xref: /openbmc/qemu/hw/misc/stm32l4x5_rcc.c (revision 6fdc5bc1)
1 /*
2  * STM32L4X5 RCC (Reset and clock control)
3  *
4  * Copyright (c) 2023 Arnaud Minier <arnaud.minier@telecom-paris.fr>
5  * Copyright (c) 2023 Inès Varhol <ines.varhol@telecom-paris.fr>
6  *
7  * SPDX-License-Identifier: GPL-2.0-or-later
8  *
9  * This work is licensed under the terms of the GNU GPL, version 2 or later.
10  * See the COPYING file in the top-level directory.
11  *
12  * The reference used is the STMicroElectronics RM0351 Reference manual
13  * for STM32L4x5 and STM32L4x6 advanced Arm ® -based 32-bit MCUs.
14  *
15  * Inspired by the BCM2835 CPRMAN clock manager implementation by Luc Michel.
16  */
17 
18 #include "qemu/osdep.h"
19 #include "qemu/log.h"
20 #include "qemu/module.h"
21 #include "qemu/timer.h"
22 #include "qapi/error.h"
23 #include "migration/vmstate.h"
24 #include "hw/misc/stm32l4x5_rcc.h"
25 #include "hw/misc/stm32l4x5_rcc_internals.h"
26 #include "hw/clock.h"
27 #include "hw/irq.h"
28 #include "hw/qdev-clock.h"
29 #include "hw/qdev-properties.h"
30 #include "hw/qdev-properties-system.h"
31 #include "hw/registerfields.h"
32 #include "trace.h"
33 
34 #define HSE_DEFAULT_FRQ 48000000ULL
35 #define HSI_FRQ 16000000ULL
36 #define MSI_DEFAULT_FRQ 4000000ULL
37 #define LSE_FRQ 32768ULL
38 #define LSI_FRQ 32000ULL
39 
40 /*
41  * Function to simply acknowledge and propagate changes in a clock mux
42  * frequency.
43  * `bypass_source` allows to bypass the period of the current source and just
44  * consider it equal to 0. This is useful during the hold phase of reset.
45  */
46 static void clock_mux_update(RccClockMuxState *mux, bool bypass_source)
47 {
48     uint64_t src_freq;
49     Clock *current_source = mux->srcs[mux->src];
50     uint32_t freq_multiplier = 0;
51     bool clk_changed = false;
52 
53     /*
54      * To avoid rounding errors, we use the clock period instead of the
55      * frequency.
56      * This means that the multiplier of the mux becomes the divider of
57      * the clock and the divider of the mux becomes the multiplier of the
58      * clock.
59      */
60     if (!bypass_source && mux->enabled && mux->divider) {
61         freq_multiplier = mux->divider;
62     }
63 
64     clk_changed |= clock_set_mul_div(mux->out, freq_multiplier, mux->multiplier);
65     clk_changed |= clock_set(mux->out, clock_get(current_source));
66     if (clk_changed) {
67         clock_propagate(mux->out);
68     }
69 
70     src_freq = clock_get_hz(current_source);
71     /* TODO: can we simply detect if the config changed so that we reduce log spam ? */
72     trace_stm32l4x5_rcc_mux_update(mux->id, mux->src, src_freq,
73                                    mux->multiplier, mux->divider);
74 }
75 
76 static void clock_mux_src_update(void *opaque, ClockEvent event)
77 {
78     RccClockMuxState **backref = opaque;
79     RccClockMuxState *s = *backref;
80     /*
81      * The backref value is equal to:
82      * s->backref + (sizeof(RccClockMuxState *) * update_src).
83      * By subtracting we can get back the index of the updated clock.
84      */
85     const uint32_t update_src = backref - s->backref;
86     /* Only update if the clock that was updated is the current source */
87     if (update_src == s->src) {
88         clock_mux_update(s, false);
89     }
90 }
91 
92 static void clock_mux_init(Object *obj)
93 {
94     RccClockMuxState *s = RCC_CLOCK_MUX(obj);
95     size_t i;
96 
97     for (i = 0; i < RCC_NUM_CLOCK_MUX_SRC; i++) {
98         char *name = g_strdup_printf("srcs[%zu]", i);
99         s->backref[i] = s;
100         s->srcs[i] = qdev_init_clock_in(DEVICE(s), name,
101                                         clock_mux_src_update,
102                                         &s->backref[i],
103                                         ClockUpdate);
104         g_free(name);
105     }
106 
107     s->out = qdev_init_clock_out(DEVICE(s), "out");
108 }
109 
110 static void clock_mux_reset_enter(Object *obj, ResetType type)
111 {
112     RccClockMuxState *s = RCC_CLOCK_MUX(obj);
113     set_clock_mux_init_info(s, s->id);
114 }
115 
116 static void clock_mux_reset_hold(Object *obj, ResetType type)
117 {
118     RccClockMuxState *s = RCC_CLOCK_MUX(obj);
119     clock_mux_update(s, true);
120 }
121 
122 static void clock_mux_reset_exit(Object *obj, ResetType type)
123 {
124     RccClockMuxState *s = RCC_CLOCK_MUX(obj);
125     clock_mux_update(s, false);
126 }
127 
128 static const VMStateDescription clock_mux_vmstate = {
129     .name = TYPE_RCC_CLOCK_MUX,
130     .version_id = 1,
131     .minimum_version_id = 1,
132     .fields = (VMStateField[]) {
133         VMSTATE_UINT32(id, RccClockMuxState),
134         VMSTATE_ARRAY_CLOCK(srcs, RccClockMuxState,
135                             RCC_NUM_CLOCK_MUX_SRC),
136         VMSTATE_BOOL(enabled, RccClockMuxState),
137         VMSTATE_UINT32(src, RccClockMuxState),
138         VMSTATE_UINT32(multiplier, RccClockMuxState),
139         VMSTATE_UINT32(divider, RccClockMuxState),
140         VMSTATE_END_OF_LIST()
141     }
142 };
143 
144 static void clock_mux_class_init(ObjectClass *klass, void *data)
145 {
146     DeviceClass *dc = DEVICE_CLASS(klass);
147     ResettableClass *rc = RESETTABLE_CLASS(klass);
148 
149     rc->phases.enter = clock_mux_reset_enter;
150     rc->phases.hold = clock_mux_reset_hold;
151     rc->phases.exit = clock_mux_reset_exit;
152     dc->vmsd = &clock_mux_vmstate;
153 }
154 
155 static void clock_mux_set_enable(RccClockMuxState *mux, bool enabled)
156 {
157     if (mux->enabled == enabled) {
158         return;
159     }
160 
161     if (enabled) {
162         trace_stm32l4x5_rcc_mux_enable(mux->id);
163     } else {
164         trace_stm32l4x5_rcc_mux_disable(mux->id);
165     }
166 
167     mux->enabled = enabled;
168     clock_mux_update(mux, false);
169 }
170 
171 static void clock_mux_set_factor(RccClockMuxState *mux,
172                                  uint32_t multiplier, uint32_t divider)
173 {
174     if (mux->multiplier == multiplier && mux->divider == divider) {
175         return;
176     }
177     trace_stm32l4x5_rcc_mux_set_factor(mux->id,
178         mux->multiplier, multiplier, mux->divider, divider);
179 
180     mux->multiplier = multiplier;
181     mux->divider = divider;
182     clock_mux_update(mux, false);
183 }
184 
185 static void clock_mux_set_source(RccClockMuxState *mux, RccClockMuxSource src)
186 {
187     if (mux->src == src) {
188         return;
189     }
190 
191     trace_stm32l4x5_rcc_mux_set_src(mux->id, mux->src, src);
192     mux->src = src;
193     clock_mux_update(mux, false);
194 }
195 
196 /*
197  * Acknowledge and propagate changes in a PLL frequency.
198  * `bypass_source` allows to bypass the period of the current source and just
199  * consider it equal to 0. This is useful during the hold phase of reset.
