Oracle® Database Advanced Application Developer's Guide 11g Release 1 (11.1) Part Number B28424-02 |
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This chapter explains how you can develop database applications that call external procedures written in other programming languages.
Topics:
Oracle Database lets you work in different languages:
PL/SQL, as described in the Oracle Database PL/SQL Language Reference
C, through the Oracle Call Interface (OCI), as described in the Oracle Call Interface Programmer's Guide
C or C++, through the Pro*C/C++ precompiler, as described in the Pro*C/C++ Programmer's Guide
COBOL, through the Pro*COBOL precompiler, as described in the Pro*COBOL Programmer's Guide
.NET , through Oracle Data Provider for .NET (ODP.NET), as described in Oracle Data Provider for .NET Developer's Guide
Visual Basic, through Oracle Objects for OLE (OO4O)and Oracle Provider for OLE DB, as described in Oracle Objects for OLE Developer's Guide and Oracle Provider for OLE DB Developer's Guide.
Java, through the JDBC Application Programmers Interface (API). See Oracle Database Java Developer's Guide.
How can you choose between these different implementation possibilities? Each of these languages offers different advantages: ease of use, the availability of programmers with specific expertise, the need for portability, and the existence of legacy code are powerful determinants.
The choice might narrow depending on how your application needs to work with Oracle Database:
PL/SQL is a powerful development tool, specialized for SQL transaction processing.
Some computation-intensive tasks are executed most efficiently in a lower level language, such as C.
The need for portability, together with the need for security, might influence you to select Java.
Most significantly, from the point of view of performance, only PL/SQL and Java methods run within the address space of the server. C/C++ methods are dispatched as external procedures, and run on the server system but outside the address space of the database server. Pro*COBOL and Pro*C/C++ are precompilers, and Visual Basic accesses Oracle Database through the OCI, which is implemented in C.
Taking all these factors into account suggests that there might be a number of situations in which you might need to implement your application in more than one language. For example, the introduction of Java running within the address space of the server suggest that you might want to import existing Java applications into the database, and then leverage this technology by calling Java functions from PL/SQL and SQL.
PL/SQL external procedures enable you to write C procedure calls as PL/SQL bodies. These C procedures are callable directly from PL/SQL, and from SQL through PL/SQL procedure calls. The database provides a special-purpose interface, the call specification, that lets you call external procedures from other languages. While this service is designed for intercommunication between SQL, PL/SQL, C, and Java, it is accessible from any base language that can call these languages. For example, your procedure can be written in a language other than Java or C and still be usable by SQL or PL/SQL, as long as your procedure is callable by C. Therefore, if you have a candidate C++ procedure, use a C++ extern
"C"
statement in that procedure to make it callable by C.
This means that the strengths and capabilities of different languages are available to you, regardless of your programmatic environment. You are not restricted to one language with its inherent limitations. External procedures promote re-usability and modularity because you can deploy specific languages for specific purposes.
An external procedure is a procedure stored in a dynamic link library (DLL), or libunit in the case of a Java class method. You register the procedure with the base language, and then call it to perform special-purpose processing.
For example, when you work in PL/SQL, the language loads the library dynamically at run time, and then calls the procedure as if it were a PL/SQL procedure. These procedures participate fully in the current transaction and can call back to the database to perform SQL operations.
The procedures are loaded only when necessary, so memory is conserved. Because the decoupling of the call specification from its implementation body means that the procedures can be enhanced without affecting the calling programs.
External procedures let you:
Isolate execution of client applications and processes from the database instance to ensure that any problems on the client side do not adversely impact the database.
Move computation-bound programs from client to server where they execute faster (because they avoid the round-trips of network communication)
Interface the database server with external systems and data sources
Extend the functionality of the database server itself
You publish external procedures through call specifications, which provide a superset of the AS
EXTERNAL
function through the AS
LANGUAGE
clause. AS
LANGUAGE
call specifications allow the publishing of external C procedures, but also Java class methods.
Note:
To support legacy applications, call specifications also enable you to publish with theAS
EXTERNAL
clause. For new application development, however, using the AS
LANGUAGE
clause is recommended.In general, call specifications enable:
Dispatching the appropriate C or Java target procedure
Datatype conversions
Parameter mode mappings
Automatic memory allocation and cleanup
Purity constraints to be specified, where necessary, for packaged functions called from SQL.
Calling Java methods or C procedures from database triggers
Location flexibility: you can put AS
LANGUAGE
call specifications in package or type specifications, or package (or type) bodies to optimize performance and hide implementation details
To use an already-existing program as an external procedure, load, publish, and then call it.
To make your external C procedures or Java methods available to PL/SQL, you must first load them. The manner of doing this depends upon whether the procedure is written in C or Java.
Topics:
One way to load Java programs is to use the CREATE
JAVA
statement, which you can execute interactively from SQL*Plus. When implicitly called by the CREATE
JAVA
statement, the Java Virtual Machine (JVM)] library manager loads Java binaries (.class
files) and resources from local BFILE
s or LOB
columns into RDBMS libunits.
Suppose a compiled Java class is stored in the operating system file /home
/java
/bin
/Agent
.class
.
Create a class libunit
in schema username
from file Agent
.class
as follows:
Connect to the database as SYSTEM
and grant the user username
the CREATE
ANY
DIRECTORY
privilege.
Connect to the database as username
and create a directory object on the server's file system:
CREATE DIRECTORY Bfile_dir AS '/home/java/bin';
The name of the directory object is an alias for the directory path leading to Agent
.class
.
Create the class libunit
:
CREATE JAVA CLASS USING BFILE (Bfile_dir, 'Agent.class');
The name of the libunit
is derived from the name of the class.
Alternatively, you can use the command-line utility LoadJava
. This uploads Java binaries and resources into a system-generated database table, then uses the CREATE
JAVA
statement to load the Java files into RDBMS libunits. You can upload Java files from file systems, Java IDEs, intranets, or the Internet.
Note:
You can load external C procedures only on platforms that support either DLLs or dynamically loadable shared libraries (such as Solaris .so
libraries).When an application calls an external C procedure, Oracle Database or Oracle Listener starts the external procedure agent, extproc
. Using the network connection established by Oracle Database or Oracle Listener, the application passes the following information to extproc
:
Name of DLL or shared library
Name of external procedure
Any parameters for the external procedure
Then extproc
loads the DLL or the shared library, runs the external procedure, and passes any values that the external procedure returns back to the application. The application and extproc
must reside on the same computer.
extproc
can call procedures in any library that complies with the calling standard used. For more information about the calling standard, see "CALLING STANDARD".
Note:
The default configuration for external procedures no longer requires a network listener to work with Oracle Database andextproc
. Oracle Database now spawns extproc
directly, eliminating the risk that Oracle Listener might spawn extproc
unexpectedly. This default configuration is recommended for maximum security.
You must change this default configuration, so that Oracle Listener spawns extproc
, if you use any of the following:
A multithreaded extproc
agent
Oracle Database in MTS mode on Windows
An AGENT
clause in the LIBRARY
specification or an AGENT
IN
clause in the PROCEDURE
specification that redirects external procedures to a different extproc
agent
Changing the default configuration requires additional network configuration steps.
To configure your database to use external procedures that are written in C, or that can be called from C applications, you or your database administrator must take the following steps:
Define the C procedures using one of the following prototypes:
Kernighan & Ritchie style prototypes; for example:
void C_findRoot(x) float x; ...
ISO/ANSI prototypes other than numeric datatypes that are less than full width (such as float
, short
, char
); for example:
void C_findRoot(double x) ...
Other datatypes that do not change size under default argument promotions.
The following example changes size under default argument promotions:
void C_findRoot(float x) ...
When you use the default configuration for external procedures, Oracle Database spawns extproc
directly. You do not need to make configuration changes for listener
.ora
and tnsnames
.ora
. Define the environment variables to be used by external procedures in the file extproc
.ora
(located at $ORACLE_HOME/hs/admin
on UNIX operating sytems and at ORACLE_HOME\hs\admin
on Windows), using the following syntax:
SET name=value (environment_variable_name value)
Set the EXTPROC_DLLS
environment variable, which restricts the DLLs that extproc
can load, to one of the following values:
NULL
; for example:
SET EXTPROC_DLLS=
This setting, the default, allows extproc
to load only the DLLs that are in directory $ORACLE_HOME
/bin
or $ORACLE_HOME
/lib
.
ONLY
followed by a colon-separated list of DLLs; for example:
SET EXTPROC_DLLS=ONLY:DLL1:DLL2
This setting allows extproc
to load only the DLLs named DLL1 and DLL2. , This setting provides maximum security.
A colon-separated list of DLLs; for example:
SET EXTPROC_DLLS=DLL1:DLL2
This setting allows extproc
to load the DLLs named DLL1 and DLL2 and the DLLs that are in directory $ORACLE_HOME
/bin
or $ORACLE_HOME
/lib
.
ANY
; for example:
SET EXTPROC_DLLS=ANY
This setting allows extproc
to load any DLL.
