/* * ARM page table walking. * * This code is licensed under the GNU GPL v2 or later. * * SPDX-License-Identifier: GPL-2.0-or-later */ #include "qemu/osdep.h" #include "qemu/log.h" #include "qemu/range.h" #include "qemu/main-loop.h" #include "exec/exec-all.h" #include "exec/page-protection.h" #include "cpu.h" #include "internals.h" #include "cpu-features.h" #include "idau.h" #ifdef CONFIG_TCG # include "tcg/oversized-guest.h" #endif typedef struct S1Translate { /* * in_mmu_idx : specifies which TTBR, TCR, etc to use for the walk. * Together with in_space, specifies the architectural translation regime. */ ARMMMUIdx in_mmu_idx; /* * in_ptw_idx: specifies which mmuidx to use for the actual * page table descriptor load operations. This will be one of the * ARMMMUIdx_Stage2* or one of the ARMMMUIdx_Phys_* indexes. * If a Secure ptw is "downgraded" to NonSecure by an NSTable bit, * this field is updated accordingly. */ ARMMMUIdx in_ptw_idx; /* * in_space: the security space for this walk. This plus * the in_mmu_idx specify the architectural translation regime. * If a Secure ptw is "downgraded" to NonSecure by an NSTable bit, * this field is updated accordingly. * * Note that the security space for the in_ptw_idx may be different * from that for the in_mmu_idx. We do not need to explicitly track * the in_ptw_idx security space because: * - if the in_ptw_idx is an ARMMMUIdx_Phys_* then the mmuidx * itself specifies the security space * - if the in_ptw_idx is an ARMMMUIdx_Stage2* then the security * space used for ptw reads is the same as that of the security * space of the stage 1 translation for all cases except where * stage 1 is Secure; in that case the only possibilities for * the ptw read are Secure and NonSecure, and the in_ptw_idx * value being Stage2 vs Stage2_S distinguishes those. */ ARMSecuritySpace in_space; /* * in_debug: is this a QEMU debug access (gdbstub, etc)? Debug * accesses will not update the guest page table access flags * and will not change the state of the softmmu TLBs. */ bool in_debug; /* * If this is stage 2 of a stage 1+2 page table walk, then this must * be true if stage 1 is an EL0 access; otherwise this is ignored. * Stage 2 is indicated by in_mmu_idx set to ARMMMUIdx_Stage2{,_S}. */ bool in_s1_is_el0; bool out_rw; bool out_be; ARMSecuritySpace out_space; hwaddr out_virt; hwaddr out_phys; void *out_host; } S1Translate; static bool get_phys_addr_nogpc(CPUARMState *env, S1Translate *ptw, vaddr address, MMUAccessType access_type, MemOp memop, GetPhysAddrResult *result, ARMMMUFaultInfo *fi); static bool get_phys_addr_gpc(CPUARMState *env, S1Translate *ptw, vaddr address, MMUAccessType access_type, MemOp memop, GetPhysAddrResult *result, ARMMMUFaultInfo *fi); /* This mapping is common between ID_AA64MMFR0.PARANGE and TCR_ELx.{I}PS. */ static const uint8_t pamax_map[] = { [0] = 32, [1] = 36, [2] = 40, [3] = 42, [4] = 44, [5] = 48, [6] = 52, }; uint8_t round_down_to_parange_index(uint8_t bit_size) { for (int i = ARRAY_SIZE(pamax_map) - 1; i >= 0; i--) { if (pamax_map[i] <= bit_size) { return i; } } g_assert_not_reached(); } uint8_t round_down_to_parange_bit_size(uint8_t bit_size) { return pamax_map[round_down_to_parange_index(bit_size)]; } /* * The cpu-specific constant value of PAMax; also used by hw/arm/virt. * Note that machvirt_init calls this on a CPU that is inited but not realized! */ unsigned int arm_pamax(ARMCPU *cpu) { if (arm_feature(&cpu->env, ARM_FEATURE_AARCH64)) { unsigned int parange = FIELD_EX64(cpu->isar.id_aa64mmfr0, ID_AA64MMFR0, PARANGE); /* * id_aa64mmfr0 is a read-only register so values outside of the * supported mappings can be considered an implementation error. */ assert(parange < ARRAY_SIZE(pamax_map)); return pamax_map[parange]; } if (arm_feature(&cpu->env, ARM_FEATURE_LPAE)) { /* v7 or v8 with LPAE */ return 40; } /* Anything else */ return 32; } /* * Convert a possible stage1+2 MMU index into the appropriate stage 1 MMU index */ ARMMMUIdx stage_1_mmu_idx(ARMMMUIdx mmu_idx) { switch (mmu_idx) { case ARMMMUIdx_E10_0: return ARMMMUIdx_Stage1_E0; case ARMMMUIdx_E10_1: return ARMMMUIdx_Stage1_E1; case ARMMMUIdx_E10_1_PAN: return ARMMMUIdx_Stage1_E1_PAN; default: return mmu_idx; } } ARMMMUIdx arm_stage1_mmu_idx(CPUARMState *env) { return stage_1_mmu_idx(arm_mmu_idx(env)); } /* * Return where we should do ptw loads from for a stage 2 walk. * This depends on whether the address we are looking up is a * Secure IPA or a NonSecure IPA, which we know from whether this is * Stage2 or Stage2_S. * If this is the Secure EL1&0 regime we need to check the NSW and SW bits. */ static ARMMMUIdx ptw_idx_for_stage_2(CPUARMState *env, ARMMMUIdx stage2idx) { bool s2walk_secure; /* * We're OK to check the current state of the CPU here because * (1) we always invalidate all TLBs when the SCR_EL3.NS or SCR_EL3.NSE bit * changes. * (2) there's no way to do a lookup that cares about Stage 2 for a * different security state to the current one for AArch64, and AArch32 * never has a secure EL2. (AArch32 ATS12NSO[UP][RW] allow EL3 to do * an NS stage 1+2 lookup while the NS bit is 0.) */ if (!arm_el_is_aa64(env, 3)) { return ARMMMUIdx_Phys_NS; } switch (arm_security_space_below_el3(env)) { case ARMSS_NonSecure: return ARMMMUIdx_Phys_NS; case ARMSS_Realm: return ARMMMUIdx_Phys_Realm; case ARMSS_Secure: if (stage2idx == ARMMMUIdx_Stage2_S) { s2walk_secure = !(env->cp15.vstcr_el2 & VSTCR_SW); } else { s2walk_secure = !(env->cp15.vtcr_el2 & VTCR_NSW); } return s2walk_secure ? ARMMMUIdx_Phys_S : ARMMMUIdx_Phys_NS; default: g_assert_not_reached(); } } static bool regime_translation_big_endian(CPUARMState *env, ARMMMUIdx mmu_idx) { return (regime_sctlr(env, mmu_idx) & SCTLR_EE) != 0; } /* Return the TTBR associated with this translation regime */ static uint64_t regime_ttbr(CPUARMState *env, ARMMMUIdx mmu_idx, int ttbrn) { if (mmu_idx == ARMMMUIdx_Stage2) { return env->cp15.vttbr_el2; } if (mmu_idx == ARMMMUIdx_Stage2_S) { return env->cp15.vsttbr_el2; } if (ttbrn == 0) { return env->cp15.ttbr0_el[regime_el(env, mmu_idx)]; } else { return env->cp15.ttbr1_el[regime_el(env, mmu_idx)]; } } /* Return true if the specified stage of address translation is disabled */ static bool regime_translation_disabled(CPUARMState *env, ARMMMUIdx mmu_idx, ARMSecuritySpace space) { uint64_t hcr_el2; if (arm_feature(env, ARM_FEATURE_M)) { bool is_secure = arm_space_is_secure(space); switch (env->v7m.mpu_ctrl[is_secure] & (R_V7M_MPU_CTRL_ENABLE_MASK | R_V7M_MPU_CTRL_HFNMIENA_MASK)) { case R_V7M_MPU_CTRL_ENABLE_MASK: /* Enabled, but not for HardFault and NMI */ return mmu_idx & ARM_MMU_IDX_M_NEGPRI; case R_V7M_MPU_CTRL_ENABLE_MASK | R_V7M_MPU_CTRL_HFNMIENA_MASK: /* Enabled for all cases */ return false; case 0: default: /* * HFNMIENA set and ENABLE clear is UNPREDICTABLE, but * we warned about that in armv7m_nvic.c when the guest set it. */ return true; } } switch (mmu_idx) { case ARMMMUIdx_Stage2: case ARMMMUIdx_Stage2_S: /* HCR.DC means HCR.VM behaves as 1 */ hcr_el2 = arm_hcr_el2_eff_secstate(env, space); return (hcr_el2 & (HCR_DC | HCR_VM)) == 0; case ARMMMUIdx_E10_0: case ARMMMUIdx_E10_1: case ARMMMUIdx_E10_1_PAN: /* TGE means that EL0/1 act as if SCTLR_EL1.M is zero */ hcr_el2 = arm_hcr_el2_eff_secstate(env, space); if (hcr_el2 & HCR_TGE) { return true; } break; case ARMMMUIdx_Stage1_E0: case ARMMMUIdx_Stage1_E1: case ARMMMUIdx_Stage1_E1_PAN: /* HCR.DC means SCTLR_EL1.M behaves as 0 */ hcr_el2 = arm_hcr_el2_eff_secstate(env, space); if (hcr_el2 & HCR_DC) { return true; } break; case ARMMMUIdx_E20_0: case ARMMMUIdx_E20_2: case ARMMMUIdx_E20_2_PAN: case ARMMMUIdx_E2: case ARMMMUIdx_E3: break; case ARMMMUIdx_Phys_S: case ARMMMUIdx_Phys_NS: case ARMMMUIdx_Phys_Root: case ARMMMUIdx_Phys_Realm: /* No translation for physical address spaces. */ return true; default: g_assert_not_reached(); } return (regime_sctlr(env, mmu_idx) & SCTLR_M) == 0; } static bool granule_protection_check(CPUARMState *env, uint64_t paddress, ARMSecuritySpace pspace, ARMMMUFaultInfo *fi) { MemTxAttrs attrs = { .secure = true, .space = ARMSS_Root, }; ARMCPU *cpu = env_archcpu(env); uint64_t gpccr = env->cp15.gpccr_el3; unsigned pps, pgs, l0gptsz, level = 0; uint64_t tableaddr, pps_mask, align, entry, index; AddressSpace *as; MemTxResult result; int gpi; if (!FIELD_EX64(gpccr, GPCCR, GPC)) { return true; } /* * GPC Priority 1 (R_GMGRR): * R_JWCSM: If the configuration of GPCCR_EL3 is invalid, * the access fails as GPT walk fault at level 0. */ /* * Configuration of PPS to a value exceeding the implemented * physical address size is invalid. */ pps = FIELD_EX64(gpccr, GPCCR, PPS); if (pps > FIELD_EX64(cpu->isar.id_aa64mmfr0, ID_AA64MMFR0, PARANGE)) { goto fault_walk; } pps = pamax_map[pps]; pps_mask = MAKE_64BIT_MASK(0, pps); switch (FIELD_EX64(gpccr, GPCCR, SH)) { case 0b10: /* outer shareable */ break; case 0b00: /* non-shareable */ case 0b11: /* inner shareable */ /* Inner and Outer non-cacheable requires Outer shareable. */ if (FIELD_EX64(gpccr, GPCCR, ORGN) == 0 && FIELD_EX64(gpccr, GPCCR, IRGN) == 0) { goto fault_walk; } break; default: /* reserved */ goto fault_walk; } switch (FIELD_EX64(gpccr, GPCCR, PGS)) { case 0b00: /* 4KB */ pgs = 12; break; case 0b01: /* 64KB */ pgs = 16; break; case 0b10: /* 16KB */ pgs = 14; break; default: /* reserved */ goto fault_walk; } /* Note this field is read-only and fixed at reset. */ l0gptsz = 30 + FIELD_EX64(gpccr, GPCCR, L0GPTSZ); /* * GPC Priority 2: Secure, Realm or Root address exceeds PPS. * R_CPDSB: A NonSecure physical address input exceeding PPS * does not experience any fault. */ if (paddress & ~pps_mask) { if (pspace == ARMSS_NonSecure) { return true; } goto fault_size; } /* GPC Priority 3: the base address of GPTBR_EL3 exceeds PPS. */ tableaddr = env->cp15.gptbr_el3 << 12; if (tableaddr & ~pps_mask) { goto fault_size; } /* * BADDR is aligned per a function of PPS and L0GPTSZ. * These bits of GPTBR_EL3 are RES0, but are not a configuration error, * unlike the RES0 bits of the GPT entries (R_XNKFZ). */ align = MAX(pps - l0gptsz + 3, 12); align = MAKE_64BIT_MASK(0, align); tableaddr &= ~align; as = arm_addressspace(env_cpu(env), attrs); /* Level 0 lookup. */ index = extract64(paddress, l0gptsz, pps - l0gptsz); tableaddr += index * 8; entry = address_space_ldq_le(as, tableaddr, attrs, &result); if (result != MEMTX_OK) { goto fault_eabt; } switch (extract32(entry, 0, 4)) { case 1: /* block descriptor */ if (entry >> 8) { goto fault_walk; /* RES0 bits not 0 */ } gpi = extract32(entry, 4, 4); goto found; case 3: /* table descriptor */ tableaddr = entry & ~0xf; align = MAX(l0gptsz - pgs - 1, 12); align = MAKE_64BIT_MASK(0, align); if (tableaddr & (~pps_mask | align)) { goto fault_walk; /* RES0 bits not 0 */ } break; default: /* invalid */ goto fault_walk; } /* Level 1 lookup */ level = 1; index = extract64(paddress, pgs + 4, l0gptsz - pgs - 4); tableaddr += index * 8; entry = address_space_ldq_le(as, tableaddr, attrs, &result); if (result != MEMTX_OK) { goto fault_eabt; } switch (extract32(entry, 0, 4)) { case 1: /* contiguous descriptor */ if (entry >> 10) { goto fault_walk; /* RES0 bits not 0 */ } /* * Because the softmmu tlb only works on units of TARGET_PAGE_SIZE, * and because we cannot invalidate by pa, and thus will always * flush entire tlbs, we don't actually care about the range here * and can simply extract the GPI as the result. */ if (extract32(entry, 8, 2) == 0) { goto fault_walk; /* reserved contig */ } gpi = extract32(entry, 4, 4); break; default: index = extract64(paddress, pgs, 4); gpi = extract64(entry, index * 4, 4); break; } found: switch (gpi) { case 0b0000: /* no access */ break; case 0b1111: /* all access */ return true; case 0b1000: case 0b1001: case 0b1010: case 0b1011: if (pspace == (gpi & 3)) { return