200  */
201 static void pll_update(RccPllState *pll, bool bypass_source)
202 {
203     uint64_t vco_freq, old_channel_freq, channel_freq;
204     int i;
205 
206     /* The common PLLM factor is handled by the PLL mux */
207     vco_freq = muldiv64(clock_get_hz(pll->in), pll->vco_multiplier, 1);
208 
209     for (i = 0; i < RCC_NUM_CHANNEL_PLL_OUT; i++) {
210         if (!pll->channel_exists[i]) {
211             continue;
212         }
213 
214         old_channel_freq = clock_get_hz(pll->channels[i]);
215         if (bypass_source ||
216             !pll->enabled ||
217             !pll->channel_enabled[i] ||
218             !pll->channel_divider[i]) {
219             channel_freq = 0;
220         } else {
221             channel_freq = muldiv64(vco_freq,
222                                     1,
223                                     pll->channel_divider[i]);
224         }
225 
226         /* No change, early continue to avoid log spam and useless propagation */
227         if (old_channel_freq == channel_freq) {
228             continue;
229         }
230 
231         clock_update_hz(pll->channels[i], channel_freq);
232         trace_stm32l4x5_rcc_pll_update(pll->id, i, vco_freq,
233             old_channel_freq, channel_freq);
234     }
235 }
236 
237 static void pll_src_update(void *opaque, ClockEvent event)
238 {
239     RccPllState *s = opaque;
240     pll_update(s, false);
241 }
242 
243 static void pll_init(Object *obj)
244 {
245     RccPllState *s = RCC_PLL(obj);
246     size_t i;
247 
248     s->in = qdev_init_clock_in(DEVICE(s), "in",
249                                pll_src_update, s, ClockUpdate);
250 
251     const char *names[] = {
252         "out-p", "out-q", "out-r",
253     };
254 
255     for (i = 0; i < RCC_NUM_CHANNEL_PLL_OUT; i++) {
256         s->channels[i] = qdev_init_clock_out(DEVICE(s), names[i]);
257     }
258 }
259 
260 static void pll_reset_enter(Object *obj, ResetType type)
261 {
262     RccPllState *s = RCC_PLL(obj);
263     set_pll_init_info(s, s->id);
264 }
265 
266 static void pll_reset_hold(Object *obj, ResetType type)
267 {
268     RccPllState *s = RCC_PLL(obj);
269     pll_update(s, true);
270 }
271 
272 static void pll_reset_exit(Object *obj, ResetType type)
273 {
274     RccPllState *s = RCC_PLL(obj);
275     pll_update(s, false);
276 }
277 
278 static const VMStateDescription pll_vmstate = {
279     .name = TYPE_RCC_PLL,
280     .version_id = 1,
281     .minimum_version_id = 1,
282     .fields = (VMStateField[]) {
283         VMSTATE_UINT32(id, RccPllState),
284         VMSTATE_CLOCK(in, RccPllState),
285         VMSTATE_ARRAY_CLOCK(channels, RccPllState,
286                             RCC_NUM_CHANNEL_PLL_OUT),
287         VMSTATE_BOOL(enabled, RccPllState),
288         VMSTATE_UINT32(vco_multiplier, RccPllState),
289         VMSTATE_BOOL_ARRAY(channel_enabled, RccPllState, RCC_NUM_CHANNEL_PLL_OUT),
290         VMSTATE_BOOL_ARRAY(channel_exists, RccPllState, RCC_NUM_CHANNEL_PLL_OUT),
291         VMSTATE_UINT32_ARRAY(channel_divider, RccPllState, RCC_NUM_CHANNEL_PLL_OUT),
292         VMSTATE_END_OF_LIST()
293     }
294 };
295 
296 static void pll_class_init(ObjectClass *klass, void *data)
297 {
298     DeviceClass *dc = DEVICE_CLASS(klass);
299     ResettableClass *rc = RESETTABLE_CLASS(klass);
300 
301     rc->phases.enter = pll_reset_enter;
302     rc->phases.hold = pll_reset_hold;
303     rc->phases.exit = pll_reset_exit;
304     dc->vmsd = &pll_vmstate;
305 }
306 
307 static void pll_set_vco_multiplier(RccPllState *pll, uint32_t vco_multiplier)
308 {
309     if (pll->vco_multiplier == vco_multiplier) {
310         return;
311     }
312 
313     if (vco_multiplier < 8 || vco_multiplier > 86) {
314         qemu_log_mask(LOG_GUEST_ERROR,
315             "%s: VCO multiplier is out of bound (%u) for PLL %u\n",
316             __func__, vco_multiplier, pll->id);
317         return;
318     }
319 
320     trace_stm32l4x5_rcc_pll_set_vco_multiplier(pll->id,
321         pll->vco_multiplier, vco_multiplier);
322 
323     pll->vco_multiplier = vco_multiplier;
324     pll_update(pll, false);
325 }
326 
327 static void pll_set_enable(RccPllState *pll, bool enabled)
328 {
329     if (pll->enabled == enabled) {
330         return;
331     }
332 
333     pll->enabled = enabled;
334     pll_update(pll, false);
335 }
336 
337 static void pll_set_channel_enable(RccPllState *pll,
338                                    PllCommonChannels channel,
339                                    bool enabled)
340 {
341     if (pll->channel_enabled[channel] == enabled) {
342         return;
343     }
344 
345     if (enabled) {
346         trace_stm32l4x5_rcc_pll_channel_enable(pll->id, channel);
347     } else {
348         trace_stm32l4x5_rcc_pll_channel_disable(pll->id, channel);
349     }
350 
351     pll->channel_enabled[channel] = enabled;
352     pll_update(pll, false);
353 }
354 
355 static void pll_set_channel_divider(RccPllState *pll,
356                                     PllCommonChannels channel,
357                                     uint32_t divider)
358 {
359     if (pll->channel_divider[channel] == divider) {
360         return;
361     }
362 
363     trace_stm32l4x5_rcc_pll_set_channel_divider(pll->id,
364         channel, pll->channel_divider[channel], divider);
365 
366     pll->channel_divider[channel] = divider;
367     pll_update(pll, false);
368 }
369 
370 static void rcc_update_irq(Stm32l4x5RccState *s)
371 {
372     /*
373      * TODO: Handle LSECSSF and CSSF flags when the CSS is implemented.
374      */
375     if (s->cifr & CIFR_IRQ_MASK) {
376         qemu_irq_raise(s->irq);
377     } else {
378         qemu_irq_lower(s->irq);
379     }
380 }
381 
382 static void rcc_update_msi(Stm32l4x5RccState *s, uint32_t previous_value)
383 {
384     uint32_t val;
385 
386     static const uint32_t msirange[] = {
387         100000, 200000, 400000, 800000, 1000000, 2000000,
388         4000000, 8000000, 16000000, 24000000, 32000000, 48000000
389     };
390     /* MSIRANGE and MSIRGSEL */
391     val = extract32(s->cr, R_CR_MSIRGSEL_SHIFT, R_CR_MSIRGSEL_LENGTH);
392     if (val) {
393         /* MSIRGSEL is set, use the MSIRANGE field */
394         val = extract32(s->cr, R_CR_MSIRANGE_SHIFT, R_CR_MSIRANGE_LENGTH);
395     } else {
396         /* MSIRGSEL is not set, use the MSISRANGE field */
397         val = extract32(s->csr, R_CSR_MSISRANGE_SHIFT, R_CSR_MSISRANGE_LENGTH);
398     }
399 
400     if (val < ARRAY_SIZE(msirange)) {
401         clock_update_hz(s->msi_rc, msirange[val]);
402     } else {
403         /*
404          * There is a hardware write protection if the value is out of bound.
405          * Restore the previous value.
