xen/x86/x86_xpmap.c

1.5  bouyer /*	$NetBSD: x86_xpmap.c,v 1.5 2008/01/15 19:55:53 bouyer Exp $	*/
1.2  bouyer
1.2  bouyer /*
1.2  bouyer  * Copyright (c) 2006 Mathieu Ropert <mro (at) adviseo.fr>
1.2  bouyer  *
1.2  bouyer  * Permission to use, copy, modify, and distribute this software for any
1.2  bouyer  * purpose with or without fee is hereby granted, provided that the above
1.2  bouyer  * copyright notice and this permission notice appear in all copies.
1.2  bouyer  *
1.2  bouyer  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
1.2  bouyer  * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
1.2  bouyer  * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
1.2  bouyer  * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
1.2  bouyer  * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
1.2  bouyer  * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
1.2  bouyer  * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
1.2  bouyer  */
1.2  bouyer
1.2  bouyer /*
1.2  bouyer  * Copyright (c) 2006, 2007 Manuel Bouyer.
1.2  bouyer  *
1.2  bouyer  * Redistribution and use in source and binary forms, with or without
1.2  bouyer  * modification, are permitted provided that the following conditions
1.2  bouyer  * are met:
1.2  bouyer  * 1. Redistributions of source code must retain the above copyright
1.2  bouyer  *    notice, this list of conditions and the following disclaimer.
1.2  bouyer  * 2. Redistributions in binary form must reproduce the above copyright
1.2  bouyer  *    notice, this list of conditions and the following disclaimer in the
1.2  bouyer  *    documentation and/or other materials provided with the distribution.
1.2  bouyer  * 3. All advertising materials mentioning features or use of this software
1.2  bouyer  *    must display the following acknowledgement:
1.2  bouyer  *	This product includes software developed by Manuel Bouyer.
1.2  bouyer  * 4. The name of the author may not be used to endorse or promote products
1.2  bouyer  *    derived from this software without specific prior written permission.
1.2  bouyer  *
1.2  bouyer  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.2  bouyer  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.2  bouyer  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.2  bouyer  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.2  bouyer  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.2  bouyer  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.2  bouyer  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.2  bouyer  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.2  bouyer  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.2  bouyer  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.2  bouyer  *
1.2  bouyer  */
1.2  bouyer
1.2  bouyer /*
1.2  bouyer  *
1.2  bouyer  * Copyright (c) 2004 Christian Limpach.
1.2  bouyer  * All rights reserved.
1.2  bouyer  *
1.2  bouyer  * Redistribution and use in source and binary forms, with or without
1.2  bouyer  * modification, are permitted provided that the following conditions
1.2  bouyer  * are met:
1.2  bouyer  * 1. Redistributions of source code must retain the above copyright
1.2  bouyer  *    notice, this list of conditions and the following disclaimer.
1.2  bouyer  * 2. Redistributions in binary form must reproduce the above copyright
1.2  bouyer  *    notice, this list of conditions and the following disclaimer in the
1.2  bouyer  *    documentation and/or other materials provided with the distribution.
1.2  bouyer  * 3. All advertising materials mentioning features or use of this software
1.2  bouyer  *    must display the following acknowledgement:
1.2  bouyer  *      This product includes software developed by Christian Limpach.
1.2  bouyer  * 4. The name of the author may not be used to endorse or promote products
1.2  bouyer  *    derived from this software without specific prior written permission.
1.2  bouyer  *
