Compaq COBOL
User Manual

13.2.2 Return of the Function Value

A function is a routine that returns a single value to the calling routine. The function value represents the return value that is assigned to the function's identifier during execution. According to the OpenVMS Calling Standard, a function value may be returned as either an actual value or a condition value that indicates success or failure.

13.2.3 The Argument List

You can use an argument list to pass information to a routine and receive results. The OpenVMS Calling Standard defines a data structure called an argument list as an argument item sequence, consisting of the first six arguments occupying six integer and six floating-point registers (R16-R21 and F16-F21), with additional argument placed on the stack. The argument information is contained in R25 (AI register). The stack pointer is contained in R30.

For detailed information, see the OpenVMS Calling Standard.

13.3 OpenVMS Alpha System Routines (OpenVMS)

System routines are OpenVMS Alpha routines that perform common tasks, such as finding the square root of a number or allocating virtual memory. You can call any system routine from your program, provided that Compaq COBOL supports the data structures required to call the routine.

The system routines used most often are OpenVMS Alpha Run-Time Library routines and system services. System routines are documented in detail in the OpenVMS RTL Library (LIB$) Manual and the OpenVMS System Services Reference Manual.

13.3.1 OpenVMS Alpha Run-Time Library Routines

The OpenVMS Alpha Run-Time Library provides commonly used routines that perform a wide variety of functions. These routines are grouped according to the types of tasks they perform, and each group has a prefix that identifies those routines as members of a particular OpenVMS Alpha Run-Time Library facility. Table 13-2 lists all the language-independent Run-Time Library facility prefixes and the types of tasks each facility performs.

Table 13-2 Run-Time Library Facilities (OpenVMS)
Facility Prefix Types of Tasks Performed

CVT$ Library routines that handle floating-point data conversion

DTK$ DECtalk routines that are used to control a Compaq DECtalk device

LIB$ Library routines that:
Obtain records from devices
Manipulate strings
Convert data types for I/O
Allocate resources
Obtain system information
Signal exceptions
Establish condition handlers
Enable detection of hardware exceptions
Process cross-reference data

MTH$ Mathematics routines that perform arithmetic, algebraic, and trigonometric calculations

OTS$ General-purpose routines that perform tasks such as data type conversions as part of a compiler's generated code

PPL$ Parallel processing routines that help you implement concurrent programs on single-CPU and multiprocessor systems

SMG$ Screen management routines that are used in designing, composing, and keeping track of complex images on a video screen

STR$ String manipulation routines that perform such tasks as searching for substrings, concatenating strings, and prefixing and appending strings

**Table 13-2 Run-Time Library Facilities (OpenVMS)**
Facility Prefix	Types of Tasks Performed
CVT$	Library routines that handle floating-point data conversion
DTK$	DECtalk routines that are used to control a Compaq DECtalk device
LIB$	Library routines that: Obtain records from devices Manipulate strings Convert data types for I/O Allocate resources Obtain system information Signal exceptions Establish condition handlers Enable detection of hardware exceptions Process cross-reference data
MTH$	Mathematics routines that perform arithmetic, algebraic, and trigonometric calculations
OTS$	General-purpose routines that perform tasks such as data type conversions as part of a compiler's generated code
PPL$	Parallel processing routines that help you implement concurrent programs on single-CPU and multiprocessor systems
SMG$	Screen management routines that are used in designing, composing, and keeping track of complex images on a video screen
STR$	String manipulation routines that perform such tasks as searching for substrings, concatenating strings, and prefixing and appending strings

13.3.2 System Services

System services are prewritten system routines that perform a variety of tasks, such as controlling processes, communicating among processes, and coordinating I/O.

Unlike the Run-Time Library routines, which are divided into groups by facility, all system services share the same facility prefix (SYS$ on OpenVMS Alpha or SYS_ on Tru64 UNIX). However, these services are logically divided into groups that perform similar tasks. Table 13-3 describes these groups.

