/*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2012 Sandvine, Inc. * Copyright (c) 2012 NetApp, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ /* * This file and its contents are supplied under the terms of the * Common Development and Distribution License ("CDDL"), version 1.0. * You may only use this file in accordance with the terms of version * 1.0 of the CDDL. * * A full copy of the text of the CDDL should have accompanied this * source. A copy of the CDDL is also available via the Internet at * http://www.illumos.org/license/CDDL. * * Copyright 2015 Pluribus Networks Inc. * Copyright 2018 Joyent, Inc. * Copyright 2021 Oxide Computer Company * Copyright 2022 OmniOS Community Edition (OmniOSce) Association. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include "vmm_ioport.h" enum vie_status { VIES_INIT = (1U << 0), VIES_MMIO = (1U << 1), VIES_INOUT = (1U << 2), VIES_OTHER = (1U << 3), VIES_INST_FETCH = (1U << 4), VIES_INST_DECODE = (1U << 5), VIES_PENDING_MMIO = (1U << 6), VIES_PENDING_INOUT = (1U << 7), VIES_REPEAT = (1U << 8), VIES_USER_FALLBACK = (1U << 9), VIES_COMPLETE = (1U << 10), }; /* State of request to perform emulated access (inout or MMIO) */ enum vie_req { VR_NONE, VR_PENDING, VR_DONE, }; struct vie_mmio { uint64_t data; uint64_t gpa; uint8_t bytes; enum vie_req state; }; struct vie_op { uint8_t op_byte; /* actual opcode byte */ uint8_t op_type; /* type of operation (e.g. MOV) */ uint16_t op_flags; }; #define VIE_INST_SIZE 15 struct vie { uint8_t inst[VIE_INST_SIZE]; /* instruction bytes */ uint8_t num_valid; /* size of the instruction */ uint8_t num_processed; uint8_t addrsize:4, opsize:4; /* address and operand sizes */ uint8_t rex_w:1, /* REX prefix */ rex_r:1, rex_x:1, rex_b:1, rex_present:1, repz_present:1, /* REP/REPE/REPZ prefix */ repnz_present:1, /* REPNE/REPNZ prefix */ opsize_override:1, /* Operand size override */ addrsize_override:1, /* Address size override */ segment_override:1; /* Segment override */ uint8_t mod:2, /* ModRM byte */ reg:4, rm:4; uint8_t ss:2, /* SIB byte */ vex_present:1, /* VEX prefixed */ vex_l:1, /* L bit */ index:4, /* SIB byte */ base:4; /* SIB byte */ uint8_t disp_bytes; uint8_t imm_bytes; uint8_t scale; uint8_t vex_reg:4, /* vvvv: first source reg specifier */ vex_pp:2, /* pp */ _sparebits:2; uint8_t _sparebytes[2]; int base_register; /* VM_REG_GUEST_xyz */ int index_register; /* VM_REG_GUEST_xyz */ int segment_register; /* VM_REG_GUEST_xyz */ int64_t displacement; /* optional addr displacement */ int64_t immediate; /* optional immediate operand */ struct vie_op op; /* opcode description */ enum vie_status status; struct vm_guest_paging paging; /* guest paging state */ uint64_t mmio_gpa; /* faulting GPA */ struct vie_mmio mmio_req_read; struct vie_mmio mmio_req_write; struct vm_inout inout; /* active in/out op */ enum vie_req inout_req_state; uint32_t inout_req_val; /* value from userspace */ }; /* struct vie_op.op_type */ enum { VIE_OP_TYPE_NONE = 0, VIE_OP_TYPE_MOV, VIE_OP_TYPE_MOVSX, VIE_OP_TYPE_MOVZX, VIE_OP_TYPE_MOV_CR, VIE_OP_TYPE_AND, VIE_OP_TYPE_OR, VIE_OP_TYPE_SUB, VIE_OP_TYPE_TWO_BYTE, VIE_OP_TYPE_PUSH, VIE_OP_TYPE_CMP, VIE_OP_TYPE_POP, VIE_OP_TYPE_MOVS, VIE_OP_TYPE_GROUP1, VIE_OP_TYPE_STOS, VIE_OP_TYPE_BITTEST, VIE_OP_TYPE_TWOB_GRP15, VIE_OP_TYPE_ADD, VIE_OP_TYPE_TEST, VIE_OP_TYPE_BEXTR, VIE_OP_TYPE_CLTS, VIE_OP_TYPE_LAST }; /* struct vie_op.op_flags */ #define VIE_OP_F_IMM (1 << 0) /* 16/32-bit immediate operand */ #define VIE_OP_F_IMM8 (1 << 1) /* 8-bit immediate operand */ #define VIE_OP_F_MOFFSET (1 << 2) /* 16/32/64-bit immediate moffset */ #define VIE_OP_F_NO_MODRM (1 << 3) #define VIE_OP_F_NO_GLA_VERIFICATION (1 << 4) #define VIE_OP_F_REG_REG (1 << 5) /* special-case for mov-cr */ static const struct vie_op three_byte_opcodes_0f38[256] = { [0xF7] = { .op_byte = 0xF7, .op_type = VIE_OP_TYPE_BEXTR, }, }; static const struct vie_op two_byte_opcodes[256] = { [0x06] = { .op_byte = 0x06, .op_type = VIE_OP_TYPE_CLTS, .op_flags = VIE_OP_F_NO_MODRM | VIE_OP_F_NO_GLA_VERIFICATION }, [0x20] = { .op_byte = 0x20, .op_type = VIE_OP_TYPE_MOV_CR, .op_flags = VIE_OP_F_REG_REG | VIE_OP_F_NO_GLA_VERIFICATION }, [0x22] = { .op_byte = 0x22, .op_type = VIE_OP_TYPE_MOV_CR, .op_flags = VIE_OP_F_REG_REG | VIE_OP_F_NO_GLA_VERIFICATION }, [0xAE] = { .op_byte = 0xAE, .op_type = VIE_OP_TYPE_TWOB_GRP15, }, [0xB6] = { .op_byte = 0xB6, .op_type = VIE_OP_TYPE_MOVZX, }, [0xB7] = { .op_byte = 0xB7, .op_type = VIE_OP_TYPE_MOVZX, }, [0xBA] = { .op_byte = 0xBA, .op_type = VIE_OP_TYPE_BITTEST, .op_flags = VIE_OP_F_IMM8, }, [0xBE] = { .op_byte = 0xBE, .op_type = VIE_OP_TYPE_MOVSX, }, }; static const struct vie_op one_byte_opcodes[256] = { [0x03] = { .op_byte = 0x03, .op_type = VIE_OP_TYPE_ADD, }, [0x0F] = { .op_byte = 0x0F, .op_type = VIE_OP_TYPE_TWO_BYTE }, [0x0B] = { .op_byte = 0x0B, .op_type = VIE_OP_TYPE_OR, }, [0x2B] = { .op_byte = 0x2B, .op_type = VIE_OP_TYPE_SUB, }, [0x39] = { .op_byte = 0x39, .op_type = VIE_OP_TYPE_CMP, }, [0x3B] = { .op_byte = 0x3B, .op_type = VIE_OP_TYPE_CMP, }, [0x88] = { .op_byte = 0x88, .op_type = VIE_OP_TYPE_MOV, }, [0x89] = { .op_byte = 0x89, .op_type = VIE_OP_TYPE_MOV, }, [0x8A] = { .op_byte = 0x8A, .op_type = VIE_OP_TYPE_MOV, }, [0x8B] = { .op_byte = 0x8B, .op_type = VIE_OP_TYPE_MOV, }, [0xA1] = { .op_byte = 0xA1, .op_type = VIE_OP_TYPE_MOV, .op_flags = VIE_OP_F_MOFFSET | VIE_OP_F_NO_MODRM, }, [0xA3] = { .op_byte = 0xA3, .op_type = VIE_OP_TYPE_MOV, .op_flags = VIE_OP_F_MOFFSET | VIE_OP_F_NO_MODRM, }, [0xA4] = { .op_byte = 0xA4, .op_type = VIE_OP_TYPE_MOVS, .op_flags = VIE_OP_F_NO_MODRM | VIE_OP_F_NO_GLA_VERIFICATION }, [0xA5] = { .op_byte = 0xA5, .op_type = VIE_OP_TYPE_MOVS, .op_flags = VIE_OP_F_NO_MODRM | VIE_OP_F_NO_GLA_VERIFICATION }, [0xAA] = { .op_byte = 0xAA, .op_type = VIE_OP_TYPE_STOS, .op_flags = VIE_OP_F_NO_MODRM | VIE_OP_F_NO_GLA_VERIFICATION }, [0xAB] = { .op_byte = 0xAB, .op_type = VIE_OP_TYPE_STOS, .op_flags = VIE_OP_F_NO_MODRM | VIE_OP_F_NO_GLA_VERIFICATION }, [0xC6] = { /* XXX Group 11 extended opcode - not just MOV */ .op_byte = 0xC6, .op_type = VIE_OP_TYPE_MOV, .op_flags = VIE_OP_F_IMM8, }, [0xC7] = { .op_byte = 0xC7, .op_type = VIE_OP_TYPE_MOV, .op_flags = VIE_OP_F_IMM, }, [0x23] = { .op_byte = 0x23, .op_type = VIE_OP_TYPE_AND, }, [0x80] = { /* Group 1 extended opcode */ .op_byte = 0x80, .op_type = VIE_OP_TYPE_GROUP1, .op_flags = VIE_OP_F_IMM8, }, [0x81] = { /* Group 1 extended opcode */ .op_byte = 0x81, .op_type = VIE_OP_TYPE_GROUP1, .op_flags = VIE_OP_F_IMM, }, [0x83] = { /* Group 1 extended opcode */ .op_byte = 0x83, .op_type = VIE_OP_TYPE_GROUP1, .op_flags = VIE_OP_F_IMM8, }, [0x8F] = { /* XXX Group 1A extended opcode - not just POP */ .op_byte = 0x8F, .op_type = VIE_OP_TYPE_POP, }, [0xF6] = { /* XXX Group 3 extended opcode - not just TEST */ .op_byte = 0xF6, .op_type = VIE_OP_TYPE_TEST, .op_flags = VIE_OP_F_IMM8, }, [0xF7] = { /* XXX Group 3 extended opcode - not just TEST */ .op_byte = 0xF7, .op_type = VIE_OP_TYPE_TEST, .op_flags = VIE_OP_F_IMM, }, [0xFF] = { /* XXX Group 5 extended opcode - not just PUSH */ .op_byte = 0xFF, .op_type = VIE_OP_TYPE_PUSH, } }; /* struct vie.mod */ #define VIE_MOD_INDIRECT 0 #define VIE_MOD_INDIRECT_DISP8 1 #define VIE_MOD_INDIRECT_DISP32 2 #define VIE_MOD_DIRECT 3 /* struct vie.rm */ #define VIE_RM_SIB 4 #define VIE_RM_DISP32 5 #define GB (1024 * 1024 * 1024) /* * Paging defines, previously pulled in from machine/pmap.h */ #define PG_V (1 << 0) /* Present */ #define PG_RW (1 << 1) /* Read/Write */ #define PG_U (1 << 2) /* User/Supervisor */ #define PG_A (1 << 5) /* Accessed */ #define PG_M (1 << 6) /* Dirty */ #define PG_PS (1 << 7) /* Largepage */ /* * Paging except defines, previously pulled in from machine/pmap.h */ #define PGEX_P (1 << 0) /* Non-present/Protection */ #define PGEX_W (1 << 1) /* Read/Write */ #define PGEX_U (1 << 2) /* User/Supervisor */ #define PGEX_RSV (1 << 3) /* (Non-)Reserved */ #define PGEX_I (1 << 4) /* Instruction */ static enum vm_reg_name gpr_map[16] = { VM_REG_GUEST_RAX, VM_REG_GUEST_RCX, VM_REG_GUEST_RDX, VM_REG_GUEST_RBX, VM_REG_GUEST_RSP, VM_REG_GUEST_RBP, VM_REG_GUEST_RSI, VM_REG_GUEST_RDI, VM_REG_GUEST_R8, VM_REG_GUEST_R9, VM_REG_GUEST_R10, VM_REG_GUEST_R11, VM_REG_GUEST_R12, VM_REG_GUEST_R13, VM_REG_GUEST_R14, VM_REG_GUEST_R15 }; static enum vm_reg_name cr_map[16] = { VM_REG_GUEST_CR0, VM_REG_LAST, VM_REG_GUEST_CR2, VM_REG_GUEST_CR3, VM_REG_GUEST_CR4, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST, VM_REG_LAST }; static uint64_t size2mask[] = { [1] = 0xff, [2] = 0xffff, [4] = 0xffffffff, [8] = 0xffffffffffffffff, }; static int vie_mmio_read(struct vie *vie, struct vm *vm, int cpuid, uint64_t gpa, uint64_t *rval, int bytes); static int vie_mmio_write(struct vie *vie, struct vm *vm, int cpuid, uint64_t gpa, uint64_t wval, int bytes); static int vie_calculate_gla(enum vm_cpu_mode cpu_mode, enum vm_reg_name seg, struct seg_desc *desc, uint64_t offset, int length, int addrsize, int prot, uint64_t *gla); static int vie_canonical_check(enum vm_cpu_mode cpu_mode, uint64_t gla); static int vie_alignment_check(int cpl, int size, uint64_t cr0, uint64_t rf, uint64_t gla); static uint64_t vie_size2mask(int size); struct vie * vie_alloc() { return (kmem_zalloc(sizeof (struct vie), KM_SLEEP)); } void vie_free(struct vie *vie) { kmem_free(vie, sizeof (struct vie)); } enum vm_reg_name vie_regnum_map(uint8_t regnum) { VERIFY3U(regnum, <, 16); return (gpr_map[regnum]); } static void vie_calc_bytereg(struct vie *vie, enum vm_reg_name *reg, int *lhbr) { *lhbr = 0; *reg = gpr_map[vie->reg]; /* * 64-bit mode imposes limitations on accessing legacy high byte * registers (lhbr). * * The legacy high-byte registers cannot be addressed if the REX * prefix is present. In this case the values 4, 5, 6 and 7 of the * 'ModRM:reg' field address %spl, %bpl, %sil and %dil respectively. * * If the REX prefix is not present then the values 4, 5, 6 and 7 * of the 'ModRM:reg' field address the legacy high-byte registers, * %ah, %ch, %dh and %bh respectively. */ if (!vie->rex_present) { if (vie->reg & 0x4) { *lhbr = 1; *reg = gpr_map[vie->reg & 0x3]; } } } static int vie_read_bytereg(struct vie *vie, struct vm *vm, int vcpuid, uint8_t *rval) { uint64_t val; int error, lhbr; enum vm_reg_name reg; vie_calc_bytereg(vie, ®, &lhbr); error = vm_get_register(vm, vcpuid, reg, &val); /* * To