--- /dev/null
+/*
+ * This file is part of the Palacios Virtual Machine Monitor developed
+ * by the V3VEE Project with funding from the United States National
+ * Science Foundation and the Department of Energy.
+ *
+ * The V3VEE Project is a joint project between Northwestern University
+ * and the University of New Mexico. You can find out more at
+ * http://www.v3vee.org
+ *
+ * Copyright (c) 2008, Peter Dinda <pdinda@northwestern.edu>
+ * Copyright (c) 2008, Jack Lange <jarusl@cs.northwestern.edu>
+ * Copyright (c) 2008, The V3VEE Project <http://www.v3vee.org>
+ * All rights reserved.
+ *
+ * Author: Peter Dinda <pdinda@northwestern.edu>
+ * Jack Lange <jarusl@cs.northwestern.edu>
+ *
+ * This is free software. You are permitted to use,
+ * redistribute, and modify it as specified in the file "V3VEE_LICENSE".
+ */
+
+
+/* Eventually we want to get rid of these */
+
+#include <geekos/cpu.h>
+#include <geekos/io_devs.h>
+#include <geekos/io.h>
+/* ** */
+
+#include <palacios/vmx.h>
+#include <palacios/vmcs.h>
+#include <palacios/vmm.h>
+#include <palacios/vmm_util.h>
+#include <palacios/vmm_string.h>
+
+
+extern void Get_MSR(unsigned int msr, uint_t * high, uint_t * low);
+extern void Set_MSR(unsigned int msr, uint_t high, uint_t low);
+extern int Enable_VMX(ullong_t regionPtr);
+extern int cpuid_ecx(unsigned int op);
+extern int Launch_VM(ullong_t vmcsPtr, uint_t eip);
+
+#define NUMPORTS 65536
+
+
+#define VMXASSIST_INFO_PORT 0x0e9
+#define ROMBIOS_PANIC_PORT 0x400
+#define ROMBIOS_PANIC_PORT2 0x401
+#define ROMBIOS_INFO_PORT 0x402
+#define ROMBIOS_DEBUG_PORT 0x403
+
+
+extern struct vmm_os_hooks * os_hooks;
+
+
+static struct VM theVM;
+
+static uint_t GetLinearIP(struct VM *vm)
+{
+ if (vm->state==VM_VMXASSIST_V8086_BIOS || vm->state==VM_VMXASSIST_V8086) {
+ return vm->vmcs.guestStateArea.cs.baseAddr + vm->vmcs.guestStateArea.rip;
+ } else {
+ return vm->vmcs.guestStateArea.rip;
+ }
+}
+
+
+static void VMXPanic()
+{
+ while (1) {}
+}
+
+
+#define MAX_CODE 512
+#define INSTR_OFFSET_START 17
+#define NOP_SEQ_LEN 10
+#define INSTR_OFFSET_END (INSTR_OFFSET_START+NOP_SEQ_LEN-1)
+#define TEMPLATE_CODE_LEN 35
+
+uint_t oldesp=0;
+uint_t myregs=0;
+
+// simply execute the instruction that is faulting and return
+static int ExecFaultingInstructionInVMM(struct VM *vm)
+{
+ uint_t address = GetLinearIP(vm);
+ myregs = (uint_t)&(vm->registers);
+
+
+ PrintTrace("About the execute faulting instruction!\n");
+ PrintTrace("Instruction is:\n");
+ PrintTraceMemDump((void*)(address),vm->vmcs.exitInfoFields.instrLength);
+
+
+ PrintTrace("The template code is:\n");
+ PrintTraceMemDump(&&template_code,TEMPLATE_CODE_LEN);
+
+ // clone the template code
+ //memcpy(&&template_code,code,MAX_CODE);
+
+ // clean up the nop field
+ memset(&&template_code+INSTR_OFFSET_START,*((uchar_t *)(&&template_code+0)),NOP_SEQ_LEN);
+ // overwrite the nops with the faulting instruction
+ memcpy(&&template_code+INSTR_OFFSET_START, (void*)(address),vm->vmcs.exitInfoFields.instrLength);
+
+ PrintTrace("Finished modifying the template code, which now is:\n");
+ PrintTraceMemDump(&&template_code,TEMPLATE_CODE_LEN);
+
+ PrintTrace("Now entering modified template code\n");
+
+
+ template_code:
+ // Template code stores current registers,
+ // restores registers, has a landing pad of noops
+ // that will be modified, restores current regs, and then returns
+ //
+ // Note that this currently ignores cr0, cr3, cr4, dr7, rsp, rip, and rflags
+ // it also blythly assumes it can exec the instruction in protected mode
+ //
+ __asm__ __volatile__ ("nop\n" // for cloning purposes (1 byte)
+ "pusha\n" // push our current regs onto the current stack (1 byte)
+ "movl %0, %%eax\n" // Get oldesp location (5 bytes)
+ "movl %%esp, (%%eax)\n" // store the current stack pointer in oldesp (2 bytes)
+ "movl %1, %%eax\n" // Get regs location (5 bytes)
+ "movl (%%eax), %%esp\n" // point esp at regs (2 bytes)
+ "popa\n" // now we have the VM registers restored (1 byte)
+ "nop\n" // now we execute the actual instruction (1 byte x 10)
+ "nop\n" // now we execute the actual instruction
+ "nop\n" // now we execute the actual instruction
+ "nop\n" // now we execute the actual instruction
+ "nop\n" // now we execute the actual instruction
+ "nop\n" // now we execute the actual instruction
+ "nop\n" // now we execute the actual instruction
+ "nop\n" // now we execute the actual instruction
+ "nop\n" // now we execute the actual instruction
+ "nop\n" // now we execute the actual instruction
+ // need to copy back to the VM registers!
