time.c source code [linux/arch/um/kernel/time.c]

1	// SPDX-License-Identifier: GPL-2.0
2	/*
3	* Copyright (C) 2015 Anton Ivanov (aivanov@{brocade.com,kot-begemot.co.uk})
4	* Copyright (C) 2015 Thomas Meyer (thomas@m3y3r.de)
5	* Copyright (C) 2012-2014 Cisco Systems
6	* Copyright (C) 2000 - 2007 Jeff Dike (jdike@{addtoit,linux.intel}.com)
7	* Copyright (C) 2019 Intel Corporation
8	*/
9
10	#include <linux/clockchips.h>
11	#include <linux/init.h>
12	#include <linux/interrupt.h>
13	#include <linux/jiffies.h>
14	#include <linux/mm.h>
15	#include <linux/sched.h>
16	#include <linux/spinlock.h>
17	#include <linux/threads.h>
18	#include <asm/irq.h>
19	#include <asm/param.h>
20	#include <kern_util.h>
21	#include <os.h>
22	#include <linux/time-internal.h>
23	#include <linux/um_timetravel.h>
24	#include <shared/init.h>
25
26	#ifdef CONFIG_UML_TIME_TRAVEL_SUPPORT
27	enum time_travel_mode time_travel_mode;
28	EXPORT_SYMBOL_GPL(time_travel_mode);
29
30	static bool time_travel_start_set;
31	static unsigned long long time_travel_start;
32	static unsigned long long time_travel_time;
33	static LIST_HEAD(time_travel_events);
34	static LIST_HEAD(time_travel_irqs);
35	static unsigned long long time_travel_timer_interval;
36	static unsigned long long time_travel_next_event;
37	static struct time_travel_event time_travel_timer_event;
38	static int time_travel_ext_fd = -`1`;
39	static unsigned int time_travel_ext_waiting;
40	static bool time_travel_ext_prev_request_valid;
41	static unsigned long long time_travel_ext_prev_request;
42	static bool time_travel_ext_free_until_valid;
43	static unsigned long long time_travel_ext_free_until;
44
45	static void time_travel_set_time(unsigned long long ns)
46	{
47	if (unlikely(ns < time_travel_time))
48	panic("time-travel: time goes backwards %lld -> %lld\n",
49	time_travel_time, ns);
50	else if (unlikely(ns >= S64_MAX))
51	panic("The system was going to sleep forever, aborting");
52
53	time_travel_time = ns;
54	}
55
56	enum time_travel_message_handling {
57	TTMH_IDLE,
58	TTMH_POLL,
59	TTMH_READ,
60	};
61
62	static void time_travel_handle_message(struct um_timetravel_msg *msg,
63	enum time_travel_message_handling mode)
64	{
65	struct um_timetravel_msg resp = {
66	.op = UM_TIMETRAVEL_ACK,
67	};
68	int ret;
69
70	/*
71	* We can't unlock here, but interrupt signals with a timetravel_handler
72	* (see um_request_irq_tt) get to the timetravel_handler anyway.
73	*/
74	if (mode != TTMH_READ) {
75	BUG_ON(mode == TTMH_IDLE && !irqs_disabled());
76
77	while (os_poll(`1`, &time_travel_ext_fd) != `0`) {
78	/ nothing /
79	}
80	}
81
82	ret = os_read_file(time_travel_ext_fd, msg, sizeof(*msg));
83
84	if (ret == `0`)
85	panic("time-travel external link is broken\n");
86	if (ret != sizeof(*msg))
87	panic("invalid time-travel message - %d bytes\n", ret);
88
89	switch (msg->op) {
90	default:
91	WARN_ONCE(`1`, "time-travel: unexpected message %lld\n",
92	(unsigned long long)msg->op);
93	break;
94	case UM_TIMETRAVEL_ACK:
95	return;
96	case UM_TIMETRAVEL_RUN:
97	time_travel_set_time(msg->time);
98	break;
99	case UM_TIMETRAVEL_FREE_UNTIL:
100	time_travel_ext_free_until_valid = true;
101	time_travel_ext_free_until = msg->time;
102	break;
103	}
104
105	resp.seq = msg->seq;
106	os_write_file(time_travel_ext_fd, &resp, sizeof(resp));
107	}
108
109	static u64 time_travel_ext_req(u32 op, u64 time)
110	{
111	static int seq;
112	int mseq = ++seq;
113	struct um_timetravel_msg msg = {
114	.op = op,
115	.time = time,
116	.seq = mseq,
117	};
118
119	/*
120	* We need to block even the timetravel handlers of SIGIO here and
121	* only restore their use when we got the ACK - otherwise we may
122	* (will) get interrupted by that, try to queue the IRQ for future
123	* processing and thus send another request while we're still waiting
124	* for an ACK, but the peer doesn't know we got interrupted and will
125	* send the ACKs in the same order as the message, but we'd need to
126	* see them in the opposite order ...