1.2  bouyer  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.2  bouyer  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.2  bouyer  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.2  bouyer  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.2  bouyer  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.2  bouyer  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.2  bouyer  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.2  bouyer  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.2  bouyer  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.2  bouyer  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.2  bouyer  */
1.2  bouyer
1.2  bouyer
1.2  bouyer #include <sys/cdefs.h>
1.5  bouyer __KERNEL_RCSID(0, "$NetBSD: x86_xpmap.c,v 1.5 2008/01/15 19:55:53 bouyer Exp $");
1.2  bouyer
1.2  bouyer #include "opt_xen.h"
1.4  bouyer #include "opt_ddb.h"
1.4  bouyer #include "ksyms.h"
1.2  bouyer
1.2  bouyer #include <sys/param.h>
1.2  bouyer #include <sys/systm.h>
1.2  bouyer
1.2  bouyer #include <uvm/uvm.h>
1.2  bouyer
1.2  bouyer #include <machine/pmap.h>
1.2  bouyer #include <machine/gdt.h>
1.2  bouyer #include <xen/xenfunc.h>
1.2  bouyer
1.2  bouyer #include <dev/isa/isareg.h>
1.2  bouyer #include <machine/isa_machdep.h>
1.2  bouyer
1.2  bouyer #undef	XENDEBUG
1.2  bouyer /* #define XENDEBUG_SYNC */
1.2  bouyer /* #define	XENDEBUG_LOW */
1.2  bouyer
1.2  bouyer #ifdef XENDEBUG
1.2  bouyer #define	XENPRINTF(x) printf x
1.2  bouyer #define	XENPRINTK(x) printk x
1.2  bouyer #define	XENPRINTK2(x) /* printk x */
1.2  bouyer
1.2  bouyer static char XBUF[256];
1.2  bouyer #else
1.2  bouyer #define	XENPRINTF(x)
1.2  bouyer #define	XENPRINTK(x)
1.2  bouyer #define	XENPRINTK2(x)
1.2  bouyer #endif
1.2  bouyer #define	PRINTF(x) printf x
1.2  bouyer #define	PRINTK(x) printk x
1.2  bouyer
1.4  bouyer /* on x86_64 kernel runs in ring 3 */
1.4  bouyer #ifdef __x86_64__
1.4  bouyer #define PG_k PG_u
1.4  bouyer #else
1.4  bouyer #define PG_k 0
1.4  bouyer #endif
1.4  bouyer
1.2  bouyer volatile shared_info_t *HYPERVISOR_shared_info;
1.2  bouyer union start_info_union start_info_union;
1.4  bouyer paddr_t *xpmap_phys_to_machine_mapping;
1.2  bouyer
1.2  bouyer void xen_failsafe_handler(void);
1.2  bouyer
1.2  bouyer #ifdef XEN3
1.2  bouyer #define HYPERVISOR_mmu_update_self(req, count, success_count) \
1.2  bouyer 	HYPERVISOR_mmu_update((req), (count), (success_count), DOMID_SELF)
1.2  bouyer #else
1.2  bouyer #define HYPERVISOR_mmu_update_self(req, count, success_count) \
1.2  bouyer 	HYPERVISOR_mmu_update((req), (count), (success_count))
1.2  bouyer #endif
1.2  bouyer
1.2  bouyer void
1.2  bouyer xen_failsafe_handler(void)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	panic("xen_failsafe_handler called!\n");
1.2  bouyer }
1.2  bouyer
1.2  bouyer
1.2  bouyer void
1.2  bouyer xen_set_ldt(vaddr_t base, uint32_t entries)
1.2  bouyer {
1.2  bouyer 	vaddr_t va;
1.2  bouyer 	vaddr_t end;
1.4  bouyer 	pt_entry_t *ptp;
1.2  bouyer 	int s;
1.2  bouyer
1.2  bouyer #ifdef __x86_64__
1.2  bouyer 	end = base + (entries << 3);
1.2  bouyer #else
1.2  bouyer 	end = base + entries * sizeof(union descriptor);
1.2  bouyer #endif
1.2  bouyer
1.2  bouyer 	for (va = base; va < end; va += PAGE_SIZE) {
1.2  bouyer 		KASSERT(va >= VM_MIN_KERNEL_ADDRESS);
1.2  bouyer 		ptp = kvtopte(va);
1.5  bouyer 		XENPRINTF(("xen_set_ldt %p %d %p\n", (void *)base,
1.5  bouyer 			      entries, ptp));
1.4  bouyer 		pmap_pte_clearbits(ptp, PG_RW);
1.2  bouyer 	}
1.2  bouyer 	s = splvm();
1.2  bouyer 	xpq_queue_set_ldt(base, entries);
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer 	splx(s);
1.2  bouyer }
1.2  bouyer
1.2  bouyer #ifdef XENDEBUG
1.2  bouyer void xpq_debug_dump(void);
1.2  bouyer #endif
1.2  bouyer
1.2  bouyer #define XPQUEUE_SIZE 2048
1.2  bouyer static mmu_update_t xpq_queue[XPQUEUE_SIZE];
1.2  bouyer static int xpq_idx = 0;
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_flush_queue()
1.2  bouyer {
1.2  bouyer 	int i, ok;
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("flush queue %p entries %d\n", xpq_queue, xpq_idx));
1.2  bouyer 	for (i = 0; i < xpq_idx; i++)
1.2  bouyer 		XENPRINTK2(("%d: %p %08x\n", i, (u_int)xpq_queue[i].ptr,
1.2  bouyer 		    (u_int)xpq_queue[i].val));
1.2  bouyer 	if (xpq_idx != 0 &&
1.2  bouyer 	    HYPERVISOR_mmu_update_self(xpq_queue, xpq_idx, &ok) < 0) {
1.2  bouyer 		printf("xpq_flush_queue: %d entries \n", xpq_idx);
