arch/powerpc/kvm/e500_tlb.c

/*
 * Copyright (C) 2008-2011 Freescale Semiconductor, Inc. All rights reserved.
 *
 * Author: Yu Liu, yu.liu@freescale.com
 *
 * Description:
 * This file is based on arch/powerpc/kvm/44x_tlb.c,
 * by Hollis Blanchard <hollisb@us.ibm.com>.
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License, version 2, as
 * published by the Free Software Foundation.
 */

#include <linux/types.h>
#include <linux/slab.h>
#include <linux/string.h>
#include <linux/kvm.h>
#include <linux/kvm_host.h>
#include <linux/highmem.h>
#include <asm/kvm_ppc.h>
#include <asm/kvm_e500.h>

#include "../mm/mmu_decl.h"
#include "e500_tlb.h"
#include "trace.h"
#include "timing.h"

#define to_htlb1_esel(esel) (tlb1_entry_num - (esel) - 1)

struct id {
	unsigned long val;
	struct id **pentry;
};

#define NUM_TIDS 256

/*
 * This table provide mappings from:
 * (guestAS,guestTID,guestPR) --> ID of physical cpu
 * guestAS	[0..1]
 * guestTID	[0..255]
 * guestPR	[0..1]
 * ID		[1..255]
 * Each vcpu keeps one vcpu_id_table.
 */
struct vcpu_id_table {
	struct id id[2][NUM_TIDS][2];
};

/*
 * This table provide reversed mappings of vcpu_id_table:
 * ID --> address of vcpu_id_table item.
 * Each physical core has one pcpu_id_table.
 */
struct pcpu_id_table {
	struct id *entry[NUM_TIDS];
};

static DEFINE_PER_CPU(struct pcpu_id_table, pcpu_sids);

/* This variable keeps last used shadow ID on local core.
 * The valid range of shadow ID is [1..255] */
static DEFINE_PER_CPU(unsigned long, pcpu_last_used_sid);

static unsigned int tlb1_entry_num;

/*
 * Allocate a free shadow id and setup a valid sid mapping in given entry.
 * A mapping is only valid when vcpu_id_table and pcpu_id_table are match.
 *
 * The caller must have preemption disabled, and keep it that way until
 * it has finished with the returned shadow id (either written into the
 * TLB or arch.shadow_pid, or discarded).
 */
static inline int local_sid_setup_one(struct id *entry)
{
	unsigned long sid;
	int ret = -1;

	sid = ++(__get_cpu_var(pcpu_last_used_sid));
	if (sid < NUM_TIDS) {
		__get_cpu_var(pcpu_sids).entry[sid] = entry;
		entry->val = sid;
		entry->pentry = &__get_cpu_var(pcpu_sids).entry[sid];
		ret = sid;
	}

	/*
	 * If sid == NUM_TIDS, we've run out of sids.  We return -1, and
	 * the caller will invalidate everything and start over.
	 *
	 * sid > NUM_TIDS indicates a race, which we disable preemption to
	 * avoid.
	 */
	WARN_ON(sid > NUM_TIDS);

	return ret;
}

/*
 * Check if given entry contain a valid shadow id mapping.
 * An ID mapping is considered valid only if
 * both vcpu and pcpu know this mapping.
 *
 * The caller must have preemption disabled, and keep it that way until
 * it has finished with the returned shadow id (either written into the
 * TLB or arch.shadow_pid, or discarded).
 */
static inline int local_sid_lookup(struct id *entry)
{
	if (entry && entry->val != 0 &&
	    __get_cpu_var(pcpu_sids).entry[entry->val] == entry &&
	    entry->pentry == &__get_cpu_var(pcpu_sids).entry[entry->val])
		return entry->val;
	return -1;
}

/* Invalidate all id mappings on local core */
static inline void local_sid_destroy_all(void)
{
	preempt_disable();
	__get_cpu_var(pcpu_last_used_sid) = 0;
	memset(&__get_cpu_var(pcpu_sids), 0, sizeof(__get_cpu_var(pcpu_sids)));
	preempt_enable();
}

static void *kvmppc_e500_id_table_alloc(struct kvmppc_vcpu_e500 *vcpu_e500)
{
	vcpu_e500->idt = kzalloc(sizeof(struct vcpu_id_table), GFP_KERNEL);
	return vcpu_e500->idt;
}

static void kvmppc_e500_id_table_free(struct kvmppc_vcpu_e500 *vcpu_e500)
{
	kfree(vcpu_e500->idt);
}

/* Invalidate all mappings on vcpu */
static void kvmppc_e500_id_table_reset_all(struct kvmppc_vcpu_e500 *vcpu_e500)
{
	memset(vcpu_e500->idt, 0, sizeof(struct vcpu_id_table));

	/* Update shadow pid when mappings are changed */
	kvmppc_e500_recalc_shadow_pid(vcpu_e500);
}

/* Invalidate one ID mapping on vcpu */
static inline void kvmppc_e500_id_table_reset_one(
			       struct kvmppc_vcpu_e500 *vcpu_e500,
			       int as, int pid, int pr)
{
	struct vcpu_id_table *idt = vcpu_e500->idt;

