info->vm_regs.rbx = time_state->guest_cpu_freq;
- PrintDebug("Guest request cpu frequency: return %ld\n", (long)info->vm_regs.rbx);
+ PrintDebug(info->vm_info, info, "Guest request cpu frequency: return %ld\n", (long)info->vm_regs.rbx);
+
+ return 0;
+}
+
+static int handle_rdhtsc_hcall(struct guest_info * info, uint_t hcall_id, void * priv_data) {
+ struct vm_core_time * time_state = &(info->time_state);
+
+ info->vm_regs.rbx = v3_get_host_time(time_state);
+
+ // PrintDebug(info->vm_info, info, "Guest request host TSC: return %ld\n", (long)info->vm_regs.rbx);
return 0;
}
/* We start running with guest_time == host_time */
uint64_t t = v3_get_host_time(&info->time_state);
- info->time_state.vm_enter_host_time = 0;
- info->time_state.vm_pause_host_time = t;
info->time_state.initial_host_time = t;
info->yield_start_cycle = t;
info->time_state.last_update = 0;
info->time_state.guest_cycles = 0;
- PrintDebug("Starting time for core %d at host time %llu/guest time %llu.\n",
+ PrintDebug(info->vm_info, info, "Starting time for core %d at host time %llu/guest time %llu.\n",
info->vcpu_id, t, info->time_state.guest_cycles);
- v3_yield(info);
+ v3_yield(info,-1);
return 0;
}
-int v3_offset_time( struct guest_info * info, sint64_t offset )
-{
- struct vm_core_time * time_state = &(info->time_state);
- if (info->vm_info->time_state.follow_host_time) {
- PrintError("Cannot offset guest time passage while slaved to host clock.\n");
- return 1;
- } else {
- time_state->guest_cycles += offset;
- }
- return 0;
-}
+static sint64_t
+host_to_guest_cycles(struct guest_info * info, sint64_t host_cycles) {
+ struct vm_core_time * core_time_state = &(info->time_state);
+ uint32_t cl_num, cl_denom;
-int v3_skip_time(struct guest_info * info) {
- if (info->vm_info->time_state.follow_host_time) {
- PrintError("Cannot skip guest time passage while slaved to host clock.\n");
- return 1;
- } else {
- info->time_state.vm_pause_host_time = v3_get_host_time(&info->time_state);
- }
- return 0;
-}
+ cl_num = core_time_state->clock_ratio_num;
+ cl_denom = core_time_state->clock_ratio_denom;
-static sint64_t host_to_guest_cycles(struct guest_info * info, sint64_t host_cycles) {
- return (host_cycles * info->time_state.clock_ratio_num) / info->time_state.clock_ratio_denom;
+ return (host_cycles * cl_num) / cl_denom;
}
-int v3_time_advance_cycles(struct guest_info * info, uint64_t *host_cycles)
-{
- uint64_t t = v3_get_host_time(&info->time_state);
-
- info->time_state.vm_pause_host_time = t;
-
- if (info->vm_info->time_state.follow_host_time) {
- /* How many guest cycles should have elapsed? */
- sint64_t host_elapsed = t - info->time_state.initial_host_time;
- sint64_t guest_elapsed = host_to_guest_cycles(info, host_elapsed);
-
- info->time_state.guest_cycles = guest_elapsed;
- } else {
- uint64_t guest_cycles;
- if (*host_cycles) {
- guest_cycles = host_to_guest_cycles(info, *host_cycles);
- } else {
- guest_cycles = host_to_guest_cycles(info, (sint64_t)(t - info->time_state.vm_pause_host_time));
- }
- info->time_state.guest_cycles += guest_cycles;
- }
+/*
+static sint64_t
