1 /*
2 * Copyright (c) 2019-2021, STMicroelectronics - All Rights Reserved
3 *
4 * SPDX-License-Identifier: BSD-3-Clause
5 */
6 #include <assert.h>
7 #include <stdint.h>
8
9 #include <platform_def.h>
10
11 #include <drivers/clk.h>
12 #include <drivers/scmi-msg.h>
13 #include <drivers/scmi.h>
14 #include <drivers/st/stm32mp1_clk.h>
15 #include <drivers/st/stm32mp_reset.h>
16 #include <dt-bindings/clock/stm32mp1-clks.h>
17 #include <dt-bindings/reset/stm32mp1-resets.h>
18
19 #define TIMEOUT_US_1MS 1000U
20
21 #define SCMI_CLOCK_NAME_SIZE 16U
22 #define SCMI_RSTD_NAME_SIZE 16U
23
24 /*
25 * struct stm32_scmi_clk - Data for the exposed clock
26 * @clock_id: Clock identifier in RCC clock driver
27 * @name: Clock string ID exposed to agent
28 * @enabled: State of the SCMI clock
29 */
30 struct stm32_scmi_clk {
31 unsigned long clock_id;
32 const char *name;
33 bool enabled;
34 };
35
36 /*
37 * struct stm32_scmi_rstd - Data for the exposed reset controller
38 * @reset_id: Reset identifier in RCC reset driver
39 * @name: Reset string ID exposed to agent
40 */
41 struct stm32_scmi_rstd {
42 unsigned long reset_id;
43 const char *name;
44 };
45
46 /* Locate all non-secure SMT message buffers in last page of SYSRAM */
47 #define SMT_BUFFER_BASE STM32MP_SCMI_NS_SHM_BASE
48 #define SMT_BUFFER0_BASE SMT_BUFFER_BASE
49 #define SMT_BUFFER1_BASE (SMT_BUFFER_BASE + 0x200)
50
51 CASSERT((STM32MP_SCMI_NS_SHM_BASE + STM32MP_SCMI_NS_SHM_SIZE) >=
52 (SMT_BUFFER1_BASE + SMT_BUF_SLOT_SIZE),
53 assert_scmi_non_secure_shm_fits_scmi_overall_buffer_size);
54
55 static struct scmi_msg_channel scmi_channel[] = {
56 [0] = {
57 .shm_addr = SMT_BUFFER0_BASE,
58 .shm_size = SMT_BUF_SLOT_SIZE,
59 },
60 [1] = {
61 .shm_addr = SMT_BUFFER1_BASE,
62 .shm_size = SMT_BUF_SLOT_SIZE,
63 },
64 };
65
plat_scmi_get_channel(unsigned int agent_id)66 struct scmi_msg_channel *plat_scmi_get_channel(unsigned int agent_id)
67 {
68 assert(agent_id < ARRAY_SIZE(scmi_channel));
69
70 return &scmi_channel[agent_id];
71 }
72
73 #define CLOCK_CELL(_scmi_id, _id, _name, _init_enabled) \
74 [_scmi_id] = { \
75 .clock_id = _id, \
76 .name = _name, \
77 .enabled = _init_enabled, \
78 }
79
80 static struct stm32_scmi_clk stm32_scmi0_clock[] = {
81 CLOCK_CELL(CK_SCMI0_HSE, CK_HSE, "ck_hse", true),
82 CLOCK_CELL(CK_SCMI0_HSI, CK_HSI, "ck_hsi", true),
83 CLOCK_CELL(CK_SCMI0_CSI, CK_CSI, "ck_csi", true),
84 CLOCK_CELL(CK_SCMI0_LSE, CK_LSE, "ck_lse", true),
85 CLOCK_CELL(CK_SCMI0_LSI, CK_LSI, "ck_lsi", true),
86 CLOCK_CELL(CK_SCMI0_PLL2_Q, PLL2_Q, "pll2_q", true),
87 CLOCK_CELL(CK_SCMI0_PLL2_R, PLL2_R, "pll2_r", true),
88 CLOCK_CELL(CK_SCMI0_MPU, CK_MPU, "ck_mpu", true),
89 CLOCK_CELL(CK_SCMI0_AXI, CK_AXI, "ck_axi", true),
90 CLOCK_CELL(CK_SCMI0_BSEC, BSEC, "bsec", true),