127	*
128	* This wouldn't matter too much, but some ACKs carry the
129	* current time (for UM_TIMETRAVEL_GET) and getting another
130	* ACK without a time would confuse us a lot!
131	*
132	* The sequence number assignment that happens here lets us
133	* debug such message handling issues more easily.
134	*/
135	block_signals_hard();
136	os_write_file(time_travel_ext_fd, &msg, sizeof(msg));
137
138	while (msg.op != UM_TIMETRAVEL_ACK)
139	time_travel_handle_message(&msg, TTMH_READ);
140
141	if (msg.seq != mseq)
142	panic("time-travel: ACK message has different seqno! op=%d, seq=%d != %d time=%lld\n",
143	msg.op, msg.seq, mseq, msg.time);
144
145	if (op == UM_TIMETRAVEL_GET)
146	time_travel_set_time(msg.time);
147	unblock_signals_hard();
148
149	return msg.time;
150	}
151
152	void __time_travel_wait_readable(int fd)
153	{
154	int fds[`2`] = { fd, time_travel_ext_fd };
155	int ret;
156
157	if (time_travel_mode != TT_MODE_EXTERNAL)
158	return;
159
160	while ((ret = os_poll(`2`, fds))) {
161	struct um_timetravel_msg msg;
162
163	if (ret == `1`)
164	time_travel_handle_message(&msg, TTMH_READ);
165	}
166	}
167	EXPORT_SYMBOL_GPL(__time_travel_wait_readable);
168
169	static void time_travel_ext_update_request(unsigned long long time)
170	{
171	if (time_travel_mode != TT_MODE_EXTERNAL)
172	return;
173
174	/ asked for exactly this time previously /
175	if (time_travel_ext_prev_request_valid &&
176	time == time_travel_ext_prev_request)
177	return;
178
179	/*
180	* if we're running and are allowed to run past the request
181	* then we don't need to update it either
182	*/
183	if (!time_travel_ext_waiting && time_travel_ext_free_until_valid &&
184	time < time_travel_ext_free_until)
185	return;
186
187	time_travel_ext_prev_request = time;
188	time_travel_ext_prev_request_valid = true;
189	time_travel_ext_req(UM_TIMETRAVEL_REQUEST, time);
190	}
191
192	void __time_travel_propagate_time(void)
193	{
194	static unsigned long long last_propagated;
195
196	if (last_propagated == time_travel_time)
197	return;
198
199	time_travel_ext_req(UM_TIMETRAVEL_UPDATE, time_travel_time);
200	last_propagated = time_travel_time;
201	}
202	EXPORT_SYMBOL_GPL(__time_travel_propagate_time);
203
204	/ returns true if we must do a wait to the simtime device /
205	static bool time_travel_ext_request(unsigned long long time)
206	{
207	/*
208	* If we received an external sync point ("free until") then we
209	* don't have to request/wait for anything until then, unless
210	* we're already waiting.
211	*/
212	if (!time_travel_ext_waiting && time_travel_ext_free_until_valid &&
213	time < time_travel_ext_free_until)
214	return false;
215
216	time_travel_ext_update_request(time);
217	return true;
218	}
219
220	static void time_travel_ext_wait(bool idle)
221	{
222	struct um_timetravel_msg msg = {
223	.op = UM_TIMETRAVEL_ACK,
224	};
225
226	time_travel_ext_prev_request_valid = false;
227	time_travel_ext_free_until_valid = false;
228	time_travel_ext_waiting++;
229
230	time_travel_ext_req(UM_TIMETRAVEL_WAIT, -`1`);
231
232	/*
233	* Here we are deep in the idle loop, so we have to break out of the
234	* kernel abstraction in a sense and implement this in terms of the
235	* UML system waiting on the VQ interrupt while sleeping, when we get
236	* the signal it'll call time_travel_ext_vq_notify_done() completing the
237	* call.