	BUG_ON(as >= 2);
	BUG_ON(pid >= NUM_TIDS);
	BUG_ON(pr >= 2);

	idt->id[as][pid][pr].val = 0;
	idt->id[as][pid][pr].pentry = NULL;

	/* Update shadow pid when mappings are changed */
	kvmppc_e500_recalc_shadow_pid(vcpu_e500);
}

/*
 * Map guest (vcpu,AS,ID,PR) to physical core shadow id.
 * This function first lookup if a valid mapping exists,
 * if not, then creates a new one.
 *
 * The caller must have preemption disabled, and keep it that way until
 * it has finished with the returned shadow id (either written into the
 * TLB or arch.shadow_pid, or discarded).
 */
static unsigned int kvmppc_e500_get_sid(struct kvmppc_vcpu_e500 *vcpu_e500,
					unsigned int as, unsigned int gid,
					unsigned int pr, int avoid_recursion)
{
	struct vcpu_id_table *idt = vcpu_e500->idt;
	int sid;

	BUG_ON(as >= 2);
	BUG_ON(gid >= NUM_TIDS);
	BUG_ON(pr >= 2);

	sid = local_sid_lookup(&idt->id[as][gid][pr]);

	while (sid <= 0) {
		/* No mapping yet */
		sid = local_sid_setup_one(&idt->id[as][gid][pr]);
		if (sid <= 0) {
			_tlbil_all();
			local_sid_destroy_all();
		}

		/* Update shadow pid when mappings are changed */
		if (!avoid_recursion)
			kvmppc_e500_recalc_shadow_pid(vcpu_e500);
	}

	return sid;
}

/* Map guest pid to shadow.
 * We use PID to keep shadow of current guest non-zero PID,
 * and use PID1 to keep shadow of guest zero PID.
 * So that guest tlbe with TID=0 can be accessed at any time */
void kvmppc_e500_recalc_shadow_pid(struct kvmppc_vcpu_e500 *vcpu_e500)
{
	preempt_disable();
	vcpu_e500->vcpu.arch.shadow_pid = kvmppc_e500_get_sid(vcpu_e500,
			get_cur_as(&vcpu_e500->vcpu),
			get_cur_pid(&vcpu_e500->vcpu),
			get_cur_pr(&vcpu_e500->vcpu), 1);
	vcpu_e500->vcpu.arch.shadow_pid1 = kvmppc_e500_get_sid(vcpu_e500,
			get_cur_as(&vcpu_e500->vcpu), 0,
			get_cur_pr(&vcpu_e500->vcpu), 1);
	preempt_enable();
}

void kvmppc_dump_tlbs(struct kvm_vcpu *vcpu)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	struct tlbe *tlbe;
	int i, tlbsel;

	printk("| %8s | %8s | %8s | %8s | %8s |\n",
			"nr", "mas1", "mas2", "mas3", "mas7");

	for (tlbsel = 0; tlbsel < 2; tlbsel++) {
		printk("Guest TLB%d:\n", tlbsel);
		for (i = 0; i < vcpu_e500->gtlb_size[tlbsel]; i++) {
			tlbe = &vcpu_e500->gtlb_arch[tlbsel][i];
			if (tlbe->mas1 & MAS1_VALID)
				printk(" G[%d][%3d] |  %08X | %08X | %08X | %08X |\n",
					tlbsel, i, tlbe->mas1, tlbe->mas2,
					tlbe->mas3, tlbe->mas7);
		}
	}
}

static inline unsigned int tlb0_get_next_victim(
		struct kvmppc_vcpu_e500 *vcpu_e500)
{
	unsigned int victim;

	victim = vcpu_e500->gtlb_nv[0]++;
	if (unlikely(vcpu_e500->gtlb_nv[0] >= KVM_E500_TLB0_WAY_NUM))
		vcpu_e500->gtlb_nv[0] = 0;

	return victim;
}

static inline unsigned int tlb1_max_shadow_size(void)
{
	/* reserve one entry for magic page */
	return tlb1_entry_num - tlbcam_index - 1;
}

static inline int tlbe_is_writable(struct tlbe *tlbe)
{
	return tlbe->mas3 & (MAS3_SW|MAS3_UW);
}

static inline u32 e500_shadow_mas3_attrib(u32 mas3, int usermode)
{
	/* Mask off reserved bits. */
	mas3 &= MAS3_ATTRIB_MASK;

	if (!usermode) {
		/* Guest is in supervisor mode,
		 * so we need to translate guest
		 * supervisor permissions into user permissions. */
		mas3 &= ~E500_TLB_USER_PERM_MASK;
		mas3 |= (mas3 & E500_TLB_SUPER_PERM_MASK) << 1;
	}

	return mas3 | E500_TLB_SUPER_PERM_MASK;
}

static inline u32 e500_shadow_mas2_attrib(u32 mas2, int usermode)
{
#ifdef CONFIG_SMP
	return (mas2 & MAS2_ATTRIB_MASK) | MAS2_M;
#else
	return mas2 & MAS2_ATTRIB_MASK;
#endif
}