+ "movl %0, %%eax\n" // recapture oldesp location (5 bytes)
+ "movl (%%eax), %%esp\n" // now we'll get our esp back from oldesp (2 bytes)
+ "popa\n" // and restore our GP regs and we're done (1 byte)
+ : "=m"(oldesp)
+ : "m"(myregs)
+ );
+
+ PrintTrace("Survived executing the faulting instruction and returning.\n");
+
+ vm->vmcs.guestStateArea.rip += vm->vmcs.exitInfoFields.instrLength;
+
+ return 0;
+
+}
+
+
+int is_vmx_capable() {
+ uint_t ret;
+ union VMX_MSR featureMSR;
+
+ ret = cpuid_ecx(1);
+ if (ret & CPUID_1_ECX_VTXFLAG) {
+ Get_MSR(IA32_FEATURE_CONTROL_MSR, &featureMSR.regs.high, &featureMSR.regs.low);
+
+ PrintTrace("MSRREGlow: 0x%.8x\n", featureMSR.regs.low);
+
+ if ((featureMSR.regs.low & FEATURE_CONTROL_VALID) != FEATURE_CONTROL_VALID) {
+ PrintDebug("VMX is locked -- enable in the BIOS\n");
+ return 0;
+ }
+ } else {
+ PrintDebug("VMX not supported on this cpu\n");
+ return 0;
+ }
+
+ return 1;
+
+}
+
+
+VmxOnRegion * Init_VMX() {
+ uint_t ret;
+ VmxOnRegion * region = NULL;
+
+
+ region = CreateVmxOnRegion();
+
+
+ ret = Enable_VMX((ullong_t)((uint_t)region));
+ if (ret == 0) {
+ PrintDebug("VMX Enabled\n");
+ } else {
+ PrintDebug("VMX failure (ret = %d)\n", ret);
+ }
+
+ theVM.vmxonregion = region;
+
+ return region;
+}
+
+extern uint_t VMCS_CLEAR();
+extern uint_t VMCS_LOAD();
+extern uint_t VMCS_STORE();
+extern uint_t VMCS_LAUNCH();
+extern uint_t VMCS_RESUME();
+extern uint_t Init_VMCS_HostState();
+extern uint_t Init_VMCS_GuestState();
+
+void SetCtrlBitsCorrectly(int msrno, int vmcsno)
+{
+ uint_t reserved =0;
+ union VMX_MSR msr;
+
+ PrintTrace("SetCtrlBitsCorrectly(%x,%x)\n", msrno, vmcsno);
+ Get_MSR(msrno, &msr.regs.high, &msr.regs.low);
+ PrintTrace("MSR %x = %x : %x \n", msrno, msr.regs.high, msr.regs.low);
+ reserved = msr.regs.low;
+ reserved &= msr.regs.high;
+ VMCS_WRITE(vmcsno, &reserved);
+}
+
+
+void SetCRBitsCorrectly(int msr0no, int msr1no, int vmcsno)
+{
+ uint_t reserved =0;
+ union VMX_MSR msr0, msr1;
+
+ PrintTrace("SetCRBitsCorrectly(%x,%x,%x)\n",msr0no,msr1no,vmcsno);
+ Get_MSR(msr0no, &msr0.regs.high, &msr0.regs.low);
+ Get_MSR(msr1no, &msr1.regs.high, &msr1.regs.low);
+ PrintTrace("MSR %x = %x, %x = %x \n", msr0no, msr0.regs.low, msr1no, msr1.regs.low);
+ reserved = msr0.regs.low;
+ reserved &= msr1.regs.low;
+ VMCS_WRITE(vmcsno, &reserved);
+}
+
+
+extern int Get_CR2();
+extern int vmRunning;
+
+
+static int PanicUnhandledVMExit(struct VM *vm)
+{
+ PrintInfo("Panicking due to VMExit with reason %u\n", vm->vmcs.exitInfoFields.reason);
+ PrintTrace("Panicking due to VMExit with reason %u\n", vm->vmcs.exitInfoFields.reason);
+ PrintTrace_VMCS_ALL();
+ PrintTrace_VMX_Regs(&(vm->registers));
+ VMXPanic();
+ return 0;
+}
+
+
+static int HandleVMPrintsAndPanics(struct VM *vm, uint_t port, uint_t data)
+{
+ if (port==VMXASSIST_INFO_PORT &&
+ (vm->state == VM_VMXASSIST_STARTUP ||
+ vm->state == VM_VMXASSIST_V8086_BIOS ||
+ vm->state == VM_VMXASSIST_V8086)) {
