plat/mediatek/mt8173/drivers/spm/spm.c - imx-atf - Git at Google

 /*
  * Copyright (c) 2015, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */
 #include <bakery_lock.h>
 #include <debug.h>
 #include <mmio.h>
 #include <mt8173_def.h>
 #include <spm.h>
 #include <spm_suspend.h>

 /*
  * System Power Manager (SPM) is a hardware module, which controls cpu or
  * system power for different power scenarios using different firmware, i.e.,
  * - spm_hotplug.c for cpu power control in cpu hotplug flow.
  * - spm_mcdi.c for cpu power control in cpu idle power saving state.
  * - spm_suspend.c for system power control in system suspend scenario.
  *
  * This file provide utility functions common to hotplug, mcdi(idle), suspend
  * power scenarios. A bakery lock (software lock) is incoporated to protect
  * certain critical sections to avoid kicking different SPM firmware
  * concurrently.
  */

 #define SPM_SYSCLK_SETTLE       128	/* 3.9ms */

 DEFINE_BAKERY_LOCK(spm_lock);

 static int spm_hotplug_ready __section("tzfw_coherent_mem");
 static int spm_mcdi_ready __section("tzfw_coherent_mem");
 static int spm_suspend_ready __section("tzfw_coherent_mem");

 void spm_lock_init(void)
 {
 	bakery_lock_init(&spm_lock);
 }

 void spm_lock_get(void)
 {
 	bakery_lock_get(&spm_lock);
 }

 void spm_lock_release(void)
 {
 	bakery_lock_release(&spm_lock);
 }

 int is_mcdi_ready(void)
 {
 	return spm_mcdi_ready;
 }

 int is_hotplug_ready(void)
 {
 	return spm_hotplug_ready;
 }

 int is_suspend_ready(void)
 {
 	return spm_suspend_ready;
 }

 void set_mcdi_ready(void)
 {
 	spm_mcdi_ready = 1;
 	spm_hotplug_ready = 0;
 	spm_suspend_ready = 0;
 }

 void set_hotplug_ready(void)
 {
 	spm_mcdi_ready = 0;
 	spm_hotplug_ready = 1;
 	spm_suspend_ready = 0;
 }

 void set_suspend_ready(void)
 {
 	spm_mcdi_ready = 0;
 	spm_hotplug_ready = 0;
 	spm_suspend_ready = 1;
 }

 void clear_all_ready(void)
 {
 	spm_mcdi_ready = 0;
 	spm_hotplug_ready = 0;
 	spm_suspend_ready = 0;
 }

 void spm_register_init(void)
 {
 	mmio_write_32(SPM_POWERON_CONFIG_SET, SPM_REGWR_CFG_KEY | SPM_REGWR_EN);

 	mmio_write_32(SPM_POWER_ON_VAL0, 0);
 	mmio_write_32(SPM_POWER_ON_VAL1, POWER_ON_VAL1_DEF);
 	mmio_write_32(SPM_PCM_PWR_IO_EN, 0);

 	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY | CON0_PCM_SW_RESET);
 	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY);
 	if (mmio_read_32(SPM_PCM_FSM_STA) != PCM_FSM_STA_DEF)
 		WARN("PCM reset failed\n");

 	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY | CON0_IM_SLEEP_DVS);
 	mmio_write_32(SPM_PCM_CON1, CON1_CFG_KEY | CON1_EVENT_LOCK_EN |
 		CON1_SPM_SRAM_ISO_B | CON1_SPM_SRAM_SLP_B | CON1_MIF_APBEN);
 	mmio_write_32(SPM_PCM_IM_PTR, 0);
 	mmio_write_32(SPM_PCM_IM_LEN, 0);

 	mmio_write_32(SPM_CLK_CON, CC_SYSCLK0_EN_1 | CC_SYSCLK0_EN_0 |
 		CC_SYSCLK1_EN_0 | CC_SRCLKENA_MASK_0 | CC_CLKSQ1_SEL |
 		CC_CXO32K_RM_EN_MD2 | CC_CXO32K_RM_EN_MD1 | CC_MD32_DCM_EN);

 	mmio_write_32(SPM_SLEEP_ISR_MASK, 0xff0c);
 	mmio_write_32(SPM_SLEEP_ISR_STATUS, 0xc);
 	mmio_write_32(SPM_PCM_SW_INT_CLEAR, 0xff);
 	mmio_write_32(SPM_MD32_SRAM_CON, 0xff0);
 }

 void spm_reset_and_init_pcm(void)
 {
 	unsigned int con1;
 	int i = 0;

