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2022 2023 2024 2025 2026 2027 2028 2029 2030 2031 2032 2033 2034 2035 2036 2037 2038 2039 2040 2041 2042 2043 2044 2045 2046 2047 2048 2049 2050 2051 2052 2053 2054 2055 2056 2057 2058 2059 2060 2061 2062 2063 2064 2065 2066 2067 2068 2069 2070 2071 2072 2073 2074 2075 2076 2077 2078 2079 2080 2081 2082 2083 2084 2085 2086 2087 2088 2089 2090 2091 2092 2093 2094 2095 2096 2097 2098 2099 2100 2101 2102 2103 2104 2105 2106 2107 2108 2109 2110 2111 2112 2113 2114 2115 2116 2117 2118 2119 2120 2121 2122 2123 2124 2125 2126 2127 2128 2129 2130 2131 2132 2133 2134 2135 2136 2137 2138 2139 2140 2141 2142 2143 2144 2145 2146 2147 2148 2149 2150 | // SPDX-License-Identifier: GPL-2.0-only /* * * Copyright 2010 Paul Mackerras, IBM Corp. <paulus@au1.ibm.com> */ #include <linux/types.h> #include <linux/string.h> #include <linux/kvm.h> #include <linux/kvm_host.h> #include <linux/highmem.h> #include <linux/gfp.h> #include <linux/slab.h> #include <linux/hugetlb.h> #include <linux/vmalloc.h> #include <linux/srcu.h> #include <linux/anon_inodes.h> #include <linux/file.h> #include <linux/debugfs.h> #include <asm/kvm_ppc.h> #include <asm/kvm_book3s.h> #include <asm/book3s/64/mmu-hash.h> #include <asm/hvcall.h> #include <asm/synch.h> #include <asm/ppc-opcode.h> #include <asm/cputable.h> #include <asm/pte-walk.h> #include "book3s.h" #include "book3s_hv.h" #include "trace_hv.h" //#define DEBUG_RESIZE_HPT 1 #ifdef DEBUG_RESIZE_HPT #define resize_hpt_debug(resize, ...) \ do { \ printk(KERN_DEBUG "RESIZE HPT %p: ", resize); \ printk(__VA_ARGS__); \ } while (0) #else #define resize_hpt_debug(resize, ...) \ do { } while (0) #endif static long kvmppc_virtmode_do_h_enter(struct kvm *kvm, unsigned long flags, long pte_index, unsigned long pteh, unsigned long ptel, unsigned long *pte_idx_ret); struct kvm_resize_hpt { /* These fields read-only after init */ struct kvm *kvm; struct work_struct work; u32 order; /* These fields protected by kvm->arch.mmu_setup_lock */ /* Possible values and their usage: * <0 an error occurred during allocation, * -EBUSY allocation is in the progress, * 0 allocation made successfully. */ int error; /* Private to the work thread, until error != -EBUSY, * then protected by kvm->arch.mmu_setup_lock. */ struct kvm_hpt_info hpt; }; int kvmppc_allocate_hpt(struct kvm_hpt_info *info, u32 order) { unsigned long hpt = 0; int cma = 0; struct page *page = NULL; struct revmap_entry *rev; unsigned long npte; if ((order < PPC_MIN_HPT_ORDER) || (order > PPC_MAX_HPT_ORDER)) return -EINVAL; page = kvm_alloc_hpt_cma(1ul << (order - PAGE_SHIFT)); if (page) { hpt = (unsigned long)pfn_to_kaddr(page_to_pfn(page)); memset((void *)hpt, 0, (1ul << order)); cma = 1; } if (!hpt) hpt = __get_free_pages(GFP_KERNEL|__GFP_ZERO|__GFP_RETRY_MAYFAIL |__GFP_NOWARN, order - PAGE_SHIFT); if (!hpt) return -ENOMEM; /* HPTEs are 2**4 bytes long */ npte = 1ul << (order - 4); /* Allocate reverse map array */ rev = vmalloc(array_size(npte, sizeof(struct revmap_entry))); if (!rev) { if (cma) kvm_free_hpt_cma(page, 1 << (order - PAGE_SHIFT)); else free_pages(hpt, order - PAGE_SHIFT); return -ENOMEM; } info->order = order; info->virt = hpt; info->cma = cma; info->rev = rev; return 0; } void kvmppc_set_hpt(struct kvm *kvm, struct kvm_hpt_info *info) { atomic64_set(&kvm->arch.mmio_update, 0); kvm->arch.hpt = *info; kvm->arch.sdr1 = __pa(info->virt) | (info->order - 18); pr_debug("KVM guest htab at %lx (order %ld), LPID %x\n", info->virt, (long)info->order, kvm->arch.lpid); } int kvmppc_alloc_reset_hpt(struct kvm *kvm, int order) { int err = -EBUSY; struct kvm_hpt_info info; mutex_lock(&kvm->arch.mmu_setup_lock); if (kvm->arch.mmu_ready) { kvm->arch.mmu_ready = 0; /* order mmu_ready vs. vcpus_running */ smp_mb(); if (atomic_read(&kvm->arch.vcpus_running)) { kvm->arch.mmu_ready = 1; goto out; } } if (kvm_is_radix(kvm)) { err = kvmppc_switch_mmu_to_hpt(kvm); if (err) goto out; } if (kvm->arch.hpt.order == order) { /* We already have a suitable HPT */ /* Set the entire HPT to 0, i.e. invalid HPTEs */ memset((void *)kvm->arch.hpt.virt, 0, 1ul << order); /* * Reset all the reverse-mapping chains for all memslots */ kvmppc_rmap_reset(kvm); err = 0; goto out; } if (kvm->arch.hpt.virt) { kvmppc_free_hpt(&kvm->arch.hpt); kvmppc_rmap_reset(kvm); } err = kvmppc_allocate_hpt(&info, order); if (err < 0) goto out; kvmppc_set_hpt(kvm, &info); out: if (err == 0) /* Ensure that each vcpu will flush its TLB on next entry. */ cpumask_setall(&kvm->arch.need_tlb_flush); mutex_unlock(&kvm->arch.mmu_setup_lock); return err; } void kvmppc_free_hpt(struct kvm_hpt_info *info) { vfree(info->rev); info->rev = NULL; if (info->cma) kvm_free_hpt_cma(virt_to_page((void *)info->virt), 1 << (info->order - PAGE_SHIFT)); else if (info->virt) free_pages(info->virt, info->order - PAGE_SHIFT); info->virt = 0; info->order = 0; } /* Bits in first HPTE dword for pagesize 4k, 64k or 16M */ static inline unsigned long hpte0_pgsize_encoding(unsigned long pgsize) { return (pgsize > 0x1000) ? HPTE_V_LARGE : 0; } /* Bits in second HPTE dword for pagesize 4k, 64k or 16M */ static inline unsigned long hpte1_pgsize_encoding(unsigned long pgsize) { return (pgsize == 0x10000) ? 0x1000 : 0; } void kvmppc_map_vrma(struct kvm_vcpu *vcpu, struct kvm_memory_slot *memslot, unsigned long porder) { unsigned long i; unsigned long npages; unsigned long hp_v, hp_r; unsigned long addr, hash; unsigned long psize; unsigned long hp0, hp1; unsigned long idx_ret; long ret; struct kvm *kvm = vcpu->kvm; psize = 1ul << porder; npages = memslot->npages >> (porder - PAGE_SHIFT); /* VRMA can't be > 1TB */ if (npages > 1ul << (40 - porder)) npages = 1ul << (40 - porder); /* Can't use more than 1 HPTE per HPTEG */ if (npages > kvmppc_hpt_mask(&kvm->arch.hpt) + 1) npages = kvmppc_hpt_mask(&kvm->arch.hpt) + 1; hp0 = HPTE_V_1TB_SEG | (VRMA_VSID << (40 - 16)) | HPTE_V_BOLTED | hpte0_pgsize_encoding(psize); hp1 = hpte1_pgsize_encoding(psize) | HPTE_R_R | HPTE_R_C | HPTE_R_M | PP_RWXX; for (i = 0; i < npages; ++i) { addr = i << porder; /* can't use hpt_hash since va > 64 bits */ hash = (i ^ (VRMA_VSID ^ (VRMA_VSID << 25))) & kvmppc_hpt_mask(&kvm->arch.hpt); /* * We assume that the hash table is empty and no * vcpus are using it at this stage. Since we create * at most one HPTE per HPTEG, we just assume entry 7 * is available and use it. */ hash = (hash << 3) + 