/* * QEMU Windows Hypervisor Platform accelerator (WHPX) * * Copyright Microsoft Corp. 2017 * * This work is licensed under the terms of the GNU GPL, version 2 or later. * See the COPYING file in the top-level directory. * */ #include "qemu/osdep.h" #include "cpu.h" #include "exec/address-spaces.h" #include "exec/ioport.h" #include "exec/gdbstub.h" #include "qemu/accel.h" #include "sysemu/whpx.h" #include "sysemu/cpus.h" #include "sysemu/runstate.h" #include "qemu/main-loop.h" #include "hw/boards.h" #include "hw/intc/ioapic.h" #include "hw/i386/apic_internal.h" #include "qemu/error-report.h" #include "qapi/error.h" #include "qapi/qapi-types-common.h" #include "qapi/qapi-visit-common.h" #include "migration/blocker.h" #include #include "whpx-internal.h" #include "whpx-accel-ops.h" #include #include #define HYPERV_APIC_BUS_FREQUENCY (200000000ULL) static const WHV_REGISTER_NAME whpx_register_names[] = { /* X64 General purpose registers */ WHvX64RegisterRax, WHvX64RegisterRcx, WHvX64RegisterRdx, WHvX64RegisterRbx, WHvX64RegisterRsp, WHvX64RegisterRbp, WHvX64RegisterRsi, WHvX64RegisterRdi, WHvX64RegisterR8, WHvX64RegisterR9, WHvX64RegisterR10, WHvX64RegisterR11, WHvX64RegisterR12, WHvX64RegisterR13, WHvX64RegisterR14, WHvX64RegisterR15, WHvX64RegisterRip, WHvX64RegisterRflags, /* X64 Segment registers */ WHvX64RegisterEs, WHvX64RegisterCs, WHvX64RegisterSs, WHvX64RegisterDs, WHvX64RegisterFs, WHvX64RegisterGs, WHvX64RegisterLdtr, WHvX64RegisterTr, /* X64 Table registers */ WHvX64RegisterIdtr, WHvX64RegisterGdtr, /* X64 Control Registers */ WHvX64RegisterCr0, WHvX64RegisterCr2, WHvX64RegisterCr3, WHvX64RegisterCr4, WHvX64RegisterCr8, /* X64 Debug Registers */ /* * WHvX64RegisterDr0, * WHvX64RegisterDr1, * WHvX64RegisterDr2, * WHvX64RegisterDr3, * WHvX64RegisterDr6, * WHvX64RegisterDr7, */ /* X64 Floating Point and Vector Registers */ WHvX64RegisterXmm0, WHvX64RegisterXmm1, WHvX64RegisterXmm2, WHvX64RegisterXmm3, WHvX64RegisterXmm4, WHvX64RegisterXmm5, WHvX64RegisterXmm6, WHvX64RegisterXmm7, WHvX64RegisterXmm8, WHvX64RegisterXmm9, WHvX64RegisterXmm10, WHvX64RegisterXmm11, WHvX64RegisterXmm12, WHvX64RegisterXmm13, WHvX64RegisterXmm14, WHvX64RegisterXmm15, WHvX64RegisterFpMmx0, WHvX64RegisterFpMmx1, WHvX64RegisterFpMmx2, WHvX64RegisterFpMmx3, WHvX64RegisterFpMmx4, WHvX64RegisterFpMmx5, WHvX64RegisterFpMmx6, WHvX64RegisterFpMmx7, WHvX64RegisterFpControlStatus, WHvX64RegisterXmmControlStatus, /* X64 MSRs */ WHvX64RegisterEfer, #ifdef TARGET_X86_64 WHvX64RegisterKernelGsBase, #endif WHvX64RegisterApicBase, /* WHvX64RegisterPat, */ WHvX64RegisterSysenterCs, WHvX64RegisterSysenterEip, WHvX64RegisterSysenterEsp, WHvX64RegisterStar, #ifdef TARGET_X86_64 WHvX64RegisterLstar, WHvX64RegisterCstar, WHvX64RegisterSfmask, #endif /* Interrupt / Event Registers */ /* * WHvRegisterPendingInterruption, * WHvRegisterInterruptState, * WHvRegisterPendingEvent0, * WHvRegisterPendingEvent1 * WHvX64RegisterDeliverabilityNotifications, */ }; struct whpx_register_set { WHV_REGISTER_VALUE values[RTL_NUMBER_OF(whpx_register_names)]; }; /* * The current implementation of instruction stepping sets the TF flag * in RFLAGS, causing the CPU to raise an INT1 after each instruction. * This corresponds to the WHvX64ExceptionTypeDebugTrapOrFault exception. * * This approach has a few limitations: * 1. Stepping over a PUSHF/SAHF instruction will save the TF flag * along with the other flags, possibly restoring it later. It would * result in another INT1 when the flags are restored, triggering * a stop in gdb that could be cleared by doing another step. * * Stepping over a POPF/LAHF instruction will let it overwrite the * TF flags, ending the stepping mode. * * 2. Stepping over an instruction raising an exception (e.g. INT, DIV, * or anything that could result in a page fault) will save the flags * to the stack, clear the TF flag, and let the guest execute the * handler. Normally, the guest will restore the original flags, * that will continue single-stepping. * * 3. Debuggers running on the guest may wish to set TF to do instruction * stepping. INT1 events generated by it would be intercepted by us, * as long as the gdb is connected to QEMU. * * In practice this means that: * 1. Stepping through flags-modifying instructions may cause gdb to * continue or stop in unexpected places. This will be fully recoverable * and will not crash the target. * * 2. Stepping over an instruction that triggers an exception will step * over the exception handler, not into it. * * 3. Debugging the guest via gdb, while running debugger on the guest * at the same time may lead to unexpected effects. Removing all * breakpoints set via QEMU will prevent any further interference * with the guest-level debuggers. * * The limitations can be addressed as shown below: * 1. PUSHF/SAHF/POPF/LAHF/IRET instructions can be emulated instead of * stepping through them. The exact semantics of the instructions is * defined in the "Combined Volume Set of Intel 64 and IA-32 * Architectures Software Developer's Manuals", however it involves a * fair amount of corner cases due to compatibility with real mode, * virtual 8086 mode, and differences between 64-bit and 32-bit modes. * * 2. We could step into the guest's exception handlers using the following * sequence: * a. Temporarily enable catching of all exception types via * whpx_set_exception_exit_bitmap(). * b. Once an exception is intercepted, read the IDT/GDT and locate * the original handler. * c. Patch the original handler, injecting an INT3 at the beginning. * d. Update the exception exit bitmap to only catch the * WHvX64ExceptionTypeBreakpointTrap exception. * e. Let the affected CPU run in the exclusive mode. * f. Restore the original handler and the exception exit bitmap. * Note that handling all corner cases related to IDT/GDT is harder * than it may seem. See x86_cpu_get_phys_page_attrs_debug() for a * rough idea. * * 3. In order to properly support guest-level debugging in parallel with * the QEMU-level debugging, we would need to be able to pass some INT1 * events to the guest. This could be done via the following methods: * a. Using the WHvRegisterPendingEvent register. As of Windows 21H1, * it seems to only work for interrupts and not software * exceptions. * b. Locating and patching the original handler by parsing IDT/GDT. * This involves relatively complex logic outlined in the previous * paragraph. * c. Emulating the exception invocation (i.e. manually updating RIP, * RFLAGS, and pushing the old values to stack). This is even more * complicated than the previous option, since it involves checking * CPL, gate attributes, and doing various adjustments depending * on the current CPU mode, whether the CPL is changing, etc. */ typedef enum WhpxStepMode { WHPX_STEP_NONE = 0, /* Halt other VCPUs */ WHPX_STEP_EXCLUSIVE, } WhpxStepMode; struct whpx_vcpu { WHV_EMULATOR_HANDLE emulator; bool window_registered; bool interruptable; bool ready_for_pic_interrupt; uint64_t tpr; uint64_t apic_base; bool interruption_pending; /* Must be the last field as it may have a tail */ WHV_RUN_VP_EXIT_CONTEXT exit_ctx; }; static bool whpx_allowed; static bool whp_dispatch_initialized; static HMODULE hWinHvPlatform, hWinHvEmulation; static uint32_t max_vcpu_index; static WHV_PROCESSOR_XSAVE_FEATURES whpx_xsave_cap; struct whpx_state whpx_global; struct WHPDispatch whp_dispatch; static bool whpx_has_xsave(void) { return whpx_xsave_cap.XsaveSupport; } /* * VP support */ static struct whpx_vcpu *get_whpx_vcpu(CPUState *cpu) { return (struct whpx_vcpu *)cpu->hax_vcpu; } static WHV_X64_SEGMENT_REGISTER whpx_seg_q2h(const SegmentCache *qs, int v86, int r86) { WHV_X64_SEGMENT_REGISTER hs; unsigned flags = qs->flags; hs.Base = qs->base; hs.Limit = qs->limit; hs.Selector = qs->selector; if (v86) { hs.Attributes = 0; hs.SegmentType = 3; hs.Present = 1; hs.DescriptorPrivilegeLevel = 3; hs.NonSystemSegment = 1; } else { hs.Attributes = (flags >> DESC_TYPE_SHIFT); if (r86) { /* hs.Base &= 0xfffff; */ } } return hs; } static SegmentCache whpx_seg_h2q(const WHV_X64_SEGMENT_REGISTER *hs) { SegmentCache qs; qs.base = hs->Base; qs.limit = hs->Limit; qs.selector = hs->Selector; qs.flags = ((uint32_t)hs->Attributes) << DESC_TYPE_SHIFT; return qs; } /* X64 Extended Control Registers */ static void whpx_set_xcrs(CPUState *cpu) { CPUX86State *env = cpu->env_ptr; HRESULT hr; struct whpx_state *whpx = &whpx_global; WHV_REGISTER_VALUE xcr0; WHV_REGISTER_NAME xcr0_name = WHvX64RegisterXCr0; if (!whpx_has_xsave()) { return; } /* Only xcr0 is supported by the hypervisor currently */ xcr0.Reg64 = env->xcr0; hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, &xcr0_name, 1, &xcr0); if (FAILED(hr)) { error_report("WHPX: Failed to