Table 13-3 System Services (OpenVMS)
Group Types of Tasks Performed

AST Allows processes to control the handling of asynchronous system traps

Change Mode Changes the access mode of particular routines

Condition Handling Designates condition handlers for special purposes

Event Flag Clears, sets, reads, and waits for event flags, and associates with event flag clusters

Information Returns information about the system, queues, jobs, processes, locks, and devices

Input/Output Performs I/O directly, without going through RMS

Lock Management Enables processes to coordinate access to shareable system resources

Logical Names Provides methods of accessing and maintaining pairs of character-string logical names and equivalence names

Memory Management Increases or decreases available virtual memory, controls paging and swapping, and creates and accesses shareable files of code or data

Process Control Creates, deletes, and controls execution of processes

Security Enhances the security of OpenVMS Alpha systems

Timer and Time Conversion Schedules events and obtains and formats binary time values

**Table 13-3 System Services (OpenVMS)**
Group	Types of Tasks Performed
AST	Allows processes to control the handling of asynchronous system traps
Change Mode	Changes the access mode of particular routines
Condition Handling	Designates condition handlers for special purposes
Event Flag	Clears, sets, reads, and waits for event flags, and associates with event flag clusters
Information	Returns information about the system, queues, jobs, processes, locks, and devices
Input/Output	Performs I/O directly, without going through RMS
Lock Management	Enables processes to coordinate access to shareable system resources
Logical Names	Provides methods of accessing and maintaining pairs of character-string logical names and equivalence names
Memory Management	Increases or decreases available virtual memory, controls paging and swapping, and creates and accesses shareable files of code or data
Process Control	Creates, deletes, and controls execution of processes
Security	Enhances the security of OpenVMS Alpha systems
Timer and Time Conversion	Schedules events and obtains and formats binary time values

13.4 Calling Routines

The basic steps for calling routines are the same whether you are calling a routine (subprogram) written in COBOL, a routine written in some other language, a system service, or a Run-Time Library routine. There are five steps required to call any system routine:

Determining the type of call
Defining the arguments
Calling the routine or service
Checking the condition value, if applicable
Locating the result

The following sections outline the steps for calling non-COBOL routines.

13.4.1 Determining the Type of Call (OpenVMS)

Before you call an external routine, you must first determine whether the call should be a procedure call or a function call. In COBOL, a routine that does not return a value should be called as a procedure call. A routine that returns a value should be called as a function call. Thus, a function call returns one of the following:

A function value (a COMP integer, COMP-1, or COMP-2 number). For example, on OpenVMS Alpha the call LIB$INDEX returns an integer value.
A return status, which is a longword (PIC 9(5) to 9(9) USAGE IS COMP) condition value that indicates the program has either successfully executed or failed. For example, on OpenVMS Alpha, LIB$GET_INPUT returns a return status.

Although you can call most system routines as a procedure call, it is recommended that you do so only when the system routine does not return a value. By checking the condition value, you can avoid errors.

The OpenVMS Alpha documentation on system services and Run-Time Library routines contains descriptions of each system routine and a description of the condition values returned. For example, the RETURNS section for the system routine LIB$STAT_TIMER follows:

RETURNS

OpenVMS usage:
type:
access:
mechanism: cond_value
longword (unsigned)
write only
by value

Because LIB$STAT_TIMER returns a value, it should be called as a function. If a system routine contains the following description under the RETURNS section, you should call the system routine as a procedure call:

RETURNS

None.

13.4.2 Defining the Argument (OpenVMS)

Most system routines have one or more arguments. These arguments are used to pass information to the system routine and to obtain information from it. Arguments can be either required or optional, and each argument has the following characteristics:

Access type (read, write, modify...)
Data type (floating point, longword...)
Passing mechanisms (by value, by reference, by descriptor...)
Argument form (scalar, array, string... )

To determine which arguments are required by a routine, check the format description of the routine in the OpenVMS documentation on system services or Run-Time Library routines. For example, the format for LIB$STAT_TIMER is as follows:

LIB$STAT_TIMER code ,value-argument [,handle-address]

The handle-address argument appears in square brackets ([]), indicating that it is an optional argument. Hence, when you call the system routine LIB$STAT_TIMER, only the first two arguments are required.

Once you have determined which arguments you need, read the argument description for information on how to call that system routine. For example, the system routine LIB$STAT_TIMER provides the following description of the code argument:

code

OpenVMS Usage:
type:
access:
mechanism: longword_signed
longword integer (signed)
read only
by reference

Code that specifies the statistic to be returned. The code argument contains the address of a signed longword integer that is this code. It must be an integer from 1 to 5.