1.2  bouyer 		for (i = 0; i < xpq_idx; i++)
1.3  bouyer 			printf("0x%016" PRIx64 ": 0x%016" PRIx64 "\n",
1.3  bouyer 			   (u_int64_t)xpq_queue[i].ptr,
1.3  bouyer 			   (u_int64_t)xpq_queue[i].val);
1.2  bouyer 		panic("HYPERVISOR_mmu_update failed\n");
1.2  bouyer 	}
1.2  bouyer 	xpq_idx = 0;
1.2  bouyer }
1.2  bouyer
1.2  bouyer static inline void
1.2  bouyer xpq_increment_idx(void)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	xpq_idx++;
1.2  bouyer 	if (__predict_false(xpq_idx == XPQUEUE_SIZE))
1.2  bouyer 		xpq_flush_queue();
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_machphys_update(paddr_t ma, paddr_t pa)
1.2  bouyer {
1.2  bouyer 	XENPRINTK2(("xpq_queue_machphys_update ma=%p pa=%p\n", (void *)ma, (void *)pa));
1.2  bouyer 	xpq_queue[xpq_idx].ptr = ma | MMU_MACHPHYS_UPDATE;
1.2  bouyer 	xpq_queue[xpq_idx].val = (pa - XPMAP_OFFSET) >> PAGE_SHIFT;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer #ifdef XENDEBUG_SYNC
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer #endif
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_pde_update(pd_entry_t *ptr, pd_entry_t val)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	KASSERT(((paddr_t)ptr & 3) == 0);
1.2  bouyer 	xpq_queue[xpq_idx].ptr = (paddr_t)ptr | MMU_NORMAL_PT_UPDATE;
1.2  bouyer 	xpq_queue[xpq_idx].val = val;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer #ifdef XENDEBUG_SYNC
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer #endif
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_pte_update(pt_entry_t *ptr, pt_entry_t val)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	KASSERT(((paddr_t)ptr & 3) == 0);
1.2  bouyer 	xpq_queue[xpq_idx].ptr = (paddr_t)ptr | MMU_NORMAL_PT_UPDATE;
1.2  bouyer 	xpq_queue[xpq_idx].val = val;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer #ifdef XENDEBUG_SYNC
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer #endif
1.2  bouyer }
1.2  bouyer
1.2  bouyer #ifdef XEN3
1.2  bouyer void
1.2  bouyer xpq_queue_pt_switch(paddr_t pa)
1.2  bouyer {
1.2  bouyer 	struct mmuext_op op;
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_pt_switch: %p %p\n", (void *)pa, (void *)pa));
1.2  bouyer 	op.cmd = MMUEXT_NEW_BASEPTR;
1.2  bouyer 	op.arg1.mfn = pa >> PAGE_SHIFT;
1.2  bouyer 	if (HYPERVISOR_mmuext_op(&op, 1, NULL, DOMID_SELF) < 0)
1.2  bouyer 		panic("xpq_queue_pt_switch");
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_pin_table(paddr_t pa)
1.2  bouyer {
1.2  bouyer 	struct mmuext_op op;
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_pin_table: %p %p\n", (void *)pa, (void *)pa));
1.2  bouyer 	op.arg1.mfn = pa >> PAGE_SHIFT;
1.2  bouyer
1.2  bouyer #ifdef __x86_64__
1.2  bouyer 	op.cmd = MMUEXT_PIN_L4_TABLE;
1.2  bouyer #else
1.2  bouyer 	op.cmd = MMUEXT_PIN_L2_TABLE;
1.2  bouyer #endif
1.2  bouyer 	if (HYPERVISOR_mmuext_op(&op, 1, NULL, DOMID_SELF) < 0)
1.2  bouyer 		panic("xpq_queue_pin_table");
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_unpin_table(paddr_t pa)
1.2  bouyer {
1.2  bouyer 	struct mmuext_op op;
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_unpin_table: %p %p\n", (void *)pa, (void *)pa));
1.2  bouyer 	op.arg1.mfn = pa >> PAGE_SHIFT;
1.2  bouyer 	op.cmd = MMUEXT_UNPIN_TABLE;
1.2  bouyer 	if (HYPERVISOR_mmuext_op(&op, 1, NULL, DOMID_SELF) < 0)
1.2  bouyer 		panic("xpq_queue_unpin_table");
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_set_ldt(vaddr_t va, uint32_t entries)
1.2  bouyer {
1.2  bouyer 	struct mmuext_op op;
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_set_ldt\n"));
1.2  bouyer 	KASSERT(va == (va & ~PAGE_MASK));
1.2  bouyer 	op.cmd = MMUEXT_SET_LDT;
1.2  bouyer 	op.arg1.linear_addr = va;
1.2  bouyer 	op.arg2.nr_ents = entries;
1.2  bouyer 	if (HYPERVISOR_mmuext_op(&op, 1, NULL, DOMID_SELF) < 0)
1.2  bouyer 		panic("xpq_queue_set_ldt");
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_tlb_flush()
1.2  bouyer {
1.2  bouyer 	struct mmuext_op op;
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_tlb_flush\n"));
1.2  bouyer 	op.cmd = MMUEXT_TLB_FLUSH_LOCAL;
1.2  bouyer 	if (HYPERVISOR_mmuext_op(&op, 1, NULL, DOMID_SELF) < 0)
1.2  bouyer 		panic("xpq_queue_tlb_flush");