set register xcr0, hr=%08lx", hr); } } static int whpx_set_tsc(CPUState *cpu) { CPUX86State *env = cpu->env_ptr; WHV_REGISTER_NAME tsc_reg = WHvX64RegisterTsc; WHV_REGISTER_VALUE tsc_val; HRESULT hr; struct whpx_state *whpx = &whpx_global; /* * Suspend the partition prior to setting the TSC to reduce the variance * in TSC across vCPUs. When the first vCPU runs post suspend, the * partition is automatically resumed. */ if (whp_dispatch.WHvSuspendPartitionTime) { /* * Unable to suspend partition while setting TSC is not a fatal * error. It just increases the likelihood of TSC variance between * vCPUs and some guest OS are able to handle that just fine. */ hr = whp_dispatch.WHvSuspendPartitionTime(whpx->partition); if (FAILED(hr)) { warn_report("WHPX: Failed to suspend partition, hr=%08lx", hr); } } tsc_val.Reg64 = env->tsc; hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, &tsc_reg, 1, &tsc_val); if (FAILED(hr)) { error_report("WHPX: Failed to set TSC, hr=%08lx", hr); return -1; } return 0; } /* * The CR8 register in the CPU is mapped to the TPR register of the APIC, * however, they use a slightly different encoding. Specifically: * * APIC.TPR[bits 7:4] = CR8[bits 3:0] * * This mechanism is described in section 10.8.6.1 of Volume 3 of Intel 64 * and IA-32 Architectures Software Developer's Manual. * * The functions below translate the value of CR8 to TPR and vice versa. */ static uint64_t whpx_apic_tpr_to_cr8(uint64_t tpr) { return tpr >> 4; } static uint64_t whpx_cr8_to_apic_tpr(uint64_t cr8) { return cr8 << 4; } static void whpx_set_registers(CPUState *cpu, int level) { struct whpx_state *whpx = &whpx_global; struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); CPUX86State *env = cpu->env_ptr; X86CPU *x86_cpu = X86_CPU(cpu); struct whpx_register_set vcxt; HRESULT hr; int idx; int idx_next; int i; int v86, r86; assert(cpu_is_stopped(cpu) || qemu_cpu_is_self(cpu)); /* * Following MSRs have side effects on the guest or are too heavy for * runtime. Limit them to full state update. */ if (level >= WHPX_SET_RESET_STATE) { whpx_set_tsc(cpu); } memset(&vcxt, 0, sizeof(struct whpx_register_set)); v86 = (env->eflags & VM_MASK); r86 = !(env->cr[0] & CR0_PE_MASK); vcpu->tpr = whpx_apic_tpr_to_cr8(cpu_get_apic_tpr(x86_cpu->apic_state)); vcpu->apic_base = cpu_get_apic_base(x86_cpu->apic_state); idx = 0; /* Indexes for first 16 registers match between HV and QEMU definitions */ idx_next = 16; for (idx = 0; idx < CPU_NB_REGS; idx += 1) { vcxt.values[idx].Reg64 = (uint64_t)env->regs[idx]; } idx = idx_next; /* Same goes for RIP and RFLAGS */ assert(whpx_register_names[idx] == WHvX64RegisterRip); vcxt.values[idx++].Reg64 = env->eip; assert(whpx_register_names[idx] == WHvX64RegisterRflags); vcxt.values[idx++].Reg64 = env->eflags; /* Translate 6+4 segment registers. HV and QEMU order matches */ assert(idx == WHvX64RegisterEs); for (i = 0; i < 6; i += 1, idx += 1) { vcxt.values[idx].Segment = whpx_seg_q2h(&env->segs[i], v86, r86); } assert(idx == WHvX64RegisterLdtr); vcxt.values[idx++].Segment = whpx_seg_q2h(&env->ldt, 0, 0); assert(idx == WHvX64RegisterTr); vcxt.values[idx++].Segment = whpx_seg_q2h(&env->tr, 0, 0); assert(idx == WHvX64RegisterIdtr); vcxt.values[idx].Table.Base = env->idt.base; vcxt.values[idx].Table.Limit = env->idt.limit; idx += 1; assert(idx == WHvX64RegisterGdtr); vcxt.values[idx].Table.Base = env->gdt.base; vcxt.values[idx].Table.Limit = env->gdt.limit; idx += 1; /* CR0, 2, 3, 4, 8 */ assert(whpx_register_names[idx] == WHvX64RegisterCr0); vcxt.values[idx++].Reg64 = env->cr[0]; assert(whpx_register_names[idx] == WHvX64RegisterCr2); vcxt.values[idx++].Reg64 = env->cr[2]; assert(whpx_register_names[idx] == WHvX64RegisterCr3); vcxt.values[idx++].Reg64 = env->cr[3]; assert(whpx_register_names[idx] == WHvX64RegisterCr4); vcxt.values[idx++].Reg64 = env->cr[4]; assert(whpx_register_names[idx] == WHvX64RegisterCr8); vcxt.values[idx++].Reg64 = vcpu->tpr; /* 8 Debug Registers - Skipped */ /* * Extended control registers needs to be handled separately depending * on whether xsave is supported/enabled or not. */ whpx_set_xcrs(cpu); /* 16 XMM registers */ assert(whpx_register_names[idx] == WHvX64RegisterXmm0); idx_next = idx + 16; for (i = 0; i < sizeof(env->xmm_regs) / sizeof(ZMMReg); i += 1, idx += 1) { vcxt.values[idx].Reg128.Low64 = env->xmm_regs[i].ZMM_Q(0); vcxt.values[idx].Reg128.High64 = env->xmm_regs[i].ZMM_Q(1); } idx = idx_next; /* 8 FP registers */ assert(whpx_register_names[idx] == WHvX64RegisterFpMmx0); for (i = 0; i < 8; i += 1, idx += 1) { vcxt.values[idx].Fp.AsUINT128.Low64 = env->fpregs[i].mmx.MMX_Q(0); /* vcxt.values[idx].Fp.AsUINT128.High64 = env->fpregs[i].mmx.MMX_Q(1); */ } /* FP control status register */ assert(whpx_register_names[idx] == WHvX64RegisterFpControlStatus); vcxt.values[idx].FpControlStatus.FpControl = env->fpuc; vcxt.values[idx].FpControlStatus.FpStatus = (env->fpus & ~0x3800) | (env->fpstt & 0x7) << 11; vcxt.values[idx].FpControlStatus.FpTag = 0; for (i = 0; i < 8; ++i) { vcxt.values[idx].FpControlStatus.FpTag |= (!env->fptags[i]) << i; } vcxt.values[idx].FpControlStatus.Reserved = 0; vcxt.values[idx].FpControlStatus.LastFpOp = env->fpop; vcxt.values[idx].FpControlStatus.LastFpRip = env->fpip; idx += 1; /* XMM control status register */ assert(whpx_register_names[idx] == WHvX64RegisterXmmControlStatus); vcxt.values[idx].XmmControlStatus.LastFpRdp = 0; vcxt.values[idx].XmmControlStatus.XmmStatusControl = env->mxcsr; vcxt.values[idx].XmmControlStatus.XmmStatusControlMask = 0x0000ffff; idx += 1; /* MSRs */ assert(whpx_register_names[idx] == WHvX64RegisterEfer); vcxt.values[idx++].Reg64 = env->efer; #ifdef TARGET_X86_64 assert(whpx_register_names[idx] == WHvX64RegisterKernelGsBase); vcxt.values[idx++].Reg64 = env->kernelgsbase; #endif assert(whpx_register_names[idx] == WHvX64RegisterApicBase); vcxt.values[idx++].Reg64 = vcpu->apic_base; /* WHvX64RegisterPat - Skipped */ assert(whpx_register_names[idx] == WHvX64RegisterSysenterCs); vcxt.values[idx++].Reg64 = env->sysenter_cs; assert(whpx_register_names[idx] == WHvX64RegisterSysenterEip); vcxt.values[idx++].Reg64 = env->sysenter_eip; assert(whpx_register_names[idx] == WHvX64RegisterSysenterEsp); vcxt.values[idx++].Reg64 = env->sysenter_esp; assert(whpx_register_names[idx] == WHvX64RegisterStar); vcxt.values[idx++].Reg64 = env->star; #ifdef TARGET_X86_64 assert(whpx_register_names[idx] == WHvX64RegisterLstar); vcxt.values[idx++].Reg64 = env->lstar; assert(whpx_register_names[idx] == WHvX64RegisterCstar); vcxt.values[idx++].Reg64 = env->cstar; assert(whpx_register_names[idx] == WHvX64RegisterSfmask); vcxt.values[idx++].Reg64 = env->fmask; #endif /* Interrupt / Event Registers - Skipped */ assert(idx == RTL_NUMBER_OF(whpx_register_names)); hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, whpx_register_names, RTL_NUMBER_OF(whpx_register_names), &vcxt.values[0]); if (FAILED(hr)) { error_report("WHPX: Failed to set virtual processor context, hr=%08lx", hr); } return; } static int whpx_get_tsc(CPUState *cpu) { CPUX86State *env = cpu->env_ptr; WHV_REGISTER_NAME tsc_reg = WHvX64RegisterTsc; WHV_REGISTER_VALUE tsc_val; HRESULT hr; struct whpx_state *whpx = &whpx_global; hr = whp_dispatch.WHvGetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, &tsc_reg, 1, &tsc_val); if (FAILED(hr)) { error_report("WHPX: Failed to get TSC, hr=%08lx", hr); return -1; } env->tsc = tsc_val.Reg64; return 0; } /* X64 Extended Control Registers */ static void whpx_get_xcrs(CPUState *cpu) { CPUX86State *env = cpu->env_ptr; HRESULT hr; struct whpx_state *whpx = &whpx_global; WHV_REGISTER_VALUE xcr0; WHV_REGISTER_NAME xcr0_name = WHvX64RegisterXCr0; if (!whpx_has_xsave()) { return; } /* Only xcr0 is supported by the hypervisor currently */ hr = whp_dispatch.WHvGetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, &xcr0_name, 1, &xcr0); if (FAILED(hr)) { error_report("WHPX: Failed to get register xcr0, hr=%08lx", hr); return; } env->xcr0 = xcr0.Reg64; } static void whpx_get_registers(CPUState *cpu) { struct whpx_state *whpx = &whpx_global; struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); CPUX86State *env = cpu->env_ptr; X86CPU *x86_cpu = X86_CPU(cpu); struct whpx_register_set vcxt; uint64_t tpr, apic_base; HRESULT hr; int idx; int idx_next; int i; assert(cpu_is_stopped(cpu) || qemu_cpu_is_self(cpu)); if (!env->tsc_valid) { whpx_get_tsc(cpu); env->tsc_valid = !runstate_is_running(); } hr = whp_dispatch.WHvGetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, whpx_register_names, RTL_NUMBER_OF(whpx_register_names), &vcxt.values[0]); if (FAILED(hr)) { error_report("WHPX: Failed to get virtual processor context, hr=%08lx", hr); } if (whpx_apic_in_platform()) { /* * Fetch the TPR value from