1 /*- 2 * SPDX-License-Identifier: BSD-2-Clause-FreeBSD 3 * 4 * Copyright (c) 2011 NetApp, Inc. 5 * All rights reserved. 6 * Copyright (c) 2018 Joyent, Inc. 7 * 8 * Redistribution and use in source and binary forms, with or without 9 * modification, are permitted provided that the following conditions 10 * are met: 11 * 1. Redistributions of source code must retain the above copyright 12 * notice, this list of conditions and the following disclaimer. 13 * 2. Redistributions in binary form must reproduce the above copyright 14 * notice, this list of conditions and the following disclaimer in the 15 * documentation and/or other materials provided with the distribution. 16 * 17 * THIS SOFTWARE IS PROVIDED BY NETAPP, INC ``AS IS'' AND 18 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 19 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 20 * ARE DISCLAIMED. IN NO EVENT SHALL NETAPP, INC OR CONTRIBUTORS BE LIABLE 21 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 22 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 23 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 24 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 25 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 26 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 27 * SUCH DAMAGE. 28 * 29 * $FreeBSD$ 30 */ 31 32 #include <sys/cdefs.h> 33 __FBSDID("$FreeBSD$"); 34 35 #include "opt_bhyve_snapshot.h" 36 37 #include <sys/param.h> 38 #include <sys/systm.h> 39 #include <sys/smp.h> 40 #include <sys/kernel.h> 41 #include <sys/malloc.h> 42 #include <sys/pcpu.h> 43 #include <sys/proc.h> 44 #include <sys/reg.h> 45 #include <sys/smr.h> 46 #include <sys/sysctl.h> 47 48 #include <vm/vm.h> 49 #include <vm/vm_extern.h> 50 #include <vm/pmap.h> 51 52 #include <machine/psl.h> 53 #include <machine/cpufunc.h> 54 #include <machine/md_var.h> 55 #include <machine/segments.h> 56 #include <machine/smp.h> 57 #include <machine/specialreg.h> 58 #include <machine/vmparam.h> 59 60 #include <machine/vmm.h> 61 #include <machine/vmm_dev.h> 62 #include <machine/vmm_instruction_emul.h> 63 #include <machine/vmm_snapshot.h> 64 65 #include "vmm_lapic.h" 66 #include "vmm_host.h" 67 #include "vmm_ioport.h" 68 #include "vmm_ktr.h" 69 #include "vmm_stat.h" 70 #include "vatpic.h" 71 #include "vlapic.h" 72 #include "vlapic_priv.h" 73 74 #include "ept.h" 75 #include "vmx_cpufunc.h" 76 #include "vmx.h" 77 #include "vmx_msr.h" 78 #include "x86.h" 79 #include "vmx_controls.h" 80 81 #define PINBASED_CTLS_ONE_SETTING \ 82 (PINBASED_EXTINT_EXITING | \ 83 PINBASED_NMI_EXITING | \ 84 PINBASED_VIRTUAL_NMI) 85 #define PINBASED_CTLS_ZERO_SETTING 0 86 87 #define PROCBASED_CTLS_WINDOW_SETTING \ 88 (PROCBASED_INT_WINDOW_EXITING | \ 89 PROCBASED_NMI_WINDOW_EXITING) 90 91 #define PROCBASED_CTLS_ONE_SETTING \ 92 (PROCBASED_SECONDARY_CONTROLS | \ 93 PROCBASED_MWAIT_EXITING | \ 94 PROCBASED_MONITOR_EXITING | \ 95 PROCBASED_IO_EXITING | \ 96 PROCBASED_MSR_BITMAPS | \ 97 PROCBASED_CTLS_WINDOW_SETTING | \ 98 PROCBASED_CR8_LOAD_EXITING | \ 99 PROCBASED_CR8_STORE_EXITING) 100 #define PROCBASED_CTLS_ZERO_SETTING \ 101 (PROCBASED_CR3_LOAD_EXITING | \ 102 PROCBASED_CR3_STORE_EXITING | \ 103 PROCBASED_IO_BITMAPS) 104 105 #define PROCBASED_CTLS2_ONE_SETTING PROCBASED2_ENABLE_EPT 106 #define PROCBASED_CTLS2_ZERO_SETTING 0 107 108 #define VM_EXIT_CTLS_ONE_SETTING \ 109 (VM_EXIT_SAVE_DEBUG_CONTROLS | \ 110 VM_EXIT_HOST_LMA | \ 111 VM_EXIT_SAVE_EFER | \ 112 VM_EXIT_LOAD_EFER | \ 113 VM_EXIT_ACKNOWLEDGE_INTERRUPT) 114 115 #define VM_EXIT_CTLS_ZERO_SETTING 0 116 117 #define VM_ENTRY_CTLS_ONE_SETTING \ 118 (VM_ENTRY_LOAD_DEBUG_CONTROLS | \ 119 VM_ENTRY_LOAD_EFER) 120 121 #define VM_ENTRY_CTLS_ZERO_SETTING \ 122 (VM_ENTRY_INTO_SMM | \ 123 VM_ENTRY_DEACTIVATE_DUAL_MONITOR) 124 125 #define HANDLED 1 126 #define UNHANDLED 0 127 128 static MALLOC_DEFINE(M_VMX, "vmx", "vmx"); 129 static MALLOC_DEFINE(M_VLAPIC, "vlapic", "vlapic"); 130 131 bool vmx_have_msr_tsc_aux; 132 133 SYSCTL_DECL(_hw_vmm); 134 SYSCTL_NODE(_hw_vmm, OID_AUTO, vmx, CTLFLAG_RW | CTLFLAG_MPSAFE, NULL, 135 NULL); 136 137 int vmxon_enabled[MAXCPU]; 138 static uint8_t *vmxon_region; 139 140 static uint32_t pinbased_ctls, procbased_ctls, procbased_ctls2; 141 static uint32_t exit_ctls, entry_ctls; 142 143 static uint64_t cr0_ones_mask, cr0_zeros_mask; 144 SYSCTL_ULONG(_hw_vmm_vmx, OID_AUTO, cr0_ones_mask, CTLFLAG_RD, 145 &cr0_ones_mask, 0, NULL); 146 SYSCTL_ULONG(_hw_vmm_vmx, OID_AUTO, cr0_zeros_mask, CTLFLAG_RD, 147 &cr0_zeros_mask, 0, NULL); 148 149 static uint64_t cr4_ones_mask, cr4_zeros_mask; 150 SYSCTL_ULONG(_hw_vmm_vmx, OID_AUTO, cr4_ones_mask, CTLFLAG_RD, 151 &cr4_ones_mask, 0, NULL); 152 SYSCTL_ULONG(_hw_vmm_vmx, OID_AUTO, cr4_zeros_mask, CTLFLAG_RD, 153 &cr4_zeros_mask, 0, NULL); 154 155 static int vmx_initialized; 156 SYSCTL_INT(_hw_vmm_vmx, OID_AUTO, initialized, CTLFLAG_RD, 157 &vmx_initialized, 0, "Intel VMX initialized"); 158 159 /* 160 * Optional capabilities 161 */ 162 static SYSCTL_NODE(_hw_vmm_vmx, OID_AUTO, cap, 163 CTLFLAG_RW | CTLFLAG_MPSAFE, NULL, 164 NULL); 165 166 static int cap_halt_exit; 167 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, halt_exit, CTLFLAG_RD, &cap_halt_exit, 0, 168 "HLT triggers a VM-exit"); 169 170 static int cap_pause_exit; 171 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, pause_exit, CTLFLAG_RD, &cap_pause_exit, 172 0, "PAUSE triggers a VM-exit"); 173 174 static int cap_wbinvd_exit; 175 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, wbinvd_exit, CTLFLAG_RD, &cap_wbinvd_exit, 176 0, "WBINVD triggers a VM-exit"); 177 178 static int cap_rdpid; 179 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, rdpid, CTLFLAG_RD, &cap_rdpid, 0, 180 "Guests are allowed to use RDPID"); 181 182 static int cap_rdtscp; 183 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, rdtscp, CTLFLAG_RD, &cap_rdtscp, 0, 184 "Guests are allowed to use RDTSCP"); 185 186 static int cap_unrestricted_guest; 187 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, unrestricted_guest, CTLFLAG_RD, 188 &cap_unrestricted_guest, 0, "Unrestricted guests"); 189 190 static int cap_monitor_trap; 191 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, monitor_trap, CTLFLAG_RD, 192 &cap_monitor_trap, 0, "Monitor trap flag"); 193 194 static int cap_invpcid; 195 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, invpcid, CTLFLAG_RD, &cap_invpcid, 196 0, "Guests are allowed to use INVPCID"); 197 198 static int tpr_shadowing; 199 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, tpr_shadowing, CTLFLAG_RD, 200 &tpr_shadowing, 0, "TPR shadowing support"); 201 202 static int virtual_interrupt_delivery; 203 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, virtual_interrupt_delivery, CTLFLAG_RD, 204 &virtual_interrupt_delivery, 0, "APICv virtual interrupt delivery support"); 205 206 static int posted_interrupts; 207 SYSCTL_INT(_hw_vmm_vmx_cap, OID_AUTO, posted_interrupts, CTLFLAG_RD, 208 &posted_interrupts, 0, "APICv posted interrupt support"); 209 210 static int pirvec = -1; 211 SYSCTL_INT(_hw_vmm_vmx, OID_AUTO, posted_interrupt_vector, CTLFLAG_RD, 212 &pirvec, 0, "APICv posted interrupt vector"); 213 214 static struct unrhdr *vpid_unr; 215 static u_int vpid_alloc_failed; 216 SYSCTL_UINT(_hw_vmm_vmx, OID_AUTO, vpid_alloc_failed, CTLFLAG_RD, 217 &vpid_alloc_failed, 0, NULL); 218 219 int guest_l1d_flush; 220 SYSCTL_INT(_hw_vmm_vmx, OID_AUTO, l1d_flush, CTLFLAG_RD, 221 &guest_l1d_flush, 0, NULL); 222 int guest_l1d_flush_sw; 223 SYSCTL_INT(_hw_vmm_vmx, OID_AUTO, l1d_flush_sw, CTLFLAG_RD, 224 &guest_l1d_flush_sw, 0, NULL); 225 226 static struct msr_entry msr_load_list[1] __aligned(16); 227 228 /* 229 * The definitions of SDT probes for VMX. 230 */ 231 232 SDT_PROBE_DEFINE3(vmm, vmx, exit, entry, 233 "struct vmx *", "int", "struct vm_exit *"); 234 235 SDT_PROBE_DEFINE4(vmm, vmx, exit, taskswitch, 236 "struct vmx *", "int", "struct vm_exit *", "struct vm_task_switch *"); 237 238 SDT_PROBE_DEFINE4(vmm, vmx, exit, craccess, 239 "struct vmx *", "int", "struct vm_exit *", "uint64_t"); 240 241 SDT_PROBE_DEFINE4(vmm, vmx, exit, rdmsr, 242 "struct vmx *", "int", "struct vm_exit *", "uint32_t"); 243 244 SDT_PROBE_DEFINE5(vmm, vmx, exit, wrmsr, 245 "struct vmx *", "int", "struct vm_exit *", "uint32_t", "uint64_t"); 246 247 SDT_PROBE_DEFINE3(vmm, vmx, exit, halt, 248 "struct vmx *", "int", "struct vm_exit *"); 249 250 SDT_PROBE_DEFINE3(vmm, vmx, exit, mtrap, 251 "struct vmx *", "int", "struct vm_exit *"); 252 253 SDT_PROBE_DEFINE3(vmm, vmx, exit, pause, 254 "struct vmx *", "int", "struct vm_exit *"); 255 256 SDT_PROBE_DEFINE3(vmm, vmx, exit, intrwindow, 257 "struct vmx *", "int", "struct vm_exit *"); 258 259 SDT_PROBE_DEFINE4(vmm, vmx, exit, interrupt, 260 "struct vmx *", "int", "struct vm_exit *", "uint32_t"); 261 262 SDT_PROBE_DEFINE3(vmm, vmx, exit, nmiwindow, 263 "struct vmx *", "int", "struct vm_exit *"); 264 265 SDT_PROBE_DEFINE3(vmm, vmx, exit, inout, 266 "struct vmx *", "int", "struct vm_exit *"); 267 268 SDT_PROBE_DEFINE3(vmm, vmx, exit, cpuid, 269 "struct vmx *", "int", "struct vm_exit *"); 270 271 SDT_PROBE_DEFINE5(vmm, vmx, exit, exception, 272 "struct vmx *", "int", "struct vm_exit *", "uint32_t", "int"); 273 274 SDT_PROBE_DEFINE5(vmm, vmx, exit, nestedfault, 275 "struct vmx *", "int", "struct vm_exit *", "uint64_t", "uint64_t"); 276 277 SDT_PROBE_DEFINE4(vmm, vmx, exit, mmiofault, 278 "struct vmx *", "int", "struct vm_exit *", "uint64_t"); 279 280 SDT_PROBE_DEFINE3(vmm, vmx, exit, eoi, 281 "struct vmx *", "int", "struct vm_exit *"); 282 283 SDT_PROBE_DEFINE3(vmm, vmx, exit, apicaccess, 284 "struct vmx *", "int", "struct vm_exit *"); 285 286 SDT_PROBE_DEFINE4(vmm, vmx, exit, apicwrite, 287 "struct vmx *", "int", "struct vm_exit *", "struct vlapic *"); 288 289 SDT_PROBE_DEFINE3(vmm, vmx, exit, xsetbv, 290 "struct vmx *", "int", "struct vm_exit *"); 291 292 SDT_PROBE_DEFINE3(vmm, vmx, exit, monitor, 293 "struct vmx *", "int", "struct vm_exit *"); 294 295 SDT_PROBE_DEFINE3(vmm, vmx, exit, mwait, 296 "struct vmx *", "int", "struct vm_exit *"); 297 298 SDT_PROBE_DEFINE3(vmm, vmx, exit, vminsn, 299 "struct vmx *", "int", "struct vm_exit *"); 300 301 SDT_PROBE_DEFINE4(vmm, vmx, exit, unknown, 302 "struct vmx *", "int", "struct vm_exit *", "uint32_t"); 303 304 SDT_PROBE_DEFINE4(vmm, vmx, exit, return, 305 "struct vmx *", "int", "struct vm_exit *", "int"); 306 307 /* 308 * Use the last page below 4GB as the APIC access address. This address is 309 * occupied by the boot firmware so it is guaranteed that it will not conflict 310 * with a page in system memory. 311 */ 312 #define APIC_ACCESS_ADDRESS 0xFFFFF000 313 314 static int vmx_getdesc(void *vcpui, int reg, struct seg_desc *desc); 315 static int vmx_getreg(void *vcpui, int reg, uint64_t *retval); 316 static int vmxctx_setreg(struct vmxctx *vmxctx, int reg, uint64_t val); 317 static void vmx_inject_pir(struct vlapic *vlapic); 318 #ifdef BHYVE_SNAPSHOT 319 static int vmx_restore_tsc(void *vcpui, uint64_t now); 320 #endif 321 322 static inline bool 323 host_has_rdpid(void) 324 { 325 return ((cpu_stdext_feature2 & CPUID_STDEXT2_RDPID) != 0); 326 } 327 328 static inline bool 329 host_has_rdtscp(void) 330 { 331 return ((amd_feature & AMDID_RDTSCP) != 0); 332 } 333 334 #ifdef KTR 335 static const char * 336 exit_reason_to_str(int reason) 337 { 338 static char reasonbuf[32]; 339 340 switch (reason) { 341 case EXIT_REASON_EXCEPTION: 342 return "exception"; 343 case EXIT_REASON_EXT_INTR: 344 return "extint"; 345 case EXIT_REASON_TRIPLE_FAULT: 346 return "triplefault"; 347 case EXIT_REASON_INIT: 348 return "init"; 349 case EXIT_REASON_SIPI: 350 return "sipi"; 351 case EXIT_REASON_IO_SMI: 352 return "iosmi"; 353 case EXIT_REASON_SMI: 354 return "smi"; 355 case EXIT_REASON_INTR_WINDOW: 356 return "intrwindow"; 357 case EXIT_REASON_NMI_WINDOW: 358 return "nmiwindow"; 359 case EXIT_REASON_TASK_SWITCH: 360 return "taskswitch"; 361 case EXIT_REASON_CPUID: 362 return "cpuid"; 363 case EXIT_REASON_GETSEC: 364 return "getsec"; 365 case EXIT_REASON_HLT: 366 return "hlt"; 367 case EXIT_REASON_INVD: 368 return "invd"; 369 case EXIT_REASON_INVLPG: 370 return "invlpg"; 371 case EXIT_REASON_RDPMC: 372 return "rdpmc"; 373 case EXIT_REASON_RDTSC: 374 return "rdtsc"; 375 case EXIT_REASON_RSM: 376 return "rsm"; 377 case EXIT_REASON_VMCALL: 378 return "vmcall"; 379 case EXIT_REASON_VMCLEAR: 380 return "vmclear"; 381 case EXIT_REASON_VMLAUNCH: 382 return "vmlaunch"; 383 case EXIT_REASON_VMPTRLD: 384 return "vmptrld"; 385 case EXIT_REASON_VMPTRST: 386 return "vmptrst"; 387 case EXIT_REASON_VMREAD: 388 return "vmread"; 389 case EXIT_REASON_VMRESUME: 390 return "vmresume"; 391 case EXIT_REASON_VMWRITE: 392 return "vmwrite"; 393 case EXIT_REASON_VMXOFF: 394 return "vmxoff"; 395 case EXIT_REASON_VMXON: 396 return "vmxon"; 397 case EXIT_REASON_CR_ACCESS: 398 return "craccess"; 399 case EXIT_REASON_DR_ACCESS: 400 return "draccess"; 401 case EXIT_REASON_INOUT: 402 return "inout"; 403 case EXIT_REASON_RDMSR: 404 return "rdmsr"; 405 case EXIT_REASON_WRMSR: 406 return "wrmsr"; 407 case EXIT_REASON_INVAL_VMCS: 408 return "invalvmcs"; 409 case EXIT_REASON_INVAL_MSR: 410 return "invalmsr"; 411 case EXIT_REASON_MWAIT: 412 return "mwait"; 413 case EXIT_REASON_MTF: 414 return "mtf"; 415 case EXIT_REASON_MONITOR: 416 return "monitor"; 417 case EXIT_REASON_PAUSE: 418 return "pause"; 419 case EXIT_REASON_MCE_DURING_ENTRY: 420 return "mce-during-entry"; 421 case EXIT_REASON_TPR: 422 return "tpr"; 423 case EXIT_REASON_APIC_ACCESS: 424 return "apic-access"; 425 case EXIT_REASON_GDTR_IDTR: 426 return "gdtridtr"; 427 case EXIT_REASON_LDTR_TR: 428 return "ldtrtr"; 429 case EXIT_REASON_EPT_FAULT: 430 return "eptfault"; 431 case EXIT_REASON_EPT_MISCONFIG: 432 return "eptmisconfig"; 433 case EXIT_REASON_INVEPT: 434 return "invept"; 435 case EXIT_REASON_RDTSCP: 436 return "rdtscp"; 437 case EXIT_REASON_VMX_PREEMPT: 438 return "vmxpreempt"; 439 case EXIT_REASON_INVVPID: 440 return "invvpid"; 441 case EXIT_REASON_WBINVD: 442 return "wbinvd"; 443 case EXIT_REASON_XSETBV: 444 return "xsetbv"; 445 case EXIT_REASON_APIC_WRITE: 446 return "apic-write"; 447 default: 448 snprintf(reasonbuf, sizeof(reasonbuf), "%d", reason); 449 return (reasonbuf); 450 } 451 } 452 #endif /* KTR */ 453 454 static int 455 vmx_allow_x2apic_msrs(struct vmx *vmx) 456 { 457 int i, error; 458 459 error = 0; 460 461 /* 462 * Allow readonly access to the following x2APIC MSRs from the guest. 463 */ 464 error += guest_msr_ro(vmx, MSR_APIC_ID); 465 error += guest_msr_ro(vmx, MSR_APIC_VERSION); 466 error += guest_msr_ro(vmx, MSR_APIC_LDR); 467 error += guest_msr_ro(vmx, MSR_APIC_SVR); 468 469 for (i = 0; i < 8; i++) 470 error += guest_msr_ro(vmx, MSR_APIC_ISR0 + i); 471 472 for (i = 0; i < 8; i++) 473 error += guest_msr_ro(vmx, MSR_APIC_TMR0 + i); 474 475 for (i = 0; i < 8; i++) 476 error += guest_msr_ro(vmx, MSR_APIC_IRR0 + i); 477 478 error += guest_msr_ro(vmx, MSR_APIC_ESR); 479 error += guest_msr_ro(vmx, MSR_APIC_LVT_TIMER); 480 error += guest_msr_ro(vmx, MSR_APIC_LVT_THERMAL); 481 error += guest_msr_ro(vmx, MSR_APIC_LVT_PCINT); 482 error += guest_msr_ro(vmx, MSR_APIC_LVT_LINT0); 483 error += guest_msr_ro(vmx, MSR_APIC_LVT_LINT1); 484 error += guest_msr_ro(vmx, MSR_APIC_LVT_ERROR); 485 error += guest_msr_ro(vmx, MSR_APIC_ICR_TIMER); 486 error += guest_msr_ro(vmx, MSR_APIC_DCR_TIMER); 487 error += guest_msr_ro(vmx, MSR_APIC_ICR); 488 489 /* 490 * Allow TPR, EOI and SELF_IPI MSRs to be read and written by the guest. 491 * 492 * These registers get special treatment described in the section 493 * "Virtualizing MSR-Based APIC Accesses". 494 */ 495 error += guest_msr_rw(vmx, MSR_APIC_TPR); 496 error += guest_msr_rw(vmx, MSR_APIC_EOI); 497 error += guest_msr_rw(vmx, MSR_APIC_SELF_IPI); 498 499 return (error); 500 } 501 502 u_long 503 vmx_fix_cr0(u_long cr0) 504 { 505 506 return ((cr0 | cr0_ones_mask) & ~cr0_zeros_mask); 507 } 508 509 u_long 510 vmx_fix_cr4(u_long cr4) 511 { 512 513 return ((cr4 | cr4_ones_mask) & ~cr4_zeros_mask); 514 } 515 516 static void 517 vpid_free(int vpid) 518 { 519 if (vpid < 0 || vpid > 0xffff) 520 panic("vpid_free: invalid vpid %d", vpid); 521 522 /* 523 * VPIDs [0,vm_maxcpu] are special and are not allocated from 524 * the unit number allocator. 