To change the default configuration for external procedures and have your extproc
agent spawned by Oracle Listener, configure your database to use external procedures that are written in C, or can be called from C applications, as follows:
Set configuration parameters for the agent, named extproc
by default, in the configuration files tnsnames
.ora
and listener
.ora
. This establishes the connection for the external procedure agent, extproc
, when the database is started.
Start a listener process exclusively for external procedures.
The Listener sets a few required environment variables (such as ORACLE_HOME
, ORACLE_SID
, and LD_LIBRARY_PATH
) for extproc
. It can also define specific environment variables in the ENVS
section of its listener
.ora
entry, and these variables are passed to the agent process. Otherwise, it provides the agent with a "clean" environment. The environment variables set for the agent are independent of those set for the client and server. Therefore, external procedures, which run in the agent process, cannot read environment variables set for the client or server processes.
Note:
It is possible for you to set and read environment variables themselves by using the standard C proceduressetenv
and getenv
, respectively. Environment variables, set this way, are specific to the agent process, which means that they can be read by all functions executed in that process, but not by any other process running on the same host.Determine whether the agent for your external procedure will run in dedicated mode (the default) or multithreaded mode. In dedicated mode, one "dedicated" agent is launched for each session. In multithreaded mode, a single multithreaded extproc
agent is launched. The multithreaded extproc
agent handles calls using different threads for different users. In a configuration where many users can call the external procedures, using a multithreaded extproc
agent is recommended to conserve system resources.
If the agent will run in dedicated mode, additional configuration of the agent process is not necessary.
If the agent will run in multithreaded mode, your database administrator must configure the database system to start the agent in multithreaded mode (as a multithreaded extproc
agent). To do this, use the agent control utility, agtctl
. For example, start extproc
using the following command:
agtctl startup extproc agent_sid
where agent_sid
is the system identifier that this extproc
agent will service. An entry for this system identifier is typically added as an entry in the file tnsnames
.ora
. For more information about using agtctl
for extproc
administration, see "Administering the Multithreaded extproc Agent".
Note:
If you use a multithreaded extproc
agent, the library you call must be thread safe—to avoid errors such as a corrupt call stack.
The database server, the agent process, and the listener process that spawns the agent process must all reside on the same host.
By default, the agent process runs on the same database instance as your main application. In situations where reliability is critical, you might want to run the agent process for the external procedure on a separate database instance (still on the same host), so that any problems in the agent do not affect the primary database server. To do so, specify the separate database instance using a database link.
Figure A-1 illustrates the architecture of the multithreaded extproc
agent.
In this context, a DLL is any dynamically loadable operating-system file that stores external procedures.
For security reasons, your DBA controls access to the DLL. Using the CREATE LIBRARY statement, the DBA creates a schema object called an alias library, which represents the DLL. Then, if you are an authorized user, the DBA grants you EXECUTE
privileges on the alias library. Alternatively, the DBA might grant you CREATE
ANY
LIBRARY
privileges, in which case you can create your own alias libraries using the following syntax:
CREATE LIBRARY [schema_name.]library_name {IS | AS} 'file_path' [AGENT 'agent_link'];
It is recommended that you specify the full path to the DLL, rather than just the DLL name. In the following example, you create alias library c_utils
, which represents DLL utils
.so
:
CREATE LIBRARY C_utils AS '/DLLs/utils.so';
To allow flexibility in specifying the DLLs, you can specify the root part of the path as an environment variable using the notation ${
VAR_NAME
}
, and set up that variable in the ENVS
section of the listener
.ora
entry.
In the following example, the agent specified by the name agent_link
is used to run any external procedure in the library C_Utils
. The environment variable EP_LIB_HOME
is expanded by the agent to the appropriate path for that instance, such as /usr/bin/dll
. Variable EP_LIB_HOME
must be set in the file listener
.ora
, for the agent to be able to access it.
create or replace database link agent_link using 'agent_tns_alias'; create or replace library C_utils is '${EP_LIB_HOME}/utils.so' agent 'agent_link';
For security reasons, extproc
, by default, loads only DLLs that are in directory $ORACLE_HOME/bin
or $ORACLE_HOME/lib
. Also, only local sessions—that is, Oracle Database client processes that are running on the same system—are allowed to connect to extproc
.
To load DLLs from other directories, set the environment variable EXTPROC_DLLS
. The value for this environment variable is a colon-separated list of DLL names qualified with the complete path. For example:
EXTPROC_DLLS=/private1/home/scott/dll/myDll.so:/private1/home/scott/dll/newDll.so
While you can set up environment variables for extproc
through the ENVS
parameter in the file listener
.ora
, you can also set up environment varilables in the extproc
initialization file extproc
.ora
in directory $ORACLE_HOME/hs/admin
. When both extproc
.ora
and ENVS
parameter in listener
.ora
are used, the environment variables defined in extproc
.ora
take precedence. See the Oracle Net manual for more information about the EXTPROC
feature.
Note:
On a Windows system, specify the path using a drive letter and backslash characters (\
) in the path.
This technique does not apply to VMS systems, where the ENVS
section of listener.ora is not supported.
You find or write a new external C procedure, then add it to the DLL. When the procedure is in the DLL, you publish it using the call specification mechanism described in the following section.
Oracle Database can only use external procedures that are published through a call specification, which maps names, parameter types, and return types for your Java class method or C external procedure to their SQL counterparts. It is written like any other PL/SQL stored procedure except that, in its body, instead of declarations and a BEGIN-END
block, you code the AS
LANGUAGE
clause.
The AS
LANGUAGE
clause specifies:
Which language the procedure is written in.
For a Java method:
The signature of the Java method.
For a C procedure:
The alias library corresponding to the DLL for a C procedure.
The name of the C procedure in a DLL.
Various options for specifying how parameters are passed.
Which parameter (if any) holds the name of the external procedure agent, extproc
, for running the procedure on a different system.
You begin the declaration using the normal CREATE
OR
REPLACE
syntax for a procedure, function, package specification, package body, type specification, or type body.
The call specification follows the name and parameter declarations. Its syntax is:
{IS | AS} LANGUAGE {C | JAVA}
Note:
Oracle Database uses a PL/SQL variant of the ANSI SQL92 External Procedure, which replaces the ANSI clauseAS
EXTERNAL
with this call specification syntax.This is then followed by either:
NAME java_string_literal_name
Where java_string_literal_name is the signature of your Java method, or by:
LIBRARY library_name [NAME c_string_literal_name] [WITH CONTEXT] [PARAMETERS (external_parameter[, external_parameter]...)];
Where library_name
is the name of your alias library, c_string_literal_name
is the name of your external C procedure, and external_parameter
stands for:
{ CONTEXT | SELF [{TDO | property}] | {parameter_name | RETURN} [property] [BY REFERENCE] [external_datatype]}
property
stands for:
{INDICATOR [{STRUCT | TDO}] | LENGTH | DURATION | MAXLEN | CHARSETID | CHARSETFORM}
Note:
Unlike Java, C does not understand SQL types; therefore, the syntax is more intricateTopics:
The AS
LANGUAGE
clause is the interface between PL/SQL and a Java class method.
The following subclauses tell PL/SQL where to locate the external C procedure, how to call it, and what to pass to it. Only the LIBRARY
subclause is required.
Topics:
Specifies a local alias library. (You cannot use a database link to specify a remote library.) The library name is a PL/SQL identifier. Therefore, if you enclose the name in double quotes, then it becomes case sensitive. (By default, the name is stored in upper case.) You must have EXECUTE
privileges on the alias library.
Specifies the external C procedure to be called. If you enclose the procedure name in double quotes, then it becomes case sensitive. (By default, the name is stored in upper case.) If you omit this subclause, then the procedure name defaults to the upper-case name of the PL/SQL procedure.
Note:
The termsLANGUAGE
and CALLING
STANDARD
apply only to the superseded AS
EXTERNAL
clause.Specifies the third-generation language in which the external procedure was written. If you omit this subclause, then the language name defaults to C.
Specifies the calling standard under which the external procedure was compiled. The supported calling standard is C. If you omit this subclause, then the calling standard defaults to C.
Specifies that a context pointer is passed to the external procedure. The context data structure is opaque to the external procedure but is available to service procedures called by the external procedure.
Specifies the positions and datatypes of parameters passed to the external procedure. It can also specify parameter properties, such as current length and maximum length, and the preferred parameter passing method (by value or by reference).
Specifies which parameter holds the name of the agent process that runs this procedure. This is intended for situations where the external procedure agent, extproc
, runs using multiple agent processes, to ensure robustness if the agent process of one external procedure fails. You can pass the name of the agent process (corresponding to the name of a database link), and if tnsnames
.ora
and listener
.ora
are set up properly across both instances, the external procedure is called on the other instance. Both instances must be on the same host.
This is similar to the AGENT
clause of the CREATE
LIBRARY
statement; specifying the value at run time through AGENT
IN
allows greater flexibility.
When the agent name is specified this way, it overrides any agent name declared in the alias library. If no agent name is specified, the default is the extproc
agent on the same instance as the calling program.
Java classes and their methods are stored in RDBMS libunits in which you can load Java sources, binaries and resources using the LOADJAVA
utility or the CREATEJAVA
SQL statements. Libunits can be considered analogous to DLLs written, for example, in C—although they map one-to-one with Java classes, whereas DLLs can contain more than one procedure.
