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| Document revision date: 15 July 2002 | |
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The following is a description of the callable interface to LDR$UNLOAD_IMAGE.
Unloads a removable executive image. This routine is called to unload an execlet. All resources are returned.Module
SYSLDR_DYN
LDR$UNLOAD_IMAGE filename ,ref_handle
Contextfilename
OpenVMS usage character string type character string access read only mechanism by descriptor
The longword address of a character string descriptor containing the file name of the executive image to be unloaded. The file name must be supplied exactly as it was supplied to LDR$LOAD_IMAGE when the executive image was loaded.ref_handle
OpenVMS usage address type longword (signed) access read only mechanism by reference
The longword address of the reference handle containing the three-longword block returned by LDR$LOAD_IMAGE when the executive image was loaded.
LDR$UNLOAD_IMAGE must be called in kernel mode.
OpenVMS usage cond_value type longword (unsigned) access write only mechanism by value
Status indicating the success or failure of the operation.
SS$_INSFARG LDR$UNLOAD_IMAGE was not called with two parameters. SS$_BADPARAMS Reference handle data inconsistent with LDRIMG block that matches the name in the first argument. LOADER$_MARKUNL A call was made to the LDR$UNLOAD_IMAGE routine to unload a removable executive image that already has an outstanding unload request against it. SS$_NOPRIV LDR$UNLOAD_IMAGE was not called in kernel mode. SS$_NORMAL Executive image was successfully removed from the system. LOADER$_NOT_UNL A call was made to LDR$UNLOAD_IMAGE to unload an executive image that is not loaded or that was not loaded with the LDR$V_UNL flag bit set. LOADER$_UNL_PEN A call was made to LDR$UNLOAD_IMAGE to unload an executive image that is in use. The image is marked to be unloaded later.
LDR$UNLOAD_IMAGE removes an executive image from system space and returns all memory resources allocated when the image was loaded. Images can only be removed if they were originally loaded with the bit LDR$V_UNL set in the input flags to LDR$LOAD_IMAGE.
You can synchronize timed program execution in the following ways:
The process control procedures that allow you to synchronize timed program execution require you to supply a system time value.
You can use either system services or RTL routines for obtaining and reading time. They are summarized in Table 4-10. With these routines, you can determine the system time, convert it to an external time, and pass a time back to the system. The system services use the operating system's default date format. With the RTL routines, you can use the default format or specify your own date format. However, if you are just using the time and date for program synchronization, using the operating system's default format is probably sufficient.
When using the RTL routines to change date/time formats, initialization routines are required. Refer to the OpenVMS RTL Library (LIB$) Manual for more information.
See Chapter 27 for a further discussion of using timing operations with the operating system.
| Routine | Description |
|---|---|
| SYS$GETTIM | Obtains the current date and time in 64-bit binary format |
| SYS$NUMTIM | Converts system date and time to numeric integer values |
| SYS$ASCTIM | Converts an absolute or delta time from 64-bit system time format to an ASCII string |
| SYS$ASCUTC | Converts an absolute time from 128-bit Coordinated Universal Time (UTC) format to an ASCII string |
| LIB$SYS_ASCTIM | Converts binary time to an ASCII string |
| SYS$BINTIM | Converts a date and time from ASCII to system format |
| SYS$BINUTC | Converts an ASCII string to an absolute time value in the 128-bit UTC format |
| SYS$FAO | Converts a binary value into an ASCII character string in decimal, hexadecimal, or octal notation and returns the character string in an output string |
| SYS$GETUTC | Returns the current time in 128-bit UTC format |
| SYS$NUMUTC | Converts an absolute 128-bit binary time into its numeric components. The numeric components are returned in local time |
| SYS$TIMCON | Converts 128-bit UTC to 64-bit system format or 64-bit system format to 128-bit UTC based on the value of the convert flag |
| LIB$ADD_TIMES | Adds two quadword times |
| LIB$CONVERT_DATE_STRING | Converts an input date/time string to an operating system internal time |
| LIB$CVT_FROM_INTERNAL_TIME | Converts internal time to external time |
| LIB$CVTF_FROM_INTERNAL_TIME | Converts internal time to external time (F-floating value) |
| LIB$CVT_TO_INTERNAL_TIME | Converts external time to internal time |
| LIB$CVTF_TO_INTERNAL_TIME | Converts external time to internal time (F-floating value) |
| LIB$CVT_VECTIM | Converts 7-word vector to internal time |
| LIB$DAY | Obtains offset to current day from base time, in number of days |
| LIB$DATE_TIME | Obtains the date and time in user-specified format |
| LIB$FORMAT_DATE_TIME | Formats a date and/or time for output |
| LIB$FREE_DATE_TIME_CONTEXT | Frees date/time context |
| LIB$GET_DATE_FORMAT | Returns the user's specified date/time input format |
| LIB$GET_MAXIMUM_DATE_LENGTH | Returns the maximum possible length of an output date/time string |
| LIB$GET_USERS_LANGUAGE | Returns the user's selected langauge |
| LIB$INIT_DATE_TIME_CONTEXT | Initializes the date/time context with a user-specified format |
| LIB$SUB_TIMES | Subtracts two quadword times |
To execute a program at a specified time, use LIB$SPAWN to create a process that executes a command procedure containing two commands---the DCL command WAIT and the command that invokes the desired program. Because you do not want the parent process to remain in hibernation until the process executes, execute the process concurrently.