238	*/
239	while (msg.op != UM_TIMETRAVEL_RUN)
240	time_travel_handle_message(&msg, idle ? TTMH_IDLE : TTMH_POLL);
241
242	time_travel_ext_waiting--;
243
244	/ we might request more stuff while polling - reset when we run /
245	time_travel_ext_prev_request_valid = false;
246	}
247
248	static void time_travel_ext_get_time(void)
249	{
250	time_travel_ext_req(UM_TIMETRAVEL_GET, -`1`);
251	}
252
253	static void __time_travel_update_time(unsigned long long ns, bool idle)
254	{
255	if (time_travel_mode == TT_MODE_EXTERNAL && time_travel_ext_request(ns))
256	time_travel_ext_wait(idle);
257	else
258	time_travel_set_time(ns);
259	}
260
261	static struct time_travel_event time_travel_first_event(void*)
262	{
263	return list_first_entry_or_null(&time_travel_events,
264	struct time_travel_event,
265	list);
266	}
267
268	static void __time_travel_add_event(struct time_travel_event *e,
269	unsigned long long time)
270	{
271	struct time_travel_event *tmp;
272	bool inserted = false;
273	unsigned long flags;
274
275	if (e->pending)
276	return;
277
278	e->pending = true;
279	e->time = time;
280
281	local_irq_save(flags);
282	list_for_each_entry(tmp, &time_travel_events, list) {
283	/*
284	* Add the new entry before one with higher time,
285	* or if they're equal and both on stack, because
286	* in that case we need to unwind the stack in the
287	* right order, and the later event (timer sleep
288	* or such) must be dequeued first.
289	*/
290	if ((tmp->time > e->time) \|\|
291	(tmp->time == e->time && tmp->onstack && e->onstack)) {
292	list_add_tail(&e->list, &tmp->list);
293	inserted = true;
294	break;
295	}
296	}
297
298	if (!inserted)
299	list_add_tail(&e->list, &time_travel_events);
300
301	tmp = time_travel_first_event();
302	time_travel_ext_update_request(tmp->time);
303	time_travel_next_event = tmp->time;
304	local_irq_restore(flags);
305	}
306
307	static void time_travel_add_event(struct time_travel_event *e,
308	unsigned long long time)
309	{
310	if (WARN_ON(!e->fn))
311	return;
312
313	__time_travel_add_event(e, time);
314	}
315
316	void time_travel_add_event_rel(struct time_travel_event *e,
317	unsigned long long delay_ns)
318	{
319	time_travel_add_event(e, time_travel_time + delay_ns);
320	}
321
322	void time_travel_periodic_timer(struct time_travel_event *e)
323	{
324	time_travel_add_event(&time_travel_timer_event,
325	time_travel_time + time_travel_timer_interval);
326	deliver_alarm();
327	}
328
329	void deliver_time_travel_irqs(void)
330	{
331	struct time_travel_event *e;
332	unsigned long flags;
333
334	/*
335	* Don't do anything for most cases. Note that because here we have
336	* to disable IRQs (and re-enable later) we'll actually recurse at
337	* the end of the function, so this is strictly necessary.
338	*/
339	if (likely(list_empty(&time_travel_irqs)))
340	return;
341
342	local_irq_save(flags);
343	irq_enter();
344	while ((e = list_first_entry_or_null(&time_travel_irqs,
345	struct time_travel_event,
346	list))) {
347	list_del(&e->list);
348	e->pending = false;
349	e->fn(e);
350	}
351	irq_exit();
352	local_irq_restore(flags);
353	}
354
355	static void time_travel_deliver_event(struct time_travel_event *e)
356	{
357	if (e == &time_travel_timer_event) {
358	/*
359	* deliver_alarm() does the irq_enter/irq_exit
360	* by itself, so must handle it specially here
361	*/
362	e->fn(e);
363	} else if (irqs_disabled()) {
364	list_add_tail(&e->list, &time_travel_irqs);
365	/*
366	* set pending again, it was set to false when the
367	* event was deleted from the original list, but
368	* now it's still pending until we deliver the IRQ.