the emulated APIC. It may get overwritten * below with the value from CR8 returned by * WHvGetVirtualProcessorRegisters(). */ whpx_apic_get(x86_cpu->apic_state); vcpu->tpr = whpx_apic_tpr_to_cr8( cpu_get_apic_tpr(x86_cpu->apic_state)); } idx = 0; /* Indexes for first 16 registers match between HV and QEMU definitions */ idx_next = 16; for (idx = 0; idx < CPU_NB_REGS; idx += 1) { env->regs[idx] = vcxt.values[idx].Reg64; } idx = idx_next; /* Same goes for RIP and RFLAGS */ assert(whpx_register_names[idx] == WHvX64RegisterRip); env->eip = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterRflags); env->eflags = vcxt.values[idx++].Reg64; /* Translate 6+4 segment registers. HV and QEMU order matches */ assert(idx == WHvX64RegisterEs); for (i = 0; i < 6; i += 1, idx += 1) { env->segs[i] = whpx_seg_h2q(&vcxt.values[idx].Segment); } assert(idx == WHvX64RegisterLdtr); env->ldt = whpx_seg_h2q(&vcxt.values[idx++].Segment); assert(idx == WHvX64RegisterTr); env->tr = whpx_seg_h2q(&vcxt.values[idx++].Segment); assert(idx == WHvX64RegisterIdtr); env->idt.base = vcxt.values[idx].Table.Base; env->idt.limit = vcxt.values[idx].Table.Limit; idx += 1; assert(idx == WHvX64RegisterGdtr); env->gdt.base = vcxt.values[idx].Table.Base; env->gdt.limit = vcxt.values[idx].Table.Limit; idx += 1; /* CR0, 2, 3, 4, 8 */ assert(whpx_register_names[idx] == WHvX64RegisterCr0); env->cr[0] = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterCr2); env->cr[2] = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterCr3); env->cr[3] = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterCr4); env->cr[4] = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterCr8); tpr = vcxt.values[idx++].Reg64; if (tpr != vcpu->tpr) { vcpu->tpr = tpr; cpu_set_apic_tpr(x86_cpu->apic_state, whpx_cr8_to_apic_tpr(tpr)); } /* 8 Debug Registers - Skipped */ /* * Extended control registers needs to be handled separately depending * on whether xsave is supported/enabled or not. */ whpx_get_xcrs(cpu); /* 16 XMM registers */ assert(whpx_register_names[idx] == WHvX64RegisterXmm0); idx_next = idx + 16; for (i = 0; i < sizeof(env->xmm_regs) / sizeof(ZMMReg); i += 1, idx += 1) { env->xmm_regs[i].ZMM_Q(0) = vcxt.values[idx].Reg128.Low64; env->xmm_regs[i].ZMM_Q(1) = vcxt.values[idx].Reg128.High64; } idx = idx_next; /* 8 FP registers */ assert(whpx_register_names[idx] == WHvX64RegisterFpMmx0); for (i = 0; i < 8; i += 1, idx += 1) { env->fpregs[i].mmx.MMX_Q(0) = vcxt.values[idx].Fp.AsUINT128.Low64; /* env->fpregs[i].mmx.MMX_Q(1) = vcxt.values[idx].Fp.AsUINT128.High64; */ } /* FP control status register */ assert(whpx_register_names[idx] == WHvX64RegisterFpControlStatus); env->fpuc = vcxt.values[idx].FpControlStatus.FpControl; env->fpstt = (vcxt.values[idx].FpControlStatus.FpStatus >> 11) & 0x7; env->fpus = vcxt.values[idx].FpControlStatus.FpStatus & ~0x3800; for (i = 0; i < 8; ++i) { env->fptags[i] = !((vcxt.values[idx].FpControlStatus.FpTag >> i) & 1); } env->fpop = vcxt.values[idx].FpControlStatus.LastFpOp; env->fpip = vcxt.values[idx].FpControlStatus.LastFpRip; idx += 1; /* XMM control status register */ assert(whpx_register_names[idx] == WHvX64RegisterXmmControlStatus); env->mxcsr = vcxt.values[idx].XmmControlStatus.XmmStatusControl; idx += 1; /* MSRs */ assert(whpx_register_names[idx] == WHvX64RegisterEfer); env->efer = vcxt.values[idx++].Reg64; #ifdef TARGET_X86_64 assert(whpx_register_names[idx] == WHvX64RegisterKernelGsBase); env->kernelgsbase = vcxt.values[idx++].Reg64; #endif assert(whpx_register_names[idx] == WHvX64RegisterApicBase); apic_base = vcxt.values[idx++].Reg64; if (apic_base != vcpu->apic_base) { vcpu->apic_base = apic_base; cpu_set_apic_base(x86_cpu->apic_state, vcpu->apic_base); } /* WHvX64RegisterPat - Skipped */ assert(whpx_register_names[idx] == WHvX64RegisterSysenterCs); env->sysenter_cs = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterSysenterEip); env->sysenter_eip = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterSysenterEsp); env->sysenter_esp = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterStar); env->star = vcxt.values[idx++].Reg64; #ifdef TARGET_X86_64 assert(whpx_register_names[idx] == WHvX64RegisterLstar); env->lstar = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterCstar); env->cstar = vcxt.values[idx++].Reg64; assert(whpx_register_names[idx] == WHvX64RegisterSfmask); env->fmask = vcxt.values[idx++].Reg64; #endif /* Interrupt / Event Registers - Skipped */ assert(idx == RTL_NUMBER_OF(whpx_register_names)); if (whpx_apic_in_platform()) { whpx_apic_get(x86_cpu->apic_state); } x86_update_hflags(env); return; } static HRESULT CALLBACK whpx_emu_ioport_callback( void *ctx, WHV_EMULATOR_IO_ACCESS_INFO *IoAccess) { MemTxAttrs attrs = { 0 }; address_space_rw(&address_space_io, IoAccess->Port, attrs, &IoAccess->Data, IoAccess->AccessSize, IoAccess->Direction); return S_OK; } static HRESULT CALLBACK whpx_emu_mmio_callback( void *ctx, WHV_EMULATOR_MEMORY_ACCESS_INFO *ma) { cpu_physical_memory_rw(ma->GpaAddress, ma->Data, ma->AccessSize, ma->Direction); return S_OK; } static HRESULT CALLBACK whpx_emu_getreg_callback( void *ctx, const WHV_REGISTER_NAME *RegisterNames, UINT32 RegisterCount, WHV_REGISTER_VALUE *RegisterValues) { HRESULT hr; struct whpx_state *whpx = &whpx_global; CPUState *cpu = (CPUState *)ctx; hr = whp_dispatch.WHvGetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, RegisterNames, RegisterCount, RegisterValues); if (FAILED(hr)) { error_report("WHPX: Failed to get virtual processor registers," " hr=%08lx", hr); } return hr; } static HRESULT CALLBACK whpx_emu_setreg_callback( void *ctx, const WHV_REGISTER_NAME *RegisterNames, UINT32 RegisterCount, const WHV_REGISTER_VALUE *RegisterValues) { HRESULT hr; struct whpx_state *whpx = &whpx_global; CPUState *cpu = (CPUState *)ctx; hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, RegisterNames, RegisterCount, RegisterValues); if (FAILED(hr)) { error_report("WHPX: Failed to set virtual processor registers," " hr=%08lx", hr); } /* * The emulator just successfully wrote the register state. We clear the * dirty state so we avoid the double write on resume of the VP. */ cpu->vcpu_dirty = false; return hr; } static HRESULT CALLBACK whpx_emu_translate_callback( void *ctx, WHV_GUEST_VIRTUAL_ADDRESS Gva, WHV_TRANSLATE_GVA_FLAGS TranslateFlags, WHV_TRANSLATE_GVA_RESULT_CODE *TranslationResult, WHV_GUEST_PHYSICAL_ADDRESS *Gpa) { HRESULT hr; struct whpx_state *whpx = &whpx_global; CPUState *cpu = (CPUState *)ctx; WHV_TRANSLATE_GVA_RESULT res; hr = whp_dispatch.WHvTranslateGva(whpx->partition, cpu->cpu_index, Gva, TranslateFlags, &res, Gpa); if (FAILED(hr)) { error_report("WHPX: Failed to translate GVA, hr=%08lx", hr); } else { *TranslationResult = res.ResultCode; } return hr; } static const WHV_EMULATOR_CALLBACKS whpx_emu_callbacks = { .Size = sizeof(WHV_EMULATOR_CALLBACKS), .WHvEmulatorIoPortCallback = whpx_emu_ioport_callback, .WHvEmulatorMemoryCallback = whpx_emu_mmio_callback, .WHvEmulatorGetVirtualProcessorRegisters = whpx_emu_getreg_callback, .WHvEmulatorSetVirtualProcessorRegisters = whpx_emu_setreg_callback, .WHvEmulatorTranslateGvaPage = whpx_emu_translate_callback, }; static int whpx_handle_mmio(CPUState *cpu, WHV_MEMORY_ACCESS_CONTEXT *ctx) { HRESULT hr; struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); WHV_EMULATOR_STATUS emu_status; hr = whp_dispatch.WHvEmulatorTryMmioEmulation( vcpu->emulator, cpu, &vcpu->exit_ctx.VpContext, ctx, &emu_status); if (FAILED(hr)) { error_report("WHPX: Failed to parse MMIO access, hr=%08lx", hr); return -1; } if (!emu_status.EmulationSuccessful) { error_report("WHPX: Failed to emulate MMIO access with" " EmulatorReturnStatus: %u", emu_status.AsUINT32); return -1; } return 0; } static int whpx_handle_portio(CPUState *cpu, WHV_X64_IO_PORT_ACCESS_CONTEXT *ctx) { HRESULT hr; struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); WHV_EMULATOR_STATUS emu_status; hr = whp_dispatch.WHvEmulatorTryIoEmulation( vcpu->emulator, cpu, &vcpu->exit_ctx.VpContext, ctx, &emu_status); if (FAILED(hr)) { error_report("WHPX: Failed to parse PortIO access, hr=%08lx", hr); return -1; } if (!emu_status.EmulationSuccessful) { error_report("WHPX: Failed to emulate PortIO access with" " EmulatorReturnStatus: %u", emu_status.AsUINT32); return -1; } return 0; } /* * Controls whether we should intercept various exceptions on the guest, * namely breakpoint/single-step events. * * The 'exceptions' argument accepts a bitmask, e.g: * (1 << WHvX64ExceptionTypeDebugTrapOrFault) | (...) */ static HRESULT whpx_set_exception_exit_bitmap(UINT64 exceptions) { struct whpx_state *whpx = &whpx_global; WHV_PARTITION_PROPERTY prop = { 0, }; HRESULT hr; if (exceptions == whpx->exception_exit_bitmap) { return