The NAME
-clause string uniquely identifies the Java method. The PL/SQL function or procedure and Java must correspond with regard to parameters. If the Java method takes no parameters, then you must code an empty parameter list for it.
When you load Java classes into the RDBMS, they are not published to SQL automatically. This is because the methods of many Java classes are called only from other Java classes, or take parameters for which there is no appropriate SQL type.
Suppose you want to publish the following Java method named J_calcFactorial
, which returns the factorial of its argument:
package myRoutines.math; public class Factorial { public static int J_calcFactorial (int n) { if (n == 1) return 1; else return n * J_calcFactorial(n - 1); } }
The following call specification publishes Java method J_calcFactorial
as PL/SQL stored function plsToJavaFac_func
, using SQL*Plus:
CREATE OR REPLACE FUNCTION Plstojavafac_func (N NUMBER) RETURN NUMBER AS LANGUAGE JAVA NAME 'myRoutines.math.Factorial.J_calcFactorial(int) return int';
In the following example, you write a PL/SQL standalone function named plsCallsCdivisor_func
that publishes C function Cdivisor_func
as an external function:
CREATE OR REPLACE FUNCTION Plscallscdivisor_func ( /* Find greatest common divisor of x and y: */ x PLS_INTEGER, y PLS_INTEGER) RETURN PLS_INTEGER AS LANGUAGE C LIBRARY C_utils NAME "Cdivisor_func"; /* Quotation marks preserve case. */
For both Java class methods and external C procedures, call specifications can be specified in any of the following locations:
Standalone PL/SQL procedures
PL/SQL Package Specifications
PL/SQL Package Bodies
Object Type Specifications
Object Type Bodies
Note:
Oracle Database version 8.0,AS
EXTERNAL
did not allow call specifications in package or type bodies.Note:
In the following examples, theAUTHID
and SQL_NAME_RESOLVE
clauses might or might not be required to fully stipulate a call specification.See Also:
Oracle Database PL/SQL Language Reference for more information about calling external procedures from PL/SQL
Oracle Database SQL Language Reference for more information about the SQL CALL
statement
Examples:
CREATE OR REPLACE PACKAGE Demo_pack AUTHID DEFINER AS PROCEDURE plsToC_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS LANGUAGE C NAME "C_demoExternal" LIBRARY SomeLib WITH CONTEXT PARAMETERS(CONTEXT, x INT, y STRING, z OCIDATE); END;
CREATE OR REPLACE PACKAGE Demo_pack AUTHID CURRENT_USER AS PROCEDURE plsToC_demoExternal_proc(x PLS_INTEGER, y VARCHAR2, z DATE); END; CREATE OR REPLACE PACKAGE BODY Demo_pack SQL_NAME_RESOLVE CURRENT_USER AS PROCEDURE plsToC_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS LANGUAGE JAVA NAME 'pkg1.class4.methodProc1(int,java.lang.String,java.sql.Date)'; END;
Note:
For examples in this topic to work, you must set up the following data structure (which requires that you have the privilegeCREATE
ANY
LIBRARY
):
CREATE OR REPLACE LIBRARY SOMELIB AS '/tmp/lib.so';
CREATE OR REPLACE TYPE Demo_typ AUTHID DEFINER AS OBJECT (Attribute1 VARCHAR2(2000), SomeLib varchar2(20), MEMBER PROCEDURE plsToC_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS LANGUAGE C NAME "C_demoExternal" LIBRARY SomeLib WITH CONTEXT -- PARAMETERS(CONTEXT, x INT, y STRING, z OCIDATE) PARAMETERS(CONTEXT, x INT, y STRING, z OCIDATE, SELF) );
CREATE OR REPLACE TYPE Demo_typ AUTHID CURRENT_USER AS OBJECT (attribute1 NUMBER, MEMBER PROCEDURE plsToJ_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE) ); CREATE OR REPLACE TYPE BODY Demo_typ AS MEMBER PROCEDURE plsToJ_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS LANGUAGE JAVA NAME 'pkg1.class4.J_demoExternal(int,java.lang.String,java.sql.Date)'; END;
Here is an example of a publishing a Java class method in a standalone PL/SQL procedure.
CREATE OR REPLACE PROCEDURE plsToJ_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AUTHID CURRENT_USER AS LANGUAGE JAVA NAME 'pkg1.class4.methodProc1(int,java.lang.String,java.sql.Date)';
Here is an example of AS
EXTERNAL
publishing a C procedure in a standalone PL/SQL program, in which the AUTHID
clause is optional. This maintains compatibility with the external procedures of Oracle Database version 8.0.
CREATE OR REPLACE PROCEDURE plsToC_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS EXTERNAL LANGUAGE C NAME "C_demoExternal" LIBRARY SomeLib WITH CONTEXT PARAMETERS(CONTEXT, x INT, y STRING, z OCIDATE);
CREATE OR REPLACE PACKAGE Demo_pack AUTHID DEFINER AS PROCEDURE plsToC_InBodyOld_proc (x PLS_INTEGER, y VARCHAR2, z DATE); PROCEDURE plsToC_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE); PROCEDURE plsToC_InBody_proc (x PLS_INTEGER, y VARCHAR2, z DATE); PROCEDURE plsToJ_InBody_proc (x PLS_INTEGER, y VARCHAR2, z DATE); PROCEDURE plsToJ_InSpec_proc (x PLS_INTEGER, y VARCHAR2, z DATE) IS LANGUAGE JAVA NAME 'pkg1.class4.J_InSpec_meth(int,java.lang.String,java.sql.Date)'; PROCEDURE C_InSpec_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS LANGUAGE C NAME "C_demoExternal" LIBRARY SomeLib WITH CONTEXT PARAMETERS(CONTEXT, x INT, y STRING, z OCIDATE); END; CREATE OR REPLACE PACKAGE BODY Demo_pack AS PROCEDURE plsToC_InBodyOld_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS EXTERNAL LANGUAGE C NAME "C_InBodyOld" LIBRARY SomeLib WITH CONTEXT PARAMETERS(CONTEXT, x INT, y STRING, z OCIDATE); PROCEDURE plsToC_demoExternal_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS LANGUAGE C NAME "C_demoExternal" LIBRARY SomeLib WITH CONTEXT PARAMETERS(CONTEXT, x INT, y STRING, z OCIDATE); PROCEDURE plsToC_InBody_proc (x PLS_INTEGER, y VARCHAR2, z DATE) AS LANGUAGE C NAME "C_InBody" LIBRARY SomeLib WITH CONTEXT PARAMETERS(CONTEXT, x INT, y STRING, z OCIDATE); PROCEDURE plsToJ_InBody_proc (x PLS_INTEGER, y VARCHAR2, z DATE) IS LANGUAGE JAVA NAME 'pkg1.class4.J_InBody_meth(int,java.lang.String,java.sql.Date)'; END;
Call specifications allows a mapping between PL/SQL and C datatypes. See "Specifying Datatypes" for datatype mappings.
Passing parameters to an external C procedure is complicated by several circumstances:
The available set of PL/SQL datatypes does not correspond one-to-one with the set of C datatypes.
Unlike C, PL/SQL includes the RDBMS concept of nullity. Therefore, PL/SQL parameters can be NULL
, whereas C parameters cannot.
The external procedure might need the current length or maximum length of CHAR
, LONG
RAW
, RAW
, and VARCHAR2
parameters.
The external procedure might need character set information about CHAR
, VARCHAR2
, and CLOB
parameters.
PL/SQL might need the current length, maximum length, or null status of values returned by the external procedure.
In the following sections, you learn how to specify a parameter list that deals with these circumstances.
Note:
The maximum number of parameters that you can pass to a C external procedure is 128. However, if you pass float or double parameters by value, then the maximum is less than 128. How much less depends on the number of such parameters and your operating system. To get a rough estimate, count each float or double passed by value as two parameters.Topics:
Do not pass parameters to an external procedure directly. Instead, pass them to the PL/SQL procedure that published the external procedure, specifying PL/SQL datatypes for the parameters. PL/SQL datatypes map to default external datatypes, as shown in Table 14-1.