true; } break; default: goto fault_walk; /* reserved */ } fi->gpcf = GPCF_Fail; goto fault_common; fault_eabt: fi->gpcf = GPCF_EABT; goto fault_common; fault_size: fi->gpcf = GPCF_AddressSize; goto fault_common; fault_walk: fi->gpcf = GPCF_Walk; fault_common: fi->level = level; fi->paddr = paddress; fi->paddr_space = pspace; return false; } static bool S1_attrs_are_device(uint8_t attrs) { /* * This slightly under-decodes the MAIR_ELx field: * 0b0000dd01 is Device with FEAT_XS, otherwise UNPREDICTABLE; * 0b0000dd1x is UNPREDICTABLE. */ return (attrs & 0xf0) == 0; } static bool S2_attrs_are_device(uint64_t hcr, uint8_t attrs) { /* * For an S1 page table walk, the stage 1 attributes are always * some form of "this is Normal memory". The combined S1+S2 * attributes are therefore only Device if stage 2 specifies Device. * With HCR_EL2.FWB == 0 this is when descriptor bits [5:4] are 0b00, * ie when cacheattrs.attrs bits [3:2] are 0b00. * With HCR_EL2.FWB == 1 this is when descriptor bit [4] is 0, ie * when cacheattrs.attrs bit [2] is 0. */ if (hcr & HCR_FWB) { return (attrs & 0x4) == 0; } else { return (attrs & 0xc) == 0; } } static ARMSecuritySpace S2_security_space(ARMSecuritySpace s1_space, ARMMMUIdx s2_mmu_idx) { /* * Return the security space to use for stage 2 when doing * the S1 page table descriptor load. */ if (regime_is_stage2(s2_mmu_idx)) { /* * The security space for ptw reads is almost always the same * as that of the security space of the stage 1 translation. * The only exception is when stage 1 is Secure; in that case * the ptw read might be to the Secure or the NonSecure space * (but never Realm or Root), and the s2_mmu_idx tells us which. * Root translations are always single-stage. */ if (s1_space == ARMSS_Secure) { return arm_secure_to_space(s2_mmu_idx == ARMMMUIdx_Stage2_S); } else { assert(s2_mmu_idx != ARMMMUIdx_Stage2_S); assert(s1_space != ARMSS_Root); return s1_space; } } else { /* ptw loads are from phys: the mmu idx itself says which space */ return arm_phys_to_space(s2_mmu_idx); } } static bool fault_s1ns(ARMSecuritySpace space, ARMMMUIdx s2_mmu_idx) { /* * For stage 2 faults in Secure EL22, S1NS indicates * whether the faulting IPA is in the Secure or NonSecure * IPA space. For all other kinds of fault, it is false. */ return space == ARMSS_Secure && regime_is_stage2(s2_mmu_idx) && s2_mmu_idx == ARMMMUIdx_Stage2_S; } /* Translate a S1 pagetable walk through S2 if needed. */ static bool S1_ptw_translate(CPUARMState *env, S1Translate *ptw, hwaddr addr, ARMMMUFaultInfo *fi) { ARMMMUIdx mmu_idx = ptw->in_mmu_idx; ARMMMUIdx s2_mmu_idx = ptw->in_ptw_idx; uint8_t pte_attrs; ptw->out_virt = addr; if (unlikely(ptw->in_debug)) { /* * From gdbstub, do not use softmmu so that we don't modify the * state of the cpu at all, including softmmu tlb contents. */ ARMSecuritySpace s2_space = S2_security_space(ptw->in_space, s2_mmu_idx); S1Translate s2ptw = { .in_mmu_idx = s2_mmu_idx, .in_ptw_idx = ptw_idx_for_stage_2(env, s2_mmu_idx), .in_space = s2_space, .in_debug = true, }; GetPhysAddrResult s2 = { }; if (get_phys_addr_gpc(env, &s2ptw, addr, MMU_DATA_LOAD, 0, &s2, fi)) { goto fail; } ptw->out_phys = s2.f.phys_addr; pte_attrs = s2.cacheattrs.attrs; ptw->out_host = NULL; ptw->out_rw = false; ptw->out_space = s2.f.attrs.space; } else { #ifdef CONFIG_TCG CPUTLBEntryFull *full; int flags; env->tlb_fi = fi; flags = probe_access_full_mmu(env, addr, 0, MMU_DATA_LOAD, arm_to_core_mmu_idx(s2_mmu_idx), &ptw->out_host, &full); env->tlb_fi = NULL; if (unlikely(flags & TLB_INVALID_MASK)) { goto fail; } ptw->out_phys = full->phys_addr | (addr & ~TARGET_PAGE_MASK); ptw->out_rw = full->prot & PAGE_WRITE; pte_attrs = full->extra.arm.pte_attrs; ptw->out_space = full->attrs.space; #else g_assert_not_reached(); #endif } if (regime_is_stage2(s2_mmu_idx)) { uint64_t hcr = arm_hcr_el2_eff_secstate(env, ptw->in_space); if ((hcr & HCR_PTW) && S2_attrs_are_device(hcr, pte_attrs)) { /* * PTW set and S1 walk touched S2 Device memory: * generate Permission fault. */ fi->type = ARMFault_Permission; fi->s2addr = addr; fi->stage2 = true; fi->s1ptw = true; fi->s1ns = fault_s1ns(ptw->in_space, s2_mmu_idx); return false; } } ptw->out_be = regime_translation_big_endian(env, mmu_idx); return true; fail: assert(fi->type != ARMFault_None); if (fi->type == ARMFault_GPCFOnOutput) { fi->type = ARMFault_GPCFOnWalk; } fi->s2addr = addr; fi->stage2 = regime_is_stage2(s2_mmu_idx); fi->s1ptw = fi->stage2; fi->s1ns = fault_s1ns(ptw->in_space, s2_mmu_idx); return false; } /* All loads done in the course of a page table walk go through here. */ static uint32_t arm_ldl_ptw(CPUARMState *env, S1Translate *ptw, ARMMMUFaultInfo *fi) { CPUState *cs = env_cpu(env); void *host = ptw->out_host; uint32_t data; if (likely(host)) { /* Page tables are in RAM, and we have the host address. */ data = qatomic_read((uint32_t *)host); if (ptw->out_be) { data = be32_to_cpu(data); } else { data = le32_to_cpu(data); } } else { /* Page tables are in MMIO. */ MemTxAttrs attrs = { .space = ptw->out_space, .secure = arm_space_is_secure(ptw->out_space), }; AddressSpace *as = arm_addressspace(cs, attrs); MemTxResult result = MEMTX_OK; if (ptw->out_be) { data = address_space_ldl_be(as, ptw->out_phys, attrs, &result); } else { data = address_space_ldl_le(as, ptw->out_phys, attrs, &result); } if (unlikely(result != MEMTX_OK)) { fi->type = ARMFault_SyncExternalOnWalk; fi->ea = arm_extabort_type(result); return 0; } } return data; } static uint64_t arm_ldq_ptw(CPUARMState *env, S1Translate *ptw, ARMMMUFaultInfo *fi) { CPUState *cs = env_cpu(env); void *host = ptw->out_host; uint64_t data; if (likely(host)) { /* Page tables are in RAM, and we have the host address. */ #ifdef CONFIG_ATOMIC64 data = qatomic_read__nocheck((uint64_t *)host); if (ptw->out_be) { data = be64_to_cpu(data); } else { data = le64_to_cpu(data); } #else if (ptw->out_be) { data = ldq_be_p(host); } else { data = ldq_le_p(host); } #endif } else { /* Page tables are in MMIO. */ MemTxAttrs attrs = { .space = ptw->out_space, .secure = arm_space_is_secure(ptw->out_space), }; AddressSpace *as = arm_addressspace(cs, attrs); MemTxResult result = MEMTX_OK; if (ptw->out_be) { data = address_space_ldq_be(as, ptw->out_phys, attrs, &result); } else { data = address_space_ldq_le(as, ptw->out_phys, attrs, &result); } if (unlikely(result != MEMTX_OK)) { fi->type = ARMFault_SyncExternalOnWalk; fi->ea = arm_extabort_type(result); return 0; } } return data; } static uint64_t arm_casq_ptw(CPUARMState *env, uint64_t old_val, uint64_t new_val, S1Translate *ptw, ARMMMUFaultInfo *fi) { #if defined(TARGET_AARCH64) && defined(CONFIG_TCG) uint64_t cur_val; void *host = ptw->out_host; if (unlikely(!host)) { /* Page table in MMIO Memory Region */ CPUState *cs = env_cpu(env); MemTxAttrs attrs = { .space = ptw->out_space, .secure = arm_space_is_secure(ptw->out_space), }; AddressSpace *as = arm_addressspace(cs, attrs); MemTxResult result = MEMTX_OK; bool need_lock = !bql_locked(); if (need_lock) { bql_lock(); } if (ptw->out_be) { cur_val = address_space_ldq_be(as, ptw->out_phys, attrs, &result); if (unlikely(result != MEMTX_OK)) { fi->type = ARMFault_SyncExternalOnWalk; fi->ea = arm_extabort_type(result); if (need_lock) { bql_unlock(); } return old_val; } if (cur_val == old_val) { address_space_stq_be(as, ptw->out_phys, new_val, attrs, &result); if (unlikely(result != MEMTX_OK)) { fi->type = ARMFault_SyncExternalOnWalk; fi->ea = arm_extabort_type(result); if (need_lock) { bql_unlock(); } return old_val; } cur_val = new_val; } } else { cur_val = address_space_ldq_le(as, ptw->out_phys, attrs, &result); if (unlikely(result != MEMTX_OK)) { fi->type = ARMFault_SyncExternalOnWalk; fi->ea = arm_extabort_type(result); if (need_lock) { bql_unlock(); } return old_val; } if (cur_val == old_val) { address_space_stq_le(as, ptw->out_phys, new_val, attrs, &result); if (unlikely(result != MEMTX_OK)) { fi->type = ARMFault_SyncExternalOnWalk; fi->ea = arm_extabort_type(result); if (need_lock) { bql_unlock(); } return old_val; } cur_val = new_val; } } if (need_lock) { bql_unlock(); } return cur_val; } /* * Raising a stage2 Protection fault for an atomic update to a read-only * page is delayed until it is certain that there is a change to make. */ if (unlikely(!ptw->out_rw)) { int flags; env->tlb_fi = fi; flags = probe_access_full_mmu(env, ptw->out_virt, 0, MMU_DATA_STORE, arm_to_core_mmu_idx(ptw->in_ptw_idx), NULL, NULL); env->tlb_fi = NULL; if (unlikely(flags & TLB_INVALID_MASK)) { /* * We know this must be a stage 2 fault because the granule * protection table does not separately track read and write * permission, so all GPC faults are caught in S1_ptw_translate(): * we only get here for "readable but not writeable". */ assert(fi->type != ARMFault_None); fi->s2addr = ptw->out_virt; fi->stage2 = true; fi->s1ptw = true; fi->s1ns = fault_s1ns(ptw->in_space, ptw->in_ptw_idx); return 0; } /* In case CAS mismatches and we loop, remember writability. */ ptw->out_rw = true; } #ifdef CONFIG_ATOMIC64 if (ptw->out_be) { old_val = cpu_to_be64(old_val); new_val = cpu_to_be64(new_val); cur_val = qatomic_cmpxchg__nocheck((uint64_t *)host, old_val, new_val); cur_val = be64_to_cpu(cur_val); } else { old_val = cpu_to_le64(old_val); new_val = cpu_to_le64(new_val); cur_val = qatomic_cmpxchg__nocheck((uint64_t *)host, old_val, new_val); cur_val = le64_to_cpu(cur_val); } #else /* * We can't support the full 64-bit atomic cmpxchg on the host. * Because this is only used for FEAT_HAFDBS, which is only for AA64, * we know that TCG_OVERSIZED_GUEST is set, which means that we are * running in round-robin mode and could only race with dma i/o. */ #if !TCG_OVERSIZED_GUEST # error "Unexpected configuration" #endif bool locked = bql_locked(); if (!locked) { bql_lock(); } if (ptw->out_be) { cur_val = ldq_be_p(host); if (cur_val == old_val) { stq_be_p(host, new_val); } } else { cur_val = ldq_le_p(host); if (cur_val == old_val) { stq_le_p(host, new_val); } } if (!locked) { bql_unlock(); } #endif return cur_val; #else /* AArch32 does not have FEAT_HADFS; non-TCG guests only use debug-mode. */ g_assert_not_reached(); #endif } static bool get_level1_table_address(CPUARMState *env, ARMMMUIdx mmu_idx, uint32_t *table, uint32_t address) { /* Note that we can only get here for an AArch32 PL0/PL1 lookup */ uint64_t tcr = regime_tcr(env, mmu_idx); int maskshift = extract32(tcr, 0, 3); uint32_t mask = ~(((uint32_t)0xffffffffu) >> maskshift); uint32_t base_mask; if (address & mask) { if (tcr & TTBCR_PD1) { /* Translation table walk disabled for TTBR1 */ return false; } *table = regime_ttbr(env, mmu_idx, 1) & 0xffffc000; } else { if (tcr & TTBCR_PD0) { /* Translation table walk disabled for TTBR0 */ return false; } base_mask = ~((uint32_t)0x3fffu >> maskshift); *table = regime_ttbr(env, mmu_idx, 0) & base_mask; } *table |= (address >> 18) & 0x3ffc; return true; } /* * Translate section/page access permissions to page R/W protection flags * @env: CPUARMState * @mmu_idx: MMU index indicating required translation regime * @ap: The 3-bit access permissions (AP[2:0]) * @domain_prot: The 2-bit domain access permissions * @is_user: TRUE if accessing from PL0 */ static int ap_to_rw_prot_is_user(CPUARMState *env, ARMMMUIdx mmu_idx, int ap, int domain_prot, bool is_user) { if (domain_prot == 3) { return PAGE_READ | PAGE_WRITE; } switch (ap) { case 0: if (arm_feature(env, ARM_FEATURE_V7)) { return 0; } switch (regime_sctlr(env, mmu_idx) & (SCTLR_S | SCTLR_R)) { case SCTLR_S: return is_user ? 0 : PAGE_READ; case SCTLR_R: return PAGE_READ; default: return 0; } case 1: return is_user ? 0 : PAGE_READ | PAGE_WRITE; case 2: if (is_user) { return PAGE_READ; } else { return PAGE_READ | PAGE_WRITE; } case 3: return PAGE_READ | PAGE_WRITE; case 4: /* Reserved. */ return 0; case 5: return is_user ? 