OpenVMS Alpha Guide to 64-Bit Addressing and VLM
Memory Management VLM Features
This chapter describes the following OpenVMS Alpha memory management
- Memory-resident global sections
- Fast I/O and buffer objects for global sections
- Shared page tables
- Expandable global page table
- Reserved memory registry
To see an example program that demonstrates many of these VLM features,
refer to Appendix D.
4.1 Overview of VLM Features
Memory-resident global sections allow a database
server to keep larger amounts of hot data cached in physical
memory. The database server then accesses the data directly from
physical memory without performing I/O read operations from the
database files on disk. With faster access to the data in physical
memory, runtime performance increases dramatically.
Fast I/O reduces CPU costs per I/O request, which
increases the performance of database operations. Fast I/O requires
data to be locked in memory through buffer objects. In
prior versions of OpenVMS Alpha, buffer objects could be created only
for process-private virtual address space. As of OpenVMS Alpha 7.2,
buffer objects can be created for global pages, including pages in
Shared page tables allow that same database server to
reduce the amount of physical memory consumed within the system.
Because multiple server processes share the same physical page tables
that map the large database cache, an OpenVMS Alpha system can support
more server processes. This increases overall system capacity and
decreases response time to client requests.
Shared page tables dramatically reduce the database server startup time
because server processes can map memory-resident global sections
hundreds of times faster than traditional global sections. With a
multiple gigabyte global database cache, the server startup performance
gains can be significant.
The system parameters GBLPAGES and
GBLPAGFIL are dynamic parameters. Users with the
CMKRNL privilege can now change these parameter values on a running
system. Increasing the value of the GBLPAGES parameter allows the
global page table to expand, on demand, up to the new maximum size.
The Reserved Memory Registry supports memory-resident
global sections and shared page tables. Through its interface within
the SYSMAN utility, the Reserved Memory Registry allows an OpenVMS
system to be configured with large amounts of memory set aside for use
within memory-resident sections or other privileged code. The Reserved
Memory Registry also allows an OpenVMS system to be properly tuned
through AUTOGEN, thus accounting for the pre-allocated reserved memory.
4.2 Memory-Resident Global Sections
Memory-resident global sections are non-file-backed global sections.
This means that the pages within a memory-resident global section are
not backed by the pagefile or by any other file on disk. Thus, no
pagefile quota is charged to any process or charged to the system. When
a process maps to a memory-resident global section and references the
pages, working set list entries are not created for the pages. No
working set quota is charged to the process.
Pages within a memory-resident global demand zero (DZRO) section
initially have zero contents.
Creating a memory-resident global DZRO section is performed by calling
either the SYS$CREATE_GDZRO system service or the SYS$CRMPSC_GDZRO_64
Mapping to a memory-resident global DZRO section is performed by
calling either the SYS$CRMPSC_GDZRO_64 system service or the
SYS$MGBLSC_64 system service.
To create a memory-resident global section, the process must have been
granted the VMS$MEM_RESIDENT_USER rights identifier. Mapping to a
memory-resident global section does not require this right identifier.
Two options are available when creating a memory-resident global DZRO
- Fault option: allocate pages only when virtual addresses are
- Allocate option: allocate all pages when section is created.
To use the fault option, it is recommended, but not required that the
pages within the memory-resident global section be deducted from the
system's fluid page count through the Reserved Memory Registry.
Using the Reserved Memory Registry ensures that AUTOGEN tunes the
system properly to exclude memory-resident global section pages in its
calculation of the system's fluid page count. AUTOGEN sizes the system
pagefile, number of processes, and working set maximum size based on
the system's fluid page count.
If the memory-resident global section has not been registered through
the Reserved Memory Registry, the system service call fails if there
are not enough fluid pages left in the system to accommodate the
memory-resident global section.
If the memory-resident global section has been registered through the
Reserved Memory Registry, the system service call fails if the size of
the global section exceeds the size of reserved memory and there are
not enough fluid pages left in the system to accommodate the additional
If memory has been reserved using the Reserved Memory Registry, that
memory must be used for the global section named in the SYSMAN command.
To return the memory to the system, SYSMAN can be run to free
the reserved memory, thus returning the pages back into the system's
count of fluid pages.
If the name of the memory-resident global section is not known at boot
time, or if a large amount of memory is to be configured out of the
system's pool of fluid memory, entries in the Reserved Memory Registry
can be added and the system can be retuned with AUTOGEN. After the
system re-boots, the reserved memory can be freed for use by
any application in the system with the VMS$MEM_RESIDENT_USER rights
identifier. This technique increases the availability of fluid memory
for use within memory-resident global sections without committing to
which applications or named global sections will receive the reserved
memory. For more information about the RESERVED_MEMORY FREE command,
see Section 22.214.171.124.
