xref: /illumos-gate/usr/src/uts/sun4/sys/clock.h (revision 43449cdcd0600512dd862537f2cf014140dd0844)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License (the "License").
6  * You may not use this file except in compliance with the License.
7  *
8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9  * or http://www.opensolaris.org/os/licensing.
10  * See the License for the specific language governing permissions
11  * and limitations under the License.
12  *
13  * When distributing Covered Code, include this CDDL HEADER in each
14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15  * If applicable, add the following below this CDDL HEADER, with the
16  * fields enclosed by brackets "[]" replaced with your own identifying
17  * information: Portions Copyright [yyyy] [name of copyright owner]
18  *
19  * CDDL HEADER END
20  */
21 /*
22  * Copyright 2009 Sun Microsystems, Inc.  All rights reserved.
23  * Use is subject to license terms.
24  */
25 
26 #ifndef _SYS_CLOCK_H
27 #define	_SYS_CLOCK_H
28 
29 #ifdef	__cplusplus
30 extern "C" {
31 #endif
32 
33 #include <sys/spl.h>
34 #include <sys/time.h>
35 #include <sys/machclock.h>
36 
37 #ifndef _ASM
38 
39 #ifdef	_KERNEL
40 
41 extern void	setcpudelay(void);
42 
43 extern uint_t	nsec_scale;
44 extern uint_t	nsec_shift;
45 extern uint_t	nsec_per_sys_tick;
46 extern uint64_t	sys_tick_freq;
47 
48 extern int	traptrace_use_stick;
49 extern uint64_t	system_clock_freq;
50 extern uint_t	sys_clock_mhz;
51 
52 extern void mon_clock_init(void);
53 extern void mon_clock_start(void);
54 extern void mon_clock_stop(void);
55 extern void mon_clock_share(void);
56 extern void mon_clock_unshare(void);
57 
58 extern hrtime_t hrtime_base;
59 extern void hres_tick(void);
60 extern void	clkstart(void);
61 extern void cbe_level14();
62 extern hrtime_t tick2ns(hrtime_t, uint_t);
63 
64 typedef struct {
65 	uint64_t cbe_level1_inum;
66 	uint64_t cbe_level10_inum;
67 } cbe_data_t;
68 
69 #endif	/* _KERNEL */
70 
71 #endif	/* _ASM */
72 
73 
74 #define	CBE_LOW_PIL	1
75 #define	CBE_LOCK_PIL	LOCK_LEVEL
76 #define	CBE_HIGH_PIL	14
77 
78 #define	ADJ_SHIFT	4	/* used in get_hrestime and _level10 */
79 
80 /*
81  * Locking strategy for high-resolution timing services
82  *
83  * We generally construct timestamps from two or more components:
84  * a hardware time source and one or more software time sources.
85  * These components cannot all be loaded simultaneously, so we need
86  * some sort of locking strategy to generate consistent timestamps.
87  *
88  * To minimize lock contention and cache thrashing we employ the
89  * weakest possible synchronization model: writers (rare) serialize
90  * on an acquisition-counting mutex, described below; readers (common)
91  * execute in parallel with no synchronization at all -- they don't
92  * exclude other readers, and they don't even exclude writers.  Instead,
93  * readers just examine the writer lock's value before and after loading
94  * all the components of a timestamp to detect writer intervention.
95  * In the rare case when a writer does intervene, the reader will
96  * detect it, discard the timestamp and try again.
97  *
98  * The writer lock, hres_lock, is a 32-bit integer consisting of an
99  * 8-bit lock and a 24-bit acquisition count.  To acquire the lock we
100  * set the lock field with ldstub, which sets the low-order 8 bits to
101  * 0xff; to clear the lock, we increment it, which simultaneously clears
102  * the lock field (0xff --> 0x00) and increments the acquisition count
103  * (due to carry into bit 8).  Thus each acquisition transforms hres_lock
104  * from N:0 to N:ff, and each release transforms N:ff into (N+1):0.