+ // Communication channel from VMXAssist
+ PrintTrace("VMXASSIST Output Port\n");
+ PrintDebug("%c",data&0xff);
+ return 1;
+ }
+
+ if ((port==ROMBIOS_PANIC_PORT ||
+ port==ROMBIOS_PANIC_PORT2 ||
+ port==ROMBIOS_DEBUG_PORT ||
+ port==ROMBIOS_INFO_PORT) &&
+ (vm->state==VM_VMXASSIST_V8086_BIOS)) {
+ // rombios is communicating
+ PrintTrace("ROMBIOS Output Port\n");
+ // PrintDebug("%c",data&0xff);
+ return 1;
+ }
+
+ if (port==BOOT_STATE_CARD_PORT && vm->state==VM_VMXASSIST_V8086_BIOS) {
+ // rombios is sending something to the display card
+ PrintTrace("Hex Display: 0x%x\n",data&0xff);
+ return 1;
+ }
+ return 0;
+}
+
+static int HandleInOutExit(struct VM *vm)
+{
+ uint_t address;
+
+ struct VMCSExitInfoFields *exitinfo = &(vm->vmcs.exitInfoFields);
+ struct VMExitIOQual * qual = (struct VMExitIOQual *)&(vm->vmcs.exitInfoFields.qualification);
+ struct VMXRegs *regs = &(vm->registers);
+
+ address=GetLinearIP(vm);
+
+ PrintTrace("Handling Input/Output Instruction Exit\n");
+
+ PrintTrace_VMX_Regs(regs);
+
+ PrintTrace("Qualifications=0x%x\n", exitinfo->qualification);
+ PrintTrace("Reason=0x%x\n", exitinfo->reason);
+ PrintTrace("IO Port: 0x%x (%d)\n", qual->port, qual->port);
+ PrintTrace("Instruction Info=%x\n", exitinfo->instrInfo);
+ PrintTrace("%x : %s %s %s instruction of length %d for %d bytes from/to port 0x%x\n",
+ address,
+ qual->dir == 0 ? "output" : "input",
+ qual->string ==0 ? "nonstring" : "STRING",
+ qual->REP == 0 ? "with no rep" : "WITH REP",
+ exitinfo->instrLength,
+ qual->accessSize==0 ? 1 : qual->accessSize==1 ? 2 : 4,
+ qual->port);
+
+ if ((qual->port == PIC_MASTER_CMD_ISR_PORT) ||
+ (qual->port == PIC_MASTER_IMR_PORT) ||
+ (qual->port == PIC_SLAVE_CMD_ISR_PORT) ||
+ (qual->port == PIC_SLAVE_IMR_PORT)) {
+ PrintTrace( "PIC Access\n");
+ }
+
+
+ if ((qual->dir == 1) && (qual->REP == 0) && (qual->string == 0)) {
+ char byte = In_Byte(qual->port);
+
+ vm->vmcs.guestStateArea.rip += exitinfo->instrLength;
+ regs->eax = (regs->eax & 0xffffff00) | byte;
+ PrintTrace("Returning 0x%x in eax\n", (regs->eax));
+ }
+
+ if (qual->dir==0 && qual->REP==0 && qual->string==0) {
+ // See if we need to handle the outb as a signal or
+ // print from the VM
+ if (HandleVMPrintsAndPanics(vm,qual->port,regs->eax)) {
+ } else {
+ // If not, just go ahead and do the outb
+ Out_Byte(qual->port,regs->eax);
+ PrintTrace("Wrote 0x%x to port\n",(regs->eax));
+ }
+ vm->vmcs.guestStateArea.rip += exitinfo->instrLength;
+ }
+
+ return 0;
+}
+
+
+static int HandleExternalIRQExit(struct VM *vm)
+{
+ struct VMCSExitInfoFields * exitinfo = &(vm->vmcs.exitInfoFields);
+ struct VMExitIntInfo * intInfo = (struct VMExitIntInfo *)&(vm->vmcs.exitInfoFields.intInfo);
+
+ PrintTrace("External Interrupt captured\n");
+ PrintTrace("IntInfo: %x\n", exitinfo->intInfo);
+
+
+ if (!intInfo->valid) {
+ // interrupts are off, but this interrupt is not acknoledged (still pending)
+ // so we turn on interrupts to deliver appropriately in the