525 */ 526 527 if (vpid > vm_maxcpu) 528 free_unr(vpid_unr, vpid); 529 } 530 531 static uint16_t 532 vpid_alloc(int vcpuid) 533 { 534 int x; 535 536 /* 537 * If the "enable vpid" execution control is not enabled then the 538 * VPID is required to be 0 for all vcpus. 539 */ 540 if ((procbased_ctls2 & PROCBASED2_ENABLE_VPID) == 0) 541 return (0); 542 543 /* 544 * Try to allocate a unique VPID for each from the unit number 545 * allocator. 546 */ 547 x = alloc_unr(vpid_unr); 548 549 if (x == -1) { 550 atomic_add_int(&vpid_alloc_failed, 1); 551 552 /* 553 * If the unit number allocator does not have enough unique 554 * VPIDs then we need to allocate from the [1,vm_maxcpu] range. 555 * 556 * These VPIDs are not be unique across VMs but this does not 557 * affect correctness because the combined mappings are also 558 * tagged with the EP4TA which is unique for each VM. 559 * 560 * It is still sub-optimal because the invvpid will invalidate 561 * combined mappings for a particular VPID across all EP4TAs. 562 */ 563 return (vcpuid + 1); 564 } 565 566 return (x); 567 } 568 569 static void 570 vpid_init(void) 571 { 572 /* 573 * VPID 0 is required when the "enable VPID" execution control is 574 * disabled. 575 * 576 * VPIDs [1,vm_maxcpu] are used as the "overflow namespace" when the 577 * unit number allocator does not have sufficient unique VPIDs to 578 * satisfy the allocation. 579 * 580 * The remaining VPIDs are managed by the unit number allocator. 581 */ 582 vpid_unr = new_unrhdr(vm_maxcpu + 1, 0xffff, NULL); 583 } 584 585 static void 586 vmx_disable(void *arg __unused) 587 { 588 struct invvpid_desc invvpid_desc = { 0 }; 589 struct invept_desc invept_desc = { 0 }; 590 591 if (vmxon_enabled[curcpu]) { 592 /* 593 * See sections 25.3.3.3 and 25.3.3.4 in Intel Vol 3b. 594 * 595 * VMXON or VMXOFF are not required to invalidate any TLB 596 * caching structures. This prevents potential retention of 597 * cached information in the TLB between distinct VMX episodes. 598 */ 599 invvpid(INVVPID_TYPE_ALL_CONTEXTS, invvpid_desc); 600 invept(INVEPT_TYPE_ALL_CONTEXTS, invept_desc); 601 vmxoff(); 602 } 603 load_cr4(rcr4() & ~CR4_VMXE); 604 } 605 606 static int 607 vmx_modcleanup(void) 608 { 609 610 if (pirvec >= 0) 611 lapic_ipi_free(pirvec); 612 613 if (vpid_unr != NULL) { 614 delete_unrhdr(vpid_unr); 615 vpid_unr = NULL; 616 } 617 618 if (nmi_flush_l1d_sw == 1) 619 nmi_flush_l1d_sw = 0; 620 621 smp_rendezvous(NULL, vmx_disable, NULL, NULL); 622 623 if (vmxon_region != NULL) 624 kmem_free(vmxon_region, (mp_maxid + 1) * PAGE_SIZE); 625 626 return (0); 627 } 628 629 static void 630 vmx_enable(void *arg __unused) 631 { 632 int error; 633 uint64_t feature_control; 634 635 feature_control = rdmsr(MSR_IA32_FEATURE_CONTROL); 636 if ((feature_control & IA32_FEATURE_CONTROL_LOCK) == 0 || 637 (feature_control & IA32_FEATURE_CONTROL_VMX_EN) == 0) { 638 wrmsr(MSR_IA32_FEATURE_CONTROL, 639 feature_control | IA32_FEATURE_CONTROL_VMX_EN | 640 IA32_FEATURE_CONTROL_LOCK); 641 } 642 643 load_cr4(rcr4() | CR4_VMXE); 644 645 *(uint32_t *)&vmxon_region[curcpu * PAGE_SIZE] = vmx_revision(); 646 error = vmxon(&vmxon_region[curcpu * PAGE_SIZE]); 647 if (error == 0) 648 vmxon_enabled[curcpu] = 1; 649 } 650 651 static void 652 vmx_modresume(void) 653 { 654 655 if (vmxon_enabled[curcpu]) 656 vmxon(&vmxon_region[curcpu * PAGE_SIZE]); 657 } 658 659 static int 660 vmx_modinit(int ipinum) 661 { 662 int error; 663 uint64_t basic, fixed0, fixed1, feature_control; 664 uint32_t tmp, procbased2_vid_bits; 665 666 /* CPUID.1:ECX[bit 5] must be 1 for processor to support VMX */ 667 if (!(cpu_feature2 & CPUID2_VMX)) { 668 printf("vmx_modinit: processor does not support VMX " 669 "operation\n"); 670 return (ENXIO); 671 } 672 673 /* 674 * Verify that MSR_IA32_FEATURE_CONTROL lock and VMXON enable bits 675 * are set (bits 0 and 2 respectively). 676 */ 677 feature_control = rdmsr(MSR_IA32_FEATURE_CONTROL); 678 if ((feature_control & IA32_FEATURE_CONTROL_LOCK) == 1 && 679 (feature_control & IA32_FEATURE_CONTROL_VMX_EN) == 0) { 680 printf("vmx_modinit: VMX operation disabled by BIOS\n"); 681 return (ENXIO); 682 } 683 684 /* 685 * Verify capabilities MSR_VMX_BASIC: 686 * - bit 54 indicates support for INS/OUTS decoding 687 */ 688 basic = rdmsr(MSR_VMX_BASIC); 689 if ((basic & (1UL << 54)) == 0) { 690 printf("vmx_modinit: processor does not support desired basic " 691 "capabilities\n"); 692 return (EINVAL); 693 } 694 695 /* Check support for primary processor-based VM-execution controls */ 696 error = vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS, 697 MSR_VMX_TRUE_PROCBASED_CTLS, 698 PROCBASED_CTLS_ONE_SETTING, 699 PROCBASED_CTLS_ZERO_SETTING, &procbased_ctls); 700 if (error) { 701 printf("vmx_modinit: processor does not support desired " 702 "primary processor-based controls\n"); 703 return (error); 704 } 705 706 /* Clear the processor-based ctl bits that are set on demand */ 707 procbased_ctls &= ~PROCBASED_CTLS_WINDOW_SETTING; 708 709 /* Check support for secondary processor-based VM-execution controls */ 710 error = vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS2, 711 MSR_VMX_PROCBASED_CTLS2, 712 PROCBASED_CTLS2_ONE_SETTING, 713 PROCBASED_CTLS2_ZERO_SETTING, &procbased_ctls2); 714 if (error) { 715 printf("vmx_modinit: processor does not support desired " 716 "secondary processor-based controls\n"); 717 return (error); 718 } 719 720 /* Check support for VPID */ 721 error = vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS2, MSR_VMX_PROCBASED_CTLS2, 722 PROCBASED2_ENABLE_VPID, 0, &tmp); 723 if (error == 0) 724 procbased_ctls2 |= PROCBASED2_ENABLE_VPID; 725 726 /* Check support for pin-based VM-execution controls */ 727 error = vmx_set_ctlreg(MSR_VMX_PINBASED_CTLS, 728 MSR_VMX_TRUE_PINBASED_CTLS, 729 PINBASED_CTLS_ONE_SETTING, 730 PINBASED_CTLS_ZERO_SETTING, &pinbased_ctls); 731 if (error) { 732 printf("vmx_modinit: processor does not support desired " 733 "pin-based controls\n"); 734 return (error); 735 } 736 737 /* Check support for VM-exit controls */ 738 error = vmx_set_ctlreg(MSR_VMX_EXIT_CTLS, MSR_VMX_TRUE_EXIT_CTLS, 739 VM_EXIT_CTLS_ONE_SETTING, 740 VM_EXIT_CTLS_ZERO_SETTING, 741 &exit_ctls); 742 if (error) { 743 printf("vmx_modinit: processor does not support desired " 744 "exit controls\n"); 745 return (error); 746 } 747 748 /* Check support for VM-entry controls */ 749 error = vmx_set_ctlreg(MSR_VMX_ENTRY_CTLS, MSR_VMX_TRUE_ENTRY_CTLS, 750 VM_ENTRY_CTLS_ONE_SETTING, VM_ENTRY_CTLS_ZERO_SETTING, 751 &entry_ctls); 752 if (error) { 753 printf("vmx_modinit: processor does not support desired " 754 "entry controls\n"); 755 return (error); 756 } 757 758 /* 759 * Check support for optional features by testing them 760 * as individual bits 761 */ 762 cap_halt_exit = (vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS, 763 MSR_VMX_TRUE_PROCBASED_CTLS, 764 PROCBASED_HLT_EXITING, 0, 765 &tmp) == 0); 766 767 cap_monitor_trap = (vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS, 768 MSR_VMX_PROCBASED_CTLS, 769 PROCBASED_MTF, 0, 770 &tmp) == 0); 771 772 cap_pause_exit = (vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS, 773 MSR_VMX_TRUE_PROCBASED_CTLS, 774 PROCBASED_PAUSE_EXITING, 0, 775 &tmp) == 0); 776 777 cap_wbinvd_exit = (vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS2, 778 MSR_VMX_PROCBASED_CTLS2, 779 PROCBASED2_WBINVD_EXITING, 780 0, 781 &tmp) == 0); 782 783 /* 784 * Check support for RDPID and/or RDTSCP. 785 * 786 * Support a pass-through-based implementation of these via the 787 * "enable RDTSCP" VM-execution control and the "RDTSC exiting" 788 * VM-execution control. 789 * 790 * The "enable RDTSCP" VM-execution control applies to both RDPID 791 * and RDTSCP (see SDM volume 3, section 25.3, "Changes to 792 * Instruction Behavior in VMX Non-root operation"); this is why 793 * only this VM-execution control needs to be enabled in order to 794 * enable passing through whichever of RDPID and/or RDTSCP are 795 * supported by the host. 796 * 797 * The "RDTSC exiting" VM-execution control applies to both RDTSC 798 * and RDTSCP (again, per SDM volume 3, section 25.3), and is 799 * already set up for RDTSC and RDTSCP pass-through by the current 800 * implementation of RDTSC. 801 * 802 * Although RDPID and RDTSCP are optional capabilities, since there 803 * does not currently seem to be a use case for enabling/disabling 804 * these via libvmmapi, choose not to support this and, instead, 805 * just statically always enable or always disable this support 806 * across all vCPUs on all VMs. (Note that there may be some 807 * complications to providing this functionality, e.g., the MSR 808 * bitmap is currently per-VM rather than per-vCPU while the 809 * capability API wants to be able to control capabilities on a 810 * per-vCPU basis). 811 */ 812 error = vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS2, 813 MSR_VMX_PROCBASED_CTLS2, 814 PROCBASED2_ENABLE_RDTSCP, 0, &tmp); 815 cap_rdpid = error == 0 && host_has_rdpid(); 816 cap_rdtscp = error == 0 && host_has_rdtscp(); 817 if (cap_rdpid || cap_rdtscp) { 818 procbased_ctls2 |= PROCBASED2_ENABLE_RDTSCP; 819 vmx_have_msr_tsc_aux = true; 820 } 821 822 cap_unrestricted_guest = (vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS2, 823 MSR_VMX_PROCBASED_CTLS2, 824 PROCBASED2_UNRESTRICTED_GUEST, 0, 825 &tmp) == 0); 826 827 cap_invpcid = (vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS2, 828 MSR_VMX_PROCBASED_CTLS2, PROCBASED2_ENABLE_INVPCID, 0, 829 &tmp) == 0); 830 831 /* 832 * Check support for TPR shadow. 833 */ 834 error = vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS, 835 MSR_VMX_TRUE_PROCBASED_CTLS, PROCBASED_USE_TPR_SHADOW, 0, 836 &tmp); 837 if (error == 0) { 838 tpr_shadowing = 1; 839 TUNABLE_INT_FETCH("hw.vmm.vmx.use_tpr_shadowing", 840 &tpr_shadowing); 841 } 842 843 if (tpr_shadowing) { 844 procbased_ctls |= PROCBASED_USE_TPR_SHADOW; 845 procbased_ctls &= ~PROCBASED_CR8_LOAD_EXITING; 846 procbased_ctls &= ~PROCBASED_CR8_STORE_EXITING; 847 } 848 849 /* 850 * Check support for virtual interrupt delivery. 851 */ 852 procbased2_vid_bits = (PROCBASED2_VIRTUALIZE_APIC_ACCESSES | 853 PROCBASED2_VIRTUALIZE_X2APIC_MODE | 854 PROCBASED2_APIC_REGISTER_VIRTUALIZATION | 855 PROCBASED2_VIRTUAL_INTERRUPT_DELIVERY); 856 857 error = vmx_set_ctlreg(MSR_VMX_PROCBASED_CTLS2, MSR_VMX_PROCBASED_CTLS2, 858 procbased2_vid_bits, 0, &tmp); 859 if (error == 0 && tpr_shadowing) { 860 virtual_interrupt_delivery = 1; 861 TUNABLE_INT_FETCH("hw.vmm.vmx.use_apic_vid", 862 &virtual_interrupt_delivery); 863 } 864 865 if (virtual_interrupt_delivery) { 866 procbased_ctls |= PROCBASED_USE_TPR_SHADOW; 867 procbased_ctls2 |= procbased2_vid_bits; 868 procbased_ctls2 &= ~PROCBASED2_VIRTUALIZE_X2APIC_MODE; 869 870 /* 871 * Check for Posted Interrupts only if Virtual Interrupt 872 * Delivery is enabled. 873 */ 874 error = vmx_set_ctlreg(MSR_VMX_PINBASED_CTLS, 875 MSR_VMX_TRUE_PINBASED_CTLS, PINBASED_POSTED_INTERRUPT, 0, 876 &tmp); 877 if (error == 0) { 878 pirvec = lapic_ipi_alloc(pti ? &IDTVEC(justreturn1_pti) : 879 &IDTVEC(justreturn)); 880 if (pirvec < 0) { 881 if (bootverbose) { 882 printf("vmx_modinit: unable to " 883 "allocate posted interrupt " 884 "vector\n"); 885 } 886 } else { 887 posted_interrupts = 1; 888 TUNABLE_INT_FETCH("hw.vmm.vmx.use_apic_pir", 889 &posted_interrupts); 890 } 891 } 892 } 893 894 if (posted_interrupts) 895 pinbased_ctls |= PINBASED_POSTED_INTERRUPT; 896 897 /* Initialize EPT */ 898 error = ept_init(ipinum); 899 if (error) { 900 printf("vmx_modinit: ept initialization failed (%d)\n", error); 901 return (error); 902 } 903 904 guest_l1d_flush = (cpu_ia32_arch_caps & 905 IA32_ARCH_CAP_SKIP_L1DFL_VMENTRY) == 0; 906 TUNABLE_INT_FETCH("hw.vmm.l1d_flush", &guest_l1d_flush); 907 908 /* 909 * L1D cache flush is enabled. Use IA32_FLUSH_CMD MSR when 910 * available. Otherwise fall back to the software flush 911 * method which loads enough data from the kernel text to 912 * flush existing L1D content, both on VMX entry and on NMI 913 * return. 914 */ 915 if (guest_l1d_flush) { 916 if ((cpu_stdext_feature3 & CPUID_STDEXT3_L1D_FLUSH) == 0) { 917 guest_l1d_flush_sw = 1; 918 TUNABLE_INT_FETCH("hw.vmm.l1d_flush_sw", 919 &guest_l1d_flush_sw); 920 } 921 if (guest_l1d_flush_sw) { 922 if (nmi_flush_l1d_sw <= 1) 923 nmi_flush_l1d_sw = 1; 924 } else { 925 msr_load_list[0].index = MSR_IA32_FLUSH_CMD; 926 msr_load_list[0].val = IA32_FLUSH_CMD_L1D; 927 } 928 } 929 930 /* 931 * Stash the cr0 and cr4 bits that must be fixed to 0 or 1 932 */ 933 fixed0 = rdmsr(MSR_VMX_CR0_FIXED0); 934 fixed1 = rdmsr(MSR_VMX_CR0_FIXED1); 935 cr0_ones_mask = fixed0 & fixed1; 936 cr0_zeros_mask = ~fixed0 & ~fixed1; 937 938 /* 939 * CR0_PE and CR0_PG can be set to zero in VMX non-root operation 940 * if unrestricted guest execution is allowed. 941 */ 942 if (cap_unrestricted_guest) 943 cr0_ones_mask &= ~(CR0_PG | CR0_PE); 944 945 /* 946 * Do not allow the guest to set CR0_NW or CR0_CD. 947 */ 948 cr0_zeros_mask |= (CR0_NW | CR0_CD); 949 950 fixed0 = rdmsr(MSR_VMX_CR4_FIXED0); 951 fixed1 = rdmsr(MSR_VMX_CR4_FIXED1); 952 cr4_ones_mask = fixed0 & fixed1; 953 cr4_zeros_mask = ~fixed0 & ~fixed1; 954 955 vpid_init(); 956 957 vmx_msr_init(); 958 959 /* enable VMX operation */ 960 vmxon_region = kmem_malloc((mp_maxid + 1) * PAGE_SIZE, 961 M_WAITOK | M_ZERO); 962 smp_rendezvous(NULL, vmx_enable, NULL, NULL); 963 964 vmx_initialized = 1; 965 966 return (0); 967 } 968 969 static void 970 vmx_trigger_hostintr(int vector) 971 { 972 uintptr_t func; 973 struct gate_descriptor *gd; 974 975 gd = &idt[vector]; 976 977 KASSERT(vector >= 32 && vector <= 255, ("vmx_trigger_hostintr: " 978 "invalid vector %d", vector)); 979 KASSERT(gd->gd_p == 1, ("gate descriptor for vector %d not present", 980 vector)); 981 KASSERT(gd->gd_type == SDT_SYSIGT, ("gate descriptor for vector %d " 982 "has invalid type %d", vector, gd->gd_type)); 983 KASSERT(gd->gd_dpl == SEL_KPL, ("gate descriptor for vector %d " 984 "has invalid dpl %d", vector, gd->gd_dpl)); 985 KASSERT(gd->gd_selector == GSEL(GCODE_SEL, SEL_KPL), ("gate descriptor " 986 "for vector %d has invalid selector %d", vector, gd->gd_selector)); 987 KASSERT(gd->gd_ist == 0, ("gate descriptor for vector %d has invalid " 988 "IST %d", vector, gd->gd_ist)); 989 990 func = ((long)gd->gd_hioffset << 16 | gd->gd_looffset); 991 vmx_call_isr(func); 992 } 993 994 static int 995 vmx_setup_cr_shadow(int which, struct vmcs *vmcs, uint32_t initial) 996 { 997 int error, mask_ident, shadow_ident; 998 uint64_t mask_value; 999 1000 if (which != 0 && which != 4) 1001 panic("vmx_setup_cr_shadow: unknown cr%d", which); 1002 1003 if (which == 0) { 1004 mask_ident = VMCS_CR0_MASK; 1005 mask_value = cr0_ones_mask | cr0_zeros_mask; 1006 shadow_ident = VMCS_CR0_SHADOW; 1007 } else { 1008 mask_ident = VMCS_CR4_MASK; 1009 mask_value = cr4_ones_mask | cr4_zeros_mask; 1010 shadow_ident = VMCS_CR4_SHADOW; 1011 } 1012 1013 error = vmcs_setreg(vmcs, 0, VMCS_IDENT(mask_ident), mask_value); 1014 if (error) 1015 return (error); 1016 1017 error = vmcs_setreg(vmcs, 0, VMCS_IDENT(shadow_ident), initial); 1018 if (error) 1019 return (error); 1020 1021 return (0); 1022 } 1023 #define vmx_setup_cr0_shadow(vmcs,init) vmx_setup_cr_shadow(0, (vmcs), (init)) 1024 #define vmx_setup_cr4_shadow(vmcs,init) vmx_setup_cr_shadow(4, (vmcs), (init)) 1025 1026 static void * 1027 vmx_init(struct vm *vm, pmap_t pmap) 1028 { 1029 int error __diagused; 1030 struct vmx *vmx; 1031 1032 vmx = malloc(sizeof(struct vmx), M_VMX, M_WAITOK | M_ZERO); 1033 vmx->vm = vm; 1034 1035 vmx->eptp = eptp(vtophys((vm_offset_t)pmap->pm_pmltop)); 1036 1037 /* 1038 * Clean up EPTP-tagged guest physical and combined mappings 1039 * 1040 * VMX transitions are not required to invalidate any guest physical 1041 * mappings. So, it may be possible for stale guest physical mappings 1042 * to be present in the processor TLBs. 1043 * 1044 * Combined mappings for this EP4TA are also invalidated for all VPIDs. 1045 */ 1046 ept_invalidate_mappings(vmx->eptp); 1047 1048 vmx->msr_bitmap = malloc_aligned(PAGE_SIZE, PAGE_SIZE, M_VMX, 1049 M_WAITOK | M_ZERO); 1050 msr_bitmap_initialize(vmx->msr_bitmap); 1051 1052 /* 1053 * It is safe to allow direct access to MSR_GSBASE and MSR_FSBASE. 