After you check the argument description, refer to Table 13-4 for the COBOL equivalent of the argument description. For example, the code argument description lists the OpenVMS Alpha usage entry longword_signed. To define the code argument, use the COBOL equivalent of longword_signed:

01 LWS PIC S9(9) COMP.

Follow the same procedure for the value argument. The description of value contains the following information:

value-argument

OpenVMS Usage:
type:
access:
mechanism: user_arg
longword (unsigned)
write only
by reference

The statistic returned by LIB$STAT_TIMER. The value-argument argument contains the address of a longword or quadword that is this statistic. All statistics are longword integers except elapsed time, which is a quadword.

For the value-argument argument, the OpenVMS Alpha usage, user_arg, indicates that the data type returned by the routine is dependent on other factors. In this case, the data type returned is dependent upon which statistic you want to return. For example, if the statistic you want to return is code 5, page fault count, you must use a signed longword integer. Refer to Table 13-4 to find the following definition for a longword_signed:

01 LWS PIC S9(9) COMP.

Regardless of which Run-Time Library routine or system service you call, you can find the definition statements for the arguments in the OpenVMS Alpha usage in Table 13-4.

13.4.3 Calling the External Routine (OpenVMS)

Once you have decided which routine you want to call, you can access the routine using the CALL statement. You set up the call to the routine or service the same way you set up any call in COBOL. To determine the syntax of the CALL statement for a function call or a procedure call, see the Compaq COBOL Reference Manual, and refer to the examples in this chapter.

Remember, you must specify the name of the routine being called and all parameters required for that routine. Make sure the data types and passing mechanisms for the parameters you are passing coincide with those defined in the routine.

13.4.4 Calling System Routines (OpenVMS)

The basic steps for calling system routines are the same as those for calling any routine. However, when calling system routines, you need to provide some additional information discussed in the following sections.

13.4.4.1 System Routine Arguments (OpenVMS)

All OpenVMS Alpha system routine arguments are described in terms of the following information:

OpenVMS Alpha usage
Data type
Type of access allowed
Passing mechanism

OpenVMS Alpha usages are data structures layered on the standard OpenVMS Alpha data types. For example, the OpenVMS Alpha usage mask_longword signifies an unsigned longword integer used as a bit mask, and the OpenVMS Alpha usage floating_point represents any OpenVMS Alpha floating-point data type. Table 13-4 lists the OpenVMS Alpha usages and the COBOL statements you need to implement them.

Table 13-4 COBOL Implementation of the OpenVMS Alpha Data Types (OpenVMS)
OpenVMS Alpha Data Type COBOL Definition

access_bit_names NA ... PIC X(128). ¹

access_mode NA ... PIC X. ¹
access_mode is usually passed BY VALUE
as PIC 9(9) COMP.

address USAGE POINTER.

address_range 01 ADDRESS-RANGE.
02 BEGINNING-ADDRESS USAGE POINTER.
02 ENDING-ADDRESS USAGE POINTER.

arg_list NA ... Constructed by the compiler as a result of using the COBOL CALL statement. An argument list may be created as follows, but may not be referenced by the COBOL CALL statement.

01 ARG-LIST.
02 ARG-COUNT PIC S9(9) COMP.
02 ARG-BY-VALUE PIC S9(9) COMP.
02 ARG-BY-REFERENCE USAGE POINTER
02 VALUE REFERENCE ARG-NAME.
... continue as needed

ast_procedure 01 AST-PROC PIC 9(9) COMP. ²

boolean 01 BOOLEAN-VALUE PIC 9(9) COMP. ²

byte_signed NA ... PIC X. ¹

byte_unsigned NA ... PIC X. ¹

channel 01 CHANNEL PIC 9(4) COMP. ²

char_string 01 CHAR-STRING PIC X to PIC X(65535).

complex_number NA ... PIC X(n) where n is length. ¹

cond_value 01 COND-VALUE PIC 9(9) COMP. ²

context 01 CONTEXT PIC 9(9) COMP. ²

date_time NA ... PIC X(8). ¹

device_name 01 DEVICE-NAME PIC X(n) where n is length.

d_floating 01 D-FLOAT USAGE COMP-2.
(when /FLOAT=D_FLOAT)

ef_cluster_name 01 CLUSTER-NAME PIC X(n) where n is length.