+guest_to_host_cycles(struct guest_info * info, sint64_t guest_cycles) {
+ struct vm_core_time * core_time_state = &(info->time_state);
+ uint32_t cl_num, cl_denom;
- return 0;
-}
+ cl_num = core_time_state->clock_ratio_num;
+ cl_denom = core_time_state->clock_ratio_denom;
-int v3_advance_time(struct guest_info * info) {
- return v3_time_advance_cycles(info, NULL);
+ return (guest_cycles * cl_denom) / cl_num;
}
+*/
-/* Called immediately upon entry in the the VMM */
-int
-v3_time_exit_vm( struct guest_info * info, uint64_t * host_cycles )
+int v3_advance_time(struct guest_info * info, uint64_t *host_cycles)
{
- return v3_time_advance_cycles(info, host_cycles);
-}
-
-/* Called immediately prior to entry to the VM */
-int
-v3_time_enter_vm( struct guest_info * info )
-{
- struct vm_core_time * time_state = &(info->time_state);
- uint64_t host_time = v3_get_host_time(&info->time_state);
+ uint64_t guest_cycles;
+
+ if (info->time_state.flags & VM_TIME_SLAVE_HOST) {
+ struct v3_time *vm_ts = &(info->vm_info->time_state);
+ uint64_t ht = v3_get_host_time(&info->time_state);
+ uint64_t host_elapsed = ht - info->time_state.initial_host_time;
+ uint64_t dilated_elapsed = (host_elapsed * vm_ts->td_num) / vm_ts->td_denom;
+ uint64_t guest_elapsed = host_to_guest_cycles(info, dilated_elapsed);
+ guest_cycles = guest_elapsed - v3_get_guest_time(&info->time_state);
+ } else if (host_cycles) {
+ guest_cycles = host_to_guest_cycles(info, *host_cycles);
+ } else {
+ guest_cycles = 0;
+ }
+
+ info->time_state.guest_cycles += guest_cycles;
- time_state->vm_enter_host_time = host_time;
return 0;
-}
-
+}
-
struct v3_timer * v3_add_timer(struct guest_info * info,
struct v3_timer_ops * ops,
void * private_data) {
struct v3_timer * timer = NULL;
timer = (struct v3_timer *)V3_Malloc(sizeof(struct v3_timer));
- V3_ASSERT(timer != NULL);
+
+ if (!timer) {
+ PrintError(info->vm_info, info, "Cannot allocate in adding a timer\n");
+ return NULL;
+ }
+
+ V3_ASSERT(info->vm_info, info,timer != NULL);
timer->ops = ops;
timer->private_data = private_data;
time_state->last_update = v3_get_guest_time(time_state);
cycles = (sint64_t)(time_state->last_update - old_time);
if (cycles < 0) {
- PrintError("Cycles appears to have rolled over - old time %lld, current time %lld.\n",
+ PrintError(info->vm_info, info, "Cycles appears to have rolled over - old time %lld, current time %lld.\n",
old_time, time_state->last_update);
return;
}
- PrintDebug("Updating timers with %lld elapsed cycles.\n", cycles);
+ //PrintDebug(info->vm_info, info, "Updating timers with %lld elapsed cycles.\n", cycles);
list_for_each_entry(tmp_timer, &(time_state->timers), timer_link) {
tmp_timer->ops->update_timer(info, cycles, time_state->guest_cpu_freq, tmp_timer->private_data);
}
}
int v3_handle_rdtsc(struct guest_info * info) {
+ PrintDebug(info->vm_info, info, "Handling virtual RDTSC call.\n");
v3_rdtsc(info);
info->vm_regs.rax &= 0x00000000ffffffffLL;
int v3_handle_rdtscp(struct guest_info * info) {
- PrintDebug("Handling virtual RDTSCP call.\n");
+ PrintDebug(info->vm_info, info, "Handling virtual RDTSCP call.\n");
v3_rdtscp(info);