369	*/
370	e->pending = true;
371	} else {
372	unsigned long flags;
373
374	local_irq_save(flags);
375	irq_enter();
376	e->fn(e);
377	irq_exit();
378	local_irq_restore(flags);
379	}
380	}
381
382	bool time_travel_del_event(struct time_travel_event *e)
383	{
384	unsigned long flags;
385
386	if (!e->pending)
387	return false;
388	local_irq_save(flags);
389	list_del(&e->list);
390	e->pending = false;
391	local_irq_restore(flags);
392	return true;
393	}
394
395	static void time_travel_update_time(unsigned long long next, bool idle)
396	{
397	struct time_travel_event ne = {
398	.onstack = true,
399	};
400	struct time_travel_event *e;
401	bool finished = idle;
402
403	/ add it without a handler - we deal with that specifically below /
404	__time_travel_add_event(&ne, next);
405
406	do {
407	e = time_travel_first_event();
408
409	BUG_ON(!e);
410	__time_travel_update_time(e->time, idle);
411
412	/ new events may have been inserted while we were waiting /
413	if (e == time_travel_first_event()) {
414	BUG_ON(!time_travel_del_event(e));
415	BUG_ON(time_travel_time != e->time);
416
417	if (e == &ne) {
418	finished = true;
419	} else {
420	if (e->onstack)
421	panic("On-stack event dequeued outside of the stack! time=%lld, event time=%lld, event=%pS\n",
422	time_travel_time, e->time, e);
423	time_travel_deliver_event(e);
424	}
425	}
426
427	e = time_travel_first_event();
428	if (e)
429	time_travel_ext_update_request(e->time);
430	} while (ne.pending && !finished);
431
432	time_travel_del_event(&ne);
433	}
434
435	static void time_travel_update_time_rel(unsigned long long offs)
436	{
437	unsigned long flags;
438
439	/*
440	* Disable interrupts before calculating the new time so
441	* that a real timer interrupt (signal) can't happen at
442	* a bad time e.g. after we read time_travel_time but
443	* before we've completed updating the time.
444	*/
445	local_irq_save(flags);
446	time_travel_update_time(time_travel_time + offs, false);
447	local_irq_restore(flags);
448	}
449
450	void time_travel_ndelay(unsigned long nsec)
451	{
452	/*
453	* Not strictly needed to use _rel() version since this is
454	* only used in INFCPU/EXT modes, but it doesn't hurt and
455	* is more readable too.
456	*/
457	time_travel_update_time_rel(nsec);
458	}
459	EXPORT_SYMBOL(time_travel_ndelay);
460
461	void time_travel_add_irq_event(struct time_travel_event *e)
462	{
463	BUG_ON(time_travel_mode != TT_MODE_EXTERNAL);
464
465	time_travel_ext_get_time();
466	/*
467	* We could model interrupt latency here, for now just
468	* don't have any latency at all and request the exact
469	* same time (again) to run the interrupt...
470	*/
471	time_travel_add_event(e, time_travel_time);
472	}
473	EXPORT_SYMBOL_GPL(time_travel_add_irq_event);
474
475	static void time_travel_oneshot_timer(struct time_travel_event *e)
476	{
477	deliver_alarm();
478	}
479
480	void time_travel_sleep(void)
481	{
482	/*
483	* Wait "forever" (using S64_MAX because there are some potential
484	* wrapping issues, especially with the current TT_MODE_EXTERNAL
485	* controller application.
486	*/
487	unsigned long long next = S64_MAX;
488
489	if (time_travel_mode == TT_MODE_BASIC)
490	os_timer_disable();
491
492	time_travel_update_time(next, true);
493
494	if (time_travel_mode == TT_MODE_BASIC &&
495	time_travel_timer_event.pending) {
496	if (time_travel_timer_event.fn == time_travel_periodic_timer) {
497	/*
498	* This is somewhat wrong - we should get the first
499	* one sooner like the os_timer_one_shot() below...