Note:
The PL/SQL datatypesBINARY_INTEGER
and PLS_INTEGER
are identical. For simplicity, this document uses "PLS_INTEGER
" to mean both BINARY_INTEGER
and PLS_INTEGER
.Table 14-1 Parameter Datatype Mappings
PL/SQL Datatype | Supported External Types | Default External Type |
---|---|---|
BINARY_INTEGER BOOLEAN PLS_INTEGER |
[UNSIGNED] CHAR [UNSIGNED] SHORT [UNSIGNED] INT [UNSIGNED] LONG SB1, SB2, SB4 UB1, UB2, UB4 SIZE_T |
INT |
NATURALFoot 1 NATURALNFootref 1 POSITIVEFootref 1 POSITIVENFootref 1 SIGNTYPEFootref 1 |
[UNSIGNED] CHAR [UNSIGNED] SHORT [UNSIGNED] INT [UNSIGNED] LONG SB1, SB2, SB4 UB1, UB2, UB4 SIZE_T |
UNSIGNED INT |
FLOAT REAL |
FLOAT |
FLOAT |
DOUBLE PRECISION |
DOUBLE |
DOUBLE |
CHAR CHARACTER LONG NCHAR NVARCHAR2 ROWID VARCHAR VARCHAR2 |
STRING OCISTRING |
STRING |
LONG RAW RAW |
RAW OCIRAW |
RAW |
BFILE BLOB CLOB NCLOB |
OCILOBLOCATOR |
OCILOBLOCATOR |
NUMBER DECFootref 1 DECIMALFootref 1 INTFootref 1 INTEGERFootref 1 NUMERICFootref 1 SMALLINTFootref 1 |
OCINUMBER |
OCINUMBER |
DATE |
OCIDATE |
OCIDATE |
TIMESTAMP TIMESTAMP WITH TIME ZONE TIMESTAMP WITH LOCAL TIME ZONE |
OCIDateTime |
OCIDateTime |
INTERVAL DAY TO SECOND INTERVAL YEAR TO MONTH |
OCIInterval |
OCIInterval |
composite object types: ADTs |
dvoid |
dvoid |
composite object types: collections (varrays, nested tables) |
OCICOLL |
OCICOLL |
Footnote 1 This PL/SQL type compiles only if you use AS
EXTERNAL
in your callspec.
Each external datatype maps to a C datatype, and the datatype conversions are performed implicitly. To avoid errors when declaring C prototype parameters, see Table 14-2, which shows the C datatype to specify for a given external datatype and PL/SQL parameter mode. For example, if the external datatype of an OUT
parameter is STRING
, then specify the datatype char * in your C prototype.
Table 14-2 External Datatype Mappings
External Datatype Corresponding to PL/SL Type | If Mode is IN or RETURN, Specify in C Prototype... | If Mode is IN by Reference or RETURN by Reference, Specify in C Prototype... | If Mode is IN OUT or OUT, Specify in C Prototype... |
---|---|---|---|
CHAR |
char |
char * |
char * |
UNSIGNED CHAR |
unsigned char |
unsigned char * |
unsigned char * |
SHORT |
short |
short * |
short * |
UNSIGNED SHORT |
unsigned short |
unsigned short * |
unsigned short * |
INT |
int |
int * |
int * |
UNSIGNED INT |
unsigned int |
unsigned int * |
unsigned int * |
LONG |
long |
long * |
long * |
UNSIGNED LONG |
unsigned long |
unsigned long * |
unsigned long * |
CHAR |
char |
char * |
char * |
UNSIGNED CHAR |
unsigned char |
unsigned char * |
unsigned char * |
SHORT |
short |
short * |
short * |
UNSIGNED SHORT |
unsigned short |
unsigned short * |
unsigned short * |
INT |
int |
int * |
int * |
UNSIGNED INT |
unsigned int |
unsigned int * |
unsigned int * |
LONG |
long |
long * |
long * |
UNSIGNED LONG |
unsigned long |
unsigned long * |
unsigned long * |
SIZE_T |
size_t |
size_t * |
size_t * |
SB1 |
sb1 |
sb1 * |
sb1 * |
UB1 |
ub1 |
ub1 * |
ub1 * |
SB2 |
sb2 |
sb2 * |
sb2 * |
UB2 |
ub2 |
ub2 * |
ub2 * |
SB4 |
sb4 |
sb4 * |
sb4 * |
UB4 |
ub4 |
ub4 * |
ub4 * |
FLOAT |
float |
float * |
float * |
DOUBLE |
double |
double * |
double * |
STRING |
char * |
char * |
char * |
RAW |
unsigned char * |
unsigned char * |
unsigned char * |
OCILOBLOCATOR |
OCILobLocator * |
OCILobLocator ** |
OCILobLocator ** |
OCINUMBER |
OCINumber * |
OCINumber * |
OCINumber * |
OCISTRING |
OCIString * |
OCIString * |
OCIString * |
OCIRAW |
OCIRaw * |
OCIRaw * |
OCIRaw * |
OCIDATE |
OCIDate * |
OCIDate * |
OCIDate * |
OCICOLL |
OCIColl * or OCIArray * or OCITable * |
OCIColl ** or OCIArray ** or OCITable ** |
OCIColl ** or OCIArray ** or OCITable ** |
OCITYPE |
OCIType * |
OCIType * |
OCIType * |
TDO |
OCIType * |
OCIType * |
OCIType * |
ADT (final types) |
dvoid* |
dvoid* |
dvoid* |
ADT (nonfinal types) |
dvoid* |
dvoid* |
dvoid** |
Composite object types are not self describing. Their description is stored in a Type Descriptor Object (TDO). Objects and indicator structs for objects have no predefined OCI datatype, but must use the datatypes generated by Oracle Database's Object Type Translator (OTT). The optional TDO argument for INDICATOR
, and for composite objects, in general, has the C datatype, OCIType *.
OCICOLL
for REF
and collection arguments is optional and only exists for the sake of completeness. You cannot map REF
s or collections onto any other datatype and vice versa.
If you specify BY
VALUE
, then scalar IN
and RETURN
arguments are passed by value (which is also the default). Alternatively, you might have them passed by reference by specifying BY
REFERENCE
.
By default, or if you specify BY
REFERENCE
, then scalar IN
OUT
, and OUT
arguments are passed by reference. Specifying BY
VALUE
for IN
OUT
, and OUT
arguments is not supported for C. The usefulness of the BY
REFERENCE
/VALUE
clause is restricted to external datatypes that are, by default, passed by value. This is true for IN
, and RETURN
arguments of the following external types:
[UNSIGNED] CHAR [UNSIGNED] SHORT [UNSIGNED] INT [UNSIGNED] LONG SIZE_T SB1 SB2 SB4 UB1 UB2 UB4 FLOAT DOUBLE
All IN
and RETURN
arguments of external types not on this list, all IN
OUT
arguments, and all OUT
arguments are passed by reference.
Generally, the PL/SQL procedure that publishes an external procedure declares a list of formal parameters, as the following example shows:
Note:
You might need to set up the following data structures for examples in this topic to work:CREATE LIBRARY MathLib AS '/tmp/math.so';
CREATE OR REPLACE FUNCTION Interp_func (
/* Find the value of y at x degrees using Lagrange interpolation: */
x IN FLOAT,
y IN FLOAT)
RETURN FLOAT AS
LANGUAGE C
NAME "Interp_func"
LIBRARY MathLib;
Each formal parameter declaration specifies a name, parameter mode, and PL/SQL datatype (which maps to the default external datatype). That might be all the information the external procedure needs. If not, then you can provide more information using the PARAMETERS
clause, which lets you specify the following:
Nondefault external datatypes
The current or maximum length of a parameter
NULL
/NOT
NULL
indicators for parameters
Character set IDs and forms
The position of parameters in the list
How IN
parameters are passed (by value or by reference)
If you decide to use the PARAMETERS
clause, keep in mind:
For every formal parameter, there must be a corresponding parameter in the PARAMETERS
clause.
If you include the WITH
CONTEXT
clause, then you must specify the parameter CONTEXT
, which shows the position of the context pointer in the parameter list.
If the external procedure is a function, then you might specify the RETURN
parameter, but it must be in the last position. If RETURN
is not specified, the default external type is used.
In some cases, you can use the PARAMETERS
clause to override the default datatype mappings. For example, you can remap the PL/SQL datatype BOOLEAN
from external datatype INT
to external datatype CHAR
.
You can also use the PARAMETERS
clause to pass more information about PL/SQL formal parameters and function results to an external procedure. Do this by specifying one or more of the following properties:
INDICATOR [{STRUCT | TDO}] LENGTH DURATION MAXLEN CHARSETID CHARSETFORM SELF
Table 14-3 shows the allowed and the default external datatypes, PL/SQL datatypes, and PL/SQL parameter modes allowed for a given property. Notice that MAXLEN
(used to specify data returned from C back to PL/SQL) cannot be applied to an IN
parameter.
Table 14-3 Properties and Datatypes
Property | Allowed External Types (C) | Default External Type (C) | Allowed PL/SQL Types | Allowed PL/SQL Modes | Default PL/SQL Passing Method |
---|---|---|---|---|---|
INDICATOR |
SHORT |
SHORT |
all scalars |
IN IN OUT OUT RETURN |
BY VALUE BY REFERENCE BY REFERENCE BY REFERENCE |
LENGTH |
[UNSIGNED] SHORT [UNSIGNED] INT [UNSIGNED] LONG |
INT |
CHAR LONG RAW RAW VARCHAR2 |
IN IN OUT OUT RETURN |
BY VALUE BY REFERENCE BY REFERENCE BY REFERENCE |
MAXLEN |
[UNSIGNED] SHORT [UNSIGNED] INT [UNSIGNED] LONG |
INT |
CHAR LONG RAW RAW VARCHAR2 |
IN OUT OUT RETURN |
BY REFERENCE BY REFERENCE BY REFERENCE |
CHARSETID CHARSETFORM |
UNSIGNED SHORT UNSIGNED INT UNSIGNED LONG |
UNSIGNED INT |
CHAR CLOB VARCHAR2 |
IN IN OUT OUT RETURN |
BY VALUE BY REFERENCE BY REFERENCE BY REFERENCE |
In the following example, the PARAMETERS
clause specifies properties for the PL/SQL formal parameters and function result:
CREATE OR REPLACE FUNCTION plsToCparse_func ( x IN PLS_INTEGER, Y IN OUT CHAR) RETURN CHAR AS LANGUAGE C LIBRARY c_utils NAME "C_parse" PARAMETERS ( x, -- stores value of x x INDICATOR, -- stores null status of x y, -- stores value of y y LENGTH, -- stores current length of y y MAXLEN, -- stores maximum length of y RETURN INDICATOR, RETURN);
With this PARAMETERS
clause, the C prototype becomes:
char *C_parse( int x, short x_ind, char *y, int *y_len, int *y_maxlen, short *retind );
A K&R prototype is needed because the indicator variable x_ind
must be of datatype short
and short
must not be used in ISO/ANSI prototypes.