0 : PAGE_READ; case 6: return PAGE_READ; case 7: if (!arm_feature(env, ARM_FEATURE_V6K)) { return 0; } return PAGE_READ; default: g_assert_not_reached(); } } /* * Translate section/page access permissions to page R/W protection flags * @env: CPUARMState * @mmu_idx: MMU index indicating required translation regime * @ap: The 3-bit access permissions (AP[2:0]) * @domain_prot: The 2-bit domain access permissions */ static int ap_to_rw_prot(CPUARMState *env, ARMMMUIdx mmu_idx, int ap, int domain_prot) { return ap_to_rw_prot_is_user(env, mmu_idx, ap, domain_prot, regime_is_user(env, mmu_idx)); } /* * Translate section/page access permissions to page R/W protection flags. * @ap: The 2-bit simple AP (AP[2:1]) * @is_user: TRUE if accessing from PL0 */ static int simple_ap_to_rw_prot_is_user(int ap, bool is_user) { switch (ap) { case 0: return is_user ? 0 : PAGE_READ | PAGE_WRITE; case 1: return PAGE_READ | PAGE_WRITE; case 2: return is_user ? 0 : PAGE_READ; case 3: return PAGE_READ; default: g_assert_not_reached(); } } static int simple_ap_to_rw_prot(CPUARMState *env, ARMMMUIdx mmu_idx, int ap) { return simple_ap_to_rw_prot_is_user(ap, regime_is_user(env, mmu_idx)); } static bool get_phys_addr_v5(CPUARMState *env, S1Translate *ptw, uint32_t address, MMUAccessType access_type, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { int level = 1; uint32_t table; uint32_t desc; int type; int ap; int domain = 0; int domain_prot; hwaddr phys_addr; uint32_t dacr; /* Pagetable walk. */ /* Lookup l1 descriptor. */ if (!get_level1_table_address(env, ptw->in_mmu_idx, &table, address)) { /* Section translation fault if page walk is disabled by PD0 or PD1 */ fi->type = ARMFault_Translation; goto do_fault; } if (!S1_ptw_translate(env, ptw, table, fi)) { goto do_fault; } desc = arm_ldl_ptw(env, ptw, fi); if (fi->type != ARMFault_None) { goto do_fault; } type = (desc & 3); domain = (desc >> 5) & 0x0f; if (regime_el(env, ptw->in_mmu_idx) == 1) { dacr = env->cp15.dacr_ns; } else { dacr = env->cp15.dacr_s; } domain_prot = (dacr >> (domain * 2)) & 3; if (type == 0) { /* Section translation fault. */ fi->type = ARMFault_Translation; goto do_fault; } if (type != 2) { level = 2; } if (domain_prot == 0 || domain_prot == 2) { fi->type = ARMFault_Domain; goto do_fault; } if (type == 2) { /* 1Mb section. */ phys_addr = (desc & 0xfff00000) | (address & 0x000fffff); ap = (desc >> 10) & 3; result->f.lg_page_size = 20; /* 1MB */ } else { /* Lookup l2 entry. */ if (type == 1) { /* Coarse pagetable. */ table = (desc & 0xfffffc00) | ((address >> 10) & 0x3fc); } else { /* Fine pagetable. */ table = (desc & 0xfffff000) | ((address >> 8) & 0xffc); } if (!S1_ptw_translate(env, ptw, table, fi)) { goto do_fault; } desc = arm_ldl_ptw(env, ptw, fi); if (fi->type != ARMFault_None) { goto do_fault; } switch (desc & 3) { case 0: /* Page translation fault. */ fi->type = ARMFault_Translation; goto do_fault; case 1: /* 64k page. */ phys_addr = (desc & 0xffff0000) | (address & 0xffff); ap = (desc >> (4 + ((address >> 13) & 6))) & 3; result->f.lg_page_size = 16; break; case 2: /* 4k page. */ phys_addr = (desc & 0xfffff000) | (address & 0xfff); ap = (desc >> (4 + ((address >> 9) & 6))) & 3; result->f.lg_page_size = 12; break; case 3: /* 1k page, or ARMv6/XScale "extended small (4k) page" */ if (type == 1) { /* ARMv6/XScale extended small page format */ if (arm_feature(env, ARM_FEATURE_XSCALE) || arm_feature(env, ARM_FEATURE_V6)) { phys_addr = (desc & 0xfffff000) | (address & 0xfff); result->f.lg_page_size = 12; } else { /* * UNPREDICTABLE in ARMv5; we choose to take a * page translation fault. */ fi->type = ARMFault_Translation; goto do_fault; } } else { phys_addr = (desc & 0xfffffc00) | (address & 0x3ff); result->f.lg_page_size = 10; } ap = (desc >> 4) & 3; break; default: /* Never happens, but compiler isn't smart enough to tell. */ g_assert_not_reached(); } } result->f.prot = ap_to_rw_prot(env, ptw->in_mmu_idx, ap, domain_prot); result->f.prot |= result->f.prot ? PAGE_EXEC : 0; if (!(result->f.prot & (1 << access_type))) { /* Access permission fault. */ fi->type = ARMFault_Permission; goto do_fault; } result->f.phys_addr = phys_addr; return false; do_fault: fi->domain = domain; fi->level = level; return true; } static bool get_phys_addr_v6(CPUARMState *env, S1Translate *ptw, uint32_t address, MMUAccessType access_type, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { ARMCPU *cpu = env_archcpu(env); ARMMMUIdx mmu_idx = ptw->in_mmu_idx; int level = 1; uint32_t table; uint32_t desc; uint32_t xn; uint32_t pxn = 0; int type; int ap; int domain = 0; int domain_prot; hwaddr phys_addr; uint32_t dacr; bool ns; int user_prot; /* Pagetable walk. */ /* Lookup l1 descriptor. */ if (!get_level1_table_address(env, mmu_idx, &table, address)) { /* Section translation fault if page walk is disabled by PD0 or PD1 */ fi->type = ARMFault_Translation; goto do_fault; } if (!S1_ptw_translate(env, ptw, table, fi)) { goto do_fault; } desc = arm_ldl_ptw(env, ptw, fi); if (fi->type != ARMFault_None) { goto do_fault; } type = (desc & 3); if (type == 0 || (type == 3 && !cpu_isar_feature(aa32_pxn, cpu))) { /* Section translation fault, or attempt to use the encoding * which is Reserved on implementations without PXN. */ fi->type = ARMFault_Translation; goto do_fault; } if ((type == 1) || !(desc & (1 << 18))) { /* Page or Section. */ domain = (desc >> 5) & 0x0f; } if (regime_el(env, mmu_idx) == 1) { dacr = env->cp15.dacr_ns; } else { dacr = env->cp15.dacr_s; } if (type == 1) { level = 2; } domain_prot = (dacr >> (domain * 2)) & 3; if (domain_prot == 0 || domain_prot == 2) { /* Section or Page domain fault */ fi->type = ARMFault_Domain; goto do_fault; } if (type != 1) { if (desc & (1 << 18)) { /* Supersection. */ phys_addr = (desc & 0xff000000) | (address & 0x00ffffff); phys_addr |= (uint64_t)extract32(desc, 20, 4) << 32; phys_addr |= (uint64_t)extract32(desc, 5, 4) << 36; result->f.lg_page_size = 24; /* 16MB */ } else { /* Section. */ phys_addr = (desc & 0xfff00000) | (address & 0x000fffff); result->f.lg_page_size = 20; /* 1MB */ } ap = ((desc >> 10) & 3) | ((desc >> 13) & 4); xn = desc & (1 << 4); pxn = desc & 1; ns = extract32(desc, 19, 1); } else { if (cpu_isar_feature(aa32_pxn, cpu)) { pxn = (desc >> 2) & 1; } ns = extract32(desc, 3, 1); /* Lookup l2 entry. */ table = (desc & 0xfffffc00) | ((address >> 10) & 0x3fc); if (!S1_ptw_translate(env, ptw, table, fi)) { goto do_fault; } desc = arm_ldl_ptw(env, ptw, fi); if (fi->type != ARMFault_None) { goto do_fault; } ap = ((desc >> 4) & 3) | ((desc >> 7) & 4); switch (desc & 3) { case 0: /* Page translation fault. */ fi->type = ARMFault_Translation; goto do_fault; case 1: /* 64k page. */ phys_addr = (desc & 0xffff0000) | (address & 0xffff); xn = desc & (1 << 15); result->f.lg_page_size = 16; break; case 2: case 3: /* 4k page. */ phys_addr = (desc & 0xfffff000) | (address & 0xfff); xn = desc & 1; result->f.lg_page_size = 12; break; default: /* Never happens, but compiler isn't smart enough to tell. */ g_assert_not_reached(); } } if (domain_prot == 3) { result->f.prot = PAGE_READ | PAGE_WRITE | PAGE_EXEC; } else { if (pxn && !regime_is_user(env, mmu_idx)) { xn = 1; } if (xn && access_type == MMU_INST_FETCH) { fi->type = ARMFault_Permission; goto do_fault; } if (arm_feature(env, ARM_FEATURE_V6K) && (regime_sctlr(env, mmu_idx) & SCTLR_AFE)) { /* The simplified model uses AP[0] as an access control bit. */ if ((ap & 1) == 0) { /* Access flag fault. */ fi->type = ARMFault_AccessFlag; goto do_fault; } result->f.prot = simple_ap_to_rw_prot(env, mmu_idx, ap >> 1); user_prot = simple_ap_to_rw_prot_is_user(ap >> 1, 1); } else { result->f.prot = ap_to_rw_prot(env, mmu_idx, ap, domain_prot); user_prot = ap_to_rw_prot_is_user(env, mmu_idx, ap, domain_prot, 1); } if (result->f.prot && !xn) { result->f.prot |= PAGE_EXEC; } if (!(result->f.prot & (1 << access_type))) { /* Access permission fault. */ fi->type = ARMFault_Permission; goto do_fault; } if (regime_is_pan(env, mmu_idx) && !regime_is_user(env, mmu_idx) && user_prot && access_type != MMU_INST_FETCH) { /* Privileged Access Never fault */ fi->type = ARMFault_Permission; goto do_fault; } } if (ns) { /* The NS bit will (as required by the architecture) have no effect if * the CPU doesn't support TZ or this is a non-secure translation * regime, because the attribute will already be non-secure. */ result->f.attrs.secure = false; result->f.attrs.space = ARMSS_NonSecure; } result->f.phys_addr = phys_addr; return false; do_fault: fi->domain = domain; fi->level = level; return true; } /* * Translate S2 section/page access permissions to protection flags * @env: CPUARMState * @s2ap: The 2-bit stage2 access permissions (S2AP) * @xn: XN (execute-never) bits * @s1_is_el0: true if this is S2 of an S1+2 walk for EL0 */ static int get_S2prot_noexecute(int s2ap) { int prot = 0; if (s2ap & 1) { prot |= PAGE_READ; } if (s2ap & 2) { prot |= PAGE_WRITE; } return prot; } static int get_S2prot(CPUARMState *env, int s2ap, int xn, bool s1_is_el0) { int prot = get_S2prot_noexecute(s2ap); if (cpu_isar_feature(any_tts2uxn, env_archcpu(env))) { switch (xn) { case 0: prot |= PAGE_EXEC; break; case 1: if (s1_is_el0) { prot |= PAGE_EXEC; } break; case 2: break; case 3: if (!s1_is_el0) { prot |= PAGE_EXEC; } break; default: g_assert_not_reached(); } } else { if (!extract32(xn, 1, 1)) { if (arm_el_is_aa64(env, 2) || prot & PAGE_READ) { prot |= PAGE_EXEC; } } } return prot; } /* * Translate section/page access permissions to protection flags * @env: CPUARMState * @mmu_idx: MMU index indicating required translation regime * @is_aa64: TRUE if AArch64 * @ap: The 2-bit simple AP (AP[2:1]) * @xn: XN (execute-never) bit * @pxn: PXN (privileged execute-never) bit * @in_pa: The original input pa space * @out_pa: The output pa space, modified by NSTable, NS, and NSE */ static int get_S1prot(CPUARMState *env, ARMMMUIdx mmu_idx, bool is_aa64, int ap, int xn, int pxn, ARMSecuritySpace in_pa, ARMSecuritySpace out_pa) { ARMCPU *cpu = env_archcpu(env); bool is_user = regime_is_user(env, mmu_idx); int prot_rw, user_rw; bool have_wxn; int wxn = 0; assert(!regime_is_stage2(mmu_idx)); user_rw = simple_ap_to_rw_prot_is_user(ap, true); if (is_user) { prot_rw = user_rw; } else { /* * PAN controls can forbid data accesses but don't affect insn fetch. * Plain PAN forbids data accesses if EL0 has data permissions; * PAN3 forbids data accesses if EL0 has either data or exec perms. * Note that for AArch64 the 'user can exec' case is exactly !xn. * We make the IMPDEF choices that SCR_EL3.SIF and Realm EL2&0 * do not affect EPAN. */ if (user_rw && regime_is_pan(env, mmu_idx)) { prot_rw = 0; } else if (cpu_isar_feature(aa64_pan3, cpu) && is_aa64 && regime_is_pan(env, mmu_idx) && (regime_sctlr(env, mmu_idx) & SCTLR_EPAN) && !xn) { prot_rw = 0; } else { prot_rw = simple_ap_to_rw_prot_is_user(ap, false); } } if (in_pa != out_pa) { switch (in_pa) { case ARMSS_Root: /* * R_ZWRVD: permission fault for insn fetched from non-Root, * I_WWBFB: SIF has no effect in EL3. */ return prot_rw; case ARMSS_Realm: /* * R_PKTDS: permission fault for insn fetched from non-Realm, * for Realm EL2 or EL2&0. The corresponding fault for EL1&0 * happens during any stage2 translation. */ switch (mmu_idx) { case ARMMMUIdx_E2: case ARMMMUIdx_E20_0: case ARMMMUIdx_E20_2: case ARMMMUIdx_E20_2_PAN: return prot_rw; default: break; } break; case ARMSS_Secure: if (env->cp15.scr_el3 & SCR_SIF) { return prot_rw; } break; default: /* Input NonSecure must have output NonSecure. */ g_assert_not_reached(); } } /* TODO have_wxn should be replaced with * ARM_FEATURE_V8 || (ARM_FEATURE_V7 && ARM_FEATURE_EL2) * when ARM_FEATURE_EL2 starts getting set. For now we assume all LPAE * compatible processors have EL2, which is required for [U]WXN. */ have_wxn = arm_feature(env, ARM_FEATURE_LPAE); if (have_wxn) { wxn = regime_sctlr(env, mmu_idx) & SCTLR_WXN; } if (is_aa64) { if (regime_has_2_ranges(mmu_idx) && !is_user) { xn = pxn || (user_rw & PAGE_WRITE); } } else if (arm_feature(env, ARM_FEATURE_V7)) { switch (regime_el(env, mmu_idx)) { case 1: case 3: if (is_user) { xn = xn || !