500	*/
501	os_timer_set_interval(time_travel_timer_interval);
502	} else {
503	os_timer_one_shot(time_travel_timer_event.time - next);
504	}
505	}
506	}
507
508	static void time_travel_handle_real_alarm(void)
509	{
510	time_travel_set_time(time_travel_next_event);
511
512	time_travel_del_event(&time_travel_timer_event);
513
514	if (time_travel_timer_event.fn == time_travel_periodic_timer)
515	time_travel_add_event(&time_travel_timer_event,
516	time_travel_time +
517	time_travel_timer_interval);
518	}
519
520	static void time_travel_set_interval(unsigned long long interval)
521	{
522	time_travel_timer_interval = interval;
523	}
524
525	static int time_travel_connect_external(const char *socket)
526	{
527	const char *sep;
528	unsigned long long id = (unsigned long long)-`1`;
529	int rc;
530
531	if ((sep = strchr(socket, `':'`))) {
532	char buf[`25`] = {};
533	if (sep - socket > sizeof(buf) - `1`)
534	goto invalid_number;
535
536	memcpy(buf, socket, sep - socket);
537	if (kstrtoull(buf, `0`, &id)) {
538	invalid_number:
539	panic("time-travel: invalid external ID in string '%s'\n",
540	socket);
541	return -EINVAL;
542	}
543
544	socket = sep + `1`;
545	}
546
547	rc = os_connect_socket(socket);
548	if (rc < `0`) {
549	panic("time-travel: failed to connect to external socket %s\n",
550	socket);
551	return rc;
552	}
553
554	time_travel_ext_fd = rc;
555
556	time_travel_ext_req(UM_TIMETRAVEL_START, id);
557
558	return `1`;
559	}
560
561	static void time_travel_set_start(void)
562	{
563	if (time_travel_start_set)
564	return;
565
566	switch (time_travel_mode) {
567	case TT_MODE_EXTERNAL:
568	time_travel_start = time_travel_ext_req(UM_TIMETRAVEL_GET_TOD, -`1`);
569	/ controller gave us the current time, so adjust by that /
570	time_travel_ext_get_time();
571	time_travel_start -= time_travel_time;
572	break;
573	case TT_MODE_INFCPU:
574	case TT_MODE_BASIC:
575	if (!time_travel_start_set)
576	time_travel_start = os_persistent_clock_emulation();
577	break;
578	case TT_MODE_OFF:
579	/ we just read the host clock with os_persistent_clock_emulation() /
580	break;
581	}
582
583	time_travel_start_set = true;
584	}
585	#else /* CONFIG_UML_TIME_TRAVEL_SUPPORT */
586	#define time_travel_start_set 0
587	#define time_travel_start 0
588	#define time_travel_time 0
589	#define time_travel_ext_waiting 0
590
591	static inline void time_travel_update_time(unsigned long long ns, bool idle)
592	{
593	}
594
595	static inline void time_travel_update_time_rel(unsigned long long offs)
596	{
597	}
598
599	static inline void time_travel_handle_real_alarm(void)
600	{
601	}
602
603	static void time_travel_set_interval(unsigned long long interval)
604	{
605	}
606
607	static inline void time_travel_set_start(void)
608	{
609	}
610
611	/ fail link if this actually gets used /
612	extern u64 time_travel_ext_req(u32 op, u64 time);
613
614	/ these are empty macros so the struct/fn need not exist /
615	#define time_travel_add_event(e, time) do { } while (0)
616	/ externally not usable - redefine here so we can /
617	#undef time_travel_del_event
618	#define time_travel_del_event(e) do { } while (0)
619	#endif
620
621	void timer_handler(int sig, struct siginfo unused_si, struct* uml_pt_regs *regs)
622	{
623	unsigned long flags;
624
625	/*
626	* In basic time-travel mode we still get real interrupts
627	* (signals) but since we don't read time from the OS, we
628	* must update the simulated time here to the expiry when
629	* we get a signal.
630	* This is not the case in inf-cpu mode, since there we
631	* never get any real signals from the OS.
