/* * sh7372 Power management support * * Copyright (C) 2011 Magnus Damm * * This file is subject to the terms and conditions of the GNU General Public * License. See the file "COPYING" in the main directory of this archive * for more details. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* DBG */ #define DBGREG1 0xe6100020 #define DBGREG9 0xe6100040 /* CPGA */ #define SYSTBCR 0xe6150024 #define MSTPSR0 0xe6150030 #define MSTPSR1 0xe6150038 #define MSTPSR2 0xe6150040 #define MSTPSR3 0xe6150048 #define MSTPSR4 0xe615004c #define PLLC01STPCR 0xe61500c8 /* SYSC */ #define SPDCR 0xe6180008 #define SWUCR 0xe6180014 #define SBAR 0xe6180020 #define WUPSMSK 0xe618002c #define WUPSMSK2 0xe6180048 #define PSTR 0xe6180080 #define WUPSFAC 0xe6180098 #define IRQCR 0xe618022c #define IRQCR2 0xe6180238 #define IRQCR3 0xe6180244 #define IRQCR4 0xe6180248 #define PDNSEL 0xe6180254 /* INTC */ #define ICR1A 0xe6900000 #define ICR2A 0xe6900004 #define ICR3A 0xe6900008 #define ICR4A 0xe690000c #define INTMSK00A 0xe6900040 #define INTMSK10A 0xe6900044 #define INTMSK20A 0xe6900048 #define INTMSK30A 0xe690004c /* MFIS */ #define SMFRAM 0xe6a70000 /* AP-System Core */ #define APARMBAREA 0xe6f10020 #define PSTR_RETRIES 100 #define PSTR_DELAY_US 10 #ifdef CONFIG_PM static int pd_power_down(struct generic_pm_domain *genpd) { struct sh7372_pm_domain *sh7372_pd = to_sh7372_pd(genpd); unsigned int mask = 1 << sh7372_pd->bit_shift; if (__raw_readl(PSTR) & mask) { unsigned int retry_count; __raw_writel(mask, SPDCR); for (retry_count = PSTR_RETRIES; retry_count; retry_count--) { if (!(__raw_readl(SPDCR) & mask)) break; cpu_relax(); } } pr_debug("sh7372 power domain down 0x%08x -> PSTR = 0x%08x\n", mask, __raw_readl(PSTR)); return 0; } static int pd_power_up(struct generic_pm_domain *genpd) { struct sh7372_pm_domain *sh7372_pd = to_sh7372_pd(genpd); unsigned int mask = 1 << sh7372_pd->bit_shift; unsigned int retry_count; int ret = 0; if (__raw_readl(PSTR) & mask) goto out; __raw_writel(mask, SWUCR); for (retry_count = 2 * PSTR_RETRIES; retry_count; retry_count--) { if (!(__raw_readl(SWUCR) & mask)) goto out; if (retry_count > PSTR_RETRIES) udelay(PSTR_DELAY_US); else cpu_relax(); } if (__raw_readl(SWUCR) & mask) ret = -EIO; out: pr_debug("sh7372 power domain up 0x%08x -> PSTR = 0x%08x\n", mask, __raw_readl(PSTR)); return ret; } static bool pd_active_wakeup(struct device *dev) { return true; } void sh7372_init_pm_domain(struct sh7372_pm_domain *sh7372_pd) { struct generic_pm_domain *genpd = &sh7372_pd->genpd; pm_genpd_init(genpd, NULL, false); genpd->stop_device = pm_clk_suspend; genpd->start_device = pm_clk_resume; genpd->dev_irq_safe = true; genpd->active_wakeup = pd_active_wakeup; genpd->power_off = pd_power_down; genpd->power_on = pd_power_up; genpd->power_on(&sh7372_pd->genpd); } void sh7372_add_device_to_domain(struct sh7372_pm_domain *sh7372_pd, struct platform_device *pdev) { struct device *dev = &pdev->dev; pm_genpd_add_device(&sh7372_pd->genpd, dev); if (pm_clk_no_clocks(dev)) pm_clk_add(dev, NULL); } void sh7372_pm_add_subdomain(struct sh7372_pm_domain *sh7372_pd, struct sh7372_pm_domain *sh7372_sd) { pm_genpd_add_subdomain(&sh7372_pd->genpd, &sh7372_sd->genpd); } struct sh7372_pm_domain sh7372_a4lc = { .bit_shift = 1, }; struct sh7372_pm_domain sh7372_a4mp = { .bit_shift = 2, }; struct sh7372_pm_domain sh7372_d4 = { .bit_shift = 3, }; struct sh7372_pm_domain sh7372_a3rv = { .bit_shift = 6, }; struct sh7372_pm_domain sh7372_a3ri = { .bit_shift = 8, }; struct sh7372_pm_domain sh7372_a3sg = { .bit_shift = 13, }; #endif /* CONFIG_PM */ static int sh7372_do_idle_core_standby(unsigned long unused) { cpu_do_idle(); /* WFI when SYSTBCR == 0x10 -> Core Standby */ return 0; } static void sh7372_enter_core_standby(void) { /* set reset vector, translate 4k */ __raw_writel(__pa(sh7372_resume_core_standby_a3sm), SBAR); __raw_writel(0, APARMBAREA); /* enter sleep mode with SYSTBCR to 0x10 */ __raw_writel(0x10, SYSTBCR); cpu_suspend(0, sh7372_do_idle_core_standby); __raw_writel(0, SYSTBCR); /* disable reset vector translation */ __raw_writel(0, SBAR); } static void sh7372_enter_a3sm_common(int pllc0_on) { /* set reset vector, translate 4k */ __raw_writel(__pa(sh7372_resume_core_standby_a3sm), SBAR); __raw_writel(0, APARMBAREA); if (pllc0_on) __raw_writel(0, PLLC01STPCR); else __raw_writel(1 << 28, PLLC01STPCR); __raw_writel(0, PDNSEL); /* power-down A3SM only, not A4S */ __raw_readl(WUPSFAC); /* read wakeup int. factor before sleep */ cpu_suspend(0, sh7372_do_idle_a3sm); __raw_readl(WUPSFAC); /* read wakeup int. factor after wakeup */ /* disable reset vector translation */ __raw_writel(0, SBAR); } static int sh7372_a3sm_valid(unsigned long *mskp, unsigned long *msk2p) { unsigned long mstpsr0, mstpsr1, mstpsr2, mstpsr3, mstpsr4; unsigned long msk, msk2; /* check active clocks to determine potential wakeup sources */ mstpsr0 = __raw_readl(MSTPSR0); if ((mstpsr0 & 0x00000003) != 0x00000003) { pr_debug("sh7372 mstpsr0 0x%08lx\n", mstpsr0); return 0; } mstpsr1 = __raw_readl(MSTPSR1); if ((mstpsr1 & 0xff079b7f) != 0xff079b7f) { pr_debug("sh7372 mstpsr1 0x%08lx\n", mstpsr1); return 0; } mstpsr2 = __raw_readl(MSTPSR2); if ((mstpsr2 & 0x000741ff) != 0x000741ff) { pr_debug("sh7372 mstpsr2 0x%08lx\n", mstpsr2); return 0; } mstpsr3 = __raw_readl(MSTPSR3); if ((mstpsr3 & 0x1a60f010) != 0x1a60f010) { pr_debug("sh7372 mstpsr3 0x%08lx\n", mstpsr3); return 0; } mstpsr4 = __raw_readl(MSTPSR4); if ((mstpsr4 & 0x00008cf0) != 0x00008cf0) { pr_debug("sh7372 mstpsr4 0x%08lx\n", mstpsr4); return 0; } msk = 0; msk2 = 0; /* make bitmaps of limited number of wakeup sources */ if ((mstpsr2 & (1 << 23)) == 0) /* SPU2 */ msk |= 1 << 31; if ((mstpsr2 & (1 << 12)) == 0) /* MFI_MFIM */ msk |= 1 << 21; if ((mstpsr4 & (1 << 3)) == 0) /* KEYSC */ msk |= 1 << 2; if ((mstpsr1 & (1 << 24)) == 0) /* CMT0 */ msk |= 1 << 1; if ((mstpsr3 & (1 << 29)) == 0) /* CMT1 */ msk |= 1 << 1; if ((mstpsr4 & (1 << 0)) == 0) /* CMT2 */ msk |= 1 << 1; if ((mstpsr2 & (1 << 13)) == 0) /* MFI_MFIS */ msk2 |= 1 << 17; *mskp = msk; *msk2p = msk2; return 1; } static void sh7372_icr_to_irqcr(unsigned long icr, u16 *irqcr1p, u16 *irqcr2p) { u16 tmp, irqcr1, irqcr2; int