(user_rw & PAGE_READ); } else { int uwxn = 0; if (have_wxn) { uwxn = regime_sctlr(env, mmu_idx) & SCTLR_UWXN; } xn = xn || !(prot_rw & PAGE_READ) || pxn || (uwxn && (user_rw & PAGE_WRITE)); } break; case 2: break; } } else { xn = wxn = 0; } if (xn || (wxn && (prot_rw & PAGE_WRITE))) { return prot_rw; } return prot_rw | PAGE_EXEC; } static ARMVAParameters aa32_va_parameters(CPUARMState *env, uint32_t va, ARMMMUIdx mmu_idx) { uint64_t tcr = regime_tcr(env, mmu_idx); uint32_t el = regime_el(env, mmu_idx); int select, tsz; bool epd, hpd; assert(mmu_idx != ARMMMUIdx_Stage2_S); if (mmu_idx == ARMMMUIdx_Stage2) { /* VTCR */ bool sext = extract32(tcr, 4, 1); bool sign = extract32(tcr, 3, 1); /* * If the sign-extend bit is not the same as t0sz[3], the result * is unpredictable. Flag this as a guest error. */ if (sign != sext) { qemu_log_mask(LOG_GUEST_ERROR, "AArch32: VTCR.S / VTCR.T0SZ[3] mismatch\n"); } tsz = sextract32(tcr, 0, 4) + 8; select = 0; hpd = false; epd = false; } else if (el == 2) { /* HTCR */ tsz = extract32(tcr, 0, 3); select = 0; hpd = extract64(tcr, 24, 1); epd = false; } else { int t0sz = extract32(tcr, 0, 3); int t1sz = extract32(tcr, 16, 3); if (t1sz == 0) { select = va > (0xffffffffu >> t0sz); } else { /* Note that we will detect errors later. */ select = va >= ~(0xffffffffu >> t1sz); } if (!select) { tsz = t0sz; epd = extract32(tcr, 7, 1); hpd = extract64(tcr, 41, 1); } else { tsz = t1sz; epd = extract32(tcr, 23, 1); hpd = extract64(tcr, 42, 1); } /* For aarch32, hpd0 is not enabled without t2e as well. */ hpd &= extract32(tcr, 6, 1); } return (ARMVAParameters) { .tsz = tsz, .select = select, .epd = epd, .hpd = hpd, }; } /* * check_s2_mmu_setup * @cpu: ARMCPU * @is_aa64: True if the translation regime is in AArch64 state * @tcr: VTCR_EL2 or VSTCR_EL2 * @ds: Effective value of TCR.DS. * @iasize: Bitsize of IPAs * @stride: Page-table stride (See the ARM ARM) * * Decode the starting level of the S2 lookup, returning INT_MIN if * the configuration is invalid. */ static int check_s2_mmu_setup(ARMCPU *cpu, bool is_aa64, uint64_t tcr, bool ds, int iasize, int stride) { int sl0, sl2, startlevel, granulebits, levels; int s1_min_iasize, s1_max_iasize; sl0 = extract32(tcr, 6, 2); if (is_aa64) { /* * AArch64.S2InvalidSL: Interpretation of SL depends on the page size, * so interleave AArch64.S2StartLevel. */ switch (stride) { case 9: /* 4KB */ /* SL2 is RES0 unless DS=1 & 4KB granule. */ sl2 = extract64(tcr, 33, 1); if (ds && sl2) { if (sl0 != 0) { goto fail; } startlevel = -1; } else { startlevel = 2 - sl0; switch (sl0) { case 2: if (arm_pamax(cpu) < 44) { goto fail; } break; case 3: if (!cpu_isar_feature(aa64_st, cpu)) { goto fail; } startlevel = 3; break; } } break; case 11: /* 16KB */ switch (sl0) { case 2: if (arm_pamax(cpu) < 42) { goto fail; } break; case 3: if (!ds) { goto fail; } break; } startlevel = 3 - sl0; break; case 13: /* 64KB */ switch (sl0) { case 2: if (arm_pamax(cpu) < 44) { goto fail; } break; case 3: goto fail; } startlevel = 3 - sl0; break; default: g_assert_not_reached(); } } else { /* * Things are simpler for AArch32 EL2, with only 4k pages. * There is no separate S2InvalidSL function, but AArch32.S2Walk * begins with walkparms.sl0 in {'1x'}. */ assert(stride == 9); if (sl0 >= 2) { goto fail; } startlevel = 2 - sl0; } /* AArch{64,32}.S2InconsistentSL are functionally equivalent. */ levels = 3 - startlevel; granulebits = stride + 3; s1_min_iasize = levels * stride + granulebits + 1; s1_max_iasize = s1_min_iasize + (stride - 1) + 4; if (iasize >= s1_min_iasize && iasize <= s1_max_iasize) { return startlevel; } fail: return INT_MIN; } static bool lpae_block_desc_valid(ARMCPU *cpu, bool ds, ARMGranuleSize gran, int level) { /* * See pseudocode AArch46.BlockDescSupported(): block descriptors * are not valid at all levels, depending on the page size. */ switch (gran) { case Gran4K: return (level == 0 && ds) || level == 1 || level == 2; case Gran16K: return (level == 1 && ds) || level == 2; case Gran64K: return (level == 1 && arm_pamax(cpu) == 52) || level == 2; default: g_assert_not_reached(); } } static bool nv_nv1_enabled(CPUARMState *env, S1Translate *ptw) { uint64_t hcr = arm_hcr_el2_eff_secstate(env, ptw->in_space); return (hcr & (HCR_NV | HCR_NV1)) == (HCR_NV | HCR_NV1); } /** * get_phys_addr_lpae: perform one stage of page table walk, LPAE format * * Returns false if the translation was successful. Otherwise, phys_ptr, * attrs, prot and page_size may not be filled in, and the populated fsr * value provides information on why the translation aborted, in the format * of a long-format DFSR/IFSR fault register, with the following caveat: * the WnR bit is never set (the caller must do this). * * @env: CPUARMState * @ptw: Current and next stage parameters for the walk. * @address: virtual address to get physical address for * @access_type: MMU_DATA_LOAD, MMU_DATA_STORE or MMU_INST_FETCH * @memop: memory operation feeding this access, or 0 for none * @result: set on translation success, * @fi: set to fault info if the translation fails */ static bool get_phys_addr_lpae(CPUARMState *env, S1Translate *ptw, uint64_t address, MMUAccessType access_type, MemOp memop, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { ARMCPU *cpu = env_archcpu(env); ARMMMUIdx mmu_idx = ptw->in_mmu_idx; int32_t level; ARMVAParameters param; uint64_t ttbr; hwaddr descaddr, indexmask, indexmask_grainsize; uint32_t tableattrs; target_ulong page_size; uint64_t attrs; int32_t stride; int addrsize, inputsize, outputsize; uint64_t tcr = regime_tcr(env, mmu_idx); int ap, xn, pxn; uint32_t el = regime_el(env, mmu_idx); uint64_t descaddrmask; bool aarch64 = arm_el_is_aa64(env, el); uint64_t descriptor, new_descriptor; ARMSecuritySpace out_space; bool device; /* TODO: This code does not support shareability levels. */ if (aarch64) { int ps; param = aa64_va_parameters(env, address, mmu_idx, access_type != MMU_INST_FETCH, !arm_el_is_aa64(env, 1)); level = 0; /* * If TxSZ is programmed to a value larger than the maximum, * or smaller than the effective minimum, it is IMPLEMENTATION * DEFINED whether we behave as if the field were programmed * within bounds, or if a level 0 Translation fault is generated. * * With FEAT_LVA, fault on less than minimum becomes required, * so our choice is to always raise the fault. */ if (param.tsz_oob) { goto do_translation_fault; } addrsize = 64 - 8 * param.tbi; inputsize = 64 - param.tsz; /* * Bound PS by PARANGE to find the effective output address size. * ID_AA64MMFR0 is a read-only register so values outside of the * supported mappings can be considered an implementation error. */ ps = FIELD_EX64(cpu->isar.id_aa64mmfr0, ID_AA64MMFR0, PARANGE); ps = MIN(ps, param.ps); assert(ps < ARRAY_SIZE(pamax_map)); outputsize = pamax_map[ps]; /* * With LPA2, the effective output address (OA) size is at most 48 bits * unless TCR.DS == 1 */ if (!param.ds && param.gran != Gran64K) { outputsize = MIN(outputsize, 48); } } else { param = aa32_va_parameters(env, address, mmu_idx); level = 1; addrsize = (mmu_idx == ARMMMUIdx_Stage2 ? 40 : 32); inputsize = addrsize - param.tsz; outputsize = 40; } /* * We determined the region when collecting the parameters, but we * have not yet validated that the address is valid for the region. * Extract the top bits and verify that they all match select. * * For aa32, if inputsize == addrsize, then we have selected the * region by exclusion in aa32_va_parameters and there is no more * validation to do here. */ if (inputsize < addrsize) { target_ulong top_bits = sextract64(address, inputsize, addrsize - inputsize); if (-top_bits != param.select) { /* The gap between the two regions is a Translation fault */ goto do_translation_fault; } } stride = arm_granule_bits(param.gran) - 3; /* * Note that QEMU ignores shareability and cacheability attributes, * so we don't need to do anything with the SH, ORGN, IRGN fields * in the TTBCR. Similarly, TTBCR:A1 selects whether we get the * ASID from TTBR0 or TTBR1, but QEMU's TLB doesn't currently * implement any ASID-like capability so we can ignore it (instead * we will always flush the TLB any time the ASID is changed). */ ttbr = regime_ttbr(env, mmu_idx, param.select); /* * Here we should have set up all the parameters for the translation: * inputsize, ttbr, epd, stride, tbi */ if (param.epd) { /* * Translation table walk disabled => Translation fault on TLB miss * Note: This is always 0 on 64-bit EL2 and EL3. */ goto do_translation_fault; } if (!regime_is_stage2(mmu_idx)) { /* * The starting level depends on the virtual address size (which can * be up to 48 bits) and the translation granule size. It indicates * the number of strides (stride bits at a time) needed to * consume the bits of the input address. In the pseudocode this is: * level = 4 - RoundUp((inputsize - grainsize) / stride) * where their 'inputsize' is our 'inputsize', 'grainsize' is * our 'stride + 3' and 'stride' is our 'stride'. * Applying the usual "rounded up m/n is (m+n-1)/n" and simplifying: * = 4 - (inputsize - stride - 3 + stride - 1) / stride * = 4 - (inputsize - 4) / stride; */ level = 4 - (inputsize - 4) / stride; } else { int startlevel = check_s2_mmu_setup(cpu, aarch64, tcr, param.ds, inputsize, stride); if (startlevel == INT_MIN) { level = 0; goto do_translation_fault; } level = startlevel; } indexmask_grainsize = MAKE_64BIT_MASK(0, stride + 3); indexmask = MAKE_64BIT_MASK(0, inputsize - (stride * (4 - level))); /* Now we can extract the actual base address from the TTBR */ descaddr = extract64(ttbr, 0, 48); /* * For FEAT_LPA and PS=6, bits [51:48] of descaddr are in [5:2] of TTBR. * * Otherwise, if the base address is out of range, raise AddressSizeFault. * In the pseudocode, this is !IsZero(baseregister<47:outputsize>), * but we've just cleared the bits above 47, so simplify the test. */ if (outputsize > 48) { descaddr |= extract64(ttbr, 2, 4) << 48; } else if (descaddr >> outputsize) { level = 0; fi->type = ARMFault_AddressSize; goto do_fault; } /* * We rely on this masking to clear the RES0 bits at the bottom of the TTBR * and also to mask out CnP (bit 0) which could validly be non-zero. */ descaddr &= ~indexmask; /* * For AArch32, the address field in the descriptor goes up to bit 39 * for both v7 and v8. However, for v8 the SBZ bits [47:40] must be 0 * or an AddressSize fault is raised. So for v8 we extract those SBZ * bits as part of the address, which will be checked via outputsize. * For AArch64, the address field goes up to bit 47, or 49 with FEAT_LPA2; * the highest bits of a 52-bit output are placed elsewhere. */ if (param.ds) { descaddrmask = MAKE_64BIT_MASK(0, 50); } else if (arm_feature(env, ARM_FEATURE_V8)) { descaddrmask = MAKE_64BIT_MASK(0, 48); } else { descaddrmask = MAKE_64BIT_MASK(0, 40); } descaddrmask &= ~indexmask_grainsize; tableattrs = 0; next_level: descaddr |= (address >> (stride * (4 - level))) & indexmask; descaddr &= ~7ULL; /* * Process the NSTable bit from the previous level. This changes * the table address space and the output space from Secure to * NonSecure. With RME, the EL3 translation regime does not change * from Root to NonSecure. */ if (ptw->in_space == ARMSS_Secure && !regime_is_stage2(mmu_idx) && extract32(tableattrs, 4, 1)) { /* * Stage2_S -> Stage2 or Phys_S -> Phys_NS * Assert the relative order of the secure/non-secure indexes. */ QEMU_BUILD_BUG_ON(ARMMMUIdx_Phys_S + 1 != ARMMMUIdx_Phys_NS); QEMU_BUILD_BUG_ON(ARMMMUIdx_Stage2_S + 1 != ARMMMUIdx_Stage2); ptw->in_ptw_idx += 1; ptw->in_space = ARMSS_NonSecure; } if (!S1_ptw_translate(env, ptw, descaddr, fi)) { goto do_fault; } descriptor = arm_ldq_ptw(env, ptw, fi); if (fi->type != ARMFault_None) { goto do_fault; } new_descriptor = descriptor; restart_atomic_update: if (!