1*ef06fc5cSmaxv /*$NetBSD: at91st.c,v 1.7 2020/07/03 16:23:02 maxv Exp $*/
2c62a0ac4Smatt
3c62a0ac4Smatt /*
4c62a0ac4Smatt * AT91RM9200 clock functions
5c62a0ac4Smatt * Copyright (c) 2007, Embedtronics Oy
6c62a0ac4Smatt * All rights reserved.
7c62a0ac4Smatt *
8c62a0ac4Smatt * Based on vx115_clk.c,
9c62a0ac4Smatt * Copyright (c) 2006, Jon Sevy <jsevy@cs.drexel.edu>
10c62a0ac4Smatt *
11c62a0ac4Smatt * Based on epclk.c
12c62a0ac4Smatt * Copyright (c) 2004 Jesse Off
13c62a0ac4Smatt * All rights reserved.
14c62a0ac4Smatt *
15c62a0ac4Smatt * Redistribution and use in source and binary forms, with or without
16c62a0ac4Smatt * modification, are permitted provided that the following conditions
17c62a0ac4Smatt * are met:
18c62a0ac4Smatt * 1. Redistributions of source code must retain the above copyright
19c62a0ac4Smatt * notice, this list of conditions and the following disclaimer.
20c62a0ac4Smatt * 2. Redistributions in binary form must reproduce the above copyright
21c62a0ac4Smatt * notice, this list of conditions and the following disclaimer in the
22c62a0ac4Smatt * documentation and/or other materials provided with the distribution.
23c62a0ac4Smatt *
24c62a0ac4Smatt * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
25c62a0ac4Smatt * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
26c62a0ac4Smatt * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
27c62a0ac4Smatt * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
28c62a0ac4Smatt * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
29c62a0ac4Smatt * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
30c62a0ac4Smatt * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
31c62a0ac4Smatt * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
32c62a0ac4Smatt * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
33c62a0ac4Smatt * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
34c62a0ac4Smatt * POSSIBILITY OF SUCH DAMAGE.
35c62a0ac4Smatt */
36c62a0ac4Smatt
37c62a0ac4Smatt /*
38c62a0ac4Smatt * Driver for the AT91RM9200 clock tick.
39c62a0ac4Smatt * We use Timer 1 for the system clock
40c62a0ac4Smatt */
41c62a0ac4Smatt
42c62a0ac4Smatt #include <sys/cdefs.h>
43*ef06fc5cSmaxv __KERNEL_RCSID(0, "$NetBSD: at91st.c,v 1.7 2020/07/03 16:23:02 maxv Exp $");
44c62a0ac4Smatt
45c62a0ac4Smatt #include <sys/types.h>
46c62a0ac4Smatt #include <sys/param.h>
47c62a0ac4Smatt #include <sys/systm.h>
48c62a0ac4Smatt #include <sys/kernel.h>
49c62a0ac4Smatt #include <sys/time.h>
50c62a0ac4Smatt #include <sys/device.h>
51c62a0ac4Smatt
52c62a0ac4Smatt #include <dev/clock_subr.h>
53c62a0ac4Smatt
54cf10107dSdyoung #include <sys/bus.h>
55c62a0ac4Smatt #include <machine/intr.h>
56c62a0ac4Smatt
57c62a0ac4Smatt #include <arm/cpufunc.h>
58c62a0ac4Smatt #include <arm/at91/at91reg.h>
59c62a0ac4Smatt #include <arm/at91/at91var.h>
60c62a0ac4Smatt #include <arm/at91/at91streg.h>
61c62a0ac4Smatt
62c62a0ac4Smatt #include <opt_hz.h> /* for HZ */
63c62a0ac4Smatt
64c62a0ac4Smatt
65c62a0ac4Smatt //#define DEBUG_CLK
66c62a0ac4Smatt #ifdef DEBUG_CLK
67c62a0ac4Smatt #define DPRINTF(fmt...) printf(fmt)
68c62a0ac4Smatt #else
69c62a0ac4Smatt #define DPRINTF(fmt...)