k; irqcr1 = 0; irqcr2 = 0; /* convert INTCA ICR register layout to SYSC IRQCR+IRQCR2 */ for (k = 0; k <= 7; k++) { tmp = (icr >> ((7 - k) * 4)) & 0xf; irqcr1 |= (tmp & 0x03) << (k * 2); irqcr2 |= (tmp >> 2) << (k * 2); } *irqcr1p = irqcr1; *irqcr2p = irqcr2; } static void sh7372_setup_a3sm(unsigned long msk, unsigned long msk2) { u16 irqcrx_low, irqcrx_high, irqcry_low, irqcry_high; unsigned long tmp; /* read IRQ0A -> IRQ15A mask */ tmp = bitrev8(__raw_readb(INTMSK00A)); tmp |= bitrev8(__raw_readb(INTMSK10A)) << 8; /* setup WUPSMSK from clocks and external IRQ mask */ msk = (~msk & 0xc030000f) | (tmp << 4); __raw_writel(msk, WUPSMSK); /* propage level/edge trigger for external IRQ 0->15 */ sh7372_icr_to_irqcr(__raw_readl(ICR1A), &irqcrx_low, &irqcry_low); sh7372_icr_to_irqcr(__raw_readl(ICR2A), &irqcrx_high, &irqcry_high); __raw_writel((irqcrx_high << 16) | irqcrx_low, IRQCR); __raw_writel((irqcry_high << 16) | irqcry_low, IRQCR2); /* read IRQ16A -> IRQ31A mask */ tmp = bitrev8(__raw_readb(INTMSK20A)); tmp |= bitrev8(__raw_readb(INTMSK30A)) << 8; /* setup WUPSMSK2 from clocks and external IRQ mask */ msk2 = (~msk2 & 0x00030000) | tmp; __raw_writel(msk2, WUPSMSK2); /* propage level/edge trigger for external IRQ 16->31 */ sh7372_icr_to_irqcr(__raw_readl(ICR3A), &irqcrx_low, &irqcry_low); sh7372_icr_to_irqcr(__raw_readl(ICR4A), &irqcrx_high, &irqcry_high); __raw_writel((irqcrx_high << 16) | irqcrx_low, IRQCR3); __raw_writel((irqcry_high << 16) | irqcry_low, IRQCR4); } #ifdef CONFIG_CPU_IDLE static void sh7372_cpuidle_setup(struct cpuidle_device *dev) { struct cpuidle_state *state; int i = dev->state_count; state = &dev->states[i]; snprintf(state->name, CPUIDLE_NAME_LEN, "C2"); strncpy(state->desc, "Core Standby Mode", CPUIDLE_DESC_LEN); state->exit_latency = 10; state->target_residency = 20 + 10; state->power_usage = 1; /* perhaps not */ state->flags = 0; state->flags |= CPUIDLE_FLAG_TIME_VALID; shmobile_cpuidle_modes[i] = sh7372_enter_core_standby; dev->state_count = i + 1; } static void sh7372_cpuidle_init(void) { shmobile_cpuidle_setup = sh7372_cpuidle_setup; } #else static void sh7372_cpuidle_init(void) {} #endif #ifdef CONFIG_SUSPEND static int sh7372_enter_suspend(suspend_state_t suspend_state) { unsigned long msk, msk2; /* check active clocks to determine potential wakeup sources */ if (sh7372_a3sm_valid(&msk, &msk2)) { /* convert INTC mask and sense to SYSC mask and sense */ sh7372_setup_a3sm(msk, msk2); /* enter A3SM sleep with PLLC0 off */ pr_debug("entering A3SM\n"); sh7372_enter_a3sm_common(0); } else { /* default to Core Standby that supports all wakeup sources */ pr_debug("entering Core Standby\n"); sh7372_enter_core_standby(); } return 0; } static void sh7372_suspend_init(void) { shmobile_suspend_ops.enter = sh7372_enter_suspend; } #else static void sh7372_suspend_init(void) {} #endif void __init sh7372_pm_init(void) { /* enable DBG hardware block to kick SYSC */ __raw_writel(0x0000a500, DBGREG9); __raw_writel(0x0000a501, DBGREG9); __raw_writel(0x00000000, DBGREG1); sh7372_suspend_init(); sh7372_cpuidle_init(); }