S_OK; } prop.ExceptionExitBitmap = exceptions; hr = whp_dispatch.WHvSetPartitionProperty( whpx->partition, WHvPartitionPropertyCodeExceptionExitBitmap, &prop, sizeof(WHV_PARTITION_PROPERTY)); if (SUCCEEDED(hr)) { whpx->exception_exit_bitmap = exceptions; } return hr; } /* * This function is called before/after stepping over a single instruction. * It will update the CPU registers to arm/disarm the instruction stepping * accordingly. */ static HRESULT whpx_vcpu_configure_single_stepping(CPUState *cpu, bool set, uint64_t *exit_context_rflags) { WHV_REGISTER_NAME reg_name; WHV_REGISTER_VALUE reg_value; HRESULT hr; struct whpx_state *whpx = &whpx_global; /* * If we are trying to step over a single instruction, we need to set the * TF bit in rflags. Otherwise, clear it. */ reg_name = WHvX64RegisterRflags; hr = whp_dispatch.WHvGetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, ®_name, 1, ®_value); if (FAILED(hr)) { error_report("WHPX: Failed to get rflags, hr=%08lx", hr); return hr; } if (exit_context_rflags) { assert(*exit_context_rflags == reg_value.Reg64); } if (set) { /* Raise WHvX64ExceptionTypeDebugTrapOrFault after each instruction */ reg_value.Reg64 |= TF_MASK; } else { reg_value.Reg64 &= ~TF_MASK; } if (exit_context_rflags) { *exit_context_rflags = reg_value.Reg64; } hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, ®_name, 1, ®_value); if (FAILED(hr)) { error_report("WHPX: Failed to set rflags," " hr=%08lx", hr); return hr; } reg_name = WHvRegisterInterruptState; reg_value.Reg64 = 0; /* Suspend delivery of hardware interrupts during single-stepping. */ reg_value.InterruptState.InterruptShadow = set != 0; hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, ®_name, 1, ®_value); if (FAILED(hr)) { error_report("WHPX: Failed to set InterruptState," " hr=%08lx", hr); return hr; } if (!set) { /* * We have just finished stepping over a single instruction, * and intercepted the INT1 generated by it. * We need to now hide the INT1 from the guest, * as it would not be expecting it. */ reg_name = WHvX64RegisterPendingDebugException; hr = whp_dispatch.WHvGetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, ®_name, 1, ®_value); if (FAILED(hr)) { error_report("WHPX: Failed to get pending debug exceptions," "hr=%08lx", hr); return hr; } if (reg_value.PendingDebugException.SingleStep) { reg_value.PendingDebugException.SingleStep = 0; hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, ®_name, 1, ®_value); if (FAILED(hr)) { error_report("WHPX: Failed to clear pending debug exceptions," "hr=%08lx", hr); return hr; } } } return S_OK; } /* Tries to find a breakpoint at the specified address. */ static struct whpx_breakpoint *whpx_lookup_breakpoint_by_addr(uint64_t address) { struct whpx_state *whpx = &whpx_global; int i; if (whpx->breakpoints.breakpoints) { for (i = 0; i < whpx->breakpoints.breakpoints->used; i++) { if (address == whpx->breakpoints.breakpoints->data[i].address) { return &whpx->breakpoints.breakpoints->data[i]; } } } return NULL; } /* * Linux uses int3 (0xCC) during startup (see int3_selftest()) and for * debugging user-mode applications. Since the WHPX API does not offer * an easy way to pass the intercepted exception back to the guest, we * resort to using INT1 instead, and let the guest always handle INT3. */ static const uint8_t whpx_breakpoint_instruction = 0xF1; /* * The WHPX QEMU backend implements breakpoints by writing the INT1 * instruction into memory (ignoring the DRx registers). This raises a few * issues that need to be carefully handled: * * 1. Although unlikely, other parts of QEMU may set multiple breakpoints * at the same location, and later remove them in arbitrary order. * This should not cause memory corruption, and should only remove the * physical breakpoint instruction when the last QEMU breakpoint is gone. * * 2. Writing arbitrary virtual memory may fail if it's not mapped to a valid * physical location. Hence, physically adding/removing a breakpoint can * theoretically fail at any time. We need to keep track of it. * * The function below rebuilds a list of low-level breakpoints (one per * address, tracking the original instruction and any errors) from the list of * high-level breakpoints (set via cpu_breakpoint_insert()). * * In order to optimize performance, this function stores the list of * high-level breakpoints (a.k.a. CPU breakpoints) used to compute the * low-level ones, so that it won't be re-invoked until these breakpoints * change. * * Note that this function decides which breakpoints should be inserted into, * memory, but doesn't actually do it. The memory accessing is done in * whpx_apply_breakpoints(). */ static void whpx_translate_cpu_breakpoints( struct whpx_breakpoints *breakpoints, CPUState *cpu, int cpu_breakpoint_count) { CPUBreakpoint *bp; int cpu_bp_index = 0; breakpoints->original_addresses = g_renew(vaddr, breakpoints->original_addresses, cpu_breakpoint_count); breakpoints->original_address_count = cpu_breakpoint_count; int max_breakpoints = cpu_breakpoint_count + (breakpoints->breakpoints ? breakpoints->breakpoints->used : 0); struct whpx_breakpoint_collection *new_breakpoints = g_malloc0(sizeof(struct whpx_breakpoint_collection) + max_breakpoints * sizeof(struct whpx_breakpoint)); new_breakpoints->allocated = max_breakpoints; new_breakpoints->used = 0; /* * 1. Preserve all old breakpoints that could not be automatically * cleared when the CPU got stopped. */ if (breakpoints->breakpoints) { int i; for (i = 0; i < breakpoints->breakpoints->used; i++) { if (breakpoints->breakpoints->data[i].state != WHPX_BP_CLEARED) { new_breakpoints->data[new_breakpoints->used++] = breakpoints->breakpoints->data[i]; } } } /* 2. Map all CPU breakpoints to WHPX breakpoints */ QTAILQ_FOREACH(bp, &cpu->breakpoints, entry) { int i; bool found = false; /* This will be used to detect changed CPU breakpoints later. */ breakpoints->original_addresses[cpu_bp_index++] = bp->pc; for (i = 0; i < new_breakpoints->used; i++) { /* * WARNING: This loop has O(N^2) complexity, where N is the * number of breakpoints. It should not be a bottleneck in * real-world scenarios, since it only needs to run once after * the breakpoints have been modified. * If this ever becomes a concern, it can be optimized by storing * high-level breakpoint objects in a tree or hash map. */ if (new_breakpoints->data[i].address == bp->pc) { /* There was already a breakpoint at this address. */ if (new_breakpoints->data[i].state == WHPX_BP_CLEAR_PENDING) { new_breakpoints->data[i].state = WHPX_BP_SET; } else if (new_breakpoints->data[i].state == WHPX_BP_SET) { new_breakpoints->data[i].state = WHPX_BP_SET_PENDING; } found = true; break; } } if (!found && new_breakpoints->used < new_breakpoints->allocated) { /* No WHPX breakpoint at this address. Create one. */ new_breakpoints->data[new_breakpoints->used].address = bp->pc; new_breakpoints->data[new_breakpoints->used].state = WHPX_BP_SET_PENDING; new_breakpoints->used++; } } /* * Free the previous breakpoint list. This can be optimized by keeping * it as shadow buffer for the next computation instead of freeing * it immediately. */ g_free(breakpoints->breakpoints); breakpoints->breakpoints = new_breakpoints; } /* * Physically inserts/removes the breakpoints by reading and writing the * physical memory, keeping a track of the failed attempts. * * Passing resuming=true will try to set all previously unset breakpoints. * Passing resuming=false will remove all inserted ones. */ static void whpx_apply_breakpoints( struct whpx_breakpoint_collection *breakpoints, CPUState *cpu, bool resuming) { int i, rc; if (!breakpoints) { return; } for (i = 0; i < breakpoints->used; i++) { /* Decide what to do right now based on the last known state. */ WhpxBreakpointState state = breakpoints->data[i].state; switch (state) { case WHPX_BP_CLEARED: if (resuming) { state = WHPX_BP_SET_PENDING; } break; case WHPX_BP_SET_PENDING: if (!resuming) { state = WHPX_BP_CLEARED; } break; case WHPX_BP_SET: if (!resuming) { state = WHPX_BP_CLEAR_PENDING; } break; case WHPX_BP_CLEAR_PENDING: if (resuming) { state = WHPX_BP_SET; } break; } if (state == WHPX_BP_SET_PENDING) { /* Remember the original instruction. */ rc = cpu_memory_rw_debug(cpu, breakpoints->data[i].address, &breakpoints->data[i].original_instruction, 1, false); if (!rc) { /* Write the breakpoint instruction. */ rc = cpu_memory_rw_debug(cpu, breakpoints->data[i].address, (void *)&whpx_breakpoint_instruction, 1, true); } if (!rc) { state = WHPX_BP_SET; } } if (state == WHPX_BP_CLEAR_PENDING) { /* Restore the original instruction. */ rc = cpu_memory_rw_debug(cpu, breakpoints->data[i].address, &breakpoints->data[i].original_instruction, 1, true); if (!rc) { state = WHPX_BP_CLEARED; } } breakpoints->data[i].state = state; } } /* * This function is called when the a VCPU is about to start and no other * VCPUs have been started so far. Since the VCPU start order could be * arbitrary, it doesn't have to be VCPU#0. * * It is used to commit the breakpoints into memory, and configure WHPX * to intercept debug exceptions. * * Note that whpx_set_exception_exit_bitmap() cannot be called if one or * more VCPUs are already running, so this is the best place to do it. */ static int whpx_first_vcpu_starting(CPUState *cpu) { struct whpx_state *whpx = &whpx_global; HRESULT hr; g_assert(qemu_mutex_iothread_locked()); if (!QTAILQ_EMPTY(&cpu->breakpoints) || (whpx->breakpoints.breakpoints && whpx->breakpoints.breakpoints->used)) { CPUBreakpoint *bp; int i = 0; bool update_pending = false; QTAILQ_FOREACH(bp, &cpu->breakpoints, entry) { if (i >= whpx->breakpoints.original_address_count || bp->pc != whpx->breakpoints.original_addresses[i]) { update_pending = true; } i++; } if (i != whpx->breakpoints.original_address_count) { update_pending = true; } if (update_pending) { /* * The CPU breakpoints have changed since the last call to * whpx_translate_cpu_breakpoints(). WHPX breakpoints must * now be recomputed. */ whpx_translate_cpu_breakpoints(&whpx->breakpoints, cpu, i); } /* Actually insert the breakpoints into the memory. */ whpx_apply_breakpoints(whpx->breakpoints.breakpoints, cpu, true); } uint64_t exception_mask; if (whpx->step_pending || (whpx->breakpoints.breakpoints && whpx->breakpoints.breakpoints->used)) { /* * We are either attempting to single-step one or more CPUs, or * have one or more breakpoints enabled. Both require intercepting * the WHvX64ExceptionTypeBreakpointTrap exception. */ exception_mask = 1UL << WHvX64ExceptionTypeDebugTrapOrFault; } else { /* Let the guest handle all exceptions. */ exception_mask = 0; } hr = whpx_set_exception_exit_bitmap(exception_mask); if (!SUCCEEDED(hr)) { error_report("WHPX: Failed to update exception exit mask," "hr=%08lx.", hr); return 1; } return 0; } /* * This function is called when the last VCPU has finished running. * It is used to remove any previously set breakpoints from memory. */ static int whpx_last_vcpu_stopping(CPUState *cpu) { whpx_apply_breakpoints(whpx_global.breakpoints.breakpoints, cpu, false); return 0; } /* Returns the address of the next instruction that is about to be executed. */ static vaddr whpx_vcpu_get_pc(CPUState *cpu, bool exit_context_valid) { if (cpu->vcpu_dirty) { /* The CPU registers have been modified by other parts of QEMU. */ CPUArchState *env = (CPUArchState *)(cpu->env_ptr); return env->eip; } else if (exit_context_valid) { /* * The CPU registers have not been modified by neither other parts * of QEMU, nor this port by calling WHvSetVirtualProcessorRegisters(). * This is the most common case. */ struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); return vcpu->exit_ctx.VpContext.Rip; } else { /* * The CPU registers have been modified by a call to * WHvSetVirtualProcessorRegisters() and must be re-queried from * the target. */ WHV_REGISTER_VALUE reg_value; WHV_REGISTER_NAME reg_name = WHvX64RegisterRip; HRESULT hr; struct whpx_state *whpx = &whpx_global; hr = whp_dispatch.WHvGetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, ®_name, 1, ®_value); if (FAILED(hr)) { error_report("WHPX: Failed to get PC, hr=%08lx", hr); return 0; } return reg_value.Reg64; } } static int whpx_handle_halt(CPUState *cpu) { CPUX86State *env = cpu->env_ptr; int ret = 0; qemu_mutex_lock_iothread(); if (!((cpu->interrupt_request & CPU_INTERRUPT_HARD) && (env->eflags & IF_MASK)) && !(cpu->interrupt_request & CPU_INTERRUPT_NMI)) { cpu->exception_index = EXCP_HLT; cpu->halted = true; ret = 1; } qemu_mutex_unlock_iothread(); return ret; } static void whpx_vcpu_pre_run(CPUState *cpu) { HRESULT hr; struct whpx_state *whpx = &whpx_global; struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); CPUX86State *env = cpu->env_ptr; X86CPU *x86_cpu = X86_CPU(cpu); int irq; uint8_t tpr; WHV_X64_PENDING_INTERRUPTION_REGISTER new_int; UINT32 reg_count = 0; WHV_REGISTER_VALUE reg_values[3]; WHV_REGISTER_NAME reg_names[3]; memset(&new_int, 0, sizeof(new_int)); memset(reg_values, 0, sizeof(reg_values)); qemu_mutex_lock_iothread(); /* Inject NMI */ if (!vcpu->interruption_pending && cpu->interrupt_request & (CPU_INTERRUPT_NMI | CPU_INTERRUPT_SMI)) { if (cpu->interrupt_request & CPU_INTERRUPT_NMI) { cpu->interrupt_request &= ~CPU_INTERRUPT_NMI; vcpu->interruptable = false; new_int.InterruptionType = WHvX64PendingNmi; new_int.InterruptionPending = 1; new_int.InterruptionVector = 2; } if (cpu->interrupt_request & CPU_INTERRUPT_SMI) { cpu->interrupt_request &= ~CPU_INTERRUPT_SMI; } } /* * Force the VCPU out of its inner loop to process any INIT requests or * commit pending TPR access. */ if (cpu->interrupt_request & (CPU_INTERRUPT_INIT | CPU_INTERRUPT_TPR)) { if ((cpu->interrupt_request & CPU_INTERRUPT_INIT) && !(env->hflags & HF_SMM_MASK)) { cpu->exit_request = 1; } if (cpu->interrupt_request & CPU_INTERRUPT_TPR) { cpu->exit_request = 1; } } /* Get pending hard interruption or replay one that was overwritten */ if (!whpx_apic_in_platform()) { if (!vcpu->interruption_pending && vcpu->interruptable && (env->eflags & IF_MASK)) { assert(!new_int.InterruptionPending); if (cpu->interrupt_request & CPU_INTERRUPT_HARD) { cpu->interrupt_request &= ~CPU_INTERRUPT_HARD; irq = cpu_get_pic_interrupt(env); if (irq >= 0) { new_int.InterruptionType = WHvX64PendingInterrupt; new_int.InterruptionPending = 1; new_int.InterruptionVector = irq; } } } /* Setup interrupt state if new one was prepared */ if (new_int.InterruptionPending) { reg_values[reg_count].PendingInterruption = new_int; reg_names[reg_count] = WHvRegisterPendingInterruption; reg_count += 1; } } else if (vcpu->ready_for_pic_interrupt && (cpu->interrupt_request & CPU_INTERRUPT_HARD)) { cpu->interrupt_request &= ~CPU_INTERRUPT_HARD; irq = cpu_get_pic_interrupt(env); if (irq >= 0) { reg_names[reg_count] = WHvRegisterPendingEvent; reg_values[reg_count].ExtIntEvent = (WHV_X64_PENDING_EXT_INT_EVENT) { .EventPending = 1, .EventType = WHvX64PendingEventExtInt, .Vector = irq, }; reg_count += 1; } } /* Sync the TPR to the CR8 if was modified during the intercept */ tpr = whpx_apic_tpr_to_cr8(cpu_get_apic_tpr(x86_cpu->apic_state)); if (tpr != vcpu->tpr) { vcpu->tpr = tpr; reg_values[reg_count].Reg64 = tpr; cpu->exit_request = 1; reg_names[reg_count] = WHvX64RegisterCr8; reg_count += 1; } /* Update the state of the interrupt delivery notification */ if (!vcpu->window_registered && cpu->interrupt_request & CPU_INTERRUPT_HARD) { reg_values[reg_count].DeliverabilityNotifications = (WHV_X64_DELIVERABILITY_NOTIFICATIONS_REGISTER) { .InterruptNotification = 1 }; vcpu->window_registered = 1; reg_names[reg_count] = WHvX64RegisterDeliverabilityNotifications; reg_count += 1; } qemu_mutex_unlock_iothread(); vcpu->ready_for_pic_interrupt = false; if (reg_count) { hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, reg_names, reg_count, reg_values); if (FAILED(hr)) { error_report("WHPX: Failed to set interrupt state registers," " hr=%08lx", hr); } } return; } static void whpx_vcpu_post_run(CPUState *cpu) { struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); CPUX86State *env = cpu->env_ptr; X86CPU *x86_cpu = X86_CPU(cpu); env->eflags = vcpu->exit_ctx.VpContext.Rflags; uint64_t tpr = vcpu->exit_ctx.VpContext.Cr8; if (vcpu->tpr != tpr) { vcpu->tpr = tpr; qemu_mutex_lock_iothread(); cpu_set_apic_tpr(x86_cpu->apic_state, whpx_cr8_to_apic_tpr(vcpu->tpr)); qemu_mutex_unlock_iothread(); } vcpu->interruption_pending = vcpu->exit_ctx.VpContext.ExecutionState.InterruptionPending; vcpu->interruptable = !vcpu->exit_ctx.VpContext.ExecutionState.InterruptShadow; return; } static void whpx_vcpu_process_async_events(CPUState *cpu) { CPUX86State *env = cpu->env_ptr; X86CPU *x86_cpu = X86_CPU(cpu); struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); if ((cpu->interrupt_request & CPU_INTERRUPT_INIT) && !