406          */
407         s->cr = (s->cr & ~R_CSR_MSISRANGE_MASK) |
408                 (previous_value & R_CSR_MSISRANGE_MASK);
409     }
410 }
411 
412 /*
413  * TODO: Add write-protection for all registers:
414  * DONE: CR
415  */
416 
417 static void rcc_update_cr_register(Stm32l4x5RccState *s, uint32_t previous_value)
418 {
419     int val;
420     const RccClockMuxSource current_pll_src =
421         CLOCK_MUX_INIT_INFO[RCC_CLOCK_MUX_PLL_INPUT].src_mapping[
422             s->clock_muxes[RCC_CLOCK_MUX_PLL_INPUT].src];
423 
424     /* PLLSAI2ON and update PLLSAI2RDY */
425     val = FIELD_EX32(s->cr, CR, PLLSAI2ON);
426     pll_set_enable(&s->plls[RCC_PLL_PLLSAI2], val);
427     s->cr = (s->cr & ~R_CR_PLLSAI2RDY_MASK) |
428             (val << R_CR_PLLSAI2RDY_SHIFT);
429     if (s->cier & R_CIER_PLLSAI2RDYIE_MASK) {
430         s->cifr |= R_CIFR_PLLSAI2RDYF_MASK;
431     }
432 
433     /* PLLSAI1ON and update PLLSAI1RDY */
434     val = FIELD_EX32(s->cr, CR, PLLSAI1ON);
435     pll_set_enable(&s->plls[RCC_PLL_PLLSAI1], val);
436     s->cr = (s->cr & ~R_CR_PLLSAI1RDY_MASK) |
437             (val << R_CR_PLLSAI1RDY_SHIFT);
438     if (s->cier & R_CIER_PLLSAI1RDYIE_MASK) {
439         s->cifr |= R_CIFR_PLLSAI1RDYF_MASK;
440     }
441 
442     /*
443      * PLLON and update PLLRDY
444      * PLLON cannot be reset if the PLL clock is used as the system clock.
445      */
446     val = FIELD_EX32(s->cr, CR, PLLON);
447     if (FIELD_EX32(s->cfgr, CFGR, SWS) != 0b11) {
448         pll_set_enable(&s->plls[RCC_PLL_PLL], val);
449         s->cr = (s->cr & ~R_CR_PLLRDY_MASK) |
450                 (val << R_CR_PLLRDY_SHIFT);
451         if (s->cier & R_CIER_PLLRDYIE_MASK) {
452             s->cifr |= R_CIFR_PLLRDYF_MASK;
453         }
454     } else {
455         s->cr |= R_CR_PLLON_MASK;
456     }
457 
458     /* CSSON: TODO */
459     /* HSEBYP: TODO */
460 
461     /*
462      * HSEON and update HSERDY.
463      * HSEON cannot be reset if the HSE oscillator is used directly or
464      * indirectly as the system clock.
465      */
466     val = FIELD_EX32(s->cr, CR, HSEON);
467     if (FIELD_EX32(s->cfgr, CFGR, SWS) != 0b10 &&
468         current_pll_src != RCC_CLOCK_MUX_SRC_HSE) {
469         s->cr = (s->cr & ~R_CR_HSERDY_MASK) |
470                 (val << R_CR_HSERDY_SHIFT);
471         if (val) {
472             clock_update_hz(s->hse, s->hse_frequency);
473             if (s->cier & R_CIER_HSERDYIE_MASK) {
474                 s->cifr |= R_CIFR_HSERDYF_MASK;
475             }
476         } else {
477             clock_update(s->hse, 0);
478         }
479     } else {
480         s->cr |= R_CR_HSEON_MASK;
481     }
482 
483     /* HSIAFS: TODO*/
484     /* HSIKERON: TODO*/
485 
486     /*
487      * HSION and update HSIRDY
488      * HSION is set by hardware if the HSI16 is used directly
489      * or indirectly as system clock.
490      */
491     if (FIELD_EX32(s->cfgr, CFGR, SWS) == 0b01 ||
492         current_pll_src == RCC_CLOCK_MUX_SRC_HSI) {
493         s->cr |= (R_CR_HSION_MASK | R_CR_HSIRDY_MASK);
494         clock_update_hz(s->hsi16_rc, HSI_FRQ);
495         if (s->cier & R_CIER_HSIRDYIE_MASK) {
496             s->cifr |= R_CIFR_HSIRDYF_MASK;
497         }
498     } else {
499         val = FIELD_EX32(s->cr, CR, HSION);
500         if (val) {
501             clock_update_hz(s->hsi16_rc, HSI_FRQ);
502             s->cr |= R_CR_HSIRDY_MASK;
503             if (s->cier & R_CIER_HSIRDYIE_MASK) {
504                 s->cifr |= R_CIFR_HSIRDYF_MASK;
505             }
506         } else {
507             clock_update(s->hsi16_rc, 0);
508             s->cr &= ~R_CR_HSIRDY_MASK;
509         }
510     }
511 
512     /* MSIPLLEN: TODO */
513 
514     /*
515      * MSION and update MSIRDY
516      * Set by hardware when used directly or indirectly as system clock.
517      */
518     if (FIELD_EX32(s->cfgr, CFGR, SWS) == 0b00 ||
519         current_pll_src == RCC_CLOCK_MUX_SRC_MSI) {
520             s->cr |= (R_CR_MSION_MASK | R_CR_MSIRDY_MASK);
521             if (!(previous_value & R_CR_MSION_MASK) && (s->cier & R_CIER_MSIRDYIE_MASK)) {
522                 s->cifr |= R_CIFR_MSIRDYF_MASK;
523             }
524             rcc_update_msi(s, previous_value);
525     } else {
526         val = FIELD_EX32(s->cr, CR, MSION);
527         if (val) {
528             s->cr |= R_CR_MSIRDY_MASK;
529             rcc_update_msi(s, previous_value);
530             if (s->cier & R_CIER_MSIRDYIE_MASK) {
531                 s->cifr |= R_CIFR_MSIRDYF_MASK;
532             }
533         } else {
534             s->cr &= ~R_CR_MSIRDY_MASK;
535             clock_update(s->msi_rc, 0);
536         }
537     }
538     rcc_update_irq(s);
539 }
540 
541 static void rcc_update_cfgr_register(Stm32l4x5RccState *s)
542 {
543     uint32_t val;
544     /* MCOPRE */
545     val = FIELD_EX32(s->cfgr, CFGR, MCOPRE);
546     if (val > 0b100) {
547         qemu_log_mask(LOG_GUEST_ERROR,
548                       "%s: Invalid MCOPRE value: 0x%"PRIx32"\n",
549                       __func__, val);
550         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_MCO], false);
551     } else {
552         clock_mux_set_factor(&s->clock_muxes[RCC_CLOCK_MUX_MCO],
553                              1, 1 << val);
554     }
555 
556     /* MCOSEL */
557     val = FIELD_EX32(s->cfgr, CFGR, MCOSEL);
558     if (val > 0b111) {
559         qemu_log_mask(LOG_GUEST_ERROR,
560                       "%s: Invalid MCOSEL value: 0x%"PRIx32"\n",
561                       __func__, val);
562         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_MCO], false);
563     } else {
564         if (val == 0) {
565             clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_MCO], false);
566         } else {
567             clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_MCO], true);
568             clock_mux_set_source(&s->clock_muxes[RCC_CLOCK_MUX_MCO],
569                                  val - 1);