To use the allocate option, the memory must be pre-allocated during
system initialization to ensure that contiguous, aligned physical pages
are available. Granularity hints may be used when mapping to the
memory-resident global section if the virtual alignment of the mapping
is on an even 8-page, 64-page, or 512-page boundary. (With a system
page size of 8 KB, granularity hint virtual alignments are on 64-KB,
512-KB, and 4-MB boundaries.) OpenVMS chooses optimal virtual alignment
to use granularity hints if the flag SEC$M_EXPREG is set on the call to
one of the mapping system services, such as SYS$MGBLSC.
Contiguous, aligned PFNs are reserved using the Reserved Memory
Registry. The contiguous, aligned pages are allocated during system
initialization, based on the description of the reserved memory. The
memory-resident global section size must be less than or equal to the
size of the reserved memory or an error is returned from the system
If memory has been reserved using the Reserved Memory Registry, that
memory must be used for the global section named in the SYSMAN command.
To return the memory to the system, SYSMAN can be run to free the
pre-reserved memory. Once the pre-reserved memory has been freed, the
allocate option can no longer be used to create the memory-resident
4.3 Fast I/O and Buffer Objects for Global Sections
As of OpenVMS Alpha 7.2, VLM applications can use Fast I/O for memory
shared by processes through global sections. In prior versions of
OpenVMS Alpha, buffer objects could be created only for process-private
virtual address space. Fast I/O requires data to be locked in memory
through buffer objects. Database applications where multiple processes
share a large cache can now create buffer objects for the following
types of global sections:
- Page file-backed global sections
- Disk file-backed global sections
- Memory-resident global sections
Buffer objects enable Fast I/O system services, which can be used to
read and write very large amounts of shared data to and from I/O
devices at an increased rate. By reducing the CPU cost per I/O request,
Fast I/O increases performance for I/O operations.
Fast I/O improves the ability of VLM applications, such as database
servers, to handle larger capacities and higher data throughput rates.
4.3.1 Comparison of $QIO and Fast I/O
The $QIO system service must ensure that a specified memory range
exists and is accessible for the duration of each direct I/O request.
Validating that the buffer exists and is accessible is done in an
operation called probing. Making sure that the buffer
cannot be deleted and that the access protection is not changed while
the I/O is still active is achieved by locking the memory pages for I/O
and by unlocking them at I/O completion.
The probing and locking/unlocking operations for I/O are costly
operations. Having to do this work for each I/O can consume a
significant percentage of CPU capacity. The advantage of Fast I/O is
that memory is locked only for the duration of a single I/O and can
otherwise be paged.
Fast I/O must still ensure that the buffer is available, but if many
I/O requests are performed from the same memory cache, performance can
increase if the cache is probed and locked only once---instead of for
each I/O. OpenVMS must then ensure only that the memory access is
unchanged between multiple I/Os. Fast I/O uses buffer objects to
achieve this goal. Fast I/O gains additional performance advantages by
pre-allocating some system resources and by streamlining the I/O flow
4.3.2 Overview of Locking Buffers
Before the I/O subsystem can move any data into a user buffer, either
by moving data from system space in a buffered I/O, or by allowing a
direct I/O operation, it must ensure that the user buffer actually
exists and is accessible.
For buffered I/O, this is usually achieved by assuming the context of
the process requesting the I/O and probing the target buffer. For most
QIO requests, this happens at IPL 2 (IPL$_ASTDEL), which ensures that
no AST can execute between the buffer probing and the moving of the
data. The buffer is not deleted until the whole operation has
completed. IPL 2 also allows the normal paging mechanisms to work while
the data is copied.
For direct I/O, this is usually achieved by locking the target pages
for I/O. This makes the pages comprising the buffer ineligible for
paging or swapping. From there on the I/O subsystem identifies the
buffer by the page frame numbers, the byte offset within the first
page, and the length of the I/O request.
This method allows for maximum flexibility because the process can
continue to page and can even be swapped out of the balance set while
the I/O is still outstanding or active. No pages need to be locked for
buffered I/O; and for direct I/O, most of the process pages can still
be paged or swapped. However, this flexibility comes at a price; all
pages involved in an I/O must be probed or locked and unlocked for
every single I/O. For applications with high I/O rates, the operating
system can spend a significant amount of time on these time-consuming
Buffer objects can help avoid much of this overhead.