70c62a0ac4Smatt #endif
71c62a0ac4Smatt
72c62a0ac4Smatt
73c62a0ac4Smatt static int at91st_match(device_t, cfdata_t, void *);
74c62a0ac4Smatt static void at91st_attach(device_t, device_t, void *);
75c62a0ac4Smatt
76c62a0ac4Smatt void rtcinit(void);
77c62a0ac4Smatt
78c62a0ac4Smatt /* callback functions for intr_functions */
79c62a0ac4Smatt static int at91st_intr(void* arg);
80c62a0ac4Smatt
81c62a0ac4Smatt struct at91st_softc {
82c62a0ac4Smatt bus_space_tag_t sc_iot;
83c62a0ac4Smatt bus_space_handle_t sc_ioh;
84c62a0ac4Smatt int sc_pid;
85c62a0ac4Smatt int sc_initialized;
86c62a0ac4Smatt };
87c62a0ac4Smatt
88c62a0ac4Smatt static struct at91st_softc *at91st_sc = NULL;
89c62a0ac4Smatt static struct timeval lasttv;
90c62a0ac4Smatt
91c62a0ac4Smatt
92c62a0ac4Smatt
93c62a0ac4Smatt /* Match value for clock timer; running at 32.768kHz, want HZ ticks per second */
94c62a0ac4Smatt /* BTW, we use HZ == 64 or HZ == 128 so have a nice divisor */
95c62a0ac4Smatt /* NOTE: don't change there without visiting the functions below which */
96c62a0ac4Smatt /* convert between timer counts and microseconds */
97c62a0ac4Smatt #define AT91ST_DIVIDER (AT91_SCLK / HZ)
98c62a0ac4Smatt #define USEC_PER_TICK (1000000 / (AT91_SCLK / AT91ST_DIVIDER))
99c62a0ac4Smatt
100c62a0ac4Smatt #if 0
101c62a0ac4Smatt static uint32_t at91st_count_to_usec(uint32_t count)
102c62a0ac4Smatt {
103c62a0ac4Smatt uint32_t result;
104c62a0ac4Smatt
105c62a0ac4Smatt /* convert specified number of ticks to usec, and round up */
106c62a0ac4Smatt /* note that with 16 kHz tick rate, maximum count will be */
107c62a0ac4Smatt /* 256 (for HZ = 64), so we won't have overflow issues */
108c62a0ac4Smatt result = (1000000 * count) / AT91_SCLK;
109c62a0ac4Smatt
110c62a0ac4Smatt if ((result * AT91_SCLK) != (count * 1000000))
111c62a0ac4Smatt {
112c62a0ac4Smatt /* round up */
113c62a0ac4Smatt result += 1;
114c62a0ac4Smatt }
115c62a0ac4Smatt
116c62a0ac4Smatt return result;
117c62a0ac4Smatt }
118c62a0ac4Smatt
119c62a0ac4Smatt /* This may only be called when overflow is avoided; typically, */
120c62a0ac4Smatt /* it will be used when usec < USEC_PER_TICK */
121c62a0ac4Smatt static uint32_t usec_to_timer_count(uint32_t usec)
122c62a0ac4Smatt {
123c62a0ac4Smatt uint32_t result;
124c62a0ac4Smatt
125c62a0ac4Smatt /* convert specified number of usec to timer ticks, and round up */
126c62a0ac4Smatt result = (AT91_SCLK * usec) / 1000000;
127c62a0ac4Smatt
128c62a0ac4Smatt if ((result * 1000000) != (usec * AT91_SCLK))
129c62a0ac4Smatt {
130c62a0ac4Smatt /* round up */
131c62a0ac4Smatt result += 1;
132c62a0ac4Smatt }
133c62a0ac4Smatt
134c62a0ac4Smatt return result;
135c62a0ac4Smatt
136c62a0ac4Smatt }
137c62a0ac4Smatt #endif
138c62a0ac4Smatt
139c62a0ac4Smatt /* macros to simplify writing to the timer controller */
140c62a0ac4Smatt #define READ_ST(offset) STREG(offset)
141c62a0ac4Smatt //bus_space_read_4(sc->sc_iot, sc->sc_ioh, offset)
142c62a0ac4Smatt #define WRITE_ST(offset, value) do { \
143c62a0ac4Smatt STREG(offset) = (value); \
144c62a0ac4Smatt } while (/*CONSTCOND*/0)
145c62a0ac4Smatt //bus_space_write_4(sc->sc_iot, sc->sc_ioh, offset, value)
146c62a0ac4Smatt
147c62a0ac4Smatt
148c62a0ac4Smatt
149cbab9cadSchs CFATTACH_DECL_NEW(at91st, sizeof(struct at91st_softc), at91st_match, at91st_attach, NULL, NULL);
150c62a0ac4Smatt
151c62a0ac4Smatt
