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git01.mediatek.com / filogic / atf / 6ec902f968eaac0ebaedfb9b77dba6247642e78e / . / plat / mediatek / mt8173 / drivers / spm / spm.c
blob: 75eb61a05cf5d3d8268c7248dc0f5afd965692a9 [file] [log] [blame]
developer65014b82015-04-13 14:47:57 +0800[diff] [blame]1/*
2 * Copyright (c) 2015, ARM Limited and Contributors. All rights reserved.
3 *
4 * Redistribution and use in source and binary forms, with or without
5 * modification, are permitted provided that the following conditions are met:
6 *
7 * Redistributions of source code must retain the above copyright notice, this
8 * list of conditions and the following disclaimer.
9 *
10 * Redistributions in binary form must reproduce the above copyright notice,
11 * this list of conditions and the following disclaimer in the documentation
12 * and/or other materials provided with the distribution.
13 *
14 * Neither the name of ARM nor the names of its contributors may be used
15 * to endorse or promote products derived from this software without specific
16 * prior written permission.
17 *
18 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
19 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
20 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
21 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
22 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
23 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
24 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
25 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
26 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
27 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
28 * POSSIBILITY OF SUCH DAMAGE.
29 */
30#include <bakery_lock.h>
31#include <debug.h>
32#include <mmio.h>
33#include <mt8173_def.h>
34#include <spm.h>
35#include <spm_suspend.h>
36
37/*
38 * System Power Manager (SPM) is a hardware module, which controls cpu or
39 * system power for different power scenarios using different firmware, i.e.,
40 * - spm_hotplug.c for cpu power control in cpu hotplug flow.
41 * - spm_mcdi.c for cpu power control in cpu idle power saving state.
42 * - spm_suspend.c for system power control in system suspend scenario.
43 *
44 * This file provide utility functions common to hotplug, mcdi(idle), suspend
45 * power scenarios. A bakery lock (software lock) is incoporated to protect
46 * certain critical sections to avoid kicking different SPM firmware
47 * concurrently.
48 */
49
50#define SPM_SYSCLK_SETTLE 128 /* 3.9ms */
51
Vikram Kanigiri7014b032015-09-09 10:53:05 +0100[diff] [blame]52DEFINE_BAKERY_LOCK(spm_lock);
53
Soren Brinkmann46dd1702016-01-14 10:11:05 -0800[diff] [blame]54static int spm_hotplug_ready __section("tzfw_coherent_mem");