obtain the value of a legacy high byte register shift the * base register right by 8 bits (%ah = %rax >> 8). */ if (lhbr) *rval = val >> 8; else *rval = val; return (error); } static int vie_write_bytereg(struct vie *vie, struct vm *vm, int vcpuid, uint8_t byte) { uint64_t origval, val, mask; int error, lhbr; enum vm_reg_name reg; vie_calc_bytereg(vie, ®, &lhbr); error = vm_get_register(vm, vcpuid, reg, &origval); if (error == 0) { val = byte; mask = 0xff; if (lhbr) { /* * Shift left by 8 to store 'byte' in a legacy high * byte register. */ val <<= 8; mask <<= 8; } val |= origval & ~mask; error = vm_set_register(vm, vcpuid, reg, val); } return (error); } static int vie_update_register(struct vm *vm, int vcpuid, enum vm_reg_name reg, uint64_t val, int size) { int error; uint64_t origval; switch (size) { case 1: case 2: error = vm_get_register(vm, vcpuid, reg, &origval); if (error) return (error); val &= size2mask[size]; val |= origval & ~size2mask[size]; break; case 4: val &= 0xffffffffUL; break; case 8: break; default: return (EINVAL); } error = vm_set_register(vm, vcpuid, reg, val); return (error); } static int vie_repeat(struct vie *vie) { vie->status |= VIES_REPEAT; /* * Clear out any cached operation values so the repeated instruction can * begin without using that stale state. Other state, such as the * decoding results, are kept around as it will not vary between * iterations of a rep-prefixed instruction. */ if ((vie->status & VIES_MMIO) != 0) { vie->mmio_req_read.state = VR_NONE; vie->mmio_req_write.state = VR_NONE; } else if ((vie->status & VIES_INOUT) != 0) { vie->inout_req_state = VR_NONE; } else { panic("unexpected emulation state"); } return (EAGAIN); } #define RFLAGS_STATUS_BITS (PSL_C | PSL_PF | PSL_AF | PSL_Z | PSL_N | PSL_V) /* * Return the status flags that would result from doing (x - y). */ /* BEGIN CSTYLED */ #define GETCC(sz) \ static ulong_t \ getcc##sz(uint##sz##_t x, uint##sz##_t y) \ { \ ulong_t rflags; \ \ __asm __volatile("sub %2,%1; pushfq; popq %0" : \ "=r" (rflags), "+r" (x) : "m" (y)); \ return (rflags); \ } struct __hack /* END CSTYLED */ GETCC(8); GETCC(16); GETCC(32); GETCC(64); static ulong_t getcc(int opsize, uint64_t x, uint64_t y) { KASSERT(opsize == 1 || opsize == 2 || opsize == 4 || opsize == 8, ("getcc: invalid operand size %d", opsize)); if (opsize == 1) return (getcc8(x, y)); else if (opsize == 2) return (getcc16(x, y)); else if (opsize == 4) return (getcc32(x, y)); else return (getcc64(x, y)); } /* * Macro creation of functions getaddflags{8,16,32,64} */ /* BEGIN CSTYLED */ #define GETADDFLAGS(sz) \ static ulong_t \ getaddflags##sz(uint##sz##_t x, uint##sz##_t y) \ { \ ulong_t rflags; \ \ __asm __volatile("add %2,%1; pushfq; popq %0" : \ "=r" (rflags), "+r" (x) : "m" (y)); \ return (rflags); \ } struct __hack /* END CSTYLED */ GETADDFLAGS(8); GETADDFLAGS(16); GETADDFLAGS(32); GETADDFLAGS(64); static ulong_t getaddflags(int opsize, uint64_t x, uint64_t y) { KASSERT(opsize == 1 || opsize == 2 || opsize == 4 || opsize == 8, ("getaddflags: invalid operand size %d", opsize)); if (opsize == 1) return (getaddflags8(x, y)); else if (opsize == 2) return (getaddflags16(x, y)); else if (opsize == 4) return (getaddflags32(x, y)); else return (getaddflags64(x, y)); } /* * Return the status flags that would result from doing (x & y). */ /* BEGIN CSTYLED */ #define GETANDFLAGS(sz) \ static ulong_t \ getandflags##sz(uint##sz##_t x, uint##sz##_t y) \ { \ ulong_t rflags; \ \ __asm __volatile("and %2,%1; pushfq; popq %0" : \ "=r" (rflags), "+r" (x) : "m" (y)); \ return (rflags); \ } struct __hack /* END CSTYLED */ GETANDFLAGS(8); GETANDFLAGS(16); GETANDFLAGS(32); GETANDFLAGS(64); static ulong_t getandflags(int opsize, uint64_t x, uint64_t y) { KASSERT(opsize == 1 || opsize == 2 || opsize == 4 || opsize == 8, ("getandflags: invalid operand size %d", opsize)); if (opsize == 1) return (getandflags8(x, y)); else if (opsize == 2) return (getandflags16(x, y)); else if (opsize == 4) return (getandflags32(x, y)); else return (getandflags64(x, y)); } static int vie_emulate_mov_cr(struct vie *vie, struct vm *vm, int vcpuid) { uint64_t val; int err; enum vm_reg_name gpr = gpr_map[vie->rm]; enum vm_reg_name cr = cr_map[vie->reg]; uint_t size = 4; if (vie->paging.cpu_mode == CPU_MODE_64BIT) { size = 8; } switch (vie->op.op_byte) { case 0x20: /* * MOV control register (ModRM:reg) to reg (ModRM:r/m) * 20/r: mov r32, CR0-CR7 * 20/r: mov r64, CR0-CR7 * REX.R + 20/0: mov r64, CR8 */ if (vie->paging.cpl != 0) { vm_inject_gp(vm, vcpuid); vie->num_processed = 0; return (0); } err = vm_get_register(vm, vcpuid, cr, &val); if (err != 0) { /* #UD for access to non-existent CRs */ vm_inject_ud(vm, vcpuid); vie->num_processed = 0; return (0); } err = vie_update_register(vm, vcpuid, gpr, val, size); break; case 0x22: { /* * MOV reg (ModRM:r/m) to control register (ModRM:reg) * 22/r: mov CR0-CR7, r32 * 22/r: mov CR0-CR7, r64 * REX.R + 22/0: mov CR8, r64 */ uint64_t old, diff; if (vie->paging.cpl != 0) { vm_inject_gp(vm, vcpuid); vie->num_processed = 0; return (0); } err = vm_get_register(vm, vcpuid, cr, &old); if (err != 0) { /* #UD for access to non-existent CRs */ vm_inject_ud(vm, vcpuid); vie->num_processed = 0; return (0); } err = vm_get_register(vm, vcpuid, gpr, &val); VERIFY0(err); val &= size2mask[size]; diff = old ^ val; switch (cr) { case VM_REG_GUEST_CR0: if ((diff & CR0_PG) != 0) { uint64_t efer; err = vm_get_register(vm, vcpuid, VM_REG_GUEST_EFER, &efer); VERIFY0(err); /* Keep the long-mode state in EFER in sync */ if ((val & CR0_PG) != 0 && (efer & EFER_LME) != 0) { efer |= EFER_LMA; } if ((val & CR0_PG) == 0 && (efer & EFER_LME) != 0) { efer &= ~EFER_LMA; } err = vm_set_register(vm, vcpuid, VM_REG_GUEST_EFER, efer); VERIFY0(err); } /* TODO: enforce more of the #GP checks */ err = vm_set_register(vm, vcpuid, cr, val); VERIFY0(err); break; case VM_REG_GUEST_CR2: case VM_REG_GUEST_CR3: case VM_REG_GUEST_CR4: /* TODO: enforce more of the #GP checks */ err = vm_set_register(vm, vcpuid, cr, val); break; default: /* The cr_map mapping should prevent this */ panic("invalid cr %d", cr); } break; } default: return (EINVAL); } return (err); } static int vie_emulate_mov(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, size; enum vm_reg_name reg; uint8_t byte; uint64_t val; size = vie->opsize; error = EINVAL; switch (vie->op.op_byte) { case 0x88: /* * MOV byte from reg (ModRM:reg) to mem (ModRM:r/m) * 88/r: mov r/m8, r8 * REX + 88/r: mov r/m8, r8 (%ah, %ch, %dh, %bh not available) */ size = 1; /* override for byte operation */ error = vie_read_bytereg(vie, vm, vcpuid, &byte); if (error == 0) { error = vie_mmio_write(vie, vm, vcpuid, gpa, byte, size); } break; case 0x89: /* * MOV from reg (ModRM:reg) to mem (ModRM:r/m) * 89/r: mov r/m16, r16 * 89/r: mov r/m32, r32 * REX.W + 89/r mov r/m64, r64 */ reg = gpr_map[vie->reg]; error = vm_get_register(vm, vcpuid, reg, &val); if (error == 0) { val &= size2mask[size]; error = vie_mmio_write(vie, vm, vcpuid, gpa, val, size); } break; case 0x8A: /* * MOV byte from mem (ModRM:r/m) to reg (ModRM:reg) * 8A/r: mov r8, r/m8 * REX + 8A/r: mov r8, r/m8 */ size = 1; /* override for byte operation */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, size); if (error == 0) error = vie_write_bytereg(vie, vm, vcpuid, val); break; case 0x8B: /* * MOV from mem (ModRM:r/m) to reg (ModRM:reg) * 8B/r: mov r16, r/m16 * 8B/r: mov r32, r/m32 * REX.W 8B/r: mov r64, r/m64 */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, size); if (error == 0) { reg = gpr_map[vie->reg]; error = vie_update_register(vm, vcpuid, reg, val, size); } break; case 0xA1: /* * MOV from seg:moffset to AX/EAX/RAX * A1: mov AX, moffs16 * A1: mov EAX, moffs32 * REX.W + A1: mov RAX, moffs64 */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, size); if (error == 0) { reg = VM_REG_GUEST_RAX; error = vie_update_register(vm, vcpuid, reg, val, size); } break; case 0xA3: /* * MOV from AX/EAX/RAX to seg:moffset * A3: mov moffs16, AX * A3: mov moffs32, EAX * REX.W + A3: mov moffs64, RAX */ error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RAX, &val); if (error == 0) { val &= size2mask[size]; error = vie_mmio_write(vie, vm, vcpuid, gpa, val, size); } break; case 0xC6: /* * MOV from imm8 to mem (ModRM:r/m) * C6/0 mov r/m8, imm8 * REX + C6/0 mov r/m8, imm8 */ size = 1; /* override for byte operation */ val = vie->immediate; error = vie_mmio_write(vie, vm, vcpuid, gpa, val, size); break; case 0xC7: /* * MOV from imm16/imm32 to mem (ModRM:r/m) * C7/0 mov r/m16, imm16 * C7/0 mov r/m32, imm32 * REX.W + C7/0 mov r/m64, imm32 (sign-extended to 64-bits) */ val = vie->immediate & size2mask[size]; error = vie_mmio_write(vie, vm, vcpuid, gpa, val, size); break; default: break; } return (error); } static int vie_emulate_movx(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, size; enum vm_reg_name reg; uint64_t val; size = vie->opsize; error = EINVAL; switch (vie->op.op_byte) { case 0xB6: /* * MOV and zero extend byte from mem (ModRM:r/m) to * reg (ModRM:reg). * * 0F B6/r movzx r16, r/m8 * 0F B6/r movzx r32, r/m8 * REX.W + 0F B6/r movzx r64, r/m8 */ /* get the first operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, 1); if (error) break; /* get the second operand */ reg = gpr_map[vie->reg]; /* zero-extend byte */ val = (uint8_t)val; /* write the result */ error = vie_update_register(vm, vcpuid, reg, val, size); break; case 0xB7: /* * MOV and zero extend word from mem (ModRM:r/m) to * reg (ModRM:reg). * * 0F B7/r movzx r32, r/m16 * REX.W + 0F B7/r movzx r64, r/m16 */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, 2); if (error) return (error); reg = gpr_map[vie->reg]; /* zero-extend word */ val = (uint16_t)val; error = vie_update_register(vm, vcpuid, reg, val, size); break; case 0xBE: /* * MOV and sign extend byte from mem (ModRM:r/m) to * reg (ModRM:reg). * * 0F BE/r movsx r16, r/m8 * 0F BE/r movsx r32, r/m8 * REX.W + 0F BE/r movsx r64, r/m8 */ /* get the first operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, 1); if (error) break; /* get the second operand */ reg = gpr_map[vie->reg]; /* sign extend byte */ val = (int8_t)val; /* write the result */ error = vie_update_register(vm, vcpuid, reg, val, size); break; default: break; } return (error); } /* * Helper function to calculate and validate a linear address. */ static int vie_get_gla(struct vie *vie, struct vm *vm, int vcpuid, int opsize, int addrsize, int prot, enum vm_reg_name seg, enum vm_reg_name gpr, uint64_t *gla) { struct seg_desc desc; uint64_t cr0, val, rflags; int error; struct vm_guest_paging *paging; paging = &vie->paging; error = vm_get_register(vm, vcpuid, VM_REG_GUEST_CR0, &cr0); KASSERT(error == 0, ("%s: error %d getting cr0", __func__, error)); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); KASSERT(error == 0, ("%s: error %d getting rflags", __func__, error)); error = vm_get_seg_desc(vm, vcpuid, seg, &desc); KASSERT(error == 0, ("%s: error %d getting segment descriptor %d", __func__, error, seg)); error = vm_get_register(vm, vcpuid, gpr, &val); KASSERT(error == 0, ("%s: error %d getting register %d", __func__, error, gpr)); if (vie_calculate_gla(paging->cpu_mode, seg, &desc, val, opsize, addrsize, prot, gla)) { if (seg == VM_REG_GUEST_SS) vm_inject_ss(vm, vcpuid, 0); else vm_inject_gp(vm, vcpuid); return (-1); } if (vie_canonical_check(paging->cpu_mode, *gla)) { if (seg == VM_REG_GUEST_SS) vm_inject_ss(vm, vcpuid, 0); else vm_inject_gp(vm, vcpuid); return (-1); } if (vie_alignment_check(paging->cpl, opsize, cr0, rflags, *gla)) { vm_inject_ac(vm, vcpuid, 0); return (-1); } return (0); } static int vie_emulate_movs(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { struct vm_copyinfo copyinfo[2]; uint64_t dstaddr, srcaddr, dstgpa, srcgpa, val; uint64_t rcx, rdi, rsi, rflags; int error, fault, opsize, seg, repeat; struct vm_guest_paging *paging; opsize = (vie->op.op_byte == 0xA4) ? 1 : vie->opsize; val = 0; error = 0; paging = &vie->paging; /* * XXX although the MOVS instruction is only supposed to be used with * the "rep" prefix some guests like FreeBSD will use "repnz" instead. * * Empirically the "repnz" prefix has identical behavior to "rep" * and the zero flag does not make a difference. */ repeat = vie->repz_present | vie->repnz_present; if (repeat) { error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RCX, &rcx); KASSERT(!error, ("%s: error %d getting rcx", __func__, error)); /* * The count register is %rcx, %ecx or %cx depending on the * address size of the instruction. */ if ((rcx & vie_size2mask(vie->addrsize)) == 0) { error = 0; goto done; } } /* * Source Destination Comments * -------------------------------------------- * (1) memory memory n/a * (2) memory mmio emulated * (3) mmio memory emulated * (4) mmio mmio emulated * * At this point we don't have sufficient information to distinguish * between (2), (3) and (4). We use 'vm_copy_setup()' to tease this * out because it will succeed only when operating on regular memory. * * XXX the emulation doesn't properly handle the case where 'gpa' * is straddling the boundary between the normal memory and MMIO. */ seg = vie->segment_override ? vie->segment_register : VM_REG_GUEST_DS; if (vie_get_gla(vie, vm, vcpuid, opsize, vie->addrsize, PROT_READ, seg, VM_REG_GUEST_RSI, &srcaddr) != 0) { goto done; } error = vm_copy_setup(vm, vcpuid, paging, srcaddr, opsize, PROT_READ, copyinfo, nitems(copyinfo), &fault); if (error == 0) { if (fault) goto done; /* Resume guest to handle fault */ /* * case (2): read from system memory and write to mmio. */ vm_copyin(vm, vcpuid, copyinfo, &val, opsize); vm_copy_teardown(vm, vcpuid, copyinfo, nitems(copyinfo)); error = vie_mmio_write(vie, vm, vcpuid, gpa, val, opsize); if (error) goto done; } else { /* * 'vm_copy_setup()' is expected to fail for cases (3) and (4) * if 'srcaddr' is in the mmio space. */ if (vie_get_gla(vie, vm, vcpuid, opsize, vie->addrsize, PROT_WRITE, VM_REG_GUEST_ES, VM_REG_GUEST_RDI, &dstaddr) != 0) { goto done; } error = vm_copy_setup(vm, vcpuid, paging, dstaddr, opsize, PROT_WRITE, copyinfo, nitems(copyinfo), &fault); if (error == 0) { if (fault) goto done; /* Resume guest to handle fault */ /* * case (3): read from MMIO and write to system memory. * * A MMIO read can have side-effects so we * commit to it only after vm_copy_setup() is * successful. If a page-fault needs to be * injected into the guest then it will happen * before the MMIO read is attempted. */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, opsize); if (error == 0) { vm_copyout(vm, vcpuid, &val, copyinfo, opsize); } /* * Regardless of whether the MMIO read was successful or * not, the copy resources must be cleaned up. */ vm_copy_teardown(vm, vcpuid, copyinfo, nitems(copyinfo)); if (error != 0) { goto done; } } else { /* * Case (4): read from and write to mmio. * * Commit to the MMIO read/write (with potential * side-effects) only after we are sure that the * instruction is not going to be restarted due * to address translation faults. */ error = vm_gla2gpa(vm, vcpuid, paging, srcaddr, PROT_READ, &srcgpa, &fault); if (error || fault) goto done; error = vm_gla2gpa(vm, vcpuid, paging, dstaddr, PROT_WRITE, &dstgpa, &fault); if (error || fault) goto done; error = vie_mmio_read(vie, vm, vcpuid, srcgpa, &val, opsize); if (error) goto done; error = vie_mmio_write(vie, vm, vcpuid, dstgpa, val, opsize); if (error) goto done; } } error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RSI, &rsi); KASSERT(error == 0, ("%s: error %d getting rsi", __func__, error)); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RDI, &rdi); KASSERT(error == 0, ("%s: error %d getting rdi", __func__, error)); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); KASSERT(error == 0, ("%s: error %d getting rflags", __func__, error)); if (rflags & PSL_D) { rsi -= opsize; rdi -= opsize; } else { rsi += opsize; rdi += opsize; } error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RSI, rsi, vie->addrsize); KASSERT(error == 0, ("%s: error %d updating rsi", __func__, error)); error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RDI, rdi, vie->addrsize); KASSERT(error == 0, ("%s: error %d updating rdi", __func__, error)); if (repeat) { rcx = rcx - 1; error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RCX, rcx, vie->addrsize); KASSERT(!error, ("%s: error %d updating rcx", __func__, error)); /* * Repeat the instruction if the count register is not zero. */ if ((rcx & vie_size2mask(vie->addrsize)) != 0) return (vie_repeat(vie)); } done: return (error); } static int vie_emulate_stos(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, opsize, repeat; uint64_t val; uint64_t rcx, rdi, rflags; opsize = (vie->op.op_byte == 0xAA) ? 1 : vie->opsize; repeat = vie->repz_present | vie->repnz_present; if (repeat) { error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RCX, &rcx); KASSERT(!error, ("%s: error %d getting rcx", __func__, error)); /* * The count register is %rcx, %ecx or %cx depending on the * address size of the instruction. */ if ((rcx & vie_size2mask(vie->addrsize)) == 0) return (0); } error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RAX, &val); KASSERT(!error, ("%s: error %d getting rax", __func__, error)); error = vie_mmio_write(vie, vm, vcpuid, gpa, val, opsize); if (error) return (error); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RDI, &rdi); KASSERT(error == 0, ("%s: error %d getting rdi", __func__, error)); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); KASSERT(error == 0, ("%s: error %d getting rflags", __func__, error)); if (rflags & PSL_D) rdi -= opsize; else rdi += opsize; error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RDI, rdi, vie->addrsize); KASSERT(error == 0, ("%s: error %d updating rdi", __func__, error)); if (repeat) { rcx = rcx - 1; error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RCX, rcx, vie->addrsize); KASSERT(!error, ("%s: error %d updating rcx", __func__, error)); /* * Repeat the instruction if the count register is not zero. */ if ((rcx & vie_size2mask(vie->addrsize)) != 0) return (vie_repeat(vie)); } return (0); } static int vie_emulate_and(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, size; enum vm_reg_name reg; uint64_t result, rflags, rflags2, val1, val2; size = vie->opsize; error = EINVAL; switch (vie->op.op_byte) { case 0x23: /* * AND reg (ModRM:reg) and mem (ModRM:r/m) and store the * result in reg. * * 23/r and r16, r/m16 * 23/r and r32, r/m32 * REX.W + 23/r and r64, r/m64 */ /* get the first operand */ reg = gpr_map[vie->reg]; error = vm_get_register(vm, vcpuid, reg, &val1); if (error) break; /* get the second operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val2, size); if (error) break; /* perform the operation and write the result */ result = val1 & val2; error = vie_update_register(vm, vcpuid, reg, result, size); break; case 0x81: case 0x83: /* * AND mem (ModRM:r/m) with immediate and store the * result in mem. * * 81 /4 and r/m16, imm16 * 81 /4 and r/m32, imm32 * REX.W + 81 /4 and r/m64, imm32 sign-extended to 64 * * 83 /4 and r/m16, imm8 sign-extended to 16 * 83 /4 and r/m32, imm8 sign-extended to 32 * REX.W + 83/4 and r/m64, imm8 sign-extended to 64 */ /* get the first operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val1, size); if (error) break; /* * perform the operation with the pre-fetched immediate * operand and write the result */ result = val1 & vie->immediate; error = vie_mmio_write(vie, vm, vcpuid, gpa, result, size); break; default: break; } if (error) return (error); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); if (error) return (error); /* * OF and CF are cleared; the SF, ZF and PF flags are set according * to the result; AF is undefined. * * The updated status flags are obtained by subtracting 0 from 'result'. */ rflags2 = getcc(size, result, 0); rflags &= ~RFLAGS_STATUS_BITS; rflags |= rflags2 & (PSL_PF | PSL_Z | PSL_N); error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, rflags, 8); return (error); } static int vie_emulate_or(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, size; enum vm_reg_name reg; uint64_t result, rflags, rflags2, val1, val2; size = vie->opsize; error = EINVAL; switch (vie->op.op_byte) { case 0x0B: /* * OR reg (ModRM:reg) and mem (ModRM:r/m) and store the * result in reg. * * 0b/r or r16, r/m16 * 0b/r or r32, r/m32 * REX.W + 0b/r or r64, r/m64 */ /* get the first operand */ reg = gpr_map[vie->reg]; error = vm_get_register(vm, vcpuid, reg, &val1); if (error) break; /* get the second operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val2, size); if (error) break; /* perform the operation and write the result */ result = val1 | val2; error = vie_update_register(vm, vcpuid, reg, result, size); break; case 0x81: case 0x83: /* * OR mem (ModRM:r/m) with immediate and store the * result in mem. * * 81 /1 or r/m16, imm16 * 81 /1 or r/m32, imm32 * REX.W + 81 /1 or r/m64, imm32 sign-extended to 64 * * 83 /1 or r/m16, imm8 sign-extended to 16 * 83 /1 or r/m32, imm8 sign-extended to 32 * REX.W + 83/1 or r/m64, imm8 sign-extended to 64 */ /* get the first operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val1, size); if (error) break; /* * perform the operation with the pre-fetched immediate * operand and write the result */ result = val1 | vie->immediate; error = vie_mmio_write(vie, vm, vcpuid, gpa, result, size); break; default: break; } if (error) return (error); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); if (error) return (error); /* * OF and CF are cleared; the SF, ZF and PF flags are set according * to the result; AF is undefined. * * The updated status flags are obtained by subtracting 0 from 'result'. */ rflags2 = getcc(size, result, 0); rflags &= ~RFLAGS_STATUS_BITS; rflags |= rflags2 & (PSL_PF | PSL_Z | PSL_N); error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, rflags, 8); return (error); } static int vie_emulate_cmp(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, size; uint64_t regop, memop, op1, op2, rflags, rflags2; enum vm_reg_name reg; size = vie->opsize; switch (vie->op.op_byte) { case 0x39: case 0x3B: /* * 39/r CMP r/m16, r16 * 39/r CMP r/m32, r32 * REX.W 39/r CMP r/m64, r64 * * 3B/r CMP r16, r/m16 * 3B/r CMP r32, r/m32 * REX.W + 3B/r CMP r64, r/m64 * * Compare the first operand with the second operand and * set status flags in EFLAGS register. The comparison is * performed by subtracting the second operand from the first * operand and then setting the status flags. */ /* Get the register operand */ reg = gpr_map[vie->reg]; error = vm_get_register(vm, vcpuid, reg, ®op); if (error) return (error); /* Get the memory operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &memop, size); if (error) return (error); if (vie->op.op_byte == 0x3B) { op1 = regop; op2 = memop; } else { op1 = memop; op2 = regop; } rflags2 = getcc(size, op1, op2); break; case 0x80: case 0x81: case 0x83: /* * 80 /7 cmp r/m8, imm8 * REX + 80 /7 cmp r/m8, imm8 * * 81 /7 cmp r/m16, imm16 * 81 /7 cmp r/m32, imm32 * REX.W + 81 /7 cmp r/m64, imm32 sign-extended to 64 * * 83 /7 cmp r/m16, imm8 sign-extended to 16 * 83 /7 cmp r/m32, imm8 sign-extended to 32 * REX.W + 83 /7 cmp r/m64, imm8 sign-extended to 64 * * Compare mem (ModRM:r/m) with immediate and set * status flags according to the results. The * comparison is performed by subtracting the * immediate from the first operand and then setting * the status flags. * */ if (vie->op.op_byte == 0x80) size = 1; /* get the first operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &op1, size); if (error) return (error); rflags2 = getcc(size, op1, vie->immediate); break; default: return (EINVAL); } error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); if (error) return (error); rflags &= ~RFLAGS_STATUS_BITS; rflags |= rflags2 & RFLAGS_STATUS_BITS; error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, rflags, 8); return (error); } static int vie_emulate_test(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, size; uint64_t op1, rflags, rflags2; size = vie->opsize; error = EINVAL; switch (vie->op.op_byte) { case 0xF6: /* * F6 /0 test r/m8, imm8 * * Test mem (ModRM:r/m) with immediate and set status * flags according to the results. The comparison is * performed by anding the immediate from the first * operand and then setting the status flags. */ if ((vie->reg & 7) != 0) return (EINVAL); size = 1; /* override for byte operation */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &op1, size); if (error) return (error); rflags2 = getandflags(size, op1, vie->immediate); break; case 0xF7: /* * F7 /0 test r/m16, imm16 * F7 /0 test r/m32, imm32 * REX.W + F7 /0 test r/m64, imm32 sign-extended to 64 * * Test mem (ModRM:r/m) with immediate and set status * flags according to the results. The comparison is * performed by anding the immediate from the first * operand and then setting the status flags. */ if ((vie->reg & 7) != 0) return (EINVAL); error = vie_mmio_read(vie, vm, vcpuid, gpa, &op1, size); if (error) return (error); rflags2 = getandflags(size, op1, vie->immediate); break; default: return (EINVAL); } error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); if (error) return (error); /* * OF and CF are cleared; the SF, ZF and PF flags are set according * to the result; AF is undefined. */ rflags &= ~RFLAGS_STATUS_BITS; rflags |= rflags2 & (PSL_PF | PSL_Z | PSL_N); error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, rflags, 8); return (error); } static int vie_emulate_bextr(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { uint64_t src1, src2, dst, rflags; unsigned start, len; int error, size; struct vm_guest_paging *paging; size = vie->opsize; error = EINVAL; paging = &vie->paging; /* * VEX.LZ.0F38.W0 F7 /r BEXTR r32a, r/m32, r32b * VEX.LZ.0F38.W1 F7 /r BEXTR r64a, r/m64, r64b * * Destination operand is ModRM:reg. Source operands are ModRM:r/m and * Vex.vvvv. * * Operand size is always 32-bit if not in 64-bit mode (W1 is ignored). */ if (size != 4 && paging->cpu_mode != CPU_MODE_64BIT) size = 4; /* * Extracts contiguous bits from the first /source/ operand (second * operand) using an index and length specified in the second /source/ * operand (third operand). */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &src1, size); if (error) return (error); error = vm_get_register(vm, vcpuid, gpr_map[vie->vex_reg], &src2); if (error) return (error); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); if (error) return (error); start = (src2 & 0xff); len = (src2 & 0xff00) >> 8; /* If no bits are extracted, the destination register is cleared. */ dst = 0; /* If START exceeds the operand size, no bits are extracted. */ if (start > size * 8) goto done; /* Length is bounded by both the destination size and start offset. */ if (start + len > size * 8) len = (size * 8) - start; if (len == 0) goto done; if (start > 0) src1 = (src1 >> start); if (len < 64) src1 = src1 & ((1ull << len) - 1); dst = src1; done: error = vie_update_register(vm, vcpuid, gpr_map[vie->reg], dst, size); if (error) return (error); /* * AMD: OF, CF cleared; SF/AF/PF undefined; ZF set by result. * Intel: ZF is set by result; AF/SF/PF undefined; all others cleared. */ rflags &= ~RFLAGS_STATUS_BITS; if (dst == 0) rflags |= PSL_Z; error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, rflags, 8); return (error); } static int vie_emulate_add(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, size; uint64_t nval, rflags, rflags2, val1, val2; enum vm_reg_name reg; size = vie->opsize; error = EINVAL; switch (vie->op.op_byte) { case 0x03: /* * ADD r/m to r and store the result in r * * 03/r ADD r16, r/m16 * 03/r ADD r32, r/m32 * REX.W + 03/r ADD r64, r/m64 */ /* get the first operand */ reg = gpr_map[vie->reg]; error = vm_get_register(vm, vcpuid, reg, &val1); if (error) break; /* get the second operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val2, size); if (error) break; /* perform the operation and write the result */ nval = val1 + val2; error = vie_update_register(vm, vcpuid, reg, nval, size); break; default: break; } if (!error) { rflags2 = getaddflags(size, val1, val2); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); if (error) return (error); rflags &= ~RFLAGS_STATUS_BITS; rflags |= rflags2 & RFLAGS_STATUS_BITS; error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, rflags, 8); } return (error); } static int vie_emulate_sub(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error, size; uint64_t nval, rflags, rflags2, val1, val2; enum vm_reg_name reg; size = vie->opsize; error = EINVAL; switch (vie->op.op_byte) { case 0x2B: /* * SUB r/m from r and store the result in r * * 2B/r SUB r16, r/m16 * 2B/r SUB r32, r/m32 * REX.W + 2B/r SUB r64, r/m64 */ /* get the first operand */ reg = gpr_map[vie->reg]; error = vm_get_register(vm, vcpuid, reg, &val1); if (error) break; /* get the second operand */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &val2, size); if (error) break; /* perform the operation and write the result */ nval = val1 - val2; error = vie_update_register(vm, vcpuid, reg, nval, size); break; default: break; } if (!error) { rflags2 = getcc(size, val1, val2); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); if (error) return (error); rflags &= ~RFLAGS_STATUS_BITS; rflags |= rflags2 & RFLAGS_STATUS_BITS; error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, rflags, 8); } return (error); } static int vie_emulate_stack_op(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { struct vm_copyinfo copyinfo[2]; struct seg_desc ss_desc; uint64_t cr0, rflags, rsp, stack_gla, val; int error, fault, size, stackaddrsize, pushop; struct vm_guest_paging *paging; val = 0; size = vie->opsize; pushop = (vie->op.op_type == VIE_OP_TYPE_PUSH) ? 1 : 0; paging = &vie->paging; /* * From "Address-Size Attributes for Stack Accesses", Intel SDL, Vol 1 */ if (paging->cpu_mode == CPU_MODE_REAL) { stackaddrsize = 2; } else if (paging->cpu_mode == CPU_MODE_64BIT) { /* * "Stack Manipulation Instructions in 64-bit Mode", SDM, Vol 3 * - Stack pointer size is always 64-bits. * - PUSH/POP of 32-bit values is not possible in 64-bit mode. * - 16-bit PUSH/POP is supported by using the operand size * override prefix (66H). */ stackaddrsize = 8; size = vie->opsize_override ? 