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/* $OpenBSD: uvm_amap.h,v 1.30 2017/02/05 01:11:50 guenther Exp $ */
/* $NetBSD: uvm_amap.h,v 1.14 2001/02/18 21:19:08 chs Exp $ */
/*
* Copyright (c) 1997 Charles D. Cranor and Washington University.
* All rights reserved.
*
* 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.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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.
*/
#ifndef _UVM_UVM_AMAP_H_
#define _UVM_UVM_AMAP_H_
/*
* uvm_amap.h: general amap interface and amap implementation-specific info
*/
/*
* an amap structure contains pointers to a set of anons that are
* mapped together in virtual memory (an anon is a single page of
* anonymous virtual memory -- see uvm_anon.h). in uvm we hide the
* details of the implementation of amaps behind a general amap
* interface. this allows us to change the amap implementation
* without having to touch the rest of the code. this file is divided
* into two parts: the definition of the uvm amap interface and the
* amap implementation-specific definitions.
*/
#ifdef _KERNEL
/*
* part 1: amap interface
*/
/*
* forward definition of vm_amap structure. only amap
* implementation-specific code should directly access the fields of
* this structure.
*/
struct vm_amap;
/*
* prototypes for the amap interface
*/
/* ensure amap can store anon */
void amap_populate(struct vm_aref *, vaddr_t);
/* add an anon to an amap */
int amap_add(struct vm_aref *, vaddr_t, struct vm_anon *,
boolean_t);
/* allocate a new amap */
struct vm_amap *amap_alloc(vaddr_t, int, int);
/* clear amap needs-copy flag */
void amap_copy(vm_map_t, vm_map_entry_t, int, boolean_t, vaddr_t,
vaddr_t);
/* resolve all COW faults now */
void amap_cow_now(vm_map_t, vm_map_entry_t);
/* free amap */
void amap_free(struct vm_amap *);
/* init amap module (at boot time) */
void amap_init(void);
/* lookup an anon @ offset in amap */
struct vm_anon *amap_lookup(struct vm_aref *, vaddr_t);
/* lookup multiple anons */
void amap_lookups(struct vm_aref *, vaddr_t, struct vm_anon **, int);
/* add a reference to an amap */
void amap_ref(struct vm_amap *, vaddr_t, vsize_t, int);
/* split reference to amap into two */
void amap_splitref(struct vm_aref *, struct vm_aref *, vaddr_t);
/* remove an anon from an amap */
void amap_unadd(struct vm_aref *, vaddr_t);
/* drop reference to an amap */
void amap_unref(struct vm_amap *, vaddr_t, vsize_t, int);
/* remove all anons from amap */
void amap_wipeout(struct vm_amap *);
boolean_t amap_swap_off(int, int);
/*
* amap flag values
*/
#define AMAP_SHARED 0x1 /* amap is shared */
#define AMAP_REFALL 0x2 /* amap_ref: reference entire amap */
#define AMAP_SWAPOFF 0x4 /* amap_swap_off() is in progress */
#endif /* _KERNEL */
/**********************************************************************/
/*
* part 2: amap implementation-specific info
*/
/*
* we currently provide an array-based amap implementation. in this
* implementation we provide the option of tracking split references
* so that we don't lose track of references during partial unmaps
* ... this is enabled with the "UVM_AMAP_PPREF" define.
*/
#define UVM_AMAP_PPREF /* track partial references */
/*
* here is the definition of the vm_amap structure and helper structures for
* this implementation.
*/
struct vm_amap_chunk {
TAILQ_ENTRY(vm_amap_chunk) ac_list;
int ac_baseslot;
uint16_t ac_usedmap;
uint16_t ac_nslot;
struct vm_anon *ac_anon[];
};
struct vm_amap {
int am_ref; /* reference count */
int am_flags; /* flags */
int am_nslot; /* # of slots currently in map */
int am_nused; /* # of slots currently in use */
#ifdef UVM_AMAP_PPREF
int *am_ppref; /* per page reference count (if !NULL) */
#endif
LIST_ENTRY(vm_amap) am_list;
union {
struct {
struct vm_amap_chunk **amn_buckets;
TAILQ_HEAD(, vm_amap_chunk) amn_chunks;
int amn_ncused; /* # of chunkers currently in use */
int amn_hashshift; /* shift count to hash slot to bucket */
} ami_normal;
/*
* MUST be last element in vm_amap because it contains a
* variably sized array element.
*/
struct vm_amap_chunk ami_small;
} am_impl;
#define am_buckets am_impl.ami_normal.amn_buckets
#define am_chunks am_impl.ami_normal.amn_chunks
#define am_ncused am_impl.ami_normal.amn_ncused
#define am_hashshift am_impl.ami_normal.amn_hashshift
#define am_small am_impl.ami_small
};
/*
* The entries in an amap are called slots. For example an amap that
* covers four pages is said to have four slots.