(descriptor & 1) || (!(descriptor & 2) && !lpae_block_desc_valid(cpu, param.ds, param.gran, level))) { /* Invalid, or a block descriptor at an invalid level */ goto do_translation_fault; } descaddr = descriptor & descaddrmask; /* * For FEAT_LPA and PS=6, bits [51:48] of descaddr are in [15:12] * of descriptor. For FEAT_LPA2 and effective DS, bits [51:50] of * descaddr are in [9:8]. Otherwise, if descaddr is out of range, * raise AddressSizeFault. */ if (outputsize > 48) { if (param.ds) { descaddr |= extract64(descriptor, 8, 2) << 50; } else { descaddr |= extract64(descriptor, 12, 4) << 48; } } else if (descaddr >> outputsize) { fi->type = ARMFault_AddressSize; goto do_fault; } if ((descriptor & 2) && (level < 3)) { /* * Table entry. The top five bits are attributes which may * propagate down through lower levels of the table (and * which are all arranged so that 0 means "no effect", so * we can gather them up by ORing in the bits at each level). */ tableattrs |= extract64(descriptor, 59, 5); level++; indexmask = indexmask_grainsize; goto next_level; } /* * Block entry at level 1 or 2, or page entry at level 3. * These are basically the same thing, although the number * of bits we pull in from the vaddr varies. Note that although * descaddrmask masks enough of the low bits of the descriptor * to give a correct page or table address, the address field * in a block descriptor is smaller; so we need to explicitly * clear the lower bits here before ORing in the low vaddr bits. * * Afterward, descaddr is the final physical address. */ page_size = (1ULL << ((stride * (4 - level)) + 3)); descaddr &= ~(hwaddr)(page_size - 1); descaddr |= (address & (page_size - 1)); if (likely(!ptw->in_debug)) { /* * Access flag. * If HA is enabled, prepare to update the descriptor below. * Otherwise, pass the access fault on to software. */ if (!(descriptor & (1 << 10))) { if (param.ha) { new_descriptor |= 1 << 10; /* AF */ } else { fi->type = ARMFault_AccessFlag; goto do_fault; } } /* * Dirty Bit. * If HD is enabled, pre-emptively set/clear the appropriate AP/S2AP * bit for writeback. The actual write protection test may still be * overridden by tableattrs, to be merged below. */ if (param.hd && extract64(descriptor, 51, 1) /* DBM */ && access_type == MMU_DATA_STORE) { if (regime_is_stage2(mmu_idx)) { new_descriptor |= 1ull << 7; /* set S2AP[1] */ } else { new_descriptor &= ~(1ull << 7); /* clear AP[2] */ } } } /* * Extract attributes from the (modified) descriptor, and apply * table descriptors. Stage 2 table descriptors do not include * any attribute fields. HPD disables all the table attributes * except NSTable (which we have already handled). */ attrs = new_descriptor & (MAKE_64BIT_MASK(2, 10) | MAKE_64BIT_MASK(50, 14)); if (!regime_is_stage2(mmu_idx)) { if (!param.hpd) { attrs |= extract64(tableattrs, 0, 2) << 53; /* XN, PXN */ /* * The sense of AP[1] vs APTable[0] is reversed, as APTable[0] == 1 * means "force PL1 access only", which means forcing AP[1] to 0. */ attrs &= ~(extract64(tableattrs, 2, 1) << 6); /* !APT[0] => AP[1] */ attrs |= extract32(tableattrs, 3, 1) << 7; /* APT[1] => AP[2] */ } } ap = extract32(attrs, 6, 2); out_space = ptw->in_space; if (regime_is_stage2(mmu_idx)) { /* * R_GYNXY: For stage2 in Realm security state, bit 55 is NS. * The bit remains ignored for other security states. * R_YMCSL: Executing an insn fetched from non-Realm causes * a stage2 permission fault. */ if (out_space == ARMSS_Realm && extract64(attrs, 55, 1)) { out_space = ARMSS_NonSecure; result->f.prot = get_S2prot_noexecute(ap); } else { xn = extract64(attrs, 53, 2); result->f.prot = get_S2prot(env, ap, xn, ptw->in_s1_is_el0); } result->cacheattrs.is_s2_format = true; result->cacheattrs.attrs = extract32(attrs, 2, 4); /* * Security state does not really affect HCR_EL2.FWB; * we only need to filter FWB for aa32 or other FEAT. */ device = S2_attrs_are_device(arm_hcr_el2_eff(env), result->cacheattrs.attrs); } else { int nse, ns = extract32(attrs, 5, 1); uint8_t attrindx; uint64_t mair; switch (out_space) { case ARMSS_Root: /* * R_GVZML: Bit 11 becomes the NSE field in the EL3 regime. * R_XTYPW: NSE and NS together select the output pa space. */ nse = extract32(attrs, 11, 1); out_space = (nse << 1) | ns; if (out_space == ARMSS_Secure && !cpu_isar_feature(aa64_sel2, cpu)) { out_space = ARMSS_NonSecure; } break; case ARMSS_Secure: if (ns) { out_space = ARMSS_NonSecure; } break; case ARMSS_Realm: switch (mmu_idx) { case ARMMMUIdx_Stage1_E0: case ARMMMUIdx_Stage1_E1: case ARMMMUIdx_Stage1_E1_PAN: /* I_CZPRF: For Realm EL1&0 stage1, NS bit is RES0. */ break; case ARMMMUIdx_E2: case ARMMMUIdx_E20_0: case ARMMMUIdx_E20_2: case ARMMMUIdx_E20_2_PAN: /* * R_LYKFZ, R_WGRZN: For Realm EL2 and EL2&1, * NS changes the output to non-secure space. */ if (ns) { out_space = ARMSS_NonSecure; } break; default: g_assert_not_reached(); } break; case ARMSS_NonSecure: /* R_QRMFF: For NonSecure state, the NS bit is RES0. */ break; default: g_assert_not_reached(); } xn = extract64(attrs, 54, 1); pxn = extract64(attrs, 53, 1); if (el == 1 && nv_nv1_enabled(env, ptw)) { /* * With FEAT_NV, when HCR_EL2.{NV,NV1} == {1,1}, the block/page * descriptor bit 54 holds PXN, 53 is RES0, and the effective value * of UXN is 0. Similarly for bits 59 and 60 in table descriptors * (which we have already folded into bits 53 and 54 of attrs). * AP[1] (descriptor bit 6, our ap bit 0) is treated as 0. * Similarly, APTable[0] from the table descriptor is treated as 0; * we already folded this into AP[1] and squashing that to 0 does * the right thing. */ pxn = xn; xn = 0; ap &= ~1; } /* * Note that we modified ptw->in_space earlier for NSTable, but * result->f.attrs retains a copy of the original security space. */ result->f.prot = get_S1prot(env, mmu_idx, aarch64, ap, xn, pxn, result->f.attrs.space, out_space); /* Index into MAIR registers for cache attributes */ attrindx = extract32(attrs, 2, 3); mair = env->cp15.mair_el[regime_el(env, mmu_idx)]; assert(attrindx <= 7); result->cacheattrs.is_s2_format = false; result->cacheattrs.attrs = extract64(mair, attrindx * 8, 8); /* When in aarch64 mode, and BTI is enabled, remember GP in the TLB. */ if (aarch64 && cpu_isar_feature(aa64_bti, cpu)) { result->f.extra.arm.guarded = extract64(attrs, 50, 1); /* GP */ } device = S1_attrs_are_device(result->cacheattrs.attrs); } /* * Enable alignment checks on Device memory. * * Per R_XCHFJ, the correct ordering for alignment, permission, * and stage 2 faults is: * - Alignment fault caused by the memory type * - Permission fault * - A stage 2 fault on the memory access * Perform the alignment check now, so that we recognize it in * the correct order. Set TLB_CHECK_ALIGNED so that any subsequent * softmmu tlb hit will also check the alignment; clear along the * non-device path so that tlb_fill_flags is consistent in the * event of restart_atomic_update. * * In v7, for a CPU without the Virtualization Extensions this * access is UNPREDICTABLE; we choose to make it take the alignment * fault as is required for a v7VE CPU. (QEMU doesn't emulate any * CPUs with ARM_FEATURE_LPAE but not ARM_FEATURE_V7VE anyway.) */ if (device) { unsigned a_bits = memop_atomicity_bits(memop); if (address & ((1 << a_bits) - 1)) { fi->type = ARMFault_Alignment; goto do_fault; } result->f.tlb_fill_flags = TLB_CHECK_ALIGNED; } else { result->f.tlb_fill_flags = 0; } if (!(result->f.prot & (1 << access_type))) { fi->type = ARMFault_Permission; goto do_fault; } /* If FEAT_HAFDBS has made changes, update the PTE. */ if (new_descriptor != descriptor) { new_descriptor = arm_casq_ptw(env, descriptor, new_descriptor, ptw, fi); if (fi->type != ARMFault_None) { goto do_fault; } /* * I_YZSVV says that if the in-memory descriptor has changed, * then we must use the information in that new value * (which might include a different output address, different * attributes, or generate a fault). * Restart the handling of the descriptor value from scratch. */ if (new_descriptor != descriptor) { descriptor = new_descriptor; goto restart_atomic_update; } } result->f.attrs.space = out_space; result->f.attrs.secure = arm_space_is_secure(out_space); /* * For FEAT_LPA2 and effective DS, the SH field in the attributes * was re-purposed for output address bits. The SH attribute in * that case comes from TCR_ELx, which we extracted earlier. */ if (param.ds) { result->cacheattrs.shareability = param.sh; } else { result->cacheattrs.shareability = extract32(attrs, 8, 2); } result->f.phys_addr = descaddr; result->f.lg_page_size = ctz64(page_size); return false; do_translation_fault: fi->type = ARMFault_Translation; do_fault: if (fi->s1ptw) { /* Retain the existing stage 2 fi->level */ assert(fi->stage2); } else { fi->level = level; fi->stage2 = regime_is_stage2(mmu_idx); } fi->s1ns = fault_s1ns(ptw->in_space, mmu_idx); return true; } static bool get_phys_addr_pmsav5(CPUARMState *env, S1Translate *ptw, uint32_t address, MMUAccessType access_type, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { int n; uint32_t mask; uint32_t base; ARMMMUIdx mmu_idx = ptw->in_mmu_idx; bool is_user = regime_is_user(env, mmu_idx); if (regime_translation_disabled(env, mmu_idx, ptw->in_space)) { /* MPU disabled. */ result->f.phys_addr = address; result->f.prot = PAGE_READ | PAGE_WRITE | PAGE_EXEC; return false; } result->f.phys_addr = address; for (n = 7; n >= 0; n--) { base = env->cp15.c6_region[n]; if ((base & 1) == 0) { continue; } mask = 1 << ((base >> 1) & 0x1f); /* Keep this shift separate from the above to avoid an (undefined) << 32. */ mask = (mask << 1) - 1; if (((base ^ address) & ~mask) == 0) { break; } } if (n < 0) { fi->type = ARMFault_Background; return true; } if (access_type == MMU_INST_FETCH) { mask = env->cp15.pmsav5_insn_ap; } else { mask = env->cp15.pmsav5_data_ap; } mask = (mask >> (n * 4)) & 0xf; switch (mask) { case 0: fi->type = ARMFault_Permission; fi->level = 1; return true; case 1: if (is_user) { fi->type = ARMFault_Permission; fi->level = 1; return true; } result->f.prot = PAGE_READ | PAGE_WRITE; break; case 2: result->f.prot = PAGE_READ; if (!is_user) { result->f.prot |= PAGE_WRITE; } break; case 3: result->f.prot = PAGE_READ | PAGE_WRITE; break; case 5: if (is_user) { fi->type = ARMFault_Permission; fi->level = 1; return true; } result->f.prot = PAGE_READ; break; case 6: result->f.prot = PAGE_READ; break; default: /* Bad permission. */ fi->type = ARMFault_Permission; fi->level = 1; return true; } result->f.prot |= PAGE_EXEC; return false; } static void get_phys_addr_pmsav7_default(CPUARMState *env, ARMMMUIdx mmu_idx, int32_t address, uint8_t *prot) { if (!arm_feature(env, ARM_FEATURE_M)) { *prot = PAGE_READ | PAGE_WRITE; switch (address) { case 0xF0000000 ... 0xFFFFFFFF: if (regime_sctlr(env, mmu_idx) & SCTLR_V) { /* hivecs execing is ok */ *prot |= PAGE_EXEC; } break; case 0x00000000 ... 0x7FFFFFFF: *prot |= PAGE_EXEC; break; } } else { /* Default system address map for M profile cores. * The architecture specifies which regions are execute-never; * at the MPU level no other checks are defined. */ switch (address) { case 0x00000000 ... 0x1fffffff: /* ROM */ case 0x20000000 ... 0x3fffffff: /* SRAM */ case 0x60000000 ... 0x7fffffff: /* RAM */ case 0x80000000 ... 0x9fffffff: /* RAM */ *prot = PAGE_READ | PAGE_WRITE | PAGE_EXEC; break; case 0x40000000 ... 0x5fffffff: /* Peripheral */ case 0xa0000000 ... 