.\" $NetBSD: pmap.9,v 1.6 2001/08/11 05:05:13 matt Exp $ .\" .\" Copyright (c) 2000, 2001 The NetBSD Foundation, Inc. .\" All rights reserved. .\" .\" This code is derived from software contributed to The NetBSD Foundation .\" by Jason R. Thorpe. .\" .\" Redistribution and use in source and binary forms, with or without .\" modification, are permitted provided that the following conditions .\" are met: .\" 1. Redistributions of source code must retain the above copyright .\" notice, this list of conditions and the following disclaimer. .\" 2. Redistributions in binary form must reproduce the above copyright .\" notice, this list of conditions and the following disclaimer in the .\" documentation and/or other materials provided with the distribution. .\" 3. All advertising materials mentioning features or use of this software .\" must display the following acknowledgement: .\" This product includes software developed by the NetBSD .\" Foundation, Inc. and its contributors. .\" 4. Neither the name of The NetBSD Foundation nor the names of its .\" contributors may be used to endorse or promote products derived .\" from this software without specific prior written permission. .\" .\" THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS .\" ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED .\" TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR .\" PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS .\" BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR .\" CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF .\" SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS .\" INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN .\" CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) .\" ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE .\" POSSIBILITY OF SUCH DAMAGE. .\" .Dd April 16, 2001 .Dt PMAP 9 .Os .Sh NAME .Nm pmap .Nd machine-dependent portion of the virtual memory system .Sh SYNOPSIS .Fd #include .Fd #include .Ft void .Fn "pmap_init" "void" .Ft void .Fn "pmap_virtual_space" "vaddr_t *vstartp" "vaddr_t *vendp" .Ft vaddr_t .Fn "pmap_steal_memory" "vsize_t size" "vaddr_t *vstartp" "vaddr_t *vendp" .Ft pmap_t .Fn "pmap_kernel" "void" .Ft pmap_t .Fn "pmap_create" "void" .Ft void .Fn "pmap_destroy" "pmap_t pmap" .Ft void .Fn "pmap_reference" "pmap_t pmap" .Ft void .Fn "pmap_fork" "pmap_t src_map" "pmap_t dst_map" .Ft long .Fn "pmap_resident_count" "pmap_t pmap" .Ft long .Fn "pmap_wired_count" "pmap_t pmap" .Ft vaddr_t .Fn "pmap_growkernel" "vaddr_t maxkvaddr" .Ft int .Fn "pmap_enter" "pmap_t pmap" "vaddr_t va" "paddr_t pa" "vm_prot_t prot" \ "int flags" .Ft void .Fn "pmap_remove" "pmap_t pmap" "vaddr_t sva" "vaddr_t eva" .Ft void .Fn "pmap_protect" "pmap_t pmap" "vaddr_t sva" "vaddr_t eva" "vm_prot_t prot" .Ft void .Fn "pmap_unwire" "pmap_t pmap" "vaddr_t va" .Ft boolean_t .Fn "pmap_extract" "pmap_t pmap" "vaddr_t va" "paddr_t *pap" .Ft void .Fn "pmap_kenter_pa" "vaddr_t va" "paddr_t pa" "vm_prot_t prot" .Ft void .Fn "pmap_kremove" "vaddr_t va" "vsize_t size" .Ft void .Fn "pmap_copy" "pmap_t dst_map" "pmap_t src_map" "vaddr_t dst_addr" \ "vsize_t len" "vaddr_t src_addr" .Ft void .Fn "pmap_collect" "pmap_t pmap" .Ft void .Fn "pmap_update" "void" .Ft void .Fn "pmap_activate" "struct proc *p" .Ft void .Fn "pmap_deactivate" "struct proc *p" .Ft void .Fn "pmap_zero_page" "paddr_t pa" .Ft void .Fn "pmap_copy_page" "paddr_t src" "paddr_t dst" .Ft void .Fn "pmap_page_protect" "struct vm_page *pg" "vm_prot_t prot" .Ft boolean_t .Fn "pmap_clear_modify" "struct vm_page *pg" .Ft boolean_t .Fn "pmap_clear_reference" "struct vm_page *pg" .Ft boolean_t .Fn "pmap_is_modified" "struct vm_page *pg" .Ft boolean_t .Fn "pmap_is_referenced" "struct vm_page *pg" .Ft paddr_t .Fn "pmap_phys_address" "int cookie" .Ft vaddr_t .Fn "PMAP_MAP_POOLPAGE" "paddr_t pa" .Ft paddr_t .Fn "PMAP_UNMAP_POOLPAGE" "vaddr_t va" .Sh DESCRIPTION The .Nm module is the machine-dependent portion of the .Nx virtual memory system .Xr uvm 9 . The purpose of the .Nm module is to manage physical address maps, to program the memory management hardware on the system, and perform any cache operations necessary to ensure correct operation of the virtual memory system. The .Nm module is also responsible for maintaining certain information required by .Xr uvm 9 . .Pp In order to cope with hardware architectures that make the invalidation of virtual address mappings expensive (e.g. TLB invalidations, TLB shootdown