+ // host
+ PrintTrace("External Interrupt is invald. Turning Interrupts back on\n");
+ asm("sti");
+ return 0;
+ }
+
+ // At this point, interrupts are off and the interrupt has been
+ // acknowledged. We will now handle the interrupt ourselves
+ // and turn interrupts back on in the host
+
+ PrintTrace("type: %d\n", intInfo->type);
+ PrintTrace("number: %d\n", intInfo->nr);
+
+ PrintTrace("Interrupt %d occuring now and handled by HandleExternalIRQExit\n",intInfo->nr);
+
+ switch (intInfo->type) {
+ case 0: { // ext. IRQ
+ // In the following, we construct an "int x" instruction
+ // where x is the specific interrupt number that is raised
+ // then we execute that instruciton
+ // because we are in host context, that means it is delivered as normal
+ // through the host IDT
+
+ ((char*)(&&ext_int_seq_start))[1] = intInfo->nr;
+
+ PrintTrace("Interrupt instruction setup done %x\n", *((ushort_t *)(&&ext_int_seq_start)));
+
+ext_int_seq_start:
+ asm("int $0");
+ }
+
+ break;
+ case 2: // NMI
+ PrintTrace("Type: NMI\n");
+ break;
+ case 3: // hw exception
+ PrintTrace("Type: HW Exception\n");
+ break;
+ case 4: // sw exception
+ PrintTrace("Type: SW Exception\n");
+ break;
+ default:
+ PrintTrace("Invalid Interrupt Type\n");
+ return -1;
+ }
+
+ if (intInfo->valid && intInfo->errorCode) {
+ PrintTrace("IntError: %x\n", exitinfo->intErrorCode);
+ }
+
+
+ return 0;
+
+}
+
+
+
+void DecodeCurrentInstruction(struct VM *vm, struct Instruction *inst)
+{
+ // this is a gruesome hack
+ uint_t address = GetLinearIP(vm);
+ uint_t length = vm->vmcs.exitInfoFields.instrLength;
+ unsigned char *t = (unsigned char *) address;
+
+
+
+ PrintTrace("DecodeCurrentInstruction: instruction is\n");
+ PrintTraceMemDump(t,length);
+
+ if (length==3 && t[0]==0x0f && t[1]==0x22 && t[2]==0xc0) {
+ // mov from eax to cr0
+ // usually used to signal
+ inst->type=VM_MOV_TO_CR0;
+ inst->address=address;
+ inst->size=length;
+ inst->input1=vm->registers.eax;
+ inst->input2=vm->vmcs.guestStateArea.cr0;
+ inst->output=vm->registers.eax;
+ PrintTrace("MOV FROM EAX TO CR0\n");
+ } else {
+ inst->type=VM_UNKNOWN_INST;
+ }
+}
+
+
+static void V8086ModeSegmentRegisterFixup(struct VM *vm)
+{
+ vm->vmcs.guestStateArea.cs.baseAddr=vm->vmcs.guestStateArea.cs.selector<<4;
+ vm->vmcs.guestStateArea.es.baseAddr=vm->vmcs.guestStateArea.es.selector<<4;
+ vm->vmcs.guestStateArea.ss.baseAddr=vm->vmcs.guestStateArea.ss.selector<<4;
+ vm->vmcs.guestStateArea.ds.baseAddr=vm->vmcs.guestStateArea.ds.selector<<4;
+ vm->vmcs.guestStateArea.fs.baseAddr=vm->vmcs.guestStateArea.fs.selector<<4;
+ vm->vmcs.guestStateArea.gs.baseAddr=vm->vmcs.guestStateArea.gs.selector<<4;
+}
+
+static void SetupV8086ModeForBoot(struct VM *vm)
+{
+ vm->state = VM_VMXASSIST_V8086_BIOS;
+
+ // Put guest into V8086 mode on return
+ vm->vmcs.guestStateArea.rflags |= EFLAGS_VM | EFLAGS_IOPL_HI | EFLAGS_IOPL_LO ;
+
+ // We will start at f000:fff0 on return
+ //