7; hp_v = hp0 | ((addr >> 16) & ~0x7fUL); hp_r = hp1 | addr; ret = kvmppc_virtmode_do_h_enter(kvm, H_EXACT, hash, hp_v, hp_r, &idx_ret); if (ret != H_SUCCESS) { pr_err("KVM: map_vrma at %lx failed, ret=%ld\n", addr, ret); break; } } } int kvmppc_mmu_hv_init(void) { unsigned long nr_lpids; if (!mmu_has_feature(MMU_FTR_LOCKLESS_TLBIE)) return -EINVAL; if (cpu_has_feature(CPU_FTR_HVMODE)) { if (WARN_ON(mfspr(SPRN_LPID) != 0)) return -EINVAL; nr_lpids = 1UL << mmu_lpid_bits; } else { nr_lpids = 1UL << KVM_MAX_NESTED_GUESTS_SHIFT; } if (!cpu_has_feature(CPU_FTR_ARCH_300)) { /* POWER7 has 10-bit LPIDs, POWER8 has 12-bit LPIDs */ if (cpu_has_feature(CPU_FTR_ARCH_207S)) WARN_ON(nr_lpids != 1UL << 12); else WARN_ON(nr_lpids != 1UL << 10); /* * Reserve the last implemented LPID use in partition * switching for POWER7 and POWER8. */ nr_lpids -= 1; } kvmppc_init_lpid(nr_lpids); return 0; } static long kvmppc_virtmode_do_h_enter(struct kvm *kvm, unsigned long flags, long pte_index, unsigned long pteh, unsigned long ptel, unsigned long *pte_idx_ret) { long ret; preempt_disable(); ret = kvmppc_do_h_enter(kvm, flags, pte_index, pteh, ptel, kvm->mm->pgd, false, pte_idx_ret); preempt_enable(); if (ret == H_TOO_HARD) { /* this can't happen */ pr_err("KVM: Oops, kvmppc_h_enter returned too hard!\n"); ret = H_RESOURCE; /* or something */ } return ret; } static struct kvmppc_slb *kvmppc_mmu_book3s_hv_find_slbe(struct kvm_vcpu *vcpu, gva_t eaddr) { u64 mask; int i; for (i = 0; i < vcpu->arch.slb_nr; i++) { if (!(vcpu->arch.slb[i].orige & SLB_ESID_V)) continue; if (vcpu->arch.slb[i].origv & SLB_VSID_B_1T) mask = ESID_MASK_1T; else mask = ESID_MASK; if (((vcpu->arch.slb[i].orige ^ eaddr) & mask) == 0) return &vcpu->arch.slb[i]; } return NULL; } static unsigned long kvmppc_mmu_get_real_addr(unsigned long v, unsigned long r, unsigned long ea) { unsigned long ra_mask; ra_mask = kvmppc_actual_pgsz(v, r) - 1; return (r & HPTE_R_RPN & ~ra_mask) | (ea & ra_mask); } static int kvmppc_mmu_book3s_64_hv_xlate(struct kvm_vcpu *vcpu, gva_t eaddr, struct kvmppc_pte *gpte, bool data, bool iswrite) { struct kvm *kvm = vcpu->kvm; struct kvmppc_slb *slbe; unsigned long slb_v; unsigned long pp, key; unsigned long v, orig_v, gr; __be64 *hptep; long int index; int virtmode = __kvmppc_get_msr_hv(vcpu) & (data ? MSR_DR : MSR_IR); if (kvm_is_radix(vcpu->kvm)) return kvmppc_mmu_radix_xlate(vcpu, eaddr, gpte, data, iswrite); /* Get SLB entry */ if (virtmode) { slbe = kvmppc_mmu_book3s_hv_find_slbe(vcpu, eaddr); if (!slbe) return -EINVAL; slb_v = slbe->origv; } else { /* real mode access */ slb_v = vcpu->kvm->arch.vrma_slb_v; } preempt_disable(); /* Find the HPTE in the hash table */ index = kvmppc_hv_find_lock_hpte(kvm, eaddr, slb_v, HPTE_V_VALID | HPTE_V_ABSENT); if (index < 0) { preempt_enable(); return -ENOENT; } hptep = (__be64 *)(kvm->arch.hpt.virt + (index << 4)); v = orig_v = be64_to_cpu(hptep[0]) & ~HPTE_V_HVLOCK; if (cpu_has_feature(CPU_FTR_ARCH_300)) v = hpte_new_to_old_v(v, be64_to_cpu(hptep[1])); gr = kvm->arch.hpt.rev[index].guest_rpte; unlock_hpte(hptep, orig_v); preempt_enable(); gpte->eaddr = eaddr; gpte->vpage = ((v & HPTE_V_AVPN) << 4) | ((eaddr >> 12) & 0xfff); /* Get PP bits and key for permission check */ pp = gr & (HPTE_R_PP0 | HPTE_R_PP); key = (__kvmppc_get_msr_hv(vcpu) & MSR_PR) ? SLB_VSID_KP : SLB_VSID_KS; key &= slb_v; /* Calculate permissions */ gpte->may_read = hpte_read_permission(pp, key); gpte->may_write = hpte_write_permission(pp, key); gpte->may_execute = gpte->may_read && !(gr & (HPTE_R_N | HPTE_R_G)); /* Storage key permission check for POWER7 */ if (data && virtmode) { int amrfield = hpte_get_skey_perm(gr, vcpu->arch.amr); if (amrfield & 1) gpte->may_read = 0; if (amrfield & 2) gpte->may_write = 0; } /* Get the guest physical address */ gpte->raddr = kvmppc_mmu_get_real_addr(v, gr, eaddr); return 0; } /* * Quick test for whether an instruction is a load or a store. * If the instruction is a load or a store, then this will indicate * which it is, at least on server processors. (Embedded processors * have some external PID instructions that don't follow the rule * embodied here.) If the instruction isn't a load or store, then * this doesn't return anything useful. */ static int instruction_is_store(ppc_inst_t instr) { unsigned int mask; unsigned int suffix; mask = 0x10000000; suffix = ppc_inst_val(instr); if (ppc_inst_prefixed(instr)) suffix = ppc_inst_suffix(instr); else if ((suffix & 0xfc000000) == 0x7c000000) mask = 0x100; /* major opcode 31 */ return (suffix & mask) != 0; } int kvmppc_hv_emulate_mmio(struct kvm_vcpu *vcpu, unsigned long gpa, gva_t ea, int is_store) { ppc_inst_t last_inst; bool is_prefixed = !!(kvmppc_get_msr(vcpu) & SRR1_PREFIXED); /* * Fast path - check if the guest physical address corresponds to a * device on the FAST_MMIO_BUS, if so we can avoid loading the * instruction all together, then we can just handle it and return. */ if (is_store) { int idx, ret; idx = srcu_read_lock(&vcpu->kvm->srcu); ret = kvm_io_bus_write(vcpu, KVM_FAST_MMIO_BUS, (gpa_t) gpa, 0, NULL); srcu_read_unlock(&vcpu->kvm->srcu, idx); if (!ret) { kvmppc_set_pc(vcpu, kvmppc_get_pc(vcpu) + (is_prefixed ? 8 : 4)); return RESUME_GUEST; } } /* * If we fail, we just return to the guest and try executing it again. */ if (kvmppc_get_last_inst(vcpu, INST_GENERIC, &last_inst) != EMULATE_DONE) return RESUME_GUEST; /* * WARNING: We do not know for sure whether the instruction we just * read from memory is the same that caused the fault in the first * place. * * If the fault is prefixed but the instruction is not or vice * versa, try again so that we don't advance pc the wrong amount. */ if (ppc_inst_prefixed(last_inst) != is_prefixed) return RESUME_GUEST; /* * If the instruction we read is neither an load or a store, * then it can't access memory, so we don't need to worry about * enforcing access permissions. So, assuming it is a load or * store, we just check that its direction (load or store) is * consistent with the original fault, since that's what we * checked the access permissions against. If there is a mismatch * we just return and retry the instruction. */ if (instruction_is_store(last_inst) != !!is_store) return RESUME_GUEST; /* * Emulated accesses are emulated by looking at the hash for * translation once, then performing the access later. The * translation could be invalidated in the meantime in which * point performing the subsequent memory access on the old * physical address could possibly be a security hole for the * guest (but not the host). * * This is less of an issue for MMIO stores since they aren't * globally visible. It could be an issue for MMIO loads to * a certain extent but we'll ignore it for now. */ vcpu->arch.paddr_accessed = gpa; vcpu->arch.vaddr_accessed = ea; return kvmppc_emulate_mmio(vcpu); } int kvmppc_book3s_hv_page_fault(struct kvm_vcpu *vcpu, unsigned long ea, unsigned long dsisr) { struct kvm *kvm = vcpu->kvm; unsigned long hpte[3], r; unsigned long hnow_v, hnow_r; __be64 *hptep; unsigned long mmu_seq, psize, pte_size; unsigned long gpa_base, gfn_base; unsigned long gpa, gfn, hva, pfn, hpa; struct kvm_memory_slot *memslot; unsigned long *rmap; struct revmap_entry *rev; struct page *page; long index, ret; bool is_ci; bool writing, write_ok; unsigned int shift; unsigned long rcbits; long mmio_update; pte_t pte, *ptep; if (kvm_is_radix(kvm)) return kvmppc_book3s_radix_page_fault(vcpu, ea, dsisr); /* * Real-mode code has already searched the HPT and found the * entry we're interested in. Lock the entry and check that * it hasn't changed. If it has, just return and re-execute the * instruction. */ if (ea != vcpu->arch.pgfault_addr) return RESUME_GUEST; if (vcpu->arch.pgfault_cache) { mmio_update = atomic64_read(&kvm->arch.mmio_update); if (mmio_update == vcpu->arch.pgfault_cache->mmio_update) { r = vcpu->arch.pgfault_cache->rpte; psize = kvmppc_actual_pgsz(vcpu->arch.pgfault_hpte[0], r); gpa_base = r & HPTE_R_RPN & ~(psize - 1); gfn_base = gpa_base >> PAGE_SHIFT; gpa = gpa_base | (ea & (psize - 1)); return kvmppc_hv_emulate_mmio(vcpu, gpa, ea, dsisr & DSISR_ISSTORE); } } index = vcpu->arch.pgfault_index; hptep = (__be64 *)(kvm->arch.hpt.virt + (index << 4)); rev = &kvm->arch.hpt.rev[index]; preempt_disable(); while (!try_lock_hpte(hptep, HPTE_V_HVLOCK)) cpu_relax(); hpte[0] = be64_to_cpu(hptep[0]) & ~HPTE_V_HVLOCK; hpte[1] = be64_to_cpu(hptep[1]); hpte[2] = r = rev->guest_rpte; unlock_hpte(hptep, hpte[0]); preempt_enable(); if (cpu_has_feature(CPU_FTR_ARCH_300)) { hpte[0] = hpte_new_to_old_v(hpte[0], hpte[1]); hpte[1] = hpte_new_to_old_r(hpte[1]); } if (hpte[0] != vcpu->arch.pgfault_hpte[0] || hpte[1] != vcpu->arch.pgfault_hpte[1]) return RESUME_GUEST; /* Translate the logical address and get the page */ psize = kvmppc_actual_pgsz(hpte[0], r); gpa_base = r & HPTE_R_RPN & ~(psize - 1); gfn_base = gpa_base >> PAGE_SHIFT; gpa = gpa_base | (ea & (psize - 1)); gfn = gpa >> PAGE_SHIFT; memslot = gfn_to_memslot(kvm, gfn); trace_kvm_page_fault_enter(vcpu, hpte, memslot, ea, dsisr); /* No memslot means it's an emulated MMIO region */ if (!memslot || (memslot->flags & KVM_MEMSLOT_INVALID)) return kvmppc_hv_emulate_mmio(vcpu, gpa, ea, dsisr & DSISR_ISSTORE); /* * This should never happen, because of the slot_is_aligned() * check in kvmppc_do_h_enter(). */ if (gfn_base < memslot->base_gfn) return -EFAULT; /* used to check for invalidations in progress */ mmu_seq = kvm->mmu_invalidate_seq; smp_rmb(); ret = -EFAULT; page = NULL; writing = (dsisr & DSISR_ISSTORE) != 0; /* If writing != 0, then the HPTE must allow writing, if we get here */ write_ok = writing; hva = gfn_to_hva_memslot(memslot, gfn); /* * Do a fast check first, since __gfn_to_pfn_memslot doesn't * do it with !atomic && !async, which is how we call it. * We always ask for write permission since the common case * is that the page is writable. */ if (get_user_page_fast_only(hva, FOLL_WRITE, &page)) { write_ok = true; } else { /* Call KVM generic code to do the slow-path check */ pfn = __gfn_to_pfn_memslot(memslot, gfn, false, false, NULL, writing, &write_ok, NULL); if (is_error_noslot_pfn(pfn)) return -EFAULT; page = NULL; if (pfn_valid(pfn)) { page = pfn_to_page(pfn); if (PageReserved(page)) page = NULL; } } /* * Read the PTE from the process' radix tree and use that * so we get the shift and attribute bits. */ spin_lock(&kvm->mmu_lock); ptep = find_kvm_host_pte(kvm, mmu_seq, hva, &shift); pte = __pte(0); if (ptep) pte = READ_ONCE(*ptep); spin_unlock(&kvm->mmu_lock); /* * If the PTE disappeared temporarily due to a THP * collapse, just return and let the guest try again. */ if (!pte_present(pte)) { if (page) put_page(page); return RESUME_GUEST; } hpa = pte_pfn(pte) << PAGE_SHIFT; pte_size = PAGE_SIZE; if (shift) pte_size = 1ul << shift; is_ci = pte_ci(pte); if (psize > pte_size) goto out_put; if (pte_size > psize) hpa |= hva & (pte_size - psize); /* Check WIMG vs. the actual page we're accessing */ if (!hpte_cache_flags_ok(r, is_ci)) { if (is_ci) goto out_put; /* * Allow guest to map emulated device memory as * uncacheable, but actually make it cacheable. */ r = (r & ~(HPTE_R_W|HPTE_R_I|HPTE_R_G)) | HPTE_R_M; } /* * Set the HPTE to point to hpa. * Since the hpa is at PAGE_SIZE granularity, make sure we * don't mask out lower-order bits if psize < PAGE_SIZE. */ if (psize < PAGE_SIZE) psize = PAGE_SIZE; r = (r & HPTE_R_KEY_HI) | (r & ~(HPTE_R_PP0 - psize)) | hpa; if (hpte_is_writable(r) && !write_ok) r = hpte_make_readonly(r); ret = RESUME_GUEST; preempt_disable(); while (!try_lock_hpte(hptep, HPTE_V_HVLOCK)) cpu_relax(); hnow_v = be64_to_cpu(hptep[0]); hnow_r = be64_to_cpu(hptep[1]); if (cpu_has_feature(CPU_FTR_ARCH_300)) { hnow_v = hpte_new_to_old_v(hnow_v, hnow_r); hnow_r = hpte_new_to_old_r(hnow_r); } /* * If the HPT is being resized, don't update the HPTE, * instead let the guest retry after the resize operation is complete. * The synchronization for mmu_ready test vs. set is provided * by the HPTE lock. */ if (!kvm->arch.mmu_ready) goto out_unlock; if ((hnow_v & ~HPTE_V_HVLOCK) != hpte[0] || hnow_r != hpte[1] || rev->guest_rpte != hpte[2]) /* HPTE has been changed under us; let the guest retry */ goto out_unlock; hpte[0] = (hpte[0] & ~HPTE_V_ABSENT) | HPTE_V_VALID; /* Always put the HPTE in the rmap chain for the page base address */ rmap = &memslot->arch.rmap[gfn_base - memslot->base_gfn]; lock_rmap(rmap); /* Check if we might have been invalidated; let the guest retry if so */ ret = RESUME_GUEST; if (mmu_invalidate_retry(vcpu->kvm, mmu_seq)) { unlock_rmap(rmap); goto out_unlock; } /* Only set R/C in real HPTE if set in both *rmap and guest_rpte */ rcbits = *rmap >> KVMPPC_RMAP_RC_SHIFT; r &= rcbits | ~(HPTE_R_R | HPTE_R_C); if (be64_to_cpu(hptep[0]) & HPTE_V_VALID) { /* HPTE was previously valid, so