 	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY | CON0_PCM_SW_RESET);
 	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY);
 	while (mmio_read_32(SPM_PCM_FSM_STA) != PCM_FSM_STA_DEF) {
 		i++;
 		if (i > 1000) {
 			i = 0;
 			WARN("PCM reset failed\n");
 			break;
 		}
 	}

 	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY | CON0_IM_SLEEP_DVS);

 	con1 = mmio_read_32(SPM_PCM_CON1) &
 		(CON1_PCM_WDT_WAKE_MODE | CON1_PCM_WDT_EN);
 	mmio_write_32(SPM_PCM_CON1, con1 | CON1_CFG_KEY | CON1_EVENT_LOCK_EN |
 		CON1_SPM_SRAM_ISO_B | CON1_SPM_SRAM_SLP_B |
 		CON1_IM_NONRP_EN | CON1_MIF_APBEN);
 }

 void spm_init_pcm_register(void)
 {
 	mmio_write_32(SPM_PCM_REG_DATA_INI, mmio_read_32(SPM_POWER_ON_VAL0));
 	mmio_write_32(SPM_PCM_PWR_IO_EN, PCM_RF_SYNC_R0);
 	mmio_write_32(SPM_PCM_PWR_IO_EN, 0);

 	mmio_write_32(SPM_PCM_REG_DATA_INI, mmio_read_32(SPM_POWER_ON_VAL1));
 	mmio_write_32(SPM_PCM_PWR_IO_EN, PCM_RF_SYNC_R7);
 	mmio_write_32(SPM_PCM_PWR_IO_EN, 0);
 }

 void spm_set_power_control(const struct pwr_ctrl *pwrctrl)
 {
 	mmio_write_32(SPM_AP_STANBY_CON, (!pwrctrl->md32_req_mask << 21) |
 					 (!pwrctrl->mfg_req_mask << 17) |
 					 (!pwrctrl->disp_req_mask << 16) |
 					 (!!pwrctrl->mcusys_idle_mask << 7) |
 					 (!!pwrctrl->ca15top_idle_mask << 6) |
 					 (!!pwrctrl->ca7top_idle_mask << 5) |
 					 (!!pwrctrl->wfi_op << 4));
 	mmio_write_32(SPM_PCM_SRC_REQ, (!!pwrctrl->pcm_apsrc_req << 0));
 	mmio_write_32(SPM_PCM_PASR_DPD_2, 0);

 	mmio_clrsetbits_32(SPM_CLK_CON, CC_SRCLKENA_MASK_0,
 		(pwrctrl->srclkenai_mask ? CC_SRCLKENA_MASK_0 : 0));

 	mmio_write_32(SPM_SLEEP_CA15_WFI0_EN, !!pwrctrl->ca15_wfi0_en);
 	mmio_write_32(SPM_SLEEP_CA15_WFI1_EN, !!pwrctrl->ca15_wfi1_en);
 	mmio_write_32(SPM_SLEEP_CA15_WFI2_EN, !!pwrctrl->ca15_wfi2_en);
 	mmio_write_32(SPM_SLEEP_CA15_WFI3_EN, !!pwrctrl->ca15_wfi3_en);
 	mmio_write_32(SPM_SLEEP_CA7_WFI0_EN, !!pwrctrl->ca7_wfi0_en);
 	mmio_write_32(SPM_SLEEP_CA7_WFI1_EN, !!pwrctrl->ca7_wfi1_en);
 	mmio_write_32(SPM_SLEEP_CA7_WFI2_EN, !!pwrctrl->ca7_wfi2_en);
 	mmio_write_32(SPM_SLEEP_CA7_WFI3_EN, !!pwrctrl->ca7_wfi3_en);
 }

 void spm_set_wakeup_event(const struct pwr_ctrl *pwrctrl)
 {
 	unsigned int val, mask;

 	if (pwrctrl->timer_val_cust == 0)
 		val = pwrctrl->timer_val ? pwrctrl->timer_val : PCM_TIMER_MAX;
 	else
 		val = pwrctrl->timer_val_cust;

 	mmio_write_32(SPM_PCM_TIMER_VAL, val);
 	mmio_setbits_32(SPM_PCM_CON1, CON1_CFG_KEY);

 	if (pwrctrl->wake_src_cust == 0)
 		mask = pwrctrl->wake_src;
 	else
 		mask = pwrctrl->wake_src_cust;

 	if (pwrctrl->syspwreq_mask)
 		mask &= ~WAKE_SRC_SYSPWREQ;