struct v3_msr *msr_val, void *priv) {
struct vm_core_time * time_state = &(info->time_state);
- V3_ASSERT(msr_num == TSC_AUX_MSR);
+ V3_ASSERT(info->vm_info, info,msr_num == TSC_AUX_MSR);
msr_val->lo = time_state->tsc_aux.lo;
msr_val->hi = time_state->tsc_aux.hi;
struct v3_msr msr_val, void *priv) {
struct vm_core_time * time_state = &(info->time_state);
- V3_ASSERT(msr_num == TSC_AUX_MSR);
+ V3_ASSERT(info->vm_info, info,msr_num == TSC_AUX_MSR);
time_state->tsc_aux.lo = msr_val.lo;
time_state->tsc_aux.hi = msr_val.hi;
struct v3_msr *msr_val, void *priv) {
uint64_t time = v3_get_guest_tsc(&info->time_state);
- V3_ASSERT(msr_num == TSC_MSR);
+ PrintDebug(info->vm_info, info, "Handling virtual TSC MSR read call.\n");
+ V3_ASSERT(info->vm_info, info,msr_num == TSC_MSR);
msr_val->hi = time >> 32;
msr_val->lo = time & 0xffffffffLL;
struct vm_core_time * time_state = &(info->time_state);
uint64_t guest_time, new_tsc;
- V3_ASSERT(msr_num == TSC_MSR);
+ PrintDebug(info->vm_info, info, "Handling virtual TSC MSR write call.\n");
+ V3_ASSERT(info->vm_info, info,msr_num == TSC_MSR);
new_tsc = (((uint64_t)msr_val.hi) << 32) | (uint64_t)msr_val.lo;
guest_time = v3_get_guest_time(time_state);
return 0;
}
+static int
+handle_time_configuration(struct v3_vm_info * vm, v3_cfg_tree_t *cfg) {
+ char *source, *dilation, *tsc;
+
+ vm->time_state.flags = V3_TIME_SLAVE_HOST;
+ vm->time_state.td_num = vm->time_state.td_denom = 1;
+
+ if (!cfg) return 0;
+
+ source = v3_cfg_val(cfg, "source");
+ if (source) {
+ if (strcasecmp(source, "none") == 0) {
+ vm->time_state.flags &= ~V3_TIME_SLAVE_HOST;
+ } else if (strcasecmp(source, "host") != 0) {
+ PrintError(vm, VCORE_NONE, "Unknown time source for VM core time management.\n");
+ } else {
+ PrintDebug(vm, VCORE_NONE,"VM time slaved to host TSC.\n");
+ }
+ }
+
+ // Should we make a separate TSC device that handles this sort of thing?
+ tsc = v3_cfg_val(cfg, "tsc");
+ if (tsc) {
+ if (strcasecmp(tsc, "host") == 0) {
+ if (!(vm->time_state.flags & V3_TIME_SLAVE_HOST)) {
+ PrintError(vm, VCORE_NONE, "WARNING: Guest TSC set to passthrough host TSC, but guest time not slaved to host time.");
+ }
+ vm->time_state.flags |= V3_TIME_TSC_PASSTHROUGH;
+ } else if (strcasecmp(source, "guest") != 0) {
+ PrintError(vm, VCORE_NONE, "ERROR: Unknown TSC configuration in time configuration.\n");
+ }
+ }
+
+ dilation = v3_cfg_val(cfg, "dilation");
+ if (dilation) {
+ if (!(vm->time_state.flags & VM_TIME_SLAVE_HOST)) {
+ PrintError(vm, VCORE_NONE, "Time dilation only valid when slaved to host time.\n");
+ } else {
+ uint32_t num = 1, denom = 1;
+ denom = atoi(dilation);
+ if ((num > 0) && (denom > 0)) {
+ vm->time_state.td_num = num;
+ vm->time_state.td_denom = denom;
+ }
+ }
+ if ((vm->time_state.td_num != 1)
+ || (vm->time_state.td_denom != 1)) {
+ V3_Print(vm, VCORE_NONE, "Time dilated from host time by a factor of %d/%d"
+ " in guest.\n", vm->time_state.td_denom,
+ vm->time_state.td_num);
+ } else {
+ PrintError(vm, VCORE_NONE,"Time dilation specifier in configuration did not"
+ " result in actual time dilation in VM.\n");
+ }
+ }
+ return 0;
+}