/*
 * writing shadow tlb entry to host TLB
 */
static inline void __write_host_tlbe(struct tlbe *stlbe, uint32_t mas0)
{
	unsigned long flags;

	local_irq_save(flags);
	mtspr(SPRN_MAS0, mas0);
	mtspr(SPRN_MAS1, stlbe->mas1);
	mtspr(SPRN_MAS2, stlbe->mas2);
	mtspr(SPRN_MAS3, stlbe->mas3);
	mtspr(SPRN_MAS7, stlbe->mas7);
	asm volatile("isync; tlbwe" : : : "memory");
	local_irq_restore(flags);
}

static inline void write_host_tlbe(struct kvmppc_vcpu_e500 *vcpu_e500,
		int tlbsel, int esel, struct tlbe *stlbe)
{
	if (tlbsel == 0) {
		__write_host_tlbe(stlbe,
				  MAS0_TLBSEL(0) |
				  MAS0_ESEL(esel & (KVM_E500_TLB0_WAY_NUM - 1)));
	} else {
		__write_host_tlbe(stlbe,
				  MAS0_TLBSEL(1) |
				  MAS0_ESEL(to_htlb1_esel(esel)));
	}
	trace_kvm_stlb_write(index_of(tlbsel, esel), stlbe->mas1, stlbe->mas2,
			     stlbe->mas3, stlbe->mas7);
}

void kvmppc_map_magic(struct kvm_vcpu *vcpu)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	struct tlbe magic;
	ulong shared_page = ((ulong)vcpu->arch.shared) & PAGE_MASK;
	unsigned int stid;
	pfn_t pfn;

	pfn = (pfn_t)virt_to_phys((void *)shared_page) >> PAGE_SHIFT;
	get_page(pfn_to_page(pfn));

	preempt_disable();
	stid = kvmppc_e500_get_sid(vcpu_e500, 0, 0, 0, 0);

	magic.mas1 = MAS1_VALID | MAS1_TS | MAS1_TID(stid) |
		     MAS1_TSIZE(BOOK3E_PAGESZ_4K);
	magic.mas2 = vcpu->arch.magic_page_ea | MAS2_M;
	magic.mas3 = (pfn << PAGE_SHIFT) |
		     MAS3_SW | MAS3_SR | MAS3_UW | MAS3_UR;
	magic.mas7 = pfn >> (32 - PAGE_SHIFT);

	__write_host_tlbe(&magic, MAS0_TLBSEL(1) | MAS0_ESEL(tlbcam_index));
	preempt_enable();
}

void kvmppc_e500_tlb_load(struct kvm_vcpu *vcpu, int cpu)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);

	/* Shadow PID may be expired on local core */
	kvmppc_e500_recalc_shadow_pid(vcpu_e500);
}

void kvmppc_e500_tlb_put(struct kvm_vcpu *vcpu)
{
}

static void kvmppc_e500_stlbe_invalidate(struct kvmppc_vcpu_e500 *vcpu_e500,
					 int tlbsel, int esel)
{
	struct tlbe *gtlbe = &vcpu_e500->gtlb_arch[tlbsel][esel];
	struct vcpu_id_table *idt = vcpu_e500->idt;
	unsigned int pr, tid, ts, pid;
	u32 val, eaddr;
	unsigned long flags;

	ts = get_tlb_ts(gtlbe);
	tid = get_tlb_tid(gtlbe);

	preempt_disable();

	/* One guest ID may be mapped to two shadow IDs */
	for (pr = 0; pr < 2; pr++) {
		/*
		 * The shadow PID can have a valid mapping on at most one
		 * host CPU.  In the common case, it will be valid on this
		 * CPU, in which case (for TLB0) we do a local invalidation
		 * of the specific address.
		 *
		 * If the shadow PID is not valid on the current host CPU, or
		 * if we're invalidating a TLB1 entry, we invalidate the
		 * entire shadow PID.
		 */
		if (tlbsel == 1 ||
		    (pid = local_sid_lookup(&idt->id[ts][tid][pr])) <= 0) {
			kvmppc_e500_id_table_reset_one(vcpu_e500, ts, tid, pr);
			continue;
		}

		/*
		 * The guest is invalidating a TLB0 entry which is in a PID
		 * that has a valid shadow mapping on this host CPU.  We
		 * search host TLB0 to invalidate it's shadow TLB entry,
		 * similar to __tlbil_va except that we need to look in AS1.
		 */
		val = (pid << MAS6_SPID_SHIFT) | MAS6_SAS;
		eaddr = get_tlb_eaddr(gtlbe);

		local_irq_save(flags);

		mtspr(SPRN_MAS6, val);
		asm volatile("tlbsx 0, %[eaddr]" : : [eaddr] "r" (eaddr));
		val = mfspr(SPRN_MAS1);
		if (val & MAS1_VALID) {
			mtspr(SPRN_MAS1, val & ~MAS1_VALID);
			asm volatile("tlbwe");
		}

		local_irq_restore(flags);
	}

	preempt_enable();
}

/* Search the guest TLB for a matching entry. */
static int kvmppc_e500_tlb_index(struct kvmppc_vcpu_e500 *vcpu_e500,
		gva_t eaddr, int tlbsel, unsigned int pid, int as)
{
	int size = vcpu_e500->gtlb_size[tlbsel];
	int set_base;
	int i;