91 CLOCK_CELL(CK_SCMI0_CRYP1, CRYP1, "cryp1", false),
92 CLOCK_CELL(CK_SCMI0_GPIOZ, GPIOZ, "gpioz", false),
93 CLOCK_CELL(CK_SCMI0_HASH1, HASH1, "hash1", false),
94 CLOCK_CELL(CK_SCMI0_I2C4, I2C4_K, "i2c4_k", false),
95 CLOCK_CELL(CK_SCMI0_I2C6, I2C6_K, "i2c6_k", false),
96 CLOCK_CELL(CK_SCMI0_IWDG1, IWDG1, "iwdg1", false),
97 CLOCK_CELL(CK_SCMI0_RNG1, RNG1_K, "rng1_k", true),
98 CLOCK_CELL(CK_SCMI0_RTC, RTC, "ck_rtc", true),
99 CLOCK_CELL(CK_SCMI0_RTCAPB, RTCAPB, "rtcapb", true),
100 CLOCK_CELL(CK_SCMI0_SPI6, SPI6_K, "spi6_k", false),
101 CLOCK_CELL(CK_SCMI0_USART1, USART1_K, "usart1_k", false),
102 };
103
104 static struct stm32_scmi_clk stm32_scmi1_clock[] = {
105 CLOCK_CELL(CK_SCMI1_PLL3_Q, PLL3_Q, "pll3_q", true),
106 CLOCK_CELL(CK_SCMI1_PLL3_R, PLL3_R, "pll3_r", true),
107 CLOCK_CELL(CK_SCMI1_MCU, CK_MCU, "ck_mcu", false),
108 };
109
110 #define RESET_CELL(_scmi_id, _id, _name) \
111 [_scmi_id] = { \
112 .reset_id = _id, \
113 .name = _name, \
114 }
115
116 static struct stm32_scmi_rstd stm32_scmi0_reset_domain[] = {
117 RESET_CELL(RST_SCMI0_SPI6, SPI6_R, "spi6"),
118 RESET_CELL(RST_SCMI0_I2C4, I2C4_R, "i2c4"),
119 RESET_CELL(RST_SCMI0_I2C6, I2C6_R, "i2c6"),
120 RESET_CELL(RST_SCMI0_USART1, USART1_R, "usart1"),
121 RESET_CELL(RST_SCMI0_STGEN, STGEN_R, "stgen"),
122 RESET_CELL(RST_SCMI0_GPIOZ, GPIOZ_R, "gpioz"),
123 RESET_CELL(RST_SCMI0_CRYP1, CRYP1_R, "cryp1"),
124 RESET_CELL(RST_SCMI0_HASH1, HASH1_R, "hash1"),
125 RESET_CELL(RST_SCMI0_RNG1, RNG1_R, "rng1"),
126 RESET_CELL(RST_SCMI0_MDMA, MDMA_R, "mdma"),
127 RESET_CELL(RST_SCMI0_MCU, MCU_R, "mcu"),
128 };
129
130 struct scmi_agent_resources {
131 struct stm32_scmi_clk *clock;
132 size_t clock_count;
133 struct stm32_scmi_rstd *rstd;
134 size_t rstd_count;
135 };
136
137 static const struct scmi_agent_resources agent_resources[] = {
138 [0] = {
139 .clock = stm32_scmi0_clock,
140 .clock_count = ARRAY_SIZE(stm32_scmi0_clock),
141 .rstd = stm32_scmi0_reset_domain,
142 .rstd_count = ARRAY_SIZE(stm32_scmi0_reset_domain),
143 },
144 [1] = {
145 .clock = stm32_scmi1_clock,
146 .clock_count = ARRAY_SIZE(stm32_scmi1_clock),
147 },
148 };
149
find_resource(unsigned int agent_id)150 static const struct scmi_agent_resources *find_resource(unsigned int agent_id)
151 {
152 assert(agent_id < ARRAY_SIZE(agent_resources));
153
154 return &agent_resources[agent_id];
155 }
156
157 #if ENABLE_ASSERTIONS
plat_scmi_protocol_count_paranoid(void)158 static size_t plat_scmi_protocol_count_paranoid(void)
159 {
160 unsigned int n = 0U;
161 unsigned int count = 0U;
162
163 for (n = 0U; n < ARRAY_SIZE(agent_resources); n++) {
164 if (agent_resources[n].clock_count) {
165 count++;
166 break;
167 }
168 }
169
170 for (n = 0U; n < ARRAY_SIZE(agent_resources); n++) {