ef_number 01 EF-NO PIC 9(9) COMP. ²

exit_handler_block NA ... PIC X(n) where n is length. ¹

fab NA ... Too complex for general COBOL use. Most of a FAB structure can be described by a lengthy COBOL record description, but such a FAB cannot then be referenced by a COBOL I-O statement. It is much simpler to do the
I-O completely within COBOL, and let the COBOL compiler generate the FAB structure, or do the I-O in another language.

file_protection 01 FILE-PROT PIC 9(4) COMP. ²

function_code 01 FUNCTION-CODE.
02 MAJOR-FUNCTION PIC 9(4) COMP. ²
02 SUB-FUNCTION PIC 9(4) COMP. ²

f_floating 01 F-FLOAT USAGE COMP-1.
(when /FLOAT=D_FLOAT or /FLOAT=G_FLOAT)

g_floating 01 G-FLOAT USAGE COMP-2.
(when /FLOAT=G_FLOAT)

identifier 01 ID PIC 9(9) COMP. ²

io_status_block 01 IOSB.
02 COND-VAL PIC 9(4) COMP. ²
02 BYTE-CNT PIC 9(4) COMP. ²
02 DEV-INFO PIC 9(9) COMP. ²

item_list_2 01 ITEM-LIST-TWO.
02 ITEM-LIST OCCURS n TIMES.
04 COMP-LENGTH PIC S9(4) COMP.
04 ITEM-CODE PIC S9(4) COMP.
04 COMP-ADDRESS PIC S9(9) COMP.
02 TERMINATOR PIC S9(9) COMP VALUE 0.

item_list_3 01 ITEM-LIST-3.
02 ITEM-LIST OCCURS n TIMES.
04 BUF-LEN PIC S9(4) COMP.
04 ITEM-CODE PIC S9(4) COMP.
04 BUFFER-ADDRESS PIC S9(9) COMP.
04 LENGTH-ADDRESS PIC S9(9) COMP.
02 TERMINATOR PIC S9(9) COMP VALUE 0.

item_list_pair 01 ITEM-LIST-PAIR.
02 ITEM-LIST OCCURS n TIMES.
04 ITEM-CODE PIC S9(9) COMP.
04 ITEM-VALUE PIC S9(9) COMP.
02 TERMINATOR PIC S9(9) COMP VALUE 0.

item_quota_list NA

lock_id 01 LOCK-ID PIC 9(9) COMP. ²

lock_status_block NA

lock_value_block NA

logical_name 01 LOG-NAME PIC X TO X(255).

longword_signed 01 LWS PIC S9(9) COMP.

longword_unsigned 01 LWU PIC 9(9) COMP. ²

mask_byte NA ... PIC X. ¹

mask_longword 01 MLW PIC 9(9) COMP. ²

mask_quadword 01 MQW PIC 9(18) COMP. ²

mask_word 01 MW PIC 9(4) COMP. ²

null_arg CALL ... USING OMITTED or
PIC S9(9) COMP VALUE 0
passed USING BY VALUE.

octaword_signed NA

octaword_unsigned NA

page_protection 01 PAGE-PROT PIC 9(9) COMP. ²

procedure 01 ENTRY-MASK PIC 9(9) COMP. ²

process_id 01 PID PIC 9(9) COMP. ²

process_name 01 PROCESS-NAME PIC X TO X(15).

quadword_signed 01 QWS PIC S9(18) COMP.

quadword_unsigned 01 QWU PIC 9(18) COMP. ²

rights_holder 01 RIGHTS-HOLDER.
02 RIGHTS-ID PIC 9(9) COMP. ²
02 ACCESS-RIGHTS PIC 9(9) COMP. ²

rights_id 01 RIGHTS-ID PIC 9(9) COMP. ²

rab NA ... Too complex for general COBOL use. Most of a RAB structure can be described by a lengthy COBOL record description, but such a RAB cannot then be referenced by a COBOL I-O statement. It is much simpler to do the I-O completely within COBOL, and let the COBOL compiler generate the RAB structure, or do the I-O in another language.

section_id 01 SECTION-ID PIC 9(18) COMP. ²

section_name 01 SECTION-NAME PIC X to X(43).

system_access_id 01 SECTION-ACCESS-ID PIC 9(18) COMP. ²

s_floating 01 S-FLOAT USAGE COMP-1.
(when /FLOAT=IEEE_FLOAT)

time_name 01 TIME-NAME PIC X(n) where n is the length.