55static int spm_mcdi_ready __section("tzfw_coherent_mem");
56static int spm_suspend_ready __section("tzfw_coherent_mem");
developer65014b82015-04-13 14:47:57 +0800[diff] [blame]57
58void spm_lock_init(void)
59{
60 bakery_lock_init(&spm_lock);
61}
62
63void spm_lock_get(void)
64{
65 bakery_lock_get(&spm_lock);
66}
67
68void spm_lock_release(void)
69{
70 bakery_lock_release(&spm_lock);
71}
72
73int is_mcdi_ready(void)
74{
75 return spm_mcdi_ready;
76}
77
78int is_hotplug_ready(void)
79{
80 return spm_hotplug_ready;
81}
82
83int is_suspend_ready(void)
84{
85 return spm_suspend_ready;
86}
87
88void set_mcdi_ready(void)
89{
90 spm_mcdi_ready = 1;
91 spm_hotplug_ready = 0;
92 spm_suspend_ready = 0;
93}
94
95void set_hotplug_ready(void)
96{
97 spm_mcdi_ready = 0;
98 spm_hotplug_ready = 1;
99 spm_suspend_ready = 0;
100}
101
102void set_suspend_ready(void)
103{
104 spm_mcdi_ready = 0;
105 spm_hotplug_ready = 0;
106 spm_suspend_ready = 1;
107}
108
109void clear_all_ready(void)
110{
111 spm_mcdi_ready = 0;
112 spm_hotplug_ready = 0;
113 spm_suspend_ready = 0;
114}
115
116void spm_register_init(void)
117{
118 mmio_write_32(SPM_POWERON_CONFIG_SET, SPM_REGWR_CFG_KEY | SPM_REGWR_EN);
119
120 mmio_write_32(SPM_POWER_ON_VAL0, 0);
121 mmio_write_32(SPM_POWER_ON_VAL1, POWER_ON_VAL1_DEF);
122 mmio_write_32(SPM_PCM_PWR_IO_EN, 0);
123
124 mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY | CON0_PCM_SW_RESET);
125 mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY);
126 if (mmio_read_32(SPM_PCM_FSM_STA) != PCM_FSM_STA_DEF)
127 WARN("PCM reset failed\n");
128
129 mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY | CON0_IM_SLEEP_DVS);
130 mmio_write_32(SPM_PCM_CON1, CON1_CFG_KEY | CON1_EVENT_LOCK_EN |
131 CON1_SPM_SRAM_ISO_B | CON1_SPM_SRAM_SLP_B | CON1_MIF_APBEN);
132 mmio_write_32(SPM_PCM_IM_PTR, 0);
133 mmio_write_32(SPM_PCM_IM_LEN, 0);
134
135 mmio_write_32(SPM_CLK_CON, CC_SYSCLK0_EN_1 | CC_SYSCLK0_EN_0 |
136 CC_SYSCLK1_EN_0 | CC_SRCLKENA_MASK_0 | CC_CLKSQ1_SEL |
137 CC_CXO32K_RM_EN_MD2 | CC_CXO32K_RM_EN_MD1 | CC_MD32_DCM_EN);
138
139 mmio_write_32(SPM_SLEEP_ISR_MASK, 0xff0c);
140 mmio_write_32(SPM_SLEEP_ISR_STATUS, 0xc);
141 mmio_write_32(SPM_PCM_SW_INT_CLEAR, 0xff);
142 mmio_write_32(SPM_MD32_SRAM_CON, 0xff0);
143}
144
145void spm_reset_and_init_pcm(void)
146{
147 unsigned int con1;
148 int i = 0;
149
150 mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY | CON0_PCM_SW_RESET);
151 mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY);
152 while (mmio_read_32(SPM_PCM_FSM_STA) != PCM_FSM_STA_DEF) {
153 i++;
154 if (i > 1000) {
155 i = 0;
156 WARN("PCM reset failed\n");
157 break;
158 }
159 }
160
161 mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY | CON0_IM_SLEEP_DVS);