1054 * The guest FSBASE and GSBASE are saved and restored during 1055 * vm-exit and vm-entry respectively. The host FSBASE and GSBASE are 1056 * always restored from the vmcs host state area on vm-exit. 1057 * 1058 * The SYSENTER_CS/ESP/EIP MSRs are identical to FS/GSBASE in 1059 * how they are saved/restored so can be directly accessed by the 1060 * guest. 1061 * 1062 * MSR_EFER is saved and restored in the guest VMCS area on a 1063 * VM exit and entry respectively. It is also restored from the 1064 * host VMCS area on a VM exit. 1065 * 1066 * The TSC MSR is exposed read-only. Writes are disallowed as 1067 * that will impact the host TSC. If the guest does a write 1068 * the "use TSC offsetting" execution control is enabled and the 1069 * difference between the host TSC and the guest TSC is written 1070 * into the TSC offset in the VMCS. 1071 * 1072 * Guest TSC_AUX support is enabled if any of guest RDPID and/or 1073 * guest RDTSCP support are enabled (since, as per Table 2-2 in SDM 1074 * volume 4, TSC_AUX is supported if any of RDPID and/or RDTSCP are 1075 * supported). If guest TSC_AUX support is enabled, TSC_AUX is 1076 * exposed read-only so that the VMM can do one fewer MSR read per 1077 * exit than if this register were exposed read-write; the guest 1078 * restore value can be updated during guest writes (expected to be 1079 * rare) instead of during all exits (common). 1080 */ 1081 if (guest_msr_rw(vmx, MSR_GSBASE) || 1082 guest_msr_rw(vmx, MSR_FSBASE) || 1083 guest_msr_rw(vmx, MSR_SYSENTER_CS_MSR) || 1084 guest_msr_rw(vmx, MSR_SYSENTER_ESP_MSR) || 1085 guest_msr_rw(vmx, MSR_SYSENTER_EIP_MSR) || 1086 guest_msr_rw(vmx, MSR_EFER) || 1087 guest_msr_ro(vmx, MSR_TSC) || 1088 ((cap_rdpid || cap_rdtscp) && guest_msr_ro(vmx, MSR_TSC_AUX))) 1089 panic("vmx_init: error setting guest msr access"); 1090 1091 if (virtual_interrupt_delivery) { 1092 error = vm_map_mmio(vm, DEFAULT_APIC_BASE, PAGE_SIZE, 1093 APIC_ACCESS_ADDRESS); 1094 /* XXX this should really return an error to the caller */ 1095 KASSERT(error == 0, ("vm_map_mmio(apicbase) error %d", error)); 1096 } 1097 1098 vmx->pmap = pmap; 1099 return (vmx); 1100 } 1101 1102 static void * 1103 vmx_vcpu_init(void *vmi, struct vcpu *vcpu1, int vcpuid) 1104 { 1105 struct vmx *vmx = vmi; 1106 struct vmcs *vmcs; 1107 struct vmx_vcpu *vcpu; 1108 uint32_t exc_bitmap; 1109 uint16_t vpid; 1110 int error; 1111 1112 vpid = vpid_alloc(vcpuid); 1113 1114 vcpu = malloc(sizeof(*vcpu), M_VMX, M_WAITOK | M_ZERO); 1115 vcpu->vmx = vmx; 1116 vcpu->vcpu = vcpu1; 1117 vcpu->vcpuid = vcpuid; 1118 vcpu->vmcs = malloc_aligned(sizeof(*vmcs), PAGE_SIZE, M_VMX, 1119 M_WAITOK | M_ZERO); 1120 vcpu->apic_page = malloc_aligned(PAGE_SIZE, PAGE_SIZE, M_VMX, 1121 M_WAITOK | M_ZERO); 1122 vcpu->pir_desc = malloc_aligned(sizeof(*vcpu->pir_desc), 64, M_VMX, 1123 M_WAITOK | M_ZERO); 1124 1125 vmcs = vcpu->vmcs; 1126 vmcs->identifier = vmx_revision(); 1127 error = vmclear(vmcs); 1128 if (error != 0) { 1129 panic("vmx_init: vmclear error %d on vcpu %d\n", 1130 error, vcpuid); 1131 } 1132 1133 vmx_msr_guest_init(vmx, vcpu); 1134 1135 error = vmcs_init(vmcs); 1136 KASSERT(error == 0, ("vmcs_init error %d", error)); 1137 1138 VMPTRLD(vmcs); 1139 error = 0; 1140 error += vmwrite(VMCS_HOST_RSP, (u_long)&vcpu->ctx); 1141 error += vmwrite(VMCS_EPTP, vmx->eptp); 1142 error += vmwrite(VMCS_PIN_BASED_CTLS, pinbased_ctls); 1143 error += vmwrite(VMCS_PRI_PROC_BASED_CTLS, procbased_ctls); 1144 if (vcpu_trap_wbinvd(vcpu->vcpu)) { 1145 KASSERT(cap_wbinvd_exit, ("WBINVD trap not available")); 1146 procbased_ctls2 |= PROCBASED2_WBINVD_EXITING; 1147 } 1148 error += vmwrite(VMCS_SEC_PROC_BASED_CTLS, procbased_ctls2); 1149 error += vmwrite(VMCS_EXIT_CTLS, exit_ctls); 1150 error += vmwrite(VMCS_ENTRY_CTLS, entry_ctls); 1151 error += vmwrite(VMCS_MSR_BITMAP, vtophys(vmx->msr_bitmap)); 1152 error += vmwrite(VMCS_VPID, vpid); 1153 1154 if (guest_l1d_flush && !guest_l1d_flush_sw) { 1155 vmcs_write(VMCS_ENTRY_MSR_LOAD, pmap_kextract( 1156 (vm_offset_t)&msr_load_list[0])); 1157 vmcs_write(VMCS_ENTRY_MSR_LOAD_COUNT, 1158 nitems(msr_load_list)); 1159 vmcs_write(VMCS_EXIT_MSR_STORE, 0); 1160 vmcs_write(VMCS_EXIT_MSR_STORE_COUNT, 0); 1161 } 1162 1163 /* exception bitmap */ 1164 if (vcpu_trace_exceptions(vcpu->vcpu)) 1165 exc_bitmap = 0xffffffff; 1166 else 1167 exc_bitmap = 1 << IDT_MC; 1168 error += vmwrite(VMCS_EXCEPTION_BITMAP, exc_bitmap); 1169 1170 vcpu->ctx.guest_dr6 = DBREG_DR6_RESERVED1; 1171 error += vmwrite(VMCS_GUEST_DR7, DBREG_DR7_RESERVED1); 1172 1173 if (tpr_shadowing) { 1174 error += vmwrite(VMCS_VIRTUAL_APIC, vtophys(vcpu->apic_page)); 1175 } 1176 1177 if (virtual_interrupt_delivery) { 1178 error += vmwrite(VMCS_APIC_ACCESS, APIC_ACCESS_ADDRESS); 1179 error += vmwrite(VMCS_EOI_EXIT0, 0); 1180 error += vmwrite(VMCS_EOI_EXIT1, 0); 1181 error += vmwrite(VMCS_EOI_EXIT2, 0); 1182 error += vmwrite(VMCS_EOI_EXIT3, 0); 1183 } 1184 if (posted_interrupts) { 1185 error += vmwrite(VMCS_PIR_VECTOR, pirvec); 1186 error += vmwrite(VMCS_PIR_DESC, vtophys(vcpu->pir_desc)); 1187 } 1188 VMCLEAR(vmcs); 1189 KASSERT(error == 0, ("vmx_init: error customizing the vmcs")); 1190 1191 vcpu->cap.set = 0; 1192 vcpu->cap.set |= cap_rdpid != 0 ? 1 << VM_CAP_RDPID : 0; 1193 vcpu->cap.set |= cap_rdtscp != 0 ? 1 << VM_CAP_RDTSCP : 0; 1194 vcpu->cap.proc_ctls = procbased_ctls; 1195 vcpu->cap.proc_ctls2 = procbased_ctls2; 1196 vcpu->cap.exc_bitmap = exc_bitmap; 1197 1198 vcpu->state.nextrip = ~0; 1199 vcpu->state.lastcpu = NOCPU; 1200 vcpu->state.vpid = vpid; 1201 1202 /* 1203 * Set up the CR0/4 shadows, and init the read shadow 1204 * to the power-on register value from the Intel Sys Arch. 1205 * CR0 - 0x60000010 1206 * CR4 - 0 1207 */ 1208 error = vmx_setup_cr0_shadow(vmcs, 0x60000010); 1209 if (error != 0) 1210 panic("vmx_setup_cr0_shadow %d", error); 1211 1212 error = vmx_setup_cr4_shadow(vmcs, 0); 1213 if (error != 0) 1214 panic("vmx_setup_cr4_shadow %d", error); 1215 1216 vcpu->ctx.pmap = vmx->pmap; 1217 1218 return (vcpu); 1219 } 1220 1221 static int 1222 vmx_handle_cpuid(struct vmx_vcpu *vcpu, struct vmxctx *vmxctx) 1223 { 1224 int handled; 1225 1226 handled = x86_emulate_cpuid(vcpu->vcpu, (uint64_t *)&vmxctx->guest_rax, 1227 (uint64_t *)&vmxctx->guest_rbx, (uint64_t *)&vmxctx->guest_rcx, 1228 (uint64_t *)&vmxctx->guest_rdx); 1229 return (handled); 1230 } 1231 1232 static __inline void 1233 vmx_run_trace(struct vmx_vcpu *vcpu) 1234 { 1235 VMX_CTR1(vcpu, "Resume execution at %#lx", vmcs_guest_rip()); 1236 } 1237 1238 static __inline void 1239 vmx_exit_trace(struct vmx_vcpu *vcpu, uint64_t rip, uint32_t exit_reason, 1240 int handled) 1241 { 1242 VMX_CTR3(vcpu, "%s %s vmexit at 0x%0lx", 1243 handled ? "handled" : "unhandled", 1244 exit_reason_to_str(exit_reason), rip); 1245 } 1246 1247 static __inline void 1248 vmx_astpending_trace(struct vmx_vcpu *vcpu, uint64_t rip) 1249 { 1250 VMX_CTR1(vcpu, "astpending vmexit at 0x%0lx", rip); 1251 } 1252 1253 static VMM_STAT_INTEL(VCPU_INVVPID_SAVED, "Number of vpid invalidations saved"); 1254 static VMM_STAT_INTEL(VCPU_INVVPID_DONE, "Number of vpid invalidations done"); 1255 1256 /* 1257 * Invalidate guest mappings identified by its vpid from the TLB. 1258 */ 1259 static __inline void 1260 vmx_invvpid(struct vmx *vmx, struct vmx_vcpu *vcpu, pmap_t pmap, int running) 1261 { 1262 struct vmxstate *vmxstate; 1263 struct invvpid_desc invvpid_desc; 1264 1265 vmxstate = &vcpu->state; 1266 if (vmxstate->vpid == 0) 1267 return; 1268 1269 if (!running) { 1270 /* 1271 * Set the 'lastcpu' to an invalid host cpu. 1272 * 1273 * This will invalidate TLB entries tagged with the vcpu's 1274 * vpid the next time it runs via vmx_set_pcpu_defaults(). 1275 */ 1276 vmxstate->lastcpu = NOCPU; 1277 return; 1278 } 1279 1280 KASSERT(curthread->td_critnest > 0, ("%s: vcpu %d running outside " 1281 "critical section", __func__, vcpu->vcpuid)); 1282 1283 /* 1284 * Invalidate all mappings tagged with 'vpid' 1285 * 1286 * We do this because this vcpu was executing on a different host 1287 * cpu when it last ran. We do not track whether it invalidated 1288 * mappings associated with its 'vpid' during that run. So we must 1289 * assume that the mappings associated with 'vpid' on 'curcpu' are 1290 * stale and invalidate them. 1291 * 1292 * Note that we incur this penalty only when the scheduler chooses to 1293 * move the thread associated with this vcpu between host cpus. 1294 * 1295 * Note also that this will invalidate mappings tagged with 'vpid' 1296 * for "all" EP4TAs. 1297 */ 1298 if (atomic_load_long(&pmap->pm_eptgen) == vmx->eptgen[curcpu]) { 1299 invvpid_desc._res1 = 0; 1300 invvpid_desc._res2 = 0; 1301 invvpid_desc.vpid = vmxstate->vpid; 1302 invvpid_desc.linear_addr = 0; 1303 invvpid(INVVPID_TYPE_SINGLE_CONTEXT, invvpid_desc); 1304 vmm_stat_incr(vcpu->vcpu, VCPU_INVVPID_DONE, 1); 1305 } else { 1306 /* 1307 * The invvpid can be skipped if an invept is going to 1308 * be performed before entering the guest. The invept 1309 * will invalidate combined mappings tagged with 1310 * 'vmx->eptp' for all vpids. 1311 */ 1312 vmm_stat_incr(vcpu->vcpu, VCPU_INVVPID_SAVED, 1); 1313 } 1314 } 1315 1316 static void 1317 vmx_set_pcpu_defaults(struct vmx *vmx, struct vmx_vcpu *vcpu, pmap_t pmap) 1318 { 1319 struct vmxstate *vmxstate; 1320 1321 vmxstate = &vcpu->state; 1322 if (vmxstate->lastcpu == curcpu) 1323 return; 1324 1325 vmxstate->lastcpu = curcpu; 1326 1327 vmm_stat_incr(vcpu->vcpu, VCPU_MIGRATIONS, 1); 1328 1329 vmcs_write(VMCS_HOST_TR_BASE, vmm_get_host_trbase()); 1330 vmcs_write(VMCS_HOST_GDTR_BASE, vmm_get_host_gdtrbase()); 1331 vmcs_write(VMCS_HOST_GS_BASE, vmm_get_host_gsbase()); 1332 vmx_invvpid(vmx, vcpu, pmap, 1); 1333 } 1334 1335 /* 1336 * We depend on 'procbased_ctls' to have the Interrupt Window Exiting bit set. 1337 */ 1338 CTASSERT((PROCBASED_CTLS_ONE_SETTING & PROCBASED_INT_WINDOW_EXITING) != 0); 1339 1340 static void __inline 1341 vmx_set_int_window_exiting(struct vmx_vcpu *vcpu) 1342 { 1343 1344 if ((vcpu->cap.proc_ctls & PROCBASED_INT_WINDOW_EXITING) == 0) { 1345 vcpu->cap.proc_ctls |= PROCBASED_INT_WINDOW_EXITING; 1346 vmcs_write(VMCS_PRI_PROC_BASED_CTLS, vcpu->cap.proc_ctls); 1347 VMX_CTR0(vcpu, "Enabling interrupt window exiting"); 1348 } 1349 } 1350 1351 static void __inline 1352 vmx_clear_int_window_exiting(struct vmx_vcpu *vcpu) 1353 { 1354 1355 KASSERT((vcpu->cap.proc_ctls & PROCBASED_INT_WINDOW_EXITING) != 0, 1356 ("intr_window_exiting not set: %#x", vcpu->cap.proc_ctls)); 1357 vcpu->cap.proc_ctls &= ~PROCBASED_INT_WINDOW_EXITING; 1358 vmcs_write(VMCS_PRI_PROC_BASED_CTLS, vcpu->cap.proc_ctls); 1359 VMX_CTR0(vcpu, "Disabling interrupt window exiting"); 1360 } 1361 1362 static void __inline 1363 vmx_set_nmi_window_exiting(struct vmx_vcpu *vcpu) 1364 { 1365 1366 if ((vcpu->cap.proc_ctls & PROCBASED_NMI_WINDOW_EXITING) == 0) { 1367 vcpu->cap.proc_ctls |= PROCBASED_NMI_WINDOW_EXITING; 1368 vmcs_write(VMCS_PRI_PROC_BASED_CTLS, vcpu->cap.proc_ctls); 1369 VMX_CTR0(vcpu, "Enabling NMI window exiting"); 1370 } 1371 } 1372 1373 static void __inline 1374 vmx_clear_nmi_window_exiting(struct vmx_vcpu *vcpu) 1375 { 1376 1377 KASSERT((vcpu->cap.proc_ctls & PROCBASED_NMI_WINDOW_EXITING) != 0, 1378 ("nmi_window_exiting not set %#x", vcpu->cap.proc_ctls)); 1379 vcpu->cap.proc_ctls &= ~PROCBASED_NMI_WINDOW_EXITING; 1380 vmcs_write(VMCS_PRI_PROC_BASED_CTLS, vcpu->cap.proc_ctls); 1381 VMX_CTR0(vcpu, "Disabling NMI window exiting"); 1382 } 1383 1384 int 1385 vmx_set_tsc_offset(struct vmx_vcpu *vcpu, uint64_t offset) 1386 { 1387 int error; 1388 1389 if ((vcpu->cap.proc_ctls & PROCBASED_TSC_OFFSET) == 0) { 1390 vcpu->cap.proc_ctls |= PROCBASED_TSC_OFFSET; 1391 vmcs_write(VMCS_PRI_PROC_BASED_CTLS, vcpu->cap.proc_ctls); 1392 VMX_CTR0(vcpu, "Enabling TSC offsetting"); 1393 } 1394 1395 error = vmwrite(VMCS_TSC_OFFSET, offset); 1396 #ifdef BHYVE_SNAPSHOT 1397 if (error == 0) 1398 vm_set_tsc_offset(vcpu->vcpu, offset); 1399 #endif 1400 return (error); 1401 } 1402 1403 #define NMI_BLOCKING (VMCS_INTERRUPTIBILITY_NMI_BLOCKING | \ 1404 VMCS_INTERRUPTIBILITY_MOVSS_BLOCKING) 1405 #define HWINTR_BLOCKING (VMCS_INTERRUPTIBILITY_STI_BLOCKING | \ 1406 VMCS_INTERRUPTIBILITY_MOVSS_BLOCKING) 1407 1408 static void 1409 vmx_inject_nmi(struct vmx_vcpu *vcpu) 1410 { 1411 uint32_t gi __diagused, info; 1412 1413 gi = vmcs_read(VMCS_GUEST_INTERRUPTIBILITY); 1414 KASSERT((gi & NMI_BLOCKING) == 0, ("vmx_inject_nmi: invalid guest " 1415 "interruptibility-state %#x", gi)); 1416 1417 info = vmcs_read(VMCS_ENTRY_INTR_INFO); 1418 KASSERT((info & VMCS_INTR_VALID) == 0, ("vmx_inject_nmi: invalid " 1419 "VM-entry interruption information %#x", info)); 1420 1421 /* 1422 * Inject the virtual NMI. The vector must be the NMI IDT entry 1423 * or the VMCS entry check will fail. 1424 */ 1425 info = IDT_NMI | VMCS_INTR_T_NMI | VMCS_INTR_VALID; 1426 vmcs_write(VMCS_ENTRY_INTR_INFO, info); 1427 1428 VMX_CTR0(vcpu, "Injecting vNMI"); 1429 1430 /* Clear the request */ 1431 vm_nmi_clear(vcpu->vcpu); 1432 } 1433 1434 static void 1435 vmx_inject_interrupts(struct vmx_vcpu *vcpu, struct vlapic *vlapic, 1436 uint64_t guestrip) 1437 { 1438 int vector, need_nmi_exiting, extint_pending; 1439 uint64_t rflags, entryinfo; 1440 uint32_t gi, info; 1441 1442 if (vcpu->cap.set & (1 << VM_CAP_MASK_HWINTR)) { 1443 return; 1444 } 1445 1446 if (vcpu->state.nextrip != guestrip) { 1447 gi = vmcs_read(VMCS_GUEST_INTERRUPTIBILITY); 1448 if (gi & HWINTR_BLOCKING) { 1449 VMX_CTR2(vcpu, "Guest interrupt blocking " 1450 "cleared due to rip change: %#lx/%#lx", 1451 vcpu->state.nextrip, guestrip); 1452 gi &= ~HWINTR_BLOCKING; 1453 vmcs_write(VMCS_GUEST_INTERRUPTIBILITY, gi); 1454 } 1455 } 1456 1457 if (vm_entry_intinfo(vcpu->vcpu, &entryinfo)) { 1458 KASSERT((entryinfo & VMCS_INTR_VALID) != 0, ("%s: entry " 1459 "intinfo is not valid: %#lx", __func__, entryinfo)); 1460 1461 info = vmcs_read(VMCS_ENTRY_INTR_INFO); 1462 KASSERT((info & VMCS_INTR_VALID) == 0, ("%s: cannot inject " 1463 "pending exception: %#lx/%#x", __func__, entryinfo, info)); 1464 1465 info = entryinfo; 1466 vector = info & 0xff; 1467 if (vector == IDT_BP || vector == IDT_OF) { 1468 /* 1469 * VT-x requires #BP and #OF to be injected as software 1470 * exceptions. 1471 */ 1472 info &= ~VMCS_INTR_T_MASK; 1473 info |= VMCS_INTR_T_SWEXCEPTION; 1474 } 1475 1476 if (info & VMCS_INTR_DEL_ERRCODE) 1477 vmcs_write(VMCS_ENTRY_EXCEPTION_ERROR, entryinfo >> 32); 1478 1479 vmcs_write(VMCS_ENTRY_INTR_INFO, info); 1480 } 1481 1482 if (vm_nmi_pending(vcpu->vcpu)) { 1483 /* 1484 * If there are no conditions blocking NMI injection then 1485 * inject it directly here otherwise enable "NMI window 1486 * exiting" to inject it as soon as we can. 1487 * 1488 * We also check for STI_BLOCKING because some implementations 1489 * don't allow NMI injection in this case. If we are running 1490 * on a processor that doesn't have this restriction it will 1491 * immediately exit and the NMI will be injected in the 1492 * "NMI window exiting" handler. 1493 */ 1494 need_nmi_exiting = 1; 1495 gi = vmcs_read(VMCS_GUEST_INTERRUPTIBILITY); 1496 if ((gi & (HWINTR_BLOCKING | NMI_BLOCKING)) == 0) { 1497 info = vmcs_read(VMCS_ENTRY_INTR_INFO); 1498 if ((info & VMCS_INTR_VALID) == 0) { 1499 vmx_inject_nmi(vcpu); 1500 need_nmi_exiting = 0; 1501 } else { 1502 VMX_CTR1(vcpu, "Cannot inject NMI " 1503 "due to VM-entry intr info %#x", info); 1504 } 1505 } else { 1506 VMX_CTR1(vcpu, "Cannot inject NMI due to " 1507 "Guest Interruptibility-state %#x", gi); 1508 } 1509 1510 if (need_nmi_exiting) 1511 vmx_set_nmi_window_exiting(vcpu); 1512 } 1513 1514 extint_pending = vm_extint_pending(vcpu->vcpu); 1515 1516 if (!extint_pending && virtual_interrupt_delivery) { 1517 vmx_inject_pir(vlapic); 1518 return; 1519 } 1520 1521 /* 1522 * If interrupt-window exiting is already in effect then don't bother 1523 * checking for pending interrupts. This is just an optimization and 1524 * not needed for correctness. 