570         }
571     }
572 
573     /* STOPWUCK */
574     /* TODO */
575 
576     /* PPRE2 */
577     val = FIELD_EX32(s->cfgr, CFGR, PPRE2);
578     if (val < 0b100) {
579         clock_mux_set_factor(&s->clock_muxes[RCC_CLOCK_MUX_PCLK2],
580                              1, 1);
581     } else {
582         clock_mux_set_factor(&s->clock_muxes[RCC_CLOCK_MUX_PCLK2],
583                              1, 1 << (val - 0b11));
584     }
585 
586     /* PPRE1 */
587     val = FIELD_EX32(s->cfgr, CFGR, PPRE1);
588     if (val < 0b100) {
589         clock_mux_set_factor(&s->clock_muxes[RCC_CLOCK_MUX_PCLK1],
590                              1, 1);
591     } else {
592         clock_mux_set_factor(&s->clock_muxes[RCC_CLOCK_MUX_PCLK1],
593                              1, 1 << (val - 0b11));
594     }
595 
596     /* HPRE */
597     val = FIELD_EX32(s->cfgr, CFGR, HPRE);
598     if (val < 0b1000) {
599         clock_mux_set_factor(&s->clock_muxes[RCC_CLOCK_MUX_HCLK],
600                              1, 1);
601     } else {
602         clock_mux_set_factor(&s->clock_muxes[RCC_CLOCK_MUX_HCLK],
603                              1, 1 << (val - 0b111));
604     }
605 
606     /* Update SWS */
607     val = FIELD_EX32(s->cfgr, CFGR, SW);
608     clock_mux_set_source(&s->clock_muxes[RCC_CLOCK_MUX_SYSCLK],
609                          val);
610     s->cfgr &= ~R_CFGR_SWS_MASK;
611     s->cfgr |= val << R_CFGR_SWS_SHIFT;
612 }
613 
614 static void rcc_update_ahb1enr(Stm32l4x5RccState *s)
615 {
616     #define AHB1ENR_SET_ENABLE(_peripheral_name) \
617         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_##_peripheral_name], \
618             FIELD_EX32(s->ahb1enr, AHB1ENR, _peripheral_name##EN))
619 
620     /* DMA2DEN: reserved for STM32L475xx */
621     AHB1ENR_SET_ENABLE(TSC);
622     AHB1ENR_SET_ENABLE(CRC);
623     AHB1ENR_SET_ENABLE(FLASH);
624     AHB1ENR_SET_ENABLE(DMA2);
625     AHB1ENR_SET_ENABLE(DMA1);
626 
627     #undef AHB1ENR_SET_ENABLE
628 }
629 
630 static void rcc_update_ahb2enr(Stm32l4x5RccState *s)
631 {
632     #define AHB2ENR_SET_ENABLE(_peripheral_name) \
633         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_##_peripheral_name], \
634             FIELD_EX32(s->ahb2enr, AHB2ENR, _peripheral_name##EN))
635 
636     AHB2ENR_SET_ENABLE(RNG);
637     /* HASHEN: reserved for STM32L475xx */
638     AHB2ENR_SET_ENABLE(AES);
639     /* DCMIEN: reserved for STM32L475xx */
640     AHB2ENR_SET_ENABLE(ADC);
641     AHB2ENR_SET_ENABLE(OTGFS);
642     /* GPIOIEN: reserved for STM32L475xx */
643     AHB2ENR_SET_ENABLE(GPIOA);
644     AHB2ENR_SET_ENABLE(GPIOB);
645     AHB2ENR_SET_ENABLE(GPIOC);
646     AHB2ENR_SET_ENABLE(GPIOD);
647     AHB2ENR_SET_ENABLE(GPIOE);
648     AHB2ENR_SET_ENABLE(GPIOF);
649     AHB2ENR_SET_ENABLE(GPIOG);
650     AHB2ENR_SET_ENABLE(GPIOH);
651 
652     #undef AHB2ENR_SET_ENABLE
653 }
654 
655 static void rcc_update_ahb3enr(Stm32l4x5RccState *s)
656 {
657     #define AHB3ENR_SET_ENABLE(_peripheral_name) \
658         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_##_peripheral_name], \
659             FIELD_EX32(s->ahb3enr, AHB3ENR, _peripheral_name##EN))
660 
661     AHB3ENR_SET_ENABLE(QSPI);
662     AHB3ENR_SET_ENABLE(FMC);
663 
664     #undef AHB3ENR_SET_ENABLE
665 }
666 
667 static void rcc_update_apb1enr(Stm32l4x5RccState *s)
668 {
669     #define APB1ENR1_SET_ENABLE(_peripheral_name) \
670         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_##_peripheral_name], \
671             FIELD_EX32(s->apb1enr1, APB1ENR1, _peripheral_name##EN))
672     #define APB1ENR2_SET_ENABLE(_peripheral_name) \
673         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_##_peripheral_name], \
674             FIELD_EX32(s->apb1enr2, APB1ENR2, _peripheral_name##EN))
675 
676     /* APB1ENR1 */
677     APB1ENR1_SET_ENABLE(LPTIM1);
678     APB1ENR1_SET_ENABLE(OPAMP);
679     APB1ENR1_SET_ENABLE(DAC1);
680     APB1ENR1_SET_ENABLE(PWR);
681     /* CAN2: reserved for STM32L4x5 */
682     APB1ENR1_SET_ENABLE(CAN1);
683     /* CRSEN: reserved for STM32L4x5 */
684     APB1ENR1_SET_ENABLE(I2C3);
685     APB1ENR1_SET_ENABLE(I2C2);
686     APB1ENR1_SET_ENABLE(I2C1);
687     APB1ENR1_SET_ENABLE(UART5);
688     APB1ENR1_SET_ENABLE(UART4);
689     APB1ENR1_SET_ENABLE(USART3);
690     APB1ENR1_SET_ENABLE(USART2);
691     APB1ENR1_SET_ENABLE(SPI3);
692     APB1ENR1_SET_ENABLE(SPI2);
693     APB1ENR1_SET_ENABLE(WWDG);
694     /* RTCAPB: reserved for STM32L4x5 */
695     APB1ENR1_SET_ENABLE(LCD);
696     APB1ENR1_SET_ENABLE(TIM7);
697     APB1ENR1_SET_ENABLE(TIM6);
698     APB1ENR1_SET_ENABLE(TIM5);
699     APB1ENR1_SET_ENABLE(TIM4);
700     APB1ENR1_SET_ENABLE(TIM3);
701     APB1ENR1_SET_ENABLE(TIM2);
702 
703     /* APB1ENR2 */
704     APB1ENR2_SET_ENABLE(LPTIM2);
705     APB1ENR2_SET_ENABLE(SWPMI1);
706     /* I2C4EN: reserved for STM32L4x5 */
707     APB1ENR2_SET_ENABLE(LPUART1);
708 
709     #undef APB1ENR1_SET_ENABLE
710     #undef APB1ENR2_SET_ENABLE
711 }
712 
713 static void rcc_update_apb2enr(Stm32l4x5RccState *s)
714 {
715     #define APB2ENR_SET_ENABLE(_peripheral_name) \
716         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_##_peripheral_name], \
717             FIELD_EX32(s->apb2enr, APB2ENR, _peripheral_name##EN))
718 
719     APB2ENR_SET_ENABLE(DFSDM1);
720     APB2ENR_SET_ENABLE(SAI2);
721     APB2ENR_SET_ENABLE(SAI1);
722     APB2ENR_SET_ENABLE(TIM17);
723     APB2ENR_SET_ENABLE(TIM16);
724     APB2ENR_SET_ENABLE(TIM15);
725     APB2ENR_SET_ENABLE(USART1);
726     APB2ENR_SET_ENABLE(TIM8);
727     APB2ENR_SET_ENABLE(SPI1);
728     APB2ENR_SET_ENABLE(TIM1);
729     APB2ENR_SET_ENABLE(SDMMC1);
730     APB2ENR_SET_ENABLE(FW);
731     APB2ENR_SET_ENABLE(SYSCFG);
732 
733     #undef APB2ENR_SET_ENABLE
734 }
735 
736 /*
737  * The 3 PLLs share the same register layout
738  * so we can use the same function for all of them
739  * Note: no frequency bounds checking is done here.