162
163 con1 = mmio_read_32(SPM_PCM_CON1) &
164 (CON1_PCM_WDT_WAKE_MODE | CON1_PCM_WDT_EN);
165 mmio_write_32(SPM_PCM_CON1, con1 | CON1_CFG_KEY | CON1_EVENT_LOCK_EN |
166 CON1_SPM_SRAM_ISO_B | CON1_SPM_SRAM_SLP_B |
167 CON1_IM_NONRP_EN | CON1_MIF_APBEN);
168}
169
170void spm_init_pcm_register(void)
171{
172 mmio_write_32(SPM_PCM_REG_DATA_INI, mmio_read_32(SPM_POWER_ON_VAL0));
173 mmio_write_32(SPM_PCM_PWR_IO_EN, PCM_RF_SYNC_R0);
174 mmio_write_32(SPM_PCM_PWR_IO_EN, 0);
175
176 mmio_write_32(SPM_PCM_REG_DATA_INI, mmio_read_32(SPM_POWER_ON_VAL1));
177 mmio_write_32(SPM_PCM_PWR_IO_EN, PCM_RF_SYNC_R7);
178 mmio_write_32(SPM_PCM_PWR_IO_EN, 0);
179}
180
181void spm_set_power_control(const struct pwr_ctrl *pwrctrl)
182{
183 mmio_write_32(SPM_AP_STANBY_CON, (!pwrctrl->md32_req_mask << 21) |
184 (!pwrctrl->mfg_req_mask << 17) |
185 (!pwrctrl->disp_req_mask << 16) |
186 (!!pwrctrl->mcusys_idle_mask << 7) |
187 (!!pwrctrl->ca15top_idle_mask << 6) |
188 (!!pwrctrl->ca7top_idle_mask << 5) |
189 (!!pwrctrl->wfi_op << 4));
190 mmio_write_32(SPM_PCM_SRC_REQ, (!!pwrctrl->pcm_apsrc_req << 0));
191 mmio_write_32(SPM_PCM_PASR_DPD_2, 0);
192
193 mmio_clrsetbits_32(SPM_CLK_CON, CC_SRCLKENA_MASK_0,
194 (pwrctrl->srclkenai_mask ? CC_SRCLKENA_MASK_0 : 0));
195
196 mmio_write_32(SPM_SLEEP_CA15_WFI0_EN, !!pwrctrl->ca15_wfi0_en);
197 mmio_write_32(SPM_SLEEP_CA15_WFI1_EN, !!pwrctrl->ca15_wfi1_en);
198 mmio_write_32(SPM_SLEEP_CA15_WFI2_EN, !!pwrctrl->ca15_wfi2_en);
199 mmio_write_32(SPM_SLEEP_CA15_WFI3_EN, !!pwrctrl->ca15_wfi3_en);
200 mmio_write_32(SPM_SLEEP_CA7_WFI0_EN, !!pwrctrl->ca7_wfi0_en);
201 mmio_write_32(SPM_SLEEP_CA7_WFI1_EN, !!pwrctrl->ca7_wfi1_en);
202 mmio_write_32(SPM_SLEEP_CA7_WFI2_EN, !!pwrctrl->ca7_wfi2_en);
203 mmio_write_32(SPM_SLEEP_CA7_WFI3_EN, !!pwrctrl->ca7_wfi3_en);
204}
205
206void spm_set_wakeup_event(const struct pwr_ctrl *pwrctrl)
207{
208 unsigned int val, mask;
209
210 if (pwrctrl->timer_val_cust == 0)
211 val = pwrctrl->timer_val ? pwrctrl->timer_val : PCM_TIMER_MAX;
212 else
213 val = pwrctrl->timer_val_cust;
214
215 mmio_write_32(SPM_PCM_TIMER_VAL, val);
216 mmio_setbits_32(SPM_PCM_CON1, CON1_CFG_KEY);
217
218 if (pwrctrl->wake_src_cust == 0)
219 mask = pwrctrl->wake_src;
220 else
221 mask = pwrctrl->wake_src_cust;
222
223 if (pwrctrl->syspwreq_mask)
224 mask &= ~WAKE_SRC_SYSPWREQ;
225
226 mmio_write_32(SPM_SLEEP_WAKEUP_EVENT_MASK, ~mask);
227 mmio_write_32(SPM_SLEEP_ISR_MASK, 0xfe04);
228}
229
230void spm_get_wakeup_status(struct wake_status *wakesta)
231{
232 wakesta->assert_pc = mmio_read_32(SPM_PCM_REG_DATA_INI);
233 wakesta->r12 = mmio_read_32(SPM_PCM_REG12_DATA);
234 wakesta->raw_sta = mmio_read_32(SPM_SLEEP_ISR_RAW_STA);
235 wakesta->wake_misc = mmio_read_32(SPM_SLEEP_WAKEUP_MISC);