+ // We want this to look as much as possible as a processor
+ // reset
+ vm->vmcs.guestStateArea.rip = 0xfff0; // note, 16 bit rip
+ vm->vmcs.guestStateArea.cs.selector = 0xf000;
+ vm->vmcs.guestStateArea.cs.limit=0xffff;
+ vm->vmcs.guestStateArea.cs.access.as_dword = 0xf3;
+
+ vm->vmcs.guestStateArea.ss.selector = 0x0000;
+ vm->vmcs.guestStateArea.ss.limit=0xffff;
+ vm->vmcs.guestStateArea.ss.access.as_dword = 0xf3;
+
+ vm->vmcs.guestStateArea.ds.selector = 0x0000;
+ vm->vmcs.guestStateArea.ds.limit=0xffff;
+ vm->vmcs.guestStateArea.ds.access.as_dword = 0xf3;
+
+ vm->vmcs.guestStateArea.es.selector = 0x0000;
+ vm->vmcs.guestStateArea.es.limit=0xffff;
+ vm->vmcs.guestStateArea.es.access.as_dword = 0xf3;
+
+ vm->vmcs.guestStateArea.fs.selector = 0x0000;
+ vm->vmcs.guestStateArea.fs.limit=0xffff;
+ vm->vmcs.guestStateArea.fs.access.as_dword = 0xf3;
+
+ vm->vmcs.guestStateArea.gs.selector = 0x0000;
+ vm->vmcs.guestStateArea.gs.limit=0xffff;
+ vm->vmcs.guestStateArea.gs.access.as_dword = 0xf3;
+
+ V8086ModeSegmentRegisterFixup(vm);
+
+ PrintTrace_VMCSData(&(vm->vmcs));
+
+}
+
+
+
+static int HandleExceptionOrNMI(struct VM *vm)
+{
+ struct Instruction inst;
+ uint_t num;
+ uint_t type;
+ uint_t errorvalid;
+ uint_t error;
+ uint_t ext=0;
+ uint_t idt=0;
+ uint_t ti=0;
+ uint_t selectorindex=0;
+
+ PrintTrace("Exception or NMI occurred\n");
+
+ num=vm->vmcs.exitInfoFields.intInfo & 0xff;
+ type=(vm->vmcs.exitInfoFields.intInfo & 0x700)>>8;
+ errorvalid=(vm->vmcs.exitInfoFields.intInfo & 0x800)>>11;
+ if (errorvalid) {
+ error=vm->vmcs.exitInfoFields.intErrorCode;
+ ext=error&0x1;
+ idt=(error&0x2)>>1;
+ ti=(error&0x4)>>2;
+ selectorindex=(error>>3)&0xffff;
+ }
+
+ PrintTrace("Exception %d now - handled by HandleExceptionOrNMI\n",num);
+
+ PrintTrace("Exception Number %u : %s\n", num, exception_names[num]);
+ PrintTrace("Exception Type %u : %s\n", type, exception_type_names[type]);
+ if (errorvalid) {
+ if (ext) {
+ PrintTrace("External\n");
+ } else {
+ PrintTrace("%s - Selector Index is %u\n", idt ? "IDT" : ti ? "LDT" : "GDT", selectorindex);
+ }
+ }
+
+ DecodeCurrentInstruction(vm,&inst);
+
+ if (inst.type==VM_MOV_TO_CR0) {
+ PrintTrace("MOV TO CR0, oldvalue=0x%x, newvalue=0x%x\n",inst.input2, inst.input1);
+ if ((inst.input2 & CR0_PE) && !(inst.input1 & CR0_PE) && vm->state==VM_VMXASSIST_STARTUP) {
+ // This is VMXAssist signalling for us to turn on V8086 mode and
+ // jump into the bios
+ PrintTrace("VMXAssist is signaling us for switch to V8086 mode and jump to 0xf000:fff0\n");
+ SetupV8086ModeForBoot(vm);
+ goto leave;
+ } else {
+ PrintTrace("Instruction is a write to CR0, but we don't understand it so we'll just exec it\n");
+ }
+ }
+
+
+ PrintTrace("Trying to execute the faulting instruction in VMM context now\n");
+ ExecFaultingInstructionInVMM(vm);
+
+ leave:
+ //
+ //PanicUnhandledVMExit(vmcs,regs);
+ //VMXPanic();
+ return 0;
+}
+
+
+static struct VM *FindVM()
+{
+ return &theVM;
+}
+
+