0xbfffffff: /* Device */ case 0xc0000000 ... 0xdfffffff: /* Device */ case 0xe0000000 ... 0xffffffff: /* System */ *prot = PAGE_READ | PAGE_WRITE; break; default: g_assert_not_reached(); } } } static bool m_is_ppb_region(CPUARMState *env, uint32_t address) { /* True if address is in the M profile PPB region 0xe0000000 - 0xe00fffff */ return arm_feature(env, ARM_FEATURE_M) && extract32(address, 20, 12) == 0xe00; } static bool m_is_system_region(CPUARMState *env, uint32_t address) { /* * True if address is in the M profile system region * 0xe0000000 - 0xffffffff */ return arm_feature(env, ARM_FEATURE_M) && extract32(address, 29, 3) == 0x7; } static bool pmsav7_use_background_region(ARMCPU *cpu, ARMMMUIdx mmu_idx, bool is_secure, bool is_user) { /* * Return true if we should use the default memory map as a * "background" region if there are no hits against any MPU regions. */ CPUARMState *env = &cpu->env; if (is_user) { return false; } if (arm_feature(env, ARM_FEATURE_M)) { return env->v7m.mpu_ctrl[is_secure] & R_V7M_MPU_CTRL_PRIVDEFENA_MASK; } if (mmu_idx == ARMMMUIdx_Stage2) { return false; } return regime_sctlr(env, mmu_idx) & SCTLR_BR; } static bool get_phys_addr_pmsav7(CPUARMState *env, S1Translate *ptw, uint32_t address, MMUAccessType access_type, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { ARMCPU *cpu = env_archcpu(env); int n; ARMMMUIdx mmu_idx = ptw->in_mmu_idx; bool is_user = regime_is_user(env, mmu_idx); bool secure = arm_space_is_secure(ptw->in_space); result->f.phys_addr = address; result->f.lg_page_size = TARGET_PAGE_BITS; result->f.prot = 0; if (regime_translation_disabled(env, mmu_idx, ptw->in_space) || m_is_ppb_region(env, address)) { /* * MPU disabled or M profile PPB access: use default memory map. * The other case which uses the default memory map in the * v7M ARM ARM pseudocode is exception vector reads from the vector * table. In QEMU those accesses are done in arm_v7m_load_vector(), * which always does a direct read using address_space_ldl(), rather * than going via this function, so we don't need to check that here. */ get_phys_addr_pmsav7_default(env, mmu_idx, address, &result->f.prot); } else { /* MPU enabled */ for (n = (int)cpu->pmsav7_dregion - 1; n >= 0; n--) { /* region search */ uint32_t base = env->pmsav7.drbar[n]; uint32_t rsize = extract32(env->pmsav7.drsr[n], 1, 5); uint32_t rmask; bool srdis = false; if (!(env->pmsav7.drsr[n] & 0x1)) { continue; } if (!rsize) { qemu_log_mask(LOG_GUEST_ERROR, "DRSR[%d]: Rsize field cannot be 0\n", n); continue; } rsize++; rmask = (1ull << rsize) - 1; if (base & rmask) { qemu_log_mask(LOG_GUEST_ERROR, "DRBAR[%d]: 0x%" PRIx32 " misaligned " "to DRSR region size, mask = 0x%" PRIx32 "\n", n, base, rmask); continue; } if (address < base || address > base + rmask) { /* * Address not in this region. We must check whether the * region covers addresses in the same page as our address. * In that case we must not report a size that covers the * whole page for a subsequent hit against a different MPU * region or the background region, because it would result in * incorrect TLB hits for subsequent accesses to addresses that * are in this MPU region. */ if (ranges_overlap(base, rmask, address & TARGET_PAGE_MASK, TARGET_PAGE_SIZE)) { result->f.lg_page_size = 0; } continue; } /* Region matched */ if (rsize >= 8) { /* no subregions for regions < 256 bytes */ int i, snd; uint32_t srdis_mask; rsize -= 3; /* sub region size (power of 2) */ snd = ((address - base) >> rsize) & 0x7; srdis = extract32(env->pmsav7.drsr[n], snd + 8, 1); srdis_mask = srdis ? 0x3 : 0x0; for (i = 2; i <= 8 && rsize < TARGET_PAGE_BITS; i *= 2) { /* * This will check in groups of 2, 4 and then 8, whether * the subregion bits are consistent. rsize is incremented * back up to give the region size, considering consistent * adjacent subregions as one region. Stop testing if rsize * is already big enough for an entire QEMU page. */ int snd_rounded = snd & ~(i - 1); uint32_t srdis_multi = extract32(env->pmsav7.drsr[n], snd_rounded + 8, i); if (srdis_mask ^ srdis_multi) { break; } srdis_mask = (srdis_mask << i) | srdis_mask; rsize++; } } if (srdis) { continue; } if (rsize < TARGET_PAGE_BITS) { result->f.lg_page_size = rsize; } break; } if (n == -1) { /* no hits */ if (!pmsav7_use_background_region(cpu, mmu_idx, secure, is_user)) { /* background fault */ fi->type = ARMFault_Background; return true; } get_phys_addr_pmsav7_default(env, mmu_idx, address, &result->f.prot); } else { /* a MPU hit! */ uint32_t ap = extract32(env->pmsav7.dracr[n], 8, 3); uint32_t xn = extract32(env->pmsav7.dracr[n], 12, 1); if (m_is_system_region(env, address)) { /* System space is always execute never */ xn = 1; } if (is_user) { /* User mode AP bit decoding */ switch (ap) { case 0: case 1: case 5: break; /* no access */ case 3: result->f.prot |= PAGE_WRITE; /* fall through */ case 2: case 6: result->f.prot |= PAGE_READ | PAGE_EXEC; break; case 7: /* for v7M, same as 6; for R profile a reserved value */ if (arm_feature(env, ARM_FEATURE_M)) { result->f.prot |= PAGE_READ | PAGE_EXEC; break; } /* fall through */ default: qemu_log_mask(LOG_GUEST_ERROR, "DRACR[%d]: Bad value for AP bits: 0x%" PRIx32 "\n", n, ap); } } else { /* Priv. mode AP bits decoding */ switch (ap) { case 0: break; /* no access */ case 1: case 2: case 3: result->f.prot |= PAGE_WRITE; /* fall through */ case 5: case 6: result->f.prot |= PAGE_READ | PAGE_EXEC; break; case 7: /* for v7M, same as 6; for R profile a reserved value */ if (arm_feature(env, ARM_FEATURE_M)) { result->f.prot |= PAGE_READ | PAGE_EXEC; break; } /* fall through */ default: qemu_log_mask(LOG_GUEST_ERROR, "DRACR[%d]: Bad value for AP bits: 0x%" PRIx32 "\n", n, ap); } } /* execute never */ if (xn) { result->f.prot &= ~PAGE_EXEC; } } } fi->type = ARMFault_Permission; fi->level = 1; return !(result->f.prot & (1 << access_type)); } static uint32_t *regime_rbar(CPUARMState *env, ARMMMUIdx mmu_idx, uint32_t secure) { if (regime_el(env, mmu_idx) == 2) { return env->pmsav8.hprbar; } else { return env->pmsav8.rbar[secure]; } } static uint32_t *regime_rlar(CPUARMState *env, ARMMMUIdx mmu_idx, uint32_t secure) { if (regime_el(env, mmu_idx) == 2) { return env->pmsav8.hprlar; } else { return env->pmsav8.rlar[secure]; } } bool pmsav8_mpu_lookup(CPUARMState *env, uint32_t address, MMUAccessType access_type, ARMMMUIdx mmu_idx, bool secure, GetPhysAddrResult *result, ARMMMUFaultInfo *fi, uint32_t *mregion) { /* * Perform a PMSAv8 MPU lookup (without also doing the SAU check * that a full phys-to-virt translation does). * mregion is (if not NULL) set to the region number which matched, * or -1 if no region number is returned (MPU off, address did not * hit a region, address hit in multiple regions). * If the region hit doesn't cover the entire TARGET_PAGE the address * is within, then we set the result page_size to 1 to force the * memory system to use a subpage. */ ARMCPU *cpu = env_archcpu(env); bool is_user = regime_is_user(env, mmu_idx); int n; int matchregion = -1; bool hit = false; uint32_t addr_page_base = address & TARGET_PAGE_MASK; uint32_t addr_page_limit = addr_page_base + (TARGET_PAGE_SIZE - 1); int region_counter; if (regime_el(env, mmu_idx) == 2) { region_counter = cpu->pmsav8r_hdregion; } else { region_counter = cpu->pmsav7_dregion; } result->f.lg_page_size = TARGET_PAGE_BITS; result->f.phys_addr = address; result->f.prot = 0; if (mregion) { *mregion = -1; } if (mmu_idx == ARMMMUIdx_Stage2) { fi->stage2 = true; } /* * Unlike the ARM ARM pseudocode, we don't need to check whether this * was an exception vector read from the vector table (which is always * done using the default system address map), because those accesses * are done in arm_v7m_load_vector(), which always does a direct * read using address_space_ldl(), rather than going via this function. */ if (regime_translation_disabled(env, mmu_idx, arm_secure_to_space(secure))) { /* MPU disabled */ hit = true; } else if (m_is_ppb_region(env, address)) { hit = true; } else { if (pmsav7_use_background_region(cpu, mmu_idx, secure, is_user)) { hit = true; } uint32_t bitmask; if (arm_feature(env, ARM_FEATURE_M)) { bitmask = 0x1f; } else { bitmask = 0x3f; fi->level = 0; } for (n = region_counter - 1; n >= 0; n--) { /* region search */ /* * Note that the base address is bits [31:x] from the register * with bits [x-1:0] all zeroes, but the limit address is bits * [31:x] from the register with bits [x:0] all ones. Where x is * 5 for Cortex-M and 6 for Cortex-R */ uint32_t base = regime_rbar(env, mmu_idx, secure)[n] & ~bitmask; uint32_t limit = regime_rlar(env, mmu_idx, secure)[n] | bitmask; if (!(regime_rlar(env, mmu_idx, secure)[n] & 0x1)) { /* Region disabled */ continue; } if (address < base || address > limit) { /* * Address not in this region. We must check whether the * region covers addresses in the same page as our address. * In that case we must not report a size that covers the * whole page for a subsequent hit against a different MPU * region or the background region, because it would result in * incorrect TLB hits for subsequent accesses to addresses that * are in this MPU region. */ if (limit >= base && ranges_overlap(base, limit - base + 1, addr_page_base, TARGET_PAGE_SIZE)) { result->f.lg_page_size = 0; } continue; } if (base > addr_page_base || limit < addr_page_limit) { result->f.lg_page_size = 0; } if (matchregion != -1) { /* * Multiple regions match -- always a failure (unlike * PMSAv7 where highest-numbered-region wins) */ fi->type = ARMFault_Permission; if (arm_feature(env, ARM_FEATURE_M)) { fi->level = 1; } return true; } matchregion = n; hit = true; } } if (!hit) { if (arm_feature(env, ARM_FEATURE_M)) { fi->type = ARMFault_Background; } else { fi->type = ARMFault_Permission; } return true; } if (matchregion == -1) { /* hit using the background region */ get_phys_addr_pmsav7_default(env, mmu_idx, address, &result->f.prot); } else { uint32_t matched_rbar = regime_rbar(env, mmu_idx, secure)[matchregion]; uint32_t matched_rlar = regime_rlar(env, mmu_idx, secure)[matchregion]; uint32_t ap = extract32(matched_rbar, 1, 2); uint32_t xn = extract32(matched_rbar, 0, 1); bool pxn = false; if (arm_feature(env, ARM_FEATURE_V8_1M)) { pxn = extract32(matched_rlar, 4, 1); } if (m_is_system_region(env, address)) { /* System space is always execute never */ xn = 1; } if (regime_el(env, mmu_idx) == 2) { result->f.prot = simple_ap_to_rw_prot_is_user(ap, mmu_idx != ARMMMUIdx_E2); } else { result->f.prot = simple_ap_to_rw_prot(env, mmu_idx, ap); } if (!arm_feature(env, ARM_FEATURE_M)) { uint8_t attrindx = extract32(matched_rlar, 1, 3); uint64_t mair = env->cp15.mair_el[regime_el(env, mmu_idx)]; uint8_t sh = extract32(matched_rlar, 3, 2); if (regime_sctlr(env, mmu_idx) & SCTLR_WXN && result->f.prot & PAGE_WRITE && mmu_idx != ARMMMUIdx_Stage2) { xn = 0x1; } if ((regime_el(env, mmu_idx) == 1) && regime_sctlr(env, mmu_idx) & SCTLR_UWXN && ap == 0x1) { pxn = 0x1; } result->cacheattrs.is_s2_format = false; result->cacheattrs.attrs = extract64(mair, attrindx * 8, 8); result->cacheattrs.shareability = sh; } if (result->f.prot && !xn && !(pxn && !is_user)) { result->f.prot |= PAGE_EXEC; } if (mregion) { *mregion = matchregion; } } fi->type = ARMFault_Permission; if (arm_feature(env, ARM_FEATURE_M)) { fi->level = 1; } return !