236 wakesta->timer_out = mmio_read_32(SPM_PCM_TIMER_OUT);
237 wakesta->r13 = mmio_read_32(SPM_PCM_REG13_DATA);
238 wakesta->idle_sta = mmio_read_32(SPM_SLEEP_SUBSYS_IDLE_STA);
239 wakesta->debug_flag = mmio_read_32(SPM_PCM_PASR_DPD_3);
240 wakesta->event_reg = mmio_read_32(SPM_PCM_EVENT_REG_STA);
241 wakesta->isr = mmio_read_32(SPM_SLEEP_ISR_STATUS);
242}
243
244void spm_init_event_vector(const struct pcm_desc *pcmdesc)
245{
246 /* init event vector register */
247 mmio_write_32(SPM_PCM_EVENT_VECTOR0, pcmdesc->vec0);
248 mmio_write_32(SPM_PCM_EVENT_VECTOR1, pcmdesc->vec1);
249 mmio_write_32(SPM_PCM_EVENT_VECTOR2, pcmdesc->vec2);
250 mmio_write_32(SPM_PCM_EVENT_VECTOR3, pcmdesc->vec3);
251 mmio_write_32(SPM_PCM_EVENT_VECTOR4, pcmdesc->vec4);
252 mmio_write_32(SPM_PCM_EVENT_VECTOR5, pcmdesc->vec5);
253 mmio_write_32(SPM_PCM_EVENT_VECTOR6, pcmdesc->vec6);
254 mmio_write_32(SPM_PCM_EVENT_VECTOR7, pcmdesc->vec7);
255
256 /* event vector will be enabled by PCM itself */
257}
258
259void spm_kick_im_to_fetch(const struct pcm_desc *pcmdesc)
260{
261 unsigned int ptr = 0, len, con0;
262
263 ptr = (unsigned int)(unsigned long)(pcmdesc->base);
264 len = pcmdesc->size - 1;
265 if (mmio_read_32(SPM_PCM_IM_PTR) != ptr ||
266 mmio_read_32(SPM_PCM_IM_LEN) != len ||
267 pcmdesc->sess > 2) {
268 mmio_write_32(SPM_PCM_IM_PTR, ptr);
269 mmio_write_32(SPM_PCM_IM_LEN, len);
270 } else {
271 mmio_setbits_32(SPM_PCM_CON1, CON1_CFG_KEY | CON1_IM_SLAVE);
272 }
273
274 /* kick IM to fetch (only toggle IM_KICK) */
275 con0 = mmio_read_32(SPM_PCM_CON0) & ~(CON0_IM_KICK | CON0_PCM_KICK);
276 mmio_write_32(SPM_PCM_CON0, con0 | CON0_CFG_KEY | CON0_IM_KICK);
277 mmio_write_32(SPM_PCM_CON0, con0 | CON0_CFG_KEY);
278
279 /* kick IM to fetch (only toggle PCM_KICK) */
280 con0 = mmio_read_32(SPM_PCM_CON0) & ~(CON0_IM_KICK | CON0_PCM_KICK);
281 mmio_write_32(SPM_PCM_CON0, con0 | CON0_CFG_KEY | CON0_PCM_KICK);
282 mmio_write_32(SPM_PCM_CON0, con0 | CON0_CFG_KEY);
283}
284
285void spm_set_sysclk_settle(void)
286{
287 mmio_write_32(SPM_CLK_SETTLE, SPM_SYSCLK_SETTLE);
288
289 INFO("settle = %u\n", mmio_read_32(SPM_CLK_SETTLE));
290}
291
292void spm_kick_pcm_to_run(struct pwr_ctrl *pwrctrl)
293{
294 unsigned int con1;
295
296 con1 = mmio_read_32(SPM_PCM_CON1) &
297 ~(CON1_PCM_WDT_WAKE_MODE | CON1_PCM_WDT_EN);
298
299 mmio_write_32(SPM_PCM_CON1, CON1_CFG_KEY | con1);
300
301 if (mmio_read_32(SPM_PCM_TIMER_VAL) > PCM_TIMER_MAX)
302 mmio_write_32(SPM_PCM_TIMER_VAL, PCM_TIMER_MAX);
303
304 mmio_write_32(SPM_PCM_WDT_TIMER_VAL,
305 mmio_read_32(SPM_PCM_TIMER_VAL) + PCM_WDT_TIMEOUT);
306
307 mmio_write_32(SPM_PCM_CON1, con1 | CON1_CFG_KEY | CON1_PCM_WDT_EN);
308 mmio_write_32(SPM_PCM_PASR_DPD_0, 0);
309