You can also use the SYS$CREPRC system service to execute a program at a specified time. However, because a process created by SYS$CREPRC hibernates rather than terminates after executing the desired program, Compaq recommends you use the LIB$SPAWN routine unless you need a detached process.
Example 4-14 executes a program at a specified delta time. The parent program prompts the user for a delta time, equates the delta time to the symbol EXECUTE_TIME, and then creates a subprocess to execute the command procedure LATER.COM. LATER.COM uses the symbol EXECUTE_TIME as the parameter for the WAIT command. (You might also allow the user to enter an absolute time and have your program change it to a delta time by subtracting the current time from the specified time. Chapter 27 discusses time manipulation.)
| Example 4-14 Executing a Program Using Delta Time | |||
|---|---|---|---|
! Delta time
CHARACTER*17 TIME
INTEGER LEN
! Mask for LIB$SPAWN
INTEGER*4 MASK
! Declare status and library routine
INTEGER STATUS, LIB$SPAWN
! Get delta time
STATUS = LIB$GET_INPUT (TIME,
2 'Time (delta): ',
2 LEN)
IF (.NOT. STATUS) CALL LIB$SIGNAL (%VAL (STATUS))
! Equate symbol to TIME
STATUS = LIB$SET_SYMBOL ('EXECUTE_TIME',
2 TIME(1:LEN))
IF (.NOT. STATUS) CALL LIB$SIGNAL (%VAL (STATUS))
! Set the mask and call LIB$SPAWN
MASK = IBSET (MASK,0) ! Execute subprocess concurrently
STATUS = LIB$SPAWN('@LATER',
2 'DATA84.IN',
2 'DATA84.RPT',
2 MASK)
END
|
LATER.COM
$ WAIT 'EXECUTE_TIME' $ RUN SYS$DRIVE0:[USER.MATH]CALC $ DELETE/SYMBOL EXECUTE_TIME |
To execute a program at timed intervals, you can use either LIB$SPAWN or SYS$CREPRC.
Using LIB$SPAWN, you can create a subprocess that executes a command procedure containing three commands: the DCL command WAIT, the command that invokes the desired program, and a GOTO command that directs control back to the WAIT command. Because you do not want the parent process to remain in hibernation until the subprocess executes, execute the subprocess concurrently. See Section 4.8.1.1 for an example of LIB$SPAWN.
Using SYS$CREPRC, create a detached process to execute a program at timed intervals as follows:
Example 4-15 executes a program at timed intervals. The program creates a subprocess that immediately hibernates. (The identification number of the created subprocess is returned to the parent process so that it can be passed to SYS$SCHDWK.) The system wakes up the subprocess at 6:00 a.m. on the 23rd (month and year default to system month and year) and every 10 minutes thereafter.
| Example 4-15 Executing a Program at Timed Intervals | |||
|---|---|---|---|
! SYS$CREPRC options and values
INTEGER OPTIONS
EXTERNAL PRC$V_HIBER
! ID of created subprocess
INTEGER CR_ID
! Binary times
INTEGER TIME(2),
2 INTERVAL(2)
.
.
.
! Set the PRC$V_HIBER bit in the OPTIONS mask and
! create the process
OPTIONS = IBSET (OPTIONS, %LOC(PRC$V_HIBER))
STATUS = SYS$CREPRC (CR_ID, ! PID of created process
2 'CHECK', ! Image
2 ,,,,,
2 'SLEEP', ! Process name
2 %VAL(4), ! Priority
2 ,,
2 %VAL(OPTIONS)) ! Hibernate
IF (.NOT. STATUS) CALL LIB$SIGNAL (%VAL(STATUS))
! Translate 6:00 a.m. (absolute time) to binary
STATUS = SYS$BINTIM ('23-- 06:00:00.00', ! 6:00 a.m.
2 TIME)
IF (.NOT. STATUS) CALL LIB$SIGNAL (%VAL(STATUS))
! Translate 10 minutes (delta time) to binary
STATUS = SYS$BINTIM ('0 :10:00.00', ! 10 minutes
2 INTERVAL)
IF (.NOT. STATUS) CALL LIB$SIGNAL (%VAL(STATUS))
! Schedule wakeup calls
STATUS = SYS$SCHDWK (CR_ID, ! ID of created process
2 ,
2 TIME, ! Initial wakeup time
2 INTERVAL) ! Repeat wakeup time
IF (.NOT. STATUS) CALL LIB$SIGNAL (%VAL(STATUS))
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When you use the system timer queue, you use the timer expiration to signal when a routine is to be executed. It allows the caller to request a timer that will activate sometime in the future. The timer is requested for the calling kernel thread. When the timer activates, the event is reported to that thread. It does not affect any other thread in the process.