 	mmio_write_32(SPM_SLEEP_WAKEUP_EVENT_MASK, ~mask);
 	mmio_write_32(SPM_SLEEP_ISR_MASK, 0xfe04);
 }

 void spm_get_wakeup_status(struct wake_status *wakesta)
 {
 	wakesta->assert_pc = mmio_read_32(SPM_PCM_REG_DATA_INI);
 	wakesta->r12 = mmio_read_32(SPM_PCM_REG12_DATA);
 	wakesta->raw_sta = mmio_read_32(SPM_SLEEP_ISR_RAW_STA);
 	wakesta->wake_misc = mmio_read_32(SPM_SLEEP_WAKEUP_MISC);
 	wakesta->timer_out = mmio_read_32(SPM_PCM_TIMER_OUT);
 	wakesta->r13 = mmio_read_32(SPM_PCM_REG13_DATA);
 	wakesta->idle_sta = mmio_read_32(SPM_SLEEP_SUBSYS_IDLE_STA);
 	wakesta->debug_flag = mmio_read_32(SPM_PCM_PASR_DPD_3);
 	wakesta->event_reg = mmio_read_32(SPM_PCM_EVENT_REG_STA);
 	wakesta->isr = mmio_read_32(SPM_SLEEP_ISR_STATUS);
 }

 void spm_init_event_vector(const struct pcm_desc *pcmdesc)
 {
 	/* init event vector register */
 	mmio_write_32(SPM_PCM_EVENT_VECTOR0, pcmdesc->vec0);
 	mmio_write_32(SPM_PCM_EVENT_VECTOR1, pcmdesc->vec1);
 	mmio_write_32(SPM_PCM_EVENT_VECTOR2, pcmdesc->vec2);
 	mmio_write_32(SPM_PCM_EVENT_VECTOR3, pcmdesc->vec3);
 	mmio_write_32(SPM_PCM_EVENT_VECTOR4, pcmdesc->vec4);
 	mmio_write_32(SPM_PCM_EVENT_VECTOR5, pcmdesc->vec5);
 	mmio_write_32(SPM_PCM_EVENT_VECTOR6, pcmdesc->vec6);
 	mmio_write_32(SPM_PCM_EVENT_VECTOR7, pcmdesc->vec7);

 	/* event vector will be enabled by PCM itself */
 }

 void spm_kick_im_to_fetch(const struct pcm_desc *pcmdesc)
 {
 	unsigned int ptr = 0, len, con0;

 	ptr = (unsigned int)(unsigned long)(pcmdesc->base);
 	len = pcmdesc->size - 1;
 	if (mmio_read_32(SPM_PCM_IM_PTR) != ptr ||
 	    mmio_read_32(SPM_PCM_IM_LEN) != len ||
 	    pcmdesc->sess > 2) {
 		mmio_write_32(SPM_PCM_IM_PTR, ptr);
 		mmio_write_32(SPM_PCM_IM_LEN, len);
 	} else {
 		mmio_setbits_32(SPM_PCM_CON1, CON1_CFG_KEY | CON1_IM_SLAVE);
 	}

 	/* kick IM to fetch (only toggle IM_KICK) */
 	con0 = mmio_read_32(SPM_PCM_CON0) & ~(CON0_IM_KICK | CON0_PCM_KICK);
 	mmio_write_32(SPM_PCM_CON0, con0 | CON0_CFG_KEY | CON0_IM_KICK);
 	mmio_write_32(SPM_PCM_CON0, con0 | CON0_CFG_KEY);

 	/* kick IM to fetch (only toggle PCM_KICK) */
 	con0 = mmio_read_32(SPM_PCM_CON0) & ~(CON0_IM_KICK | CON0_PCM_KICK);
 	mmio_write_32(SPM_PCM_CON0, con0 | CON0_CFG_KEY | CON0_PCM_KICK);
 	mmio_write_32(SPM_PCM_CON0, con0 | CON0_CFG_KEY);
 }

 void spm_set_sysclk_settle(void)
 {
 	mmio_write_32(SPM_CLK_SETTLE, SPM_SYSCLK_SETTLE);

