Document revision date: 19 July 1999 | |
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On Alpha systems, when a process is executing an image, a subset of its pages resides in physical memory; these pages are called the working set of the process. The working set includes pages in both the program region and the control region. The initial size of a process's working set is defined by the process's working set default (WSDEFAULT) quota, which is specified in pagelets. When ample physical memory is available, a process's working-set upper growth limit can be expanded to its working set extent (WSEXTENT).
When the image refers to a page that is not in memory, a page fault occurs, and the page is brought into memory, possibly replacing an existing page in the working set. If the page that is going to be replaced is modified during the execution of the image, that page is written into a paging file on disk. When this page is needed again, it is brought back into memory, again replacing a current page from the working set. This exchange of pages between physical memory and secondary storage is called paging.
The paging of a process's working set is transparent to the process. However, if a program is very large or if pages in the program image that are used often are being paged in and out frequently, the overhead required for paging may decrease the program's efficiency. The SYS$ADJWSL, SYS$PURGWS, and SYS$LKWSET system services allow a process, within limits, to counteract these potential problems.
The Adjust Working Set Limit (SYS$ADJWSL) system service increases or decreases the maximum number of pages that a process can have in its working set. The format for this routine is as follows:
SYS$ADJWSL ([pagcnt],[wsetlm]) |
On Alpha systems, use the pagcnt argument to specify the number of pagelets to add or subtract from the current working set size. The Alpha system rounds the specified number of pagelets to a multiple of the system's page size. The new working set size is returned in wsetlm in units of pagelets.
The Purge Working Set (SYS$PURGWS) system service removes one or more pages from the working set.
The Lock Pages in Working Set (SYS$LKWSET) system service makes one or more pages in the working set ineligible for paging by locking them in the working set. Once locked into the working set, those pages remain in the working set until they are unlocked explicitly with the Unlock Pages in Working Set (SYS$ULWSET) system service, or program execution ends. The format is as follows:
SYS$LKWSET (inadr ,[retadr] ,[acmode]) |
Specifying a Range of Addresses
On Alpha systems, use the inadr argument to specify the range of addresses to be locked. SYS$LKWSET rounds the addresses to CPU-specific page boundaries, if necessary. The range of addresses of the pages actually locked are returned in the retadr argument.
However, because the Alpha system's instructions cannot contain full virtual addresses, the Alpha system's images must reference procedures and data indirectly through a pointer to a procedure descriptor. The procedure descriptor contains information about the procedure, including the actual code address. These pointers to procedure descriptors and data are collected into a program section called a linkage section. Therefore, it is not sufficient simply to lock a section of code into memory to improve performance. You must also lock the associated linkage section into the working set.
To lock the linkage section into memory, you must determine the start and end addresses that encompass the linkage section and pass these addresses as values in the inadr argument to a call to SYS$LKWSET. For more information about linking, see Migrating to an OpenVMS AXP System: Recompiling and Relinking Applications.
Use the acmode argument to specify the access mode to
be associated with the pages you want locked.
22.4.6 Process Swapping
The operating system balances the needs of all the processes currently executing, providing each with the system resources it requires on an as-needed basis. The memory management routines balance the memory requirements of the process. Thus, the sum of the working sets for all processes currently in physical memory is called the balance set.
When a process whose working set is in memory becomes inactive---for example, to wait for an I/O request or to hibernate---the entire working set or part of it may be removed from memory to provide space for another process's working set to be brought in for execution. This removal from memory is called swapping.
The working set may be removed in two ways:
When a process is swapped out of the balance set, all the pages (both modified and unmodified) of its working set are swapped, including any pages that had been locked in the working set.
A privileged process may lock itself in the balance set. While pages can still be paged in and out of the working set, the process remains in memory even when it is inactive. To lock itself in the balance set, the process issues the Set Process Swap Mode (SYS$SETSWM) system service, as follows:
$SETSWM_S SWPFLG=#1 |
This call to SYS$SETSWM disables process swap mode. You can also disable swap mode by setting the appropriate bit in the STSFLG argument to the Create Process (SYS$CREPRC) system service; however, you need the PSWAPM privilege to alter process swap mode.
A process can also lock particular pages in memory with the Lock Pages in Memory (SYS$LCKPAG) system service. These pages are forced into the process's working set if they are not already there. When pages are locked in memory with this service, the pages remain in memory even when the remainder of the process's working set is swapped out of the balance set. These remaining pages stay in memory until they are unlocked with SYS$ULKPAG. The SYS$LCKPAG system service can be useful in special circumstances, for example, for routines that perform I/O operations to devices without using the operating system's I/O system.
You need the PSWAPM privilege to issue the SYS$LCKPAG or SYS$ULKPAG
system service.