t_floating 01 T-FLOAT USAGE COMP-2.
(when /FLOAT=IEEE_FLOAT )

uic 01 UIC PIC 9(9) COMP. ²

user_arg 01 USER-ARG PIC 9(9) COMP. ²

varying_arg Dependent upon application.

vector_byte_signed NA ... ³

vector_byte_unsigned NA ... ³

vector_longword_signed NA ... ³

vector_longword_unsigned NA ... ³

vector_quadword_signed NA ... ³

vector_quadword_unsigned NA ... ³

vector_word_signed NA ... ³

vector_word_unsigned NA ... ³

word_signed 01 WS PIC S9(4) COMP.

word_unsigned 01 WS PIC 9(4) COMP. ²

**Table 13-4 COBOL Implementation of the OpenVMS Alpha Data Types (OpenVMS)**
OpenVMS Alpha Data Type	COBOL Definition
access_bit_names	NA ... PIC X(128). ¹
access_mode	NA ... PIC X. ¹ access_mode is usually passed BY VALUE as PIC 9(9) COMP.
address	USAGE POINTER.
address_range	01 ADDRESS-RANGE. 02 BEGINNING-ADDRESS USAGE POINTER. 02 ENDING-ADDRESS USAGE POINTER.
arg_list	NA ... Constructed by the compiler as a result of using the COBOL CALL statement. An argument list may be created as follows, but may not be referenced by the COBOL CALL statement. 01 ARG-LIST. 02 ARG-COUNT PIC S9(9) COMP. 02 ARG-BY-VALUE PIC S9(9) COMP. 02 ARG-BY-REFERENCE USAGE POINTER 02 VALUE REFERENCE ARG-NAME. ... continue as needed
ast_procedure	01 AST-PROC PIC 9(9) COMP. ²
boolean	01 BOOLEAN-VALUE PIC 9(9) COMP. ²
byte_signed	NA ... PIC X. ¹
byte_unsigned	NA ... PIC X. ¹
channel	01 CHANNEL PIC 9(4) COMP. ²
char_string	01 CHAR-STRING PIC X to PIC X(65535).
complex_number	NA ... PIC X(n) where n is length. ¹
cond_value	01 COND-VALUE PIC 9(9) COMP. ²
context	01 CONTEXT PIC 9(9) COMP. ²
date_time	NA ... PIC X(8). ¹
device_name	01 DEVICE-NAME PIC X(n) where n is length.
d_floating	01 D-FLOAT USAGE COMP-2. (when /FLOAT=D_FLOAT)
ef_cluster_name	01 CLUSTER-NAME PIC X(n) where n is length.
ef_number	01 EF-NO PIC 9(9) COMP. ²
exit_handler_block	NA ... PIC X(n) where n is length. ¹
fab	NA ... Too complex for general COBOL use. Most of a FAB structure can be described by a lengthy COBOL record description, but such a FAB cannot then be referenced by a COBOL I-O statement. It is much simpler to do the I-O completely within COBOL, and let the COBOL compiler generate the FAB structure, or do the I-O in another language.
file_protection	01 FILE-PROT PIC 9(4) COMP. ²
function_code	01 FUNCTION-CODE. 02 MAJOR-FUNCTION PIC 9(4) COMP. ² 02 SUB-FUNCTION PIC 9(4) COMP. ²
f_floating	01 F-FLOAT USAGE COMP-1. (when /FLOAT=D_FLOAT or /FLOAT=G_FLOAT)
g_floating	01 G-FLOAT USAGE COMP-2. (when /FLOAT=G_FLOAT)
identifier	01 ID PIC 9(9) COMP. ²
io_status_block	01 IOSB. 02 COND-VAL PIC 9(4) COMP. ² 02 BYTE-CNT PIC 9(4) COMP. ² 02 DEV-INFO PIC 9(9) COMP. ²
item_list_2	01 ITEM-LIST-TWO. 02 ITEM-LIST OCCURS n TIMES. 04 COMP-LENGTH PIC S9(4) COMP. 04 ITEM-CODE PIC S9(4) COMP. 04 COMP-ADDRESS PIC S9(9) COMP. 02 TERMINATOR PIC S9(9) COMP VALUE 0.
item_list_3	01 ITEM-LIST-3. 02 ITEM-LIST OCCURS n TIMES. 04 BUF-LEN PIC S9(4) COMP. 04 ITEM-CODE PIC S9(4) COMP. 04 BUFFER-ADDRESS PIC S9(9) COMP. 04 LENGTH-ADDRESS PIC S9(9) COMP. 02 TERMINATOR PIC S9(9) COMP VALUE 0.