 	INFO("settle = %u\n", mmio_read_32(SPM_CLK_SETTLE));
 }

 void spm_kick_pcm_to_run(struct pwr_ctrl *pwrctrl)
 {
 	unsigned int con1;

 	con1 = mmio_read_32(SPM_PCM_CON1) &
 		~(CON1_PCM_WDT_WAKE_MODE | CON1_PCM_WDT_EN);

 	mmio_write_32(SPM_PCM_CON1, CON1_CFG_KEY | con1);

 	if (mmio_read_32(SPM_PCM_TIMER_VAL) > PCM_TIMER_MAX)
 		mmio_write_32(SPM_PCM_TIMER_VAL, PCM_TIMER_MAX);

 	mmio_write_32(SPM_PCM_WDT_TIMER_VAL,
 		mmio_read_32(SPM_PCM_TIMER_VAL) + PCM_WDT_TIMEOUT);

 	mmio_write_32(SPM_PCM_CON1, con1 | CON1_CFG_KEY | CON1_PCM_WDT_EN);
 	mmio_write_32(SPM_PCM_PASR_DPD_0, 0);

 	mmio_write_32(SPM_PCM_MAS_PAUSE_MASK, 0xffffffff);
 	mmio_write_32(SPM_PCM_REG_DATA_INI, 0);
 	mmio_clrbits_32(SPM_CLK_CON, CC_DISABLE_DORM_PWR);

 	mmio_write_32(SPM_PCM_FLAGS, pwrctrl->pcm_flags);

 	mmio_clrsetbits_32(SPM_CLK_CON, CC_LOCK_INFRA_DCM,
 		(pwrctrl->infra_dcm_lock ? CC_LOCK_INFRA_DCM : 0));

 	mmio_write_32(SPM_PCM_PWR_IO_EN,
 		(pwrctrl->r0_ctrl_en ? PCM_PWRIO_EN_R0 : 0) |
 		(pwrctrl->r7_ctrl_en ? PCM_PWRIO_EN_R7 : 0));
 }

 void spm_clean_after_wakeup(void)
 {
 	mmio_clrsetbits_32(SPM_PCM_CON1, CON1_PCM_WDT_EN, CON1_CFG_KEY);

 	mmio_write_32(SPM_PCM_PWR_IO_EN, 0);
 	mmio_write_32(SPM_SLEEP_CPU_WAKEUP_EVENT, 0);
 	mmio_clrsetbits_32(SPM_PCM_CON1, CON1_PCM_TIMER_EN, CON1_CFG_KEY);

 	mmio_write_32(SPM_SLEEP_WAKEUP_EVENT_MASK, ~0);
 	mmio_write_32(SPM_SLEEP_ISR_MASK, 0xFF0C);
 	mmio_write_32(SPM_SLEEP_ISR_STATUS, 0xC);
 	mmio_write_32(SPM_PCM_SW_INT_CLEAR, 0xFF);
 }

 enum wake_reason_t spm_output_wake_reason(struct wake_status *wakesta)
 {
 	enum wake_reason_t wr;
 	int i;

 	wr = WR_UNKNOWN;

 	if (wakesta->assert_pc != 0) {
 		ERROR("PCM ASSERT AT %u, r12=0x%x, r13=0x%x, debug_flag=0x%x\n",
 		      wakesta->assert_pc, wakesta->r12, wakesta->r13,
 		      wakesta->debug_flag);
 		return WR_PCM_ASSERT;
 	}

 	if (wakesta->r12 & WAKE_SRC_SPM_MERGE) {
 		if (wakesta->wake_misc & WAKE_MISC_PCM_TIMER)
 			wr = WR_PCM_TIMER;
 		if (wakesta->wake_misc & WAKE_MISC_CPU_WAKE)
 			wr = WR_WAKE_SRC;
 	}

 	for (i = 1; i < 32; i++) {
 		if (wakesta->r12 & (1U << i))
 			wr = WR_WAKE_SRC;
 	}

 	if ((wakesta->event_reg & 0x100000) == 0) {
 		INFO("pcm sleep abort!\n");
 		wr = WR_PCM_ABORT;
 	}

 	INFO("timer_out = %u, r12 = 0x%x, r13 = 0x%x, debug_flag = 0x%x\n",
 	     wakesta->timer_out, wakesta->r12, wakesta->r13,
 	     wakesta->debug_flag);

 	INFO("raw_sta = 0x%x, idle_sta = 0x%x, event_reg = 0x%x, isr = 0x%x\n",
 	     wakesta->raw_sta, wakesta->idle_sta, wakesta->event_reg,
 	     wakesta->isr);

 	return wr;
 }

 void spm_boot_init(void)
 {
 	/* set spm transaction to secure mode */
 	mmio_write_32(DEVAPC0_APC_CON, 0x0);
 	mmio_write_32(DEVAPC0_MAS_SEC_0, 0x200);

