This document provides an overview of the general prerequisites and and a short description of the facilities that are available in Natural for implementing a Natural RPC (Remote Procedure Call) environment.
The following topics are covered:
If the RPC environment is to be implemented on different plattforms, the corresponding current versions of Natural for Mainframes, Windows, UNIX or OpenVMS will be required. In addition, the following required or optional products, subproducts and facilities are available for use in a Natural RPC environment:
Product | Purpose |
---|---|
EntireX Communicator (EntireX Broker) | The EntireX Broker of the Software AG product EntireX Communicator usually establishes the middleware layer between the Natural client and a Natural server. It uses the ACI protocol and comprises the appropriate client/server stubs. |
Entire Net-Work | This Software AG product is required if the transport method used by EntireX Broker is Entire Net-work. This is the preferred transport method. |
TCP/IP | Required if the transport method used by EntireX Broker is
TCP/IP.
See also Using TCP/IP as a Transport Method in Setting Up a Natural RPC Environment. |
EntireX Developer's Kit | Included in the EntireX Communicator product, this kit is required for non-Natural programming language support. |
Directory Services | A remote directory server (RDS) enables you to define directory
definitions in one place so that its services can be used by all clients in an
RPC environment.
An RDS is required if the Location Transparency provided by EntireX Broker is used. |
Natural Security | Optional.
This Software AG add-on product is required on the server side to protect Natural RPC servers and services when security is active on the client and vice versa. |
EntireX RPC | Optional.
Natural RPC fully supports EntireX RPC for 3GL. EntireX RPC is included in the EntireX Communicator product. |
EntireX Security | Optional.
Natural RPC fully supports EntireX Security on the client and on the server side. EntireX Security is included in the EntireX Broker product. |
For the supported Software AG product versions, refer to Software AG Product Versions Required with Natural in the current Natural Release Notes for Mainframes.
For information on other products that may be involved in a Natural RPC-based environment, see the corresponding product documentation.
The following Natural statements are used in the creation of a Natural RPC environment:
In the section Restrictions and Limitations, the paragraphs Natural Statement Reactions and Notes on Natural Statements on the Server provide information on what you should know about any deviating behavior of these statements when they are used in a Natural RPC environment.
The following Natural utilities are used in the creation and maintenance of a Natural RPC environment:
SYSRPC
This utility is used to maintain remote procedure call environments.
This utility is used to locate and test Natural Application
Programming Interfaces (APIs, see below) contained in the current system
library SYSEXT
either in a local Windows
environment or in a remote environment located on a UNIX, OpenVMS or a
mainframe platform.
SYSPARM
On mainframes, this utility is used for creating and maintaining a set of Natural profile parameters that is stored under a profile name.
Under Windows, UNIX and OpenVMS, this utility is used to modify global and local configuration files and to create or modify parameter files.
The purpose of Natural Application Programming Interfaces (API) is to retrieve or modify information or use services that are not accessible by Natural statements.
The following Application Programming Interfaces available in the
Natural library SYSEXT
are intended for being used with the
Natural RPC:
API | Purpose |
---|---|
USR1071N |
Set user ID, password and ticket criteria for Natural RPC.
See Using Security. |
USR2007N |
Specify a default server address that is to be used each time a
remote program cannot be addressed via the service directory.
See Specifying a Default Server Address within a Natural Session in Operating a Natural RPC Environment. |
USR2032N |
Support the commit for a CLOSE CONVERSATION statement
on the client side. When called, this API will cause an implicit END
TRANSACTION at the end of the individual conversation.
See Database Transactions in Introducing Natural RPC, section Conversational CALLNAT. |
USR2035N |
Set the required SSL parameter string if the Secure Socket Layer
(SSL) for the TCP/IP communication to the EntireX Broker is used.
See Using Secure Socket Layer in Operating a Natural RPC Environment. |
USR2071N |
Has to be called in case of non-Natural Security clients for specifying logon data which are then passed to the server. See Using Natural RPC with Natural Security in Using Security. |
USR2072N |
Specify a password which is used for the LOGON in
conjunction with profile parameter SRVUSER .
See Server Side in Using Security, section Using Natural RPC with EntireX Security. |
USR2073N |
Ping or terminate an RPC server from within your application.
See Using Application Programming Interface USR2073N in Terminating a Natural RPC Server. |
USR2074N |
Change the Natural Security password on the RPC server via a
Natural RPC service request.
See Change Password in Using Security. |
USR2075N |
Terminate an EntireX Broker Service from within your
application.
See Using Application Programming Interface USR2075N in Terminating a Natural RPC Server. |
USR4008N |
On the client side, specifiy an alternate name of a library to
which the server will logon.
See Using the Logon Option in Operating a Natural RPC Environment. |
USR4009N |
Set or get parameters for EntireX in a Natural RPC client or
server environment.