2 : 8; } else { /* * In protected or compatibility mode the 'B' flag in the * stack-segment descriptor determines the size of the * stack pointer. */ error = vm_get_seg_desc(vm, vcpuid, VM_REG_GUEST_SS, &ss_desc); KASSERT(error == 0, ("%s: error %d getting SS descriptor", __func__, error)); if (SEG_DESC_DEF32(ss_desc.access)) stackaddrsize = 4; else stackaddrsize = 2; } error = vm_get_register(vm, vcpuid, VM_REG_GUEST_CR0, &cr0); KASSERT(error == 0, ("%s: error %d getting cr0", __func__, error)); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); KASSERT(error == 0, ("%s: error %d getting rflags", __func__, error)); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RSP, &rsp); KASSERT(error == 0, ("%s: error %d getting rsp", __func__, error)); if (pushop) { rsp -= size; } if (vie_calculate_gla(paging->cpu_mode, VM_REG_GUEST_SS, &ss_desc, rsp, size, stackaddrsize, pushop ? PROT_WRITE : PROT_READ, &stack_gla)) { vm_inject_ss(vm, vcpuid, 0); return (0); } if (vie_canonical_check(paging->cpu_mode, stack_gla)) { vm_inject_ss(vm, vcpuid, 0); return (0); } if (vie_alignment_check(paging->cpl, size, cr0, rflags, stack_gla)) { vm_inject_ac(vm, vcpuid, 0); return (0); } error = vm_copy_setup(vm, vcpuid, paging, stack_gla, size, pushop ? PROT_WRITE : PROT_READ, copyinfo, nitems(copyinfo), &fault); if (error || fault) return (error); if (pushop) { error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, size); if (error == 0) vm_copyout(vm, vcpuid, &val, copyinfo, size); } else { vm_copyin(vm, vcpuid, copyinfo, &val, size); error = vie_mmio_write(vie, vm, vcpuid, gpa, val, size); rsp += size; } vm_copy_teardown(vm, vcpuid, copyinfo, nitems(copyinfo)); if (error == 0) { error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RSP, rsp, stackaddrsize); KASSERT(error == 0, ("error %d updating rsp", error)); } return (error); } static int vie_emulate_push(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error; /* * Table A-6, "Opcode Extensions", Intel SDM, Vol 2. * * PUSH is part of the group 5 extended opcodes and is identified * by ModRM:reg = b110. */ if ((vie->reg & 7) != 6) return (EINVAL); error = vie_emulate_stack_op(vie, vm, vcpuid, gpa); return (error); } static int vie_emulate_pop(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error; /* * Table A-6, "Opcode Extensions", Intel SDM, Vol 2. * * POP is part of the group 1A extended opcodes and is identified * by ModRM:reg = b000. */ if ((vie->reg & 7) != 0) return (EINVAL); error = vie_emulate_stack_op(vie, vm, vcpuid, gpa); return (error); } static int vie_emulate_group1(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error; switch (vie->reg & 7) { case 0x1: /* OR */ error = vie_emulate_or(vie, vm, vcpuid, gpa); break; case 0x4: /* AND */ error = vie_emulate_and(vie, vm, vcpuid, gpa); break; case 0x7: /* CMP */ error = vie_emulate_cmp(vie, vm, vcpuid, gpa); break; default: error = EINVAL; break; } return (error); } static int vie_emulate_bittest(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { uint64_t val, rflags; int error, bitmask, bitoff; /* * 0F BA is a Group 8 extended opcode. * * Currently we only emulate the 'Bit Test' instruction which is * identified by a ModR/M:reg encoding of 100b. */ if ((vie->reg & 7) != 4) return (EINVAL); error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); KASSERT(error == 0, ("%s: error %d getting rflags", __func__, error)); error = vie_mmio_read(vie, vm, vcpuid, gpa, &val, vie->opsize); if (error) return (error); /* * Intel SDM, Vol 2, Table 3-2: * "Range of Bit Positions Specified by Bit Offset Operands" */ bitmask = vie->opsize * 8 - 1; bitoff = vie->immediate & bitmask; /* Copy the bit into the Carry flag in %rflags */ if (val & (1UL << bitoff)) rflags |= PSL_C; else rflags &= ~PSL_C; error = vie_update_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, rflags, 8); KASSERT(error == 0, ("%s: error %d updating rflags", __func__, error)); return (0); } static int vie_emulate_twob_group15(struct vie *vie, struct vm *vm, int vcpuid, uint64_t gpa) { int error; uint64_t buf; switch (vie->reg & 7) { case 0x7: /* CLFLUSH, CLFLUSHOPT, and SFENCE */ if (vie->mod == 0x3) { /* * SFENCE. Ignore it, VM exit provides enough * barriers on its own. */ error = 0; } else { /* * CLFLUSH, CLFLUSHOPT. Only check for access * rights. */ error = vie_mmio_read(vie, vm, vcpuid, gpa, &buf, 1); } break; default: error = EINVAL; break; } return (error); } static int vie_emulate_clts(struct vie *vie, struct vm *vm, int vcpuid) { uint64_t val; int error __maybe_unused; if (vie->paging.cpl != 0) { vm_inject_gp(vm, vcpuid); vie->num_processed = 0; return (0); } error = vm_get_register(vm, vcpuid, VM_REG_GUEST_CR0, &val); ASSERT(error == 0); /* Clear %cr0.TS */ val &= ~CR0_TS; error = vm_set_register(vm, vcpuid, VM_REG_GUEST_CR0, val); ASSERT(error == 0); return (0); } static int vie_mmio_read(struct vie *vie, struct vm *vm, int cpuid, uint64_t gpa, uint64_t *rval, int bytes) { int err; if (vie->mmio_req_read.state == VR_DONE) { ASSERT(vie->mmio_req_read.bytes == bytes); ASSERT(vie->mmio_req_read.gpa == gpa); *rval = vie->mmio_req_read.data; return (0); } err = vm_service_mmio_read(vm, cpuid, gpa, rval, bytes); if (err == 0) { /* * A successful read from an in-kernel-emulated device may come * with side effects, so stash the result in case it's used for * an instruction which subsequently needs to issue an MMIO * write to userspace. */ ASSERT(vie->mmio_req_read.state == VR_NONE); vie->mmio_req_read.bytes = bytes; vie->mmio_req_read.gpa = gpa; vie->mmio_req_read.data = *rval; vie->mmio_req_read.state = VR_DONE; } else if (err == ESRCH) { /* Hope that userspace emulation can fulfill this read */ vie->mmio_req_read.bytes = bytes; vie->mmio_req_read.gpa = gpa; vie->mmio_req_read.state = VR_PENDING; vie->status |= VIES_PENDING_MMIO; } else if (err < 0) { /* * The MMIO read failed in such a way that fallback to handling * in userspace is required. */ vie->status |= VIES_USER_FALLBACK; } return (err); } static int vie_mmio_write(struct vie *vie, struct vm *vm, int cpuid, uint64_t gpa, uint64_t wval, int bytes) { int err; if (vie->mmio_req_write.state == VR_DONE) { ASSERT(vie->mmio_req_write.bytes == bytes); ASSERT(vie->mmio_req_write.gpa == gpa); return (0); } err = vm_service_mmio_write(vm, cpuid, gpa, wval, bytes); if (err == 0) { /* * A successful write to an in-kernel-emulated device probably * results in side effects, so stash the fact that such a write * succeeded in case the operation requires other work. */ vie->mmio_req_write.bytes = bytes; vie->mmio_req_write.gpa = gpa; vie->mmio_req_write.data = wval; vie->mmio_req_write.state = VR_DONE; } else if (err == ESRCH) { /* Hope that userspace emulation can fulfill this write */ vie->mmio_req_write.bytes = bytes; vie->mmio_req_write.gpa = gpa; vie->mmio_req_write.data = wval; vie->mmio_req_write.state = VR_PENDING; vie->status |= VIES_PENDING_MMIO; } else if (err < 0) { /* * The MMIO write failed in such a way that fallback to handling * in userspace is required. */ vie->status |= VIES_USER_FALLBACK; } return (err); } int vie_emulate_mmio(struct vie *vie, struct vm *vm, int vcpuid) { int error; uint64_t gpa; if ((vie->status & (VIES_INST_DECODE | VIES_MMIO)) != (VIES_INST_DECODE | VIES_MMIO)) { return (EINVAL); } gpa = vie->mmio_gpa; switch (vie->op.op_type) { case VIE_OP_TYPE_GROUP1: error = vie_emulate_group1(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_POP: error = vie_emulate_pop(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_PUSH: error = vie_emulate_push(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_CMP: error = vie_emulate_cmp(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_MOV: error = vie_emulate_mov(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_MOVSX: case VIE_OP_TYPE_MOVZX: error = vie_emulate_movx(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_MOVS: error = vie_emulate_movs(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_STOS: error = vie_emulate_stos(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_AND: error = vie_emulate_and(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_OR: error = vie_emulate_or(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_SUB: error = vie_emulate_sub(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_BITTEST: error = vie_emulate_bittest(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_TWOB_GRP15: error = vie_emulate_twob_group15(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_ADD: error = vie_emulate_add(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_TEST: error = vie_emulate_test(vie, vm, vcpuid, gpa); break; case VIE_OP_TYPE_BEXTR: error = vie_emulate_bextr(vie, vm, vcpuid, gpa); break; default: error = EINVAL; break; } if (error == ESRCH) { /* Return to userspace with the mmio request */ return (-1); } return (error); } static int vie_emulate_inout_port(struct vie *vie, struct vm *vm, int vcpuid, uint32_t *eax) { uint32_t mask, val; bool in; int err; mask = vie_size2mask(vie->inout.bytes); in = (vie->inout.flags & INOUT_IN) != 0; if (!in) { val = *eax & mask; } if (vie->inout_req_state != VR_DONE) { err = vm_ioport_access(vm, vcpuid, in, vie->inout.port, vie->inout.bytes, &val); val &= mask; } else { /* * This port access was handled in userspace and the result was * injected in to be handled now. */ val = vie->inout_req_val & mask; vie->inout_req_state = VR_NONE; err = 0; } if (err == ESRCH) { vie->status |= VIES_PENDING_INOUT; vie->inout_req_state = VR_PENDING; return (err); } else if (err != 0) { return (err); } if (in) { *eax = (*eax & ~mask) | val; } return (0); } static enum vm_reg_name vie_inout_segname(const struct vie *vie) { uint8_t segidx = vie->inout.segment; const enum vm_reg_name segmap[] = { VM_REG_GUEST_ES, VM_REG_GUEST_CS, VM_REG_GUEST_SS, VM_REG_GUEST_DS, VM_REG_GUEST_FS, VM_REG_GUEST_GS, }; const uint8_t maxidx = (sizeof (segmap) / sizeof (segmap[0])); if (segidx >= maxidx) { panic("unexpected segment index %u", segidx); } return (segmap[segidx]); } static int vie_emulate_inout_str(struct vie *vie, struct vm *vm, int vcpuid) { uint8_t bytes, addrsize; uint64_t index, count = 0, gla, rflags; int prot, err, fault; bool in, repeat; enum vm_reg_name seg_reg, idx_reg; struct vm_copyinfo copyinfo[2]; in = (vie->inout.flags & INOUT_IN) != 0; bytes = vie->inout.bytes; addrsize = vie->inout.addrsize; prot = in ? PROT_WRITE : PROT_READ; ASSERT(bytes == 1 || bytes == 2 || bytes == 4); ASSERT(addrsize == 2 || addrsize == 4 || addrsize == 8); idx_reg = (in) ? VM_REG_GUEST_RDI : VM_REG_GUEST_RSI; seg_reg = vie_inout_segname(vie); err = vm_get_register(vm, vcpuid, idx_reg, &index); ASSERT(err == 0); index = index & vie_size2mask(addrsize); repeat = (vie->inout.flags & INOUT_REP) != 0; /* Count register */ if (repeat) { err = vm_get_register(vm, vcpuid, VM_REG_GUEST_RCX, &count); count &= vie_size2mask(addrsize); if (count == 0) { /* * If we were asked to emulate a REP INS/OUTS when the * count register is zero, no further work is required. */ return (0); } } else { count = 1; } gla = 0; if (vie_get_gla(vie, vm, vcpuid, bytes, addrsize, prot, seg_reg, idx_reg, &gla) != 0) { /* vie_get_gla() already injected the appropriate fault */ return (0); } /* * The INS/OUTS emulate currently assumes that the memory target resides * within the guest system memory, rather than a device MMIO region. If * such a case becomes a necessity, that additional handling could be * put in place. */ err = vm_copy_setup(vm, vcpuid, &vie->paging, gla, bytes, prot, copyinfo, nitems(copyinfo), &fault); if (err) { /* Unrecoverable error */ return (err); } else if (fault) { /* Resume guest to handle fault */ return (0); } if (!in) { vm_copyin(vm, vcpuid, copyinfo, &vie->inout.eax, bytes); } err = vie_emulate_inout_port(vie, vm, vcpuid, &vie->inout.eax); if (err == 0 && in) { vm_copyout(vm, vcpuid, &vie->inout.eax, copyinfo, bytes); } vm_copy_teardown(vm, vcpuid, copyinfo, nitems(copyinfo)); if (err == 0) { err = vm_get_register(vm, vcpuid, VM_REG_GUEST_RFLAGS, &rflags); ASSERT(err == 0); /* Update index */ if (rflags & PSL_D) { index -= bytes; } else { index += bytes; } /* Update index register */ err = vie_update_register(vm, vcpuid, idx_reg, index, addrsize); ASSERT(err == 0); /* * Update count register only if the instruction had a repeat * prefix. */ if ((vie->inout.flags & INOUT_REP) != 0) { count--; err = vie_update_register(vm, vcpuid, VM_REG_GUEST_RCX, count, addrsize); ASSERT(err == 0); if (count != 0) { return (vie_repeat(vie)); } } } return (err); } int vie_emulate_inout(struct vie *vie, struct vm *vm, int vcpuid) { int err = 0; if ((vie->status & VIES_INOUT) == 0) { return (EINVAL); } if ((vie->inout.flags & INOUT_STR) == 0) { /* * For now, using the 'rep' prefixes with plain (non-string) * in/out is not supported. */ if ((vie->inout.flags & INOUT_REP) != 0) { return (EINVAL); } err = vie_emulate_inout_port(vie, vm, vcpuid, &vie->inout.eax); if (err == 0 && (vie->inout.flags & INOUT_IN) != 0) { /* * With the inX access now a success, the result needs * to be stored in the guest %rax. */ err = vm_set_register(vm, vcpuid, VM_REG_GUEST_RAX, vie->inout.eax); VERIFY0(err); } } else { vie->status &= ~VIES_REPEAT; err = vie_emulate_inout_str(vie, vm, vcpuid); } if (err < 0) { /* * Access to an I/O port failed in such a way that fallback to * handling in userspace is required. */ vie->status |= VIES_USER_FALLBACK; } else if (err == ESRCH) { ASSERT(vie->status & VIES_PENDING_INOUT); /* Return to userspace with the in/out request */ err = -1; } return (err); } int vie_emulate_other(struct vie *vie, struct vm *vm, int vcpuid) { int error; if ((vie->status & (VIES_INST_DECODE | VIES_OTHER)) != (VIES_INST_DECODE | VIES_OTHER)) { return (EINVAL); } switch (vie->op.op_type) { case VIE_OP_TYPE_CLTS: error = vie_emulate_clts(vie, vm, vcpuid); break; case VIE_OP_TYPE_MOV_CR: error = vie_emulate_mov_cr(vie, vm, vcpuid); break; default: error = EINVAL; break; } return (error); } void vie_reset(struct vie *vie) { vie->status = 0; vie->num_processed = vie->num_valid = 0; } void vie_advance_pc(struct vie *vie, uint64_t *nextrip) { VERIFY((vie->status & VIES_REPEAT) == 0); *nextrip += vie->num_processed; vie_reset(vie); } void vie_exitinfo(const struct vie *vie, struct vm_exit *vme) { if (vie->status & VIES_USER_FALLBACK) { /* * Despite the fact that the instruction was successfully * decoded, some aspect of the emulation failed in such a way * that it is left up to userspace to complete the operation. */ vie_fallback_exitinfo(vie, vme); } else if (vie->status & VIES_MMIO) { vme->exitcode = VM_EXITCODE_MMIO; if (vie->mmio_req_read.state == VR_PENDING) { vme->u.mmio.gpa = vie->mmio_req_read.gpa; vme->u.mmio.data = 0; vme->u.mmio.bytes = vie->mmio_req_read.bytes; vme->u.mmio.read = 1; } else if (vie->mmio_req_write.state == VR_PENDING) { vme->u.mmio.gpa = vie->mmio_req_write.gpa; vme->u.mmio.data = vie->mmio_req_write.data & vie_size2mask(vie->mmio_req_write.bytes); vme->u.mmio.bytes = vie->mmio_req_write.bytes; vme->u.mmio.read = 0; } else { panic("bad pending MMIO state"); } } else if (vie->status & VIES_INOUT) { vme->exitcode = VM_EXITCODE_INOUT; vme->u.inout.port = vie->inout.port; vme->u.inout.bytes = vie->inout.bytes; if ((vie->inout.flags & INOUT_IN) != 0) { vme->u.inout.flags = INOUT_IN; vme->u.inout.eax = 0; } else { vme->u.inout.flags = 0; vme->u.inout.eax = vie->inout.eax & vie_size2mask(vie->inout.bytes); } } else { panic("no pending operation"); } } /* * In the case of a decoding or verification failure, bailing out to userspace * to do the instruction emulation is our only option for now. */ void vie_fallback_exitinfo(const struct vie *vie, struct vm_exit *vme) { if ((vie->status & VIES_INST_FETCH) == 0) { bzero(&vme->u.inst_emul, sizeof (vme->u.inst_emul)); } else { ASSERT(sizeof (vie->inst) == sizeof (vme->u.inst_emul.inst)); bcopy(vie->inst, vme->u.inst_emul.inst, sizeof (vie->inst)); vme->u.inst_emul.num_valid = vie->num_valid; } vme->exitcode = VM_EXITCODE_INST_EMUL; } void vie_cs_info(const struct vie *vie, struct vm *vm, int vcpuid, uint64_t *cs_base, int *cs_d) { struct seg_desc cs_desc; int error __maybe_unused; error = vm_get_seg_desc(vm, vcpuid, VM_REG_GUEST_CS, &cs_desc); ASSERT(error == 0); /* Initialization required for the paging info to be populated */ VERIFY(vie->status & VIES_INIT); switch (vie->paging.cpu_mode) { case CPU_MODE_REAL: *cs_base = cs_desc.base; *cs_d = 0; break; case CPU_MODE_PROTECTED: case CPU_MODE_COMPATIBILITY: *cs_base = cs_desc.base; *cs_d = SEG_DESC_DEF32(cs_desc.access) ? 1 : 0; break; default: *cs_base = 0; *cs_d = 0; break; } } bool vie_pending(const struct vie *vie) { /* * These VIE status bits indicate conditions which must be addressed * through either device IO fulfillment (with corresponding * vie_fulfill_*()) or complete userspace emulation (followed by a * vie_reset()). */ const enum vie_status of_interest = VIES_PENDING_MMIO | VIES_PENDING_INOUT | VIES_USER_FALLBACK; return ((vie->status & of_interest) != 0); } bool vie_needs_fetch(const struct vie *vie) { if (vie->status & VIES_INST_FETCH) { ASSERT(vie->num_valid != 0); return (false); } return (true); } static int vie_alignment_check(int cpl, int size, uint64_t cr0, uint64_t rf, uint64_t gla) { KASSERT(size == 1 || size == 2 || size == 4 || size == 8, ("%s: invalid size %d", __func__, size)); KASSERT(cpl >= 0 && cpl <= 3, ("%s: invalid cpl %d", __func__, cpl)); if (cpl != 3 || (cr0 & CR0_AM) == 0 || (rf & PSL_AC) == 0) return (0); return ((gla & (size - 1)) ? 1 : 0); } static int vie_canonical_check(enum vm_cpu_mode cpu_mode, uint64_t gla) { uint64_t mask; if (cpu_mode != CPU_MODE_64BIT) return (0); /* * The value of the bit 47 in the 'gla' should be replicated in the * most significant 16 bits. */ mask = ~((1UL << 48) - 1); if (gla & (1UL << 47)) return ((gla & mask) != mask); else return ((gla & mask) != 0); } static uint64_t vie_size2mask(int size) { KASSERT(size == 1 || size == 2 || size == 4 || size == 8, ("vie_size2mask: invalid size %d", size)); return (size2mask[size]); } static int vie_calculate_gla(enum vm_cpu_mode cpu_mode, enum vm_reg_name seg, struct seg_desc *desc, uint64_t offset, int length, int addrsize, int prot, uint64_t *gla) { uint64_t firstoff, low_limit, high_limit, segbase; int glasize, type; KASSERT(seg >= VM_REG_GUEST_ES && seg <= VM_REG_GUEST_GS, ("%s: invalid segment %d", __func__, seg)); KASSERT(length == 1 || length == 2 || length == 4 || length == 8, ("%s: invalid operand size %d", __func__, length)); KASSERT((prot & ~(PROT_READ | PROT_WRITE)) == 0, ("%s: invalid prot %x", __func__, prot)); firstoff = offset; if (cpu_mode == CPU_MODE_64BIT) { KASSERT(addrsize == 4 || addrsize == 8, ("%s: invalid address " "size %d for cpu_mode %d", __func__, addrsize, cpu_mode)); glasize = 8; } else { KASSERT(addrsize == 2 || addrsize == 4, ("%s: invalid address " "size %d for cpu mode %d", __func__, addrsize, cpu_mode)); glasize = 4; /* * If the segment selector is loaded with a NULL selector * then the descriptor is unusable and attempting to use * it results in a #GP(0). */ if (SEG_DESC_UNUSABLE(desc->access)) return (-1); /* * The processor generates a #NP exception when a segment * register is loaded with a selector that points to a * descriptor that is not present. If this was the case then * it would have been checked before the VM-exit. */ KASSERT(SEG_DESC_PRESENT(desc->access), ("segment %d not present: %x", seg, desc->access)); /* * The descriptor type must indicate a code/data segment. */ type = SEG_DESC_TYPE(desc->access); KASSERT(type >= 16 && type <= 31, ("segment %d has invalid " "descriptor type %x", seg, type)); if (prot & PROT_READ) { /* #GP on a read access to a exec-only code segment */ if ((type & 0xA) == 0x8) return (-1); } if (prot & PROT_WRITE) { /* * #GP on a write access to a code segment or a * read-only data segment. */ if (type & 0x8) /* code segment */ return (-1); if ((type & 0xA) == 0) /* read-only data seg */ return (-1); } /* * 'desc->limit' is fully expanded taking granularity into * account. */ if ((type & 0xC) == 0x4) { /* expand-down data segment */ low_limit = desc->limit + 1; high_limit = SEG_DESC_DEF32(desc->access) ? 