(result->f.prot & (1 << access_type)); } static bool v8m_is_sau_exempt(CPUARMState *env, uint32_t address, MMUAccessType access_type) { /* * The architecture specifies that certain address ranges are * exempt from v8M SAU/IDAU checks. */ return (access_type == MMU_INST_FETCH && m_is_system_region(env, address)) || (address >= 0xe0000000 && address <= 0xe0002fff) || (address >= 0xe000e000 && address <= 0xe000efff) || (address >= 0xe002e000 && address <= 0xe002efff) || (address >= 0xe0040000 && address <= 0xe0041fff) || (address >= 0xe00ff000 && address <= 0xe00fffff); } void v8m_security_lookup(CPUARMState *env, uint32_t address, MMUAccessType access_type, ARMMMUIdx mmu_idx, bool is_secure, V8M_SAttributes *sattrs) { /* * Look up the security attributes for this address. Compare the * pseudocode SecurityCheck() function. * We assume the caller has zero-initialized *sattrs. */ ARMCPU *cpu = env_archcpu(env); int r; bool idau_exempt = false, idau_ns = true, idau_nsc = true; int idau_region = IREGION_NOTVALID; uint32_t addr_page_base = address & TARGET_PAGE_MASK; uint32_t addr_page_limit = addr_page_base + (TARGET_PAGE_SIZE - 1); if (cpu->idau) { IDAUInterfaceClass *iic = IDAU_INTERFACE_GET_CLASS(cpu->idau); IDAUInterface *ii = IDAU_INTERFACE(cpu->idau); iic->check(ii, address, &idau_region, &idau_exempt, &idau_ns, &idau_nsc); } if (access_type == MMU_INST_FETCH && extract32(address, 28, 4) == 0xf) { /* 0xf0000000..0xffffffff is always S for insn fetches */ return; } if (idau_exempt || v8m_is_sau_exempt(env, address, access_type)) { sattrs->ns = !is_secure; return; } if (idau_region != IREGION_NOTVALID) { sattrs->irvalid = true; sattrs->iregion = idau_region; } switch (env->sau.ctrl & 3) { case 0: /* SAU.ENABLE == 0, SAU.ALLNS == 0 */ break; case 2: /* SAU.ENABLE == 0, SAU.ALLNS == 1 */ sattrs->ns = true; break; default: /* SAU.ENABLE == 1 */ for (r = 0; r < cpu->sau_sregion; r++) { if (env->sau.rlar[r] & 1) { uint32_t base = env->sau.rbar[r] & ~0x1f; uint32_t limit = env->sau.rlar[r] | 0x1f; if (base <= address && limit >= address) { if (base > addr_page_base || limit < addr_page_limit) { sattrs->subpage = true; } if (sattrs->srvalid) { /* * If we hit in more than one region then we must report * as Secure, not NS-Callable, with no valid region * number info. */ sattrs->ns = false; sattrs->nsc = false; sattrs->sregion = 0; sattrs->srvalid = false; break; } else { if (env->sau.rlar[r] & 2) { sattrs->nsc = true; } else { sattrs->ns = true; } sattrs->srvalid = true; sattrs->sregion = r; } } else { /* * Address not in this region. We must check whether the * region covers addresses in the same page as our address. * In that case we must not report a size that covers the * whole page for a subsequent hit against a different MPU * region or the background region, because it would result * in incorrect TLB hits for subsequent accesses to * addresses that are in this MPU region. */ if (limit >= base && ranges_overlap(base, limit - base + 1, addr_page_base, TARGET_PAGE_SIZE)) { sattrs->subpage = true; } } } } break; } /* * The IDAU will override the SAU lookup results if it specifies * higher security than the SAU does. */ if (!idau_ns) { if (sattrs->ns || (!idau_nsc && sattrs->nsc)) { sattrs->ns = false; sattrs->nsc = idau_nsc; } } } static bool get_phys_addr_pmsav8(CPUARMState *env, S1Translate *ptw, uint32_t address, MMUAccessType access_type, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { V8M_SAttributes sattrs = {}; ARMMMUIdx mmu_idx = ptw->in_mmu_idx; bool secure = arm_space_is_secure(ptw->in_space); bool ret; if (arm_feature(env, ARM_FEATURE_M_SECURITY)) { v8m_security_lookup(env, address, access_type, mmu_idx, secure, &sattrs); if (access_type == MMU_INST_FETCH) { /* * Instruction fetches always use the MMU bank and the * transaction attribute determined by the fetch address, * regardless of CPU state. This is painful for QEMU * to handle, because it would mean we need to encode * into the mmu_idx not just the (user, negpri) information * for the current security state but also that for the * other security state, which would balloon the number * of mmu_idx values needed alarmingly. * Fortunately we can avoid this because it's not actually * possible to arbitrarily execute code from memory with * the wrong security attribute: it will always generate * an exception of some kind or another, apart from the * special case of an NS CPU executing an SG instruction * in S&NSC memory. So we always just fail the translation * here and sort things out in the exception handler * (including possibly emulating an SG instruction). */ if (sattrs.ns != !secure) { if (sattrs.nsc) { fi->type = ARMFault_QEMU_NSCExec; } else { fi->type = ARMFault_QEMU_SFault; } result->f.lg_page_size = sattrs.subpage ? 0 : TARGET_PAGE_BITS; result->f.phys_addr = address; result->f.prot = 0; return true; } } else { /* * For data accesses we always use the MMU bank indicated * by the current CPU state, but the security attributes * might downgrade a secure access to nonsecure. */ if (sattrs.ns) { result->f.attrs.secure = false; result->f.attrs.space = ARMSS_NonSecure; } else if (!secure) { /* * NS access to S memory must fault. * Architecturally we should first check whether the * MPU information for this address indicates that we * are doing an unaligned access to Device memory, which * should generate a UsageFault instead. QEMU does not * currently check for that kind of unaligned access though. * If we added it we would need to do so as a special case * for M_FAKE_FSR_SFAULT in arm_v7m_cpu_do_interrupt(). */ fi->type = ARMFault_QEMU_SFault; result->f.lg_page_size = sattrs.subpage ? 0 : TARGET_PAGE_BITS; result->f.phys_addr = address; result->f.prot = 0; return true; } } } ret = pmsav8_mpu_lookup(env, address, access_type, mmu_idx, secure, result, fi, NULL); if (sattrs.subpage) { result->f.lg_page_size = 0; } return ret; } /* * Translate from the 4-bit stage 2 representation of * memory attributes (without cache-allocation hints) to * the 8-bit representation of the stage 1 MAIR registers * (which includes allocation hints). * * ref: shared/translation/attrs/S2AttrDecode() * .../S2ConvertAttrsHints() */ static uint8_t convert_stage2_attrs(uint64_t hcr, uint8_t s2attrs) { uint8_t hiattr = extract32(s2attrs, 2, 2); uint8_t loattr = extract32(s2attrs, 0, 2); uint8_t hihint = 0, lohint = 0; if (hiattr != 0) { /* normal memory */ if (hcr & HCR_CD) { /* cache disabled */ hiattr = loattr = 1; /* non-cacheable */ } else { if (hiattr != 1) { /* Write-through or write-back */ hihint = 3; /* RW allocate */ } if (loattr != 1) { /* Write-through or write-back */ lohint = 3; /* RW allocate */ } } } return (hiattr << 6) | (hihint << 4) | (loattr << 2) | lohint; } /* * Combine either inner or outer cacheability attributes for normal * memory, according to table D4-42 and pseudocode procedure * CombineS1S2AttrHints() of ARM DDI 0487B.b (the ARMv8 ARM). * * NB: only stage 1 includes allocation hints (RW bits), leading to * some asymmetry. */ static uint8_t combine_cacheattr_nibble(uint8_t s1, uint8_t s2) { if (s1 == 4 || s2 == 4) { /* non-cacheable has precedence */ return 4; } else if (extract32(s1, 2, 2) == 0 || extract32(s1, 2, 2) == 2) { /* stage 1 write-through takes precedence */ return s1; } else if (extract32(s2, 2, 2) == 2) { /* stage 2 write-through takes precedence, but the allocation hint * is still taken from stage 1 */ return (2 << 2) | extract32(s1, 0, 2); } else { /* write-back */ return s1; } } /* * Combine the memory type and cacheability attributes of * s1 and s2 for the HCR_EL2.FWB == 0 case, returning the * combined attributes in MAIR_EL1 format. */ static uint8_t combined_attrs_nofwb(uint64_t hcr, ARMCacheAttrs s1, ARMCacheAttrs s2) { uint8_t s1lo, s2lo, s1hi, s2hi, s2_mair_attrs, ret_attrs; if (s2.is_s2_format) { s2_mair_attrs = convert_stage2_attrs(hcr, s2.attrs); } else { s2_mair_attrs = s2.attrs; } s1lo = extract32(s1.attrs, 0, 4); s2lo = extract32(s2_mair_attrs, 0, 4); s1hi = extract32(s1.attrs, 4, 4); s2hi = extract32(s2_mair_attrs, 4, 4); /* Combine memory type and cacheability attributes */ if (s1hi == 0 || s2hi == 0) { /* Device has precedence over normal */ if (s1lo == 0 || s2lo == 0) { /* nGnRnE has precedence over anything */ ret_attrs = 0; } else if (s1lo == 4 || s2lo == 4) { /* non-Reordering has precedence over Reordering */ ret_attrs = 4; /* nGnRE */ } else if (s1lo == 8 || s2lo == 8) { /* non-Gathering has precedence over Gathering */ ret_attrs = 8; /* nGRE */ } else { ret_attrs = 0xc; /* GRE */ } } else { /* Normal memory */ /* Outer/inner cacheability combine independently */ ret_attrs = combine_cacheattr_nibble(s1hi, s2hi) << 4 | combine_cacheattr_nibble(s1lo, s2lo); } return ret_attrs; } static uint8_t force_cacheattr_nibble_wb(uint8_t attr) { /* * Given the 4 bits specifying the outer or inner cacheability * in MAIR format, return a value specifying Normal Write-Back, * with the allocation and transient hints taken from the input * if the input specified some kind of cacheable attribute. */ if (attr == 0 || attr == 4) { /* * 0 == an UNPREDICTABLE encoding * 4 == Non-cacheable * Either way, force Write-Back RW allocate non-transient */ return 0xf; } /* Change WriteThrough to WriteBack, keep allocation and transient hints */ return attr | 4; } /* * Combine the memory type and cacheability attributes of * s1 and s2 for the HCR_EL2.FWB == 1 case, returning the * combined attributes in MAIR_EL1 format. */ static uint8_t combined_attrs_fwb(ARMCacheAttrs s1, ARMCacheAttrs s2) { assert(s2.is_s2_format && !s1.is_s2_format); switch (s2.attrs) { case 7: /* Use stage 1 attributes */ return s1.attrs; case 6: /* * Force Normal Write-Back. Note that if S1 is Normal cacheable * then we take the allocation hints from it; otherwise it is * RW allocate, non-transient. */ if ((s1.attrs & 0xf0) == 0) { /* S1 is Device */ return 0xff; } /* Need to check the Inner and Outer nibbles separately */ return force_cacheattr_nibble_wb(s1.attrs & 0xf) | force_cacheattr_nibble_wb(s1.attrs >> 4) << 4; case 5: /* If S1 attrs are Device, use them; otherwise Normal Non-cacheable */ if ((s1.attrs & 0xf0) == 0) { return s1.attrs; } return 0x44; case 0 ... 3: /* Force Device, of subtype specified by S2 */ return s2.attrs << 2; default: /* * RESERVED values (including RES0 descriptor bit [5] being nonzero); * arbitrarily force Device. */ return 0; } } /* * Combine S1 and S2 cacheability/shareability attributes, per D4.5.4 * and CombineS1S2Desc() * * @env: CPUARMState * @s1: Attributes from stage 1 walk * @s2: Attributes from stage 2 walk */ static ARMCacheAttrs combine_cacheattrs(uint64_t hcr, ARMCacheAttrs s1, ARMCacheAttrs s2) { ARMCacheAttrs ret; bool tagged = false; assert(!s1.is_s2_format); ret.is_s2_format = false; if (s1.attrs == 0xf0) { tagged = true; s1.attrs = 0xff; } /* Combine shareability attributes (table D4-43) */ if (s1.shareability == 2 || s2.shareability == 2) { /* if either are outer-shareable, the result is outer-shareable */ ret.shareability = 2; } else if (s1.shareability == 3 || s2.shareability == 3) { /* if either are inner-shareable, the result is inner-shareable */ ret.shareability = 3; } else { /* both non-shareable */ ret.shareability = 0; } /* Combine memory type and cacheability attributes */ if (hcr & HCR_FWB) { ret.attrs = combined_attrs_fwb(s1, s2); } else { ret.attrs = combined_attrs_nofwb(hcr, s1, s2); } /* * Any location for which the resultant memory type is any * type of Device memory is always treated as Outer Shareable. * Any location for which the resultant memory type is Normal * Inner Non-cacheable, Outer Non-cacheable is always treated * as Outer Shareable. * TODO: FEAT_XS adds another value (0x40) also meaning iNCoNC */ if ((ret.attrs & 0xf0) == 0 || ret.attrs == 0x44) { ret.shareability = 2; } /* TODO: CombineS1S2Desc does not consider transient, only WB, RWA. */ if (tagged && ret.attrs == 0xff) { ret.attrs = 0xf0; } return ret; } /* * MMU disabled. S1 addresses within aa64 translation regimes are * still checked for bounds -- see AArch64.S1DisabledOutput(). */ static bool get_phys_addr_disabled(CPUARMState *env, S1Translate *ptw, vaddr address, MMUAccessType access_type, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { ARMMMUIdx mmu_idx = ptw->in_mmu_idx; uint8_t memattr = 0x00; /* Device nGnRnE */ uint8_t shareability = 0; /* non-shareable */ int r_el; switch (mmu_idx) { case ARMMMUIdx_Stage2: case ARMMMUIdx_Stage2_S: case ARMMMUIdx_Phys_S: case ARMMMUIdx_Phys_NS: case ARMMMUIdx_Phys_Root: case ARMMMUIdx_Phys_Realm: break; default: r_el = regime_el(env, mmu_idx); if (arm_el_is_aa64(env, r_el)) { int pamax = arm_pamax(env_archcpu(env)); uint64_t tcr = env->cp15.tcr_el[r_el]; int addrtop, tbi; tbi = aa64_va_parameter_tbi(tcr, mmu_idx); if (access_type == MMU_INST_FETCH) { tbi &= ~aa64_va_parameter_tbid(tcr, mmu_idx); } tbi = (tbi >> extract64(address, 55, 1)) & 1; addrtop = (tbi ? 