/* $NetBSD: pmap.new.h,v 1.7 1998/08/13 21:36:05 thorpej 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. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgment: * This product includes software developed by Charles D. Cranor and * Washington University. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * 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. */ /* * pmap.h: see pmap.c for the history of this pmap module. */ #ifndef _I386_PMAP_H_ #define _I386_PMAP_H_ #include #include #include /* * see pte.h for a description of i386 MMU terminology and hardware * interface. * * a pmap describes a processes' 4GB virtual address space. this * virtual address space can be broken up into 1024 4MB regions which * are described by PDEs in the PDP. the PDEs are defined as follows: * * (ranges are inclusive -> exclusive, just like vm_map_entry start/end) * (the following assumes that KERNBASE is 0xf0000000) * * PDE#s VA range usage * 0->959 0x0 -> 0xefc00000 user address space, note that the * max user address is 0xefbfe000 * the final two pages in the last 4MB * used to be reserved for the UAREA * but now are no longer used * 959 0xefc00000-> recursive mapping of PDP (used for * 0xf0000000 linear mapping of PTPs) * 960->1023 0xf0000000-> kernel address space (constant * 0xffc00000 across all pmap's/processes) * 1023 0xffc00000-> "alternate" recursive PDP mapping * (for other pmaps) * * * note: a recursive PDP mapping provides a way to map all the PTEs for * a 4GB address space into a linear chunk of virtual memory. in other * words, the PTE for page 0 is the first int mapped into the 4MB recursive * area. the PTE for page 1 is the second int. the very last int in the * 4MB range is the PTE that maps VA 0xffffe000 (the last page in a 4GB * address). * * all pmap's PD's must have the same values in slots 960->1023 so that * the kernel is always mapped in every process. these values are loaded * into the PD at pmap creation time. * * at any one time only one pmap can be active on a processor. this is * the pmap whose PDP is pointed to by processor register %cr3. this pmap * will have all its PTEs mapped into memory at the recursive mapping * point (slot #959 as show above). when the pmap code wants to find the * PTE for a virtual address, all it has to do is the following: * * address of PTE = (959 * 4MB) + (VA / NBPG) * sizeof(pt_entry_t) * = 0xefc00000 + (VA /4096) * 4 * * what happens if the pmap layer is asked to perform an operation * on a pmap that is not the one which is currently active? in that * case we take the PA of the PDP of non-active pmap and put it in * slot 1023 of the active pmap. this causes the non-active pmap's * PTEs to get mapped in the final 4MB of the 4GB address space * (e.g. starting at 0xffc00000). * * the following figure shows the effects of the recursive PDP mapping: * * PDP (%cr3) * +----+ * | 0| -> PTP#0 that maps VA 0x0 -> 0x400000 * | | * | | * | 959| -> points back to PDP (%cr3) mapping VA 0xefc00000 -> 0xf0000000 * | 960| -> first kernel PTP (maps 0xf0000000 -> 0xf0400000) * | | * |1023| -> points to alternate pmap's PDP (maps 0xffc00000 -> end) * +----+ * * note that the PDE#959 VA (0xefc00000) is defined as "PTE_BASE" * note that the PDE#1023 VA (0xffc00000) is defined as "APTE_BASE" * * starting at VA 0xefc00000 the current active PDP (%cr3) acts as a * PTP: * * PTP#959 == PDP(%cr3) => maps VA 0xefc00000 -> 0xf0000000 * +----+ * | 0| -> maps the contents of PTP#0 at VA 0xefc00000->0xefc01000 * | | * | | * | 959| -> maps contents