4.3.3 Overview of Buffer Objects
A buffer object is a process entity that is associated with a virtual
address range within a process. When the buffer object is created, all
pages in this address range are locked in memory. These pages cannot be
freed until the buffer object has been deleted. The Fast I/O
environment uses this feature by locking the buffer object itself
during $IO_SETUP. This prevents the buffer object and its associated
pages from being deleted. The buffer object is unlocked during
$IO_CLEANUP. This replaces the costly probe, lock, and unlock
operations with simple checks validating that the I/O buffer does not
exceed the buffer object. The trade-off is that the pages associated
with the buffer object are permanently locked in memory. An application
may need more physical memory but it can then execute faster.
To control this type of access to the system's memory, a user must hold
the VMS$BUFFER_OBJECT_USER identifier, and the system allows only a
certain number of pages locked for use in buffer objects. This number
is controlled by the dynamic SYSGEN parameter MAXBOBMEM.
A second buffer object property allows Fast I/O to perform several
I/O-related tasks entirely from system context at high IPL, without
having to assume process context. When a buffer object is created, the
system maps by default a section of system space (S2) to process pages
associated with the buffer object. This system space window is
protected to allow read and write access only from kernel mode. Because
all of system space is equally accessible from within any context, it
is now possible to avoid the still expensive context switch to assume
the original user's process context.
The convenience of having system space access to buffer object pages
comes at a price. For example, even though S2 space usually measures
several gigabytes, this may still be insufficient if several gigabytes
of database cache should be shared for Fast I/O by many processes. In
such an environment all or most I/O to or from the cache buffers is
direct I/O, and the system space mapping is not needed.
As of OpenVMS Version 7.2, buffer objects can be created with or
without an associated system space window. Resources used by buffer
objects are charged as follows:
- Physical pages are charged against MAXBOBMEM unless the page
belongs to a memory-resident section, or the page is already associated
with another buffer object.
- By default, system space window pages are charged against MAXBOBS2.
They are charged against MAXBOBS0S1 if CBO$_SVA_32 is specified.
- If CBO$_NOSVA is set, no system space window is created, and only
MAXBOBMEM is charged as appropriate.
For more information about using Fast I/O features, see the
OpenVMS I/O User's Reference Manual.
4.3.4 Creating and Using Buffer Objects
When creating and using buffer objects, you must be aware of the
- Buffer objects can be associated only with process space (P0, P1,
or P2) pages.
- PFN-mapped pages cannot be associated with buffer objects.
- The special type of buffer object without associated system space
can be used only to describe Fast /O data buffers. The IOSA must always
be associated with a full buffer object with system space.
- Some Fast I/O operations are not fully optimized if the data buffer
is associated with a buffer object without system space. Copying of
data at the completion of buffered I/O or disk-read I/O through the
VIOC cache may happen at IPL 8 in system context for full buffer
objects. However, it must happen in process context for buffer objects
without system space. If your application implements its own caching,
Compaq recommends bypassing the VIOC for disk I/O by setting the
IO$M_NOVCACHE function code modifier. Fast I/O recognizes this
condition and uses the maximum level of optimization regardless of the
type of buffer object.
4.4 Shared Page Tables
Shared page tables enable two or more processes to map to the same
physical pages without each process incurring the overhead of page
table construction, page file accounting, and working set quota
accounting. Internally, shared page tables are treated as a special
type of global section and are specifically used to map pages that are
part of a memory-resident global section. The special global section
that provides page table sharing is called a shared page table
section. Shared page table sections themselves are memory
Shared page tables are created and propagated to multiple processes by
a cooperating set of system services. No special privileges or rights
identifiers are required for a process or application to use shared
page tables. The VMS$MEM_RESIDENT_USER rights identifier is required
only to create a memory-resident global section. Processes that do not
have this identifier can benefit from shared page tables (as long as
certain mapping criteria prevail).
Similar to memory reserved for memory-resident global sections, memory
for shared page tables must be deducted from the system's set of fluid
pages. The Reserved Memory Registry allows for this deduction when a
memory-resident global section is registered.
4.4.1 Memory Requirements for Private Page Tables
Table 4-1 highlights the physical memory requirements for private page
tables and shared page tables that map to various sizes of global
sections by various numbers of processes. This table illustrates the
amount of physical memory saved systemwide through the use of shared
page tables. For example, when 100 processes map to a 1 GB global
section, 99 MB of physical memory are saved by mapping to the global
section with shared page tables.
Overall system performance benefits from this physical memory savings
because of the reduced contention for the physical memory system
resource. Individual processes benefit from the reduction of working
set usage by page table pages, thus allowing a process to keep more
private code and data in physical memory.