152c62a0ac4Smatt
153c62a0ac4Smatt static int
at91st_match(device_t parent,cfdata_t match,void * aux)154c62a0ac4Smatt at91st_match(device_t parent, cfdata_t match, void *aux)
155c62a0ac4Smatt {
156c62a0ac4Smatt if (strcmp(match->cf_name, "at91st") == 0)
157c62a0ac4Smatt return 2;
158c62a0ac4Smatt return 0;
159c62a0ac4Smatt }
160c62a0ac4Smatt
161c62a0ac4Smatt static void
at91st_attach(device_t parent,device_t self,void * aux)162c62a0ac4Smatt at91st_attach(device_t parent, device_t self, void *aux)
163c62a0ac4Smatt {
164cbab9cadSchs struct at91st_softc *sc = device_private(self);
165cbab9cadSchs struct at91bus_attach_args *sa = aux;
166c62a0ac4Smatt
167c62a0ac4Smatt printf("\n");
168c62a0ac4Smatt
169c62a0ac4Smatt sc->sc_iot = sa->sa_iot;
170c62a0ac4Smatt sc->sc_pid = sa->sa_pid;
171c62a0ac4Smatt
172c62a0ac4Smatt #if 0
173c62a0ac4Smatt DPRINTF("-> bus_space_map()\n");
174c62a0ac4Smatt
175c62a0ac4Smatt /* map bus space and get handle */
176c62a0ac4Smatt if (bus_space_map(sc->sc_iot, sa->sa_addr, sa->sa_size, 0, &sc->sc_ioh) != 0)
177cbab9cadSchs panic("%s: Cannot map registers", device_xname(self));
178c62a0ac4Smatt #endif
179c62a0ac4Smatt
180c62a0ac4Smatt if (at91st_sc == NULL)
181c62a0ac4Smatt at91st_sc = sc;
182c62a0ac4Smatt
183c62a0ac4Smatt at91_peripheral_clock(sc->sc_pid, 1);
184c62a0ac4Smatt
185c62a0ac4Smatt WRITE_ST(ST_IDR, -1); /* make sure interrupts are disabled */
186c62a0ac4Smatt
187c62a0ac4Smatt /* set up and enable interval timer 1 as kernel timer, */
188c62a0ac4Smatt /* using 32kHz clock source */
189c62a0ac4Smatt WRITE_ST(ST_PIMR, AT91ST_DIVIDER);
190c62a0ac4Smatt WRITE_ST(ST_RTMR, 1);
191c62a0ac4Smatt
192c62a0ac4Smatt sc->sc_initialized = 1;
193c62a0ac4Smatt
194c62a0ac4Smatt DPRINTF("%s: done\n", __FUNCTION__);
195c62a0ac4Smatt
196c62a0ac4Smatt }
197c62a0ac4Smatt
198c62a0ac4Smatt /*
199c62a0ac4Smatt * at91st_intr:
200c62a0ac4Smatt *
201c62a0ac4Smatt *Handle the hardclock interrupt.
202c62a0ac4Smatt */
203c62a0ac4Smatt static int
at91st_intr(void * arg)204c62a0ac4Smatt at91st_intr(void *arg)
205c62a0ac4Smatt {
206c62a0ac4Smatt // struct at91st_softc *sc = at91st_sc;
207c62a0ac4Smatt
208c62a0ac4Smatt /* make sure it's the kernel timer that generated the interrupt */
209c62a0ac4Smatt /* need to do this since the interrupt line is shared by the */
210c62a0ac4Smatt /* other interval and PWM timers */
211c62a0ac4Smatt if (READ_ST(ST_SR) & ST_SR_PITS)
212c62a0ac4Smatt {
213c62a0ac4Smatt /* call the kernel timer handler */
214c62a0ac4Smatt hardclock((struct clockframe*) arg);
215c62a0ac4Smatt #if 0
216*ef06fc5cSmaxv if (getticks() % (HZ * 10) == 0)
217*ef06fc5cSmaxv printf("time %i sec\n", getticks()/HZ);
218c62a0ac4Smatt #endif
219c62a0ac4Smatt return 1;
220c62a0ac4Smatt }
221c62a0ac4Smatt else
222c62a0ac4Smatt {
223c62a0ac4Smatt /* it's one of the other timers; just pass it on */
224c62a0ac4Smatt return 0;
225c62a0ac4Smatt }
226c62a0ac4Smatt
227c62a0ac4Smatt }
228c62a0ac4Smatt
229c62a0ac4Smatt /*
230c62a0ac4Smatt * setstatclockrate:
231c62a0ac4Smatt *
232c62a0ac4Smatt *Set the rate of the statistics clock.
233c62a0ac4Smatt *
234c62a0ac4Smatt *We assume that hz is either stathz or profhz, and that neither
235c62a0ac4Smatt *will change after being set by cpu_initclocks(). We could
236c62a0ac4Smatt *recalculate the intervals here, but that would be a pain.