we need to invalidate it */ unlock_rmap(rmap); hptep[0] |= cpu_to_be64(HPTE_V_ABSENT); kvmppc_invalidate_hpte(kvm, hptep, index); /* don't lose previous R and C bits */ r |= be64_to_cpu(hptep[1]) & (HPTE_R_R | HPTE_R_C); } else { kvmppc_add_revmap_chain(kvm, rev, rmap, index, 0); } if (cpu_has_feature(CPU_FTR_ARCH_300)) { r = hpte_old_to_new_r(hpte[0], r); hpte[0] = hpte_old_to_new_v(hpte[0]); } hptep[1] = cpu_to_be64(r); eieio(); __unlock_hpte(hptep, hpte[0]); asm volatile("ptesync" : : : "memory"); preempt_enable(); if (page && hpte_is_writable(r)) set_page_dirty_lock(page); out_put: trace_kvm_page_fault_exit(vcpu, hpte, ret); if (page) put_page(page); return ret; out_unlock: __unlock_hpte(hptep, be64_to_cpu(hptep[0])); preempt_enable(); goto out_put; } void kvmppc_rmap_reset(struct kvm *kvm) { struct kvm_memslots *slots; struct kvm_memory_slot *memslot; int srcu_idx, bkt; srcu_idx = srcu_read_lock(&kvm->srcu); slots = kvm_memslots(kvm); kvm_for_each_memslot(memslot, bkt, slots) { /* Mutual exclusion with kvm_unmap_hva_range etc. */ spin_lock(&kvm->mmu_lock); /* * This assumes it is acceptable to lose reference and * change bits across a reset. */ memset(memslot->arch.rmap, 0, memslot->npages * sizeof(*memslot->arch.rmap)); spin_unlock(&kvm->mmu_lock); } srcu_read_unlock(&kvm->srcu, srcu_idx); } /* Must be called with both HPTE and rmap locked */ static void kvmppc_unmap_hpte(struct kvm *kvm, unsigned long i, struct kvm_memory_slot *memslot, unsigned long *rmapp, unsigned long gfn) { __be64 *hptep = (__be64 *) (kvm->arch.hpt.virt + (i << 4)); struct revmap_entry *rev = kvm->arch.hpt.rev; unsigned long j, h; unsigned long ptel, psize, rcbits; j = rev[i].forw; if (j == i) { /* chain is now empty */ *rmapp &= ~(KVMPPC_RMAP_PRESENT | KVMPPC_RMAP_INDEX); } else { /* remove i from chain */ h = rev[i].back; rev[h].forw = j; rev[j].back = h; rev[i].forw = rev[i].back = i; *rmapp = (*rmapp & ~KVMPPC_RMAP_INDEX) | j; } /* Now check and modify the HPTE */ ptel = rev[i].guest_rpte; psize = kvmppc_actual_pgsz(be64_to_cpu(hptep[0]), ptel); if ((be64_to_cpu(hptep[0]) & HPTE_V_VALID) && hpte_rpn(ptel, psize) == gfn) { hptep[0] |= cpu_to_be64(HPTE_V_ABSENT); kvmppc_invalidate_hpte(kvm, hptep, i); hptep[1] &= ~cpu_to_be64(HPTE_R_KEY_HI | HPTE_R_KEY_LO); /* Harvest R and C */ rcbits = be64_to_cpu(hptep[1]) & (HPTE_R_R | HPTE_R_C); *rmapp |= rcbits << KVMPPC_RMAP_RC_SHIFT; if ((rcbits & HPTE_R_C) && memslot->dirty_bitmap) kvmppc_update_dirty_map(memslot, gfn, psize); if (rcbits & ~rev[i].guest_rpte) { rev[i].guest_rpte = ptel | rcbits; note_hpte_modification(kvm, &rev[i]); } } } static void kvm_unmap_rmapp(struct kvm *kvm, struct kvm_memory_slot *memslot, unsigned long gfn) { unsigned long i; __be64 *hptep; unsigned long *rmapp; rmapp = &memslot->arch.rmap[gfn - memslot->base_gfn]; for (;;) { lock_rmap(rmapp); if (!(*rmapp & KVMPPC_RMAP_PRESENT)) { unlock_rmap(rmapp); break; } /* * To avoid an ABBA deadlock with the HPTE lock bit, * we can't spin on the HPTE lock while holding the * rmap chain lock. */ i = *rmapp & KVMPPC_RMAP_INDEX; hptep = (__be64 *) (kvm->arch.hpt.virt + (i << 4)); if (!try_lock_hpte(hptep, HPTE_V_HVLOCK)) { /* unlock rmap before spinning on the HPTE lock */ unlock_rmap(rmapp); while (be64_to_cpu(hptep[0]) & HPTE_V_HVLOCK) cpu_relax(); continue; } kvmppc_unmap_hpte(kvm, i, memslot, rmapp, gfn); unlock_rmap(rmapp); __unlock_hpte(hptep, be64_to_cpu(hptep[0])); } } bool kvm_unmap_gfn_range_hv(struct kvm *kvm, struct kvm_gfn_range *range) { gfn_t gfn; if (kvm_is_radix(kvm)) { for (gfn = range->start; gfn < range->end; gfn++) kvm_unmap_radix(kvm, range->slot, gfn); } else { for (gfn = range->start; gfn < range->end; gfn++) kvm_unmap_rmapp(kvm, range->slot, gfn); } return false; } void kvmppc_core_flush_memslot_hv(struct kvm *kvm, struct kvm_memory_slot *memslot) { unsigned long gfn; unsigned long n; unsigned long *rmapp; gfn = memslot->base_gfn; rmapp = memslot->arch.rmap; if (kvm_is_radix(kvm)) { kvmppc_radix_flush_memslot(kvm, memslot); return; } for (n = memslot->npages; n; --n, ++gfn) { /* * Testing the present bit without locking is OK because * the memslot has been marked invalid already, and hence * no new HPTEs referencing this page can be created, * thus the present bit can't go from 0 to 1. */ if (*rmapp & KVMPPC_RMAP_PRESENT) kvm_unmap_rmapp(kvm, memslot, gfn); ++rmapp; } } static bool kvm_age_rmapp(struct kvm *kvm, struct kvm_memory_slot *memslot, unsigned long gfn) { struct revmap_entry *rev = kvm->arch.hpt.rev; unsigned long head, i, j; __be64 *hptep; bool ret = false; unsigned long *rmapp; rmapp = &memslot->arch.rmap[gfn - memslot->base_gfn]; retry: lock_rmap(rmapp); if (*rmapp & KVMPPC_RMAP_REFERENCED) { *rmapp &= ~KVMPPC_RMAP_REFERENCED; ret = true; } if (!(*rmapp & KVMPPC_RMAP_PRESENT)) { unlock_rmap(rmapp); return ret; } i = head = *rmapp & KVMPPC_RMAP_INDEX; do { hptep = (__be64 *) (kvm->arch.hpt.virt + (i << 4)); j = rev[i].forw; /* If this HPTE isn't referenced, ignore it */ if (!(be64_to_cpu(hptep[1]) & HPTE_R_R)) continue; if (!try_lock_hpte(hptep, HPTE_V_HVLOCK)) { /* unlock rmap before spinning on the HPTE lock */ unlock_rmap(rmapp); while (be64_to_cpu(hptep[0]) & HPTE_V_HVLOCK) cpu_relax(); goto retry; } /* Now check and modify the HPTE */ if ((be64_to_cpu(hptep[0]) & HPTE_V_VALID) && (be64_to_cpu(hptep[1]) & HPTE_R_R)) { kvmppc_clear_ref_hpte(kvm, hptep, i); if (!(rev[i].guest_rpte & HPTE_R_R)) { rev[i].guest_rpte |= HPTE_R_R; note_hpte_modification(kvm, &rev[i]); } ret = true; } __unlock_hpte(hptep, be64_to_cpu(hptep[0])); } while ((i = j) != head); unlock_rmap(rmapp); return ret; } bool kvm_age_gfn_hv(struct kvm *kvm, struct kvm_gfn_range *range) { gfn_t gfn; bool ret = false; if (kvm_is_radix(kvm)) { for (gfn = range->start; gfn < range->end; gfn++) ret |= kvm_age_radix(kvm, range->slot, gfn); } else { for (gfn = range->start; gfn < range->end; gfn++) ret |= kvm_age_rmapp(kvm, range->slot, gfn); } return ret; } static bool kvm_test_age_rmapp(struct kvm *kvm, struct kvm_memory_slot *memslot, unsigned long gfn) { struct revmap_entry *rev = kvm->arch.hpt.rev; unsigned long head, i, j; unsigned long *hp; bool ret = true; unsigned long *rmapp; rmapp = &memslot->arch.rmap[gfn - memslot->base_gfn]; if (*rmapp & KVMPPC_RMAP_REFERENCED) return true; lock_rmap(rmapp); if (*rmapp & KVMPPC_RMAP_REFERENCED) goto out; if (*rmapp & KVMPPC_RMAP_PRESENT) { i = head = *rmapp & KVMPPC_RMAP_INDEX; do { hp = (unsigned long *)(kvm->arch.hpt.virt + (i << 4)); j = rev[i].forw; if (be64_to_cpu(hp[1]) & HPTE_R_R) goto out; } while ((i = j) != head); } ret = false; out: unlock_rmap(rmapp); return ret; } bool kvm_test_age_gfn_hv(struct kvm *kvm, struct kvm_gfn_range *range) { WARN_ON(range->start + 1 != range->end); if (kvm_is_radix(kvm)) return kvm_test_age_radix(kvm, range->slot, range->start); else return kvm_test_age_rmapp(kvm, range->slot, range->start); } bool kvm_set_spte_gfn_hv(struct kvm *kvm, struct kvm_gfn_range *range) { WARN_ON(range->start + 1 != range->end); if (kvm_is_radix(kvm)) kvm_unmap_radix(kvm, range->slot, range->start); else kvm_unmap_rmapp(kvm, range->slot, range->start); return false; } static int vcpus_running(struct kvm *kvm) { return atomic_read(&kvm->arch.vcpus_running) != 0; } /* * Returns the number of system pages that are dirty. * This can be more than 1 if we find a huge-page HPTE. */ static int kvm_test_clear_dirty_npages(struct kvm *kvm, unsigned long *rmapp) { struct revmap_entry *rev = kvm->arch.hpt.rev; unsigned long head, i, j; unsigned long n; unsigned long v, r; __be64 *hptep; int npages_dirty = 0; retry: lock_rmap(rmapp); if (!(*rmapp & KVMPPC_RMAP_PRESENT)) { unlock_rmap(rmapp); return npages_dirty; } i = head = *rmapp & KVMPPC_RMAP_INDEX; do { unsigned long hptep1; hptep = (__be64 *) (kvm->arch.hpt.virt + (i << 4)); j = rev[i].forw; /* * Checking the C (changed) bit here is racy since there * is no guarantee about when the hardware writes it back. * If the HPTE is not writable then it is stable since the * page can't be written to, and we would have done a tlbie * (which forces the hardware to complete any writeback) * when making the HPTE read-only. * If vcpus are running then this call is racy anyway * since the page could get dirtied subsequently, so we * expect there to be a further call which would pick up * any delayed C bit writeback. * Otherwise we need to do the tlbie even if C==0 in * order to pick up any delayed writeback of C. */ hptep1 = be64_to_cpu(hptep[1]); if (!(hptep1 & HPTE_R_C) && (!hpte_is_writable(hptep1) || vcpus_running(kvm))) continue; if (!try_lock_hpte(hptep, HPTE_V_HVLOCK)) { /* unlock rmap before spinning on the HPTE lock */ unlock_rmap(rmapp); while (hptep[0] & cpu_to_be64(HPTE_V_HVLOCK)) cpu_relax(); goto retry; } /* Now check and modify the HPTE */ if (!(hptep[0] & cpu_to_be64(HPTE_V_VALID))) { __unlock_hpte(hptep, be64_to_cpu(hptep[0])); continue; } /* need to make it temporarily absent so C is stable */ hptep[0] |= cpu_to_be64(HPTE_V_ABSENT); kvmppc_invalidate_hpte(kvm, hptep, i); v = be64_to_cpu(hptep[0]); r = be64_to_cpu(hptep[1]); if (r & HPTE_R_C) { hptep[1] = cpu_to_be64(r & ~HPTE_R_C); if (!(rev[i].guest_rpte & HPTE_R_C)) { rev[i].guest_rpte |= HPTE_R_C; note_hpte_modification(kvm, &rev[i]); } n = kvmppc_actual_pgsz(v, r); n = (n + PAGE_SIZE - 1) >> PAGE_SHIFT; if (n > npages_dirty) npages_dirty = n; eieio(); } v &= ~HPTE_V_ABSENT; v |= HPTE_V_VALID; __unlock_hpte(hptep, v); } while ((i = j) != head); unlock_rmap(rmapp); return npages_dirty; } void kvmppc_harvest_vpa_dirty(struct kvmppc_vpa *vpa, struct kvm_memory_slot *memslot, unsigned long *map) { unsigned long gfn; if (!vpa->dirty || !vpa->pinned_addr) return; gfn = vpa->gpa >> PAGE_SHIFT; if (gfn < memslot->base_gfn || gfn >= memslot->base_gfn + memslot->npages) return; vpa->dirty = false; if (map) __set_bit_le(gfn - memslot->base_gfn, map); } long kvmppc_hv_get_dirty_log_hpt(struct kvm *kvm, struct kvm_memory_slot *memslot, unsigned long *map) { unsigned long i; unsigned long *rmapp; preempt_disable(); rmapp = memslot->arch.rmap; for (i = 0; i < memslot->npages; ++i) { int npages = kvm_test_clear_dirty_npages(kvm, rmapp); /* * Note that if npages > 0 then i must be a multiple of npages, * since we always put huge-page HPTEs in the rmap chain * corresponding to their page base address. */ if (npages) set_dirty_bits(map, i, npages); ++rmapp; } preempt_enable(); return 0; } void *kvmppc_pin_guest_page(struct kvm *kvm, unsigned long gpa, unsigned long *nb_ret) { struct kvm_memory_slot *memslot; unsigned long gfn = gpa >> PAGE_SHIFT; struct page *page, *pages[1]; int npages; unsigned long hva, offset; int srcu_idx; srcu_idx = srcu_read_lock(&kvm->srcu); memslot = gfn_to_memslot(kvm, gfn); if (!memslot || (memslot->flags & KVM_MEMSLOT_INVALID)) goto err; hva = gfn_to_hva_memslot(memslot, gfn); npages = get_user_pages_fast(hva, 1, FOLL_WRITE, pages); if (npages < 1) goto err; page = pages[0]; srcu_read_unlock(&kvm->srcu, srcu_idx); offset = gpa & (PAGE_SIZE - 1); if (nb_ret) *nb_ret = PAGE_SIZE - offset; return page_address(page) + offset; err: srcu_read_unlock(&kvm->srcu, srcu_idx); return NULL; } void kvmppc_unpin_guest_page(struct kvm *kvm, void *va, unsigned long gpa, bool dirty) { struct page *page = virt_to_page(va); struct kvm_memory_slot *memslot; unsigned long gfn; int srcu_idx; put_page(page); if (!dirty) return; /* We need to mark this page dirty in the memslot dirty_bitmap, if any */ gfn = gpa >> PAGE_SHIFT; srcu_idx = srcu_read_lock(&kvm->srcu); memslot = gfn_to_memslot(kvm, gfn); if (memslot && memslot->dirty_bitmap) set_bit_le(gfn - memslot->base_gfn, memslot->dirty_bitmap); srcu_read_unlock(&kvm->srcu, srcu_idx); } /* * HPT resizing */ static int resize_hpt_allocate(struct kvm_resize_hpt *resize) { int rc; rc = kvmppc_allocate_hpt(&resize->hpt, resize->order); if (rc < 0) return rc; resize_hpt_debug(resize, "%s(): HPT @ 0x%lx\n", __func__, resize->hpt.virt); return 0; } static unsigned long resize_hpt_rehash_hpte(struct kvm_resize_hpt *resize, unsigned long idx) { struct kvm *kvm = resize->kvm; struct kvm_hpt_info *old = &kvm->arch.hpt; struct kvm_hpt_info *new = &resize->hpt; unsigned long old_hash_mask = (1ULL << (old->order - 7)) - 1; unsigned long new_hash_mask = (1ULL << (new->order - 7)) - 1; __be64 *hptep, *new_hptep; unsigned long vpte, rpte, guest_rpte; int ret; struct revmap_entry *rev; unsigned long apsize, avpn, pteg, hash; unsigned long new_idx, new_pteg, replace_vpte; int pshift; hptep = (__be64 *)(old->virt + (idx << 4)); /* Guest is stopped, so new HPTEs can't be added or faulted * in, only unmapped or altered by host actions. So, it's * safe to check this before we take the HPTE lock */ vpte = be64_to_cpu(hptep[0]); if (!(vpte & HPTE_V_VALID) && !