171 if (agent_resources[n].rstd_count) {
172 count++;
173 break;
174 }
175 }
176
177 return count;
178 }
179 #endif
180
181 static const char vendor[] = "ST";
182 static const char sub_vendor[] = "";
183
plat_scmi_vendor_name(void)184 const char *plat_scmi_vendor_name(void)
185 {
186 return vendor;
187 }
188
plat_scmi_sub_vendor_name(void)189 const char *plat_scmi_sub_vendor_name(void)
190 {
191 return sub_vendor;
192 }
193
194 /* Currently supporting Clocks and Reset Domains */
195 static const uint8_t plat_protocol_list[] = {
196 SCMI_PROTOCOL_ID_CLOCK,
197 SCMI_PROTOCOL_ID_RESET_DOMAIN,
198 0U /* Null termination */
199 };
200
plat_scmi_protocol_count(void)201 size_t plat_scmi_protocol_count(void)
202 {
203 const size_t count = ARRAY_SIZE(plat_protocol_list) - 1U;
204
205 assert(count == plat_scmi_protocol_count_paranoid());
206
207 return count;
208 }
209
plat_scmi_protocol_list(unsigned int agent_id __unused)210 const uint8_t *plat_scmi_protocol_list(unsigned int agent_id __unused)
211 {
212 assert(plat_scmi_protocol_count_paranoid() ==
213 (ARRAY_SIZE(plat_protocol_list) - 1U));
214
215 return plat_protocol_list;
216 }
217
218 /*
219 * Platform SCMI clocks
220 */
find_clock(unsigned int agent_id,unsigned int scmi_id)221 static struct stm32_scmi_clk *find_clock(unsigned int agent_id,
222 unsigned int scmi_id)
223 {
224 const struct scmi_agent_resources *resource = find_resource(agent_id);
225 size_t n = 0U;
226
227 if (resource != NULL) {
228 for (n = 0U; n < resource->clock_count; n++) {
229 if (n == scmi_id) {
230 return &resource->clock[n];
231 }
232 }
233 }
234
235 return NULL;
236 }
237
plat_scmi_clock_count(unsigned int agent_id)238 size_t plat_scmi_clock_count(unsigned int agent_id)
239 {
240 const struct scmi_agent_resources *resource = find_resource(agent_id);
241
242 if (resource == NULL) {
243 return 0U;
244 }
245
246 return resource->clock_count;
247 }
248
plat_scmi_clock_get_name(unsigned int agent_id,unsigned int scmi_id)249 const char *plat_scmi_clock_get_name(unsigned int agent_id,
250 unsigned int scmi_id)
251 {
252 struct stm32_scmi_clk *clock = find_clock(agent_id, scmi_id);
253
254 if ((clock == NULL) ||
255 !stm32mp_nsec_can_access_clock(clock->clock_id)) {
256 return NULL;
257 }
258
259 return clock->name;
260 }
261
plat_scmi_clock_rates_array(unsigned int agent_id,unsigned int scmi_id,unsigned long * array,size_t * nb_elts)262 int32_t plat_scmi_clock_rates_array(unsigned int agent_id, unsigned int scmi_id,
263 unsigned long *array, size_t *nb_elts)
264 {
265 struct stm32_scmi_clk *clock = find_clock(agent_id, scmi_id);
266
267 if (clock == NULL) {
268 return SCMI_NOT_FOUND;
269 }
270
271 if (!stm32mp_nsec_can_access_clock(clock->clock_id)) {
272 return SCMI_DENIED;
273 }
274
275 if (array == NULL) {
