#include <palacios/vmm_instrument.h>
#include <palacios/vmm_ctrl_regs.h>
#include <palacios/vmm_lowlevel.h>
+#include <palacios/vmm_sprintf.h>
#ifdef CONFIG_SVM
#include <palacios/svm.h>
#include <palacios/vmx.h>
#endif
+#ifdef CONFIG_VNET
+#include <palacios/vmm_vnet.h>
+#endif
+
v3_cpu_arch_t v3_cpu_types[CONFIG_MAX_CPUS];
struct v3_os_hooks * os_hooks = NULL;
+int v3_dbg_enable = 0;
-
-
-static struct guest_info * allocate_guest() {
- void * info = V3_Malloc(sizeof(struct guest_info));
- memset(info, 0, sizeof(struct guest_info));
- return info;
-}
-
-
static void init_cpu(void * arg) {
uint32_t cpu_id = (uint32_t)(addr_t)arg;
} else
#endif
{
- PrintError("CPU has no virtualization Extensions\n");
+ PrintError("CPU has no virtualizationExtensions\n");
}
}
-
-
void Init_V3(struct v3_os_hooks * hooks, int num_cpus) {
int i;
+ V3_Print("V3 Print statement to fix a Kitten page fault bug\n");
+
// Set global variables.
os_hooks = hooks;
// Register all the possible device types
v3_init_devices();
-#ifdef INSTRUMENT_VMM
+ // Register all shadow paging handlers
+ V3_init_shdw_paging();
+
+
+#ifdef CONFIG_SYMMOD
+ V3_init_symmod();
+#endif
+
+#ifdef CONFIG_INSTRUMENT_VMM
v3_init_instrumentation();
#endif
+
+#ifdef CONFIG_VNET
+ V3_init_vnet();
+#endif
+
if ((hooks) && (hooks->call_on_cpu)) {
for (i = 0; i < num_cpus; i++) {
}
}
+
v3_cpu_arch_t v3_get_cpu_type(int cpu_id) {
return v3_cpu_types[cpu_id];
}
-struct guest_info * v3_create_vm(void * cfg) {
- struct guest_info * info = allocate_guest();
-
- if (!info) {
- PrintError("Could not allocate Guest\n");
- return NULL;
- }
+struct v3_vm_info * v3_create_vm(void * cfg) {
+ struct v3_vm_info * vm = v3_config_guest(cfg);
- if (v3_config_guest(info, cfg) == -1) {
+ if (vm == NULL) {
PrintError("Could not configure guest\n");
return NULL;
}
- return info;
+ return vm;
}
-int v3_start_vm(struct guest_info * info, unsigned int cpu_mask) {
+
+static int start_core(void *p)
+{
+ struct guest_info * info = (struct guest_info*)p;
+
+
+ PrintDebug("core %u: in start_core\n",info->cpu_id);
- info->cpu_id = v3_get_cpu_id();
+ // we assume here that the APs are in INIT mode
+ // and only the BSP is in REAL
+ // the per-architecture code will rely on this
+ // assumption
- V3_Print("V3 -- Starting VM\n");
switch (v3_cpu_types[info->cpu_id]) {
#ifdef CONFIG_SVM
break;
#endif
default:
- PrintError("Attemping to enter a guest on an invalid CPU\n");
+ PrintError("Attempting to enter a guest on an invalid CPU\n");
+ return -1;
+ }
+ // should not happen
+ return 0;
+}
+
+
+static uint32_t get_next_core(unsigned int cpu_mask, uint32_t last_proc)
+{
+ uint32_t proc_to_use;
+
+ PrintDebug("In get_next_core cpu_mask=0x%x last_proc=%u\n",cpu_mask,last_proc);
+
+ proc_to_use=(last_proc+1) % 32; // only 32 procs
+ // This will wrap around, and eventually we can use proc 0,