632	*/
633	if (time_travel_mode == TT_MODE_BASIC)
634	time_travel_handle_real_alarm();
635
636	local_irq_save(flags);
637	do_IRQ(TIMER_IRQ, regs);
638	local_irq_restore(flags);
639	}
640
641	static int itimer_shutdown(struct clock_event_device *evt)
642	{
643	if (time_travel_mode != TT_MODE_OFF)
644	time_travel_del_event(&time_travel_timer_event);
645
646	if (time_travel_mode != TT_MODE_INFCPU &&
647	time_travel_mode != TT_MODE_EXTERNAL)
648	os_timer_disable();
649
650	return `0`;
651	}
652
653	static int itimer_set_periodic(struct clock_event_device *evt)
654	{
655	unsigned long long interval = NSEC_PER_SEC / HZ;
656
657	if (time_travel_mode != TT_MODE_OFF) {
658	time_travel_del_event(&time_travel_timer_event);
659	time_travel_set_event_fn(&time_travel_timer_event,
660	time_travel_periodic_timer);
661	time_travel_set_interval(interval);
662	time_travel_add_event(&time_travel_timer_event,
663	time_travel_time + interval);
664	}
665
666	if (time_travel_mode != TT_MODE_INFCPU &&
667	time_travel_mode != TT_MODE_EXTERNAL)
668	os_timer_set_interval(interval);
669
670	return `0`;
671	}
672
673	static int itimer_next_event(unsigned long delta,
674	struct clock_event_device *evt)
675	{
676	delta += `1`;
677
678	if (time_travel_mode != TT_MODE_OFF) {
679	time_travel_del_event(&time_travel_timer_event);
680	time_travel_set_event_fn(&time_travel_timer_event,
681	time_travel_oneshot_timer);
682	time_travel_add_event(&time_travel_timer_event,
683	time_travel_time + delta);
684	}
685
686	if (time_travel_mode != TT_MODE_INFCPU &&
687	time_travel_mode != TT_MODE_EXTERNAL)
688	return os_timer_one_shot(delta);
689
690	return `0`;
691	}
692
693	static int itimer_one_shot(struct clock_event_device *evt)
694	{
695	return itimer_next_event(delta: `0`, evt);
696	}
697
698	static struct clock_event_device timer_clockevent = {
699	.name = "posix-timer",
700	.rating = `250`,
701	.cpumask = cpu_possible_mask,
702	.features = CLOCK_EVT_FEAT_PERIODIC \|
703	CLOCK_EVT_FEAT_ONESHOT,
704	.set_state_shutdown = itimer_shutdown,
705	.set_state_periodic = itimer_set_periodic,
706	.set_state_oneshot = itimer_one_shot,
707	.set_next_event = itimer_next_event,
708	.shift = `0`,
709	.max_delta_ns = `0xffffffff`,
710	.max_delta_ticks = `0xffffffff`,
711	.min_delta_ns = TIMER_MIN_DELTA,
712	.min_delta_ticks = TIMER_MIN_DELTA, // microsecond resolution should be enough for anyone, same as 640K RAM
713	.irq = `0`,
714	.mult = `1`,
715	};
716
717	static irqreturn_t um_timer(int irq, void *dev)
718	{
719	if (get_current()->mm != NULL)
720	{
721	/ userspace - relay signal, results in correct userspace timers /
722	os_alarm_process(get_current()->mm->context.id.u.pid);
723	}
724
725	(*timer_clockevent.event_handler)(&timer_clockevent);
726
727	return IRQ_HANDLED;
728	}
729
730	static u64 timer_read(struct clocksource *cs)
731	{
732	if (time_travel_mode != TT_MODE_OFF) {
733	/*
734	* We make reading the timer cost a bit so that we don't get
735	* stuck in loops that expect time to move more than the
736	* exact requested sleep amount, e.g. python's socket server,
737	* see https://bugs.python.org/issue37026.
738	*
739	* However, don't do that when we're in interrupt or such as
740	* then we might recurse into our own processing, and get to
741	* even more waiting, and that's not good - it messes up the
742	* "what do I do next" and onstack event we use to know when
743	* to return from time_travel_update_time().