	if (tlbsel == 0) {
		int mask = size / KVM_E500_TLB0_WAY_NUM - 1;
		set_base = (eaddr >> PAGE_SHIFT) & mask;
		set_base *= KVM_E500_TLB0_WAY_NUM;
		size = KVM_E500_TLB0_WAY_NUM;
	} else {
		set_base = 0;
	}

	for (i = 0; i < size; i++) {
		struct tlbe *tlbe = &vcpu_e500->gtlb_arch[tlbsel][set_base + i];
		unsigned int tid;

		if (eaddr < get_tlb_eaddr(tlbe))
			continue;

		if (eaddr > get_tlb_end(tlbe))
			continue;

		tid = get_tlb_tid(tlbe);
		if (tid && (tid != pid))
			continue;

		if (!get_tlb_v(tlbe))
			continue;

		if (get_tlb_ts(tlbe) != as && as != -1)
			continue;

		return set_base + i;
	}

	return -1;
}

static inline void kvmppc_e500_priv_setup(struct tlbe_priv *priv,
					  struct tlbe *gtlbe,
					  pfn_t pfn)
{
	priv->pfn = pfn;
	priv->flags = E500_TLB_VALID;

	if (tlbe_is_writable(gtlbe))
		priv->flags |= E500_TLB_DIRTY;
}

static inline void kvmppc_e500_priv_release(struct tlbe_priv *priv)
{
	if (priv->flags & E500_TLB_VALID) {
		if (priv->flags & E500_TLB_DIRTY)
			kvm_release_pfn_dirty(priv->pfn);
		else
			kvm_release_pfn_clean(priv->pfn);

		priv->flags = 0;
	}
}

static inline void kvmppc_e500_deliver_tlb_miss(struct kvm_vcpu *vcpu,
		unsigned int eaddr, int as)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	unsigned int victim, pidsel, tsized;
	int tlbsel;

	/* since we only have two TLBs, only lower bit is used. */
	tlbsel = (vcpu_e500->mas4 >> 28) & 0x1;
	victim = (tlbsel == 0) ? tlb0_get_next_victim(vcpu_e500) : 0;
	pidsel = (vcpu_e500->mas4 >> 16) & 0xf;
	tsized = (vcpu_e500->mas4 >> 7) & 0x1f;

	vcpu_e500->mas0 = MAS0_TLBSEL(tlbsel) | MAS0_ESEL(victim)
		| MAS0_NV(vcpu_e500->gtlb_nv[tlbsel]);
	vcpu_e500->mas1 = MAS1_VALID | (as ? MAS1_TS : 0)
		| MAS1_TID(vcpu_e500->pid[pidsel])
		| MAS1_TSIZE(tsized);
	vcpu_e500->mas2 = (eaddr & MAS2_EPN)
		| (vcpu_e500->mas4 & MAS2_ATTRIB_MASK);
	vcpu_e500->mas3 &= MAS3_U0 | MAS3_U1 | MAS3_U2 | MAS3_U3;
	vcpu_e500->mas6 = (vcpu_e500->mas6 & MAS6_SPID1)
		| (get_cur_pid(vcpu) << 16)
		| (as ? MAS6_SAS : 0);
	vcpu_e500->mas7 = 0;
}

static inline void kvmppc_e500_setup_stlbe(struct kvmppc_vcpu_e500 *vcpu_e500,
					   struct tlbe *gtlbe, int tsize,
					   struct tlbe_priv *priv,
					   u64 gvaddr, struct tlbe *stlbe)
{
	pfn_t pfn = priv->pfn;
	unsigned int stid;

	stid = kvmppc_e500_get_sid(vcpu_e500, get_tlb_ts(gtlbe),
				   get_tlb_tid(gtlbe),
				   get_cur_pr(&vcpu_e500->vcpu), 0);

	/* Force TS=1 IPROT=0 for all guest mappings. */
	stlbe->mas1 = MAS1_TSIZE(tsize)
		| MAS1_TID(stid) | MAS1_TS | MAS1_VALID;
	stlbe->mas2 = (gvaddr & MAS2_EPN)
		| e500_shadow_mas2_attrib(gtlbe->mas2,
				vcpu_e500->vcpu.arch.shared->msr & MSR_PR);
	stlbe->mas3 = ((pfn << PAGE_SHIFT) & MAS3_RPN)
		| e500_shadow_mas3_attrib(gtlbe->mas3,
				vcpu_e500->vcpu.arch.shared->msr & MSR_PR);
	stlbe->mas7 = (pfn >> (32 - PAGE_SHIFT)) & MAS7_RPN;
}


static inline void kvmppc_e500_shadow_map(struct kvmppc_vcpu_e500 *vcpu_e500,
	u64 gvaddr, gfn_t gfn, struct tlbe *gtlbe, int tlbsel, int esel,
	struct tlbe *stlbe)
{
	struct kvm_memory_slot *slot;
	unsigned long pfn, hva;
	int pfnmap = 0;
	int tsize = BOOK3E_PAGESZ_4K;
	struct tlbe_priv *priv;