1525 */ 1526 if ((vcpu->cap.proc_ctls & PROCBASED_INT_WINDOW_EXITING) != 0) { 1527 VMX_CTR0(vcpu, "Skip interrupt injection due to " 1528 "pending int_window_exiting"); 1529 return; 1530 } 1531 1532 if (!extint_pending) { 1533 /* Ask the local apic for a vector to inject */ 1534 if (!vlapic_pending_intr(vlapic, &vector)) 1535 return; 1536 1537 /* 1538 * From the Intel SDM, Volume 3, Section "Maskable 1539 * Hardware Interrupts": 1540 * - maskable interrupt vectors [16,255] can be delivered 1541 * through the local APIC. 1542 */ 1543 KASSERT(vector >= 16 && vector <= 255, 1544 ("invalid vector %d from local APIC", vector)); 1545 } else { 1546 /* Ask the legacy pic for a vector to inject */ 1547 vatpic_pending_intr(vcpu->vmx->vm, &vector); 1548 1549 /* 1550 * From the Intel SDM, Volume 3, Section "Maskable 1551 * Hardware Interrupts": 1552 * - maskable interrupt vectors [0,255] can be delivered 1553 * through the INTR pin. 1554 */ 1555 KASSERT(vector >= 0 && vector <= 255, 1556 ("invalid vector %d from INTR", vector)); 1557 } 1558 1559 /* Check RFLAGS.IF and the interruptibility state of the guest */ 1560 rflags = vmcs_read(VMCS_GUEST_RFLAGS); 1561 if ((rflags & PSL_I) == 0) { 1562 VMX_CTR2(vcpu, "Cannot inject vector %d due to " 1563 "rflags %#lx", vector, rflags); 1564 goto cantinject; 1565 } 1566 1567 gi = vmcs_read(VMCS_GUEST_INTERRUPTIBILITY); 1568 if (gi & HWINTR_BLOCKING) { 1569 VMX_CTR2(vcpu, "Cannot inject vector %d due to " 1570 "Guest Interruptibility-state %#x", vector, gi); 1571 goto cantinject; 1572 } 1573 1574 info = vmcs_read(VMCS_ENTRY_INTR_INFO); 1575 if (info & VMCS_INTR_VALID) { 1576 /* 1577 * This is expected and could happen for multiple reasons: 1578 * - A vectoring VM-entry was aborted due to astpending 1579 * - A VM-exit happened during event injection. 1580 * - An exception was injected above. 1581 * - An NMI was injected above or after "NMI window exiting" 1582 */ 1583 VMX_CTR2(vcpu, "Cannot inject vector %d due to " 1584 "VM-entry intr info %#x", vector, info); 1585 goto cantinject; 1586 } 1587 1588 /* Inject the interrupt */ 1589 info = VMCS_INTR_T_HWINTR | VMCS_INTR_VALID; 1590 info |= vector; 1591 vmcs_write(VMCS_ENTRY_INTR_INFO, info); 1592 1593 if (!extint_pending) { 1594 /* Update the Local APIC ISR */ 1595 vlapic_intr_accepted(vlapic, vector); 1596 } else { 1597 vm_extint_clear(vcpu->vcpu); 1598 vatpic_intr_accepted(vcpu->vmx->vm, vector); 1599 1600 /* 1601 * After we accepted the current ExtINT the PIC may 1602 * have posted another one. If that is the case, set 1603 * the Interrupt Window Exiting execution control so 1604 * we can inject that one too. 1605 * 1606 * Also, interrupt window exiting allows us to inject any 1607 * pending APIC vector that was preempted by the ExtINT 1608 * as soon as possible. This applies both for the software 1609 * emulated vlapic and the hardware assisted virtual APIC. 1610 */ 1611 vmx_set_int_window_exiting(vcpu); 1612 } 1613 1614 VMX_CTR1(vcpu, "Injecting hwintr at vector %d", vector); 1615 1616 return; 1617 1618 cantinject: 1619 /* 1620 * Set the Interrupt Window Exiting execution control so we can inject 1621 * the interrupt as soon as blocking condition goes away. 1622 */ 1623 vmx_set_int_window_exiting(vcpu); 1624 } 1625 1626 /* 1627 * If the Virtual NMIs execution control is '1' then the logical processor 1628 * tracks virtual-NMI blocking in the Guest Interruptibility-state field of 1629 * the VMCS. An IRET instruction in VMX non-root operation will remove any 1630 * virtual-NMI blocking. 1631 * 1632 * This unblocking occurs even if the IRET causes a fault. In this case the 1633 * hypervisor needs to restore virtual-NMI blocking before resuming the guest. 1634 */ 1635 static void 1636 vmx_restore_nmi_blocking(struct vmx_vcpu *vcpu) 1637 { 1638 uint32_t gi; 1639 1640 VMX_CTR0(vcpu, "Restore Virtual-NMI blocking"); 1641 gi = vmcs_read(VMCS_GUEST_INTERRUPTIBILITY); 1642 gi |= VMCS_INTERRUPTIBILITY_NMI_BLOCKING; 1643 vmcs_write(VMCS_GUEST_INTERRUPTIBILITY, gi); 1644 } 1645 1646 static void 1647 vmx_clear_nmi_blocking(struct vmx_vcpu *vcpu) 1648 { 1649 uint32_t gi; 1650 1651 VMX_CTR0(vcpu, "Clear Virtual-NMI blocking"); 1652 gi = vmcs_read(VMCS_GUEST_INTERRUPTIBILITY); 1653 gi &= ~VMCS_INTERRUPTIBILITY_NMI_BLOCKING; 1654 vmcs_write(VMCS_GUEST_INTERRUPTIBILITY, gi); 1655 } 1656 1657 static void 1658 vmx_assert_nmi_blocking(struct vmx_vcpu *vcpu) 1659 { 1660 uint32_t gi __diagused; 1661 1662 gi = vmcs_read(VMCS_GUEST_INTERRUPTIBILITY); 1663 KASSERT(gi & VMCS_INTERRUPTIBILITY_NMI_BLOCKING, 1664 ("NMI blocking is not in effect %#x", gi)); 1665 } 1666 1667 static int 1668 vmx_emulate_xsetbv(struct vmx *vmx, struct vmx_vcpu *vcpu, 1669 struct vm_exit *vmexit) 1670 { 1671 struct vmxctx *vmxctx; 1672 uint64_t xcrval; 1673 const struct xsave_limits *limits; 1674 1675 vmxctx = &vcpu->ctx; 1676 limits = vmm_get_xsave_limits(); 1677 1678 /* 1679 * Note that the processor raises a GP# fault on its own if 1680 * xsetbv is executed for CPL != 0, so we do not have to 1681 * emulate that fault here. 1682 */ 1683 1684 /* Only xcr0 is supported. */ 1685 if (vmxctx->guest_rcx != 0) { 1686 vm_inject_gp(vcpu->vcpu); 1687 return (HANDLED); 1688 } 1689 1690 /* We only handle xcr0 if both the host and guest have XSAVE enabled. */ 1691 if (!limits->xsave_enabled || !(vmcs_read(VMCS_GUEST_CR4) & CR4_XSAVE)) { 1692 vm_inject_ud(vcpu->vcpu); 1693 return (HANDLED); 1694 } 1695 1696 xcrval = vmxctx->guest_rdx << 32 | (vmxctx->guest_rax & 0xffffffff); 1697 if ((xcrval & ~limits->xcr0_allowed) != 0) { 1698 vm_inject_gp(vcpu->vcpu); 1699 return (HANDLED); 1700 } 1701 1702 if (!(xcrval & XFEATURE_ENABLED_X87)) { 1703 vm_inject_gp(vcpu->vcpu); 1704 return (HANDLED); 1705 } 1706 1707 /* AVX (YMM_Hi128) requires SSE. */ 1708 if (xcrval & XFEATURE_ENABLED_AVX && 1709 (xcrval & XFEATURE_AVX) != XFEATURE_AVX) { 1710 vm_inject_gp(vcpu->vcpu); 1711 return (HANDLED); 1712 } 1713 1714 /* 1715 * AVX512 requires base AVX (YMM_Hi128) as well as OpMask, 1716 * ZMM_Hi256, and Hi16_ZMM. 1717 */ 1718 if (xcrval & XFEATURE_AVX512 && 1719 (xcrval & (XFEATURE_AVX512 | XFEATURE_AVX)) != 1720 (XFEATURE_AVX512 | XFEATURE_AVX)) { 1721 vm_inject_gp(vcpu->vcpu); 1722 return (HANDLED); 1723 } 1724 1725 /* 1726 * Intel MPX requires both bound register state flags to be 1727 * set. 1728 */ 1729 if (((xcrval & XFEATURE_ENABLED_BNDREGS) != 0) != 1730 ((xcrval & XFEATURE_ENABLED_BNDCSR) != 0)) { 1731 vm_inject_gp(vcpu->vcpu); 1732 return (HANDLED); 1733 } 1734 1735 /* 1736 * This runs "inside" vmrun() with the guest's FPU state, so 1737 * modifying xcr0 directly modifies the guest's xcr0, not the 1738 * host's. 1739 */ 1740 load_xcr(0, xcrval); 1741 return (HANDLED); 1742 } 1743 1744 static uint64_t 1745 vmx_get_guest_reg(struct vmx_vcpu *vcpu, int ident) 1746 { 1747 const struct vmxctx *vmxctx; 1748 1749 vmxctx = &vcpu->ctx; 1750 1751 switch (ident) { 1752 case 0: 1753 return (vmxctx->guest_rax); 1754 case 1: 1755 return (vmxctx->guest_rcx); 1756 case 2: 1757 return (vmxctx->guest_rdx); 1758 case 3: 1759 return (vmxctx->guest_rbx); 1760 case 4: 1761 return (vmcs_read(VMCS_GUEST_RSP)); 1762 case 5: 1763 return (vmxctx->guest_rbp); 1764 case 6: 1765 return (vmxctx->guest_rsi); 1766 case 7: 1767 return (vmxctx->guest_rdi); 1768 case 8: 1769 return (vmxctx->guest_r8); 1770 case 9: 1771 return (vmxctx->guest_r9); 1772 case 10: 1773 return (vmxctx->guest_r10); 1774 case 11: 1775 return (vmxctx->guest_r11); 1776 case 12: 1777 return (vmxctx->guest_r12); 1778 case 13: 1779 return (vmxctx->guest_r13); 1780 case 14: 1781 return (vmxctx->guest_r14); 1782 case 15: 1783 return (vmxctx->guest_r15); 1784 default: 1785 panic("invalid vmx register %d", ident); 1786 } 1787 } 1788 1789 static void 1790 vmx_set_guest_reg(struct vmx_vcpu *vcpu, int ident, uint64_t regval) 1791 { 1792 struct vmxctx *vmxctx; 1793 1794 vmxctx = &vcpu->ctx; 1795 1796 switch (ident) { 1797 case 0: 1798 vmxctx->guest_rax = regval; 1799 break; 1800 case 1: 1801 vmxctx->guest_rcx = regval; 1802 break; 1803 case 2: 1804 vmxctx->guest_rdx = regval; 1805 break; 1806 case 3: 1807 vmxctx->guest_rbx = regval; 1808 break; 1809 case 4: 1810 vmcs_write(VMCS_GUEST_RSP, regval); 1811 break; 1812 case 5: 1813 vmxctx->guest_rbp = regval; 1814 break; 1815 case 6: 1816 vmxctx->guest_rsi = regval; 1817 break; 1818 case 7: 1819 vmxctx->guest_rdi = regval; 1820 break; 1821 case 8: 1822 vmxctx->guest_r8 = regval; 1823 break; 1824 case 9: 1825 vmxctx->guest_r9 = regval; 1826 break; 1827 case 10: 1828 vmxctx->guest_r10 = regval; 1829 break; 1830 case 11: 1831 vmxctx->guest_r11 = regval; 1832 break; 1833 case 12: 1834 vmxctx->guest_r12 = regval; 1835 break; 1836 case 13: 1837 vmxctx->guest_r13 = regval; 1838 break; 1839 case 14: 1840 vmxctx->guest_r14 = regval; 1841 break; 1842 case 15: 1843 vmxctx->guest_r15 = regval; 1844 break; 1845 default: 1846 panic("invalid vmx register %d", ident); 1847 } 1848 } 1849 1850 static int 1851 vmx_emulate_cr0_access(struct vmx_vcpu *vcpu, uint64_t exitqual) 1852 { 1853 uint64_t crval, regval; 1854 1855 /* We only handle mov to %cr0 at this time */ 1856 if ((exitqual & 0xf0) != 0x00) 1857 return (UNHANDLED); 1858 1859 regval = vmx_get_guest_reg(vcpu, (exitqual >> 8) & 0xf); 1860 1861 vmcs_write(VMCS_CR0_SHADOW, regval); 1862 1863 crval = regval | cr0_ones_mask; 1864 crval &= ~cr0_zeros_mask; 1865 vmcs_write(VMCS_GUEST_CR0, crval); 1866 1867 if (regval & CR0_PG) { 1868 uint64_t efer, entry_ctls; 1869 1870 /* 1871 * If CR0.PG is 1 and EFER.LME is 1 then EFER.LMA and 1872 * the "IA-32e mode guest" bit in VM-entry control must be 1873 * equal. 1874 */ 1875 efer = vmcs_read(VMCS_GUEST_IA32_EFER); 1876 if (efer & EFER_LME) { 1877 efer |= EFER_LMA; 1878 vmcs_write(VMCS_GUEST_IA32_EFER, efer); 1879 entry_ctls = vmcs_read(VMCS_ENTRY_CTLS); 1880 entry_ctls |= VM_ENTRY_GUEST_LMA; 1881 vmcs_write(VMCS_ENTRY_CTLS, entry_ctls); 1882 } 1883 } 1884 1885 return (HANDLED); 1886 } 1887 1888 static int 1889 vmx_emulate_cr4_access(struct vmx_vcpu *vcpu, uint64_t exitqual) 1890 { 1891 uint64_t crval, regval; 1892 1893 /* We only handle mov to %cr4 at this time */ 1894 if ((exitqual & 0xf0) != 0x00) 1895 return (UNHANDLED); 1896 1897 regval = vmx_get_guest_reg(vcpu, (exitqual >> 8) & 0xf); 1898 1899 vmcs_write(VMCS_CR4_SHADOW, regval); 1900 1901 crval = regval | cr4_ones_mask; 1902 crval &= ~cr4_zeros_mask; 1903 vmcs_write(VMCS_GUEST_CR4, crval); 1904 1905 return (HANDLED); 1906 } 1907 1908 static int 1909 vmx_emulate_cr8_access(struct vmx *vmx, struct vmx_vcpu *vcpu, 1910 uint64_t exitqual) 1911 { 1912 struct vlapic *vlapic; 1913 uint64_t cr8; 1914 int regnum; 1915 1916 /* We only handle mov %cr8 to/from a register at this time. */ 1917 if ((exitqual & 0xe0) != 0x00) { 1918 return (UNHANDLED); 1919 } 1920 1921 vlapic = vm_lapic(vcpu->vcpu); 1922 regnum = (exitqual >> 8) & 0xf; 1923 if (exitqual & 0x10) { 1924 cr8 = vlapic_get_cr8(vlapic); 1925 vmx_set_guest_reg(vcpu, regnum, cr8); 1926 } else { 1927 cr8 = vmx_get_guest_reg(vcpu, regnum); 1928 vlapic_set_cr8(vlapic, cr8); 1929 } 1930 1931 return (HANDLED); 1932 } 1933 1934 /* 1935 * From section "Guest Register State" in the Intel SDM: CPL = SS.DPL 1936 */ 1937 static int 1938 vmx_cpl(void) 1939 { 1940 uint32_t ssar; 1941 1942 ssar = vmcs_read(VMCS_GUEST_SS_ACCESS_RIGHTS); 1943 return ((ssar >> 5) & 0x3); 1944 } 1945 1946 static enum vm_cpu_mode 1947 vmx_cpu_mode(void) 1948 { 1949 uint32_t csar; 1950 1951 if (vmcs_read(VMCS_GUEST_IA32_EFER) & EFER_LMA) { 1952 csar = vmcs_read(VMCS_GUEST_CS_ACCESS_RIGHTS); 1953 if (csar & 0x2000) 1954 return (CPU_MODE_64BIT); /* CS.L = 1 */ 1955 else 1956 return (CPU_MODE_COMPATIBILITY); 1957 } else if (vmcs_read(VMCS_GUEST_CR0) & CR0_PE) { 1958 return (CPU_MODE_PROTECTED); 1959 } else { 1960 return (CPU_MODE_REAL); 1961 } 1962 } 1963 1964 static enum vm_paging_mode 1965 vmx_paging_mode(void) 1966 { 1967 uint64_t cr4; 1968 1969 if (!(vmcs_read(VMCS_GUEST_CR0) & CR0_PG)) 1970 return (PAGING_MODE_FLAT); 1971 cr4 = vmcs_read(VMCS_GUEST_CR4); 1972 if (!(cr4 & CR4_PAE)) 1973 return (PAGING_MODE_32); 1974 if (vmcs_read(VMCS_GUEST_IA32_EFER) & EFER_LME) { 1975 if (!(cr4 & CR4_LA57)) 1976 return (PAGING_MODE_64); 1977 return (PAGING_MODE_64_LA57); 1978 } else 1979 return (PAGING_MODE_PAE); 1980 } 1981 1982 static uint64_t 1983 inout_str_index(struct vmx_vcpu *vcpu, int in) 1984 { 1985 uint64_t val; 1986 int error __diagused; 1987 enum vm_reg_name reg; 1988 1989 reg = in ? VM_REG_GUEST_RDI : VM_REG_GUEST_RSI; 1990 error = vmx_getreg(vcpu, reg, &val); 1991 KASSERT(error == 0, ("%s: vmx_getreg error %d", __func__, error)); 1992 return (val); 1993 } 1994 1995 static uint64_t 1996 inout_str_count(struct vmx_vcpu *vcpu, int rep) 1997 { 1998 uint64_t val; 1999 int error __diagused; 2000 2001 if (rep) { 2002 error = vmx_getreg(vcpu, VM_REG_GUEST_RCX, &val); 2003 KASSERT(!error, ("%s: vmx_getreg error %d", __func__, error)); 2004 } else { 2005 val = 1; 2006 } 2007 return (val); 2008 } 2009 2010 static int 2011 inout_str_addrsize(uint32_t inst_info) 2012 { 2013 uint32_t size; 2014 2015 size = (inst_info >> 7) & 0x7; 2016 switch (size) { 2017 case 0: 2018 return (2); /* 16 bit */ 2019 case 1: 2020 return (4); /* 32 bit */ 2021 case 2: 2022 return (8); /* 64 bit */ 2023 default: 2024 panic("%s: invalid size encoding %d", __func__, size); 2025 } 2026 } 2027 2028 static void 2029 inout_str_seginfo(struct vmx_vcpu *vcpu, uint32_t inst_info, int in, 2030 struct vm_inout_str *vis) 2031 { 2032 int error __diagused, s; 2033 2034 if (in) { 2035 vis->seg_name = VM_REG_GUEST_ES; 2036 } else { 2037 s = (inst_info >> 15) & 0x7; 2038 vis->seg_name = vm_segment_name(s); 2039 } 2040 2041 error = vmx_getdesc(vcpu, vis->seg_name, &vis->seg_desc); 2042 KASSERT(error == 0, ("%s: vmx_getdesc error %d", __func__, error)); 2043 } 2044 2045 static void 2046 vmx_paging_info(struct vm_guest_paging *paging) 2047 { 2048 paging->cr3 = vmcs_guest_cr3(); 2049 paging->cpl = vmx_cpl(); 2050 paging->cpu_mode = vmx_cpu_mode(); 2051 paging->paging_mode = vmx_paging_mode(); 2052 } 2053 2054 static void 2055 vmexit_inst_emul(struct vm_exit *vmexit, uint64_t gpa, uint64_t gla) 2056 { 2057 struct vm_guest_paging *paging; 2058 uint32_t csar; 2059 2060 paging = &vmexit->u.inst_emul.paging; 2061 2062 vmexit->exitcode = VM_EXITCODE_INST_EMUL; 2063 vmexit->inst_length = 0; 2064 vmexit->u.inst_emul.gpa = gpa; 2065 vmexit->u.inst_emul.gla = gla; 2066 vmx_paging_info(paging); 2067 switch (paging->cpu_mode) { 2068 case CPU_MODE_REAL: 2069 vmexit->u.inst_emul.cs_base = vmcs_read(VMCS_GUEST_CS_BASE); 2070 vmexit->u.inst_emul.cs_d = 0; 2071 break; 2072 case CPU_MODE_PROTECTED: 2073 case CPU_MODE_COMPATIBILITY: 2074 vmexit->u.inst_emul.cs_base = vmcs_read(VMCS_GUEST_CS_BASE); 2075 csar = vmcs_read(VMCS_GUEST_CS_ACCESS_RIGHTS); 2076 vmexit->u.inst_emul.cs_d = SEG_DESC_DEF32(csar); 2077 break; 2078 default: 2079 vmexit->u.inst_emul.cs_base = 0; 2080 vmexit->u.inst_emul.cs_d = 0; 2081 break; 2082 } 2083 vie_init(&vmexit->u.inst_emul.vie, NULL, 0); 2084 } 2085 2086 static int 2087 ept_fault_type(uint64_t ept_qual) 2088 { 2089 int fault_type; 2090 2091 if (ept_qual & EPT_VIOLATION_DATA_WRITE) 2092 fault_type = VM_PROT_WRITE; 2093 else if (ept_qual & EPT_VIOLATION_INST_FETCH) 2094 fault_type = VM_PROT_EXECUTE; 2095 else 2096 fault_type= VM_PROT_READ; 2097 2098 return (fault_type); 2099 } 2100 2101 static bool 2102 ept_emulation_fault(uint64_t ept_qual) 2103 { 2104 int read, write; 2105 2106 /* EPT fault on an instruction fetch doesn't make sense here */ 2107 if (ept_qual & EPT_VIOLATION_INST_FETCH) 2108 return (false); 2109 2110 /* EPT fault must be a read fault or a write fault */ 2111 read = ept_qual & EPT_VIOLATION_DATA_READ ? 1 : 0; 2112 write = ept_qual & EPT_VIOLATION_DATA_WRITE ? 1 : 0; 2113 if ((read | write) == 0) 2114 return (false); 2115 2116 /* 2117 * The EPT violation must have been caused by accessing a 2118 * guest-physical address that is a translation of a guest-linear 2119 * address. 2120 */ 2121 if ((ept_qual & EPT_VIOLATION_GLA_VALID) == 0 || 2122 (ept_qual & EPT_VIOLATION_XLAT_VALID) == 0) { 2123 return (false); 2124 } 2125 2126 return (true); 2127 } 2128 2129 static __inline int 2130 apic_access_virtualization(struct vmx_vcpu *vcpu) 2131 { 2132 uint32_t proc_ctls2; 2133 2134 proc_ctls2 = vcpu->cap.proc_ctls2; 2135 return ((proc_ctls2 & PROCBASED2_VIRTUALIZE_APIC_ACCESSES) ? 1 : 0); 2136 } 2137 2138 static __inline int 2139 x2apic_virtualization(struct vmx_vcpu *vcpu) 2140 { 2141 uint32_t proc_ctls2; 2142 2143 proc_ctls2 = vcpu->cap.proc_ctls2; 2144 return ((proc_ctls2 & PROCBASED2_VIRTUALIZE_X2APIC_MODE) ? 