For the actual signal, you can use an event flag or AST. With this method, you do not need a separate process to control program execution. However, you do use up your process's quotas for ASTs and timer queue requests.
Use the system service SYS$SETIMR to place a request in the system timer queue. The format of this service is as follows:
|
SYS$SETIMR ([efn] ,daytim ,[astadr] ,[reqidt] ,[flags]) |
Specify the absolute or delta time at which you want the program to begin execution using the daytim argument. Use the SYS$BINTIM system service to convert an ASCII time to the binary system format required for this argument.
Once the system has reached this time, the timer expires. To signal timer expiration, set an event flag in the efn argument or specify an AST routine to be executed in the astadr argument. Refer to Section 6.6 and Chapter 8 for more information about using event flags and ASTs.
How Timer Requests Are Identified
The reqidt argument identifies each system time request uniquely. Then, if you need to cancel a request, you can refer to each request separately.
To cancel a timer request, use the SYS$CANTIM system service.
4.9 Controlling Kernel Threads and Process Execution
You can control kernel threads and process execution in the following ways:
There are two ways to halt the execution of a kernel thread or process temporarily:
The kernel thread can continue execution normally only after a corresponding Wake from Hibernation (SYS$WAKE) system service (if it is hibernating), or after a Resume Process (SYS$RESUME) system service, if it is suspended.
Suspending or hibernating a kernel thread puts it into a dormant state; the thread is not deleted.
A process in hibernation can control itself; a process in suspension requires another process to control it. Table 4-11 compares hibernating and suspended processes.
| Hibernation | Suspension |
|---|---|
| Can cause only self to hibernate. | Can suspend self or another process, depending on privilege; suspends all threads associated with the specified process. |
| Reversed by SYS$WAKE/SYS$SCHDWK system service. | Reversed by SYS$RESUME system service. |
| Interruptible; can receive ASTs. | Noninterruptible; cannot receive ASTs 1. |
| Can wake self. | Cannot cause self to resume. |
| Can schedule wake up at an absolute time or at a fixed time interval. | Cannot schedule resumption. |
Table 4-12 summarizes the system services and routines that can place a process in or remove a process from hibernation or suspension.
| Routine | Function |
|---|---|
| Hibernating Processes | |
| SYS$HIBER | Places the requesting kernel thread in the hibernation state. An AST can be delivered to the thread while it is hibernating. The service puts only the calling thread into HIB; no other thread is affected. |
| SYS$WAKE | Resumes execution of a kernel thread in hibernation. This service wakes all hibernating kernel threads in a process regardless of the caller. Any thread that is not hibernating when the service is called is marked wake pending. Because of the wake pending, the next call to SYS$HIBER completes immediately and the thread does not hibernate. Premature wakeups must be handled in the code. |
| SYS$SCHDWK | Resumes execution of a kernel thread in hibernation at a specified time. This service schedules a wakeup request for a thread that is about to call SYS$HIBER. The wakeup affects only the requesting thread; any other hibernating kernel threads are not affected. |
| LIB$WAIT | Uses the services SYS$SCHDWK and SYS$HIBER. |
| SYS$CANWAK | Cancels a scheduled wakeup issued by SYS$SCHDWK. Unless called with a specific timer request ID, this service cancels all timers for all threads in the process regardless of the calling thread. |
| Suspended Kernel Threads and Processes | |
| SYS$SUSPEND | Puts in a suspended state all threads associated with the specified process. |
| SYS$RESUME | Puts in an execution state all threads of the specified process. |
The hibernate/wake mechanism provides an efficient way to prepare an image for execution and then to place it in a wait state until it is needed.
If you create a subprocess that must execute the same function repeatedly and must execute immediately when it is needed, you could use the SYS$HIBER and SYS$WAKE system services, as shown in the following example:
/* Process TAURUS */
#include <stdio.h>
#include <descrip.h>
main() {
unsigned int status;
$DESCRIPTOR(prcnam,"ORION");
$DESCRIPTOR(image,"COMPUTE.EXE");
/* Create ORION */
status = SYS$CREPRC(0, (1) /* Process id */
&image, /* Image */
0, 0, 0, 0, 0,
&prcnam, /* Process name */
0, 0, 0, 0);
if ((status & 1) != 1)
LIB$SIGNAL(status);
.
.
.
/* Wake ORION */
status = SYS$WAKE(0, &prcnam); (2)
if ((status & 1) != 1)
LIB$SIGNAL(status);
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/* Wake ORION again */
status = SYS$WAKE(0, &prcnam);
if ((status & 1) != 1)
LIB$SIGNAL(status);
.
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.
}
/* Process ORION and image COMPUTE */
#include <stdio.h>
#include <ssdef.h>
.
.
.
sleep:
status = SYS$HIBER(); (3)
if ((status & 1) != 1)
LIB$SIGNAL(status);
.
.
.
goto sleep;
}
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