(env->hflags & HF_SMM_MASK)) { whpx_cpu_synchronize_state(cpu); do_cpu_init(x86_cpu); vcpu->interruptable = true; } if (cpu->interrupt_request & CPU_INTERRUPT_POLL) { cpu->interrupt_request &= ~CPU_INTERRUPT_POLL; apic_poll_irq(x86_cpu->apic_state); } if (((cpu->interrupt_request & CPU_INTERRUPT_HARD) && (env->eflags & IF_MASK)) || (cpu->interrupt_request & CPU_INTERRUPT_NMI)) { cpu->halted = false; } if (cpu->interrupt_request & CPU_INTERRUPT_SIPI) { whpx_cpu_synchronize_state(cpu); do_cpu_sipi(x86_cpu); } if (cpu->interrupt_request & CPU_INTERRUPT_TPR) { cpu->interrupt_request &= ~CPU_INTERRUPT_TPR; whpx_cpu_synchronize_state(cpu); apic_handle_tpr_access_report(x86_cpu->apic_state, env->eip, env->tpr_access_type); } return; } static int whpx_vcpu_run(CPUState *cpu) { HRESULT hr; struct whpx_state *whpx = &whpx_global; struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); struct whpx_breakpoint *stepped_over_bp = NULL; WhpxStepMode exclusive_step_mode = WHPX_STEP_NONE; int ret; g_assert(qemu_mutex_iothread_locked()); if (whpx->running_cpus++ == 0) { /* Insert breakpoints into memory, update exception exit bitmap. */ ret = whpx_first_vcpu_starting(cpu); if (ret != 0) { return ret; } } if (whpx->breakpoints.breakpoints && whpx->breakpoints.breakpoints->used > 0) { uint64_t pc = whpx_vcpu_get_pc(cpu, true); stepped_over_bp = whpx_lookup_breakpoint_by_addr(pc); if (stepped_over_bp && stepped_over_bp->state != WHPX_BP_SET) { stepped_over_bp = NULL; } if (stepped_over_bp) { /* * We are trying to run the instruction overwritten by an active * breakpoint. We will temporarily disable the breakpoint, suspend * other CPUs, and step over the instruction. */ exclusive_step_mode = WHPX_STEP_EXCLUSIVE; } } if (exclusive_step_mode == WHPX_STEP_NONE) { whpx_vcpu_process_async_events(cpu); if (cpu->halted && !whpx_apic_in_platform()) { cpu->exception_index = EXCP_HLT; qatomic_set(&cpu->exit_request, false); return 0; } } qemu_mutex_unlock_iothread(); if (exclusive_step_mode != WHPX_STEP_NONE) { start_exclusive(); g_assert(cpu == current_cpu); g_assert(!cpu->running); cpu->running = true; hr = whpx_set_exception_exit_bitmap( 1UL << WHvX64ExceptionTypeDebugTrapOrFault); if (!SUCCEEDED(hr)) { error_report("WHPX: Failed to update exception exit mask, " "hr=%08lx.", hr); return 1; } if (stepped_over_bp) { /* Temporarily disable the triggered breakpoint. */ cpu_memory_rw_debug(cpu, stepped_over_bp->address, &stepped_over_bp->original_instruction, 1, true); } } else { cpu_exec_start(cpu); } do { if (cpu->vcpu_dirty) { whpx_set_registers(cpu, WHPX_SET_RUNTIME_STATE); cpu->vcpu_dirty = false; } if (exclusive_step_mode == WHPX_STEP_NONE) { whpx_vcpu_pre_run(cpu); if (qatomic_read(&cpu->exit_request)) { whpx_vcpu_kick(cpu); } } if (exclusive_step_mode != WHPX_STEP_NONE || cpu->singlestep_enabled) { whpx_vcpu_configure_single_stepping(cpu, true, NULL); } hr = whp_dispatch.WHvRunVirtualProcessor( whpx->partition, cpu->cpu_index, &vcpu->exit_ctx, sizeof(vcpu->exit_ctx)); if (FAILED(hr)) { error_report("WHPX: Failed to exec a virtual processor," " hr=%08lx", hr); ret = -1; break; } if (exclusive_step_mode != WHPX_STEP_NONE || cpu->singlestep_enabled) { whpx_vcpu_configure_single_stepping(cpu, false, &vcpu->exit_ctx.VpContext.Rflags); } whpx_vcpu_post_run(cpu); switch (vcpu->exit_ctx.ExitReason) { case WHvRunVpExitReasonMemoryAccess: ret = whpx_handle_mmio(cpu, &vcpu->exit_ctx.MemoryAccess); break; case WHvRunVpExitReasonX64IoPortAccess: ret = whpx_handle_portio(cpu, &vcpu->exit_ctx.IoPortAccess); break; case WHvRunVpExitReasonX64InterruptWindow: vcpu->ready_for_pic_interrupt = 1; vcpu->window_registered = 0; ret = 0; break; case WHvRunVpExitReasonX64ApicEoi: assert(whpx_apic_in_platform()); ioapic_eoi_broadcast(vcpu->exit_ctx.ApicEoi.InterruptVector); break; case WHvRunVpExitReasonX64Halt: /* * WARNING: as of build 19043.1526 (21H1), this exit reason is no * longer used. */ ret = whpx_handle_halt(cpu); break; case WHvRunVpExitReasonX64ApicInitSipiTrap: { WHV_INTERRUPT_CONTROL ipi = {0}; uint64_t icr = vcpu->exit_ctx.ApicInitSipi.ApicIcr; uint32_t delivery_mode = (icr & APIC_ICR_DELIV_MOD) >> APIC_ICR_DELIV_MOD_SHIFT; int dest_shorthand = (icr & APIC_ICR_DEST_SHORT) >> APIC_ICR_DEST_SHORT_SHIFT; bool broadcast = false; bool include_self = false; uint32_t i; /* We only registered for INIT and SIPI exits. */ if ((delivery_mode != APIC_DM_INIT) && (delivery_mode != APIC_DM_SIPI)) { error_report( "WHPX: Unexpected APIC exit that is not a INIT or SIPI"); break; } if (delivery_mode == APIC_DM_INIT) { ipi.Type = WHvX64InterruptTypeInit; } else { ipi.Type = WHvX64InterruptTypeSipi; } ipi.DestinationMode = ((icr & APIC_ICR_DEST_MOD) >> APIC_ICR_DEST_MOD_SHIFT) ? WHvX64InterruptDestinationModeLogical : WHvX64InterruptDestinationModePhysical; ipi.TriggerMode = ((icr & APIC_ICR_TRIGGER_MOD) >> APIC_ICR_TRIGGER_MOD_SHIFT) ? WHvX64InterruptTriggerModeLevel : WHvX64InterruptTriggerModeEdge; ipi.Vector = icr & APIC_VECTOR_MASK; switch (dest_shorthand) { /* no shorthand. Bits 56-63 contain the destination. */ case 0: ipi.Destination = (icr >> 56) & APIC_VECTOR_MASK; hr = whp_dispatch.WHvRequestInterrupt(whpx->partition, &ipi, sizeof(ipi)); if (FAILED(hr)) { error_report("WHPX: Failed to request interrupt hr=%08lx", hr); } break; /* self */ case 1: include_self = true; break; /* broadcast, including self */ case 2: broadcast = true; include_self = true; break; /* broadcast, excluding self */ case 3: broadcast = true; break; } if (!broadcast && !include_self) { break; } for (i = 0; i <= max_vcpu_index; i++) { if (i == cpu->cpu_index && !include_self) { continue; } /* * Assuming that APIC Ids are identity mapped since * WHvX64RegisterApicId & WHvX64RegisterInitialApicId registers * are not handled yet and the hypervisor doesn't allow the * guest to modify the APIC ID. */ ipi.Destination = i; hr = whp_dispatch.WHvRequestInterrupt(whpx->partition, &ipi, sizeof(ipi)); if (FAILED(hr)) { error_report( "WHPX: Failed to request SIPI for %d, hr=%08lx", i, hr); } } break; } case WHvRunVpExitReasonCanceled: if (exclusive_step_mode != WHPX_STEP_NONE) { /* * We are trying to step over a single instruction, and * likely got a request to stop from another thread. * Delay it until we are done stepping * over. */ ret = 0; } else { cpu->exception_index = EXCP_INTERRUPT; ret = 1; } break; case WHvRunVpExitReasonX64MsrAccess: { WHV_REGISTER_VALUE reg_values[3] = {0}; WHV_REGISTER_NAME reg_names[3]; UINT32 reg_count; reg_names[0] = WHvX64RegisterRip; reg_names[1] = WHvX64RegisterRax; reg_names[2] = WHvX64RegisterRdx; reg_values[0].Reg64 = vcpu->exit_ctx.VpContext.Rip + vcpu->exit_ctx.VpContext.InstructionLength; /* * For all unsupported MSR access we: * ignore writes * return 0 on read. */ reg_count = vcpu->exit_ctx.MsrAccess.AccessInfo.IsWrite ? 1 : 3; hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, reg_names, reg_count, reg_values); if (FAILED(hr)) { error_report("WHPX: Failed to set MsrAccess state " " registers, hr=%08lx", hr); } ret = 0; break; } case WHvRunVpExitReasonX64Cpuid: { WHV_REGISTER_VALUE reg_values[5]; WHV_REGISTER_NAME reg_names[5]; UINT32 reg_count = 5; UINT64 cpuid_fn, rip = 0, rax = 0, rcx = 0, rdx = 0, rbx = 0; X86CPU *x86_cpu = X86_CPU(cpu); CPUX86State *env = &x86_cpu->env; memset(reg_values, 0, sizeof(reg_values)); rip = vcpu->exit_ctx.VpContext.Rip + vcpu->exit_ctx.VpContext.InstructionLength; cpuid_fn = vcpu->exit_ctx.CpuidAccess.Rax; /* * Ideally, these should be supplied to the hypervisor during VCPU * initialization and it should be able to satisfy this request. * But, currently, WHPX doesn't support setting CPUID values in the * hypervisor once the partition has been setup, which is too late * since VCPUs are realized later. For now, use the values from * QEMU to satisfy these requests, until WHPX adds support for * being able to set these values in the hypervisor at runtime. */ cpu_x86_cpuid(env, cpuid_fn, 0, (UINT32 *)&rax, (UINT32 *)&rbx, (UINT32 *)&rcx, (UINT32 *)&rdx); switch (cpuid_fn) { case 0x40000000: /* Expose the vmware cpu frequency cpuid leaf */ rax = 0x40000010; rbx = rcx = rdx = 0; break; case 0x40000010: rax = env->tsc_khz; rbx = env->apic_bus_freq / 1000; /* Hz to KHz */ rcx = rdx = 0; break; case 0x80000001: /* Remove any support of OSVW */ rcx &= ~CPUID_EXT3_OSVW; break; } reg_names[0] = WHvX64RegisterRip; reg_names[1] = WHvX64RegisterRax; reg_names[2] = WHvX64RegisterRcx; reg_names[3] = WHvX64RegisterRdx; reg_names[4] = WHvX64RegisterRbx; reg_values[0].Reg64 = rip; reg_values[1].Reg64 = rax; reg_values[2].Reg64 = rcx; reg_values[3].Reg64 = rdx; reg_values[4].Reg64 = rbx; hr = whp_dispatch.WHvSetVirtualProcessorRegisters( whpx->partition, cpu->cpu_index, reg_names, reg_count, reg_values); if (FAILED(hr)) { error_report("WHPX: Failed to set CpuidAccess state registers," " hr=%08lx", hr); } ret = 0; break; } case WHvRunVpExitReasonException: whpx_get_registers(cpu); if ((vcpu->exit_ctx.VpException.ExceptionType == WHvX64ExceptionTypeDebugTrapOrFault) && (vcpu->exit_ctx.VpException.InstructionByteCount >= 1) && (vcpu->exit_ctx.VpException.InstructionBytes[0] == whpx_breakpoint_instruction)) { /* Stopped at a software breakpoint. */ cpu->exception_index = EXCP_DEBUG; } else if ((vcpu->exit_ctx.VpException.ExceptionType == WHvX64ExceptionTypeDebugTrapOrFault) && !cpu->singlestep_enabled) { /* * Just finished stepping over a breakpoint, but