of PTP#959 (the PDP) at VA 0xeffbf000 * | 960| -> maps contents of first kernel PTP * | | * |1023| * +----+ * * note that mapping of the PDP at PTP#959's VA (0xeffbf000) is * defined as "PDP_BASE".... within that mapping there are two * defines: * "PDP_PDE" (0xeffbfefc) is the VA of the PDE in the PDP * which points back to itself. * "APDP_PDE" (0xeffbfffc) is the VA of the PDE in the PDP which * establishes the recursive mapping of the alternate pmap. * to set the alternate PDP, one just has to put the correct * PA info in *APDP_PDE. * * note that in the APTE_BASE space, the APDP appears at VA * "APDP_BASE" (0xfffff000). */ /* * the following defines identify the slots used as described above. */ #define PDSLOT_PTE ((KERNBASE/NBPD)-1) /* 959: for recursive PDP map */ #define PDSLOT_KERN (KERNBASE/NBPD) /* 960: start of kernel space */ #define PDSLOT_APTE ((unsigned)1023) /* 1023: alternative recursive slot */ /* * the following defines give the virtual addresses of various MMU * data structures: * PTE_BASE and APTE_BASE: the base VA of the linear PTE mappings * PTD_BASE and APTD_BASE: the base VA of the recursive mapping of the PTD * PDP_PDE and APDP_PDE: the VA of the PDE that points back to the PDP/APDP */ #define PTE_BASE ((pt_entry_t *) (PDSLOT_PTE * NBPD) ) #define APTE_BASE ((pt_entry_t *) (PDSLOT_APTE * NBPD) ) #define PDP_BASE ((pd_entry_t *) (((char *)PTE_BASE) + (PDSLOT_PTE * NBPG)) ) #define APDP_BASE ((pd_entry_t *) (((char *)APTE_BASE) + (PDSLOT_APTE * NBPG)) ) #define PDP_PDE (PDP_BASE + PDSLOT_PTE) #define APDP_PDE (PDP_BASE + PDSLOT_APTE) /* * XXXCDC: tmp xlate from old names: * PTDPTDI -> PDSLOT_PTE * KPTDI -> PDSLOT_KERN * APTDPTDI -> PDSLOT_APTE */ /* * the follow define determines how many PTPs should be set up for the * kernel by locore.s at boot time. this should be large enough to * get the VM system running. once the VM system is running, the * pmap module can add more PTPs to the kernel area on demand. */ #ifndef NKPTP #define NKPTP 4 /* 16MB to start */ #endif #define NKPTP_MIN 4 /* smallest value we allow */ #define NKPTP_MAX (1024 - (KERNBASE/NBPD) - 1) /* largest value (-1 for APTP space) */ /* * various address macros * * vtopte: return a pointer to the PTE mapping a VA * kvtopte: same as above (takes a KVA, but doesn't matter with this pmap) * ptetov: given a pointer to a PTE, return the VA that it maps * vtophys: translate a VA to the PA mapped to it * * plus alternative versions of the above */ #define vtopte(VA) (PTE_BASE + i386_btop(VA)) #define kvtopte(VA) vtopte(VA) #define ptetov(PT) (i386_ptob(PT - PTE_BASE)) #define vtophys(VA) ((*vtopte(VA) & PG_FRAME) | ((unsigned)(VA) & ~PG_FRAME)) #define avtopte(VA) (APTE_BASE + i386_btop(VA)) #define ptetoav(PT) (i386_ptob(PT - APTE_BASE)) #define avtophys(VA) ((*avtopte(VA) & PG_FRAME) | ((unsigned)(VA) & ~PG_FRAME)) /* * pdei/ptei: generate index into PDP/PTP from a VA */ #define pdei(VA) (((VA) & PD_MASK) >> PDSHIFT) #define ptei(VA) (((VA) & PT_MASK) >> PGSHIFT) /* * PTP macros: * a PTP's index is the PD index of the PDE that points to it * a PTP's offset is the byte-offset in the PTE space that this PTP is at * a PTP's VA is the first VA mapped by that PTP * * note that NBPG == number of bytes in a PTP (4096 bytes == 1024 entries) * NBPD == number of bytes a PTP can map (4MB) */ #define ptp_i2o(I) ((I) * NBPG) /* index => offset */ #define ptp_o2i(O) ((O) / NBPG) /* offset => index */ #define ptp_i2v(I) ((I) * NBPD) /* index => VA */ #define ptp_v2i(V) ((V) / NBPD) /* VA => index (same as pdei) */ /* * PG_AVAIL usage: we make use of the ignored bits of the PTE */ #define PG_W PG_AVAIL1 /* "wired" mapping */ #define PG_PVLIST PG_AVAIL2 /* mapping has entry on pvlist */ /* PG_AVAIL3 not used */ #ifdef _KERNEL /* * pmap data structures: see pmap.c for details of locking. */ struct pmap; typedef struct pmap *pmap_t; /* * we maintain a list of all non-kernel pmaps */ LIST_HEAD(pmap_head, pmap); /* struct pmap_head: head of a pmap list */ /* * the pmap structure * * note that the pm_obj contains the simple_lock, the reference count, * page list, and number of PTPs within the pmap. */ struct pmap { struct uvm_object pm_obj; /* object (lck by object lock) */ LIST_ENTRY(pmap) pm_list; /* list (lck by pm_list lock) */ pd_entry_t *pm_pdir; /* VA of PD (lck by object lock) */ u_int32_t pm_pdirpa; /* PA of PD (read-only after create) */ struct vm_page *pm_ptphint; /* pointer to a random PTP in our pmap */ struct pmap_statistics pm_stats; /* pmap stats (lck by object lock) */ }; /* * for each managed physical page we maintain a list of 's * which it is mapped at. the list is headed by a pv_head structure. * there is one pv_head per managed phys page (allocated at boot time). * the pv_head structure points to a list of pv_entry structures (each * describes one mapping). */ struct pv_entry; struct pv_head { simple_lock_data_t pvh_lock; /* locks every pv on this list */ struct pv_entry *pvh_list; /* head of list (locked by pvh_lock) */ }; struct pv_entry { /* all fields locked by their pvh_lock */ struct pv_entry *pv_next; /* next entry */ struct pmap *pv_pmap; /* the pmap */ vaddr_t pv_va; /* the virtual address */ struct vm_page *pv_ptp; /* the vm_page of the PTP */ }; /* * pv_entrys are dynamically allocated in chunks from a single page. * we keep track of how many pv_entrys are in use for each page and * we can free pv_entry pages if needed. there is one lock for the * entire allocation system. */ struct pv_page_info { TAILQ_ENTRY(pv_page) pvpi_list; struct pv_entry *pvpi_pvfree; int pvpi_nfree; }; /* * number of pv_entry's in a pv_page * (note: won't work on systems where NPBG isn't a constant) */ #define PVE_PER_PVPAGE ( (NBPG - sizeof(struct pv_page_info)) / \ sizeof(struct pv_entry) ) /* * a pv_page: where pv_entrys are allocated from */ struct pv_page { struct pv_page_info pvinfo; struct pv_entry pvents[PVE_PER_PVPAGE]; }; /* * pmap_remove_record: a record of VAs that have been unmapped, used to * flush TLB. if we have more than PMAP_RR_MAX then we stop recording. */ #define PMAP_RR_MAX 16 /* max of 16 pages (64K) */ struct pmap_remove_record { int prr_npages; vaddr_t prr_vas[PMAP_RR_MAX]; }; /* * pmap_transfer_location: used to pass the current location in the * pmap between pmap_transfer and pmap_transfer_ptes [e.g. during * a pmap_copy]. */ struct pmap_transfer_location { vaddr_t addr; /* the address (page-aligned) */ pt_entry_t *pte; /* the PTE that maps address */ struct vm_page *ptp; /* the PTP that the PTE lives in */ }; /* * global kernel variables */ /* PTDpaddr: is the physical address of the kernel's PDP */ extern u_long PTDpaddr; extern struct pmap kernel_pmap_store; /* kernel pmap */ extern int nkpde; /* current # of PDEs for kernel */ extern int pmap_pg_g; /* do we support PG_G? */ /* * macros */ #define pmap_kernel() (&kernel_pmap_store) #define pmap_resident_count(pmap) ((pmap)->pm_stats.resident_count) #define pmap_update() tlbflush() #define pmap_clear_modify(pg) pmap_change_attrs(pg, 0, PG_M) #define pmap_clear_reference(pg) pmap_change_attrs(pg, 