237c62a0ac4Smatt */
238c62a0ac4Smatt void
setstatclockrate(int hzz)239c62a0ac4Smatt setstatclockrate(int hzz)
240c62a0ac4Smatt {
241c62a0ac4Smatt /* use hardclock */
242c62a0ac4Smatt (void)hzz;
243c62a0ac4Smatt }
244c62a0ac4Smatt
245c62a0ac4Smatt /*
246c62a0ac4Smatt * cpu_initclocks:
247c62a0ac4Smatt *
248c62a0ac4Smatt *Initialize the clock and get it going.
249c62a0ac4Smatt */
250c62a0ac4Smatt static void udelay(unsigned int usec);
251c62a0ac4Smatt
252c62a0ac4Smatt void
cpu_initclocks(void)253c62a0ac4Smatt cpu_initclocks(void)
254c62a0ac4Smatt {
255c62a0ac4Smatt struct at91st_softc *sc = at91st_sc;
256c62a0ac4Smatt
257c62a0ac4Smatt if (!sc || !sc->sc_initialized)
258c62a0ac4Smatt panic("%s: driver has not been initialized! (sc=%p)", __FUNCTION__, sc);
259c62a0ac4Smatt
260c62a0ac4Smatt stathz = profhz = 0;
261c62a0ac4Smatt
262c62a0ac4Smatt /* set up and enable interval timer 1 as kernel timer, */
263c62a0ac4Smatt /* using 32kHz clock source */
264c62a0ac4Smatt WRITE_ST(ST_PIMR, AT91ST_DIVIDER);
265c62a0ac4Smatt
266c62a0ac4Smatt /* register interrupt handler */
267c62a0ac4Smatt at91_intr_establish(sc->sc_pid, IPL_CLOCK, INTR_HIGH_LEVEL, at91st_intr, NULL);
268c62a0ac4Smatt
269c62a0ac4Smatt /* enable interrupts from timer */
270c62a0ac4Smatt WRITE_ST(ST_IER, ST_SR_PITS);
271c62a0ac4Smatt }
272c62a0ac4Smatt
273c62a0ac4Smatt
274c62a0ac4Smatt
275c62a0ac4Smatt
276c62a0ac4Smatt /*
277c62a0ac4Smatt * microtime:
278c62a0ac4Smatt *
279c62a0ac4Smatt *Fill in the specified timeval struct with the current time
280c62a0ac4Smatt *accurate to the microsecond.
281c62a0ac4Smatt */
282c62a0ac4Smatt void
microtime(register struct timeval * tvp)283c62a0ac4Smatt microtime(register struct timeval *tvp)
284c62a0ac4Smatt {
285c62a0ac4Smatt // struct at91st_softc *sc = at91st_sc;
286c62a0ac4Smatt u_int oldirqstate;
287c62a0ac4Smatt u_int current_count;
288c62a0ac4Smatt
289c62a0ac4Smatt #ifdef DEBUG
290c62a0ac4Smatt if (at91st_sc == NULL) {
291c62a0ac4Smatt printf("microtime: called before initialize at91st\n");
292c62a0ac4Smatt tvp->tv_sec = 0;
293c62a0ac4Smatt tvp->tv_usec = 0;
294c62a0ac4Smatt return;
295c62a0ac4Smatt }
296c62a0ac4Smatt #endif
297c62a0ac4Smatt
298c62a0ac4Smatt oldirqstate = disable_interrupts(I32_bit);
299c62a0ac4Smatt
300c62a0ac4Smatt /* get current timer count */
301c62a0ac4Smatt current_count = READ_ST(ST_CRTR);
302c62a0ac4Smatt
303c62a0ac4Smatt /* Fill in the timeval struct. */
304c62a0ac4Smatt *tvp = time;
305c62a0ac4Smatt
306c62a0ac4Smatt #if 0
307c62a0ac4Smatt /* Refine the usec field using current timer count */
308c62a0ac4Smatt tvp->tv_usec += at91st_count_to_usec(AT91ST_DIVIDER - current_count);
309c62a0ac4Smatt
310c62a0ac4Smatt /* Make sure microseconds doesn't overflow. */
311c62a0ac4Smatt while (__predict_false(tvp->tv_usec >= 1000000))
312c62a0ac4Smatt {
313c62a0ac4Smatt tvp->tv_usec -= 1000000;
314c62a0ac4Smatt tvp->tv_sec++;
315c62a0ac4Smatt }
316c62a0ac4Smatt #endif
317c62a0ac4Smatt