+int Do_VMM(struct VMXRegs regs)
+{
+
+ ullong_t vmcs_ptr = 0;
+ uint_t vmcs_ptr_low = 0;
+ int ret = 0;
+ uint_t vmx_abort = 0;
+
+
+
+ PrintTrace("Vm Exit\n");
+ ret = VMCS_STORE(&vmcs_ptr);
+ vmcs_ptr &= 0xffffffff;
+ vmcs_ptr_low += vmcs_ptr;
+
+
+
+
+ PrintTrace("ret=%d\n", ret);
+ PrintTrace("Revision: %x\n", *(uint_t *)(vmcs_ptr_low));
+ vmx_abort = *(uint_t*)(((char *)vmcs_ptr_low)+4);
+
+ struct VM *vm = FindVM();
+
+ if (vmx_abort != 0) {
+ PrintTrace("VM ABORTED w/ code: %x\n", vmx_abort);
+ return -1;
+ }
+
+ vm->registers = regs;
+
+ if (CopyOutVMCSData(&(vm->vmcs)) != 0) {
+ PrintTrace("Could not copy out VMCS\n");
+ return -1;
+ }
+
+
+ PrintTrace("Guest esp: 0x%x (%u)\n", vm->vmcs.guestStateArea.rsp, vm->vmcs.guestStateArea.rsp);
+
+ PrintTrace("VM Exit for reason: %d (%x)\n",
+ vm->vmcs.exitInfoFields.reason & 0x00000fff,
+ vm->vmcs.exitInfoFields.reason);
+
+ if (vm->vmcs.exitInfoFields.reason & (0x1<<29) ) {
+ PrintTrace("VM Exit is from VMX root operation. Panicking\n");
+ VMXPanic();
+ }
+
+ if (vm->vmcs.exitInfoFields.reason & (0x1<<31) ) {
+ PrintTrace("VM Exit is due to a VM entry failure. Shouldn't happen here. Panicking\n");
+ PrintTrace_VMCSData(&(vm->vmcs));
+ VMXPanic();
+ }
+
+ switch (vm->vmcs.exitInfoFields.reason) {
+ case VM_EXIT_REASON_INFO_EXCEPTION_OR_NMI:
+ ret = HandleExceptionOrNMI(vm);
+ break;
+ case VM_EXIT_REASON_EXTERNAL_INTR:
+ ret = HandleExternalIRQExit(vm);
+ break;
+ case VM_EXIT_REASON_TRIPLE_FAULT:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_INIT_SIGNAL:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_STARTUP_IPI:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_IO_SMI:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_OTHER_SMI:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_INTR_WINDOW:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_NMI_WINDOW:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_TASK_SWITCH:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_CPUID:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_INVD:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_INVLPG:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_RDPMC:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_RDTSC:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_RSM:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMCALL:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMCLEAR:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMLAUNCH:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMPTRLD:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMPTRST:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMREAD:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMRESUME:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMWRITE:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMXOFF:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_VMXON:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_CR_REG_ACCESSES:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_MOV_DR:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_IO_INSTR:
+ ret = HandleInOutExit(vm);
+ break;
+ case VM_EXIT_REASON_RDMSR:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_WRMSR:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_ENTRY_FAIL_INVALID_GUEST_STATE:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_ENTRY_FAIL_MSR_LOAD:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_MWAIT:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_MONITOR:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_PAUSE:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_ENTRY_FAILURE_MACHINE_CHECK:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ case VM_EXIT_REASON_TPR_BELOW_THRESHOLD:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ default:
+ ret = PanicUnhandledVMExit(vm);
+ break;
+ }
+
+
+ regs = vm->registers;
+ CopyInVMCSData(&(vm->vmcs));
+
+ /*
+ {
+ VMCS_CLEAR(vmcs_ptr);
+ }
+ */
+
+ PrintTrace("Returning from Do_VMM: %d\n", ret);
+
+ return ret;
+}
+
+
+static void ConfigureExits(struct VM *vm)
+{
+ CopyOutVMCSExecCtrlFields(&(vm->vmcs.execCtrlFields));
+
+ vm->vmcs.execCtrlFields.pinCtrls |= 0
+ // EXTERNAL_INTERRUPT_EXITING
+ | NMI_EXITING;
+ vm->vmcs.execCtrlFields.procCtrls |= 0
+ // INTERRUPT_WINDOWS_EXIT
+ | USE_TSC_OFFSETTING
+ | HLT_EXITING
+ |INVLPG_EXITING
+ |MWAIT_EXITING
+ |RDPMC_EXITING
+ |RDTSC_EXITING
+ |MOVDR_EXITING
+ |UNCONDITION_IO_EXITING
+ |MONITOR_EXITING
+ |PAUSE_EXITING ;
+
+ CopyInVMCSExecCtrlFields(&(vm->vmcs.execCtrlFields));
+
+ CopyOutVMCSExitCtrlFields(&(vm->vmcs.exitCtrlFields));
+
+ vm->vmcs.exitCtrlFields.exitCtrls |= ACK_IRQ_ON_EXIT;
+
+ CopyInVMCSExitCtrlFields(&(vm->vmcs.exitCtrlFields));
+
+
+/* VMCS_READ(VM_EXIT_CTRLS, &flags); */
+/* flags |= ACK_IRQ_ON_EXIT; */
+/* VMCS_WRITE(VM_EXIT_CTRLS, &flags); */
+}
+
+
+extern int RunVMM();
+extern int SAFE_VM_LAUNCH();
+
+int MyLaunch(struct VM *vm)
+{
+ ullong_t vmcs = (ullong_t)((uint_t) (vm->vmcsregion));
+ uint_t entry_eip = vm->descriptor.entry_ip;
+ uint_t exit_eip = vm->descriptor.exit_eip;
+ uint_t guest_esp = vm->descriptor.guest_esp;
+ uint_t f = 0xffffffff;
+ uint_t tmpReg = 0;
+ int ret;
+ int vmm_ret = 0;
+
+ PrintTrace("Guest ESP: 0x%x (%u)\n", guest_esp, guest_esp);
+
+ exit_eip=(uint_t)RunVMM;
+
+ PrintTrace("Clear\n");
+ VMCS_CLEAR(vmcs);
+ PrintTrace("Load\n");
+ VMCS_LOAD(vmcs);
+
+
+ PrintTrace("VMCS_LINK_PTR\n");
+ VMCS_WRITE(VMCS_LINK_PTR, &f);
+ PrintTrace("VMCS_LINK_PTR_HIGH\n");
+ VMCS_WRITE(VMCS_LINK_PTR_HIGH, &f);
+
+
+ SetCtrlBitsCorrectly(IA32_VMX_PINBASED_CTLS_MSR, PIN_VM_EXEC_CTRLS);
+ SetCtrlBitsCorrectly(IA32_VMX_PROCBASED_CTLS_MSR, PROC_VM_EXEC_CTRLS);
+ SetCtrlBitsCorrectly(IA32_VMX_EXIT_CTLS_MSR, VM_EXIT_CTRLS);
+ SetCtrlBitsCorrectly(IA32_VMX_ENTRY_CTLS_MSR, VM_ENTRY_CTRLS);
+
+ //
+ //
+ //SetCtrlBitsCorrectly(IA32_something,GUEST_IA32_DEBUGCTL);
+ //SetCtrlBitsCorrectly(IA32_something,GUEST_IA32_DEBUGCTL_HIGH);