the * gdb does not expect us to do single-stepping. * Don't do anything special. */ cpu->exception_index = EXCP_INTERRUPT; } else { /* Another exception or debug event. Report it to GDB. */ cpu->exception_index = EXCP_DEBUG; } ret = 1; break; case WHvRunVpExitReasonNone: case WHvRunVpExitReasonUnrecoverableException: case WHvRunVpExitReasonInvalidVpRegisterValue: case WHvRunVpExitReasonUnsupportedFeature: default: error_report("WHPX: Unexpected VP exit code %d", vcpu->exit_ctx.ExitReason); whpx_get_registers(cpu); qemu_mutex_lock_iothread(); qemu_system_guest_panicked(cpu_get_crash_info(cpu)); qemu_mutex_unlock_iothread(); break; } } while (!ret); if (stepped_over_bp) { /* Restore the breakpoint we stepped over */ cpu_memory_rw_debug(cpu, stepped_over_bp->address, (void *)&whpx_breakpoint_instruction, 1, true); } if (exclusive_step_mode != WHPX_STEP_NONE) { g_assert(cpu_in_exclusive_context(cpu)); cpu->running = false; end_exclusive(); exclusive_step_mode = WHPX_STEP_NONE; } else { cpu_exec_end(cpu); } qemu_mutex_lock_iothread(); current_cpu = cpu; if (--whpx->running_cpus == 0) { whpx_last_vcpu_stopping(cpu); } qatomic_set(&cpu->exit_request, false); return ret < 0; } static void do_whpx_cpu_synchronize_state(CPUState *cpu, run_on_cpu_data arg) { if (!cpu->vcpu_dirty) { whpx_get_registers(cpu); cpu->vcpu_dirty = true; } } static void do_whpx_cpu_synchronize_post_reset(CPUState *cpu, run_on_cpu_data arg) { whpx_set_registers(cpu, WHPX_SET_RESET_STATE); cpu->vcpu_dirty = false; } static void do_whpx_cpu_synchronize_post_init(CPUState *cpu, run_on_cpu_data arg) { whpx_set_registers(cpu, WHPX_SET_FULL_STATE); cpu->vcpu_dirty = false; } static void do_whpx_cpu_synchronize_pre_loadvm(CPUState *cpu, run_on_cpu_data arg) { cpu->vcpu_dirty = true; } /* * CPU support. */ void whpx_cpu_synchronize_state(CPUState *cpu) { if (!cpu->vcpu_dirty) { run_on_cpu(cpu, do_whpx_cpu_synchronize_state, RUN_ON_CPU_NULL); } } void whpx_cpu_synchronize_post_reset(CPUState *cpu) { run_on_cpu(cpu, do_whpx_cpu_synchronize_post_reset, RUN_ON_CPU_NULL); } void whpx_cpu_synchronize_post_init(CPUState *cpu) { run_on_cpu(cpu, do_whpx_cpu_synchronize_post_init, RUN_ON_CPU_NULL); } void whpx_cpu_synchronize_pre_loadvm(CPUState *cpu) { run_on_cpu(cpu, do_whpx_cpu_synchronize_pre_loadvm, RUN_ON_CPU_NULL); } void whpx_cpu_synchronize_pre_resume(bool step_pending) { whpx_global.step_pending = step_pending; } /* * Vcpu support. */ static Error *whpx_migration_blocker; static void whpx_cpu_update_state(void *opaque, bool running, RunState state) { CPUX86State *env = opaque; if (running) { env->tsc_valid = false; } } int whpx_init_vcpu(CPUState *cpu) { HRESULT hr; struct whpx_state *whpx = &whpx_global; struct whpx_vcpu *vcpu = NULL; Error *local_error = NULL; CPUX86State *env = cpu->env_ptr; X86CPU *x86_cpu = X86_CPU(cpu); UINT64 freq = 0; int ret; /* Add migration blockers for all unsupported features of the * Windows Hypervisor Platform */ if (whpx_migration_blocker == NULL) { error_setg(&whpx_migration_blocker, "State blocked due to non-migratable CPUID feature support," "dirty memory tracking support, and XSAVE/XRSTOR support"); if (migrate_add_blocker(whpx_migration_blocker, &local_error) < 0) { error_report_err(local_error); error_free(whpx_migration_blocker); ret = -EINVAL; goto error; } } vcpu = g_new0(struct whpx_vcpu, 1); if (!vcpu) { error_report("WHPX: Failed to allocte VCPU context."); ret = -ENOMEM; goto error; } hr = whp_dispatch.WHvEmulatorCreateEmulator( &whpx_emu_callbacks, &vcpu->emulator); if (FAILED(hr)) { error_report("WHPX: Failed to setup instruction completion support," " hr=%08lx", hr); ret = -EINVAL; goto error; } hr = whp_dispatch.WHvCreateVirtualProcessor( whpx->partition, cpu->cpu_index, 0); if (FAILED(hr)) { error_report("WHPX: Failed to create a virtual processor," " hr=%08lx", hr); whp_dispatch.WHvEmulatorDestroyEmulator(vcpu->emulator); ret = -EINVAL; goto error; } /* * vcpu's TSC frequency is either specified by user, or use the value * provided by Hyper-V if the former is not present. In the latter case, we * query it from Hyper-V and record in env->tsc_khz, so that vcpu's TSC * frequency can be migrated later via this field. */ if (!env->tsc_khz) { hr = whp_dispatch.WHvGetCapability( WHvCapabilityCodeProcessorClockFrequency, &freq, sizeof(freq), NULL); if (hr != WHV_E_UNKNOWN_CAPABILITY) { if (FAILED(hr)) { printf("WHPX: Failed to query tsc frequency, hr=0x%08lx\n", hr); } else { env->tsc_khz = freq / 1000; /* Hz to KHz */ } } } env->apic_bus_freq = HYPERV_APIC_BUS_FREQUENCY; hr = whp_dispatch.WHvGetCapability( WHvCapabilityCodeInterruptClockFrequency, &freq, sizeof(freq), NULL); if (hr != WHV_E_UNKNOWN_CAPABILITY) { if (FAILED(hr)) { printf("WHPX: Failed to query apic bus frequency hr=0x%08lx\n", hr); } else { env->apic_bus_freq = freq; } } /* * If the vmware cpuid frequency leaf option is set, and we have a valid * tsc value, trap the corresponding cpuid's. */ if (x86_cpu->vmware_cpuid_freq && env->tsc_khz) { UINT32 cpuidExitList[] = {1, 0x80000001, 0x40000000, 0x40000010}; hr = whp_dispatch.WHvSetPartitionProperty( whpx->partition, WHvPartitionPropertyCodeCpuidExitList, cpuidExitList, RTL_NUMBER_OF(cpuidExitList) * sizeof(UINT32)); if (FAILED(hr)) { error_report("WHPX: Failed to set partition CpuidExitList hr=%08lx", hr); ret = -EINVAL; goto error; } } vcpu->interruptable = true; cpu->vcpu_dirty = true; cpu->hax_vcpu = (struct hax_vcpu_state *)vcpu; max_vcpu_index = max(max_vcpu_index, cpu->cpu_index); qemu_add_vm_change_state_handler(whpx_cpu_update_state, cpu->env_ptr); return 0; error: g_free(vcpu); return ret; } int whpx_vcpu_exec(CPUState *cpu) { int ret; int fatal; for (;;) { if (cpu->exception_index >= EXCP_INTERRUPT) { ret = cpu->exception_index; cpu->exception_index = -1; break; } fatal = whpx_vcpu_run(cpu); if (fatal) { error_report("WHPX: Failed to exec a virtual processor"); abort(); } } return ret; } void whpx_destroy_vcpu(CPUState *cpu) { struct whpx_state *whpx = &whpx_global; struct whpx_vcpu *vcpu = get_whpx_vcpu(cpu); whp_dispatch.WHvDeleteVirtualProcessor(whpx->partition, cpu->cpu_index); whp_dispatch.WHvEmulatorDestroyEmulator(vcpu->emulator); g_free(cpu->hax_vcpu); return; } void whpx_vcpu_kick(CPUState *cpu) { struct whpx_state *whpx = &whpx_global; whp_dispatch.WHvCancelRunVirtualProcessor( whpx->partition, cpu->cpu_index, 0); } /* * Memory support. */ static void whpx_update_mapping(hwaddr start_pa, ram_addr_t size, void *host_va, int add, int rom, const char *name) { struct whpx_state *whpx = &whpx_global; HRESULT hr; /* if (add) { printf("WHPX: ADD PA:%p Size:%p, Host:%p, %s, '%s'\n", (void*)start_pa, (void*)size, host_va, (rom ? "ROM" : "RAM"), name); } else { printf("WHPX: DEL PA:%p Size:%p, Host:%p, '%s'\n", (void*)start_pa, (void*)size, host_va, name); } */ if (add) { hr = whp_dispatch.WHvMapGpaRange(whpx->partition, host_va, start_pa, size, (WHvMapGpaRangeFlagRead | WHvMapGpaRangeFlagExecute | (rom ? 0 : WHvMapGpaRangeFlagWrite))); } else { hr = whp_dispatch.WHvUnmapGpaRange(whpx->partition, start_pa, size); } if (FAILED(hr)) { error_report("WHPX: Failed to %s GPA range '%s' PA:%p, Size:%p bytes," " Host:%p, hr=%08lx", (add ? "MAP" : "UNMAP"), name, (void *)(uintptr_t)start_pa, (void *)size, host_va, hr); } } static void whpx_process_section(MemoryRegionSection *section, int add) { MemoryRegion *mr = section->mr; hwaddr start_pa = section->offset_within_address_space; ram_addr_t size = int128_get64(section->size); unsigned int delta; uint64_t host_va; if (!memory_region_is_ram(mr)) { return; } delta = qemu_real_host_page_size() - (start_pa & ~qemu_real_host_page_mask()); delta &= ~qemu_real_host_page_mask(); if (delta > size) { return; } start_pa += delta; size -= delta; size &= qemu_real_host_page_mask(); if (!size || (start_pa & ~qemu_real_host_page_mask())) { return; } host_va = (uintptr_t)memory_region_get_ram_ptr(mr) + section->offset_within_region + delta; whpx_update_mapping(start_pa, size, (void *)(uintptr_t)host_va, add, memory_region_is_rom(mr), mr->name); } static void whpx_region_add(MemoryListener *listener, MemoryRegionSection *section) { memory_region_ref(section->mr); whpx_process_section(section, 1); } static void whpx_region_del(MemoryListener *listener, MemoryRegionSection *section) { whpx_process_section(section, 0); memory_region_unref(section->mr); } static void whpx_transaction_begin(MemoryListener *listener) { } static void whpx_transaction_commit(MemoryListener *listener) { } static void whpx_log_sync(MemoryListener *listener, MemoryRegionSection *section) { MemoryRegion *mr = section->mr; if (!memory_region_is_ram(mr)) { return; } memory_region_set_dirty(mr, 0, int128_get64(section->size)); } static