 	/* Only CPU0 is online during boot, initialize cpu online reserve bit */
 	mmio_write_32(SPM_PCM_RESERVE, 0xFE);
 	mmio_clrbits_32(AP_PLL_CON3, 0xFFFFF);
 	mmio_clrbits_32(AP_PLL_CON4, 0xF);
 	spm_lock_init();
 	spm_register_init();
 }
	/*
	* Copyright (c) 2015, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/
	#include <bakery_lock.h>
	#include <debug.h>
	#include <mmio.h>
	#include <mt8173_def.h>
	#include <spm.h>
	#include <spm_suspend.h>

	/*
	* System Power Manager (SPM) is a hardware module, which controls cpu or
	* system power for different power scenarios using different firmware, i.e.,
	* - spm_hotplug.c for cpu power control in cpu hotplug flow.
	* - spm_mcdi.c for cpu power control in cpu idle power saving state.
	* - spm_suspend.c for system power control in system suspend scenario.
	*
	* This file provide utility functions common to hotplug, mcdi(idle), suspend
	* power scenarios. A bakery lock (software lock) is incoporated to protect
	* certain critical sections to avoid kicking different SPM firmware
	* concurrently.
	*/

	#define SPM_SYSCLK_SETTLE 128 /* 3.9ms */

	DEFINE_BAKERY_LOCK(spm_lock);

	static int spm_hotplug_ready __section("tzfw_coherent_mem");
	static int spm_mcdi_ready __section("tzfw_coherent_mem");
	static int spm_suspend_ready __section("tzfw_coherent_mem");

	void spm_lock_init(void)
	{
	bakery_lock_init(&spm_lock);
	}

	void spm_lock_get(void)
	{
	bakery_lock_get(&spm_lock);
	}

	void spm_lock_release(void)
	{
	bakery_lock_release(&spm_lock);
	}

	int is_mcdi_ready(void)
	{
	return spm_mcdi_ready;
	}

	int is_hotplug_ready(void)
	{
	return spm_hotplug_ready;
	}

	int is_suspend_ready(void)
	{
	return spm_suspend_ready;
	}

	void set_mcdi_ready(void)
	{
	spm_mcdi_ready = 1;
	spm_hotplug_ready = 0;
	spm_suspend_ready = 0;
	}

	void set_hotplug_ready(void)
	{
	spm_mcdi_ready = 0;
	spm_hotplug_ready = 1;
	spm_suspend_ready = 0;
	}

	void set_suspend_ready(void)
	{
	spm_mcdi_ready = 0;
	spm_hotplug_ready = 0;
	spm_suspend_ready = 1;
	}

	void clear_all_ready(void)
	{
	spm_mcdi_ready = 0;
	spm_hotplug_ready = 0;
	spm_suspend_ready = 0;
	}

	void spm_register_init(void)
	{
	mmio_write_32(SPM_POWERON_CONFIG_SET, SPM_REGWR_CFG_KEY \| SPM_REGWR_EN);

	mmio_write_32(SPM_POWER_ON_VAL0, 0);
	mmio_write_32(SPM_POWER_ON_VAL1, POWER_ON_VAL1_DEF);
	mmio_write_32(SPM_PCM_PWR_IO_EN, 0);

	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY \| CON0_PCM_SW_RESET);
	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY);
	if (mmio_read_32(SPM_PCM_FSM_STA) != PCM_FSM_STA_DEF)
	WARN("PCM reset failed\n");

	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY \| CON0_IM_SLEEP_DVS);
	mmio_write_32(SPM_PCM_CON1, CON1_CFG_KEY \| CON1_EVENT_LOCK_EN \|
	CON1_SPM_SRAM_ISO_B \| CON1_SPM_SRAM_SLP_B \| CON1_MIF_APBEN);
	mmio_write_32(SPM_PCM_IM_PTR, 0);
	mmio_write_32(SPM_PCM_IM_LEN, 0);

	mmio_write_32(SPM_CLK_CON, CC_SYSCLK0_EN_1 \| CC_SYSCLK0_EN_0 \|
	CC_SYSCLK1_EN_0 \| CC_SRCLKENA_MASK_0 \| CC_CLKSQ1_SEL \|
	CC_CXO32K_RM_EN_MD2 \| CC_CXO32K_RM_EN_MD1 \| CC_MD32_DCM_EN);

	mmio_write_32(SPM_SLEEP_ISR_MASK, 0xff0c);
	mmio_write_32(SPM_SLEEP_ISR_STATUS, 0xc);
	mmio_write_32(SPM_PCM_SW_INT_CLEAR, 0xff);
	mmio_write_32(SPM_MD32_SRAM_CON, 0xff0);
	}

	void spm_reset_and_init_pcm(void)
	{
	unsigned int con1;
	int i = 0;

