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.ds RH "Data Structure Sizing Rules
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APPENDIX D. VAX KERNEL DATA STRUCTURE SIZING RULES .R

Certain system data structures are sized at compile time according to the maximum number of simultaneous users expected, while others are calculated at boot time based on the physical resources present, e.g. memory. This appendix lists both sets of rules and also includes some hints on changing built-in limitations on certain data structures.

Compile time rules

The file /sys/conf\|/param.c contains the definitions of almost all data structures sized at compile time. This file is copied into the directory of each configured system to allow configuration-dependent rules and values to be maintained. (Each copy normally depends on the copy in /sys/conf, and global modifications cause the file to be recopied unless the makefile is modified.) The rules implied by its contents are summarized below (here MAXUSERS refers to the value defined in the configuration file in the ``maxusers'' rule). Most limits are computed at compile time and stored in global variables for use by other modules; they may generally be patched in the system binary image before rebooting to test new values.

nproc

The maximum number of processes which may be running at any time. It is referred to in other calculations as NPROC and is defined to be 20 + 8 * MAXUSERS

ntext

The maximum number of active shared text segments. The constant is intended to allow for network servers and common commands that remain in the table. It is defined as 36 + MAXUSERS.

ninode

The maximum number of files in the file system which may be active at any time. This includes files in use by users, as well as directory files being read or written by the system and files associated with bound sockets in the UNIX IPC domain. It is defined as (NPROC + 16 + MAXUSERS) + 32

nfile

The number of ``file table'' structures. One file table structure is used for each open, unshared, file descriptor. Multiple file descriptors may reference a single file table entry when they are created through a dup call, or as the result of a fork. This is defined to be 16 * (NPROC + 16 + MAXUSERS) / 10 + 32

ncallout

The number of ``callout'' structures. One callout structure is used per internal system event handled with a timeout. Timeouts are used for terminal delays, watchdog routines in device drivers, protocol timeout processing, etc. This is defined as 16 + NPROC

nclist

The number of ``c-list'' structures. C-list structures are used in terminal I/O, and currently each holds 60 characters. Their number is defined as 60 + 12 * MAXUSERS

nmbclusters

The maximum number of pages which may be allocated by the network. This is defined as 256 (a quarter megabyte of memory) in /sys/h/mbuf.h. In practice, the network rarely uses this much memory. It starts off by allocating 8 kilobytes of memory, then requesting more as required. This value represents an upper bound.

nquota

The number of ``quota'' structures allocated. Quota structures are present only when disc quotas are configured in the system. One quota structure is kept per user. This is defined to be (MAXUSERS * 9) / 7 + 3

ndquot

The number of ``dquot'' structures allocated. Dquot structures are present only when disc quotas are configured in the system. One dquot structure is required per user, per active file system quota. That is, when a user manipulates a file on a file system on which quotas are enabled, the information regarding the user's quotas on that file system must be in-core. This information is cached, so that not all information must be present in-core all the time. This is defined as NINODE + (MAXUSERS * NMOUNT) / 4 where NMOUNT is the maximum number of mountable file systems.

In addition to the above values, the system page tables (used to map virtual memory in the kernel's address space) are sized at compile time by the SYSPTSIZE definition in the file /sys/vax/vmparam.h. This is defined to be 20 + MAXUSERS pages of page tables. Its definition affects the size of many data structures allocated at boot time because it constrains the amount of virtual memory which may be addressed by the running system. This is often the limiting factor in the size of the buffer cache, in which case a message is printed when the system configures at boot time.

Run-time calculations

The most important data structures sized at run-time are those used in the buffer cache. Allocation is done by allocating physical memory (and system virtual memory) immediately after the system has been started up; look in the file /sys/vax/machdep.c. The amount of physical memory which may be allocated to the buffer cache is constrained by the size of the system page tables, among other things. While the system may calculate a large amount of memory to be allocated to the buffer cache, if the system page table is too small to map this physical memory into the virtual address space of the system, only as much as can be mapped will be used.