1 : 0); 2145 } 2146 2147 static int 2148 vmx_handle_apic_write(struct vmx_vcpu *vcpu, struct vlapic *vlapic, 2149 uint64_t qual) 2150 { 2151 int error, handled, offset; 2152 uint32_t *apic_regs, vector; 2153 bool retu; 2154 2155 handled = HANDLED; 2156 offset = APIC_WRITE_OFFSET(qual); 2157 2158 if (!apic_access_virtualization(vcpu)) { 2159 /* 2160 * In general there should not be any APIC write VM-exits 2161 * unless APIC-access virtualization is enabled. 2162 * 2163 * However self-IPI virtualization can legitimately trigger 2164 * an APIC-write VM-exit so treat it specially. 2165 */ 2166 if (x2apic_virtualization(vcpu) && 2167 offset == APIC_OFFSET_SELF_IPI) { 2168 apic_regs = (uint32_t *)(vlapic->apic_page); 2169 vector = apic_regs[APIC_OFFSET_SELF_IPI / 4]; 2170 vlapic_self_ipi_handler(vlapic, vector); 2171 return (HANDLED); 2172 } else 2173 return (UNHANDLED); 2174 } 2175 2176 switch (offset) { 2177 case APIC_OFFSET_ID: 2178 vlapic_id_write_handler(vlapic); 2179 break; 2180 case APIC_OFFSET_LDR: 2181 vlapic_ldr_write_handler(vlapic); 2182 break; 2183 case APIC_OFFSET_DFR: 2184 vlapic_dfr_write_handler(vlapic); 2185 break; 2186 case APIC_OFFSET_SVR: 2187 vlapic_svr_write_handler(vlapic); 2188 break; 2189 case APIC_OFFSET_ESR: 2190 vlapic_esr_write_handler(vlapic); 2191 break; 2192 case APIC_OFFSET_ICR_LOW: 2193 retu = false; 2194 error = vlapic_icrlo_write_handler(vlapic, &retu); 2195 if (error != 0 || retu) 2196 handled = UNHANDLED; 2197 break; 2198 case APIC_OFFSET_CMCI_LVT: 2199 case APIC_OFFSET_TIMER_LVT ... APIC_OFFSET_ERROR_LVT: 2200 vlapic_lvt_write_handler(vlapic, offset); 2201 break; 2202 case APIC_OFFSET_TIMER_ICR: 2203 vlapic_icrtmr_write_handler(vlapic); 2204 break; 2205 case APIC_OFFSET_TIMER_DCR: 2206 vlapic_dcr_write_handler(vlapic); 2207 break; 2208 default: 2209 handled = UNHANDLED; 2210 break; 2211 } 2212 return (handled); 2213 } 2214 2215 static bool 2216 apic_access_fault(struct vmx_vcpu *vcpu, uint64_t gpa) 2217 { 2218 2219 if (apic_access_virtualization(vcpu) && 2220 (gpa >= DEFAULT_APIC_BASE && gpa < DEFAULT_APIC_BASE + PAGE_SIZE)) 2221 return (true); 2222 else 2223 return (false); 2224 } 2225 2226 static int 2227 vmx_handle_apic_access(struct vmx_vcpu *vcpu, struct vm_exit *vmexit) 2228 { 2229 uint64_t qual; 2230 int access_type, offset, allowed; 2231 2232 if (!apic_access_virtualization(vcpu)) 2233 return (UNHANDLED); 2234 2235 qual = vmexit->u.vmx.exit_qualification; 2236 access_type = APIC_ACCESS_TYPE(qual); 2237 offset = APIC_ACCESS_OFFSET(qual); 2238 2239 allowed = 0; 2240 if (access_type == 0) { 2241 /* 2242 * Read data access to the following registers is expected. 2243 */ 2244 switch (offset) { 2245 case APIC_OFFSET_APR: 2246 case APIC_OFFSET_PPR: 2247 case APIC_OFFSET_RRR: 2248 case APIC_OFFSET_CMCI_LVT: 2249 case APIC_OFFSET_TIMER_CCR: 2250 allowed = 1; 2251 break; 2252 default: 2253 break; 2254 } 2255 } else if (access_type == 1) { 2256 /* 2257 * Write data access to the following registers is expected. 2258 */ 2259 switch (offset) { 2260 case APIC_OFFSET_VER: 2261 case APIC_OFFSET_APR: 2262 case APIC_OFFSET_PPR: 2263 case APIC_OFFSET_RRR: 2264 case APIC_OFFSET_ISR0 ... APIC_OFFSET_ISR7: 2265 case APIC_OFFSET_TMR0 ... APIC_OFFSET_TMR7: 2266 case APIC_OFFSET_IRR0 ... APIC_OFFSET_IRR7: 2267 case APIC_OFFSET_CMCI_LVT: 2268 case APIC_OFFSET_TIMER_CCR: 2269 allowed = 1; 2270 break; 2271 default: 2272 break; 2273 } 2274 } 2275 2276 if (allowed) { 2277 vmexit_inst_emul(vmexit, DEFAULT_APIC_BASE + offset, 2278 VIE_INVALID_GLA); 2279 } 2280 2281 /* 2282 * Regardless of whether the APIC-access is allowed this handler 2283 * always returns UNHANDLED: 2284 * - if the access is allowed then it is handled by emulating the 2285 * instruction that caused the VM-exit (outside the critical section) 2286 * - if the access is not allowed then it will be converted to an 2287 * exitcode of VM_EXITCODE_VMX and will be dealt with in userland. 2288 */ 2289 return (UNHANDLED); 2290 } 2291 2292 static enum task_switch_reason 2293 vmx_task_switch_reason(uint64_t qual) 2294 { 2295 int reason; 2296 2297 reason = (qual >> 30) & 0x3; 2298 switch (reason) { 2299 case 0: 2300 return (TSR_CALL); 2301 case 1: 2302 return (TSR_IRET); 2303 case 2: 2304 return (TSR_JMP); 2305 case 3: 2306 return (TSR_IDT_GATE); 2307 default: 2308 panic("%s: invalid reason %d", __func__, reason); 2309 } 2310 } 2311 2312 static int 2313 emulate_wrmsr(struct vmx_vcpu *vcpu, u_int num, uint64_t val, bool *retu) 2314 { 2315 int error; 2316 2317 if (lapic_msr(num)) 2318 error = lapic_wrmsr(vcpu->vcpu, num, val, retu); 2319 else 2320 error = vmx_wrmsr(vcpu, num, val, retu); 2321 2322 return (error); 2323 } 2324 2325 static int 2326 emulate_rdmsr(struct vmx_vcpu *vcpu, u_int num, bool *retu) 2327 { 2328 struct vmxctx *vmxctx; 2329 uint64_t result; 2330 uint32_t eax, edx; 2331 int error; 2332 2333 if (lapic_msr(num)) 2334 error = lapic_rdmsr(vcpu->vcpu, num, &result, retu); 2335 else 2336 error = vmx_rdmsr(vcpu, num, &result, retu); 2337 2338 if (error == 0) { 2339 eax = result; 2340 vmxctx = &vcpu->ctx; 2341 error = vmxctx_setreg(vmxctx, VM_REG_GUEST_RAX, eax); 2342 KASSERT(error == 0, ("vmxctx_setreg(rax) error %d", error)); 2343 2344 edx = result >> 32; 2345 error = vmxctx_setreg(vmxctx, VM_REG_GUEST_RDX, edx); 2346 KASSERT(error == 0, ("vmxctx_setreg(rdx) error %d", error)); 2347 } 2348 2349 return (error); 2350 } 2351 2352 static int 2353 vmx_exit_process(struct vmx *vmx, struct vmx_vcpu *vcpu, struct vm_exit *vmexit) 2354 { 2355 int error, errcode, errcode_valid, handled, in; 2356 struct vmxctx *vmxctx; 2357 struct vlapic *vlapic; 2358 struct vm_inout_str *vis; 2359 struct vm_task_switch *ts; 2360 uint32_t eax, ecx, edx, idtvec_info, idtvec_err, intr_info, inst_info; 2361 uint32_t intr_type, intr_vec, reason; 2362 uint64_t exitintinfo, qual, gpa; 2363 #ifdef KDTRACE_HOOKS 2364 int vcpuid; 2365 #endif 2366 bool retu; 2367 2368 CTASSERT((PINBASED_CTLS_ONE_SETTING & PINBASED_VIRTUAL_NMI) != 0); 2369 CTASSERT((PINBASED_CTLS_ONE_SETTING & PINBASED_NMI_EXITING) != 0); 2370 2371 handled = UNHANDLED; 2372 vmxctx = &vcpu->ctx; 2373 #ifdef KDTRACE_HOOKS 2374 vcpuid = vcpu->vcpuid; 2375 #endif 2376 2377 qual = vmexit->u.vmx.exit_qualification; 2378 reason = vmexit->u.vmx.exit_reason; 2379 vmexit->exitcode = VM_EXITCODE_BOGUS; 2380 2381 vmm_stat_incr(vcpu->vcpu, VMEXIT_COUNT, 1); 2382 SDT_PROBE3(vmm, vmx, exit, entry, vmx, vcpuid, vmexit); 2383 2384 /* 2385 * VM-entry failures during or after loading guest state. 2386 * 2387 * These VM-exits are uncommon but must be handled specially 2388 * as most VM-exit fields are not populated as usual. 2389 */ 2390 if (__predict_false(reason == EXIT_REASON_MCE_DURING_ENTRY)) { 2391 VMX_CTR0(vcpu, "Handling MCE during VM-entry"); 2392 __asm __volatile("int $18"); 2393 return (1); 2394 } 2395 2396 /* 2397 * VM exits that can be triggered during event delivery need to 2398 * be handled specially by re-injecting the event if the IDT 2399 * vectoring information field's valid bit is set. 2400 * 2401 * See "Information for VM Exits During Event Delivery" in Intel SDM 2402 * for details. 2403 */ 2404 idtvec_info = vmcs_idt_vectoring_info(); 2405 if (idtvec_info & VMCS_IDT_VEC_VALID) { 2406 idtvec_info &= ~(1 << 12); /* clear undefined bit */ 2407 exitintinfo = idtvec_info; 2408 if (idtvec_info & VMCS_IDT_VEC_ERRCODE_VALID) { 2409 idtvec_err = vmcs_idt_vectoring_err(); 2410 exitintinfo |= (uint64_t)idtvec_err << 32; 2411 } 2412 error = vm_exit_intinfo(vcpu->vcpu, exitintinfo); 2413 KASSERT(error == 0, ("%s: vm_set_intinfo error %d", 2414 __func__, error)); 2415 2416 /* 2417 * If 'virtual NMIs' are being used and the VM-exit 2418 * happened while injecting an NMI during the previous 2419 * VM-entry, then clear "blocking by NMI" in the 2420 * Guest Interruptibility-State so the NMI can be 2421 * reinjected on the subsequent VM-entry. 2422 * 2423 * However, if the NMI was being delivered through a task 2424 * gate, then the new task must start execution with NMIs 2425 * blocked so don't clear NMI blocking in this case. 2426 */ 2427 intr_type = idtvec_info & VMCS_INTR_T_MASK; 2428 if (intr_type == VMCS_INTR_T_NMI) { 2429 if (reason != EXIT_REASON_TASK_SWITCH) 2430 vmx_clear_nmi_blocking(vcpu); 2431 else 2432 vmx_assert_nmi_blocking(vcpu); 2433 } 2434 2435 /* 2436 * Update VM-entry instruction length if the event being 2437 * delivered was a software interrupt or software exception. 2438 */ 2439 if (intr_type == VMCS_INTR_T_SWINTR || 2440 intr_type == VMCS_INTR_T_PRIV_SWEXCEPTION || 2441 intr_type == VMCS_INTR_T_SWEXCEPTION) { 2442 vmcs_write(VMCS_ENTRY_INST_LENGTH, vmexit->inst_length); 2443 } 2444 } 2445 2446 switch (reason) { 2447 case EXIT_REASON_TASK_SWITCH: 2448 ts = &vmexit->u.task_switch; 2449 ts->tsssel = qual & 0xffff; 2450 ts->reason = vmx_task_switch_reason(qual); 2451 ts->ext = 0; 2452 ts->errcode_valid = 0; 2453 vmx_paging_info(&ts->paging); 2454 /* 2455 * If the task switch was due to a CALL, JMP, IRET, software 2456 * interrupt (INT n) or software exception (INT3, INTO), 2457 * then the saved %rip references the instruction that caused 2458 * the task switch. The instruction length field in the VMCS 2459 * is valid in this case. 2460 * 2461 * In all other cases (e.g., NMI, hardware exception) the 2462 * saved %rip is one that would have been saved in the old TSS 2463 * had the task switch completed normally so the instruction 2464 * length field is not needed in this case and is explicitly 2465 * set to 0. 2466 */ 2467 if (ts->reason == TSR_IDT_GATE) { 2468 KASSERT(idtvec_info & VMCS_IDT_VEC_VALID, 2469 ("invalid idtvec_info %#x for IDT task switch", 2470 idtvec_info)); 2471 intr_type = idtvec_info & VMCS_INTR_T_MASK; 2472 if (intr_type != VMCS_INTR_T_SWINTR && 2473 intr_type != VMCS_INTR_T_SWEXCEPTION && 2474 intr_type != VMCS_INTR_T_PRIV_SWEXCEPTION) { 2475 /* Task switch triggered by external event */ 2476 ts->ext = 1; 2477 vmexit->inst_length = 0; 2478 if (idtvec_info & VMCS_IDT_VEC_ERRCODE_VALID) { 2479 ts->errcode_valid = 1; 2480 ts->errcode = vmcs_idt_vectoring_err(); 2481 } 2482 } 2483 } 2484 vmexit->exitcode = VM_EXITCODE_TASK_SWITCH; 2485 SDT_PROBE4(vmm, vmx, exit, taskswitch, vmx, vcpuid, vmexit, ts); 2486 VMX_CTR4(vcpu, "task switch reason %d, tss 0x%04x, " 2487 "%s errcode 0x%016lx", ts->reason, ts->tsssel, 2488 ts->ext ? "external" : "internal", 2489 ((uint64_t)ts->errcode << 32) | ts->errcode_valid); 2490 break; 2491 case EXIT_REASON_CR_ACCESS: 2492 vmm_stat_incr(vcpu->vcpu, VMEXIT_CR_ACCESS, 1); 2493 SDT_PROBE4(vmm, vmx, exit, craccess, vmx, vcpuid, vmexit, qual); 2494 switch (qual & 0xf) { 2495 case 0: 2496 handled = vmx_emulate_cr0_access(vcpu, qual); 2497 break; 2498 case 4: 2499 handled = vmx_emulate_cr4_access(vcpu, qual); 2500 break; 2501 case 8: 2502 handled = vmx_emulate_cr8_access(vmx, vcpu, qual); 2503 break; 2504 } 2505 break; 2506 case EXIT_REASON_RDMSR: 2507 vmm_stat_incr(vcpu->vcpu, VMEXIT_RDMSR, 1); 2508 retu = false; 2509 ecx = vmxctx->guest_rcx; 2510 VMX_CTR1(vcpu, "rdmsr 0x%08x", ecx); 2511 SDT_PROBE4(vmm, vmx, exit, rdmsr, vmx, vcpuid, vmexit, ecx); 2512 error = emulate_rdmsr(vcpu, ecx, &retu); 2513 if (error) { 2514 vmexit->exitcode = VM_EXITCODE_RDMSR; 2515 vmexit->u.msr.code = ecx; 2516 } else if (!retu) { 2517 handled = HANDLED; 2518 } else { 2519 /* Return to userspace with a valid exitcode */ 2520 KASSERT(vmexit->exitcode != VM_EXITCODE_BOGUS, 2521 ("emulate_rdmsr retu with bogus exitcode")); 2522 } 2523 break; 2524 case EXIT_REASON_WRMSR: 2525 vmm_stat_incr(vcpu->vcpu, VMEXIT_WRMSR, 1); 2526 retu = false; 2527 eax = vmxctx->guest_rax; 2528 ecx = vmxctx->guest_rcx; 2529 edx = vmxctx->guest_rdx; 2530 VMX_CTR2(vcpu, "wrmsr 0x%08x value 0x%016lx", 2531 ecx, (uint64_t)edx << 32 | eax); 2532 SDT_PROBE5(vmm, vmx, exit, wrmsr, vmx, vmexit, vcpuid, ecx, 2533 (uint64_t)edx << 32 | eax); 2534 error = emulate_wrmsr(vcpu, ecx, (uint64_t)edx << 32 | eax, 2535 &retu); 2536 if (error) { 2537 vmexit->exitcode = VM_EXITCODE_WRMSR; 2538 vmexit->u.msr.code = ecx; 2539 vmexit->u.msr.wval = (uint64_t)edx << 32 | eax; 2540 } else if (!retu) { 2541 handled = HANDLED; 2542 } else { 2543 /* Return to userspace with a valid exitcode */ 2544 KASSERT(vmexit->exitcode != VM_EXITCODE_BOGUS, 2545 ("emulate_wrmsr retu with bogus exitcode")); 2546 } 2547 break; 2548 case EXIT_REASON_HLT: 2549 vmm_stat_incr(vcpu->vcpu, VMEXIT_HLT, 1); 2550 SDT_PROBE3(vmm, vmx, exit, halt, vmx, vcpuid, vmexit); 2551 vmexit->exitcode = VM_EXITCODE_HLT; 2552 vmexit->u.hlt.rflags = vmcs_read(VMCS_GUEST_RFLAGS); 2553 if (virtual_interrupt_delivery) 2554 vmexit->u.hlt.intr_status = 2555 vmcs_read(VMCS_GUEST_INTR_STATUS); 2556 else 2557 vmexit->u.hlt.intr_status = 0; 2558 break; 2559 case EXIT_REASON_MTF: 2560 vmm_stat_incr(vcpu->vcpu, VMEXIT_MTRAP, 1); 2561 SDT_PROBE3(vmm, vmx, exit, mtrap, vmx, vcpuid, vmexit); 2562 vmexit->exitcode = VM_EXITCODE_MTRAP; 2563 vmexit->inst_length = 0; 2564 break; 2565 case EXIT_REASON_PAUSE: 2566 vmm_stat_incr(vcpu->vcpu, VMEXIT_PAUSE, 1); 2567 SDT_PROBE3(vmm, vmx, exit, pause, vmx, vcpuid, vmexit); 2568 vmexit->exitcode = VM_EXITCODE_PAUSE; 2569 break; 2570 case EXIT_REASON_INTR_WINDOW: 2571 vmm_stat_incr(vcpu->vcpu, VMEXIT_INTR_WINDOW, 1); 2572 SDT_PROBE3(vmm, vmx, exit, intrwindow, vmx, vcpuid, vmexit); 2573 vmx_clear_int_window_exiting(vcpu); 2574 return (1); 2575 case EXIT_REASON_EXT_INTR: 2576 /* 2577 * External interrupts serve only to cause VM exits and allow 2578 * the host interrupt handler to run. 2579 * 2580 * If this external interrupt triggers a virtual interrupt 2581 * to a VM, then that state will be recorded by the 2582 * host interrupt handler in the VM's softc. We will inject 2583 * this virtual interrupt during the subsequent VM enter. 2584 */ 2585 intr_info = vmcs_read(VMCS_EXIT_INTR_INFO); 2586 SDT_PROBE4(vmm, vmx, exit, interrupt, 2587 vmx, vcpuid, vmexit, intr_info); 2588 2589 /* 2590 * XXX: Ignore this exit if VMCS_INTR_VALID is not set. 2591 * This appears to be a bug in VMware Fusion? 2592 */ 2593 if (!(intr_info & VMCS_INTR_VALID)) 2594 return (1); 2595 KASSERT((intr_info & VMCS_INTR_VALID) != 0 && 2596 (intr_info & VMCS_INTR_T_MASK) == VMCS_INTR_T_HWINTR, 2597 ("VM exit interruption info invalid: %#x", intr_info)); 2598 vmx_trigger_hostintr(intr_info & 0xff); 2599 2600 /* 2601 * This is special. We want to treat this as an 'handled' 2602 * VM-exit but not increment the instruction pointer. 2603 */ 2604 vmm_stat_incr(vcpu->vcpu, VMEXIT_EXTINT, 1); 2605 return (1); 2606 case EXIT_REASON_NMI_WINDOW: 2607 SDT_PROBE3(vmm, vmx, exit, nmiwindow, vmx, vcpuid, vmexit); 2608 /* Exit to allow the pending virtual NMI to be injected */ 2609 if (vm_nmi_pending(vcpu->vcpu)) 2610 vmx_inject_nmi(vcpu); 2611 vmx_clear_nmi_window_exiting(vcpu); 2612 vmm_stat_incr(vcpu->vcpu, VMEXIT_NMI_WINDOW, 1); 2613 return (1); 2614 case EXIT_REASON_INOUT: 2615 vmm_stat_incr(vcpu->vcpu, VMEXIT_INOUT, 1); 2616 vmexit->exitcode = VM_EXITCODE_INOUT; 2617 vmexit->u.inout.bytes = (qual & 0x7) + 1; 2618 vmexit->u.inout.in = in = (qual & 0x8) ? 1 : 0; 2619 vmexit->u.inout.string = (qual & 0x10) ? 1 : 0; 2620 vmexit->u.inout.rep = (qual & 0x20) ? 1 : 0; 2621 vmexit->u.inout.port = (uint16_t)(qual >> 16); 2622 vmexit->u.inout.eax = (uint32_t)(vmxctx->guest_rax); 2623 if (vmexit->u.inout.string) { 2624 inst_info = vmcs_read(VMCS_EXIT_INSTRUCTION_INFO); 2625 vmexit->exitcode = VM_EXITCODE_INOUT_STR; 2626 vis = &vmexit->u.inout_str; 2627 vmx_paging_info(&vis->paging); 2628 vis->rflags = vmcs_read(VMCS_GUEST_RFLAGS); 2629 vis->cr0 = vmcs_read(VMCS_GUEST_CR0); 2630 vis->index = inout_str_index(vcpu, in); 2631 vis->count = inout_str_count(vcpu, vis->inout.rep); 2632 vis->addrsize = inout_str_addrsize(inst_info); 2633 inout_str_seginfo(vcpu, inst_info, in, vis); 2634 } 2635 SDT_PROBE3(vmm, vmx, exit, inout, vmx, vcpuid, vmexit); 2636 break; 2637 case EXIT_REASON_CPUID: 2638 vmm_stat_incr(vcpu->vcpu, VMEXIT_CPUID, 1); 2639 SDT_PROBE3(vmm, vmx, exit, cpuid, vmx, vcpuid, vmexit); 2640 handled = vmx_handle_cpuid(vcpu, vmxctx); 2641 break; 2642 case EXIT_REASON_EXCEPTION: 2643 vmm_stat_incr(vcpu->vcpu, VMEXIT_EXCEPTION, 1); 2644 intr_info = vmcs_read(VMCS_EXIT_INTR_INFO); 2645 KASSERT((intr_info & VMCS_INTR_VALID) != 0, 2646 ("VM exit interruption info invalid: %#x", intr_info)); 2647 2648 intr_vec = intr_info & 0xff; 2649 intr_type = intr_info & VMCS_INTR_T_MASK; 2650 2651 /* 2652 * If Virtual NMIs control is 1 and the VM-exit is due to a 2653 * fault encountered during the execution of IRET then we must 2654 * restore the state of "virtual-NMI blocking" before resuming 2655 * the guest. 