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_flush_cache()
1.2  bouyer {
1.2  bouyer 	struct mmuext_op op;
1.2  bouyer 	int s = splvm();
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_flush_cache\n"));
1.2  bouyer 	op.cmd = MMUEXT_FLUSH_CACHE;
1.2  bouyer 	if (HYPERVISOR_mmuext_op(&op, 1, NULL, DOMID_SELF) < 0)
1.2  bouyer 		panic("xpq_flush_cache");
1.2  bouyer 	splx(s);
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_invlpg(vaddr_t va)
1.2  bouyer {
1.2  bouyer 	struct mmuext_op op;
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_invlpg %p\n", (void *)va));
1.2  bouyer 	op.cmd = MMUEXT_INVLPG_LOCAL;
1.2  bouyer 	op.arg1.linear_addr = (va & ~PAGE_MASK);
1.2  bouyer 	if (HYPERVISOR_mmuext_op(&op, 1, NULL, DOMID_SELF) < 0)
1.2  bouyer 		panic("xpq_queue_invlpg");
1.2  bouyer }
1.2  bouyer
1.2  bouyer int
1.2  bouyer xpq_update_foreign(pt_entry_t *ptr, pt_entry_t val, int dom)
1.2  bouyer {
1.2  bouyer 	mmu_update_t op;
1.2  bouyer 	int ok;
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer
1.2  bouyer 	op.ptr = (paddr_t)ptr;
1.2  bouyer 	op.val = val;
1.2  bouyer 	if (HYPERVISOR_mmu_update(&op, 1, &ok, dom) < 0)
1.2  bouyer 		return EFAULT;
1.2  bouyer 	return (0);
1.2  bouyer }
1.2  bouyer #else /* XEN3 */
1.2  bouyer void
1.2  bouyer xpq_queue_pt_switch(paddr_t pa)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_pt_switch: %p %p\n", (void *)pa, (void *)pa));
1.2  bouyer 	xpq_queue[xpq_idx].ptr = pa | MMU_EXTENDED_COMMAND;
1.2  bouyer 	xpq_queue[xpq_idx].val = MMUEXT_NEW_BASEPTR;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_pin_table(paddr_t pa)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_pin_table: %p %p\n", (void *)pa, (void *)pa));
1.2  bouyer 	xpq_queue[xpq_idx].ptr = pa | MMU_EXTENDED_COMMAND;
1.2  bouyer 	xpq_queue[xpq_idx].val = MMUEXT_PIN_L2_TABLE;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_unpin_table(paddr_t pa)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_unpin_table: %p %p\n", (void *)pa, (void *)pa));
1.2  bouyer 	xpq_queue[xpq_idx].ptr = pa | MMU_EXTENDED_COMMAND;
1.2  bouyer 	xpq_queue[xpq_idx].val = MMUEXT_UNPIN_TABLE;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_set_ldt(vaddr_t va, uint32_t entries)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_set_ldt\n"));
1.2  bouyer 	KASSERT(va == (va & ~PAGE_MASK));
1.2  bouyer 	xpq_queue[xpq_idx].ptr = MMU_EXTENDED_COMMAND | va;
1.2  bouyer 	xpq_queue[xpq_idx].val = MMUEXT_SET_LDT | (entries << MMUEXT_CMD_SHIFT);
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_tlb_flush()
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_tlb_flush\n"));
1.2  bouyer 	xpq_queue[xpq_idx].ptr = MMU_EXTENDED_COMMAND;
1.2  bouyer 	xpq_queue[xpq_idx].val = MMUEXT_TLB_FLUSH;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_flush_cache()
1.2  bouyer {
1.2  bouyer 	int s = splvm();
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_flush_cache\n"));
1.2  bouyer 	xpq_queue[xpq_idx].ptr = MMU_EXTENDED_COMMAND;
1.2  bouyer 	xpq_queue[xpq_idx].val = MMUEXT_FLUSH_CACHE;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer 	splx(s);
1.2  bouyer }
1.2  bouyer
1.2  bouyer void
1.2  bouyer xpq_queue_invlpg(vaddr_t va)
1.2  bouyer {
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("xpq_queue_invlpg %p\n", (void *)va));
1.2  bouyer 	xpq_queue[xpq_idx].ptr = (va & ~PAGE_MASK) | MMU_EXTENDED_COMMAND;
1.2  bouyer 	xpq_queue[xpq_idx].val = MMUEXT_INVLPG;
1.2  bouyer 	xpq_increment_idx();
1.2  bouyer }
1.2  bouyer
1.2  bouyer int
1.2  bouyer xpq_update_foreign(pt_entry_t *ptr, pt_entry_t val, int dom)
1.2  bouyer {
1.2  bouyer 	mmu_update_t xpq_up[3];
1.2  bouyer
1.2  bouyer 	xpq_up[0].ptr = MMU_EXTENDED_COMMAND;
1.2  bouyer 	xpq_up[0].val = MMUEXT_SET_FOREIGNDOM | (dom << 16);
1.2  bouyer 	xpq_up[1].ptr = (paddr_t)ptr;
1.2  bouyer 	xpq_up[1].val = val;
1.2  bouyer 	if (HYPERVISOR_mmu_update_self(xpq_up, 2, NULL) < 0)
1.2  bouyer 		return EFAULT;
1.2  bouyer 	return (0);
1.2  bouyer }
1.2  bouyer #endif /* XEN3 */
1.2  bouyer
1.2  bouyer #ifdef XENDEBUG
1.2  bouyer void
1.2  bouyer xpq_debug_dump()
1.2  bouyer {
1.2  bouyer 	int i;
1.2  bouyer
1.2  bouyer 	XENPRINTK2(("idx: %d\n", xpq_idx));