	/*
	 * Translate guest physical to true physical, acquiring
	 * a page reference if it is normal, non-reserved memory.
	 *
	 * gfn_to_memslot() must succeed because otherwise we wouldn't
	 * have gotten this far.  Eventually we should just pass the slot
	 * pointer through from the first lookup.
	 */
	slot = gfn_to_memslot(vcpu_e500->vcpu.kvm, gfn);
	hva = gfn_to_hva_memslot(slot, gfn);

	if (tlbsel == 1) {
		struct vm_area_struct *vma;
		down_read(&current->mm->mmap_sem);

		vma = find_vma(current->mm, hva);
		if (vma && hva >= vma->vm_start &&
		    (vma->vm_flags & VM_PFNMAP)) {
			/*
			 * This VMA is a physically contiguous region (e.g.
			 * /dev/mem) that bypasses normal Linux page
			 * management.  Find the overlap between the
			 * vma and the memslot.
			 */

			unsigned long start, end;
			unsigned long slot_start, slot_end;

			pfnmap = 1;

			start = vma->vm_pgoff;
			end = start +
			      ((vma->vm_end - vma->vm_start) >> PAGE_SHIFT);

			pfn = start + ((hva - vma->vm_start) >> PAGE_SHIFT);

			slot_start = pfn - (gfn - slot->base_gfn);
			slot_end = slot_start + slot->npages;

			if (start < slot_start)
				start = slot_start;
			if (end > slot_end)
				end = slot_end;

			tsize = (gtlbe->mas1 & MAS1_TSIZE_MASK) >>
				MAS1_TSIZE_SHIFT;

			/*
			 * e500 doesn't implement the lowest tsize bit,
			 * or 1K pages.
			 */
			tsize = max(BOOK3E_PAGESZ_4K, tsize & ~1);

			/*
			 * Now find the largest tsize (up to what the guest
			 * requested) that will cover gfn, stay within the
			 * range, and for which gfn and pfn are mutually
			 * aligned.
			 */

			for (; tsize > BOOK3E_PAGESZ_4K; tsize -= 2) {
				unsigned long gfn_start, gfn_end, tsize_pages;
				tsize_pages = 1 << (tsize - 2);

				gfn_start = gfn & ~(tsize_pages - 1);
				gfn_end = gfn_start + tsize_pages;

				if (gfn_start + pfn - gfn < start)
					continue;
				if (gfn_end + pfn - gfn > end)
					continue;
				if ((gfn & (tsize_pages - 1)) !=
				    (pfn & (tsize_pages - 1)))
					continue;

				gvaddr &= ~((tsize_pages << PAGE_SHIFT) - 1);
				pfn &= ~(tsize_pages - 1);
				break;
			}
		}

		up_read(&current->mm->mmap_sem);
	}

	if (likely(!pfnmap)) {
		pfn = gfn_to_pfn_memslot(vcpu_e500->vcpu.kvm, slot, gfn);
		if (is_error_pfn(pfn)) {
			printk(KERN_ERR "Couldn't get real page for gfn %lx!\n",
					(long)gfn);
			kvm_release_pfn_clean(pfn);
			return;
		}
	}

	/* Drop old priv and setup new one. */
	priv = &vcpu_e500->gtlb_priv[tlbsel][esel];
	kvmppc_e500_priv_release(priv);
	kvmppc_e500_priv_setup(priv, gtlbe, pfn);

	kvmppc_e500_setup_stlbe(vcpu_e500, gtlbe, tsize, priv, gvaddr, stlbe);
}

/* XXX only map the one-one case, for now use TLB0 */
static int kvmppc_e500_tlb0_map(struct kvmppc_vcpu_e500 *vcpu_e500,
				int esel, struct tlbe *stlbe)
{
	struct tlbe *gtlbe;

	gtlbe = &vcpu_e500->gtlb_arch[0][esel];

	kvmppc_e500_shadow_map(vcpu_e500, get_tlb_eaddr(gtlbe),
			get_tlb_raddr(gtlbe) >> PAGE_SHIFT,
			gtlbe, 0, esel, stlbe);

	return esel;
}

/* Caller must ensure that the specified guest TLB entry is safe to insert into
 * the shadow TLB. */
/* XXX for both one-one and one-to-many , for now use TLB1 */
static int kvmppc_e500_tlb1_map(struct kvmppc_vcpu_e500 *vcpu_e500,
		u64 gvaddr, gfn_t gfn, struct tlbe *gtlbe, struct tlbe *stlbe)
{
	unsigned int victim;

	victim = vcpu_e500->gtlb_nv[1]++;

	if (unlikely(vcpu_e500->gtlb_nv[1] >= tlb1_max_shadow_size()))
		vcpu_e500->gtlb_nv[1] = 0;

	kvmppc_e500_shadow_map(vcpu_e500, gvaddr, gfn, gtlbe, 1, victim, stlbe);

	return victim;
}

void kvmppc_mmu_msr_notify(struct kvm_vcpu *vcpu, u32 old_msr)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);

	/* Recalc shadow pid since MSR changes */
	kvmppc_e500_recalc_shadow_pid(vcpu_e500);
}

static inline int kvmppc_e500_gtlbe_invalidate(
				struct kvmppc_vcpu_e500 *vcpu_e500,
				int tlbsel, int esel)
{
	struct tlbe *gtlbe = &vcpu_e500->gtlb_arch[tlbsel][esel];

	if (unlikely(get_tlb_iprot(gtlbe)))
		return -1;

	gtlbe->mas1 = 0;

	return 0;
}

int kvmppc_e500_emul_mt_mmucsr0(struct kvmppc_vcpu_e500 *vcpu_e500, ulong value)
{
	int esel;

	if (value & MMUCSR0_TLB0FI)
		for (esel = 0; esel < vcpu_e500->gtlb_size[0]; esel++)
			kvmppc_e500_gtlbe_invalidate(vcpu_e500, 0, esel);
	if (value & MMUCSR0_TLB1FI)
		for (esel = 0; esel < vcpu_e500->gtlb_size[1]; esel++)
			kvmppc_e500_gtlbe_invalidate(vcpu_e500, 1, esel);

