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git01.mediatek.com / filogic / atf / e0b52cc65b275130bf36eb70e8d69953397fe09d / . / plat / mediatek / drivers / cpu_pm / cpcv3_2 / mt_cpu_pm.c
blob: 313ad470fa87de5bdbabe4669e9f1c06c78a48f9 [file] [log] [blame]
/*
* Copyright (c) 2022, MediaTek Inc. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <assert.h>
#include <stdint.h>
#include <lib/spinlock.h>
#include <lib/mtk_init/mtk_init.h>
#include <lib/pm/mtk_pm.h>
#include "mt_cpu_pm.h"
#include "mt_cpu_pm_cpc.h"
#include "mt_cpu_pm_mbox.h"
#include <mt_lp_rm.h>
#include "mt_smp.h"
#include <mtk_mmap_pool.h>
#include <platform_def.h>
/*
* The locker must use the bakery locker when cache turns off.
* Using spin_lock will gain better performance.
*/
#ifdef MT_CPU_PM_USING_BAKERY_LOCK
DEFINE_BAKERY_LOCK(mt_cpu_pm_lock);
#define plat_cpu_pm_lock_init() bakery_lock_init(&mt_cpu_pm_lock)
#define plat_cpu_pm_lock() bakery_lock_get(&mt_cpu_pm_lock)
#define plat_cpu_pm_unlock() bakery_lock_release(&mt_cpu_pm_lock)
#else
spinlock_t mt_cpu_pm_lock;
#define plat_cpu_pm_lock_init()
#define plat_cpu_pm_lock() spin_lock(&mt_cpu_pm_lock)
#define plat_cpu_pm_unlock() spin_unlock(&mt_cpu_pm_lock)
#endif
enum mt_pwr_node {
MT_PWR_NONMCUSYS = 0,
MT_PWR_MCUSYS_PDN,
MT_PWR_SUSPEND,
MT_PWR_SYSTEM_MEM,
MT_PWR_SYSTEM_PLL,
MT_PWR_SYSTEM_BUS,
MT_PWR_MAX,
};
#define CPU_PM_DEPD_INIT BIT(0)
#define CPU_PM_DEPD_READY BIT(1)
#define CPU_PM_PLAT_READY BIT(2)
#ifdef CPU_PM_TINYSYS_SUPPORT
#define CPU_PM_INIT_READY (CPU_PM_DEPD_INIT | CPU_PM_DEPD_READY)
#define CPU_PM_LP_READY (CPU_PM_INIT_READY | CPU_PM_PLAT_READY)
#else
#define CPU_PM_LP_READY (CPU_PM_PLAT_READY)
#endif
#if CONFIG_MTK_PM_SUPPORT
#if CONFIG_MTK_CPU_SUSPEND_EN || CONFIG_MTK_SMP_EN
static void cpupm_cpu_resume_common(const struct mtk_cpupm_pwrstate *state)
{
CPU_PM_ASSERT(state != NULL);
mtk_cpc_core_on_hint_clr(state->info.cpuid);
}
#endif
#if CONFIG_MTK_SMP_EN
static int cpupm_cpu_pwr_on_prepare(unsigned int cpu, uintptr_t entry)
{
struct cpu_pwr_ctrl pwr_ctrl;
PER_CPU_PWR_CTRL(pwr_ctrl, cpu);
mt_smp_core_bootup_address_set(&pwr_ctrl, entry);
mt_smp_core_init_arch(0, cpu, 1, &pwr_ctrl);
return mt_smp_power_core_on(cpu, &pwr_ctrl);
}
static void cpupm_cpu_resume_smp(const struct mtk_cpupm_pwrstate *state)
{
CPU_PM_ASSERT(state != NULL);
plat_cpu_pm_lock();
mmio_clrbits_32(CPC_MCUSYS_CPC_FLOW_CTRL_CFG,
GIC_WAKEUP_IGNORE(state->info.cpuid));
plat_cpu_pm_unlock();
cpupm_cpu_resume_common(state);
}
static void cpupm_cpu_suspend_smp(const struct mtk_cpupm_pwrstate *state)