The buffer cache is comprised of a number of ``buffer headers'' and a pool of pages attached to these headers. Buffer headers are divided into two categories: those used for swapping and paging, and those used for normal file I/O. The system tries to allocate 10% of the first two megabytes and 5% of the remaining available physical memory for the buffer cache (where available does not count that space occupied by the system's text and data segments). If this results in fewer than 16 pages of memory allocated, then 16 pages are allocated. This value is kept in the initialized variable bufpages so that it may be patched in the binary image (to allow tuning without recompiling the system), or the default may be overridden with a configuration-file option. For example, the option options BUFPAGES="3200" causes 3200 pages (3.2M bytes) to be used by the buffer cache. A sufficient number of file I/O buffer headers are then allocated to allow each to hold 2 pages each. Each buffer maps 8K bytes. If the number of buffer pages is larger than can be mapped by the buffer headers, the number of pages is reduced. The number of buffer headers allocated is stored in the global variable nbuf, which may be patched before the system is booted. The system option options NBUF="1000" forces the allocation of 1000 buffer headers. Half as many swap I/O buffer headers as file I/O buffers are allocated, but no more than 256.

System size limitations

As distributed, the sum of the virtual sizes of the core-resident processes is limited to 256M bytes. The size of the text segment of a single process is currently limited to 6M bytes. It may be increased to no greater than the data segment size limit (see below) by redefining MAXTSIZ. This may be done with a configuration file option, e.g. options MAXTSIZ="(10*1024*1024)" to set the limit to 10 million bytes. Other per-process limits discussed here may be changed with similar options with names given in parentheses. Soft, user-changeable limits are set to 512K bytes for stack (DFLSSIZ) and 6M bytes for the data segment (DFLDSIZ) by default; these may be increased up to the hard limit with the setrlimit\|(2) system call. The data and stack segment size hard limits are set by a system configuration option to one of 17M, 33M or 64M bytes. One of these sizes is chosen based on the definition of MAXDSIZ; with no option, the limit is 17M bytes; with an option options MAXDSIZ="(32*1024*1024)" (or any value between 17M and 33M), the limit is increased to 33M bytes, and values larger than 33M result in a limit of 64M bytes. You must be careful in doing this that you have adequate paging space. As normally configured , the system has 16M or 32M bytes per paging area, depending on disk size. The best way to get more space is to provide multiple, thereby interleaved, paging areas. Increasing the virtual memory limits results in interleaving of swap space in larger sections (from 500K bytes to 1M or 2M bytes).

By default, the virtual memory system allocates enough memory for system page tables mapping user page tables to allow 256 megabytes of simultaneous active virtual memory. That is, the sum of the virtual memory sizes of all (completely- or partially-) resident processes can not exceed this limit. If the limit is exceeded, some process(es) must be swapped out. To increase the amount of resident virtual space possible, you can alter the constant USRPTSIZE (in /sys/vax/vmparam.h). Each page of system page tables allows 8 megabytes of user virtual memory.

Because the file system block numbers are stored in page table pg_blkno entries, the maximum size of a file system is limited to 2^24 1024 byte blocks. Thus no file system can be larger than 8 gigabytes.

The number of mountable file systems is set at 20 by the definition of NMOUNT in /sys/h/param.h. This should be sufficient; if not, the value can be increased up to 255. If you have many disks, it makes sense to make some of them single file systems, and the paging areas don't count in this total.

The limit to the number of files that a process may have open simultaneously is set to 64. This limit is set by the NOFILE definition in /sys/h/param.h. It may be increased arbitrarily, with the caveat that the user structure expands by 5 bytes for each file, and thus UPAGES (/sys/vax/machparam.h) must be increased accordingly.

The amount of physical memory is currently limited to 64 Mb by the size of the index fields in the core-map (/sys/h/cmap.h). The limit may be increased by following instructions in that file to enlarge those fields.