105  *
106  * Readers can detect writer intervention by loading hres_lock before
107  * and after loading the time components they need; if either lock value
108  * contains 0xff in the low-order bits (lock held), or if the lock values
109  * are not equal (lock was acquired and released), a writer intervened
110  * and the reader must try again.  If the lock values are equal and the
111  * low-order 8 bits are clear, the timestamp must be valid.  We can check
112  * both of these conditions with a single compare instruction by checking
113  * whether old_hres_lock & ~1 == new_hres_lock, as illustrated by the
114  * following table of all possible lock states:
115  *
116  *	initial	& ~1	final		result of compare
117  *	------------	-----		-----------------
118  *	now:00		now:00		valid
119  *	now:00		now:ff		invalid
120  *	now:00		later:00	invalid
121  *	now:00		later:ff	invalid
122  *	now:fe		now:ff		invalid
123  *	now:fe		later:00	invalid
124  *	now:fe		later:ff	invalid
125  *
126  * Implementation considerations:
127  *
128  * (1) Load buffering.
129  *
130  * On a CPU that does load buffering we must ensure that the load of
131  * hres_lock completes before the load of any timestamp components.
132  * This is essential *even on a CPU that does in-order loads* because
133  * accessing the hardware time source may not involve a memory reference
134  * (e.g. rd %tick).  A convenient way to address this is to clear the
135  * lower bit (andn with 1) of the old lock value right away, since this
136  * generates a dependency on the load of hres_lock.  We have to do this
137  * anyway to perform the lock comparison described above.
138  *
139  * (2) Out-of-order loads.
140  *
141  * On a CPU that does out-of-order loads we must ensure that the loads
142  * of all timestamp components have completed before we load the final
143  * value of hres_lock.  This can be done either by generating load
144  * dependencies on the timestamp components or by membar #LoadLoad.
145  *
146  * (3) Interaction with the high level cyclic handler, hres_tick().
147  *
148  * One unusual property of hres_lock is that it's acquired in a high
149  * level cyclic handler, hres_tick().  Thus, hres_lock must be acquired at
150  * CBE_HIGH_PIL or higher to prevent single-CPU deadlock.
151  *
152  * (4) Cross-calls.
153  *
154  * If a cross-call happens while one CPU has hres_lock and another is
155  * trying to acquire it in the clock interrupt path, the system will
156  * deadlock: the first CPU will never release hres_lock since it's
157  * waiting to be released from the cross-call, and the cross-call can't
158  * complete because the second CPU is spinning on hres_lock with traps
159  * disabled.  Thus cross-calls must be blocked while holding hres_lock.
160  *
161  * Together, (3) and (4) imply that hres_lock should only be acquired
162  * at PIL >= max(XCALL_PIL, CBE_HIGH_PIL), or while traps are disabled.
163  */
164 #define	HRES_LOCK_OFFSET 3
165 
166 #define	CLOCK_LOCK(oldsplp)	\
167 	lock_set_spl((lock_t *)&hres_lock + HRES_LOCK_OFFSET, \
168 		ipltospl(CBE_HIGH_PIL), oldsplp)
169 
170 #define	CLOCK_UNLOCK(spl)	\
171 	membar_ldst_stst();	\
172 	hres_lock++;		\
173 	splx(spl);		\
174 	LOCKSTAT_RECORD0(LS_CLOCK_UNLOCK_RELEASE,	\
175 		(lock_t *)&hres_lock + HRES_LOCK_OFFSET);
176 
177 /*
178  * NATIVE_TIME_TO_NSEC_SCALE is called with NSEC_SHIFT to convert hi-res
179  * timestamps into nanoseconds. On systems that have a %stick register,
180  * hi-res timestamps are in %stick units. On systems that do not have a
181  * %stick register, hi-res timestamps are in %tick units.
182  *
183  * NATIVE_TIME_TO_NSEC_SCALE is called with TICK_NSEC_SHIFT to convert from
184  * %tick units to nanoseconds on all implementations whether %stick is
185  * available or not.
186  */
187 
188 /*
189  * At least 62.5 MHz CPU %tick frequency
190  */
191 
192 #define	TICK_NSEC_SHIFT	4
193 
194 /*
195  * Convert hi-res native time (V9's %tick in our case) into nanoseconds.
196  *
197  * The challenge is to multiply a %tick value by (NANOSEC / sys_tick_freq)
198  * without using floating point and without overflowing 64-bit integers.
199  * We assume that all sun4u systems will have a 16 nsec or better clock
200  * (i.e. faster than 62.5 MHz), which means that (ticks << 4) has units
201  * greater than one nanosecond, so converting from (ticks << 4) to nsec
202  * requires multiplication by a rational number, R, between 0 and 1.