The additional parameters in the C prototype correspond to the INDICATOR
(for x
), LENGTH
(of y
), and MAXLEN
(of y
), as well as the INDICATOR
for the function result in the PARAMETERS
clause. The parameter RETURN
corresponds to the C function identifier, which stores the result value.
Topics:
An INDICATOR
is a parameter whose value indicates whether or not another parameter is NULL
. PL/SQL does not need indicators, because the RDBMS concept of nullity is built into the language. However, an external procedure might need to know if a parameter or function result is NULL
. Also, an external procedure might need to signal the server that a returned value is actually a NULL
, and must be treated accordingly.
In such cases, you can use the property INDICATOR
to associate an indicator with a formal parameter. If the PL/SQL procedure is a function, then you can also associate an indicator with the function result, as shown earlier.
To check the value of an indicator, you can use the constants OCI_IND_NULL
and OCI_IND_NOTNULL
. If the indicator equals OCI_IND_NULL
, then the associated parameter or function result is NULL
. If the indicator equals OCI_IND_NOTNULL
, then the parameter or function result is not NULL
.
For IN
parameters, which are inherently read-only, INDICATOR
is passed by value (unless you specify BY
REFERENCE
) and is read-only (even if you specify BY
REFERENCE
). For OUT
, IN
OUT
, and RETURN
parameters, INDICATOR
is passed by reference by default.
The INDICATOR
can also have a STRUCT
or TDO option. Because specifying INDICATOR
as a property of an object is not supported, and because arguments of objects have complete indicator structs instead of INDICATOR
scalars, you must specify this by using the STRUCT
option. You must use the type descriptor object (TDO) option for composite objects and collections,
In PL/SQL, there is no standard way to indicate the length of a RAW
or string parameter. However, in many cases, you want to pass the length of such a parameter to and from an external procedure. Using the properties LENGTH
and MAXLEN
, you can specify parameters that store the current length and maximum length of a formal parameter.
Note:
With a parameter of typeRAW
or LONG
RAW
, you must use the property LENGTH
. Also, if that parameter is IN
OUT
and NULL
or OUT
and NULL
, then you must set the length of the corresponding C parameter to zero.For IN
parameters, LENGTH
is passed by value (unless you specify BY
REFERENCE
) and is read-only. For OUT
, IN
OUT
, and RETURN
parameters, LENGTH
is passed by reference.
As mentioned earlier, MAXLEN
does not apply to IN
parameters. For OUT
, IN
OUT
, and RETURN
parameters, MAXLEN
is passed by reference and is read-only.
Oracle Database provides globalization support, which lets you process single-byte and multibyte character data and convert between character sets. It also lets your applications run in different language environments.
By default, if the server and agent use the exact same $ORACLE_HOME
value, the agent uses the same globalization support settings as the server (including any settings that were specified with ALTER
SESSION
statements).
If the agent is running in a separate $ORACLE_HOME
(even if the same location is specified by two different aliases or symbolic links), the agent uses the same globalization support settings as the server except for the character set; the default character set for the agent is defined by the NLS_LANG
and NLS_NCHAR
environment settings for the agent.
The properties CHARSETID
and CHARSETFORM
identify the nondefault character set from which the character data being passed was formed. With CHAR
, CLOB
, and VARCHAR2
parameters, you can use CHARSETID
and CHARSETFORM
to pass the character set ID and form to the external procedure.
For IN
parameters, CHARSETID
and CHARSETFORM
are passed by value (unless you specify BY
REFERENCE
) and are read-only (even if you specify BY
REFERENCE
). For OUT
, IN
OUT
, and RETURN
parameters, CHARSETID
and CHARSETFORM
are passed by reference and are read-only.
The OCI attribute names for these properties are OCI_ATTR_CHARSET_ID
and OCI_ATTR_CHARSET_FORM
.
See Also:
Oracle Call Interface Programmer's Guide for more information about OCI_ATTR_CHARSET_ID
and OCI_ATTR_CHARSET_FORM
Oracle Database Globalization Support Guide for more information about using national language data with the OCI
Remember, each formal parameter of the external procedure must have a corresponding parameter in the PARAMETERS
clause. Their positions can differ, because PL/SQL associates them by name, not by position. However, the PARAMETERS
clause and the C prototype for the external procedure must have the same number of parameters, and they must be in the same order.
SELF
is the always-present argument of an object type's member procedure, namely the object instance itself. In most cases, this argument is implicit and is not listed in the argument list of the PL/SQL procedure. However, SELF
must be explicitly specified as an argument of the PARAMETERS
clause.
For example, assume that a user wants to create a Person
object, consisting of a person's name and date of birth, and then create a table of this object type. The user eventually wants to determine the age of each Person
object in this table.
In SQL*Plus, the Person
object type can be created by:
CREATE OR REPLACE TYPE Person1_typ AS OBJECT ( Name VARCHAR2(30), B_date DATE, MEMBER FUNCTION calcAge_func RETURN NUMBER) );
Typically, the member function is implemented in PL/SQL, but in this example it is an external procedure. The body of the member function is declared as follows:
CREATE OR REPLACE TYPE BODY Person1_typ AS MEMBER FUNCTION calcAge_func RETURN NUMBER AS LANGUAGE C NAME "age" LIBRARY agelib WITH CONTEXT PARAMETERS ( CONTEXT, SELF, SELF INDICATOR STRUCT, SELF TDO, RETURN INDICATOR ); END;
Notice that the calcAge_func
member function does not take any arguments, but only returns a number. A member function is always called on an instance of the associated object type. The object instance itself always is an implicit argument of the member function. To refer to the implicit argument, the SELF
keyword is used. This is incorporated into the external procedure syntax by supporting references to SELF
in the parameters clause.
The matching table is created and populated.
CREATE TABLE Person_tab OF Person1_typ; INSERT INTO Person_tab VALUES ('SCOTT', TO_DATE('14-MAY-85')); INSERT INTO Person_tab VALUES ('JOHN', TO_DATE('22-DEC-71'));
Finally, we retrieve the information of interest from the table.
SELECT p.name, p.b_date, p.calcAge_func() FROM Person_tab p; NAME B_DATE P.CALCAGE_ ------------------------------ --------- ---------- SCOTT 14-MAY-85 0 JOHN 22-DEC-71 0
The following is sample C code that implements the external
member function and the Object-Type-Translator (OTT)-generated struct
definitions:
#include <oci.h> struct PERSON { OCIString *NAME; OCIDate B_DATE; }; typedef struct PERSON PERSON; struct PERSON_ind { OCIInd _atomic; OCIInd NAME; OCIInd B_DATE; }; typedef struct PERSON_ind PERSON_ind; OCINumber *age (ctx, person_obj, person_obj_ind, tdo, ret_ind) OCIExtProcContext *ctx; PERSON *person_obj; PERSON_ind *person_obj_ind; OCIType *tdo; OCIInd *ret_ind; { sword err; text errbuf[512]; OCIEnv *envh; OCISvcCtx *svch; OCIError *errh; OCINumber *age; int inum = 0; sword status; /* get OCI Environment */ err = OCIExtProcGetEnv( ctx, &envh, &svch, &errh ); /* initialize return age to 0 */ age = (OCINumber *)OCIExtProcAllocCallMemory(ctx, sizeof(OCINumber)); status = OCINumberFromInt(errh, &inum, sizeof(inum), OCI_NUMBER_SIGNED, age); if (status != OCI_SUCCESS) { OCIExtProcRaiseExcp(ctx, (int)1476); return (age); } /* return NULL if the person object is null or the birthdate is null */ if ( person_obj_ind->_atomic == OCI_IND_NULL || person_obj_ind->B_DATE == OCI_IND_NULL ) { *ret_ind = OCI_IND_NULL; return (age); } /* The actual implementation to calculate the age is left to the reader, but an easy way of doing this is a callback of the form: select trunc(months_between(sysdate, person_obj->b_date) / 12) from DUAL; */ *ret_ind = OCI_IND_NOTNULL; return (age); }
In C, you can pass IN
scalar parameters by value (the value of the parameter is passed) or by reference (a pointer to the value is passed). When an external procedure expects a pointer to a scalar, specify BY
REFERENCE
phrase to pass the parameter by reference:
CREATE OR REPLACE PROCEDURE findRoot_proc ( x IN DOUBLE PRECISION) AS LANGUAGE C LIBRARY c_utils NAME "C_findRoot" PARAMETERS ( x BY REFERENCE);
In this case, the C prototype is:
void C_findRoot(double *x);
The default (used when there is no PARAMETERS
clause) is:
void C_findRoot(double x);
By including the WITH
CONTEXT
clause, you can give an external procedure access to information about parameters, exceptions, memory allocation, and the user environment. The WITH
CONTEXT
clause specifies that a context pointer is passed to the external procedure. For example, if you write the following PL/SQL function:
CREATE OR REPLACE FUNCTION getNum_func ( x IN REAL) RETURN PLS_INTEGER AS LANGUAGE C LIBRARY c_utils NAME "C_getNum" WITH CONTEXT PARAMETERS ( CONTEXT, x BY REFERENCE, RETURN INDICATOR);
The C prototype is:
int C_getNum( OCIExtProcContext *with_context, float *x, short *retind);
The context data structure is opaque to the external procedure; but, is available to service procedures called by the external procedure.