2656 * 2657 * See "Resuming Guest Software after Handling an Exception". 2658 * See "Information for VM Exits Due to Vectored Events". 2659 */ 2660 if ((idtvec_info & VMCS_IDT_VEC_VALID) == 0 && 2661 (intr_vec != IDT_DF) && 2662 (intr_info & EXIT_QUAL_NMIUDTI) != 0) 2663 vmx_restore_nmi_blocking(vcpu); 2664 2665 /* 2666 * The NMI has already been handled in vmx_exit_handle_nmi(). 2667 */ 2668 if (intr_type == VMCS_INTR_T_NMI) 2669 return (1); 2670 2671 /* 2672 * Call the machine check handler by hand. Also don't reflect 2673 * the machine check back into the guest. 2674 */ 2675 if (intr_vec == IDT_MC) { 2676 VMX_CTR0(vcpu, "Vectoring to MCE handler"); 2677 __asm __volatile("int $18"); 2678 return (1); 2679 } 2680 2681 /* 2682 * If the hypervisor has requested user exits for 2683 * debug exceptions, bounce them out to userland. 2684 */ 2685 if (intr_type == VMCS_INTR_T_SWEXCEPTION && intr_vec == IDT_BP && 2686 (vcpu->cap.set & (1 << VM_CAP_BPT_EXIT))) { 2687 vmexit->exitcode = VM_EXITCODE_BPT; 2688 vmexit->u.bpt.inst_length = vmexit->inst_length; 2689 vmexit->inst_length = 0; 2690 break; 2691 } 2692 2693 if (intr_vec == IDT_PF) { 2694 error = vmxctx_setreg(vmxctx, VM_REG_GUEST_CR2, qual); 2695 KASSERT(error == 0, ("%s: vmxctx_setreg(cr2) error %d", 2696 __func__, error)); 2697 } 2698 2699 /* 2700 * Software exceptions exhibit trap-like behavior. This in 2701 * turn requires populating the VM-entry instruction length 2702 * so that the %rip in the trap frame is past the INT3/INTO 2703 * instruction. 2704 */ 2705 if (intr_type == VMCS_INTR_T_SWEXCEPTION) 2706 vmcs_write(VMCS_ENTRY_INST_LENGTH, vmexit->inst_length); 2707 2708 /* Reflect all other exceptions back into the guest */ 2709 errcode_valid = errcode = 0; 2710 if (intr_info & VMCS_INTR_DEL_ERRCODE) { 2711 errcode_valid = 1; 2712 errcode = vmcs_read(VMCS_EXIT_INTR_ERRCODE); 2713 } 2714 VMX_CTR2(vcpu, "Reflecting exception %d/%#x into " 2715 "the guest", intr_vec, errcode); 2716 SDT_PROBE5(vmm, vmx, exit, exception, 2717 vmx, vcpuid, vmexit, intr_vec, errcode); 2718 error = vm_inject_exception(vcpu->vcpu, intr_vec, 2719 errcode_valid, errcode, 0); 2720 KASSERT(error == 0, ("%s: vm_inject_exception error %d", 2721 __func__, error)); 2722 return (1); 2723 2724 case EXIT_REASON_EPT_FAULT: 2725 /* 2726 * If 'gpa' lies within the address space allocated to 2727 * memory then this must be a nested page fault otherwise 2728 * this must be an instruction that accesses MMIO space. 2729 */ 2730 gpa = vmcs_gpa(); 2731 if (vm_mem_allocated(vcpu->vcpu, gpa) || 2732 apic_access_fault(vcpu, gpa)) { 2733 vmexit->exitcode = VM_EXITCODE_PAGING; 2734 vmexit->inst_length = 0; 2735 vmexit->u.paging.gpa = gpa; 2736 vmexit->u.paging.fault_type = ept_fault_type(qual); 2737 vmm_stat_incr(vcpu->vcpu, VMEXIT_NESTED_FAULT, 1); 2738 SDT_PROBE5(vmm, vmx, exit, nestedfault, 2739 vmx, vcpuid, vmexit, gpa, qual); 2740 } else if (ept_emulation_fault(qual)) { 2741 vmexit_inst_emul(vmexit, gpa, vmcs_gla()); 2742 vmm_stat_incr(vcpu->vcpu, VMEXIT_INST_EMUL, 1); 2743 SDT_PROBE4(vmm, vmx, exit, mmiofault, 2744 vmx, vcpuid, vmexit, gpa); 2745 } 2746 /* 2747 * If Virtual NMIs control is 1 and the VM-exit is due to an 2748 * EPT fault during the execution of IRET then we must restore 2749 * the state of "virtual-NMI blocking" before resuming. 2750 * 2751 * See description of "NMI unblocking due to IRET" in 2752 * "Exit Qualification for EPT Violations". 2753 */ 2754 if ((idtvec_info & VMCS_IDT_VEC_VALID) == 0 && 2755 (qual & EXIT_QUAL_NMIUDTI) != 0) 2756 vmx_restore_nmi_blocking(vcpu); 2757 break; 2758 case EXIT_REASON_VIRTUALIZED_EOI: 2759 vmexit->exitcode = VM_EXITCODE_IOAPIC_EOI; 2760 vmexit->u.ioapic_eoi.vector = qual & 0xFF; 2761 SDT_PROBE3(vmm, vmx, exit, eoi, vmx, vcpuid, vmexit); 2762 vmexit->inst_length = 0; /* trap-like */ 2763 break; 2764 case EXIT_REASON_APIC_ACCESS: 2765 SDT_PROBE3(vmm, vmx, exit, apicaccess, vmx, vcpuid, vmexit); 2766 handled = vmx_handle_apic_access(vcpu, vmexit); 2767 break; 2768 case EXIT_REASON_APIC_WRITE: 2769 /* 2770 * APIC-write VM exit is trap-like so the %rip is already 2771 * pointing to the next instruction. 2772 */ 2773 vmexit->inst_length = 0; 2774 vlapic = vm_lapic(vcpu->vcpu); 2775 SDT_PROBE4(vmm, vmx, exit, apicwrite, 2776 vmx, vcpuid, vmexit, vlapic); 2777 handled = vmx_handle_apic_write(vcpu, vlapic, qual); 2778 break; 2779 case EXIT_REASON_XSETBV: 2780 SDT_PROBE3(vmm, vmx, exit, xsetbv, vmx, vcpuid, vmexit); 2781 handled = vmx_emulate_xsetbv(vmx, vcpu, vmexit); 2782 break; 2783 case EXIT_REASON_MONITOR: 2784 SDT_PROBE3(vmm, vmx, exit, monitor, vmx, vcpuid, vmexit); 2785 vmexit->exitcode = VM_EXITCODE_MONITOR; 2786 break; 2787 case EXIT_REASON_MWAIT: 2788 SDT_PROBE3(vmm, vmx, exit, mwait, vmx, vcpuid, vmexit); 2789 vmexit->exitcode = VM_EXITCODE_MWAIT; 2790 break; 2791 case EXIT_REASON_TPR: 2792 vlapic = vm_lapic(vcpu->vcpu); 2793 vlapic_sync_tpr(vlapic); 2794 vmexit->inst_length = 0; 2795 handled = HANDLED; 2796 break; 2797 case EXIT_REASON_VMCALL: 2798 case EXIT_REASON_VMCLEAR: 2799 case EXIT_REASON_VMLAUNCH: 2800 case EXIT_REASON_VMPTRLD: 2801 case EXIT_REASON_VMPTRST: 2802 case EXIT_REASON_VMREAD: 2803 case EXIT_REASON_VMRESUME: 2804 case EXIT_REASON_VMWRITE: 2805 case EXIT_REASON_VMXOFF: 2806 case EXIT_REASON_VMXON: 2807 SDT_PROBE3(vmm, vmx, exit, vminsn, vmx, vcpuid, vmexit); 2808 vmexit->exitcode = VM_EXITCODE_VMINSN; 2809 break; 2810 case EXIT_REASON_INVD: 2811 case EXIT_REASON_WBINVD: 2812 /* ignore exit */ 2813 handled = HANDLED; 2814 break; 2815 default: 2816 SDT_PROBE4(vmm, vmx, exit, unknown, 2817 vmx, vcpuid, vmexit, reason); 2818 vmm_stat_incr(vcpu->vcpu, VMEXIT_UNKNOWN, 1); 2819 break; 2820 } 2821 2822 if (handled) { 2823 /* 2824 * It is possible that control is returned to userland 2825 * even though we were able to handle the VM exit in the 2826 * kernel. 2827 * 2828 * In such a case we want to make sure that the userland 2829 * restarts guest execution at the instruction *after* 2830 * the one we just processed. Therefore we update the 2831 * guest rip in the VMCS and in 'vmexit'. 2832 */ 2833 vmexit->rip += vmexit->inst_length; 2834 vmexit->inst_length = 0; 2835 vmcs_write(VMCS_GUEST_RIP, vmexit->rip); 2836 } else { 2837 if (vmexit->exitcode == VM_EXITCODE_BOGUS) { 2838 /* 2839 * If this VM exit was not claimed by anybody then 2840 * treat it as a generic VMX exit. 2841 */ 2842 vmexit->exitcode = VM_EXITCODE_VMX; 2843 vmexit->u.vmx.status = VM_SUCCESS; 2844 vmexit->u.vmx.inst_type = 0; 2845 vmexit->u.vmx.inst_error = 0; 2846 } else { 2847 /* 2848 * The exitcode and collateral have been populated. 2849 * The VM exit will be processed further in userland. 2850 */ 2851 } 2852 } 2853 2854 SDT_PROBE4(vmm, vmx, exit, return, 2855 vmx, vcpuid, vmexit, handled); 2856 return (handled); 2857 } 2858 2859 static __inline void 2860 vmx_exit_inst_error(struct vmxctx *vmxctx, int rc, struct vm_exit *vmexit) 2861 { 2862 2863 KASSERT(vmxctx->inst_fail_status != VM_SUCCESS, 2864 ("vmx_exit_inst_error: invalid inst_fail_status %d", 2865 vmxctx->inst_fail_status)); 2866 2867 vmexit->inst_length = 0; 2868 vmexit->exitcode = VM_EXITCODE_VMX; 2869 vmexit->u.vmx.status = vmxctx->inst_fail_status; 2870 vmexit->u.vmx.inst_error = vmcs_instruction_error(); 2871 vmexit->u.vmx.exit_reason = ~0; 2872 vmexit->u.vmx.exit_qualification = ~0; 2873 2874 switch (rc) { 2875 case VMX_VMRESUME_ERROR: 2876 case VMX_VMLAUNCH_ERROR: 2877 vmexit->u.vmx.inst_type = rc; 2878 break; 2879 default: 2880 panic("vm_exit_inst_error: vmx_enter_guest returned %d", rc); 2881 } 2882 } 2883 2884 /* 2885 * If the NMI-exiting VM execution control is set to '1' then an NMI in 2886 * non-root operation causes a VM-exit. NMI blocking is in effect so it is 2887 * sufficient to simply vector to the NMI handler via a software interrupt. 2888 * However, this must be done before maskable interrupts are enabled 2889 * otherwise the "iret" issued by an interrupt handler will incorrectly 2890 * clear NMI blocking. 2891 */ 2892 static __inline void 2893 vmx_exit_handle_nmi(struct vmx_vcpu *vcpu, struct vm_exit *vmexit) 2894 { 2895 uint32_t intr_info; 2896 2897 KASSERT((read_rflags() & PSL_I) == 0, ("interrupts enabled")); 2898 2899 if (vmexit->u.vmx.exit_reason != EXIT_REASON_EXCEPTION) 2900 return; 2901 2902 intr_info = vmcs_read(VMCS_EXIT_INTR_INFO); 2903 KASSERT((intr_info & VMCS_INTR_VALID) != 0, 2904 ("VM exit interruption info invalid: %#x", intr_info)); 2905 2906 if ((intr_info & VMCS_INTR_T_MASK) == VMCS_INTR_T_NMI) { 2907 KASSERT((intr_info & 0xff) == IDT_NMI, ("VM exit due " 2908 "to NMI has invalid vector: %#x", intr_info)); 2909 VMX_CTR0(vcpu, "Vectoring to NMI handler"); 2910 __asm __volatile("int $2"); 2911 } 2912 } 2913 2914 static __inline void 2915 vmx_dr_enter_guest(struct vmxctx *vmxctx) 2916 { 2917 register_t rflags; 2918 2919 /* Save host control debug registers. */ 2920 vmxctx->host_dr7 = rdr7(); 2921 vmxctx->host_debugctl = rdmsr(MSR_DEBUGCTLMSR); 2922 2923 /* 2924 * Disable debugging in DR7 and DEBUGCTL to avoid triggering 2925 * exceptions in the host based on the guest DRx values. The 2926 * guest DR7 and DEBUGCTL are saved/restored in the VMCS. 2927 */ 2928 load_dr7(0); 2929 wrmsr(MSR_DEBUGCTLMSR, 0); 2930 2931 /* 2932 * Disable single stepping the kernel to avoid corrupting the 2933 * guest DR6. A debugger might still be able to corrupt the 2934 * guest DR6 by setting a breakpoint after this point and then 2935 * single stepping. 2936 */ 2937 rflags = read_rflags(); 2938 vmxctx->host_tf = rflags & PSL_T; 2939 write_rflags(rflags & ~PSL_T); 2940 2941 /* Save host debug registers. */ 2942 vmxctx->host_dr0 = rdr0(); 2943 vmxctx->host_dr1 = rdr1(); 2944 vmxctx->host_dr2 = rdr2(); 2945 vmxctx->host_dr3 = rdr3(); 2946 vmxctx->host_dr6 = rdr6(); 2947 2948 /* Restore guest debug registers. */ 2949 load_dr0(vmxctx->guest_dr0); 2950 load_dr1(vmxctx->guest_dr1); 2951 load_dr2(vmxctx->guest_dr2); 2952 load_dr3(vmxctx->guest_dr3); 2953 load_dr6(vmxctx->guest_dr6); 2954 } 2955 2956 static __inline void 2957 vmx_dr_leave_guest(struct vmxctx *vmxctx) 2958 { 2959 2960 /* Save guest debug registers. */ 2961 vmxctx->guest_dr0 = rdr0(); 2962 vmxctx->guest_dr1 = rdr1(); 2963 vmxctx->guest_dr2 = rdr2(); 2964 vmxctx->guest_dr3 = rdr3(); 2965 vmxctx->guest_dr6 = rdr6(); 2966 2967 /* 2968 * Restore host debug registers. Restore DR7, DEBUGCTL, and 2969 * PSL_T last. 2970 */ 2971 load_dr0(vmxctx->host_dr0); 2972 load_dr1(vmxctx->host_dr1); 2973 load_dr2(vmxctx->host_dr2); 2974 load_dr3(vmxctx->host_dr3); 2975 load_dr6(vmxctx->host_dr6); 2976 wrmsr(MSR_DEBUGCTLMSR, vmxctx->host_debugctl); 2977 load_dr7(vmxctx->host_dr7); 2978 write_rflags(read_rflags() | vmxctx->host_tf); 2979 } 2980 2981 static __inline void 2982 vmx_pmap_activate(struct vmx *vmx, pmap_t pmap) 2983 { 2984 long eptgen; 2985 int cpu; 2986 2987 cpu = curcpu; 2988 2989 CPU_SET_ATOMIC(cpu, &pmap->pm_active); 2990 smr_enter(pmap->pm_eptsmr); 2991 eptgen = atomic_load_long(&pmap->pm_eptgen); 2992 if (eptgen != vmx->eptgen[cpu]) { 2993 vmx->eptgen[cpu] = eptgen; 2994 invept(INVEPT_TYPE_SINGLE_CONTEXT, 2995 (struct invept_desc){ .eptp = vmx->eptp, ._res = 0 }); 2996 } 2997 } 2998 2999 static __inline void 3000 vmx_pmap_deactivate(struct vmx *vmx, pmap_t pmap) 3001 { 3002 smr_exit(pmap->pm_eptsmr); 3003 CPU_CLR_ATOMIC(curcpu, &pmap->pm_active); 3004 } 3005 3006 static int 3007 vmx_run(void *vcpui, register_t rip, pmap_t pmap, struct vm_eventinfo *evinfo) 3008 { 3009 int rc, handled, launched; 3010 struct vmx *vmx; 3011 struct vmx_vcpu *vcpu; 3012 struct vmxctx *vmxctx; 3013 struct vmcs *vmcs; 3014 struct vm_exit *vmexit; 3015 struct vlapic *vlapic; 3016 uint32_t exit_reason; 3017 struct region_descriptor gdtr, idtr; 3018 uint16_t ldt_sel; 3019 3020 vcpu = vcpui; 3021 vmx = vcpu->vmx; 3022 vmcs = vcpu->vmcs; 3023 vmxctx = &vcpu->ctx; 3024 vlapic = vm_lapic(vcpu->vcpu); 3025 vmexit = vm_exitinfo(vcpu->vcpu); 3026 launched = 0; 3027 3028 KASSERT(vmxctx->pmap == pmap, 3029 ("pmap %p different than ctx pmap %p", pmap, vmxctx->pmap)); 3030 3031 vmx_msr_guest_enter(vcpu); 3032 3033 VMPTRLD(vmcs); 3034 3035 /* 3036 * XXX 3037 * We do this every time because we may setup the virtual machine 3038 * from a different process than the one that actually runs it. 3039 * 3040 * If the life of a virtual machine was spent entirely in the context 3041 * of a single process we could do this once in vmx_init(). 3042 */ 3043 vmcs_write(VMCS_HOST_CR3, rcr3()); 3044 3045 vmcs_write(VMCS_GUEST_RIP, rip); 3046 vmx_set_pcpu_defaults(vmx, vcpu, pmap); 3047 do { 3048 KASSERT(vmcs_guest_rip() == rip, ("%s: vmcs guest rip mismatch " 3049 "%#lx/%#lx", __func__, vmcs_guest_rip(), rip)); 3050 3051 handled = UNHANDLED; 3052 /* 3053 * Interrupts are disabled from this point on until the 3054 * guest starts executing. This is done for the following 3055 * reasons: 3056 * 3057 * If an AST is asserted on this thread after the check below, 3058 * then the IPI_AST notification will not be lost, because it 3059 * will cause a VM exit due to external interrupt as soon as 3060 * the guest state is loaded. 3061 * 3062 * A posted interrupt after 'vmx_inject_interrupts()' will 3063 * not be "lost" because it will be held pending in the host 3064 * APIC because interrupts are disabled. The pending interrupt 3065 * will be recognized as soon as the guest state is loaded. 3066 * 3067 * The same reasoning applies to the IPI generated by 3068 * pmap_invalidate_ept(). 3069 */ 3070 disable_intr(); 3071 vmx_inject_interrupts(vcpu, vlapic, rip); 3072 3073 /* 3074 * Check for vcpu suspension after injecting events because 3075 * vmx_inject_interrupts() can suspend the vcpu due to a 3076 * triple fault. 3077 */ 3078 if (vcpu_suspended(evinfo)) { 3079 enable_intr(); 3080 vm_exit_suspended(vcpu->vcpu, rip); 3081 break; 3082 } 3083 3084 if (vcpu_rendezvous_pending(vcpu->vcpu, evinfo)) { 3085 enable_intr(); 3086 vm_exit_rendezvous(vcpu->vcpu, rip); 3087 break; 3088 } 3089 3090 if (vcpu_reqidle(evinfo)) { 3091 enable_intr(); 3092 vm_exit_reqidle(vcpu->vcpu, rip); 3093 break; 3094 } 3095 3096 if (vcpu_should_yield(vcpu->vcpu)) { 3097 enable_intr(); 3098 vm_exit_astpending(vcpu->vcpu, rip); 3099 vmx_astpending_trace(vcpu, rip); 3100 handled = HANDLED; 3101 break; 3102 } 3103 3104 if (vcpu_debugged(vcpu->vcpu)) { 3105 enable_intr(); 3106 vm_exit_debug(vcpu->vcpu, rip); 3107 break; 3108 } 3109 3110 /* 3111 * If TPR Shadowing is enabled, the TPR Threshold 3112 * must be updated right before entering the guest. 3113 */ 3114 if (tpr_shadowing && !virtual_interrupt_delivery) { 3115 if ((vcpu->cap.proc_ctls & PROCBASED_USE_TPR_SHADOW) != 0) { 3116 vmcs_write(VMCS_TPR_THRESHOLD, vlapic_get_cr8(vlapic)); 3117 } 3118 } 3119 3120 /* 3121 * VM exits restore the base address but not the 3122 * limits of GDTR and IDTR. The VMCS only stores the 3123 * base address, so VM exits set the limits to 0xffff. 3124 * Save and restore the full GDTR and IDTR to restore 3125 * the limits. 3126 * 3127 * The VMCS does not save the LDTR at all, and VM 3128 * exits clear LDTR as if a NULL selector were loaded. 3129 * The userspace hypervisor probably doesn't use a 3130 * LDT, but save and restore it to be safe. 3131 */ 3132 sgdt(&gdtr); 3133 sidt(&idtr); 3134 ldt_sel = sldt(); 3135 3136 /* 3137 * The TSC_AUX MSR must be saved/restored while interrupts 3138 * are disabled so that it is not possible for the guest 3139 * TSC_AUX MSR value to be overwritten by the resume 3140 * portion of the IPI_SUSPEND codepath. This is why the 3141 * transition of this MSR is handled separately from those 3142 * handled by vmx_msr_guest_{enter,exit}(), which are ok to 3143 * be transitioned with preemption disabled but interrupts 3144 * enabled. 