0xffffffff : 0xffff; } else { /* code segment or expand-up data segment */ low_limit = 0; high_limit = desc->limit; } while (length > 0) { offset &= vie_size2mask(addrsize); if (offset < low_limit || offset > high_limit) return (-1); offset++; length--; } } /* * In 64-bit mode all segments except %fs and %gs have a segment * base address of 0. */ if (cpu_mode == CPU_MODE_64BIT && seg != VM_REG_GUEST_FS && seg != VM_REG_GUEST_GS) { segbase = 0; } else { segbase = desc->base; } /* * Truncate 'firstoff' to the effective address size before adding * it to the segment base. */ firstoff &= vie_size2mask(addrsize); *gla = (segbase + firstoff) & vie_size2mask(glasize); return (0); } void vie_init_mmio(struct vie *vie, const char *inst_bytes, uint8_t inst_length, const struct vm_guest_paging *paging, uint64_t gpa) { KASSERT(inst_length <= VIE_INST_SIZE, ("%s: invalid instruction length (%d)", __func__, inst_length)); bzero(vie, sizeof (struct vie)); vie->base_register = VM_REG_LAST; vie->index_register = VM_REG_LAST; vie->segment_register = VM_REG_LAST; vie->status = VIES_INIT | VIES_MMIO; if (inst_length != 0) { bcopy(inst_bytes, vie->inst, inst_length); vie->num_valid = inst_length; vie->status |= VIES_INST_FETCH; } vie->paging = *paging; vie->mmio_gpa = gpa; } void vie_init_inout(struct vie *vie, const struct vm_inout *inout, uint8_t inst_len, const struct vm_guest_paging *paging) { bzero(vie, sizeof (struct vie)); vie->status = VIES_INIT | VIES_INOUT; vie->inout = *inout; vie->paging = *paging; /* * Since VMX/SVM assists already decoded the nature of the in/out * instruction, let the status reflect that. */ vie->status |= VIES_INST_FETCH | VIES_INST_DECODE; vie->num_processed = inst_len; } void vie_init_other(struct vie *vie, const struct vm_guest_paging *paging) { bzero(vie, sizeof (struct vie)); vie->base_register = VM_REG_LAST; vie->index_register = VM_REG_LAST; vie->segment_register = VM_REG_LAST; vie->status = VIES_INIT | VIES_OTHER; vie->paging = *paging; } int vie_fulfill_mmio(struct vie *vie, const struct vm_mmio *result) { struct vie_mmio *pending; if ((vie->status & VIES_MMIO) == 0 || (vie->status & VIES_PENDING_MMIO) == 0) { return (EINVAL); } if (result->read) { pending = &vie->mmio_req_read; } else { pending = &vie->mmio_req_write; } if (pending->state != VR_PENDING || pending->bytes != result->bytes || pending->gpa != result->gpa) { return (EINVAL); } if (result->read) { pending->data = result->data & vie_size2mask(pending->bytes); } pending->state = VR_DONE; vie->status &= ~VIES_PENDING_MMIO; return (0); } int vie_fulfill_inout(struct vie *vie, const struct vm_inout *result) { if ((vie->status & VIES_INOUT) == 0 || (vie->status & VIES_PENDING_INOUT) == 0) { return (EINVAL); } if ((vie->inout.flags & INOUT_IN) != (result->flags & INOUT_IN) || vie->inout.bytes != result->bytes || vie->inout.port != result->port) { return (EINVAL); } if (result->flags & INOUT_IN) { vie->inout_req_val = result->eax & vie_size2mask(vie->inout.bytes); } vie->inout_req_state = VR_DONE; vie->status &= ~(VIES_PENDING_INOUT); return (0); } uint64_t vie_mmio_gpa(const struct vie *vie) { return (vie->mmio_gpa); } static int pf_error_code(int usermode, int prot, int rsvd, uint64_t pte) { int error_code = 0; if (pte & PG_V) error_code |= PGEX_P; if (prot & PROT_WRITE) error_code |= PGEX_W; if (usermode) error_code |= PGEX_U; if (rsvd) error_code |= PGEX_RSV; if (prot & PROT_EXEC) error_code |= PGEX_I; return (error_code); } static void ptp_release(vm_page_t **vmp) { if (*vmp != NULL) { (void) vmp_release(*vmp); *vmp = NULL; } } static void * ptp_hold(struct vm *vm, int vcpu, uintptr_t gpa, size_t len, vm_page_t **vmp) { vm_client_t *vmc = vm_get_vmclient(vm, vcpu); const uintptr_t hold_gpa = gpa & PAGEMASK; /* Hold must not cross a page boundary */ VERIFY3U(gpa + len, <=, hold_gpa + PAGESIZE); if (*vmp != NULL) { (void) vmp_release(*vmp); } *vmp = vmc_hold(vmc, hold_gpa, PROT_READ | PROT_WRITE); if (*vmp == NULL) { return (NULL); } return ((caddr_t)vmp_get_writable(*vmp) + (gpa - hold_gpa)); } static int _vm_gla2gpa(struct vm *vm, int vcpuid, struct vm_guest_paging *paging, uint64_t gla, int prot, uint64_t *gpa, int *guest_fault, bool check_only) { int nlevels, pfcode; int ptpshift = 0, ptpindex = 0; uint64_t ptpphys; uint64_t *ptpbase = NULL, pte = 0, pgsize = 0; vm_page_t *cookie = NULL; const bool usermode = paging->cpl == 3; const bool writable = (prot & PROT_WRITE) != 0; *guest_fault = 0; restart: ptpphys = paging->cr3; /* root of the page tables */ ptp_release(&cookie); if (vie_canonical_check(paging->cpu_mode, gla)) { /* * XXX assuming a non-stack reference otherwise a stack fault * should be generated. */ if (!check_only) vm_inject_gp(vm, vcpuid); *guest_fault = 1; return (0); } if (paging->paging_mode == PAGING_MODE_FLAT) { *gpa = gla; return (0); } if (paging->paging_mode == PAGING_MODE_32) { uint32_t *ptpbase32, pte32; nlevels = 2; while (--nlevels >= 0) { /* Zero out the lower 12 bits. */ ptpphys &= ~0xfff; ptpbase32 = ptp_hold(vm, vcpuid, ptpphys, PAGE_SIZE, &cookie); if (ptpbase32 == NULL) { return (EFAULT); } ptpshift = PAGE_SHIFT + nlevels * 10; ptpindex = (gla >> ptpshift) & 0x3FF; pgsize = 1UL << ptpshift; pte32 = ptpbase32[ptpindex]; if ((pte32 & PG_V) == 0 || (usermode && (pte32 & PG_U) == 0) || (writable && (pte32 & PG_RW) == 0)) { if (!check_only) { pfcode = pf_error_code(usermode, prot, 0, pte32); vm_inject_pf(vm, vcpuid, pfcode, gla); } ptp_release(&cookie); *guest_fault = 1; return (0); } /* * Emulate the x86 MMU's management of the accessed * and dirty flags. While the accessed flag is set * at every level of the page table, the dirty flag * is only set at the last level providing the guest * physical address. */ if (!check_only && (pte32 & PG_A) == 0) { if (atomic_cmpset_32(&ptpbase32[ptpindex], pte32, pte32 | PG_A) == 0) { goto restart; } } /* XXX must be ignored if CR4.PSE=0 */ if (nlevels > 0 && (pte32 & PG_PS) != 0) break; ptpphys = pte32; } /* Set the dirty bit in the page table entry if necessary */ if (!check_only && writable && (pte32 & PG_M) == 0) { if (atomic_cmpset_32(&ptpbase32[ptpindex], pte32, pte32 | PG_M) == 0) { goto restart; } } /* Zero out the lower 'ptpshift' bits */ pte32 >>= ptpshift; pte32 <<= ptpshift; *gpa = pte32 | (gla & (pgsize - 1)); ptp_release(&cookie); return (0); } if (paging->paging_mode == PAGING_MODE_PAE) { /* Zero out the lower 5 bits and the upper 32 bits */ ptpphys &= 0xffffffe0UL; ptpbase = ptp_hold(vm, vcpuid, ptpphys, sizeof (*ptpbase) * 4, &cookie); if (ptpbase == NULL) { return (EFAULT); } ptpindex = (gla >> 30) & 0x3; pte = ptpbase[ptpindex]; if ((pte & PG_V) == 0) { if (!check_only) { pfcode = pf_error_code(usermode, prot, 0, pte); vm_inject_pf(vm, vcpuid, pfcode, gla); } ptp_release(&cookie); *guest_fault = 1; return (0); } ptpphys = pte; nlevels = 2; } else { nlevels = 4; } while (--nlevels >= 0) { /* Zero out the lower 12 bits and the upper 12 bits */ ptpphys &= 0x000ffffffffff000UL; ptpbase = ptp_hold(vm, vcpuid, ptpphys, PAGE_SIZE, &cookie); if (ptpbase == NULL) { return (EFAULT); } ptpshift = PAGE_SHIFT + nlevels * 9; ptpindex = (gla >> ptpshift) & 0x1FF; pgsize = 1UL << ptpshift; pte = ptpbase[ptpindex]; if ((pte & PG_V) == 0 || (usermode && (pte & PG_U) == 0) || (writable && (pte & PG_RW) == 0)) { if (!check_only) { pfcode = pf_error_code(usermode, prot, 0, pte); vm_inject_pf(vm, vcpuid, pfcode, gla); } ptp_release(&cookie); *guest_fault = 1; return (0); } /* Set the accessed bit in the page table entry */ if (!check_only && (pte & PG_A) == 0) { if (atomic_cmpset_64(&ptpbase[ptpindex], pte, pte | PG_A) == 0) { goto restart; } } if (nlevels > 0 && (pte & PG_PS) != 0) { if (pgsize > 1 * GB) { if (!check_only) { pfcode = pf_error_code(usermode, prot, 1, pte); vm_inject_pf(vm, vcpuid, pfcode, gla); } ptp_release(&cookie); *guest_fault = 1; return (0); } break; } ptpphys = pte; } /* Set the dirty bit in the page table entry if necessary */ if (!check_only && writable && (pte & PG_M) == 0) { if (atomic_cmpset_64(&ptpbase[ptpindex], pte, pte | PG_M) == 0) goto restart; } ptp_release(&cookie); /* Zero out the lower 'ptpshift' bits and the upper 12 bits */ pte >>= ptpshift; pte <<= (ptpshift + 12); pte >>= 12; *gpa = pte | (gla & (pgsize - 1)); return (0); } int vm_gla2gpa(struct vm *vm, int vcpuid, struct vm_guest_paging *paging, uint64_t gla, int prot, uint64_t *gpa, int *guest_fault) { return (_vm_gla2gpa(vm, vcpuid, paging, gla, prot, gpa, guest_fault, false)); } int vm_gla2gpa_nofault(struct vm *vm, int vcpuid, struct vm_guest_paging *paging, uint64_t gla, int prot, uint64_t *gpa, int *guest_fault) { return (_vm_gla2gpa(vm, vcpuid, paging, gla, prot, gpa, guest_fault, true)); } int vie_fetch_instruction(struct vie *vie, struct vm *vm, int vcpuid, uint64_t rip, int *faultptr) { struct vm_copyinfo copyinfo[2]; int error, prot; if ((vie->status & VIES_INIT) == 0) { return (EINVAL); } prot = PROT_READ | PROT_EXEC; error = vm_copy_setup(vm, vcpuid, &vie->paging, rip, VIE_INST_SIZE, prot, copyinfo, nitems(copyinfo), faultptr); if (error || *faultptr) return (error); vm_copyin(vm, vcpuid, copyinfo, vie->inst, VIE_INST_SIZE); vm_copy_teardown(vm, vcpuid, copyinfo, nitems(copyinfo)); vie->num_valid = VIE_INST_SIZE; vie->status |= VIES_INST_FETCH; return (0); } static int vie_peek(struct vie *vie, uint8_t *x) { if (vie->num_processed < vie->num_valid) { *x = vie->inst[vie->num_processed]; return (0); } else return (-1); } static void vie_advance(struct vie *vie) { vie->num_processed++; } static bool segment_override(uint8_t x, int *seg) { switch (x) { case 0x2E: *seg = VM_REG_GUEST_CS; break; case 0x36: *seg = VM_REG_GUEST_SS; break; case 0x3E: *seg = VM_REG_GUEST_DS; break; case 0x26: *seg = VM_REG_GUEST_ES; break; case 0x64: *seg = VM_REG_GUEST_FS; break; case 0x65: *seg = VM_REG_GUEST_GS; break; default: return (false); } return (true); } static int decode_prefixes(struct vie *vie, enum vm_cpu_mode cpu_mode, int cs_d) { uint8_t x; while (1) { if (vie_peek(vie, &x)) return (-1); if (x == 0x66) vie->opsize_override = 1; else if (x == 0x67) vie->addrsize_override = 1; else if (x == 0xF3) vie->repz_present = 1; else if (x == 0xF2) vie->repnz_present = 1; else if (segment_override(x, &vie->segment_register)) vie->segment_override = 1; else break; vie_advance(vie); } /* * From section 2.2.1, "REX Prefixes", Intel SDM Vol 2: * - Only one REX prefix is allowed per instruction. * - The REX prefix must immediately precede the opcode byte or the * escape opcode byte. * - If an instruction has a mandatory prefix (0x66, 0xF2 or 0xF3) * the mandatory prefix must come before the REX prefix. */ if (cpu_mode == CPU_MODE_64BIT && x >= 0x40 && x <= 0x4F) { vie->rex_present = 1; vie->rex_w = x & 0x8 ? 1 : 0; vie->rex_r = x & 0x4 ? 1 : 0; vie->rex_x = x & 0x2 ? 1 : 0; vie->rex_b = x & 0x1 ? 1 : 0; vie_advance(vie); } /* * ยง 2.3.5, "The VEX Prefix", SDM Vol 2. */ if ((cpu_mode == CPU_MODE_64BIT || cpu_mode == CPU_MODE_COMPATIBILITY) && x == 0xC4) { const struct vie_op *optab; /* 3-byte VEX prefix. */ vie->vex_present = 1; vie_advance(vie); if (vie_peek(vie, &x)) return (-1); /* * 2nd byte: [R', X', B', mmmmm[4:0]]. Bits are inverted * relative to REX encoding. */ vie->rex_r = x & 0x80 ? 0 : 1; vie->rex_x = x & 0x40 ? 0 : 1; vie->rex_b = x & 0x20 ? 0 : 1; switch (x & 0x1F) { case 0x2: /* 0F 38. */ optab = three_byte_opcodes_0f38; break; case 0x1: /* 0F class - nothing handled here yet. */ /* FALLTHROUGH */ case 0x3: /* 0F 3A class - nothing handled here yet. */ /* FALLTHROUGH */ default: /* Reserved (#UD). */ return (-1); } vie_advance(vie); if (vie_peek(vie, &x)) return (-1); /* 3rd byte: [W, vvvv[6:3], L, pp[1:0]]. */ vie->rex_w = x & 0x80 ? 