operations for multiple processors), the .Nm module is allowed to delay mapping invalidation or protection operations until such time as they are actually necessary. The functions that are allowed to delay such actions are .Fn pmap_enter , .Fn pmap_remove , .Fn pmap_protect , .Fn pmap_kenter_pa , and .Fn pmap_kremove . Callers of these functions must use the .Fn pmap_update function to notify the .Nm module that the mappings need to be made correct. Since the .Nm module is provided with information as to which processors are using a given physical map, the .Nm module may use whatever optimizations it has available to reduce the expense of virtual-to-physical mapping synchronization. .Ss HEADER FILES AND DATA STRUCTURES Machine-dependent code must provide the header file .Pa . This file contains the definition of the .Dv pmap structure: .Bd -literal -offset indent struct pmap { /* Contents defined by pmap implementation. */ }; typedef struct pmap *pmap_t; .Ed .Pp This header file may also define other data structures that the .Nm implementation uses. .Pp Note that all prototypes for .Nm interface functions are provided by the header file .Pa . It is possible to override this behavior by defining the C pre-processor macro .Dq PMAP_EXCLUDE_DECLS . This may be used to add a layer of indirection to .Nm API calls, for handling different MMU types in a single .Nm module, for example. If the .Dq PMAP_EXCLUDE_DECLS macro is defined, .Pa .Em must provide function prototypes in a block like so: .Bd -literal -offset indent #ifdef _KERNEL /* not exposed to user namespace */ __BEGIN_DECLS /* make safe for C++ */ /* Prototypes go here. */ __END_DECLS #endif /* _KERNEL */ .Ed .Pp The header file .Pa defines a structure for tracking .Nm statistics (see below). This structure is defined as: .Bd -literal -offset indent struct pmap_statistics { long resident_count; /* number of mapped pages */ long wired_count; /* number of wired pages */ }; .Ed .Ss WIRED MAPPINGS The .Nm module is based on the premise that all information contained in the physical maps it manages is redundant. That is, physical map information may be .Dq forgotten by the .Nm module in the event that it is necessary to do so; it can be rebuilt by .Xr uvm 9 by taking a page fault. There is one exception to this rule: so-called .Dq wired mappings may not be forgotten. Wired mappings are those for which either no high-level information exists with which to rebuild the mapping, or mappings which are needed by critical sections of code where taking a page fault is unacceptable. Information about which mappings are wired is provided to the .Nm module when a mapping is established. .Ss MODIFIED/REFERENCED INFORMATION The .Nm module is required to keep track of whether or not a page managed by the virtual memory system has been referenced or modified. This information is used by .Xr uvm 9 to determine what happens to the page when scanned by the pagedaemon. .Pp Many CPUs provide hardware support for tracking modified/referenced information. However, many CPUs, particularly modern RISC CPUs, do not. On CPUs which lack hardware support for modified/referenced tracking, the .Nm module must emulate it in software. There are several strategies for doing this, and the best strategy depends on the CPU. .Pp The .Dq referenced attribute is used by the pagedaemon to determine if a page is .Dq active . Active pages are not candidates for re-use in the page replacement algorithm. Accurate referenced information is not required for correct operation; if supplying referenced information for a page is not feasible, then the .Nm implementation should always consider the .Dq referenced attribute to be FALSE. .Pp The .Dq modified attribute is used by the pagedaemon to determine if a page needs to be cleaned (written to backing store; swap space, a regular file, etc.). Accurate modified information .Em must be provided by the .Nm module for correct operation of the virtual memory system. .Pp Note that modified/referenced information is only tracked for pages managed by the virtual memory system (i.e. pages for which a vm_page structure exists). In addition, only .Dq managed mappings of those pages have modified/referenced tracking. Mappings entered with the .Fn pmap_enter function are .Dq managed mappings. It is possible for .Dq unmanaged mappings of a page to be created, using the .Fn pmap_kenter_pa function. The use of .Dq unmanaged mappings should be limited