3145 * 3146 * These vmx_msr_guest_{enter,exit}_tsc_aux() calls can be 3147 * anywhere in this loop so long as they happen with 3148 * interrupts disabled. This location is chosen for 3149 * simplicity. 3150 */ 3151 vmx_msr_guest_enter_tsc_aux(vmx, vcpu); 3152 3153 vmx_dr_enter_guest(vmxctx); 3154 3155 /* 3156 * Mark the EPT as active on this host CPU and invalidate 3157 * EPTP-tagged TLB entries if required. 3158 */ 3159 vmx_pmap_activate(vmx, pmap); 3160 3161 vmx_run_trace(vcpu); 3162 rc = vmx_enter_guest(vmxctx, vmx, launched); 3163 3164 vmx_pmap_deactivate(vmx, pmap); 3165 vmx_dr_leave_guest(vmxctx); 3166 vmx_msr_guest_exit_tsc_aux(vmx, vcpu); 3167 3168 bare_lgdt(&gdtr); 3169 lidt(&idtr); 3170 lldt(ldt_sel); 3171 3172 /* Collect some information for VM exit processing */ 3173 vmexit->rip = rip = vmcs_guest_rip(); 3174 vmexit->inst_length = vmexit_instruction_length(); 3175 vmexit->u.vmx.exit_reason = exit_reason = vmcs_exit_reason(); 3176 vmexit->u.vmx.exit_qualification = vmcs_exit_qualification(); 3177 3178 /* Update 'nextrip' */ 3179 vcpu->state.nextrip = rip; 3180 3181 if (rc == VMX_GUEST_VMEXIT) { 3182 vmx_exit_handle_nmi(vcpu, vmexit); 3183 enable_intr(); 3184 handled = vmx_exit_process(vmx, vcpu, vmexit); 3185 } else { 3186 enable_intr(); 3187 vmx_exit_inst_error(vmxctx, rc, vmexit); 3188 } 3189 launched = 1; 3190 vmx_exit_trace(vcpu, rip, exit_reason, handled); 3191 rip = vmexit->rip; 3192 } while (handled); 3193 3194 /* 3195 * If a VM exit has been handled then the exitcode must be BOGUS 3196 * If a VM exit is not handled then the exitcode must not be BOGUS 3197 */ 3198 if ((handled && vmexit->exitcode != VM_EXITCODE_BOGUS) || 3199 (!handled && vmexit->exitcode == VM_EXITCODE_BOGUS)) { 3200 panic("Mismatch between handled (%d) and exitcode (%d)", 3201 handled, vmexit->exitcode); 3202 } 3203 3204 VMX_CTR1(vcpu, "returning from vmx_run: exitcode %d", 3205 vmexit->exitcode); 3206 3207 VMCLEAR(vmcs); 3208 vmx_msr_guest_exit(vcpu); 3209 3210 return (0); 3211 } 3212 3213 static void 3214 vmx_vcpu_cleanup(void *vcpui) 3215 { 3216 struct vmx_vcpu *vcpu = vcpui; 3217 3218 vpid_free(vcpu->state.vpid); 3219 free(vcpu->pir_desc, M_VMX); 3220 free(vcpu->apic_page, M_VMX); 3221 free(vcpu->vmcs, M_VMX); 3222 free(vcpu, M_VMX); 3223 } 3224 3225 static void 3226 vmx_cleanup(void *vmi) 3227 { 3228 struct vmx *vmx = vmi; 3229 3230 if (virtual_interrupt_delivery) 3231 vm_unmap_mmio(vmx->vm, DEFAULT_APIC_BASE, PAGE_SIZE); 3232 3233 free(vmx->msr_bitmap, M_VMX); 3234 free(vmx, M_VMX); 3235 3236 return; 3237 } 3238 3239 static register_t * 3240 vmxctx_regptr(struct vmxctx *vmxctx, int reg) 3241 { 3242 3243 switch (reg) { 3244 case VM_REG_GUEST_RAX: 3245 return (&vmxctx->guest_rax); 3246 case VM_REG_GUEST_RBX: 3247 return (&vmxctx->guest_rbx); 3248 case VM_REG_GUEST_RCX: 3249 return (&vmxctx->guest_rcx); 3250 case VM_REG_GUEST_RDX: 3251 return (&vmxctx->guest_rdx); 3252 case VM_REG_GUEST_RSI: 3253 return (&vmxctx->guest_rsi); 3254 case VM_REG_GUEST_RDI: 3255 return (&vmxctx->guest_rdi); 3256 case VM_REG_GUEST_RBP: 3257 return (&vmxctx->guest_rbp); 3258 case VM_REG_GUEST_R8: 3259 return (&vmxctx->guest_r8); 3260 case VM_REG_GUEST_R9: 3261 return (&vmxctx->guest_r9); 3262 case VM_REG_GUEST_R10: 3263 return (&vmxctx->guest_r10); 3264 case VM_REG_GUEST_R11: 3265 return (&vmxctx->guest_r11); 3266 case VM_REG_GUEST_R12: 3267 return (&vmxctx->guest_r12); 3268 case VM_REG_GUEST_R13: 3269 return (&vmxctx->guest_r13); 3270 case VM_REG_GUEST_R14: 3271 return (&vmxctx->guest_r14); 3272 case VM_REG_GUEST_R15: 3273 return (&vmxctx->guest_r15); 3274 case VM_REG_GUEST_CR2: 3275 return (&vmxctx->guest_cr2); 3276 case VM_REG_GUEST_DR0: 3277 return (&vmxctx->guest_dr0); 3278 case VM_REG_GUEST_DR1: 3279 return (&vmxctx->guest_dr1); 3280 case VM_REG_GUEST_DR2: 3281 return (&vmxctx->guest_dr2); 3282 case VM_REG_GUEST_DR3: 3283 return (&vmxctx->guest_dr3); 3284 case VM_REG_GUEST_DR6: 3285 return (&vmxctx->guest_dr6); 3286 default: 3287 break; 3288 } 3289 return (NULL); 3290 } 3291 3292 static int 3293 vmxctx_getreg(struct vmxctx *vmxctx, int reg, uint64_t *retval) 3294 { 3295 register_t *regp; 3296 3297 if ((regp = vmxctx_regptr(vmxctx, reg)) != NULL) { 3298 *retval = *regp; 3299 return (0); 3300 } else 3301 return (EINVAL); 3302 } 3303 3304 static int 3305 vmxctx_setreg(struct vmxctx *vmxctx, int reg, uint64_t val) 3306 { 3307 register_t *regp; 3308 3309 if ((regp = vmxctx_regptr(vmxctx, reg)) != NULL) { 3310 *regp = val; 3311 return (0); 3312 } else 3313 return (EINVAL); 3314 } 3315 3316 static int 3317 vmx_get_intr_shadow(struct vmx_vcpu *vcpu, int running, uint64_t *retval) 3318 { 3319 uint64_t gi; 3320 int error; 3321 3322 error = vmcs_getreg(vcpu->vmcs, running, 3323 VMCS_IDENT(VMCS_GUEST_INTERRUPTIBILITY), &gi); 3324 *retval = (gi & HWINTR_BLOCKING) ? 1 : 0; 3325 return (error); 3326 } 3327 3328 static int 3329 vmx_modify_intr_shadow(struct vmx_vcpu *vcpu, int running, uint64_t val) 3330 { 3331 struct vmcs *vmcs; 3332 uint64_t gi; 3333 int error, ident; 3334 3335 /* 3336 * Forcing the vcpu into an interrupt shadow is not supported. 3337 */ 3338 if (val) { 3339 error = EINVAL; 3340 goto done; 3341 } 3342 3343 vmcs = vcpu->vmcs; 3344 ident = VMCS_IDENT(VMCS_GUEST_INTERRUPTIBILITY); 3345 error = vmcs_getreg(vmcs, running, ident, &gi); 3346 if (error == 0) { 3347 gi &= ~HWINTR_BLOCKING; 3348 error = vmcs_setreg(vmcs, running, ident, gi); 3349 } 3350 done: 3351 VMX_CTR2(vcpu, "Setting intr_shadow to %#lx %s", val, 3352 error ? "failed" : "succeeded"); 3353 return (error); 3354 } 3355 3356 static int 3357 vmx_shadow_reg(int reg) 3358 { 3359 int shreg; 3360 3361 shreg = -1; 3362 3363 switch (reg) { 3364 case VM_REG_GUEST_CR0: 3365 shreg = VMCS_CR0_SHADOW; 3366 break; 3367 case VM_REG_GUEST_CR4: 3368 shreg = VMCS_CR4_SHADOW; 3369 break; 3370 default: 3371 break; 3372 } 3373 3374 return (shreg); 3375 } 3376 3377 static int 3378 vmx_getreg(void *vcpui, int reg, uint64_t *retval) 3379 { 3380 int running, hostcpu; 3381 struct vmx_vcpu *vcpu = vcpui; 3382 struct vmx *vmx = vcpu->vmx; 3383 3384 running = vcpu_is_running(vcpu->vcpu, &hostcpu); 3385 if (running && hostcpu != curcpu) 3386 panic("vmx_getreg: %s%d is running", vm_name(vmx->vm), 3387 vcpu->vcpuid); 3388 3389 if (reg == VM_REG_GUEST_INTR_SHADOW) 3390 return (vmx_get_intr_shadow(vcpu, running, retval)); 3391 3392 if (vmxctx_getreg(&vcpu->ctx, reg, retval) == 0) 3393 return (0); 3394 3395 return (vmcs_getreg(vcpu->vmcs, running, reg, retval)); 3396 } 3397 3398 static int 3399 vmx_setreg(void *vcpui, int reg, uint64_t val) 3400 { 3401 int error, hostcpu, running, shadow; 3402 uint64_t ctls; 3403 pmap_t pmap; 3404 struct vmx_vcpu *vcpu = vcpui; 3405 struct vmx *vmx = vcpu->vmx; 3406 3407 running = vcpu_is_running(vcpu->vcpu, &hostcpu); 3408 if (running && hostcpu != curcpu) 3409 panic("vmx_setreg: %s%d is running", vm_name(vmx->vm), 3410 vcpu->vcpuid); 3411 3412 if (reg == VM_REG_GUEST_INTR_SHADOW) 3413 return (vmx_modify_intr_shadow(vcpu, running, val)); 3414 3415 if (vmxctx_setreg(&vcpu->ctx, reg, val) == 0) 3416 return (0); 3417 3418 /* Do not permit user write access to VMCS fields by offset. */ 3419 if (reg < 0) 3420 return (EINVAL); 3421 3422 error = vmcs_setreg(vcpu->vmcs, running, reg, val); 3423 3424 if (error == 0) { 3425 /* 3426 * If the "load EFER" VM-entry control is 1 then the 3427 * value of EFER.LMA must be identical to "IA-32e mode guest" 3428 * bit in the VM-entry control. 3429 */ 3430 if ((entry_ctls & VM_ENTRY_LOAD_EFER) != 0 && 3431 (reg == VM_REG_GUEST_EFER)) { 3432 vmcs_getreg(vcpu->vmcs, running, 3433 VMCS_IDENT(VMCS_ENTRY_CTLS), &ctls); 3434 if (val & EFER_LMA) 3435 ctls |= VM_ENTRY_GUEST_LMA; 3436 else 3437 ctls &= ~VM_ENTRY_GUEST_LMA; 3438 vmcs_setreg(vcpu->vmcs, running, 3439 VMCS_IDENT(VMCS_ENTRY_CTLS), ctls); 3440 } 3441 3442 shadow = vmx_shadow_reg(reg); 3443 if (shadow > 0) { 3444 /* 3445 * Store the unmodified value in the shadow 3446 */ 3447 error = vmcs_setreg(vcpu->vmcs, running, 3448 VMCS_IDENT(shadow), val); 3449 } 3450 3451 if (reg == VM_REG_GUEST_CR3) { 3452 /* 3453 * Invalidate the guest vcpu's TLB mappings to emulate 3454 * the behavior of updating %cr3. 3455 * 3456 * XXX the processor retains global mappings when %cr3 3457 * is updated but vmx_invvpid() does not. 3458 */ 3459 pmap = vcpu->ctx.pmap; 3460 vmx_invvpid(vmx, vcpu, pmap, running); 3461 } 3462 } 3463 3464 return (error); 3465 } 3466 3467 static int 3468 vmx_getdesc(void *vcpui, int reg, struct seg_desc *desc) 3469 { 3470 int hostcpu, running; 3471 struct vmx_vcpu *vcpu = vcpui; 3472 struct vmx *vmx = vcpu->vmx; 3473 3474 running = vcpu_is_running(vcpu->vcpu, &hostcpu); 3475 if (running && hostcpu != curcpu) 3476 panic("vmx_getdesc: %s%d is running", vm_name(vmx->vm), 3477 vcpu->vcpuid); 3478 3479 return (vmcs_getdesc(vcpu->vmcs, running, reg, desc)); 3480 } 3481 3482 static int 3483 vmx_setdesc(void *vcpui, int reg, struct seg_desc *desc) 3484 { 3485 int hostcpu, running; 3486 struct vmx_vcpu *vcpu = vcpui; 3487 struct vmx *vmx = vcpu->vmx; 3488 3489 running = vcpu_is_running(vcpu->vcpu, &hostcpu); 3490 if (running && hostcpu != curcpu) 3491 panic("vmx_setdesc: %s%d is running", vm_name(vmx->vm), 3492 vcpu->vcpuid); 3493 3494 return (vmcs_setdesc(vcpu->vmcs, running, reg, desc)); 3495 } 3496 3497 static int 3498 vmx_getcap(void *vcpui, int type, int *retval) 3499 { 3500 struct vmx_vcpu *vcpu = vcpui; 3501 int vcap; 3502 int ret; 3503 3504 ret = ENOENT; 3505 3506 vcap = vcpu->cap.set; 3507 3508 switch (type) { 3509 case VM_CAP_HALT_EXIT: 3510 if (cap_halt_exit) 3511 ret = 0; 3512 break; 3513 case VM_CAP_PAUSE_EXIT: 3514 if (cap_pause_exit) 3515 ret = 0; 3516 break; 3517 case VM_CAP_MTRAP_EXIT: 3518 if (cap_monitor_trap) 3519 ret = 0; 3520 break; 3521 case VM_CAP_RDPID: 3522 if (cap_rdpid) 3523 ret = 0; 3524 break; 3525 case VM_CAP_RDTSCP: 3526 if (cap_rdtscp) 3527 ret = 0; 3528 break; 3529 case VM_CAP_UNRESTRICTED_GUEST: 3530 if (cap_unrestricted_guest) 3531 ret = 0; 3532 break; 3533 case VM_CAP_ENABLE_INVPCID: 3534 if (cap_invpcid) 3535 ret = 0; 3536 break; 3537 case VM_CAP_BPT_EXIT: 3538 case VM_CAP_IPI_EXIT: 3539 ret = 0; 3540 break; 3541 default: 3542 break; 3543 } 3544 3545 if (ret == 0) 3546 *retval = (vcap & (1 << type)) ? 1 : 0; 3547 3548 return (ret); 3549 } 3550 3551 static int 3552 vmx_setcap(void *vcpui, int type, int val) 3553 { 3554 struct vmx_vcpu *vcpu = vcpui; 3555 struct vmcs *vmcs = vcpu->vmcs; 3556 struct vlapic *vlapic; 3557 uint32_t baseval; 3558 uint32_t *pptr; 3559 int error; 3560 int flag; 3561 int reg; 3562 int retval; 3563 3564 retval = ENOENT; 3565 pptr = NULL; 3566 3567 switch (type) { 3568 case VM_CAP_HALT_EXIT: 3569 if (cap_halt_exit) { 3570 retval = 0; 3571 pptr = &vcpu->cap.proc_ctls; 3572 baseval = *pptr; 3573 flag = PROCBASED_HLT_EXITING; 3574 reg = VMCS_PRI_PROC_BASED_CTLS; 3575 } 3576 break; 3577 case VM_CAP_MTRAP_EXIT: 3578 if (cap_monitor_trap) { 3579 retval = 0; 3580 pptr = &vcpu->cap.proc_ctls; 3581 baseval = *pptr; 3582 flag = PROCBASED_MTF; 3583 reg = VMCS_PRI_PROC_BASED_CTLS; 3584 } 3585 break; 3586 case VM_CAP_PAUSE_EXIT: 3587 if (cap_pause_exit) { 3588 retval = 0; 3589 pptr = &vcpu->cap.proc_ctls; 3590 baseval = *pptr; 3591 flag = PROCBASED_PAUSE_EXITING; 3592 reg = VMCS_PRI_PROC_BASED_CTLS; 3593 } 3594 break; 3595 case VM_CAP_RDPID: 3596 case VM_CAP_RDTSCP: 3597 if (cap_rdpid || cap_rdtscp) 3598 /* 3599 * Choose not to support enabling/disabling 3600 * RDPID/RDTSCP via libvmmapi since, as per the 3601 * discussion in vmx_modinit(), RDPID/RDTSCP are 3602 * either always enabled or always disabled. 3603 */ 3604 error = EOPNOTSUPP; 3605 break; 3606 case VM_CAP_UNRESTRICTED_GUEST: 3607 if (cap_unrestricted_guest) { 3608 retval = 0; 3609 pptr = &vcpu->cap.proc_ctls2; 3610 baseval = *pptr; 3611 flag = PROCBASED2_UNRESTRICTED_GUEST; 3612 reg = VMCS_SEC_PROC_BASED_CTLS; 3613 } 3614 break; 3615 case VM_CAP_ENABLE_INVPCID: 3616 if (cap_invpcid) { 3617 retval = 0; 3618 pptr = &vcpu->cap.proc_ctls2; 3619 baseval = *pptr; 3620 flag = PROCBASED2_ENABLE_INVPCID; 3621 reg = VMCS_SEC_PROC_BASED_CTLS; 3622 } 3623 break; 3624 case VM_CAP_BPT_EXIT: 3625 retval = 0; 3626 3627 /* Don't change the bitmap if we are tracing all exceptions. */ 3628 if (vcpu->cap.exc_bitmap != 0xffffffff) { 3629 pptr = &vcpu->cap.exc_bitmap; 3630 baseval = *pptr; 3631 flag = (1 << IDT_BP); 3632 reg = VMCS_EXCEPTION_BITMAP; 3633 } 3634 break; 3635 case VM_CAP_IPI_EXIT: 3636 retval = 0; 3637 3638 vlapic = vm_lapic(vcpu->vcpu); 3639 vlapic->ipi_exit = val; 3640 break; 3641 case VM_CAP_MASK_HWINTR: 3642 retval = 0; 3643 break; 3644 default: 3645 break; 3646 } 3647 3648 if (retval) 3649 return (retval); 3650 3651 if (pptr != NULL) { 3652 if (val) { 3653 baseval |= flag; 3654 } else { 3655 baseval &= ~flag; 3656 } 3657 VMPTRLD(vmcs); 3658 error = vmwrite(reg, baseval); 3659 VMCLEAR(vmcs); 3660 3661 if (error) 3662 return (error); 3663 3664 /* 3665 * Update optional stored flags, and record 3666 * setting 3667 */ 3668 *pptr = baseval; 3669 } 3670 3671 if (val) { 3672 vcpu->cap.set |= (1 << type); 3673 } else { 3674 vcpu->cap.set &= ~(1 << type); 3675 } 3676 3677 return (0); 3678 } 3679 3680 static struct vmspace * 3681 vmx_vmspace_alloc(vm_offset_t min, vm_offset_t max) 3682 { 3683 return (ept_vmspace_alloc(min, max)); 3684 } 3685 3686 static void 3687 vmx_vmspace_free(struct vmspace *vmspace) 3688 { 3689 ept_vmspace_free(vmspace); 3690 } 3691 3692 struct vlapic_vtx { 3693 struct vlapic vlapic; 3694 struct pir_desc *pir_desc; 3695 struct vmx_vcpu *vcpu; 3696 u_int pending_prio; 3697 }; 3698 3699 #define VPR_PRIO_BIT(vpr) (1 << ((vpr) >> 4)) 3700 3701 #define VMX_CTR_PIR(vlapic, pir_desc, notify, vector, level, msg) \ 3702 do { \ 3703 VLAPIC_CTR2(vlapic, msg " assert %s-triggered vector %d", \ 3704 level ? "level" : "edge", vector); \ 3705 VLAPIC_CTR1(vlapic, msg " pir0 0x%016lx", pir_desc->pir[0]); \ 3706 VLAPIC_CTR1(vlapic, msg " pir1 0x%016lx", pir_desc->pir[1]); \ 3707 VLAPIC_CTR1(vlapic, msg " pir2 0x%016lx", pir_desc->pir[2]); \ 3708 VLAPIC_CTR1(vlapic, msg " pir3 0x%016lx", pir_desc->pir[3]); \ 3709 VLAPIC_CTR1(vlapic, msg " notify: %s", notify ? "yes" : "no"); \ 3710 } while (0) 3711 3712 /* 3713 * vlapic->ops handlers that utilize the APICv hardware assist described in 3714 * Chapter 29 of the Intel SDM. 3715 */ 3716 static int 3717 vmx_set_intr_ready(struct vlapic *vlapic, int vector, bool level) 3718 { 3719 struct vlapic_vtx *vlapic_vtx; 3720 struct pir_desc *pir_desc; 3721 uint64_t mask; 3722 int idx, notify = 0; 3723 3724 vlapic_vtx = (struct vlapic_vtx *)vlapic; 3725 pir_desc = vlapic_vtx->pir_desc; 3726 3727 /* 3728 * Keep track of interrupt requests in the PIR descriptor. This is 3729 * because the virtual APIC page pointed to by the VMCS cannot be 3730 * modified if the vcpu is running. 3731 */ 3732 idx = vector / 64; 3733 mask = 1UL << (vector % 64); 3734 atomic_set_long(&pir_desc->pir[idx], mask); 3735 3736 /* 3737 * A notification is required whenever the 'pending' bit makes a 3738 * transition from 0->1. 3739 * 3740 * Even if the 'pending' bit is already asserted, notification about 3741 * the incoming interrupt may still be necessary. For example, if a 3742 * vCPU is HLTed with a high PPR, a low priority interrupt would cause 3743 * the 0->1 'pending' transition with a notification, but the vCPU 3744 * would ignore the interrupt for the time being. The same vCPU would 3745 * need to then be notified if a high-priority interrupt arrived which 3746 * satisfied the PPR. 3747 * 3748 * The priorities of interrupts injected while 'pending' is asserted 3749 * are tracked in a custom bitfield 'pending_prio'. Should the 3750 * to-be-injected interrupt exceed the priorities already present, the 3751 * notification is sent. The priorities recorded in 'pending_prio' are 3752 * cleared whenever the 'pending' bit makes another 0->1 transition. 