
MySQL-specific error numbers returned by
mysql_errno()
differ from
SQLSTATE values returned by
mysql_sqlstate()
. For example,
the mysql client program displays errors
using the following format, where 1146
is the
mysql_errno()
value and
'42S02'
is the corresponding
mysql_sqlstate()
value:
shell> SELECT * FROM no_such_table;
ERROR 1146 (42S02): Table 'test.no_such_table' doesn't exist
An error code value for the last
mysql_
call,
if it failed. zero means no error occurred.
xxx
()
None.
const char *mysql_error(MYSQL *mysql)
For the connection specified by mysql
,
mysql_error()
returns a
null-terminated string containing the error message for the most
recently invoked API function that failed. If a function did not
fail, the return value of
mysql_error()
may be the
previous error or an empty string to indicate no error.
A rule of thumb is that all functions that have to ask the
server for information reset
mysql_error()
if they succeed.
For functions that reset
mysql_error()
, either of these
two tests can be used to check for an error:
if(*mysql_error(&mysql)) { // an error occurred } if(mysql_error(&mysql)[0]) { // an error occurred }
The language of the client error messages may be changed by recompiling the MySQL client library. You can choose error messages in several different languages. See Section 10.2, “Setting the Error Message Language”.
A null-terminated character string that describes the error. An empty string if no error occurred.
None.
This function should not be used. Use
mysql_real_escape_string()
instead.
mysql_escape_string()
is
identical to
mysql_real_escape_string()
except that
mysql_real_escape_string()
takes
a connection handler as its first argument and escapes the
string according to the current character set.
mysql_escape_string()
does not
take a connection argument and does not respect the current
character set.
MYSQL_FIELD *mysql_fetch_field(MYSQL_RES
*result)
Returns the definition of one column of a result set as a
MYSQL_FIELD
structure. Call this function
repeatedly to retrieve information about all columns in the
result set. mysql_fetch_field()
returns NULL
when no more fields are left.
mysql_fetch_field()
is reset to
return information about the first field each time you execute a
new SELECT
query. The field
returned by mysql_fetch_field()
is also affected by calls to
mysql_field_seek()
.
If you've called mysql_query()
to perform a SELECT
on a table
but have not called
mysql_store_result()
, MySQL
returns the default blob length (8KB) if you call
mysql_fetch_field()
to ask for
the length of a BLOB
field. (The
8KB size is chosen because MySQL does not know the maximum
length for the BLOB
. This should
be made configurable sometime.) Once you've retrieved the result
set, field->max_length
contains the length
of the largest value for this column in the specific query.
The MYSQL_FIELD
structure for the current
column. NULL
if no columns are left.
None.
MYSQL_FIELD *field; while((field = mysql_fetch_field(result))) { printf("field name %s\n", field->name); }
MYSQL_FIELD *mysql_fetch_field_direct(MYSQL_RES
*result, unsigned int fieldnr)
Given a field number fieldnr
for a column
within a result set, returns that column's field definition as a
MYSQL_FIELD
structure. Use this function to
retrieve the definition for an arbitrary column. Specify a value
for fieldnr
in the range from 0 to
mysql_num_fields(result)-1
.
The MYSQL_FIELD
structure for the specified
column.
None.
unsigned int num_fields; unsigned int i; MYSQL_FIELD *field; num_fields = mysql_num_fields(result); for(i = 0; i < num_fields; i++) { field = mysql_fetch_field_direct(result, i); printf("Field %u is %s\n", i, field->name); }
MYSQL_FIELD *mysql_fetch_fields(MYSQL_RES
*result)
Returns an array of all MYSQL_FIELD
structures for a result set. Each structure provides the field
definition for one column of the result set.
An array of MYSQL_FIELD
structures for all
columns of a result set.
None.
unsigned int num_fields; unsigned int i; MYSQL_FIELD *fields; num_fields = mysql_num_fields(result); fields = mysql_fetch_fields(result); for(i = 0; i < num_fields; i++) { printf("Field %u is %s\n", i, fields[i].name); }
unsigned long *mysql_fetch_lengths(MYSQL_RES
*result)
Returns the lengths of the columns of the current row within a
result set. If you plan to copy field values, this length
information is also useful for optimization, because you can
avoid calling strlen()
. In addition, if the
result set contains binary data, you
must use this function to
determine the size of the data, because
strlen()
returns incorrect results for any
field containing null characters.
The length for empty columns and for columns containing
NULL
values is zero. To see how to
distinguish these two cases, see the description for
mysql_fetch_row()
.
An array of unsigned long integers representing the size of each
column (not including any terminating null bytes).
NULL
if an error occurred.
mysql_fetch_lengths()
is valid
only for the current row of the result set. It returns
NULL
if you call it before calling
mysql_fetch_row()
or after
retrieving all rows in the result.
MYSQL_ROW row; unsigned long *lengths; unsigned int num_fields; unsigned int i; row = mysql_fetch_row(result); if (row) { num_fields = mysql_num_fields(result); lengths = mysql_fetch_lengths(result); for(i = 0; i < num_fields; i++) { printf("Column %u is %lu bytes in length.\n", i, lengths[i]); } }
MYSQL_ROW mysql_fetch_row(MYSQL_RES *result)
Retrieves the next row of a result set. When used after
mysql_store_result()
,
mysql_fetch_row()
returns
NULL
when there are no more rows to retrieve.
When used after
mysql_use_result()
,
mysql_fetch_row()
returns
NULL
when there are no more rows to retrieve
or if an error occurred.
The number of values in the row is given by
mysql_num_fields(result)
. If
row
holds the return value from a call to
mysql_fetch_row()
, pointers to
the values are accessed as row[0]
to
row[mysql_num_fields(result)-1]
.
NULL
values in the row are indicated by
NULL
pointers.
The lengths of the field values in the row may be obtained by
calling mysql_fetch_lengths()
.
Empty fields and fields containing NULL
both
have length 0; you can distinguish these by checking the pointer
for the field value. If the pointer is NULL
,
the field is NULL
; otherwise, the field is
empty.
A MYSQL_ROW
structure for the next row.
NULL
if there are no more rows to retrieve or
if an error occurred.
Errors are not reset between calls to
mysql_fetch_row()
The connection to the server was lost during the query.
An unknown error occurred.
MYSQL_ROW row; unsigned int num_fields; unsigned int i; num_fields = mysql_num_fields(result); while ((row = mysql_fetch_row(result))) { unsigned long *lengths; lengths = mysql_fetch_lengths(result); for(i = 0; i < num_fields; i++) { printf("[%.*s] ", (int) lengths[i], row[i] ? row[i] : "NULL"); } printf("\n"); }
unsigned int mysql_field_count(MYSQL *mysql)
Returns the number of columns for the most recent query on the connection.
The normal use of this function is when
mysql_store_result()
returned
NULL
(and thus you have no result set
pointer). In this case, you can call
mysql_field_count()
to determine
whether mysql_store_result()
should have produced a nonempty result. This enables the client
program to take proper action without knowing whether the query
was a SELECT
(or
SELECT
-like) statement. The
example shown here illustrates how this may be done.
An unsigned integer representing the number of columns in a result set.
None.
MYSQL_RES *result; unsigned int num_fields; unsigned int num_rows; if (mysql_query(&mysql,query_string)) { // error } else // query succeeded, process any data returned by it { result = mysql_store_result(&mysql); if (result) // there are rows { num_fields = mysql_num_fields(result); // retrieve rows, then call mysql_free_result(result) } else // mysql_store_result() returned nothing; should it have? { if(mysql_field_count(&mysql) == 0) { // query does not return data // (it was not a SELECT) num_rows = mysql_affected_rows(&mysql); } else // mysql_store_result() should have returned data { fprintf(stderr, "Error: %s\n", mysql_error(&mysql)); } } }
An alternative is to replace the
mysql_field_count(&mysql)
call with
mysql_errno(&mysql)
. In this
case, you are checking directly for an error from
mysql_store_result()
rather than
inferring from the value of
mysql_field_count()
whether the
statement was a SELECT
.
MYSQL_FIELD_OFFSET mysql_field_seek(MYSQL_RES *result,
MYSQL_FIELD_OFFSET offset)
Sets the field cursor to the given offset. The next call to
mysql_fetch_field()
retrieves
the field definition of the column associated with that offset.
To seek to the beginning of a row, pass an
offset
value of zero.
The previous value of the field cursor.
None.
MYSQL_FIELD_OFFSET mysql_field_tell(MYSQL_RES
*result)
Returns the position of the field cursor used for the last
mysql_fetch_field()
. This value
can be used as an argument to
mysql_field_seek()
.
The current offset of the field cursor.
None.
void mysql_free_result(MYSQL_RES *result)
Frees the memory allocated for a result set by
mysql_store_result()
,
mysql_use_result()
,
mysql_list_dbs()
, and so forth.
When you are done with a result set, you must free the memory it
uses by calling
mysql_free_result()
.
Do not attempt to access a result set after freeing it.
None.
None.
void mysql_get_character_set_info(MYSQL *mysql,
MY_CHARSET_INFO *cs)
This function provides information about the default client
character set. The default character set may be changed with the
mysql_set_character_set()
function.
This example shows the fields that are available in the
MY_CHARSET_INFO
structure:
if (!mysql_set_character_set(&mysql, "utf8")) { MY_CHARSET_INFO cs; mysql_get_character_set_info(&mysql, &cs); printf("character set information:\n"); printf("character set+collation number: %d\n", cs.number); printf("character set name: %s\n", cs.name); printf("collation name: %s\n", cs.csname); printf("comment: %s\n", cs.comment); printf("directory: %s\n", cs.dir); printf("multi byte character min. length: %d\n", cs.mbminlen); printf("multi byte character max. length: %d\n", cs.mbmaxlen); }
const char *mysql_get_client_info(void)
Returns a string that represents the MySQL client library
version; for example, "5.5.50"
.
The function value is the MySQL version. For Connector/C, this is the MySQL version on which the Connector/C distribution is based. For more information, see Section 23.8.4.4, “C API Server and Client Library Versions”.
A character string that represents the MySQL client library version.
None.
unsigned long mysql_get_client_version(void)
Returns an integer that represents the MySQL client library
version. The value has the format XYYZZ
where
X
is the major version, YY
is the release level (or minor version), and
ZZ
is the sub-version within the release
level:
major_version*10000 + release_level*100 + sub_version
For example, "5.5.50"
is returned
as 50550
.
The function value is the MySQL version. For Connector/C, this is the MySQL version on which the Connector/C distribution is based. For more information, see Section 23.8.4.4, “C API Server and Client Library Versions”.
An integer that represents the MySQL client library version.
None.
const char *mysql_get_host_info(MYSQL *mysql)
Returns a string describing the type of connection in use, including the server host name.
A character string representing the server host name and the connection type.
None.
unsigned int mysql_get_proto_info(MYSQL
*mysql)
Returns the protocol version used by current connection.
An unsigned integer representing the protocol version used by the current connection.
None.
const char *mysql_get_server_info(MYSQL
*mysql)
Returns a string that represents the MySQL server version; for
example, "5.5.50"
.
A character string that represents the MySQL server version.
None.
unsigned long mysql_get_server_version(MYSQL
*mysql)
Returns an integer that represents the MySQL server version. The
value has the format XYYZZ
where
X
is the major version, YY
is the release level (or minor version), and
ZZ
is the sub-version within the release
level:
major_version*10000 + release_level*100 + sub_version
For example, "5.5.50"
is returned
as 50550
.
This function is useful in client programs for determining whether some version-specific server capability exists.
An integer that represents the MySQL server version.
None.
const char *mysql_get_ssl_cipher(MYSQL
*mysql)
mysql_get_ssl_cipher()
returns
the encryption cipher used for the given connection to the
server. mysql
is the connection handler
returned from mysql_init()
.
A string naming the encryption cipher used for the connection,
or NULL
if no cipher is being used.
unsigned long mysql_hex_string(char *to, const char
*from, unsigned long length)
This function creates a legal SQL string for use in an SQL statement. See Section 9.1.1, “String Literals”.
The string in the from
argument is encoded in
hexadecimal format, with each character encoded as two
hexadecimal digits. The result is placed in the
to
argument, followed by a terminating null
byte.
The string pointed to by from
must be
length
bytes long. You must allocate the
to
buffer to be at least
length*2+1
bytes long. When
mysql_hex_string()
returns, the
contents of to
is a null-terminated string.
The return value is the length of the encoded string, not
including the terminating null byte.
The return value can be placed into an SQL statement using
either X'
or
value
'0x
format.
However, the return value does not include the
value
X'...'
or 0x
. The caller
must supply whichever of those is desired.
char query[1000],*end; end = strmov(query,"INSERT INTO test_table values("); end = strmov(end,"X'"); end += mysql_hex_string(end,"What is this",12); end = strmov(end,"',X'"); end += mysql_hex_string(end,"binary data: \0\r\n",16); end = strmov(end,"')"); if (mysql_real_query(&mysql,query,(unsigned int) (end - query))) { fprintf(stderr, "Failed to insert row, Error: %s\n", mysql_error(&mysql)); }
The strmov()
function used in the example is
included in the libmysqlclient
library and
works like strcpy()
but returns a pointer to
the terminating null of the first parameter.
The length of the encoded string that is placed into
to
, not including the terminating null
character.
None.
const char *mysql_info(MYSQL *mysql)
Retrieves a string providing information about the most recently
executed statement, but only for the statements listed here. For
other statements, mysql_info()
returns NULL
. The format of the string varies
depending on the type of statement, as described here. The
numbers are illustrative only; the string contains values
appropriate for the statement.
String format: Records: 100 Duplicates: 0 Warnings:
0
INSERT INTO ... VALUES
(...),(...),(...)...
String format: Records: 3 Duplicates: 0 Warnings:
0
String format: Records: 1 Deleted: 0 Skipped: 0
Warnings: 0
String format: Records: 3 Duplicates: 0 Warnings:
0
String format: Rows matched: 40 Changed: 40
Warnings: 0
mysql_info()
returns a
non-NULL
value for
INSERT ...
VALUES
only for the multiple-row form of the statement
(that is, only if multiple value lists are specified).
A character string representing additional information about the
most recently executed statement. NULL
if no
information is available for the statement.
None.
MYSQL *mysql_init(MYSQL *mysql)
Allocates or initializes a MYSQL
object
suitable for
mysql_real_connect()
. If
mysql
is a NULL
pointer,
the function allocates, initializes, and returns a new object.
Otherwise, the object is initialized and the address of the
object is returned. If
mysql_init()
allocates a new
object, it is freed when
mysql_close()
is called to close
the connection.
In a nonmulti-threaded environment,
mysql_init()
invokes
mysql_library_init()
automatically as necessary. However,
mysql_library_init()
is not
thread-safe in a multi-threaded environment, and thus neither is
mysql_init()
. Before calling
mysql_init()
, either call
mysql_library_init()
prior to
spawning any threads, or use a mutex to protect the
mysql_library_init()
call. This
should be done prior to any other client library call.
An initialized MYSQL*
handle.
NULL
if there was insufficient memory to
allocate a new object.
In case of insufficient memory, NULL
is
returned.
my_ulonglong mysql_insert_id(MYSQL *mysql)
Returns the value generated for an
AUTO_INCREMENT
column by the previous
INSERT
or
UPDATE
statement. Use this
function after you have performed an
INSERT
statement into a table
that contains an AUTO_INCREMENT
field, or
have used INSERT
or
UPDATE
to set a column value with
LAST_INSERT_ID(
.
expr
)
The return value of
mysql_insert_id()
is always zero
unless explicitly updated under one of the following conditions:
INSERT
statements that store
a value into an AUTO_INCREMENT
column.
This is true whether the value is automatically generated by
storing the special values NULL
or
0
into the column, or is an explicit
nonspecial value.
In the case of a multiple-row
INSERT
statement,
mysql_insert_id()
returns
the first automatically generated
AUTO_INCREMENT
value that was
successfully inserted.
If no rows are successfully inserted,
mysql_insert_id()
returns 0.
If an INSERT
... SELECT
statement is executed, and no
automatically generated value is successfully inserted,
mysql_insert_id()
returns
the ID of the last inserted row.
If an INSERT
... SELECT
statement uses
LAST_INSERT_ID(
,
expr
)mysql_insert_id()
returns
expr
.
INSERT
statements that
generate an AUTO_INCREMENT
value by
inserting
LAST_INSERT_ID(
into any column or by updating any column to
expr
)LAST_INSERT_ID(
.
expr
)
If the previous statement returned an error, the value of
mysql_insert_id()
is
undefined.
The return value of
mysql_insert_id()
can be
simplified to the following sequence:
If there is an AUTO_INCREMENT
column, and
an automatically generated value was successfully inserted,
return the first such value.
If
LAST_INSERT_ID(
occurred in the statement, return
expr
)expr
, even if there was an
AUTO_INCREMENT
column in the affected
table.
The return value varies depending on the statement used.
When called after an INSERT
statement:
If there is an AUTO_INCREMENT
column
in the table, and there were some explicit values for
this column that were successfully inserted into the
table, return the last of the explicit values.
When called after an
INSERT
... ON DUPLICATE KEY UPDATE
statement:
If there is an AUTO_INCREMENT
column
in the table and there were some explicit successfully
inserted values or some updated values, return the last
of the inserted or updated values.
mysql_insert_id()
returns
0
if the previous statement does not use an
AUTO_INCREMENT
value. If you need to save the
value for later, be sure to call
mysql_insert_id()
immediately
after the statement that generates the value.
The value of mysql_insert_id()
is affected only by statements issued within the current client
connection. It is not affected by statements issued by other
clients.
The LAST_INSERT_ID()
SQL function
will contain the value of the first automatically generated
value that was successfully inserted.
LAST_INSERT_ID()
is not reset
between statements because the value of that function is
maintained in the server. Another difference from
mysql_insert_id()
is that
LAST_INSERT_ID()
is not updated
if you set an AUTO_INCREMENT
column to a
specific nonspecial value. See
Section 12.14, “Information Functions”.
mysql_insert_id()
returns
0
following a
CALL
statement for a stored
procedure that generates an AUTO_INCREMENT
value because in this case
mysql_insert_id()
applies to
CALL
and not the statement within
the procedure. Within the procedure, you can use
LAST_INSERT_ID()
at the SQL level
to obtain the AUTO_INCREMENT
value.
The reason for the differences between
LAST_INSERT_ID()
and
mysql_insert_id()
is that
LAST_INSERT_ID()
is made easy to
use in scripts while
mysql_insert_id()
tries to
provide more exact information about what happens to the
AUTO_INCREMENT
column.
Described in the preceding discussion.
None.
int mysql_kill(MYSQL *mysql, unsigned long
pid)
Asks the server to kill the thread specified by
pid
.
This function is deprecated. It is preferable to use
mysql_query()
to issue an SQL
KILL
statement instead.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
void mysql_library_end(void)
This function finalizes the MySQL library. Call it when you are
done using the library (for example, after disconnecting from
the server). The action taken by the call depends on whether
your application is linked to the MySQL client library or the
MySQL embedded server library. For a client program linked
against the libmysqlclient
library by using
the -lmysqlclient
flag,
mysql_library_end()
performs
some memory management to clean up. For an embedded server
application linked against the libmysqld
library by using the -lmysqld
flag,
mysql_library_end()
shuts down
the embedded server and then cleans up.
For usage information, see Section 23.8.6, “C API Function Overview”, and Section 23.8.7.40, “mysql_library_init()”.
int mysql_library_init(int argc, char **argv, char
**groups)
Call this function to initialize the MySQL library before you
call any other MySQL function, whether your application is a
regular client program or uses the embedded server. If the
application uses the embedded server, this call starts the
server and initializes any subsystems (mysys
,
InnoDB
, and so forth) that the server uses.
After your application is done using the MySQL library, call
mysql_library_end()
to clean up.
See Section 23.8.7.39, “mysql_library_end()”.
The choice of whether the application operates as a regular
client or uses the embedded server depends on whether you use
the libmysqlclient
or
libmysqld
library at link time to produce the
final executable. For additional information, see
Section 23.8.6, “C API Function Overview”.
In a nonmulti-threaded environment, the call to
mysql_library_init()
may be
omitted, because mysql_init()
will invoke it automatically as necessary. However,
mysql_library_init()
is not
thread-safe in a multi-threaded environment, and thus neither is
mysql_init()
, which calls
mysql_library_init()
. You must
either call mysql_library_init()
prior to spawning any threads, or else use a mutex to protect
the call, whether you invoke
mysql_library_init()
or
indirectly through mysql_init()
.
Do this prior to any other client library call.
The argc
and argv
arguments are analogous to the arguments to
main()
, and enable passing of options to the
embedded server. For convenience, argc
may be
0
(zero) if there are no command-line
arguments for the server. This is the usual case for
applications intended for use only as regular (nonembedded)
clients, and the call typically is written as
mysql_library_init(0, NULL,
NULL)
.