744	*/
745	if (!irqs_disabled() && !in_interrupt() && !in_softirq() &&
746	!time_travel_ext_waiting)
747	time_travel_update_time_rel(offs: TIMER_MULTIPLIER);
748	return time_travel_time / TIMER_MULTIPLIER;
749	}
750
751	return os_nsecs() / TIMER_MULTIPLIER;
752	}
753
754	static struct clocksource timer_clocksource = {
755	.name = "timer",
756	.rating = `300`,
757	.read = timer_read,
758	.mask = CLOCKSOURCE_MASK(`64`),
759	.flags = CLOCK_SOURCE_IS_CONTINUOUS,
760	};
761
762	static void __init um_timer_setup(void)
763	{
764	int err;
765
766	err = request_irq(irq: TIMER_IRQ, handler: um_timer, IRQF_TIMER, name: "hr timer", NULL);
767	if (err != `0`)
768	printk(KERN_ERR "register_timer : request_irq failed - "
769	"errno = %d\n", -err);
770
771	err = os_timer_create();
772	if (err != `0`) {
773	printk(KERN_ERR "creation of timer failed - errno = %d\n", -err);
774	return;
775	}
776
777	err = clocksource_register_hz(cs: &timer_clocksource, NSEC_PER_SEC/TIMER_MULTIPLIER);
778	if (err) {
779	printk(KERN_ERR "clocksource_register_hz returned %d\n", err);
780	return;
781	}
782	clockevents_register_device(dev: &timer_clockevent);
783	}
784
785	void read_persistent_clock64(struct timespec64 *ts)
786	{
787	long long nsecs;
788
789	time_travel_set_start();
790
791	if (time_travel_mode != TT_MODE_OFF)
792	nsecs = time_travel_start + time_travel_time;
793	else
794	nsecs = os_persistent_clock_emulation();
795
796	set_normalized_timespec64(ts, sec: nsecs / NSEC_PER_SEC,
797	nsec: nsecs % NSEC_PER_SEC);
798	}
799
800	void __init time_init(void)
801	{
802	timer_set_signal_handler();
803	late_time_init = um_timer_setup;
804	}
805
806	#ifdef CONFIG_UML_TIME_TRAVEL_SUPPORT
807	unsigned long calibrate_delay_is_known(void)
808	{
809	if (time_travel_mode == TT_MODE_INFCPU \|\|
810	time_travel_mode == TT_MODE_EXTERNAL)
811	return `1`;
812	return `0`;
813	}
814
815	int setup_time_travel(char *str)
816	{
817	if (strcmp(str, "=inf-cpu") == `0`) {
818	time_travel_mode = TT_MODE_INFCPU;
819	timer_clockevent.name = "time-travel-timer-infcpu";
820	timer_clocksource.name = "time-travel-clock";
821	return `1`;
822	}
823
824	if (strncmp(str, "=ext:", `5`) == `0`) {
825	time_travel_mode = TT_MODE_EXTERNAL;
826	timer_clockevent.name = "time-travel-timer-external";
827	timer_clocksource.name = "time-travel-clock-external";
828	return time_travel_connect_external(str + `5`);
829	}
830
831	if (!*str) {
832	time_travel_mode = TT_MODE_BASIC;
833	timer_clockevent.name = "time-travel-timer";
834	timer_clocksource.name = "time-travel-clock";
835	return `1`;
836	}
837
838	return -EINVAL;
839	}
840
841	__setup("time-travel", setup_time_travel);
842	__uml_help(setup_time_travel,
843	"time-travel\n"
844	"This option just enables basic time travel mode, in which the clock/timers\n"
845	"inside the UML instance skip forward when there's nothing to do, rather than\n"
846	"waiting for real time to elapse. However, instance CPU speed is limited by\n"
847	"the real CPU speed, so e.g. a 10ms timer will always fire after ~10ms wall\n"
848	"clock (but quicker when there's nothing to do).\n"
849	"\n"
850	"time-travel=inf-cpu\n"
851	"This enables time travel mode with infinite processing power, in which there\n"
852	"are no wall clock timers, and any CPU processing happens - as seen from the\n"
853	"guest - instantly. This can be useful for accurate simulation regardless of\n"
854	"debug overhead, physical CPU speed, etc. but is somewhat dangerous as it can\n"
855	"easily lead to getting stuck (e.g. if anything in the system busy loops).\n"
856	"\n"
857	"time-travel=ext:[ID:]/path/to/socket\n"
858	"This enables time travel mode similar to =inf-cpu, except the system will\n"
859	"use the given socket to coordinate with a central scheduler, in order to\n"
860	"have more than one system simultaneously be on simulated time. The virtio\n"
861	"driver code in UML knows about this so you can also simulate networks and\n"
862	"devices using it, assuming the device has the right capabilities.\n"
863	"The optional ID is a 64-bit integer that's sent to the central scheduler.\n");
864
865	int setup_time_travel_start(char *str)
866	{
867	int err;
868
869	err = kstrtoull(str, `0`, &time_travel_start);
870	if (err)
871	return err;
872
873	time_travel_start_set = `1`;
874	return `1`;
875	}
876
877	__setup("time-travel-start", setup_time_travel_start);
878	__uml_help(setup_time_travel_start,
879	"time-travel-start=<seconds>\n"
880	"Configure the UML instance's wall clock to start at this value rather than\n"
881	"the host's wall clock at the time of UML boot.\n");
882	#endif
883

source code of linux/arch/um/kernel/time.c