3753 */ 3754 if (atomic_cmpset_long(&pir_desc->pending, 0, 1) != 0) { 3755 notify = 1; 3756 vlapic_vtx->pending_prio = 0; 3757 } else { 3758 const u_int old_prio = vlapic_vtx->pending_prio; 3759 const u_int prio_bit = VPR_PRIO_BIT(vector & APIC_TPR_INT); 3760 3761 if ((old_prio & prio_bit) == 0 && prio_bit > old_prio) { 3762 atomic_set_int(&vlapic_vtx->pending_prio, prio_bit); 3763 notify = 1; 3764 } 3765 } 3766 3767 VMX_CTR_PIR(vlapic, pir_desc, notify, vector, level, 3768 "vmx_set_intr_ready"); 3769 return (notify); 3770 } 3771 3772 static int 3773 vmx_pending_intr(struct vlapic *vlapic, int *vecptr) 3774 { 3775 struct vlapic_vtx *vlapic_vtx; 3776 struct pir_desc *pir_desc; 3777 struct LAPIC *lapic; 3778 uint64_t pending, pirval; 3779 uint8_t ppr, vpr, rvi; 3780 struct vm_exit *vmexit; 3781 int i; 3782 3783 /* 3784 * This function is only expected to be called from the 'HLT' exit 3785 * handler which does not care about the vector that is pending. 3786 */ 3787 KASSERT(vecptr == NULL, ("vmx_pending_intr: vecptr must be NULL")); 3788 3789 vlapic_vtx = (struct vlapic_vtx *)vlapic; 3790 pir_desc = vlapic_vtx->pir_desc; 3791 lapic = vlapic->apic_page; 3792 3793 /* 3794 * While a virtual interrupt may have already been 3795 * processed the actual delivery maybe pending the 3796 * interruptibility of the guest. Recognize a pending 3797 * interrupt by reevaluating virtual interrupts 3798 * following Section 30.2.1 in the Intel SDM Volume 3. 3799 */ 3800 vmexit = vm_exitinfo(vlapic->vcpu); 3801 KASSERT(vmexit->exitcode == VM_EXITCODE_HLT, 3802 ("vmx_pending_intr: exitcode not 'HLT'")); 3803 rvi = vmexit->u.hlt.intr_status & APIC_TPR_INT; 3804 ppr = lapic->ppr & APIC_TPR_INT; 3805 if (rvi > ppr) 3806 return (1); 3807 3808 pending = atomic_load_acq_long(&pir_desc->pending); 3809 if (!pending) 3810 return (0); 3811 3812 /* 3813 * If there is an interrupt pending then it will be recognized only 3814 * if its priority is greater than the processor priority. 3815 * 3816 * Special case: if the processor priority is zero then any pending 3817 * interrupt will be recognized. 3818 */ 3819 if (ppr == 0) 3820 return (1); 3821 3822 VLAPIC_CTR1(vlapic, "HLT with non-zero PPR %d", lapic->ppr); 3823 3824 vpr = 0; 3825 for (i = 3; i >= 0; i--) { 3826 pirval = pir_desc->pir[i]; 3827 if (pirval != 0) { 3828 vpr = (i * 64 + flsl(pirval) - 1) & APIC_TPR_INT; 3829 break; 3830 } 3831 } 3832 3833 /* 3834 * If the highest-priority pending interrupt falls short of the 3835 * processor priority of this vCPU, ensure that 'pending_prio' does not 3836 * have any stale bits which would preclude a higher-priority interrupt 3837 * from incurring a notification later. 3838 */ 3839 if (vpr <= ppr) { 3840 const u_int prio_bit = VPR_PRIO_BIT(vpr); 3841 const u_int old = vlapic_vtx->pending_prio; 3842 3843 if (old > prio_bit && (old & prio_bit) == 0) { 3844 vlapic_vtx->pending_prio = prio_bit; 3845 } 3846 return (0); 3847 } 3848 return (1); 3849 } 3850 3851 static void 3852 vmx_intr_accepted(struct vlapic *vlapic, int vector) 3853 { 3854 3855 panic("vmx_intr_accepted: not expected to be called"); 3856 } 3857 3858 static void 3859 vmx_set_tmr(struct vlapic *vlapic, int vector, bool level) 3860 { 3861 struct vlapic_vtx *vlapic_vtx; 3862 struct vmcs *vmcs; 3863 uint64_t mask, val; 3864 3865 KASSERT(vector >= 0 && vector <= 255, ("invalid vector %d", vector)); 3866 KASSERT(!vcpu_is_running(vlapic->vcpu, NULL), 3867 ("vmx_set_tmr: vcpu cannot be running")); 3868 3869 vlapic_vtx = (struct vlapic_vtx *)vlapic; 3870 vmcs = vlapic_vtx->vcpu->vmcs; 3871 mask = 1UL << (vector % 64); 3872 3873 VMPTRLD(vmcs); 3874 val = vmcs_read(VMCS_EOI_EXIT(vector)); 3875 if (level) 3876 val |= mask; 3877 else 3878 val &= ~mask; 3879 vmcs_write(VMCS_EOI_EXIT(vector), val); 3880 VMCLEAR(vmcs); 3881 } 3882 3883 static void 3884 vmx_enable_x2apic_mode_ts(struct vlapic *vlapic) 3885 { 3886 struct vlapic_vtx *vlapic_vtx; 3887 struct vmx_vcpu *vcpu; 3888 struct vmcs *vmcs; 3889 uint32_t proc_ctls; 3890 3891 vlapic_vtx = (struct vlapic_vtx *)vlapic; 3892 vcpu = vlapic_vtx->vcpu; 3893 vmcs = vcpu->vmcs; 3894 3895 proc_ctls = vcpu->cap.proc_ctls; 3896 proc_ctls &= ~PROCBASED_USE_TPR_SHADOW; 3897 proc_ctls |= PROCBASED_CR8_LOAD_EXITING; 3898 proc_ctls |= PROCBASED_CR8_STORE_EXITING; 3899 vcpu->cap.proc_ctls = proc_ctls; 3900 3901 VMPTRLD(vmcs); 3902 vmcs_write(VMCS_PRI_PROC_BASED_CTLS, proc_ctls); 3903 VMCLEAR(vmcs); 3904 } 3905 3906 static void 3907 vmx_enable_x2apic_mode_vid(struct vlapic *vlapic) 3908 { 3909 struct vlapic_vtx *vlapic_vtx; 3910 struct vmx *vmx; 3911 struct vmx_vcpu *vcpu; 3912 struct vmcs *vmcs; 3913 uint32_t proc_ctls2; 3914 int error __diagused; 3915 3916 vlapic_vtx = (struct vlapic_vtx *)vlapic; 3917 vcpu = vlapic_vtx->vcpu; 3918 vmx = vcpu->vmx; 3919 vmcs = vcpu->vmcs; 3920 3921 proc_ctls2 = vcpu->cap.proc_ctls2; 3922 KASSERT((proc_ctls2 & PROCBASED2_VIRTUALIZE_APIC_ACCESSES) != 0, 3923 ("%s: invalid proc_ctls2 %#x", __func__, proc_ctls2)); 3924 3925 proc_ctls2 &= ~PROCBASED2_VIRTUALIZE_APIC_ACCESSES; 3926 proc_ctls2 |= PROCBASED2_VIRTUALIZE_X2APIC_MODE; 3927 vcpu->cap.proc_ctls2 = proc_ctls2; 3928 3929 VMPTRLD(vmcs); 3930 vmcs_write(VMCS_SEC_PROC_BASED_CTLS, proc_ctls2); 3931 VMCLEAR(vmcs); 3932 3933 if (vlapic->vcpuid == 0) { 3934 /* 3935 * The nested page table mappings are shared by all vcpus 3936 * so unmap the APIC access page just once. 3937 */ 3938 error = vm_unmap_mmio(vmx->vm, DEFAULT_APIC_BASE, PAGE_SIZE); 3939 KASSERT(error == 0, ("%s: vm_unmap_mmio error %d", 3940 __func__, error)); 3941 3942 /* 3943 * The MSR bitmap is shared by all vcpus so modify it only 3944 * once in the context of vcpu 0. 3945 */ 3946 error = vmx_allow_x2apic_msrs(vmx); 3947 KASSERT(error == 0, ("%s: vmx_allow_x2apic_msrs error %d", 3948 __func__, error)); 3949 } 3950 } 3951 3952 static void 3953 vmx_post_intr(struct vlapic *vlapic, int hostcpu) 3954 { 3955 3956 ipi_cpu(hostcpu, pirvec); 3957 } 3958 3959 /* 3960 * Transfer the pending interrupts in the PIR descriptor to the IRR 3961 * in the virtual APIC page. 3962 */ 3963 static void 3964 vmx_inject_pir(struct vlapic *vlapic) 3965 { 3966 struct vlapic_vtx *vlapic_vtx; 3967 struct pir_desc *pir_desc; 3968 struct LAPIC *lapic; 3969 uint64_t val, pirval; 3970 int rvi, pirbase = -1; 3971 uint16_t intr_status_old, intr_status_new; 3972 3973 vlapic_vtx = (struct vlapic_vtx *)vlapic; 3974 pir_desc = vlapic_vtx->pir_desc; 3975 if (atomic_cmpset_long(&pir_desc->pending, 1, 0) == 0) { 3976 VLAPIC_CTR0(vlapic, "vmx_inject_pir: " 3977 "no posted interrupt pending"); 3978 return; 3979 } 3980 3981 pirval = 0; 3982 pirbase = -1; 3983 lapic = vlapic->apic_page; 3984 3985 val = atomic_readandclear_long(&pir_desc->pir[0]); 3986 if (val != 0) { 3987 lapic->irr0 |= val; 3988 lapic->irr1 |= val >> 32; 3989 pirbase = 0; 3990 pirval = val; 3991 } 3992 3993 val = atomic_readandclear_long(&pir_desc->pir[1]); 3994 if (val != 0) { 3995 lapic->irr2 |= val; 3996 lapic->irr3 |= val >> 32; 3997 pirbase = 64; 3998 pirval = val; 3999 } 4000 4001 val = atomic_readandclear_long(&pir_desc->pir[2]); 4002 if (val != 0) { 4003 lapic->irr4 |= val; 4004 lapic->irr5 |= val >> 32; 4005 pirbase = 128; 4006 pirval = val; 4007 } 4008 4009 val = atomic_readandclear_long(&pir_desc->pir[3]); 4010 if (val != 0) { 4011 lapic->irr6 |= val; 4012 lapic->irr7 |= val >> 32; 4013 pirbase = 192; 4014 pirval = val; 4015 } 4016 4017 VLAPIC_CTR_IRR(vlapic, "vmx_inject_pir"); 4018 4019 /* 4020 * Update RVI so the processor can evaluate pending virtual 4021 * interrupts on VM-entry. 4022 * 4023 * It is possible for pirval to be 0 here, even though the 4024 * pending bit has been set. The scenario is: 4025 * CPU-Y is sending a posted interrupt to CPU-X, which 4026 * is running a guest and processing posted interrupts in h/w. 4027 * CPU-X will eventually exit and the state seen in s/w is 4028 * the pending bit set, but no PIR bits set. 4029 * 4030 * CPU-X CPU-Y 4031 * (vm running) (host running) 4032 * rx posted interrupt 4033 * CLEAR pending bit 4034 * SET PIR bit 4035 * READ/CLEAR PIR bits 4036 * SET pending bit 4037 * (vm exit) 4038 * pending bit set, PIR 0 4039 */ 4040 if (pirval != 0) { 4041 rvi = pirbase + flsl(pirval) - 1; 4042 intr_status_old = vmcs_read(VMCS_GUEST_INTR_STATUS); 4043 intr_status_new = (intr_status_old & 0xFF00) | rvi; 4044 if (intr_status_new > intr_status_old) { 4045 vmcs_write(VMCS_GUEST_INTR_STATUS, intr_status_new); 4046 VLAPIC_CTR2(vlapic, "vmx_inject_pir: " 4047 "guest_intr_status changed from 0x%04x to 0x%04x", 4048 intr_status_old, intr_status_new); 4049 } 4050 } 4051 } 4052 4053 static struct vlapic * 4054 vmx_vlapic_init(void *vcpui) 4055 { 4056 struct vmx *vmx; 4057 struct vmx_vcpu *vcpu; 4058 struct vlapic *vlapic; 4059 struct vlapic_vtx *vlapic_vtx; 4060 4061 vcpu = vcpui; 4062 vmx = vcpu->vmx; 4063 4064 vlapic = malloc(sizeof(struct vlapic_vtx), M_VLAPIC, M_WAITOK | M_ZERO); 4065 vlapic->vm = vmx->vm; 4066 vlapic->vcpu = vcpu->vcpu; 4067 vlapic->vcpuid = vcpu->vcpuid; 4068 vlapic->apic_page = (struct LAPIC *)vcpu->apic_page; 4069 4070 vlapic_vtx = (struct vlapic_vtx *)vlapic; 4071 vlapic_vtx->pir_desc = vcpu->pir_desc; 4072 vlapic_vtx->vcpu = vcpu; 4073 4074 if (tpr_shadowing) { 4075 vlapic->ops.enable_x2apic_mode = vmx_enable_x2apic_mode_ts; 4076 } 4077 4078 if (virtual_interrupt_delivery) { 4079 vlapic->ops.set_intr_ready = vmx_set_intr_ready; 4080 vlapic->ops.pending_intr = vmx_pending_intr; 4081 vlapic->ops.intr_accepted = vmx_intr_accepted; 4082 vlapic->ops.set_tmr = vmx_set_tmr; 4083 vlapic->ops.enable_x2apic_mode = vmx_enable_x2apic_mode_vid; 4084 } 4085 4086 if (posted_interrupts) 4087 vlapic->ops.post_intr = vmx_post_intr; 4088 4089 vlapic_init(vlapic); 4090 4091 return (vlapic); 4092 } 4093 4094 static void 4095 vmx_vlapic_cleanup(struct vlapic *vlapic) 4096 { 4097 4098 vlapic_cleanup(vlapic); 4099 free(vlapic, M_VLAPIC); 4100 } 4101 4102 #ifdef BHYVE_SNAPSHOT 4103 static int 4104 vmx_vcpu_snapshot(void *vcpui, struct vm_snapshot_meta *meta) 4105 { 4106 struct vmcs *vmcs; 4107 struct vmx *vmx; 4108 struct vmx_vcpu *vcpu; 4109 struct vmxctx *vmxctx; 4110 int err, run, hostcpu; 4111 4112 err = 0; 4113 vcpu = vcpui; 4114 vmx = vcpu->vmx; 4115 vmcs = vcpu->vmcs; 4116 4117 run = vcpu_is_running(vcpu->vcpu, &hostcpu); 4118 if (run && hostcpu != curcpu) { 4119 printf("%s: %s%d is running", __func__, vm_name(vmx->vm), 4120 vcpu->vcpuid); 4121 return (EINVAL); 4122 } 4123 4124 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_CR0, meta); 4125 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_CR3, meta); 4126 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_CR4, meta); 4127 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_DR7, meta); 4128 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_RSP, meta); 4129 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_RIP, meta); 4130 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_RFLAGS, meta); 4131 4132 /* Guest segments */ 4133 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_ES, meta); 4134 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_ES, meta); 4135 4136 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_CS, meta); 4137 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_CS, meta); 4138 4139 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_SS, meta); 4140 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_SS, meta); 4141 4142 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_DS, meta); 4143 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_DS, meta); 4144 4145 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_FS, meta); 4146 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_FS, meta); 4147 4148 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_GS, meta); 4149 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_GS, meta); 4150 4151 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_TR, meta); 4152 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_TR, meta); 4153 4154 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_LDTR, meta); 4155 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_LDTR, meta); 4156 4157 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_EFER, meta); 4158 4159 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_IDTR, meta); 4160 err += vmcs_snapshot_desc(vmcs, run, VM_REG_GUEST_GDTR, meta); 4161 4162 /* Guest page tables */ 4163 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_PDPTE0, meta); 4164 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_PDPTE1, meta); 4165 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_PDPTE2, meta); 4166 err += vmcs_snapshot_reg(vmcs, run, VM_REG_GUEST_PDPTE3, meta); 4167 4168 /* Other guest state */ 4169 err += vmcs_snapshot_any(vmcs, run, VMCS_GUEST_IA32_SYSENTER_CS, meta); 4170 err += vmcs_snapshot_any(vmcs, run, VMCS_GUEST_IA32_SYSENTER_ESP, meta); 4171 err += vmcs_snapshot_any(vmcs, run, VMCS_GUEST_IA32_SYSENTER_EIP, meta); 4172 err += vmcs_snapshot_any(vmcs, run, VMCS_GUEST_INTERRUPTIBILITY, meta); 4173 err += vmcs_snapshot_any(vmcs, run, VMCS_GUEST_ACTIVITY, meta); 4174 err += vmcs_snapshot_any(vmcs, run, VMCS_ENTRY_CTLS, meta); 4175 err += vmcs_snapshot_any(vmcs, run, VMCS_EXIT_CTLS, meta); 4176 if (err != 0) 4177 goto done; 4178 4179 SNAPSHOT_BUF_OR_LEAVE(vcpu->guest_msrs, 4180 sizeof(vcpu->guest_msrs), meta, err, done); 4181 4182 SNAPSHOT_BUF_OR_LEAVE(vcpu->pir_desc, 4183 sizeof(*vcpu->pir_desc), meta, err, done); 4184 4185 vmxctx = &vcpu->ctx; 4186 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_rdi, meta, err, done); 4187 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_rsi, meta, err, done); 4188 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_rdx, meta, err, done); 4189 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_rcx, meta, err, done); 4190 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_r8, meta, err, done); 4191 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_r9, meta, err, done); 4192 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_rax, meta, err, done); 4193 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_rbx, meta, err, done); 4194 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_rbp, meta, err, done); 4195 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_r10, meta, err, done); 4196 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_r11, meta, err, done); 4197 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_r12, meta, err, done); 4198 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_r13, meta, err, done); 4199 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_r14, meta, err, done); 4200 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_r15, meta, err, done); 4201 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_cr2, meta, err, done); 4202 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_dr0, meta, err, done); 4203 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_dr1, meta, err, done); 4204 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_dr2, meta, err, done); 4205 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_dr3, meta, err, done); 4206 SNAPSHOT_VAR_OR_LEAVE(vmxctx->guest_dr6, meta, err, done); 4207 4208 done: 4209 return (err); 4210 } 4211 4212 static int 4213 vmx_restore_tsc(void *vcpui, uint64_t offset) 4214 { 4215 struct vmx_vcpu *vcpu = vcpui; 4216 struct vmcs *vmcs; 4217 struct vmx *vmx; 4218 int error, running, hostcpu; 4219 4220 vmx = vcpu->vmx; 4221 vmcs = vcpu->vmcs; 4222 4223 running = vcpu_is_running(vcpu->vcpu, &hostcpu); 4224 if (running && hostcpu != curcpu) { 4225 printf("%s: %s%d is running", __func__, vm_name(vmx->vm), 4226 vcpu->vcpuid); 4227 return (EINVAL); 4228 } 4229 4230 if (!running) 4231 VMPTRLD(vmcs); 4232 4233 error = vmx_set_tsc_offset(vcpu, offset); 4234 4235 if (!running) 4236 VMCLEAR(vmcs); 4237 return (error); 4238 } 4239 #endif 4240 4241 const struct vmm_ops vmm_ops_intel = { 4242 .modinit = vmx_modinit, 4243 .modcleanup = vmx_modcleanup, 4244 .modresume = vmx_modresume, 4245 .init = vmx_init, 4246 .run = vmx_run, 4247 .cleanup = vmx_cleanup, 4248 .vcpu_init = vmx_vcpu_init, 4249 .vcpu_cleanup = vmx_vcpu_cleanup, 4250 .getreg = vmx_getreg, 4251 .setreg = vmx_setreg, 4252 .getdesc = vmx_getdesc, 4253 .setdesc = vmx_setdesc, 4254 .getcap = vmx_getcap, 4255 .setcap = vmx_setcap, 4256 .vmspace_alloc = vmx_vmspace_alloc, 4257 .vmspace_free = vmx_vmspace_free, 4258 .vlapic_init = vmx_vlapic_init, 4259 .vlapic_cleanup = vmx_vlapic_cleanup, 4260 #ifdef BHYVE_SNAPSHOT 4261 .vcpu_snapshot = vmx_vcpu_snapshot, 4262 .restore_tsc = vmx_restore_tsc, 4263 #endif 4264 }; 4265