#include <mysql.h> #include <stdlib.h> int main(void) { if (mysql_library_init(0, NULL, NULL)) { fprintf(stderr, "could not initialize MySQL library\n"); exit(1); } /* Use any MySQL API functions here */ mysql_library_end(); return EXIT_SUCCESS; }
When arguments are to be passed (argc
is
greater than 0
), the first element of
argv
is ignored (it typically contains the
program name).
mysql_library_init()
makes a
copy of the arguments so it is safe to destroy
argv
or groups
after the
call.
For embedded applications, if you want to connect to an external
server without starting the embedded server, you have to specify
a negative value for argc
.
The groups
argument is an array of strings
that indicate the groups in option files from which to read
options. See Section 4.2.6, “Using Option Files”. Make the final
entry in the array NULL
. For convenience, if
the groups
argument itself is
NULL
, the [server]
and
[embedded]
groups are used by default.
#include <mysql.h> #include <stdlib.h> static char *server_args[] = { "this_program", /* this string is not used */ "--datadir=.", "--key_buffer_size=32M" }; static char *server_groups[] = { "embedded", "server", "this_program_SERVER", (char *)NULL }; int main(void) { if (mysql_library_init(sizeof(server_args) / sizeof(char *), server_args, server_groups)) { fprintf(stderr, "could not initialize MySQL library\n"); exit(1); } /* Use any MySQL API functions here */ mysql_library_end(); return EXIT_SUCCESS; }
Zero for success. Nonzero if an error occurred.
MYSQL_RES *mysql_list_dbs(MYSQL *mysql, const char
*wild)
Returns a result set consisting of database names on the server
that match the simple regular expression specified by the
wild
parameter. wild
may
contain the wildcard characters
“%
” or
“_
”, or may be a
NULL
pointer to match all databases. Calling
mysql_list_dbs()
is similar to
executing the query SHOW DATABASES [LIKE
.
wild
]
You must free the result set with
mysql_free_result()
.
A MYSQL_RES
result set for success.
NULL
if an error occurred.
Commands were executed in an improper order.
Out of memory.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
MYSQL_RES *mysql_list_fields(MYSQL *mysql, const char
*table, const char *wild)
Returns an empty result set for which the metadata provides
information about the columns in the given table that match the
simple regular expression specified by the
wild
parameter. wild
may
contain the wildcard characters
“%
” or
“_
”, or may be a
NULL
pointer to match all fields. Calling
mysql_list_fields()
is similar
to executing the query SHOW COLUMNS FROM
.
tbl_name
[LIKE
wild
]
It is preferable to use SHOW COLUMNS FROM
instead of
tbl_name
mysql_list_fields()
.
You must free the result set with
mysql_free_result()
.
A MYSQL_RES
result set for success.
NULL
if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
int i; MYSQL_RES *tbl_cols = mysql_list_fields(mysql, "mytbl", "f%"); unsigned int field_cnt = mysql_num_fields(tbl_cols); printf("Number of columns: %d\n", field_cnt); for (i=0; i < field_cnt; ++i) { /* col describes i-th column of the table */ MYSQL_FIELD *col = mysql_fetch_field_direct(tbl_cols, i); printf ("Column %d: %s\n", i, col->name); } mysql_free_result(tbl_cols);
MYSQL_RES *mysql_list_processes(MYSQL *mysql)
Returns a result set describing the current server threads. This
is the same kind of information as that reported by
mysqladmin processlist or a
SHOW PROCESSLIST
query.
You must free the result set with
mysql_free_result()
.
A MYSQL_RES
result set for success.
NULL
if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
MYSQL_RES *mysql_list_tables(MYSQL *mysql, const char
*wild)
Returns a result set consisting of table names in the current
database that match the simple regular expression specified by
the wild
parameter. wild
may contain the wildcard characters
“%
” or
“_
”, or may be a
NULL
pointer to match all tables. Calling
mysql_list_tables()
is similar
to executing the query SHOW TABLES [LIKE
.
wild
]
You must free the result set with
mysql_free_result()
.
A MYSQL_RES
result set for success.
NULL
if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
my_bool mysql_more_results(MYSQL *mysql)
This function is used when you execute multiple statements
specified as a single statement string, or when you execute
CALL
statements, which can return
multiple result sets.
mysql_more_results()
true if
more results exist from the currently executed statement, in
which case the application must call
mysql_next_result()
to fetch the
results.
TRUE
(1) if more results exist.
FALSE
(0) if no more results exist.
In most cases, you can call
mysql_next_result()
instead to
test whether more results exist and initiate retrieval if so.
See Section 23.8.17, “C API Support for Multiple Statement Execution”, and Section 23.8.7.46, “mysql_next_result()”.
None.
int mysql_next_result(MYSQL *mysql)
This function is used when you execute multiple statements
specified as a single statement string, or when you use
CALL
statements to execute stored
procedures, which can return multiple result sets.
mysql_next_result()
reads the
next statement result and returns a status to indicate whether
more results exist. If
mysql_next_result()
returns an
error, there are no more results.
Before each call to
mysql_next_result()
, you must
call mysql_free_result()
for the
current statement if it is a statement that returned a result
set (rather than just a result status).
After calling
mysql_next_result()
the state of
the connection is as if you had called
mysql_real_query()
or
mysql_query()
for the next
statement. This means that you can call
mysql_store_result()
,
mysql_warning_count()
,
mysql_affected_rows()
, and so
forth.
If your program uses CALL
statements to execute stored procedures, the
CLIENT_MULTI_RESULTS
flag must be enabled.
This is because each CALL
returns
a result to indicate the call status, in addition to any result
sets that might be returned by statements executed within the
procedure. Because CALL
can
return multiple results, process them using a loop that calls
mysql_next_result()
to determine
whether there are more results.
CLIENT_MULTI_RESULTS
can be enabled when you
call mysql_real_connect()
,
either explicitly by passing the
CLIENT_MULTI_RESULTS
flag itself, or
implicitly by passing CLIENT_MULTI_STATEMENTS
(which also enables CLIENT_MULTI_RESULTS
). As
of MySQL 5.5.3, CLIENT_MULTI_RESULTS
is
enabled by default.
It is also possible to test whether there are more results by
calling mysql_more_results()
.
However, this function does not change the connection state, so
if it returns true, you must still call
mysql_next_result()
to advance
to the next result.
For an example that shows how to use
mysql_next_result()
, see
Section 23.8.17, “C API Support for Multiple Statement Execution”.
Return Value | Description |
---|---|
0 | Successful and there are more results |
-1 | Successful and there are no more results |
>0 | An error occurred |
Commands were executed in an improper order. For example, if
you did not call
mysql_use_result()
for a
previous result set.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
unsigned int mysql_num_fields(MYSQL_RES
*result)
To pass a MYSQL*
argument instead, use
unsigned int mysql_field_count(MYSQL *mysql)
.
Returns the number of columns in a result set.
You can get the number of columns either from a pointer to a
result set or to a connection handle. You would use the
connection handle if
mysql_store_result()
or
mysql_use_result()
returned
NULL
(and thus you have no result set
pointer). In this case, you can call
mysql_field_count()
to determine
whether mysql_store_result()
should have produced a nonempty result. This enables the client
program to take proper action without knowing whether the query
was a SELECT
(or
SELECT
-like) statement. The
example shown here illustrates how this may be done.
An unsigned integer representing the number of columns in a result set.
None.
MYSQL_RES *result; unsigned int num_fields; unsigned int num_rows; if (mysql_query(&mysql,query_string)) { // error } else // query succeeded, process any data returned by it { result = mysql_store_result(&mysql); if (result) // there are rows { num_fields = mysql_num_fields(result); // retrieve rows, then call mysql_free_result(result) } else // mysql_store_result() returned nothing; should it have? { if (mysql_errno(&mysql)) { fprintf(stderr, "Error: %s\n", mysql_error(&mysql)); } else if (mysql_field_count(&mysql) == 0) { // query does not return data // (it was not a SELECT) num_rows = mysql_affected_rows(&mysql); } } }
An alternative (if you know that your query should have returned
a result set) is to replace the
mysql_errno(&mysql)
call
with a check whether
mysql_field_count(&mysql)
returns 0. This happens only if something went wrong.
my_ulonglong mysql_num_rows(MYSQL_RES
*result)
Returns the number of rows in the result set.
The use of mysql_num_rows()
depends on whether you use
mysql_store_result()
or
mysql_use_result()
to return the
result set. If you use
mysql_store_result()
,
mysql_num_rows()
may be called
immediately. If you use
mysql_use_result()
,
mysql_num_rows()
does not return
the correct value until all the rows in the result set have been
retrieved.
mysql_num_rows()
is intended for
use with statements that return a result set, such as
SELECT
. For statements such as
INSERT
,
UPDATE
, or
DELETE
, the number of affected
rows can be obtained with
mysql_affected_rows()
.
The number of rows in the result set.
None.
int mysql_options(MYSQL *mysql, enum mysql_option
option, const void *arg)
Can be used to set extra connect options and affect behavior for a connection. This function may be called multiple times to set several options.
Call mysql_options()
after
mysql_init()
and before
mysql_connect()
or
mysql_real_connect()
.
The option
argument is the option that you
want to set; the arg
argument is the value
for the option. If the option is an integer, specify a pointer
to the value of the integer as the arg
argument.
The following list describes the possible options, their effect,
and how arg
is used for each option. Several
of the options apply only when the application is linked against
the libmysqld
embedded server library and are
unused for applications linked against the
libmysqlclient
client library. For option
descriptions that indicate arg
is unused, its
value is irrelevant; it is conventional to pass 0.
MYSQL_DEFAULT_AUTH
(argument type:
char *
)
The name of the authentication plugin to use. This option was added in MySQL 5.5.7.
MYSQL_ENABLE_CLEARTEXT_PLUGIN
(argument
type: my_bool *
)
Enable the mysql_clear_password
cleartext
authentication plugin. (See
Section 6.4.1.5, “The Cleartext Client-Side Authentication Plugin”.) This
option was added in MySQL 5.5.27.
MYSQL_INIT_COMMAND
(argument type:
char *
)
SQL statement to execute when connecting to the MySQL server. Automatically re-executed if reconnection occurs.
MYSQL_OPT_COMPRESS
(argument: not used)
Use the compressed client/server protocol.
MYSQL_OPT_CONNECT_TIMEOUT
(argument type:
unsigned int *
)
The connect timeout in seconds.
MYSQL_OPT_GUESS_CONNECTION
(argument: not
used)
For an application linked against the
libmysqld
embedded server library, this
enables the library to guess whether to use the embedded
server or a remote server. “Guess” means that
if the host name is set and is not
localhost
, it uses a remote server. This
behavior is the default.
MYSQL_OPT_USE_EMBEDDED_CONNECTION
and
MYSQL_OPT_USE_REMOTE_CONNECTION
can be
used to override it. This option is ignored for applications
linked against the libmysqlclient
client
library.
MYSQL_OPT_LOCAL_INFILE
(argument type:
optional pointer to unsigned int
)
If no pointer is given or if pointer points to an
unsigned int
that has a nonzero value,
the LOAD DATA
LOCAL INFILE
statement is enabled.
MYSQL_OPT_NAMED_PIPE
(argument: not used)
Use a named pipe to connect to the MySQL server on Windows, if the server permits named-pipe connections.
MYSQL_OPT_PROTOCOL
(argument type:
unsigned int *
)
Type of protocol to use. Specify one of the enum values of
mysql_protocol_type
defined in
mysql.h
.
MYSQL_OPT_READ_TIMEOUT
(argument type:
unsigned int *
)
The timeout in seconds for each attempt to read from the
server. There are retries if necessary, so the total
effective timeout value is three times the option value. You
can set the value so that a lost connection can be detected
earlier than the TCP/IP
Close_Wait_Timeout
value of 10 minutes.
Implementation of this timeout uses mechanisms that may not be available on all platforms. On such a platform, a client that issues a read call might under certain circumstances wait without timing out. For example, a client might not time out if the server is not responding because it is waiting for a “disk full” condition to clear.
MYSQL_OPT_RECONNECT
(argument type:
my_bool *
)
Enable or disable automatic reconnection to the server if the connection is found to have been lost. Reconnect is off by default; this option provides a way to set reconnection behavior explicitly.
MYSQL_OPT_SSL_VERIFY_SERVER_CERT
(argument type: my_bool *
)
Enable or disable verification of the server's Common Name value in its certificate against the host name used when connecting to the server. The connection is rejected if there is a mismatch. For encrypted connections, this feature can be used to prevent man-in-the-middle attacks. Verification is disabled by default.
MYSQL_OPT_USE_EMBEDDED_CONNECTION
(argument: not used)
For an application linked against the
libmysqld
embedded server library, this
forces the use of the embedded server for the connection.
This option is ignored for applications linked against the
libmysqlclient
client library.
MYSQL_OPT_USE_REMOTE_CONNECTION
(argument: not used)
For an application linked against the
libmysqld
embedded server library, this
forces the use of a remote server for the connection. This
option is ignored for applications linked against the
libmysqlclient
client library.
MYSQL_OPT_USE_RESULT
(argument: not used)
This option is unused.
MYSQL_OPT_WRITE_TIMEOUT
(argument type:
unsigned int *
)
The timeout in seconds for each attempt to write to the server. There is a retry if necessary, so the total effective timeout value is two times the option value.
MYSQL_PLUGIN_DIR
(argument type:
char *
)
The directory in which to look for client plugins. This option was added in MySQL 5.5.7.
MYSQL_READ_DEFAULT_FILE
(argument type:
char *
)
Read options from the named option file instead of from
my.cnf
.
MYSQL_READ_DEFAULT_GROUP
(argument type:
char *
)
Read options from the named group from
my.cnf
or the file specified with
MYSQL_READ_DEFAULT_FILE
.
MYSQL_REPORT_DATA_TRUNCATION
(argument
type: my_bool *
)
Enable or disable reporting of data truncation errors for
prepared statements using the error
member of MYSQL_BIND
structures.
(Default: enabled.)
MYSQL_SECURE_AUTH
(argument type:
my_bool *
)
Whether to connect to a server that does not support the password hashing used in MySQL 4.1.1 and later.
MYSQL_SET_CHARSET_DIR
(argument type:
char *
)
The path name to the directory that contains character set definition files.
MYSQL_SET_CHARSET_NAME
(argument type:
char *
)
The name of the character set to use as the default
character set. The argument can be
MYSQL_AUTODETECT_CHARSET_NAME
to cause
the character set to be autodetected based on the operating
system setting (see Section 10.1.4, “Connection Character Sets and Collations”).
MYSQL_SET_CLIENT_IP
(argument type:
char *
)
For an application linked against the
libmysqld
embedded server library (when
libmysqld
is compiled with authentication
support), this means that the user is considered to have
connected from the specified IP address (specified as a
string) for authentication purposes. This option is ignored
for applications linked against the
libmysqlclient
client library.
MYSQL_SHARED_MEMORY_BASE_NAME
(argument
type: char *
)
The name of the shared-memory object for communication to
the server on Windows, if the server supports shared-memory
connections. Specify the same value as the
--shared-memory-base-name
option used for the mysqld server you
want to connect to.
The client
group is always read if you use
MYSQL_READ_DEFAULT_FILE
or
MYSQL_READ_DEFAULT_GROUP
.
The specified group in the option file may contain the following options.
Option | Description |
---|---|
character-sets-dir= | The directory where character sets are installed. |
compress | Use the compressed client/server protocol. |
connect-timeout= | The connect timeout in seconds. On Linux this timeout is also used for waiting for the first answer from the server. |
database= | Connect to this database if no database was specified in the connect command. |
debug | Debug options. |
default-character-set= | The default character set to use. |
disable-local-infile | Disable use of LOAD DATA
LOCAL INFILE . |
enable-cleartext-plugin | Enable the mysql_clear_password cleartext
authentication plugin. Added in MySQL 5.5.27. |
host= | Default host name. |
init-command= | Statement to execute when connecting to MySQL server. Automatically re-executed if reconnection occurs. |
interactive-timeout= | Same as specifying CLIENT_INTERACTIVE to
mysql_real_connect() .
See Section 23.8.7.52, “mysql_real_connect()”. |
local-infile[={0|1}] | If no argument or nonzero argument, enable use of
LOAD DATA
LOCAL ; otherwise disable. |
max_allowed_packet= | Maximum size of packet that client can read from server. |
multi-queries , multi-results | Enable multiple result sets from multiple-statement executions or stored procedures. |
multi-statements | Enable the client to send multiple statements in a single string
(separated by ; characters). |
password= | Default password. |
pipe | Use named pipes to connect to a MySQL server on Windows. |
port= | Default port number. |
protocol={TCP|SOCKET|PIPE|MEMORY} | The protocol to use when connecting to the server. |
return-found-rows | Tell mysql_info() to return found rows
instead of updated rows when using
UPDATE . |
shared-memory-base-name= | Shared-memory name to use to connect to server. |
socket={ | Default socket file. |
ssl-ca= | Certificate Authority file. |
ssl-capath= | Certificate Authority directory. |
ssl-cert= | Certificate file. |
ssl-cipher= | Permissible SSL ciphers. |
ssl-key= | Key file. |
timeout= | Like connect-timeout . |
user | Default user. |
timeout
has been replaced by
connect-timeout
, but
timeout
is still supported for backward
compatibility.
For more information about option files used by MySQL programs, see Section 4.2.6, “Using Option Files”.
Zero for success. Nonzero if you specify an unknown option.
The following mysql_options()
calls request the use of compression in the client/server
protocol, cause options to be read from the
[odbc]
group of option files, and disable
transaction autocommit mode:
MYSQL mysql; mysql_init(&mysql); mysql_options(&mysql,MYSQL_OPT_COMPRESS,0); mysql_options(&mysql,MYSQL_READ_DEFAULT_GROUP,"odbc"); mysql_options(&mysql,MYSQL_INIT_COMMAND,"SET autocommit=0"); if (!mysql_real_connect(&mysql,"host","user","passwd","database",0,NULL,0)) { fprintf(stderr, "Failed to connect to database: Error: %s\n", mysql_error(&mysql)); }
This code requests that the client use the compressed
client/server protocol and read the additional options from the
odbc
section in the
my.cnf
file.
int mysql_ping(MYSQL *mysql)
Checks whether the connection to the server is working. If the
connection has gone down and auto-reconnect is enabled an
attempt to reconnect is made. If the connection is down and
auto-reconnect is disabled,
mysql_ping()
returns an error.
Auto-reconnect is disabled by default. To enable it, call
mysql_options()
with the
MYSQL_OPT_RECONNECT
option. For details, see
Section 23.8.7.49, “mysql_options()”.
mysql_ping()
can be used by
clients that remain idle for a long while, to check whether the
server has closed the connection and reconnect if necessary.
If mysql_ping()
) does cause a
reconnect, there is no explicit indication of it. To determine
whether a reconnect occurs, call
mysql_thread_id()
to get the
original connection identifier before calling
mysql_ping()
, then call
mysql_thread_id()
again to see
whether the identifier has changed.
If reconnect occurs, some characteristics of the connection will have been reset. For details about these characteristics, see Section 23.8.16, “Controlling Automatic Reconnection Behavior”.
Zero if the connection to the server is active. Nonzero if an error occurred. A nonzero return does not indicate whether the MySQL server itself is down; the connection might be broken for other reasons such as network problems.
Commands were executed in an improper order.
The MySQL server has gone away.
An unknown error occurred.
int mysql_query(MYSQL *mysql, const char
*stmt_str)
Executes the SQL statement pointed to by the null-terminated
string stmt_str
. Normally, the string must
consist of a single SQL statement without a terminating
semicolon (“;
”) or
\g
. If multiple-statement execution has been
enabled, the string can contain several statements separated by
semicolons. See Section 23.8.17, “C API Support for Multiple Statement Execution”.
mysql_query()
cannot be used for
statements that contain binary data; you must use
mysql_real_query()
instead.
(Binary data may contain the
“\0
” character, which
mysql_query()
interprets as the
end of the statement string.)
If you want to know whether the statement should return a result
set, you can use
mysql_field_count()
to check for
this. See Section 23.8.7.22, “mysql_field_count()”.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
MYSQL *mysql_real_connect(MYSQL *mysql, const char
*host, const char *user, const char *passwd, const char *db,
unsigned int port, const char *unix_socket, unsigned long
client_flag)
mysql_real_connect()
attempts to
establish a connection to a MySQL database engine running on
host
.
mysql_real_connect()
must
complete successfully before you can execute any other API
functions that require a valid MYSQL
connection handle structure.
The parameters are specified as follows:
For the first parameter, specify the address of an existing
MYSQL
structure. Before calling
mysql_real_connect()
, call
mysql_init()
to initialize
the MYSQL
structure. You can change a lot
of connect options with the
mysql_options()
call. See
Section 23.8.7.49, “mysql_options()”.
The value of host
may be either a host
name or an IP address. If host
is
NULL
or the string
"localhost"
, a connection to the local
host is assumed. For Windows, the client connects using a
shared-memory connection, if the server has shared-memory
connections enabled. Otherwise, TCP/IP is used. For Unix,
the client connects using a Unix socket file. For local
connections, you can also influence the type of connection
to use with the MYSQL_OPT_PROTOCOL
or
MYSQL_OPT_NAMED_PIPE
options to
mysql_options()
. The type of
connection must be supported by the server. For a
host
value of "."
on
Windows, the client connects using a named pipe, if the
server has named-pipe connections enabled. If named-pipe
connections are not enabled, an error occurs.