	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY \| CON0_PCM_SW_RESET);
	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY);
	while (mmio_read_32(SPM_PCM_FSM_STA) != PCM_FSM_STA_DEF) {
	i++;
	if (i > 1000) {
	i = 0;
	WARN("PCM reset failed\n");
	break;
	}
	}

	mmio_write_32(SPM_PCM_CON0, CON0_CFG_KEY \| CON0_IM_SLEEP_DVS);

	con1 = mmio_read_32(SPM_PCM_CON1) &
	(CON1_PCM_WDT_WAKE_MODE \| CON1_PCM_WDT_EN);
	mmio_write_32(SPM_PCM_CON1, con1 \| CON1_CFG_KEY \| CON1_EVENT_LOCK_EN \|
	CON1_SPM_SRAM_ISO_B \| CON1_SPM_SRAM_SLP_B \|
	CON1_IM_NONRP_EN \| CON1_MIF_APBEN);
	}

	void spm_init_pcm_register(void)
	{
	mmio_write_32(SPM_PCM_REG_DATA_INI, mmio_read_32(SPM_POWER_ON_VAL0));
	mmio_write_32(SPM_PCM_PWR_IO_EN, PCM_RF_SYNC_R0);
	mmio_write_32(SPM_PCM_PWR_IO_EN, 0);

	mmio_write_32(SPM_PCM_REG_DATA_INI, mmio_read_32(SPM_POWER_ON_VAL1));
	mmio_write_32(SPM_PCM_PWR_IO_EN, PCM_RF_SYNC_R7);
	mmio_write_32(SPM_PCM_PWR_IO_EN, 0);
	}

	void spm_set_power_control(const struct pwr_ctrl *pwrctrl)
	{
	mmio_write_32(SPM_AP_STANBY_CON, (!pwrctrl->md32_req_mask << 21) \|
	(!pwrctrl->mfg_req_mask << 17) \|
	(!pwrctrl->disp_req_mask << 16) \|
	(!!pwrctrl->mcusys_idle_mask << 7) \|
	(!!pwrctrl->ca15top_idle_mask << 6) \|
	(!!pwrctrl->ca7top_idle_mask << 5) \|
	(!!pwrctrl->wfi_op << 4));
	mmio_write_32(SPM_PCM_SRC_REQ, (!!pwrctrl->pcm_apsrc_req << 0));
	mmio_write_32(SPM_PCM_PASR_DPD_2, 0);

	mmio_clrsetbits_32(SPM_CLK_CON, CC_SRCLKENA_MASK_0,
	(pwrctrl->srclkenai_mask ? CC_SRCLKENA_MASK_0 : 0));

	mmio_write_32(SPM_SLEEP_CA15_WFI0_EN, !!pwrctrl->ca15_wfi0_en);
	mmio_write_32(SPM_SLEEP_CA15_WFI1_EN, !!pwrctrl->ca15_wfi1_en);
	mmio_write_32(SPM_SLEEP_CA15_WFI2_EN, !!pwrctrl->ca15_wfi2_en);
	mmio_write_32(SPM_SLEEP_CA15_WFI3_EN, !!pwrctrl->ca15_wfi3_en);
	mmio_write_32(SPM_SLEEP_CA7_WFI0_EN, !!pwrctrl->ca7_wfi0_en);
	mmio_write_32(SPM_SLEEP_CA7_WFI1_EN, !!pwrctrl->ca7_wfi1_en);
	mmio_write_32(SPM_SLEEP_CA7_WFI2_EN, !!pwrctrl->ca7_wfi2_en);
	mmio_write_32(SPM_SLEEP_CA7_WFI3_EN, !!pwrctrl->ca7_wfi3_en);
	}

	void spm_set_wakeup_event(const struct pwr_ctrl *pwrctrl)
	{
	unsigned int val, mask;

	if (pwrctrl->timer_val_cust == 0)
	val = pwrctrl->timer_val ? pwrctrl->timer_val : PCM_TIMER_MAX;
	else
	val = pwrctrl->timer_val_cust;

	mmio_write_32(SPM_PCM_TIMER_VAL, val);
	mmio_setbits_32(SPM_PCM_CON1, CON1_CFG_KEY);

	if (pwrctrl->wake_src_cust == 0)
	mask = pwrctrl->wake_src;
	else
	mask = pwrctrl->wake_src_cust;

	if (pwrctrl->syspwreq_mask)
	mask &= ~WAKE_SRC_SYSPWREQ;