22.4.7 Sections
A section is a disk file or a portion of a disk file containing data or instructions that can be brought into memory and made available to a process for manipulation and execution. A section can also be one or more consecutive page frames in physical memory or I/O space; such sections, which require you to specify page frame number (PFN) mapping, are discussed in Chapter 21, Section 21.5.6.15.
Sections are either private or global (shared).
When modified pages in writable disk file sections are paged out of memory during image execution, they are written back into the section file rather than into the paging file, as is the normal case with files. (However, copy-on-reference sections are not written back into the section file.)
The use of disk file sections involves these two distinct operations:
The Create and Map Section (SYS$CRMPSC) system service creates and maps a private section or a global section. Because a private section is used only by a single process, creation and mapping are simultaneous operations. In the case of a global section, one process can create a permanent global section and not map to it; other processes can map to it. A process can also create and map a global section in one operation.
The following sections describe the creation, mapping, and use of disk
file sections. In each case, operations and requirements that are
common to both private sections and global sections are described
first, followed by additional notes and requirements for the use of
global sections. Section 22.4.7.9 discusses global page-file sections.
22.4.7.1 Creating Sections
To create a disk file section, you must follow these steps:
Before you can use a file as a section, you must open it using OpenVMS RMS. The following example shows the OpenVMS RMS file access block ($FAB) and $OPEN macros used to open the file and the channel specification to the SYS$CRMPSC system service necessary for reading an existing file:
SECFAB: $FAB FNM=<SECTION.TST>, ; File access block FOP=UFO RTV= -1 . . . $OPEN FAB=SECFAB $CRMPSC_S - CHAN=SECFAB+FAB$L_STV,... |
The file options parameter (FOP) indicates that the file is to be opened for user I/O; this option is required so that OpenVMS RMS assigns the channel using the access mode of the caller. OpenVMS RMS returns the channel number on which the file is accessed; this channel number is specified as input to the SYS$CRMPSC system service (chan argument). The same channel number can be used for multiple create and map section operations.
The option RTV= -1 tells the file system to keep all of the pointers to be mapped in memory at all times. If this option is omitted, the SYS$CRMPSC service requests the file system to expand the pointer areas if necessary. Storage for these pointers is charged to the BYTLM quota, which means that opening a badly fragmented file can fail with an EXBYTLM failure status. Too many fragmented sections may cause the byte limit to be exceeded.
The file may be a new file that is to be created while it is in use as a section. In this case, use the $CREATE macro to open the file. If you are creating a new file, the file access block (FAB) for the file must specify an allocation quantity (ALQ parameter).
You can also use SYS$CREATE to open an existing file; if the file does not exist, it is created. The following example shows the required fields in the FAB for the conditional creation of a file:
GBLFAB: $FAB FNM=<GLOBAL.TST>, - ALQ=4, - FAC=PUT,- FOP=<UFO,CIF,CBT>, - SHR=<PUT,UPI> . . . $CREATE FAB=GBLFAB |
When the $CREATE macro is invoked, it creates the file GLOBAL.TST if the file does not currently exist. The CBT (contiguous best try) option requests that, if possible, the file be contiguous. Although section files are not required to be contiguous, better performance can result if they are.
22.4.7.3 Defining the Section Extents
After the file is opened successfully, the SYS$CRMPSC system service
can create a section from the entire file or from only certain portions
of it. The following arguments to SYS$CRMPSC define the extents of the
file that comprise the section:
The flags argument to the SYS$CRMPSC system service defines the following section characteristics:
Table 22-3 shows the flag bits that must be set for specific characteristics on Alpha systems.
Section to Be Created | ||||
---|---|---|---|---|
Correct Flag Combinations |
Private | Global | PFN Private |
PFN Global |
SEC$M_GBL | 0 | 1 | 0 | 1 |
SEC$M_CRF | Optional | Optional | 0 | 0 |
SEC$M_DZRO | Optional | Optional | 0 | 0 |
SEC$M_WRT | Optional | Optional | Optional | Optional |
SEC$M_PERM | Not used | Optional | Not used | 1 |
SEC$M_SYSGBL | Not used | Optional | Not used | Optional |
SEC$M_PFNMAP | 0 | 0 | 1 | 1 |
SEC$M_EXPREG | Optional | Optional | Optional | Optional |
SEC$M_PAGFIL | 0 | Optional | 0 | 0 |
When you specify section characteristics, the following restrictions apply:
If the section is a global section, you must assign a character string name (gsdnam argument) to it so that other processes can identify it when they map it. The format of this character string name is explained in Section 22.4.7.6.
The flags argument specifies the following types of global section:
Group global sections can be shared only by processes executing with the same group number. The name of a group global section is implicitly qualified by the group number of the process that created it. When other processes map it, their group numbers must match.