The user
parameter contains the user's
MySQL login ID. If user
is
NULL
or the empty string
""
, the current user is assumed. Under
Unix, this is the current login name. Under Windows ODBC,
the current user name must be specified explicitly. See the
Connector/ODBC section of Chapter 23, Connectors and APIs.
The passwd
parameter contains the
password for user
. If
passwd
is NULL
, only
entries in the user
table for the user
that have a blank (empty) password field are checked for a
match. This enables the database administrator to set up the
MySQL privilege system in such a way that users get
different privileges depending on whether they have
specified a password.
Do not attempt to encrypt the password before calling
mysql_real_connect()
;
password encryption is handled automatically by the client
API.
The user
and passwd
parameters use whatever character set has been configured
for the MYSQL
object. By default, this is
latin1
, but can be changed by calling
mysql_options(mysql,
MYSQL_SET_CHARSET_NAME,
"
prior
to connecting.
charset_name
")
db
is the database name. If
db
is not NULL
, the
connection sets the default database to this value.
If port
is not 0, the value is used as
the port number for the TCP/IP connection. Note that the
host
parameter determines the type of the
connection.
If unix_socket
is not
NULL
, the string specifies the socket or
named pipe to use. Note that the host
parameter determines the type of the connection.
The value of client_flag
is usually 0,
but can be set to a combination of the following flags to
enable certain features.
Flag Name | Flag Description |
---|---|
CLIENT_COMPRESS | Use compression in the client/server protocol. |
CLIENT_FOUND_ROWS | Return the number of found (matched) rows, not the number of changed rows. |
CLIENT_IGNORE_SIGPIPE | Prevents the client library from installing a SIGPIPE
signal handler. This can be used to avoid conflicts
with a handler that the application has already
installed. |
CLIENT_IGNORE_SPACE | Permit spaces after function names. Makes all functions names reserved words. |
CLIENT_INTERACTIVE | Permit interactive_timeout seconds of
inactivity (rather than
wait_timeout
seconds) before closing the connection. The client's
session
wait_timeout
variable is set to the value of the session
interactive_timeout
variable. |
CLIENT_LOCAL_FILES | Enable LOAD DATA
LOCAL handling. |
CLIENT_MULTI_RESULTS | Tell the server that the client can handle multiple result sets from
multiple-statement executions or stored procedures.
This flag is automatically enabled if
CLIENT_MULTI_STATEMENTS is
enabled. See the note following this table for more
information about this flag. |
CLIENT_MULTI_STATEMENTS | Tell the server that the client may send multiple statements in a single
string (separated by ;
characters). If this flag is not set,
multiple-statement execution is disabled. See the
note following this table for more information about
this flag. |
CLIENT_NO_SCHEMA | Do not permit db_name.tbl_name.col_name
syntax. This is for ODBC. It causes the parser to
generate an error if you use that syntax, which is
useful for trapping bugs in some ODBC programs. |
CLIENT_ODBC | Unused. |
CLIENT_SSL | Use SSL (encrypted protocol). Do not set this option within an
application program; it is set internally in the
client library. Instead, use
mysql_ssl_set()
before calling
mysql_real_connect() . |
CLIENT_REMEMBER_OPTIONS | Remember options specified by calls to
mysql_options() .
Without this option, if
mysql_real_connect()
fails, you must repeat the
mysql_options()
calls before trying to connect again. With this
option, the
mysql_options()
calls need not be repeated. |
If your program uses CALL
statements to execute stored procedures, the
CLIENT_MULTI_RESULTS
flag must be enabled.
This is because each CALL
returns
a result to indicate the call status, in addition to any result
sets that might be returned by statements executed within the
procedure. Because CALL
can
return multiple results, process them using a loop that calls
mysql_next_result()
to determine
whether there are more results.
CLIENT_MULTI_RESULTS
can be enabled when you
call mysql_real_connect()
,
either explicitly by passing the
CLIENT_MULTI_RESULTS
flag itself, or
implicitly by passing CLIENT_MULTI_STATEMENTS
(which also enables CLIENT_MULTI_RESULTS
). As
of MySQL 5.5.3, CLIENT_MULTI_RESULTS
is
enabled by default.
If you enable CLIENT_MULTI_STATEMENTS
or
CLIENT_MULTI_RESULTS
, you should process the
result for every call to
mysql_query()
or
mysql_real_query()
by using a
loop that calls
mysql_next_result()
to determine
whether there are more results. For an example, see
Section 23.8.17, “C API Support for Multiple Statement Execution”.
For some parameters, it is possible to have the value taken from
an option file rather than from an explicit value in the
mysql_real_connect()
call. To do
this, call mysql_options()
with
the MYSQL_READ_DEFAULT_FILE
or
MYSQL_READ_DEFAULT_GROUP
option before
calling mysql_real_connect()
.
Then, in the
mysql_real_connect()
call,
specify the “no-value” value for each parameter to
be read from an option file:
For host
, specify a value of
NULL
or the empty string
(""
).
For user
, specify a value of
NULL
or the empty string.
For passwd
, specify a value of
NULL
. (For the password, a value of the
empty string in the
mysql_real_connect()
call
cannot be overridden in an option file, because the empty
string indicates explicitly that the MySQL account must have
an empty password.)
For db
, specify a value of
NULL
or the empty string.
For port
, specify a value of 0.
For unix_socket
, specify a value of
NULL
.
If no value is found in an option file for a parameter, its default value is used as indicated in the descriptions given earlier in this section.
A MYSQL*
connection handle if the connection
was successful, NULL
if the connection was
unsuccessful. For a successful connection, the return value is
the same as the value of the first parameter.
Failed to connect to the MySQL server.
Failed to connect to the local MySQL server.
Failed to create an IP socket.
Out of memory.
Failed to create a Unix socket.
Failed to find the IP address for the host name.
A protocol mismatch resulted from attempting to connect to a server with a client library that uses a different protocol version.
Failed to create a named pipe on Windows.
Failed to wait for a named pipe on Windows.
Failed to get a pipe handler on Windows.
If connect_timeout
> 0
and it took longer than
connect_timeout
seconds to
connect to the server or if the server died while executing
the init-command
.
The MYSQL
connection handle is already
connected.
MYSQL mysql; mysql_init(&mysql); mysql_options(&mysql,MYSQL_READ_DEFAULT_GROUP,"your_prog_name"); if (!mysql_real_connect(&mysql,"host","user","passwd","database",0,NULL,0)) { fprintf(stderr, "Failed to connect to database: Error: %s\n", mysql_error(&mysql)); }
By using mysql_options()
the
MySQL library reads the [client]
and
[your_prog_name]
sections in the
my.cnf
file which ensures that your program
works, even if someone has set up MySQL in some nonstandard way.
Upon connection,
mysql_real_connect()
sets the
reconnect
flag (part of the
MYSQL
structure) to a value of
1
in versions of the API older than 5.0.3, or
0
in newer versions. A value of
1
for this flag indicates that if a statement
cannot be performed because of a lost connection, to try
reconnecting to the server before giving up. You can use the
MYSQL_OPT_RECONNECT
option to
mysql_options()
to control
reconnection behavior.
unsigned long mysql_real_escape_string(MYSQL *mysql,
char *to, const char *from, unsigned long length)
This function creates a legal SQL string for use in an SQL statement. See Section 9.1.1, “String Literals”.
The mysql
argument must be a valid, open
connection because character escaping depends on the character
set in use by the server.
The string in the from
argument is encoded to
produce an escaped SQL string, taking into account the current
character set of the connection. The result is placed in the
to
argument, followed by a terminating null
byte.
Characters encoded are “\
”,
“'
”,
“"
”, NUL
(ASCII 0), “\n
”,
“\r
”, and Control+Z. Strictly
speaking, MySQL requires only that backslash and the quote
character used to quote the string in the query be escaped.
mysql_real_escape_string()
quotes the other characters to make them easier to read in log
files. For comparison, see the quoting rules for literal strings
and the QUOTE()
SQL function in
Section 9.1.1, “String Literals”, and
Section 12.5, “String Functions”.
The string pointed to by from
must be
length
bytes long. You must allocate the
to
buffer to be at least
length*2+1
bytes long. (In the worst case,
each character may need to be encoded as using two bytes, and
there must be room for the terminating null byte.) When
mysql_real_escape_string()
returns, the contents of to
is a
null-terminated string. The return value is the length of the
encoded string, not including the terminating null byte.
If you must change the character set of the connection, use the
mysql_set_character_set()
function rather than executing a SET NAMES
(or SET CHARACTER SET
) statement.
mysql_set_character_set()
works
like SET NAMES
but also affects the character
set used by
mysql_real_escape_string()
,
which SET NAMES
does not.
The following example inserts two escaped strings into an
INSERT
statement, each within single quote
characters:
char query[1000],*end; end = strmov(query,"INSERT INTO test_table VALUES("); *end++ = '\''; end += mysql_real_escape_string(&mysql,end,"What is this",12); *end++ = '\''; *end++ = ','; *end++ = '\''; end += mysql_real_escape_string(&mysql,end,"binary data: \0\r\n",16); *end++ = '\''; *end++ = ')'; if (mysql_real_query(&mysql,query,(unsigned int) (end - query))) { fprintf(stderr, "Failed to insert row, Error: %s\n", mysql_error(&mysql)); }
The strmov()
function used in the example is
included in the libmysqlclient
library and
works like strcpy()
but returns a pointer to
the terminating null of the first parameter.
The length of the encoded string that is placed into the
to
argument, not including the terminating
null character.
None.
int mysql_real_query(MYSQL *mysql, const char
*stmt_str, unsigned long length)
Executes the SQL statement pointed to by
stmt_str
, a string length
bytes long. Normally, the string must consist of a single SQL
statement without a terminating semicolon
(“;
”) or \g
.
If multiple-statement execution has been enabled, the string can
contain several statements separated by semicolons. See
Section 23.8.17, “C API Support for Multiple Statement Execution”.
mysql_query()
cannot be used for
statements that contain binary data; you must use
mysql_real_query()
instead.
(Binary data may contain the
“\0
” character, which
mysql_query()
interprets as the
end of the statement string.) In addition,
mysql_real_query()
is faster
than mysql_query()
because it
does not call strlen()
on the statement
string.
If you want to know whether the statement should return a result
set, you can use
mysql_field_count()
to check for
this. See Section 23.8.7.22, “mysql_field_count()”.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
int mysql_refresh(MYSQL *mysql, unsigned int
options)
This function flushes tables or caches, or resets replication
server information. The connected user must have the
RELOAD
privilege.
The options
argument is a bit mask composed
from any combination of the following values. Multiple values
can be OR'ed together to perform multiple operations with a
single call.
REFRESH_GRANT
Refresh the grant tables, like
FLUSH
PRIVILEGES
.
REFRESH_LOG
Flush the logs, like
FLUSH LOGS
.
REFRESH_TABLES
Flush the table cache, like
FLUSH
TABLES
.
REFRESH_HOSTS
Flush the host cache, like
FLUSH
HOSTS
.
REFRESH_STATUS
Reset status variables, like
FLUSH
STATUS
.
REFRESH_THREADS
Flush the thread cache.
REFRESH_SLAVE
On a slave replication server, reset the master server
information and restart the slave, like
RESET SLAVE
.
REFRESH_MASTER
On a master replication server, remove the binary log files
listed in the binary log index and truncate the index file,
like RESET MASTER
.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
int mysql_reload(MYSQL *mysql)
Asks the MySQL server to reload the grant tables. The connected
user must have the RELOAD
privilege.
This function is deprecated. It is preferable to use
mysql_query()
to issue an SQL
FLUSH
PRIVILEGES
statement instead.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
my_bool mysql_rollback(MYSQL *mysql)
Rolls back the current transaction.
The action of this function is subject to the value of the
completion_type
system
variable. In particular, if the value of
completion_type
is
RELEASE
(or 2), the server performs a release
after terminating a transaction and closes the client
connection. Call mysql_close()
from the client program to close the connection from the client
side.
Zero for success. Nonzero if an error occurred.
None.
MYSQL_ROW_OFFSET mysql_row_seek(MYSQL_RES *result,
MYSQL_ROW_OFFSET offset)
Sets the row cursor to an arbitrary row in a query result set.
The offset
value is a row offset, typically a
value returned from
mysql_row_tell()
or from
mysql_row_seek()
. This value is
not a row number; to seek to a row within a result set by
number, use mysql_data_seek()
instead.
This function requires that the result set structure contains
the entire result of the query, so
mysql_row_seek()
may be used
only in conjunction with
mysql_store_result()
, not with
mysql_use_result()
.
The previous value of the row cursor. This value may be passed
to a subsequent call to
mysql_row_seek()
.
None.
MYSQL_ROW_OFFSET mysql_row_tell(MYSQL_RES
*result)
Returns the current position of the row cursor for the last
mysql_fetch_row()
. This value
can be used as an argument to
mysql_row_seek()
.
Use mysql_row_tell()
only after
mysql_store_result()
, not after
mysql_use_result()
.
The current offset of the row cursor.
None.
int mysql_select_db(MYSQL *mysql, const char
*db)
Causes the database specified by db
to become
the default (current) database on the connection specified by
mysql
. In subsequent queries, this database
is the default for table references that include no explicit
database specifier.
mysql_select_db()
fails unless
the connected user can be authenticated as having permission to
use the database.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
int mysql_set_character_set(MYSQL *mysql, const char
*csname)
This function is used to set the default character set for the
current connection. The string csname
specifies a valid character set name. The connection collation
becomes the default collation of the character set. This
function works like the SET NAMES
statement,
but also sets the value of mysql->charset
,
and thus affects the character set used by
mysql_real_escape_string()
Zero for success. Nonzero if an error occurred.
MYSQL mysql; mysql_init(&mysql); if (!mysql_real_connect(&mysql,"host","user","passwd","database",0,NULL,0)) { fprintf(stderr, "Failed to connect to database: Error: %s\n", mysql_error(&mysql)); } if (!mysql_set_character_set(&mysql, "utf8")) { printf("New client character set: %s\n", mysql_character_set_name(&mysql)); }
void mysql_set_local_infile_default(MYSQL
*mysql);
Sets the LOAD DATA
LOCAL INFILE
callback functions to the defaults used
internally by the C client library. The library calls this
function automatically if
mysql_set_local_infile_handler()
has not been called or does not supply valid functions for each
of its callbacks.
None.
None.
void mysql_set_local_infile_handler(MYSQL *mysql, int
(*local_infile_init)(void **, const char *, void *), int
(*local_infile_read)(void *, char *, unsigned int), void
(*local_infile_end)(void *), int (*local_infile_error)(void *,
char*, unsigned int), void *userdata);
This function installs callbacks to be used during the execution
of LOAD DATA LOCAL
INFILE
statements. It enables application programs to
exert control over local (client-side) data file reading. The
arguments are the connection handler, a set of pointers to
callback functions, and a pointer to a data area that the
callbacks can use to share information.
To use
mysql_set_local_infile_handler()
,
you must write the following callback functions:
int local_infile_init(void **ptr, const char *filename, void *userdata);
The initialization function. This is called once to do any setup
necessary, open the data file, allocate data structures, and so
forth. The first void**
argument is a pointer
to a pointer. You can set the pointer (that is,
*ptr
) to a value that will be passed to each
of the other callbacks (as a void*
). The
callbacks can use this pointed-to value to maintain state
information. The userdata
argument is the
same value that is passed to
mysql_set_local_infile_handler()
.
The initialization function should return zero for success, nonzero for an error.
int local_infile_read(void *ptr, char *buf, unsigned int buf_len);
The data-reading function. This is called repeatedly to read the
data file. buf
points to the buffer where the
read data is stored, and buf_len
is the
maximum number of bytes that the callback can read and store in
the buffer. (It can read fewer bytes, but should not read more.)
The return value is the number of bytes read, or zero when no more data could be read (this indicates EOF). Return a value less than zero if an error occurs.
void local_infile_end(void *ptr)
The termination function. This is called once after
local_infile_read()
has returned zero (EOF)
or an error. Within this function, deallocate any memory
allocated by local_infile_init()
and perform
any other cleanup necessary. It is invoked even if the
initialization function returns an error.
int local_infile_error(void *ptr, char *error_msg, unsigned int error_msg_len);
The error-handling function. This is called to get a textual
error message to return to the user in case any of your other
functions returns an error. error_msg
points
to the buffer into which the message is written, and
error_msg_len
is the length of the buffer.
Write the message as a null-terminated string, at most
error_msg_len
−1 bytes long.
The return value is the error number.
Typically, the other callbacks store the error message in the
data structure pointed to by ptr
, so that
local_infile_error()
can copy the message
from there into error_msg
.
After calling
mysql_set_local_infile_handler()
in your C code and passing pointers to your callback functions,
you can then issue a
LOAD DATA LOCAL
INFILE
statement (for example, by using
mysql_query()
). The client
library automatically invokes your callbacks. The file name
specified in LOAD
DATA LOCAL INFILE
will be passed as the second
parameter to the local_infile_init()
callback.
None.
None.
int mysql_set_server_option(MYSQL *mysql, enum
enum_mysql_set_option option)
Enables or disables an option for the connection.
option
can have one of the following values.
Option | Description |
---|---|
MYSQL_OPTION_MULTI_STATEMENTS_ON | Enable multiple-statement support |
MYSQL_OPTION_MULTI_STATEMENTS_OFF | Disable multiple-statement support |
If you enable multiple-statement support, you should retrieve
results from calls to
mysql_query()
or
mysql_real_query()
by using a
loop that calls
mysql_next_result()
to determine
whether there are more results. For an example, see
Section 23.8.17, “C API Support for Multiple Statement Execution”.
Enabling multiple-statement support with
MYSQL_OPTION_MULTI_STATEMENTS_ON
does not
have quite the same effect as enabling it by passing the
CLIENT_MULTI_STATEMENTS
flag to
mysql_real_connect()
:
CLIENT_MULTI_STATEMENTS
also enables
CLIENT_MULTI_RESULTS
. If you are using the
CALL
SQL statement in your
programs, multiple-result support must be enabled; this means
that MYSQL_OPTION_MULTI_STATEMENTS_ON
by
itself is insufficient to permit the use of
CALL
.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
The server did not support
mysql_set_server_option()
(which is the case that the server is older than 4.1.1) or
the server did not support the option one tried to set.
int mysql_shutdown(MYSQL *mysql, enum
mysql_enum_shutdown_level shutdown_level)
Asks the database server to shut down. The connected user must
have the SHUTDOWN
privilege.
MySQL servers support only one type of shutdown;
shutdown_level
must be equal to
SHUTDOWN_DEFAULT
. Dynamically linked
executables which have been compiled with older versions of the
libmysqlclient
headers and call
mysql_shutdown()
need to be used
with the old libmysqlclient
dynamic library.
The shutdown process is described in Section 5.1.12, “The Server Shutdown Process”.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
const char *mysql_sqlstate(MYSQL *mysql)
Returns a null-terminated string containing the SQLSTATE error
code for the most recently executed SQL statement. The error
code consists of five characters. '00000'
means “no error.” The values are specified by ANSI
SQL and ODBC. For a list of possible values, see
Appendix B, Errors, Error Codes, and Common Problems.
SQLSTATE values returned by
mysql_sqlstate()
differ from
MySQL-specific error numbers returned by
mysql_errno()
. For example, the
mysql client program displays errors using
the following format, where 1146
is the
mysql_errno()
value and
'42S02'
is the corresponding
mysql_sqlstate()
value:
shell> SELECT * FROM no_such_table;
ERROR 1146 (42S02): Table 'test.no_such_table' doesn't exist
Not all MySQL error numbers are mapped to SQLSTATE error codes.
The value 'HY000'
(general error) is used for
unmapped error numbers.
If you call mysql_sqlstate()
after mysql_real_connect()
fails, mysql_sqlstate()
might
not return a useful value. For example, this happens if a host
is blocked by the server and the connection is closed without
any SQLSTATE value being sent to the client.
A null-terminated character string containing the SQLSTATE error code.
See Section 23.8.7.14, “mysql_errno()”, Section 23.8.7.15, “mysql_error()”, and Section 23.8.11.27, “mysql_stmt_sqlstate()”.
my_bool mysql_ssl_set(MYSQL *mysql, const char *key,
const char *cert, const char *ca, const char *capath, const char
*cipher)
mysql_ssl_set()
is used for
establishing secure connections using SSL. It must be called
before mysql_real_connect()
.
mysql_ssl_set()
does nothing
unless SSL support is enabled in the client library.
mysql
is the connection handler returned from
mysql_init()
. The other
parameters are specified as follows:
key
is the path name to the key file.
cert
is the path name to the certificate
file.
ca
is the path name to the certificate
authority file.
capath
is the path name to a directory
that contains trusted SSL CA certificates in PEM format.
cipher
is a list of permissible ciphers
to use for SSL encryption.