740  */
741 static void rcc_update_pllsaixcfgr(Stm32l4x5RccState *s, RccPll pll_id)
742 {
743     uint32_t reg, val;
744     switch (pll_id) {
745     case RCC_PLL_PLL:
746         reg = s->pllcfgr;
747         break;
748     case RCC_PLL_PLLSAI1:
749         reg = s->pllsai1cfgr;
750         break;
751     case RCC_PLL_PLLSAI2:
752         reg = s->pllsai2cfgr;
753         break;
754     default:
755         qemu_log_mask(LOG_GUEST_ERROR,
756                       "%s: Invalid PLL ID: %u\n", __func__, pll_id);
757         return;
758     }
759 
760     /* PLLPDIV */
761     val = FIELD_EX32(reg, PLLCFGR, PLLPDIV);
762     /* 1 is a reserved value */
763     if (val == 0) {
764         /* Get PLLP value */
765         val = FIELD_EX32(reg, PLLCFGR, PLLP);
766         pll_set_channel_divider(&s->plls[pll_id], RCC_PLL_COMMON_CHANNEL_P,
767             (val ? 17 : 7));
768     } else if (val > 1) {
769         pll_set_channel_divider(&s->plls[pll_id], RCC_PLL_COMMON_CHANNEL_P,
770             val);
771     }
772 
773 
774     /* PLLR */
775     val = FIELD_EX32(reg, PLLCFGR, PLLR);
776     pll_set_channel_divider(&s->plls[pll_id], RCC_PLL_COMMON_CHANNEL_R,
777         2 * (val + 1));
778 
779     /* PLLREN */
780     val = FIELD_EX32(reg, PLLCFGR, PLLREN);
781     pll_set_channel_enable(&s->plls[pll_id], RCC_PLL_COMMON_CHANNEL_R, val);
782 
783     /* PLLQ */
784     val = FIELD_EX32(reg, PLLCFGR, PLLQ);
785     pll_set_channel_divider(&s->plls[pll_id], RCC_PLL_COMMON_CHANNEL_Q,
786         2 * (val + 1));
787 
788     /* PLLQEN */
789     val = FIELD_EX32(reg, PLLCFGR, PLLQEN);
790     pll_set_channel_enable(&s->plls[pll_id], RCC_PLL_COMMON_CHANNEL_Q, val);
791 
792     /* PLLPEN */
793     val = FIELD_EX32(reg, PLLCFGR, PLLPEN);
794     pll_set_channel_enable(&s->plls[pll_id], RCC_PLL_COMMON_CHANNEL_P, val);
795 
796     /* PLLN */
797     val = FIELD_EX32(reg, PLLCFGR, PLLN);
798     pll_set_vco_multiplier(&s->plls[pll_id], val);
799 }
800 
801 static void rcc_update_pllcfgr(Stm32l4x5RccState *s)
802 {
803     int val;
804 
805     /* Use common layout */
806     rcc_update_pllsaixcfgr(s, RCC_PLL_PLL);
807 
808     /* Fetch specific fields for pllcfgr */
809 
810     /* PLLM */
811     val = FIELD_EX32(s->pllcfgr, PLLCFGR, PLLM);
812     clock_mux_set_factor(&s->clock_muxes[RCC_CLOCK_MUX_PLL_INPUT], 1, (val + 1));
813 
814     /* PLLSRC */
815     val = FIELD_EX32(s->pllcfgr, PLLCFGR, PLLSRC);
816     if (val == 0) {
817         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_PLL_INPUT], false);
818     } else {
819         clock_mux_set_source(&s->clock_muxes[RCC_CLOCK_MUX_PLL_INPUT], val - 1);
820         clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_PLL_INPUT], true);
821     }
822 }
823 
824 static void rcc_update_ccipr(Stm32l4x5RccState *s)
825 {
826     #define CCIPR_SET_SOURCE(_peripheral_name) \
827         clock_mux_set_source(&s->clock_muxes[RCC_CLOCK_MUX_##_peripheral_name], \
828             FIELD_EX32(s->ccipr, CCIPR, _peripheral_name##SEL))
829 
830     CCIPR_SET_SOURCE(DFSDM1);
831     CCIPR_SET_SOURCE(SWPMI1);
832     CCIPR_SET_SOURCE(ADC);
833     CCIPR_SET_SOURCE(CLK48);
834     CCIPR_SET_SOURCE(SAI2);
835     CCIPR_SET_SOURCE(SAI1);
836     CCIPR_SET_SOURCE(LPTIM2);
837     CCIPR_SET_SOURCE(LPTIM1);
838     CCIPR_SET_SOURCE(I2C3);
839     CCIPR_SET_SOURCE(I2C2);
840     CCIPR_SET_SOURCE(I2C1);
841     CCIPR_SET_SOURCE(LPUART1);
842     CCIPR_SET_SOURCE(UART5);
843     CCIPR_SET_SOURCE(UART4);
844     CCIPR_SET_SOURCE(USART3);
845     CCIPR_SET_SOURCE(USART2);
846     CCIPR_SET_SOURCE(USART1);
847 
848     #undef CCIPR_SET_SOURCE
849 }
850 
851 static void rcc_update_bdcr(Stm32l4x5RccState *s)
852 {
853     int val;
854 
855     /* LSCOSEL */
856     val = FIELD_EX32(s->bdcr, BDCR, LSCOSEL);
857     clock_mux_set_source(&s->clock_muxes[RCC_CLOCK_MUX_LSCO], val);
858 
859     val = FIELD_EX32(s->bdcr, BDCR, LSCOEN);
860     clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_LSCO], val);
861 
862     /* BDRST */
863     /*
864      * The documentation is not clear if the RTCEN flag disables the RTC and
865      * the LCD common mux or if it only affects the RTC.
866      * As the LCDEN flag exists, we assume here that it only affects the RTC.
867      */
868     val = FIELD_EX32(s->bdcr, BDCR, RTCEN);
869     clock_mux_set_enable(&s->clock_muxes[RCC_CLOCK_MUX_RTC], val);
870     /* LCD and RTC share the same clock */
871     val = FIELD_EX32(s->bdcr, BDCR, RTCSEL);
872     clock_mux_set_source(&s->clock_muxes[RCC_CLOCK_MUX_LCD_AND_RTC_COMMON], val);
873 
874     /* LSECSSON */
875     /* LSEDRV[1:0] */
876     /* LSEBYP */
877 
878     /* LSEON: Update LSERDY at the same time */
879     val = FIELD_EX32(s->bdcr, BDCR, LSEON);
880     if (val) {
881         clock_update_hz(s->lse_crystal, LSE_FRQ);
882         s->bdcr |= R_BDCR_LSERDY_MASK;
883         if (s->cier & R_CIER_LSERDYIE_MASK) {
884             s->cifr |= R_CIFR_LSERDYF_MASK;
885         }
886     } else {
887         clock_update(s->lse_crystal, 0);
888         s->bdcr &= ~R_BDCR_LSERDY_MASK;
889     }
890 
891     rcc_update_irq(s);
892 }
893 
894 static void rcc_update_csr(Stm32l4x5RccState *s)
895 {
896     int val;
897 
898     /* Reset flags: Not implemented */
899     /* MSISRANGE: Not implemented after reset */
900 
901     /* LSION: Update LSIRDY at the same time */
902     val = FIELD_EX32(s->csr, CSR, LSION);
903     if (val) {
904         clock_update_hz(s->lsi_rc, LSI_FRQ);
905         s->csr |= R_CSR_LSIRDY_MASK;
906         if (s->cier & R_CIER_LSIRDYIE_MASK) {
907             s->cifr |= R_CIFR_LSIRDYF_MASK;
908         }
909     } else {
910         /*
911          * TODO: Handle when the LSI is set independently of LSION.
912          * E.g. when the LSI is set by the RTC.
913          * See the reference manual for more details.
914          */
915         clock_update(s->lsi_rc, 0);
916         s->csr &= ~R_CSR_LSIRDY_MASK;
917     }
918 
919     rcc_update_irq(s);
920 }
921 
922 static void stm32l4x5_rcc_reset_hold(Object *obj, ResetType type)
923 {
924     Stm32l4x5RccState *s = STM32L4X5_RCC(obj);
925     s->cr = 0x00000063;
926     /*
927      * Factory-programmed calibration data
928      * From the reference manual: 0x10XX 00XX
929      * Value taken from a real card.