Table 4-1 Page Table Size Requirements
- PPT = Private Page Tables
- SHPT = Shared Page Tables
Number of | Size of Global Section
Mapping | 8MB 1GB 8GB 1TB
Processes | PPT SHPT PPT SHPT PPT SHPT PPT SHPT
1 | 8KB 8KB 1MB 1MB 8MB 8MB 1GB 1GB
10 | 80KB 8KB 10MB 1MB 80MB 8MB 10GB 1GB
100 | 800KB 8KB 100MB 1MB 800MB 8MB 100GB 1GB
1000 | 8MB 8KB 1GB 1MB 8GB 8MB 1TB 1GB
4.4.2 Shared Page Tables and Private Data
To benefit from shared page tables, a process does not require any
special privileges or rights identifiers. Only the creator of a
memory-resident global section requires the rights identifier
VMS$MEM_RESIDENT_USER. The creation of the memory-resident global
section causes the creation of the shared page tables that map that
global section unless the Reserved Memory Registry indicates that no
shared page tables are required. At first glance, it may appear that
there is a security risk inherent in allowing this greater level of
data sharing. There is no security risk for the reasons described in
An application or process that maps to a memory-resident global section
with shared page tables must take the following steps:
- Create a shared page table region by calling the system service
The starting virtual address of the region is
rounded down and the length is rounded up such that the region starts
and ends on an even page table page boundary.
- Use either the SYS$CRMPSC_GDZRO_64 system service or the
SYS$MGBLSC_64 system service to map to a memory-resident global
section. These services enable the caller to use the shared page tables
associated with the global section if the following conditions are met:
- The caller specifies a read/write access mode with the mapping
request that is exactly the same as the access mode associated with the
global section to map.
- The caller specifies proper virtual addressing alignments with the
A shared page table region can only map memory-resident global
sections. An application can map more than one memory-resident global
section into a shared page table region. The starting virtual address
for global sections mapped into a shared page table region are always
rounded to a page table page boundary. This prevents two distinct
global sections from sharing the same page table page. Attempts to
create virtual address space in a shared page table region with any
other system service except those listed in Step 2 will fail.
Processes can specify a non-shared page table region for mapping to a
memory- resident global section with shared page tables. In this case,
process private page tables are used to map to the global section.
4.5 Expandable Global Page Table
The GBLPAGES system parameter defines the size of the global page
table. The value stored in the parameter file is used at boot time to
establish the initial size of the global page table.
As of OpenVMS Alpha Version 7.1, the system parameters GBLPAGES and
GBLPAGFIL have been modified to become dynamic parameters. Users with
the CMKRNL privilege can now change their effective values on the
running system. Increasing the value of the GBLPAGES parameter at
runtime allows the global page table to expand, on demand, up to the
new maximum size. All the following conditions must be met for the
global page table to expand or grow:
- The global page table has insufficient contiguous free space to
allow the requested creation of a global section.
- The current setting of the GBLPAGES parameter allows the global
page table to expand.
- There is sufficient unused virtual memory at the higher end of the
global page table to expand into.
- The system has sufficient fluid memory (pages not locked in memory)
to allow the global page table to expand.
Because the global page table is mapped in 64-bit S2 space, which is a
minimum of 6 GB, these conditions can be met by almost all systems.
Only extremely memory-starved systems or systems with applications
making extensive use of S2 virtual address space may make it impossible
to grow the global page table on demand.
Because global pages are a system resource that also affects other
tuning parameters, Compaq recommends using AUTOGEN and rebooting
systems in order to increase GBLPAGES. If a reboot is not possible for
operational reasons, the parameter may be changed on the running system
using the following commands:
$ RUN SYS$SYSTEM:SYSGEN
SYSGEN> USE ACTIVE
SYSGEN> SET GBLPAGES new_value
SYSGEN> WRITE ACTIVE
The WRITE ACTIVE command requires the CMKRNL privilege.
The same commands also allow you to reduce the effective size of the
global page table. The global page table is actually reduced and full
pages are released to the system as fluid pages under the following
- A global section is deleted, thus freeing up global page table
- The value of GBLPAGES indicates a smaller size of the global page
table than the current size
- Unused entries exist at the high address end of the global page
table allowing to contract the stucture
Reducing the active value of GBLPAGES below the number of currently
used global pages does not affect currently used global pages. It only
prevents the creation of additional global pages.
Increasing the active value of the GBLPAGFIL parameter always succeeds,
up to the maximum positive integer value. As with GBLPAGES, reducing
the value of GBLPAGFIL below the number of global pages that may be
paged against the system's pagefile has no effect on these pages. Doing
so simply prevents the creation of additional global pagefile sections.
Note that an increase of GBLPAGFIL may also require that additional
pagefile space be satisfied by installing an additional pagefile.