Any unused SSL parameters may be given as
NULL
.
This function always returns 0
. If SSL setup
is incorrect,
mysql_real_connect()
returns an
error when you attempt to connect.
const char *mysql_stat(MYSQL *mysql)
Returns a character string containing information similar to that provided by the mysqladmin status command. This includes uptime in seconds and the number of running threads, questions, reloads, and open tables.
A character string describing the server status.
NULL
if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
MYSQL_RES *mysql_store_result(MYSQL *mysql)
After invoking mysql_query()
or
mysql_real_query()
, you must
call mysql_store_result()
or
mysql_use_result()
for every
statement that successfully produces a result set
(SELECT
,
SHOW
,
DESCRIBE
,
EXPLAIN
,
CHECK TABLE
, and so forth). You
must also call
mysql_free_result()
after you
are done with the result set.
You need not call
mysql_store_result()
or
mysql_use_result()
for other
statements, but it does not do any harm or cause any notable
performance degradation if you call
mysql_store_result()
in all
cases. You can detect whether the statement has a result set by
checking whether
mysql_store_result()
returns a
nonzero value (more about this later).
If you enable multiple-statement support, you should retrieve
results from calls to
mysql_query()
or
mysql_real_query()
by using a
loop that calls
mysql_next_result()
to determine
whether there are more results. For an example, see
Section 23.8.17, “C API Support for Multiple Statement Execution”.
If you want to know whether a statement should return a result
set, you can use
mysql_field_count()
to check for
this. See Section 23.8.7.22, “mysql_field_count()”.
mysql_store_result()
reads the
entire result of a query to the client, allocates a
MYSQL_RES
structure, and places the result
into this structure.
mysql_store_result()
returns a
null pointer if the statement did not return a result set (for
example, if it was an INSERT
statement).
mysql_store_result()
also
returns a null pointer if reading of the result set failed. You
can check whether an error occurred by checking whether
mysql_error()
returns a nonempty
string, mysql_errno()
returns
nonzero, or mysql_field_count()
returns zero.
An empty result set is returned if there are no rows returned. (An empty result set differs from a null pointer as a return value.)
After you have called
mysql_store_result()
and gotten
back a result that is not a null pointer, you can call
mysql_num_rows()
to find out how
many rows are in the result set.
You can call mysql_fetch_row()
to fetch rows from the result set, or
mysql_row_seek()
and
mysql_row_tell()
to obtain or
set the current row position within the result set.
A MYSQL_RES
result structure with the
results. NULL
(0) if an error occurred.
mysql_store_result()
resets
mysql_error()
and
mysql_errno()
if it succeeds.
Commands were executed in an improper order.
Out of memory.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
unsigned long mysql_thread_id(MYSQL *mysql)
Returns the thread ID of the current connection. This value can
be used as an argument to
mysql_kill()
to kill the thread.
If the connection is lost and you reconnect with
mysql_ping()
, the thread ID
changes. This means you should not get the thread ID and store
it for later. You should get it when you need it.
This function does not work correctly if thread IDs become
larger than 32 bits, which can occur on some systems. To avoid
problems with
mysql_thread_id()
, do not use
it. To get the connection ID, execute a SELECT
CONNECTION_ID()
query and retrieve the result.
The thread ID of the current connection.
None.
MYSQL_RES *mysql_use_result(MYSQL *mysql)
After invoking mysql_query()
or
mysql_real_query()
, you must
call mysql_store_result()
or
mysql_use_result()
for every
statement that successfully produces a result set
(SELECT
,
SHOW
,
DESCRIBE
,
EXPLAIN
,
CHECK TABLE
, and so forth). You
must also call
mysql_free_result()
after you
are done with the result set.
mysql_use_result()
initiates a
result set retrieval but does not actually read the result set
into the client like
mysql_store_result()
does.
Instead, each row must be retrieved individually by making calls
to mysql_fetch_row()
. This reads
the result of a query directly from the server without storing
it in a temporary table or local buffer, which is somewhat
faster and uses much less memory than
mysql_store_result()
. The client
allocates memory only for the current row and a communication
buffer that may grow up to
max_allowed_packet
bytes.
On the other hand, you should not use
mysql_use_result()
for locking
reads if you are doing a lot of processing for each row on the
client side, or if the output is sent to a screen on which the
user may type a ^S
(stop scroll). This ties
up the server and prevent other threads from updating any tables
from which the data is being fetched.
When using mysql_use_result()
,
you must execute
mysql_fetch_row()
until a
NULL
value is returned, otherwise, the
unfetched rows are returned as part of the result set for your
next query. The C API gives the error Commands out of
sync; you can't run this command now
if you forget to
do this!
You may not use
mysql_data_seek()
,
mysql_row_seek()
,
mysql_row_tell()
,
mysql_num_rows()
, or
mysql_affected_rows()
with a
result returned from
mysql_use_result()
, nor may you
issue other queries until
mysql_use_result()
has finished.
(However, after you have fetched all the rows,
mysql_num_rows()
accurately
returns the number of rows fetched.)
You must call
mysql_free_result()
once you are
done with the result set.
When using the libmysqld
embedded server, the
memory benefits are essentially lost because memory usage
incrementally increases with each row retrieved until
mysql_free_result()
is called.
A MYSQL_RES
result structure.
NULL
if an error occurred.
mysql_use_result()
resets
mysql_error()
and
mysql_errno()
if it succeeds.
Commands were executed in an improper order.
Out of memory.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
The MySQL client/server protocol provides for the use of prepared
statements. This capability uses the MYSQL_STMT
statement handler data structure returned by the
mysql_stmt_init()
initialization
function. Prepared execution is an efficient way to execute a
statement more than once. The statement is first parsed to prepare
it for execution. Then it is executed one or more times at a later
time, using the statement handle returned by the initialization
function.
Prepared execution is faster than direct execution for statements executed more than once, primarily because the query is parsed only once. In the case of direct execution, the query is parsed every time it is executed. Prepared execution also can provide a reduction of network traffic because for each execution of the prepared statement, it is necessary only to send the data for the parameters.
Prepared statements might not provide a performance increase in some situations. For best results, test your application both with prepared and nonprepared statements and choose whichever yields best performance.
Another advantage of prepared statements is that it uses a binary protocol that makes data transfer between client and server more efficient.
For a list of SQL statements that can be used as prepared statements, see Section 13.5, “SQL Syntax for Prepared Statements”.
Metadata changes to tables or views referred to by prepared statements are detected and cause automatic repreparation of the statement when it is next executed. For more information, see Section 13.5.4, “Automatic Prepared Statement Repreparation”.
Prepared statements use several data structures:
To obtain a statement handle, pass a MYSQL
connection handler to
mysql_stmt_init()
, which
returns a pointer to a MYSQL_STMT
data
structure. This structure is used for further operations with
the statement. To specify the statement to prepare, pass the
MYSQL_STMT
pointer and the statement string
to mysql_stmt_prepare()
.
To provide input parameters for a prepared statement, set up
MYSQL_BIND
structures and pass them to
mysql_stmt_bind_param()
. To
receive output column values, set up
MYSQL_BIND
structures and pass them to
mysql_stmt_bind_result()
.
The MYSQL_TIME
structure is used to
transfer temporal data in both directions.
The following discussion describes the prepared statement data types in detail. For examples that show how to use them, see Section 23.8.11.10, “mysql_stmt_execute()”, and Section 23.8.11.11, “mysql_stmt_fetch()”.
This structure is a handle for a prepared statement. A handle
is created by calling
mysql_stmt_init()
, which
returns a pointer to a MYSQL_STMT
. The
handle is used for all subsequent operations with the
statement until you close it with
mysql_stmt_close()
, at which
point the handle becomes invalid.
The MYSQL_STMT
structure has no members
intended for application use. Applications should not try to
copy a MYSQL_STMT
structure. There is no
guarantee that such a copy will be usable.
Multiple statement handles can be associated with a single connection. The limit on the number of handles depends on the available system resources.
This structure is used both for statement input (data values sent to the server) and output (result values returned from the server):
For input, use MYSQL_BIND
structures
with
mysql_stmt_bind_param()
to
bind parameter data values to buffers for use by
mysql_stmt_execute()
.
For output, use MYSQL_BIND
structures
with
mysql_stmt_bind_result()
to bind buffers to result set columns, for use in fetching
rows with
mysql_stmt_fetch()
.
To use a MYSQL_BIND
structure, zero its
contents to initialize it, then set its members appropriately.
For example, to declare and initialize an array of three
MYSQL_BIND
structures, use this code:
MYSQL_BIND bind[3]; memset(bind, 0, sizeof(bind));
The MYSQL_BIND
structure contains the
following members for use by application programs. For several
of the members, the manner of use depends on whether the
structure is used for input or output.
enum enum_field_types buffer_type
The type of the buffer. This member indicates the data
type of the C language variable bound to a statement
parameter or result set column. For input,
buffer_type
indicates the type of the
variable containing the value to be sent to the server.
For output, it indicates the type of the variable into
which a value received from the server should be stored.
For permissible buffer_type
values, see
Section 23.8.9.1, “C API Prepared Statement Type Codes”.
void *buffer
A pointer to the buffer to be used for data transfer. This is the address of a C language variable.
For input, buffer
is a pointer to the
variable in which you store the data value for a statement
parameter. When you call
mysql_stmt_execute()
,
MySQL use the value stored in the variable in place of the
corresponding parameter marker in the statement (specified
with ?
in the statement string).
For output, buffer
is a pointer to the
variable in which to return a result set column value.
When you call
mysql_stmt_fetch()
, MySQL
stores a column value from the current row of the result
set in this variable. You can access the value when the
call returns.
To minimize the need for MySQL to perform type conversions between C language values on the client side and SQL values on the server side, use C variables that have types similar to those of the corresponding SQL values:
For numeric data types, buffer
should point to a variable of the proper numeric C
type. For integer variables (which can be
char
for single-byte values or an
integer type for larger values), you should also
indicate whether the variable has the
unsigned
attribute by setting the
is_unsigned
member, described
later.
For character (nonbinary) and binary string data
types, buffer
should point to a
character buffer.
For date and time data types,
buffer
should point to a
MYSQL_TIME
structure.
For guidelines about mapping between C types and SQL types and notes about type conversions, see Section 23.8.9.1, “C API Prepared Statement Type Codes”, and Section 23.8.9.2, “C API Prepared Statement Type Conversions”.
unsigned long buffer_length
The actual size of *buffer
in bytes.
This indicates the maximum amount of data that can be
stored in the buffer. For character and binary C data, the
buffer_length
value specifies the
length of *buffer
when used with
mysql_stmt_bind_param()
to
specify input values, or the maximum number of output data
bytes that can be fetched into the buffer when used with
mysql_stmt_bind_result()
.
unsigned long *length
A pointer to an unsigned long
variable
that indicates the actual number of bytes of data stored
in *buffer
. length
is used for character or binary C data.
For input parameter data binding, set
*length
to indicate the actual length
of the parameter value stored in
*buffer
. This is used by
mysql_stmt_execute()
.
For output value binding, MySQL sets
*length
when you call
mysql_stmt_fetch()
. The
mysql_stmt_fetch()
return
value determines how to interpret the length:
If the return value is 0, *length
indicates the actual length of the parameter value.
If the return value is
MYSQL_DATA_TRUNCATED
,
*length
indicates the nontruncated
length of the parameter value. In this case, the
minimum of *length
and
buffer_length
indicates the actual
length of the value.
length
is ignored for numeric and
temporal data types because the
buffer_type
value determines the length
of the data value.
If you must determine the length of a returned value before fetching it, see Section 23.8.11.11, “mysql_stmt_fetch()”, for some strategies.
my_bool *is_null
This member points to a my_bool
variable that is true if a value is
NULL
, false if it is not
NULL
. For input, set
*is_null
to true to indicate that you
are passing a NULL
value as a statement
parameter.
is_null
is a
pointer to a boolean scalar, not a
boolean scalar, to provide flexibility in how you specify
NULL
values:
If your data values are always
NULL
, use
MYSQL_TYPE_NULL
as the
buffer_type
value when you bind the
column. The other MYSQL_BIND
members, including is_null
, do not
matter.
If your data values are always NOT
NULL
, set is_null = (my_bool*)
0
, and set the other members appropriately
for the variable you are binding.
In all other cases, set the other members
appropriately and set is_null
to
the address of a my_bool
variable.
Set that variable's value to true or false
appropriately between executions to indicate whether
the corresponding data value is
NULL
or NOT
NULL
, respectively.
For output, when you fetch a row, MySQL sets the value
pointed to by is_null
to true or false
according to whether the result set column value returned
from the statement is or is not NULL
.
my_bool is_unsigned
This member applies for C variables with data types that
can be unsigned
(char
, short int
,
int
, long long int
).
Set is_unsigned
to true if the variable
pointed to by buffer
is
unsigned
and false otherwise. For
example, if you bind a signed char
variable to buffer
, specify a type code
of MYSQL_TYPE_TINY
and set
is_unsigned
to false. If you bind an
unsigned char
instead, the type code is
the same but is_unsigned
should be
true. (For char
, it is not defined
whether it is signed or unsigned, so it is best to be
explicit about signedness by using signed
char
or unsigned char
.)
is_unsigned
applies only to the C
language variable on the client side. It indicates nothing
about the signedness of the corresponding SQL value on the
server side. For example, if you use an
int
variable to supply a value for a
BIGINT UNSIGNED
column,
is_unsigned
should be false because
int
is a signed type. If you use an
unsigned int
variable to supply a value
for a BIGINT
column,
is_unsigned
should be true because
unsigned int
is an unsigned type. MySQL
performs the proper conversion between signed and unsigned
values in both directions, although a warning occurs if
truncation results.
my_bool *error
For output, set this member to point to a
my_bool
variable to have truncation
information for the parameter stored there after a row
fetching operation. When truncation reporting is enabled,
mysql_stmt_fetch()
returns
MYSQL_DATA_TRUNCATED
and
*error
is true in the
MYSQL_BIND
structures for parameters in
which truncation occurred. Truncation indicates loss of
sign or significant digits, or that a string was too long
to fit in a column. Truncation reporting is enabled by
default, but can be controlled by calling
mysql_options()
with the
MYSQL_REPORT_DATA_TRUNCATION
option.
This structure is used to send and receive
DATE
,
TIME
,
DATETIME
, and
TIMESTAMP
data directly to and
from the server. Set the buffer
member to
point to a MYSQL_TIME
structure, and set
the buffer_type
member of a
MYSQL_BIND
structure to one of the temporal
types (MYSQL_TYPE_TIME
,
MYSQL_TYPE_DATE
,
MYSQL_TYPE_DATETIME
,
MYSQL_TYPE_TIMESTAMP
).
The MYSQL_TIME
structure contains the
members listed in the following table.
Member | Description |
---|---|
unsigned int year | The year |
unsigned int month | The month of the year |
unsigned int day | The day of the month |
unsigned int hour | The hour of the day |
unsigned int minute | The minute of the hour |
unsigned int second | The second of the minute |
my_bool neg | A boolean flag indicating whether the time is negative |
unsigned long second_part | The fractional part of the second in microseconds; currently unused |
Only those parts of a MYSQL_TIME
structure
that apply to a given type of temporal value are used. The
year
, month
, and
day
elements are used for
DATE
,
DATETIME
, and
TIMESTAMP
values. The
hour
, minute
, and
second
elements are used for
TIME
,
DATETIME
, and
TIMESTAMP
values. See
Section 23.8.19, “C API Prepared Statement Handling of Date and Time Values”.
The buffer_type
member of
MYSQL_BIND
structures indicates the data type
of the C language variable bound to a statement parameter or
result set column. For input, buffer_type
indicates the type of the variable containing the value to be
sent to the server. For output, it indicates the type of the
variable into which a value received from the server should be
stored.
The following table shows the permissible values for the
buffer_type
member of
MYSQL_BIND
structures for input values sent
to the server. The table shows the C variable types that you can
use, the corresponding type codes, and the SQL data types for
which the supplied value can be used without conversion. Choose
the buffer_type
value according to the data
type of the C language variable that you are binding. For the
integer types, you should also set the
is_unsigned
member to indicate whether the
variable is signed or unsigned.
Input Variable C Type | buffer_type Value | SQL Type of Destination Value |
---|---|---|
signed char | MYSQL_TYPE_TINY | TINYINT |
short int | MYSQL_TYPE_SHORT | SMALLINT |
int | MYSQL_TYPE_LONG | INT |
long long int | MYSQL_TYPE_LONGLONG | BIGINT |
float | MYSQL_TYPE_FLOAT | FLOAT |
double | MYSQL_TYPE_DOUBLE | DOUBLE |
MYSQL_TIME | MYSQL_TYPE_TIME | TIME |
MYSQL_TIME | MYSQL_TYPE_DATE | DATE |
MYSQL_TIME | MYSQL_TYPE_DATETIME | DATETIME |
MYSQL_TIME | MYSQL_TYPE_TIMESTAMP | TIMESTAMP |
char[] | MYSQL_TYPE_STRING | TEXT ,
CHAR ,
VARCHAR |
char[] | MYSQL_TYPE_BLOB | BLOB ,
BINARY ,
VARBINARY |
MYSQL_TYPE_NULL | NULL |
Use MYSQL_TYPE_NULL
as indicated in the
description for the is_null
member in
Section 23.8.9, “C API Prepared Statement Data Structures”.
For input string data, use MYSQL_TYPE_STRING
or MYSQL_TYPE_BLOB
depending on whether the
value is a character (nonbinary) or binary string:
MYSQL_TYPE_STRING
indicates character
input string data. The value is assumed to be in the
character set indicated by the
character_set_client
system
variable. If the server stores the value into a column with
a different character set, it converts the value to that
character set.
MYSQL_TYPE_BLOB
indicates binary input
string data. The value is treated as having the
binary
character set. That is, it is
treated as a byte string and no conversion occurs.
The following table shows the permissible values for the
buffer_type
member of
MYSQL_BIND
structures for output values
received from the server. The table shows the SQL types of
received values, the corresponding type codes that such values
have in result set metadata, and the recommended C language data
types to bind to the MYSQL_BIND
structure to
receive the SQL values without conversion. Choose the
buffer_type
value according to the data type
of the C language variable that you are binding. For the integer
types, you should also set the is_unsigned
member to indicate whether the variable is signed or unsigned.
SQL Type of Received Value | buffer_type Value | Output Variable C Type |
---|---|---|
TINYINT | MYSQL_TYPE_TINY | signed char |
SMALLINT | MYSQL_TYPE_SHORT | short int |
MEDIUMINT | MYSQL_TYPE_INT24 | int |
INT | MYSQL_TYPE_LONG | int |
BIGINT | MYSQL_TYPE_LONGLONG | long long int |
FLOAT | MYSQL_TYPE_FLOAT | float |
DOUBLE | MYSQL_TYPE_DOUBLE | double |
DECIMAL | MYSQL_TYPE_NEWDECIMAL | char[] |
YEAR | MYSQL_TYPE_SHORT | short int |
TIME | MYSQL_TYPE_TIME | MYSQL_TIME |
DATE | MYSQL_TYPE_DATE | MYSQL_TIME |
DATETIME | MYSQL_TYPE_DATETIME | MYSQL_TIME |
TIMESTAMP | MYSQL_TYPE_TIMESTAMP | MYSQL_TIME |
CHAR ,
BINARY | MYSQL_TYPE_STRING | char[] |
VARCHAR ,
VARBINARY | MYSQL_TYPE_VAR_STRING | char[] |
TINYBLOB ,
TINYTEXT | MYSQL_TYPE_TINY_BLOB | char[] |
BLOB , TEXT | MYSQL_TYPE_BLOB | char[] |
MEDIUMBLOB ,
MEDIUMTEXT | MYSQL_TYPE_MEDIUM_BLOB | char[] |
LONGBLOB ,
LONGTEXT | MYSQL_TYPE_LONG_BLOB | char[] |
BIT | MYSQL_TYPE_BIT | char[] |
Prepared statements transmit data between the client and server using C language variables on the client side that correspond to SQL values on the server side. If there is a mismatch between the C variable type on the client side and the corresponding SQL value type on the server side, MySQL performs implicit type conversions in both directions.
MySQL knows the type code for the SQL value on the server side.
The buffer_type
value in the
MYSQL_BIND
structure indicates the type code
of the C variable that holds the value on the client side. The
two codes together tell MySQL what conversion must be performed,
if any. Here are some examples:
If you use MYSQL_TYPE_LONG
with an
int
variable to pass an integer value to
the server that is to be stored into a
FLOAT
column, MySQL converts
the value to floating-point format before storing it.
If you fetch an SQL MEDIUMINT
column value, but specify a buffer_type
value of MYSQL_TYPE_LONGLONG
and use a C
variable of type long long int
as the
destination buffer, MySQL converts the
MEDIUMINT
value (which
requires less than 8 bytes) for storage into the
long long int
(an 8-byte variable).
If you fetch a numeric column with a value of 255 into a
char[4]
character array and specify a
buffer_type
value of
MYSQL_TYPE_STRING
, the resulting value in
the array is a 4-byte string '255\0'
.