{
struct cpu_pwr_ctrl pwr_ctrl;
CPU_PM_ASSERT(state != NULL);
PER_CPU_PWR_CTRL(pwr_ctrl, state->info.cpuid);
mt_smp_power_core_off(&pwr_ctrl);
mmio_setbits_32(CPC_MCUSYS_CPC_FLOW_CTRL_CFG,
GIC_WAKEUP_IGNORE(state->info.cpuid));
}
static void cpupm_smp_init(unsigned int cpu, uintptr_t sec_entrypoint)
{
unsigned int reg;
struct mtk_cpupm_pwrstate state = {
.info = {
.cpuid = cpu,
.mode = MTK_CPU_PM_SMP,
},
.pwr = {
.afflv = 0,
.state_id = 0,
},
};
reg = mmio_read_32(CPC_MCUSYS_CPC_FLOW_CTRL_CFG);
if ((reg & CPC_MCUSYS_CPC_RESET_PWR_ON_EN) != 0) {
INFO("[%s:%d][CPU_PM] reset pwr on is enabled then clear it!\n",
__func__, __LINE__);
mmio_clrbits_32(CPC_MCUSYS_CPC_FLOW_CTRL_CFG, CPC_MCUSYS_CPC_RESET_PWR_ON_EN);
}
cpupm_cpu_pwr_on_prepare(cpu, sec_entrypoint);
cpupm_cpu_resume_smp(&state);
}
static struct mtk_cpu_smp_ops cpcv3_2_cpu_smp = {
.init = cpupm_smp_init,
.cpu_pwr_on_prepare = cpupm_cpu_pwr_on_prepare,
.cpu_on = cpupm_cpu_resume_smp,
.cpu_off = cpupm_cpu_suspend_smp,
};
#endif /* CONFIG_MTK_SMP_EN */
#if CONFIG_MTK_CPU_SUSPEND_EN
#define CPUPM_READY_MS (40000)
#define CPUPM_ARCH_TIME_MS(ms) (ms * 1000 * SYS_COUNTER_FREQ_IN_MHZ)
#define CPUPM_BOOTUP_TIME_THR CPUPM_ARCH_TIME_MS(CPUPM_READY_MS)
static int mt_pwr_nodes[MT_PWR_MAX];
static int plat_mt_lp_cpu_rc;
static unsigned int cpu_pm_status;
static unsigned int plat_prev_stateid;
static int mcusys_prepare_suspend(const struct mtk_cpupm_pwrstate *state)
{
unsigned int stateid = state->pwr.state_id;
if (mtk_cpc_mcusys_off_prepare() != CPC_SUCCESS) {
goto mt_pwr_mcusysoff_break;
}
if (!IS_PLAT_SUSPEND_ID(stateid)) {
if (mt_pwr_nodes[MT_PWR_SYSTEM_MEM] != 0) {
stateid = MT_PLAT_PWR_STATE_SYSTEM_MEM;
} else if (mt_pwr_nodes[MT_PWR_SYSTEM_PLL] != 0) {
stateid = MT_PLAT_PWR_STATE_SYSTEM_PLL;
} else if (mt_pwr_nodes[MT_PWR_SYSTEM_BUS] != 0) {
stateid = MT_PLAT_PWR_STATE_SYSTEM_BUS;
} else if (mt_pwr_nodes[MT_PWR_SUSPEND] != 0) {
stateid = MT_PLAT_PWR_STATE_SUSPEND;
} else {
stateid = MT_PLAT_PWR_STATE_MCUSYS;
}
}
plat_prev_stateid = stateid;
plat_mt_lp_cpu_rc = mt_lp_rm_find_and_run_constraint(0, state->info.cpuid, stateid, NULL);
if (plat_mt_lp_cpu_rc < 0) {
goto mt_pwr_mcusysoff_reflect;
}
#ifdef CPU_PM_TINYSYS_SUPPORT
mtk_set_cpu_pm_preffered_cpu(state->info.cpuid);
#endif
return MTK_CPUPM_E_OK;
mt_pwr_mcusysoff_reflect:
mtk_cpc_mcusys_off_reflect();
mt_pwr_mcusysoff_break:
plat_mt_lp_cpu_rc = -1;
return MTK_CPUPM_E_FAIL;
}
static int mcusys_prepare_resume(const struct mtk_cpupm_pwrstate *state)
{
