/* * MMP2 Power Management Routines * * This software program is licensed subject to the GNU General Public License * (GPL).Version 2,June 1991, available at http://www.fsf.org/copyleft/gpl.html * * (C) Copyright 2012 Marvell International Ltd. * All Rights Reserved */ #include <linux/kernel.h> #include <linux/errno.h> #include <linux/err.h> #include <linux/time.h> #include <linux/delay.h> #include <linux/suspend.h> #include <linux/irq.h> #include <linux/io.h> #include <linux/interrupt.h> #include <asm/mach-types.h> #include <mach/hardware.h> #include <mach/cputype.h> #include <mach/addr-map.h> #include <mach/pm-mmp2.h> #include <mach/regs-icu.h> #include <mach/irqs.h> int mmp2_set_wake(struct irq_data *d, unsigned int on) { int irq = d->irq; struct irq_desc *desc = irq_to_desc(irq); unsigned long data = 0; if (unlikely(irq >= nr_irqs)) { pr_err("IRQ nubmers are out of boundary!\n"); return -EINVAL; } if (on) { if (desc->action) desc->action->flags |= IRQF_NO_SUSPEND; } else { if (desc->action) desc->action->flags &= ~IRQF_NO_SUSPEND; } /* enable wakeup sources */ switch (irq) { case IRQ_MMP2_RTC: case IRQ_MMP2_RTC_ALARM: data = MPMU_WUCRM_PJ_WAKEUP(4) | MPMU_WUCRM_PJ_RTC_ALARM; break; case IRQ_MMP2_PMIC: data = MPMU_WUCRM_PJ_WAKEUP(7); break; case IRQ_MMP2_MMC2: /* mmc use WAKEUP2, same as GPIO wakeup source */ data = MPMU_WUCRM_PJ_WAKEUP(2); break; } if (on) { if (data) { data |= __raw_readl(MPMU_WUCRM_PJ); __raw_writel(data, MPMU_WUCRM_PJ); } } else { if (data) { data = ~data & __raw_readl(MPMU_WUCRM_PJ); __raw_writel(data, MPMU_WUCRM_PJ); } } return 0; } static void pm_scu_clk_disable(void) { unsigned int val; /* close AXI fabric clock gate */ __raw_writel(0x0, CIU_REG(0x64)); __raw_writel(0x0, CIU_REG(0x68)); /* close MCB master clock gate */ val = __raw_readl(CIU_REG(0x1c)); val |= 0xf0; __raw_writel(val, CIU_REG(0x1c)); return ; } static void pm_scu_clk_enable(void) { unsigned int val; /* open AXI fabric clock gate */ __raw_writel(0x03003003, CIU_REG(0x64)); __raw_writel(0x00303030, CIU_REG(0x68)); /* open MCB master clock gate */ val = __raw_readl(CIU_REG(0x1c)); val &= ~(0xf0); __raw_writel(val, CIU_REG(0x1c)); return ; } static void pm_mpmu_clk_disable(void) { /* * disable clocks in MPMU_CGR_PJ register * except clock for APMU_PLL1, APMU_PLL1_2 and AP_26M */ __raw_writel(0x0000a010, MPMU_CGR_PJ); } static void pm_mpmu_clk_enable(void) { unsigned int val; __raw_writel(0xdffefffe, MPMU_CGR_PJ); val = __raw_readl(MPMU_PLL2_CTRL1); val |= (1 << 29); __raw_writel(val, MPMU_PLL2_CTRL1); return ; } void mmp2_pm_enter_lowpower_mode(int state) { uint32_t idle_cfg, apcr; idle_cfg = __raw_readl(APMU_PJ_IDLE_CFG); apcr = __raw_readl(MPMU_PCR_PJ); apcr &= ~(MPMU_PCR_PJ_SLPEN | MPMU_PCR_PJ_DDRCORSD | MPMU_PCR_PJ_APBSD | MPMU_PCR_PJ_AXISD | MPMU_PCR_PJ_VCTCXOSD | (1 << 13)); idle_cfg &= ~APMU_PJ_IDLE_CFG_PJ_IDLE; switch (state) { case POWER_MODE_SYS_SLEEP: apcr |= MPMU_PCR_PJ_SLPEN; /* set the SLPEN bit */ apcr |= MPMU_PCR_PJ_VCTCXOSD; /* set VCTCXOSD */ /* fall through */ case POWER_MODE_CHIP_SLEEP: apcr |= MPMU_PCR_PJ_SLPEN; /* fall through */ case POWER_MODE_APPS_SLEEP: apcr |= MPMU_PCR_PJ_APBSD; /* set APBSD */ /* fall through */ case POWER_MODE_APPS_IDLE: apcr |= MPMU_PCR_PJ_AXISD; /* set AXISDD bit */ apcr |= MPMU_PCR_PJ_DDRCORSD; /* set DDRCORSD bit */ idle_cfg |= APMU_PJ_IDLE_CFG_PJ_PWRDWN; /* PJ power down */ apcr |= MPMU_PCR_PJ_SPSD; /* fall through */ case POWER_MODE_CORE_EXTIDLE: idle_cfg |= APMU_PJ_IDLE_CFG_PJ_IDLE; /* set the IDLE bit */ idle_cfg &= ~APMU_PJ_IDLE_CFG_ISO_MODE_CNTRL_MASK; idle_cfg |= APMU_PJ_IDLE_CFG_PWR_SW(3) | APMU_PJ_IDLE_CFG_L2_PWR_SW; break; case POWER_MODE_CORE_INTIDLE: apcr &= ~MPMU_PCR_PJ_SPSD; break; } /* set reserve bits */ apcr |= (1 << 30) | (1 << 25); /* finally write the registers back */ __raw_writel(idle_cfg, APMU_PJ_IDLE_CFG); __raw_writel(apcr, MPMU_PCR_PJ); /* 0xfe086000 */ } static int mmp2_pm_enter(suspend_state_t state) { int temp; temp = __raw_readl(MMP2_ICU_INT4_MASK); if (temp & (1 << 1)) { printk(KERN_ERR "%s: PMIC interrupt is handling\n", __func__); return -EAGAIN; } temp = __raw_readl(APMU_SRAM_PWR_DWN); temp |= ((1 << 19) | (1 << 18)); __raw_writel(temp, APMU_SRAM_PWR_DWN); pm_mpmu_clk_disable(); pm_scu_clk_disable(); printk(KERN_INFO "%s: before suspend\n", __func__); cpu_do_idle(); printk(KERN_INFO "%s: after suspend\n", __func__); pm_mpmu_clk_enable(); /* enable clocks in MPMU */ pm_scu_clk_enable(); /* enable clocks in SCU */ return 0; } /* * Called after processes are frozen, but before we shut down devices. */ static int mmp2_pm_prepare(void) { mmp2_pm_enter_lowpower_mode(POWER_MODE_SYS_SLEEP); return 0; } /* * Called after devices are re-setup, but before processes are thawed. */ static void mmp2_pm_finish(void) { mmp2_pm_enter_lowpower_mode(POWER_MODE_CORE_INTIDLE); } static int mmp2_pm_valid(suspend_state_t state) { return ((state == PM_SUSPEND_STANDBY) || (state == PM_SUSPEND_MEM)); } /* * Set to PM_DISK_FIRMWARE so we can quickly veto suspend-to-disk. */ static const struct platform_suspend_ops mmp2_pm_ops = { .valid = mmp2_pm_valid, .prepare = mmp2_pm_prepare, .enter = mmp2_pm_enter, .finish = mmp2_pm_finish, }; static int __init mmp2_pm_init(void) { uint32_t apcr; if (!cpu_is_mmp2()) return -EIO; suspend_set_ops(&mmp2_pm_ops); /* * Set bit 0, Slow clock Select 32K clock input instead of VCXO * VCXO is chosen by default, which would be disabled in suspend */ __raw_writel(0x5, MPMU_SCCR); /* * Clear bit 23 of CIU_CPU_CONF * direct PJ4 to DDR access through Memory Controller slow queue * fast queue has issue and cause lcd will flick */ __raw_writel(__raw_readl(CIU_REG(0x8)) & ~(0x1 << 23), CIU_REG(0x8)); /* Clear default low power control bit */ apcr = __raw_readl(MPMU_PCR_PJ); apcr &= ~(MPMU_PCR_PJ_SLPEN | MPMU_PCR_PJ_DDRCORSD | MPMU_PCR_PJ_APBSD | MPMU_PCR_PJ_AXISD | 1 << 13); __raw_writel(apcr, MPMU_PCR_PJ); return 0; } late_initcall(mmp2_pm_init);