	/* Invalidate all vcpu id mappings */
	kvmppc_e500_id_table_reset_all(vcpu_e500);

	return EMULATE_DONE;
}

int kvmppc_e500_emul_tlbivax(struct kvm_vcpu *vcpu, int ra, int rb)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	unsigned int ia;
	int esel, tlbsel;
	gva_t ea;

	ea = ((ra) ? kvmppc_get_gpr(vcpu, ra) : 0) + kvmppc_get_gpr(vcpu, rb);

	ia = (ea >> 2) & 0x1;

	/* since we only have two TLBs, only lower bit is used. */
	tlbsel = (ea >> 3) & 0x1;

	if (ia) {
		/* invalidate all entries */
		for (esel = 0; esel < vcpu_e500->gtlb_size[tlbsel]; esel++)
			kvmppc_e500_gtlbe_invalidate(vcpu_e500, tlbsel, esel);
	} else {
		ea &= 0xfffff000;
		esel = kvmppc_e500_tlb_index(vcpu_e500, ea, tlbsel,
				get_cur_pid(vcpu), -1);
		if (esel >= 0)
			kvmppc_e500_gtlbe_invalidate(vcpu_e500, tlbsel, esel);
	}

	/* Invalidate all vcpu id mappings */
	kvmppc_e500_id_table_reset_all(vcpu_e500);

	return EMULATE_DONE;
}

int kvmppc_e500_emul_tlbre(struct kvm_vcpu *vcpu)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	int tlbsel, esel;
	struct tlbe *gtlbe;

	tlbsel = get_tlb_tlbsel(vcpu_e500);
	esel = get_tlb_esel(vcpu_e500, tlbsel);

	gtlbe = &vcpu_e500->gtlb_arch[tlbsel][esel];
	vcpu_e500->mas0 &= ~MAS0_NV(~0);
	vcpu_e500->mas0 |= MAS0_NV(vcpu_e500->gtlb_nv[tlbsel]);
	vcpu_e500->mas1 = gtlbe->mas1;
	vcpu_e500->mas2 = gtlbe->mas2;
	vcpu_e500->mas3 = gtlbe->mas3;
	vcpu_e500->mas7 = gtlbe->mas7;

	return EMULATE_DONE;
}

int kvmppc_e500_emul_tlbsx(struct kvm_vcpu *vcpu, int rb)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	int as = !!get_cur_sas(vcpu_e500);
	unsigned int pid = get_cur_spid(vcpu_e500);
	int esel, tlbsel;
	struct tlbe *gtlbe = NULL;
	gva_t ea;

	ea = kvmppc_get_gpr(vcpu, rb);

	for (tlbsel = 0; tlbsel < 2; tlbsel++) {
		esel = kvmppc_e500_tlb_index(vcpu_e500, ea, tlbsel, pid, as);
		if (esel >= 0) {
			gtlbe = &vcpu_e500->gtlb_arch[tlbsel][esel];
			break;
		}
	}

	if (gtlbe) {
		vcpu_e500->mas0 = MAS0_TLBSEL(tlbsel) | MAS0_ESEL(esel)
			| MAS0_NV(vcpu_e500->gtlb_nv[tlbsel]);
		vcpu_e500->mas1 = gtlbe->mas1;
		vcpu_e500->mas2 = gtlbe->mas2;
		vcpu_e500->mas3 = gtlbe->mas3;
		vcpu_e500->mas7 = gtlbe->mas7;
	} else {
		int victim;

		/* since we only have two TLBs, only lower bit is used. */
		tlbsel = vcpu_e500->mas4 >> 28 & 0x1;
		victim = (tlbsel == 0) ? tlb0_get_next_victim(vcpu_e500) : 0;

		vcpu_e500->mas0 = MAS0_TLBSEL(tlbsel) | MAS0_ESEL(victim)
			| MAS0_NV(vcpu_e500->gtlb_nv[tlbsel]);
		vcpu_e500->mas1 = (vcpu_e500->mas6 & MAS6_SPID0)
			| (vcpu_e500->mas6 & (MAS6_SAS ? MAS1_TS : 0))
			| (vcpu_e500->mas4 & MAS4_TSIZED(~0));
		vcpu_e500->mas2 &= MAS2_EPN;
		vcpu_e500->mas2 |= vcpu_e500->mas4 & MAS2_ATTRIB_MASK;
		vcpu_e500->mas3 &= MAS3_U0 | MAS3_U1 | MAS3_U2 | MAS3_U3;
		vcpu_e500->mas7 = 0;
	}

	kvmppc_set_exit_type(vcpu, EMULATED_TLBSX_EXITS);
	return EMULATE_DONE;
}

int kvmppc_e500_emul_tlbwe(struct kvm_vcpu *vcpu)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	struct tlbe *gtlbe;
	int tlbsel, esel;