if (plat_mt_lp_cpu_rc < 0) {
return MTK_CPUPM_E_FAIL;
}
mt_lp_rm_reset_constraint(plat_mt_lp_cpu_rc, state->info.cpuid, plat_prev_stateid);
mtk_cpc_mcusys_off_reflect();
return MTK_CPUPM_E_OK;
}
static unsigned int cpupm_do_pstate_off(const mtk_pstate_type psci_state,
const struct mtk_cpupm_pwrstate *state)
{
unsigned int pstate = MT_CPUPM_PWR_DOMAIN_CORE;
if (!state || (state->pwr.afflv > PLAT_MAX_PWR_LVL)) {
CPU_PM_ASSERT(0);
}
switch (state->pwr.state_id) {
case MT_PLAT_PWR_STATE_SYSTEM_MEM:
mt_pwr_nodes[MT_PWR_SYSTEM_MEM] += 1;
break;
case MT_PLAT_PWR_STATE_SYSTEM_PLL:
mt_pwr_nodes[MT_PWR_SYSTEM_PLL] += 1;
break;
case MT_PLAT_PWR_STATE_SYSTEM_BUS:
mt_pwr_nodes[MT_PWR_SYSTEM_BUS] += 1;
break;
case MT_PLAT_PWR_STATE_SUSPEND:
mt_pwr_nodes[MT_PWR_SUSPEND] += 1;
break;
default:
if (!IS_MT_PLAT_PWR_STATE_MCUSYS(state->pwr.state_id) &&
!IS_PLAT_SYSTEM_SUSPEND(state->pwr.afflv)) {
plat_cpu_pm_lock();
mt_pwr_nodes[MT_PWR_NONMCUSYS] += 1;
flush_dcache_range((uintptr_t)&mt_pwr_nodes[MT_PWR_NONMCUSYS],
sizeof(mt_pwr_nodes[MT_PWR_NONMCUSYS]));
plat_cpu_pm_unlock();
}
break;
}
if ((mt_pwr_nodes[MT_PWR_NONMCUSYS] == 0) && IS_PLAT_MCUSYSOFF_AFFLV(state->pwr.afflv)) {
/* Prepare to power down mcusys */
if (mcusys_prepare_suspend(state) == MTK_CPUPM_E_OK) {
mt_pwr_nodes[MT_PWR_MCUSYS_PDN] += 1;
flush_dcache_range((uintptr_t)&mt_pwr_nodes[MT_PWR_MCUSYS_PDN],
sizeof(mt_pwr_nodes[MT_PWR_MCUSYS_PDN]));
pstate |= (MT_CPUPM_PWR_DOMAIN_MCUSYS | MT_CPUPM_PWR_DOMAIN_CLUSTER);
}
}
if (state->pwr.afflv >= PLAT_MT_CPU_SUSPEND_CLUSTER) {
pstate |= MT_CPUPM_PWR_DOMAIN_CLUSTER;
}
if (psci_get_pstate_pwrlvl(psci_state) >= PLAT_MT_CPU_SUSPEND_CLUSTER) {
pstate |= MT_CPUPM_PWR_DOMAIN_PERCORE_DSU;
}
return pstate;
}
static unsigned int cpupm_do_pstate_on(const mtk_pstate_type psci_state,
const struct mtk_cpupm_pwrstate *state)
{
unsigned int pstate = MT_CPUPM_PWR_DOMAIN_CORE;
CPU_PM_ASSERT(state != NULL);
if (state->pwr.afflv > PLAT_MAX_PWR_LVL) {
CPU_PM_ASSERT(0);
}
if (mt_pwr_nodes[MT_PWR_MCUSYS_PDN] != 0) {
mt_pwr_nodes[MT_PWR_MCUSYS_PDN] = 0;
flush_dcache_range((uintptr_t)&mt_pwr_nodes[MT_PWR_MCUSYS_PDN],
sizeof(mt_pwr_nodes[MT_PWR_MCUSYS_PDN]));
pstate |= (MT_CPUPM_PWR_DOMAIN_MCUSYS | MT_CPUPM_PWR_DOMAIN_CLUSTER);
mcusys_prepare_resume(state);
}
if (state->pwr.afflv >= PLAT_MT_CPU_SUSPEND_CLUSTER) {
pstate |= MT_CPUPM_PWR_DOMAIN_CLUSTER;
}
switch (state->pwr.state_id) {
case MT_PLAT_PWR_STATE_SYSTEM_MEM:
mt_pwr_nodes[MT_PWR_SYSTEM_MEM] -= 1;
CPU_PM_ASSERT(mt_pwr_nodes[MT_PWR_SYSTEM_MEM] >= 0);
break;
case MT_PLAT_PWR_STATE_SYSTEM_PLL:
mt_pwr_nodes[MT_PWR_SYSTEM_PLL] -= 1;
CPU_PM_ASSERT(mt_pwr_nodes[MT_PWR_SYSTEM_PLL] >= 0);
break;
case MT_PLAT_PWR_STATE_SYSTEM_BUS:
mt_pwr_nodes[MT_PWR_SYSTEM_BUS] -= 1;
CPU_PM_ASSERT(mt_pwr_nodes[MT_PWR_SYSTEM_BUS] >= 0);
break;
case MT_PLAT_PWR_STATE_SUSPEND:
mt_pwr_nodes[MT_PWR_SUSPEND] -= 1;
CPU_PM_ASSERT(mt_pwr_nodes[MT_PWR_SUSPEND] >= 0);
break;
default:
if (!IS_MT_PLAT_PWR_STATE_MCUSYS(state->pwr.state_id) &&
!IS_PLAT_SYSTEM_SUSPEND(state->pwr.afflv)) {
plat_cpu_pm_lock();
mt_pwr_nodes[MT_PWR_NONMCUSYS] -= 1;
flush_dcache_range((uintptr_t)&mt_pwr_nodes[MT_PWR_NONMCUSYS],
sizeof(mt_pwr_nodes[MT_PWR_NONMCUSYS]));
plat_cpu_pm_unlock();
}
break;
}
if (IS_PLAT_SYSTEM_SUSPEND(state->pwr.afflv) ||
(IS_PLAT_SYSTEM_RETENTION(state->pwr.afflv) && (mt_pwr_nodes[MT_PWR_SUSPEND] > 0))) {
mtk_cpc_time_sync();
}
if (mt_pwr_nodes[MT_PWR_NONMCUSYS] < 0) {
CPU_PM_ASSERT(0);
}
pstate |= MT_CPUPM_PWR_DOMAIN_PERCORE_DSU;
return pstate;
}
static void cpupm_cpu_resume(const struct mtk_cpupm_pwrstate *state)
{
cpupm_cpu_resume_common(state);
}
static void cpupm_mcusys_resume(const struct mtk_cpupm_pwrstate *state)
{
assert(state != NULL);
}
static void cpupm_mcusys_suspend(const struct mtk_cpupm_pwrstate *state)
{
assert(state != NULL);
}
static unsigned int cpupm_get_pstate(enum mt_cpupm_pwr_domain domain,
const mtk_pstate_type psci_state,
const struct mtk_cpupm_pwrstate *state)
{
unsigned int pstate = 0;
if (state == NULL) {
return 0;
}
if (state->info.mode == MTK_CPU_PM_SMP) {
pstate = MT_CPUPM_PWR_DOMAIN_CORE;
} else {
if (domain == CPUPM_PWR_OFF) {
pstate = cpupm_do_pstate_off(psci_state, state);
} else if (domain == CPUPM_PWR_ON) {
pstate = cpupm_do_pstate_on(psci_state, state);
} else {
INFO("[%s:%d][CPU_PM] unknown pwr domain :%d\n",
__func__, __LINE__, domain);
assert(0);
}
}
return pstate;
}
static int cpupm_init(void)
{
int ret = MTK_CPUPM_E_OK;
#ifdef CPU_PM_TINYSYS_SUPPORT
int status;
if ((cpu_pm_status & CPU_PM_INIT_READY) == CPU_PM_INIT_READY) {
return MTK_CPUPM_E_OK;
}
if (!(cpu_pm_status & CPU_PM_DEPD_INIT)) {
status = mtk_lp_depd_condition(CPUPM_MBOX_WAIT_DEV_INIT);
if (status == 0) {
plat_cpu_pm_lock();
cpu_pm_status |= CPU_PM_DEPD_INIT;
plat_cpu_pm_unlock();
}
}
if ((cpu_pm_status & CPU_PM_DEPD_INIT) && !(cpu_pm_status & CPU_PM_DEPD_READY)) {
status = mtk_lp_depd_condition(CPUPM_MBOX_WAIT_TASK_READY);
if (status == 0) {
plat_cpu_pm_lock();
cpu_pm_status |= CPU_PM_DEPD_READY;
plat_cpu_pm_unlock();
}
}
ret = ((cpu_pm_status & CPU_PM_INIT_READY) == CPU_PM_INIT_READY) ?