930      */
931     s->icscr = 0x106E0082;
932     s->cfgr = 0x0;
933     s->pllcfgr = 0x00001000;
934     s->pllsai1cfgr = 0x00001000;
935     s->pllsai2cfgr = 0x00001000;
936     s->cier = 0x0;
937     s->cifr = 0x0;
938     s->ahb1rstr = 0x0;
939     s->ahb2rstr = 0x0;
940     s->ahb3rstr = 0x0;
941     s->apb1rstr1 = 0x0;
942     s->apb1rstr2 = 0x0;
943     s->apb2rstr = 0x0;
944     s->ahb1enr = 0x00000100;
945     s->ahb2enr = 0x0;
946     s->ahb3enr = 0x0;
947     s->apb1enr1 = 0x0;
948     s->apb1enr2 = 0x0;
949     s->apb2enr = 0x0;
950     s->ahb1smenr = 0x00011303;
951     s->ahb2smenr = 0x000532FF;
952     s->ahb3smenr =  0x00000101;
953     s->apb1smenr1 = 0xF2FECA3F;
954     s->apb1smenr2 = 0x00000025;
955     s->apb2smenr = 0x01677C01;
956     s->ccipr = 0x0;
957     s->bdcr = 0x0;
958     s->csr = 0x0C000600;
959 }
960 
961 static uint64_t stm32l4x5_rcc_read(void *opaque, hwaddr addr,
962                                      unsigned int size)
963 {
964     Stm32l4x5RccState *s = opaque;
965     uint64_t retvalue = 0;
966 
967     switch (addr) {
968     case A_CR:
969         retvalue = s->cr;
970         break;
971     case A_ICSCR:
972         retvalue = s->icscr;
973         break;
974     case A_CFGR:
975         retvalue = s->cfgr;
976         break;
977     case A_PLLCFGR:
978         retvalue = s->pllcfgr;
979         break;
980     case A_PLLSAI1CFGR:
981         retvalue = s->pllsai1cfgr;
982         break;
983     case A_PLLSAI2CFGR:
984         retvalue = s->pllsai2cfgr;
985         break;
986     case A_CIER:
987         retvalue = s->cier;
988         break;
989     case A_CIFR:
990         retvalue = s->cifr;
991         break;
992     case A_CICR:
993         /* CICR is write only, return the reset value = 0 */
994         break;
995     case A_AHB1RSTR:
996         retvalue = s->ahb1rstr;
997         break;
998     case A_AHB2RSTR:
999         retvalue = s->ahb2rstr;
1000         break;
1001     case A_AHB3RSTR:
1002         retvalue = s->ahb3rstr;
1003         break;
1004     case A_APB1RSTR1:
1005         retvalue = s->apb1rstr1;
1006         break;
1007     case A_APB1RSTR2:
1008         retvalue = s->apb1rstr2;
1009         break;
1010     case A_APB2RSTR:
1011         retvalue = s->apb2rstr;
1012         break;
1013     case A_AHB1ENR:
1014         retvalue = s->ahb1enr;
1015         break;
1016     case A_AHB2ENR:
1017         retvalue = s->ahb2enr;
1018         break;
1019     case A_AHB3ENR:
1020         retvalue = s->ahb3enr;
1021         break;
1022     case A_APB1ENR1:
1023         retvalue = s->apb1enr1;
1024         break;
1025     case A_APB1ENR2:
1026         retvalue = s->apb1enr2;
1027         break;
1028     case A_APB2ENR:
1029         retvalue = s->apb2enr;
1030         break;
1031     case A_AHB1SMENR:
1032         retvalue = s->ahb1smenr;
1033         break;
1034     case A_AHB2SMENR:
1035         retvalue = s->ahb2smenr;
1036         break;
1037     case A_AHB3SMENR:
1038         retvalue = s->ahb3smenr;
1039         break;
1040     case A_APB1SMENR1:
1041         retvalue = s->apb1smenr1;
1042         break;
1043     case A_APB1SMENR2:
1044         retvalue = s->apb1smenr2;
1045         break;
1046     case A_APB2SMENR:
1047         retvalue = s->apb2smenr;
1048         break;
1049     case A_CCIPR:
1050         retvalue = s->ccipr;
1051         break;
1052     case A_BDCR:
1053         retvalue = s->bdcr;
1054         break;
1055     case A_CSR:
1056         retvalue = s->csr;
1057         break;
1058     default:
1059         qemu_log_mask(LOG_GUEST_ERROR,
1060                       "%s: Bad offset 0x%"HWADDR_PRIx"\n", __func__, addr);
1061         break;
1062     }
1063 
1064     trace_stm32l4x5_rcc_read(addr, retvalue);
1065 
1066     return retvalue;
1067 }
1068 
1069 static void stm32l4x5_rcc_write(void *opaque, hwaddr addr,
1070                                   uint64_t val64, unsigned int size)
1071 {
1072     Stm32l4x5RccState *s = opaque;
1073     uint32_t previous_value = 0;
1074     const uint32_t value = val64;
1075 
1076     trace_stm32l4x5_rcc_write(addr, value);
1077 
1078     switch (addr) {
1079     case A_CR:
1080         previous_value = s->cr;
1081         s->cr = (s->cr & CR_READ_SET_MASK) |
1082                 (value & (CR_READ_SET_MASK | ~CR_READ_ONLY_MASK));
1083         rcc_update_cr_register(s, previous_value);
1084         break;
1085     case A_ICSCR:
1086         s->icscr = value & ~ICSCR_READ_ONLY_MASK;
1087         qemu_log_mask(LOG_UNIMP,
1088                 "%s: Side-effects not implemented for ICSCR\n", __func__);
1089         break;
1090     case A_CFGR:
1091         s->cfgr = value & ~CFGR_READ_ONLY_MASK;
1092         rcc_update_cfgr_register(s);
1093         break;
1094     case A_PLLCFGR:
1095         s->pllcfgr = value;
1096         rcc_update_pllcfgr(s);
1097         break;
1098     case A_PLLSAI1CFGR:
1099         s->pllsai1cfgr = value;
1100         rcc_update_pllsaixcfgr(s, RCC_PLL_PLLSAI1);
1101         break;
1102     case A_PLLSAI2CFGR:
1103         s->pllsai2cfgr = value;
1104         rcc_update_pllsaixcfgr(s, RCC_PLL_PLLSAI2);
1105         break;
1106     case A_CIER:
1107         s->cier = value;
1108         qemu_log_mask(LOG_UNIMP,
1109                 "%s: Side-effects not implemented for CIER\n", __func__);
1110         break;
1111     case A_CIFR:
1112         qemu_log_mask(LOG_GUEST_ERROR,
1113             "%s: Write attempt into read-only register (CIFR) 0x%"PRIx32"\n",
1114             __func__, value);
1115         break;
1116     case A_CICR:
1117         /* Clear interrupt flags by writing a 1 to the CICR register */
1118         s->cifr &= ~value;
1119         rcc_update_irq(s);
1120         break;
1121     /* Reset behaviors are not implemented */
1122     case A_AHB1RSTR:
1123         s->ahb1rstr = value;
1124         qemu_log_mask(LOG_UNIMP,
1125                 "%s: Side-effects not implemented for AHB1RSTR\n", __func__);
1126         break;
1127     case A_AHB2RSTR:
1128         s->ahb2rstr = value;
1129         qemu_log_mask(LOG_UNIMP,
1130                 "%s: Side-effects not implemented for AHB2RSTR\n", __func__);
1131         break;
1132     case A_AHB3RSTR:
1133         s->ahb3rstr = value;
1134         qemu_log_mask(LOG_UNIMP,
1135                 "%s: Side-effects not implemented for AHB3RSTR\n", __func__);
1136         break;
1137     case A_APB1RSTR1:
1138         s->apb1rstr1 = value;
1139         qemu_log_mask(LOG_UNIMP,
1140                 "%s: Side-effects not implemented for APB1RSTR1\n", __func__);
1141         break;
1142     case A_APB1RSTR2:
1143         s->apb1rstr2 = value;
1144         qemu_log_mask(LOG_UNIMP,