to code which may execute in interrupt context (for example, the kernel memory allocator), or to enter mappings for physical addresses which are not managed by the virtual memory system. .Dq Unmanaged mappings may only be entered into the kernel's virtual address space. This constraint is placed on the callers of the .Fn pmap_kenter_pa and .Fn pmap_kremove functions so that the .Nm implementation need not block interrupts when manipulating data structures or holding locks. .Pp Also note that the modified/referenced information must be tracked on a per-page basis; they are not attributes of a mapping, but attributes of a page. Therefore, even after all mappings for a given page have been removed, the modified/referenced information for that page .Em must be preserved. The only time the modified/referenced attributes may be cleared is when the virtual memory system explicitly calls the .Fn pmap_clear_modify and .Fn pmap_clear_reference functions. .Ss STATISTICS The .Nm is required to keep statistics as to the number of .Dq resident pages and the number of .Dq wired pages. .Pp A .Dq resident page is one for which a mapping exists. This statistic is used to compute the resident size of a process and enforce resource limits. Only pages (whether managed by the virtual memory system or not) which are mapped into a physical map should be counted in the resident count. .Pp A .Dq wired page is one for which a wired mapping exists. This statistic is used to enforce resource limits. .Pp Note that it is recommended (though not required) that the .Nm implementation utilize the .Dv pmap_statistics structure in the tracking of .Nm statistics by placing it inside the .Dv pmap structure and adjusting the counts when mappings are established, changed, or removed. This avoids potentially expensive data structure traversals when the statistics are queried. .Ss REQUIRED FUNCTIONS This section describes functions that a .Nm module must provide to the virtual memory system. .Bl -tag -width offset -indent .It void Fn "pmap_init" "void" This function initializes the .Nm module. It is called by .Fn uvm_init to initialize any data structures that the module needs to manage physical maps. .It pmap_t Fn "pmap_kernel" "void" Return a pointer to the .Dv pmap structure that maps the kernel virtual address space. .Pp Note that this function may be provided as a C pre-processor macro. .It void Fn "pmap_virtual_space" "vaddr_t *vstartp" "vaddr_t *vendp" The .Fn pmap_virtual_space function is called to determine the initial kernel virtual address space beginning and end. These values are used to create the kernel's virtual memory map. The function must set .Fa *vstartp to the first kernel virtual address that will be managed by .Xr uvm 9 , and must set .Fa *vendp to the last kernel virtual address that will be managed by .Xr uvm 9 . .Pp If the .Fn pmap_growkernel feature is used by a .Nm implementation, then .Fa *vendp should be set to the maximum kernel virtual address allowed by the implementation. If .Fn pmap_growkernel is not used, then .Fa *vendp .Em must be set to the maximum kernel virtual address that can be mapped with the resources currently allocated to map the kernel virtual address space. .It pmap_t Fn "pmap_create" "void" Create a physical map and return it to the caller. The reference count on the new map is 1. .It void Fn "pmap_destroy" "pmap_t pmap" Drop the reference count on the specified physical map. If the reference count drops to 0, all resources associated with the physical map are released and the physical map destroyed. In the case of a drop-to-0, no mappings will exist in the map. The .Nm implementation may assert this. .It void Fn "pmap_reference" "pmap_t pmap" Increment the reference count on the specified physical map. .It long Fn "pmap_resident_count" "pmap_t pmap" Query the .Dq resident pages statistic for .Fa pmap . .Pp Note that this function may be provided as a C pre-processor macro. .It long Fn "pmap_wired_count" "pmap_t pmap" Query the .Dq wired pages" statistic for .Fa pmap . .Pp Note that this function may be provided as a C pre-processor macro. .It int Fn "pmap_enter" "pmap_t pmap" "vaddr_t va" "paddr_t pa" \ "vm_prot_t prot" "int flags" Create a mapping in physical map .Fa pmap for the physical address .Fa pa at the virtual address .Fa va with protection specified by bits in .Fa prot : .Bl -tag -width "VM_PROT_EXECUTE " -indent .It VM_PROT_READ The mapping must allow reading. .It