MemoryListener whpx_memory_listener = { .name = "whpx", .begin = whpx_transaction_begin, .commit = whpx_transaction_commit, .region_add = whpx_region_add, .region_del = whpx_region_del, .log_sync = whpx_log_sync, .priority = 10, }; static void whpx_memory_init(void) { memory_listener_register(&whpx_memory_listener, &address_space_memory); } /* * Load the functions from the given library, using the given handle. If a * handle is provided, it is used, otherwise the library is opened. The * handle will be updated on return with the opened one. */ static bool load_whp_dispatch_fns(HMODULE *handle, WHPFunctionList function_list) { HMODULE hLib = *handle; #define WINHV_PLATFORM_DLL "WinHvPlatform.dll" #define WINHV_EMULATION_DLL "WinHvEmulation.dll" #define WHP_LOAD_FIELD_OPTIONAL(return_type, function_name, signature) \ whp_dispatch.function_name = \ (function_name ## _t)GetProcAddress(hLib, #function_name); \ #define WHP_LOAD_FIELD(return_type, function_name, signature) \ whp_dispatch.function_name = \ (function_name ## _t)GetProcAddress(hLib, #function_name); \ if (!whp_dispatch.function_name) { \ error_report("Could not load function %s", #function_name); \ goto error; \ } \ #define WHP_LOAD_LIB(lib_name, handle_lib) \ if (!handle_lib) { \ handle_lib = LoadLibrary(lib_name); \ if (!handle_lib) { \ error_report("Could not load library %s.", lib_name); \ goto error; \ } \ } \ switch (function_list) { case WINHV_PLATFORM_FNS_DEFAULT: WHP_LOAD_LIB(WINHV_PLATFORM_DLL, hLib) LIST_WINHVPLATFORM_FUNCTIONS(WHP_LOAD_FIELD) break; case WINHV_EMULATION_FNS_DEFAULT: WHP_LOAD_LIB(WINHV_EMULATION_DLL, hLib) LIST_WINHVEMULATION_FUNCTIONS(WHP_LOAD_FIELD) break; case WINHV_PLATFORM_FNS_SUPPLEMENTAL: WHP_LOAD_LIB(WINHV_PLATFORM_DLL, hLib) LIST_WINHVPLATFORM_FUNCTIONS_SUPPLEMENTAL(WHP_LOAD_FIELD_OPTIONAL) break; } *handle = hLib; return true; error: if (hLib) { FreeLibrary(hLib); } return false; } static void whpx_set_kernel_irqchip(Object *obj, Visitor *v, const char *name, void *opaque, Error **errp) { struct whpx_state *whpx = &whpx_global; OnOffSplit mode; if (!visit_type_OnOffSplit(v, name, &mode, errp)) { return; } switch (mode) { case ON_OFF_SPLIT_ON: whpx->kernel_irqchip_allowed = true; whpx->kernel_irqchip_required = true; break; case ON_OFF_SPLIT_OFF: whpx->kernel_irqchip_allowed = false; whpx->kernel_irqchip_required = false; break; case ON_OFF_SPLIT_SPLIT: error_setg(errp, "WHPX: split irqchip currently not supported"); error_append_hint(errp, "Try without kernel-irqchip or with kernel-irqchip=on|off"); break; default: /* * The value was checked in visit_type_OnOffSplit() above. If * we get here, then something is wrong in QEMU. */ abort(); } } /* * Partition support */ static int whpx_accel_init(MachineState *ms) { struct whpx_state *whpx; int ret; HRESULT hr; WHV_CAPABILITY whpx_cap; UINT32 whpx_cap_size; WHV_PARTITION_PROPERTY prop; UINT32 cpuidExitList[] = {1, 0x80000001}; WHV_CAPABILITY_FEATURES features = {0}; whpx = &whpx_global; if (!init_whp_dispatch()) { ret = -ENOSYS; goto error; } whpx->mem_quota = ms->ram_size; hr = whp_dispatch.WHvGetCapability( WHvCapabilityCodeHypervisorPresent, &whpx_cap, sizeof(whpx_cap), &whpx_cap_size); if (FAILED(hr) || !whpx_cap.HypervisorPresent) { error_report("WHPX: No accelerator found, hr=%08lx", hr); ret = -ENOSPC; goto error; } hr = whp_dispatch.WHvGetCapability( WHvCapabilityCodeFeatures, &features, sizeof(features), NULL); if (FAILED(hr)) { error_report("WHPX: Failed to query capabilities, hr=%08lx", hr); ret = -EINVAL; goto error; } hr = whp_dispatch.WHvCreatePartition(&whpx->partition); if (FAILED(hr)) { error_report("WHPX: Failed to create partition, hr=%08lx", hr); ret = -EINVAL; goto error; } /* * Query the XSAVE capability of the partition. Any error here is not * considered fatal. */ hr = whp_dispatch.WHvGetPartitionProperty( whpx->partition, WHvPartitionPropertyCodeProcessorXsaveFeatures, &whpx_xsave_cap, sizeof(whpx_xsave_cap), &whpx_cap_size); /* * Windows version which don't support this property will return with the * specific error code. */ if (FAILED(hr) && hr != WHV_E_UNKNOWN_PROPERTY) { error_report("WHPX: Failed to query XSAVE capability, hr=%08lx", hr); } if (!whpx_has_xsave()) { printf("WHPX: Partition is not XSAVE capable\n"); } memset(&prop, 0, sizeof(WHV_PARTITION_PROPERTY)); prop.ProcessorCount = ms->smp.cpus; hr = whp_dispatch.WHvSetPartitionProperty( whpx->partition, WHvPartitionPropertyCodeProcessorCount, &prop, sizeof(WHV_PARTITION_PROPERTY)); if (FAILED(hr)) { error_report("WHPX: Failed to set partition core count to %d," " hr=%08lx", ms->smp.cores, hr); ret = -EINVAL; goto error; } /* * Error out if WHP doesn't support apic emulation and user is requiring * it. */ if (whpx->kernel_irqchip_required && (!features.LocalApicEmulation || !whp_dispatch.WHvSetVirtualProcessorInterruptControllerState2)) { error_report("WHPX: kernel irqchip requested, but unavailable. " "Try without kernel-irqchip or with kernel-irqchip=off"); ret = -EINVAL; goto error; } if (whpx->kernel_irqchip_allowed && features.LocalApicEmulation && whp_dispatch.WHvSetVirtualProcessorInterruptControllerState2) { WHV_X64_LOCAL_APIC_EMULATION_MODE mode = WHvX64LocalApicEmulationModeXApic; printf("WHPX: setting APIC emulation mode in the hypervisor\n"); hr = whp_dispatch.WHvSetPartitionProperty( whpx->partition, WHvPartitionPropertyCodeLocalApicEmulationMode, &mode, sizeof(mode)); if (FAILED(hr)) { error_report("WHPX: Failed to enable kernel irqchip hr=%08lx", hr); if (whpx->kernel_irqchip_required) { error_report("WHPX: kernel irqchip requested, but unavailable"); ret = -EINVAL; goto error; } } else { whpx->apic_in_platform = true; } } /* Register for MSR and CPUID exits */ memset(&prop, 0, sizeof(WHV_PARTITION_PROPERTY)); prop.ExtendedVmExits.X64MsrExit = 1; prop.ExtendedVmExits.X64CpuidExit = 1; prop.ExtendedVmExits.ExceptionExit = 1; if (whpx_apic_in_platform()) { prop.ExtendedVmExits.X64ApicInitSipiExitTrap = 1; } hr = whp_dispatch.WHvSetPartitionProperty( whpx->partition, WHvPartitionPropertyCodeExtendedVmExits, &prop, sizeof(WHV_PARTITION_PROPERTY)); if (FAILED(hr)) { error_report("WHPX: Failed to enable MSR & CPUIDexit, hr=%08lx", hr); ret = -EINVAL; goto error; } hr = whp_dispatch.WHvSetPartitionProperty( whpx->partition, WHvPartitionPropertyCodeCpuidExitList, cpuidExitList, RTL_NUMBER_OF(cpuidExitList) * sizeof(UINT32)); if (FAILED(hr)) { error_report("WHPX: Failed to set partition CpuidExitList hr=%08lx", hr); ret = -EINVAL; goto error; } /* * We do not want to intercept any exceptions from the guest, * until we actually start debugging with gdb. */ whpx->exception_exit_bitmap = -1; hr = whpx_set_exception_exit_bitmap(0); if (FAILED(hr)) { error_report("WHPX: Failed to set exception exit bitmap, hr=%08lx", hr); ret = -EINVAL; goto error; } hr = whp_dispatch.WHvSetupPartition(whpx->partition); if (FAILED(hr)) { error_report("WHPX: Failed to setup partition, hr=%08lx", hr); ret = -EINVAL; goto error; } whpx_memory_init(); printf("Windows Hypervisor Platform accelerator is operational\n"); return 0; error: if (NULL != whpx->partition) { whp_dispatch.WHvDeletePartition(whpx->partition); whpx->partition = NULL; } return ret; } int whpx_enabled(void) { return whpx_allowed; } bool whpx_apic_in_platform(void) { return whpx_global.apic_in_platform; } static void whpx_accel_class_init(ObjectClass *oc, void *data) { AccelClass *ac = ACCEL_CLASS(oc); ac->name = "WHPX"; ac->init_machine = whpx_accel_init; ac->allowed = &whpx_allowed; object_class_property_add(oc, "kernel-irqchip", "on|off|split", NULL, whpx_set_kernel_irqchip, NULL, NULL); object_class_property_set_description(oc, "kernel-irqchip", "Configure WHPX in-kernel irqchip"); } static void whpx_accel_instance_init(Object *obj) { struct whpx_state *whpx = &whpx_global; memset(whpx, 0, sizeof(struct whpx_state)); /* Turn on kernel-irqchip, by default */ whpx->kernel_irqchip_allowed = true; } static const TypeInfo whpx_accel_type = { .name = ACCEL_CLASS_NAME("whpx"), .parent = TYPE_ACCEL, .instance_init = whpx_accel_instance_init, .class_init = whpx_accel_class_init, }; static void whpx_type_init(void) { type_register_static(&whpx_accel_type); } bool init_whp_dispatch(void) { if (whp_dispatch_initialized) { return true; } if (!load_whp_dispatch_fns(&hWinHvPlatform, WINHV_PLATFORM_FNS_DEFAULT)) { goto error; } if (!load_whp_dispatch_fns(&hWinHvEmulation, WINHV_EMULATION_FNS_DEFAULT)) { goto error; } assert(load_whp_dispatch_fns(&hWinHvPlatform, WINHV_PLATFORM_FNS_SUPPLEMENTAL)); whp_dispatch_initialized = true; return true; error: if (hWinHvPlatform) { FreeLibrary(hWinHvPlatform); } if (hWinHvEmulation) { FreeLibrary(hWinHvEmulation); } return false; } type_init(whpx_type_init);