1.2  bouyer 	for (i = 0; i < xpq_idx; i++) {
1.2  bouyer 		sprintf(XBUF, "%x %08x ", (u_int)xpq_queue[i].ptr,
1.2  bouyer 		    (u_int)xpq_queue[i].val);
1.2  bouyer 		if (++i < xpq_idx)
1.2  bouyer 			sprintf(XBUF + strlen(XBUF), "%x %08x ",
1.2  bouyer 			    (u_int)xpq_queue[i].ptr, (u_int)xpq_queue[i].val);
1.2  bouyer 		if (++i < xpq_idx)
1.2  bouyer 			sprintf(XBUF + strlen(XBUF), "%x %08x ",
1.2  bouyer 			    (u_int)xpq_queue[i].ptr, (u_int)xpq_queue[i].val);
1.2  bouyer 		if (++i < xpq_idx)
1.2  bouyer 			sprintf(XBUF + strlen(XBUF), "%x %08x ",
1.2  bouyer 			    (u_int)xpq_queue[i].ptr, (u_int)xpq_queue[i].val);
1.2  bouyer 		XENPRINTK2(("%d: %s\n", xpq_idx, XBUF));
1.2  bouyer 	}
1.2  bouyer }
1.2  bouyer #endif
1.2  bouyer
1.2  bouyer
1.2  bouyer extern volatile struct xencons_interface *xencons_interface; /* XXX */
1.2  bouyer extern struct xenstore_domain_interface *xenstore_interface; /* XXX */
1.2  bouyer
1.2  bouyer static void xen_bt_set_readonly (vaddr_t);
1.2  bouyer static void xen_bootstrap_tables (vaddr_t, vaddr_t, int, int, int);
1.2  bouyer
1.2  bouyer /* How many PDEs ? */
1.2  bouyer #if L2_SLOT_KERNBASE > 0
1.2  bouyer #define TABLE_L2_ENTRIES (2 * (NKL2_KIMG_ENTRIES + 1))
1.2  bouyer #else
1.2  bouyer #define TABLE_L2_ENTRIES (NKL2_KIMG_ENTRIES + 1)
1.2  bouyer #endif
1.2  bouyer
1.2  bouyer /*
1.2  bouyer  * Construct and switch to new pagetables
1.2  bouyer  * first_avail is the first vaddr we can use after
1.2  bouyer  * we get rid of Xen pagetables
1.2  bouyer  */
1.2  bouyer
1.2  bouyer vaddr_t xen_pmap_bootstrap (void);
1.2  bouyer
1.2  bouyer /*
1.2  bouyer  * Function to get rid of Xen bootstrap tables
1.2  bouyer  */
1.2  bouyer
1.2  bouyer vaddr_t
1.2  bouyer xen_pmap_bootstrap()
1.2  bouyer {
1.4  bouyer 	int count, oldcount;
1.4  bouyer 	long mapsize;
1.4  bouyer 	const int l2_4_count = PTP_LEVELS - 1;
1.2  bouyer 	vaddr_t bootstrap_tables, init_tables;
1.2  bouyer
1.2  bouyer 	xpmap_phys_to_machine_mapping = (paddr_t *) xen_start_info.mfn_list;
1.2  bouyer 	init_tables = xen_start_info.pt_base;
1.2  bouyer 	__PRINTK(("xen_arch_pmap_bootstrap init_tables=0x%lx\n", init_tables));
1.2  bouyer
1.2  bouyer 	/* Space after Xen boostrap tables should be free */
1.2  bouyer 	bootstrap_tables = xen_start_info.pt_base +
1.2  bouyer 		(xen_start_info.nr_pt_frames * PAGE_SIZE);
1.2  bouyer
1.4  bouyer 	/*
1.4  bouyer 	 * Calculate how many space we need
1.4  bouyer 	 * first everything mapped before the Xen bootstrap tables
1.4  bouyer 	 */
1.4  bouyer 	mapsize = init_tables - KERNTEXTOFF;
1.4  bouyer 	/* after the tables we'll have:
1.4  bouyer 	 *  - UAREA
1.4  bouyer 	 *  - dummy user PGD (x86_64)
1.4  bouyer 	 *  - HYPERVISOR_shared_info
1.4  bouyer 	 *  - ISA I/O mem (if needed)
1.4  bouyer 	 */
1.4  bouyer 	mapsize += UPAGES * NBPG;
1.4  bouyer #ifdef __x86_64__
1.4  bouyer 	mapsize += NBPG;
1.4  bouyer #endif
1.4  bouyer 	mapsize += NBPG;
1.2  bouyer
1.2  bouyer #ifdef DOM0OPS
1.2  bouyer 	if (xen_start_info.flags & SIF_INITDOMAIN) {
1.2  bouyer 		/* space for ISA I/O mem */
1.4  bouyer 		mapsize += IOM_SIZE;
1.4  bouyer 	}
1.4  bouyer #endif
1.4  bouyer 	/* at this point mapsize doens't include the table size */
1.4  bouyer
1.4  bouyer #ifdef __x86_64__
1.4  bouyer 	count = TABLE_L2_ENTRIES;
1.4  bouyer #else
1.4  bouyer 	count = (mapsize + (NBPD_L2 -1)) >> L2_SHIFT;
1.4  bouyer #endif /* __x86_64__ */
1.4  bouyer
1.4  bouyer 	/* now compute how many L2 pages we need exactly */
1.4  bouyer 	XENPRINTK(("bootstrap_final mapsize 0x%lx count %d\n", mapsize, count));
1.4  bouyer 	while (mapsize + (count + l2_4_count) * PAGE_SIZE + KERNTEXTOFF >
1.4  bouyer 	    ((long)count << L2_SHIFT) + KERNBASE) {
1.4  bouyer 		count++;
1.2  bouyer 	}
1.4  bouyer #ifndef __x86_64__
1.5  bouyer 	/*
1.5  bouyer 	 * one more L2 page: we'll alocate several pages after kva_start
1.5  bouyer 	 * in pmap_bootstrap() before pmap_growkernel(), which have not been
1.5  bouyer 	 * counted here. It's not a big issue to allocate one more L2 as
1.5  bouyer 	 * pmap_growkernel() will be called anyway.
1.5  bouyer 	 */
1.5  bouyer 	count++;
1.4  bouyer 	nkptp[1] = count;
1.2  bouyer #endif
1.2  bouyer