int v3_init_time_vm(struct v3_vm_info * vm) {
+ v3_cfg_tree_t * cfg_tree = vm->cfg_data->cfg;
int ret;
-
- PrintDebug("Installing TSC MSR hook.\n");
+
+ PrintDebug(vm, VCORE_NONE, "Installing TSC MSR hook.\n");
ret = v3_hook_msr(vm, TSC_MSR,
tsc_msr_read_hook, tsc_msr_write_hook, NULL);
return ret;
}
- PrintDebug("Installing TSC_AUX MSR hook.\n");
+ PrintDebug(vm, VCORE_NONE, "Installing TSC_AUX MSR hook.\n");
ret = v3_hook_msr(vm, TSC_AUX_MSR, tsc_aux_msr_read_hook,
tsc_aux_msr_write_hook, NULL);
return ret;
}
- PrintDebug("Registering TIME_CPUFREQ hypercall.\n");
+ PrintDebug(vm, VCORE_NONE, "Registering TIME_CPUFREQ hypercall.\n");
ret = v3_register_hypercall(vm, TIME_CPUFREQ_HCALL,
handle_cpufreq_hcall, NULL);
+ PrintDebug(vm, VCORE_NONE, "Registering TIME_RDHTSC hypercall.\n");
+ ret = v3_register_hypercall(vm, TIME_RDHTSC_HCALL,
+ handle_rdhtsc_hcall, NULL);
- vm->time_state.td_num = 1;
- vm->time_state.td_denom = 1;
- PrintDebug("Setting base time dilation factor to %d/%d.\n",
- vm->time_state.td_num, vm->time_state.td_denom);
+ handle_time_configuration(vm, v3_cfg_subtree(cfg_tree, "time"));
- vm->time_state.follow_host_time = 1;
- PrintDebug("Locking guest time to host time.\n");
return ret;
}
v3_remove_hypercall(vm, TIME_CPUFREQ_HCALL);
}
+static uint32_t
+gcd ( uint32_t a, uint32_t b )
+{
+ uint32_t c;
+ while ( a != 0 ) {
+ c = a; a = b%a; b = c;
+ }
+ return b;
+}
+
+static int compute_core_ratios(struct guest_info * info,
+ uint32_t hostKhz, uint32_t guestKhz)
+{
+ struct vm_core_time * time_state = &(info->time_state);
+ uint32_t khzGCD;
+
+ /* Compute these using the GCD() of the guest and host CPU freq.
+ * If the GCD is too small, make it "big enough" */
+ khzGCD = gcd(hostKhz, guestKhz);
+ if (khzGCD < 1024)
+ khzGCD = 1024;
+
+ time_state->clock_ratio_num = guestKhz / khzGCD;
+ time_state->clock_ratio_denom = hostKhz / khzGCD;
+
+ time_state->ipc_ratio_num = 1;
+ time_state->ipc_ratio_denom = 1;
+
+ return 0;
+}
+
void v3_init_time_core(struct guest_info * info) {
struct vm_core_time * time_state = &(info->time_state);
v3_cfg_tree_t * cfg_tree = info->core_cfg_data;
if (khz) {
time_state->guest_cpu_freq = atoi(khz);
- PrintDebug("Logical Core %d (vcpu=%d) CPU frequency requested at %d khz.\n",
+ PrintDebug(info->vm_info, info, "Logical Core %d (vcpu=%d) CPU frequency requested at %d khz.\n",
info->pcpu_id, info->vcpu_id, time_state->guest_cpu_freq);
}
if ( (khz == NULL) ||
- (time_state->guest_cpu_freq <= 0) ||
- (time_state->guest_cpu_freq > time_state->host_cpu_freq) ) {
-
+ (time_state->guest_cpu_freq <= 0)) {
+/* || (time_state->guest_cpu_freq > time_state->host_cpu_freq) ) { */
time_state->guest_cpu_freq = time_state->host_cpu_freq;
}
+ compute_core_ratios(info, time_state->host_cpu_freq,
+ time_state->guest_cpu_freq);
+
+ time_state->flags = 0;
+ if (info->vm_info->time_state.flags & V3_TIME_SLAVE_HOST) {
+ time_state->flags |= VM_TIME_SLAVE_HOST;
+ }
+ if (info->vm_info->time_state.flags & V3_TIME_TSC_PASSTHROUGH) {
+ time_state->flags |= VM_TIME_TSC_PASSTHROUGH;
+ }
- /* Compute these using the GCD() of the guest and host CPU freq.