203  * To avoid floating-point we precompute (R * 2^32) during boot and
204  * stash this away in nsec_scale.  Thus we can compute (tick * R) as
205  * (tick * nsec_scale) >> 32, which is accurate to about 1 part per billion.
206  *
207  * To avoid 64-bit overflow when multiplying (tick << 4) by nsec_scale,
208  * we split (tick << 4) into its high and low 32-bit pieces, H and L,
209  * multiply each piece separately, and add up the relevant bits of the
210  * partial products.  Putting it all together we have:
211  *
212  * nsec = (tick << 4) * R
213  *	= ((tick << 4) * nsec_scale) >> 32
214  *	= ((H << 32) + L) * nsec_scale) >> 32
215  *	= (H * nsec_scale) + ((L * nsec_scale) >> 32)
216  *
217  * The last line is the computation we actually perform: it requires no
218  * floating point and all intermediate results fit in 64-bit registers.
219  *
220  * Note that we require that tick is less than (1 << (64 - NSEC_SHIFT));
221  * greater values will result in overflow and misbehavior (not that this
222  * is a serious problem; (1 << (64 - NSEC_SHIFT)) nanoseconds is over
223  * thirty-six years).  Nonetheless, clients may wish to be aware of this
224  * limitation; NATIVE_TIME_MAX() returns this maximum native time.
225  *
226  * We provide two versions of this macro: a "full-service" version that
227  * just converts ticks to nanoseconds and a higher-performance version that
228  * expects the scaling factor nsec_scale as its second argument (so that
229  * callers can distance the load of nsec_scale from its use).  Note that
230  * we take a fast path if we determine the ticks to be less than 32 bits
231  * (as it often is for the delta between %tick values for successive
232  * firings of the hres_tick() cyclic).
233  *
234  * Note that in the 32-bit path we don't even bother clearing NPT.
235  * We get away with this by making hardclk.c ensure than nsec_scale
236  * is even, so we can take advantage of the associativity of modular
237  * arithmetic: multiplying %tick by any even number, say 2*n, is
238  * equivalent to multiplying %tick by 2, then by n.  Multiplication
239  * by 2 is equivalent to shifting left by one, which clears NPT.
240  *
241  * Finally, note that the macros use the labels "6:" and "7:"; these
242  * labels must not be used across an invocation of either macro.
243  */
244 #define	NATIVE_TIME_TO_NSEC_SCALE(out, scr1, scr2, shift)		\
245 	srlx	out, 32, scr2;		/* check high 32 bits */	\
246 /* CSTYLED */ 								\
247 	brz,a,pt scr2, 6f;		/* if clear, 32-bit fast path */\
248 	mulx	out, scr1, out;		/* delay: 32-bit fast path */	\
249 	sllx	out, shift, out;	/* clear NPT and pre-scale */	\
250 	srlx	out, 32, scr2;		/* scr2 = hi32(tick<<4) = H */	\
251 	mulx	scr2, scr1, scr2;	/* scr2 = (H*F) */		\
252 	srl	out, 0, out;		/* out = lo32(tick<<4) = L */	\
253 	mulx	out, scr1, scr1;	/* scr1 = (L*F) */		\
254 	srlx	scr1, 32, scr1;		/* scr1 = (L*F) >> 32 */	\
255 	ba	7f;			/* branch over 32-bit path */	\
256 	add	scr1, scr2, out;	/* out = (H*F) + ((L*F) >> 32) */\
257 6:									\
258 	srlx	out, 32 - shift, out;					\
259 7:
260 
261 #define	NATIVE_TIME_TO_NSEC(out, scr1, scr2)				\
262 	sethi	%hi(nsec_scale), scr1;	/* load scaling factor */	\
263 	ld	[scr1 + %lo(nsec_scale)], scr1;				\
264 	NATIVE_TIME_TO_NSEC_SCALE(out, scr1, scr2, NSEC_SHIFT);
265 
266 #define	NATIVE_TIME_MAX(out)						\
267 	mov	-1, out;						\
268 	srlx	out, NSEC_SHIFT, out
269 
270 /*
271  * NSEC_SHIFT and VTRACE_SHIFT constants are defined in
272  * <sys/machclock.h> file.
273  */
274 
275 #ifdef	__cplusplus
276 }
277 #endif
278 
279 #endif	/* !_SYS_CLOCK_H */
280