MySQL returns DECIMAL
values
as the string representation of the original server-side
value, which is why the corresponding C type is
char[]
. For example,
12.345
is returned to the client as
'12.345'
. If you specify
MYSQL_TYPE_NEWDECIMAL
and bind a string
buffer to the MYSQL_BIND
structure,
mysql_stmt_fetch()
stores
the value in the buffer as a string without conversion. If
instead you specify a numeric variable and type code,
mysql_stmt_fetch()
converts
the string-format DECIMAL
value to numeric form.
For the MYSQL_TYPE_BIT
type code,
BIT
values are returned into
a string buffer, which is why the corresponding C type is
char[]
. The value represents a bit string
that requires interpretation on the client side. To return
the value as a type that is easier to deal with, you can
cause the value to be cast to integer using either of the
following types of expressions:
SELECT bit_col + 0 FROM t SELECT CAST(bit_col AS UNSIGNED) FROM t
To retrieve the value, bind an integer variable large enough to hold the value and specify the appropriate corresponding integer type code.
Before binding variables to the MYSQL_BIND
structures that are to be used for fetching column values, you
can check the type codes for each column of the result set. This
might be desirable if you want to determine which variable types
would be best to use to avoid type conversions. To get the type
codes, call
mysql_stmt_result_metadata()
after executing the prepared statement with
mysql_stmt_execute()
. The
metadata provides access to the type codes for the result set as
described in Section 23.8.11.23, “mysql_stmt_result_metadata()”, and
Section 23.8.5, “C API Data Structures”.
To determine whether output string values in a result set
returned from the server contain binary or nonbinary data, check
whether the charsetnr
value of the result set
metadata is 63 (see Section 23.8.5, “C API Data Structures”). If
so, the character set is binary
, which
indicates binary rather than nonbinary data. This enables you to
distinguish BINARY
from
CHAR
,
VARBINARY
from
VARCHAR
, and the
BLOB
types from the
TEXT
types.
If you cause the max_length
member of the
MYSQL_FIELD
column metadata structures to be
set (by calling
mysql_stmt_attr_set()
), be aware
that the max_length
values for the result set
indicate the lengths of the longest string representation of the
result values, not the lengths of the binary representation.
That is, max_length
does not necessarily
correspond to the size of the buffers needed to fetch the values
with the binary protocol used for prepared statements. Choose
the size of the buffers according to the types of the variables
into which you fetch the values. For example, a
TINYINT
column containing the value -128
might have a max_length
value of 4. But the
binary representation of any TINYINT
value
requires only 1 byte for storage, so you can supply a
signed char
variable in which to store the
value and set is_unsigned
to indicate that
values are signed.
Metadata changes to tables or views referred to by prepared statements are detected and cause automatic repreparation of the statement when it is next executed. For more information, see Section 13.5.4, “Automatic Prepared Statement Repreparation”.
The functions available for prepared statement processing are summarized here and described in greater detail in a later section. See Section 23.8.11, “C API Prepared Statement Function Descriptions”.
Function | Description |
---|---|
mysql_stmt_affected_rows() | Returns the number of rows changed, deleted, or inserted by prepared
UPDATE ,
DELETE , or
INSERT statement |
mysql_stmt_attr_get() | Gets value of an attribute for a prepared statement |
mysql_stmt_attr_set() | Sets an attribute for a prepared statement |
mysql_stmt_bind_param() | Associates application data buffers with the parameter markers in a prepared SQL statement |
mysql_stmt_bind_result() | Associates application data buffers with columns in a result set |
mysql_stmt_close() | Frees memory used by a prepared statement |
mysql_stmt_data_seek() | Seeks to an arbitrary row number in a statement result set |
mysql_stmt_errno() | Returns the error number for the last statement execution |
mysql_stmt_error() | Returns the error message for the last statement execution |
mysql_stmt_execute() | Executes a prepared statement |
mysql_stmt_fetch() | Fetches the next row of data from a result set and returns data for all bound columns |
mysql_stmt_fetch_column() | Fetch data for one column of the current row of a result set |
mysql_stmt_field_count() | Returns the number of result columns for the most recent statement |
mysql_stmt_free_result() | Free the resources allocated to a statement handle |
mysql_stmt_init() | Allocates memory for a MYSQL_STMT structure and
initializes it |
mysql_stmt_insert_id() | Returns the ID generated for an AUTO_INCREMENT column
by a prepared statement |
mysql_stmt_next_result() | Returns/initiates the next result in a multiple-result execution |
mysql_stmt_num_rows() | Returns the row count from a buffered statement result set |
mysql_stmt_param_count() | Returns the number of parameters in a prepared statement |
mysql_stmt_param_metadata() | (Return parameter metadata in the form of a result set) This function does nothing |
mysql_stmt_prepare() | Prepares an SQL statement string for execution |
mysql_stmt_reset() | Resets the statement buffers in the server |
mysql_stmt_result_metadata() | Returns prepared statement metadata in the form of a result set |
mysql_stmt_row_seek() | Seeks to a row offset in a statement result set, using value returned
from mysql_stmt_row_tell() |
mysql_stmt_row_tell() | Returns the statement row cursor position |
mysql_stmt_send_long_data() | Sends long data in chunks to server |
mysql_stmt_sqlstate() | Returns the SQLSTATE error code for the last statement execution |
mysql_stmt_store_result() | Retrieves a complete result set to the client |
Call mysql_stmt_init()
to create a
statement handle, then
mysql_stmt_prepare()
to prepare
the statement string,
mysql_stmt_bind_param()
to supply
the parameter data, and
mysql_stmt_execute()
to execute
the statement. You can repeat the
mysql_stmt_execute()
by changing
parameter values in the respective buffers supplied through
mysql_stmt_bind_param()
.
You can send text or binary data in chunks to server using
mysql_stmt_send_long_data()
. See
Section 23.8.11.26, “mysql_stmt_send_long_data()”.
If the statement is a SELECT
or any
other statement that produces a result set,
mysql_stmt_prepare()
also returns
the result set metadata information in the form of a
MYSQL_RES
result set through
mysql_stmt_result_metadata()
.
You can supply the result buffers using
mysql_stmt_bind_result()
, so that
the mysql_stmt_fetch()
automatically returns data to these buffers. This is row-by-row
fetching.
When statement execution has been completed, close the statement
handle using mysql_stmt_close()
so
that all resources associated with it can be freed.
If you obtained a SELECT
statement's result set metadata by calling
mysql_stmt_result_metadata()
, you
should also free the metadata using
mysql_free_result()
.
To prepare and execute a statement, an application follows these steps:
Create a prepared statement handle with
mysql_stmt_init()
. To prepare
the statement on the server, call
mysql_stmt_prepare()
and pass
it a string containing the SQL statement.
If the statement will produce a result set, call
mysql_stmt_result_metadata()
to obtain the result set metadata. This metadata is itself in
the form of result set, albeit a separate one from the one
that contains the rows returned by the query. The metadata
result set indicates how many columns are in the result and
contains information about each column.
Set the values of any parameters using
mysql_stmt_bind_param()
. All
parameters must be set. Otherwise, statement execution returns
an error or produces unexpected results.
Call mysql_stmt_execute()
to
execute the statement.
If the statement produces a result set, bind the data buffers
to use for retrieving the row values by calling
mysql_stmt_bind_result()
.
Fetch the data into the buffers row by row by calling
mysql_stmt_fetch()
repeatedly
until no more rows are found.
Repeat steps 3 through 6 as necessary, by changing the parameter values and re-executing the statement.
When mysql_stmt_prepare()
is
called, the MySQL client/server protocol performs these actions:
The server parses the statement and sends the okay status back to the client by assigning a statement ID. It also sends total number of parameters, a column count, and its metadata if it is a result set oriented statement. All syntax and semantics of the statement are checked by the server during this call.
The client uses this statement ID for the further operations, so that the server can identify the statement from among its pool of statements.
When mysql_stmt_execute()
is
called, the MySQL client/server protocol performs these actions:
The client uses the statement handle and sends the parameter data to the server.
The server identifies the statement using the ID provided by the client, replaces the parameter markers with the newly supplied data, and executes the statement. If the statement produces a result set, the server sends the data back to the client. Otherwise, it sends an okay status and the number of rows changed, deleted, or inserted.
When mysql_stmt_fetch()
is called,
the MySQL client/server protocol performs these actions:
The client reads the data from the current row of the result set and places it into the application data buffers by doing the necessary conversions. If the application buffer type is same as that of the field type returned from the server, the conversions are straightforward.
If an error occurs, you can get the statement error number, error
message, and SQLSTATE code using
mysql_stmt_errno()
,
mysql_stmt_error()
, and
mysql_stmt_sqlstate()
,
respectively.
For prepared statements that are executed with the
mysql_stmt_prepare()
and
mysql_stmt_execute()
C API
functions, the server writes Prepare
and
Execute
lines to the general query log so that
you can tell when statements are prepared and executed.
Suppose that you prepare and execute a statement as follows:
Call mysql_stmt_prepare()
to
prepare the statement string "SELECT ?"
.
Call mysql_stmt_bind_param()
to bind the value 3
to the parameter in the
prepared statement.
Call mysql_stmt_execute()
to
execute the prepared statement.
As a result of the preceding calls, the server writes the following lines to the general query log:
Prepare [1] SELECT ? Execute [1] SELECT 3
Each Prepare
and Execute
line in the log is tagged with a
[
statement
identifier so that you can keep track of which prepared statement
is being logged. N
]N
is a positive
integer. If there are multiple prepared statements active
simultaneously for the client, N
may be
greater than 1. Each Execute
lines shows a
prepared statement after substitution of data values for
?
parameters.
To prepare and execute queries, use the functions described in detail in the following sections.
All functions that operate with a MYSQL_STMT
structure begin with the prefix mysql_stmt_
.
To create a MYSQL_STMT
handle, use the
mysql_stmt_init()
function.
my_ulonglong mysql_stmt_affected_rows(MYSQL_STMT
*stmt)
mysql_stmt_affected_rows()
may
be called immediately after executing a statement with
mysql_stmt_execute()
. It is like
mysql_affected_rows()
but for
prepared statements. For a description of what the affected-rows
value returned by this function means, See
Section 23.8.7.1, “mysql_affected_rows()”.
None.
See the Example in Section 23.8.11.10, “mysql_stmt_execute()”.
my_bool mysql_stmt_attr_get(MYSQL_STMT *stmt, enum
enum_stmt_attr_type option, void *arg)
Can be used to get the current value for a statement attribute.
The option
argument is the option that you
want to get; the arg
should point to a
variable that should contain the option value. If the option is
an integer, arg
should point to the value of
the integer.
See Section 23.8.11.3, “mysql_stmt_attr_set()”, for a list of options and option types.
Zero for success. Nonzero if option
is
unknown.
None.
my_bool mysql_stmt_attr_set(MYSQL_STMT *stmt, enum
enum_stmt_attr_type option, const void *arg)
Can be used to affect behavior for a prepared statement. This function may be called multiple times to set several options.
The option
argument is the option that you
want to set. The arg
argument is the value
for the option. arg
should point to a
variable that is set to the desired attribute value. The
variable type is as indicated in the following table.
The following table shows the possible option
values.
Option | Argument Type | Function |
---|---|---|
STMT_ATTR_UPDATE_MAX_LENGTH | my_bool * | If set to 1, causes
mysql_stmt_store_result()
to update the metadata
MYSQL_FIELD->max_length value. |
STMT_ATTR_CURSOR_TYPE | unsigned long * | Type of cursor to open for statement when
mysql_stmt_execute() is
invoked. *arg can be
CURSOR_TYPE_NO_CURSOR (the default)
or CURSOR_TYPE_READ_ONLY . |
STMT_ATTR_PREFETCH_ROWS | unsigned long * | Number of rows to fetch from server at a time when using a cursor.
*arg can be in the range from 1 to
the maximum value of unsigned long .
The default is 1. |
If you use the STMT_ATTR_CURSOR_TYPE
option
with CURSOR_TYPE_READ_ONLY
, a cursor is
opened for the statement when you invoke
mysql_stmt_execute()
. If there
is already an open cursor from a previous
mysql_stmt_execute()
call, it
closes the cursor before opening a new one.
mysql_stmt_reset()
also closes
any open cursor before preparing the statement for re-execution.
mysql_stmt_free_result()
closes
any open cursor.
If you open a cursor for a prepared statement,
mysql_stmt_store_result()
is
unnecessary, because that function causes the result set to be
buffered on the client side.
Zero for success. Nonzero if option
is
unknown.
None.
The following example opens a cursor for a prepared statement and sets the number of rows to fetch at a time to 5:
MYSQL_STMT *stmt; int rc; unsigned long type; unsigned long prefetch_rows = 5; stmt = mysql_stmt_init(mysql); type = (unsigned long) CURSOR_TYPE_READ_ONLY; rc = mysql_stmt_attr_set(stmt, STMT_ATTR_CURSOR_TYPE, (void*) &type); /* ... check return value ... */ rc = mysql_stmt_attr_set(stmt, STMT_ATTR_PREFETCH_ROWS, (void*) &prefetch_rows); /* ... check return value ... */
my_bool mysql_stmt_bind_param(MYSQL_STMT *stmt,
MYSQL_BIND *bind)
mysql_stmt_bind_param()
is used
to bind input data for the parameter markers in the SQL
statement that was passed to
mysql_stmt_prepare()
. It uses
MYSQL_BIND
structures to supply the data.
bind
is the address of an array of
MYSQL_BIND
structures. The client library
expects the array to contain one element for each
?
parameter marker that is present in the
query.
Suppose that you prepare the following statement:
INSERT INTO mytbl VALUES(?,?,?)
When you bind the parameters, the array of
MYSQL_BIND
structures must contain three
elements, and can be declared like this:
MYSQL_BIND bind[3];
Section 23.8.9, “C API Prepared Statement Data Structures”,
describes the members of each MYSQL_BIND
element and how they should be set to provide input values.
Zero for success. Nonzero if an error occurred.
The conversion is not supported. Possibly the
buffer_type
value is invalid or is not
one of the supported types.
Out of memory.
An unknown error occurred.
See the Example in Section 23.8.11.10, “mysql_stmt_execute()”.
my_bool mysql_stmt_bind_result(MYSQL_STMT *stmt,
MYSQL_BIND *bind)
mysql_stmt_bind_result()
is used
to associate (that is, bind) output columns in the result set to
data buffers and length buffers. When
mysql_stmt_fetch()
is called to
fetch data, the MySQL client/server protocol places the data for
the bound columns into the specified buffers.
All columns must be bound to buffers prior to calling
mysql_stmt_fetch()
.
bind
is the address of an array of
MYSQL_BIND
structures. The client library
expects the array to contain one element for each column of the
result set. If you do not bind columns to
MYSQL_BIND
structures,
mysql_stmt_fetch()
simply
ignores the data fetch. The buffers should be large enough to
hold the data values, because the protocol does not return data
values in chunks.
A column can be bound or rebound at any time, even after a
result set has been partially retrieved. The new binding takes
effect the next time
mysql_stmt_fetch()
is called.
Suppose that an application binds the columns in a result set
and calls mysql_stmt_fetch()
.
The client/server protocol returns data in the bound buffers.
Then suppose that the application binds the columns to a
different set of buffers. The protocol places data into the
newly bound buffers when the next call to
mysql_stmt_fetch()
occurs.
To bind a column, an application calls
mysql_stmt_bind_result()
and
passes the type, address, and length of the output buffer into
which the value should be stored.
Section 23.8.9, “C API Prepared Statement Data Structures”,
describes the members of each MYSQL_BIND
element and how they should be set to receive output values.
Zero for success. Nonzero if an error occurred.
The conversion is not supported. Possibly the
buffer_type
value is invalid or is not
one of the supported types.
Out of memory.
An unknown error occurred.
See the Example in Section 23.8.11.11, “mysql_stmt_fetch()”.
my_bool mysql_stmt_close(MYSQL_STMT *)
Closes the prepared statement.
mysql_stmt_close()
also
deallocates the statement handle pointed to by
stmt
.
If the current statement has pending or unread results, this function cancels them so that the next query can be executed.
Zero for success. Nonzero if an error occurred.
The MySQL server has gone away.
An unknown error occurred.
See the Example in Section 23.8.11.10, “mysql_stmt_execute()”.
void mysql_stmt_data_seek(MYSQL_STMT *stmt,
my_ulonglong offset)
Seeks to an arbitrary row in a statement result set. The
offset
value is a row number and should be in
the range from 0
to
mysql_stmt_num_rows(stmt)-1
.
This function requires that the statement result set structure
contains the entire result of the last executed query, so
mysql_stmt_data_seek()
may be
used only in conjunction with
mysql_stmt_store_result()
.
None.
None.
unsigned int mysql_stmt_errno(MYSQL_STMT
*stmt)
For the statement specified by stmt
,
mysql_stmt_errno()
returns the
error code for the most recently invoked statement API function
that can succeed or fail. A return value of zero means that no
error occurred. Client error message numbers are listed in the
MySQL errmsg.h
header file. Server error
message numbers are listed in
mysqld_error.h
. Errors also are listed at
Appendix B, Errors, Error Codes, and Common Problems.
An error code value. Zero if no error occurred.
None.
const char *mysql_stmt_error(MYSQL_STMT
*stmt)
For the statement specified by stmt
,
mysql_stmt_error()
returns a
null-terminated string containing the error message for the most
recently invoked statement API function that can succeed or
fail. An empty string (""
) is returned if no
error occurred. Either of these two tests can be used to check
for an error:
if(*mysql_stmt_errno(stmt)) { // an error occurred } if (mysql_stmt_error(stmt)[0]) { // an error occurred }
The language of the client error messages may be changed by recompiling the MySQL client library. You can choose error messages in several different languages.
A character string that describes the error. An empty string if no error occurred.
None.
int mysql_stmt_execute(MYSQL_STMT *stmt)
mysql_stmt_execute()
executes
the prepared query associated with the statement handle. The
currently bound parameter marker values are sent to server
during this call, and the server replaces the markers with this
newly supplied data.
Statement processing following
mysql_stmt_execute()
depends on
the type of statement:
For an UPDATE
,
DELETE
, or
INSERT
, the number of
changed, deleted, or inserted rows can be found by calling
mysql_stmt_affected_rows()
.
For a statement such as
SELECT
that generates a
result set, you must call
mysql_stmt_fetch()
to fetch
the data prior to calling any other functions that result in
query processing. For more information on how to fetch the
results, refer to Section 23.8.11.11, “mysql_stmt_fetch()”.
Do not following invocation of
mysql_stmt_execute()
with a
call to mysql_store_result()
or mysql_use_result()
. Those
functions are not intended for processing results from
prepared statements.
For statements that generate a result set, you can request that
mysql_stmt_execute()
open a
cursor for the statement by calling
mysql_stmt_attr_set()
before
executing the statement. If you execute a statement multiple
times, mysql_stmt_execute()
closes any open cursor before opening a new one.
Metadata changes to tables or views referred to by prepared statements are detected and cause automatic repreparation of the statement when it is next executed. For more information, see Section 13.5.4, “Automatic Prepared Statement Repreparation”.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
Out of memory.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
The following example demonstrates how to create and populate a
table using mysql_stmt_init()
,
mysql_stmt_prepare()
,
mysql_stmt_param_count()
,
mysql_stmt_bind_param()
,
mysql_stmt_execute()
, and
mysql_stmt_affected_rows()
. The
mysql
variable is assumed to be a valid
connection handle. For an example that shows how to retrieve
data, see Section 23.8.11.11, “mysql_stmt_fetch()”.