VM_PROT_WRITE The mapping must allow writing. .It VM_PROT_EXECUTE The page mapped contains instructions that will be executed by the processor. .El .Pp The .Fa flags argument contains protection bits (the same bits as used in the .Fa prot argument) indicating the type of access that caused the mapping to be created. This information may be used to seed modified/referenced information for the page being mapped, possibly avoiding redundant faults on platforms that track modified/referenced information in software. Other information provided by .Fa flags : .Bl -tag -width "PMAP_CANFAIL " -indent .It PMAP_WIRED The mapping being created is a wired mapping. .It PMAP_CANFAIL The call to .Fn pmap_enter is allowed to fail. If this flag is .Em not set, and the .Fn pmap_enter call is unable to create the mapping, perhaps due to insufficient resources, the .Nm module must panic. .El .Pp The access type provided in the .Fa flags argument will never exceed the protection specified by .Fa prot . The .Nm implementation may assert this. Note that on systems that do not provide hardware support for tracking modified/referenced information, modified/referenced information for the page .Em must be seeded with the access type provided in .Fa flags if the PMAP_WIRED flag is set. This is to prevent a fault for the purpose of tracking modified/referenced information from occurring while the system is in a critical section where a fault would be unacceptable. .Pp Note that .Fn pmap_enter is sometimes called to enter a mapping at a virtual address for which a mapping already exists. In this situation, the implementation must take whatever action is necessary to invalidate the previous mapping before entering the new one. .Pp Also note that .Fn pmap_enter is sometimes called to change the protection for a pre-existing mapping, or to change the .Dq wired attribute for a pre-existing mapping. .Pp The .Fn pmap_enter function returns 0 on success or an error code indicating the mode of failure. .It void Fn "pmap_remove" "pmap_t pmap" "vaddr_t sva" "vaddr_t eva" Remove mappings from the virtual address range .Fa sva to .Fa eva from the specified physical map. .It void Fn "pmap_protect" "pmap_t pmap" "vaddr_t sva" "vaddr_t eva" \ "vm_prot_t prot" Set the protection of the mappings in the virtual address range .Fa sva to .Fa eva in the specified physical map. .It void Fn "pmap_unwire" "pmap_t pmap" "vaddr_t va" Clear the .Dq wired attribute on the mapping for virtual address .Fa va . .It boolean_t Fn "pmap_extract" "pmap_t pmap" "vaddr_t va" "paddr_t *pap" This function extracts a mapping from the specified physical map. It serves two purposes: to determine if a mapping exists for the specified virtual address, and to determine what physical address is mapped at the specified virtual address. .Pp The .Fn pmap_extract function returns FALSE if a mapping for .Fa va does not exist. Otherwise, it returns TRUE and places the physical address mapped at .Fa va into .Fa *pap if the .Fa pap argument is non-NULL. .It void Fn "pmap_kenter_pa" "vaddr_t va" "paddr_t pa" "vm_prot_t prot" Enter an .Dq unmanaged mapping for physical address .Fa pa at virtual address .Fa va with protection .Fa prot into the kernel physical map. Mappings of this type are always .Dq wired , and are unaffected by routines that alter the protection of pages (such as .Fn pmap_page_protect ) Ns . Such mappings are also not included in the gathering of modified/referenced information about a page. Mappings created with .Fn pmap_kenter_pa may be removed only with a call to .Fn pmap_kremove . .Pp Note that .Fn pmap_kenter_pa must be safe for use in interrupt context. .Fn splvm blocks interrupts that might cause .Fn pmap_kenter_pa to be called. .It void Fn "pmap_kremove" "vaddr_t va" "vsize_t size" Remove all mappings starting at virtual address .Fa va for .Fa size bytes from the kernel physical map. All mappings that are removed must be the .Dq unmanaged type created with .Fn pmap_kenter_pa . The implementation may assert this. .It void Fn "pmap_copy" "pmap_t dst_map" "pmap_t src_map" "vaddr_t dst_addr" \ "vsize_t len" "vaddr_t src_addr" This function copies the mappings starting at .Fa src_addr in .Fa src_map for .Fa len bytes into .Fa dst_map starting at .Fa dst_addr . .Pp Note that while this function is required to be provided by a .Nm implementation, it is not actually required to do anything. .Fn pmap_copy is merely advisory (it is used in the .Xr