1.4  bouyer 	/*
1.4  bouyer 	 * install bootstrap pages. We may need more L2 pages than will
1.4  bouyer 	 * have the final table here, as it's installed after the final table
1.4  bouyer 	 */
1.4  bouyer 	oldcount = count;
1.4  bouyer
1.4  bouyer bootstrap_again:
1.4  bouyer 	XENPRINTK(("bootstrap_again oldcount %d\n", oldcount));
1.2  bouyer 	/*
1.2  bouyer 	 * Xen space we'll reclaim may not be enough for our new page tables,
1.2  bouyer 	 * move bootstrap tables if necessary
1.2  bouyer 	 */
1.4  bouyer 	if (bootstrap_tables < init_tables + ((count + l2_4_count) * PAGE_SIZE))
1.2  bouyer 		bootstrap_tables = init_tables +
1.4  bouyer 					((count + l2_4_count) * PAGE_SIZE);
1.4  bouyer 	/* make sure we have enough to map the bootstrap_tables */
1.4  bouyer 	if (bootstrap_tables + ((oldcount + l2_4_count) * PAGE_SIZE) >
1.4  bouyer 	    ((long)oldcount << L2_SHIFT) + KERNBASE) {
1.4  bouyer 		oldcount++;
1.4  bouyer 		goto bootstrap_again;
1.4  bouyer 	}
1.2  bouyer
1.2  bouyer 	/* Create temporary tables */
1.2  bouyer 	xen_bootstrap_tables(xen_start_info.pt_base, bootstrap_tables,
1.4  bouyer 		xen_start_info.nr_pt_frames, oldcount, 0);
1.2  bouyer
1.2  bouyer 	/* Create final tables */
1.2  bouyer 	xen_bootstrap_tables(bootstrap_tables, init_tables,
1.4  bouyer 	    oldcount + l2_4_count, count, 1);
1.2  bouyer
1.4  bouyer 	/* zero out free space after tables */
1.4  bouyer 	memset((void *)(init_tables + ((count + l2_4_count) * PAGE_SIZE)), 0,
1.4  bouyer 	    (UPAGES + 1) * NBPG);
1.4  bouyer 	return (init_tables + ((count + l2_4_count) * PAGE_SIZE));
1.2  bouyer }
1.2  bouyer
1.2  bouyer
1.2  bouyer /*
1.2  bouyer  * Build a new table and switch to it
1.2  bouyer  * old_count is # of old tables (including PGD, PDTPE and PDE)
1.2  bouyer  * new_count is # of new tables (PTE only)
1.2  bouyer  * we assume areas don't overlap
1.2  bouyer  */
1.2  bouyer
1.2  bouyer
1.2  bouyer static void
1.2  bouyer xen_bootstrap_tables (vaddr_t old_pgd, vaddr_t new_pgd,
1.2  bouyer 	int old_count, int new_count, int final)
1.2  bouyer {
1.2  bouyer 	pd_entry_t *pdtpe, *pde, *pte;
1.2  bouyer 	pd_entry_t *cur_pgd, *bt_pgd;
1.2  bouyer 	paddr_t addr, page;
1.2  bouyer 	vaddr_t avail, text_end, map_end;
1.2  bouyer 	int i;
1.2  bouyer 	extern char __data_start;
1.2  bouyer
1.2  bouyer 	__PRINTK(("xen_bootstrap_tables(0x%lx, 0x%lx, %d, %d)\n",
1.2  bouyer 	    old_pgd, new_pgd, old_count, new_count));
1.2  bouyer 	text_end = ((vaddr_t)&__data_start) & ~PAGE_MASK;
1.2  bouyer 	/*
1.2  bouyer 	 * size of R/W area after kernel text:
1.2  bouyer 	 *  xencons_interface (if present)
1.2  bouyer 	 *  xenstore_interface (if present)
1.4  bouyer 	 *  table pages (new_count + (PTP_LEVELS - 1) entries)
1.2  bouyer 	 * extra mappings (only when final is true):
1.4  bouyer 	 *  UAREA
1.4  bouyer 	 *  dummy user PGD (x86_64 only)/gdt page (i386 only)
1.2  bouyer 	 *  HYPERVISOR_shared_info
1.2  bouyer 	 *  ISA I/O mem (if needed)
1.2  bouyer 	 */
1.4  bouyer 	map_end = new_pgd + ((new_count + PTP_LEVELS - 1) * NBPG);
1.2  bouyer 	if (final) {
1.4  bouyer 		map_end += (UPAGES + 1) * NBPG;
1.4  bouyer 		HYPERVISOR_shared_info = (shared_info_t *)map_end;
1.2  bouyer 		map_end += NBPG;
1.2  bouyer 	}
1.4  bouyer 	/*
1.4  bouyer 	 * we always set atdevbase, as it's used by init386 to find the first
1.4  bouyer 	 * available VA. map_end is updated only if we are dom0, so
1.4  bouyer 	 * atdevbase -> atdevbase + IOM_SIZE will be mapped only in
1.4  bouyer 	 * this case.
1.4  bouyer 	 */
1.4  bouyer 	if (final)
1.4  bouyer 		atdevbase = map_end;
1.2  bouyer #ifdef DOM0OPS
1.2  bouyer 	if (final && (xen_start_info.flags & SIF_INITDOMAIN)) {
1.2  bouyer 		/* ISA I/O mem */
1.2  bouyer 		map_end += IOM_SIZE;
1.2  bouyer 	}
1.2  bouyer #endif /* DOM0OPS */
1.2  bouyer
1.2  bouyer 	__PRINTK(("xen_bootstrap_tables text_end 0x%lx map_end 0x%lx\n",
1.2  bouyer 	    text_end, map_end));
1.2  bouyer
1.2  bouyer 	/*
1.2  bouyer 	 * Create bootstrap page tables
1.2  bouyer 	 * What we need:
1.2  bouyer 	 * - a PGD (level 4)
1.2  bouyer 	 * - a PDTPE (level 3)
1.2  bouyer 	 * - a PDE (level2)
1.2  bouyer 	 * - some PTEs (level 1)
1.2  bouyer 	 */
1.2  bouyer