#define STRING_SIZE 50 #define DROP_SAMPLE_TABLE "DROP TABLE IF EXISTS test_table" #define CREATE_SAMPLE_TABLE "CREATE TABLE test_table(col1 INT,\ col2 VARCHAR(40),\ col3 SMALLINT,\ col4 TIMESTAMP)" #define INSERT_SAMPLE "INSERT INTO \ test_table(col1,col2,col3) \ VALUES(?,?,?)" MYSQL_STMT *stmt; MYSQL_BIND bind[3]; my_ulonglong affected_rows; int param_count; short small_data; int int_data; char str_data[STRING_SIZE]; unsigned long str_length; my_bool is_null; if (mysql_query(mysql, DROP_SAMPLE_TABLE)) { fprintf(stderr, " DROP TABLE failed\n"); fprintf(stderr, " %s\n", mysql_error(mysql)); exit(0); } if (mysql_query(mysql, CREATE_SAMPLE_TABLE)) { fprintf(stderr, " CREATE TABLE failed\n"); fprintf(stderr, " %s\n", mysql_error(mysql)); exit(0); } /* Prepare an INSERT query with 3 parameters */ /* (the TIMESTAMP column is not named; the server */ /* sets it to the current date and time) */ stmt = mysql_stmt_init(mysql); if (!stmt) { fprintf(stderr, " mysql_stmt_init(), out of memory\n"); exit(0); } if (mysql_stmt_prepare(stmt, INSERT_SAMPLE, strlen(INSERT_SAMPLE))) { fprintf(stderr, " mysql_stmt_prepare(), INSERT failed\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } fprintf(stdout, " prepare, INSERT successful\n"); /* Get the parameter count from the statement */ param_count= mysql_stmt_param_count(stmt); fprintf(stdout, " total parameters in INSERT: %d\n", param_count); if (param_count != 3) /* validate parameter count */ { fprintf(stderr, " invalid parameter count returned by MySQL\n"); exit(0); } /* Bind the data for all 3 parameters */ memset(bind, 0, sizeof(bind)); /* INTEGER PARAM */ /* This is a number type, so there is no need to specify buffer_length */ bind[0].buffer_type= MYSQL_TYPE_LONG; bind[0].buffer= (char *)&int_data; bind[0].is_null= 0; bind[0].length= 0; /* STRING PARAM */ bind[1].buffer_type= MYSQL_TYPE_STRING; bind[1].buffer= (char *)str_data; bind[1].buffer_length= STRING_SIZE; bind[1].is_null= 0; bind[1].length= &str_length; /* SMALLINT PARAM */ bind[2].buffer_type= MYSQL_TYPE_SHORT; bind[2].buffer= (char *)&small_data; bind[2].is_null= &is_null; bind[2].length= 0; /* Bind the buffers */ if (mysql_stmt_bind_param(stmt, bind)) { fprintf(stderr, " mysql_stmt_bind_param() failed\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } /* Specify the data values for the first row */ int_data= 10; /* integer */ strncpy(str_data, "MySQL", STRING_SIZE); /* string */ str_length= strlen(str_data); /* INSERT SMALLINT data as NULL */ is_null= 1; /* Execute the INSERT statement - 1*/ if (mysql_stmt_execute(stmt)) { fprintf(stderr, " mysql_stmt_execute(), 1 failed\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } /* Get the number of affected rows */ affected_rows= mysql_stmt_affected_rows(stmt); fprintf(stdout, " total affected rows(insert 1): %lu\n", (unsigned long) affected_rows); if (affected_rows != 1) /* validate affected rows */ { fprintf(stderr, " invalid affected rows by MySQL\n"); exit(0); } /* Specify data values for second row, then re-execute the statement */ int_data= 1000; strncpy(str_data, " The most popular Open Source database", STRING_SIZE); str_length= strlen(str_data); small_data= 1000; /* smallint */ is_null= 0; /* reset */ /* Execute the INSERT statement - 2*/ if (mysql_stmt_execute(stmt)) { fprintf(stderr, " mysql_stmt_execute, 2 failed\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } /* Get the total rows affected */ affected_rows= mysql_stmt_affected_rows(stmt); fprintf(stdout, " total affected rows(insert 2): %lu\n", (unsigned long) affected_rows); if (affected_rows != 1) /* validate affected rows */ { fprintf(stderr, " invalid affected rows by MySQL\n"); exit(0); } /* Close the statement */ if (mysql_stmt_close(stmt)) { fprintf(stderr, " failed while closing the statement\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); }
For complete examples on the use of prepared statement
functions, refer to the file
tests/mysql_client_test.c
. This file can
be obtained from a MySQL source distribution or from the
source repository (see Section 2.9, “Installing MySQL from Source”).
int mysql_stmt_fetch(MYSQL_STMT *stmt)
mysql_stmt_fetch()
returns the
next row in the result set. It can be called only while the
result set exists; that is, after a call to
mysql_stmt_execute()
for a
statement such as SELECT
that
produces a result set.
mysql_stmt_fetch()
returns row
data using the buffers bound by
mysql_stmt_bind_result()
. It
returns the data in those buffers for all the columns in the
current row set and the lengths are returned to the
length
pointer. All columns must be bound by
the application before it calls
mysql_stmt_fetch()
.
By default, result sets are fetched unbuffered a row at a time
from the server. To buffer the entire result set on the client,
call mysql_stmt_store_result()
after binding the data buffers and before calling
mysql_stmt_fetch()
.
If a fetched data value is a NULL
value, the
*is_null
value of the corresponding
MYSQL_BIND
structure contains TRUE (1).
Otherwise, the data and its length are returned in the
*buffer
and *length
elements based on the buffer type specified by the application.
Each numeric and temporal type has a fixed length, as listed in
the following table. The length of the string types depends on
the length of the actual data value, as indicated by
data_length
.
Type | Length |
---|---|
MYSQL_TYPE_TINY | 1 |
MYSQL_TYPE_SHORT | 2 |
MYSQL_TYPE_LONG | 4 |
MYSQL_TYPE_LONGLONG | 8 |
MYSQL_TYPE_FLOAT | 4 |
MYSQL_TYPE_DOUBLE | 8 |
MYSQL_TYPE_TIME | sizeof(MYSQL_TIME) |
MYSQL_TYPE_DATE | sizeof(MYSQL_TIME) |
MYSQL_TYPE_DATETIME | sizeof(MYSQL_TIME) |
MYSQL_TYPE_STRING | data length |
MYSQL_TYPE_BLOB | data_length |
In some cases you might want to determine the length of a column
value before fetching it with
mysql_stmt_fetch()
. For example,
the value might be a long string or
BLOB
value for which you want to
know how much space must be allocated. To accomplish this, you
can use these strategies:
Before invoking
mysql_stmt_fetch()
to
retrieve individual rows, pass
STMT_ATTR_UPDATE_MAX_LENGTH
to
mysql_stmt_attr_set()
, then
invoke
mysql_stmt_store_result()
to
buffer the entire result on the client side. Setting the
STMT_ATTR_UPDATE_MAX_LENGTH
attribute
causes the maximal length of column values to be indicated
by the max_length
member of the result
set metadata returned by
mysql_stmt_result_metadata()
.
Invoke mysql_stmt_fetch()
with a zero-length buffer for the column in question and a
pointer in which the real length can be stored. Then use the
real length with
mysql_stmt_fetch_column()
.
real_length= 0; bind[0].buffer= 0; bind[0].buffer_length= 0; bind[0].length= &real_length mysql_stmt_bind_result(stmt, bind); mysql_stmt_fetch(stmt); if (real_length > 0) { data= malloc(real_length); bind[0].buffer= data; bind[0].buffer_length= real_length; mysql_stmt_fetch_column(stmt, bind, 0, 0); }
Return Value | Description |
---|---|
0 | Successful, the data has been fetched to application data buffers. |
1 | Error occurred. Error code and message can be obtained by calling
mysql_stmt_errno() and
mysql_stmt_error() . |
MYSQL_NO_DATA | No more rows/data exists |
MYSQL_DATA_TRUNCATED | Data truncation occurred |
MYSQL_DATA_TRUNCATED
is returned when
truncation reporting is enabled. To determine which column
values were truncated when this value is returned, check the
error
members of the
MYSQL_BIND
structures used for fetching
values. Truncation reporting is enabled by default, but can be
controlled by calling
mysql_options()
with the
MYSQL_REPORT_DATA_TRUNCATION
option.
Commands were executed in an improper order.
Out of memory.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
The buffer type is MYSQL_TYPE_DATE
,
MYSQL_TYPE_TIME
,
MYSQL_TYPE_DATETIME
, or
MYSQL_TYPE_TIMESTAMP
, but the data type
is not DATE
,
TIME
,
DATETIME
, or
TIMESTAMP
.
All other unsupported conversion errors are returned from
mysql_stmt_bind_result()
.
The following example demonstrates how to fetch data from a
table using
mysql_stmt_result_metadata()
,
mysql_stmt_bind_result()
, and
mysql_stmt_fetch()
. (This
example expects to retrieve the two rows inserted by the example
shown in Section 23.8.11.10, “mysql_stmt_execute()”.) The
mysql
variable is assumed to be a valid
connection handle.
#define STRING_SIZE 50 #define SELECT_SAMPLE "SELECT col1, col2, col3, col4 \ FROM test_table" MYSQL_STMT *stmt; MYSQL_BIND bind[4]; MYSQL_RES *prepare_meta_result; MYSQL_TIME ts; unsigned long length[4]; int param_count, column_count, row_count; short small_data; int int_data; char str_data[STRING_SIZE]; my_bool is_null[4]; my_bool error[4]; /* Prepare a SELECT query to fetch data from test_table */ stmt = mysql_stmt_init(mysql); if (!stmt) { fprintf(stderr, " mysql_stmt_init(), out of memory\n"); exit(0); } if (mysql_stmt_prepare(stmt, SELECT_SAMPLE, strlen(SELECT_SAMPLE))) { fprintf(stderr, " mysql_stmt_prepare(), SELECT failed\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } fprintf(stdout, " prepare, SELECT successful\n"); /* Get the parameter count from the statement */ param_count= mysql_stmt_param_count(stmt); fprintf(stdout, " total parameters in SELECT: %d\n", param_count); if (param_count != 0) /* validate parameter count */ { fprintf(stderr, " invalid parameter count returned by MySQL\n"); exit(0); } /* Fetch result set meta information */ prepare_meta_result = mysql_stmt_result_metadata(stmt); if (!prepare_meta_result) { fprintf(stderr, " mysql_stmt_result_metadata(), \ returned no meta information\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } /* Get total columns in the query */ column_count= mysql_num_fields(prepare_meta_result); fprintf(stdout, " total columns in SELECT statement: %d\n", column_count); if (column_count != 4) /* validate column count */ { fprintf(stderr, " invalid column count returned by MySQL\n"); exit(0); } /* Execute the SELECT query */ if (mysql_stmt_execute(stmt)) { fprintf(stderr, " mysql_stmt_execute(), failed\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } /* Bind the result buffers for all 4 columns before fetching them */ memset(bind, 0, sizeof(bind)); /* INTEGER COLUMN */ bind[0].buffer_type= MYSQL_TYPE_LONG; bind[0].buffer= (char *)&int_data; bind[0].is_null= &is_null[0]; bind[0].length= &length[0]; bind[0].error= &error[0]; /* STRING COLUMN */ bind[1].buffer_type= MYSQL_TYPE_STRING; bind[1].buffer= (char *)str_data; bind[1].buffer_length= STRING_SIZE; bind[1].is_null= &is_null[1]; bind[1].length= &length[1]; bind[1].error= &error[1]; /* SMALLINT COLUMN */ bind[2].buffer_type= MYSQL_TYPE_SHORT; bind[2].buffer= (char *)&small_data; bind[2].is_null= &is_null[2]; bind[2].length= &length[2]; bind[2].error= &error[2]; /* TIMESTAMP COLUMN */ bind[3].buffer_type= MYSQL_TYPE_TIMESTAMP; bind[3].buffer= (char *)&ts; bind[3].is_null= &is_null[3]; bind[3].length= &length[3]; bind[3].error= &error[3]; /* Bind the result buffers */ if (mysql_stmt_bind_result(stmt, bind)) { fprintf(stderr, " mysql_stmt_bind_result() failed\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } /* Now buffer all results to client (optional step) */ if (mysql_stmt_store_result(stmt)) { fprintf(stderr, " mysql_stmt_store_result() failed\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); } /* Fetch all rows */ row_count= 0; fprintf(stdout, "Fetching results ...\n"); while (!mysql_stmt_fetch(stmt)) { row_count++; fprintf(stdout, " row %d\n", row_count); /* column 1 */ fprintf(stdout, " column1 (integer) : "); if (is_null[0]) fprintf(stdout, " NULL\n"); else fprintf(stdout, " %d(%ld)\n", int_data, length[0]); /* column 2 */ fprintf(stdout, " column2 (string) : "); if (is_null[1]) fprintf(stdout, " NULL\n"); else fprintf(stdout, " %s(%ld)\n", str_data, length[1]); /* column 3 */ fprintf(stdout, " column3 (smallint) : "); if (is_null[2]) fprintf(stdout, " NULL\n"); else fprintf(stdout, " %d(%ld)\n", small_data, length[2]); /* column 4 */ fprintf(stdout, " column4 (timestamp): "); if (is_null[3]) fprintf(stdout, " NULL\n"); else fprintf(stdout, " %04d-%02d-%02d %02d:%02d:%02d (%ld)\n", ts.year, ts.month, ts.day, ts.hour, ts.minute, ts.second, length[3]); fprintf(stdout, "\n"); } /* Validate rows fetched */ fprintf(stdout, " total rows fetched: %d\n", row_count); if (row_count != 2) { fprintf(stderr, " MySQL failed to return all rows\n"); exit(0); } /* Free the prepared result metadata */ mysql_free_result(prepare_meta_result); /* Close the statement */ if (mysql_stmt_close(stmt)) { fprintf(stderr, " failed while closing the statement\n"); fprintf(stderr, " %s\n", mysql_stmt_error(stmt)); exit(0); }
int mysql_stmt_fetch_column(MYSQL_STMT *stmt,
MYSQL_BIND *bind, unsigned int column, unsigned long
offset)
Fetch one column from the current result set row.
bind
provides the buffer where data should be
placed. It should be set up the same way as for
mysql_stmt_bind_result()
.
column
indicates which column to fetch. The
first column is numbered 0. offset
is the
offset within the data value at which to begin retrieving data.
This can be used for fetching the data value in pieces. The
beginning of the value is offset 0.
Zero for success. Nonzero if an error occurred.
Invalid column number.
The end of the result set has already been reached.
unsigned int mysql_stmt_field_count(MYSQL_STMT
*stmt)
Returns the number of columns for the most recent statement for
the statement handler. This value is zero for statements such as
INSERT
or
DELETE
that do not produce result
sets.
mysql_stmt_field_count()
can be
called after you have prepared a statement by invoking
mysql_stmt_prepare()
.
An unsigned integer representing the number of columns in a result set.
None.
my_bool mysql_stmt_free_result(MYSQL_STMT
*stmt)
Releases memory associated with the result set produced by
execution of the prepared statement. If there is a cursor open
for the statement,
mysql_stmt_free_result()
closes
it.
Zero for success. Nonzero if an error occurred.
MYSQL_STMT *mysql_stmt_init(MYSQL *mysql)
Create a MYSQL_STMT
handle. The handle should
be freed with mysql_stmt_close(MYSQL_STMT
*)
.
See also Section 23.8.9, “C API Prepared Statement Data Structures”, for more information.
A pointer to a MYSQL_STMT
structure in case
of success. NULL
if out of memory.
Out of memory.
my_ulonglong mysql_stmt_insert_id(MYSQL_STMT
*stmt)
Returns the value generated for an
AUTO_INCREMENT
column by the prepared
INSERT
or
UPDATE
statement. Use this
function after you have executed a prepared
INSERT
statement on a table which
contains an AUTO_INCREMENT
field.
See Section 23.8.7.37, “mysql_insert_id()”, for more information.
Value for AUTO_INCREMENT
column which was
automatically generated or explicitly set during execution of
prepared statement, or value generated by
LAST_INSERT_ID(
function. Return value is undefined if statement does not set
expr
)AUTO_INCREMENT
value.
None.
int mysql_stmt_next_result(MYSQL_STMT *mysql)
This function is used when you use prepared
CALL
statements to execute stored
procedures, which can return multiple result sets. Use a loop
that calls
mysql_stmt_next_result()
to
determine whether there are more results. If a procedure has
OUT
or INOUT
parameters,
their values will be returned as a single-row result set
following any other result sets. The values will appear in the
order in which they are declared in the procedure parameter
list.
mysql_stmt_next_result()
returns
a status to indicate whether more results exist. If
mysql_stmt_next_result()
returns
an error, there are no more results.
Before each call to
mysql_stmt_next_result()
, you
must call
mysql_stmt_free_result()
for the
current result if it produced a result set (rather than just a
result status).
After calling
mysql_stmt_next_result()
the
state of the connection is as if you had called
mysql_stmt_execute()
. This means
that you can call
mysql_stmt_bind_result()
,
mysql_stmt_affected_rows()
, and
so forth.
It is also possible to test whether there are more results by
calling mysql_more_results()
.
However, this function does not change the connection state, so
if it returns true, you must still call
mysql_stmt_next_result()
to
advance to the next result.
For an example that shows how to use
mysql_stmt_next_result()
, see
Section 23.8.20, “C API Support for Prepared CALL Statements”.
mysql_stmt_next_result()
was
added in MySQL 5.5.3.
Return Value | Description |
---|---|
0 | Successful and there are more results |
-1 | Successful and there are no more results |
>0 | An error occurred |
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
my_ulonglong mysql_stmt_num_rows(MYSQL_STMT
*stmt)
Returns the number of rows in the result set.
The use of mysql_stmt_num_rows()
depends on whether you used
mysql_stmt_store_result()
to
buffer the entire result set in the statement handle. If you use
mysql_stmt_store_result()
,
mysql_stmt_num_rows()
may be
called immediately. Otherwise, the row count is unavailable
unless you count the rows as you fetch them.
mysql_stmt_num_rows()
is
intended for use with statements that return a result set, such
as SELECT
. For statements such as
INSERT
,
UPDATE
, or
DELETE
, the number of affected
rows can be obtained with
mysql_stmt_affected_rows()
.
The number of rows in the result set.
None.
unsigned long mysql_stmt_param_count(MYSQL_STMT
*stmt)
Returns the number of parameter markers present in the prepared statement.
An unsigned long integer representing the number of parameters in a statement.
None.
See the Example in Section 23.8.11.10, “mysql_stmt_execute()”.
MYSQL_RES *mysql_stmt_param_metadata(MYSQL_STMT
*stmt)
This function currently does nothing.
int mysql_stmt_prepare(MYSQL_STMT *stmt, const char
*stmt_str, unsigned long length)
Given the statement handle returned by
mysql_stmt_init()
, prepares the
SQL statement pointed to by the string
stmt_str
and returns a status value. The
string length should be given by the length
argument. The string must consist of a single SQL statement. You
should not add a terminating semicolon
(“;
”) or \g
to the statement.
The application can include one or more parameter markers in the
SQL statement by embedding question mark (?
)
characters into the SQL string at the appropriate positions.
The markers are legal only in certain places in SQL statements.
For example, they are permitted in the
VALUES()
list of an
INSERT
statement (to specify
column values for a row), or in a comparison with a column in a
WHERE
clause to specify a comparison value.
However, they are not permitted for identifiers (such as table
or column names), or to specify both operands of a binary
operator such as the =
equal sign. The latter
restriction is necessary because it would be impossible to
determine the parameter type. In general, parameters are legal
only in Data Manipulation Language (DML) statements, and not in
Data Definition Language (DDL) statements.
The parameter markers must be bound to application variables
using mysql_stmt_bind_param()
before executing the statement.
Metadata changes to tables or views referred to by prepared statements are detected and cause automatic repreparation of the statement when it is next executed. For more information, see Section 13.5.4, “Automatic Prepared Statement Repreparation”.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
Out of memory.
The MySQL server has gone away.
The connection to the server was lost during the query
An unknown error occurred.
If the prepare operation was unsuccessful (that is,
mysql_stmt_prepare()
returns
nonzero), the error message can be obtained by calling
mysql_stmt_error()
.
See the Example in Section 23.8.11.10, “mysql_stmt_execute()”.
my_bool mysql_stmt_reset(MYSQL_STMT *stmt)
Resets a prepared statement on client and server to state after
prepare. It resets the statement on the server, data sent using
mysql_stmt_send_long_data()
,
unbuffered result sets and current errors. It does not clear
bindings or stored result sets. Stored result sets will be
cleared when executing the prepared statement (or closing it).
To re-prepare the statement with another query, use
mysql_stmt_prepare()
.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
The MySQL server has gone away.
The connection to the server was lost during the query
An unknown error occurred.
MYSQL_RES *mysql_stmt_result_metadata(MYSQL_STMT
*stmt)
If a statement passed to
mysql_stmt_prepare()
is one that
produces a result set,
mysql_stmt_result_metadata()
returns the result set metadata in the form of a pointer to a
MYSQL_RES
structure that can be used to
process the meta information such as number of fields and
individual field information. This result set pointer can be
passed as an argument to any of the field-based API functions
that process result set metadata, such as:
The result set structure should be freed when you are done with
it, which you can do by passing it to
mysql_free_result()
. This is
similar to the way you free a result set obtained from a call to
mysql_store_result()
.
The result set returned by
mysql_stmt_result_metadata()
contains only metadata. It does not contain any row results. The
rows are obtained by using the statement handle with
mysql_stmt_fetch()
.
A MYSQL_RES
result structure.
NULL
if no meta information exists for the
prepared query.
Out of memory.
An unknown error occurred.
See the Example in Section 23.8.11.11, “mysql_stmt_fetch()”.
MYSQL_ROW_OFFSET mysql_stmt_row_seek(MYSQL_STMT *stmt,
MYSQL_ROW_OFFSET offset)
Sets the row cursor to an arbitrary row in a statement result
set. The offset
value is a row offset that
should be a value returned from
mysql_stmt_row_tell()
or from
mysql_stmt_row_seek()
. This
value is not a row number; if you want to seek to a row within a
result set by number, use
mysql_stmt_data_seek()
instead.
This function requires that the result set structure contains
the entire result of the query, so
mysql_stmt_row_seek()
may be
used only in conjunction with
mysql_stmt_store_result()
.