See Setting/Getting Parameters for EntireX in Operating a Natural RPC Environment. |
USR4010N |
On the client side, retrieve the runtime settings of a server.
See Retrieving the Runtime Settings of a Server in Operating a Natural RPC Environment. |
USR4371N |
On the client side, set the user ID and ETID for Natural RPC servers which were configured with Impersonation = A (automatic logon). |
USR6304N |
Set or get the reliable state for the reliable Natural RPC.
See Reliable RPC on the Natural RPC Client Side in Reliable RPC. |
USR6305N |
Commit or rollback reliable RPC message(s). This API is required
if the reliable RPC state has been set to "client commit"
See Reliable RPC on the Natural RPC Client Side in Reliable RPC. |
USR6306N |
Retrieve the status of all reliable RPC messages of the user who
is currently logged on to the EntireX Broker.
See Reliable RPC on the Natural RPC Server Side in Reliable RPC. |
Note that the RPC-specific APIs accept all values also in mixed mode. An
uppercase translation will take place only if the example program
USRnnnnP
(source object) is used to
invoke the corresponding subprogram
USRnnnnN
. Exception: All
USRnnnnP
programs that deal with
passwords provide an option to enter the passwords in mixed case mode.
For an explanation of the Natural object types that are typically
provided for each API, see the Natural utility
SYSEXT
.
This section describes the specific mapping of Software AG IDL data types, groups, arrays and structures to the Natural programming language. Please note also the remarks and hints on the IDL data types valid for all language bindings found in the Software AG IDL File (in the EntireX documentation).
In the table below, the following metasymbols and informal terms are used for the IDL.
The metasymbols [ and ] surround optional lexical entities.
The informal term number (or in some cases number.number) is a sequence of numeric characters, for example 123.
Software AG IDL | Description | Natural Data Format | Note |
---|---|---|---|
Anumber | Alphanumeric | Anumber | |
AV | Alphanumeric variable length | A DYNAMIC | |
AVnumber | Alphanumeric variable length with maximum length | A DYNAMIC | |
Bnumber | Binary | Bnumber | |
BV | Binary variable length | B DYNAMIC | |
BVnumber | Binary variable length with maximum length | B DYNAMIC | |
D | Date | D | 3,5 |
F4 | Floating point (small) | F4 | 2 |
F8 | Floating point (large) | F8 | 2 |
I1 | Integer (small) | I1 | |
I2 | Integer (medium) | I2 | |
I4 | Integer (large) | I4 | |
Knumber | Kanji | Anumber | 1 |
KV | Kanji variable length | A DYNAMIC | 1 |
KVnumber | Kanji variable length with maximum length | A DYNAMIC | 1 |
L | Logical | L | |
Nnumber[.number] | Unpacked decimal | Nnumber[.number] | |
NUnumber[.number] | Unpacked decimal unsigned | Nnumber[.number] | |
Pnumber[.number] | Packed decimal | Pnumber[.number] | |
PUnumber[.number] | Packed decimal unsigned | Pnumber[.number] | |
T | Time | T | 3,4 |
Unumber | Unicode | Unumber | |
UV | Unicode variable length | U DYNAMIC | |
UVnumber | Unicode variable length with maximum length | U DYNAMIC |
See also the hints and restrictions on the Software AG IDL Data Types (in the EntireX documentation) valid for all language bindings.
Data type K is an RPC-specific data format that is not part of the Natural language.
When floating-point data types are used, errors due to rounding can occur, so that the values of senders and receivers might differ slightly. This is especially true if client and server use different representations for floating point data (IEEE, HFP).
Count of days AD (anno domini, after the birth of Christ). The valid range is from 1.1.0001 up to 28.11.2737. Mapping of the number to the date in the complete range from 1.1.0001 on, follows the Julian and Gregorian calendar, taking into consideration the following rules:
Years that are evenly divisible by 4 are leap years.
Years that are evenly divisible by 100 are not leap years unless rule 3, below, is true.
Years that are evenly divisible by 400 are leap years.
Before the year 1582 AD, rule 1 from the Julian calendar is used. After the year 1582 AD, rules 1, 2 and 3 of the Gregorian calendar are used.