0, PG_U) #define pmap_copy(DP,SP,D,L,S) pmap_transfer(DP,SP,D,L,S, FALSE) #define pmap_is_modified(pg) pmap_test_attrs(pg, PG_M) #define pmap_is_referenced(pg) pmap_test_attrs(pg, PG_U) #define pmap_move(DP,SP,D,L,S) pmap_transfer(DP,SP,D,L,S, TRUE) #define pmap_phys_address(ppn) i386_ptob(ppn) #define pmap_valid_entry(E) ((E) & PG_V) /* is PDE or PTE valid? */ /* * prototypes */ void pmap_activate __P((struct proc *)); void pmap_bootstrap __P((vaddr_t)); boolean_t pmap_change_attrs __P((struct vm_page *, int, int)); void pmap_deactivate __P((struct proc *)); static void pmap_kenter_pa __P((vaddr_t, paddr_t, vm_prot_t)); static void pmap_page_protect __P((struct vm_page *, vm_prot_t)); void pmap_page_remove __P((struct vm_page *)); static void pmap_protect __P((struct pmap *, vaddr_t, vaddr_t, vm_prot_t)); void pmap_remove __P((struct pmap *, vaddr_t, vaddr_t)); boolean_t pmap_test_attrs __P((struct vm_page *, int)); void pmap_transfer __P((struct pmap *, struct pmap *, vaddr_t, vsize_t, vaddr_t, boolean_t)); static void pmap_update_pg __P((vaddr_t)); static void pmap_update_2pg __P((vaddr_t,vaddr_t)); void pmap_write_protect __P((struct pmap *, vaddr_t, vaddr_t, vm_prot_t)); vaddr_t reserve_dumppages __P((vaddr_t)); /* XXX: not a pmap fn */ #define PMAP_GROWKERNEL /* turn on pmap_growkernel interface */ /* * inline functions */ /* * pmap_update_pg: flush one page from the TLB (or flush the whole thing * if hardware doesn't support one-page flushing) */ __inline static void pmap_update_pg(va) vaddr_t va; { #if defined(I386_CPU) if (cpu_class == CPUCLASS_386) pmap_update(); else #endif invlpg((u_int) va); } /* * pmap_update_2pg: flush two pages from the TLB */ __inline static void pmap_update_2pg(va, vb) vaddr_t va, vb; { #if defined(I386_CPU) if (cpu_class == CPUCLASS_386) pmap_update(); else #endif { invlpg((u_int) va); invlpg((u_int) vb); } } /* * pmap_page_protect: change the protection of all recorded mappings * of a managed page * * => this function is a frontend for pmap_page_remove/pmap_change_attrs * => we only have to worry about making the page more protected. * unprotecting a page is done on-demand at fault time. */ __inline static void pmap_page_protect(pg, prot) struct vm_page *pg; vm_prot_t prot; { if ((prot & VM_PROT_WRITE) == 0) { if (prot & (VM_PROT_READ|VM_PROT_EXECUTE)) { (void) pmap_change_attrs(pg, PG_RO, PG_RW); } else { pmap_page_remove(pg); } } } /* * pmap_protect: change the protection of pages in a pmap * * => this function is a frontend for pmap_remove/pmap_write_protect * => we only have to worry about making the page more protected. * unprotecting a page is done on-demand at fault time. */ __inline static void pmap_protect(pmap, sva, eva, prot) struct pmap *pmap; vaddr_t sva, eva; vm_prot_t prot; { if ((prot & VM_PROT_WRITE) == 0) { if (prot & (VM_PROT_READ|VM_PROT_EXECUTE)) { pmap_write_protect(pmap, sva, eva, prot); } else { pmap_remove(pmap, sva, eva); } } } /* * pmap_kenter_pa: enter a kernel mapping without R/M (pv_entry) tracking * * => no need to lock anything, assume va is already allocated * => should be faster than normal pmap enter function */ __inline static void pmap_kenter_pa(va, pa, prot) vaddr_t va; paddr_t pa; vm_prot_t prot; { pt_entry_t *pte, opte; pte = vtopte(va); opte = *pte; *pte = pa | ((prot & VM_PROT_WRITE)? PG_RW : PG_RO) | PG_V | pmap_pg_g; /* zap! */ if (pmap_valid_entry(opte)) pmap_update_pg(va); } vaddr_t pmap_map __P((vaddr_t, paddr_t, paddr_t, int)); #endif /* _KERNEL */ #endif /* _I386_PMAP_H_ */