The previous value of the row cursor. This value may be passed
to a subsequent call to
mysql_stmt_row_seek()
.
None.
MYSQL_ROW_OFFSET mysql_stmt_row_tell(MYSQL_STMT
*stmt)
Returns the current position of the row cursor for the last
mysql_stmt_fetch()
. This value
can be used as an argument to
mysql_stmt_row_seek()
.
You should use
mysql_stmt_row_tell()
only after
mysql_stmt_store_result()
.
The current offset of the row cursor.
None.
my_bool mysql_stmt_send_long_data(MYSQL_STMT *stmt,
unsigned int parameter_number, const char *data, unsigned long
length)
Enables an application to send parameter data to the server in
pieces (or “chunks”). Call this function after
mysql_stmt_bind_param()
and
before mysql_stmt_execute()
. It
can be called multiple times to send the parts of a character or
binary data value for a column, which must be one of the
TEXT
or
BLOB
data types.
parameter_number
indicates which parameter to
associate the data with. Parameters are numbered beginning with
0. data
is a pointer to a buffer containing
data to be sent, and length
indicates the
number of bytes in the buffer.
The next mysql_stmt_execute()
call ignores the bind buffer for all parameters that have been
used with
mysql_stmt_send_long_data()
since last
mysql_stmt_execute()
or
mysql_stmt_reset()
.
If you want to reset/forget the sent data, you can do it with
mysql_stmt_reset()
. See
Section 23.8.11.22, “mysql_stmt_reset()”.
As of MySQL 5.5.11, the
max_long_data_size
system
variable controls the maximum size of parameter values that can
be sent with
mysql_stmt_send_long_data()
. If
this variable not set at server startup, the default is the
value of the max_allowed_packet
system variable.
max_long_data_size
is
deprecated. In MySQL 5.6, it is removed and the maximum
parameter size is controlled by
max_allowed_packet
.
Zero for success. Nonzero if an error occurred.
The parameter does not have a string or binary type.
Commands were executed in an improper order.
The MySQL server has gone away.
Out of memory.
An unknown error occurred.
The following example demonstrates how to send the data for a
TEXT
column in chunks. It inserts
the data value 'MySQL - The most popular Open Source
database'
into the text_column
column. The mysql
variable is assumed to be a
valid connection handle.
#define INSERT_QUERY "INSERT INTO \ test_long_data(text_column) VALUES(?)" MYSQL_BIND bind[1]; long length; stmt = mysql_stmt_init(mysql); if (!stmt) { fprintf(stderr, " mysql_stmt_init(), out of memory\n"); exit(0); } if (mysql_stmt_prepare(stmt, INSERT_QUERY, strlen(INSERT_QUERY))) { fprintf(stderr, "\n mysql_stmt_prepare(), INSERT failed"); fprintf(stderr, "\n %s", mysql_stmt_error(stmt)); exit(0); } memset(bind, 0, sizeof(bind)); bind[0].buffer_type= MYSQL_TYPE_STRING; bind[0].length= &length; bind[0].is_null= 0; /* Bind the buffers */ if (mysql_stmt_bind_param(stmt, bind)) { fprintf(stderr, "\n param bind failed"); fprintf(stderr, "\n %s", mysql_stmt_error(stmt)); exit(0); } /* Supply data in chunks to server */ if (mysql_stmt_send_long_data(stmt,0,"MySQL",5)) { fprintf(stderr, "\n send_long_data failed"); fprintf(stderr, "\n %s", mysql_stmt_error(stmt)); exit(0); } /* Supply the next piece of data */ if (mysql_stmt_send_long_data(stmt,0, " - The most popular Open Source database",40)) { fprintf(stderr, "\n send_long_data failed"); fprintf(stderr, "\n %s", mysql_stmt_error(stmt)); exit(0); } /* Now, execute the query */ if (mysql_stmt_execute(stmt)) { fprintf(stderr, "\n mysql_stmt_execute failed"); fprintf(stderr, "\n %s", mysql_stmt_error(stmt)); exit(0); }
const char *mysql_stmt_sqlstate(MYSQL_STMT
*stmt)
For the statement specified by stmt
,
mysql_stmt_sqlstate()
returns a
null-terminated string containing the SQLSTATE error code for
the most recently invoked prepared statement API function that
can succeed or fail. The error code consists of five characters.
"00000"
means “no error.” The
values are specified by ANSI SQL and ODBC. For a list of
possible values, see Appendix B, Errors, Error Codes, and Common Problems.
Not all MySQL errors are mapped to SQLSTATE codes. The value
"HY000"
(general error) is used for unmapped
errors.
A null-terminated character string containing the SQLSTATE error code.
int mysql_stmt_store_result(MYSQL_STMT *stmt)
Result sets are produced by calling
mysql_stmt_execute()
to executed
prepared statements for SQL statements such as
SELECT
,
SHOW
,
DESCRIBE
, and
EXPLAIN
. By default, result sets
for successfully executed prepared statements are not buffered
on the client and
mysql_stmt_fetch()
fetches them
one at a time from the server. To cause the complete result set
to be buffered on the client, call
mysql_stmt_store_result()
after
binding data buffers with
mysql_stmt_bind_result()
and
before calling
mysql_stmt_fetch()
to fetch
rows. (For an example, see Section 23.8.11.11, “mysql_stmt_fetch()”.)
mysql_stmt_store_result()
is
optional for result set processing, unless you will call
mysql_stmt_data_seek()
,
mysql_stmt_row_seek()
, or
mysql_stmt_row_tell()
. Those
functions require a seekable result set.
It is unnecessary to call
mysql_stmt_store_result()
after
executing an SQL statement that does not produce a result set,
but if you do, it does not harm or cause any notable performance
problem. You can detect whether the statement produced a result
set by checking if
mysql_stmt_result_metadata()
returns NULL
. For more information, refer to
Section 23.8.11.23, “mysql_stmt_result_metadata()”.
MySQL does not by default calculate
MYSQL_FIELD->max_length
for all columns
in mysql_stmt_store_result()
because calculating this would slow down
mysql_stmt_store_result()
considerably and most applications do not need
max_length
. If you want
max_length
to be updated, you can call
mysql_stmt_attr_set(MYSQL_STMT,
STMT_ATTR_UPDATE_MAX_LENGTH, &flag)
to enable
this. See Section 23.8.11.3, “mysql_stmt_attr_set()”.
Zero for success. Nonzero if an error occurred.
Commands were executed in an improper order.
Out of memory.
The MySQL server has gone away.
The connection to the server was lost during the query.
An unknown error occurred.
To create a threaded client, use the functions described in the following sections. See also Section 23.8.4.2, “Writing C API Threaded Client Programs”.
void my_init(void)
my_init()
initializes some
global variables that MySQL needs. It also calls
mysql_thread_init()
for this
thread.
It is necessary for my_init()
to
be called early in the initialization phase of a program's use
of the MySQL library. However,
my_init()
is automatically
called by mysql_init()
,
mysql_library_init()
,
mysql_server_init()
, and
mysql_connect()
. If you ensure
that your program invokes one of those functions before any
other MySQL calls, there is no need to invoke
my_init()
explicitly.
To access the prototype for
my_init()
, your program should
include these header files:
#include <my_global.h> #include <my_sys.h>
None.
void mysql_thread_end(void)
This function needs to be called before calling
pthread_exit()
to free memory allocated by
mysql_thread_init()
.
mysql_thread_end()
is
not invoked automatically by the client library. It
must be called explicitly to avoid a memory leak.
None.
my_bool mysql_thread_init(void)
This function must be called early within each created thread to
initialize thread-specific variables. However, you may not
necessarily need to invoke it explicitly:
mysql_thread_init()
is
automatically called by
my_init()
, which itself is
automatically called by
mysql_init()
,
mysql_library_init()
,
mysql_server_init()
, and
mysql_connect()
. If you invoke
any of those functions,
mysql_thread_init()
will be
called for you.
Zero for success. Nonzero if an error occurred.
MySQL applications can be written to use an embedded server. See
Section 23.7, “libmysqld, the Embedded MySQL Server Library”. To write such an application, you
must link it against the libmysqld
library by
using the -lmysqld
flag rather than linking it
against the libmysqlclient
client library by
using the -lmysqlclient
flag. However, the calls
to initialize and finalize the library are the same whether you
write a client application or one that uses the embedded server:
Call mysql_library_init()
to
initialize the library and
mysql_library_end()
when you are
done with it. See Section 23.8.6, “C API Function Overview”.
int mysql_server_init(int argc, char **argv, char
**groups)
This function initializes the MySQL library, which must be done
before you call any other MySQL function. However,
mysql_server_init()
is
deprecated and you should call
mysql_library_init()
instead.
See Section 23.8.7.40, “mysql_library_init()”.
Zero for success. Nonzero if an error occurred.
void mysql_server_end(void)
This function finalizes the MySQL library, which should be done
when you are done using the library. However,
mysql_server_end()
is deprecated
and mysql_library_end()
should
be used instead. See Section 23.8.7.39, “mysql_library_end()”.
None.
This section describes functions used for the client-side plugin
API. They enable management of client plugins. For a description
of the st_mysql_client_plugin
structure used by
these functions, see Section 24.2.4.2.3, “Client Plugin Descriptors”.
It is unlikely that a client program needs to call the functions
in this section. For example, a client that supports the use of
authentication plugins normally causes a plugin to be loaded by
calling mysql_options()
to set the
MYSQL_DEFAULT_AUTH
and
MYSQL_PLUGIN_DIR
options:
char *plugin_dir = "path_to_plugin_dir
"; char *default_auth = "plugin_name
"; /* ... process command-line options ... */ mysql_options(&mysql, MYSQL_PLUGIN_DIR, plugin_dir); mysql_options(&mysql, MYSQL_DEFAULT_AUTH, default_auth);
Typically, the program will also accept
--plugin-dir
and --default-auth
options that enable users to override the default values.
struct st_mysql_client_plugin
*mysql_client_find_plugin(MYSQL *mysql, const char *name, int
type)
Returns a pointer to a loaded plugin, loading the plugin first if necessary. An error occurs if the type is invalid or the plugin cannot be found or loaded.
Specify the parameters as follows:
mysql
: A pointer to a
MYSQL
structure. The plugin API does not
require a connection to a MySQL server, but this structure
must be properly initialized. The structure is used to
obtain connection-related information.
name
: The plugin name.
type
: The plugin type.
This function was added in MySQL 5.5.7.
A pointer to the plugin for success. NULL
if
an error occurred.
To check for errors, call the
mysql_error()
or
mysql_errno()
function. See
Section 23.8.7.15, “mysql_error()”, and
Section 23.8.7.14, “mysql_errno()”.
MYSQL mysql; struct st_mysql_client_plugin *p; if ((p = mysql_client_find_plugin(&mysql, "myplugin", MYSQL_CLIENT_AUTHENTICATION_PLUGIN, 0))) { printf("Plugin version: %d.%d.%d\n", p->version[0], p->version[1], p->version[2]); }
struct st_mysql_client_plugin
*mysql_client_register_plugin(MYSQL *mysql, struct
st_mysql_client_plugin *plugin)
Adds a plugin structure to the list of loaded plugins. An error occurs if the plugin is already loaded.
Specify the parameters as follows:
mysql
: A pointer to a
MYSQL
structure. The plugin API does not
require a connection to a MySQL server, but this structure
must be properly initialized. The structure is used to
obtain connection-related information.
plugin
: A pointer to the plugin
structure.
This function was added in MySQL 5.5.7.
A pointer to the plugin for success. NULL
if
an error occurred.
To check for errors, call the
mysql_error()
or
mysql_errno()
function. See
Section 23.8.7.15, “mysql_error()”, and
Section 23.8.7.14, “mysql_errno()”.
struct st_mysql_client_plugin *mysql_load_plugin(MYSQL
*mysql, const char *name, int type, int argc, ...)
Loads a MySQL client plugin, specified by name and type. An error occurs if the type is invalid or the plugin cannot be loaded.
It is not possible to load multiple plugins of the same type. An error occurs if you try to load a plugin of a type already loaded.
Specify the parameters as follows:
mysql
: A pointer to a
MYSQL
structure. The plugin API does not
require a connection to a MySQL server, but this structure
must be properly initialized. The structure is used to
obtain connection-related information.
name
: The name of the plugin to load.
type
: The type of plugin to load, or
−1 to disable type checking. If type is not −1,
only plugins matching the type are considered for loading.
argc
: The number of following arguments
(0 if there are none). Interpretation of any following
arguments depends on the plugin type.
This function was added in MySQL 5.5.7.
Another way to cause plugins to be loaded is to set the
LIBMYSQL_PLUGINS
environment variable to a
semicolon-separated list of plugin names. For example:
shell> export LIBMYSQL_PLUGINS="myplugin1;myplugin2"
Plugins named by LIBMYSQL_PLUGINS
are loaded
when the client program calls
mysql_library_init()
. No error
is reported if problems occur loading these plugins.
A pointer to the plugin if it was loaded successfully.
NULL
if an error occurred.
To check for errors, call the
mysql_error()
or
mysql_errno()
function. See
Section 23.8.7.15, “mysql_error()”, and
Section 23.8.7.14, “mysql_errno()”.
MYSQL mysql; if(!mysql_load_plugin(&mysql, "myplugin", MYSQL_CLIENT_AUTHENTICATION_PLUGIN, 0)) { fprintf(stderr, "Error: %s\n", mysql_error(&mysql)); exit(-1); }
See also Section 23.8.14.3, “mysql_load_plugin()”, Section 23.8.7.15, “mysql_error()”, Section 23.8.7.14, “mysql_errno()”.
struct st_mysql_client_plugin
*mysql_load_plugin_v(MYSQL *mysql, const char *name, int type,
int argc, va_list args)
This function is equivalent to
mysql_load_plugin()
, but it
accepts a va_list
instead of a variable list
of parameters.
This function was added in MySQL 5.5.7.
See also Section 23.8.14.3, “mysql_load_plugin()”.
int mysql_plugin_options(struct st_mysql_client_plugin
*plugin, const char *option, const void *value)
Passes an option type and value to a plugin. This function can be called multiple times to set several options. If the plugin does not have an option handler, an error occurs.
Specify the parameters as follows:
plugin
: A pointer to the plugin
structure.
option
: The option to be set.
value
: A pointer to the option value.
This function was added in MySQL 5.5.7.
Zero for success, 1 if an error occurred. If the plugin has an option handler, that handler should also return zero for success and 1 if an error occurred.
It is possible for
mysql_store_result()
to return
NULL
following a successful call to
mysql_query()
. When this
happens, it means one of the following conditions occurred:
You can always check whether the statement should have produced
a nonempty result by calling
mysql_field_count()
. If
mysql_field_count()
returns
zero, the result is empty and the last query was a statement
that does not return values (for example, an
INSERT
or a
DELETE
). If
mysql_field_count()
returns a
nonzero value, the statement should have produced a nonempty
result. See the description of the
mysql_field_count()
function for
an example.
You can test for an error by calling
mysql_error()
or
mysql_errno()
.
In addition to the result set returned by a query, you can also get the following information:
mysql_affected_rows()
returns the number of rows affected by the last query when
doing an INSERT
,
UPDATE
, or
DELETE
.
For a fast re-create, use TRUNCATE
TABLE
.
mysql_num_rows()
returns the
number of rows in a result set. With
mysql_store_result()
,
mysql_num_rows()
may be
called as soon as
mysql_store_result()
returns. With
mysql_use_result()
,
mysql_num_rows()
may be
called only after you have fetched all the rows with
mysql_fetch_row()
.
mysql_insert_id()
returns
the ID generated by the last query that inserted a row into
a table with an AUTO_INCREMENT
index. See
Section 23.8.7.37, “mysql_insert_id()”.
Some queries
(LOAD DATA INFILE
...
,
INSERT INTO
... SELECT ...
,
UPDATE
) return additional
information. The result is returned by
mysql_info()
. See the
description for mysql_info()
for the format of the string that it returns.
mysql_info()
returns a
NULL
pointer if there is no additional
information.
If you insert a record into a table that contains an
AUTO_INCREMENT
column, you can obtain the
value stored into that column by calling the
mysql_insert_id()
function.
You can check from your C applications whether a value was
stored in an AUTO_INCREMENT
column by
executing the following code (which assumes that you've checked
that the statement succeeded). It determines whether the query
was an INSERT
with an
AUTO_INCREMENT
index:
if ((result = mysql_store_result(&mysql)) == 0 && mysql_field_count(&mysql) == 0 && mysql_insert_id(&mysql) != 0) { used_id = mysql_insert_id(&mysql); }
When a new AUTO_INCREMENT
value has been
generated, you can also obtain it by executing a SELECT
LAST_INSERT_ID()
statement with
mysql_query()
and retrieving the
value from the result set returned by the statement.
When inserting multiple values, the last automatically incremented value is returned.
For LAST_INSERT_ID()
, the most
recently generated ID is maintained in the server on a
per-connection basis. It is not changed by another client. It is
not even changed if you update another
AUTO_INCREMENT
column with a nonmagic value
(that is, a value that is not NULL
and not
0
). Using
LAST_INSERT_ID()
and
AUTO_INCREMENT
columns simultaneously from
multiple clients is perfectly valid. Each client will receive
the last inserted ID for the last statement
that client executed.
If you want to use the ID that was generated for one table and insert it into a second table, you can use SQL statements like this:
INSERT INTO foo (auto,text) VALUES(NULL,'text'); # generate ID by inserting NULL INSERT INTO foo2 (id,text) VALUES(LAST_INSERT_ID(),'text'); # use ID in second table
mysql_insert_id()
returns the
value stored into an AUTO_INCREMENT
column,
whether that value is automatically generated by storing
NULL
or 0
or was specified
as an explicit value.
LAST_INSERT_ID()
returns only
automatically generated AUTO_INCREMENT
values. If you store an explicit value other than
NULL
or 0
, it does not
affect the value returned by
LAST_INSERT_ID()
.
For more information on obtaining the last ID in an
AUTO_INCREMENT
column:
For information on
LAST_INSERT_ID()
, which can
be used within an SQL statement, see
Section 12.14, “Information Functions”.
For information on
mysql_insert_id()
, the
function you use from within the C API, see
Section 23.8.7.37, “mysql_insert_id()”.
For information on obtaining the auto-incremented value when
using Connector/J, see
Retrieving AUTO_INCREMENT
Column Values through JDBC.
For information on obtaining the auto-incremented value when using Connector/ODBC, see Obtaining Auto-Increment Values.
The MySQL client library can perform an automatic reconnection to the server if it finds that the connection is down when you attempt to send a statement to the server to be executed. If auto-reconnect is enabled, the library tries once to reconnect to the server and send the statement again.
Auto-reconnect is disabled by default.
If it is important for your application to know that the
connection has been dropped (so that it can exit or take action to
adjust for the loss of state information), be sure that
auto-reconnect is disabled. To ensure this, call
mysql_options()
with the
MYSQL_OPT_RECONNECT
option:
my_bool reconnect = 0; mysql_options(&mysql, MYSQL_OPT_RECONNECT, &reconnect);
If the connection has gone down, the effect of
mysql_ping()
depends on the
auto-reconnect state. If auto-reconnect is enabled,
mysql_ping()
performs a reconnect.
Otherwise, it returns an error.
Some client programs might provide the capability of controlling
automatic reconnection. For example, mysql
reconnects by default, but the
--skip-reconnect
option can be used to suppress this behavior.
If an automatic reconnection does occur (for example, as a result
of calling mysql_ping()
), there is
no explicit indication of it. To check for reconnection, call
mysql_thread_id()
to get the
original connection identifier before calling
mysql_ping()
, then call
mysql_thread_id()
again to see
whether the identifier changed.
Automatic reconnection can be convenient because you need not implement your own reconnect code, but if a reconnection does occur, several aspects of the connection state are reset on the server side and your application will not be notified.
The connection-related state is affected as follows:
Any active transactions are rolled back and autocommit mode is reset.
All table locks are released.
All TEMPORARY
tables are closed (and
dropped).
Session system variables are reinitialized to the values of
the corresponding global system variables, including system
variables that are set implicitly by statements such as
SET NAMES
.
User variable settings are lost.
Prepared statements are released.
HANDLER
variables are closed.
The value of LAST_INSERT_ID()
is reset to 0.
Locks acquired with GET_LOCK()
are released.
If the connection drops, it is possible that the session
associated with the connection on the server side will still be
running if the server has not yet detected that the client is no
longer connected. In this case, any locks held by the original
connection still belong to that session, so you may want to kill
it by calling mysql_kill()
.
By default, mysql_query()
and
mysql_real_query()
interpret their
statement string argument as a single statement to be executed,
and you process the result according to whether the statement
produces a result set (a set of rows, as for
SELECT
) or an affected-rows count
(as for INSERT
,
UPDATE
, and so forth).
MySQL also supports the execution of a string containing multiple
statements separated by semicolon (;
)
characters. This capability is enabled by special options that are
specified either when you connect to the server with
mysql_real_connect()
or after
connecting by calling`
mysql_set_server_option()
.