See the following table for the relation of the packed number to a real date:
Date / Range of Dates | Value / Range of Values |
---|---|
1.1.0000 | 0 (special value - no date) |
undefined dates | 1 - 364 (do not use) |
1.1.0001 | 365 |
1.1.1970 | 719527 (start of C-time functions) |
28.11.2737 | 999999 (maximum date) |
Count of tenth of seconds AD (anno domini, after the birth of Christ). The valid range is from 1.1.0001 00:00:00.0 up to 16.11.3168 9:46:39 plus 0.9 seconds. See the following table for the relation of the packed number to a real time:
Time / Range of Times | Value / Range of Values |
---|---|
1.1.0000 00:00:00.0 | 0 (special value - no date) |
undefined times | 1 - 315359999 |
1.1.0001 00:00:00.0 | 315360000 |
1.1.1970 00:00:00.0 | 621671328000 (start of C-time functions) |
The relation between the packed number of a Date and Time data type is as follows:
tenths of a second per day = 24*60*60*10 = 864000
number of time | = number of date | * 864000 |
315360000 | = 365 | * 864000 1.1.0001 00:00:00.0 |
621671328000 | = 719527 | * 864000 1.1.1970 00:00:00.0 |
number of date | = number of time | / 864000 |
365 | = 315360000 | / 864000 1.1.0001 |
719527 | = 621671328000 | / 864000 1.1.1970 |
The library name as specified in the IDL file is not supported by
Natural. By default, a Natural client sends the library name
SYSTEM
to the server. To send a library name other than
SYSTEM
from a client to a server, the following steps are required
for the client:
To send a library name other than SYSTEM
from a client
to a server
On the client, turn on the logon option.
Call application programming interface
USR4008N
to specify
the name of the library, otherwise the name of the current library is sent
The length of the library name is limited to 8 characters.
The program name is sent from a client to the server. Special characters are not replaced. The program alias is not sent to the server.
The generated Natural interface object has the same name.
In the RPC server, the IDL program name sent is used to locate the Natural subprogram.
The length of the program name is limited to 8 characters.
The parameter names as given in the parameter-data-definition of the IDL file are replaced by artificial names in the generated Natural interface object.
See parameter-data-definition in the section Software AG IDL Grammar in the EntireX documentation.
Fixed arrays within the IDL file are mapped to fixed Natural arrays. The lower bound is set to 1 and the upper bound is set to the upper bound given in the IDL file.
See the array-definition (in the section Software AG IDL Grammar in the EntireX documentation) for the syntax on how to describe fixed arrays within the IDL file and refer to fixed-bound-array-index.
Unbounded arrays within the IDL file are mapped to Natural X-arrays. The lower bound is always fixed and set to 1.
See the array-definition (in the section Software AG IDL Grammar in the EntireX documentation) for the syntax of unbounded arrays within the IDL file and refer to unbounded-array-index.
Note:
Natural variable arrays (Natural notation (../1:V)) can be used on
the Natural RPC server side instead of Natural fixed arrays or X-arrays. An RPC
client can pass either an IDL fixed array or IDL unbounded array to a Natural
RPC server with such a Natural variable array. In the RPC server, the variable
array cannot be resized; this means the number of array occurrences cannot be
changed, and the Natural RPC server will always pass back the same number of
occurrences.
Groups within the IDL file are mapped to Natural groups. See group-parameter-definition (in the section Software AG IDL Grammar in the EntireX documentation) for the syntax on how to describe groups within the IDL file.
Structures within the IDL file are mapped to Natural groups. See structure-definition (in the section Software AG IDL Grammar in the EntireX documentation) for the syntax on how to describe structures within the IDL file.
The IDL syntax allows you to define parameters as IN parameters, OUT parameters, or INOUT parameters (which is the default if nothing is specified). This direction specification is reflected by Natural as follows:
Parameters with the OUT
attribute are
sent from the RPC client to the RPC server. They are always provided with the
call by reference method.
Parameters with the IN
attribute are
sent from the RPC server to the RPC client. They are always provided with the
call by reference method.
Parameters with the INOUT
attribute
are sent from the RPC client to the RPC server and then back to the RPC
client.
Only the direction information of the top-level fields (level 1) is relevant. Group fields always inherit the specification from their parent. A different specification is ignored.
See attribute-list (in the section Software AG IDL Grammar in the EntireX documentation) for the syntax on how to describe attributes within the IDL file and refer to direction-attribute.
Note:
If you define an interface object layout in the Natural application
SYSRPC
, the meaning of the direction attributes IN and OUT are
reversed compared to the IDL:
IN
in SYSTRPC
is
OUT
in IDL
OUT
in SYSTRPC
is
IN
in IDL
The ALIGNED
attribute is not relevant
for the programming language Natural. However, a Natural client can send the
ALIGNED
attribute to an RPC server where it
might be needed. To do this you need a Natural interface object that has been
generated from an IDL file.
See attribute-list (in the section Software AG IDL Grammar in the EntireX documentation) for the syntax of attributes in the IDL file and refer to the aligned-attribute.
The IDL syntax allows definitions of procedures only. It does not have the concept of a function. A function is a procedure which, in addition to the parameters, returns a value. Procedures and functions are transparent between clients and server. This means a client using a function can call a server implemented as a procedure, and vice versa.
The Natural RPC does not support functions.