1145                 "%s: Side-effects not implemented for APB1RSTR2\n", __func__);
1146         break;
1147     case A_APB2RSTR:
1148         s->apb2rstr = value;
1149         qemu_log_mask(LOG_UNIMP,
1150                 "%s: Side-effects not implemented for APB2RSTR\n", __func__);
1151         break;
1152     case A_AHB1ENR:
1153         s->ahb1enr = value;
1154         rcc_update_ahb1enr(s);
1155         break;
1156     case A_AHB2ENR:
1157         s->ahb2enr = value;
1158         rcc_update_ahb2enr(s);
1159         break;
1160     case A_AHB3ENR:
1161         s->ahb3enr = value;
1162         rcc_update_ahb3enr(s);
1163         break;
1164     case A_APB1ENR1:
1165         s->apb1enr1 = value;
1166         rcc_update_apb1enr(s);
1167         break;
1168     case A_APB1ENR2:
1169         s->apb1enr2 = value;
1170         rcc_update_apb1enr(s);
1171         break;
1172     case A_APB2ENR:
1173         s->apb2enr = (s->apb2enr & APB2ENR_READ_SET_MASK) | value;
1174         rcc_update_apb2enr(s);
1175         break;
1176     /* Behaviors for Sleep and Stop modes are not implemented */
1177     case A_AHB1SMENR:
1178         s->ahb1smenr = value;
1179         qemu_log_mask(LOG_UNIMP,
1180                 "%s: Side-effects not implemented for AHB1SMENR\n", __func__);
1181         break;
1182     case A_AHB2SMENR:
1183         s->ahb2smenr = value;
1184         qemu_log_mask(LOG_UNIMP,
1185                 "%s: Side-effects not implemented for AHB2SMENR\n", __func__);
1186         break;
1187     case A_AHB3SMENR:
1188         s->ahb3smenr = value;
1189         qemu_log_mask(LOG_UNIMP,
1190                 "%s: Side-effects not implemented for AHB3SMENR\n", __func__);
1191         break;
1192     case A_APB1SMENR1:
1193         s->apb1smenr1 = value;
1194         qemu_log_mask(LOG_UNIMP,
1195                 "%s: Side-effects not implemented for APB1SMENR1\n", __func__);
1196         break;
1197     case A_APB1SMENR2:
1198         s->apb1smenr2 = value;
1199         qemu_log_mask(LOG_UNIMP,
1200                 "%s: Side-effects not implemented for APB1SMENR2\n", __func__);
1201         break;
1202     case A_APB2SMENR:
1203         s->apb2smenr = value;
1204         qemu_log_mask(LOG_UNIMP,
1205                 "%s: Side-effects not implemented for APB2SMENR\n", __func__);
1206         break;
1207     case A_CCIPR:
1208         s->ccipr = value;
1209         rcc_update_ccipr(s);
1210         break;
1211     case A_BDCR:
1212         s->bdcr = value & ~BDCR_READ_ONLY_MASK;
1213         rcc_update_bdcr(s);
1214         break;
1215     case A_CSR:
1216         s->csr = value & ~CSR_READ_ONLY_MASK;
1217         rcc_update_csr(s);
1218         break;
1219     default:
1220         qemu_log_mask(LOG_GUEST_ERROR,
1221                       "%s: Bad offset 0x%"HWADDR_PRIx"\n", __func__, addr);
1222     }
1223 }
1224 
1225 static const MemoryRegionOps stm32l4x5_rcc_ops = {
1226     .read = stm32l4x5_rcc_read,
1227     .write = stm32l4x5_rcc_write,
1228     .endianness = DEVICE_NATIVE_ENDIAN,
1229     .valid = {
1230         .max_access_size = 4,
1231         .min_access_size = 4,
1232         .unaligned = false
1233     },
1234     .impl = {
1235         .max_access_size = 4,
1236         .min_access_size = 4,
1237         .unaligned = false
1238     },
1239 };
1240 
1241 static const ClockPortInitArray stm32l4x5_rcc_clocks = {
1242     QDEV_CLOCK_IN(Stm32l4x5RccState, hsi16_rc, NULL, 0),
1243     QDEV_CLOCK_IN(Stm32l4x5RccState, msi_rc, NULL, 0),
1244     QDEV_CLOCK_IN(Stm32l4x5RccState, hse, NULL, 0),
1245     QDEV_CLOCK_IN(Stm32l4x5RccState, lsi_rc, NULL, 0),
1246     QDEV_CLOCK_IN(Stm32l4x5RccState, lse_crystal, NULL, 0),
1247     QDEV_CLOCK_IN(Stm32l4x5RccState, sai1_extclk, NULL, 0),
1248     QDEV_CLOCK_IN(Stm32l4x5RccState, sai2_extclk, NULL, 0),
1249     QDEV_CLOCK_END
1250 };
1251 
1252 
1253 static void stm32l4x5_rcc_init(Object *obj)
1254 {
1255     Stm32l4x5RccState *s = STM32L4X5_RCC(obj);
1256     size_t i;
1257 
1258     sysbus_init_irq(SYS_BUS_DEVICE(obj), &s->irq);
1259 
1260     memory_region_init_io(&s->mmio, obj, &stm32l4x5_rcc_ops, s,
1261                           TYPE_STM32L4X5_RCC, 0x400);
1262     sysbus_init_mmio(SYS_BUS_DEVICE(obj), &s->mmio);
1263 
1264     qdev_init_clocks(DEVICE(s), stm32l4x5_rcc_clocks);
1265 
1266     for (i = 0; i < RCC_NUM_PLL; i++) {
1267         object_initialize_child(obj, PLL_INIT_INFO[i].name,
1268                                 &s->plls[i], TYPE_RCC_PLL);
1269         set_pll_init_info(&s->plls[i], i);
1270     }
1271 
1272     for (i = 0; i < RCC_NUM_CLOCK_MUX; i++) {
1273         char *alias;
1274 
1275         object_initialize_child(obj, CLOCK_MUX_INIT_INFO[i].name,
1276                                 &s->clock_muxes[i],
1277                                 TYPE_RCC_CLOCK_MUX);
1278         set_clock_mux_init_info(&s->clock_muxes[i], i);
1279 
1280         if (!CLOCK_MUX_INIT_INFO[i].hidden) {
1281             /* Expose muxes output as RCC outputs */
1282             alias = g_strdup_printf("%s-out", CLOCK_MUX_INIT_INFO[i].name);
1283             qdev_alias_clock(DEVICE(&s->clock_muxes[i]), "out", DEVICE(obj), alias);
1284             g_free(alias);
1285         }
1286     }
1287 
1288     s->gnd = clock_new(obj, "gnd");
1289 }
1290 
1291 static void connect_mux_sources(Stm32l4x5RccState *s,
1292                                 RccClockMuxState *mux,
1293                                 const RccClockMuxSource *clk_mapping)
1294 {
1295     size_t i;
1296 
1297     Clock * const CLK_SRC_MAPPING[] = {
1298         [RCC_CLOCK_MUX_SRC_GND] = s->gnd,
1299         [RCC_CLOCK_MUX_SRC_HSI] = s->hsi16_rc,
1300         [RCC_CLOCK_MUX_SRC_HSE] = s->hse,
1301         [RCC_CLOCK_MUX_SRC_MSI] = s->msi_rc,
1302         [RCC_CLOCK_MUX_SRC_LSI] = s->lsi_rc,
1303         [RCC_CLOCK_MUX_SRC_LSE] = s->lse_crystal,
1304         [RCC_CLOCK_MUX_SRC_SAI1_EXTCLK] = s->sai1_extclk,
1305         [RCC_CLOCK_MUX_SRC_SAI2_EXTCLK] = s->sai2_extclk,
1306         [RCC_CLOCK_MUX_SRC_PLL] =
1307             s->plls[RCC_PLL_PLL].channels[RCC_PLL_CHANNEL_PLLCLK],
1308         [RCC_CLOCK_MUX_SRC_PLLSAI1] =
1309             s->plls[RCC_PLL_PLLSAI1].channels[RCC_PLLSAI1_CHANNEL_PLLSAI1CLK],
1310         [RCC_CLOCK_MUX_SRC_PLLSAI2] =
1311             s->plls[RCC_PLL_PLLSAI2].channels[RCC_PLLSAI2_CHANNEL_PLLSAI2CLK],
1312         [RCC_CLOCK_MUX_SRC_PLLSAI3] =
1313             s->plls[RCC_PLL_PLL].channels[RCC_PLL_CHANNEL_PLLSAI3CLK],
1314         [RCC_CLOCK_MUX_SRC_PLL48M1] =
1315             s->plls[RCC_PLL_PLL].channels[RCC_PLL_CHANNEL_PLL48M1CLK],
1316         [RCC_CLOCK_MUX_SRC_PLL48M2] =
1317             s->plls[RCC_PLL_PLLSAI1].channels[RCC_PLLSAI1_CHANNEL_PLL48M2CLK],