1.2  bouyer 	cur_pgd = (pd_entry_t *) old_pgd;
1.2  bouyer 	bt_pgd = (pd_entry_t *) new_pgd;
1.2  bouyer 	memset (bt_pgd, 0, PAGE_SIZE);
1.2  bouyer 	avail = new_pgd + PAGE_SIZE;
1.4  bouyer #if PTP_LEVELS > 3
1.2  bouyer 	/* Install level 3 */
1.2  bouyer 	pdtpe = (pd_entry_t *) avail;
1.2  bouyer 	memset (pdtpe, 0, PAGE_SIZE);
1.2  bouyer 	avail += PAGE_SIZE;
1.2  bouyer
1.2  bouyer 	addr = ((paddr_t) pdtpe) - KERNBASE;
1.2  bouyer 	bt_pgd[pl4_pi(KERNTEXTOFF)] =
1.4  bouyer 	    xpmap_ptom_masked(addr) | PG_k | PG_RW | PG_V;
1.2  bouyer
1.2  bouyer 	__PRINTK(("L3 va 0x%lx pa 0x%lx entry 0x%lx -> L4[0x%x]\n",
1.2  bouyer 	    pdtpe, addr, bt_pgd[pl4_pi(KERNTEXTOFF)], pl4_pi(KERNTEXTOFF)));
1.4  bouyer #else
1.4  bouyer 	pdtpe = bt_pgd;
1.4  bouyer #endif /* PTP_LEVELS > 3 */
1.2  bouyer
1.4  bouyer #if PTP_LEVELS > 2
1.2  bouyer 	/* Level 2 */
1.2  bouyer 	pde = (pd_entry_t *) avail;
1.2  bouyer 	memset(pde, 0, PAGE_SIZE);
1.2  bouyer 	avail += PAGE_SIZE;
1.2  bouyer
1.2  bouyer 	addr = ((paddr_t) pde) - KERNBASE;
1.2  bouyer 	pdtpe[pl3_pi(KERNTEXTOFF)] =
1.4  bouyer 	    xpmap_ptom_masked(addr) | PG_k | PG_RW | PG_V;
1.2  bouyer 	__PRINTK(("L2 va 0x%lx pa 0x%lx entry 0x%lx -> L3[0x%x]\n",
1.2  bouyer 	    pde, addr, pdtpe[pl3_pi(KERNTEXTOFF)], pl3_pi(KERNTEXTOFF)));
1.4  bouyer #else
1.4  bouyer 	pde = bt_pgd;
1.4  bouyer #endif /* PTP_LEVELS > 3 */
1.2  bouyer
1.2  bouyer 	/* Level 1 */
1.2  bouyer 	page = KERNTEXTOFF;
1.2  bouyer 	for (i = 0; i < new_count; i ++) {
1.2  bouyer 		paddr_t cur_page = page;
1.2  bouyer
1.2  bouyer 		pte = (pd_entry_t *) avail;
1.2  bouyer 		avail += PAGE_SIZE;
1.2  bouyer
1.2  bouyer 		memset(pte, 0, PAGE_SIZE);
1.2  bouyer 		while (pl2_pi(page) == pl2_pi (cur_page)) {
1.2  bouyer 			if (page >= map_end) {
1.2  bouyer 				/* not mapped at all */
1.2  bouyer 				pte[pl1_pi(page)] = 0;
1.2  bouyer 				page += PAGE_SIZE;
1.2  bouyer 				continue;
1.2  bouyer 			}
1.2  bouyer 			pte[pl1_pi(page)] = xpmap_ptom_masked(page - KERNBASE);
1.2  bouyer 			if (page == (vaddr_t)HYPERVISOR_shared_info) {
1.2  bouyer 				pte[pl1_pi(page)] = xen_start_info.shared_info;
1.2  bouyer 				__PRINTK(("HYPERVISOR_shared_info "
1.2  bouyer 				    "va 0x%lx pte 0x%lx\n",
1.2  bouyer 				    HYPERVISOR_shared_info, pte[pl1_pi(page)]));
1.2  bouyer 			}
1.4  bouyer #ifdef XEN3
1.2  bouyer 			if (xpmap_ptom_masked(page - KERNBASE) ==
1.2  bouyer 			    (xen_start_info.console_mfn << PAGE_SHIFT)) {
1.2  bouyer 				xencons_interface = (void *)page;
1.2  bouyer 				pte[pl1_pi(page)] =
1.2  bouyer 				    (xen_start_info.console_mfn << PAGE_SHIFT);
1.2  bouyer 				__PRINTK(("xencons_interface "
1.4  bouyer 				    "va 0x%lx pte 0x%lx\n",
1.2  bouyer 				    xencons_interface, pte[pl1_pi(page)]));
1.2  bouyer 			}
1.2  bouyer 			if (xpmap_ptom_masked(page - KERNBASE) ==
1.2  bouyer 			    (xen_start_info.store_mfn << PAGE_SHIFT)) {
1.2  bouyer 				xenstore_interface = (void *)page;
1.2  bouyer 				pte[pl1_pi(page)] =
1.2  bouyer 				    (xen_start_info.store_mfn << PAGE_SHIFT);
1.2  bouyer 				__PRINTK(("xenstore_interface "
1.2  bouyer 				    "va 0x%lx pte 0x%lx\n",
1.2  bouyer 				    xenstore_interface, pte[pl1_pi(page)]));
1.2  bouyer 			}
1.4  bouyer #endif /* XEN3 */
1.2  bouyer #ifdef DOM0OPS
1.2  bouyer 			if (page >= (vaddr_t)atdevbase &&
1.2  bouyer 			    page < (vaddr_t)atdevbase + IOM_SIZE) {
1.2  bouyer 				pte[pl1_pi(page)] =
1.2  bouyer 				    IOM_BEGIN + (page - (vaddr_t)atdevbase);
1.2  bouyer 			}
1.2  bouyer #endif
1.4  bouyer 			pte[pl1_pi(page)] |= PG_k | PG_V;
1.2  bouyer 			if (page < text_end) {
1.2  bouyer 				/* map kernel text RO */
1.2  bouyer 				pte[pl1_pi(page)] |= 0;
1.2  bouyer 			} else if (page >= old_pgd
1.2  bouyer 			    && page < old_pgd + (old_count * PAGE_SIZE)) {
1.2  bouyer 				/* map old page tables RO */
1.2  bouyer 				pte[pl1_pi(page)] |= 0;
1.2  bouyer 			} else if (page >= new_pgd &&
1.4  bouyer 			    page < new_pgd + ((new_count + PTP_LEVELS - 1) * PAGE_SIZE)) {
1.2  bouyer 				/* map new page tables RO */
1.2  bouyer 				pte[pl1_pi(page)] |= 0;
1.2  bouyer 			} else {
1.2  bouyer 				/* map page RW */
1.2  bouyer 				pte[pl1_pi(page)] |= PG_RW;
1.2  bouyer 			}