276 *nb_elts = 1U;
277 } else if (*nb_elts == 1U) {
278 *array = clk_get_rate(clock->clock_id);
279 } else {
280 return SCMI_GENERIC_ERROR;
281 }
282
283 return SCMI_SUCCESS;
284 }
285
plat_scmi_clock_get_rate(unsigned int agent_id,unsigned int scmi_id)286 unsigned long plat_scmi_clock_get_rate(unsigned int agent_id,
287 unsigned int scmi_id)
288 {
289 struct stm32_scmi_clk *clock = find_clock(agent_id, scmi_id);
290
291 if ((clock == NULL) ||
292 !stm32mp_nsec_can_access_clock(clock->clock_id)) {
293 return 0U;
294 }
295
296 return clk_get_rate(clock->clock_id);
297 }
298
plat_scmi_clock_get_state(unsigned int agent_id,unsigned int scmi_id)299 int32_t plat_scmi_clock_get_state(unsigned int agent_id, unsigned int scmi_id)
300 {
301 struct stm32_scmi_clk *clock = find_clock(agent_id, scmi_id);
302
303 if ((clock == NULL) ||
304 !stm32mp_nsec_can_access_clock(clock->clock_id)) {
305 return 0U;
306 }
307
308 return (int32_t)clock->enabled;
309 }
310
plat_scmi_clock_set_state(unsigned int agent_id,unsigned int scmi_id,bool enable_not_disable)311 int32_t plat_scmi_clock_set_state(unsigned int agent_id, unsigned int scmi_id,
312 bool enable_not_disable)
313 {
314 struct stm32_scmi_clk *clock = find_clock(agent_id, scmi_id);
315
316 if (clock == NULL) {
317 return SCMI_NOT_FOUND;
318 }
319
320 if (!stm32mp_nsec_can_access_clock(clock->clock_id)) {
321 return SCMI_DENIED;
322 }
323
324 if (enable_not_disable) {
325 if (!clock->enabled) {
326 VERBOSE("SCMI clock %u enable\n", scmi_id);
327 clk_enable(clock->clock_id);
328 clock->enabled = true;
329 }
330 } else {
331 if (clock->enabled) {
332 VERBOSE("SCMI clock %u disable\n", scmi_id);
333 clk_disable(clock->clock_id);
334 clock->enabled = false;
335 }
336 }
337
338 return SCMI_SUCCESS;
339 }
340
341 /*
342 * Platform SCMI reset domains
343 */
find_rstd(unsigned int agent_id,unsigned int scmi_id)344 static struct stm32_scmi_rstd *find_rstd(unsigned int agent_id,
345 unsigned int scmi_id)
346 {
347 const struct scmi_agent_resources *resource = find_resource(agent_id);
348 size_t n;
349
350 if (resource != NULL) {
351 for (n = 0U; n < resource->rstd_count; n++) {
352 if (n == scmi_id) {
353 return &resource->rstd[n];
354 }
355 }
356 }
357
358 return NULL;
359 }
360
plat_scmi_rstd_get_name(unsigned int agent_id,unsigned int scmi_id)361 const char *plat_scmi_rstd_get_name(unsigned int agent_id, unsigned int scmi_id)
362 {
363 const struct stm32_scmi_rstd *rstd = find_rstd(agent_id, scmi_id);
364
365 if (rstd == NULL) {
366 return NULL;
367 }
368
369 return rstd->name;
370 }
371
plat_scmi_rstd_count(unsigned int agent_id)372 size_t plat_scmi_rstd_count(unsigned int agent_id)
373 {
374 const struct scmi_agent_resources *resource = find_resource(agent_id);
375