1318         [RCC_CLOCK_MUX_SRC_PLLADC1] =
1319             s->plls[RCC_PLL_PLLSAI1].channels[RCC_PLLSAI1_CHANNEL_PLLADC1CLK],
1320         [RCC_CLOCK_MUX_SRC_PLLADC2] =
1321             s->plls[RCC_PLL_PLLSAI2] .channels[RCC_PLLSAI2_CHANNEL_PLLADC2CLK],
1322         [RCC_CLOCK_MUX_SRC_SYSCLK] = s->clock_muxes[RCC_CLOCK_MUX_SYSCLK].out,
1323         [RCC_CLOCK_MUX_SRC_HCLK] = s->clock_muxes[RCC_CLOCK_MUX_HCLK].out,
1324         [RCC_CLOCK_MUX_SRC_PCLK1] = s->clock_muxes[RCC_CLOCK_MUX_PCLK1].out,
1325         [RCC_CLOCK_MUX_SRC_PCLK2] = s->clock_muxes[RCC_CLOCK_MUX_PCLK2].out,
1326         [RCC_CLOCK_MUX_SRC_HSE_OVER_32] = s->clock_muxes[RCC_CLOCK_MUX_HSE_OVER_32].out,
1327         [RCC_CLOCK_MUX_SRC_LCD_AND_RTC_COMMON] =
1328             s->clock_muxes[RCC_CLOCK_MUX_LCD_AND_RTC_COMMON].out,
1329     };
1330 
1331     assert(ARRAY_SIZE(CLK_SRC_MAPPING) == RCC_CLOCK_MUX_SRC_NUMBER);
1332 
1333     for (i = 0; i < RCC_NUM_CLOCK_MUX_SRC; i++) {
1334         RccClockMuxSource mapping = clk_mapping[i];
1335         clock_set_source(mux->srcs[i], CLK_SRC_MAPPING[mapping]);
1336     }
1337 }
1338 
1339 
1340 static const VMStateDescription vmstate_stm32l4x5_rcc = {
1341     .name = TYPE_STM32L4X5_RCC,
1342     .version_id = 1,
1343     .minimum_version_id = 1,
1344     .fields = (VMStateField[]) {
1345         VMSTATE_UINT32(cr, Stm32l4x5RccState),
1346         VMSTATE_UINT32(icscr, Stm32l4x5RccState),
1347         VMSTATE_UINT32(cfgr, Stm32l4x5RccState),
1348         VMSTATE_UINT32(pllcfgr, Stm32l4x5RccState),
1349         VMSTATE_UINT32(pllsai1cfgr, Stm32l4x5RccState),
1350         VMSTATE_UINT32(pllsai2cfgr, Stm32l4x5RccState),
1351         VMSTATE_UINT32(cier, Stm32l4x5RccState),
1352         VMSTATE_UINT32(cifr, Stm32l4x5RccState),
1353         VMSTATE_UINT32(ahb1rstr, Stm32l4x5RccState),
1354         VMSTATE_UINT32(ahb2rstr, Stm32l4x5RccState),
1355         VMSTATE_UINT32(ahb3rstr, Stm32l4x5RccState),
1356         VMSTATE_UINT32(apb1rstr1, Stm32l4x5RccState),
1357         VMSTATE_UINT32(apb1rstr2, Stm32l4x5RccState),
1358         VMSTATE_UINT32(apb2rstr, Stm32l4x5RccState),
1359         VMSTATE_UINT32(ahb1enr, Stm32l4x5RccState),
1360         VMSTATE_UINT32(ahb2enr, Stm32l4x5RccState),
1361         VMSTATE_UINT32(ahb3enr, Stm32l4x5RccState),
1362         VMSTATE_UINT32(apb1enr1, Stm32l4x5RccState),
1363         VMSTATE_UINT32(apb1enr2, Stm32l4x5RccState),
1364         VMSTATE_UINT32(apb2enr, Stm32l4x5RccState),
1365         VMSTATE_UINT32(ahb1smenr, Stm32l4x5RccState),
1366         VMSTATE_UINT32(ahb2smenr, Stm32l4x5RccState),
1367         VMSTATE_UINT32(ahb3smenr, Stm32l4x5RccState),
1368         VMSTATE_UINT32(apb1smenr1, Stm32l4x5RccState),
1369         VMSTATE_UINT32(apb1smenr2, Stm32l4x5RccState),
1370         VMSTATE_UINT32(apb2smenr, Stm32l4x5RccState),
1371         VMSTATE_UINT32(ccipr, Stm32l4x5RccState),
1372         VMSTATE_UINT32(bdcr, Stm32l4x5RccState),
1373         VMSTATE_UINT32(csr, Stm32l4x5RccState),
1374         VMSTATE_CLOCK(hsi16_rc, Stm32l4x5RccState),
1375         VMSTATE_CLOCK(msi_rc, Stm32l4x5RccState),
1376         VMSTATE_CLOCK(hse, Stm32l4x5RccState),
1377         VMSTATE_CLOCK(lsi_rc, Stm32l4x5RccState),
1378         VMSTATE_CLOCK(lse_crystal, Stm32l4x5RccState),
1379         VMSTATE_CLOCK(sai1_extclk, Stm32l4x5RccState),
1380         VMSTATE_CLOCK(sai2_extclk, Stm32l4x5RccState),
1381         VMSTATE_END_OF_LIST()
1382     }
1383 };
1384 
1385 
1386 static void stm32l4x5_rcc_realize(DeviceState *dev, Error **errp)
1387 {
1388     Stm32l4x5RccState *s = STM32L4X5_RCC(dev);
1389     size_t i;
1390 
1391     if (s->hse_frequency <  4000000ULL ||
1392         s->hse_frequency > 48000000ULL) {
1393             error_setg(errp,
1394                 "HSE frequency is outside of the allowed [4-48]Mhz range: %" PRIx64 "",
1395                 s->hse_frequency);
1396             return;
1397         }
1398 
1399     for (i = 0; i < RCC_NUM_PLL; i++) {
1400         RccPllState *pll = &s->plls[i];
1401 
1402         clock_set_source(pll->in, s->clock_muxes[RCC_CLOCK_MUX_PLL_INPUT].out);
1403 
1404         if (!qdev_realize(DEVICE(pll), NULL, errp)) {
1405             return;
1406         }
1407     }
1408 
1409     for (i = 0; i < RCC_NUM_CLOCK_MUX; i++) {
1410         RccClockMuxState *clock_mux = &s->clock_muxes[i];
1411 
1412         connect_mux_sources(s, clock_mux, CLOCK_MUX_INIT_INFO[i].src_mapping);
1413 
1414         if (!qdev_realize(DEVICE(clock_mux), NULL, errp)) {
1415             return;
1416         }
1417     }
1418 
1419     /*
1420      * Start clocks after everything is connected
1421      * to propagate the frequencies along the tree.
1422      */
1423     clock_update_hz(s->msi_rc, MSI_DEFAULT_FRQ);
1424     clock_update_hz(s->sai1_extclk, s->sai1_extclk_frequency);
1425     clock_update_hz(s->sai2_extclk, s->sai2_extclk_frequency);
1426     clock_update(s->gnd, 0);
1427 }
1428 
1429 static Property stm32l4x5_rcc_properties[] = {
1430     DEFINE_PROP_UINT64("hse_frequency", Stm32l4x5RccState,
1431         hse_frequency, HSE_DEFAULT_FRQ),
1432     DEFINE_PROP_UINT64("sai1_extclk_frequency", Stm32l4x5RccState,
1433         sai1_extclk_frequency, 0),
1434     DEFINE_PROP_UINT64("sai2_extclk_frequency", Stm32l4x5RccState,
1435         sai2_extclk_frequency, 0),
1436     DEFINE_PROP_END_OF_LIST(),
1437 };
1438 
1439 static void stm32l4x5_rcc_class_init(ObjectClass *klass, void *data)
1440 {
1441     DeviceClass *dc = DEVICE_CLASS(klass);
1442     ResettableClass *rc = RESETTABLE_CLASS(klass);
1443 
1444     assert(ARRAY_SIZE(CLOCK_MUX_INIT_INFO) == RCC_NUM_CLOCK_MUX);
1445 
1446     rc->phases.hold = stm32l4x5_rcc_reset_hold;
1447     device_class_set_props(dc, stm32l4x5_rcc_properties);
1448     dc->realize = stm32l4x5_rcc_realize;
1449     dc->vmsd = &vmstate_stm32l4x5_rcc;
1450 }
1451 
1452 static const TypeInfo stm32l4x5_rcc_types[] = {
1453     {
1454         .name           = TYPE_STM32L4X5_RCC,
1455         .parent         = TYPE_SYS_BUS_DEVICE,
1456         .instance_size  = sizeof(Stm32l4x5RccState),
1457         .instance_init  = stm32l4x5_rcc_init,
1458         .class_init     = stm32l4x5_rcc_class_init,
1459     }, {
1460         .name = TYPE_RCC_CLOCK_MUX,
1461         .parent = TYPE_DEVICE,
1462         .instance_size = sizeof(RccClockMuxState),
1463         .instance_init = clock_mux_init,
1464         .class_init = clock_mux_class_init,
1465     }, {
1466         .name = TYPE_RCC_PLL,
1467         .parent = TYPE_DEVICE,
1468         .instance_size = sizeof(RccPllState),
1469         .instance_init = pll_init,
1470         .class_init = pll_class_init,
1471     }
1472 };
1473 
1474 DEFINE_TYPES(stm32l4x5_rcc_types)
1475