	tlbsel = get_tlb_tlbsel(vcpu_e500);
	esel = get_tlb_esel(vcpu_e500, tlbsel);

	gtlbe = &vcpu_e500->gtlb_arch[tlbsel][esel];

	if (get_tlb_v(gtlbe))
		kvmppc_e500_stlbe_invalidate(vcpu_e500, tlbsel, esel);

	gtlbe->mas1 = vcpu_e500->mas1;
	gtlbe->mas2 = vcpu_e500->mas2;
	gtlbe->mas3 = vcpu_e500->mas3;
	gtlbe->mas7 = vcpu_e500->mas7;

	trace_kvm_gtlb_write(vcpu_e500->mas0, gtlbe->mas1, gtlbe->mas2,
			     gtlbe->mas3, gtlbe->mas7);

	/* Invalidate shadow mappings for the about-to-be-clobbered TLBE. */
	if (tlbe_is_host_safe(vcpu, gtlbe)) {
		struct tlbe stlbe;
		int stlbsel, sesel;
		u64 eaddr;
		u64 raddr;

		preempt_disable();
		switch (tlbsel) {
		case 0:
			/* TLB0 */
			gtlbe->mas1 &= ~MAS1_TSIZE(~0);
			gtlbe->mas1 |= MAS1_TSIZE(BOOK3E_PAGESZ_4K);

			stlbsel = 0;
			sesel = kvmppc_e500_tlb0_map(vcpu_e500, esel, &stlbe);

			break;

		case 1:
			/* TLB1 */
			eaddr = get_tlb_eaddr(gtlbe);
			raddr = get_tlb_raddr(gtlbe);

			/* Create a 4KB mapping on the host.
			 * If the guest wanted a large page,
			 * only the first 4KB is mapped here and the rest
			 * are mapped on the fly. */
			stlbsel = 1;
			sesel = kvmppc_e500_tlb1_map(vcpu_e500, eaddr,
					raddr >> PAGE_SHIFT, gtlbe, &stlbe);
			break;

		default:
			BUG();
		}
		write_host_tlbe(vcpu_e500, stlbsel, sesel, &stlbe);
		preempt_enable();
	}

	kvmppc_set_exit_type(vcpu, EMULATED_TLBWE_EXITS);
	return EMULATE_DONE;
}

int kvmppc_mmu_itlb_index(struct kvm_vcpu *vcpu, gva_t eaddr)
{
	unsigned int as = !!(vcpu->arch.shared->msr & MSR_IS);

	return kvmppc_e500_tlb_search(vcpu, eaddr, get_cur_pid(vcpu), as);
}

int kvmppc_mmu_dtlb_index(struct kvm_vcpu *vcpu, gva_t eaddr)
{
	unsigned int as = !!(vcpu->arch.shared->msr & MSR_DS);

	return kvmppc_e500_tlb_search(vcpu, eaddr, get_cur_pid(vcpu), as);
}

void kvmppc_mmu_itlb_miss(struct kvm_vcpu *vcpu)
{
	unsigned int as = !!(vcpu->arch.shared->msr & MSR_IS);

	kvmppc_e500_deliver_tlb_miss(vcpu, vcpu->arch.pc, as);
}

void kvmppc_mmu_dtlb_miss(struct kvm_vcpu *vcpu)
{
	unsigned int as = !!(vcpu->arch.shared->msr & MSR_DS);

	kvmppc_e500_deliver_tlb_miss(vcpu, vcpu->arch.fault_dear, as);
}

gpa_t kvmppc_mmu_xlate(struct kvm_vcpu *vcpu, unsigned int index,
			gva_t eaddr)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	struct tlbe *gtlbe =
		&vcpu_e500->gtlb_arch[tlbsel_of(index)][esel_of(index)];
	u64 pgmask = get_tlb_bytes(gtlbe) - 1;

	return get_tlb_raddr(gtlbe) | (eaddr & pgmask);
}

void kvmppc_mmu_destroy(struct kvm_vcpu *vcpu)
{
}

void kvmppc_mmu_map(struct kvm_vcpu *vcpu, u64 eaddr, gpa_t gpaddr,
			unsigned int index)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	struct tlbe_priv *priv;
	struct tlbe *gtlbe, stlbe;
	int tlbsel = tlbsel_of(index);
	int esel = esel_of(index);
	int stlbsel, sesel;

	gtlbe = &vcpu_e500->gtlb_arch[tlbsel][esel];

	preempt_disable();
	switch (tlbsel) {
	case 0:
		stlbsel = 0;
		sesel = esel;
		priv = &vcpu_e500->gtlb_priv[stlbsel][sesel];

		kvmppc_e500_setup_stlbe(vcpu_e500, gtlbe, BOOK3E_PAGESZ_4K,
					priv, eaddr, &stlbe);
		break;

	case 1: {
		gfn_t gfn = gpaddr >> PAGE_SHIFT;

		stlbsel = 1;
		sesel = kvmppc_e500_tlb1_map(vcpu_e500, eaddr, gfn,
					     gtlbe, &stlbe);
		break;
	}