If you also include the PARAMETERS
clause, then you must specify the parameter CONTEXT
, which shows the position of the context pointer in the parameter list. If you omit the PARAMETERS
clause, then the context pointer is the first parameter passed to the external procedure.
PL/SQL supports the IN
, IN
OUT
, and OUT
parameter modes, as well as the RETURN
clause for procedures returning values.
Now that you have published your Java class method or external C procedure, you are ready to call it.
Do not call an external procedure directly. Instead, use the CALL
statement to call the PL/SQL procedure that published the external procedure. See "CALL Statement Syntax".
Such calls, which you code in the same manner as a call to a regular PL/SQL procedure, can appear in the following:
Anonymous blocks
Standalone and packaged procedures
Methods of an object type
Database triggers
SQL statements (calls to packaged functions only).
Any PL/SQL block or procedure executing on the server side, or on the client side, (for example, in a tool such as Oracle Forms) can call an external procedure. On the server side, the external procedure runs in a separate process address space, which safeguards your database. Figure 14-1 shows how Oracle Database and external procedures interact.
Figure 14-1 Oracle Database and External Procedures
Topics:
Before calling external procedures, consider the privileges, permissions, and synonyms that exist in the execution environment.
Topics:
When external procedures are called through CALL
specifications, they execute with definer's privileges, rather than invoker privileges.
A program executing with invoker privileges is not bound to a particular schema. It executes at the calling site and accesses database items (such as tables and views) with the caller's visibility and permissions. However, a program executing with definer's privileges is bound to the schema in which it is defined. It executes at the defining site, in the definer's schema, and accesses database items with the definer's visibility and permissions.
To call external procedures, a user must have the EXECUTE
privilege on the call specification and on any resources used by the procedure.
In SQL*Plus, you can use the GRANT
and REVOKE
data control statements to manage permissions. For example:
GRANT EXECUTE ON plsToJ_demoExternal_proc TO Public; REVOKE EXECUTE ON plsToJ_demoExternal_proc FROM Public; GRANT EXECUTE ON JAVA RESOURCE "appImages" TO Public; GRANT EXECUTE ON plsToJ_demoExternal_proc TO Scott; REVOKE EXECUTE ON plsToJ_demoExternal_proc FROM Scott;
See Also:
Oracle Database SQL Language Reference for more information about the GRANT
statement
Oracle Database SQL Language Reference for more information about the REVOKE
statement
For convenience, you or your DBA can create synonyms for external procedures using the CREATE
PUBLIC
SYNONYM
statement. In the following example, your DBA creates a public synonym, which is accessible to all users. If PUBLIC
is not specified, then the synonym is private and accessible only within its schema.
CREATE PUBLIC SYNONYM Rfac FOR Scott.RecursiveFactorial;
Call the external procedure through the SQL CALL
statement. You can execute the CALL
statement interactively from SQL*Plus. The syntax is:
CALL [schema.][{object_type_name | package_name}]procedure_name[@dblink_name] [(parameter_list)] [INTO :host_variable][INDICATOR][:indicator_variable];
This is equivalent to executing a procedure myproc
using a SQL statement of the form "SELECT
myproc(
...)
FROM
DUAL
," except that the overhead associated with performing the SELECT
is not incurred.
For example, here is an anonymous PL/SQL block that uses dynamic SQL to call plsToC_demoExternal_proc
, which we published. PL/SQL passes three parameters to the external C procedure C_demoExternal_proc
.
DECLARE xx NUMBER(4); yy VARCHAR2(10); zz DATE; BEGIN EXECUTE IMMEDIATE 'CALL plsToC_demoExternal_proc(:xxx, :yyy, :zzz)' USING xx,yy,zz; END;
The semantics of the CALL
statement is identical to the that of an equivalent BEGIN-END
block.
Note:
CALL
is the only SQL statement that cannot be put, by itself, in a PL/SQL BEGIN-END
block. It can be part of an EXECUTE
IMMEDIATE
statement within a BEGIN-END
block.To call the J_calcFactorial
class method published earlier:
Declare and initialize two SQL*Plus host variables:
VARIABLE x NUMBER VARIABLE y NUMBER EXECUTE :x := 5;
Call J_calcFactorial
:
CALL J_calcFactorial(:x) INTO :y; PRINT y
Result:
Y ------ 120
To call an external C procedure, PL/SQL must find the path of the appropriate DLL. The PL/SQL engine retrieves the path from the data dictionary, based on the library alias from the AS
LANGUAGE
clause of the procedure declaration.
Next, PL/SQL alerts a Listener process which, in turn, spawns a session-specific agent. By default, this agent is named extproc
, although you can specify other names in the listener
.ora
file. The Listener hands over the connection to the agent, and PL/SQL passes to the agent the name of the DLL, the name of the external procedure, and any parameters.
Then, the agent loads the DLL and runs the external procedure. Also, the agent handles service calls (such as raising an exception) and callbacks to Oracle Database. Finally, the agent passes to PL/SQL any values returned by the external procedure.
Note:
Although some DLL caching takes place, there is no guarantee that your DLL will remain in the cache; therefore, do not store global variables in your DLL.After the external procedure completes, the agent remains active throughout your Oracle Database session; when you log off, the agent is killed. Consequently, you incur the cost of launching the agent only once, no matter how many calls you make. Still, call an external procedure only when the computational benefits outweigh the cost.
Here, we call PL/SQL function plsCallsCdivisor_func
, which we published previously, from an anonymous block. PL/SQL passes the two integer parameters to external function Cdivisor_func
, which returns their greatest common divisor.
DECLARE g PLS_INTEGER; a PLS_INTEGER; b PLS_INTEGER; CALL plsCallsCdivisor_func(a, b); IF g IN (2,4,8) THEN ...
The PL/SQL compiler raises compile time errors if an AS
EXTERNAL
call specification is found in a TYPE
or PACKAGE
specification.
C programs can raise exceptions through the OCIExtproc
functions.
When called from an external procedure, a service routine can raise exceptions, allocate memory, and call OCI handles for callbacks to the server. To use a service routine, you must specify the WITH
CONTEXT
clause, which lets you pass a context structure to the external procedure. The context structure is declared in header file ociextp
.h
as follows:
typedef struct OCIExtProcContext OCIExtProcContext;
Note:
ociextp.h
is located in $ORACLE_HOME/plsql/public
on Linux and UNIX.Service procedures:
This service routine allocates n bytes of memory for the duration of the external procedure call. Any memory allocated by the function is freed automatically as soon as control returns to PL/SQL.
Note:
Do not have the external procedure call the C functionfree
to free memory allocated by this service routine, as this is handled automatically.The C prototype for this function is as follows:
dvoid *OCIExtProcAllocCallMemory( OCIExtProcContext *with_context, size_t amount);
The parameters with_context
and amount
are the context pointer and number of bytes to allocate, respectively. The function returns an untyped pointer to the allocated memory. A return value of zero indicates failure.