1.4  bouyer 			if (page  == old_pgd || page >= new_pgd)
1.4  bouyer 				__PRINTK(("va 0x%lx pa 0x%lx "
1.2  bouyer 				    "entry 0x%lx -> L1[0x%x]\n",
1.2  bouyer 				    page, page - KERNBASE,
1.2  bouyer 				    pte[pl1_pi(page)], pl1_pi(page)));
1.2  bouyer 			page += PAGE_SIZE;
1.2  bouyer 		}
1.2  bouyer
1.2  bouyer 		addr = ((paddr_t) pte) - KERNBASE;
1.2  bouyer 		pde[pl2_pi(cur_page)] =
1.4  bouyer 		    xpmap_ptom_masked(addr) | PG_k | PG_RW | PG_V;
1.2  bouyer 		__PRINTK(("L1 va 0x%lx pa 0x%lx entry 0x%lx -> L2[0x%x]\n",
1.2  bouyer 		    pte, addr, pde[pl2_pi(cur_page)], pl2_pi(cur_page)));
1.2  bouyer 		/* Mark readonly */
1.2  bouyer 		xen_bt_set_readonly((vaddr_t) pte);
1.2  bouyer 	}
1.2  bouyer
1.2  bouyer 	/* Install recursive page tables mapping */
1.2  bouyer 	bt_pgd[PDIR_SLOT_PTE] =
1.4  bouyer 	    xpmap_ptom_masked(new_pgd - KERNBASE) | PG_k | PG_V;
1.2  bouyer 	__PRINTK(("bt_pgd[PDIR_SLOT_PTE] va 0x%lx pa 0x%lx entry 0x%lx\n",
1.2  bouyer 	    new_pgd, new_pgd - KERNBASE, bt_pgd[PDIR_SLOT_PTE]));
1.2  bouyer
1.2  bouyer 	/* Mark tables RO */
1.2  bouyer 	xen_bt_set_readonly((vaddr_t) pde);
1.4  bouyer #if PTP_LEVELS > 2
1.2  bouyer 	xen_bt_set_readonly((vaddr_t) pdtpe);
1.4  bouyer #endif
1.4  bouyer #if PTP_LEVELS > 3
1.2  bouyer 	xen_bt_set_readonly(new_pgd);
1.4  bouyer #endif
1.2  bouyer 	/* Pin the PGD */
1.2  bouyer 	__PRINTK(("pin PDG\n"));
1.2  bouyer 	xpq_queue_pin_table(xpmap_ptom_masked(new_pgd - KERNBASE));
1.4  bouyer #ifdef __i386__
1.4  bouyer 	/* Save phys. addr of PDP, for libkvm. */
1.4  bouyer 	PDPpaddr = new_pgd;
1.4  bouyer #endif
1.2  bouyer 	/* Switch to new tables */
1.2  bouyer 	__PRINTK(("switch to PDG\n"));
1.2  bouyer 	xpq_queue_pt_switch(xpmap_ptom_masked(new_pgd - KERNBASE));
1.2  bouyer 	__PRINTK(("bt_pgd[PDIR_SLOT_PTE] now entry 0x%lx\n",
1.2  bouyer 	    bt_pgd[PDIR_SLOT_PTE]));
1.2  bouyer
1.2  bouyer 	/* Now we can safely reclaim space taken by old tables */
1.2  bouyer
1.2  bouyer 	__PRINTK(("unpin old PDG\n"));
1.2  bouyer 	/* Unpin old PGD */
1.2  bouyer 	xpq_queue_unpin_table(xpmap_ptom_masked(old_pgd - KERNBASE));
1.2  bouyer 	/* Mark old tables RW */
1.2  bouyer 	page = old_pgd;
1.2  bouyer 	addr = (paddr_t) pde[pl2_pi(page)] & PG_FRAME;
1.2  bouyer 	addr = xpmap_mtop(addr);
1.2  bouyer 	pte = (pd_entry_t *) (addr + KERNBASE);
1.2  bouyer 	pte += pl1_pi(page);
1.2  bouyer 	__PRINTK(("*pde 0x%lx addr 0x%lx pte 0x%lx\n",
1.2  bouyer 	    pde[pl2_pi(page)], addr, pte));
1.2  bouyer 	while (page < old_pgd + (old_count * PAGE_SIZE) && page < map_end) {
1.2  bouyer 		addr = xpmap_ptom(((paddr_t) pte) - KERNBASE);
1.4  bouyer 		XENPRINTK(("addr 0x%lx pte 0x%lx *pte 0x%lx\n",
1.4  bouyer 		   addr, pte, *pte));
1.2  bouyer 		xpq_queue_pte_update((pt_entry_t *) addr, *pte | PG_RW);
1.2  bouyer 		page += PAGE_SIZE;
1.2  bouyer 		/*
1.2  bouyer 		 * Our ptes are contiguous
1.2  bouyer 		 * so it's safe to just "++" here
1.2  bouyer 		 */
1.2  bouyer 		pte++;
1.2  bouyer 	}
1.2  bouyer 	xpq_flush_queue();
1.2  bouyer }
1.2  bouyer
1.2  bouyer
1.2  bouyer /*
1.2  bouyer  * Bootstrap helper functions
1.2  bouyer  */
1.2  bouyer
1.2  bouyer /*
1.2  bouyer  * Mark a page readonly
1.2  bouyer  * XXX: assuming vaddr = paddr + KERNBASE
1.2  bouyer  */
1.2  bouyer
1.2  bouyer static void
1.2  bouyer xen_bt_set_readonly (vaddr_t page)
1.2  bouyer {
1.2  bouyer 	pt_entry_t entry;
1.2  bouyer
1.2  bouyer 	entry = xpmap_ptom_masked(page - KERNBASE);
1.4  bouyer 	entry |= PG_k | PG_V;
1.2  bouyer
1.2  bouyer 	HYPERVISOR_update_va_mapping (page, entry, UVMF_INVLPG);
1.2  bouyer }
1.4  bouyer
1.4  bouyer #ifdef __x86_64__
1.4  bouyer void
1.4  bouyer xen_set_user_pgd(paddr_t page)
1.4  bouyer {
1.4  bouyer 	struct mmuext_op op;
1.4  bouyer 	int s = splvm();
1.4  bouyer
1.4  bouyer 	xpq_flush_queue();
1.4  bouyer 	op.cmd = MMUEXT_NEW_USER_BASEPTR;
1.4  bouyer 	op.arg1.mfn = xpmap_phys_to_machine_mapping[page >> PAGE_SHIFT];
1.4  bouyer         if (HYPERVISOR_mmuext_op(&op, 1, NULL, DOMID_SELF) < 0)
1.4  bouyer 		panic("xen_set_user_pgd: failed to install new user page"
1.4  bouyer 			" directory %lx", page);
1.4  bouyer 	splx(s);
1.4  bouyer }
1.4  bouyer #endif /* __x86_64__ */