+ // since that's clearly available
+ while (!((cpu_mask >> proc_to_use)&0x1)) {
+ proc_to_use=(proc_to_use+1)%32;
+ }
+ return proc_to_use;
+}
+
+int v3_start_vm(struct v3_vm_info * vm, unsigned int cpu_mask) {
+ uint32_t i;
+ uint32_t last_proc;
+ uint32_t proc_to_use;
+ char tname[16];
+
+ V3_Print("V3 -- Starting VM (%u cores)\n",vm->num_cores);
+
+ // We assume that we are running on CPU 0 of the underlying system
+ last_proc=0;
+
+ // We will fork off cores 1..n first, then boot core zero
+
+ // for the AP, we need to create threads
+
+ for (i = 1; i < vm->num_cores; i++) {
+ if (!os_hooks->start_thread_on_cpu) {
+ PrintError("Host OS does not support start_thread_on_cpu - FAILING\n");
return -1;
+ }
+
+ proc_to_use=get_next_core(cpu_mask,last_proc);
+ last_proc=proc_to_use;
+
+ // vm->cores[i].cpu_id=i;
+ // vm->cores[i].physical_cpu_id=proc_to_use;
+
+ PrintDebug("Starting virtual core %u on logical core %u\n",i,proc_to_use);
+
+ sprintf(tname,"core%u",i);
+
+ PrintDebug("run: core=%u, func=0x%p, arg=0x%p, name=%s\n",
+ proc_to_use, start_core, &(vm->cores[i]), tname);
+
+ // TODO: actually manage these threads instead of just launching them
+ if (!(os_hooks->start_thread_on_cpu(proc_to_use,start_core,&(vm->cores[i]),tname))) {
+ PrintError("Thread launch failed\n");
+ return -1;
+ }
}
+ // vm->cores[0].cpu_id=0;
+ // vm->cores[0].physical_cpu_id=0;
+
+ // Finally launch the BSP on core 0
+ sprintf(tname,"core%u",0);
+ if (!os_hooks->start_thread_on_cpu(0,start_core,&(vm->cores[0]),tname)) {
+ PrintError("Thread launch failed\n");
+ return -1;
+ }
return 0;
+
}
} while (0) \
+
void v3_yield_cond(struct guest_info * info) {
uint64_t cur_cycle;
rdtscll(cur_cycle);
- if (cur_cycle > (info->yield_start_cycle + info->yield_cycle_period)) {
+ if (cur_cycle > (info->yield_start_cycle + info->vm_info->yield_cycle_period)) {
/*
PrintDebug("Conditional Yield (cur_cyle=%p, start_cycle=%p, period=%p)\n",
}
}
+
/*
* unconditional cpu yield
* if the yielding thread is a guest context, the guest quantum is reset on resumption
-void v3_interrupt_cpu(struct guest_info * info, int logical_cpu) {
+
+void v3_print_cond(const char * fmt, ...) {
+ if (v3_dbg_enable == 1) {
+ char buf[2048];
+ va_list ap;
+
+ va_start(ap, fmt);
+ vsnprintf(buf, 2048, fmt, ap);
+ va_end(ap);
+
+ V3_Print("%s", buf);
+ }
+}
+
+
+
+
+void v3_interrupt_cpu(struct v3_vm_info * vm, int logical_cpu, int vector) {
extern struct v3_os_hooks * os_hooks;
if ((os_hooks) && (os_hooks)->interrupt_cpu) {
- (os_hooks)->interrupt_cpu(info, logical_cpu);
+ (os_hooks)->interrupt_cpu(vm, logical_cpu, vector);
}
}
-
-
int v3_vm_enter(struct guest_info * info) {
switch (v3_cpu_types[info->cpu_id]) {
#ifdef CONFIG_SVM
return v3_svm_enter(info);
break;
#endif
-#if CONFIG_VMX && 0
+#if CONFIG_VMX
case V3_VMX_CPU:
case V3_VMX_EPT_CPU:
return v3_vmx_enter(info);
return -1;
}
}
-
-
-