310 mmio_write_32(SPM_PCM_MAS_PAUSE_MASK, 0xffffffff);
311 mmio_write_32(SPM_PCM_REG_DATA_INI, 0);
312 mmio_clrbits_32(SPM_CLK_CON, CC_DISABLE_DORM_PWR);
313
314 mmio_write_32(SPM_PCM_FLAGS, pwrctrl->pcm_flags);
315
316 mmio_clrsetbits_32(SPM_CLK_CON, CC_LOCK_INFRA_DCM,
317 (pwrctrl->infra_dcm_lock ? CC_LOCK_INFRA_DCM : 0));
318
319 mmio_write_32(SPM_PCM_PWR_IO_EN,
320 (pwrctrl->r0_ctrl_en ? PCM_PWRIO_EN_R0 : 0) |
321 (pwrctrl->r7_ctrl_en ? PCM_PWRIO_EN_R7 : 0));
322}
323
324void spm_clean_after_wakeup(void)
325{
326 mmio_clrsetbits_32(SPM_PCM_CON1, CON1_PCM_WDT_EN, CON1_CFG_KEY);
327
328 mmio_write_32(SPM_PCM_PWR_IO_EN, 0);
329 mmio_write_32(SPM_SLEEP_CPU_WAKEUP_EVENT, 0);
330 mmio_clrsetbits_32(SPM_PCM_CON1, CON1_PCM_TIMER_EN, CON1_CFG_KEY);
331
332 mmio_write_32(SPM_SLEEP_WAKEUP_EVENT_MASK, ~0);
333 mmio_write_32(SPM_SLEEP_ISR_MASK, 0xFF0C);
334 mmio_write_32(SPM_SLEEP_ISR_STATUS, 0xC);
335 mmio_write_32(SPM_PCM_SW_INT_CLEAR, 0xFF);
336}
337
338enum wake_reason_t spm_output_wake_reason(struct wake_status *wakesta)
339{
340 enum wake_reason_t wr;
341 int i;
342
343 wr = WR_UNKNOWN;
344
345 if (wakesta->assert_pc != 0) {
346 ERROR("PCM ASSERT AT %u, r12=0x%x, r13=0x%x, debug_flag=0x%x\n",
347 wakesta->assert_pc, wakesta->r12, wakesta->r13,
348 wakesta->debug_flag);
349 return WR_PCM_ASSERT;
350 }
351
352 if (wakesta->r12 & WAKE_SRC_SPM_MERGE) {
353 if (wakesta->wake_misc & WAKE_MISC_PCM_TIMER)
354 wr = WR_PCM_TIMER;
355 if (wakesta->wake_misc & WAKE_MISC_CPU_WAKE)
356 wr = WR_WAKE_SRC;
357 }
358
359 for (i = 1; i < 32; i++) {
360 if (wakesta->r12 & (1U << i))
361 wr = WR_WAKE_SRC;
362 }
363
364 if ((wakesta->event_reg & 0x100000) == 0) {
365 INFO("pcm sleep abort!\n");
366 wr = WR_PCM_ABORT;
367 }
368
369 INFO("timer_out = %u, r12 = 0x%x, r13 = 0x%x, debug_flag = 0x%x\n",
370 wakesta->timer_out, wakesta->r12, wakesta->r13,
371 wakesta->debug_flag);
372
373 INFO("raw_sta = 0x%x, idle_sta = 0x%x, event_reg = 0x%x, isr = 0x%x\n",
374 wakesta->raw_sta, wakesta->idle_sta, wakesta->event_reg,
375 wakesta->isr);
376
developer65014b82015-04-13 14:47:57 +0800[diff] [blame]377 return wr;
378}
379
380void spm_boot_init(void)
381{
developer89ddad12016-03-29 17:42:41 +0800[diff] [blame]382 /* set spm transaction to secure mode */
383 mmio_write_32(DEVAPC0_APC_CON, 0x0);
384 mmio_write_32(DEVAPC0_MAS_SEC_0, 0x200);
385
developer65014b82015-04-13 14:47:57 +0800[diff] [blame]386 /* Only CPU0 is online during boot, initialize cpu online reserve bit */
387 mmio_write_32(SPM_PCM_RESERVE, 0xFE);
developer512a3112015-11-16 14:26:14 +0800[diff] [blame]388 mmio_clrbits_32(AP_PLL_CON3, 0xFFFFF);
389 mmio_clrbits_32(AP_PLL_CON4, 0xF);
developer65014b82015-04-13 14:47:57 +0800[diff] [blame]390 spm_lock_init();
391 spm_register_init();
392}