- * If the GCD is too small, make it "big enough" */
- time_state->clock_ratio_num = 1;
- time_state->clock_ratio_denom = 1;
+ if ((time_state->clock_ratio_denom != 1) ||
+ (time_state->clock_ratio_num != 1) ||
+ (info->vm_info->time_state.td_num != 1) ||
+ (info->vm_info->time_state.td_denom != 1)) {
+ if (time_state->flags | VM_TIME_TSC_PASSTHROUGH) {
+ PrintError(info->vm_info, info, "WARNING: Cannot use reqested passthrough TSC with clock or time modification also requested.\n");
+ time_state->flags &= ~VM_TIME_TSC_PASSTHROUGH;
+ }
+ time_state->flags |= VM_TIME_TRAP_RDTSC;
+ }
- PrintDebug("Logical Core %d (vcpu=%d) CPU frequency set to %d KHz (host CPU frequency = %d KHz).\n",
+ PrintDebug(info->vm_info, info, "Logical Core %d (vcpu=%d) CPU frequency set to %d KHz (host CPU frequency = %d KHz).\n",
info->pcpu_id, info->vcpu_id,
time_state->guest_cpu_freq,
time_state->host_cpu_freq);
+ PrintDebug(info->vm_info, info, " td_mult = %d/%d, cl_mult = %u/%u, ipc_mult = %u/%u.\n",
+ info->vm_info->time_state.td_num,
+ info->vm_info->time_state.td_denom,
+ time_state->clock_ratio_num, time_state->clock_ratio_denom,
+ time_state->ipc_ratio_num, time_state->ipc_ratio_denom);
+ PrintDebug(info->vm_info, info, " time source = %s, tsc handling = %s\n",
+ (time_state->flags & VM_TIME_SLAVE_HOST) ? "host" : "none",
+ (time_state->flags & VM_TIME_TSC_PASSTHROUGH) ? "passthrough"
+ : (time_state->flags & VM_TIME_TRAP_RDTSC) ? "trapping"
+ : "offsettting");
time_state->guest_cycles = 0;
time_state->tsc_guest_offset = 0;
time_state->last_update = 0;
-
time_state->initial_host_time = 0;
- time_state->vm_enter_host_time = 0;
- time_state->vm_pause_host_time = 0;
-
- time_state->time_flags = 0; // XXX need to set trap TSC flag or not wisely
INIT_LIST_HEAD(&(time_state->timers));
time_state->num_timers = 0;
-
+
time_state->tsc_aux.lo = 0;
time_state->tsc_aux.hi = 0;
}
struct v3_timer * tmr = NULL;
struct v3_timer * tmp = NULL;
- list_for_each_entry_safe(tmr, tmp, &(time_state->timers), timer_link) {
- v3_remove_timer(core, tmr);
+ if (*(void**)&time_state->timers) {
+ list_for_each_entry_safe(tmr, tmp, &(time_state->timers), timer_link) {
+ v3_remove_timer(core, tmr);
+ }
}
-
}