In SQL*Plus, suppose you publish external function plsToC_concat_func
, as follows:
CREATE OR REPLACE FUNCTION plsToC_concat_func ( str1 IN VARCHAR2, str2 IN VARCHAR2) RETURN VARCHAR2 AS LANGUAGE C NAME "concat" LIBRARY stringlib WITH CONTEXT PARAMETERS ( CONTEXT, str1 STRING, str1 INDICATOR short, str2 STRING, str2 INDICATOR short, RETURN INDICATOR short, RETURN LENGTH short, RETURN STRING);
When called, C_concat
concatenates two strings, then returns the result:
select plsToC_concat_func('hello ', 'world') from DUAL; PLSTOC_CONCAT_FUNC('HELLO','WORLD') ----------------------------------------------------------------------------- hello world
If either string is NULL
, the result is also NULL
. As the following example shows, C_concat
uses OCIExtProcAllocCallMemory
to allocate memory for the result string:
#include <stdio.h> #include <stdlib.h> #include <string.h> #include <oci.h> #include <ociextp.h> char *concat(ctx, str1, str1_i, str2, str2_i, ret_i, ret_l) OCIExtProcContext *ctx; char *str1; short str1_i; char *str2; short str2_i; short *ret_i; short *ret_l; { char *tmp; short len; /* Check for null inputs. */ if ((str1_i == OCI_IND_NULL) || (str2_i == OCI_IND_NULL)) { *ret_i = (short)OCI_IND_NULL; /* PL/SQL has no notion of a NULL ptr, so return a zero-byte string. */ tmp = OCIExtProcAllocCallMemory(ctx, 1); tmp[0] = '\0'; return(tmp); } /* Allocate memory for result string, including NULL terminator. */ len = strlen(str1) + strlen(str2); tmp = OCIExtProcAllocCallMemory(ctx, len + 1); strcpy(tmp, str1); strcat(tmp, str2); /* Set NULL indicator and length. */ *ret_i = (short)OCI_IND_NOTNULL; *ret_l = len; /* Return pointer, which PL/SQL frees later. */ return(tmp); } #ifdef LATER static void checkerr (/*_ OCIError *errhp, sword status _*/); void checkerr(errhp, status) OCIError *errhp; sword status; { text errbuf[512]; sb4 errcode = 0; switch (status) { case OCI_SUCCESS: break; case OCI_SUCCESS_WITH_INFO: (void) printf("Error - OCI_SUCCESS_WITH_INFO\n"); break; case OCI_NEED_DATA: (void) printf("Error - OCI_NEED_DATA\n"); break; case OCI_NO_DATA: (void) printf("Error - OCI_NODATA\n"); break; case OCI_ERROR: (void) OCIErrorGet((dvoid *)errhp, (ub4) 1, (text *) NULL, &errcode, errbuf, (ub4) sizeof(errbuf), OCI_HTYPE_ERROR); (void) printf("Error - %.*s\n", 512, errbuf); break; case OCI_INVALID_HANDLE: (void) printf("Error - OCI_INVALID_HANDLE\n"); break; case OCI_STILL_EXECUTING: (void) printf("Error - OCI_STILL_EXECUTE\n"); break; case OCI_CONTINUE: (void) printf("Error - OCI_CONTINUE\n"); break; default: break; } } char *concat(ctx, str1, str1_i, str2, str2_i, ret_i, ret_l) OCIExtProcContext *ctx; char *str1; short str1_i; char *str2; short str2_i; short *ret_i; short *ret_l; { char *tmp; short len; /* Check for null inputs. */ if ((str1_i == OCI_IND_NULL) || (str2_i == OCI_IND_NULL)) { *ret_i = (short)OCI_IND_NULL; /* PL/SQL has no notion of a NULL ptr, so return a zero-byte string. */ tmp = OCIExtProcAllocCallMemory(ctx, 1); tmp[0] = '\0'; return(tmp); } /* Allocate memory for result string, including NULL terminator. */ len = strlen(str1) + strlen(str2); tmp = OCIExtProcAllocCallMemory(ctx, len + 1); strcpy(tmp, str1); strcat(tmp, str2); /* Set NULL indicator and length. */ *ret_i = (short)OCI_IND_NOTNULL; *ret_l = len; /* Return pointer, which PL/SQL frees later. */ return(tmp); } /*======================================================================*/ int main(char *argv, int argc) { OCIExtProcContext *ctx; char *str1; short str1_i; char *str2; short str2_i; short *ret_i; short *ret_l; /* OCI Handles */ OCIEnv *envhp; OCIServer *srvhp; OCISvcCtx *svchp; OCIError *errhp; OCISession *authp; OCIStmt *stmthp; OCILobLocator *clob, *blob; OCILobLocator *Lob_loc; /* Initialize and Logon */ (void) OCIInitialize((ub4) OCI_DEFAULT, (dvoid *)0, (dvoid * (*)(dvoid *, size_t)) 0, (dvoid * (*)(dvoid *, dvoid *, size_t))0, (void (*)(dvoid *, dvoid *)) 0 ); (void) OCIEnvInit( (OCIEnv **) &envhp, OCI_DEFAULT, (size_t) 0, (dvoid **) 0 ); (void) OCIHandleAlloc( (dvoid *) envhp, (dvoid **) &errhp, OCI_HTYPE_ERROR, (size_t) 0, (dvoid **) 0); /* Server contexts */ (void) OCIHandleAlloc( (dvoid *) envhp, (dvoid **) &srvhp, OCI_HTYPE_SERVER, (size_t) 0, (dvoid **) 0); /* Service context */ (void) OCIHandleAlloc( (dvoid *) envhp, (dvoid **) &svchp, OCI_HTYPE_SVCCTX, (size_t) 0, (dvoid **) 0); /* Attach to Oracle Database */ (void) OCIServerAttach( srvhp, errhp, (text *)"", strlen(""), 0); /* Set attribute server context in the service context */ (void) OCIAttrSet ((dvoid *) svchp, OCI_HTYPE_SVCCTX, (dvoid *)srvhp, (ub4) 0, OCI_ATTR_SERVER, (OCIError *) errhp); (void) OCIHandleAlloc((dvoid *) envhp, (dvoid **)&authp, (ub4) OCI_HTYPE_SESSION, (size_t) 0, (dvoid **) 0); (void) OCIAttrSet((dvoid *) authp, (ub4) OCI_HTYPE_SESSION, (dvoid *) "samp", (ub4)4, (ub4) OCI_ATTR_USERNAME, errhp); (void) OCIAttrSet((dvoid *) authp, (ub4) OCI_HTYPE_SESSION, (dvoid *) "password", (ub4) 4, (ub4) OCI_ATTR_PASSWORD, errhp); /* Begin a User Session */ checkerr(errhp, OCISessionBegin ( svchp, errhp, authp, OCI_CRED_RDBMS, (ub4) OCI_DEFAULT)); (void) OCIAttrSet((dvoid *) svchp, (ub4) OCI_HTYPE_SVCCTX, (dvoid *) authp, (ub4) 0, (ub4) OCI_ATTR_SESSION, errhp); /* -----------------------User Logged In------------------------------*/ printf ("user logged in \n"); /* allocate a statement handle */ checkerr(errhp, OCIHandleAlloc( (dvoid *) envhp, (dvoid **) &stmthp, OCI_HTYPE_STMT, (size_t) 0, (dvoid **) 0)); checkerr(errhp, OCIDescriptorAlloc((dvoid *)envhp, (dvoid **) &Lob_loc, (ub4) OCI_DTYPE_LOB, (size_t) 0, (dvoid **) 0)); /* ------- subroutine called here-----------------------*/ printf ("calling concat...\n"); concat(ctx, str1, str1_i, str2, str2_i, ret_i, ret_l); return 0; } #endif
This service routine raises a predefined exception, which must have a valid Oracle Database error number in the range 1..32,767. After doing any necessary cleanup, your external procedure must return immediately. (No values are assigned to OUT
or IN
OUT
parameters.) The C prototype for this function follows:
int OCIExtProcRaiseExcp( OCIExtProcContext *with_context, size_t errnum);
The parameters with_context
and error_number
are the context pointer and Oracle Database error number. The return values OCIEXTPROC_SUCCESS
and OCIEXTPROC_ERROR
indicate success or failure.
In SQL*Plus, suppose you publish external procedure plsTo_divide_proc
, as follows:
CREATE OR REPLACE PROCEDURE plsTo_divide_proc ( dividend IN PLS_INTEGER, divisor IN PLS_INTEGER, result OUT FLOAT) AS LANGUAGE C NAME "C_divide" LIBRARY MathLib WITH CONTEXT PARAMETERS ( CONTEXT, dividend INT, divisor INT, result FLOAT);
When called, C_divide
finds the quotient of two numbers. As the following example shows, if the divisor is zero, C_divide
uses OCIExtProcRaiseExcp
to raise the predefined exception ZERO_DIVIDE
:
void C_divide (ctx, dividend, divisor, result) OCIExtProcContext *ctx; int dividend; int divisor; float *result; { /* Check for zero divisor. */ if (divisor == (int)0) { /* Raise exception ZERO_DIVIDE, which is Oracle Database error 1476. */ if (OCIExtProcRaiseExcp(ctx, (int)1476) == OCIEXTPROC_SUCCESS) { return; } else { /* Incorrect parameters were passed. */ assert(0); } } *result = (float)dividend / (float)divisor; }
This service routine raises a user-defined exception and returns a user-defined error message. The C prototype for this function follows:
int OCIExtProcRaiseExcpWithMsg( OCIExtProcContext *with_context, size_t error_number, text *error_message, size_t len);
The parameters with_context
, error_number
, and error_message
are the context pointer, Oracle Database error number, and error message text. The parameter len
stores the length of the error message. If the message is a null-terminated string, then len
is zero. The return values OCIEXTPROC_SUCCESS
and OCIEXTPROC_ERROR
indicate success or failure.
In the previous example, we published external procedure plsTo_divide_proc
. In the following example, you use a different implementation. With this version, if the divisor is zero, then C_divide
uses OCIExtProcRaiseExcpWithMsg
to raise a user-defined exception:
void C_divide (ctx, dividend, divisor, result) OCIExtProcContext *ctx; int dividend; int divisor; float *result; /* Check for zero divisor. */ if (divisor == (int)0) { /* Raise a user-defined exception, which is Oracle Database error 20100, and return a null-terminated error message. */ if (OCIExtProcRaiseExcpWithMsg(ctx, (int)20100, "divisor is zero", 0) == OCIEXTPROC_SUCCESS) { return; } else { /* Incorrect parameters were passed. */ assert(0); } } *result = dividend / divisor; }
To enable callbacks, use the function OCIExtProcGetEnv.