fork 2 path to .Dq pre-fault the child's address space). .It void Fn "pmap_collect" "pmap_t pmap" This function is called just before a process is swapped out to allow the .Nm module to release resources used to map the process's address space. The implementation may choose to remove physical mappings in order to free e.g. page tables back to the system. Note, however, that wired mappings must .Em not be removed when .Fn pmap_collect is called. .Pp Note that while this function is required to be provided by a .Nm implementation, it is not actually required to do anything. .Fn pmap_collect is merely advisory. It is recommended, however, that .Fn pmap_collect be fully implemented by a .Nm implementation. .It void Fn "pmap_update" "void" This function is used to inform the .Nm module that all physical mappings must now be correct. That is, all delayed virtual-to-physical mappings updates (such as TLB invalidation or address space identifier updates) must be completed. This routine must be used after calls to .Fn pmap_enter , .Fn pmap_remove , .Fn pmap_protect , .Fn pmap_kenter_pa , and .Fn pmap_kremove in order to ensure correct operation of the virtual memory system. .Pp If a .Nm implementation does not delay virtual-to-physical mapping updates, .Fn pmap_update has no operation. In this case, the call may be deleted using a C pre-processor macro in .Pa . .It void Fn "pmap_activate" "struct proc *p" Activate the physical map used by process .Fa p . This is called by the virtual memory system when the the virtual memory context for a process is changed, and is also often used by machine-dependent context switch code to program the memory management hardware with the process's page table base, etc. Note that .Fn pmap_activate may not always be called when .Fa p is the current process. .Fn pmap_activate must be able to handle this scenario. .It void Fn "pmap_deactivate" "struct proc *p" Deactivate the physical map used by process .Fa p . It is generally used in conjunction with .Fn pmap_activate . Like .Fn pmap_activate , .Fn pmap_deactivate may not always be called when .Fa p is the current process. .It void Fn "pmap_zero_page" "paddr_t pa" Zero the PAGE_SIZE sized region starting at physical address .Fa pa . The .Nm implementation must take whatever steps are necessary to map the page to a kernel-accessible address and zero the page. It is suggested that implementations use an optimized zeroing algorithm, as the performance of this function directly impacts page fault performance. The implementation may assume that the region is PAGE_SIZE aligned and exactly PAGE_SIZE bytes in length. .Pp Note that the cache configuration of the platform should also be considered in the implementation of .Fn pmap_zero_page . For example, on systems with a physically-addressed cache, the cache load caused by zeroing the page will not be wasted, as the zeroing is usually done on-demand. However, on systems with a virtually-addressed cached, the cache load caused by zeroing the page .Em will be wasted, as the page will be mapped at a virtual address which is different from that used to zero the page. In the virtually-addressed cache case, care should also be taken to avoid cache alias problems. .It void Fn "pmap_copy_page" "paddr_t src" "paddr_t dst" Copy the PAGE_SIZE sized region starting at physical address .Fa src to the same sized region starting at physical address .Fa dst . The .Nm implementation must take whatever steps are necessary to map the source and destination pages to a kernel-accessible address and perform the copy. It is suggested that implementations use an optimized copy algorithm, as the performance of this function directly impacts page fault performance. The implementation may assume that both regions are PAGE_SIZE aligned and exactly PAGE_SIZE bytes in length. .Pp The same cache considerations that apply to .Fn pmap_zero_page apply to .Fn pmap_copy_page . .It void Fn "pmap_page_protect" "struct vm_page *pg" "vm_prot_t prot" Lower the permissions for all mappings of the page .Fa pg to .Fa prot . This function is used by the virtual memory system to implement copy-on-write (called with VM_PROT_READ set in .Fa prot ) and to revoke all mappings when cleaning a page (called with no bits set in .Fa prot ) Ns . Access permissions must never be added to a page as a result of this call. .It boolean_t Fn "pmap_clear_modify" "struct vm_page *pg" Clear the .Dq modified attribute on the page .Fa pg . .Pp The .Fn pmap_clear_modify function returns TRUE or FALSE indicating whether or not the .Dq modified attribute was set on the page before it was cleared. .Pp Note that this function may be provided as a C pre-processor macro. .It boolean_t Fn "pmap_clear_reference" "struct vm_page *pg" Clear the .Dq referenced attribute on the page .Fa pg . .Pp The .Fn pmap_clear_reference function returns TRUE or FALSE indicating whether or not the .Dq referenced attribute was set on the page before it was cleared. .Pp Note that this function may be provided as a C pre-processor macro. .It boolean_t Fn "pmap_is_modified" "struct vm_page *pg" Test whether or not the .Dq modified attribute is set on page .Fa pg . .Pp Note that this function may be provided as a C pre-processor macro. .It boolean_t Fn "pmap_is_referenced" "struct vm_page *pg" Test whether or not the .Dq referenced attribute is set on page .Fa pg . .Pp Note that this function may be provided as a C pre-processor macro. .It paddr_t Fn "pmap_phys_address" "int cookie" Convert a cookie returned by a device .Fn mmap function into a physical address. This function is provided to accommodate systems which have physical address spaces larger than can be directly addressed by the platform's .Fa paddr_t type. The existence of this function is highly dubious, and it is expected that this function will be removed from the .Nm pmap API in a future release of .Nx . .Pp Note that this function may be provided as a C pre-processor macro. .El .Ss OPTIONAL FUNCTIONS This section describes several optional functions in the .Nm API. .Bl -tag -width offset -indent .It vaddr_t Fn "pmap_steal_memory" "vsize_t size" "vaddr_t *vstartp" \ "vaddr_t *vendp" This function is a bootstrap memory allocator, which may be provided as an alternative to the bootstrap memory allocator used within .Xr uvm 9 itself. It is particularly useful on systems which provide e.g. a direct-mapped memory segment. This function works by stealing pages from the (to be) managed memory pool, which has already been provided to .Xr uvm 9 in the vm_physmem[] array. The pages are then mapped, or otherwise made accessible to the kernel, in a machine-dependent way. The memory must be zeroed by .Fn pmap_steal_memory . Note that memory allocated with .Fn pmap_steal_memory will never be freed, and mappings made by .Fn pmap_steal_memory must never be .Dq forgotten . .Pp Note that .Fn pmap_steal_memory should not be used as a general-purpose early-startup memory allocation routine. It is intended to be used only by the .Fn uvm_pageboot_alloc routine and its supporting routines. If you need to allocate memory before the virtual memory system is initialized, use .Fn uvm_pageboot_alloc . See .Xr uvm 9 for more information. .Pp The .Fn pmap_steal_memory function returns the kernel-accessible address of the allocated memory. If no memory can be allocated, or if allocated memory cannot be mapped, the function must panic. .Pp If the .Fn pmap_steal_memory function uses address space from the range provided to .Xr uvm 9 by the .Fn pmap_virtual_space call, then .Fn pmap_steal_memory must adjust .Fa *vstartp and .Fa *vendp upon return. .Pp The .Fn pmap_steal_memory function is enabled by defining the C pre-processor macro .Dq PMAP_STEAL_MEMORY in .Pa . .It vaddr_t Fn "pmap_growkernel" "vaddr_t maxkvaddr" Management of the kernel virtual address space is complicated by the fact that it is not always safe to wait for resources with which to map a kernel virtual address. However, it is not always desirable to pre-allocate all resources necessary to map the entire kernel virtual address space. .Pp The .Fn pmap_growkernel interface is designed to help alleviate this problem. The virtual memory startup code may choose to allocate an initial set of mapping resources (e.g. page tables) and set an internal variable indicating how much kernel virtual address space can be mapped using those initial resources. Then, when the virtual memory system wishes to map something at an address beyond that initial limit, it calls .Fn pmap_growkernel to pre-allocate more sources with which to create the mapping. Note that once additional kernel virtual address space mapping resources have been allocated, they should not be freed; it is likely they will be needed again. .Pp The .Fn pmap_growkernel function returns the new maximum kernel virtual address that can be mapped with the resources it has available. If new resources cannot