*
* The slots of an amap are clustered into chunks of UVM_AMAP_CHUNK
* slots each. The data structure of a chunk is vm_amap_chunk.
* Every chunk contains an array of pointers to vm_anon, and a bitmap
* is used to represent which of the slots are in use.
*
* Small amaps of up to UVM_AMAP_CHUNK slots have the chunk directly
* embedded in the amap structure.
*
* amaps with more slots are normal amaps and organize chunks in a hash
* table. The hash table is organized as an array of buckets.
* All chunks of the amap are additionally stored in a linked list.
* Chunks that belong to the same hash bucket are stored in the list
* consecutively. When all slots in a chunk are unused, the chunk is freed.
*
* For large amaps, the bucket array can grow large. See the description
* below how large bucket arrays are avoided.
*/
/*
* defines for handling of large sparce amaps:
*
* one of the problems of array-based amaps is that if you allocate a
* large sparcely-used area of virtual memory you end up allocating
* large arrays that, for the most part, don't get used. this is a
* problem for BSD in that the kernel likes to make these types of
* allocations to "reserve" memory for possible future use.
*
* for example, the kernel allocates (reserves) a large chunk of user
* VM for possible stack growth. most of the time only a page or two
* of this VM is actually used. since the stack is anonymous memory
* it makes sense for it to live in an amap, but if we allocated an
* amap for the entire stack range we could end up wasting a large
* amount of malloc'd KVM.
*
* for example, on the i386 at boot time we allocate two amaps for the stack
* of /sbin/init:
* 1. a 7680 slot amap at protection PROT_NONE (reserve space for stack)
* 2. a 512 slot amap at protection PROT_READ|PROT_WRITE (top of stack)
*
* most of the array allocated for the amaps for this is never used.
* the amap interface provides a way for us to avoid this problem by
* allowing amap_copy() to break larger amaps up into smaller sized
* chunks (controlled by the "canchunk" option). we use this feature
* to reduce our memory usage with the BSD stack management. if we
* are asked to create an amap with more than UVM_AMAP_LARGE slots in it,
* we attempt to break it up into a UVM_AMAP_CHUNK sized amap if the
* "canchunk" flag is set.
*
* so, in the i386 example, the 7680 slot area is never referenced so
* nothing gets allocated (amap_copy is never called because the protection
* is zero). the 512 slot area for the top of the stack is referenced.
* the chunking code breaks it up into 16 slot chunks (hopefully a single
* 16 slot chunk is enough to handle the whole stack).
*/
#define UVM_AMAP_LARGE 256 /* # of slots in "large" amap */
#define UVM_AMAP_CHUNK 16 /* # of slots to chunk large amaps in */
#define UVM_AMAP_SMALL(amap) ((amap)->am_nslot <= UVM_AMAP_CHUNK)
#define UVM_AMAP_SLOTIDX(slot) ((slot) % UVM_AMAP_CHUNK)
#define UVM_AMAP_BUCKET(amap, slot) \
(((slot) / UVM_AMAP_CHUNK) >> (amap)->am_hashshift)
#ifdef _KERNEL
/*
* macros
*/
/* AMAP_B2SLOT: convert byte offset to slot */
#define AMAP_B2SLOT(S,B) { \
KASSERT(((B) & (PAGE_SIZE - 1)) == 0); \
(S) = (B) >> PAGE_SHIFT; \
}
#define AMAP_CHUNK_FOREACH(chunk, amap) \
for (chunk = (UVM_AMAP_SMALL(amap) ? \
&(amap)->am_small : TAILQ_FIRST(&(amap)->am_chunks)); \
(chunk) != NULL; (chunk) = TAILQ_NEXT(chunk, ac_list))
#define AMAP_BASE_SLOT(slot) \
(((slot) / UVM_AMAP_CHUNK) * UVM_AMAP_CHUNK)
/*
* flags macros
*/
#define amap_flags(AMAP) ((AMAP)->am_flags)
#define amap_refs(AMAP) ((AMAP)->am_ref)
/*
* if we enable PPREF, then we have a couple of extra functions that
* we need to prototype here...
*/
#ifdef UVM_AMAP_PPREF
#define PPREF_NONE ((int *) -1) /* not using ppref */
/* adjust references */
void amap_pp_adjref(struct vm_amap *, int, vsize_t, int);
/* establish ppref */
void amap_pp_establish(struct vm_amap *);
/* wipe part of an amap */
void amap_wiperange(struct vm_amap *, int, int);
#endif /* UVM_AMAP_PPREF */
#endif /* _KERNEL */
#endif /* _UVM_UVM_AMAP_H_ */
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