A temporary global section is automatically deleted when no processes are mapped to it, but a permanent global section remains in existence even when no processes are mapped to it. A permanent global section must be explicitly marked for deletion with the Delete Global Section (SYS$DGBLSC) system service.
You need the user privileges PRMGBL and SYSGBL to create permanent group global sections or system global sections (temporary or permanent), respectively.
A system global section is available to all processes in the system.
Optionally, a process creating a global section can specify a
protection mask (prot argument) to restrict all access
or a type of access (read, write, execute, delete) to other processes.
22.4.7.6 Global Section Name
The gsdnam argument specifies a descriptor that points to a character string.
Translation of the gsdnam argument proceeds in the following manner:
For example, assume that you have made the following logical name assignment:
$ DEFINE GBL$GSDATA GSDATA_001 |
Your program contains the following statements:
#include <descrip.h> . . . $DESCRIPTOR(gsdnam,"GSDATA"); . . . status = sys$crmpsc(&gsdnam, ...); |
The following logical name translation takes place:
There are three exceptions to the logical name translation method discussed in this section:
When you call the SYS$CRMPSC system service to create or map a section, or both, you must provide the service with a range of virtual addresses (inadr argument) into which the section is to be mapped.
On Alpha systems, the inadr argument specifies the size and location of the section by its start and end addresses. SYS$CRMPSC interprets the inadr argument in the following ways:
On Alpha Systems, if you know specifically which pages the section should be mapped into, you provide these addresses in a 2-longword array. For example, to map a private section of 10 pages into virtual pages 10 through 19 of the program region, specify the input address array as follows:
unsigned int maprange[1]; /* Assume page size = 8 KB */ maprange[0] = 0x14000; /* Address (hex) of page 10 */ maprange[1] = 0x27FFF; /* Address (hex) of page 19 */ |
On Alpha systems, the inadr argument range must have a lower address on an even page boundary and a higher address exactly one less than a page boundary. You do this to avoid programming errors that might arise because of incorrect programming assumptions about page sizes. For example, the range can be expressed as the following on an 8 KB page system:
If the range is not expressed in terms of page-inclusive boundaries, then an SS$_INVARG condition value is returned.
You do not need to know the explicit addresses to provide an input address range. If you want the section mapped into the first available virtual address range in the program region (P0) or control region (P1), you can specify the SEC$M_EXPREG flag bit in the flags argument. In this case, the addresses specified by the inadr argument control whether the service finds the first available space in the P0 or P1. The value specified or defaulted for the pagcnt argument determines the amount of space mapped.
On Alpha systems, the relpag argument specifies the location in the section file at which you want mapping to begin.
On Alpha systems, the SYS$CRMPSC and SYS$MGBLSC system services map a minimum of one CPU-specific page. If the section file does not fill a single page, the remainder of the page is filled with zeros after faulting the page into memory. The extra space on the page should not be used by your application because only the data that fits into the section file will be written back to the disk.
The following example shows part of a program used to map a section at the current end of the program region:
unsigned int status, inadr[1], retadr[1], flags; /* This range used merely to indicate P0 space since SEC$M_EXPREG is specified */ inadr[0]= 0x200; /* Any program (P0) region address */ inadr[1]= 0x200; /* Any P0 address (can be same) */ . . . /* Address range returned in retadr */ flags = SEC$M_EXPREG; status = sys$crmpsc(&inadr, &retadr, flags, ...); |
The addresses specified do not have to be currently in the virtual address space of the process. The SYS$CRMPSC system service creates the required virtual address space during the mapping of the section. If you specify the retadr argument, the service returns the range of addresses actually mapped.
On Alpha systems, the starting retadr address should match inadr, plus relpag if specified. The ending (higher) address will be limited by the lower of:
After a section is mapped successfully, the image can refer to the pages using one of the following:
The following example shows part of a program used to create and map a process section on Alpha systems:
SECFAB: $FAB FNM=<SECTION.TST>, - FOP=UFO, - FAC=PUT, - SHR=<GET,PUT,UPI> ; MAPRANGE: .LONG ^X14000 ; First 8 KB page .LONG ^X27FFF ; Last page RETRANGE: .BLKL 1 ; First page mapped ENDRANGE: .BLKL 1 ; Last page mapped . . . $OPEN FAB=SECFAB ; Open section file BLBS R0,10$ BSBW ERROR 10$: $CRMPSC_S - INADR=MAPRANGE,- ; Input address array RETADR=RETRANGE,- ; Output array PAGCNT=#4,- ; Map four pagelets FLAGS=#SEC$M_WRT,- ; Read/write section CHAN=SECFAB+FAB$L_STV ; Channel number BLBS R0,20$ BSBW ERROR 20$: MOVL RETRANGE,R6 ; Point to start of section |
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