(vpte & HPTE_V_ABSENT)) return 0; /* nothing to do */ while (!try_lock_hpte(hptep, HPTE_V_HVLOCK)) cpu_relax(); vpte = be64_to_cpu(hptep[0]); ret = 0; if (!(vpte & HPTE_V_VALID) && !(vpte & HPTE_V_ABSENT)) /* Nothing to do */ goto out; if (cpu_has_feature(CPU_FTR_ARCH_300)) { rpte = be64_to_cpu(hptep[1]); vpte = hpte_new_to_old_v(vpte, rpte); } /* Unmap */ rev = &old->rev[idx]; guest_rpte = rev->guest_rpte; ret = -EIO; apsize = kvmppc_actual_pgsz(vpte, guest_rpte); if (!apsize) goto out; if (vpte & HPTE_V_VALID) { unsigned long gfn = hpte_rpn(guest_rpte, apsize); int srcu_idx = srcu_read_lock(&kvm->srcu); struct kvm_memory_slot *memslot = __gfn_to_memslot(kvm_memslots(kvm), gfn); if (memslot) { unsigned long *rmapp; rmapp = &memslot->arch.rmap[gfn - memslot->base_gfn]; lock_rmap(rmapp); kvmppc_unmap_hpte(kvm, idx, memslot, rmapp, gfn); unlock_rmap(rmapp); } srcu_read_unlock(&kvm->srcu, srcu_idx); } /* Reload PTE after unmap */ vpte = be64_to_cpu(hptep[0]); BUG_ON(vpte & HPTE_V_VALID); BUG_ON(!(vpte & HPTE_V_ABSENT)); ret = 0; if (!(vpte & HPTE_V_BOLTED)) goto out; rpte = be64_to_cpu(hptep[1]); if (cpu_has_feature(CPU_FTR_ARCH_300)) { vpte = hpte_new_to_old_v(vpte, rpte); rpte = hpte_new_to_old_r(rpte); } pshift = kvmppc_hpte_base_page_shift(vpte, rpte); avpn = HPTE_V_AVPN_VAL(vpte) & ~(((1ul << pshift) - 1) >> 23); pteg = idx / HPTES_PER_GROUP; if (vpte & HPTE_V_SECONDARY) pteg = ~pteg; if (!(vpte & HPTE_V_1TB_SEG)) { unsigned long offset, vsid; /* We only have 28 - 23 bits of offset in avpn */ offset = (avpn & 0x1f) << 23; vsid = avpn >> 5; /* We can find more bits from the pteg value */ if (pshift < 23) offset |= ((vsid ^ pteg) & old_hash_mask) << pshift; hash = vsid ^ (offset >> pshift); } else { unsigned long offset, vsid; /* We only have 40 - 23 bits of seg_off in avpn */ offset = (avpn & 0x1ffff) << 23; vsid = avpn >> 17; if (pshift < 23) offset |= ((vsid ^ (vsid << 25) ^ pteg) & old_hash_mask) << pshift; hash = vsid ^ (vsid << 25) ^ (offset >> pshift); } new_pteg = hash & new_hash_mask; if (vpte & HPTE_V_SECONDARY) new_pteg = ~hash & new_hash_mask; new_idx = new_pteg * HPTES_PER_GROUP + (idx % HPTES_PER_GROUP); new_hptep = (__be64 *)(new->virt + (new_idx << 4)); replace_vpte = be64_to_cpu(new_hptep[0]); if (cpu_has_feature(CPU_FTR_ARCH_300)) { unsigned long replace_rpte = be64_to_cpu(new_hptep[1]); replace_vpte = hpte_new_to_old_v(replace_vpte, replace_rpte); } if (replace_vpte & (HPTE_V_VALID | HPTE_V_ABSENT)) { BUG_ON(new->order >= old->order); if (replace_vpte & HPTE_V_BOLTED) { if (vpte & HPTE_V_BOLTED) /* Bolted collision, nothing we can do */ ret = -ENOSPC; /* Discard the new HPTE */ goto out; } /* Discard the previous HPTE */ } if (cpu_has_feature(CPU_FTR_ARCH_300)) { rpte = hpte_old_to_new_r(vpte, rpte); vpte = hpte_old_to_new_v(vpte); } new_hptep[1] = cpu_to_be64(rpte); new->rev[new_idx].guest_rpte = guest_rpte; /* No need for a barrier, since new HPT isn't active */ new_hptep[0] = cpu_to_be64(vpte); unlock_hpte(new_hptep, vpte); out: unlock_hpte(hptep, vpte); return ret; } static int resize_hpt_rehash(struct kvm_resize_hpt *resize) { struct kvm *kvm = resize->kvm; unsigned long i; int rc; for (i = 0; i < kvmppc_hpt_npte(&kvm->arch.hpt); i++) { rc = resize_hpt_rehash_hpte(resize, i); if (rc != 0) return rc; } return 0; } static void resize_hpt_pivot(struct kvm_resize_hpt *resize) { struct kvm *kvm = resize->kvm; struct kvm_hpt_info hpt_tmp; /* Exchange the pending tables in the resize structure with * the active tables */ resize_hpt_debug(resize, "resize_hpt_pivot()\n"); spin_lock(&kvm->mmu_lock); asm volatile("ptesync" : : : "memory"); hpt_tmp = kvm->arch.hpt; kvmppc_set_hpt(kvm, &resize->hpt); resize->hpt = hpt_tmp; spin_unlock(&kvm->mmu_lock); synchronize_srcu_expedited(&kvm->srcu); if (cpu_has_feature(CPU_FTR_ARCH_300)) kvmppc_setup_partition_table(kvm); resize_hpt_debug(resize, "resize_hpt_pivot() done\n"); } static void resize_hpt_release(struct kvm *kvm, struct kvm_resize_hpt *resize) { if (WARN_ON(!mutex_is_locked(&kvm->arch.mmu_setup_lock))) return; if (!resize) return; if (resize->error != -EBUSY) { if (resize->hpt.virt) kvmppc_free_hpt(&resize->hpt); kfree(resize); } if (kvm->arch.resize_hpt == resize) kvm->arch.resize_hpt = NULL; } static void resize_hpt_prepare_work(struct work_struct *work) { struct kvm_resize_hpt *resize = container_of(work, struct kvm_resize_hpt, work); struct kvm *kvm = resize->kvm; int err = 0; if (WARN_ON(resize->error != -EBUSY)) return; mutex_lock(&kvm->arch.mmu_setup_lock); /* Request is still current? */ if (kvm->arch.resize_hpt == resize) { /* We may request large allocations here: * do not sleep with kvm->arch.mmu_setup_lock held for a while. */ mutex_unlock(&kvm->arch.mmu_setup_lock); resize_hpt_debug(resize, "%s(): order = %d\n", __func__, resize->order); err = resize_hpt_allocate(resize); /* We have strict assumption about -EBUSY * when preparing for HPT resize. */ if (WARN_ON(err == -EBUSY)) err = -EINPROGRESS; mutex_lock(&kvm->arch.mmu_setup_lock); /* It is possible that kvm->arch.resize_hpt != resize * after we grab kvm->arch.mmu_setup_lock again. */ } resize->error = err; if (kvm->arch.resize_hpt != resize) resize_hpt_release(kvm, resize); mutex_unlock(&kvm->arch.mmu_setup_lock); } int kvm_vm_ioctl_resize_hpt_prepare(struct kvm *kvm, struct kvm_ppc_resize_hpt *rhpt) { unsigned long flags = rhpt->flags; unsigned long shift = rhpt->shift; struct kvm_resize_hpt *resize; int ret; if (flags != 0 || kvm_is_radix(kvm)) return -EINVAL; if (shift && ((shift < 18) || (shift > 46))) return -EINVAL; mutex_lock(&kvm->arch.mmu_setup_lock); resize = kvm->arch.resize_hpt; if (resize) { if (resize->order == shift) { /* Suitable resize in progress? */ ret = resize->error; if (ret == -EBUSY) ret = 100; /* estimated time in ms */ else if (ret) resize_hpt_release(kvm, resize); goto out; } /* not suitable, cancel it */ resize_hpt_release(kvm, resize); } ret = 0; if (!shift) goto out; /* nothing to do */ /* start new resize */ resize = kzalloc(sizeof(*resize), GFP_KERNEL); if (!resize) { ret = -ENOMEM; goto out; } resize->error = -EBUSY; resize->order = shift; resize->kvm = kvm; INIT_WORK(&resize->work, resize_hpt_prepare_work); kvm->arch.resize_hpt = resize; schedule_work(&resize->work); ret = 100; /* estimated time in ms */ out: mutex_unlock(&kvm->arch.mmu_setup_lock); return ret; } static void resize_hpt_boot_vcpu(void *opaque) { /* Nothing to do, just force a KVM exit */ } int kvm_vm_ioctl_resize_hpt_commit(struct kvm *kvm, struct kvm_ppc_resize_hpt *rhpt) { unsigned long flags = rhpt->flags; unsigned long shift = rhpt->shift; struct kvm_resize_hpt *resize; int ret; if (flags != 0 || kvm_is_radix(kvm)) return -EINVAL; if (shift && ((shift < 18) || (shift > 46))) return -EINVAL; mutex_lock(&kvm->arch.mmu_setup_lock); resize = kvm->arch.resize_hpt; /* This shouldn't be possible */ ret = -EIO; if (WARN_ON(!kvm->arch.mmu_ready)) goto out_no_hpt; /* Stop VCPUs from running while we mess with the HPT */ kvm->arch.mmu_ready = 0; smp_mb(); /* Boot all CPUs out of the guest so they re-read * mmu_ready */ on_each_cpu(resize_hpt_boot_vcpu, NULL, 1); ret = -ENXIO; if (!resize || (resize->order != shift)) goto out; ret = resize->error; if (ret) goto out; ret = resize_hpt_rehash(resize); if (ret) goto out; resize_hpt_pivot(resize); out: /* Let VCPUs run again */ kvm->arch.mmu_ready = 1; smp_mb(); out_no_hpt: resize_hpt_release(kvm, resize); mutex_unlock(&kvm->arch.mmu_setup_lock); return ret; } /* * Functions for reading and writing the hash table via reads and * writes on a file descriptor. * * Reads return the guest view of the hash table, which has to be * pieced together from the real hash table and the guest_rpte * values in the revmap array. * * On writes, each HPTE written is considered in turn, and if it * is valid, it is written to the HPT as if an H_ENTER with the * exact flag set was done. When the invalid count is non-zero * in the header written to the stream, the kernel will make * sure that that many HPTEs are invalid, and invalidate them * if not. */ struct kvm_htab_ctx { unsigned long index; unsigned long flags; struct kvm *kvm; int first_pass; }; #define HPTE_SIZE (2 * sizeof(unsigned long)) /* * Returns 1 if this HPT entry has been modified or has pending * R/C bit changes. */ static int hpte_dirty(struct revmap_entry *revp, __be64 *hptp) { unsigned long rcbits_unset; if (revp->guest_rpte & HPTE_GR_MODIFIED) return 1; /* Also need to consider changes in reference and changed bits */ rcbits_unset = ~revp->guest_rpte & (HPTE_R_R | HPTE_R_C); if ((be64_to_cpu(hptp[0]) & HPTE_V_VALID) && (be64_to_cpu(hptp[1]) & rcbits_unset)) return 1; return 0; } static long record_hpte(unsigned long flags, __be64 *hptp, unsigned long *hpte, struct revmap_entry *revp, int want_valid, int first_pass) { unsigned long v, r, hr; unsigned long rcbits_unset; int ok = 1; int valid, dirty; /* Unmodified entries are uninteresting except on the first pass */ dirty = hpte_dirty(revp, hptp); if (!first_pass && !dirty) return 0; valid = 0; if (be64_to_cpu(hptp[0]) & (HPTE_V_VALID | HPTE_V_ABSENT)) { valid = 1; if ((flags & KVM_GET_HTAB_BOLTED_ONLY) && !(be64_to_cpu(hptp[0]) & HPTE_V_BOLTED)) valid = 0; } if (valid != want_valid) return 0; v = r = 0; if (valid || dirty) { /* lock the HPTE so it's stable and read it */ preempt_disable(); while (!try_lock_hpte(hptp, HPTE_V_HVLOCK)) cpu_relax(); v = be64_to_cpu(hptp[0]); hr = be64_to_cpu(hptp[1]); if (cpu_has_feature(CPU_FTR_ARCH_300)) { v = hpte_new_to_old_v(v, hr); hr = hpte_new_to_old_r(hr); } /* re-evaluate valid and dirty from synchronized HPTE value */ valid = !!(v & HPTE_V_VALID); dirty = !!(revp->guest_rpte & HPTE_GR_MODIFIED); /* Harvest R and C into guest view if necessary */ rcbits_unset = ~revp->guest_rpte & (HPTE_R_R | HPTE_R_C); if (valid && (rcbits_unset & hr)) { revp->guest_rpte |= (hr & (HPTE_R_R | HPTE_R_C)) | HPTE_GR_MODIFIED; dirty = 1; } if (v & HPTE_V_ABSENT) { v &= ~HPTE_V_ABSENT; v |= HPTE_V_VALID; valid = 1; } if ((flags & KVM_GET_HTAB_BOLTED_ONLY) && !(v & HPTE_V_BOLTED)) valid = 0; r = revp->guest_rpte; /* only clear modified if this is the right sort of entry */ if (valid == want_valid && dirty) { r &= ~HPTE_GR_MODIFIED; revp->guest_rpte = r; } unlock_hpte(hptp, be64_to_cpu(hptp[0])); preempt_enable(); if (!(valid == want_valid && (first_pass || dirty))) ok = 0; } hpte[0] = cpu_to_be64(v); hpte[1] = cpu_to_be64(r); return ok; } static ssize_t kvm_htab_read(struct file *file, char __user *buf, size_t count, loff_t *ppos) { struct kvm_htab_ctx *ctx = file->private_data; struct kvm *kvm = ctx->kvm; struct kvm_get_htab_header hdr; __be64 *hptp; struct revmap_entry *revp; unsigned long i, nb, nw; unsigned long __user *lbuf; struct kvm_get_htab_header __user *hptr; unsigned long flags; int first_pass; unsigned long hpte[2]; if (!access_ok(buf, count)) return -EFAULT; if (kvm_is_radix(kvm)) return 0; first_pass = ctx->first_pass; flags = ctx->flags; i = ctx->index; hptp = (__be64 *)(kvm->arch.hpt.virt + (i * HPTE_SIZE)); revp = kvm->arch.hpt.rev + i; lbuf = (unsigned long __user *)buf; nb = 0; while (nb + sizeof(hdr) + HPTE_SIZE < count) { /* Initialize header */ hptr = (struct kvm_get_htab_header __user *)buf; hdr.n_valid = 0; hdr.n_invalid = 0; nw = nb; nb += sizeof(hdr); lbuf = (unsigned long __user *)(buf + sizeof(hdr)); /* Skip uninteresting entries, i.e. clean on not-first pass */ if (!first_pass) { while (i < kvmppc_hpt_npte(&kvm->arch.hpt) && !hpte_dirty(revp, hptp)) { ++i; hptp += 2; ++revp; } } hdr.index = i; /* Grab a series of valid entries */ while (i < kvmppc_hpt_npte(&kvm->arch.hpt) && hdr.n_valid < 0xffff && nb + HPTE_SIZE < count && record_hpte(flags, hptp, hpte, revp, 1, first_pass)) { /* valid entry, write it out */ ++hdr.n_valid; if (__put_user(hpte[0], lbuf) || __put_user(hpte[1], lbuf + 1)) return -EFAULT; nb += HPTE_SIZE; lbuf += 2; ++i; hptp += 2; ++revp; } /* Now skip invalid entries while we can */ while (i < kvmppc_hpt_npte(&kvm->arch.hpt) && hdr.n_invalid < 0xffff && record_hpte(flags, hptp, hpte, revp, 0, first_pass)) { /* found an invalid entry */ ++hdr.n_invalid; ++i; hptp += 2; ++revp; } if (hdr.n_valid || hdr.n_invalid) { /* write back the header */ if (__copy_to_user(hptr, &hdr, sizeof(hdr))) return -EFAULT; nw = nb; buf = (char __user *)lbuf; } else { nb = nw; } /* Check if we've wrapped around the hash table */ if (i >= kvmppc_hpt_npte(&kvm->arch.hpt)) { i = 0; ctx->first_pass = 0; break; } } ctx->index = i; return nb; } static ssize_t kvm_htab_write(struct file *file, const char __user *buf, size_t count, loff_t *ppos) { struct kvm_htab_ctx *ctx = file->private_data; struct kvm *kvm = ctx->kvm; struct kvm_get_htab_header hdr; unsigned long i, j; unsigned long v, r; unsigned long __user *lbuf; __be64 *hptp; unsigned long tmp[2]; ssize_t nb; long int err, ret; int