	mmio_write_32(SPM_SLEEP_WAKEUP_EVENT_MASK, ~mask);
	mmio_write_32(SPM_SLEEP_ISR_MASK, 0xfe04);
	}

	void spm_get_wakeup_status(struct wake_status *wakesta)
	{
	wakesta->assert_pc = mmio_read_32(SPM_PCM_REG_DATA_INI);
	wakesta->r12 = mmio_read_32(SPM_PCM_REG12_DATA);
	wakesta->raw_sta = mmio_read_32(SPM_SLEEP_ISR_RAW_STA);
	wakesta->wake_misc = mmio_read_32(SPM_SLEEP_WAKEUP_MISC);
	wakesta->timer_out = mmio_read_32(SPM_PCM_TIMER_OUT);
	wakesta->r13 = mmio_read_32(SPM_PCM_REG13_DATA);
	wakesta->idle_sta = mmio_read_32(SPM_SLEEP_SUBSYS_IDLE_STA);
	wakesta->debug_flag = mmio_read_32(SPM_PCM_PASR_DPD_3);
	wakesta->event_reg = mmio_read_32(SPM_PCM_EVENT_REG_STA);
	wakesta->isr = mmio_read_32(SPM_SLEEP_ISR_STATUS);
	}

	void spm_init_event_vector(const struct pcm_desc *pcmdesc)
	{
	/* init event vector register */
	mmio_write_32(SPM_PCM_EVENT_VECTOR0, pcmdesc->vec0);
	mmio_write_32(SPM_PCM_EVENT_VECTOR1, pcmdesc->vec1);
	mmio_write_32(SPM_PCM_EVENT_VECTOR2, pcmdesc->vec2);
	mmio_write_32(SPM_PCM_EVENT_VECTOR3, pcmdesc->vec3);
	mmio_write_32(SPM_PCM_EVENT_VECTOR4, pcmdesc->vec4);
	mmio_write_32(SPM_PCM_EVENT_VECTOR5, pcmdesc->vec5);
	mmio_write_32(SPM_PCM_EVENT_VECTOR6, pcmdesc->vec6);
	mmio_write_32(SPM_PCM_EVENT_VECTOR7, pcmdesc->vec7);

	/* event vector will be enabled by PCM itself */
	}

	void spm_kick_im_to_fetch(const struct pcm_desc *pcmdesc)
	{
	unsigned int ptr = 0, len, con0;

	ptr = (unsigned int)(unsigned long)(pcmdesc->base);
	len = pcmdesc->size - 1;
	if (mmio_read_32(SPM_PCM_IM_PTR) != ptr \|\|
	mmio_read_32(SPM_PCM_IM_LEN) != len \|\|
	pcmdesc->sess > 2) {
	mmio_write_32(SPM_PCM_IM_PTR, ptr);
	mmio_write_32(SPM_PCM_IM_LEN, len);
	} else {
	mmio_setbits_32(SPM_PCM_CON1, CON1_CFG_KEY \| CON1_IM_SLAVE);
	}

	/* kick IM to fetch (only toggle IM_KICK) */
	con0 = mmio_read_32(SPM_PCM_CON0) & ~(CON0_IM_KICK \| CON0_PCM_KICK);
	mmio_write_32(SPM_PCM_CON0, con0 \| CON0_CFG_KEY \| CON0_IM_KICK);
	mmio_write_32(SPM_PCM_CON0, con0 \| CON0_CFG_KEY);

	/* kick IM to fetch (only toggle PCM_KICK) */
	con0 = mmio_read_32(SPM_PCM_CON0) & ~(CON0_IM_KICK \| CON0_PCM_KICK);
	mmio_write_32(SPM_PCM_CON0, con0 \| CON0_CFG_KEY \| CON0_PCM_KICK);
	mmio_write_32(SPM_PCM_CON0, con0 \| CON0_CFG_KEY);
	}

	void spm_set_sysclk_settle(void)
	{
	mmio_write_32(SPM_CLK_SETTLE, SPM_SYSCLK_SETTLE);