+
+
+ /* Host state */
+ PrintTrace("Setting up host state\n");
+ SetCRBitsCorrectly(IA32_VMX_CR0_FIXED0_MSR, IA32_VMX_CR0_FIXED1_MSR, HOST_CR0);
+ SetCRBitsCorrectly(IA32_VMX_CR4_FIXED0_MSR, IA32_VMX_CR4_FIXED1_MSR, HOST_CR4);
+ ret = Init_VMCS_HostState();
+
+ if (ret != VMX_SUCCESS) {
+ if (ret == VMX_FAIL_VALID) {
+ PrintTrace("Init Host state: VMCS FAILED WITH ERROR\n");
+ } else {
+ PrintTrace("Init Host state: Invalid VMCS\n");
+ }
+ return ret;
+ }
+
+ // PrintTrace("HOST_RIP: %x (%u)\n", exit_eip, exit_eip);
+ VMCS_WRITE(HOST_RIP, &exit_eip);
+
+ /* Guest state */
+ PrintTrace("Setting up guest state\n");
+ PrintTrace("GUEST_RIP: %x (%u)\n", entry_eip, entry_eip);
+ VMCS_WRITE(GUEST_RIP,&entry_eip);
+
+ SetCRBitsCorrectly(IA32_VMX_CR0_FIXED0_MSR, IA32_VMX_CR0_FIXED1_MSR, GUEST_CR0);
+ SetCRBitsCorrectly(IA32_VMX_CR4_FIXED0_MSR, IA32_VMX_CR4_FIXED1_MSR, GUEST_CR4);
+ ret = Init_VMCS_GuestState();
+
+ PrintTrace("InitGuestState returned\n");
+ if (ret != VMX_SUCCESS) {
+ if (ret == VMX_FAIL_VALID) {
+ PrintTrace("Init Guest state: VMCS FAILED WITH ERROR\n");
+ } else {
+ PrintTrace("Init Guest state: Invalid VMCS\n");
+ }
+ return ret;
+ }
+ PrintTrace("GUEST_RSP: %x (%u)\n", guest_esp, (uint_t)guest_esp);
+ VMCS_WRITE(GUEST_RSP,&guest_esp);
+
+ // tmpReg = 0x4100;
+ tmpReg = 0xffffffff;
+ if (VMCS_WRITE(EXCEPTION_BITMAP,&tmpReg ) != VMX_SUCCESS) {
+ PrintInfo("Bitmap error\n");
+ }
+
+ ConfigureExits(vm);
+
+ PrintTrace("VMCS_LAUNCH\n");
+
+ vm->state=VM_VMXASSIST_STARTUP;
+
+ vmm_ret = SAFE_VM_LAUNCH();
+
+ PrintTrace("VMM error %d\n", vmm_ret);
+
+ return vmm_ret;
+}
+
+
+
+
+int VMLaunch(struct VMDescriptor *vm)
+{
+ VMCS * vmcs = CreateVMCS();
+ int rc;
+
+ ullong_t vmcs_ptr = (ullong_t)((uint_t)vmcs);
+ uint_t top = (vmcs_ptr>>32)&0xffffffff;
+ uint_t bottom = (vmcs_ptr)&0xffffffff;
+
+ theVM.vmcsregion = vmcs;
+ theVM.descriptor = *vm;
+
+ PrintTrace("vmcs_ptr_top=%x vmcs_ptr_bottom=%x, eip=%x\n", top, bottom, vm->entry_ip);
+ rc=MyLaunch(&theVM); // vmcs_ptr, vm->entry_ip, vm->exit_eip, vm->guest_esp);
+ PrintTrace("Returned from MyLaunch();\n");
+ return rc;
+}
+
+
+VmxOnRegion * CreateVmxOnRegion() {
+ union VMX_MSR basicMSR;
+ VmxOnRegion * region = (VmxOnRegion *)(os_hooks)->allocate_pages(1);
+
+ Get_MSR(IA32_VMX_BASIC_MSR, &basicMSR.regs.high, &basicMSR.regs.low);
+ // memcpy(region, &basicMSR.vmxBasic.revision, sizeof(uint_t));
+
+ *(ulong_t*)region = basicMSR.vmxBasic.revision;
+
+ PrintInfo("VMX revision: 0x%lu\n", *(ulong_t *)region);
+
+ return region;
+}
+
+VMCS * CreateVMCS() {
+ union VMX_MSR basicMSR;
+ VMCS * vmcs = (VMCS *)(os_hooks)->allocate_pages(1);
+
+ Get_MSR(IA32_VMX_BASIC_MSR, &basicMSR.regs.high, &basicMSR.regs.low);
+ *(ulong_t *)vmcs = basicMSR.vmxBasic.revision;
+ *(ulong_t *)((char*)vmcs + 4) = 0;
+
+ PrintTrace("VMCS Region size: %u\n", basicMSR.vmxBasic.regionSize);
+ PrintTrace("VMCS Abort: %x\n",*(uint_t *)(((char*)vmcs)+4));
+
+ return vmcs;
+}