1 : 0; vie->vex_reg = ((~(unsigned)x & 0x78u) >> 3); vie->vex_l = !!(x & 0x4); vie->vex_pp = (x & 0x3); /* PP: 1=66 2=F3 3=F2 prefixes. */ switch (vie->vex_pp) { case 0x1: vie->opsize_override = 1; break; case 0x2: vie->repz_present = 1; break; case 0x3: vie->repnz_present = 1; break; } vie_advance(vie); /* Opcode, sans literal prefix prefix. */ if (vie_peek(vie, &x)) return (-1); vie->op = optab[x]; if (vie->op.op_type == VIE_OP_TYPE_NONE) return (-1); vie_advance(vie); } /* * Section "Operand-Size And Address-Size Attributes", Intel SDM, Vol 1 */ if (cpu_mode == CPU_MODE_64BIT) { /* * Default address size is 64-bits and default operand size * is 32-bits. */ vie->addrsize = vie->addrsize_override ? 4 : 8; if (vie->rex_w) vie->opsize = 8; else if (vie->opsize_override) vie->opsize = 2; else vie->opsize = 4; } else if (cs_d) { /* Default address and operand sizes are 32-bits */ vie->addrsize = vie->addrsize_override ? 2 : 4; vie->opsize = vie->opsize_override ? 2 : 4; } else { /* Default address and operand sizes are 16-bits */ vie->addrsize = vie->addrsize_override ? 4 : 2; vie->opsize = vie->opsize_override ? 4 : 2; } return (0); } static int decode_two_byte_opcode(struct vie *vie) { uint8_t x; if (vie_peek(vie, &x)) return (-1); vie->op = two_byte_opcodes[x]; if (vie->op.op_type == VIE_OP_TYPE_NONE) return (-1); vie_advance(vie); return (0); } static int decode_opcode(struct vie *vie) { uint8_t x; if (vie_peek(vie, &x)) return (-1); /* Already did this via VEX prefix. */ if (vie->op.op_type != VIE_OP_TYPE_NONE) return (0); vie->op = one_byte_opcodes[x]; if (vie->op.op_type == VIE_OP_TYPE_NONE) return (-1); vie_advance(vie); if (vie->op.op_type == VIE_OP_TYPE_TWO_BYTE) return (decode_two_byte_opcode(vie)); return (0); } static int decode_modrm(struct vie *vie, enum vm_cpu_mode cpu_mode) { uint8_t x; /* * Handling mov-to/from-cr is special since it is not issuing * mmio/pio requests and can be done in real mode. We must bypass some * of the other existing decoding restrictions for it. */ const bool is_movcr = ((vie->op.op_flags & VIE_OP_F_REG_REG) != 0); if (vie->op.op_flags & VIE_OP_F_NO_MODRM) return (0); if (cpu_mode == CPU_MODE_REAL && !is_movcr) return (-1); if (vie_peek(vie, &x)) return (-1); vie->mod = (x >> 6) & 0x3; vie->rm = (x >> 0) & 0x7; vie->reg = (x >> 3) & 0x7; /* * A direct addressing mode makes no sense in the context of an EPT * fault. There has to be a memory access involved to cause the * EPT fault. */ if (vie->mod == VIE_MOD_DIRECT && !is_movcr) return (-1); if ((vie->mod == VIE_MOD_INDIRECT && vie->rm == VIE_RM_DISP32) || (vie->mod != VIE_MOD_DIRECT && vie->rm == VIE_RM_SIB)) { /* * Table 2-5: Special Cases of REX Encodings * * mod=0, r/m=5 is used in the compatibility mode to * indicate a disp32 without a base register. * * mod!=3, r/m=4 is used in the compatibility mode to * indicate that the SIB byte is present. * * The 'b' bit in the REX prefix is don't care in * this case. */ } else { vie->rm |= (vie->rex_b << 3); } vie->reg |= (vie->rex_r << 3); /* SIB */ if (vie->mod != VIE_MOD_DIRECT && vie->rm == VIE_RM_SIB) goto done; vie->base_register = gpr_map[vie->rm]; switch (vie->mod) { case VIE_MOD_INDIRECT_DISP8: vie->disp_bytes = 1; break; case VIE_MOD_INDIRECT_DISP32: vie->disp_bytes = 4; break; case VIE_MOD_INDIRECT: if (vie->rm == VIE_RM_DISP32) { vie->disp_bytes = 4; /* * Table 2-7. RIP-Relative Addressing * * In 64-bit mode mod=00 r/m=101 implies [rip] + disp32 * whereas in compatibility mode it just implies disp32. */ if (cpu_mode == CPU_MODE_64BIT) vie->base_register = VM_REG_GUEST_RIP; else vie->base_register = VM_REG_LAST; } break; } done: vie_advance(vie); return (0); } static int decode_sib(struct vie *vie) { uint8_t x; /* Proceed only if SIB byte is present */ if (vie->mod == VIE_MOD_DIRECT || vie->rm != VIE_RM_SIB) return (0); if (vie_peek(vie, &x)) return (-1); /* De-construct the SIB byte */ vie->ss = (x >> 6) & 0x3; vie->index = (x >> 3) & 0x7; vie->base = (x >> 0) & 0x7; /* Apply the REX prefix modifiers */ vie->index |= vie->rex_x << 3; vie->base |= vie->rex_b << 3; switch (vie->mod) { case VIE_MOD_INDIRECT_DISP8: vie->disp_bytes = 1; break; case VIE_MOD_INDIRECT_DISP32: vie->disp_bytes = 4; break; } if (vie->mod == VIE_MOD_INDIRECT && (vie->base == 5 || vie->base == 13)) { /* * Special case when base register is unused if mod = 0 * and base = %rbp or %r13. * * Documented in: * Table 2-3: 32-bit Addressing Forms with the SIB Byte * Table 2-5: Special Cases of REX Encodings */ vie->disp_bytes = 4; } else { vie->base_register = gpr_map[vie->base]; } /* * All encodings of 'index' are valid except for %rsp (4). * * Documented in: * Table 2-3: 32-bit Addressing Forms with the SIB Byte * Table 2-5: Special Cases of REX Encodings */ if (vie->index != 4) vie->index_register = gpr_map[vie->index]; /* 'scale' makes sense only in the context of an index register */ if (vie->index_register < VM_REG_LAST) vie->scale = 1 << vie->ss; vie_advance(vie); return (0); } static int decode_displacement(struct vie *vie) { int n, i; uint8_t x; union { char buf[4]; int8_t signed8; int32_t signed32; } u; if ((n = vie->disp_bytes) == 0) return (0); if (n != 1 && n != 4) panic("decode_displacement: invalid disp_bytes %d", n); for (i = 0; i < n; i++) { if (vie_peek(vie, &x)) return (-1); u.buf[i] = x; vie_advance(vie); } if (n == 1) vie->displacement = u.signed8; /* sign-extended */ else vie->displacement = u.signed32; /* sign-extended */ return (0); } static int decode_immediate(struct vie *vie) { int i, n; uint8_t x; union { char buf[4]; int8_t signed8; int16_t signed16; int32_t signed32; } u; /* Figure out immediate operand size (if any) */ if (vie->op.op_flags & VIE_OP_F_IMM) { /* * Section 2.2.1.5 "Immediates", Intel SDM: * In 64-bit mode the typical size of immediate operands * remains 32-bits. When the operand size if 64-bits, the * processor sign-extends all immediates to 64-bits prior * to their use. */ if (vie->opsize == 4 || vie->opsize == 8) vie->imm_bytes = 4; else vie->imm_bytes = 2; } else if (vie->op.op_flags & VIE_OP_F_IMM8) { vie->imm_bytes = 1; } if ((n = vie->imm_bytes) == 0) return (0); KASSERT(n == 1 || n == 2 || n == 4, ("%s: invalid number of immediate bytes: %d", __func__, n)); for (i = 0; i < n; i++) { if (vie_peek(vie, &x)) return (-1); u.buf[i] = x; vie_advance(vie); } /* sign-extend the immediate value before use */ if (n == 1) vie->immediate = u.signed8; else if (n == 2) vie->immediate = u.signed16; else vie->immediate = u.signed32; return (0); } static int decode_moffset(struct vie *vie) { int i, n; uint8_t x; union { char buf[8]; uint64_t u64; } u; if ((vie->op.op_flags & VIE_OP_F_MOFFSET) == 0) return (0); /* * Section 2.2.1.4, "Direct Memory-Offset MOVs", Intel SDM: * The memory offset size follows the address-size of the instruction. */ n = vie->addrsize; KASSERT(n == 2 || n == 4 || n == 8, ("invalid moffset bytes: %d", n)); u.u64 = 0; for (i = 0; i < n; i++) { if (vie_peek(vie, &x)) return (-1); u.buf[i] = x; vie_advance(vie); } vie->displacement = u.u64; return (0); } /* * Verify that the 'guest linear address' provided as collateral of the nested * page table fault matches with our instruction decoding. */ int vie_verify_gla(struct vie *vie, struct vm *vm, int cpuid, uint64_t gla) { int error; uint64_t base, segbase, idx, gla2; enum vm_reg_name seg; struct seg_desc desc; ASSERT((vie->status & VIES_INST_DECODE) != 0); /* * If there was no valid GLA context with the exit, or the decoded * instruction acts on more than one address, verification is done. */ if (gla == VIE_INVALID_GLA || (vie->op.op_flags & VIE_OP_F_NO_GLA_VERIFICATION) != 0) { return (0); } base = 0; if (vie->base_register != VM_REG_LAST) { error = vm_get_register(vm, cpuid, vie->base_register, &base); if (error) { printf("verify_gla: error %d getting base reg %d\n", error, vie->base_register); return (-1); } /* * RIP-relative addressing starts from the following * instruction */ if (vie->base_register == VM_REG_GUEST_RIP) base += vie->num_processed; } idx = 0; if (vie->index_register != VM_REG_LAST) { error = vm_get_register(vm, cpuid, vie->index_register, &idx); if (error) { printf("verify_gla: error %d getting index reg %d\n", error, vie->index_register); return (-1); } } /* * From "Specifying a Segment Selector", Intel SDM, Vol 1 * * In 64-bit mode, segmentation is generally (but not * completely) disabled. The exceptions are the FS and GS * segments. * * In legacy IA-32 mode, when the ESP or EBP register is used * as the base, the SS segment is the default segment. For * other data references, except when relative to stack or * string destination the DS segment is the default. These * can be overridden to allow other segments to be accessed. */ if (vie->segment_override) { seg = vie->segment_register; } else if (vie->base_register == VM_REG_GUEST_RSP || vie->base_register == VM_REG_GUEST_RBP) { seg = VM_REG_GUEST_SS; } else { seg = VM_REG_GUEST_DS; } if (vie->paging.cpu_mode == CPU_MODE_64BIT && seg != VM_REG_GUEST_FS && seg != VM_REG_GUEST_GS) { segbase = 0; } else { error = vm_get_seg_desc(vm, cpuid, seg, &desc); if (error) { printf("verify_gla: error %d getting segment" " descriptor %d", error, vie->segment_register); return (-1); } segbase = desc.base; } gla2 = segbase + base + vie->scale * idx + vie->displacement; gla2 &= size2mask[vie->addrsize]; if (gla != gla2) { printf("verify_gla mismatch: segbase(0x%0lx)" "base(0x%0lx), scale(%d), index(0x%0lx), " "disp(0x%0lx), gla(0x%0lx), gla2(0x%0lx)\n", segbase, base, vie->scale, idx, vie->displacement, gla, gla2); return (-1); } return (0); } int vie_decode_instruction(struct vie *vie, struct vm *vm, int cpuid, int cs_d) { enum vm_cpu_mode cpu_mode; if ((vie->status & VIES_INST_FETCH) == 0) { return (EINVAL); } cpu_mode = vie->paging.cpu_mode; if (decode_prefixes(vie, cpu_mode, cs_d)) return (-1); if (decode_opcode(vie)) return (-1); if (decode_modrm(vie, cpu_mode)) return (-1); if (decode_sib(vie)) return (-1); if (decode_displacement(vie)) return (-1); if (decode_immediate(vie)) return (-1); if (decode_moffset(vie)) return (-1); vie->status |= VIES_INST_DECODE; return (0); }