be allocated, .Fn pmap_growkernel must panic. .Pp The .Fn pmap_growkernel function is enabled by defining the C pre-processor macro .Dq PMAP_GROWKERNEL in .Pa . .It void Fn "pmap_fork" "pmap_t src_map" "pmap_t dst_map" Some .Nm implementations may need to keep track of other information not directly related to the virtual address space. For example, on the i386 port, the Local Descriptor Table state of a process is associated with the pmap (this is due to the fact that applications manipulate the Local Descriptor Table directly expect it to be logically associated with the virtual memory state of the process). .Pp The .Fn pmap_fork function is provided as a way to associate information from .Fa src_map with .Fa dst_map when a .Dv vmspace is forked. .Fn pmap_fork is called from .Fn uvmspace_fork . .Pp The .Fn pmap_fork function is enabled by defining the C pre-processor macro .Dq PMAP_FORK in .Pa . .It vaddr_t Fn "PMAP_MAP_POOLPAGE" "paddr_t pa" This function is used by the .Xr pool 9 memory pool manager. Pools allocate backing pages one at a time. This is provided as a means to use hardware features such as a direct-mapped memory segment to map the pages used by the .Xr pool 9 allocator. This can lead to better performance by e.g. reducing TLB contention. .Pp .Fn PMAP_MAP_POOLPAGE returns the kernel-accessible address of the page being mapped. It must always succeed. .Pp The use of .Fn PMAP_MAP_POOLPAGE is enabled by defining it as a C pre-processor macro in .Fa . If .Fn PMAP_MAP_POOLPAGE is defined, .Fn PMAP_UNMAP_POOLPAGE must also be defined. .Pp The following is an example of how to define .Fn PMAP_MAP_POOLPAGE : .Bd -literal -offset indent #define PMAP_MAP_POOLPAGE(pa) MIPS_PHYS_TO_KSEG0((pa)) .Ed .Pp This takes the physical address of a page and returns the KSEG0 address of that page on a MIPS processor. .It paddr_t Fn "PMAP_UNMAP_POOLPAGE" "vaddr_t va" This function is the inverse of .Fn PMAP_MAP_POOLPAGE . .Pp .Fn PMAP_UNMAP_POOLPAGE returns the physical address of the page corresponding to the provided kernel-accessible address. .Pp The use of .Fn PMAP_UNMAP_POOLPAGE is enabled by defining it as a C pre-processor macro in .Fa . If .Fn PMAP_UNMAP_POOLPAGE is defined, .Fn PMAP_MAP_POOLPAGE must also be defined. .Pp The following is an example of how to define .Fn PMAP_UNMAP_POOLPAGE : .Bd -literal -offset indent #define PMAP_UNMAP_POOLPAGE(pa) MIPS_KSEG0_TO_PHYS((va)) .Ed .Pp This takes the KSEG0 address of a previously-mapped pool page and returns the physical address of that page on a MIPS processor. .El .Sh SEE ALSO .Xr uvm 9 .Sh HISTORY The .Nm module was originally part of the design of the virtual memory system in the Mach Operating System. The goal was to provide a clean separation between the machine-independent and the machine-dependent portions of the virtual memory system, in stark contrast to the original .Bx 3 virtual memory system, which was specific to the VAX. .Pp Between .Bx 4.3 and .Bx 4.4 , the Mach virtual memory system, including the .Nm API, was ported to .Bx and included in the .Bx 4.4 release. .Pp .Nx inherited the .Bx version of the Mach virtual memory system. .Nx 1.4 was the first .Nx release with the new .Xr uvm 9 virtual memory system, which included several changes to the .Nm API. Since the introduction of .Xr uvm 9 , the .Nm API has evolved further. .Sh BUGS The use and definition of .Fn pmap_activate and .Fn pmap_deactivate needs to be reexamined. .Pp The use of .Fn pmap_copy needs to be reexamined. Empirical evidence suggests that performance of the system suffers when .Fn pmap_copy actually performs its defined function. This is largely due to the fact that the copy of the virtual-to-physical mappings is wasted if the process calls .Xr execve 2 after .Xr fork 2 . For this reason, it is recommended that .Nm implementations leave the body of the .Fn pmap_copy function empty for now. .Sh AUTHOR The original Mach VAX .Nm module was written by .An Avadis Tevanian, Jr. and .An Michael Wayne Young . .Pp .An Mike Hibler did the integration of the Mach virtual memory system into .Bx 4.4 and implemented a .Nm module for the Motorola 68020+68851/68030/68040. .Pp The .Nm API as it exists in .Nx is derived from .Bx 4.4 , and has been modified by .An Chuck Cranor , .An Charles M. Hannum , .An Chuck Silvers , .An Wolfgang Solfrank , .An Bill Sommerfeld , and .An Jason R. Thorpe . .Pp The author of this document is .An Jason R. Thorpe .Aq thorpej@netbsd.org .