MTK_CPUPM_E_OK : MTK_CPUPM_E_FAIL;
#endif
return ret;
}
static int cpupm_pwr_state_valid(unsigned int afflv, unsigned int state)
{
if (cpu_pm_status == CPU_PM_LP_READY) {
return MTK_CPUPM_E_OK;
}
if (cpupm_init() != MTK_CPUPM_E_OK) {
return MTK_CPUPM_E_FAIL;
}
if (read_cntpct_el0() >= (uint64_t)CPUPM_BOOTUP_TIME_THR) {
plat_cpu_pm_lock();
cpu_pm_status |= CPU_PM_PLAT_READY;
plat_cpu_pm_unlock();
}
if (!IS_PLAT_SYSTEM_SUSPEND(afflv) && (cpu_pm_status & CPU_PM_PLAT_READY) == 0) {
return MTK_CPUPM_E_FAIL;
}
return MTK_CPUPM_E_OK;
}
static struct mtk_cpu_pm_ops cpcv3_2_mcdi = {
.get_pstate = cpupm_get_pstate,
.pwr_state_valid = cpupm_pwr_state_valid,
.cpu_resume = cpupm_cpu_resume,
.mcusys_suspend = cpupm_mcusys_suspend,
.mcusys_resume = cpupm_mcusys_resume,
};
#endif /* CONFIG_MTK_CPU_SUSPEND_EN */
#endif /* CONFIG_MTK_PM_SUPPORT */
/*
* Depend on mtk pm methodology, the psci op init must
* be invoked after cpu pm to avoid initialization fail.
*/
int mt_plat_cpu_pm_init(void)
{
plat_cpu_pm_lock_init();
mtk_cpc_init();
#if CONFIG_MTK_PM_SUPPORT
#if CONFIG_MTK_CPU_SUSPEND_EN
register_cpu_pm_ops(CPU_PM_FN, &cpcv3_2_mcdi);
#endif /* CONFIG_MTK_CPU_SUSPEND_EN */
#if CONFIG_MTK_SMP_EN
register_cpu_smp_ops(CPU_PM_FN, &cpcv3_2_cpu_smp);
#endif /* CONFIG_MTK_SMP_EN */
#endif /* CONFIG_MTK_PM_SUPPORT */
INFO("[%s:%d] - CPU PM INIT finished\n", __func__, __LINE__);
return 0;
}
MTK_ARCH_INIT(mt_plat_cpu_pm_init);
static const mmap_region_t cpu_pm_mmap[] MTK_MMAP_SECTION = {
#ifdef CPU_PM_TINYSYS_SUPPORT
#if CONFIG_MTK_PM_SUPPORT && CONFIG_MTK_CPU_SUSPEND_EN
MAP_REGION_FLAT(CPU_EB_TCM_BASE, CPU_EB_TCM_SIZE, MT_DEVICE | MT_RW | MT_SECURE),
#endif
#endif
{0}
};
DECLARE_MTK_MMAP_REGIONS(cpu_pm_mmap);