55 : 63); if (extract64(address, pamax, addrtop - pamax + 1) != 0) { fi->type = ARMFault_AddressSize; fi->level = 0; fi->stage2 = false; return 1; } /* * When TBI is disabled, we've just validated that all of the * bits above PAMax are zero, so logically we only need to * clear the top byte for TBI. But it's clearer to follow * the pseudocode set of addrdesc.paddress. */ address = extract64(address, 0, 52); } /* Fill in cacheattr a-la AArch64.TranslateAddressS1Off. */ if (r_el == 1) { uint64_t hcr = arm_hcr_el2_eff_secstate(env, ptw->in_space); if (hcr & HCR_DC) { if (hcr & HCR_DCT) { memattr = 0xf0; /* Tagged, Normal, WB, RWA */ } else { memattr = 0xff; /* Normal, WB, RWA */ } } } if (memattr == 0) { if (access_type == MMU_INST_FETCH) { if (regime_sctlr(env, mmu_idx) & SCTLR_I) { memattr = 0xee; /* Normal, WT, RA, NT */ } else { memattr = 0x44; /* Normal, NC, No */ } } shareability = 2; /* outer shareable */ } result->cacheattrs.is_s2_format = false; break; } result->f.phys_addr = address; result->f.prot = PAGE_READ | PAGE_WRITE | PAGE_EXEC; result->f.lg_page_size = TARGET_PAGE_BITS; result->cacheattrs.shareability = shareability; result->cacheattrs.attrs = memattr; return false; } static bool get_phys_addr_twostage(CPUARMState *env, S1Translate *ptw, vaddr address, MMUAccessType access_type, MemOp memop, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { hwaddr ipa; int s1_prot, s1_lgpgsz; ARMSecuritySpace in_space = ptw->in_space; bool ret, ipa_secure, s1_guarded; ARMCacheAttrs cacheattrs1; ARMSecuritySpace ipa_space; uint64_t hcr; ret = get_phys_addr_nogpc(env, ptw, address, access_type, memop, result, fi); /* If S1 fails, return early. */ if (ret) { return ret; } ipa = result->f.phys_addr; ipa_secure = result->f.attrs.secure; ipa_space = result->f.attrs.space; ptw->in_s1_is_el0 = ptw->in_mmu_idx == ARMMMUIdx_Stage1_E0; ptw->in_mmu_idx = ipa_secure ? ARMMMUIdx_Stage2_S : ARMMMUIdx_Stage2; ptw->in_space = ipa_space; ptw->in_ptw_idx = ptw_idx_for_stage_2(env, ptw->in_mmu_idx); /* * S1 is done, now do S2 translation. * Save the stage1 results so that we may merge prot and cacheattrs later. */ s1_prot = result->f.prot; s1_lgpgsz = result->f.lg_page_size; s1_guarded = result->f.extra.arm.guarded; cacheattrs1 = result->cacheattrs; memset(result, 0, sizeof(*result)); ret = get_phys_addr_nogpc(env, ptw, ipa, access_type, memop, result, fi); fi->s2addr = ipa; /* Combine the S1 and S2 perms. */ result->f.prot &= s1_prot; /* If S2 fails, return early. */ if (ret) { return ret; } /* * If either S1 or S2 returned a result smaller than TARGET_PAGE_SIZE, * this means "don't put this in the TLB"; in this case, return a * result with lg_page_size == 0 to achieve that. Otherwise, * use the maximum of the S1 & S2 page size, so that invalidation * of pages > TARGET_PAGE_SIZE works correctly. (This works even though * we know the combined result permissions etc only cover the minimum * of the S1 and S2 page size, because we know that the common TLB code * never actually creates TLB entries bigger than TARGET_PAGE_SIZE, * and passing a larger page size value only affects invalidations.) */ if (result->f.lg_page_size < TARGET_PAGE_BITS || s1_lgpgsz < TARGET_PAGE_BITS) { result->f.lg_page_size = 0; } else if (result->f.lg_page_size < s1_lgpgsz) { result->f.lg_page_size = s1_lgpgsz; } /* Combine the S1 and S2 cache attributes. */ hcr = arm_hcr_el2_eff_secstate(env, in_space); if (hcr & HCR_DC) { /* * HCR.DC forces the first stage attributes to * Normal Non-Shareable, * Inner Write-Back Read-Allocate Write-Allocate, * Outer Write-Back Read-Allocate Write-Allocate. * Do not overwrite Tagged within attrs. */ if (cacheattrs1.attrs != 0xf0) { cacheattrs1.attrs = 0xff; } cacheattrs1.shareability = 0; } result->cacheattrs = combine_cacheattrs(hcr, cacheattrs1, result->cacheattrs); /* No BTI GP information in stage 2, we just use the S1 value */ result->f.extra.arm.guarded = s1_guarded; /* * Check if IPA translates to secure or non-secure PA space. * Note that VSTCR overrides VTCR and {N}SW overrides {N}SA. */ if (in_space == ARMSS_Secure) { result->f.attrs.secure = !(env->cp15.vstcr_el2 & (VSTCR_SA | VSTCR_SW)) && (ipa_secure || !(env->cp15.vtcr_el2 & (VTCR_NSA | VTCR_NSW))); result->f.attrs.space = arm_secure_to_space(result->f.attrs.secure); } return false; } static bool get_phys_addr_nogpc(CPUARMState *env, S1Translate *ptw, vaddr address, MMUAccessType access_type, MemOp memop, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { ARMMMUIdx mmu_idx = ptw->in_mmu_idx; ARMMMUIdx s1_mmu_idx; /* * The page table entries may downgrade Secure to NonSecure, but * cannot upgrade a NonSecure translation regime's attributes * to Secure or Realm. */ result->f.attrs.space = ptw->in_space; result->f.attrs.secure = arm_space_is_secure(ptw->in_space); switch (mmu_idx) { case ARMMMUIdx_Phys_S: case ARMMMUIdx_Phys_NS: case ARMMMUIdx_Phys_Root: case ARMMMUIdx_Phys_Realm: /* Checking Phys early avoids special casing later vs regime_el. */ return get_phys_addr_disabled(env, ptw, address, access_type, result, fi); case ARMMMUIdx_Stage1_E0: case ARMMMUIdx_Stage1_E1: case ARMMMUIdx_Stage1_E1_PAN: /* * First stage lookup uses second stage for ptw; only * Secure has both S and NS IPA and starts with Stage2_S. */ ptw->in_ptw_idx = (ptw->in_space == ARMSS_Secure) ? ARMMMUIdx_Stage2_S : ARMMMUIdx_Stage2; break; case ARMMMUIdx_Stage2: case ARMMMUIdx_Stage2_S: /* * Second stage lookup uses physical for ptw; whether this is S or * NS may depend on the SW/NSW bits if this is a stage 2 lookup for * the Secure EL2&0 regime. */ ptw->in_ptw_idx = ptw_idx_for_stage_2(env, mmu_idx); break; case ARMMMUIdx_E10_0: s1_mmu_idx = ARMMMUIdx_Stage1_E0; goto do_twostage; case ARMMMUIdx_E10_1: s1_mmu_idx = ARMMMUIdx_Stage1_E1; goto do_twostage; case ARMMMUIdx_E10_1_PAN: s1_mmu_idx = ARMMMUIdx_Stage1_E1_PAN; do_twostage: /* * Call ourselves recursively to do the stage 1 and then stage 2 * translations if mmu_idx is a two-stage regime, and EL2 present. * Otherwise, a stage1+stage2 translation is just stage 1. */ ptw->in_mmu_idx = mmu_idx = s1_mmu_idx; if (arm_feature(env, ARM_FEATURE_EL2) && !regime_translation_disabled(env, ARMMMUIdx_Stage2, ptw->in_space)) { return get_phys_addr_twostage(env, ptw, address, access_type, memop, result, fi); } /* fall through */ default: /* Single stage uses physical for ptw. */ ptw->in_ptw_idx = arm_space_to_phys(ptw->in_space); break; } result->f.attrs.user = regime_is_user(env, mmu_idx); /* * Fast Context Switch Extension. This doesn't exist at all in v8. * In v7 and earlier it affects all stage 1 translations. */ if (address < 0x02000000 && mmu_idx != ARMMMUIdx_Stage2 && !arm_feature(env, ARM_FEATURE_V8)) { if (regime_el(env, mmu_idx) == 3) { address += env->cp15.fcseidr_s; } else { address += env->cp15.fcseidr_ns; } } if (arm_feature(env, ARM_FEATURE_PMSA)) { bool ret; result->f.lg_page_size = TARGET_PAGE_BITS; if (arm_feature(env, ARM_FEATURE_V8)) { /* PMSAv8 */ ret = get_phys_addr_pmsav8(env, ptw, address, access_type, result, fi); } else if (arm_feature(env, ARM_FEATURE_V7)) { /* PMSAv7 */ ret = get_phys_addr_pmsav7(env, ptw, address, access_type, result, fi); } else { /* Pre-v7 MPU */ ret = get_phys_addr_pmsav5(env, ptw, address, access_type, result, fi); } qemu_log_mask(CPU_LOG_MMU, "PMSA MPU lookup for %s at 0x%08" PRIx32 " mmu_idx %u -> %s (prot %c%c%c)\n", access_type == MMU_DATA_LOAD ? "reading" : (access_type == MMU_DATA_STORE ? "writing" : "execute"), (uint32_t)address, mmu_idx, ret ? "Miss" : "Hit", result->f.prot & PAGE_READ ? 'r' : '-', result->f.prot & PAGE_WRITE ? 'w' : '-', result->f.prot & PAGE_EXEC ? 'x' : '-'); return ret; } /* Definitely a real MMU, not an MPU */ if (regime_translation_disabled(env, mmu_idx, ptw->in_space)) { return get_phys_addr_disabled(env, ptw, address, access_type, result, fi); } if (regime_using_lpae_format(env, mmu_idx)) { return get_phys_addr_lpae(env, ptw, address, access_type, memop, result, fi); } else if (arm_feature(env, ARM_FEATURE_V7) || regime_sctlr(env, mmu_idx) & SCTLR_XP) { return get_phys_addr_v6(env, ptw, address, access_type, result, fi); } else { return get_phys_addr_v5(env, ptw, address, access_type, result, fi); } } static bool get_phys_addr_gpc(CPUARMState *env, S1Translate *ptw, vaddr address, MMUAccessType access_type, MemOp memop, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { if (get_phys_addr_nogpc(env, ptw, address, access_type, memop, result, fi)) { return true; } if (!granule_protection_check(env, result->f.phys_addr, result->f.attrs.space, fi)) { fi->type = ARMFault_GPCFOnOutput; return true; } return false; } bool get_phys_addr_with_space_nogpc(CPUARMState *env, vaddr address, MMUAccessType access_type, MemOp memop, ARMMMUIdx mmu_idx, ARMSecuritySpace space, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { S1Translate ptw = { .in_mmu_idx = mmu_idx, .in_space = space, }; return get_phys_addr_nogpc(env, &ptw, address, access_type, memop, result, fi); } bool get_phys_addr(CPUARMState *env, vaddr address, MMUAccessType access_type, MemOp memop, ARMMMUIdx mmu_idx, GetPhysAddrResult *result, ARMMMUFaultInfo *fi) { S1Translate ptw = { .in_mmu_idx = mmu_idx, }; ARMSecuritySpace ss; switch (mmu_idx) { case ARMMMUIdx_E10_0: case ARMMMUIdx_E10_1: case ARMMMUIdx_E10_1_PAN: case ARMMMUIdx_E20_0: case ARMMMUIdx_E20_2: case ARMMMUIdx_E20_2_PAN: case ARMMMUIdx_Stage1_E0: case ARMMMUIdx_Stage1_E1: case ARMMMUIdx_Stage1_E1_PAN: case ARMMMUIdx_E2: if (arm_aa32_secure_pl1_0(env)) { ss = ARMSS_Secure; } else { ss = arm_security_space_below_el3(env); } break; case ARMMMUIdx_Stage2: /* * For Secure EL2, we need this index to be NonSecure; * otherwise this will already be NonSecure or Realm. */ ss = arm_security_space_below_el3(env); if (ss == ARMSS_Secure) { ss = ARMSS_NonSecure; } break; case ARMMMUIdx_Phys_NS: case ARMMMUIdx_MPrivNegPri: case ARMMMUIdx_MUserNegPri: case ARMMMUIdx_MPriv: case ARMMMUIdx_MUser: ss = ARMSS_NonSecure; break; case ARMMMUIdx_Stage2_S: case ARMMMUIdx_Phys_S: case ARMMMUIdx_MSPrivNegPri: case ARMMMUIdx_MSUserNegPri: case ARMMMUIdx_MSPriv: case ARMMMUIdx_MSUser: ss = ARMSS_Secure; break; case ARMMMUIdx_E3: if (arm_feature(env, ARM_FEATURE_AARCH64) && cpu_isar_feature(aa64_rme, env_archcpu(env))) { ss = ARMSS_Root; } else { ss = ARMSS_Secure; } break; case ARMMMUIdx_Phys_Root: ss = ARMSS_Root; break; case ARMMMUIdx_Phys_Realm: ss = ARMSS_Realm; break; default: g_assert_not_reached(); } ptw.in_space = ss; return get_phys_addr_gpc(env, &ptw, address, access_type, memop, result, fi); } hwaddr arm_cpu_get_phys_page_attrs_debug(CPUState *cs, vaddr addr, MemTxAttrs *attrs) { ARMCPU *cpu = ARM_CPU(cs); CPUARMState *env = &cpu->env; ARMMMUIdx mmu_idx = arm_mmu_idx(env); ARMSecuritySpace ss = arm_security_space(env); S1Translate ptw = { .in_mmu_idx = mmu_idx, .in_space = ss, .in_debug = true, }; GetPhysAddrResult res = {}; ARMMMUFaultInfo fi = {}; bool ret; ret = get_phys_addr_gpc(env, &ptw, addr, MMU_DATA_LOAD, 0, &res, &fi); *attrs = res.f.attrs; if (ret) { return -1; } return res.f.phys_addr; }