318c62a0ac4Smatt /* Make sure the time has advanced. */
319c62a0ac4Smatt if (__predict_false(tvp->tv_sec == lasttv.tv_sec && tvp->tv_usec <= lasttv.tv_usec))
320c62a0ac4Smatt {
321c62a0ac4Smatt tvp->tv_usec = lasttv.tv_usec + 1;
322c62a0ac4Smatt if (tvp->tv_usec >= 1000000)
323c62a0ac4Smatt {
324c62a0ac4Smatt tvp->tv_usec -= 1000000;
325c62a0ac4Smatt tvp->tv_sec++;
326c62a0ac4Smatt }
327c62a0ac4Smatt }
328c62a0ac4Smatt
329c62a0ac4Smatt lasttv = *tvp;
330c62a0ac4Smatt
331c62a0ac4Smatt restore_interrupts(oldirqstate);
332c62a0ac4Smatt }
333c62a0ac4Smatt
334c62a0ac4Smatt
335c62a0ac4Smatt #if 0
336c62a0ac4Smatt static void tdelay(unsigned int ticks)
337c62a0ac4Smatt {
33808a4aba7Sskrll uint32_t start, end, current;
339c62a0ac4Smatt
340*ef06fc5cSmaxv current = getticks();
341c62a0ac4Smatt start = current;
342c62a0ac4Smatt end = start + ticks;
343c62a0ac4Smatt
344c62a0ac4Smatt /* just loop for the specified number of ticks */
345c62a0ac4Smatt while (current < end)
346*ef06fc5cSmaxv current = getticks();
347c62a0ac4Smatt }
348c62a0ac4Smatt #endif
349c62a0ac4Smatt
udelay(unsigned int usec)350c62a0ac4Smatt static void udelay(unsigned int usec)
351c62a0ac4Smatt {
352c62a0ac4Smatt // struct at91st_softc *sc = at91st_sc;
35308a4aba7Sskrll uint32_t crtv, t, diff;
354c62a0ac4Smatt
355c62a0ac4Smatt usec = (usec * 1000 + AT91_SCLK - 1) / AT91_SCLK + 1;
356c62a0ac4Smatt
357c62a0ac4Smatt for (crtv = READ_ST(ST_CRTR);;) {
358c62a0ac4Smatt while (crtv == (t = READ_ST(ST_CRTR))) ;
359c62a0ac4Smatt diff = (t - crtv) & ST_CRTR_CRTV;
360c62a0ac4Smatt if (diff >= usec) {
361c62a0ac4Smatt break;
362c62a0ac4Smatt }
363c62a0ac4Smatt crtv = t;
364c62a0ac4Smatt usec -= diff;
365c62a0ac4Smatt }
366c62a0ac4Smatt }
367c62a0ac4Smatt
368c62a0ac4Smatt
369c62a0ac4Smatt
370c62a0ac4Smatt /*
371c62a0ac4Smatt * delay:
372c62a0ac4Smatt *
373c62a0ac4Smatt *Delay for at least N microseconds. Note that due to our coarse clock,
374c62a0ac4Smatt * our resolution is 61 us. But we round up so we'll wait at least as
375c62a0ac4Smatt * long as requested.
376c62a0ac4Smatt */
377c62a0ac4Smatt void
delay(unsigned int usec)378c62a0ac4Smatt delay(unsigned int usec)
379c62a0ac4Smatt {
380c62a0ac4Smatt
381c62a0ac4Smatt #ifdef DEBUG
382c62a0ac4Smatt if (at91st_sc == NULL) {
383c62a0ac4Smatt printf("delay: called before start at91st\n");
384c62a0ac4Smatt return;
385c62a0ac4Smatt }
386c62a0ac4Smatt #endif
387c62a0ac4Smatt
388c62a0ac4Smatt if (usec >= USEC_PER_TICK)
389c62a0ac4Smatt {
390c62a0ac4Smatt /* have more than 1 tick; just do in ticks */
391c62a0ac4Smatt unsigned int ticks = usec / USEC_PER_TICK;
392c62a0ac4Smatt if (ticks*USEC_PER_TICK != usec)
393c62a0ac4Smatt ticks += 1;
394c62a0ac4Smatt while (ticks-- > 0) {
395c62a0ac4Smatt udelay(USEC_PER_TICK);
396c62a0ac4Smatt }
397c62a0ac4Smatt }
398c62a0ac4Smatt else
399c62a0ac4Smatt {
400c62a0ac4Smatt /* less than 1 tick; can do as usec */
401c62a0ac4Smatt udelay(usec);
402c62a0ac4Smatt }
403c62a0ac4Smatt
404c62a0ac4Smatt }
405c62a0ac4Smatt
406