Topics:
This service routine enables OCI callbacks to the database during an external procedure call. The environment handles obtained by using this function re-use the existing connection to go back to the database. If you need to establish a new connection to the database, you cannot use these handles; instead, you must create your own.
The C prototype for this function follows:
sword OCIExtProcGetEnv ( OCIExtProcContext *with_context, OCIEnv envh, OCISvcCtx svch, OCIError errh )
The parameter with_context
is the context pointer, and the parameters envh
, svch
, and errh
are the OCI environment, service, and error handles, respectively. The return values OCIEXTPROC_SUCCESS
and OCIEXTPROC_ERROR
indicate success or failure.
Both external C procedures and Java class methods can call-back to the database to do SQL operations. For a working example, see "Example: Calling an External Procedure" .
Note:
Callbacks are not necessarily a same-session phenomenon; you might execute an SQL statement in a different session throughOCIlogon
.An external C procedure executing on Oracle Database can call a service routine to obtain OCI environment and service handles. With the OCI, you can use callbacks to execute SQL statements and PL/SQL subprograms, fetch data, and manipulate LOBs. Callbacks and external procedures operate in the same user session and transaction context, and so have the same user privileges.
In SQL*Plus, suppose you run the following script:
CREATE TABLE Emp_tab (empno NUMBER(10)) CREATE PROCEDURE plsToC_insertIntoEmpTab_proc ( empno PLS_INTEGER) AS LANGUAGE C NAME "C_insertEmpTab" LIBRARY insert_lib WITH CONTEXT PARAMETERS ( CONTEXT, empno LONG);
Later, you might call service routine OCIExtProcGetEnv
from external procedure plsToC_insertIntoEmpTab_proc
, as follows:
#include <stdio.h> #include <stdlib.h> #include <oratypes.h> #include <oci.h> /* includes ociextp.h */ ... void C_insertIntoEmpTab (ctx, empno) OCIExtProcContext *ctx; long empno; { OCIEnv *envhp; OCISvcCtx *svchp; OCIError *errhp; int err; ... err = OCIExtProcGetEnv(ctx, &envhp, &svchp, &errhp); ... }
If you do not use callbacks, you do not need to include oci
.h
; instead, just include ociextp
.h
.
To execute object-related callbacks from your external procedures, the OCI environment in the extproc
agent is fully initialized in object mode. You retrieve handles to this environment with the OCIExtProcGetEnv
procedure.
The object run-time environment lets you use static, as well as dynamic, object support provided by OCI. To utilize static support, use the OTT to generate C structs for the appropriate object types, and then use conventional C code to access the object attributes.
For those objects whose types are unknown at external procedure creation time, an alternative, dynamic, way of accessing objects is first to call OCIDescribeAny
to obtain attribute and method information about the type. Then, OCIObjectGetAttr
and OCIObjectSetAttr
can be called to retrieve and set attribute values.
Because the current external procedure model is stateless, OCIExtProcGetEnv
must be called in every external procedure that wants to execute callbacks, or call OCIExtProc
. service routines. After every external procedure call, the callback mechanism is cleaned up and all OCI handles are freed.
With callbacks, the following SQL statements and OCI subprograms are not supported:
Transaction control statements such as COMMIT
Data definition statements such as CREATE
The following object-oriented OCI subprograms:
OCIObjectNew OCIObjectPin OCIObjectUnpin OCIObjectPinCountReset OCIObjectLock OCIObjectMarkUpdate OCIObjectUnmark OCIObjectUnmarkByRef OCIObjectAlwaysLatest OCIObjectNotAlwaysLatest OCIObjectMarkDeleteByRef OCIObjectMarkDelete OCIObjectFlush OCIObjectFlushRefresh OCIObjectGetTypeRef OCIObjectGetObjectRef OCIObjectExists OCIObjectIsLocked OCIObjectIsDirtied OCIObjectIsLoaded OCIObjectRefresh OCIObjectPinTable OCIObjectArrayPin OCICacheFlush, OCICacheFlushRefresh, OCICacheRefresh OCICacheUnpin OCICacheFree OCICacheUnmark OCICacheGetObjects OCICacheRegister
Polling-mode OCI subprograms such as OCIGetPieceInfo
The following OCI subprograms:
OCIEnvInit OCIInitialize OCIPasswordChange OCIServerAttach OCIServerDetach OCISessionBegin OCISessionEnd OCISvcCtxToLda OCITransCommit OCITransDetach OCITransRollback OCITransStart
Also, with OCI subprogram OCIHandleAlloc
, the following handle types are not supported:
OCI_HTYPE_SERVER OCI_HTYPE_SESSION OCI_HTYPE_SVCCTX OCI_HTYPE_TRANS
Usually, when an external procedure fails, its prototype is faulty. In other words, the prototype does not match the one generated internally by PL/SQL. This can happen if you specify an incompatible C datatype. For example, to pass an OUT
parameter of type REAL
, you must specify float *
. Specifying float
, double
*
, or any other C datatype results in a mismatch.
In such cases, you might get:
lost RPC connection to external routine agent
This error, which means that extproc
terminated abnormally because the external procedure caused a core dump. To avoid errors when declaring C prototype parameters, see the preceding tables.
To help you debug external procedures, PL/SQL provides the utility package DEBUG_EXTPROC
. To install the package, run the script dbgextp
.sql
, which you can find in the PL/SQL demo directory. (For the location of the directory, see your Oracle Database Installation or User's Guide.)
To use the package, follow the instructions in dbgextp
.sql
. Your Oracle Database account must have EXECUTE
privileges on the package and CREATE
LIBRARY
privileges.
Note:
DEBUG_EXTPROC
works only on platforms with debuggers that can attach to a running process.Also in the PL/SQL demo directory is the script extproc
.sql
, which demonstrates the calling of an external procedure. The companion file extproc
.c
contains the C source code for the external procedure.
To run the demo, follow the instructions in extproc
.sql
. You must use the SCOTT
account, which must have CREATE
LIBRARY
privileges.
A global variable is declared outside of a function, and its value is shared by all functions of a program. In case of external procedures, this means that all functions in a DLL share the value of the global. The usage of global variables is discouraged for two reasons:
Threading
In the nonthreaded configuration of the agent process, only one function is active at a time. In the case of the multithreaded extproc
agent, multiple functions can be active at the same time, and two or more functions might try to access the global variable concurrently, with unsuccessful results.
DLL caching
Global variables are also used to store data that is intended to persist beyond the lifetime of a function. For example, suppose that functions func1
and func2
try to pass data to each other. Because of the DLL caching feature, it is possible that after func1
completes, the DLL will be unloaded, causing all global variables to lose their values. When func2
executes, the DLL is reloaded, and all global variables are initialized to 0, which is inconsistent with their values at the completion of func1
.
There are two types of static variables: external and internal. An external static variable is a special case of a global variable, so its usage is discouraged. Internal static variables are local to a particular function, but remain in existence rather than coming and going each time the function is activated. Therefore, they provide private, permanent storage within a single function. These variables are used to pass on data to subsequent calls to the same function. But, because of the DLL caching feature mentioned previously, the DLL might be unloaded and reloaded between calls, which means that the internal static variable loses its value.
See Also:
Templatemakefile
in the RDBMS subdirectory /public
for help creating a dynamic link libraryWhen calling external procedures:
Never write to IN
parameters or overflow the capacity of OUT
parameters. (PL/SQL does no run time checks for these error conditions.)
Never read an OUT
parameter or a function result.
Always assign a value to IN
OUT
and OUT
parameters and to function results. Otherwise, your external procedure will not return successfully.
If you include the WITH
CONTEXT
and PARAMETERS
clauses, then you must specify the parameter CONTEXT
, which shows the position of the context pointer in the parameter list.
If you include the PARAMETERS
clause, and if the external procedure is a function, then you must specify the parameter RETURN
in the last position.
For every formal parameter, there must be a corresponding parameter in the PARAMETERS
clause. Also, ensure that the datatypes of parameters in the PARAMETERS
clause are compatible with those in the C prototype, because no implicit conversions are done.
With a parameter of type RAW
or LONG
RAW
, you must use the property LENGTH
. Also, if that parameter is IN
OUT
or OUT
and null, then you must set the length of the corresponding C parameter to zero.
The following restrictions apply to external procedures:
This feature is available only on platforms that support DLLs.
Only C procedures and procedures callable from C code are supported.
You cannot pass PL/SQL cursor variables or records to an external procedure. For records, use instances of object types instead.
In the LIBRARY
subclause, you cannot use a database link to specify a remote library.
The maximum number of parameters that you can pass to a external procedure is 128. However, if you pass float or double parameters by value, then the maximum is less than 128. How much less depends on the number of such parameters and your operating system. To get a rough estimate, count each float or double passed by value as two parameters.