376 if (resource == NULL) {
377 return 0U;
378 }
379
380 return resource->rstd_count;
381 }
382
plat_scmi_rstd_autonomous(unsigned int agent_id,unsigned int scmi_id,uint32_t state)383 int32_t plat_scmi_rstd_autonomous(unsigned int agent_id, unsigned int scmi_id,
384 uint32_t state)
385 {
386 const struct stm32_scmi_rstd *rstd = find_rstd(agent_id, scmi_id);
387
388 if (rstd == NULL) {
389 return SCMI_NOT_FOUND;
390 }
391
392 if (!stm32mp_nsec_can_access_reset(rstd->reset_id)) {
393 return SCMI_DENIED;
394 }
395
396 /* Supports only reset with context loss */
397 if (state != 0U) {
398 return SCMI_NOT_SUPPORTED;
399 }
400
401 VERBOSE("SCMI reset %lu cycle\n", rstd->reset_id);
402
403 if (stm32mp_reset_assert(rstd->reset_id, TIMEOUT_US_1MS)) {
404 return SCMI_HARDWARE_ERROR;
405 }
406
407 if (stm32mp_reset_deassert(rstd->reset_id, TIMEOUT_US_1MS)) {
408 return SCMI_HARDWARE_ERROR;
409 }
410
411 return SCMI_SUCCESS;
412 }
413
plat_scmi_rstd_set_state(unsigned int agent_id,unsigned int scmi_id,bool assert_not_deassert)414 int32_t plat_scmi_rstd_set_state(unsigned int agent_id, unsigned int scmi_id,
415 bool assert_not_deassert)
416 {
417 const struct stm32_scmi_rstd *rstd = find_rstd(agent_id, scmi_id);
418
419 if (rstd == NULL) {
420 return SCMI_NOT_FOUND;
421 }
422
423 if (!stm32mp_nsec_can_access_reset(rstd->reset_id)) {
424 return SCMI_DENIED;
425 }
426
427 if (assert_not_deassert) {
428 VERBOSE("SCMI reset %lu set\n", rstd->reset_id);
429 stm32mp_reset_set(rstd->reset_id);
430 } else {
431 VERBOSE("SCMI reset %lu release\n", rstd->reset_id);
432 stm32mp_reset_release(rstd->reset_id);
433 }
434
435 return SCMI_SUCCESS;
436 }
437
438 /*
439 * Initialize platform SCMI resources
440 */
stm32mp1_init_scmi_server(void)441 void stm32mp1_init_scmi_server(void)
442 {
443 size_t i;
444
445 for (i = 0U; i < ARRAY_SIZE(scmi_channel); i++) {
446 scmi_smt_init_agent_channel(&scmi_channel[i]);
447 }
448
449 for (i = 0U; i < ARRAY_SIZE(agent_resources); i++) {
450 const struct scmi_agent_resources *res = &agent_resources[i];
451 size_t j;
452
453 for (j = 0U; j < res->clock_count; j++) {
454 struct stm32_scmi_clk *clk = &res->clock[j];
455
456 if ((clk->name == NULL) ||
457 (strlen(clk->name) >= SCMI_CLOCK_NAME_SIZE)) {
458 ERROR("Invalid SCMI clock name\n");
459 panic();
460 }
461
462 /* Sync SCMI clocks with their targeted initial state */
463 if (clk->enabled &&
464 stm32mp_nsec_can_access_clock(clk->clock_id)) {
465 clk_enable(clk->clock_id);
466 }
467 }
468
469 for (j = 0U; j < res->rstd_count; j++) {
470 struct stm32_scmi_rstd *rstd = &res->rstd[j];
471
472 if ((rstd->name == NULL) ||
473 (strlen(rstd->name) >= SCMI_RSTD_NAME_SIZE)) {
474 ERROR("Invalid SCMI reset domain name\n");
475 panic();
476 }
477 }
478 }
479 }
480