Executing a multiple-statement string can produce multiple result
sets or row-count indicators. Processing these results involves a
different approach than for the single-statement case: After
handling the result from the first statement, it is necessary to
check whether more results exist and process them in turn if so.
To support multiple-result processing, the C API includes the
mysql_more_results()
and
mysql_next_result()
functions.
These functions are used at the end of a loop that iterates as
long as more results are available. Failure to process
the result this way may result in a dropped connection to the
server.
Multiple-result processing also is required if you execute
CALL
statements for stored
procedures. Results from a stored procedure have these
characteristics:
Statements within the procedure may produce result sets (for
example, if it executes SELECT
statements). These result sets are returned in the order that
they are produced as the procedure executes.
In general, the caller cannot know how many result sets a procedure will return. Procedure execution may depend on loops or conditional statements that cause the execution path to differ from one call to the next. Therefore, you must be prepared to retrieve multiple results.
The final result from the procedure is a status result that includes no result set. The status indicates whether the procedure succeeded or an error occurred.
The multiple statement and result capabilities can be used only
with mysql_query()
or
mysql_real_query()
. They cannot be
used with the prepared statement interface. Prepared statement
handles are defined to work only with strings that contain a
single statement. See Section 23.8.8, “C API Prepared Statements”.
To enable multiple-statement execution and result processing, the following options may be used:
The mysql_real_connect()
function has a flags
argument for which two
option values are relevant:
CLIENT_MULTI_RESULTS
enables the client
program to process multiple results. This option
must be enabled if you execute
CALL
statements for stored
procedures that produce result sets. Otherwise, such
procedures result in an error Error 1312 (0A000):
PROCEDURE
. As of
MySQL 5.5.3, proc_name
can't
return a result set in the given contextCLIENT_MULTI_RESULTS
is
enabled by default.
CLIENT_MULTI_STATEMENTS
enables
mysql_query()
and
mysql_real_query()
to
execute statement strings containing multiple statements
separated by semicolons. This option also enables
CLIENT_MULTI_RESULTS
implicitly, so a
flags
argument of
CLIENT_MULTI_STATEMENTS
to
mysql_real_connect()
is
equivalent to an argument of
CLIENT_MULTI_STATEMENTS |
CLIENT_MULTI_RESULTS
. That is,
CLIENT_MULTI_STATEMENTS
is sufficient
to enable multiple-statement execution and all
multiple-result processing.
After the connection to the server has been established, you
can use the
mysql_set_server_option()
function to enable or disable multiple-statement execution by
passing it an argument of
MYSQL_OPTION_MULTI_STATEMENTS_ON
or
MYSQL_OPTION_MULTI_STATEMENTS_OFF
. Enabling
multiple-statement execution with this function also enables
processing of “simple” results for a
multiple-statement string where each statement produces a
single result, but is not sufficient to
permit processing of stored procedures that produce result
sets.
The following procedure outlines a suggested strategy for handling multiple statements:
Pass CLIENT_MULTI_STATEMENTS
to
mysql_real_connect()
, to fully
enable multiple-statement execution and multiple-result
processing.
After calling mysql_query()
or
mysql_real_query()
and
verifying that it succeeds, enter a loop within which you
process statement results.
For each iteration of the loop, handle the current statement result, retrieving either a result set or an affected-rows count. If an error occurs, exit the loop.
At the end of the loop, call
mysql_next_result()
to check
whether another result exists and initiate retrieval for it if
so. If no more results are available, exit the loop.
One possible implementation of the preceding strategy is shown
following. The final part of the loop can be reduced to a simple
test of whether
mysql_next_result()
returns
nonzero. The code as written distinguishes between no more results
and an error, which enables a message to be printed for the latter
occurrence.
/* connect to server with the CLIENT_MULTI_STATEMENTS option */ if (mysql_real_connect (mysql, host_name, user_name, password, db_name, port_num, socket_name, CLIENT_MULTI_STATEMENTS) == NULL) { printf("mysql_real_connect() failed\n"); mysql_close(mysql); exit(1); } /* execute multiple statements */ status = mysql_query(mysql, "DROP TABLE IF EXISTS test_table;\ CREATE TABLE test_table(id INT);\ INSERT INTO test_table VALUES(10);\ UPDATE test_table SET id=20 WHERE id=10;\ SELECT * FROM test_table;\ DROP TABLE test_table"); if (status) { printf("Could not execute statement(s)"); mysql_close(mysql); exit(0); } /* process each statement result */ do { /* did current statement return data? */ result = mysql_store_result(mysql); if (result) { /* yes; process rows and free the result set */ process_result_set(mysql, result); mysql_free_result(result); } else /* no result set or error */ { if (mysql_field_count(mysql) == 0) { printf("%lld rows affected\n", mysql_affected_rows(mysql)); } else /* some error occurred */ { printf("Could not retrieve result set\n"); break; } } /* more results? -1 = no, >0 = error, 0 = yes (keep looping) */ if ((status = mysql_next_result(mysql)) > 0) printf("Could not execute statement\n"); } while (status == 0); mysql_close(mysql);
Here follows a list of the currently known problems with prepared statements:
TIME
,
TIMESTAMP
, and
DATETIME
do not support parts
of seconds (for example, from
DATE_FORMAT()
).
When converting an integer to string,
ZEROFILL
is honored with prepared
statements in some cases where the MySQL server does not print
the leading zeros. (For example, with
MIN(
).
number-with-zerofill
)
When converting a floating-point number to a string in the client, the rightmost digits of the converted value may differ slightly from those of the original value.
Prepared statements use the query cache under the conditions described in Section 8.10.3.1, “How the Query Cache Operates”.
Prepared statements do not support multi-statements (that is,
multiple statements within a single string separated by
;
characters).
Before MySQL 5.5.3, prepared
CALL
statements cannot invoke
stored procedures that return result sets because prepared
statements do not support multiple result sets. Nor can the
calling application access a stored procedure's
OUT
or INOUT
parameters
when the procedure returns. As of MySQL 5.5.3, these
capabilities are supported as described in
Section 23.8.20, “C API Support for Prepared CALL Statements”.
The binary (prepared statement) protocol enables you to send and
receive date and time values (DATE
,
TIME
,
DATETIME
, and
TIMESTAMP
), using the
MYSQL_TIME
structure. The members of this
structure are described in
Section 23.8.9, “C API Prepared Statement Data Structures”.
To send temporal data values, create a prepared statement using
mysql_stmt_prepare()
. Then, before
calling mysql_stmt_execute()
to
execute the statement, use the following procedure to set up each
temporal parameter:
In the MYSQL_BIND
structure associated with
the data value, set the buffer_type
member
to the type that indicates what kind of temporal value you're
sending. For DATE
,
TIME
,
DATETIME
, or
TIMESTAMP
values, set
buffer_type
to
MYSQL_TYPE_DATE
,
MYSQL_TYPE_TIME
,
MYSQL_TYPE_DATETIME
, or
MYSQL_TYPE_TIMESTAMP
, respectively.
Set the buffer
member of the
MYSQL_BIND
structure to the address of the
MYSQL_TIME
structure in which you pass the
temporal value.
Fill in the members of the MYSQL_TIME
structure that are appropriate for the type of temporal value
to pass.
Use mysql_stmt_bind_param()
to
bind the parameter data to the statement. Then you can call
mysql_stmt_execute()
.
To retrieve temporal values, the procedure is similar, except that
you set the buffer_type
member to the type of
value you expect to receive, and the buffer
member to the address of a MYSQL_TIME
structure
into which the returned value should be placed. Use
mysql_stmt_bind_result()
to bind
the buffers to the statement after calling
mysql_stmt_execute()
and before
fetching the results.
Here is a simple example that inserts
DATE
,
TIME
, and
TIMESTAMP
data. The
mysql
variable is assumed to be a valid
connection handle.
MYSQL_TIME ts; MYSQL_BIND bind[3]; MYSQL_STMT *stmt; strmov(query, "INSERT INTO test_table(date_field, time_field, \ timestamp_field) VALUES(?,?,?"); stmt = mysql_stmt_init(mysql); if (!stmt) { fprintf(stderr, " mysql_stmt_init(), out of memory\n"); exit(0); } if (mysql_stmt_prepare(mysql, query, strlen(query))) { fprintf(stderr, "\n mysql_stmt_prepare(), INSERT failed"); fprintf(stderr, "\n %s", mysql_stmt_error(stmt)); exit(0); } /* set up input buffers for all 3 parameters */ bind[0].buffer_type= MYSQL_TYPE_DATE; bind[0].buffer= (char *)&ts; bind[0].is_null= 0; bind[0].length= 0; ... bind[1]= bind[2]= bind[0]; ... mysql_stmt_bind_param(stmt, bind); /* supply the data to be sent in the ts structure */ ts.year= 2002; ts.month= 02; ts.day= 03; ts.hour= 10; ts.minute= 45; ts.second= 20; mysql_stmt_execute(stmt); ..
This section describes prepared-statement support in the C API for
stored procedures executed using
CALL
statements:
Prior to MySQL 5.5.3, prepared CALL
statements can be used only for stored procedures that produce at
most one result set. Nor can the calling application use
placeholders for OUT
or
INOUT
parameters.
MySQL 5.5.3 expands support for stored procedures executed using
prepared CALL
statements in the
following ways:
A stored procedure can produce any number of result sets. The number of columns and the data types of the columns need not be the same for all result sets.
The final values of OUT
and
INOUT
parameters are available to the
calling application after the procedure returns. These
parameters are returned as an extra single-row result set
following any result sets produced by the procedure itself.
The row contains the values of the OUT
and
INOUT
parameters in the order in which they
are declared in the procedure parameter list.
The following discussion shows how to use these capabilities
through the C API for prepared statements. To use prepared
CALL
statements through the
PREPARE
and
EXECUTE
statements, see
Section 13.2.1, “CALL Syntax”.
If an application might be compiled or executed in a context where
a version of MySQL older than 5.5.3 is used, prepared
CALL
capabilities for multiple
result sets and OUT
or INOUT
parameters might not be available:
For the client side, the application will not compile unless the libraries are from MySQL 5.5.3 or higher (the API function and symbols introduced in that version will not be present).
To verify at runtime that the server is recent enough, a client can use this test:
if (mysql_get_server_version(mysql) < 50503) { fprintf(stderr, "Server does not support required CALL capabilities\n"); mysql_close(mysql); exit (1); }
An application that executes a prepared
CALL
statement should use a loop
that fetches a result and then invokes
mysql_stmt_next_result()
to
determine whether there are more results. The results consist of
any result sets produced by the stored procedure followed by a
final status value that indicates whether the procedure terminated
successfully.
If the procedure has OUT
or
INOUT
parameters, the result set preceding the
final status value contains their values. To determine whether a
result set contains parameter values, test whether the
SERVER_PS_OUT_PARAMS
bit is set in the
server_status
member of the
MYSQL
connection handler:
mysql->server_status & SERVER_PS_OUT_PARAMS
The following example uses a prepared
CALL
statement to execute a stored
procedure that produces multiple result sets and that provides
parameter values back to the caller by means of
OUT
and INOUT
parameters.
The procedure takes parameters of all three types
(IN
, OUT
,
INOUT
), displays their initial values, assigns
new values, displays the updated values, and returns. The expected
return information from the procedure therefore consists of
multiple result sets and a final status:
One result set from a SELECT
that displays the initial parameter values:
10
, NULL
,
30
. (The OUT
parameter
is assigned a value by the caller, but this assignment is
expected to be ineffective: OUT
parameters
are seen as NULL
within a procedure until
assigned a value within the procedure.)
One result set from a SELECT
that displays the modified parameter values:
100
, 200
,
300
.
One result set containing the final OUT
and
INOUT
parameter values:
200
, 300
.
A final status packet.
The code to execute the procedure:
MYSQL_STMT *stmt; MYSQL_BIND ps_params[3]; /* input parameter buffers */ int int_data[3]; /* input/output values */ my_bool is_null[3]; /* output value nullability */ int status; /* set up stored procedure */ status = mysql_query(mysql, "DROP PROCEDURE IF EXISTS p1"); test_error(mysql, status); status = mysql_query(mysql, "CREATE PROCEDURE p1(" " IN p_in INT, " " OUT p_out INT, " " INOUT p_inout INT) " "BEGIN " " SELECT p_in, p_out, p_inout; " " SET p_in = 100, p_out = 200, p_inout = 300; " " SELECT p_in, p_out, p_inout; " "END"); test_error(mysql, status); /* initialize and prepare CALL statement with parameter placeholders */ stmt = mysql_stmt_init(mysql); if (!stmt) { printf("Could not initialize statement\n"); exit(1); } status = mysql_stmt_prepare(stmt, "CALL p1(?, ?, ?)", 16); test_stmt_error(stmt, status); /* initialize parameters: p_in, p_out, p_inout (all INT) */ memset(ps_params, 0, sizeof (ps_params)); ps_params[0].buffer_type = MYSQL_TYPE_LONG; ps_params[0].buffer = (char *) &int_data[0]; ps_params[0].length = 0; ps_params[0].is_null = 0; ps_params[1].buffer_type = MYSQL_TYPE_LONG; ps_params[1].buffer = (char *) &int_data[1]; ps_params[1].length = 0; ps_params[1].is_null = 0; ps_params[2].buffer_type = MYSQL_TYPE_LONG; ps_params[2].buffer = (char *) &int_data[2]; ps_params[2].length = 0; ps_params[2].is_null = 0; /* bind parameters */ status = mysql_stmt_bind_param(stmt, ps_params); test_stmt_error(stmt, status); /* assign values to parameters and execute statement */ int_data[0]= 10; /* p_in */ int_data[1]= 20; /* p_out */ int_data[2]= 30; /* p_inout */ status = mysql_stmt_execute(stmt); test_stmt_error(stmt, status); /* process results until there are no more */ do { int i; int num_fields; /* number of columns in result */ MYSQL_FIELD *fields; /* for result set metadata */ MYSQL_BIND *rs_bind; /* for output buffers */ /* the column count is > 0 if there is a result set */ /* 0 if the result is only the final status packet */ num_fields = mysql_stmt_field_count(stmt); if (num_fields > 0) { /* there is a result set to fetch */ printf("Number of columns in result: %d\n", (int) num_fields); /* what kind of result set is this? */ printf("Data: "); if(mysql->server_status & SERVER_PS_OUT_PARAMS) printf("this result set contains OUT/INOUT parameters\n"); else printf("this result set is produced by the procedure\n"); MYSQL_RES *rs_metadata = mysql_stmt_result_metadata(stmt); test_stmt_error(stmt, rs_metadata == NULL); fields = mysql_fetch_fields(rs_metadata); rs_bind = (MYSQL_BIND *) malloc(sizeof (MYSQL_BIND) * num_fields); if (!rs_bind) { printf("Cannot allocate output buffers\n"); exit(1); } memset(rs_bind, 0, sizeof (MYSQL_BIND) * num_fields); /* set up and bind result set output buffers */ for (i = 0; i < num_fields; ++i) { rs_bind[i].buffer_type = fields[i].type; rs_bind[i].is_null = &is_null[i]; switch (fields[i].type) { case MYSQL_TYPE_LONG: rs_bind[i].buffer = (char *) &(int_data[i]); rs_bind[i].buffer_length = sizeof (int_data); break; default: fprintf(stderr, "ERROR: unexpected type: %d.\n", fields[i].type); exit(1); } } status = mysql_stmt_bind_result(stmt, rs_bind); test_stmt_error(stmt, status); /* fetch and display result set rows */ while (1) { status = mysql_stmt_fetch(stmt); if (status == 1 || status == MYSQL_NO_DATA) break; for (i = 0; i < num_fields; ++i) { switch (rs_bind[i].buffer_type) { case MYSQL_TYPE_LONG: if (*rs_bind[i].is_null) printf(" val[%d] = NULL;", i); else printf(" val[%d] = %ld;", i, (long) *((int *) rs_bind[i].buffer)); break; default: printf(" unexpected type (%d)\n", rs_bind[i].buffer_type); } } printf("\n"); } mysql_free_result(rs_metadata); /* free metadata */ free(rs_bind); /* free output buffers */ } else { /* no columns = final status packet */ printf("End of procedure output\n"); } /* more results? -1 = no, >0 = error, 0 = yes (keep looking) */ status = mysql_stmt_next_result(stmt); if (status > 0) test_stmt_error(stmt, status); } while (status == 0); mysql_stmt_close(stmt);
Execution of the procedure should produce the following output:
Number of columns in result: 3 Data: this result set is produced by the procedure val[0] = 10; val[1] = NULL; val[2] = 30; Number of columns in result: 3 Data: this result set is produced by the procedure val[0] = 100; val[1] = 200; val[2] = 300; Number of columns in result: 2 Data: this result set contains OUT/INOUT parameters val[0] = 200; val[1] = 300; End of procedure output
The code uses two utility routines,
test_error()
and
test_stmt_error()
, to check for errors and
terminate after printing diagnostic information if an error
occurred:
static void test_error(MYSQL *mysql, int status) { if (status) { fprintf(stderr, "Error: %s (errno: %d)\n", mysql_error(mysql), mysql_errno(mysql)); exit(1); } } static void test_stmt_error(MYSQL_STMT *stmt, int status) { if (status) { fprintf(stderr, "Error: %s (errno: %d)\n", mysql_stmt_error(stmt), mysql_stmt_errno(stmt)); exit(1); } }
The MySQL PHP API manual is now published in standalone form, not as part of the MySQL Reference Manual. See MySQL and PHP.
The Perl DBI
module provides a generic interface
for database access. You can write a DBI script that works with many
different database engines without change. To use DBI with MySQL,
install the following:
The DBI
module.
The DBD::mysql
module. This is the DataBase
Driver (DBD) module for Perl.
Optionally, the DBD module for any other type of database server you want to access.
Perl DBI is the recommended Perl interface. It replaces an older
interface called mysqlperl
, which should be
considered obsolete.
These sections contain information about using Perl with MySQL and writing MySQL applications in Perl:
For installation instructions for Perl DBI support, see Section 2.13, “Perl Installation Notes”.
For an example of reading options from option files, see Section 5.3.4, “Using Client Programs in a Multiple-Server Environment”.
For secure coding tips, see Section 6.1.1, “Security Guidelines”.
For debugging tips, see Section 24.5.1.4, “Debugging mysqld under gdb”.
For some Perl-specific environment variables, see Section 2.12, “Environment Variables”.
For considerations for running on OS X, see Section 2.4, “Installing MySQL on OS X”.
For ways to quote string literals, see Section 9.1.1, “String Literals”.
DBI information is available at the command line, online, or in printed form:
Once you have the DBI
and
DBD::mysql
modules installed, you can get
information about them at the command line with the
perldoc
command:
shell>perldoc DBI
shell>perldoc DBI::FAQ
shell>perldoc DBD::mysql
You can also use pod2man
,
pod2html
, and so on to translate this
information into other formats.
For online information about Perl DBI, visit the DBI Web site,
http://dbi.perl.org/. That site hosts a general
DBI mailing list. Oracle Corporation hosts a list specifically
about DBD::mysql
; see
Section 1.5.1, “MySQL Mailing Lists”.
For printed information, the official DBI book is Programming the Perl DBI (Alligator Descartes and Tim Bunce, O'Reilly & Associates, 2000). Information about the book is available at the DBI Web site, http://dbi.perl.org/.
For information that focuses specifically on using DBI with MySQL, see MySQL and Perl for the Web (Paul DuBois, New Riders, 2001). This book's Web site is http://www.kitebird.com/mysql-perl/.
MySQLdb
is a third-party driver that provides
MySQL support for Python, compliant with the Python DB API version
2.0. It can be found at
http://sourceforge.net/projects/mysql-python/.
The new MySQL Connector/Python component provides an interface to the same Python API, and is built into the MySQL Server and supported by Oracle. See MySQL Connector/Python Developer Guide for details on the Connector, as well as coding guidelines for Python applications and sample Python code.
Two APIs are available for Ruby programmers developing MySQL applications:
The MySQL/Ruby API is based on the
libmysqlclient
API library. For information
on installing and using the MySQL/Ruby API, see
Section 23.12.1, “The MySQL/Ruby API”.
The Ruby/MySQL API is written to use the native MySQL network protocol (a native driver). For information on installing and using the Ruby/MySQL API, see Section 23.12.2, “The Ruby/MySQL API”.
For background and syntax information about the Ruby language, see Ruby Programming Language.
The MySQL/Ruby module provides access to MySQL databases using
Ruby through libmysqlclient
.
For information on installing the module, and the functions exposed, see MySQL/Ruby.
The Ruby/MySQL module provides access to MySQL databases using Ruby through a native driver interface using the MySQL network protocol.
For information on installing the module, and the functions exposed, see Ruby/MySQL.
MySQLtcl
is a simple API for accessing a MySQL
database server from the
Tcl programming
language. It can be found at
http://www.xdobry.de/mysqltcl/.
Eiffel MySQL is an interface to the MySQL database server using the Eiffel programming language, written by Michael Ravits. It can be found at http://efsa.sourceforge.net/archive/ravits/mysql.htm.