item_list_pair	01 ITEM-LIST-PAIR. 02 ITEM-LIST OCCURS n TIMES. 04 ITEM-CODE PIC S9(9) COMP. 04 ITEM-VALUE PIC S9(9) COMP. 02 TERMINATOR PIC S9(9) COMP VALUE 0.
item_quota_list	NA
lock_id	01 LOCK-ID PIC 9(9) COMP. ²
lock_status_block	NA
lock_value_block	NA
logical_name	01 LOG-NAME PIC X TO X(255).
longword_signed	01 LWS PIC S9(9) COMP.
longword_unsigned	01 LWU PIC 9(9) COMP. ²
mask_byte	NA ... PIC X. ¹
mask_longword	01 MLW PIC 9(9) COMP. ²
mask_quadword	01 MQW PIC 9(18) COMP. ²
mask_word	01 MW PIC 9(4) COMP. ²
null_arg	CALL ... USING OMITTED or PIC S9(9) COMP VALUE 0 passed USING BY VALUE.
octaword_signed	NA
octaword_unsigned	NA
page_protection	01 PAGE-PROT PIC 9(9) COMP. ²
procedure	01 ENTRY-MASK PIC 9(9) COMP. ²
process_id	01 PID PIC 9(9) COMP. ²
process_name	01 PROCESS-NAME PIC X TO X(15).
quadword_signed	01 QWS PIC S9(18) COMP.
quadword_unsigned	01 QWU PIC 9(18) COMP. ²
rights_holder	01 RIGHTS-HOLDER. 02 RIGHTS-ID PIC 9(9) COMP. ² 02 ACCESS-RIGHTS PIC 9(9) COMP. ²
rights_id	01 RIGHTS-ID PIC 9(9) COMP. ²
rab	NA ... Too complex for general COBOL use. Most of a RAB structure can be described by a lengthy COBOL record description, but such a RAB cannot then be referenced by a COBOL I-O statement. It is much simpler to do the I-O completely within COBOL, and let the COBOL compiler generate the RAB structure, or do the I-O in another language.
section_id	01 SECTION-ID PIC 9(18) COMP. ²
section_name	01 SECTION-NAME PIC X to X(43).
system_access_id	01 SECTION-ACCESS-ID PIC 9(18) COMP. ²
s_floating	01 S-FLOAT USAGE COMP-1. (when /FLOAT=IEEE_FLOAT)
time_name	01 TIME-NAME PIC X(n) where n is the length.
t_floating	01 T-FLOAT USAGE COMP-2. (when /FLOAT=IEEE_FLOAT )
uic	01 UIC PIC 9(9) COMP. ²
user_arg	01 USER-ARG PIC 9(9) COMP. ²
varying_arg	Dependent upon application.
vector_byte_signed	NA ... ³
vector_byte_unsigned	NA ... ³
vector_longword_signed	NA ... ³
vector_longword_unsigned	NA ... ³
vector_quadword_signed	NA ... ³
vector_quadword_unsigned	NA ... ³
vector_word_signed	NA ... ³
vector_word_unsigned	NA ... ³
word_signed	01 WS PIC S9(4) COMP.
word_unsigned	01 WS PIC 9(4) COMP. ²

¹Most OpenVMS Alpha data types not directly supported in COBOL can be represented as an alphanumeric data item of a certain number of bytes. While COBOL does not interpret the data type, it may be used to pass objects from one language to another.
²Although unsigned computational data structures are not directly supported in COBOL, you may substitute the signed equivalent provided you do not exceed the range of the signed data structure.
³COBOL does not permit the passing of variable-length data structures.

Contents

Index

code
OpenVMS Usage: type: access: mechanism:	longword_signed longword integer (signed) read only by reference

value-argument
OpenVMS Usage: type: access: mechanism:	user_arg longword (unsigned) write only by reference

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13.2.2 Return of the Function Value

Compaq COBOL
User Manual