mmu_ready; int pshift; if (!access_ok(buf, count)) return -EFAULT; if (kvm_is_radix(kvm)) return -EINVAL; /* lock out vcpus from running while we're doing this */ mutex_lock(&kvm->arch.mmu_setup_lock); mmu_ready = kvm->arch.mmu_ready; if (mmu_ready) { kvm->arch.mmu_ready = 0; /* temporarily */ /* order mmu_ready vs. vcpus_running */ smp_mb(); if (atomic_read(&kvm->arch.vcpus_running)) { kvm->arch.mmu_ready = 1; mutex_unlock(&kvm->arch.mmu_setup_lock); return -EBUSY; } } err = 0; for (nb = 0; nb + sizeof(hdr) <= count; ) { err = -EFAULT; if (__copy_from_user(&hdr, buf, sizeof(hdr))) break; err = 0; if (nb + hdr.n_valid * HPTE_SIZE > count) break; nb += sizeof(hdr); buf += sizeof(hdr); err = -EINVAL; i = hdr.index; if (i >= kvmppc_hpt_npte(&kvm->arch.hpt) || i + hdr.n_valid + hdr.n_invalid > kvmppc_hpt_npte(&kvm->arch.hpt)) break; hptp = (__be64 *)(kvm->arch.hpt.virt + (i * HPTE_SIZE)); lbuf = (unsigned long __user *)buf; for (j = 0; j < hdr.n_valid; ++j) { __be64 hpte_v; __be64 hpte_r; err = -EFAULT; if (__get_user(hpte_v, lbuf) || __get_user(hpte_r, lbuf + 1)) goto out; v = be64_to_cpu(hpte_v); r = be64_to_cpu(hpte_r); err = -EINVAL; if (!(v & HPTE_V_VALID)) goto out; pshift = kvmppc_hpte_base_page_shift(v, r); if (pshift <= 0) goto out; lbuf += 2; nb += HPTE_SIZE; if (be64_to_cpu(hptp[0]) & (HPTE_V_VALID | HPTE_V_ABSENT)) kvmppc_do_h_remove(kvm, 0, i, 0, tmp); err = -EIO; ret = kvmppc_virtmode_do_h_enter(kvm, H_EXACT, i, v, r, tmp); if (ret != H_SUCCESS) { pr_err("%s ret %ld i=%ld v=%lx r=%lx\n", __func__, ret, i, v, r); goto out; } if (!mmu_ready && is_vrma_hpte(v)) { unsigned long senc, lpcr; senc = slb_pgsize_encoding(1ul << pshift); kvm->arch.vrma_slb_v = senc | SLB_VSID_B_1T | (VRMA_VSID << SLB_VSID_SHIFT_1T); if (!cpu_has_feature(CPU_FTR_ARCH_300)) { lpcr = senc << (LPCR_VRMASD_SH - 4); kvmppc_update_lpcr(kvm, lpcr, LPCR_VRMASD); } else { kvmppc_setup_partition_table(kvm); } mmu_ready = 1; } ++i; hptp += 2; } for (j = 0; j < hdr.n_invalid; ++j) { if (be64_to_cpu(hptp[0]) & (HPTE_V_VALID | HPTE_V_ABSENT)) kvmppc_do_h_remove(kvm, 0, i, 0, tmp); ++i; hptp += 2; } err = 0; } out: /* Order HPTE updates vs. mmu_ready */ smp_wmb(); kvm->arch.mmu_ready = mmu_ready; mutex_unlock(&kvm->arch.mmu_setup_lock); if (err) return err; return nb; } static int kvm_htab_release(struct inode *inode, struct file *filp) { struct kvm_htab_ctx *ctx = filp->private_data; filp->private_data = NULL; if (!(ctx->flags & KVM_GET_HTAB_WRITE)) atomic_dec(&ctx->kvm->arch.hpte_mod_interest); kvm_put_kvm(ctx->kvm); kfree(ctx); return 0; } static const struct file_operations kvm_htab_fops = { .read = kvm_htab_read, .write = kvm_htab_write, .llseek = default_llseek, .release = kvm_htab_release, }; int kvm_vm_ioctl_get_htab_fd(struct kvm *kvm, struct kvm_get_htab_fd *ghf) { int ret; struct kvm_htab_ctx *ctx; int rwflag; /* reject flags we don't recognize */ if (ghf->flags & ~(KVM_GET_HTAB_BOLTED_ONLY | KVM_GET_HTAB_WRITE)) return -EINVAL; ctx = kzalloc(sizeof(*ctx), GFP_KERNEL); if (!ctx) return -ENOMEM; kvm_get_kvm(kvm); ctx->kvm = kvm; ctx->index = ghf->start_index; ctx->flags = ghf->flags; ctx->first_pass = 1; rwflag = (ghf->flags & KVM_GET_HTAB_WRITE) ? O_WRONLY : O_RDONLY; ret = anon_inode_getfd("kvm-htab", &kvm_htab_fops, ctx, rwflag | O_CLOEXEC); if (ret < 0) { kfree(ctx); kvm_put_kvm_no_destroy(kvm); return ret; } if (rwflag == O_RDONLY) { mutex_lock(&kvm->slots_lock); atomic_inc(&kvm->arch.hpte_mod_interest); /* make sure kvmppc_do_h_enter etc. see the increment */ synchronize_srcu_expedited(&kvm->srcu); mutex_unlock(&kvm->slots_lock); } return ret; } struct debugfs_htab_state { struct kvm *kvm; struct mutex mutex; unsigned long hpt_index; int chars_left; int buf_index; char buf[64]; }; static int debugfs_htab_open(struct inode *inode, struct file *file) { struct kvm *kvm = inode->i_private; struct debugfs_htab_state *p; p = kzalloc(sizeof(*p), GFP_KERNEL); if (!p) return -ENOMEM; kvm_get_kvm(kvm); p->kvm = kvm; mutex_init(&p->mutex); file->private_data = p; return nonseekable_open(inode, file); } static int debugfs_htab_release(struct inode *inode, struct file *file) { struct debugfs_htab_state *p = file->private_data; kvm_put_kvm(p->kvm); kfree(p); return 0; } static ssize_t debugfs_htab_read(struct file *file, char __user *buf, size_t len, loff_t *ppos) { struct debugfs_htab_state *p = file->private_data; ssize_t ret, r; unsigned long i, n; unsigned long v, hr, gr; struct kvm *kvm; __be64 *hptp; kvm = p->kvm; if (kvm_is_radix(kvm)) return 0; ret = mutex_lock_interruptible(&p->mutex); if (ret) return ret; if (p->chars_left) { n = p->chars_left; if (n > len) n = len; r = copy_to_user(buf, p->buf + p->buf_index, n); n -= r; p->chars_left -= n; p->buf_index += n; buf += n; len -= n; ret = n; if (r) { if (!n) ret = -EFAULT; goto out; } } i = p->hpt_index; hptp = (__be64 *)(kvm->arch.hpt.virt + (i * HPTE_SIZE)); for (; len != 0 && i < kvmppc_hpt_npte(&kvm->arch.hpt); ++i, hptp += 2) { if (!(be64_to_cpu(hptp[0]) & (HPTE_V_VALID | HPTE_V_ABSENT))) continue; /* lock the HPTE so it's stable and read it */ preempt_disable(); while (!try_lock_hpte(hptp, HPTE_V_HVLOCK)) cpu_relax(); v = be64_to_cpu(hptp[0]) & ~HPTE_V_HVLOCK; hr = be64_to_cpu(hptp[1]); gr = kvm->arch.hpt.rev[i].guest_rpte; unlock_hpte(hptp, v); preempt_enable(); if (!(v & (HPTE_V_VALID | HPTE_V_ABSENT))) continue; n = scnprintf(p->buf, sizeof(p->buf), "%6lx %.16lx %.16lx %.16lx\n", i, v, hr, gr); p->chars_left = n; if (n > len) n = len; r = copy_to_user(buf, p->buf, n); n -= r; p->chars_left -= n; p->buf_index = n; buf += n; len -= n; ret += n; if (r) { if (!ret) ret = -EFAULT; goto out; } } p->hpt_index = i; out: mutex_unlock(&p->mutex); return ret; } static ssize_t debugfs_htab_write(struct file *file, const char __user *buf, size_t len, loff_t *ppos) { return -EACCES; } static const struct file_operations debugfs_htab_fops = { .owner = THIS_MODULE, .open = debugfs_htab_open, .release = debugfs_htab_release, .read = debugfs_htab_read, .write = debugfs_htab_write, .llseek = generic_file_llseek, }; void kvmppc_mmu_debugfs_init(struct kvm *kvm) { debugfs_create_file("htab", 0400, kvm->debugfs_dentry, kvm, &debugfs_htab_fops); } void kvmppc_mmu_book3s_hv_init(struct kvm_vcpu *vcpu) { struct kvmppc_mmu *mmu = &vcpu->arch.mmu; vcpu->arch.slb_nr = 32; /* POWER7/POWER8 */ mmu->xlate = kvmppc_mmu_book3s_64_hv_xlate; vcpu->arch.hflags |= BOOK3S_HFLAG_SLB; } |