	default:
		BUG();
		break;
	}

	write_host_tlbe(vcpu_e500, stlbsel, sesel, &stlbe);
	preempt_enable();
}

int kvmppc_e500_tlb_search(struct kvm_vcpu *vcpu,
				gva_t eaddr, unsigned int pid, int as)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);
	int esel, tlbsel;

	for (tlbsel = 0; tlbsel < 2; tlbsel++) {
		esel = kvmppc_e500_tlb_index(vcpu_e500, eaddr, tlbsel, pid, as);
		if (esel >= 0)
			return index_of(tlbsel, esel);
	}

	return -1;
}

void kvmppc_set_pid(struct kvm_vcpu *vcpu, u32 pid)
{
	struct kvmppc_vcpu_e500 *vcpu_e500 = to_e500(vcpu);

	if (vcpu->arch.pid != pid) {
		vcpu_e500->pid[0] = vcpu->arch.pid = pid;
		kvmppc_e500_recalc_shadow_pid(vcpu_e500);
	}
}

void kvmppc_e500_tlb_setup(struct kvmppc_vcpu_e500 *vcpu_e500)
{
	struct tlbe *tlbe;

	/* Insert large initial mapping for guest. */
	tlbe = &vcpu_e500->gtlb_arch[1][0];
	tlbe->mas1 = MAS1_VALID | MAS1_TSIZE(BOOK3E_PAGESZ_256M);
	tlbe->mas2 = 0;
	tlbe->mas3 = E500_TLB_SUPER_PERM_MASK;
	tlbe->mas7 = 0;

	/* 4K map for serial output. Used by kernel wrapper. */
	tlbe = &vcpu_e500->gtlb_arch[1][1];
	tlbe->mas1 = MAS1_VALID | MAS1_TSIZE(BOOK3E_PAGESZ_4K);
	tlbe->mas2 = (0xe0004500 & 0xFFFFF000) | MAS2_I | MAS2_G;
	tlbe->mas3 = (0xe0004500 & 0xFFFFF000) | E500_TLB_SUPER_PERM_MASK;
	tlbe->mas7 = 0;
}

int kvmppc_e500_tlb_init(struct kvmppc_vcpu_e500 *vcpu_e500)
{
	tlb1_entry_num = mfspr(SPRN_TLB1CFG) & 0xFFF;

	vcpu_e500->gtlb_size[0] = KVM_E500_TLB0_SIZE;
	vcpu_e500->gtlb_arch[0] =
		kzalloc(sizeof(struct tlbe) * KVM_E500_TLB0_SIZE, GFP_KERNEL);
	if (vcpu_e500->gtlb_arch[0] == NULL)
		goto err_out;

	vcpu_e500->gtlb_size[1] = KVM_E500_TLB1_SIZE;
	vcpu_e500->gtlb_arch[1] =
		kzalloc(sizeof(struct tlbe) * KVM_E500_TLB1_SIZE, GFP_KERNEL);
	if (vcpu_e500->gtlb_arch[1] == NULL)
		goto err_out_guest0;

	vcpu_e500->gtlb_priv[0] = (struct tlbe_priv *)
		kzalloc(sizeof(struct tlbe_priv) * KVM_E500_TLB0_SIZE, GFP_KERNEL);
	if (vcpu_e500->gtlb_priv[0] == NULL)
		goto err_out_guest1;
	vcpu_e500->gtlb_priv[1] = (struct tlbe_priv *)
		kzalloc(sizeof(struct tlbe_priv) * KVM_E500_TLB1_SIZE, GFP_KERNEL);

	if (vcpu_e500->gtlb_priv[1] == NULL)
		goto err_out_priv0;

	if (kvmppc_e500_id_table_alloc(vcpu_e500) == NULL)
		goto err_out_priv1;

	/* Init TLB configuration register */
	vcpu_e500->tlb0cfg = mfspr(SPRN_TLB0CFG) & ~0xfffUL;
	vcpu_e500->tlb0cfg |= vcpu_e500->gtlb_size[0];
	vcpu_e500->tlb1cfg = mfspr(SPRN_TLB1CFG) & ~0xfffUL;
	vcpu_e500->tlb1cfg |= vcpu_e500->gtlb_size[1];

	return 0;

err_out_priv1:
	kfree(vcpu_e500->gtlb_priv[1]);
err_out_priv0:
	kfree(vcpu_e500->gtlb_priv[0]);
err_out_guest1:
	kfree(vcpu_e500->gtlb_arch[1]);
err_out_guest0:
	kfree(vcpu_e500->gtlb_arch[0]);
err_out:
	return -1;
}

void kvmppc_e500_tlb_uninit(struct kvmppc_vcpu_e500 *vcpu_e500)
{
	int stlbsel, i;

	/* release all privs */
	for (stlbsel = 0; stlbsel < 2; stlbsel++)
		for (i = 0; i < vcpu_e500->gtlb_size[stlbsel]; i++) {
			struct tlbe_priv *priv =
				&vcpu_e500->gtlb_priv[stlbsel][i];
			kvmppc_e500_priv_release(priv);
		}

	kvmppc_e500_id_table_free(vcpu_e500);
	kfree(vcpu_e500->gtlb_arch[1]);
	kfree(vcpu_e500->gtlb_arch[0]);
}