	INFO("settle = %u\n", mmio_read_32(SPM_CLK_SETTLE));
	}

	void spm_kick_pcm_to_run(struct pwr_ctrl *pwrctrl)
	{
	unsigned int con1;

	con1 = mmio_read_32(SPM_PCM_CON1) &
	~(CON1_PCM_WDT_WAKE_MODE \| CON1_PCM_WDT_EN);

	mmio_write_32(SPM_PCM_CON1, CON1_CFG_KEY \| con1);

	if (mmio_read_32(SPM_PCM_TIMER_VAL) > PCM_TIMER_MAX)
	mmio_write_32(SPM_PCM_TIMER_VAL, PCM_TIMER_MAX);

	mmio_write_32(SPM_PCM_WDT_TIMER_VAL,
	mmio_read_32(SPM_PCM_TIMER_VAL) + PCM_WDT_TIMEOUT);

	mmio_write_32(SPM_PCM_CON1, con1 \| CON1_CFG_KEY \| CON1_PCM_WDT_EN);
	mmio_write_32(SPM_PCM_PASR_DPD_0, 0);

	mmio_write_32(SPM_PCM_MAS_PAUSE_MASK, 0xffffffff);
	mmio_write_32(SPM_PCM_REG_DATA_INI, 0);
	mmio_clrbits_32(SPM_CLK_CON, CC_DISABLE_DORM_PWR);

	mmio_write_32(SPM_PCM_FLAGS, pwrctrl->pcm_flags);

	mmio_clrsetbits_32(SPM_CLK_CON, CC_LOCK_INFRA_DCM,
	(pwrctrl->infra_dcm_lock ? CC_LOCK_INFRA_DCM : 0));

	mmio_write_32(SPM_PCM_PWR_IO_EN,
	(pwrctrl->r0_ctrl_en ? PCM_PWRIO_EN_R0 : 0) \|
	(pwrctrl->r7_ctrl_en ? PCM_PWRIO_EN_R7 : 0));
	}

	void spm_clean_after_wakeup(void)
	{
	mmio_clrsetbits_32(SPM_PCM_CON1, CON1_PCM_WDT_EN, CON1_CFG_KEY);

	mmio_write_32(SPM_PCM_PWR_IO_EN, 0);
	mmio_write_32(SPM_SLEEP_CPU_WAKEUP_EVENT, 0);
	mmio_clrsetbits_32(SPM_PCM_CON1, CON1_PCM_TIMER_EN, CON1_CFG_KEY);

	mmio_write_32(SPM_SLEEP_WAKEUP_EVENT_MASK, ~0);
	mmio_write_32(SPM_SLEEP_ISR_MASK, 0xFF0C);
	mmio_write_32(SPM_SLEEP_ISR_STATUS, 0xC);
	mmio_write_32(SPM_PCM_SW_INT_CLEAR, 0xFF);
	}

	enum wake_reason_t spm_output_wake_reason(struct wake_status *wakesta)
	{
	enum wake_reason_t wr;
	int i;

	wr = WR_UNKNOWN;

	if (wakesta->assert_pc != 0) {
	ERROR("PCM ASSERT AT %u, r12=0x%x, r13=0x%x, debug_flag=0x%x\n",
	wakesta->assert_pc, wakesta->r12, wakesta->r13,
	wakesta->debug_flag);
	return WR_PCM_ASSERT;
	}

	if (wakesta->r12 & WAKE_SRC_SPM_MERGE) {
	if (wakesta->wake_misc & WAKE_MISC_PCM_TIMER)
	wr = WR_PCM_TIMER;
	if (wakesta->wake_misc & WAKE_MISC_CPU_WAKE)
	wr = WR_WAKE_SRC;
	}

	for (i = 1; i < 32; i++) {
	if (wakesta->r12 & (1U << i))
	wr = WR_WAKE_SRC;
	}

	if ((wakesta->event_reg & 0x100000) == 0) {
	INFO("pcm sleep abort!\n");
	wr = WR_PCM_ABORT;
	}

	INFO("timer_out = %u, r12 = 0x%x, r13 = 0x%x, debug_flag = 0x%x\n",
	wakesta->timer_out, wakesta->r12, wakesta->r13,
	wakesta->debug_flag);

	INFO("raw_sta = 0x%x, idle_sta = 0x%x, event_reg = 0x%x, isr = 0x%x\n",
	wakesta->raw_sta, wakesta->idle_sta, wakesta->event_reg,
	wakesta->isr);

	return wr;
	}

	void spm_boot_init(void)
	{
	/* set spm transaction to secure mode */
	mmio_write_32(DEVAPC0_APC_CON, 0x0);
	mmio_write_32(DEVAPC0_MAS_SEC_0, 0x200);

	/* Only CPU0 is online during boot, initialize cpu online reserve bit */
	mmio_write_32(SPM_PCM_RESERVE, 0xFE);
	mmio_clrbits_32(AP_PLL_CON3, 0xFFFFF);
	mmio_clrbits_32(AP_PLL_CON4, 0xF);
	spm_lock_init();
	spm_register_init();
	}